Alcatel BTS Hardware Description

Alcatel GSM Evolium BTS A9100 Hardware Description

BTS Document Sub-System Description Release B9 from MR4

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BLANK PAGE BREAK

Status

RELEASED

Short title

EVOL. BTS A9100 HW Desc. All rights reserved. Passing on and copying of this document, use and communication of its contents not permitted without written authorization from Alcatel.

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3BK 20942 AAAA TQZZA Ed.13

Contents

Contents Preface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 1

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Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 1.1 Modularity and Common Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 1.2 Cabinets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 1.2.1 Cabinet Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 1.2.2 Cabinet Dimensions and Weight . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 1.3 Subracks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 1.3.1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 1.3.2 Subrack Dimensions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 1.4 Cabinet-Mounted Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 1.4.1 Overview of Cabinet-Mounted Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 1.4.2 Dimensions and Weight of Cabinet-Mounted Equipment . . . . . . . . . . . . . . . . . . . 33 1.5 Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36 Configurations - Rack Layouts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 2.1 Naming Conventions for the BTS Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 2.2 Indoor Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 2.2.1 Indoor Configurations - Standard BTS GSM 900/1800/1900 . . . . . . . . . . . . . . . . 38 2.2.2 Indoor Configurations - Low Losses GSM 900/1800/1900 . . . . . . . . . . . . . . . . . . 48 2.2.3 Indoor Configurations - High Power GSM 1800 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52 2.2.4 Indoor Configurations - Extended Cell GSM 900 . . . . . . . . . . . . . . . . . . . . . . . . . . . 57 2.2.5 Indoor Configurations - Multiband BTS GSM 900/1800 . . . . . . . . . . . . . . . . . . . . . 60 2.2.6 Indoor Configurations - Multiband Cells GSM 900/1800 . . . . . . . . . . . . . . . . . . . . 71 2.2.7 AC Indoor Configurations GSM 900/1800 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76 2.3 A9100 BTS Indoor (G3) Extension with Twin TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81 2.3.1 G3 MINI - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . 81 2.3.2 G3 MINI - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 82 2.3.3 G3 MINI - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 82 2.3.4 G3 MEDI - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 83 2.3.5 G3 MEDI - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . 84 2.3.6 G3 MEDI - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . 85 2.4 A9100 BTS Indoor (G4) Extension with Twin TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 2.4.1 G4 MINI - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . 86 2.4.2 G4 MINI - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 87 2.4.3 G4 MINI - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 87 2.4.4 G4 MEDI - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 88 2.4.5 G4 MEDI - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . 90 2.4.6 G4 MEDI - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . 92 2.5 Multistandard Base Station Indoor Configurations with Single TRX . . . . . . . . . . . . . . . . . . . . . 95 2.5.1 MBI Configurations - Standard BTS GSM 850/900/1800/1900 . . . . . . . . . . . . . . 95 2.5.2 MBI Configurations - Low Losses GSM 900/1800/1900 . . . . . . . . . . . . . . . . . . . 108 2.5.3 MBI Configurations - High Power GSM 1800 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112 2.5.4 MBI Configurations - Extended Cell GSM 900 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 2.5.5 MBI Configurations - Multiband BTS GSM 900/1800 and GSM 900/1900 . . . 120 2.5.6 MBI Configurations - Multiband Cells GSM 900/1800 . . . . . . . . . . . . . . . . . . . . . 131 2.6 Multistandard Base Station Indoor Configurations with Twin TRX . . . . . . . . . . . . . . . . . . . . . . 138 2.6.1 Capacity Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 138 2.6.2 Capacity Mode Low Loss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 147 2.6.3 Multiband & MB Cell . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 153 2.6.4 Coverage Mode TxDiv. 2Rx Div. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 157 2.6.5 Coverage Mode TxDiv. 2Rx Div. Low Loss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 163 2.6.6 Coverage Mode TxDiv. 4Rx Div. Low Loss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 168 2.6.7 Extended Cell . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 172 2.6.8 Extended Cell TxDiv, 4RX Div for outer cell . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 175

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Multistandard Base Station Indoor Mixed Configurations Based on Extension with Twin TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177 2.7.1 MBI3 - 1 sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . . 178 2.7.2 MBI3 - 2 sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . 179 2.7.3 MBI3 - 3 sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . 180 2.7.4 MBI5 - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . . 181 2.7.5 MBI5 - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . 182 2.7.6 MBI5 - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . 183 Multistandard Base Station Indoor Mixed Configurations Based on Extension with Twin TRX (Only in MBI5 Cabinet Variant AB) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 185 2.8.1 MBI5 AB variant - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . 186 2.8.2 MBI5 AB variant - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . 187 2.8.3 MBI5 AB variant - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . 188 Outdoor Configurations with Single TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 190 2.9.1 Outdoor Configurations - Standard BTS GSM 900/1800/1900 . . . . . . . . . . . . . 190 2.9.2 Outdoor Configurations - Low Losses GSM 900/1800/1900 . . . . . . . . . . . . . . . . 206 2.9.3 Outdoor Configurations - High Power GSM 1800 . . . . . . . . . . . . . . . . . . . . . . . . . 210 2.9.4 Outdoor Configurations - Multiband BTS GSM 900/1800 . . . . . . . . . . . . . . . . . . 217 2.9.5 Outdoor Configurations - Multiband Cells GSM 900/1800 . . . . . . . . . . . . . . . . . 228 Outdoor Configurations with Twin TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 236 2.10.1 Capacity Mode Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 237 2.10.2 Capacity Mode Low Loss Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 238 2.10.3 Multiband Configurations - CBO - Multiband 1 + 1 Sector with Twin-TRX . . . . 239 2.10.4 Coverage Mode TX Diversity Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 240 2.10.5 Coverage Mode with TX Diversity Low Loss Configurations - CBO - 1 Sector TX Diversity Low Loss with Twin-TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 241 2.10.6 Coverage Mode TX-Diversity 4 RX Configurations - CBO - 1 Sector TX Diversity 4RX with Twin-TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 242 Outdoor Configurations Based on Extension with Twin TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . 244 2.11.1 CBO 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . . . 244 2.11.2 CBO 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . . 245 2.11.3 CBO DC 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 245 2.11.4 CBO DC 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 246 Multistandard Base Station Outdoor Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 247 2.12.1 MBO Standard Configurations - GSM 850/900/1800/1900 . . . . . . . . . . . . . . . . . 247 2.12.2 MBO Low Losses Configurations - GSM 900/1800/1900 . . . . . . . . . . . . . . . . . . 254 2.12.3 MBO High Power Configurations - GSM 900/1800 . . . . . . . . . . . . . . . . . . . . . . . . 257 2.12.4 MBO Multiband BTS Configurations - GSM 900/1800 and GSM 900/1900 . . 261 2.12.5 MBO Multiband Cells Configurations - GSM 900/1800 . . . . . . . . . . . . . . . . . . . . 268 2.12.6 MBO Multiband BTS, Multiband Cells Configurations - GSM 850/1800/1900 273 Multistandard Base Station Outdoor Configurations Based on Extension with Twin TRX . 275 2.13.1 MBO1 - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . 275 2.13.2 MBO1 - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . 276 2.13.3 MBO1 - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . 277 2.13.4 MBO2 - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . . 278 2.13.5 MBO2 - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . 279 2.13.6 MBO2 - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . . 280 Multistandard Base Station Outdoor Evolution Configurations with Single TRX . . . . . . . . . 281 2.14.1 A9100 MBO1E 1 Sector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 281 2.14.2 A9100 MBO1E 2 Sectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 281 2.14.3 A9100 MBO2E 3 Sectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 282 2.14.4 A9100 MBO2E 2 Sectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 283 2.14.5 A9100 MBO2E 3 Sectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 283 2.14.6 A9100 MBO2 4 Sectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 284 2.14.7 A9100 MBO2 6 Sectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 284 Multistandard Base Station Outdoor Evolution Mixed Configurations Based on Extension with Twin TRX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 285

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2.15.1 MBO1E - 1 Sector mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . . 2.15.2 MBO1E - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . 2.15.3 MBO1E - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . 2.15.4 MBO2E - 2 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . 2.15.5 MBO2E - 3 Sectors mixed configuration Single/Twin-TRX . . . . . . . . . . . . . . . . . 2.16 Multistandard Base Station Outdoor Evolution Configurations with Twin TRX . . . . . . . . . . . 2.16.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.2 Transceiver Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.3 Cabling Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.4 Capacity Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.5 Capacity Mode Low Loss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.6 Multiband & Multiband Cell . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.7 Coverage Mode TxDiv. 2Rx Div. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.8 Coverage Mode TxDiv. 2Rx Div. Low Loss . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.9 Coverage Mode TxDiv. 4Rx Div. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.10 Extended Cell . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.16.11 Extended Cell TxDiv, 4RX Div for outer cell . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Indoor Cabinets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1 CIMI/CIDI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.1 CIMI/CIDI Cabinet Access and Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.2 CIMI/CIDI Cabinet Interconnection Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.3 CIMI/CIDI Signal Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.4 CIMI/CIDI DC Supplies Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.5 CIMI/CIDI Power Supply and Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.6 CIMI/CIDI Cables and Cable Sets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1.7 CIMI/CIDI Data and Control Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2 CIMA/CIDE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.1 DC Power Supply Variant . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.2 AC Power Supply Variant . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.3 CIMA/CIDE Cabinet Access and Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.4 CIMA/CIDE Cabinet Interconnection Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.5 CIMA/CIDE Signal Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.6 CIMA/CIDE External Power Supply Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.7 CIMA/CIDE Power Supply and Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.8 CIMA/CIDE Cables and Cable Sets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.9 CIMA/CIDE Data and Control Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3 Multistandard Base Station Indoor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.1 DC Power Supply Variant . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.2 AC Power Supply Variant . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.3 MBI Cabinet Access and Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.4 MBI3/MBI5 Cabinet Interconnection Panels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.5 MBI Signal Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.6 MBI External Power Supply Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.7 MBI Power Supply and Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.8 MBI Cables and Cable Sets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.9 MBI Data and Control Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Outdoor Cabinets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1 Outdoor Cabinets General Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.1 COME/COMI/COEP with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.2 CODE/CODI/COEP with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.3 CPT2 with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.4 MBO1 with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.5 MBO1DC with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.6 MBO1E with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.7 MBO1EDC with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.8 MBO1T with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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285 286 287 288 289 290 290 291 292 298 307 312 317 321 326 331 333 335 336 337 340 341 346 347 349 353 354 355 355 356 359 360 361 363 368 373 374 375 375 376 380 382 386 387 393 397 399 400 401 402 403 404 405 406 407 408

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Contents

4.2

4.3

4.4

4.5

4.6

4.7 4.8

4.9

6 / 910

4.1.9 MBO2 with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.10 MBO2E with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.11 MBO2DC with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.12 MBO2EDC with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.13 COBO with Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.14 Side Compartment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.15 BTS Compartment 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.16 BTS Compartment 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.17 MBO1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.18 MBO1DC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.19 MBO1T . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.20 MBO1E . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.21 MBO1EDC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.22 MBOE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.23 MBOEDC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.24 MBOEE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.25 MBOEEDC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1.26 CBO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Outdoor Cabinet Access and Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.1 COME/COMI/CODI/CODE Cabinet Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.2 CPT2 Cabinet Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.3 MBO1/MBO1DC/MBO1T/MBO1E Cabinet Access . . . . . . . . . . . . . . . . . . . . . . . . 4.2.4 MBO2/MBO2DC/MBO2E Cabinet Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.5 CBO Cabinet Access . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.2.6 Outdoor Cabinet Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Outdoor Cabinet Interconnection Panel COMI/COME/CODI/CODE . . . . . . . . . . . . . . . . . . . . 4.3.1 Interconnection Panel - COME/COMI COAR Front View . . . . . . . . . . . . . . . . . . . 4.3.2 Interconnection Panel - CODE/CODI COAR Front View . . . . . . . . . . . . . . . . . . . 4.3.3 Interconnection Panel - BTS A9100 Outdoor Rear View . . . . . . . . . . . . . . . . . . . Outdoor Cabinet Signal Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.1 XIO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.2 External Clock Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.3 Abis Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.4.4 Miscellaneous Connections Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Outdoor Control Board CPT2/MBO1/MBO1DC/MBO1T/MBO1E/MBO2/MBO2DC/ MBO2E/CBO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.1 Connection Area (COAR) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.2 BTSRI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.3 XIOB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.5.4 RIBAT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Outdoor Cabinet Power Supply and Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.1 COME/COMI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.2 CODE/CODI/CPT2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.3 MBO1/MBO2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.4 MBO1DC/MBO2DC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.5 MBO1T . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.6 MBO1E/MBO2E . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.7 MBO1EDC/MBO2EDC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.8 CBO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.6.9 Temperature Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Outdoor Cabinet Lightning Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Outdoor Cabinet Cables and Cable Sets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.8.1 Internal Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.8.2 External Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Outdoor Cabinet Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.9.1 Outdoor Cabinet DC Power and Alarm Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.9.2 Outdoor Cabinet Data and Control Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

409 410 411 412 413 413 415 416 417 418 418 419 420 421 422 422 422 423 425 425 426 427 428 430 430 434 435 436 437 438 438 441 441 441 442 444 446 447 449 450 450 453 455 456 457 458 459 460 462 463 464 464 481 482 482 489

3BK 20942 AAAA TQZZA Ed.13

Contents

5

6

7

8

9

External Battery Cabinets . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1 External Indoor Battery Cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1.1 Mechanical Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1.2 External Battery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.1.3 Battery Cabinet External Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2 External Battery Cabinet Outdoor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.1 Mechanical Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.2 External Battery . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.3 Auxiliary Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2.4 External Battery Cabinet Outdoor Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Standard Telecommunications Subrack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.1 STASR General Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.2 STASR Mechanical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3 STASR Electrical Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3.1 Power Supplies and Grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3.2 Backplane . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3.3 Connectors and Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AC Power Subracks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1 SRACDC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.1 SRACDC Mechanical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.2 SRACDC Subrack Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.1.3 SRACDC Electrical Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.2 ACSR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.2.1 ACSR Mechanical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.2.2 ACSR Subrack Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.2.3 ACSR Electrical Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.3 ASIB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.3.1 ASIB Mechanical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.3.2 ASIB Layout . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7.3.3 ASIB Electrical Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Station Unit Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.1 Introduction to Station Unit Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2 Transmission and Clock Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2.1 Abis Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2.2 Transmission and Clock Microprocessor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2.3 Station Unit Module Clock Generation Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.2.4 Q1 Link . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.3 Base Station Internal Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.4 Operations and Maintenance Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.4.1 BTS Control Bus . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.4.2 OMU Microprocessor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.4.3 Glue Logic . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.5 Remote Inventory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.6 Station Unit Module Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.7 Station Unit Module LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8.8 Station Unit Module Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transceiver Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1 Single Transceiver Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1.1 Introduction to Transceiver Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1.2 Digital Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1.3 Analog Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1.4 TRE Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1.5 Transceiver Equipment LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.1.6 Transceiver Equipment Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2 TWIN Transceiver Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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9.2.1 Introduction to TWIN TRA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2.2 Digital Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2.3 Analog Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2.4 TWIN TRA Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2.5 Transceiver Equipments Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2.6 Transceiver Equipments LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.2.7 Transceiver Equipments Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Antenna Networks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1 ANX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1.1 AN Downlink Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1.2 AN Uplink Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1.3 BTS Control Bus Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1.4 Antenna Network Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1.5 AN Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1.6 ANX LEDs and Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1.7 ANX Performance Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.1.8 ANX Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.2 ANY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.2.1 ANY Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.2.2 ANY Performance Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.2.3 ANY Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3 ANC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3.1 ANC Basic Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3.2 ANC Detailed Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3.3 ANC Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3.4 ANC LEDs and Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3.5 ANC Performance Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.3.6 ANC Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4 AGC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4.1 AGC Basic Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4.2 AGC Detailed Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4.3 AGC Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4.4 Antenna Network Geran Combiner Controller . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4.5 AGC Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4.6 AGC LEDs and Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4.7 AGC Performance Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.4.8 AGC Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5 ANB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5.1 ANB Basic Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5.2 ANB Detailed Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5.3 ANB Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5.4 ANB LEDs and Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5.5 ANB Performance Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.5.6 ANB Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.6 GSM/UMTS Co-Siting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.6.1 Diplexer Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.6.2 Diplexer Mechanical Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.6.3 Environmental Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10.6.4 EMC Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Temperature Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.1 Cooling System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.1.1 Fan Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.1.2 Fan Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.1.3 Top Fan Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.2 HEX2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.2.1 LED(s) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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573 574 577 579 581 582 583 585 586 587 588 589 590 592 594 596 597 599 600 602 604 606 606 607 608 609 610 611 615 615 616 617 618 623 625 626 629 632 632 633 634 635 635 636 639 640 641 642 642 643 644 645 647 650 651 652

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Contents

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11.2.2 Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.2.3 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.2.4 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3 HEX3/HEX4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3.1 Blower Rotation Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3.2 Temperature Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3.3 Alarm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3.4 LED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3.5 Test Port . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3.6 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3.7 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3.8 Mechanical Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4 HEX5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4.1 Blower Rotation Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4.2 Temperature Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4.3 Alarm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4.4 LED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4.5 Test Port . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4.6 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4.7 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4.8 Mechanical Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5 HEX8/HEX9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5.1 Blower Rotation Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5.2 Temperature Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5.3 Alarm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5.4 LED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5.5 Test Port . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5.6 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5.7 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.5.8 Mechanical Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6 DAC8/DAC9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.1 Blower Rotation Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.2 Temperature Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.3 Filter Mats . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.4 Alarm . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.5 LED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.6 Test Port . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.7 RS232 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.8 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.9 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.6.10 Mechanical Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.7 HEAT2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.7.1 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.7.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.8 HEAT3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.8.1 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.8.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.9 HEAT4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.9.1 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.9.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.10 HEATDC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.10.1 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.10.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Supplies and Distribution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.1 ACIB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.1.1 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.1.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

3BK 20942 AAAA TQZZA Ed.13

652 653 653 654 655 655 655 655 655 656 656 657 658 659 659 659 659 659 660 660 661 662 663 663 663 663 663 664 664 665 666 667 667 667 667 667 667 668 668 669 669 670 671 672 673 674 674 675 676 676 677 678 678 679 680 681 681

9 / 910

Contents

12.2 12.3 12.4 12.5 12.6

12.7 12.8 12.9 12.10 12.11

12.12

12.13

12.14

12.15

12.16

12.17

12.18

12.19

12.20

12.21

10 / 910

LPFC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LPFMT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LPFM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LPFU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ACDUE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.6.1 Technical Charateristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.6.2 ACDUE Views . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ACMU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ACMUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ACSU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ACUC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . APOD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.11.1 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.11.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PM08 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.12.1 PM08 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.12.2 PM08 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.12.3 PM08 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PM11 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.13.1 PM11 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.13.2 PM11 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.13.3 PM11 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.13.4 PM11 LED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PM12 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.14.1 PM12 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.14.2 PM12 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.14.3 PM12 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.14.4 PM12 LED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PM18 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.15.1 Performance Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.15.2 LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.15.3 Fuses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.15.4 Protection and Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.15.5 PM18 Front View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.15.6 Weight . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BCU1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.16.1 BCU1 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.16.2 BCU1 LEDs, LCD, Alarms and Buttons . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.16.3 BCU1 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BCU2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.17.1 BCU2 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.17.2 BCU2 LEDs, LCD, Alarms and Buttons . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.17.3 BCU2 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.17.4 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BACO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.18.1 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.18.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BAC2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.19.1 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.19.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ABAC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.20.1 Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.20.2 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ADAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.21.1 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.21.2 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.21.3 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

682 683 684 686 687 687 688 688 690 690 691 693 694 694 695 695 696 698 699 699 700 702 702 703 703 705 707 707 708 708 709 711 711 712 713 714 714 716 718 718 718 721 724 724 725 726 726 727 728 728 729 730 730 731 732 733 733

3BK 20942 AAAA TQZZA Ed.13

Contents

12.22

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14

ADAM2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.22.1 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.22.2 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.22.3 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.23 ADAM4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.23.1 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.23.2 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.23.3 Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.24 BU41 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.24.1 Charging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.24.2 Discharging and Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.24.3 Front and Top View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.24.4 BU41 Mounted in MBO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.25 BU100 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.25.1 Charging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.25.2 Discharging and Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.25.3 Front and Top View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.26 BU101 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.26.1 Charging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.26.2 Discharging and Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.26.3 Front and Top View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.27 BU102 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.27.1 Charging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.27.2 Discharging and Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.27.3 Front and Top View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.28 BATS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.28.1 Batteries . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.28.2 Charging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.28.3 Discharging and Storage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.28.4 RIBATS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.28.5 Temperature Sensor . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.28.6 Battery Breaker . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.28.7 Front and Top View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.29 RIBAT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.29.1 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.29.2 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.29.3 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.29.4 XBCB Bus Termination . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.30 DCDP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.30.1 Front and Top View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.30.2 Front Panel Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.30.3 Rear Panel Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.31 DCDU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.31.1 Front and Side View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.31.2 Front Panel Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.32 DCDUE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.33 DCMU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.34 DCUC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.34.1 Front and Side View . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.34.2 Front Panel Connectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ACRI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.1 ACRI Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.2 ACRI LEDs and Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13.3 ACRI Front Panel . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Antenna Connector Lightning Protectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.1 Lightning Protector Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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734 735 736 736 737 738 739 739 740 741 741 742 743 744 745 746 746 747 748 749 749 750 750 751 751 752 752 753 753 754 754 754 754 755 755 756 757 757 758 759 760 760 761 762 763 764 765 768 769 770 771 772 773 774 775 776

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16

14.1.1 Operating Principles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.1.2 Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.1.3 Lightning Power Spectrum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.1.4 Quarter-Wave Stub . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.2 Lightning Protector Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14.3 Lightning Protector Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Range Extension Kit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.1 Introduction to REK . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.2 Overall Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.2.1 Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.2.2 Configurations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.3 Masthead Amplification Box . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.3.1 Transmit Power Amplifier and Required Attenuators . . . . . . . . . . . . . . . . . . . . . . . 15.3.2 Receive Amplifier . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.3.3 Output Duplexer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.3.4 Input Splitter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.3.5 RF Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.3.6 Supervision Circuits and Alarm Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.3.7 Bias Circuit and Lightning Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.3.8 Mechanical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.4 Power Distribution Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.4.1 Supervision and Alarm Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.4.2 LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.4.3 Reset Buttons . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.4.4 Bias Circuit and Lightning Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.4.5 Mechanical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.5 REK Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.5.1 Masthead Amplification Box Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.5.2 Power Distribution Unit Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.6 REK Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.6.1 Cabling Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.6.2 Masthead Amplification Box Cabling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.6.3 PDU Cabling in Indoor BTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.6.4 PDU Cabling in Outdoor BTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.7 REK Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.7.1 Ground Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.7.2 Alarm Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.7.3 DC Power Supply Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15.7.4 Jumper Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Tower-Mounted Amplifier . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.1 Introduction to TMA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.2 Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.2.1 Tower Mounted Amplifier with External Solution . . . . . . . . . . . . . . . . . . . . . . . . . . 16.2.2 Tower Mounted Amplifier with AGC Support . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3 Tower-Mounted Amplifier . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.1 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.2 Frequency Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.3.3 Mechanical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.4 Power Distribution Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.4.1 Appearance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.4.2 Switches and LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.4.3 Reset Button . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.4.4 Switching On . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.4.5 PDU LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.5 Bias T . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.6 Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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776 776 777 778 779 779 781 782 783 783 784 790 791 792 792 792 793 794 794 795 796 797 798 798 798 799 801 801 802 803 803 805 806 807 810 810 811 812 813 815 816 818 818 819 820 821 822 823 824 824 826 826 826 826 827 829

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Contents

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16.6.1 Indoor Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.6.2 Outdoor Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.7 TMA Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.7.1 Indoor/Outdoor BTS Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.7.2 Indoor BTS Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16.7.3 Outdoor BTS Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cable Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1 Internal Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.1 ANCO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.2 ANIC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.3 ANLC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.4 ANOC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.5 BOBU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.6 BOMU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.7 BOMUE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.8 BOMUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.9 BOSU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.10 BTSRI3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.11 BTSRI5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.12 BTSRIMA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.13 BTSRIMI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.14 BTSRIOUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.15 BUMA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.16 BUMI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.17 CA12 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.18 CA-2MMC2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.19 CA-ABIS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.20 CA-ACB2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.21 CA-ACSC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.22 CA-ADABM, CA-ADABP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.23 CA-ADACM, CA-ADACP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.24 CA-ADCO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.25 CA-ALPC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.26 CA-APC2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.27 CA-ASMC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.28 CA-BABRM, CA-BABRP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.29 CA-BRCM, CA-BRCP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.30 CA-BTSCA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.31 CA-CSTR . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.32 CA-DFUX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.33 CA-GCMW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.34 CA-Ground . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.35 CA-Ground1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.36 CA-Ground2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.37 CA-H2PC1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.38 CA-H2PC2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.39 CA-H2PC3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.40 CA-HOAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.41 CA-MLBP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.42 CA-MXBP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.43 CA-OHAC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.44 CA-ONCCx . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.45 CA-OSCP1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.46 CA-OSCP2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.47 CA-OSCP3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.48 CA-OSPC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.49 CA-PCAN, CA-PCAP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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Contents

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17.1.50 CA-PCOS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.51 CA-PDCM, CA-PDCP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.52 CA-RFMW . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.53 CA-RIBCO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.54 CA-RICPT1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.55 CA-RICPT2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.56 CA-RIMO1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.57 CA-RIMO2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.58 CA-SENSP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.59 CA-XBCBO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.60 CA-XIOC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.61 CA-XIOPC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.62 CIMA Bus Bar . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.63 CIMI Bus Bar . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.64 RXRC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.1.65 TXRC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2 External Cables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.1 CA01 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.2 CA02 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.3 CA03 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.4 CA04 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.5 CA-CBTE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.6 CA-GC35 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.7 CA-GND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.8 CA-PC2W16 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.9 CA-PC35BK . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.10 CA-PC35BL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.11 CA-PCEBM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.12 CA-PCEBP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.13 CA-RIBEB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.14 CA-RIBEO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.15 OCC23 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.16 OCC33 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.17 SCG2/3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.18 SCG3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.19 SCM1/3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17.2.20 SCM2/3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Environment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.1 Indoor Climatic and Mechanical Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.1.1 Environmental Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.1.2 Operational Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.1.3 Transportation Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.1.4 Storage Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.2 Outdoor Climatic and Mechanical Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.2.1 Environmental Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.2.2 Operational Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.2.3 Transportation Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.2.4 Storage Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.3 Electromagnetic Compatibility . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.3.1 EMC Immunity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.3.2 Transient Bursts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.3.3 Spurious Emissions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.4 Acoustic Noise . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18.5 Safety Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

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878 879 879 879 880 880 881 881 882 882 883 883 884 885 886 886 887 887 888 888 889 889 890 890 890 891 891 891 892 892 893 894 895 896 897 898 899 901 902 902 902 903 904 905 905 905 906 907 908 908 909 909 910 910

3BK 20942 AAAA TQZZA Ed.13

Preface

Preface Purpose

The Evolium BTS A9100 Hardware Description describes the cabinets, subracks, modules and cables of the Evolium BTS A9100. All equipment, features and functions described in this document may not be available on your system.

What’s New

In Edition 13 Section Tower Mounted Amplifier with AGC Support (Section 16.2.2) was added. Description improvement in Transceiver Equipments LEDs (Section 9.2.6).

In Edition 12 The following sections were added: Performance Characteristics with AGC GSM 900P Module Functional Variant ’B’ (Section 10.4.7.2) Performance Characteristics with AGC GSM 900P Module Functional Variant ’C’ (Section 10.4.7.3). Description improvement for filter attenuation in: ANC Performance Characteristics (Section 10.3.5) General Performance Characteristics (Section 10.4.7.1). Information about AGX module was removed.

In Edition 11 Section DAC8/DAC9 (Section 11.6) was added.

In Edition 10 Description improvement in: Indoor Cabinets (Section 3) Outdoor Cabinet Interconnection Panel COMI/COME/CODI/CODE (Section 4.3) Outdoor Cabinet Signal Interfaces (Section 4.4).

3BK 20942 AAAA TQZZA Ed.13

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Preface

In Edition 09 The following sections were added: A9100 BTS Indoor (G3) Extension with Twin TRX (Section 2.3) A9100 BTS Indoor (G4) Extension with Twin TRX (Section 2.4) Multistandard Base Station Indoor Mixed Configurations Based on Extension with Twin TRX (Section 2.7) Multistandard Base Station Indoor Mixed Configurations Based on Extension with Twin TRX (Only in MBI5 Cabinet Variant AB) (Section 2.8) Multistandard Base Station Outdoor Configurations Based on Extension with Twin TRX (Section 2.13) Multistandard Base Station Outdoor Evolution Mixed Configurations Based on Extension with Twin TRX (Section 2.15) Outdoor Configurations Based on Extension with Twin TRX (Section 2.11).

In Edition 08 Insertion loss in transmit pass band parameter was corrected in AGC Performance Characteristics (Section 10.4.7). Section External Battery Cabinet Outdoor Interfaces (Section 5.2.4) was added. Description improvement in: LEDs (Section 12.15.2) PM18 Front View (Section 12.15.5).

In Edition 07 Section TWIN Transceiver Equipment (Section 9.2) was added. Description improvement in: LEDs (Section 12.17.2.1) BCU2 Front Panel (Section 12.17.3).

In Edition 06 Description improvement in: LEDs (Section 12.17.2.1) BCU2 Front Panel (Section 12.17.3).

In Edition 05 Section DCDUE (Section 12.32) was added. The following sections were updated for MBOxEDC cabinet variant: Outdoor Cabinets (Section 1.2.1.2) Available Cabinets and Subracks (Section 1.4.1.1) Available Cabinet-Mounted Equipment / Modules (Section 1.4.1.2) Dimensions and Weight of Cabinet-Mounted Equipment (Section 1.4.2) Outdoor Cabinets General Information (Section 4.1)

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Preface

Outdoor Cabinet Access and Features (Section 4.2) Outdoor Cabinet Power Supply and Grounding (Section 4.6) MBO1/MBO1DC/MBO2/MBO2DC Internal Cables (Section 4.8.1.4) MBO1/MBO1DC/MBO1T/MBO2/MBO2DC (Section 4.9.1.3) Description improvement in Output Power Parameters (Section 12.15.1.3). Title formatting for Outdoor Control Board CPT2/MBO1/MBO1DC/MBO1T/MBO1E/MBO2/MBO2DC/ MBO2E/CBO (Section 4.5)

In Edition 04 The document was updated for A9100 MBS Evolution Outdoor. The following sections are added: HEX8/HEX9 (Section 11.5) ACDUE (Section 12.6) BOMUE (Section 17.1.7) PM18 (Section 12.15) The following sections were updated for MBOxE cabinet variant: Outdoor Cabinets (Section 1.2.1.2) Available Cabinets and Subracks (Section 1.4.1.1) Available Cabinet-Mounted Equipment / Modules (Section 1.4.1.2) Dimensions and Weight of Cabinet-Mounted Equipment (Section 1.4.2) Outdoor Cabinets General Information (Section 4.1) Outdoor Cabinet Access and Features (Section 4.2) Outdoor Cabinet Power Supply and Grounding (Section 4.6) MBO1/MBO1DC/MBO2/MBO2DC Internal Cables (Section 4.8.1.4) MBO1/MBO1DC/MBO1T/MBO2/MBO2DC (Section 4.9.1.3)

In Edition 03 The following sections were added for Geran Antenna Network: AGC (Section 10.4) AGX. Section ANC (Section 10.3) was updated for ANCGP.

In Edition 02 The document was updated with remark that XBCB connector is used for inventory of powered off BTSs at factory level. Section Transceiver Equipment (Section 9) was updated for new power amplifier TEPADHE on TADHE. The following sections were added for MBO1T cabinet variant: ACMUT (Section 12.8)

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Preface

LPFMT (Section 12.3) BOMUT (Section 17.1.8) The following sections were updated for MBO1T cabinet variant: Outdoor Cabinets (Section 1.2.1.2) Available Cabinet-Mounted Equipment / Modules (Section 1.4.1.2) Dimensions and Weight of Cabinet-Mounted Equipment (Section 1.4.2) MBO1T (Section 4.1.19) Outdoor Cabinet Access and Features (Section 4.2) MBO1T (Section 4.6.5) MBO1/MBO1DC/MBO2/MBO2DC Internal Cables (Section 4.8.1.4) MBO1/MBO1DC/MBO1T/MBO2/MBO2DC (Section 4.9.1.3) The following sections were updated for CBO cabinet with permanent DC connection: Outdoor Cabinets (Section 1.2.1.2) Available Cabinet-Mounted Equipment / Modules (Section 1.4.1.2) Dimensions and Weight of Cabinet-Mounted Equipment (Section 1.4.2) CBO (Section 4.1.26) CBO (Section 4.6.8) CBO (Section 4.9.1.5) The following sections were added: Outdoor CBO - 2x2 (Section 2.9.1.5) Outdoor CBO - 3x1 (Section 2.9.1.9) HEAT4 (Section 11.9) DCDU (Section 12.31). Section External Battery Cabinet Outdoor (Section 5.2) was updated for new EBCO Design on KNUERR TECORAS basis.

In Edition 01 Improvement of Abis interface description in Abis Interface (Section 3.1.3.4). Introduction of TRX EDGE+ with RF High Power for GSM 900/1800, Transceiver Equipment (Section 9) has been updated due to introduction of TRX EDGE+ with RF High Power for GSM 900/1800. Update for widen the AC voltage range of PM12 AC/DC converter from 230V+/-15% to 150~280V AC.

Audience

This manual is for: Commissioning personnel System support engineers Training department (for reference use) Any other personnel interested in the Evolium BTS A9100 hardware.

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Assumed Knowledge

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The reader must have a general knowledge of telecommunications systems, terminology and BTS functions.

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Preface

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1 Overview

1 Overview This Overview gives information needed for project managers and foremen, for the presentation to the customer and site planning.

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1 Overview

1.1 Modularity and Common Information The BTS A9100’s modular design allows for omni-directional, sectorized and multiband configurations. Configurations are built from a small range of primary components. This allows BTS installations to be tailored to suit different situations and applications. The basic building blocks of a BTS A9100 installation are: Cabinets for indoor and outdoor installations Four types of subrack. SRACDC, ACSR, and ASIB house the AC/DC power modules; STASR houses the telecommunications modules and AC/DC power modules A number of telecommunications modules Power supply modules Modules for temperature control. Additional cabinet equipment is required, such as fans, power supplies, heat exchangers, optional batteries and cables. The arrangement of the subracks in the cabinets takes into account the requirements for: Thermal cooling, achieved with forced-air cooling Minimization of floor space, achieved with back-to-back, back-to-wall or side-to-side cabinet installations Ease of access and maintenance, from the front of the cabinets Future system expansion.

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1 Overview

Configurations

Based on those building blocks all possible BTS A9100 configurations are assembled, see Configurations - Rack Layouts (Section 2).

Operating Temperatures

All BTS A9100 equipment operates in a temperature-controlled environment. The internal temperature of enclosures is regulated with a combination of heaters, heat exchangers and cooling fans, depending on the type of installation required. Environmental conditions, such as the availability of an indoor or outdoor site and climate, are taken into consideration when planning an installation.

Grounding

Grounding of BTS A9100 equipment installations is maintained throughout, via a distributed earthing system which interconnects all metallic parts with the cabinet ground. A cabinet bus bar (or a cableform equivalent) is an important part of this earthing system. The bus bar complies with European standard EN60950 V2. Equipment cabinets must be connected to a suitable external system ground at the installation site.

Units of Measurement

Standard TEP units of measurement are used for BTS A9100 equipment. Metric and imperial equivalents for the TEP units are as follows: 1 HU = 44.45 mm (1.75 inches) 1 WU = 5.08 mm (0.20 inches).

Standards

All BTS A9100 equipment complies with the following ETSs: ETS 300 342-2 EMC for European Digital Cellular Telecommunications Systems GSM Recommendation for Base Station Equipment 11.21, prETS300.

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1 Overview

1.2 Cabinets 1.2.1 Cabinet Overview The type of cabinet used depends on a number of different items required for a particular installation. Cabinet types and requirements are described below for: Indoor cabinets Outdoor cabinets Configurations Indoor power requirements Outdoor power requirements Cabling.

1.2.1.1 Indoor Cabinets The available indoor cabinets, and the number of subracks they can contain, are: CIMI - two STASRs CIDI - two STASRs CIMA - five STASRs, or three STASRs and one ASIB CIDE - five STASRs, or four STASRs and a battery area for BU41s or BU100s MBI3 - three STASRs, or two STASRs and a battery area for BU101s MBI5 - five STASRs, or four STASRs and a battery area for BU101s.

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1 Overview

1.2.1.2 Outdoor Cabinets The available outdoor cabinets, and the number of subracks they can contain, are: COMI - two STASRs and one SRACDC or ACSR and a battery area for BU41s or BU100s and MV area COME - five STASRs and one SRACDC or ACSR and a battery area for BU41s or BU100s and MV area CODI - four STASRs and a battery area for BU41s or BU100s and MV area CODE - seven STASRs and a battery area for BU41s or BU100s and MV area CPT2 - five STASRs and a battery area for BU41s or BU100s MBO1 - four STASRs and a battery area for BU41s or BU101s MBO1DC - three STASRs and an MW area MBO1T - three STASRs and an MW area MBO1E - three STASRs, power supplies subrack and an optional area for batteries or microwave MBO1EDC - three STASRs and an optional area for microwave MBO2 - eight STASRs and a battery area for BU41s or BU101s MBO2DC - six STASRs and a MW area MBO2E - six STASRs, power supplies subrack and an optional area for batteries or microwave MBO2EDC - six STASRs and an optional area for microwave CBO - two STASRs with a MW area and optional BATS for the AC variant. An additional cabinet, COEP, is required when upgrading a COMI to the functionality of a COME, or when upgrading a CODI to the functionality of a CODE.

1.2.1.3 Indoor Power Requirements The CIMI/CIDI, CIMA/CIDE, and MBI3/MBI5 cabinets are designed to operate from the following external supply voltages: CIMI and CIMA DC external supply variant: 0/ -48 VDC 0/ -60 VDC. CIMA/CIDE and MBI3/MBI5 AC external supply variant, 230 VAC 1 Ø The AC input is converted to 0/ -48 VDC nom. for use within the cabinets. In the event of a mains failure, an optional battery backup unit BU41 or BU100 can be used to provide the DC supply voltage. For more information about the CIMI/CIDI and CIMA/CIDE, refer to CIMI/CIDI (Section 3.1) and CIMA/CIDE (Section 3.2), respectively. For more information about the BU41 and BU100, refer to BU41 (Section 12.24) and BU100 (Section 12.25) respectively.

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1 Overview

1.2.1.4 Outdoor Power Requirements The COMI/CODI, COME/CODE, CPT2, and MBO1/MBO1E/MBO2/MBO2E cabinets are designed to operate from external AC mains supplies: 230 VAC 1Ø 400 VAC 3Ø. The CBO and MBO1T cabinet are designed to operate from external AC mains supplies 230 VAC 1Ø. The AC input is converted to 0/ -48 VDC nom. for use within the cabinets. In the event of a mains failure, an optional battery backup unit, BU41 or BU100, can be used to provide the DC supply voltage. The CBO DC and MBO1DC/MBO2DC cabinets are designed to operate from external DC mains supplies. The 0/ -48 VDC nom. input is distributed for use within the cabinets. For more information about the COMI/CODI, COME/CODE, CPT2, CBO and MBO1/MBO2, refer to Outdoor Cabinets (Section 4). For more information about the BU41, BU100 and BU101, refer to BU41 (Section 12.24), BU100 (Section 12.25) and BU101 (Section 12.26) respectively.

1.2.1.5 Cabling The cable sets supplied with the BTS A9100 fall into the following categories: Power Abis links Internal interconnection.

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1 Overview

1.2.2 Cabinet Dimensions and Weight The following table shows the overall dimensions and the weight of all cabinets.

Cabinet

Height Overall/ Usable

Width Overall/ Usable

CIMI/CIDI

920 mm/ 16 HU

CIMA/CIDE

Depth

Weight

600 mm/ 84 WU

450 mm

115 kg fully equipped

1940 mm/ 38 HU

600 mm/ 84 WU

450 mm

270 kg fully equipped (AC and DC)

COMI/CODI

1500 mm/ 24 HU

1200 mm/ 2 x 84 WU

(side compartment)

24 HU = 17 HU for equipment + 7 HU for battery

700 mm

200 kg empty (except for HEX2 and HEAT2)

COME/CODE (compartment 1 and 2)

1500 mm/ 24 HU

1800 mm/ 3 x 84 WU

700 mm

295 kg empty (except for HEX2 and HEAT2)

(side compartment)

24 HU = 17 HU for equipment + 7 HU for batteries

COEP

1500 mm/ 24 HU

600 mm/ 84 WU

700 mm

95 kg empty (except for HEX2 and HEAT2)

CPT2

1500 mm/ 24 HU

1200 mm/ 2 x 84 WU

700 mm

380 kg fully equipped w/ o battery

MBI3

1300 mm/ 23 HU

600 mm/ 84 WU

450 mm

170 kg fully equipped (AC and DC)

MBI5

1940 mm/ 38 HU

600 mm/ 84 WU

450 mm

270 kg fully equipped (AC and DC)

MBO1/MBO1DC/MBO1T 1500 mm/ 24 HU

825 mm/ 162 WU

750 mm

95 kg not equipped w/ o battery

MBO1E

1610 mm/26 HU

940 mm/ 185 WU

750 mm

90 kg for empty cabinet

MBO2/MBO2DC

1500 mm/ 24 HU

1500 mm/ 295 WU

750 mm

175 kg not equipped w/ o battery

MBO2E

1610 mm/26 HU

1550 mm/ 305 WU

750 mm

150 kg for empty cabinet

CBO/CBO DC

900 mm/ 18 HU

720 mm/ 84 WU

700 mm

150 kg fully equipped

Table 1: Cabinets, Dimensions and Weight

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1 Overview

1.3 Subracks 1.3.1 Overview The subracks are constructed from two steel-chromate side plates and five metal extrusions which form a frame box. Attached to the frame box are the backplane module and FANU guide rails, and other components such as a ground connector. The subrack is equipped with six integral lugs which enable it to be fixed to the equipment rack with self-tapping screws. The subracks conform to ETSI standard IEC297-3 for 19 inch telecommunications equipment practice. The subrack plug-in modules are electrically connected by inserting them into the backplane connectors along plastic guide rails. The connectors have guide-pins which ensure the module and subrack connectors mate together, without risk of bending the connector pins. The plug-in modules are secured in the subrack with Camloc quarter-turn fasteners. There are four types of subrack: STASR The STASR is the basic subrack used for all indoor and outdoor applications. It can contain a mixture of telecommunications and power supply plug-in modules. When the subrack contains TREs additional components, the FANU and FACB, are attached to the subrack. For more information about the STASR, refer to Standard Telecommunications Subrack (Section 6). SRACDC The SRACDC is an AC power supply subrack for BTS A9100 outdoor configurations. For more information about the SRACDC, refer to SRACDC (Section 7.1). ACSR The ACSR is an AC power supply subrack used for BTS A9100 outdoor configurations. For more information about the ACSR, refer to ACSR (Section 7.2). ASIB The ASIB is only used for indoor applications. For more information about the ASIB, refer to ASIB (Section 7.3).

1.3.2 Subrack Dimensions The following table shows the overall dimensions of all the subracks. They are the same for STASR, SRACDC, ACSR and ASIB. Height (TEP/ mm)

Width (TEP/ mm)

Depth (mm)

7 HU/ 311.5

84 WU/ 431.8

304.4

(= 6 HU for modules + 1 HU for fans) Table 2: Subracks, Dimensions

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1.4 Cabinet-Mounted Equipment 1.4.1 Overview of Cabinet-Mounted Equipment The cabinet-mounted equipment and modules available for the BTS A9100 are listed in the following tables. The tables also provide a reference to the sections that describe each item.

1.4.1.1 Available Cabinets and Subracks The cabinet and subracks available for the BTS A9100 are listed below. Mnemonic

Description

Part No.

For More Information...

ACSR

AC Subrack for PM11

3BK 08712

ACSR (Section 7.2)

ASIB

AC/DC Subrack Individual Battery

3BK 08676

ASIB (Section 7.3)

CIDE

Cabinet Indoor Medi

3BK 25098

CIMA/CIDE (Section 3.2)

CIDI

Cabinet Indoor Mini

3BK 25099

CIMI/CIDI (Section 3.1)

CIMA

Cabinet Indoor Medi

3BK 07181

CIMA/CIDE (Section 3.2)

CIMI

Cabinet Indoor Mini

3BK 07605

CIMI/CIDI (Section 3.1)

CODE

Cabinet Outdoor Medi

3BK 25100

Outdoor Cabinets (Section 4)

CODI

Cabinet Outdoor Mini

3BK 25101

Outdoor Cabinets (Section 4)

COEP

Cabinet Outdoor Expanding Part

3BK 07979

Outdoor Cabinets (Section 4)

COME

Cabinet Outdoor Medi

3BK 07606

Outdoor Cabinets (Section 4)

COMI

Cabinet Outdoor Mini

3BK 07607

Outdoor Cabinets (Section 4)

CPT2

Compact Outdoor, 2 Doors

3BK 25468

Outdoor Cabinets (Section 4)

MBI3

Multistandard BTS Indoor, 1 Door

3BK 25964

Multistandard Base Station Indoor (Section 3.3)

MBI5

Multistandard BTS Indoor, 2 Doors

3BK 25965

Multistandard Base Station Indoor (Section 3.3)

MBO1

Multistandard BTS Outdoor, 1 Door

3BK 25673

Outdoor Cabinets (Section 4)

MBO1E/MBO1EDC Multistandard BTS Evolution Outdoor, 1 Door

3BK 27263

Outdoor Cabinets (Section 4)

MBO2

3BK 25675

Outdoor Cabinets (Section 4)

MBO2E/MBO2EDC Multistandard BTS Evolution Outdoor, 2 Doors

3BK 27264

Outdoor Cabinets (Section 4)

MBOE

3BK 25677

Outdoor Cabinets (Section 4)

MBOEE/MBOEEDC Extension Outdoor Evolution Cabinet Multistandard

3BK 27265

Outdoor Cabinets (Section 4)

MBO1DC

Multistandard BTS DC Outdoor, 1 Door

3BK 26612

Outdoor Cabinets (Section 4)

MBO2DC

Multistandard BTS DC Outdoor, 2 Doors

3BK 26614

Outdoor Cabinets (Section 4)

MBOEDC

Extension Outdoor DC Cabinet Multistandard

3BK 26616

Outdoor Cabinets (Section 4)

Multistandard BTS Outdoor, 2 Doors

Extension Outdoor Cabinet Multistandard

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Mnemonic

Description

Part No.

For More Information...

MBO1T

Multistandard BTS Outdoor Tropical, 1 Door

3BK 27138

Outdoor Cabinets (Section 4)

SRACDC

AC/DC Subrack Outdoor

3BK 07987

SRACDC (Section 7.1)

STASR

Standard Communications Subrack

3BK 07193

Standard Telecommunications Subrack (Section 6)

CBO

Compact BTS Outdoor

3BK 26320

Outdoor Cabinets (Section 4)

CBO DC

Compact BTS Outdoor DC powered

3BK 27013

Outdoor Cabinets (Section 4)

Table 3: Cabinet and Subrack Part Numbers

1.4.1.2 Available Cabinet-Mounted Equipment / Modules The cabinet-mounted equipment and modules available for the BTS A9100 are listed in the following table. Mnemonic

Description

Part No.

For More Information...

ABAC

AC Indoor Battery Control Unit

3BK 08673

ABAC (Section 12.20)

ACDUE

AC Distribution Unit Evolution

3BK 27266

ACDUE (Section 12.6)

ACIB

AC Interface Box

3BK 07989

ACIB (Section 12.1)

ACRI

AC Remote Inventory

3BK 07941

ACRI (Section 13)

ACMU

AC Switch Unit Multistandard

3BK 25785

ACMU (Section 12.7)

ACMUT

AC Distribution Unit Tropical

3BK 27140

ACMUT (Section 12.8)

ACSU

AC Switch Unit

3BK 25126

ACSU (Section 12.9)

ACUC

AC Connection Unit Compact

3BK 26323

ACUC (Section 12.10)

ADAM

Adapter Module

3BK 25025

ADAM (Section 12.21)

ADAM2

Adapter Module 2

3BK 25475

ADAM2 (Section 12.22)

ADAM4

Adapter Module 4

3BK 25997

ADAM4 (Section 12.23)

AFIP

AC Indoor Filter Panel

3BK 08674

CIMA/CIDE Power Supply and Grounding (Section 3.2.7)

ANCD

Antenna Network Combined GSM 1800 Module

3BK 08995

ANC (Section 10.3)

ANCG

Antenna Network Combined GSM 900 Module

3BK 08993

ANC (Section 10.3)

ANCL

Antenna Network Combined GSM 850 Module

3BK 25900

ANC (Section 10.3)

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Mnemonic

Description

Part No.

For More Information...

ANCP

Antenna Network Combined GSM 1900 Module

3BK 25393

ANC (Section 10.3)

ANXD

Antenna Network X GSM 1800 Module

3BK 07241

ANX (Section 10.1)

ANXG

Antenna Network X GSM 900 Module

3BK 07232

ANX (Section 10.1)

ANXP

Antenna Network GSM 1900 Module

3BK 08459

ANX (Section 10.1)

ANYD

Antenna Network Y GSM 1800 Module

3BK 07245

ANY (Section 10.2)

ANYG

Antenna Network Y GSM 900 Module

3BK 07237

ANY (Section 10.2)

ANYL

Antenna Network Y GSM 850 Module

3BK 25903

ANY (Section 10.2)

ANYP

Antenna Network Y GSM 1900 Module

3BK 08465

ANY (Section 10.2)

APOD

AC Indoor Power Distribution Panel

3BK 08675

APOD (Section 12.11)

BACO

Battery Connection Box

3BK 07988 AA

BACO (Section 12.18)

BAC2

Battery Connection Box

3BK 07988 AB

BAC2 (Section 12.19)

BATS

Small Battery Unit

3BK 25848

BATS (Section 12.28)

BCU1

Battery Control Unit 1

3BK 06784

BCU1 (Section 12.16)

BCU2

Battery Control Unit 2

3BK 08714

BCU2 (Section 12.17)

BU41

Battery Unit 40 Ah

3BK 08035

BU41 (Section 12.24)

BU100

Battery Unit 100 Ah

3BK 08932

BU100 (Section 12.25)

BU101

Battery Unit 100 Ah for using in MBO

3BK 25854

BU101 (Section 12.26)

DAC8

Direct Air Cooling 8 used in MBOEE

3BK 27794

DAC8/DAC9 (Section 11.6)

DAC9

Direct Air Cooling 9 used in MBO1E

3BK 27795

DAC8/DAC9 (Section 11.6)

DCDP

DC Distribution Panel

3BK 07990

DCDP (Section 12.30)

DCDU

DC Distribution Unit

3BK 27015

DCDU (Section 12.31)

DCDUE

DC Distribution Unit Evolution

3BK 27267

DCDUE (Section 12.32)

DCMU

DC Connection Unit Multistandard

3BK 26618

DCMU (Section 12.33)

DCUC

DC Distribution Unit Compact

3BK 26324

DCUC (Section 12.34)

FACB

Fan Control Board

3BK 07202

Cooling System (Section 11.1)

FANU

Fan Unit

3BK 07205

Cooling System (Section 11.1)

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Mnemonic

Description

Part No.

For More Information...

HEAT2

Heating Unit 2

3BK 08075

HEAT2 (Section 11.7)

HEAT3

Heating Unit 3

3BK 26343

HEAT3 (Section 11.8)

HEATDC

Heating Unit DC

3BK 26619

HEATDC (Section 11.10)

HEX2

Heat Exchanger 2

3BK 07978

HEX2 (Section 11.2)

HEX3

Heat Exchanger 3 for using in MBOE

3BK 25659

HEX3/HEX4 (Section 11.3)

HEX4

Heat Exchanger 4 for using in MBO1

3BK 25660

HEX3/HEX4 (Section 11.3)

HEX5

Heat Exchanger 5 for using in CBO

3BK 26325

HEX5 (Section 11.4)

HEX8

Heat Exchanger 8 for using in MBOEE

3BK 27148

HEX8/HEX9 (Section 11.5)

HEX9

Heat Exchanger 9 for using in MBO1E

3BK 27149

HEX8/HEX9 (Section 11.5)

LPFC

Lightning Protection and Filter Unit Compact

3BK 26322

LPFC (Section 12.2)

LPFMT

Lightning Protection and Filter Unit Tropical

3BK 27141

LPFMT (Section 12.3)

LPFM

Lightning Protection and Filter Unit Multistandard

3BK 25786

LPFM (Section 12.4)

LPFU

Lightning Protection and Filter Unit

3BK 25157

LPFU (Section 12.5)

PM08

Power Module 800 W

3BK 06783

PM08 (Section 12.12)

PM11

Power Module 1100 W

3BK 08713

PM11 (Section 12.13)

PM12

Power Module 1200 W

3BK 25024

PM12 (Section 12.14)

PM18

Power Module 1800 W

3BK 27198

PM18 (Section 12.15)

RIBAT

Remote Inventory Battery

3BK 25134

RIBAT (Section 12.29)

SUMA

Station Unit Module Advanced

3BK 08925

Station Unit Modules (Section 8)

SUMP

Station Unit Module PCM

3BK 07224

Station Unit Modules (Section 8)

TADH

Transceiver Module GSM 1800 High Power

3BK 25373

Transceiver Equipment (Section 9)

TAGH

Transceiver Module GSM 900 High Power

3BK 26154

Transceiver Equipment (Section 9)

TRAD

Transceiver Module GSM 1800 Medium Power

3BK 08980

Transceiver Equipment (Section 9)

TRADE

Transceiver Module GSM 1800 Medium Power Enhanced 8-PSK power

3BK 26526

Transceiver Equipment (Section 9)

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Mnemonic

Description

Part No.

For More Information...

TRAG

Transceiver Module GSM 900 Medium Power

3BK 08967

Transceiver Equipment (Section 9)

TRAGE

Transceiver Module GSM 900 Medium Power Enhanced 8-PSK power

3BK 26525

Transceiver Equipment (Section 9)

TRAL

Transceiver Module GSM 850 Medium Power

3BK 25894

Transceiver Equipment (Section 9)

TRAP

Transceiver Module GSM 1900 Medium Power

3BK 25825

Transceiver Equipment (Section 9)

TRDH

Transceiver Module GSM 1800 High Power

3BK 07723

Transceiver Equipment (Section 9)

TRDM

Transceiver Module GSM 1800 Medium Power

3BK 07372

Transceiver Equipment (Section 9)

TRGM

Transceiver Module GSM 900 Medium Power

3BK 07206

Transceiver Equipment (Section 9)

TRPM

Transceiver Module GSM 1900

3BK 08556

Transceiver Equipment (Section 9)

Table 4: Equipment and Module Part Numbers

1.4.1.3 Module Replacement For detailed information on how to replace modules in the BTS A9100, see the Evolium BTS A9100/A9110 Corrective Maintenance Handbook.

1.4.2 Dimensions and Weight of Cabinet-Mounted Equipment The following table shows the overall dimensions and weight of heavy cabinet-mounted equipment. Height

Width

Depth

Module

TEP/ mm

TEP/ mm

mm

Weight

ABAC

3 HU/ 128

44 WU/ 223

285

-

ACIB

3 HU/ 128

28 WU/ 141.6

285

-

ACMU

-/172

-/237

127

-

ACMUT

-/172

-/217

125

-

ACRI

3 HU/ 128

6 WU/ 30

285

-

ACUC

-/ 135

-/ 150

146

-

ADAM

-/ 39

42 WU/ 213

280

-

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1 Overview

Height

Width

Depth

Module

TEP/ mm

TEP/ mm

mm

Weight

ADAM2

-/ 39

28 WU/ 142

280

-

ADAM4

-/ 39

56 WU/ 284

280

-

ANC

6 HU/ 265

28 WU/ 142

298

-

ANX

6 HU/ 265

31 WU/ 160

298

-

ANY

6 HU/ 265

10 WU/ 52

298

-

APOD

3 HU/ 128

34 WU/ 172

285

-

BACO

3 HU/ 128

50 WU/ 253

285

-

BAC2

6 HU/ 265

14 WU/ 71

285

-

BATS

6 HU/ 265

28 WU/ 142

280

15 kg

BCU1

3 HU/ 128

9 WU/ 45.7

280

-

BCU2

6 HU/ 265

10 WU/ 51

280

-

BU41

-/ 200

-/ 250

200

50 kg

BU100

-/ 234

-/ 250

400

120 kg

BU101

-/ 234

-/ 250

400

120 kg

DCDP

2 HU/ 89

95 WU/ 482.6

152.5

-

DCDU

-/227

-/120

147

-

DCDUE DCMU

-/ 172

-/ 237

125

-

DCUC

-/ 135

-/ 150

146

-

FACB

-/ 95

-/ 55

-

-

FANU

1 HU/ 44

26 WU/ 133

298

-

HEAT

-/ 80

-/ 234.5

140

-

HEAT3

1 HU/ 44

19 WU/ 482

350

-

HEAT4

-/60

-/445

350

-

HEATDC

-/ 101

-/ 170

-/ 145

-

HEX2

-/ 1045

-/ 440

152

24 kg

HEX3

-/ 1150

-/ 450

150

24 kg

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1 Overview

Height

Width

Depth

Module

TEP/ mm

TEP/ mm

mm

Weight

HEX4

-/ 1150

-/ 600

150

28 kg

HEX5

-/ 770

-/ 450

130

16 kg

LPFM

-/261

-/181

75

-

LPFMT

-/261

-/181

75

-

LPQD

n/a

n/a

n/a

-

LPQG

n/a

n/a

n/a

-

LPQM

n/a

n/a

n/a

-

LPQP

n/a

n/a

n/a

-

PM08

3 HU/ 128

15 WU/ 76

280

-

PM11

6 HU/ 265

15 WU/ 76

280

-

PM12

-/ 240

14 WU/ 71

280

-

SUMP

6 HU/ 265

10 WU/ 52

298

-

SUMA

6 HU/ 265

10 WU/ 52

298

-

TRE

6 HU/ 265

21 WU/ 106

298

-

6 HU/ 265

28 WU/ 142

298

-

Table 5: Cabinet-Mounted Equipment, Dimensions and Weight

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1 Overview

1.5 Cables Most BTS A9100 cables are common to both the mini and medi cabinets. The number of standard RF cables that are used varies according to the configuration. The cabling consists of both: Discrete cables, which have the designation CA Cable sets, which have the designation CS. The grouping of certain cables into cable sets can provide advantages in terms of ease of installation or manufacturing. The BTS A9100 cables are categorized as internal and external cables. Internal Cables These are the cables and cable sets that are internal to the BTS. They interconnect the various modules and are necessary for all configurations. External Cables These are the cables that connect the BTS A9100 to: The customer’s 2 Mbit/s PCM distribution board The customer’s 0/ -48 V DC power source and ground point (indoor BTS A9100s) The BTS Terminal Another BTS for clock synchronization.

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2 Configurations - Rack Layouts

2 Configurations - Rack Layouts This chapter shows all possible configurations of the rack layouts for the following BTS types.

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2 Configurations - Rack Layouts

2.1 Naming Conventions for the BTS Configurations In the following sections all possible configurations are listed in figures, sorted by the different types of BTSs. The naming conventions used for the BTS configurations are listed in the following table. 1x1...4

Means 1 sector with up to 4 TREs

3x1...2

Means 3 sectors with up to 2 TRXs per sector

1x1...2/ 1x1...2

Means Multiband configuration, with 1 sector and up to 2 TREs in Band 1, and 1 sector and up to 2 TREs in Band 2

1x(...2/ ...2)

Means Multiband configuration, with 1 sector and up to 2 TREs in each band

Table 6: Naming Conventions Used for the BTS Configurations

2.2 Indoor Configurations 2.2.1 Indoor Configurations - Standard BTS GSM 900/1800/1900 The following configurations are valid for GSM 900/1800/1900 unless otherwise stated.

2.2.1.1 Indoor MINI - 1x1...4 The following figure shows the rack layouts of the Indoor MINI - 1x1...4 configuration. Top Stage

FANU

FANU

SUM

ANY

TRE4

TRE3

FANU

Stage 1

FANU

TRE2

ANX

TRE1

− The BTS has n TREs − If no ANY (2 TREs max.): TRE1 and TRE2 are connected to ANX

Dummy Panels

FANU

FANU

Connection Area The BTS has 1 sector with n TREs S U M A

IDU 1

IDU 2

ANC 1 ( Sector 1 )

a b ANC 1 TRE 1 2 3 4

Microwave IDU (Optional) TRE4 Stage 1

FANU

TRE3

TRE2 FANU

TRE1

Empty space

FANU

Figure 1: Indoor MINI - 1x1...4 Configuration

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2 Configurations - Rack Layouts

2.2.1.2 Indoor MINI - 2x1...2 The following figure shows the rack layouts of the Indoor MINI - 2x1...2 configuration. Top Stage

FANU

SUM

FANU

FANU

ANX

ANX

( Sector 2 )

TRE4 Stage 1

( Sector 1 )

TRE3

FANU

TRE2 FANU

− Sector 1 has n TREs − Sector 2 has p TREs

TRE1

Dummy Panels

FANU

Connection Area The BTS has 2 sectors with respectively n and p TREs ANC 2

S U M A

IDU 1

( Sector 2 )

ANC 1 ( Sector 1 )

a b ANC 1 TRE 1 2

a b ANC 2 TRE 1 2

Microwave IDU (Optional) TRE2 Stage 1

TRE1

FANU

TRE2 FANU

TRE1

Empty space

FANU

On each ANC: The two bridges will be removed at installation time (On site)

Figure 2: Indoor MINI - 2x1...2 Configuration

2.2.1.3 Indoor MINI - 1x1...3 + 1x1 The following figure shows the rack layout of the Indoor MINI - 1x1...3 + 1x1 configuration. Connection Area

ANC 2

IDU 1

( Sector 2 )

S U M A

The BTS has 2 sectors with respectively n and p TREs (p=1) ANC 1 ( Sector 1 )

a b ANC 1 TRE 1 2 3

a b ANC 2 TRE 1

Microwave IDU (Optional) Empty space TRE1 Stage 1

FANU

TRE3

TRE2 FANU

TRE1 FANU

On each ANC: The two bridges will be removed at installation time (On site)

Figure 3: Indoor MINI - 1x1...3 + 1x1 Configuration

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2 Configurations - Rack Layouts

2.2.1.4 Indoor MINI - 3x1 The following figure shows the rack layouts of the Indoor MINI - 3x1 configuration. FANU

SUM

FANU

ANX ( Sector 2 )

FANU

FANU

TRE

FANU

ANX ( Sector 3 )

ANX ( Sector 1 )

TRE

FANU

TRE

The BTS has 3 TREs, one per sector

AIR

Connection Area

The BTS has 3 sectors with 1 TRE each

ANC 3

ANC 2

ANC 1

( Sector 3 )

( Sector 2 )

( Sector 1 )

a b ANC 1 TRE 1

S U M A

a b ANC 2 TRE 1

a b ANC 3 TRE 1

Empty space

TRE1 FANU

TRE1 FANU

TRE1 FANU

On each ANC: The two bridges will be removed at installation time (On site)

Figure 4: Indoor MINI - 3x1 Configuration

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2 Configurations - Rack Layouts

2.2.1.5 Indoor MEDI - 1x1...8 The following figure shows the rack layouts of the Indoor MEDI - 1x1...8 configuration. (The ANX version is only valid for GSM 900/1800). Top Stage

FANU

FANU

FANU

Stage 3

FANU

FANU

FANU

− The BTS has n TREs − If no ANY (2 TREs max.), TRE1 and TRE2 are connected to ANX − If ANY2 only: ANY2 is connected to ANX TRE8 (TRE6)

Stage 2

TRE7 (TRE5)

FANU

SUM

ANY 3

TRE6

FANU

ANY 1

TRE5

FANU

ANY 2

ANX

− ANY filling order: ANY2 then ANY1 then ANY3 − If the BTS has 6 TREs max., the numbering scheme is a little bit different for: TRE5 and TRE6.

Dummy Panels TRE4 Stage 1

TRE3

FANU

TRE2 FANU

TRE1 FANU

Connection Area

The BTS has n TREs

Stage 3

a IDU 1

b ANC

IDU 2

ANY 1 TRE6

TRE5

FANU

Stage 2 S U M A

TRE8

FANU

ANY 2

TRE7

FANU

ANY 1

TRE 1 2 3 4

ANY 2 5 6 7 8

If no ANY (4 TREs maximum), TRE1 to TRE4 are connected to ANC

ANC

Microwave IDU (Optional) TRE4 Stage 1

FANU

TRE3

TRE2 FANU

TRE1

Empty space

FANU

Figure 5: Indoor MEDI - 1x1...8 Configuration

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2 Configurations - Rack Layouts

2.2.1.6 Indoor MEDI - 1x2...8 (GSM 1900; ANX version) The following figure shows the rack layout of the Indoor MEDI - 1x2...8 configuration (GSM 1900; ANX version). Connection Area The BTS has n TRE

a

b ANX

Stage 3

ANY1 ANY2 IDU 1

ANY3

IDU2 TRE 1 2 3 4

TRE6

TRE5

TRE8

5 6 7 8

TRE7 − If no ANY (2 TREs max.): TRE1 and 2 connected to ANX − If ANY2 only: ANY2 connected to ANX

Stage 2

FANU

S U M A

FANU

ANY 3

ANY 1

FANU

ANY 2

ANX

− ANY filling order: ANY2 then ANY1 then ANY3

Microwave IDU (Optional) Empty space TRE4 Stage 1

FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 6: Indoor MEDI - 1x2...8 Configuration (GSM 1900; ANX version)

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2 Configurations - Rack Layouts

2.2.1.7 Indoor MEDI - 1x9...12 This configuration is the logical extension of the 1x2...8 configuration with a minimum of nine TREs. The following figure shows the rack layouts of the Indoor MEDI - 1x9...12 configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 1x11...12 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 1x10 without restrictions: 45 W at + 45 C. Top Stage

FANU TRE12

FANU TRE11

TRE10

FANU TRE9

− The BTS has n TREs FANU

Stage 3

FANU

ANY 4

TRE8 (TRE6)

Stage 2

ANY 5

TRE7 (TRE5)

FANU

SUM

ANY 3

FANU

ANX 2

TRE6

FANU

ANY 1

− Both ANXs are set to the same sector number

TRE5

FANU

ANY 2

ANX 1

Dummy Panels

Stage 1

TRE4 FANU

TRE3

TRE12

TRE11

TRE2 FANU

TRE1 FANU

Connection Area

Stage 3

FANU

FANU

IDU 1

TRE8

Stage 2

TRE6

FANU

ANY 2

TRE9

ANC 2

TRE5

FANU

ANY 1

The BTS has n TREs

a b ANC 1

FANU

IDU 2

TRE7

FANU S U M A

TRE10

ANC 1

ANY 1

ANY 2

TRE 1 2 3 4

5 6 7 8

a b ANC 2 TRE 9 10 11 12

Microwave IDU (Optional)

Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Empty space

Figure 7: Indoor MEDI - 1x9...12 Configuration

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2 Configurations - Rack Layouts

2.2.1.8 Indoor MEDI - 2x1...6 The following figure shows the rack layouts of the Indoor MEDI - 2x1...6 configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 2x6 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 2x1...5 without restrictions: 45 W at + 45 C. Top Stage

FANU TRE6

Stage 3

FANU TRE5

FANU

ANY3

FANU TRE4

FANU

ANY1

TRE3

FANU

ANY2

Sector 1 has n TREs Sector 2 has p TREs

ANX (Sector 2)

For each sector: TRE6

Stage 2

TRE5

FANU

SUM

Stage 1

ANY3

TRE2

FANU

ANY1

FANU

ANY2

TRE4 FANU

TRE3

TRE6

TRE5

TRE1

TRE2 FANU

− If no ANY (2 TREs max.): TRE1 and TRE2 are connected to ANX − ANY filling order: ANY2 then ANY1 then ANY3

ANX (Sector 1)

Dummy Panels

TRE1 FANU

Connection Area

Stage 3

FANU

FANU

ANY4

IDU 1

TRE6

TRE4

ANY3

S U M A

ANC 2 ( Sector 2 )

TRE5

FANU

a b ANC 1 ANY1

ANY2

TRE 1 2 3 4

FANU

ANY2

The BTS has 2 sectors with respectively n and p TREs

FANU

TRE2 Stage 2

TRE3

ANY1

TRE1 FANU ANC 1 ( Sector 1 )

56

a b ANC 2 ANY3 TRE 1 2 3 4

ANY4 56

Microwave IDU (Optional) Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Empty space

Figure 8: Indoor MEDI - 2x1...6 Configuration

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2 Configurations - Rack Layouts

2.2.1.9 Indoor MEDI - 1x1...8 + 1x1...4 (GSM 900/1800) The following figure shows the rack layout of the Indoor MEDI - 1x1...8 + 1x1...4 configuration. Connection Area TRE4

Stage 3

TRE3

FANU

FANU

IDU 1

TRE8

Stage 2

TRE6

FANU

ANY 2

TRE1

ANC 2 (Sector 2)

TRE5

FANU

ANY 1

The BTS has 2 sectors with respectively n and p TREs

a b ANC 1

FANU

IDU 2

TRE7

FANU S U M A

TRE2

ANC 1 (Sector 1)

ANY 1

ANY 2

TRE 1 2 3 4

5678

a b ANC 2 TRE 1 2 3 4

Microwave IDU (Optional) TRE4 Stage 1

FANU

TRE3

TRE2 FANU

TRE1

Empty space

FANU

Figure 9: Indoor MEDI - 1x1...8 + 1x1...4 Configuration

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2 Configurations - Rack Layouts

2.2.1.10 Indoor MEDI - 3x1...4 The following figure shows the rack layouts of the Indoor MEDI - 3x1...4. (The ANX version is only valid for GSM 900/1800).

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 3x4 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 3x1...3 without restrictions: 45 W at + 45 C. Top Stage

FANU

FANU TRE3

TRE4

FANU

Stage 3

FANU TRE3

TRE4

FANU

FANU

Sector 1 has n TREs Sector 2 has p TREs Sector 3 has q TREs

ANY

ANX (Sector 3)

TRE2

ANY

TRE1

TRE2

FANU

Stage 2

ANX (Sector 2) TRE1

FANU

SUM

FANU

ANY

For each sector: TRE1 and TRE2 are connected to ANX if 2 TREs only (no ANY)

ANX (Sector 1)

Dummy Panels Stage 1

TRE4 FANU

TRE3

TRE4

TRE3

TRE2

TRE1 FANU

FANU

Connection Area

FANU

Stage 3

ANC 3 ( Sector 3 )

TRE4

FANU

IDU 1

TRE3

a b ANC 1

FANU

IDU 2

The BTS has 3 sectors with respectively n, p and q TREs

ANC 2 ( Sector 2 )

a b ANC 2

TRE 1 2 3 4 TRE 1 2 3 4

a b ANC 3 TRE2 FANU

Stage 2

TRE1

TRE2 FANU

TRE1 FANU

TRE 1 2 3 4

ANC 1 ( Sector 1 )

S U M A

Microwave IDU (Optional) Empty space

Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 10: Indoor MEDI - 3x1...4 Configuration

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2 Configurations - Rack Layouts

2.2.1.11 Indoor MEDI - 3x1...4 (GSM 1900; ANX version) The following figure shows the rack layout of the Indoor MEDI - 3x1...4 configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 3x4 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 3x1...3 without restrictions: 45 W at + 45 C. Connection Area TRE4

TRE3

TRE4

TRE3 The BTS has 3 sectors with respectiv ely n, p and q TREs

a Stage 3

FANU

FANU

ANY2

ANX3 (Sector 3)

ANY3

FANU

ANX2 (Sector 2)

b

a

b

ANX1

ANX2

ANY2

ANY2

TRE 1 2 3 4

TRE 1 2 3 4 a

b

ANX3 ANY3 TRE 1 2 3 4 TRE2 Stage 2

TRE1

FANU

S U M A

IDU1

TRE2 FANU

IDU2

TRE1 FANU

ANY1

For each sector, TRE1 and 2 connected to ANX if 2 TREs only (no ANY)

ANX1 (Sector 1) Microwave IDU (Optional) Empty space

Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 11: Indoor MEDI - 3x1...4 Configuration (GSM 1900; ANX version)

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2 Configurations - Rack Layouts

2.2.2 Indoor Configurations - Low Losses GSM 900/1800/1900 2.2.2.1 Indoor MEDI - 1x3...8 - Low Losses The following figure shows the rack layouts of the Indoor MEDI - 1x3...8 Low Losses configuration. FANU

Top Stage

FANU

FANU TRE6

Stage 3

FANU

FANU

TRE5

FANU

ANY2

− The BTS has n TREs and one sector

ANX2

− ANX1 and ANX2 are set to the same sector number − ANY1 only present if n>6 or if ANY Pre−equipment TRE4 Stage 2

FANU

FANU

SUM

ANY1

TRE3 FANU

ANX1

Extension from 1x6 to 1x8

Stage 1

TRE8 FANU

TRE7

TRE2 FANU

Dummy Panels

TRE1 FANU

Connection Area TRE6

TRE5

The BTS has 1 sector with n TREs a b ANC1

Stage 3

FANU

FANU

TRE 1 2 7 8 IDU1

IDU2

TRE4 Stage 2

FANU

a b ANC2

FANU

FANU

SUMA

ANC2

TRE3 FANU

ANC1

TRE 3 4 5 6

Both ANCs are set to the same sector number In case of 1x3...4, on each ANC, The bridges will be removed at installation (on site) if no more than 2 TREs are onnected to them Extension from 1x6 to 1x8 Microwave IDU (Optional)

Stage 1

TRE8 FANU

TRE7

TRE2 FANU

TRE1 FANU

Empty space

Figure 12: Indoor MEDI - 1x3...8 - Low Losses Configuration

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2 Configurations - Rack Layouts

2.2.2.2 Indoor MEDI - 1x9...12 - Low Losses The following figure shows the rack layout of the Indoor MEDI - 1x9...12 Low Losses configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 1x11...12 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 1x1...10 without restrictions: 45 W at + 45 C. Connection Area TRE12

Stage 3

TRE11

FANU

ANC 3

TRE6

FANU

IDU 1

TRE5

FANU

IDU 2

ANC 2

The BTS has 1 sector with n TREs

a b ANC 1

a b ANC 2

TRE 1 2 7 8

TRE 3 4 5 6

a b ANC 3

Stage 2

TRE10 FANU

TRE9

TRE4 FANU S U M A

TRE3 FANU

ANC 1

TRE 9 10 11 12 The 3 ANCs are set to the same sector number Extension from 1x8 to 1x12 Microwave IDU (Optional)

Stage 1

TRE8 FANU

TRE7

TRE2 FANU

TRE1 FANU

Empty space

Figure 13: Indoor MEDI - 1x9...12 - Low Losses Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.2.2.3 Indoor MEDI - 2x1...6 - Low Losses The following figure shows the rack layout of the Indoor MEDI - 2x1...6 Low Losses configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 2x6 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 2x1...5 without restrictions: 45 W at + 45 C. FANU

Top Stage

TRE6

Stage 3

FANU TRE5

FANU

FANU TRE6

FANU

TRE5

FANU

Sector 1 has n TREs Sector 2 has p TREs

ANY

ANX3 (Sector 2)

ANY

ANX2 (Sector 1)

In each sector, both ANXs are set to the same sector number.

Stage 2

TRE4 FANU

SUM

TRE3

TRE4 FANU

ANX4 (Sector 2)

TRE3 FANU

When no ANY, TREs 3 and 4 are directly connected to ANX

ANX1 (Sector 1)

Extension from 2x4 to 2x6 Stage 1

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Dummy Panels

Figure 14: Indoor MEDI - 2x1...6 - Low Losses Configuration

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2 Configurations - Rack Layouts

2.2.2.4 Indoor MEDI - 2x3...6 - Low Losses The following figure shows the rack layout of the Indoor MEDI - 2x3...6 Low Losses configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 2x6 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 2x3...5 without restrictions: 45 W at + 45 C. Connection Area TRE6

TRE5

TRE6

TRE5

The BTS has 2 sectors with respectively n and p TREs Sector 1:

Stage 3

FANU

ANC3 (Sector 2)

FANU

IDU1

a b ANC1

FANU

IDU2

ANC2 (Sector 1)

a b ANC2

TRE 1 2

3 456

Sector 2: a b ANC3 TRE4 Stage 2

TRE3

FANU

TRE4 FANU

FANU S U M A

ANC4 (Sector 2)

a b ANC4

TRE3

ANC1 (Sector 1)

TRE 1 2

3 456

In each sector: Both ANCs are set to the same sector number Extension from 2x4 to 2x6 Microwave IDU (Optional)

TRE2 Stage 1

FANU

TRE1

TRE2 FANU

TRE1 FANU

Empty space In case of 2x3...4: On each ANC: The two bridges will be removed at installation time (On site), if no more than 2 TREs are connected to them

Figure 15: Indoor MEDI - 2x3...6 - Low Losses Configuration

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2 Configurations - Rack Layouts

2.2.3 Indoor Configurations - High Power GSM 1800 2.2.3.1 Indoor MINI - 2x1 The following figure shows the rack layout of the Indoor MINI- 2x1- High Power GSM 1800 configuration. Rack Layout with classical HP TREs: Connection Area

ANC2

IDU1

( Sector 2 )

S U M A

The BTS has 2 sectors with 1 TRE each ANC1 ( Sector 1 )

a b ANC1 TRE 1

a b ANC2 TRE 1

Microwave IDU (Optional) Empty space TRE1 Stage 1

FANU

TRE1 FANU

FANU

On each ANC: the two bridges will be removed at installation time (On site)

Rack Layout with EDGE HP TREs: Connection Area

ANC2 ( Sector 2 )

IDU 1

S U M A

TRE1 Stage 1

FANU

ANC1 ( Sector 1 )

TRE1 FANU

FANU

Figure 16: Indoor MINI - 2x1 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.2.3.2 Indoor MEDI - 1x1...4 The following figure shows the rack layouts of the Indoor MEDI- 1x1...4 High Power GSM 1800 configuration. The BTS has 1 sector with n TREs

Connection Area

a

b ANC1

TRE 1 2 3 4 Stage 3

FANU

FANU

IDU1

FANU

On site, on the ANC: Bridges can be removed if only 2 TREs connected to the ANC

IDU2 With classical HP TRE:

Connection Area

TRE4

FANU

Stage 2

FANU

FANU

FANU

IDU1

S U M A

IDU2

TRE4

ANC1 (Sector 1)

FANU

FANU

S U M A

Stage 1

TRE3 FANU

TRE2 FANU Microwave IDU (Optional)

FANU

FANU

FANU

ANC1 (Sector 1)

TRE1 FANU TRE3

TRE2

TRE1

FANU

FANU

FANU

Empty space

Figure 17: Indoor MEDI - 1x1...4 - High Power GSM 1800 Configuration

2.2.3.3 Indoor MEDI - 2x1...2 This configuration must be considered as a sub-equipment of the 3x1...2 High Power configuration.

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2 Configurations - Rack Layouts

2.2.3.4 Indoor MEDI - 2x1...4 The following figure shows the rack layouts of the Indoor MED I- 2x1...4 High Power GSM 1800 configuration. The BTS has 2 sectors with respectively n and p TREs

Connection Area TRE4

TRE3

a

a

b

b

ANC1 Stage 3

FANU

FANU

IDU1

FANU

IDU2

1 2 3 4

TRE

ANC2 (Sector 2)

ANC2 TRE

1 2 3 4

On site, on each ANC: the two bridges can be removed if only 2 TREs connected

With classical HP TRE:

TRE4

Connection Area TRE4

TRE2 Stage 2

FANU

FANU

TRE1

FANU

IDU1

ANC1 (Sector 1)

TRE2

FANU

FANU

Microwave IDU (Optional)

TRE1

IDU2

ANC2 (Sector 2)

TRE4 TRDH

FANU

TRE3

FANU

FANU

S U M A

Stage 1

FANU

TRE3

TRE2 FANU

S U M A

TRE1 FANU

ANC1 (Sector 1)

FANU

TRE3

TRE2

TRE1

FANU

FANU

FANU

Empty space

Figure 18: Indoor MEDI - 2x1...4 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.2.3.5 Indoor MEDI - 3x1...2 The following figure shows the rack layouts of the Indoor MEDI - 3x1...2 High Power GSM 1800 configuration. FANU

Top Stage

FANU

FANU

The BTS has 3 sectors with respectively n, p and q TREs

TRE2

FANU

Stage 3

FANU

FANU

ANX3 (Sector 3)

TRE 1 2

TRE1

TRE2

FANU

Stage 2

a b ANC1

ANX2 (Sector 2)

TRE 1 2

a b ANC3

TRE1

FANU

a b ANC2

FANU

TRE 1 2

ANX1 (Sector 1)

SUM

Microwave IDU (Optional)

TRE2 Stage 1

FANU

Empty space

TRE1

FANU

FANU

Connection Area

On each ANC, t he two bridges are removed at installation (on site).

TRE2

Stage 3

FANU

FANU

ANC3 (Sector 3)

FANU

ANC2 IDU1

IDU2

(Sector 2)

With classical HP TREs: Connection Area TRE2

TRE2

TRE1 Stage 2

FANU

FANU

TRE1 FANU

FANU

ANC3 (Sector 3)

ANC1 (Sector 1)

SUMA

FANU

TRE1 FANU

IDU1

TRE2 FANU

TRE2 FANU

FANU

ANC2 (Sector 2)

TRE1 FANU

ANC1 (Sector 1)

SUMA

Stage 1

FANU

IDU2

TRE1 FANU

FANU

TRE2

TRE1

FANU

FANU

Figure 19: Indoor MEDI - 3x1...2 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.2.3.6 Indoor MEDI - 3x1...3 The following figure shows the rack layouts of the Indoor MEDI - 3x1...3 High Power GSM 1800 configuration. Connection Area TRE3 (MP)

TRE2 (HP)

The BTS has 3 sectors with respectively n, p and q TREs

TRE3 (MP) a

a

b

ANC1 Stage 3

FANU

FANU

ANC3 (Sector 3)

IDU1

FANU

IDU2

ANC2 (Sector 2)

a

b

ANC2

nc

b

ANC3

nc

nc

1 2 3

1 2 3

1 2 3

HP MP

HP MP

HP MP

For 3x1...2: On each ANC: The two bridges will be removed at installation time. (On site) One HP TRE transmitting per antenna

(HP) TRE2

(HP) TRE1 Stage 2

FANU

FANU

(HP) TRE1 FANU

S U M A

ANC1 (Sector 1)

For 3x3: On each ANC: The bridge where the MP TRE is connected is removed on site

With classical HP TRE: Connection Area TRE3 TRDM

FANU

(MP) TRE3 Stage 1

FANU

(HP) TRE2 FANU

Microwave IDU (Optional) Empty space

(HP) TRE1

ANC3 (Sector 3)

TRE2 TRDH

FANU

IDU1

IDU2

TRE3 TRDM

FANU

ANC2 (Sector 2)

FANU

TRDH TRE1 FANU

TRDH TRE2 FANU

S U M A

TRDM TRE3 FANU

TRDH TRE1 FANU

ANC1 (Sector 1)

TRDH TRE2 FANU

TRDM TRE1 FANU

Figure 20: Indoor MEDI - 3x1...3 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.2.4 Indoor Configurations - Extended Cell GSM 900 Extended cell configurations are based either on REK or on RX TMA use as shown in the following figures. INNER CELL

OUTER CELL

MAB

A

B

MAB

MAB

PDU 1

MAB

PDU 2

ANC Sector 1 A

B

A

ANC Sector 2

TRE 2 TRE 4 TRE 1 TRE 3

nc TRE 1

B ANC Sector 2

nc

nc

TRE 2

TRE 3

nc TRE 4

In the Outer Cell, the br idges are removed on each ANC

Figure 21: Extended Cell Configuration Based on REK Use INNER CELL

OUTER CELL

TMA

A

B

TMA

PDU 1

ANC Sector 2 A TRE 2 TRE 4 TRE 1 TRE 3

B ANC Sector 1

TRE 2 TRE 4 TRE 1 TRE 3

Figure 22: Extended Cell Configuration Based on RX TMA Use

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2 Configurations - Rack Layouts

2.2.4.1 Indoor MEDI - Extended Cell Configuration Based on REK The following figure shows the rack layout of the Indoor MEDI extended cell configuration based on REK use. Connection Area

The BTS has 2 sectors with respectively n and p TREs: − n TREs in the Outer cell − p TREs in the Inner cell The configur ation is based on 1x4 Low Losses configuration, extended with a 1x4 sector

Stage 3

IDU1

IDU2

ANC2 Inner Cell (Sector 2)

Inner Cell: a

b ANC2

TRE 1 2 3 4 Outer Cell: a TRE4 Stage 2

TRE3

FANU

TRE2 FANU

ANC3 Outer cell

FANU

S U M A

(Sector 1)

ANC1 Outer cell (Sector 1)

b ANC1

TRE1 TRE 1

a

b ANC3

2 TRE 3 4 nc nc nc nc

− ANC1 and ANC3 are set to the same sector number − The bridges are removed on ANC1 and ANC3

Microwave IDU (Optional)

Empty space

Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 23: Indoor MEDI - Extended Cell Configuration Based on REK Use

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2 Configurations - Rack Layouts

2.2.4.2 Indoor MEDI - Extended Cell Configuration Based on RX TMA Use The following figure shows the rack layout of the Indoor MEDI extended cell configuration based on RX TMA use. Connection Area

The BTS has 2 sectors with respectively n and p TREs: − n TREs in the Outer Cell − p TREs in the Inner Cell

Stage 3

IDU1

IDU2

ANC2 Inner Cell

Inner Cell: a

(Sector 2)

b ANC2

TRE 1 2 3 4 Outer Cell: a TRE4 Stage 2

TRE3

FANU

TRE2 FANU

TRE1 FANU

S U M A

b ANC1

TRE 1 2 3 4

ANC1 Outer Cell (Sector 1) Microwave IDU (Optional) Empty space

Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 24: Indoor MEDI - Extended Cell Configuration Based on RX TMA Use

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2 Configurations - Rack Layouts

2.2.5 Indoor Configurations - Multiband BTS GSM 900/1800 2.2.5.1 Indoor MINI - 1x1...2/ 1x1...2 The following figure shows the rack layouts of the Indoor MINI - 1x1...2/ 1x1...2 - Multiband BTS configuration. Top Stage

FANU

SUM

FANU

FANU

ANX

ANX

( Sector 2 )

( Sector 1 )

− Sector 1 has n TREs − Sector 2 has p TREs

GSM 1800

Stage 1

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

The BTS has 2 sectors with respectively n and p TREs

Connection Area

ANC 2

IDU 1

( Sector 2 )

S U M A

Dummy Panels

ANC 1 ( Sector 1 )

a b ANC 1 TRE 1 2

a b ANC 2 TRE 1 2

Microwave IDU (Optional)

Stage 1

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Empty space GSM 1800

On each ANC: The two bridges will be removed at installation time (On site)

Figure 25: Indoor MINI - 1x1...2/ 1x1...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.2 Indoor MEDI - 1x1...6/1x1...6 The following figure shows the rack layouts of the Indoor MEDI - 1x1...6/1x1...6 - Multiband BTS configuration. Top Stage

FANU TRE6

FANU TRE5

FANU TRE4

TRE3

− Sector 1 has n TREs − Sector 2 has p TREs

Stage 3

FANU

FANU

ANY3

TRE6

Stage 2

ANY1

ANY2

TRE5

FANU

SUM

ANY3

FANU

TRE2

FANU

ANY1

ANX (Sector 2) TRE1

FANU

ANY2

For each sector: − If no ANY (2 TREs max.), TRE1 and TRE2 are connected to ANX − ANY filling order: ANY2 then ANY1 then ANY3

ANX (Sector 1)

GSM 1800 Dummy Panels Stage 1

TRE4 FANU

TRE3

TRE4

TRE3

TRE2 FANU

TRE1 FANU

Connection Area

FANU

Stage 3

FANU

ANY4

IDU1

TRE2

TRE1

The BTS has 2 sectors with respectively n and p TREs

a b ANC1

FANU

ANY3

ANC2 (Sector 2)

ANY1

ANY2

TRE 1 2 3 4 TRE6

56

TRE5

a b ANC2 TRE6 Stage 2

FANU

FANU

TRE5 FANU

ANY3 SUMA

ANY2

ANY1

ANC1 (Sector 1)

TRE 1 2 5 6

ANY4 34

Microwave IDU (Optional) GSM 1800 Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Empty space

Figure 26: Indoor MEDI - 1x1...6/1x1...6 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.3 Indoor MEDI - 1x1...8/1x1...4 The following figure shows the rack layouts of the Indoor MEDI - 1x1...8/1x1...4 - Multiband BTS configuration. Top Stage

FANU TRE4

Stage 3

FANU TRE3

FANU

FANU TRE2

FANU

FANU

ANY4

TRE8

Stage 2

TRE7

FANU

TRE1

TRE6

FANU

ANX2 (Sector 2)

TRE5

The BTS has 2 sectors: − One with n TREs in GSM 900 − One with p TREs in GSM 1800

The configur ation is based on 1x8 configur ation, and extended with a 1x4 sector

GSM 1800

FANU

Dumm y panels SUM ANY3 ANY1

ANY2

ANX1 (Sector 1)

TRE4 Stage 1

TRE3

FANU

TRE2 FANU

TRE1 FANU

Connection Area TRE4

TRE3

TRE2

TRE1

The BTS has 2 sectors with respectiv ely n and p TREs The configur ation is based on 1x8 configur ation, and extended with a 1x4 sector

Stage 3

FANU

FANU

FANU a

IDU1

IDU2

b ANC1

ANC2 (Sector 2) ANY1

TRE6

TRE5

TRE8

TRE7

ANY2

TRE 1 2 3 4

5 6 7 8

If no ANY (4 TREs maxim um), TRE1 to 4 are connected to ANC

Stage 2

FANU

FANU

FANU

a

b ANC2

ANY2

SUMA

ANY1

ANC1 (Sector 1)

TRE 1 2 3 4

Microwave IDU (Optional) GSM 1800 Empty space

TRE4 Stage 1

FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 27: Indoor MEDI - 1x1...8/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.4 Indoor MEDI - 1x1...4/1x1...8 The following figure shows the rack layout of the Indoor MEDI - 1x1...4/1x1...8 Multiband BTS configuration. Connection Area TRE4

TRE3

TRE2

TRE1

The BTS has 2 sectors with respectively n and p TREs The configuration is based on 1x8 configuration, and extended with a 1x4 sector

Stage 3

FANU

FANU

FANU a

IDU1

IDU2

b ANC1

ANC2 (Sector 2) ANY1

TRE6

TRE5

TRE8

TRE7

ANY2

TRE 1 2 3 4

5 6 7 8

If no ANY (4 TREs maximum), TRE1 to 4 are connected to ANC

Stage 2

FANU

FANU

FANU

a

b ANC2

ANY2

SUMA

ANY1

ANC1 (Sector 1)

TRE 1 2 3 4

Microwave IDU (Optional) GSM 1800 Empty space TRE4 Stage 1

FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 28: Indoor MEDI - 1x1...4/1x1...8 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.5 Indoor MEDI - 1x3...8LL/1x1...4 The following figure shows the rack layouts of the Indoor MEDI 1x3...8LL/1x1...4 - Multiband BTS configuration. Top Stage

FANU TRE4

Stage 3

FANU TRE3

FANU

FANU

ANX3 (Sector 2)

ANY

TRE2

FANU TRE4

FANU

ANY

TRE1

TRE3

ANX2 (Sector 1)

TRE2

TRE1

The BTS has 2 sectors: One with n TREs in GSM 900 One with p TREs in GSM 1800 Minimum TREs in sector 1 is 5

The configuration is based on 1x8 Low Loss configuration, extended with a 1x4 sector

ANX1 and ANX2 are set to the same sector number Stage 2

FANU

FANU

SUM

FANU

ANY

ANX1 (Sector 1) GSM 1800 Dummy panels

TRE4 Stage 1

TRE3

FANU

TRE2 FANU

TRE1 FANU

Connection Area TRE4

Stage 3

TRE3

FANU

ANC3 (Sector 2)

TRE6

FANU

IDU1

TRE5

FANU

IDU2

ANC2 (Sector 1)

In case of 1x3...4LL/1x1...4 On ANC1 and ANC2: The bridges will be removed at installation time (on site), if no more than 2 TREs are connected to them The BTS has 2 sectors with respectively n and p TREs The configuration is based on 1x8 Low Loss configuration, extended with a 1x4 sector

a

b ANC1

a

b ANC2

TRE 1 2 7 8 TRE 3 4 5 6 Stage 2

TRE2 FANU

TRE1

TRE4 FANU S U M A

TRE3 FANU

ANC1 (Sector 1)

ANC1 and ANC2 are set to the same sector number

a

b ANC3

TRE 1 2 3 4 GSM 1800 Microwave IDU (Optional) Stage 1

TRE8 FANU

TRE7

TRE2 FANU

TRE1 FANU

Empty space

Figure 29: Indoor MEDI - 1x3...8LL/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.6 Indoor MEDI - 1x1...4/2x1...4 The following figure shows the rack layouts of the Indoor MEDI - 1x1...4/2x1...4 - Multiband BTS configuration. Top Stage

FANU

FANU

TRE4

Stage 3

TRE3

FANU TRE4

TRE3

FANU

FANU

FANU

Sector 1 has n TREs Sector 2 has p TREs Sector 3 has q TREs

ANY

ANX (Sector 3)

TRE2

Stage 2

ANY

TRE1

ANX (Sector 2)

TRE2

FANU

TRE1

FANU

SUM

For each sector, TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector

FANU

ANY

ANX (Sector 1)

GSM 1800 Dummy Panels

Stage 1

TRE4 FANU

TRE3

TRE2

TRE1 FANU

FANU

Connection Area TRE4

TRE3

FANU

Stage 3

ANC3 ( Sector 3 )

TRE4

FANU

IDU1

TRE3

FANU

IDU 2

ANC2 ( Sector 2 )

The BTS has 3 sectors with respectively n, p and q TREs

a b ANC1

a b ANC2

TRE 1 2 3 4 TRE 1 2 3 4

a b ANC3

Stage 2

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE 1 2 3 4

ANC1 ( Sector 1 )

SUMA

GSM 1800 Microwave IDU (Optional) Empty space Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 30: Indoor MEDI - 1x1...4/2x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.7 Indoor MEDI - 2x1...4/1x1...4 The following figure shows the rack layouts of the Indoor MEDI - 2x1...4/1x1...4 - Multiband BTS configuration. Top Stage

FANU TRE4

Stage 3

FANU

ANX (Sector 3)

TRE2

Stage 2

TRE3

TRE4

FANU

FANU

ANY

FANU

TRE3

FANU

ANY

TRE1

FANU

ANX (Sector 2)

TRE2

FANU

ANY

Sector 2 has p TREs Sector 3 has q TREs

TRE1

FANU

SUM

Sector 1 has n TREs

For each sector, TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector

ANX (Sector 1)

GSM 1800 Dummy Panels TRE4 FANU

Stage 1

TRE3

TRE2

TRE1 FANU

FANU

Connection Area TRE4

TRE3

FANU

Stage 3

ANC3 ( Sector 3 )

TRE4

FANU

IDU1

TRE3

FANU

IDU2

ANC2 ( Sector 2 )

The BTS has 3 sectors with respectively n, p and q TREs

a b ANC1

a b ANC2

TRE 1 2 3 4 TRE 1 2 3 4

a b ANC3 Stage 2

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE 1 2 3 4

ANC1 ( Sector 1 )

SUMA

GSM 1800 Microwave IDU (Optional) Empty space Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 31: Indoor MEDI - 2x1...4/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.8 Indoor MEDI - 1x1...4/...4,...2,...2 The following figure shows the rack layouts of the Indoor MEDI 1x1...4/...4,...2,...2 - Multiband BTS configuration. FANU

Top Stage

FANU

TRE4

TRE3

FANU TRE3

TRE4

Sector 1 has n TREs Stage 3

FANU

FANU

FANU

Sector 2 has p TREs Sector 3 has q TREs

ANY

ANX (Sector 3)

ANY

ANX (Sector 2)

Sector 4 has r TREs

In sectors 2 and 3, TRE2 Stage 2

TRE1

TRE2

FANU

FANU

TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector

FANU

ANX (Sector 4)

SUM

TRE1

ANX (Sector 1)

GSM 1800 Dummy Panels Stage 1

TRE2 FANU

TRE1

TRE4

TRE3

TRE2

TRE1 FANU

FANU

Connection Area

Stage 3

FANU

ANC3 (Sector 3)

TRE4

FANU

IDU1

TRE3

FANU

IDU2

ANC2 (Sector 2)

The BTS has 4 sectors with respectively n, p, q and r TREs

a b ANC1 TRE 1 2

a b ANC3

Stage 2

TRE2 FANU

TRE1

TRE2 FANU

ANC4 ( Sector 4 )

SUMA

TRE1 FANU

a b ANC2 TRE 1 2 3 4

a b ANC4

TRE 1 2 3 4 TRE 1 2

ANC1 ( Sector 1 )

GSM 1800 Microwave IDU (Optional) Empty space Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 32: Indoor MEDI - 1x1...4/...4,...2,...2 - Multiband BTS Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.2.5.9 Indoor MEDI - ...4,...2,...2/1x1...4 The following figure shows the rack layouts of the Indoor MEDI ...4,...2,...2/1x1...4 - Multiband BTS configuration. Top Stage

FANU

FANU

TRE4

FANU

TRE3

TRE3

TRE4

Sector 1 has n TREs FANU

FANU

Stage 3

FANU

Sector 2 has p TREs Sector 3 has q TREs

ANY

ANX (Sector 3)

ANY

ANX (Sector 2)

Sector 4 has r TREs

In sectors 2 and 3: TRE2 Stage 2

TRE1

TRE2

FANU

FANU

FANU

ANX (Sector 4)

SUM

TRE1

TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector

ANX (Sector 1)

GSM 1800 Dummy Panels Stage 1

TRE2 FANU

TRE1

TRE4

TRE3

TRE2

TRE1 FANU

FANU

Connection Area

Stage 3

FANU

ANC3 (Sector 3)

TRE4

FANU

IDU1

TRE3

a b ANC1

FANU

IDU2

The BTS has 4 sectors with respectively n, p, q and r TREs

ANC2 (Sector 2)

a b ANC2

TRE 1 2

TRE 1 2 3 4

a b ANC3

Stage 2

TRE2 FANU

TRE1

TRE2 FANU

ANC4 (Sector 4)

SUMA

TRE1 FANU

TRE 1 2 3 4

a b ANC4 TRE 1 2

ANC1 (Sector 1)

GSM 1800 Microwave IDU (Optional) Empty space Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 33: Indoor MEDI - ...4,...2,...2/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.10 Indoor MEDI - 2x1...4/2x1...2 The following figure shows the rack layouts of the Indoor MEDI - 2x1...4/2x1...2 - Multiband BTS configuration. FANU

Top Stage

FANU

TRE4

TRE3

FANU TRE4

TRE3

Sector 1 has n TREs Sector 2 has p TREs Stage 3

FANU

FANU

FANU

Sector 3 has q TREs ANY

ANX3 (Sector 3)

ANY

ANX2 (Sector 2)

Sector 4 has r TREs

In sectors 2 and 3:

TRE2 Stage 2

TRE1

FANU

TRE2 FANU

TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector.

