ericsson 2g counters

Counter NameTRAFFDLGPRSSCAN

TBFDLGPRS

TBFDLEGPRS

DLBPDCH

DLGPDCH

DLEPDCH

DLTBFPBPDCH

DLTBFPGPDCH

DLTBFPEPDCH

DLACTBPDCH

DLACTGPDCH

DLACTEPDCH

DLACTTBFPBPDCH

DLACTTBFPGPDCH

DLACTTBFPEPDCH

STRBPDCH

STRGPDCH

STREPDCH

QOSWDLBASIC

QOSWDLGPRS

QOSWDLEGPRS

EPDCHGE

GETBFONPDCH

GNOETBFONPDCH

TRAFFULGPRSSCAN

TBFULGPRS

TBFULEGPRS

ULBPDCH

ULGPDCH

ULEPDCH

ULTBFPBPDCH

ULTBFPGPDCH

ULTBFPEPDCH

ULACTBPDCH

ULACTGPDCH

ULACTEPDCH

ULACTTBFPBPDCH

ULACTTBFPGPDCH

ULACTTBFPEPDCH

QOSWULBASIC

QOSWULGPRS

QOSWULEGPRS

TBFDCDLCAP

TRAFDCDLTBF

MAXDCTSDL

MUTILDCDL

TRAFEEVOSCAN

TSDCDL

AVAILRBLKS

USEDDLRBLKS

USEDULRBLKS

ALLPDCHACC

ALLPDCHACTACC

ALLPDCHPEAK

ALLPDCHSCAN

MUTILBASIC

TRAFGPRS2SCAN

TRAFF2BTBFSCAN

MAXGTSDL

MAXEGTSDL

MUTIL15

MUTIL14

MUTIL13

MUTIL12

TBFDLEGPRSCAP

MUTILBASICUL

TRAFGPRS3SCAN

BULTBFSCAN

MAXGTSUL

MAXEGTSUL

MUTIL14UL

MUTIL13UL

MUTIL12UL

TBFULGPRSCAP

TBFULEGPRSCAP

GSLMAX

GSLUTIL

GSLSCAN

GSL0040

GSL4160

GSL6180

GSL8190

GSL9100

AGW

AGWTRAF

AOIP

AOIPCAP

BSC

BSCAMSG

BSCMSLOT

BSCRFSUP

BSCSCCCL

LOADREG

PGW

PGWLDIST

TRH

ABISIP

ABISTG

MOMCTR

NONRES64K

RES64K

SCABISDEL

TBFDLGPRSCAP

SUPERCH

SUPERCH2

CELEVENTD

CELEVENTH

CELEVENTI

CELEVENTS

CELEVENTSC

CELLAFFER

CELLAHFER

CELLAWFER

CELLBTSPS

CELLCCHDR

CELLCCHHO

CELLCONF

CELLDUALT

CELLDYNPC

CELLEFFER

CELLFERF

CELLFERH

CELLFFER

CELLFLXAB

CELLMSQ

CELLPAG

CELLHCS

CELLHFER

CELLHSCSD

CELLMSCAP

CELLSQI

CELLSQIDL

CLCCCH

CLTCHDRAW

CELTCHF

CELTCHH

CELTCHFP

CHGRP0F

CHGRP0H

CHGRP0SQI

CLRATECHG

CLRXQUAL

CLSDCCH, CLSDCCHO

CLSMS

CLTCH

CLTCHEAS

CLTCHDRF

CLTCHDRAF

CLTCHDRH

CLTCHDRAH

CLTCHFV1

CLTCHFV3C

CLTCHFV2, CLTCHHV1, CLTCHFV3, CLTCHHV3 and CLTCHFV5

CLTCHHV3C

CLTCHFV5C

DOWNTIME

IDLEUTCHF (4 object types)

