2G HUAWEI KPIS

TYPE NAMECS_ACCESSIBILITY PAGING OVERLOAD RATECS_ACCESSIBILITY PAGING OVERLOAD CS NUMBERCS_ACCESSIBILITY PAGING OVERLOAD PS NUMBERCS_ACCESSIBILITY RACH_SUCCESS_RATECS_ACCESSIBILITY DISCARDED RACH NUMBERCS_ACCESSIBILITY SDCCH BLOCKING CONGESTIONCS_ACCESSIBILITY SDCCH BLOCKING CONGESTION NUMBERCS_ACCESSIBILITY SD_USAGE_MOC_CALLCS_ACCESSIBILITY SD_USAGE_MOC_SMSCS_ACCESSIBILITY SD_USAGE_MOC_MTCCS_ACCESSIBILITY SD_USAGE_MOC_EMERGENCYCS_ACCESSIBILITY SD_USAGE_MOC_CALL REESTABLISHMENTCS_ACCESSIBILITY SD_USAGE_MOC_LOCAITON UPDATINGCS_ACCESSIBILITY SD_USAGE_MOC_IMSI DETACHCS_ACCESSIBILITY SD_USAGE_MOC_PACKET SERVICECS_ACCESSIBILITY SDCCH SEIZ SUCCESS RATECS_ACCESSIBILITY SDCCH SEIZ FAIL NUMBERCS_ACCESSIBILITY IMMEDIATE_ASSIGNMENT_SUCCESS_RATECS_ACCESSIBILITY T3101_TIMER_EXPIRECS_ACCESSIBILITY TCH BLOCKING CALL SETUPCS_ACCESSIBILITY TCH BLOCKING HO CS_ACCESSIBILITY TCH BLOCKING CALL SETUP NUMBERCS_ACCESSIBILITY TCH BLOCKING HO NUMBERCS_ACCESSIBILITY TCH SEIZ SUCCESS RATECS_ACCESSIBILITY ASSIGNMENT SUCCESS RATECS_ACCESSIBILITY LOCATION UPDATE SUCCESS RATECS_ACCESSIBILITY TCH AVAILABILITYCS_ACCESSIBILITY SD AVAILABILITYCS_ACCESSIBILITY CELL OUT OF SERVICECS_ACCESSIBILITY AVERAGE CALL SETUP DURATIONCS_ACCESSIBILITY AVERAGE CALL ACCESS DURATIONCS_ACCESSIBILITY CHANNEL REQUIRED MOCCS_ACCESSIBILITY CHANNEL REQUIRED MTCCS_ACCESSIBILITY CHANNEL REQUIRED ECALLCS_ACCESSIBILITY CHANNEL REQUIRED RE ESTABLISHMENTCS_ACCESSIBILITY CHANNEL REQUIRED LOCATION UPDATECS_ACCESSIBILITY CHANNEL REQUIRED PACKET CALLCS_ACCESSIBILITY CHANNEL REQUIRED LMU AND RESERVEDCS_ACCESSIBILITY CHANNEL REQUIRED PROTOCOL INCOMPTCS_ACCESSIBILITY CHANNEL ACTIVATION TIMEOUT IMMEDIATE ASSIGNMENTCS_ACCESSIBILITY CHANNEL ACTIVATION TIMEOUT ASSIGNMENT PROCEDURECS_ACCESSIBILITY CHANNEL ACTIVATION TIMEOUT MODE MODIFYCS_ACCESSIBILITY CHANNEL ACTIVATION TIMEOUT INTRACELL HO CS_ACCESSIBILITY CHANNEL ACTIVATION TIMEOUT INCOMING INTERNAL INTERCELL

CS_ACCESSIBILITY CHANNEL ACTIVATION TIMEOUT INCOMING EXTERNALCS_ACCESSIBILITY FAILED ASSIGNMENTS ON A INTERFACE MOCCS_ACCESSIBILITY FAILED ASSIGNMENTS ON A INTERFACE MTCCS_ACCESSIBILITY FAILED ASSIGNMENTS ON A INTERFACE EMERGENCY CALLCS_ACCESSIBILITY FAILED ASSIGNMENTS ON A INTERFACE EMERGENCY REESTABCS_ACCESSIBILITY FAILED ASSIGNMENTS SIGNALIING CHANNELCS_ACCESSIBILITY REASON FAILED ASSIGNMENTS INVALID STATECS_ACCESSIBILITY REASON FAILED ASSIGNMENTS INVALID MESSAGECS_ACCESSIBILITY REASON FAILED ASSIGNMENTS CIC UNAVAILABLECS_ACCESSIBILITY REASON FAILED ASSIGNMENT A INTERFACE FAILURESCS_ACCESSIBILITY REASON FAILED ASSIGNEMNTS CLEAR COMMAND SEND BY BSCCS_ACCESSIBILITY REASON FAILED ASSIGNEMNTS NO CHANNELCS_ACCESSIBILITY REASON FAILED ASSIGNEMNTS TIME OUTCS_ACCESSIBILITY REASON FAILED ASSIGNEMNTS TERESTRIAL RES REQ FAILEDCS_ACCESSIBILITY REASON FAILED ASSIGNEMNTS NO ABIS RESOURCECS_ACCESSIBILITY REASON FAILED ASSIGNEMNTS REQUESTED SPEECH VERISONS UNAVAILACS_ACCESSIBILITY REASON FAILED ASSIGNEMNTS RADIO FAILUERCS_ACCESSIBILITY TRAFFIC VOLUME ON TCHCS_ACCESSIBILITY TRAFFIC VOLUME ON TCHFCS_ACCESSIBILITY TRAFFIC VOLUME ON TCHHCS_ACCESSIBILITY TRAFFIC VOLUME ON EFRCS_ACCESSIBILITY TRAFFIC VOLUME ON AMR TCHFCS_ACCESSIBILITY TRAFFIC VOLUME ON AMR TCHHCS_ACCESSIBILITY TRAFFIC VOLUME ON SDCS_ACCESSIBILITY TRX USEABILITYCS_ACCESSIBILITY SDCCH DROP RATECS_ACCESSIBILITY SDCCH DROP NUMBERCS_ACCESSIBILITY SDCCH DROPS ERROR INDICATION T200CS_ACCESSIBILITY SDCCH DROPS ERROR INDICATION UDM RESPONSECS_ACCESSIBILITY SDCCH DROPS ERROR INDICATION SEQUENCE ERRORCS_ACCESSIBILITY SDCCH DROPS CONNECTION FAILURE RL FAILURECS_ACCESSIBILITY SDCCH DROPS CONNECTION FAILURE HO ACCESS FAILURECS_ACCESSIBILITY SDCCH DROPS CONNECTION FAILURE OM INTERVENTIONCS_ACCESSIBILITY SDCCH DROPS CONNECTION FAILURE NO RADIO RESOURCECS_ACCESSIBILITY SDCCH DROPS CONNECTION FAILURE OTHERCS_ACCESSIBILITY SDCCH DROPS RELEASE INDICATIONCS_ACCESSIBILITY SDCCH DROPS NO MR FOR LONG TIMECS_ACCESSIBILITY SDCCH DROPS ABIS TRESTRIAL FAILURECS_ACCESSIBILITY SDCCH DROPS EQUIPMENT FAILURECS_ACCESSIBILITY SDCCH DROPS FORCED HOCS_ACCESSIBILITY SDCCH DROPS RESOURCE CHECKCS_ACCESSIBILITY SD_RADIO_DROPS REASON TACS_ACCESSIBILITY SD RADIO DROPS REASON RX LEVELCS_ACCESSIBILITY SD RADIO DROPS REASON RX QUALCS_ACCESSIBILITY SD RADIO DROPS OTHER

CS_ACCESSIBILITY NUMBER OF CHANNEL CONVERSION (TCH-SDCCH)CS_ACCESSIBILITY NUMBER OF CHANNEL CONVERSION (SDCCH-TCH)CS_ACCESSIBILITY MAX NUMBER OF BUSY CHANNELS (SDCCH)CS_ACCESSIBILITY MAX NUMBER OF BUSY CHANNELS (TCHF)CS_ACCESSIBILITY MAX NUMBER OF BUSY CHANNELS (TCHH)CS_ACCESSIBILITY MEAN DURATION OF CALL ACCESS

CS_ACCESSIBILITY MEAN DURATION OF CALL ESTABLISHMENT

SHORT NAME HUAWEI FORMULA VALUEPAG_OVER_LOAD_R (L3188C+L3188D) %PAG_OVER_LOAD_CS_N L3188C #PAG_OVER_LOAD_PS_N L3188D #RACH_SUCC_RATE ((A300A+A300C+A300D+A300E+A300F+A300H+A300I+A30 %RACH_DISCARDED_N L3189I #SD_BLK_R K3001/iif(K3000=0,1,K3000)*100 %SD_BLK_N K3001 #SD_USAGE_MOC_CALL_N A3030A #SD_USAGE_MOC_SMS_N A3030B #SD_USAGE_MTC_N A3030C #SD_USAGE_EMER_N A3030D #SD_USAGE_CALL_RESTAB_N A3030E #SD_USAGE_LU_N A3030F #SD_USAGE_IMSI_N A3030G #SD_USAGE_PS_N A3030H #SD_SEIZ_SUCC_R (CR330A-CR330B)/iif(CR330A=0,1,CR330A)*100 %SD_SEIZ_FAIL_N CR330B #IASS_SUCC_R CA3030J/iif(CA301J=0,1,CA301J)*100 %T3101_EXPIRE_N CA304 #TCH_RAW_BLK_R (K3021+K3011A) %TCH_HO_BLK K3011B/iif(K3010B=0,1,K3010B)*100 %TCH_RAW_BLK_N K3011A #TCH_HO_BLK_N K3011B #TCH_SEIZ_SUCC_R (CR331A-CR331B)/iif(CR331A=0,1,CR331A)*100 %ASS_SUCC_R CA313/iif(CA310=0,1,CA310)*100 %LOC_UPDATE_SUCC_RATE %TCH_AVAILABILITY K3015/iif(K3016=0,1,K3016)*100 %SD_AVAILABILITY K3005/iif(K3006=0,1,K3006)*100 %CELL_OUT_SERVE_DUR (86400-CR373) SecAVG_CALL_SETP_DUR AA3251 secAVG_CALL_ACCESS_DUR AA3250 secCH_REQ_MOC_N A300A %CH_REQ_MTC_N A300C #CH_REQ_ECALL_N A300D #CH_REQ_REESTAB_N A300E #CH_REQ_LU_N A300F #CH_REQ_PACK_CALL_N A300H #CH_REQ_LMU_RES_N A300I #CH_REQ_PROT_INCOM_N A300K #CH_ACT_TO_IMAS_N CR330C #CH_ACT_TO_ASS_N CR331C #CH_ACT_TO_MMOD_N CR332C #CH_ACT_TO_INTRACELL_N CR333C #CH_ACT_TO_INCOM_INTER_N CR334C #

CH_ACT_TO_INCOM_EXT_N CR335C #FAIL_ASS_A_MOC_N A312Aa #FAIL_ASS_A_MTC_N A312Ca #FAIL_ASS_A_ECALL_N A312Da #FAIL_ASS_A_REESTAB_N A312Ea #FAIL_ASS_SIG_CH_N A312S #REA_FAIL_ASS_INVALID_STAT_N A3129I #REA_FAIL_ASS_INVALID_MSG_N A3129J #REA_FAIL_ASS_CIC_UNVAVAI_N A3129E #REA_FAIL_ASS_A_INTER_FAIL_N A3129G #REA_FAIL_ASS_A_CC_MSC_N A3129H #REA_FAIL_ASS_NR_N A312A #REA_FAIL_ASS_TO_N A3129C #REA_FAIL_ASS_TRES_RES_FAIL_N A3129N #REA_FAIL_ASS_NO_ABIS_N A312F #REA_FAIL_ASS_SPE_VER_UNAVIL_N A3129S #REA_FAIL_ASS_RIMF_FAIL_N CA315 #TCH_TRAFFIC K3014 ErlTCH_TRAF_FR (([CR3551]*24)-[AR3551C]-[AR3557C]) ErlTCH_TRAF_HR (([CR3552]*24)-[AR3552C]) ErlTCH_TRAF_EFR AR3557C

TCH_TRAF_AMR_FR AR3551C

TCH_TRAF_AMR_HR AR3552C

SD_TRAFFIC K3004 ErlTRX_USE S3656/iif(S3655=0,1,S3655)*100 %SD_DROP_R CM30/iif(CA3030J=0,1,CA3030J)*100 %SD_DROP_N CM30 #SD_DROP_ERR_IND_T200_N M3000A #SD_DROP_ERR_IND_UDM_RSP_N M3000B #SD_DROP_ERR_IND_SE_N M3000C #SD_DROP_CONN_FAIL_RLF_N M3001A #SD_DROP_CONN_FAIL_HO_ACCESS_N M3001B #SD_DROP_CONN_FAIL_OMI_N M3001C #SD_DROP_CONN_FAIL_NR_N M3001D #SD_DROP_CONN_FAIL_OTH_N M3001E #SD_DROP_RELEASE_IND_N M3002 #SD_DROP_NO_MR_N M302 #SD_DROP_ABIS_FAIL_N M303 #SD_DROP_EQ_FAIL_N M304 #SD_DROP_FORCED_HO_N M305 #SD_DROP_RES_CHECK_N M306 #SD_RADIO_DROP_TA_N M3020A #SD_RADIO_DROP_RXLEV_N M3020B #SD_RARIO_DROP_RXQUAL_N M3020C #SD_RADIO_DROP_OTHER_N M3020D #

R3516AR3516BR3560R3561R3562

MEAN_DUR_ACCESS AA032MEAN_DUR_ESTAB AA033

MS ACESS FORMATPAG_OVER_LOAD_R:(L3188C+L3188D)PAG_OVER_LOAD_CS_N:L3188CPAG_OVER_LOAD_PS_N:L3188DRACH_SUCC_RATE:((A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K)-L3189I)/iif((A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K)=0,1,(A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K))*100RACH_DISCARDED_N:L3189ISD_BLK_R:K3001/iif(K3000=0,1,K3000)*100SD_BLK_N:K3001SD_USAGE_MOC_CALL_N:A3030ASD_USAGE_MOC_SMS_N:A3030BSD_USAGE_MTC_N:A3030CSD_USAGE_EMER_N:A3030DSD_USAGE_CALL_RESTAB_N:A3030ESD_USAGE_LU_N:A3030FSD_USAGE_IMSI_N:A3030GSD_USAGE_PS_N:A3030HSD_SEIZ_SUCC_R:(CR330A-CR330B)/iif(CR330A=0,1,CR330A)*100SD_SEIZ_FAIL_N:CR330BIASS_SUCC_R:CA3030J/iif(CA301J=0,1,CA301J)*100T3101_EXPIRE_N:CA304TCH_RAW_BLK_R:(K3021+K3011A)TCH_HO_BLK:K3011B/iif(K3010B=0,1,K3010B)*100TCH_RAW_BLK_N:K3011ATCH_HO_BLK_N:K3011BTCH_SEIZ_SUCC_R:(CR331A-CR331B)/iif(CR331A=0,1,CR331A)*100ASS_SUCC_R:CA313/iif(CA310=0,1,CA310)*100LOC_UPDATE_SUCC_RATE:TCH_AVAILABILITY:K3015/iif(K3016=0,1,K3016)*100SD_AVAILABILITY:K3005/iif(K3006=0,1,K3006)*100CELL_OUT_SERVE_DUR:(86400-CR373)AVG_CALL_SETP_DUR:AA3251AVG_CALL_ACCESS_DUR:AA3250CH_REQ_MOC_N:A300ACH_REQ_MTC_N:A300CCH_REQ_ECALL_N:A300DCH_REQ_REESTAB_N:A300ECH_REQ_LU_N:A300FCH_REQ_PACK_CALL_N:A300HCH_REQ_LMU_RES_N:A300ICH_REQ_PROT_INCOM_N:A300KCH_ACT_TO_IMAS_N:CR330CCH_ACT_TO_ASS_N:CR331CCH_ACT_TO_MMOD_N:CR332CCH_ACT_TO_INTRACELL_N:CR333CCH_ACT_TO_INCOM_INTER_N:CR334C

CH_ACT_TO_INCOM_EXT_N:CR335CFAIL_ASS_A_MOC_N:A312AaFAIL_ASS_A_MTC_N:A312CaFAIL_ASS_A_ECALL_N:A312DaFAIL_ASS_A_REESTAB_N:A312EaFAIL_ASS_SIG_CH_N:A312SREA_FAIL_ASS_INVALID_STAT_N:A3129IREA_FAIL_ASS_INVALID_MSG_N:A3129JREA_FAIL_ASS_CIC_UNVAVAI_N:A3129EREA_FAIL_ASS_A_INTER_FAIL_N:A3129GREA_FAIL_ASS_A_CC_MSC_N:A3129HREA_FAIL_ASS_NR_N:A312AREA_FAIL_ASS_TO_N:A3129CREA_FAIL_ASS_TRES_RES_FAIL_N:A3129NREA_FAIL_ASS_NO_ABIS_N:A312FREA_FAIL_ASS_SPE_VER_UNAVIL_N:A3129SREA_FAIL_ASS_RIMF_FAIL_N:CA315TCH_TRAFFIC:K3014TCH_TRAF_FR:(([CR3551]*24)-[AR3551C]-[AR3557C])TCH_TRAF_HR: (([CR3552]*24)-[AR3552C])TCH_TRAF_EFR:AR3557CTCH_TRAF_AMR_FR:AR3551CTCH_TRAF_AMR_HR:AR3552CSD_TRAFFIC:K3004TRX_USE:S3656/iif(S3655=0,1,S3655)*100SD_DROP_R:CM30/iif(CA3030J=0,1,CA3030J)*100SD_DROP_N:CM30SD_DROP_ERR_IND_T200_N:M3000ASD_DROP_ERR_IND_UDM_RSP_N:M3000BSD_DROP_ERR_IND_SE_N:M3000CSD_DROP_CONN_FAIL_RLF_N:M3001ASD_DROP_CONN_FAIL_HO_ACCESS_N:M3001BSD_DROP_CONN_FAIL_OMI_N:M3001CSD_DROP_CONN_FAIL_NR_N:M3001DSD_DROP_CONN_FAIL_OTH_N:M3001ESD_DROP_RELEASE_IND_N:M3002SD_DROP_NO_MR_N:M302SD_DROP_ABIS_FAIL_N:M303SD_DROP_EQ_FAIL_N:M304SD_DROP_FORCED_HO_N:M305SD_DROP_RES_CHECK_N:M306SD_RADIO_DROP_TA_N:M3020ASD_RADIO_DROP_RXLEV_N:M3020BSD_RARIO_DROP_RXQUAL_N:M3020CSD_RADIO_DROP_OTHER_N:M3020D

:R3516A:R3516B:R3560:R3561:R3562MEAN_DUR_ACCESS:AA032MEAN_DUR_ESTAB:AA033

RACH_SUCC_RATE:((A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K)-L3189I)/iif((A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K)=0,1,(A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K))*100

RACH_SUCC_RATE:((A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K)-L3189I)/iif((A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K)=0,1,(A300A+A300C+A300D+A300E+A300F+A300H+A300I+A300K))*100

NAMECALL DROPS ON TCH INCLUDING HOCALL DROPS ON TCH EXLUDING HOMINUTES PER DROPRADIO DROP RATEHO DROP RATETOTAL DROPSHO DROPSRADIO DROPSTCH DROPS ERROR INDICATIONSTCH DROPS CONNECTION FAILURETCH DROPS RELEASE INDICATIONTCH DROPS ERROR INDICATION T200TCH DROPS ERROR INDICATION UDM RESPONSETCH DROPS ERROR INDICATION SEQUENCE ERRORTCH DROPS CONNECTION FAILURE RL FAILURETCH DROPS CONNECTION FAILURE HO ACCESS FAILURETCH DROPS CONNECTION FAILURE OM INTERVENTIONTCH DROPS CONNECTION FAILURE NO RADIO RESOURCETCH DROPS CONNECTION FAILURE OTHERTCH DROPS RELEASE INDICATIONTCH DROPS NO MR FOR LONG TIMETCH DROPS ABIS TRESTRIAL FAILURETCH DROPS EQUIPMENT FAILURETCH DROPS FORCED HOTCH DROPS RESOURCE CHECKTCH DROP TATCH DROP UL REC LevelTCH DROP DL LevelTCH DROP UL/DL LevelTCH DROP UL FERTCH DROP DL FERTCH DROP UL/DL FERTCH DROP UL QUALTCH DROP DL QUALTCH DROP UL/DL QuALTCH DROP OTHERNORMAL SPEECH DISCONNECTIONSBAD SPEECH CONNECTIONSNUMBER OF MUTE TIMESMEAN TA DURING RADIO LINK FAILUREINTERFERENCE BAND SDCCH 1INTERFERENCE BAND SDCCH 2INTERFERENCE BAND SDCCH 3INTERFERENCE BAND SDCCH 4

INTERFERENCE BAND SDCCH 5INTERFERENCE BAND TCH 1 %INTERFERENCE BAND TCH 2 %INTERFERENCE BAND TCH 3 %INTERFERENCE BAND TCH 4 %INTERFERENCE BAND TCH 5 %Uplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareUplink Quality ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA Share

TA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareTA ShareRADIO LINK FAILURES PER TRXUL DL Balance Level 1UL DL Balance Level 2UL DL Balance Level 3UL DL Balance Level 4UL DL Balance Level 5UL DL Balance Level 6UL DL Balance Level 7UL DL Balance Level 8UL DL Balance Level 9UL DL Balance Level 10UL DL Balance Level 11MAIN LEVEL MRDIVERSITY LEVEL MRUplink Interference MessageDownlink interference indication messageMean Quality of UL SignalMean Quality of DL Signal

SHORT NAME HUAWEI FORMULADCR_INCL_HO CM33/iif((K3013A+K3013B+K3023)=0,1,(K3013A+K3013B+K

DCR_EXCLU_HO CM33/iif((K3013A+CH323+CH343-CH313-CH333)=0,1,(K30

MPD_SUB CM33/iif(K3014=0,1,K3014)*60DCR_RADIO CM330/iif((K3013A+K3013B)=0,1,(K3013A+K3013B))*100DCR_HO (RH3331+K3012B)TOTAL_DROPS_N CM33HO_DROPS_N (RH3331+K3012B)RADIO_DROPS_N CM33CTCH_DROP_ERR_IND_N (M3100A+M3200A+M3100B+M3200B+M3100C+M3200C)TCH_DROP_CONN_FAIL_N (M3101A+M3201A+M3101B+M3201B+M3101C+M3201C+M3TCH_DROP_RELEASE_IND_N (M3102+M3202)TCH_DROP_ERR_IND_T200_N M3100A+M3200ATCH_DROP_ERR_IND_UDM_RSP_N M3100B+M3200BTCH_DROP_ERR_IND_SE_N (M3100C+M3200C)TCH_DROP_CONN_FAIL_RLF_N (M3101A+M3201A)TCH_DROP_CONN_FAIL_HO_ACCESS_N (M3101B+M3201B)TCH_DROP_CONN_FAIL_OMI_N (M3101C+M3201C)TCH_DROP_CONN_FAIL_NR_N (M3101D+M3201D)TCH_DROP_CONN_FAIL_OTH_N (M3101E+M3201E)TCH_DROP_RELEASE_IND_N (M3102+M3202)TCH_DROP_NO_MR_N (M312+M322)TCH_DROP_ABIS_FAIL_N (M313+M323)TCH_DROP_EQ_FAIL_N (M314+M324)TCH_DROP_FORCED_HO_N (M315+M325)TCH_DROP_RES_CHECK_N M316TCH_DROP_TA_N M3030ATCH_DROP_UL_LEV_N M3030BTCH_DROP_DL_LEV_N M3030CTCH_DROP_UL_DL_LEV_N M3030DTCH_DROP_UL_FER_N M3030ETCH_DROP_DL_FER_N M3030FTCH_DROP_UL_DL_FER_N M3030GTCH_DROP_UL_QUAL_N M3030HTCH_DROP_DL_QUAL_N M3030ITCH_DROP_UL_DL_QUAL_N M3030JTCH_DROP_OTH_N M3030KSPEECH_DISC_NOR_N A03701SPEECH_DISC_BAD_N A03702CALL_MUTE_N M3128AMEAN_TA_RLF (AS4347D+AS4348D)IB_SD_1_PER S4200A/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0

IB_SD_2_PER S4200B/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0

IB_SD_3_PER S4200C/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0

IB_SD_4_PER S4200D/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0

IB_SD_5_PER S4200E/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0

IB_TCH_1_PER (S4207A+S4208A)/iif((S4207A+S4208A+S4207B+S4208B

IB_TCH_2_PER (S4207B+S4208B)/iif((S4207A+S4208A+S4207B+S4208B

IB_TCH_3_PER (S4207C+S4208C)/iif((S4207A+S4208A+S4207B+S4208B

IB_TCH_4_PER (S4207D+S4208D)/iif((S4207A+S4208A+S4207B+S4208B

IB_TCH_5_PER (S4207E+S4208E)/iif((S4207A+S4208A+S4207B+S4208B

UL_Q_0_PER (CS410C+CS410A)/iif(UL_SUM=0,1,UL_SUM)*100UL_Q_1_PER (CS411C+CS411A)/iif(UL_SUM=0,1,UL_SUM)*100UL_Q_2_PER (CS412C+CS412A)/iif(UL_SUM=0,1,UL_SUM)*100UL_Q_3_PER (CS413C+CS413A)/iif(UL_SUM=0,1,UL_SUM)*100UL_Q_4_PER (CS414C+CS414A)/iif(UL_SUM=0,1,UL_SUM)*100UL_Q_5_PER (CS415C+CS415A)/iif(UL_SUM=0,1,UL_SUM)*100UL_Q_6_PER (CS416C+CS416A)/iif(UL_SUM=0,1,UL_SUM)*100UL_Q_7_PER (CS417C+CS417A)/iif(UL_SUM=0,1,UL_SUM)*100DL_Q_0_PER (CS410D+CS410B)/iif(DL_SUM=0,1,UL_SUM)*100DL_Q_1_PER (CS411D+CS411B)/iif(DL_SUM=0,1,UL_SUM)*100DL_Q_2_PER (CS412D+CS412B)/iif(DL_SUM=0,1,UL_SUM)*100DL_Q_3_PER (CS413D+CS413B)/iif(DL_SUM=0,1,UL_SUM)*100DL_Q_4_PER (CS414D+CS414B)/iif(DL_SUM=0,1,UL_SUM)*100DL_Q_5_PER (CS415D+CS415B)/iif(DL_SUM=0,1,UL_SUM)*100DL_Q_6_PER (CS416D+CS416B)/iif(DL_SUM=0,1,UL_SUM)*100DL_Q_7_PER (CS417D+CS417B)/iif(DL_SUM=0,1,UL_SUM)*100TA0 S4400A/iif(TA_SUM=0,1,TA_SUM)*100TA1 S4401A/iif(TA_SUM=0,1,TA_SUM)*100TA2 S4402A/iif(TA_SUM=0,1,TA_SUM)*100TA3 S4403A/iif(TA_SUM=0,1,TA_SUM)*100TA4 S4404A/iif(TA_SUM=0,1,TA_SUM)*100TA5 S4405A/iif(TA_SUM=0,1,TA_SUM)*100TA6 S4406A/iif(TA_SUM=0,1,TA_SUM)*100TA7 S4407A/iif(TA_SUM=0,1,TA_SUM)*100TA8 S4408A/iif(TA_SUM=0,1,TA_SUM)*100TA9 S4409A/iif(TA_SUM=0,1,TA_SUM)*100TA10 S4410A/iif(TA_SUM=0,1,TA_SUM)*100TA11 S4411A/iif(TA_SUM=0,1,TA_SUM)*100TA12 S4412A/iif(TA_SUM=0,1,TA_SUM)*100TA13 S4413A/iif(TA_SUM=0,1,TA_SUM)*100TA14 S4414A/iif(TA_SUM=0,1,TA_SUM)*100TA15 S4415A/iif(TA_SUM=0,1,TA_SUM)*100TA16 S4416A/iif(TA_SUM=0,1,TA_SUM)*100TA17 S4417A/iif(TA_SUM=0,1,TA_SUM)*100TA18 S4418A/iif(TA_SUM=0,1,TA_SUM)*100TA19 S4419A/iif(TA_SUM=0,1,TA_SUM)*100TA20 S4420A/iif(TA_SUM=0,1,TA_SUM)*100TA21 S4421A/iif(TA_SUM=0,1,TA_SUM)*100TA22 S4422A/iif(TA_SUM=0,1,TA_SUM)*100

TA23 S4423A/iif(TA_SUM=0,1,TA_SUM)*100TA24 S4424A/iif(TA_SUM=0,1,TA_SUM)*100TA25 S4425A/iif(TA_SUM=0,1,TA_SUM)*100TA26 S4426A/iif(TA_SUM=0,1,TA_SUM)*100TA27 S4427A/iif(TA_SUM=0,1,TA_SUM)*100TA28 S4428A/iif(TA_SUM=0,1,TA_SUM)*100TA29 S4429A/iif(TA_SUM=0,1,TA_SUM)*100TA30 S4430A/iif(TA_SUM=0,1,TA_SUM)*100TA32 S4432A/iif(TA_SUM=0,1,TA_SUM)*100TA34 S4434A/iif(TA_SUM=0,1,TA_SUM)*100TA36 S4436A/iif(TA_SUM=0,1,TA_SUM)*100TA38 S4438A/iif(TA_SUM=0,1,TA_SUM)*100TA40 S4440A/iif(TA_SUM=0,1,TA_SUM)*100TA45 S4445A/iif(TA_SUM=0,1,TA_SUM)*100TA50 S4450A/iif(TA_SUM=0,1,TA_SUM)*100TA55 S4455A/iif(TA_SUM=0,1,TA_SUM)*100TAGT63 S4463A/iif(TA_SUM=0,1,TA_SUM)*100RLF_PER_TRX S4357D+S4358DUL_DL_BAL_1 S462AUL_DL_BAL_2 S462BUL_DL_BAL_3 S462CUL_DL_BAL_4 S462DUL_DL_BAL_5 S462EUL_DL_BAL_6 S462FUL_DL_BAL_7 S462GUL_DL_BAL_8 S462HUL_DL_BAL_9 S462IUL_DL_BAL_10 S462JUL_DL_BAL_11 S462KMAIN_LEVEL S4556DIVERSITY_LEVEL S4557UL_INTERFERENCE_MSG S4219ADL_INTERFERENCE_MSG S4219BMEAN_UL_QUALITY AS326AMEAN_DL_QUALITY AS326B

VALUE MS ACCESS FORMAT% DCR_INCL_HO:CM33/iif((K3013A+K3013B+K3023)=0,1,(K3013A+K3013B+K3023))*100% DCR_EXCLU_HO:CM33/iif((K3013A+CH323+CH343-CH313-CH333)=0,1,(K3013A+CH323+CH343-CH313-CH333))*100# MPD_SUB:CM33/iif(K3014=0,1,K3014)*60% DCR_RADIO:CM330/iif((K3013A+K3013B)=0,1,(K3013A+K3013B))*100% DCR_HO:(RH3331+K3012B)# TOTAL_DROPS_N:CM33# HO_DROPS_N:(RH3331+K3012B)# RADIO_DROPS_N:CM33C# TCH_DROP_ERR_IND_N:(M3100A+M3200A+M3100B+M3200B+M3100C+M3200C)# TCH_DROP_CONN_FAIL_N:(M3101A+M3201A+M3101B+M3201B+M3101C+M3201C+M3101D+M3201D+M3101E+M3201E)# TCH_DROP_RELEASE_IND_N:(M3102+M3202)# TCH_DROP_ERR_IND_T200_N:M3100A+M3200A# TCH_DROP_ERR_IND_UDM_RSP_N:M3100B+M3200B# TCH_DROP_ERR_IND_SE_N:(M3100C+M3200C)# TCH_DROP_CONN_FAIL_RLF_N:(M3101A+M3201A)# TCH_DROP_CONN_FAIL_HO_ACCESS_N:(M3101B+M3201B)# TCH_DROP_CONN_FAIL_OMI_N:(M3101C+M3201C)# TCH_DROP_CONN_FAIL_NR_N:(M3101D+M3201D)# TCH_DROP_CONN_FAIL_OTH_N:(M3101E+M3201E)# TCH_DROP_RELEASE_IND_N:(M3102+M3202)# TCH_DROP_NO_MR_N:(M312+M322)# TCH_DROP_ABIS_FAIL_N:(M313+M323)# TCH_DROP_EQ_FAIL_N:(M314+M324)# TCH_DROP_FORCED_HO_N:(M315+M325)# TCH_DROP_RES_CHECK_N:M316# TCH_DROP_TA_N:M3030A# TCH_DROP_UL_LEV_N:M3030B# TCH_DROP_DL_LEV_N:M3030C# TCH_DROP_UL_DL_LEV_N:M3030D# TCH_DROP_UL_FER_N:M3030E# TCH_DROP_DL_FER_N:M3030F# TCH_DROP_UL_DL_FER_N:M3030G# TCH_DROP_UL_QUAL_N:M3030H# TCH_DROP_DL_QUAL_N:M3030I# TCH_DROP_UL_DL_QUAL_N:M3030J# TCH_DROP_OTH_N:M3030K# SPEECH_DISC_NOR_N:A03701# SPEECH_DISC_BAD_N:A03702

CALL_MUTE_N:M3128AMEAN_TA_RLF:(AS4347D+AS4348D)

# IB_SD_1_PER:S4200A/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))*100# IB_SD_2_PER:S4200B/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))*100# IB_SD_3_PER:S4200C/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))*100# IB_SD_4_PER:S4200D/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))

# IB_SD_5_PER:S4200E/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))# IB_TCH_1_PER:(S4207A+S4208A)/iif((S4207A+S4208A+S4207B+S4208B+S4207C+S4208 # IB_TCH_2_PER:(S4207B+S4208B)/iif((S4207A+S4208A+S4207B+S4208B+S4207C+S4208 # IB_TCH_3_PER:(S4207C+S4208C)/iif((S4207A+S4208A+S4207B+S4208B+S4207C+S4208 # IB_TCH_4_PER:(S4207D+S4208D)/iif((S4207A+S4208A+S4207B+S4208B+S4207C+S4208 # IB_TCH_5_PER:(S4207E+S4208E)/iif((S4207A+S4208A+S4207B+S4208B+S4207C+S4208 # UL_Q_0_PER:(CS410C+CS410A)/iif(UL_SUM=0,1,UL_SUM)*100# UL_Q_1_PER:(CS411C+CS411A)/iif(UL_SUM=0,1,UL_SUM)*100# UL_Q_2_PER:(CS412C+CS412A)/iif(UL_SUM=0,1,UL_SUM)*100# UL_Q_3_PER:(CS413C+CS413A)/iif(UL_SUM=0,1,UL_SUM)*100# UL_Q_4_PER:(CS414C+CS414A)/iif(UL_SUM=0,1,UL_SUM)*100# UL_Q_5_PER:(CS415C+CS415A)/iif(UL_SUM=0,1,UL_SUM)*100# UL_Q_6_PER:(CS416C+CS416A)/iif(UL_SUM=0,1,UL_SUM)*100# UL_Q_7_PER:(CS417C+CS417A)/iif(UL_SUM=0,1,UL_SUM)*100# DL_Q_0_PER:(CS410D+CS410B)/iif(DL_SUM=0,1,UL_SUM)*100# DL_Q_1_PER:(CS411D+CS411B)/iif(DL_SUM=0,1,UL_SUM)*100# DL_Q_2_PER:(CS412D+CS412B)/iif(DL_SUM=0,1,UL_SUM)*100# DL_Q_3_PER:(CS413D+CS413B)/iif(DL_SUM=0,1,UL_SUM)*100# DL_Q_4_PER:(CS414D+CS414B)/iif(DL_SUM=0,1,UL_SUM)*100# DL_Q_5_PER:(CS415D+CS415B)/iif(DL_SUM=0,1,UL_SUM)*100# DL_Q_6_PER:(CS416D+CS416B)/iif(DL_SUM=0,1,UL_SUM)*100# DL_Q_7_PER:(CS417D+CS417B)/iif(DL_SUM=0,1,UL_SUM)*100# TA0:S4400A/iif(TA_SUM=0,1,TA_SUM)*100# TA1:S4401A/iif(TA_SUM=0,1,TA_SUM)*100# TA2:S4402A/iif(TA_SUM=0,1,TA_SUM)*100# TA3:S4403A/iif(TA_SUM=0,1,TA_SUM)*100# TA4:S4404A/iif(TA_SUM=0,1,TA_SUM)*100# TA5:S4405A/iif(TA_SUM=0,1,TA_SUM)*100# TA6:S4406A/iif(TA_SUM=0,1,TA_SUM)*100# TA7:S4407A/iif(TA_SUM=0,1,TA_SUM)*100# TA8:S4408A/iif(TA_SUM=0,1,TA_SUM)*100# TA9:S4409A/iif(TA_SUM=0,1,TA_SUM)*100# TA10:S4410A/iif(TA_SUM=0,1,TA_SUM)*100# TA11:S4411A/iif(TA_SUM=0,1,TA_SUM)*100# TA12:S4412A/iif(TA_SUM=0,1,TA_SUM)*100# TA13:S4413A/iif(TA_SUM=0,1,TA_SUM)*100# TA14:S4414A/iif(TA_SUM=0,1,TA_SUM)*100# TA15:S4415A/iif(TA_SUM=0,1,TA_SUM)*100# TA16:S4416A/iif(TA_SUM=0,1,TA_SUM)*100# TA17:S4417A/iif(TA_SUM=0,1,TA_SUM)*100# TA18:S4418A/iif(TA_SUM=0,1,TA_SUM)*100# TA19:S4419A/iif(TA_SUM=0,1,TA_SUM)*100# TA20:S4420A/iif(TA_SUM=0,1,TA_SUM)*100# TA21:S4421A/iif(TA_SUM=0,1,TA_SUM)*100# TA22:S4422A/iif(TA_SUM=0,1,TA_SUM)*100

# TA23:S4423A/iif(TA_SUM=0,1,TA_SUM)*100# TA24:S4424A/iif(TA_SUM=0,1,TA_SUM)*100# TA25:S4425A/iif(TA_SUM=0,1,TA_SUM)*100# TA26:S4426A/iif(TA_SUM=0,1,TA_SUM)*100# TA27:S4427A/iif(TA_SUM=0,1,TA_SUM)*100# TA28:S4428A/iif(TA_SUM=0,1,TA_SUM)*100# TA29:S4429A/iif(TA_SUM=0,1,TA_SUM)*100# TA30:S4430A/iif(TA_SUM=0,1,TA_SUM)*100# TA32:S4432A/iif(TA_SUM=0,1,TA_SUM)*100# TA34:S4434A/iif(TA_SUM=0,1,TA_SUM)*100# TA36:S4436A/iif(TA_SUM=0,1,TA_SUM)*100# TA38:S4438A/iif(TA_SUM=0,1,TA_SUM)*100# TA40:S4440A/iif(TA_SUM=0,1,TA_SUM)*100# TA45:S4445A/iif(TA_SUM=0,1,TA_SUM)*100# TA50:S4450A/iif(TA_SUM=0,1,TA_SUM)*100# TA55:S4455A/iif(TA_SUM=0,1,TA_SUM)*100# TAGT63:S4463A/iif(TA_SUM=0,1,TA_SUM)*100# RLF_PER_TRX:S4357D+S4358D# UL_DL_BAL_1:S462A# UL_DL_BAL_2:S462B# UL_DL_BAL_3:S462C# UL_DL_BAL_4:S462D# UL_DL_BAL_5:S462E# UL_DL_BAL_6:S462F# UL_DL_BAL_7:S462G# UL_DL_BAL_8:S462H# UL_DL_BAL_9:S462I# UL_DL_BAL_10:S462J# UL_DL_BAL_11:S462K

MAIN_LEVEL:S4556DIVERSITY_LEVEL:S4557UL_INTERFERENCE_MSG:S4219ADL_INTERFERENCE_MSG:S4219BMEAN_UL_QUALITY:AS326AMEAN_DL_QUALITY:AS326B

DCR_EXCLU_HO:CM33/iif((K3013A+CH323+CH343-CH313-CH333)=0,1,(K3013A+CH323+CH343-CH313-CH333))*100

TCH_DROP_CONN_FAIL_N:(M3101A+M3201A+M3101B+M3201B+M3101C+M3201C+M3101D+M3201D+M3101E+M3201E)

IB_SD_1_PER:S4200A/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))*100IB_SD_2_PER:S4200B/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))*100IB_SD_3_PER:S4200C/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))*100IB_SD_4_PER:S4200D/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))

IB_SD_5_PER:S4200E/iif((S4200A+S4200B+S4200C+S4200D+S4200E)=0,1,(S4200A+S4200B+S4200C+S4200D+S4200E))

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NAMEOUT GOING HANDOVER SUCCESS RATEOUT GOING RADIO HANDOVER SUCCESS RATEINCOM HO SUCCESS RATEINTRA CELL HO SUCCESS RATEINTERNAL RADIO HO SUCCESS RATEEXTERNAL INCOMING INTERCELL HO SUCCESS RATEEXTERNAL INCOMING RADIO HO SUCCESS RATEEXTERNAL OUTGOING HO SUCCESS RATEEXTERNAL OUTGOING CELL RADIO HO SUCCESS RATEIRAT HO SUCCESS RATEINTRACELl HO REQ ULAID TO OLAIDINTRACELl HO REQ OLAID TO ULAIDINTRACELl HO REQ AMR TCHF TO TCHHINTRACELl HO REQ TCHH to TCHFINTRACELl HO REQ UL INTERVENTIONINTRACELl HO REQ DL INTERVENTIONFAILED INTRAL CELL HO NO CHANNEL AVAILABLEFAILED INTRAL CELL HO TRESTRIAL RESOURCE REQUEST FAILEDFAILED INTRAL CELL HO A INTERFACE FAILUREFAILED INTRAL CELL HO TIMER EXPIREFAILED INTRA CELL HO F to HFAILED INTRA CELL HO H to FFAILED INTRA CELL HO NO ABISFAILED INTRA CELL HO SPEECH UNAVAILABLEFAILED INTRA CELL HO CHANNEL ACTIVATION FAILEDFAILED INCOMING HO NO RESOURCE AVAILABLEFAILED INCOMING HO TERESTRIAL RESOUCE REQUEST FAILEDFAILED INCOMING HO RECONECTION TO OLD CHANNEL FAILED INCOMING HO FAILURE A INTERFACEFAILED OUTGOING HO NO RADIOFAILED OUTGOING HO TERESTRIAL RESOURCE REQUEST FAILEDFAILED OUTGOING HO A INTERFACE FAILOUTGOING HO ATTEMPTS UL QUALITYOUTGOING HO ATTEMPTS DL QUALITYOUTGOING HO ATTEMPTS UL LEVELOUTGOING HO ATTEMPTS DL LEVELOUTGOING HO ATTEMPTS TAOUTGOING HO ATTEMPTS PBGTOUTGOING HO ATTEMPTS LOADOUTGOING HO ATTEMPTS RAPID FIELD DROPOUTGOING HO ATTEMPTS MSC INTERVENTIONOUTGOING HO ATTEMPTS OM INTERVENTIONOUTGOING HO ATTEMPTS OTHER

SHORT NAME HUAWEI FORMULAHOSR_OUT (CH313+CH333)/iif((CH310+CH330)=0,1,(CH

HOSR_RADIO (CH313+CH333)/iif((CH311+CH331)=0,1,(CH

HOSR_INCOM CH323/iif(CH321=0,1,CH321)*100

HOSR_INTRACELL CH303/iif(CH300=0,1,CH300)*100HOSE_INTERNAL_RADIO (CH303+CH323)/iif((CH300+CH320)=0,1,(CH3HOSR_EXT_INCOM CH343/iif(CH340=0,1,CH340)*100HOSR_EXT_INCOM_RADIO CH343/iif(CH341=0,1,CH341)*100HOSR_EXT_OUT CH333/iif(CH330=0,1,CH330)*100HOSR_EXT_OUT_RADIO CH333/iif(CH331=0,1,CH331)*100HOSR_IRAT CH3531H35071+H35081ATT_INTRACELL_UOLAID H3002ATT_INTRACELL_OULAID H3001ATT_INTRACELL_AMR_FH H3005AATT_INTRACELL_AMR_HF H3005BATT_INTRACELL_ULINT CH3036AATT_INTRACELL_DLINT CH3036BINTRA_FAIL_HO_RADIO H3029AINTRA_FAIL_HO_TRES_FAIL H302BINTRA_FAIL_HO_A_INTER H302GINTRA_FAIL_HO_A_TIMER (H3027Ca+H3028Ca)

INTRA_FAIL_HO_A_FH H3025AINTRA_FAIL_HO_A_HF H3025BINTRA_FAIL_HO_NO_ABIS H302EINTRA_FAIL_HO_SPEECH_UNAV H302HINTRA_FAIL_HO_CH_ACTV_FAIL H302IINCOM_FAIL_NO_RADIO H3229AINCOM_FAIL_HO_TRES_FAIL H3229BINCOM_FAIL_RFOC H322DINCOM_FAIL_A_INTER H322GOUT_FAIL_HO_NO_RADIO H312AOUT_FAIL_HO_TRES_FAIL H312BOUT_FAIL_HO_A_INTER H312GHO_ATT_UL_QUAL H310AHO_ATT_DL_QUAL H310BHO_ATT_UL_LEVEL H310CHO_ATT_DL_LEVEL H310DHO_ATT_TA H310EHO_ATT_PBGT H310FHO_ATT_LOAD H310GHO_ATT_RPD H310HHO_ATT_MSC_INTERVEN H310IHO_ATT_OM_INTERVEN H310JHO_ATT_OTHER H310L

MS ACCESS FORMATHOSR_OUT:(CH313+CH333)/iif((CH310+CH330)=0,1,(CH310+CH330))*100HOSR_RADIO:(CH313+CH333)/iif((CH311+CH331)=0,1,(CH311+CH331))*100HOSR_INCOM:CH323/iif(CH321=0,1,CH321)*100HOSR_INTRACELL:CH303/iif(CH300=0,1,CH300)*100HOSE_INTERNAL_RADIO:(CH303+CH323)/iif((CH300+CH320)=0,1,(CH300+CH320))*100HOSR_EXT_INCOM:CH343/iif(CH340=0,1,CH340)*100HOSR_EXT_INCOM_RADIO:CH343/iif(CH341=0,1,CH341)*100HOSR_EXT_OUT:CH333/iif(CH330=0,1,CH330)*100HOSR_EXT_OUT_RADIO:CH333/iif(CH331=0,1,CH331)*100HOSR_IRAT:CH3531H35071+H35081ATT_INTRACELL_UOLAID:H3002ATT_INTRACELL_OULAID:H3001ATT_INTRACELL_AMR_FH:H3005AATT_INTRACELL_AMR_HF:H3005BATT_INTRACELL_ULINT:CH3036AATT_INTRACELL_DLINT:CH3036BINTRA_FAIL_HO_RADIO:H3029AINTRA_FAIL_HO_TRES_FAIL:H302BINTRA_FAIL_HO_A_INTER:H302GINTRA_FAIL_HO_A_TIMER:(H3027Ca+H3028Ca)INTRA_FAIL_HO_A_FH:H3025AINTRA_FAIL_HO_A_HF:H3025BINTRA_FAIL_HO_NO_ABIS:H302EINTRA_FAIL_HO_SPEECH_UNAV:H302HINTRA_FAIL_HO_CH_ACTV_FAIL:H302IINCOM_FAIL_NO_RADIO:H3229AINCOM_FAIL_HO_TRES_FAIL:H3229BINCOM_FAIL_RFOC:H322DINCOM_FAIL_A_INTER:H322GOUT_FAIL_HO_NO_RADIO:H312AOUT_FAIL_HO_TRES_FAIL:H312BOUT_FAIL_HO_A_INTER:H312GHO_ATT_UL_QUAL:H310AHO_ATT_DL_QUAL:H310BHO_ATT_UL_LEVEL:H310CHO_ATT_DL_LEVEL:H310DHO_ATT_TA:H310EHO_ATT_PBGT:H310FHO_ATT_LOAD:H310GHO_ATT_RPD:H310HHO_ATT_MSC_INTERVEN:H310IHO_ATT_OM_INTERVEN:H310JHO_ATT_OTHER:H310L

NAME SHORT NAMESUCCESS UPLINK ASSIGNMENT RATE UL_ASS_SUCC_RATESUCCESS UPLINK ASSIGNMENT ON PS UL_ASS_SUCC_RATE_PSSUCCESS UPLINK ASSIGNMENT PACCH UL_ASS_SUCC_RATE_PACCHSUCCESSFUL DOWNLINK ASSIGNMENT RATE DL_ASS_SUCC_RATESUCCESS DOWNLINK ASSIGNMENT RATE PS DL_ASS_SUCC_RATE_PSSUCCESS DOWNLINK ASSIGNMENT RATE PACCH DL_ASS_SUCC_RATE_PACCHTBF ESTABLISHMENT SUCCESS RATE TBF_ESTAB_SUCC_RATEUL TBF ESTABLISHMENT SUCCESS RATE UL_TBF_ESTAB_SUCC_RATEDL TBF ESTABLISHMENT SUCCESS RATE DL_TBF_ESTAB_SUCC_RATEUL GPRS TBF ESTABLISHMENT SUCCESS RATE UL_GPRS_TBF_ESTAB_SUCC_RATEUL EDGE TBF ESTABLISHMENT SUCCESS RATE UL_EDGE_TBF_ESTAB_SUCC_RATEDL GPRS TBF ESTABLISHMENT SUCCESS RATE DL_GPRS_TBF_ESTAB_SUCC_RATEDL EDGE TBF ESTABLISHMENT SUCCESS RATE DL_EDGE_TBF_ESTAB_SUCC_RATEUL PDCH UTILIZATION UL_PDCH_UTILDL PDCH UTILIZATION DL_PDCH_UTILPDCH OCCUPATION RATE PDCH_OCC_RATEBSC RECLAIMED DYNAMIC PDCH BSC_RECLAIM_DYN_PDCHFAILED UL GPRS TBF ESTABLISHMENT NR FAIL_UL_GPRS_TBF_NRFAILED UL GPRS TBF ESTABLISHMENT MS NO RESPONSE FAIL_UL_GPRS_TBF_MS_NO_RESFAILED UL GPRS TBF ESTABLISHMENT OTH CAUSE FAIL_UL_GPRS_TBF_OTHFAILED DL GPRS TBF ESTABLISHMENT NR FAIL_DL_GPRS_TBF_NRFAILED DL GPRS TBF ESTABLISHMENT MS NO RESPONSE FAIL_DL_GPRS_TBF_MS_NO_RESFAILED DL GPRS TBF ESTABLISHMENT OTH CAUSE FAIL_DL_GPRS_TBF_OTHFAILED UL EGPRS TBF ESTABLISHMENT NR FAIL_UL_EDGE_TBF_NRFAILED UL EGPRS TBF ESTABLISHMENT MS NO RESPONSE FAIL_UL_EDGE_TBF_MS_NO_RESFAILED UL EGPRS TBF ESTABLISHMENT OTH CAUSE FAIL_UL_EDGE_TBF_OTHFAILED DL EGPRS TBF ESTABLISHMENT NR FAIL_DL_EDGE_TBF_NRFAILED DL EGPRS TBF ESTABLISHMENT MS NO RESPONSE FAIL_DL_EDGE_TBF_MS_NO_RESFAILED DL EGPRS TBF ESTABLISHMENT OTH CAUSE FAIL_DL_EDGE_TBF_OTH

HUAWEI FORMULA NUM HUAWEI FORMULA DEN VALUEA9502*100 A9501 %A9504*100 A9503 %A9506*100 A9505 %A9508*100 A9507 %A9510*100 A9509 %A9512*100 A9511 %(A9002+A9102+A9202+A9302)*100 (A9001+A9101+A9201+A9301) %(A9002+A9202)*100 (A9001+A9201) %(A9102+A9302)*100 (A9101+A9301) %A9002*100 A9001 %A9202*100 A9201 %A9102*100 A9101 %A9302*100 A9301 %R9204*100 R9206 %R9205*100 R9207 %AR9311*100 AR9303 %R9344*100 R9343 %A9003 #A9004 #A9016 #A9103 #A9104 #A9115 #A9203 #A9204 #A9216 #A9303 #A9304 #A9315 #

MS ACESS FORMAT CommentsUL_ASS_SUCC_RATE:round(A950 0UL_ASS_SUCC_RATE_PS:round(A 0UL_ASS_SUCC_RATE_PACCH:roun 0DL_ASS_SUCC_RATE:round(A950 0DL_ASS_SUCC_RATE_PS:round(A 0DL_ASS_SUCC_RATE_PACCH:roun 0TBF_ESTAB_SUCC_RATE:round(( 0UL_TBF_ESTAB_SUCC_RATE:roun 0DL_TBF_ESTAB_SUCC_RATE:roun 0UL_GPRS_TBF_ESTAB_SUCC_RATE 0UL_EDGE_TBF_ESTAB_SUCC_RATE 0DL_GPRS_TBF_ESTAB_SUCC_RATE 0DL_EDGE_TBF_ESTAB_SUCC_RATE:round(A9302*100/A9301,2)UL_PDCH_UTIL:round(R9204*100/R9206,2)DL_PDCH_UTIL:round(R9205*100/R9207,2)PDCH_OCC_RATE:round(AR9311*100/AR9303,2)BSC_RECLAIM_DYN_PDCH:round(R9344*100/R9343,2)FAIL_UL_GPRS_TBF_NR:A9003FAIL_UL_GPRS_TBF_MS_NO_RES:A9004FAIL_UL_GPRS_TBF_OTH:A9016FAIL_DL_GPRS_TBF_NR:A9103FAIL_DL_GPRS_TBF_MS_NO_RES:A9104FAIL_DL_GPRS_TBF_OTH:A9115FAIL_UL_EDGE_TBF_NR:A9203FAIL_UL_EDGE_TBF_MS_NO_RES:A9204FAIL_UL_EDGE_TBF_OTH:A9216FAIL_DL_EDGE_TBF_NR:A9303 0FAIL_DL_EDGE_TBF_MS_NO_RES 0FAIL_DL_EDGE_TBF_OTH:A9315 0

NAME SHORT NAMEUL GPRS RLC RETRANS UL_GPRS_RLC_RETRANDL GPRS RLC RETRANS DL_GPRS_RLC_RETRANUL EDGE RLC RETRANS UL_EDGE_RLC_RETRANDL EDGE RLC RETRANS DL_EDGE_RLC_RETRANUL AVG THP GPRS RLC PER PDCH UL_AVG_THP_GPRS_RLC_PDCHDL AVG THP GPRS RLC PER PDCH DL_AVG_THP_GPRS_RLC_PDCHUL AVG THP EDGE RLC PER PDCH UL_AVG_THP_EDGE_RLC_PDCHDL AVG THP EDGE RLC PER PDCH DL_AVG_THP_EDGE_RLC_PDCHUL AVG THP PER PDCH UL_AVG_THP_PDCHDL AVG THP PER PDCH DL_AVG_THP_PDCHUL AVG THP GPRS RLC PER CELL UL_AVG_THP_GPRS_RLC_CELLDL AVG THP GPRS RLC PER CELL DL_AVG_THP_GPRS_RLC_CELLUL AVG THP EDGE RLC PER CELL UL_AVG_THP_EDGE_RLC_CELLDL AVG THP EDGE RLC PER CELL DL_AVG_THP_EDGE_RLC_CELLUL AVG THP PER CELLDL AVG THP PER CELLUL CS1 CODING SHARE UL_CS1_COD_SHUL CS2 CODING SHARE UL_CS2_COD_SHUL CS3 CODING SHARE UL_CS3_COD_SHUL CS4 CODING SHARE UL_CS4_COD_SHDL CS1 CODING SHARE DL_CS1_COD_SHDL CS2 CODING SHARE DL_CS2_COD_SHDL CS3 CODING SHARE DL_CS3_COD_SHDL CS4 CODING SHARE DL_CS4_COD_SHCS1 CODING SHARE CS1_COD_SHARECS2 CODING SHARE CS2_COD_SHARECS3 CODING SHARE CS3_COD_SHARECS4 CODING SHARE CS4_COD_SHAREUL MCS1 CODING SHARE UL_MCS_1_COD_SHUL MCS2 CODING SHARE UL_MCS_2_COD_SHUL MCS3 CODING SHARE UL_MCS_3_COD_SHUL MCS4 CODING SHARE UL_MCS_4_COD_SHUL MCS5 CODING SHARE UL_MCS_5_COD_SHUL MCS6 CODING SHARE UL_MCS_6_COD_SHUL MCS7 CODING SHARE UL_MCS_7_COD_SHUL MCS8 CODING SHARE UL_MCS_8_COD_SHUL MCS9 CODING SHARE UL_MCS_9_COD_SHDL MCS1 CODING SHARE DL_MCS_1_COD_SHDL MCS2 CODING SHARE DL_MCS_2_COD_SHDL MCS3 CODING SHARE DL_MCS_3_COD_SHDL MCS4 CODING SHARE DL_MCS_4_COD_SHDL MCS5 CODING SHARE DL_MCS_5_COD_SHDL MCS6 CODING SHARE DL_MCS_6_COD_SHDL MCS7 CODING SHARE DL_MCS_7_COD_SH

DL MCS8 CODING SHARE DL_MCS_8_COD_SHDL MCS9 CODING SHARE DL_MCS_9_COD_SHMCS1 CODING SHARE MCS1_COD_SHMCS2 CODING SHARE MCS2_COD_SHMCS3 CODING SHARE MCS3_COD_SHMCS4 CODING SHARE MCS4_COD_SHMCS5 CODING SHARE MCS5_COD_SHMCS6 CODING SHARE MCS6_COD_SHMCS7 CODING SHARE MCS7_COD_SHMCS8 CODING SHARE MCS8_COD_SHMCS9 CODING SHARE MCS9_COD_SH

HUAWEI FORMULA NUM HUAWEI FORMULA DEN VALUE(L9001-(L9006+L9007+L9008+L9009)) L9001 %(L9101-(L9106+L9107+L9108+L9109)) L9101 %(L9201-(L9211+L9212+L9213+L9214+L9215+L9216+L92L9201 %(L9301-(L9311+L9312+L9313+L9314+L9315+L9316+L93L9301 %(((L9006*23+L9007*34+L9008*40+L9009*54)*8)/1024)((L9002+L9003+L9004+L9005)/50) kbps(((L9106*23+L9107*34+L9108*40+L9109*54)*8)/1024)((L9102+L9103+L9104+L9105)/50) kbps(((L9211*22+L9212*28+L9213*37+L9214*44+L9215*56(((L9202+L9203+L9204+L9205+L9206+L9207+kbps(((L9311*22+L9312*28+L9313*37+L9314*44+L9315*56(((L9302+L9303+L9304+L9305+L9306+L9307+kbps(((L9006*23+L9007*34+L9008*40+L9009*54+L9211*2 ((L9002+L9003+L9004+L9005)/50)+(((L9202kbps(((L9106*23+L9107*34+L9108*40+L9109*54+L9311*2 ((L9102+L9103+L9104+L9105)/50)+(((L9302kbpsL9006*23+L9007*34+L9008*40+L9009*54*8 L9020L9106*23+L9107*34+L9108*40+L9109*54*8 L9121L9211*22+L9212*28+L9213*37+L9214*44+L9215*56+LL9235L9311*22+L9312*28+L9313*37+L9314*44+L9315*56+LL9336

