RF Measurement Quantities Slide 1
NokiaEDU RF Measurement Quantities LTE Optimization Principles [FL16A] Module 01
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© Nokia 2016
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RF Measurement Quantities Slide 2
Copyright and confidentiality
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© Nokia 2016
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RF Measurement Quantities Slide 4
Module Objectives • After completing this module, you will be able to:
• Describe the most relevant quantities: RSRP, RSRQ, RSSI, SINR • Explain the definitions of the measurement quantities and their value ranges
• Give an overview of interdependencies of the different measurement quantities • Revise the meaning of measured values in terms of network performance • Discuss related practical issues and their impact on network analysis
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RF Measurement Quantities Slide 5
Course pre requisites • Before taking this course it is expected that the students have attended: or have an equal level of knowledge and experience of the following;
• • • • •
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Confidential
TM5117: LTE Air Interface RA4120: LTE Radio Planning RA4123: LTE Signaling RA4121: LTE Parameters RA4133: LTE Counters and KPI
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RF Measurement Quantities Slide 6
Index • RSRP: Reference Signal Received Power
• RSSI: Received Signal Strength Indicator • RSRQ: Reference Signal Received Quality • SINR, CINR, SNR
• Definition and measurement • Mapping RSRP / RSRQ to SINR • MIMO variants of the RF quantities and use cases
• 3GPP defined measurement accuracy for UEs
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RF Measurement Quantities Slide 7
Reference Signal from 3-Sector 2x2 MIMO Cells
R1
R0
R0
R1
R1
R1
R0
R1
R0
R1
R0
R0
R1
R0
R1
R1
R0
R1
R0
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R1
R0
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R1
R0
R1
R0
R0
R1
R0
R1
R1
R1
R0
R0
Slot (0.5 ms)
R1
R0
R0
R0
Cell#3 (PCI 11)
Cell#2 (PCI 10)
Cell#1 (PCI 9)
R1
Slot (0.5 ms)
Slot (0.5 ms)
Subframe
Slot (0.5 ms)
Slot (0.5 ms)
Slot (0.5 ms)
Subframe
Subframe
R0: RS of antenna port 0 R1: RS of antenna port 1
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• RS frequency shift based on PCI modulo-3
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RF Measurement Quantities Slide 8
Reference Signal from 3-Sector 2x2 MIMO Cells -RS as seen by UE from cells of a 3-sector FDD site -no RS-RS interference since PCImod3 are different R1 R1 R1 R0 R0 R0 R1 R1 R1 R0 R0 R0
R0 R0 R0 R1 R1 R1 R0 R0 R0 R1 R1 R1
R1 R1 R1 R0 R0 R0 R1 R1 R1 R0 R0 R0
Slot (0.5 ms)
R0 R0 R0 R1 R1 R1 R0 R0 R0 R1 R1 R1
Slot (0.5 ms)
Subframe
Sector 1: red Sector 2: green Sector 3: blue
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R0: RS of antenna port 0 R1: RS of antenna port 1
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• Same-site cells are frame-synchronized in FDD. In TDD all cells are frame-
synchronized.