PREEMP

RANDOMACC

RNDACCEXT

NCELLREL, NECELLREL

NICELASS, NECELASS

NICELHO, NECELHO

NICELHOEX, NECELHOEX

BSCGPRS

BSCGPRS2

BSCQOS

CCCHLOAD

CELLEIT

CELLEIT2

CELLGPRS

CELLGPRS2

CELLGPRS3

CELLGPRS4

CELLGPRSO

CELLQOSG

CELLQOSEG

CELLQOSS

CLQOSSCON and CLQOSSCON2

DELSTRTBF

EMGPRS

GPHLOADREG

GPRSCAP

RLINKBITR

TRAFEEVO

TRAFDLGPRS

TRAFULGPRS

TRAFGPRS2

TRAFGPRS3

CLDTMEST

CLDTMPER

CLDTMQOS

NUCELLREL

CCALLS

CMSESTAB

CESTCHACTIV

CESTIMMASS

TFCASSALL

TASSATT

TASSALL

TCASSALL

Inc

Outg

AW

AB

CNDROP

CNRELCONG

CDISTA

CDISSS

CDISQA

CLUNDROP

CLUDISTA

CLUDISSS

CLUDISQA

CCONGS

CTCONGS

CSCSTCONG

CSCSOPTCONG

TFNRELCONG

TFCONGSAS

TFCONGSHO

TFTCONGS

TFTHARDCONGS

ALRFPERFACC

ALNOTRAFACC

ALLOWDLQUALACC

ALNSCAN

HIGHFERDLFR

BADQDL

LOWSSDL

TFNDROP

TFNCEDROP

TFDISTA

TFDISSSUL

TFDISFERUL

TFDISQAUL

TFSUDLOS

Ncalls

Icalls

T_DR_BQ

T_DR_FER

T_DR_TA

T_DR_SUD

T_DR_OTH

TFDISTAA

TFDISSULA

TFDISFERULA

TFDISQAULA

TFSUDLOSA

EASULACTMREP

EASULCAPMREP

EASDLACTSBL

EASDLCAPSBL

DISETA

DISBSS

DISBQA

DISRET3G

HOVERCNT

HOVERSUC

HORTTOCH

HODUPFT

HOTOKCL

HOTOHCS

HODWNQA

HOASBCL

HOSUCBCL

HOATTLSS

HOATTHR

TSQIGOOD

TSQIACCPT

TSQIBAD

TSQIGOODAW

TSQIACCPTAW

TSQIBADAW

TSQIGOODAF

TSQIACCPTAF

TSQIBADAF

TSQIGOODAH

TSQIACCPTAH

TSQIBADAH

TCONGAFR

TCONGAHR

TCONGAWB

TCONGEFR

TCONGHR

TRAFAFR

TRAFAHR

TRAFAWB

TRAFEFR

TRAFHR

TRAFSCAN

THV1TCONGSCC

TFV2TCONGSCC

TFV3TCONGSCC

THV3TCONGSCC

TFV5TCONGSCC

TFV3FERCM1

TFV3TFCM1

TFV5FERCM1

TFV5TFCM1

TFV1FER

TFV1FERTF

THV3FERCM1

THV3TFCM1

THV1FER

THV1FERTF

QUAL00DL

QUAL10DL

QUAL20DL

QUAL30DL

QUAL40DL

QUAL50DL

QUAL60DL

QUAL70DL

QUAL00UL

QUAL10UL

QUAL20UL

QUAL30UL

QUAL40UL

QUAL50UL

QUAL60UL

QUAL70UL

HOINUQA

HOINSUC

HOINBOCH

BCDTCBCOM

BCLOSSCOM

BCDTCBSUC

BCLOSSSUC

HOATFRHRAMR

HOSUCFRHRAMR

HOATFRHRAW

HOSUCFRHRAW

HOATFRHRNAMR

HOSUCFRHRNAMR

HOATHRFRAMR

HOSUCHRFRAMR

HOATHRFRNAMR

HOSUCHRFRNAMR

ATAMRLDHRFRHO

SUCAMRLDHRFRHO

ATNAMRLDHRFRHO

SUCNAMRLDHRFRHO

AMRABHOSUCFRHR

NAMRABHOSUCFRHR

AWABHOSUCFRHR

HOSUCTCHOPT

HOATTHRPACK

HOSUCHRPACK

BSINITDREGHO

MSINITDREGHO

TCHSIG

HOAATOL

HOSUCOL

HOATTULMAXIHO

HOSUCULMAXIHO

HOATTOLMAXIHO

HOSUCOLMAXIHO

LOLCOMUL

LOLSUCUL

DTCBCOMUL

DTCBSUCUL

TAOLCOMUL

TAOLSUCUL

SCLDCOMUL

SCLDSUCUL

OLSCLDCOM

OLSCLDSUC

LOCEVAL

BRHILAYER

TIMEHCSOUT

HOSUCHR

TFESTPGSM

TFDROPPGSM

TFCONGPGSM

TFTRALPACC

ITFUSIB1

CLSTIME

TOTCLSTIME

HOATTLS

HOSUCLS

TMASSALL

TMCASSALL

TMHOATT

TMHOSUCC

TMCHREQACC

TMCHRECACC

TMCNCMATT

TMCNCBATT

TFHSCSDMAIN

TFHSCSDNESEC

TFHSCSDESEC

HOATTPH

DISPH

FAILPH

CONFATTC

CONFATTT

TFDUALTRALACC

TFDUALNDROP

TFDUALCASSALL

TFDUALASSALL

TFV3CM1DL

TFV3CM1UL

THV3CM1DL

THV3CM1UL

TFV5CM1DL

TFV5CM1UL

NQPCCNT

RQHIGHCNT

NIQLOWCNT

RQT11CNT

NPCALLOCCNT

RQLOSSCNT

NQPCUTRANCNT

RQHIUTRANCNT

NIQLOWUTRANCNT

RQTQHOCNT

RQLOSSUTRANCNT

Accessibility

Retainability

Quality

TFTRALACC0

TAVACC0

TACCSCAN0

ALLPDCHSCAN0

ALLPDCHACC0

TFNDROP0

TFQADLDIS0

TFQAULDIS0

TFQABLDIS0

TFFERDLDIS0

TFFERULDIS0

TFFERBLDIS0

TFSSDLDIS0

TFSSULDIS0

TFSSBLDIS0

TFSUDLOS0

TFTADIS0

TSQ0GOOD

TSQ0AFGOOD

TSQ0AWGOOD

TSQ0ACCPT

TSQ0AFACCPT

TSQ0AWACCPT

TSQ0BAD

TSQ0AFBAD

TSQ0AWBAD

THTRALACC0

THNDROP0

THQADLDIS0

THQAULDIS0

THQABLDIS0

THFERDLDIS0

THFERULDIS0

THFERBLDIS0

THSSDLDIS0

THSSULDIS0

THSSBLDIS0

THSUDLOS0

THTADIS0

HOINUQA0

HOINDQA0

HOINBQA0

TSQ0AHGOOD

TSQ0AHACCPT

TSQ0AHBAD

TSQ0GOODDL

TSQ0ACCPTDL

TSQ0BADDL

TSQ0AFGOODDL

TSQ0AFACCPTDL

TSQ0AFBADDL

TSQ0AWGOODDL

TSQ0AWACCPTDL

TSQ0AWBADDL

TSQ0AHGOODDL

TSQ0AHACCPTDL

TSQ0AHBADDL

TDTMATT

TDTMALLOCATT

TFSPV1DTMSUC

TFSPV2DTMSUC

TFSPV3DTMSUC

TFSPV5DTMSUC

THSPV1DTMSUC

THSPV3DTMSUC

SAICTRALACC

THSAICTRALACC

SAICSCAN

ULSAICVOL

DLSAICVOL

BPWRO100

BPWR90100

BPWR8090

BPWR7080

BPWR6070

BPWR5060

BPWR0050

NUMTCHB

NUMTCHBRED

ACCTCHBREDDB

NUMPDCHB

NUMPDCHBRED

ACCPDCHBREDDB

NUMOB

NUMOBRED

ACCOBREDDB

NUMSDCCHB

NUMSDCCHBRED

ACCSDCCHBREDDB

Level one performance indicators

Level two performance indicators

Additional performance indicators

DLSTRVOL

DLINTBGVOL

ULINTBGVOL

DLGMMVOL

ULGMMVOL

GPRSAVA

GPRSCELLAVA

DLMSGTHR

DLMSEGTHR

ULMSGTHR

ULMSEGTHR

DLMSEGDATA

DLMSGDATA

ULMSEGDATA

ULMSGDATA

CNROCNT

DLBGGDATA

DLTBFEST

FAILDLTBFEST

HOVERCNT EXT

HOVERCNT External

HOVERCNT INT

HOVERCNT Internal

HOVERSUC EXT

HOVERSUC External

HOVERSUC INT

HOVERSUC Internal

LDISOTH

LDISRR

MUTIL22

MUTIL23

MUTIL24

MUTIL25

MUTIL33

MUTIL34

MUTIL35

MUTIL44

MUTIL45

MUTIL55

NPAG1LOTOT

NPAG1RESUCC

NPAG2RESUCC

PDRAC

RAACCFA

SUMEIABSUCC

SUMEIAWSUCC

SUMEIHOSUCC

SUMEOABSUCC

SUMEOAWSUCC

SUMEOHOSUCC

SUMIABSUCC

SUMIAWSUCC

SUMIHOSUCC

SUMOABSUCC

SUMOAWSUCC

SUMOHOSUCC

TCHDROP

TFCASSALLSUB

TFNDROPSUB

TFNRELCONGSUB

TFNSCAN

TFTRALACC

TFV3TRALACC

THCASSALL

THCASSALLSUB

THNDROP

THNDROPSUB

THNRELCONG

THNRELCONGSUB

THNSCAN

THTRALACC

THV3TRALACC

TNDROP

TSQIACCPTSUB

TSQIACCPTSUBAF

TSQIACCPTSUBAH

TSQIBADSUB

TSQIBADSUBAF

TSQIBADSUBAH

TSQIGOODSUB

TSQIGOODSUBAF

TSQIGOODSUBAH

DescriptionTotal number of scans (accumulations).

Accumulated number of EGPRS mode DL TBFs (active users), for all types of traffic, including effective streaming PDCH and PDCH used for EIT, in the cell.

Accumulated number of effective streaming B-PDCH, excluding PDCH used for EIT.

Accumulated number of effective streaming G-PDCH, excluding PDCH used for EIT.

Accumulated number of effective streaming E-PDCH, excluding PDCH used for EIT.

Total number of scans (accumulations).

Accumulated number of EGPRS mode UL TBFs (active users), for all types of traffic, including effective streaming PDCH and PDCH used for EIT, in the cell.

Accumulated number of Basic and GPRS mode DL TBFs (active users), for all types of traffic, including effective streaming PDCH and PDCH used for EIT, in the cell.

Accumulated number of B-PDCH that carried one or more DL TBFs of any mode in the cell (a B-PDCH used on the DL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of G-PDCH that carried one or more DL TBFs of any mode in the cell (a G-PDCH used on the DL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.Accumulated number of E-PDCH that carried one or more DL TBFs of any mode in the cell (an E-PDCH used on the DL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous DL TBFs of any mode per used B-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous DL TBFs of any mode per used G-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous DL TBFs of any mode per used E-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT. With Flexible Abis the counter values will be slightly higher.

Accumulated number of B-PDCH that carried one or more DL active TBFs of any mode in the cell (an active B-PDCH on the DL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of G-PDCH that carried one or more active DL TBFs of any mode in the cell (an active G-PDCH on the DL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of E-PDCH that carried one or more active DL TBFs of any mode in the cell (an active E-PDCH on the DL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous active DL TBFs that are not in “Delayed release of DL TBF” or “Early Setup of DL TBF” of any mode per active B-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous active DL TBFs that are not in “Delayed release of DL TBF” or “Early Setup of DL TBF” of any mode per active G-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous active DL TBFs that are not in “Delayed release of DL TBF” or “Early Setup of DL TBF” of any mode per active E-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated QoS weights on each used B-PDCH in the cell, for all types of traffic, excluding effective streaming PDCH, but including PDCH used for EIT. EIT TBFs on these PDCH are counted with a QoS weight of zero.

Accumulated QoS weights on each used G-PDCH in the cell, for all types of traffic, excluding effective streaming PDCH, but including PDCH used for EIT. EIT TBFs on these PDCH are counted with a QoS weight of zero.Accumulated QoS weights on each used E-PDCH in the cell, for all types of traffic, excluding effective streaming PDCH, but including PDCH used for EIT. EIT TBFs on these PDCH are counted with a QoS weight of zero.

The counter EPDCHGE counts the accumulated number of EGPRS PDCHs that are simultaneously reserved by at least one downlink EGPRS mode TBF and at least one downlink Basic mode or GPRS mode TBF. The counter is per cell.

The counter GETBFONPDCH contains the accumulated number of downlink Basic mode and downlink GPRS mode TBFs on each EGPRS PDCH reserved by at least one downlink EGPRS mode TBF. The counter is per cell.

The counter GNOETBFONPDCH contains the accumulated number of downlink Basic mode and downlink GPRS mode TBFs on each EGPRS PDCH not reserved by any downlink EGPRS mode TBF. The counter is per cell.

Accumulated number of Basic and GPRS mode UL TBFs (active users), for all types of traffic, including effective streaming PDCH and PDCH used for EIT, in the cell.

Accumulated number of B-PDCH that carried one or more UL TBFs of any mode in the cell (a B-PDCH used on the UL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of G-PDCH that carried one or more UL TBFs of any mode in the cell (a G-PDCH used on the UL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of E-PDCH that carried one or more UL TBFs of any mode in the cell (an E-PDCH used on the UL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.Accumulated number of simultaneous UL TBFs of any mode per used B-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous UL TBFs of any mode per used G-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Number of downlink TBFs where the MS is capable of using dual carriers.

Number of downlink TBFs, in EGPRS mode, reserved on dual carriers.

Maximum possible number of time slots reservable for MSs on downlink TBFs in EGPRS mode, reserved on dual carriers.

Number of scans for the counters in this object type. This counter is only valid for counters in object type TRAFEEVO.

Number of time slots with one or more uplink or downlink TBFs currently reserved on dual carriers.

Number of accumulations. The same value for both the allocated and active accumulators.ALLPDCHSCANSUB is the counter for the overlaid subcell.

Total number of scans of the cell carried out for the number of DL TBFs. This counter is only valid for counters in object type TRAFGPRS2.

