ID Counter name in view Network element, releaseM5000C5 MAC_HS_PDU_RETR_DIST_CL_5 WBTS, WN8.0M5000C6 MAC_D_PDU_DROP_BTS_OWFL WBTS, WN8.0M5000C3 MAC_HS_PDU_RETR_DIST_CL_3 WBTS, WN8.0M5000C4 MAC_HS_PDU_RETR_DIST_CL_4 WBTS, WN8.0M5000C7 MAC_D_PDU_TOT WBTS, WN8.0M5000C8 CQI_DIST_CL_0 WBTS, WN8.0M5000C10 CQI_DIST_CL_2 WBTS, WN8.0M5000C11 CQI_DIST_CL_3 WBTS, WN8.0M5000C12 CQI_DIST_CL_4 WBTS, WN8.0M5000C13 CQI_DIST_CL_5 WBTS, WN8.0M5000C1 MAC_HS_PDU_RETR_DIST_CL_1 WBTS, WN8.0M5000C2 MAC_HS_PDU_RETR_DIST_CL_2 WBTS, WN8.0M5000C9 CQI_DIST_CL_1 WBTS, WN8.0M5000C0 MAC_HS_PDU_RETR_DIST_CL_0 WBTS, WN8.0M5000C351 CQI_CORR_MIMO_D_CLASS12 WBTS, WN8.0M5000C352 CQI_CORR_MIMO_D_CLASS13 WBTS, WN8.0M5000C18 CQI_DIST_CL_10 WBTS, WN8.0M5000C355 CQI_CORR_MIMO_D_CLASS16 WBTS, WN8.0M5000C15 CQI_DIST_CL_7 WBTS, WN8.0M5000C356 CQI_CORR_MIMO_D_CLASS17 WBTS, WN8.0M5000C14 CQI_DIST_CL_6 WBTS, WN8.0M5000C353 CQI_CORR_MIMO_D_CLASS14 WBTS, WN8.0M5000C17 CQI_DIST_CL_9 WBTS, WN8.0M5000C354 CQI_CORR_MIMO_D_CLASS15 WBTS, WN8.0M5000C16 CQI_DIST_CL_8 WBTS, WN8.0M5000C404 HSDPA_USERS_0_7_IN_CELLS WBTS, WN8.0M5000C405 HSDPA_USERS_0_8_IN_CELLS WBTS, WN8.0M5000C357 CQI_CORR_MIMO_D_CLASS18 WBTS, WN8.0M5000C358 MIMO_D_UE_ACT_SUM WBTS, WN8.0M5000C406 HSDPA_USERS_1_7_IN_CELLS WBTS, WN8.0M5000C407 HSDPA_USERS_1_8_IN_CELLS WBTS, WN8.0M5000C408 HSDPA_USERS_2_7_IN_CELLS WBTS, WN8.0M5000C409 HSDPA_USERS_4_0_IN_CELLS WBTS, WN8.0M5000C410 HSDPA_USERS_4_1_IN_CELLS WBTS, WN8.0M5000C411 HSDPA_USERS_4_2_IN_CELLS WBTS, WN8.0M5000C412 HSDPA_USERS_4_3_IN_CELLS WBTS, WN8.0M5000C413 HSDPA_USERS_4_4_IN_CELLS WBTS, WN8.0M5000C414 HSDPA_USERS_4_5_IN_CELLS WBTS, WN8.0M5000C435 MC_HSDPA_DATA_RECEIVED WBTS, WN8.0M5000C368 RES_FRACT_LOAD_CLASS_06 WBTS, WN8.0M5000C29 CQI_DIST_CL_21 WBTS, WN8.0M5000C30 CQI_DIST_CL_22 WBTS, WN8.0M5000C31 CQI_DIST_CL_23 WBTS, WN8.0M5000C32 CQI_DIST_CL_24 WBTS, WN8.0M5000C33 CQI_DIST_CL_25 WBTS, WN8.0M5000C34 CQI_DIST_CL_26 WBTS, WN8.0M5000C35 CQI_DIST_CL_27 WBTS, WN8.0M5000C364 RES_FRACT_LOAD_CLASS_02 WBTS, WN8.0M5000C37 CQI_DIST_CL_29 WBTS, WN8.0M5000C365 RES_FRACT_LOAD_CLASS_03 WBTS, WN8.0M5000C36 CQI_DIST_CL_28 WBTS, WN8.0M5000C362 RES_FRACT_LOAD_CLASS_00 WBTS, WN8.0M5000C363 RES_FRACT_LOAD_CLASS_01 WBTS, WN8.0