L9002 (L9002+L9003+L9004+L9005) %L9003 (L9002+L9003+L9004+L9005) %L9004 (L9002+L9003+L9004+L9005) %L9005 (L9002+L9003+L9004+L9005) %L9102 (L9102+L9103+L9104+L9105) %L9103 (L9102+L9103+L9104+L9105) %L9104 (L9102+L9103+L9104+L9105) %L9105 (L9102+L9103+L9104+L9105) %(L9002+L9102) (L9002+L9003+L9004+L9005+L9102+L9103+%(L9003+L9103) (L9002+L9003+L9004+L9005+L9102+L9103+%(L9004+L9104) (L9002+L9003+L9004+L9005+L9102+L9103+%(L9005+L9105) (L9002+L9003+L9004+L9005+L9102+L9103+%L9202 (L9202+L9203+L9204+L9205+L9206+L9207+%L9203 (L9202+L9203+L9204+L9205+L9206+L9207+%L9204 (L9202+L9203+L9204+L9205+L9206+L9207+%L9205 (L9202+L9203+L9204+L9205+L9206+L9207+%L9206 (L9202+L9203+L9204+L9205+L9206+L9207+%L9207 (L9202+L9203+L9204+L9205+L9206+L9207+%L9208 (L9202+L9203+L9204+L9205+L9206+L9207+%L9209 (L9202+L9203+L9204+L9205+L9206+L9207+%L9210 (L9202+L9203+L9204+L9205+L9206+L9207+%L9302 (L9302+L9303+L9304+L9305+L9306+L9307+%L9303 (L9302+L9303+L9304+L9305+L9306+L9307+%L9304 (L9302+L9303+L9304+L9305+L9306+L9307+%L9305 (L9302+L9303+L9304+L9305+L9306+L9307+%L9306 (L9302+L9303+L9304+L9305+L9306+L9307+%L9307 (L9302+L9303+L9304+L9305+L9306+L9307+%L9308 (L9302+L9303+L9304+L9305+L9306+L9307+%

L9309 (L9302+L9303+L9304+L9305+L9306+L9307+%L9310 (L9302+L9303+L9304+L9305+L9306+L9307+%(L9202+L9302) (L9202+L9203+L9204+L9205+L9206+L9207 %(L9203+L9303) (L9202+L9203+L9204+L9205+L9206+L9207 %(L9204+L9304) (L9202+L9203+L9204+L9205+L9206+L9207 %(L9205+L9305) (L9202+L9203+L9204+L9205+L9206+L9207 %(L9206+L9306) (L9202+L9203+L9204+L9205+L9206+L9207 %(L9207+L9307) (L9202+L9203+L9204+L9205+L9206+L9207 %(L9208+L9308) (L9202+L9203+L9204+L9205+L9206+L9207 %(L9209+L9309) (L9202+L9203+L9204+L9205+L9206+L9207 %(L9210+L9310) (L9202+L9203+L9204+L9205+L9206+L9207 %

MS ACESS FORMAT CommentsUL_GPRS_RLC_RETRAN:(L9001-(L9006+L9007+L9008 0DL_GPRS_RLC_RETRAN:(L9101-(L9106+L9107+L9108 0UL_EDGE_RLC_RETRAN:(L9201-(L9211+L9212+L921 0DL_EDGE_RLC_RETRAN:(L9301-(L9311+L9312+L931 0UL_AVG_THP_GPRS_RLC_PDCH:(((L9006*23+L9007*3 0DL_AVG_THP_GPRS_RLC_PDCH:(((L9106*23+L9107*3 0UL_AVG_THP_EDGE_RLC_PDCH:(((L9211*22+L9212*2 0DL_AVG_THP_EDGE_RLC_PDCH:(((L9311*22+L9312*2 0UL_AVG_THP_PDCH:(((L9006*23+L9007*34+L9008*4 0DL_AVG_THP_PDCH:(((L9106*23+L9107*34+L9108*4 0UL_AVG_THP_GPRS_RLC_CELL:L9006*23+L9007*34 Counters not available in PRSDL_AVG_THP_GPRS_RLC_CELL:L9106*23+L9107*34 Counters not available in PRSUL_AVG_THP_EDGE_RLC_CELL:L9211*22+L9212*28 Counters not available in PRSDL_AVG_THP_EDGE_RLC_CELL:L9311*22+L9312*28 Counters not available in PRS

Counters not available in PRSCounters not available in PRS

UL_CS1_COD_SH:L9002/(L9002+L9003+L9004+L900 0UL_CS2_COD_SH:L9003/(L9002+L9003+L9004+L900 0UL_CS3_COD_SH:L9004/(L9002+L9003+L9004+L900 0UL_CS4_COD_SH:L9005/(L9002+L9003+L9004+L900 0DL_CS1_COD_SH:L9102/(L9102+L9103+L9104+L910 0DL_CS2_COD_SH:L9103/(L9102+L9103+L9104+L910 0DL_CS3_COD_SH:L9104/(L9102+L9103+L9104+L910 0DL_CS4_COD_SH:L9105/(L9102+L9103+L9104+L910 0CS1_COD_SHARE:(L9002+L9102)/(L9002+L9003+L9 0CS2_COD_SHARE:(L9003+L9103)/(L9002+L9003+L9 0CS3_COD_SHARE:(L9004+L9104)/(L9002+L9003+L9 0CS4_COD_SHARE:(L9005+L9105)/(L9002+L9003+L9 0UL_MCS_1_COD_SH:L9202/(L9202+L9203+L9204+L 0UL_MCS_2_COD_SH:L9203/(L9202+L9203+L9204+L 0UL_MCS_3_COD_SH:L9204/(L9202+L9203+L9204+L 0UL_MCS_4_COD_SH:L9205/(L9202+L9203+L9204+L 0UL_MCS_5_COD_SH:L9206/(L9202+L9203+L9204+L 0UL_MCS_6_COD_SH:L9207/(L9202+L9203+L9204+L 0UL_MCS_7_COD_SH:L9208/(L9202+L9203+L9204+L 0UL_MCS_8_COD_SH:L9209/(L9202+L9203+L9204+L 0UL_MCS_9_COD_SH:L9210/(L9202+L9203+L9204+L 0DL_MCS_1_COD_SH:L9302/(L9302+L9303+L9304+L 0DL_MCS_2_COD_SH:L9303/(L9302+L9303+L9304+L 0DL_MCS_3_COD_SH:L9304/(L9302+L9303+L9304+L 0DL_MCS_4_COD_SH:L9305/(L9302+L9303+L9304+L 0DL_MCS_5_COD_SH:L9306/(L9302+L9303+L9304+L 0DL_MCS_6_COD_SH:L9307/(L9302+L9303+L9304+L 0DL_MCS_7_COD_SH:L9308/(L9302+L9303+L9304+L 0

DL_MCS_8_COD_SH:L9309/(L9302+L9303+L9304+L 0DL_MCS_9_COD_SH:L9310/(L9302+L9303+L9304+L 0MCS1_COD_SH:(L9202+L9302)/(L9202+L9203+L920 0MCS2_COD_SH:(L9203+L9303)/(L9202+L9203+L920 0MCS3_COD_SH:(L9204+L9304)/(L9202+L9203+L920 0MCS4_COD_SH:(L9205+L9305)/(L9202+L9203+L920 0MCS5_COD_SH:(L9206+L9306)/(L9202+L9203+L920 0MCS6_COD_SH:(L9207+L9307)/(L9202+L9203+L920 0MCS7_COD_SH:(L9208+L9308)/(L9202+L9203+L920 0MCS8_COD_SH:(L9209+L9309)/(L9202+L9203+L920 0MCS9_COD_SH:(L9210+L9310)/(L9202+L9203+L920 0

NAMETBF DROP RATE

UL TBF DROP RATEDL TBF DROP RATE

UL GPRS TBF DROP RATEDL GPRS TBF DROP RATEUL EDGE TBF DROP RATEDL EDGE TBF DROP RATE

UL GPRS PAY LOADDL GPRS PAT LOADUL EDGE PAY LOADDL EDGE PAY LOADTOTAL UL PAY LOADTOTAL DL PAY LOAD

DL EGPRS TBF ABNORMAL RELEASE N3105 OVER FLOWDL EGPRS TBF ABNORMAL RELEASE SUSPEND

DL EGPRS TBF ABNORMAL RELEASE FLUSHDL EGPRS TBF ABNORMAL RELEASE NO CHANNELDL EGPRS TBF ABNORMAL RELEASE PREEMPTION

DL EGPRS TBF ABNORMAL RELEASE OTHER CAUSESDL EGPRS TBF ABNORMAL RELEASE CS HANDOVER

DL EGPRS TBF ABNORMAL RELEASE ABIS RESOURCE PREEMPTIONDL GPRS TBF ABNORMAL RELEASE N3105 OVER FLOW

DL GPRS TBF ABNORMAL RELEASE SUSPENDDL GPRS TBF ABNORMAL RELEASE FLUSH

DL GPRS TBF ABNORMAL RELEASE NO CHANNELDL GPRS TBF ABNORMAL RELEASE PREEMPTION

DL GPRS TBF ABNORMAL RELEASE OTHER CAUSESDL GPRS TBF ABNORMAL RELEASE CS HANDOVER

DL GPRS TBF ABNORMAL RELEASE ABIS RESOURCE PREEMPTIONDL GPRS TBF ABNORMAL RELEASE EDGE USER

UL EGPRS TBF ABNORMAL RELEASE N3101 OVER FLOWUL EGPRS TBF ABNORMAL RELEASE N3103 OVER FLOW

UL EGPRS TBF ABNORMAL RELEASE SUSPENDUL EGPRS TBF ABNORMAL RELEASE FLUSH

UL EGPRS TBF ABNORMAL RELEASE NO CHANNELUL EGPRS TBF ABNORMAL RELEASE PREEMPTION

UL EGPRS TBF ABNORMAL RELEASE OTHER CAUSESUL EGPRS TBF ABNORMAL RELEASE CS HANDOVER

UL EGPRS TBF ABNORMAL RELEASE ABIS RESOURCE PREEMPTIONUL GPRS TBF ABNORMAL RELEASE N3101 OVER FLOWUL GPRS TBF ABNORMAL RELEASE N3103 OVER FLOW

UL GPRS TBF ABNORMAL RELEASE SUSPENDUL GPRS TBF ABNORMAL RELEASE FLUSH

UL GPRS TBF ABNORMAL RELEASE NO CHANNELUL GPRS TBF ABNORMAL RELEASE PREEMPTION

UL GPRS TBF ABNORMAL RELEASE OTHER CAUSESUL GPRS TBF ABNORMAL RELEASE CS HANDOVER

UL GPRS TBF ABNORMAL RELEASE ABIS RESOURCE PREEMPTIONAVG DURATION OF UL EDGE TBF

TOTAL DURATION OF UL EDGE TBFAVG DURATION OF DL GPRS TBF

TOTAL DURATION OF DL GPRS TBFABIS TDM SUCCESS RATE

ABIS IP/HDLC SUCCESS RATEUNSUCCESSFUL APPLICATION ATTEMPTS NO IDLE TS

UNSUCCESSFUL APPLICATION ATTEMPTS CONNECTION FAILUREUNSUCCESSFUL APPLICATION ATTEMPTS BTS FAILURE

UNSUCCESSFUL APPLICATION ATTEMPTS OTHERSUNSUCCESSFUL APPLICATION ATTEMPTS LIMIT BTS DSP

SHORT NAMETBF_DROP_RATE

UL_TBF_DROP_RATEDL_TBF_DROP_RATE

UL_GPRS_TBF_DROP_RATEDL_GPRS_TBF_DROP_RATEUL_EDGE_TBF_DROP_RATEDL_EDGE_TBF_DROP_RATE

UL_GPRS_PAYLOADDL_GPRS_PAYLOADUL_EDGE_PAYLOADDL_EDGE_PAYLOAD

TOTAL_UL_PAY_LOADTOTAL_DL_PAY_LOAD

DL_EDGE_TBF_REL_N3105DL_EDGE_TBF_REL_SUSPEND

DL_EDGE_TBF_REL_FLUSHDL_EDGE_TBF_REL_NR

DL_EDGE_TBF_REL_PREEMPDL_EDGE_TBF_REL_OTH

DL_EDGE_TBF_REL_CSHODL_GPRS_TBF_REL_ABIS_PREEMP

DL_GPRS_TBF_REL_N3105DL_GPRS_TBF_REL_SUSPEND

DL_GPRS_TBF_REL_FLUSHDL_GPRS_TBF_REL_NR

DL_GPRS_TBF_REL_PREEMPDL_GPRS_TBF_REL_OTH

DL_GPRS_TBF_REL_CSHODL_GPRS_TBF_REL_ABIS_PREEMP

DL_GPRS_TBF_REL_ABIS_EDGEUSERUL_EDGE_TBF_REL_N3101UL_EDGE_TBF_REL_N3103

UL_EDGE_TBF_REL_SUSPENDUL_EDGE_TBF_REL_FLUSH

UL_EDGE_TBF_REL_NRUL_EDGE_TBF_REL_PREEMP

UL_EDGE_TBF_REL_OTHUL_EDGE_TBF_REL_CSHO

UL_EDGE_TBF_REL_ABIS_PREEMPUL_GPRS_TBF_REL_N3101UL_GPRS_TBF_REL_N3103

UL_GPRS_TBF_REL_SUSPENDUL_GPRS_TBF_REL_FLUSH

UL_GPRS_TBF_REL_NRUL_GPRS_TBF_REL_PREEMP

UL_GPRS_TBF_REL_OTHUL_GPRS_TBF_REL_CSHO

UL_GPRS_TBF_REL_ABIS_PREEMPAVG_DUR_UL_EDGE_TBFTOT_DUR_UL_EDGE_TBFAVG_DUR_DL_GPRS_TBFTOT_DUR_DL_GPRS_TBF

ABIS_TDM_SUCC_RABIS_IP_HDLC_SUCC_R

FAIL_APP_ATT_NO_IDLE_TSFAIL_APP_ATT_NO_CON_FAIL

FAIL_APP_ATT_BTS_FAILFAIL_APP_ATT_OTHER

FAIL_APP_ATT_LIM_BTS_DSP

FORMULA NUM(A9006+A9007+A9010+A9017+A9018+A9206+A9207+A9210+A9217+A9218+A9106+A9109+A9116+A9117+A9306+A9309+A9316+A9317)

(A9006+A9007+A9010+A9017+A9018+A9206+A9207+A9210+A9217+A9218)(A9106+A9109+A9116+A9117+A9306+A9309+A9316+A9317)

(A9006+A9007+A9010+A9017+A9018)(A9106+A9109+A9116+A9117)

(A9206+A9207+A9210+A9217+A9218)(A9306+A9309+A9316+A9317)

((L9006*23+L9007*34+L9008*40+L9009*54)*8)/1024((L9106*23+L9107*34+L9108*40+L9109*54)*8)/1024((L9211*22+L9212*28+L9213*37+L9214*44+L9215*56+L9216*74+L9217*56+L9218*68+L92((L9311*22+L9312*28+L9313*37+L9314*44+L9315*56+L9316*74+L9317*56+L9318*68+L93((L9006*23+L9007*34+L9008*40+L9009*54*8/1024+L9211*22+L9212*28+L9213*37+L921((L9106*23+L9107*34+L9108*40+L9109*54*8/1024+L9311*22+L9312*28+L9313*37+L931

A9306

A9307

A9308

A9309

A9316

A9317

A9335

A9336

A9106

A9107

A9108

A9109

A9116

A9117

A9137

A9138

A9132

A9206

A9207

A9208

A9209

A9210

A9217

A9218

A9237

A9238

A9006

A9007

A9008

A9009

A9010

A9017

A9018

A9039

A9040

AA9213

A9214

AA9114

A9113

R9102R9106R9109R9110R9111R9112R9115

FORMULA DEN VALUE MS ACESS FORMAT COMMENTS(A9002+A9202+A9102+A9302) % TBF_DROP_RATE:(A9 0

(A9002+A9202) % UL_TBF_DROP_RATE: 0(A9102+A9302) % DL_TBF_DROP_RATE: 0

A9002 % UL_GPRS_TBF_DROP_ 0A9102 % DL_GPRS_TBF_DROP_ 0A9202 % UL_EDGE_TBF_DROP_ 0A9302 % DL_EDGE_TBF_DROP_ 0

MB UL_GPRS_PAYLOAD:(( 0 MB DL_GPRS_PAYLOAD:(( 0 MB UL_EDGE_PAYLOAD:(( 0 MB DL_EDGE_PAYLOAD:(( 0 MB TOTAL_UL_PAY_LOAD: 0 MB TOTAL_DL_PAY_LOAD: 0

# DL_EDGE_TBF_REL_N 0# DL_EDGE_TBF_REL_S 0# DL_EDGE_TBF_REL_F 0# DL_EDGE_TBF_REL_N 0# DL_EDGE_TBF_REL_P 0# DL_EDGE_TBF_REL_O 0# DL_EDGE_TBF_REL_C 0# DL_GPRS_TBF_REL_A 0# DL_GPRS_TBF_REL_N 0# DL_GPRS_TBF_REL_S 0# DL_GPRS_TBF_REL_FL 0# DL_GPRS_TBF_REL_N 0# DL_GPRS_TBF_REL_P 0# DL_GPRS_TBF_REL_O 0# DL_GPRS_TBF_REL_C 0# DL_GPRS_TBF_REL_A 0# DL_GPRS_TBF_REL_A 0# UL_EDGE_TBF_REL_N 0# UL_EDGE_TBF_REL_N 0# UL_EDGE_TBF_REL_S 0# UL_EDGE_TBF_REL_F 0# UL_EDGE_TBF_REL_N 0# UL_EDGE_TBF_REL_P 0# UL_EDGE_TBF_REL_O 0# UL_EDGE_TBF_REL_C 0# UL_EDGE_TBF_REL_A 0# UL_GPRS_TBF_REL_N 0# UL_GPRS_TBF_REL_N 0# UL_GPRS_TBF_REL_S 0# UL_GPRS_TBF_REL_F 0# UL_GPRS_TBF_REL_N 0# UL_GPRS_TBF_REL_P 0# UL_GPRS_TBF_REL_O 0# UL_GPRS_TBF_REL_C 0

# UL_GPRS_TBF_REL_A 0SEC AVG_DUR_UL_EDGE_T 0SEC TOT_DUR_UL_EDGE_T 0SEC AVG_DUR_DL_GPRS_T 0SEC TOT_DUR_DL_GPRS_T 0

R9101 %ABIS_TDM_SUCC_R:R9102/R9101*100 0R9105 %ABIS_IP_HDLC_SUCC_R:R9106/R9105*1000

#FAIL_APP_ATT_NO_IDLE_TS:R9109 0#FAIL_APP_ATT_NO_CON_FAIL:R9110 0#FAIL_APP_ATT_BTS_FAIL:R9111 0#FAIL_APP_ATT_OTHER:R9112 0#FAIL_APP_ATT_LIM_BTS_DSP:R9115 0

COUNTER_NO DESCRIPTIONH371 Out going inter cell HO commands Fail Outgoing intercell HosH373 Successful Outgoing intercell HOSH380 Incoming Intercell HO RequestH382 Failed incoming Intercell HosH383 Successful Incoming intercell HOS

FEATURE_NAME IMPACT2G/3G Cell Reselection Based on MS State Cell

2G/3G Co-Transmission Resources Management on MBSC Cell

A Interface Protocol Process Cell

Cell

A5/1 Encryption Flow Optimization Cell

Access Cell

Access Cell

Access Cell

Access Cell

Access Cell

Access Cell

Access Cell

Access Cell

Access Cell

Access Cell

Access Cell

Access Cell

Adaptive Adjustment of Uplink and Downlink Channels Cell

Adjustment of Adaptive Timing Advance Cell

AFCAutomatic Frequency Correction Cell

AFCAutomatic Frequency Correction Cell

AMR Coding Rate Threshold Adaptive Adjustment Cell




A5/1 and A5/2 Ciphering AlgorithmA5/1 Encryption Flow Optimization










AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR Cell

Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR HR Cell

AMR Wireless Link Timer Cell




Antenna Frequency Hopping Cell




Assignment and Immediate Assignment Cell



Basic Cell Re-selection Cell




AMR HRTFO



Basic Cell Selection Cell

Cell

Cell

BCCH Dense Frequency Multiplexing Cell



BSC Node Redundancy Cell

Basic Cell SelectionBasic Cell Re-selection

Basic Cell SelectionBasic Cell Re-selection




BSS Paging Coordination Cell

BSS-Based LCS Cell ID + TA Cell



















Call Control Cell

Call Control Cell

Call Control Cell

Call Control Cell

Call Reestablishment Cell

Cell Frequency Scan Cell




Co-BCCH Cell Cell

Compact BTS Automatic Capacity Planning Define Cell

Compact BTS Automatic Capacity Planning Cell



Compact BTS Automatic Configuration and Planning Cell





Cell

Concentric Cell Cell





Compact BTS Automatic Configuration and Planning




Cell

Configuration Management Define Cell

Configuration Management Cell



Configuration Management Define Cell
















Concentric CellEnhanced Dual-Band Network







Direct Retry Cell

Direct Retry Cell

Direct Retry Cell

Direct Retry Cell

Discontinuous Reception DRX Cell

Discontinuous Reception DRX Cell

Discontinuous Transmission DTX Downlink Cell

CellDiscontinuous Transmission DTX DownlinkHalf Rate Speech

Discontinuous Transmission DTX Uplink Cell

Cell

Dynamic Adjustment Between FR and HR Cell

Dynamic Cell Power Off Cell











Dynamic Transmit Diversity Cell

EICC Cell

Emergency Call Service TS12 Cell


Discontinuous Transmission DTX UplinkHalf Rate Speech



Encrypted Network Management Cell




Cell

Enhanced BCCH Power Consumption Optimization Cell





Enhanced Channel Assignment Algorithm Cell
























Enhanced Dual-Band Network Cell





Encrypted Network ManagementSoft-Synchronized Network






















Enhanced Measurement ReportEMR Cell












Enhanced Multi Level Precedence and PreemptionEMLPP Cell



CellEnhanced Power Control AlgorithmHUAWEI III Power Control Algorithm

Cell

Extended Cell Cell

Extended Cell Cell

Fast 3G Reselection at 2G CS Call Release Cell

Flex Abis Cell

Flex Abis Cell

Flex MAIO Cell

Flex MAIO Cell

Frequency Band Cell

Frequency Band Cell

Frequency Band Define Cell

Frequency Band Cell

Enhanced Power Control AlgorithmHUAWEI III Power Control Algorithm

Frequency Hopping RF hopping, baseband hopping Define Cell




Frequency Hopping RF hopping, baseband hopping Cell




G3 Fax TS61, TS62 Cell

Gb Interface Function Cell

Group Call EMLPP Cell






GSM Flow Control Cell








GSM/WCDMA Interoperability Cell













Cell

Cell

Cell

Cell

Cell

Cell

Cell

GSM/WCDMA InteroperabilityGSM/TD-SCDMA Interoperability

GSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA Interoperability

Cell

Cell

Cell

Cell

Cell

Cell

Half Rate Speech Cell

GSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA Interoperability

GSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA Interoperability



IBCA Interference Based Channel Allocation Cell
























































IMSI Detach Cell

Intelligent Combiner Bypass Cell

Latency Reduction Cell

MBSC Load Balancing Cell

MBSC Load Balancing Cell

MSRD Cell

Multi-band Sharing One BSC Cell





Multi-site Cell Cell

Network Operation Mode Support Cell

Network Support SAIC Cell

Network-Controlled Cell Reselection NC2 Cell





















Networking Control Mode Cell




None Cell

None Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BSC Cell

O&M of BTS Cell

O&M of BTS Cell

O&M of BTS Cell

O&M of BTS Cell

O&M of BTS Cell

O&M of BTS Cell

O&M of BTS Cell

O&M of BTS Cell

O&M of BTS Cell

Cell

Packet Assignment Taken Over by the BTS Cell

Packet Assignment Taken Over by the BTS Cell

Packet System Information Cell



Paging Cell

Paging Cell

Paging Cell

Paging Cell

Paging Cell

Paging Cell

O&M of BTSTRX Working Voltage Adjustment

PoC QoS Cell

PoC QoS Cell

PoC QoS Cell

PoC QoS Cell

Point To Point Short Message Service TS21, TS22 Cell

Point To Point Short Message Service TS21, TS22 Cell

Power Control Cell

Power Optimization Based on Channel Type Cell

Power Optimization Based on Channel Type Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Public Voice Group Call Service Cell

Public Voice Group Call Service Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

QoS ARP&THP Cell

Radio Common Channel Management Cell


Processing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement Report

Public Voice Group Call ServicePublic Voice Broadcast ServicePublic Voice Group Call ServicePublic Voice Broadcast ServicePublic Voice Group Call ServicePublic Voice Broadcast ServicePublic Voice Group Call ServicePublic Voice Broadcast ServicePublic Voice Group Call ServicePublic Voice Broadcast ServicePublic Voice Group Call ServicePublic Voice Broadcast ServicePublic Voice Group Call ServicePublic Voice Broadcast ServicePublic Voice Group Call ServicePublic Voice Broadcast ServicePublic Voice Group Call ServicePublic Voice Broadcast Service
















Radio Dedicated Channel Management Cell



































RAN Sharing Cell

Resource Reservation Cell



Robust Air Interface Signalling Cell



SDCCH Dynamic Adjustment Cell




Cell

Short Message Service Cell Broadcast TS23 Cell

SDCCH HandoverEnhanced Channel Assignment Algorithm

Simplified Cell Broadcast Cell














Soft-Synchronized Network Cell

Streaming QoSGBR Cell

Streaming QoSGBR Cell

System Information Sending Cell

System Information Sending Cell

Talker Identification Cell

TC Pool Cell

TCH Re-assignment Cell

TCH Re-assignment Cell

TRX Cooperation Cell



TRX Power Amplifier Intelligent Shutdown Cell

TRX Power Amplifier Intelligent Shutdown Cell

Cell

Voice Quality Index Uplink VQI Cell










WB AMR Cell

WB AMR Cell

WB AMR Cell

WB AMR Cell

WB AMR Cell

WB AMR Cell

WB AMR Cell

Uplink EGPRS2-ADownlink EGPRS2-A

WB AMR Cell

WB AMR Cell

WB AMR Cell

PARAMETER_ID PARAMETER_NAME MML_COMMANDPOS2QUATER 2Quater Message TransSET GCELLCCUTRANSYS

ENGSMPSDLMACUser Plane DL Flow CtrSET GCELLPSOTHERPARA

MSCVER MSC Version IndicationSET GCELLCCUTRANSYS

ENCRY Encryption Algorithm SET GCELLBASICPARA

SDFASTHOSWIT SD Quick HO SET GCELLSOFT

ACCCONTROLCLAccess Control Class SET GCELLPRACH

MAXRETRANS1 Max Retransmissions forSET GCELLPRACH




PL1 Persistence Level 1 SET GCELLPRACH




SVALUE S Value SET GCELLPRACH

TXINT TX_INT SET GCELLPRACH

ACCBURST Access Burst Type SET GCELLPSBASE

AccStaServiceTypPS Initial Access Servi SET GCELLPSOTHERPARA

MAXTA Max TA SET GCELLBASICPARA

FREQADJ Frequency Adjust SwitcSET GCELLOTHEXT

FREQADJVALUE Frequency Adjust ValueSET GCELLOTHEXT

RTPSWITCH Measure Link Delay SwiSET GCELLBASICPARA

AMRDADTHAW AMR Downlink AdaptiveSET GCELLCCAMR

AMRUADTHAW AMR Uplink Adaptive TSET GCELLCCAMR

DLLTFERLOWTH Downlink Long-term FESET GCELLCCAMR

DLLTFERTGT Downlink Long-term FESET GCELLCCAMR

DLLTFERUPTH Downlink Long-term FESET GCELLCCAMR

DLLTTHADJFA Downlink Threshold AdjSET GCELLCCAMR

LTFERLOWTH Uplink Long-term FER SET GCELLCCAMR

LTFERTGT Uplink Long-term FER TSET GCELLCCAMR

LTFERUPTH Uplink Long-term FER SET GCELLCCAMR

LTTHADJFA Uplink Threshold AdjustSET GCELLCCAMR

RATECTRLSW AMR Rate Control SwitSET GCELLCCAMR

RATSCCHENABLIs Ratscch Function EnSET GCELLCCAMR

ACTCDSETF AMR ACS[F] SET GCELLCCAMR

AUTOADJULTHHYAuto Adjust UL TH and SET GCELLCCAMR

DLHYSTF1 AMR DL Coding Rate adSET GCELLCCAMR



DLTHF1 AMR DL Coding Rate adSET GCELLCCAMR



INITCDMDF AMR Starting Mode[F] SET GCELLCCAMR

ULHYSTF1 AMR UL Coding Rate adSET GCELLCCAMR



ULTHF1 AMR UL Coding Rate adSET GCELLCCAMR



NBAMRTFOSWITTFO Switch SET GCELLBASICPARA

ACTCDSETH AMR ACS[H] SET GCELLCCAMR

AUTOADJULTHHYAuto Adjust UL TH and SET GCELLCCAMR

DLHYSTH1 AMR DL Coding Rate adSET GCELLCCAMR



DLTHH1 AMR DL Coding Rate adSET GCELLCCAMR



INITCDMDH AMR Starting Mode[H] SET GCELLCCAMR

ULHYSTH1 AMR UL Coding Rate adSET GCELLCCAMR



ULTHH1 AMR UL Coding Rate adSET GCELLCCAMR



AMRTCHHPRIORAMR TCH/H Prior Allo SET GCELLCHMGAD

AMRTCHHPRIORAMR TCH/H Prior Cell SET GCELLCHMGAD

AFRDSBLCNT AFR Radio Link TimeouSET GCELLCCBASIC

AFRSAMULFRM AFR SACCH Multi-Fra SET GCELLCCBASIC

AHRDSBLCNT AHR Radio Link TimeouSET GCELLCCBASIC

AHRSAMULFRM AHR SACCH Multi-Fra SET GCELLCCBASIC

HOPTRXHSN Hop TRX Group HSN ADD GCELLHOPANTGRP

HOPTRXINDEX Hop TRX Group Index ADD GCELLHOPANTGRP

HPANTMODE Cell Antenna Hopping SET GCELLHOPANT

HPANTMODE Cell Antenna Hopping SET GCELLHOPANTQUICKSETUP

FASTCALLTCHTHFast Call Setup TCH U SET GCELLBASICPARA

IMMASSCBB Immediate Assignment SET GCELLBASICPARA

IMMASSEN TCH Immediate AssignSET GCELLBASICPARA

ACS Additional Reselect ParSET GCELLIDLEAD

PT Cell Reselect Penalty TSET GCELLIDLEAD

TO Cell Reselect TemporarSET GCELLIDLEAD

CRH Cell Reselect Hysteres SET GCELLIDLEBASIC

CRO Cell Reselect Offset SET GCELLIDLEBASIC

PI Cell Reselect ParameterSET GCELLIDLEBASIC

CBQ Cell Bar Qualify SET GCELLIDLEBASIC

CBA Cell Bar Access SET GCELLIDLEBASIC

NCCPERMIT NCC Permitted SET GCELLIDLEBASIC

TIGHTBCCHASSMLevel Thresh for Ass SET GCELLCHMGAD

TIGHTBCCHASSMQuality Thresh for As SET GCELLCHMGAD

TIGHTBCCHSWITTIGHT BCCH Switch SET GCELLCHMGBASIC

CNFAULTDELAY CN Fault Delay SET GBSCREDGRP

REHOSTABSTIMEReHost Absolute Time SET GREDGRPPRIMHOSTPOLICY

REHOSTDELAYTIReHostDelayTime SET GREDGRPPRIMHOSTPOLICY

REHOSTTYPE ReHost Type SET GREDGRPPRIMHOSTPOLICY

BSSPAGINGCOORBSS Paging Co-ordinatSET GCELLPSBASE

ALTIDECI Antenna Altitude DecimaSET GCELLLCS

ALTITUDE Antenna Altitude Int ParSET GCELLLCS

ANTAANGLE Antenna Azimuth AngleSET GCELLLCS

INCLUDEANG Included Angle SET GCELLLCS

INPUTMD Latitude and Longitude SET GCELLLCS

NSLATI NS Latitude SET GCELLLCS

WELONGI WE Longitude SET GCELLLCS

LATIDECI Latitude Decimal Part SET GCELLLCS

LATIDEGREE Latitude Degree Part SET GCELLLCS

LATIINT Latitude Int Part SET GCELLLCS

LATIMINUTE Latitude Minute Part SET GCELLLCS

LATISECONDDECLatitude Second DecimaSET GCELLLCS

LATISECONDINT Latitude Second Int ParSET GCELLLCS

LONGIDECI Longitude Decimal PartSET GCELLLCS

LONGIDEGREE Longitude Degree Part SET GCELLLCS

LONGIINT Longitude Int Part SET GCELLLCS

LONGIMINUTE Longitude Minute Part SET GCELLLCS

LONGISECONDDELongitude Second DeciSET GCELLLCS

LONGISECONDINLongitude Second Int PSET GCELLLCS

ACTL2REEST Activate L2 Re-establi SET GCELLSOFT

FORCEDCELLEFRAllow Forced EFR in CeSET GCELLSOFT

MSCAPABLESTATMS Capability Statistic SET GCELLSOFT

TMRBADQUALDISTimer for Bad Quality DISET GCELLSOFT

CALLRESTABDISCall Reestablishment FSET GCELLBASICPARA

FREQLST Freq Band List SET GCELLFREQSCAN

STRTM Start Time SET GCELLFREQSCAN

FREQSCANRLSTFrequency Scan ResultSET GCELLSOFT

INTERBANDSTATInterfere Band Stat Alg SET GCELLSOFT

DBFREQBCCHIU BCCH IUO of Double FrADD GCELL

LAC1 Cell LAC SET BTSAUTOPLANCFG

MAXFQNUM1 Maximum TRX NumberSET BTSAUTOPLANCFG

NBRCELLSWITCHNeighbor Cell Plan SwiSET BTSAUTOPLANCFG

RA1 Route Area SET BTSAUTOPLANCFG

TYPE Freq. Band ADD BTSAUTOPLAN

CGIRACSWITCH CGI and RAC Plan SwitSET BTSAUTOPLANCFG

FQBSICOPTSWITFreq. and BSIC OptimizSET BTSAUTOPLANCFG

FQBSICSWITCH Freq. and BSIC Plan SwSET BTSAUTOPLANCFG

FQBSICSWITCH1Freq. and BSIC Plan SwSET BTSAUTOPLANCFG

RA Route Area SET BTSAUTOPLANCFG

ENIUO Enhanced Concentric AADD GCELL

ASSOLRXLEVOFFAssign to Overlayer Rx SET GCELLCHMGAD

HOOLRXLEVOFFHandover to UnderlayerSET GCELLCHMGAD

HRIUOLDRATESELoad of UL-OL Cells RaSET GCELLCHMGAD

LOWRXLEVOLFORAllocate OL Channel B SET GCELLCHMGAD

TCHTRIBUSYUNDTch Traffic Busy UnderSET GCELLCHMGAD

TCHTRICBUSYOVTch Traffic Busy OverlaSET GCELLCHMGAD

IUOCHNTRAN Dynamic Channel ConverSET GCELLPSCHM

IUOTP Cell IUO Type ADD GCELL

BCC BCC ADD GCELL

BSPAGBLKSRES Number of PAGCH BlocADD GCELL

BSPBCCHBLKS Number of PBCCH BlocADD GCELL

BSPRACHBLKS Number of PRACH BlocADD GCELL

NCC NCC ADD GCELL

NBR2GNCELL1IDNeighbor 2G Cell 1 Ind ADD GIBCAPNCGRP

NBR2GNCELL2IDNeighbor 2G Cell 2 Ind ADD GIBCAPNCGRP

CELLLIST Cell Index List ADD GSMSCB

CELLNAMELIST Cell Name List ADD GSMSCB

CI1 Cell CI SET BTSAUTOPLANCFG

CELL2GBA1BCCH2G NCELL BCCH SET GCELL2GBA1

CELL2GBA1TAG 2GBA1 Input Tag SET GCELL2GBA1

VOICEVER Speech Version SET GCELLCCACCESS

CELL2GBA2BCCH2G NCELL BCCH SET GCELLHO2GBA2

CELL2GBA2TAG 2GBA2 Input Tag SET GCELLHO2GBA2

HOCTRLSWITCH Current HO Control Alg

FDDBA2TAG FDDBA2 Input Tag SET GCELLHOFDDBA2

TDDBA2TAG TDDBA2 Input Tag SET GCELLHOTDDBA2

TDDSCRAMBLE Cell Parameter ID SET GCELLHOTDDBA2

ITEM NCCELL No.