Total number DL TBFs scanned which were of mode Basic. Counter for GPRS mode TBFs TRAFF2GTBFSCAN. Counter for EGPRS mode TBFs TRAFF2ETBFSCAN.

Accumulation of maximum possible number of timeslots reservable by the MS for all DL B-TBFs and G-TBFs scanned.

Accumulation of maximum possible number of timeslots reservable by the MS for all DL E-TBFs scanned.

Accumulated number of simultaneous UL TBFs of any mode per used E-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT. With Flexible Abis the counter values will be slightly higher.

Accumulated number of B-PDCH that carried one or more active UL TBF of any mode in the cell (an active B-PDCH on the DL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of G-PDCH that carried one or more active UL TBF of any mode in the cell (an active G-PDCH on the DL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.Accumulated number of E-PDCH that carried one or more active UL TBF of any mode in the cell (an active E-PDCH on the UL). Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous active UL TBFs that are not in “Extended UL TBF” of any mode per active B-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous active UL TBFs that are not in “Extended UL TBF” of any mode per active G-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated number of simultaneous active UL TBFs that are not in “Extended UL TBF” of any mode per active E-PDCH in the cell. Valid for all types of traffic, including effective streaming PDCH and PDCH used for EIT.

Accumulated QoS weights on each used B-PDCH in the cell, for all types of traffic, excluding effective streaming PDCH, but including PDCH used for EIT. EIT TBFs on these PDCH are counted with a QoS weight of zero.

Accumulated QoS weights on each used G-PDCH in the cell, for all types of traffic, excluding effective streaming PDCH, but including PDCH used for EIT. EIT TBFs on these PDCH are counted with a QoS weight of zero.

Accumulated QoS weights on each used E-PDCH in the cell, for all types of traffic, excluding effective streaming PDCH, but including PDCH used for EIT. EIT TBFs on these PDCH are counted with a QoS weight of zero.

Sum of percentage shares of reserved time slots for all EGPRS mode downlink TBFs reserved on dual carriers related to the maximum possible reservable time slots.

Total number of available 20 ms RLC blocks on all allocated PDCHs. The counters shows the number of available RLC blocks in one direction and will be the same for the uplink and the downlink. Also PDCHs in the packet idle list are considered.

Total number of occupied (schedlued) 20 ms RLC blocks on the downlink. All types of RLC blocks counted including data blocks, control blocks, retransmissions, dummy blocks and all blocks for abnormally released TBFsTotal number of occupied (scheduled) 20 ms RLC blocks on the uplink. All types of RLC blocks counted including data blocks, control blocks, retransmissions, repetitions, dummy blocks and blocks for abnormally released TBFs

Number of allocated PDCHs accumulator. Every 10 seconds the number of allocated PDCH in the cell is recorded and added to an accumulator. Divide by ALLPDCHSCAN to get the average number of allocated PDCH during the measurement period. Number of allocated PDCHs on channel group zero are counted separately by ALLPDCHACC0see Section 5.7.17.ALLPDCHACCSUB is the counter for the overlaid subcell.

Number of used PDCHs accumulator. Every 10 seconds the number of used PDCH (carrying an uplink and/or downlink TBF) in the cell is recorded and added to an accumulator. Divide by ALLPDCHSCAN to get the average number of used PDCH during the measurement period.

Maximum number of PDCHs used, either carrying packet traffic, being in delayed release mode or being in extended uplink mode, per cell during the last 60 minutes.

Accumulation of the percentage of number of timeslots actually reserved versus maximum number of timeslots possible for the MS to reserve, calculated for every DL Basic mode TBFs scanned. One scan of all downlink TBFs in the cell carried out every 10 seconds. Counter for GPRS mode TBFs MUTILGPRS. Counter for EGPRS mode TBFs MUTILEGPRSWith Flexible Abis the counter value of MUTILEGPRS will be slightly lower.

Number of DL TBFs (of any mode) scanned where only 1 out of a possible 5 timeslots were reserved. Also MUTIL25, MUTIL35, MUTIL45, MUTIL55. With Flexible Abis the counter values will be affected. For MUTIL15, MUTIL25, MUTIL35 and MUTIL45 the values will be slightly higher and for MUTIL55 slightly lower.

Number of DL TBFs (of any mode) scanned where only 1 out of a possible 4 timeslots were reserved. Also MUTIL24, MUTIL34, MUTIL44. With Flexible Abis the counter values will be affected. For MUTIL14, MUTIL24 and MUTIL34 the values will be slightly higher and for MUTIL44 slightly lower.

Number of simultaneous DL TBFs for GPRS only capable mobiles in a cell.

Number of simultaneous DL TBFs for EGPRS capable mobiles in a cell.

Total number of scans of the cell carried out for the number of UL TBFs. This counter is only valid for counters in object type TRAFGPRS3.

Total number UL TBFs scanned which were of mode Basic. Counter for GPRS mode TBFs GULTBFSCAN. Counter for EGPRS mode TBFs EULTBFSCAN.

Accumulation of maximum possible number of timeslots reservable by the MS for all UL B-TBFs and G-TBFs scanned.

Accumulation of maximum possible number of timeslots reservable by the MS for all UL E-TBFs scanned.

Number of UL TBFs scanned where 1 out of 4 maximum reservable timeslots were reserved. Also MUTIL24UL, MUTIL34UL, MUTIL44UL.

Number of UL TBFs scanned where 1 out of 3 maximum reservable timeslots were reserved. Also MUTIL23UL, MUTIL33UL.

Number of UL TBFs scanned where 1 out of 2 maximum reservable timeslots were reserved. Also MUTIL22UL.

Accumulation of number of simultaneous UL TBFs for GPRS only capable mobiles in a cell.

Accumulation of number of simultaneous UL TBFs for EGPRS capable mobiles in a cell.

Accumulation of the percentages (GSL devices in use / maximum GSL devices possible to use) taken at each scan.

Total number of scans of the PCU taken in relation to the GSL device utilization.

Number scans where the fraction of (GSL devices in use / maximum GSL devices possible to use) is between 0% and 40%.





Counters for AGW RP CPU Load.

Counters for AGW RP Traffic.

Counters for A over IP.

Counters for capacity lock for the A over IP interface

Paging and MS sessions

Measurements for Messages on A Interface per BSC

Multislot connections

RF output power supervision

Counters for Capacity Locks for SCC statistics

Load regulation in the CP

Counters for PGW RP CPU Load

Counters for PGW Load Distribution

Load on all GARP-2 RPs running the TRH application.

The counters are stored and presented per Transceiver Group (TG) and indicate the amount of IP traffic between BSC and BTS.

The counters are stored and presented per Transceiver Group (TG) and treat jitter buffer delay, jitter buffer drops and bundling group delay for ABIS over IP.

The counters are stored and presented per Multi Carrier Power Amplifier (MCPA) and show power utilization and service quality impact.

Status of the non-64K pool of Abis paths

Status of the 64K pool of Abis paths

Delay measurements per super channel for packet Abis

Number of DL TBFs (of any mode) scanned where only 1 out of a possible 3 timeslots were reserved. Also MUTIL23, MUTIL33. With Flexible Abis the counter values will be affected. For MUTIL13 and MUTIL23 the values will be slightly higher and for MUTIL33 slightly lower.

Number of DL TBFs (of any mode) scanned where only 1 out of a possible 2 timeslots were reserved. Also MUTIL22. With Flexible Abis the counter values will be affected. For MUTIL12 the values will be slightly higher and for MUTIL22 slightly lower.

Accumulation of the percentage of number of timeslots actually reserved versus. maximum number of timeslots possible for the MS to reserve, calculated for every UL Basic mode TBFs scanned. One scan of all uplink TBFs in the cell carried out every 10 seconds. Counter for GPRS mode TBFs MUTILGPRSUL. Counter for EGPRS mode TBFs MUTILEGPRSUL

The counter GSLMAX is the maximum number of GSL Sub devices possible to use at each scan. Note-GSLMAX may differ between each scan. It depends on the following factors: Seized GSL Capacity Remaining Processing Capacity in the physical link layer Remaining Idle GSL Sub Device Capacity First a calculation is performed to obtain the remaining Processing Capacity in the physical link layer. Then the remaining Idle GSL Sub Device Capacity is calculated. The smallest of these values is used as the figure for how sub many devices that could be used as GSL sub channels. The result is added to the current number or Seized GSL devices to obtain GSLMAX. GSLMAX can also be expressed with the following algorithm: GSLMAX = GSL Sub Dev Seized as B-PDCH + (GSL Dev Seized as G- or E-PDCH * 4) + min[GSL Sub Dev Available due to processing capacitylimits of the physical link layer, Number of Idle GSL Sub Devices].

Super Channel quality counters

Superchannel load counters.

Subscriber initiated disconnections

Cell load sharing and handovers due to operation and maintenance intervention

Intra cell channel change

Handover between overlaid and underlaid subcells

Handover from overlaid to underlaid subcell, additional causes

FER intervals in SQS data Collection for codec type AMR FR

FER intervals in SQS data Collection for codec type AMR HR

Registration of FER intervals in SQS data Collection for Codec Type AMR-WB per cell.