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RF Measurement Quantities Slide 9
Reference Signal from 3-Sector 4x2/4x4 MIMO Cells
R1 R3
R0 R2
R1 R3
R0 R2
R0
R1 R3
R1
R0 R2
R0
R1 R3
R1
R0 R2
Slot (0.5 ms)
Cell#3 (PCI 11)
Cell#2 (PCI 10)
Cell#1 (PCI 9)
R1 R3
R0
R1 R3
R0
R0 R2
R1
R0 R2
R1
R1 R3
R0
R1 R3
R0
R0 R2
R1
R0 R2
R1
R1 R3
R0
R1 R3
R0
R0 R2
R1
R0 R2
R1
R1 R3
R0
R1 R3
R0
R0 R2
R1
R0 R2
R1
R0
R1
R0
R1
Slot (0.5 ms)
Slot (0.5 ms)
Subframe
Slot (0.5 ms)
Slot (0.5 ms)
Slot (0.5 ms)
Subframe
Subframe
R0: RS of antenna R1: RS of antenna R2: RS of antenna R3: RS of antenna
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port 0 port 1 port 2 port 3
© Nokia 2016
• RS frequency shift based on PCI modulo-3
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RF Measurement Quantities Slide 10
Reference signals for TM9 For use in SU 4x4 MIMO and Liquid Cell
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CRS
UL feedback
MCS PMI Rank
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1 2 3 4 5
CRS DM-RS CSI-RS PDCCH PDSCH
24 24 4 8 108
TM9 4 layers 4x4 MIMO
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CQI PMI Rank
DL feedback
CSI-RS
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1
DL feedback
TM4 4 layers 4x4 MIMO
CRS
1
0
CQI PMI* Rank
24 8 136
DM-RS
0 1
CRS PDCCH PDSCH
UL feedback
• PDSCH channel estimation based on demodulation reference signals (DM-RS) – ports 7..14 (up to 8 layers) • CQI report based on Channel State Information Reference Signals (CSI-RS) – ports 15..22 • Closed loop precoding based on CSI-RS, reported by PMI • CSI-RS is configured to each Rel10 UE via RRC reconfiguration
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© Nokia 2016
CSI-RS based feedback: • • • • • • •
CSI-RS introduced to give better indication of PDSCH interference, Cell specific RS suffers from inter cell interference from control channels and other Cell specific RS Channel can be estimated between all eNB-UE antenna pairs No limit on how many UEs can use CSI-RS based channel estimate, regardless of CSI-RS periodicity No impact on UE battery consumption Relatively low and configurable periodicity of CSI-RS subframe Also CSI-RS subframe offset is configurable Helps to avoid CSI-RS collisions in low loaded networks
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RF Measurement Quantities Slide 11
RSRP - RSRP is the linear average of received power of RS resource elements
- UE measures the rx power of multiple RS REs and takes average of them - Reporting range -44…-140 dBm Definition
• R0: tx antenna 1 R1: tx antenna 2
Reference signal received power (RSRP), is defined as the linear average over the power contributions (in [W]) of the resource elements that carry cell-specific reference signals within the considered measurement frequency bandwidth. For RSRP determination the cell-specific reference signals R0 according TS 36.211 [3] shall be used. If the UE can reliably detect that R1 is available it may use R1 in addition to R0 to determine RSRP. The reference point for the RSRP shall be the antenna connector of the UE.
Applicable for
If receiver diversity is in use by the UE, the reported value shall not be lower than the corresponding RSRP of any of the individual diversity branches. RRC_IDLE intra-frequency, RRC_IDLE inter-frequency, RRC_CONNECTED intra-frequency, RRC_CONNECTED inter-frequency
Note1: The number of resource elements within the considered measurement frequency bandwidth and within the measurement period that are used by the UE to determine RSRP is left up to the UE implementation with the limitation that corresponding measurement accuracy requirements have to be fulfilled. Note 2: The power per resource element is determined from the energy received during the useful part of the symbol, excluding the CP.
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Definition in 3GPP TS 36.214
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RF Measurement Quantities Slide 12
RSRP Mapping - The reporting range of RSRP is defined from -140 dBm to -44 dBm with 1 dB resolution - The mapping of measured quantity is defined in the table below:
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Reported value
Measured quantity value
Unit
RSRP_00
RSRP -140
dBm
RSRP_01
-140 RSRP < -139
dBm
RSRP_02
-139 RSRP < -138
dBm
…
…
…
RSRP_95
-46 RSRP < -45
dBm
RSRP_96
-45 RSRP < -44
dBm
RSRP_97
-44 RSRP
dBm
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3GPP TS 36.133 V8.9.0 (2010-03)
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RF Measurement Quantities Slide 13
RSRP Measurement Using Different Devices •
Comparison of Samsung UE and R&S TMSW / PCTel EX scanners – UE inside car and scanners using the same antenna mounted on car roof RSRP measurement, idle cell and fully loaded cell -65 1
31
61
91
121
151
181
211
241
271
301
331
361
391
RSRP [dBm]
-70
-75
2-3dB difference in measured RSRP
-80
PCTel RSRP R&S RSRP UE RSRP
-85
-90
UE starts downloading
time, seconds
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Samsung UE inside car, R&S and PCTel scanners in the same antenna via power splitter on the car roof. Identical antenna line loss for the scanners.
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RF Measurement Quantities Slide 14
RSRP vs CPICH RSCP •
Below a measurement of 2.1GHz CPICH RSCP versus 1.8GHz/20MHz RSRP using a multi-RAT multi-band scanner.
•
Should RSRP be scaled somehow to make it comparable to RSCP?