SET GCELLHOBASICSET GCELLHOEMGSET GCELLHOFITPENSET GCELLHOIUO

SET GCELLIDLEFDDBA1SET GCELLIDLETDDBA1SET GCELL2GBA1SET GCELLHO2GBA2SET GCELLHOFDDBA2SET GCELLHOTDDBA2

ITEMVALID Item Valid

FRAMEOFFSET Frame Offset SET GCELLOTHEXT

RFMAXPWRDEC Max RC Power ReductiSET GCELLOTHEXT

TFRMSTARTTIMEFrame Start Time SET GCELLOTHEXT

ITEMINDEX Item Index SET GCELLREV

ITEMVALUE Value SET GCELLREV

DIRECTRYEN Directed Retry SET GCELLBASICPARA

ASSLOADJUDGEAssignment Cell Load SET GCELLCCBASIC

DTLOADTHRED Directed Retry Load AcSET GCELLCCBASIC

CDRTTRYFBDTHCell Directed Retry For SET GCELLOTHEXT

DRXTIMERMAX Max. Duration of DRX SET GCELLPSBASE

SPGCCCCHSUP Support SPLIT_PG_C SET GCELLPSBASE

FRDLDTX FR Use Downlink DTX SET GCELLBASICPARA

HRDLDTX HR Use Downlink DTX SET GCELLBASICPARA

SET GCELLIDLEFDDBA1SET GCELLIDLETDDBA1SET GCELL2GBA1SET GCELLHO2GBA2SET GCELLHOFDDBA2SET GCELLHOTDDBA2

FRULDTX FR Uplink DTX SET GCELLBASICPARA

HRULDTX HR Uplink DTX SET GCELLBASICPARA

ENTCHADJALLO Enhanced TCH Adjust ASET GCELLCHMGBASIC

PROTECTTIME Dyn. Turning Off Cell PSET GCELLDYNTURNOFF

SAMECVGCELLL Same Coverage Cell LoSET GCELLDYNTURNOFF

SAMECVGCELLL Same Coverage Cell LoSET GCELLDYNTURNOFF

TURNOFFCELLC Dyn. Turning Off Cell SET GCELLDYNTURNOFF

TURNOFFCELLSTDyn. Turning Off Cell SSET GCELLDYNTURNOFF

TURNOFFCELLSTDyn. Turning Off Cell SSET GCELLDYNTURNOFF

TURNONCELLLODyn. Turning On Cell L SET GCELLDYNTURNOFF

SAMECVGCELLIDSame Coverage Cell NSET GCELLDYNTURNOFF

SAMECVGCELLIDSame Coverage Cell InSET GCELLDYNTURNOFF

SAMECVGCELLNSame Coverage Cell NSET GCELLDYNTURNOFF

TURNOFFENABL Enable Turning Off CellSET GCELLDYNTURNOFF

DYNPBTSUPPORDynamic Transmission SET GCELLCHMGBASIC

STIRCALLOWED EICC Allowed SET GCELLSOFT

EMCPRILV Priority of Emergency CSET GCELLCCAD

PREEMPTIONPEREmergency Call PreempSET GCELLCCAD

ERGCALLDIS Emergent Call Disable SET GCELLCCBASIC

RSVCHMFORECNMax Channel Num ReseSET GCELLCHMGBASIC

DUMMYBITRANDDummy Bit RandomizatiSET GCELLSOFT

STOPSI5SWITCHStop Send SI 5/5bis/5teSET GCELLSOFT

TCHTIMEHOPERITCH Time Handover PeSET GCELLSOFT

TCHTIMEHOSWITTCH Time Handover SwSET GCELLSOFT

FLEXTSCSWITCHFlex TSC Switch SET GCELLSOFT

MAINBCCHPWDTPower Derating Active SET GCELLOTHEXT

MAINBCCHPWRDPower Derating EnableSET GCELLOTHEXT

MAINBCCHPWRDTPower Derating End Ti SET GCELLOTHEXT

MAINBCCHPWRDPower Derating Range SET GCELLOTHEXT

MAINBCCHPWRDTPower Derating Start T SET GCELLOTHEXT

CHANINTERMES Active CH Interf. Meas.SET GCELLCHMGAD

CHPWRINSUFFA Channel Assign Allow foSET GCELLCHMGAD

CIRESTVALUE C/I Estimate Value SET GCELLCHMGAD

FREQLOADSHARGSM900 Band Traffic LSET GCELLCHMGAD

HISPRIOALLOW History Record Priority SET GCELLCHMGAD

INTERFPRIALLO Interf. Priority Allowed SET GCELLCHMGAD

LOADSHAREALL Balance Traffic AllowedSET GCELLCHMGAD

MCPAOPTALG MCPA Optimization SwiSET GCELLCHMGAD

NAMRLFRMTRXAAssign Non-AMR User SET GCELLCHMGAD

PWRPRIORALLO Power Priority Allowed SET GCELLCHMGAD

QTRUPWRSHAREMulti-Density TRX PoweSET GCELLCHMGAD

TCHBUSYTHRESTCH Traffic Busy ThresSET GCELLCHMGAD

TRXPRIALLOW Allocation TRX Priority SET GCELLCHMGAD

ALLOWAMRHALFRatio of AMR-HR SET GCELLCHMGBASIC

ALLOWHALFRAT Ratio of TCHH SET GCELLCHMGBASIC

CHALLOCSTRAT Channel Allocate Strat SET GCELLCHMGBASIC

FACTORYMODE Factory Mode SET GCELLCHMGBASIC

INTERFTHRES0 Interference Band ThreSET GCELLOTHEXT






INTERPERIOD Interference Calculatio SET GCELLOTHEXT

CELLINEXTP Cell Inner/Extra PropertADD GCELL

DBLFREQADJCIDSame Group Cell IndexADD GCELL

DBLFREQADJCN Same Group Cell NameADD GCELL

DBLFREQADJIDTSame Group Cell IndexADD GCELL

ATCBHYST Distance Hysteresis BeSET GCELLHOEDBPARA

ATCBTHRED Distance Between BoundSET GCELLHOEDBPARA

EDBLASTTIME Number of Satisfactor SET GCELLHOEDBPARA

EDBSTATTIME Total Number of MeasuSET GCELLHOEDBPARA

EDBSYSFLOWLESubcell HO Allowed FloSET GCELLHOEDBPARA

HOPENALTYTIMEInter UL/OL Subcells HSET GCELLHOEDBPARA

INNASSOPTEN OL Subcell Assignment SET GCELLHOEDBPARA

INNCELLEDGEHOInner Cell EDGE HO EnSET GCELLHOEDBPARA

INNLOADHOEN Load HO of OL Subcell SET GCELLHOEDBPARA

INNLOADHOPERIOL Subcell Load DiversSET GCELLHOEDBPARA

INNLOADHOSTEPStep Length of OL Sub SET GCELLHOEDBPARA

INNSERIOVERLDInner Cell Serious Ove SET GCELLHOEDBPARA

INTOINNREXLEV Incoming OL Subcell HSET GCELLHOEDBPARA

OUTASSOPTEN UL Subcell Assignment SET GCELLHOEDBPARA

OUTGENOVERLDUL Subcell General OveSET GCELLHOEDBPARA

OUTINNREXLEVTOutgoing OL Subcell HSET GCELLHOEDBPARA

OUTLOADHOENALoad HO Allowed SET GCELLHOEDBPARA

OUTLOADHOMODMOD Step LEN of UL LSET GCELLHOEDBPARA

OUTLOADHOPERUL Subcell Load HierarSET GCELLHOEDBPARA

OUTLOADHOSTEStep Length of UL SubcSET GCELLHOEDBPARA

OUTLOWLOADTHUL Subcell Lower LoadSET GCELLHOEDBPARA

OUTSERIOVERLDUL Subcell Serious OveSET GCELLHOEDBPARA

INVALBSICEN Invalid BSIC Reporting SET GCELLCCUTRANSYS

MEASURETYPE Measurement Report TSET GCELLCCUTRANSYS

SCALEORDER SCALE_ORDER SET GCELLCCUTRANSYS

SEARCH3G 3G Search PRIO SET GCELLCCUTRANSYS

CBSIGNLEN Filter Length for SDC SET GCELLHOFITPEN

CBTRAFFLEN Filter Length for TCH SET GCELLHOFITPEN

MBSIGNLEN Filter Length for SD SET GCELLHOFITPEN

MBTRAFFLEN Filter Length for TCH SET GCELLHOFITPEN

NRBSDCCHFFLEFilter Length for S SET GCELLHOFITPEN

NRBTCHFFLEN Filter Length for TC SET GCELLHOFITPEN

RQSIGNLEN Filter Length for SD SET GCELLHOFITPEN

RQTRAFFLEN Filter Length for TCH SET GCELLHOFITPEN

EMLPPEN Allow EMLPP SET GCELLCCBASIC

HIGHESTPRIORITHighest Priority for QualSET GCELLCHMGBASIC

HIGHPRIUSERQUHighest Priority User QuaSET GCELLCHMGBASIC

DNPCEN DL PC Allowed SET GCELLBASICPARA

UPPCEN UL PC Allowed SET GCELLBASICPARA

EXTTP Cell Extension Type ADD GCELL

EXTCELLTHRENHExtended Cell ThroughSET GCELLPSOTHERPARA

CELLSELECTAFTSelect 3G Cell After CaSET GCELLCCAD

LOWLEVSUBRESLow-level Sublink ResoSET GCELLSOFT

SUBRESPREEMPSublink Resources Pre SET GCELLSOFT

FLEXMAIO Start Flex MAIO SwitchADD GCELL

HSNSW HSN Modification SwitcADD GCELL

TYPE Freq. Band ADD GCELL

OTHERFREQ Other Frequency ADD GCELLQUICKSETUP

BCCHFREQ Main BCCH FrequencyADD GCELLQUICKSETUP

TYPE Cell Type ADD GCELLQUICKSETUP

HSN HSN ADD GCELLMAGRP

TSC TSC ADD GCELLMAGRP

HOPINDEX Hop Index ADD GCELLMAGRP

HOPMODE Hop Mode ADD GCELLMAGRP

CANPC PWRC SET GCELLCCCH

BCCHTRXHP Frequency Hopping MoSET GCELLHOPQUICKSETUP

FHMODE Frequency Hopping Mo

MACODINGMOD ARFCN Coding SchemSET GCELLSOFT

DATATRAFFSET Data Service Allowed SET GCELLOTHEXT

BVCI PTP BVC Identifier

EMLPPPRIORITYeMLPP Priority SET GCELLGSMR

FACCHSENDNOTFACCH Send NotificatioSET GCELLGSMR

FACCHSENDPGMFACCH Send Paging MsgSET GCELLGSMR

GCSIMPREEMPTIVGCS IM Preemption ESET GCELLGSMR

SENDFACCHNOTPSend FACCH NotificationSET GCELLGSMR

SENDFACCHPAGPSend FACCH Paging PriSET GCELLGSMR

CSDSP CS Data Service PRI ADD GCELL

CSVSP CS Voice Service PRI ADD GCELL

PSHPSP PS High PRI Service P ADD GCELL

PSLPSVP PS Low PRI Service PRADD GCELL

VIPCELL VIP Cell ADD GCELL

ABISFCEN SDCCH Congestion FlowSET GCELLCCCH

PAGINGAVGCAPAAverage Paging MessagSET GCELLSOFT

PAGINGMAXCAPAMAX Paging Message NSET GCELLSOFT

DIVERSITY Diversity

FDDCELLOFF FDD Reporting Offset SET GCELLCCUTRANSYS

FDDCELLTHRED FDD Reporting ThreshoSET GCELLCCUTRANSYS

FDDFREQCNUM FDD Multirate Reportin SET GCELLCCUTRANSYS

FDDQMIN FDD Qmin SET GCELLCCUTRANSYS

FDDQMINOFFSETFDD Qmin Offset SET GCELLCCUTRANSYS

SET GCELLHOPTPSET GCELLHOPQUICKSETUP

ADD PTPBVCBLK PTPBVC

ADD GEXT3GCELLSET GCELLHOFDDBA2SET GCELLHOTDDBA2

FDDQOFF FDD Q Offset SET GCELLCCUTRANSYS

FDDREP FDD REP QUANT SET GCELLCCUTRANSYS

FDDRSCPMIN FDD RSCP Min. SET GCELLCCUTRANSYS

FDDBA1TAG FDDBA1 Input Tag SET GCELLIDLEFDDBA1

FDDDIVERSITY Diversity Indication SET GCELLIDLEFDDBA1

FDDDLUARFAN Downlink Frequency SET GCELLIDLEFDDBA1

FDDSCRAMBLE Scrambling Code SET GCELLIDLEFDDBA1

SCRAMBLE Scrambling Code or Cel

DF DL UARFCN

CELL1800OFF 1800 Reporting Offset SET GCELLCCUTRANSYS

CELL1800THRED1800 Reporting ThreshoSET GCELLCCUTRANSYS

CELL900OFF 900 Reporting Offset SET GCELLCCUTRANSYS

CELL900THRED 900 Reporting ThresholSET GCELLCCUTRANSYS

QCI Qsearch C Initial SET GCELLCCUTRANSYS

ADD GEXT3GCELLSET GCELLHOFDDBA2

ADD GEXT3GCELLSET GCELLHOFDDBA2SET GCELLHOTDDBA2

QI Qsearch I SET GCELLCCUTRANSYS

QP Qsearch P SET GCELLCCUTRANSYS

QSEARCHC Qsearch C SET GCELLCCUTRANSYS

HOECNOTH3G Ec/No Threshold for BeSET GCELLHOUTRANFDD

BET3GHOEN Better 3G Cell HO Allo

HORSCPTH3G RSCP Threshold for Bet

HRATESPT Support Half Rate SET GCELLCCCH

SET GCELLHOUTRANFDDSET GCELLHOUTRANTDD


NBR2GNCELL1N Neighbor 2G Cell 1 Na ADD GIBCAPNCGRP

NBR2GNCELL2N Neighbor 2G Cell 2 Na ADD GIBCAPNCGRP

IBCAAFRSOFTBLIBCA AMR FR Soft BlocSET GCELLCHMGAD

IBCAAHRSOFTBLIBCA AMR HR Soft BlocSET GCELLCHMGAD

IBCAALLOWED IBCA Allowed SET GCELLCHMGAD

IBCAASSWAITMEIBCA Assign Waiting MSET GCELLCHMGAD

IBCACALLINFOFI IBCA Call Information FiSET GCELLCHMGAD

IBCACALLSOFTBIBCA Set-up Call Soft BSET GCELLCHMGAD

IBCACALLTARGETarget CIR Offset of IB SET GCELLCHMGAD

IBCADLPATHLOSIBCA Downlink Path LosSET GCELLCHMGAD

IBCAEHOASSWAIIBCA Urgent HO WaitinSET GCELLCHMGAD

IBCAFLEXTSCAL IBCA Flexible TSC All SET GCELLCHMGAD

IBCAFORCEDBT IBCA Forced BTS SynchSET GCELLCHMGAD

IBCAFRSOFTBLKIBCA FR/EFR Soft BlocSET GCELLCHMGAD

IBCAHOASSWAITIBCA HO Waiting EffectSET GCELLCHMGAD

IBCAHRSOFTBLKIBCA HR Soft Block ThSET GCELLCHMGAD

IBCAICDMRELEVIBCA ICDM Initial LevelSET GCELLCHMGAD

IBCAICDMSWITCIBCA ICDM Switch SET GCELLCHMGAD

IBCAINITPCRXLEIBCA Init. Power Contr SET GCELLCHMGAD

IBCAINITPCRXLEIBCA Init. Power Contr SET GCELLCHMGAD

IBCAINITPCRXQ IBCA Init. Pwr Ctrl Rx SET GCELLCHMGAD

IBCAINITPCRXQ IBCA Init. Pwr Ctrl Rx SET GCELLCHMGAD

IBCAIUOPATHLOIBCA IUO Path Loss OffSET GCELLCHMGAD

IBCAMAIOUSMTDIBCA MAIO Using MethSET GCELLCHMGAD

IBCAMAXINTFSRIBCA Max. Interferenc SET GCELLCHMGAD

IBCANCELLPATHIBCA Pathloss Est of NSET GCELLCHMGAD

IBCANEWCALLCITarget CIR Offset of I SET GCELLCHMGAD

IBCANHOASSWAIIBCA Natural HO Waiti SET GCELLCHMGAD

IBCANONMEANCIBCA Non Measurement SET GCELLCHMGAD

IBCAOPRREVISECorrected Factor of IBCSET GCELLCHMGAD

IBCAPATHLOSSOIBCA Pathloss Offset SET GCELLCHMGAD

IBCAPLFILTFACTIBCA Path Lose Filter FSET GCELLCHMGAD

IBCASCELLPATHIBCA Service Cell PathSET GCELLCHMGAD

IBCASOFTBLKSAIBCA Soft Block SAIC OSET GCELLCHMGAD

IBCASOFTBLKSWIBCA Soft Block SwitchSET GCELLCHMGAD

IBCASUBCHNHA IBCA Sub-Channel HanSET GCELLCHMGAD

IBCATARGETCIRIBCA MAIO Target C/I SET GCELLCHMGAD

IBCAUSEDIUOSUIUO IBCA Allowed SET GCELLCHMGAD

IBCAUSRDYNCMIBCA User Dyn MeasureSET GCELLCHMGAD

IBCAWAFRSOFTBIBCA WAMR FR Soft BlSET GCELLCHMGAD

LOOSESDCCHLOIBCA Loose Trx SDCCHSET GCELLCHMGAD

TIGHTSDCCHRXLIBCA Tight Trx SDCCH SET GCELLCHMGAD

WAITSDCCHIDLEIBCA Wait SDCCH Idle SET GCELLCHMGAD

MAIO1 MAIO 1 SET GCELLMAIOPLAN












HOPINDEX Hop Index SET GCELLMAIOPLAN

ATT Attach-detach Allowed SET GCELLIDLEBASIC

ICBALLOW ICB Allowed SET GCELLBASICPARA

RTTIPDCHMULTI RTTI PDCH Multiplex TSET GCELLPSCHM

OutSysLoadHoEn Allow Inter-RAT Load HSET GCELLHOINTERRATLDB

IDTYPE Index Type SET GCELLHOINTERRATLDB

MSRDMCSLEV MSRD MCS Threshold SET GCELLPSCHM

MBR Multi-band report SET GCELLCCBASIC

GSMFREQCNUM Serving Band ReportingSET GCELLCCUTRANSYS

BANDINDICATORHigh Band Indicator of SET GCELLSOFT



PWRLOCATION Location Group Power SET GCELLSOFT

NMO Network Operation ModSET GCELLPSBASE

BTSSAICPCADJSSwitch for BTS SupportSET GCELLSOFT

ALLOWEDMEASRAllowed Measure ReporSET GCELLNC2PARA

CELLRESELSTRA2G/3G Cell ReselectionSET GCELLNC2PARA

CELLRXQUALWOCell Rx Quality WorsenSET GCELLNC2PARA

EGPRSBEPLIMIT EDGE 8PSK Quality ThSET GCELLNC2PARA

EGPRSBEPLIMIT EDGE GMSK Quality ThSET GCELLNC2PARA

FILTERWNDSIZE Filter Window Size SET GCELLNC2PARA

GPRSRXQUALLIMGPRS Quality ThresholSET GCELLNC2PARA

LOADRESELALL Cell Load Reselection SET GCELLNC2PARA

LOADRESELMAXLoad Reselect Level ThSET GCELLNC2PARA

LOADRESELRXT Load Reselection ReceiSET GCELLNC2PARA

LOADRESELSTA Load Reselection Start SET GCELLNC2PARA

MINACCRXLEV Cell Reselection Level SET GCELLNC2PARA

MSRXQUALSTATMS Rx Quality Statistic SET GCELLNC2PARA

NORMALRESELACell Normal Reselectio SET GCELLNC2PARA

PENALTYLASTTMCell Penalty Duration SET GCELLNC2PARA

PENALTYRXLEV Cell Penalty Level SET GCELLNC2PARA

RESELHYST Cell Reselection HysterSET GCELLNC2PARA

RESELINTERVALCell Reselect Interval SET GCELLNC2PARA

RESELWATCHPENormal Cell Reselectio SET GCELLNC2PARA

RESELWORSENLNormal Cell Reselectio SET GCELLNC2PARA

URGENTRESELACell Urgent ReselectionSET GCELLNC2PARA

NONDRXPERIODNon-DRX Period SET GCELLNWCTRLMSRPARA

RPTPERIODI Cell Reselection MR PeSET GCELLNWCTRLMSRPARA

RPTPERIODT Cell Reselection MR PeSET GCELLNWCTRLMSRPARA

NCO Network Control Mode SET GCELLPSBASE

CHANFAULTALM PDCH Available ThreshoSET GCELLSOFT

CHANPDOUTTIM PDCH Out-of-SynchroniSET GCELLSOFT

HOCELLIDTYPE Specify Index of Cell H SET FHO

HOCELLNAME Cell Name of Handover SET FHO

HOMOD Handover Scope SET FHO

CHANFAULTALMSMonitoring Alarm SwitchSET GCELLSOFT

CHANFAULTALM TCH Available ThresholSET GCELLSOFT

DETECTFRAMEPEPeriod of Mute Detect SET GCELLSOFT

EXCEPFRAMETHExceptional Frame ThreSET GCELLSOFT

MUTECHECKCLASPeriod of Mute Detect SET GCELLSOFT

MUTECHECKCLAMute Detect Class2 SwiSET GCELLSOFT

MUTECHECKPEI Period of Mute Detect SET GCELLSOFT

MUTEFORBITCALAccess Prohibited Upo SET GCELLSOFT

MUTERELCALLENForced Call Release U SET GCELLSOFT

TCMUTEDETECTMute Detect Class1 SwiSET GCELLSOFT

UMCROSSTALKOUm Interface Crosstalk SET GCELLSOFT

OPC OSP Code ADD GCELLQUICKSETUP

ADMSTAT Administrative State SET GCELLADMSTAT

LOWNOISESWH Diversity LNA Bypass PSET GCELLOTHBASIC

CELLCOVERAGECell Coverage Type SET GCELLOTHEXT

PODECTHRES Power Output ReductioSET GCELLOTHEXT

POERRTHRES Power Output Error ThrSET GCELLOTHEXT

VSWRERRTHRESVSWR TRX Unadjusted SET GCELLOTHEXT

VSWRUNJUSTTHVSWR TRX Error ThresSET GCELLOTHEXT

OUTSERVICEALMCell Out-of-Service Ala SET GCELLSOFT

BTSadjust Adjust Voltage SET GCELLBASICPARA

IMMASSDLSHIFTMove Immediate Assig SET GCELLPSOTHERPARA

PACKASSDLSHIFMove Packet AssignmeSET GCELLPSOTHERPARA

MEASORDER Allow MR Command or SET GCELLPSI1

PSI1RPT PSI1 Repetition Period SET GCELLPSI1

PSISTATUSIND Support PSI Status Me SET GCELLPSI1

PAGTIMES Paging Times SET GCELLCCBASIC

BSPAMFRAMS Multi-Frames in a Cycl SET GCELLIDLEBASIC

PAGINGLIFETIMEBTS Paging Lifetime SET GCELLSOFT

PMOAFLAG Cell Paging Package SwSET GCELLSOFT

PMI Interval for Sending CeSET GCELLSOFT

PMNUM Number of Cell Paging SET GCELLSOFT

POCDELAY Transmission Delay of SET GCELLPSOTHERPARA

POCGBRMAX Max. GBR for POC ServSET GCELLPSOTHERPARA

POCGBRMIN Min. GBR for POC ServSET GCELLPSOTHERPARA

PocSup POC Support SET GCELLPSOTHERPARA

DNSENDSMDIS Short Message DownlinSET GCELLCCAD

UPSENDSMDIS Short Message Uplink DSET GCELLCCAD

CELL8PSKPOWERCell 8PSK Power AttenSET GCELLBASICPARA

TIMESLOTVOLADVoltage Adjust Based TSET GCELLBASICPARA

PDCHPWRSAVENPDCH Power Saving EnSET GCELLSOFT

LEVELRPT Level Report Switch SET GCELLBASICPARA

EXTMEASORD Extension Measureme SET GCELLEXTMSRPARA

EXTRPTPERIOD Extension MR Period SET GCELLEXTMSRPARA

EXTRPTTYPE Extension MR Type SET GCELLEXTMSRPARA

INTFREQUENCY Interference FrequencySET GCELLEXTMSRPARA

NCCPERMITED NCC Permitted SET GCELLEXTMSRPARA

CELLOVERCVGRCell Over Coverage DLSET GCELLOTHEXT

CELLOVERCVGTACell Over Coverage TASET GCELLOTHEXT

CELLWEAKCVGRCell Weak Coverage DLSET GCELLOTHEXT

CELLWEAKCVGTCell Weak Coverage TASET GCELLOTHEXT

DTRTYPE DRX Type SET GCELLGSMR

NY2 Ny2 SET GCELLGSMR

CRMSGRESENDIChannel Release ResendSET GCELLGSMR

CRMSGRESENDNChannel Release ReseSET GCELLGSMR

DLTESTRESENDIDownload Test Resend ISET GCELLGSMR

DLTESTRESEND Download Test ResendSET GCELLGSMR

FACCHRESENDINFACCH Msg Resend IntSET GCELLGSMR

GCSCHNASSULCVGCS Channel Assign iSET GCELLGSMR

NCHOCBLOCKNUNCH Occupy Block Nu SET GCELLGSMR

NCHSTARTBLOCNCH Start Block SET GCELLGSMR

UIC UIC SET GCELLGSMR

BEARP1PRIWEIGBestEffort-ARP1 Priorit SET GCELLPSCHM



BKGARP1PRIWEIBackground-ARP1 PriorSET GCELLPSCHM



THP1ARP1PRIWETHP1-ARP1 Priority WeSET GCELLPSCHM









QOSOPT Support QoS Optimize SET GCELLPSOTHERPARA

PSRACHACCLEVPS RACH Min. Access SET GCELLCCACCESS

PWRDIV Power Deviation SET GCELLCCACCESS

PWRDIVIND Power Deviation IndicatSET GCELLCCACCESS

RACHACCLEV CS RACH Min. Access SET GCELLCCACCESS

RANERRTHRED Random Access Error TSET GCELLCCACCESS

COMMACC Common Access ControSET GCELLCCBASIC

MSMAXRETRAN MS MAX Retrans SET GCELLCCBASIC

RACHBUSYTHRERACH Busy Threshold SET GCELLCCBASIC

SPECACC Special Access ControlSET GCELLCCBASIC

CCCHLOADINDP CCCH Load Indication SET GCELLCCCH

CCCHLOADTHRECCCH Load Threshold SET GCELLCCCH

FMSMAXOPCC MS_TXPWR_MAX_CCSET GCELLCCCH

OVERLOADINTV Overload Indication PerSET GCELLCCCH

RACHLDAVERSL Average RACH Load TiSET GCELLCCCH

BSAGBLKSRES CCCH Blocks ReservedSET GCELLIDLEBASIC

TX TX-integer SET GCELLIDLEBASIC

CELLPAGINGOV Cell Paging Overload TSET GCELLSOFT

MAXTADROPCALLMAX TA Drop Call FilteSET GCELLCCAD

MAXTADROPCALMax TA Drop Call SwitcSET GCELLCCAD

MAXTADROPCALMAX TA Drop Call ThreSET GCELLCCAD

RLT Radio Link Timeout SET GCELLCCBASIC

SAMULFRM SACCH Multi-Frames SET GCELLCCBASIC

RFRESINDPRD Radio Resource ReportSET GCELLCCCH

SDDROPSTATDLLDL Level Threshold fo SET GCELLOTHEXT

SDDROPSTATDLDL Quality Threshold f SET GCELLOTHEXT

SDDROPSTATULLUL Level Threshold fo SET GCELLOTHEXT

SDDROPSTATULUL Quality Threshold f SET GCELLOTHEXT

TCHDROPSTATDDL FER Threshold for SET GCELLOTHEXT

TCHDROPSTATDLDL Level Threshold for SET GCELLOTHEXT

TCHDROPSTATDDL Quality Threshold f SET GCELLOTHEXT

TCHDROPSTATUUL FER Threshold for SET GCELLOTHEXT

TCHDROPSTATULUL Level Threshold for SET GCELLOTHEXT

TCHDROPSTATUUL Quality Threshold f SET GCELLOTHEXT

BADQUALDISCTHBad Quality DisconnectSET GCELLSOFT

DROPCTRLABISCDrop Optimize ABIS LinSET GCELLSOFT

DROPCTRLCONNFDrop Optimize Conn FailSET GCELLSOFT

DROPCTRLCONNDrop Optimize Conn FaiSET GCELLSOFT


DROPCTRLCONNFDrop Optimize Conn Fail[SET GCELLSOFT


DROPCTRLEQUIPDrop Optimize EquipmenSET GCELLSOFT

DROPCTRLERRI Drop Optimize Err Ind[uSET GCELLSOFT

DROPCTRLERRI Drop Optimize Err Ind[sSET GCELLSOFT

DROPCTRLERRINDrop Optimize Err Ind[TSET GCELLSOFT

DROPCTRLFORCHDrop Optimize Forced HSET GCELLSOFT

DROPCTRLINBS Drop Optimize Into-BS SET GCELLSOFT

DROPCTRLINTR Drop Optimize Intra-B SET GCELLSOFT

DROPCTRLINTRADrop Optimize Intra-CeSET GCELLSOFT

DROPCTRLNOMRDrop Optimize No MR fSET GCELLSOFT

DROPCTRLOUTBDrop Optimize Out-BSCSET GCELLSOFT

DROPCTRLRELINDrop Optimize Release SET GCELLSOFT

DROPCTRLRESCDrop Optimize ResourcSET GCELLSOFT

CELLOPPWRGRPCell Operator Power G SET GCELLCHMGAD

GRADEACCALLOGrade Access Allow SET GCELLCHMGBASIC

HPRIOR Highest Priority SET GCELLCHMGBASIC

REVCHANNUM Reserved Channel NumSET GCELLCHMGBASIC

REPEATDLFASETRepeated Downlink F SET GCELLCCBASIC

REPEATDLFATHRRepeated Downlink FASET GCELLCCBASIC

REPEATSASET Repeated SACCH SET GCELLCCBASIC

SDDYN SDCCH Dynamic AllocatSET GCELLBASICPARA

CELLMAXSD Cell SDCCH Channel SET GCELLCHMGBASIC

IDLESDTHRES Idle SDCCH Threshold SET GCELLCHMGBASIC

MINRESTIMETCHTCH Minimum RecoverySET GCELLCHMGBASIC

DIFFBANDSDCCHDifferent Band SDCCH SET GCELLCHMGBASIC

IFCBSHAKEHANDIf CB Shake Hand ADD GCBSADDR

CODE Code ADD GSMSCB

ET End Time ADD GSMSCB

INT Broadcast Interval ADD GSMSCB

REP Repeat ADD GSMSCB

ST Start Time ADD GSMSCB

TEXT Content of Message ADD GSMSCB

UPDATE Update ADD GSMSCB

DRXEN SMCBC DRX SET GCELLOTHEXT

BROADCASTCONBroadcast Content SET GCELLSBC

BROADCASTINTEBroadcast Interval SET GCELLSBC

SUPPORTCELLB Support Cell Broadcas SET GCELLSBC

CHANID Chan ID

GS Geography Scope

SCHEME Coding Scheme

TSCPLANEN TSC Plan Enable SET GCELLSOFT

GBRQOS Support GBR QoS SET GCELLPSOTHERPARA

OccupyStreamingSPreempt Switch of Str SET GCELLPSOTHERPARA

RXMIN Minum Access RXLEV SET GCELLBASICPARA

ECSC ECSC SET GCELLCCBASIC

TALKERINFINT Talker Info Interval SET GCELLGSMR

TCPOOLID TC Pool ID SET BSCBASIC

REASSFREQBANFrequency Band of ReaSET GCELLCCAD

REASSEN Allow Reassign SET GCELLCCBASIC

BHPREPOLICY Switchback Policy of B SET GCELLCCACCESS

SET GCELLSBCADD GSMSCB



TRXAIDSWITCH TRX Aiding Function CoSET GCELLCCACCESS

AIDDELAYPROTEAiding Delay Protect T SET GCELLSOFT

DYNOpenTrxPoweAllow Dynamic Shutdo SET GCELLBASICPARA

ReservedIdleCh Reserved TCH Number fSET GCELLOTHEXT

CELLSCENARIO Cell Scenario SET GCELLBASICPARA

RPTVOICE Report Speech Quality SET GCELLOTHBASIC

FERSTATTH1 FER Threshold 1 SET GCELLOTHEXT







FERRPTEN FER Report Enable SET GCELLSOFT

RPTDLVQIALLOWReport Downlink VQI ASET GCELLSOFT

ACTCDSETWB AMR ACS[WB] SET GCELLCCAMR

DLHYSTWB1 AMR DL Coding Rate adSET GCELLCCAMR

DLHYSTWB2 AMR DL Coding Rate adSET GCELLCCAMR

DLTHWB1 AMR DL Coding Rate adSET GCELLCCAMR

DLTHWB2 AMR DL Coding Rate adSET GCELLCCAMR

INITCDMDWB AMR Starting Mode[WBSET GCELLCCAMR

ULHYSTWB1 AMR UL Coding Rate adSET GCELLCCAMR

ULHYSTWB2 AMR UL Coding Rate adSET GCELLCCAMR

ULTHWB1 AMR UL Coding Rate adSET GCELLCCAMR

ULTHWB2 AMR UL Coding Rate adSET GCELLCCAMR

DESCRIPTION GUI_VALUE_RANGE ACTUAL_VALUE_RANGE UNITWhether to transmit the 2Quate BCCHNormBCCHNorm,BCCHNorm, BCCHExt None

Whether to support PS downlink MAOFFOFF, ONON OFF, ON None

Protocol version of the MSC that R98_or_belowR98 or beR98_or_below, R99_or_aboNone

Encryption algorithm supported bA5/0~0 A5/1~1 A5/2~2 A5/0, A5/1, A5/2, A5/3, A5/4None

Whether to enable the SDCCH quicOFFOff, ONOn OFF, ON None

Access control class of the MS 0~65535 0~65535 None

Maximum retransmission for radio p1_Times1_Times, 2_Ti 1_Times, 2_Times, 4_TimesNone




0_level0_level, 1_level10_level, 1_level, 2_level, 3_lNone




Minimum timeslots between two suT_1212, T_1515, T_202T_12, T_15, T_20, T_30, T_None

Extension transmission timeslots T_22, T_33, T_44, T_5 T_2, T_3, T_4, T_5, T_6, T_None

8BIT8BIT, 11BIT11BIT 8BIT, 11BIT None

Whether the initial service is upli ULPRIORITYUplink PriorULPRIORITY, NEUTRAL, DNone

Maximum time advance TA. The va0~255 0~255 None

Whether to enable the automatic fNONo, YESYes NO, YES None

0~65535 0~65535 None

Whether to measure the delay on DISABLEDisable, ENA DISABLE, ENABLE None

Whether to enable the adaptive adjNONo, YESYes NO, YES None

Whether to enable the adaptive adjNONo, YESYes NO, YES None

Lower voice quality threshold as 2~255 2~255 None

Persistence level 1 of the radio access priority.During MS access, the access priority of the MS is set. If the priority of the MS is higher than the access priority of the MS, the cell allows the access of the MS. Otherwise, the cell rejects the access of the MS. The value "no use" indicates this parameter is not used.Persistence level 2 of the radio access priority. During MS access, the access priority of the MS is set. If the priority of the MS is higher than the access priority of the MS, the cell allows the access of the MS. Otherwise, the cell rejects the access of the MS. The value "no use" indicates this parameter is not used.Persistence level 3 of the radio access priority. During MS access, the access priority of the MS is set. If the priority of the MS is higher than the access priority of the MS, the cell allows the access of the MS. Otherwise, the cell rejects the access of the MS. The value "no use" indicates this parameter is not used.Persistence level 4 of the radio access priority. During MS access, the access priority of the MS is set. If the priority of the MS is higher than the access priority of the MS, the cell allows the access of the MS. Otherwise, the cell rejects the access of the MS. The value "no use" indicates this parameter is not used.

Access pulse type of the PRACH, uplink PTCCH and packet control acknowledge message of the MS.8bit: 8 bit pulse access mode; 11bit: 11 bit pulse access mode.

Frequency correction parameter. Used for the fast-moving handover algorithm, the value of this parameter must be translated into a binary number. The value consists of 16 bit. The most significant bit indicates whether the parameter is valid. Bits 14 to 8 indicate the level threshold. Bits 7 to 0 indicate the threshold of the bit error ratio BER.The BSC6900 sends this parameter to the BTS, which adjusts the frequency of an MS according to the value of this parameter.

Target value of the voice quality 2~255 2~255 None

Upper voice quality threshold as 2~255 2~255 None

Factor of downlink threshold adju2~255 2~255 None

2~255 2~255 None

Target voice quality value associ 2~255 2~255 None

Upper voice quality threshold as 2~255 2~255 None

Factor of uplink threshold adjustm2~255 2~255 None

Switch for controlling the AMR ratALG1Algorithm I, ALG2ALG1, ALG2, NONE None

This parameter specifies whetherDISABLEDisable, ENA DISABLE, ENABLE None

Active coding set ACS[F], indicate4_75KBIT/S~0 5_15KBI4_75KBIT/S, 5_15KBIT/S, 5None

Whether to allow automatic adjustmNONo, YESYes NO, YES None

Adjustment hysteresis 1 of AMR do0~15 0~15 None



Adjustment threshold 1 of AMR dow0~63 0~63 dB



Initial coding mode used for full 0~3 0~3 None

Based on the RQI in the call meas0~15 0~15 None



Based on the RQI in the call meas0~63 0~63 dB

Lower voice quality threshold associated with the automatic adjustment of the AMR handover uplink threshold



Whether to enable the Tandem DISABLEDisable, ENA DISABLE, ENABLE None

Active coding set ACS[H], indicate4_75KBIT/S~0 5_15KBI4_75KBIT/S, 5_15KBIT/S, 5None

Whether to allow automatic adjustNONo, YESYes NO, YES None







Initial coding mode used for half 0~3 0~3 None







Whether to enable the BSC to assiOFFOff, ONOn OFF, ON None

Load threshold for assigning half r0~99 0~99 per cen

Counter for radio link failures d 4_Times, 8_Times, 12_1920~30720, step:480 ms

Number of SACCH multiframes dur0~63 0~30240, step:480 ms

Counter for radio link failures d 4_Times, 8_Times, 12_1920~30720, step:480 ms

Number of SACCH multiframes dur0~63 0~30240, step:480 ms

Hoping sequence number HSN of a h0~63 0~63 None

TRX index that a hopping antenna 0~23 0~23 None

NO_HPANTNo, YES_HNO_HPANT, YES_HPANT, None

NO_HPANTNo, YES_HNO_HPANT, YES_HPANT None

After a channel request message i0~100 0~100 per cen

The channel activation and immedNONO, YESYES NO, YES None

Whether to allow immediate TCH aNONo, YESYes NO, YES None

COMPUL0Compulsory 0,COMPUL0, COMPUL1, FLENone

Cell Reselect Penalty Time PT is u0~31 0~31 s

Cell Reselect Temporary Offset TO0~7 0~7 None

Cell reselection hysteresis. This 0dB, 2dB, 4dB, 6dB, 8d0dB, 2dB, 4dB, 6dB, 8dB, 1 dB

Whether to enable the TRX to support antenna hoppingIn a GSM cell, the BCCH broadcasts the frequency, frame number, system information, and paging group. If an MS is in an unfavorable position or the antenna of the main TRX that carries the BCCH fails, the MS receives poor broadcast control signals or even cannot receive any broadcast control message from the BCCH. To avoid such a problem, the antenna hopping function is involved. With this function, the messages transmitted in the main TRX that carries the BCCH are also transmitted on the antennas of all the other TRXs in the cell in turn. This helps the MSs receive quality broadcast control data. This function can be configured only for dual-frequency BTSs. If this parameter is set to NONE, the BTS does not support antenna hopping.Whether to enable the TRX to support antenna hoppingIn a GSM cell, the BCCH broadcasts the frequency, frame number, system information, and paging group. If an MS is in an unfavorable position or the antenna of the main TRX that carries the BCCH fails, the MS receives poor broadcast control signals or even cannot receive any broadcast control message from the BCCH. To avoid such as problem, the antenna hopping function is involved. With this function, the messages transmitted in the main TRX that carries the BCCH are also transmitted on the antennas of all the other TRXs in the cell in turn. This helps the MSs receive quality broadcast control data. This function can be configured only for dual-frequency BTSs.

The default value of this parameter is 0 in system message 3 and, has no special significance.In system message 4, if the value of this parameter is 0, it means that the MSs must retrieve the PI parameters and other parameters relevant to cell reselection and the parameters relevant to C2 calculation from the remaining bytes of system message 4.If the value is 1, it means that the MS must retrieve the parameters from the remaining bytes of system message 7 or 8.

0~63 0~126, step: 2 dB

Cell Reselect Offset CRO, indicating a correction of the C2.Proper setting of this parameter can reduce the number of handover times, helpful for assigning an MS to a better cell. In a special case that the PT is 31, the larger the CRO value is, the lower the possibility of handing over an MS to the cell.Generally, do not set the CRO to a value larger than 25 dB. The CRO with a too large value will cause uncertain states in a network. The CRO values of the cells with different priorities in a network are almost the same. Refer to GSM Rec. 05.08 and GSM Rec. 04.08. The setting of this parameter affects only the MSs supporting the protocol of GSM Phase 2 or a later version.

Cell Reselect Parameters Indicat NONo, YESYes NO, YES None

NONo, YESYes NO, YES None

NONO, YESYES NO, YES None

SELECTION0_PERM, SELECTION0_PERM, SELENone

0~63 0~63 dB

0~7 0~7 None

Whether to enable the BCCH aggrOFFOff, ONOn OFF, ON None

Time delay of the detection on co1~60 1~60 s

YES NO Low NormalYES YES Low NormalYES NO Low NormalYES YES Low Normal

A set of NCCs of the cells to be measured by the MS. This parameter is an information element IE in the system information type 2 and 6 messages. If a bit of the value of this parameter is set to 1, the MS reports the corresponding measurement report to the BTS. The value of this parameter has a byte eight bits. Each bit maps with an NCC 0~7 and the most significant bit corresponds to NCC 7. If bit N is 0, the MS does not measure the cell level of NCC N.2. The uplink receive quality level after filtering is lower than "Quality Thresh. for Assigning Main BCCH Carrier Channel Under TIGHT BCCH". 3. The non-BCCH load is higher than "Intracell Non Main BCCH Load Threshold of TIGHT BCCH".2. The uplink receive quality level after filtering is lower than "Quality Thresh. for Assigning Main BCCH Carrier Channel Under TIGHT BCCH". 3. The non-BCCH load is higher than "Intracell Non Main BCCH Load Threshold of TIGHT BCCH".

Absolute time of re-homing hour, min, sec 00:00:00~23:59:59 None

Delay time of re-homing 1~3600 1~3600 s

Policy type of re-homing REHOSTRIGHTNOWReHREHOSTRIGHTNOW, REHNone

Whether to support the paging fuNONO, YESYES NO, YES None

Decimal part of the antenna altitu0~9 0~0.9, step:0.1 m

Integer part of the antenna altitud0~6553 0~6553 m

Size of the azimuth angle of the c0~360 0~360 degree

Included angle formed by the majo0~360 0~360 degree

Mode of inputting the latitude and DegreeDegree, D_min_Degree, D_min_sec None

Whether the cell is located in the North_latitudeNorth lati North_latitude, South_latitu None

This parameter is used to select thEast_LongitudeEast LoEast_Longitude, West_LongNone

Decimal value when the latitude whNone 1~5 characters degree

Decimal value when the longitude w0~90 0~90 degree

Integer value when the latitude wh0~90 0~90 degree

Value of the minute part when the0~59 0~59 minute

Decimal value of the second part 0~9 0~9 second

Integer value of the second part 0~59 0~59 second

Decimal value when the longitude wNone 1~5 characters degree

Value of the degree part when the0~180 0~180 degree

Integer value when the longitude w0~180 0~180 degree

Value of the minute part when the0~59 0~59 minute

Decimal value of the second part 0~9 0~9 second

Integer value of the second part 0~59 0~59 second

Whether to activate the function NONo, YESYes NO, YES None

Whether to forcibly enable the E NONo, YESYes NO, YES None

Whether to collect the informationOFFOff, ONOn OFF, ON None

Duration time for determining that2~4 2~4 s

Whether to allow call re-establishNONo, YESYes NO, YES None

List of frequency bands 0~1023 0~1023 None

Start time of frequency scanning hour, min, sec HOUR{0~23}, MIN{0~59}, SNone

MainDiversityMainDiv MainDiversity, MaximumMe None

Type of an interference band statINTBANIINTBANI, INTBINTBANI, INTBANII None

Whether the primary BCCH is configInnerInner, ExtraExtra Inner, Extra None

Location area code LAC. The MS ca1~65533,65535 1~65533, 65535 None

Maximum number of TRXs that can1~2 1~2 None

When this switch is on, it indicateOFFOFF, ONON OFF, ON None

Route area of the current cell 0~255 0~255 None

Frequency band to which the newlyGSM900, DCS1800, G GSM900, DCS1800, GSM85None

If the parameter is set to 1, it i OFFOFF, ONON OFF, ON None

Whether to generate the frequencOFFOFF, ONON OFF, ON None

If this switch is on, it indicates OFFOFF, ONON OFF, ON None

If this switch is on, it indicates OFFOFF, ONON OFF, ON None

Route area of the current cell 0~255 0~255 None

OFFOff, ONOn OFF, ON None

Offset relative to the level thres 0~61 0~61 dB

0~61 0~61 dB

Whether to enable the BSC to assigNONo, YESYes NO, YES None

Whether to assign overlay channelOFFOff, ONOn OFF, ON None

Type of a scanning result in the period from the start of a frequency scanning task to the reporting of the scanning result.Frequency scanning refers to the scanning of an uplink receive level of a cell frequency. The scanning result reflects the strength of frequency signals received by the cell.

If a cell supports the enhanced concentric cell function, when an overlaid-to-underlaid handover or an underlaid-to-overlaid handover is decided, the MS compares the receive level value respectively with the values of "OtoU HO Received Level Threshold" and "UtoO HO Received Level Threshold" in "SET GCELLHOIUO" to decide whether to trigger an enhanced concentric cell handover.If the cell does not support the enhanced concentric cell function, the MS compares the actual receive level value with the threshold of receive level to decide whether to trigger a concentric cell handover. In addition, when an underlaid-to-overlaid handover is decided, the underlay cell load is considered.

If the cell is an enhanced concentric cell, this parameter with the current downlink received signal level and "UtoO HO Received Level Threshold" determines whether to assign a channel in the underlaid subcell to the intra-BSC incoming handover to the concentric cell or intra-BSC inter-cell handover.If the cell is an ordinary concentric cell, this parameter with the current downlink received signal level, "RX_LEV Threshold", and "RX_LEV Hysteresis" determines whether to assign a channel in the underlaid subcell to the intra-BSC incoming handover to the concentric cell or intra-BSC inter-cell handover.

Threshold for determining that the0~100 0~100 per cen

0~100 0~100 per cen

Conversion policy of the dynamic CONVERT0Only convert CONVERT0, CONVERT1, None

Normal_cellNormal CellNormal_cell, Concentric_celNone

Base station color code BCC of a 0~7 0~7 None

Number of PAGCH blocks 0~12 0~12 None

Number of PBCCH blocks 1~4 1~4 None

Number of PRACH blocks 0~12 0~12 None

0~7 0~7 None

Uniform number of neighboring cel0~5047 0~5047 None

Index of neighboring GSM cell 2. 0~5047 0~5047 None

List of cell indexes. All cell ind None 0~5000 characters None

None 0~5000 characters None

Cell identity code. The cell is a r 0~65535 0~65535 None

BCCH frequency of a 2G neighbor 0~1023 0~1023 None

Whether to generate the 2G BA1 taAUTOAuto, MANUManuAUTO, MANU None

Speech version supported by a ceFULL_RATE_VER1, FUFull_rate_Ver1, Full_rate_VeNone

BCCH frequency of a 2G neighbor 0~1023 0~1023 None

This parameter indicate whether tAUTOAuto, MANUManuAUTO, MANU None

Whether to use handover algorithmHOALGORITHM1HandoverHOALGORITHM1, HOALGONone

This parameter indicate whether tAUTOAuto, MANUManuAUTO, MANU None

Whether the FDD BA2 table is geneAUTOAuto, ManualManAUTO, Manual None

Cell parameter ID of a TDD cell. 0~127 0~127 None

Number of a row to be changed in1~64 1~64 None

The BSC assigns channels in the overlaid subcell to the MS in a concentric cell. If the channel seizure ratio of overlaid subcell is greater than the value of this parameter, half-rate channels are assigned. Otherwise, full-rate channels are assigned. Channel seizure ratio = Num. of busy TCHF + Num. of busy TCHH/2%. This parameter is valid for the concentric cell. When the "Allow Rate Selection Based on Overlaid/Underlaid Subcell Load" is set to Yes, the "TCH Traffic Busy Threshold %" is invalid for the concentric cell.

Owing to different coverage areas of the overlaid and underlaid parts, the two parts can be logically regarded as two cells. With many channels, the overlaid part is the major traffic bearer layer, recruiting most MSs in its coverage area. The underlaid part is used for coverage, providing services for the areas that the overlaid part cannot cover. The underlaid part covers the overlaid part, and thus the underlaid part can also share some traffic.An enhanced dual band network is amelioration to the existing dual band network. In such a network, two cells physically with a collocation site but different coverage areas form a cell group logically, namely, an inner cell and an extra cell. Channel resource sharing and cell load balancing is realized in the two cells through the algorithm of enhanced dual band network.

Network color code that is provided by the telecom operator. The NCC is used to identify networks from area to area. The NCC is unique nationwide.The BCC and the NCC form the BSIC.

? | : < > " @ # ! % ^ & * . [ ] / \ \\ '

Used for parameter control TRUESupport, FALSENoTRUE, FALSE None

Frame offset. The frame offset te 0~255 0~255 None

Maximum number of levels that th0~21 0~21 None

This parameter indicates start fr 0~65535 0~65535 None

Reserved parameter for cells. The1~30 1~30 None

Value of a reserved parameter for0~65535 0~65535 None

Whether to enable a directed retrNONo, YESYes NO, YES None

When this parameter is set to ENADISABLEDisable, ENA DISABLE, ENABLE None

Threshold of the load in the target0~100 0~100 per cen

Threshold of forbidding directed 0~100 0~100 per cen

00, 11, 22, 44, 88, 161 0, 1, 2, 4, 8, 16, 32, 64 s

Whether to support SPLIT_PG_CYNONO, YESYES NO, YES None

Whether the downlink discontinuouNONo, YESYes NO, YES None

Whether the downlink DTX functionNONo, YESYes NO, YES None

1: switch to the DRX mode in one second.Value n indicates that the MS enters the DRX mode n seconds later.

Whether the uplink DTX function iMay_UseMay Use, ShallMay_Use, Shall_Use, Shal None

Whether the uplink DTX function iMay_UseMay Use, ShallMay_Use, Shall_Use, Shal None

Whether to enable the cell to centNONo, YESYes NO, YES None

This parameter specifies a period o0~255 0~255 min

The BSC6900 checks the load of th1~16 1~16 None

A cell that can be disabled is all 0~100 0~100 per cen

If the number of channels includi 0~8 0~8 None

This parameter specifies the end tHOUR, MINUTE 00:00~23:59 None

This parameter specifies the start HOUR, MINUTE 00:00~23:59 None

When the load of the same coverage0~100 0~100 per cen

Index of a cell with the same cove0~2047 0~2047 None

Index type used when the commaBYNAMEBy name, BYIDBYNAME, BYID None

Name of the same coverage cell None 1~64 characters None

DISABLEDisable, ENABDISABLE, ENABLE, SLEEPNone

Whether to enable the cell to supNOTSUPPORTNot SuppNOTSUPPORT, DDIVERSITNone

Whether to enable the EICC algoNONo, YESYes NO, YES None

Priority level of an emergency ca 1~15 1~15 None

If this parameter is set to ON, t OFFOff, ONOn OFF, ON None

This parameter specifies whether to enable the Dynamic Cell Power Off feature. When this parameter is set to ENABLE, the BSC can disable the cell within the period of time specified by "TURNOFFCELLSTRTIME" and "TURNOFFCELLSTPTIME";When this parameter is set to DISABLE, the BSC will never disable the cell; When this parameter is set to SLEEP, the BSC will disable the cell unconditionally within "TURNOFFCELLSTRTIME" and "TURNOFFCELLSTPTIME",and enable the cell unconditionally within the other time.Currently, this parameter can be set to SLEEPING only for the BTS3900E. For other base stations, this parameter cannot be set to SLEEPING.

Whether to disable emergency callNONo, YESYes NO, YES None

Maximum number of TCH channels0~190 0~190 None

Whether a BTS randomizes the duOFFOff, ONOn OFF, ON None

This parameter specifies whetherOFFOff, ONOn OFF, ON None

This parameter specifies the inte 1~600 1~600 s

This parameter specifies whether OFFOff, ONOn OFF, ON None

Whether to enable the function ofOFFOff, ONOn OFF, ON None

This parameter specifies whetherNONo, YESYes NO, YES None


This parameter specifies the end hour, min 00:00~23:59 None

This parameter specifies the ran 0~15 0~3, Step:0.2 dB

This parameter specifies the star hour, min 00:00~23:59 None

Whether to measure the channel inNONo, YESYes NO, YES None

Whether to allow a multi-density NONo, YESYes NO, YES None

This parameter specifies the estima0~22 0~22 dB

Threshold for load sharing in th 0~100 0~100 per cen


Whether to consider interference NONo, YESYes NO, YES None

If this parameter is set to YES, t NONo, YESYes NO, YES None

If the MCPA Optimization Switch iOFFOff, ONOn ON, OFF None

Whether to preferentially allocat NONo, YESYes NO, YES None


Whether to use the statistical mulNONENone, DYNAMICDyNONE, DYNAMIC None

If the current channel seizure rati 0~100 0~100 per cen

This parameter specifies whether NONo, YESYes NO, YES None

0~100 0~100 per cen

0~100 0~100 per cen

CAPABILITYCapability CAPABILITY, QUALITY, P None

If this parameter is set to ON, t OFFOff, ONOn OFF, ON None

48~115 48~115 None

48~115 48~115 None

48~115 48~115 None

48~115 48~115 None

48~115 48~115 None

48~115 48~115 None

Period during which interference 1~31 480~14880, step: 480 ms

This parameter specifies whether InnerInner, ExtraExtra Inner, Extra None

Index of a same group cell in an 0~2047 0~2047 None

Name of a same group cell in an None 1~64 characters None

Index type of a same group cell BYNAMEBy Name, BYIDBYNAME, BYID None

Hysteresis in the distance betwee0~63 0~63 dB

Whether to consider history priority records during channel assignment.If this parameter is set to YES, the history priority records are considered. If this parameter is set to NO, the history priority records are not considered.

Maximum ratio of the number of AMR half rate channels to the total number of channels in a cell. When the resource allocation principle is determined by the BSC, no AMR half rate channel can be further assigned if the ratio of the number of AMR half rate channels to the total number of channels in the cell is greater than or equal to the value of this parameter. When the resource allocation principle is not determined by the BSC, radio resource allocation does not depend on the setting of this parameter.Total number of channels = number of half rate channels + number of full rate channels x 2Maximum ratio of the number of half rate channels to the total number of channels in a cell. When the resource allocation principle is determined by the BSC, no half rate channel can be further assigned if the ratio of the number of half rate channels to the total number of channels in the cell is greater than or equal to the value of this parameter. When the resource allocation principle is not determined by the BSC, radio resource allocation does not depend on the setting of this parameter.Total number of channels = number of half rate channels + number of full rate channels x 2If this parameter is set to PSRELATIVELY, the factors are listed as follows in a descending order of priority: capacity factors, PS cooperation factors, quality factors, and management factors.If this parameter is set to PSABSOLUTELY, the factors are listed as follows in a descending order of priority: PS cooperation factors, capacity factors, quality factors, and management factors.

Threshold used for interference measurement.The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the interference on each of the idle channels. This helps the BSC6900 to assign channels. According to the strength of interference signals, the interference signals are classified into five interference levels. The values of these levels are called interference band thresholds. The BTS determines the current interference level based on these thresholds, and then reports a radio resource indication message to the BSC6900. The BSC6900 compares the busy and idle channels reported in the measurement report and in the radio resource indication message to determine whether to perform a handover. The interference band statistics result provides reference for threshold setting and interference analysis. For details, see GSM Rec. 08.08 and GSM Rec. 08.58.Threshold used for interference measurement.The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the interference on each of the idle channels. This helps the BSC6900 to assign channels. According to the strength of interference signals, the interference signals are classified into five interference levels. The values of these levels are called interference band thresholds. The BTS determines the current interference level based on these thresholds, and then reports a radio resource indication message to the BSC6900. The BSC6900 compares the busy and idle channels reported in the measurement report and in the radio resource indication message to determine whether to perform a handover. The interference band statistics result provides reference for threshold setting and interference analysis. For details, see GSM Rec. 08.08 and GSM Rec. 08.58.Threshold used for interference measurement.The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the interference on each of the idle channels. This helps the BSC6900 to assign channels. According to the strength of interference signals, the interference signals are classified into five interference levels. The values of these levels are called interference band thresholds. The BTS determines the current interference level based on these thresholds, and then reports a radio resource indication message to the BSC6900. The BSC6900 compares the busy and idle channels reported in the measurement report and in the radio resource indication message to determine whether to perform a handover. The interference band statistics result provides reference for threshold setting and interference analysis. For details, see GSM Rec. 08.08 and GSM Rec. 08.58.Threshold used for interference measurement.The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the interference on each of the idle channels. This helps the BSC6900 to assign channels. According to the strength of interference signals, the interference signals are classified into five interference levels. The values of these levels are called interference band thresholds. The BTS determines the current interference level based on these thresholds, and then reports a radio resource indication message to the BSC6900. The BSC6900 compares the busy and idle channels reported in the measurement report and in the radio resource indication message to determine whether to perform a handover. The interference band statistics result provides reference for threshold setting and interference analysis. For details, see GSM Rec. 08.08 and GSM Rec. 08.58.Threshold used for interference measurement.The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the interference on each of the idle channels. This helps the BSC6900 to assign channels. According to the strength of interference signals, the interference signals are classified into five interference levels. The values of these levels are called interference band thresholds. The BTS determines the current interference level based on these thresholds, and then reports a radio resource indication message to the BSC6900. The BSC6900 compares the busy and idle channels reported in the measurement report and in the radio resource indication message to determine whether to perform a handover. The interference band statistics result provides reference for threshold setting and interference analysis. For details, see GSM Rec. 08.08 and GSM Rec. 08.58.Threshold used for interference measurement.The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the interference on each of the idle channels. This helps the BSC6900 to assign channels. According to the strength of interference signals, the interference signals are classified into five interference levels. The values of these levels are called interference band thresholds. The BTS determines the current interference level based on these thresholds, and then reports a radio resource indication message to the BSC6900. The BSC6900 compares the busy and idle channels reported in the measurement report and in the radio resource indication message to determine whether to perform a handover. The interference band statistics result provides reference for threshold setting and interference analysis. For details, see GSM Rec. 08.08 and GSM Rec. 08.58.

0~63 0~63 dB

1~255 1~255 s

1~255 1~255 s

If the current system flow control 0~11 0~11 None

An MS cannot be handed over from t0~255 0~255 s

Whether to assign channel requestsNONo, YESYes NO, YES None

Whether to allow underlay-to-oveNONo, YESYes NO, YES None

Whether to allow underlay-to-oveNONo, YESYes NO, YES None

Overlay-to-underlay load handover1~255 1~255 s

Level step during overlay-to-unde0~63 0~63 dB

In an enhanced dual-band network, 0~100 0~100 per cen

Lower threshold of the overlay le 0~63 0~63 dB

Whether to assign channel requestsNONo, YESYes NO, YES None

When the load of the underlay subce0~100 0~100 per cen

Lower threshold of the overlay le 0~63 0~63 dB

Whether to switch some of the callNONo, YESYes NO, YES None

If the underlay load is higher th 1~255 1~255 s

When the load of the underlay sub1~255 1~255 s

Level step during underlay-to-ove0~63 0~63 dB

When the load of the underlay subc0~100 0~100 per cen

When the load of the underlay sub0~100 0~100 per cen

Whether a measurement report canNONo, YESYes NO, YES None

Distance between the boundary of the overlaid subcell and the boundary of the underlaid subcell. This parameter specifies the difference between the coverage of the overlaid subcell and the coverage of the underlaid subcell in the concentric cell or dual-frequency network scenario. The boundaries of the overlaid and underlaid subcells are determined according to the relative value between the signal strength of the serving cell and the signal strength of the neighbor cell. Assume that the signal strength of the serving cell is SSs and that the signal strength of the neighbor cell is SSn. If SSs = SSn, the MS is on the boundary of the underlaid subcell. If SSs - SSn > "Distance Between Boudaries of Subcells", the MS is in the coverage of the overlaid subcell.In the tight BCCH handover algorithm, this parameter specifies the difference between the coverage of the TRX that carries the BCCH and the coverage of the TRX that does not carry the BCCH. The relevant computation is the same as the preceding computation.According to the P/N rule, if the conditions for the handover between the subcells of an enhanced dual-frequency network are met during P of N measurements, the handover is triggered.This parameter specifies the number P.According to the P/N rule, if the conditions for the handover between the subcells of an enhanced dual-frequency network are met during P of N measurements, the handover is triggered.This parameter specifies the number N.

Type of the measurement report EnhMeasReportEnhancEnhMeasReport, ComMeasRNone

ADD0dB+0dB, ADD10dB+ADD0dB, ADD10dB, AutomaNone

Whether to allow the MS to searcNONo, YESYes NO, YES None

Number of enhanced measurement0~31 TCH:0~14880, step:480; SDms

Number of enhanced measurement0~31 TCH:0~14880, step:480; SDms

For the purpose of accurately re 0~31 TCH:0~14880, step:480; SDms







Full rate TCHs are assigned prefer1~14 1~14 None

Whether to enable the priority-b NONo, YESYes NO, YES None

Whether to allow BTS power contNONo, YESYes NO, YES None

If the SCALE_Order reported by the MS is 0 dBm, level values 0-63 map with -110 dBm to -47 dBm.If the SCALE_Order reported by the MS is Automatic, the MS chooses the least SCALE while ensuring that the MS can report the most strong level.

Whether to allow the function of enhanced multi-level precedence and preemption eMLPP. With the eMLPP function enabled, the network can use different policies such as queuing, preemption, or directed retry based on the priorities of different calls when network resources are occupied. If this parameter is set to YES, when preemption occurs, the MS with the lowest priority initiates a handover, and the MS with a higher priority seizes the idle channel after a handover. If this parameter is set to NO, an MS with a lower priority releases the channel, the MS with a higher priority seizes the idle channel after the release.The eMLPP has up to seven priorities: A, B, 0, 1, 2, 3, and 4. The two highest priorities A and B are internally reserved for local use only. Priorities 0 to 4 can be subscribed by MSs for global use. With the support of the MSC, HLR, and mobile terminal containing a SIM card, the eMLPP function can be perfectly implemented.

Whether to allow MS power contrNONo, YESYes NO, YES None

Normal_cellNormal cell Normal_cell, DualTst_ExtCelNone

Whether to support the downlink tCLOSEClose, OPENOpCLOSE, OPEN None


Whether to permit the preemption NONo, YESYes NO, YES None


Whether to enable the function ofOFFOff, ONOn OFF, ON None

Whether dynamic use of HSNs is eOFFOff, ONOn OFF, ON None

GSM900, DCS1800, G GSM900, DCS1800, GSM90None

Ordinary frequency. Multiple fre None 1~200 characters None

Frequency of the BCCH TRX 0~1023 0~1023 None

Cell type. Currently, the fast BT GSM900GSM900, DCSGSM900, DCS1800 None

Whether a cell is an extension cell.A double-timeslot extension cell regards an additional TDMA frame as access delay extension. In theory, the supported TA value is 219, that is, a time delay of about 120 kilometers.

PCS1900: The cell supports PCS1900 frequency band.GSM850_PCS1900: The cell supports GSM850 and PCS1900 frequency bands.

0~63 0~63 None

0~7 0~7 None

Index of the frequency hopping d0~63 0~63 None

Implementation mode of frequencBaseBand_FHBaseBanBaseBand_FH, RF_FH None

Whether an MS uses the calculatedNONo, YESYes NO, YES None

Frequency hopping mode of the TNO_HopNo hop, HopHoNO_Hop, Hop None

This parameter specifies the freq NO_FHNo frequency hopNO_FH, BaseBand_FH, RF_None

Coding mode in which an ARFCN isCA_MACA+MA, FrequenCA_MA, Frequency_List, None

Data service supported by the BSNT14_5K~0 NT12K~1 NNT14_5K, NT12K, NT6K, T1None

Identifies a unique PTP BVC wit 2~65534 2~65534 None

Indicating whether the eMLPP functiNoPriorityNo Priority, PriNoPriority, Priority4, Priority3None

Whether to allow sending notificatNONo, YESYes NO, YES None

Whether to allow sending paging NONo, YESYes NO, YES None

Whether direct preemption of the NONo, YESYes NO, YES None

Priority of the notification messa NoPriorityNo Priority, PriNoPriority, Priority4, Priority3None

Priority of the paging message traNoPriorityNo Priority, PriNoPriority, Priority4, Priority3None

0~7 0~7 None

0~7 0~7 None

Priority of the PS high priority ser0~7 0~7 None

Priority of the PS low priority serv0~7 0~7 None

Is VIP Cell.The parameter is usedNONo, YESYes NO, YES None


Average number of paging message10~65535 10~65535 None

Maximum number of paging messag10~65535 10~65535 None

Whether to activate transmit dive NONo, YESYes NO, YES None

0~7 0~42, step: 6 dB

0~7 0~36, Positive infinity, step: dB

Number of UTRAN FDD cells that 0~3 0~3 None

0~7 -20, -6, -18, -8, -16, -10, -14 dB

Offset of the minimum threshold f0~7 0~7 dB

Hopping sequence number HSN, indicating 64 types of frequency hopping sequences. If this parameter is set to 0, the frequency hopping is performed in sequence.If this parameter is set to a value from 1 to 63, the frequency hopping is performed in a pseudo-random manner, that is a disciplinary random manner.The TSC is short for the Training Sequence Code.The TSC must be the same as the BCC. The delay equalization is performed by using the specified TSC when the MS or BTS receives the signal. The demodulation cannot be received because the delay equalization cannot be performed for the signals with same frequency using different TSCs. This can effectively prevent incorrectly invalid reception, and prevent the co-channel interference.

Priority of the CS data service. The parameter is used for BSC6900 flow control.The smaller the value of this parameter, the higher the priority.Priority of a speech service in the CS domain. The parameter is used for BSC6900 flow control.The smaller the value of this parameter, the higher the priority.

Whether to permit Abis flow control.The flow control function helps in better call management. If congestion occurs, the system lightens its load by rejecting some services or prolonging the time for service requests. The Abis flow control is used to lighten the system load caused by Abis flows.

...7: 42 dB6: 36 dB7: positive infinity

7: -12 dBThis parameter is valid only when FDD REP QUANT is set to EcN0.

0~15 Negative infinity, -28~28, stedB

This parameter specifies whether RSCPRSCP, EcN0Ec/NRSCP, EcN0 None

0~15 -114~-84, step: 2 dBm

AUTOAuto, MANUManuAUTO, MANU None

Diversity indication of a 3G cell 0~1 0~1 None

Downlink frequency number that a0~16383 0~16383 None

0~511 0~511 None

Scrambling code of a 3G cell. The0~511 0~511 None

Downlink frequency of the externa0~16383 0~16383 None

0~7 0~42, step: 6 dB


0~7 0~42, step: 6 dB


This parameter specifies the thresUse_Qsearch_IUse QseUse_Qsearch_I, Always None

A 3G cell can be a candidate cell only when the average receive level of the 3G cell is greater than the value of this parameter of the current serving cell.The values of this parameter correspond to the following decibel values:0: - always select a cell if acceptable1: -28 dB2: -24 dB...15: 28 dB

14 = -86 dBm, 15 = -84 dBm.AUTO: In this mode, the system fills in the BA1 and BA2 lists according to neighboring relations of cells.MANU: In this mode, you can maintain the BA tables by yourself. If the neighboring relations of cells are changed, for example, after a neighboring cell is added or deleted, you must maintain the BA1 and BA2 lists by yourself.

Scrambling code of a 3G cell, used for distinguishing MSs or cells. Scrambling codes are used after spreading. Therefore, the bandwidth of a signal is not changed. Instead, signals from different sources are differentiated. Scrambling prevents multiple transmitters from using the same code word for spreading.On the uplink, the scrambling function is used for differentiating MSs. On the downlink, the function is used for differentiating cells.

...7: 42 dB6: 36 dB7: positive infinity...7: 42 dB6: 36 dB7: positive infinity

0~15 -98, -94, -90, -86, -82, -78, - None

This parameter specifies one threshold of the0~15 -98, -94, -90, -86, -82, -78, - None

0~15 -98, -94, -90, -86, -82, -78, - None

The 3G better cell handover can be0~49 0~49 dB


The 3G better cell handover is tri 0~63 0~63 dB

Whether to support the half-rate sNONo, YESYes NO, YES None

3: -86 dBm 4: -82 dBm5: -78 dBm 6: -74 dBm 7: always, that is, the MS keeps searching for 3G cells 8: -78 dBm9: -74 dBm 10: -70 dBm 11: -66 dBm 12: -62 dBm 13: -58 dBm 14: -54 dBm 15: Positive infinitynever, that is, the MS does not search for 3G cells

In connection mode, if the signal level is below [0-7] or above [8-15], the MS starts to search for 3G cells. For example, if this parameter is set to 5 and if the signal level of the serving cell is lower than 5, the MS starts to search for 3G cells; if this parameter is set to 10 and if the signal level of the serving cell is above 10, then the MS starts to search for 3G cells. 0: -98 dBm 1: -94 dBm...6: -74 dBm7: always8: -78 dBm9: -74 dBm...14: -54 dBm 15: Positive infinity never

Name of neighboring GSM cell 1 None 1~64 characters None

Name of neighboring GSM cell 2 None 1~64 characters None

Minimum C/I ratio that IBCA AMR FR0~23 0~23 dB

Minimum C/I ratio that IBCA AMR HR0~23 0~23 dB

Whether to enable the IBCA algoNONo, YESYes NO, YES None

Length of the timer for a new cal 0~20 0~10, Step: 0.5 s

Number of measurement reports sa1~4 TCH:480~1920, step:480; Sms

When the IBCA algorithm is enabled0~14 0~14 dB

When the IBCA algorithm is enabled0~14 0~14 dB

0~63 0~63 dB

Length of the timer for a call to 0~20 0~10, Step: 0.5 s

Whether the IBCA flexible TSC funOFFNot Allowed, ONAl OFF, ON None

Whether the IBCA forced BTS synchOFFNot Allowed, ONAl OFF, ON None

Minimum C/I ratio that IBCA FR/EFR0~23 0~23 dB

Length of the timer for a call to w 0~20 0~10, Step: 0.5 s

Minimum C/I ratio that IBCA HR ser0~23 0~23 dB

In the ICDM matrix algorithm, the s0~31 0~31 dB

Whether to enable the ICDM algoriNONo, YESYes NO, YES None

Adds a specified offset to the dow0~63 0~63 dB

Adds a specified offset to the upl 0~63 0~63 dB

Adds a specified offset to the dow0~22 0~22 dB

Adds a specified offset to the upl 0~22 0~22 dB

In an IUO cell or a CoBCCH cell, 0~63 0~63 dB

Determines the MAIO selection me0Max. optimized MAIO,0, 1 None

The IBCA interference evaluation 5~40 5~40 None

Estimates the receive level of th 0~63 0~63 dB

When the IBCA algorithm is enable0~30 0~30 dB

Length of the timer for a call to 0~20 0~10, Step: 0.5 s

Estimates the receive level of th 0~16 0~16 None

When the IBCA algorithm is enabled0~63 0~63 None

When the path loss of an MS to a 0~50 0~50 dB

Considers the influence of history 0~10 0~10 None

Use this parameter when the path0~160 0~160 dB

MSs that support SAIC can tolerat0~23 0~23 dB

Whether to deny the access of a cNONo, YESYes NO, YES None

Whether the handover of the calls OFFNot Allowed, ONAl OFF, ON None

Difference between uplink and downlink path losses, which is used to estimate the downlink path loss of a call when the downlink path loss cannot be computed directly according to a measurement report. This parameter is configured according to the combined loss and hierarchical dual-antenna gain 3 dB of the BTS."IBCA Downlink Path Loss Offset" = combined loss of BTS + hierarchical dual-antenna gain of BTS 3 dB

Whether a MAIO meets the access 0~63 0~63 None

Whether to enable the IBCA algoriNODisabled in OL and UNO, UNDER, INNER, YES None

Whether a single IBCA MS can dynNONo, YESYes NO, YES None

The lowest C/I ratio that can be t 0~23 0~23 dB

When the load of an SDCCH on the 0~100 0~100 per cen

If the SDCCH load on the TRXs of0~63 0~63 dB

When the dynamic PDCH needs to u0~60 0~60 s

Mobile allocation index offset 1. 0~11 0~11 None

Mobile allocation index offset 10 0~11 0~11 None











Logical number of the MA group 0~63 0~63 None

Attach-detach Allowed ATT. If thiNONo, YESYes NO, YES None

NONO, YESYES, NULLNO, YES, NULL None

Maximum number of RTTI TBFs that10~80 10~80 None


Type of an index BYNAMEBy Name, BYIDBYNAME, BYID None

Threshold of the MS Receiver D MCS1MCS1, MCS2MCSMCS1, MCS2, MCS3, MCS4None

This parameter is used to enable the Intelligent Combiner Bypass ICB function on the BCCH TRX of a cell.This parameter specifies whether to allow the cell to enable the ICB function. When this parameter is set to YES, the TCHs on the non-BCCH TRX are preferentially assigned. In this way, the largest possible number of idle TCHs is reserved on the BCCH TRX, and thus the BCCH TRX enters the ICB mode.

Used for requesting the MS to rep0~3 0~3 None

0~3 0~3 None

Whether the cells at the 1900 fr 0~1 0~1 None

Whether the cells at the 850 fre 0~1 0~1 None

Whether the cells at the 900 fre 0~1 0~1 None

Whether to enable the power amplifOnlyCurPwrLocOnly CurOnlyCurPwrLoc, ALLPwrLocNone

This parameter is related to the NMOINetwork Operation NMOI, NMOII, NMOIII None

Whether to specify "Power Cont OFFOff, ONOn OFF, ON None

Number of allowed measure report 0~16 0~16 None

This parameter specifies whether a2GPreference for 2G Cel2G, 3G None

The number of times that the dow0~100 0~100 per cen

Used for EDGE 8PSK transmission q0~31 0~31 None

Used for EDGE GMSK transmission q0~31 0~31 None

Maximum number of former values wh0~32 0~32 None

Used for the GPRS transmission qu0~7 0~7 None

Whether to allow the cell load resFORBIDForbid, PERMITFORBID, PERMIT None

Threshold for allowing the MS to re0~63 0~63 None

When the uplink load or downlink l0~100 0~100 per cen

When the uplink load or downlink l0~100 0~100 per cen

Minimum receive level for a neighbo0~63 0~63 None

When the number of received meas0~255 0~255 None

Whether to allow the cell normal rFORBIDForbid, PERMITFORBID, PERMIT None

2. The BSIC of a neighboring cell must be valid.3. The signals of the neighboring cells must be the strongest among all the neighboring cells at the same frequency band.

Penalty duration for cell reselect 0~255 0~255 s

When the cell reselection failure m0~63 0~63 None

Indicating that during cell reselec0~63 0~63 None

NC2 cell reselection interval in th 1~10 1~10 s

The number of received Packet Mea1~32 1~32 None

If the number of times when the re1~32 1~32 None

Whether to allow cell urgent reselFORBIDForbid, PERMITFORBID, PERMIT None

Period when the cell is in the no NODRXNODRX, 0.24sec0.NODRX, 0.24sec, 0.48sec, 0.s

Cell reselection measurement repo0.48sec0.48sec, 0.96se0.48sec, 0.96sec, 1.92sec, s

Cell reselection measurement rep0.48sec0.48sec, 0.96se0.48sec, 0.96sec, 1.92sec, s

Network control mode for cell re NC0NC0, NC1NC1, NCNC0, NC1, NC2 None

This parameter specifies the prop0~100 0~100 per cen

This parameter is used to check w1~64 1~64 s

Type of indexing the target cell BYCELLNAMEBy cell nBYCELLNAME, BYCGI None

Unique name of the target cell None 1~64 characters None

Type of handover in terms of conFREEFree, INCELLIntraFREE, INCELL, OUTCELL, None

This parameter determines whether OFFOff, ONOn OFF, ON None

This parameter specifies the propo0~100 0~100 per cen

Interval for sending test TRAU fra0~255 0~255 s

Threshold for the rate of the num0~100 0~100 per cen

Period of performing class-1 mute0~255 0~255 s

Whether to enable the class-2 muDISABLEDISABLE, E DISABLE, ENABLE None

Period of performing the class-2 0~255 0~255 s

Time for prohibiting the call fro 0~15 0~15 min

Whether to forcibly release a call NONo, YESYes NO, YES None

Whether to enable the class-1 muDISABLEDISABLE, E DISABLE, ENABLE None

NONot Allowed, YESAl NO, YES None

Code of the signaling point of the1~16777215 1~16777215 None

Administrative state of a cell LOCKLock, UNLOCKUnLock, Unlock, Shutdown None

Whether to permit the low noise OFFOff, ONOn OFF, ON None

OUTDOOR_CELLOutdoorOUTDOOR_CELL, INDOORNone

This parameter specifies a conditi0~9 0~9 None

This parameter specifies a conditi0~9 0~9 None

This parameter specifies a condit0~12 0~12 None

This parameter specifies a condit0~12 0~12 None

Whether to report a cell out-of-serNONo, YESYes NO, YES None


This parameter specifies whetherNONot Support, YESSuNO, YES None

Whether to support the function NONot Support, YESSuNO, YES None

Whether to allow the MS to the s NONo, YESYes NO, YES None

Period for sending the packet mes1~16 1~16 None

Whether the BSC supports the stNONo, YESYes NO, YES None

For the BTS, this parameter is us1~8 1~8 None

2_M_PERIOD2 Multifram940~4230, step: 470 ms

Lifetime of a paging message in t0~255 0~255 ms

Whether to enable Paging MessagCLOSEForced turn-off, CLOSE, OPEN, AUTO None

Interval for sending cell paging 1~8 50~400, step: 50 ms

Number of cell paging group pack2~15 2~15 None

Whether the crosstalk optimization function over the Um interface is allowed. If this parameter is set to YES when call drops occur on the Um interface, this function can avoid crosstalk due to very early assignment of the channel that is not released.If this parameter is set to YES and the ongoing service is speech service, the BSC also sends the Channel Release message to the MS and starts the timer T3109 when a call drop occurs upon the reception of the Conn Fail or Err Ind message reported by the MS.

If the coverage type of a cell is outdoor coverage, the BTS detects whether the standing wave alarm is generated only when the forward power is greater than 35 dBm. If the coverage type of a cell is indoor coverage, the BTS detects whether the standing wave radio alarm is generated only when the forward power is greater than 30 dBm.

Number of multiframes in a cycle on a paging sub-channel. In fact, this parameter specifies the number of paging sub-channels that a paging channel in a cell is divided into.In an actual network, an MS does not listen to other paging sub-channels but its belonging paging sub-channel only. Refer to GSM Rec. 05.02 and GSM Rec. 05.08. The larger the value of this parameter, the more the number of the paging sub-channels in a cell, and the fewer the number of the users belonging to each paging sub-channel. In this case, the mean uptime of the MS battery can be prolonged. Refer to the computing mode of paging group in GSM 05.02 of GSM Standards. The larger the value of this parameter, however, the larger the time delay of a paging message in a space segment. Thus, the average service performance of the system lowers. Based on the principle of ensuring that overload does not occur to paging channels, you must set this parameter to a value as small as possible. You must regularly measure the overload conditions of the paging channels in a running network and accordingly adjust the value of this parameter properly. A paging message in a location area must be sent in all the cells within this location area at the same time. Therefore, the capacity of a paging channel of each cell in a location area must be the same or nearly the same. The capacity refers to the calculated number of paging sub-channels of each cell.