Counters for BTS Power Savings

Dropped connections for control channels

Handovers on SDCCH

Adaptive configuration of logical channels

Statistics on MSs capable of 900/1800 dual band. MSs with 900/1800 + extra band/bands will also be included

Counters for dynamic BTS and MS power control

FER intervals in SQS data Collection for codec type EFR

Frame erasure rate (FER) counters, full-rate

Frame erasure rate (FER) counters, half-rate

FER intervals in SQS data Collection for codec type FR

Counters on cell level for flexibly allocated Abis paths per cell.

Counters for the feature Prioritised MS Queuing

Paging counters on cell level

Locating measurements for HCS

FER intervals in SQS data Collection for codec type HR

Measurement for High Speed Circuit Switched Data

Counters for MSs with Miscellaneous Capabilities per Cell

Speech quality supervision measurements for TCH/Fs uplink.

Speech quality supervision downlink

CCCH Availability

Traffic measurements for dropped connections per cell level for TCH/F SPV5

TCH/FR connections

TCH/HR connections

Primary band

Counters on cell level for monitoring selected performance indicators separately for channel group zero.

Counters on cell level for monitoring selected performance indicators separately for channel group zero.

Speech quality supervision downlink for channel group zero

To monitor Dynamic FR/HR mode adaptation.

Counters on cell level for monitoring the distribution of downlink and uplink RXQUAL values.

Traffic measurements for SDCCH per cell. SDCCH counters (O=OL =>SUB)

Short Message Service counters

Traffic channel connections counters and Packet ABIS Overload counter for CS.

Counters for Enhanced AMR Coverage.

Counters for dropped connections on all FR traffic channels

Counters for dropped connections on AMR full rate

Counters for dropped connections for all HR traffic channels

Counters for dropped connections on AMR half rate

Counters for TCH utilization for Speech Version 1 FR

Counters for TCH utilization and SCC capacity locks statistics for optional speech codecs (Counters in CLTCHFV2 shown here)

Counters for codec mode utilization for AMR full rate

Counters for codec mode utilization for AMR half rate

Codec Mode Utilization measurements for TCH/F Speech Version 5 on cell level.

Downtime statistics

Counters for idle traffic channels (H=HR or F=FR) per subcell (U=UL,O=OL)

Preemptive allocation attempts

Random access

Random access, extended

Handover counters (internal/external)

Counters for handovers at assignment (internal/external)

Counters for handover decisions (internal/external)

Handover attempts at high handover rate and classifying serving cell (internal/external)

Counters for GPRS on BSC level. Mixed usage.

Counters for GPRS on BSC level. Currently used to monitor GPH RP load per PCU and NC2 performance, respectively.

QoS monitoring on BSS level. Note NOT to be used to monitor the overall user IP throughput for the BSC.

Number of CS and PS immediate assignment and immediate assignment reject messages sent on the CCCH. Cell level.

Counters on cell level to monitor the performance of EIT with respect to the Push-To-Talk service.

Counters on cell level to monitor the performance of EIT with respect to the Push-To-Talk service.

Counters to monitor GPRS on cell level.

Counters for GPRS on cell level. Throughput counters based on MS EGPRS/GPRS capability and number of counters for active GPRS and EGPRS users.

Counters for GPRS for the overlaid subcell. Mixed usage.

IP throughput on cell level for Basic and GPRS mode TBFs.

IP throughput on cell level for EGPRS mode TBFs.

IP throughput on cell level for streaming.

Counters on cell level for streaming negotiation for resources.

Counters on BSC level to assist with the setting of parameters for TBF “keep alive” mechanisms related to streaming.

Counter to monitor the GPH processor load per RP (for all types of RP platforms in the PCU).

GPH Overload Protection function counters per BSC.

Packet Switched Capacity Locks Counters per BSC

Radio link quality measures for downlink CS-1/2/3/4 and EGPRS mode transfers on cell level.

Traffic load measurements for Edge Evolution

GRPS/EGRPS traffic load counters for the downlink on cell level.

GRPS/EGRPS traffic load counters for the uplink on cell level.

Multislot utilization counters for the downlink on cell level.

Multislot utilization counters for the uplink on cell level.

Counters on cell level for DTM connection set-up attempts and successful establishments per channel service.

Counters on cell level for IP data volume and IP throughput for DTM connections.

GSM to UTRAN handovers

Channel allocation attempt counter (on SDCCH).

Successful MS channel establishments on SDCCH.

Number of SDCCH establishment failure due to time-out after sending Immediate Assignment, timer T3101 expired.

Counters for GPRS on cell level. Mixed usage including PDCH allocation counters and radio link quality measures for all uplink transfers and downlink CS-1/2 mode transfers. Counters to monitor number of RLC data blocks used for EGPRS mode TBFs at optimum coding scheme according to LQC algorithm.

Counters for GPRS on cell level. GPRS availability, IP latency and IP data volume and rejected new PS session setups due to packet Abis congestion. Counters for counting the user data volume generated by SAIC capable mobiles

Counters on cell level for the multislot utilization for DTM TBFs. Also DL IP buffer discards and UL accessibility/retainability for DTM connections. Counters for number of active GPRS and EGPRS users in DTM

Number of SDDCH establishment failure that occurs under channel allocation and channel activation. Note that this counter is stepped also in case of SDCCH congestion.

Number of assignment complete messages for all MS power classes in underlaid subcell, full-rate. There is also an identical counter for overlaid subcells, TFCASSALLSUB. There are corresponding counters for half-rate, THCASSALL and THCASSALLSUB, respectively.

Number of first assignment attempts on TCH for all MS power classes. Both successful and unsuccessful attempts are counted in the target cell.

Number of assignment complete messages on TCH for all MS power classes.

Sum of all incoming handovers to a cell from all its neighbors.

Sum of all outgoing handovers from a cell to all its neighbors.

Number of successful assignments to worse cell, counter HOSUCWCL.

Number of successful assignments to better cell, counter HOSUCBCL.

The total number of dropped SDCCH channels in a cell.

Dropped SDCCH connection at excessive Timing Advance (TA).

Number of congestion at incoming handover in underlaid subcell. The counter is also available for half-rate and for overlaid subcells, e.g. THCONGSHOSUB.

Number of first assignment attempts on TCH for all MS power classes. Successful attempts are counted in the target cell and failed attempts are counted in the serving cell. The serving cell is the cell where the mobile station was tuned to an SDCCH or TCH for signalling.

Number of released connection on SDCCH due to TCH— and transcoder congestion in underlaid and overlaid subcell. The subset for overlaid subcells is CNRELCONGSUB. The two counters are located in CLSDCCH and CLSDCCHO respectively. CNDROP is stepped at the same time.

Dropped SDCCH connection at low signal strength on down— or uplink in underlaid subcell i.e. below LOWSSDL and/or LOWSSUL. There is also a counter for overlaid subcell, CDISSSSUB.Dropped SDCCH connection at bad quality down— or uplink per cell in underlaid subcell i.e. worse than BADQDL and/or BADQUL. There is also a counter for overlaid subcell, CDISQASUB.

The total number of dropped SDCCH channels during location area update in a cell. The counter CLUNDROP is incremented for abnormal terminations that occur during location area update.

Dropped SDCCH connection during location area update at excessive Timing Advance (TA). CLUDISTA works as CDISTA, but is only incremented for drops during location area update.

Dropped SDCCH connection during location area update at low signal strength on down— or uplink in underlaid subcell i.e. below LOWSSDL and/or LOWSSUL. There is also a counter for overlaid subcell, CLUDSSSUB. CLUDISSS and CLUDISSSSUB works as CDISSS and CDISSSSUB respectively, but are only incremented for drops during location area update.

Dropped SDCCH connection during location area update at bad quality down— or uplink per cell in underlaid subcell i.e. worse than BADQDL and/or BADQUL. There is also a counter for overlaid subcell, CLUDISQASUB. CLUDISQA and CLUDISQASUB works as CDISQA and CDISQASUB respectively, but are only incremented for drops during location area update.

Congestion counter for underlaid subcell. Stepped each time an allocation attempt fails due to SDCCH congestion. Also available for overlaid subcells, CCONGSSUB.

Congestion time counter for underlaid subcell. The counter is stepped each second all available SDCCH channels are busy. Also available for overlaid subcells, CTCONSUB.

Congestion time counter for signalling connection setup for procedures requiring a TCH. Starts incrementing when a signalling connection setup attempt for a procedure requiring a TCH fails and stops incrementing when there is a successful signalling connection setup of any kind on a SDCCH or a TCH.

Congestion time counter for signalling connection setup for procedures that can be completed on a SDCCH. Starts incrementing when a signalling connection setup attempt for a procedure that can be completed on an SDCCH fails and stops incrementing when there is a successful signalling connection setup of any kind on a SDCCH.

Number of released TCH signalling connections due to transcoder resource congestion during immediate assignment on TCH. The corresponding counter for half-rate is THNRELCONG. These counters are also available for overlaid subcell as TFNRELCONGSUB and THNRELCONGSUB. TFNDROP is stepped at the same time.

Number of failed channel allocation attempts at assignment or immediate assignment in underlaid subcell. The counter is also available for half-rate and for overlaid subcells, e.g. THCONGSASSUB.