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PCTEL MX measurement simultaneously at 2.1GHz and 1.8GHz RSRP = RS tx power per subcarrier per tx antenna – path loss + antenna gains CPICH RSCP = CPICH tx power – path loss + antenna gain
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RF Measurement Quantities Slide 15
Quiz: RSRP vs CPICH RSCP •
Below a measurement of 2.1GHz CPICH RSCP versus 1.8GHz/20MHz RSRP using a multi-RAT multi-band scanner.
• •
Should RSRP be scaled somehow to make it comparable to RSCP? Which one (WCDMA or LTE) is having higher link loss? Assume:
• • •
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40W Tx power for both systems. 10% CPICH power for WCDMA 20MHz bandwidth for LTE
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40w ¨46dBm 1200 ¨30.8dB 200 ¨23dB 2/7 ¨-5.4dB
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RF Measurement Quantities Slide 16
Index • RSRP: Reference Signal Received Power
• RSSI: Received Signal Strength Indicator • RSRQ: Reference Signal Received Quality • SINR, CINR, SNR
• Definition and measurement • Mapping RSRP / RSRQ to SINR • MIMO variants of the RF quantities and use cases
• 3GPP defined measurement accuracy for UEs
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RF Measurement Quantities Slide 17
RSSI - RSSI is internal to UE, not reported in uplink to eNB
- RSSI measures all power within the measurement bandwidth • hence it includes thermal noise, interference and serving cell power
R0
R1
R0
R0
R1
R0
R1
R1
R0
R1
R0
R0
R1
R0
R1
OFDM symbol containing R0 17
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Time
R1
Freq
- Measured over those OFDM symbols that contain RS for antenna port R 0
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RF Measurement Quantities Slide 18
Relation between RSSI and RSRP - RSSI = wideband power= noise + serving cell power + interference power - Without noise and interference, 100% DL PRB activity:
RSSI=12*N*RSRP Where: – N is number of PRBs across the RSSI is measured and depends on the BW - Based on the above, under 100% PRB utilization and high SNR:
RSRP (dBm)= RSSI (dBm) -10*log (12*N)
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Converting RSSI=12xNxRSRP to logarithmic domain, RSSI (dBm) = 10log(12xN) + RSRP(dBm) RSRP (dBm) = RSSI (dBm) – 10 log(12xN)
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RF Measurement Quantities Slide 19
Relation between RSSI and RSRP Field Measurement in Fully Loaded 10MHz Cell RSRP versus RSSI for fully loaded cell, 10MHz system bandwidth (100% of REs active)
-93
-88
-83
-78
-73
-68
-63
-58
-53
-48 -75
RSRP [dBm]
-85
-95
-105
Measurement: slope ~28 dB agrees with theory (27.8dB)
-115
-125 RSSI [dBm]
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Samsung BT-3710 + XCAL
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RF Measurement Quantities Slide 20
Relation of RSSI and RSRP Impact in Cell Load -40 1
60 6
11
16
21
26
31
36
-50
- RSRP is independent of cell load
-60
40
SCell-RSSI(Com) SCell-RSRP(Com)
-70
RSSI increases about 5-6dB
-80
-90
RSRP independent of cell load
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Number of RBs
RB Num(DL) Power, dBm
- RSSI increases about 5dB when PRB activity increases to 100%,10MHz cell
50
20
10
UE starts downloading -100
0 Time, seconds
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RF Measurement Quantities Slide 21
Index • RSRP: Reference Signal Received Power
• RSSI: Received Signal Strength Indicator • RSRQ: Reference Signal Received Quality • SINR, CINR, SNR
• Definition and measurement • Mapping RSRP / RSRQ to SINR • MIMO variants of the RF quantities and use cases
• 3GPP defined measurement accuracy for UEs
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RF Measurement Quantities Slide 22
RSRQ RSRQ = N x RSRP / RSSI Where: • RSSI is pure wide band power measurement, including serving cell power, interference and thermal noise • N: RSSI measurement bandwidth in PRBs
R0: tx antenna 1 R1: tx antenna 2
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3GPP TS 36.214
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RF Measurement Quantities Slide 23
RSRQ Mapping - RSRQ reporting range -3…-19.5dB - (Some devices report values < -20dB)
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Reported value