M5000C38 CQI_DIST_CL_30 WBTS, WN8.0M5000C360 MACE_PDU_RX_COR_16QAM WBTS, WN8.0M5000C361 MACE_PDU_RX_RETR_16QAM WBTS, WN8.0M5000C436 MC_HSDPA_DATA_DISCARDED WBTS, WN8.0M5000C359 EDCH_16QAM_UE_ACT_SUM WBTS, WN8.0M5000C366 RES_FRACT_LOAD_CLASS_04 WBTS, WN8.0M5000C367 RES_FRACT_LOAD_CLASS_05 WBTS, WN8.0M5000C107 RETRANS_7_CODE_QPSK WBTS, WN8.0M5000C106 RETRANS_6_CODE_QPSK WBTS, WN8.0M5000C108 RETRANS_8_CODE_QPSK WBTS, WN8.0M5000C103 ORIG_TRANS_13_CODE_16QAM WBTS, WN8.0M5000C102 ORIG_TRANS_12_CODE_16QAM WBTS, WN8.0M5000C105 ORIG_TRANS_15_CODE_16QAM WBTS, WN8.0M5000C104 ORIG_TRANS_14_CODE_16QAM WBTS, WN8.0M5000C99 ORIG_TRANS_9_CODE_16QAM WBTS, WN8.0M5000C19 CQI_DIST_CL_11 WBTS, WN8.0M5000C20 CQI_DIST_CL_12 WBTS, WN8.0M5000C379 RES_FRACT_LOAD_CLASS_17 WBTS, WN8.0M5000C101 ORIG_TRANS_11_CODE_16QAM WBTS, WN8.0M5000C378 RES_FRACT_LOAD_CLASS_16 WBTS, WN8.0M5000C100 ORIG_TRANS_10_CODE_16QAM WBTS, WN8.0M5000C23 CQI_DIST_CL_15 WBTS, WN8.0M5000C24 CQI_DIST_CL_16 WBTS, WN8.0M5000C21 CQI_DIST_CL_13 WBTS, WN8.0M5000C22 CQI_DIST_CL_14 WBTS, WN8.0M5000C373 RES_FRACT_LOAD_CLASS_11 WBTS, WN8.0M5000C28 CQI_DIST_CL_20 WBTS, WN8.0M5000C374 RES_FRACT_LOAD_CLASS_12 WBTS, WN8.0M5000C27 CQI_DIST_CL_19 WBTS, WN8.0M5000C375 RES_FRACT_LOAD_CLASS_13 WBTS, WN8.0M5000C26 CQI_DIST_CL_18 WBTS, WN8.0M5000C376 RES_FRACT_LOAD_CLASS_14 WBTS, WN8.0M5000C25 CQI_DIST_CL_17 WBTS, WN8.0M5000C369 RES_FRACT_LOAD_CLASS_07 WBTS, WN8.0M5000C370 RES_FRACT_LOAD_CLASS_08 WBTS, WN8.0M5000C371 RES_FRACT_LOAD_CLASS_09 WBTS, WN8.0M5000C372 RES_FRACT_LOAD_CLASS_10 WBTS, WN8.0M5000C377 RES_FRACT_LOAD_CLASS_15 WBTS, WN8.0M5000C55 ORIG_TRANS_2_CODE_16QAM WBTS, WN8.0M5000C54 ORIG_TRANS_1_CODE_16QAM WBTS, WN8.0M5000C57 ORIG_TRANS_4_CODE_16QAM WBTS, WN8.0M5000C56 ORIG_TRANS_3_CODE_16QAM WBTS, WN8.0M5000C111 RETRANS_11_CODE_QPSK WBTS, WN8.0M5000C51 ORIG_TRANS_3_CODE_QPSK WBTS, WN8.0M5000C112 RETRANS_12_CODE_QPSK WBTS, WN8.0M5000C50 ORIG_TRANS_2_CODE_QPSK