Nokia Siemens Networks WCDMA RAN, Rel. RU20, Operating Documentation, Issue 04
WCDMA RNC Engineering Description DN0938143 Issue 1-4 Approval Date 2010-09-23
Confidential
WCDMA RNC Engineering Description
The information in this document is subject to change without notice and describes only the product defined in the introduction of this documentation. This documentation is intended for the use of Nokia Siemens Networks customers only for the purposes of the agreement under which the document is submitted, and no part of it may be used, reproduced, modified or transmitted in any form or means without the prior written permission of Nokia Siemens Networks. The documentation has been prepared to be used by professional and properly trained personnel, and the customer assumes full responsibility when using it. Nokia Siemens Networks welcomes customer comments as part of the process of continuous development and improvement of the documentation. The information or statements given in this documentation concerning the suitability, capacity, or performance of the mentioned hardware or software products are given "as is" and all liability arising in connection with such hardware or software products shall be defined conclusively and finally in a separate agreement between Nokia Siemens Networks and the customer. However, Nokia Siemens Networks has made all reasonable efforts to ensure that the instructions contained in the document are adequate and free of material errors and omissions. Nokia Siemens Networks will, if deemed necessary by Nokia Siemens Networks, explain issues which may not be covered by the document. Nokia Siemens Networks will correct errors in this documentation as soon as possible. IN NO EVENT WILL Nokia Siemens Networks BE LIABLE FOR ERRORS IN THIS DOCUMENTATION OR FOR ANY DAMAGES, INCLUDING BUT NOT LIMITED TO SPECIAL, DIRECT, INDIRECT, INCIDENTAL OR CONSEQUENTIAL OR ANY LOSSES, SUCH AS BUT NOT LIMITED TO LOSS OF PROFIT, REVENUE, BUSINESS INTERRUPTION, BUSINESS OPPORTUNITY OR DATA,THAT MAY ARISE FROM THE USE OF THIS DOCUMENT OR THE INFORMATION IN IT. This documentation and the product it describes are considered protected by copyrights and other intellectual property rights according to the applicable laws. The wave logo is a trademark of Nokia Siemens Networks Oy. Nokia is a registered trademark of Nokia Corporation. Siemens is a registered trademark of Siemens AG. Other product names mentioned in this document may be trademarks of their respective owners, and they are mentioned for identification purposes only. Copyright © Nokia Siemens Networks 2010. All rights reserved
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Important Notice on Product Safety Elevated voltages are inevitably present at specific points in this electrical equipment. Some of the parts may also have elevated operating temperatures. Non-observance of these conditions and the safety instructions can result in personal injury or in property damage. Therefore, only trained and qualified personnel may install and maintain the system. The system complies with the standard EN 60950 / IEC 60950. All equipment connected has to comply with the applicable safety standards.
The same text in German: Wichtiger Hinweis zur Produktsicherheit In elektrischen Anlagen stehen zwangsläufig bestimmte Teile der Geräte unter Spannung. Einige Teile können auch eine hohe Betriebstemperatur aufweisen. Eine Nichtbeachtung dieser Situation und der Warnungshinweise kann zu Körperverletzungen und Sachschäden führen. Deshalb wird vorausgesetzt, dass nur geschultes und qualifiziertes Personal die Anlagen installiert und wartet. Das System entspricht den Anforderungen der EN 60950 / IEC 60950. Angeschlossene Geräte müssen die zutreffenden Sicherheitsbestimmungen erfüllen.
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DN0938143 Issue 1-4
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Table of contents This document has 117 pages. Summary of changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
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About WCDMA RNC Engineering Description. . . . . . . . . . . . . . . . . . . . 10
2
RNC Hardware Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
3 3.1 3.2 3.3
IPA2800 System Architecture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Internal Messaging and Resource Allocation. . . . . . . . . . . . . . . . . . . . . Computing System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Redundancy Principles for IPA2800 Network Elements . . . . . . . . . . . .
13 15 16 17
4 4.1 4.1.1 4.1.2 4.1.3 4.2 4.3 4.4 4.4.1 4.5
Mechanical Construction of the IPA2800 Network Elements. . . . . . . . . Cabinets. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . EC216 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IC186/-B. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Dimensions of Cabinets in Floor Rail on Free-standing Installations. . . Subracks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Plug-in Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cabling. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Cabling Principles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cooling Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
21 21 22 23 24 27 28 29 30 30
5 5.1 5.2 5.3 5.3.1
Cabinet and Subrack Descriptions for RNC2600. . . . . . . . . . . . . . . . . . RNC2600 Cabinet Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Equipment in the Subracks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RNC2600 Upgrades and Expansions in RN5.0 . . . . . . . . . . . . . . . . . . . Optional Expansions for RNC2600 . . . . . . . . . . . . . . . . . . . . . . . . . . . .
31 31 33 36 36
6 6.1 6.2 6.3 6.3.1 6.3.2 6.4 6.4.1 6.4.2
Cabinet and Subrack Descriptions for RNC450. . . . . . . . . . . . . . . . . . . RNC450 Cabinet Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Equipment in the subracks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RNC450 Upgrades and Expansions in RN5.0 . . . . . . . . . . . . . . . . . . . . Mandatory Upgrades for RNC450 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Optional Upgrades and Expansions for RNC450 . . . . . . . . . . . . . . . . . RNC450 Upgrades and Expansions in RN4.0 . . . . . . . . . . . . . . . . . . . . Mandatory Upgrades for RNC450 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Optional Upgrades and Expansions for RNC450 . . . . . . . . . . . . . . . . .
37 37 39 42 42 42 42 42 43
7 7.1 7.1.1 7.1.2 7.1.3 7.1.4 7.1.5 7.2 7.3 7.3.1
Cabinet and Subrack Descriptions for RNC196. . . . . . . . . . . . . . . . . . . RNC196 Cabinet Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RNC196 Step 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RNC196 Step 6 and RNC196 Step 7. . . . . . . . . . . . . . . . . . . . . . . . . . . Hardware Upgrade to RNC196 Step 6 and RNC196 Step 7 . . . . . . . . . RNC196 Step 8 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Hardware Upgrade to RNC196 Step 8 . . . . . . . . . . . . . . . . . . . . . . . . . Equipment in the Subracks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Upgrades and Expansions for RNC196 in RN5.0 . . . . . . . . . . . . . . . . . Mandatory Upgrades for RNC196 . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
44 44 45 47 49 52 54 57 60 60
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7.3.2 7.4 7.4.1 7.4.2
Optional Upgrades for RNC196 . . . . . . . . . . . . . . . . . . . Upgrades and Expansions for RNC196 in RN4.0 . . . . . . Mandatory Upgrades for RNC196 . . . . . . . . . . . . . . . . . Optional Upgrades for RNC196 . . . . . . . . . . . . . . . . . . .
8 8.1 8.2 8.2.1 8.2.2 8.2.3 8.2.4 8.2.5 8.2.6 8.2.7 8.2.8 8.2.9 8.3 8.3.1 8.3.2 8.3.3 8.4 8.4.1 8.4.2 8.4.3 8.4.4 8.5 8.5.1 8.5.2 8.5.3 8.6
Functional Unit Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62 Functional Unit Categories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62 Management, Control Computer and Data Processing Units . . . . . . . . . 62 DMCU, Data and Macro Diversity Combining Unit . . . . . . . . . . . . . . . . . 62 GTPU, Gateway Tunneling Protocol Unit . . . . . . . . . . . . . . . . . . . . . . . . 64 ICSU, Interface Control and Signalling Unit . . . . . . . . . . . . . . . . . . . . . . 67 Integrated OMS, Operation and Maintenance Server and its sub-units . 70 ESA24, Ethernet Switch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 ESA12, Ethernet Switch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74 OMU, Operation and Maintenance Unit and Its Subunits . . . . . . . . . . . . 75 RRMU, Radio Resource Management Unit . . . . . . . . . . . . . . . . . . . . . . 80 RSMU, Resource and Switch Management Unit . . . . . . . . . . . . . . . . . . 83 Switching and Multiplexing Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 A2SU, AAL2 Switching Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 MXU, Multiplexer Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90 SFU, Switching Fabric Unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 92 Network Interface Units. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 NIP1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 NIS1 / NIS1P. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 NPS1 / NPS1P . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 NPGE / NPGEP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 Timing, Power Distribution and Hardware Management Subsystems . 100 TBU, Timing and Hardware Management Bus Unit . . . . . . . . . . . . . . . 100 HMS, Hardware Management Subsystem . . . . . . . . . . . . . . . . . . . . . . 104 Power Distribution Subsystem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 107 EHU, External Hardware Alarm Unit. . . . . . . . . . . . . . . . . . . . . . . . . . . 111
9 9.1 9.2 9.3 9.4 9.5 9.6 9.7 9.8
Interfaces to the Environment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112 Power Supply and Grounding Interfaces . . . . . . . . . . . . . . . . . . . . . . . 112 PDH TDM Interfaces. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116 SDH TDM Interfaces. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116 External Synchronisation Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . 116 External HW Alarm Interfaces. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 Ethernet/LAN Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 Mouse, Keyboard, VDU, SCSI and Printer Interfaces . . . . . . . . . . . . . 117 RS232 Service Terminal Interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
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List of figures Figure 1 Figure 2 Figure 3 Figure 4 Figure 5 Figure 6 Figure 7 Figure 8 Figure 9 Figure 10 Figure 11 Figure 12 Figure 13 Figure 14 Figure 15 Figure 16 Figure 17 Figure 18 Figure 19 Figure 20 Figure 21 Figure 22 Figure 23 Figure 24 Figure 25 Figure 26 Figure 27 Figure 28 Figure 29 Figure 30 Figure 31 Figure 32 Figure 33 Figure 34 Figure 35 Figure 36 Figure 37 Figure 38 Figure 39 Figure 40 Figure 41 Figure 42
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Block diagram of the RNC2600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Block diagram of the RNC450 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 EC216 cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 IC186-B cabinet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 Dimensions of the EC216 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 Dimensions of the IC186-B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 Dimensions of EC216 / IC186-B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 SRA1 subrack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 Layout options for the RNC2600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 RNAC cabinet in RNC2600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 RNBC cabinet in RNC2600 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 Layout options for the RNC450 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 RNAC cabinet in RNC450 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 RNBC cabinet in RNC450 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 39 Layout options for the RNC196 (with optional cabling cabinet) . . . . . . . 44 RNAC cabinet - RNC196 step 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46 RNBC cabinet - RNC196 steps 2-5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 RNAC cabinet - RNC196 steps 6 and 7. . . . . . . . . . . . . . . . . . . . . . . . . 48 RNBC cabinet - RNC196 steps 6 and 7. . . . . . . . . . . . . . . . . . . . . . . . . 49 Configuration steps RNC196 step 6 and 7 with mandatory hardware changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50 RNAC cabinet - RNC196 step 8 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 RNBC cabinet - RNC196 step 8 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 Configuration step RNC196 step 8 with mandatory hardware changes 56 DMCU's interfaces - CDSP-DH . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 DMCU's interfaces - CDSP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 64 GTPU's interfaces - CCP18-C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65 GTPU's interfaces - CCP18-A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 66 GTPU's interfaces - CCP10 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 67 ICSU's interfaces - CCP18-C. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 ICSU's interfaces - CCP18-A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69 ICSU's interfaces - CCP10 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70 Integrated OMS interfaces (MCP18-B) . . . . . . . . . . . . . . . . . . . . . . . . . 71 Integrated OMS storage device interfaces. . . . . . . . . . . . . . . . . . . . . . . 72 SCSI connection principle for integrated OMS storage devices (MCP18-B) 73 ESA24's interfaces. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74 ESA12's interfaces. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75 OMU's interfaces - CCP18-A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76 OMU's interfaces - CCP10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77 OMU's storage devices' interfaces. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78 SCSI connection principle for OMU storage devices - CCP18-A and HDS-B 79 SCSI connection principle for OMU storage devices - CCP10, HDS-A and MDS-A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 RRMU's interfaces - CCP18-C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
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Figure 43 Figure 44 Figure 45 Figure 46 Figure 47 Figure 48 Figure 49 Figure 50 Figure 51 Figure 52 Figure 53 Figure 54 Figure 55 Figure 56 Figure 57 Figure 58 Figure 59 Figure 60 Figure 61 Figure 62 Figure 63 Figure 64 Figure 65 Figure 66 Figure 67 Figure 68 Figure 69 Figure 70 Figure 71
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RRMU's interfaces - CCP18-A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82 RRMU's interfaces - CCP10 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 RSMU's interfaces - CCP18-C . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84 RSMU's interfaces - CCP18-A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 RSMU's interfaces - CCP10. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86 ATM connections to SFU - RNC450 . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 A2SU's interfaces - AL2S-D . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 89 A2SU's interfaces - AL2S-B . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90 MXU's interfaces - MX1G6 and MX1G6-A . . . . . . . . . . . . . . . . . . . . . . . 91 MXU's interfaces - MX622 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 92 SFU's interfaces - SF20H . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 SFU's interfaces - SF10E . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 SFU's interfaces - SF10 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 NIP1's interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 NIS1's interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 NPS1(P) interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98 NPGE(P) interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 TSS3/-A's interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 102 TBUF's interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 Connection principle of the duplicated clock distribution bus . . . . . . . . 104 Block diagram of the HMS subsystem . . . . . . . . . . . . . . . . . . . . . . . . . 105 Connection principle of the duplicated HMS bus . . . . . . . . . . . . . . . . . 106 PD30/PD20's interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108 General power distribution principle for RNC . . . . . . . . . . . . . . . . . . . . 110 DC/DC converter structure in a plug-in unit . . . . . . . . . . . . . . . . . . . . . 111 Power supply interfaces of CPD120-A with DC/I principle . . . . . . . . . . 113 Power supply interfaces of CPD120-A with DC/C principle . . . . . . . . . 114 Power supply interfaces of CPD80-B with two connection alternatives and optional ETS grounding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115 Power supply interfaces of CPD80-A and their connection alternatives: DC/I and DC/C principle . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116
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List of tables Table 1 Table 2 Table 3 Table 4 Table 5 Table 6 Table 7 Table 8 Table 9 Table 10 Table 11
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Computing platform hierarchy levels for IPA2800 RNC . . . . . . . . . . . . 16 Redundancy principles of the functional units in the RNC . . . . . . . . . . 19 Number of units in RNC2600 subracks . . . . . . . . . . . . . . . . . . . . . . . . . 34 Maximum number of units in the RNC2600 for each configuration step 34 Numbers of units in RNC450 subracks . . . . . . . . . . . . . . . . . . . . . . . . . 39 Maximum number of units in the RNC450 for each configuration step . 40 Minimum hardware level and configuration expansion for RNC196 step 6 51 Minimum hardware level and configuration expansion for RNC196 step 7 51 Minimum hardware level and configuration expansion for RNC196 step 8 57 Number of units in RNC196 subracks . . . . . . . . . . . . . . . . . . . . . . . . . . 57 Maximum number of units in RNC196 for each configuration step . . . . 59
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WCDMA RNC Engineering Description
Summary of changes
Summary of changes Changes between document issues are cumulative. Therefore, the latest document issue contains all changes made to previous issues. Issue 1-4 In Table 1 Computing Platform Hierarchy Levels, operating system for MCP18-B has been corrected to Linux. Issue 1-3 Reference to Hardware upgrades from RNC196 step 7 to step 8 removed because this document is not ready. Issue 1-2 MCP18-B removed. added text to clarify the difference between Upgrade and Expansion in Chapter 1. Added Chaper 5.3 RNC2600 Upgrades and Expansions in RN5.0.Chaper 6.3.1, added Minimum hardware requirement for all configurations in RN5.0: the disk size for Integrated OMS must be at least 147 GB. Added reference to Hardware Expansion for RNC450 and Upgrading RNC450 to RNC2600Chaper 6.3.2, Added reference to Hardware Expansion for RNC450 and Upgrading RNC450 to RNC2600Chaper 6.4.1, Added reference to Hardware Expansion for RNC450 and Upgrading RNC450 to RNC2600Chaper 7.3.1, added Minimum hardware requirement for all configurations in RN5.0: the disk size for Integrated OMS must be at least 147 GB. Chaper 7.3.2, Added reference to Hardware Expansion for RNC196.Chaper 7.4.1, Added reference to Hardware Expansion for RNC196. Issue 1-1 Chapter 1: Noted that the upgrades supported in RN4.0 are also supported in RN5.0. Added RNC196 step 5 to step 6 and 7. Added Full CDSP-DH upgrade. Chapter 6.3.3 Optional upgrades and expansions for RNC450:Noted that the upgrades supported in RN4.0 are also supported in RN5.0. Added full CDSP-DH upgrade. Chapter 6.4.2 Optional upgrades and expansions for RNC450: Added Full CDSP-DH upgrade. Chapter 7.1.4 RNC196 step 8 and chapter 7.1.5 Hardware upgrade to RNC196 step 8 was updated according to new architecture. Chapter 7.3.2 Optional upgrades for RNC196: Added RNC196 step 7 to step 8 upgrade. Added Full CDSP-DH upgrade. Noted that the upgrades supported in RN4.0 are also supported in RN5.0. Issue 1-0 Issue 1-0 is the first issue for the RNC2600 network element with RN5.0 software. The main, optional change from RN4.0 is that the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. With the integrated OMS, its plug-in unit MCP18-B and the related two HDDs must also be removed, as well as all SCSI connections between OMS and the HDD, and the LAN connection between OMS and the Ethernet Switch (ESA24).
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About WCDMA RNC Engineering Description
WCDMA RNC Engineering Description
1 About WCDMA RNC Engineering Description This Engineering Description provides the basic information needed for the installation planning of the WCDMA RNC. It does not include the installation planning instructions for the site power supply equipment or for the PDH and alarm distribution frames. WCDMA RNC Engineering Description provides the following information: • • • • • • •
System architecture Mechanical construction of the network element Cabinet and subrack descriptions for RNC2600 Cabinet and subrack descriptions for RNC450 Cabinet and subrack descriptions for RNC196 Functional unit descriptions Interfaces to the environment
New deliveries, expansions, and upgrades This document describes the hardware configurations, mechanics, and electromechanics for RNC2600 new deliveries and expansions, as well as upgrades and expansions for previously delivered RNC450 and RNC196 at RN5.0 and RN4.0 hardware level. Cabinet mechanics used in the different delivery types are described in section Mechanical construction of the IPA2800 network elements. Hardware configurations for RNC450 are described in section Cabinet and subrack descriptions for RNC450 and for RNC196 (Upgrading to RNC196 step 6 and 7, upgrading RNC196 step 7 to step 8) in section Cabinet and subrack descriptions for RNC196. For more information on upgrades at RN5.0 hardware level, see Upgrading from RN4.0 OMS to RN5.0 OMS and Upgrading from integrated RNC OMS to standalone RNC OMS. For more information on upgrades at RN4.0 hardware level, see Upgrading RNC450 to RNC2600, Replacing CDSP-C with CDSP-DH and Enabling HSDPA Capacity Enhancement in CDSP-DH and SFU and IP Upgrade. Full CDSP-DH upgrade is supported at RN4.0 and RN5.0 hardware level, see Replacing CDSP-C with CDSP-DH and Enabling HSDPA Capacity Enhancement in CDSP-DH and SFU and IP Upgrade. All upgrades supported in RN4.0 are also supported in RN5.0. The term “expansion” in this document means that extra hardware is added to RNC to provide new configuration step, for example from RNC2600 step 1 to RNC2600 step 3. Term “upgrade” means that existing hardware is some how changed to provide the use of new feature or capacity level, for example from RNC196 step 5 to RNC196 step 6/7, RNC196 step 7 to 8, IP upgrade, etc. Other related documentation The site requirements for the RNC are described in the document Installation Site Requirements for MGW and RNC. It provides the following information: • • • • •
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Technical specifications General hardware platform requirements Equipment room requirements Site power supply Grounding and bonding
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• • • •
About WCDMA RNC Engineering Description
Electromagnetic compatibility Operational environment Ventilation in the equipment rooms Specifications of interfaces to the environment
For information on changes in previous releases, which have been removed in this release, see Upgrades and expansions for RNC196 in RN3.0/RN2.2 and NEMU, Network Element Management Unit and its subunits in WCDMA RNC Engineering Description documents for previous releases and Product Description for RNC2600.