Measured quantity value
Unit
RSRQ_00
RSRQ -19.5
dB
RSRQ_01
-19.5 RSRQ < -19
dB
RSRQ_02
-19 RSRQ < -18.5
dB
…
…
…
RSRQ_32
-4 RSRQ < -3.5
dB
RSRQ_33
-3.5 RSRQ < -3
dB
RSRQ_34
-3 RSRQ
dB
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3GPP TS 36.133 V8.9.0 (2010-03)
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RF Measurement Quantities Slide 24
RSRQ Theoretical Values in Idle and Fully Loaded Cell RSRQ = N x RSRP / RSSI, N = measured bandwidth in PRBs • Idle cell: When there is no traffic, and assuming only the reference symbols are
transmitted (there are 2 of them within the same symbol of a resource block) from a single Tx antenna then the RSSI is generated by only the 2 reference symbols so the result becomes: – RSRQ = -3 dB for 1Tx
– RSRQ = -6dB for 2Tx - Fully loaded cell: Cell with 100% PRB utilization If all resource elements are active and are transmitted with equal power then – RSRQ = -10.8 dB for 1Tx – RSRQ = -13 dB for 2Tx
In practice, UEs seem to report RSRQ ~neg11dB for fully loaded cell, assuming no other-cell interference
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RF Measurement Quantities Slide 25
RSRQ/SNR/RSRP Measurement, 2Tx cell - Only serving cell on-air, FDD ZTE (QC)
Idle cell RSRQ= neg6dB UE starts downloading
SNR drops but RSRP not
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RF Measurement Quantities Slide 26
RSRQ Measurement Using Different Devices •
Comparison of Samsung UE and TMSW / PCTel EX scanners – UE inside car, scanners on car roof using the same antenna RSRQ measurement, idle cell and fully loaded cell 0 -2
1
31
61
91
121
151
181
211
241
271
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331
361
391
RSRQ [dB]
-4 -6 -8 -10 -12 -14
PCTel RSRQ R&S RSRQ UE RSRQ
-16 -18 -20
UE starts downloading
Measured RSRQ depends on device
time, seconds
NOTE: R&S RSRQ independent of cell load!!
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Samsung UE inside car, R&S and PCTel scanners in the same antenna via power splitter on the car roof. Identical antenna line loss for the scanners.
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RF Measurement Quantities Slide 27
Index • RSRP: Reference Signal Received Power
• RSSI: Received Signal Strength Indicator • RSRQ: Reference Signal Received Quality • SINR, CINR, SNR
• Definition and measurement • Mapping RSRP / RSRQ to SINR • MIMO variants of the RF quantities and use cases
• 3GPP defined measurement accuracy for UEs
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RF Measurement Quantities Slide 28
SINR / SNR / CINR Definition and Measurement SINR = S / (I+N) • Usually SINR=SNR=CINR unless the receiver is able to separate interference from thermal noise • Example: IRC receiver can separate dominant interferer from noise • The actual measurement definition must be checked for every measurement device
-
which signal the ‘S’ measures?
-
what is the measurement bandwidth?
-
is the measured SNR instantaneous or average value?
-
if the average SNR is measured, what is the number of samples averaged? Typically UEs measure SNR from RS
• • •
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Exact measurement method uncertain, since UE chipset vendors don’t typically reveal technical data Scanners measure SNR from PSS/SSS and/or RS
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RF Measurement Quantities Slide 29
SINR Measurement Using Different Devices •
Comparison of Samsung UE and TMSW / PCTel Ex scanners SINR measurement, idle cell and fully loaded cell 80
DL starts, PRB utilization to100%
SINR dBm / throughput Mbps
70
60
PCTel SSS SINR
50
PCTel RS SINR R&S SSS SINR UE SINR
40
DL Throughput 30 20 10 0 1
31
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91
121
151
Secondary Sync Signal SNR much worse than RS SNR 29
181
211
241
271
301
331
361
391
time, seconds
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Sync signal SNR suffers from neigbour sector interference from the same site.
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RF Measurement Quantities Slide 30
RS CINR and RSRP Measured by FDD Scanner •Q: What would CINR be if network was fully loaded? Can RS CINR be used
for dominance analysis?
RS CINR
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What would be the CINR at the marker position if all cells were fully loaded?