Maximum transmission delay of the250~650 250~650 None

Maximum bandwidth of the POC ser6~120 6~120 None

Minimum bandwidth of the POC ser6~120 6~120 None

Whether to support the push to taNotSupportNot Support,NotSupport, Support None

Whether to prohibit sending point-NONo, YESYes NO, YES None

This parameter specifies whether tNONo, YESYes NO, YES None

0~50 0~50 None

This parameter determines whetherNONo, YESYes, NULLNNO, YES, NULL None


Whether to support the reporting oNONot Support, YESSupNO, YES, NONE None

Whether the network requires an EM0EM0, EM1EM1 EM0, EM1 None

Time interval between two exten 60sec60sec, 120sec12060sec, 120sec, 240sec, 480s

TYPE1TYPE1, TYPE2TTYPE1, TYPE2, TYPE3 None

Frequency index of the interfere 0~31 0~31 None

NCC bitmap of the measurement re0~255 0~255 None

Threshold of the downlink receive0~63 0~63 dB

Threshold of the TA of an over-co0~63 0~63 None

Threshold of the downlink receive0~63 0~63 dB

Threshold of the TA of an weak-co0~63 0~63 None

Type of the DRX supporting the VNONo, YESYes NO, YES None

Number of retransmissions of 1~255 1~255 None

Time interval for the BTS resend 1~255 10~2550, step: 10 ms

Number of times of the BTS rese 1~255 1~255 None

Interval for resending downlink t 0~255 0~255 s

Number of times of the BSC6900 r1~255 1~255 None

Interval of sending a paging mess0~255 0~12750, step: 50 ms

Whether the assignment of channelNONo, YESYes NO, YES None

Number of blocks occupied by the0~7 0~7 None

Number of the start block occupie0~7 0~7 None

Used to identify the uplink acces 0~64 0~64 None

ARP1 priority in the BE service. 1~10 1~10 None



ARP1 priority in the Background s1~10 1~10 None



Combination of the THP1 and ARP1 1~10 1~10 None









Whether to support QoC optimizatiNONot Support, YESSuNO, YES None

Minimum access level of the ra -121~-104 -121~-104 dBm

If a class 3 MS on the DCS1800 b0~3 0~3 None

Timeslot power attenuation level of the EDGE TRX in 8PSK. The attenuation level ranges from 0 to 50, each of which corresponds to an attenuation of 0.2 dB. When the EDGE TRX sends signals in 8PSK, the transmit power must be lower than the mean power in GMSK.

Type 2: The MS sends the network a measurement report on the six strongest TRXs. For the six carriers, the BSIC must be decoded successfully and the NCC specified by NCC_PERMITTED is carried. The measurement report contains the received signal level and the decoded BSIC.Type 3: The MS does not need to decode the BSIC for the TRXs that the measurement report concerns. The measurement report contains the received signal level and the interference measurement of one of the concerned TRXs.

The MS does not receive the origNONo, YESYes NO, YES None

Minimum access level of the ra -121~-104 -121~-104 dBm

0~255 0~255 None

Level of common access control, uL0_FORBID, L1_FORBIL0_FORBID, L1_FORBID, LNone

1_Times1_Times, 2_Ti 1_Times, 2_Times, 4_TimesNone

Level threshold of the MS random 0~63 0~63 dB

This parameter is used for load coL11_FORBID, L12_FORL11_FORBID, L12_FORBID,None

Time interval for sending overlo 0~255 0~255 s

Used for the BTS to notify the B 20~100 20~100 per cen

244-250 410-89 or 251-255 38.

Maximum number of Channel Request messages that can be sent by an MS in an immediate assignment procedure. After the MS initiates the immediate assignment procedure, it always listens to the messages on the BCCH and all the common control channels CCCHs in the CCCH group to which the MS belongs. If the MS does not receive Immediate Assignment or Immediate Assignment Extend messages, it retransmits Channel Request messages at a specified interval. If the downlink quality is poor, the MS may send SABM frames to the BTS multiple times.

0~19 0~19 None

1~255 1~255 s

0~65535 0~65535 None

BS-AG-BLKS-RES, indicating the 0~7 0~7 None

system message 3, this parameter is used to control the transmit power of MSs. For details, see GSM Rec. 05.05.In a GSM900 cell, the maximum power control level of an MS ranges from 0 to 19, corresponding respectively to the following values unit: dBm: 43, 41, 39, 37, 35, 33, 31, 29, 27, 25, 23, 21, 19, 17, 15, 13, 11, 9, 7, and 5.Generally, the maximum transmit power supported by an MS is level 5 corresponding to 33 dBm. The minimum transmit power supported by an MS is level 19 corresponding to 5 dBm. Other transmit power levels are reserved for high-power MSs.In a GSM1800 or GSM1900 cell, the maximum power control level of an MS ranges from 0 to 31, corresponding respectively to the following values unit: dBm: 30, 28, 26, 24, 22, 20, 18, 16, 14, 12, 10, 8, 6, 4, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 36, 34, and 32. Generally, the maximum transmit power supported by an MS is level 0 corresponding to 30 dBm. The minimum transmit power supported by an MS is level 15 corresponding to 0 dBm. Other transmit power levels are reserved for high-power MSs.Interval for the BTS transmitting overload messages to the BSC6900. This parameter is used to control the reporting frequency of overload messages by the channel and TRX.The overload can be the TRX processor overload, downlink CCCH overload, or AGCH overload. For details, see GSM Rec. 08.58.Number of RACH burst timeslots in a RACH load measurement.The value of this parameter indicates the interval during which the BSC6900 determines whether an RACH timeslot is busy. For details, see GSM Rec. 08.58.

TX_33, TX_44, TX_55, TX_3, TX_4, TX_5, TX_6, TNone

Maximum number of reported pagin1~20 1~20 None

Number of measurement reports M0~31 0~31 None

Whether to initiate a forcible c OFFOff, ONOn OFF, ON None

Whether the time advance after filt0~255 0~255 None

4_Times, 8_Times, 12_1920~30720, step: 480 ms

0~63 0~30240, step: 480 ms

0~255 0~255 s

Level threshold for measuring the0~63 0~63 dB

Quality threshold for measuring t 0~70 0~70 None

Level threshold for measuring the0~63 0~63 dB

Quality threshold for measuring th0~70 0~70 None

When a call drops on the TCH, the0~1000 0~1000 per mil

When a call drops on the TCH, the0~63 0~63 dB

When a call drops on the TCH, the0~70 0~70 None

When a call drops on the TCH, the0~1000 0~1000 per mil

When a call drops on the TCH, the 0~63 0~63 dB

When a call drops on the TCH, the 0~70 0~70 None

Quality threshold for determining 0~70 0~70 None

Whether to optimize the call drops 0~1 0~1 None

Whether to optimize the call drops0~1 0~1 None


and SDCCH do not share a physical channel.When this parameter is set to 7, 12, or 32, S is 115 if the CCCH and SDCCH share a physical channel.The timeslot for sending messages is a random value from the collection of {0, 1..., MAXT, 8-1}. The number of timeslots excluding the timeslot used to send messages between two adjacent channel request messages is a random value from the collection of {S, S+1, ..., S+T-1}.When T increases, the interval between two adjacent channel requests increases, and RACH conflicts decrease.When S increases, the interval between two adjacent channel request messages increases, and RACH conflicts decrease, thus improving the usage of AGCH and SDCCH.The access time of the MS, however, is prolonged and the network performance is decreased when T and S increase. Under normal conditions, an appropriate T value should be used to ensure that S is as low as possible, and ensure that AGCH and SDCCH are not overloaded.

Time for disconnecting a call when the MS fails to decode the SACCH. Once a dedicated channel is assigned to the MS, the counter S is enabled and the initial value is set to this parameter value.Each time an SACCH message is not decoded, the counter S decreases by 1. Each time an SACCH message is correctly decoded, the counter S increases by 2. When the counter S is equal to 0, the downlink radio link is considered as failed. Therefore, when the voice or data quality is degraded to an unacceptable situation and it cannot be improved through power control or channel handover, the connection is to be re-established or released.When the BTS receives the SACCH measurement report from the MS, the counter for determining whether a radio link is faulty is set to the value of this parameter. Each time the BTS fails to decode the SACCH measurement report sent by the MS, the counter decreases by 1. If the BTS successfully decodes the SACCH measurement report, the counter increases by 2.When the value of this parameter is 0, the BTS regards the radio link as faulty. The BTS sends a connection failure indication message to the BSC6900. The number of SACCH multi-frames and the radio link failure counter in the system message specify the radio link failure time on the uplink and that on the downlink respectively. The judgment standard is whether the measurement report in SACCH is correctly decoded.Interval for sending the radio resource indication messages. The TRX reports the interference level for each of the channels that have been idle for the whole measurement period.This parameter is used by a BTS to inform the BSC6900 of the interference levels on idle channels of a TRX. For details, see GSM Rec. 08.58 and 08.08.


Whether to optimize the call drops 0~1 0~1 None














Power of each passage on the MROP1Operator 1, OP2OpeOP1, OP2, OP3, OP4, NONNone

Whether to allow hierarchical accNONo, YESYes NO, YES None

Maximum priority level of an MS th1~14 1~14 None

When assign channels, the BSC ens0~190 0~190 None

Whether to enable the Repeated DNONo, YESYes NO, YES None

If the cell supports the Repeate 0~7 0~7 None

Whether to enable the Repeated SNONo, YESYes NO, YES None

Whether to allow SDCCH dynamic NONo, YESYes NO, YES None

Maximum number of SDCCHs in the0~255 0~255 None

When the number of idle SDCCH ch0~63 0~63 None

Minimum time required for a TCH60~3600 60~3600 s

Whether to allow an MS to reportNONo, YESYes NO, YES None

Whether the handshake mechanismYESYes, NONo YES, NO None

1~1023 1~1023 None

End date and time of a broadcastyear, month, day, hour, 1970-1-1 00:00:00~2538-12-None

Time interval for sending a simpl 2~3600 2~3600 s

0~65535 0~65535 None

A key parameter that indicates year, month, day, hour, 1970-1-1 00:00:00~2538-12-None

Content of the cell broadcast me None 1~615 charactersGB2312, None

0~15 0~15 None


Contents of a cell broadcast mesNone 1~80 characters None

Time interval for a cell broadcas 2~3600 2~3600 s

Whether to support the broadcastNONo, YESYes NO, YES None

Channel number of a simple cell 0~65535 0~65535 None

LAC_CICELL IMME, PLLAC_CI, PLMN, LAC, CI None

A key parameter that indicates t GERMANGERMAN, ENGLIGERMAN, ENGLISH, ITALI None

Whether to allow TSC planning. If NONo, YESYes NO, YES None

Obtains the QoS parameter from NONot Support, YESSuNO, YES None

When the PDCHs are insufficient, tOFFOFF, ONON OFF, ON None

Minimum received signal level of t0~63 0~63 dB

The early classmark sending contrNONo, YESYes NO, YES None

This parameter specifies the inte 0~255 0~255 s

If you enable the TC pool functio 0~4095 0~4095 None

Whether to re-assign the radio chaSame_BandSame Band, Same_Band, Diff_Band None

Whether to allow the reassignmenNONo, YESYes NO, YES None

Mutual-aid changeback policy of ALLAll, PARTPart ALL, PART None

The value of this parameter cannot be 0.This parameter, "Geography Scope", and "Update" uniquely decide a cell broadcast message.

A key parameter that indicates how many times the BSC6900 broadcasts cell messages. You can obtain the cell broadcast times by running the "DSP GSMSCB" command.The value 0 indicates no repeat.

Update code for a simple cell broadcast message.This parameter together with "Code" uniquely identifies a cell broadcast message.

Whether to support the discontinuous reception mechanism DRX. To reduce the power consumption, the DRX is introduced into the GSM Specification. MSs supporting the DRX can consume less power to receive interested broadcast messages. This prolongs the service time of MS batteries.BSCs supporting the DRX must send scheduling messages to MSs so that the MSs can use the DRX function. The period occupied by broadcast messages that are contained in a scheduling message is called a scheduling period. In the sending sequence, a scheduling message contain the description of each short message to be broadcasted and the position of each broadcast message in the scheduling period.

Geographical coverage of a simple cell broadcast message. You can run "DSP GSMSCB" to query and obtain the information.This parameter, "Code", and "Update" uniquely specify a cell broadcast message.

Whether to enable the TRX aidingTRXAid_NotAllowTRX AiTRXAid_NotAllow, AllowReFNone

Delay time for mutual-aid detection1~60 1~60 min


This parameter specifies the numb0~16 0~16 None

Information about the cell scenariCOMMONCOMMON, MUCOMMON, MULTIPATH, INNone

Whether to allow the BTS to reportNONot report, YESRepNO, YES, NONE None

If the FER carried in the measure0~1000 0~1000 per mil

If the FER carried in the MR rece0~1000 0~1000 per mil






Whether the BTS reports the framNONo, YESYes NO, YES None

Whether to allow the BTS to reporDISABLEDisable, ENA DISABLE, ENABLE, UNSU None

Active coding set ACS[WB], indica6_60KBIT/S, 8_85KBIT/0~7 None





Initial coding mode used for broa 0~2 0~2 None





DEFAULT_VALUE RECOMMENDED_VAPARAMETER_RELATIONSHIP CAUTIONBCCHNorm BCCHNorm If this parameter is BCCHExt," None

OFF OFF None None

R98_or_below R98_or_below None If the GSM

A5/0-1&A5/1-0&A5/A5/0-1&A5/1-0&A5/None The value o

OFF OFF None None

0 0 None None

7_Times 7_Times None None




12_level 12_level None None




T_20 T_20 None None

T_20 T_20 None None

8BIT 8BIT None None

NEUTRAL NEUTRAL None None

62 In Normal cell,the None If this para

NO NO None None

36671 36671 None None

DISABLE DISABLE None None

NO NO None None

NO NO None None

2 2 Generally, t"DLLTFERLOWTH" < "DLLTFERTGT"; "DLLTFERLOWTH" < "DLLTFERUPTH".

8 The setting of this parameter

60 60 Generally, t

2 2 None Generally, t

2 2 Generally, t

8 8 The value of

60 60 Generally, t

2 2 None Generally, t

ALG1 ALG1 None


4_75KBIT/S-1&5_154_75KBIT/S-1&5_15None

YES YES None None

2 2 The setting of this parameter m None



12 12 None

17 17 None

25 25 None

1 1 None None



3 3 None None

15 15 None

The recommended value is 8 when DTX is disabled.The recommended value is 14 when DTX is enabled.

FER with the discontinuous transmission DTX enabled is a little higher than the one without the DTX enabled. It is recommended that you set the value of this parameter to 14 when the DTX is enabled. Based on this value, you can make adjustments in the above mentioned principle according to actual test results."DLLTFERUPTH" > "DLLTFERTGT";

"DLLTFERUPTH" > "DLLTFERLOWTH".

"LTFERLOWTH" < "LTFERTGT"; "LTFERLOWTH" < "LTFERUPTH"."LTFERLOWTH" < "LTFERTGT";"LTFERTGT" < "LTFERUPTH"."LTFERUPTH" > "LTFERTGT"; "LTFERUPTH" > "LTFERLOWTH".

If this parameter is set to Algorithm II, the BTS performs AMR rate adaptation according to the BER value. Algorithm II is valid only for the EMR.If this parameter is set to None, the AMR rate adaptation algorithm is not enabled, and a fixed coding rate is used.

If this parameter involves three coding rates, the value of "AMR Starting Mode[F]" can be 0, 1, or 2; the values of the following parameters make sense while the other adjustable thresholds and hysteresis of AMR coding rate do not: "AMR UL Coding Rate adj.th1[F]", "AMR UL Coding Rate adj.hyst1[F]", "AMR DL Coding Rate adj.th1[F]", "AMR DL Coding Rate adj.hyst1[F]", "AMR UL Coding Rate adj.th2[F]", "AMR UL Coding Rate adj.hyst2[F]", "AMR DL Coding Rate adj.th2[F]", and "AMR DL Coding Rate adj.hyst2[F]".If this parameter involves four full rate coding rates, the value of "AMR Starting Mode[F]" can be 0, 1, 2, and 3; all the adjustable thresholds and hysteresis of AMR coding rate make sense.

"DLTHF1" < "DLTHF2";"DLTHF1" + "DLHYSTF1" < "DLTHF2" + "DLHYSTF2"."DLTHF2" < "DLTHF3";"DLTHF2" + "DLHYSTF2" < "DLTHF3" + "DLHYSTF3"."DLTHF2" < "DLTHF3"; "DLTHF2" + "DLHYSTF2" < "DLTHF3" + "DLHYSTF3".

"ULTHF1" < "ULTHF2"; "ULTHF1" + "ULHYSTF1" < "ULTHF2" + "ULHYSTF2".

19 19 None

28 28 None


4_75KBIT/S-1&5_154_75KBIT/S-1&5_15None

YES YES None None

3 3 The setting of this parameter None



23 23 None

31 31 None

63 63 None

0 0 None None



15 15 None None

23 23 None

31 31 None

63 63 None

ON ON None None

55 55 None None

64_Times 64_Times None With a good

48 48 None With a good

52_Times 52_Times None With a good

32 32 None With a good

0 0 None None

None None None The paramet

NONE NONE None None

None None None None

0 0 None None

NO NO None None

NO NO None None

FLEX FLEX None ACS is usua

0 0 None None

0 0 None None

6dB 6dB None None

"ULTHF2" < "ULTHF3"; "ULTHF2" + "ULHYSTF2" < "ULTHF3" + "ULHYSTF3"."ULTHF2" < "ULTHF3"; "ULTHF2" + "ULHYSTF2" < "ULTHF3" + "ULHYSTF3".

If this parameter involves three coding rates, the value of "AMR Starting Mode[H]" can be 0, 1, or 2; the values of the following parameters make sense while the other adjustable thresholds and hysteresis of AMR coding rate do not: "AMR UL Coding Rate adj.th1[H]", "AMR UL Coding Rate adj.hyst1[H]", "AMR DL Coding Rate adj.th1[H]", "AMR DL Coding Rate adj.hyst1[H]", "AMR UL Coding Rate adj.th2[H]", "AMR UL Coding Rate adj.hyst2[H]", "AMR DL Coding Rate adj.th2[H]", and "AMR DL Coding Rate adj.hyst2[H]".If this parameter involves four half rate coding rates, the value of "AMR Starting Mode[H]" can be 0, 1, 2, and 3; all the adjustable thresholds and hysteresis of AMR coding rate make sense.

"DLTHH1" < "DLTHH2"; "DLTHH1" + "DLHYSTH1" < "DLTHH2" + "DLHYSTH2"."DLTHH2" < "DLTHH3"; "DLTHH2" + "DLHYSTH2" < "DLTHH3" + "DLHYSTH3"."DLTHH2" < "DLTHH3"; "DLTHH2" + "DLHYSTH2" < "DLTHH3" + "DLHYSTH3".

"ULTHH1" < "ULTHH2"; "ULTHH1" + "ULHYSTH1" < "ULTHH2" + "ULHYSTH2"."ULTHH2" < "ULTHH3"; "ULTHH2" + "ULHYSTH2" < "ULTHH3" + "ULHYSTH3"."ULTHH2" < "ULTHH3"; "ULTHH2" + "ULHYSTH2" < "ULTHH3" + "ULHYSTH3".

0 0 None The setting

YES YES None None

NO NO None If the value

NO The CBA function appNone If the value

SELECTION0_PERSELECTION0_PERNone None

30 30 This parameter is valid only None


OFF OFF None Multi-band

30 30 None None

None None None None

600 None None None

REHOSTDELAY REHOSTDELAY None None

YES YES None This param

0 0 None None

40 40 None None

360 None None None

360 360 None None

Degree Degree None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

NO NO None None

NO NO None When this pa

OFF OFF None None

3 3 None None

YES If this parameter is None None

None None None None

None None None None

MaximumMeanValuMaximumMeanValuNone This paramet

INTBANII INTBANII None None

None None None

None None None None

1 1 None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None None

ON ON None None

35 35 None


YES YES None None

ON ON None None

If the coverage area in the underlaid subcell is large and tight frequency reuse is used in the overlaid subcell, the recommended value is Inner.If the coverage areas in the overlaid and underlaid subcells are similar and tight frequency reuse is used on the BCCH, the recommended value is Extra.

In an enhanced concentric cell, if "LOWRXLEVOLFORBIDSWITCH" is set to ON, this parameter and "OTOURECEIVETH" determine whether the current uplink receive level meets the condition for assigning channels of the overlaid subcell during the assignment of the underlaid subcell channels and overlaid subcell channels.In a normal concentric cell, if "LOWRXLEVOLFORBIDSWITCH" is set to ON, this parameter, together with "RECLEVTHRES" and "RECLEVHYST", determines whether the current uplink receive level meets the condition for assigning channels of the overlaid subcell during the assignment of the underlaid subcell channels and overlaid subcell channels.

60 60 "TCHTRICBUSYOVERLAYTHR" anNone

70 70 "TCHTRICBUSYOVERLAYTHR" anNone

CONVERT0 CONVERT0 None None

Normal_cell Normal_cell None None

None None None None

4 4 None None

1 1 None None

1 1 None None

None None None None

None None None None

None None None None

None None None None

None None None None

None None None The CI can

None None None None

None None None None

FULL_RATE_VER1FULL_RATE_VER1None None

None None None None

None None None None

HOALGORITHM1 HOALGORITHM1 The value of this parameter m None

None None None None

None None None None

None None None None

None None None None

None None None None

0 0 None For a BTS of

5 5 None If this para

65535 65535 None For the BTS

None None None None

65535 65535 None None

YES YES None None


85 85 The value of DTLOADTHRED musNone

90 90 None None

4 4 None None

NO NO None None

YES YES None None

YES YES None None

Shall_Use Shall_Use None None

Shall_Use Shall_Use None None

YES None None None

5 5 This parameter is valid only w None

5 5 1. This parameter is valid only None

50 50 This parameter is valid only w When the sa


0:00 None When "TURNOFFCELLSTPTIME" < "None

0:00 None This parameter is valid only None


None None This parameter is valid only w None

BYNAME BYNAME This parameter is valid only w None

None None This parameter is valid only w None

None DISABLE None None

NOTSUPPORT NOTSUPPORT None None

NO NO None None

15 15 None None

OFF OFF None None

NO NO None None

0 0 This parameter is valid only wh None

OFF OFF None None

OFF OFF None None

60 60 None None

OFF OFF None None

OFF OFF None None

YES YES This parameter is valid when None

NO NO None None

None None This parameter is valid when None

0 0 This parameter is valid when None

0:00 None This parameter is valid when None

YES YES None None

YES YES This parameter is valid only w None

22 22 None None

25 25 None None

YES YES None None

YES YES None None

YES YES None None

OFF OFF None This parame

NO NO None None

YES YES None None

NONE NONE None None

60 60 None None

YES YES None None

100 100 The following condition mu None

100 100 The following condition mu None

CAPABILITY CAPABILITY None None

OFF None None None







20 20 None

None None None None

None None None None

None None None None

None None None None


3. In the following BTSs, the value range is 115 to 48: BTS3X 03.1130 and its later versions, 3001c 07.0301 and its later versions, 3002c 02.0820 and its later versions, and double-transceiver BTSs.4. If the value of this parameter is too great, the averaging result cannot accurately reflect changes. If the value is too small, frequent averaging of interference levels causes a waste of resources.




10 10 This parameter is valid only whe None


NO NO This parameter is valid only whe None

YES YES This parameter is valid only whe None

NO NO This parameter is valid only whe None














NO NO None None

ComMeasReport ComMeasReport None The Enhance

ADD0dB ADD0dB None None

YES YES None None









NO NO None None


NO NO None When this pa

YES YES None The downlink

YES YES None

Normal_cell Normal_cell None None

CLOSE CLOSE None None

NO NO None None

NO NO This parameter is valid when " None

NO NO This parameter is valid when " None

OFF When tight frequencThis parameter is valid when None

OFF OFF This parameter is valid when None

None None None The value o

None None None None

None None None None

None None None None

GSM1800 or GSM1900 cell, the power control level of the MS ranges from 0 to 31. Generally, the maximum transmit power supported by an MS is level 0 mapping to 30 dBm. The minimum transmit power supported by an MS is level 15 mapping to 2 dBm. Other transmit power levels are reserved for high-power MSs.

0 0 None HSNs are op

None None None None



YES YES None None

None None None None

NO_FH NO_FH None You must dea

CA_MA CA_MA None If there ar

NT14_5K-0&NT12K-NT14_5K-0&NT12K-None None

None None None The paramet

Priority4 Priority4 None None

NO NO None None

NO NO None None

YES YES None None

NoPriority NoPriority None None

NoPriority NoPriority None None

5 5 None The larger t

3 3 None The larger t



NO NO None None

YES YES None None



None None None None

0 0 None None

0 0 None None

2 2 None None


0 0 None None

8 8 None None

RSCP RSCP None None

6 6 None None

None None None None

None None None None

None None None The value r

None None None None

None 0 None None

None None None None

0 0 None None

0 0 None None

0 0 None None

0 0 None None

Use_Qsearch_I Use_Qsearch_I None None

15 15 None None

15 15 None None

15 15 None None

35 35 This parameter is valid only when thNone

NO NO This parameter is valid only None

50 50 None

NO NO None None

1. The ""INTERRATOUTBSCHOEN"" regarding the "SET GCELLHOBASIC" command is set to YES. 2. The ""BET3GHOEN"" parameter is set to YES. 3. The ""FDDREP"" parameter regarding the "SET GCELLCCUTRANSYS" command is set to RSCP.

None None None None

None None None None



NO NO None None

4 4 None None

4 4 None None

0 0 None None

4 4 None None

7 7 None None

0 0 None None

OFF OFF None None

OFF OFF None None

10 10 None None

2 2 None None

13 13 None None

10 10 None None

YES YES None None

0 0 None None

0 0 None None

0 0 None None

0 0 None None

4 4 None None

0 0 None None

20 20 None None

0 0 None None

7 7 None None

9 9 None None

4 4 None None

0 0 None None

15 It is recommended thaNone None

6 6 None None

110 110 None None

1 1 None None

NO NO None None

OFF OFF None None

20 20 None None

UNDER UNDER None None

NO NO None None

5 5 None None

80 80 None None

40 40 None None

4 4 None None

None None This parameter is valid only None












None None None None

YES YES None The ATT must

NO NO None None

30 30 None None

NO NO None None

None None None None

MCS5 MCS5 None None

0 If the traffic volum None None

3 3 This parameter is valid when " None

1 1 None None

1 1 None None

1 1 None None

ALLPwrLoc ALLPwrLoc None None

NMOII NMOII None None

OFF OFF None For a double

4 4 None None

2G 2G None None

30 30 None None

16 16 None None

7 7 None None

6 6 None None

5 5 None None

PERMIT PERMIT None The functio

40 40 None None

60 60 None None

85 85 None None

15 15 None None

200 200 None None

PERMIT PERMIT None None

10 10 None None

30 30 None None

6 6 None None

2 2 None None

10 10 None None

1 1 None None

PERMIT PERMIT None None

0.24sec 0.24sec None None



NC0 NC0 None None

0 0 None None

10 10 None None

None None None None

None None None None

None None None None

OFF OFF None This functio

100 100 None None

None 2 None. None.

None 25 None. None.

None 5 This parameter is valid when None.

None DISABLE This parameter is valid when None.

None 4 None. None.

0 0 None If the value

NO NO None If this para

None DISABLE None None

NO NO None None

None None None None

UNLOCK UNLOCK None None

ON ON None For the BTS

OUTDOOR_CELL OUTDOOR_CELL None None

2 2 None None

2 2 None If this param

2 2 None If this param

2 2 None None

YES YES None None

YES YES None None

NO NO None None

NO NO None None

NO NO None None

6 6 None None

NO NO None None

4 4 None None

2_M_PERIOD 2_M_PERIOD None A paging bl

255 255 None None

OPEN OPEN None None

2 2 None None

5 5 None None

650 650 None None

16 16 None None

6 6 None None

Support Support None None

NO NO None

NO NO None

0 0 This parameter is valid only w This parame

NO NO None None

NO NO None None

YES None None None

EM0 EM0 None None

60sec 60sec None If the value

TYPE1 TYPE1 None None

1 1 None None

1 1 None None

30 30 None None

1 1 None None

20 20 None None

1 1 None None

YES YES None None

10 10 None None

10 10 None None

3 3 None None

0 0 None None

5 5 None None

8 8 None None

YES YES None None



64 64 None None

8 8 None None

4 4 None None

2 2 None None

4 4 None None

2 2 None None

1 1 None None

10 10 None None

6 6 None None

4 4 None None

8 8 None None

4 4 None None

3 3 None None

6 6 None None

3 3 None None

2 2 None None

NO NO None None

-109 -109 The value of this parameter mu This paramet

1 1 None None

During upgrade, pay more attention to the setting of this parameter. Be sure to check it. If an area is allowed for receiving short messages, set this parameter to NO.If the value of this parameter is YES, the MS in either idle or connected mode cannot occupy radio channel resources to send short messages.Pay special attention to the setting of this parameter during an upgrade. If sending short messages is allowed, this parameter must be set to No.If this parameter is set to Yes, radio channels cannot be used to send short messages regardless of whether an MS is busy or not.

YES YES None None

-109 -109 The value of this parameter mu This paramet

225 225 None None

L0_FORBID-0&L1_L0_FORBID-0&L1_None None


16 16 None

L11_FORBID-0&L1L11_FORBID-0&L1None None

15 15 None None

80 80 None None

If the value of this parameter is too low, the BTS easily considers that the RACH timeslot is busy and reports overload messages to the BSC6900. If the value is too high, the BTS cannot determine the status of the RACH timeslot correctly.The settings of the BTS312, BTS3001C, BTS3001CP, BTS3002C, and double-transceiver BTS must be consistent with the meaning and requirement of the BTS30.

5 5 None The defaul

15 15 None None

5000 5000 None None

1 1 NoneCBCHs are configured.When the GSMR is enabled, NCHs are configured.

TX_32 TX_32 None None

4 4 None None

20 20 None None

OFF OFF None None

255 255 None None


32 32 None None

10 10 None None

6 6 None The level va

55 55 None The paramete

6 6 None The level va

55 55 None The paramete

40 40 None None

6 6 None None

55 55 None None

40 40 None None

6 6 None None

55 55 None None

55 55 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

1 1 None None

255 255 The parameter value corresponds None

NO NO None None


0 0 None The range of

NO NO None None

5 5 This parameter is valid when " None

NO NO None None

YES YES None The SDCCH d


2 2 None


NO NO None This parame

YES YES None None

This parameter is one of the conditions for the dynamic conversion of the TCHF to the SDCCH.In addition to the condition that the number of idle SDCCHs should be smaller than or equal to "IDLESDTHRES", the following three conditions must be met to trigger the conversion from the TCHF to the SDCCH:1. "SDDYN" in "SET GCELLBASICPARA" is set to YES.2. In the cell, the value of number of idle TCHFs + number of idle TCHHs/2 is greater than four and is greater than the number of TRXs. Idle TCHFs exist in the cell.3. Number of SDCCHs + 8 < "CELLMAXSD".

None None None None

None None None None

None 60 None None

None None None None

None None None None

None None The maximum length of this paraNone

None None None None

YES YES None None

Cell name None None None

60 60 None None

NO NO None

None None None None

None LAC_CI None None

None ENGLISH None None

NO NO None None

NO NO None None

OFF OFF None None

8 8 None If the value

YES 1. For a 900/1800 MHzNone It is recomm

0 0 None None

None None None None

Diff_Band Diff_Band This parameter is valid when To improve t

YES YES None None

ALL ALL None None

When the simple cell broadcast function is enabled, the BSC6900 provides the simple cell broadcast service if the CBC is not provided. The simple cell broadcast function is used to broadcast the messages that are not changed frequently.The simple cell broadcast function and the cell broadcast function provided by the CBC cannot be enabled simultaneously.

AllowReCheckRes AllowReCheckRes None


YES YES None None

2 2 This parameter is valid when The paramet

COMMON COMMON None None

NO NO None None

2 2 None None

4 4 None None

8 8 None None

16 16 None None

32 32 None None

64 64 None None

128 128 None None

NO For the double-transNone None


6_60KBIT/S-1&8_856_60KBIT/S-1&8_85None



12 12 None

18 18 None

2 2 None None


originally configured BCCH TRX is normal, baseband FH aiding switchback can be performed and the cell is restored to the baseband FH mode.After TRX aiding BCCH aiding or baseband FH aiding or switchback occurs, the cell is re-initialized.For any types of BTS, no aiding is performed within 15 minutes after the cell is initialized.

If this parameter involves two coding rates, the value of "AMR Starting Mode[WB]" can be 0 or 1; the values of the following parameters make sense while the other adjustable thresholds and hysteresis of AMR coding rate do not: "AMR UL Coding Rate adj.th1[WB]", "AMR UL Coding Rate adj.hyst1[WB]", "AMR DL Coding Rate adj.th1[WB]", and "AMR DL Coding Rate adj.hyst1[WB]".If this parameter involves three coding rates, the value of "AMR Starting Mode[WB]" can be 0, 1, or 2; the values of the following parameters make sense while the other adjustable thresholds and hysteresis of AMR coding rate do not: "AMR UL Coding Rate adj.th1[WB]", "AMR UL Coding Rate adj.hyst1[WB]", "AMR DL Coding Rate adj.th1[WB]", "AMR DL Coding Rate adj.hyst1[WB]", "AMR UL Coding Rate adj.th2[WB]", "AMR UL Coding Rate adj.hyst2[WB]", "AMR DL Coding Rate adj.th2[WB]", and "AMR DL Coding Rate adj.hyst2[WB]".

"DLTHWB1" < "DLTHWB2"; ["DLTHWB1" + "DLHYSTWB1" < "DLTHWB2" + "DLHYSTWB2"."DLTHWB1" < "DLTHWB2"; ["DLTHWB1" + "DLHYSTWB1" < "DLTHWB2" + "DLHYSTWB2".


21 21 None

25 25 None

"ULTHWB1" < "ULTHWB2"; "ULTHWB1" + "ULHYSTWB1" < "ULTHWB2" + "ULHYSTWB2"."ULTHWB1" < "ULTHWB2"; "ULTHWB1" + "ULHYSTWB1" < "ULTHWB2" + "ULHYSTWB2".

RADIO_PERFORMACE_IMPACT ATTRIBUTENone Radio

The number of block retransmissionsEquipment

None Radio

None Radio

If this function is enabled after enc Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

The throughput is affected. Radio

None Radio

None Radio

None Radio

When this parameter is set to on, t Radio

When this parameter is set to YES aRadio

When this parameter is set to YES aRadio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

When this parameter is set to on, t Radio

The ACS may affect the MOS. Radio

None Radio

None Radio

None Radio

None Radio

The coding rate and MOS are affectRadio



The setting of this parameter affec Radio

None Radio

None Radio

None Radio




When this parameter is set to ENABRadio


None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio


None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

If this parameter is set to a greater Radio

If this parameter is set to higher va Radio




None Equipment

None Equipment

None Radio

None Equipment

None Radio

None Radio

None Radio

None Radio


None Radio

RadioIf this parameter is set to a smaller value, pingpong location update may occur, thus increasing the signaling load on the SDCCH.If this parameter is set to a greater value, the MS may not camp on an optimum cell for a long time after entering a new location area.

None Radio

Radio

None Radio

None Radio

Radio

Radio

Radio

None Radio

None Equipment

The MS calculates C1 and C2 of the serving cell at a minimum interval of 5s. When necessary, the MS re-calculates C1 and C2 of all non-serving cells neighboring cells. The MS constantly checks whether a cell reselection is required by checking following conditions:Whether the path loss C1 of the current serving cell drops below 0 within 5s. If yes, the path loss is too large. C2 of an appropriate non-serving cell exceeds that of the serving cell in 5s and the following conditions are met:The C2 of a new cell in another LAC minus CRH broadcast in the system information 3 and 4 of the serving cell exceeds C2 of the serving cell in 5s.A cell reselection is performed in the last 15s, and the C2 of the new cell minus 5 dB constantly exceeds the C2 of the serving cell in 5s.A better cell exists if the above conditions are met. If a better cell exists, the MS reselects a cell, and does not select the previous cell within 5s.

The most significant three bits of BSIC for all cells map with the NCC. NCC Permitted should be set properly to avoid too many call drops. The MS does not report the information on the neighboring cells in the network whose corresponding NCC bit is set to 0. Thus, this parameter should be set properly. Otherwise, an MS during an ongoing call cannot perform normal handover and a cross-coverage call drop occurs. For details, see GSM Rec. 05. 08.During an ongoing call, the MS reports to the BTS the signal information on neighboring cells. A report covers a maximum of six cells. Thus, the MS should report those possible target cells, rather than selecting cells only based on the signal level. Generally, the MS does not report the information on the cells belonging to other GSM PLMNs.This function enables the MS to measure only those specified cells. This parameter specifies the codes of the NCCs to be measured by the MS.On the SCH, the system constantly transmits the BSIC, the first three bits of which indicate the NCC. Thus, the MS needs to compare only this parameter with the adjacent NCCs measured. Then, the MS reports the matched NCCs to the BTS and discards others.The setting of this parameter affects only those MSs during conversation, as well as boundary handovers.If this parameter is set to a greater value, the BCCH may idle while non-BCCHs are congested, thus affecting the traffic volume during busy times.If this parameter is set to a smaller value, the assignment of the BCCH may fail, and thus the access success rate may be decreased.If this parameter is set to a greater value, the assignment of the BCCH may fail, and thus the handover success rate may be decreased.If this parameter is set to a smaller value, the BCCH may idle while non-BCCHs are congested, thus affecting the traffic volume during busy times.

None Equipment

None Equipment

None Equipment

None Radio

None Equipment

None Equipment

None Radio

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

If this parameter is set to YES, the Radio

None Equipment

None Radio

Call reestablishment can decrease tRadio

None Radio

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

Radio

None Radio

None Radio

If this parameter is set to a smaller value, call drops may occur because the handover may not be performed timely.If this parameter is set to a greater value, unnecessary handovers may be performed.

Radio

Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

If this parameter is set to a greater value, the half-rate channels are assigned to the MS only when the channel seizure ratio of underlaid subcell is very high. Insufficient half-rate channels can be assigned to the MS. Thus, the capacity of the BSC is reduced.If this parameter is set to a smaller value, the half-rate channels are assigned to the MS only when the channel seizure ratio of underlaid subcell is very low. The calls use the half-rate channel even if there are enough full-rate channels, which influences the voice quality.

If this parameter is set to a greater value, the half-rate channels are assigned to the MS only when the channel seizure ratio of overlaid subcell is very high. Insufficient half-rate channels can be assigned to the MS. Thus, the capacity of the BSC is reduced.If this parameter is set to a smaller value, the half-rate channels are assigned to the MS only when the channel seizure ratio of overlaid subcell is very low. The calls use the half-rate channel even if there are enough full-rate channels, which influences the voice quality.

None Radio

This technology prevents the loss Radio

None Radio

None Radio

None Equipment

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

Radio

Radio

The discontinuous transmission DTX function allows a transmitter to stop power transmission in the case of no voice transfer. This function has the following benefits: In the uplink: decreasing the power consumption of the MS and reducing system interference In the downlink: decreasing power consumption of the BTS, reducing system interference, and reducing intermodulation inside the BTSFrom the network perspective, the inter-frequency interference is reduced and the network quality is improved.


Radio

Radio

Radio

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Radio

None Radio

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio


The discontinuous transmission DTX function allows a transmitter to stop power transmission in the case of no voice transfer. This function has the following benefits: In the uplink: decreasing the power consumption of the MS and reducing system interference In the downlink: decreasing power consumption of the BTS, reducing system interference, and reducing intermodulation inside the BTSFrom the network perspective, the inter-frequency interference is reduced and the network quality is improved.If this parameter is set to NO, the forced handover and call delay caused by timeslot arrangement can be avoided, but this may cause some TCHF-only calls to fail.If this parameter is set to Yes, calls may fail when the timeslot arrangement fails and when the MS does not select the TCHF in the concentric cell.

None Radio

None Radio

None Radio

None Radio

If this parameter is set to a smaller Radio

If this parameter is set to ON, the Radio

None Radio

When this parameter is set to YES, Equipment

When this parameter is set to YES, Equipment

None Equipment

None Equipment

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

In scenarios with heavy traffic, the Radio

None Radio

None Equipment

None Radio


None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Equipment

None Radio

None Radio


None Radio

None Radio

If this parameter is set to a greate Radio

Radio

None Radio

None Radio

None Radio

None Radio


None Radio

Radio

None Radio



None Radio






None Radio

If this parameter is set to a greater value, congestion may occur in the underlaid subcell.If this parameter is set to a smaller value, ping-pong handovers may occur.

If this parameter is set to a greater value, congestion may occur in the underlaid subcell;If this parameter is set to a smaller value, handover success rate may be decreased.

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

This feature only applies to the ar Radio

None Transport

None Transport

None Radio

None Radio

None Radio

None Radio

None Radio

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Equipment

None Equipment

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

If this parameter is set to a too gr Radio

None Radio

If this parameter is set to a too greatRadio

None Radio

None Equipment

None Equipment



None Radio


None Radio

None Radio

None Radio

None Radio


None Radio

None Radio




None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio


None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

If this parameter is set to YES, cel Radio

None Radio

None Radio

None Radio

None Radio


None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Equipment

None Radio

None Radio

None Equipment

None Radio

Radio

None Equipment

None Radio

None Radio

None Radio

None Equipment

None Radio

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

redundant position is still available, the MS reports the measurement results of other neighboring cells regardless of the bands at which the neighboring cells are located.If this parameter is set to 2, the MS reports the measurement results of two neighboring cell known and permitted by the NCC at each band with the best signal the band serving the current cell not included. The MS reports the measurement result of the neighbor cell at the band serving the current cell in the redundant position. If the redundant position is still available, the MS reports the measurement results of other neighboring cells regardless of the bands at which the neighboring cells are located.If this parameter is set to 3, the MS reports the measurement results of three neighboring cells known and permitted by the NCC at each band with the best signal the band serving the current cell not included. The MS reports the measurement result of the neighboring cell at the band serving the current cell in the redundant position. If the redundant position is still available, the MS reports the measurement results of other neighboring cells regardless of the bands at which the neighboring cells are located.

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

If this timer is set to a greater va Equipment

None. Equipment

None. Equipment

None. Equipment

None. Equipment

None Radio

None Radio

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

Properly setting this parameter can Radio

If this parameter is set to a great Radio

None Radio

None Equipment

None Equipment

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio


None Radio

None Radio



This parameter can be used to limitRadio

This parameter should be set as requRadio

If this parameter is set to a small Radio

This parameter can be used to contRadio

If this parameter is set to a smalle Radio

If this parameter is set to smaller Radio

None Radio

If this parameter is set to a small Radio

Radio

The setting of this parameter may Radio

If this parameter is set to a smaller value, the BTS frequently sends the overload messages to the BSC6900. Thus, the system resource usage decreases and MSs are difficult to access the network.If this parameter is set to a greater value, the BTS sends an overload message to the BSC6900 at a long interval. Thus, system faults may occur.

Radio

None Radio

None Radio

None Radio


Radio

None Radio

Radio

None Radio

None Radio

None Radio

None Radio

When this parameter is set to a lar Radio






None Equipment

None Radio

None Radio

None Radio

If the number of RACH conflicts in a cell is small, T should be set to a great value. If the number of RACH conflicts in a cell is large, T should be set to a small value. The increase in T and S prolongs the access time of an MS, thus affecting the access performance of the whole network. Therefore, appropriate values should be selected for T and S.When the network traffic is heavy, the success rate of immediate assignment is low if the sum of S and T is low. Thus, the value of T should be properly adjusted to make the sum of S and T great.

If this parameter is set to a smaller value, the radio link is vulnerable to failure, thus call drops are likely to occur.If this parameter is set to a greater value, the MS may not release the connection for a long time, thus decreasing the resource usage. The parameter is valid in the downlink.

If this parameter is set to a smaller value, the radio resource status is reported too frequently, thus increasing the load of the BSC6900.If this parameter is set to a greater value, the radio resource status is not immediately reported and thus the BSC6900 cannot handle the interference to the BTS in time.

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

None Radio

Not involved Radio

None Radio

None Radio


None Radio

None Radio

None Radio

None Radio

If this parameter is set to a smalle Radio

Radio

Radio

If this function is enabled, numbe Radio

None Radio

If this parameter is set to a greater value and consequently there is a small number of requests for SDCCHs, the SDCCHs of a cell are in idle state and the TCH traffic volume during busy time is decreased.if this parameter is set to a smaller value and consequently there is a large number of requests for SDCCHs, the requests cannot be met and the access success rate is decreased.If this parameter is set to a smaller value, the idle state of the current SDCCHs cannot be indicated correctly and consequently the rollback of SDCCHs immediately triggers adjustment and affects the access success rate.If this parameter is set to a larger value, the channel allocation algorithm becomes less sensitive and consequently the SDCCHs stay in idle state and cannot be rolled back for a long period of time, thus affecting the TCH traffic volume.

None Equipment

None Radio

None Radio

None Equipment

None Radio

None Radio

None Equipment

None Radio

None Radio

None Radio

None Radio

None Radio

None Equipment

None Radio

None Radio

None Radio

None Radio


None Radio

None Radio

None Equipment

None Radio

If this parameter is set to YES, th Radio

None Equipment

None Radio

None Equipment

None Equipment

None Equipment

None Equipment

None Radio

This parameter affects only the statiRadio







None Equipment

None Radio


None Radio

None Radio

None Radio

None Radio


None Radio

None Radio

None Radio

None Radio

IMPACT PARAMETEPARAMETEMML_COMDESCRIPTI FEATURE_ GUI_VALUACTUAL_VUNIT DEFAULT_

RECOMMENPARAMETECAUTION RADIO_PE ATTRIBUTE

FEATURE_NAME IMPACTAMR FR Cell

AMR FR Cell

AMR FR Cell

AMR FR/HR Dynamic Adjustment Cell





AMR HR Cell

AMR HR Cell











Chain Cell Handover Cell








































Cell

Cell

Direct Retry Cell

Fast Move Handover Cell








Cell

Cell

Cell

HUAWEI I Handover Cell







Concentric CellAMR FRConcentric CellAMR HR

GSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA InteroperabilityGSM/WCDMA InteroperabilityGSM/TD-SCDMA Interoperability







Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

HUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II Handover

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

HUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II Handover

HUAWEI I HandoverHUAWEI II Handover




HUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II Handover

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

Cell

HUAWEI II Handover Cell

HUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II Handover


HUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II Handover









































Pre-processing of Measurement Report Cell




SDCCH Handover Cell

PARAMETER_ID PARAMETER_NAMEDLQUALIMITAMRFR DL Qual. Limit for AMR FR

RXLEVOFF Interfere HO Qual. Thresh Offset for AMR FR

ULQUALIMITAMRFR UL Qual. Limit for AMR FR

INFHHOLAST Intracell F-H HO Last Time

INFHHOSTAT Intracell F-H HO Stat Time

INHOF2HTH F2H HO Threshold

INHOH2FTH H2F HO Threshold

INTRACELLFHHOEN Intracell F-H HO Allowed

DLQUALIMITAMRHR DL Qual. Limit for AMR HR

ULQUALIMITAMRHR UL Qual. Limit for AMR HR

ABCDownQuality Downlink Quality Threshold in Assigning Better

ABCUpQuality Uplink Quality Threshold in Assigning Better Cel

ABCWaitMaxTime Maximum Better Cell Assigning Duration

AssignBetterCellEn Assigning Better Cell Allowed

SDCCHWaitMREn Waiting for MR on SDCCH Switch

SDCCHWaitMRTimeLen Duration for Waiting MR on SDCCH

TIGHTBCCHHOLASTTIME TIGHT BCCH HO Valid Time

TIGHTBCCHHOSTATTIME TIGHT BCCH HO Watch Time

TIGHTBCCHHOLOADTHRES Load Threshold for TIGHT BCCH HO

TIGHTBCCHRXQUALTHRES RX_QUAL Threshold for TIGHT BCCH HO

HODIRFORECASTEN Handover Direction Forecast Enable

HODIRLASTTIME Handover Direction Forecast Last Times

HODIRSTATIME Handover Direction Forecast Statistic Times

ATCBHOEN Concentric Circles ATCB HO Allowed

ACCESSOPTILAY Incoming-to-BSC HO Optimum Layer

ENGOVERLDTHRSH En Iuo Out Cell General OverLoad Thred

ENLDHOPRD Load Classification HO Period

ENLDHOSTP Load Classification HO Step

ENLOWLDTHRSH En Iuo Out Cell Low Load Thred

ENSOVERLDTHRSH En Iuo Out Cell Serious OverLoad Thred

ENUTOOLOADINILEV IniLev for EnUtoO Load HO

HOALGOPERMLAY Pref. Subcell in HO of Intra-BSC

IMMASSTAALLOW TA Pref. of Imme-Assign Allowed

IMMASSTATHRES TA Threshold of Imme-Assign Pref

IUOHODURATIME UO HO Valid Time

IUOHOSTATIME UO HO Watch Time

OLTOULHOALLOW OL to UL HO Allowed

OPTILAYER Assign Optimum Layer

OPTILEVTHRES Assign-optimum-level Threshold

OPTITATHRES TA Threshold of Assignment Pref

OTOURECEIVETH OtoU HO Received Level Threshold

PSOTOURECEIVETHRSH PS OtoU HO Receive Level Threshold

PSUTOORECEIVETHRSH PS UtoO HO Receive Level Threshold

RECLEVHYST RX_LEV Hysteresis

RECLEVTHRES RX_LEV Threshold

RECLEVUOHOALLOW RX_LEV for UO HO Allowed

RECQUALTH RX_QUAL Threshold

RECQUALUOHOALLOW RX_QUAL for UO HO Allowed

TAFORUOHOALLOW TA for UO HO Allowed

TAHYST TA Hysteresis

TATHRES TA Threshold

TIMEOTOUFAILPUN Penalty Time after OtoU HO Fail

TIMEUTOOFAILPUN Penalty Time after UtoO HO Fail

ULTOOLHOALLOW UL to OL HO Allowed

UTOOFAILMAXTIME MaxRetry Time after UtoO Fail

UTOOHOPENTIME Penalty Time of UtoO HO

UTOORECTH UtoO HO Received Level Threshold

UTOOTRAFHOALLOW UtoO Traffic HO Allowed

UTRAFHOPERIOD Underlay HO Step Period

UTRAFHOSTEP Underlay HO Step Level

RECEIVEQUALTHRSHAMRFR ReceiveQualThrshAMRFR

RECEIVEQUALTHRSHAMRHR ReceiveQualThrshAMRHR

MINPWRLEVDIRTRY Min Power Level For Directed Retry

QUICKHOEN Quick Handover Enable

HODOWNTRIGE Quick Handover Down Trigger Level

HOUPTRIGE Quick Handover Up Trigger Level

IGNOREMRNUM Ignore Measurement Report Number

MOVESPEEDTHRES Quick Move Speed Threshold

MSLEVSTRQPBGT EN Quick PBGT HO ALG When MS Leaves BT

NCELLFILTER Neighbor Cell Filter Length MR Number

SCELLFILTER Serving Cell Filter Length MR Number

INTERRATCELLRESELEN Inter-RAT Cell Reselection Enable

INTERRATINBSCHOEN Inter-RAT In BSC Handover Enable

INTERRATOUTBSCHOEN Inter-RAT Out BSC Handover Enable

EDGELAST1 Handover Algorithm I Edge HO Valid Time

EDGESTAT1 Handover Algorithm I Edge HO Watch Time

PBGTHOEN PBGT HO Allowed

FLTPARAA1 Filter Parameter A1








FLTPARAB Filter Parameter B

DIRMAGANSITEFLAG Directly Magnifier BTS Flag

BQHOEN BQ HO Allowed

COBSCMSCADJEN Co-BSC/MSC Adj

CONHOEN Concentric Circles HO Allowed

DLEDGETHRES Edge HO DL RX_LEV Threshold

FRINGEHOEN Edge HO Allowed

HOCDCMINDWPWR Min DL Level on Candidate Cell

HOCDCMINUPPWR Min UL Level on Candidate Cell

INTERFHOEN Interference HO Allowed

INTRACELLHOEN Intracell HO Allowed

LEVHOEN Level HO Allowed

LEVHOHYST Inter-layer HO Hysteresis

LoadHoEn Load Handover Support

QCKMVHOEN MS Fast Moving HO Allowed

RXQCKFALLHOEN Rx_Level_Drop HO Allowed

SIGCHANHOEN SDCCH HO Allowed

TAHOEN TA HO Allowed

ULEDGETHRES Edge HO UL RX_LEV Threshold

BANTIME Forbidden time after MAX Times

CONTINTV Interval for Consecutive HO Jud.

KBIAS K Bias

LOADHOPERIOD Load HO Step Period

LOADHOSTEP Load HO Step Level

LOADOFFSET Load HO Bandwidth

MAXCNTNUM MAX Consecutive HO Times

MAXRESEND Max Resend Times of Phy.Info.

OutBscLoadHoEn Inter BSC Load Information Allowed

QCKSTATCNT MS Fast-moving Watch Cells

QCKTIMETH MS Fast-moving Time Threshold

QCKTRUECNT MS Fast-moving Valid Cells

SPEEDPUNISH Penalty on MS Fast Moving HO

SPEEDPUNISHT Penalty Time on Fast Moving HO

SYSFLOWLEV System Flux Threshold for Load HO

T3105 T3105

TRIGTHRES Load HO Threshold

RXQUAL1 Interfere HO Qual. Thresh 1 for Non-AMR FR












CONTHOMININTV Min Interval for Consecutive Hos

NEWURGHOMININTV Min Interval for Emerg. HO

PENALTYEN Penalty Allowed

SDHOMININTV Min Interval for SDCCH Hos

TCHHOMININTV Min Interval for TCH Hos

LoadAccThres Load handover Load Accept Threshold

HOTHRES Inter-layer HO Threshold

HOOFFSET Quick Handover Offset

HOPUNISHVALUE Quick Handover Punish Value

TIMEPUNISH Quick Handover Punish Time

LAYER Layer of The Cell

PRIOR Cell Priority

DLINTERFLEVLIMIT Interf.of DL Level Threshold

DLINTERFQUALLIMIT Interf.of DL Qual.Threshold

QLENSD Filter Length for TCH Qual.

QLENSI Filter Length for SDCCH Qual.

QTRUDNPWRLASTTIME Qtru Down Power Inadequate Last Time

QTRUDNPWRSTATTIME Qtru Down Power Inadequate Stat Time

SSLENSD Filter Length for TCH Level

SSLENSI Filter Length for SDCCH Level

UPINTERFQUALLIMIT Interf.of UL Qual. Threshold

UPINTERLEVLIMIT Interf.of UL Level Threshold

UPRXLEVLASTTIME Duration of Uplink Received Level Differ

UPRXLEVSMOOTHPARA Smooth Factor of Uplink Received Level

UPRXLEVSTATICTIME Observe Time of UL RX Level Difference

DLQUALIMIT DL Qual. Threshold

NODLMRHOALLOWLIMIT Cons.No Dl Mr.HO Allowed Limit

NODLMRHOEN No Dl Mr.HO Allowed

NODLMRHOQUALLIMIT No Dl Mr.Ul Qual HO Limit

TALIMIT TA Threshold

ULQUALIMIT UL Qual. Threshold

DATAQUAFLTLEN Filter Length for TCH Qual

DATASTRFLTLEN Filter Length for TCH Level

FAILSIGSTRPUNISH Penalty Level after HO Fail

INTERFEREHOPENTIME Penalty Time on Interfere HO

LOADHOPENTIME Penalty Time on Load HO

LOADHOPENVALUE Penalty Value on Load HO

MRMISSCOUNT Allowed MR Number Lost

NCELLFLTLEN Filter Length for Ncell RX_LEV

NSIGSTRFLTLEN NCell Filter Length for SDCCH Level

PENALTYTIMER CfgPenaltyTimer

RSCPENALTYTIMER RscPenaltyTimer

SIGQUAFLTLEN Filter Length for SDCCH Qual

SIGSTRFLTLEN Filter Length for SDCCH Level

SSBQPUNISH Penalty Level after BQ HO

SSTAPUNISH Penalty Level after TA HO

TAFLTLEN Filter Length for TA

TASIGSTRFLTLEN TA Filter Length for SDCCH Level

TIMEAMRFHPUNISH Penalty Time after AMR TCHF-H HO Fail

TIMEBQPUNISH Penalty Time after BQ HO

TIMETAPUNISH Penalty Time after TA HO

UMPENALTYTIMER UmPenaltyTimer

HOOPTSEL Inter-rat HO Preference

HOPRETH2G HO Preference Threshold for 2G Cell

ADAPTASSIGNMENTFLOW Assignment Procedure in Intra-Cell HO Allowed

FORCEMSACCESS Force MS to Send Ho Access SWITCH

QTRUCHANMANGSWITCH QTRU Signal Merge Avoid Switch

QUERYCMAFTERINBSCHO Query Classmark after In-BSC HO Enabled

SENDCMAFTERINBSCHO Send Classmark ENQ Result to MSC Enabled

AMRFULLTOHALFHOALLOW AMR F-H Ho Allowed

AMRFULLTOHALFHOATCBADJSTEP AMR F-H Ho ATCB Adjust Step

AMRFULLTOHALFHOATCBTHRESH AMR F-H Ho ATCB Threshold

AMRFULLTOHALFHOPATHADJSTEP AMR F-H Ho Pathloss Adjust Step

AMRFULLTOHALFHOPATHTHRESH AMR F-H Ho Pathloss Threshold

AMRFULLTOHALFHOQUALTHRESH AMR F-H Ho Qual. Threshold

AMRFULLTOHALFHOTHRESH AMR F-H Traffic Threshold

AMRHALFTOFULLHOATCBTHRESH AMR H-F Ho ATCB Threshold

AMRHALFTOFULLHOPATHTHRESH AMR H-F Ho Pathloss Threshold

AMRHALFTOFULLHOQUALALLOW Allow AMR H-F Quality-based HO

AMRHALFTOFULLHOQUALTHRESH AMR H-F Ho Qual. Threshold

AMRHALFTOFULLHOTHRESH AMR H-F Traffic Threshold

BETTERCELLHOEN Better Cell Handover Enable

EDGELAST Handover Algorithm II Edge HO Valid Time

EDGESTAT Handover Algorithm II Edge HO Watch Time

FULLTOHALFHOATCBOFFSET F-H ATCB Offset Overlay

FULLTOHALFHODURATION F-H Ho Duration

FULLTOHALFHOLASTTIME F-H Ho Last Time

FULLTOHALFHOPATHOFFSET F-H Pathloss Offset Overlay

FULLTOHALFHOPERIOD F-H Ho Period

FULLTOHALFHOSTATTIME F-H Ho Stat. Time

HALFTOFULLATCBOFFSET H-F ATCB Offset Overlay

HALFTOFULLHODURATION H-F Ho Duration

HALFTOFULLHOLASTTIME H-F Ho Last Time

HALFTOFULLHOPATHOFFSET H-F Pathloss Offset Overlay

HALFTOFULLHOSTATTIME H-F Ho Stat. Time

INTERFERELASTTIME Interfere HO Valid Time

INTERFERESTATTIME Interfere HO Static Time

NOAMRFULLTOHALFHOALLOW Non-AMR F-H Ho Allowed

NOAMRFULLTOHALFHOATCBADJSTEP Non-AMR F-H Ho ATCB Adjust Step

NOAMRFULLTOHALFHOATCBTHRESH Non-AMR F-H Ho ATCB Threshold

NOAMRFULLTOHALFHOPATHADJSTEP Non-AMR F-H Ho Pathloss Adjust Step

NOAMRFULLTOHALFHOPATHTHRESH Non-AMR F-H Ho Pathloss Threshold

NOAMRFULLTOHALFHOQUALTHRESH Non-AMR F-H Ho Qual. Threshold

NOAMRFULLTOHALFTHRESH Non-AMR F-H Traffic Threshold

NOAMRHALFTOFULLHOATCBTHRESH Non-AMR H-F Ho ATCB Threshold

NOAMRHALFTOFULLHOPATHTHRESH Non-AMR H-F Ho Pathloss Threshold

NOAMRHALFTOFULLHOQUALALLOW Allow Non-AMR H-F Quality-based HO

NOAMRHALFTOFULLHOQUALTHRESH Non-AMR H-F Ho Qual. Threshold

NOAMRHALFTOFULLTHRESH Non-AMR H-F Traffic Threshold

PATHLOSSHOEN Pathloss Ho. Enable

BSMSPWRLEV Transfer BTS/MS Power Class

BTSMESRPTPREPROC MR.Preprocessing

MRPREPROCFREQ Sent Freq.of preprocessed MR

PRIMMESPPT Transfer Original MR

INRBSCSDHOEN Inter-BSC SDCCH HO ALLowed

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DESCRIPTIONDownlink quality limit for emergency handover in an AMR full rate call. The value of this parameter corresponds to the quality levels 0 to 7 multiplied by 10. An emergency handover can be triggered only when the downlink reception quality of an MS is higher than the value of this parameter, which indicates a poor quality

For AMR FR voice services, a fixed amount of offset is added to the corresponding grade of the received signal quality for the interference handover of non-AMR FR voice services.