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RNC Hardware Changes
WCDMA RNC Engineering Description
2 RNC Hardware Changes This section summarises the differences in the hardware implementation between RN4.0 and RN5.0. New plug-in units Compared to RNC2600 on RN4.0 level, RNC2600 on RN5.0 level contains the following new plug-in units: •
TSS3-A clock plug-in unit Implemented to RN5.0 based RNC2600, with special instructions available for and can be used with RN4.0 software Due to 2N redundancy a mixed configuration of TSS3 and TSS3-A is not allowed
Functional units changes •
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As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended.
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IPA2800 System Architecture
3 IPA2800 System Architecture The IPA2800 network elements have a distributed processing architecture based on a modular software and hardware structure. The distribution of processes is achieved by using a multi-processor system, in which the functions of the network element are divided among several functional units. In the IPA2800 network element, each functional unit usually consists of one plug-in unit, which has a fixed capacity. The capacity reserved for a given function can be increased by simply installing additional units of the appropriate type to the configuration – another benefit from the modular structure. Each functional unit has a separate task group to handle. For example, the ATM Switch Matrix has been organised as a separate unit, Switch Fabric Unit (SFU), and it is controlled by another unit, called Resource and Switch Management Unit (RSMU). The key operation and maintenance functions are performed by the Operation and Maintenance Unit (OMU), the external SDH STM-1 and Ethernet interfaces are provided by the Network Interface Units (NPS1(P)) and (NPGE(P)), respectively, and so on. Each functional unit has its own, separate hardware and software; some of them are equipped with a dedicated Pentium®II, Pentium®III or Pentium®M 745-type computer. These units are referred to as computer units, some of which have storage devices as dedicated sub-units. The hardware of the functional units and the tasks each unit handles are described in more detail in chapter Functional unit descriptions. Further information is available in the Product Description. The figures below present the block diagrams of the Radio Network Controller, RNC2600 and RNC450, their functional units and the internal and external interfaces.
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IPA2800 System Architecture
WCDMA RNC Engineering Description
ICSU
MXU NPS1(P)
DMCU NPGE(P)
SFU ICSU Ethernet Ethernet
SWU
RSMU
MXU MXU
DMCU
OMU
Ethernet
WDU
OMS*
TBU EHU
HDD* * Optionally, the integrated OMS and the related HDDs can be removed as of RN5.0. SWITCHING AND MULTIPLEXING UNIT NETWORK INTERFACE UNIT MANAGEMENT, CONTROL COMPUTER AND DATA PROCESSING UNIT DN70618302
Figure 1
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Block diagram of the RNC2600
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IPA2800 System Architecture
ICSU A2SU GTPU MXU ICSU
DMCU NIP1
RRMU MXU
DMCU E1/T1/JT1 Iu Iur ATM Iub
GTPU
RSMU OMS */ NEMU
ETHERNET 100 BASE Tx
SFU
OMU
ICSU Hard disk
FDU
WDU
A2SU
A2SU MXU
DMCU Iu Iur Iub
STM-1 ATM
NIS1
DMCU
GTPU
TBU EHU SWITCHING AND MULTIPLEXING UNIT NETWORK INTERFACE UNIT MANAGEMENT, CONTROL COMPUTER AND DATA PROCESSING UNIT
* OMS replaces NEMU in RN3.0
DN01128754
Figure 2
3.1
Block diagram of the RNC450
Internal Messaging and Resource Allocation In terms of network element architecture, perhaps the most significant single feature of the ATM technology is that it allows for relatively easy designing of switching devices with high capacity and low delay. A primary bottleneck in the design of the 2nd generation systems, the switching capacity is no longer such a limiting factor in 3rd generation systems. This is reflected in the architecture of the RNC in the following ways: •
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Nearly all of the network element's internal traffic is routed through its switching fabric. In the IPA2800 network elements, the message bus between its units consists of standard ATM virtual channels routed through the switching fabric. However, the IPA2800 has timing and Hardware Management (alarm) buses separate from the ATM connections. The timing bus has been separated to ensure that the strict timing requirements of the ATM technology are met, while an individual Hardware Management bus ensures that some basic functions in the network
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IPA2800 System Architecture
•
3.2
WCDMA RNC Engineering Description
element can be carried out without any support from its control units when the network element is being taken into use, upgraded or serviced, or during normal operation. Virtually all DSPs (Digital Signal Processors) in the system can be used by any control computer. In the IPA2800 network elements, the DSPs are organised as pools whose services are available to the control computers through the ATM virtual message bus. This ensures optimal use of the system's DSP resources. As a consequence, the plug-in units containing DSPs have been separated from the control computers on the functional unit level and they form functional units of their own. This kind of architecture has been achieved by enabling the routing of the user data of a call multiple times through the switching fabric while it is being processed.
Computing System The computing system of the IPA2800 network elements consists of various microprocessor based computers and microcontrollers with either proprietary or standard operating systems, as well as standard message transfer protocols. It is organised according to a four-level hierarchy, as shown in the table below.
Level
Type
Processor
Operating system
PIUs
Communication to upper level/other units
Level 4
Management computer
Intel P M 745
Linux
MCP18-B
TCP/IP
Control computer
Intel Pentium M (CCP18-C / CCP18-A)
DMX with POSIX
CCP18-C/ CCP18-A/ CCP10
LAN/Ethernet, ATM virtual channels
Chorus
MX1G6/-A,
ATM virtual channels
Level 3
Intel PIII
Intel PIII (CCP10) Level 2
Unit computer
Motorola PowerQuicc II
SF10E, AL2S-D/-B, CDSP-C/-B/DH, NP2GE-B, NP8S1-B
Level 1
Table 1
Control processor
8-bit microcontroller
No OS needed
Embedded in all PIUs
Selected case by case
Computing platform hierarchy levels for IPA2800 RNC Management computer unit MCP18-B and control computer unit CCP18-C/CCP18A/CCP10 The MCP18-B and CCP18-C / CCP18-A / CCP10 plug-in units are used as the management computer units and control computer units, respectively, in the IPA2800 network elements. Both are single board computers with an onboard PCI bus. The
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IPA2800 System Architecture
MCP18-B and CCP18-C / CCP18-A are based on Pentium M 745 1800 MHz microprocessor. As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. For more information on the MCP18-B and CCP18-C / CCP18-A / CCP10 plug-in units, see the individual Plug-in Unit Descriptions online.
3.3
Redundancy Principles for IPA2800 Network Elements The reliability of the operations in the IPA2800 network elements has been ensured by backing up all crucial parts of the system following various redundancy principles, as described in the sections below. Functional unit-specific redundancy principles are named in chapter Functional unit descriptions. Redundancy of the functional units Different redundancy techniques are used for backing up different types of functional units. The Operation and Maintenance Unit, the main Switch Fabric, the radio resource and switch control units along with all crucial databases are backed up according to the 2N redundancy principle, that is, by duplication according to the hot-standby method. When a defect is detected in an active functional unit, a spare unit is set active by an automatic recovery function. The spare unit is designated for only one active unit, and the software in the unit pair is kept synchronised. Most units with 2N redundancy, except for most of the subrack-specific Timing Buffers and multiplexers, are located in the two first subracks of the network element. The two units of a mutually redundant pair are placed in different subracks. Switchover can be performed between units of a redundant unit pair independently of the other corresponding pairs, which means that no subrack-level switchover procedure is needed in the network element. The STM-1 network interface units can optionally use 2N redundancy. Until RN3.0, NIS1 unit is the default non-redundant unit. As of RN4.0, NPS1 and NPGE units are the default non-redundant units. These can be turned into redundant, 2N duplicate, units (NIS1P or NPS1P and NPGEP, respectively) providing additional equipment protection by adding another NIS1, NPS1 or NPGE unit to the network element or by changing the cabling of the existing two units. In NIS1, the SDH transmission protection is ensured by the MSP 1+1, bidirectional protection switching mode, where the traffic is carried via two multiplex sections. The signalling units, AAL2 switch, and the units handling user or control plane functions are backed up according to the N+1 or SN+ principle. N+1 principle means that there is one spare unit available ready to take over the tasks of a faulty unit. Load sharing, SN+, means that the workload is shared between all devices, and if one malfunctions, the other units are able to carry the full load. Ensuring reliability at unit level In the Intel processors, the following methods are used to ensure proper operation: • • • •
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Error correcting RAM in critical parts ECC in read-write memories Parity checks in data transmission on the PCI bus Reporting on certain error events in data transactions on the system bus
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IPA2800 System Architecture
• • • •
WCDMA RNC Engineering Description
Memory area protection (standard Intel processor capability) Time-out supervision Continuous supervision of the functioning of processes including restarts, when required Continuous testing of operations (as a background run) in all computer units
Units without nominal redundancy Some of the functional units of the network element do not have redundancy at all. These are units which interface the network element to the environment. As of RN4.0, the non-redundant units are NPGE, NPS1 and integrated OMS. As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. Integrated or standalone OMS is left without backup because a failure in it does not prevent the switching or cause any drop in the capacity available; the network element only loses both its local and upper-level operation and maintenance interface. The network interfaces are more crucial to the whole system. The PDH network interface units are organised as pools of resources, with several units available at a time to handle an assignment. It is recommended that connections to any given direction will be divided between two or more units located in different subracks. This ensures that a failure in, for example, one of the power supply plug-in units will not interrupt the traffic to one direction altogether. If there is surplus capacity available for the network interfaces, it is recommended that it be used for backing up the crucial connections and sharing the load between all the network interfaces available for connections towards that direction. Redundancy of the power distribution, timing distribution, and Hardware Management Subsystems Virtually the entire power distribution chain from the rectifiers and power feed cables to individual pieces of equipment in the cabinets has been duplicated to minimise the risk of downtime due to power failures in the IPA2800 equipment or cabling. The redundancy for the power supply from the rectifiers to the cabinets has been achieved by duplicating the power inputs in each cabinet, along with the input cables. The two units are placed in different subracks. On the other hand, each cabinet is equipped with a duplicated power distribution system, which allows feeding the voltages to units that are backing each other up through two separate distribution lines. Likewise, the IPA2800 network elements have a duplicated alarm collection (or Hardware Management) and clock distribution system organised by means of redundant system clock or timing buffer unit in each subrack and separate, redundant cables for the alarm collection and clock distribution buses. The synchronisation reference can be fed to each IPA2800 network element from up to five inputs, three from line interfaces and two from external sources.
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RNC FU
Redundancy principle
RSMU
2N
Plug-In unit variant choices for RNC196 or RNC450
Plug-In unit variant choices for RNC2600
2 * CCP10
2 * CCP18-A
or
or
2 * CCP18-A
2 * CCP18-C
or 2 * CCP18-C MXU
2N
2 * MX622-B
2 * MX1G6-A
or 2 * MX662-C or 2 * MX622-D as same subrack WO-SP pair OMU
2N
2 * CCP10
2* CCP18-A
or 2 * CCP18-A SFU
2N
2 * SF10
2 * SF20H
or 2 * SF10E TBU
2N
2 * TSS3 or 2 * TSS3-A
2 * TSS3 or 2 * TSS3-A
in subracks 1-2 and in subracks 1-2 and 2 * TBUF in other subracks
2 * TBUFin other subracks
WDU / OMU
2N
Mixed use of WDW18, WDW18S, WDW36 , WDW73 or WDW147
WDW147
ICSU
N+1
Mixed use of CCP10, CCP18-A, and CCP18-C
CCP18-A
Mixed use of
N/A
A2SU
SN+
or CCP18-C
AL2S-B and AL2SD DMCU
SN+
Mixed use of CDSP-C and CDSP-DH
CDSP-DH
GTPU
SN+
Mixed use of CCP10, CCP18-A, and CCP18-C
N/A
Table 2
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Redundancy principles of the functional units in the RNC
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IPA2800 System Architecture
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RNC FU
Redundancy principle
Plug-In unit variant choices for RNC196 or RNC450
Plug-In unit variant choices for RNC2600
NIP1
No redundancy (Transport redundancy organised by call routing).
NI16P1A
N/A
NIS1
No redundancy (Transport redundancy organised by call routing and/or MSP1+1).
NI4S1-B
N/A
NIS1P
2N (Transport redundancy organised by MSP1+1 and call routing).
2 * NI4S1-B
N/A
NPGE
No redundancy
NP2GE-B
NP2GE-B
NPGEP
2N
2 * NP2GE-B
2 * NP2GE-B
NPS1
No redundancy (Transport redundancy organised by routing).
NP8S1-B
NP8S1-B
NPS1P
2N (Transport redundancy organised by routing and MSP and/or MSP1+1).
2 * NP8S1-B
2 * NP8S1-B
EHU
No redundancy
EHAT
EHAT
No redundancy
MCP18-B
MCP18-B
OMS
1)
SWU
Optional 2N (for 1 * ESA12 LAN connectivity) 2) or
1-2 * ESA24
1-2 * ESA24
Table 2 1)
2)
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Redundancy principles of the functional units in the RNC (Cont.)
As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. Equipment database does not recognise ESA24 as a functional unit and HMS does not supervise it.
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Mechanical Construction of the IPA2800 Network Elements
4 Mechanical Construction of the IPA2800 Network Elements The mechanical construction of the IPA2800 network elements is based on M2000 mechanics platform, which follows a standard hierarchy: • • • • •
Cabinets Cooling and power supply equipment Subracks Plug-in units Internal cables
The system is based on IEC/ETSI standards for metric dimensioning, along with EN, UL, and Telcordia recommendations for advanced features in terms of safety, protection against interference, stability, and durability. Particular attention has been paid to thermal resistance.
4.1
Cabinets The equipment of the IPA2800 network elements is housed in EC216 or IC186/-B equipment cabinets. Each cabinet has space for four subracks, the cabinet-specific power distribution panels plus the subrack-specific cooling equipment, all of which are installed at the factory, along with the plug-in units and intracabinet cables. The RNC features two different equipment cabinets: • •
RNC Cabinet A (RNAC) RNC Cabinet B (RNBC)
The cabinets are dimensioned according to ETS 300119-2 and IEC 60917-2 standards. The emphasis of its design is on easy transportability and suitability for installations in premises with a normal or even lower room height. Due to the simple mechanical structure with relatively few components, the cabinet is easy to assemble and disassemble when necessary. The employment of thin sheet steel technology in its manufacture, along with the use of aluminium or sheet metal profile as the material for the doors makes the cabinet frame light in weight. When fully equipped, the weight of a single cabinet is circa: • •
EC216: 260 kg IC186/-B: 230 kg
The cabinets meet the IEC 60950 and UL 60950 safety requirements, along with the EN 300019-1-3, Class 3.1E environmental requirements. Based on a riveted (EC216) or welded (IC186/-B) frame structure, the earthquake resistance of the cabinet is in accordance with Telcordia GR-63-CORE Zone 4, and the EMC emission and immunity characteristics comply with the EN 300386 and CFR 47, FCC Part 15 standards, respectively. NEBS compliance NEBS stands for Network Equipment Building System. It is a set of Telcordia (former Bellcore) Standards, whose purpose is to unify HW requirements and help Telephone companies to evaluate the suitability of products for use in their networks. Compliance
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Mechanical Construction of the IPA2800 Network Elements
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to NEBS is usually inquired by RBOC:s (Regional Bell Operator Company) in the USA. The IPA2800 Network Element Hardware is NEBS Level 3 compliant, covering GR-63CORE and GR-1089-CORE in Central Office or equivalent premises, as applicable for type 2 ports, as specified in GR-1089-CORE.
4.1.1
EC216
Figure 3
EC216 cabinet
The EC216 cabinet consists of the following parts (see figure above): •
• •
22
Riveted self-supporting cabinet frame made of sheet metal with incorporated mounting flanges for subrack installation and equipment place for CPD120-A cabinet power supply units Doors manufactured of sheet metal profile (2 pcs) Two CPD120-A power distribution units at the top of the cabinet, complete with connectors for redundant incoming and outgoing supply lines plus circuit breakers for the latter
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Mechanical Construction of the IPA2800 Network Elements
• • • • •
Side cover plates at the ends of the cabinet rows Vertical grounding bars Adjustable feet for permanent installation FTRA-B Fan units CAIND-A Network Element Alarm indicator (only in the first cabinet).
•
CS216-A cable shelves CS216-A cable shelves are equipped under the two topmost subracks in the backside of the RNAC cabinet. CPAL-A, CPSY-A and CPSY-B panels are equipped below the CS216-A.
The cabinet doors can be easily removed, for example, for the duration of the installation. They have levers with an active locking mechanism, plus separate locks for securing the levers to their places.
4.1.2
IC186/-B Air Guide CPD80-B Cabinet Power distribution Side Cover Plates
Cable Support
Doors Plug-in units
Fan tray + Cover plate Subrack
Adjustment foot
DN02179668
Figure 4
IC186-B cabinet
The IC186/-B cabinet consists of the following parts (see figure above):
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Mechanical Construction of the IPA2800 Network Elements
• • •
• • • • •
WCDMA RNC Engineering Description
Welded, self-supporting cabinet frame made of sheet metal, with incorporated mounting flanges for subrack installation Doors manufactured of aluminium profile (4 pcs) Two CPD80-B power distribution units at the top of the cabinet, complete with connectors for redundant incoming and outgoing supply lines plus circuit breakers for the latter Side cover plates at the ends of the cabinet rows Grounding flanges between adjacent cabinets (4 pcs) Vertical grounding bars (2 pcs) Horizontal grounding bars (5 pcs) Adjustable feet for permanent installation (4 pcs)
The cabinet doors can be easily removed, for example, for the duration of the installation. They have levers with an active locking mechanism, plus separate locks for securing the levers to their places.
4.1.3
Dimensions of Cabinets in Floor Rail on Free-standing Installations The cabinets can be installed either on floor rails or free-standing. The final installation height of the cabinets varies somewhat, depending on whether they are installed on rails or free-standing. The equipment room must have a height of at least 2300 mm (86.8 in) with EC216 and 1900 mm (74.8 in) with IC186/-B, so that the cabinets can be lifted to upward position from the horizontal position they are transported in. The minimum distance between an RNC cabinet and another cabinet row is 700 mm (27.6 in). If installed to the end of an existing row, the minimum distance between the end of a cabinet row and the wall is 1000 mm (39.4 in) for working area. The dimensions of the EC216 cabinet, and the needed space for conducting cables from the top or bottom of the cabinet are shown in the figure below.
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Figure 5
Mechanical Construction of the IPA2800 Network Elements
Dimensions of the EC216
The dimensions of the IC186/-B cabinet and the needed space for conducting cables from the top or bottom of the cabinet are shown in the figure below.
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600
50
IC186 Primary area for routing cables
50 500
180
Secondary area for routing cables
100
Secondary area for routing cables
50 70
50
DN02133818
Figure 6
FRONT
Dimensions of the IC186-B
For more information on requirements of the equipment room and layout, see sections Operational environment and Equipment room layout in Installation Site Requirements for MGW and RNC. Dimensions of cabinets in free-standing installation When installed free-standing, the cabinets stand on adjustable feet. The dimensions of the cabinet frame adjustment range provided by the feet are shown in the below figure.
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Figure 7
Mechanical Construction of the IPA2800 Network Elements
Dimensions of EC216 / IC186-B
Dimensions of cabinets in installation on floor rails The height of the cabinet rows, when installed on floor rails, is the following: • •
EC216: 2060 mm (81.1 in) plus the height of the rail and accessories IC186/-B: 1760 mm (69.3 in) plus the height of the rail and accessories
For example, if 75-mm (3 in) high rails are used, the total height of the EC216 cabinets is 2135 mm (84.1 in).
4.2
Subracks The RNC uses the following subrack types: EC216: • •
SRA3: all subracks SRBI-C: all subracks
IC186-B: • • •
SRA1-B / SRA1-A: subracks 1-2 in RNAC SRA2-B / SRA2-A: subracks 3-4 in RNAC and 1-4 in RNBC SRBI-B: subracks 3-4 in RNAC and 1-4 in RNBC
RNAC subracks 1 and 2 house nearly all 2N redundant equipment in the network element. Units which make up a mutually redundant pair are placed in separate subracks, except for upgrades from previously delivered RNCs to RNC196 step 6 and
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RNC196 step 7. Each of the two subracks has an individual configuration, with N+1redundant units or those with no redundancy equipped in some of the slots. RNAC subracks 3 and 4 and all RNBC subracks feature N+1 redundant units or those with no backup at all, with 2N redundant pairs of MXU units in each subrack as the only exceptions. A 2N redundant MXU is located in the same subrack as all tributary units connected to them are in the same subrack. The differences between the different subrack types are: •
•
In comparison to SRA1, SRA2 and SRA3 integrate more of the internal cabling of the subrack, such as signals from the MXUs to tributary units, into its back interface unit. SRBI-C is equipped behind the SRA3 and SRBI-B is equipped behind the SRA2 subrack to provide modular backplane connections using BIE1T or BIE1C connector panels.