FANU

ANX4 (Sector 4)

SUM

TRE1

ANX1 (Sector 1)

GSM 1800 Dummy Panels

Stage 1

TRE2 FANU

TRE1

TRE2

TRE1

TRE2

TRE1 FANU

FANU

Connection Area TRE2

TRE1

The BTS has 4 sectors with: n+r TREs in GSM 900 p+q TREs in GSM 1800 Sectors GSM 900:

FANU

Stage 3

ANC3 (Sector 3)

FANU

IDU1

FANU

IDU2

a b ANC1 TRE 1 2 3 4

TRE4

TRE3

a b ANC4

ANC2 (Sector 2)

TRE3

TRE4

TRE 1 2 3 4

Sectors GSM 1800:

STASR 3

FANU

Stage 2

FANU

ANC4 (Sector 4)

a b ANC2

FANU

SUMA

ANC1 (Sector 1)

TRE 1 2

a b ANC3 TRE 1 2

GSM 1800 Microwave IDU (Optional) TRE2 Stage 1

FANU

TRE1

TRE2 FANU

TRE1

Empty space

FANU

Figure 34: Indoor MEDI - 2x1...4/2x1...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.5.11 Indoor MEDI - 2x1...2/2x1...4 The following figure shows the rack layouts of the Indoor MEDI - 2x1...2/2x1...4 - Multiband BTS configuration. FANU

Top Stage

FANU

TRE4

FANU

TRE3

TRE3

TRE4

Sector 1 has n TREs Sector 2 has p TREs FANU

Stage 3

FANU

FANU

Sector 3 has q TREs Sector 4 has r TREs

ANY

ANX3 (Sector 3)

ANY

ANX2 (Sector 2)

In sectors 2 and 3: TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector TRE2

TRE1

FANU

Stage 2

TRE2 FANU

FANU

ANX4 (Sector 4)

SUM

TRE1

ANX1 (Sector 1)

GSM 1800 Dummy Panels

Stage 1

TRE2 FANU

TRE1

TRE2

TRE1 FANU

FANU

Connection Area TRE2

TRE1

TRE2

TRE1

The BTS has 4 sectors with: n+r TREs in GSM 900 p+q TREs in GSM 1800 Sectors GSM 900:

FANU

Stage 3

ANC3 (Sector 3)

FANU

IDU1

FANU

IDU2

a b ANC4

a b ANC1

ANC2 (Sector 2)

TRE 1 2

TRE 1 2

Sectors GSM 1800: STASR 3

Stage 2

TRE4 FANU

TRE3

TRE4 FANU

ANC4 (Sector 4)

SUMA

TRE3 FANU

ANC1 (Sector 1)

a b ANC3

a b ANC2 TRE 1 2 3 4

TRE 1 2 3 4

GSM 1800 Microwave IDU (Optional) TRE2 Stage 1

FANU

TRE1

TRE2 FANU

TRE1

Empty space

FANU

Figure 35: Indoor MEDI - 2x1...2/2x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.6 Indoor Configurations - Multiband Cells GSM 900/1800 2.2.6.1 Indoor MINI - 1x(...2/...2) The following figure shows the rack layouts of the Indoor MINI - 1x(...2/...2) Multiband Cells configuration. Top Stage

FANU

SUM

FANU

FANU

ANX2

ANX1

The single sector has: − n TREs in the GSM 900 band − p TREs in the GSM 1800 band ANX1 and ANX2 are set to the same sector number

GSM 1800 TRE2 Stage 1

TRE1

FANU

TRE2 FANU

Dummy Panels

TRE1 FANU

Connection Area a ANC2

IDU1

S U M A

ANC1

b

a

ANC1 TRE 1 2

b

ANC2 TRE 1 2

ANC1 and ANC2 are set to the same sector number Microwave IDU (Optional) Empty space TRE2 Stage 1

FANU

TRE1

TRE2 FANU

TRE1 FANU

GSM 1800

On each ANC: The two bridges will be removed at installation time (On site)

Figure 36: Indoor MINI - 1x(...2/...2) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.2.6.2 Indoor MEDI - 1x(...6/...6) The following figure shows the rack layouts of the Indoor MEDI - 1x(...6/...6) Multiband Cells configuration. Top Stage

FANU

TRE6

Stage 3

FANU

TRE5

FANU

FANU

ANY3

TRE6

Stage 2

ANY1

TRE5

ANY3

TRE2

FANU

ANY1

TRE3

The single sector has: n TREs in the GSM 900 band p TREs in the GSM 1800 band

FANU

ANY2

FANU

SUM

FANU

TRE4

ANX2

TRE1

FANU

ANY2

ANX1

ANX 1 and ANX 2 are set to the same sector number For each frequency band: If no ANY (2 TREs max.), TRE1 and TRE2 are connected to ANX ANY filling order: ANY2 then ANY1 then ANY3

GSM 1800 TRE4

Stage 1

TRE3

FANU

TRE2

FANU

TRE1

The BTS has one sector with: p TREs in GSM 900 n TREs in GSM 1800

Connection Area

TRE4

TRE3

Dummy Panels

FANU

TRE2

TRE1

a

b

ANC1 Stage 3

FANU

FANU

FANU

ANY1 IDU1

ANY4

ANY3

ANY2

ANC2

TRE 1 2 3 4 a TRE6

Stage 2

TRE6

TRE5

FANU

FANU

ANC2

TRE5

FANU

56 b

ANY3 TRE 1 2 5 6

SUMA

ANY2

ANY1

ANC1

ANY4 34

Both ANCs are set to the same sector number Microwave IDU (Optional)

TRE4

Stage 1

FANU

TRE3

TRE2

FANU

TRE1

FANU

GSM 1800 Empty space

Figure 37: Indoor MEDI - 1x(...6/...6) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.2.6.3 Indoor MEDI - 2x(...4/...2) The following figure shows the rack layouts of the Indoor MEDI - 2x(...4/...2) Multiband Cells configuration. FANU

Top Stage

FANU

TRE4

TRE4

FANU

FANU

Stage 3

ANY

ANX3 (Sector 2)

TRE2

TRE1

ANX2 (Sector 1)

TRE2 FANU

TRE1

Sector 1 has: − p TREs in the GSM 900 band − n TREs in the GSM 1800 band Sector 2 has: − q TREs in the GSM 900 band − r TREs in the GSM 1800 band

ANX1 and ANX2 are set to the same sector number (1) ANX3 and ANX4 are set to the same sector number (2)

FANU

ANX4 (Sector 2)

SUM

TRE3

FANU

ANY

FANU

Stage 2

FANU

TRE3

ANX1 (Sector 1)

In the upper part of the BTS, TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector

GSM 1800 TRE2 Stage 1

TRE1

FANU

TRE2 FANU

TRE1

Connection Area TRE2

Stage 3

TRE1

FANU ANC3 (Sector 2)

TRE4

TRE2

FANU

IDU1

Dummy Panels

FANU

FANU

IDU2

TRE3

TRE1

ANC2 (Sector 1)

TRE3

TRE4

Sector 1 has: − n TREs in the GSM 900 band − p TREs in the GSM 1800 band Sector 2 has: − r TREs in the GSM 900 band − q TREs in the GSM 1800 band a b ANC1

a b ANC2

TRE 1 2 3 4

STASR 3

TRE 1 2

ANC 1 and ANC 2 are set to the same sector number (1) FANU

Stage 2

FANU

ANC4 (Sector 2)

FANU

SUMA

ANC1 (Sector 1)

a b ANC3 TRE 1 2

a b ANC4 TRE 1 2 3 4

ANC3 and ANC4 are set to the same sector number (2) TRE2 Stage 1

FANU

TRE1

TRE2 FANU

TRE1 FANU

GSM 1800 Microwave IDU (Optional) Empty space

Figure 38: Indoor MEDI - 2x(...4/...2) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.2.6.4 Indoor MEDI - 2x(...2/...4) The following figure shows the rack layouts of the Indoor MEDI - 2x(...2/...4) Multiband Cells configuration. FANU

Top Stage

FANU

TRE4

TRE3

FANU

FANU

Stage 3

ANY

FANU

ANX3 (Sector 2)

TRE3

TRE4

FANU

ANY

ANX2 (Sector 1)

Sector 1 has: − n TREs in the GSM 900 band − p TREs in the GSM 1800 band Sector 2 has: − q TREs in the GSM 1800 band − r TREs in the GSM 900 band ANX1 and ANX2 are set to the same sector number (1) ANX3 and ANX4 are set to the same sector number (2)

TRE2 Stage 2

TRE1

FANU

TRE2 FANU

TRE1 FANU

In the upper part of the BTS, ANX4 (Sector 2)

SUM

ANX1 (Sector 1)

TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector

GSM 1800 TRE2 Stage 1

TRE1

FANU

TRE2 FANU

FANU

Connection Area TRE2

Stage 3

TRE1

FANU ANC3 (Sector 2)

TRE2

FANU

IDU1

TRE1

FANU

IDU2

ANC2 (Sector 1)

Sector 1 has: − n TREs in the GSM 900 band − p TREs in the GSM 1800 band Sector 2 has: − q TREs in the GSM 1800 band − r TREs in the GSM 900 band a b ANC1

a b ANC2

TRE 1 2 TRE 1 2 3 4 ANC1 and ANC2 are set to the same sector number (1)

STASR 3 TRE4 Stage 2

Dummy Panels

TRE1

TRE3

FANU

TRE4 FANU

ANC4 (Sector 2)

TRE3 FANU

SUMA

ANC1 (Sector 1)

a b ANC3

a b ANC4

TRE 1 2 3 4

TRE 1 2

ANC3 and ANC4 are set to the same sector number (2) GSM 1800 Microwave IDU (Optional) TRE2 Stage 1

FANU

TRE1

TRE2 FANU

TRE1 FANU

Empty space

Figure 39: Indoor MEDI - 2x(...2/...4) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.2.6.5 Indoor MEDI - 1x(...2/...2), 1x(...4/...4) The following figure shows the rack layouts of the Indoor MEDI - 1x(...2/...2), 1x(...4/...4) - Multiband Cells configuration. FANU

Top Stage

FANU

TRE4

Stage 3

TRE3

FANU

ANY

FANU

FANU

ANX3 (Sector 2)

TRE3

TRE4

FANU

ANY

ANX2 (Sector 2)

Sector 1 has: − n TREs in the GSM 900 band − r TREs in the GSM 1800 band Sector 2 has: − p TREs in the GSM 900 band − q TREs in the GSM 1800 band ANX1 and ANX4 are set to the same sector number (1) ANX2 and ANX3 are set to the same sector number (2)

TRE2 Stage 2

TRE1

FANU

SUM

TRE2 FANU

TRE1 FANU

ANX4 (Sector 1)

ANX1 (Sector 1)

In the upper part of the BTS, TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector

GSM 1800 Dummy Panels Stage 1

TRE2 FANU

TRE1

TRE2

TRE1

TRE2 FANU

TRE1 FANU

Connection Area

FANU

Stage 3

ANC3 (Sector 1)

TRE2

FANU

IDU1

TRE1

Sector 1 has: − n TREs in the GSM 900 band − q TREs in the GSM 1800 band Sector 2 has: − r TREs in the GSM 900 band − p TREs in the GSM 1800 band

FANU

IDU2

ANC2 (Sector 2)

a b ANC3

a b ANC1

TRE 1 2

TRE 1 2 TRE4

TRE3

STASR 3 TRE4 Stage 2

FANU

FANU

ANC4 (Sector 2)

TRE3 FANU

SUMA

ANC1 (Sector 1)

ANC1 and ANC3 are set to the same sector number (1) a b ANC4

a b ANC2 TRE 1 2 3 4

TRE 1 2 3 4

ANC2 and ANC4 are set to the same sector number (2) GSM 1800 TRE2

TRE1

TRE2

TRE1

Microwave IDU (Optional) Stage 1

FANU

FANU

FANU

Empty space

Figure 40: Indoor MEDI - 1x(...2/...2), 1x(...4/...4) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.2.7 AC Indoor Configurations GSM 900/1800 2.2.7.1 AC Indoor MEDI - 1x1...8 The following figure shows the rack layouts of the AC Indoor MEDI - 1x1...8 configuration. BTS−CA

AFIP

ABAC

Stage 3 (*)

PMO8 PMO8 5 4 FANU TRE8

PMO8 PMO8 3 2 FANU TRE7

TRE6

FANU

Stage 2

A C R I

APOD

FANU

PMO8 BCU1 1 FANU TRE5

a b ANX ANY1 ANY2

ANY3

TRE 1 2 3 4

5678

FANU

− If no ANY (2 TREs max.), TRE1 and TRE2 are connected to ANX SUM

ANY3 ANY1

TRE4 Stage 1 (*)

ANY2

TRE3

TRE2

FANU

FANU

ANX

TRE1

− If ANY2 only, ANY2 is connected to ANX − ANY filling order: ANY2 then ANY1 + ANY3 (*) Fan stage always present

FANU

Dummy Panels Options depending of the configuration

BBU

Options if GSM 1800

Connection Area TRE8

TRE7

TRE6

The BTS has n TREs TRE5

a Stage 3

FANU

FANU

b ANC

FANU

ANY1 ANY2

TRE4 Stage 2

Stage 1

TRE3

FANU ADAM PM12

ANY1

PM12 FANU

TRE2 FANU

PM12

SUMA

FANU

ANY2

ANC

TRE 1 2 3 4

TRE1

5678

If no ANY (4 TREs maximum), TRE1 to TRE4 are connected to ANC Pre−equipment of ANY possible

FANU BATS or 2 x IDU FANU

BATS or Microwave IDU (Optional) BBU (Option)

Empty space

Figure 41: AC Indoor MEDI - 1x1...8 Configuration

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2 Configurations - Rack Layouts

2.2.7.2 AC Indoor MEDI - 2x1...2 This configuration must be considered as a sub-equipment of the 3x1...2 configuration (sector 3 is not equipped).

2.2.7.3 AC Indoor MEDI - 3x1...2 The following figure shows the rack layouts of the AC Indoor MEDI - 3x1...2 configuration. BTS−CA

AFIP

ABAC

Stage 3

PMO8 PMO8 5 4 FANU

PMO8 PMO8 3 2 FANU TRE2

ANX (Sector 3)

FANU

Stage 2

FANU

SUM

ACR I

APOD

PMO8 BCU1 1 FANU

a b ANX

a b ANX

a b ANX

1 2 2

1 2 3

TRE 1 2 Sector 1

TRE1

FANU

ANX (Sector 2)

Dummy Panels

ANX (Sector 1)

Options depending on the configuration Options if GSM 1800

TRE2 Stage 1

TRE1

TRE2

FANU

FANU

TRE1 FANU

BBU

Connection Area TRE2

Stage 3

TRE1

TRE2

FANU

ANC3 (Sector 3)

FANU

FANU

IDU2

IDU1

TRE1

TRE2

ANC2 (Sector 2)

TRE1

The BTS has 3 sectors with respectively n, p and q TREs a b ANC1 TRE 1 2

a b ANC2 TRE 1 2 a b ANC3

BATS

TRE 1 2 Stage 2

FANU ADAM PM12

Stage 1

PM12

FANU

FANU

PM12

SUMA

FANU

FANU

ANC1 (Sector 1) FANU

BATS or Microwave IDU (Optional) BBU

Empty space

Figure 42: AC Indoor MEDI - 3x1...2 Configuration

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2 Configurations - Rack Layouts

2.2.7.4 AC Indoor MEDI - 2x1...6 The following figure shows the rack layout of the AC Indoor MEDI - 2x1...6 configuration. Connection Area TRE4

TRE3

TRE2

TRE1

The BTS has 2 sectors with respectively n and p TREs a b ANC1

FANU

Stage 3

FANU

ANY1

BATS or 2 x IDU

SUMA

FANU

ANC2 (Sector 2)

ANY2

TRE2 TRE6

34 5 6

a b ANC2

TRE5

FANU ADAM

Stage 2

TRE1

TRE 1 2

PM12

PM12

FANU

PM12

ANY2

FANU

ANY1

ANC1 (Sector 1)

TRE 1 2

34 5 6

BATS or Microwave IDU (optional) TRE6 Stage 1

TRE5

FANU

TRE4 FANU

TRE3

Empty space

FANU

Figure 43: AC Indoor MEDI - 2x1...6 Configuration

2.2.7.5 AC Indoor MEDI - 3x1...4 The following figure shows the rack layout of the AC Indoor MEDI - 3x1...4 configuration. Connection Area TRE4

TRE3

FANU

Stage 3

TRE4

FANU

FANU

BATS or 2 x IDU

ANC 3 ( Sector 3 )

TRE3

ANC 2 ( Sector 2 )

The BTS has 3 sectors with respectively n, p and q TREs

a b ANC 1

a b ANC 2

TRE 1 2 3 4 TRE 1 2 3 4

a b ANC 3

Stage 2

TRE2 FANU ADAM P M 1 2

P M 1 2

TRE1

TRE2 FANU

TRE 1 2 3 4

ANC 1 ( Sector 1 )

S U M A

P M 1 2

TRE1 FANU

BATS or Microwave IDU (Optional)

Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Empty space

Figure 44: AC Indoor MEDI - 3x1...4 Configuration

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2 Configurations - Rack Layouts

2.2.7.6 AC Indoor MEDI - 1x1...8/1x1...4 The following figure shows the rack layout of the AC Indoor MEDI 1x1...8/1x1...4 Multiband BTS configuration. Connection Area TRE8

TRE7

TRE6

TRE5

The BTS has 2 sectors with respectively n and p TREs a b ANC 1

FANU

Stage 3

FANU

FANU

TRE 1 2 3 4 IDU

ANY 1

ANY 2

ANC 2 ( Sector 2 )

a b ANC 2

ANY 1 TRE4

TRE3

FANU ADAM

Stage 2

P M 1 2

P M 1 2

TRE2 FANU

P M 1 2

TRE1

TRE 1 2 3 4

ANY 2 5678

FANU ANC 1 ( Sector 1 )

S U M A

If no ANY (4 TREs maximum), TRE1 to TRE4 are connected to ANC

Microwave IDU (Optional) GSM 1800

Stage 1

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Empty space

Figure 45: AC Indoor MEDI - 1x1...8/1x1...4 Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.2.7.7 DC Power Distribution from an AC Indoor Cabinet To extend on site the capacities in terms of TREs per sector, the coupling of a DC Indoor cabinet to an AC Indoor cabinet can be envisaged. A typical case is a 3x6 sectored site with the following hardware: 1x6 AC Indoor MEDI + 2x6 DC Indoor MEDI. This configuration requires the following actions: Add additional AC/DC converters in the AC Indoor cabinet, (3 x AC/DC converters in the case of a standalone AC Indoor cabinet) Use of a DC power cable between the two cabinets. AFIP Subrack AC/DC

DC

BTS−CA

Power Cable

ASIB

BU41 AC Cabinet

DC Cabinet

Figure 46: Interconnection between an AC Cabinet and a DC Cabinet Maximum number of TREs depending on DC Consumption: GSM 900: 3 x PM08 up to eight TREs, 5 x PM08 if more than eight TREs; maximum TREs: 18 (a 3x6 site configuration is possible) GSM 1800: 3 x PM08 up to six TREs, 4 x PM08 up to eight TREs, 5 x PM08 if more than eight TREs; maximum TREs: 12 (a 3x6 site configuration is not possible).

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2 Configurations - Rack Layouts

2.3 A9100 BTS Indoor (G3) Extension with Twin TRX The following table gives the possible configuration extension based on Twin TRX modules. Cabinet

Number of sectors

AC

DC

Carriesrs per sector

Carriesrs per sector

Single TRX -> Twin Single TRX -> Twin TRX TRX Mini

Medi

1

n.a.

4 -> 8

2

n.a.

2/2 -> 4/4

3

n.a.

1/1/1 -> 2/2/2

1

n.a.

12 -> 16

2

n.a.

6/6 -> 8/8

3

n.a.

4/4/4 -> 6/6/6

2.3.1 G3 MINI - 1 Sector mixed configuration Single/Twin-TRX

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2 Configurations - Rack Layouts

2.3.2 G3 MINI - 2 Sectors mixed configuration Single/Twin-TRX

2.3.3 G3 MINI - 3 Sectors mixed configuration Single/Twin-TRX

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2.3.4 G3 MEDI - 1 Sector mixed configuration Single/Twin-TRX

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2.3.5 G3 MEDI - 2 Sectors mixed configuration Single/Twin-TRX

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2 Configurations - Rack Layouts

2.3.6 G3 MEDI - 3 Sectors mixed configuration Single/Twin-TRX

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2 Configurations - Rack Layouts

2.4 A9100 BTS Indoor (G4) Extension with Twin TRX The following table gives the possible configuration extension based on Twin TRX modules. Cabinet

Number of sectiors

AC

DC

Carriesrs per sector

Carriesrs per sector

Single TRX -> Twin Single TRX -> Twin TRX TRX Mini

Medi

*

1

n.a.

4 -> 8

2

n.a.

2/2 -> 4/4

3

n.a.

1/1/1 -> 2/2/2

1

n.a.

12 -> 16

2

2/2 -> 4/4

6/6 -> 8/8

3

2/2/2 (4/4/4) -> 4/6/6(6/6/6)

4/4/4 -> 6/6/6

: Change of SUMA location

2.4.1 G4 MINI - 1 Sector mixed configuration Single/Twin-TRX

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2 Configurations - Rack Layouts

2.4.2 G4 MINI - 2 Sectors mixed configuration Single/Twin-TRX

2.4.3 G4 MINI - 3 Sectors mixed configuration Single/Twin-TRX

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2.4.4 G4 MEDI - 1 Sector mixed configuration Single/Twin-TRX

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2.4.5 G4 MEDI - 2 Sectors mixed configuration Single/Twin-TRX

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2.4.6 G4 MEDI - 3 Sectors mixed configuration Single/Twin-TRX

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2.5 Multistandard Base Station Indoor Configurations with Single TRX 2.5.1 MBI Configurations - Standard BTS GSM 850/900/1800/1900 The following configurations are valid for GSM 850/900/1800/1900 unless otherwise indicated.

2.5.1.1 MBI3 - 1x1...8 - DC The following figure shows the rack layout of the MBI3 - 1x1...8 - DC configuration.

Note:

Restrictions None. for GSM 850. For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 1x7...8 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 1x6 without restrictions: 45 W at + 45 C. The BTS has 1 sector with n TREs Connection Area a TRE8

TRE7

TRE6

TRE5

b ANC1

ANY1 TRE 1 3 5 7 FANU

SUMA

FANU

FANU Air Inlet

ANY 2

ANY2 2 46 8

ANY 1

ANC1

If more than 4 TREs, 2 ANYs are required. Pre−equipment possible Up to 4 TREs, and if no ANY pre−equipped, TRE1 to TRE4 are directly connected to the ANC

Dummy Panel

The ANC can be replaced by the ANB in case fewer than 3TREs

Empty space TRE4 FANU

TRE3

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 47: MBI3 - 1x1...8 - DC Configuration

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2 Configurations - Rack Layouts

2.5.1.2 MBI3 - 1x1...4 - AC The following figure shows the rack layout of the MBI3 - 1x1...4 - AC configuration.

Note:

Restrictions None. for GSM 850.

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Connection Area

The BTS has 1 sector with n TREs

ADAM

PM1 2

BATS (Option)

PM1 2

FANU

FANU

FANU Air Inlet

SUMA

ANC1

Dummy Panel

TRE4 FANU

TRE3

TRE2 FANU Air Inlet STAND

a

b ANC1

TRE 1 3 2 4

The ANC can be replaced by the ANB in case of fewer than 3TREs

Empty space

TRE1 FANU

Figure 48: MBI3 - 1x1...4 - AC Configuration

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2 Configurations - Rack Layouts

2.5.1.3 MBI3 - 2x1...4 - DC The following figure shows the rack layout of the MBI3 - 2x1...4 - DC configuration.

Note:

Restrictions None. for GSM 850. For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 2x4 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 2x1...3 without restrictions: 45 W at + 45 C. The BTS has 2 sectors: Sector 1 with n TREs, Sector 2 with p TREs

Connection Area TRE4

TRE3

TRE4

TRE3

a FANU

FANU Air Inlet

b ANC1

SUMA

b ANC2

FANU TRE 1 3 2 4 Sector 1

ANC2 (Sector 2)

a

TRE 1 3 2 4 Sector 2

ANC1 (Sector 1) The ANC can be replaced by the ANB in case of fewer than 3TREs

Dummy Panel Empty space

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 49: MBI3 - 2x1...4 - DC Configuration

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2 Configurations - Rack Layouts

2.5.1.4 MBI3 - 2x1...2 - AC The following figure shows the rack layout of the MBI3 - 2x1...2 - AC configuration.

Note:

Restrictions None. for GSM 850. Connection Area

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ADAM

PM1 2

BATS (Option)

PM1 2

FANU

FANU

FANU Air Inlet

The BTS has 2 sectors: Sector 1 with n TREs, Sector 2 with p TREs

a

b ANC1

TRE 1 ANC2 (Sector 2)

SUMA

ANC1 (Sector 1)

2

a

b ANC2

TRE 1

Sector 1

2

Sector 2

The ANC can be replaced by the ANB also

Dummy Panel

Empty space

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 50: MBI3 - 2x1...2 - AC Configuration

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2 Configurations - Rack Layouts

2.5.1.5 MBI3 - 3x1...2 - DC The following figure shows the rack layout of the MBI3 - 3x1...2 - DC configuration.

Note:

Restrictions None. for GSM 850. The BTS has 3 sectors: Sector 1 with n TREs, Sector 2 with p TREs, Sector 3 with q TREs

Connection Area TRE2

TRE1

ANC3 (Sector 3) a

FANU

FANU

FANU Air Inlet

ANC2 (Sector 2)

SUMA

b ANC1

TRE 1

2

Sector 1

ANC1 (Sector 1)

a b ANC2 TRE 1

2

Sector 2

a b ANC3 TRE 1

2

Sector 3

Dummy Panel

The ANC can be replaced by the ANB also Empty space TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 51: MBI3 - 3x1...2 - DC Configuration

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2 Configurations - Rack Layouts

2.5.1.6 MBI3 - 3x1 - AC The following figure shows the rack layout of the MBI3 - 3x1 - AC configuration.

Note:

Restrictions None. for GSM 850. Connection Area

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ADAM

PM1 2

BATS (Option)

PM1 2

FANU

FANU

FANU Air Inlet

The BTS has 3 sectors, one TRE per sector

a

b ANC1

TRE 1 ANC3 (Sector 3)

ANC2 (Sector 2)

ANC1 (Sector 1)

a

b ANC2

TRE 1

Sector 1

Sector 2

a b ANC3 Dummy Panel TRE 1 Sector 3 SUMA

The ANC can be replaced by the ANB also TRE1

FANU

TRE1 FANU Air Inlet STAND

TRE1 FANU

Empty space

Figure 52: MBI3 - 3x1 - AC Configuration

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2 Configurations - Rack Layouts

2.5.1.7 MBI5 - 1x1...8 - AC or DC The following figure shows the rack layout of the MBI5 - 1x1...8 - AC or DC configuration. Connection Area The BTS has 1 sector with n TREs TRE8

TRE7

TRE6

TRE5 a

b ANC1

ANY1 FANU

FANU Air Inlet

ANY 2

FANU

ANY 1

ANC1

Dummy Panel

TRE 1 3 5 7

ANY2 2 46 8

If more than 4 TREs, 2 ANYs are required. Pre−equipment possible Up to 4 TREs, and if no ANY pre−equipped, TRE1 to TRE4 are directly connected to the ANC The ANC can be replaced by the ANB in case of fewer than 3 TREs

TRE4

TRE3

TRE2

TRE1

12345678 1234567 12345678 1234567 12345678 1234567 123 12345678 1234567 12345678 1234567 12345678 1234567 123456 123456 1234567 12345678 123456 123456 1234567 1234567890123456 1234567890123456 BBU or STASR 1234567890123456 1234567890123456 1234567890123456 1234567890123456 FANU

FANU

FANU

Air Inlet

ADAM

SUMA

PM1 2

PM1 2

PM1 2

BATS (Option)

Modules present only in AC configuration Empty space

FANU

FANU

FANU

(Option)

STAND

Figure 53: MBI5 - 1x1...8 - AC or DC configuration

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2 Configurations - Rack Layouts

2.5.1.8 MBI5 - 1x9...12 (Low Loss) - AC or DC This configuration is the logical extension of the 1x1...8 configuration with a minimum of nine TREs. The following figure shows the rack layout of the MBI5 1x9...12 (Low Loss) - AC or DC configuration.

Note:

Restrictions None. for GSM 850. For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 1x11...12 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 1x10 without restrictions: 45 W at + 45 C. Connection Area TRE8

TRE7

TRE6

The BTS has 1 sector with n TREs TRE5 a

b ANC1

ANY1 FANU Air Inlet

FANU

FANU

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ANY 2

ANY 1

ANY2

TRE 1 3 5 7

2 4 6 8

a b ANC2

ANC1

9 TRE

12 11 10

Dummy Panel

Both ANCs are set to the same sector number TRE4

TRE3

TRE2

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FANU Air Inlet

TRE1 FANU

ADAM

SUMA

PM1 2

PM1 2

ANC2

PM1 2

123 123

Modules present only in AC configuration Empty space

Dummy Panel

TRE12 FANU

TRE11

TRE10 FANU Air Inlet STAND

TRE9 FANU

Figure 54: MBI5 - 1x9...12 (Low Loss) - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.1.9 MBI5 - 2x1...4 - AC The following figure shows the rack layout of the MBI5 - 2x1...4 - AC configuration with BU101.

Note:

Restrictions None. for GSM 850. Connection Area TRE4

TRE3

TRE4

TRE3

The BTS has 2 sectors: Sector 1 with n TREs, Sector 2 with p TREs

a b ANC1 FANU

FANU FANU Air Inlet

ANC2 (Sector 2)

ANC1 (Sector 1)

a b ANC2

TRE 1 3 2 4

TRE 1 3 2 4

Sector 1

Sector 2

The ANC can be replaced by the ANB in case of fewer than 3 TREs Dummy Panel

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Air Inlet ADAM

PM12

PM12

PM12

SUMA Empty space

FANU

FANU

FANU

Air Inlet

BBU (BU101)

STAND

Figure 55: MBI5 - 2x1...4 - AC Configuration with BU101

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2 Configurations - Rack Layouts

2.5.1.10 MBI5 - 2x1...6 - AC or DC The following figure shows the rack layout of the MBI5 - 2x1...6 - AC or DC configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 2x6 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 2x1...5 without restrictions: 45 W at + 45 C. Connection Area TRE6

TRE5

TRE4

TRE3

The BTS has 2 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs

a

b ANC1

Sector 1

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FANU

FANU Air Inlet

BATS (Option)

SUMA

ANY1

FANU TRE 1 3

ANY 2

ANC2 (Sector 2)

a b ANC2 Sector 2 ANY2

Dummy Panel TRE 1 3

TRE5

TRE6

TRE2 FANU

TRE1

FANU Air Inlet

PM1 2

ANY 1

ANC1 (Sector 1)

FANU

TRE3

123 123

Modules present only in AC configuration Empty space

Dummy Panel

TRE4

In each sector, If no more than 4 TREs, no ANY is required. TRE1 to 4 are then cabled on ANC.

The ANC can be replaced by the ANB in case of fewer than 3 TREs

ADAM

PM1 2

24 56

FANU

12345678 12345678 12345678 12345678 12345678 12345678 12345678 PM1 2

2 4 56

TRE2

FANU Air Inlet STAND

TRE1 FANU

Figure 56: MBI5 - 2x1...6 - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.1.11 MBI5 - 1x1...8 + 1x1...4 - AC or DC The following figure shows the rack layout of the MBI5 - 1x1...8 + 1x1...4 - AC or DC configuration.

Note:

Restrictions None. for GSM 850 and GSM 1900. The BTS has 2 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs

Connection Area TRE8

TRE7

TRE6

TRE5 a b ANC1

Sector 1

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FANU

BATS (Option)

ANY 2

FANU

FANU Air Inlet

ANY 1

ANC2 (Sector 2)

TRE

Sector 2

1 3 2 4

a b ANC2

ANY1

ANY2

Dummy Panel

TRE4

TRE 1 3 5 7

TRE3

TRE2

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FANU

2 46 8

TRE1 FANU

Air Inlet

ADAM

PM1 2

PM1 2 PM1 2

SUMA

ANC1 (Sector 1)

FANU

TRE3

TRE2

FANU Air Inlet STAND

Modules present only in AC configuration Empty space

Dummy Panel

TRE4

123 123

TRE1 FANU

Figure 57: MBI5 - 1x1...8 + 1x1...4 - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.1.12 MBI5 - 3x1...2 - AC The following figure shows the rack layout of the MBI5 - 3x1...2 - AC configuration with BU101.

Note:

Restrictions None. for GSM 850. The BTS has 3 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs, − Sector 3 with q TREs

Connection Area TRE2

TRE1 ANC3 (Sector 3)

a b ANC1 FANU

FANU Air Inlet

a b ANC2

FANU TRE 1

2

TRE 1

Sector 1

ANC2 (Sector 2)

2

Sector 2

ANC1 (Sector 1) a b ANC3 TRE 1

2

Sector 3

TRE2

TRE1

TRE2

FANU

FANU

TRE1 FANU

The ANC can be replaced by the ANB also

Air Inlet ADAM P M 1 2 FANU

P M 1 2

P M 1 2

S U M A

FANU

Empty space FANU

Air Inlet

BBU (BU101)

STAND

Figure 58: MBI5 - 3x1...2 - AC Configuration with BU101

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2 Configurations - Rack Layouts

2.5.1.13 MBI5 - 3x1...4 - AC or DC The following figure shows the rack layout of the MBI5 - 3x1...4 - AC or DC configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 3x4 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 3x1...3 without restrictions: 45 W at + 45 C. Connection Area TRE4

TRE3

TRE4

FANU

ANC3 (Sector 3)

TRE3

FANU FANU Air Inlet

123456 123456 123456 123456 123456 123456 123456 BATS (Option)

The BTS has 2 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs, − Sector 3 with q TREs

a

b ANC1

TRE 1 3 2 4

a b ANC2

a b ANC3

1 3 2 4

1 3 2 4

ANC2 (Sector 2) The ANC can be replaced by the ANB in case of fewer than 3 TREs

Dummy Panel

TRE2

TRE1

TRE2

FANU

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FANU

TRE1 FANU

Air Inlet

ADAM

SUMA

PM1 2 PM1 2

PM1 2

ANC1 (Sector 1)

Dummy Panel

TRE4 FANU

TRE3

TRE2 FANU Air Inlet STAND

12 12

Modules present only in AC configuration Empty space

TRE1 FANU

Figure 59: MBI5 - 3x1...4 - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.2 MBI Configurations - Low Losses GSM 900/1800/1900 2.5.2.1 MBI3 - 1x3...4 - Low Losses - AC or DC The following figure shows the rack layout of the MBI3 - 1x3...4 - Low Losses - AC or DC configuration.

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1234567 1234567 1234567 1234567 1234567 1234567 1234567

Connection Area

ADAM

PM1 2

PM1 2

FANU

The BTS has 1 sector with n TREs

BATS (Option)

PM1 2

SUMA

ANC1

FANU

TRE3

a

b ANC2

TRE2 FANU Air Inlet STAND

TRE 1

2

3

4

Both ANCs are set to the same sector number

On each ANC: The two bridges will be removed at installation time (on site)

Dummy Panel

TRE4

b ANC1

FANU

FANU Air Inlet

ANC2

a

TRE1 FANU

12 12

Modules present only in AC configuration Empty space

Figure 60: MBI3 - 1x3...4 - Low Losses - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.2.2 MBI5 - 1x3...8 - Low Losses - AC or DC The following figure shows the rack layout of the MBI5 - 1x3...8 - Low Losses - AC or DC configuration. The BTS has 1 sector with n TREs

Connection Area TRE8

TRE7

TRE6

TRE5 a

b ANC1

TRE 1 5 2 6 FANU

FANU Air Inlet

a

b ANC2

TRE 3 7 4 8

FANU Both ANCs are set to the same sector number

ANC2

ANC1

In case of 1x3...4 On each ANC: The two bridges will be removed at installation time (on site), if no more than 2 TREs are connected to them.

Dummy Panel

TRE4

TRE3

TRE2

TRE1

12345678 1234567 12345678 1234567 12345678 1234567 123 12345678 1234567 123 12345678 1234567 12345678 1234567 123456 123456 1234567 12345678 123456 123456 1234567 1234567890123456 1234567890123456 BBU or STASR 1234567890123456 1234567890123456 1234567890123456 1234567890123456 FANU

FANU

FANU

Air Inlet

ADAM

SUMA

PM12

PM12

PM12

BATS (Option)

Modules present only in AC configuration Empty space

FANU

FANU

FANU

(Option)

STAND

Figure 61: MBI5 - 1x3...8 - Low Losses - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.2.3 MBI5 - 1x9...12 - Low Losses - AC or DC The following figure shows the rack layout of the MBI5 - 1x9...12 - Low Losses - AC or DC configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 1x11...12 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 1x1...10 without restrictions: 45 W at + 45 C. The BTS has 1 sector with n TREs

Connection Area TRE8

TRE7

FANU

ANC2

TRE6

TRE5

a

FANU FANU Air Inlet

1234567 1234567 1234567 1234567 1234567 1234567 1234567 BATS (Option)

TRE

b ANC1

a b ANC2

15 2 6

374 8

ANC1 a b ANC3

Dummy Panel

TRE4

TRE3

FANU

TRE2

FANU Air Inlet

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TRE 9 11 10 12

TRE1

The 3 ANCs are set to the same sector number

FANU

ADAM

PM1 2

PM1 2

PM1 2

SUMA

ANC3

Modules present only in AC configuration Empty space

Dummy Panel

TRE12 FANU

TRE11

123 123

TRE10

FANU Air Inlet STAND

TRE9 FANU

Figure 62: MBI5 - 1x9...12 - Low Losses - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.2.4 MBI5 - 2x3...6 - Low Losses - DC The following figure shows the rack layout of the MBI5 - 2x3...6 - Low Losses - DC configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 2x6 with 45 W at + 40 C or with 28 W at + 45 C. Configurations up to 2x3...5 without restrictions: 45 W at + 45 C. The BTS has 2 sectors with respectively n and p TREs

Connection Area TRE6

TRE5

TRE6

TRE5

Sector 1:

FANU

FANU FANU Air Inlet

TRE

a b ANC1

a b ANC2

1

3 5 46

2

Sector 2: ANC3 (Sector 2)

ANC2 (Sector 1)

Dummy Panel

TRE

a b ANC3

a b ANC4

1

3 5 46

2

In each sector: Both ANCs are set to the same sector number TRE4

TRE3

TRE4 FANU Air Inlet

FANU

S U M A

ANC4 (Sector 2)

TRE3 FANU

ANC1 (Sector 1)

In case of 2x3...4 On each ANC: The two bridges will be removed at installation time (on site), if no more than 2 TREs are connected to them.

Dummy Panel

Empty space TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 63: Indoor MEDI - 2x1...6 - Low Losses Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.5.3 MBI Configurations - High Power GSM 1800 2.5.3.1 MBI3 - 2x1 - High Power - AC or DC The following figure shows the rack layout of the MBI3 - 2x1- High Power - AC or DC configuration.

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The BTS has 2 sectors with 1 TRE each

123456 123456 123456 123456 123456 123456 123456

Connection Area

ADAM

PM12

PM12

FANU

FANU

Air Inlet

ANC2 (Sector 2)

SUMA

BATS (Option)

a b ANC1

a

b ANC2

FANU

TRE 1

TRE 1

ANC1 (Sector 1)

On each ANC: The two bridges will be removed at installation time (on site)

Dummy Panel

The ANC can be replaced by the ANB also

TRE1 FANU

TRE1 FANU Air Inlet STAND

FANU

Empty space

123 123

Modules present only in AC configuration

Figure 64: MBI3 - 2x1 - High Power - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.3.2 MBI5 - 1x1...4 - High Power - AC or DC The following figure shows the rack layout of the MBI5 - 1x1...4 - High Power - AC or DC configuration. Connection Area

The BTS has 1 sector with n TREs

FANU

FANU Air Inlet

123456 123456 123456 123456 123456 123456 123456

FANU

a

TRE

b ANC1

1 3 2 4

BATS (Option)

On site, on the ANC: The two bridges can be removed if only 2 TREs are connected

Dummy Panel

TRE4

The ANC can be replaced by the ANB in case of fewer than 3 TREs FANU

FANU Air Inlet

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FANU

ADAM

PM1 2 PM1 2

PM1 2

SUMA

ANC1

123 123

Empty space Modules present only in AC configuration

Dummy Panel

TRE3 FANU

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 65: MBI5 - 1x1...4 - High Power - AC or DC Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.5.3.3 MBI5 - 2x1...4 - High Power - AC or DC The following figure shows the rack layout of the MBI5 - 2x1...4 - High Power - AC or DC configuration. Connection Area TRE4

TRE3 The BTS has 2 sectors with respectively n and p TREs

FANU

123456 123456 123456 123456 123456 123456 123456 FANU Air Inlet

BATS (Option)

FANU

ANC2 (Sector 2)

TRE

a b ANC1

a b ANC2

1 3 2 4

1 3 2 4

On site, on each ANC: The two bridges can be removed if only 2 TREs are connected

Dummy Panel

TRE4 The ANC can be replaced by the ANB in case of fewer than 3 TREs TRE2

12345678 12345678 12345678 12345678 12345678 12345678 12345678 FANU

FANU

TRE1 FANU

Air Inlet

ADAM

SUMA

PM1 2

PM1 2

PM1 2

ANC1 (Sector 1)

12 12

Empty space Modules present only in AC configuration

Dummy Panel

TRE3 FANU

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 66: MBI5 - 2x1...4 - High Power - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.3.4 MBI5 - 3x1...3 - High Power - AC or DC The following figure shows the rack layout of the MBI5 - 3x1...3 - High Power - AC or DC configuration. The BTS has 3 sectors with respectively n, p and q TREs

Connection Area TRE3

TRE2

TRE3

a b ANC1 FANU

ANC3 (Sector 3)

123456 123456 123456 123456 123456 123456 123456 123456

FANU FANU Air Inlet

BATS (Option)

TRE 1 3 2

ANC2 (Sector 2)

TRE2

FANU

12345678 12345678 12345678 12345678 12345678 12345678 12345678

FANU

a b ANC3

1 3 2

1 3 2

In case of 3x1...2: On each ANC: The two bridges can be removed if only 2 TREs are connected (on site). One HP TRE transmitting per antenna.

Dummy Panel

TRE1

a b ANC2

TRE1

The ANC can be replaced by the ANB in case of fewer than 3 TREs

FANU

Air Inlet

ADAM

PM1 2 PM1 2

PM1 2

S U M A

ANC1 (Sector 1)

12 12

Empty space Modules present only in AC configuration

Dummy Panel

TRE3 FANU

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 67: MBI5 - 3x1...3 - High Power - AC or DC Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.5.3.5 MBI5 - 3x4 - High Power - DC The MBI5 - 3x4 - High Power - DC configuration is an extension of the 3x2 configuration described earlier. The extension is realized by adding a second BTS cabinet with the following TRE split: Cabinet 1: 2x4 HP TREs (the MBI5 3x1...2 is reconfigured to MBI5 2x1...4) Cabinet 2: 1x4 HP TREs build on an MBI5 cabinet basis.

2.5.3.6 MBI5 - 3x6 - High Power - DC The MBI5 - 3x6 - High Power - DC configuration is based on two cabinets with the following TRE split: Cabinet 1: 1x6 TREs + 1x3 TREs Cabinet 2: 1x6 TREs + 1x3 TREs These configurations use a mixture of high-power and medium-power TREs.

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2 Configurations - Rack Layouts

2.5.4 MBI Configurations - Extended Cell GSM 900 Extended cell configurations are based either on REK or on RX TMA use as shown in the following figures. INNER CELL

OUTER CELL

MAB

A

B

MAB

MAB

PDU 1

MAB

PDU 2

ANC Sector 1 A

B

A

ANC Sector 2

TRE 2 TRE 4 TRE 1 TRE 3

nc TRE 1

B ANC Sector 2

nc

nc

TRE 2

TRE 3

nc TRE 4

In the Outer Cell, the br idges are removed on each ANC

Figure 68: Extended Cell Configuration Based on REK Use INNER CELL

OUTER CELL

TMA

TMA DC B ANC Sector 2

PDU 1

Bias T A

DC

Bias T B

A TRE 2 TRE 4 TRE 1 TRE 3

ANC Sector 1 TRE 2 TRE 4 TRE 1 TRE 3

Figure 69: Extended Cell Configuration Based on RX TMA Use

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2 Configurations - Rack Layouts

2.5.4.1 MBI5 - Extended Cell Configuration Based on REK The following figure shows the rack layout of the MBI5 - Extended Cell Configuration Based on REK Use. Connection Area TRE4

TRE3

TRE2

TRE1

The BTS has 2 sectors with respectively n and p TREs: − n TREs in the Inner cell, − p TREs in the Outer cell

Inner Cell:

FANU

ANC3 Outer Cell (Sector 2)

FANU Air Inlet

123456 123456 123456 123456 123456 123456 123456 BATS (Option)

a b ANC1

FANU

TRE 1 3 2 4 ANC2 Outer Cell (Sector 2)

a b ANC2

Dummy Panel

TRE4

TRE3

Outer Cell:

TRE2

TRE1

TRE 1 3 2 4

a b ANC3 TRE 1 3 2 4

ANC2 and ANC3 are set to the same sector number FANU

FANU

FANU

The bridges are removed on ANC2 and ANC3 at installation time (on site)

12345678 12345678 12345678 12345678 123 12345678 12345678 123 12345678 123456 123456 123456 123456 123456 123456 1234567890123456 1234567890123456 BBU or STASR 1234567890123456 1234567890123456 1234567890123456 1234567890123456 Air Inlet

ADAM

SUMA

PM12

PM12

FANU

PM12

FANU

ANC1 Inner Cell (Sector 1) FANU

Modules present only in AC configuration Empty space

(Option)

STAND

Figure 70: MBI5 - Extended Cell Configuration Based on REK Use

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2 Configurations - Rack Layouts

2.5.4.2 MBI5 - Extended Cell Configuration Based on RX TMA Use The following figure shows the rack layout of the MBI5 - Extended Cell Configuration Based on RX TMA Use. Connection Area TRE4

TRE3

TRE2

TRE1

The BTS has 2 sectors with respectively n and p TREs: − n TREs in the Inner cell, − p TREs in the Outer cell

Inner Cell:

FANU

FANU Air Inlet

123456 123456 123456 123456 123456 123456 123456 BATS (Option)

a b ANC1

FANU

TRE 1 3 2 4

ANC2 Outer Cell (Sector 2)

Outer Cell: a b ANC2

Dummy Panel

TRE4

TRE3

TRE2

TRE1

TRE 1 3 2 4

12345678 12345678 12345678 12345678 12 12345678 12345678 12 123456 123456 1234567 12345678 123456 123456 1234567 1234567890123456 1234567890123456 BBU or STASR 1234567890123456 1234567890123456 1234567890123456 1234567890123456 FANU

FANU

FANU

Air Inlet

ADAM

P M 1 2

P M 1 2

FANU

P M 1 2

S U M A

FANU

ANC1 Inner Cell (Sector 1) FANU

Modules present only in AC configuration Empty space

(Option)

STAND

Figure 71: MBI5 - Extended Cell Configuration Based on RX TMA Use

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2 Configurations - Rack Layouts

2.5.5 MBI Configurations - Multiband BTS GSM 900/1800 and GSM 900/1900 2.5.5.1 MBI3 - 1x1...4/1x1...4 The following figure shows the rack layout of the MBI3 - 1x1...4/1x1...4 Multiband BTS configuration. The BTS has 2 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs

Connection Area TRE4

TRE3

TRE4

TRE3

a b ANC1 FANU

FANU Air Inlet

FANU

TRE 1 3 2 4 Sector 1

S U M A

ANC2 (Sector 2)

ANC1 (Sector 1)

a b ANC2 TRE 1 3 2 4 Sector 2

The ANC can be replaced by the ANB in case of fewer than 3 TREs

Dummy Panel GSM 1800 / GSM 1900 Empty space

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 72: MBI3 - 1x1...4/1x1...4 - Multiband BTS Configuration

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2.5.5.2 MBI5 - 1x1...6/1x1...6 The following figure shows the rack layout of the MBI5 - 1x1...6/1x1...6 Multiband BTS configuration. Connection Area TRE6

TRE5

TRE4

TRE3

The BTS has 2 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs

a b ANC1 Sector 1 FANU

FANU Air Inlet

123456 123456 123456 123456 123456 123456 123456 123456 BATS (Option)

SUMA

ANY1

FANU TRE 1 3

ANY 2

ANC2 (Sector 2)

a b ANC2 Sector 2 ANY2

Dummy Panel

TRE 1 3

TRE5

TRE6

TRE2 FANU

2 4 5 6

TRE1

2 456

In each sector, if no more than 4 TREs, no ANY is required. TRE1 to 4 are then cabled on ANC.

FANU

FANU

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Air Inlet

ADAM

PM1 2

PM1 2

The ANC can be replaced by the ANB in case of fewer than 3 TREs

PM1 2 ANY 1

ANC1 (Sector 1)

GSM 1800 / GSM 1900

Dummy Panel

TRE4 FANU

TRE3

TRE2

FANU Air Inlet STAND

TRE1

12 12

Empty space Modules present only in AC configuration

FANU

Figure 73: MBI5 - 1x1...6/1x1...6 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.3 MBI5 - 1x1...8/1x1...4 The following figure shows the rack layout of the MBI5 - 1x1...8/1x1...4 Multiband BTS configuration. The BTS has 2 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs

Connection Area TRE8

TRE7

TRE6

TRE5 a b ANC1

Sector 1 TRE

123456 123456 123456 123456 123456 123456 123456 FANU

ANY 2

FANU

BATS (Option)

1 3 2 4

FANU Air Inlet a b ANC2

Sector 2

ANY 1

ANC2 (Sector 2)

ANY1 TRE 1 3 5 7

ANY2 2 4 6 8

Dummy Panel In sector 2, if no more than 4 TREs, no ANY is required. TRE1 to 4 are then cabled on ANC.

TRE4

TRE3

TRE2

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FANU

TRE1 FANU

The ANC can be replaced by the ANB in case of fewer than 3 TREs

Air Inlet

ADAM

PM1 2

PM1 2

GSM 1800 / GSM 1900

PM1 2 SUMA

ANC1 (Sector 1)

Modules present only in AC configuration

Dummy Panel

TRE4 FANU

TRE3

123 123

Empty space

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 74: MBI5 - 1x1...8/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.4 MBI5 - 1x1...4/1x1...8 The following figure shows the rack layout of the MBI5 - 1x1...4/1x1...8 Multiband BTS configuration. The BTS has 2 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs

Connection Area TRE8

TRE7

TRE6

TRE5 a b ANC1

Sector 1 TRE

123456 123456 123456 123456 123456 123456 123456 FANU

ANY 2

FANU Air Inlet

a b ANC2

Sector 2

ANY 1

BATS (Option)

1 3 2 4

FANU

ANC2 (Sector 2)

ANY1 TRE 1 3 5 7

ANY2 2 4 6 8

Dummy Panel

In sector 2, if no more than 4 TREs, no ANY is required. TRE1 to 4 are then cabled on ANC. TRE4

TRE3

FANU

TRE2 FANU

TRE1 FANU

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Air Inlet

The ANC can be replaced by the ANB in case of fewer than 3 TREs

ADAM

PM1 2

PM1 2

PM1 2

SUMA

ANC1 (Sector 1)

123 123

Empty space Modules present only in AC configuration

Dummy Panel

TRE4 FANU

TRE3

GSM 1800 / GSM 1900

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 75: MBI5 - 1x1...4/1x1...8 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.5 MBI5 - 1x3...8LL/1x1...4 The following figure shows the rack layout of the MBI5 - 1x3...8LL/1x1...4 Multiband BTS configuration. The BTS has 2 sectors with respectively n and p TREs

Connection Area TRE4

TRE3

TRE6

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FANU

TRE5

FANU FANU Air Inlet

BATS (Option)

ANC3 (Sector 2)

The configuration is based on 1x3...8 Low Loss configuration extended with a 1x4 sector.

Sector 1 TRE

a b ANC1

a b ANC2

12 7 8

3 4 5 6

ANC2 (Sector 1) a b ANC3

Sector 2

Dummy Panel

TRE 1 3 2 4

TRE2

TRE1

TRE4

12345678 12345678 12345678 12345678 12345678 12345678 12345678 FANU

FANU Air Inlet

TRE3 FANU

ADAM

PM1 2

PM1 2

PM1 2

SUMA

ANC1 (Sector 1)

In case of 1x3...4 LL/1x1...4 On ANC1 and ANC2: The two bridges will be removed at installation time (on site), if no more than 2 TREs are connected to them.

Dummy Panel GSM 1800 / GSM 1900

123 123

Modules present only in AC configuration

TRE8 FANU

TRE7

TRE2 FANU Air Inlet STAND

TRE1

Empty space

FANU

Figure 76: MBI5 - 1x3...8LL/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.6 MBI5 - 1x1...4/2x1...4 The following figure shows the rack layout of the Indoor MBI5 - 1x1...4/2x1...4 Multiband BTS configuration. Connection Area TRE4

TRE3

TRE4

TRE3 The BTS has 3 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs, − Sector 3 with q TREs

1234567 1234567 1234567 1234567 1234567 1234567 1234567

FANU

FANU FANU Air Inlet

BATS (Option)

ANC3 (Sector 3)

TRE 1 3 2 4 ANC2 (Sector 2)

TRE1

TRE2

12345678 12345678 12345678 12345678 12345678 12345678 12345678 FANU

FANU Air Inlet

Sector 1

a b ANC2

a b ANC3

1 3 2 4

1 3 2 4

Sector 2

Sector 3

The ANC can be replaced by the ANB in case of fewer than 3 TREs

Dummy Panel

TRE2

a b ANC1

TRE1 FANU

ADAM

PM1 2

PM1 2

PM1 2

SUMA

ANC1 (Sector 1)

Dummy Panel GSM 1800 / GSM 1900

123 123

Modules present only in AC configuration

TRE4 FANU

TRE3

TRE2 FANU Air Inlet STAND

TRE1

Empty space

FANU

Figure 77: MBI5 - 1x1...4/2x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.7 MBI5 - 2x1...4/1x1...4 The following figure shows the rack layout of the MBI5 - 2x1...4/1x1...4 Multiband BTS configuration. Connection Area TRE4

TRE3

TRE4

TRE3 The BTS has 3 sectors: − Sector 1 with n TREs, − Sector 2 with p TREs, − Sector 3 with q TREs

1234567 1234567 1234567 1234567 1234567 1234567 1234567

FANU FANU Air Inlet

FANU

BATS (Option)

ANC3 (Sector 3)

ANC2 (Sector 2)

TRE1

TRE2

12345678 12345678 12345678 12345678 12345678 12345678 12345678 FANU

FANU Air Inlet

a b ANC2

a b ANC3

TRE 1 3 2 4

1 3 2 4

1 3 2 4

Sector 1

Sector 2

Sector 3

The ANC can be replaced by the ANB in case of fewer than 3 TREs

Dummy Panel

TRE2

a b ANC1

TRE1 FANU

ADAM

PM1 2

PM1 2

PM1 2

SUMA

ANC1 (Sector 1)

Dummy Panel GSM 1800 / GSM 1900

123 123

Modules present only in AC configuration

TRE4 FANU

TRE3

TRE2 FANU Air Inlet STAND

TRE1

Empty space

FANU

Figure 78: MBI5 - 2x1...4/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.8 MBI5 - 1x1...4/...4,...2,...2 The following figure shows the rack layout of the MBI5 - 1x1...4/...4,...2,...2 Multiband BTS configuration. The BTS has 4 sectors with respectively n, p, q and r TREs

Connection Area TRE4

TRE3

TRE4

TRE3 a b ANC1

FANU

FANU FANU Air Inlet

ANC3 (Sector 3)

ANC2 (Sector 2)

TRE 1

2

TRE 1 3 2 4

Sector 1

Sector 2

a b ANC3

a b ANC4

TRE 1 3 2 4 Sector 3

Dummy Panel

a b ANC2

TRE 1

2

Sector 4

The ANC can be replaced by the ANB in case of fewer than 3 TREs

TRE2

TRE1

TRE2 FANU Air Inlet

FANU

S U M A

ANC4 (Sector 4)

TRE1 FANU

GSM 1800 / GSM 1900 Empty space

ANC1 (Sector 1)

Dummy Panel

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 TRE1 FANU FANU

Figure 79: MBI5 - 1x1...4/...4,...2,...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.9 MBI5 - ...4,...2,...2/1x1...4 The following figure shows the rack layout of the MBI5 - ...4,...2,...2/1x1...4 Multiband BTS configuration. The BTS has 4 sectors with respectively n, p, q and r TREs

Connection Area TRE4

TRE3

TRE4

TRE3 a b ANC1

FANU

FANU FANU Air Inlet

ANC3 (Sector 3)

ANC2 (Sector 2)

TRE 1

2

Sector 1

a b ANC2 TRE 1 3 2 4 Sector 2

a b ANC3 TRE 1 3 2 4

a b ANC4 TRE 1

Sector 3

Dummy Panel

2

Sector 4

GSM 1800 / GSM 1900 Empty space TRE2

TRE1

TRE2 FANU Air Inlet

FANU

S U M A

ANC4 (Sector 4)

TRE1 FANU

ANC1 (Sector 1)

Dummy Panel

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU FANU

Figure 80: MBI5 - ...4,...2,...2/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.10 MBI5 - 2x1...4/2x1...2 The following figure shows the rack layout of the MBI5 - 2x1...4/2x1...2 Multiband BTS configuration. Connection Area TRE2

TRE1

TRE2

TRE1 The BTS has 4 sectors with respectively n, p, q and r TREs

FANU

FANU FANU Air Inlet

ANC3 (Sector 3)

ANC2 (Sector 2)

Dummy Panel TRE4

TRE3

TRE4

a b ANC1 TRE 1 3 2 4

a b ANC2 TRE 1

Sector 2

a b ANC3

a b ANC4

TRE3 TRE 1

2

TRE 1 3 2 4

Sector 3

FANU FANU Air Inlet

FANU

S U M A

ANC4 (Sector 4)

2

Sector 1

ANC1 (Sector 1)

Sector 4

The ANC can be replaced by the ANB in case of fewer than 3 TREs

GSM 1800 / GSM 1900 Empty space

Dummy Panel

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 TRE1 FANU FANU

Figure 81: MBI5 - 2x1...4/2x1...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.5.11 MBI5 - 2x1...2/2x1...4 The following figure shows the rack layout of the MBI5 - 2x1...2/2x1...4 Multiband BTS configuration. Connection Area TRE2

TRE1

TRE2

TRE1

The BTS has 4 sectors with respectively n, p, q and r TREs

a b ANC1 FANU

FANU FANU Air Inlet

TRE 1

2

Sector 1 ANC3 (Sector 3)

a b ANC2 TRE 1 3 2 4 Sector 2

ANC2 (Sector 2) a b ANC3

a b ANC4

Dummy Panel TRE 1 3 2 4

TRE 1

Sector 3

TRE4

TRE3

TRE4 FANU Air Inlet

FANU

TRE3

2

Sector 4

The ANC can be replaced by the ANB in case of fewer than 3 TREs

FANU

GSM 1800 / GSM 1900 S U M A

ANC4 (Sector 4)

ANC1 (Sector 1)

Empty space

Dummy Panel

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU FANU

Figure 82: MBI5 - 2x1...2/2x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.5.6 MBI Configurations - Multiband Cells GSM 900/1800 2.5.6.1 MBI3 - 1x(...4/...4) The following figure shows the rack layout of the MBI3 - 1x(...4/...4) - Multiband Cells - DC configuration. Connection Area TRE4

TRE3

TRE4

TRE3

The BTS has 1 sector with: − n TREs in GSM 900 band, − p TREs in GSM 1800 band ANC1 and ANC2 are set to the same sector number

FANU

FANU Air Inlet S U M A

ANC2

FANU

a b ANC1 TRE 1 3 2 4

a b ANC2 TRE 1 3 2 4

ANC1 The ANC can be replaced by the ANB in case of fewer than 3 TREs

Dummy Panel GSM 1800 Empty space

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 83: MBI3 - 1x(...4/...4) - Multiband Cells - DC Configuration

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2 Configurations - Rack Layouts

2.5.6.2 MBI5 - 1x(...6/...6) The following figure shows the rack layout of the MBI5 - 1x(...6/...6) - Multiband Cells - AC or DC configuration. Connection Area TRE6

TRE5

TRE4

TRE3

The BTS has 1 sector with: − p TREs in GSM 900 band, − n TREs in GSM 1800 band

a b ANC1

123456 123456 123456 123456 123456 123456 123456

FANU

FANU Air Inlet

BATS (Option)

SUMA

ANY1

FANU TRE 1 3

ANY 2

ANC2

a b ANC2 ANY2

Dummy Panel

TRE 1 3

TRE5

TRE6

TRE2 FANU

TRE1 FANU

12345678 12345678 12345678 12345678 12345678 12345678 12345678 FANU

Air Inlet

PM1 2

PM1 2

ANC1 and ANC2 are set to the same sector number.

ANY 1

ANC1

The ANC can be replaced by the ANB in case of fewer than 3 TREs GSM 1800

Dummy Panel

12 12 TRE4 FANU

TRE3

2 456

If no more than 4 TREs, no ANY is required. TRE1 to TRE4 are then cabled on ANC.

ADAM

PM1 2

2 456

TRE2

FANU Air Inlet STAND

Empty space Modules present only in AC configuration

TRE1 FANU

Figure 84: MBI5 - 1x(...6/...6) - Multiband Cells - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.6.3 MBI5 - 1x(...8/...4) The following figure shows the rack layout of the MBI5 - 1x(...8/...4) - Multiband Cells - AC or DC configuration. The BTS has 1 sector with: − n TREs in GSM 900 band, − p TREs in GSM 1800 band

Connection Area TRE8

TRE7

TRE6

TRE5 a b ANC1 TRE

123456 123456 123456 123456 123456 123456 123456

FANU

FANU Air Inlet

BATS (Option)

ANY 2

1 3 2 4

FANU a b ANC2

ANY 1

ANC2 ANY1 TRE 1 3 5 7

ANY2 2 4 6 8

Dummy Panel ANC1 and ANC2 are set to the same sector number.

TRE4

TRE3

FANU

TRE2 FANU

TRE1

12345678 12345678 12345678 12345678 12345678 12345678 12345678

Air Inlet

The ANC can be replaced by the ANB in case of fewer than 3 TREs

ADAM

SUMA

PM1 2

PM1 2

FANU

TRE3

TRE2 FANU Air Inlet STAND

GSM 1800

ANC1

PM1 2

123 123

Dummy Panel

TRE4

ANC2, If no more than 4 TREs, no ANY is required. TRE1 to TRE4 are then cabled on ANC.

FANU

Empty space Modules present only in AC configuration

TRE1 FANU

Figure 85: MBI5 - 1x(...8/...4) - Multiband Cells - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.6.4 MBI5 - 1x(...4/...8) The following figure shows the rack layouts of the MBI5 - 1x(...4/...8) - Multiband Cells - AC or DC configuration. The BTS has 1 sector with: − n TREs in GSM 900 band, − p TREs in GSM 1800 band

Connection Area TRE8

TRE7

TRE6

TRE5 a b ANC1 TRE

123456 123456 123456 123456 123456 123456 123456

FANU

FANU Air Inlet

BATS (Option)

ANY 2

1 3 2 4

FANU a b ANC2

ANY 1

ANC2 ANY1 TRE 1 3 5 7

ANY2 2 4 6 8

Dummy Panel ANC1 and ANC2 are set to the same sector number.

ANC 2, if no more than 4 TREs, no ANY is required. TRE1 to TRE4 are then cabled on ANC. TRE4

TRE3

FANU

TRE2 FANU

TRE1 FANU

12345678 12345678 12345678 12345678 12345678 12345678 12345678

The ANC can be replaced by the ANB in case of fewer than 3 TREs.

Air Inlet

ADAM

SUMA

PM1 2

PM1 2

ANC1

Empty space

123

Modules present only in AC configuration

Dummy Panel

TRE4 FANU

GSM 1800

PM1 2

TRE3

TRE2 FANU Air Inlet STAND

TRE1 FANU

Figure 86: MBI5 - 1x(...4/...8) - Multiband Cells - AC or DC Configuration

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2 Configurations - Rack Layouts

2.5.6.5 MBI5 - 2x(...4/...2) The following figure shows the rack layout of the MBI5 - 2x(...4/...2) - Multiband Cells - DC configuration. Connection Area TRE2

TRE1

TRE2

TRE1

The BTS has 2 sectors. Sector 1: − n TREs in GSM 900 band, − p TREs in GSM 1800 band

FANU

FANU FANU Air Inlet

ANC3 (Sector 2)

ANC2 (Sector 1)

ANC1 and ANC2 are set to the same sector number.

a b ANC1 TRE 1 3 2 4

a b ANC2 TRE 1

2

Dummy Panel TRE4

TRE3

TRE4

TRE3

Sector 2: − q TREs in GSM 1800 band, − r TREs in GSM 900 band ANC3 and ANC4 are set to the same sector number.

FANU FANU Air Inlet

FANU

ANC4 (Sector 2)

SUMA

ANC1 (Sector 1)

a b ANC3 TRE 1

2

a b ANC4 TRE 1 3 2 4

The ANC can be replaced by the ANB in case of fewer than 3 TREs Dummy Panel GSM 1800 Empty space TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU FANU

Figure 87: MBI5 - 2x(...4/...2) - Multiband Cells - DC Configuration

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2.5.6.6 MBI5 - 2x(...2/...4) The following figure shows the rack layout of the MBI5 - 2x(...2/...4) - Multiband Cells - DC configuration. Connection Area TRE2

TRE1

The BTS has 2 sectors.

TRE2

TRE1

Sector 1: − n TREs in GSM 900 band, − p TREs in GSM 1800 band ANC1 and ANC2 are set to the same sector number.

FANU

FANU FANU Air Inlet

ANC3 (Sector 2)

ANC2 (Sector 1)

a b ANC1 TRE 1

2

a b ANC2 TRE 1 3 2 4

Sector 2: − q TREs in GSM 1800 band, − r TREs in GSM 900 band

Dummy Panel

ANC3 and ANC4 are set to the same sector number. TRE4

TRE3

TRE4 FANU

FANU

TRE3 FANU

Air Inlet

a b ANC3 TRE 1 3 2 4

ANC4 (Sector 2)

SUMA

a b ANC4 TRE 1

2

ANC1 (Sector 1) The ANC can be replaced by the ANB in case of fewer than 3 TREs.

Dummy Panel GSM 1800 Empty space TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU FANU

Figure 88: MBI5 - 2x(...2/...4) - Multiband Cells - DC Configuration

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2.5.6.7 MBI5 - 1x(...2/...2), 1x(...4/...4) The following figure shows the rack layout of the MBI5 - 1x(...2/...2), 1x(...4/...4) - Multiband Cells - DC configuration. Connection Area TRE2

TRE1

The BTS has 2 sectors.

TRE2

TRE1

Sector 1: − n TREs in GSM 900 band, − q TREs in GSM 1800 band ANC1 and ANC3 are set to the same sector number.

FANU FANU Air Inlet

FANU

ANC3 (Sector 1)

ANC2 (Sector 2)

TRE 1

2

a b ANC3 TRE 1

2

Sector 2: − p TREs in GSM 1800 band, − r TREs in GSM 900 band

Dummy Panel TRE4

a b ANC1

TRE3

ANC2 and ANC4 are set to the same sector number. TRE4 FANU

TRE3

FANU FANU Air Inlet

a b ANC2 TRE 1 3 2 4

ANC4 (Sector 2)

SUMA

ANC1 (Sector 1)

a b ANC4 TRE 1 3 2 4

The ANC can be replaced by the ANB in case of fewer than 3 TREs.

Dummy Panel GSM 1800 Empty space

TRE2 FANU

TRE1

TRE2 FANU Air Inlet STAND

TRE1 FANU FANU

Figure 89: MBI5 - 1x(...2/...2), 1x(...4/...4) - Multiband Cells - DC Configuration

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2.6 Multistandard Base Station Indoor Configurations with Twin TRX 2.6.1 Capacity Mode 2.6.1.1 MBI3 - 1 Sector with Twin-TRX

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2.6.1.2 MBI5 - 1 Sector with Twin-TRX

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2.6.1.3 MBI3 - 2 Sectors with Twin-TRX

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2.6.1.4 MBI5 - 2 Sectors with Twin-TRX

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2.6.1.5 MBI3 - 3 Sectors with Twin-TRX

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2.6.1.6 MBI5 - 3 Sectors with Twin-TRX Configurations with maximum 4/4/4 TRX.

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Configurations with intended, respective more than 4/4/4 TRX.

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2.6.1.7 MBI3 - 4 Sectors with Twin-TRX

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2.6.1.8 MBI5 - 4 Sectors with Twin-TRX

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2.6.2 Capacity Mode Low Loss 2.6.2.1 MBI3 - 1 Sector Low Loss with Twin-TRX

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2.6.2.2 MBI5 - 1 Sector Low Loss with Twin-TRX

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2.6.2.3 MBI3 - 2 Sectors Low Loss with Twin-TRX

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2.6.2.4 MBI5 - 2 Sectors Low Loss with Twin-TRX

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2.6.2.5 MBI5 - 3 Sectors Low Loss with Twin-TRX

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2.6.3 Multiband & MB Cell 2.6.3.1 MBI3 - Multiband 1 + 1 Sector with Twin-TRX

Multiband BTS: The BTS has 2 sectors with n and p TRX. Multiband cell: The BTS has one sector with n TRX in 900 MHz and p TRX in 1800 MHz.

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2.6.3.2 MBI5 - Multiband 1 + 1 Sectors with Twin-TRX

Multiband BTS: The BTS has 2 sectors with n and p TRX. Multiband cell: The BTS has one sector with n TRX in 900 MHz and p TRX in 1800 MHz.

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2.6.3.3 MBI5 - Multiband 2 + 2 Sectors with Twin-TRX

Multiband BTS: The BTS has 4 sectors with n and q TRX in 900 MHz plus p and r TRX in 1800 TRX. Multiband cell: The BTS has 1 sector with n TRX in 900MHz and p TRX in 1800 MHz and 1 sector with q TRX in 900 MHz and r TRX in 1800 TRX.

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2.6.3.4 MBI5 - Multiband 3 + 3 Sectors with Twin-TRX

Multiband BTS: The BTS has 6 sectors with n, q, s TRX in 900 MHz and p, r, t TRX in 1800 MHz. Multiband cell: The BTS has 1 sector with n TRX in 900 MHz and p TRX in 1800 MHz plus 1 sector with q TRX in 900 MHz and r TRX in 1800 MHz plus 1 sector with s TRX in 900 MHz and t TRX in 1800 MHz.

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2.6.4 Coverage Mode TxDiv. 2Rx Div. 2.6.4.1 MBI3 - 1 Sector TX Diversity 2 RX with Twin-TRX

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2.6.4.2 MBI5 - 1 Sectors TX Diversity 2 RX with Twin-TRX

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2.6.4.3 MBI3 - 2 Sector TX Diversity 2 RX with Twin-TRX

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2.6.4.4 MBI5 - 2 Sectors TX Diversity 2 RX with Twin-TRX

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2.6.4.5 MBI3 - 3 Sector TX Diversity 2RX with Twin-TRX

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2.6.4.6 MBI5 - 3 Sector TX Diversity 2RX with Twin-TRX

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2.6.5 Coverage Mode TxDiv. 2Rx Div. Low Loss 2.6.5.1 MBI3 - 1 Sector TX Diversity Low Loss with Twin-TRX

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2.6.5.2 MBI5 - 1 Sector TX Diversity Low Loss with Twin-TRX

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2.6.5.3 MBI3 - 2 Sectors TX Diversity Low Loss with Twin-TRX

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2.6.5.4 MBI5 - 2 Sectors TX Diversity Low Loss with Twin-TRX

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2.6.5.5 MBI5 - 3 Sectors TX Diversity Low Loss with Twin-TRX

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2.6.6 Coverage Mode TxDiv. 4Rx Div. Low Loss 2.6.6.1 MBI3 - 1 Sector TX Diversity 4 RX with Twin-TRX

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2.6.6.2 MBI5 - 1 Sector TX Diversity 4 RX with Twin-TRX

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2.6.6.3 MBI3 - 2 Sector TX Diversity 4 RX with Twin-TRX

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2.6.6.4 MBI5 - 2 Sector TX Diversity 4 RX with Twin-TRX

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2.6.6.5 MBI5 - 3 Sectors TX Diversity 4 RX with Twin-TRX

2.6.7 Extended Cell 2.6.7.1 MBI3 - Extended Cell with Twin-TRX AC or DC configuration, with up to 4 + 4 TRX.

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2.6.7.2 MBI5 - Extended Cell with Twin-TRX

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2.6.8 Extended Cell TxDiv, 4RX Div for outer cell 2.6.8.1 MBI3 - Extended Cell TX Diversity 4 RX with Twin-TRX

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2.6.8.2 MBI5 - Extended Cell TX Diversity 4 RX with Twin-TRX

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2.7 Multistandard Base Station Indoor Mixed Configurations Based on Extension with Twin TRX The following table gives the possible configuration extension based on Twin TRX modules. Cabinet

Number of sectiors

AC

DC

Carriesrs per sector

Carriesrs per sector

Single TRX -> Twin Single TRX -> Twin TRX TRX MBI3

MBI5

Mini

Medi

*

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1

4 -> 8

8 -> 12

2

2/2 -> 4/4

4/4 -> 4/6(6/6*)

3

1/1/1 -> 2/2/2

2/2/2 -> 4/4/4

1

n.a.

12 -> 16

2

n.a.

6/6 -> 8/8

3

4/4/4 -> 4/6/6 (6/6/6*)

4/4/4 -> 6/6/6

1

n.a.

4 -> 8

2

n.a.

2/2 -> 4/4

3

n.a.

1/1/1 -> 2/2/2

1

n.a.

12 -> 16

2

2/2 -> 4/4

6/6 -> 8/8

3

2/2/2 (4/4/4) -> 4/6/6(6/6/6)

4/4/4 -> 6/6/6

: Change of SUMA location

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2.7.1 MBI3 - 1 sector mixed configuration Single/Twin-TRX

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2.7.2 MBI3 - 2 sectors mixed configuration Single/Twin-TRX

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2.7.3 MBI3 - 3 sectors mixed configuration Single/Twin-TRX

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2.7.4 MBI5 - 1 Sector mixed configuration Single/Twin-TRX

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2.7.5 MBI5 - 2 Sectors mixed configuration Single/Twin-TRX

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2.7.6 MBI5 - 3 Sectors mixed configuration Single/Twin-TRX

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2.8 Multistandard Base Station Indoor Mixed Configurations Based on Extension with Twin TRX (Only in MBI5 Cabinet Variant AB) The following table gives the possible configuration extension based on Twin TRX modules. Cabinet

Number of sectiors

AC

DC

Carriesrs per sector

Carriesrs per sector

Single TRX -> Twin Single TRX -> Twin TRX TRX MBI5 (AB)

*

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1

n.a.

12 -> 16

2

n.a.

6/6 -> 12/12

3

4/4/4 -> 4/6/6(6/6/6)

4/4/4 -> 6/6/6

: Change of SUMA location

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2.8.1 MBI5 AB variant - 1 Sector mixed configuration Single/Twin-TRX

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2.8.2 MBI5 AB variant - 2 Sectors mixed configuration Single/Twin-TRX

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2.8.3 MBI5 AB variant - 3 Sectors mixed configuration Single/Twin-TRX

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2.9 Outdoor Configurations with Single TRX 2.9.1 Outdoor Configurations - Standard BTS GSM 900/1800/1900 2.9.1.1 Outdoor CBO - 1x1...2 The following figure shows the rack layouts of the Outdoor CBO - 1x1...2 configuration.

Figure 90: Outdoor CBO - 1x1...2 Configuration

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2.9.1.2 Outdoor MINI - 1x1...4 The following figure shows the rack layouts of the Outdoor MINI - 1x1...4 configuration.

OPTIONS

SUM

ANY

ANX

The BTS has n TREs If ANY not equipped (2 TREs max.), TRE1 and TRE2 are directly connected to ANX

AIR Empty space, no dummy panels needed

TRE4

TRE3

FANU

TRE2 FANU AIR

TRE1 FANU

AIR

The BTS has 1 sector with n TREs

a b ANC1

AIR

TRE 1 2 3 4 SUMA

ANC1

AIR

Empty space

TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

Figure 91: Outdoor MINI - 1x1...4 Configuration

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2.9.1.3 Outdoor MINI - 1x1...8 The following figure shows the rack layout of the Outdoor MINI - 1x1...8 configuration. AIR TRE8

TRE6

TRE7

TRE5

The BTS has 1 sector with n TREs a FANU

FANU

b

FANU ANC1

AIR

ANY1 SUMA

ANY2

ANY 1

ANY2

ANC1 TRE 1 2 3 4

5 6 7 8

AIR If more than 4 TREs, 2 ANY are required pre−equipment possible.

Up to 4 TREs, and if no ANY pre−equipment, TRE1 to TRE4 are directly connected to the ANC.

TRE4 FANU

TRE3

TRE2 FANU

TRE1

Empty space

FANU

AIR

Figure 92: Outdoor MINI - 1x1...8 Configuration

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2.9.1.4 Outdoor CBO - 2x1 The following figure shows the rack layouts of the Outdoor CBO - 2x1 configuration.

1234567890123456 1234567890123456 1234567890123456 BATS

ANC2

The BTS has 2 sector with 1 TRE

a

ANC1

b ANC1

TRE 1

a

b ANC2

TRE 1

ADAM2

PM12

PM12

SUMA TRE1

FANU

FANU HEAT3

TRE1 FANU

12 12

Empty space Options

Figure 93: Outdoor CBO - 2x1 Configuration

2.9.1.5 Outdoor CBO - 2x2 The following figure shows the rack layouts of the Outdoor CBO - 2x2 configuration. This configuration is available only on CBO DC variant.

Figure 94: Outdoor CBO - 2x2 Configuration

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2.9.1.6 Outdoor MINI - 2x1...2 The following figure shows the rack layouts of the Outdoor MINI - 2x1...2 configuration.

OPTIONS

SUM

ANX (Sector 2)

ANX (Sector 1)

The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs

Empty space, no dummy panels needed AIR

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

AIR

AIR

The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs AIR

a

b

a

ANC1 ANC2 (Sector 2)

SUMA

ANC1 (Sector 1)

TRE 1 2 Sector 1

b ANC2

TRE 1 2 Sector 2

AIR

Empty space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

Figure 95: Outdoor MINI - 2x1...2 Configuration

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2.9.1.7 Outdoor MINI - 2x1...4 The following figure shows the rack layout of the Outdoor Mini - 2x1...4 configuration. AIR TRE4

TRE3

TRE4

TRE3

The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs

FANU

FANU

FANU

AIR

a

b ANC1

ANC2 (Sector 2)

SUMA

ANC1 (Sector 1)

TRE 1 2 3 4 Sector 1

a

b ANC2

TRE 1 2 3 4 Sector 2

AIR

Empty space

TRE2

TRE2

TRE1 FANU

FANU

TRE1 FANU

AIR

Figure 96: Outdoor MINI - 2x1...4 Configuration

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2.9.1.8 Outdoor MINI - 3x1 The following figure shows the rack layout of the Outdoor MINI - 3x1 configuration.

OPTIONS

ANX SUM

(Sector 2)

FANU

ANX (Sector 3)

TRE 3

FANU

ANX (Sector 1)

TRE 2

FANU

The BTS has 3 TREs, one per sector

Empty space, no dummy panels needed

TRE 1

AIR

Figure 97: Outdoor MINI - 3x1 Configuration

2.9.1.9 Outdoor CBO - 3x1 The following figure shows the rack layout of the CBO - 3x1 configuration. This configuration is available only on CBO DC variant.

Figure 98: CBO 3x1 Configuration

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2.9.1.10 Outdoor MINI - 3x1...2 The following figure shows the rack layout of the Outdoor MINI - 3x1...2 configuration. AIR TRE2

TRE1 ANC3 (Sector 3)

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

a FANU

FANU

FANU

a

b

b

a

b

ANC3

ANC2

ANC1

AIR

ANC2

ANC1 SUMA

(Sector 2)

TRE 1 2 Sector 1

TRE 1 2 Sector 2

TRE 1 2 Sector 3

(Sector 1) On each ANC, the bridges can be removed at installation (on site), if maximum power is required.

AIR

Empty space

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

AIR

Figure 99: Outdoor MINI - 3x1...2 Configuration

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2.9.1.11 Outdoor MINI - 3x1...2 - GSM 1900 (ANX version) The following figure shows the rack layout of the Outdoor MINI - 3x1...2 - GSM 1900 configuration (ANX version). AIR TRE2

TRE1 ANX 3 ( Sector 3 )

FANU

FANU AIR

ANX 2 ( Sector 2 )

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

FANU

S U M A

ANX 1

a b ANX 1

a b ANX 2

a b ANX 3

( Sector 1 ) TRE 1 2 Sector 1

TRE 1 2 Sector 2

TRE 1 2 Sector 3

AIR

Empty space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

Figure 100: Outdoor MINI - 3x1...2 - GSM 1900 Configuration (ANX version)

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2.9.1.12 Outdoor MEDI - 1x1...8 The following figure shows the rack layouts of the Outdoor MEDI - 1x1...8 configuration for GSM 900/1800. AIR TRE8

TRE7

TRE6

TRE5

OPTIONS The BTS has n TREs FANU

FANU AIR

FANU

If no ANY (2 TREs max.), TRE1 and TRE2 are connected to ANX If ANY 2 only, ANY2 is connected to ANX1

ANY3 ANY1

SUM

ANY2

ANX1 ANY filling order: ANY2 then ANY1 then ANY3

AIR

AIR

Empty space, no dummy panels needed TRE4

TRE3

FANU

TRE2 FANU

AIR

TRE1 FANU

AIR

AIR

AIR TRE8

TRE6

TRE7

TRE5 The BTS has 1 sector with n TREs a

b ANC1

FANU

FANU

AIR

FANU

AIR TRE ANY2

SUMA

ANY1

ANY1

ANY2

1 2 3 4

5 6 7 8

ANC1 If more than 4 TREs, 2 ANYs are required Pre−equipment possible

AIR

AIR

Empty Space TRE4 FANU AIR

TRE3

TRE2 FANU AIR

TRE1 FANU

Figure 101: Outdoor MEDI - 1x1...8 Configuration

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2.9.1.13 Outdoor MEDI - 1x9...12 The following figure shows the rack layouts of the Outdoor MEDI - 1x9...12 configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 1x11...12 with 28 W at + 40 C. Configurations up to 1x1...10 without restrictions: 45 W at + 45 C. AIR TRE8

TRE7

TRE6

TRE5

OPTIONS

FANU

SUM

ANY 1

ANY 2

ANX 1

FANU AIR

ANY ANY 3 1

FANU

ANY 2

ANX1 and ANX2 are set to the same sector number

ANX 2 Empty space, no dummy panels needed

AIR

AIR

TRE12 FANU

TRE11

TRE10 FANU

TRE9 FANU

TRE4 FANU

TRE3

TRE2

TRE1 FANU

TRE6

TRE5

FANU AIR

AIR

AIR

AIR TRE8

TRE7

The BTS has 1 sector with n TREs a b ANC 1 FANU

FANU AIR

AIR

S U M A

ANC 2

ANY 2

FANU

ANY 1

ANY 1

ANY 2

TRE 1 2 3 4

5 678

ANC 1

a b ANC 2 9 TRE

10 11 12

AIR

AIR

Both ANCs are set to the same sector number

Empty Space TRE12 FANU

TRE11

TRE10 FANU AIR

TRE9 FANU

TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

Figure 102: Outdoor MEDI - 1x9...12 Configuration

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2.9.1.14 Outdoor CPT2 - 2x1...6 The following figure shows the rack layout of the Outdoor CPT2 - 2x1...6 configuration for GSM 900 and GSM 1800.

Note:

Restrictions For the GSM 1800 configuration using TRAD/TRADE TREs, the following restriction has to be considered: 2x5...6 with 45 W at + 40 C. Configurations up to 2x1...4 without restrictions: 45 W at + 45 C. The BTS has 2 sectors:

AIR

ACSU

TRE5

TRE6

TRE6

TRE5

ADAM

− Sector 1 with n TREs − Sector 2 with p TREs a

PM1 2

PM1 2

PM1 2

ANY1

b

ANC1

ANC1 (Sector 1) FANU

FANU

TRE 1 2

AIR

SUMA

IDU1

IDU2

ANY1

FANU

AIR

ANY2

ANC2 (Sector 2)

3 4 5 6

a b ANC2 ANY2

TRE4 FANU

TRE3

TRE1

TRE2 FANU

AIR TRE 1 2

FANU

In each sector, if no more than 4 TREs, no ANY is required. TRE 1 to 4 are then cabled on ANC

BBU TRE4 FANU LPFU

3 4 5 6

TRE3

TRE2 FANU AIR

TRE1

Empty space

FANU Microwave IDU locations

Figure 103: Outdoor CPT2 - 2x1...6 Configuration

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2.9.1.15 Outdoor MEDI - 2x1...6 The following figure shows the rack layouts of the Outdoor MEDI - 2x1...6 configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 2x6 with 28 W at + 40 C. Configurations up to 2x1...5 without restrictions: 45 W at + 45 C. AIR TRE6

TRE5

TRE6

TRE5

OPTIONS

FANU

FANU

FANU

AIR

SUM ANY3 ANY1

ANY2

ANX (Sector 1)

AIR

TRE4

ANX (Sector 2) Empty space, no dummy panels needed

AIR

TRE3

FANU

ANY2

ANY3 ANY1

For each sector, TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector (No ANY)

TRE2 FANU

TRE1 FANU

TRE4

TRE3

FANU

TRE2 FANU

AIR

TRE1 FANU

AIR

AIR

AIR TRE6

TRE5

TRE6

TRE5

The BTS has 2 sectors : − Sector 1 with n TREs − Sector 2 with p TREs a b ANC1

FANU

FANU

FANU

FANU

FANU

AIR

FANU ANY1

AIR TRE

SUMA

ANY2

ANY1

ANC1 (Sector 1)

ANY4

AIR

ANY3

ANC2 (Sector 2)

1 2 3 4

a b ANC2 ANY3

AIR

ANY2 56

TRE 1 2 3 4

ANY4 56

In each sector, if no more than 4 TREs, no ANY is required. TRE1 to TRE4 are then cabled on ANC TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Empty Space

AIR

Figure 104: Outdoor MEDI - 2x1...6 Configuration

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2 Configurations - Rack Layouts

2.9.1.16 Outdoor CPT2 - 3x1...4 The following figure shows the rack layout of the Outdoor CPT2 - 3x1...4 configuration.

Note:

Restrictions For the GSM 1800 configuration using TRAD/TRADE TREs, the following restrictions have to be considered: 3x4 with 45 W at + 40 C. Configurations up to 3x1...3 without restrictions: 45 W at + 45 C. For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 3x4 with 28 W at + 40 C. Configurations up to 3x1...3 without restrictions: 45 W at + 45 C. AIR

ACSU TRE4

TRE3

TRE4

TRE3

ADAM

PM1 2

PM1 2

IDU2

PM1 2

ANC1 (Sector 1) FANU

FANU

The BTS has 3 sectors: − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

FANU

AIR

a

AIR ANC3 (Sector 3)

IDU1

SUMA

FANU

TRE3

TRE2 FANU

TRE1

a

b

ANC2

a

b

ANC3

ANC2 (Sector 2) TRE

TRE4

b

ANC1

1 2 3 4

1 2 3 4

1 2 3 4

AIR

FANU Empty space

BBU

Microwave IDU locations TRE2 FANU

LPFU

TRE1

TRE2 FANU

TRE1 FANU

AIR

Figure 105: Outdoor CPT2 - 3x1...4 Configuration

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2.9.1.17 Outdoor MEDI - 3x1...4 The following figure shows the rack layouts of the Outdoor MEDI - 3x1...4 configuration. (The ANX version is only valid for GSM 900/1800).

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 3x4 with 28 W at + 40 C. Configurations up to 3x1...3 without restrictions: 45 W at + 45 C. AIR TRE4

TRE4

TRE3

TRE3

OPTIONS

FANU

FANU

FANU

For each sector, TRE1 and TRE2 are connected to ANX if 2 TREs max. (no ANY)

AIR

ANY1 SUM

ANX (Sector 1)

ANX (Sector 3)

ANY3

ANY2

ANX (Sector 2) Empty space, no dummy panels needed

AIR

TRE4

AIR

TRE3

FANU

TRE2 FANU AIR

TRE1 FANU

TRE2

TRE1 FANU AIR

TRE1 FANU

AIR

AIR TRE4

FANU

TRE2

FANU

FANU AIR

TRE3

FANU

ANC1 (Sector 1)

SUMA

TRE4

TRE3

FANU

TRE4

FANU AIR

ANC3 (Sector 3)

TRE3

FANU

The BTS has 3 sectors: − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

a b ANC1

a b ANC2

a b ANC3

ANC2 (Sector 2) TRE 1 2 3 4

AIR

1 2 3 4

1 2 3 4

AIR Empty Space

TRE2 FANU

FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

Figure 106: Outdoor MEDI - 3x1...4 Configuration

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2.9.1.18 Outdoor MEDI - 3x1...4 GSM 1900 The following figure shows the rack layout of the Outdoor MEDI - 3x1...4 GSM 1900 configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 3x4 with 28 W at + 40 C Configurations up to 3x1...3 without restrictions: 45 W at + 45 C. AIR

AIR TRE4

TRE3

TRE4

TRE3 The BTS has 3 sectors: − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

FANU AIR

SUMA

ANY1

ANX1 (Sector 1)

ANY3

FANU AIR

ANX3 (Sector 3)

FANU

a

b

ANY2

ANX2 (Sector 2)

TRE4 FANU

TRE3

AIR

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

a

b ANX3

ANY2

ANY3

1 2 3 4

1 2 3 4

For each sector: ANY is required if more than 2 TREs Pre−equipment possible

TRE2 FANU AIR

b ANX2

ANY1 TRE1 2 3 4

AIR

a

ANX1

TRE1

Empty space

FANU

Figure 107: Outdoor MEDI - 3x1...4 GSM 1900 Configuration

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2 Configurations - Rack Layouts

2.9.2 Outdoor Configurations - Low Losses GSM 900/1800/1900 2.9.2.1 Outdoor MEDI - 1x3...8 Low Losses The following figure shows the rack layouts of the Outdoor MEDI - 1x3...8 Low Losses configuration. AIR TRE6

TRE5

OPTIONS The BTS has one sector with n TREs

FANU

SUM

ANY1

FANU AIR

ANX1

FANU

ANY2

ANX1 and ANX2 are set to the same sector number

ANX2

AIR

AIR

Extension from 1x6 to 1x8 Empty space, no dummy panels needed TRE8

TRE7

FANU

TRE2 FANU AIR

TRE1 FANU

TRE4 FANU

FANU AIR

AIR

TRE3 FANU

AIR

The BTS has 1 sector with n TREs

a b ANC1 AIR

a b ANC2

AIR TRE 1 2 3 4 ANC1

SUMA

ANC2

AIR

TRE 5 6 7 8

Both ANCs are set to the same sector number (Remote Inventory) Empty Space

AIR

In case of 1x3...4:

TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

TRE8 FANU

TRE7

TRE6 FANU

TRE5

On each ANC, the two bridges will be removed at installation (on site), if no more than 2 TREs are connected to them

FANU

AIR

Figure 108: Outdoor MEDI - 1x3...8 - Low Losses Configuration

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2 Configurations - Rack Layouts

2.9.2.2 Outdoor MEDI - 1x9...12 Low Losses The following figure shows the rack layout of the Outdoor MEDI - 1x9...12 Low Losses configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 1x11...12 with 28 W at + 40 C. Configurations up to 1x1...10 without restrictions: 45 W at + 45 C. AIR

AIR TRE4

TRE3

TRE12

TRE11

TRE10

TRE9

The BTS has 1 sector with n TREs FANU

FANU AIR

SUMA

FANU

FANU

ANC1

ANC3

FANU AIR

FANU

a

b ANC1

AIR

AIR

TRE2 FANU AIR

TRE1 FANU

TRE8 FANU

b ANC2

a

b ANC3

ANC2 TRE1 2 3 4

FANU

a

TRE7

7 8 11 12

The 3 ANCs are set to the same sector number

TRE6 FANU AIR

5 6 9 10

TRE5

Empty space

FANU

Figure 109: Outdoor MEDI - 1x9...12 - Low Losses Configuration

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2 Configurations - Rack Layouts

2.9.2.3 Outdoor MEDI - 2x3...6 Low Losses The following figure shows the rack layouts of the Outdoor MEDI - 2x3...6 Low Losses configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 2x6 with 28 W at + 40 C. Configurations up to 2x3...5 without restrictions: 45 W at + 45 C. AIR TRE5

TRE6

TRE6

TRE5

The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs

OPTIONS

FANU

FANU

FANU

AIR

ANX4 (Sector 2)

SUM

ANX1 (Sector 1)

ANX3 (Sector 2)

ANY

TRE1

TRE2 FANU AIR

ANX2 (Sector 1)

TRE1 FANU

TRE4 FANU

TRE3

TRE4 FANU AIR

TRE6

Empty space, no dummy panels needed

TRE3 FANU

The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs

AIR

AIR

− When no ANY, TREs 3 and 4 are directly connected to ANX

Extension from 2x4 to 2x6

AIR

AIR

TRE2 FANU

ANY

In each sector: − Both ANXs are set to the same sector number

TRE5

TRE6

TRE5 a b ANC1 TRE 1 2 5 6

FANU

FANU AIR

FANU

FANU

(Sector 1) ANC4

SUMA

FANU AIR

ANC3

a b ANC2 ANC2

AIR

3 4

FANU

(Sector 2) ANC1

a b ANC4

TRE 1 2 5 6

a b ANC3 3 4

In each sector, both ANCs are set to the same sector number

AIR

Extension from 2x4 to 2x6 Empty Space TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

TRE4 FANU

TRE3 FANU AIR

TRE2

TRE1 FANU

On each ANC, the two bridges will be removed at installation (on site), if no more than 2 TREs are connected to them

Figure 110: Outdoor MEDI - 2x3...6 - Low Losses Configuration

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2 Configurations - Rack Layouts

2.9.2.4 Outdoor MEDI - 3x3...4 Low Losses The following figure shows the rack layout of the Outdoor MEDI - 3x3...4 Low Losses configuration.

Note:

Restrictions For the GSM 1900 configuration using TRAP TREs, the following restrictions have to be considered: 3x4 with 28 W at + 40 C. Configuration 3x3 without restrictions: 45 W at + 45 C. AIR

AIR TRE4

TRE3

FANU

ANC6 (Sector 3)

FANU AIR

FANU

TRE2

TRE1

FANU

ANC5 (Sector 3)

FANU AIR

The BTS has 3 sectors: − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs Sector 1

Sector 2

a

a

FANU

b ANC1

12

TRE 1 2 ANC4 (Sector 1)

SUMA

ANC1 (Sector 1)

ANC3 (Sector 2)

ANC2 (Sector 2)

AIR

a

b ANC4

TRE 3

AIR

b ANC2

4

a

a b ANC5 12

b ANC3 3

Sector 3

4

a

b ANC6 3

4

On each ANC, bridges are removed at installation (on site), if no more than 2 TREs are connected to them

TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

AIR

TRE1 FANU

Per sector, both ANCs are set to the same sector number Empty Space

Figure 111: Outdoor MEDI - 3x3...4 - Low Losses Configuration

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2 Configurations - Rack Layouts

2.9.3 Outdoor Configurations - High Power GSM 1800 2.9.3.1 Outdoor MINI - 1x1...4 The following figure shows the rack layouts of the Outdoor MINI - 1x1...4 High Power GSM 1800 configuration. The BTS has 1 sector

AIR TRE4

a b ANC1 TRE 1 2 3 4

FANU

FANU AIR

FANU

On each ANC, bridges are removed at installation (on site), if no more than 2 TREs are connected to them

Empty space

SUMA

ANC1

With classical HP TREs AIR

AIR TRE4

FANU

TRE3 FANU

TRE2 FANU

TRE1 FANU

FANU AIR

FANU

SUMA ANC1

AIR AIR

TRE3 FANU

TRE2

TRE1

FANU AIR

FANU

Figure 112: Outdoor MINI - 1x1...4 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.9.3.2 Outdoor MINI - 2x1 The following figure shows the rack layouts of the Outdoor MINI - 2x1 - High Power GSM 1800 configuration.

OPTIONS

The BTS has 2 sectors: Sector 1 with 1 TRE Sector 2 with 1 TRE SUM

ANX2 (Sector 2)

ANX1 (Sector 1) Empty space, no dummy panels needed AIR

TRDH TRE1 FANU

FANU

TRDH TRE1 FANU

AIR AIR

The BTS has 2 sectors with 1 TRE each

a

AIR ANC2

SUMA

(Sector 2)

ANC1 (Sector 1)

b ANC1

TRE 1 Sector 1

a b ANC2 TRE 1 Sector 2

AIR

Empty space

TRE1 FANU

FANU

TRE1 FANU

On each ANC, t he two bridges are removed at installation (on site), if no more than 2 TREs are connected to them

AIR

Figure 113: Outdoor MINI - 2x1 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.9.3.3 Outdoor MINI - 2x1...2 The following figure shows the rack layouts of the Outdoor MINI - 2x1...2 High Power GSM 1800 configuration. The BTS has 2 sectors with up to 2 TREs each

AIR

a

TRE2

a

b ANC1

1 2

TRE

FANU

TRE

Sector 1

FANU

FANU

b ANC2

1 2 Sector 2

AIR On each ANC, bridges will be removed at installation (on site).

ANC2 (Sector 2)

SUMA

ANC1 (Sector 1)

Empty space

With classical HP TREs

AIR

AIR TRE2 TRE1 FANU

TRE2 FANU

TRE1 FANU

FANU

FANU AIR

FANU

AIR ANC2 (Sector 2)

SUMA

ANC1 (Sector 1)

AIR

TRE1

TRE2

TRE1

FANU

FANU AIR

FANU

Figure 114: Outdoor MINI - 2x1...2 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.9.3.4 Outdoor MEDI - 2x1...2 This configuration must be considered as a sub-equipment of the Outdoor MEDI - 3x1...2 - High Power GSM 1800 configuration. Configuration replaced by MINI configuration.

2.9.3.5 Outdoor MEDI - 2x1...4 The following figure shows the rack layouts of the Outdoor MEDI - 2x1...4 High Power GSM 1800 configuration.

Note:

Restrictions For the GSM 1800 configuration using TADH TREs, the ambient temperature is + 38 C.

AIR

AIR

TRE4

TRE4 The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs FANU

FANU

FANU

FANU

FANU

FANU

AIR

AIR a

SUMA

ANC1 (Sector 1)

b ANC1

a b ANC2

ANC2 (Sector 2) 1 2 3 4

AIR

1 2 3 4

AIR On each ANC, the two bridges are removed at installation (on site),if no more than 2 TREs are connected to them

TRE3 FANU

TRE2 FANU

TRE1 FANU

TRE3

TRE2

FANU

AIR

TRE1 Empty slots No Dummy Panels

FANU

FANU AIR

With classical HP TREs AIR

AIR TRE4

TRE4

FANU

FANU AIR

FANU

FANU

FANU AIR

ANC1 (Sector 1)

SUMA

FANU

ANC2 (Sector 2)

AIR

AIR

TRE3

TRE2

TRE1

TRE3

TRE2

TRE1

FANU

FANU AIR

FANU

FANU

FANU AIR

FANU

Figure 115: Outdoor MEDI- 2x1...4 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.9.3.6 Outdoor CPT2 - 3x1...2 The following figure shows the rack layouts of the Outdoor CPT2 - 3x1...2 High Power GSM 1800 configuration.