Soft congestion time counter for underlaid subcell. The counter starts to increment when a channel is requested but no idle channels are available. The corresponding half-rate counter for overlaid subcells is named THTCONSUB. In the case of GPRS no consideration is made as to whether on-demand PDCHs exist in the cell or not i.e. both on-demand and fixed PDCHs are regarded as busy.

Hard congestion time counter for underlaid subcell. The counter starts to increment only when it has not been possible to allocate a channel with the help of any type of preemption. The corresponding counter for overlaid subcells is named TFTHARDCONSUB. The corresponding counters for halfrate are called THTHARDCONGS and THTHARDCONSUB In the case of GPRS no consideration is made as to whether on-demand PDCHs exist in the cell, simply whether the preemption has failed or not.

The accumulated number of RADIO X-CEIVER ADMINISTRATION MANAGED OBJECT FAULT alarms with alarm slogan RF PERFORMANCE and RADIO X-CEIVER ADMINISTRATION TRANSCEIVER GROUP FAULT alarms with alarm slogan RF PERFORMANCE. The number of currently active alarms is scanned every five minutes.

The accumulated number of CELL RF OUTPUT POWER SUPERVISION alarms with the reason NO TRAFFIC. The number of currently active alarms is scanned every five minutes.

The accumulated number of CELL RF OUTPUT POWER SUPERVISION alarms with the reason LOW DL QUALITY. The number of currently active alarms is scanned every five minutes.

The total number of dropped full-rate TCH in underlaid subcell. The counter is also available for half-rate and for overlaid subcells, e.g. THNDROPSUB.

Total number of dropped full-rate TCH connections at excessive TA. Also available for half-rate, e.g. THDISTA.

Number of calls terminated in a cell.

Number of initiated calls in a cell, e.g. the sum of the four “CASSALL” counters for TCH or CMSESTAB for SDCCH.

The rate of TCH drops at bad quality on either uplink, downlink or both for the whole cell.

The rate of TCH drops at high FER on either uplink, downlink or both for the whole cell.

The rate of TCH drops due to excessive Timing Advance for the whole cell.

The rate of TCH drops due to sudden loss of the connection for the whole cell.

The rate of TCH drops due to other reasons than the above known reasons.

Total number of dropped AMR full-rate TCH connections at excessive TA. Also available for half-rate, e.g. THDISTAA .

The counter is stepped for each Measurement Report that is received while the terminal is in repeated SACCH mode on the uplink.

The counter is stepped for each DL SACCH block received by the MS while in repeated SACCH mode on the downlink.

The counter is incremented by one every five minutes when the number of currently active alarms is scanned in order to update the counters ALRFPERFACC, ALNOTRAFACC and ALLOWDLQUALACC.

Threshold value for FER downlink for fullrate. Filtered FER measurements on the downlink for fullrate are compared to HIGHFERUL when evaluating urgency conditions. The evaluated condition is used for statistical counter incrementation only. There are separate BSC exchange properties for uplink, downlink and per codec halfrate, fullrate, enhanced fullrate, AMR halfrate and AMR fullrate. For example the corresponding parameter for uplink and AMR halfrate is HIGHFERULAHR. Note that evaluation of the FER threshold requires the feature Enhanced Measurement Reporting (EMR). Value range: 0-96 FER units. Default value: 4 FER Units.

Threshold value for Bad Quality downlink based on RXQUAL. Filtered quality measurements on the downlink are compared to BADQx when evaluating urgency conditions. The evaluated condition is used for statistical counter incrementation only. The corresponding parameter for uplink is BADQUL. Value range: 0-100dtqu. Default value: 55dtqu.

Threshold values for attenuation of Signal Strength downlink. Filtered downlink signal strength values are compared with LOWSSx when analyzing urgency conditions. The evaluated condition is used for statistical counter incrementation only. The corresponding parameter for uplink is LOWSSULValue range: -47-(-110)dBm. Default value: -104dBm.

The total number of dropped full rate TCH connections in underlaid subcell that occur when a subscriber to subscriber connection has already been established. The counter is incremented when a connection is dropped after any of the three messages 44.018 ASSIGNMENT COMPLETE, 44.018 HANDOVER COMPLETE, 44.018 CHANNEL MODE MODIFY ACKNOWLEDGE and before one of the DTAP messages 24.008 RELEASE or 24.008 DISCONNECT is received by the BSC. For inter BSC handovers and inter system handovers, the target BSC assumes that the call connection is already established, and the counter is incremented in the target BSC in case of dropped connection. The counter is also available for half-rate and for overlaid subcells, e.g. THNCEDROPSUB.

Total number of dropped full-rate TCH connection at low signal strength on uplink in underlaid subcell i.e. below LOWSSUL. Different combinations for overlaid subcell, up/down and both-way link and half-rate, e.g. THDISSSBLSUB is the signal strength drop counter for half-rate, both links in overlaid subcell. If both links have low signal strength, only the both link counters are stepped.

Total number of dropped full-rate TCH connections at high FER on uplink in underlaid subcell i.e. worse than (above) HIGHFERULFR. Different combinations for overlaid subcell, up/down and both-way link and codec, e.g. THDISFERBLSUB is the bad quality drop counter for half-rate, both links in overlaid subcell. If both links have bad quality, only the both link counters are stepped.

Total number of dropped TCH connection due to bad quality based on RXQUAL on uplink in underlaid subcell i.e. worse than (above) BADQUL. Different combinations for overlaid subcell, up/down and both ways link and half-rate, e.g. THDISQABLSUB is the bad quality drop counter for half-rate, both links in overlaid subcell. If both links have bad quality, only the both link counters are stepped.

Sudden loss of connection in underlaid subcell. Sudden loss apply when the locating algorithm indicates missing measurement results, but none of the urgency conditions mentioned above (that is excessive TA, low signal strength, high FER or bad quality) apply. The counter is also available for half-rate and for overlaid subcells, e.g. THSUDLOSSUB.

Total number of dropped AMR full-rate TCH connections due to low signal strength on uplink in underlaid subcell i.e. below LOWSSUL. Different combinations for overlaid subcell, up/down/both links and half-rate, e.g. THDISSBLSUBA is the signal strength drop counter for AMR half-rate, both links in overlaid subcell. If both links have low signal strength, only the both link counters are stepped.

Total number of dropped AMR full rate TCH connections at high FER on uplink in underlaid subcell. Different combinations for overlaid subcell, up/down and both-way link and codec, e.g. THDISFERBLSUBA is the bad quality drop counter for AMR half-rate, both links in overlaid subcell. If both links have bad quality, only the both link counters are stepped.

Total number of dropped AMR full-rate TCH connections at bad quality on uplink in underlaid subcell. Different combinations for overlaid subcell, up/down/both links and half-rate, e.g. THDISQABLSUBA is the bad quality drop counter for AMR half-rate, both links in overlaid subcell. If both links have bad quality, only the both link counters are stepped.

Sudden loss of AMR full-rate connection in underlaid subcell. Sudden loss apply when the locating algorithm indicates missing measurement results, but none of the urgency conditions mentioned above (that is excessive TA, low signal strength, high FER or bad quality) apply. The counter is also available for AMR half-rate and for overlaid subcells, e.g. THSUDLOSSUBA.

The counters is stepped for each Measurement Report that is received from an MS capable of repeated SACCH, while the feature Enhanced AMR Coverage is activated in the BSC.

Normal disconnection at excessive timing advance.

Normal disconnection at low signal strength.

Normal disconnection at bad quality.

Disconnection with request to immediately connect to UTRAN network.

Number of Handover Commands sent to the MS.

Number of successful handover to the neighboring cell.

Number of handover attempts where the MS returns to the old channel or has been ordered by the network and succeeded in getting back to the old channel.

Number of successful handovers back to old cell within 10 seconds.

Handover attempt made to better K-cell (only for the Ericsson 1 locating algorithm). The corresponding for better L-cell is called HOTOLCL.

Handover attempt due to HCS.

Number of assignment attempts to better cell. The corresponding counter for assignment to worse cell is called HOASWCL.

Number of successful assignment attempts to better cell. The corresponding counter for assignment to worse cell is called HOSUCWCL.

Number of handover attempts at high handover rate. The counter for successful handovers at high handover rate is HOSUCHR.

Accumulated number of SQI samples that represented good speech quality. The corresponding counter for overlaid subcell is TSQIGOODSUB

Accumulated number of SQI samples that represented acceptable speech quality. The corresponding counter for overlaid subcell is TSQIACCPTSUB

Accumulated number of SQI samples that represented unsatisfactory speech quality. The corresponding counter for overlaid subcell is TSQIBADSUB

Accumulated number of SQI samples for AMR full rate that represented good speech quality. The corresponding counter for overlaid subcell is TSQIGOODSUBAF

Total time in seconds when no speech resource for AMR FR has been available for new traffic due to SCC capacity lock mechanism.

Total time in seconds when no speech resource for AMR HR has been available for new traffic due to SCC capacity lock mechanism.

Total time in seconds when no speech resource for AMR WB has been available for new traffic due to SCC capacity lock mechanism.

Total time in seconds when no speech resource for EFR has been available for new traffic due to SCC capacity lock mechanism.

Total time in seconds when no speech resource for HR has been available for new traffic due to SCC capacity lock mechanism.

Accumulated traffic level (number of calls) using AMR FR speech codec.