The value of this parameter corresponds to multiplying quality level 0 to 7 by 10. An emergency handover can be triggered only when the uplink receive quality of the MS is greater than the value of this parameter.

The triggering of intra-cell F-H handovers must meet the P/N criteria, that is, when the condition for intra-cell F-H handovers is met for P seconds during N seconds, an intra-cell F-H handover is triggered. This parameter corresponds to the P in the P/N criteria.

The triggering of intra-cell F-H handovers must meet the P/N criteria, that is, when the condition for intra-cell F-H handovers is met for P seconds during N seconds, an intra-cell F-H handover is triggered. This parameter corresponds to the N in the P/N criteria.

For an AMR call, if the currently occupied channel is a full rate channel and the Radio Quality Indication RQI is always higher than the threshold set by this parameter, an intra-cell F-H handover is triggered.

For an AMR call, if the currently occupied channel is a half rate channel and the Radio Quality Indication RQI is always lower than the threshold set by this parameter, an intra-cell H-F handover is triggered.

Whether to allow AMR handovers. This parameter has no impact on dynamic non-AMR F-H handovers.

Downlink quality limit for emergency handover in an AMR half rate call. The value of this parameter corresponds to the quality levels 0 to 7 multiplied by 10. An emergency handover can be triggered only when the downlink reception quality of an MS is higher than the value of this parameter, which indicates a poor quality

The value of this parameter corresponds to multiplying quality level 0 to 7 by 10. An emergency handover can be triggered only when the uplink receive quality of the MS is greater than the value of this parameter.

Downlink quality level threshold for the MS to be assigned with a channel of the better cell.

Uplink quality level threshold for the MS to be assigned with a channel of the better cell.

The maximum duration for the BSC to select the best cell according to MRs in the MS assigning procedure. The BSC assigns the channel of the serving cell to the MS if the best cell is not selected within the duration specified by this parameter.

Switch for assigning the channel of a better cell to the MS during MS access.

Whether a call must camp on the SDCCH for a specific duration before being assigned with a traffic channel.

Duration for a call camping on the SDCCH before being assigned with a traffic channel.

The P/N criterion must be met for triggering a TIGHT BCCH handover. That is, the TIGHT BCCH handover can be triggered only if P seconds among N seconds meet the triggering conditions. This parameter corresponds to P in the P/N criterion.

The P/N criterion must be met for triggering a TIGHTBCCH handover. That is, the TIGHTBCCH handover can be triggered only if P seconds among N seconds meet the triggering conditions. This parameter corresponds to N in the P/N criterion.

When an intra-cell TIGHT BCCH handover needs to be performed handover from the non-BCCH to BCCH, the downlink receive quality must be smaller than the value of this parameter.

Handover directio forcast switch. When this parameter is set to YES, the BSC6900 can forecast the handover direction of the call in fast handover so that the best target cell can be selected for handover.

Whether to enable the ATCB handover algorithm for the concentric cell. According to the neighbor cell signal, the ATCB handover algorithm determines the coverage of the overlaid subcell and balances the load between the overlaid subcell, underlaid subcell, and neighbor cell. Therefore, the algorithm helps to decrease t

Subcell preferred during the incoming inter-BSC handover to the concentric cell. In the case of incoming inter-BSC handover to the concentric cell, the channels in this subcell are preferred.

If the load of the underlaid subcell is greater than this threshold, certain calls in the underlaid subcell are handed over to the overlaid subcell to balance the traffic between the overlaid and underlaid subcells.

Signal level step for the hierarchical load-based handover from the overlaid subcell to the underlaid subcell

If the load of the underlaid subcell is less than this threshold, certain calls in the overlaid subcell are handed over to the underlaid subcell to balance the traffic between the overlaid and underlaid subcells.

If the load of the underlaid subcell is greater than this threshold, the period of the load-based handover from the underlaid subcell to the overlaid subcell, "UL Subcell Load Hierarchical HO Periods", is decreased by "MOD Step LEN of UL Load HO Period" every second to accelerate the handover.

Initial signal level used to compute the handover zone for an MS during the hierarchical load-based handover from the underlaid subcell to the overlaid subcell of the enhanced concentric cell

Whether to assign channels according to the access_delay value in channel request messages during immediate channel assignment

When the access_delay value in the channel request message is smaller than this parameter, the overlay channels are assigned preferentially; otherwise, the underlay channels are assigned preferentially.

The triggering of concentric circle handovers must meet the P/N criteria, that is, when P out of N measurement reports meet the condition for concentric circle handovers, a concentric circle handover is triggered. This parameter corresponds to the P in the P/N criteria.

The triggering of concentric circle handovers must meet the P/N criteria, that is, when P out of N measurement reports meet the condition for concentric circle handovers, a concentric circle handover is triggered. This parameter corresponds to the N in the P/N criteria.

Whether to allow overlay-to-underlay handovers

Channel assignment policies used when TCHs are assigned in an IUO cell: SysOpt: The system selects the preferentially-assigned service layer and assigns channels according to the measurement reports on SDCCHs; USubcell: preferentially assigns the TCHs on the underlay; OSubcell: preferentially assigns the TCHs

Preferentially assigns channels on the overlay when the uplink receive level on the SDCCH is no smaller than "Assign-optimum-level Threshold" and the TA is smaller than "TA Threshold of Assignment Pref"; otherwise, assigns channels on the underlay to ensure successful channel assignment.

Preferentially assigns channels on the overlay when the uplink receive level on the SDCCH is no smaller than "Assign-optimum-level Threshold" and the TA is smaller than "TA Threshold of Assignment Pref"; otherwise, assigns channels on the underlay to ensure successful channel assignment.

One of the parameters that decide the underlay and overlay areas in an enhanced IUO cell. The underlay and overlay areas are decided by "OtoU HO Received Level Threshold", "UtoO HO Received Level Threshold", "RX_QUAL Threshold", "TA Threshold", and "TA Hysteresis" together.

Threshold of the receive level for triggering the handover of the PS services from the overlaid subcell to the underlaid subcell

Threshold of the receive level for triggering the handover of the PS services from the underlaid subcell to the overlaid subcell

One of the parameters that decide the underlay and overlay areas. The underlay and overlay areas are determined by "RX_QUAL Threshold", "RX_LEV Threshold", "RX_LEV Hysteresis", "TA Threshold", and "TA Hysteresis" together.

One of the parameters that decide the underlay and overlay areas. The underlay and overlay areas are determined by "RX_QUAL Threshold", "RX_LEV Threshold", "RX_LEV Hysteresis", "TA Threshold", and "TA Hysteresis" together.

Whether to use the downlink receive level as a condition in IUO handover decision

2. The uplink receive quality level after filtering is lower than "Quality Thresh. for Assigning Main BCCH Carrier Channel Under TIGHT BCCH". 3. The non-BCCH load is higher than "Intracell Non Main BCCH Load Threshold of TIGHT BCCH".

This parameter indicates P in the P/N rule for MS handover direction forcast. P/N rule: Among N handovers, the MS is handed over to Class B chain neighboring cell for successively P times, then the BSC6900 determines that the MS is moving to the Class B chain neighboring cell.This parameter indicates N in the P/N rule for MS handover direction forcast. P/N rule: Among N handovers, the MS is handed over to Class B chain neighboring cell for successively P times, then the BSC6900 determines that the MS is moving to the Class B chain neighboring cell.

If all the calls in the overlaid subcell are handed over to the underlaid subcell when the channel seizure ratio of the underlaid subcell is less than "En Iuo Out Cell Low Load Thred", the BSC load increases sharply. In this case, the target subcell may be congested and drop calls. To avoid such a problem, the hierarchical load-based handover algorithm is used to hand over the calls from the overlaid subcell to the underlaid cell level by level.This parameter specifies the period of the handover at each hierarchy level.

If this parameter is set to USubcell, a channel in the underlaid subcell is assigned preferentially.If this parameter is set to NoPrefer, a channel is assigned simply according to channel assignment algorithms.

One of the parameters that decide the underlay and overlay areas. If "Enhanced Concentric Allowed" is set to OFF, the underlay and overlay areas are determined by "RX_QUAL Threshold", "RX_LEV Threshold", "RX_LEV Hysteresis", "TA Threshold", and "TA Hysteresis" together; if "Enhanced Concentric Allowed" is set to ON, the underlay and overlay areas are determined by "RX_QUAL Threshold", "UtoO HO Received Level Threshold", "OtoU HO Received Level Threshold", "TA Threshold", and "TA Hysteresis" together.

Whether to use the downlink receive quality as a condition in IUO handover decision

Whether the TA is used as a decisive condition for the concentric cell handover

After an OL subcell to UL subcell handover of an MS fails, the MS does not perform OL subell-UL subcell handovers within the value of the parameter.

After an UL subcell to OL subcell handover of an MS fails, the MS does not perform UL subcell to OL subcell handovers within the value of the parameter.

Whether a UL subcell to OL subcell handover is allowed

When a UL subcell-OL subcel handover decision is performed to a call, the BSC determines whether the number of handover failures reaches the "MaxRetry Time after UtoO Fail". If the number reaches the threshold, the UL subcell to OL subcell handover is prohibited. Otherwise, the UL subcell to OL subcell handover i

After an MS performs a OL subcell to UL subcell handover successfully, the MS cannot be handed over to the OL subcell again within the value of the parameter.

One of the parameters that determine the coverage of the OL subcell and of the UL subcell. "UtoO HO Received Level Threshold", "OtoU HO Received Level Threshold", "ReceiveQualThrshAMRFR", "TA Threshold", and "TA Hysteresis" determine the coverage of the OL subcell and UL subcell.

Hierarchical handover period of the load handover from the UL subcell to the OL subcell. If the channel seizure ratio of the UL subcell is greater than the UL subcell general overload threshold, all the calls in the cell send handover requests at the same time and the load on the BSC increases in a short time. Thus, conge

Hierarchical level step of the load handover from the UL subcell to the OL subcell

IUO cell receive quality threshold AMRFR, which is used for IUO handover decision

IUO cell receive quality threshold AMRHR, which is used for IUO handover decision

In a direct retry, when the receive level of a neighboring cell is no smaller than this parameter, the neighboring cell can be a candidate cell for the direct retry.

Whether to allow the fast handover algorithm

Fast handover can be triggered only when the downlink level of the serving cell is less than this parameter.

Fast handover can be triggered only when the uplink signal level of the serving cell is less than this parameter.

Number of invalid measurement reports allowed when the BSC6900 filters the measurement reports. When the number of received measurement reports is no larger than this parameter, the BSC does not perform filtering or make quick handover judgment.

A quick handover can be initiated only if the rate of an MS is higher than this parameter during a certain period of time.

Whether to enable "Triggering the quick PBGT algorithm only when an MS is far from the BTS"

For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured values in several consecutive measurement reports. This parameter indicates the number of measurement reports used for the filtering of neighboring cell information.

When the network receives measurement reports, in consideration of the accuracy of a single measurement report, the measurement values in certain measurement reports are filtered to represent the radio operating environment. The parameter specifies the number of measurement reports used for filtering measurement

This parameter specifies whether the reselection from 2G cells to 3G cells is allowed.

This parameter specifies whether the handover from 3G cells to 2G cells is allowed.

This parameter specifies whether the handover from 2G cells to 3G cells is allowed.

Whether to use the PBGT handover algorithm. PBGT handovers are based on path loss. The PBGT handover algorithm searches in real time for cells that have lower path loss and meet certain system requirements, and decides whether to perform the handovers. To avoid ping-pong handovers, PBGT handovers can occ

When "Enhanced Concentric Allowed" is set to OFF, "TA Hysteresis", "RX_LEV Threshold", "RX_LEV Hysteresis", "RX_QUAL Threshold", and "TA Threshold" determine the coverage of the OL subcell and UL subcell.When "Enhanced Concentric Allowed" is set to ON, "TA Hysteresis", "UtoO HO Received Level Threshold", "OtoU HO Received Level Threshold", "RX_QUAL Threshold", and "TA Threshold" determine the coverage of the OL subcell and UL subcell.When "Enhanced Concentric Allowed" is set to OFF, "TA Hysteresis", "RX_LEV Threshold", "RX_LEV Hysteresis", "RX_QUAL Threshold", and "TA Threshold" determine the coverage of the OL subcell and UL subcell.When "Enhanced Concentric Allowed" is set to ON, "TA Hysteresis", "UtoO HO Received Level Threshold", "OtoU HO Received Level Threshold", "RX_QUAL Threshold", and "TA Threshold" determine the coverage of the OL subcell and UL subcell.

If the existing call is performed in the UL subcell, a UL subcell to OL subcell handover is triggered, and "UL to OL HO Allowed" is set to YES, the timer is started and the calls in the UL subcell are hierarchically handed over to the OL subcell if the traffic volume in the UL subcell reaches "En Iuo Out Cell General OverLoad Thred". Otherwise, if the traffic volume in the UL subcell is smaller than "En Iuo Out Cell General OverLoad Thred", the timer stops, and hierarchical handovers are not performed.If this parameter is set to NO, the traffic volume in the UL subcell is not taken into account for triggering the UL subcell to OL subcell handover or the OL subcell to UL subcell handover in an enhanced concentric cell.

According to the P/N rule, if the conditions for edge handover are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number P.According to the P/N rule, if the conditions for edge handover are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number N.

One of the nine parameters filter parameters A1 to A8 and filter parameter B used to configure the filter for determining whether the received signal level drops rapidly. The computation formula is as follows: C1nt = A1 x Cnt + A2 x Cnt-t + A3 x Cnt-2t + ... + A8 x Cnt-7tIf C1nt is less than B and Cnt is less than the threshold for edge handover, the signal level is considered dropping rapidly.In the formula, A1 to A8 are filter parameters A1 to A8 minus 10 and B is the negative of filter parameter B. Cnt indicates the received signal level in the uplink measurement report of the serving cell received at time nt.Setting the filter helps to configure the maximum allowed signal level drop degree.




Trend of the received signal level of the cell during a period. This parameter helps to configure the filter for determining whether the received signal level drops rapidly. If this parameter is higher, a more rapid signal level drop is required to trigger the handover due to rapid signal level drop.

Whether to enable the bad quality BQ handover algorithm. Whether to trigger BQ handover depends on the uplink and downlink transmit quality measured by using BER. If the uplink or downlink BQ exceeds the BQ handover threshold, emergency BQ handover is triggered. The possible causes of BER increase or quality

Whether to adjust the candidate cell queue to give priority to intra-BSC/MSC handover

Whether to enable the concentric cell handover algorithm. The concentric cell handover helps to achieve wide coverage in the underlaid subcell and aggressive frequency reuse in the overlaid subcell and to improve the system capacity and conversation quality. The concentric cell handover can be classified into two types

Threshold for downlink edge handover. If the downlink receive level remains less than this threshold for a period of time, the edge handover is triggered. If the PBGT handover algorithm is enabled, this threshold can be decreased accordingly. If the PBGT handover algorithm is disabled, over-coverage, co-channel interf

Whether to enable the edge handover algorithm. When an MS makes a call at the edge of a cell, the call may drop if the received signal level is too low. To avoid such a call drop, the edge handover algorithm is involved. When the uplink signal level of the serving cell is less than "Edge HO UL RX_LEV Threshold" or the

If the downlink received signal level of a neighbor cell is greater than "Min DL Level on Candidate Cell" plus "Min Access Level Offset", the neighbor cell can be listed in the candidate cell queue for handover.

If the uplink received signal level of a neighbor cell is greater than "Min UL Level on Candidate Cell" plus "Min Access Level Offset", the neighbor cell can be listed in the candidate cell queue for handover.

Whether to allow the interference handover algorithm. Interference handovers are triggered when the receive level is higher than the receive threshold while the transmit quality is lower than the interference handover quality threshold, that is, when the MSs are subject to all kinds of radio interferences.

Whether to allow intra-cell handovers

Whether to allow inter-layer and inter-level handovers. The inter-layer and inter-level handover algorithm is achieved through the setting of different layers and priorities for cells, which switches traffic to cells of a higher precedence decided by "Layer of the cell" and "Cell priority" together.

This parameter specifies whether a traffic load-sharing handover is enabled. The load handover helps to reduce cell congestion, improve success rate of channel assignment, and balance the traffic load among cells, thus improving the network performance. The load handover is used as an emergency measure instead of a

Whether to enable the fast moving micro-cell handover algorithm. The fast moving micro-cell handover algorithm enables fast moving MSs to switch over to macro-cells, thus reducing the handover times.

Whether to use the emergency handover algorithm in case the receive level of the MSs drops rapidly, thus preventing call drops.

Whether to enable a handover between signaling channels

Whether to enable the time advance TA handover. The TA handover determines whether the timing advance TA is higher than the predefined TA threshold. When the TA is higher than the predefined TA threshold, a TA handover is triggered. The TA is calculated based on the distance between the MS and the BTS. The lon

If the UL receive level remains lower than the "Edge HO UL RX_LEV Threshold" for a period, the edge handover is triggered.

Duration in which intra-cell handover is forbidden after the number of consecutive intra-cell handovers reaches the maximum. Intra-cell handover can be conducted again only after this duration.

The twice intra-cell handover events during this interval are considered consecutive handover events.

K offset used in K sequencing. To reduce ping-pong handovers, the system performs K sorting based on the downlink receive level of the candidate cells. But before doing that, the system subtracts "K Bias" from the actual downlink receive level of the candidate cells.

In hierarchical load handovers, starting from "Edge HO DL RX_LEV Threshold", a "Load HO Step Level" is added to the upper handover threshold after every "Load HO Step Period". In this way, all the calls in the current serving cell whose receive level is in the range "Edge HO DL RX_LEV Threshold" to "Edge HO DL

Number of consecutive intra-cell handovers allowed in a cell. When the interval between two intra-cell handovers is lower than a certain time threshold, these two intra-cell handovers are considered consecutive. When a certain number of intra-cell handovers occur consecutively, intra-cell handovers will be disallowed in the





Whether a cell is a repeater. With simpler functions than a BTS, a repeater is a coverage extension device of a BTS. It is applied to widely-stretched areas or indoor areas to solve the dead zone problem of BTS coverage. Using repeaters cannot increase the traffic capacity of a network but improve the coverage only. Because the BTS coverage increases, however, the total traffic improves accordingly.The setting of this parameter has effects on handovers. Repeaters use the asynchronous transfer mode ATM due to a greater distance between them. Therefore, handovers between repeaters are asynchronous. Synchronous handovers will fail.

Inter-layer handover threshold of the serving cell = "Inter-layer HO threshold" - "Inter-layer HO Hysteresis"; Inter-layer handover threshold of a neighboring cell = "Inter-layer HO threshold" + "Adjacent Cell Inter-layer HO Hysteresis" - 64.

When the load of a cell reaches or exceeds "Load HO Threshold", all the calls that are using this cell as the serving cell generate handover requests at the same time, which will suddenly increase the load of the processor. Under some circumstances, congestion occurs in the cell, which will result in call drop. To solve this problem, the BSC uses the hierarchical load handover algorithm to control the number of users included in each level of handovers. This parameter indicates the duration of each handover level.

In the handover algorithm of the first generation, load handovers can be performed only when the receive level of the current serving cell is in the range "Edge HO DL RX_LEV Threshold" to "Edge HO DL RX_LEV Threshold" + "Load HO Bandwidth". In the handover algorithm of the second generation, load handovers can be performed only when the level difference between the neighboring cell and the serving cell is between "Inter-cell HO Hysteresis" - "Load HO Bandwidth" and "Inter-cell HO Hysteresis".

Whether to use external 2G neighboring cells as the target cells of load handovers

This parameter is used in the P/N criteria decision: If an MS quickly passes through N out of P micro-cells lately, the BSC enables the fast moving micro-cell handover algorithm. This parameter corresponds to the N in the P/N criteria.

A time threshold determined based on the radius of a cell and the moving speed of an MS. If the MS crosses the cell in a time period shorter than this threshold, the BSC concludes that the MS quickly passes through the cell. Otherwise, it concludes that the MS slowly passes the cell.

This parameter is used in the P/N criteria decision: If an MS quickly passes through N out of P micro-cells lately, the BSC enables the fast moving micro-cell handover algorithm. This parameter corresponds to the P in the P/N criteria.

Level value of the penalty that is performed on the neighboring cells of the cell where a fast-moving MS is located. The neighboring cells must be located at the Macro, Micro, or Pico layer other than the Umbrella layer.

Period in which penalty is performed on the neighboring cells of the cell where a fast-moving MS is located. The neighboring cells must be located at the Macro, Micro, or Pico layer but not the Umbrella layer.

The system flux level is the current flux control level of the system. A load handover is allowed only when the system flux is lower than the value of this parameter.

When the BTS sends physical information to the MS, the BTS starts the timer T3105.If the timer T3105 expires before the BTS receives the SAMB frame from MS, the BTS resends physical information to the MS and restarts the timer T3105. The maximum times for resending physical information is "Max Resend Times o

The load handover is triggered when the traffic load in a cell is greater than the value of this parameter.

Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full Rate.












Minimum interval between two consecutive emergency handovers performed by an MS. During this interval, no emergency handover is allowed.

After a new SDCCH is assigned to an MS, the MS can be handed over to another channel only if the time during which the MS occupies the SDCCH is longer than the period specified by this parameter.

After a new TCH is assigned to an MS, the MS can be handed over to another channel only if the time during which the MS occupies the TCH is longer than the period specified by this parameter.

If the load of a cell is lower than the value of this parameter, the cell can admit the users handed over from other cells with higher load. Otherwise, the cell rejects such users.

Fast handover can be triggered only when the path loss difference between the serving cell and a neighbor cell on the chain is equal to or greater than this parameter.

To avoid ping-pong handover, the received signal of the original serving cell is decreased by "Quick handover punish value" in "Quick handover punish time" after fast handover succeeds.

After the fast handover is successful, the penalty on the original serving cell is performed within the "Quick handover punish time": the receive level of the original serving cell is decreased by "Quick handover punish value", to prevent ping-pong handovers.

Layer where a cell is located. The network designed by Huawei has four layers: Umbrella layer 4, Macro layer 3, Micro layer 2, and Picolayer 1. Each layer can be set with 16 priorities.

This parameter controls handover between cells at the same layer. Generally, the cells at the same layer are set with the same priority. If the cells at the same layer have different priorities, a cell with a smaller priority value has a higher priority.

Threshold for determining whether downlink interference exists. If the downlink level is equal to or greater than "Interf.of DL Level Threshold" and the downlink quality level is equal to or greater than "Interf.of DL Qual.Threshold", downlink interference exists. The value range 0 to 63 is mapped to the range -110 dBm to -

Threshold for determining whether downlink interference exists. If the downlink level is equal to or greater than "Interf.of DL Level Threshold" and the downlink quality level is equal to or greater than "Interf.of DL Qual.Threshold", downlink interference exists.

For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured values in several consecutive measurement reports. This parameter indicates the number of measurement reports used for the filtering of the signal quality on service or data channels. This parameter is us

For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured values in several consecutive measurement reports. This parameter indicates the number of measurement reports used for the filtering of the signal quality on signaling channels. This parameter is used to

The P/N criteria is used to determine low downlink power for multi-density carriers. If the downlink power of a multi-density carrier remains low during a consecutive P seconds out of N seconds, the downlink power of the multi-density carrier is considered low. This parameter corresponds to the P in the P/N criteria.

The P/N criteria is used to determine low downlink power for multi-density carriers. If the downlink power of a multi-density carrier remains low during a consecutive P seconds out of N seconds, the downlink power of the multi-density carrier is considered low. This parameter corresponds to the N in the P/N criteria.

Maximum times for a Physical Information message to be transmitted. When the retransmission times exceeds this parameter and the BTS still cannot receive any correct SAMB frame from the MS, the BTS sends a connection failure message including the handover failure information to the BSC, which releases the assigned channel and stops timer T3105 after receiving this message. In a non-synchronized handover, an MS keeps sending Handover Access Burst messages usually, the value of timer T3124 is 320 ms to the network. When detecting these messages, the BTS returns a Physical Information message to the MS through the main DCCH FACCH channel, starts timer T3105, and sends a MSG_ABIS_HO_DETECT message to the BSC. The BTS includes the information of different physical layers in the Physical Information message, thus ensuring correct traffic transmission for the MS. If the timer timeouts before a SAMB frame is received from the MS, the BTS retransmits the Physical Information message to the MS. For details, see protocols 08.58 and 04.08.

Minimum interval between the two consecutive handover decisions of an MS. The BSC cannot make a handover decision during the minimum interval.To avoid frequent handover events in the cell, the BSC starts a timer after delivering a handover command to an MS. The BSC allows the MS to make a second handover decision only after the timer expires. This parameter specifies the duration of the timer.

After a handover fails due to congestion of the target cell, the system needs to punish the target cell to prevent the MS from attempting to switch to the target cell again. Ping-pong handovers can easily occur when handovers are of more TA or bad quality. In these cases, the system needs to punish the current serving cells.

Handover threshold during the handovers between cells on different layers or of different priorities. This value is used to suppress inter-layer ping-pong handovers. Inter-layer handover threshold of the serving cell = "Inter-layer HO threshold" - "Inter-layer HO Hysteresis"; Inter-layer handover threshold of a neighboring cell = "Inter-layer HO Threshold" + "Adjacent Cell Inter-layer HO Hysteresis" - 64.

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number of successive measurement reports that are used to determine the signal strength on tra

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. The parameter specifies the number of successive measurement reports that are used to determine the signal strength on si

One of the thresholds to determine whether the uplink interference exists. If the uplink level is not smaller than "Interf.of UL Level Threshold" and the uplink quality of the channel is not less than "Interf.of UL Qual. Threshold", the uplink interference exists.

One of the thresholds to determine whether the uplink interference exists. If the uplink level is not smaller than "Interf.of UL Level Threshold" and the uplink quality of the channel is not less than "Interf.of UL Qual. Threshold", the uplink interference exists.

If the difference between uplink receive levels of calls within the same timeslot is greater than "Offset of the difference between uplink received levels" for P seconds among N seconds, the call with weak uplink receive level within the timeslot will be handed over to another timeslot. This parameter corresponds to P in the

After the existing uplink receive level, uplink receive level after the previous optimization, and the value of this parameter are weight-averaged, the uplink receive level after the optimization at this time is obtained and used for determing the difference between the uplink receive levels.

If the difference between uplink receive levels of calls within the same timeslot is greater than "Offset of the difference between uplink received levels" for P seconds among N seconds, the call with weak uplink receive level within the timeslot will be handed over to another timeslot. This parameter corresponds to N in the

Downlink quality threshold for emergency handover. This parameter is represented as the product of 10 and a quality level that ranges from 0 to 7. The emergency handover can be triggered only when the downlink receive quality of an MS is greaterindicate bad quality than this threshold.

Decisions of no-downlink measurement report handovers can be made only when the number of consecutive no-downlink measurement reports in the current call is no larger than this parameter.

Whether to enable the no-downlink measurement report handover algorithm

When a certain number of no-downlink measurement reports are received consecutively and the uplink receive quality is no smaller than this parameter, no-downlink measurement report emergency handovers are triggered. No-downlink measurement report emergency handovers choose the inter-cell handover mode preferential

An emergency handover is triggered when TA is greater than or equal to the value of this parameter.

An emergency handover due to bad quality is triggered when the uplink receive quality is not smaller than "UL Qual. Threshold".

Number of measurement reports sampled for averaging the signal quality on a speech/data channel. Averaging the signal quality in multiple measurement reports helps to avoid a sharp signal quality drop due to Rayleigh fading and to ensure the comprehensiveness of a handover decision.

Number of measurement reports sampled for averaging the signal strength on a speech/data channel. Averaging the signal strength in multiple measurement reports helps to avoid a sharp signal level drop due to Rayleigh fading and to ensure the comprehensiveness of a handover decision.

Penalty signal level imposed on a target cell to which the handover fails due to congestion or poor radio quality. This penalty helps to prevent the MS from making a second handover attempt to the target cell.

Specifies an interval between two consecutive interference handovers

After a load handover succeeds, the BSC punishes the former serving cell during "Penalty Time on Load HO" by subtracting "Penalty Value on Load HO" from the receive level of the former serving cell, thus avoiding ping-pong handovers.

After a load handover succeeds, the BSC punishes the former serving cell during "Penalty Time on Load HO" by subtracting "Penalty Value on Load HO" from the receive level of the former serving cell, thus avoiding ping-pong handovers.

If the number of measurement reports lost consecutively is no larger than this value, linear interpolation is performed for the values in the lost measurement reports based on the values in the two measurement reports preceding and following the lost measurement reports. Otherwise, the lost measurement reports will b

For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured values in several consecutive measurement reports. This parameter indicates the number of measurement reports used for the filtering of neighboring cell signal strength.

For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured values in several consecutive measurement reports. This parameter indicates the number of measurement reports received on signaling channels used for the filtering of neighboring cell signal strength.

Timer of penalty on a neighboring cell when a handover fails due to faults of data configration.

Timer for punishing the neighboring cells when handover failures occur due to resource-related causes, such as resources being insufficient

Number of measurement reports used for averaging the signal quality of signaling channels. This parameter helps avoid sharp drop of signal levels caused by Raileigh fading and to ensure correct handover decisions.

Number of measurement reports used for averaging the signal strength of signaling channels. This parameter helps avoid sharp drop of signal levels caused by Raileigh fading and to ensure correct handover decisions.

After a handovr due to bad quality is successful, the penalty on the original serving cell is performed within the "Penalty Time after BQ HO": the receive level of the original serving cell is decreased by "Penalty Level after BQ HO", to prevent ping-pong handovers.

After the time advancing handover is successful, the penalty on the original serving cell is performed within the "Penalty Time after TA HO": the receive level of the original serving cell is decreased by "Penalty Level after TA HO", to prevent ping-pong handovers.

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number of measurement reports sampled for filtering the TA.

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number of measurement reports sampled for filtering the TA on the signaling channel.

Within the preset time, no AMR FR-to-HR handover is allowed if the previous FR-to-HR handover fails due to channel unavailability or channel mismatch.

After a handovr due to bad quality is successful, the penalty on the original serving cell is performed within the "Penalty Time after BQ HO": the receive level of the original serving cell is decreased by "Penalty Level after BQ HO", to prevent ping-pong handovers.

After the time advancing handover is successful, the penalty on the original serving cell is performed within the "Penalty Time after TA HO": the receive level of the original serving cell is decreased by "Penalty Level after TA HO", to prevent ping-pong handovers.

Timer of penalty on a neighboring cell when a handover fails due to faults of air interface connection.

This parameter specifies whether a 2G cell or to a 3G cell is preferentially selected as the target cell for handover. When this parameter is set to Pre_2G_Cell, the BSC preferentially selects a 2G candidate cell as the target cell for handover.

If the receive level of the neighboring 2G cell that ranks the first in the candidate cell list is equal to or smaller than this threshold, the BSC preferentially selects a neighboring 3G cell as the handover target cell. Otherwise, the BSC preferentially selects a neighboring 2G cell as the handover target cell.

Whether to hand over an MS to another channel during an intra-cell handover through the assignment process

Whether an MS is forced to send a Handover Access message, which is indicated by an information element in the handover command.

Whether to query the classmark of the call in an incoming BSC handover

Whether to report the classmark queried by the BSC6900 to the MSC

Whether to enable the algorithm for the load-based AMR handover between full rate and half rate

If N signal merge events are consecutively detected among P times of measurements, the forcible intra-cell handover is triggered to switch the call with the highest signal strength to another timeslot in the cell.Here, N indicates "UL Signal Strength Difference Detections", P indicates "UL Signal Strength Difference Maintains".

ATCB threshold for the AMR handover from full rate to half rate. If the ATCB of an AMR full rate call is equal to or greater than this threshold, the AMR call is handed over from full rate to half rate.

Path loss threshold for the AMR handover from full rate to half rate. If the path loss of an AMR full rate call is equal to or less than this threshold, the AMR call is handed over from full rate to half rate.

Quality threshold for the AMR handover from full rate to half rate. If the uplink and downlink receive quality levels of an AMR full rate call are equal to or less than this threshold, the AMR call is handed over from full rate to half rate.

Load threshold for the AMR handover from full rate to half rate. If the cell load is greater than this threshold, the AMR full rate calls are handed over to half rate.

ATCB threshold for the AMR handover from half rate to full rate. If the ATCB of an AMR half rate call is less than this threshold, the AMR call is handed over from half rate to full rate.

Path loss threshold for the AMR handover from half rate to full rate. If the path loss of an AMR half rate call is greater than this threshold, the AMR call is handed over from half rate to full rate.

Whether to enable the algorithm for the uplink and downlink receive quality based AMR handover from half rate to full rate

Quality threshold for the AMR handover from half rate to full rate. If the receive quality level of an AMR half rate call is greater than this threshold, the AMR call is handed over from half rate to full rate.

Load threshold for the AMR handover from half rate to full rate. If the cell load is less than this threshold, the AMR half rate calls are handed over to full rate.

Whether to enable the algorithm for the handover to a better cell

ATCB difference between the overlaid and underlaid subcells

Duration of the handover from full rate to half rate. If the cell load is greater than the preset threshold, the calls that meet the conditions for the handover from full rate to half rate are handed over from full rate to half rate in this duration.

Path loss difference between the overlaid and underlaid subcells

Period of the handover from full rate to half rate. If the cell load is greater than the preset threshold, the calls that meet the conditions for the handover from full rate to half rate are handed over in "H-F Ho Duration". This parameter specifies the bandwidth to be handed over at each hierarchy level.

ATCB difference between the overlaid and underlaid subcells

Duration of the handover from half rate to full rate. If the cell load is less than the preset threshold, the calls that meet the conditions for the handover from half rate to full rate are handed over from half rate to full rate in this duration.

Path loss difference between the overlaid and underlaid subcells

The triggering of interference handovers must meet the P/N criteria, that is, when P out of N measurement reports meet the condition for interference handovers, a concentric circle handover is triggered. This parameter corresponds to the P in the P/N criteria.

The triggering of interference handovers must meet the P/N criteria, that is, when P out of N measurement reports meet the condition for interference handovers, a concentric circle handover is triggered. This parameter corresponds to the N in the P/N criteria.

Whether to allow non-AMR voice F-H handover

Decides the offset of the current ATCB together with other two parameters: "F-H Ho Period" and period of triggering a F-H handover, thus selecting target users for F-H handovers. ATCB offset = Period of triggering a F-H handover / "F-H Ho Period" + 1 * "Non-AMR F-H Ho ATCB Adjust Step".

When the ATCB value of non-AMR full rate voice is no smaller than this parameter, the condition for non-AMR F-H handovers is met.

When the path loss value of non-AMR full rate voice is no larger than this parameter, the condition for non-AMR F-H handovers is met.

Quality threshold for non-AMR F-H handovers. When the uplink receive quality and downlink receive quality of a user are both smaller than this parameter, a F-H handover is triggered for the user.

When the load of a cell is no smaller than this threshold, non-AMR F-H handovers are triggered in the cell.

When the ATCB value of non-AMR half rate voice is no larger than this threshold, the condition for non-AMR H-F handovers is met.

When the path loss value of non-AMR half rate voice is no smaller than this threshold, the condition for non-AMR H-F handovers is met.

Whether to trigger non-AMR H-F handovers according to the uplink and downlink receive quality

Quality threshold for non-AMR H-F handovers. When the receive quality of a user is no smaller than this parameter, the user meets the condition for H-F handovers.

When the load of a cell is no larger than this threshold, non-AMR H-F handovers are triggered in the cell.

Whether to perform path loss-based sorting in a better cell handover algorithm

Whether to enable the BTS to transfer BTS/MS power class to the BSC

Whether to enable the BTS to preprocess measurement reports. This parameter determines where to conduct power control.

Frequency at which the BTSs submit pre-processed measurement reports to the BSC

Whether the BTSs send the original measurement reports to the BSC after pre-processing them. When this parameter is set to YES, the BTSs sends the original and pre-processed measurement reports to the BSC.

Whether to allow inter-BSC SDCCH handovers

With "F-H Ho Period" and the duration for triggering handover from full rate to half rate, this parameter determines the current ATCB offset by which to choose the MSs to undergo handover from full rate to half rate.ATCB offset = duration for triggering handover from full rate to half rate/"F-H Ho Period" + 1 x "AMR F-H Ho ATCB Adjust Step"

With "F-H Ho Period" and the duration for triggering handover from full rate to half rate, this parameter determines the current path loss offset by which to choose the MSs to undergo handover from full rate to half rate.Path loss offset = duration for triggering handover from full rate to half rate/"F-H Ho Period" + 1 x "AMR F-H Ho Pathloss Adjust Step"

According to the P/N rule, if the conditions for edge handover are met in P of N measurement reports, the handover is triggered.This parameter specifies the number P.According to the P/N rule, if the conditions for edge handover are met in P of N measurement reports, the handover is triggered.This parameter specifies the number N.

According to the P/N rule, if the conditions for the handover from full rate to half rate are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number P.

According to the P/N rule, if the conditions for the handover from full rate to half rate are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number N.

According to the P/N rule, if the conditions for the handover from half rate to full rate are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number P.

According to the P/N rule, if the conditions for the handover from half rate to full rate are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number N.

Decides the current path cost offset together with other two parameters: "F-H Ho Period" and period of triggering a F-H handover, thus selecting target users for F-H handovers. Path cost offset = Period of triggering a F-H handover / "F-H Ho Period" + 1 * "Non-AMR F-H Ho Pathloss Adjust Step".

GUI_VALUE_RANGE ACTUAL_VALUE_RANGE UNIT DEFAULT_VALUE0~70 0~70 None 60

0~70 0~70 None 5

0~70 0~70 None 60

1~32 0.5~16, step:0.5 s 8

1~32 0.5~16, step:0.5 s 10

0~39 0~39 None 25

0~39 0~39 None 12

NONo, YESYes NO, YES None YES

0~70 0~70 None 55

0~70 0~70 None 55

0~70 0~70 None 50

0~70 0~70 None 50

10~80 1~8, step:0.1 s 40

OFFOff, ONOn OFF, ON None OFF

OFFOff, ONOn OFF, ON None OFF

0~100 0~10, step:0.1 s 10

1~32 0.5~16, step:0.5 s 4

1~32 0.5~16, step:0.5 s 6

0~100 0~100 per cent 80

0~7 0~7 None 3

NONo, YESYes NO, YES None NO

0~16 0~16 None 3

0~16 0~16 None 3

NOClose, YESOpen NO, YES None NO

OSubcellOverlaid subcellOSubcell, USubcell, NoPrefeNone Usubcell

0~100 0~100 per cent 70

1~255 1~255 s 5

0~63 0~63 dB 5

0~100 0~100 per cent 20

0~100 0~100 per cent 80

0~63 0~63 dB 63

SysOptSystem optimizatioSysOpt, OSubcell, USubcell,None SysOpt


0~255 0~255 bit 0

1~32 0.5~16, step:0.5 s 8

1~32 0.5~16, step:0.5 s 10


SysOptSystem optimizatioSysOpt, OSubcell, USubcell,None SysOpt

0~63 0~63 dB 35

0~255 0~255 bit 63

0~63 0~63 dB 20

0~63 0~63 None 25

0~63 0~63 None 35

0~63 0~63 dB 5

0~63 0~63 dB 30


0~70 0~70 None 60



0~255 0~255 bit 0

0~255 0~255 bit 63

0~255 0~255 s 10

10~255 10~255 s 40


0~8 0~8 None 3

0~255 0~255 s 10

0~63 0~63 dB 35


1~255 1~255 s 5

1~63 1~63 dB 5

0~70 0~70 None 50

0~70 0~70 None 40

0~63 0~63 dB 16


0~63 0~63 dB 50

0~63 0~63 dB 50

0~32 0~32 None 1

0~600 0~600 m/s 35


1~20 TCH:480~9600, step:480; Sms 4

1~20 TCH:480~9600, step:480; Sms 4




1~32 0.5~16, step:0.5 s 4

1~32 0.5~16, step:0.5 s 6


0~20 0~20 None 10

0~20 0~20 None 10

0~20 0~20 None 10

0~20 0~20 None 10

0~20 0~20 None 10

0~20 0~20 None 10

0~20 0~20 None 10

0~20 0~20 None 10

0~200 0~200 None 0





0~63 0~63 dB 20


0~63 0~63 dB 10

0~63 0~63 dB 0




0~63 0~63 dB 2






0~63 0~63 dB 10

1~200 1~200 s 20

1~200 1~200 s 6

0~63 0~63 dB 0

1~255 1~255 s 10

1~63 1~63 dB 5

0~63 0~63 dB 25

1~20 1~20 None 3

1~255 1~255 None 30


1~10 1~10 None 3

0~255 0~255 s 15

1~10 1~10 None 2

0~63 0~63 dB 30

0~255 0~255 s 40

0,8~11 0, 8~11 None 10

0~255 0~2550, step:10 ms 7

0~100 0~100 None 90

0~70 0~70 None 60

0~70 0~70 None 42

0~70 0~70 None 41

0~70 0~70 None 40

0~70 0~70 None 50

0~70 0~70 None 49

0~70 0~70 None 48

0~70 0~70 None 47

0~70 0~70 None 46

0~70 0~70 None 45

0~70 0~70 None 44

0~70 0~70 None 43

0~60 0~60 s 4

0~60 0~60 s 4


0~60 0~60 s 2

0~60 0~60 s 2

0~100 0~100 per cent 80

0~63 0~63 dB 25

0~127 0~127 dB 68

0~63 0~63 dB 63

0~255 0~255 s 10

1, 2, 3, 4 1, 2, 3, 4 None 3

PRIOR-1Priority-1, PRIOR-PRIOR-1, PRIOR-2, PRIOR-None None

0~63 0~63 dB 35

0~70 0~70 None 40

1~32 TCH:480~15360, step:480; ms 6

1~32 TCH:480~15360, step:480; ms 2

1~16 1~16 s 3

1~16 1~16 s 5

1~32 TCH:480~15360, step:480; ms 6

1~32 TCH:480~15360, step:480; ms 2

0~70 0~70 None 40

0~63 0~63 dB 30

1~16 1~16 s 4

1~10 0.1~1, step:0.1 None 6

1~16 1~16 s 5

0~70 0~70 None 55

0~64 0~64 None 8


0~70 0~70 None 50

0~255 0~255 bit 255

0~70 0~70 None 55

1~31 TCH:480~14880, step:480; ms 4

1~31 TCH:480~14880, step:480; ms 4

0~63 0~63 dB 30

0~255 0~255 s 15

0~255 0~255 s 10

0~63 0~63 dB 63

0~31 0~31 None 4

1~31 TCH:480~14880, step:480; ms 4

1~31 TCH:480~14880, step:480; ms 2

0~255 0~255 s 255

0~255 0~255 s 5

1~31 TCH:480~14880, step:480; ms 2

1~31 TCH:480~14880, step:480; ms 2

0~63 0~63 dB 63

0~63 0~63 dB 63

1~31 TCH:480~14880, step:480; ms 4

1~31 TCH:480~14880, step:480; ms 2

0~255 0~255 s 10

0~255 0~255 s 10

0~255 0~255 s 30

0~255 0~255 s 10

Pre_2G_CellPreference foPre_2G_Cell, Pre_3G_Cell, None Pre_2G_CellThres

0~63 0~63 dB 25



NOClose, YESOpen NO, YES None NO




0~255 0~255 dB 2

0~255 0~255 dB 20

0~255 0~255 dB 1

0~255 0~255 dB 100

0~7 0~7 None 0

0~100 0~100 per cent 75

0~255 0~255 dB 4

0~255 0~255 dB 108


0~7 0~7 None 3

0~100 0~100 per cent 15


1~32 0.5~16, step:0.5 s 1

1~32 0.5~16, step:0.5 s 1

0~255 0~255 dB 20

0~600 0~600 s 5

1~32 0.5~16, step:0.5 s 4

0~255 0~255 dB 10

0~600 0~600 s 1

1~32 0.5~16, step:0.5 s 6

0~255 0~255 dB 20

0~600 0~600 s 5

1~32 0.5~16, step:0.5 s 4

0~255 0~255 dB 10

1~32 0.5~16, step:0.5 s 6

1~16 0.5~8, step:0.5 s 2

1~16 0.5~8, step:0.5 s 3


0~255 0~255 dB 2

0~255 0~255 dB 30

0~255 0~255 dB 1

0~255 0~255 dB 95

0~7 0~7 None 0

0~100 0~100 per cent 85

0~255 0~255 dB 14

0~255 0~255 dB 103


0~7 0~7 None 2

0~100 0~100 per cent 25



BSC_PreprocessingBSC pBSC_Preprocessing, BTS_PNone BTS_Preprocessing

NOreportDo not report, NOreport, Twice_ps, Once_None Once_ps



RECOMMENDED_VALUE60

5

60

8

10

25

12

YES

55

55

50

50

40

OFF

OFF

10

4

6

80

3

NO

3

3

NO

Usubcell

70

5

5

20

80

63

SysOpt

NO

0

8

10

YES

SysOpt

35

63

20

25

35

5

30

YES

60

NO

NO

0

63

10

40

YES

3

10

35

NO

5

5

50

40

16

NO

50

50

1

35

NO

4

4

NO

NO

NO

4

6

YES

10

10

10

10

10

10

10

10

0

NO

YES

YES

NO

YES

10

0

YES

In the hot-spot areas, densely populated urban areas, urban areas, suburbs, and rural areas, the recommended value is YES; in the high-speed circumstances, the recommended value is NO.

YES

2

NO

Set this parameter to YES only in special scenarios such as highways.

In dual-band networking mode for densely populated urban areas, the level drops rapidly due to multiple barriers. The propagation loss of the 1800 MHz frequency band is greater than the propagation loss of the 900 MHz frequency band. Considering the preceding factors, you can set this parameter to YES for the DCS1

NO

YES

10

20

6

0

10

5

25

3

The recommended value is 20 when HUAWEI I Handover is used;The recommended value is 15 when HUAWEI II Handover is used.

30

NO

3

15

2

30

40

10

7

90

60

42

41

40

50

49

48

47

46

45

44

43

4

4

YES

2

2

80

25

68

63

10

3

None

35

40

6

2

3

5

6

2

40

30

4

6

5

55

8

NO

50

255

55

4

4

30

15

10

63

4

4

2

255

5

2

2

63

63

4

2

10

10

30

10

Pre_2G_CellThres

25

NO

YES

NO

NO

NO

NO

2

20

1

100

0

75

4

108

NO

3

15

YES

1

1

20

5

4

10

1

6

20

5

4

10

6

2

3

NO

2

30

1

95

0

85

14

103

NO

2

25

NO

YES

BTS_Preprocessing

Once_ps

NO

NO

PARAMETER_RELATIONSHIPNone

None

None

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "INTRACELLFHHOEN" is set to YES. The following condition must be met: "INFHHOSTAT" >= "INFHHOLAST".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "INTRACELLFHHOEN" is set to YES. The following condition must be met: "INFHHOSTAT" >= "INFHHOLAST".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "INTRACELLFHHOEN" is set to YES.

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "INTRACELLFHHOEN" is set to YES.

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "INTRACELLHOEN" is set to YES.

None

None

None

None

None

None

None

None

This parameter is valid only when "TIGHTBCCHSWITCH" in "SET GCELLCHMGBASIC" is set to ON. The following condition must be met: "TIGHTBCCHHOSTATTIME" >= "TIGHTBCCHHOLASTTIME".

This parameter is valid only when "TIGHTBCCHSWITCH" in "SET GCELLCHMGBASIC" is set to ON. The following condition must be met: "TIGHTBCCHHOSTATTIME" >= "TIGHTBCCHHOLASTTIME".

This parameter is valid only when "TIGHTBCCHSWITCH" in "SET GCELLCHMGBASIC" is set to ON.

This parameter is valid only when "TIGHTBCCHSWITCH" in "SET GCELLCHMGBASIC" is set to ON.

When parameter ""Quick handover enable"" is configured to "YES",then parameter ""Handover Direction Forecast Enable"" can be configured to "YES".Furthermore,before open "Handover Direction Forecast Enable", parameter

"Handover Direction Forecast Statistic Times" >= "Handover Direction Forecast Last Times"

"Handover Direction Forecast Statistic Times" >= "Handover Direction Forecast Last Times"

This parameter is valid only when "IUOTP" is set to Concentric_cell.

This parameter is valid only when "IUOTP" in "ADD GCELL" is set to Concentric_cell.

This parameter is valid only when "UTOOTRAFHOALLOW" is set to YES. The following condition must be met: "ENSOVERLDTHRSH" > "ENGOVERLDTHRSH" > "ENLOWLDTHRSH".

This parameter is valid only when "IUOTP" in "ADD GCELL" is set to EDB_cell.




This parameter is valid only when "IUOTP" in "ADD GCELL" is set to Concentric_cell and "HOCTRLSWITCH" in "SET GCELLHOBASIC" is set to HOALGORITHM2.



This parameter is valid only when "IMMASSTAALLOW" is set to YES.

The following condition must be met: "IUOHOSTATIME" >= "IUOHODURATIME".

The following condition must be met: "IUOHOSTATIME" >= "IUOHODURATIME".



This parameter is valid only when "IUOTP" in "ADD GCELL" is set to Concentric_cell and "OPTILAYER" is set to SysOpt.

This parameter is valid only when "IUOTP" in "ADD GCELL" is set to Concentric_cell and "OPTILAYER" is set to SysOpt.


None

None

This parameter is valid only when "IUOTP" in "ADD GCELL" is set to Concentric_cell and "ENIUO" is set to OFF.

This parameter is valid only when "IUOTP" in "ADD GCELL" is set to Concentric_cell and "ENIUO" is set to OFF.






This parameter is valid only when "IUOTP" in "ADD GCELL" is set to Concentric_cell. The following condition must be met: "TALIMIT" > "TATHRES".












This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1.

None

This parameter is valid only when "QUICKHOEN" in "SET GCELLHOBASIC" is set to YES.







None

None

None

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "FRINGEHOEN" is set to YES. The following condition must be met: "EDGESTAT1" >= "EDGELAST1".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "FRINGEHOEN" is set to YES. The following condition must be met: "EDGESTAT1" >= "EDGELAST1".


This parameter is valid only when "RXQCKFALLHOEN" in "SET GCELLHOBASIC" is set to YES. The following condition must be met: "FLTPARAA1" + "FLTPARAA2" + "FLTPARAA3" + "FLTPARAA4" + "FLTPARAA5" + "








This parameter is valid only when "RXQCKFALLHOEN" in "SET GCELLHOBASIC" is set to YES.

None

None

None

None

This parameter is valid when "FRINGEHOEN" is set to YES or "LOADHOEN" is set to YES.

None

None

None

None

None


None

None

None


None

None

This parameter is valid when "FRINGEHOEN" is set to YES or "RXQCKFALLHOEN" is set to YES.

None

This parameter, together with "BANTIME", limits the handover frequency in the cell.

None

This parameter is valid only when "LOADHOEN" in "SET GCELLHOBASIC" is set to YES.

This parameter is valid only when "LOADHOEN" in "SET GCELLHOBASIC" is set to YES. The value of this parameter must be smaller than "LOADOFFSET".


None

None


This parameter is valid only when "QCKMVHOEN" in "SET GCELLHOBASIC" is set to YES. The following condition must be met: "QCKSTATCNT" >= "QCKTRUECNT".

This parameter is valid only when "QCKMVHOEN" in "SET GCELLHOBASIC" is set to YES.

This parameter is valid only when "QCKMVHOEN" in "SET GCELLHOBASIC" is set to YES. The following condition must be met: "QCKSTATCNT" >= "QCKTRUECNT".

None

None


None


None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

When the cell is a 2G external cell, this parameter is valid only when the "" OutBscLoadHoEn"" parameter regarding the "SET GCELLHOAD" command is set to YES. W

None


None

None

None

None

None

None

None

None

This parameter is valid only when "QTRUPWRSHARE" is not set to NONE. The following condition must be met: "QTRUDNPWRSTATTIME" >= "QTRUDNPWRLASTTIME".

This parameter is valid only when "QTRUPWRSHARE" is not set to NONE. The following condition must be met: "QTRUDNPWRSTATTIME" >= "QTRUDNPWRLASTTIME".

None

None

None

None

The following condition must be met: "UPRXLEVSTATICTIME" >= "UPRXLEVLASTTIME".

None

The following condition must be met: "UPRXLEVSTATICTIME" >= "UPRXLEVLASTTIME".

This parameter is valid only when "BQHOEN" in "SET GCELLHOBASIC" is set to YES.

This parameter is valid only when "NODLMRHOEN" in "SET GCELLHOEMG" is set to YES.

None

This parameter is valid only when "NODLMRHOEN" in "SET GCELLHOEMG" is set to YES.

This parameter is valid only when "TAHOEN" in "SET GCELLHOBASIC" is set to YES.

This parameter is valid only when "BQHOEN" in "SET GCELLHOBASIC" is set to YES and "NODLMRHOEN" in "SET GCELLHOEMG" is set to YES.

None

None

None

This parameter is valid only when "HOCTRLSWITCH" in "SET GCELLHOBASIC" is set to HOALGORITHM2.



None

None


None

None

None

None

None

None

None


None

None

None

None

This parameter is valid only when the ""INTERRATOUTBSCHOEN"" parameter regarding the "SET GCELLHOBASIC" command is set to YES.

This parameter is valid only when "HOOPTSEL" is set to Pre_2G_CellThres.

None

None

None

None

None


This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2 and "AMRFULLTOHALFHOALLOW" is set to YES.












This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2 and "FRINGEHOEN" is set to YES. The following condition must be met: "EDGESTAT" >= "EDGELAST".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2 and "FRINGEHOEN" is set to YES. The following condition must be met: "EDGESTAT" >= "EDGELAST".





This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "FULLTOHALFHODURATION" >= "FULLTOHALFHOPERIOD".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "FULLTOHALFHOSTATTIME" >= "FULLTOHALFHOLASTTIME".



This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "HALFTOFULLHOSTATTIME" >= "HALFTOFULLHOLASTTIME".


This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "HALFTOFULLHOSTATTIME" >= "HALFTOFULLHOLASTTIME".

This parameter is valid only when "INTERFHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "INTERFERESTATTIME" >= "INTERFERELASTTIME".

This parameter is valid only when "INTERFHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "INTERFERESTATTIME" >= "INTERFERELASTTIME".


This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2 and "NOAMRFULLTOHALFHOALLOW" is set to YES.












This parameter must be set when "BTSMESRPTPREPROC" is set to BTS_PreprocessingN.

If the value of this parameter is BSC_Preprocessing, the pre-processing is performed on the BSC. In this case, the following parameters are invalid: "PRIMMESPPT", "BSMSPWRLEV", and "MRPREPROCFREQ".

This parameter must be set when "BTSMESRPTPREPROC" is set to BTS_PreprocessingN.

This parameter must be set when "BTSMESRPTPREPROC" is set to BTS_Preprocessing. This parameter must be set to NO when "MPMODE" of the BTS that serving this cell is set to MODE4_1 and there are more than t

This parameter is valid only when "SIGCHANHOEN" in "SET GCELLHOBASIC" is set to YES.

CAUTIONThe setting

For AMR call

The setting

None

None

None

None

None

The setting

The setting

None

None

The value of

Before enab

If the para

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

If the value

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

You can inc

None

None

None

None

None

None

None

The physical

None

This paramet

This paramet

This paramet

This paramet

This paramet

This paramet

This paramet

This paramet

This paramet

This paramet

This paramet

This paramet

None

None

None

None

None

None

Set this par

None

None

None

None

Each layer h

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

Because the

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

If "MR.Prepr

This parame

When this p

None

None

RADIO_PERFORMACE_IMPACTIf this parameter is set to a smaller value, the handovers due to bad downlink quality may increase, thus decreasing the handover success rate. If this parameter is set to a greater value, handovers due to bad downlink quality are less possible to occur, thus increasing the call drop rate.

None

If this parameter is set to a smaller value, the handovers due to bad uplink quality may increase, thus decreasing the handover success rate. If this parameter is set to a greater value, handovers due to bad uplink quality are less possible to occur, thus increasing the call drop rate.

None

None

None

If this parameter is set to a smaller value, the handovers due to bad downlink quality may increase, thus decreasing the handover success rate. If this parameter is set to a greater value, handovers due to bad downlink quality are less possible to occur, thus increasing the call drop rate.

If this parameter is set to a smaller value, the handovers due to bad uplink quality may increase, thus decreasing the handover success rate. If this parameter is set to a greater value, handovers due to bad uplink quality are less possible to occur, thus increasing the call drop rate.

The smaller the value of this parameter is, the more MSs select a neighboring cell in directed retry.

The smaller the value of this parameter is, the more MSs select a neighboring cell in directed retry.

The setting of this parameter affects the access delay of parts of MSs.

If this parameter is set to YES, the voice quality is enhanced and the handover times is reduced, but the call access delay is prolonged. The call access delay is affected by both the setting of "Maximum Assigning Duration" and the duration for waiting MRs on the SDCCH. The maximum delay is the value of "Maximum

If this switch is set to ON, the call access delay may be prolonged, but the performance of the algorithms in which the SDCCH MRs are used are enhanced.

The greater the value of this parameter is, the longer the call access duration is, the MRs are filtered more completely. Generally, you are advised to set this parameter to a value smaller than 20.

None

None

None

If this parameter is set to YES, the probability of MS handover to the cell in the direction opposite to the moving direction during fast handover is reduced.

If this parameter is set to a great value, there are strict restrictions on the judgement of the MS moving direction.

If this parameter is set to a great value, there are strict restrictions on the judgement of the MS moving direction.

None

None

If this parameter is set to a greater value, congestion may occur in the underlaid subcell; if this parameter is set to a smaller value, congestion may occur in the overlaid subcell.

If this parameter is set to a smaller value, congestion may occur in the underlaid subcell in a short time; if this parameter is set to a greater value, congestion in the overlaid subcell is difficult to be relieved.

If this parameter is set to a greater value, congestion may occur in the underlaid subcell in a short time; if this parameter is set to a smaller value, congestion in the overlaid subcell is difficult to be relieved.