Note:

Restrictions For the GSM 1800 configuration using TADH TREs, the ambient temperature is + 40 C. TRE2

ADAM P M 1 2

P M 1 2

The BTS has 3 sectors: − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

AIR

ACSU

P M 1 2

IDU 2

ANC 1 (Sector 1) a FANU

FANU AIR

FANU

a

b

a

b

b

ANC 1

ANC 2

ANC 3

1 2

1 2

1 2

AIR

ANC 3 (Sector 3)

TRE2

S U M A

IDU 1

ANC 2 (Sector 2)

On each ANC: Bridges will be removed at installation time, on site

TRE1 AIR

FANU

FANU

FANU

Empty space BBU

FANU LPFU

Microwave IDU locations

TRE1

TRE2

TRE1 FANU AIR

FANU

With classical HP TREs AIR

ACSU TRE2

ADAM P M 1 2

P M 1 2

P M 1 2

IDU 2

ANC 1 (Sector 1) FANU

FANU AIR

FANU

AIR ANC 3 (Sector 3)

FANU

TRE2

TRE1

FANU

FANU

BBU

IDU 1

S U M A

ANC 2 (Sector 2)

AIR

TRE1

TRE2

TRE1

FANU

FANU AIR

FANU

LPFU

Figure 116: Outdoor CPT2 - 3x1...2 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.9.3.7 Outdoor MEDI - 3x1...2 The following figure shows the rack layouts of the Outdoor MEDI - 3x1...2 High Power GSM 1800 configuration. With classical HP TREs

AIR

AIR

AIR

TRE2

TRE2 OPTIONS

FANU

FANU

FANU

FANU

SUM

ANX 1

ANX 3

ANX 2

(Sector 1)

(Sector 3)

(Sector 2)

FANU

TRE2

TRE1

FANU AIR

FANU

TRE1

TRE2

FANU

FANU

ANC 1 ( Sector 1 )

ANC 2 ( Sector 2 )

ANC 3 ( Sector 3 )

AIR

AIR

TRE1 FANU

FANU

a

S U M A

AIR

AIR

FANU AIR

AIR

AIR

FANU

AIR

TRE2

TRE1

FANU AIR

FANU

1

TRE1

TRE2

TRE1

FANU

FANU AIR

FANU

AIR

AIR

Empty space, no dummy panels needed

TRE2

FANU AIR

S U M A

ANC 1 ( Sector 1 )

FANU AIR

FANU

ANC 2 ( Sector 2 )

ANC 3 ( Sector 3 )

AIR

AIR

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

a b ANC 1

1 2

a b ANC 2

1 2

a b ANC 3

1 2

Empty space, no dummy panels needed

TRE2 FANU

FANU AIR

TRE1 FANU

TRE1 FANU

TRE2 FANU AIR

TRE1 FANU

On each ANC: The two bridges will be removed at installation time (On site)

Figure 117: Outdoor MEDI - 3x1...2 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.9.3.8 Outdoor MEDI - 3x1...3 The following figure shows the rack layouts of the Outdoor MEDI - 3x1...3 - High Power GSM 1800 configuration. The configuration is based on the 3x1...2 High Power GSM 1800 configuration, extended with Medium Power TREs. AIR

AIR TRE2 (HP)

TRE3 (MP)

FANU AIR

FANU

TRE3 (MP)

FANU

The BTS has 3 sectors − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

a b ANC 1

a b ANC 2

a b ANC 3

nc 1 2 3 HP MP

nc 1 2 3 HP MP

nc 1 2 3 HP MP

AIR

S U M A

ANC 1 (Sector 1)

ANC 3 (Sector 3)

ANC 2 (Sector 2)

AIR

On each ANC: "The bridge, where the TRE MP is connected, is removed on site"

AIR

Empty slots. No Dummy Panels (MP) TRE3 FANU

(HP) TRE2 FANU AIR

(HP) TRE1 FANU

(HP) TRE2

(HP) TRE1 FANU

FANU AIR

(HP) TRE1 FANU

With classical HP TREs AIR

AIR TRE3 (MP)

TRE2 (HP)

FANU AIR S U M A

ANC 1 (Sector 1)

ANC 3 (Sector 3)

AIR

(MP) TRE3 FANU

FANU AIR

TRE3 (MP)

FANU

ANC 2 (Sector 2) AIR

(HP) TRE2

(HP) TRE1

FANU AIR

FANU

(HP) TRE1 FANU

(HP) TRE2

(HP) TRE1

FANU AIR

FANU

Figure 118: Outdoor MEDI - 3x1...3 - High Power GSM 1800 Configuration

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2 Configurations - Rack Layouts

2.9.4 Outdoor Configurations - Multiband BTS GSM 900/1800 2.9.4.1 Outdoor MINI - 1x1...2/1x1...2 The following figure shows the rack layouts of the Outdoor MINI - 1x1...2/1x1...2 - Multiband BTS configuration. OPTIONS

SUM

ANX (Sector 2)

ANX (Sector 1)

Sector 1 has n TREs Sector 2 has p TREs Empty space, no dummy panels needed

AIR

GSM 1800

TRE2

TRE1

FANU

TRE2 FANU AIR

TRE1 FANU

AIR The BTS has 2 sectors : − Sector 1 with n TREs − Sector 2 with p TREs

a b ANC 1

AIR ANC 2 ( Sector 2 )

S U M A

ANC 1 ( Sector 1 )

TRE 1 2 Sector 1

a b ANC 2 TRE 1 2 Sector 2

On the 2 ANCs the bridges can be removed to get more power at antenna output (Low Losses) (Operation to be performed during installation phase)

AIR

GSM 1800 Empty space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

Figure 119: Outdoor MINI - 1x1...2/1x1...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.2 Outdoor MINI - 1x1...4/1x1...4 The following figure shows the rack layout of the Outdoor MINI - 1x1...4/1x1...4 - Multiband BTS configuration. AIR TRE4

TRE3

FANU

TRE4

TRE3

FANU FANU AIR

ANC 2 ( Sector 2 )

S U M A

The BTS has 2 sectors : − Sector 1 with n TREs − Sector 2 with p TREs

a b ANC 1

ANC 1 ( Sector 1 )

TRE 1 2 3 4 Sector 1

a b ANC 2 TRE 1 2 3 4 Sector 2

AIR GSM 1800 Empty space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

Figure 120: Outdoor MINI - 1x1...4/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.3 Outdoor MEDI - 1x1...6/1x1...6 The following figure shows the rack layouts of the Outdoor MEDI 1x1...6/1x1...6 - Multiband BTS configuration. AIR TRE6

TRE5

TRE6

TRE5

OPTIONS

For each sector : FANU

SUM

ANY ANY 3 1

ANY 2

ANX (Sector 1)

FANU AIR

ANY ANY 3 1

ANY 2

FANU

ANX (Sector 2)

TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector (no ANY) Empty space, no dummy panels needed GSM 1800

AIR

TRE4

AIR

TRE3

FANU

TRE2 FANU AIR

TRE1 FANU

TRE4

TRE3

FANU

TRE2 FANU AIR

TRE1 FANU

AIR

AIR TRE6

TRE5

TRE6

TRE5

The BTS has 2 sectors : − Sector 1 with n TREs − Sector 2 with p TREs a b ANC 1

FANU

S U M A

FANU AIR

ANY 2

FANU

ANY 1

FANU

ANC 1 ( Sector 1 )

FANU AIR

ANY 4

FANU

ANY 1 TRE 1 2 3 4

ANY 3

ANC 2 ( Sector 2 )

56

a b ANC 2 ANY 3

AIR

AIR

ANY 2

TRE 1 2 3 4

ANY 4 56

In each sector : If no more than 4 TREs, no ANY is required, TRE1 to TRE4 are then cabled on ANC

TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

Empty Space GSM 1800

Figure 121: Outdoor MEDI - 1x1...6/1x1...6 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.4 Outdoor MEDI - 1x1...4/2x1...4 The following figure shows the rack layouts of the Outdoor MEDI 1x1...4/2x1...4 - Multiband BTS configuration. AIR TRE4

TRE3

TRE4

TRE3

OPTIONS

FANU

ANY 1

SUM

ANX (Sector 1)

ANY 3

FANU AIR

ANX (Sector 3)

FANU

For each sector : TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector (no ANY)

ANY 2

ANX (Sector 2)

Empty space, no dummy panels needed GSM 1800

AIR

AIR

TRE4

TRE3

FANU

TRE2 FANU AIR

TRE1 FANU

TRE2

TRE2 FANU AIR

TRE1 FANU

AIR

AIR TRE4

FANU

TRE1

FANU

FANU AIR

TRE3

FANU

S U M A

( Sector 1 ) ANC 1

TRE4

TRE3

FANU

TRE4

FANU AIR

TRE3

FANU a b ANC 1

( Sector 3 ) ANC 3

( Sector 2 ) ANC 2

AIR

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

TRE 1 2 3 4

a b ANC 2

1 2 3 4

a b ANC 3

1 2 3 4

AIR GSM 1800 Empty Space TRE2

FANU

FANU AIR

TRE1 FANU

TRE2 FANU

TRE1 FANU AIR

TRE2

TRE1 FANU

Figure 122: Outdoor MEDI - 1x1...4/2x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.5 Outdoor MEDI - 2x1...4/1x1...4 The following figure shows the rack layouts of the Outdoor MEDI 2x1...4/1x1...4 - Multiband BTS configuration. AIR TRE3

TRE4

TRE4

TRE3

OPTIONS

For each sector: FANU

ANY 1

SUM

ANX (Sector 1)

ANY 3

FANU AIR

ANX (Sector 3)

ANY 2

AIR

TRE4 FANU

TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector (no ANY) Empty space, no dummy panels needed

ANX (Sector 2)

GSM 1800

AIR

TRE3

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2

TRE1 FANU

TRE4

TRE3

FANU AIR

AIR

AIR

AIR TRE4

FANU

FANU

FANU AIR

TRE3

FANU

S U M A

( Sector 1 ) ANC 1

TRE4

TRE3

FANU

FANU AIR

( Sector 3 ) ANC 3

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

FANU a b ANC 1 ( Sector 2 ) ANC 2

a b ANC 2

TRE 1 2 3 4

1 2 3 4

a b ANC 3

1 2 3 4

AIR

AIR

Empty Space GSM 1800 TRE2 FANU

FANU AIR

TRE1 FANU

TRE2 FANU

TRE1 FANU AIR

TRE2

TRE1 FANU

Figure 123: Outdoor MEDI - 2x1...4/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.6 Outdoor CPT2 - 2x1...2/2x1...2 The following figure shows the rack layout of the Outdoor CPT2 - 2x1...2/2x1...2 - Multiband BTS configuration. AIR

ACSU

TRE2

Legend

TRE1

ADAM P M 1 2

P M 1 2

P M 1 2

IDU 2

ANC 1 (Sector 1) FANU

FANU AIR

FANU a b ANC 1

AIR ANC 3 (Sector 3) TRE2 FANU

The BTS has 4 sectors: − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

ANC 4 (Sector 4)

FANU

IDU 1

TRE1

S U M A

a b ANC 2

a b ANC 3

1 2

1 2

ANC 2 (Sector 2) TRE 1 2

AIR

FANU GSM 1800

BBU

Empty space TRE2 FANU

LPFU

a b ANC 4

TRE2

TRE1 FANU AIR

1 2

TRE1 FANU

Microwave IDU locations

Figure 124: Outdoor CPT2 - 2x1...2/2x1...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.7 Outdoor MEDI - 1x1...4/...4,...2,...2 The following figure shows the rack layouts of the Outdoor MEDI 1x1...4/...4,...2,...2 - Multiband BTS configuration. AIR TRE4

TRE3

TRE4

TRE3

OPTIONS

FANU

SUM

ANX (Sector 4)

ANX (Sector 1)

ANY

FANU AIR

ANX (Sector 3)

FANU

ANY

AIR

ANX (Sector 2) Empty space, no dummy panels needed

AIR

GSM 1800

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE4

TRE3

AIR

TRE1 FANU

TRE4

TRE3

AIR

FANU

FANU AIR

AIR

( Sector 4 ) ANC 4

TRE2 FANU AIR

S U M A

( Sector 1 ) ANC 1

( Sector 3 ) ANC 3

The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

FANU a b ANC 1 ( Sector 2 ) ANC 2

TRE 1 2

a b ANC 2

1 2 3 4

a b ANC 3

1 2 3 4

AIR

AIR

a b ANC 4 GSM 1800 Empty Space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1 FANU AIR

TRE2

TRE1 FANU

1 2

Figure 125: Outdoor MEDI - 1x1...4/...4,...2,...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.8 Outdoor MEDI - ...4,...2,...2/1x1...4 The following figure shows the rack layouts of the Outdoor MEDI ...4,...2,...2/1x1...4 - Multiband BTS configuration. AIR TRE4

TRE3

TRE4

TRE3

OPTIONS

FANU

SUM

ANX (Sector 4)

ANX (Sector 1)

ANY

FANU AIR

ANX (Sector 3)

FANU

ANY

ANX (Sector 2) Empty slots no dummy panels needed

AIR

AIR

GSM 1800

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE4

TRE3

TRE1 FANU

TRE4

TRE3

AIR

AIR

FANU

FANU

S U M A

( Sector 1 ) ANC 1

( Sector 3 ) ANC 3

a b ANC 1 ( Sector 2 ) ANC 2

AIR

The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

FANU

AIR

AIR

( Sector 4 ) ANC 4

TRE2 FANU AIR

TRE 1 2

a

b ANC 2

1 2 3 4

a b ANC 3

1 2 3 4

AIR a b ANC 4 GSM 1800 Empty Space

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

1 2

Figure 126: Outdoor MEDI - ...4,...2,...2/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.9 Outdoor MEDI - 2x1...4/2x1...2 The following figure shows the rack layouts of the Outdoor MEDI 2x1...4/2x1...2 - Multiband BTS configuration. AIR TRE4

TRE3

TRE4

TRE3

OPTIONS

FANU

SUM

ANX (Sector 4)

ANX

ANY

(Sector 1)

FANU AIR

ANX

FANU

ANY

(Sector 3)

ANX (Sector 2)

AIR

Empty space, no dummy panels needed

AIR

GSM 1800

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE4

TRE3

TRE1 FANU

TRE4

TRE3

AIR

AIR

FANU

FANU AIR

AIR

( Sector 4 ) ANC 4

TRE2 FANU AIR

S U M A

( Sector 1 ) ANC 1

( Sector 3 ) ANC 3

AIR

The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

FANU a b ANC 1 ( Sector 2 ) ANC 2

TRE 1 2

a b ANC 2

1 23 4

a b ANC 3

1 23 4

AIR a b ANC 4 GSM 1800 Empty Space

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1 FANU AIR

TRE2

TRE1 FANU

1 2

Figure 127: Outdoor MEDI - 2x1...4/2x1...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.10 Outdoor MEDI - 2x1...2/2x1...4 The following figure shows the rack layouts of the Outdoor MEDI 2x1...2/2x1...4 - Multiband BTS configuration. AIR TRE4

TRE3

TRE4

TRE3

OPTIONS

FANU

ANX (Sector 4)

SUM

ANX (Sector 1)

FANU AIR

ANX (Sector 3)

ANY

FANU

ANY

AIR

ANX (Sector 2) Empty space, no dummy panels needed

AIR

GSM 1800

TRE2

TRE1

FANU

TRE2 FANU AIR

TRE1 FANU

TRE2

TRE1

FANU

AIR

TRE1 FANU

AIR TRE4

TRE3

FANU

S U M A

( Sector 1 ) ANC 1

TRE4

FANU AIR

AIR

( Sector 4 ) ANC 4

TRE2 FANU AIR

( Sector 3 ) ANC 3

AIR

TRE3

The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

FANU a b ANC 1 ( Sector 2 ) ANC 2

TRE 1 2

a b ANC 2

1 2 3 4

a b ANC 3

1 2 3 4

AIR a b ANC 4 Empty Space GSM 1800

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1 FANU AIR

TRE2

TRE1 FANU

1 2

Figure 128: Outdoor MEDI - 2x1...2/2x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.4.11 Outdoor MEDI - 2x1...3/2x1...3 The following figure shows the rack layout of the Outdoor MEDI - 2x1...3/2x1...3 - Multiband BTS configuration. AIR

AIR

TRE3

FANU

TRE3

FANU

FANU

( Sector 1 ) ANC 1

( Sector 3 ) ANC 3

FANU AIR

( Sector 4 ) ANC 4

S U M A

TRE3

TRE3

FANU AIR

FANU

( Sector 2 ) ANC 2

The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

a b ANC 1

TRE 1 2 3

a b ANC 2

1 2 3

1 23 a b ANC 4

AIR

AIR

a b ANC 3

1 2 3 TRE2

TRE1

FANU

TRE2

TRE1

FANU AIR

FANU

TRE2 FANU

TRE1

TRE2

FANU AIR

TRE1

GSM 1800

FANU

Empty Space

Figure 129: Outdoor MEDI - 2x1...3/2x1...3 - Multiband BTS Configuration

2.9.4.12 Outdoor MEDI - 3x1...2/3x1...2 The following figure shows the rack layout of the Outdoor MEDI - 3x1...2/3x1...2 - Multiband BTS configuration. AIR TRE2

AIR

TRE1

TRE2

TRE1

ANC 6 ( Sector 6 )

FANU

FANU

FANU

ANC 5 ( Sector 5 )

FANU

FANU

AIR ANC 4 ( Sector 4 )

S U M A

FANU

AIR ANC 1 ( Sector 1 )

ANC 3 ( Sector 3 )

ANC 2 ( Sector 2 )

AIR

The BTS has 6 sectors. − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs − Sector 5 with s TREs − Sector 6 with t TREs a b ANC 1

a b ANC 2

a b ANC 3

1 2

1 2

1 2

a b ANC 4

a b ANC 5

a b ANC 6

1 2

1 2

1 2

AIR

GSM 900 GSM 1800 TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

Empty space

Figure 130: Outdoor MEDI - 3x1...2/3x1...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.9.5 Outdoor Configurations - Multiband Cells GSM 900/1800 2.9.5.1 Outdoor MINI - 1x(...2/...2) The following figure shows the rack layouts of the Outdoor MINI - 1x(...2/...2) Multiband Cells configuration. OPTIONS

The single sector has : n TREs in the GSM 900 band p TREs in the GSM 1800 band ANX 1 and ANX 2 are set to the same sector number SUM

ANX 2

ANX 1

Empty space, no dummy panels needed GSM 1800

AIR

TRE2

TRE1

FANU

TRE2 FANU AIR

TRE1 FANU

AIR The single sector has : n TREs in the GSM 900 band p TREs in the GSM 1800 band

a b ANC 1

AIR

TRE 1 2 S U M A

ANC 2

a b ANC 2 TRE 1 2

ANC 1 On the 2 ANCs the bridges can be removed to get more power at the antenna output (Low Loss) (Operation to be performed during installation phase)

AIR

Empty space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

GSM 1800

Figure 131: Outdoor MINI - 1x(...2/...2) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.9.5.2 Outdoor MINI - 1x(...4/...4) The following figure shows the rack layout of the Outdoor MINI - 1x(...4/...4) Multiband Cells configuration. AIR TRE4

TRE3

FANU

TRE4

FANU

TRE3

FANU AIR

S U M A

ANC 2

The single sector has : n TREs in the GSM 900 band p TREs in the GSM 1800 band

a b ANC 1 TRE 1 2 3 4

a b ANC 2 TRE 1 2 3 4

ANC 1

AIR

Empty space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

GSM 1800

Figure 132: Outdoor MINI - 1x(...4/...4) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.9.5.3 Outdoor MEDI - 1x(...6/...6) The following figure shows the rack layouts of the Outdoor MEDI - 1x(...6/...6) Multiband Cells configuration. AIR TRE6

TRE5

TRE6

TRE5

OPTIONS

The single sector has : n TREs in the GSM 1800 band p TREs in the GSM 900 band ANX 1 and ANX 2 are set to the same sector number

FANU

SUM

ANY ANY 3 1

ANY 2

ANX 1

FANU AIR

ANY ANY 3 1

AIR

FANU

ANY 2

ANX 2

For each frequency band : TRE1 and TRE2 are connected to ANX if 2 TREs max. in the sector (No ANY)

Empty space no dummy panels needed

AIR

GSM 1800

TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

TRE4 FANU

TRE3

TRE2

TRE1 FANU

TRE6

TRE5

FANU AIR

AIR

AIR TRE6

TRE5

The BTS has 1 sector with : − n TREs in the GSM 900 band − p TREs in the GSM 1800 band a b ANC 1

FANU

S U M A

FANU AIR

ANY 2

FANU

ANY 1

FANU

ANC 1

FANU AIR

ANY 4

FANU

ANY 1 TRE 1 2 3 4

ANY 3

ANC 2

56

a b ANC 2 ANY 3

AIR

AIR

ANY 2

TRE 1 2 3 4

ANY 4 56

In each sector : If no more than 4 TREs, no ANY is required, TRE1 to TRE4 are then cabled on ANC TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU AIR

TRE1 FANU

Empty Space GSM 1800

Figure 133: Outdoor MEDI - 1x(...6/...6) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.9.5.4 Outdoor CPT2 - 2x(...2/...2) The following figure shows the rack layout of the Outdoor CPT2 - 2x(...2/...2) Multiband Cells configuration. AIR

ACSU

TRE2

Legend

TRE1

ADAM P M 1 2

P M 1 2

P M 1 2

IDU 2

ANC 1 (Sector 1) FANU

FANU AIR

FANU a b ANC 1

AIR ANC 3 (Sector 1)

TRE2 FANU

The BTS has 2 sectors: − Sector 1 with n TREs in GSM 900 and r TREs in GSM 1800 − Sector 2 with p TREs in GSM 900 and q TREs in GSM 1800

ANC 4 (Sector 2)

FANU

IDU 1

S U M A

ANC 2 (Sector 2)

TRE 1 2

a b ANC 2

a b ANC 3

1 2

1 2

AIR

TRE1 FANU

GSM 1800

BBU

Empty space TRE2 FANU

LPFU

a b ANC 4

TRE1

TRE2 FANU AIR

TRE1 FANU

1 2 Microwave IDU locations

Figure 134: Outdoor CPT2 - 2x(...2/...2) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.9.5.5 Outdoor MEDI - 2x(...4/...2) The following figure shows the rack layouts of the Outdoor MEDI - 2x(...4/...2) Multiband Cells configuration. AIR TRE4

TRE3

TRE4

TRE3

Sector 1 has: n TREs in the GSM 1800 band p TREs in the GSM 900 band

OPTIONS Sector 2 has: q TREs in the GSM 900 band r TREs in the GSM 1800 band FANU

ANX 4 (Sector 2)

SUM

ANX 1 (Sector 1)

ANY

FANU AIR

ANX 3 (Sector 2)

FANU

ANY

AIR

ANX 2 (Sector 1)

ANX 1 and ANX 2 are set to the same sector number (1) ANX 3 and ANX4 are set to to the same sector number (2)

AIR Empty space no dummy panels needed GSM 1800

TRE2

TRE1

FANU

TRE2 FANU AIR

TRE1 FANU

TRE2

TRE1

FANU

TRE2 FANU AIR

TRE1 FANU

AIR

AIR TRE4

TRE3

TRE4

TRE3 The BTS has 2 sectors.

Sector 1 FANU

FANU AIR

AIR

a b ANC 1

FANU

TRE 1 2 ( Sector 2 ) ANC 4

S U M A

( Sector 1 ) ANC 1

( Sector 2 ) ANC 3

( Sector 1 ) ANC 2 Sector 2

AIR

a b ANC 3

TRE1

TRE2 FANU AIR

1 23 4

a b ANC 4

AIR 1 2 3 4

TRE2 FANU

a b ANC 2

TRE1 FANU

TRE2 FANU

TRE1 FANU AIR

TRE2

TRE1 FANU

1 2

Empty Space GSM 1800

Figure 135: Outdoor MEDI - 2x(...4/...2) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.9.5.6 Outdoor MEDI - 2x(...2/...4) The following figure shows the rack layouts of the Outdoor MEDI - 2x(...2/...4) Multiband Cells configuration. AIR TRE4

TRE3

TRE4

TRE3

Sector 1 has: n TREs in the GSM 900 band p TREs in the GSM 1800 band

OPTIONS Sector 2 has: q TREs in the GSM 1800 band r TREs in the GSM 900 band FANU

SUM

ANX 4 (Sector 2)

ANX 1 (Sector 1)

ANY

FANU AIR

ANX 3 (Sector 2)

FANU ANX 1 and ANX 2 are set to the same sector number (1)

ANY

ANX 2 (Sector 1)

ANX 3 and ANX4 are set to to the same sector number (2)

AIR

AIR

Empty space no dummy panels needed GSM 1800 TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE4

TRE3

TRE2

TRE1 FANU

TRE4

TRE3

FANU AIR

AIR

AIR The BTS has 2 sectors Sector 1

FANU

FANU AIR

AIR

a b ANC 1

FANU

TRE 1 2 ( Sector 2 ) ANC 4

S U M A

( Sector 1 ) ANC 1

( Sector 2 ) ANC 3

( Sector 1 ) ANC 2

AIR

a b ANC 2

1 2 3 4

Sector 2 a b ANC 3

a b ANC 4

AIR 1 2 3 4

1 2

Empty Space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

GSM 1800

Figure 136: Outdoor MEDI - 2x(...2/...4) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.9.5.7 Outdoor MEDI - 1x(...2/...2),1x(...4/...4) The following figure shows the rack layouts of the Outdoor MEDI 1x(...2/...2),1x(...4/...4) - Multiband Cells configuration. AIR TRE4

TRE3

TRE4

TRE3

Setor 1 has: n TREs in the GSM 900 band r TREs in the GSM 1800 band

OPTIONS Setor 2 has: p TREs in the GSM 900 band q TREs in the GSM 1800 band FANU

ANX 4 (Sector 1)

SUM

ANX 1 (Sector 1)

ANY

FANU AIR

ANX 3 (Sector 2)

FANU

ANY

ANX 2 (Sector 2)

ANX 1 and ANX 4 are set to the same sector number (1) ANX 2 and ANX3 are set to the same sector number (2)

AIR

AIR

Empty space no dummy panels needed GSM 1800

TRE2

TRE1

FANU

TRE2 FANU AIR

TRE1 FANU

TRE2

TRE1

FANU

TRE2 FANU AIR

TRE1 FANU

AIR

AIR TRE4

TRE3

TRE4

TRE3 The BTS has 2 sectors Sector 1

FANU

FANU AIR

AIR

a b ANC 1

FANU

TRE 1 2 ( Sector 1 ) ANC 4

S U M A

( Sector 1 ) ANC 1

( Sector 2 ) ANC 3

AIR

a b ANC 4

( Sector 2 ) ANC 2

1 2

Sector 2 a b ANC 3

a b ANC 2

AIR 1 2 3 4

1 2 3 4

Empty Space TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1 FANU AIR

TRE2

TRE1 FANU

GSM 1800

Figure 137: Outdoor MEDI - 1x(...2/...2),1x(...4/...4) - Multiband Cells Configuration

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2.9.5.8 Outdoor MEDI - 3x(...2/...2) The following figure shows the rack layout of the Outdoor MEDI - 3x(...2/...2) Multiband Cells configuration. AIR TRE2

AIR

TRE1

TRE2

The BTS has 3 sectors.

TRE1

ANC 6 ( Sector 3 )

FANU

FANU

ANC 5 ( Sector 3 )

FANU

FANU

ANC 1 ( Sector 1 )

ANC 3 ( Sector 2 )

FANU

AIR ANC 4 ( Sector 2 )

S U M A

FANU

AIR

Sector 1 : a b ANC 1

a b ANC 2

1 2

1 2

a b ANC 3

a b ANC 4

1 2

1 2

a b ANC 5

a b ANC 6

1 2

1 2

Sector 2 :

ANC 2 ( Sector 1 ) Sector 3 :

AIR

AIR

GSM 900 GSM 1800 TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU AIR

TRE1 FANU

Empty space

Figure 138: Outdoor MEDI - 3x(...2/...2) - Multiband Cells Configuration

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2.10 Outdoor Configurations with Twin TRX The following table gives the A9100 Compact BTS Outdoor TWIN TRX configurations. TWIN Mode

Number of sectors

AC with BU5

AC w/o BU5

DC

carriers per sector

carriers per sector

carriers per sector

1

4

4

6

2

2/2

2/2

3/3 or 4/2

3

-

2/1/1

2/2/2

Capacity Mode Low 1 Loss

4

4

6

2

-

-

3/3

Multiband & MB Cell

1

2 +2

2 +2

4+2

Coverage Mode TxDiv. 2Rx Div.

1

2

2

2

2

1/1

1/1

1/1

3

-

-

1/1/1

1 Coverage Mode TxDiv. 2Rx Div Low Loss

2

2

2

1 Coverage Mode TxDiv. 4Rx Div Low Loss

2

2

2

Capacity Mode

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2.10.1 Capacity Mode Configurations 2.10.1.1 CBO - 1 sector with Twin-TRX

2.10.1.2 CBO - 2 sectors with Twin-TRX

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2.10.1.3 CBO - 3 sectors with Twin-TRX

2.10.2 Capacity Mode Low Loss Configurations 2.10.2.1 CBO - 1 Sector Low Loss with Twin-TRX

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2.10.2.2 CBO - 2 Sectors Low Loss with Twin-TRX

2.10.3 Multiband Configurations - CBO - Multiband 1 + 1 Sector with Twin-TRX

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2 Configurations - Rack Layouts

2.10.4 Coverage Mode TX Diversity Configurations 2.10.4.1 CBO - 1 Sector TX Diversity 2RX with Twin-TRX

2.10.4.2 CBO - 2 Sectors TX Diversity 2RX with Twin-TRX

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2.10.4.3 CBO - 3 Sectors TX Diversity 2RX with Twin-TRX

2.10.5 Coverage Mode with TX Diversity Low Loss Configurations - CBO - 1 Sector TX Diversity Low Loss with Twin-TRX

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2.10.6 Coverage Mode TX-Diversity 4 RX Configurations - CBO - 1 Sector TX Diversity 4RX with Twin-TRX

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2 Configurations - Rack Layouts

2.11 Outdoor Configurations Based on Extension with Twin TRX The following table gives the possible configuration extension based on Twin TRX modules. Cabinet

Number of sectors

Carriesrs per sector Single TRX -> Twin TRX

CBO

CBO DC

1

2 -> 4

2

1/1 -> 2/2

1

n.a.

2

2/2 -> 3/3

3

1/1/1 -> 2/2/2

2.11.1 CBO 1 Sector mixed configuration Single/Twin-TRX

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2.11.2 CBO 2 Sectors mixed configuration Single/Twin-TRX

2.11.3 CBO DC 2 Sectors mixed configuration Single/Twin-TRX

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2.11.4 CBO DC 2 Sectors mixed configuration Single/Twin-TRX

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2 Configurations - Rack Layouts

2.12 Multistandard Base Station Outdoor Configurations 2.12.1 MBO Standard Configurations - GSM 850/900/1800/1900 GSM 850 is not supported by all BSS software releases. If you are in doubt, contact Alcatel support.

2.12.1.1 MBO1 - 1x1...8 The following figure shows the rack layout of the MBO1 - 1x1...8 configuration.

Note:

Restrictions For GSM 1900, the configuration is limited to six TREs.

123 123 123 123 123 123

ADAM4

P M 1 2

P M 1 2

The BTS has 1 sector with n TREs

P M 1 2

a

b

ANC 1

ANY 1 TRE8

TRE7

TRE6

ANY 2

TRE5 TRE 1 3 5 7

2 4 6 8

The ANC can be replaced by the ANB in case of less than 3TRE s

FANU

FANU

FANU

AIR

If more than 4 TREs, 2 ANY are required Pre−equipment possible

Up to 4 TREs, and if no ANY pre−equipment, the TRE1 to TRE4 are directly connected to the ANC

S U M A

ANY 2

ANY 1

ANC 1 Empty space Dummy panels if no modules installed

123

PM12 equipped if GSM 1900, or if n>6, otherwise: dummy panel is installed Available only on AC configuration

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 139: MBO1 - 1x1...8 Configuration

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2.12.1.2 MBO1 - 2x1...4 The following figure shows the rack layout of the MBO1 - 2x1...4 configuration.

Note:

Restrictions None. for GSM 850. For GSM 1900, the configuration is limited to six TREs over the two sectors.

1234 1234 1234 1234 1234 1234 1234

ADAM4

P M 1 2

P M 1 2

TRE4

P M 1 2

The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs

TRE3

TRE4

TRE3 a

b

a

ANC 1

TRE 1 3 2 4

TRE 1 3 2 4

Sector 1 FANU

FANU

S U M A

Sector 2

FANU The ANC can be replaced by the ANB in case of less than 3TRE s

AIR

ANC 2 (Sector 2)

b ANC 2

ANC 1 (Sector 1)

Empty space Dummy panels if no modules installed

123 123

PM12 equipped if GSM 1900, or if (n+p)>6, otherwise: dummy panel is installed Available only on AC configuration

TRE1

TRE2 FANU

TRE2 FANU

TRE1 FANU

Figure 140: MBO1 - 2x1...4 Configuration

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2.12.1.3 MBO1 - 3x1...2 The following figure shows the rack layout of the MBO1 - 3x1...2 configuration.

Note:

Restrictions None. for GSM 850.

123 123 123 123 123 123

ADAM4 P M 1 2

P M 1 2

TRE2

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

P M 1 2

a b ANC 1

a b ANC 2

a b ANC 3

TRE1 ANC 3 ( Sector 3 )

FANU

FANU

FANU AIR

ANC 2 ( Sector 2 )

S U M A

ANC 1

TRE 1 2 Sector 1

TRE 1 2 Sector 2

TRE 1 2 Sector 3

On each ANC: The bridges can be removed at installation time (on site), if maximum power is required The ANC can be replaced by the ANB in case of less than 3TRE s

( Sector 1 )

Empty space Dummy panels if no modules installed

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

12

PM12 equipped if GSM 1900, otherwise: dummy panel is installed Available only on AC configuration

Figure 141: MBO1 - 3x1...2 Configuration

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2.12.1.4 MBO2 - 1x9...12 The following figure shows the rack layout of the MBO2 - 1x9...12 configuration.

Note:

Restrictions None. for GSM 850.

123 123 123 123 123 123

ADAM4 P M 1 2

P M 1 2

TRE8

P M 1 2

The BTS has 1 sector with n TREs

P M 1 2

TRE6

TRE7

a b ANC 1

TRE5

ANY 1

ANY 2

TRE 1 3 5 7

2 468

a b ANC 2 9 FANU

S U M A

FANU AIR

ANY 2

TRE

FANU AIR

ANY 1

11 10 12

Both ANCs are set to the same sector number ANC 2

ANC 1

Empty space Dummy panels if no modules installed

123 123

PM12 equipped if GSM 1900 and if n>6. Otherwise: dummy panel is installed

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE12 FANU

TRE11

TRE10 FANU

TRE9 FANU

Figure 142: MBO2 - 1x9...12 Configuration

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2.12.1.5 MBO2 - 2x1...6 The following figure shows the rack layout of the MBO - 2x1...6 configuration. ADAM4 P M 1 2

P M 1 2

P M 1 2

1234 1234 1234 1234 1234 1234

The BTS has 2 sectors : − Sector 1 with n TREs − Sector 2 with p TREs

P M 1 2

TRE6

a b ANC 1

TRE5

TRE6

ANY 1

TRE5 TRE 1 3

2 456

a b ANC 2 FANU

FANU

FANU

FANU

FANU AIR

AIR

S U M A

ANY 1

ANC 1 ( Sector 1 )

FANU

ANY 2

AIR

ANC 2 ( Sector 2 )

ANY 2 TRE 1 3 2 4 5 6 In each sector : If no more than 4 TREs, no ANY is required. TREs 1 to TRE4 are then cabled on ANC The ANC can be replaced by the ANB in case of less than 3TRE s

AIR

Empty space Dummy panels if no modules installed

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

123 123

PM12 equipped if GSM 1900 and if (n+p)>6. Otherwise: dummy panel is installed Available only on AC configuration

Figure 143: MBO2 - 2x1...6 Configuration

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2 Configurations - Rack Layouts

2.12.1.6 MBO2 - 1x1...8 + 1x1...4 The following figure shows the rack layout of the MBO2 - 1x1...8 + 1x1...4 configuration.

Note:

Restrictions None. for GSM 850.

123 123 123 123 123 123

ADAM4 P M 1 2

P M 1 2

TRE8

P M 1 2

The BTS has 2 sectors with respectively n and p TREs

P M 1 2

TRE6

TRE7

a b ANC 1 ANY 1

ANY 2

TRE 1 3 5 7

2 468

TRE5

a b ANC 2 FANU

S U M A

FANU

FANU AIR

ANY 2

9

AIR

ANY 1

TRE

11 10 12

ANC 2 (Sector 2)

ANC 1 (Sector 1)

Empty space

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE12 FANU

TRE11

TRE10 FANU

TRE9 FANU

12 12

Dummy panels if no modules installed PM12 equipped if GSM 1900 and if (n+p)>6. Otherwise: dummy panel is installed

Figure 144: MBO2 - 1x1...8 + 1x1...4 Configuration

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2.12.1.7 MBO2 - 3x1...4 The following figure shows the rack layout of the MBO2 - 3x1...4 configuration. ADAM4 P M 1 2

P M 1 2

TRE2

P M 1 2

123 123 123 123 123 P M 1 2

The BTS has 3 sectors: − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

TRE1 ANC 3 (Sector 3)

FANU

FANU AIR

TRE4

TRE3 a b ANC 1

a b ANC 2

a b ANC 3

TRE 1 3 2 4

1 3 2 4

1 3 2 4

FANU AIR

S U M A

ANC 1 (Sector 1)

ANC 2 (Sector 2)

The ANC can be replaced by the ANB in case of less than 3TRE s

Empty space Dummy panels if no modules installed

123 123 TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

PM12 equipped if GSM 1900 and if (n+p+q)>6. Otherwise: dummy panel is installed Available only on AC configuration

Figure 145: MBO2 - 3x1...4 Configuration

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2.12.2 MBO Low Losses Configurations - GSM 900/1800/1900 2.12.2.1 MBO1 - 1x5...8 Low Losses The following figure shows the rack layout of the MBO1 - 1x5...8 - Low Losses configuration.

Note:

Restrictions For GSM 1900, the configuration is limited to six TREs.

1234 1234 1234 1234 1234 1234 1234

ADAM4 P M 1 2

P M 1 2

TRE7

TRE8

The BTS has 1 sector with n TREs

P M 1 2

a b ANC 1

TRE 1 3 2 4 TRE4

a b ANC 2

TRE 5 7 6 8

TRE3 Both ANCs are set to the same sector number

FANU

FANU

FANU

AIR S U M A

ANC 2

ANC 1

Empty space

12 12 TRE6 FANU

TRE5

TRE2 FANU

TRE1

Dummy panels if no modules installed PM12 equipped if GSM 1900 and if n>6. Otherwise: dummy panel is installed

FANU

Figure 146: MBO1 - 1x5...8 - Low Losses Configuration

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2.12.2.2 MBO2 - 2x3...6 Low Losses The following figure shows the rack layout of the MBO2 - 2x3...6 - Low Losses configuration. ADAM4 P M 1 2

P M 1 2

P M 1 2

1234 1234 1234 1234 1234 1234

The BTS has 2 sectors : − Sector 1 with n TREs − Sector 2 with p TREs

P M 1 2

TRE6

a b ANC 1 TRE 1 5 2 6

TRE5

TRE6

TRE5

a b ANC 2 TRE 1 5 2 6

FANU

FANU AIR

FANU

S U M A

ANC 4 (Sector 1)

ANC 1 (Sector 1)

FANU

FANU

FANU AIR

ANC 3 (Sector 2)

ANC 2 (Sector 2)

a b ANC 4 3

4

a b ANC 3 3

4

In each sector : Both ANCs are set to the same sector number

On each ANC: The two bridges will be removed at installation time (On site), if no more than 2 TREs are connected to them, and kept otherwise.

Empty space

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

12

Dummy panels if no modules installed PM12 equipped if GSM 1900 and if (n+p)>6. Otherwise: dummy panel is installed

Figure 147: MBO2 - 2x3...6 - Low Losses Configuration

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2.12.2.3 MBO2 - 3x3...4 Low Losses The following figure shows the rack layout of the MBO2 - 3x3...4 - Low Losses configuration. ADAM4 P M 1 2

P M 1 2

TRE4

P M 1 2

1234 1234 1234 1234 1234 1234

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

P M 1 2

TRE3

Sector 1

Sector 2

a

a

b

ANC 1

ANC 6 (Sector 3)

TRE2

TRE1

ANC 5 (Sector 3)

TRE 1 a

FANU

FANU AIR

FANU

S U M A

ANC 4 (Sector 1)

ANC 1 (Sector 1)

FANU AIR

ANC 2 1

2 b

ANC 4

FANU

b

a

2 b

ANC 3

Sector 3

a

b

ANC 5

1 a

2 b

ANC 6

FANU TRE 3

ANC 3 (Sector 2)

ANC 2 (Sector 2)

4

3

4

3

4

On each ANC: Bridges will be removed at installation time (on site) Per sector, both ANCs are set to the same sector number

Empty space Dummy panels if no modules installed

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

123 123

PM12 equipped if GSM 1900 and if (n+p+q)>6. Otherwise: dummy panel is installed

Figure 148: MBO2 - 3x3...4 - Low Losses Configuration

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2.12.3 MBO High Power Configurations - GSM 900/1800 2.12.3.1 MBO1 - 1x1...4 The following figure shows the rack layout of the MBO1 - 1x1...4 - High Power GSM 900/1800 configuration. ADAM4 The BTS has 1 sector P M 1 2

P M 1 2

P M 1 2

a

b

ANC 1

TRE

1

3 2 4

On site: on the ANC: Bridges can be removed if only 2 TREs connected to the ANC FANU

FANU

FANU

AIR

S U M A

The ANC can be replaced by the ANB in case of less than 3TRE s

ANC 1

Empty space Dummy panels if no modules installed TRE4 FANU

TRE3

TRE2 FANU

TRE1

Available only on AC configuration

FANU

Figure 149: MBO1 - 1x1...4 - High Power GSM 1800 Configuration

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2.12.3.2 MBO1 - 2x1...2 The following figure shows the rack layout of the MBO1 - 2x1...2 - High Power GSM 900/1800 configuration. ADAM4 P M 1 2

P M 1 2

P M 1 2 The BTS has 2 sectors with up to 2 TREs each a b ANC 1 TRE 1

2

a b ANC 2 TRE 1

Sector 1

FANU

FANU

FANU

AIR

S U M A

ANC 2 (Sector 2)

2

Sector 2

On each ANC: Bridges will be removed at installation time, on site The ANC can be replaced by the ANB in case of less than 3TRE s

ANC 1 (Sector 1)

AIR Empty space Dummy panels if no modules installed

TRE2

TRE1

TRE2

TRE1 Available only on AC configuration

FANU

FANU

FANU

Figure 150: MBO1 - 2x1...2 - High Power GSM 1800 Configuration

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2.12.3.3 MBO1 - 3x2 The following figure shows the rack layout of the MBO1 - 3x2 - High Power GSM 900/1800 configuration. ADAM4 The BTS has 3 sectors with 2 TREs each P M 1 2

P M 1 2

P M 1 2

a

TRE 1 TRE2

a

ANC 3 (Sector 3)

FANU

FANU

b

a

ANC 2 TRE 1

2

Sector 1

TRE1

FANU

b

ANC 1

2

b

ANC 3 TRE 1

Sector 2

2

Sector 3

On each ANC: Bridges will be removed at installation time, on site

The ANC can be replaced by the ANB in case of less than 3TRE s

AIR

S U M A

ANC 2 (Sector 2)

ANC 1 (Sector 1)

Empty space Dummy panels if no modules installed

TRE2 FANU

TRE2

TRE1 FANU

TRE1

Available only on AC configuration

FANU

Figure 151: MBO1 - 3x2 - High Power GSM 1800 Configuration

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2.12.3.4 MBO2 - 2x1...4 The following figure shows the rack layout of the MBO2 - 2x1...4 - High Power GSM 900/1800 configuration. ADAM4 P M 1 2

P M 1 2

1234 1234 1234 1234 1234

P M 1 2

FANU

The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs

P M 1 2

FANU AIR

a b ANC 1

a b ANC 2

1 324

1324

On site, and on each ANC: Bridges can be removed if only 2 TREs connected

FANU AIR

The ANC can be replaced by the ANB in case of less than 3TRE s

S U M A

ANC 1 (Sector 1)

ANC 2 (Sector 2) Empty space

AIR

AIR

Dummy panels if no modules installed

123 123

PM12 equipped if (n+p)>6, otherwise: dummy panel is installed

TRE4

TRE3

FANU

TRE2

TRE1 FANU

FANU

TRE4

TRE3

FANU

TRE2

FANU

TRE1

Available only on AC configuration

FANU

Figure 152: MBO2 - 2x1...4 - High Power GSM 1800 Configuration

2.12.3.5 MBO2 - 3x1...4 The following figure shows the rack layout of the MBO2 - 3x1...4 - High Power GSM 900/1800 configuration. ADAM4 P M 1 2

TRE2

P M 1 2

P M 1 2

TRE1

123 123 123 123 123

The BTS has 3 sectors: − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

P M 1 2

ANC 3 (Sector 3)

TRE4

a b ANC 1

TRE3

TRE 1 3 2 4 FANU

FANU

FANU AIR S U M A

FANU

FANU AIR

ANC 1 (Sector 1)

FANU

a b ANC 2

a b ANC 3

1 3 2 4

1 3 2 4

The ANC can be replaced by the ANB in case of less than 3TRE s

ANC 2 (Sector 2) Empty space Dummy panels if no modules installed

123 123

PM12 equipped if (n+p+q)>6, otherwise: dummy panel is installed

TRE4 FANU

TRE3 FANU

TRE2

TRE1 FANU

TRE4 FANU

TRE3 FANU

TRE2

TRE1

Available only on AC configuration

FANU

Figure 153: MBO2 - 3x1...4 - High Power GSM 1800 Configuration

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2.12.4 MBO Multiband BTS Configurations - GSM 900/1800 and GSM 900/1900 2.12.4.1 MBO1 - 1x1...4/1x1...4 The following figure shows the rack layout of the MBO1 - 1x1...4/1x1...4 Multiband BTS configuration.

1234 1234 1234 1234 1234 1234 1234

ADAM4

P M 1 2

P M 1 2

TRE4

P M 1 2

Multiband BTS: The BTS has 2 sectors : − Sector 1 with n TREs − Sector 2 with p TREs

TRE3

TRE4

TRE3

a b ANC 1 TRE 1 3 2 4 Sector 1

FANU

FANU

FANU

AIR

S U M A

ANC 2 (Sector 2)

a b ANC 2 TRE 1 3 2 4 Sector 2

The ANC can be replaced by the ANB in case of less than 3TRE s

ANC 1 (Sector 1)

GSM 1800 / GSM 1900 Dummy panels if no modules installed Empty space

123 123

PM12 equipped if (n+p)>6, otherwise: dummy panel is installed

TRE1

TRE2

TRE2

TRE1

Available only on AC configuration

FANU

FANU

FANU

Figure 154: MBO1 - 1x1...4/1x1...4 - Multiband BTS Configuration

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2.12.4.2 MBO2 - 1x1...6/1x1...6 The following figure shows the rack layout of the MBO2 - 1x1...6/1x1...6 Multiband BTS configuration. ADAM4 Multiband BTS: P M 1 2

P M 1 2

P M 1 2

The BTS has 2 sectors : − Sector 1 with n TREs − Sector 2 with p TREs

TRE6

TRE6

TRE5

TRE5

a b ANC 2

a b ANC 1

ANY 2

ANY 1 TRE 1 3 FANU AIR

FANU

S U M A

FANU

ANY 1

FANU AIR

FANU

ANC 1 (Sector 1)

FANU

ANY 2

ANC 2 (Sector 2)

2 4 56

TRE 1 3

2 4 56

In each sector : If no more than 4 TREs, no ANY is required, TRE1 to TRE4 are then cabled on ANC The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900

Dummy panels if no modules installed Empty space TRE3

TRE4

TRE2

FANU

FANU

TRE1 FANU

TRE4

TRE3

FANU

TRE2 FANU

TRE1 Available only on AC configuration

FANU

Figure 155: MBO2 - 1x1...6/1x1...6 - Multiband BTS Configuration

2.12.4.3 MBO2 - 1x1...8/1x1...4 The following figure shows the rack layout of the MBO2 - 1x1...8/1x1...4 Multiband BTS configuration. ADAM4 P M 1 2

P M 1 2

Multiband BTS: The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs

P M 1 2

a b ANC 1 TRE8

TRE6

TRE7

FANU

TRE5 ANY 2 2 468 a b ANC 2

FANU

FANU AIR

ANY 1 TRE 1 3 5 7

AIR

TRE 1 3 2 4 S U M A

ANY 2

ANY 1

ANC 2 (Sector 2)

ANC 1 (Sector 1)

In sector 1: If no more than 4 TREs, no ANY is required. TRE1 to 4 are then cabled on ANC The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900 Dummy panels if no modules installed Empty space

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 156: MBO2 - 1x1...8/1x1...4 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.12.4.4 MBO2 - 1x1...4/1x1...8 The following figure shows the rack layout of the MBO2 - 1x1...4/1x1...8 Multiband BTS configuration. ADAM4 P M 1 2

P M 1 2

Multiband BTS: The BTS has 2 sectors: − Sector 1 with n TREs − Sector 2 with p TREs

P M 1 2

a b ANC 1 TRE8

TRE6

TRE7

FANU

ANY 2

AIR

ANY 1

ANY 1

ANY 2

TRE 1 3 5 7

2 468

a b ANC 2

FANU

FANU AIR

S U M A

TRE5

ANC 2 (Sector 2)

ANC 1 (Sector 1)

TRE 1 3 2 4 In sector 1: If no more than 4 TREs, no ANY is required. TRE1 to 4 are then cabled on ANC The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900

Dummy panels if no modules installed Empty space TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 157: MBO2 - 1x1...4/1x1...8 - Multiband BTS Configuration

2.12.4.5 MBO2 - 1x1...4/2x1...4 The following figure shows the rack layout of the MBO2 - 1x1...4/2x1...4 Multiband BTS configuration. ADAM4

Multiband BTS: P M 1 2

P M 1 2

TRE4

P M 1 2

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

TRE3

TRE4

TRE3

a b ANC 1

FANU FANU

FANU

S U M A

ANC 3 (Sector 3)

TRE 1 3 2 4 Sector 1

AIR

AIR ANC 1 (Sector 1)

ANC 2 (Sector 2)

a b ANC 2

1 3 24 Sector 2

a b ANC 3

1 3 24 Sector 3

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900

Dummy panels if no modules installed Empty space Available only on AC configuration

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Figure 158: MBO2 - 1x1...4/2x1...4 - Multiband BTS Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.12.4.6 MBO2 - 2x1...4/1x1...4 The following figure shows the rack layout of the MBO2 - 2x1...4/1x1...4 Multiband BTS configuration. ADAM4 P M 1 2

P M 1 2

TRE4

Multiband BTS :

P M 1 2

The BTS has 3 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs

TRE4

TRE3

FANU

FANU

TRE3

a b ANC 1

FANU

S U M A

ANC 3 (Sector 3)

TRE 1 3 2 4

AIR

AIR

a b ANC 2

ANC 1 (Sector 1)

ANC 2 (Sector 2)

1 3 24

a b ANC 3

1 3 24

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900

Dummy panels if no modules installed Empty space TRE1

TRE2 FANU

TRE2 FANU

TRE1 FANU

TRE4

TRE3

FANU

TRE2 FANU

TRE1

Available only on AC configuration

FANU

Figure 159: MBO2 - 2x1...4/1x1...4 - Multiband BTS Configuration

2.12.4.7 MBO2 - 1x1...4/...4,...2,...2 The following figure shows the rack layout of the MBO2 - 1x1...4/...4,...2,...2 Multiband BTS configuration. ADAM4 P M 1 2

P M 1 2

TRE4

Multiband BTS : The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

P M 1 2

TRE4

TRE3

a b ANC 1

TRE3

TRE 1 3 2 4 a b ANC 3

FANU FANU

FANU

AIR

AIR S U M A

ANC 3 (Sector 3)

ANC 1 (Sector 1)

TRE 1 3 2 4 ANC 4 (Sector 4)

ANC 2 (Sector 2)

a b ANC 2 1

2

a b ANC 4 1

2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900 Dummy panels if no modules installed Empty space

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 160: MBO2 - 1x1...4/...4,...2,...2 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.12.4.8 MBO2 - ...4,...2,...2/1x1...4 The following figure shows the rack layout of the MBO2 - ...4,...2,...2/1x1...4 Multiband BTS configuration. ADAM4 P M 1 2

P M 1 2

TRE4

Multiband BTS : The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

P M 1 2

TRE3

TRE4

a b ANC 1

TRE3

TRE 1 3 2 4 FANU FANU

FANU

S U M A

ANC 3 (Sector 3)

a b ANC 3

AIR

AIR

ANC 1 (Sector 1)

ANC 4 (Sector 4)

ANC 2 (Sector 2)

a b ANC 2 1

2

a b ANC 4

TRE 1 3 2 4

1

2

GSM 1800 Dummy panels if no modules installed TRE2

TRE1

FANU

TRE2 FANU

TRE1 FANU

TRE2

TRE1

FANU

TRE2 FANU

TRE1

Empty space

FANU

Figure 161: MBO2 - ...4,...2,...2/1x1...4 - Multiband BTS Configuration

2.12.4.9 MBO2 - 2x1...4/2x1...2 The following figure shows the rack layout of the MBO2 - 2x1...4/2x1...2 Multiband BTS configuration. ADAM4 P M 1 2

P M 1 2

TRE4

Multiband BTS :

P M 1 2

The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

TRE3

TRE4

TRE3

a b ANC 1 TRE 1 3 2 4

FANU

FANU

FANU

AIR S U M A

ANC 3 (Sector 3)

a b ANC 3

AIR

ANC 1 (Sector 1)

ANC 4 (Sector 4)

ANC 2 (Sector 2)

TRE 1 3 2 4

a b ANC 2 1

2

a b ANC 4 1

2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900 Dummy panels if no modules installed Empty space TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 162: MBO2 - 2x1...4/2x1...2 - Multiband BTS Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.12.4.10 MBO2 - 2x1...2/2x1...4 The following figure shows the rack layout of the MBO2 - 2x1...2/2x1...4 Multiband BTS configuration. ADAM4 P M 1 2

P M 1 2

TRE4

Multiband BTS :

P M 1 2

The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

TRE3

TRE4

a b ANC 1

TRE3

a b ANC 2

TRE 1 3 2 4 FANU

FANU

FANU AIR

AIR S U M A

ANC 3 (Sector 3)

ANC 1 (Sector 1)

ANC 4 (Sector 4)

ANC 2 (Sector 2)

1

2

a b ANC 4

a b ANC 3

1

TRE 1 3 2 4

2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900

Dummy panels if no modules installed Empty space TRE2

TRE1

TRE2

FANU

FANU

TRE1 FANU

TRE2

TRE1

FANU

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 163: MBO2 - 2x1...2/2x1...4 - Multiband BTS Configuration

2.12.4.11 MBO2 - 2x1...3/2x1...3 The following figure shows the rack layout of the MBO2 - 2x1...3/2x1...3 Multiband BTS configuration. ADAM4

Multiband BTS : P M 1 2

P M 1 2

P M 1 2

The BTS has 4 sectors : − Sector 1 with n TREs − Sector 2 with p TREs − Sector 3 with q TREs − Sector 4 with r TREs

TRE3

TRE3

FANU

FANU

FANU

TRE3

FANU AIR

FANU

AIR S U M A

ANC 3 (Sector 3)

ANC 1 (Sector 1)

TRE3

ANC 4 (Sector 4)

FANU

ANC 2 (Sector 2)

a b ANC 1

a b ANC 2

TRE 1 3 2

1 3 2

a b ANC 3

a b ANC 4

TRE 1 3 2

1 3 2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900 Dummy panels if no modules installed Empty space TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 164: MBO2 - 2x1...3/2x1...3 - Multiband BTS Configuration

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2 Configurations - Rack Layouts

2.12.4.12 MBO2 - 3x1...2/3x1...2 The following figure shows the rack layout of the MBO2 - 3x1...2/3x1...2 Multiband BTS configuration. Multiband BTS:

ADAM4 P M 1 2

P M 1 2

TRE4

The BTS has 6 sectors :

P M 1 2

TRE3

FANU

ANC 6 (Sector 6)

FANU AIR

S U M A

ANC 3 (Sector 3)

FANU

ANC 1 (Sector 1)

TRE2

TRE1

FANU

ANC 5 (Sector 5)

FANU AIR

ANC 4 (Sector 4)

Sector 1

Sector 2

a b ANC 1

a b ANC 2

TRE 1

1

2

2

Sector 4

Sector 5

a b ANC 4

a b ANC 5

Sector 3 a

b ANC 3 1

2

Sector 6 a

b ANC 6

FANU TRE 1

ANC 2 (Sector 2)

2

1

2

1

2

On each ANC: Bridges will be removed at installation time (on site) The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 / GSM 1900

Dummy panels if no modules installed Empty space TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 165: MBO2 - 3x1...2/3x1...2 - Multiband BTS Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.12.5 MBO Multiband Cells Configurations - GSM 900/1800 2.12.5.1 MBO1 - 1x(...4/...4) The following figure shows the rack layout of the MBO1 - 1x(...4/...4) - Multiband Cells configuration.

1234 1234 1234 1234 1234 1234

ADAM4

P M 1 2

P M 1 2

TRE4

P M 1 2

Multiband Cell:

TRE3

TRE4

TRE3

The BTS has only 1 sector with: − n TREs in GSM 900 band − p TREs in GSM 1800 band ANC1 and ANC2 are set to the same sector number

FANU

FANU

FANU

a b ANC 1

a b ANC 2

TRE 1 3 2 4

TRE 1 3 2 4

AIR The ANC can be replaced by the ANB in case of less than 3TRE s

S U M A

ANC 2

ANC 1

GSM 1800 Dummy panels if no modules installed Empty space

123 123

PM12 equipped if (n+p)>6, otherwise: dummy panel is installed

TRE1

TRE2 FANU

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 166: MBO1 - 1x(...4/...4) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.12.5.2 MBO2 - 1x(...6/...6) The following figure shows the rack layout of the MBO2 - 1x(...6/...6) - Multiband Cells configuration. ADAM4 P M 1 2

P M 1 2

Multiband Cell:

P M 1 2

The BTS has only 1 sector with: − p TREs in GSM 900 band − n TREs in GSM 1800 band ANC1 and ANC2 are set to the same sector number TRE6

TRE6

TRE5

TRE5

a b ANC 2

a b ANC 1

FANU AIR

FANU

S U M A

ANY 1

FANU AIR

FANU

FANU

ANY 2

ANC 1

ANY 1

FANU

ANC 2

ANY 2

TRE 1 3 2 4 56 TRE 1 3 2 4 56 On each ANC: If no more than 4 TREs, no ANY is required, TRE1 to TRE4 are then cabled on ANC The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 Dummy panels if no modules installed Empty space TRE4

TRE3

TRE2

FANU

FANU

TRE1 FANU

TRE4

TRE3

FANU

TRE2 FANU

TRE1 Available only on AC configuration

FANU

Figure 167: MBO2 - 1x(...6/...6) - Multiband Cells Configuration

2.12.5.3 MBO2 - 1x(...8/...4) The following figure shows the rack layout of the MBO2 - 1x(...8/...4) - Multiband Cells configuration. Multiband Cell:

ADAM4 P M 1 2

P M 1 2

TRE8

The BTS has only 1 sector with − n TREs in GSM 900 band − p TREs in GSM 1800 band

P M 1 2

ANC1 and ANC2 are set to the same sector number

TRE6

TRE7

FANU

a b ANC 1

TRE5

FANU

FANU AIR

ANY 1

ANY 2

TRE 1 3 5 7

2 468

a b ANC 2

AIR

TRE 1 3 2 4

S U M A

ANY 2

ANY 1

ANC1

ANC 2

On ANC1: If no more than 4 TREs, no ANY is required. TRE1 to 4 are then cabled on ANC The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 Dummy panels if no modules installed Empty space

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 168: MBO2 - 1x(...8/...4) - Multiband Cells Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.12.5.4 MBO2 - 1x(...4/...8) The following figure shows the rack layout of the MBO2 - 1x(...4/...8) - Multiband Cells configuration. Multiband Cell:

ADAM4 P M 1 2

P M 1 2

TRE8

The BTS has only 1 sector with − p TREs in GSM 900 band − n TREs in GSM 1800 band

P M 1 2

ANC1 and ANC2 are set to the same sector number

TRE6

TRE7

FANU

FANU

FANU AIR

S U M A

ANY 2

a b ANC 1

TRE5

ANY 2 2 468

a b ANC 2

AIR

ANY 1

ANY 1 TRE 1 3 5 7

ANC1

TRE 1 3 2 4 On ANC1: If no more than 4 TREs, no ANY is required. TRE1 to 4 are then cabled on ANC

ANC 2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 Dummy panels if no modules installed Empty space TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE4 FANU

TRE3

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 169: MBO2 - 1x(...4/...8) - Multiband Cells Configuration

2.12.5.5 MBO2 - 2x(...4/...2) The following figure shows the rack layout of the MBO2 - 2x(...4/...2) - Multiband Cells configuration. Multiband Cell:

ADAM4

The BTS has 2 sectors : P M 1 2

P M 1 2

TRE4

P M 1 2

Sector 1: − n TREs in GSM 1800 band − p TREs in GSM 900 band

TRE4

TRE3

Sector 2: − q TREs in GSM 1800 band − r TREs in GSM 900 band

TRE3

a b ANC 1

FANU

FANU

TRE 1 3 2 4

FANU

1

2

AIR

AIR

a b ANC 3

S U M A

ANC 3 (Sector 2)

a b ANC 2

ANC 1 (Sector 1)

ANC 4 (Sector 2)

ANC 2 (Sector 1)

a b ANC 4

TRE 1 3 2 4

1

2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 Dummy panels if no modules installed Empty space TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 170: MBO2 - 2x(...4/...2) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.12.5.6 MBO2 - 2x(...2/...4) The following figure shows the rack layout of the MBO2 - 2x(...2/...4) - Multiband Cells configuration. ADAM4 P M 1 2

P M 1 2

TRE4

Multiband Cell: The BTS has 2 sectors : Sector 1: − n TREs in GSM 1800 band − p TREs in GSM 900 band

P M 1 2

TRE3

TRE4

Sector 2: − q TREs in GSM 1800 band − r TREs in GSM 900 band

TRE3

a b ANC 1

FANU

FANU

TRE 1 3 2 4

FANU

1

2

AIR

AIR

a b ANC 4

a b ANC 3

S U M A

ANC 3 (Sector 2)

a b ANC 2

ANC 1 (Sector 1)

ANC 4 (Sector 2)

ANC 2 (Sector 1)

1

TRE 1 3 2 4

2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 Dummy panels if no modules installed Empty space TRE2

TRE1

FANU

TRE2 FANU

TRE1 FANU

TRE2

TRE1

FANU

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 171: MBO2 - 2x(...2/...4) - Multiband Cells Configuration

2.12.5.7 MBO2 - 2x(...3/...3) The following figure shows the rack layout of the MBO2 - 2x(...3/...3) - Multiband Cells configuration. ADAM4 P M 1 2

P M 1 2

Multiband Cell: The BTS has 2 sectors : Sector 1: − n TREs in GSM 1800 band − p TREs in GSM 900 band

P M 1 2

TRE3

TRE3

TRE3

TRE3

Sector 2: − q TREs in GSM 1800 band − r TREs in GSM 900 band a b ANC 1

FANU

FANU

FANU

FANU AIR

FANU

AIR S U M A

ANC 3 (Sector 2)

ANC 1 (Sector 1)

ANC 4 (Sector 2)

FANU

a b ANC 2

TRE1 3 2

1 3 2

a b ANC 3

a b ANC 4

TRE 1 3 2

1 3 2

ANC 2 (Sector 1)

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 Dummy panels if no modules installed Empty space TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 172: MBO2 - 2x(...3/...3) - Multiband Cells Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.12.5.8 MBO2 - 1x(...2/...2),1x(...4/...4) The following figure shows the rack layout of the MBO2 - 1x(...2/...2),1x(...4/...4) - Multiband Cells configuration. Multiband Cell:

ADAM4 P M 1 2

P M 1 2

The BTS has 2 sectors :

P M 1 2

Sector 1: − n TREs in GSM 900 band − p TREs in GSM 1800 band

a b ANC 1 TRE4

TRE3

TRE4

a b ANC 3

TRE3

TRE 1 3 2 4

FANU

FANU

FANU AIR

AIR S U M A

ANC 3 (Sector 1)

1 3 24

Sector 2: − q TREs in GSM 900 band − r TREs in GSM 1800 band

ANC 1 (Sector 1)

a b ANC 2

ANC 4 (Sector 2)

ANC 2 (Sector 2)

TRE 1

a b ANC 4

2

1

2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 Dummy panels if no modules installed Empty space TRE2

TRE1

FANU

TRE2 FANU

TRE1 FANU

TRE2

TRE1

FANU

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 173: MBO2 - 1x(...2/...2),1x(...4/...4) - Multiband Cells Configuration

2.12.5.9 MBO2 - 3x(...2/...2) The following figure shows the rack layout of the MBO2 - 3x(...2/...2) - Multiband Cells configuration. Multiband Cell:

ADAM4 P M 1 2

P M 1 2

TRE4

The BTS has 3 sectors : Sector 1: ANC1 + ANC2 Sector 2: ANC3 + ANC4 Sector 3: ANC5 + ANC6

P M 1 2

TRE3

ANC 6 (Sector 3)

TRE2

TRE1

ANC 5 (Sector 3)

TRE 1 2 Sector 2 FANU

FANU AIR

S U M A

ANC 3 (Sector 2)

Sector 2

Sector 1 a b ANC 1

FANU

FANU

ANC 1 (Sector 1)

ANC 4 (Sector 2)

FANU AIR

FANU

ANC 2 (Sector 1)

a b ANC 4

a b ANC 2 1

a

b ANC 3

2 1 Sector 3

a b ANC 5

2

a

b ANC 6

1 2 TRE 1 2 1 On each ANC: Bridges will be removed at installation time (on site)

2

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 1800 Dummy panels if no modules installed Empty space TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

TRE2 FANU

TRE1

TRE2 FANU

TRE1 FANU

Available only on AC configuration

Figure 174: MBO2 - 3x(...2/...2) - Multiband Cells Configuration

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2 Configurations - Rack Layouts

2.12.6 MBO Multiband BTS, Multiband Cells Configurations - GSM 850/1800/1900 GSM 850 is not supported by all BSS software releases. If you are in doubt, contact Alcatel support.

2.12.6.1 MBO2 - 3x1/3x1...3 The following figure shows the rack layout of the MBO2 - 3x1/3x1...3 Multiband BTS configuration. ADAM4 P M 1 2

P M 1 2

TRE2

P M 1 2

1234 1234 1234 1234 1234 1234

TRE1

FANU

The BTS has 6 sectors:

P M 1 2

ANC 6 (Sector 6)

FANU

FANU

TRE3

ANC 5 (Sector 5)

FANU

S U M A

ANC 1 (Sector 1)

a

b ANC 1

b ANC 2

Sector 3

a

b ANC 6

1 3 2

1 3 2

Sector 4

Sector 5

Sector 6

a

a

b ANC 3

b ANC 4

a

b ANC 5

FANU

ANC 4 (Sector 4)

1

TRE 1

AIR

AIR

ANC 3 (Sector 3)

Sector 2

a

TRE 1 3 2

TRE1

FANU

Sector 1

ANC 2 (Sector 2)

1

On each ANC: Bridges will be removed at installation time (on site) The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 850 Dummy panels if no modules installed Empty space

TRE1 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE1 FANU

TRE3

TRE2 FANU

TRE1 FANU

123 123

PM12 equipped if GSM 1900, and if TREs (n+p+t)>3. Otherwise: dummy panel is installed

Available only on AC configuration

Figure 175: MBO2 - 3x1/3x1...3 Multiband BTS Configuration

3BK 20942 AAAA TQZZA Ed.13

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2 Configurations - Rack Layouts

2.12.6.2 MBO2 - 3x(1/...3) The following figure shows the rack layout of the MBO2 - 3x(1/...3) Multiband Cells configuration. ADAM4 P M 1 2

P M 1 2

TRE2

P M 1 2

1234 1234 1234 1234 1234 1234

TRE1

FANU

The BTS has 3 sectors:

P M 1 2

ANC 6 (Sector 3)

FANU

FANU

TRE3

ANC 5 (Sector 3)

FANU

FANU AIR

AIR

S U M A

ANC 3 (Sector 1)

ANC 1 (Sector 1)

Sector 2

a

a

b ANC 1

ANC 4 (Sector 2)

a

b ANC 3

b ANC 2

Sector 3

a

b ANC 6

1 3 2

TRE 1 3 2

TRE1

FANU

Sector 1

a

b ANC 4

1 3 2

a

1

TRE 1

b ANC 5

1

On each ANC: Bridges will be removed at installation time (on site)

ANC 2 (Sector 2)

The ANC can be replaced by the ANB in case of less than 3TRE s

GSM 850 Dummy panels if no modules installed Empty space

123 TRE1 FANU

TRE3

TRE2 FANU

TRE1 FANU

TRE1 FANU

TRE3

TRE2 FANU

TRE1 FANU

PM12 equipped if GSM 1900, and if TREs (n+p+t)>3. Otherwise: dummy panel is installed Available only on AC configuration

Figure 176: MBO2 - 3x(1/...3) Multiband Cells Configuration

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2.13 Multistandard Base Station Outdoor Configurations Based on Extension with Twin TRX The following table gives the possible configuration extension based on Twin TRX modules. Cabinet

Number of sectors

Carriesrs per sector Single TRX -> Twin TRX

MBO1 MBO1T

MBO2

1

8 -> 12

2

4/4 ->4/6(6/6*)

3

2/2/2 -> 4/4/4

1

12 -> 16

2

6/6 -> 8/8

3

4/4/4 -> 6/6/6

2.13.1 MBO1 - 1 Sector mixed configuration Single/Twin-TRX

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2.13.2 MBO1 - 2 Sectors mixed configuration Single/Twin-TRX

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2.13.3 MBO1 - 3 Sectors mixed configuration Single/Twin-TRX

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2.13.4 MBO2 - 1 Sector mixed configuration Single/Twin-TRX

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2.13.5 MBO2 - 2 Sectors mixed configuration Single/Twin-TRX

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2 Configurations - Rack Layouts

2.13.6 MBO2 - 3 Sectors mixed configuration Single/Twin-TRX

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2.14 Multistandard Base Station Outdoor Evolution Configurations with Single TRX 2.14.1 A9100 MBO1E 1 Sector

2.14.2 A9100 MBO1E 2 Sectors

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2.14.3 A9100 MBO2E 3 Sectors

The following figure shows the MBO1E - 3 sectors with 3 TRE in one sector.

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2.14.4 A9100 MBO2E 2 Sectors

2.14.5 A9100 MBO2E 3 Sectors

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2.14.6 A9100 MBO2 4 Sectors

2.14.7 A9100 MBO2 6 Sectors

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2.15 Multistandard Base Station Outdoor Evolution Mixed Configurations Based on Extension with Twin TRX The following table gives the possible configuration extension based on Twin TRX modules. Cabinet

Number of sectors

Carriesrs per sector Single TRX -> Twin TRX

MBO1E

MBO2E

1

8 -> 12

2

4/4 ->4/6(6/6*)

3

2/2/2 -> 4/4/4

1

n.a.

2

8/6 -> 12/12

3

4/4/4 -> 8/8/8

2.15.1 MBO1E - 1 Sector mixed configuration Single/Twin-TRX

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2.15.2 MBO1E - 2 Sectors mixed configuration Single/Twin-TRX

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2.15.3 MBO1E - 3 Sectors mixed configuration Single/Twin-TRX

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2.15.4 MBO2E - 2 Sectors mixed configuration Single/Twin-TRX

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2.15.5 MBO2E - 3 Sectors mixed configuration Single/Twin-TRX

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2.16 Multistandard Base Station Outdoor Evolution Configurations with Twin TRX 2.16.1 Introduction The following table gives the Twin TRX configurations. Twin Mode

Capacity Mode

Capacity Mode Low Loss

Multiband & Multiband Cell

Coverage Mode TxDiv. 2Rx Div.

Coverage Mode TxDiv. 2Rx Div. Low Loss

Coverage Mode TxDiv. 4Rx Div.

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Number of sectors

MBO1E

MBO2E

Carriers per sector

Carriers per sector

1

8

8

2

6/6

8/8

3

4/4/4

8/8/8

4

2/2/2/2

6/6/6/6

1

12

16

2

6/6

12/12

3

-

8/8/8

1

6+6

12 + 12

2

2/2 + 2/2

6/6 + 6/6

3

-

4/4/4 + 4/4/4

1

4

4

2

2/2

4/4

3

2/2/2

4/4/4

1

2

2

2

2/2

2/2

3

-

2/2/2

1

2

2

2

2/2

2/2

3

-

2/2/2

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Twin Mode

Number of sectors

MBO1E

MBO2E

Carriers per sector

Carriers per sector

Extended Cell

1 In, 1 Out

4+4

8+8

Extended Cell TxDiv, 4RX Div for outer cell

1 In, 1 Out

4+2

8+2

Table 7: Twin TRX Configurations

2.16.2 Transceiver Module TRM stands for TRansceiver Module and it can be: Twin module (TGT09 TGT18), or Single module (TRAG TAGH TRAD TRAP TRAL TADH) The twin module can operate as: One TRM for two TRE, and two TRX in capacity mode One TRM for one TRE, and one TRX in Tx Div mode.

TRX 1a TRM

TRX 1 TRX 1b

Capacity Mode

Tx Div Mode

Figure 177: Twin Module Modes

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2.16.3 Cabling Information 2.16.3.1 Standard Configuration The following symbol

is equivalent with

Figure 178: Up to 4 TREs or

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Figure 179: Up to 4 TREs

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The following symbol

is equivalent with

Figure 180: Up to 6 TREs

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The following symbol

is equivalent with

Figure 181: Up to 8 TREs

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2.16.3.2 Tx Div 2Rx Div Configurations The following symbol

is equivalent with

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2.16.3.3 Tx Div 4Rx Div Configurations The following symbol

is equivalent with

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2.16.4 Capacity Mode 2.16.4.1 MBO1E - 1 Sector with Twin-TRX

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2.16.4.2 MBO1E - 2 Sectors with Twin-TRX

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2.16.4.3 MBO1E - 3 Sectors with Twin-TRX

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2.16.4.4 MBO1 - 4 Sectors with Twin-TRX

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2.16.4.5 MBO2E - 1 Sector with Twin-TRX

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2.16.4.6 MBO2E - 2 Sectors with Twin-TRX

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2.16.4.7 MBO2E - 3 Sectors with Twin-TRX

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2.16.4.8 MBO1E - 4 Sectors with Twin-TRX

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2.16.4.9 MBO2E - 4 Sectors with Twin-TRX

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2.16.5 Capacity Mode Low Loss 2.16.5.1 MBO1 - 1 Sector Low Loss with Twin-TRX

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2.16.5.2 MBO2E - 1 Sector Low Loss with Twin-TRX

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2.16.5.3 MBO1E - 2 Sectors Low Loss with Twin-TRX

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2.16.5.4 MBO2E - 2 Sectors Low Loss with Twin-TRX

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2.16.5.5 MBO2E - 3 Sectors Low Loss with Twin-TRX

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2.16.6 Multiband & Multiband Cell 2.16.6.1 MBO1E - Multiband 1 + 1 Sector with Twin-TRX

Multiband BTS: The BTS has 2 sectors with n and p TRX Multiband Cell: The BTS has 1 sector with n TRX in 900 MHz and p TRX in 1800 MHz

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2.16.6.2 MBO1E - Multiband 2 + 2 Sectors with Twin-TRX

Multiband BTS: The BTS has 4 sectors with n and q TRX in 900 MHz plus p and r TRX in 1800 MHz Multiband Cell: The BTS has 1 sector with n TRX in 900 MHz and p TRX in 1800 MHz and 1 sector with q TRX in 900 MHz and r TRX in 1800 MHz

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2.16.6.3 MBO2E - Multiband 1 + 1 Sector with Twin-TRX

Multiband BTS: The BTS has 2 sectors with n and p TRX Multiband Cell: The BTS has 1 sector with n TRX in 900 MHz and p TRX in 1800 MHz

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2.16.6.4 MBO2E - Multiband 2 + 2 Sectors with Twin-TRX

Multiband BTS: The BTS has 4 sectors with n and q TRX in 900 MHz plus p and r TRX in 1800 MHz Multiband Cell: The BTS has 1 sector with n TRX in 900 MHz and p TRX in 1800 MHz and 1 sector with q TRX in 900 MHz and r TRX in 1800 MHz

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2.16.6.5 MBO2E - Multiband 3 + 3 Sectors with Twin-TRX

Multiband BTS: The BTS has 6 sectors with n,q,s TRX in 900 MHz plus p,r,t TRX in 1800 MHz Multiband Cell: The BTS has 1sector with n TRX in 900 MHz and p TRX in 1800 MHz plus 1 sector with q TRX in 900 MHz and r TRX in 1800 MHz plus 1 sector with s TRX in 900 MHz and t TRX in 1800 MHz

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2.16.7 Coverage Mode TxDiv. 2Rx Div. 2.16.7.1 MBO1E - 1 Sector TX Diversity 2RX with Twin-TRX

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2.16.7.2 MBO1E - Multiband 2 + 2 Sectors with Twin-TRX

2.16.7.3 MBO1E - 3 Sectors TX Diversity 2RX with Twin-TRX

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2.16.7.4 MBO2E - 1 Sector TX Diversity 2RX with Twin-TRX

2.16.7.5 MBO2E - 2 Sectors TX Diversity 2RX with Twin-TRX

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2.16.7.6 MBO2E - 3 Sectors TX Diversity 2RX with Twin-TRX

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2.16.8 Coverage Mode TxDiv. 2Rx Div. Low Loss 2.16.8.1 MBO1E - 1 Sector TX Diversity Low Loss with Twin-TRX

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2.16.8.2 MBO2E - 1 Sector TX Diversity Low Loss with Twin-TRX

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2.16.8.3 MBO1E - 2 Sectors TX Diversity Low Loss with Twin-TRX

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2.16.8.4 MBO2E - 2 Sectors TX Diversity Low Loss with Twin-TRX

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2.16.8.5 MBO2E - 3 Sectors TX Diversity Low Loss with Twin-TRX

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2.16.9 Coverage Mode TxDiv. 4Rx Div. 2.16.9.1 MBO1E - 1 Sector TX Diversity 4RX with Twin-TRX

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2.16.9.2 MBO2E - 1 Sector TX Diversity 4RX with Twin-TRX

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2.16.9.3 MBO1E - 2 Sectors TX Diversity 4RX with Twin-TRX

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2.16.9.4 MBO2E - 2 Sectors TX Diversity 4RX with Twin-TRX

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2.16.9.5 MBO2E - 3 Sectors TX Diversity 4RX with Twin-TRX

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2.16.10 Extended Cell 2.16.10.1 MBO1E - Extended Cell with Twin-TRX

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2.16.10.2 MBO2E - Extended Cell with Twin-TRX

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2.16.11 Extended Cell TxDiv, 4RX Div for outer cell 2.16.11.1 MBO1E - Extended Cell TX Diversity 4 RX with Twin-TRX

2.16.11.2 MBO2E - Extended Cell with Twin-TRX

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3 Indoor Cabinets

3 Indoor Cabinets This chapter describes the indoor cabinets used in BTS A9100 configurations. The descriptions are supported with diagrams and illustrations, where necessary.

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3 Indoor Cabinets

3.1 CIMI/CIDI The CIMI and CIDI are indoor cabinets that support both omnidirectional and sectorized configurations. The following figure shows the position of the main modules. CIMI Top FANUs Interconnection Panel

CIDI

Interconnection Panel

STASR 2

STASR 2

Dummy Panel

Dummy Panel

STASR 1

STASR 1

FANUs

FANUs

Air Inlet

Air Inlet

Figure 182: CIMI/CIDI Module Positions Both cabinets are designed to house two STASRs. In the CIMI, the upper subrack (STASR2) contains the SUM and may contain TRE and/or AN modules. The lower subrack (STASR1) can contain TRE and/or AN modules. In the CIDI, the upper subrack (STASR2) can contain the SUM, the microwave equipment and/or AN modules. The lower subrack (STASR1) can contain the SUM and/or TRE modules.

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3.1.1 CIMI/CIDI Cabinet Access and Features The following figure shows the CIMI/CIDI equipped with the interconnection panel and two empty subracks. Perforated Cover contains FANUs (CIMI only).

RF Interface Equipment Label

Interconnection Area

Perforated Door Strips

Dust Filter (CIDI only)

Subrack

EMC Gasket (CIMI only) Adjustable Feet

Figure 183: CIMI/CIDI Equipped with Empty Subracks

3.1.1.1 Construction The CIMI/CIDI is a steel box construction with four adjustable feet, on its underside, to compensate for any unevenness in the floor. The cabinet has no side access; all cable interfaces are accessible from the front or the top of the cabinet. The structure and dimensions of the mechanical rack and equipment comply with IEC 297 standards.

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3.1.1.2 Door The CIMI/CIDI can be installed in back-to-back or back-to-wall configurations. Access to the subracks and the interconnection panel is via a door at the front of the cabinet. The door is the full height of the cabinet. In the CIMI, the door is fitted with a copper-beryllium gasket to ensure EMC integrity when closed. An optional dust filter can be fitted to the CIDI door. The filter is removable for cleaning.

3.1.1.3 Cables All external cables, except for the antenna, are connected to the interconnection panel. The external cables include the DC supply and Abis connections. The antenna cabling is connected at the top of the cabinet. A ribbon cable is used in the cabinet to link the subracks together; see the following figure. In the CIMI, the top end of the cable terminates on the TFBP (refer to Top Fan Unit (Section 11.1.3)) for more information). In the CIDI, the cable terminates at the rear connector of the top subrack. The bottom end terminates on the BTSRI board (refer to Remote Inventory (Section 8.5) for more information).

TFBP (CIMI only)

Subrack Rear

Ribbon Cable

Front Subrack

BTSRI

Figure 184: CIMI/CIDI Subracks Interconnection Cable

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3.1.1.4 Cabinet Top The following figure is a top view of the CIMI, showing antenna connectors and the fan cover. The cover is cut away to reveal extractor fans. The fans are installed and removed via the front of the cabinet. The CIDI cabinet differs in that it requires no top fans and no Top Fan Backplane. The cabinet has a perforated top cover. Fan Cover

Top Fans (x6)

Top Fan Backplane

Ground Bolt

Sector q/A

Sector n/A

Sector q/B

Sector n/B

Sector r/A

Sector p/A Sector p/B

Sector r/B Antenna Connectors

Antenna Connectors

Front Interconnection Panel

Note:

DC Filter Connectors

Sector n/p/q/r means the sector with n/p/q/r TREs. A and B are numbering conventions of the antennas. Antenna connectors are not necessary completely equipped.

Figure 185: CIMI/CIDI Top View The antennas are connected to RF connectors in a recess at the top of the cabinet. An M8 bolt is also located on the top for connecting the cabinet to ground. Any unequipped holes are fitted with a blanking plate.

3.1.1.5 Cooling The CIMI is air cooled by fans, both inside the cabinet and at the top. Cool air is drawn-in through perforations on the door and is then forced up, through the subracks, by the internal fans. The warm air is expelled through perforations at the top of the cabinet. The CIDI is cooled by fans inside the cabinet only, it does not require top fans. Refer to Temperature Control (Section 11) for details of the cooling system hardware.

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3.1.2 CIMI/CIDI Cabinet Interconnection Panel All the external electrical interfaces are located on a panel at the top of the cabinet; see the following figure. Interconnection Area (BTSCA)

Power Supply and Circuit Breaker Area (DCBREAK)

Abis Interface Group

Abis 4

Abis 3

XGND GND

External Input/Output Interface Group

Abis 2

Abis 1

XCLK1 Out

Abis 4 I Abis 3 I Abis 2 I Abis1

For details see below

XCLK2 In/Out

XCLK1 In

XRT

XGPS

XIO Interface Connectors XBCB

Equipment Labels

Krone Strip External Clock Interface Group

CIMI

Abis Relays

CIDI

DC Variant

DC Filter Connectors

Equipment Labels

DC Variant

DC Filter Connectors

−48V −48V

I

I

0 0 BTS S INT R 1

0V

0V

I I

I

I

0

0

0

0 S R 2

Circuit Breakers

INT

SR1

SR2

Circuit Breakers

Figure 186: CIMI/CIDI Interconnection Panel On the left-hand side (see the previous figure) is the interconnection area (BTSCA); the shaded areas identify separate groups of connectors. The power supply input-connectors and circuit breakers are located on the right-hand side. All interfaces are overvoltage protected. Located behind the interconnection area is an External Input/Output Board. The XIOB is connected to the interconnection area and contains a 24 V DC/DC converter and interface circuitry for external alarms. The interconnection panel provides interfaces for the: XIO, external clock, and Abis signals DC supplies.

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3.1.3 CIMI/CIDI Signal Interfaces The CIMI/CIDI have XIO, external clock and Abis signal interfaces. The connectors and functions for each of these interfaces are described, as well as the external alarm inputs.

3.1.3.1 XIO Interface The XIO connectors allow various external alarm devices to be connected to the BTS A9100. These include smoke and flood detectors, as well as electro-mechanical switches. Crimped or clamp strip contacts can be used on the XIO connectors. The positions of the XIO connectors are shown in Figure 186.

XI1 GND XI2 GND XI3 GND XI4 GND XI5 GND XI6 GND XI7 GND XI8 GND

A detailed view of the XIO connectors is given in the following figure.

XI9 GND XI10 GND XI11 GND XI12 GND XI13 GND XI14 GND XI15 GND XI16 GND

XIO 1

XIO 2

XI17 GND XI18 GND XI19 GND XI20 GND XI21 GND XI22 GND XI23 GND XI24 GND

External Alarm Inputs

+24V +24V +24V +24V X01 X02 X03 X04 X05 X06 X07 X08 X GND X GND X GND X GND

XIO 3

External Alarm Outputs

XIO 4

Figure 187: BTS A9100 Indoor XIO Interface Connectors

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The XIO connectors are described in functional groups in the following table. External Alarm Inputs

Connectors XIO 1 to XIO 3 provide an interface for connecting 24 external alarm inputs. Each input alarm is reported to the OMC-R where it is mapped to customer-defined ASCII text. The ASCII text describes the particular alarm. Each alarm input has two adjacent pins associated with it on the XIO connector. If these pins are open-circuit (open loop), an alarm is generated.

External Alarm Outputs

Connector XIO 4 provides an interface for the SUM to control eight external alarm devices. This feature is for future use. The SUM is described in Station Unit Modules (Section 8).

+ 24 VDC Supply

Connector XIO 4 provides a + 24 VDC power source for external alarm devices that require a power supply.

XGND

The XGND connector is used when attaching the external alarm 24 VDC ground to the BTS A9100 ground. If the connector pins are not short-circuited (open loop), the input and output alarms are isolated from the BTS A9100 ground.

Table 8: BTS A9100 Indoor XIO Interface Connectors (Functional Groups)

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3.1.3.2 External Alarm Inputs The following table gives a detailed view of the external alarm inputs. Alarm Description

Alarm Connection

Alarm Generation

Alarm number

XIO Input

Alarm Class

1

1

9

No

Outside

2

2

9

Yes

Outside

3

3

9

No

Outside

4

4

9

No

Outside

5

5

9

No

Outside

6

6

9

No

Outside

7

7

9

No

Outside

8

8

9

Yes

Outside

9

9

9

Yes

Outside

10

10

9

Yes

Outside

11

11

9

Yes

Outside

12

12

9

Yes

Outside

13

13

9

Yes

Outside

14

14

9

Yes

Outside

15

15

9

Yes

Outside

16

16

9

Yes

Outside

17

17

9

Yes

Outside

18

18

9

Yes

Outside

19

19

9

Yes

Outside

20

20

9

Yes

Outside

21

21

9

Yes

Outside

22

22

9

Yes

Outside

23

23

9

Yes

Outside

24

24

9

Yes

Outside

Table 9: BTS A9100 Indoor External Alarm Inputs

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3.1.3.3 External Clock Interface The external clock interface provides connectors for a variety of functions (see Figure 186). The connectors are described in the following table. XBCB

The XBCB connector provides an external interface to the BCB. Certain external control functions can be implemented via the XBCB connector: RI Power supply status Battery status Additional Input/Output signals. The BTS A9100 does not have to be powered up when accessing the Remote Inventory function.

XRT

The XRT connector provides access to the BTS A9100 via an asynchronous serial interface. The signal levels conform to CCITT V.24. This allows a standard terminal to be used for radio supervision and loop-test purposes. The data rate is programmable between 1200 and 115,000 baud. The XRT Interface is controlled by the SUM.

XGPS

The XGPS connector provides an asynchronous serial interface. This controls and supervises an external GPS receiver. The signal levels conform to CCITT V.24. The data rate is programmable between 1200 and 115,000 baud. This interface can also be used to synchronize the BTS A9100 to the GPS receiver. The synchronizing signal conforms to RS-422. The XGPS Interface is controlled by the SUM.

XCLK

The XCLK connectors are used to synchronize the BTS A9100 to another BTS, which can be a G1 BTS, a G2 BTS or a BTS A9100. The signaling interface conforms to RS-422. The XCLK1 In and XCLK1 Out are connected together, pin-to-pin. The XCLK2 In/Out connector provides a bi-directional clock interface. The XCLK Interface is controlled by the SUM.

Table 10: BTS A9100 External Clock Interface Connectors

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3.1.3.4 Abis Interface The Abis Interface provides components for a variety of functions (see Figure 186). The interface consists of the connectors described in the following table. Abis Connectors

The Abis Interface connects the BTS A9100 to the BSC. There are four connectors, these are Abis 1, 2, 3 and 4. All the connectors provide 120 and 75 impedances. The impedance is selected by the type of cable connector plugged into the interface. For 120 cable connection the CA01 cable should be used, for 75 cable connection the CA02 cable should be used. Note: Only Abis 1 and 2 are currently used; Abis 3 and 4 are provided for future use.

Krone Strip Connector

When the Krone connector is used for Abis connection, depending on the cable impedance, the following remarks must be taken into account: If 120 cables are used the SP2M connector must be removed from the Abis connectors If 75 cables are used the SP2M connector must be plugged into the Abis connectors. The Krone strip supports an overvoltage protection device and an Abis monitoring device. The overvoltage protection device is a ’make-before-break’ type. This means there is no interruption of service during insertion and removal.

Abis Relays

Four relays, one for each Abis Interface, are controlled by the SUM. The relays can be used to: Perform loop-back tests on the individual Abis Interfaces. Provide transparent routing of the Abis traffic when the BTS A9100 is powered down or faulty. This ensures that the Abis connection is not broken in multidrop configurations.

Table 11: BTS A9100 Abis Interface Connectors

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3.1.4 CIMI/CIDI DC Supplies Interface The external power supply inputs to the CIMI/CIDI are located at the top of the cabinet (see Figure 186). The components are listed in the following table. DC Filters

In CIMI there are two DC filter connectors; one for the 0 V input and one for the -48/-60 VDC input. CIDI requires only a single filter in the -48/-60 VDC line. The 0 V input connector consists of an M8 bolt.

Circuit Breakers

Three hydraulic-magnet type DC circuit breakers protect the CIMI/CIDI equipment from overload. Each subrack power supply is protected by a separate circuit breaker. The XIOB (which includes the interconnection area) and the top fan backplane share the third breaker (see CIMI/CIDI Power Supply and Grounding (Section 3.1.5)).

Table 12: CIMI/CIDI, DC Supplies Interface

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3.1.5 CIMI/CIDI Power Supply and Grounding The CIMI/CIDI is powered from a -48/-60 VDC external power source. Power is distributed to the cabinet via: One filtered and one unfiltered input connector for CIDI Two filtered input connectors for CIMI. As shown in the figure below. Ground (M8 Bolt)

DC Supply Part of Interconnection Panel

0 VDC Filter

−48/−60 VDC Filter

Circuit Breakers 2

1

5A

XIOB

Top Fan Backplane (CIMI only)

STASR2

STASR1

25 A

25 A

Figure 188: CIMI/CIDI DC Power Interconnections Each subrack has: A filtered input of -48/-60 VDC A filtered 0 V return A ground connector A circuit breaker. The XIOB and TFBP have the same inputs as the subracks.

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The following table shows the rated values for the power components. Item

Component/Rating

0 and -48/-60 VDC Filters

4 µF capacitors, rated at 75 A.

Circuit Breakers 1 and 2

25 A

Circuit Breaker 3

5A

Table 13: CIMI/CIDI Power Component Ratings The CIMI/CIDI is EMC protected at both cabinet and module level. At cabinet level, the CIMI/CIDI is connected to ground via a cable terminated on top of the cabinet with an M8 bolt. At module level, ground continuity is carried to the subracks via the cabinet bus bar. A functionally identical alternative to the cabinet bus bar is used in later models of CIMI. This is a branched cableform. The CIDI uses a bus bar for this purpose. The bus bar (or cableform) also distributes the DC voltages to the subracks and other CIMI/CIDI equipment.

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3.1.6 CIMI/CIDI Cables and Cable Sets This section lists the cables and cable sets for all BTS A9100 CIMI/CIDI configurations. For the physical and electrical descriptions of the discrete cables see Cable Descriptions (Section 17). For some of the cables and cable sets there exist different variants. For the variants used in a specific cabinet refer to its parts list.

3.1.6.1 Internal Cables The CIMI/CIDI internal cables consist of the discrete cables and cable sets listed in the following table. Table 15 lists and describes the cables that comprise the cable sets. Mnemonic

Description

Part Number

BTSRIMI

The BTSRIMI is a flat cable and Printed Circuit Board. It interconnects the subrack backplanes (and the TFBP in case of CIMI). A BTSRI board is permanently attached to one end of the cable.

3BK 07720

BUMI

The BUMI is a branched cableform. It contains cables for the DC power connections to the subracks, XIOB, and top fans.

3BK 07763

CA-ADCO

Cable Assembly - Alarm Disable Connector disables eight alarm inputs. It connects to an XIO connector on the Interconnection Panel.

3BK 07953

CIMI bus bar

The CIMI bus bar is a hardware module used for the DC power connections to the subracks, XIOB, and top fans.

3BK 07763

CS02

Cable Set 02 is an Antenna Network cable set. It connects an ANY to another ANY or to an ANX/ANC.

3BK 07598

CS03

Cable Set 03 is a TRE cable set which connects a TRE to an ANX/ANC or ANY.

3BK 07599

CS04

Cable Set 04 is an Antenna cable set. It connects an ANX/ANC to two antenna cabinet connectors.

3BK 07600

CS05

Cable Set 05 is the BTS Connection Area to SUM cable set. In a CIMI it interconnects the SUM and the Interconnection Panel. The cable set carries the Abis1 and Abis2 Interfaces, and clock and control signals to and from the SUM.

3BK 07199

Table 14: CIMI/CIDI Internal Cables

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3.1.6.2 Cable Sets The cable sets used in the CIMI/CIDE cabinets are described in the table below. Cable Set

Cable

Description

Part Number

Quantity

CS02

RXRC

The Receiver Radio Frequency Cable connects an ANY RX connector to an ANX or another ANY RX connector.

3BK 07920

2

TXRC

The Transmitter Radio Frequency Cable connects an ANY TX connector to an ANX or another ANY TX connector.

3BK 07919

1

RXRC

RXRC connects a TRE RX connector to an ANY, ANX or ANC RX connector.

3BK 07920

2

TXRC

TXRC connects a TRE TX connector to an ANY, ANX or ANC TX connector.

3BK 07919

1

CS04

ANIC

The Antenna Indoor Cable provides a duplex connection between the ANX/ANC and a cabinet antenna connector.

3BK 07921

2

CS05

CA-ABIS

The Cable Assembly - Abis BTSCA-SUM Cable carries the Abis1 /2 Interfaces from the Interconnection Panel to the SUM.

3BK 07922

1

CA-BTSCA

The Cable Assembly - BTSCA-SUM Flat Cable carries clock and control signals between the Interconnection Panel and the SUM.

3BK 07923

1

CS03

Table 15: CIMI/CIDI Cable Sets

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3.1.6.3 External Cables The CIMI/CIDI external cables consist of discrete cables that are listed and described in the following table. Mnemonic

Description

Part Number

Antenna Jumper

Antenna jumpers, 1 m/ 2 m/ 3 m / 5 m length, HCF1/ 2, 2 x 7/ 16 straight male connectors. They connect the BTS to the main antenna cables.

3BK 05360

CA01

Cable Assembly 01 is a 120 PCM cable. It provides the Abis1 and Abis2 connections between the BTS A9100 Interconnection Panel and the customer’s 2 Mbit/s PCM distribution board.

3BK 07594

This cable can be replaced by one made on-site to the desired length. The cable used is L907, an 8 pair, shielded, 2 Mbit/s, 120 PCM cable.

1AC 01328 0004

Cable Assembly 02 is a 75 PCM cable. It provides the Abis1 and Abis2 connections between the BTS A9100 Interconnection Panel and the customer’s 2 Mbit/s PCM distribution board.

3BK 07595

This cable can be replaced by one made on-site to the desired length. The cable used is Flex3, a multi-coaxial, 2 Mbit/s, 75 PCM cable.

1AC 00110 0011

A shorting plug, SP2M is used with Flex3, for impedance matching.

3BK 08949

CA-CBTE

The Cable Assembly - Cable BTS Terminal is the BTS Terminal cable. It connects the BTS Terminal to the BTS Terminal connector on the SUM.

3BK 07951

CA-GC35

The Cable Assembly - Ground Cable 35 mm sq. is the cabinet ground cable. It connects to the M8 ground bolt on the cabinet, and to the customer’s ground point.

3BK 08031

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq., yellow/green power cable.

1AC 01723 0003

Cable Assembly - Power Cable Two Wires 16 mm sq. is a -48/ 0 VDC cabinet power cable. It connects to the DC connectors on the Interconnection Panel, and to the customer’s DC power source.

3BK 08029

This cable can be replaced by one made on-site to the desired length. The cables used are a 16 mm sq. blue power cable and a 16 mm sq. black power cable.

1AC 00147 0001 (Blue)

Cable Assembly - Power Cable 35 mm sq. Black is a 0 VDC cabinet power cable. It connects to the 0 VDC connector on the Interconnection Panel, and to the customer’s 0 VDC power source.

3BK 08030

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq. black power cable.

1AC 01723 0001

CA02

CA-PC2W16

CA-PC35BK

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Mnemonic

Description

Part Number

CA- PC35BL

Cable Assembly - Power Cable 35 mm sq. Blue is a -48 VDC cabinet power cable. It connects to the -48 VDC connector on the Interconnection Panel, and to the customer’s -48 VDC power source.

3BK 08032

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq. blue power cable.

1AC 01723 0002

External Alarms

This cable can be made on-site to the desired length. The cable used is L907, an 8-pair, shielded, 2 Mbit/s, 120 PCM cable.

1AC 01328 0001

SCG2/3

Synchronization Cable Generation 2/3 is a clock synchronization cable. It connects a G2 BTS to the BTS A9100.

3BK 08101

SCG3

Synchronization Cable Generation 3 is a clock synchronization cable. It connects a BTS A9100 to another BTS A9100.

3BK 07950

SCM1/3

Synchronization Cable Mark 1/3 is a clock synchronization cable. It connects a G1 BTS Mark1 to the BTS A9100.

3BK 08102

SCM2/3

Synchronization Cable Mark 2/3 is a clock synchronization cable. It connects a G1 BTS Mark2 to the BTS A9100.

3BK 08103

Table 16: CIMI/CIDI External Cables

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3.1.7 CIMI/CIDI Data and Control Cabling The following figure shows the logical interconnections provided by the data and control cables. CA GC35, CA PC2W16, CA PC35BK, CA PC35BL

CA01/02

SCG2/3, SCG3, SCM1/3, SCM2/3

CA−ADCO TFBP

BTSCA

DC (CIMI only)

CS05 BTSRIMI

CA−CBTE

STASR 2 Backplane SUM

STASR 1 Backplane

BTSRI

Figure 189: CIMI/CIDI Data and Control Cabling

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3.2 CIMA/CIDE The CIMA/CIDE are indoor cabinets that support both omnidirectional and sectorized configurations. There are two variants, where the allowed configurations are determined by the type of external power supply used by the cabinet: DC power supply variant AC power supply variant. The following figure shows the position of the main modules for both variants. DC variant Top FANUs Connector Area

AC variant Top FANUs Connector Area

Connector Area STASR 5

STASR 5

Connector Area STASR 4

ASIB Up to 4 TREs

Up to 4 TREs

Power control modules

Up to 4 TREs

FANUs Air Inlet

Air Inlet

FANUs FANUs Air Inlet

Air Inlet STASR 4

STASR 4

STASR 3

STASR 3 ANs

Dummy Panel STASR 3

Up to 2 ANCs and up to 2 Microwave Modules

Up to 4 TREs or ANs

Dummy Panel

FANUs Air Inlet

STASR 3 STASR 2

Up to 4 TREs

SUM and ANs

Dummy Panel

Up to 4 TREs

SUM, ANYs and ANCs

FANUs Air Inlet

Up to 4 TREs

FANUs

FANUs Air Inlet

FANUs Air Inlet STASR 1

Up to 4 TREs

Dummy Panel

Air Inlet

CIMA

Up to 4 TREs

Dummy Panel STASR 1

STASR 1

STASR 1

Dummy Panel STASR 2

FANUs Air Inlet STASR 2

SUM and ANs

Up to 2 ANCs and up to 2 Microwave Modules

Up to 4 TREs

FANUs Air Inlet STASR 2

FANUs

FANUs Air Inlet

Batteries Fitted into special Battery Tray

Batteries Fitted into special Battery Tray or another STASR fitted with TREs *)

Dummy Panel

Dummy Panel

CIMA

CIDE

ADAM, 3 PM12s, SUM, ANC

CIDE

* ) If TREs are installed FANUs are installed under this STASR instead of over it.

Figure 190: CIMA/CIDE Module Positions

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3.2.1 DC Power Supply Variant The DC variant of the cabinet is designed to house up to five STASRs. The odd-numbered subrack positions (1, 3 and 5) each contain up to four TREs. STASR2 contains the SUM and a mixture of ANX, ANY or ANC modules, as required. STASR4 can contain only a mixture of ANX, ANY or ANC modules, as well as microwave communications modules. Cooling is provided by FANUs situated at the base of each of the odd-numbered subracks and, in the CIMA, also at the top of the cabinet.

3.2.2 AC Power Supply Variant The AC variant of the CIMA is designed to house up to three STASRs and an ASIB subrack. The odd-numbered subrack positions (1 and 3) each contain up to four TREs. STASR2 contains the SUM and a mixture of ANX and ANY modules, as required. The battery tray in the bottom of the cabinet can contain a BU41 or a BU100, in the CIMA, Subrack 4 is an ASIB subrack containing the AC power control modules. The AC variant of the CIDE uses a backup battery which can be housed internally or externally: If an internal battery is used, the CIDE holds four STASRs. STASR1 contains the SUM, three PM12s and the ADAM. STASR2 and 4 each contain up to four TREs. STASR3 contains up to two ANCs, and optionally, up to two microwave communications modules If an external battery is used, the CIDE holds five STASRs. The battery tray at the bottom of CIDE is replaced by a STASR which contains up to four additional TREs. In this case FANUs are installed under this STASR. Cooling is provided by FANUs situated at the base of each of the subracks containing TREs and the power control subrack.

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3.2.3 CIMA/CIDE Cabinet Access and Features The following figure shows the CIMA/CIDE equipped with the interconnection panel and five empty subracks. Top Cover RF Interface

RF Interface Equipment Label

Interconnection Area

Note that the AC variant uses an ASIB to replace the top STASR.

Perforated Door Strips

EMC Gasket (CIMA only)

STASR

Note that the AC variant may replace the bottom STASR with a battery tray containing BU41 or BU100.

Adjustable Feet

Figure 191: CIMA/CIDE Equipped with Empty Subracks

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3.2.3.1 Construction The CIMA/CIDE is a steel box construction with four adjustable feet, on its underside, to compensate for any unevenness in the floor. The cabinet has no side access; all cable interfaces are accessible from the front or the top of the cabinet. The structure and dimensions of the mechanical rack and equipment comply with IEC 297 standards.

3.2.3.2 Door The CIMA/CIDE can be installed in back-to-back or back-to-wall configurations. Access to the subracks and the interconnection panel is via a door at the front of the cabinet. The door is the full height of the cabinet and, in the CIMA, is fitted with a copper-beryllium gasket to ensure EMC integrity when closed.

3.2.3.3 Cables All external cables, except for the antenna, are connected to the interconnection panel. The external cables include the AC or DC supply and Abis connections. The antenna cabling is connected at the top of the cabinet. A ribbon cable is used within the cabinet to link the subracks together; see the following figure. The top end of the cable terminates on the TFBP (CIMA only - refer to Top Fan Unit (Section 11.1.3) for more information). The bottom end terminates on the BTSRI board (refer to Remote Inventory (Section 8.5) for more information). If an internal battery is used in the AC Variant, the ribbon cable also connects to the RIBAT (refer to RIBAT (Section 12.29) for more information).

TFBP (CIMA only)

Subrack

TFBP (CIMA only)

Subrack

Ribbon Cable

Subrack

Ribbon Cable

Subrack

Subrack Rear

Rear

Front

BTSRI

Sub rack or Battery Tray

RIBAT in Case of Battery (CIDE only)

AC variant

Subrack

DC variant

Front

Subrack

Subrack

BTSRI

Subrack

Figure 192: CIMA/CIDE Subracks Interconnection Cable

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3.2.3.4 Cabinet Top The following figure is a top view of the CIMA, showing antenna connectors and the fan cover. The cover is cut away to reveal extractor fans. The fans are installed and removed via the front of the cabinet. Fan Cover

Top Fans (x6)

Top Fan Backplane

Ground Bolt

Sector q/A

Sector n/A

Sector q/B

Sector n/B

Sector r/A

Sector p/A

Sector r/B

Sector p/B

Antenna Connectors

Antenna Connectors

Front Interconnection Panel

Note:

AC or DC Filter Connectors, depending on CIMA variant

Sector n/p/q/r means the sector with n/p/q/r TREs. A and B are numbering conventions of the antennas. Antenna connectors are not necessary completely equipped.

Figure 193: CIMA Top View The following figure is a top view of the CIDE. The CIDE has no top fans, just a perforated top cover. Top Cover

AC Mains Filter Terminals

Ground Bolt

Sector q/A

Sector n/A

Sector q/B

Sector n/B

Sector r/A

Sector p/A

Sector r/B

Sector p/B

Antenna Connectors

Interconnection Panel

Note:

Antenna Connectors

Front DC Filter Connectors

DC Output Connector

Sector n/p/q/r means the sector with n/p/q/r TREs. A and B are numbering conventions of the antennas. Antenna connectors are not necessary completely equipped.

Figure 194: CIDE Top View The antennae are connected to RF connectors at the top of the cabinet. An M8 bolt is also located on the top for connecting the cabinet to ground. Any unequipped holes are fitted with a blanking plate. The CIDE AC variant has an AC filter set in the roof plate next to the antenna connectors on the left side. The filter has terminals for connection to a 230 VAC 1Ø supply.

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3.2.3.5 Cooling The CIMA/CIDE is air cooled by fans, inside the cabinet and, in the CIMA, additionally at the top. Cool air is drawn in through perforations on the door and is then forced up, through the subracks, by the internal fans. The warm air is expelled through perforations at the top of the cabinet by the top fans. Refer to Temperature Control (Section 11) for details of the cooling system hardware.

3.2.4 CIMA/CIDE Cabinet Interconnection Panel All the external electrical interfaces are located on a front-facing panel at the top of the cabinet. The following figure shows the details of the CIMA/CIDE DC and AC variants. The exception is the CIDE AC mains input, which is located in the cabinet roof. AC mains input terminals are part of the AC mains filter. The filter is located next to the antenna connectors, see Figure 194. Interconnection Area (BTSCA)

Power Supply and Circuit Breaker Area (DCBREAK)

Abis Interface Group Equipment Labels

Abis 4

XGND GND

Abis 3

For details see below

Krone Strip

CIMA

CIMA DC Variant DC Filter Connectors

Abis 1

Abis 4 I Abis 3 I Abis 2 I Abis1

XCLK1 Out

External Clock Interface Group

External Input/Output Interface Group

Abis 2

XCLK2 In/Out

XCLK1 In

XRT

XGPS

XBCB

XIO Interface Connectors

Abis Relays

AC Variant

DC Output

CIDE DC & AC Variant

AC Input

Equipment Labels

DC Filter Connectors

−48V −48V

I

I

0 0 BTS S INT R 1

I

0

I

0 S R 2

Circuit Breakers

+ EXT. BATTERY _

I

0 S R 3

0V

DC OUT 200 W max

DC OUT −48 V/200 W max

0V

I

DC Output (−48 V)

I

0V

L

EXTERN DC I

−48V

I

I

I

I

I

0 S R 4

S R 5

N

External Battery

0 0 0 0 0 0 INT & SR1 SR2 SR3 SR4 SR5 DC OUT

External DC

Circuit Breakers

Figure 195: CIMA/CIDE Interconnection Panel, DC and AC Variants On the left-hand side of the Interconnection Panel (see the previous figure) is the interconnection area; the shaded areas identify separate groups of connectors. The power supply input-connectors and circuit breakers are located on the right-hand side. Located behind the interconnection area is an XIOB. The XIOB is connected to the interconnection area and contains a 24 V DC/DC converter and interface circuitry for external alarms. The interconnection panel provides interfaces for: XIO, external clock and Abis signals External power supplies for both DC and AC variants.

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3.2.5 CIMA/CIDE Signal Interfaces The three CIMA/CIDE signal interfaces are described below. XIO Interface

The XIO connectors allow various external alarm devices to be connected to the BTS A9100. These include smoke and flood detectors, as well as electro-mechanical switches. Crimped or clamp strip contacts can be used on the XIO connectors. The positions of the XIO connectors are shown in Figure 195. A detailed view of the XIO connectors is given in Figure 187. The XIO connectors are described in functional groups in Table 8. Table 9 gives a detailed view of the eternal alarm inputs.

External Clock Interface

The external clock interface provides connectors for a variety of functions; see Figure 195. The connectors are described in Table 10.

Abis Interface

The Abis Interface provides components for a variety of functions; see Figure 195. The interface consists of the connectors described in Table 11.

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3.2.6 CIMA/CIDE External Power Supply Interfaces The external power supply interfaces for the CIMA/CIDE AC and DC variants are described below.

3.2.6.1 CIMA DC Variant Interface The external power supply inputs to the CIMA are located on a panel to the right of the interconnection area; see Figure 195. The components are listed in the following table. DC Filters

There are two DC filter connectors; one for the 0 V input and one for the -48/-60 VDC input.

Circuit Breakers

Six hydraulic-magnet type DC circuit breakers protect the CIMA equipment from overload. Each subrack power supply is protected by a separate circuit breaker. The XIOB (which includes the interconnection area) and the top fan backplane share the sixth breaker (see Figure 196).

Table 17: CIMA, DC Power Supply Interface

3.2.6.2 CIMA AC Variant Interface The external power supply inputs to the CIMA are located on a panel to the right of the interconnection area; see Figure 195. The components are listed in the following table. AC Filter

There is one AC filter connector, for the 230 VAC 1Ø input.

DC Filter

There is one DC filter connector, for the -48/-60 VDC output.

Circuit Breaker

One hydraulic-magnet type DC circuit breaker protects the CIMA equipment from overload. The CIMA power supply system for the AC variant is described in Figure 197.

DC Output

A 9-pin D-type connector provides -48 VDC supply at 200 W max.

Table 18: CIMA, AC Power Supply Interface

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3.2.6.3 CIDE DC and AC Variant Interface The external power supply inputs to the CIDE are located on top of an AC mains filter fitted in the roof of the cabinet; see Figure 194. The components are listed in the following table. AC Filter

There is one AC filter connector, for the 230 VAC 1Ø input.

DC Filters

There are two DC filter connectors; one for the 0 V input and one for the -48/-60 VDC input.

Circuit Breakers

Six hydraulic-magnet type DC circuit breakers protect the CIDE equipment from overload. Each subrack power supply is protected by a separate circuit breaker. See Figures 196 and 198.

DC Output

A 9-pin D-type connector provides -48 VDC supply at 200 W max. to two optional Microwave Communication Modules.

Table 19: CIDE, DC and AC Power Supply Interface

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3.2.7 CIMA/CIDE Power Supply and Grounding 3.2.7.1 CIMA/CIDE DC Variant The CIMA/CIDE is powered from a -48/-60 VDC external power source. Power is distributed to the cabinet via two filtered input connectors; see the following figure. DC Supply Part of Interconnection Panel

Ground (M8 Bolt)

0 VDC Filter

−48/−60 VDC Filter

DC Output −48 V / 200 W max (CIDE only)

Circuit Breakers

6

5

4

3

2

1

5A XIOB

Top Fan Backplane (CIMA only)

STASR 5

25 A

STASR 4

25 A

STASR 3

25 A

STASR 2

25 A

STASR 1

25 A

Figure 196: CIMA/CIDE DC Power Interconnections Each subrack has: A filtered input of -48/-60 VDC A filtered 0 V return A ground connector A circuit breaker. The XIOB and TFBP (CIMA only) have the same inputs as the subracks.

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The following table shows the rated values for the power components. Item

Component/Rating

0 and -48/-60 VDC Filters

4 µF capacitors, rated at 75 A.

Circuit Breakers 1 - 5

25 A

Circuit Breaker 6

5A

Table 20: CIMA/CIDE Power Component Ratings The CIMA/CIDE is EMC-protected at both cabinet and module level. At cabinet level, the CIMA/CIDE is connected to ground via a cable terminated on top of the cabinet with an M8 bolt. At module level, ground continuity is carried to the subracks via the cabinet bus bar. In the CIMA, a functionally identical alternative to the cabinet bus bar is used in the AC variant and the later DC variant of CIMA. This is a branched cableform. The bus bar (or cableform) also distributes the DC voltages to the subracks and other CIMA/CIDE equipment.

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3.2.7.2 CIMA AC Variant The following figure shows the power supply distribution for the CIMA AC variant. ASIB

AC In put AFIP Control

APOD

Alarms

To/From FANUs

ACRI PM08/5

PM08/4

PM08/3

PM08/2

PM08/1

BCB

BCU1

Shunt DC Bus GND

0 VDC

−48 VDC

ABAC S h u n t

APOD

Ground (M8 Bolt)

Circuit Breakers 6

5

4

3

2

1

0 VDC (M6 Bolt) 5A

5A AFIP

XIOB * External Battery

Top Fan Backplane

STASR 4

25 A

STASR 3

25 A

* BU41 or BU100

0 VDC −48 VDC

STASR 2

25 A

STASR 1

25 A

External −48 VDC 200 W

* Only one battery possible

Figure 197: CIMA AC Variant Power Supply System

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The AC input is 230 VAC 1Ø. The AC input is connected to the AFIP, where it is filtered and passed to the APOD. The APOD is located in the ASIB and contains an AC circuit breaker used to isolate the AC input supply. The ASIB contains the modules that: Convert the AC input to 0/ -48 VDC. Refer to APOD (Section 12.11) and PM08 (Section 12.12) for detailed descriptions of the APOD and the PM08s, respectively. Up to five PM08s are used in the CIMA; these are PM08/5 to PM08/1 Control the output DC voltage level for battery charging and testing. Refer to BCU1 (Section 12.16), ABAC (Section 12.20), BU41 (Section 12.24), BU100 (Section 12.25) for detailed descriptions of BCU1 and the ABAC, and the optional items BU41 and BU100, respectively. The DC supply produced in the ASIB is connected to the remaining modules in the CIMA via the circuit breakers located on the APOD. The CIMA is EMC-protected at both cabinet and module level. At cabinet level, the CIMA is connected to ground via a cable terminated on top of the cabinet with an M8 bolt. At module level, ground continuity is carried to the subracks via a branched cableform. The cables are terminated with FASTON, Mate-N-Lock and spade connectors.