Accumulated traffic level (number of calls) using AMR HR speech codec.

Accumulated traffic level (number of calls) using AMR WB speech codec.

Accumulated traffic level (number of calls) using EFR speech codec.

Accumulated traffic level (number of calls) using HR speech codec.

Number of accumulations of traffic level counters.

The counters is stepped for each DL SACCH block received by an MS capable of repeated SACCH, while the feature Enhanced AMR Coverage is activated in the BSC.

Number of handover attempts due to bad downlink quality. There is one HO counter for bad uplink quality called HOUPLQAand one for excessive timing advance called HOEXCTA.

Number of handover attempts when the serving cell is a low signal strength cell. The corresponding counter for attempts at high signal strength is called HOATTHSS.

Accumulated number of SQI samples for AMR wideband that represented good speech quality. The corresponding counter for overlaid subcell is TSQIGOODSUBAW

Accumulated number of SQI samples for AMR wideband that represented acceptable speech quality. The corresponding counter for overlaid subcell is TSQIACCPTSUBAW

Accumulated number of SQI samples for AMR wideband that represented unsatisfactory speech quality. The corresponding counter for overlaid subcell is TSQIBADSUBAW

Accumulated number of SQI samples for AMR full rate that represented acceptable speech quality. The corresponding counter for overlaid subcell is TSQIACCPTSUBAF

Accumulated number of SQI samples for AMR full rate that represented unsatisfactory speech quality. The corresponding counter for overlaid subcell is TSQIBADSUBAF

Accumulated number of SQI samples for AMR half rate that represented good speech quality. The corresponding counter for overlaid subcell is TSQIGOODSUBAHAccumulated number of SQI samples for AMR half rate that represented acceptable speech quality. The corresponding counter for overlaid subcell is TSQIACCPTSUBAH

Accumulated number of SQI samples for AMR half rate that represented unsatisfactory speech quality. The corresponding counter for overlaid subcell is TSQIBADSUBAH

Total congestion time (in seconds) when no speech codec resource for HR has been available to setup new traffic due to the SCC capacity lock mechanism.

Total congestion time (in seconds) when no speech codec resource for EFR has been available to setup new traffic due to the SCC capacity lock mechanism.

Total congestion time (in seconds) when no speech codec resource for AMR FR has been available to setup new traffic due to the SCC capacity lock mechanism.

Total congestion time (in seconds) when no speech codec resource for AMR HR has been available to setup new traffic due to the SCC capacity lock mechanism.

Total congestion time (in seconds) when no speech codec resource for AMR WB has been available to setup new traffic due to the SCC capacity lock mechanism.

Number of frames erased by the BTS for full rate Speech Version 1. TFV2FER is the corresponding counter for full rate Speech Version 2 (EFR).

Number of frames erased by the BTS for half rate Speech Version 1.

Total number of frames transmitted by the MS for half rate full rate Speech Version 1.

Number of quality 0 reported on downlink.








Number of quality 0 reported on uplink.








Number of successful intra cell handovers.

Number of intra-cell handover attempt out of BCCH channel group, BCCHDTCB criteria.

Number of intra-cell handover attempt out of BCCH channel group, BCCHLOSS criteria.

Number of successful intra-cell handover out of BCCH channel group, BCCHDTCB criteria.

Number of successful intra-cell handover out of BCCH channel group, BCCHLOSS criteria.

Number of frames erased by the BTS for full rate AMR codec mode 1. TFV3FERCM2 is the corresponding counter for AMR codec mode 2. TFV3FERCM3 is the corresponding counter for AMR codec mode 3. TFV3FERCM4 is the corresponding counter for AMR codec mode 4.

Total number of frames transmitted by the MS for full rate AMR codec mode 1. TFV3TFCM2 is the corresponding counter for AMR codec mode 2. TFV3TFCM3 is the corresponding counter for AMR codec mode 3. TFV3TFCM4 is the corresponding counter for AMR codec mode 4.

Number of frames erased by the BTS for full rate AMR Wideband codec mode 1. TFV5FERCM2 is the corresponding counter for AMR Wideband codec mode 2. TFV5FERCM3 is the corresponding counter for AMR Wideband codec mode 3.Total number of frames transmitted by the MS for AMR wideband codec mode 1. TFV5TFCM2 is the corresponding counter for AMR wideband codec mode 2. TFV5TFCM3 is the corresponding counter for AMR wideband codec mode 3.

Total number of frames transmitted by the MS for full rate full rate Speech Version 1. TFV2FERTF is the corresponding counter for full rate Speech Version 2 (EFR).

Number of frames erased by the BTS for half rate AMR codec mode 1. THV3FERCM2 is the corresponding counter for AMR codec mode 2. THV3FERCM3 is the corresponding counter for AMR codec mode 3. THV3FERCM4 is the corresponding counter for AMR codec mode 4.

Total number of frames transmitted by the MS for half rate AMR codec mode 1. THV3TFCM2 is the corresponding counter for AMR codec mode 2. THV3TFCM3 is the corresponding counter for AMR codec mode 3. THV3TFCM4 is the corresponding counter for AMR codec mode 4.

Number of intra cell handover attempts (decisions) at bad uplink quality. The corresponding counter for the downlink is HOINDQAand for both links is HOINBQA. Only HOINBQA is stepped at bad quality on both links.

Number of unsuccessful intra cell handover attempts where the MS returns to the old channel or has been ordered by the network and succeeded in getting back to the old channel.

Number of Intra Cell Handover Attempts due to HR to FR channel rate change triggered by bad quality, made by an AMR capable mobile.

Number of successful Intra Cell Handovers due to HR to FR channel rate change triggered by bad quality, made by an AMR capable mobile.

Number of Intra Cell Handover attempts due to HR to FR channel rate change triggered by bad quality, made by a mobile not capable of AMR.

Number of successful intra cell handovers, due to HR to FR channel rate change triggered by bad quality, made by a mobile not capable of AMR.

Number of intra cell handover attempts, due to HR to FR channel rate change triggered by low cell load and low Abis load, for AMR/HR calls.

Number of successful intra cell handovers, due to HR to FR channel rate change triggered by low cell load and low Abis load, for AMR/HR calls.

Number of intra cell handover attempts, due to HR to FR channel rate change triggered by low cell load and low Abis load, for non AMR/HR calls.

Number of successful intra cell handovers, due to HR to FR channel rate change triggered by low cell load and low Abis load, for non AMR/HR calls.

Number of successful intra cell handovers due to FR to HR channel rate change triggered by high Abis load by a mobile not capable of AMR.

Number of successful intra cell handovers due to FR to HR channel rate change triggered by high Abis load, made by a mobile capable of AMR Wideband.

Number of successful Intra Cell Handover due to TCH optimization.

Number of intra cell handover attempts due to half rate packing.

Number of successful intra cell handovers due to half rate packing.

Accumulated initial BTS power down regulation after handover, in dB.

Accumulated initial MS power down regulation after handover in, dB.

Number of TCH connections for signalling. Object type CLTCH.

Number of handover attempts from underlaid to overlaid subcell. The corresponding counter for handover to underlaid subcell is called HOAATUL.

Number of successful assignment attempts to overlaid subcell. The corresponding counter for underlaid subcell is called HOSUCUL.

Number of handover attempts from overlaid to underlaid subcell due to maximum number of intracell handovers in overlaid subcell.

Number of successful handover attempts from overlaid to underlaid subcell due to maximum number of intracell handovers in overlaid subcell.

Number of handover attempts from underlaid to overlaid subcell due to maximum number of intracell handovers in underlaid subcell.

Number of successful handover attempts from underlaid to overlaid subcell due to maximum number of intracell handovers in underlaid subcell.

Subcell change attempts from overlaid to underlaid when reaching LOL criteria for subcell change.

Successful subcell changes from overlaid to underlaid when the LOL criterion was the reason for the subcell change.

Subcell change attempts from overlaid to underlaid when reaching DTCB criteria for subcell change.

Successful subcell changes from overlaid to underlaid when the DTCB criterion was the reason for the subcell change.

Subcell change attempts from overlaid to underlaid when reaching TAOL criteria for subcell change.

Successful subcell changes from overlaid to underlaid when the TAOL criterion was the reason for the subcell change.

Subcell change attempts from overlaid to underlaid due to dynamic underlaid/overlaid subcell load distribution.

Successful subcell changes from overlaid to underlaid when subcell load distribution (SCLD) was the reason for change.

Subcell change attempts from underlaid to overlaid when subcell load distribution (SCLD) was the reason for change.

Number of intra cell handover attempts, due to FR to HR channel rate change triggered by high cell load or high Abis load, made by a mobile capable of AMR Narrowband, but not capable of AMR Wideband.

Number of successful intra cell handovers, due to FR to HR channel rate change triggered by high cell load or high Abis load, made by a mobile capable of AMR Narrowband, but not capable of AMR Wideband.

Number of intra cell handover attempts, due to FR to HR channel rate change triggered by high cell load or high Abis load, made by an AMR Wideband capable mobile.Number of successful intra cell handovers, due to FR to HR channel rate change triggered by high cell load or high Abis load, made by an AMR Wideband capable mobile.

Number of intra cell handover attempts, due to FR to HR channel rate change triggered by high cell load or high Abis load, made by a mobile not capable of AMR.