If this parameter is set to a greater value, traffic load on the underlaid subcell is increased, and thus congestion may occur in the underlaid subcell. If this parameter is set to a smaller value, traffic load on the overlaid subcell is increased, and thus congestion may occur in the overlaid subcell.

If this parameter is set to a greater value, the congestion relieving speed in the underlaid subcell is decreased. If this parameter is set to a smaller value, traffic load on the overlaid subcell is increased, and thus congestion may occur in the overlaid subcell.

If this parameter is set to a greater value, congestion in the underlaid subcell may not be relieved in time. If this parameter is set to a smaller value, many calls may be handed over from the underlaid subcell to the overlaid subcell in a shot period, thus causing network congestion in the overlaid subcell and handover failu

None

None

None

None

None

None

None

If this parameter is set to a greater value, congestion may occur in the underlaid subcell; if this parameter is set to a smaller value, assignment success rate may be decreased.

If this parameter is set to a greater value, assignment success rate may be decreased; if this parameter is set to a smaller value, congestion may occur in the underlaid subcell.

None

None

None

None

None

None

None

If this parameter is set to a greater value, the traffic volume during busy time may be decreased.If this parameter is set to a smaller value, the voice quality may be decreased.If this parameter is set to a greater value, the traffic volume during busy time may be decreased.If this parameter is set to a smaller value, the voice quality may be decreased.

If this parameter is set to a greater value, the BCCH may idle while non-BCCHs are congested, thus affecting the traffic volume during busy times and the access success rate.If this parameter is set to a smaller value, unnecessary handovers may be performed, thus the voice quality is decreased.

None

None

None

None

If this parameter is set to a greater value, call drop rate may be increased and congestion may occur in the overlaid subcell; if this parameter is set to a smaller value, handover success rate may be decreased.

If this parameter is set to a greater value, congestion may occur in the underlaid subcell; if this parameter is set to a smaller value, handover success rate may be decreased.

None

None

None

None

If this parameter is set to a greater value, congestion in the underlaid subcell is difficult to be relieved; if this parameter is set to a smaller value, congestion may occur in the overlaid subcell in a short time.

If this parameter is set to a greater value, congestion may occur in the overlaid subcell in a short time; if this parameter is set to a smaller value, congestion in the underlaid subcell is difficult to be relieved.

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

If this parameter is set to a greater value, congestion may occur in the underlaid subcell.If this parameter is set to a smaller value, ping-pong handovers may occur.

If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, call drops may occur because the handover may not be performed timely.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, call drops may occur because the handover may not be performed timely.

If this parameter is set to a greater value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.

None

None

None

None

None

None

None

None

None

If this parameter is set to a smaller value, call drops may occur due to delayed handover; if this parameter is set to a greater value, unnecessary handover may be performed, thus affecting the voice quality.

None

This parameter limits the number of candidate cells. If this parameter is set to a greater value, some desired cells may be excluded from the candidate cells and call drops may occur. If this parameter is set to a smaller value, an unwanted cell may become the candidate cell, thus leading to handover failures or call drops.

This parameter limits the number of candidate cells. If this parameter is set to a greater value, some desired cells may be excluded from the candidate cells and call drops may occur. If this parameter is set to a smaller value, an unwanted cell may become the candidate cell, thus leading to handover failures or call drops.

None

None

None

None

None

None

None

None

None

If this parameter is set to a smaller value, call drops may occur due to delayed handover; if this parameter is set to a greater value, unnecessary handover may be performed, thus affecting the voice quality.

None

If this parameter is set to a smaller value, handovers may be performed frequently; if this parameter is set to a greater value, handovers may not be performed in time and call drops may occur.

None

None

If this parameter is set to a greater value, congestion may occur in the neighboring cells in a short time; if this parameter is set to a smaller value, congestion in the serving cell is difficult to be relieved.

None

If this parameter is set to a smaller value, call drops may occur or voice quality may be decreased due to delayed handover; if this parameter is set to a greater value, unnecessary handover may be performed.

None

None

If this parameter is set to a greater value, unnecessary handovers between micro cells are performed, thus affecting the voice quality. If this parameter is set to a smaller value, congestion may occur in macro cells.

None

If this parameter is set to a greater value, congestion may occur in macro cells. If this parameter is set to a smaller value, unnecessary handovers between micro cells are performed, thus affecting the voice quality.

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

If this parameter is set to a smaller value, handovers may be performed frequently; if this parameter is set to a greater value, handovers may not be performed in time and call drops may occur.

If this parameter is set to a smaller value, handovers are performed frequently; if this parameter is set to a greater value, handovers cannot be performed timely, thus leading to call drops.

None

If this parameter is set to a greater value, the handover cannot be performed in time and call drops may occur. If this parameter is set to a smaller value, unexpected handovers may be performed due to incorrect MR when the call is initially set up, thus affecting handover success rate.

If this parameter is set to a greater value, the handover cannot be performed in time and call drops may occur. If this parameter is set to a smaller value, unexpected handovers may be performed due to incorrect MR when the call is initially set up, thus affecting handover success rate.

If this parameter is set to a too small value, the corresponding cell may reject some handover requests; thus the traffic congestion on the neighboring cells with heavy traffic cannot be relieved. If this parameter is set to a too great value, the corresp

None

If this parameter is set to a greater value, it is difficult for the MS to be handed over to the original cell, thus leading to call drop when there is no suitable neighboring cell. If this parameter is set to a smaller value, the MS is likely to be handed over to the original cell again, thus leading to ping-pong handovers.

None

None

None

None

None

None

If this parameter is set to a greater value, the handover to micro cells becomes difficult, and congestion may occur in macro cells.If this parameter is set to a smaller value, more handovers may be performed, thus the voice quality is decreased.If this parameter is set to a greater value, the handover to micro cells becomes difficult, and congestion may occur in macro cells.If this parameter is set to a smaller value, more handovers may be performed, thus the voice quality is decreased.

If this parameter is set to a greater value, call drops may occur because the handover may not be performed timely.If this parameter is set to a smaller value, unnecessary handovers may be performed.

If this parameter is set to a greater value, it is difficult for the MS to be handed over to the original cell, thus leading to call drop when there is no suitable neighboring cell.If this parameter is set to a smaller value, the MS is likely to be handed over to the original cell again, thus leading to ping-pong handovers.

If this parameter is set to a greater value, downlink power insufficiency may not be solved in time, thus leading to call drops.If this parameter is set to a smaller value, unnecessary handovers may be performed, thus the voice quality is decreased.If this parameter is set to a greater value, unnecessary handovers may be performed, thus the voice quality is decreased.If this parameter is set to a smaller value, downlink power insufficiency may not be solved in time, thus leading to call drops.

None

None

None

None

None

If this parameter is set to a greater value, handover may not be performed when the downlink voice quality is bad, thus leading to call drops. If this parameter is set to a smaller value, unnecessary handovers may be performed, thus decreasing the user experience and network traffic load.

None

None

The handover decision is allowed only when the uplink receive quality is greater than or equal to the value of this parameter. Therefore, if this parameter is set to a greater value, the handovers due to no-downlink measurement report cannot be triggered.

If this parameter is set to a greater value, the handover cannot be performed in time and call drops may occur. If this parameter is set to a smaller value, the coverage area of the cell is reduced, and the traffic volume on the cell may be decreased.

If this parameter is set to a greater value, handover may not be performed when the uplink voice quality is bad, thus leading to call drops. If this parameter is set to a smaller value, unnecessary handovers may be performed, thus affecting the voice quality.

None

None

If this parameter is set to a greater value, call drops may occur due to no suitable neighboring cell for handover. If this parameter is set to a smaller value, handover success rate may be decreased.

None

None

This parameter should be set to a small value because the signaling channel seizure duration is shorter than the traffic channel seizure duration for the MS.

If this parameter is set to a greater value, the target cell for the previous handover will not be selected for the next handover, but the probability of call drop increases. If this parameter is set to a smaller value, the probability of handover failure increases.


None

None



None

None

If this parameter is set to a greater value, cell congestion may be difficult to be relieved, thus affecting the traffic volume during busy times and the access success rate. If this parameter is set to a smaller value, handover success rate may be decreased.




None

None

The switching from an intra-cell handover procedure to an assignment procedure shortens the duration of the intra-cell handover.

None

None

None

None

If this switch is turned on, AMR FR calls can be switched into AMR HR calls to relieve the network congestion, but the voice quality is decreased; if this switch is turned off, AMR FR calls cannot be switched into AMR HR calls, that is, network congestion cannot be relieved through the handover from TCHF to TCHH.

If this parameter is set to a greater value, the handover cannot be performed in time and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed, thus affecting the voice quality.

If this parameter is set to a greater value, unnecessary handovers may be performed, thus affecting the voice quality.If this parameter is set to a smaller value, the handover cannot be performed in time and call drops may occur.

If this parameter is set to a greater value, call drops may occur.If this parameter is set to a smaller value, handover may be performed frequently and the signaling load in the cell is increased.If this parameter is set to a greater value, it is difficult for the MS to be handed over to the serving cell, thus leading to call drop when there is no suitable neighboring cell.If this parameter is set to a smaller value, the MS is likely to be handed over to the serving cell again, thus leading to ping-pong handovers.If this parameter is set to a greater value, it is difficult for the MS to be handed over to the serving cell, thus leading to call drop when there is no suitable neighboring cell.If this parameter is set to a smaller value, the MS is likely to be handed over to the serving cell again, thus leading to ping-pong handovers.

If this parameter is set to a greater value, the calls cannot be handed over to TCHH in a short period when the traffic volume is increased greatly. Thus, the network congestion cannot be relieved in time. If this parameter is set to a smaller value, calls are handed over to TCHH unnecessarily, thus causing MOS loss of th

If this parameter is set to a greater value, only MSs in the center of the cell use the TCHH, thus leading to timeslot waste and the network congestion cannot be relieved in time. If this parameter is set to a smaller value, MSs at the edge of the cell and with poor quality also cannot be handed over to the TCHF, thus affecti

If this parameter is set to a greater value, MSs at the edge of the cell and with poor quality also cannot be handed over to the TCHF, thus affecting the voice quality. If this parameter is set to a smaller value, only MSs in the center of the cell use the TCHH, thus leading to timeslot waste and the network congestion cannot

None

If this parameter is set to a greater value, handover cannot be triggered even when the quality is poor, thus affecting the voice quality; if this parameter is set to a smaller value, handover is triggered even when the quality is good, thus the network congestion cannot be relieved in time.

If this parameter is set to a smaller value, calls are handed over to TCHH unnecessarily, thus causing MOS loss of the customer; if this parameter is set to a greater value, TCHF-TCHH handover is performed only when the traffic volume is high, and thus network congestion may occur.

None

None

If this parameter is set to YES, FR calls can be switched into HR calls to relieve the network congestion, but the voice quality is decreased; if this parameter is set to NO, FR calls cannot be switched into HR calls, that is, network congestion cannot be relieved through the handover from TCHF to TCHH.

If this parameter is set to a greater value, the calls cannot be handed over to TCHH in a short period when the traffic volume is increased greatly. Thus, the network congestion cannot be relieved in time. If this parameter is set to a smaller value, calls are handed over to TCHH unnecessarily, thus causing MOS loss of th

If this parameter is set to a greater value, only MSs in the center of the cell use the TCHH, thus leading to timeslot waste and the network congestion cannot be relieved in time. If this parameter is set to a smaller value, MSs at the edge of the cell and with poor quality also cannot be handed over to the TCHF, thus affecti

If this parameter is set to a greater value, MSs at the edge of the cell and with poor quality also cannot be handed over to the TCHF, thus affecting the voice quality. If this parameter is set to a smaller value, only MSs in the center of the cell use the TCHH, thus leading to timeslot waste and the network congestion cannot

None

If this parameter is set to a greater value, handover cannot be triggered even when the quality is poor, thus affecting the voice quality; if this parameter is set to a smaller value, handover is triggered even when the quality is good, thus the network congestion cannot be relieved in time.

If this parameter is set to a smaller value, calls are handed over to TCHH unnecessarily, thus causing MOS loss of the customer; if this parameter is set to a greater value, TCHF-TCHH handover is performed only when the traffic volume is high, thus network congestion may occur.

None

None

If this parameter is set to BTS_Preprocessing, signaling on the Abis interface and BSC load are decreased, thus enhancing the response speed and the network performance.

None

None

None

If this parameter is set to a greater value, the handover margin is increased in a short period and many MSs are handed over from TCHF to TCHH, thus affecting the voice quality.If this parameter is set to a smaller value, the handover margin is enlarged slowly and it takes a long time to initiate a TCHF-TCHH handover. Thus, network congestion cannot be relieved in time.If this parameter is set to a greater value, only MSs in the center of the cell can meet the handover condition. Thus, the network congestion cannot be relieved in time.If this parameter is set to a smaller value, MSs at the edge of the cell can also meet the handover condition, thus affecting the voice quality.

If this parameter is set to a greater value, the handover margin is increased in a short period and many MSs are handed over from TCHF to TCHH, thus affecting the voice quality.If this parameter is set to a smaller value, the handover margin is enlarged slowly and it takes a long time to initiate a TCHF-TCHH handover. Thus, network congestion cannot be relieved in time.If this parameter is set to a greater value, MSs at the edge of the cell can also meet the handover condition, thus affecting the voice quality.If this parameter is set to a smaller value, only MSs in the center of the cell can meet the handover condition. Thus, the network congestion cannot be relieved in time.If this parameter is set to a greater value, MSs with poor quality can also meet the handover condition, thus affecting the voice quality.If this parameter is set to a smaller value, little MSs can meet the handover condition. Thus, the network congestion cannot be relieved in time.

If this parameter is set to a greater value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a greater value, the voice quality may be decreased.If this parameter is set to a smaller value, the congestion relieving capability may be decreased.If this parameter is set to a smaller value, the duration of an AMR TCHF-TCHH handover is short after the handover is triggered. Thus, few MSs can be handed over from TCHF to TCHH, and the congestion relieving capability is decreased.If this parameter is set to a greater value, the duration of an AMR TCHF-TCHH handover is long after the handover is triggered. Thus, even the MSs on the edge of the cell are handed over from TCHF to TCHH, and the voice quality deteriorates.If this parameter is set to a greater value, the handover cannot be performed in time and network congestion may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, network congestion may occur because the handover may not be performed timely.If this parameter is set to a smaller value, the voice quality may be decreased.If this parameter is set to a smaller value, the handover zone is enlarged in a short time, and thus many MSs are handed over from TCHF to TCHH. If this parameter is set to a greater value, the handover zone is enlarged slowly and it takes a long time to initiate a TCHF-TCHH handover. Thus, and the congestion relieving capability is decreased.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, network congestion may occur because the handover may not be performed timely.If this parameter is set to a greater value, only an MS close to the overlaid subcell can be assigned TCHHs. Thus, timeslots are wasted. If this parameter is set to a smaller value, an MS of bad quality on the edge of the overlaid subcell cannot be handed over from TCHH to TCHF. Thus, the voice quality of the call is decreased.

If this parameter is set to a greater value, the TCHH-to-TCHF handover cannot be performed in time, thus the voice quality is decreased.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, only MSs in the center area of the overlaid subcell can be assigned TCHHs. Thus, timeslots are wasted and the congestion relieving capability is decreased.If this parameter is set to a smaller value, MSs on the edge of the overlaid subcell also use the TCHH. Thus, the voice quality of the call is decreased.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a greater value, the handover cannot be performed in time, and thus the voice quality is decreased.If this parameter is set to a greater value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, the handover cannot be performed in time, thus the voice quality is decreased or call drops may occur.

If this parameter is set to a greater value, the handover margin is increased in a short period and many MSs are handed over from TCHF to TCHH, thus affecting the voice quality.If this parameter is set to a smaller value, the handover margin is enlarged slowly and it takes a long time to initiate a TCHF-TCHH handover. Thus, the network congestion cannot be relieved in time.If this parameter is set to a greater value, only MSs in the center of the cell can meet the handover condition. Thus, the network congestion cannot be relieved in time.If this parameter is set to a smaller value, MSs at the edge of the cell can also meet the handover condition, thus affecting the voice quality.

If this parameter is set to a greater value, the handover margin is increased in a short period and many MSs are handed over from TCHF to TCHH, thus affecting the voice quality.If this parameter is set to a smaller value, the handover margin is enlarged slowly and it takes a long time to initiate a TCHF-TCHH handover. Thus, network congestion cannot be relieved in time.If this parameter is set to a greater value, MSs at the edge of the cell can also meet the handover condition, thus affecting the voice quality.If this parameter is set to a smaller value, only MSs in the center of the cell can meet the handover condition. Thus, the network congestion cannot be relieved in time.If this parameter is set to a greater value, MSs with poor quality can also meet the handover condition, thus affecting the voice quality.If this parameter is set to a smaller value, little MSs can meet the handover condition. Thus, the network congestion cannot be relieved in time.

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FEATURE_NAME IMPACT PARAMETER_IDActive Power Control Cell COMBINERLOSS

Active Power Control Cell DOUBLEANTENNAGAIN

Active Power Control Cell EXPDLRXLEV

Active Power Control Cell EXPULRXLEV

Active Power Control Cell PATHLOSS

Active Power Control Cell PWRBCDALLOWD

AMR Power Control Cell AMRBTSPWRNUM

AMR Power Control Cell AMRDLLEVFTLEN

AMR Power Control Cell AMRDLPREDLEND

AMR Power Control Cell AMRDLQHTHRED

AMR Power Control Cell AMRDLQLTHRED

AMR Power Control Cell AMRDLQUAFTLEN

AMR Power Control Cell AMRDLQUALBADTRIG

AMR Power Control Cell AMRDLQUALBADUPLEV

AMR Power Control Cell AMRDLSSHTHRED

AMR Power Control Cell AMRDLSSLTHRED

AMR Power Control Cell AMRMAXADJPCVAL

AMR Power Control Cell AMRMAXSTEP0



AMR Power Control Cell AMRMAXVALADJRX

AMR Power Control Cell AMRMRCOMPREG

AMR Power Control Cell AMRPCADJPERIOD

AMR Power Control Cell AMRQUALSTEP

AMR Power Control Cell AMRULLEVFTLEN

AMR Power Control Cell AMRULPREDLEND

AMR Power Control Cell AMRULQHTHRED

AMR Power Control Cell AMRULQLOWTHRED

AMR Power Control Cell AMRULQUAFTLEN

AMR Power Control Cell AMRULQUALBADTRIG

AMR Power Control Cell AMRULQUALBADUPLEV

AMR Power Control Cell AMRULSSHTHRED

AMR Power Control Cell AMRULSSLTHRED

Enhanced Power Control Algorithm Cell BTSPWRNUM

Enhanced Power Control Algorithm Cell DLLEVFILTLEN

Enhanced Power Control Algorithm Cell DLPREDLEND

Enhanced Power Control Algorithm Cell DLQUAFILTLEN

Enhanced Power Control Algorithm Cell DLQUALBADTRIG

Enhanced Power Control Algorithm Cell DLQUALBADUPLEV

Enhanced Power Control Algorithm Cell MAXADJPCVAL

Enhanced Power Control Algorithm Cell MAXSTEP0



Enhanced Power Control Algorithm Cell MAXVALADJRX

Enhanced Power Control Algorithm Cell MRCOMPREG

Enhanced Power Control Algorithm Cell QUALSTEP

Enhanced Power Control Algorithm Cell ULLEVFILTLEN

Enhanced Power Control Algorithm Cell ULPREDLEND

Enhanced Power Control Algorithm Cell ULQUAFILTLEN

Enhanced Power Control Algorithm Cell ULQUALBADTRIG

Enhanced Power Control Algorithm Cell ULQUALBADUPLEV

Enhanced Power Control Algorithm Cell AMRSADLUPGRADE

Enhanced Power Control Algorithm Cell DLQHIGHTHRED

Enhanced Power Control Algorithm Cell DLQLOWTHRED

Enhanced Power Control Algorithm Cell DLSSHIGHTHRED

Enhanced Power Control Algorithm Cell DLSSLOWTHRED

Enhanced Power Control Algorithm Cell PCADJPERIOD

Enhanced Power Control Algorithm Cell PWRCTRLSW

Enhanced Power Control Algorithm Cell ULQHIGHTHRED

Enhanced Power Control Algorithm Cell ULQLOWTHRED

Enhanced Power Control Algorithm Cell ULSSHIGHTHRED

Enhanced Power Control Algorithm Cell ULSSLOWTHRED

HUAWEI III Power Control Algorithm Cell AMRCALLPCALLOWED

HUAWEI III Power Control Algorithm Cell DLADJPRD

HUAWEI III Power Control Algorithm Cell DLAFSREXQUALHIGHTHRED

HUAWEI III Power Control Algorithm Cell DLAFSREXQUALLOWTHRED

HUAWEI III Power Control Algorithm Cell DLAHSREXQUALHIGHTHRED

HUAWEI III Power Control Algorithm Cell DLAHSREXQUALLOWTHRED

HUAWEI III Power Control Algorithm Cell DLFILTADJFACTOR

HUAWEI III Power Control Algorithm Cell DLFSREXQUALHIGHTHRED

HUAWEI III Power Control Algorithm Cell DLFSREXQUALLOWTHRED

HUAWEI III Power Control Algorithm Cell DLHSREXQUALHIGHTHRED

HUAWEI III Power Control Algorithm Cell DLHSREXQUALLOWTHRED

HUAWEI III Power Control Algorithm Cell DLMAXDOWNSTEP

HUAWEI III Power Control Algorithm Cell DLMAXUPSTEP

HUAWEI III Power Control Algorithm Cell DLREXLEVADJFCTR

HUAWEI III Power Control Algorithm Cell DLREXLEVEXPFLTLEN

HUAWEI III Power Control Algorithm Cell DLREXLEVHIGHTHRED

HUAWEI III Power Control Algorithm Cell DLREXLEVLOWTHRED

HUAWEI III Power Control Algorithm Cell DLREXLEVSLDWINDOW

HUAWEI III Power Control Algorithm Cell DLREXQUALADJFCTR

HUAWEI III Power Control Algorithm Cell DLREXQUALEXPFLTLEN

HUAWEI III Power Control Algorithm Cell DLREXQUALSLDWINDOW

HUAWEI III Power Control Algorithm Cell DLRXLEVPROTECTFACTOR

HUAWEI III Power Control Algorithm Cell DLRXQUALPROTECTFACTOR

HUAWEI III Power Control Algorithm Cell FINESTEPPCALLOWED

HUAWEI III Power Control Algorithm Cell MRMISSNUM

HUAWEI III Power Control Algorithm Cell NONAMRCALLPCALLOWED

HUAWEI III Power Control Algorithm Cell PWRCTRLOPTIMIZEDEN

HUAWEI III Power Control Algorithm Cell SDMRCUTNUM

HUAWEI III Power Control Algorithm Cell TCHMRCUTNUM

HUAWEI III Power Control Algorithm Cell ULADJPRD

HUAWEI III Power Control Algorithm Cell ULAFSREXQUALHIGHTHRED

HUAWEI III Power Control Algorithm Cell ULAFSREXQUALLOWTHRED

HUAWEI III Power Control Algorithm Cell ULAHSREXQUALHIGHTHRED

HUAWEI III Power Control Algorithm Cell ULAHSREXQUALLOWTHRED

HUAWEI III Power Control Algorithm Cell ULFILTADJFACTOR

HUAWEI III Power Control Algorithm Cell ULFSREXQUALHIGHTHRED

HUAWEI III Power Control Algorithm Cell ULFSREXQUALLOWTHRED

HUAWEI III Power Control Algorithm Cell ULHSREXQUALHIGHTHRED

HUAWEI III Power Control Algorithm Cell ULHSREXQUALLOWTHRED

HUAWEI III Power Control Algorithm Cell ULMAXDOWNSTEP

HUAWEI III Power Control Algorithm Cell ULMAXUPSTEP

HUAWEI III Power Control Algorithm Cell ULREXLEVADJFCTR

HUAWEI III Power Control Algorithm Cell ULREXLEVEXPFLTLEN

HUAWEI III Power Control Algorithm Cell ULREXLEVHIGHTHRED

HUAWEI III Power Control Algorithm Cell ULREXLEVLOWTHRED

HUAWEI III Power Control Algorithm Cell ULREXLEVSLDWINDOW

HUAWEI III Power Control Algorithm Cell ULREXQUALADJFCTR

HUAWEI III Power Control Algorithm Cell ULREXQUALEXPFLTLEN

HUAWEI III Power Control Algorithm Cell ULREXQUALSLDWINDOW

HUAWEI III Power Control Algorithm Cell ULRXLEVPROTECTFACTOR

HUAWEI III Power Control Algorithm Cell ULRXQUALPROTECTFACTOR

Network Support SAIC Cell SAICTHREDAPDTVALUE

Network Support SAIC Cell SAICTHREDAPDTVALUE

Network Support SAIC Cell SAICALLOWED

Power Control Cell ALPHA

Power Control Cell GAMMA

Power Control Cell NAVGI

Power Control Cell PB

Power Control Cell PCMEASCHAN

Power Control Cell TAVGT

Power Control Cell TAVGW

PARAMETER_NAME MML_COMMANDCombiner Loss SET GCELLPWRBASIC

Double Antenna Gain SET GCELLPWRBASIC

Expected DL RX_LEV SET GCELLPWRBASIC

Expected UL RX_LEV SET GCELLPWRBASIC

Path Loss of Different Frequency Band SET GCELLPWRBASIC

Power Forecast Allowed SET GCELLPWRBASIC

AMR BTS PC Class SET GCELLPWR2

AMR Filter Length for DL RX_LEV SET GCELLPWR2

AMR DL MR. Number Predicted SET GCELLPWR2

AMR DL Qual. Upper Threshold SET GCELLPWR2

AMR DL Qual. Lower Threshold SET GCELLPWR2

AMR Filter Length for DL Qual. SET GCELLPWR2

AMR DL Qual Bad Trig Threshold SET GCELLPWR2

AMR DL Qual Bad UpLEVDiff SET GCELLPWR2

AMR DL RX_LEV Upper Threshold SET GCELLPWR2

AMR DL RX_LEV Lower Threshold SET GCELLPWR2

AMR MAX Up Adj. PC Value by Qual. SET GCELLPWR2

AMR MAX Down Adj. Value Qual. Zone 0 SET GCELLPWR2



AMR MAX Up Adj. PC Value by RX_LEV SET GCELLPWR2

AMR MR. Compensation Allowed SET GCELLPWR2

AMR PC Interval SET GCELLPWR2

AMR MAX Down Adj. PC Value by Qual. SET GCELLPWR2

AMR Filter Length for UL RX_LEV SET GCELLPWR2

AMR UL MR. Number Predicted SET GCELLPWR2

AMR UL Qual. Upper Threshold SET GCELLPWR2

AMR UL Qual. Lower Threshold SET GCELLPWR2

AMR Filter Length for UL Qual SET GCELLPWR2

AMR UL Qual. Bad Trig Threshold SET GCELLPWR2

AMR UL Qual. Bad UpLEVDiff SET GCELLPWR2

AMR UL RX_LEV Upper Threshold SET GCELLPWR2

AMR UL RX_LEV Lower Threshold SET GCELLPWR2

BTS PC Class SET GCELLPWR2

Filter Length for DL RX_LEV SET GCELLPWR2

DL MR. Number Predicted SET GCELLPWR2

Filter Length for DL Qual. SET GCELLPWR2

DL Qual. Bad Trig Threshold SET GCELLPWR2

DL Qual. Bad UpLEVDiff SET GCELLPWR2

MAX Up Adj. PC Value by Qual. SET GCELLPWR2

MAX Down Adj.Value Qual.Zone 0 SET GCELLPWR2



MAX Up Adj. PC Value by RX_LEV SET GCELLPWR2

MR. Compensation Allowed SET GCELLPWR2

MAX Down Adj. PC Value by Qual. SET GCELLPWR2

Filter Length for UL RX_LEV SET GCELLPWR2

UL MR. Number Predicted SET GCELLPWR2

Filter Length for UL Qual. SET GCELLPWR2

UL Qual. Bad Trig Threshold SET GCELLPWR2

UL Qual. Bad UpLEVDiff SET GCELLPWR2

AMR SACCH Downlink Power Upgrade SET GCELLPWRBASIC

DL Qual. Upper Threshold SET GCELLPWRBASIC

DL Qual. Lower Threshold SET GCELLPWRBASIC

DL RX_LEV Upper Threshold SET GCELLPWRBASIC

DL RX_LEV Lower Threshold SET GCELLPWRBASIC

PC Interval SET GCELLPWRBASIC

Power Control Switch SET GCELLPWRBASIC

UL Qual. Upper Threshold SET GCELLPWRBASIC

UL Qual. Lower Threshold SET GCELLPWRBASIC

UL RX_LEV Upper Threshold SET GCELLPWRBASIC

UL RX_LEV Lower Threshold SET GCELLPWRBASIC

Allow III Power Control For AMR SET GCELLPWR3

PwrCtrlDLAdjPeriod SET GCELLPWR3

DLAFSRexQualHighThred SET GCELLPWR3

DLAFSRexQualLowThred SET GCELLPWR3

DLAHSRexQualHighThred SET GCELLPWR3

DLAHSRexQualLowThred SET GCELLPWR3

III DL Filter Adjust Factor SET GCELLPWR3

DLFSRexQualHighThred SET GCELLPWR3

DLFSRexQualLowThred SET GCELLPWR3

DLHSRexQualHighThred SET GCELLPWR3

DLHSRexQualLowThred SET GCELLPWR3

DLMAXDownStep SET GCELLPWR3

DLMAXUpStep SET GCELLPWR3

DLRexLevAdjustFactor SET GCELLPWR3

DLRexLevExponentFilterLen SET GCELLPWR3

DLRexLevHighThred SET GCELLPWR3

DLRexLevLowthred SET GCELLPWR3

DLRexLevSlideWindow SET GCELLPWR3

DLRexQualAdjustFactor SET GCELLPWR3

DLRexQualExponentFilterLen SET GCELLPWR3

DLRexQualSlideWindow SET GCELLPWR3

III DL RexLev Protect Factor SET GCELLPWR3

III DL RexQual Protect Factor SET GCELLPWR3

0.2dB Power Control Enable SET GCELLPWR3

MRMissNumber SET GCELLPWR3

Allow III Power Control For Non-AMR SET GCELLPWR3

III Power Control Optimized Enable SET GCELLPWR3

SdMrCutNum SET GCELLPWR3

TchMrCutNum SET GCELLPWR3

PwrCtrlULAdjPeriod SET GCELLPWR3

ULAFSRexQualHighThred SET GCELLPWR3

ULAFSRexQualLowThred SET GCELLPWR3

ULAHSRexQualHighThred SET GCELLPWR3

ULAHSRexQualLowThred SET GCELLPWR3

III UL Filter Adjust Factor SET GCELLPWR3

ULFSRexQualHighThred SET GCELLPWR3

ULFSRexQualLowThred SET GCELLPWR3

ULHSRexQualHighThred SET GCELLPWR3

ULHSRexQualLowThred SET GCELLPWR3

ULMAXDownStep SET GCELLPWR3

ULMAXUpStep SET GCELLPWR3

ULRexLevAdjustFactor SET GCELLPWR3

ULRexLevExponentFilterLen SET GCELLPWR3

ULRexLevHighThred SET GCELLPWR3

ULRexLevLowThred SET GCELLPWR3

ULRexLevSlideWindow SET GCELLPWR3

ULRexQualAdjustFactor SET GCELLPWR3

ULRexQualExponentFilterLen SET GCELLPWR3

ULRexQualSlideWindow SET GCELLPWR3

III UL RexLev Protect Factor SET GCELLPWR3

III UL RexQual Protect Factor SET GCELLPWR3

Power Control Threshold Adjust for SAIC SET GCELLPWR2

Power Control threshold Adjust for SAIC SET GCELLPWR3

Saic Allowed SET GCELLPWRBASIC

ALPHA SET GCELLPSPWPARA

GAMMA SET GCELLPSPWPARA

N_AVG_I SET GCELLPSPWPARA

Pb SET GCELLPSPWPARA

PC_MEAS_CHAN SET GCELLPSPWPARA

T_AVG_T SET GCELLPSPWPARA

T_AVG_W SET GCELLPSPWPARA

DESCRIPTIONCombined loss used to estimate the downlink power during assignment

Dual-antenna gain used to estimate the downlink power during assignment

Received signal strength at an MS expected in power forecast, which helps to compute the initial transmit power of the BTS

Received signal strength at the BTS expected in power forecast, which helps to compute the initial transmit power of an MS

Transmission loss difference between radio frequencies on different bands

Whether to allow active power control. If this parameter is set to YES, the system performs power forecast in the process of initial access assignment or service channel activation during intra-BSC handovers, and sends the forecast initial power information to the BTSs through channel activation messages. In this w

Maximum degree by which the BSC can control the power of the AMR BTS dynamically

Number of measurement reports sampled for averaging downlink AMR signal strength. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in several successive measurement reports to reflect the radio environment.

Quality level threshold for decreasing downlink AMR signal power. If the BTS transmits AMR signals at a quality level less than "AMR DL Qual. Upper Threshold", the BSC decreases the power of the BTS. If downlink receive level - "AMR MAX Down Adj. PC Value by Qual." < "AMR DL RX_LEV Lower Threshold", the BSC

Quality level threshold for increasing downlink AMR signal power. If the BTS transmits AMR signals at a quality level greater than "AMR DL Qual. Lower Threshold", the BSC increases the power of the BTS. If downlink receive level + "AMR MAX Up Adj. PC Value by Qual." > "AMR DL RX_LEV Upper Threshold", the BSC

Number of measurement reports sampled for averaging downlink AMR signal quality. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in several successive measurement reports to reflect the radio environment.

During downlink power control, if the downlink receive quality level is equal to or greater than this threshold, "AMR DL RX_LEV Upper Threshold" is increased by "AMR DL Qual Bad UpLEVDiff" to further increase the expected downlink power level.

During downlink power control, if the downlink receive quality level is equal to or greater than "AMR DL Qual Bad Trig Threshold", "AMR DL RX_LEV Upper Threshold" is increased by "AMR DL Qual Bad UpLEVDiff" to further increase the expected downlink power level.

Maximum step by which the power can be increased according to received signal quality

Maximum step by which the power can be increased according to received signal level

Minimum interval between two consecutive AMR power control commands

Maximum step by which the power can be decreased according to received signal quality

Number of measurement reports sampled for averaging uplink AMR signal strength. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in several successive measurement reports to reflect the radio environment.

Quality level threshold for decreasing the power of an uplink AMR call. If the MS transmits AMR signals at a quality level less than "AMR ULQual. Upper Threshold", the BTS decreases the power of the MS. If uplink receive level - "AMR MAX Down Adj. PC Value by Qual." < "AMR UL RX_LEV Lower Threshold", the BTS

Quality level threshold for increasing the power of an uplink AMR call. If the MS transmits AMR signals at a quality level greater than "AMR UL Qual. Lower Threshold", the BTS increases the power of the MS. If uplink receive level + "AMR MAX Up Adj. PC Value by Qual." > "AMR UL RX_LEV Upper Threshold", the BTS

Number of measurement reports sampled for averaging uplink AMR signal quality. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in several successive measurement reports to reflect the radio environment.

During uplink power control, if the uplink receive quality level is equal to or greater than this threshold, "AMR UL RX_LEV Upper Threshold" is increased by "AMR UL Qual. Bad UpLEVDiff" to further increase the expected uplink power level.

During uplink power control, if the uplink receive quality level is equal to or greater than "AMR UL Qual. Bad Trig Threshold", "AMR UL RX_LEV Upper Threshold" is increased by "AMR UL Qual. Bad UpLEVDiff" to further increase the expected uplink power level.

Maximum degree by which the BSC can control the power of the BTS dynamically

Number of measurement reports sampled for averaging downlink signal strength. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in several successive measurement reports to reflect the radio environment.

Number of measurement reports sampled for averaging downlink signal quality. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in several successive measurement reports to reflect the radio environment.

During downlink power control, if the downlink receive quality level is equal to or greater than "DL Qual, bad Trig Threshold", "DL RX_LEV Upper Threshold" is increased by "DL Qual. Bad UpLEVDiff" to further increase the expected downlink power level.

To prevent late power control to a certain degree, the power control algorithm involves a measurement report prediction filter. The BSC can sample several downlink measurement reports in a short time and filter them according to a specific weight to predict future N measurement reports.This parameter specifies the number N.

Upper threshold for downlink AMR signal strength.If the downlink received AMR signal level is greater than this threshold, a power decrease is computed. Then, the power is decreased by the least of the power decrease, maximum power adjustment step allowed by the quality zone to which the received signal quality belongs, and "AMR MAX Down Adj. PC Value by Qual.".Power decrease = downlink received signal level - "AMR DL RX_LEV Upper Threshold" + "AMR DL RX_LEV Lower Threshold"/2The maximum power adjustment step allowed by the quality zone is chosen from "AMR MAX Down Adj. Value Qual. Zone 0", "AMR MAX Down Adj. Value Qual. Zone 1", and "AMR MAX Down Adj. Value Qual. Zone 2" according to the quality zone.

Lower threshold for downlink AMR signal strength.If the downlink received AMR signal level is less than this threshold, a power increase is computed. Then, the power is increased by the least of the power increase, "AMR MAX Up Adj. PC Value by RX_LEV", and "AMR MAX Up Adj. PC Value by Qual.".Power increase = "AMR DL RX_LEV Upper Threshold" + "AMR DL RX_LEV Lower Threshold"/2 - downlink received signal level.

Maximum step by which the power can be decreased when the received signal quality belongs to quality zone 0. Huawei power control algorithm generation II classifies the received signal quality into three quality zones. The maximum step by which the power can be decreased according to signal level varies according to the quality zones.Maximum step by which the power can be decreased when the received signal quality belongs to quality zone 1. Huawei power control algorithm generation II classifies the received signal quality into three quality zones. The maximum step by which the power can be decreased according to signal level varies according to the quality zones.Maximum step by which the power can be decreased when the received signal quality belongs to quality zone 2. Huawei power control algorithm generation II classifies the received signal quality into three quality zones. The maximum step by which the power can be decreased according to signal level varies according to the quality zones.

If this parameter is set to YES, Huawei power control algorithm generation II puts a currently received measurement report into the measurement report compensation queue. Then, the algorithm records the change in the transmit power based on the MS/BTS power in the measurement report. According to the power change, the algorithm compensates the received signal level in a history measurement report after measurement report interpolation.Before making a power control decision, the BSC samples and weights the received signal level and quality in several history measurement reports. The MS/BTS transmit power may vary over these measurement reports. To ensure the accuracy of the received signal level and quality to be weighted, the power control algorithm needs to compensate the received signal level and quality in the history measurement reports where the transmit power differs from the current transmit power.

To prevent late power control to a certain degree, the power control algorithm involves a measurement report prediction filter. The BSC can sample several downlink measurement reports in a short time and then weight them to predict future N measurement reports.This parameter specifies the number N.

Upper threshold for uplink AMR signal strengthIf the uplink received AMR signal level is greater than this threshold, a power decrease is computed. Then, the power is decreased by the least of the power decrease, maximum power adjustment step allowed by the quality zone to which the received signal quality belongs, and "AMR MAX Down Adj. PC Value by Qual.".Power decrease = uplink received signal level - "AMR UL RX_LEV Upper Threshold" + "AMR UL RX_LEV Lower Threshold"/2The maximum power adjustment step allowed by the quality zone is chosen from "AMR MAX Down Adj. Value Qual. Zone 0", "AMR MAX Down Adj. Value Qual. Zone 1", and "AMR MAX Down Adj. Value Qual. Zone 2" according to the quality zone.

Lower threshold for uplink AMR signal strength.If the uplink received AMR signal level is less than this threshold, a power increase is computed. Then, the power is increased by the least of the power increase, "AMR MAX Up Adj. PC Value by RX_LEV", and "AMR MAX Up Adj. PC Value by Qual.".Power increase = "AMR UL RX_LEV Upper Threshold" + "AMR UL RX_LEV Lower Threshold"/2 - uplink received signal level.

To prevent late power control to a certain degree, the power control algorithm involves a measurement report prediction filter. The BSC can sample several downlink measurement reports in a short time and then weight them to predict future N measurement reports.This parameter specifies the number N.

During downlink power control, if the downlink receive quality level is equal to or greater than "DL Qual, bad Trig Threshold", "DL RX_LEV Upper Threshold" is increased by "DL Qual. Bad UpLEVDiff" to further increase the expected downlink power level.

Step of upward power adjustment according to the quality of the received signals

Huawei power control algorithm II divides three quality zones according to the quality of the receive signals. When the power is downwardly adjusted according to the level, the maximum downward adjustment step can vary according to the quality of the received signals. This parameter specifies the maximum step of dow



Step of upward power adjustment according to the quality of the received signals

Step of downward power adjustment according to the quality of the received signals

When the network receives measurement reports, in consideration of the accuracy of a single measurement report, the measurement values in certain measurement reports are filtered to represent the radio operating environment. This parameter specifies the number of measurement reports sampled for filtering the uplin

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number of measurement reports sampled for filtering the uplink signal quality.

In the case of power control, when the uplink receive quality is not smaller than "UL Qual. Bad Trig Threshold", the actual "UL RX_LEV Upper Threshold" is increased by "UL Qual. Bad UpLEVDiff".

In the case of power control, when the uplink receive quality is not smaller than "UL Qual. Bad Trig Threshold", the actual "UL RX_LEV Upper Threshold" is increased by "UL Qual. Bad UpLEVDiff".

Number of levels by which the BTS increases the power of an SACCH frame. This parameter is used for SACCH power control. When sending an SACCH frame, the BTS increases the power of the SACCH frame by this specified number of levels.

Quality level threshold for decreasing downlink signal power. If the BTS transmits signals at a quality level less than this threshold, the BSC decreases the power of the BTS. If downlink receive level - "MAX Down Adj. PC Value by Qual." < "DL RX_LEV Lower Threshold", however, the BSC does not adjust the transmit p

Quality level threshold for increasing downlink signal power. If the BTS transmits signals at a quality level greater than this threshold, the BSC increases the power of the BTS. If downlink receive level + "MAX Up Adj. PC Value by Qual." > "DL RX_LEV Upper Threshold", however, the BSC does not adjust the transmit po

Minimum interval between two consecutive power control commands

Whether to enable power control algorithm II or power control algorithm III

The MS transmit power is decreased only when the quality level of the MS transmit signal is smaller than the value of the parameter. If the uplink receive level - "MAX Up Adj. PC Value by Qual.]/PARA] is smaller than "UL RX_LEV Lower Threshold", the MS transmit power is not adjusted.

The MS transmit power is increased only when the quality level of the MS transmit signal is greater than the value of the parameter. If the uplink receive level + "MAX Up Adj. PC Value by Qual.]/PARA] is greater than "UL RX_LEV Upper Threshold", the MS transmit power is not adjusted.

When the uplink receive level reaches the threshold, Huawei II power control is performed.

When the uplink receive level is below the threshold, Huawei II power control is performed.

Whether to enable the III power control algorithm for AMR calls. If enabled, power control is performed on AMR calls.

Minimum interval between two consecutive downlink power control commands

If the downlink receive quality level of an AMR full rate call is greater than this parameter, the call needs to undergo Huawei power control generation III.

If the downlink receive quality level of an AMR full rate call is smaller than this parameter, the call needs to undergo Huawei power control generation III.

If the downlink receive quality level of an AMR half rate call is greater than this parameter, the call needs to undergo Huawei power control generation III.

If the downlink receive quality level of an AMR half rate call is smaller than this parameter, the call needs to undergo Huawei power control generation III.

Filter adjustment factor for downlink power control. Setting this parameter high helps to smooth the filtered values and to reduce the impact of poor measurement reports on the filtered values. Setting this parameter low helps to draw the filtered values close to the actual values and to heighten the power control effect.

Upper quality threshold for Huawei power control generation III on a full rate call. If the downlink receive quality level of a full rate call is greater than this threshold, the call needs to undergo Huawei power control generation III.

Lower quality threshold for Huawei power control generation III on a full rate call. If the downlink receive quality level of a full rate call is smaller than this threshold, the call needs to undergo Huawei power control generation III.

Upper quality threshold for Huawei power control generation III on a half rate call. If the downlink receive quality level of a half rate call is greater than this threshold, the call needs to undergo Huawei power control generation III.

Lower quality threshold for Huawei power control generation III on a half rate call. If the downlink receive quality level of a half rate call is smallter than this threshold, the call needs to undergo Huawei power control generation III.

Maximum step by which to decrease downlink power according to signal strength

Maximum step by which to increase downlink power according to signal strength

Percentage of signal strength in the factors by which to determine the downlink power control step

Length of the exponential filter for downlink signal strength. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to filter the measured values in several successive measurement reports to reflect the radio environment.

Upper receive level threshold for downlink power control. If the downlink receive level is greater than this threshold, the power of the downlink signal needs to be decreased.

Lower receive level threshold for downlink power control. If the downlink receive level is smaller than this threshold, the power of the uplink signal needs to be increased.

Length of the slide window filter for downlink signal strength. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to filter the measured values in several successive measurement reports to reflect the radio environment.

Percentage of quality level in the factors by which to determine the downlink power control step

Length of the exponential filter for downlink signal quality. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to filter the measured values in several successive measurement reports to reflect the radio environment.

Whether power control algorithm II allows measurement report compensation. When making a power control decision, the BSC retrieves a certain number of history measurement reports and performs weighted filtering on the receive level values and receive quality values in these reports, which may be obtained when different transmit powers were used by BTSs or MSs. To ensure that correct receive level values and receive quality values are used in filtering, you must compensate the receive level values and receive quality values in history measurement reports obtained when transmit powers different than the current one were used.

To compensate the delay of power adjustment, the power control algorithm implements the prediction and filtering function. In other words, the BSC samples several uplink measurement reports, performs weighted filtering, and predicts N measurement reports from the current time onwards in a short period. This parameter determines the number of uplink measurement reports predicted by the BSC. In other words, the value of this parameter equals to the previous number N.

Upper threshold for downlink signal strengthIf the downlink received signal level is greater than this threshold, a power decrease is computed. Then, the power is decreased by the least of the power decrease, maximum power adjustment step allowed by the quality zone to which the received signal quality belongs, and "MAX Down Adj. PC Value by Qual.".Power decrease = downlink received signal level - "DL RX_LEV Upper Threshold" + "AMR DL RX_LEV Lower Threshold"/2The maximum power adjustment step allowed by the quality zone is chosen from "MAX Down Adj.Value Qual.Zone 0", "MAX Down Adj.Value Qual.Zone 1", and "MAX Down Adj.Value Qual.Zone 2" according to the quality zone.

Lower threshold for downlink signal strengthIf the downlink received signal level is less than this threshold, a power increase is computed. Then, the power is increased by the least of the power increase, "MAX Up Adj. PC Value by RX_LEV", and "MAX Up Adj. PC Value by Qual.".Power increase = "DL RX_LEV Upper Threshold" + "AMR DL RX_LEV Lower Threshold"/2 - downlink received signal level

Length of the slide window filter for downlink signal quality. A single measurement report may not reflect the actual network situations accurately. Therefore, the BSC needs to filter the measured values in several successive measurement reports to reflect the radio environment.

A power control step cannot exceed the step computed according to "III DL RexLev Protect Factor" and "III DL RexQual Protect Factor".

A power control step cannot exceed the step computed according to "III DL RexLev Protect Factor" and "III DL RexQual Protect Factor".

Whether to enable 0.2 dB downlink power control. This power control function improves the power control precision.

When the number of the lost measurement reports exceeds this parameter during a power control period, the power control stops.

Whether to enable the III power control algorithm for Non-AMR calls. If enabled, power control is performed on Non-AMR calls.

Whether to enable the optimized power control algorithm III

Maximum number of discarded MRs allowed on the SDCCH in a power control period

Maximum number of discarded MRs allowed on the TCH in a power control period

Minimum interval between two consecutive uplink power control commands

Current call is an AMR full-rate call, and when the uplink receive quality is greater than the threshold, Huawei III power control is performed.

Current call is an AMR full-rate call, and when the uplink receive quality is lower than the threshold, Huawei III power control is performed.

Current call is an AMR half-rate call, and when the uplink receive quality is greater than the threshold, Huawei III power control is performed.

Current call is an AMR half-rate call, and when the uplink receive quality is lower than the threshold, Huawei III power control is performed.

Filter adjustment factor for uplink power control. If this parameter is set to a large value, the filtered values become smooth, thus reducing the impact of poor measurement reports on the filtered values. If this parameter is set to a small value, the filter values are close to the actual ones and thus the power control speed i

Current call is a full-rate call, and when the uplink receive quality is greater than the threshold, Huawei III power control is performed.

Current call is a full-rate call, and when the uplink receive quality is lower than the threshold, Huawei III power control is performed.

Current call is a half-rate call, and when the uplink receive quality is greater than the threshold, Huawei III power control is performed.

Current call is a half-rate call, and when the uplink receive quality is lower than the threshold, Huawei III power control is performed.

Maximum permissible adjustment step when the BSC decreases the uplink transmit power

Maximum permissible adjustment step when the BSC increases the uplink transmit power

Step adjustment ratio of the receive level in the uplink power control

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number of measurement reports sampled for exponent filtering of the uplink signal strength.

When the uplink receive level reaches the threshold, Huawei III power control is performed.

When the uplink receive level is lower than the threshold, Huawei III power control is performed.

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number of measurement reports sampled for slide-window filtering of the uplink signal strength.

Step adjustment ratio of the receive quality in the uplink power control

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number of measurement reports sampled for exponent filtering of the uplink signal quality.

When the network receives measurement reports, the measurement values in several straight measurement reports are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number of measurement reports sampled for slide-window filtering of the uplink signal quality.

Signal strength factor for the protective limitation on calculating the uplink power control adjustment step. The calculated step value cannot exceed the step value that is obtained on the basis of the signal strength protection factor and the signal quality protection factor.

Signal strength factor for the protective limitation on calculating the uplink power control adjustment step. The calculated step value cannot exceed the step value that is obtained on the basis of the signal strength protection factor and the signal quality protection factor.

Adjustment step of the downlink signal quality threshold in power control algorithm III for MSs that support SAIC. The network side uses a lower downlink signal quality threshold for SAIC-supported MSs in power control, thus lowering the transmit power of the corresponding BTS and reducing the interferences in the who

Adjustment step of the downlink signal quality threshold in power control algorithm III for MSs that support SAIC. The network side uses a lower downlink signal quality threshold for SAIC-supported MSs in power control, thus lowering the transmit power of the corresponding BTS and reducing the interferences in the who

Whether an MS supports the SAIC function

It is used to perform open loop power control. Alpha parameter is used by the MS to calculate the output power PCH of the uplink PDCH. This parameter is used to set the reduced class of the Tx power of the MS, in correspondence with the path loss, when the GPRS dynamic power control is enabled.

Expected signal receiving strength on the BTS side when GPRS dynamic power control is implemented

Filter consistent of the collision signal strength of power control. When sampling must be performed NAVGI times before the MS obtains the efficient measurement signal.

BTS power attenuation on the measured PBCCH

Channel used for the measured receiving power. It is used to set the measured receiving power level of the channel and control the power of the uplink.

Filter period of the signal strength in the packet transmission mode of the MS. In the packet transmission mode, the signal level filter parameter of the filter period of the signal strength for power control in the packet transmission mode. The MS in the packet transmission mode measures the downlink signal strength. T

Filter period of the signal strength in the packet idle mode of the MS. In the packet idle mode, the signal level filter parameter of the filter period of the signal strength for power control in the packet idle mode. The MS in the packet idle mode measures the downlink signal strength. This parameter is used to calculate t

GUI_VALUE_RANGE0~100

0~255

0~63

0~63

0~255

NONo, YESYes

1~16

1~20

0~3

0~7

0~7

1~20

0~7

0~63

0~63

0~63

0~32

0~30

0~30

0~30

0~32

NONo, YESYes

1~15

0~4

1~20

0~3

0~7

0~7

1~20

0~7

0~63

0~63

0~63

1~16

1~20

0~3

1~20

0~7

0~63

0~32

0~30

0~30

0~30

0~32

NONo, YESYes

0~4

1~20

0~3

1~20

0~7

0~63

0~15

0~7

0~7

0~63

0~63

1~15

PWR2Power control II, PWR3Power controlIII

0~7

0~7

0~63

0~63

OFFNot Allowed, ONAllowed

0~255

1~30

1~30

1~30

1~30

1~10

1~30

1~30

1~30

1~30

1~30

1~30

0~10

0~19

0~63

0~63

1~20

0~10

0~19

1~20

0~100

0~100

NONo, YESYes

1~255

OFFNot Allowed, ONAllowed

NONo, YESYes

0~5

0~10

0~255

1~30

1~30

1~30

1~30

1~10

1~30

1~30

1~30

1~30

1~30

1~30

0~10

0~19

0~63

0~63

1~20

0~10

0~19

1~20

0~100

0~100

0~2

0~4

NONo, YESYes

00.0, 10.1, 20.2, 30.3, 40.4, 50.5, 60.6, 70.7, 80.8, 90.9, 101.0

0~31

0~15

DB00dB, DB2-2dB, DB4-4dB, DB6-6dB, DB8-8dB, DB10-10dB, DB12-12dB, DB14-14dB, DB16-16dB, DB18-18dB, DB20-20dB, DB22-22dB, DB24-24dB, DB26-26dB, DB28-28dB, DB30-30dB

BCCHBCCH, PDCHPDCH

0~25

0~25

ACTUAL_VALUE_RANGE0~10, step:0.1

0~25.5, step:0.1

0~63

0~63

0~25.5, step:0.01

NO, YES

2~32, step:2

TCH:480~9600, step:480; SDCCH:470~9400, step:470

0~3

0~7

0~7


0~7

0~63

0~63

0~63

0~32

0~30

0~30

0~30

0~32

NO, YES

480~7200, step:480

0~4


0~3

0~7

0~7


0~7

0~63

0~63

0~63

2~32, step:2


0~3


0~7

0~63

0~32

0~30

0~30

0~30

0~32

NO, YES

0~4


0~3


0~7

0~63

0~15

0~7

0~7

0~63

0~63


PWR2, PWR3

0~7

0~7

0~63

0~63

OFF, ON


1~30

1~30

1~30

1~30

1~10

1~30

1~30

1~30

1~30

1~30

1~30

0~10


0~63

0~63


0~10



0~100

0~100

NO, YES

1~255

OFF, ON

NO, YES

0~5

0~10


1~30

1~30

1~30

1~30

1~10

1~30

1~30

1~30

1~30

1~30

1~30

0~10


0~63

0~63


0~10



0~100

0~100

0~2

0~4

NO, YES

0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10

0~31

0~15

DB0, DB2, DB4, DB6, DB8, DB10, DB12, DB14, DB16, DB18, DB20, DB22, DB24, DB26, DB28, DB30

BCCH, PDCH

0~25

0~25

UNIT DEFAULT_VALUE RECOMMENDED_VALUEdB 45 45

dB 30 30

dB 30 30

dB 30 30

dB 79 79

None NO NO

dB 16 16

ms 5 5

None 0 0

None 0 0

None 3 3

ms 5 5

None 2 2

dB 8 8

dB 33 33

dB 25 25

dB 8 8

dB 2 2

dB 0 0

dB 0 0

dB 8 8

None YES YES

ms 3 3

dB 4 4

ms 5 5

None 0 0

None 0 0

None 3 3

ms 5 5

None 3 3

dB 6 6

dB 30 30

dB 18 18

dB 16 16

ms 5 5

None 0 0

ms 5 5

None 2 2

dB 10 10

dB 8 8

dB 2 2

dB 0 0

dB 0 0

dB 8 8

None YES YES

dB 2 2

ms 5 5

None 0 0

ms 5 5

None 3 3

dB 5 5

None 0 0

None 0 0

None 2 2

dB 45 45

dB 28 28

ms 3 3

None PWR3 PWR3

None 0 0

None 3 3

dB 30 30

dB 18 18

None ON ON

ms 3 3

dB 14 14

dB 14 14

dB 16 16

dB 16 16

None 3 3

dB 16 16

dB 16 16

dB 18 18

dB 18 18

dB 4 4

dB 8 8

None 3 3

ms 3 3

dB 20 20

dB 20 20

ms 1 1

None 6 6

ms 3 3

ms 1 1

None 5 5

None 55 55

None NO NO

None 5 5

None ON ON

None NO NO

None 1 1

None 3 3

ms 3 3

dB 14 14

dB 14 14

dB 16 16

dB 16 16

None 3 3

dB 16 16

dB 16 16

dB 18 18

dB 18 18

dB 6 6

dB 8 8

None 3 3

ms 3 3

dB 18 18

dB 18 18

ms 1 1

None 6 6

ms 3 3

ms 1 1

None 6 6

None 75 75

None 1 1

None 3 3

None NO NO

None 6 6

None 12 12

None 2 2

dB DB2 DB2

None PDCH PDCH

None 10 10

None 10 10

PARAMETER_RELATIONSHIPThis parameter is valid only when "PWRBCDALLOWD" is set to YES.

This parameter is valid only when "PWRBCDALLOWD" is set to YES.




None

This parameter is valid when "PWRCTRLSW" in the "SET GCELLPWRBASIC" command is set to PWR2.


This parameter is valid when "PWRCTRLSW" in the "SET GCELLPWRBASIC" command is set to PWR2 and "DNPCEN" in the "SET GCELLBASICPARA" command is set to YES.

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "AMRDLQLTHRED" >= "AMRDLQHTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "AMRDLQLTHRED" >= "AMRDLQHTHRED".




This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "AMRDLSSHTHRED" >= "AMRDLSSLTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "AMRDLSSHTHRED" >= "AMRDLSSLTHRED".











This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "AMRULQLOWTHRED" >= "AMRULQHTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "AMRULQLOWTHRED" >= "AMRULQHTHRED".




This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "AMRULSSHTHRED" >= "AMRULSSLTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "AMRULSSHTHRED" >= "AMRULSSLTHRED".














This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2 and "UPPCEN" in "SET GCELLBASICPARA" is set to YES.





None

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "DLQLOWTHRED" >= "DLQHIGHTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "DLQLOWTHRED" >= "DLQHIGHTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "DLSSHIGHTHRED" >= "DLSSLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "DLSSHIGHTHRED" >= "DLSSLOWTHRED".


None

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "ULQLOWTHRED" >= "ULQHIGHTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "ULQLOWTHRED" >= "ULQHIGHTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "ULSSHIGHTHRED" >= "ULSSLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR2. The following condition must be met: "ULSSHIGHTHRED" >= "ULSSLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3.


This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLAFSREXQUALHIGHTHRED" >= "DLAFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLAFSREXQUALHIGHTHRED" >= "DLAFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLAHSREXQUALHIGHTHRED" >= "DLAFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLAHSREXQUALHIGHTHRED" >= "DLAFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLOPTIMIZEDEN" is set to YES.

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLFSREXQUALHIGHTHRED" >= "DLFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLFSREXQUALHIGHTHRED" >= "DLFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLHSREXQUALHIGHTHRED" >= "DLHSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLHSREXQUALHIGHTHRED" >= "DLHSREXQUALLOWTHRED".





This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLREXLEVHIGHTHRED" >= "DLREXLEVLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "DLREXLEVHIGHTHRED" >= "DLREXLEVLOWTHRED".














