Lte High capacity event parameters

Lte High capacity event parameters Prepared By: RAJESH KUMAR

Focus areas • LTE High Capacity Focus Areas • Control Channel Dimensioning • PUCCH Resources • PDCCH Resources • UL Noise Rise • PRB Utilization / Cell Throughput Capacity • MP Load • RRC Connection Setup Intensity • Due to UE releases by Inactivity • Due to UE releases by RLC Supervision • Incoming Handover Intensity • Hardware expansion • Connected Users License • Summary of High Capacity Parameter Settings

Control channel resources • UL Control Channel Resources • PUCCH • nRB,PUCCH depends on number of SR and CQI resources  Focus Area for High Capacity Parameters • PRACH • nRB,PRACH in 1 radio frame is independent of bandwidth and is fixed for different cell range • DL Control Channel Resources • PDCCH • nRE,PDCCH depends on CFI  Focus Area for High Capacity Parameters • PCFICH • nRE,PCFICH in 1 radio frame is 160, independent of bandwidth and # of antenna ports • PHICH • nRE,PHICH in 1 radio frame depends on bandwidth and is fixed for different bandwidth • PBCH • nRE,PBCH in 1 radio frame is 240, independent of bandwidth and # of antenna ports

Pucch resourcesintro • PUCCH is used for transmitting • SR, HARQ ACK/NACK (PUCCH Format 1) • CQI, RI (PUCCH Format 2) • UE is allocated SR and CQI resources during setup procedure, and the resources are kept as long as UE is UL synchronized. • UE is not allowed to connect to a cell if there’s no free SR resources • noOfPucchSrUsers and noOfPucchCqiUsers determine number of resources for SR and CQI per cell • PUCCH is allocated by • 2 RB at the band edges (RB-pair) • Time domain sharing, each PUCCH is assigned to a UE with a periodicity deciding which sub-frame UE can access PUCCH (default periodicity for CQI is 80ms, SR is 10ms) • Current setting • noOfPucchSrUsers, noOfPucchCqiUsers = 320

Pucch resourceshighest pucch resources for sr & CQI TSR = 10ms (SR periodicity) nSF,PUCCH = 10 (# sub-frames for PUCCH) ncap = 4 (CQI resources/RB pair) TCQI = 80ms (CQI periodicity) • 1st attempt (nRB,format1 = nRB,format2 = 4) nSR,res = (36*4-44)*10*10/10 = 1000 (>810) nCQI,res = 4*4*80*10/10 = 1280 (>880) • 3rd attempt (nRB,format1 = 6, nRB,format2 = 2) nSR,res= (36*6-44)*10*10/10 = 1720 (>810) nCQI,res = 2*4*80*10/10 = 640 (<880) • 2nd attempt (nRB,format1 = 5, nRB,format2 = 3) nSR,res= (36*5-44)*10*10/10 = 1360 (>810) nCQI,res = 3*4*80*10/10 = 960 (>880) noOfPucchSrUsers (limited by nCQI.res)=noOfPucchCqiUsers=640 This setting will reduce peak UL throughput

Pucch resourcesnumber of pucch rb-pairs • Recommended setting (noOfPucchSrUsers = noOfPucchCqiUsers = 640) nPUCCH,SR = [640/10 * 10/10] = 64 nRB,Format1 = [(64+44)/36] = 3 nRB,Format2 = [640/(4*80) * 10/10] = 2 nRB,PUCCH = 3 + 2 = 5 (even  6, < max RB pair per DU)  Odd number will leave 1 RB-pair unused by PUCCH and PUSCH • Current setting (noOfPucchSrUsers = noOfPucchCqiUsers = 320) nPUCCH,SR = [320/10 * 10/10] = 32 nRB,Format1 = [(32+44)/36] = 3 nRB,Format2 = [320/(4*80) * 10/10] = 1 nRB,PUCCH = 3 + 1 = 4

Pucch resourcesobservability • pmPucchSrCqiResCongCqi • The number of times a PUCCH allocation request for CQI resource(s) could not be granted • pmPucchSrCqiResCongSr • The number of times a PUCCH allocation request for SR resource(s) could not be granted