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3.2.7.3 CIDE AC Variant The following figure shows the power supply distribution for the AC variant. The presence of the battery depends on the power supply option selected: CIDE without backup battery CIDE with an internal backup battery CIDE with an external backup battery. AC Filter

AC In put

OMU

PM12/3

PM12/2

PM12/1

ADAM

0 VDC

−48 VDC

DCBREAK

Optional inter nal or external Battery Unit

Circuit Breakers DC Output 200 W max

6

5

4

3

2

1

BU41 or BU100

RIBAT

0 VDC (M6 Bolt) Ground (M8 Bolt) XIOB

STASR 5

10 A

25 A

STASR 4

25 A

STASR 3

25 A

STASR 2

25 A

STASR 1

25 A

Figure 198: CIDE AC Variant Power Supply System

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The AC input is 230 VAC 1Ø. The AC input is connected to the AC Filter, where it is filtered and passed to three PM12s. The mains power connection to each PM12 is via a flying socket. The three PM12s convert the AC input to 0/ -48 VDC. Refer to PM12 (Section 12.14) for a description of the PM12. Up to three PM12s are used in a CIDE; these are PM12/3 to PM12/1. Control of the output DC voltage level for battery charging and testing is provided by the OMU via the BCB. Charge/discharge current is monitored via a shunt in the ADAM. The ADAM acts as an interface between the PM12s, the batteries and the power distribution inside the BTS. Refer to ADAM (Section 12.21) for a detailed description of the ADAM and for a functional description of the power supply system. DC power is distributed in the BTS via DCBREAK and the bus bar. DCBREAK contains six circuit breakers, five for STASRs 1 - 5, and one for the XIOB. The CIDE is EMC-protected at both cabinet and module level. At cabinet level, the CIDE is connected to ground via a cable terminated on top of the cabinet with an M8 bolt. At module level, ground continuity is carried to the subracks via a bus bar system. The cables are terminated with FASTON, Mate-N-Lock and spade connectors.

3.2.8 CIMA/CIDE Cables and Cable Sets This section lists the cables and cable sets for all BTS A9100 CIMA/CIDE configurations. For the physical and electrical descriptions of the discrete cables, see Cable Descriptions (Section 17). For some of the cables and cable sets, there exist different variants. For the variants used in a specific cabinet, refer to its parts list.

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3.2.8.1 Internal Cables The CIMA/CIDE internal cables consist of the discrete cables and cable sets. The following table lists the cables and cable sets, Table 22 lists and describes the cables that comprise the cable sets. Mnemonic

Description

Part Number

ADABA

ADABA connects the battery via breakers to ADAM. It includes a cable for the battery temperature sensor.

3BK 25146

ADABM

ADABM connects the -48 VDC filter to ADAM or the interconnection area. 3BK 25139

BTSRIMA

The CIMA BTS Remote Inventory Board with Cable for MEDI is a flat 3BK 07720 cable and a PCB. It interconnects the subrack backplanes and the TFBP. A BTSRI board is permanently attached to one end of the flat cable.

BUMA

The Cable Assembly Maxi as used in the later variant of CIMA is a branched cableform. It contains cables for the DC power connections to the subracks, XIOB, and top fans.

3BK 07762

CA-ADCO

The CA-ADCO disables eight alarm inputs. It connects to an XIO connector on the Interconnection Panel.

3BK 07953

CIMA bus bar

The CIMA bus bar is a hardware module used for the DC power connections to the subracks, XIOB, and top fans.

3BK 07762

CS02

CS02 is an AN cable set. It connects an ANY to another ANY or to an ANX or ANC.

3BK 07598

CS03

CS03 is a TRE cable set.

3BK 07599

In a CIMA, it connects a TRE to an ANX or ANY. In a CIDE, it connects a TRE to an ANC. CS04

CS04 is an ANT cable set. It connects an ANX or ANC to two antenna cabinet connectors.

3BK 07600

CS05

CS05 is the BTSCA-to-SUM cable set. In a CIMA, it interconnects the 3BK 07199 SUM and the Interconnection Panel. The cable set carries the Abis1 and Abis2 Interfaces, and clock and control signals to and from the SUM.

CA-PCAN

CA-PCAN connects the -48 VDC filter (on DCBREAK) to ADAM or to the interconnection area.

3BK 25115

CA-PCAP

CA-PCAP connects the 0 VDC filter (on DCBREAK) to ADAM or to the interconnection area.

3BK 25114

Table 21: CIMA/CIDE Internal Cables

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3.2.8.2 Cable Sets The cable sets used in the CIMA/CIDE cabinets are described in the table below. Cable Sets

Mnemonic

Description

Part Number

Qty

ADABA

CA-ADABM

CA-ADABM connects -48 VDC from ADAM to the battery breaker.

3BK 25139

1

CA-ADABP

CA-ADABP connects 0 VDC from ADAM to the battery breaker.

3BK 25138

1

CA-BABRM

CA-BABRM connects -48 VDC from the battery breaker to the battery interconnection area.

3BK 25141

1

CA-BABRP

CA-BABRP connects 0 VDC from the battery breaker to the battery interconnection area.

3BK 25140

1

CA-BSENS

CA-BSENS connects the battery temperature sensor to RIBAT.

3BK 08119

1

RXRC

The RXRC connects an ANY RX connector to an ANX, ANC or another ANY RX connector.

3BK 07920

2

TXRC

The TXRC connects an ANY TX connector to an ANX, ANC or another ANY TX connector.

3BK 07919

1

RXRC

The RXRC connects a TRE RX connector to an ANY, ANX or ANC RX connector.

3BK 07920

2

TXRC

The TXRC connects a TRE TX connector to an ANY, ANX or ANC TX connector.

3BK 07919

1

CS04

ANIC

The ANIC provides a duplex connection between the ANX or ANC and a cabinet antenna connector.

3BK 07921

2

CS05

CA-ABIS

The CA-ABIS carries the Abis1 /2 Interfaces from the Interconnection Panel to the SUM.

3BK 07922

1

CA-BTSCA

The CA-BTSCA carries clock and control signals between the Interconnection Panel and the SUM.

3BK 07923

1

CS02

CS03

Table 22: CIMA/CIDE Cable Sets

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3.2.8.3 External Cables The CIMA/CIDE external cables consist of discrete cables that are listed and described in the following table. Mnemonic

Description

Part Number

AC Supply

This AC power supply cable can be made on-site to the desired length. The cable used is a single pair, 4 mm sq. power cable.

1AC 00170 0012

Antenna Jumper

Antenna jumpers, 1 m/ 2 m/ 3 m/ 5 m length, HCF1/ 2, 2 x 7/ 16 straight male connectors. They connect the BTS to the main antenna cables.

3BK 05360

CA01

CA01 is a 120 PCM cable. It provides the Abis1 and Abis2 connections between the BTS A9100 Interconnection Panel and the customer’s 2 Mbit/s PCM distribution board.

3BK 07594

This cable can be replaced by one made on-site to the desired length. The cable used is L907, an 8-pair, shielded, 2 Mbit/s, 120 PCM cable.

1AC 01328 0004

CA02 is a 75 PCM cable. It provides the Abis1 and Abis2 connections between the BTS A9100 Interconnection Panel and the customer’s 2 Mbit/s PCM distribution board.

3BK 07595

This cable can be replaced by one made on-site to the desired length. The cable used is Flex3, a multicoaxial, 2 Mbit/s, 75 PCM cable.

1AC 00110 0011

A shorting plug, SP2M is used with Flex3, for impedance matching.

3BK 08949

CA-CBTE

CA-CBTE is the BTS Terminal cable. It connects the BTS Terminal to the BTS Terminal connector on the SUM.

3BK 07951

CA-GC35

CA-GC35 is the cabinet ground cable. It connects to the M8 ground bolt on the cabinet, and to the customer’s ground point.

3BK 08031

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq. yellow/green power cable.

1AC 01723 0003

CA PC2W16 is a -48/ 0 VDC cabinet power cable. It connects to the DC connectors on the Interconnection Panel, and to the customer’s DC power source.

3BK 08029

This cable can be replaced by one made on-site to the desired length. The cables used are a 16 mm sq. blue power cable and a 16 mm sq. black power cable.

1AC 00147 0001 (Blue)

CA PC35BK is a 0 VDC cabinet power cable. It connects to the 0 VDC connector on the Interconnection Panel, and to the customer’s 0 VDC power source.

3BK 08030

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq. black power cable.

1AC 01723 0001

CA02

CA-PC2W16

CA-PC35BK

CA -PC35BL

1AC 00147 0002 (Black)

CA PC35BL is a -48 VDC cabinet power cable. It connects to the -48 3BK 08032 VDC connector on the Interconnection Panel, and to the customer’s -48 VDC power source.

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Mnemonic

Description

Part Number

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq. blue power cable.

1AC 01723 0002

External Alarms

This cable can be made on-site to the desired length. The cable used is L907, an 8-pair, shielded, 2 Mbit/s, 120 PCM cable.

1AC 01328 0001

SCG2/3

SCG2/3 is a clock synchronization cable. It connects a G2 BTS to the BTS A9100.

3BK 08101

SCG3

SCG3 is a clock synchronization cable. It connects a BTS A9100 to another BTS A9100.

3BK 07950

SCM1/3

SCM1/3 is a clock synchronization cable. It connects a G1 BTS Mark 1 to the BTS A9100.

3BK 08102

SCM2/3

SCM2/3 is a clock synchronization cable. It connects a G1 BTS Mark 2 to the BTS A9100.

3BK 08103

Table 23: CIMA/CIDE External Cables

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3.2.9 CIMA/CIDE Data and Control Cabling The following figure shows the logical interconnections provided by the data and control cables.

TFBP (CIMA only)

STASR 5 Backplane CA GC35, CA PC2W16, CA PC35BK, CA PC35BL

CA01/02 STASR 4 Backplane

SCG2/3, SCG3, SCM1/3, SCM2/3

CA−ADCO

BTSCA

DC STASR 3 Backplane

CS05

CA−CBTE STASR 2 Backplane SUM

STASR 1 Backplane

BTSRIMA BTSRI

Figure 199: CIMA/CIDE Data and Control Cabling

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3.3 Multistandard Base Station Indoor The MBI3/MBI5 are indoor cabinets that support both omnidirectional and sectorized configurations. There are two variants, where the allowed configurations are determined by the type of external power supply used by the cabinet: DC power supply variant AC power supply variant. The following figure shows the position of the main modules for both variants. Top FANUs Connector Area STASR 5

Top FANUs Connector Area STASR 5

FANUs

FANUs

FANUs

Air Inlet

Air Inlet

STASR 4

Dummy Panel STASR 3

STASR 4

SUM, ANYs and ANCs, BATS (option)

SUM, ANYs and ANCs

STASR 3

Up to 4 TREs

Air Inlet STASR 4

Top FANUs Connector Area

STASR 5

Up to 4 TREs

Up to 4 TREs

Top FANUs Connector Area

Dummy Panel STASR 3

SUM, ANYs and ANCs

Dummy Panel STASR 3

DC: TREs, ANC AC: ADAM, 2 or 3PM12s, BATS (Option)

Up to 4 TREs

Up to 4 TREs

Up to 4 TREs

FANUs

FANUs

FANUs

FANUs

Air Inlet

Air Inlet

Air Inlet

Air Inlet

STASR 2

STASR 2

DC: SUM, ANYs, ANCs AC: SUM, ANCs

Dummy Panel STASR 1

STASR 2

SUM, ANYs and ANCs

DC: Up to 4 TREs

ADAM, 3 PM12s, SUM, ANC

Dummy Panel

FANUs

Dummy Panel STASR 1

STASR 2

ADAM, 3 PM12s, SUM, ANC BATS (option)

STASR 1 Up to 4 TREs

Up to 4 TREs

AC: SUM, TREs

FANUs

FANUs

FANUs

Air Inlet

Air Inlet

Air Inlet

MBI3 − AC or DC Variant

MBI5 − DC Variant

Large batteries fitted into special battery tray

Empty Space

MBI5 − AC Variant with or w/o BATS MBI5 − AC Variant with large BBU

Figure 200: MBI3/MBI5 Module Positions

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3.3.1 DC Power Supply Variant The DC variant of the cabinets is designed to house up to three or five STASRs. The odd-numbered subrack positions each contain up to four TREs. STASR2 contains the SUM and a mixture of ANY and ANC modules, as required. STASR4 can contain only a mixture of ANY or ANC modules, as well as microwave communications modules. Cooling is provided by FANUs situated at the base of each of the odd-numbered subracks and also at the top of the cabinets.

3.3.2 AC Power Supply Variant The AC variant of the MBIs uses a backup battery which can be housed internally or externally: If an internal battery is used, the MBI3 holds two and the MBI5 holds four STASRs. STASR1 contains the SUM, three PM12s and the ADAM. STASR2 and 4 each contain up to four TREs. STASR3 contains up to two ANCs, and optionally, up to two microwave communications modules If an external battery is used, the MBI3 hold three and the MBI5 holds five STASRs. The battery tray at the bottom of the MBI is replaced by a STASR which contains up to four additional TREs. In this case FANUs are installed under this STASR. Cooling is provided by FANUs situated at the base of each of the subracks containing TREs and the power control subrack.

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3.3.3 MBI Cabinet Access and Features The following figures show the MBI3/MBI5 equipped with the interconnection panel and three or five empty subracks.

3.3.3.1 MBI3 Cabinet Top Fan Unit AC Input RF Interface Interconnection Area

RF Interface Equipment Label

Perforated Door Strips

STASR

Adjustable Feet

Figure 201: MBI3 Equipped with Empty Subracks

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3.3.3.2 MBI5 Cabinet Top Fan Unit AC Input RF Interface Interconnection Area

RF Interface Equipment Label

Perforated Door Strips

EMC Gasket

STASR Note that the AC variant may replace the bottom STASR with a battery tray containing BU101

Adjustable Feet

Figure 202: MBI5 Equipped with Empty Subracks

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3.3.3.3 Construction The MBI3/MBI5 are steel box constructions with four adjustable feet on the underside, to compensate for any unevenness in the floor. The cabinets have no side access; all cable interfaces are accessible from the front or the top of the cabinets. The structure and dimensions of the mechanical rack and equipment comply with IEC 297 standards.

3.3.3.4 Door The MBI3/MBI5 can be installed in back-to-back or back-to-wall configurations. Access to the subracks and the interconnection panel is via a door at the front of the cabinet. The door is the full height of the cabinet.

3.3.3.5 Cables All external cables, except for the antenna and AC supply, are connected to the interconnection panel. The external cables include DC supply and Abis connections. The antenna cabling and AC supply are connected at the top of the cabinet. A ribbon cable is used within the cabinet to link the subracks together; see the following figure. The top end of the cable terminates on the TFBP (refer to Top Fan Unit (Section 11.1.3) for more information). The bottom end terminates on the BTSRI board (refer to Remote Inventory (Section 8.5) for more information). If an internal battery is used in the AC variant, the ribbon cable also connects to the RIBAT (refer to RIBAT (Section 12.29) for more information). MBI5 AC variant

DC variant

TFBP Subrack

Subrack

MBI3 DC variant

Subrack

AC variant

Subrack

Subrack

Ribbon Cable

Subrack

Subrack

Subrack Rear

Front

Subrack

Subrack

Subrack

Subrack

Subrack

Subrack

Subrack

Subrack or Battery Tray BTSRI

RIBAT in case of battery

FANU in case of subrack

Figure 203: MBI3/MBI5 Subracks Interconnection Cable

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3.3.3.6 Cabinet Top The following figure is a top view of the MBI3/MBI5, showing antenna connectors, AC main filter terminal, fan cover and ground bolt. The cover is cut away to reveal extractor fans. The fans are installed and removed via the front of the cabinet. AC Filter with new Fixation Panel

Fan Cover

Top Fans (x6)

Top Fan Backplane

Ground Bolt M8

Antenna labelling on the roof

Antenna labelling on the roof

Q ANT A

N ANT A

Q ANT B

N ANT B

R ANT A (*)

Auxiliary3 x N antenna blocks (microwave)

R ANT B

P ANT B

P ANT A

Antenna Connectors

External Input Board Multistandard BTS Connection Area Blind XIBM Plate MSCA

Power Supply and Circuit Breaker Area

Hole for SMA connector GPS

(*) Auxiliary 3 x 7/16 antenna blocks Note: Antenna connectors are not necessary completely equipped.

Figure 204: MBI3/MBI5 Top View The antennas are connected to RF connectors at the top of the cabinet. An M8 bolt is also located on the top for connecting the cabinet to ground. Any unequipped holes are fitted with a blanking plate. The MBI3/MBI5 AC variant has an AC filter set in the roof plate next to the antenna connectors on the left side. The filter has terminals for connection to a 230 VAC 1Ø supply.

3.3.3.7 Cooling The MBIs are air cooled by fans, inside the cabinet and additionally at the top. Cool air is drawn in through perforations on the door and is then forced up, through the subracks, by the internal fans. The warm air is expelled through perforations at the top of the cabinet by the top fans. Refer to Temperature Control (Section 11) for details of the cooling system hardware.

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3.3.4 MBI3/MBI5 Cabinet Interconnection Panels All the external electrical interfaces are located on front-facing panels at the top of the cabinet. The following figures show the details of the MBI3/MBI5 interconnection panels. The exception is the AC mains input, which is located in the cabinet roof. AC mains input terminals are part of the AC mains filter. The filter is located next to the antenna connectors, see Figure 204.

External Interface Connectors

DC Output

GND +12 V

External Clock Interface Group Abis Interface Group

Equipment Labels

Abis 3

Abis 1

Abis 4

Abis 2

DC Output −48 V/500 W max

DC Filter Connectors

−48V

XCLK1 Out

Equipment Labels

Power Supply and Circuit Breaker Area DCBR3

Multistandard Connection Area MSCA

XCLK1 In

External Alarm Input Board Multistandard XIBM

0V

DC OUT 500 W max

XCLK2 In/Out

XBCB

Abis 4 I Abis 3 I Abis 2 I Abis1 I

I

I

I

0 0 0 0 INT & SR1 SR2 SR3 DC OUT RS232

XRT

Krone Strip

Abis Relays

Circuit Breakers

Extension Area (Blind Plate)

Figure 205: MBI3 Interconnection Panels

GND +12 V

External Clock Interface Group Abis Interface Group

Equipment Labels

Abis 3

Abis 1

Abis 4

Abis 2

DC Output −48 V/500 W max

DC Filter Connectors

−48V

XCLK1 Out

Equipment Labels External Interface Connectors DC Output

Power Supply and Circuit Breaker Area DCBR5

Multistandard Connection Area MSCA

XCLK1 In

External Alarm Input Board Multistandard XIBM

0V

DC OUT 500 W max

XCLK2 In/Out

XBCB

Abis 4 I Abis 3 I Abis 2 I Abis1 I

I

I

I

I

I

0 0 0 0 0 0 INT & SR1 SR2 SR3 SR4 SR5 DC OUT

XRT

RS232

Krone Strip

Abis Relays

Extension Area (Blind Plate)

Circuit Breakers

Figure 206: MBI5 Interconnection Panels

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On the left-hand side of the interconnection area (see figures above) is the External Alarm Input Board Multistandard XIBM, followed by the Multistandard Interconnection Area MSCA in the middle. An extension area is covered with a blind plate. The power supply input/output connectors and circuit breakers are located on DCBR3/DCBR5 on the right-hand side. The XIBM contains a 12 V DC/DC converter and interface circuitry for external alarms on the back side of the panel. The interconnection panels provide interfaces for: Signals External alarms External clock Abis. DC Power supplies.

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3.3.5 MBI Signal Interfaces The MBI has XIBM, MSCA clock and MSCA Abis signal interfaces. The connectors and functions for each of these interfaces are described below.

3.3.5.1 XIBM Interface Connectors The XIBM interface connectors are listed in the following table. External Alarm Interface

’Mini Combicon’ connectors XI 1 and XI 2 provide an interface for connecting 16 external alarm inputs. Each input alarm is reported to the OMC-R where it is mapped to customer-defined ASCII text. The ASCII text describes the particular alarm. Each alarm input has two adjacent pins associated with it on the XI connector. If these pins are open-circuit (open loop), an alarm is generated. So every unconnected input alarm is bridged by a short circuit on the plug-in connector. For test purpose, it is possible with software to pull the alarm inputs on active or inactive level in order to check them.

DC Output

The DC Output Connector provides a + 12 VDC power source for external alarm devices that require a power supply. The GND connector is used when attaching the external alarm 12 VDC ground to the BTS A9100 ground. If the connector pins are not short-circuited (open loop), the input and output alarms are isolated from the BTS A9100 ground.

XBCB

The XBCB connector provides an external interface to the internal BCB: If the BTS is powered, the XBCB can be used to control external devices (e.g., AC/DC power supply, batteries or to provide additional I/O signals) If the BTS is not powered, the XBCB can be externally powered. Then the direction of the interface is reversed so that it can be used for remote inventory of the whole BTS. This feature is used only at factory level. The signal levels are according to RS-485. An EEPROM is used to store the remote inventory data of the XIBM.

Table 24: XIBM Interface Connectors

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The XI connectors allow various external alarm devices to be connected to the BTS A9100. These include smoke and flood detectors, as well as electro-mechanical switches. Crimped or clamp strip contacts can be used on the XI connectors. The positions of the XI connectors are shown in Figures 205 and 206.

XI1 GND XI2 GND XI3 GND XI4 GND XI5 GND XI6 GND XI7 GND XI8 GND

A detailed view of the XI connectors is given in the following figure.

XI9 GND XI10 GND XI11 GND XI12 GND XI13 GND XI14 GND XI15 GND XI16 GND

XI 1

XI 2

Figure 207: MBI External Alarm Interface Connectors

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3.3.5.2 MSCA Clock Interface The MSCA external clock interface provides connectors for a variety of functions; see Figures 205 and 206. The connectors are described in the following table. XRT

The XRT connector provides access to the BTS A9100 via an asynchronous serial interface. The signal levels conform to CCITT V.24. This allows a standard terminal to be used for radio supervision and loop-test purposes. The data rate is programmable between 1200 and 115,000 baud. Only transmit and receive lines are used. Hardware flow control is not implemented. Drivers and control of the XRT interface are located on the SUMA.

RS-232

The RS-232 connector provides an asynchronous serial interface to control and supervise an external GPS receiver or an antenna tilt signal. The signal levels conform to CCITT V.24. The data rate is programmable between 1200 and 115,000 baud. Only transmit and receive lines are used. Hardware flow is not implemented. This interface can also be used to synchronize the BTS A9100 to the GPS receiver or another external clock reference. These signal lines are according to RS-422 Drivers and control of the RS-232 interface are located on the SUMA.

XCLK

The XCLK connectors are used to synchronize the BTS A9100 to another BTS (G1 BTS, G2 BTS, BTS A9100) in time and frequency or vice versa. The signaling interface conforms to RS-422. There are three XCLK connectors: XCLK1IN: input XCLK1OUT: output XCLK2IN/OUT: bi-directional interface. The input XCLK1IN and the output XCLK1OUT are connected together, pin-to-pin. The XCLK2IN/OUT connector provides a bi-directional clock interface. Bus drivers and control logic are located on the SUMA.

Table 25: MSCA External Clock Interface Connectors

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3.3.5.3 MSCA Abis Interface The MSCA Abis Interface provides components for a variety of functions; see Figures 205 and 206. The interface consists of the connectors described in the following table. Abis Connectors

The Abis Interface connects the BTS A9100 to the BSC. There are four connectors, these are Abis1 , 2, 3 and 4. All connectors provide 120 and 75 impedances. The impedance is selected by the type of cable connector plugged into the interface. Note: Only Abis1 and 2 are currently used; Abis 3 and 4 are provided for future use.

Krone Strip Connector

The Krone strip supports an overvoltage protection device and an Abis monitoring device. The overvoltage protection device is a ’make-before-break’ type. This means there is no interruption of service during insertion and removal of the inserts.

Abis Relays

Four relays, one for each Abis Interface, are controlled by the SUMA. The relays can be used to: Perform loop-back tests on the individual Abis Interfaces Provide transparent routing of the Abis traffic when the BTS A9100 is powered down or faulty. This ensures that the Abis connection is not broken in multidrop configurations.

Table 26: MSCA Abis Interface Connectors

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3.3.6 MBI External Power Supply Interfaces The external power supply inputs/outputs to/from the MBI3/MBI5 are located on top of the AC mains filter fitted in the roof of the cabinet or on the power supply and circuit breaker area DCBR3/DCBR5, see Figures 201 and 202. The components are listed in the following table. AC Filter

There is one AC filter connector, for the 230 VAC 1Ø input.

DC Filters

There are two DC filter connectors; one for the 0 V input and one for the -48/ -60 VDC input.

Circuit Breakers

Four (MBI3) or six (MBI5) hydraulic-magnet type DC circuit breakers protect the MBI equipment from overload. Each subrack power supply is protected by a separate circuit breaker. See Figures 205 and 206.

DC Output

A 3-pin D-type connector provides -48 VDC supply at 500 W max. to two optional Microwave Communication Modules or external transmission equipment, pylon lightning, etc.

Table 27: MBI, DC and AC Power Supply Interface

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3.3.7 MBI Power Supply and Grounding 3.3.7.1 MBI DC Variant The MBI DC variants are powered from a -48/ -60 VDC external power source. Power is distributed to the cabinet via two filtered input connectors; see the following figures. Ground DC Input 0V (M8 Bolt)

DC Input −48 V

DC Output −48 V / 500 W max

DCBR3

0 VDC Filter

−48/−60 VDC Filter

Clamp Panel (not on DCBR3)

Circuit Breakers INT & DC OUT

SR3

SR2

SR1

XIBM

15 A

Top Fan Backplane

30 A STASR3

30 A STASR2

30 A STASR1

BUS Bar

BUS Bar

Figure 208: MBI3 DC Power Interconnections DC Input −48 V

Ground DC Input DC Output 0V (M8 Bolt) −48 V / 500 W max

DCBR5

0 VDC Filter

−48/−60 VDC Filter Clamp Panel (not on DCBR5)

Circuit Breakers INT & DC OUT

SR5 SR4

SR3

SR2

SR1

XIBM 15 A Top Fan Backplane

STASR 5

STASR 4

STASR 3

STASR 2

STASR 1

BUS Bar

30 A

30 A

30 A

30 A

30 A

BUS Bar

Figure 209: MBI5 DC Power Interconnections

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Each subrack has: A filtered input of -48/ -60 VDC A filtered 0 V return A ground connector A circuit breaker. The XIBM and TFBP have the same inputs as the subracks. The following table shows the rated values for the power components. Items

Component/Rating

0 and -48/ -60 VDC Filters

4 µF capacitors, rated at 75 A

Circuit Breakers 1 - 3 (MBI3)

30 A

Circuit Breakers 1 - 5 (MBI5) Circuit Breaker 4 (MBI3)

15 A

Circuit Breaker 6 (MBI5) Table 28: MBI Power Component Ratings The MBIs are EMC-protected at both cabinet and module level. At cabinet level, the MBIs are connected to ground via a cable terminated on top of the cabinet with an M8 bolt. At module level, ground continuity is carried to the subracks via the cabinet bus bar. The bus bar also distributes the DC voltages to the subracks and other MBI equipment.

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3.3.7.2 MBI AC Variant The following figures show the power supply distribution for the AC variant of MBI5. MBI3 AC variants are similar (only fewer circuit breakers and STASRs), but it is not possible to install a large internal backup battery (no BU101 possible, only BATS). The presence of the battery depends on the power supply option selected: MBI without backup battery MBI with an internal backup battery MBI with an external backup battery. AC Filter

AC I nput

OMU

PM12/3

PM12/2

PM12/1

ADAM 0 VDC Ground (M8 Bolt)

−48 VDC DC Output

DCBR5 0 VDC Filter

−48V/−60 VDC Filter

Circuit Breakers

XIBM 15 A

Top Fan Backplane

STASR 5

STASR 4

STASR 3

STASR 2

STASR 1 BUS Bar

30 A

30 A

30 A

30 A

30 A

BUS Bar

Figure 210: MBI5 AC Variant Power Supply System w/o Battery

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AC Filter

AC I nput

OMU

PM12/3

PM12/2

PM12/1

Back panel

ADAM Front side

LOAD 0 VDC

Ground (M8 Bolt)

−48 VDC

BATT −48 VDC Battery Breakers

DC Output

DCBR5 0 VDC Filter

−48V/−60 VDC Filter

Optional internal Battery Unit

+ − Battery

RIBAT

Circuit Breakers to BCB

XIBM 15 A

Top Fan Backplane

STASR 5

STASR 4

STASR 3

STASR 2

STASR 1 BUS Bar

30 A

30 A

30 A

30 A

30 A

BUS Bar

Figure 211: MBI5 AC Variant Power Supply System with Internal Battery

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AC Filter

AC I nput

OMU

PM12/3

PM12/2

PM12/1

Back panel

ADAM Front side

Ground (M8 Bolt)

LOAD 0 VDC

−48 VDC

BATT −48 VDC Battery Breakers

DC Output

DCBR5 0 VDC Filter

GND

−48V/−60 VDC Filter

Optional external Battery Unit −

+ Battery

RIBAT

Circuit Breakers XBCB

XIBM 15 A

Top Fan Backplane

STASR 5

STASR 4

STASR 3

STASR 2

STASR 1 BUS Bar

30 A

30 A

30 A

30 A

30 A

BUS Bar

Figure 212: MBI5 AC Variant Power Supply System with External Battery

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The AC input is 230 VAC 1Ø. The AC input is connected to the AC filter, where it is filtered and passed to three PM12s. The mains power connection to each PM12 is via a flying socket. The three PM12s convert the AC input to 0/ -48 VDC. Refer to PM12 (Section 12.14) for a description of the PM12. Up to three PM12s are used in a MBI; these are PM12/1 to PM12/3. Control of the output DC voltage level for battery charging and testing is provided by the OMU via the BCB. Charge/discharge current is monitored via a shunt in the ADAM. The ADAM acts as an interface between PM12s, batteries and power distribution inside the BTS. Refer to ADAM (Section 12.21) for a detailed description of the ADAM and for a functional description of the power supply system. In the MBI3, DC power is distributed in the BTS via the DCBR3 and the bus bar. The DCBR3 contains four circuit breakers, three for STASRs 1 - 3 and one for the XIBM and top fan unit. In the MBI5, DC power is distributed in the BTS via the DCBR5 and the bus bar. The DCBR5 contains six circuit breakers, five for STASRs 1 - 5 and one for the XIBM and top fan unit. The MBIs are EMC-protected at both cabinet and module level. At cabinet level, the MBIs are connected to ground via a cable terminated on top of the cabinet with an M8 bolt. At module level, ground continuity is carried to the subracks via a bus bar system. The cables are terminated with FASTON, Mate-N-Lock and spade connectors.

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3.3.8 MBI Cables and Cable Sets This section lists the cables and cable sets for all BTS A9100 MBI configurations. For the physical and electrical descriptions of the discrete cables see Cable Descriptions (Section 17). For some of the cables and cable sets, there exist different variants. For the variants used in a specific cabinet, refer to its parts list.

3.3.8.1 Internal Cables The MBI internal cables consist of the discrete cables and cable sets. The following table lists the cables and cable sets, Table 30 lists and describes the cables that comprise the cable sets. Mnemonic

Description

Part Number

ADABA

ADABA connects the battery via breakers to ADAM. It includes a cable for the battery temperature sensor.

3BK 25146

ADABM

ADABM connects the -48 VDC filter to a clamp panel. In combination with CA-PCAN, it connects to the circuit breakers of DCBR3/DCBR5.

3BK 25139

BTSRI3

The BTS Remote Inventory Board with Cable for MBI3 is a flat cable and a PCB. It interconnects the subrack backplanes and the TFBP. A BTSRI board is permanently attached to one end of the flat cable.

3BK 025973

BTSRI5

The BTS Remote Inventory Board with Cable for MBI5 is a flat cable and a PCB. It interconnects the subrack backplanes and the TFBP. A BTSRI board is permanently attached to one end of the flat cable.

3BK 025974

CA-ADCO

The CA-ADCO disables eight alarm inputs. It connects to an XIO connector on the Interconnection Panel.

3BK 07953

CABATS

CABATS connects the small battery unit BATS to ADAM.

3BK 25873

CA-PCAN

CA-PCAN connects the ADAM or the -48 VDC filter (on DCBR3/DCBR5) to the DC breakers on DCBR3/DCBR5.

3BK 25115

CA-PCAP

CA-PCAP connects the 0 VDC filter (on DCBR3/DCBR5) to ADAM.

3BK 25114

CS02

CS02 is an AN cable set. It connects an ANY to another ANY or to an ANC.

3BK 07598

CS03

CS03 is a TRE cable set.

3BK 07599

It connects a TRE to an ANC. CS04

CS04 is an ANT cable set. It connects an ANC to two antenna cabinet connectors.

3BK 07600

CS05

CS05 is the MSCA-to-SUM cable set. It interconnects the SUM and the MSCA. The cable set carries the Abis1 and Abis2 Interfaces, and clock and control signals to and from the SUM.

3BK 07199

Table 29: MBI Internal Cables

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3.3.8.2 Cable Sets The following table describes the cables contained in each MBI cable set. Cable Sets

Mnemonic

Description

Part Number

Qty

ADABA

CA-ADABM

CA-ADABM connects -48 VDC from ADAM to the battery breaker.

3BK 25139

1

CA-ADABP

CA-ADABP connects 0 VDC from ADAM to the battery breaker.

3BK 25138

1

CA-BABRM

CA-BABRM connects -48 VDC from the battery breaker to the battery interconnection area.

3BK 25141

1

CA-BABRP

CA-BABRP connects 0 VDC from the battery breaker to the battery interconnection area.

3BK 25140

1

CA-BSENS

CA-BSENS connects the battery temperature sensor to RIBAT.

3BK 08119

1

RXRC

The RXRC connects an ANY RX connector to an ANC or another ANY RX connector.

3BK 07920

2

TXRC

The TXRC connects an ANY TX connector to an ANC or another ANY TX connector.

3BK 07919

1

RXRC

The RXRC connects a TRE RX connector to an ANY or ANC RX connector.

3BK 07920

2

TXRC

The TXRC connects a TRE TX connector to an ANY or ANC TX connector.

3BK 07919

1

CS04

ANIC

The ANIC provides a duplex connection between the ANC and a cabinet antenna connector.

3BK 07921

2

CS05

CA-ABIS

The CA-ABIS carries the Abis1 /2 Interfaces from the MSCA to the SUM.

3BK 07922

1

CA-BTSCA

The CA-BTSCA carries clock and control signals between the MSCA and the SUM.

3BK 07923

1

CS02

CS03

Table 30: MBI Cable Sets

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3.3.8.3 External Cables The MBI external cables consist of discrete cables that are listed and described in the following table. Mnemonic

Description

Part Number

AC Supply

This AC power supply cable can be made on-site to the desired length. The cable used is a single-pair, 4 mm sq. power cable.

1AC 00170 0012

Antenna Jumper

Antenna jumpers, 1 m/ 2 m/ 3 m/ 5 m length, HCF1/ 2, 2 x 7/ 16 straight male connectors. They connect the BTS to the main antenna cables.

3BK 05360

CA01

CA01 is a 120 PCM cable. It provides the Abis1 and Abis2 connections between the BTS A9100 Interconnection Panel MSCA and the customer’s 2 Mbit/s PCM distribution board.

3BK 07594

This cable can be replaced by one made on-site to the desired length. The cable used is L907, an 8-pair, shielded, 2 Mbit/s, 120 PCM cable.

1AC 01328 0004

CA02 is a 75 PCM cable. It provides the Abis1 and Abis2 connections between the BTS A9100 Interconnection Panel MSCA and the customer’s 2 Mbit/s PCM distribution board.

3BK 07595

This cable can be replaced by one made on-site to the desired length. The cable used is Flex3, a multicoaxial, 2 Mbit/s, 75 PCM cable.

1AC 00110 0011

A shorting plug, SP2M is used with Flex3, for impedance matching.

3BK 08949

CA-CBTE

CA-CBTE is the BTS Terminal cable. It connects the BTS Terminal to the BTS Terminal connector on the SUM.

3BK 07951

CA-GC35

CA-GC35 is the cabinet ground cable. It connects to the M8 ground bolt on the cabinet, and to the customer’s ground point.

3BK 08031

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq. yellow/green power cable.

1AC 01723 0003

CA PC2W16 is a -48/ 0 VDC cabinet power cable. It connects the DC connectors on the DCBR3/DCBR5 and the customer’s DC power source.

3BK 08029

This cable can be replaced by one made on-site to the desired length. The cables used are a 16 mm sq. blue power cable and a 16 mm sq. black power cable.

1AC 00147 0001 (Blue)

CA02

CAPC2W16

CA-PC35BK CA PC35BK is a 0 VDC cabinet power cable. It connects the 0 VDC connector on the DCBR3/DCBR5 and the customer’s 0 VDC power source.

CA -PC35BL

1AC 00147 0002 (Black) 3BK 08030

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq. black power cable.

1AC 01723 0001

CA PC35BL is a -48 VDC cabinet power cable. It connects the -48 VDC connector on the DCBR3/DCBR5 and the customer’s -48 VDC power source.

3BK 08032

This cable can be replaced by one made on-site to the desired length. The cable used is a 35 mm sq. blue power cable.

1AC 01723 0002

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Mnemonic

Description

Part Number

External Alarms

This cable can be made on-site to the desired length. The cable used is L907, an 8-pair, shielded, 2 Mbit/s, 120 PCM cable.

1AC 01328 0001

SCG2/3

SCG2/3 is a clock synchronization cable. It connects a G2 BTS to the BTS A9100.

3BK 08101

SCG3

SCG3 is a clock synchronization cable. It connects a BTS A9100 to another BTS A9100.

3BK 07950

SCM1/3

SCM1/3 is a clock synchronization cable. It connects a G1 BTS Mark 1 to the BTS A9100.

3BK 08102

SCM2/3

SCM2/3 is a clock synchronization cable. It connects a G1 BTS Mark 2 to the BTS A9100.

3BK 08103

Table 31: MBI External Cables

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3.3.9 MBI Data and Control Cabling The following figures show the logical interconnections provided by data and control cables. CA GC35, CA PC2W16, CA PC35BK, CA PC35BL

CA01/02

TFBP

SCG2/3, SCG3, SCM1/3, SCM2/3

CA−ADCO

BTSRI3 DC

XIBM/MSCA

STASR 3 Backplane

CS05

CA−CBTE

STASR 2 Backplane SUM

STASR 1 Backplane

BTSRI

Figure 213: MBI3 Data and Control Cabling

TFBP

STASR 5 Backplane CA GC35, CA PC2W16, CA PC35BK, CA PC35BL

CA01/02 STASR 4 Backplane

SCG2/3, SCG3, SCM1/3, SCM2/3 CA−ADCO

XIBM/MSCA

DC STASR 3 Backplane

CS05

CA−CBTE STASR 2 Backplane SUMA

STASR 1 Backplane

BTSRI5 BTSRI

Figure 214: MBI5 Data and Control Cabling

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4 Outdoor Cabinets This chapter describes the outdoor cabinets used in BTS A9100 configurations. The sections are supported with diagrams and illustrations if necessary.

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4.1 Outdoor Cabinets General Information There are four classes of outdoor cabinets available to house the BTS A9100 equipment: COME/CODE - three-door outdoor cabinet COMI/CODI/CPT2/MBO2/MBO2E/MBO2EDC - two-door outdoor cabinet COEP/MBOE/MBOEDC/MBOEEDC - one-door outdoor extension cabinet MBO1/MBO1DC/MBO1T/MBO1E/MBO1EDC - one-door outdoor cabinet CBO - one-door outdoor cabinet. The COEP is designed to allow the extension in the field of a COMI to a COME and a CODI to a CODE. The MBOE/MBOEE is designed to extend an MBO1/MBO1E to an MBO2/MBO2E. The MBOEDC/MBOEEDC is designed to extend an MBO1DC/MBO2EDC to an MBO2DC/MBO2EDC. All outdoor cabinets support both omnidirectional and sectorized configurations. The following figures show the possible positions of the main modules. The positions of the modules in the subracks are configuration dependent; for more information, refer to Configurations - Rack Layouts (Section 2). COME/COMI/CODE/CODI/CPT2 cabinets have two or three compartments: Side compartment BTS compartment 1 BTS compartment 2. MBO1/MBO1E/MBO2/MBO2E cabinets have one or two compartments: MBO1/MBO1E MBOE/MBOEE. MBO1DC/MBO1EDC/MBO2DC/MBO2EDC cabinets have one or two compartments: MBO1DC/MBO1EDC MBOEDC/MBOEEDC. The MBO1T and CBO cabinets have one compartment.

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4.1.1 COME/COMI/COEP with Modules COME COMI Service Light and AC Power Socket

Side Compartment

COEP

BTS Compartment 1

BTS Compartment 2

Equipment Labels Door Alarms Override Key Switch

Electricity Meter Option

ACSB

Option

STASR 5

DCDP

Interconnection Panel SRACDC or ACSR

STASR 2

STASR 4

Document Holder STASR 1

BTSRIOUT

STASR 3

Smoke Detector Service Light and AC Power Socket (not neces sarily equipped)

Not neces sarily equipped

Door Alarm Switch (installation on upper or lower posi tion)

Battery (2 BU41s or BU100) Flood De tector (installation on left or right posi tion)

Front View

HEAT2

HEAT2

HEAT2

HEAT2

HEAT2

HEX2

HEX2

HEX2

Top View

Figure 215: COME/COMI/COEP Module Positions

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4.1.2 CODE/CODI/COEP with Modules CODE CODI

Service Light and AC Power Socket Equipment Labels Door Alarms Override Key Switch (Bus−bar)

Side Compartment

COEP

BTS Compartment 1

BTS Compartment 2 Smoke Detector

ACSU STASR 3

STASR 6

Options or 2nd Battery

STASR 2

STASR 5

Battery

STASR 1

STASR 4

STASR 7

Interconnection Panel Document Holder

LPFU

Door Alarm Switch

Flood Detector

BTSRIOUT

Front View

HEAT2 HEX2

HEAT2

HEAT2

HEX2

HEX2

Top View

Figure 216: CODE/CODI/COEP Module Positions

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4.1.3 CPT2 with Modules Service Light and AC Power Socket Equipment Labels Door Alarms Override Key Switch (Bus−bar)

Side Compartment

BTS Compartment 1 Smoke Detector

ACSU STASR 6 STASR 3

OUTC Document Holder

Door Alarm Switch

STASR 5 STASR 2

Battery

STASR 4

LPFU Flood Detector

Front View

HEAT2

HEAT2 HEX2

HEX2

Top View

Figure 217: CPT2 Module Positions

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4.1.4 MBO1 with Modules Service Light Smoke Detektor AC Switch Unit (ACMU) LPFM

ADAM4

STASR 7 HEX Breaker Options Area (e.g. Microwaves)

STASR 3 Batteries

Document Holder Battery Cover

Door Alarms Override Key Switch

OUTC STASR 2

Batteries

STASR 1

Door Alarm Switch Flood Detector

Front View

HEAT2

HEX4

Top View

Figure 218: MBO1 Module Positions

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4.1.5 MBO1DC with Modules Service Light Smoke Detektor DC Connection Unit (DCMU)

HEX Breaker Options Area (e.g. Microwaves)

STASR 3

Door Alarms Override Key Switch

OUTC STASR 2

STASR 1

Door Alarm Switch Flood Detector

Front View

HEATDC

HEX4

Top View

Figure 219: MBO1DC Module Positions

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4.1.6 MBO1E with Modules Service Light

Document Holder

Options Area (e.g. Microwaves)

Smoke Detektor

HEX Breaker STASR 3 Door Alarms Override Key Switch

Batteries

STASR 2 OUTC

Battery Cover

ACDUE

STASR 1

PM 18

Door Alarm Switch Flood Detector

Front View

HEAT2

HEX9

Top View

Figure 220: MBO1E Module Positions

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4.1.7 MBO1EDC with Modules Service Light

Document Holder

Options Area (e.g. Microwaves)

Smoke Detektor

HEX Breaker STASR 3 Door Alarms Override Key Switch

Options Area (e.g. Microwaves)

DCDUE

STASR 2 OUTC

STASR 1

Door Alarm Switch Flood Detector Front View

HEATDC

HEX9

Top View

Figure 221: MBO1EDC Module Positions

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4.1.8 MBO1T with Modules AC Switch Unit Tropical (ACMUT) LPFMT ADAM 4

STASR 7 HEX Breaker Options Area (e.g. Microwaves)

STASR 3 Batteries Document Holder Battery Cover

OUTC STASR 2

Batteries

STASR 1

Door Alarm Switch

Front View

HEX4

Top View

Figure 222: MBO1T Module Positions

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4.1.9 MBO2 with Modules MBO2

Service Light

MBOE

MBO1

Smoke Detektor AC Switch Unit (ACMU) LPFM ADAM4

STASR 7

STASR 0

Options Area (e.g. Microwaves)

HEX Breaker

Door Alarms Override Key Switch STASR 3

STASR 6

Batteries OUTC Document Holder Battery Cover

STASR 2

STASR 5

Batteries

Door Alarm Switch STASR 1

STASR 4 Flood Detector

Front View

HEAT2

HEAT2 HEX4

HEX3

Top View

Figure 223: MBO2 Module Positions

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4.1.10 MBO2E with Modules MBO2E

Service Light

MBOEE

MBO1E

Smoke Detektor Document Holder HEX Breaker

STASR 3

STASR 6

Options Area (e.g. Microwaves)

Batteries

STASR 2

Door Alarms Override Key Switch

STASR 5

ACDUE

OUTC

Battery Cover STASR 1

STASR 4

Batteries

Door Alarm Switch Flood Detector

PM 18

Front View

HEAT2 HEAT2 HEX9

HEX8

Top View

Figure 224: MBO2E Module Positions

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4.1.11 MBO2DC with Modules MBO2DC

Service Light

MBOEDC

MBO1DC

Smoke Detektor DC Connection Unit (DCMU)

HEX Breaker

Options Area (e.g. Microwaves)

Door Alarms Override Key Switch STASR 3

STASR 6

OUTC

STASR 2

STASR 5

Door Alarm Switch STASR 1

STASR 4 Flood Detector

Front View

HEATDC

HEAT2 HEX4

HEX3

Top View

Figure 225: MBO2DC Module Positions

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4.1.12 MBO2EDC with Modules MBO2EDC

Service Light

MBOEEDC

MBO1EDC

Smoke Detektor Document Holder HEX Breaker

STASR 3

STASR 6

Options Area (e.g. Microwaves)

Options Area (e.g. Microwaves)

STASR 2

Door Alarms Override Key Switch

STASR 5

DCDUE

OUTC

STASR 1

STASR 4

Door Alarm Switch Flood Detector

Front View

HEATDC HEATDC HEX9

HEX8

Top View

Figure 226: MBO2EDC Module Positions

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4.1.13 COBO with Modules CBO

Options Area (e.g. Microwaves)

Door Switch

DCUC ACUC OUTC

STASR 2

LPFC

ADAM 2

External Batteries Breaker STASR 1

Cables Entry

Front View

HEAT3

HEX5

Top View

Figure 227: CBO Module Positions

4.1.14 Side Compartment The side compartment is designed to house AC/DC power equipment and provide an external cables connection point. All external cables, except RF cables, enter the side compartment. The layout of the Side Compartment differs for COME/COMI and CODE/CODI/CPT2 versions.

4.1.14.1 COME/COMI At the top of the compartment is room for an optional electricity meter. An ACSB provides AC distribution and circuit breakers for the incoming AC mains supply. The ACSB also provides lightning protection for the AC supply lines. The SRACDC or ACSR houses the modules that convert the AC mains supply into a 0/-48 VDC supply. Between the side compartment and BTS compartment 1 is the Interconnection Panel. This provides connectors for DC supplies, and for the external Abis, alarm and clock cables.

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4.1.14.2 CODE/CODI AC mains power is applied to the LPFU located at the bottom of the side compartment. The LPFU provides lightning protection for the AC supply lines and HF filtering for the incoming AC supply. At the top of the side compartment is the ACSU which provides AC distribution. The ACSU contains AC circuit breakers and a thermostat with the associated power relays. Directly underneath the ACSU a STASR contains the ADAM and three PM12s. There is also provision for optional microwave equipment. Above the batteries on the floor, an additional BU41 or BU100 can be fitted. Between the side compartment and BTS compartment 1 is the Interconnection Panel. This provides connectors for DC supplies, and for the external Abis, alarm and clock cables.

4.1.14.3 CPT2 AC mains power is applied to the LPFU located at the bottom of the side compartment. The LPFU provides lightning protection for the AC supply lines and HF filtering for the incoming AC supply. At the top of the side compartment is the ACSU which provides AC distribution. The ACSU contains AC circuit breakers and a thermostat with the associated power relays. Directly underneath the ACSU a STASR contains the ADAM and three PM12s. Directly above the batteries a STASR contains up to four TREs and three FANUs. At the right side of the compartment is the Outdoor Control Board (OUTC). It contains the XIOB, BTSRI, RIBAT and COAR functions and provides connectors for DC supplies, temperature sensor, and for the external Abis, alarm and clock cables.

4.1.14.4 Common Features Other equipment items include: BOSU for power distribution. In the CODE, circuit breakers are provided in the BOSU for isolating the DC supply from the XIOB, HEX2, STASR7 and the Power Distribution Units HEAT2 on the floor in the COME and on the lower left side panel in the CODE/CPT2 Two optional BU41s or one BU100 on the floor in the COME. The CODE has one BU41 or one BU100 on the floor; and an additional BU41 or BU100 can be fitted above (as an option) Document holder on the side panel Equipment labels on the side panel HEX2 on the inside of the door Door alarm switch on the side frame Door alarm override key switch on the side frame (COME/COMI) or on the bus-bar (CODE/CODI/CPT2) Service light, AC power socket at the top.

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4.1.15 BTS Compartment 1 The equipment contained in compartment 1 in the COME/COMI and CODE/CODI/CPT2 cabinets is described below. COME/COMI

A COME/COMI BTS compartment 1 holds two STASRs. The lower subrack (STASR1) contains up to four TREs and three FANUs. The upper subrack (STASR2) holds the SUM and a mixture of ANX or ANY modules, as required.

CODE/CODI/CPT2

A CODE/CODI/CPT2 BTS Compartment 1 holds three STASRs. The top and bottom subracks contain up to four TREs and three FANUs each. The middle subrack holds the SUM and a mixture of ANC and ANY modules as required.

In addition, all BTS compartment 1s have the following common equipment: Up to two HEAT2s on the floor for COME/COMI, one HEAT2 for CODE/CODI/CPT2 HEX2 on the inside of the door Door alarm switch on the side frame Flood detector on the floor RF lightning protectors in the floor Smoke detector on the ceiling Service light and an AC power socket at the top. The method used for DC supply isolation depends on the compartment type: For the COME/COMI, there are two possibilities: The DCDP above the upper subrack. Circuit breakers are provided for isolating the DC supply from the STASRs, HEX2s, XIOB and optional microwave link equipment. The optional equipment is housed above the DCDP Circuit breakers are provided in the BOBU for isolating the DC supply from the STASRs, HEX2s, XIOB and optional microwave link equipment. The optional equipment is housed above the upper subrack (STASR2). In the CODE/CODI/CPT2, circuit breakers are provided in the BOBU for isolating the DC supply from the STASRs and HEXxs.

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4.1.16 BTS Compartment 2 BTS compartment 2 holds three STASRs. The upper and lower subracks each contain up to four TREs and three FANUs. The middle subrack contains a mixture of ANX, ANY or ANC modules, as required. Other equipment includes: For COME, up to two HEAT2s on the floor; one HEAT2 for CODE HEX2 on the inside of the door Door alarm switch on the side frame RF lightning protectors in the floor Service light and an AC power socket at the top (not necessarily equipped).

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4.1.17 MBO1 MBO1 is designed to house AC/DC power equipment. All external cables enter the MBO1 at roof top. AC mains power is applied to the LPFM located at the left upper side of the MBO1 compartment. The LPFM provides lightning protection for the AC supply lines and HF filtering for the incoming AC supply. At the left upper back side of the compartment is the ACMU which provides AC distribution. The ACMU contains AC circuit breakers and a thermostat with the associated power relays. Underneath the ACMU optional modules (e.g., microwaves) are installed. The batteries (BU101) are located directly underneath these optional modules. There is a specific battery box which contains two batteries in an upper and two batteries in a lower block. All batteries are connected in series. To the right of the batteries and the optional modules, a rack frame is installed which contains four STASRs. The top STASR (STASR7) contains ADAM4 and two, three or four PM12s. STASR1 (bottom) contains up to four TREs and three FANUs. STASR2 above contains a mixture of SUMA, ANY and ANC modules as required. STASR3 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. At the right side of the compartment is the Outdoor Control Board (OUTC). It contains the XIOB, BTSRI, RIBAT and COAR functions and provides connectors for DC supplies, temperature sensor, and for the external Abis, alarm and clock cables. Other equipment includes: BOMU for power and alarm distribution in MBO1/MBOE. Circuit breakers are provided in the BOMU for isolating the DC supply from the XIOB, HEX3/HEX4, STASRs and the Power Distribution Units HEX4 on the inside of the door HEAT2 at the back of the front door underneath HEX4 Document holder in the cover of the battery box Equipment labels on the side panel Door alarm switch on the side frame Door alarm override key switch (part of BOMU) Service light, AC power socket, and smoke detector at the top Flood detector on the floor.

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4.1.18 MBO1DC MBO1DC is designed to house DC power equipment. All external cables enter the MBO1DC at roof top. DC mains power is applied to the DCMU located at the left upper side of the MBO1DC compartment. The DCMU provides DC distribution inside the cabinets. It contains DC circuit breakers and a thermostat with the associated power relays. Underneath the DCMU optional modules (e.g., microwaves) are installed. Directly underneath these optional modules is an empty area. To the right of the empty area and the optional modules, a rack frame is installed which contains three STASRs. STASR1 (bottom) contains up to four TREs and three FANUs. STASR2 above contains a mixture of SUMA, ANY and ANC modules as required. STASR3 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. At the right side of the compartment is the Outdoor Control Board (OUTC). It contains the XIOB, BTSRI and COAR functions and provides connectors for DC supplies, temperature sensor plug SENSP, and for the external Abis, alarm and clock cables. Other equipment includes: BOMU for power and alarm distribution in MBO1DC/MBOEDC. Circuit breakers are provided in the BOMU for isolating the DC supply from the XIOB, HEX3/HEX4, STASRs and the Power Distribution Units HEX4 on the inside of the door HEATDC at the back of the front door underneath HEX4 Equipment labels on the side panel Door alarm switch on the side frame Door alarm override key switch (part of BOMU) Service light DC and smoke detector at the top Flood detector on the floor.

4.1.19 MBO1T MBO1T is designed to house AC/DC power equipment. All external cables enter the MBO1T at roof top. AC mains power is applied to the LPFMT located at the left upper side of the MBO1T compartment. The LPFMT provides lightning protection for the AC supply line and HF filtering for the incoming AC supply. At the left upper back side of the compartment is the ACMUT which provides AC distribution. The ACMUT contains an AC circuit breaker. Underneath the ACMUT optional modules (e.g., microwaves) are installed. The batteries (BU101) are located directly underneath these optional modules. There is a specific battery box which contains two batteries in an upper and two batteries in a lower block. All batteries are connected in series.

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To the right of the batteries and the optional modules, a rack frame is installed which contains four STASRs. The top STASR (STASR7) contains ADAM4 and two or three PM12s. STASR1 (bottom) contains up to four TREs and three FANUs. STASR2 above contains a mixture of SUMA, ANY and ANC modules as required. STASR3 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. At the right side of the compartment is the Outdoor Control Board (OUTC). It contains the XIOB, BTSRI, RIBAT and COAR functions and provides connectors for DC supplies, temperature sensor, and for the external Abis, alarm and clock cables. Other equipment includes: BOMUT for power and alarm distribution in MBO1T. Circuit breakers are provided in the BOMUT for isolating the DC supply from the XIOB, HEX4, STASRs and one Power Distribution Units HEX4 on the inside of the door Document holder in the cover of the battery box Equipment labels on the side panel Door alarm switch on the right bottom side.

4.1.20 MBO1E MBOE1 is designed to house AC/DC power equipment. All external cables enter the MBO1E at bottom plate. AC mains power is applied to the ACDUE located at the left lower side of the MBO1E compartment. The ACDUE provides lightning protection for the AC supply lines and HF filtering for the incoming AC supply. The ACDUE provides also AC distribution, AC circuit breakers and a thermostat with the associated power relays. Behind the ACDUE optional modules (e.g., microwaves) or batteries are installed. There is a specific battery box which contains two batteries in an upper and two batteries in a lower block. All batteries are connected in series. A secong battery branch can be installed on top of the first one. To the right of the batteries and the optional modules, a rack frame is installed which contains three STASRs and the power supply subrack. STASR1 (bottom) contains up to four TREs and three FANUs. STASR2 above contains a mixture of SUMA, ANY and ANC modules as required. STASR3 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. At the right side of the compartment is the Outdoor Control Board (OUTC). It contains the XIOB, BTSRI, RIBAT and COAR functions and provides connectors for DC supplies, temperature sensor, and for the external Abis, alarm and clock cables. Other equipment includes:

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BOMUE for power and alarm distribution in MBO1E/MBOEE. Circuit breakers are provided in the BOMUE for isolating the DC supply from the XIOB, HEX8/HEX9 or DAC8/DAC9, STASRs and the Power Distribution Unit HEX9/DAC9 on the inside of the door HEAT2 on the bottom plate of MBO1E rack Document holder in the cover of the battery box Equipment labels on the side panel Door alarm switch on the side frame Door alarm override key switch (part of BOMUE) Service light, AC power socket, and smoke detector at the top Flood detector on the floor.

4.1.21 MBO1EDC MBO1EDC is designed to house DC power equipment. All external cables enter the MBO1EDC at bottom of the rack. DC mains power is applied to the DCDUE located at the left lower side of the MBO1EDC compartment. The DCDUE provides DC distribution inside the cabinets. It contains DC circuit breakers and a thermostat with the associated power relays. Behind DCDUE optional modules (e.g., microwaves) can be installed. To the right of the empty area and the optional modules, a rack frame is installed which contains three STASRs. STASR1 (bottom) contains up to four TREs and three FANUs. STASR2 above contains a mixture of SUMA, ANY and ANC modules as required. STASR3 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. At the right side of the compartment is the Outdoor Control Board (OUTC). It contains the XIOB, BTSRI and COAR functions and provides connectors for DC supplies, temperature sensor plug SENSP, and for the external Abis, alarm and clock cables. Other equipment includes: BOMUE for power and alarm distribution in MBO1EDC/MBOEEDC. Circuit breakers are provided in the BOMUE for isolating the DC supply from the XIOB, HEX8/HEX9, STASRs and the Power Distribution Unit HEX9 on the inside of the door HEATDC on the bottom plate of MBO1EDC rack Equipment labels on the side panel Door alarm switch on the side frame Door alarm override key switch (part of BOMUE) Service light DC and smoke detector at the top Flood detector on the floor.

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4.1.22 MBOE An MBOE holds four STASRs. The top subrack (STASR0) can be used for optional 19” units. The bottom subrack (STASR4) contains up to four TREs and three FANUs each. STASR5 above contains a mixture of ANC and ANY modules as required. STASR6 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. Other equipment includes: HEX3 on the inside of the door HEAT2 at the bottom on the right side frame Door alarm switch on the side frame RF lightning protectors in the roof Service light and an AC power socket at the top.

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4.1.23 MBOEDC An MBOE holds three STASRs. STASR0 use was cancelled. In the free space above STASR6, optional 19“ equipment can be fitted. The bottom subrack (STASR4) contains up to four TREs and three FANUs each. STASR5 above contains a mixture of ANC and ANY modules as required. STASR6 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. Other equipment includes: HEX3 on the inside of the door HEATDC at the bottom on the right side frame Door alarm switch on the side frame RF lightning protectors in the roof Service light at the top.

4.1.24 MBOEE An MBOEE holds three STASRs and optional equipment. The bottom subrack (STASR4) contains up to four TREs and three FANUs each. STASR5 above contains a mixture of ANC and ANY modules as required. STASR6 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. Other equipment includes: HEX8/DAC8 on the inside of the door HEAT2 on the bottom plate on MBOEE Door alarm switch on the side frame RF lightning protectors in the bottom plate.

4.1.25 MBOEEDC An MBOEE holds three STASRs and optional equipment. The bottom subrack (STASR4) contains up to four TREs and three FANUs each. STASR5 above contains a mixture of ANC and ANY modules as required. STASR6 above contains up to four TREs or a mixture of TREs and an ANC and three FANUs each. Other equipment includes: HEX8 on the inside of the door HEATDC at the bottom on the right side frame Door alarm switch on the side frame RF lightning protectors in the bottom plate Service light at the top.

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4.1.26 CBO 4.1.26.1 CBO AC Variant CBO is designed to house two TREs with up to two ANCs and an optional BATS module. Above the STASRs, up to three 19” units can be installed. All external cables enter the CBO at the right side of the cabinet where the cables entry is located. AC mains power is applied to the LPFC located above the cable entry of the CBO cabinet. The LPFC provides lightning protection for the AC supply lines and HF filtering for the incoming AC supply. Above the LPFC is the ACUC which provides AC distribution. The ACUC contains AC circuit breakers, a thermostat and an AC power socket. The DCUC, which provides DC distribution, is located above the ACUC. At the top of the rack space is foreseen for options installation. A maximum of three MW units can be installed. The bottom STASR (STASR1) contains the ADAM2, two PM12s, SUMA and up to two TREs and three FANUs. STASR2 above contains the BATS and up to two ANC modules. At the right side of the compartment is the Outdoor Control Board (OUTC). It contains the XIOB, BTSRI, RIBAT and COAR functions, temperature sensor, and for the external Abis, alarm and clock cables. Other equipment includes: HEX5 on the inside of the door HEAT3 under the STASR1 Equipment labels on the side panel Door alarm switch on the side frame Degasing filtered holes are foreseen at the top and the bottom of the cabinet Two holes are foreseen at the bottom of the door for water outlet from HEX5.

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4.1.26.2 CBO DC Variant CBO is designed to house four TREs with up to three ANBs. When three ANBs are used only three TREs can be equipped. Above the STASRs, up to three 19” units can be installed. All external cables enter the CBO at the right side of the cabinet where the cables entry is located. DC mains power is applied to the DC filter located at the cable entry of the CBO cabinet. The DCUC, which provides DC distribution, is located above the cables entry. At the top of the rack space is foreseen for options installation. A maximum of three MW units can be installed. The bottom STASR (STASR1) contains the SUMA and up to three TREs, or up to four TREs and three FANUs. STASR2 above contains the SUMA and up to two ANBs or up to three ANB modules. At the right side of the compartment is the Outdoor Control Board (OUTC). It contains the XIOB, BTSRI, RIBAT and COAR functions, temperature sensor, and for the external Abis, alarm and clock cables. Other equipment includes: HEX5 on the inside of the door HEAT4 under the STASR1 Equipment labels on the side panel Door alarm switch on the side frame Two holes are foreseen at the bottom of the door for water outlet from HEX5.

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4.2 Outdoor Cabinet Access and Features The following figures show the BTS A9100 outdoor cabinets without subracks.

4.2.1 COME/COMI/CODI/CODE Cabinet Access Alternative Door Style

Side Compartment

BTS Compartment 1 Hinged Outer Roof Subrack Mounting Rail BTS Compartment 2 Lifting Ring

Inner Roof (flat on CODE/CODI) Bolt and Washer

Interconnection Panel

RIBAT (CODE/ CODI only)

Cable Entry Plate COME/COMI: Perforated Panel, carries COAR CODE/CODI: Part of Panel, carries COAR and RIBATs

Guiding Channel

Cabinet Joining Brackets

Antenna Connectors Plinth Side Panel

Cabinets joined by four M8 Bolts. Guiding Channel used for tool ac cess from side of cabinet

Removable Panel

Figure 228: BTS A9100 Outdoor Cabinet Construction

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4.2.2 CPT2 Cabinet Access Hinged Outer Roof

Side panel

Outdoor Control Board (OUTC)

Figure 229: BTS A9100 Outdoor Cabinet Construction CPT2

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4.2.3 MBO1/MBO1DC/MBO1T/MBO1E Cabinet Access

Figure 230: Multistandard BTS Outdoor Cabinet Construction MBO1/MBO1DC/MBO1T

Figure 231: Multistandard BTS Evolution Outdoor Cabinet Construction MBO1E

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4.2.4 MBO2/MBO2DC/MBO2E Cabinet Access

Figure 232: Multistandard BTS Outdoor Cabinet Construction MBO2/MBO2DC

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Figure 233: Multistandard BTS Evolution Outdoor Cabinet Construction MBO2E

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4.2.5 CBO Cabinet Access

Figure 234: Compact BTS Outdoor Construction CBO

4.2.6 Outdoor Cabinet Features The main design features of the outdoor cabinets are listed below: Cabinet extensibility on site Cabinet dismountable on site for easier manual transportation Front access to BTS equipment only Side walls removable - thus extended cabinet without partition wall inside Easy removable roof, socle panels (except for MBO1/MBO2/CBO) and heat exchanger Double-skinned wall (except for CBO) and roof Cooling by air/air heat exchanger (generic) Environmental- and EMC-protected.

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4.2.6.1 Construction Each BTS A9100 compartment consists of a box-shaped frame bolted to a plinth. Other components are added to this basic construction, as required. Two or three compartments are bolted together. The method of joining the cabinets is different for each variant. One COME/COMI variant uses joining brackets fixed to the sides and bottom of the cabinet frame. Another COME/COMI variant and CODE/CODI/CPT2/MBO1/MBO1DC/MBO1T/MBO1E/MBO2/MBO2DC/MBO2E use four M8 bolts in the corners of the cabinet with guiding channels at the rear of the cabinet to help locate the fixing tool and bolts. The COME/COMI side compartment and BTS Compartment 1 are separated by perforated panels which prevents RF interference from entering the side compartment. Similar panels are used in CODE/CODI/CPT2/MBO1/MBO2 but only as a structural element and support for COAR and RIBATs (CODE/CODI) or OUTC (CPT2/MBO1/MBO1DC/MBO1E/MBO2/MBO2DC/MBO2E). The space between BTS Compartments 1 and 2 is open. Each compartment has a separate rear panel. In the COME/CODE, the side compartment and BTS Compartment 2 each have a side panel. In the COMI/CODI/CPT2, the side compartment and BTS Compartment 1 each have a side panel. In the MBO1/MBO1DC/MBO1T, the compartment has two side panels. In the MBO2/MBO2DC, MBO1/MBO1DC and MBOE/MBOEDC have a side panel each.

4.2.6.2 Roof The outer roof of each compartment can be raised at the front and unhinged at the rear for removal. This reveals an inner roof (flat on CODE/CODI/CPT2/MBOx/MBOxDC/MBOxE) and four lifting rings. Each outer roof must be removed, in turn, from right to left. On MBOx/MBOxDC roofs, a label warns to lift the top cover with care in windy conditions.

4.2.6.3 Door All the BTS A9100 cabinets can be installed in back-to-back or back-to-wall configurations. Access to each compartment is via a door at the front. The door provides both an environmental and EMC seal when closed. Mounted on the inside of the door is a HEXx. Above (COME/COMI/CBO) or under (CODE/CODI/CPT2/MBO1/MBO1DC/MBO1E/MBO2/MBO2DC/MBO2E) the HEXx is a latch mechanism for keeping the door open during maintenance. Each door contains a door lock opened by a key. Each door presses an electronic switch. All door switches are serially connected. In the side compartment or MBO1/MBO1DC/MBO1E compartment, there is another mounted electronic switch, the so-called door alarm override switch, which uses the same key as the side compartment or MBO/MBODC compartment door lock. It ensures that non-authorized opening of the doors leads to an alarm. Not less than 0.8 m free space must be left in front of the cabinet doors, and 0.1 or 0.2 m at the side and back.

4.2.6.4 Subracks The subracks are secured to two vertical mounting rails. The rails are positioned on the left and right sides of each compartment. Refer to Standard Telecommunications Subrack (Section 6) and AC Power Subracks (Section 7) for detailed information on STASR, SRACDC, and ACSR, respectively.

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4.2.6.5 External Cable Entry All external cables, including antenna cables, enter the cabinet via the cable entry plate or from below the plinth. The plate can be fitted to the front or left side of the side compartment plinth. The outward-facing sides of the plinths are covered by removable panels. For the MBO1/MBO1DC/MBO1T/MBO2/MBO2DC, the side panel has a variable notch on the bottom or top so that all external cables can be passed through. If the external cables come directly from the BTS socket, the notch is not needed and can be closed. There is a space between the side panel and internal rack construction to take in the cables. The cables are fixed at the side of the internal rack and led to the top where they enter the cabinet. For the CBO, the cables entry has an adjustable cover plate that must be removed so that the cables can be passed through it.

4.2.6.6 Internal Interconnections Internal power and signal connections between the side compartment and BTS compartment 1 are made via the interconnection panel or the outdoor control board (CPT2). Internal signal connections between MBO1 and MBOE are made via the outdoor control board. The interconnection panel also contains a PCB. Refer to Outdoor Cabinet Interconnection Panel COMI/COME/CODI/CODE (Section 4.3) for detailed information on the interconnection panel. The outdoor control board performs the functions of four boards: the COAR, XIOB, BTSRI, and RIBAT. Refer to Outdoor Cabinet Signal Interfaces (Section 4.4) for detailed information. BTS compartments 1 and 2 have RF connectors fitted to the floor. These are for antenna cabling.

4.2.6.7 STASR Ribbon Cable In the COME/CODE only, a ribbon cable is used in the cabinet to link the STASRs together. The ribbon cable is in two parts, joined by the BTSRIOUT board between them. One cable part connects to the subracks in BTS compartment 1, and the other to the subracks in BTS compartment 2. Refer to Remote Inventory (Section 8.5) for information on the Remote Inventory function.

4.2.6.8 Heating and Cooling Heating is provided by HEAT2/HEAT3/HEATDC if the internal air temperature is below 10 C. Above this temperature, module cooling is provided by FANUs. If the temperature increases above 20 C, the HEXxs switch on. As the temperature rises further, the HEXx fan speed increases. HEXxs transfer heat from the cabinet interior to the outside air environment. Refer to HEX2 (Section 11.2), HEX3/HEX4 (Section 11.3), HEX5 (Section 11.4), HEX8/HEX9 (Section 11.5), HEAT2 (Section 11.7), HEAT3 (Section 11.8) and HEATDC (Section 11.10) for detailed information.

4.2.6.9 Cabinet Installation All the BTS A9100 cabinets can be installed in back-to-back or back-to-wall configurations. Access to the subracks and the interconnection panel is via a door at the front of the cabinet. Not less than 0.8 m free space must be left in front of the cabinet doors.

4.2.6.10 Additional Outdoor Cabinet Features The outdoor cabinets include the following additional features.

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4.2.6.11 Adjustable Feet Adjustable feet are provided in each corner of the compartment (MBO1/MBO1DC/MBO2/MBO2DC) or compartment plinth for levelling the cabinet.

4.2.6.12 Wind Load The cabinet is designed to withstand a wind load of 180 km/h.

4.2.6.13 Smoke Detector An optical smoke detector is fitted to the inner roof plate of the MBO1, on the right side wall of MBO1E or BTS compartment 1 (COME/COMI/CODE/CODI/CPT2). In case of smoke inside the BTS, an alarm is raised.

4.2.6.14 Flood Detector A flood detector is fitted to the bottom plate of the MBO1 or BTS compartment 1 (COME/COMI/CODE/CODI/CPT2). If water enters the BTS above the bottom plate, an alarm is raised.

4.2.6.15 Service Light/AC Power Socket In each compartment a service light with an integral 230 VAC power socket is fitted (not necessarily equipped in BTS compartment 2). If needed, the service light can be switched on by the service staff.

4.2.6.16 Document Holder At the left side wall inside of the side compartment and MBO1E a document box is mounted to store A4 documents. In MBO1 the document holder is fitted on the cover of the battery box.

4.2.6.17 Extensibility The BTS cabinet COMI can be extended on site to COME by adding an additional BTS cabinet COEP at the right hand side. The same applies to extend a CODI to a CODE by adding a COEP. An MBO1/MBO1DC/MBO1E/MBO1EDC cabinet can be extended on site to MBO2/MBO2DC/MBO2E/MBO2EDC by adding an MBOE/MBOEDC/MBOEE/MBOEEDC. MBO1T cabinet is not extendible.

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4.3 Outdoor Cabinet Interconnection Panel COMI/COME/CODI/CODE All the power and signal connections between the side compartment and BTS compartment 1 are made via the interconnection panel for COME/COMI/CODE/CODI (via OUTC for CPT2). The following figure shows the details when viewed from the side compartment. CODE/CODI

COME/COMI AC Connectors RIBAT1

Heater

Light

COAR

COAR Ground

DC Connectors −48 V (Blue)

0 V (Red)

(Viewed from Side Compartment)

RIBAT2 −48 V (Blue)

0 V (Black)

(Viewed from Side Compartment)

Figure 235: BTS A9100 Outdoor, Interconnection Panel The interconnection panel carries the components listed in the following table. COME/ COMI

CODE/ CODI

Two filter connectors to provide 230 VAC power for HEAT2, service light and AC power socket in BTS compartment 1.

X

-

0/ -48 V power distribution

X

-

-

X

M8 ground bolt.

X

-

Connectors for RIBAT1 and RIBAT2.

-

X

Status and control signals via the COAR.

X

X

Components

Two filters with M6 bolt connectors for DC power distribution by the DCDP or One filter with one M6 bolt connector (-48 VDC) and one M6 bolt (0 VDC) for DC power distribution by the BOBU. One Feed through terminal HDFKV25 (-48 VDC) and one M6 bolt (0 VDC) for DC power distribution.

Table 32: BTS A9100 Outdoor, Interconnection Panel Components

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4.3.1 Interconnection Panel - COME/COMI COAR Front View The following figure shows the COME/COMI COAR, viewed from the side compartment. Ext−Alarms

External Input/ Output Interface Group

Surge Protectors Alarms Side Comp X303 XI17−24

XBCB

XGND XRT External Clock Interface Group

XCLK2 In/Out

XGPS

HEX Power

Equipment Labels

XCLK1 In Abis 4

XCLK1 Out

Abis 3

Abis Interface Group

Abis 2 Abis Relays Abis 1 Krone Strip

Figure 236: COME/COMI COAR Front View The shaded areas in the above figure identify separate external interface groups. All these interfaces are overvoltage protected.

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4.3.2 Interconnection Panel - CODE/CODI COAR Front View The following figure shows the front view of the CODE/CODI COAR. Alarms Side Comp

Ext−Alarms External Input/ Output Interface Group

EBCB Surge Protectors

X303 XI17−24

XBCB

XGND Equipment Labels

XRT External Clock Interface Group

XCLK2 In/Out

XGPS

XCLK1 In Abis 4

XCLK1 Out

Abis 3

Abis Interface Group

Abis 2 Abis Relays Abis 1 Krone Strip

Figure 237: CODE/CODI COAR Front View

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4.3.3 Interconnection Panel - BTS A9100 Outdoor Rear View

ALARM BTS2

ALARM BTS1

The following figure shows the rear view of the COME/COMI and CODE/CODI COAR.

COME/ COMI only

ABIS 1+2

ABIS1

ABIS2

SUM

ABIS 3+4

HEX Power

Figure 238: BTS A9100 Outdoor COAR Rear View Located behind the COAR (BTS compartment 1 side) is the XIOB. The XIOB is connected to the COAR and contains a 24 V DC/DC converter and interface circuitry for external alarms. The COAR provides interfaces for: XIO External clock Abis Miscellaneous connections.

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4.4 Outdoor Cabinet Signal Interfaces The outdoor cabinet has XIO, external clock and Abis signal interfaces. It also has a miscellaneous connections interface. The connectors and functions for each of these interfaces are described below.

4.4.1 XIO The XIO connectors allow various alarm devices to be connected to the BTS A9100. These include smoke and flood detectors, as well as electro-mechanical switches. Crimped or clamp strip contacts can be used on the XIO connectors. The positions of the XIO connectors are shown in Figures 236, 237 and 239. The XIO interface connectors are described in the following table. External Alarm Inputs

The Ext-Alarms connector provides an interface for three external alarms. These are alarms that are external to the cabinet (for example, an antenna lamp failure alarm) and the inputs are protected by surge arresters. The three external alarms are part of a group of 16 alarms which includes the pre-wired smoke detector, door switches, etc. The 16 alarms are reported to the OMC-R via the SUM. At the OMC-R, the alarms are mapped to predefined and customer-defined ASCII text. The ASCII text describes the particular alarm. Each external alarm input has two adjacent pins associated with it on the Ext-Alarms connector. If these pins are open-circuit (open loop), an alarm is generated.

Additional Alarm Inputs

Connector XI17-24 provides an interface for connecting eight additional non-BTS alarm inputs. Each additional alarm is reported to the OMC-R via the SUM. At the OMC-R, the additional alarms are mapped to customer-defined ASCII text. The ASCII text describes the particular alarm. Each additional alarm input has two adjacent pins associated with it on the XI17-24 connector. If these pins are open circuit (open loop), an alarm is generated.

External Alarm Outputs

Connector X300 provides an interface for the SUM to control eight external alarm devices. This feature is for future use. The SUM is described in Station Unit Modules (Section 8).

+ 24 VDC Supply

Connector X303 provides a + 24 VDC power source for external alarm devices that require a power supply.

+ 5 VDC Supply

Connector X112 provides a + 5 VDC power source for RIBAT.

XGND

The XGND connector is used when referencing the external alarm 24 VDC ground to the BTS A9100 ground. If the connector pins are not short-circuited (open loop), the input and output alarms are isolated from the BTS A9100 ground.

Table 33: BTS A9100 Outdoor Interface Connectors

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4.4.1.1 Pre-Wired Internal Alarms The following table shows a list of the pre-wired internal alarms. These alarms are not configurable.

Pre-wired Internal Alarm

Side Compartment

BTS Compartment 1

BTS Compartment 2

Door alarm*

X

X

X

Door alarm over-ride

X

-

-

Smoke detector alarm

X***

X

-

Float detector alarm

X***

X

-

Heat exchange. alarm*

X **

X

X

Table 34: BTS A9100 Outdoor Pre-wired Internal Alarms * These alarms are serially linked and reported as only one alarm in case of multi-failure. ** When equipped (more than six TREs). *** For MBO1/MBO1DC/MBO2/MBO2DC only.

4.4.1.2 Ext-Alarms Connector The following table shows the pin assignment of the Ext-Alarms connector. The inputs of the Ext-alarms connector are protected by surge arrestors and are configurable. Pin

Description

1

GND (braid earthing clamp)

2

ALM 1 (GND)

3

ALM 1 (ext. alarm no 10)

4

ALM 2 (GND)

5

ALM 2 (ext. alarm no 13)

6

ALM 3 (GND)

7

ALM 3 (ext. alarm no 14)

8

GND (braid earthing clamp)

Table 35: BTS A9100 Outdoor Ext-Alarms Connector

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4.4.1.3 External Alarm Inputs To enhance the capabilities of the BTS A9100 outdoor in terms of coverage, the REK feature may be used (not for CPT2). The REK is composed of two modules, a Masthead Amplification Box and a Power Distribution Unit, but only Power Distribution Unit ensures the alarm interface with the BTS. Up to seven alarms can be reported to the BTS (taking into account that the maximum configuration is six TREs, and that in an outdoor BTS only eight external alarms are available for that purpose). The BTS A9100 outdoor can handle up to 24 external alarms but 8 inputs are not realized so not usable. The remaining 16 external alarms are used as follows: 5 external alarms are connected to internal sensors, not configurable 3 external alarms have protected inputs on dedicated connector and are configurable 8 external alarms on dedicated connector, configurable. The following table gives detailed view of the external alarm inputs. Alarm Description Alarm Number

XIO Input

Alarm Class

Alarm Connection

Alarm Generation

1

1

9

Not used

-

2

2

9

Not used

-

3

3

9

Yes

Inside

4

4

9

Yes

Inside

5

5

9

Yes

Inside

6

6

9

Yes

Inside

7

7

9

Yes

Inside

8

8

9

Not used

-

9

9

9

Not used

-

10

10

9

Yes

Outside

11

11

9

Not used

-

12

12

9

Not used

-

13

13

9

Yes

Outside

14

14

9

Yes

Outside

15

15

9

Not used

-

16

16

9

Not used

-

17

17

9

Yes

Inside (*)

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Alarm Description Alarm Number

XIO Input

Alarm Class

Alarm Connection

Alarm Generation

18

18

9

Yes

Inside (*)

19

19

9

Yes

Inside (*)

20

20

9

Yes

Inside (*)

21

21

9

Yes

Inside (*)

22

22

9

Yes

Inside (*)

23

23

9

Yes

Inside (*)

24

24

9

Yes

Inside

Table 36: BTS A9100 Outdoor External Alarm Inputs (*) Provisions for REK: Masthead Amplification Box and Power Distribution Unit alarms (not for CPT2).

4.4.2 External Clock Interface The external clock interface provides connectors for a variety of functions; see Figures 236, 237 and 239. The connectors are described in Table 10.

4.4.3 Abis Interface The Abis Interface provides components for a variety of functions; see Figures COME/COMI COAR Front View (236), CODE/CODI COAR Front View (237) and OUTC, Front View (239). The interface consists of the connectors described in Table BTS A9100 Abis Interface Connectors (11).

4.4.4 Miscellaneous Connections Interface Connectors are provided for the side compartment, see the following table. Alarms

This includes the door alarm switch and the HEXx alarm.

HEX2 This is the 0/ -48 VDC power supply from the DCDP or BOBU (COME/COMI (depending on COME/COMI variant). only) Table 37: BTS A9100 Outdoor Miscellaneous Connections Interface

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4.5 Outdoor Control Board CPT2/MBO1/MBO1DC/MBO1T/MBO1E/MBO2/MBO2DC/ MBO2E/CBO The Outdoor Control Board (OUTC) performs the functions of the following four separate boards: COAR XIOB BTSRI RIBAT The figure below shows the front part of the OUTC. EBCB (optional)

DC

IN

ALARM INPUTS

EXT − ALARMS

External

Output Interface Group

XBCB

SUN CONNECTION

ALARM OUTPUTS

Input/

SIDE COMPARTMENT ALARMS

External Input/

XRT

Output Interface

XGPS

COMPARTMENT 1 ALARMS

Group

ABIS4

XCLK 2 IN/ OUT

External Clock

XCLK 1 IN

ABIS3

Interface

ABIS 3&4

Interface Group

Interface Group ABIS1

ABIS 1 Remote

Abis

ABIS2

ABIS 1&2

Abis

KRONE CONNECT

XCLK 1 OUT

Group

ABIS 2

FLAT CABLE SIDE COMPARTMENT

Inventory Part FLAT CABLE COMPARTMENT 1

TEMP. SENSOR

RIBAT Port

Figure 239: OUTC, Front View

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All the functions of these four boards are kept except for the following: The output voltage provided on the external output connector is 12 V instead of 24 V. The current per output is limited to 50 mA instead of 100 mA. No galvanic isolation between external inputs/outputs and the BTS. The ’Power Architecture’ of the OUTC is different from that of the earlier boards (see the following figure). Each part of the board is powered by the power supply of the OUTC, even the BTSRI, RIBAT and BCB parts of the XIOB. On the earlier boards, these parts are only supplied via the BCB_VCC.

−48/ 60V

DC

VCC5.5

Linear Regulator

DC

Linear Regulator

External Power Supply

VCC12 5V

VCC_BRI

XBCB_VCC

BCB_VCC

VCC Temp Sensor

SUM

VDD

ALARM INPUTS

XBCB

ALARM Outputs

NGTSL

RIBAT Part NGTSL1 ...2 ...3

BTSRI Part

Driver VCC_BRI

XIOB Part NGTSL

BCB_VCC

BCB_VCC_BP

Figure 240: OUTC, Power Architecture

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4.5.1 Connection Area (COAR) The Connection Area is part of the OUTC. It provides external BTS interfaces which are grouped in three different functional parts: Abis External Clock Interface External Inputs/Outputs.

4.5.1.1 Abis The Abis part provides the external interfaces for four separate Abis links (Abis 1 ... Abis 4). The interface consists of the connectors described in BTS A9100 Abis Interface Connectors (11). The KRONE Strip Connector also provides the possibility to monitor the Abis links. Therefore the overvoltage insert has to be pulled out and has to be replaced by a special monitor insert. The interconnection between the SUMA and the OUTC consists of the following cables: Abis 1, 2 cable

The Abis cable is a four pair, RF shielded cable. It is a 120 cable which is used if the external Abis cables have 120 or 75 . The needed impedance conversion is realized on the OUTC itself.

Abis 3, 4 cable

The Abis cable is a four pair, RF shielded cable. It is a 120 cable which is used if the external Abis cables have 120 or 75 . The needed impedance conversion is realized on the OUTC itself.

OUTC-SUM cable

The OUTC-SUM cable is a flat cable with 37 wires. It is equipped on the SUMA side with a Sub-D connector of 37-pins/male, on the OUTC side with a Sub-D connector of 37-pins/female.

Table 38: Interconnection OUTC - SUMA

4.5.1.2 External Clock Interface The external clock interface provides connectors for a variety of functions. The connectors are described in Table BTS A9100 External Clock Interface Connectors (10).

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4.5.1.3 External Inputs/Outputs The external Input/Output part of the OUTC provides the interfaces for 16 BTS alarm inputs and eight alarm outputs. ’Open’ alarm inputs are interpreted by the BTS as ’alarm on’. Therefore any unconnected input alarm has to be bridged by a short circuit on the plug-in connector. The following table described the external inputs/outputs. On-board Connectors

These are two ’Mini Combicon’ connectors, one Sub-D 9 and one Sub-D 15 connector (to connect five internal BTS alarms, e.g., heat exchanger, door, fire, key, water) and one connector with screws for special protected alarm inputs (three alarms). One of the two ’Mini Combicon’ connectors provides eight alarm inputs; the other one provides the alarm outputs and + 12 VDC voltage.

Plug in Connectors

The insert in these connectors have either clamp strip contacts or crimp contacts. The version with a clamp strip is used for customer with no common interface where no pre-equipped cable can be used. The version with crimp contacts is the solution if the customer has a common interface and pre-equipped cables can be used. Every unconnected input alarm has to be bridged by a short circuit on the plug-in connector.

Alarm Disable Connector

The alarm disable insert consists of a connector with crimp contacts which provides the short circuits for eight alarm inputs. It is inserted in the alarm input connectors which are not connected by an external alarm cable to suppress alarms based on open inputs.

Overvoltage Protection

The OUTC additionally provides surge arrestors for three alarms to protect the circuitry of these inputs. These are on the ’EXT-ALARMS’ connector for external alarm numbers 10, 13, and 14. Alarms 17 to 24 are not protected by special transient or overvoltage components but these inputs have to withstand a 1.2/ 50 1500 V wave. The alarm outputs are protected by bi-directional suppressor diodes.

Table 39: External Inputs/Outputs

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4.5.2 BTSRI The BTS Remote Inventory part of the OUTC is used to store basic information about a BTS in non-volatile memory. Flat cables from compartment 1 and side compartment or MBO1/MBO2 are connected to the BTSRI. The mounting position of the flat cables are located on the bottom of the OUTC (see Figure 239). The following figure shows the block diagram of the BTSRI.

Flat Cable Side Compartment or MBO1

B C B

BCB Driver

NGTSL

EEPROM

p l u s Reset Circuit

Flat Cable BTS Compartment 1 or MBOE

B C B p l u s

Protection Overcurrent

BCB_VCC_BP

Figure 241: Block Diagram of BTSRI The heart of the BTSRI is an NGTSL-ASIC. An EEPROM is used as memory (256 x 16 bits). A reset circuit (MAX 811) is used to reset the ASIC at power on. The BTSRI is either powered via the flat cable (BCB_VCC_BP, provided by the SUMA) or via the power supply of the OUTC board. An overcurrent protection protects the BCB_VCC_BP line. The access to this board can be established via the BCB bus. There are two possibilities to establish a link to the BTSRI: If the BTS is in traffic, the SUM can use the BCB bus as the interface to the BTSRI If the BTS is unpowered, the BTSRI can be accessed by an external tool via the XBCB- (and BCB-) bus. Then the external tool provides the necessary power supply. This feature is used only at factory level. The subrack number is coded on the flat cable with holes. Five wires are reserved on the cable for that purpose. Up to six subracks can be coded which corresponds to the large outdoor configuration.

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4.5.3 XIOB The External Alarm Input and Output Board (XIOB) is used as the interface between the external environment and the BTS. The board provides 16 BTS alarm inputs and eight alarm outputs. These alarms are described in the tables BTS A9100 Outdoor Interface Connectors (33) to BTS A9100 Outdoor External Alarm Inputs (36). The XIOB functions are integrated in the OUTC. The following figure shows the block diagram of the XIOB. 48V in

BCB VCC

12 VDC 5 VDC Overcurrent Protection

12V out

EEPROM 12 VDC

Alarm Inputs NGTSL

1 Outputs

BCB BUS

Bus Driver

NGTSL

2

Alarm Inputs

GND

NGTSL

3

EBCB_VCC

EBCB_SP

Alarm Inputs XBCB_VCC

TTL/ RS485 conversion

XBCB_BUS

Figure 242: Block Diagram of the XIOB Three NGTSLs are used; each NGTSL handles eight alarm inputs. The first NGTSL also controls eight outputs and the EEPROM, which is used to store the remote inventory data of the XIOB. The third NGTSL can be used to pull the alarm inputs to the active or inactive status for test purposes. It is possible to pull the alarm inputs with software on active or inactive level in order to check them. Alarm test 0 pulls all inputs to the inactive status and alarm test 1 pulls all inputs to the active status. The alarm inputs use comparators to detect an alarm. Open alarm inputs are regarded as active. A current of approximately 1 mA flows from the alarm input to ground if the alarm input is pulled to ground. An alarm line must stay longer than 1 ms in the active status in order to be detected as active. The alarm outputs use Darlington transistor arrays with open collectors. No galvanic isolation is provided between inputs/outputs to the BTS. One common ground (GND) is used within the BTS including inputs and outputs.

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The DC/DC converter is switched on if the BCB_VCC (powered by the SUMA) is available. An overcurrent protection protects the BCB_VCC line. A 12 VDC power supply is used to supply input and output circuitry. This power supply can be used to supply relays that can be switched with the outputs. An XBCB interface provides access to the internal base station control bus (BCB): If the BTS is powered, then the interface can be used to control external devices If the BTS is unpowered, the XBCB can be powered externally. Then the direction of the interface is changed so that it can be used for remote inventory of the BTS. This feature is used only at factory level. The signal levels are according to RS-485. An ABTE 16246 is used as the internal BCB driver.

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4.5.4 RIBAT The RIBAT board is part of the battery, but physically integrated in the OUTC. Its task is to measure the battery temperature and to provide the OMU with the temperature value and the battery Remote Inventory information which includes the information of the battery type. Knowledge of the temperature value is necessary for charging. The board contains a BCB interface to transfer the information. The RIBAT is supplied from the BTS not from the batteries. The power consumption is about 30 mA. The operating temperature range of the board is 0 C to 70 C. The connection and addressing differs for different configurations. The following figure shows the RIBAT block diagram. Remote Supply Voltage Input Fixed address 0000 0011 1100 0001 (JC1 hqx )

BCB NGTSL

D A RI EEPROM

Temperature Sensor

Figure 243: RIBAT Block Diagram The board consists of an NGTSL which is the terminal for the ISL data link, the Remote Inventory EEPROM including the Remote Inventory information, and the analog part for temperature measuring. The analog part includes signal conditioning and an ADC to digitize the temperature value. An external PT100 temperature sensor is connected to the analog part. The ADC outputs are connected directly to the NGTSL alarm inputs. Power supply is provided remotely either via the BCB_VCC_BP or the internal power supply of the OUTC. The internal battery of the outdoor BTS is located inside a side compartment. The RIBAT is connected to the BCB via a flat band cable coming from the backplane. The battery temperature range which can be measured is between -10 C and 70 C. This range is extended against the operating temperature range of the batteries (0 C to 50 C) and the minimum operating temperature range of the RIBAT to submit high or low temperature alarms. The measurement resolution is 0.5 C. Values below -10 C means a short cut at the temperature sensor. Values above 70 C means a not-connected or interrupted sensor.

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4.6 Outdoor Cabinet Power Supply and Grounding There are different power supply systems for the COME/COMI, CODE/CODI/CPT2/MBO1/MBO2 and MBO1DC/MBO2DC. These are described in the following sections.

4.6.1 COME/COMI For the COME/COMI there exist two different power supply systems, one based on PM08s with BCU1 and another one based on PM11s with BCU2. Certain elements are common for both variants. The AC input is connected to the ACSB via the optional electricity meter. The ACSB contains lightning overvoltage protectors, input supply fuses, and circuit breakers for AC power distribution. The AC input can be 230 VAC 1Ø or 415 VAC 3Ø. The switched outputs from the ACSB are 230 VAC 1Ø. These are used for: HEAT2s Service light and AC power sockets SRACDC or ACSR. The COME/COMI is grounded by connecting an external ground cable to an M8 bolt fitted to the side compartment plinth. From there, separate ground straps are used to ground the major equipment modules in each compartment.

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4.6.1.1 COME/COMI Power Supply with PM08s and BCU1 The COME/COMI power supply system with PM08s and BCU1 is shown in the following figure. AC Input

Electricity Meter

AC to Heaters, Service Light and AC Power Sockets

ACSB

To/From FANUs

Control

ACIB

Alarms

XBCB ACRI PM08/5

PM08/4

PM08/3

PM08/2

PM08/1

BCU1

Shunt

0 VDC −48 VDC

DC Bus

Shunt

BACO

SRACDC

BU41

Figure 244: COME/COMI AC/DC Power Supply System with PM08s and BCU1 The SRACDC contains the modules that: Convert the AC input to 0/ -48 VDC. Refer to ACIB (Section 12.1) and PM08 (Section 12.12) for detailed descriptions of the ACIB and the PM08s, respectively. Three PM08s are used in the COMI; five PM08s are used in the COME. Control the output DC voltage level for battery charging and testing. Refer to BCU1 (Section 12.16), BACO (Section 12.18) and BU41 (Section 12.24) for detailed descriptions of the BCU1, and the optional BACO and BU41, respectively. The DC supply produced in the SRACDC is connected to the DCDP via the interconnection panel. Refer to DCDP (Section 12.30) for a detailed description of the DCDP.

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4.6.1.2 COME/COMI Power Supply with PM11s and BCU2 The COME/COMI power supply system with PM11s and BCU2 is shown in the following figure. AC Input

Electricity Meter

AC to Heaters, Service Light and AC Power Sockets

ACSB

Control Alarms

To/From FANUs

XBCB PM11/4

PM11/3

PM11/2

PM11/1

BCU2

Shunt

0 VDC −48 VDC

DC Bus

Shunt

BAC2

ACSR

BU41 or BU100

Figure 245: COME/COMI AC/DC Power Supply System with PM11s and BCU2 The ACSR contains the modules that: Convert the AC input to 0/ -48 VDC. Refer to PM11 (Section 12.13) for a detailed description of the PM11s. Three PM11s are used in the COMI; four PM11s are used in the COME Control the output DC voltage level for battery charging and testing. Refer to BCU2 (Section 12.17), BAC2 (Section 12.19), BU41 (Section 12.24), and BU100 (Section 12.25) for detailed descriptions of the BCU2, and the optional BAC2 and BU41 or BU100, respectively. The DC supply produced in the ACSR is connected to the BOBU via the interconnection panel. The ACSB used in combination with PM11s is slightly different from the ACSB used in combination with PM08s. In Figure 245 the ACSB distributes the AC input directly to the PM11s and the ACSB executes the functions normally performed by the ACIB.

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4.6.2 CODE/CODI/CPT2 The CODE/CODI/CPT2 power supply system differs from that of COME/COMI because it is completely integrated in the BTS. The system control functions are performed by the OMU which is part of the SUMA. The following figures show the power supply system for the CODE/CODI/CPT2. AC mains power is applied to the LPFU located at the bottom of the side compartment. The LPFU provides overvoltage lightning protection for the AC supply lines and HF filtering for the incoming AC supply (for a detailed description of the LPFU, refer to LPFU (Section 12.5)). The AC input can be 230 VAC 1Ø or 400 VAC 3 Ø. AC power is then passed to the ACSU located at the top of the side compartment. The ACSU provides AC distribution via seven AC circuit breakers. The switched outputs from the ACSU are used for: Two or three PM12s HEAT2s and optional air conditioning Service Light and AC power sockets. For a detailed description of the ACSU, refer to ACSU (Section 12.9). The CODE/CODI/CPT2 are grounded by connecting an external ground cable to an M8 bolt fitted to the side compartment plinth. From there, separate ground straps are used to ground the major equipment modules in each compartment. AC Input

LPFU

AC to Heaters, Service Light and AC Power Sockets

ACSU

PM12/3

PM12/2

PM12/1

0 VDC ADAM

−48 VDC

DC Bus

STASR

BU41 or BU100 OMU

RIBAT

Figure 246: CODE/CODI/CPT2 AC/DC Power Supply System

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The STASR contains the modules that: Convert the AC input to 0/ -48 VDC. Refer to PM12 (Section 12.14) for a detailed description of the PM12s. Three PM12s are used in the CODE/CODI/CPT2. The operation of the PM12s is controlled by software running in the OMU Sense the output DC voltage level for battery charging and testing. The sense data is passed to the OMU. Refer to ADAM (Section 12.21), BU41 (Section 12.24) and BU100 (Section 12.25) for detailed descriptions of ADAM and the batteries BU41, BU100 and BU101. The DC supply produced in the STASR is connected to the BOSU and BOBU via the interconnection panel. A specific installation set can be used to connect the DC power of the bus bar via external cable entry to external loads like transmission equipment, pylon lightning, etc...

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4.6.3 MBO1/MBO2 The MBO1/MBO2 power supply system differs from that of COME/COMI because it is completely integrated in the BTS. The system control functions are performed by the OMU which is part of the SUMA. The following figure shows the power supply systems for MBO1 and MBO2. AC mains power is applied to the LPFM located at the upper side of the MBO1 compartment. The LPFM provides overvoltage lightning protection for the AC supply lines and HF filtering for the incoming AC supply (for a detailed description of the LPFM, refer to LPFM (Section 12.4)). The AC input can be 230 VAC 1Ø or 400 VAC 3 Ø. AC power is then passed to the ACMU located at the top of the MBO1 compartment. The ACMU provides AC distribution via five AC circuit breakers. The switched outputs from the ACMU are used for: Two to four PM12s in combination with ADAM4 HEAT2s and optional air conditioning Service Light and AC power sockets. For a detailed description of the ACMU, refer to ACMU (Section 12.7). The MBO1/MBOE are grounded by connecting an external ground cable to an M8 bolt fitted to the left upper side of the MBO1 (near LPFM). From there, separate ground straps are used to ground the major equipment modules in each compartment. AC Input

LPFM

PM12/4*

ACMU

PM12/3*

PM12/2

AC to Heaters, Service Light and AC Power Sockets

PM12/1

0 VDC ADAM4 DC Bus

−48 VDC

STASR

BU101 OMU RIBAT

* not necessarily equipped

Figure 247: MBO1/MBO2 AC/DC Power Supply System

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The STASR contains the modules that: Convert the AC input to 0/ -48 VDC. Refer to PM12 (Section 12.14) for a detailed description of the PM12s. Two or three PM12s are used in the MBO1; three or four PM12s are used in the MBO2. The operation of the PM12s is controlled by software running in the OMU Sense the output DC voltage level for battery charging and testing. The sense data is passed to the OMU. Refer to ADAM4 (Section 12.23) and BU101 (Section 12.26) for detailed descriptions of ADAM4 and the BU101 battery. The DC supply produced in the STASR is connected to the BOMU via ADAM4. A specific installation set can be used to connect the DC power of the bus bar via external cable entry to external loads like transmission equipment, pylon lightning, etc...

4.6.4 MBO1DC/MBO2DC The MBO1DC/MBO2DC power supply system differs from that of COME/COMI because it is completely integrated in the BTS. The system control functions are performed by the OMU which is part of the SUMA. The following figure shows the power supply systems for MBO1 and MBO2. DC mains power is applied to the DC In filters located at the upper side of the MBO1DC compartment. DC power is then passed to the DCMU located at the top of the MBO1DC compartment. The DCMU provides DC distribution via four DC circuit breakers. The switched outputs from the DCMU are used for: BTS compartments HEATDCs and optional air conditioning Service Light. For a detailed description of the DCMU, refer to DCMU (Section 12.33). The MBO1DC/MBOEDC are grounded by connecting an external ground cable to an M8 bolt fitted to the left upper side of the MBO1DC. From there, separate ground straps are used to ground the major equipment modules in each compartment. DC Input DC Filter

DCMU

DC to Heaters and Service Light

0 VDC DC Bus

−48 VDC

Figure 248: MBO1DC/MBO2DC Power Supply System The DC supply is connected to the BOMU via the DCMU. A specific installation set can be used to connect the DC power of the bus bar via external cable entry to external loads like transmission equipment, pylon lightning, etc...

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4.6.5 MBO1T MBO1T is derived from MBO1 by reducing the used equipment. The following figure shows the power supply systems for MBO1T. AC mains power is applied to the LPFMT located at the upper side of the MBO1T compartment. The LPFMT provides overvoltage lightning protection for the AC supply line and HF filtering for the incoming AC supply (for a detailed description of the LPFMT, refer to LPFMT (Section 12.3)). The AC input is 230 VAC 1Ø. AC power is then passed to the ACMUT located at the top of the MBO1T1 compartment. The ACMUT provides AC distribution via one AC circuit breaker. The switched outputs from the ACMUT are used for two to three PM12s in combination with ADAM4. For a detailed description of the ACMUT, refer to ACMUT (Section 12.8). The MBO1T is grounded by connecting an external ground cable to an M8 bolt fitted to the left upper side of the MBO1T (near LPFMT). From there, separate ground straps are used to ground the major equipment modules in each compartment. AC Input

LPFCT

PM12/3*

ACMUT

PM12/2

PM12/1

0 VDC ADAM

DC Bus

−48 VDC

STASR

BU101 OMU RIBAT

* not necessarily equipped

Figure 249: MBO1T AC/DC Power Supply System The STASR contains the modules that: Convert the AC input to 0/ -48 VDC. Refer to PM12 (Section 12.14) for a detailed description of the PM12s. Two or three PM12s are used in the MBO1T. The operation of the PM12s is controlled by software running in the OMU Sense the output DC voltage level for battery charging and testing. The sense data is passed to the OMU. Refer to ADAM (Section 12.21) and BU101 (Section 12.26) for detailed descriptions of ADAM and the BU101 battery. The DC supply produced in the PM12 and is connected to the BOMUT via ADAM4. A specific installation set can be used to connect the DC power of the bus bar via external cable entry to external loads like transmission equipment, pylon lightning, etc...

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4.6.6 MBO1E/MBO2E The following figure shows the power supply systems for MBO1E and MBO2E. AC mains power is applied to the ACDUE located at the lower side of the MBO1E compartment (for a detailed description of the ACDUE, refer to ACDUE (Section 12.6)). The AC input can be 230 VAC 1Ø or 400 VAC 3 Ø. AC power is then passed to the switching block located at the middle part of ACDUE. The switching block provides AC distribution via five AC circuit breakers. The switched outputs are used for: One to three PM18 rectifiers supervised by PM18 controller HEAT2s Service Light and AC power socket. The MBO1E/MBOEE are grounded by connecting an external ground cable to an M8 bolt fitted to the left lower side of the MBO1E (near the front left fixing point). From there, separate ground straps are used to ground the major equipment modules in each compartment. AC Input

ACDUE LP Filter

PM18/3

ACDUE Switching

PM18/2

AC to Heaters, Service Light and AC Power Sockets

PM18/1

0 VDC PM18SR DC Bus

−48 VDC

BU101 PM18C RIBAT

Figure 250: MBO1E/MBO2E AC/DC Power Supply System

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The PM18SR contains the modules that: Convert the AC input to 0/ -48 VDC. Refer to PM18 (Section 12.15) for a detailed description of the PM18s. One or two PM18s are used in the MBO1E; two or three PM18s are used in the MBO2E. The operation of the PM18s is controlled by the PM18 controller Sense the output DC voltage level for battery charging and testing. The sense data is passed to the controller. Refer to PM18 (Section 12.15) and BU101 (Section 12.26) for detailed descriptions of PM18 and the BU101 battery. The DC supply produced in the PM18 power supply subrack and is connected to the BOMUE. A specific installation set can be used to connect the DC power of the bus bar via external cable entry to external loads like transmission equipment, pylon lightning, etc...

4.6.7 MBO1EDC/MBO2EDC The MBO1EDC/MBO2EDC power supply system is completely integrated in the BTS. The system control functions are performed by the OMU which is part of the SUMA. The following figure shows the power supply systems for MBO1EDC and MBO2DC. DC mains power is applied to the DC In clamps located in the DCDUE at the lower side of the MBO1EDC compartment. DC power is then passed to the DC In filter located at the bottom of the MBO1EDC compartment. The DCDUE provides DC distribution via four DC circuit breakers. The switched outputs from the DCMU are used for: BTS compartments Service Light HEATDCs and optional air conditioning. For a detailed description of the DCDUE, refer to DCDUE (Section 12.32). The MBO1EDC/MBOEEDC are grounded by connecting an external ground cable to an M8 bolt fitted to the left lower side of the MBO1EDC. From there, separate ground straps are used to ground the major equipment modules in each compartment. DC Input DC Filter

DCDUE

DC to Heaters and Service Light

0 VDC DC Bus

−48 VDC

Figure 251: MBO1EDC/MBO2EDC Power Supply System The DC supply is connected to the BOMUE via the DCDUE.

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A specific installation set can be used to connect the DC power of the bus bar via external cable entry to external loads like transmission equipment, pylon lightning, etc...