The subracks are designed according to the ETS 300119-4 standard, with particular attention paid to durability even under demanding conditions, along with compact dimensioning for optimal use of cabinet space. Their simple attachment mechanism makes it easy to demount the subrack and replace it with a new one in case it gets broken. The IPA2800 network elements provide full EMC protection on the cabinet level. All subracks are installed in the cabinets at the factory. The dimensions of the subracks are (H x W x D): •
300 x 500 x 300 mm (11.8 x 19.7 x 11.8 in).
DN99572546
Figure 8
4.3
SRA1 subrack
Plug-in Units The printed circuit boards of the plug-in units are multi-layered and covered with a protective coating. They enable the use of both soldered and pressfit through-hole components, along with surface-mounted ones. The plug-in units are generally connected to
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WCDMA RNC Engineering Description
Mechanical Construction of the IPA2800 Network Elements
the other parts of the system by means of backplane connectors of Hard Metric type, which are designed in accordance with the IEC 1076-4-101 standard. Some of the connections, however, are made from the front panels, normally by means of standard RJ45 connectors. The plug-in units of the IPA2800 network elements are designed to support hot-swapping. They are equipped with various LED indicators for monitoring the unit's condition; one indicator found in each unit, for example, shows that the unit is separated from the system and can be extracted from the subrack. The printed boards of the plug-in units come in two sizes (H x D): • •
115 x 285 mm (4.5 x 11.2 in; TBUF and TSS3/-A units) 265 x 285 mm (10.4 x 11.2 in; all other plug-in units)
The front panels of the units are made of aluminium. They are equipped with insertion/extraction levers, which help to manage the friction encountered at their installation, caused by the high number of connector pins typically needed for the backplane connections. The levers are a highly appropriate feature, since the force to be overcome for a single plug-in unit may be as high as 400 N, equal to the weight of 41 kilograms. Like their printed boards, the front panels of the plug-in units come in two sizes (H x W): • •
4.4
145 x 25 mm (5.71 x 0.98 in; TBUF and TSS3/-A units) 295 x (n x 25) mm (11.61 x (n x 0.98) in; all other plug-in units)
Cabling The cabling of the network element consists of interconnection cables (intermediate cables) and station cables (outgoing cables) as described below. All connections to the Switch Fabric, multiplexing units, and the wideband network interfaces are made by means of high-frequency (HF) cables. Elsewhere in the system, the type of the cables used has been determined on the basis of the requirements of the associated hardware, following standard practices in the industry. Interconnection cables The interconnection cables comprise all cables running inside and between the cabinets which form a single network element. The interconnection cables are cut to length and equipped with connectors. They comprise the following cables: • • • • • •
Power supply cables ATM connection cables Hardware Management Bus cables Synchronisation and timing cables SCSI cables between storage devices and their master units LAN/Ethernet cables
Site cables The site (outgoing) cables are all the cables which leave the network element. They include: • • • •
DN0938143 Issue 1-4
Trunk circuit cables from the network interfaces Power supply cables Grounding cables I/O cables
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Mechanical Construction of the IPA2800 Network Elements
•
WCDMA RNC Engineering Description
TCP/IP cables
The site cables connect directly to the plug-in units, to back interface units located at the rear side of the IC186/-B cabinets or to units in the cabling cabinet.
4.4.1
General Cabling Principles The general cabling principles for the IPA2800 network elements are as follows: • •
•
•
The interconnection cables between plug-in units in the same subrack (intrasubrack cables) are delivered completely installed in the cabinets. The interconnection cables between different subracks in the same cabinet or between the equipment cabinet and the cabling cabinet (intracabinet cables) run directly from subrack to subrack/cabling cabinet. These cables are delivered completely installed in the cabinets, as individual cable sets for each cabinet type. However, if the cabling cabinet is delivered separately, also the intracabinet cables for it are delivered in separate boxes. The interconnection cables running between different cabinets (intercabinet cables) are led directly from one cabinet to another through the cable path. These cables are delivered with one end of each cable installed in an appropriate cabinet. The interconnection cables are delivered as prefabricated cable sets. The site cables can be routed to the environment through the opening at the bottom (raised floor installations) or top plate (normal installation) of the cabinet. These cables must be installed at the site.
All the cables entering the cabinet(s), except for the DC power feed cables, must have protective wires which are grounded to the frame of the network element at the connectors in the cabling cabinets.
4.5
Cooling Equipment Each subrack in the network element is provided with a dedicated fan tray cooling unit, since forced cooling is needed in the cabinets due to the high thermal density. There are two fan tray variants: • •
FTRA-B in EC216, controlled by PD30 FTRA in IC186/-B, controlled by PD20
The fan trays have eight separate fans with an aggregate capacity sufficient to ensure N+1 redundancy (if one of the fans fails, this will not cause any rise in the temperature) and air deflectors, which help to spread the cool air evenly through the subrack. The FTRA-B fan trays are controlled by the PD30 power supply plug-in units and the FTRA fan trays are controlled by the PD20 plug-in units on the basis of messages sent by OMU. OMU, in turn, is supported by the Hardware Management System, which collects alarms from FTRA/-Bs and controls the temperature inside each plug-in unit. In case high temperatures are detected, OMU will automatically instruct the PD30/PD20s (via the HMS bus) to increase the rotation speed of the fans so that the temperature can be restored to an appropriate level. Like the subracks, FTRA/-B fan trays are fixed to the cabinets by attaching them to the mounting flanges. In case of a severe fault, a fan tray can be hot-swapped without any need for plug-in unit switch-over procedures. For more information, see Replacing plugin units and other hardware units.
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Cabinet and Subrack Descriptions for RNC2600
5 Cabinet and Subrack Descriptions for RNC2600 5.1
RNC2600 Cabinet Types The RNC2600 features two different equipment cabinets, RNAC and RNBC, of the type EC216. The subracks of the cabinets are assigned with numbers starting from 1 at the top of cabinet and ending to 4 at its bottom. The RNAC and RNBC cabinets can be configured from left to right or from right to left. The positions of the cabinets in the two different layout options are shown in the figure below.
Left-to-right configuration 1200mm
600mm
RNAC
RNBC
Right-to-left configuration
RNBC
RNAC
Front side of the cabinets DN0624966
Figure 9
Layout options for the RNC2600
RNC2600 has three configuration steps: •
•
•
RNC2600/Step 1 Configuration step 1 of RNC2600 implements the minimum capacity and it consists of cabinet mechanics for RNAC and a fully equipped RNAC cabinet. RNC2600/Step 2 Configuration step 2 of RNC2600 consists of a fully equipped RNAC cabinet and cabinet mechanics for RNBC cabinet; all four subracks for RNBC cabinet, all needed plug-in unit types for subracks 1 and 2 of RNBC cabinet, and cover plates for subracks 3 and 4 of RNBC cabinet. Configuration step 2 of RNC2600 includes no plug-in units for subracks 3 and 4 in RNBC, not even PD30s or TBUFs. Cover plates fill the front sides of subracks 3 and 4 entirely. RNC2600/Step 3 Configuration step 3 of RNC2600 consists of all needed plug-in unit types equipped at RNAC and RNBC cabinets.
In addition to the RNC2600 configuration steps:
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Cabinet and Subrack Descriptions for RNC2600
• •
WCDMA RNC Engineering Description
The NISx units with STM-1 interfaces are replaced with NPGE(P) units with IP interface units or NPS1(P) units with SDH STM-1 interfaces. Optional second ESA24 can be ordered separately.
The following figures present the hardware configuration options and configuration steps for the RNC cabinets. RNAC
* Optionally, the
SFU 0
integrated OMS and the two related HDDs can be removed as of RN5.0
ICSU 0 RSMU 0 SWU 0 OMS * DMCU 0 DMCU 1 MXU 0 PD30 MXU 1 DMCU 2 DMCU 3 WDU 0 (OMU) HDD 0 (OMS) * OMU 0 NPGEP 0 / NPS1P 0 NPGEP 2 TBUF TSS3/-A
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
1
38 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
ICSU 1 RSMU 1 SWU 1 ICSU 2 DMCU 4 DMCU 5 MXU 2 PD30 MXU 3 DMCU 6 DMCU 7 WDU 1 (OMU) HDD 1 (OMS) * OMU 1 NPGEP 1 / NPS1P 1 NPGEP 3 TBUF TSS3/-A
SFU 1
2
RNC2600/ Step 1
38 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
ICSU 3 ICSU 4 ICSU 5 ICSU 6 EHU DMCU 8 DMCU 9 DMCU 10 MXU 4 PD30 MXU 5 DMCU 11 DMCU 12 ICSU 7 NPGEP 4 / NPS1P 2 NPGEP 6 / NPS1P 4 TBUF TBUF
3
38 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
ICSU 8 ICSU 9 ICSU 10 ICSU 11 ICSU 12 DMCU 13 DMCU 14 DMCU 15 MXU 6 PD30 MXU 7 DMCU 16 DMCU 17 ICSU 13 NPGEP 5 / NPS1P 3 NPGEP 7 / NPS1P 5 TBUF TBUF
4
38
38 DN0938743
Figure 10
32
RNAC cabinet in RNC2600
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DN0938143 Issue 1-4
ICSU 32 ICSU 33 ICSU 34 ICSU 35 ICSU 36 DMCU 33 DMCU 34 DMCU 35 MXU 6 PD30 MXU 7 DMCU 16 DMCU 17 ICSU 13 NPGEP 13 / NPS1P 11 NPGEP 15 / NPS1P 13 TBUF TBUF
ICSU 26 ICSU 27 ICSU 28 ICSU 29 ICSU 30 DMCU 28 DMCU 29 DMCU 30 MXU 12 PD30 MXU 13 DMCU 31 DMCU 32 ICSU 31 NPGEP 12 / NPS1P 10 NPGEP 14 / NPS1P 12 TBUF TBUF
ICSU 20 ICSU 21 ICSU 22 ICSU 23 ICSU 24 DMCU 23 DMCU 24 DMCU 25 MXU 10 PD30 MXU 11 DMCU 26 DMCU 27 ICSU 25 NPGEP 9 / NPS1P 7 NPGEP 11 / NPS1P 9 TBUF TBUF
ICSU 14 ICSU 15 ICSU 16 ICSU 17 ICSU 18 DMCU 18 DMCU 19 DMCU 20 MXU 8 PD30 MXU 9 DMCU 21 DMCU 22 ICSU 19 NPGEP 8 / NPS1P 6 NPGEP 10 / NPS1P 8 TBUF TBUF
WCDMA RNC Engineering Description
Figure 11
5.2
DN0938143 Issue 1-4
Cabinet and Subrack Descriptions for RNC2600
RNBC
1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
RNC2600/ Step 2 38
2 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
RNC2600/ Step 3 38
4 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
DN0938755
RNBC cabinet in RNC2600
Equipment in the Subracks
The configurations of the subracks are shown in the tables below.
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Cabinet and Subrack Descriptions for RNC2600
Unit type
RNAC configuration step 1
WCDMA RNC Engineering Description
RNBC configuration step 2
RNBC configuration step 3
Min.
Max. conf.
conf.
SR 1
SR 2
SR 3
SR 4
SR 1
SR 2
SR 3
SR 4
RNAC
RNAC - RNBC
DMCU / CDSP-DH
4
4
5
5
5
5
5
5
18
38
EHU / EHAT
—
—
1
—
—
—
—
—
1
1
ICSU / CCP18-C
1
2
5
6
6
6
6
6
14
38
MXU / MX1G6-A
2
2
2
2
2
2
2
2
8
16
NPS1P / NP8S1-B
0-1
0-1
0-2
0-2
0-2
0-2
0-2
0-2
0-6
0-14
NPS1 / NP8S1-B
0-1
0-1
0-2
0-2
0-2
0-2
0-2
0-2
0-6
0-14
NPGEP / NP2GE-B
0-2
0-2
0-2
0-2
0-2
0-2
0-2
0-2
0-8
0-16
NPGE / NP2GE-B
0-2
0-2
0-2
0-2
0-2
0-2
0-2
0-2
0-8
0-16
OMU / CCP18-A
1
1
—
—
—
—
—
—
2
2
- / PD30
1
1
1
1
1
1
1
1
4
8
RSMU / CCP18-C
1
1
—
—
—
—
—
—
2
2
SFU / SF20H
1
1
—
—
—
—
—
—
2
2
TBU / TSS3/-A
1
1
—
—
—
—
—
—
2
2
TBU / TBUF
1
1
2
2
2
2
2
2
6
14
HDS-B
1
1
—
—
—
—
—
—
2
2
WDU / WDW147 (OMU)
1
1
—
—
—
—
—
—
2
2
HDD / WDW147 (OMS) 1)
1
1
—
—
—
—
—
—
2
2
SWU / ESA24
1
0-1
—
—
—
—
—
—
1-2
1-2
OMS / MCP18-B a)
1
—
—
—
—
—
—
—
1
1
Table 3
Number of units in RNC2600 subracks a) As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended.
Unit type
Configuration steps
DMCU / CDSP-DH
RNC2600/Step 1
RNC2600/Step 2
RNC2600/Step 3
18
28
38
EHU / EHAT
1 for all configurations
ICSU / CCP18-C
14
26
38
MXU / MX1G6-A
8
12
16
0-6
0-10
0-14
NPS1P / NP8S1-B a)/b)
Table 4
34
Maximum number of units in the RNC2600 for each configuration step
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Cabinet and Subrack Descriptions for RNC2600
Unit type
Configuration steps RNC2600/Step 1
RNC2600/Step 2
RNC2600/Step 3
NPS1 / NP8S1-B a)/b)
0-6
0-10
0-14
NPGEP / NP2GE-B a)/b)
0-8
0-12
0-16
NPGE / NP2GE-B a)/b)
0-8
0-12
0-16
OMU / CCP18-A
2 for all configurations
- / PD30
4
6
RSMU / CCP18-C
2 for all configurations
SFU / SF20H
2 for all configurations
TBU / TSS3/-A
2 for all configurations
TBU / TBUF
6
10
HDS-B
2 for all configurations
WDU / WDW147 (OMU)
2 for all configurations
HDD / WDW147 (OMS) c)
2 for all configurations
SWU / ESA24 a) OMS / MCP18-B c)
Table 4
8
14
1-2 for all configurations 1 for all configurations
Maximum number of units in the RNC2600 for each configuration step
a) Units are optional. b) NPS1 and NPS1P units and NPGE and NPGEP units are mutually exclusive. c) As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. For information on the capacities of the alternative configurations, see RNC2600 capacity in Product Description for RNC2600. Back interface units at the rear of the cabinets in RNC2600 In RNC2600, the cabling cabinet is not used. Connections are made either from the back interface units located at the rear side of the cabinets or from the front panels of the plugin units. For more information, see section Interfaces to the environment. The back interface units located at the rear side of the cabinet are described below: •
•
•
DN0938143 Issue 1-4
BISFA Back interface unit SFP type A for SF20H with 24 SFP connectors for cabling to NPGE(P), NPS1(P) and MXU units. BISFA also contains an RJ-45 connector for cabling between redundant SFUs. BISFB Back interface unit SFP type B for MX1G6-A with 4 SFP connectors for cabling to SFU. BISFB-A Back interface unit SFP type B for MBMS upgrades to RNC196, IC186/IC186-B mechanics.
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Cabinet and Subrack Descriptions for RNC2600
•
•
5.3 5.3.1
WCDMA RNC Engineering Description
BISFC Back interface unit SFP type C for NP2GE-B and NP8S1-B plug-in units. The back interface unit contains 4 SFP connectors for cabling to SFU and an RJ-45 connector for ETH service terminal for debugging the NP2GE-B or NP8S1-B. BISFD Back interface unit SFP type D for SF20H with 8 SFP connectors for NPGE(P), NPS1(P) and MXU units.
RNC2600 Upgrades and Expansions in RN5.0 Optional Expansions for RNC2600 The optional hardware expansion changes the RNC2600 configuration step 1 to step 2/3, and step 2 to step 3. For instructions on how to add RNBC expansion cabinet and configuration steps RNC2600/Step 2 and RNC2600/Step 3 to RNC configuration, see Hardware Expansion for RNC2600. In addition to these three configuration steps, the following optional expansions are available for RNC2600: •
•
•
NPS1(P) expansion: There are no NPS1(P) units included in the basic configuration of RNC2600 by default. NPGE(P) expansion: There are no NPGE(P) units included in the basic configuration of RNC2600 by default. SWU expansion: One optional SWU can be ordered separately.
For instructions, see also Hardware Expansion for RNC2600.
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Cabinet and Subrack Descriptions for RNC450
6 Cabinet and Subrack Descriptions for RNC450 6.1
RNC450 Cabinet Types The RNC450 features two different equipment cabinets, RNAC and RNBC, of the type EC216. The subracks of the cabinets are assigned with numbers starting from 1 at the top of cabinet and ending to 4 at its bottom. The RNAC and RNBC cabinets can be configured from left to right or from right to left. The positions of the cabinets in the two different layout options are shown in the figure below.
Left-to-right configuration 1200mm
600mm
RNAC
RNBC
Right-to-left configuration
RNBC
RNAC
Front side of the cabinets DN0624966
Figure 12
Layout options for the RNC450
RNC450 has three configuration steps: •
•
•
RNC450 step 1 Configuration step 1 of RNC450 implements the minimum capacity and it consists of cabinet mechanics for RNAC and a fully equipped RNAC cabinet. RNC450 step 2 Configuration step 2 of RNC450 consists of a fully equipped RNAC cabinet and cabinet mechanics for RNBC cabinet; all four subracks for RNBC cabinet, all needed plug-in unit types for subracks 1 and 2 of RNBC cabinet and cover plates for subracks 3 and 4 of RNBC cabinet. Configuration step 2 of RNC450 includes no plug-in units for subracks 3 and 4 in RNBC, not even PD30s or TBUFs. Cover plates fill the front sides of subracks 3 and 4 entirely. RNC450 step 3 Configuration step 3 of RNC450 consists of all needed plug-in unit types equipped at RNAC and RNBC cabinets.
In addition to the RNC450 configuration steps:
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Cabinet and Subrack Descriptions for RNC450
•
• •
WCDMA RNC Engineering Description
Two NISx units with STM-1 interfaces are included in the basic configuration of RNC450 configuration step 1. Additional NISx units can be ordered separately. NIS1P 10-11 can be configured in RNAC or RNBC. One optional NIP1 unit with E1, T1, JT1 interfaces can be ordered separately. Optional second ESA24 can be ordered separately.
The following figures present the hardware configuration options and configuration steps for the RNC cabinets.