Pdcch resourcesadaptive pdcch (1/2) • PDCCH is used for • UL/DL scheduling assignments, e.g. PUSCH/PDSCH resource indication, transport format indication, HARQ info and PUCCH/PUSCH PC commands • Number of OFDM symbols available for PDCCH in a sub-frame is CFI. Max OFDM symbols, limited by pdcchCfiMode, is not exceeded • Recommended setting: • Bandwidth =< 10MHz : CFI_AUTO_MAXIMUM_3 (current setting), to handle peaks of PDCCH load • Bandwidth > 10MHz : CFI_AUTO_MAXIMUM_2, since higher number of symbols for PDCCH can increase RB pairs for PUCCH, which leads to reduced UL peak rate

Pdcch resourcesobservability • pmPdcchCceUtil • PDF of % of CCEs utilized compared with total CCEs available (at the maximum CFI permitted by pdcchCfiMode) each subframe, considering bandwidth and antenna configuration. • pmPdcchCfiUtil • PDF of number of subframes each CFI value was assigned

Ul noise risepzeronominalpucch, pzeronominalpusch • pZeroNominalPucch and pZeroNominalPusch can be used to adjust power control target, trade off between coverage and capacity • Current setting • pZeroNominalPucch = -117dBm • pZeroNominalPusch = -96dBm (should be reduced to default -103dBm to reduce UL interference peaks at high load)

Ul noise riseobservability • pmSinrPucchDistr • Distribution of the SINR values calculated for PUCCH • pmSinrPuschDistr • Distribution of the SINR values calculated for PUSCH • pmRadioRecInterferencePwr • The measured Noise and Interference Power on PUSCH, according to 36.214 of the SINR values calculated for PUSCH • pmRadioRecInterferencePwrPucch • The measured Noise and Interference Power on PUCCH, according to 36.214 • pmRadioTbsPwrRestricted • The number of Transport Blocks on MAC level scheduled in uplink where the UE was considered to be power limited. • pmRadioTbsPwrUnrestricted • The number of Transport Blocks on MAC level scheduled in uplink where the UE was NOT considered to be power limited.

Prb utilization / cell throughput capacityschedulingalgorithm • Current setting schedulingAlgorithm = 3 (PROPORTIONAL_FAIR_MEDIUM), propose to change to following at high load • 4 (PROPORTIONAL_FAIR_LOW) or • 5 (MAXIMUM_C_OVER_I) • Higher Cell Throughput • Higher TTI utilization • Higher PRB utilization • Performance comparison between different schedulers • Best cell throughput (from lowest to highest) • RR < ER < PFH < PFM < PFL < MCI • System fairness (from lowest to highest) • MCI < PFL < PFM < PFL < ER < RR For PFL or Max C/I, user at cell edge may have low throughput, as scheduler has higher weightage for RF condition System Fairness Cell Throughput

Prb utilization / cell throughput capacityobservability • Average Cell Throughput UL = pmUeThpVolUl/(pmSchedActivityCellUl/1000) • Average Cell Throughput DL = pmPdcpVolDlDrb/(pmSchedActivityCellDl/1000) • pmPrbUtilUl • A distribution that shows the uplink Physical Resource Block (PRB) pair utilization (total number of used PRB pairs by available PRB pairs) on the Physical Uplink Shared Channel (PUSCH) • pmPrbUtilDl • A distribution that shows the downlink Physical Resource Block (PRB) pair utilization (total number of used PRB pairs by available PRB pairs) on the Physical Downlink Shared Channel (PDSCH) • Average # Simultaneous Active UE UL = pmActiveUeUlSum/pmSchedActivityCellUl • Average # Simultaneous Active UE DL = pmActiveUeDlSum/pmSchedActivityCellDl

Mp loadmp load control mechanism (new in L13A) • Main contributors (signaling) for MP Load • RRC Connection Setups • Incoming Handovers • Paging Requests