Number of successful intra cell handovers, due to FR to HR channel rate change triggered by high cell load or high Abis load, made by a mobile not capable of AMR.

Number of successful intra cell handovers due to FR to HR channel rate change triggered by high Abis load, made by a mobile capable of AMR Narrowband, but not capable of AMR Wideband.

Successful subcell changes from underlaid to overlaid when subcell load distribution (SCLD) was the reason for change

Accumulated number of locating evaluations.

Accumulated number of locating evaluations where HCS ranking differs from basic ranking.

Number of successful handovers at high handover rate.

Number of connections successfully established, TFESTPGSMSUBfor overlaid subcells.

Number of dropped connections due to failure, TFDROPPGSMSUBfor overlaid subcells.

Congestion time, TFCONGPGSMSUB for overlaid subcells.

Traffic level accumulator, TFTRALPACCSUBfor overlaid subcells.

Accumulated number of idle TCH/F in the underlaid subcell in interference band 1. The corresponding counter for half-rate and overlaid subcell is ITHOSIB1.

Accumulated time in seconds when CLS evaluation is performed in the cell.

Total time for the CLS feature being activate in seconds.

Handover attempts due to CLS.

Successful handovers due to CLS.

Assignment attempts for multislot connections.

Successful assignment attempts for multislot connections.

Handover attempts for multislot connections.

Successful handovers for multislot connections.

Number of requested channels for multislot connections.

Number of received channels for multislot connections.

Configuration change attempts for multislot connections initiated by the MSC.

Traffic level accumulator for seized HSCSD main channels.

Traffic level accumulator for seized non essential HSCSD secondary channels.

Traffic level accumulator for seized essential HSCSD secondary channels.

Number of handover attempts due to preemption.

Number of disconnections due to preemption.

Number of preemption failures.

Number of all re-configuration attempts from TCH to SDCCH.

Number of all re-configuration attempts from SDCCH to TCH.

Traffic level accumulator for dual band MSs. The number of accumulations of the counter is counted in TFNSCAN in the object type CELTCHF, see Section 5.3.

Dropped dual band MS connections due to failure.

Assignment complete for all (dual band) MS power classes.

Assignment attempts for all (dual band) MS power classes.

Accumulated time in seconds when the servings cells channel availability is below or equal to HCSOUT. Note that the counter is only stepped it the feature HCS Traffic Distribution is active.

Configuration change attempts for multislot connections initiated by the BSC. The attempts are made internal in the BSC and do not necessarily lead to sending any messages to the MS or the MSC. In a situation where a connection has less channels than required for a longer period, the counter will be incremented every 5 seconds.

Time spent on full rate AMR (Speech Version 3) codec mode 1 (of the codec set as defined in the BSC) downlink. TFV3CM2DL is the corresponding counter for AMR codec mode 2. TFV3CM3DL is the corresponding counter for AMR codec mode 3. TFV3CM4DL is the corresponding counter for AMR codec mode 4.

Time spent on full rate AMR (Speech Version 3) codec mode 1 uplink. TFV3CM2UL is the corresponding counter for AMR codec mode 2. TFV3CM3UL is the corresponding counter for AMR codec mode 3. TFV3CM4UL is the corresponding counter for AMR codec mode 4.

Time spent on half rate AMR (Speech Version 3) codec mode 1 downlink. THV3CM2DL is the corresponding counter for AMR codec mode 2. THV3CM3DL is the corresponding counter for AMR codec mode 3. THV3CM4DL is the corresponding counter for AMR codec mode 4.

Time spent on half rate AMR (Speech Version 3) codec mode 1 uplink. THV3CM2UL is the corresponding counter for AMR codec mode 2. THV3CM3UL is the corresponding counter for AMR codec mode 3. THV3CM4UL is the corresponding counter for AMR codec mode 4.

Time spent on full rate AMR Wideband (Speech Version 5) codec mode 1 (of the codec set as defined in the BSC) downlink. TFV5CM2DL is the corresponding counter for AMR Wideband (Speech Version 5) codec mode 2. TFV5CM3DL is the corresponding counter for AMR Wideband (Speech Version 5) codec mode 3.

Time spent on full rate AMR Wideband (Speech Version 5) codec mode 1 uplink. TFV5CM2UL is the corresponding counter for AMR Wideband (Speech Version 5) codec mode 2. TFV5CM3UL is the corresponding counter for AMR Wideband (Speech Version 5) codec mode 3.

The total number of queued GSM priority connections. Only stepped once per received Assignment Request message where the MS gets queued.

The total number of GSM priority connections not inserted in the queue when the queue was full, due to too low ranking.

The total number of GSM priority connections removed from the queue due to time-out of GSM queuing timer T11.

The total number of times a GSM or UTRAN non-priority connection allocates a channel in a cell where a queue exists.

Number of queued UTRAN Priority Connections. The counter is only stepped once per received HANDOVER REQUEST message where MS gets queued.

Number of UTRAN Priority Connections removed from the queue when queue is full, due to arrival of a higher ranked GSM or UTRAN Priority Connection.

Number of UTRAN Priority Connections not inserted in the queue when queue is full, due to low ranking.

Number of UTRAN Priority Connections that have been removed from the queue due to timeout of TQHO.

Number of queued UTRAN Priority Connections that are released due to reception of CLEAR COMMAND message from the MSC.

Separate traffic level counters for full-rate, half-rate and PS traffic. Congestion counters would not be relevant for an individual channel group.

Separate dropped call and reason for drop counters for full-rate and half-rate.

A full set of Speech Quality Supervision counters plus intra-cell handover counters.

Full-rate traffic level accumulator.

Number of available TCH accumulator. Both FR and HR.

Number of scans taken for traffic level accumulators in channel group zero. Both FR and HR.

Number accumulations of allocated PDCHs in channel group zero.

Number of allocated PDCHs on channel group zero accumulator.

Number of dropped TCH/F connections in channel group zero.

Number of dropped TCH/F connections at bad quality downlink.

Number of dropped TCH/F connections at bad quality uplink.

Number of dropped TCH/F connections at bad quality both links.

Number of dropped TCH/F connections at high FER downlink

Number of dropped TCH/F connections at high FER uplink

Number of dropped TCH/F connections at high FER both links

Number of dropped TCH/F connections at low signal strength downlink.

Number of dropped TCH/F connections at low signal strength uplink.

Number of dropped TCH/F connections at low signal strength both links.

Number of suddenly lost TCH/F connections.

Number of dropped TCH/F connections at excessive TA.

Number of measurements with good speech quality UL in channel group zero when an AMR Narrowband codec is used and the channel rate is FR.

Number of measurements with good speech quality UL in channel group zero when an AMR Wideband codec is used.

Number of measurements with acceptable speech quality UL in channel group zero when an AMR Narrowband codec is used and the channel rate is FR.

Number of measurements with acceptable speech quality UL in channel group zero when an AMR Wideband codec is used.

Number of measurements with unsatisfactory speech quality UL in channel group zero when an AMR Narrowband codec is used and the channel rate is FR.

Number of measurements with unsatisfactory speech quality UL in channel group zero when an AMR Wideband codec is used

Half-rate traffic level accumulator.

Number of dropped TCH/H connections in channel group zero.

Number of dropped TCH/H connections at bad quality downlink.

The total number of GSM priority connections removed from the queue due to the arrival of a higher ranked GSM or UTRAN priority connection (and the queue was full).

The total number of queued GSM priority connections released from the queue due to loss of radio contact with the MS or because the Service User abandon the call.

Number of measurements with good speech quality UL in channel group zero when the channel rates are FR and HR and when the speech version is SPV1 or SPV2.

Number of measurements with acceptable speech quality UL in channel group zero when the channel rates are FR and HR and when the speech version is SPV1 or SPV2.

Number of measurements with unsatisfactory speech quality UL in channel group zero when the channel rates are FR and HR and when the speech version is SPV1 or SPV2.

Number of dropped TCH/H connections at bad quality uplink.

Number of dropped TCH/H connections at bad quality both links.

Number of dropped TCH/H connections at high FER downlink

Number of dropped TCH/H connections at high FER uplink

Number of dropped TCH/H connections at high FER both links

Number of dropped TCH/H connections at low signal strength downlink.

Number of dropped TCH/H connections at low signal strength uplink.

Number of dropped TCH/H connections at low signal strength both links.

Number of suddenly lost TCH/H connections.

Number of dropped TCH/H connections at excessive TA.

Number of intra cell handover attempts at bad uplink quality. Both FR and HR.

Number of intra cell handover attempts at bad downlink quality. Both FR and HR.

Number of intra cell handover attempts at bad quality UL on both links. Both FR and HR.

Number of measurements with good speech quality UL in channel group zero when an AMR Narrowband codec is used and the channel rate is HR.

Number of measurements with acceptable speech quality UL in channel group zero when an AMR Narrowband codec is used and the channel rate is HR.

Number of measurements with unsatisfactory speech quality UL in channel group zero when an AMR Narrowband codec is used and the channel rate is HR.

Number of measurements with good speech quality DL in channel group zero when channel rates are FR and HR and when the speech version is SPV1 or SPV2.

Number of measurements with good speech quality DL in channel group zero when an AMR Narrowband codec is used and the channel rate is FR.