4.6.8 CBO 4.6.8.1 CBO AC Variant The CBO power supply system is completely integrated in the BTS. The system control functions are performed by the OMU which is part of the SUMA. The following figure shows the power supply system for the CBO. AC mains power is applied to the LPFC located above the cables entry compartment. The LPFC provides overvoltage lightning protection for the AC supply lines and HF filtering for the incoming AC supply (for a detailed description of the LPFC, refer to LPFC (Section 12.2)). The AC input is 230 VAC 1Ø. AC power is then passed to the ACUC located above the LPFC. The ACUC provides AC distribution via two AC circuit breakers. The switched outputs from the ACUC are used for: Two PM12s in combination with ADAM2 HEAT3 AC power socket. For a detailed description of the ACUC, refer to ACUC (Section 12.10). The CBO is grounded by connecting an external ground cable to an M8 socket fitted to the right upper side of the cables entry. From there, separate ground straps are used to ground all equipment modules. AC Input

LPFC

ACUC

AC to Heater and AC Power Sockets

STASR PM12/2

PM12/1 ADAM2

DC Bus

OMU

0 VDC −48 VDC

BATS or External Batteries RIBAT

Figure 252: CBO AC Variant Power Supply System The STASR contains the modules that: Convert the AC input to 0/-48 VDC. Refer to PM12 (Section 12.14) for a detailed description of the PM12s. Two PM12s are used in the CBO. The operation of the PM12s is controlled by software running in the OMU. Sense the output DC voltage level for battery charging and testing. The sense data is passed to the OMU. Refer to ADAM2 (Section 12.22) and BATS (Section 12.28) for detailed descriptions of ADAM2 and the BATS battery. The DC supply produced in the PM12 is connected to the DCUC via ADAM2. Refer to DCUC (Section 12.34) for a detailed description of DCUC.

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4.6.8.2 CBO DC Variant The CBO DC variant DC power supply distribution differs from that of CBO AC variant. The following figure shows the power supply distribution for CBO DC variant. DC mains power is applied to the DC In filter located above the cables entry compartment. DC power is then passed to the DCDU located at the top of the CBO DC compartment. The DCDU provides DC distribution via five DC circuit breakers. The switched outputs from the DCDU are used for: BTS compartments Optional equipments Heater HEAT4 Heat exchanger HEX5. For a detailed description of the DCDU, refer to DCDU (Section 12.31). The CBO DC varinat is grounded by connecting an external ground cable to an M8 bolt fitted to the left upper side of the MBO1DC. From there, separate ground straps are used to ground the major equipment modules in each compartment. DC Input DC Filter

DCDU

DC to Heater and Heat Exchanger

0 VDC DC Bus

−48 VDC

Figure 253: CBO DC Variant Power Supply System

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4.6.9 Temperature Control How the temperature is controlled in the different cabinets is described in the following sections.

4.6.9.1 COMI, COME, CODI, CODE, MBO, MBOxE The ACSB/ACSU/ACMU contain a relay which is controlled by a thermostat. When the temperature is above -20 C, the AC supply is connected to the AC/DC converters. If the temperature is below -20 C when the BTS A9100 is first switched on, there is no AC supply to the AC/DC converters. This means that the 0/ -48 VDC supply is not available and the BTS A9100 cannot operate. AC power is available only on the HEAT2 to warm-up the cabinet. When the HEAT2 raise the internal cabinet temperature above -20 C, the power relay is activated and the AC supplies are passed to the AC/DC converters. The HEAT2 prevents the internal cabinet temperature from dropping below 0 C. When the internal cabinet temperature rises above 0 C, the SUM switches on the telecommunications modules and the BTS A9100 becomes operational.

4.6.9.2 CBO For CBO AC variant with the ACUC, a permanent connection is maintained up to -33 C. When switched on at minus temperature, both the HEAT3 and AC/DC are powered in time in order to warm up the cabinet to above 0 C. When the internal cabinet temperature rises above 0 C, the SUM switches on the telecommunications modules and the BTS A9100 becomes operational. The HEAT3 prevents the internal cabinet temperature from dropping below 0 C.

4.6.9.3 CBO DC For CBO DC variant with theDCUC, a permanent connection is maintained up to -33 C. When switched on at minus temperature, both the HEAT4 and DC are powered in time in order to warm up the cabinet to above 0 C. When the internal cabinet temperature rises above 0 C, the SUM switches on the telecommunications modules and the BTS A9100 becomes operational. The HEAT4 prevents the internal cabinet temperature from dropping below 0 C.

4.6.9.4 MBO1T As MBO1T is designed to be used in tropical areas only cooling facilities are implemented by HEX4 unit.

4.6.9.5 MBODC/MBOxEDC With the DCMU/DCDUE, a permanent connection is maintained up to -33 C. When switched on at minus temperature, the HEATDC is powered in order to warm up the cabinet to above 0 C. When the internal cabinet temperature rises above 0 C, the SUM switches on the telecommunications modules and the BTS A9100 becomes operational. The HEATDC prevents the internal cabinet temperature from dropping below 0 C.

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4.7 Outdoor Cabinet Lightning Protection Protection against the effects of lightning strikes is provided for external cables, see the following table. External Cable

Lightning Protection

AC Mains Supply

Two types of lightning protectors can be fitted: Medium stage protectors (DIN VDE 0675-6, Class C) are installed in the ACSB for supply lines L1, L2, L3 and N Coarse protectors (DIN VDE 0675-6, Class B) are installed externally if the cabinet is sited in exposed locations. Such locations are, for example, building tops and open fields.

Abis Interface

Medium-stage spark gap overvoltage protection is provided by the Krone strip on the COAR or OUTC.

Three External Alarms

Combined medium stage and fine overvoltage protection is provided by the COAR or OUTC surge protectors. Additional external coarse protection is unnecessary.

Antenna Connectors

Quarter wave (λ/4) lightning protectors are fitted at the bottom of BTS compartment 1 and 2. For detailed information on the lightning protectors, refer to Antenna Connector Lightning Protectors (Section 14).

Table 40: BTS A9100 Outdoor Lightning Protection

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4.8 Outdoor Cabinet Cables and Cable Sets This section lists the cables and cable sets for all BTS A9100 outdoor configurations.

4.8.1 Internal Cables The BTS A9100 outdoor internal cables consist of the discrete cables and cable sets listed in the tables COMI/COME/COEP Outdoor Internal Cables (41) to CPT2 Outdoor Internal Cables (43). Table BTS A9100 Outdoor Cable Sets (46) lists and describes the cables that comprise the cable sets. For the physical and electrical descriptions of the discrete cables, see Cable Descriptions (Section 17). For some of the cables and cable sets there exist different variants. For the variants used in a specific cabinet refer to its accompanying cable list.

4.8.1.1 COMI/COME/COEP Internal Cables COME Mnemonic

Description

Part Number

COMI

COEP

BTSRIOUT

BTSRIOUT is a flat cable which is permanently attached to a BTSRI board. It interconnects the BTS compartment 1 STASR backplanes and the BTSRI.

3BK 08126

X

-

CA-ACSC

CA-ACSC gathers alarms from the side compartment. This consists of the key switch, door switch and HEX2 alarms. The cable connects to the Alarms Side Comp connector on the COAR.

3BK 08078

X

-

CA-ADCO

CA-ADCO disables eight alarm inputs. It connects to the XI17 - 24 connector on the COAR.

3BK 07953

X

-

CA-APC2

CA-APC2 gathers BTS compartment 1 alarms from the door switch, smoke detector, flood detector and HEX2.

3BK 08215

X

-

CA-ASMC

CA-ASMC is an AC power cable. It connects 230 VAC from the ACSB to the ACIB.

3BK 08807

X

-

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COME Mnemonic

Description

Part Number

COMI

COEP

CA-ONCCx

CA-ONCCx carries:

-

X

-

0/ -48 VDC from the bus bar TX/RX from the Connection Area Abis 1/2 Interfaces from the SUM. The cable connects to the customer equipment in BTS compartment 1. CA-OSCP1

CA-OSCP1 short circuits the HEX2 P1 connector of CA-ACSC. This suppresses the side compartment HEX2 alarm. The side compartment HEX2 is only fitted in the COME when there are more than six TREs.

3BK 08095

X

-

CA-OSCP2

CA-OSCP2 short circuits the Alarms BTS2 connector on the COAR. This suppresses the BTS compartment 2 HEX2 and door switch alarms. BTS compartment 2 is part of COME.

3BK 08096

X

-

CS02

CS02 is an AN cable set. It connects an ANY to another ANY or to an ANX/ANC.

3BK 07598

X

X

CS03

CS03 is a TRE cable set. It connects a TRE to an ANX/ANC or an ANY.

3BK 07599

X

X

CS07

CS07 is an ANT cable set. It connects an ANX/ANC to two antenna cabinet connectors.

3BK 07964

X

X

CS08

CS08 is the customer equipment cable set. It connects a BTS to the microwave equipment and other customer equipment.

3BK 08036

X

-

CS09

CS09 is a BTS compartment 1 basic cable set. It contains cables for:

3BK 08037

X

-

DC power connections to the STASRs, HEX2 and XIOB Signal connections to the SUM. This includes the Abis1 and Abis2 Interfaces, clock, control and alarm signals.

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COME Mnemonic

Description

Part Number

COMI

COEP

CS10

CS10 is an optional cable set. It provides the 0/ -48 VDC supply for the side compartment HEX2. The side compartment HEX2 is only fitted in the COME when there are more than six TREs.

3BK 08042

-

X

CS11

CS11 is the BTS compartment 2 basic cable set. It contains cables for:

3BK 08040

-

X

3BK 08041

X

-

DC power connections to the STASRs and HEX2 Signal connections between the STASRs. CS12

CS12 is a TRE cable set. It connects a TRE to ANY.

Table 41: COMI/COME/COEP Outdoor Internal Cables

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4.8.1.2 CODI/CODE/COEP Internal Cables CODE Mnemonic

Description

Part Number

CODI

COEP

BATCO

BATCO connects the battery via breakers to the interconnection area. It includes a cable for the battery temperature sensor.

3BK 25156

X

-

BTSRIOUT

BTSRIOUT is a flat cable which is permanently attached to a BTSRI board. It interconnects the BTS compartment 1 STASR backplanes and the BTSRI.

3BK 08126

X

-

CA-ADCO

CA-ADCO disables eight alarm inputs. It connects to the XI17 - 24 connector on the COAR.

3BK 07953

X

-

CA-ONCCx

CA-ONCCx carries:

-

X

-

0/ -48 VDC from the bus bar TX/RX from the Connection Area Abis 1/2 Interfaces from the SUM. The cable connects to the customer equipment in BTS compartment 1. CS03

CS03 is a TRE cable set. It connects a TRE to an ANX/ANC or an ANY.

3BK 07599

X

X

CS07

CS07 is an ANT cable set. It connects 3BK 07964 an ANX/ANC to two antenna cabinet connectors.

X

X

CS08

CS08 is the customer equipment cable set. It connects a BTS to the microwave equipment and other customer equipment.

3BK 08036

X

-

CS11

CS11 is the BTS compartment 2 basic cable set. It contains cables for:

3BK 08040

-

X

DC power connections to the STASRs and HEX2 Signal connections between the STASRs.

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CODE Mnemonic

Description

Part Number

CODI

COEP

CS15

CS15 is a BTS compartment 1 basic cable set. It contains cables for:

3BK 08719

X

-

3BK 08775

X

-

DC power connections to the STASRs, HEX2 and XIOB Signal connections to the SUM. This includes the Abis1 and Abis2 Interfaces, clock, control and alarm signals. CS16

CS16 is a side compartment basic cable set. It contains cables for: DC power connections to the HEX2 Signal connections to the SUM. This includes control and alarm signals.

Table 42: CODI/CODE/COEP Outdoor Internal Cables

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4.8.1.3 CPT2 Internal Cables Mnemonic

Description

Part Number

BATCO Version AA

BATCO AA connects the battery via breakers to the interconnection area. It includes a cable for the battery temperature sensor.

3BK 25156

CS03

CS03 is a TRE cable set. It connects a TRE to an ANC or an ANY.

3BK 07599

CS07

CS07 is an ANT cable set. It connects an ANC to two antenna cabinet connectors.

3BK 07964

CS15

CS15 is a BTS compartment 1 basic cable set. It contains cables for:

3BK 08719

DC power connections to the STASRs, HEX2 and OUTC Signal connections to the SUM. This includes the Abis1 and Abis2 Interfaces, clock, control and alarm signals. CS16

CS16 is a side compartment basic cable set. It contains cables for:

3BK 08775

DC power connections to the HEX2 Signal connections to the SUM. This includes control and alarm signals. Table 43: CPT2 Outdoor Internal Cables

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4.8.1.4 MBO1/MBO1DC/MBO2/MBO2DC Internal Cables Mnemonic

Description

Part Number

MBO1

MBO2

BATCO Version BA

BATCO BA connects the battery via breakers to the interconnection area. It includes a cable for the battery temperature sensor.

3BK 25156

X

X

CM01

CM01 is an MBO1 basic cable set. It contains cables for:

3BK 25818

X

X

3BK 27268

X

X

3BK 25819

-

X

3BK 27269

-

X

DC power connections to the STASRs, HEX4 and OUTC Signal connections to the SUM. This includes the Abis1 and Abis2 Interfaces, clock, control and alarm signals Remote inventory data. CMO1E

CM01E is an MBO1E basic cable set. It contains cables for: DC power connections to the STASRs, HEX9/DAC9 and OUTC Signal connections to the SUM. This includes the Abis1 and Abis2 Interfaces, clock, control and alarm signals Remote inventory data.

CM02

CM02 is an MBOE compartment basic cable set. It contains cables for: DC power connections and alarms to the HEX3 DC power connections to the STASRs Remote inventory data.

CM02E

CM02E is an MBOEE compartment basic cable set. It contains cables for: DC power connections and alarms to the HEX8/DAC8 DC power connections to the STASRs Remote inventory data.

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Mnemonic

Description

Part Number

MBO1

MBO2

CMO11*

CM011 is an MBO1DC basic cable set. It contains cables for:

3BK 26621

X

X

3BK 27142

X

-

DC power connections to the STASRs, HEX4 and OUTC Signal connections to the SUM. This includes the Abis1 and Abis2 Interfaces, clock, control and alarm signals SENSP Remote inventory data. CMO1T**

CMO1T is an MBO1T basic cable set. It contains cables for: DC power connections to the STASRs, HEX4 and OUTC Signal connections to the SUM. This includes the Abis1 and Abis2 Interfaces, clock, control and alarm signals Remote inventory data.

CS03

CS03 is a TRE cable set. It connects a TRE to an ANC or an ANY.

3BK 07599

X

X

CS07

CS07 is an ANT cable set. It connects an ANC to two antenna cabinet connectors.

3BK 07964

X

X

*

: Available only for MBODC

**

: Available only for MBO1T

Table 44: MBO1/MBO1DC/MBO1T/MBO2/MBO2DC Outdoor Internal Cables

4.8.1.5 CBO Internal Cables Mnemonic

Description

Part Number

CBOA

CBOA is an CBO basic cable set. It contains cables for:

3BK 26346

DC power connections to the STASRs, HEX5 and OUTC Signal connections to the SUM. This includes the Abis1 and Abis2 Interfaces, clock, control and alarm signals Remote inventory data. BATSC

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BATSC connects the battery to the ADAM board and the 0 V bolt.

3BK 26354

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Mnemonic

Description

Part Number

CS03

CS03 is a TRE cable set. It connects a TRE to an ANC or an ANY.

3BK 07599

CS26

CS26 is an ANT cable set. It connects an ANC to two antenna cabinet connectors.

3BK 26351

Table 45: CBO Outdoor Internal Cables

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4.8.1.6 BTS A9100 Outdoor Internal Cable Sets Cable Sets

Mnemonic

Description

Part Number

Quantity

BATCO Version AA

CA-BABRM

CA-BABRM connects -48 VDC from the battery to the battery breaker.

3BK 25141

1

CA-BABRP

CA-BABRP connects 0 VDC from the battery to the battery breakers.

3BK 25140

1

CA-BRCM

CA-BRCM connects -48 VDC from the battery breaker to the battery interconnection area.

3BK 25246

1

CA-BRCP

CA-BRCP connects 0 VDC from the battery breaker to battery interconnection area.

3BK 25245

1

CA-BSENS

CA-BSENS connects the battery temperature sensor to RIBAT or OUTC.

3BK 08119

1

CA-CBRM

CA-CBRM connects -48 VDC from the battery to the battery breaker.

3BK 25868

1

CA-CBRP

CA-CBRP connects 0 VDC from the battery to the battery breakers.

3BK 25869

1

CA-BRCM

CA-BRCM connects -48 VDC from the battery breaker to the battery interconnection area.

3BK 25246

1

CA-BRCP

CA-BRCP connects 0 VDC from the battery breaker to battery interconnection area.

3BK 25245

1

CA-BSENS

CA-BSENS connects the battery temperature sensor to RIBAT or OUTC.

3BK 08119

1

CA-PDCP

CA-PDCP connects the 0 VDC from the battery to the ground bolt.

3BK 25231

1

CA-ADACM

CA-ADACM connects the -48 VDC from the battery to the ADAM2 board.

3BK 25248

1

BOMU

Bus bar Outdoor Multistandard Unit.

3BK 25672

1

3BK 25822

1

3BK 25182

1

BATCO Version AB

BATSC

CM01

Carries AC and DC power supplies to the STASRs, XIOB, HEX3/ HEX4, HEAT2, service lights, customer and microwave equipment. Transfers alarms from the HEX3/ HEX4, smoke detector, flood detector, and door switches to the OUTC. CA-RIMO1

Remote Inventory Multistandard Out cable. RIMO1 transfers remote inventory data of MBO1 modules to OUTC.

CA-Ground

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CA-Ground is a cabinet ground cable. It connects LPFM to a ground bolt.

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Cable Sets

CMO1T

Mnemonic

Description

Part Number

Quantity

CA-BRCP

CA-BRCP connects 0 VDC from the battery breaker to battery interconnection area.

3BK 25245

1

CA-ABIS

The CA-ABIS carries the Abis1 /2 Interfaces from the COAR (OUTC) to the SUM.

3BK 07922

1

CA-BTSCA

The CA-BTSCA carries clock and control signals between the COAR (OUTC) and the SUM.

3BK 07923

1

CA-RIMO1

Remote Inventory Multistandard Out cable.

3BK 25822

1

RIMO1 transfers remote inventory data of MBO1 modules to OUTC.

CM01E

CA-Ground

CA-Ground is a cabinet ground cable. It connects LPFM to a ground bolt.

3BK 25182

1

CA-BRCP

CA-BRCP connects 0 VDC from the battery breaker to battery interconnection area.

3BK 25245

1

CA-ABIS

The CA-ABIS carries the Abis1 /2 Interfaces from the COAR (OUTC) to the SUM.

3BK 07922

1

CA-BTSCA

The CA-BTSCA carries clock and control signals between the COAR (OUTC) and the SUM.

3BK 07923

1

CA-OSCP4

The CA-OSCP4 short circuits the Alarms BTS2 connector on the OUTC. This suppresses the MBO2 HEX3 and door switch alarms.

3BK 272003

1

CA-RIC1

Remote Inventory Multistandard Evolution Out cable.

3BK 27319

1

CA-XBCBPS CA-XBCBPS carries alarm and Remote Inventory information from the PM18C to the OUTC.

3BK 27318

1

CA-ABIS

The CA-ABIS carries the Abis1 /2 Interfaces from the COAR (OUTC) to the SUM.

3BK 07922

1

CA-BTSCA

The CA-BTSCA carries clock and control signals between the COAR (OUTC) and the SUM.

3BK 07923

1

CA-PCOS

Power cable outdoor for upper subracks (MBO2).

3BK 08809 AA

2

CA-PCOS

Power cable outdoor for bottom subrack (MBO2).

3BK 08809 BA

1

CA-HOAP

HEX outdoor alarm and power cable.

3BK 25820

1

RIC1 transfers remote inventory data of MBO1E modules to OUTC.

CM02

The CA-HOAP connects HEX3 and BOMU transferring DC power and alarms.

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Cable Sets

Mnemonic

Description

Part Number

Quantity

CA-RIMO2

Remote Inventory Multistandard Out cable.

3BK 25823

1

CA-RIMO2 transfers remote inventory data of MBO2 modules to OUTC. CM02E

CA-PCOS

Power cable outdoor for upper subracks (MBO2E).

3BK 08809 BB

3

CA-HOAP

HEX outdoor alarm and power cable.

3BK 25820

1

3BK 27320

1

3BK 25672

1

3BK 25822

1

The CA-HOAP connects HEX3 and BOMU transferring DC power and alarms. CA-RIC2

Remote Inventory Multistandard Out Evolution cable. CA-RIC2 transfers remote inventory data of MBO2E modules to OUTC.

CMO11

BOMU

Bus bar Outdoor Multistandard Unit. BOBU carries DC power supplies to the STASRs, XIOB, HEX3/ HEX4, HEATDC, service lights, customer and microwave equipment. BOBU transfers alarms from the HEX3/ HEX4, smoke detector, flood detector, and door switches to the OUTC.

CA-RIMO1

Remote Inventory Multistandard Out cable. RIMO1 transfers remote inventory data of MBO1DC modules to OUTC.

CS02

CS03

CS07

CA-SENSP

Temperature sensor plug.

3BK 26147

1

CA-ABIS

The CA-ABIS carries the Abis1 /2 Interfaces from the COAR (OUTC) to the SUM.

3BK 07922

1

CA-BTSCA

The CA-BTSCA carries clock and control signals between the COAR (OUTC) and the SUM.

3BK 07923

1

RXRC

RXRC connects an ANY RX connector to an ANX/ANC or another ANY RX connector.

3BK 07920

2

TXRC

TXRC connects an ANY TX connector to an ANX/ANC or another ANY TX connector.

3BK 07919

1

RXRC

RXRC connects a TRE RX connector to an ANY or ANX/ANC RX connector.

3BK 07920

2

TXRC

TXRC connects a TRE TX connector to an ANY or ANX/ANC TX connector.

3BK 07919

1

ANOC

ANOC provides a duplex connection between the ANX/ANC and a cabinet antenna connector.

3BK 07965

2

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Cable Sets

Mnemonic

Description

Part Number

Quantity

CS08 Variant BA

CA-DFUX

CA-DFUX carries the Abis1 /2 Interfaces to the SUM.

3BK 08503

1

CS08 Variant CA

CA-GCMW

CA-GCMW is a cabinet ground cable. It connects the microwave equipment to ground.

3BK 07934

1

CA-MXBP

CA-MXBP carries 0/ -48 VDC from the bus bar. The cable connects to the microwave equipment in BTS compartment 1.

3BK 08886

1

CA-RFMW

CA-RFMW carries the TX/RX to the bottom plate of the BTS.

3BK 07931

1

CA-2MMC2

CA-2MMC2 carries the Abis1 /2 Interfaces to the SUM.

3BK 08289

1

CA-GCMW

CA-GCMW is a cabinet ground cable. It connects the microwave equipment to ground.

3BK 07934

1

CA-MLBP

CA-MLBP carries 0/ -48 VDC from the bus bar. The cable connects to the microwave equipment in BTS compartment 1.

3BK 08887

1

CA-RFMW

CA-RFMW carries the TX/RX to the bottom plate of the BTS.

3BK 07931

1

CA-ABIS

CA-ABIS carries the Abis1 /2 Interfaces from the COAR to the SUM.

3BK 07922

1

CA-BTSCA

CA-BTSCA carries clock and control signals between the COAR and the SUM.

3BK 07923

1

CA-H2PC1

H2PC1 carries 0/ -48 VDC from the DCDP. The cable connects to the BTS compartment 1 HEX2.

3BK 08077

1

CA-OSPC

CA-OSPC carries 0/ -48 VDC from the DCDP to an STASR.

3BK 08079

2

CA-XBCBO

CA-XBCBO carries alarm and Remote Inventory information from the ACRI to the COAR.

3BK 08205

1

CA-XIOPC

CA-XIOPC carries 0/ -48 VDC from the DCDP to the XIOB.

3BK 08087

1

CA-H2PC2

Cable Assembly - HEX2 Power Cable 2 carries 0/ -48 VDC from the DCDP. The cable connects to the COAR.

3BK 08092

1

CA-H2PC3

Cable Assembly - HEX2 Power Cable 3 carries 0/ -48 VDC from the HEX Power connector on the COAR. The cable connects to the side compartment HEX2.

3BK 08093

1

CS08 Variant BB

CS09

CS10

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Cable Sets

Mnemonic

Description

Part Number

Quantity

CS11 Variant AA

CA12

Cable Assembly 12 is a flat cable that interconnects the BTS compartment 2 STASR backplanes and the BTSRIOUT.

3BK 08086

1

CA-ACB2

Cable Assembly - Alarm Cable BTS2 gathers alarms from BTS compartment 2. This consists of the door switch and HEX2 alarms. The cable connects to the Alarms BTS2 connector on the COAR.

3BK 08091

1

CA-H2PC1

CA-H2PC1 carries 0/ -48 VDC from the DCDP. The cable connects to the BTS compartment 2 HEX2.

3BK 08077

1

CA-OSPC

CA-OSPC carries 0/ -48 VDC from the DCDP to an STASR.

3BK 08079

1 of AA, 2 of AB

CA12

CA12 is a flat cable that interconnects the BTS compartment 2 STASR backplanes and the BTSRIOUT.

3BK 08086

1

CA-OHAC

CA-OHAC carries:

3BK 08810

1

CS11 Variant BA

0/ -48 VDC from the BOBU Alarms to the BOBU. The cable connects to the BTS compartment 2 HEX2.

CS12

CS15 Variant CA

CA-PCOS

Cable Assembly - Power Cable Outdoor Subrack carries 0/ -48 VDC from the BOBU to the STASR.

3BK 08809

3

RXRC

The RXRC connects a TRE RX connector to an ANY connector.

3BK 07920

2

TXRC

The TXRC connects a TRE TX connector to an ANY connector.

3BK 07919

1

BOBU

BOBU carries AC and DC power supplies to the STASRs, XIOB, HEX2, HEAT, service lights, customer and microwave equipment.

3BK 08742

1

BOBU transfers alarms from the HEX2, smoke detector, flood detector, and door switches to the COAR. CA-ABIS

The CA-ABIS carries the Abis1 /2 Interfaces from the COAR to the SUM.

3BK 07922

1

CA-BTSCA

The CA-BTSCA carries clock and control signals between the COAR and the SUM.

3BK 07923

1

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Cable Sets

Mnemonic

Description

Part Number

Quantity

CA-OHAC

CA-OHAC carries:

3BK 08810

1

3BK 08742

1

0/ -48 VDC from the BOBU Alarms to the BOBU. The cable connects to the BTS compartment 1 HEX2. CS15 Variant DA

BOBU

BOBU carries AC and DC power supplies to the STASRs, XIOB, HEX2, HEAT, service lights, customer and microwave equipment. BOBU transfers alarms from the HEX2, smoke detector, flood detector, and door switches to the OUTC.

CA-RICPT2

The CA-RICPT2 is a flat cable which is permanently attached to the OUTC board. It interconnects the BTS compartment 1 STASR backplanes and the OUTC.

3BK 25538

1

CA-OHAC

CA-OHAC carries:

3BK 08810

1

3BK 08741

1

CA-Ground1 CA-Ground1 is a cabinet ground cable. It connects the ACSB to a ground bolt.

3BK 08118

1

CA-Ground2 CA-Ground2 is a cabinet ground cable. It connects between two ground bolts.

3BK 08117

1

CA-OHAC

3BK 08810

1

3BK 08205

1

0/ -48 VDC from the BOBU Alarms to the BOBU. The cable connects to the BTS compartment 1 (CPT2) HEX2. CS16

BOSU

Variant AA

BOSU carries AC and DC power supplies to the HEX2, HEAT, service lights, and ASCB/ACSU. BOSU transfers alarms from the HEX2, key and door switch to the COAR.

CA-OHAC carries: 0/ -48 VDC from the BOBU Alarms to the BOBU. The cable connects to the BTS compartment 1 HEX2.

CA-XBCBO

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CA-XBCBO carries alarm and Remote Inventory information from the BCU2 to the COAR.

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Cable Sets

Mnemonic

Description

Part Number

Quantity

CS16

BOSU

BOSU carries AC and DC power supplies to the HEX2, HEAT, service lights, and ACSB/ACSU.

3BK 08741

1

Variant CA

BOSU transfers alarms from the HEX2, key and door switch to the COAR. CA-CSTR

CA-CSTR connects the COAR with RIBAT 1, RIBAT 2 and STASR7.

3BK 25178

1

CA-Ground

CA-Ground is a cabinet ground cable. It connects the LPFU grounding bolt to the bottom plate.

3BK 25182

1

CA-OHAC

CA-OHAC carries:

3BK 08810

1

0/ -48 VDC from the BOBU Alarms to the BOBU. The cable connects to the BTS compartment 1 HEX2.

CS16

CA-PDCM

CA-PDCM carries -48 VDC from ADAM to the side wall interconnection area.

3BK 25232

1

CA-PDCP

CA-PDCP carries 0 VDC from ADAM to the side wall interconnection area.

3BK 25231

1

CA-ADACM

CA-ADACM carries -48 VDC from ADAM to the battery interconnection area.

3BK 25248

1

CA-ADACP

CA-ADACP carries 0 VDC from ADAM to the battery interconnection area.

3BK 25247

1

BOSU

BOSU carries AC and DC power supplies to the HEX2, HEAT, service lights, and ACSU.

3BK 08741

1

Variant DA

BOSU transfers alarms from the HEX2, key and door switch to the OUTC. CA-Ground

CA-Ground is a cabinet ground cable. It connects the LPFU grounding bolt to the bottom plate.

3BK 25182

1

CA-RICPT1

The CA-RICPT1 is a flat cable which is permanently attached to the OUTC board. It interconnects the side compartment STASR backplanes and the OUTC.

3BK 25537

1

CA-OHAC

CA-OHAC carries:

3BK 08810

1

0/ -48 VDC from the BOBU Alarms to the BOBU The cable connects to the BTS compartment 1 HEX2.

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Cable Sets

Mnemonic

Description

Part Number

Quantity

CA-PDCM

CA-PDCM carries -48 VDC from ADAM/ADAM2 to the side wall interconnection area.

3BK 25232

1

CA-PDCP

CA-PDCP carries 0 VDC from ADAM/ADAM2 to the side wall interconnection area.

3BK 25231

1

CA-ADACM

CA-ADACM carries -48 VDC from ADAM/ADAM2 to the battery interconnection area.

3BK 25248

1

CA-ADACP

CA-ADACP carries 0 VDC from ADAM/ADAM2 to the battery interconnection area.

3BK 25247

1

CA-ABIS

The CA-ABIS carries the Abis1 /2 Interfaces from the OUTC to the SUMA.

3BK 07922

1

CA-BTSCA

The CA-BTSCA carries clock and control signals between the OUTC and the SUMA.

3BK 07923

1

CS25

ANCO

ANCO provides a duplex connection between the ANX/ANC and a cabinet antenna connector.

3BK26151

2

CS26

ANLC

ANLC provides a duplex connection between the ANX/ANC and a cabinet antenna connector.

3BK 26349

2

CS27

ANCO

ANCO provides a duplex connection between the ANX/ANC and a cabinet antenna connector.

3BK26151

2

Table 46: BTS A9100 Outdoor Cable Sets

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4.8.2 External Cables The BTS A9100 outdoor external cables consist of the discrete cables listed in the following table. They belong to COME/COMI and CODE/CODI. There are no COEP external cables, because COEP is used to extend COMI to COME and CODI to CODE. Mnemonic

Description

Part Number

AC Supply

This cable can be made on-site to the desired length. The cable used is a five-core, 6 mm sq. power cable.

1AC 00468 0003

Antenna Jumper

Antenna jumpers, 1 m/ 2 m/ 3 m/ 5 m length, HCF1/ 2, 2 x 7/ 16 straight male connectors. They connect the BTS to the main antenna cables.

3BK 05360

This cable can be replaced by one made on-site to the desired length. The cable used is L907, an 8-pair, shielded, 2 Mbit/s, 120 PCM cable.

1AC 01328 0004

This cable can be replaced by one made on site to the desired length. The cable used is Flex3, a multicoaxial, 2 Mbit/s, 75 PCM cable.

1AC 00110 0011

CA-CBTE

CA-CBTE is the BTS Terminal cable. It connects the BTS Terminal to the BTS Terminal connector on the SUM.

3BK 07951

CA-GC35

CA-GC35 is the cabinet ground cable. It connects to the M8 ground 3BK 08031 bolt on the side compartment floor, and to the customer’s ground point. This cable can be replaced by one made on-site to the desired length. The cable used is a 50 mm sq. yellow/green power cable.

1AC 00465 0003

OCC23

OCC23 is a clock synchronization cable. It connects a G2 BTS to the BTS A9100.

3BK 08303

OCC33

OCC33 is a clock synchronization cable. It connects a BTS A9100 to another BTS A9100.

3BK 08304

Table 47: BTS A9100 Outdoor External Cables List

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4.9 Outdoor Cabinet Cabling The various types of cabling used in outdoor cabinets is described in the following sections. This includes DC power and alarm cabling, as well as data and control cabling. The cabling descriptions are group by outdoor cabinet types.

4.9.1 Outdoor Cabinet DC Power and Alarm Cabling The DC power and alarm cabling for the COME/COMI/CODE/CODI, CPT2, MBO1/MBO1DC/MBO2/MBO2DC, and CBO cabinets are described separately. The descriptions are supported by diagrams.

4.9.1.1 COME/COMI/CODE/CODI There are two variants of cable sets used to distribute DC power and alarms within the BTS A9100 outdoor cabinets: One variant is used for COME/COMI AXXX One variant is used for COME/COMI BXXX and CODE/CODI. The following figure shows the cables that carry DC power and alarms within the COME/COMI AXXX. Side Compartment

BTS Compartment 1

BTS Compartment (COME only)

XIOB

DCDP

CA−XIOPC X6

HEX2 (optional)

CA−OSPC

X12−X14

X1 X7

X8

To STASRs (COME only)

X9/X10

CA−ADCO CA−OSPC CA−H2PC3

HEX Power

CA−ACSC

Alarms Side Comp

HEX Power

Power

CA−H2PC2

To STASRs

(COME only) CA−H2PC1 AB CA−ACB2 for COME CA−OSCP2 for COMI

Alarms BTS2

Alarm

(COME only)

COAR CA−H2PC1 AA

Door Switch Key Switch

HEX2

HEX2

Alarms BTS1

(COME only)

Power

Power

Alarm

Alarm

CA−APC2

Door Switch

Door Switch

Smoke Detector Flood Detector

Figure 254: COME/COMI AXXX, DC Power and Alarm Cabling

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The following figure shows the cables and bus bars that carry DC power and alarms within the COME/COMI BXXX and CODE/CODI. Note that, although the bus bars carry AC power, this is not shown in the following figure. Side Compartment

BTS Compartment 1 GND 0 VDC

XIOB

GND

BOSU

(CODE/COME only)

0 VDC

(COME only)

−48 VDC Optional Power Supplies (CODE only)

BTS Compartment 2

Optional Power Supplies

−48 VDC

BOBU

STASR 1

CA−ADCO

STASR 2

STASR 7 (CODE only)

Alarms BTS

STASR 3 STASR 4

Alarms Side Comp

STASR 5 STASR 6

HEX2

COAR

HEX2

HEX2 (CODE/ COME only)

(optional)

Power

Power

Power

Alarm

Alarm

Alarm

Door Switch Door Switch

Door Switch

Key Switch

Smoke Detector Flood Detector

Figure 255: COME/COMI BXXX and CODE/CODI, DC Power and Alarm Cabling

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4.9.1.2 CPT2 The following figure shows the cables and bus bars that carry DC power and alarms within the CPT2. Note that, although the bus bars carry AC power, this is not shown in the figures. Side Compartment

BTS Compartment 1 GND

GND

0 VDC

0 VDC

−48 VDC

−48 VDC

BOSU

BOBU

STASR 2

STASR 4

CA−ADCO STASR 3

STASR 5 Alarms BTS

STASR 6

Alarms Side Comp

HEX2

XIOB Function

HEX2

(optional) OUTC Power

Power

Alarm

Alarm

Door Switch

Door Switch

Key Switch

Smoke Detector Flood Detector

Figure 256: CPT2 DC Power and Alarm Cabling

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4.9.1.3 MBO1/MBO1DC/MBO1T/MBO2/MBO2DC The following figure show the cables and bus bars that carry DC power and alarms within the MBO1/MBO1DC/MBO1T/MBO1E and MBO2/MBO2DC/MBO2E. GND 0 VDC −48 VDC

Door Switch Key Switch Smoke Detector Water Detector HEX4

STASR 7 STASR 3 STASR 2 STASR 1

BOMU

CA−ADCO X901 Alarms X910 XIOB Function

OUTC

Figure 257: MBO1/MBO1DC DC Power and Alarm Cabling GND 0 VDC −48 VDC

Door Switch

HEX4

STASR 7 STASR 3 STASR 2 STASR 1

BOMUT

CA−ADCO X901 Alarms X910 XIOB Function

OUTC

Figure 258: MBO1T DC Power and Alarm Cabling

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GND 0 VDC −48 VDC

Door Switch

Door Switch Key Switch Smoke Detector Water Detector

HEX3

HEX4 STASR 7

STASR 0 (not used)

STASR 3

STASR 6 STASR 5

STASR 2 STASR 1

BOMU

STASR 4

CA−ADCO X901 Alarms X910 XIOB Function

OUTC

MBO1

MBOE

Figure 259: MBO2/MBO2DC DC Power and Alarm Cabling

4.9.1.4 MBO1E/MBO1EDC/MBO2E/MBO2EDC The following figure show the cables and bus bars that carry DC power and alarms within the MBO1E/MBO1EDC and MBO2E/MBO2EDC. GND 0 VDC −48 VDC

Door Switch Key Switch Smoke Detector Water Detector HEX9

STASR 3 STASR 2 STASR 1

BOMUE

CA−ADCO X901 Alarms X910 XIOB Function

OUTC

Figure 260: MBO1E/MBO1EDC Power and Alarm Cabling

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GND 0 VDC −48 VDC

Door Switch

Door Switch Key Switch Smoke Detector Water Detector

HEX8

HEX9

STASR 6

STASR 3

STASR 5

STASR 2 STASR 1

BOMUE

STASR 4

CA−ADCO X901 Alarms X910 XIOB Function

OUTC

MBO1E

MBOEE

Figure 261: MBO2E/MBO2EDC Power and Alarm Cabling

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4.9.1.5 CBO CBO AC Variant

The following figure shows the cables that carry DC power and alarms within the CBO AC variant. Note that, although the bus bars carry AC power, this are not shown in the figures. GND 0 VDC −48 VDC

HEX5 Optional Equipment STASR 2 STASR 1

DCUC

CA−ADCO X901 Alarms X910 XIOB Function

OUTC

CBO

Figure 262: CBO DC Power and Alarm Cabling

CBO DC Variant

The following figure shows the cables that carry DC power and alarms within the CBO AC variant. GND 0 VDC −48 VDC

HEAT4 HEX5 Optional Equipment STASR 2 STASR 1

DCDU

CA−ADCO X901 Alarms X910 XIOB Function

OUTC

CBO

Figure 263: CBO DC Power and Alarm Cabling

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4.9.2 Outdoor Cabinet Data and Control Cabling The following sections described the data and control cabling used in the different types of outdoor cabinets.

4.9.2.1 COME/COMI The following figure shows the logical interconnections provided by the data and control cables for the COME/COMI. COEP

STASR5 Backplane

COAR OCC23/OCC33

CA−ABIS

STASR2 Backplane

STASR4 Backplane

SUM STASR1 Backplane

STASR3 Backplane

BTSRIOUT

CA12

BTSRI

Figure 264: COME/COMI Data and Control Cabling

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4.9.2.2 CODE/CODI The following figure shows the logical interconnections provided by the data and control cables for the CODE/CODI. STASR 7 Backplane

RIBAT 1

COEP

RIBAT 2

STASR 3 Backplane

STASR 6 Backplane

COAR OCC23/OCC33

CA−ABIS

STASR 2 Backplane

STASR 5 Backplane

SUMA

STASR 1 Backplane

STASR 4 Backplane

BTSRIOUT CA12 BTSRI

Figure 265: CODE/CODI Data and Control Cabling

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4.9.2.3 CPT2 The following figures show the logical interconnections provided by the data and control cables for the CPT2. STASR 6 Backplane

STASR 3 Backplane

Option: OCC23/OCC33

CA−ABIS

CA−BTSCA STASR 2 Backplane

STASR 5 Backplane

OUTC SUMA

STASR 4 Backplane

CA−RICPT1

CA−RICPT2

Figure 266: CPT2 Data and Control Cabling

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4.9.2.4 MBO1/MBO2 The following figures show the logical interconnections provided by the data and control cables for the MBO1/MBO1DC/MBO1T/MBO2/MBO2DC. The STASR7 is equipped only in MBO1 and MBO2.

STASR 7 Backplane

Option: OCC23/OCC33

STASR 3 Backplane

CA−ABIS

STASR 2 Backplane

CA−BTSCA

SUMA OUTC

STASR 1 Backplane

CA−RIMO1

Figure 267: MBO1/MBO1DC/MBO1T Data and Control Cabling

STASR 7 Backplane STASR 0 Backplane (not equipped) Option: OCC23/OCC33

STASR 3 Backplane

STASR 6 Backplane

CA−ABIS

STASR 2 Backplane

STASR 5 Backplane

CA−BTSCA

SUMA OUTC

STASR 1 Backplane

CA−RIMO1

MBO1

STASR 4 Backplane

CA−RIMO2

MBOE

Figure 268: MBO2/MBO2DC Data and Control Cabling

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4.9.2.5 MBO1E/MBO2E The following figures show the logical interconnections provided by the data and control cables for the MBO1E/MBO1EDC/MMBO2E/MBO2EDC. The PM18SR is equipped only in MBO1E and MBO2E AC variants. Option: OCC23/OCC33 XBCBPS PM18SR

PM18C STASR 3 Backplane

CA−ABIS

STASR 2 Backplane

CA−BTSCA

SUMA OUTC

STASR 1 Backplane

CA−RIC1

Figure 269: MBO1E Data and Control Cabling Option: OCC23/OCC33

XBCBPS PM18SR

PM18C STASR 3 Backplane

STASR 6 Backplane

CA−ABIS

STASR 2 Backplane

STASR 5 Backplane

CA−BTSCA OUTC SUMA

STASR 1 Backplane

CA−RIC1

STASR 4 Backplane

CA−RIC2

MBO1E

MBOEE

Figure 270: MBO2E Data and Control Cabling

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4.9.2.6 CBO The following figure shows the logical interconnections provided by the data and control cables for the CBO. Option: OCC23/OCC33

STASR 2 Backplane

OUTC CA−ABIS

CA−BTSCA STASR 1 Backplane SUMA

CA−RIBCO

Figure 271: CBO Data and Control Cabling

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5 External Battery Cabinets The sections describe mechanical design of battery cabinets and cabling between the battery cabinets and the BTS.

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5.1 External Indoor Battery Cabinet The external indoor battery cabinet is used to house a large backup battery. In this case it is not allowed to use a BTS configuration with an internal battery in parallel. As required up to three battery units (48 V) can be installed inside the cabinet. The following figures show block diagrams illustrating the principle. If battery units are connected to different BTSs, each battery unit is connected with separate DC connectors and can be switched on/off by a separate circuit switch (block diagram 1). Battery units can also be connected in parallel. Then DC output connectors of BTS1 are used. DC battery voltage can be switched on/off by using the common circuit switch. DC Output Connectors BTS2 BTS3

XBCB

BTS1

3 2 1

Breaker F3

Temperature Sensor

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 3

Battery Unit 3

Breaker F2

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 2

Battery Unit 2

Breaker F1

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 1

Battery Unit 1

Figure 272: External Indoor Battery Cabinet, Block Diagram 3x1 Battery Units

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DC Output Connectors BTS2 BTS3

XBCB 3 2 1

BTS1

Common Breaker F4

Breaker F3

Temperature Sensor

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 3

Battery Unit 3

Breaker F2

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 2

Battery Unit 2

Breaker F1

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 1

Battery Unit 1

Figure 273: External Indoor Battery Cabinet, Block Diagram 1x2 + 1x1 Battery Units XBCB

DC Output Connectors BTS2 BTS1 BTS3

3 2 1

Common Breaker F4

Breaker F3

Temperature Sensor

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 3 Battery Unit 3

Breaker F2

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 2 Battery Unit 2 Breaker F1

− +

− +

− +

− +

12 V

12 V

12 V

12 V

RIBAT 1 Battery Unit 1

Figure 274: External Indoor Battery Cabinet, Block Diagram 1x3 Battery Units

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5.1.1 Mechanical Design The external indoor battery is built by using the housing of the MBI3 cabinet (see MBI Cabinet Access and Features (Section 3.3.3)). For environmental conditions and electromagnetic compatibility, see Environment (Section 18). The following figure shows that the battery units are mounted in three shelves, one unit per shelf. Each unit consists of four separate battery blocks (12 V) connected in line. Battery units can be connected to separate circuit switches (placed at the left side of each unit) and separate connectors (placed at the connection area at the top) for different BTSs. Battery units can also be connected in parallel with a common circuit switch (connection area at the top) and a common connector for one BTS. Adjustable brackets are at both sides of each shelf for positioning of the battery unit. The distance between battery blocks is maintained by means of spacers supplied with the battery. Battery units are covered with a small cover plate to secure the batteries. Common Circuit Switch

XBCB Connectors for RIBAT Cable

DC Output Connectors (to BTS)

Circuit Switch for one Battery Unit

Different types of Battery Units just shown for demonstration (cabinet must be equipped with identical batteries)

Circuit Switch for one Battery Unit

Cover Plate

Figure 275: External Indoor Battery Cabinet

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One battery terminal of each unit is connected with a temperature sensor, which monitors the battery temperature. The output from the sensor is used by the SUMA to regulate the charging voltage and thus prevent battery overheating. First this sensor information is collected and stored in RIBAT boards, which are placed behind each battery unit at the rear side of the shelves. RIBAT boards are powered by a BTS via RIBAT cable(s). RIBAT boards (for more information see RIBAT (Section 12.29) ) are connected with the XBCB connectors placed at the connection area on the top. If battery units are connected in parallel, corresponding RIBAT boards are also connected together producing a common result of monitoring. RIBAT and DC battery cables are connected to the BTS(s) passing through the battery cabinet on the top.

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5.1.2 External Battery The battery type used in the external indoor battery cabinet is BU101. This type is also used in indoor and outdoor BTSs and external outdoor battery cabinets. A detailed description, including charging, discharging and storage parameters, is given in BU101 (Section 12.26). Battery blocks of one unit are installed in line (contrary to the installation in an MBO cabinet) as shown in the following figure. To BUS Bar via Circuit Breaker

To BUS Bar Temperature Sensor Cable (to RIBAT)

Battery

Battery

Battery

Battery

Front View

Jumper

Top View

Figure 276: External Indoor Battery Unit

5.1.3 Battery Cabinet External Cabling There are following cables used for connection of an external battery cabinet indoor with a BTS and ground: CA-PCEBP, 3BK 25259 AAAA, Power Cable external Battery 0 V CA-PCEBM, 3BK 25260 AAAA, Power Cable external Battery -48 V CA-GND, 3BK 25349 AAAA, Ground Cable for external Battery CA-RIBEB, 3BK 25258 AAAA, RIBAT Cable for external indoor Battery. Mechanical design of cables can be found in External Cables (Section 17.2).

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5.2 External Battery Cabinet Outdoor The external battery cabinet outdoor battery cabinet is used to house a large backup battery. In this case it is not allowed to use a BTS configuration with an internal battery in parallel. As required, up to three battery units (48 V) can be installed inside the cabinet. The following figure shows a block diagram illustrating the principle. All battery units are connected in parallel via two bus bars. Each battery branch can be switched on/off separately by a single pole circuit switch. Complete DC battery voltage can be switched on/off by using the common circuit switch. Connection to the BTS is made via terminal blocks. Common Circuit Switch +VE BUS Bar BTS −VE BUS Bar Terminal Block

Single Pole Circuit Switch

− +

− +

− +

− +

12 V

12 V

12 V

12 V Battery Unit 3

Single Pole Circuit Switch

− +

− +

− +

− +

12 V

12 V

12 V

12 V

Battery Unit 2

Single Pole Circuit Switch

− +

− +

− +

− +

12 V

12 V

12 V

12 V Battery Unit 1

Figure 277: External Outdoor Battery Cabinet, Block Diagram

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5.2.1 Mechanical Design 5.2.1.1 Dimensions and Weight The external outdoor battery cabinet has the following dimensions and weight. Cabinet Version

3BK 26004 AAAA

3BK 26004 AAAB

Total Height

1500 mm

1312 mm

Width

700 mm

680 mm

Depth

800 mm

830 mm

Table 48: Dimensions

Cabinet pre-equipped with ACU but without batteries.

< 180 kg

Cabinet with three battery units.

< 600 kg

Table 49: Weight

5.2.1.2 Cabinet The external outdoor battery cabinet consists of a box-shaped frame bolted to a plinth. Four clearance long holes in the bottom (one in each edge) allow to fix the cabinet to the fundament using M12 anchor bolts. Other components are added to this basic construction. The cabinet has foam-insulated walls and roof. The following figures show the internal arrangement of the different variants of cabinets. The battery units are mounted in three shelves, one unit per shelf. Each unit consists of four separate battery blocks (12 V) connected in line. The minus line of each battery unit is connected to a separate single-pole circuit switch placed at the DC breaker box above the battery floors in cabinet version 3BK 26004 AAAA and at the AC/DC distribution box in cabinet verion 3BK 26004 AAAB. From that circuit switch the minus line is connected to a bus bar. Plus lines of all battery units are connected to another bus bar. Both bus bars are connected with a double pole main circuit switch (placed at the DC breaker box) and then with terminal blocks placed at the bottom of the right side wall for further connection to BTS. An exhausting tube for each battery unit is connected to the roof or bottom plate. Adjustable brackets are at both sides of each shelf to position the battery unit. The distance between battery blocks is maintained by means of spacers supplied with the battery.

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Battery units are covered in front with a small cover plate to secure the batteries. RIBAT Plate

Door Switch RIBAT Plate Smoke Detector

Door Switch

Smoke Detector

DC Breaker Box

Battery Units

Battery Units

A

A

Transmission Blocks

Airconditioner with integrated heater AC Box (behind frame)

External Cable Entry

Front View

Airconditioner with integrated heater

External Cable Entry

Front View

AC/DC Box and Transmission Blocks (behind frame) Battery Unit

Battery Unit

Jumper

Jumper

Internal Cable Entry

Internal Cable Entry

Top View A (Bottom Floor)

Exhausting Holes

Internal Cable Entry

Top View A (Bottom Floor)

Figure 278: External Battery Cabinet Outdoor Variant 3BK 26004 AAAA (Left) and 3BK 26004 AAAB (Right) Main (+) battery terminal of each unit is connected to a temperature sensor, which monitors the battery temperature. The output from the sensor is used by the SUMA to regulate the charging voltage and thus to prevent battery overheating. This sensor information is collected and stored in RIBAT boards, which are placed above the DC breaker box. RIBAT boards (for more information see RIBAT (Section 12.29)) are powered by the BTS via the CA-RIBEO cable.

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5.2.1.3 Door Access to the external outdoor battery cabinet is via a door at the front. The door provides both an environmental seal and EMI protection when closed. Mounted on the inside of the door is an air conditioner with an integrated heater. Above the air conditioner is a latch mechanism for keeping the door open during maintenance. Restrainers allow fixing the door open at 90 and 135. The door has a 3-point latching system with a Eurocylinder barrel located centrally, opened by a key. The door presses an electronic switch. This switch causes an alarm, if the door is open. The switch can be switched off during maintenance.

5.2.1.4 Cable Entry and Terminals AC, DC, RIBAT (CA-RIBEO) and Alarm cables enter the cabinet via the cable entry plate at the bottom of back, the left or right side wall. Internally, cables are passed through cable glands at the ground floor. For cabinet version 3BK 26004 AAAA the cables are connected to the DC and alarm terminals (placed at the right inner side wall), the AC distribution box (placed at the left inner side wall), or to the first RIBAT board. For cabinet version 3BK 26004 AAAB the cables are connected to the AC/DC power connection box (placed at the left inner side wall) or to the first RIBAT board. The AC distribution box is shown in the figure 279 for cabinet version 3BK 26004 AAAA (left) and for cabinet version 3BK 26004 AAAB (right). It contains an 1-pole AC main switch (L), a residual current breaker (RCB) for the service light and socket, and a switch for the air conditioner and integrated heater. Lightning protectors for AC leads (L, N) are placed at the right and wired to the earthing strip. Residual Current Breaker ’Service Light/ Socket’

To Service Light/ Socket

Surge Protections

To Service Light/ Socket Air Conditioner/Heater Smoke Detector

Residual Current Breaker ’Service Light/Socket’

To Airconditioner/ Heater

Battery Strings 1,2,3 DC Disconnector

Surge Protections

AC Distribution Box

Switch ’Airconditioner/ Heater’ AC Main Switch

To Battery Strings

AC Main Switch

AC Main Entry Bottom Plate

Switch ’Air conditioner/ Heater’

AC/DC Distribution Box

Cable Entry Bottom Plate

Figure 279: AC Distribution Box for Cabinet Version 3BK 26004 AAAA (Left) and 3BK 26004 AAAB (Right)

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5.2.1.5 Environmental Conditions The external battery cabinet equipment housings provide the necessary environmental and safety protection according to the standard ETS 300 019 -1-4 class 4.1, for outdoor equipment. The minimum ambient temperature is -33 C, exceptional ambient temperature is up to +50 C. Shock and vibration according to class 4M3; earthquake according to Bellcore 3. Storage conditions are according to ETS 300 019-1-1 class 1.2. Transportation conditions (packed) are either according to ETS 300 019-1-2 class 2.3 (public transportation, cabinet without batteries fitted) or to ETS 300 019-1-2 class 2.2 (careful transportation, cabinet with battery fitted). Transport and crane lifting with batteries is possible.

5.2.1.6 Electromagnetic Compatibility Conducted emission on AC (air conditioner/heater) are according to EN 55022 class B. Harmonic current emissions on AC lines are according to EN 61000-3-2.

5.2.2 External Battery The battery type used in the external outdoor battery cabinet is BU101. This type is also used in indoor and outdoor BTSs and internal indoor battery cabinet. A detailed description, including charging, discharging and storage parameters, is given in BU101 (Section 12.26). Battery blocks of one unit are installed in line (contrary to the installation in the MBO cabinet) as shown in the following figure. To BUS Bar via Circuit Breaker

To BUS Bar

Temperature Sensor Cable (to RIBAT) Battery

Battery

Battery

Battery

Front View

Jumper Exhausting Hoses

Top View

Figure 280: External Outdoor Battery Unit

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5.2.3 Auxiliary Equipment The auxiliary equipment installed in the external battery cabinets is described below.

5.2.3.1 Air Conditioner The air conditioner is used to maintain the temperature of the battery in range of about 20 - 25 C at ambient temperature up to 45 C, solar load included. The air conditioner is fixed to the door via 2x5 M5 studs placed on the door. The unit is supplied by 230 VAC; cooling capacity is 350 W. The following figure shows the internal and external air paths. Air Outlet

Top Internal Air Path

Rear Side

Door Side

External Air Path

Air Inlet

Door Side

Rear Side

Air Paths Side View

Figure 281: Air Conditioner Unit, Air Paths The internal warmer air is taken into the internal fan at the top of the unit and is forced through the evaporator coil and supplied back to the bottom of the cabinet. The heater element is located in front of the fan intake area. The external cooler air is taken into the external fan positioned in the bottom of the unit and is forced through the coil and exhausted back to the external environment at the top. Supervision of the air conditioner produces one sum alarm if the unit fails. The alarm line is wired to signal terminals for further connection to BTS.

5.2.3.2 Heater The heater is used for a warm-up period from -33 C and to maintain temperature inside the cabinet above 10 C. The heater is integrated in the air conditioner. The heater element (1 kW) is located in the upper internal part of the air conditioner just before the internal fan intake. The heater is controlled by a control board and is supplied by 230 VDC. For protection, two thermal switches are placed close to the heater elements. Both have a setting of 40 C for cut off and 25 C for resetting.

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5.2.3.3 Overcurrent Protections The breakers for the AC lines are fitted in a box in the left side wall of the cabinet: Breaker

Type

Description

1x 1-pole

C16 A MCB in L line

Incoming mains line

1x 2-pole

6A/ 30 mA RCB in L and N lines

Interior light and service socket

1x 1-pole

C10 A MVB in L line

Air conditioner and heater

Table 50: Overcurrent Protection AC Lines The breakers for the DC lines are fitted in the distribution box at the top of the cabinet: Breaker

Type

Description

1x 2-pole

80 A MCB fast acting in 0 V and -48 V main DC lines

Main DC Outgoing

3x 1-pole

80 A MCB in -48 V line

Separate battery branch

1x 1-pole

2 A fuse or MCB in 12 V line

Smoke detector

Note: The 0 V lead (+ pole of battery) is connected to PE inside of BTS. Note: The 0 V and -48 V main DC lines can also be switched off/on by a 2-pole circuit switch inside the BTS. Table 51: Overcurrent Protection DC Lines

5.2.3.4 Lightning Protection Lightning protection is equipped for AC lines only. It is fitted in the left side wall of the cabinet close to cable entry and wired to the earthing strip. There are medium stage protectors (category c) for L and N leads.

5.2.3.5 Door Switch The cabinet is equipped with an electromechanical door switch. If the door is opened, an alarm is raised and sent to the BTS. The alarm line is wired to signal terminals. The alarm can be cancelled manually if an open door is required for maintenance operations etc...

5.2.3.6 Smoke Detector An optical smoke detector is fitted on the top of the right inner side wall of the cabinet. In case of smoke inside the cabinet, an alarm is raised and sent to the BTS. The smoke detector is powered by + 12 VDC provided from the BTS. Alarm and DC power lines are wired to signal terminals.

5.2.3.7 Service Light and AC Power Socket A service light and integral 230 VAC power socket are fitted at the top of the cabinet, both protected by one common 6 A MCB.

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5.2.3.8 RIBAT The RIBAT is a printed circuit board for remote inventory and temperature supervision of the battery. Up to three RIBAT boards (one for each battery unit) can be fitted in one cabinet. The boards are placed on a 19” panel and fitted above the distribution box on the top. Each RIBAT reports the supervision result at a dedicated address (for more information, see RIBAT (Section 12.29)). RIBAT boards are powered by + 5 VDC provided from the BTS. RIBATs are connected to the XBCB bus in the BTS via the CA-RIBEO cable.

5.2.3.9 Document Holder The document holder is attached to the inner side of the door or side wall to store A4 documents.

5.2.4 External Battery Cabinet Outdoor Interfaces 5.2.4.1 A9100 MBS Outdoor Interfaces The following intrerfaces are available for A9100 MBS Outdoor and older BTS cabinets: AC 230V TN-S, TN-C, TT power systems are used, 3- or 5-wire (L,N,PE). Voltage range is -150 - 280 V AC and overvoltage protection class II installed in each BTS cabinet External DC 48V (charging voltage) AC/DC rectifiers PM12 are designed for permanent connection to DC load and backup battery (DC bus) Nominal voltage: -48V DC (0V pole connected to PE in BTS cabinet) Voltage range Ufloat: -52.5 to –57V temperature regulated 2-wire system (floating) connection to external battery. Voltage setting Cell voltage at 20C (battery manufacturer’s recommendation) can be set by means of Local Terminal in a commissioning mode Cell voltage range 2.20V to 2.35V in step 0.01V Default setting 2.29 V/cell. Charge current limitation Maximum charge current can be set by means of Local Terminal in a commissioning mode: Limitation range: 0A to 15.5A in step 0.5A Default setting: 8A. Boost charge Not applicable. Temperature regulation See XBCB Interface. Overvoltage protection DC bus is not overvoltage protected. It is strongly requested to route DC wires between BTS cabinet and external battery in a metallic cable tray connected to site common bonding network (CBN). DC wiring

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Maximum length of wires 10 m Wire cross section must be chosen to be in line with (in general 16 or 25 mm2): Maximum allowed DC voltage drop 2V Used MCB 70A inside BTS cabinet Wire load capability. XBCB Needed for temperature regulation of charging voltage. XBCB is an external connection to BTS Control Bus with BTS specific requirements. Next to external battery PBA RIBAT 3BK 25133 AAAA must be placed. The RIBAT connections are: Temperature sensor XBCB cable to BTS RIBAT termination. Alarm Optional interface used when an external equipment has to be supervised by BTS OMC (e.g. door of ext. enclosure, cooling equipment, smoke detector etc., if any). Up to three external alarm inputs can be connected using dedicated overvoltage protected terminals inside of BTS. External alarm interface characteristics: Electromechanical contacts or optocoupler, floating Normal closed - alarm loop conductive in normal status (no alarm). Grounding All collocated equipment, antenna pole and feeders, BTS cabinet, external equipment, cable trays, must be properly connected to the site common bonding network (CBN) in shortest possible way.

5.2.4.2 A9100 MBS Evolution Outdoor Interfaces The following intrerfaces are available for A9100 MBS Evolution Outdoor cabinet: AC 230V TN-S, TN-C, TT power systems are used, 3- or 5-wire (L,N,PE). Voltage range is -150 - 280 V AC and overvoltage protection class II installed in each BTS cabinet. External DC 48V (charging voltage) AC/DC rectifiers PM18 used in MBO Evolution cabinet are designed for permanent connection to DC load and backup battery. Nominal voltage- 48V DC (0V pole connected to PE in BTS cabinet) Voltage range Ufloat = -52.5 to -57V temperature regulated 2-wire system (floating) connection to external battery. Voltage setting Cell voltage at 20C (battery manufacturer’s recommendation) can be set by means of Local Terminal in a commissioning mode. Cell voltage range 2.20V to 2.35V in step 0.01V

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Default setting 2.29 V/cell. Charge current limitation Maximum charge current can be set by means of Local Terminal in a commissioning mode. Limitation range 1A to 31A in step of 1A. Default setting 8A. Boost charge Boost charge mode (charging with elevated voltage) can be selected by means of Local Terminal in a commissioning mode. Boost charge returns to float charge mode automatically after 5h time period or on demand by appropriate selection in Local Terminal in a commissioning mode. Temperature regulation PM18 temperture sensor must be connected to external battery. Connection to PM18 is done by means of an extension cord. For routing the extension cord same rules apply as for DC wires. Overvoltage protection DC bus is not overvoltage protected. It is strongly requested to route DC wires between BTS cabinet and external battery in a metallic cable tray connected to site common bonding network (CBN). DC wiring Maximum length of wires 10 m. Wire cross section must be chosen to be in line with (in general 16 or 25 mm2): Maximum allowed DC voltage drop 2V Used MCB 80A inside PM18 Wire load capability. XBCB Not applicable. Alarm Optional interface used when an external equipment has to be supervised by BTS OMC (e.g. door of ext. enclosure, cooling equipment, smoke detector etc., if any). Up to three external alarm inputs can be connected using dedicated overvoltage protected terminals inside of BTS. External alarm interface characteristics: Electromechanical contacts or optocoupler, floating Normal closed - alarm loop conductive in normal status (no alarm). Grounding All collocated equipment, antenna pole and feeders, BTS cabinet, external equipment, cable trays, must be properly connected to the site common bonding network (CBN) in shortest possible way.

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5.2.4.3 External Battery Cabinet Cabling There following cables are used to connect an external outdoor battery cabinet with a BTS and ground: PC05B5, 3BK 25561 AAAA, AC Power Cable, 3x2.5 mm² in 100 m roll PC25BL1D, 3BK 25995 AAAA, Power Cable (-48 V), 1x25 mm² blue in 100 m roll PC25B1D, 3BK 08963 BAAA, Power Cable (0 V), 1x25 mm² black in 100 m roll PC50YG1D, 3BK 08961 BAAA, Ground Cable, 50 mm² green/yellow in 100 m roll CA12058, 3BK 08965 AAAA, Alarm Cable, L907, 4 quads, 120 Ohms in 100 m roll CA-RIBEO, 3BK 26138 AAAA, RIBAT Cable external Battery outdoor. All external cables listed above are fixed installation cables connected to terminals at both sides. Cable lengths depend on the local distance between the battery cabinet and the BTS. The CA-RIBEO cable is connected to the first RIBAT board at the battery cabinet side. At the BTS side, the cable is connected to the OUTC board via an XBCB connector. The mechanical design of the CA-RIBEO cable/connector is found in External Cables (Section 17.2).

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6 Standard Telecommunications Subrack

6 Standard Telecommunications Subrack The sections are supported with diagrams and illustrations, where necessary. An illustration of the subrack is also included.

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6 Standard Telecommunications Subrack

6.1 STASR General Information The STASR is the standard telecommunications subrack for all BTS A9100 configurations. The number of subracks used, and the types of plug-in modules fitted into the subracks, is configuration dependent. Each STASR plug-in module has a unique number which identifies its position within the cabinet. The number consists of: Subrack number - coded on the subrack interconnecting ribbon cable Slot position within subrack - coded on the subrack backplane PCB. The possible plug-in modules can be: TRE SUMA/SUMP Antenna Network modules: ANC, ANX, ANY Power Supply equipment: ADAM, ADAM4, PM12 Microwave modules.

6.2 STASR Mechanical Characteristics The following figure shows the STASR with no modules fitted.

Inter−subrack Connector

Ground Connector

Power Connector

Module Connector

Subrack Fixing Lug

Hole for Camloc Fastener

FANU Guide Rail

Backplane

Module Guide Rail

Module Connector

Figure 282: STASR Construction For common information and dimensions refer to Subracks (Section 1.3). The STASR has an integral backplane, which provides the electrical and signaling interface for the modules. The backplane has nine connectors for the plug-in modules and three for the FANUs. An inter-subrack cable connector at the top of the backplane is provided for multiple subrack configurations. The power connection consists of three FASTON connectors. Refer to the STASR Electrical Description (Section 6.3) for a description of the subrack backplane.

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6 Standard Telecommunications Subrack

6.3 STASR Electrical Description The STASR is described below in terms of power supplies and grounding, the backplane, and connectors and cables.

6.3.1 Power Supplies and Grounding The STASR receives its -48/ -60 VDC supply from the cabinet DC distribution panel, via the cabinet bus bar. Each module fitted within the STASR has its own on-board DC/DC converter, except the ANY which is a passive RF module. Ground continuity, between the subrack and the equipment rack, is ensured by using earth linking straps. The straps are attached to the equipment rack bus bar at one end and terminated on the subrack with a FASTON connector. The subrack is also fixed to the equipment rack with conductive self-tapping screws.

6.3.2 Backplane The backplane is a multi-layer PCB. It distributes the -48/ -60 VDC, to power the subrack equipment, and the digital signals between the various plug-in modules. The following figure shows a front view of the backplane and the positions of the various connectors. Module Connectors

Power Connectors 0 V GND −48 V

Ribbon Cable Connector

FACB

FACB Connectors X113

X100

Equipment Label

X116

X117

Connector Identity X101

X102 X110

Pin 1, Row A

X103

X104

X105

X106 X111

X107

X108

X109 X112

FANU Connectors

Figure 283: STASR Backplane Connector Layout, Front View

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6.3.3 Connectors and Cables The following table lists and describes the STASR cables and connectors. For connector locations, see Figure 283. Name

Quantity

Type and Description

Module Connectors

9

Millipacs Type 1.

FACB Connectors

2

2 x 6-pin male Header type connector. 2 x 16-pin male Header type connector. The FACB connectors are linked to the FANU connectors via the backplane printed wiring.

FANU Connectors

3

Ribbon Cable

1

Type R 1/3 30-M connectors. Three FANU connectors are positioned at the bottom of the subrack backplane (see Figure 283). C 64 M (DIN 41612) connector. The cable is used to interconnect multiple subracks (see Figure CIMI/CIDI Subracks Interconnection Cable (184) and Figure 192). It is pre-equipped with the correct number of connectors for the number of subracks deployed.

Power Cable

1

Three-core twin and earth, terminated with a three-in-one FASTON connector.

Table 52: STASR Connectors and Cables The following table lists the module connectors and the associated modules. The symbol shows that the particular connector is a possible plug-in position for the associated module.

ConnectorSUMA

SUMP

X101

ANC

ANX

-

-

-

-

X102

-

-

X103

-

-

X104

-

-

-

X105

-

-

-

-

-

X106

ANY

-

TRE

TRE HP

IDU

-

-

-

-

-

-

-

-

-

X107

-

-

-

X108

-

-

-

X109

-

-

-

-

-

-

-

-

-

-

-

Table 53: STASR Module Connectors and Associated Modules

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7 AC Power Subracks

7 AC Power Subracks The sections are supported with diagrams and illustrations, where necessary. An illustration of each subrack is also included.

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7.1 SRACDC The SRACDC is the power subrack used for all BTS A9100 outdoor configurations with the PM08 power supply modules. It contains plug-in modules which convert the AC mains supply into a 48 VDC supply. The plug-in modules are fitted in predefined slots within the subrack. SRACDC contains the following modules: ACIB ACRI BACO BCU1 Up to five PM08s FANUs.

7.1.1 SRACDC Mechanical Characteristics The following figure shows the SRACDC subrack with no modules fitted. Pin 1, Row A

X200

X201

X202

Backplane

Connector Identity

Subrack Fixing Lug

X100

X101

X102

X103

X104

X106

Module Guide Rail

FANU Connector

Hole for Camloc Fastener

FANU Guide Rail

Module Connectors

Figure 284: SRACDC Subrack Front View For common information and dimensions refer to Subracks (Section 1.3). The SRACDC has an integral backplane, which provides the electrical and signaling interface for the modules. The backplane contains nine connectors for the plug-in modules and three for the FANUs.

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7.1.2 SRACDC Subrack Layout Modules are fitted at the predefined positions shown in the following figure.

BACO

PM08/5

PM08/4

ACRI

PM08/3

PM08/2

ACIB

PM08/1

BCU1

Figure 285: SRACDC Module Positions There are five PM08 slots. The PM08s are identified by numbers in the range 1 to 5, as shown.

7.1.3 SRACDC Electrical Description The SRACDC is described below in terms of power supplies and grounding, the backplane, and connectors and cables.

7.1.3.1 Power Supplies and Grounding The SRACDC power supply system subrack is fixed to the equipment rack with conductive self-tapping screws. Ground continuity is maintained by the metal fittings and securing brackets. The SRACDC is isolated from the AC supply voltage. The 230 VAC supply from the ACSB connects directly to the AC IN connector on the front of ACIB (see the following figure). From there it connects to the front of the PM08s where it is converted to 0/ -48 VDC. The DC is connected to the SRACDC backplane for distribution to: BACO for charging the optional batteries DCDP for further distribution to the STASR subracks, XIOB and HEX2s.

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7.1.3.2 Backplane The SRACDC backplane distributes the 0/ -48 VDC to the subrack equipment that requires it. Two power cables carry the DC power to the equipment external to the SRACDC. The following figure shows a rear view of the backplane and the positions of the various connectors. X204 X204

−48V R211

R201

X203

0V

X203 Module Connector

0/−48 VDC Power Out Connectors

FANU Connector

Figure 286: SRACDC Backplane Connector Layout Rear View

7.1.3.3 Connectors and Cables The following table lists and describes the SRACDC subrack cables and connectors. For connector locations, see Figures SRACDC Subrack Front View (284) and SRACDC Backplane Connector Layout Rear View (286). Name

Quantity

Type and Description

Module Connectors

6

H15-F (DIN 41612). The connectors are used by the PM08s and the BACO.

Module Connectors

3

R64-M-a-c (DIN 41612). The connectors are used by the ACRI, BACO and BCU1.

FANU Connectors

3

Type R 1/3 30-M connectors. Three FANU connectors are positioned at the bottom of the subrack backplane (see Figure 286).

Ribbon Cable

1

C 64 M (DIN 41612) connector. The cable is used to interconnect multiple subracks. It is pre-equipped with the correct number of connectors for the number of subracks deployed.

Power Cables

2

60 A power terminals M5 x 8. The cables carry the 0/-48 VDC to the interconnection panel.

Table 54: SRACDC Connectors and Cables

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7.2 ACSR The ACSR is the power subrack used for BTS A9100 outdoor configurations with PM11 power supply modules. ACSR contains plug-in modules which convert the AC mains supply into a 48 VDC supply. The plug-in modules are fitted in predefined slots within the subrack. ACSR contains the following modules: BAC2 BCU2 Up to four PM11s FANUs.

7.2.1 ACSR Mechanical Characteristics The following figure shows the ACSR subrack with no modules fitted. Pin 1, Row A

Backplane

Subrack Fixing Lug

Module Guide Rail

Hole for Camloc Fastener

FANU Guide Rail

FANU Connector

Module Connectors

Figure 287: ACSR Subrack Front View For common information and dimensions refer to Subracks (Section 1.3). The ACSR has an integral backplane, which provides the electrical and signaling interface for the modules. The backplane contains six connectors for the plug-in modules and two for the FANUs.

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7.2.2 ACSR Subrack Layout Modules are fitted at the predefined positions shown in the following figure.

BAC2

PM11/4

PM11/3

PM11/2

PM11/1

BCU2

Figure 288: ACSR Module Positions There are four PM11 slots. The PM11s are identified by numbers in the range 1 to 4, as shown.

7.2.3 ACSR Electrical Description The ACSR is described below in terms of power supplies and grounding, the backplane, and connectors and cables.

7.2.3.1 Power Supplies and Grounding The ACSR power supply system subrack is fixed to the equipment rack with conductive self-tapping screws. Ground continuity is maintained by the metal fittings and securing brackets. The ACSR is connected to the AC supply voltage. The 230 VAC supply from the ACSB connects to the ACSR backplane. From there it connects to the PM11s where it is converted to 0/ -48 VDC. The DC is connected to the ACSR backplane for distribution to: BAC2 for charging the optional batteries BOBU for further distribution to the STASR subracks, XIOB and HEX2s.

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7.2.3.2 Backplane The ACSR backplane distributes the 230 VAC supply from the ACSB to the PM11s. The backplane also distributes the 0/ -48 VDC to the subrack equipment that requires it. One five-wire power cable carries the AC power from the ACSB to the backplane. Two power cables carry the DC power to the equipment external to the ACSR. The following figure shows a rear view of the backplane and the positions of the various connectors.

Module Connector

L1 L2 N L3

230 VAC Power In Connectors

GND (M5 Bolt)

FANU Connector

0/−48 VDC Power Out Connectors

Figure 289: ACSR Backplane Connector Layout Rear View

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7.2.3.3 Connectors and Cables The following table lists and describes the ACSR subrack cables and connectors. For connector locations, see Figures ACSR Subrack Front View (287) and ACSR Backplane Connector Layout Rear View (289). Name

Quantity

Type and Description

Module Connectors

5

H15-F (DIN 41612). The connectors are used by the PM11s and BAC2.

Module Connectors

1

R64-M-a-c (DIN 41612). The connector is used by BCU2.

FANU Connectors

2

Type R 1/3 30-M connectors. Two FANU connectors are positioned at the bottom of the subrack backplane (see Figure 289).

Ribbon Cable

1

C 64 M (DIN 41612) connector. The cable is used to interconnect multiple subracks. It is pre-equipped with the correct number of connectors for the number of subracks deployed.

AC Power Cables

1

Four FASTON connectors and one M5 x 8 terminal. The cables carry the 230 VAC (L1, L2, L3, N, and GND) from the ACSB.

DC Power Cables

2

60 A power terminals M5 x 8. The cables carry the 0/ -48 VDC to the interconnection panel.

Table 55: ACSR Connectors and Cables

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7.3 ASIB The ASIB is the power subrack for the BTS A9100 indoor configurations powered from an AC mains supply. It contains plug-in modules which convert the AC mains supply into a 48 VDC supply. The plug-in modules are fitted in predefined slots within the subrack.

7.3.1 ASIB Mechanical Characteristics The following figure shows the ASIB subrack with no modules fitted. Pin 1, Row A

X201

X202

X250

Backplane X300 Connector Identity

Subrack Fixing Lug

X100

X101

X102

X103

X104

X106

Module Guide Rail

FANU Connector

Hole for Camloc Fastener

FANU Guide Rail

Module Connectors

Figure 290: ASIB Front View For common information and dimensions, refer to Subracks (Section 1.3). The ASIB has an integral backplane, which provides the electrical and signaling interface for the modules. The backplane has nine connectors for the plug-in modules and three for the FANUs.

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7.3.2 ASIB Layout Modules are fitted at the predefined positions shown in the following figure.

ABAC

PM08/5

PM08/4

APOD

PM08/3

PM08/2

PM08/1

ACRI

BCU1

Figure 291: ASIB Module Positions There are five PM08 slots. The PM08s are identified by numbers in the range 1 to 5, as shown.

7.3.3 ASIB Electrical Description The ASIB is described below in terms of power supplies and grounding, the backplane, and connectors and cables.

7.3.3.1 Power Supplies and Grounding The ASIB is isolated from the AC supply voltage. The 230 VAC supply from the AFIP connects via the backplane to the APOD. From there it connects to the front of the PM08s where it is converted to 0/ -48 VDC. The DC is connected to the ASIB backplane for distribution to: ABAC for charging the optional batteries Cabinet cable trunk for further distribution to the STASR subracks. The subrack is fixed to the equipment rack with conductive M6 screws. Ground continuity is maintained by the metal fittings and securing brackets.

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7.3.3.2 Backplane The backplane distributes the 0/ -48 VDC to the subrack equipment that requires it. Four power cables carry DC power to the equipment external to the ASIB. The following figure shows a rear view of the backplane and the positions of the various connectors.

Module Connector

FANU Connector

Figure 292: ASIB Backplane Connector Layout Rear View

7.3.3.3 Connectors and Cables The following table lists and describes the ASIB subrack cables and connectors. For connector locations, see Figures ASIB Front View (290) and ASIB Backplane Connector Layout Rear View (292). Name

Quantity

Type and Description

Module Connectors

6

H15-F (DIN 41612). The connectors are used by the PM08s and the ABAC.

Module Connectors

3

R64-M-a-c (DIN 41612). The connectors are used by the ACRI, ABAC and BCU1.

FANU Connectors

3

Type R 1/3 30-M connectors. Three FANU connectors are positioned at the bottom of the subrack backplane (see Figure 292).

Ribbon Cable

1

C 64 M (DIN 41612) connector. The cable is used to interconnect multiple subracks. It is pre-equipped with the correct number of connectors for the number of subracks deployed.

Power Cables

4

60 A power terminals M5 x 8. The cables carry the 0/ -48 VDC to the interconnection panel.

Table 56: ASIB Connectors and Cables

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8 Station Unit Modules The sections are supported with diagrams, where necessary, showing the functional blocks and their interfaces. A drawing of the physical appearance of the module is also included, showing LED indicators, connectors and controls.

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8.1 Introduction to Station Unit Modules The SUMP/SUMA provides the central management and control of all the BTS A9100 modules. It is responsible for the following functional areas: Digital transmission Timing and clock generation Management of the BTS internal digital interfaces O and M functions RI Control of the AC/DC converters and check of the batteries (SUMA only). The following figure gives an overview of all the interfaces connected to the SUMP/SUMA.

BTS BTS G1/G2/A9100 EXT CLK ref

XCLK(14)

BTS A9100 CLKI (13) OML(1) RSLi(7), TCHi(8)

RSL(2),TCH(3) BSC

TRE

IOM(10), IOM−CONF(9)

RCB(5)

IOM(10), IOM_CONF(9)

Other Abis flows(6)

AN TSC

SUMA/ SUMP

Qmux(4)

AC/DC

IGPS (16) GPS

XGPS (15) REL_CON(18)

Internal GPS receiver

FAN

*) Battery

CA EBCB(12)

BCB(11)

MMI(17)

*) Battery XBCB(12) External tool

: *) for SUMA only

BTS Terminal

Figure 293: The SUMP/SUMA in its Environment The following table provides information relative to the links mentioned in the figure above. All external links connected to the CA in Figure 293 are routed through the CA to the SUMA/SUMP.

Note:

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The AN, ANX, ANY, ANC modules are connected to the BCB, but only the ANX and ANC are connected to IOM and IOM_CONF.

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Link

1

Comment

OML

L

The link carries O and M messages between the BSC and BTS. The link is routed by the SUMP/SUMA from/to Abis to/from BSII.

RSL

L

These links are transparently routed by the SUMP/SUMA from/to Abis

TCH

L

To/from the BSII.

Qmux

L

This link is used for the remote transmission O and M between the TSC and the Transmission part of the BTS.

RCB

L

This link is used to control the ring functions between the BIEs by managing F, S, R, FEA, AIS bits.

Other Abis flows

L

All the other flows carried by the Abis are transparently routed in Abis ring or drop through the SUMP/SUMA.

RSLi

L

The Radio signaling Link is for TRE telecom function.

TCHi

L

The Traffic Channel is for TRE telecom function.

IOM_CONF

L

It is used to broadcast the IOM configuration by the SUMP/SUMA.

IOM

L

This link carries O and M messages exchanged between the SUMP/SUMA and other BTS modules connected on the IOM. These links are used for BTS internal O and M between SUMP/SUMA and other BTS equipment.

BCB

P

The link is connected to other BTS modules and allows the BTS Remote Inventory supported by SUMP/SUMA.

XBCB (EBCB)

P

The link is connected to the external tool for Remote Inventory. XBCB is changed into EBCB in between SUMP/SUMA and CA. When the SUMP/SUMA is powered off, the BTS module Remote Inventory information is reported to the external tool through the EBCB. This feature is used only at factory level. When the SUMP/SUMA is powered on, the alarms from XIOB are reported to SUMP/SUMA through the EBCB.

CLKI

P

This link distributes BTS internal synchronizing signals to TRE and AN.

XCLK

P

The link carries BTS external clock synchronization signals for either the master or slave configuration.

XGPS

P

These flows are used in order to communicate with the GPS system. It is External GPS when the GPS system is outside the BTS and Internal GPS when it is plugged inside the SUMP/SUMA. These flows carry the supervision interface of the GPS system (Configuration, Fault).

IGPS

P

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These flows carry the GPS CLK reference.

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Link

1

Comment

MMI

L

This link is connected to a PC used as a BTS Terminal which includes the local BTS O and M application. it includes: The download of software for SUMP/SUMA and other BTS downloadable modules The BTS commissioning tests The O and M commands for the Transmission part of the SUMP/SUMA The O and M commands for the Clock part of the SUMP/SUMA (for OCXO calibration and OCXO tuning).

REL_CON

P

This relay command flow is used to control Abis relays. This flow has its own physical interface.

Table 57: SUMP/SUMA Interfaces 1)

This column indicates for each link if it is a logical link (L) or a physical link (P).

The following figure shows the functional block diagram of the SUMP/SUMA. External Interfaces

Internal Interfaces System Master Clock, TDMA Frame Clock and Frame Number Distribution to TRE and AN

XCLK XGPS CLK

Abis 1 Abis 2

CLKI

2 Mbit/s 2 Mbit/s

2 Mbit/s Transmission & Clock

BSII Switch and Timing

HFFI 2 Mbit/s 2 Mbit/s 2 Mbit/s

XGPS

BSII 0 BSII 1 BSII 2 (SUMA only)

XRT MMI

XBCB

HFFI

O&M

RI

BCB

Hook for Future Interface: It consists of 4 Lines which are in the backplane and which are free for future evolution.

Figure 294: SUMP/SUMA Basic Architecture

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The SUMP/SUMA provides a switchable 2 Mbit/s duplex connection between the Abis Interface and the BSII. The BSII is used to transfer TCH information to the TRE module, and O and M information to the OMU/SUM microprocessor. SUMA has an additional BSII 2 interface. This is used exclusively to carry TCH information. The SUMP/SUMA comprises the following functional blocks: Transmission and Clock BSII OMU RI. The SUMP uses two microprocessors, the SUMA only one to run the software/firmware for the O and M and Transmission and Clock functions.

8.2 Transmission and Clock Functions The SUMP/SUMA Transmission and Clock functions provide: Clock selection and generation Two 2 Mbit/s interfaces to the BSC, via a PCM link. The following figure shows the Transmission and Clock architecture. XCLK CGU

XGPS CLK

2 Mbit/s

Abis 1

2 Mbit/s

Abis 2

Abis 3

Abis 4

CLK

Framer

CLK

Framer

CLK

Framer

CLK

CLKI

Time Slot Switch

2 Mbit/s

Time Slot Switch

2 Mbit/s

Framer

Optional with Piggy−back Board

XGPS TMMI

Transmission & Clock Micropro− cessor (*) (*) for SUMA part of the SUM processor

BSII 0 BSII 1 BSII 2 (SUMA only)

Figure 295: SUMP/SUMA Transmission and Clock Architecture The principal functional components and interfaces of the Transmission and Clock are as follows: Abis Interface Transmission and Clock microprocessor CGU Q1 link.

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8.2.1 Abis Interface The Abis Interface is the digital interface to the BSC. The SUMP/SUMA provides two G.703 Abis Interfaces. They support the following communications links: TCH, which carries speech and/or data OML, which uses a LAPD protocol RSL, which carries signaling data for the telecommunications functions Q1 Link, which carries transmission management data. Relays, mounted on the cabinet interconnection panel, are used to route the Abis links transparently if the SUMP/SUMA is switched off. The Abis Interface consists of the functional entities shown in the following table. Clock Recovery

The Clock circuit recovers timing from the PCM link.

Framer Device

The Framer is responsible for: Insertion of frame/multiframe synchronization patterns Monitoring frame and multiframe synchronization HDB3 coding/decoding for PCM AIS detection Frame and CRC error detection. The Framer can be configured for CRC by the Transmission and Clock/SUM microprocessor, via the Time Slot Switch.

Time Slot Switch

The Time Slot Switch is responsible for mapping the 64 kbit/s time slots onto the TCH. The switch is configured by the Transmission and Clock/SUM microprocessor.

Loop-back Relays

Relays on the SUMP/SUMA provide a loop-back on the Abis Interface for testing the Abis links.

Table 58: SUMP/SUMA, Abis Interface Functional Entities Two additional Abis Interfaces can be implemented with a ’Piggy-back’ board (SUMA only). This is an optional feature of the BTS A9100.

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8.2.2 Transmission and Clock Microprocessor In case of SUMA the Transmission and Clock functions run on the only SUM microprocessor. The Transmission and Clock microprocessor controls the transmission and clock functions on the SUMP/SUMA. It consists of a QUICC (SUMP) or PowerQUICC (SUMA), with access to the RAM and to the EEPROM. The external signal connected to the microprocessor is the XGPS, for controlling a GPS receiver.

8.2.3 Station Unit Module Clock Generation Unit The functions of the clock generation unit consist of the: Generation of the GSM clock by an internal OCXO for TRE and AN modules in the BTS Possibility to synchronize the OCXO: On an external clock reference coming from (Slave synchronization Slave BTS) another BTS (G1, G2, BTS A9100) On the Abis clock (PCM synchronization - Master BTS) On the GPS CLOCK receiver (GPS synchronization - Master BTS) No synchronization (OCXO in free run mode) (OCXO free running Master BTS). Generation of both frame clock and frame number for TRE and AN modules in the BTS: For the Master BTS, it is a local generation For Slave BTS, both frame clock and frame number are aligned on those provided by the Master BTS. Distribution through the CLKI of GSM clock, frame clock and frame number OCXO calibration (which is done on time in the factory and consists of the measurement of the OCXO curve and is stored in the SUM EEPROM) OCXO tuning (which consists of the change of the OCXO tuning value) Possibility to synchronize other BTSs (G1 BTS, G2 BTS, BTS A9100). In the case of ’OCXO free running’, an on-site periodic electronic tuning is necessary. (For further information, refer to the Evolium BTS A9100/A9110 Corrective Maintenance Handbook). Regarding ’GPS synchronization’, the SUMA hardware is ready to have a GPS receiver plugged in. ’GPS synchronization’ concerns frequency synchronization and time synchronization (so that all BTSs have the same Frame Number).

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8.2.4 Q1 Link The Q1 link is a logical link routed via the Abis Interface, the Time Slot Switch, the BSII switch and the BSII to the OandM functions. The OandM functions are performed remotely by the BSC TSC, via the Q1 link, or locally via a BTS Terminal. All BTS A9100 transmission equipment have Q1 addresses, which identify them to the TSC. The transmission equipment is supervised by the TSC using the Q1 protocol. The TSC, or a local BTS Terminal, can interrogate the SUMP/SUMA for the following data: Performance measurement Alarms Abis clock source Loop request Firmware version Hardware version. The Q1 link is also used for software downloads, for configuration purposes.

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8.3 Base Station Internal Interface The BSII is an internal digital interface to the TRE module. The BSII bus consists of three 2 Mbit/s full duplex links: BSII 0 BSII 1 BSII 2. The BSII basically consists of the following two functional components: BSII PLL The BSII PLL is logically a part of the CGU. It locks the BSII CLK to a fixed frequency of 2.048 MHz. The clock is then distributed to the Transmission and Clock/SUM microprocessor, and an NGISL device. Distribution is via the SUMP/SUMA Glue Logic. The NGISL device is an ASIC, providing an internal serial link to the Remote Inventory EEPROM. It also performs serial-to-parallel conversion, to allow the OMU microprocessor access to the EEPROM. BSII Switch The BSII switch performs the following functions: Distribution of the system clock, TDMA frame clock and FN 64 kbit/s time slot mapping Q1 message routing. The BSII switch is implemented with a CPLD, which is a part of the Glue Logic. Its main function is to select between BSII 0, BSII 1 and BSII 2, which are the internal interfaces for O and M data distribution and uplink and downlink TCH. The data is multiplexed, via line drivers, onto the internal interfaces under control of the Transmission and Clock/SUM microprocessor. The Glue logic monitors the status of the BSII PLL via a lock detect signal. The drivers are disabled if the PLL is not locked to the BSII clock.

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8.4 Operations and Maintenance Functions The O and M functions include: Starting the BTS A9100 Configuring the BTS A9100, under control of the BSC Executing maintenance commands Filtering and correlating faults Reporting, and acting on, the status of the modules Controlling the PM12s, depending on the battery status (SUMA only). The OMU/SUM microprocessor performs the following O and M functions: Configuration management Fault management Performance management Configuration and supervision of the BSII Routing MMI messages to the Transmission and Clock microprocessor (SUMP only) Test facilities. The O and M architecture is shown in the following figure. It consists of the following functional entities: OMU microprocessor for SUMP and for SUMA as part of the SUM processor SDRAM Flash EEPROM NGISL ASIC Glue logic. XRT External Interfaces

OMU Microprocessor (*)

MMI LEDs

SDRAM

Flash EEPROM

Control Bus

Reset

BSII

Address & Data Bus

Glue Logic

(*) for SUMA part of the SUM processor

NGISL

BCB

Remote Inventory

Figure 296: SUMP/SUMA, O and M Architecture

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8.4.1 BTS Control Bus Most of the internal control functions are managed via the BCB. The BCB also interfaces to an EEPROM which holds inventory information on the BTS A9100 modules. The BCB is used for the following functions: Accessing the RI Detecting module insertion/extraction Collecting alarm/data Controlling the battery and PM12s (SUMA only). The BCB is also used for: Remote bit setting Remote bit setting consists of setting memory bits to control, disable or reset certain hardware. There are eight such BCB bits available, one of which is reserved for power supply control Boundary scanning Boundary scanning allows remote access to a particular module, via a boundary scan path. This facility can be used to reprogram the module’s initialization sequence. For example, by downloading fresh data to an on-board Flash EEPROM.

8.4.2 OMU Microprocessor In the SUMA, the O and M functions only run on the SUM processor. The OMU microprocessor controls the O and M functions on the SUMP. It is a Power QUICC device, with access to the following memory devices: SDRAM, organized as 32 bits wide and accessible in 8, 16 or 32 bit words Flash EPROM providing memory that is 32 bits wide. The external signals connected to the microprocessor are: MMI - for connecting a BTS terminal XRT - for radio supervision and loop tests.

8.4.3 Glue Logic Glue logic, implemented as a PLA, supports the CPU and connects the various functional blocks together.

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8.5 Remote Inventory The Remote Inventory is related to an Alcatel standard. It consists of storing in non-volatile memory the basic information related to a module from the hardware (and possibly software) point of view. This information is available out of the module even for unpowered modules. The range of information goes from module manufacturing (serial number, manufacturing and repair history, ...) to module design (part number, hardware capability, firmware release...). One part of the Remote Inventory is mandatory, while another is optional. Access to the inventory information is ’remote’ because it is managed externally to the module. However, this access can be requested from different levels: Module access Inventory of the unplugged (and so unpowered) modules through a dedicated module connector Internal BTS access Inventory of all BTS modules from a central node internal to the BTS (SUMP/SUMA). Only the SUMP/SUMA has to be powered. External BTS access Inventory of all BTS modules from a central node external to the BTS (XBCB-connected tool). It is used at factory level when the complete BTS is unpowered (including the SUMP/SUMA). For both internal and external BTS accesses, the BCB is used.

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8.6 Station Unit Module Power Supply The SUMP is powered by two identical DC/DC converters. The DC/DC converters work in parallel to provide all the voltages required by the SUMP circuitry. This parallel mode of operation provides redundancy. If one DC/DC converter fails, the other is capable of supplying all the necessary SUMP voltages. The SUMA is powered by a single, highly reliable DC/DC converter. The SUMP/SUMA DC/DC converters’ input/output voltages are shown in the following table. Voltage

Value

V in

-38.4 VDC min. -72 VDC max. -48 VDC to -60 VDC nom.

V out SUMP

+ 3.3 VDC ±3 % + 5.1 VDC ±3 % + 12 VDC ±10 %

V out SUMA

+ 3.3 VDC ±2 % + 5.1 VDC ±2 %

Table 59: SUMP/SUMA Input/Output Voltages Normal operation of V out is unaffected by temperature fluctuations in the range -10o C to 70o C. The power supply also has the elements described below.

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Fuse

The inputs of the power supply are protected by an on-board fuse, located on the SUMP/SUMA board.

Protection

The SUMP/SUMA power supply circuitry is protected against short circuit and accidental polarity inversion on its inputs.

Grounding

Ground continuity for the module is achieved with ground pins on the subrack backplane which connect to the bus bar ground.

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8.7 Station Unit Module LEDs There are eight LEDs on the SUMP front panel or six LEDs on the SUMA front panel, which provide a visual indication of the operational status of the SUMP/SUMA module (see Figure 297). The following table describes each LED and provides a definition of the various operational states. LED

Color

OML

Yellow

ABIS 1

O and M

ABIS 2

OMU (for SUMP) FAULT (for SUMA)

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Status

Description

SUMP

SUMA

Status of the OML.

X

X

X

X

X

X

X

X

X

X

On

Link connected.

Blinking

Connecting link.

Off

Link disconnected.

Yellow

Status of Abis1 for Transmission and Clock. On

Abis 1 serviceable.

Blinking

Failure detected on Abis1 .

Off

Not configured or not used.

Yellow

O and M status for the OMU. On

Operational.

Blinking

In a transient state, before reaching the operational state.

Off

Not used.

Yellow

Status of Abis2 for Transmission and Clock. On

Abis 2 serviceable.

Blinking

Failure detected on Abis2 .

Off

Not configured or not used.

Red

OMU alarm status.

On

Fatal alarm or module is unserviceable.

Blinking

Non-fatal alarm.

Off

No alarm.

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8 Station Unit Modules

LED

Color

Status

Trans FAULT

PS1 (for SUMP)

PS2

ABIS 3

ABIS 4

SUMP

SUMA

Transmission and Clock alarm status.

X

-

X

X

X

-

-

(X)

-

(X)

On

Fatal alarm or module is unserviceable.

Blinking

Non-fatal alarm.

Off

No alarms.

Green

ON (for SUMA)

Description

Converter 1 status.

On

Converter 1 serviceable.

Off

Converter 1 faulty.

Green (SUMP only)

Converter 2 status.

On

Converter 2 serviceable.

Off

Converter 2 faulty.

Yellow

Status of Abis 3 for Transmission and Clock. On

Abis 3 serviceable.

Blinking

Failure detected on Abis 3.

Off

Not configured or not used.

Yellow

Status of Abis 4 for Transmission and Clock. On

Abis 4 serviceable.

Blinking

Failure detected on Abis 4.

Off

Not configured or not used.

Table 60: SUMP/SUMA LED Descriptions (X) Optional, if piggy-back board is connected on the SUMA board.

Note:

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During a reset of the OMU microprocessor, all the red and yellow LEDs are lit for approximately 100 ms. This is a test of the LEDs to make sure they are all working.

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8.8 Station Unit Module Front Panel The following figure shows the SUMP and SUMA front panels. SUMP

SUMA Camloc Fasteners Module Extractors

Abis 1/2 Connector

Abis 3/4 Connector

Equipment Label

LEDs

BTS Connection Area Connector

Optional Piggy− back Board

BTS Terminal Connector

Test Connector

USB Connector OML

ABIS1

O&M

ABIS2

OMU

Trans FAULT

PS1

PS2

LEDs

GPS Connector

LEDs

Figure 297: SUMP/SUMA Front Panel

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The following table describes the SUMP/SUMA front panel connectors. Connector

Type

Description

SUMP

SUMA

Abis 1/2

9-pin Sub-D female

Provides two Abis Interfaces. The connector is pre-equipped for both 75 and 120 impedance cables. The impedance is selected by the type of cable connector used.

X

X

Two more Abis Interfaces are possible with a piggy-back board. Abis 3/4

9-pin Sub-D female

Provides two Abis Interfaces on SUMA piggy-back board. The connector is pre-equipped for both 75 and 120 impedance cables. The impedance is selected by the type of cable connector used.

-

X

BTS Connection Area

37-pin Sub-D female

Provides the following digital interfaces:

X

X

XBCB XRT XGPS XGPS CLKX CLK1 Abis relay control.

BTS Terminal

9-pin Sub-D female

For connecting a computer terminal. It provides a V.24 asynchronous serial interface, which can be used for local maintenance and configuration purposes. Presence of a terminal is automatically detected.

X

X

BTS Terminal

USB port

For connecting a computer terminal. It provides a high-speed serial interface, which can be used for local maintenance and configuration purposes. Either the V.24 interface or the USB interface can be connected to a BTS Terminal, but not both. Presence of a terminal is automatically detected.

-

X

Test

9-pin Sub-D male

Provides remote access to the OMU and Transmission and Clock microprocessors (in case of SUMP) and to the SUM processor (in case of SUMA) for factory test purposes.

X

X

GPS

SMA female

Provides a synchronization output from an optional on-board GPS receiver.

-

X

Table 61: SUMP/SUMA Front Panel Connectors

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9 Transceiver Equipment

9 Transceiver Equipment The sections are supported with diagrams showing the functional blocks and their interfaces. A drawing of the physical appearance of the module is also included, showing LED indicators, connectors and controls.

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9 Transceiver Equipment

9.1 Single Transceiver Equipment 9.1.1 Introduction to Transceiver Equipment The TRE combines digital baseband and analog RF functions in one module. The architecture is split into three functional blocks: Digital part TRED Analog part TREA with the power amplifier TEPAxx (for TADH/TAGH/TRAD/TRADE/TRAG/TRAGE/TAGHE/TRAL/TRAP), TEPADHE (for TADHE) or TREPAxx (for TRDH, TRDM, TRGM, TRPM) Power supply TREP (for TRDH, TRDM, TRGM, TRPM), TREPS (for TRAG/TRAD), or TREPSH (for TADH/TRADE/TADHE/TAGH/TRAGE/TAGHE/TRAL/TRAP). In the TADH/TRADE/TADHE/TAGH/TRAGE/TAGHE/TRAD/TRAG/TRAL/TRAP TRE variants TRED and TREA are implemented in one submodule (TREDAx). The TRE basic architecture is shown in the following figure. TREDAx (for TADH/TRAD/TRAG/TRAL/TRAP) TREDAxE (for TRADE/TADHE/TRAGE/TAGHE) T(R)EPAxx TRED

TREA

to ANCx from

TREPxx

Figure 298: TRE Basic Architecture The TRE performs the digital functions interface to the SUM and the analog functions interface to the AN module. The TRE contains its own integrated power supply.

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9 Transceiver Equipment

The following types of TRE modules are available for the different BTS A9100 variants: TADH, TRE high power module for GSM 1800 TAGH, TRE high power module for GSM 900 TRAD, TRE medium power module for GSM 1800 TRADE, TRE module medium power for GSM 1800, enhanced 8-PSK power TADHE, TRE high power module for GSM 1800 GMSK and 8-PSK TRAG, TRE medium power module for GSM 900 TRAGE, TRE module medium power for GSM 900, enhanced 8-PSK power TAGHE, TRE high power module for GSM 900 GMSK and 8-PSK TRAL, TRE medium power module for GSM 850 TRAP, TRE medium power module for GSM 1900 TRDH, TRE high power module for GSM 1800 TRDM, TRE medium power module for GSM 1800 TRGM, TRE medium power module for GSM 900 TRPM, TRE medium power module for GSM 1900. GSM 850 is not supported by all BSS software releases. If you are in doubt, contact Alcatel support.

9.1.2 Digital Functions The following figures show a block diagram of the TRED hardware architecture. They show the functional blocks, relative to each other, and the interfaces to the TRED. The shaded areas identify separate functional blocks, which are implemented on the same hardware device.

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9.1.2.1 TRED Architecture of TRDH, TRDM, TRGM, TRPM RCD

RPI

Power Switch/Reset MMI/Debug 1

Debug 2

LEDs

ETI

RI

BCBT ADR

SCP

ETA

CLKI I2C

CGU ECPL

MBED DEM BSII 0

DEC

BSII 1 MUX

BED

DEM

CUL

CUI

FHL HFFI

TXP

ENC

ENCT

Figure 299: TRED Architecture (TRDH, TRDM, TRGM, TRPM) The TRED (TRDH, TRDM, TRGM, TRPM) consists of the following functional entities (refer to the figure above): Entity Control Parallel Link (ECPL) signaling and Control Processor (SCP) Decoder (DEC) Demodulator (DEM) Multiplexer, Baseband, Encryption and Decryption (MBED) Encoder and Transmitter Processor (ENCT) Carrier Unit Logic (CUL) Clock Generation Unit (CGU) External Test Adapter (ETA) Remote Inventory (RI).

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9.1.2.2 TRED Architecture of TADH, TAGH, TRAD, TRADE, TADHE, TRAG, TRAGE, TAGHE, TRAL, TRAP RCD

RPI

Power Swit/Reset

USB : MMI Debug ET

LEDs

RI

BCB ADR

SCP

I2C

CLKI BSII0 BSII1 BSII2

CGU ECPL

DCOP

UBEL

IRDMC

MBED

DEM DRCS

From IF Filter

FHL

BBTX

To

HFFI

ASIC

I/Q Modulator

IRDM DEC MUX

DEM

BED

TXP

ENC

ENCT

on TREA

Figure 300: TRED Architecture (TADH, TAGH, TRAD, TRADE, TADHE,TRAG, TRAGE, TAGHE, TRAL, TRAP)

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The TRED (TADH, TAGH, TRAD, TADHE, TRADE, TRAG, TRAGE, TAGHE, TRAL, TRAP) consists of the following functional entities (refer to the figure above): ECPL SCP DEC DEM Incremental Redundancy Data Memory (IRDM) MBED, part of the UBEL Decoder Co-processor (DCOP), part of the UBEL IRDM Controller (IRDMC), part of the UBEL United Baseband Logic (UBEL), containing the MBED, DCOP, and IRDMC ENCT CGU RI Baseband ASIC for Transmitter (BBTX), located on the TREA Diversity Receiver Chip Set (DRCS), located on the TREA.

9.1.2.3 TRED System Interfaces The TRED provides a number of system interfaces. The following table briefly describes each of them (see also Figures 299 and 300). ADR

Module address: provides a unique address to each module in the BTS. Used to set BCB physical BCB terminal address and BSII HDLC address.

BCB

Base station control bus: used for Remote Inventory (RI) read write and for controlling and supervision of the power supply.

CLKI

Clock interface: used to distribute the Evolium BTS A9100 master clock and the frame clock multiplexed on the same line with the frame number in a serial format.

BSII

Base station internal interface: transfers all TCH-related data (traffic and signaling) and internal O and M data. TADH/TAGH/TRAD/TRADE/TADHE/TRAG/TRAGE/TAGHE/TRAL/TRAP: three links, TRDH/TRDM/TRGM/TRPM: two links.

HFFI

Hook for future interface, is a spare interface and can be used for future extensions.

FHL

Frequency hopping link: used for downlink baseband frequency hopping.

RCD

Remote cabling detection: detects DC voltage variations on the TREA receiver inputs.

RPI

Remote power interface: consists of: Power lines for TRED and TREA DC supply On/off control of the power supply Alarm handling for the TREP/TREPS/TREPSH DC input and DC output signals.

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MMI/ Debug 1

Debug interface: for TRE (development and validation only).

Debug 2

Debug interface: for TRE (development and validation only).

PSwitch/Manual front panel power switch: disables the TREP/TREPS/TREPSH for TRE maintenance Reset (security function for actions on RF cables). Also used to generate the push button reset (PB_SRST) with fast off/on sequence. LEDs

Front panel LED control.

ETI

Used to trace the ECPL, or access it with a test tool.

I2C

Interface to the TREA EEPROM which stores the calibration and adjustment data.

CUI

Transfers uplink and downlink TCH data, and configuration/control data between TRED and TREA.