Mp load1.1 RRC Connection setup intensity(due to UE releases by inactivity) • The time a UE can be inactive before it is released is controlled by tInactivityTimer • Current setting for tInactivityTimer is 10s, requirement from UE vendor • Recommend to change to 30s to reduce signaling load for high capacity cells • For tInactivityTimer set to 30s, • E-RAB drop rate will increase due to the E-RAB drops only consider the abnormal E-RAB Releases if there was data in buffer (i.e. active). • Number of UEs stay in RRC_Connected state will be larger, thus lowering the number of available Connected Users License for new users

Mp load1.2 RRC Connection setup intensity(due to UE releases by rLC Supervision) – cont’ • As part of Radio Connection Supervision, RLC failures are caused by • T310 expiry • Max RLC re-transmissions reached • T310 is controlled by • After receiving N310 consecutive “out-of-sync” indications, start timer T310 • After receiving N311 consecutive “in-sync” indications, stop timer T310 • After T310 expired  Radio Link Failure • Current settings: • N310 = 20 (recommended, no change) • N311 = 1 (recommended, no change) • T310 = 2s (recommended, no change)  UE is released after T310 (2s) + T311 (3s)

Mp load1.2 RRC Connection setup intensity(due to UE releases by rLC Supervision) • RLC re-transmissions are controlled by • Max # RLC re-transmissions before stopping and indicating to RRC max RLC re-tx reached • SRB/DRB :: dlMaxRetxThreshold (Current setting: 8/8, recommended, no change) • SRB/DRB :: ulMaxRetxThreshold (Current setting: 8/8, recommended, no change) • Poll timer for RLC re-Tx (if no status report received) • SRB/DRB :: tPollRetransmitDl (Current: 45ms/50ms, recommend 80ms/80ms) • SRB/DRB :: tPollRetransmitUl (Current: 45ms/50ms, recommend 80ms/80ms) Re-Tx count Increase Poll timer may reduce SE/TTI usage for re-Tx and free SE/TTI for traffic, but re-Tx time is extended from 360-400ms to 640ms (80ms x 8) #1 … #8 RLC Failure

Mp load2. incoming handovers intensity • Current setting for handover is • ReportConfigEUtraBestCell::a3offset = 3dB • ReportConfigEUtraBestCell:: hysteresisA3 = 1dB • ReportConfigEUtraBestCell:: timeToTriggerA3 = 40ms • Propose to change a3offset to 5dB (handover margin increased to 6dB) for high capacity cells to reduce signaling load. a3offsetAnrDelta remains unchanged Increase handover margin reduces handovers and may impact retainability Will review feasibility to use alternative approach on ‘UE Level Oscillating Handover Minimization’ feature

Mp load3. hardware expansion • MP capacity for DUS is higher than MP capacity on DUL

Mp loadobservability • pmProcessorLoad • The average CPU load on the whole MP system (all the CPU cores). • pmProcessorLoadDistr • A distribution of the CPU load of the MP corresponding to the definition of the CPU load used by MP Load Management. • This counter also includes CPU load consumption from execution on priorities below traffic priority. This includes CPU load from performance management and some O&M tasks. • pmPagS1Received • This counter counts the number of received S1AP paging messages in the RBS. • pmPagS1Discarded • The number of discarded S1AP paging messages not routed to any cell due to high load (MP Load Control). • pmRrcConnEstabFailHighLoad • The total number of failed RRC connection establishments due to high load (MP Load Control). • pmRrcConnEstabFailOverload • The total number of failed RRC connection establishments due to overload (Procedure Latency Supervision). • pmHoPrepRejInHighLoad • The number of Handover Preparation Failure messages sent by the target eNodeB due to high load (MP Load Ccontrol). • pmHoPrepRejInOverload • The number of Handover Preparation Failure messages sent by the target eNodeB due to overload (Procedure Latency Supervision).

Connected users license • Current Connected Users License is 800 per DUL • Connected Users license should be topped-up for high traffic sites on demand basis Increase Connected Users License may have impact on signaling load Connected Users License check is part of RRC Setup procedure

Connected usersobservability • pmRrcConnEstabFailLic • The total number of failed RRC Connection Establishments due to lack of connected users license

Summary of high cap parameters

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Lte High capacity event parameters

Lte High capacity event parameters

Presentation Transcript

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