This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULAFSREXQUALHIGHTHRED" >= "ULAFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULAFSREXQUALHIGHTHRED" >= "ULAFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULAHSREXQUALHIGHTHRED" >= "ULAHSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULAHSREXQUALHIGHTHRED" >= "ULAHSREXQUALLOWTHRED".


This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULFSREXQUALHIGHTHRED" >= "ULFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULFSREXQUALHIGHTHRED" >= "ULFSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULHSREXQUALHIGHTHRED" >= "ULHSREXQUALLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULHSREXQUALHIGHTHRED" >= "ULHSREXQUALLOWTHRED".





This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULREXLEVHIGHTHRED" >= "ULREXLEVLOWTHRED".

This parameter is valid only when "PWRCTRLSW" in "SET GCELLPWRBASIC" is set to PWR3. The following condition must be met: "ULREXLEVHIGHTHRED" >= "ULREXLEVLOWTHRED".







This parameter is valid only when "SAICALLOWED" in "SET GCELLPWRBASIC" is set to YES.



None

None

None

None

None

None

None

CAUTIONNone

If you do not use a dual-antenna to receive signals, set this parameter to 0.

None

None

None

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RADIO_PERFORMACE_IMPACTNone

As the double antenna gain increases, the downlink power increases; as the double antenna gain decreases, the downlink power decreases.

If this parameter is set to a greater value, the effectiveness of power control is reduced, and thus the network interference can not be reduced effectively. If this parameter is set to a smaller value, call drops may occur due to excessive power control.

If this parameter is set to a greater value, the effectiveness of power control is reduced, and thus the network interference can not be reduced effectively. If this parameter is set to a smaller value, call drops may occur due to excessive power control.

None

None

If this parameter is set to a smaller value, the dynamic power adjustment range for the BTS is decreased. This may cause power waste and increase network interference when the downlink quality is good.

None

None

If this parameter is set to a smaller value, downlink power control may not be performed when the voice quality is good, thus causing the power waste and increasing the interference. If this parameter is set to a greater value, downlink power control may be performed when the voice quality is bad, thus affecting the voice

If this parameter is set to a greater value, uplink power control may not be performed when the voice quality is bad, thus affecting the voice quality. If this parameter is set to a smaller value, uplink power control may be performed when the voice quality is good, thus causing the power waste and increasing the interferenc

None

None

None

If this parameter is set to a greater value, downlink power control may not be performed when the downlink level is high, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, downlink power control may be performed when the downlink power is low, in this way, call dr

If this parameter is set to a greater value, uplink power control may be performed when the downlink level is high, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, power control may not be performed when the downlink power is low, in this way, call drops may occu

If this parameter is set to a smaller value, call drops may occur due to delayed power control; if this parameter is set to a greater value, power waste may occur and network interference may be increased.

If this parameter is set to a smaller value, fast power control cannot be realized. If this parameter is set to a greater value, the power control may be performed excessively, thus leading to call drops.



If this parameter is set to a smaller value, call drops may occur due to delayed power control; if this parameter is set to a greater value, power waste may occur and network interference may be increased.

None

If this parameter is set to a greater value, power control may not be performed in time. If this parameter is set to a smaller value, power control may be performed frequently, thus increasing the signaling load.

If this parameter is set to a smaller value, the algorithm cannot realize fast power control. If this parameter is set to a greater value, call drops may occur.

None

None



None

None

None

If this parameter is set to a greater value, power control may not be performed when the uplink level is high, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, downlink power control may be performed when the uplink power is low, in this way, call drops may occur.

If this parameter is set to a greater value, uplink power control may be performed when the uplink level is high, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, power control may not be performed when the uplink power is low, in this way, call drops may occur.

If this parameter is set to a smaller value, the range of BTS dynamic power adjustment is decreased, and thus network interference is difficult to be reduced.

None

None

None

None

None

If this parameter is set to a smaller value, call drops may occur due to delayed power control; if this parameter is set to a greater value, the power control may be performed excessively, thus leading to ping-pong power control.

If this parameter is set to a smaller value, the algorithm cannot realize fast power control. If this parameter is set to a greater value, the power control may be performed excessively, thus leading to poor quality, low level, and ping-pong power control..



If this parameter is set to a smaller value, call drops may occur due to delayed power control; if this parameter is set to a greater value, the power control may be performed excessively, thus leading to ping-pong power control.

None

If this parameter is set to a smaller value, the algorithm cannot realize fast power control. If this parameter is set to a greater value, the power control may be performed excessively, thus leading to poor quality, low level, and ping-pong power control.

None

None

None

None

None

None



If this parameter is set to a greater value, decrease power control may not be performed when the downlink level is high, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, decrease power control may be performed when the downlink power is low, in this way, call d

If this parameter is set to a greater value, increase power control may be performed when the downlink level is high, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, increase power control may not be performed when the downlink power is low, in this way, call dro

None

None

If this parameter is set to a smaller value, downward power control is not performed when the signal quality is good, thus causing power waste and increasing the interference. If this parameter is set to a greater value, downward power control is performed even though the signal quality is bad, thus affecting the speech qu

If this parameter is set to a greater value, upward power control may not be performed when the voice quality is bad, thus affecting the voice quality. If this parameter is set to a smaller value, upward power control may be performed when the voice quality is good, thus causing the power waste and increasing the interfer

If this parameter is set to a greater value, downward power control may not be performed when the voice quality is good, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, downward power control may be performed when the voice quality is bad, thus affecting the voi

If this parameter is set to a greater value, upward power control may be performed when the voice quality is good, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, upward power control may not be performed when the voice quality is bad, thus affecting the voice qua

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

If this parameter is set to a greater value, decrease power control may not be performed when the downlink level is high, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, decrease power control may be performed when the downlink power is low, in this way, call d

If this parameter is set to a greater value, increase power control may be performed when the downlink level is high, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, increase power control may not be performed when the downlink power is low, in this way, call dro

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

If this parameter is set to a greater value, downward power control may not be performed when the voice quality is good, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, downward power control may be performed when the voice quality is bad, thus affecting the voi

If this parameter is set to a greater value, upward power control may be performed when the voice quality is good, thus causing the power waste and increasing the interference. If this parameter is set to a smaller value, upward power control may not be performed when the voice quality is bad, thus affecting the voice qua

None

None

None

None

None

None

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None

None

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ATTRIBUTEEquipment

Equipment

Radio

Radio

Radio

Radio

Radio

Radio

Radio

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Radio

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Equipment

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Radio

IMPACT PARAMETER_ID PARAMETER_NAMECell BETTERCELLLASTTIME Better Cell HO Valid Time

Cell BETTERCELLSTATTIME Better Cell HO Watch Time

Cell BQLASTTIME BQ HO Valid Time

Cell BQMARGIN BQ HO Margin

Cell BQSTATTIME BQ HO Watch Time

Cell CHAINNCELLTYPE Chain Neighbour Cell Type

Cell DRHOLEVRANGE Directed Retry Handover Level Range

Cell EDGEADJLASTTIME Edge HO AdjCell Valid Time

Cell EDGEADJSTATTIME Edge HO AdjCell Watch Time

Cell HCSLASTTIME HCS HO Valid Time

Cell HCSSTATTIME HCS HO Watch Time

Cell HOLASTTIME Quick Handover Last Time

Cell HOSTATICTIME Quick Handover Static Time

Cell IBCADYNCMEASURENCELLALLOWED IBCA Dyn Measure Neighbour Cell Flag

Cell IBCANCELLFLAG IBCA Neighbor Cell Flag

Cell IBCARXLEVOFFSET IBCA RxLev Offset

Cell INTELEVHOHYST Adjacent Cell Inter-layer HO Hysteresis

Cell INTERCELLHYST Inter-cell HO Hysteresis

Cell ISCHAINNCELL Chain Neighbor Cell

Cell LEVLAST Layer HO Valid Time

Cell LEVSTAT Layer HO Watch Time

Cell MINOFFSET Min Access Level Offset

Cell PBGTLAST PBGT Valid Time

Cell PBGTMARGIN PBGT HO Threshold

Cell PBGTSTAT PBGT Watch Time

Cell SRCHOCTRLSWITCH Current HO CTRL Algorithm in Source Cell

Cell TALASTTIME TA HO Valid Time

Cell TASTATTIME TA HO Watch Time

Cell ULBQLASTTIME UL BQ HO Last Time

Cell ULBQSTATTIME UL BQ HO Static Time

Cell NBR2GNCELLID Neighbor 2G Cell Index

Cell NBR2GNCELLNAME Neighbor 2G Cell Name

Cell NBRCI Neighbour Cell CI

Cell NBRLAC Neighbour Cell LAC

Cell NBRMCC Neighbour Cell MCC

Cell NBRMNC Neighbour Cell MNC

Cell SRCCI Source Cell CI

Cell SRCLAC Source Cell LAC

Cell SRCMCC Source Cell MCC

Cell SRCMNC Source Cell MNC

MML_COMMANDADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

ADD G2GNCELL

DESCRIPTION

If "downlink level of the neighbor cell after filtering" - "downlink level of the serving cell after power control compensation" > "Inter-cell HO Hysteresis" - "BQ HO Margin" + 64, the BQ handover to the neighbor cell is triggered.

This parameter indicates the geographical location relation between the neighboring cell and the serving cell. In the BSC6900, if direction A is selected, then the reverse direction is B.

Maximum signal level difference between the neighbor cell and the serving cell for triggering directed retry

Whether to measure the IBCA neighbor cells of the serving cell dynamically. If the dynamic measurement is enabled, when a call uses a channel, the BSC sends the SACCH Modify message to modify the frequencies in the BA2 table in System Information 5, 5bis, and 5ter to the frequencies at which the IBCA neighbor c

Indicates whether this neighboring cell is the IBCA neighboring cell of the serving cell. That is, when a cell is configured as the neighboring cell of the serving cell, whether the IBCA algorithm considers the interference between the serving cell and the neighboring cell.

Estimates the receive level of the unmeasured IBCA neighboring cells. When a consecutive "IBCA Non Measurement Ncell Stat. Num" measurement reports cover less than six neighboring cells or the number of the reported neighboring cells is smaller than that of the actually configured neighboring cells, this parameter

Hysteresis value during the handovers between cells on different layers or of different priorities. This value is used to suppress inter-layer ping-pong handovers.

Reduces ping-pong handovers between cells on a same layer. This parameter is invalid when cells are on different layers.

Whether the cell is a chain neighboring cell

The triggering of inter-layer handovers must meet the P/N criteria, that is, when the condition for inter-layer handovers is met for a consecutive P seconds during N seconds, an inter-layer handover is triggered. This parameter corresponds to the P in the P/N criteria.

The triggering of inter-layer handovers must meet the P/N criteria, that is, when the condition for inter-layer handovers is met for a consecutive P seconds during N seconds, an inter-layer handover is triggered. This parameter corresponds to the N in the P/N criteria.

The triggering of PBGT handovers must meet the P/N criteria, that is, when the condition for PBGT handovers is met for a consecutive P seconds during N seconds, a PBGT handover is triggered. This parameter corresponds to the P in the P/N criteria.

PBGT handovers to a neighboring cell are allowed only when the downlink level difference between the neighboring cell and the serving cell is larger than this parameter. When the value of this parameter is smaller than 64, handovers to a neighboring cell with a lower level than the current serving cell are allowed.

The triggering of PBGT handovers must meet the P/N criteria, that is, when the condition for PBGT handovers is met for a consecutive P seconds during N seconds, a PBGT handover is triggered. This parameter corresponds to the N in the P/N criteria.

Whether the currently used handover algorithm in the source cell is HO Algorithm I or HO Algorithm II

The P/N criterion must be met for triggering a TA handover. That is, the TA handover can be triggered only if P measurement reports among N measurement reports meet the triggering conditions. This parameter corresponds to P in the P/N criterion.

The P/N criterion must be met for triggering a TA handover. That is, the TA handover can be triggered only if P measurement reports among N measurement reports meet the triggering conditions. This parameter corresponds to N in the P/N criterion.

The P/N criterion must be met for triggering a UL BQ handover. That is, the UL BQ handover can be triggered only if P measurement reports among N measurement reports meet the triggering conditions. This parameter corresponds to P in the P/N criterion.

The P/N criterion must be met for triggering a UL BQ handover. That is, the UL BQ handover can be triggered only if P measurement reports among N measurement reports meet the triggering conditions. This parameter corresponds to N in the P/N criterion.

Name of a cell

Cell ID of a neighboring cell

Local Area Code LAC of a neighboring cell

Mobile Country Code MCC of a neighboring cell

Mobile Network Code MNC of a neighboring cell

Source cell ID

Local area code LAC of the source cell

Mobile country code MCC of the source cell

Mobile network code MNC of the source cell

According to the P/N rule, if the conditions for the handover to a better cell due to interference are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number P.According to the P/N rule, if the conditions for the handover to a better cell due to interference are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number N.According to the P/N rule, if the conditions for emergency BQ handover are met in P of N measurement reports, the handover is triggered.This parameter specifies the number P.

According to the P/N rule, if the conditions for emergency BQ handover are met in P of N measurement reports, the handover is triggered.This parameter specifies the number N.

According to the P/N rule, if a neighbor cell meets the conditions for selecting the neighbor cell for edge handover in P of N measurement reports, the edge handover to the neighbor cell is triggered.This parameter specifies the number P.According to the P/N rule, if a neighbor cell meets the conditions for selecting the neighbor cell for edge handover in P of N measurement reports, the edge handover to the neighbor cell is triggered.This parameter specifies the number N.According to the P/N rule, if the conditions for the handover to a different micro cell due to fast movement are met in P of N measurement reports, the handover is triggered.This parameter specifies the number P.According to the P/N rule, if the conditions for the handover to a different micro cell due to fast movement are met in P of N measurement reports, the handover is triggered.This parameter specifies the number N.According to the P/N rule, if the conditions for fast handover are met in P of N measurement reports, the handover is triggered.This parameter specifies the number P.According to the P/N rule, if the conditions for fast handover are met in P of N measurement reports, the handover is triggered.This parameter specifies the number N.

Minimum receive level offset.An MS can be handed over to a neighboring cell only when the downlink level of the neighboring cell is greater than the sum of "Min DL level on candidate Cell" and the value of this parameter.

Uniform number of a cell index within a BSC6900, which uniquely identifies a cell.

FEATURE_NAMEHUAWEI II Handover

HUAWEI II Handover

HUAWEI II Handover

HUAWEI II Handover

Chain Cell Handover

HUAWEI II Handover

HUAWEI II Handover

HUAWEI II Handover

HUAWEI II Handover

Fast Move Handover

Fast Move Handover

IBCA Interference Based Channel Allocation



Chain Cell Handover

HUAWEI I Handover

HUAWEI I Handover

HUAWEI I Handover

HUAWEI II Handover

HUAWEI II Handover

HUAWEI II Handover

HUAWEI II Handover

Configuration Management












HUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II Handover

HUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II Handover


GUI_VALUE_RANGE1~32

1~32

1~16

0~127

1~16

QUICK_HO_NCELL_TYPE_AQUICK_HO_NCELL_TYPE_A, QUICK_HO_NCELL_TYPE_BQUICK_HO_NCELL_TYPE_B

0~128

1~32

1~32

1~16

1~16

1~32

1~32

NONo, YESYes

NONo, YESYes

0~63

0~127

0~63

NONo, YESYes

1~32

1~32

0~63

1~32

0~127

1~32

HOALGORITHM1Handover algorithm I, HOALGORITHM2Handover algorithm II

1~16

1~16

1~8

1~8

0~5047

None

0~65535

1~65533,65535

None

None

0~65535

1~65533,65535

None

None

ACTUAL_VALUE_RANGE UNIT DEFAULT_VALUE0.5~16, step:0.5 s 4

0.5~16, step:0.5 s 6

0.5~8, step:0.5 s 1

0~127 dB 69

0.5~8, step:0.5 s 1

QUICK_HO_NCELL_TYPE_A, QUICK_HO_NCELL_TYPE_B None QUICK_HO_NCELL_TYPE_A

0~128 dB 72

0.5~16, step:0.5 s 4

0.5~16, step:0.5 s 6

0.5~8, step:0.5 s 2

0.5~8, step:0.5 s 3

0.5~16, step:0.5 s 3

0.5~16, step:0.5 s 4

NO, YES None NO

NO, YES None NO

0~63 dB 4

0~127 dB 67

0~63 dB 4

NO, YES None NO

0.5~16, step:0.5 s 4

0.5~16, step:0.5 s 6

0~63 dB 0

0.5~16, step:0.5 s 4

0~127 dB 68

0.5~16, step:0.5 s 6

HOALGORITHM1, HOALGORITHM2 None HOALGORITHM1

0.5~8, step:0.5 s 1

0.5~0.8, step:0.5 s 1

0.5~4, step:0.5 s 1

0.5~4, step:0.5 s 1

0~5047 None None

1~64 characters None None

0~65535 None None

1~65533, 65535 None None



0~65535 None None

1~65533, 65535 None None



RECOMMENDED_VALUE4

6

1

69

1

QUICK_HO_NCELL_TYPE_A

72

4

6

2

3

3

4

Set this parameter to YES for the neighboring cell with co-channel interference and the neighboring cell that may cause interference; set this parameter to NO for other neighboring cells.

NO

4

67

In densely populated urban areas, the recommended value is 4; in the suburbs, the recommended value is 8.

NO

4

6

0

4

In densely populated urban areas, the recommended value is 68; in the suburbs, the recommended value is 72.

6

HOALGORITHM1

1

1

1

1

None

None

None

None

None

None

None

None

None

None

PARAMETER_RELATIONSHIPThis parameter is valid only when "BETTERCELLHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "BETTERCELLSTATTIME" >= "BETTERCELLLASTTIME".

This parameter is valid only when "BETTERCELLHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "BETTERCELLSTATTIME" >= "BETTERCELLLASTTIME".

This parameter is valid only when "BQHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "BQSTATTIME" >= "BQLASTTIME".

None

This parameter is valid only when "BQHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "BQSTATTIME" >= "BQLASTTIME".

None

None

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2 and "FRINGEHOEN" is set to YES. The following condition must be met: "EDGEADJSTATTIME" >= "EDGEADJLASTTIME".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2 and "FRINGEHOEN" is set to YES. The following condition must be met: "EDGEADJSTATTIME" >= "EDGEADJLASTTIME".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "HCSSTATTIME" >= "HCSLASTTIME".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "HCSSTATTIME" >= "HCSLASTTIME".

This parameter is valid only when "QUICKHOEN" in "SET GCELLHOBASIC" is set to YES. The following condition must be met: "HOSTATICTIME" >= "HOLASTTIME".

This parameter is valid only when "QUICKHOEN" in "SET GCELLHOBASIC" is set to YES. The following condition must be met: "HOSTATICTIME" >= "HOLASTTIME".

None

None

None

None

None

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "LEVHOEN" is set to YES. The following condition must be met: "LEVSTAT" >= "LEVLAST".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "LEVHOEN" is set to YES. The following condition must be met: "LEVSTAT" >= "LEVLAST".

This parameter is based on "HOCDCMINDWPWR" and "HOCDCMINUPPWR". Different offset can be set for different neighboring cells. The following condition must be met for a neighboring cell to be added into the candidate cell queue: Neighboring cell uplink level >= "HOCDCMINUPPWR" + "MINOFFSET"; Neig

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "PBGTHOEN" is set to YES. The following condition must be met: "PBGTSTAT" >= "PBGTLAST".

None

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM1 and "PBGTHOEN" is set to YES. The following condition must be met: "PBGTSTAT" >= "PBGTLAST".

The value of this parameter must be the same as that of "HOCTRLSWITCH" in "SET GCELLHOBASIC".

This parameter is valid only when "HOCTRLSWITCH" is set to HOALGORITHM2 and "TAHOEN" is set to YES. The following condition must be met: "TASTATTIME" >= "TALASTTIME".

This parameter is valid only when "TAHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "TASTATTIME" >= "TALASTTIME".

This parameter is valid only when "BETTERCELLHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "ULBQSTATTIME" >= "ULBQLASTTIME".

This parameter is valid only when "BETTERCELLHOEN" is set to YES and "HOCTRLSWITCH" is set to HOALGORITHM2. The following condition must be met: "ULBQSTATTIME" >= "ULBQLASTTIME".

None

None

None

None

None

None

None

None

None

None

Inter-layer HO threshold of the neighboring cell = "Inter-layer HO threshold" + "Adjacent Cell Inter-layer HO Hysteresis" - 64.The value of "Inter-layer HO threshold" can be set through "SET GCELLHOBASIC".

CAUTIONNone

None

None

When the M900/M1800 BSC is upgraded to BSC6000, this parameter needs to be set to 69. If this parameter is not set to 69 in this case, the handover algorithm supported by this parameter is invalid.

None

None

None

None

None

None

None

None

None

None

The parameter IBCA Allowed of the serving cell and the neighbor cell should be set to Yes before the configuration of this parameter.

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

RADIO_PERFORMACE_IMPACT

None

The setting of this parameter depends on the actual physical location of the chain neighboring cell. Otherwise, fast PBGT handover may fail.

None

None

None

None

None

None

None

None

None

None

None

If this parameter is set to a greater value, unnecessary handovers may be performed; if this parameter is set to a smaller value, handovers may not be performed in time and call drops may occur.

None

None

None

None

None

None

None

None

None

None

None

None

If this parameter is set to a greater value, the handover cannot be performed in time, thus the voice quality is decreased and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, handovers cannot be performed in time. Thus the voice quality is decreased and call drops may occur.If this parameter is set to a greater value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.

If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.

If this parameter is set to a greater value, the MS takes a longer time to meet the conditions for triggering the handover and the handover cannot be performed in time. Thus, call drops may occur or more handovers are triggered.If this parameter is set to a smaller value, the MS takes a shorter time to meet the conditions for triggering the handover, and thus network congestion may occur on the macro cell.If this parameter is set to a greater value, congestion may occur in the macro cell.If this parameter is set to a smaller value, the handover cannot be performed in time. Thus, call drops may occur or more handovers are triggered.If this parameter is set to a greater value, the handover cannot be performed in time and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, call drops may occur because the handover may not be performed timely.

If this parameter is set to a greater value, congestion may occur in the macro subcell;If this parameter is set to a smaller value, unnecessary handovers may be performed, thus the voice quality is decreased and ping-pong handovers may be performed.If this parameter is set to a greater value, unnecessary handovers may be performed, thus the voice quality is decreased and ping-pong handover may occur.If this parameter is set to a smaller value, congestion may occur in the macro subcell.

If this parameter is set to a greater value, the handover cannot be performed in time and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.

If this parameter is set to a greater value, the handover cannot be performed in time and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.

If this parameter is set to a greater value, the handover cannot be performed in time and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, the handover cannot be performed in time and call drops may occur.

ATTRIBUTERadio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

IMPACT PARAMETER_ID PARAMETER_NAME MML_COMMAND DESCRIPTION FEATURE_NAMECell COMSC Co-MSC ADD GEXT2GCELL Whether the BSC

Cell ISEDGESUPPORTEDGE Support in ExternADD GEXT2GCELL A service supporEGPRS

Cell ISGPRSSUPPORTGPRS Support in ExternADD GEXT2GCELL A service supporGPRS

Cell ISNC2SUPPORT NC2 Support in ExternaADD GEXT2GCELL A service supporNetwork-Controlled

Cell LAYER Layer of the cell ADD GEXT2GCELL A network basica

Cell LoadHoEnExt2G Load Handover SupportADD GEXT2GCELL Indicates that i

Cell MSRXMIN Min DL level on candidaADD GEXT2GCELL

Cell PRIOR Cell Priority ADD GEXT2GCELL This parameter c

Cell RA RAC ADD GEXT2GCELL The NS performsConfiguration Man

Cell SDPUNTIME Penalty Time on Tast ADD GEXT2GCELL Period in which

Cell SDPUNVAL Penalty on Fast Movin ADD GEXT2GCELL Level value of t

Cell BCC BCC ADD GEXT2GCELL Base station colConfiguration Man

Cell BCCH BCCH FD ADD GEXT2GCELL BCCH frequency Configuration Man



The M criteria supports setting minimum values for the downlink receive level of neighboring cells. The M criteria is met only when ,Estimated downlink level of neighboring cells >= "Min DL level on candidate Cell" + "Min Access Level Offset"Estimated uplink level of neighboring cells >= "Min UL level on candidate Cell" + "Min Access Level Offset"



GUI_VALUE_RANGE ACTUAL_VALUE_RANGE UNIT DEFAULT_VALUE RECOMMENDED_VALUENONo, YESYes NO, YES None NO NO

NONot support, YESSupNO, YES None YES YES

NONot support, YESSupNO, YES None YES YES

NONot support, YESSupNO, YES None NO NO

1, 2, 3, 4 1, 2, 3, 4 None 3 3

NONo, YESYes NO, YES None NO NO

0~63 0~63 dB 10 10

Prior-1, Prior-2, Prior-3,Prior-1, Prior-2, Prior-3, PrioNone Prior-1 Prior-1

0~255 0~255 None 0 0

0~255 0~255 s 40 40

0~63 0~63 dB 30 30

0~7 0~7 None None None

0~1023 0~1023 None None None

PARAMETER_RELATIONSHIP CAUTION RADIO_PERFORMACE_IMPACT ATTRIBUTENone None None Radio

None None None Radio



There are four network layers, thaNone None Radio


None None This parameter limits the number of Radio

This parameter, together with "LANone None Radio


None None If this parameter is set to a greate Radio

None None If this parameter is set to a greate Radio



IMPACT PARAMETER_ID PARAMETER_NAME MML_COMMANDCell ECNOOFF Ec/No Offset ADD G3GNCELL

Cell HODURT3G FDD 3G Better Cell HO Valid Time ADD G3GNCELL

Cell HODURT3GTDD TDD 3G Better Cell HO Valid Time ADD G3GNCELL

Cell HOSTAT3G FDD 3G Better Cell HO Watch Time ADD G3GNCELL

Cell HOSTAT3GTDD TDD 3G Better Cell HO Watch Time ADD G3GNCELL

Cell RSCPOFF RSCP Offset ADD G3GNCELL

Cell NBR3GNCELLID Neighbor Cell Index ADD G3GNCELL

Cell NBR3GNCELLNAME Neighbor Cell Name ADD G3GNCELL

Cell SRC3GNCELLID Source Cell Index ADD G3GNCELL

Cell SRC3GNCELLNAME Source Cell Name ADD G3GNCELL

DESCRIPTION

This parameter adjusts "Min RSCP threshold" to enable the selection of 3G candidate cells based on cell priorities

Name of a neighboring cell

Name of a source cell

As a performance counter for 3G cells, Ec/No indicates the ratio of the energy per received chip to the spectral noise power density.If the Ec/No of a 3G neighbor cell is greater than "HOECNOTH3G" plus this parameter, the neighbor cell is listed in the candidate cell queue.According to the P/N rule, if the conditions for the handover to a better 3G cell are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number P.According to the P/N rule, if the conditions for the handover to a better 3G cell are met for P seconds within N seconds, the handover is triggered.This parameter specifies the number P.According to the P/N rule, if the conditions for the handover to a better 3G cell are met in P of N measurement reports, the handover is triggered.This parameter specifies the number N.According to the P/N rule, if the conditions for the handover to a better 3G cell are met in P of N measurement reports, the handover is triggered.This parameter specifies the number N.

Uniform number of a neighboring cell index within a BSC, which uniquely identifies a cell.The value range of the index of a 3G external cell is 5048 to 8047.

A source cell index must be unique in one BSC. It is used to uniquely identify a source cell. The value of this parameter ranges from 0 to 2047.

FEATURE_NAME GUI_VALUE_RANGEGSM/WCDMA Interoperability 0~49

1~32

1~32

1~32

1~32

0~63

Configuration Management 5048~8047

Configuration Management None

Configuration Management 0~2047

Configuration Management None

HUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverHUAWEI I HandoverHUAWEI II HandoverGSM/WCDMA InteroperabilityGSM/TD-SCDMA Interoperability

ACTUAL_VALUE_RANGE UNIT DEFAULT_VALUE RECOMMENDED_VALUE0~49 dB 3 3

0.5~16, step:0.5 s 8 8

0.5~16, step:0.5 s 8 8

0.5~16, step:0.5 s 10 10

0.5~16, step:0.5 s 10 10

0~63 dB 3 3

5048~8047 None None None

1~64 characters None None None


1~64 characters None None None

PARAMETER_RELATIONSHIPA 3G neighboring cell can be added into the candidate cell queue when the following conditions are met: "INTERRATOUTBSCHOEN" is set to YES; "BET3GHOEN" is set to YES; the Ec/No of the 3G neighboring cell for a period of time is greater than the sun of "HOECNOTH3G" and "ECNOOFF".

This parameter is valid only when "BET3GHOEN" is set to YES. The following condition must be met: "HOSTAT3G" >= "HODURT3G".

This parameter is valid only when "BET3GHOEN" is set to YES. The following condition must be met: "HOSTAT3GTDD" >= "HODURT3GTDD".

This parameter is valid only when "INTERRATOUTBSCHOEN" is set to YES and "BET3GHOEN" is set to YES. The following condition must be met: "HOSTAT3G" >= "HODURT3G".

This parameter is valid only when "INTERRATOUTBSCHOEN" is set to YES and "BET3GHOEN" is set to YES. The following condition must be met: "HOSTAT3GTDD" >= "HODURT3GTDD".

A 3G cell can be added into the candidate cell queue when the following conditions are met: "INTERRATOUTBSCHOEN" is set to YES; "BET3GHOEN" is set to YES; the RSCP of the 3G cell for a period of time is greater than the sun of "HORSCPTH3G" and "RSCPOFF".

None

None

None

None

CAUTIONNone

None

None

None

None

None

None

None

None

None

RADIO_PERFORMACE_IMPACTIf this parameter is set to a greater value, the corresponding neighboring 3G cell may be difficult to become the candidate neighboring cell of the serving cell. In this way, call drops may occur because the handovers may not be performed timely. If this parameter is set to a smaller value, a call may be handed over to a neig

None

None

None

None

If this parameter is set to a greater value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a smaller value, unnecessary handovers may be performed.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a greater value, unnecessary handovers may be performed.If this parameter is set to a smaller value, the handover cannot be performed in time. Thus, the voice quality is decreased and call drops may occur.If this parameter is set to a greater value, some desired cells may be excluded from the candidate cells, thus leading to call drops.If this parameter is set to a smaller value, an unwanted cell may become a candidate cell, thus leading to handover failures.

ATTRIBUTERadio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Equipment

IMPACT PARAMETER_ID PARAMETER_NAME MML_COMMANDCell CELLLAYER Layer of the cell ADD GEXT3GCELL

Cell ECNOTHRES Ec/No Threshold for Layer Of 3G Cell ADD GEXT3GCELL

Cell FDDECQUALTHRSH PS FDD Ec/No Quality Threshold ADD GEXT3GCELL

Cell FDDRSCPQUALTHRSH PS FDD RSCP Quality Threshold ADD GEXT3GCELL

Cell LoadHoEnExt3G Load Handover Support ADD GEXT3GCELL

Cell MINECNOTHRES Min Ec/No threshold ADD GEXT3GCELL

Cell MINRSCPTHRES Min RSCP threshold ADD GEXT3GCELL

Cell RA Route Area ADD GEXT3GCELL

Cell RSCPTHRES RSCP Threshold for Layer of 3G Cell ADD GEXT3GCELL

Cell TDDRSCPQUALTHRSH PS TDD RSCP Quality Threshold ADD GEXT3GCELL

Cell RNCID RNC ID ADD GEXT3GCELL

Cell SYNCCASE Sync case ADD GEXT3GCELL

Cell UTRANCELLTYPE Utran Cell Type ADD GEXT3GCELL

DESCRIPTIONLayer of the cell. If the layer of the cell is lower, it is more likely that a handover to the cell will be triggered.

Threshold for determining the layer of the 3G neighbor cell. If the Ec/No of the 3G neighbor cell is less than this threshold, the neighbor cell is set to the lowest layer layer 5.

Minimum Ec/No of the 3G FDD cell candidate

Minimum RSCP of the 3G FDD cell candidate

Indicates that if a 3G neighboring cell supports load handovers, the BSC adds the load information of the local cells in the signaling procedures related to this neighboring cell.

Selects 3G candidate cells. If the measured value of a 3G neighboring cell is lower than this threshold, the 3G neighboring cell will be removed from among the 3G candidate cells.

Selects 3G candidate cells. If the measured value of a 3G neighboring cell is lower than this threshold, the 3G neighboring cell will be removed from among the 3G candidate cells.

The NS performs location management based on routing areas during GPRS packet services. Each routing area has a routing area identifier.

This parameter determines the layers of 3G neighboring cells. If the measured value of a 3G neighboring cell is lower than this threshold, the 3G neighboring cell is positioned at the bottom layer, that is, layer 4.

Minimum RSCP quality threshold that the TDD 3G candidate cell must reach

RNC ID of a 3G external cell. The value of this parameter must be consistent with the data configuration at the RNC.

Synchronization status. This parameter is used to identify different 3G cells. This parameter should be same with the configuration of 3G cells.

This parameter specifies the type of a 3G cell. A cell type can be Frequency Division Duplex FDD or Time Division Duplex TDD.

FEATURE_NAME

GSM/WCDMA Interoperability





GSM/TD-SCDMA Interoperability


GSM/TD-SCDMA Interoperability






GUI_VALUE_RANGE ACTUAL_VALUE_RANGE UNIT1, 2, 3, 4 1, 2, 3, 4 None

0~49 0~49 dB

0~49 0~49 dB

0~63 0~63 None


0~49 0~49 dB

0~63 0~63 dB

0~255 0~255 None

0~63 0~63 dB

0~63 0~63 None

0~4095 0~4095 None

SyncCase1Sync case 1, SyncCase2Sync case 2 SyncCase1, SyncCase2 None

FDDFDD, TDDTDD FDD, TDD None

DEFAULT_VALUE RECOMMENDED_VALUE3 3

30 30

10 10

10 10

NO NO

10 10

10 10

0 0

30 30

10 10

None None

None None

None None


None

None

None

None

None

A 3G cell can be added into the candidate cell queue when the following conditions are met: "INTERRATOUTBSCHOEN" is set to YES; "BET3GHOEN" is set to YES; the RSCP of the 3G cell for a period of time is greater than the sum of "HORSCPTH3G" and "RSCPOFF".

None

None

None

None

This parameter is valid only when "UTRANCELLTYPE" is set to TDD.

None

CAUTIONNone

None

None

None

None

None

None

None

None

None

None

None

None


None

None

None

None

None

None

None

None

None

None

If this parameter is set to a greater value, some desired cells may be excluded from the candidate cells, thus leading to call drops.If this parameter is set to a smaller value, an unwanted cell may become a candidate cell, thus leading to handover failures.If this parameter is set to a greater value, some desired cells may be excluded from the candidate cells, thus leading to call drops.If this parameter is set to a smaller value, an unwanted cell may become a candidate cell, thus leading to handover failures.

ATTRIBUTERadio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Equipment

Radio

Radio

IMPACT PARAMETER_ID PARAMETER_NAMETRX ADMSTAT Administrative State

TRX ANTPASSNO Antenna Pass No

TRX ANTPASSNO Sub-Location Group Antenna Pass No.

TRX AREDISTHD Abnormal Release Threshold

TRX ARELBASE Abnormal Release Statistic Base

TRX ARELWTHD Abnormal Warn Threshold

TRX BBDIF Up Down Balance Basic Difference

TRX BFRANGE Up Down Balance Floating Range

TRX BWTHD Up Down Balance Alarm Threshold

TRX CENDTHD Congestion End Threshold

TRX CPS Allow Dynamic Shutdown TRX

TRX CSTARTTHD Congestion Start Threshold

TRX FCETHD Flow Control End Threshold

TRX FCSTHD Flow Control Start Threshold

TRX FREQ Frequency

TRX FREQREUSEMODE Frequency Reuse Mode

TRX HOPTYPE Hop Type

TRX INHOPWROVERLOADTHRESHOLD Power Overload Threshold In Ho. In

TRX ISMAINBCCH Is Main BCCH TRX

TRX IUO Concentric Attribute

TRX MAXPDCHNUM Maximum Number of PDCH

TRX MAXTSOCP Maximum Number of Occupied Abis Timeslots

TRX NOTRASP Statistical Period of No-traffic

TRX OPTL TRX Priority

TRX OUTHOPWROVERLOADTHRESHOLD Power Overload Threshold In Ho. Out

TRX PAOPTILEVEL Priority of Shut Down TRX

TRX PL16QAM 16QAM Transmitter Power Reduce Level

TRX PL32QAM 32QAM Transmitter Power Reduce Level

TRX PL8PSK TRX 8PSK Level

TRX POWL Power Level

TRX POWT Power Type

TRX PWRSPNR Power Finetune

TRX RCVMD Receive Mode

TRX RXUCHAINNO RXU Chain No

TRX RXUIDTYPE RXU Index Type

TRX RXUNAME RXU Name

TRX RXUPOS RXU Chain Position

TRX SDFLAG Shut Down Enabled

TRX SNDMD Send Mode

TRX TCHAJFLAG TCH Rate Adjust Allow

TRX TRXID TRX ID

TRX TRXNO TRX No.

TRX TRXPN TRX Board Pass No.

TRX TRXPN Sub-Location Group TRX Board Pass No.

TRX TRXTP TRX Board Type

TRX TSPWRRESERVE Timeslot Power Reserve

TRX WLAETIME End Time of WLA Detection

TRX WLAFLAG Wireless Link Alarm Critical Permit

TRX WLARP WLA Prompting Recover Period

TRX WLASTIME Begin Time of WLA Detection

TRX WLNKALMFLAG Wireless Link Alarm Flag

MML_COMMANDSET GTRXADMSTATMandatory

ADD TRXBIND2PHYBRDMandatory

ADD BTSBINDLOCGRPOptional

SET GTRXRLALMOptional






SET GTRXFCOptional

SET GTRXDEVOptional

SET GTRXFCOptional

SET GTRXFCOptional

SET GTRXFCOptional

ADD GTRXMandatory

SET GTRXDEVOptional

SET GTRXHOPOptional

SET GTRXDEVOptional

ADD GTRXOptional

SET GTRXIUOMandatory

SET GTRXBASEOptional

SET GTRXBASEOptional


SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional





SET GTRXDEVOptional

SET GTRXDEVOptional

SET GTRXDEVOptional

ADD GTRXOptional


ADD BTSBINDLOCGRPMandatory


SET GTRXDEVOptional





SET GTRXRLALMMandatory

SET FHOMandatorySET GTRXCHANHOPMandatorySET GTRXHOPMandatorySET GTRXBASEMandatorySET GTRXCHANMandatorySET GTRXFCMandatorySET GTRXIUOMandatorySET GTRXADMSTATMandatorySET GTRXCHANADMSTATMandatoryADD GTRXMandatoryADD TRXBIND2PHYBRDMandatorySET GTRXRLALMMandatorySET GTRXDEVMandatoryADD GTRXBIND2HDLCPATHMandatorySTR BTSTSTMandatorySTR TRXBURSTTSTMandatory

DESCRIPTIONAdministrative state of the TRX

Number of the antenna feeder channel mapped to the RXU

Antenna pass No. of the RXU of a sub-location group. The parameter is configured only when the MRRU or GRRU is used in the sub-location group.

Threshold for reporting the recovery alarm for the abnormal release alarm. If the percentage of the abnormal channel releases is equal to or less than this threshold, the recovery alarm for the abnormal release alarm is reported. That is, the abnormal release alarm is cleared.

Threshold for reporting the abnormal release alarm. In a timeslot, the release statistics base, B, multiplied by the number of channels, N, is the channel release sum, S. If the percentage of the abnormal channel releases in the latest S channel releases exceeds this threshold, the abnormal release alarm is reported.

Reference difference between uplink and downlink levels. This parameter works with "Up Down Balance Floating Range" to count uplink-downlink imbalances.

Threshold for reporting the uplink-downlink imbalance alarm. If the percentage of the uplink-downlink imbalance measurement reports in the total valid measurement reports is equal to or greater than this threshold, the uplink-downlink imbalance alarm is reported.

Threshold for stopping LAPD link congestion control. This parameter cannot be set too small. If this parameter is set too small, the congestion control duration is too long, and thus the transmission capability of signaling links cannot be fully used. The difference between the congestion start and end thresholds cannot be to

This parameter specifies whether to allow the BSC6900 to enable or disable the power amplifier of a TRX based on the traffic volume.

Threshold for starting LAPD link congestion control. This parameter cannot be set too high. If this parameter is set too high, the signaling link may be congested before congestion control is started. The congestion start and end thresholds cannot be set too low. If they are set too low, congestion control may be started fre

Threshold for stopping RSL flow control. If the occupancy of the LAPD queue is less than this threshold, the BSC6900 stops flow control.

Threshold for starting RSL flow control. If the occupancy of the LAPD queue is greater than this threshold, the BSC6900 starts flow control.

Frequency of the TRX

Frequency multiplexing mode in the TRX. To enable a loose frequency multiplexing mode such as 4x3 multiplexing, set this parameter to LOOSE. To enable a tight frequency multiplexing mode such as 1x3 or 1x1, set this parameter to TIGHT.

Power overload threshold for triggering incoming handover to the TRX under the prerequisite that the power amplifier of the TRX provides the maximum output power.

Whether to enable the TRX to carry the main BCCH in the cell

Concentric cell attributes of TRX. If the cell where a TRX is located is configured as a concentric cell, set this parameter to OVERLAID or UNDERLAID as required. If the cell where a TRX is located is not configured as a concentric cell, the default value of this parameter is NONE.

Maximum number of PDCHs that can be assigned in the TRX

Maximum number of 16 kbit/s Abis timeslots that the PDCHs can use in the TRX

Maximum number of measurement periods in which there is no traffic. If the number of measurement periods in which there is no traffic reaches this parameter, the BTS reports an alarm indicating that there is no traffic.

This parameter specifies the TRX priority in channel assignment. The smaller this parameter is, the higher the TRX priority is. For two TRXs with other conditions identical, channels on the TRX with higher priority are preferentially assigned.

Power overload threshold for triggering outgoing handover from the TRX under the prerequisite that the power amplifier of the TRX provides the maximum output power. If the power overload exceeds this threshold, the TRX triggers outgoing handover for lack of power.

Priority level at which the BSC shuts down the power amplifier of the TRX when the intelligent shutdown function is enabled. If this parameter is set smaller, the priority level is higher, the power amplifier of the TRX is shut down earlier.

Power attenuation level of all the other timeslots of the BCCH except for timeslot 7 in 16QAM. The attenuation level ranges from 0 to 50, with the step of 0.2 dB. When the EDGE TRX sends signals in 16QAM, the transmit power must be lower than the mean power in GMSK.

Power attenuation level of all the other timeslots of the BCCH except for timeslot 7 in 32QAM. The attenuation level ranges from 0 to 50, with the step of 0.2 dB. When the EDGE TRX sends signals in 32QAM, the transmit power must be lower than the mean power in GMSK.

Power attenuation level of the EDGE TRX. There are 50 power attenuation levels. At each level, the power is attenuated by 0.2 dB. The spectrum requirements are met only when the power of an EDGE transceiver for transmitting 8PSK signals is lower than the average power for GMSK modulation.

This parameter specifies the maximum transmit power supported by the power amplifier of the TRX. The macro BTS and the mini BTS support different power levels.

Finetune of the TRX power. During the static finetune of the TRX power, the BSC adjusts the TRX power at a step of 0.2 dB. In some scenarios, the losses vary depending on the tributaries where the power is combined, and the power difference before and after the power output is not an integral multiple of 2 dB. As a re

Number of the RXU chain to which the RXU belongs

Index type of the RXU

Name of the RXU

Position number of the RXU on the RXU chain

This parameter specifies whether the BSC6900 automatically shuts down the power amplifier of the TRX to save power when the BTS is powered by batteries after a power failure.

Whether to allow the cell to dynamically change a channel from full rate to half rate or from half rate to full rate. If this parameter is set to YES, the conversion is allowed; if the parameter is set to NO, the conversion is not allowed and the changed channel is restored to the previous rate mode. In addition, this paramet

If the percentage of the abnormal channel releases in the latest S channel releases exceeds the Abnormal Warn Threshold, the abnormal release alarm is reported.If the percentage of the abnormal channel releases in the latest S channel releases is equal to or less than the Abnormal Release Threshold, the recovery alarm for the abnormal release alarm is reported. That is, the abnormal release alarm is cleared.

Allowed fluctuation of the difference between uplink and downlink levels relative to the reference difference. If the difference between uplink and downlink levels is outside the fluctuation range, the uplink and downlink are considered imbalanced.For example, assume that the Up Down Balance Basic Difference is set to 8 and that the Up Down Balance Floating Range is set to 30. If the difference between uplink and downlink levels is greater than 38 = 8 + 30 or less than -22 = 8 - 30, the uplink and downlink are considered imbalanced. If the difference between uplink and downlink levels is between -22 and 38, the uplink and downlink are considered balanced.

Frequency hopping mode of the TRX. Frequency hopping assists in interference averaging and frequency diversity.If this parameter is set to RF_FH, the TX and RX parts of the TRX take part in the frequency hopping. In this case, the number of hopping frequencies can exceed the number of TRXs in the cell. If this parameter is set to BaseBand_FH, each transmitter works at a fixed frequency. That is, the TX part does not take part in the frequency hopping. The baseband signals are switched for the frequency-hopping transmission. The RX part, however, takes part in the frequency hopping.

This parameter specifies the transmit power level of the TRX. The greater this parameter is, the smaller the transmit power is. When this parameter is set to "0", the transmit power level of the TRX is the greatest. Each time this parameter increases by one level, the transmit power reduces by 2 dB.For different types of BTSs, the value range of this parameter is different.BTS3X: 0-10BTS3001C: 0-13BTS3002C: 0-10Double-transceiver BTSs BTS3012,BTS3012AE,BTS3006C: 0-10DBS3900 GSM, BTS3900 GSM, BTS3900A GSM: 0-10.

The BTS3012, BTS3012AE, BTS3012II, BTS3006C, and BTS3002E do not support Main Diversity.The DBS3900 GSM and BTS3900 GSM support Four Diversity Receiver and Main Diversity.

The DBS3900 GSM GRRU does not support Wide Band Combining, Transmitter Independent or Combining, Power Booster Technology, or DPBT.The BTS3900 GSM and BTS3900A GSM do not support Transmitter Independent or Wide Band Combining.

Index of a TRX, uniquely identifying a TRX in a BSC6900.

Number of a TRX in a BTS. The number of a TRX is unique in a BTS.

Number of the channel bound to the TRX on the TRX board. TRX Pass No. of the DTRU/DRRU/BTS3900B of the BTS in separate mode must be 0 or 1; TRX Pass No. of the QTRU/MRRU/MRFU/GRFU/BTS3900E of the BTS in separate mode must be 0 to 5; TRX Pass No. of the GRRU of the BTS in separate mode shoul

TRX board pass number in the sub-location group to which the TRX of the main location group is bound

Type of the TRX board bound to the TRX

Maximum degree by which the output power of the multi-density TRX board can exceed the maximum output power within a short time

Time when the BTS stops checking for a radio link alarm. If this time is up, the BTS stops checking for or reporting a radio link alarm until the next alarm detection start time is up.

Whether to enable the BTS to report a major radio link alarm. If this parameter is set to YES, the BTS reports a major radio link alarm when a radio link warning is not cleared within "WLARP". If this parameter is set to NO, the BTS does not report any major radio link alarm.

Period for clearing a radio link warning. If a radio link warning is cleared within this period, the BTS reports the recovery alarm for the warning. If a radio link warning is not cleared within this period, the BTS determines whether to report a major radio link alarm according to "WLAFLAG".

Time when the BTS starts to check for a radio link alarm. If this time is up, the BTS starts to check for and report a radio link alarm.

Whether to enable the BSC to deliver radio link alarm parameters to the BTS. If this parameter is set to YES, the BSC delivers the radio link alarm parameters to the BTS. If this parameter is set to NO, the BSC does not deliver the radio link alarm parameters to the BTS.

FEATURE_NAMEO&M of BTS

O&M of BTS

Multi-site Cell

Radio Dedicated Channel Management



GSM Flow Control

TRX Power Amplifier Intelligent Shutdown

GSM Flow Control

GSM Flow Control

GSM Flow Control

Frequency Band


Frequency Hopping RF hopping, baseband hopping

Enhanced Channel Assignment Algorithm


Concentric Cell

PDCH Dynamic Adjustment

Flex Abis




TRX Power Amplifier Intelligent Shutdown

EGPRS

EGPRS

EGPRS





O&M of BTS

O&M of BTS

O&M of BTS

O&M of BTS

Active Backup Power Control


Dynamic Adjustment Between FR and HR

Processing of Measurement ReportPre-processing of Measurement Report

Processing of Measurement ReportPre-processing of Measurement ReportProcessing of Measurement ReportPre-processing of Measurement Report



O&M of BTS

Multi-site Cell

O&M of BTS


O&M of BTS

O&M of BTS

O&M of BTS

O&M of BTS

O&M of BTS

GUI_VALUE_RANGELockLock, UnlockUnlock, ShutdownShutdown

AA, BB

AA, BB

0~80

5~126

5~100

0~254

10~254

20~100

20~90

NONo, YESYes

30~100

0~100

0~100

0~1023

LOOSELoose, TIGHTTight

NO_FHNo Frequency Hopping, BaseBand_FHBaseband Frequency Hopping, RF_FHRF Frequency Hopping

0~50

NONo, YESYes

OVERLAIDOverlaid Subcell, UNDERLAIDUnderlaid Subcell, NONENone

0~8

0~32

1~255

L0Level0, L1Level1, L2Level2, L3Level3, L4Level4, L5Level5, L6Level6, L7Level7

0~50

L0Level0, L1Level1, L2Level2, L3Level3, L4Level4, L5Level5, L6Level6, L7Level7

0~50

0~50

0~50

0~13

80W80W, 63W63W, 60W60W, 55W55W, 50W50W, 45W45W, 40W40W, 31W31W, 30W30W, 27W27W, 26W26W, 25W25W, 24W24W, 21W21W, 20W20W, 19W19W, 18W18W, 17W17W, 16W16W, 15W15W, 14W14W, 13_3W13.3W, 13W13W, 12_5W12.5W, 12W12W, 11_5W11.5W, 11W11W, 10W10W, 9_5W9.5W, 9

DB00.0dB, DB2-0.2dB, DB4-0.4dB, DB6-0.6dB, DB8-0.8dB, DB10-1.0dB, DB12-1.2dB, DB14-1.4dB, DB16-1.6dB, DB18-1.8dB, DefaultDefault

INDEPENDENTIndependent Receiver, DIVIDINGDividing Receiver, FOURDIVERSITYFour Diversity Receiver, MAINDIVERSITYMain Diversity, NONENone

0~249

RXUNAMEBy RXU Name, RXUPOSBy RXU Position No, SRNSNBy Subrack No

None

1~6

DISABLEDisable, ENABLEEnable

NOCOMBNo Combination, PBTPBT, WBANDCOMBWideband Combination, DIVERSITYTransmit Diversity, DDIVERSITYDynamic Transmit Diversity, DPBTDPBT, DTICTransmit Independency or Combination, NONEnone

NONo, YESYes

0~3071

0~71

0~7

0~7

TRXTRX, TRUTRU/DTRU, QTRUQTRU, DRRUDRRU, DRFUDRFU, MRRUMRRU, MRFUMRFU, GRFUGRFU, GRRUGRRU, BTS3900BBTS3900B, BTS3900EBTS3900E

0~50

0~24

NONo, YESYes

1~255

0~24

NONo, YESYes

ACTUAL_VALUE_RANGELock, Unlock, Shutdown

A, B

A, B

0~80

5~126

5~100

0~254

10~254

20~100

20~90

NO, YES

30~100

0~100

0~100

0~1023

LOOSE, TIGHT

NO_FH, BaseBand_FH, RF_FH

0~50

NO, YES

OVERLAID, UNDERLAID, NONE

0~8

0~32

5~1275, step:5

L0, L1, L2, L3, L4, L5, L6, L7

0~50

L0, L1, L2, L3, L4, L5, L6, L7

0~10, step:0.2

0~10, step:0.2

0~10, step:0.2

0~13

80W, 63W, 60W, 55W, 50W, 45W, 40W, 31W, 30W, 27W, 26W, 25W, 24W, 21W, 20W, 19W, 18W, 17W, 16W, 15W, 14W, 13_3W, 13W, 12_5W, 12W, 11_5W, 11W, 10W, 9_5W, 9W, 8_5W, 8W, 7_5W, 7W, 6_5W, 6W, 5_5W, 5W, 4_5W, 4W, 3_7W, 3_1W, 3W, 2_5W, 2W, 200mW, DEFAULT

DB0, DB2, DB4, DB6, DB8, DB10, DB12, DB14, DB16, DB18, Default

INDEPENDENT, DIVIDING, FOURDIVERSITY, MAINDIVERSITY, NONE

0~249

RXUNAME, RXUPOS, SRNSN

1~64 characters

1~6

DISABLE, ENABLE

NOCOMB, PBT, WBANDCOMB, DIVERSITY, DDIVERSITY, DPBT, DTIC, NONE

NO, YES

0~3071

0~71

0~7

0~7

TRX, TRU, QTRU, DRRU, DRFU, MRRU, MRFU, GRFU, GRRU, BTS3900B, BTS3900E

0~50

0~24

NO, YES

5~1275, step:5

0~24

NO, YES

UNIT DEFAULT_VALUENone Unlock

None None

None None

per cent 50

None 100

per cent 100

None 8

None 30

per cent 80

per cent 80

None NO

per cent 90

per cent 55

per cent 85

None None

None LOOSE

None NO_FH

W 8

None NO

None NONE

None 8

None 32

min 48

None L0

W 15

None L0

dB 0

dB 0

dB 0

None 0

None DEFAULT

None Default

None NONE

None None

None None

None None

None None

None ENABLE

None NONE

None NO

None None

None None

None None

None None

None None

W 20

h 22

None NO

min 12

h 8

None NO

RECOMMENDED_VALUEUnlock

None

None

50

100

100

8

30

80

80

NO

90

75

85

None

LOOSE

NO_FH

8

NO

NONE

8

32

48

L0

15

L0

0

0

0

0

None

Default

NONE

None

None

None

None

ENABLE

NONE

NO

None

None

None

None

None

22

NO

12

8

NO

If the board is configured with five TRXs, the recommended value of this parameter is 50. If the board is configured with six TRXs, the recommended value of this parameter is 48.


None

None

This parameter is valid only when "WLNKALMFLAG" is set to YES.






None

This parameter is valid only when "BSCDynSwitchTrxPAAllow" in "SET BSCDSTPA" and "DYNOpenTrxPower" in "SET GCELLBASICPARA" are set to YES.

None

None

None

None

None

This parameter depends on "FHMODE" in "SET GCELLHOPTP". This parameter can be set to BaseBand_FH only when "FHMODE" is set to BaseBand_FH or Hybrid_FH. This parameter can be set to RF_FH only when "FHMODE" is set to RF_FH or Hybrid_FH.

None

None

This parameter is valid only when "IUOTP" in "MOD GCELL" is set to Concentric_cell.

None

None


This parameter is valid only when "TRXPRIALLOW" is set to YES.

None

This parameter is valid only when "BSCDynSwitchTrxPAAllow" in "SET BSCDSTPA","DYNOpenTrxPower" in "SET GCELLBASICPARA" and "CPS" are set to YES.

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None





None

CAUTIONNone

The parameter cannot be modified.

None

None

None

None

None

None

None

None

This parameter cannot be set to YES for the TRX that carries the main BCCH.

None

None

None

The value range of this parameter depends on the frequency range of the cell band.

None

After this parameter is modified, the services in the cell are handed over forcedly. The cell is reset after all the handover succeeds or after ten seconds.

This parameter must be equal to or less than "OUTHOPWROVERLOADTHRESHOLD" to protect the other timeslots/cells from overload and underpower.

Each cell can be configured with only one TRX that carries the main BCCH.

None

None

None

None

None

None

None

This parameter is valid for the EDGE TRX only.

This parameter is valid for the EDGE TRX only.

This parameter is valid only for EDGE TRXs and is invalid for ordinary TRXs.

None

None

None

None





None

None

None


None




None

None

None

None

None

None


None

None

None

None

None

None

None

None

If this parameter is set too small, the congestion control duration is too long, and thus the transmission capability of signaling links cannot be fully used. If the difference between the values of "CSTARTTHD" and "CENDTHD" is small, the signaling link is unstable and congestion control is performed frequently. In this

None

None

None

None

The setting of this parameter must be consistent with the actual frequency reuse pattern of the TRX. Otherwise, the speech quality will be bad.

If this parameter is set to "NO_FH", the anti-interference capability of the TRX is decreased.

If the value of this parameter is set too high, the power load of other timeslots or cells is burdened.

None

None

None

None

None

None

If the value of this parameter is set too small, frequent handovers are likely to occur.

None

None

None

None

None

None

If the value of this parameter is set inappropriately high or small, the BTS cabinet top output power is inconsistent with the TRX output power.

None

None

None

None

None

The TRX is shut down automatically, and the capacity of the cell is decreased.

None

None

If the value of this parameter is too high, the congestion control is delayed, which leads to deteriorated performance on the signaling link and certain messages may be lost.If the difference between the values of "CSTARTTHD" and "CENDTHD" is small, the signaling link is unstable and congestion control is performed frequently. In this case, the paging messages may be abandoned.