TSS3 EHU OMU 1 ICSU 2 ICSU 3 TSS3
B: HDD 1 OMS
TBUF
OMU 0 ICSU 0 ICSU 1 TBUF
B: HDD 0 OMS
SFU 0
DMCU 0 DMCU 1 ESA24 0 (SWU 0) OMS ICSU 22 RSMU 0 MXU 0 PD30 MXU 1 A2SU 0 A2SU 1 A: WDU 0 OMU
SFU 1
DCMU 4 DMCU 5 ICSU 4 ICSU 5 ICSU 6 DMCU 6 DMCU 7 DMCU 8 MXU 4 PD30 MXU 5 A2SU 3 DMCU 9 DMCU 10 NIS1P 10/NIP 1 0/NPGE(P) 0 GTPU 1 / ICSU25 NIS1P 0/NPGE(P) 6 NIS1P 2 TBUF TBUF DMCU 11 DMCU 12 ICSU 7 ICSU 8 ICSU 9 DMCU 13 DMCU 14 DMCU 15 MXU 6 PD30 MXU 7 A2SU 4 DMCU 16 DMCU 17 NIS1P 11/NPGE(P) 1 GTPU 2 / ICSU26 NIS1P 1/NPGE(P) 7 NIS1P 3 TBUF TBUF
Configuration step 1
DMCU 2 DMCU 3 ESA24 1 (SWU 1) GTPU 0 / ICSU24 ICSU 23 RSMU 1 MXU 2 PD30 MXU 3 A2SU 2 A: WDU 1 OMU
RNAC
DN70621159
Figure 13
38
FRONT VIEW
RNAC cabinet in RNC450
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DN0938143 Issue 1-4
-/ NPGE(P) 5 DMCU 37 ICSU 19 ICSU 20 ICSU 21 DMCU 38 DMCU 39 DMCU 40 MXU 14 PD30 MXU 15 A2SU 8 DMCU 41 DMCU 42 DMCU 43 GTPU 7 / ICSU31 NIS1P 10 NIS1P 11 TBUF TBUF -/ NPGE(P) 4 DMCU 30 ICSU 16 ICSU 17 ICSU 18 DMCU 31 DMCU 32 DMCU 33 MXU 12 PD30 MXU 13 A2SU 7 DMCU 34 DMCU 35 DMCU 36 GTPU 6 / ICSU30 NIS1P 6 NIS1P 10 TBUF TBUF -/ NPGE(P) 3 DMCU 25 ICSU 13 ICSU 14 ICSU 15 DMCU 26 DMCU 27 MXU 10 PD30 MXU 11 A2SU 6 DMCU 28 DMCU 29 GTPU 4 / ICSU28 GTPU 5 / ICSU29 NIS1P 5 NIS1P 7 TBUF TBUF
-/ NPGE(P) 2 DMCU 18 ICSU 10 ICSU 11 ICSU 12 DMCU 19 DMCU 20 DMCU 21 MXU 8 PD30 MXU 9 A2SU 5 DMCU 22 DMCU 23 DMCU 24 GTPU 3 / ICSU27 NIS1P 4 NIS1P 6 TBUF TBUF
WCDMA RNC Engineering Description
Figure 14
6.2
Unit type
Table 5
DN0938143 Issue 1-4
Cabinet and Subrack Descriptions for RNC450
RNBC
Configuration step 2
Configuration step 3
DN70621174
FRONT VIEW
RNBC cabinet in RNC450
Equipment in the subracks
The configurations of the subracks are shown in the tables below.
RNAC
RNBC
Min
Max
SR 1
SR 2
SR 3
SR 4
SRs 1–4
conf.
conf.
A2SU
2
1
1
1
1
5
9
DMCU
2
2
7
7
5–7 a)
18
44
Numbers of units in RNC450 subracks
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Cabinet and Subrack Descriptions for RNC450
Unit type
WCDMA RNC Engineering Description
RNAC
RNBC
Min
Max
SR 1
SR 2
SR 3
SR 4
SRs 1–4
conf.
conf.
EHU
—
1
—
—
—
1
1
GTPU
—
1
1
1
1
3
7
ICSU e)
3
3–4
3–4
3–4
3–5 f)
12
32
MXU
2
2
2
2
2
8
16
OMS d)
1
—
—
—
—
1
1
ESA24
1
0–1
—
—
—
1
2
OMS HDD d)
1
1
—
—
—
2
2
NIP1
—
—
0–1
—
—
0
1
NIS1
—
—
1–2
1–2
0–2 b)
2
6
NIS1P
—
—
1–3 c)
1–3 c)
0–2
2
12
NPGE(P)
—
—
1–2
1–2
0–1
2
8
OMU
1
1
—
—
—
2
2
OMU WDU
1
1
—
—
—
2
2
PD30
1
1
1
1
1
4
8
RRMU e)
1
1
—
—
—
2
2
RSMU
1
1
—
—
—
2
2
SFU
1
1
—
—
—
2
2
TBUF
1
1
2
2
2
6
14
TSS3
1
1
—
—
—
2
2
a) In RNBC Sr2, there are 5 DMCU units. b) 0–2 unprotected NIS1 units in RNBC Sr1 or Sr3. Maximum number of unprotected NIS1 units is 6. c) NIS1P 10-11 can be configured in RNAC or RNBC. d) Integrated OMS replaces NEMU as of RN3.0 new deliveries. As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. e) ICSU replaces RRMU in both subracks after RN4.0 software release upgrade. f) In RNBC Sr2, there are 3–5 ICSU units. In other RNBC subracks, there are 3–4 ICSU units.
Table 5
Numbers of units in RNC450 subracks (Cont.)
Unit type
Configuration steps RNC450 step 1 RNC450 step 2 RNC450 step 3
A2SU
5
7
9
DMCU
18
30
44
EHU
1 for all configurations
ESA24
2 for all configurations
Table 6
40
Maximum number of units in the RNC450 for each configuration step
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WCDMA RNC Engineering Description
Cabinet and Subrack Descriptions for RNC450
Unit type
Configuration steps RNC450 step 1 RNC450 step 2 RNC450 step 3
GTPU
3
6
8
ICSU b)
10
16
22
MXU
8
12
16
OMS a)
1 for all configurations
OMS Hard disk HDD a)
2 for all configurations
NIP1
1 for all configurations
NIS1
4
6
6
NIS1P
6
10
12
NPGE(P)
4
6
8
OMU
2 for all configurations
OMU Hard disk WDU
2 for all configurations
PD30
4
6
RRMU b)
2 for all configurations
RSMU
2 for all configurations
SFU
2 for all configurations
TBUF TSS3
6
10
8
14
2 for all configurations
a) Integrated OMS replaces NEMU as of RN3.0 new deliveries. As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. b) ICSU replaces RRMU in both subracks after RN4.0 software release upgrade.
Table 6
Maximum number of units in the RNC450 for each configuration step
For information on the capacities of the alternative configurations, see RNC450 capacity in Product Description for RNC450. For information on equipping rules for interface units NIS1P, NIS1, and NIP1 in RNC450, see NIS1P, NIS1, and NIP1 equipping rules in Equipment Lists for RNC450. Back interface units at the rear of the RNAC cabinet in RNC450 In RNC450, the cabling cabinet is not used. Connections are made either from the back interface units located at the rear side of the RNAC cabinet or from the front panels of the plug-in units. For more information, see Interfaces to the environment in this document. The back interface units located at the rear side of the RNAC cabinet are described below: •
DN0938143 Issue 1-4
CPSY-A and CPSY-B Back interface units for synchronisation with 2 pieces of BNC connectors and 3 pieces of RJ45 connectors for external synchronisation inputs and outputs in each
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Cabinet and Subrack Descriptions for RNC450
•
•
6.3 6.3.1
WCDMA RNC Engineering Description
unit. CPSY-A (for TSS3/-A 0) and CPSY-B (for TSS3/-A 1) are equipped in the same network element. CPAL-A Back interface unit for alarms with one D25 connector for EXAU-A / EXAU controls, one D37 connector for general current/voltage outputs, 2 pieces of D37 connectors for voltage controlled inputs, and one D25 connector for current controlled alarm inputs. CPAL-A, CPSY-A and CPSY-B units are equipped below the CS216-A cable shelves, which are located under the two topmost subracks in the backside of the RNAC cabinet. BIE1T or BIE1C The rear of the subracks are fitted with SRBI-C, subrack for back interface. If the optional NIP1 0 is used, BIE1T balanced connector panel or BIE1C coaxial connector panel is installed in the SRBI-C behind the NIP1 0 installation position in RNAC subrack 3, slot 15.
RNC450 Upgrades and Expansions in RN5.0 Mandatory Upgrades for RNC450 Minimum hardware requirement for all configurations in RN5.0: the disk size for Integrated OMS must be at least 147 GB. Before RN5.0 software upgrade, all AL2S-B plug-in units in A2SU functional units must be replaced with the plug-in unit variant AL2S-D. For more information, prerequisites and the instructions, see Hardware Expansion for RNC450 and Upgrading RNC450 to RNC2600.
6.3.2
Optional Upgrades and Expansions for RNC450 As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. The upgrades supported in RN4.0 are also supported in RN5.0 Full CDSP-DH upgrade (replacing all CDSP-C with CDSP-DH) is supported. For more information, prerequisites and the instructions, see Hardware Expansion for RNC450 and Upgrading RNC450 to RNC2600.
6.4 6.4.1
RNC450 Upgrades and Expansions in RN4.0 Mandatory Upgrades for RNC450 In RN4.0 software release, the RRMU functional unit is removed from configuration and is configured as ICSU unit. RRMU functions are divided between the RSMU, ICSU, and OMU functional units. The location service feature moves to RSMU. For more information, prerequisites and the instructions, see Hardware Expansion for RNC450 and Upgrading RNC450 to RNC2600.
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WCDMA RNC Engineering Description
6.4.2
Optional Upgrades and Expansions for RNC450 •
•
•
•
•
DN0938143 Issue 1-4
Cabinet and Subrack Descriptions for RNC450
Upgrading RNC450 to RNC2600 This optional upgrade changes an RNC450 hardware configuration to an RNC2600 hardware configuration. As a prerequisite, the RN4.0 software upgrade must have been installed. This is a major upgrade which should be planned thoroughly in advance and only performed during a time of low traffic, by experienced site personnel and by strict adherence to the prerequisites and upgrade process. Automated macros are available to support the upgrade process. Some of the main changes to functional unit and plug-in unit configuration are • NIS1(P) / NIP1 functional units are replaced by NPS1(P) functional units, using new NP8S1-B plug-in units • All CDSPx plug-in units are replaced by CDSP-DH plug-in units • All MXU functional units receive the new MX1G6-A plug-in unit • SF10 and SF10E units are replaced with SF20H units • GTPU and A2SU units are removed and count of ICSU units increases • Existing functional units are relocated inside the network element For more information, prerequisites and the instructions, see Upgrading RNC450 to RNC2600. SFU upgrade In SFU upgrade, the SF10 plug-in units are replaced by the SF10E plug-in units in the RNAC cabinet. The SFU upgrade is prerequisite for IP upgrade. New RNAC cabinet deliveries in RN4.0 use the SF10E plug-in unit, so they do not require an SFU upgrade. For more information, see SFU and IP Upgrade. IP upgrade IP upgrade deploys IP over Ethernet (IPoE) transport for the Iu-CS, Iu-PS and Iur interfaces of an RNC. This is achieved by equipping new NP2GE-B plug-in units into an RNC cabinet and recreating existing ATM interfaces as Ethernet interfaces. The NP2GE-B plug-in units can be equipped in a cabinet into slots specified in upgrade documentation. The SFU upgrade must be completed before starting the IP upgrade. For more information, see SFU and IP Upgrade. Replacing CDSP-C with CDSP-DH (RAN1266, RAN1258) CDSP-C plug-in units for DMCU can be replaced with CDSP-DH plug-in units (RAN1266) in existing installations in the following cases: • To expand the existing DMCU configuration with new units • To replace a broken unit • To enable DMCU for the feature RAN1258: HSDPA 14 Mbps per User (CDSPDH is mandatory equipment for RAN1258) Mixed CDSP-C and CDSP-DH configurations are allowed. However, only specific CDSP-DH units in the network element can be enabled for the RAN1258 feature. For more information, see Replacing CDSP-C with CDSP-DH and Enabling HSDPA Capacity Enhancement in CDSP-DH. Full CDSP-DH upgrade (replacing all CDSP-C with CDSP-DH is supported). For more information, see Replacing CDSP-C with CDSP-DH and Enabling HSDPA Capacity Enhancement in CDSP-DH.
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Cabinet and Subrack Descriptions for RNC196
WCDMA RNC Engineering Description
7 Cabinet and Subrack Descriptions for RNC196 7.1
RNC196 Cabinet Types The RNC196 features two different equipment cabinets, RNAC and RNBC, of the type IC186-B or IC186. The subracks of the cabinets are assigned with numbers starting from 1 at the top of cabinet and ending to 4 at its bottom. In RNC196, it is possible to include an optional cabling cabinet CEXT in the RNC configuration. For more information on the cabling cabinet, see section Cabinets in WCDMA RNC Engineering Description for previous releases. The RNAC and RNBC cabinets can be configured from left to right or from right to left. CEXT can be placed on either side of the RNAC and RNBC cabinets, at the end of the row, but not in between. The positions of the cabinets in different layout options are shown in the figure below.
Left-to-right configuration 1500mm
600mm
RNAC
CEXT
RNBC
RNAC
CEXT
RNBC
Right-to-left configuration
RNBC
CEXT
RNAC
RNBC
CEXT
RNAC
Front side of the cabinets DN0426042
Figure 15
44
Layout options for the RNC196 (with optional cabling cabinet)
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WCDMA RNC Engineering Description
Cabinet and Subrack Descriptions for RNC196
RNC196 has eight configuration steps. RNC cabinets delivered up to RN2.1 HW level featured five configuration steps. In RN2.2/RN3.0 two new configuration expansion steps are introduced for RNC196: configuration step 6 and step 7. In RN5.0, the eighth configuration expansion step is introduced. RNC196 configuration step 1 is supported in RN2.2/RN3.0, but is not available for new deliveries. Configuration expansion steps 2–5 are also available for RNC196 in RN2.2/RN3.0 level expansion deliveries, with the exception that configuration step 2 does not include the RNBC expansion cabinet. The RNBC expansion cabinet must be ordered at RN2.1 level. The following sections present the hardware configuration options and configuration steps for the RNC196 cabinets. Notation RNC196 step 5 is used to refer to configuration steps 1–5. Notation RNC196 step 7 is used to refer to both RNC196 step 6 and RNC196 step 7. Notation RNC196 step 8 is used to refer to configuration step 8.
7.1.1
RNC196 Step 5 Previously delivered RNC cabinets feature five configuration steps and are configured as shown in the figures RNAC cabinet - RNC196 step 1 and RNBC cabinet - RNC196 steps 2-5.
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NIP1 2/ NPGE(P) 1 NIP1 3 ICSU 3 ICSU 4 ICSU 5 DMCU 6 DMCU 7 DMCU 8 MXU 4 PD20 MXU 5 DMCU 9 DMCU 10 DMCU 11 A2SU 2 iICSU 6 GTPU 1 / ICSU25 NIS1(P) 3 TBUF TBUF
NIP1 0/ NPGE(P) 0 NIP1 1 ICSU 0 ICSU 1 ICSU 2 DMCU 0 DMCU 1 DMCU 2 MXU 2 PD20 MXU 3 DMCU 3 DMCU 4 DMCU 5 A2SU 1 GTPU 0 / ICSU24 NIS1(P) 2 TBUF TBUF
Figure 16
46 DN70621517
NIS1(P) 4/ NPGE(P) 6 NIS1(P) 6 NIS1(P) 0 A2SU 0 RRMU 0 RSMU 0 MXU 0 PD20 EHU ESA12 / ESA24 0 NEMU
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TBUF
TSS3
TSS3
WDU 0 (OMU) WDU 1 (OMU) TBUF
HDD 0 (NEMU/OMS) OMU 0
HDD 1 (NEMU/OMS) OMU 1
FDU (OMU)
SFU 0
SFU 1 NIS1(P) 5/ NPGE(P) 7 NIS1(P) 7 NIS1(P) 1 Optional ESA24 1 RRMU 1 RSMU 1 MXU 1 PD20
Cabinet and Subrack Descriptions for RNC196 WCDMA RNC Engineering Description
RNAC
Configuration step 1
FRONT VIEW
RNAC cabinet - RNC196 step 1
DN0938143 Issue 1-4
WCDMA RNC Engineering Description
Cabinet and Subrack Descriptions for RNC196
NIP1 10/ NPGE(P) 5 NIP1 11 ICSU 16 ICSU 17 ICSU 18 DMCU 36 DMCU 37 DMCU 38 MXU 12 PD20 MXU 13 DMCU 39 DMCU 40 DMCU 41 A2SU 6 GTPU 5 / ICSU29 DMCU 42 DMCU 43 TBUF TBUF
NIP1 8/ NPGE(P) 4 NIP1 9 ICSU 13 ICSU 14 ICSU 15 DMCU 28 DMCU 29 DMCU 30 MXU 10 PD20 MXU 11 DMCU 31 DMCU 32 DMCU 33 A2SU 5 GTPU 4 / ICSU28 DMCU 34 DMCU 35 TBUF TBUF
NIP1 6/ NPGE(P) 3 NIP1 7 ICSU 10 ICSU 11 ICSU 12 DMCU 20 DMCU 21 DMCU 22 MXU 8 PD20 MXU 9 DMCU 23 DMCU 24 DMCU 25 A2SU 4 GTPU 3 / ICSU27 DMCU 26 DMCU 27 TBUF TBUF
NIP1 4/ NPGE(P) 2 NIP1 5 ICSU 7 ICSU 8 ICSU 9 DMCU 12 DMCU 13 DMCU 14 MXU 6 PD20 MXU 7 DMCU 15 DMCU 16 DMCU 17 A2SU 3 GTPU 2 / ICSU26 DMCU 18 DMCU 19 TBUF TBUF
RNBC
7.1.2
Configuration step 2
Configuration step 3
Configuration step 4
Configuration step 5
DN70621532
FRONT VIEW
Figure 17
RNBC cabinet - RNC196 steps 2-5
RNC196 Step 6 and RNC196 Step 7 The following figures show the maximum configuration after RNC196 configuration steps 6 and 7 are taken into use. The two configuration steps are presented in the same figures as the functional unit positions are the same. The two configuration steps differ in the type of plug-in unit variant used: in RNC196 step 7, the newest variants are required for all units.
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DMCU 42 ICSU 3 ICSU 4 ICSU 5 DMCU 6 DMCU 7 DMCU 8 MXU 4 PD20 MXU 5 DMCU 9 DMCU 10 DMCU 11 A2SU 2 NISx 1 GTPU 1 NISx 3 TBU 1 TBU 0
NIP1 0 (Optional) DMCU 34 ICSU 0 ICSU 1 ICSU 2 DMCU 0 DMCU 1 DMCU 2 MXU 2 PD20 MXU 3 DMCU 3 DMCU 4 DMCU 5 A2SU 1 NISx 0 GTPU 0 NISx 2 TBU 1 TBU 0
Figure 18
48 SFU 1 DMCU 26 DMCU 27 A2SU 8 Optional ESA24 1 ICSU 23 RSMU 1 MXU 14 PD20 MXU 15 GTPU 6 EHU A: WDU 1 (OMU) B: HDD 1 (OMS) OMU 1 ICSU 20 ICSU 21 TBU 1 TBU 0
DMCU 18 DMCU 19 A2SU 7 A2SU 0 ICSU 22 RSMU 0 MXU 0 PD20 MXU 1 ESA12 / ESA24 0 OMS A: WDU 0 (OMU) B: HDD 0 (OMS) OMU 0 ICSU 6 ICSU 19 TBU 1 TBU 0
SFU 0
Cabinet and Subrack Descriptions for RNC196 WCDMA RNC Engineering Description
RNAC
Configuration step 1
DN70623803
FRONT VIEW
RNAC cabinet - RNC196 steps 6 and 7
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WCDMA RNC Engineering Description
Cabinet and Subrack Descriptions for RNC196
Configuration step 2
Configuration step 3
Configuration step 4
Configuration step 5
DMCU 43 ICSU 16 ICSU 17 ICSU 18 DMCU 36 DMCU 37 DMCU 38 MXU 12 PD20 MXU 13 DMCU 39 DMCU 40 DMCU 41 A2SU 6 GTPU 5 NIS1P 9 NIS1P 11 TBU 1
TBU 0
DMCU 35 ICSU 13 ICSU 14 ICSU 15 DMCU 28 DMCU 29 DMCU 30 MXU 10 PD20 MXU 11 DMCU 31 DMCU 32 DMCU 33 A2SU 5 GTPU 4 NIS1P / NIS1 8 NIS1P / NIS1 10 TBU 1 TBU 0
ICSU 10 ICSU 11 ICSU 12 DMCU 20 DMCU 21 DMCU 22 MXU 8 PD20 MXU 9 DMCU 23 DMCU 24 GTPU 7 A2SU 4 GTPU 3 NIS1P 5 NIS1P 7 TBU 1
TBU 0
DMCU 25 ICSU 7 ICSU 8 ICSU 9 DMCU 12 DMCU 13 DMCU 14 MXU 6 PD20 MXU 7 DMCU 15 DMCU 16 DMCU 17 A2SU 3 GTPU 2 NIS1P / NIS1 4 NIS1P / NIS1 6 TBU 1 TBU 0
RNBC
DN70623815
Figure 19
7.1.3
FRONT VIEW
RNBC cabinet - RNC196 steps 6 and 7
Hardware Upgrade to RNC196 Step 6 and RNC196 Step 7 An overview of the configurations for the RNC196 configuration steps 6 and 7 is shown in the figure and sections below. For more information on the hardware changes and detailed instructions on how to carry out the configuration step expansion, see document Hardware upgrades from RNC196 step 5 to steps 6 and 7. The configuration steps differ in the requirements for plug-in unit variant level. See the tables Minimum hardware level for RNC196 step 6 and Minimum hardware level for RNC196 step 7 for more information. Both of the configuration expansion steps require cabling and configuration changes to the RNC.