USB

Universal serial bus as known from the personal computer domain. It is used to channel the tool interfaces ET/ISA, MMI, ALFS and Debug which are all targets for communication with a PC.

Table 62: TRED Interface Descriptions

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9.1.2.4 Entity Control Parallel Link The ECPL is the main internal control bus. It provides a parallel interface between the SCP and the other functional blocks in the TRED.

9.1.2.5 Signaling and Control Processor The SCP performs Layer 2 and Layer 3 central processing for signaling and O and M functions. Layer 2 performs O and M functions using LAPD protocols. Layer 3 performs general traffic management functions for the Air Interface. The SCP consists of a Power QUICC device, supported by SDRAM and Flash Memory. The following figure shows a block diagram of the SCP and its peripheral memory and logic devices. USB MMI (only TRAx/TADH) RI

LEDs

SCP Microprocessor

Flash Memory

SDRAM

I2CA

Address & Control Bus Chip Select Data Bus TRED Glue Logic

BSII

ETA

Power Switch/ Reset

ETI

Only TRGM, TRDM, TRDH, TRPM ECPL

Figure 301: TRED, SCP Functional Blocks

9.1.2.6 Decoder The decoder performs uplink channel decoding, and interfaces the TRAU frames to the BSII. The hardware consists of a DSP and an SRAM. The functions performed by the decoder are: Soft-decision bit combining for antenna diversity (TRDH, TRDM, TRGM, TRPM) Decryption and decryption process control On the terrestrial link side: Rate adaptation TRAU frame adaptation. On the radio channel side: Channel decoding Speech, data and signal de-interleaving. Measurements preprocessing In-band control of the demodulator.

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9 Transceiver Equipment

Block Diagram

The following figure shows a functional block diagram of the decoder. To/From MBED

Coded Uplink Data

Decoded Uplink Data

ECPL

DSP and Memory

DCOP

IRDM ECPL

IRDMC UBEL

Interrupt/Reset only TRAx/TADH

Figure 302: TRED, Decoder

Decoder DSP

The decoder consists of a DSP and its associated SRAM. The input to the decoder consists of a serial interface. The interface carries clock, frame signals and the demodulated data from eight RF time slots. The DSP decodes and transmits eight full-rate or enhanced full-rate (or 16 half-rate) TCHs to the BSII, via the MBED. Each full-rate channel can be replaced by a GPRS channel. The ECPL interface is used mostly for booting code during resets. The interrupt/reset interface sets the boot mode, and later provides frame and time slot interrupts.

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9.1.2.7 Incremental Redundancy Data Memory The IRDM is required by the EGPRS feature to store demodulated packet data blocks for incremental redundancy function.

9.1.2.8 IRDM Controller Hardware and access control function for the IRDM. The IRDMC function is implemented in the UBEL FPGA.

9.1.2.9 Decoder Co-processor The DCOP is a slave of the DEC used to enhance signal processing functions which are more efficiently implemented in a FPGA than in a DSP. The introduction of the DCOP is linked to the EGPRS feature. The DCOP function is implemented in the UBEL FPGA.

9.1.2.10 Demodulator The demodulator demodulates the uplink channels. The functions performed are: Antenna diversity combining (TADH/TAGH/TRAD/TRADE/TADHE/TRAG/TRAGE/TAGHE/TRAL/TRAP) Radio link measurements on a burst basis Using control information provided by the decoder: Preprocessing Channel demodulation Equalization of the received signals. DC offset compensation.

Block Diagram

The following figure shows a functional block diagram of the demodulator. Modulated Input from CUL/DRCS

Demodulated Output to MBED

DSP and Memory

DSP and Memory

ECPL

Interrupt/Reset

Figure 303: TRED Demodulator

Demodulator DSPs

The demodulator consists of two DSPs, each of which has its own SRAM. The inputs to the demodulator consist of two serial interfaces. The interfaces carry clock, frame signals and the data from eight RF time slots. Each DSP demodulates eight full-rate or enhanced full-rate (or 16 half-rate) TCHs for one antenna path. It demodulates either access or normal bursts (TRDH, TRDM, TRGM, TRPM). It combines and demodulates either access or normal burst for both antenna paths (TADH/TAGH/TRAD/TRADE/TADHE/TRAG/TRAGE/TAGHE/TRAL/TRAP).

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The ECPL interface is used almost exclusively for booting code during resets. The interrupt/reset interface sets the boot mode, and later provides frame and time slot interrupts.

9.1.2.11 Multiplexer, Baseband, Encryption and Decryption The MBED functions are combined in a single FPGA. The functions performed by the MBED are: Multiplexing of baseband data Baseband encryption Baseband decryption Interfacing digital processing functions on the TCH. The following figure shows a functional block diagram of the MBED. CLKI

ECPL

Timing

Control

To Encoder

Ciphering Encoder Interface

BSII

Uplink and Downlink Multiplexer

BSII Multiplexer Decoder Interface

Frequency Hopping Link Block

Demodulator Interface

FHL

To Demodulator

To Decoder

Figure 304: TRED, Multiplexer, Baseband, Encryption and Decryption

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The following table gives a short description of each block. Control

The Control block is the main controlling function of the MBED. It contains several status and control registers that are updated via the ECPL interface.

Timing

The Timing block is connected to CLKI which carries the master clock, frame clock and frame number. The main role of the timing block is to: Provide clocks for the DSPs Retrieve the frame number and transfer it to the ECPL.

Ciphering

The Ciphering block performs pattern generation according to the configuration information, that is: A5 type Encryption/decryption key Frame number. The configuration information is sent in band from the encoder/decoder. This means that it is possible to change the A5 algorithm and key on a call-by-call basis.

BSII Multiplexer

The BSII Multiplexer selects between the BSII links for the uplink and downlink directions. The selection of the correct bits to be sent downlink, and the insertion of bits at the correct position in uplink, is done by the DSPs.

Uplink and Downlink Multiplexer

The Uplink Multiplexer handles two data flows: Data from the decoder. Additionally, the uplink cipher key is forwarded to the ciphering block TCH data from the demodulator is forwarded to the decoder. The deciphering bits coming from the ciphering block are added to this data stream. The Downlink Multiplexer splits the data stream coming from the encoder: In-band signaling from the TXP is forwarded to the demodulator, together with the ARFCN The downlink ciphering key is extracted and forwarded to the ciphering block. The ciphering bits from the ciphering block are sent back to the ENCT The FHL data stream is forwarded to the FHL Interface.

Frequency Hopping Link Block

The Frequency Hopping Link Block provides the interface to the FHL. If the FHL is configured and used, the data is sent to, and received from, the FHL. If the FHL is not configured, the downlink data is forwarded to the TXP.

Demodulator Interface

The Demodulator Interface provides clock and frame signals for the demodulator DSPs.

Decoder Interface

The Decoder Interface provides the connection to and from the decoder. It also provides clock and frame signals to the decoder DSP.

Encoder Interface

The Encoder Interface provides the connection to and from the encoder and TXP. It also provides clock and frame signals to the encoder DSP.

Table 63: TRE, MBED Functional Entities

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9.1.2.12 Encoder and Transmitter The ENCT receives the downlink TRAU frames from the BSII, performs channel encoding on them and transmits them to the TREA block. The hardware consists of a DSP and an SRAM. The functions performed by the ENCT are: On the terrestrial link side: Rate adaptation TRAU frames management Transcoder time alignment. On the radio channel side: Channel coding Speech, data and signaling interleaving. Radio frequency hopping law computation for downlink and uplink TREA control, including transmitter and receiver parts FHL interface management if baseband hopping Encryption and encryption process control. The following figure shows a functional block diagram of the ENCT. MBED BSII MUX

CUL or BBTX

Uplink/Downlink MUX

DSP Encoder

TXP

Figure 305: TRED, ENCT Functional Block

Encoder

The Encoder encodes the data for eight full-rate or enhanced full-rate (or 16 half-rate) TCHs. Each full-rate channel can be replaced by a GPRS channel. This data is received from the MBED. The encoded data, ciphering configuration and the frequency number for the RF transmission, are sent to the MBED.

TXP

The MBED sends the encoded data to the TXP for transmission on the Air Interface. It also sends the cipher bits coming from the ciphering block. The TXP processes the data and extracts all additional information coming from the Encoder or FHL. The resulting data stream is sent to the CUL or BBTX.

9.1.2.13 Carrier Unit Logic For TRDH, TRDM, TRGM, TRPM only, the CUL adapts the ENCT DSP signals to provide the various data and control lines required for the TREA. The CUL consists of an FPGA and some external drivers and registers.

9.1.2.14 Clock Generation Unit The CGU consists of two PLLs: one for the BSII clock and one for the CLKI clock. It also provides an internal clock distribution function.

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9.1.2.15 External Test Adapter For TRDH, TRDM, TRGM, TRPM only, the ETA device contains its own internal logic and drivers which enables external test equipment to be connected to the ECPL.

9.1.2.16 TRE Remote Inventory Remote Inventory is used to store information about the TRE module (part number, name, serial number, etc.). It consists of an EEPROM which is connected to the BCB ASIC. The stored information is read via the BCB.

9.1.2.17 Baseband Transmitter Module For TADH/TAGH/TRAD/TRADE/TADHE/TRAG/TRAGE/TAGHE/TRAL/TRAP only, the BBTX adapts ENCT DSP signals to provide various data and control lines required for the TREA. The BBTX consists of a mixed signal ASIC.

9.1.2.18 Diversity Receiver Chip Set For TADH/TAGH/TRAD/TRADE/TADHE/TRAG/TRAGE/TAGHE/TRAL/TRAP only: DRCS performs IF A/D conversion and digital filtering and decimation for both antenna paths.

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9.1.3 Analog Functions The TRE analog part performs the analog functions within the TRE. These functions are split between the two functional parts: TRE analog part TREA TRE power amplifier TREPAxx or TEPAxx. For GSM 1900, the TRE analog part is called TREAP. Depending on the frequency for the TRE power amplifier, there are different variants available: TEPAD for GSM 1800, medium power TEPADE for GSM 1800, medium power, enhanced 8-PSK power TEPADH for GSM 1800, high power TEPADHE for GSM 1800, high power GMSK and 8-PSK TEPAG for GSM 900, medium power TEPAGE for GSM 900, medium/high power, enhanced 8-PSK power TEPAGH for GSM 900, high power TEPAL for GSM 850, medium power TEPAP for GSM 1900, medium power TREPAGM for GSM 900, medium power TREPADM for GSM 1800, medium power TREPAPM for GSM 1900, medium power TREPADH for GSM 1800, high power.

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9.1.3.1 Analog Architecture -TRDH, TRDM, TRGM, TRPM The following figure shows a block diagram of the TRE analog part hardware architecture for the TRDH, TRDM, TRGM, and TRPM. It shows the functional blocks and the interfaces to the TRED. The shaded areas define the TREA and TEPAxx (or TREPAxx) parts. TX Synthesizer 1

IF Synthesizer

From ENCT via CUL (CUI)

TX Synthesizer 2

TX Power Regulation

I I/Q Modulator & Up−converter

Baseband Modulator

IF Filter

TX Mixer

To Combiner/ Duplexer

Q TX Driver Amplifier

Clean−up Oscillator

TX Power Amplifier

Loop Coupling

RF Loop

TREPAxx Baseband Filter

I/Q Demodulator

ADC

RX Synthesizer 1

ADC

RX Synthesizer 2

To DEM on TRED via CUL (CUI)

IF Filter

Baseband Filter

I/Q Demodulator

IF Filter

RF Mixer

LNA

RX0

From Antenna Network

RF Mixer

LNA

RX1

TREA

Figure 306: TRE Analog Part Architecture (TRDH, TRDM, TRGM, TRPM)

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9.1.3.2 Analog Architecture -TADH, TAGH, TRAD, TRAG, TRAL, TRAP The following figure shows a block diagram of the TRE analog part hardware architecture for the TADH, TAGH, TRAD, TRAG, TRAL, and TRAP. It shows the functional blocks and the interfaces to the TRED. The shaded areas define the TREA and TEPAxx (or TREPAxx) parts. IF Synthesizer

TX Synthesizer 1

TX Synthesizer 2

TX Power Regulation

I From ENCT

Modulator & Up−converter

Baseband Modulator

To combiner IF Filter

Mixer

Q

Duplexer TX Driver Amplifier

BBTX

TX Power Amplifier

Transmitter part

Clean−up Oscillator

Reveiver part

RF Loop

Loop Coupling

TEPAxx ADC

To DEM on TRED

DDC

DRCS

IF Filter

RF Mixer

LNA

RX0

RX Synth. 1

From Antenna Network

RX Synth. 2

ADC

IF Filter

RF Mixer

LNA

RX1

TREA Digital part (positioned at analog module)

Figure 307: TRE Analog Part Architecture (TADH, TAGH, TRAD, TRAG, TRAL, TRAP)

9.1.3.3 Analog Architecture - TRAGE, TAGHE, TRADE, TADHE The following figure shows a block diagram of the TRE analog part hardware architecture for the TRADE/TADHE/TRAGE/TAGHE. It shows the functional blocks and the interfaces to the TRED. The shaded area defines the digital part positioned on the analog module.

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TX Synthesizer 1

I From ENCT

Baseband Modulator

TX Synthesizer 2

TX Power Regulation

To combiner

Modulator & Up−converter

Duplexer

Q

TX Power Amplifier

TX Driver Amplifier

BBTX Transmitter part

Clean−up Oscillator

Reveiver part

TEPAxx/ TEPADHE ADC

To DEM on TRED

DDC

DRCS

IF Filter

RF Mixer

LNA

RX0

RX Synth. 1

From Antenna Network

RX Synth. 2 ADC

IF Filter

RF Mixer

LNA

RX1

TREA Digital part (positioned at analog module)

Figure 308: TRE Analog Part Architecture (TRAGE/TAGHE/TRADE/TADHE)

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9.1.3.4 TRE Analog Functional Entities The following table gives a short description of each of the TRE analog functional entities. Baseband Modulator

The baseband modulator transforms the incoming digital data stream into two baseband signals: I and Q. These baseband signals are fed to the up-converter. The modulation is GSMK modulation or EDGE*. * for TADH/TAGH/TRAD/TRADE/TADHE/TRAG/TRAGE/TAGHE/TRAL/TRAP

I/Q Modulator and Up-converter

The I/Q baseband signals are fed to the up-converter. Then they are transformed into the IF frequency band (211 MHz). For TRAGE/TAGHE/TRADE/TADHE the I/Q baseband signals are directly transformed into the RF frequency band.

Transmitter Amplifiers

The TX amplification stages are physically split between the TREA and TEPAxx (or TREPAxx) sections (see Figure 306, Figure307 or Figure 308). The stages comprise the following three components: TX Driver Amplifier The TX Driver Amplifier stage is located on the TREA. It consists of a preamplifier, power control circuitry, and a main amplifier. An isolator provides output impedance matching and protection for a low voltage FET on the output Power Regulation The Power Regulation stage is located on the TREA. It consists of a control path and a multiplexing detection path. An EEPROM is used to store data for calibrating the transmitter output power. The control path consists of a 12-bit DAC. The detection path consists of a 12-bit ADC and a low-pass filter. (For TADH/TAGH/TRAD/TRADE/TADHE/TRAG/TRAGE/TAGHE/TRAL/TRAP it is implemented on the BBTX). TX Power Amplifier. The TX Power Amplifier is located on the TEPAxx (or TREPAxx) part of the module. It provides the final amplification stage for the transmit RF signal, from the TREA. It feeds the amplified RF signal to the AN module, as required.

Clean-up Oscillator

The Clean-up Oscillator provides spectrally pure reference clocks required for synchronization of the transmitters, receivers and synthesizers.

Transmitter Hopping Synthesizers

The Transmitter Hopping Synthesizers generate the RF frequencies for the transmitter. There are two hopping synthesizers working in parallel. While one synthesizer is active, the other selects the next transmission frequency.

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Receivers

Two receivers are physically located on the TREA. The main functions of the receivers for TRGM, TRDM, TRDH, TRPM are: Low noise amplification Down conversion IF filtering IQ demodulation Baseband filtering Baseband digitizing. The main functions of the receivers for TADH, TAGH, TRAD, TRADE, TADHE, TRAG, TRAGE, TAGHE, TRAL, TRAP are: Low noise amplification Down conversion IF filtering IF sampling Digital I/Q demodulation Digital Baseband filtering Digital Decimation.

Receiver Synthesizers

The Receiver Hopping Synthesizers generate the RF frequencies for the receiver. There are two hopping synthesizers working in parallel. While one synthesizer is active, the other selects the next receive frequency.

RF Loop

The RF Loop provides an analog test loop between the transmitter and receivers. It performs analog self-tests, mainly for start-up test purposes. The RF Loop circuitry generates a frequency of 45 MHz (GSM 850/GSM 900), 95 MHz (GSM 1800), or 80 MHz (GSM 1900) and converts the transmitter output signals to the receiver frequency. The RF Loop functionality is physically split between the: TREA, which contains the RF loop itself TEPAxx (or TREPAxx), which contains the RF loop coupling function (see Figure 306 and Figure 307). The RF Loop is removed in case of TRAGE/TAGHE/TRADE/TADHE (see Figure 308).

Table 64: TRE Analog Part Functional Entities

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9.1.4 TRE Power Supply The TREP, TREPS, TREPSH are on-board power supplies, providing all the necessary voltages and currents for the TRE analog and digital functions. In the case of medium-power TREs, the power supply consists of one DC/DC converter. For high-power TREs, the power supply contains an additional DC/DC converter which provides a + 26 V supply for the high-power analog circuits.

9.1.4.1 Voltages For normal operational requirements, the DC input voltage V in can be any value between -38.4 VDC and -72 VDC. If the input is too low, the power supply switches off automatically. When the input voltage is restored, the power supply switches back on. If the input voltage falls below -38.4 VDC, the output is maintained within the specified values, until the TRE power supply switches off. The following table provides the TRE power supply output voltage parameters. Output Voltage

Tolerance

Min. Value

Max. Value

TRE Version (1)

TRE Version (2)

TRE Version (3)

+ 3.3 V

±3 %

3.2 V

3.4 V

X

X

X

+ 5.1 V

±3 %

4.95 V

5.25 V

X

-

-5.1 V

±3 %

-4.95 V

-5.25 V

-

X

+ 5.3 V

±3 %

5.14 V

5.46 V

-

X

+ 12 V

±3 %

11.64 V

12.36 V

X

-

-12 V

±5 %

-11.4 V

-12.6 V

X

-

+ 26 V

±2 %

25.48 V

26.52 V

X

X

X

X

(1): TRDH, TRDM, TRGM, TRPM (2): TADH, TAGH, TRAD, TRAG, TRAL, TRAP (3): TRAGE, TAGHE, TRADE, TADHE Table 65: Output Voltage Parameters

9.1.4.2 Fuse The TRE power supply input is protected by a fuse with a high-breaking capacity (15 A).

9.1.4.3 ON/OFF Switch The TRE module is equipped with an on/off power switch. It is a rocker type switch, fitted slightly below the front panel’s profile to prevent accidental switching.

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9.1.4.4 Remote Switching The TREPS can be remotely switched on and off by the OMU, via the BCB. This feature is implemented on the module with an optically isolated on/off switch.

9.1.4.5 Low Voltage Alarms If an output voltage falls below a preset threshold value, an alarm is raised. The following table gives the minimum and maximum threshold values. The values are measured across the output connector pins. Output Voltage

Threshold Min.

Threshold Max.

TRE Version (1)

TRE Version (2)

TRE Version (3)

+ 3.3 V

2.7 V

3.0 V

X

X

X

+ 5.1 V

4.2 V

4.6 V

X

-

-5.1 V

-4.2 V

-4.6 V

-

X

+ 5.3 V

4.4 V

4.8 V

-

X

+ 12 V

10.0 V

11.0 V

X

-

-12 V

-10.0 V

-11.0 V

X

-

+ 26 V

22.0 V

24.0 V

X

X

X

X

(1): TRDH, TRDM, TRGM, TRPM (2): TADH, TAGH, TRAD, TRAG, TRAL, TRAP (3): TRAGE, TAGHE, TRADE, TADHE Table 66: Low Voltage Alarm Thresholds

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9.1.5 Transceiver Equipment LEDs There are eight LEDs (TRDH, TRDM, TRGM, TRPM) or six LEDs (TADH, TAGH, TRAD, TRADE, TADHE, TRAG, TRAGE, TAGHE, TRAL, TRAP) on the front panel, which provide a visual indication of the operational status of the TRE module (see Figures 309 and 310). The following table describes each LED their various operational states.

LED

Color

RSL

Yellow

TX

OP

BCCH

FAULT

Description

TRE Version (1)

TRE Version (2)

RSL connection status

X

X

On

Link connected

-

-

Blinking

Connecting link

-

-

Off

Link disconnected

-

-

Transmission status (not BCCH)

X

X

On

Transmitting on SDCCH, CBCH or TCH

-

-

Blinking

Emitting (normal operation)

-

-

Off

Not transmitting

-

-

TRE operational status

X

X

On

Fully operational

-

-

Blinking

Initializing

-

-

Off

Not operational

-

-

BCCH transmission status

X

X

On

Transmitting

-

-

Off

Not transmitting

-

-

Alarm status

X

X

Status

Yellow

Yellow

Yellow

Red

(1): two LEDs connected in parallel (2): one LED On

Fatal alarm

-

-

Blinking

Non-fatal alarm

-

-

Off

No alarm

-

-

Status of the + 5 V power supply

X

+ 5 V present

-

5 V POWER Green On

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LED

3.3 V POWER

PWR

Color

Status

Description

TRE Version (1)

TRE Version (2)

Off

+ 5 V faulty

-

-

Status of the + 3.3 V power supply

X

-

On

+ 3.3 V present

-

-

Off

+ 3.3 V faulty

-

-

Status of the TRE power supply output voltages

-

X

On

Output voltages present

-

-

Off

Output voltages faulty

-

-

Green

Green

(1): TRDH, TRDM, TRGM, TRPM (2): TADH, TAGH, TRAD, TRADE, TADHE, TRAG, TRAGE, TAGHE, TRAL, TRAP Table 67: TRE LED Descriptions

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9.1.6 Transceiver Equipment Front Panel The following figures show the TRE front panels.

9.1.6.1 Front Panel - TRDH, TRDM, TRGM, and TRPM Camloc Fasteners

Equipment Label

Transmitter Connector POWER ENABLE

On/Off Rocker Switch

TX

OFF

Test Connector

Module Extractor

TEST

RX 0

Receiver Connectors

RX 1

LEDs

RSL

TX

OP

BCCH FAULT

5V

3.3V POWER

Figure 309: TRE Front Panel (TRDH, TRDM, TRGM, TRPM)

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9.1.6.2 Front Panel - TADH, TAGH, TRAD, TRADE, TADHE, TRAG, TRAGE, TAGHE, TRAL, and TRAP Camloc Fasteners

Transmitter Connector TX

POWER ENABLE On/Off Rocker Switch

OFF

TEST

USB Test Connector

Equipment Labels

Module Extractor

RX0 Receiver Connectors

LEDs

RX1

RSL

TX

0P

BCCH

PWR

FAULT

Figure 310: TRE Front Panel (TADH, TAGH, TRAD, TRADE, TADHE, TRAG, TRAGE, TAGHE, TRAL, TRAP)

9.1.6.3 Connectors The following table describes the TRE front panel connectors.

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Connector

Description

Test

Provides an interface to the TRE for factory test purposes.

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Connector

Description

TX

Provides the transmit RF Interface to the AN module.

RX 0, RX 1

Provides two receive RF Interfaces from the AN module.

Table 68: TRE Front Panel Connectors

9.2 TWIN Transceiver Equipment 9.2.1 Introduction to TWIN TRA The TWIN TRA combines digital baseband and analog RF functions in one module. The architecture is split into three functional blocks: Digital part TRA-D Analog part TRA-A with two power amplifiers TGPA Power supply TGPS. The TRA-D and TRA-A are implemented in one submodule TGDA. The TWIN TRA basic architecture is shown in the following figure. TGTx TGDAx TGPAMx

to AGCx from

TRA−D

TRA−A TGPAMx

to AGCx from

TGPS

Figure 311: TWIN TRA Basic Architecture The TWIN TRA performs the digital functions interface to the SUM and the analog functions interface to the AN module. The TWIN TRA contains its own integrated power supply. The following types of TWIN TRA modules are available for the different BTS A9100 variants: TGT09, TWIN TRA medium power module for GSM 900 TGT18, TWIN TRA medium power module for GSM 1800

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9.2.2 Digital Functions 9.2.2.1 TRA-D Architecture RX Synth. Modulator/ Filter / Buffer for GSM, EDGE, enh. EDGE TX Synth.

FLASH

SDRAM

Level & Bias TX DAC Ramping CPLD

SDRAM Ramp DAC

SCP

SYS

TX Synth. Module

TXP ENC

ECPL

HPI

BIAS DAC

RX Synth. Module

DSP1

DRC1 DEM CLKI BSII

DRC2

HFFI FHL

To/from LALE

IQ MUX Monitoring

FPGA SYS

ADC DEM HPI DSP2

DEM ctrl.

DSA

DEC FPGA

SDRAM

Figure 312: TRA-D Architecture The TRA-D consists of the following functional entities: Signalling and Control Processor (SCP) Digital Signal Processor 1 (DSP1) Digital Signal Processor 2 (DSP2) Field Programable GateArray (FPGA) Flash Memory SDRAM Glue Logic (CPLD) Diversity Receiver Chip (DRC).

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9.2.2.2 TRA-D System Interfaces Interface

Description

BCB

Base station control bus: used for Remote Inventory (RI) read write and for controlling and supervision of the power supply.

ADR

Module address: provides a unique address to each module in the BTS. Used to set BCB physical BCB terminal address and BSII HDLC address.

RCD

Remote cabling detection: detects DC voltage variations on the TRA-A receiver inputs.

BSII

Base station internal interface: transfers all TCH-related data (traffic and signaling) and internal O&M data.

FHL

Frequency hopping link: used for downlink baseband frequency hopping.

HFFI

Hook for future interface, is a spare interface and can be used for future extensions.

CLKI

Clock interface: used to distribute the Evolium BTS A9100 master clock and the frame clock multiplexed on the same line with the frame number in a serial format.

TDTI

Proprietary interface used as debug and test interface.

MMI

Debug interface: for TGTx (development and validation only).

RPI

Remote power interface: consists of: Power lines for TGD-A DC supply TGPS ON/OFF control of the power supply Alarm handling for the TGPS DC input and DC output signals.

LEDs

Front panel LED control.

PSwitch/ Reset

Manual front panel power switch: disables the TGPS for TRA maintenance (security function for actions on RF cables). Also used to generate the push button reset (PB_SRST) with fast OFF/ON sequence.

Table 69: TRED Interface Descriptions

9.2.2.3 Signalling and Control Processor The SCP is responsible for the basic initialisation including the boot of the DSPs and signalling processing. It communicates with the O&M and performs the needed actions.

9.2.2.4 Digital Signal Processor 1 The DSP1 performs the telecom Layer 1 functions of the TXP, ENC and DEM.

9.2.2.5 Digital Signal Processor 2 The DSP1 performs the telecom Layer 1 functions of the DEC and DEM.

9.2.2.6 Field Programable Gate Array The FPGA integrates the following functions:

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TX Data Module Buffer, modulator tables, filter, gain and offset adjust. Ramping Module Ramping control interface to ramping DAC. Level and BIAS Module BIAC control interface to BIAS DAC. Power Switch Module Switches power supply with exact timing. TX Synthesizer Module Interface to TX synthesizers. RX Synthesizer Module Interface to RX synthesizers. GTA Module Interface to GTA’s. Monitoring Module Receives monitoring data. Perform demultiplexing and storing of the monitoring data in corresponding registers.

9.2.2.7 Flash Memory Flash Memory is used to store the TWIN TRA origin software and the software packages.

9.2.2.8 SDRAM SDRAM dedicated working memory for SCP and DSP.

9.2.2.9 CPLD Contains the necessary glue logic for the SCP.

9.2.2.10 DRC Diversity Receiver Chip integrates the interface between the digital and analog baseband part in receive direction.

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9.2.3 Analog Functions 9.2.3.1 TGTx Analog Architecture TX Synthesizer 1

TX Power Regulation

I From ENCT

To combiner

Modulator & Up−converter

Baseband Modulator

TX1 Duplexer

Q TX Power Amplifier

TX Driver Amplifier

TGPAM1 TX Synthesizer 2

TX Power Regulation

I From ENCT

To combiner

Modulator & Up−converter

Baseband Modulator

TX2 Duplexer

Q

TX Power Amplifier

TX Driver Amplifier Transmitter part Reveiver part

TGPAM2

X

DRC

90 ADC

To DEM on TRED

IF Filter

MUX

X X

DDC

RF Mixer

LNA

RX1_0

RX Synth. 1

From Antenna Network

90 ADC

IF Filter

MUX

X X

DRC

RF Mixer

LNA

RX1_1

RF Mixer

LNA

RX2_0

Clean−up Oscillator

90 ADC

To DEM on TRED

IF Filter

MUX

X DDC

X

RX Synth. 2

From Antenna Network

90 ADC

IF Filter

MUX

RF Mixer

LNA

RX2_1

X Figure 313: TGTx Analog Architecture

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9.2.3.2 TGTx Analog Functional Entities The following table gives a short description of each of the TWIN TRA analog functional entities. Baseband Modulator

The baseband modulator transforms the incoming digital data stream into two baseband signals: I and Q. These baseband signals are fed to the up-converter. The modulation is GSMK modulation or EDGE.

I/Q Modulator and Up-converter

The I/Q baseband signals are fed to the up-converter. Then they are transformed into the RF frequency band.

Transmitter Amplifiers

The TX amplification stages are physically split between the TGDAx and TGPAMx sections (see Figure 313). The stages comprise the following three components: TX Driver Amplifier The TX Driver Amplifier stage is located on the TGDAx. It consists of a preamplifier, power control circuitry, and a main amplifier. Power Regulation The Power Regulation stage is located on the TGDAx. It consists of a control path and a multiplexing detection path. An Flash is used to store data for calibrating the transmitter output power. TX Power Amplifier. The TX Power Amplifier is located on the TGPAMx part of the module. It provides the final amplification stage for the transmit RF signal, from the TGDAx. It feeds the amplified RF signal to the AN module, as required.

Clean-up Oscillator

The Clean-up Oscillator provides spectrally pure reference clocks required for synchronization of the transmitters, receivers and synthesizers.

Transmitter Fast Hopping Synthesizers

The Transmitter Fast Hopping Synthesizers generate the RF frequencies for the transmitter.

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Receivers

The main functions of the receivers are: Low noise amplification Down conversion IF filtering BB sampling Digital I/Q demodulation Digital Baseband filtering Digital Decimation.

Receiver Synthesizers

The Receiver Fast Hopping Synthesizers generate the RF frequencies for the receiver.

Table 70: TWIN TRA Analog Part Functional Entities

9.2.4 TWIN TRA Power Supply The TGPS is an on-board power supply, providing all the necessary voltages and currents for the TWIN TRA analog and digital functions.

9.2.4.1 Voltages For normal operational requirements, the DC input voltage V in can be any value between -38.4 VDC and -72 VDC. If the input is too low, the power supply switches OFF automatically. When the input voltage is restored, the power supply switches back ON. If the input voltage falls below -38.4 VDC, the output is maintained within the specified values, until the TRA power supply switches off. The following table provides the TRA power supply output voltage parameters. Output Voltage

Tolerance

Min. Value

Max. Value

+ 1.2 V

±3 %

+ 1.164 V

+ 1.236 V

+ 3.3 V

±3 %

+ 3.2 V

+ 3.4 V

+ 5.3 V

±3 %

+ 5.14 V

+ 5.46 V

+ 6.5 V

±2 %

+ 6.37 V

+ 6.63 V

+ 24 V

±2 %

+ 23.52 V

+ 24.48 V

+.30 V

±2 %

+ 29.4 V

+ 30.6 V

Table 71: Output Voltage Parameters

9.2.4.2 Fuse The TWIN TRA power supply input is protected by a fuse with a high-breaking capacity (25 A).

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9.2.4.3 ON/OFF Switch The TWIN TRA module is equipped with an ON/OFF power switch. It is a rocker type switch, fitted slightly below the front panel’s profile to prevent accidental switching.

9.2.4.4 Remote Switching The TGPS can be remotely switched ON and OFF by the OMU, via the BCB. This feature is implemented on the module with an optically isolated ON/OFF switch.

9.2.4.5 Low Voltage Alarms If an output voltage falls below a preset threshold value, an alarm is raised. The following table gives the minimum and maximum threshold values. The values are measured across the output connector pins. Output Voltage

Treshold Min.

Treshold Max.

+ 1.2 V

+ 0.984 V

+ 1.116 V

+ 3.3 V

+ 2.7 V

+ 3.0 V

+ 5.3 V

+ 4.4 V

+ 4.8 V

+ 6.5 V

+ 5.3 V

+ 6.0 V

+ 24 V

+ 20.4 V

+ 22.3 V

+30 V

+ 25.5 V

+ 27.9 V

Table 72: Low Voltage Alarm Thresholds

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9.2.5 Transceiver Equipments Front Panel The following figures show the TWIN TRA front panel. Camloc Fasteners

Transmitter Connector TX1

RX10 RX11

ENABLE ON/OFF Rocker Switch

POWER OFF

LEDs

TX1

TX2

BCH1

BCH2

OP1

OP2

PWR

FAULT

Equipment Labels

Module Extractor USB Test Connector

TEST

Transmitter Connector TX2

Receiver Connectors

RX20 RX21

Figure 314: TWIN TRA Front Panel

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9.2.6 Transceiver Equipments LEDs There are 8 LEDs on the front panel, which provide a visual indication of the operational status of the TWIN TRA module (see Figure 314). The green “Power” and the red “FAULT” LED are common for both TRX. For the yellow LEDs, each column represents one TRX. The following table describes the LEDs and their various operational states. LED

Color

TX1, TX2

Yellow

OP1, OP2

Status

Transmission status (not BCCH) ON

At least one dedicated channel is activated on the TRX (x) (CS-traffic onTCH or signalling on SDCCH)

Blinking

No dedicated channel (TCH/SDCCH) is activated on the TRX (x), but the TRX (x) may be emitting Dummy Bursts or GPRS-bursts

OFF

The TRX (x) is not emitting RF for TCH

Yellow

TRE operational status ON

The TRX (x) is fully operational with telecom parameters

Blinking

The TRX (x) has received the Configure Request, configuration is ongoing

Normal Blinking Fast OFF BCH1, BCH2

PWR

FAULT

Description

Yellow

The TRX (x) is O&M operational with RSL established, waiting for Telecom-configuration Not operational BCCH transmission status

ON

The TRX (x) is configured as BCCH-TRX and emitting the BCCH

OFF

The TRX (x) is configured as TCH-TRX

Green

Status of the TRE power supply output voltages ON

The module is powered ON

OFF

The module is powered OFF

Red

Alarm status ON

The TRA has entered the ‘Out-of-order’ state

Blinking

At least one non-fatal alarm is active

OFF

All alarms are ‘OFF’, the ‘Alarms-in-force-lists’ (AIFL) of both TRX are empty

Table 73: TWIN TRA LED Descriptions

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9.2.7 Transceiver Equipments Connectors The following table describes the TWIN TRA front panel connectors. Connector

Description

Test

Provides an interface to the TRE for factory test purposes.

TX1, TX2

Provide two transmit RF Interface to the AN module.

RX10, RX20

Provide two receive RF Interfaces from the AN module via the normal path.

RX11, RX21

Provide two receive RF Interfaces from the AN module via the antenna diversity path.

Table 74: TWIN TRA Front Panel Connectors

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10 Antenna Networks The sections are supported with diagrams where necessary, showing the functional blocks and their interfaces. Drawings of the physical appearance of the modules are also included, showing LED indicators, connectors and controls.

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10.1 ANX The ANX provides the intermediate RF stage between the TREs and the antenna. The following figure shows the basic architecture. TXA

ANT A

Duplexer

RX0A RX1A

Splitter

RX1B RX0B

Splitter

Duplexer

TXB

ANT B

Figure 315: ANX Basic Architecture On the downlink, the ANX connects two TRE transmitters to two antennas. On the uplink, it splits the received signals and passes them to the TRE receivers. The following types of ANX modules are available for the different BTS A9100 variants: ANXG, ANX module for GSM 900 ANXD, ANX module for GSM 1800 ANXP, ANX module for GSM 1900. The following figure shows the ANX in more detail. The shaded areas identify the uplink functions. Directional Coupler

TXA In Uplink Functions TRE

Duplexer

RX0A Out

ANT A

LNA Filter RX1A Out Power Splitter A

BSII

AN Microprocessor

LEDs Gain Control

VSWR Receiver

BCB Interface

Rotary Switch

BCB

Remote Switching Power Splitter B

DC/DC Converter

DC Feed

−48 VDC

RX1B Out LNA TRE

RX0B Out

Duplexer

ANT B

Uplink Functions TXB In

Directional Coupler

Figure 316: ANX Architecture The duplexers provide coupling of the transmitted and received signals, allowing a single antenna to be used for both downlink and uplink channels. The ANX also allows the return loss of the transmitted signals to be measured, at the antenna connector, using VSWR techniques.

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The uplink channel comprises amplifiers, with remotely-adjustable gain control, remote DC feed and power splitters.

10.1.1 AN Downlink Functions The downlink functions are performed by the components shown in the following table. No. of Components Downlink Component

Description

ANX

ANC

ANB

AGC

Combiner

The combiner is used to connect two TX inputs to the single antenna. Connection between the combiner output TX..OUT and the input to the duplexer TX..IN is made by a link on the front panel of the AN.

-

2

-

2

Duplexer

The duplexer provides the coupling function for the transmitted and received RF signals. The duplexer provides a bi-directional signal path. Thus a single antenna can be used for the transmission and reception of both downlink and uplink channels.

2

2

2

2

The downlink path functions of the duplexer are provided by a transmit filter, which: Provides a transmitter path to the antenna Suppresses unwanted emissions outside the downlink band, especially emissions that fall into the uplink band Prevents downlink signals from blocking the receiver Prevents noise or spurious emissions in the downlink signal from causing interference in the receive band. Directional Coupler

The antenna directional coupler comprises a dual directional coupler. It monitors the VSWR forward and reflected power at the antenna connector. These values are used to measure the return loss of the antenna (refer also to Antenna Network Controller (Section 10.1.4) for a description of the VSWR receiver).

2

2

2

2

Bias T

The interface provides the DC supply for the optional Tower Mounte Amplifier

-

-

-

2

Table 75: ANX/ANC/AGC/ANB, Downlink Components

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10.1.2 AN Uplink Functions The uplink functions are performed by the components shown in the following table. No. of Components Uplink Component Duplexer

Description

ANX

ANC

ANB

AGC

The duplexer provides the coupling function for the transmitted and received RF signals. The duplexer provides a bi-directional signal path. Thus a single antenna can be used for the transmission and reception of both downlink and uplink channels. The uplink path functions of the duplexer are provided by a receive filter, which:

2

2

2

2

2

2

2

2

Provides an RF path from the antenna to the receiver Suppresses unwanted signals outside the uplink band Prevents downlink signals from entering the receiver. LNA

The LNA amplifies the received RF signals. The LNA consists of a balanced amplifier configuration, designed to provide good VSWR values, noise compression and good reliability. The LNA contains a digital step-attenuator for controlling the overall gain of the antenna network. The attenuator compensates for any losses in the connecting cables, for example, when an ANY module is used.

Remote DC Feed

The remote DC feed is used for feeding a + 5 V TTL signal to the receiver output ports. This is used to provide an indication of the status of the antenna cable connections.

1

1

1

1

Power Splitter

A power splitter distributes the received signals to two separate outputs. It also supports the correct grouping of the connectors, which simplifies the external cable interconnections for the BTS A9100 modules.

2

2

2

2

Table 76: ANX/ANC/AGC/ANB, Uplink Components

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10.1.3 BTS Control Bus Interface The BCB Interface is located on the backplane. It interfaces the data and control signals to the BCB as listed in the following table. Signal

Description

RI

The Remote Inventory stores data such as the RIT name, module type, frequency band, diversity and duplexer type.

Power Supply Control

The BCB Interface supports remote on/off switching of the DC/DC converters. They are switched with an optically-isolated switch on the power supply.

DC Line Supervision

The BCB Interface delivers a TTL level signal which is used by the remote DC feed. A circuit in the TRE detects the signal and feeds back a status message to the BCB (refer to AN Uplink Functions (Section 10.1.2) for information about the remote DC feed).

Rotary Switch

The BCB Interface is connected to a rotary switch on the ANX front panel. The switch position is associated with the antenna sector, in sectorized configurations. The switch position is read via coded address lines.

Table 77: ANX/ANC/AGC/ANB, BCB Interface

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10.1.4 Antenna Network Controller The ANCON is responsible for maintaining the operation of the ANX. Its principal functions are: Setting the LNA gain for the assigned TREA receiver Supervising LNA alarms Measuring antenna VSWR Reporting VSWR alarms Selecting the antenna sector Detecting RF cabling status RI, via the BCB Interface Remote power on/off, via the BCB Interface Status display, via front panel LEDs. The following figure shows the ANCON architecture. The shaded areas represent hardware shared by different functions. Flash EEPROM

SRAM

Control Signals

Backplane VSWR Receiver TXA

Forward Mixer

Reverse TXB

Glue Logic Baseband ADC

BSII Interface

Forward Reverse Input MUX

BSII PLL

AN Microprocessor

Local Synthesizer

Subrack Address

LNA 1 LNA Control Signals & Alarms

2048 MHz

LNA 2 CLKII PLL

CLKI Interface

DC Feed & Rotary Switch RI Alarms To LNAs

DC/DC Converter

On/Off

BCB ASIC

BCB Interface

RI EEPROM DC Input

−48 VDC

Figure 317: ANCON Architecture The ANCON functional entities are described in the sections below.

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10.1.4.1 VSWR Receiver The VSWR receiver is a selective VSWR meter which measures the forward and reflected (reverse) power of the transmitters. The VSWR is measured at the output of the duplexer couplers, and fed to an RF MUX in the receiver (see Figure 317). The VSWR receiver consists of: Local synthesizer Input MUX. A local synthesizer generates a signal which is used to compare the baseband frequency with the ARFCN. The local synthesizer is set to the ARFCN frequency by the AN microprocessor. The input MUX provides the RF inputs to the VSWR receiver. It provides a selective input of the forward and reverse power from transmitters A and B. The input MUX operates under the control of the AN microprocessor.

10.1.4.2 BSII Frame Clock PLL The BSII frame clock PLL recovers the BSII frame clock from the backplane. The clock outputs are used for BSII communications, the AN microprocessor and the PLL lock-detect signal. BSII Frame CLK

PLL Switch

BSII Comms

Loop Filter VCXO

Glue Logic

Clock Edge Control Signal

Microprocessor

BSII PLL Lock Detect

Figure 318: ANCON, BSII Frame Clock PLL

10.1.4.3 CLKII Clock PLL The CLKII clock PLL recovers the BSII master clock from the backplane. The clock outputs are used for the local synthesizer reference clock, the ’start conversion’ signal for the baseband ADC and the CLKII lock-detect signal. BSII Master CLK

PLL Switch

Local Synthesizer

Loop Filter VCXO

Clock Edge Control Signal

Glue Logic

Start Conversion

CLKII Lock Detect

Figure 319: ANCON, CLKII Clock PLL

10.1.4.4 AN Microprocessor The AN microprocessor performs LNA alarm supervision and gain setting, and control of the status LEDs. It also provides an interface to the baseband ADC in the VSWR receiver (see Figure 317). The microprocessor compares the ADC output with known VSWR values. If the VSWR exceeds predefined thresholds, an alarm is raised (refer to Table ANX LED Descriptions (80)). If the reflected power is very high, the transmitters are shut down to avoid possible damage to equipment. High reflected power can be caused by, for example, a break in the antenna coupling. The AN microprocessor hardware consists of a QUICC microprocessor supported by two memory devices, a Flash EEPROM and an SRAM.

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10.1.4.5 Glue Logic Glue logic consists of a number of registers, implemented on a single CPLD device. It also converts 5 V TTL signals to 3.3 V, required by the Power QUICC microprocessor. The Glue logic maintains the following interfaces and/or functions: AN microprocessor to the BSII Board/module address register Baseband ADC LNA error register LNA gain adjustment register. The Glue logic also controls the BSII frame clock PLL and the CLKII master clock PLL with a clock edge control signal (see Figure 318 and Figure 319).

10.1.4.6 Remote Inventory Remote Inventory is used to store information about the ANX module (part number, name, serial number, etc.). It consists of an EEPROM which is connected to the BCB ASIC. The stored information is read via the BCB Interface.

10.1.5 AN Power Supply The ANPS is a DC/DC converter, providing all the necessary voltages for the ANX/ANC components.

10.1.5.1 Voltages The following table provides ANPS input/output voltage parameters. Voltage

Value

V in

-38.4 VDC min. -72 VDC max. -48 VDC to -60 VDC nom.

V out

+ 5.1 VDC ±3 % + 12 VDC ±3 %

Table 78: ANPS Input/Output Voltage Parameters Normal operation of V out is unaffected by temperature fluctuations in the range -10o C to 70o C.

10.1.5.2 Fuse The input of the ANPS is protected by a fuse with a high-breaking capacity (15 A).

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10.1.5.3 Protection The ANPS circuitry is protected against short circuit and accidental polarity inversion on its inputs.

10.1.5.4 Grounding Ground continuity for the module is achieved with ground pins on the subrack backplane which connect to the bus bar ground.

10.1.5.5 Remote Switching The ANPS can be remotely switched on and off by the OMU, via the BCB. This feature is implemented on the module with an optically isolated on/off switch.

10.1.5.6 Low Voltage Alarms Alarms are raised if the voltage level is too low. The following table provides the low voltage threshold tolerances for ANPS alarms. Voltage

Threshold Min.

Threshold Max.

Vin

30.4 V

38.4 V

5.1 V

4.2 V

4.6 V

12 V

10.0 V

11.0 V

Table 79: ANPS Alarm Thresholds

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10.1.6 ANX LEDs and Alarms This section provides information on the ANX’s LEDs and Alarms.

10.1.6.1 LEDs There are eight LEDs on the front panel, which provide a visual indication of the operational status of the ANX module. The following table describes each LED and their various operational states. LED

Color

VSWR A

Yellow

VSWR B

O and M

ALARM

5V

12 V

Status

VSWR status of Antenna 1. On

Good VSWR.

Slow Blinking

Threshold 1 reached.

Fast Blinking

Threshold 2 reached.

Off

VSWR not supervised.

Yellow

Yellow

Red

Green

Green

Description

VSWR status of Antenna 2. On

Good VSWR.

Slow Blinking

Threshold 1 reached.

Fast Blinking

Threshold 2 reached.

Off

VSWR not supervised.

-

O and M status.

On

IOM link operational.

Off

IOM link not established.

-

Alarm status (both LEDs are connected in parallel)

On

IOM link operational

Blinking

Non-urgent alarm.

Off

IOM link not established.

-

Status of + 5 V power supply.

On

+ 5 V present.

Off

+ 5 V faulty.

-

Status of + 12 V power supply.

On

+ 12 V present.

Off

+ 12 V faulty.

Table 80: ANX LED Descriptions

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10.1.6.2 Alarms The ANX detects the alarm conditions shown in the following table. VSWR

The AN microprocessor can raise four alarms when VSWR values exceed certain preset thresholds. The values are downloaded from the OMU software. There is a non-urgent and an urgent alarm for each antenna.

Amplifier

There are two amplifier alarms for each LNA. One indicates degraded amplifier performance, and the other a total failure. A total failure is regarded as performance that is below a usable output.

DC line supervision

The remote + 5 V TTL DC feed signal is used for supervision of the RF cabling continuity. A circuit in the TREA receiver detects the signal and a message is fed back, via the BCB.

Table 81: ANX/ANC/AGC/ANB Alarm Conditions

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10.1.7 ANX Performance Characteristics The performance characteristics of the ANXs/ANCs are shown in the following table. Parameter

GSM 900

GSM 1800

GSM 1900

Transmit band.

925 - 960 MHz

1805 - 1880 MHz

1930 - 1990 MHz

Receive band.

880 - 915 MHz

1710 - 1785 MHz

1850 - 1910 MHz

Power for each transmitter channel input.

45 W maximum

63 W maximum

45 W maximum

Number of channels.

174

374

299

Bandwidth for each channel.

200 kHz

200 kHz

200 kHz

Return loss at receive port.

> 18 dB

> 18 dB

> 18 dB

Return loss at transmit port.

> 18 dB

> 18 dB

> 18 dB

Return loss at antenna port.

> 18 dB

> 18 dB

> 18 dB

Return loss at coupler port.

> 18 dB

≥ 18 dB

≥ 18 dB

Group delay distortion in transmit band.

≤100 ns

≤ 100 ns

≤ 100 ns

Isolation between receive port and antenna port.

>30 dB

>30 dB

> 30 dB

Isolation between receive ports.

22 dB

22 dB

> 22 dB

Isolation between transmit ports (A to B/ 1 to 2).

>50 dB/ 22 dB

>50 dB/ 22 dB

>50 dB/ 22 dB

Insertion loss in transmit pass band.

0.3 - 1.6 dB

< 0.3 - 1.6 dB

< 0.3 - 1.6 dB

Intermodulation products at antenna port with 2x 20 W signals at one transmit port and 50 on receive port in receive band.

<-103 dBm

<-103 dBm

<-103 dBm

Intermodulation products at antenna port with 2x 20 W signals at one transmit port and 50 on receive port in transmit band.

<-75 dBc

<-75 dBc

<-75 dBc

RF input impedance.

50

50

50

RF output impedance.

50

50

50

1)

1) For ANX with bridge: >16 dB. Table 82: ANX Performance Characteristics

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10.1.8 ANX Front Panel The following figure shows the layout and O and M features of the ANX’s front panel. Camloc Fasteners Module Extractors

RX0AOUT Transmitter Connectors RX1AOUT TXAIN

Antenna Connectors

ANTA ANTB Equipment Label

TXBIN RX1BOUT Receiver Connectors RX0BOUT Rotary Switch

VSWRA LEDs

O&M

VSWRB

ALARM

ALARM

5V

12V

Figure 320: ANX Front Panel

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The ANX has two transmitter input connectors and four receiver output connectors on its front panel. Therefore, one ANX module can be interfaced to two TRE modules, or an ANY module if used. The following table describes the ANX front panel connectors. Connector

Description

TXAIN

Provides the RF transmitter interfaces from two TRE modules, or an ANY module if used.

TXBIN RX0AOUT RX1AOUT RX0BOUT RX1BOUT

ANTA ANTB

Provides the RF receiver interfaces between antenna A and the first TRE receiver connectors RX0 and RX1, or an ANY module if used. Provides the RF receiver interfaces between antenna B and the second TRE receiver connectors RX0 and RX1, or an ANY module if used. Provides the RF interface to/ from two antennas, A and B.

Table 83: ANX Front Panel Connectors

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10.2 ANY The ANY is a passive RF module, having neither a controller nor a power supply. It is an optional RF distribution device, which is used to expand the capacity of the ANX/ANC. Therefore, it is basically an extension unit to the ANX/ANC module. The following types of ANY modules are available for the different BTS A9100 variants: ANYD, ANY module for GSM 1800 ANYDH, ANY module for GSM 1800 high power ANYG, ANY module for GSM 900 ANYGH, ANY module for GSM 900 high power ANYL, ANY module for GSM 850 ANYP, ANY module for GSM 1900. GSM 850 is not supported by all BSS software releases. If you are in doubt, contact Alcatel support. The following figure shows the logical position of the ANY in relation to the TREs and the ANX. The signal paths are also indicated. TRE Antenna

TRE ANY

ANX/ ANC

TRE TRE

Downlink Path TRE Antenna

TRE ANY

ANX/ ANC

TRE

TRE Uplink Path

Figure 321: ANY Relationships

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The ANY performs functions for both the: Downlink path The RF signals coming from the TREs enter the ANY at four TX connectors on the front panel. They are combined in pairs by RF combiners and fed to two TX output connectors. The ANY performs a 4:2 reduction of the TRE transmitter outputs. The two concentrated outputs are coupled to the ANX/ANC inputs, via external RF cables. Uplink path. Each of the four RF signals from the ANX/ANC passes through a 1:2 RF splitter. These signals are distributed in four groups to the TREs, via external RF cables. Each group provides a path for antenna diversity and non-diversity.

10.2.1 ANY Functions The following figure shows the method of combining the transmitter outputs and distributing the receiver inputs. Combiner TXA In1

RX0A Out1

RX1A Out1

TXA Out RX0A In

TXA In2

Power Divider

ANX/ ANC

RX1A In

RX0A Out2

RX1A Out2

RF Interfaces to/ from Four TRE Modules

ANYRI

BCB Interface

Combiner TXB In1

RX0B Out1

RX1B Out1

TXB Out RX0B In

TXB In2

Power Divider

ANX/ ANC

RX1B In

RX0B Out2

RX1B Out2

Figure 322: ANY Architecture

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The ANY consists of the functional entities shown in the following table. Combiner

The Combiner consists of two hybrid devices. Each device concentrates two transmitter outputs into one, thus halving the number of antennas required. The combiner takes the TX outputs from four TREs, via external cabling, and feeds them to the TXIN connectors on the ANX/ANC.

Power Dividers

The Power Dividers split and distribute the received RF signals, from the ANX module, to four outputs. The outputs are connected, via external cabling, to the inputs of the TRE module. There are two Power Dividers in each ANY module, each consisting of two splitters, providing diversity and non-diversity paths.

BCB Interface

The BCB interface is located on the subrack backplane. It interfaces the following ANYRI data to the BCB Bus: Inventory Subrack position of the ANY Subrack number.

ANY Remote Inventory

The ANYRI is specifically designed to hold Remote Inventory data for the ANY module. It is functionally and physically separate from the RF part of the ANY. The ANYRI consists of three components: BCB Interface driver BCB ASIC Serial EEPROM. The inventory data, which is held in a serial EEPROM, is transferred via the BCB ASIC and the BCB Interface. The ANYRI components are powered from a DC supply, which is present on the backplane.

Table 84: ANY, Functional Entities

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10.2.2 ANY Performance Characteristics The performance characteristics of the ANY are shown in the following table. Parameter

GSM 850

GSM 900

GSM 1800

GSM 1900

Transmit band.

869 - 894 MHz

925 - 960 MHz

1805 - 1880 MHz

1930 - 1990 MHz

Receive band.

824 - 849 MHz

880 - 915 MHz

1710 - 1785 MHz

1850 - 1910 MHz

Power for each transmitter channel input for:

45 W maximum

45 W maximum

45 W maximum

45 W maximum

High power ANY - ANYHx.

-

63 W maximum

63 W maximum

-

Number of channels.

124

174

374

299

Bandwidth for each channel.

200 kHz

200 kHz

200 kHz

200 kHz

Insertion loss at transmit band.

3.3 ± 0.2 dB

3.3 ± 0.2 dB

3.3 ± 0.2 dB

3.3 ± 0.2 dB

Insertion loss at receive band.

3.3 ± 0.2 dB

3.3 ± 0.2 dB

3.3 ± 0.2 dB

3.3 ± 0.2 dB

Return loss at receive port.

> 21 dB

> 21 dB

> 21 dB

> 21 dB

Return loss at transmit port.

> 21 dB

> 21 dB

> 21 dB

> 21 dB

Isolation between transmit and receive ports.

> 85 dB

> 90 dB

≤ 90 dB

≤ 90 dB

Isolation between receive output ports of same coupler.

> 25 dB

> 25 dB

> 25 dB

> 25 dB

Isolation between receive ports of different networks.

> 50 dB

> 50 dB

> 50 dB

> 50 dB

Isolation between transmit input ports of same network.

> 25 dB

> 25 dB

> 25 dB

> 25 dB

Isolation between transmit input ports of different networks.

> 50 dB

> 50 dB

> 50 dB

> 50 dB

Intermodulation products at antenna port with 2 x 40 W (2 x 30 W for GSM 1800 and GSM 1900) signals at one transmit port and 50 on receive port in receive band.

< -108 dBm

< -108 dBm

< -108 dBm

< -108 dBm

Medium power ANY - ANYx.

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Parameter

GSM 850

GSM 900

GSM 1800

GSM 1900

Intermodulation products at antenna port with 2 x 40 W (2 x 30 W for GSM 1800 and GSM 1900) signals at one transmit port and 50 on receive port in transmit band.

< -75 dBc

< -75 dBc

< - 75 dBc

< - 75 dBc

RF input impedance.

50

50

50

50

RF output impedance.

50

50

50

50

Table 85: ANY Performance Characteristics

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10.2.3 ANY Front Panel The following figure shows the layout of the ANY front panel. Camloc Fasteners Module Extractor

Mnemonic or Serial Number Label

RX0AIN

Transmitter Connectors

Receiver Connectors

TXAOUT

TXAIN1

RX1AIN RX0AOUT1

RX1AOUT1 RX0AOUT2

TXAIN2

RX1AOUT2 RX0BIN

TXBOUT

TXBIN1

TXBIN2

RX1BIN RX0BOUT1

RX1BOUT1 RX0BOUT2

RX1BOUT2

Mnemonic or Serial Number Label

Module Extractor

Figure 323: ANY Front Panel

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10.2.3.1 Transmitter Connectors The ANY has four transmitter input connectors and two transmitter output connectors on its front panel. The following table describes the ANY transmitter connectors. Connector

Description

TXAOUT

Provide two RF interfaces to the transmitter inputs of an ANX/ANC module.

TXBOUT TXAIN1, TXAIN2 TXBIN1, TXBIN2

Provide four RF interfaces from four TRE transmitter outputs.

Table 86: ANY Transmitter Connectors

10.2.3.2 Receiver Connectors The ANY has four receiver input connectors and eight receiver output connectors on its front panel. The following table describes the ANY receiver connectors. Connector

Description

RX0AIN

Provide two RF receiver interfaces from the ANX/ANC receiver outputs RX0AOUT and RX1AOUT.

RX1AIN RX0BIN RX1BIN RX0AOUT1, RX1AOUT1 RX0AOUT2, RX1AOUT2

Provide two RF receiver interfaces from the ANX/ANC receiver outputs RX0BOUT and RX1BOUT. Each pair of connectors provide two RF receiver interfaces to the TRE receiver inputs RX0 and RX1.

RX0BOUT1, RX1BOUT1 RX0BOUT2, RX1BOUT2 Table 87: ANY Receiver Connectors

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10.3 ANC The ANC provides the intermediate RF stage between the TREs and the antenna. Its tasks are to: Combine the output signals of up to four transmitters and to connect them to up to two antennas Feed the received signals from the antenna to the radio front end, where the signals are amplified and distributed to up to eight receivers Allow simultaneous transmission and receiving on antennas (duplexer) Provide filtering for the TX- and RX-path Supervise the VSWR of the antennas.

10.3.1 ANC Basic Architecture The following figure shows the basic architecture. TXAIN1 TXAIN2 RX0AOUT1 RX0AOUT2 RX1AOUT1 RX1AOUT2

Combiner

Duplexer

ANT A

Splitter

ANCC RX0BOUT1 RX0BOUT2 RX1BOUT1 RX1BOUT2 TXBIN1 TXBIN2

Splitter

Combiner

Duplexer

ANT B

Figure 324: ANC Basic Architecture

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10.3.2 ANC Detailed Architecture The following figure shows the ANC in more detail. TX Combiner A

Load 60 W*)

TXAIN1 TXAIN2 TXAOUT External Bridge A Directional Coupler A

TXAIN

Uplink Functions TRE

Duplexer A

RX0AOUT1 RX0AOUT2 RX1AOUT1 RX1AOUT2

LNA

ANTA Filter

ANCC

Power Splitter A

BSII

AN Microprocessor

LEDs

VSWR Receiver

Gain Control

BCB Interface Remote Switching RX1BOUT1

Power Splitter B

DC Feed

BCB

DC/DC Converter

−48 VDC

RX1BOUT2 TRE

LNA

RX0BOUT1 RX0BOUT2

Uplink Functions TXBIN

Duplexer B

ANTB Directional Coupler B

External Bridge B TXBOUT TXBIN1 TXBIN2 Load 60 W*) TX Combiner B

*) 150 W for ANCD/ANCP

Figure 325: ANC Architecture

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10.3.3 ANC Description On the downlink, the ANC connects two TRE transmitters to two antennas. On the uplink, it splits the received signals and passes them to the TRE receivers. The following types of ANC modules are available for the different BTS A9100 variants: ANCD, ANC module for GSM 1800 ANCG, ANC module for GSM 900 ANCGP, ANC module for PGSM 900 ANCL, ANC module for GSM 850 ANCP, ANC module for GSM 1900. GSM 850 is not supported by all BSS software releases. If you are in doubt, contact Alcatel support. If one transmitter is used in each branch A and B, the RF signals pass the duplexers before feeding the antennas. If two transmitters are used in a branch, the coupler will be used in front of the duplexer. This coupler is connected by an RF cable bridge. The duplexers provide coupling of the transmitted and received signals, allowing a single antenna to be used for both downlink and uplink channels. The ANC also allows the return loss of the transmitted signals to be measured, at the antenna connector, using VSWR techniques. The uplink channel comprises amplifiers, with remotely-adjustable gain control, remote DC feed and power splitters. The ANC functions; interface, controller and power supply are given below.

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Downlink Functions

The downlink functions are performed by the components shown in Table ANX/ANC/AGC/ANB, Downlink Components (75).

Uplink Functions

The uplink functions are performed by the components shown in Table ANX/ANC/AGC/ANB, Uplink Components (76).

BTS Control Bus Interface

The BCB Interface is located on the backplane. It interfaces the data and control signals to the BCB as listed in Table ANX/ANC/AGC/ANB, BCB Interface (77).

Antenna Network Controller

From a functional point of view the ANCC is the same as the ANCON used in the ANX (but without the DC/DC converter). Therefore for a description of the ANCC, see Antenna Network Controller (Section 10.1.4).

Power Supply

As part of the ANCC there is a DC/DC converter, providing all the necessary voltages for the ANC components. As the DC/DC is functionally the same as the one used in the ANX, refer to AN Power Supply (Section 10.1.5) for its description.

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10.3.4 ANC LEDs and Alarms This section provides information on the ANC’s LEDs and Alarms.

10.3.4.1 LEDs There are four LEDs on the front panel, which provide a visual indication of the operational status of the ANC module. The following table describes each LED and defines their various operational states. LED

Color

VSWR A

Yellow

VSWR B

O and M

ALARM

Status

Description VSWR status of Antenna 2

On

VSWR OK

Slow Blinking

Low threshold reached

Fast Blinking

High threshold reached

Off

VSWR not supervised

Yellow

VSWR status of Antenna 1 On

VSWR OK

Slow Blinking

Low threshold reached

Fast Blinking

High threshold reached

Off

VSWR not supervised

Yellow/ Red

O and M status Yellow On

ANC is in O and M operational mode

Red On

Not used. (Only active during startup LED test in case of LNA cabling error)

Off

ANC is not operational

Yellow/ Red

Alarm status Yellow On

Normal situation (FS/SW running, no alarms present, module is powered)

Red Blinking

Non-fatal alarm present

Off

No Power presence or LED failure

Red On

Fatal alarm for the module or module in out-of-order state

Table 88: ANC/ANB LED Descriptions

10.3.4.2 Alarms The ANC detects the alarm conditions shown in Table ANX/ANC/AGC/ANB Alarm Conditions (81).

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10.3.5 ANC Performance Characteristics The performance characteristics of the ANCs are shown in the following table. Parameter

GSM 850 1)

GSM 900

Transmit band.

869 - 894 MHz

925 - 960 MHz 935 - 960 MHz

Receive band.

824 - 849 MHz

GSM 1800

1805 - 1880 MHz 1930 - 1990 MHz 4)

1710 - 1785 MHz 1850 - 1910 MHz

880 - 915 MHz 890 - 915 MHz

GSM 1900

4)

Power for each transmitter channel input.

63 W maximum

63 W maximum

63 W maximum

63 W maximum

Number of channels.

124

174

374

299

Bandwidth for each channel.

200 kHz

200 kHz

200 kHz

200 kHz

Return loss at receive port.

> 16 dB

> 16 dB

> 16 dB

> 16 dB

Return loss at transmit port.

> 16 dB

> 16 dB

> 16 dB

> 18 dB

> 18 dB

2)

> 16 dB 3)

Return loss at antenna port.

> 18 dB

> 18 dB

Return loss at coupler port.

> 18 dB

> 18 dB

≥ 18 dB

≥ 18 dB

Group delay distortion in transmit band.

≤100 ns

≤100 ns

≤ 100 ns

≤ 100 ns

Isolation between receive port >30 dB and antenna port.

>30 dB

>30 dB

> 30 dB

Isolation between receive ports.

>20 dB

22 dB

22 dB

> 22 dB

Isolation between transmit ports (A to B/ 1 to 2).

>50 dB/ 22 dB

>50 dB/ 22 dB

>50 dB/ 22 dB

>50 dB/ 22 dB

Insertion loss in transmit pass band without combiner.

0.3 - 1.6 dB

0.3 - 1.6 dB

< 0.3 - 1.6 dB

< 0.3 - 1.6 dB

Insertion loss in transmit pass band with combiner.

3.4 - 5.3 dB

3.4 - 5.3 dB

3.4 - 5.2 dB

3.4 - 5.2 dB

Intermodulation products at antenna port with 2x 20 W signals at one transmit port and 50 on receive port in receive band.

<-101 dBm

<-103 dBm

<-103 dBm

<-103 dBm

Intermodulation products at antenna port with 2x 20 W signals at one transmit port and 50 on receive port in transmit band.

-75 dBc

<-75 dBc

<-75 dBc

<-75 dBc

RF input impedance.

50

50

50

50

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Parameter

GSM 850

RF output impedance.

50

1)

GSM 900

GSM 1800

GSM 1900

50

50

50

1) Valid for ANCL only.

3) For ANC with bridge: >16 dB.

2) For ANC with bridge: >18 dB.

4) For ANCGP

Table 89: ANC Performance Characteristics

10.3.6 ANC Front Panel The following figures show the layout and O and M features of the three versions of the ANC front panel.

10.3.6.1 ANC Front Panel - Version 1 Camloc Fasteners

Transmitter Input Connectors

TXAIN1

RX1AOUT1 RX0AOUT1 RX1AOUT2

TXAIN2 RF bridge (if TXAIN1 and/or TXAIN2 used)

RX0AOUT2

TXAIN

VSWRB ALARM

Combined Transmitter Output Connector (TXAIN1 + TXAIN2)

TXAOUT

ANTB

High Voltage Warning TXBOUT Antenna Connector ANTA Module Extractor

LEDs

TXBIN

O&M VSWRA TXBIN2 RX0BOUT2

Receiver Connectors

RX1BOUT2 RX0BOUT1

TXBIN1

RX1BOUT1

Figure 326: ANC Front Panel Version 1

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10.3.6.2 ANC Front Panel - Version 2 Camloc Fasteners

TXAIN1 Transmitter Input Connectors

RX1AOUT1 TXAIN2

RX0AOUT1 RX1AOUT2 RX0AOUT2 VSWRB ALARM

Combined Transmitter Output Connector (TXAIN1 + TXAIN2)

TXAIN

Antenna Connector

TXAOUT

ANTA

ANTB

High Voltage Warning TXBOUT RF bridge (if TXBIN1 and/or TXBIN2 used) TXBIN

Module Extractor

LEDs

O&M VSWRA

TXBIN2

RX0BOUT2 Receiver Connectors

RX1BOUT2 TXBIN1 RX0BOUT1 RX1BOUT1

Figure 327: ANC Front Panel Version 2

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10.3.6.3 ANC Front Panel - Version 3 Camloc Fasteners Combined Transmitter Output Connector (TXAIN1 + TXAIN2)

TXAOUT

RX1AOUT1

TXAIN

RF bridge (if TXAIN1 and/or TXAIN2 used)

RX0AOUT1 RX1AOUT2

TXAIN1

Transmitter Input Connectors

RX0AOUT2 VSWRB TXAIN2

ALARM

Antenna Connector

ANTA

ANTB

High Voltage Warning

Module Extractor

LEDs

O&M

TXBIN2

VSWRA RX0BOUT2

Receiver Connectors

TXBIN1

RX1BOUT2 RX0BOUT1

TXBIN

RX1BOUT1 TXBOUT

Figure 328: ANC Front Panel Version 3

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10.3.6.4 Connectors The ANC has four transmitter input connectors and eight receiver output connectors on its front panel. Therefore, one ANC module can be interfaced to four TRE modules or two ANY modules, if used. The following table describes the ANC front panel connectors. Connector

Description

TXAIN1, TXAIN2

Provide the RF transmitter interfaces from four TRE modules, or two ANY modules if used.

TXBIN1, TXBIN2 TXAIN, TXAOUT

A bridge between both connectors provides the interface between two combined RF transmitter signals and the duplexer of branch A.

TXBIN, TXBOUT

A bridge between both connectors provides the interface between two combined RF transmitter signals and the duplexer of branch B.

RX0AOUT1

Provide the RF receiver interfaces between antenna A and the first TRE receiver connectors RX0 and RX1, or a first ANY module if used.

RX1AOUT1 RX0AOUT2 RX1AOUT2 RX0BOUT1 RX1BOUT1 RX0BOUT2 RX1BOUT2 ANTA

Provide the RF receiver interfaces between antenna A and the second TRE receiver connectors RX0 and RX1, or a first ANY module if used. Provide the RF receiver interfaces between antenna B and the third TRE receiver connectors RX0 and RX1, or a second ANY module if used. Provide the RF receiver interfaces between antenna B and the fourth TRE receiver connectors RX0 and RX1, or a second ANY module if used. Provide the RF interface to/ from two antennas, A and B.

ANTB Table 90: ANC Front Panel Connectors The front panel connector types are described in the following table. ANC Version 1

ANC Versions 2 and 3

ANTA, ANTB

7/ 16

7/ 16

TXAOUT, TXBOUT

N female

SMA female

All other TXnn

N female

N female

All RXnn

SMB

SMB

Table 91: ANC, Front Panel Connector Types

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10.4 AGC The AGC provides the intermediate RF stage between the TREs and the antenna. Its functions are to: Combine the output signals of up to four transmitters and to connect them to up to two antennas Feed the received signals from the antenna to the radio front end, where the signals are amplified and distributed to up to eight receivers Allow simultaneous transmission and receiving on antennas (duplexer) Provide filtering for the TX- and RX-path Supervise the VSWR of the antennas.

10.4.1 AGC Basic Architecture The following figure shows the basic architecture. TXAIN1 TXAIN2 RX0AOUT1 RX0AOUT2 RX1AOUT1 RX1AOUT2

Combiner

ANT A

Splitter

AGCC+ AGCPS RX0BOUT1 RX0BOUT2 RX1BOUT1 RX1BOUT2 TXBIN1 TXBIN2

Duplexer

LNA VSWR MUX BiasT UC

Splitter

Combiner

Duplexer

ANT B

Figure 329: AGC Basic Architecture

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10.4.2 AGC Detailed Architecture The following figure shows the AGC in more detail. TX Combiner A

Load 150 W

TXAIN1 TXAIN2 TXAOUT External Bridge A Directional Coupler A

TXAIN

Uplink Functions TRE

Duplexer A

RX0AOUT1 RX0AOUT2 RX1AOUT1 RX1AOUT2

LNA

ANTA Filter

AGCC

Power Splitter A

BSII

AN Microprocessor

LEDs

VSWR Receiver

Gain Control

BCB Interface Remote Switching RX1BOUT1

Power Splitter B

DC Feed

BCB

DC/DC Converter

−48 VDC

RX1BOUT2 TRE

LNA

RX0BOUT1 RX0BOUT2

Uplink Functions TXBIN

Duplexer B

ANTB Directional Coupler B

External Bridge B TXBOUT TXBIN1 TXBIN2 Load 150 W TX Combiner B

Figure 330: AGC Architecture

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10.4.3 AGC Description On the downlink, the AGC connects four TRE transmitters to two antennas. On the uplink, it splits the received signals and passes them to the TRE receivers. The following types of AGC modules are available for the different BTS A9100 variants: AGC18, AGC module for GSM 1800 AGC9E, AGC module for GSM 900. If one transmitter is used in each branch A and B, the RF signals pass the duplexers before feeding the antennas. If two transmitters are used in a branch, the coupler will be used in front of the duplexer. This coupler is connected by an RF cable bridge. The duplexers provide coupling of the transmitted and received signals, allowing a single antenna to be used for both downlink and uplink channels. The AGC also allows the return loss of the transmitted signals to be measured, at the antenna connector, using VSWR techniques. The uplink channel comprises amplifiers, with remotely-adjustable gain control, remote DC feed and power splitters. The AGC functions, interface, controller and power supply are given below.

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Downlink Functions

The downlink functions are performed by the components shown in Table ANX/ANC/AGC/ANB, Downlink Components (75).

Uplink Functions

The uplink functions are performed by the components shown in Table ANX/ANC/AGC/ANB, Uplink Components (76).

BTS Control Bus Interface

The BCB Interface is located on the backplane. It interfaces the data and control signals to the BCB as listed in Table ANX/ANC/AGC/ANB, BCB Interface (77).

Antenna Network Controller

From a functional point of view the AGCC is the same as the ANCON used in the ANX (but without the DC/DC converter). Therefore for a description of the AGCC, see Antenna Network Controller (Section 10.1.4).

Power Supply

As part of the AGCC there is a DC/DC converter, providing all the necessary voltages for the AGC components. Refer to AGC Power Supply (Section 10.4.5) for its description.

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10.4.4 Antenna Network Geran Combiner Controller The AGCC is responsible for maintaining the operation of the AGC. Its principal functions are: Setting the LNA gain for the assigned TREA receiver Supervising LNA alarms Measuring antenna VSWR Reporting VSWR alarms Selecting the antenna sector Detecting RF cabling status RI, via the BCB Interface Remote power on/off, via the BCB Interface Status display, via front panel LEDs. Measurement of the antenna output power Reporting the antenna output power Tower mounted amplifier (TMA) current supervision.

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The following figure shows the AGCC architecture. BCB

38−78V

Power Module

12V

Current Sense + Switch

FLASH

SDRAM

RI

5V 3.3V

ADC DEBUG1 DEBUG2

DC Ant A DC Ant B

12V TMA A

SCP

12V TMA B

BSII0 BSII1

BSII MUX

ANT SEL For Rev RES

IO

HDLCU

LNA/RXMUX

I2C

I2C HFFI

HFFI

Synthesizer ACU ANLU

ADC

X

RF

Receiver

Figure 331: AGCC Architecture The AGCC interfaces provides the following interfaces: On backpanel connector BCB BSII CLKI DEBUG1 DEBUG2. On LNA/RXMUX connector LNAC RCD RF TMAFD. The AGCC functional entities are described in the following sections.

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10.4.4.1 VSWR Receiver The VSWR receiver is a selective VSWR meter which measures the forward and reflected (reverse) power of the transmitters. The VSWR is measured at the output of the duplexer couplers, and fed to an RF MUX in the receiver (see Figure 331). The VSWR receiver consists of: Local synthesizer Input MUX. A local synthesizer generates a signal which is used to compare the baseband frequency with the ARFCN. The local synthesizer is set to the ARFCN frequency by the AN microprocessor. The input MUX provides the RF inputs to the VSWR receiver. It provides a selective input of the forward and reverse power from transmitters A and B. The input MUX operates under the control of the AN microprocessor.

10.4.4.2 BSII Frame Clock PLL The BSII frame clock PLL recovers the BSII frame clock from the backplane. The clock outputs are used for BSII communications, the AN microprocessor and the PLL lock-detect signal. BSII Frame CLK

PLL Switch

BSII Comms

Loop Filter VCXO

Glue Logic

Clock Edge Control Signal

Microprocessor

BSII PLL Lock Detect

Figure 332: AGCC, BSII Frame Clock PLL

10.4.4.3 CLKII Clock PLL The CLKII clock PLL recovers the BSII master clock from the backplane. The clock outputs are used for the local synthesizer reference clock, the ’start conversion’ signal for the baseband ADC and the CLKII lock-detect signal. BSII Master CLK

PLL Switch

Local Synthesizer

Loop Filter VCXO

Clock Edge Control Signal

Glue Logic

Start Conversion

CLKII Lock Detect

Figure 333: AGCC, CLKII Clock PLL

10.4.4.4 Signal Control Processor The SCP performs LNA alarm supervision and gain setting, and control of the status LEDs. It also provides an interface to the baseband ADC in the VSWR receiver (see Figure 331). The microprocessor compares the ADC output with known VSWR values. If the VSWR exceeds predefined thresholds, an alarm is raised (refer to Table AGC LEDs and Alarms (Section 10.4.6)). If the reflected power is very high, the transmitters are shut down to avoid possible damage to equipment. High reflected power can be caused by, for example, a break in the antenna coupling. The SCP hardware consists of a microprocessor supported by two memory devices, a Flash EEPROM and an SDRAM.

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10.4.4.5 Antenna Network Logic Unit The Antenna Network Logic Unit (ANLU) contains the follwing blocks: Clock and Reset Control Unit (CRCU) MicroBlaze Systeem HDLC Unit BSII Multiplexer HFFI Unit Register Unit I2C Unit Analog Control CIrcuit (ACU).

MikroBlaze System

I2C BSII0 BSII1

BSII MUX

IO

HDLCU

IO

ACU

ACU

REGU HFFI

CLK−CLK2x/Fx

HFFI

BSII_CLK40M96 CLK25M6

CRCU CLK_SDRAM DOWN

CLKII_CLK26M CLK_SDRAMIN

UP CLKII_WIN_PLL BSII_WIN_PLL

Figure 334: ANLU Architecture

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10.4.4.6 Receiver The front-end receiver is realized by one device, which includes a direct conversion QPSK demodulator, the PLL and synthesizer. The downconverter can handle receive frequency in the GSM, DCS or PCS band. Control data will be entered by means of an I2C interface. The RF signal from the LNA board is fed directly into the downconverter. The I/Q baseband output signal of the downconverter is sampled and converted using a dual sigma-delta ADC. The data output is serial at a word rate of 270.83kHz for each I and Q. The ADC is interfaced by the Analog Control Unit (ACU),

10.4.4.7 TMA Feeding and Current Supervision The power for the two TMA will be switched on and off by means of an ANLU GPIO signal and a MOSFET. The current supervision is done with an Overcurrent Protection Circuit, which includes a current sense amplifier, a comparator and an internal voltage reference. The current sense amplifier output is converted by a 10 bit ADC and the SCP can read the actual current value via the I2C bus. Additional the current sense IC has a comparator with a latched output. It gives an over current alarm if the current is higher than 300mA. This latched alarm signal is used to switch off the 12V directly by hardware to prevent a DC/DC converter shot down.

10.4.4.8 BCB and RI The main functions are: ISL, provides access via BCN on the ISL interface to RI ASIC RI EEPROM, is a serial EEPROM that stores information about AGCC module RPI, Remote Power Interface controls the AGCC power supply and supervises the signals of input and output voltages RCD, Radio Cabling Detection allows an automatic uplink RF cabling detection and supervision BCB_Vdd, BCB bus powered if DC/DC converter is off or self powered if DC/DC converter is on ADR, Physical address from backpanel for RI ASIC address setting and for SCP BSII address setting.

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10.4.4.9 Glue Logic Glue logic consists of a number of registers, implemented on a single CPLD device. It also converts 5 V TTL signals to 3.3 V, required by the microprocessor. The Glue logic maintains the following interfaces and/or functions: AN microprocessor to the BSII Board/module address register Baseband ADC LNA error register LNA gain adjustment register. The Glue logic also controls the BSII frame clock PLL and the CLKII master clock PLL with a clock edge control signal (see Figure 332 and Figure 333).

10.4.4.10 Remote Inventory Remote Inventory is used to store information about the AGC module (part number, name, serial number, etc.). It consists of an EEPROM which is connected to the BCB ASIC. The stored information is read via the BCB Interface.

10.4.5 AGC Power Supply The AGCPS is a DC/DC converter, providing all the necessary voltages for the AGC components.

10.4.5.1 Voltages The following table provides AGCPS input/output voltage parameters. Voltage

Value

V in

-38.4 VDC min. -72 VDC max. -48 VDC to -60 VDC nom.

V out

+3.3 VDC ±3 % + 5.1 VDC ±3 % + 12 VDC ±3 %

Table 92: AGCPS Input/Output Voltage Parameters Normal operation of V out is unaffected by temperature fluctuations in the range 0o C to 70o C.

10.4.5.2 Fuse The input of the AGCPS is protected by a fuse with a high-breaking capacity.

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10.4.5.3 Protection The AGCPS circuitry is protected against short circuit and accidental polarity inversion on its inputs.

10.4.5.4 Grounding Ground continuity for the module is achieved with ground pins on the subrack backplane which connect to the bus bar ground.

10.4.5.5 Remote Switching The AGCPS can be remotely switched on and off by the OMU, via the BCB. This feature is implemented on the module with an optically isolated on/off switch.

10.4.5.6 Low Voltage Alarms Alarms are raised if the voltage level is too low. The following table provides the low voltage threshold tolerances for AGCPS alarms. Voltage

Threshold Min.

Threshold Max.

Vin

30.4 V

38.4 V

3.3 V

2.7 V

3.0 V

5.1 V

4.2 V

4.6 V

12 V

10.0 V

11.0 V

Table 93: AGCPS Alarm Thresholds

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10.4.6 AGC LEDs and Alarms This section provides information on the AGC’s LEDs and Alarms.

10.4.6.1 LEDs There are two LEDs on the front panel, which provide a visual indication of the operational status of the AGC module. The following table describes each LED and defines their various operational states. LED

Color

ON

Green

OM / ALARM

Status

Description Power status

On

Module is switched on

Off

Module is switched off

Yellow/ Red

Alarm status Yellow On

OM operational status (normal operation)

Yellow Blinking

Not defined

Red Blinking

Not defined

Red On

LNA, TMA or VSWR alarm on port A or B

Table 94: AGC LED Descriptions

10.4.6.2 Alarms The AGC detects the alarm conditions shown in Table ANX/ANC/AGC/ANB Alarm Conditions (81).

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10.4.7 AGC Performance Characteristics 10.4.7.1 General Performance Characteristics The performance characteristics of the AGCs are shown in the following table. Parameter

GSM 900 P

GSM 900 E

GSM 1800

Transmit band.

935 - 960 MHz

925 - 960 MHz

1805 - 1880 MHz

Receive band.

890 - 915 MHz

880 - 915 MHz

1710 - 1785 MHz

Power for each transmitter channel input.

80 W maximum

80 W maximum

80 W maximum

Number of channels.

124

174

374

Bandwidth for each channel.

200 kHz

200 kHz

200 kHz

Return loss at receive port.

> 16 dB

> 16 dB

> 16 dB

Return loss at transmit port.

> 16 dB

> 16 dB

> 16 dB

Return loss at antenna port.

> 18 dB

> 18 dB

> 18 dB

Group delay distortion in transmit band.

≤100 ns

≤100 ns

≤ 100 ns

Isolation between receive port and antenna port.

>30 dB

>30 dB

>30 dB

Isolation between receive ports.

>20 dB

>20 dB

>20 dB

Isolation between transmit ports (A to >50 dB/ 22 dB B/ 1 to 2).

>50 dB/ 22 dB

>50 dB/ 22 dB

Insertion loss in transmit pass band without combiner.

0.3 - 1.6 dB

0.3 - 1.6 dB

0.3 - 1.6 dB

Insertion loss in transmit pass band with combiner.

3.4 - 5.3 dB

3.4 - 5.3 dB

3.4 - 5.2 dB

Intermodulation products at antenna port with 2x 28 W signals at one transmit port and 50 on receive port in receive band.

<-100 dBm

<-100 dBm

<-100 dBm

Intermodulation products at antenna port with 2x 28 W signals at one transmit port and 50 on receive port in transmit band.

<-36 dBm

<-36 dBm

<-36 dBm

RF input impedance.

50

50

50

RF output impedance.

50

50

50

Table 95: AGC Performance Characteristics

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TX to RX isolation: TXAIN -> RX1AOUT1 / RX1AOUT2 / RX1BOUT1 / RX1BOUT2 TXBIN -> RX0AOUT1 / RX0AOUT2 / RX0BOUT1 / RX0BOUT2 No.

Start Freq (MHz)

Stop Freq (MHz)

Atten (dB) with RX gain

Atten (dB) without RX gain

A14

890

915

> 64

> 79

ANTA -> RX1AOUT1 / RX1AOUT2 / RX1BOUT1 / RX1BOUT2 ANTB -> RX0AOUT1 / RX0AOUT2 / RX0BOUT1 / RX0BOUT2 No.

Start Freq (MHz)

Stop Freq (MHz)

Attenuation (dBc)

A20 (Out of band rejection)

816

880

> 30

A21 (RX passband)

890

915

LNA Passband gain

10.4.7.2 Performance Characteristics with AGC GSM 900P Module Functional Variant ’B’ Compared to general perfomrance characteristics, the variant ’B’ has the following specific values: TX to RX isolation: TXAIN -> RX1AOUT1 / RX1AOUT2 / RX1BOUT1 / RX1BOUT2 TXBIN -> RX0AOUT1 / RX0AOUT2 / RX0BOUT1 / RX0BOUT2 No.

Start Freq (MHz)

Stop Freq (MHz)

Atten (dB) with RX gain

Atten (dB) without RX gain

A14

896

915

> 64

> 79

ANTA -> RX1AOUT1 / RX1AOUT2 / RX1BOUT1 / RX1BOUT2 ANTB -> RX0AOUT1 / RX0AOUT2 / RX0BOUT1 / RX0BOUT2 No.

Start Freq (MHz)

Stop Freq (MHz)

Attenuation (dBc)

A20 (Out of band rejection)

816

888

> 30

A21 (RX passband)

896

915

LNA Passband gain

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10.4.7.3 Performance Characteristics with AGC GSM 900P Module Functional Variant ’C’ Compared to general perfomrance characteristics, the variant ’C’ has the following specific values: TX to RX isolation: TXAIN -> RX1AOUT1 / RX1AOUT2 / RX1BOUT1 / RX1BOUT2 TXBIN -> RX0AOUT1 / RX0AOUT2 / RX0BOUT1 / RX0BOUT2 No.

Start Freq (MHz)

Stop Freq (MHz)

Atten (dB) with RX gain

Atten (dB) without RX gain

A14

902

915

> 64

> 79

ANTA -> RX1AOUT1 / RX1AOUT2 / RX1BOUT1 / RX1BOUT2 ANTB -> RX0AOUT1 / RX0AOUT2 / RX0BOUT1 / RX0BOUT2 No.

Start Freq (MHz)

Stop Freq (MHz)

Attenuation (dBc)

A20 (Out of band rejection)

816

888

> 50

A21 (RX passband)

902

915

LNA Passband gain

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10.4.8 AGC Front Panel The following figures show the layout and O& M features of the three versions of the AGC front panel.

10.4.8.1 AGC Front Panel - Version 1 Camloc Fasteners

Antenna Connector

TXAIN1

Transmitter Input Connectors

ANTA RX0AOUT1 RX1AOUT1 TXAIN2

RF bridge (if TXAIN1 and/or TXAIN2 used)

TXAIN RX0AOUT2 TXAOUT

RX1AOUT2

Hot Surface Warning

RX1BOUT2

Module Extractor

Combined Transmitter Output Connector (TXAIN1 + TXAIN2)

RX0BOUT2 TXBIN2

Receiver Connectors TXBIN

TXBIN1

RX1BOUT1 RX0BOUT1 ON

LEDs

OM/ALARM TXBOUT

High Voltage Warning ANTB

Figure 335: AGC Front Panel - Version 1

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10.4.8.2 AGC Front Panel - Version 2 Camloc Fasteners

Antenna Connector

TXAIN1 ANTA RX0AOUT1 RX1AOUT1 Transmitter Input Connectors

TXAIN2 Hot Surface Warning

RF bridge (if TXAIN1 and/or TXAIN2 used)

RX0AOUT2 TXAOUT

RX1AOUT2

Combined Transmitter Output Connector (TXAIN1 + TXAIN2)

TXAIN

Module Extractor

RX1BOUT2 RX0BOUT2 TXBIN2 TXBIN

Receiver Connectors

TXBIN1 RX1BOUT1 RX0BOUT1 ON LEDs

OM/ALARM TXBOUT

High Voltage Warning

ANTB

Figure 336: AGC Front Panel - Version 2

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10.4.8.3 Connectors The AGC has four transmitter input connectors and eight receiver output connectors on its front panel. Therefore, one AGC module can be interfaced to four TRE modules or two ANY modules, if used. The following table describes the AGC front panel connectors. Connector

Description

TXAIN1, TXAIN2

Provide the RF transmitter interfaces from four TRE modules, or two ANY modules if used.

TXBIN1, TXBIN2 TXAIN, TXAOUT

A bridge between both connectors provides the interface between two combined RF transmitter signals and the duplexer of branch A.

TXBIN, TXBOUT

A bridge between both connectors provides the interface between two combined RF transmitter signals and the duplexer of branch B.

RX0AOUT1

Provide the RF receiver interfaces between antenna A and the first TRE receiver connectors RX0 and RX1, or a first ANY module if used.

RX1AOUT1 RX0AOUT2 RX1AOUT2 RX0BOUT1 RX1BOUT1 RX0BOUT2 RX1BOUT2 ANTA

Provide the RF receiver interfaces between antenna A and the second TRE receiver connectors RX0 and RX1, or a first ANY module if used. Provide the RF receiver interfaces between antenna B and the third TRE receiver connectors RX0 and RX1, or a second ANY module if used. Provide the RF receiver interfaces between antenna B and the fourth TRE receiver connectors RX0 and RX1, or a second ANY module if used. Provide the RF interface to/ from two antennas, A and B.

ANTB Table 96: AGC Front Panel Connectors The front panel connector types are described in the following table. Connector

Type

ANTA, ANTB

7/ 16 female

TXAOUT, TXBOUT

N female or SnapN

All other TXnn

N female or SnapN

All RXnn

SMB male

Table 97: AGC, Front Panel Connector Types

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10.5 ANB The ANB provides the intermediate RF stage between the TREs and the antenna. Its tasks are to: Combine the output signals of up to two transmitters and to connect them to up to two antennas Feed the received signals from the antenna to the radio front end, where the signals are amplified and distributed to up to eight receivers Allow simultaneous transmission and receiving on antennas (duplexer) Provide filtering for the TX- and RX-path Supervise the VSWR of the antennas.

10.5.1 ANB Basic Architecture The following figure shows the basic architecture. TXAIN RX0AOUT1 RX0AOUT2 RX1AOUT1 RX1AOUT2

Duplexer

ANT A

Splitter

ANCC RX0BOUT1 RX0BOUT2 RX1BOUT1 RX1BOUT2 TXBIN

Splitter

Duplexer

ANT B

Figure 337: ANB Basic Architecture

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10.5.2 ANB Detailed Architecture The following figure shows the ANB in more detail.

Directional Coupler A

TXAIN

Uplink Functions TRE

Duplexer A

RX0AOUT1 RX0AOUT2 RX1AOUT1 RX1AOUT2

LNA

ANTA Filter

ANCC

Power Splitter A

BSII

AN Microprocessor

LEDs

VSWR Receiver

Gain Control

BCB Interface Remote Switching RX1BOUT1

Power Splitter B

DC Feed

BCB

DC/DC Converter

−48 VDC

RX1BOUT2 TRE

LNA

RX0BOUT1 RX0BOUT2

Uplink Functions TXBIN

Duplexer B

ANTB Directional Coupler B

Figure 338: ANB Architecture

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10.5.3 ANB Description On the downlink, the ANB connects two TRE transmitters to two antennas. On the uplink, it splits the received signals and passes them to the TRE receivers. The following types of ANB modules are available for the different BTS A9100 variants: ANBD, ANB module for GSM 1800 ANBG, ANB module for GSM 900. In each branch A and B, the RF signals pass the duplexers before feeding the antennas. The duplexers provide coupling of the transmitted and received signals, allowing a single antenna to be used for both downlink and uplink channels. The ANB also allows the return loss of the transmitted signals to be measured, at the antenna connector, using VSWR techniques. The uplink channel comprises amplifiers, with remotely-adjustable gain control, remote DC feed and power splitters. The table below describes the downlink and uplink functions, the interface, the controller and the power supply for the ANB.

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Downlink Functions

The downlink functions are performed by the components shown in Table ANX/ANC/AGC/ANB, Downlink Components (75).

Uplink Functions

The uplink functions are performed by the components shown in Table ANX/ANC/AGC/ANB, Uplink Components (76).

BTS Control Bus Interface

The BCB Interface is located on the backplane. It interfaces the data and control signals to the BCB as listed in Table ANX/ANC/AGC/ANB, BCB Interface (77).

Antenna Network Controller

From a functional point of view the ANCC is the same as the ANCON used in the ANX (but without the DC/DC converter). There,fore for the description of the ANCC, see Antenna Network Controller (Section 10.1.4).

Power Supply

As part of the ANCC there is a DC/DC converter, providing all the necessary voltages for the ANB components. As the DC/DC is functionally the same as the one used in the ANX refer to AN Power Supply (Section 10.1.5) for its description.

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10.5.4 ANB LEDs and Alarms This section provides information on the ANB’s LEDs and Alarms. There are four LEDs on the front panel, which provide a visual indication of the operational status of the ANB module. As the LEDs functionality is the same as in ANC refer to ANC/ANB LED Descriptions for its description. The ANB detects the alarm conditions shown in Table ANX/ANC/AGC/ANB Alarm Conditions (81).

10.5.5 ANB Performance Characteristics The performance characteristics of the ANBs are shown in the following table. Parameter

GSM 900

GSM 1800

Transmit band.

925 - 960 MHz

1805 - 1880 MHz

Receive band.

880 - 915 MHz

1710 - 1785 MHz

Power for each transmitter channel input.

63 W maximum

63 W maximum

Number of channels.

174

374

Bandwidth for each channel.

200 kHz

200 kHz

Return loss at receive port.

> 16 dB

> 16 dB

Return loss at transmit port.

> 16 dB

> 16 dB

Return loss at antenna port.

> 16 dB 1)

> 16 dB

Return loss at coupler port.

> 18 dB

≥ 18 dB

Group delay distortion in transmit band.

≤100 ns

≤ 100 ns

Isolation between receive port and antenna port.

>30 dB

>30 dB

Isolation between receive ports.

>20 dB

>20 dB

Isolation between transmit ports (A to B/ 1 to 2).

>50 dB/ 22 dB

>50 dB/ 22 dB

Insertion loss in transmit pass band.

0.3 - 1.6 dB

< 0.3 - 1.6 dB

Intermodulation products at antenna port with 2x 20 W signals at one transmit port and 50 on receive port in receive band.

<-101 dBm

<-101 dBm

Intermodulation products at antenna port with 2x 20 W signals at one transmit port and 50 on receive port in transmit band.

<-75 dBc

<-75 dBc

RF input impedance.

50

50

RF output impedance.

50

50

1) For ANB with bridge: >16 dB. Table 98: ANB Performance Characteristics

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10.5.6 ANB Front Panel The following figures show the layout and O and M features of the two versions of the ANB front panel.

10.5.6.1 ANB Front Panel - Version 1 Camloc Fasteners

Transmitter Input Connector RX1AOUT1 RX0AOUT1

TXAIN VSWRB ALARM

ANTB

High Voltage Warning

Antenna Connector ANTA Module Extractor

LEDs

TXBIN

O&M VSWRA

Receiver Connectors

RX0BOUT1 RX1BOUT1

Figure 339: ANB Front Panel Version 1

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10.5.6.2 ANB Front Panel - Version 2 Camloc Fasteners

Transmitter Input Connector RX1AOUT1 RX0AOUT1

VSWRB ALARM TXAIN

Antenna Connector

ANTA

ANTB

High Voltage Warning

Transmitter Input Connector TXBIN

Module Extractor

LEDs

O&M VSWRA

Receiver Connectors

RX0BOUT1 RX1BOUT1

Figure 340: ANB Front Panel Version 2

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10.5.6.3 Connectors The ANB has two transmitter input connectors and four receiver output connectors on its front panel. Therefore, one ANB module can be interfaced to two TRE modules or two ANY modules, if used. The following table describes the ANB front panel connectors. Connector

Description

TXAIN

Provide the RF transmitter interfaces from two TRE modules or two ANY modules, if used.

TXBIN RX0AOUT1 RX1AOUT1 RX0AOUT2 RX1AOUT2 RX0BOUT1 RX1BOUT1 RX0BOUT2 RX1BOUT2 ANTA ANTB

Provide the RF receiver interfaces between antenna A and the first TRE receiver connectors RX0 and RX1. Provide the RF receiver interfaces between antenna A and the second TRE receiver connectors RX0 and RX1. Provide the RF receiver interfaces between antenna B and the third TRE receiver connectors RX0 and RX1. Provide the RF receiver interfaces between antenna B and the fourth TRE receiver connectors RX0 and RX1. Provide the RF interface to/ from two antennas, A and B.

Table 99: ANB Front Panel Connectors The front panel connector types are described in the following table. ANTA, ANTB

7/ 16

TXAIN, TXBIN

N female

All RXnnOUT

SMB male

Table 100: ANB, Front Panel Connector Types

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10.6 GSM/UMTS Co-Siting GSM cabinets and UMTS cabinets can be installed at the same site. Normally all antenna feeder cables between antennas (A and B) and BTSs have to be installed separately for GSM and UMTS as shown in the following figure. Separate Antenna Feeders A + B for GSM and UMTS

GSM Antennas A+B

AB

AB

ANCx

ANRU

BTS

Node B

GSM 850/900/1800

UMTS

UMTS Antennas A+B

Figure 341: GSM/UMTS Co-Siting With the help of diplexer filters at both ends of the feeder cables, the GSM (850/900/1800) band and the UMTS band can be decoupled in order to use the same feeder cable for both services. The following figure shows the principle. Double−Diplexer

Diplexer B Antennas A + B GSM

Diplexer A

Antennas A + B UMTS

Diplexer Double−Diplexer AB

AB

ANCx

ANRU

BTS

Node B

GSM 850/900/1800

UMTS

Common Antenna Feeders

Figure 342: GSM/UMTS Co-Siting with Diplexers and Common Feeders

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10.6.1 Diplexer Functional Description The following figure shows the block diagram of the diplexer. The base station feeder cable of the GSM and UMTS part is connected to the according BTS port of the diplexer. The signal passes the bandpath filter of the diplexer and is available at the antenna connector. Antenna

Diplexer

GSM Bandpath

GSM BTS

UMTS Bandpath

TMA BIAS Circuit

UMTS BTS

Figure 343: Diplexer, Block Diagram The insertion losses of the filters are as low as possible to achieve the best noise figures in the uplink and low attenuation in the TX downlink. GSM and UMTS bandpath filters provide following features: Suppression of spurious and noise signals from the transmitter(s) out of band Suppression of intermodulation product(s) Rejection of harmonics of the transmitter(s) Isolation of the UMTS branch (GSM part) or GSM branch (UMTS part). The following table shows the out-of-band attenuations of the diplexer filters. Filter

Frequency (MHz)

Attenuation

Remark

GSM 850

1920 - 2170

>60 dB

UMTS Band

824 - 960

>60 dB

GSM 850 Band

GSM 900 GSM 1800 UMTS

GSM 900 Band UMTS

1710 - 1880

>60 dB

GSM 1800 Band

Table 101: Diplexer Filters Out-of-Band Attenuations

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The UMTS branch is additionally equipped with a Tower Mounted Amplifier (TMA) BIAS circuit. This BIAS circuit allows the DC power supply (12 VDC) of a TMA using the RF feeder cable. The appropriate power distribution unit (PDU) is part of the ANRU module. The GSM part of the diplexer is decoupled from the UMTS BIAS circuit part. If both branches (GSM and UMTS) are equipped with a tower mounted amplifier, this external diplexer cannot be used. Then all necessary equipment of a TMA (inclusive of feeders) has to be installed twice.

10.6.2 Diplexer Mechanical Design The external diplexers are designed for indoor and outdoor applications. They are fully purchased items. Therefore mechanical design, dimensions and weight depend on the selected manufacturer and cannot be described here in detail. Moreover there are additional differences in dimensions between GSM 850/900/UMTS and GSM 1800/UMTS diplexers, depending on the frequencies used. The following figure shows a GSM 1800 (DCS)/UMTS double-diplexer (for antennas A and B) as an example.

Side View

RF Connector DCS

ANT

UMTS Ground Connector

DCS

UMTS

ANT

Mounting Flanges (with holes)

Bottom View

Figure 344: Diplexer, Mechanical Design (Example) The diplexer has six RF connectors (7/16 female) for connecting GSM BTS, UMTS BTS and antennas. A ground connector is available to connect the diplexer to ground. Two mounting flanges are used to fix the diplexer to immobile equipment near the BTSs.

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10.6.3 Environmental Conditions The external diplexer housings provide the necessary environmental and safety protection according to the standard ETS 300 019 -1-4 class 4.1E. The minimum ambient temperature is -45 C, humidity up to 100 % at + 38 C. Earthquake is according to ETS 300 019 -2-3.

10.6.4 EMC Requirements The EMC requirements are derived from ETS 300 342-3/phase 2, TS 25.104 and EN 55022.

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11 Temperature Control The sections are supported with diagrams, if necessary. Illustrations of the FANU and FACB are also included.

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11.1 Cooling System The BTS A9100 is equipped with a forced-air cooling system. Depending on the BTS A9100 variant the cooling system may consist of up to three RITs; see the following figure. The three RITs are: FANU FACB TFBP. TFBP FANU

FACB

Ribbon Cable Connectors Subrack Backplane

FACB FANU

Figure 345: Cooling System Components A FANU consists of a moulded-plastic frame containing two fan blowers (see Figure 347). The FANU is connected to the TFBP or subrack backplane. Three FANUs are controlled by one FACB. The FACB monitors the fans and provides power and digital speed control of the FANUs. The FACB is fitted on a TFBP or a subrack backplane, as required. A special case exists where two FANUs are fitted as a pair below the ACSR used in BTS A9100 outdoor configurations. These two FANUs are controlled by the BCU2 contained in the ACSR. The BCU2 monitors the fans and provides power and digital speed control of the FANUs. A feature of the cooling system is its ability to control the front and back rows of fans, independently of each other (see Figure 348). This enables the temperature inside the cabinet to be regulated more precisely. It also extends the life of the fans and keeps noise levels to a minimum.

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11.1.1 Fan Units The FANUs are usually installed in groups of three. The exception is where they are fitted as a pair below the ACSR used in variant 2 of the BTS A9100 outdoor configurations. The FANUs are normally situated below the subracks containing TREs. Additional FANUs can be installed at the top of the equipment rack; see the following figure. EBCB (optional)

DC

IN

ALARM INPUTS

EXT − ALARMS

External

Output Interface Group

XBCB

SUN CONNECTION

ALARM OUTPUTS

Input/

SIDE COMPARTMENT ALARMS

External Input/

XRT

Output Interface

XGPS

COMPARTMENT 1 ALARMS

Group

ABIS4

XCLK 2 IN/ OUT

External Clock

XCLK 1 IN

ABIS3

Interface

ABIS 3&4

Interface Group

Interface Group ABIS1

ABIS 1 Remote

Abis

ABIS2

ABIS 1&2

Abis

KRONE CONNECT

XCLK 1 OUT

Group

ABIS 2

FLAT CABLE SIDE COMPARTMENT

Inventory Part FLAT CABLE COMPARTMENT 1

TEMP. SENSOR

RIBAT Port

Figure 346: Subrack Air Circulation The fan blowers are driven by electronically-commutated motors. These are protected against reverse polarity and blocking due to an obstruction in the fan blades. Air is taken from the front of the cabinet and forced through the subracks. The fans force the air in an upwards direction to dissipate the heat generated by the subrack modules (mainly the TREs). The FANUs at the top of the rack assist air flow by pulling the air through the rack and expelling it through grills at the top of the cabinet. Dummy panels are used to fill the FANU positions that are not equipped (indoor racks). These provide an air outlet at the back of the subrack.

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11.1.1.1 FANU Appearance The FANU consists of a moulded-plastic frame for mounting the two fan blowers. The fan blowers are manufactured from fiberglass reinforced plastic. They are fixed in the moulded-plastic frame with a simple snap-in mechanism. The FANUs are inserted in guide rails, at the bottom of the subrack, and locked in position with a latch. The electrical connection is achieved with a connector, fitted to the rear of the FANU, which plugs-in to the subrack backplane. The following figure shows a three-dimensional image of the FANU. Blowers

Power Connector

Latch

Handle

Guide Rails

Figure 347: FANU

11.1.1.2 Fan Blower Operational Parameters The following table lists the operational parameters for the fan blowers. Parameter

Description

Type:

PAPST 4318/2, version 113

Max. air flow:

170 m / h

Acoustic noise:

<45 dB

Operating voltage:

20 VDC to 40 VDC

3

Table 102: Fan Blower Unit Operating Parameters

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11.1.2 Fan Control The principal function of the FACB is to control the fan speed of the front and back rows of fans, independently of each other. Each FACB controls three FANUs. The BCU2 performs the functions of the FACB in the special case of a pair of FANUs fitted below the ACSR used in variant 2 of the BTS A9100 outdoor configurations. The FACB has the following functionality: Performs control and supervision of the fans Detects the fan module and its date of manufacture Supplies power to the fans Provides an interface to the BCB. The following figure shows the FACB architecture in block diagram form. −38 VDC to −72 VDC

Fuse

Filtering and Surge Limiting

RI EEPROM

DC/DC Converter (Front Row)

Input Voltage Monitoring

20 VDC to 40 VDC

Regulator

FANUs BCB Interface

Voltage Monitor and Limiter

FACB Controller Backplane Address

Front Row Fans

Back Row Fans

Fan Speed

Regulator

DC/DC Converter (Back Row)

20 VDC to 40 VDC

Figure 348: FACB Architecture The FACB activates the fans within the temperature range: -40 C to + 70 C. However, at very low temperatures, in the range -40 C to -10 C, the fans operate without digital speed control.