None

None

None

Not involved

None

None

None

None

None

None

None

ATTRIBUTEEquipment

Equipment

Equipment

Equipment

Equipment

Equipment

Equipment

Equipment

Equipment

Equipment

Equipment

Equipment

Equipment

Equipment

Radio

Radio

Radio

Equipment

Radio

Radio

Radio

Equipment

Equipment

Radio

Equipment

Equipment

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Equipment

Equipment

Equipment

Equipment

Equipment

Radio

Radio

Radio

Equipment

Equipment

Equipment

Equipment

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Equipment





FEATURE_NAME IMPACTClass11 DTM Cell

Dual Carriers in Downlink Cell

EGPRS Cell

Cell

HMC DTM Cell

Network Assisted Cell Change NACC Cell

Cell


Packet SI Status Cell

GPRS Cell

PS Handover Cell

PS Handover Cell

Latency Reduction Cell

DTM Cell

DTM Cell

GPRS Cell

GPRS Cell

Dynamically Adjusting the Uplink MCS Coding Cell

EGPRS Cell

EGPRS Cell

Downlink EGPRS2-A Cell


EGPRS Cell

EGPRS Cell

EGPRS Cell

Uplink EGPRS2-A Cell

Uplink EGPRS2-A Cell

EGPRS Cell


GPRS Cell



Cell

GPRS Cell

GPRS Cell

GPRS Cell

PDCH Dynamic Adjustment Cell

MSRD Cell




11-Bit EGPRS Access Cell

Coding Scheme Cell

Coding Scheme Cell

Coding Scheme Cell

Coding Scheme Cell

Coding Scheme Cell

Uplink EGPRS2-ADownlink EGPRS2-A

Network-Controlled Cell Reselection NC2Network Assisted Cell Change NACC

Compact BTS Automatic Configuration and Planning

Coding Scheme Cell

Coding Scheme Cell

Coding Scheme Cell

CS-3/CS-4 Cell

CS-3/CS-4 Cell

CS-3/CS-4 Cell

CS-3/CS-4 Cell

CS-3/CS-4 Cell

CS-3/CS-4 Cell

CS-3/CS-4 Cell

CS-3/CS-4 Cell





EGPRS Cell

Extended Uplink TBF Cell




GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell

GPRS Cell










PARAMETER_ID PARAMETER_NAME MML_COMMANDCLASS11DTM Support Class11 DTM SET GCELLGPRS

DLDCSPT Support Downlink Dual-Carrier SET GCELLGPRS

EDGE EDGE SET GCELLGPRS

EGPRS2A EGPRS2-A SET GCELLGPRS

HMCDTM Support HMC DTM SET GCELLGPRS

NACCSPT Support NACC SET GCELLGPRS

NBRSPT64 Support 64 Neighbour Cells SET GCELLGPRS

NC2SPT Support NC2 SET GCELLGPRS

PKTSI PACKET SI SET GCELLGPRS

RA Routing Area SET GCELLGPRS

SPTINTERRATINBSCPSHO Support In Inter-RAT Inter-cell PS Handover SET GCELLGPRS

SPTINTERRATOUTBSCPSHO Support Out Inter-RAT Inter-Cell PS Handover SET GCELLGPRS

SPTREDUCELATENCY Support Reduced Latency Capability SET GCELLGPRS

SUPPORTDTM Support DTM SET GCELLGPRS

SUPPORTENDTM Support Enhanced DTM SET GCELLGPRS

GPRS GPRS SET GCELLGPRS

PCUNO PCU No. SET GCELLGPRS

ADJUSTULMCSTYPE Support EGPRS Uplink MCS Dynamic Adjust SET GCELLEGPRSP

BEPPERIOD Bep Period SET GCELLEGPRSP

DNDEFAULTMCS Downlink Default MCS Type SET GCELLEGPRSP

DNE2ADEFAULTMCS Downlink EGPRS2-A Default MCS Type SET GCELLEGPRSP

DNE2AFIXMCS Downlink EGPRS2-A Fixed MCS Type SET GCELLEGPRSP

DNFIXMCS Downlink Fixed MCS Type SET GCELLEGPRSP

LQCMODE Link Quality Control Mode SET GCELLEGPRSP

UPDEFAULTMCS Uplink Default MCS Type SET GCELLEGPRSP

UPE2ADEFAULTMCS Uplink EGPRS2-A Default MCS Type SET GCELLEGPRSP

UPE2AFIXMCS Uplink EGPRS2-A Fixed MCS Type SET GCELLEGPRSP

UPFIXMCS Uplink Fixed MCS Type SET GCELLEGPRSP

BVCI PTPBVC Identifier ADD GCELLQUICKS

GPRS Support GPRS ADD GCELLQUICKS

NCC NCC ADD GCELLQUICKS

NSEI NSE Identifier ADD GCELLQUICKS

RA Route Area ADD GCELLQUICKS

C31HYST GPRS Cell Reselect Hysteresis Applied to C31 CriSET GCELLRESELE

C32QUAL Exceptional Rule for GPRS Reselect Offset SET GCELLRESELE

GPRSCELLRESELECTHYESTERGPRS Cell Reselect Hysteresis SET GCELLRESELE

PDCHUPLEV PDCH Uplink Multiplex Threshold SET GCELLPSCHM

MSRDPDCHLEV MSRD PDCH Multiplex Threshold SET GCELLPSCHM

PDCHDWNLEV PDCH Downlink Multiplex Threshold SET GCELLPSCHM

PDCHREFORMING PDCH Reforming SET GCELLPSCHM

MAXPDCHRATE Maximum Rate Threshold of PDCHs in a Cell SET GCELLPSCHM

EGPRS11BITCHANREQ Support 11BIT EGPRS Access SET GCELLPSBASE

DNDEFAULTCS Downlink Default CS Type SET GCELLPSCS

DNFIXCS Downlink Fixed CS Type SET GCELLPSCS

DNTHDCSDEGRADE1 Downlink TBF Threshold from CS2 to CS1 SET GCELLPSCS

DNTHDCSUPGRADE1 Downlink TBF Threshold from CS1 to CS2 SET GCELLPSCS

UPDEFAULTCS Uplink Default CS Type SET GCELLPSCS

UPFIXCS Uplink Fixed CS Type SET GCELLPSCS

UPTHDCSDEGRADE1 Uplink TBF Threshold from CS2 to CS1 SET GCELLPSCS

UPTHDCSUPGRADE1 Uplink TBF Threshold from CS1 to CS2 SET GCELLPSCS









DIVERT16QAMDELAY Diversity Transmitter 16QAM Delay SET GCELLBASICP

DIVERT32QAMDELAY Diversity Transmitter 32QAM Delay SET GCELLBASICP

POWERREDUCE16QAM 16QAM Transmitter Power Reduce Level SET GCELLBASICP

POWERREDUCE32QAM 32QAM Transmitter Power Reduce Level SET GCELLBASICP

DIVERT8PSKDELAY Diversity Transmitter 8PSK Delay SET GCELLBASICP

DLTBFESTDELAY Downlink TBF Establishment Delay SET GCELLPRIVAT

UPEXTTBFINACTDELAY Inactive Period of Extended Uplink TBF SET GCELLPRIVAT

UPTBFRELDELAY Release Delay of Non-extended Uplink TBF SET GCELLPRIVAT

EXTUTBFNODATA Not Send Dummy Message with Extended UplinkSET GCELLPSBASE

GMSKDELAY Diversity Transmitter GMSK Delay SET GCELLBASICP

GPRSPENALTYTIME GPRS Penalty Time SET GCELLNCRESE

GPRSTEMPOFFSET GPRS Temporary Offset SET GCELLNCRESE

RSLCTOFFER GPRS Reselection Offset SET GCELLNCRESE

DNTBFRELDELAY Release Delay of Downlink TBF SET GCELLPRIVAT

BSCVMAX BS_CV_MAX SET GCELLPSBASE

CTRLACKTYPE Control Acknowledge Type SET GCELLPSBASE

PANDEC PAN_DEC SET GCELLPSBASE

PANINC PAN_INC SET GCELLPSBASE

PANMAX PAN_MAX SET GCELLPSBASE

PRIACCTHR Packet Access Priority SET GCELLPSBASE

RACOLOR Routing Area Color Code SET GCELLPSBASE

SGSNR Protocol Version Supported by SGSN SET GCELLPSBASE

DlGprsTbfExpandOp Downlink GPRS TBF Window Expansion OptimizaSET GCELLPSOTHE

RANDACCESSRETRY Allow MS to Access to Another Cell SET GCELLRESELE

RARESELECTHYST Accessorial Hysteresis of Cell Selection SET GCELLRESELE

TRESEL Cell Reselection Forbidden Time SET GCELLRESELE

CELLBARACCESS2 Cell Access Bar Switch SET GCELLSERVPA

EXCACC Exclusive Access SET GCELLSERVPA

GPRSHCSTHR Threshold of HCS Signal Strength SET GCELLSERVPA

MSTXPWRMAX Maximum TX Power for Access PCH SET GCELLSERVPA

MULTIBANDREP Multi-Band Report SET GCELLSERVPA

PRIORCLASS Cell HCS Prior Class SET GCELLSERVPA

RXLEVACCMIN Minimum Receiving level for Access SET GCELLSERVPA

ABISTSFREETM Timer of Releasing Abis Timeslot SET GCELLPSCHM

ALLOCSINGLEPDCHFORSIGNAAllocate One PDCH for Signaling Data SET GCELLPSCHM

DefaultDynPdchPreTranNum Number of Dynamic Channel Pre-Converted SET GCELLPSCHM

DWNDYNCHNTRANLEV Downlink Multiplex Threshold of Dynamic ChanneSET GCELLPSCHM

DYNCHFREETM Timer of Releasing Idle Dynamic Channel SET GCELLPSCHM

DYNCHNPREEMPTLEV Level of Preempting Dynamic Channel SET GCELLPSCHM

DYNCHTRANRESLEV Reservation Threshold of Dynamic Channel ConvSET GCELLPSCHM

ReservedDynPdchPreTranNum Number of Reserved Dynamic Channel SET GCELLPSCHM

UPDYNCHNTRANLEV Uplink Multiplex Threshold of Dynamic Channel SET GCELLPSCHM

DESCRIPTIONWhether the cell supports the MS with the DTM multi-timeslot capability of class 11

Whether the cell supports DLDC

Whether the current cell supports EDGE

Whether the current cell supports EGPRS2-A

Whether the cell supports the MS with the DTM multi-timeslot capability

Whether to support the network assisted cell change NACC. The NACC is used in the network control modes NC0, NC1 or NC2. The NACC enables the network to notify the MS of the system information of the neighboring cell when the MS is in the packet transmission state. In this way, the MS can reselect a cell in a sh

Whether to support the network control 2 NC2. The NC2 enables the network side to control the cell reselection for the MS when the MS reports the measurement report of the local cell and the neighboring cell.When this parameter is set to "YES" and "Network Control Mode" in "SET GCELLPSBASE" is set to "NC2", the n

Whether the cell supports the PACKET SI STATUS flow. In the PACKET SI STATUS flow, the MS sends the Packet PSI/SI Status message to indicate that the MS has stored the system message. The network side sends the Packet Serving Cell Data message to notify the MS of the system message not stored.

Identifies the routing area of the current cell

Whether to support In Inter-RAT Inter-cell PS Handover. The MS in the UMTS cell can be handed over to the BSC local cell through PS handover algorithm.

Whether support Out Inter-RAT Inter-Cell PS Handover. The MS in the BSC local cell can be handed over to the UMTS cell through PS handover algorithm.

Cell supports reduced latency capability. This parameter is used to reduce the latency during the transmission, thus improving the user experience for conversational services.

Whether to support dual transfer mode DTM. The DTM allows an MS to use the circuit switching service and the packet switching service at the same time. This function must be supported by the network side.

Whether to support the enhanced DTM function. Comparing to the DTM, the enhanced DTM improves the CS setup and release. During the CS service setup, the PS service is not interrupted.

Whether the current cell supports GPRS

Number of the PCU to which the current cell belongs

Average period for sending the measurement report over the EGPRS channel

Default coding scheme of the downlink EDGE link. If the downlink adopts the dynamic adjustment coding scheme, this parameter can be used to set the coding scheme for transmission during initial access. If the downlink uses the fixed coding scheme, the TBF uses the fixed coding scheme.

Default coding scheme used on the downlink EGPRS2-A link. If the downlink uses the dynamic coding scheme, this parameter specifies the coding scheme that is used for the transmission in initial access. If the downlink uses the fixed coding scheme, the TBF uses the fixed coding scheme.

Fixed coding scheme that is used on the downlink EGPRS2-A link. If the downlink uses the fixed coding scheme, this parameter can be set MSC1-4, MSC7-8 or DAS5-12.. If the downlink uses the dynamic coding scheme, this parameter is set to UNFIXED.

Coding scheme of the downlink EDGE link. If the downlink uses the fixed coding scheme, this parameter is set to a value ranging from MCS1 to MCS9. If the downlink uses the dynamic adjustment coding scheme, this parameter is set to UNFIXED.

It is applicable to the radio transmission environment to improve the link quality. Link adaptation LA indicates adjusting the coding mode of the channel dynamically according to the transmission quality of the link. The link transmission quality is measured by the 8PSK MEAN BEP and 8PSK CV BEP in the Packet EGPRS Do

Default coding scheme of the uplink EDGE link. If the uplink adopts the dynamic adjustment coding scheme, this parameter can be used to set the coding scheme for transmission during initial access. If the uplink uses the fixed coding scheme, the TBF uses the fixed coding scheme.

Default coding scheme used on the uplink EGPRS2-A link. If the uplink uses the dynamic coding scheme, this parameter specifies the coding scheme that is used for the transmission in initial access. If the uplink uses the fixed coding scheme, the TBF uses the fixed coding scheme.

Fixed coding scheme that is used on the uplink EGPRS2-A link. If the uplink uses the fixed coding scheme, this parameter can be set to any one in MCS1-6 and UAS7-11. If the uplink uses the dynamic coding scheme, this parameter can be set to UNFIXED.

Coding scheme of the uplink EDGE link. If the uplink uses the fixed coding scheme, this parameter is set to a value ranging from MCS1 to MCS9. If the uplink uses the dynamic adjustment coding scheme, this parameter is set to UNFIXED.

The BSSGP virtual connection identifier. It is used to identify multiple BVCs that multiplexes the NS-VC.

Whether the currently cell supports the GPRS

Network color code. It is used to uniquely identify different public land mobile network PLMN of the adjacent country.

The identifier of a network service entity NSE.An NSE manages a group of NSVCs.

Route area of the current cell

Whether the reselection hysteresis parameter is applied to the C31 criterion

Whether GPRS cell reselection offset is used for C32 calculation during cell reselection. If this parameter is set to 1, then only the positive hysteresis of the neighoring cell is used in C32 calculation.

Hysteresis value of the cell in the same routing area. When the MS in the ready state reselects a cell, if the original cell and the target cell are in the same routing area, the C2 values of the two cells at the border of the cell are quite different due to radio channel fading. As a result, the MS frequently reselects cells. Fre

PDCH uplink multiplex threshold, indicating the maximum TBFs on the uplink PDCH parameter value/10.

PDCH Downlink multiplex threshold in the Mobile Station Receiver Diversity MSRD mode. When this parameter is set to "80", the MS does not adopt the MSRD mode. When the number of the TBF on the PDCH that is assigned to the MS exceeds this parameter or the coding rate of the PDCH is smaller than the thresho

PDCH downlink multiplex threshold, Indicating the maximum TBFs on the downlink PDCH parameter value/10.

Maximum value of the PDCH ratio in a cell. The number of available TCHs and PDCHs in a cell is set to a fixed value. The PDCH ratio is: available PDCHTCH/F + static PDCH. This parameter is used to restrict the PDCH ratio.

Whether to support the 11-bit EGPRS access request

Coding scheme of the default GPRS downlink. Dynamic adjustment coding: the coding scheme used during initial access transmission. If the downlink uses the fixed coding scheme, the TBF uses the fixed coding scheme.

Adjustment mode of the downlink GPRS link coding scheme. If the fixed coding scheme is used, this parameter is set to a value ranging from CS1 to CS4. If the dynamic coding scheme is used, this parameter is set to UNFIXED.

Retransmission threshold when the coding mode of the downlink TBF is changed from CS2 to CS1. When the downlink TBF retransmission rate is greater than or equals to this value, the coding mode of the TBF is changed from CS2 to CS1.

Retransmission threshold when the coding mode of the downlink TBF is changed from CS1 to CS2. When the TBF retransmission rate is less than or equals to this value, the coding mode of the TBF is changed from CS1 to CS2.

Default coding scheme of the uplink GPRS link. If the uplink adopts the dynamic adjustment coding scheme, this parameter can be used to set the coding scheme for transmission during initial access. If the uplink uses the fixed coding scheme, the TBF uses the fixed coding scheme.

Whether the PCU of the cell supports the 64 neighboring cells. This parameter determines the capability of reporting the number of the neighboring cells of the BSC in the NACC and NC2 function.

value 1 indicates that the uplink coding scheme is adjusted according to downlink quality measurements reported by MS; value 2 indicates that the uplink coding scheme is adjusted according to uplink quality measurements reported by BTS.

1. When "Level of Preempting Dynamic Channel" is set to "No preempt of service TCHF" and "PDCH Reforming" is set to "Yes", the channels for the CS service is released if the CS service fails be switched to another channel.2: When "Level of Preempting Dynamic Channel" is set to "Preempt all dynamic TCHFs" or "No preempt of CCHs" and "PDCH Reforming" is set to "Yes", the CS service is switched to the original channel if the CS service fails to be switched to another channel.

Adjustment mode of the uplink GPRS link coding scheme. If the fixed coding scheme is used, this parameter is a value ranging from CS1 to CS4. If the dynamic coding scheme is used, this parameter is set to UNFIXED.

Retransmission threshold when the coding mode of the uplink TBF is changed from CS2 to CS1. When the retransmission rate of the uplink TBF is greater than or equal to this threshold, the coding mode of the uplink TBF is changed from CS2 to CS1.

Retransmission threshold when the coding mode of the uplink TBF is changed from CS1 to CS2. When the retransmission rate of the uplink TBF is less than or equal to this threshold, the coding mode of the uplink TBF is changed from CS1 to CS2.

Retransmission threshold when the coding mode of the TBF is changed from CS3 to CS2. When the TBF retransmission rate is greater than or equals to this value, the coding mode of the TBF is changed from CS3 to CS2.

Retransmission threshold when the coding mode of the downlink TBF is changed from CS4 to CS3. When the downlink TBF Retransmission rate is greater than or equals to this value, the coding mode of the TBF is changed from CS4 to CS3.

Retransmission threshold when the coding mode of the TBF is changed from CS2 to CS3. When the downlink TBF retransmission rate is less than or equals to CS2 to CS1, the coding mode of the TBF is changed from CS2 to CS3.

Retransmission threshold when the coding mode of the downlink TBF is changed from CS3 to CS4. When the downlink TBF retransmission rate is less than or equals to this value, the coding mode of the downlink TBF is changed from CS3 to CS4.





Delay of transmit diversity when 16QAM is used. Generally, the parameter is applicable to general fading environments. The transmit diversity can generally bring a gain of 3 dB to 5 dB. The fading conditions vary with the MS location; therefore, MSs in a fixed time delay obtain different gains. In addition, the EDGE se

Delay of transmit diversity when 32QAM is used. Generally, the parameter is applicable to general fading environments. The transmit diversity can generally bring a gain of 3 dB to 5 dB. The fading conditions vary with the MS location; therefore, MSs in a fixed time delay obtain different gains. In addition, the EDGE se

Power attenuation level of timeslot 7 of the BCCH in 16QAM. The attenuation level ranges from 0 to 50, with the step of 0.2 dB. When the EDGE TRX sends signals in 16QAM, the transmit power must be lower than the mean power in GMSK.

Power attenuation level of timeslot 7 of the BCCH in 32QAM. The attenuation level ranges from 0 to 50, with the step of 0.2 dB. When the EDGE TRX sends signals in 32QAM, the transmit power must be lower than the mean power in GMSK.

Delay of transmit diversity when 8PSK is used. Generally, the parameter is applicable to general fading environments. The transmit diversity can generally bring a gain of 3 dB to 5 dB. The fading conditions vary with the MS location; therefore, MSs in a fixed time delay obtain different gains. In addition, the EDGE serv

Time interval between sending of the Packet Uplink Ack/Nack message and setup of the DL TBF. After receiving the Packet Uplink Ack/Nack message FAI = 1, the MS releases the UL TBF and starts to monitor CCCH. In this case, if the MS receives the downlink assignment message before being handed over to the CCCH,

Inactive period of extended uplink TBF. After the network side receives the last uplink RLC data block CountValue=0 of the MS supporting the extended uplink TBF, the uplink TBF is released immediately. Instead, the uplink TBF is set to the inactive state. In the inactive period, if the MS needs to transmit the uplink RLC

Delay of releasing the non-extended uplink TBF. After receiving the last uplink RLC data block CountValue=0, the network side sends the message Packet Uplink Ack/Nack with FAI=1 to notify the MS of releasing the uplink TBF. After this parameter is set, the network side notifies the MS of releasing this TBF after speci

Whether to send the Dummy message during the deactivated period of the extended uplink TBF

Delay of transmit diversity when GMSK is used. Generally, the parameter is applicable to general fading environments. In this case, the transmit diversity can obtain the gain of 3 dB to 5 dB. The fading degrees, however, vary with environments. For a fixed delay, different UEs may obtain different gains. In addition,

Timer used when the MS calculates the C2 used to evaluate the channel quality during cell reselection. The time information is transmitted in the system message of each cell.

This parameter is used to prevent repeated cell reselection of a fast moving MS. The MS does not select this cell when the duration of maintaining the BCCH signal channel strength does not reach the penalty time.

Used for calculating C2. The MS with a large value can be assigned with high access priority.

Delay of releasing the downlink TBF. After the last downlink RLC data block is transmitted on the network side and all the transmitted downlink data blocks are received, the MS is not informed to stop this downlink TBF. Instead, the state of the last data block is forcibly set to "not received" and the RRBP flag of th

This parameter is used to set the parameter BS_CV_MAX for MS countdown. This parameter is used for the MS to calculate the CV. This parameter also determines the duration of the timer T3198. When the MS sends one uplink RLC data block, the receiving state of this data block is set to Pending and the timer T3198 is s

Format of the control acknowledge message of the MS. Four access bursts are used to obtain timing advance without sending polling message; RLC/MAC control block is used to obtain timing advance after sending polling message.

This parameter sets the PAN_DEC value used by the counter N3102 of the MS. When the timer T3182 of the MS expires, the N3102 reduces the value of PAN_DEC. 0: the value of PAN_DEC is 0; 7: the value of PAN_DEC is 7; Value N indicates that PAN_DEC is N; Not use: this parameter is not used.

This parameter sets the PAN_INC value used by the counter N3102 of the MS. When receiving the packet uplink acknowledged or unacknowledged message sent by the network VS or VA increases, the MS increases the count PAN_INC of the counter N3102. 0: the value of PAN_INC is 0; 7: the value of PAN_INC is 7; V

RAN_MAX value, the maximum value of the N3102. 4: the value of PAN_MAX is 4; 32: the value of PAN_MAX is 32. Value N indicates that PAN_DEC is N; Not use: this parameter is not used.

Access priority of the MS that is allowed to access the cell. The MS sends the packet channel request containing the 2-bit radio priority message. The priority of the 2-bit radio priority message ranges from 1 to 4 in descending order. During the MS access, the BSC compares the radio priority in the channel request with the

Routing area color code of the GPRS cell

Protocol version supported by the SGSN

Expanded size of the GPRS RLC window. This parameter is used to expand the size of the GRPS RLC window. The expanded window size breaks the restrictions of 64 defined in the protocol and reduces the probability of GRPS RLC window stopping.

Whether to allow the MS to access another cell

Hysteresis of cell selection in different routing area. When a standby or ready MS starts cell reselection, if the original cell and the target cell are in the different routing area, the signal level of the neighboring cell must be greater that of the current cell. Their difference must be larger than the specified hysteresis. Otherw

Forbidden time of cell reselection

Whether the cell can be added to the reselected candidate cell list. If this parameter is set to "NoPermit", the cell cannot be reselected as the candidate cell for handover. If this parameter is set to "Permit", the cell can be reselected as the candidate cell for handover.

Whether it is a SoLSA exclusive access cell. If it is a SoLSA exclusive access cell, only the MS subscribing the Localised Service Area LSA can access this cell.

Threshold of hierarchical cell structure HCS signal strength. The MS calculates the C31 according to the signal strength and its threshold and selects the adjacent cell during cell reselection.

Maximum TX power for the MS to access the PCH

Multi-band point report value, including "report six cells with the strongest signal at each frequency point", "report one cell with the strongest signal at each frequency point","report two cells with the strongest signal at each frequency point", and "report three cells with the strongest signal at each frequency point".

Minimum receiving power level for the MS in the cell to access the system

When this parameter is set to ON, the GMM/SM signaling service is assigned only one PDCH; otherwise, the GMM/SM signaling service is assigned one or more PDCHs as required.

Priority of the hierarchical cell structure HCS. 0: indicates the lowest priority; 7: indicates the highest priority.

Interval between detection of the Abis timeslot being in idle state and releasing of the Abis timeslot. When channels are idle, the timer is started. When the timer expires, the Abis timeslot is released. When all the TBFs on the channel are released, the Abis timeslot is not released at once. Instead, the timer is started when the channels are idle. Before the timer expires, if new service request is received and the Abis timeslot is occupied, then the timer is stopped; otherwise, the timeslot is released after the timer expires.When "Number of Dynamic Channel Pre-Converted" is greater than 0, the Abis timeslots are not released after the static PDCH and pre-converted PDCH are idle.

When this parameter is greater than 0, three sub-links are bound to the static PDCH and pre-converted PDCH in a cell by default. The pre-converted PDCH can be preempted when it is idle. You can set "Number of Reserved Dynamic Channel" as required when you expect the pre-converted PDCH not to be preempted.

Downlink multiplex threshold of dynamic channel conversion. When the subscriber number on the channel reaches the value threshold/10, the dynamic channel conversion is triggered.

Time to wait for releasing the dynamic channel after the TBF on the dynamic channel is released. When all the TBFs on the channel are released, the dynamic channel is not released at once. Instead, the timer is started when the channels are idle. Before the timer expires, if new service request is received, the dynamic c

Number of full-rate TCHs reserved for the CS domain. This parameter is valid only when "Level of Preempting Dynamic Channel" is set to LEVEL1 or LEVEL2.

This parameter specifies the number of the reserved PDCHs that are not used for channel converstion in the dynamic transferable channel pool.

Uplink multiplex threshold of dynamic channel conversion. When the subscriber number on the channel reaches the value threshold/10, the dynamic channel conversion application is triggered.

"No preempt of CCHs" indicates the circuit domain can preempt all the dynamic channels except the CCHs."No preempt of service TCHF" indicates the circuit domain cannot preempt all the dynamic channels of bearer services.

GUI_VALUE_RANGEUNSUPPORTNot Support, SUPPORTSupport

UNSUPPORTNot Support, SUPPORTSupport

NONo, YESYes

NONo, YESYes


NONo, YESYes

NONo, YESYes

NONo, YESYes

NONo, YESYes

0~255






NONot support, SupportAsInnPcuSupport as built-in PCU, SupportAsExtPcuSupport as external Pcu

0~31

0Not support dynamic adjustment, 1According to downlink quality measurements reported by MS, 2According to

0~10

MCS1MCS1, MCS2MCS2, MCS3MCS3, MCS4MCS4, MCS5MCS5, MCS6MCS6, MCS7MCS7, MCS8MCS8, M

MCS1MCS1, MCS2MCS2, MCS3MCS3, MCS4MCS4, MCS7MCS7, MCS8MCS8, DAS5DAS5, DAS6DAS6, DAS7

MCS1MCS1, MCS2MCS2, MCS3MCS3, MCS4MCS4, MCS7MCS7, MCS8MCS8, DAS5DAS5, DAS6DAS6, DAS7

MCS1MCS1, MCS2MCS2, MCS3MCS3, MCS4MCS4, MCS5MCS5, MCS6MCS6, MCS7MCS7, MCS8MCS8, MC

IRIR, LALA

MCS1MCS1, MCS2MCS2, MCS3MCS3, MCS4MCS4, MCS5MCS5, MCS6MCS6, MCS7MCS7, MCS8MCS8, M

MCS1MCS1, MCS2MCS2, MCS3MCS3, MCS4MCS4, MCS5MCS5, MCS6MCS6, UAS7UAS7, UAS8UAS8, UAS9

MCS1MCS1, MCS2MCS2, MCS3MCS3, MCS4MCS4, MCS5MCS5, MCS6MCS6, UAS7UAS7, UAS8UAS8, UAS9

MCS1MCS1, MCS2MCS2, MCS3MCS3, MCS4MCS4, MCS5MCS5, MCS6MCS6, MCS7MCS7, MCS8MCS8, MC

2~65534

NONot Support, SupportAsInnPcuSupport As Inner Pcu, SupportAsExtPcuSupport As Outer Pcu

0~7

0~65534

0~255

C31NOTUSENot Use c31 standard, C31STANDARDUse c31 standard

0~1

0dB0dB, 2dB2dB, 4dB4dB, 6dB6dB, 8dB8dB, 10dB10dB, 12dB12dB, 14dB14dB

10~70

10~80

10~160

NONO, YESYES

0~100

NONO, YESYES

CS1CS1, CS2CS2, CS3CS3, CS4CS4

CS1CS1, CS2CS2, CS3CS3, CS4CS4, UNFIXEDUNFIXED

0~64

0~64

CS1CS1, CS2CS2, CS3CS3, CS4CS4

CS1CS1, CS2CS2, CS3CS3, CS4CS4, UNFIXEDUNFIXED

0~64

0~64

0~64

0~64

0~64

0~64

0~64

0~64

0~64

0~64

4~32

4~32

0~50

0~50

4~32

0~300

0~5000

0~300

SENDSEND, NOTSENDNOTSEND

4~32

10sec10secsec100sec, 110sec110sec, 120sec120sec, 130sec130sec, 140sec140sec, 150sec150sec, 160sec160

0db0db, 10db10db, 20db20db, 30db30db, 40db40db, 50db50db, 60db60db, infinityinfinity, nouseno use

MINUS_52db-52db, MINUS_48db-48db, MINUS_44db-44db, MINUS_40db-40db, MINUS_36db-36db, MINUS_32db-

0~5000

0~15

4BURST4Burst, RLC/MACRLC/MAC

Pan_00, Pan_11, Pan_22, Pan_33, Pan_44, Pan_55, Pan_66, Pan_77, 255not use



0No packet access, 3Packet access of level 1, 4Packet access of levels 1-2, 5Packet access of levels 1-3, 6Packe

0~7

0 Release 98 or older, 1Release 99 onwards

0~127

NONo, YESYes

0dB0dB, 2dB2dB, 4dB4dB, 6dB6dB, 8dB8dB, 10dB10dB, 12dB12dB, 14dB14dB, nouseno use

5sec5sec, 10sec10sec, 15sec15sec, 20sec20sec, 30sec30sec, 60sec60sec, 120sec120sec, 300sec300sec, nou

PermitPermit Cell Access, NoPermitProhibit Cell Access

NoExclusiveNoExclusive, ExclusiveExclusive

DB110-110dB-100dB, DB98-98dB, DB96-96dB, DB94-94dB, DB92-92dB, DB90-90dB, DB88-88dB, DB86-86dB,

0~31

REPORT6Report six, REPORT1Report one, REPORT2Report two, REPORT3Report three

00, 11, 22, 33, 44, 55, 66, 77, nouseno use

0~63

10~3600

OFFOFF, ONON

0~32

10~80

10~3600

LEVEL0Preempt all dynamic TCHFs, LEVEL1No preempt of CCHs, LEVEL2No preempt of service TCHF

0~8

0~8

10~70

ACTUAL_VALUE_RANGE UNIT DEFAULT_VALUE RECOMMENDED_VALUEUNSUPPORT, SUPPORT None UNSUPPORT None

UNSUPPORT, SUPPORT None UNSUPPORT None

NO, YES None NO None







0~255 None 0 None






NO, SupportAsInnPcu, SupportAsExtPcu None None None

0~31 None None None

0, 1, 2 None 2 2

0~10 None 5 5

MCS1, MCS2, MCS3, MCS4, MCS5, MCS6, None MCS6 MCS6

MCS1, MCS2, MCS3, MCS4, MCS7, MCS8, DNone DAS6 DAS6

MCS1, MCS2, MCS3, MCS4, MCS7, MCS8, DNone UNFIXED UNFIXED

MCS1, MCS2, MCS3, MCS4, MCS5, MCS6, None UNFIXED UNFIXED

IR, LA None IR IR






NO, SupportAsInnPcu, SupportAsExtPcu None NO NO

0~7 None None None



C31NOTUSE, C31STANDARD None C31STANDARD C31STANDARD

0~1 None 0 0

0dB, 2dB, 4dB, 6dB, 8dB, 10dB, 12dB, 14dB dB 2dB 2dB

10~70 None 70 70

10~80 None 40 40

10~160 None 80 80

NO, YES None NO NO

0~100 per cen 30 30

NO, YES None YES YES

CS1, CS2, CS3, CS4 None CS2 CS2

CS1, CS2, CS3, CS4, UNFIXED None UNFIXED UNFIXED

0~64 per cen 10 10

0~64 per cen 5 5

CS1, CS2, CS3, CS4 None CS1 CS1

CS1, CS2, CS3, CS4, UNFIXED None UNFIXED UNFIXED

0~64 per cen 10 10

0~64 per cen 5 5

0~64 per cen 5 5

0~64 per cen 5 5

0~64 per cen 2 2

0~64 per cen 2 2

0~64 per cen 5 5

0~64 per cen 5 5

0~64 per cen 2 2

0~64 per cen 2 2

0.5~4, step: 1/8 bit 4 4

0.5~4, step: 1/8 bit 4 4

0~10, step: 0.2 dB 0 0

0~10, step: 0.2 dB 0 0

0.5~4, step: 1/8 bit 4 4

0~300 ms 90 90

0~5000 ms 2000 2000

0~300 ms 120 120

SEND, NOTSEND None SEND SEND

0.5~4, step: 1/8 bit 20 20

10sec, 20sec, 30sec, 40sec, 50sec, 60sec, 7s 10sec 10sec

0db, 10db, 20db, 30db, 40db, 50db, 60db, infidB 10db 10db

MINUS_52db, MINUS_48db, MINUS_44db, MINdB MINUS_2db MINUS_2db

0~5000 ms 2400 2400

0~15 None 10 10

4BURST, RLC/MAC None 4BURST 4BURST

Pan_0, Pan_1, Pan_2, Pan_3, Pan_4, Pan_5None Pan_1 Pan_1

Pan_0, Pan_1, Pan_2, Pan_3, Pan_4, Pan_5None Pan_2 Pan_2

Pan_4, Pan_8, Pan_12, Pan_16, Pan_20, PaNone Pan_20 Pan_20

0, 3, 4, 5, 6 None 6 6

0~7 None 1 1

Release 98 or older, Release 99 onwards None Release 99 onward Release 99 onwards

0~127 None 0 0

NO, YES None YES YES

0dB, 2dB, 4dB, 6dB, 8dB, 10dB, 12dB, 14dB,dB 2dB 2dB

5sec, 10sec, 15sec, 20sec, 30sec, 60sec, 12s 10sec 10sec

Permit, NoPermit None Permit Permit

NoExclusive, Exclusive None NoExclusive NoExclusive

DB110, DB108, DB106, DB104, DB102, DB10dB DB110 DB110

0~31 None 2 2

REPORT6, REPORT1, REPORT2, REPORTNone REPORT6 REPORT6

0, 1, 2, 3, 4, 5, 6, 7, no use None 2 2

0~63 None 2 2

10~3600 s 15 15

OFF, ON None OFF OFF

0~32 None 0 0

10~80 None 20 20

10~3600 s 20 20

LEVEL0, LEVEL1, LEVEL2 None LEVEL0 LEVEL0

0~8 None 2 2

0~8 None 0 0

10~70 None 20 20

PARAMETER_RELATIONSHIPThis parameter is valid only when "GPRS" is set to SupportAsInnPcu and "SUPPORTDTM" is set to SUPPORT.

This parameter is valid only when "GPRS" is set to SupportAsInnPcu.

This parameter is valid only when "GPRS" is set to SupportAsInnPcu or SupportAsExtPcu.


This parameter is valid only when "GPRS" is set to SupportAsInnPcu and "SUPPORTDTM" is set to SUPPORT.










This parameter is valid only when "GPRS" is set to SupportAsInnPcu and "SUPPORTDTM" is set to SUPPORT.

None

This parameter is valid only when "GPRS" is set to SupportAsExtPcu.

None

None

None

This parameter is valid only when "EGPRS2A" is set to YES.


None

None

None



None

None

None

None

None

None

None

None

None

None

The value of this parameter must be smaller than or equal to "PDCH Downlink Multiplex Threshold".

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

If "UPEXTTBFINACTDELAY" in the "SET GCELLPRIVATEOPTPARA" command is set to 0, "EXTUTBFNODATA" must be 0

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

CAUTION RADIO_PERFORMACE_IMPACT ATTRIBUTENone None Radio

None None Radio

None None Radio

None None Radio

None None Equipment

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Equipment

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Equipment

None None Radio

None None Radio

None None Equipment

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

This parameNone Equipment

This parameNone Equipment

None None Equipment

None None Equipment

None None Equipment

None If this parameter is set improperly Radio

None None Radio

None None Radio

None None Radio

The value ofNone Equipment

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None The throughput of the GPRS service Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

None None Radio

IMPACT PARAMETER_ID PARAMETER_NAME MML_COMMANDCell IMMASSAINTERFTIMER IMM ASS A IF Creation Timer SET GCELLTMR

Cell TQHO Into-BSC HO REQ Queue Timer SET GCELLTMR

Cell IMMASSMAXDELAYTIME Max Delay of IMM ASS Retransmit SET GCELLCCTMR

Cell IMMASSMAXSENDNUM Max Transmit Times of IMM ASS SET GCELLCCTMR

Cell N3101 Maximum Value of N3101 SET GCELLSTANDA



Cell N200ESTAB N200 of Establish SET GCELLCCTMR

Cell N200FFULL N200 of FACCH/Full Rate SET GCELLCCTMR

Cell N200FHALF N200 of FACCH/Half Rate SET GCELLCCTMR

Cell N200REL N200 of Release SET GCELLCCTMR

Cell N200SACCH N200 of SACCH SET GCELLCCTMR

Cell N200SDCCH N200 of SDCCH SET GCELLCCTMR

Cell TIQUEUINGTIMER T11 SET GCELLTMR

Cell T200FACCHF T200 FACCH/F SET GCELLCCTMR

Cell T200FACCHH T200 FACCH/H SET GCELLCCTMR

Cell T200SACCHS T200 SACCH SDCCH SET GCELLCCTMR

Cell T200SACCT0 T200 SACCH TCH SAPI0 SET GCELLCCTMR

Cell T200SACCH3 T200 SACCH TCH SAPI3 SET GCELLCCTMR

Cell T200SDCCH T200 SDCCH SET GCELLCCTMR

Cell T200SDCCH3 T200 SDCCH SAPI3 SET GCELLCCTMR

Cell INTRABSCCODECHOCMDTIMER T25 SET GCELLTMR

Cell ESTABINDTIMER T3101 SET GCELLTMR

Cell INTRABSCHOTIMER T3103A SET GCELLTMR

Cell INTRACELLHOTIMER T3103C SET GCELLTMR

Cell ASSTIMER T3107 SET GCELLTMR

Cell WAITFORRELIND T3109 SET GCELLTMR

Cell WAITFORRELINDAMRHR T3109 for AMR HR SET GCELLTMR

Cell DELAYSENDRFCHREL T3111 SET GCELLTMR

Cell T3115 T3115 SET GCELLGSMR

Cell INBSCHOTIMER T3121 SET GCELLTMR

Cell IMMREJWAITINDTIMER T3122 SET GCELLTMR

Cell T3168 T3168 SET GCELLPSBASE

Cell T3192 T3192 SET GCELLPSBASE

Cell T3212 T3212 SET GCELLIDLEBASI

Cell OUTBSCHOCMDTIMER T7 SET GCELLTMR

Cell OUTBSCHOCLEARTIMER T8 SET GCELLTMR

Cell ULDATAFWDTMR Timer for UL Data Forward SET GCELLTMR

Cell WAITRESVCHANREFRESHTIMER Timer of Reserved TCH for EMC SET GCELLTMR

Cell MSIPFAILINDDELAY TREESTABLISH SET GCELLTMR

Cell IMMASSRESENDEN Use IMM ASS Retransmit ParameteSET GCELLCCTMR

Cell N200PARASWITCH Use LAPDm N200 SET GCELLCCTMR

Cell WAITFORRELINDAMRFR Wait for REL Indication AMR FR SET GCELLTMR

DESCRIPTIONTimer for the BSC6900 waiting for a CC message after sending a CR message. If the timer expires, the seized SDCCH is released.

Maximum time delay in resending an immediate assignment message. Within the period specified by this parameter, an immediate assignment message can be dispatched and retransmitted. Otherwise, the message is not dispatched or retransmitted.

Maximum number of retransmissions of an immediate assignment message. When the value of this parameter is reached, the immediate assignment message is not retransmitted even if the value of "Max Delay of Imm_Ass Retransmit" is not exceeded.

Maximum value of the N3101 counter. In the dynamic uplink allocation mode, the network side enables multiple MSs to share the same uplink channel through the USF value in the downlink data block. After the network side allocates the USF to the uplink TBF the uplink TBF is set up successfully, N3101 is started. The ne

Maximum value of the N3101 counter. When the uplink transmission ends, if the network side receives the last RLC data block, the network side sends an FAI=1 uplink packet acknowledged/unacknowledged message and starts N3103. If the packet control acknowledgement message is not received in the specified time,

Maximum value of the N3105 counter. After the downlink TBF is set up successfully, the N3105 is started on the network side. After the downlink RLC data block is added with the RRBP domain on the network side, the valid packet acknowledged message responded by the MS is received in the uplink RLC data block in t

This parameter specifies the expiry value of timer T200 used for the FACCH/TCHF over the Um interface. For the function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".

This parameter specifies the expiry value of timer T200 used for the FACCH/TCHH over the Um interface. For the function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".

This parameter specifies the expiry value of timer T200 used for the SACCH over the Um interface when the TCH supports SAPI0 services. For the function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".

This parameter specifies the expiry value of timer T200 used for the SACCH over the Um interface when the TCH supports SAPI3 services. For the function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".

The timer is used to set the time when the BSC6900 waits for an Internal Handover Command message after a Internal Handover Required message is reported in an internal BSC handover when A interface is IP. If the timer expires, the internal BSC handover fails.

Timer for the BSC waiting for an Establish Indication message after sending an Immediate Assignment message. If T3101 expires before the BSC receives an Establish Indication message, the BSS releases the seized SDCCH.

Timer started after the BSC6900 delivers a handover command in an intra-BSC inter-cell handover. If the BSC6900 receives a handover complete message before this timer expires, the timer stops. If this timer expires, the BSC6900 considers the handover as failed.

Timer started after the BSC6900 delivers a handover command in an intra-BSC intra-cell handover. If the BSC6900 receives a handover complete message before this timer expires, the timer stops. If this timer expires, the BSC6900 considers the handover as failed.

After the BSC6900 delivers an assignment command, the T3107 timer starts. If the BSC6900 receives an assignment complete message within the scheduled time, the T3107 timer stops. If the timer expires, the BSC6900 sends an assignment failure message.

This timer is used to set the time of waiting for a ReleaseIndication message after a ChannelRelease message is sent. If the timer expires, the channel is deactivated.

When the BSC sends a ChannelRelease message and the current call uses the AMRHR encoding mode, the timer T3109 AMRHR is started. If the BSC receives the ReleaseIndication message before the T3109 AMRHR timer expires, the timer T3109 AMRHR is stopped. If the timer T3109 AMRHR expires, the BSC deac

Timer for delaying a connection release. This parameter is used for delaying the channel deactivation after the active signaling link is broken. The purpose is to reserve some time for the disconnection that may be repeated. After receiving a REL IND message sent by the BTS, the BSC6900 starts the timer. When t

Timer for retransmitting the VGCS UPLINK GRANT message

Timer for the BSC6900 waiting for a handover complete message after sending a handover request acknowledgment message in 2G/3G handover or inter-BSC handover. If the timer expires, a Clear REQ message is reported.

T3168 is used to set the maximum duration for the MS to wait for the uplink assignment message. After the MS originates the uplink TBF setup request by sending the packet resource request or the channel request in the packet uplink acknowledge message, the timer T3168 is started to wait for the packet uplink assi

Duration of releasing the TBF after the MS receives the last data block. When the MS receives the RLC data block containing the flag identifying the last data block and confirms that all the RLC data blocks in the TBF are received, the MS sends the packet downlink acknowledge message containing the last flag ackno

This parameter specifies the length of the timer for periodic location update.

The timer is used to set the time when the BSC6900 waits for an HO REQ ACK message after a Handover Request message is reported in an outgoing BSC handover. If the timer expires, the outgoing BSC handover fails.

The timer is used to set the time when the BSC6900 waits for a handover success message after a handover command is sent in an outgoing BSC handover. If the timer expires, the outgoing BSC handover fails.

Duration for uplink data transmission on the original channel if the TC resources are changed before and after the handover

The TCHs reserved for the emergency call are assigned to the user during the service assignment. If the TCHs are not assigned to the emergency call within a period, the TCHs are released from the reservation queue.

Length of the timer that is started to wait for a channel requested by an incoming BSC handover request message.When the MSC allows the queuing of incoming BSC handover requests, the BSC6900 starts the queuing procedure and the timer if no channel is available for assignment. If the channel request is successful before the timer expires, the timer stops. If the timer expires, the incoming BSC handover fails.

Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of retransmissions of the I frame.For the function of N200 and the effect of the parameter, see the description of "T200 SDCCH".

Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of retransmissions of the I frame on the FACCH a full-rate channel.For the function of N200 and the effect of the parameter, see the description of "T200 SDCCH".

Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of retransmissions of the I frame on the FACCH a half-rate channel.For the function of N200 and the effect of the parameter, see the description of "T200 SDCCH".Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of retransmissions of the I frame during the multi-frame release.For the function of N200 and the effect of the parameter, see the description of "T200 SDCCH".Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of retransmissions of the I frame on the SACCH.For the function of N200 and the effect of the parameter, see the description of "T200 SDCCH".Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of retransmissions of the I frame on the SDCCH.For the function of N200 and the effect of the parameter, see the description of "T200 SDCCH".This parameter indicates the queue timer for assignment.When the BSC6900 receives an assignment request and no channel is available for assignment, the BSC6900 starts the queuing procedure and the timer. If the channel request is successful before the timer expires, the timer stops. If the timer expires, the channel assignment fails.

This parameter specifies the expiry value of timer T200 used for the SACCH on the SDCCH.For the function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".

T200 prevents the data link layer from deadlock during data transmission. The data link layer transforms the physical link that is vulnerable to errors into a sequential non-error data link. The entities at the two ends of this data link use the acknowledgement retransmission mechanism.Each message must be confirmed by the peer end. In unknown cases, both ends are waiting if a message is lost. At this time, the deadlock of the system occurs. Therefore, the transmit end must establish a timer. When the timer expires, the transmit end regards that the receive end does not receive the message and then the transmit end retransmits the message. The number of retransmissions is determined by N200. T200 and the N200 ensure that the data link layer sequentially transmits data and that the transmission is free from errors.This parameter specifies the expiry value of timer T200 when the SDCCH supports SAPI3 services.For the function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".

Timer carried by the Wait Indication information element when the BSC6900 sends an immediate assignment reject message to an MS.After the MS receives the immediate assignment reject message, the MS reattempts to access the network after the timer expires.

Call reestablishment timer

Whether the BSC6900 sends immediate assignment retransmission parameters to the BTS

When the BSC6900 sends a ChannelRelease message and the current call uses the AMRFR encoding mode, the timer T3109 AMRFR is started. If the BSC6900 receives the ReleaseIndication message before the T3109 AMRFR timer expires, the timer T3109 AMRFR is stopped. If the timer T3109 AMRFR expires, the

Whether the BSC6900 sends the LAPDm N200 parameter to the BTS. If this parameter is set to YES, the BSC sends the LAPDm N200 parameter. If this parameter is set to NO, the BSC6900 does not send the LAPDm N200 parameter.

FEATURE_NAME GUI_VALUE_RANGE ACTUAL_VALUE_RANGE UNITA Interface Protocol Process 1000~30000 1000~30000 ms

1~30 1~30 s

Assignment and Immediate Assignment 0~254 0~254 ms

Assignment and Immediate Assignment 1~5 1~5 None

GPRS 8~30 8~30 None

GPRS 2~5 2~5 None

GPRS 3~10 3~10 None

Radio Link Management 5~254 5~254 None






Enhanced Channel Assignment Algorithm 1~30 1~30 s

Radio Link Management 1~255 5~1275, step: 5 ms







HUAWEI I Handover 500~60000 500~60000 ms


500~60000 500~60000 ms

500~60000 500~60000 ms


Radio Dedicated Channel Management 4000~33000 4000~33000 ms

AMR HR 3000~34000 3000~34000 ms

Radio Dedicated Channel Management 500~60000 500~60000 ms

Public Voice Broadcast Service 1~255 1~255 s

500~60000 500~60000 ms

Assignment and Immediate Assignment 0~255 0~255 s

GPRS 500ms500ms0ms1000ms500ms, 1000ms, 1500ms, 2 ms

GPRS 0ms0ms0ms1000ms, 10ms, 80ms, 120ms, 160ms, ms

Location Updating 0~255 0~1530, step: 6 min

500~60000 500~60000 ms

500~60000 500~60000 ms

O&M of BSC 0~240 0~240 ms

Emergency Call Service TS12 1~30 1~30 s





Call Reestablishment 5000~40000 5000~40000 ms

Assignment and Immediate Assignment NONo, YESYes NO, YES None

Radio Link Management OFFOff, ONOn OFF, ON None

AMR FR 3000~34000 3000~34000 ms

DEFAULT_VALUE5000

8

4

2

20

3

10

5

34

29

5

5

23

8

50

50

60

150

200

60

60

None

3000

10000

10000

10000

27000

26000

1000

10

10000

10

500ms

500ms

20

10000

10000

180

15

15000

NO

OFF

34000

RECOMMENDED_VALUE5000

8

4

2

20

3

10

5

34

29

5

5

23

8

50

50

60

150

200

60

60

None

3000

10000

10000

10000

27000

26000

1000

10

10000

10

500ms

500ms

20

10000

10000

In Abis over TDM transmission, the recommended value is 180; in Abis over IP transmission, the recommended value is 200.

15

15000

NO

OFF

34000


None

None

None

None

None

None

N200ESTAB must be set when "

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

CAUTIONNone

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

It is recommended that you select a greater value, such as 16, 20, or 25, in the area with heavy traffic, but a smaller value, such as 2 or 3, in the area with light traffic. To properly specify the value of this parameter, it is necessary to perform overall and long-term measurement on the entities involved regarding their processing capability and traffic, such as the processing capability of the MSC and BSC, and the load on the A interface, Abis interface, Um interface, HLR, and VLR.The location update period in the MSC must be greater than that in the BSC.In the GSM system, it is possible that a powered-on MS is identified as implicit off-line if the MS sends no location update request within a long period.When the MS reselects another cell in the same LAC, the MS is restarted through T3212 timeout if the T3212 of the new cell differs from that of the original cell.When this parameter differs in the cells of the same LAC, it is possible that the MS is identified as implicit off-line if the MS sends no location update request for a long period. In this case, system plays "The subscriber you dial is power off." even though the called MS is on.In an LAC, the value of this parameter should be the same in all cells.If this parameter is set to a greater value, too many channel resources are occupied and the congestion occurs.If this parameter is set to a smaller value, the handover success rate may fall.If this parameter is set to a greater value, too many channel resources are occupied and the congestion occurs.If this parameter is set to a smaller value, the handover success rate may fall.

If the timer is set to a greater value, the time of reserving channel resources for an emergency call is long. In this case, the channel usage for ordinary calls is affected. If the timer is set to a smaller value, reserved channel resources may not be assigned to an emergency call. In this case, the call fails.

None

None

None

None

RADIO_PERFORMACE_IMPACTIf this timer is set to a greater value, channel resources may be wasted, thus causing congestion.

None

None

None

None

None

None

None

None

None

None

None

If timer T200 is set to a smaller value, the transmit end may mistakenly regard that the link is faulty and the data transmission fails before the transmit end receives a response from the peer end. If timer N200 is set to a smaller value,







None

If this parameter is set to a higher value, channel resources may be wasted and congestion occurs; if this parameter is set to a lower value, the assignment success rate may decrease.

If this parameter is set to a greater value, channel resources may be wasted, thus causing congestion.


If this timer is set to a greater value, channel resources may be wasted, thus causing congestion.

None

If this parameter is set to a greater value, channel resources may be wasted, thus causing congestion. If this parameter is set to a smaller value, the handover success rate may decrease.

If this parameter is set to a smaller value, the channel load may increase and the access success rate may decrease.

None

None

If this parameter is set to a smaller value, the paging success rate increases but the load on the SDCCH also increases, thus causing congestion on the SDCCH.

None

None

None

None

If this parameter is set to a greater value, the call-completion rate of MS increases but the BSC6900 load may also increase.If this parameter is set to a smaller value, the increase of the call completion rate is not obvious.If this parameter is set to a greater value, the call-completion rate of MS increases but the BSC6900 load may also increase.If this parameter is set to a smaller value, the increase of the call completion rate is not obvious.

If this timer is set to a greater value, channel resources may be wasted, thus causing congestion.If this timer is set to a smaller value, the success rate of immediate assignment may decrease.If this timer is set to a greater value, channel resources may be wasted, thus causing congestion. If this timer is set to a smaller value, the handover success rate may decrease.If this timer is set to a greater value, channel resources may be wasted, thus causing congestion. If this timer is set to a smaller value, the handover success rate may decrease.

If this parameter is set to YES, the call completion rate of the MS increases but the BSC6900 load also increases.


If this timer is set to a greater value, the radio resources are occupied for a too long time, thus affecting the channel resource usage. If this timer is set to a smaller value, the call reestablishment success rate decreases.

If this parameter is set to Yes, the BSC6900 sends the LAPDm N200 parameter. If this parameter is set to OFF, the BSC6900 does not send the LAPDm N200 parameter.If a BTS does not support this parameter, the parameter should be set to No. Otherwise, the BTS cannot be initialized.

ATTRIBUTEEquipment

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Equipment

Radio

Radio

Radio

Radio

Radio

Radio

Radio

Equipment

Radio

Radio

Radio

Radio

Radio

GUI VALUE0 -631 -622 -613 -604 -595 -586 -577 -568 -559 -54

10 -5311 -5212 -5113 -5014 -4915 -4816 -4717 -4618 -4519 -4420 -4321 -4222 -4123 -4024 -3925 -3826 -3727 -3628 -3529 -3430 -3331 -3232 -3133 -3034 -2935 -2836 -2737 -2638 -2539 -2440 -2341 -2242 -2143 -2044 -1945 -1846 -17

47 -1648 -1549 -1450 -1351 -1252 -1153 -1054 -955 -856 -757 -658 -559 -460 -361 -262 -163 064 165 266 367 468 569 670 771 872 973 1074 1175 1276 1377 1478 1579 1680 1781 1882 1983 2084 2185 2286 2387 2488 2589 2690 2791 2892 2993 3094 31

95 3296 3397 3498 3599 36

100 37101 38102 39103 40104 41105 42106 43107 44108 45109 46110 47111 48112 49113 50114 51115 52116 53117 54118 55119 56120 57121 58122 59123 60124 61125 62126 63

MAXPDCHRATE To adjust the PDCH conversion threshold in the cell. PDCH2SDEN Dynamic PDCH Conversion to SDCCH GCELLBASICPARASDDYN SDCCH Dynamic Allocation Allowed GCELLBASICPARAIDLESDTHRES Idle TCH Threshold N1 GCELLCHMGBASICCELLMAXSD Cell SDCCH Channel Maximum GCELLCHMGBASICMINRESTIMETCH TCH Minimum Recovery Time GCELLCHMGBASICSDCCHDYNADJTSNUM Num of TSs Convertible to SDCCHs per TRX GCELLCHMGBASICRACHACCLEV CS RACH Min. Access Level GCELLCCACCESSPSRACHACCLEV PS RACH Min. Access Level GCELLCCACCESSRXMIN Minimum Access RXLEV GCELLBASICPARAACTL2REEST Activate L2 Re-establishment GCELLSOFT

HOPOWERBOOST Power Boost before HO Enabled or Not GCELLOTHBASIC

B10

Num of TSs Convertible to SDCCHs per TRX(Range[0..8])

B11

CS RACH Min. Access Level(Range[-121..-104])

B12

PS RACH Min. Access Level(Range[-121..-104])

B13

Minimum Access RXLEV(Range[0..63])

ACCESSIBILITY MOBILITY RETAINABILITYL3188C CH313 CM33L3188D CH333 K3013AA330 CH310 K3013BA331 CH330 K3023A300A CH311 CM330A300C CH331 RH3331A300D CH323 K3012BA300E CH320 CM33CA300F CH303 M3100AA300H CH300 M3100BA300I CH301 M3100CA300K CH321 M3101AL3189I CH343 M3101BK3001 CH340 M3101CK3000 CH341 M3101DA3030A H3002 M3101EA3030B H3001 M3102A3030C H3005A M312A3030D H3005B M313A3030E CH3036A M314A3030F CH3036B M315A3030G H3029A M316A3030H H302B M3200ACR330A H302G M3200BCR330B H3027Ca M3200CCA3030J H3028Ca M3201ACA301J H3025A M3201BCA304 H3025B M3201CK3021 H302E M3201DK3011A H302H M3201EK3020 H302I M3202K3010A H3229A M322K3011B H322D M323K3010B H322G M324CR331A H312A M325CR331B H312B M3030ACA313 H312G M3030BCA310 H310A M3030CK3015 H310B M3030DK3016 H310C M3030EK3005 H310D M3030FK3006 H310E M3030GCR373 H310F M3030HCR330C H310G M3030I

CR331C H310H M3030JCR332C H310I M3030KCR333C H310J M3128ACR334C H310L AS4347DCR335C H3229B S4200A

A312Aa CH3531 S4200B

A312Ca H35071 S4200C

A312Da H35081 S4200D

A312Ea S4400A S4200E

A312S S4401A S4207A

A3129I S4402A S4207B

A3129J S4403A S4207C

A3129E S4404A S4207D

A3129G S4405A S4207E

A3129H S4406A CS410A

A312A S4407A CS411A

A3129C S4408A CS412A

A3129N S4409A CS413A

A312F S4410A CS414A

CA315 S4411A CS415A

K3014 S4412A CS416A

K3034 S4413A CS417A

AR3551C S4414A CS410B

AR3552C S4415A CS411B

K3004 S4416A CS412B

S3656 S4417A CS413B

S3655 S4418A CS414B

CM30 S4419A CS415B

K3003 S4420A CS416BM3000A S4421A CS417BM3000B S4422A CS410CM3000C S4423A CS410DM3001A S4424A S4208BM3001B S4425A CS411CM3001C S4426A CS411DM3001D S4427A S4208CM3001E S4428A CS412CM3002 S4429A CS412DM302 S4430A S4208DM303 S4432A CS413CM304 S4434A CS413DM305 S4436A S4208EM306 S4438A S4208ACA303J S4440A CS414CM3020A S4445A CS414D

M3020B S4450A CS415CM3020C S4455A CS415DM3020D S4463A CS416CA3129S CS416D

CS417CCS417DAS4348D

M326CM3600CM3601CM3602A03701A03702

P_ACCESSIBILITY P_PERFORMANCEA9502 A9002A9504 A9006A9506 A9007A9508 A9008A9510 A9009A9512 A9010R9204 A9017R9205 A9018 A9039AR9311 A9102 A9040R9344 A9106 A9132A9003 A9107 A9137A9004 A9108 A9138A9016 A9109 A9237A9103 A9113 A9238A9104 A9116 A9335A9115 A9117 A9336A9203 A9202 AA9114A9204 A9206 AA9213A9216 A9207A9303 A9208A9304 A9209A9315 A9210A9001 A9214A9201 A9217A9101 A9218A9301 A9302R9206 A9306R9207 A9307AR9303 A9308R9343 A9309A9501 A9316A9503 A9317A9505 L9006A9507 L9007A9509 L9008A9511 L9009

L9106L9107L9108L9109L9211L9212L9213L9214

L9215L9216L9217L9218L9219L9311L9312L9313L9314L9315L9316L9317L9318L9319L9202L9203L9204L9205L9206L9207L9208L9209L9210L9302L9303L9304L9305L9306L9307L9308L9309L9310L9002L9003L9004L9005L9102L9103L9104L9105L9001L9101L9201L9301

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2G HUAWEI KPIS