WBTS, WN8.0M5000C109 RETRANS_9_CODE_QPSK WBTS, WN8.0M5000C53 ORIG_TRANS_5_CODE_QPSK WBTS, WN8.0M5000C110 RETRANS_10_CODE_QPSK WBTS, WN8.0M5000C52 ORIG_TRANS_4_CODE_QPSK WBTS, WN8.0M5000C115 RETRANS_15_CODE_QPSK WBTS, WN8.0M5000C116 RETRANS_6_CODE_16QAM WBTS, WN8.0M5000C113 RETRANS_13_CODE_QPSK WBTS, WN8.0M5000C49 ORIG_TRANS_1_CODE_QPSK WBTS, WN8.0

M5000C114 RETRANS_14_CODE_QPSK WBTS, WN8.0M5000C117 RETRANS_7_CODE_16QAM WBTS, WN8.0M5000C118 RETRANS_8_CODE_16QAM WBTS, WN8.0M5000C316 UNHAPPY_FRACT_LOAD_DISTR_C_17 WBTS, WN8.0M5000C315 UNHAPPY_FRACT_LOAD_DISTR_C_16 WBTS, WN8.0M5000C314 UNHAPPY_FRACT_LOAD_DISTR_C_15 WBTS, WN8.0M5000C313 UNHAPPY_FRACT_LOAD_DISTR_C_14 WBTS, WN8.0M5000C320 MACE_PDUS_2MS_TTI WBTS, WN8.0M5000C319 UNHAPPY_FRACT_LOAD_DISTR_C_20 WBTS, WN8.0M5000C318 UNHAPPY_FRACT_LOAD_DISTR_C_19 WBTS, WN8.0M5000C317 UNHAPPY_FRACT_LOAD_DISTR_C_18 WBTS, WN8.0M5000C312 UNHAPPY_FRACT_LOAD_DISTR_C_13 WBTS, WN8.0M5000C58 ORIG_TRANS_5_CODE_16QAM WBTS, WN8.0M5000C311 UNHAPPY_FRACT_LOAD_DISTR_C_12 WBTS, WN8.0M5000C46 DISC_MAC_HS_PDU_T1 WBTS, WN8.0M5000C45 TTI_NOT_SEND_DATA_FROM_BUFF WBTS, WN8.0M5000C44 TTI_NOT_SCHED_DATA_IN_BUFF WBTS, WN8.0M5000C119 RETRANS_9_CODE_16QAM WBTS, WN8.0M5000C43 MAX_MAC_D_PDU_BUFF_DELAY WBTS, WN8.0M5000C120 RETRANS_10_CODE_16QAM WBTS, WN8.0M5000C42 MIN_MAC_D_PDU_BUFF_DELAY WBTS, WN8.0M5000C121 RETRANS_11_CODE_16QAM WBTS, WN8.0M5000C41 AVE_MAC_D_PDU_BUFF_DELAY WBTS, WN8.0M5000C122 RETRANS_12_CODE_16QAM WBTS, WN8.0M5000C40 MAC_D_PDU_656 WBTS, WN8.0M5000C123 RETRANS_13_CODE_16QAM WBTS, WN8.0M5000C39 CQI_FAILED WBTS, WN8.0M5000C124 RETRANS_14_CODE_16QAM WBTS, WN8.0M5000C125 RETRANS_15_CODE_16QAM WBTS, WN8.0M5000C126 RECEIVED_HS_MACD_BITS WBTS, WN8.0M5000C127 DISCARDED_HS_MACD_BITS WBTS, WN8.0M5000C128 MACE_PDU_RETR_00_COUNTER WBTS, WN8.0M5000C325 SUM_HSUPA_USERS_10MS_TTI WBTS, WN8.0M5000C324 SUM_HSUPA_USERS_2MS_TTI WBTS, WN8.0M5000C327 DENOM_CPC_USERS WBTS, WN8.0M5000C326 DENOM_HSUPA_USERS WBTS, WN8.0M5000C329 ACTIVE_DC_HSDPA_USERS_1C_SUM WBTS, WN8.0M5000C328 ACTIVE_DC_HSDPA_USERS_2C_SUM WBTS, WN8.0M5000C330 