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11.1.2.1 FACE Functional Entities The FACB consists of the functional entities described in the following table. FACB Controller

The controller is responsible for the following interfaces: I/O for the BCB Backplane address Date of FANU manufacture Fan speed control output Remote on/off switching RI EEPROM.

BCB Interface

All OMU messages, such as fan alarms, are communicated via the BCB interface. The BCB also provides an interface to the Remote Inventory EEPROM, via the FACB controller.

RI EEPROM

The Remote Inventory EEPROM stores information about the FACB.

Power Supply

The FANU power supply consist of two on-board DC/DC converters. These provide power independently for the front and back rows of fans. The DC/DC converters operate on an input voltage in the range -38 VDC to -72 VDC. This is converted to a variable output in the range + 20 VDC to + 40 VDC. The input to the FACB DC/DC converters is protected from accidental reverse polarity, transient voltages and surges.

Fan Speed Control

The output of the DC/DC converters is monitored and dynamically regulated by the FACB controller PWM techniques. A square wave output signal from the fans indicates rotational speed of the fans. The PWM signal is used to control the fan speed.

Table 103: FACB Functional Entities

11.1.2.2 Fuse The input of the FACB is protected by a fuse with a high breaking capacity (3.5 A).

11.1.2.3 Date Coding Three pins on the FANU connector are hard-wired to provide a fixed code for the year of manufacture. The code is read from the FACB controller.

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11.1.2.4 Remote Switching The front and back row DC/DC converters can be remotely switched on and off, independently of each other. The fan speeds for each row can also be adjusted. This function is implemented by the OMU, via the BCB Interface to the FACB.

11.1.2.5 FACB Appearance The FACB is a small PCB which is fitted to the STASR backplane between the third and fourth module connectors (see Figure 283). The following figure shows the layout of the FACB; only the principle components are marked. The layout is shown so that the FACB can be easily identified. Connector

Connector

Controller

Figure 349: FACB Component Layout

11.1.2.6 Alarms Two independent fan alarms, for the front and back rows, can be raised under the control of the FACB. An alarm is raised when a fan-related output voltage is out of tolerance. The following table lists the voltage threshold-tolerances before an alarm is raised. Voltage

Threshold Min.

Threshold Max.

U Front

13 V

20 V

U Back

13 V

20 V

Table 104: Alarm Threshold Voltages

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11.1.3 Top Fan Unit In some BTS A9100 variants, additional FANUs at the top of the cabinet assist the air circulation. They are connected to the TFBP, which provides the electrical and signaling interface between the FANUs and the FACB. The TFBP is mounted at the top of the cabinet, on the rear wall. It is powered from a -48/ -60 VDC external power source, via the cabinet bus bar. The following figure shows the TFBP connector layout. FANU Connectors

Connector Identity

X110

X112

X111

X117

Equipment Label

X116

FACB

X113

0V Ribbon Cable Connector

Ground −48 VDC

X100

Pin 1, Row A

Figure 350: TFBP Connector Layout The following table lists and describes the TFBP connectors. Connector

Type

Description

X110, X111, X112

R 1/3, male

FANU Connectors

X116

2 x 6-pin Header, male

X117

2 x 16-pin Header, male

The FACB connectors are linked to the FANU connectors via the TFBP printed wiring.

X100

C 64 M DIN 41612, male

Ribbon Cable

X113

3 x FASTON

Power

Table 105: TFBP Connectors

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11.2 HEX2 HEX2 is used in outdoor BTS A9100 versions. It maintains the correct air environment within the cabinets. The airflow within the cabinets is isolated from the outside environment. HEX2 is mounted on the inside of the compartment door. It cools the internal air by transferring heat to the outside environment. The following figure shows the main components of HEX2. Temperature Sensor

Air Outlet

HEX2 Inner Fans Warm Air Inlet

Warm Air Inlet Air Outlet

HEX2

Heat Sink Cassette

HEX2 Mounting on Alternative Cabinet Door

Door Outer Compartment Subrack

Subrack

Inner Compartment

FANU

FANU Outer Fans

Cool Air Outlet

Cool Air Outlet Air Inlet

HEX2 Control Box

Air Inlet

Figure 351: HEX2 Main Components HEX2 is a box which is divided into inner and outer compartments by a heat sink cassette. Warm air from inside the cabinet is drawn into the inner compartment by the inner fans. It is then blown past the heat sink cassette and returned to the cabinet as cool air. The heat gathered in the heat sink cassette is transferred to the outside environment by the air stream in the outer compartment. The outside air is drawn into the outer compartment by the outer fans. The fan controller is contained in a control box. When the internal temperature reaches 20 C, the inner fans switch on and operate at minimum speed. When the internal temperature reaches 30 C, the outer fans switch on and also operate at minimum speed. As the temperature rises further, fan speed increases for both the inner and outer fans. If the temperature sensor fails or is disconnected, all fans operate at maximum speed and an alarm is raised.

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11.2.1 LED(s) There are three versions of HEX2, two with only one LED and another one with four LEDs, where the reason for the alarm is shown in more detail (but only on the module itself): Versions with one LED (versions ADAC, ADCA) There is one LED on the front of the control box. It illuminates when there is an alarm Version with four LEDs (version ADBA) There are the following four LEDs on the module: High/Low Temp: Temperature sensor failure, inside temperature above 70 C or below -60 C Heater: Heater failure (not used; not correlated to HEAT2) Ext. Fan: External fan failure Int. Fan: Internal fan failure. But the alarm raised by HEX2 is only an accumulative alarm.

11.2.2 Alarms HEX2 raises an alarm when: A fan fails The temperature sensor is disconnected The controller is faulty The internal temperature reaches 70 C.

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11.2.3 Appearance The following figure shows the front and the two possible rear views of HEX2.

Equipment Labels Air Outlet

Temperature Sensor Connector LEDs: LED

High/Low Temp

Fan Cables

Fan

Heater

Control Box

Ext. Fan

Alarm Connector

Int. Fan

DC Connector Rear Side (Version ADCA) *)

Door Side

Rear Side (Version ADBA)

*) Version ADCA has only the left fan and internal cabling

Figure 352: HEX2 Appearance

11.2.4 Connectors The following table describes the HEX2 control box connectors. Connector

Type

Description

DC Connector

9-pin Sub-D male

48 VDC power in.

Alarm Connector

9-pin Sub-D female

Alarm out.

Table 106: HEX2 Front Panel Connectors

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11.3 HEX3/HEX4 HEX3 and HEX4 are used in Multistandard BTS outdoor versions. They maintain the correct air environment within the cabinets. Fresh air cooling is not allowed in the outdoor BTSs. Therefore the airflow within the cabinets is isolated from the outside environment. HEX4 is mounted on the inside of the MBO1 door, HEX3 is mounted on the inside of the MBOE door. They cool the internal air by transferring heat to the outside environment. The following figure shows the main components of HEX3 and HEX4. Temperature Sensor

Air Outlet

HEX3/4

Inner Fan

Warm Air Inlet

HEX2

Heat Sink Cassette Door

Outer Compartment Subrack Inner Compartment FANU Outer Fan

Cool Air Outlet

Air Inlet

Figure 353: HEX3/HEX4 Main Components HEX3 and HEX4 are boxes which are divided into inner and outer circuits by a heat sink cassette (core). The core consists of thermal conductive material allowing heat exchange between both circuits. The air is circulated by one blower in each circuit. Warm air from inside the cabinet is drawn into the inner compartment by the inner fan. It is then blown past the heat sink cassette and returned to the cabinet as cool air. The heat gathered in the heat sink cassette is transferred to the outside environment by the air stream in the outer compartment. The outside air is drawn into the outer compartment by the outer fan.

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11.3.1 Blower Rotation Control The temperature-controlled regulation of blower rotation is contained in a control unit which is assembled inside an inner circuit. The inner and outer blower are independent of each other. The control of blowers is an internal function of the heat exchanger. When the internal temperature reaches 20 C, the inner fans switch on and operate at minimum speed. When the internal temperature reaches 30 C, the outer fans switch on and also operate at minimum speed. As the temperature rises further, fan speed increases for both the inner and outer fans. After switch-on, the blower speed accelerates continuously up to the maximum specified rotation. Then the speed is regulated down to the specified ramp.

11.3.2 Temperature Sensor The temperature sensor is mounted in the heat exchanger at the air inlet of the inner circuit. Failure of the temperature sensor (e.g., sensor disconnected or short circuited) causes the following response: All blowers are rotating at full specified speed Alarm occurs, red LED is lit. The response can be delayed up to 5 seconds after the failure occurs.

11.3.3 Alarm There is one alarm output per heat exchanger. An alarm is raised when: At least one blower fails Temperature sensor/plug disconnected or short circuited The controller is faulty Temperature exceeds 70 C Temperature drops below -60 C (sensor failure). The response can be delayed up to 5 seconds after the failure occurs.

11.3.4 LED An alarm indication is implemented by means of a visible red LED located on the lid (inner circuit side). The red LED is lit in case of an alarm.

11.3.5 Test Port The test port allows the connection of an external temperature simulator (variable resistor) setting a temperature value to check the blower operation depending on the temperature.

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11.3.6 Appearance The following figure shows the front and the rear views of the HEX3/HEX4. Note that the HEX3 and HEX4 only differ in width and weight. Door Side

Front Side DCand Alarm Connector Fan

LED Test Connector

Air Outlet*

Equipment Labels Air Inlet (Protected with grid)

Air Inlet*

Air Outlet (Protected with grid if necessary)

Water Outlet

Fan

Guiding tubes for fixing bolts

* Grid not necessary

Figure 354: HEX3/HEX4 Appearance

11.3.7 Connectors The following table describes the HEX3/HEX4 connectors. Connector

Type

Description

DC and Alarm Connector

9-pin Sub-D male

48 VDC power in (fuse T6.3 A) Alarm out.

Test Connector

9-pin Sub-D female

Connection of external temperature simulator.

Table 107: HEX3/HEX4 Connectors

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11.3.8 Mechanical Parameters The following table lists the mechanical parameters of the HEX3/HEX4. Parameter

HEX3

HEX4

Height (mm)

1150

1150

Width (mm)

450

600

Depth (mm)

150

150

Weight (kg)

24

28

Table 108: HEX3/HEX4 Mechanical Parameters

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11.4 HEX5 HEX5 is used in Compact BTS Outdoor (CBO) versions. It maintains the correct air environment within the cabinets. Fresh air cooling is not allowed in the outdoor BTSs. Therefore the air flow within the cabinets is isolated from the outside environment. HEX5 is mounted on the inside of the CBO door. It cools the internal air by transferring heat to the outside environment. The following figure shows the main components of HEX5. Temperature Sensor

Air Outlet

HEX5

Inner Fan

Warm Air Inlet

HEX2

Cooling Core Door

Outer Compartment Inner Compartment

Outer Fan

1234 1234 1234 1234 1234 1234 1234 1234 1234 1234

Subrack

FANU Cool Air Outlet

Air Inlet

Figure 355: HEX5 Main Components HEX5 is a box which is divided into inner and outer circuits by a heat sink cassette (core). The core consists of thermal conductive material allowing heat exchange between both circuits. The air is circulated by one blower in each circuit. Warm air from inside the cabinet is drawn into the inner compartment by the inner fan. It is then blown past the heat sink cassette and returned to the cabinet as cool air. The heat gathered in the heat sink cassette is transferred to the outside environment by the air stream in the outer compartment. The outside air is drawn into the outer compartment by the outer fan.

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11.4.1 Blower Rotation Control The temperature-controlled regulation of blower rotation is contained within a control unit which is assembled inside the inner circuit. The inner and outer blower are independent of each other. The control of the blowers is an internal function of the heat exchanger. When the internal temperature reaches 20 C, the inner fans switch on and operate at minimum speed. When the internal temperature reaches 30 C, the outer fans switch on and also operate at minimum speed. As the temperature rises further, fan speed increases for both the inner and outer fans. After switch-on, the blower speed accelerates continuously up to the maximum specified rotation. Then the speed is regulated down to the specified ramp.

11.4.2 Temperature Sensor The temperature sensor is mounted in the heat exchanger at the air inlet of inner circuit. Failure of the temperature sensor (e.g., sensor disconnected or short circuited) causes the following response: All blowers are rotating at full specified speed Alarm occurs, red LED is lit flashing. The response can be delayed up to 15 seconds. after the failure occurs.

11.4.3 Alarm There is one alarm output per heat exchanger. An alarm is raised when: At least one blower fails Temperature sensor/plug disconnected or short circuited The controller is faulty Temperature exceeds 70 C Temperature drops below -60 C (sensor failure). The response can be delayed up to 15 seconds. after the failure occurs.

11.4.4 LED An alarm indication is implemented by means of a visible red LED located on the lid (inner circuit side): The red LED is lit flashing in case of a temperature/temperature sensor alarm The red LED is lit continuously in case of a fan alarm.

11.4.5 Test Port The test port allows the connection of an external temperature simulator (variable resistor) setting a temperature value to check the blower operation depending on the temperature.

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11.4.6 Appearance The following figure shows the front and the rear views of HEX5. Rear Side

Door Side

Air Intlet

Air Outlet

Grill Guard Equipment Labels

DC and Alarm Connector Test Connector

Air Outlet

Air Intlet

Water Outlet

Figure 356: HEX5 Appearance

11.4.7 Connectors The following table describes the HEX5 connectors. Connector

Type

Description

DC and Alarm Connector

9-pin Sub-D male

48 VDC power in (fuse T6.3 A) Alarm out.

Test Connector

9-pin Sub-D female

Connection of external temperature simulator.

Table 109: HEX5 Connectors

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11.4.8 Mechanical Parameters The following table lists the mechanical parameters of the HEX5. Parameter

HEX5

Height (mm)

800

Width (mm)

450

Depth (mm)

130

Weight (kg)

13

Table 110: HEX5 Mechanical Parameters

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11.5 HEX8/HEX9 HEX8 and HEX9 are used in Multistandard BTS Evolution outdoor versions. They maintain the correct air environment within the cabinets. Fresh air cooling is not allowed in the outdoor BTSs. Therefore the airflow within the cabinets is isolated from the outside environment. HEX9 is mounted on the inside of the MBO1E door, HEX8 is mounted on the inside of the MBOEE door. They cool the internal air by transferring heat to the outside environment. The following figure shows the main components of HEX8 and HEX9. Temperature Sensor

Air Outlet

HEX8/9

Inner Fan

Warm Air Inlet

HEX2

Heat Sink Cassette Door

Outer Compartment Subrack Inner Compartment FANU Outer Fan

Cool Air Outlet

Air Inlet

Figure 357: HEX8/HEX9 Main Components HEX8 and HEX9 are boxes which are divided into inner and outer circuits by a heat sink cassette (core). The core consists of thermal conductive material allowing heat exchange between both circuits. The air is circulated by one blower in each circuit. Warm air from inside the cabinet is drawn into the inner compartment by the inner fan. It is then blown past the heat sink cassette and returned to the cabinet as cool air. The heat gathered in the heat sink cassette is transferred to the outside environment by the air stream in the outer compartment. The outside air is drawn into the outer compartment by the outer fan.

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11.5.1 Blower Rotation Control The temperature-controlled regulation of blower rotation is contained in a control unit which is assembled inside an inner circuit. The inner and outer blower are independent of each other. The control of blowers is an internal function of the heat exchanger. When the internal temperature reaches 20 C, the inner fans switch on and operate at minimum speed. When the internal temperature reaches 30 C, the outer fans switch on and also operate at minimum speed. As the temperature rises further, fan speed increases for both the inner and outer fans. After switch-on, the blower speed accelerates continuously up to the maximum specified rotation. Then the speed is regulated down to the specified ramp.

11.5.2 Temperature Sensor The temperature sensor is mounted in the heat exchanger at the air inlet of the inner circuit. Failure of the temperature sensor (e.g., sensor disconnected or short circuited) causes the following response: All blowers are rotating at full specified speed Alarm occurs, red LED is lit. The response can be delayed up to 5 seconds after the failure occurs.

11.5.3 Alarm There is one alarm output per heat exchanger. An alarm is raised when: At least one blower fails Temperature sensor/plug disconnected or short circuited The controller is faulty Temperature exceeds 70 C Temperature drops below -60 C (sensor failure). The response can be delayed up to 5 seconds after the failure occurs.

11.5.4 LED An alarm indication is implemented by means of a visible red LED located on the lid (inner circuit side). The red LED is lit in case of an alarm.

11.5.5 Test Port The test port allows the connection of an external temperature simulator (variable resistor) setting a temperature value to check the blower operation depending on the temperature.

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11.5.6 Appearance The following figure shows the front and the rear views of the HEX8/HEX9. Note that the HEX8 and HEX9 only differ in width and weight. Door Side

Front Side DCand Alarm Connector Fan

LED Test Connector

Air Outlet*

Equipment Labels Air Inlet (Protected with grid)

Air Inlet*

Air Outlet (Protected with grid if necessary)

Water Outlet

Fan

Guiding tubes for fixing bolts

* Grid not necessary

Figure 358: HEX8/HEX9 Appearance

11.5.7 Connectors The following table describes the HEX8/HEX9 connectors. Connector

Type

Description

DC and Alarm Connector

9-pin Sub-D male

48 VDC power in (fuse T6.3 A) Alarm out.

Test Connector

9-pin Sub-D female

Connection of external temperature simulator.

Table 111: HEX8/HEX9 Connectors

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11.5.8 Mechanical Parameters The following table lists the mechanical parameters of the HEX3/HEX4. Parameter

HEX8

HEX9

Height (mm)

1250

1250

Width (mm)

450

600

Depth (mm)

150

150

Weight (kg)

24

28

Table 112: HEX8/HEX9 Mechanical Parameters

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11.6 DAC8/DAC9 DAC8 and DAC9 are used in Multistandard BTS Evolution outdoor versions. They maintain the correct air environment within the cabinets using fresh air cooling. DAC9 is mounted on the inside of the MBO1E door, DAC8 is mounted on the inside of the MBOEE door. They cool the internal air by transferring heat to the outside environment. The following figure shows the main components of DAC8 and DAC9.

Air Outlet

DAC8/9

Air Outlet with Filter Mat and Grid

Subrack

FANU

Fan

FANU

Subrack

Door Air Inlet with Filter Mat

FANU

FANU

Fresh Air Channel

Fan

Subrack

FANU

FANU

Air Inlet

Figure 359: DAC8/DAC9 Main Components The DAC8 and DAC9 consists of metal boxes with an air inlet and an air outlet in the front side as shown in Figure 359. In these cut-outs filter mats are mounted. Compared to HEX system, where the air inside of the cabinet is separated from ambient air, the DAC system uses fresh air to cool the equipment inside of the cabinet. The ambient air is drawn by fans through the hydrophobic filter mat and blown into the BTS through cut-outs directly below the subracks. There it arises to the top of the BTS and leaves it by the air outlet. The air outlet is protected against intrusion of water and insects by a filter mat and an additional fly screen.

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11.6.1 Blower Rotation Control The temperature-controlled regulation of blower rotation is contained in a control unit which is assembled inside an inner circuit. The control of blowers is an internal function of the direct air cooling module. When the internal temperature reaches 30 C, the fans switch ON and operate at 1500 rpm speed. When the internal temperature reaches 35 C and is below 55  C the fan speed increases linearly up to 2500 rpm. As the temperature rises further, fan speed increases up to maximum speed of 2900 rpm.

11.6.2 Temperature Sensor The temperature sensor is mounted on the controller PBA. Failure of the temperature sensor (e.g., sensor disconnected or short circuited) causes the following response: All blowers are rotating at full specified speed Alarm occurs, red LED is lit. The response can be delayed up to 15 seconds after the failure occurs.

11.6.3 Filter Mats The inlet filter is a cassette consisting of a frame mounted on the door containing a filter mat. The filter mat is made of hydrophobic material but not gas proof. The outlet fleece filter mat is additional protected by a fly screen.

11.6.4 Alarm There is one alarm output per cooling unit. An alarm is raised when: At least one blower fails Temperature sensor/plug disconnected or short circuited The controller is faulty Temperature exceeds 70 C Temperature drops below -60 C (sensor failure). The response can be delayed up to 15 seconds after the failure occurs.

11.6.5 LED An alarm indication is implemented by means of a visible red LED located on the lid (inner circuit side). The red LED is lit in case of an alarm.

11.6.6 Test Port The test port allows the connection of an external temperature simulator (variable resistor) setting a temperature value to check the blower operation depending on the temperature.

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11.6.7 RS232 The RS232 port allows the connection of an external terminal to readout the fan speed..

11.6.8 Appearance The following figure shows the front and the rear views of the DAC8/DAC9. Note that the DAC8 and HEX9 only differ in width and weight. Door Side

Front Side DC and Alarm Connector

Air Outlet with Filter Mat and Grid

RS232 LED Test Connector

Equipment Labels

Air Outlet

Fan

Air Inlet with Filter Mat

Air Outlet Air Barrier Air Outlet

Fan

Air Outlet

Figure 360: DAC8/DAC9 Appearance

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11.6.9 Connectors The following table describes the DAC8/DAC9 connectors. Connector

Type

Description

DC and Alarm Connector

9-pin Sub-D male

48 VDC power in (fuse T6.3 A) Alarm out.

Temperature and Test Connector

9-pin Sub-D female

Connection of external temperature simulator.

RS232

RJ45

For readout the fan speed.

Table 113: DAC8/DAC9 Connectors

11.6.10 Mechanical Parameters The following table lists the mechanical parameters of the DAC8/DAC9. Parameter

DAC8

DAC9

Height (mm)

1229

1229

Width (mm)

449

600

Depth (mm)

150

150

Weight (kg)

18

22

Table 114: DAC8/DAC9 Mechanical Parameters

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11.7 HEAT2 HEAT2 is an electrical air heater used in outdoor BTS A9100 versions. It switches on automatically when the internal air temperature falls below a predefined value. HEAT2 is an electro-mechanical assembly fitted to the floor, the side wall or beneath the HEX4 (MBO1) of each compartment in the outdoor BTS A9100. The following figure shows the circuit schematic. Internal Thermostat External Thermostat

10

Fan

AA Variant: 600 W CA Variant: 950 W Heater

X1

X2 (Variant AA only)

Figure 361: HEAT2 Circuit Schematic The 230 VAC supply enters HEAT2 at connector X1. From there it is routed to the heater and fan (via connector X2 in case of variant AA). If, in case of variant AA, another HEAT2 is fitted, its AC supply is provided by the socket which is part of connector X2. The external thermostat closes a switch when the temperature is below 10 C. The switch completes the circuit for the AC supply to the heater and fan. The fan blows air through the heating elements of the heater. The heater is protected by an internal thermostat. If the temperature of the heater assembly exceeds 90 C, the thermostat within the heater assembly opens a switch. This breaks the AC circuit to the heater elements.

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11.7.1 Appearance The HEAT2 has two variants: variant AA and variant CA. Each variant is shown separately.

11.7.1.1 Variant AA The following figure shows the side and top views of HEAT2 variant AA. Heater Assembly External Thermostat

Connector X2 Fan

Connector X1

Side View

Grille Screw

Temperature Adjuster

Top View

Figure 362: HEAT2 Variant AA Appearance

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11.7.1.2 Variant CA The following figure shows the side and top view of HEAT2 variant CA. Grid Connector X1 Heater

Fan Thermostat (Thermostat fixed at 10 oC with safety varnish) Angle

Side View Connection Cable L = 800 m

Connection Area

Label High Voltage DIN/ ISO 3864 (Size 20 mm)

Equipment Labels

Top View

Figure 363: HEAT2 Variant CA

11.7.2 Connectors The following table describes the HEAT2 connectors. Connector

Description

X1

Provides the 230 VAC input.

X2 (Variant AA only)

Provides the 230 VAC source for a second, optional HEAT2.

Table 115: HEAT2 Connectors

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11.8 HEAT3 HEAT3 is an electrical air heater used in outdoor BTS Compact versions. It switches on automatically when the internal air temperature falls below a predefined value. HEAT3 is an electrical assembly fitted between the bottom plate of the Compact BTS Outdoor and the lowest subrack. The following figure shows the circuit schematic. Integral Temperature Limiter

External Thermostat

10 °C 500 W

Heater

X1 L PE N

Figure 364: HEAT3 Circuit Schematic The 230 VAC supply enters HEAT3 at connector X1. The external thermostat closes a switch when the temperature is below 10 C. The switch completes the circuit for the AC supply to the heater. The heater is protected by an internal thermostat. If the temperature of the heater assembly exceeds 70 C, the thermostat within the heater assembly opens a switch. This breaks the AC circuit to the heater elements.

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11.8.1 Appearance The following figure shows the side and top views of HEAT3.

Connector X1

Heater Plate

Heating Mat

Labels

Figure 365: HEAT3 Appearance

11.8.2 Connectors The following table describes the HEAT3 connectors. Connector

Description

X1

Provides the 230 VAC input.

Table 116: HEAT3 Connectors

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11.9 HEAT4 HEAT4 is an electrical air heater used in outdoor BTS Compact versions. It switches on automatically when the internal air temperature falls below a predefined value. HEAT4 is an electrical assembly fitted between the bottom plate of the Compact BTS Outdoor and the lowest subrack. The following figure shows the circuit schematic.

Figure 366: HEAT4 Circuit Schematic The -48 VDC supply enters HEAT4 at power connector. The external thermostat closes a switch when the temperature is below 10 C. The switch completes the circuit for the DC supply to the heater. The heater is protected by an internal thermostat. If the temperature of the heater assembly exceeds 70 C, the thermostat within the heater assembly opens a switch. This breaks the DC circuit to the heater elements.

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11.9.1 Appearance The following figure shows the side and top views of HEAT4. Power Connector

Heating Mat

Heater Plate

Labels

Figure 367: HEAT4 Appearance

11.9.2 Connectors The following table describes the HEAT4 connectors. Connector

Description

Power connector

Provides the -48 VDC input.

Table 117: HEAT4 Connectors

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11.10 HEATDC HEAT DC is an electrical air heater used in DC A9100 MBS GSM outdoor versions. It switches on automatically when the internal air temperature falls below + 10 C. HEAT DC is an electro-mechanical assembly fitted to the side wall or beneath the HEX4 (MBO1) of each compartment in the DC A9100 MBS GSM outdoor. The following figure shows the circuit schematic.

Figure 368: HEAT DC Circuit Schematic The - 48 VDC supply enters HEAT2 at connector X1. From there it is routed to the heater and fan. The external thermostat closes a switch when the temperature is below 10 C. The switch completes the circuit for the DC supply to the heater and fan. The fan blows air through the heating elements of the heater. The heater is protected by an internal temperature limiter in case of fan failure. If the temperature of the heater assembly exceeds 110 C, the temperature limiter opens a switch. This breaks the DC circuit to the heater elements.

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11.10.1 Appearance The following figure shows the side and top views of HEATDC. Grid

Air flow

Heater

Fan Angle

Side View Connector X1

Label Hot Surface DIN/ISO 3864 (Size 20 mm)

Top View

Figure 369: HEATDC Appearance

11.10.2 Connectors The following table describes the HEATDC connectors. Connector

Description

X1

Provides the - 48 VDC input.

Table 118: HEATDC Connectors

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12 Power Supplies and Distribution The sections are supported with diagrams, where necessary, showing the functional blocks and their interfaces. A drawing of the physical appearance of the module is also included, showing the connectors and controls.

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12.1 ACIB The ACIB is used in outdoor BTS A9100 versions. It distributes its AC input to five output connectors. The five output connectors provide the AC power source for the PM08s. The ACIB is housed in the SRACDC. It distributes 230 VAC to the five PM08s. If the temperature in the ACIB falls below a predefined level, the AC supply to the PM08s is automatically switched off. The following figure shows the circuit schematic. Output 1 /3 PE N

PM08/1

L1/L3 PE N

PM08/2

L1/L3 PE N

PM08/3

L1/L2

Input 1 /3

Relay

L1/L3

PE N

PM08/4

L1/L2 L1/L2

PE N

L1/L1

PM08/5

L1/L1 −20 Temperature Sensor

N PE = Permanent Earth

PE

Figure 370: ACIB Circuit Schematic The ACIB input connector is connected to the ACSB where provision is made for 1Ø or 3Ø operation. If the cabinet AC supply is: 230 VAC 1Ø - each of the three live wires in the input connector receives the same, single phase L1. The PM08s connected to the output connectors also receive the phase L1. 400 VAC 3Ø - each of the three live wires in the input connector receives a different phase, L1, L2 or L3. The PM08s connected to the output connectors share the L1, L2 and L3 phases, as shown in the above figure. The AC input is connected to the five AC outputs via a relay which is controlled by a temperature sensor. When the temperature is above -20 C, the AC input is connected to the five AC output connectors. If the temperature is below -20 C when the BTS A9100 is first switched on, there is no AC supply to the PM08s. This means that the 0/ -48 VDC supply is not available and the BTS A9100 cannot operate. However, AC power is available to the HEAT2s. When the HEAT2s raise the internal cabinet temperature above -20 C, the relay is activated and the DC supplies are produced. The HEAT2s prevent the internal cabinet temperature from falling to -20 C thereafter. When the internal cabinet temperature rises above 0 C, the SUMP switches on the telecommunications modules and the BTS A9100 becomes operational.

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12.1.1 Front Panel The following figure shows the front panel of the ACIB. Camloc Fastener

Warning Label

AC In Equipment Labels

5

4

AC Out

3 2

1

Figure 371: ACIB Front Panel

12.1.2 Connectors The following table describes the ACIB front panel connectors. Connector

Description

AC In

Provides a 230 VAC 1Ø or 400 VAC 3Ø input.

AC Out 1- 5

Provides 230 VAC 1Ø outputs for the five PM08s.

Table 119: ACIB Front Panel Connectors

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12.2 LPFC The LPFC is used in Compact BTS Outdoor cabinets. Its functions are: Connection of AC mains to the BTS Lightning protection of the AC mains In Line filtering. The following figure shows the block diagram of the LPFC.

Lightning Protectors

AC Line Filter AC in Terminals L

L

N

N

PE

PE

Metal Box

Bolt M6

Figure 372: LPFC Block Diagram The multistandard BTS outdoor cabinet is supplied with 230 VAC 1 Ø. The LPFC is mounted above the cables entry compartment. The cover of the LPFC has a window which allows checking the lightning protection modules without removing the cover.

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The following figure shows the LPFC top view. AC Out to ACUC

Recess in cover Equipment Labels

Handle

LPFC Cover

AC Mains In

Bolt M8 for GND

Figure 373: LPFC Top View

12.3 LPFMT The LPFMT is used in multistandard BTS outdoor tropical cabinets. Its functions are: Connection of AC mains to the BTS Lightning protection of the AC mains In Line filtering. The following figure shows the block diagram of the LPFMT.

Lightning Protectors

AC Line Filter AC in Terminals

L

L

N

N

PE

PE

Metal Box

Bolt M6

Figure 374: LPFMT Block Diagram The multistandard BTS outdoor cabinet is supplied with 230 VAC 1phase.

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The LPFMT is mounted on the left upper side of the MBO1T cabinet. The cover of the LPFMT has a window which allows checking the lightning protection modules without removing the cover. The following figure shows the LPFMT top view.

L

Recess in cover

INDICATION LIGHTN. PROTECT.

ACout to ACMUT

LPFCT Cover

Information, Equipment and Warning Lables

Bolt M6 for GND

Figure 375: LPFMT Top View

12.4 LPFM The LPFM is used in multistandard BTS outdoor cabinets. Its functions are: Connection of AC mains to the BTS Lightning protection of the AC mains In Line filtering. The following figure shows the block diagram of the LPFM.

Lightning Protectors

AC Line Filter AC in Terminals L3

L3

L2

L2

L1

L1

N

N

PE

PE

Metal Box

Bolt M6

Figure 376: LPFM Block Diagram The multistandard BTS outdoor cabinet can be supplied with 230 VAC 1 Ø or 400 VAC 3Ø. If the cabinet AC supply is: 230 VAC 1 Ø - the three AC In terminals are connected by a bridge, i.e., each of the three live wires receives the same, single phase L1.

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400 VAC 3 Ø - each of the three live wires at the AC In terminals receives a different phase, L1, L2 or L3. The LPFM is mounted on the left upper side of the MBO1 cabinet. The cover of the LPFM has a window which allows checking the lightning protection modules without removing the cover.

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L1

L2

L3

LPFM Cover

Recess in cover

INDICATION LIGHTN. PROTECT.

The following figure shows the LPFM top view. ACout to ACMU

Information, Equipment and Warning Lables

Bolt M6 for GND

Figure 377: LPFM Top View

12.5 LPFU The LPFU is used in outdoor BTS A9100 configurations. Its functions are: Connection of AC mains to the BTS Lightning protection of the AC mains In Line filtering. The following figure shows the block diagram of version AA (three phases).

Lightning Protectors

AC Line Filter AC in Terminals L3

L3

L2

L2

L1

L1

N

N

PE

PE

Metal Box

Bolt M6

Figure 378: LPFU Version AA, Block Diagram The outdoor BTS can be supplied with 230 VAC 1 Ø or 400 VAC 3Ø. If the cabinet AC supply is: 230 VAC 1 Ø - the three AC In terminals are connected by a bridge, i.e., each of the three live wires receives the same, single phase L1 400 VAC 3 Ø - each of the three live wires at the AC In terminals receives a different phase, L1, L2 or L3.

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The following figure shows the LPFU top view with its cover removed. Glands PE N

AC in Terminals

1 2

PG29

3

PG16 L1 Lightning Protectors AC Filter 3 phases

L2 L3 N

Bolt M6

Figure 379: LPFU Version AA, Top View (with Cover Removed)

12.6 ACDUE The AC Distribution Unit is used for MBO1E cabinets. The ACDUE contains: AC cable access in bottom inside the Filter/OVP part 3-phase input (L1, L2, L3, N, PE) AC line filtering Surge protectors Overcurrent protection devices Thermostat. The ACDUE box is divided in two parts: Filter and OVP function in bottom AC-distribution and MCB above.

12.6.1 Technical Charateristics Parameter

ACDUE

Line filtering, rated current

3 x 12 A

Line filtering, leakage current

Max. 4 mA/phase at 230 V

Line filteri damping

30 db at 1 MHz, 70 dB at 10 MHz to 1 GHz

Overcurrent protection devices

4 x 16 A (3 for rectifiers, 1 for heaters) 1 x 10 A (for light and service socket)

AC power switch thermostat

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12.6.2 ACDUE Views

Figure 380: ACDUE Views

12.7 ACMU The ACMU is used in multistandard BTS outdoor configurations. Its functions are: Distribution of the AC input to AC/DC converters, heaters/air conditioning and Service Lights (with AC power sockets) Switching the AC lines to the connected modules by using circuit breakers. The following figure shows the block diagram. N Temperature Sensor N

−20

Circuit Breakers

K1 F5

L1

F4

L2

F3

L3

F2

L2

L1 AC Mains In 3 Phase AC−Mains− Connection

distributed to all modules

to PM12/1

to PM12/2

L2

L3

to PM12/3

to Heat2/Airc.

L3

F1

N

PE

PE

to Service Light and AC Power Socket

distributed to all modules

Figure 381: ACMU Block Diagram

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The AC input controlled by circuit breakers is connected to the three AC/DC converters via a relay which is controlled by a temperature sensor. When the temperature is above -20 C, the AC input is connected to the three AC output connectors. If the temperature is below -20 C when the BTS A9100 is first switched on, there is no AC Supply to the PM12s. This means that the 0/ -48 V supply is not available and the BTS A9100 cannot operate. However, AC power is available to the HEAT2. When the HEAT2s raise the internal cabinet temperature above -20 C, the relay is activated and the DC supplies are produced. The HEAT2s prevent the internal cabinet temperature from falling to -20 C thereafter. When the internal cabinet temperature rises above 0 C, the SUMA switches on the telecommunications modules and the BTS A9100 become operational.

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The following figure shows the ACMU front panel.

Warning Label

L1

BTS L2

L3

F5

F4

F3

HEATING

SERVICE + LIGHT

F2

F1

Equipment Label

Warning Label

Figure 382: ACMU Front Panel

12.8 ACMUT The ACMUT is used in multistandard BTS outdoor tropical configurations. Its functions are: Distribution of the AC input to AC/DC converters and air conditioning Switching the AC line to the connected modules by using circuit breakers. The following figure shows the block diagram. N N AC Mains In 1 Phase AC−Mains− Connection

distributed to all modules

Circuit Breaker F5 L

L

PE

PE

up to three PM12/1

distributed to all modules

Figure 383: ACMUT Block Diagram The AC input controlled by circuit breakers is connected to the three AC/DC converters. The following figure shows the ACMUT front panel. WARNING: TO ISOLATE THE COMPLETE SYSTEM SWITCH OFF THE AC MAINS AND BATTERY BREAKER

L1 F5

Figure 384: ACMUT Front Panel

12.9 ACSU The ACSU is used in outdoor BTS A9100 configurations. Its functions are:

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Distribution of the AC input to AC/DC converters, heaters/air conditioning and Service Lights (with AC power sockets) Switching the AC lines to the connected modules by using circuit breakers. The following figure shows the block diagram for CODI/CODE/CPT2. N Temperature Sensor N distributed to all modules

−20

Circuit Breakers L1

L1

to PM12/1

L2

to PM12/2

L3

to PM12/3

L1

to Heat2/Airc.

L2

to Heat2/Airc.

L3

to Heat2/Airc.

L1

to Service Light and AC Power Socket

AC Mains In 3 Phase AC−Mains− Connection

L2

L3

PE PE

distributed to all modules

Figure 385: CODI/CODE/CPT2, ASCU Block Diagram The AC input controlled by circuit breakers is connected to the three AC/DC converters via a relay which is controlled by a temperature sensor. When the temperature is above -20 C, the AC input is connected to the two or three AC output connectors. If the temperature is below -20 C when the BTS A9100 is first switched on, there is no AC Supply to the PM12s. This means that the 0/ -48 V supply is not available and the BTS A9100 cannot operate. However, AC power is available to the HEAT2. When the HEAT2s raise the internal cabinet temperature above -20 C, the relay is activated and the DC supplies are produced. The HEAT2s prevent the internal cabinet temperature from falling to -20 C thereafter. When the internal cabinet temperature rises above 0 C, the SUMA switches on the telecommunications modules and the BTS A9100 become operational. The following figure shows the ACSU front panel of CODI/CODE/CPT2. BTS

HEATING

SERVICE + LIGHT

L1

L2

L3

L1

L2

L3

F7

F6

F5

F4

F3

F2

Warning Label

F1

Figure 386: ACSU Front Panel CODI/CODE/CPT2

12.10 ACUC The ACUC is used in Compact BTS Outdoor (CBO) configurations.

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Its functions are: Distribution of the AC input to AC/DC converters, heaters/air conditioning and AC power socket Switching the AC lines to the connected modules by using circuit breakers. The following figure shows the block diagram. F4 1

V=10 C 2

PE

AC Mains In 1 Phase AC Mains Connection

X1

F2

F3 L

N

3

2 X2

F1

L

N 1

X3

L

L N

N

L

PE

4 X4

X5

PE

N

5

6 X6

7 X7

PE

L

N X21

9

8 X8

X9

PE N L

N PE L N PE L

N PE L

TO PM12

TO HEAT3

Figure 387: ACUC Block Diagram The AC input controlled by circuit breakers is connected to the two AC/DC converters. From -33 C the AC power is applied to the PM12 modules, FAN units and to HEAT3. When the internal cabinet temperature rises above 0 C, the SUMA switches on the telecommunications modules and the CBO become operational. When the internal cabinet temperature rises above 10 C, the HEAT3 is switched off.

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The following figure shows the ACUC front panel.

BTS F1

HEATING RCB SERVICE F2 F3

SERVICE SOCKET S1

WARNING: TO ISOLATE THE COPMPLETE SYSTEM SWITCH OFF THE AC−MAINS AND BATTERY BREAKER

Figure 388: ACUC Front Panel

12.11 APOD The APOD is used in indoor BTS A9100 versions that use an AC power supply. It distributes its AC input to five output connectors. The five output connectors provide the AC power source for the PM08s. The DC output from the PM08s is then distributed to the subracks and other equipment by the APOD. The APOD is housed in the ASIB. It distributes 230 VAC to the five PM08s. The DC supply produced by the PM08s is connected to the remaining modules in the cabinet via the circuit breakers located on the APOD, as shown in the following figure. APOD

AC Circuit Breaker

L N

Input 1

PE DC Circuit Breakers INT Subrack 4 Subrack 3 −48 VDC Subrack 2 Subrack 1 EXT 0 VDC

6 5 4 3 2

PM08/5

PM08/4

PM08/3

PM08/2

PM08/1

1

PE DC Bus

Figure 389: APOD Circuit Schematic

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12.11.1 Front Panel The following figure shows the front panel of the APOD. Camloc Fastener

Warning Label

DC Output Circuit Breakers

AC Input Circuit Breaker

Equipment Labels

5

4 3 AC Output Cables to PM08s

1 2

Figure 390: APOD Front Panel

12.11.2 Connectors The following table describes the APOD front panel connectors. Connector

Description

AC Input

AC Input Circuit Breaker.

INT, SR1, SR2, SR3, SR4, EXT

DC Output Circuit Breakers.

AC Out 1- 5

Provides 230 VAC 1Ø outputs for the five PM08s.

Table 120: APOD Front Panel Connectors

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12.12 PM08 PM08 is used in outdoor BTS A9100 versions. It converts the AC input voltage to provide DC power for the cabinet equipment.

12.12.1 PM08 Functional Description PM08 is housed in the SRACDC. It is an 800 W AC/DC power supply module which converts 230 VAC to 0/ -48 VDC nom. Five PM08s (PM08/1 - PM08/5) are fitted in parallel to provide n + 1 redundancy, with load sharing. The following figure shows the arrangement. AC Input Control

ACIB

Alarms

PM08/5

PM08/4

PM08/3

PM08/2

PM08/1

BCU1

0 VDC −48 VDC DC Bus

Figure 391: PM08 Load-Sharing The BCU1 performs the functions listed in the following table for the PM08s. Control

PM08 outputs are connected to the SRACDC backplane DC Bus and monitored by BCU1. When the output voltage changes because of a changed load, the PM08s automatically compensate for the change. BCU1 controls the overall output voltage of the PM08s. The nominal -48 V output is typically -54.5 V at 20 C. During battery charging, BCU1 changes the output voltage within the range -52 V to -57 V. During battery testing, the output voltage can be reduced to -44 V. The DC Bus provides DC power to the DCDP and the BU41, via the BACO.

Alarm Collection

The PM08 raises alarms for both Mains power failure and power module failure. The alarm is collected by the BCU1. For more information on alarms, refer to PM08 Electrical Characteristics (Section 12.12.2).

Table 121: BCU1 Functions for PM08

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12.12.2 PM08 Electrical Characteristics The electrical characteristics for the PM08 are described in terms of input and output voltages, fuses, output current and protection and alarms.

12.12.2.1 Input Voltage The following table shows the PM08 input voltage parameters. Input

Parameter

Input voltage

220 VAC to 230 VAC (±15 %)

Frequency

47 Hz to 63 Hz

Number of phases

Single phase

Table 122: PM08 Input Voltage Parameters

Note:

The PM08 can be operated at 110 VAC if the output power is limited to 500 W.

12.12.2.2 Fuses Both the live and neutral inputs of the PM08 are protected by fast acting 10 A fuses. The fuses are accessed by removing protective caps on the module’s front panel.

12.12.2.3 Output Voltage The following table shows the PM08 output voltage parameters. Output

Parameter o

Nominal output voltage at 20 C.

-54.5 VDC

Output voltage range.

-50 VDC to -58 VDC

Line regulation.

U in ±15 %

Dynamic load regulation.

5 % of output voltage

Static load regulation.

0.2 %

Dynamic response.

2 ms

Voltage ripple.

< 400 mV p-p

Table 123: PM08 Output Voltage Parameters

Note:

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If the BCU1 fails or is not fitted, the PM08 produces an output of -52 VDC (±0.25 V). If batteries are not fitted, the default voltage is produced at all times.

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12.12.2.4 Output Current The following table shows the PM08 output current parameters. Output

Parameter

Nominal I out at -54.6 VDC

15 A

Minimum I out

0A

Maximum I out

19 A

Current limitation (I max).

16 A to 19 A

Derating.

3 % of I out (at > 60 C)

Shared load current.

<10 % of I out (of single module).

o

Table 124: PM08 Output Current Parameters

12.12.2.5 Protection and Alarms The PM08’s internal protection feature raises an alarm and shuts down the PM08 for: Mains power failure Under voltage: output voltage below -40.5 VDC Over voltage: output voltage exceeds -60 VDC Over current: output voltage at 0 V (short circuit) Over temperature: PM08 heat sink temperature in range + 85 C to + 100 C.

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12.12.3 PM08 Front Panel The following figure shows the front panel of the PM08. Camloc Fastener

AC In Connector Fuses Labels Status LED

Handle

Figure 392: PM08 Front Panel

12.12.3.1 PM08 LEDs The PM08 has a single LED on its front panel. The type of LED fitted depends on the part number of the PM08. The following table shows the PM08 part numbers and associated LED states. PM08 Part Number

LED State

Description

3BK 06783 BAAA

Green

Normal operating conditions.

Off

Fault.

Green

Normal operating conditions.

Orange

Power limitation mode (maximum power of 800 W reached).

Red

Fault.

3BK 06783 BBAA

Table 125: PM08 LED States

12.12.3.2 Connectors The only PM08 front panel connector is AC In, an IEC 320 connector for coded conditions, where the 230 VAC input cable from the ACIB is plugged in.

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12.13 PM11 The PM11 is used in outdoor BTS A9100 versions where the ACSR is employed. PM11 converts the AC input voltage to provide DC power for the cabinet equipment.

12.13.1 PM11 Functional Description The PM11 is housed in the ACSR. It is an 1100 W AC/DC power supply module which converts 230 VAC to 0/ -48 VDC nom. Four PM11s (PM11/1 PM11/4) are fitted in parallel to provide n + 1 redundancy, with load sharing. The following figure shows the arrangement. AC Input

ACSB

Control Alarms

PM11/4

PM11/3

PM11/2

PM11/1

BCU2

0 VDC −48 VDC DC Bus

Figure 393: PM11 Load-Sharing The BCU2 performs the functions listed in the following table for the PM11s. Control

PM11 outputs are connected to the ACSR backplane DC Bus and monitored by the BCU2. When the output voltage changes because of a changed load, the PM11s automatically compensate for the change. The BCU2 controls the overall output voltage of the PM11s. The nominal -48 V output is typically -54.5 V at 20 C. During battery charging, the BCU2 changes the output voltage within the range -52 V to -57 V. During battery testing, the output voltage can be reduced to -44 V. The DC Bus provides DC power to the BOBU and the BU41 or BU100, via the BAC2.

Alarm Collection

The PM11 raises alarms for both Mains power failure and power module failure. The alarm is collected by the BCU2. For more information on alarms, refer to PM11 Electrical Characteristics (Section 12.13.2).

Table 126: BCU2 Functions for PM11

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12.13.2 PM11 Electrical Characteristics The electrical characteristics of the PM11 are described in terms of input and output voltages, fuses, output current, and protection and alarms.

12.13.2.1 Input Voltage The following table shows the PM11 input voltage parameters. Input

Parameter

Input voltage

220 VAC to 230 VAC (±15 %)

Frequency

47 Hz to 63 Hz

Number of phases

Single phase

Table 127: PM11 Input Voltage Parameters

Note:

The PM11 can be operated at 110 VAC if the output power is limited to 500 W.

12.13.2.2 Fuses Both the live and neutral inputs of the PM11 are protected by fast acting 10 A fuses. The fuses are accessed by removing protective caps on the module’s front panel.

12.13.2.3 Output Voltage The following table shows the PM11 output voltage parameters. Output

Parameter o

Nominal output voltage at 20 C.

-54.6 VDC

Output voltage range.

-50 VDC to -57 VDC

Line regulation.

U in ±15 %

Dynamic load regulation.

5 % of output voltage

Static load regulation.

0.2 %

Dynamic response.

2 ms

Voltage ripple.

< 400 mV p-p

Table 128: PM11 Output Voltage Parameters

Note:

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If the BCU2 fails or is not fitted, the PM11 produces an output of -52 VDC (±0.25 V). If batteries are not fitted, the default voltage is produced at all times.

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12.13.2.4 Output Current The following table shows the PM11 output current parameters. Output

Parameter

Nominal I out at -54.6 VDC

20 A

Minimum I out

0A

Maximum I out

24 A

Current limitation (I max)

21 A to 24 A

Derating

3 % of I out (at > 60 C)

Shared load current

<10 % of I out (of single module)

o

Table 129: PM11 Output Current Parameters

12.13.2.5 Protection and Alarms The PM11’s internal protection feature raises an alarm and shuts down the PM11 for: Mains power failure Under voltage: output voltage below -40.5 VDC Over voltage: output voltage exceeds -60 VDC Over current: output voltage at 0 V (short circuit) Over temperature: PM11 heat sink temperature in range + 85 C to + 100 C.

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12.13.3 PM11 Front Panel The following figure shows the front panel of the PM11. Camloc Fastener

Status LED

Handle

Labels

Fuses

Figure 394: PM11 Front Panel

12.13.4 PM11 LED The PM11 has a single LED on its front panel. The following table shows the LED states. LED State

Description

Green

Normal operating conditions.

Off

Fault.

Table 130: PM11 LED States

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12.14 PM12 The PM12 converts the AC input voltage to provide DC power for the cabinet equipment. The PM12 is used in indoor and outdoor BTS A9100 versions where the SUMA is employed.

12.14.1 PM12 Functional Description Up to three PM12s and an ADAM or up to four PM12s and an ADAM4 are put together in one-half or two-thirds of a STASR (see Figure 408 or 414). The ADAM/ADAM4 is connected to the DC distribution of the BTS. Each PM12 is controlled from the OMU (part of SUMA) via the BCB. Batteries fitted to a BTS have a temperature sensor which is controlled by the RIBAT (see RIBAT (Section 12.29)) or the OUTC (see Outdoor Control Board CPT2/MBO1/MBO1DC/MBO1T/MBO1E/MBO2/MBO2DC/ MBO2E/CBO (Section 4.5). The OMU reads the stored battery size/charge current and the temperature out of the RIBAT or OUTC and sets the PM12s according to these values. PM12 is an AC/DC power supply module which converts 230 VAC to 0/-48 VDC nom. The output power of the PM12 module depends on the input voltage range and temperature range as listed in the following table.

*

Output Power

Input Voltage

Temperature

900W*

150V...187V

-25C...70C

1200W

187V...264V

-25C...70C

900W*

264V...280V

-25C...70C

100W

150V...280V

-40C...-25C

: Available only on PM12 module version 3BK25024 ABxx

Table 131: PM12 Output Power Values Two to four PM12s (PM12/1 - PM12/4) are fitted in parallel with load sharing (see Figure 246 or MBO1/MBO2 AC/DC Power Supply System (247)) controlled by a local sharing bus. The OMU performs the functions listed in the following table for the PM12s.

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Control

PM12 outputs are connected via ADAM/ADAM4 to the STASR backplane DC Bus and monitored by the OMU. When the output voltage changes because of a changed load, the PM12s automatically compensate for the change. OMU controls the overall output voltage of the PM12s. Default output voltage without OMU control is 52.2V. Depending on battery cell voltage set in RIBAT/OUTC, OMU sets the output voltage of PM12 in range 52.2-57V. The DC Bus provides DC power to the: BOBU/BOMU/BOSU BU41, BU100 or BU101, via the ADAM/ADAM4.

Alarm Collection

The PM12 raises alarms for both Mains power failure and power module failure. The alarm is collected by the OMU. For more information on alarms, refer to PM12 Electrical Characteristics (Section 12.14.2).

Table 132: OMU Functions for PM12

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12.14.2 PM12 Electrical Characteristics The electrical characteristics of the PM12 are described in terms of input and output voltage, fuses, output current, and protections and alarms.

12.14.2.1 Input Voltage The following table shows the PM12 input voltage parameters. Input

Parameter

Nominal input voltage

230/ 240 VAC

Input voltage range

187 VAC to 264 VAC

Frequency

47 Hz to 63 Hz

Number of phases

Single phase

Table 133: PM12 Input Voltage Parameters

12.14.2.2 Fuses Both the live and neutral inputs of the PM12 are protected by fast acting 10 A fuses. The fuses are accessed by removing the cover of the module.

12.14.2.3 Output Voltage The following table shows the PM12 output voltage parameters. Output

Parameter o

Nominal output voltage at 20 C

-54.5 VDC (in case of Ucell=2.27V)

Output voltage range

-50 VDC to -57 VDC

Line regulation

U in ±15 %

Dynamic load regulation

5 % of output voltage

Static load regulation

0.2 %

Dynamic response

2 ms

Voltage ripple

< 400 mV p-p

Table 134: PM12 Output Voltage Parameters

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12.14.2.4 Output Current The following table shows the PM12 output current parameters. Output

Parameter

Nominal I out at -54.6 VDC

20 A

Minimum I out

0A

Maximum I out

24 A

Current limitation (I max)

21 A to 24 A

Derating

3 % of I out (at > 60 C)

Shared load current

<10 % of I out (of single module)

Table 135: PM12 Output Current Parameters

12.14.2.5 Protection and Alarms The PM12’s internal protection feature raises an alarm and shuts down the PM12 for: Mains power failure Under voltage: output voltage below -40.5 VDC Over voltage: output voltage exceeds -60 VDC Over current: output voltage at 0 V (short circuit) Over temperature: PM12 heat sink temperature in range + 85 C to + 100 C.

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12.14.3 PM12 Front Panel The following figure shows the front panel of the PM12. Camloc Fastener

AC In Connector

Status LED

ON

Equipment Labels

Handle

Figure 395: PM12 Front Panel

12.14.4 PM12 LED The PM12 has a single LED on its front panel. The following table shows the LED states. LED State

Description

Green

Normal operating conditions.

Off

Fault.

Table 136: PM12 LED States

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12.15 PM18 The PM18 converts the AC input voltage to provide DC power for the cabinet equipment. PM18 are used in outdoor BTS or MBS. The consists of the subrack PM18SR which contains a control unit PM18C, up to 3 rectifier PM18R and a temperature sensor. Each rectifier has an output power of 1800 W. The PM18C controls the the power modules and handles the alarm reporting to the SUMU via XBCB and RS232. The battery management is done by the PM18C internally of the power supply without any control functions of the SUMA.

12.15.1 Performance Characteristics 12.15.1.1 Input Voltage Parameters The following table shows the PM18 input voltage parameters. Input

PM18

Nominal input voltage

230 VAC

Input voltage range

150 VAC to 280 VAC

Frequency

47 Hz to 63 Hz

Number of phases

Single or three phase

12.15.1.2 Output Voltage Parameters The following table shows the PM18 output voltage parameters. Output

PM18 o

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Nominal output voltage at 20 C

-52.5 VDC … -54VDC

Output voltage range

-42 … -57 VDC

Line regulation

+/-10 %

Dynamic load regulation

+/-10 %

Dynamic response

50 ms

Voltage ripple

< 200 mV p-p

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12.15.1.3 Output Power Parameters The following table shows the PM18 output power parameters. Output

PM18 per module

Nominal output voltage UN

52.5 - 54 V

Output voltage range UR

48 - 57 V

Nominal power at UR

1800 W

Maximum I out

40 A (limitation mode)

Output power de-rating

2 % of I out/ K (at > 55C)

12.15.2 LEDs 12.15.2.1 PM18SR The PM18SR from Cherokee has a single LED on it. LED

Color

State

Description

LVD (Low Voltage Disconnection)

Green

ON

Battery connected

OFF

Battery not connected

12.15.2.2 PM18C LEDs The PM18C from Cherokee has a single LED on its front panel. The following table shows the LED states for the Cherokee PM18C. LED

Color

State

Description

ON

Green

ON

Normal operational conditions. Monitoring OK

Blinking

Monitoring start-up

OFF

Monitoring fail

The PM18C from H+S has two LEDs on its front panel. The following table shows the LED states for the H+S PM18C.

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LED

Color

Status

Description

ON

Green

ON

Normal operational conditions

OFF

Module not operational

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LED

Color

Status

Description

Alarm

Red

ON

Fault

OFF

Normal operational conditions

12.15.2.3 PM18R LEDs The Cherokee PM18R has four LEDs on its front panel. The following table shows the LED states. LED

Color

State

Description

AC OK

Green

ON

AC voltage OK

OFF

Module not operational

ON

DC voltage OK

OFF

Module not operational

ON

Output overvoltage

OFF

Normal operational conditions

ON

Excessive temperature

OFF

Normal operational conditions

DC OK

OVP

OTP

Green

Red

Red

The H+S PM18R has two LEDs on its front panel. The following table shows the LED states. LED

Color

State

Description

ON

Green

ON

Normal operational conditions

OFF

Module not operational

ON

Fault

OFF

Normal operational conditions

Fault

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Red

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12.15.3 Fuses Both the live and neutral inputs of the PM18 are protected by fuses. PM

Fuses

PM18

12.5 A, medium delay

The fuses are accessed by removing the protective caps on the module’s front panel.

12.15.4 Protection and Alarms The PM’s internal protection feature raises an alarm and shuts down the PM for the following reasons: Mains power failure Under-voltage: Output voltage below -40.5 VDC Over-voltage: Output voltage exceeds -60 VDC Over-current: Output voltage at 0 V (short circuit) Over-temperature: PM12 heat sink temperature in the range of +85C to +100C.

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12.15.5 PM18 Front View

Battery Connectors Battery Breaker

Fault ON

XBCB

Load Connectors

RS232 + Temp. Sensor

Alarm ON

The PM18 consists of the subrack PM18SR, which contains a control unit PM18C, up to 3 rectifiers PM18R and a temperature sensor.

Fault ON

Mains Connectors

Fault ON

Figure 396: PM18 H+S Front View LVD ON

Battery Breaker

AC Batt −

DC

OVP

AC

OTP Batt +

OUT −

DC

OVP

OTP

OUT −

AC

DC

OVP

OTP

Mains Connectors

Figure 397: PM18 Cherokee Front View

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12.15.6 Weight

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PM

Weight

PM18 Rectifier

3 kg / module

PM18 Subrack H+S

5 kg

PM18 Subrack Cherokee

7,5 kg

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12.16 BCU1 The BCU1 is used in outdoor BTS A9100 versions. It controls the DC output voltage and battery operation.

12.16.1 BCU1 Functional Description The BCU1 is housed in the SRACDC. It performs control functions for the batteries and some of the modules within the SRACDC. The following figure shows the arrangement. For simplicity, only two of the five PM08s are shown. Control Alarms XBCB ACRI PM08/2

PM08/1

BCU1 V Shunt

0 VDC −48 VDC

DC Bus V Shunt

BACO

SRACDC

BU41

Figure 398: BCU1 Interconnections The BCU1 connects to the PM08s, ACRI and BACO via the SRACDC backplane. The voltages across the shunt resistors provide the BCU1 with a measurement of the currents drawn. BU41 contains up to two battery groups which are referred to as branches. Each branch provides -48 VDC. The functions performed are: PM08 control Alarm supervision Battery management.

12.16.1.1 PM08 Control The BCU1 controls the PM08 output voltage and collects any alarms that are produced. For more information on the PM08, refer to PM08 (Section 12.12).

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12.16.1.2 Alarm Supervision The BCU1 collects alarms and reports them to the ACRI. The alarms are: AC power failure PM08 failure Battery malfunction BCU1 fault. For more details of the alarm information, refer to BCU1 LEDs, LCD, Alarms and Buttons (Section 12.16.2).

12.16.1.3 Battery Management The BCU1 provides the battery management functions described in the following table. Deep Discharge Protection

During normal operation, a trickle charge current ensures that the batteries remain fully charged. When an AC mains failure occurs, the batteries supply DC power to the BTS A9100. This discharges the batteries causing their output voltage to fall. If the output voltage falls below -42 VDC (±0.5 V), the BCU1/BCU2 disconnects the batteries by deactivating relays in the BACO/BAC2. This prevents deep discharge of the batteries which shortens their life.

Charging Current Regulation

When charging the batteries, BCU1/BCU2 regulates the charging current so that battery life is not shortened. Charging current is adjusted by changing the PM08/PM11 output voltages. Charging current regulation: Limits the maximum charging current, depending on battery type and the number of battery branches. For more details of the charging current limits, refer to BU41 (Section 12.24) and BU100 (Section 12.25). Adjusts the charging current to avoid overheating the batteries. A temperature sensor, fitted to one battery branch, is connected to BCU1 via the BACO. The charging voltage, at an ambient temperature of o 20 C, is typically -54.6 VDC. If the temperature sensor fails, or is not fitted, the PM08/PM11 output voltage is set to -52 VDC.

Table 137: BCU1/BCU2 Battery Management Functions

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12.16.2 BCU1 LEDs, LCD, Alarms and Buttons The different LEDs, the LCD, alarms, buttons and the special menu for the BCU1 are described separately below.

12.16.2.1 LEDs The following table describes the front panel LEDs. LED

Color

State

Description

On

Green

On

Normal state - BCU1 internal reference voltage is available.

Off

BCU1 faulty.

On

Battery backup in operation (battery discharging) or battery malfunction.

Off

Normal state.

On

n/a

Off

Normal state.

Bat.

Test

Red

Yellow

Table 138: BCU1 LED Descriptions

12.16.2.2 LCD The BCU1 has an LCD on its front panel (see Figure 399). Information is viewed using the front panel Function and Status buttons to scroll through several display options. The LCD provides two rows of alphanumeric information where each row consists of eight characters. The first row displays a message and the second row displays associated parameters or choices.

12.16.2.3 Alarms The BCU1 collects alarms and reports them to the ACRI. The alarms are described in the following table. Alarm Type

Description

BCU1 Fault

The internal reference voltage used by the BCU1 has failed.

PM08 Failure

The alarm information specifies the identity number of the failed module and the number of modules fitted.

AC Failure

The AC mains supply has failed or been switched off.

Battery Malfunction

The identity number of the battery branch that failed is reported. A battery malfunction occurs if: The battery was automatically disconnected because of a malfunction during charging Deep discharge protection occurred.

Table 139: BCU1 Alarms

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12.16.2.4 Function Button Using the Function button, the following information can be displayed: PM08s output voltage (Uload) Battery voltage (Ubatt) Output current (Iload) Battery current (Ibatt), where: + = charging - = discharging. Battery temperature.

12.16.2.5 Status Button Using the Status button, the following information can be displayed: Alarm type, where the character: V represents BCU1 failure R represents a rectifier (PM08) failure M represents an AC mains failure B represents a battery malfunction. Status of the PM08s, represented by a five-character sequence. Each character position represents a physical PM08 slot position, where: N - slot not occupied F - PM08 failed Y - PM08 serviceable. Battery type and number of battery branches.

12.16.2.6 Special Menu The special menu is activated by pressing the Function and Status buttons simultaneously, for five seconds. Selections in the special menu are then made using the Function and Status buttons individually. Using the special menu, the following tasks can be performed: Set battery type Set number of branches in use. Refer to the Evolium BTS A9100/A9110 Corrective Maintenance Handbook for details of how to use the special menu facility.

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12.16.3 BCU1 Front Panel The following figure shows the front panel of the BCU1. Camloc Fastener

Labels

Status LEDs On

Test

Bat.

LCD Display

Control Buttons

Function

Status

Connector RS−232 (For factory service and test only.)

RS−232

Handle

Figure 399: BCU1 Front Panel

12.17 BCU2 The BCU2 is used in outdoor BTS A9100 versions where the ACSR is employed. It: Controls the DC output voltage and battery operation Collects alarms from the ACSR modules Controls the ACSR FANUs Provides the interface to the BTS Remote Inventory function.

12.17.1 BCU2 Functional Description The BCU2 is housed in the ACSR. It performs control functions for the batteries and some of the modules within the ACSR. The following figure shows the arrangement. For simplicity, only two of the four PM11s are shown. Control Alarms

XBCB PM11/2

PM11/1

BCU2 V Shunt

0 VDC −48 VDC

DC Bus V Shunt

BAC2

ACSR

BU41 or BU100

Figure 400: BCU2 Interconnections

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BCU2 connects to the PM11s and BAC2 via the ACSR backplane. The voltages across the shunt resistors provide BCU2 with a measurement of the currents drawn. BU41 contains up to two battery groups and BU100 contains one battery group. These battery groups are referred to as branches. Each branch provides -48 VDC. The functions performed are: PM11 control Alarm supervision Battery management ACRI system functions.

12.17.1.1 PM11 Control The BCU2 controls the PM11 output voltage and collects any alarms that are produced. For more information on the PM11, refer to PM11 (Section 12.13).

12.17.1.2 Alarm Supervision The BCU2 collects alarms and reports them to the OMU on the SUMP. The alarms are: AC power failure PM11 failure Battery malfunction BCU2 fault. For more details of the alarm information, refer to BCU2 LEDs, LCD, Alarms and Buttons (Section 12.17.2).

12.17.1.3 Battery Management The BCU2 provides the battery management functions described in Table BCU1/BCU2 Battery Management Functions (137).

12.17.1.4 ACRI System Functions The ACRI system implemented on the BCU2 consists of the functions listed in the following table.

3BK 20942 AAAA TQZZA Ed.13

ANPS

The BCU2 contains an ANPS which converts the -48 VDC input supply to the DC voltages required by the other components. For more information on the ANPS, refer to AN Power Supply (Section 10.1.5).

Modified FACB

The BCU2 contains a modified FACB which reports fan faults and controls the two FANUs that cool the ACSR modules. For more information on the FACB and FANUs, refer to Fan Control (Section 11.1.2).

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12 Power Supplies and Distribution

XBCB

The BCU2 contains a BCB ASIC that transfers information to the OMU in the SUMP via the XBCB. This consists of: Alarms from modified FACB Alarms internal to the BCU2 Alarms from the battery and PM11s Remote Inventory information.

RI

The BCU2 contains a Remote Inventory that is used to store information about the module (part number, name, serial number, etc.). It consists of an EEPROM which is connected to the BCB ASIC.

Table 140: BCU2, ACRI System Functions

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12.17.2 BCU2 LEDs, LCD, Alarms and Buttons The different LEDs, the LCD, alarms, buttons and the special menu for the BCU2 are described separately below.

12.17.2.1 LEDs The following table describes the front panel LEDs. LED

Color

State

Description

On

Green

ON

Normal state - BCU2 internal reference voltage is available.

OFF

BCU2 faulty.

ON

Battery backup in operation (battery discharging) or battery malfunction.

OFF

Normal state.

ON

n/a

OFF

Normal state.

ON

When XBCB bus is connected and OK and internal power supply (48V/5V converter) is operational.

OFF

Otherwise.

Bat.

Test

Red

Yellow

Power ON

Table 141: BCU2 LED Description

12.17.2.2 LCD The BCU2 has an LCD on its front panel (see Figure 401). Information is viewed using the front panel Function and Status buttons to scroll through several display options. The LCD provides one row of alphanumeric information where the row consists of eight characters.

12.17.2.3 Alarms The BCU2 collects alarms and reports them to the OMU on the SUMP. The alarms are described in the following table.

3BK 20942 AAAA TQZZA Ed.13

Alarm Type

Description

BCU2 Fault

The internal reference voltage used by the BCU2 has failed.

PM11 Failure

The alarm information specifies the identity number of the failed module and the number of modules fitted.

AC Failure

The AC mains supply has failed or been switched off.

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12 Power Supplies and Distribution

Alarm Type

Description

Fan Status

The status of the two FANUs located below the ACSR.

Battery Malfunction

The identity number of the battery branch that failed is reported. A battery malfunction occurs if: The battery was automatically disconnected because of a malfunction during charging Deep discharge protection occurred.

Table 142: BCU2 Alarms

12.17.2.4 Function Button Using the Function button, the following information can be displayed: PM11s output voltage (Uload) Battery voltage (Ubatt) Output current (Iload) Battery current (Ibatt), where: + = charging - = discharging. Battery temperature.

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12 Power Supplies and Distribution

12.17.2.5 Status Button Using the Status button, the following information can be displayed: Alarm type, where the character: V represents BCU2 failure R represents a rectifier (PM11) failure M represents an AC mains failure B represents a battery malfunction. Status of the PM11s, represented by a four-character sequence. Each character position represents a physical PM11 slot position, where: N - slot not occupied F - PM11 failed. Y - PM11 serviceable. Battery type and number of battery branches.

12.17.2.6 Special Menu The special menu is activated by pressing the Function and Status buttons simultaneously, for five seconds. Selections in the special menu are then made using the Function and Status buttons individually. Using the special menu, the following tasks can be performed: Set battery type Set number of branches in use. Refer to the Evolium BTS A9100/A9110 Corrective Maintenance Handbook for details of how to use the special menu facility.

3BK 20942 AAAA TQZZA Ed.13

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12 Power Supplies and Distribution

12.17.3 BCU2 Front Panel The following figure shows the front panel of the BCU2. Camloc Fastener

Labels

Status LEDs On

Control Buttons

Test

Function

Bat.

LCD Display

Status

RS−232

Handle

Power ON

XBCB Connector Temperature Connector

Figure 401: BCU2 Front Panel

12.17.4 Connectors The following table describes the BCU2 front panel connectors. Connector

Description

Temperature

For connection of temperature sensor from BU41 or BU100.

XBCB

Provides a: + 5 VDC signal to enable ANPS Serial interface for the transfer of alarms and Remote Inventory information to the OMU.

Table 143: BCU2 Front Panel Connectors

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12 Power Supplies and Distribution

12.18 BACO The BACO is used in outdoor BTS A9100 versions. It interconnects the batteries and the DC outputs of the PM08s. The BACO contains: Circuit breakers for manual isolation of the batteries Relays for automatic isolation of the batteries, controlled by the BCU1. The BACO is housed in the SRACDC. It interconnects up to two battery branches to the SRACDC backplane DC bus. The battery branches must be of the same type and capacity. The following figure shows the circuit schematic. BU41

BACO

SRACDC Backplane

Circuit Breakers BATOUT+ 48 VDC nom.

DC Bus Shunt

K1 BATOUT− RELBATT1

Branch 1

UBATT− 48 VDC nom.

K2 To BCU1

Branch 2

RELBATT2 Sensor Signals

Temperature Sensor

Figure 402: BACO Circuit Schematic Circuit breakers are provided for manual isolation of the batteries during battery maintenance. When in use, the circuit breakers trip automatically when the current drawn exceeds 60 A. During an AC mains failure, BU41 provides battery power to the DC bus via relays K1 and K2, and a shunt resistor. If the battery discharge becomes excessive, BCU1 deactivates the relays to isolate the batteries. Relays K1 and K2 are controlled by the signals RELBATT1 and RELBATT2, respectively. During battery charging and discharging, the relays operate simultaneously. During battery testing, they operate independently.

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12.18.1 Front Panel The following figure shows the front panel of the BACO. Camloc Fastener

Equipment Labels

Warning Label

Battery Connection Cables

Figure 403: BACO Front Panel

12.18.2 Connectors The following table describes the BACO connectors. Connector

Description

X200

Connects battery temperature sensor signals to SRACDC backplane.

Battery Connectors

Connects to battery terminals. There are two cables for each branch.

Table 144: BACO Front Panel Connectors

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12 Power Supplies and Distribution

12.19 BAC2 The BAC2 is used in outdoor BTS A9100 versions. It interconnects the batteries and the DC outputs of the PM08s or PM11s. The BAC2 contains: Circuit breakers for manual isolation of the batteries Relays for automatic isolation of the batteries, controlled by the BCU2. The BAC2 is housed in the ACSR. It interconnects up to two battery branches to the ACSR backplane DC bus. The battery branches must be of the same type and capacity. The following figure shows the circuit schematic. BAC2

BU41 or BU100

ACSR Backplane

Circuit Breakers BATOUT+ 48 VDC nom.

DC Bus Shunt

K1 BATOUT− RELBATT1

Branch 1

UBATT− 48 VDC nom.

Branch 2 (BU41 only)

K2

RELBATT2

To BCU2

Sensor Signals Temperature Sensor

Figure 404: BAC2 Circuit Schematic Circuit breakers are provided for manual isolation of the batteries during battery maintenance. When in use, the circuit breakers trip automatically when the current drawn exceeds 60 A. During an AC mains failure, BU41 or BU100 provides battery power to the DC bus via relays K1 and K2, and a shunt resistor. If the battery discharge becomes excessive, BCU2 deactivates the relays to isolate the batteries. Relays K1 and K2 are controlled by the signals RELBATT1 and RELBATT2, respectively. During battery charging and discharging, the relays operate simultaneously. During battery testing, they operate independently.

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12.19.1 Front Panel The following figure shows the front panel of the BAC2. Camloc Fastener

AC Mains and Battery Breakers

Equipment Labels

Battery Connection Cables

Figure 405: BAC2 Front Panel

12.19.2 Connectors The following table describes the BAC2 connectors. Connector

Description

Battery Connectors

Connects to battery terminals. There are two cables for each branch.

Table 145: BAC2 Front Panel Connectors

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12.20 ABAC The ABAC is used in indoor BTS A9100 versions that use an AC power supply. It interconnects the batteries and the DC outputs of the PM08s. The ABAC contains: Circuit breakers for manual isolation of the battery Relays for automatic isolation of the battery, controlled by the BCU1. The ABAC is housed in the ASIB. It interconnects a maximum of one battery branch to the ASIB backplane DC bus. The battery branch can be BU41 or BU100. The following figure shows the circuit schematic. ABAC

BU41 or BU100

ASIB Backplane

Circuit Breakers BATOUT+ 48 VDC

nom.

DC Bus Shunt

K1 BATOUT−

Branch 1

RELBATT1 UBATT− To BCU1 Sensor Signals

Temperature Sensor

Figure 406: ABAC Circuit Schematic Circuit breakers are provided for manual isolation of the battery branch during battery maintenance. When in use, the circuit breakers trip automatically when the current drawn exceeds 60 A. During an AC mains failure, BU41 or BU100 provides battery power to the DC bus via relay K1, and a shunt resistor. If the battery discharge becomes excessive, the BCU1 deactivates the relay to isolate the battery branch. Relay K1 is controlled by the signal RELBATT1.

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12.20.1 Front Panel The following figure shows the front panel of the ABAC. Camloc Fastener

+ Equipment Labels

−

Battery Connection Cables

Figure 407: ABAC Front Panel

12.20.2 Connectors The following table describes the ABAC connectors. Connector

Description

X200

Connects battery temperature sensor signals to the ASIB backplane.

Battery Connectors

Connects to battery terminals. There are two cables only (one branch).

Table 146: ABAC Front Panel Connectors

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12 Power Supplies and Distribution

12.21 ADAM ADAM is used in the AC/DC power supply of BTS A9100 configurations as the interface between the PM12s, the batteries and the power distribution inside the BTS. ADAM consists of: An air permeable metal frame, mounted in one-half of a STASR above the PM12s (see the following figure) A small backpanel with the connectors for three PM12s and a terminal for the wiring of the BTS. In addition, the ADAM contains on its backpanel: The relay for battery protection The relay control A shunt for measuring the battery current. The following figure shows the position of ADAM in the STASR. ADAM

PM12

Figure 408: ADAM, Position in the STASR

3BK 20942 AAAA TQZZA Ed.13

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12.21.1 Block Diagram The following figure shows the block diagram. ADAM Backpanel

Frontpanel

−48 VDC Subracks

−48 VDC Subracks

0VDC

0VDC

−48 VDC Battery

−48 VDC Battery

OMU (SUMA)

Relay Control PM12/1

Battery Shunt

PM12/2 Signals

PM12/3

Figure 409: ADAM Block Diagram The relay protects the battery in case of discharging. If the voltage reaches the lower limit, the relay separates the -48 VDC line of the battery. The relay has its own control circuit, so it works independently of the OMU.

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12.21.2 Appearance The following figure shows the front side view of ADAM.

Figure 410: ADAM Front Side View

12.21.3 Connectors On the backpanel there are three connectors for the PM12s. Each of them contains two blocks with 4x2 high current contacts (one block for 0 VDC and one for -48 VDC) and a 24-pin block for the control signals. On the front panel there are the terminals for the DC supply of the subracks (via BOBU/BOMU/BOSU) and the back-up battery.

3BK 20942 AAAA TQZZA Ed.13

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12.22 ADAM2 ADAM2 is used in the AC/DC power supply of Compact BTS Outdoor configurations as the interface between the PM12s, the batteries and the power distribution inside the BTS. ADAM2 consists of: An air permeable metal frame, mounted in one-third of a STASR above the PM12s (see the following figure) A small backpanel with the connectors for two PM12s and terminal for the wiring of the BTS. In addition, the ADAM2 contains on its backpanel: The relay for battery protection The relay control A shunt for measuring the battery current. The following figure shows the position of ADAM2 in the STASR. ADAM2

PM12

Figure 411: ADAM2, Position in the STASR

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12 Power Supplies and Distribution

12.22.1 Block Diagram The following figure shows the block diagram. ADAM Backpanel

Frontpanel

−48 VDC Subracks

−48 VDC Subracks

0VDC

0VDC

−48 VDC Battery

−48 VDC Battery

OMU (SUMA)

Relay Control

Battery Shunt

PM12/1 Signals

PM12/2

Figure 412: ADAM2 Block Diagram The relay protects the battery in case of discharging. If the voltage reaches the lower limit (42 V), the relay separates the DC line of the battery. The relay has its own control circuit, so it works independently of the OMU.

3BK 20942 AAAA TQZZA Ed.13

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12.22.2 Appearance The following figure shows the front side view of ADAM2.

0V BATT.

− 48V − 48V

Figure 413: ADAM2 Front Side View

12.22.3 Connectors On the backpanel there are two connectors for the PM12s. Each of them contains two blocks with 4x2 high current contacts (one block for 0 VDC and one for -48 VDC) and a 24-pin block for the control signals. On the front panel there are the terminals for the DC supply of the subracks (via DCUC) and the back-up battery.

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12 Power Supplies and Distribution

12.23 ADAM4 ADAM4 is used in the AC/DC power supply of BTS A9100 MBO1/MBO2 configurations as the interface between the PM12s, the batteries and the power distribution inside the BTS. ADAM4 is installed in combination with two to four PM12s. If less than four PM12s are installed, the empty PM12 slot is covered by a dummy panel. ADAM4 consists of: An air permeable metal frame, mounted in two third of a STASR above the PM12s (see the following figure) A small backpanel with the connectors for four PM12s and terminal for the wiring of the BTS. In addition, ADAM4 contains on its backpanel: The relay for battery protection The relay control A shunt for measuring the battery current. The following figure shows the position of ADAM4 in the STASR.

ADAM4

PM12

Figure 414: ADAM4 Position in the STASR

3BK 20942 AAAA TQZZA Ed.13

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12.23.1 Block Diagram The following figure shows the block diagram. ADAM4 Backpanel

Frontpanel

−48 VDC Subracks 0VDC

−48 VDC Subracks 0VDC

0VDC

0VDC

−48 VDC

Battery −48 VDC

Battery

OMU (SUMA)

Relay Control PM12/1

Battery Shunt

PM12/2 Signals

PM12/3

PM12/4

Figure 415: ADAM4 Block Diagram The relay protects the battery in case of discharging. If the voltage reaches the lower limit, the relay separates the -48 VDC line of the battery. The relay has its own control circuit, so it works independently of the OMU.

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12.23.2 Appearance The following figure shows the front side view of ADAM4.

Figure 416: ADAM4 Front Side View

12.23.3 Connectors On the backpanel there are two connectors for the PM12s. Each of them contains two blocks with 4x2 high current contacts (one block for 0 VDC and one for -48 VDC) and a 24-pin block for the control signals. On the front panel there are the terminals for the DC supply of the subracks (via BOMU) and the back-up battery.

3BK 20942 AAAA TQZZA Ed.13

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12.24 BU41 The BU41 is an optional feature used in outdoor BTS A9100 versions. It provides an emergency DC power source for use in the event of a mains supply failure. The principal components of BU41 are four high performance, sealed, lead-acid batteries that conform to the DIN 43539 standard. They connect in series to provide a 48 VDC nom. power source, referred to as a branch. Optionally, a second branch of four sealed lead-acid batteries can be fitted to double the backup period. Each battery branch is independently connected to the BACO or BAC2. Note however, that only one battery branch can be connected to an ABAC or ADAM. When two battery branches are used, both branches must consist of batteries of the same type and capacity. This is required because the charging and testing circuits assume both branches are the same. Connected to one of the battery terminals is a temperature sensor. This monitors the battery temperature. The output from the sensor is used by the BCU1/SUMA to regulate the charging voltage and thus prevent battery overheating. Each battery branch is fitted with venting tubes. The venting tubes discharge to the external environment the gasses produced during battery charging.

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12.24.1 Charging The BU41 charging characteristics conform to the DIN 41773 (float charging) standard. The following table shows the battery type and the charging current limit for the number of battery branches in use. Battery Type

One Branch

Two Branches

40 Ah

6A

12 A

Table 147: BU41 Battery Type and Charging Current Limit The following table shows the recommended charging voltage versus battery temperature. Temperature

Voltage Per Cell

Total Voltage (± 1%)

0 C

2.3773

57.05

5 C

2.3484

56.36

10 C

2.3215

55.72

15 C

2.2966

55.12

20 C

2.2737

54.57

25 C

2.2528

54.07

30 C

2.2339

53.61

35 C

2.2170

53.21

40 C

2.2021

52.85

45 C

2.1892

52.54

50 C

2.1783

52.29

Table 148: BU41 Charging Voltage Versus Battery Temperature

Note:

Avoid excessive battery gas leakage by not exceeding a charging voltage of 2.35 V per cell (56.40 V total) at 20 C.

12.24.2 Discharging and Storage Discharging below 1.75 V per cell (42 V total) can damage the batteries. Batteries may be stored without recharging only for a restricted time. Therefore manufacturers instructions (delivered with the product) must be followed.

3BK 20942 AAAA TQZZA Ed.13

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12.24.3 Front and Top View The following figure shows the front and top views of BU41. Supplier’s Information Label Equipment Labels Vent Tube

Front View

Top View

Figure 417: BU41 Front and Top Views

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12 Power Supplies and Distribution

12.24.4 BU41 Mounted in MBO The MBO offers a specific battery box. The batteries are arranged as shown in the following figure. The battery box is covered with a plate to secure the batteries. Exhausting Nipple Exhausting Tube

Equipment Lables −

−

Upper Block

Warning Lables

Supplier Information Lable

Internal Battery Cable +

+

−

−

+

+

Battery Box (Part of BTS)

Lower Block

Front View

Figure 418: BU41 in MBO - Front View

3BK 20942 AAAA TQZZA Ed.13

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12.25 BU100 The BU100 is an optional feature used in all outdoor BTS A9100 versions and in indoor versions that use an AC power supply. It provides an emergency DC power source for use in the event of a mains supply failure. The principal components of the BU100 are four high performance, sealed, lead-acid batteries that conform to the DIN 43539 standard. They connect in series to provide a 48 VDC nom. power source, referred to as a branch. The battery branch is connected to the BACO, BAC2, ABAC or ADAM as appropriate. Connected to one of the battery terminals is a temperature sensor. This monitors the battery temperature. The output from the sensor is used by the BCU1, BCU2 or SUMA to regulate the charging voltage and thus prevent battery overheating. The battery branch is fitted with venting tubes. The venting tubes discharge the gasses produced during battery charging to the external environment.

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12.25.1 Charging The BU100 charging characteristics conform to the DIN 41773 (float charging) standard. The following table shows the battery type and the charging current limit. Battery Type

Limit

100 Ah

12 A

Table 149: BU100 Battery Type and Charging Current Limit The following table shows the recommended charging voltage versus battery temperature. Temperature

Voltage Per Cell

Total Voltage (± 1%)

0 C

2.3773

57.05

5 C

2.3484

56.36

10 C

2.3215

55.72

15 C

2.2966

55.12

20 C

2.2737

54.57

25 C

2.2528

54.07

30 C

2.2339

53.61

35 C

2.2170

53.21

40 C

2.2021

52.85

45 C

2.1892

52.54

50 C

2.1783

52.29

Table 150: BU100 Charging Voltage Versus Battery Temperature

Note:

3BK 20942 AAAA TQZZA Ed.13

Avoid excessive battery gas leakage by not exceeding a charging voltage of 2.35 V per cell (56.40 V total) at 20 C.

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12.25.2 Discharging and Storage Discharging below 1.75 V per cell (42 V total) can damage the batteries. Batteries may be stored without recharging only for a restricted time. Therefore manufacturers instructions (delivered with the product) must be followed.

12.25.3 Front and Top View The following figure shows the front and top views of BU100.

Front View

Battery Retainer

Top View Vent Tube

Figure 419: BU100 Front and Top Views

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12.26 BU101 The BU101 is an optional feature used in Multistandard Outdoor BTS Cabinets. It provides an emergency DC power source for use in the event of a mains supply failure. The principal components of the BU101 are four high performance, sealed, lead-acid batteries that conform to the DIN 43539 standard. They are connected in series to provide a 48 VDC nom. power source, referred to as a branch. The battery branch is connected to ADAM or ADAM4. Connected to one of the battery terminals is a temperature sensor. This monitors the battery temperature. The output from the sensor is used by the SUMA to regulate the charging voltage and thus prevent battery overheating. The battery branch is fitted with venting tubes. The venting tubes discharge the gases produced during battery charging to the external environment.

3BK 20942 AAAA TQZZA Ed.13

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12.26.1 Charging The BU101 charging characteristics conform to the IEC 896-2 standard. The following table shows the battery type and the charging current limit. Battery Type

Limit

100 Ah

12 A

Table 151: BU101 Battery Type and Charging Current Limit The following table shows the recommended charging voltage versus battery temperature. Temperature

Voltage Per Cell

Total Voltage (± 1%)

0 C

2.3773

57.05

5 C

2.3484

56.36

10 C

2.3215

55.72

15 C

2.2966

55.12

20 C

2.2737

54.57

25 C

2.2528

54.07

30 C

2.2339

53.61

35 C

2.2170

53.21

40 C

2.2021

52.85

45 C

2.1892

52.54

50 C

2.1783

52.29

Table 152: BU101 Charging Voltage Versus Battery Temperature

Note:

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12 Power Supplies and Distribution

12.26.2 Discharging and Storage Discharging below 1.75 V per cell (42 V total) can damage the batteries. Batteries may be stored without recharging only for a restricted time. Therefore manufacturers instructions (delivered with the product) must be followed.

12.26.3 Front and Top View The following figure shows the front and top view of the BU101. The battery box is covered with a plate to secure the batteries. To Circuit Breaker

Exhausting Nipple Exhausting Tube Battery

Battery Connection Cable

Upper Block

Equipment Lables To Circuit Breaker Temperature Sensor Jumper

Battery Box (Part of BTS) Battery

Battery Jumper

Lower Block Warning Lables Exhausting Tube Supplier Information Lable

Front View

Top View

Figure 420: BU101 Front and Top View

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12.27 BU102 The BU102 is an optional feature used in External Battery Cabinets Outdoor. It provides an emergency DC power source for use in the event of a mains supply failure. The principal components of the BU102 are four high performance, sealed, gel batteries. They are connected in series to provide a 48 VDC nom. power source, referred to as a branch. The battery branch is connected to ADAM4 in a BTS cabinet. A temperature sensor is connected to one of the 0 V battery terminal. This monitors the battery temperature. The output from the sensor is used by the SUMA to regulate the charging voltage and thus prevent battery overheating. The battery branch is fitted with venting tubes. The venting tubes divert the gases produced during battery charging to the external environment.

12.27.1 Charging The BU102 charging characteristics conform to the IEC 896-2 standard. The following table shows the battery type and the charging current limit. Battery Type

Limit

90 Ah

8 A for one battery branch 16 A for more than one battery branch

Table 153: BU102 Battery Type and Charging Current Limit The following table shows the charging voltage versus battery temperature in case of default setting 2.29 V/ cell. Temperature

Voltage Per Cell

Total Voltage (± 1%)

0 C

2.38

57.125

5 C

2.3587

56.616

10 C

2.3370

56.1

15 C

2.3162

55.59

20 C

2.295

55.08

25 C

2.2737

54.57

30 C

2.2525

54.06

35 C

2.2312

53.55

40 C

2.21

53.04

Table 154: BU102 Charging Voltage Versus Battery Temperature

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12.27.2 Discharging and Storage Discharging is interrupted at 1.75 V per cell (42 V total) in order to avoid damaging the batteries. Batteries may be stored without recharging only for a restricted time. Therefore manufacturers instructions (delivered with the product) must be followed.

12.27.3 Front and Top View The following figure shows the front and top view of BU102. The battery box is covered with a plate to secure the batteries. TX Synthesizer 1

I From ENCT

Baseband Modulator

TX Synthesizer 2

TX Power Regulation

To combiner

Modulator & Up−converter

Duplexer

Q

TX Power Amplifier

TX Driver Amplifier

BBTX Transmitter part

Clean−up Oscillator

Reveiver part

TEPAxx/ TEPADHE ADC

To DEM on TRED

DDC

DRCS

IF Filter

RF Mixer

LNA

RX0

RX Synth. 1

From Antenna Network

RX Synth. 2 ADC

IF Filter

RF Mixer

LNA

RX1

TREA Digital part (positioned at analog module)

Figure 421: BU102 Front and Top View

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12.28 BATS The small battery BATS is a plug-in unit for the subrack STASR with a width of 28 TE. It is used in indoor cabinets. It provides an emergency DC power source for use in the event of a mains supply failure. It contains: A block of four batteries Printed board RIBATs Temperature sensor Battery breaker. The following figure shows the block diagram.

−

+ SBS8

+

+

−

−

SBS8

SBS8

+

−

SBS8

Batteries

Circuit Breaker

Temperature Sensor

RIBATS Feed Through Clamps

− + 48 V to ADAM

to BCB

Figure 422: BATS Block Diagram

12.28.1 Batteries The batteries are connected in series and have nominal 48 V and a capacity of 8 Ah. A BATS can be plugged in any unused subrack position. The principal components of BATS are four high performance, sealed, lead-acid batteries that conform to the IEC 896-2 standard. They are connected in series to provide a 48 VDC nom. power source, referred to as a branch. The DC clamps of the module are connected to the battery clamps on the front side of ADAM.

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12.28.2 Charging The BATS charging characteristics conform to the DIN 41773 (float charging) standard. The following table shows the battery type and the charging current limit. Battery Type

Charging Current Limit

8 Ah

2A

Table 155: BATS Battery Type and Charging Current Limit The following table shows the recommended charging voltage versus battery temperature. Temperature

Voltage Per Cell

Total Voltage (± 1%)

0 C

2.3773

57.05

5 C

2.3484

56.36

10 C

2.3215

55.72

15 C

2.2966

55.12

20 C

2.2737

54.57

25 C

2.2528

54.07

30 C

2.2339

53.61

35 C

2.2170

53.21

40 C

2.2021

52.85

45 C

2.1892

52.54

50 C

2.1783

52.29

Table 156: BATS Charging Voltage Versus Battery Temperature

Note:

In order to avoid excessive battery gas leakage from the battery, the charging voltage must not exceed 2.35 V per cell (56.40 V total) at 20 C.

12.28.3 Discharging and Storage Discharging below 1.75 V per cell (42 V total) can damage the batteries. Batteries may be stored without recharging only for a restricted time. Therefore manufacturers instructions (delivered with the product) must be followed. Storage of discharged batteries is not allowed.

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12.28.4 RIBATS The RIBATS is a small PCB mounted on the BATS frame. It collects the value of the temperature sensor and transfers this information to the OMU via the BCB. It is directly connected to a backplane connector of the STASR. The RIBATS is supplied from the BTS via the BCB, not from the batteries.

12.28.5 Temperature Sensor Connected to one of the battery terminals is a temperature sensor. This monitors the battery temperature. The output from the sensor is used by the SUMA to regulate the charging voltage and thus prevent battery overheating.

12.28.6 Battery Breaker A battery breaker is mounted on the front side of BATS: 2 x 60 A, 80 V. The battery breaker disconnects the connection between the batteries and ADAM.

12.28.7 Front and Top View The following figure shows the front view of the BATS.

Cicuit Breaker

DC Clamps Alcatel Product Identification Serial Number Identification Module Extractor

Figure 423: BATS Front View

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12.29 RIBAT The RIBAT board is part of the battery. Its task is to measure the battery temperature and to provide the OMU with the temperature value and the battery Remote Inventory information which includes the information for the battery type. Knowledge of the temperature value is necessary for charging. The board contains a BCB interface to transfer the information. Dependenting on the configuration, different interfaces are used: the BCB/EBCB, XBCB. The RIBAT is supplied from the BTS, not from the batteries. The power consumption is about 100 mA.

12.29.1 Block Diagram The connection and addressing differs for different configurations. The following figure shows the RIBAT block diagram. Remote Supply Voltage Input

detect BCB/ EBCB Con nection

Internal Addressing

External Addressing

BCB/ EBCB

NGTSL

Control Logic D XBCB IN

A RS 485 TTL

RI EEPROM

Line term.

XBCB Out

Loop BCB IF to cascaded RIBAT

Temperature Sensor

Figure 424: RIBAT Block Diagram

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12.29.2 Functional Description The board consists of: An NGTSL; which is the terminal for the ISL data link The Remote Inventory EEPROM including the Remote Inventory information The analog part for temperature measuring Address switching the BCB/EBCB, XBCB interfaces. In order to differ between internal or external addressing and internal or external connection, the BCB/EBCB connection is detected. The BCB/EBCB connection is true if the battery is located inside the BTS cabinet. In this case, addressing is switched to internal and the XBCB interface is disabled by the control logic. If the addressing is switched to external, the XBCB interface is active. If there is no other terminal or RIBAT connected to XBCB Out, it has to be terminated with a line termination plug. The analog part includes signal conditioning and an ADC to digitize the temperature value. An external PT100 temperature sensor is connected to the analog part. The ADC outputs are connected directly to the NGTSL alarm inputs. Power supply is provided remotely either from inside the BTS or via the XBCB connection. The internal battery of the outdoor BTS is located inside a side compartment. For this, the EBCB is fed to the side compartment. The RIBAT is connected to the EBCB via a flat band cable like it is done with a backplane. In this case addressing is switched to internal and the battery gets subrack number 0 (due to wire cutting on the flat band cable). Two cascaded batteries are possible by using different slot numbers (slot 1, slot 2) to address them. One wire of the flat band cable is used for this. The battery temperature range which can be measured is between -10 C and 70 C. This range is extended against the operating temperature range of the batteries (0 C to 50 C) and the minimum operating temperature range of the RIBAT to submit high or low temperature alarms. The measurement resolution is 0.5 C. Values below -10 C mean a short cut at the temperature sensor. Values above 70 C mean a not-connected or interrupted sensor.

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12.29.3 Appearance The RIBAT is a small board with a C96 connector for the flat band cable, a Sub-D 9 connector for the temperature sensor and two Sub-D 15 connectors for the XBCB input and output. The top view is shown in the following figure. The temperature sensor is mounted on one pole of the batteries to give a good thermal contact.

XBCB Connectors used in case of external batteries

EBCB Connector used in case of internal batteries

Connector for Temperature Sensor

Figure 425: RIBAT Top View

12.29.4 XBCB Bus Termination Because the XBCB is an RS-485 bus, it has to be terminated at the end of the line. At the BTS side this is already done on the COAR. At the RIBAT side, this is done by a termination plug. The termination plug consists of an 15-pin Sub-D male connector and a small PCB (50 mm x 30 mm) with termination and pull up/pull down resistors on it. The plug is connected to the XBCB Out at the RIBAT. In case of cascaded RIBATs, the plug is connected to the remaining XBCB Out.

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12.30 DCDP The DCDP is used in outdoor BTS A9100 versions. It distributes -48 VDC to the equipment modules. Each DC output is over-current protected by its own circuit breaker. The circuit breakers are reset manually. The DCDP is housed in BTS compartment 1 above the top STASR. The following figure shows the circuit schematic. 0 V Input

−48V Input

Line Load

X1

XIOB

X1

1

6

Optional Equipment

X2

1

6

Optional Equipment

X3

1

6

Optional Equipment

X4

1

6

Spare

X5

1

6

Heat Exchanger 1

X6

Heat Exchanger 2

X7

Heat Exchanger 3

X8

Subrack 1/1

X9

Subrack 1/2

X10

Spare or Subrack 1/3

X11

Subrack 2/1

X12

Subrack 2/2

X13

Subrack 2/3

X14

F1 15 A

F2 15 A

F3 25 A

F4 25 A

F5 25 A

F6 25 A

F7 25 A

F8 25 A

Figure 426: DCDP Circuit Schematic

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The DCDP 0/ -48 VDC input supply is distributed to the front panel output connectors, via six circuit breakers. The circuit breaker trip currents are: 15 A for F1, which supplies the connectors for the XIOB and optional equipment (such as microwave or termination of network line equipment) 15 A for F2, which supplies the connectors for the heat exchangers 25 A for F3 - F8, which supply the connectors for the STASRs. The 0 VDC input is grounded in the DCDP and connected to each output connector.

12.30.1 Front and Top View The following figure shows the front and top views of the DCDP. X1

X2

X3

X4

X5 F1

X6

X7

F2

F3

F4

F5

F6

F7

F8

X9

X10 X11

X12 X13

X14

X8

Front View

Equipment Labels

Red 0 V

Blue −48 V

Top View

Figure 427: DCDP Front and Top View

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12.30.2 Front Panel Connectors The following table describes the DCDP front panel connectors. Connector

Description

X1

Provides 0/ -48 VDC for the XIOB.

X2 - X4

Provides 0/ -48 VDC for the microwave equipment, if fitted.

X5

Spare.

X6 - X8

Provides 0/ -48 VDC for the heat exchanger controllers.

X9 - X14

Provides 0/ -48 VDC for the STASRs.

Table 157: DCDP Front Panel Connectors

12.30.3 Rear Panel Connectors The following table describes the DCDP rear panel connectors. Connector

Description

-48 V IN

Provides the -48 VDC input.

0 V IN

Provides the 0 VDC input.

Ground

Provides the ground connection for the unit.

Table 158: DCDP Rear Panel Connectors

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12.31 DCDU The DCDU is used in Compact BTS Outdoor DC versions. It distributes -48 VDC to the equipment modules. Each DC output is over-current protected by its own circuit breaker. The circuit breakers are reset manually. The DCUC is housed in the BTS compartment above the cable entry. The following figure shows the circuit schematic. 0V Rail −48V Rail

Figure 428: DCDU Circuit Schematic The DCDU 0/ -48 VDC input supply is distributed to the front panel output connectors, via six circuit breakers. The circuit breaker trip currents are: 70 A for F1, which supplies the complete BTS and is the main breaker 25 A for F2 and F3, which supply the connectors for the STASRs. 15 A for F4, which supplies the connectors for the XIOB and optional equipment (such as microwave or termination of network lines equipment) 15 A for F5, which supplies the connectors for the heat exchangers 15 A for F6, which supplies the connectors for the heater. The 0 VDC input is grounded in the DCUC and connected to each output connector.

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12.31.1 Front and Side View The following figures show the front and side views of the DCDU.

0V

−48V

0V −48V 0V −48V

X1 X2 X3 X4 X5 X6 X7 X8 X9 X10

OPTIONS

SR1

SR2

HEX

OPT

XIOB

HEX

HEAT

BTS

70 A

Equipment Labels

Figure 429: DCDU Front View

Figure 430: DCDU Side View

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12.31.2 Front Panel Connectors The following table describes the DCDU front panel connectors. Connector

Description

X1 - X3

Provides 0 VDC for the optional equipment.

X4 - X6

Provides -48 VDC for the optional equipment.

X7, X8

Provides 0/ -48 VDC for the Heat Exchanger.

X9, X10

Provides 0/ -48 VDC for the XIOB.

Table 159: DCDU Front Panel Connectors

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12.32 DCDUE The DCDUE is used in DC A9100 MBS GSM Evolution Outdoor versions. It distributes -48 VDC to the equipment modules. Each DC output is over-current protected by its own circuit breaker. The circuit breakers are reset manually. The DCDUE is housed in the left side of the BTS compartment. The following figure shows the circuit schematic.

Figure 431: DCDUE Circuit Schematic The DCDUE 0/ -48 VDC input supply is distributed to the front panel output connectors, via four circuit breakers. The circuit breaker trip currents are: 100 A for F1, which supplies the complete BTS 15 A for F2, which supplies the Service Light 15 A for F3 and F4, which supply the heaters.

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The following figure shows the front and side views of the DCDUE.

Figure 432: DCDUE Front and Side View

12.33 DCMU The DCMU is used in DC A9100 MBS GSM Outdoor versions. It distributes -48 VDC to the equipment modules. Each DC output is over-current protected by its own circuit breaker. The circuit breakers are reset manually. The DCMU is housed in the left side of the BTS compartment. The following figure shows the circuit schematic.

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EXTERNAL DC IN −48V

0V

MBO ROOF 0V BOLT

0V BOLT

0V

C1

BUSBAR CONNECTION X9

F4

F3

15A

15A

F2

15A

F1

−48V

70A

0V −48V

X8

X7

X6

X5

X4

X3

0V

LIGHT 1 LIGHT 2

_ +

1

2

_

DC OUT / 48V

DC IN / 48V

X21

X20

−48V

X2

X1

2

DC OUT / 48V

0V

0V

0V

−48V

−48V

−48V

1

Main ground

DC IN / 48V

K2

K1

F5

_

+

+

1

−48V 0V

−48V 0V

HEATDC 1

HEATDC 2

2

_ +

Figure 433: DCMU Circuit Schematic The DCMU 0/ -48 VDC input supply is distributed to the front panel output connectors, via four circuit breakers. The circuit breaker trip currents are: 75 A for F1, which supplies the complete BTS 15 A for F2, which supplies the Service Light 15 A for F3 and F4, which supply the heat exchangers.

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The following figure shows the front and side views of the DCMU.

70A

15A

15A

15A

Equipment Labels BTS

SERVICE LIGHT

HEATING 1

HEATING 2

F1

F2

F3

F4

Front View

Side View

Figure 434: DCMU Front and Side View

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12.34 DCUC The DCUC is used in Compact BTS Outdoor versions. It distributes -48 VDC to the equipment modules. Each DC output is over-current protected by its own circuit breaker. The circuit breakers are reset manually. The DCUC is housed in the BTS compartment above the ACUC. The following figure shows the circuit schematic. 0V Rail 0V Input

− 48 V Rail −48V Input 25A

25A

15A

15A

F1 SR1

F2 SR2

F3 F4 OPT HEX

X1 0V NU GND −48V

0V NU GND −48V

SR 1

SR 2

0V

−48V

X20

X21

X2 X3

X4 X5 X6

OPTIONAL EQUIPMENT

0V

0V −48V

X7 X8

HEX 5

−48V

X9 X10

XIOB

Figure 435: DCUC Circuit Schematic The DCUC 0/ -48 VDC input supply is distributed to the front panel output connectors, via four circuit breakers. The circuit breaker trip currents are: 25 A for F1 and F2, which supply the connectors for the STASRs. 15 A for F3, which supplies the connectors for the XIOB and optional equipment (such as microwave or termination of network lines equipment) 15 A for F4, which supplies the connectors for the heat exchangers The 0 VDC input is grounded in the DCUC and connected to each output connector.

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12.34.1 Front and Side View The following figure shows the front and side views of the DCUC.

−48V

0V X1

X2

X3

X4

X5

0V −48V 0V −48V

X6

OPTIONS

SR1

X7

X8 X9 X10

HEX

SR2

OPT

XIOB

HEX

0V −48V

Equipment labels Front View

Black 0V

Blue − 48V

GND Side View

Figure 436: DCUC Front and Side View

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12.34.2 Front Panel Connectors The following table describes the DCUC front panel connectors. Connector

Description

X1 - X3

Provides 0 VDC for the optional equipment.

X4 - X6

Provides -48 VDC for the optional equipment.

X7, X8

Provides 0/ -48 VDC for the Heat Exchanger.

X9, X10

Provides 0/ -48 VDC for the XIOB.

Table 160: DCUC Front Panel Connectors

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13 ACRI

13 ACRI The sections are supported with diagrams, where necessary, showing the functional blocks and their interfaces. A drawing of the physical appearance of the module is also included, showing the connectors and controls.

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13 ACRI

13.1 ACRI Functional Description The ACRI is used in indoor and outdoor BTS A9100 versions. There are two functionally identical variants. The sole difference is that the indoor variant has the BCB interface available on the backplane connector. The ACRI: Collects alarms from the SRACDC modules Controls the SRACDC FANUs. The ACRI is housed in the SRACDC. The following figure shows the functional block diagram. ANPS

−48 VDC Input Supply

DC/DC Converter

Output Voltages

FACB

FANUs

Fan Alarms

Power Alarms

BCB ASIC

XBCB

RI EEPROM

Figure 437: ACRI Block Diagram

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13 ACRI

The ACRI consists of the functional entities described in the following table. ANPS

The ANPS which the -48 VDC input supply to the DC voltages required by the other components. For more information on the ANPS, refer to AN Power Supply (Section 10.1.5).