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Cabinet and Subrack Descriptions for RNC196
WCDMA RNC Engineering Description
The configuration of the RNC must be at least RNC196 step 5 before the RNC196 configuration step 6 and 7 expansions.
g In the following figure Configuration steps RNC196 steps 6 and 7 with mandatory hardware changes: in slots which show two functional unit names, the lower one shows the functional unit equipped in that slot in configuration steps 1–5 and the upper one shows the functional unit equipped in that same slot after the mandatory hardware changes have been carried out in the expansion to RNC196 step 6 and 7.
= unit relocated or removed = unit added = unit upgraded to newest variant
TBU 0 TBU 1
NISx 4 NISx 6 NIS1P 5 NIS1P 7
TBU 0 TBU 1 TBU 0
Configuration step 4
TBU 1
NISx 8 NISx 10 NIS1P 9 NIS1P 11
Configuration step 3
TBU 0
GTPU 7
Configuration step 2
Configuration step 5
TBU 1
DMCU 25
NIP1 10 NIP1 11 ICSU 16 ICSU 17 ICSU 18 DMCU 36 DMCU 37 DMCU 38 MXU 12 PD20 MXU 13 DMCU 39 DMCU 40 DMCU 41 A2SU 6 GTPU 5 DMCU 42 DMCU 43
DMCU 43
NIP1 8 NIP1 9 ICSU 13 ICSU 14 ICSU 15 DMCU 28 DMCU 29 DMCU 30 MXU 10 PD20 MXU 11 DMCU 31 DMCU 32 DMCU 33 A2SU 5 GTPU 4 DMCU 34 DMCU 35
DMCU 35
NIP1 6 NIP1 7 ICSU 10 ICSU 11 ICSU 12 DMCU 20 DMCU 21 DMCU 22 MXU 8 PD20 MXU 9 DMCU 23 DMCU 24 DMCU 25 A2SU 4 GTPU 3 DMCU 26 DMCU 27
-
Configuration step 6
Figure 20
NIP1 4 NIP1 5 ICSU 7 ICSU 8 ICSU 9 DMCU 12 DMCU 13 DMCU 14 MXU 6 PD20 MXU 7 DMCU 15 DMCU 16 DMCU 17 A2SU 3 GTPU 2 DMCU 18 DMCU 19
TBU 0 TBU 1 TBU 0 TBU 1 TBU 0 TBU 1 TBU 0 TBU 1
DMCU 18 NISx 4 DMCU 19 NISx 6 NISx 0 A2SU 7 A2SU 0 RRMU 0 RSMU 0 MXU 0 PD20 EHU MXU 1 ESA12 / ESA24 0 NEMU HDD 0 WDU 0 (NEMU) (OMU) OMU 0 ICSU 6 WDU 0 (OMU) ICSU 19 NIS1P 5 DMCU 26 NIS1P 7 DMCU 27 NISx 1 A2SU 8 ESA24 1 (Optional) RRMU 1 RSMU 1 MXU 1 MXU 14 PD20 MXU 15 FDU GTPU 6 EHU HDD 0 WDU 0 (NEMU) (OMU) OMU 1 WDU 1 ICSU 20 (OMU) ICSU 21
NIP1 2 DMCU 42 NIP1 3 ICSU 3 ICSU 4 ICSU 5 DMCU 6 DMCU 7 DMCU 8 MXU 4 PD20 MXU 5 DMCU 9 DMCU 10 DMCU 11 A2SU 2 ICSU 6 NISx 1 GTPU 1 NISx 3
Configuration Step 1
RNBC
NIP1 0 Optional NIP1 1 DMCU 34 ICSU 0 ICSU 1 ICSU 2 DMCU 0 DMCU 1 DMCU 2 MXU 2 PD20 MXU 3 DMCU 3 DMCU 4 DMCU 5 A2SU 1 NISx 0 GTPU 0 NISx 2
SFU 1
SFU 0
RNAC
Configuration step 7
= unit upgraded to newest variant
DN0638349
Configuration steps RNC196 step 6 and 7 with mandatory hardware changes
RNC196 step 6 RNC196 step 6 can be achieved with the following hardware changes. For detailed information on the hardware changes and instructions on how to carry out the expansion, see document Hardware upgrades from RNC196 step 5 to steps 6 and 7.
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Cabinet and Subrack Descriptions for RNC196
Functional unit
Minimum HW level
Configuration expansion step 6
A2SU
AL2S-B
Add 2 AL2S-D units
GTPU
CCP10
Add 3 CCP18-C/CCP18-A units
ICSU
CCP10
Add 2 CCP18-C/CCP18-A units
MXU
MX622-D
Add 2 MX622-D units or Add 2 MX622-D units and upgrade all MX622C/-B units to MX622-D
NISx
NI4S1-B
Add up to 8 new NISx units
OMU
CCP18-A
Upgrade 2 CCP10 units to CCP18-A
OMU WDU HDD
HDS-B
Upgrade 2 OMU HDS/-A units to 2 HDS-B units
DMCU
CDSP-C
Reconfigure existing CDSP-Cs to new locations In RN4.0, upgrade CDSP-C units to CDSP-DH
FDU
Remove MDS-A (replaced by OMU's USB connection for external USB devices. The USB memory stick can be used only with CCP18-A.)
NIP1
NI16P1A
RRMU
Remove excessive NIP1 units – 1 unit remains In RN4.0, remove and reconfigure as ICSU units
RSMU
CCP10
OMS
MCP18-B
Integrated OMS replaces NEMU as of RN3.0 As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended.
Table 7
Minimum hardware level and configuration expansion for RNC196 step 6
RNC196 step 7 RNC196 step 7 can be achieved with the hardware changes listed below, required in addition to the hardware changes made for configuration step RNC196 step 6. For detailed information on the hardware changes and instructions on how to carry out the expansion, see document Hardware upgrades from RNC196 step 5 to steps 6 and 7. Functional unit
Minimum HW level
Configuration expansion step 7
A2SU
AL2S-D
Upgrade remaining 7 AL2S-B units to AL2S-D
GTPU
CCP18-C
Upgrade remaining 6 CCP10 units to CCP18C/CCP18-A
CCP18-A ICSU
CCP18-C CCP18-A
Table 8
DN0938143 Issue 1-4
Upgrade remaining 19 CCP10 units to CCP18C/CCP18-A
Minimum hardware level and configuration expansion for RNC196 step 7
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Cabinet and Subrack Descriptions for RNC196
Functional unit
WCDMA RNC Engineering Description
Minimum HW level
RRMU
Configuration expansion step 7 In RN4.0, removed and reconfigured as ICSU units
RSMU
CCP18-C
Upgrade 2 CCP10 units to CCP18-C/CCP18-A
CCP18-A MXU
MX622-D
DMCU
CDSP-C
OMU
CCP18-A
OMU WDU HDD
HDS-B
OMS
MCP18-B
In RN4.0, upgrade CDSP-C units to CDSP-DH
Integrated OMS replaces NEMU as of RN3.0. As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended.
Table 8
7.1.4
Minimum hardware level and configuration expansion for RNC196 step 7
RNC196 Step 8 The following figures show the maximum configuration after RNC196 configuration step 8 is taken into use.
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Figure 21
DN0938319
DN0938143 Issue 1-4 TBUF TBUF
TBUF
PD20 MXU 3 DMCU DMCU A2SU -ICSU 25 GTPU NPS1P 0 NISx 2 TBUF
- /0NPGE(P) 0 NIP1 -NIP1 1 ICSU 0 ICSU 1 ICSU 2 DMCU DMCU 1 DMCU 2 MXU 2
EHU ) 1 (OMS) 1 (NEMU/OMS HDD HDD B: A: WDU 1 (OMU) OMU 1 20(OMU) ICSU WDU 1 ICSU 21 TBUF TSS3
55 NIS1P NISx NPGEP 1 7 7 27 NPGEP 3 DMCU NIS1P NISx -NISx 1 NPS1P 3 Optional ESA24 1 ICSU RRMU231 RSMU 1 14 MXU 1 PD20 15 MXU FDU (OMU) ICSU 24
SFU 1
TBUF
TSS3
NEMU 0 (OMS) ) 0 (NEMU/OMS B: HDD HDD A: WDU 0 (OMU) OMU 0 ICSU WDU 60 (OMU) ICSU 19
-NIS1P NISx 4 4 NPGEP 0 DMCU NISx 6 619 NPGEP 2 NIS1P -NISx 0 NPS1P 2 -A2SU RRMU220 ICSU RSMU 0 MXU 0 PD20 MXU EHU 1 ESA240 ESA12 /ESA24 ESA24 ESA12/
SFU 0
CPD80-B 0
PD20 MXU 5 DMCU DMCU DMCU A2SU ICSU ICSU 26 GTPU NPS1P 1 NISx 3
1 2 / NPGE(P) -NIP1 -NIP1 3 ICSU 3 ICSU 4 ICSU 5 DMCU 6 DMCU 7 DMCU 8 MXU 4
WCDMA RNC Engineering Description Cabinet and Subrack Descriptions for RNC196
CPD80-B 1
1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
2
38
3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
4 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
RNAC cabinet - RNC196 step 8
FRONT VIEW
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1
1
7.1.5
54 TBUF
2
2
2 3
3
3
DN0938322
Figure 22 TBUF
4
4
4
4
5
5
5
5
6
6
6
6
7
7
7
7
8
8
8
8
PD20 MXU 7 DMCU DMCU DMCU A2SU ICSU 27 DMCU 2 NPS1P -DMCU TBUF
2 4 / NPGE(P) -NIP1 -NIP1 5 ICSU 7 ICSU 8 ICSU 9 DMCU 12 DMCU 13 DMCU 14 MXU 6
3
A2SU GTPU ICSU 29 DMCU 3 -NPS1P -DMCU TBUF
1
2
PD20 MXU 9 DMCU DMCU DMCU ICSU 28
3 6 / NPGE(P) -NIP1 7 NIP1 ICSU 10 ICSU 11 ICSU 12 DMCU DMCU 21 DMCU 22 MXU 8
1
PD20 MXU 11 DMCU DMCU DMCU A2SU GTPU ICSU 30 -DMCU 4/ NPGEP(P) 6 NPS1P -DMCU TBUF TBUF
4 8 / NPGE(P) -NIP1 -NIP1 9 ICSU 13 ICSU 14 ICSU 15 DMCU 28 DMCU 29 DMCU 30 MXU 10
CPD80-B 0
PD20 MXU 13 DMCU DMCU DMCU A2SU GTPU ICSU 31 DMCU 5/ NPGE(P) 7 -NPS1P -DMCU TBUF TBUF
5 10 / NPGE(P) -NIP1 -NIP1 11 ICSU 16 ICSU 17 ICSU 18 DMCU 36 DMCU 37 DMCU 38 MXU 12
Cabinet and Subrack Descriptions for RNC196 WCDMA RNC Engineering Description
CPD80-B 1
9 10 11 12 13 14 15 16 17 18 19
1
38
9 10 11 12 13 14 15 16 17 18 19
2
38
3 9 10 11 12 13 14 15 16 17 18 19
38
4 9 10 11 12 13 14 15 16 17 18 19
38
FRONT VIEW
RNBC cabinet - RNC196 step 8
Hardware Upgrade to RNC196 Step 8
An overview of the configuration for the RNC196 configuration step 8 is shown in the figure and sections below.
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WCDMA RNC Engineering Description
Cabinet and Subrack Descriptions for RNC196
Configuration step 8 differs in the requirements for plug-in unit variant level. See the table Minimum hardware level for RNC196 step 8 for more information. The configuration expansion step requires cabling and configuration changes to the RNC. The configuration of the RNC must be at least RNC196 step 7 before the RNC196 configuration step 8 expansion.
g In the following figure Configuration step RNC196 step 8 with mandatory hardware changes: in slots which show two functional unit names, the lower one shows the functional unit equipped in that slot in RNC196 step 7 and the upper one shows the functional unit equipped in that same slot after the mandatory hardware changes have been carried out in the expansion to RNC196 configuration step 8.
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55
56
1. 2. 3. 4.
Figure 23 38
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TBUF
38
TBUF
NPS1P / NPGEP(P)
ICSU
TBUF
TBUF
ICSU NPS1P
38
TBUF
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
NPS1P/ NPGE(P)
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
ICSU
4 ICSU
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 TBUF
PD20 MXU 7 DMCU 15 DMCU DMCU 16 DMCU 17 A2SU 3 GTPU 2 -DMCU 4 NIS1(P) -DMCU 6 NIS1(P)
TBUF
ICSU NPS1P
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
PD20 MXU 9 DMCU 23 DMCU 24 DMCU 7 GTPU A2SU 4 GTPU 3 DMCU 5 -NIS1P NIS1P -DMCU 7
CPD80-B 0
PD20 MXU 11 DMCU 31 DMCU 32 DMCU 33 A2SU 5 GTPU 4 NIS1(P) 8 / -DMCU NPGEP(P) 6 -DMCU 10 NIS1(P)
3 2 4 / NPGE(P) -NIP1 DMCU NIP1 5 25 ICSU 7 ICSU 8 ICSU 9 DMCU 12 DMCU 13 DMCU 14 MXU 6
TSS3
RNAC
PD20 MXU 13 DMCU 39 DMCU 40 DMCU 41 A2SU 6 GTPU 5 9/ DMCU -NIS1P NPGE(P) 7 DMCU 11 -NIS1P
2
3 6 - / NPGE(P) NIP1 -NIP1 7 ICSU 10 ICSU 11 ICSU 12 DMCU 20 DMCU 21 DMCU 22 MXU 8
TBUF
1
4 8 / NPGE(P) -NIP1 NIP1 9 35 DMCU ICSU 13 ICSU 14 ICSU 15 DMCU 28 DMCU 29 DMCU 30 MXU 10
TBUF
NEMU 0 (OMS) ) 0 (NEMU/OMS B: HDD HDD A: WDU 0 (OMU) 0 OMU ICSU WDU 60 (OMU) ICSU 19
CPD80-B 1
5 10 / NPGE(P) -NIP1 NIP1 1143 DMCU ICSU 16 ICSU 17 ICSU 18 DMCU 36 DMCU 37 DMCU 38 MXU 12
TBUF
EHU ) 1 (OMS) 1 (NEMU/OMS HDD HDD B: A: WDU 1 (OMU) 1 OMU 20(OMU) ICSU WDU 1 ICSU 21 TBUF TSS3
SFU 0 DMCU NISx 4 418 NPGEP 0 NIS1P DMCU NISx 6 619 NPGEP 2 NIS1P NISx A2SU0 7 NPS1P 2 A2SU 0 0 RRMU22 ICSU RSMU 0 MXU 0 PD20 MXU EHU 1 ESA240 ESA12 /ESA24 ESA24 ESA12/
SFU upgrade (SF10E)
TBUF
ICSU NPS1P
SFU 1 5 5 26 NPGEP 1 DMCU NISx NIS1P 7 7 27 NPGEP 3 DMCU NIS1P NISx NISx NPS1P 3 A2SU1 8 Optional ESA24 1 1 RRMU23 ICSU RSMU 1 14 MXU 1 PD20 Pd20 15 MXU FDU (OMU) ICSU GTPU 6
CPD80-B 0
TBUF
ICSU NPS1P
PD20 MXU 3 DMCU 3 DMCU 4 DMCU 5 DMCU A2SU 1 -NIS1(P) 0 GTPU 0 2 2 NISx NIS1(P)
0 0 / NPGE(P) -NIP1 NIP1 1 34 DMCU ICSU 0 ICSU 1 ICSU 2 DMCU 0 DMCU 1 DMCU 2 MXU 2
IP upgrade (NP2GE-B)
PD20 MXU 5 DMCU 9 DMCU 10 DMCU 11 A2SU 2 NIS1(P) ICSU 1 GTPU 1 3 3 NISx NIS1(P)
1 2 / NPGE(P) -NIP1 NIP1 3 42 DMCU ICSU 3 ICSU 4 ICSU 5 DMCU 6 DMCU 7 DMCU 8 MXU 4
Cabinet and Subrack Descriptions for RNC196 WCDMA RNC Engineering Description
RNBC CPD80-B 1
1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
IP upgrade (NP2GE-B)
38
2 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
38
3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
IP upgrade (NP2GE-B)
IP upgrade (NP2GE-B)
38
4 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
HSPA upgrade (CDSP-DH)
38
ICSU upgrade (CCP18-C)
NPS1(P) upgrade (NP8S1(P))
DN0938697
Configuration step RNC196 step 8 with mandatory hardware changes
Configuration step RNC196 step 8
Configuration step 8 can be achieved with the following hardware changes.
There are five possible starting configurations for upgrading RNC196 step 7 to step 8:
RNC196 step 7 RNC196 step 7 with IP / Iu-PS not totally IP based RNC196 step 7 with IP / Iu-PS totally IP based RNC196 step 7 with all IP optional upgrade
DN0938143 Issue 1-4
WCDMA RNC Engineering Description
Cabinet and Subrack Descriptions for RNC196
5. RNC196 step 7 with HSPA optional upgrade 6. RNC196 step 7 with full CDSP-DH upgrade (all CDSP-Cs are replaced with CDSPDH) Functional unit
Minimum HW level
Configuration expansion step 8
SFU
SF10E
Remove 2 SF10 units and Replace with 2 SF10E units Note: Only if starting from 1), 5) or 6) above
A2SU
Remove all remaining AL2S-D units
GTPU
Remove all CCP18-A units
ICSU
CCP18-C
Add 8 CCP18-C units, unless starting from 3) or 4) above
NPS1(P)
NP8S1-B
Remove all remaining NI16P1A / NI4S1-B units and Add up to 6 NP8S1-B plug-in units a)
DMCU
CDSP-DH
Remove all CDSP-C units and Replace with up to 18 CDSP-DH units Note: exactly 18 CDSP-DH must be equipped
OMS
MCP18-B
Integrated OMS replaces NEMU as of RN3.0 As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended.
a) The number depends on the desired configuration.
Table 9
7.2
Minimum hardware level and configuration expansion for RNC196 step 8
Equipment in the Subracks The table below shows the configurations of the subracks for RNC196 step 5, RNC196 step 7 and RNC196 step 8. The RNC196 step 7 covers both RNC196 step 6 and RNC196 step 7 maximum configurations.
Unit type
A2SU
Table 10
DN0938143 Issue 1-4
Conf.
RNAC
RNBC
Min
Max
SR 1
SR 2
SR 3
SR 4
SRs 1–4
conf.
conf.
RNC196 step 5
1
—
1
1
1
3
7
RNC196 step 7
2
1
1
1
1
5
9
RNC196 step 8
—
—
—
—
—
—
—
Number of units in RNC196 subracks
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Cabinet and Subrack Descriptions for RNC196
Unit type
Conf.
WCDMA RNC Engineering Description
RNAC
RNBC
Min
Max
SR 1
SR 2
SR 3
SR 4
SRs 1–4
conf.
conf.