CAPABLE_DC_HSDPA_USERS_SUM WBTS, WN8.0M5000C321 MACE_PDUS_10MS_TTI WBTS, WN8.0M5000C323 MACE_PDU_DATA_10MS_TTI WBTS, WN8.0M5000C47 DISC_MAC_HS_PDU_MAX_RETRANS WBTS, WN8.0M5000C322 MACE_PDU_DATA_2MS_TTI WBTS, WN8.0M5000C48 DISC_MAC_HS_PDU_OTH_REASON WBTS, WN8.0M5000C133 MACE_PDU_RETR_05_COUNTER WBTS, WN8.0M5000C73 HS_SCCH_PWR_DIST_CLASS_4 WBTS, WN8.0M5000C134 MACE_PDU_RETR_06_COUNTER WBTS, WN8.0M5000C72 HS_SCCH_PWR_DIST_CLASS_3 WBTS, WN8.0M5000C131 MACE_PDU_RETR_03_COUNTER WBTS, WN8.0M5000C75 HS_SCCH_PWR_SUM WBTS, WN8.0M5000C132 MACE_PDU_RETR_04_COUNTER WBTS, WN8.0M5000C74 HS_SCCH_PWR_DIST_CLASS_5 WBTS, WN8.0M5000C129 MACE_PDU_RETR_01_COUNTER WBTS, WN8.0M5000C77 HSDPA_USERS_0_2_IN_CELLS WBTS, WN8.0

M5000C130 MACE_PDU_RETR_02_COUNTER WBTS, WN8.0M5000C76 HSDPA_USERS_0_1_IN_CELLS WBTS, WN8.0M5000C78 HSDPA_USERS_0_3_IN_CELLS WBTS, WN8.0M5000C137 MACE_PDU_RETR_09_COUNTER WBTS, WN8.0M5000C69 HS_SCCH_PWR_DIST_CLASS_0 WBTS, WN8.0M5000C138 MACE_PDU_RETR_10_COUNTER WBTS, WN8.0M5000C135 MACE_PDU_RETR_07_COUNTER WBTS, WN8.0M5000C71 HS_SCCH_PWR_DIST_CLASS_2 WBTS, WN8.0M5000C136 MACE_PDU_RETR_08_COUNTER WBTS, WN8.0M5000C70 HS_SCCH_PWR_DIST_CLASS_1 WBTS, WN8.0M5000C340 CQI_CORR_MIMO_D_CLASS1 WBTS, WN8.0M5000C339 CQI_CORR_MIMO_D_CLASS0 WBTS, WN8.0M5000C338 RETRANS_MAC_EHS_PDU_MIMO_D WBTS, WN8.0M5000C337 ORIG_TRANS_MAC_EHS_PDU_MIMO_D WBTS, WN8.0M5000C336 TTI_SCHED_MIMO_D WBTS, WN8.0M5000C335 TTI_SCHED_MIMO_S WBTS, WN8.0M5000C334 TTI_DC_HSDPA_USER_SECONDARY_2C WBTS, WN8.0M5000C333 TTI_DC_HSDPA_USER_PRIMARY_2C WBTS, WN8.0M5000C332 TTI_DC_HSDPA_USER_SECONDARY_1C WBTS, WN8.0M5000C331 TTI_DC_HSDPA_USER_PRIMARY_1C WBTS, WN8.0M5000C142 MACE_PDU_HARQ_FAIL_COUNTER WBTS, WN8.0M5000C64 RETRANS_1_CODE_16QAM WBTS, WN8.0M5000C143 MACE_PDU_LOST_COUNTER WBTS, WN8.0M5000C63 RETRANS_5_CODE_QPSK WBTS, WN8.0M5000C144 MACE_PDU_RETR_UNKNOWN_COUNTER WBTS, WN8.0M5000C62 RETRANS_4_CODE_QPSK WBTS, WN8.0M5000C145 HSUPA_DL_PWR_DIST_CLASS_01 WBTS, WN8.0M5000C61 RETRANS_3_CODE_QPSK WBTS, WN8.0M5000C68 RETRANS_5_CODE_16QAM WBTS, WN8.0M5000C139 MACE_PDU_RETR_11_COUNTER WBTS, WN8.0M5000C67 