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RF Measurement Quantities Slide 31
Index • RSRP: Reference Signal Received Power
• RSSI: Received Signal Strength Indicator • RSRQ: Reference Signal Received Quality • SINR, CINR, SNR
• Definition and measurement • Mapping RSRP / RSRQ to SINR • MIMO variants of the RF quantities and use cases
• 3GPP defined measurement accuracy for UEs
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RF Measurement Quantities Slide 32
Mapping RSRP to SNR Motivation: Sometimes might be useful to be able to map RSRP to SNR
•
•
Assuming only thermal noise, RSRP can be mapped approximately to SNR
•
In practical field conditions, this does not seem to work very well:
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–
Insufficient averaging for fading signal by measurement equipment
–
Tx signal nonlinearities cause EVM that saturates measured SNR to ~25-30dB.
–
Receiver non-idealities, such as carrier frequency offset, Doppler spread, oscillator, phase noise etc also saturate SNR
–
Interference
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EVM= ERROR VECTOR MAGNITUDE
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RF Measurement Quantities Slide 33
Mapping RSRP to SNR Samsung XCAL measurement in lab, non-fading channel •Lab measurement in shielded box, UE-reported RSRP versus UE-reported SINR
In 100% loaded cell reported SINR saturates, probably due to subcarrier leakage or other imperfections.
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Samsung BT-3710 + XCAL
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RF Measurement Quantities Slide 34
Mapping RSRP to SNR XCAL field measurement, fading channel • Fading channel measurement, drive test. SINR versus RSRP, measurement
-7
-2
3
8
13
18
23
-75
RSRP [dBm]
-85
Samsung UE measurement values are instantaneous snapshots high variance due to fading.
-95
-105
-115
-125 SINR [dB]
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Samsung BT-3710 + XCAL
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RF Measurement Quantities Slide 35
Mapping RSRQ to SINR Theory (1/2) -
RSRQ depends on own cell traffic load, but SINR doesn’t depend on own cell load.
•
Used Resource Elements per Resource Block (RE/RB) in serving cell is an input parameter for RSRQ -> SINR mapping
•
Assumption: RSRP doesn’t contain noise power
SINR
RSRP *12 N Pi Pn _ 12 N
Pn _ xN Pn _ RE xN x RE / RB _ used N # RBs RSSI Pi RSRP * xN Pn _ 12 N RSRQ
N * RSRP RSSI
SINR
35
RSRP *12 N 12 N * RSRP 1 RSRP * xN x RSRQ RSRQ
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Noise + interference power as function of RSSI and RSRP RSSI as function of RSRQ
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RF Measurement Quantities Slide 36
Mapping RSRQ to SINR Theory (2/2)
RSRQ vs SINR 30.00
- Equation used:
25.00
12 1 x RSRQ
20.00
2 RE/RB
15.00
SINR (dB)
SINR
4 RE/RB 6 RE/RB
10.00
8 RE/RB 10 RE/RB
5.00
Where x=RE/RB
12 RE/RB
0.00 -20
-19
-18
-17
-16
-15
-14
-13
-12
-11
-10
-9
-8
-7
-6
-5
-4
-3
-5.00
- 2RE/RB equals to empty cell. Only Reference Signal power is considered from serving cell.
-10.00 RSRQ (dB)
RSRP vs. SNR 40.00
- 12RE/RB equals to fully loaded serving cell. All resource elements are carrying data.
• Currently available measurement UEs and scanners report SINR directly
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SNR (dB)
- In practice, mapping from RSRQ to SINR seems difficult
35.00
15.00 SNR 10.00 5.00 0.00 -135
-130
-125
-120
-115
-110
-105
-100
-95
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-5.00 -10.00 -15.00 RSRP (dBm )
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Idle cell: SINR = 12/(2-2)=infinite
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RF Measurement Quantities Slide 37
Mapping RSRQ to SINR Lab Measurements
SINR vs. RSRQ
- Lab measurements match well the calculated results
35 30 25
- Measured with Agilent scanner
20
SINR
• RSRP
• RSRQ
15 10 5
• Reference signal SINR
0 -5
- Cable connection between BTS and scanner
-20 -19 -18 -17 -16 -15 -14 -13 -12 -11 -10
-9
-8
-7
-6
-5
-4
-3
-2
-1
0
-10
• Attenuator used to reduce signal level
RSRQ Measured - full traffic
• No traffic: only control channels and reference signals
Caculated - no traffic
Calculated - full traffic load
Measured - no traffic
SNR vs. RSRP
• Full traffic load: data send in each RB
40 35 30 25
SNR
20 Measured-full traffic
15
Calculated
10
Measured - no traffic
5 0 -140 -135 -130 -125 -120 -115 -110 -105 -100 -5
-95
-90
-85
-80
-10 -15 RSRP
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Terminals do not report SINR but only RSRQ and RSRP. Note: Validity of formula have been proven in lab under above conditions and with only one cell on air ( i.e. no other cell interference). Measurements from the field will differ as exact load can not be set
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RF Measurement Quantities Slide 38
Mapping RSRQ to SINR Field Measurement RSRQSINR mapping have high variance in field conditions.