RNC196 step 5
—
—
6
6
8
12
44
RNC196 step 7
2
2
7
7
5–7 a)
18
44
RNC196 step 8
1
1
2
3
11
18
18
RNC196 step 5
1
—
—
—
—
1
1
RNC196 step 7
—
1
—
—
—
1
1
RNC196 step 8
—
1
—
—
—
1
1
RNC196 step 5
—
—
1
1
1
2
6
RNC196 step 7
—
1
1
1
1–2 b)
4
8
RNC196 step 8
—
—
—
—
—
—
—
RNC196 step 5
1
1
3
4
3
9
21
RNC196 step 7
3
3
3
3
3
12
24
RNC196 step 8
3
4
4
4
17
32
32
RNC196 step 5
1
1
2
2
2
6
14
RNC196 step 7
2
2
2
2
2
8
16
RNC196 step 8
2
2
2
2
8
16
16
RNC196 step 5
1
—
—
—
—
1
1
RNC196 step 7
1
—
—
—
—
1
1
RNC196 step 8
0–1
—
—
—
—
—
1
RNC196 step 5
1
1
—
—
—
2
2
RNC196 step 7
1
1
—
—
—
2
2
RNC196 step 8
0–1
0–1
—
—
—
—
2
ESA24 c)
1
0–1
—
—
—
1
2
ESA12 c)
1
—
—
—
—
1
1
RNC196 step 5
1
—
0–2
0–2
0–2
—
12
RNC196 step 7
1
—
—
—
—
1
1
RNC196 step 8
—
—
—
—
—
—
—
RNC196 step 5
1–3
0–1
0–1
0–1
—
2
6
RNC196 step 7
—
—
1–2
1–2
0–2 d)
2
6
RNC196 step 8
—
—
—
—
—
—
—
RNC196 step 5
1–3
1–3
0–1
0–1
—
2
8
RNC196 step 7
—
—
1–2
1–2
0–2
2
12
RNC196 step 8
—
—
—
—
—
—
—
RNC196 step 5
0–1
0–1
0–1
0–1
0–1
—
8
RNC196 step 7
—
—
—
—
—
—
—
RNC196 step 8
—
—
0–1
0–1
0–6
—
8
DMCU
EHU
GTPU
ICSU h)
MXU
OMS f)
OMS HDD e)
NIP1
NIS1
NIS1P
NPGE(P)
Table 10
58
Number of units in RNC196 subracks (Cont.)
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DN0938143 Issue 1-4
WCDMA RNC Engineering Description
Unit type
Conf.
Cabinet and Subrack Descriptions for RNC196
RNAC
RNBC
Min
Max
SR 1
SR 2
SR 3
SR 4
SRs 1–4
conf.
conf.
RNC196 step 5
—
—
—
—
—
—
—
RNC196 step 7
—
—
—
—
—
—
—
RNC196 step 8
—
—
0–1
0–1
0-4
0
6
OMU
1
1
—
—
—
2
2
OMU WDU
1
1
—
—
—
2
2
—
1
—
—
—
1
1
PD20
1
1
1
1
1
4
8
RRMU f)
1
1
—
—
—
2
2
RSMU
1
1
—
—
—
2
2
SFU
1
1
—
—
—
2
2
TBUF
1
1
2
2
2
6
14
TSS3
1
1
—
—
—
2
2
NPS1(P)
OMU FDU h)
RNC196 step 5
a) In RNBC Sr2, there are 5 DMCUs. b) In RNBC Sr2, there are 2 GTPUs. c) RNC196 is configured with either ESA24 or ESA12. d) 0-2 NIS1 units in RNBC Sr1 or Sr3: maximum number of NIS1 units is 6. e) Integrated OMS replaces NEMU in RN3.0. As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. f) ICSU replaces RRMU in both subracks after RN4.0 software release upgrade. g) In RNBC Sr2, there are 6 DMCUs. h) RNC196 step 5 only: FDU is removed when adding configuration step RNC196 step 6 and RNC196 step 7.
Table 10
Number of units in RNC196 subracks (Cont.)
Unit type
Configuration steps Step 1
Step 2
Step 3
Step 4
Step 5
Step 6
Step 7
Step 8
A2SU
3
4
5
6
7
9
9
—
DMCU
12
20
28
36
44
44
44
18
EHU
1 for all configurations
ESA24
2 for all configurations
ESA12
1 for all configurations
GTPU
2
3
4
5
6
8
8
—
ICSU a)
7
10
13
16
19
22
22
32
MXU
6
8
10
12
14
16
16
16
Table 11
DN0938143 Issue 1-4
Maximum number of units in RNC196 for each configuration step
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Cabinet and Subrack Descriptions for RNC196
WCDMA RNC Engineering Description
Unit type
Configuration steps Step 1
Step 2
Step 3
OMS b)
Step 4
Step 5
Step 6
Step 7
Step 8
1
1
—
1 for all configurations
* OMS replaces NEMU as of RN3.0 OMS HDD b)
2 for all configurations
NIP1
4
6
8
NIS1
10
12
6 for all configurations
NIS1P
—
8 for all configurations
12
12
—
NPGE(P)
4
5
6
7
8
—
—
8
NPS1(P)
—
—
—
—
—
—
—
6
—
—
—
8
8
8
OMU
2 for all configurations
OMU WDU
2 for all configurations
OMU FDU
1 for all configurations
PD20
4
5
6
RRMU a)
7
8
2 for all configurations
—
RSMU
2 for all configurations
SFU
2 for all configurations
TBUF
6
TSS3
8
10
12
14
14
14
14
2 for all configurations
a) ICSU replaces RRMU in both subracks after RN4.0 software release upgrade. b) As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended..
Table 11
Maximum number of units in RNC196 for each configuration step (Cont.) For information on the capacities of the alternative configurations, see RNC196 capacity in Product Description for RNC196.
7.3 7.3.1
Upgrades and Expansions for RNC196 in RN5.0 Mandatory Upgrades for RNC196 Minimum hardware requirement for all configurations in RN5.0: the disk size for Integrated OMS must be at least 147 GB. Before RN5.0 software upgrade, all AL2S-B plug-in units in A2SU functional units must be replaced with the plug-in unit variant AL2S-D.
7.3.2
Optional Upgrades for RNC196 As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended.
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Cabinet and Subrack Descriptions for RNC196
RNC196 step 7 to step 8 upgrade is supported. For more informaiton, see Hardware Expansion for RNC196. Full CDSP-DH upgrade (replacing all CDSP-C with CDSP-DH) is supported. For more information, see Replacing CDSP-C with CDSP-DH and Enabling HSDPA Capacity Enhancement in CDSP-DH. The upgrades supported in RN4.0 are also supported in RN5.0.
7.4 7.4.1
Upgrades and Expansions for RNC196 in RN4.0 Mandatory Upgrades for RNC196 In RN4.0 software release, the RRMU functional unit is removed from configuration and is configured as ICSU unit. RRMU functions are divided between the RSMU, ICSU, and OMU functional units. The location service feature moves to RSMU. For more informaiton, see Hardware Expansion for RNC196.
7.4.2
Optional Upgrades for RNC196 •
•
•
•
DN0938143 Issue 1-4
RRMU to ICSU When the RRMU functional unit is removed, its CCP10/CCP18-A/CCP18-C plug-in units are released. They can be configured as ICSU, which means that ICSU capacity increases by two plug-in units. For more informaiton, see Hardware Expansion for RNC196. SFU upgrade In SFU upgrade, the SF10 plug-in units are replaced by the SF10E plug-in units in the RNAC cabinet. The SFU upgrade is prerequisite for IP upgrade. For more information, see SFU and IP Upgrade. IP upgrade IP upgrade deploys IP over Ethernet (IPoE) transport for the Iu-CS, Iu-PS and Iur interfaces of an RNC. This is achieved by equipping new NP2GE-B plug-in units into an RNC cabinet and recreating existing ATM interfaces as Ethernet interfaces. The NP2GE-B plug-in units can be equipped in a cabinet into slots specified in upgrade documentation. The SFU upgrade must be completed before starting the IP upgrade. For more information, see SFU and IP Upgrade. Replacing CDSP-C with CDSP-DH (RAN1266, RAN1258) CDSP-C plug-in units for DMCU can be replaced with CDSP-DH plug-in units (RAN1266) in existing installations in the following cases: • to expand the existing DMCU configuration with new units • to replace a broken unit • to enable DMCU for the feature RAN1258: HSDPA 14 Mbps per User (CDSPDH is mandatory equipment for RAN1258) Mixed CDSP-C and CDSP-DH configurations are allowed. However, only specific CDSP-DH units in the network element can be enabled for the RAN1258 feature. For more information, see Replacing CDSP-C with CDSP-DH and Enabling HSDPA Capacity Enhancement in CDSP-DH.
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Functional Unit Descriptions
WCDMA RNC Engineering Description
8 Functional Unit Descriptions 8.1
Functional Unit Categories The functional units of the RNC fall into four general categories according to their main functions: • • • •
Management, control computer and data processing units Switching and multiplexing units Network element interface units Units in the timing, power distribution, and hardware management subsystems
The units in the first three categories make up the hardware system blocks which are responsible for the main functions of the network element, such as switching, signalling, and database handling. The units in the last category are mainly blocks in the different subsystems, which are needed for the operation and maintenance of the network element, such as clock signal distribution, power distribution, and Hardware Management System. All these subsystems are controlled up to a degree by one of the computer units of the network element, the Operation and Maintenance Unit (OMU). Notations The following notations are used throughout this chapter: • •
8.2
The index numbers of the plug-in units run from left to right and top to bottom. Even though the CCP18-A and CCP10 plug-in units are all equipped with onboard LAN/Ethernet and SCSI interfaces, these are included in the functional unit interface lists only when the LAN or SCSI facility is actually used (in OMU unit only).
Management, Control Computer and Data Processing Units The management and control computer units are on the highest level in the computing hierarchy of the IPA2800 network elements. Their tasks are roughly the following: •
• • • • • •
Operation and maintenance, including control of the Hardware Management System (or alarm system) and activation of appropriate recovery and diagnostics procedures when a fault occurs Switch fabric control and ATM circuit hunting Control of some of the signal processing units Maintenance of the radio network configuration and recovery Monitoring of the MS connections Handling of signalling functions and management of the associated protocols Interfacing with both local users and the higher-level network management system
The management and control computer unit category comprises the following functional units:
8.2.1
DMCU, Data and Macro Diversity Combining Unit Purpose:
62
Although from the technical point of view DMCU is a signal processing unit, it performs some control plane functions besides its signal processing tasks. Its tasks are the following:
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WCDMA RNC Engineering Description
Functional Unit Descriptions
• • • • • • •
WCDMA L1 functions, including macro diversity combining and outer loop power control RLC-U and RLC-C protocol processing MAC-C and MAC-D protocol processing PDCP protocol processing GTP termination encryption HSDPA with CDSP-DH
All DSPs and RISC processors of the unit are automatically allocated within the RNC according to the capacity need. Redundancy:
SN+
Type:
Signal processing unit with no sub-units
Plug-in unit:
CDSP-DH / CDSP-C / CDSP-B Configurable Dynamic Signal Processing Platform
Interfaces:
ATM interface to MXU
LAN / ETHERNET: MASTER SLAVE 1 SLAVE 2 SLAVE 3
LED RS-232 CONNECTORS: MASTER SLAVE 1 SLAVE 2 SLAVE 3
BACKPLANE: -TIMING & SYNC - HMS - POWER SUPPLY - MXU DN7088176
Figure 24
DN0938143 Issue 1-4
DMCU's interfaces - CDSP-DH
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Functional Unit Descriptions
WCDMA RNC Engineering Description
INTERFACES:
BACKPLANE: -
TIMING & SYNC HMS POWER SUPPLY MXU
SERVICE TERMINAL
CDSP
Figure 25
8.2.2
DN00256144
DMCU's interfaces - CDSP
GTPU, Gateway Tunneling Protocol Unit Purpose:
GTPU facilitates RNC connections towards the SGSN by performing those RNC-specific Iu user plane functions which are related to GTP protocols. These include: • •
Routing based on GTP tunnel ID UDP/IP protocol termination
Redundancy:
SN+
Type:
Computer unit with no sub-units
Plug-in unit:
CCP18-C / CCP18-A / CCP10 Control Computer, Pentium M (CCP18-C / CCP18-A) Control Computer, Pentium III (CCP10)
Interfaces:
64
ATM interface to MXU
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WCDMA RNC Engineering Description
Functional Unit Descriptions
INTERFACES:
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - LAN / ETHERNET - POWER FEED - JTAG/ISP
DN70391828
Figure 26
DN0938143 Issue 1-4
GTPU's interfaces - CCP18-C
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Functional Unit Descriptions
WCDMA RNC Engineering Description
INTERFACES:
USB
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - SCSI (TO STORAGE DEVICES IN SUBRACKS) - LAN / ETHERNET - POWER FEED - JTAG/ISP DN0621415
Figure 27
66
GTPU's interfaces - CCP18-A
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WCDMA RNC Engineering Description
Functional Unit Descriptions
INTERFACES:
BACKPLANE: -
TIMING & SYNC HMS POWER SUPPLY MXU SCSI (NOT USED) LAN (NOT USED)
SERVICE TERMINAL
CCP10
Figure 28
8.2.3
DN00249775
GTPU's interfaces - CCP10
ICSU, Interface Control and Signalling Unit Purpose:
ICSU handles signalling functions and the associated traffic control functions, including the following tasks: • • • • • •
Admission control Radio resource management Handover control Packet scheduling Signalling protocols to Iu, Iub, and Iur interfaces, including NBAP, RNSAP, and RANAP Monitoring and recovery of the signalling links
Redundancy:
N+1
Type:
Computer unit with no sub-units
Plug-in unit:
CCP18-C / CCP18-A / CCP10 Control Computer, Pentium M (CCP18-C / CCP18-A) Control Computer, Pentium III (CCP10)
Interfaces:
DN0938143 Issue 1-4
ATM interface to MXU
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Functional Unit Descriptions
WCDMA RNC Engineering Description
INTERFACES:
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - LAN / ETHERNET - POWER FEED - JTAG/ISP
DN70391828
Figure 29
68
ICSU's interfaces - CCP18-C
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WCDMA RNC Engineering Description
Functional Unit Descriptions
INTERFACES:
USB
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - SCSI (TO STORAGE DEVICES IN SUBRACKS) - LAN / ETHERNET - POWER FEED - JTAG/ISP DN0621415
Figure 30
DN0938143 Issue 1-4
ICSU's interfaces - CCP18-A
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Functional Unit Descriptions
WCDMA RNC Engineering Description
INTERFACES:
BACKPLANE: -
TIMING & SYNC HMS POWER SUPPLY MXU SCSI (NOT USED) LAN (NOT USED)
SERVICE TERMINAL
CCP10
Figure 31
8.2.4
DN00249775
ICSU's interfaces - CCP10
Integrated OMS, Operation and Maintenance Server and its subunits Integrated OMS replaces NEMU as of RN3.0. As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. Purpose:
Integrated OMS provides the following facilities: • • • • •
Local user interface Interface towards the higher level network management system O&M functions which are not handled by other computer units of the RNC Post-processing support for measurement and statistics Peripheral device control
Integrated OMS is equipped with storage devices for storing measurement and statistical data, and an Ethernet switch with 12 or 24 physical LAN interfaces for connections to the upper-level network management system and the site LAN. Both facilities are implemented as separate plug-in units and described in separate sections which follow this one.
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Functional Unit Descriptions
Redundancy:
None
Type:
Computer unit, with dedicated storage devices and the Ethernet Switch unit (ESA12/ESA24) as sub-units.
Plug-in unit:
MCP18-B Management Computer, Pentium M 745 (MCP18-B)
MCP18-B Interfaces:
Small Computer Systems Interface (SCSI)
LAN/Ethernet to NMS, OMU and Site LAN via ESA24/ESA12 LAN/Ethernet to OMU via ESA24/ESA12 USB * VDU *) The USB ports can be used to connect a keyboard, a mouse or a bootable device to the MCP18-B. USB-PS/2 adapters are not supported.
INTERFACES: SVGA
USB
RESET SWITCH
BACKPLANE: - HMS - SCSI (TO STORAGE DEVICES IN SUBRACKS) - LAN / ETHERNET - POWER FEED - JTAG/ISP DN05226345
Figure 32
Integrated OMS interfaces (MCP18-B)
Integrated OMS storage devices
DN0938143 Issue 1-4
Purpose:
Integrated OMS is equipped with dedicated hard disks, which serve as a storage for the measurement and statistical data it collects.
Redundancy:
2N (hard disk drive)
Type:
Sub-unit to integrated OMS
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Functional Unit Descriptions
Plug-in unit:
WCDMA RNC Engineering Description
HDS-B Hard Disk Drive with SCSI Interface
Interfaces:
Small Computer System Interface (SCSI) INTERFACES:
BACKPLANE: - HMS - POWER SUPPLY - SCSI
LED
DN00256429
Figure 33
Integrated OMS storage device interfaces
Configuration and redundancy principles of integrated OMS storage devices Integrated OMS has a duplicated hard disk unit for storing all crucial measurement and statistical data. The disks are connected to integrated OMS by means of two SCSI buses, the connection principles of which are shown in the figure below.
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RNAC 2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18 19
WDU 0 (OMS)
1
OMS RNC SUBRACK 1
SCSI 0
SCSI 1
WDU 1 (OMS)
RNC SUBRACK 2
DN0938779
BUS END POINT
Figure 34
8.2.5
SCSI connection principle for integrated OMS storage devices (MCP18-B)
ESA24, Ethernet Switch RNC can have either ESA24 or ESA12 LAN/Ethernet switch. Purpose:
ESA24 is an Ethernet switch, which provides physical LAN/Ethernet interfaces for connections between OMU, integrated OMS and the other units of the network element. The ESA24 upgrade increases LAN switching capacity. Redundant ESA24 is needed for AGPS feature.
Redundancy:
None/2N
Type:
Sub-unit to integrated OMS
Plug-in unit:
ESA24 Ethernet Switch
Capacity/ Performance Interfaces:
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24 physical 10/100 Base-T Ethernet interfaces
LAN/Ethernet to OMU, integrated OMS, and site LAN
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INTERFACES:
LAN
SERVICE TERMINAL
BACKPLANE: - TIMING & SYNC (NOT USED) - HMS (NOT USED) - POWER SUPPLY - LAN ESA24
Figure 35
8.2.6
DN03451956
ESA24's interfaces
ESA12, Ethernet Switch RNC can have either ESA24 or ESA12 LAN/Ethernet switch. Purpose:
ESA12 is an Ethernet switch which provides physical LAN/Ethernet interfaces for connections between OMU, integrated OMS and the other units of the network element.
Redundancy:
None
Type:
Sub-unit to integrated OMS
Plug-in unit:
ESA12 Ethernet Switch
Capacity/ Performance Interfaces:
74
12 physical 10/100 Base-T Ethernet interfaces
LAN/Ethernet to OMU, integrated OMS, and site LAN
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Functional Unit Descriptions
INTERFACES:
BACKPLANE: - TIMING & SYNC (NOT USED) - HMS (NOT USED) - POWER SUPPLY
12 x LAN / ETHERNET
ESA12
Figure 36
8.2.7
DN02179274
ESA12's interfaces
OMU, Operation and Maintenance Unit and Its Subunits Purpose:
OMU handles all RNC's crucial upper-level system maintenance functions, such as hardware configuration management, Hardware Management System (HMS) supervision, and the associated centralised recovery functions. It also serves as an interface between integrated OMS and the other units of the network element. In the event of a fault, OMU automatically activates appropriate recovery and diagnostics procedures within RNC. In addition, OMU is responsible for the maintenance of the radio network configuration. It monitors the status of the network, separates faulty units from the system if necessary, automatically initiates the associated recovery procedures, and houses the databases that contain information on the radio network configuration. OMU has dedicated storage devices, which house the entire system software and the event buffer for intermediate storing of alarms, along with the radio network configuration files.
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Redundancy:
2N
Type:
Computer unit with a dedicated storage device unit as a sub-unit.
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Plug-in unit:
CCP18-A / CCP10 Control Computer, Pentium M (CCP18-A) Control Computer, Pentium III (CCP10)
Interfaces:
ATM virtual channels to MXU LAN/Ethernet via ESA24/ESA12 to integrated OMS Duplicated Small Computer Systems Interface (SCSI) Service Terminal interface Multiplexer Interface Duplicated Hardware Management System (HMS) interface
INTERFACES:
USB
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - SCSI (TO STORAGE DEVICES IN SUBRACKS) - LAN / ETHERNET - POWER FEED - JTAG/ISP DN0621415
Figure 37
76
OMU's interfaces - CCP18-A
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INTERFACES:
BACKPLANE: -
TIMING & SYNC HMS POWER SUPPLY MXU SCSI LAN
SERVICE TERMINAL
CCP10
Figure 38
DN00249799
OMU's interfaces - CCP10
OMU's storage devices Purpose:
OMU has two dedicated hard disk units, which serve as a redundant storage for the entire system software, the event buffer for intermediate storing of alarms, and the radio network configuration files. Backup copies are made onto a USB memory stick that is connected to the CCP18-A front plate. Only memory sticks can be used.