RETRANS_4_CODE_16QAM WBTS, WN8.0M5000C140 MACE_PDU_RETR_12_COUNTER WBTS, WN8.0M5000C66 RETRANS_3_CODE_16QAM WBTS, WN8.0M5000C141 MACE_PDU_DTX_COUNTER WBTS, WN8.0M5000C65 RETRANS_2_CODE_16QAM WBTS, WN8.0M5000C146 HSUPA_DL_PWR_DIST_CLASS_02 WBTS, WN8.0M5000C60 RETRANS_2_CODE_QPSK WBTS, WN8.0M5000C147 HSUPA_DL_PWR_DIST_CLASS_03 WBTS, WN8.0M5000C59 RETRANS_1_CODE_QPSK WBTS, WN8.0M5000C148 HSUPA_DL_PWR_DIST_CLASS_04 WBTS, WN8.0M5000C350 CQI_CORR_MIMO_D_CLASS11 WBTS, WN8.0M5000C347 CQI_CORR_MIMO_D_CLASS8 WBTS, WN8.0M5000C346 CQI_CORR_MIMO_D_CLASS7 WBTS, WN8.0M5000C349 CQI_CORR_MIMO_D_CLASS10 WBTS, WN8.0M5000C348 CQI_CORR_MIMO_D_CLASS9 WBTS, WN8.0M5000C343 CQI_CORR_MIMO_D_CLASS4 WBTS, WN8.0M5000C342 CQI_CORR_MIMO_D_CLASS3 WBTS, WN8.0M5000C345 CQI_CORR_MIMO_D_CLASS6 WBTS, WN8.0M5000C344 CQI_CORR_MIMO_D_CLASS5 WBTS, WN8.0M5000C341 CQI_CORR_MIMO_D_CLASS2 WBTS, WN8.0M5123C21 ifPackets_BE WBTS, WN8.0M5123C22 ifDroppedOctets_BE WBTS, WN8.0M5123C23 ifDroppedPackets_BE WBTS, WN8.0M5123C24 ifRxOctets_EF WBTS, WN8.0

M5123C25 ifRxPackets_EF WBTS, WN8.0M5000C92 ORIG_TRANS_12_CODE_QPSK WBTS, WN8.0M5000C93 ORIG_TRANS_13_CODE_QPSK WBTS, WN8.0M5000C90 ORIG_TRANS_10_CODE_QPSK WBTS, WN8.0M5000C91 ORIG_TRANS_11_CODE_QPSK WBTS, WN8.0M5000C89 ORIG_TRANS_9_CODE_QPSK WBTS, WN8.0M5123C16 ifOctets_AF1 WBTS, WN8.0M5000C98 ORIG_TRANS_8_CODE_16QAM WBTS, WN8.0M5123C18 ifDroppedOctets_AF1 WBTS, WN8.0M5000C96 ORIG_TRANS_6_CODE_16QAM WBTS, WN8.0M5123C17 ifPackets_AF1 WBTS, WN8.0M5000C97 ORIG_TRANS_7_CODE_16QAM WBTS, WN8.0M5123C20 ifOctets_BE WBTS, WN8.0M5000C94 ORIG_TRANS_14_CODE_QPSK WBTS, WN8.0M5123C19 ifDroppedPackets_AF1 WBTS, WN8.0M5000C95 ORIG_TRANS_15_CODE_QPSK WBTS, WN8.0M5123C34 ifRxOctets_BE WBTS, WN8.0M5123C35 ifRxPackets_BE WBTS, WN8.0M5123C32 ifRxOctets_AF1 WBTS, WN8.0M5123C33 ifRxPackets_AF1 WBTS, WN8.0M5000C79 HSDPA_USERS_1_0_IN_CELLS WBTS, WN8.0M5000C80 HSDPA_USERS_1_1_IN_CELLS WBTS, WN8.0M5000C81 HSDPA_USERS_1_2_IN_CELLS WBTS, WN8.0M5000C82 HSDPA_USERS_2_0_IN_CELLS WBTS, WN8.0M5123C27 ifRxPackets_AF4 WBTS, WN8.0M5000C87 ORIG_TRANS_7_CODE_QPSK