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Terminals do not report SINR to eNB, only RSRQ and RSRP.
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RF Measurement Quantities Slide 39
Index • RSRP: Reference Signal Received Power
• RSSI: Received Signal Strength Indicator • RSRQ: Reference Signal Received Quality • SINR, CINR, SNR • Definition and measurement
• Mapping RSRP / RSRQ to SINR • MIMO variants of the RF quantities and use cases • 3GPP defined measurement accuracy for UEs
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RF Measurement Quantities Slide 40
MIMO Variants - Terminals and scanners may report RSRP, RSSI, RSRQ, SINR per receiver antenna - Example: RSRP
• RSRP0 measured at rx. antenna 0 • RSRP1 measured at rx. antenna 1 - Measurement capabilities should be checked case-by-case - Some devices measure even more MIMO quantities • Altair chipset measures four SINR values for a 2Tx BTS, one value per Tx-Rx pair
• Some scanners and the old LG chipset measures antenna correlation coefficient - Question: How can these multi-antenna measurements be used in practical field testing?
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RF Measurement Quantities Slide 41
Use cases for multi-antenna RF quantities - MIMO throughput is degraded by: • Too large power imbalance between receiver branches
• Too large power imbalance between Tx branches • High Tx/Rx antenna correlation - In practice, only power imbalance can be measured by commercial devices
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RF Measurement Quantities Slide 42
Rx Antenna Power Imbalance Field Measurement - Note RSSI power imbalance between receive antenna branches • This should be eliminated, if possible 02/18/2010 14:13:33.716
-45 02/18/2010 14:15:16.143 -50
02/18/2010 14:16:58.647
02/18/2010 14:18:40.153
02/18/2010 14:20:22.159
02/18/2010 14:22:03.167
-55
-60
RSSI [dBm]
-65 Data Average of SCell-RSSI(Com) Average of RSSI(Ant0) Average of RSSI(Ant1)
-70
-75
-80
-85
-90
-95 time Time
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RF Measurement Quantities Slide 43
Rx Antenna Power Imbalance: Impact On Rank Field Measurement - Too large antenna power imbalance can reduce channel rank tx falls to single stream even at high SNR -65
RSSI0 RSSI1
-70 -75 Rx power imbalance
-80 -85 -90
50
100
150
200
250
300
350
400
450
500
550
seconds Rank fluctuation at high RSSI (SNR)
Rx power imbalance dB
10 5
Rank indicator, {0,1}
0 -5
50
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250
300
350
400
450
500
550
seconds 43
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If antenna power imbalance is large, second branch is effectively removed. In field tests, it’s difficult to tell whether rank reduction is caused by power imbalance or channel correlation, since often these happen simultaneously (e.g. line-of-sight).
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RF Measurement Quantities Slide 44
Channel Correlation - High channel correlation degrades multi-stream throughput performance – Even high SNR won’t improve throughput if channel correlation is too high
- Typical problem case: Two vertical antennas on car roof SNR is excellent but MIMO throughput is bad – Solution: use cross-polarized antennas, or take antennas inside car!
- Problem: Channel correlation is not usually reported by DT tools or scanners
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RF Measurement Quantities Slide 45
Channel Correlation, Drive Test Example - The same dt route driven twice, 2.6GHz@10MHz, Huawei E398, tm3 • vertical: two vertical scanner antennas mounted on car roof, mean tput = 29Mbps
• x-pol: custom-made cross-polarized omni antenna on car roof, mean tput = 33Mbps x-pol versus two vertical
1 0.9 0.8
0.6
CDF
x-pol vertical
x-pol has better peak tput
0.7
0.5 0.4 0.3
Vertical has better tput in bad RF
0.2 0.1 0
45
0
10
20
30 40 MAC DL tput, Mbps
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In the test, x-pol had 5dB worse total gain due to attenuation in the RF feeder network. Regardless, xpol gives higher peak tput.