Redundancy:
2N (HDS-B) none (MDS-A/B)
Type:
Sub-unit to OMU
Plug-in unit:
HDS-A/-B: Hard Disk Drive with SCSI Interface MDS-A/-B : Magneto Optical Drive with SCSI Interface
External devices: Interfaces:
USB memory stick, one for each OMU (for CCP18-A only)
Small Computer System Interface (SCSI) Universal Serial BUS (USB, CCP18-A)
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INTERFACES: BACKPLANE: - HMS - POWER SUPPLY - SCSI
MDS /-A
HDS /-A
DN02179305
Figure 39
OMU's storage devices' interfaces
Configuration and redundancy principle of OMU's storage devices The two mutually redundant WDUs are connected simultaneously to both OMUs by means of separate SCSI buses. This ensures that a spare unit is immediately available for either one of the mutually redundant OMUs, eliminating the need for OMU switchover in case of a memory unit failure. The USB stick is an optional external device that is not automatically delivered. Only the USB memory stick that is connected to the active OMU can be used. For OMU switchover, two USB memory sticks are needed: one for each OMU. The connection principle for the memory units is illustrated in the figures below.
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RNAC
1
2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18 19
RNAC SUBRACK 1
OMU 0
WDU 0 (OMU)
SCSI 0
SCSI 1
1
2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18 19
DN0640747
Figure 40
DN0938143 Issue 1-4
OMU 1
WDU 1 (OMU)
RNAC SUBRACK 2
BUS END POINT
SCSI connection principle for OMU storage devices - CCP18-A and HDS-B
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RNAC 2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18 19
1
2
3
4
5
6
7
8
9 10 11 12 13 14 15 16 17 18 19
WDU 0 (OMU)
OMU 0
1
RNC SUBRACK 1
DN99573042
Figure 41
8.2.8
WDU 1 (OMU)
RNC SUBRACK 2
SCSI 1
OMU 1
FDU (OMU)
SCSI 0
BUS END POINT
SCSI connection principle for OMU storage devices - CCP10, HDS-A and MDS-A
RRMU, Radio Resource Management Unit Purpose:
RRMU performs RNC-wide paging and IPA2800 messaging.
Redundancy:
2N
Type:
Computer unit
Plug-in unit:
CCP18-C / CCP18-A / CCP18-A / CCP10 Control Computer, Pentium M (CCP18-C/CCP18-A) Control Computer, Pentium III (CCP10)
Interfaces:
80
ATM interface to MXU
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Functional Unit Descriptions
INTERFACES:
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - LAN / ETHERNET - POWER FEED - JTAG/ISP
DN70391828
Figure 42
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RRMU's interfaces - CCP18-C
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INTERFACES:
USB
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - SCSI (TO STORAGE DEVICES IN SUBRACKS) - LAN / ETHERNET - POWER FEED - JTAG/ISP DN0621415
Figure 43
82
RRMU's interfaces - CCP18-A
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Functional Unit Descriptions
INTERFACES:
BACKPLANE: -
TIMING & SYNC HMS POWER SUPPLY MXU SCSI (NOT USED) LAN (NOT USED)
SERVICE TERMINAL
CCP10
Figure 44
8.2.9
DN00249775
RRMU's interfaces - CCP10
RSMU, Resource and Switch Management Unit Purpose:
RSMU controls the switch fabrics in RNC and establishes connections for calls according to requests from the signalling computer units (ICSUs). It also handles DSP resource management. ATM switching management functions comprise: • • •
Establishment of both internal and external connections via SFU, including ATM circuit hunting Management and control of SFU, A2SU and MXU Transmission resource management.
DSP resource management tasks comprise: • • •
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Supervision and management of the DMCU units, including the necessary software upload procedures Allocation of the DSPs and associated computer resources to different tasks, such as microdiversity combining and data traffic Management of the ATM connections within DMCU
Redundancy:
2N
Type:
Computer unit
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Plug-in unit:
CCP18-C / CCP18-A / CCP10 Control Computer, Pentium M (CCP18-C/CCP18-A) Control Computer, Pentium III (CCP10)
Interfaces:
ATM interface to MXU
INTERFACES:
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - LAN / ETHERNET - POWER FEED - JTAG/ISP
DN70391828
Figure 45
84
RSMU's interfaces - CCP18-C
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Functional Unit Descriptions
INTERFACES:
USB
RESET SWITCH
SERVICE TERMINAL
BACKPLANE: - HMS - SCSI (TO STORAGE DEVICES IN SUBRACKS) - LAN / ETHERNET - POWER FEED - JTAG/ISP DN0621415
Figure 46
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RSMU's interfaces - CCP18-A
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INTERFACES:
BACKPLANE: -
TIMING & SYNC HMS POWER SUPPLY MXU SCSI (NOT USED) LAN (NOT USED)
SERVICE TERMINAL
CCP10
Figure 47
8.3
DN00249775
RSMU's interfaces - CCP10
Switching and Multiplexing Units Switching and multiplexing in RNC is based on the Asynchronous Transfer Mode (ATM) technology with full support to the various traffic types used in the network. The units in this category are the following: • •
•
ATM Switching Fabric Units (SFUs) which are used for switching the calls processed by the network element Multiplexer Units (MXUs), for connecting the low-bit-rate network interface units, along with the computer units and signal processing units (which typically have small to moderate bandwidth requirements) to the ATM switch fabric AAL2 Switching Units (A2SUs), which ensure efficient transport of information with limited transfer delay for low-to-moderate bit-rate units connected to the main switch fabric.
In addition, the units in this block provide the ATM interface, which serves as the main message bus between the units in the network element. Upper-level control functions for all three units are performed by the RSMU functional unit.
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MXU's connections within the RNC The figure below shows how the ATM connections in RNC are allocated to its various units in RNC450. The SFU switching fabric has 16 ports for connections to the other units in the network element, with an aggregate capacity of 10Gbit/s (equivalent to 64STM-1 lines); each port, in turn, has a capacity of 622 Mbit/s. The connections through the ports are allocated in the following manner: RNC2600, RNC450, RNC196 step 6, RNC196 step 7 and RNC196 step 8 • •
2–6 (12 redundant) ports are used for the external STM-1 connections provided by the NIS1, NPGE and NPS1 units. Eight ports are used for connections to the low-bit-rate network interface units and the computer units via the mutually redundant MXU pairs. One MXU pair requires one port.
The equipment of RNC is organised as groups of units around its MXU pairs, with each group connecting to a MXU pair of its own. When adding the RNC196 configuration step 6, the MXU 1 is moved to RNAC subrack 1 and a new MXU pair, MXU 14 and MXU 15 are added to RNAC subrack 2. After the configuration step RNC196 step 6 upgrade, both MXU pairs in RNAC subracks 1–2 serve the subracks they are located in. The figure below shows the MXU pairs and the devices connecting to each MXU pair in RNC450. The number of units included in each subrack is given after each unit.
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2 pcs
A2SU
1 3-8
1 pcs
RSMU
1 pcs
RRMU
MXU
NIP 1
0-1 pcs ***
ICSU
3 pcs
DMCU
DMCU
A2SU
1 pcs
5-7 pcs* ICSU
2 pcs 2 pcs
MXU SFU
DMCU
GTPU 1 pcs
OMU
1 pcs
A2SU
2
1-2 pcs **
2-12 pcs NIS 1
1 pcs
RSMU
1 pcs
RRMU
2 pcs
ICSU
2 pcs
DMCU
1 pcs
MXU
OMU
* 5 DMCUs in RNBC Sr2 ** 2 GTPUs in RNBC Sr2 *** 1 NIP1 in RNAC Sr3
DN01128575
Figure 48
8.3.1
ATM connections to SFU - RNC450
A2SU, AAL2 Switching Unit Purpose:
A2SU unit handles the ATM adaptation layer type 2, AAL2, switching. A2SU is an AAL type 2 CPS minipacket switching unit, which is used in association with the Multiplexing Unit (MXU) for facilitating connections between the main Switch Fabric (SFU) and the low-to-moderate bit-rate units (computer units, signal processing units and low-bit-rate network interface units). The function of the A2SU unit is to switch the AAL type 2 CPS minipackets. The AAL 2 minipackets coming into and going out of A2SU are embedded in ATM cells. Before the switching the AAL 2 minipackets are removed from the ATM cells, and after the switching they are packed again into ATM cells.
Redundancy:
88
SN+
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Functional Unit Descriptions
Type:
Signal processing unit
Plug-in unit:
AL2S-D / AL2S-B AAL type 2 switching unit
Interfaces:
ATM interface to MXU
LAN / ETHERNET: MASTER SLAVE 1 SLAVE 2 SLAVE 3
LED RS-232 CONNECTORS: MASTER SLAVE 1 SLAVE 2 SLAVE 3
BACKPLANE: -TIMING & SYNC - HMS - POWER SUPPLY - MXU DN7088176
Figure 49
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A2SU's interfaces - AL2S-D
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INTERFACES: BACK PLANE: -
TIMING & SYNC HMS POWER SUPPLY MXU
SERVICE TERMINAL
AL2S-B
Figure 50
8.3.2
DN00249833
A2SU's interfaces - AL2S-B
MXU, Multiplexer Unit Purpose:
The MXU units enable connection of the low-to-medium bit-rate signal processing units and computer units, as well as low-bit-rate network interface units, to the ATM switch fabric. The task of MXU is to perform the multiplexing and demultiplexing of ATM cells and perform ATM layer management and processing functions such as header translation, UPC/NPC parameter control, OAM functions, traffic management, performance monitoring and collection of performance data.
Redundancy:
2N
Type:
Multiplexer unit
Plug-in unit:
MX1G6-A / MX1G6 / MX622-D / MX622-C / MX622-B ATM Multiplexer plug-in unit 622 Mbit/s
Capacity:
622 Mbit/s
Interfaces:
ATM interfaces to: • • •
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SFU switching block SFU unit computer Control computer units (including DMCU)
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Functional Unit Descriptions
• • •
Network interfaces A2SU Connection between the passive MXU via the active one to OMU (for OAM purposes)
INTERFACES: BACKPLANE: - TIMING & SYNC - HMS - POWER FEED - SFU - TRIBUTARY UNITS - REDUNDANCY INTERFACE - BOUNDARY SCAN INTERFACE LED
SERVICE TERMINAL
DN70170272
Figure 51
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MX1G6/ MX1G6-A
MXU's interfaces - MX1G6 and MX1G6-A
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INTERFACES: BACKPLANE: - TIMING & SYNC - HMS - POWER FEED - SFU - TRIBUTARY UNITS - SFU UNIT COMPUTER - OMU FROM PASSIVE MUX VIA THE ACTIVE ONE LED
SERVICE TERMINAL
MX622
Figure 52
8.3.3
DN02179344
MXU's interfaces - MX622
SFU, Switching Fabric Unit Purpose:
SFU serves as the main switch fabric of the network element. It operates according to a non-blocking connection principle, which means that a connection can be established any time provided that the needed input and output capacity is available. SFU supports both pointto-point and point-to-multipoint connection topologies, as well as differentiated handling of various ATM service categories.
Redundancy:
2N
Type:
Switching fabric
Plug-in unit:
SF20H, SF10E, SF10 ATM Switch Fabric Plug-in Unit 10 Gbit/s
Capacity:
10 Gbit/s
Interfaces:
ATM interfaces to: • • •
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NI4S1 network interfaces Low-bit-rate network interfaces and control computers (via MXUs) OMU from the unit computer of SFU (for OAM purposes and software uploads, via MXUs)
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LED
ETH SER
DN70166955
Figure 53
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SF20H
SFU's interfaces - SF20H
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WCDMA RNC Engineering Description
INTERFACES: BACKPLANE: - TIMING & SYNC - HMS - POWER SUPPLY - SWITCH PORT TO TRIBUTARY UNITS - OMU (FROM UNIT COMPUTER VIA MXU) LAN (TESTING ONLY) SERVICE TERMINAL
SFP (SFPIF2G5)
DN70498095
Figure 54
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SFU's interfaces - SF10E
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Functional Unit Descriptions
INTERFACES: BACKPLANE: - TIMING & SYNC - HMS - POWER SUPPLY - SWITCH PORT TO TRIBUTARY UNITS - OMU (FROM UNIT COMPUTER VIA MXU)
LAN SERVICE TERMINAL
SF10
Figure 55
8.4
DN02179356
SFU's interfaces - SF10
Network Interface Units These units serve as the trunk network interfaces of the network element and execute physical layer and ATM layer functions, such as policing, statistics, Operation Administration Maintenance (OAM), buffer management, and scheduling. The category comprises the following units: • • • •
NIP1, Network Interface Unit PDH NIS1 / NIS1P, Network Interface Unit STM-1 NPS1 / NPS1P NPGE / NPGEP
One network interface unit contains more than one physical interface. Each interface can be configured to be used as an Iu, Iub, or Iur interface within the total connection capacity of the network element.
g To ensure at least partial backup for the power supply to the network interfaces, SDH/TDM trunk connections from RNC to any direction should be divided between at least two, preferably even more units, which are located in different subracks.
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8.4.1
WCDMA RNC Engineering Description
NIP1 NIP1 is optional in RNC450, RNC196 step 6 and RNC196 step 7. Purpose:
This ATM network interface unit contains PDH E1/T1/JT1 interfaces with Inverse Multiplexing for ATM (IMA) function, which allows for flexible grouping of physical links to logical IMA groups. Normally, the PDH lines are used for connections between RNC and the BTSs.
Redundancy:
None
Type:
Interface unit
Plug-in unit:
NI16P1A ATM Network Interface 16 × PDH E1/T1/JT1
Capacity/ performance: Sixteen physical PDH electrical interfaces, each with a bandwidth of: • • Interfaces:
2048 kbit/s (E1) or 1544 kbit/s (T1/JT1)
ATM interface to MXU Clock reference output to TSS3/-A
INTERFACES: LAN (NOT USED)
BACKPLANE: -
TIMING & SYNC HMS POWER SUPPLY MXU E1 / T1 / JT1 CLOCK REFERENCE OUTPUT TO TSS3
SERVICE TERMINAL
NI16P1A
Figure 56
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DN02179492
NIP1's interfaces
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8.4.2
Functional Unit Descriptions
NIS1 / NIS1P Purpose:
NIS1 provides SDH STM-1 interfaces and handles bit timing, line coding, and timing recovery.
Redundancy:
NIS1: none (organised by routing and/or MSP 1+1) NIS1P: 2N
Type:
Interface unit
Plug-in unit:
NI4S1-B Network Interface 4 × 155 Mbit/s STM-1
Capacity/ performance: Four physical SDH STM-1 interfaces, with a bandwidth of 155,52 Mbit/s for each Interfaces:
ATM interface to SFU Clock reference output to TSS3/-A
INTERFACES: STM-1
BACKPLANE: -
TIMING & SYNC HMS POWER SUPPLY SFU CLOCK REFERENCE OUTPUT TO TSS3
LAN (NOT USED) SERVICE TERMINAL
NI4S1-B
Figure 57
8.4.3
NPS1 / NPS1P Purpose:
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DN02179368
NIS1's interfaces
NPS1(P) provides SDH STM-1/STM-4 interfaces and an RJ45 connector, and handles multiprotocol packet processing at wire speed and network connectivity.
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Note that RN4.0 SW does not support STM-4 interface. Redundancy:
NPS1: none (organised by routing) NPS1P: 2N (organised by routing and MSP and/or MSP 1+1)
Type:
Interface unit
Plug-in unit:
NP8S1, NP8S1-B Network Interface 8 × 155 Mbit/s STM-1 or Network Interface 2 × 622 Mbit/s STM-4; one RJ45 connector Note that RN4.0 SW does not support STM-4 interface.
Capacity/ performance: Eight optical STM-1/OC-3 interfaces, with a bandwidth of 155,52 Mbit/s each, or two optical STM-4/OC-12 interfaces, 622,08 Mbit/s each Note that RN4.0 SW does not support STM-4 interface. Interfaces:
Fast Ethernet physical layer interface Switch fabric interface Timing and synchronization interface Hardware management system interface ATM interface to SFU CLASS 1 LASER PRODUCT IEC/EN 60825-1
INTERFACES: BACKPLANE:
1
Tx Rx
2
Tx Rx
3
STM-1 / STM-4*
-
TIMING & SYNC HMS POWER SUPPLY SFU CLOCK REFERENCE OUTPUT TO TSS3 - LAN 1-5
Tx Rx
4 5 6 7 8
Tx Rx Tx
STM-1
Rx Tx Rx Tx Rx Tx Rx
SERVICE TERMINAL
* STM-4 interface cannot be used
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DN70550849
NP8S1-B, NP8S1-A, NP8S1
Figure 58
NPS1(P) interfaces
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8.4.4
Functional Unit Descriptions
NPGE / NPGEP Purpose:
NPGE(P) provides Ethernet interfaces and handles multiprotocol packet processing at wire speed.
Redundancy:
NPGE: none NPGEP: 2N
Type:
Interface unit
Plug-in unit:
NP2GE, NP2GE-B 2 × Gigabit Ethernet interface 1000Base-LX/T (optical/electrical), 2 × Fast Ethernet interface 10/100 Base-T (electrical)
Capacity/ performance: Two 1000Base-LX/T (optical or electrical) Gigabit Ethernet interfaces and two 10/100 Base-T (electrical) Fast Ethernet interfaces Interfaces:
Fast Ethernet physical layer interface Switch fabric interface Timing and synchronization interface Hardware Management System interface ATM interface to SFU
Figure 59
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NPGE(P) interfaces
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8.5
WCDMA RNC Engineering Description
Timing, Power Distribution and Hardware Management Subsystems The timing, power distribution, and Hardware Management Subsystems form the lowest level in the computing hierarchy of the IPA2800 network elements. Each subsystem is composed of a redundant master unit and a duplicated data distribution/collection bus. In each case, the bus actually extends through some lower level units to virtually all of the network element's plug-in units, which are equipped with dedicated hardware blocks supporting the core parts of the subsystem. The clock distribution and Hardware Management subsystems in the network element use the same two types of plug-in units, namely: • •
TSS3/-A, Timing and Synchronization, SDH Stratum 3 TBUF, Timing Buffer.
The clock system meets Stratum 3 level accuracy requirement, as defined in the Bellcore TA-NWT-1244 standard. The power distribution subsystem in the network element uses the following type of plug-in units: RNC450 with EC216: • •
PD30, Power Distribution Plug-in Unit 30 A* CD120-A, Cabinet Power Distributor 120 A * Note that with PD30, FTRA-B is required.
RNC196 with IC186-B: • •
8.5.1
PD20, Power Distribution Plug-in Unit 20 A CDP80-B, Cabinet Power Distributor 80 A
TBU, Timing and Hardware Management Bus Unit The Timing and Hardware Management Bus Unit (TBU) is responsible for the network element synchronisation, timing signal distribution and message transfer functions in the hardware management system. TBU is a duplicated functional unit that consists of two plug-in units in each subrack as well as a serial bus spanning all plug-in units of the network element. The two plug-in units, the Timing and Synchronisation, SDH Stratum 3 (TSS3/-A) and Timing Buffer (TBUF) and their functions are described below. TSS3/-A, Timing and Synchronisation, SDH Stratum 3
g New clock plug-in unit variant TSS3-A is implemented in RN5.0 based RNC2600 deliveries. However, TSS3-A can be used with RN4.0 software if Bridge HMX1BNGX version inside the plug-in unit is newer than in RN4.0 release package. Refer to technical note TS-RNC-HW-066 for more detail.
g Due to 2N redundancy a mixed configuration of TSS3 and TSS3-A is not allowed. The same variant must be used for both clock units in each RNC. Purpose:
100
TSS3/-As generate the clock signals necessary for synchronising the functions of RNC. Normally, TSS3/-A operates in a synchronous mode, that is, it receives an input timing reference signal from an upper level of the network and adjusts its local oscillator to the long time mean value by filtering jitter and wander from the timing signal. It transmits the ref-
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WCDMA RNC Engineering Description
Functional Unit Descriptions
erence to the plug-in units in the same subrack, as well as to the TBUF units, which distribute the signals to units not directly fed by TSS3/-As. TSS3/-A has inputs for both synchronisation references from other network elements via the network interfaces, and for those from external sources (options are 2048 kbit/s, 2048 kHz, 64+8 kHz, 1544 kHz, or 1544 kbit/s (TSS3-A)). TSS3-A input is 5 V tolerant. If all synchronisation references are lost, TSS3/-A can operate by independently generating the synchronisation reference for the units in the network element. TSS3/-As are also involved in the functioning of the HMS bus. They convey HMS messages through the HMS bridge node to the HMS master node. Each OMU has one master node. TSS3-A is designed to conform ITU-T G813, G.703 and Bellcore GR1244 recommendation. Redundancy:
2N
Type:
Functional unit with TBUF units as sub-units
Plug-in unit:
TSS3/-A Timing and Synchronisation, SDH Stratum 3
Interfaces:
Synchronisation reference interfaces: • • • • •
Three line inputs (from STM-1 or PDH lines) Two external inputs (2048 kbit/s, 2048 kHz, 64+8 kHz, 1544 kHz, or 1544 kbit/s (TSS3-A)) Eight outputs to cabinet timing buses One output to subrack timing bus One external timing output (2048 kHz, 2048 kbit/s (TSS3-A), 1544 kHz (TSS3-A), or 1544 kbit/s (TSS3-A))
HMS interface
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Figure 60
WCDMA RNC Engineering Description
TSS3/-A's interfaces
TBUF, Timing Buffer Purpose:
The TBUF unit is a clock buffer which distributes the synchronisation signals generated by TSS3/-As to those plug-in units that are not directly fed by TSS3/-As. TBUFs are also involved in the functioning of the HMS bus. They convey HMS messages through the HMS bridge node to the HMS master node. Each OMU has one master node.