FACB

The FACB reports fan faults and controls the FANUs that cool the SRACDC modules. For more information on the FANUs and FACB, refer to Fan Units (Section 11.1.1) and Fan Control (Section 11.1.2), respectively.

XBCB

The way in which the BCB ASIC transfers information to the OMU in the SUMP depends on the ACRI variant. For the indoor variant, the information is transferred via the BCB, available on the backplane. For the outdoor variant, the information is transferred via the XBCB connector on the front panel. This information consists of: Alarms from the FACB Alarms from the battery, PM08s and BCU1 Remote Inventory information.

RI

The Remote Inventory is used to store information about the module (part number, name, serial number, etc.). It consists of an EEPROM which is connected to the BCB ASIC.

Table 161: ACRI Functional Entities

13.2 ACRI LEDs and Alarms The two LEDs on the front panel are connected in parallel. They indicate the state of the + 5 VDC output of the ANPS. The alarm information consists of: Fan status Number of PM08s fitted Number of PM08s that are serviceable Battery malfunction BCU1 failure.

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13.3 ACRI Front Panel The following figure shows the front panel of the ACRI. Camloc Fastener

LEDs

POWER ON

Connector

Handle

Figure 438: ACRI Front Panel The ACRI XBCB connector provides a: + 5 VDC signal to enable ANPS Serial interface for the transfer of alarms and Remote Inventory information to the OMU.

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14 Antenna Connector Lightning Protectors

14 Antenna Connector Lightning Protectors The sections are supported with diagrams, where necessary, showing the functional blocks and their interfaces. A drawing of the physical appearance of the modules is also included which shows the connectors.

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14 Antenna Connector Lightning Protectors

14.1 Lightning Protector Functional Description Antenna connector lightning protectors are used in outdoor BTS A9100 versions. They protect the RF inputs and outputs from the effects of nearby or direct lightning strikes. The lightning protectors are described in the sections: Operating principles Types.

14.1.1 Operating Principles Lightning strikes and induced pulses have characteristics which are very different from the desired RF signals transmitted and received by the BTS A9100. These differences allow a lightning strike to be suppressed. The BTS A9100 lightning protectors are based on a ’quarter-wavelength shorting stub’. This has the effect of passing all operational RF signals, but effectively shorting any lightning voltage spikes to the cabinet’s chassis ground. The protectors can be used in both the transmit and receive signal paths. They are installed to form part of the cabinet’s external RF connections.

14.1.2 Types Even though the LPQG, LPQD, LPQP, and LPQM types can have different suppliers, the product numbers are always identical. The following table lists the product numbers. Type

Variant Product Numbers

LPQG

3BK 05817 AAAA

LPQD

3BK 05818 AAAA

LPQP

3BK 08691 AAAA

LPQM

3BK 25444 AAAA

Table 162: Antenna Connector Lightning Protector Types and Variants The AAAA variants are functionally identical, differing only in dimensions and appearance.

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14.1.3 Lightning Power Spectrum Quarter-wave stub lightning protectors remove lightning current on a frequency selection basis. The following figure shows the power spectrum of a typical lightning strike. Amplitude Density (V/m/Hz)

0

2

100

Frequency (kHz)

Figure 439: Lightning Strike Power Spectrum As lightning has a power spectrum with very little energy above 100 kHz, a band-pass protection filter can be used. This passes the frequencies of interest (which are much above 100 kHz), yet rejects the low frequencies generated by lightning. The antenna connector lightning protectors perform this function using the quarter-wavelength shorting stub.

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14.1.4 Quarter-Wave Stub The quarter-wave stub is a coaxial line exactly one quarter-wavelength long. One end is connected to the through path and the other end is simply shorted. The following figure shows the equivalent circuit of the antenna connector lightning protectors. Signal Conductor

Signal Path

Signal Summed Signal Split Shield/ Chassis Ground 100 % Reflection (180 Delay) Shorting Stub = l /4 (+ 90 Delay for Signals of F = 1/l)

Short Circuit

Figure 440: Antenna Connector Lightning Protectors Equivalent Circuit During normal operation, the RF transmission signal arrives at the input of the shorting stub, where it is split. One part travels along the matched quarter-wavelength stub, thus changing its phase by 90. At the short, the signal is reflected and hence shifted by a further 180. It then travels back along the stub and is again shifted by 90 by the time it reaches the junction. The other part continues along the straight-through path. The reflected and straight-through signals are therefore exactly one cycle out of phase at the junction. The signals are summed at the junction. Apart from negligible jitter, the resulting signal is identical to the original signal. In contrast to the high frequency transmission signals, the much lower frequency lightning spectrum is not matched to the stub. Its components are, effectively, shorted to ground (as they are shifted completely out of phase by the short). At the same time, they have a negligible shift when travelling down the stub.

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14.2 Lightning Protector Electrical Characteristics The following table shows the electrical characteristics. The lightning protectors have little effect on system performance during normal operation. Characteristic

LPQG

LPQD

LPQP

LPQM

Usable frequency range:

870 - 970 MHz

1700 - 1900 MHz

1800 - 2000 MHz

870 - 970 MHz and

Insertion loss:

≤ 0.1 dB

≤0.1 dB

≤0.1 dB

≤0.1 dB

VSWR:

≤ 1.1

≤1.1

≤1.1

≤1.1

Impedance:

50

50

50

50

1700 - 2200 MHz

Table 163: Lightning Protector Electrical Characteristics

14.3 Lightning Protector Appearance Lightning protectors can be designed with an internal filter or with a shorting stub (depending on the manufacturer). The following figure shows the appearance of the antenna connector lightning protector with shorting stub. 7/16 female coaxial RF Cable Connector

V−Shaped Grounding Washers Plinth

Sealing Washers

Quarter Wavelength Shorting Stub 7/16 female coaxial RF Cable Connector

Figure 441: Lightning Protector Appearance with Shorting Stub The protectors are mounted in the plinth at the bottom of the cabinet. Each protector consists of a coaxial through-connection with the protection mechanism located below the plinth.

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15 Range Extension Kit

15 Range Extension Kit This chapter describes the range extension kit (REK) which is aimed at enhancing the capabilities of the Evolium BTS A9100 in terms of coverage. The REK is designed to compensate the feeder losses which significantly impact the density of sites to be implemented over the service area of GSM networks.

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15 Range Extension Kit

15.1 Introduction to REK The basic advantage of the REK is to enhance the capabilities of the Evolium BTS A9100 in terms of coverage by increasing the size of the cell, which significantly impacts the density of sites to be implemented over the service area of GSM networks. Other advantages are range extension of road cell, compensation of the eventual error of site location by radio network planning and compensation of RF performance impairment due to antenna feeder and ANx losses. The REK can be used with a wide variety of Evolium BTS A9100 indoor and outdoor configurations in GSM 900 with a coupling constraint of maximum one TRX/TRE to each antenna. Cross-polarized antennas can still be used respecting this constraint. For practical reasons, configurations are limited to a maximum of six TREs per BTS site, assuming a 3x2 configuration. The REK is designed to minimize BTS and system impacts. The BTS has no knowledge of the REK’s presence and is not involved in its configuration. Configuration of the REK is reduced to manual attenuator setting at installation. Supervision is minimal. It only involves external alarms to the BTS and there is no recovery mechanism. The system impact concerns the handling of these new external alarms at the OMC-R level. The REK is composed of two modules: A Masthead Amplification Box, to be installed close to the antenna, featuring power amplification downlink and low noise amplification uplink, along with proper supervision means A Power Distribution Unit, to be installed in the BTS cabinet or close to the BTS, providing DC power for the purpose of remotely feeding the masthead amplification module through the antenna feeder and collecting the alarm signals.

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15.2 Overall Description 15.2.1 Architecture The following figure shows a two TRX configuration. The equipment has three sections: The Masthead Amplification Box. Each MAB provides bi-directional amplification for one antenna port. The antennas are not part of the MAB. The use of two separate antennas or one cross-polar antenna (decoupling >25 dB) is possible The feeder cables. Up to 11 dB of loss is supported allowing 1/2” cables with up to 100 m length if used as an extension for a standard Evolium BTS A9100. The DC feed and supervision of the masthead equipment is also done via the feeder cables The Power Distribution Unit. This module provides the interface towards the BTS. The power supply for the masthead equipment and the alarm handling is provided by this module. This module is located beside the BTS rack for indoor applications and inside the cabinet for outdoor configurations. Antenna Port 1

Antenna Port 2

MAB

MAB

SV

Legend: MAB

Masthead Amplification Box

B

Bias and Lightning Protection

SV

Supervision Circuit

PDU

Power Distribution Unit

PS

MAB Power Supply

AL

Alarm Interface

ANx

Antenna Network

BTS

Base Transceiver Station

SV

B

B

RF feeder cables

PDU

PS B

B AL

ANx

BTS

Figure 442: REK Architecture

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15.2.2 Configurations The REK is usable in site configurations featuring one antenna per TRX, and therefore well adapted for the implementation of air combining. The technical constraints are: no TX coupling in the BTS (no ANY in the configuration), respectively the sectors, which means only one TRE transmitting on each antenna. (On the ANC, the included combiner will be disabled by removal of the two bridges and the TREs connected directly to the duplexers). The different possible site configurations are shown separately below.

15.2.2.1 With One TRE The following figure shows a one-cell configuration using the REK.

MAB

MAB

MAB

PDU

A

ANX

MAB

PDU

B

or

A

B

ANC

nc

nc TRE 1

nc

TRE 1

On the ANC, the two bridges are removed

nc

− If RX antenna dive rsity is absolutely required, a second MAB must be installed on the path B Legend: MAB Mast Amplification Board PDU Power Distribution Unit

Figure 443: Cell with One TRE If RX antenna diversity is absolutely required, a second MAB must be installed on path B.

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15.2.2.2 With Two TREs and RX Antenna Diversity The figure below shows the configuration for one cell with two TREs and RX antenna diversity.

MAB

MAB

MAB

MAB

PDU

PDU

A

B

A

or

ANX

B

nc TRE 1

On the ANC, the two bridges are removed

ANC

TRE 2

TRE 1

nc TRE 2

Legend: MAB Mast Amplification Board PDU Power Distribution Unit

Figure 444: Cell with two TREs and RX Antenna Diversity Active

15.2.2.3 3x1 without RX Antenna Diversity, with ANX As shown in Figures443 and 444 above, one MAB is required per TRE. However, one PDU can supply two MABs (two TREs connected) These two TREs do not need to belong to the same sector. Thus a 3x1 configuration requires only two PDUs if there is no RX antenna diversity.

MAB

MAB

MAB

PDU1

A

B ANX Sector 1

PDU2

A

B ANX Sector 2

TRE 1 nc TRE 1 Legend: MAB Mast Amplification Board PDU Power Distribution Unit

A

B ANC Sector 3

nc

TRE 1

nc

Figure 445: 3x1 Configuration without RX Antenna Diversity - ANX Variant

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15.2.2.4 3x1 without RX Antenna Diversity, with ANC A 3x1 configuration without RX antenna diversity using the ANC is shown in the following figure.

MAB

MAB

MAB

PDU1

A

B

PDU2

A

ANC Sector 1 nc

nc nc

TRE 1

B

A

ANC Sector 2 nc

nc

nc

nc

TRE 1

B ANC Sector 3

TRE 1

nc nc

On each ANC, the two bridges are removed Legend: MAB Mast Amplification Board PDU Power Distribution Unit

Figure 446: 3x1 Configuration without RX Antenna Diversity - ANC Variant

15.2.2.5 3x2 with ANX The following figure shows a 3x2 configuration using the ANX.

MAB

MAB

MAB

PDU 1

A

MAB

MAB

PDU 2

B ANX Sector 1

TRE 1 TRE 2 Legend: MAB Mast Amplification Board PDU Power Distribution Unit

A

PDU 3

B ANX Sector 2

TRE 1

MAB

TRE 2

A

B ANX Sector 3

TRE 1

TRE 2

Figure 447: 3x2 Configuration - ANX Variant

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15.2.2.6 3x2 with ANC The figure below shows a 3x2 configuration using the ANC.

MAB

MAB

MAB

PDU 1

A

MAB

PDU 2

B

A

ANC Sector 1 nc TRE 1

MAB

PDU 3

B

A

ANC Sector 2 nc

TRE 2

nc TRE 1

MAB

nc TRE 2

B ANC Sector 3 nc

TRE 1

nc TRE 2

On each ANC, the two bridges are removed Legend: MAB Mast Amplification Board PDU Power Distribution Unit

Figure 448: 3x2 Configuration - ANC Variant

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15.2.2.7 Extended Cell Configuration The extended cell configuration is composed of one Inner Cell with up to four TREs, and one Outer Cell with up to four TREs. The REK is used in the Outer Cell. INNER CELL

OUTER CELL

MAB

A

B

MAB

MAB

MAB

PDU 1

ANC Sector 1 A

TRE 2 TRE 4 TRE 1 TRE 3

PDU 2

B

A

ANC Sector 2 nc TRE 1

nc TRE 2

B ANC Sector 2 nc

TRE 3

nc TRE 4

In the Outer Cell, the bridges are removed on each ANC Legend: MAB Mast Amplification Board PDU Power Distribution Unit

Figure 449: Extended Cell Based on ANC (and SUMA) Installation In case of an Evolium BTS 9100 equipped with ANX and SUMP, the SUMP has to be replaced by a SUMA. INNER CELL

A

B

OUTER CELL

MAB

MAB

MAB

MAB

ANX Sector 1 PDU

PDU

ANY TRE 2 TRE 4 TRE 1 TRE 3 Legend: MAB Mast Amplification Board PDU Power Distribution Unit

A

B ANX Sector 2

TRE 1

TRE 2

A

B ANX Sector 2

TRE 3

TRE 4

Figure 450: Extended Cell Based on ANX (and SUMA) Installation

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15.2.2.8 BTS Configurations Due to limited DC power distribution in outdoor cabinets which can accept no more than three PDUs and external alarm limitation, the configurations are limited to a maximum of six TREs per BTS. In addition, no multiband configuration is foreseen. Considering these limitations, the following configurations are possible.

ANC

Rack Layout Type

Notes

X

X

1x1...4

(1)

X

X

X

2x1...2

X

X

X

X

2x1...2

3x1

X

X

X

X

3x1

MEDI

1x4 Low Loss

X

X

X

X

2x1...4 Low Loss

(1)

MEDI

3x.2

X

X

X

X

3x1...4

(1)

MEDI

Extended Cell 1x1...4, 1x1...4 Low Loss

X

X

X

1x1...4 + 1x1...4 Low Loss

(2)

Rack

Configuration Type

Indoor

Outdoor

ANX

MINI

1x1...2

X

X

MINI

2x1

X

MINI

2x2

MINI

Table 164: BTS Configurations with REK (1) These BTS configurations are without TX coupling: no ANY. (2) In the 1x1...4 Low Loss part, the two bridges of each ANC are removed. For rack layouts see Configurations - Rack Layouts (Section 2).

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15.3 Masthead Amplification Box The Masthead Amplification Box for GSM 900 (part number 3BK 08848 AAAA) is a bi-directional amplifier for one antenna port. It is designed for outdoor installation on a tubular mounted support below the antenna. The Masthead Amplification Box architecture is shown in the following figure. Legend: PDU Power Distribution Unit

D U P L E X E R

Det To/From PDU

Bias & Alarm

To/From Antenna

Figure 451: Block Diagram of the Bi-directional Amplifier The bi-directional amplifier is composed of: A circulator at the BTS input A power amplifier in the Tx path A low noise amplifier in the Rx path A duplexer at the antenna output A reflected power detector at the output of the power amplifier A Bias T and a lightning protection module A power regulation (DC voltage regulators for the Tx and Rx amplifiers), not represented in figure above Alarm circuitry, collecting alarms (from DC regulators, Tx and Rx amplifiers), not represented in figure above Two switches for adjusting the gains of the Tx and Rx paths (independent from each other), not represented in figure above.

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15.3.1 Transmit Power Amplifier and Required Attenuators The required output power (transmit) of the masthead equipment (including output filter) is 44.5 dBm (28 W). To adapt the amplifier to the different BTS types and antenna cable losses, an attenuator in front of the amplifier is needed. Because of the high input power in the standard Evolium BTS A9100, this attenuator is split into a fixed part (8 dB) and a variable part (range 0...15.5 dB). The fixed attenuator is built to limit the signal level at the output of the variable attenuator to maximum 2.5 W (34 dBm). The variable attenuator is digital and can be manually adjusted in steps of 0.5 dB depending on BTS type and cable losses (see the following figure). The variable attenuator supports an input power in the range of 21.65 to 32.75 dBm and is dimensioned for up to 34 dBm (i.e., 2.5 W) to allow some margin.

Figure 452: RX and TX Attenuation Setting The amplifier itself is composed of one class A and two class AB stages. The output stage is a quadrature to improve the reliability and manufacturability of the design. An isolator is added on the output for protection from operation in a high output VSWR as well as reverse intermodulation performance. The insertion loss is 0.35 dB. The gain is maintained within ±1.5 dB tolerance by employing passive temperature compensation on the amplifier input. This maintains the gain within the required tolerance over the whole range of frequency, temperature, power supply and input power variations, so there is no control loop on the amplifier gain. The amplifier can be damaged, if the maximum input power is >41 dBm. A thermal protection/shut-down circuitry is incorporated in order to prevent the amplifier from damage in case of a too high temperature inside the Masthead Amplification Box enclosure. A DC regulator is introduced to avoid gain fluctuations of the power amplifier, because the amplifier is DC-fed via the feeder cable which introduces up to 3 V of voltage drop (depending on the cable length and DC current).

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15.3.2 Receive Amplifier As shown in Figure 451, the receiver amplifier is a balanced two-stage design. Each arm of the balanced amplifier contains two standard LNAs (the first stage is GaAs and the second stage is bipolar for GSM 900). The maximum overall gain measured from the antenna input to the output of the Masthead Amplification Box is 16 dB for GSM 900. The noise figure remains below 2.5 dB (for temperatures up to 50 C. Temperature compensation is provided through a passive temperature variable attenuator on the amplifier output. Its insertion loss is 2 dB. A DC voltage regulator is also included to minimize the LNA gain variations due to input voltage fluctuations. The receive amplifier includes a manually settable attenuator at its output, which allows decreasing the gain by 10 dB in steps of 1 dB in order to adapt for the different cable lengths (see Figure 452). It is a digital attenuator, controlled by a manual rotary switch. Its insertion loss is 2 dB in GSM 900. A bandpass filter is added to ensure adequate rejection of the transmit band signal coming into the receive amplifier input. Its insertion loss is 1.5 dB. Since the receive amplifier involves two low noise amplifiers in parallel, any single LNA failure will only produce a 6 dB decrease of the amplifier gain.

15.3.3 Output Duplexer The masthead output duplexer is located at the antenna port of the masthead box. It has to prevent the Rx path from being interfered by the own Tx signals and to suppress the Tx noise in the Rx band. A further function is the attenuation of Tx harmonics if necessary. In order to achieve a low level of intermodulation (-110 dB) at the output of the low noise amplifier, the Tx/Rx isolation is 80 dB. The duplexer has a Tx insertion loss of 1.1 dB for GSM 900. The Rx insertion loss is 1.2 dB for GSM 900.

15.3.4 Input Splitter The masthead input splitter routes the Tx signal coming from the antenna cable to the Tx power amplifier and the output signal of the LNA to the antenna cable. As shown in Figure 451 it is implemented with a circulator. Together with the Masthead Amplification Box output duplexer, it prevents the masthead equipment from self-oscillating. Another function of the input splitter is to prevent the Masthead Amplification Box receive amplifier from generating intermodulation by reversely injected Tx signals. Its insertion loss in Tx is 0.35 dB and in Rx is 0.3 dB.

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15.3.5 RF Specifications The RF specifications of the Masthead Amplification Box are summarized in the following table. Parameter

Requirement

Transmit Path Frequency range

925 - 960 MHz

Impedance

50

Input VSWR

<1.5 at the input of the masthead amplification box

Output power

44.5 dBm ±1.5 dB

Gain variation

Max ± 1.5 dB versus frequency, temperature and input power ranges

Variable attenuator

Tunable from 0...15.5 dB in steps of 0.5 dB

Max input level for attenuator setting 0 dB

≤41 dBm

Receive Path Frequency range

880 - 915 MHz

Impedance

50

Input, Output VSWR

<1.5

Gain in Rx path

16 dB ±1 dB for -10 to + 40 C 16 dB ±1.5 dB for -40 to + 60 C

Attenuator setting at output

0...10 dB in steps of 1 dB

Output duplexer Tx bandpass

925 - 960 MHz

Rx Bandpass

880 - 915 MHz

Tx/Rx isolation in Tx and Rx band

70 dB minimum

Table 165: RF Specifications of the Masthead Amplification Box

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15.3.6 Supervision Circuits and Alarm Interface Two alarms per TRX function are provided by the Masthead Amplification Box, one fatal and one non fatal. The fatal alarm is raised in case of a fatal failure (e.g., power amplifier out of order). The non-fatal alarm is raised in case of a non-fatal failure (e.g., acceptable performance degradation). The signaling of the alarms from the MAB to the PDU is done via the corresponding antenna cable, using low frequency signals that are coupled onto the RF coaxial lines via the Bias tee and lightning protection module. An alarm is active if its corresponding frequency is present. The fatal alarm is activated by: High reflected power at the power amplifier output High current draw by the power amplifier Low input voltage to the power amplifier High temperature. The non-fatal alarm is activated by: Low bias current on the transistors in the receive amplifier (in one or both arms of the balanced amplifier) High bias current on the transistors in the receive amplifier (in one or both arms of the balanced amplifier).

15.3.7 Bias Circuit and Lightning Protection For each antenna cable this circuit is located at both ends, i.e., inside the MAB and inside the PDU. The bias circuit is used for remote DC feeding and alarm signaling of the masthead box. It is the first circuit at the input of the MAB on the feeder cable side, so that the DC signal is extracted before any RF function is performed in the MAB. Its insertion loss in Tx is 0.5 dB and includes a lightning protector.

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15.3.8 Mechanical Characteristics The overall dimensions of the MAB are 38 x 32 x 27 cm (see the following figure). The weight is maximum 19 kg. Alcatel ID no. label Alcatel serial no. label M6

7/16 female

Figure 453: Masthead Amplification Box The enclosure is constructed from aluminium pieces. The back side is so formed that it can be easily mounted onto the tower. The front side is covered with fins which provide cooling. The receive components are mounted in the back half since they do not dissipate much heat. The transmit amplifier and DC power regulation are mounted in the front half. The two halves of the enclosure are bolted together with an environmental seal between them. All RF connectors are placed on the bottom side of the enclosure. Access for gain adjustment is provided on the bottom side via a removable cover. The RF connector type is 7/ 16 female on both sides of the MAB (towards the PDU and towards the antenna). The MAB is fitted with a M6 threaded rod for 2 grounding via a yellow/green 16 mm ground cable (in the installation kit).

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15.4 Power Distribution Unit The Power Distribution Unit (part number 3BK 08850 ABAA) provides power supply and alarm interface for two Masthead Amplification Boxes. It is located at the BTS site, either wall-mounted close to the BTS in the case of an indoor site or integrated inside the BTS cabinet in the case of an outdoor BTS. The primary voltage of the Power Distribution Unit is -48 VDC. The secondary voltages are 33.7 VDC and are fed to the two Masthead Amplification Boxes via Bias tees which are integrated parts of the module. The Bias tees also provide the lightning protection at the BTS end of the feeder cable. The Power Distribution Unit includes two separate DC/DC converters, each providing one Masthead Amplification Box with DC power. The power consumption for the Power Distribution Unit is 600 W at a power dissipation of 115 W. The Power Distribution Unit architecture is shown in the following figure. Feeder cable

Feeder cable

PDU Power supply control & supervision

BIAS T

DC/DC converter

Alarm interface

TRX 1

Alarm 1

DC/DC converter

DC filter

−48 V DC

BIAS T

Alarm interface

Alarm 2

TRX2

Legend: PDU Power Distribution Unit

Figure 454: Power Distribution Unit Block Diagram

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15.4.1 Supervision and Alarm Interfaces The two alarm interfaces located in the Power Distribution Unit collect the alarms corresponding to each TRX and coming from the corresponding Masthead Amplification Box (extraction in the Bias T, DC reject filtering and detection of the alarm low frequency) or from the corresponding DC/DC converter through the power supply control and supervision circuit. The Masthead Amplification Box alarm signals consist of low frequency signals that are extracted from the feeder cables via the Bias T and after DC cut filtering. An alarm is active if its corresponding frequency is present. The Power Distribution Unit itself has only one alarm corresponding to a DC/DC converter failure, which is fatal. The list of alarm causes and corresponding actions is summarized in the following table.

Alarm Cause

Fatal

Non Fatal

High reflected power at the power amplifier output.

X

-

DC power shut down in Power Distribution Unit.

High current draw by the power amplifier.

X

-

DC power shut down in Power Distribution Unit.

Low input voltage to the power amplifier.

X

-

None.

High temperature in the power amplifier.

X

-

Power shut down in PA at Masthead Amplification Box level, no action on the LNA. Automatic recovery for both power and alarm signal below a defined temperature level.

High and low bias current on the transistors in the receive amplifier.

-

X

None.

DC/DC converter failure.

X

-

None.

Action

Table 166: List of Alarms The alarm interfaces provide an external alarm interface towards the BTS (one logical signal per alarm). The Power Distribution Unit collects the fatal and non-fatal alarms for each TRX and groups the two non-fatal alarms together using an OR function, resulting in three external alarms at the output of the alarm interfaces: Fatal alarm TRX1 Fatal alarm TRX2 Non-fatal alarm TRX1 or TRX2.

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When several PDUs are used in the same BTS, the non-fatal alarms of the different PDUs are grouped in a single alarm in order to reduce the number of alarms. This is accomplished by alarm circuitry in the PDU which allows the connection of those alarms in parallel by an alarm combining cable.

15.4.2 LEDs LEDs are provided on the front panel of the Power Distribution Unit to indicate the status and the alarms. The following table describes each LED and provides a definition of their various operational states.

LED

Meaning

Color

LED On

LED Off

LED Flashing

TRX 1 MAB

Fatal alarm

Red

Alarm on

Alarm off

-

TRX 1 MAB

Non-fatal alarm

Red

-

Alarm off

Alarm on

TRX 2 MAB

Fatal alarm

Red

Alarm on

Alarm off

-

TRX 2 MAB

Non-fatal alarm

Red

-

Alarm off

Alarm on

TRX 1 DCDC

DC/DC Converter failure

Red

Alarm on

Alarm off

-

TRX 2 DCDC

DC/DC Converter failure

Red

Alarm on

Alarm off

-

DC INPUT STATUS

DC Input status

Green

DC input OK

No DC input

-

Table 167: LEDs of Power Distribution Unit

15.4.3 Reset Buttons If the power cable is connected to the PDU before complete installation has been carried out, one or more red LEDs can be activated. In this case, resetting the PDU is required. Resetting is carried out by pressing the ’TRX 1 RESET’ and ’TRX 2 RESET’ buttons.

15.4.4 Bias Circuit and Lightning Protection There is one Bias T per feeder cable. It is used to DC feed the corresponding Masthead Amplification Box and to extract the alarms from the Masthead Amplification Box. It includes a lightning protector which performances are as specified in IEC 1000-4-5 level 4. This lightning protector is sufficient to protect the BTS. No other lightning protector can be installed between the PDU and the MAB, in order to avoid cutting the DC feed.

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15.4.5 Mechanical Characteristics The dimensions of the Power Distribution Unit are a height of 3U, a depth of 280 mm and a width of 28 TE (see the following figure). Front view

Top view

Rear view

Side view

Celwave Serial no. label

Alcatel ID no. label

Figure 455: Drawing of Power Distribution Unit

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All connections are located on the front panel (see the following figure).

TRX 1 MAB

TRX 1 MAB

TRX 2 MAB

TRX 1 DCDC

TRX 2 DCDC

TRX 2 MAB

B

D DC INPUT STATUS H

STS INTERFACE

G

G

TRX 1 RESET

TRX 2 RESET

TRX 1 BTS

C

F

TRX 2 BTS

E

DC POWER

A

I

Legend: A − ground rod, diam 8 mm B − TRX 1 MAB female 7/16 connector C− D−T E−

TRX 1 BTS female 7/16 connector RX 2 MAB female 7/16 connector TRX 2 BTS female 7/16 connector

F − alarm SubD male 9 pin connector G − reset button H − DC status LED − green I − DC supply SubD male 3 pin high power connector

Figure 456: Power Distribution Unit Front Panel The RF connectors are of 7/ 16 female type on ANx and feeder sides of the PDU. The PDU is fitted with a M6 threaded rod for grounding via a yellow/green 16 mm 2 ground cable (in the installation kit).

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15.5 REK Installation 15.5.1 Masthead Amplification Box Installation The MAB is fixed on the same vertical tubular support (∅ 40 to ∅ 200 mm) as the antenna using mounting hardware (two hose clamp steel bands and two hose clamp lock sets) as close as possible to the antenna. The MAB is mounted vertically on the pole with the connectors pointing downwards. The following figure shows the installation of MAB on the pole.

Mast MAB

70mm

70mm

Legend: MAB Mast Amplification Board

Figure 457: MAB Installation on the Pole

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15.5.2 Power Distribution Unit Installation The PDUs are fitted in a subrack and the subrack is fixed on the wall or in a 19” rack. This is a standard 3U high, 19” subrack with front fixation which can carry up to three PDUs. The following figure shows the installation of a PDU inside an Evolium BTS A9100 outdoor or in a 19” rack for an indoor site. Figure 459 shows the installation of a PDU for an indoor site on the wall (with brackets). The first PDU is to the left in the PDU subrack.

Figure 458: Installation of PDU in an Evolium BTS A9100 Outdoor or in 19” Rack for Indoor Blind plate

x2

Bracket

Figure 459: Wall Installation of PDU for Indoor Site

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15.6 REK Cabling 15.6.1 Cabling Overview Depending on the installation, the distance between the BTS, PDU, and MAB can be variable. Thus RF jumper cables have been defined to cover this flexibility.

15.6.1.1 Indoor Cabling Overview The following figure shows an indoor cabling overview of the Evolium BTS A9100.

ANTENNA

Legend: MAB Mast Amplification Board PDU Power Distribution Unit

MAB

ANT BTS GRD connection

RF jumper

Ground bar RF jumper

FEEDER

RF jumper Installation on wall or 19" rack

Alarm extension cable

PDU

BTS indoor

RF jumper GRD connection

Alarm combining cable

DC cable to power supply 3x2,5mm toward second PDU

toward third PDU

Figure 460: Evolium BTS A9100 Indoor Cabling Overview

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15.6.1.2 Outdoor Cabling Overview The following figure shows an outdoor cabling overview of the Evolium BTS A9100.

ANTENNA

Legend: MAB Mast Amplification Board PDU Power Distribution Unit MAB

ANT BTS GRD connection Ground bar RF jumper

RF jumper

FEEDER

BTS outdoor Alarm combining cable

PDU

Options panel 19" rack

DCDP GRD connection

DC cable to power supply

ANx

Alarm extension cable

Cable gland

RF jumper

Jumper set for outdoor BTS

Figure 461: Evolium BTS A9100 Outdoor Cabling Overview The following sections describe the cabling of the MAB and PDU for indoor and outdoor versions in more details.

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15.6.2 Masthead Amplification Box Cabling The following figure shows the cabling of the MAB in detail. There are two 7/ 16 female connectors marked BTS and ANT on the lower side downward. The ANT connector is connected to the antenna by an RF jumper. The BTS connector is connected to the transmission/reception coaxial cable going down to the BTS (Power Distribution Unit) by an RF jumper. The connectors on the jumpers are sealed at both ends. The ground cable is connected to the M6 rod of Masthead Amplification Box and to the ground or copper bar on the other side. antenna Legend: MAB Mast Amplification Board

pole fixation

MAB

4x insulation

pole fixation

Jumper cable

Ground cable

OR

Ground bar

Copper bar

Feeder

Figure 462: Cabling of Masthead Amplification Box

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15.6.3 PDU Cabling in Indoor BTS The following figure shows the cabling of the PDU in an indoor Evolium BTS A9100 in detail. Between the PDU and MABs, classical RF jumpers are used without lightning protectors in the form of quarter wave stubs or attenuators. Lightning protectors at the feeder entry in the shelter (necessary for operation without the REK) are suppressed, because they cut the DC power supply to the MAB. The PDU itself contains lightning protectors. The ’TRX 1 MAB’ 7/ 16 female connector is connected to the antenna feeder line with an RF jumper. The ’TRX 1 BTS’ 7/ 16 female connector is connected to the antenna output of the Evolium BTS A9100 with an RF jumper. When a second MAB is connected to the same PDU, these connections are done to ’TRX 2 MAB’ and ’TRX 2 BTS’. The ground cable is connected to the M6 rod of the MAB and to the ground or copper bar on the other side. The alarm cable has two parts. The alarm combining cable can be connected to three PDUs with three Sub-D 9 pin female connectors at the ’BTS Interface’. The 15-pin connector on the other end is connected to the alarm extension cable. The other end of the alarm extension cable is connected to the alarm interface of the Evolium BTS A9100. 2

Connection to a DC power supply is via a 10 m cable 3x2.5 mm with tips on one end and a Sub-D connector 3-pin (high current) at the PDU end. The output of the -48 VDC power supply is protected by a 15 A fuse. MAB Legend: MAB Mast Amplification Board PDU Power Distribution Unit

Jumper cable

Feeder

PDU TRX MAB BTS INTERFACE DC POWER

TRX BTS

Blue Yellow/Green Brown (black)

−48V GND 0V

DC Power supply cable Alarm combining cable

Jumper cable to second and third PDU

Ground cable

BTS Indoor Cooper bar

Alarm extension cable

Figure 463: PDU Cabling for Indoor Evolium BTS A9100

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15.6.4 PDU Cabling in Outdoor BTS The following figures show the cabling of the PDU in the outdoor Evolium BTS A9100 in detail. The versions just differ in connecting the DC power supply. Lightning protectors at the feeder entry in the shelter (necessary for operation without the REK) are removed, because they cut the DC power supply to the MAB. The PDU itself contains lightning protectors. The ’TRX 1 MAB’ 7/ 16 female connector is connected to an RF jumper. The RF jumper is connected to the 7/ 16 coaxial socket fitted at the bottom of the Evolium BTS A9100. The ’TRX 1 BTS’ 7/ 16 female connector is connected with the ANx of the Evolium BTS A9100 with an RF jumper. When a second MAB is connected to the same PDU, these connections are done to the ’TRX 2 MAB’ and ’TRX 2 BTS’. The ground cable is connected to the M6 rod of the PDU and the FASTON connector in the middle compartment. The alarm cable has two parts. The alarm combining cable can be connected to three PDUs with three Sub-D 9-pin female connectors at the ’BTS Interface’. The 15-pin connector on the other end is connected to the alarm extension cable. The other end of the alarm extension cable is connected to the alarm interface of the Evolium BTS A9100. For outdoor BTS, the alarm cable has to go to the left compartment, crossing two times the bottom of the BTS by cable glands.

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For outdoor Evolium BTS A9100 equipped with a DC bus bar, the DC power supply cable is connected to this bus bar (see the following figure). If there is no bus bar, the PDU is connected to the DCDP panel at the high current outputs via a specific DC cable (see Figure 465). This cable has two branches to supply the racks with the TREs and the relevant PDU. In this way, PDU1 is connected with DCDP X9, PDU2 with DCDP X12, and PDU3 with DCDP X14. EVOLIUM BTS A9100 Fastion connector Alarm combining cable Ground cable

to second and third PDU

TRX MAB BTS INTERFACE DC POWER

TRX BTS

Alarm extension cable

PDU GND

DC Power supply cable

ANx

Jumper cable PDU − ANx

BUS BAR Jumper cable PDU − Feeder

BTS Bottom Plate

RF 7/16 Coaxial socket Cable gland

Legend: MAB Mast Amplification Board PDU Power Distribution Unit

MAB Jumper cable Feeder

Figure 464: PDU Cabling for Outdoor Evolium BTS A9100 with DC Bus Bar

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EVOLIUM BTS A9100 Middle compartment

Fastion connector Alarm combining cable Ground cable

t o

to second and third PDU

r a c k

TRX MAB BTS INTERFACE DC POWER

TRX BTS

Alarm extension cable

s u p p l y

PDU

GND

DCDP DC Power supply cable ANx

Jumper cable PDU − ANx

Jumper cable PDU − Feeder

BTS Bottom Plate

RF 7/16 Coaxial socket Cable gland Legend: MAB Mast Amplification Board PDU Power Distribution Unit

MAB Jumper cable Feeder

Figure 465: PDU Cabling for Outdoor Evolium BTS A9100 without DC Bus Bar

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15.7 REK Cables 15.7.1 Ground Cable The ground cables for the MAB and the indoor PDU (part number 3BK 08824 AAAA) and the outdoor PDU (part number 3BK 07934 AAAA) installation are shown in the following figures. Lug 5 6

Shrinkable tube

Shrinkable tube

Lug 5 8

10000 mm

Figure 466: Ground Cable for MAB and Indoor PDU Lug 6

Thermo−retractable label with marking

Faston connector

10000 mm

Figure 467: Ground Cable for Outdoor PDU

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15.7.2 Alarm Cable The alarm cable has two parts: the alarm combining cable, 0.6 m (part number 3BK 08819 AAAA) and the alarm extension cable indoor, 8 m (part number 3BK 08818 AAAA) or the alarm extension cable outdoor, 2 m (part number 3BK 08915 AAAA) as shown in the following figure.

SubD 15 pin male 3x SubD 9 pin female

Alarm Combining Cable

SubD 15 pin female

2000 mm (outdoor) 8000 mm (indoor)

Alarm Extension Cable

Figure 468: Alarm Combining/Extension Cable

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15.7.3 DC Power Supply Cable The DC power supply cable for indoor Power Distribution Unit installation (part number 3BK 08916 AAAA) is shown in the following figure. (10000

100 mm

−48 V blue GND ye−green 0 V brown

SubD 3 pin female high current

Figure 469: DC Power Supply Cable for Indoor Power Distribution Unit The DC power supply cable for PDU installation in outdoor Evolium BTS A9100 with a DC power supply bus bar (part number 3BK 08919 AAAA) is shown in the following figure. The DC power supply cable for PDU installation in outdoor Evolium BTS A9100 without a DC power supply bus bar (part number 3BK 08918 AAAA) is shown in Figure 471. A3 (0V) A2 (GND) A1 (−48V)

0V GND −48V

SubD 3 HP female

Mate N lock 3 male 700 mm

Figure 470: DC Power Supply Cable for PDU in Outdoor Evolium BTS A9100 with Power Supply Bus Bar

BROWN YE−GR Faston, female

0V Not used GND −48V

BLUE A3 A2 A1

A3 A2 A1

SubD 3 HP female

700 mm 1300 mm

SubD 3 HP male

Figure 471: DC Power Supply Cable for PDU in Outdoor Evolium BTS A9100 without Power Supply Bus Bar

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15.7.4 Jumper Cable For indoor installation of the REK, there are four jumper cables (MAB/Power Distribution Unit) available with a length of 1 m (part number 3BK 05360 BAAA), 2 m (part number 3BK 05360 CAAA), 3 m (part number 3BK 05360 DAAA), and 5 m (part number 3BK 05360 ELAA). MAB jumper cables are identical for indoor and outdoor Evolium BTS A9100. For outdoor installation of the REK, there are two different jumper cables for the PDU: RF cable PDU - ANx (part number 3BK 07965 AAAA) and RF cable PDU - feeder (part number 3BK 07965 ABAA). The following figure shows the jumper cable.

Figure 472: Jumper Cable

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16 Tower-Mounted Amplifier

16 Tower-Mounted Amplifier The TMA is designed to compensate the feeder losses which significantly impact the density of sites to be implemented over the service area of GSM networks.

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16.1 Introduction to TMA A significant part of the benefits brought by the outstanding sensitivity of the Evolium BTS A9100 can be lost if the losses incurred by signals along the feeder cable between the receiving antenna and the antenna coupling module (ANxx) are too high. In fact, the noise factor of the system is degraded by an amount depending on the feeder loss. The basic idea of tower-mounted amplification is to implement a low-noise amplifier as close as possible to the antenna (see figure below), so as to compensate for all losses incurred by received signals. The TMA solution can be used in GSM 900 or GSM 1800 indoor and outdoor configurations. Antennas

Duplexer

Duplexer

Duplexer

Duplexer

TMAs

Feeders

Mobile Unit

BTS Antenna Network combining: ANCx

TRE

TRE

Figure 473: Principles of Tower-Mounted Amplification Tower-mounted amplification appears as an efficient sensitivity enhancement technique. However, both uplink and downlink power budgets must be considered for the calculation of the coverage ranges. The smallest available path loss determines the range. In that respect, tower-mounted amplification can be beneficial in those cases where system performance is limited by a weaker uplink budget. On the other hand, in a balanced uplink/downlink situation, the introduction of tower-mounted amplification can be an efficient means to reduce the output power level of all mobile stations. The uplink power control mechanism provided at each base station will force all mobiles to reduce their emission level. Two benefits can be obtained in that case: Lower output favorably impacts the standby time of every mobile station Lower output power contributes to minimizing the electromagnetic pollution within the service area.

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16 Tower-Mounted Amplifier

In summary, the decision to exploit tower-mounted amplification can be influenced by system design considerations but also result from the application of the Operator’s internal policy. The counterpart of getting better sensitivity by means of a tower-mounted amplifier is the risk of degrading the blocking and intermodulation characteristics of the base station if the value of the amplification gain greatly exceeds the value of the feeder losses. The attention of Operators is drawn to the fact that, in such a case, the site equipment might not fully comply with ETSI requirements settled in GSM rec 05.05. The TMA can be used with a wide variety of Evolium BTS A9100 indoor and outdoor configurations in GSM 900, GSM 1800 or GSM 1900 with a coupling constraint of a of one TRX/TRE maximum to each antenna. Cross-polarized antennas can still be used respecting this constraint. For practical reasons, configurations are limited to a maximum of six TREs per BTS site assuming a 3x2 configuration. The TMA is designed to minimize BTS and system impacts. The BTS has no knowledge of the TMA presence and is not involved in its configuration. Supervision is minimal. It only involves external alarms to the BTS and there is no recovery mechanism. The system impact concerns the handling of these new external alarms at the OMC-R level.

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16.2 Architecture For TMA usage two solutions are available: Tower Mounted Amplifier with external solution Tower Mounted Amplifier with AGC support.

16.2.1 Tower Mounted Amplifier with External Solution The TMA with external solution is basically composed of three modules (see figure below): A Tower-Mounted Amplifier (TMA), installed close to the antenna, featuring the transmit signal bypassed to the antenna and the receive signal amplified by a low-noise amplifier A Bias T module, used to insert the DC voltage in the RF antenna cable to feed the TMA. The Bias T module is suited for GSM 900, GSM 1800, and GSM 1900 A Power Distribution Unit (PDU), installed in the BTS cabinet or close to the BTS, providing DC power to remotely feed the masthead amplification module through the antenna feeder and collect the alarm signals.

Antennas

Duplexer

Tower Mounted Amplifiers

Duplexer

. . . Duplexer

Duplexer

Feeders

BTS

Bias T

. . . Bias T

. . . External Alarms

Power Distribution Unit 48 V DC

Figure 474: TMA with External Solution Architecture The PDU is designed to supply and to monitor up to six TMAs (typical BTS configuration of 3x2 TRXs/TREs), independently of their frequency band (i.e., the same PDU equipment can be used with the TMA of GSM 900, GSM 1800, and GSM 1900. In fact, the PDU has no frequency notation). For indoor BTS installations, the PDU can be installed on the wall or in a separate transmission cabinet (if available) and be powered by the BTS power supply. For outdoor BTS configurations, it is possible to install the PDU inside the BTS cabinet. The PDU is also powered by the BTS power supply.

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16.2.2 Tower Mounted Amplifier with AGC Support The TMA withAGC support is basically composed of two modules (see figure below): A Tower-Mounted Amplifier (TMA), installed close to the antenna, featuring the transmit signal bypassed to the antenna and the receive signal amplified by a low-noise amplifier An Antenna Network module (AGC) containing the Bias T module used to insert the DC voltage in the RF antenna cable to feed the TMA and the power supply providing the DC power to remotely feed the masthead amplification module through the antenna feeder.

TMA

TMA

Duplexer

Duplexer

Duplexer

Duplexer

Bias

Bias

Fixed TMA Rx Gain

BTS AGC TRE

Bias

TRE

Bias Adjustable AGC Rx Gain

Feeder Cable Loss

AGC Power Supply, Switching and Supervision

Figure 475: TMA with AGC Support Architecture

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16.3 Tower-Mounted Amplifier The tower-mounted amplifier is available for GSM 900, GSM 1800 and GSM 1900, as shown in the following table. Part number GSM 900

3BK 08451 AAAA

GSM 1800

3BK 08497 AAAA 3BK 08497 BAAA 3BK 08497 CAAA 3BK 08497 DAAB

GSM 1900

3BK 08498 AAAA 3BK 08498 BAAA

Table 168: TMA Part Numbers

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16.3.1 Appearance The tower-mounted amplifier includes a low noise amplifier for the receive path and a double duplexer TX/RX for one antenna port. It is designed for outdoor installation on a tubular mounted support below the antenna. Amplifiers for GSM 900 and GSM 1800/ GSM 1900 are offered by different manufacturers. Therefore, the appearance of TMAs can differ, as shown in the following figures as an example. Side View

Top View

Ground terminal screw M6

Connectors 7/16 female on the bottom face of the box

Front View

BTS

ANT

Figure 476: Tower-Mounted Amplifier for GSM 900

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Side View

Front View Antenna Mast

Ground terminal screw M6

Stainless steel attachment collar

Bottom View

Connectors 7/16 female on the bottom face of the box

ANT

BTS

Figure 477: Tower-Mounted Amplifier for GSM 1800/ GSM 1900

16.3.2 Frequency Range The RX and TX frequency ranges of the tower-mounted amplifiers are summarized in the following table. Parameter

GSM 900

GSM 1800

GSM 1900

Frequency range RX

925 - 960 MHz

1710 - 1785 MHz

1850 - 1910 MHz

Frequency range TX

880 - 915 MHz

1805 - 1880 MHz

1930 - 1990 MHz

Table 169: Frequency Ranges of the Tower-Mounted Amplifiers Other RF specifications depend on which TMA version of a specific manufacturer is used, the current position of the BTS, the TMA, and the antenna on site and the corresponding cable lengths.

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16.3.3 Mechanical Characteristics The overall dimensions and weights of the examples shown above are listed in the following table. Parameter

GSM 900

GSM 1800

GSM 1900

Dimensions

357.5 x 168 x 112 mm

265 x 158 x 95 mm

265 x 158 x 95 mm

Weight

6 kg

2.5 kg

2.5 kg

Table 170: Tower-Mounted Amplifiers, Weight and Dimensions The back side of the tower-mounted amplifier is so formed that it can be easily attached on the same vertical tubular support as the antenna using one (GSM 1800/ GSM 1900) or two (GSM 900) stainless steel attachment collars provided as close as possible to the antenna. The equipment is guaranteed to be watertight when the equipment is installed with the connectors downwards and the two coaxial cables (jumpers) connected to the equipment. The connectors on the jumpers are insulated at both ends, i.e., one at the antenna connector, two at the tower-mounted amplifier, and one at the feeder head. There are two 7/ 16 female connectors marked BTS and ANT on the front (lower side down). The antenna connector is connected to the antenna by an RF jumper. The BTS connector is connected to the transmission/reception coaxial cable going down to the BTS by an RF jumper. The tower-mounted amplifier is fitted with an M6 threaded rod for grounding via a black 16 mm² ground cable (in the installation kit) connected to the pylon or building ground, depending on the installation.

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16.4 Power Distribution Unit The Power Distribution Unit (wall installation: part number 3BK 08456 AAAA, 19” installation: part number 3BK 08456 ABAA) provides power supply and an alarm interface for up to six tower-mounted amplifiers. It is located at the BTS site, either wall-mounted close to the BTS in an indoor site or integrated inside the BTS cabinet in an outdoor BTS. The primary voltage of the Power Distribution Unit is -48 VDC. The secondary voltages are + 12 VDC and are fed to the six tower-mounted amplifiers via Bias tees which are not integrated parts of the module. The BTS is informed by an alarm indication if there is a defective DC/DC converter, a malfunction of the tower-mounted amplifier, or an connection error of the various parts of cables and equipment. The Power Distribution Unit includes three separate DC/DC converters each providing two tower-mounted amplifiers with DC power. The power consumption for the Power Distribution Unit is 30 W.

16.4.1 Appearance The Power Distribution Units are shown in the following figures. Serial no. label

Fixing hole

LEDs Reset button Power switch

1

2

1

14

1 2

1 2

1 2

1 2

1 2

1 2

Terminal blocks (secondary power connection)

Main power supply cable

Ground braid collars

Terminal block (for alarm cable)

Top View

Ground connector (M6)

Side View

Figure 478: Power Distribution Unit, Wall Version for BTS Indoor

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1

2

1

14

1 2

1 2

1 2

1 2

1 2

1 2

Ground braid collars

Power supply cable

Ground connector (M6)

Top View

Front View

Figure 479: Power Distribution Unit, 19” Version for BTS Outdoor

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16.4.2 Switches and LEDs There is a main power switch used to switch the main power on or off. The corresponding orange LED indicates the presence of -48 V primary voltage. Three green LEDs indicate the presence of the secondary voltage for two channels each (1 + 2, 3 + 4, 5 + 6). The output channels can be separately switched on/off. A corresponding red LED indicates the presence of + 12 VDC secondary voltage.

16.4.3 Reset Button Each channel has a separate reset button. If pressed for at least two seconds, the concerned red LED goes out. The PDU is also fitted with a main reset button to reset all channels used in a single action.

16.4.4 Switching On Before switching on the power supply at the PDU input, all switches have to be in the OFF position (all LEDs are also OFF). When the main power is switched on, the orange LED ’main power’ indicates the presence of primary voltage, while the three green LEDs indicate that the secondary power for all separate channels is available. The six red LEDs (for channel 1 to channel 6) indicate when the tower-mounted amplifier alarms come on. After switching on the separate channel switches and pressing the reset buttons, the corresponding tower-mounted amplifiers are supplied and the red LEDs are OFF.

16.4.5 PDU LEDs LEDs are provided on the top (wall installation) or on the side (19” installation) of the Power Distribution Unit to indicate the status and the alarms. The following table describes each LED and provides a definition of their operational states. LED

Color

LED On

LED Off

-48 VDC

Orange

Main power available

No main power available

POWER TMA 1 and 2

Green

Secondary power available

DC/DC converter is faulty (alarm)

POWER TMA 3 and 4

Green

Secondary power available

DC/DC converter is faulty (alarm)

POWER TMA 5 and 6

Green

Secondary power available

DC/DC converter is faulty (alarm)

TMA 1 to TMA 6

Red

TMA malfunction or connection errors (alarm)

No fault

Table 171: Power Distribution Unit LEDs

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16.5 Bias T The Bias T unit (part number 3BK 08453 ABAA or 3BK 08454 ABAA) is a power supply injector to transport the + 12 VDC power supply energy to the tower-mounted amplifier through the coaxial cable between the antenna and the BTS. The injector is designed for indoor and outdoor installation between the BTS and the coaxial transmission-reception cable. Two Bias T versions are available: Bias T for indoor BTS-RF connectors 7/ 16 male/ side TMA; female/ side BTS Bias T for outdoor BTS-RF connectors 7/ 16 female/ side TMA; male/ side BTS. The outdoor version is normally combined with a 90 bend. Both indoor and outdoor versions are combined with a surge arrestor. The Bias T units are shown in the following figures. Ground Terminal Screw M6

7/16 Male connector to TMA

ANT

BTS

Male Connector to PDU 7/16 Female connector to BTS

Figure 480: Bias T, Indoor Version

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7/16 Female connector to TMA

Ground Terminal Screw M6

ANT

BTS 7/16 Male connector to BTS Male Connector to PDU

Figure 481: Bias T, Outdoor Version

Figure 482: Surge Arrestor

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16.6 Installation 16.6.1 Indoor Installation Depending on the installation, the distance between the BTS, the Power Distribution Unit, and the Tower-Mounted Amplifier can be variable. Thus RF jumper cables have been defined to cover this flexibility. The PDU and Bias T are installed outside the BTS.

ANTENNA

The following figure shows an indoor installation.

TMA

ANT BTS GND connection Ground bar RF jumper

RF jumper

Feeder

Surge Arrestor RF jumper

Bias T for BTS Indoor Bias T Injector Cable

Alarm cable

Wall Installation

PDU

BTS indoor DC cable to power supply

GND connection

Figure 483: Indoor Installation

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16.6.2 Outdoor Installation Contrary to indoor installation, in an outdoor installation the PDU and Bias T are installed inside the BTS. The PDU has a 19” version which is installed in a subrack. The Bias T, including 90 bend and surge arrestor, are installed in the bottom or top of the cabinet.

ANTENNA

The following figures show the principle outdoor installations for BTS versions with a Bias T installation on the bottom.

TMA

ANT BTS GND connection Ground bar RF jumper

RF jumper

Feeder

Ground cable

BTS Outdoor

19’’ subrack

PDU 19" subrack

DC cable to power supply COAR Bus bar ’Octopus’ cable fitted with 6 cables Alarm cable ANx

Cable gland

Surge Arrestor Bias T with 90 RF jumper

Figure 484: Principle Outdoor Installation for Evolium A9100 BTS

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ANTENNA

16 Tower-Mounted Amplifier

TMA

ANT BTS GND connection Ground bar RF jumper

RF jumper

Feeder

Ground cable Bus bar

BTS Outdoor

DC cable to power supply 19’’ subrack

PDU 19" subrack

ANx

Alarm cable

OUTC

’Octopus’ cable fitted with 6 cables

Surge Arrestor Bias T with 90 RF jumper

Figure 485: Principle Outdoor Installation for Evolium A9100 BTS Evolution

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16.7 TMA Cables 16.7.1 Indoor/Outdoor BTS Cables Cables for both indoor and outdoor BTS installation of the TMA are described.

16.7.1.1 TMA Ground Cable The TMA ground cable (part number 3BK 08452 ABAA) is shown in the following figure. Ring tongue M6

Shrink sheath

Ring tongue M8

Figure 486: Ground Cable for Tower-Mounted Amplifier

16.7.1.2 Jumper Cable For indoor and outdoor installation of the tower-mounted amplifier, there are several jumper cables with different cable lengths (part numbers 3BK 05360 xxxx or 3BK 07965 xxxx). Variant ’xxxx’ represents cable lengths. The following figure shows the jumper cable.

Figure 487: Jumper Cable

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16.7.2 Indoor BTS Cables The Bias T cable and the cable set used for indoor BTS installations are described in the following sections.

16.7.2.1 Bias T Cable The Bias T cable (part number 3BK 25482 AAAA) is shown in the following figure. PDU side

Bias T side

Figure 488: Bias T Cable

16.7.2.2 Indoor Cable Set For indoor installation there is a specific cable set (part number 3BK 25484 AAAA) containing a ground cable, a DC power supply cable, and an alarm cable. All cables are shown in the following figures.

braid overturned

Figure 489: Indoor DC Cable Lug M6

30 mm shrink sheath

Figure 490: Indoor Ground Cable

FM2A armored cable

Figure 491: Indoor Alarm Cable

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16.7.3 Outdoor BTS Cables The cable and cable set used for outdoor BTS installations are described in the following sections.

16.7.3.1 Octopus Cable The ’Octopus’ cable (part number 3BK 25483 AAAA) is fitted with six cables and is shown in the following figure. Bulkhead feedthrough cable jack

Straight cable plug

Spacer

Female connectors

Figure 492: ’Octopus’ Cable

16.7.3.2 Outdoor Cable Set For outdoor installation there is a specific cable set (part number 3BK 25485 AAAA) containing a ground cable, a DC power supply cable, and an alarm cable. All cables are shown in the following figures. −48 V Not used 0V braid overturned Mate N lock 3 male

Figure 493: Outdoor DC Cable 30 mm shrink sheath

Figure 494: Outdoor Ground Cable

Figure 495: Outdoor Alarm Cable

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17 Cable Descriptions This chapter describes the internal and external cables. Where appropriate, the pin-to-pin interconnections between cable connectors are illustrated in diagrams.

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17 Cable Descriptions

17.1 Internal Cables The physical and electrical characteristics for the indoor and outdoor internal cables are given in the following sections.

17.1.1 ANCO The ANCO (part number 3BK 26151) connections are shown in the following figure. Lightning Protector

AN Shield

Type 7/16, straight, male

Type 7/16, right angle, male

Figure 496: ANCO Connections

17.1.2 ANIC The ANIC (part number 3BK 07921) connections are shown in the following figure. ANT Cabinet Connector

AN Shield

Type 7/16, straight, female

Type 7/16, right angle, male M3 Thread

Figure 497: ANIC Connections

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17.1.3 ANLC The ANLC (part number 3BK 26349) connections are shown in the following figure. Lightning Protector

AN Shield

Type 7/16, Straight, Male

Type 7/16, Right Angle, Male

Figure 498: ANLC Connections

17.1.4 ANOC The ANOC (part number 3BK 07965) connections are shown in the following figure. Lightning Protector

AN Shield

Type 7/16, right angle, male

Type 7/16, right angle, male

Figure 499: ANOC Connections

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17.1.5 BOBU Both Variant AA and Variant CA of the BOBU are described.

17.1.5.1 Variant AA Appearance The front and side views of the BOBU (part number 3BK08742) Variant AA are shown in the following figure. P1

P13 P2

P19

P3 P4 P5 P6 P7 P8

P20 P21 P22

P14

P23 P24 P25

P9

P26 P15 P27

P16

P17 P10 P11 P18

P28

P12

Figure 500: BOBU Variant AA Appearance

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17.1.5.2 Variant AA Circuit Schematic The BOBU Variant AA connections are shown in the following figure. Top P1

Service Light

P19

Smoke Alarm, +24 V / 0 V

P2

PDU3 (STASR 6)

P3

PDU2 (STASR 4)

P4

PDU1 (STASR 1)

P20

XIOB Supply

P21

Light Filter

P22

Heater Filter

P13

COAR Alarms

P23

−48 V Filter

P24

0 V Bolt

P25

Ground Bolt

P26

STASR 2

1

2

3

4

5 6 7

8

9 10 11 12

P5

Supply Option X1

P6

Supply Option X2

P7

Supply Option X3

P8

Supply Option X4

P14

STASR 6

P9

STASR 3

P27

STASR 1

P16

STASR 4

P10

HEX2 (BTS 1)

P11

Water

XIOB and Options

STASR 3

STASR 2

STASR 1 P15

STASR 5 STASR 6 STASR 5

STASR 4 P17 P18

HEX2

HEX2 (BTS 2) or Loop

P28

Door 1 and 2 Switches

P12

HEAT Bottom

Layer: 1 2 3

Signal: WATER HEX2−1 HEX2−2

Layer: 4T/B 5T/B 6

1

2

3

4

Signal: SMOKE / DOOR1 24V / DOOR2 XGND

5 6 7

8

9 10 11 12

Layer: 7 8T/B 9

Signal: −48VG −48V0 / −48VG GND−0V

Layer: 10 11 12 T / B

Signal: GND−0V NF1 LIF1 / LIF2

Figure 501: BOBU Variant AA Circuit Schematic

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17.1.5.3 Variant AA Connectors The connectors of the BOBU are shown in the following table. Connector

Type

P1, P12

Wieland GST 1813 S, male with female contacts.

P2, P3, P4

Mate-N-Lock, female with female contacts.

P5, P6, P7, P8, P11

Mate-N-Lock, female with female contacts.

P9, P14, P15, P16

Anderson Powerpole, unisex.

P10, P17

Mate-N-Lock, female with female contacts.

P13

9-pin Sub-D, female.

P18

Mate-N-Lock, male with male contacts.

P19

DIN wire ferrules 2.5 mm

P20, P28

Mate-N-Lock, male with female contacts.

P21, P22

FASTON 6.3, female contacts.

P23, P24

Lug, ring, crimp, 6 mm.

P25

Lug, ring, crimp, 8 mm.

P26

Triple FASTON, male with female contacts.

P27

Triple FASTON, female with female contacts.

2

Table 172: BOBU Variant AA Connectors

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17.1.5.4 Variant CA Appearance The front and side views of the BOBU (part number 3BK 08742) Variant CA are shown in the following figure.

Figure 502: BOBU Variant CA Appearance

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17.1.5.5 Variant CA Circuit Schematic The BOBU Variant CA connections are shown in the following figure. ELECTRICAL GENERAL SCHEME

CONNECTORS TECHNOLOGIES

Figure 503: BOBU Variant CA Circuit Schematic

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17.1.6 BOMU Diagrams illustrate both the BOMU’s appearance and its circuit schematics.

17.1.6.1 Appearance The front and side views of the BOMU (part number 3BK 25672) are shown in the following figure.

Figure 504: BOMU Appearance

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17.1.6.2 Circuit Schematic The BOMU connections are shown in the following figure.

Figure 505: BOMU Circuit Schematic

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17.1.7 BOMUE Diagrams illustrate both the BOMU’s appearance and its circuit schematics.

17.1.7.1 Appearance The front and side views of the BOMUE (part number 3BK 27262) are shown in the following figure.

Figure 506: BOMUE Appearance

17.1.7.2 Circuit Schematic The BOMUE connections are shown in the following figure.

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Figure 507: BOMUE Circuit Schematic

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17 Cable Descriptions

17.1.8 BOMUT Diagrams illustrate both the BOMUT’s appearance and its circuit schematics.

17.1.8.1 Appearance The front and side views of the BOMUT (part number 3BK 27143) are shown in the following figure.

Figure 508: BOMUT Appearance

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17 Cable Descriptions

17.1.8.2 Circuit Schematic The BOMUT connections are shown in the following figure.

Figure 509: BOMUT Circuit Schematic

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17 Cable Descriptions

17.1.9 BOSU The BOSU variants, AA and CA, are described in terms of appearance and connections.

17.1.9.1 Variant AA Appearance The front and side views of the BOSU (part number 3BK 08741) Variant AA are shown in the following figure. P1

P4 P5 P6

P7

P8

P9

P2

P10

P12

P11

P3

Figure 510: BOSU Variant AA Appearance

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17 Cable Descriptions

17.1.9.2 Variant AA Circuit Schematic The BOSU Variant AA connections are shown in the following figure. Top P1

Service Light

P4

Service Filter

P5

ACSB/ASCU

P6

Heater Filter

P7

COAR Alarms

1

2

3

4

5 6

Layer: 1 2 3 4 5 6T/B

Signal: XGND DOOR HEX2 GND NF1 LIF1 / LIF2

P8

−48 VDC Input

P9

0 VDC Input

P2

HEX2 Alarm

Keyswitch

P10

Ground Bolt

P12 (or loop) P11

Door Switch

P3

Heater Module HEAT2 Bottom

P1, P3: P2: P4:, P6: P5, P11: P7: P8: P9, P10: P12:

1

2

3

4

5 6

Wieland GST 1813 S, male with female contacts Tripple Faston, female with female contacts Anderson Powerpole, unisex DIN wire ferrules 2.5 mm 9−pin Sub−D female Lug, ring, crimp, 8 mm Lug, ring, crimp, 6 mm Matenlock, male with male contacts

Figure 511: BOSU Variant AA Circuit Schematic

850 / 910

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17 Cable Descriptions

17.1.9.3 Variant CA Appearance The front and side views of the BOSU (part number 3BK 08741) Variant CA are in the following figure.

Figure 512: BOSU Variant CA Appearance

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17 Cable Descriptions

17.1.9.4 Variant CA Circuit Schematic The BOSU Variant CA connections are shown in the following figure. ELECTRICAL GENERAL SCHEME

CONNECTORS TECHNOLOGIES

Figure 513: BOSU Variant CA Circuit Schematic

852 / 910

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17 Cable Descriptions

17.1.10 BTSRI3 The connections for the BTSRI3I (part number 3BK 25973) are shown in the following figure. STASR 2

STASR 1

STASR 3

TFBP

BTSRI 1

1

44

P1

P2

45

P3

P4

P5

Break in wire for coding purposes P1: P2 − P4: P5:

Non−removable, self cutting, 50 pins DIN 41612, 64 pins, rows A and C only, female Flat cable connector, 50 pins, female

Figure 514: BTSRI3 Connections

17.1.11 BTSRI5 The connections for the BTSRI5 (part number 3BK 25974) are shown in the following figure. STASR 2

STASR 1

STASR 3

STASR 4

STASR 5

TFBP

BTSRI 1

1

44

P1

P2

45

P3

46

P4

47

P5

P6

P7

Break in wire for coding purposes P1: P2 − P6: P7:

Non−removable, self cutting, 50 pins DIN 41612, 64 pins, rows A and C only, female Flat cable connector, 50 pins, female

Figure 515: BTSRI5 Connections

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17 Cable Descriptions

17.1.12 BTSRIMA The connections for the BTSRIMA (part number 3BK 07720) are shown in the following figure. STASR 2

STASR 1

STASR 3

STASR 4

STASR 5

TFBP

BTSRI 1

1

44

P1

P2

45

P3

46

P4

47

P5

P6

P7

Break in wire for coding purposes P1: P2 − P6: P7:

Non−removable, self cutting, 50 pins DIN 41612, 64 pins, rows A and C only, female Flat cable connector, 50 pins, female

Figure 516: BTSRIMA Connections

17.1.13 BTSRIMI The connections for the BTSRIMI (part number 3BK 07720) are shown in the following figure. STASR 1

STASR 2

TFBP

BTSRI 1

1

44

P1

P2

P3

P4

Break in wire for coding purposes P1: P2, P3: P4:

Non−removable, self cutting, 50 pins DIN 41612, 64 pins, rows A and C only, female Flat cable connector, 50 pins, female

Figure 517: BTSRIMI Connections

854 / 910

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17 Cable Descriptions

17.1.14 BTSRIOUT The connections for the BTSRIOUT (part number 3BK 08126) are shown in the following figure. Variant CA

Variant AA

STASR 2

STASR 3

1

1

STASR 1 BTSRI

1

44

P1

P2

P3

P4

Break in wire for coding purposes P1: P2, P3, P4:

Non−removable, self cutting, 50 pins DIN 41612, 64 pins, rows A and C only, female

Figure 518: BTSRIOUT Connections

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17 Cable Descriptions

17.1.15 BUMA The BUMA (part number 3BK 07762) cableform connections are shown in the following figure. x7 (Red) P1

GND x7 (Black)

Filter

P2

x7 (Blue) P3

Breakers x3 (Red, Blue, Black)

P4

XIOB x3 (Red, Blue, Black) x3 (Red, Blue, Black)

Top Fan Backplane Subrack 5

P6

Subrack 4

P7

Subrack 3

P8

Subrack 2

P9

Subrack 1

P10

P5

x3 (Red, Blue, Black)

x3 (Red, Blue, Black)

x3 (Red, Blue, Black)

x3 (Red, Blue, Black)

GND Bolt GND

Filter

Breakers

0V

−48 V

Subrack 1 − 5 and Top Fan Backplane

XIOB 1

GND

2

−48 V

GND

0V

3

4 P4 x7 P1 P1: P2: P3: P4: P5 − P10:

P2

0V

−48 V

3

3

1

P5 to P10 1

4

1

P3

Spade, male, M8 hole Spade, male, M6 hole Spade, male, open tongue, M5 Matenlock, female Triple Faston, female

Figure 519: BUMA Connections

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17 Cable Descriptions

17.1.16 BUMI The BUMI (part number 3BK 07763) cableform connections are shown in the following figure. x4 (Red) P1

GND x4 (Black)

Filter

P2

x4 (Blue) P3

Breakers x3 (Red, Blue, Black)

P4

XIOB x3 (Red, Blue, Black)

Top Fan Backplane

x3 (Red, Blue, Black) Subrack 2

P6

Subrack 1

P7

P5

x3 (Red, Blue, Black)

GND Bolt

GND

Filter

Breakers

0V

−48 V

Subrack 1, 2 and Top Fan Backplane

XIOB

1

GND

2

−48 V

GND

−48 V 0V

3

4 P4 x4 P1

P1: P2: P3: P4: P5 − P7:

P2

0V

3

3

1

P5 to P7 1

4

1

P3

Spade, male, M8 hole Spade, male, M6 hole Spade, male, open tongue, M5 Matenlock, female Triple Faston, female

Figure 520: BUMI Connections

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17 Cable Descriptions

17.1.17 CA12 The connections for the CA12 (part number 3BK 08086) are shown in the following figure. STASR 3

STASR 4

1

STASR5 1

BTSRIOUT Connector 45

P1

46

P2

47

P3

P4

Break in wire for coding purposes P1: P2 − P4:

Flat cable connector, 50 pins, female DIN 41612, 64 pins, row A and C only, female

Figure 521: CA12 Connections

17.1.18 CA-2MMC2 The CA-2MMC2 (part number 3BK 08289) connections are shown in the following figure. COAR

Microwave UL Black

7

2

Transparent

6

7

Screen

1

1

Screen

3

5

Transparent

8

9

Black

9 9−pin Sub−D male 1

5

6

9

4 9−pin Sub−D female 1

5

6

9

Figure 522: CA-2MMC2 Connections

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17 Cable Descriptions

17.1.19 CA-ABIS The CA-ABIS (part number 3BK 07922) connections are shown in the following figure. SUM side

Shield

BTSCA

1

1

2

2

3

3

4

4

5

5

6

6

7

7

8

8

9

9

9−pin Sub−D male 1 5

6

9−pin Sub−D female 5 1

9

9

6

Figure 523: CA-ABIS Connections

17.1.20 CA-ACB2 The CA-ACB2 (part number 3BK 08091) cable connections are shown in the following figure. BTS Compartment 2

COAR

1 P2 2

5

4

6

5

P1

P1

P3

1

5

6 P1: P2: P3:

9

5

1

9

6

9−pin Sub−D male Receptacle Faston 4.8 x 0.5 9−pin Sub−D female

Figure 524: CA-ACB2 Connections

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17 Cable Descriptions

17.1.21 CA-ACSC The CA-ACSC (part number 3BK 08078) cable connections are shown in the following figure. Side Compartment

COAR 1

P2 2

4 P3 5

5

6

6

7

P1

P1

P4

1

6 P1 − P4: P2: P3:

1

5

9

5

6

9

9−pin Sub−D male Receptacle Faston 4.8 x 0.5 DIN wire ferrules

Figure 525: CA-ACSC Connections

17.1.22 CA-ADABM, CA-ADABP The CA-ADABM (part number 3BK 25139) connections and the CA-ADABP (part number 3BK 25138) connections are shown in the following figure. Battery Breaker

Lug, ring crimp, M6

CA−ADABM:

Blue

CA−ADABP:

Black

ADAM

DIN wire ferrule

Figure 526: CA-ADABM, CA-ADABP Connections

860 / 910

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17 Cable Descriptions

17.1.23 CA-ADACM, CA-ADACP The CA-ADACM (part number 3BK 25248) connections and the CA -ADACP (part number 3BK 25247) connections are shown in the following figure. ADAM

CA−ADACM:

Blue

CA−ADACP:

Black

DIN wire ferrule

Battery Interconnection

DIN wire ferrule

Figure 527: CA-ADACM, CA-ADACP Connections

17.1.24 CA-ADCO The CA-ADCO (part number 3BK 07953) cable connections are shown in the following figure. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 Clamp strip, Phoenix FK−MPC 1,5/16−STF−3,81

Figure 528: CA-ADCO Connections

3BK 20942 AAAA TQZZA Ed.13

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17 Cable Descriptions

17.1.25 CA-ALPC The CA-ALPC (part number 3BK 26348) cable connections are shown in the following figure.

9−Pin Sub−D Male

9−Pin Sub−D Female

Figure 529: CA-ALPC Appearance Alarm −

1 2

P2 To Door Switch Alarm + 9 Alarm − 5 Alarm +

6 7 4

− 48 V 6

5

− 48 V 7 P3

OUTC

0V 2

P4

To DCUC X8

P5

To DCUC X7

0V 3 P1 HEX5

P1 P2 P3 P4, P5

9−Pin Sub−D Female Wire Ferrules 9−Pin Sub−D Male Twin Wire Ferrules

Figure 530: CA-ALPC Circuit Schematic

862 / 910

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17 Cable Descriptions

17.1.26 CA-APC2 The CA-APC2 (part number 3BK 08215) cable connections are shown in the following figure. BTS Compartment 1

COAR

1 2 P4 3 4

6 P3 7

11 P2 12

5

14

6

15

P1

P1

P5

1

5

6 P1: P2, P4: P3: P5:

9

8

15

1

9

9−pin Sub−D male DIN wire ferrules Receptagle Faston 4.8x0.5 9−pin Sub−D female

Figure 531: CA-APC2 Connections

3BK 20942 AAAA TQZZA Ed.13

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17 Cable Descriptions

17.1.27 CA-ASMC The CA-ASMC (part number 3BK 08807) connections are shown in the following figure. ACIB

ACSB

1

Black 2

2

Black 1

3

Blue

4

Brown P1 Yellow/Green P3

P2 4

1

P1

P1: P2: P3:

P2

Quardruple Faston, female, 6.3x0.8 Lug, ring, crimp, 5 mm DIN wire ferrules 2.5 mm 2

Figure 532: CA-ASMC Connections

17.1.28 CA-BABRM, CA-BABRP The CA-BABRM (part number 3BK 25141) connections and the CA-BABRP (part number 2BK 25140) connections are shown in the following figure. Battery Breaker

CA−BABRM:

Blue

CA−BABRP:

Black

Lug, ring crimp, M6

Interconnection Area

Lug, ring crimp, M6

Figure 533: CA-BABRM, CA-BABRP Connections

17.1.29 CA-BRCM, CA-BRCP The CA-BRCM (part number 3BK 25246) connections and the CA-BRCP (part number 3BK 25245) connections are shown in the following figure. Battery

CA−BRCM:

Blue

CA−BRCP:

Black

Battery Breaker

DIN wire ferrule Angled Crimp Connector for M6

Figure 534: CA-BRCM, CA-BRCP Connections

864 / 910

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17 Cable Descriptions

17.1.30 CA-BTSCA The CA-BTSCA (part number 3BK 07923) connections are shown in the following figure. SUM side

BTSCA 1

1

37−pin Sub−D male

37−pin Sub−D female

Figure 535: CA-BTSCA Connections

17.1.31 CA-CSTR The connections for the CA-CSTR (part number 3BK 25178) are shown in the following figure. STASR 7

RIBAT2

RIBAT1

1

COAR 1

BTSRIOUT Connector

45

P1

50

P2

P3

P4

Break in wire for coding purposes P1 − P3: P4:

DIN 41612, 64 pins, row A and C only, female Flat cable connector, 50 pins, female

Figure 536: CA-CSTR Connections

3BK 20942 AAAA TQZZA Ed.13

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17 Cable Descriptions

17.1.32 CA-DFUX The CA-DFUX (part number 3BK 08503) cable connections are shown in the following figure. SUM

Microwave UX

1 20 2

Pair 1

21 3

Pair 2

22 4

Pair 3

23 5

Pair 4 Rx Blue

24 6

Pair 5

25 7

Pair 6

26 8

Pair 7

27 9

Pair 8

28 P1 10 29 11

Pair 1

30 12

Pair 2

31 13

Pair 3

32 14

Pair 4 TX Red

33 15

Pair 5

34 16

Pair 6

35 17

Pair 7

36 18

Pair 8

37 P2 P3

P8 P7 P6 P5 P4 P3 P2 P1

1

19

20 P1:

Pouyet, P44920−CA blue

P2:

Pouyet, P44920−CA red

P3:

37−pin Sub−D male

37

Figure 537: CA-DFUX Connections

866 / 910

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17 Cable Descriptions

17.1.33 CA-GCMW The CA-GCMW (part number 3BK 07934) connections are shown in the following figure. Ground

Microwave Equipment Yellow/Green

Lug, ring, crimp

Receptacle, Faston 5.3 x 0.8

Figure 538: CA-GCMW Connections

17.1.34 CA-Ground The CA-Ground (part number 3BK 25182) connections are shown in the following figure. LPFU

CA−BABRM:

Blue

CA−BABRP:

Black

Lug, ring crimp, M6

Bottom Plate

Lug, ring crimp, M8

Figure 539: CA-Ground Connections

17.1.35 CA-Ground1 The CA-Ground1 (part number 3BK 08118) connections are shown in the following figure. SRACDC

ACSB Yellow/Green

Lug, ring crimp, 8 mm

DIN wire ferrule

Figure 540: CA-Ground1 Connections

3BK 20942 AAAA TQZZA Ed.13

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17 Cable Descriptions

17.1.36 CA-Ground2 The CA-Ground2 (part number 3BK 08177) connections are shown in the following figure. SRACDC

ACSB Yellow/Green

Lug, ring, crimp, 8 mm

Lug, ring, crimp, 8 mm

Figure 541: CA-Ground2 Connections

17.1.37 CA-H2PC1 The CA-H2PC1 (part number 3BK 08077) connections are shown in the following figure. HEX2

DCDP

1

1

2

2

3

3

4

4

5

5

6

6

7

7

8

8

9

9

9−pin Sub−D female 5 1

9

6

9−pin Sub−D male 1 5

6

9

Figure 542: CA-H2PC1 Connections

868 / 910

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17 Cable Descriptions

17.1.38 CA-H2PC2 The CA-H2PC2 (part number 08092) connections are shown in the following figure. COAR

DCDP

1

1

2

2

3

3

4

4

5

5

6

6

7

7

8

8

9

9

9−pin Sub−D female 1

5

6

9

9−pin Sub−D male 1

5

6

9

Figure 543: CA-H2PC2 Connections

3BK 20942 AAAA TQZZA Ed.13

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17 Cable Descriptions

17.1.39 CA-H2PC3 The CA-H2PC3 (part number 3BK 08093) connections are shown in the following figure. HEX2

COAR

1

1

2

2

3

3

4

4

5

5

6

6

7

7

8

8

9

9

9−pin Sub−D female 5 1

9

9−pin Sub−D female 5 1

6

9

6

Figure 544: CA-H2PC3 Connections

17.1.40 CA-HOAP The CA-HOAP (part number 3BK 25820) connections are shown in the following figure. BOMU

HEX3 5

4

9

3

2 2 3 6 1 7 9−pin Sub−D female 1 5

6

Matenlock, male 4

1

9

Figure 545: CA-HOAP Connections

870 / 910

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17 Cable Descriptions

17.1.41 CA-MLBP The CA-MLBP (part number 3BK 08886) connections are shown in the following figure. Microwave UL

BOBU

1

2

3 1

5 Plug for three female contacts

Matenlock, male 2

5

1

1

Figure 546: CA-MLBP Connections

17.1.42 CA-MXBP The CA-MXBP (part number 3BK 08886) connections are shown in the following figure. Microwave UX

BOBU

1

1

2 2

3 Sub−D size A for three HP contacts, male and female

Matenlock, male 2

3

1

1

Figure 547: CA-MXBP Connections

3BK 20942 AAAA TQZZA Ed.13

871 / 910

17 Cable Descriptions

17.1.43 CA-OHAC The CA-OHAC (part number 3BK 08810) connections are shown in the following figure. HEX2

BOSU or BOBU

1

1

9

2

9−pin Sub−D male HEX2 2 3 3 6 4 7 9−pin Sub−D female 1 5

6

Matenlock, male 4

1

9

Figure 548: CA-OHAC Connections

872 / 910

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17 Cable Descriptions

17.1.44 CA-ONCCx The CA-ONCCx cable has three connection types. Each type is illustrated in a separate diagram.

17.1.44.1 Type 1 Connections The CA-ONCCx type 1 connections are shown in the following figure. BOBU 2 1 COAR/ABIS2 P1 6 7

8 9 SUM P2 4 5 3 1

2

1

P1, P5 Matenlock, male

2

Customer Equipment

1

5

8 P2, P3, P4 9

9

6

9−pin Sub−D male

6 7 COAR/ABIS1 P3 6 7

8 9 BOBU P4 2 1 P5

Figure 549: CA-ONCCx Type 1 Connections

3BK 20942 AAAA TQZZA Ed.13

873 / 910

17 Cable Descriptions

17.1.44.2 Type 2 Connections The CA-ONCCx type 2 connections are shown in the following figure. DCDP 1 6 COAR/ABIS2 P1 6 7

8 9 SUM P2 4 5 3 1 1

5

2

Customer Equipment

P1 to P5 9

6

8

9−pin Sub−D male 9

6 7 COAR/ABIS1 P3 6 7

8 9 DCDP P4 1 6 P5

Figure 550: CA-ONCCx Type 2 Connections

874 / 910

3BK 20942 AAAA TQZZA Ed.13

17 Cable Descriptions

17.1.44.3 Type 3 Connections The CA-ONCCx type 3 connections are shown in the following figure. COAR/ABIS2 6 7

8 9 SUM P1 4 5 3 1 1

2

Customer Equipment

5

P1, P2, P3 8

9

6

9−pin Sub−D male 9

6 7 COAR/ABIS1 P2 6 7

8 9 P3

Figure 551: CA-ONCCx Type 3 Connections

3BK 20942 AAAA TQZZA Ed.13

875 / 910

17 Cable Descriptions

17.1.45 CA-OSCP1 The CA-OSCP1 (part number 3BK 08095) cable connections are shown in the following figure. Side Compartment 1

2 3 4 5 6 7 8 9 9−pin Sub−D female 1 5

6

9

Figure 552: CA-OSCP1 Connections

876 / 910

3BK 20942 AAAA TQZZA Ed.13

17 Cable Descriptions

17.1.46 CA-OSCP2 The CA-OSCP2 (part number 3BK 08096) cable connections are shown in the following figure. BTS Compartment 1 1

2 3 4 5 6 7 8 9 9−pin Sub−D female 1 5

6

9

Figure 553: CA-OSCP2 Connections

17.1.47 CA-OSCP3 The CA-OSCP3 (part number 3BK 25548) cable connections are shown in the following figure. CBO

15− Pin Sub−D Female

Figure 554: CA-OSCP3 Connections

3BK 20942 AAAA TQZZA Ed.13

877 / 910

17 Cable Descriptions

17.1.48 CA-OSPC The CA-OSPC (part number 3BK 08079) connections are shown in the following figure. DCDP

STASR

1

−48 V

2

GND

3

0V Three Faston 6.8x0.8, female

Sub−D size A for three HP contacts

3

1

Figure 555: CA-OSPC Connections

17.1.49 CA-PCAN, CA-PCAP The CA-PCAN (part number 3BK 25115) and the CA-PCAP (part number 3BK 25114) connections are shown in the following figure. DCBREAK

CA−PCAN:

Blue

CA−PCAP:

Black

Lug, ring crimp, M6

ADAM

DIN wire ferrule

Figure 556: CA-PCAN, CA-PCAP Connections

17.1.50 CA-PCOS The CA-PCOS (part number 3BK 08809) connections are shown in the following figure. STASR

BOBU

1

3

3

2

4

1

Triple Faston, female 4

1

Triple Faston, male 3

1

Figure 557: CA-PCOS Connections

878 / 910

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17 Cable Descriptions

17.1.51 CA-PDCM, CA-PDCP The CA-PDCM (part number 3BK 25232) connections and the CA-PDCP (part number 3BK 25231) connections are shown in the following figure. ADAM

Battery Interconnection

CA−PDCM:

Blue

CA−PDCP:

Black

DIN wire ferrule

DIN wire ferrule

Figure 558: CA-PDCM, CA-PDCP Connections

17.1.52 CA-RFMW The CA-RFMW (part number 3BK 07931) connections are shown in the following figure. Connection Area

Microwave Equipment Shield

N type, male

N type, female

Figure 559: CA-RFMW Connections

17.1.53 CA-RIBCO The connections for the CA-RIBCO (part number 3BK 26347) are shown in the following figure. STASR 1

STASR 2

OUTC Flat Cable Connector Side Compart− ment 44*

P1 *: P1 : P2/P3 :

P2

P3

Break wire for coding purposes Flat cable connector, 50 pins, female DIN 41612, 64 pins, row A and only, female

Figure 560: CA-RIBCO Connections

3BK 20942 AAAA TQZZA Ed.13

879 / 910

17 Cable Descriptions

17.1.54 CA-RICPT1 The connections for the CA-RICPT1 (part number 3BK 25537) are shown in the following figure. STASR 2

44

P1

P1 : P2/P3 :

STASR 3

1

OUTC Flat Cable Connector Side Compart− ment

45

P2

P3

Break wire for coding purposes Flat cable connector, 50 pins, female DIN 41612, 64 pins, row A and C only, female

Figure 561: CA-RICPT1 Connections

17.1.55 CA-RICPT2 The connections for the CA-RICPT2 (part number 3BK 25538) are shown in the following figure. STASR 4 OUTC Flat Cable Connector Side Compart− ment 1

STASR 6 1

44 45 46

P1

P1 : P2/P4 :

STASR 5

1

47

P2

48

P3

P4

Break wire for coding purposes Flat cable connector, 50 pins, female DIN 41612, 64 pins, row A and only, female

Figure 562: CA-RICPT2 Connections

880 / 910

3BK 20942 AAAA TQZZA Ed.13

17 Cable Descriptions

17.1.56 CA-RIMO1 The connections for the CA-RIMO1 (part number 3BK 25822) are shown in the following figure. STASR 1

STASR 2

STASR 3

STASR 7

OUTC Flat Cable Connector Side Compart− ment 44*

P1

P2

*: P1 : P2/P5 :

45*

44, 45, 46, 47, 48*

P3

P4

P5

Break wire for coding purposes Flat cable connector, 50 pins, female DIN 41612, 64 pins, row A and only, female

Figure 563: CA-RIMO1 Connections

17.1.57 CA-RIMO2 The connections for the CA-RIMO2 (part number 3BK 25823) are shown in the following figure. STASR 5

STASR 4

STASR 6

STASR 0

OUTC Flat Cable Connector BTS Compart− ment 1 44, 45, 46* P1 *: P1 : P2/P5 :

47*

P2

48*

P3

44, 45*

P4

P5

Break wire for coding purposes Flat cable connector, 50 pins, female DIN 41612, 64 pins, row A and only, female

Figure 564: CA-RIMO2 Connections

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17.1.58 CA-SENSP The CA-SENSP (part number 3BK 26147) connections are shown in the following figure. 1

2 3 4 5 6

Resistor 105 Ohm 1%

7 8 9

9−Pin Sub−D Female

Figure 565: CA-SENSP Connections

17.1.59 CA-XBCBO The CA-XBCBO (part number 3BK 08205) connections are shown in the following figure. ACRI

COAR 15

15

15−pin Sub−D male

15−pin Sub−D male

Figure 566: CA-XBCBO Connections

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17 Cable Descriptions

17.1.60 CA-XIOC The CA-XIOC (part number 3BK 26353) connections are shown in the following figure. XIOB 1 − 48V (Blue)

To DCUC X10

2 Not Used 3 0V (Black)

To DCUC X9 DIN Wire Ferrules

Mate−N Lock, Male 3

1

Figure 567: CA-XIOC Connections

17.1.61 CA-XIOPC The CA-XIOPC (part number 3BK 08087) connections are shown in the following figure. DCDP 1

2 3 4 5 XIOB

6

1

7

2

8

3

9

Matenlock, female 3

1

9−pin Sub−D male 5

1

6

9

Figure 568: CA-XIOPC Connections

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17.1.62 CIMA Bus Bar The CIMA (part number 3BK 07762) bus bar connections are shown in the following figure. x7 (Red)

P1

x7 (Blue)

Ground (M8 bolt) P3

Circuit Breakers

x7 (Black) 0 VDC Filter

P2 x3 (Red, Blue, Black)

P4 P5

XIOB

x3 (Red, Blue, Black)

Top Fan Backplane

Fixing Rail x3 (Red, Blue, Black) P6

Subrack 5 Fixing Holes x3 (Red, Blue, Black)

P7

Subrack 4

P8

Subrack 3

P9

Subrack 2

P10

Subrack 1

x3 (Red, Blue, Black)

x3 (Red, Blue, Black)

x3 (Red, Blue, Black)

Bus Bar

GND Bolt

GND

Filter

Breakers

0V

−48 V

Subrack 1 − 5 and Top Fan Backplane

XIOB

1

GND

2

−48 V

GND

−48 V 0V

3

4 P4 x7 P1 P1: P2: P3: P4: P5 − P10:

0V

3

3

1

P5 − P10 1

4

1

P2 P3 Spade, made, M8 hole Spade, male, M6 hole Spade, male, open tongue, M5 Matenlock, female Triple Faston, female

Figure 569: CIMA Bus Bar Connections

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17.1.63 CIMI Bus Bar The CIMI (part number 3BK 07763) bus bar connections are shown in the following figure. x4 (Red)

P1

x4 (Blue)

Ground (M8 bolt) P3

Circuit Breakers

x4 (Black) 0 VDC Filter

P2 x3 (Red, Blue, Black)

P4 P5

XIOB

x3 (Red, Blue, Black)

Top Fan Backplane

Fixing Holes

x3 (Red, Blue, Black) P6

Subrack 2

P7

Subrack 1

Fixing Rail

x3 (Red, Blue, Black)

Bus Bar

GND Bolt GND

Filter

Breakers

0V

−48 V

Subrack 1, 2 and Top Fan Backplane

XIOB 1

GND

2

−48 V

GND

−48 V

3

0V 4 P4

x4 P1 P1: P2: P3: P4: P5 − P7:

P2

0V

3

3

1

P5 − P7 1

4

1

P3

Spade, made, M8 hole Spade, male, M6 hole Spade, male, open tongue, M5 Matenlock, female Triple Faston, female

Figure 570: CIMI Bus Bar Connections

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17.1.64 RXRC The RXRC (part number 3BK 07920) connections are shown in the following figure. TRE/AN

AN Shield

Alignment Hole

P1

P2 Note: For ANS modules only one RXRC line is fitted

P1, P2:

Subminiature connectors, 50

series SMB, straight, female

Figure 571: RXRC Connections

17.1.65 TXRC The TXRC (part number 3BK 07919) connections are shown in the following figure. TRE/AN

AN Shield

Coaxial connector, 50

series N

Coaxial connector, 50

series N

Figure 572: TXRC Connections

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17 Cable Descriptions

17.2 External Cables The physical and electrical characteristics for the indoor and outdoor external cables are given in the following sections.

17.2.1 CA01 The CA01 (part number 3BK 07594) Abis cable connections are shown in the following figure. BTS A9100 side

Customer’s Distribution Board

1

2 3 4 5

Shield

6 7 8 9 9−pin Sub−D male 1

Customer dependent

5

6

9

Figure 573: CA01 Connections

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17.2.2 CA02 The CA02 (part number 3BK 07595) Abis cable connections are shown in the following figure. BTS A9100 side

Customer’s Distribution Board

1

2 3 4 5 6

Shield

7 8 9 9−pin Sub−D male 1

6

Customer dependent

5

9

Figure 574: CA02 Connections

17.2.3 CA03 The CA03 (part number 3BK 07596) Abis cable connections are shown in the following figure. TX

Shield

RX

Figure 575: CA03 Connections

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17.2.4 CA04 The CA04 (part number 3BK 07597) Abis cable connections are shown in the following figure. Shield

Figure 576: CA04 Connections

17.2.5 CA-CBTE The CA-CBTE (part number 3BK 07951) cable connections are shown in the following figure. BTS Terminal

SUM Shield 1

1

2

2

3

3

4

4

5

5

6

6

7

7

8

8

9

9

9−pin Sub−D male 1 5

6

9

9−pin Sub−D female 5

9

1

6

Figure 577: CA-CBTE Connections

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17.2.6 CA-GC35 The CA-GC35 (part number 3BK 08031) cable connections are shown in the following figure. Customer’s Ground Point

BTS A9100

Lug, ring, crimp, 9 mm

Figure 578: CA-GC35 Connections

17.2.7 CA-GND The CA-GND (part number 3BK 25349) cable connection is shown in the following figure. Lug, Ring M8

Lug, Ring M8

Figure 579: CA-GND Connection

17.2.8 CA-PC2W16 The CA-PC2W16 (part number 3BK 08029) cable connections are shown in the following figure. Customer’s −48/0 VDC Source

BTS A9100 Black Wire 0 V

Black Wire 0 V

1

3

Blue Wire −48 V

Blue Wire −48 V

2

4

Lug, ring, crimp, 5.8 mm

1

2

Lug, ring, crimp, 5.8 mm

3

4

Figure 580: CA-PC2W16 Connections

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17.2.9 CA-PC35BK The CA-PC35BL (part number 3BK 08032) cable connections are shown in the following figure. BTS A9100

Customer’s 0 VDC Source Black Wire 0 V

Black Wire 0 V

Lug, ring, crimp, 5.8 mm

Lug, ring, crimp, 5.8 mm

Figure 581: CA-PC35BK Connections

17.2.10 CA-PC35BL The CA-PC35BL (part number 3BK 08032) cable connections are shown in the following figure. Customer’s −48 VDC Source

BTS A9100 Blue Wire −48 V

Blue Wire −48 V

Lug, ring, crimp, 5.8 mm

Lug, ring, crimp, 5.8 mm

Figure 582: CA-PC35BL Connections

17.2.11 CA-PCEBM The CA-PCEBM (part number 3BK 25260) cable connection is shown in the following figure. Lug, Ring M6

Shrinking Sleeve

Lug, Pin

Figure 583: CA-PCEBM Connection

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17.2.12 CA-PCEBP The CA-PCEBP (part number 3BK 25259) cable connection is shown in the following figure. Lug, Ring M6

Shrinking Sleeve

Lug, Pin

Figure 584: CA-PCEBP Connection

17.2.13 CA-RIBEB The CA-RIBEB (part number 3BK 25258) cable connections are shown in the following figure. 15 pin female connector

15 pin male connector

123 123 123 8

1

123 123 123 Wiring list

15

9

8

COAR/OUTC Side P1/male

External Battery Side P2/female

Quad Number

1/9, 2/10 4/12, 6/14 5/13, 8 3/11, 7/15

1/9, 2/10 4/12, 6/14 5/13, 8 3/11, 7/15

I II III iV

15

1

9

Figure 585: CA-RIBEB Connections

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17 Cable Descriptions

17.2.14 CA-RIBEO The CA-RIBEO (part number 3BK 26138) cable connections are shown in the following figure. 15 pin female connector (to first RIBAT at external Battery Cabinet outdoor; assembling on site after guiding through cable gland)

15 pin male connector (to OUTC at BTS )

1234 1234 1234 8

1

15

9

1234 1234 1234 8

Wiring list COAR/OUTC Side P1/male

External Battery Side P2/female

Quad Number

1/9, 2/10 4/12, 6/14 5/13, 8 3/11, 7/15

1/9, 2/10 4/12, 6/14 5/13, 8 3/11, 7/15

I II III iV

1

15

9

Figure 586: CA-RIBEO Connections

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17.2.15 OCC23 The OCC23 (part number 3BK 08303) cable connections are shown in the following figure. BTS A9100

G2 BTS Shield

1

1

5

5

9

9

4

4

8

8

3

3

7

7

2

2

6

6

9−pin Sub−D male 1

5

6

Shield Solder Point

9

9−pin Sub−D male 1 5

6

9

Figure 587: OCC23 Connections

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17.2.16 OCC33 The OCC33 (part number 3BK 08304) cable connections are shown in the following figure. BTS A9100

BTS A9100 Shield

1

1

5

5

9

9

4

4

8

8

3

3

7

7

2

2

6

6

9−pin Sub−D male 1

5

6

Shield Solder Point

9

9−pin Sub−D male 1 5

6

9

Figure 588: OCC33 Connections

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17.2.17 SCG2/3 The SCG2/3 (part number 3BK 08101) cable connections are shown in the following figure. BTS A9100

G2 BTS Shield

1

1

5

5

9

9

4

4

8

8

3

3

7

7

2

2

6

6

9−pin Sub−D male 9 6

5

Shield Solder Point

1

9−pin Sub−D male 1 5

6

9

Figure 589: SCG2/3 Connections

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17.2.18 SCG3 The SCG3 (part number 3BK 07950) cable connections are shown in the following figure. COAR of Second BTS A9100

COAR of First BTS A9100 Shield

1

1

2

2

6

6

3

3

7

7

4

4

8

8

5

5

9

9

9−pin Sub−D male 1 5

6

9

9−pin Sub−D male 1

5

6

9

Figure 590: SCG3 Connections

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17.2.19 SCM1/3 The SCM1/3 (part number 3BK 08102) cable connections are shown in the following figure. G1 BTS Mark1

BTS A9100 Shield

1

1

5

9

9

5 P3

4

6

8

2

3

7

7

3

2

8

6

4 P2

P1 9

6

P3

9

6

Shield Solder Point

P1

1

1

5

P2 5

P1, P2, P3:

5

1

6

9

9−pin Sub−D male

Figure 591: SCM1/3 Connections

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17.2.20 SCM2/3 The SCM2/3 (part number 3BK 08103) cable connections are shown in the following figure. BTS A9100

G1 BTS Mark2 Shield

1

1

5

5

9

9

4

4

8

8

3

3

7

7

2

2

6

6

9−pin Sub−D male 9 6

5

Shield Solder Point

1

9−pin Sub−D male 1 5

6

9

Figure 592: SCM2/3 Connections

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18 Environment The sections are supported with data tables, where necessary. References to the relevant European and International standards are also given, when appropriate.

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18.1 Indoor Climatic and Mechanical Conditions This section describes the climatic and mechanical conditions required for the safe and efficient operation of indoor BTS A9100 equipment. It includes information on the following: Environmental requirements Operational conditions Transportation conditions Storage conditions.

18.1.1 Environmental Requirements The BTS A9100 equipment housings provide the necessary environmental and safety protection according to the standard ETS 300 019, for indoor equipment.

18.1.2 Operational Conditions Operational conditions are specified in accordance with Class 3.1E, ETS 300 019-1-3, as shown in the following table. Type

Condition

Limit

Climatic

Low temperature

-5 C

High temperature

+45 C

Low relative humidity

5%

High relative humidity

90 %

Low absolute humidity

1 g/ m3

High absolute humidity

25 g/ m3

Rate of change of temperature

0.5 C/ min

Low air pressure

70 kPa

High air pressure

106 kPa

Mechanical

Displacement amplitude in Frequency Range 2-9 Hz

0.3 mm p-p

(Vibration)

Acceleration amplitude in Frequency Range 9-200 Hz

0.1 m/ s2

Shock

-

40 m/ s

2

Table 173: Environmental Conditions for Indoor Operation

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18.1.3 Transportation Conditions Transportation conditions are specified in accordance with Class2.2, ETS 300 019 -1-2, as shown in the following table. Type

Condition

Limit

Climatic

Low temperature

-40 C

High temperature

+70 C

High relative humidity

95 %

High absolute humidity

60 g/ m

Low air pressure

70 kPa

Displacement amplitude (frequency 2- 9 Hz)

3.5 mm

Acceleration amplitude (frequency 9-200 Hz)

10 m/ s

Acceleration amplitude (frequency 200-500 Hz)

15 m/ s2

Free Fall

100 mm

Steady State Acceleration

20 m/ s

Static Load

5 kPa

Mechanical

3

2

2

Table 174: Environmental Conditions for Transportation

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18.1.4 Storage Conditions Storage conditions are specified in accordance with Class 1.2, ETS 300 019-1 -1, as shown in the following table. Type

Condition

Limit

Climatic

Low temperature

-25 C

High temperature

+55 C

Low relative humidity

10 %

High relative humidity

100 %

Low absolute humidity

0.5 g/ m3

High absolute humidity

29 g/ m

Low air pressure

70 kPa

High air pressure

106 kPa

Displacement amplitude (frequency 2 - 9 Hz)

1.5 mm

Acceleration amplitude (frequency 9 - 200 Hz)

5 m/ s

Steady State Acceleration

40 m/ s2

Static Load

5 kPa

Mechanical

3

2

Table 175: Environmental Conditions for Storage

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18.2 Outdoor Climatic and Mechanical Conditions This section describes the climatic and mechanical conditions required for the safe and efficient operation of outdoor BTS A9100 equipment. It includes information on the following: Environmental requirements Operational conditions Transportation conditions Storage conditions.

18.2.1 Environmental Requirements The BTS A9100 equipment housings provide the necessary environmental and safety protection according to the standard ETS 300 019, for outdoor equipment.

18.2.2 Operational Conditions Operational conditions are specified in accordance with Class 4.1E, ETS 300 019-1 -4, as shown in the following table. Type

Condition

Limit

Climatic

Low temperature

-45 C

High temperature

+45 C

Low relative humidity

8%

High relative humidity

100 %

Low absolute humidity

0.26 g/ m

High absolute humidity

30 g/ m3

Rate of change of temperature

0.5 C/ min

Low air pressure

70 kPa

High air pressure

106 kPa

Mechanical

Displacement amplitude in Frequency Range 2-9 Hz

1.5 mm p-p

(Vibration)

Acceleration amplitude in Frequency Range 9-200 Hz

5 m/ s

Shock

-

70 m/ s2

3

2

Table 176: Environmental Conditions for Outdoor Operation

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18.2.3 Transportation Conditions Transportation conditions are specified in accordance with Class2.2, ETS 300 019 -1-2, as shown in the following table. Type

Condition

Limit

Climatic

Low temperature

-40 C

High temperature

+70 C

High relative humidity

95 %

High absolute humidity

60 g/ m

Low air pressure

70 kPa

Displacement amplitude (frequency 2 - 9 Hz)

3.5 mm

Acceleration amplitude (frequency 9-200 Hz)

10 m/ s

Acceleration amplitude (frequency 200-500 Hz)

15 m/ s2

Free Fall

100 mm

Steady State Acceleration

20 m/ s

Static Load

5 kPa

Mechanical

3

2

2

Table 177: Environmental Conditions for Transportation

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18.2.4 Storage Conditions Storage conditions are specified in accordance with Class 1.2, ETS 300 019-1 -1, as shown in the following table. Type

Condition

Limit

Climatic

Low temperature

-25 C

High temperature

+55 C

Low relative humidity

10 %

High relative humidity

100 %

Low absolute humidity

0.5 g/ m3

High absolute humidity

29 g/ m

Low air pressure

70 kPa

High air pressure

106 kPa

Displacement amplitude (frequency 2 - 9 Hz)

1.5 mm

Acceleration amplitude (frequency 9 - 200 Hz)

5 m/ s

Steady State Acceleration

40 m/ s2

Static Load

5 kPa

Mechanical

3

2

Table 178: Environmental Conditions for Storage

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18.3 Electromagnetic Compatibility This section describes the EMC compatibility of BTS A9100 equipment. It provides information on the following: EMC immunity Transient bursts Spurious emissions. BTS A9100 equipment complies with the following EMC standards: European Directive 89/336/EEC ETS 300 342 Part 2, and Draft ETSI EN 300 342 Part 2.

18.3.1 EMC Immunity This section contains information on EMC immunity. EMC immunity ensures the normal operation of BTS A9100 equipment when subjected to the conditions specified in the following table. Parameter

Standard

Electrostatic Discharge

IEC 1000-4-2: Levels 2 and 3.

RF Common Mode

IEC 1000-4-6: 3 Vrms 150 kHz to 80 MHz.

Radiated Fields

IEC 1000-4-3: 3 V/ m, 80 MHz to 1 GHz (+ 1.8 GHz excepted reception band).

Transient Pulse Immunity

IEC 1000-4-4: Levels 2 and 3 (see Table Permitted Transient Bursts (180)). ETS 300 342-2.

Surges (on AC lines)

IEC 1000-4-5: level 500 V at differential mode; level 1 kV at common mode. Note that all outdoor Evolium™ BTS A9100 external lines have better surge protection characteristics than that defined in IEC 1000-4-5.

Table 179: EMC Immunity

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18.3.2 Transient Bursts The following table shows the IEC 1000-4-4 Levels 2 and 3 transient voltage bursts. These are the voltage bursts that the different types of lines can withstand without causing permanent defects to the equipment. Peak Amplitude

Level

Line Type

±2000 V

3

AC power lines

±1000 V

2

DC power lines

±500 V

2

Signal lines (including RF)

Table 180: Permitted Transient Bursts

Note:

The amplitudes shown in the above table must not exceed 50 ns duration or have a rise time of less than 5 ns.

18.3.3 Spurious Emissions Potential EMC emissions of BTS A9100 equipment (unintentionally produced) are shown in the following table. Type

Standard

Frequency Range

Conducted Emissions on Power Lines:

EN 55022 Class B (AC powered BTS)

150 kHz - 30 MHz

Radiated Emissions from Enclosure:

GSM 11.21

EN 55022 Class A (DC powered BTS) 30 MHz - 4 GHz

Table 181: EMC Emissions

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18.4 Acoustic Noise This section describes the acoustic noise parameters which apply to BTS A9100 equipment. The acoustic noise generated by the equipment is measured according to ISO 7779 and ISO 9296. Noise limits for the measurements are in accordance with GSM 11.22 and ETS 300 753, respectively.

18.5 Safety Requirements Safety standards cover protection against: Electric shock Skin burns Radio frequency radiation hazards Fire hazards Mechanical hazards Energy hazards Chemical hazards. The indoor and outdoor BTS are compliant with the following safety standards: Indoor BTS EN60215 - Safety Requirements for Radio Transmitting Equipment EN60950 - Safety of Information Technology Equipment. Outdoor BTS EN60215 - Safety Requirements for Radio Transmitting Equipment EN60950 - Safety of Information Technology Equipment EN41003 - Safety Requirements for Apparatus for Connection to Telecommunications Networks ISO 3864 - Safety Colors and Safety Signs.

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