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RF Measurement Quantities Slide 46
Impact of Channel Correlation on MIMO Tput Measurement Example, SINR=25dB - SINR=25dB, constant over the measurement
- High spatial correlation causes rank-1 transmission even at very high SNR!! (second stream tput goes to almost zero) PHY tput for substreams, EPA 3km/h, 2.6GHz, 3GPP low, medium, high correlation 90 stream 1 stream 2 stream 1 + stream 2
80 70
PHY tput [Mbits/sec]
60
low spatial correlation
High spatial correlation
50 40 30 20
medium spatial correlation
10 0 50
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3GPP high, medium, low, medium, high. SNR=25dB (set in fading simulator)
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RF Measurement Quantities Slide 47
Impact of UE Orientation Measurement in Excellent RF PHY tput [Mbps], CINR [dB]
100
80
60
PHY DL Throughput [Mbps] CINR 0 [dB] CINR 1 [dB]
40
20
1 19 37 55 73 91 109 127 145 163 181 199 217 235 253 271 289 307 325 343 361 379 397 415 433 451 469 487 505 523 541 559 577 595 613 631 649 667
0
UE orientation changes
Time
1 19 37 55 73 91 109 127 145 163 181 199 217 235 253 271 289 307 325 343 361 379 397 415 433 451 469 487 505 523 541 559 577 595 613 631 649 667
-55
-60
RSRP [dBm]
Main message 1: MIMO throughput is very sensitive to UE orientation!
-65
-70
-75
-80
-85
47
Main message 2: Eliminating power imbalance or channel correlation alone is not sufficient for good MIMO throughput. Both should be eliminated! In practice, this is a trial and error process in stationary measurements.
Antenna0 RSRP [dBm] Antenna1 RSRP [dBm]
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MIMO throughput impacted by SINR, power imbalance and channel correlation. These almost impossible to control in field conditions.
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RF Measurement Quantities Slide 48
LTE Tx antenna imbalance impact on throughput. Also imbalance in Tx branch power impacts on MIMO performance. - Improper antenna connector or feeder installation. - Asymmetric indoor installation.
Indoor testing results: • 6dB difference -> average 5.51 Mb/s (11%) lower throughput. • 10dB difference -> average 9.94 Mb/s (20%) lower throughput. • 13dB difference -> average 14.33 Mb/s (29%) lower throughput.
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RF Measurement Quantities Slide 49
Index • RSRP: Reference Signal Received Power
• RSSI: Received Signal Strength Indicator • RSRQ: Reference Signal Received Quality • SINR, CINR, SNR
• Definition and measurement • Mapping RSRP / RSRQ to SINR • MIMO variants of the RF quantities and use cases
• 3GPP defined measurement accuracy for UEs
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RF Measurement Quantities Slide 50
Measurement Accuracy Requirement: RSRP 3GPP TS 36.133 (simplified) • RSRP absolute accuracy
under normal conditions
• ± 6dB intra-frequency and inter-frequency
• Needed for setting random access pre-amble tx power and triggering coverage-based handover (A5) - RSRP relative accuracy between two cells under normal conditions • ± 2dB intra-frequency • ± 6dB inter-frequency
• For triggering better cell handover (A3)
• RSRP reporting range in signaling (handovers):
50
Reported value
Measured quantity value
Unit
RSRP_00
RSRP -140
dBm
RSRP_01
-140 RSRP < -139
dBm
RSRP_02
-139 RSRP < -138
dBm
…
…
…
RSRP_95
-46 RSRP < -45
dBm
RSRP_96
-45 RSRP < -44
dBm
RSRP_97
-44 RSRP
dBm
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RF Measurement Quantities Slide 51
Measurement Accuracy Requirement: RSRQ 3GPP TS 36.133 (simplified) - RSRQ absolute accuracy under normal conditions • ± 2.5dB intra-frequency and inter-frequency
- RSRQ relative accuracy between two cells under normal conditions • ± 3dB inter-frequency (intra-frequency not defined) - RSRQ reporting range in RRC signaling (handovers) Reported value
51
Measured quantity value
Unit
RSRQ_00
RSRQ -19.5
dB
RSRQ_01
-19.5 RSRQ < -19
dB
RSRQ_02
-19 RSRQ < -18.5
dB
…
…
…
RSRQ_32
-4 RSRQ < -3.5
dB
RSRQ_33
-3.5 RSRQ < -3
dB
RSRQ_34
-3 RSRQ
dB
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RF Measurement Quantities Slide 52
NokiaEDU
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