Redundancy:
2N
Type:
Functional unit, sub-unit of TSS3/-A
Plug-in unit:
TBUF Timing Buffer
Interfaces:
Synchronisation reference interfaces: • • •
102
One input from TSS3/-A or another TBUF One output to subrack timing bus One output to another TBUF
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HMS interface INTERFACES: BACKPLANE: - ONE CLOCK REFERENCE INPUT FROM TSS3 OR TBUF - ONE TIMING & SYNC OUTPUT TO SUBRACK TIMING BUS - ONE TIMING & SYNC OUTPUT TO ANOTHER TBUF - HMS
TBUF
Figure 61
DN02179371
TBUF's interfaces
Connection principle and redundancy for the timing and synchronisation distribution bus RNC has two separate timing and synchronisation distribution buses to ensure 2N redundancy for the internal timing signal distribution. Each bus has its own system clock (a TSS3/-A plug-in unit), distribution cabling, and timing buffers (TBUF plug-in units). The two TSS3/-A units backing up each other are placed in different subracks (subracks 1 and 2), each of which is powered by a power supply plug-in unit of its own to ensure redundancy for the power supply. Each of these subracks is also equipped with a TBUF plug-in unit, which connects the equipment in the subrack to the other clock distribution bus. The RNAC subracks 3 and 4 and all RNBC subracks have two separate TBUF units, which connect to different clock distribution buses by means of cables of their own. In order to function correctly, the differential buses need terminations in the ends of the bus by means of a termination cable. Due to the expansion of the network element through the configuration steps, the end of the bus and similarly the termination point changes. When a new subrack is taken into use in a configuration step, the cabling must always be moved to the new subrack. Duplicated buses need two terminations, which means that four terminators altogether in each cabinet are required for the HMS and the timing and synchronisation distribution bus. The clock distribution principle in the network element is shown in the figure below.
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RNAC
RNBC
RNAC SUBRACK1
RNBC SUBRACK1
RNAC SUBRACK2
RNBC SUBRACK2
RNAC SUBRACK3
RNBC SUBRACK3
RNAC SUBRACK4
RNBC SUBRACK4
DN70680727
In RNC2600/Step1 HMS BUS 0 HMS BUS 1
In RNC2600/Step3 HMS BUS 0 HMS BUS 1
BUS STARTING POINT
Figure 62
8.5.2
Connection principle of the duplicated clock distribution bus
HMS, Hardware Management Subsystem The Hardware Management Subsystem has three hierarchically organised layers of equipment. The upmost level in the hierarchy is formed by the Hardware Management Master Nodes (HMMNs), one in each OMU, which control the whole subsystem. TSS3/As and TBUFs in the subracks have separate Hardware Management System Bridge nodes (HMSBs), which form the next, intermediate level in the hierarchy. As the name suggests, they serve as bridges which connect HMMNs to the lowest-level blocks in the hierarchy, Hardware Management System Slave Nodes. Implemented as dedicated
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hardware blocks in all plug-in units, the latter are independent from the other blocks of the plug-in unit, for example, in terms of the power supply. A block diagram which illustrates the HMS subsystem implementation is shown in the figure below. CABINET 1 HMMN OMU 0 HMSS
CABINET 2
SUBRACK 1 PIU HMSS
PIU HMSS
SUBRACK 1
PIU HMSS
PIU HMSS
HMSB 0
PIU HMSS
PIU HMSS
HMSB 0
TSS3
TBUF
BACKPLANE BUS
HMSS
BACKPLANE BUS
HMSS
HMSB 1
HMSB 1
TBUF
TBUF
BACKPLANE BUS
HMSS
HMMN OMU 1 HMSS
BACKPLANE BUS
HMSS
SUBRACK 2 PIU HMSS
PIU HMSS
PIU HMSS
HMSB 0 TBUF
BACKPLANE BUS
HMSS
HMSB 1 TSS3
BACKPLANE BUS
HMSS
SUBRACK 4
SUBRACK 4
PIU HMSS
PIU HMSS
PIU HMSS
PIU HMSS
HMSB 0 TBUF
HMSS
HMSS
PIU HMSS
HMSB 0 TBUF
BACKPLANE BUS
HMSS
HMSB 1 TBUF
PIU HMSS BACKPLANE BUS
HMSB 1 TBUF
BACKPLANE BUS
HMSS
BACKPLANE BUS
TO OTHER RACKS
DN99573245
HMSB = HMS BRIDGE HMSS = HMS SLAVE NODE HMMN = HARDWARE MANAGEMENT MASTER NODE
Figure 63
Block diagram of the HMS subsystem
Connection principle and redundancy of the HMS bus RNC has also two mutually redundant hardware management buses, which are implemented by means of the same plug-in units as the timing and synchronisation buses, TSS3/-As and TBUFs. The routing of the hardware management buses, however, differs somewhat from that of the timing and synchronisation buses. The hardware management bus is organised in such a way that TSS3/-As and TBUFs are on an equal level of the subsystem; both act as parallel HMS bridges which convey messages to the HMS master node. Each OMU has one master node.
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In order to function correctly, the differential buses need terminations in the ends of the bus by means of cabling. Due to the expansion of the network element through the configuration steps, the end of the bus and similarly the termination point changes. When a new subrack is taken into use in a configuration step, the cabling must always be moved to the new subrack. Duplicated buses need two terminations, which means that four terminators altogether in each cabinet are required for the HMS and the timing and synchronisation distribution bus. The connection principle of the HMS buses in the network element is shown in the figure below. RNAC
RNAC SUBRACK1
RNBC SUBRACK1
RNAC SUBRACK2
RNBC SUBRACK2
RNAC SUBRACK3
RNBC SUBRACK3
RNAC SUBRACK4
RNBC SUBRACK4
DN70680715
Figure 64
106
RNBC
In RNC2600/Step1 HMS BUS 0 HMS BUS 1
In RNC2600/Step3 HMS BUS 0 HMS BUS 1
Connection principle of the duplicated HMS bus
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8.5.3
Functional Unit Descriptions
Power Distribution Subsystem The power distribution subsystem in the network element uses the following type of plug-in units: EC216: • •
PD30, Power Distribution Plug-in Unit 30 A* CD120-A, Cabinet Power Distributor 120 A * Note that with PD30, FTRA-B is required.
IC186-B: • •
PD20, Power Distribution Plug-in Unit 20 A CDP80-B, Cabinet Power Distributor 80 A
Purpose:
The Power Distribution Subsystem distributes the -48V power from the rectifiers or batteries to the equipment inside the RNC cabinets. This subsystem consists of two CPD120-A or CPD80-B / CPD80-A power distribution panels at the top of each cabinet, one PD30/PD20 power distribution plug-in unit in each subrack, and the associated cabling. See Cable Lists for RNC for a visual representation of the power feed to each subrack. The PD30/PD20 unit also controls the cooling equipment of its own subrack on the basis of messages sent by OMU.
Redundancy:
Power distribution subsystem is duplicated by providing two independent feeding input branches from cabinet level to plug-in unit level.
Type:
Power distribution
Plug-in unit:
CPD120-A: Cabinet Power Distributor 120 A and PD30: Power Distribution Plug-in Unit 30 A CPD80-B / CPD80-A: Cabinet Power Distributor 80 A and PD20: Power Distribution Plug-in Unit 20 A
Interfaces:
One input for each of the two CPD120-As or CPD80-B/-As; or one duplicated input from the site power supply to the CPD80 Four outputs to subracks (in CPD120-A/CPD80-B/-A) or four duplicated outputs to subracks (in CPD80) Outputs to four groups of plug-in units (in PD30/PD20) Four duplicated inputs from CPD80 (in PD20) Fan tray control and alarm interface
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FUSES
LED
DN00256417
Figure 65
PD30/PD20's interfaces
Power distribution principle and redundancy To ensure 2N redundancy for the power distribution lines, the RNC cabinets are provided with two independent feeding input branches. In EC216, each feeding branch connects to a dedicated CPD120-A. Each CPD120-A unit contains: •
• •
Connectors for one of the two mutually redundant supply lines from the batteries/rectifiers. In this way the two independent input branches are kept separate until the subrack level. Connectors for four supply lines to the subracks. Each subrack is supplied by a line from both CPD120-As, giving 2N redundancy. Circuit breakers for the outgoing supply lines, each with 30-A rating
The CPD120-A allows for either grounding the 0V lead from the battery or for a use of a separate grounding cable to achieve floating battery voltage. From the CPD120-A unit, the voltage is fed through the subrack-specific PD30 power distribution plug-in units, which have individual 10-A fuses for each outgoing distribution line, to the other plug-in units in a likewise manner as to the cabinets, that is, through two mutually redundant supply lines. The two distribution lines are finally combined in the power converter
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blocks of individual plug-in units, which adapt the voltage so that it is appropriate for the plug-in unit components. In the IC186-B cabinet, each branch connects to a dedicated CPD80-B / CPD80-A unit, which contains: •
• •
Connectors for one of the two mutually redundant supply lines from the batteries/rectifiers. In this way the two independent input branches are kept separate until the subrack level. Connectors for four supply lines to the subracks. Each subrack is supplied by a line from both CPD80-B / -As, giving 2N redundancy. Circuit breakers for the outgoing supply lines, each with 20-A rating
In the IC186 cabinet both feeding branches connect into the same CPD80 unit, which contains • • •
Connectors for the two mutually redundant supply lines from the batteries/rectifiers Connectors for the four duplicated supply lines to the subracks Circuit breakers for the outgoing supply lines, each with 20-A rating
The CPD80-B/-A /CPD80 power distribution unit allows for either grounding the 0V lead from the battery or for a use of a separate grounding cable to achieve floating battery voltage. From the power distribution unit, the voltage is fed through the subrack-specific PD20 power distribution plug-in units, which have individual 8-A fuses for each outgoing distribution line, to the other plug-in units in a similar manner as to the cabinets, that is, through two mutually redundant supply lines. The two distribution lines are finally combined in the power converter blocks of individual plug-in units. The power converter blocks adapt the voltage so that it is appropriate for the plug-in unit components.
g Operating voltages must be fed in each cabinet of the network element using two separate pairs of supply cables. The general power distribution principle for RNC is shown in the figure below. The internal DC/DC converter structure of the plug-in units is shown in the second figure.
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Protection area of the main fuse
Protection area of the circuit breaker at the cabinet level
-UB2 -UB2 Main fuses or circuit breakers in power system
DC
BOV 0
Filter
DC UB2
UB2
SMD fuses on PCB
Glass tube fuses in front panel
Terminal blocks and circuit breakers
BOV 1 Power distribution plug-in unit
Cabinet
Protection area of the fuse at the plug-in unit level
UB1
UB1
-UB1
-UB1
Protection area of the glass tube fuse at the subrack level
Backplane
Plug-in unit
Subrack
dn02180104
Figure 66
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General power distribution principle for RNC
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B 0V B 0V
ENABLE = INPUT CIRCUIT
UO 1 GND
= ON/OFF
UB 1 UB 2
DC/DC CONVERTER STRUCTURE IN A PLUG-IN UNIT
ENABLE =
UO 2 GND
= ON/OFF POWER CONTROL FROM HMS NODE
ALARM TO HMS NODE
ALARM CIRCUIT
dn02179535
Figure 67
DC/DC converter structure in a plug-in unit
For information on power consumption, see Installation Site Requirements for MGW and RNC.
8.6
EHU, External Hardware Alarm Unit Purpose:
The purpose of the External Hardware Alarm Unit is to receive external alarms and send indications of them as messages via HMS to the external alarm handler located in OMU. Another function of EHU is to drive the optional External Hardware Alarm panel (EXAU-A / EXAU), the cabinet integrated lamp, and possible other external equipment.
Redundancy:
None
Plug-in unit:
EHAT External Hardware Alarm Terminal
Interfaces:
Interfaces include 32 voltage controlled inputs, 8 current controlled inputs, 16 general purpose 20 mA current outputs. Connections to external devices via CPSAL/-B back interface unit located at the rear of the RNAC cabinet or CPAL back interface unit in the cabling cabinet.
Location:
One unit per network element, in RNAC subrack 1.
EXAU-A / EXAU, External hardware alarm unit The optional peripheral EXAU-A / EXAU provides a visual alarm of the fault indications of RNC. The EXAU-A / EXAU unit is located in the equipment room. CAIND/-A, Cabinet alarm indicator The CAIND/-A is located on top of the RNAC cabinet and provides a visual alarm indicating the network element with a fault.
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9 Interfaces to the Environment RNC has the following interfaces to the network it is used in: • • • • •
• •
Power supply and grounding interfaces PDH/TDM trunk circuit interfaces (E1/T1/JT1) SDH/TDM trunk circuit interfaces (STM-1/OC-3) External synchronisation and HW alarm interfaces Ethernet/LAN interfaces to integrated OMS. As of RN5.0, the functional unit OMS can be selected between the current integrated OMS or an external standalone OMS network element. For RN5.0 new deliveries, the standalone OMS is recommended. Interfaces for peripheral devices (keyboard, mouse, VDU, printer, external storage device) Service terminal interfaces
There are two locations for making the connections: • •
Rear side of the cabinet (the back interface units) Front side of the cabinet (front panels of the plug-in units)
These connections are briefly described in the following sections. For more information, see Cabinet Interfaces and External Cables of MGW and RNC and Installation Site Requirements for the MGW and RNC..
g The cables leaving the network element are not included in the network element delivery.
9.1
Power Supply and Grounding Interfaces The interfaces for the power supply and grounding are located on the back panel of the CPD120-A / CPD80-B / CPD80-A / CPD80 cabinet power distribution units at the top of the cabinet. Each cabinet is equipped with two cabinet distribution units. The power supply cables can be routed from top or bottom of the cabinet regardless of the location of the unit. The requirements for the power supply and grounding cables are described in sections Site power supply and Grounding and bonding of the Installation Site Requirements. Installation alternatives for the power supply and grounding cables are described in section Installing the site power supply cables and grounding the network element in Installing the MGW and RNC.
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Interfaces to the Environment
B
-UB2 +UB2 -UB1
+UB1
A 2
2
DC/I DN05158732
(A) and (B): the two alternatives for connecting the grounding cable (2) The CPD120-A is grounded to the cabinet grounding busbar with a grounding strip. Figure 68
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Power supply interfaces of CPD120-A with DC/I principle
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-UB2 B0V -UB1
1
2
1
B0V
2
DC/C DN05160839
(1): Grounding strip between the +UB terminal connector on the CPD120-A on the top of the cabinet and the horizontal grounding busbar of the cabinet (2): The CPD120-A is grounded to the cabinet grounding busbar with a grounding strip. Figure 69
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Power supply interfaces of CPD120-A with DC/C principle
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Interfaces to the Environment
For optional ETS 300 253 +UB2 B0V grounding +UB1
CPD80-B 1 -UB2 +UB2
-UB1 +UB1 CPD80-B 0
CPD80-B 1 -UB2 +UB2
Figure 70
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DN02180143 -UB1 +UB1 CPD80-B 0 Power supply interfaces of CPD80-B with two connection alternatives and optional ETS grounding
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DC/I
DC/C +UB1
+UB0 -UB0 -UB1
+UB0 -UB0
+UB1 -UB1
DN01154291
REAR SIDE
Figure 71
9.2
REAR SIDE
Power supply interfaces of CPD80-A and their connection alternatives: DC/I and DC/C principle
PDH TDM Interfaces The network element's PDH connections from the NIP1 units are made via BIE1C / BIE1T connector panels at the rear side of the cabinets. The BIE1C / BIE1T connector panels are located directly behind the NIP1 units that they serve. It is possible to cable the back interface units directly into the environment or, alternatively, the cables can be routed through the cabling cabinet panels. The numbers of the PDH/TDM lines and the plug-in unit connectors they connect to are listed in the Cable Lists for RNC. The PDH and TDM circuit cables are usually cut and connected at the installation site, but they can also be prepared at the factory. Cables with one connector are usually prepared at the site.
9.3
SDH TDM Interfaces The connectors for the STM-1/OC-3 cables are located on the front panels of the NIS1 or NP8S1-B plug-in units. The STM-1/OC-3 connections are routed to the BISFC panel. The BISFC panel is located at the backside of the RNAC cabinet. The use of the BISFC panel is optional. It is possible to route the STM-1 cables to the environment directly from the front panels of the NIS1 or NP8S1-B units or from the BISFC panel.
9.4
External Synchronisation Interfaces The synchronisation interfaces are located on the TSS3/-A plug-in unit. The connections can be routed through the external synchronisation connector panel CPSY-A (TSS3/-A 0), CPSY-B (TSS3/-A 1), or CPSAL-B / CPSAL depending on the configuration. The back interface units CPSY-A, CPSY-B and CPSAL-B are located at the rear side of the RNAC cabinet. RNC's external synchronisation interfaces support 2.048 Mbit/s and 2.048 MHz connections.
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9.5
Interfaces to the Environment
External HW Alarm Interfaces The external hardware alarms interfaces are located on the EHAT plug-in unit. The connections can be routed through the alarms connector panel or unit CPAL-A or CPSALB / CPSAL depending on the configuration. The CPAL-A and CPSAL/-B units are located at the rear side of the RNAC cabinet. The units also have EXAU-A / EXAU panel control.
9.6
Ethernet/LAN Interfaces The external LAN/Ethernet connections are routed directly out of the plug-in unit front panel connectors. The connectors for RNC's Ethernet/LAN interfaces to the NetAct, site LAN, and other destinations, for example, to printers, are placed on both the front panels and back interface units of the ESA24 plug-in unit, whereas ESA12 has connectors only on the front panel. The connection to OMS is protected by the MCP18-B's firewall. The ESA24 has 24 LAN interfaces of which 22 are at the backplane connectors and 2 on the front panel (RJ45 connectors). There is also one additional serial port on the front panel (RJ45 connector). The ESA12 has 12 LAN interfaces, up to nine of which can be used for connections to the environment.
g A cabinet is configured with either the ESA24 or ESA12. Although AL2S-D / AL2S-B, CCP18-C / CCP18-A / CCP10, CDSP-DH / CDSP-C, MX1G6-A / MX1G6, MX622-D / MX622-C / MX622-B, NI4S1-B, and SF10E / SF10 units include a LAN interface, they are provided for test use only.
9.7
Mouse, Keyboard, VDU, SCSI and Printer Interfaces The MCP18-B plug-in unit has separate interfaces for a VDU and external storage devices. It also has four USB ports that can be used to connect a keyboard, mouse or a bootable device to the MCP18-B. USB-PS/2 adapters are not supported. The form and pin-out of the SVGA and USB interfaces follow standard industry practises. The MCP18-B's SCSI interface's pin-out follows the industry standard for Wide Ultra3 SCSI. The SCSI bus is terminated by means of an active onboard terminator in MCP18-B.
9.8
RS232 Service Terminal Interfaces RNC's service terminal interfaces are intended to be used for temporary service operations, for example, debugging. For more information, see section Functional unit descriptions.
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