Number of measurements with acceptable speech quality DL in channel group zero when an AMR Narrowband codec is used and the channel rate is FR.

Number of measurements with unsatisfactory speech quality DL in channel group zero when an AMR Narrowband codec is used and the channel rate is FR.

Number of measurements with good speech quality DL in channel group zero when an AMR Wideband codec is used and the channel rate is FR.

Number of measurements with acceptable speech quality DL in channel group zero when an AMR Wideband codec is used and the channel rate is FR.

Number of measurements with unsatisfactory speech quality DL in channel group zero when an AMR Wideband codec is used and the channel rate is FR.

Number of measurements with good speech quality DL in channel group zero when an AMR Narrowband codec is used and the channel rate is HR.

Number of measurements with acceptable speech quality DL in channel group zero when an AMR Narrowband codec is used and the channel rate is HR.

Number of measurements with unsatisfactory speech quality DL in channel group zero when an AMR Narrowband codec is used and the channel rate is HR.

Number of attempts to establish a DTM connection, stepped before the MS is allowed to enter DTM mode.

Number of attempts to allocate channels for a DTM connection. This counter is stepped when all checks to see if the MS is allowed to enter DTM are performed.

Number of successful establishments of a DTM connection, TCH/FR Speech Version 1.




Number of successful establishments of a DTM connection, TCH/HR Speech Version 1.

Number of successful establishments of a DTM connection, TCH/HR Speech Version 3.

Traffic level accumulator for SAIC capable MSs with channel rate HR.

Number of accumulations of the counter SAICTRALACC and THSAICTRALACC, respectively.

Number of measurements with acceptable speech quality DL in channel group zero when channel rates are FR and HR and when the speech version is SPV1 or SPV2.

Number of measurements with unsatisfactory speech quality in DL channel group zero when channel rates are FR and HR and when the speech version is SPV1 or SPV2.

Traffic level counter (accumulation counter) that gives continuous information about the number of active SAIC (Single Antenna Interference Cancellation) capable MSs per cell. SAIC is in 3GPP TS 24.008 called “Downlink Advanced Receiver Performance”. The corresponding internal traffic level counter is incremented when Classmark 3 information for a SAIC capable MS is received.

Number of bursts with a nominal power > 100% of the available power.

Number of bursts with a nominal power <= 100% and > 90% of the available power.





Number of bursts with a nominal power <= 50% of the available power.

Total number of TCH bursts.

Number of TCH bursts with reduced power due to power backoff.

Accumulated TCH power reduction in dB.

Total number of PDCH bursts.

Number of PDCH bursts with reduced power due to power backoff.

Accumulated PDCH power reduction in dB.

Total number of other bursts.

Number of other bursts with reduced power due to power backoff.

Accumulated other power reduction in dB.

Total number of SDCCH bursts

Number of SDCCH bursts with reduced power due to power backoff

Accumulated SDCCH power reduction in dB

Are usually for monitoring of specific features and impacts.

Total LLC data volume transferred for all types of streaming (EIT) PFCs downlink.

Total LLC data volume transferred in interactive and background PFCs downlink.

Total LLC data volume transferred in interactive and background PFCs uplink.

Total LLC data volume of GMM/SM signalling transferred downlink.

Total LLC data volume of GMM/SM signalling transferred uplink.

Total number of “traffic injections”, which are attempted in the cell every 5 minutes.

Accumulation of (LLC throughput * LLC data volume) for GPRS capable MSs downlink, traffic classes background and interactive.

Accumulation of (LLC throughput * LLC data volume) for EGPRS capable MSs downlink, traffic classes background and interactive.

Accumulation of (LLC throughput * LLC data volume) for GPRS capable MSs uplink, traffic classes background and interactive.

Accumulation of (LLC throughput * LLC data volume) for EGPRS capable MSs uplink, traffic classes background and interactive.

Accumulated LLC data volume for EGPRS capable MSs downlink, traffic classes background and interactive.

Accumulated LLC data volume for GPRS capable MSs downlink, traffic classes background and interactive.

Accumulated LLC data volume for EGPRS capable MSs uplink, traffic classes background and interactive.

Accumulated LLC data volume for GPRS capable MSs uplink, traffic classes background and interactive.

Number of all accepted random accesses

Accumulated total LLC data received on the downlink inGPRS mode transfers for QoS class Background.

The total number of attempts to establish a downlink TBF

The total number of attempts to establish a downlink TBF that resulted in a failure due to lack of resources

Number of Handover Commands sent to the MS (External)

Number of Handover Commands sent to the MS (External)

The LLC user data volume generated by SAIC capable mobiles on the uplink. (GMM/SM signalling is not included). Note: The counter ULSAICVOL includes transfers for both DTM and non-DTM.

The LLC user data volume generated by SAIC capable mobiles on the downlink. (GMM/SM signalling is not included). Note: The counter DLSAICVOL includes transfers for both DTM and non-DTM.

These counters are directly related to the ability of the BSS to transport IP packets. Typically they are sets of counters that focus on one area of BSS performance (which could usually be affected by a number of different factors) which impacts the user perception of the service. For example the IP throughput counters on cell level measure the speed with which the BSS can transfer IP packets.

These counters are indirectly related to the ability of the BSS to transport IP packets. They should be used for trouble-shooting purposes to identify the specific factors that are causing the level one indicators to show poor performance. For example the GPRS traffic load counters show how the number of users sharing the available PDCHs is affecting the measured IP throughput. They should not be used on their own for any dimensioning purposes.

Number of five-minute intervals the cell is suspected to be unavailable for GPRS. Will be incremented for each five-minute interval there is no Packet Switched traffic, after at least 5 traffic injections have been attempted within a five minute interval.

Number of Handover Commands sent to the MS (Internal)

Number of Handover Commands sent to the MS (Internal)

Number of successful handover to the neighbouring cell (External)

Number of successful handover to the neighbouring cell (External)

Number of successful handover to the neighbouring cell (Internal)

Number of successful handover to the neighbouring cell (Internal)

Number of times the entire contents of a downlink buffer in the PCU were discarded

The counter LDISRR counts the total number of times,per cell, that the entire content of the downlink LLC PDUsignalling is not included in the counts.)

Number of DL TBFs (of any mode) scanned where only1 out of a possible 2 timeslots were reserved










Total Number of first Page Request

Total no of successful first page response

Total no of successful second page response

Number of packet data random accesses

Number of failed random accesses

Sum of Successful External Assignment Handovers to Better Cell (Incoming Handover)

Sum of Successful External Assignment Handovers to Worse Cell (Incoming Handover)

Sum of Successful External Handovers (Incoming Handover)

Sum of Successful External Assignment Handovers to Better Cell (Outgoing Handover)

Sum of Successful External Assignment Handovers to Worse Cell (Outgoing Handover)

Sum of Successful External Handovers (Outgoing Handover)

Sum of Successful Internal Assignment Handovers to Better Cell (Incoming Handover)

Sum of Successful Internal Assignment Handovers to Worse Cell (Incoming Handover)

Sum of Successful Internal Handovers (Incoming Handover)

Sum of Successful Internal Assignment Handovers to Better Cell (Outgoing Handover)

Sum of Successful Internal Assignment Handovers to Worse Cell (Outgoing Handover)

Sum of Successful Internal Handovers (Outgoing Handover)

Total Number of Drops on TCH

Number of assignment complete messages for allMS power classes in overlaid subcell, full-rate.

The total number of dropped full-rate TCH in overlaid subcell

Number of released TCH due to radio resource congestion in overlaid subcell

Number of accumulations of traffic level counter for full-rate TCH

Traffic level accumulator for full-rate TCH

Traffic level accumulator full rate

Number of assignment complete messages for all MSpower classes in underlaid subcell, half-rate

Number of assignment complete messages for all MSpower classes in overlaid subcell, half-rate

The total number of dropped half-rate TCH in underlaid subcell

The total number of dropped half-rate TCH in overlaid subcell

Number of released TCH signalling connections due to transcoder resource congestion during immediate assignment on TCH (HALF RATE)

Number of released TCH due to radio resource congestion in overlaid subcell for half rate

Number of accumulations of traffic level counter for half-rate TCH

Traffic level accumulator for half-rate TCH

Traffic level accumulator half rate

Total Number of Drops on TCH

between 4,5 and 16,5 dBQ. Accumulated number of SQI samples that represented acceptable speech quality for overlaid cells

Accumulated number of SQI samples for AMR full ratethat represented acceptable speech quality for overlaid cells

Accumulated number of SQI samples for AMR halfrate that represented acceptable speech quality for overlaid cells

<4,5 dBQ. Accumulated number of SQI samples that represented unacceptable speech quality for overlaid cells

Accumulated number of SQI samples for AMR full rate that represented unacceptable speech quality for overlaid cells

Accumulated number of SQI samples for AMR halfrate that represented unsatisfactory speech quality overlaid cells

>16,5 dBQ. Accumulated number of SQI samples thatrepresented good speech quality for overlaid cells

AF Accumulated number of SQI samples for AMR full ratethat represented good speech quality overlaid cells

Accumulated number of SQI samples for AMRhalf rate that represented good speech quality overlaid cells

ericsson 2g counters

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