WBTS, WN8.0M5123C26 ifRxOctets_AF4 WBTS, WN8.0M5000C88 ORIG_TRANS_8_CODE_QPSK WBTS, WN8.0M5123C31 ifRxPackets_AF2 WBTS, WN8.0M5000C83 HSDPA_USERS_2_1_IN_CELLS WBTS, WN8.0M5123C30 ifRxOctets_AF2 WBTS, WN8.0M5000C84 HSDPA_USERS_3_0_IN_CELLS WBTS, WN8.0M5123C29 ifRxPackets_AF3 WBTS, WN8.0M5000C85 HSDPA_BUFF_WITH_DATA_PER_TTI WBTS, WN8.0M5123C28 ifRxOctets_AF3 WBTS, WN8.0M5000C86 ORIG_TRANS_6_CODE_QPSK WBTS, WN8.0M5000C301 UNHAPPY_FRACT_LOAD_DISTR_C_02 WBTS, WN8.0M5123C14 ifDroppedOctets_AF2 WBTS, WN8.0M5123C15 ifDroppedPackets_AF2 WBTS, WN8.0M5123C12 ifOctets_AF2 WBTS, WN8.0M5123C13 ifPackets_AF2 WBTS, WN8.0M5123C10 ifDroppedOctets_AF3 WBTS, WN8.0M5123C11 ifDroppedPackets_AF3 WBTS, WN8.0M5000C308 UNHAPPY_FRACT_LOAD_DISTR_C_09 WBTS, WN8.0M5000C309 UNHAPPY_FRACT_LOAD_DISTR_C_10 WBTS, WN8.0M5000C306 UNHAPPY_FRACT_LOAD_DISTR_C_07 WBTS, WN8.0M5000C307 UNHAPPY_FRACT_LOAD_DISTR_C_08 WBTS, WN8.0M5000C304 UNHAPPY_FRACT_LOAD_DISTR_C_05 WBTS, WN8.0M5000C305 UNHAPPY_FRACT_LOAD_DISTR_C_06 WBTS, WN8.0M5000C302 UNHAPPY_FRACT_LOAD_DISTR_C_03 WBTS, WN8.0M5000C303 UNHAPPY_FRACT_LOAD_DISTR_C_04 WBTS, WN8.0M5000C310 UNHAPPY_FRACT_LOAD_DISTR_C_11 WBTS, WN8.0M5123C9 ifPackets_AF3 WBTS, WN8.0M5123C8 ifOctets_AF3 WBTS, WN8.0

M5123C7 ifDroppedPackets_AF4 WBTS, WN8.0M5123C6 ifDroppedOctets_AF4 WBTS, WN8.0M5140C3 trafficSelectorMismatch WBTS, WN8.0M5140C2 espCryptographicErrors WBTS, WN8.0duration period_duration, period_duration_sum WBTS, WN8.0M5140C4 sentESPPackets WBTS, WN8.0busy_hour busy_hour WBTS, WN8.0M5138C1 receivedPacketMatchDefPol WBTS, WN8.0M5138C9 sentPacketMatchDefPol WBTS, WN8.0M5138C4 recvUnprotPacketMatchProtPol WBTS, WN8.0M5138C3 receivedPacketMatchDiscPol WBTS, WN8.0M5138C2 receivedPacketMatchBypassPol WBTS, WN8.0M5138C12 failedSAEstablishments WBTS, WN8.0M5140C0 receivedESPpackets WBTS, WN8.0M5138C10 sentPacketBypassPol WBTS, WN8.0M5138C11 sentPacketMatchDiscPol WBTS, WN8.0M5140C1 antiReplayErrors WBTS, WN8.0M5137C28 ifRxOctets_AF3 WBTS, WN8.0M5137C27 ifRxPackets_AF4 WBTS, WN8.0M5137C30 ifRxOctets_AF2 WBTS, WN8.0M5137C29 ifRxPackets_AF3 WBTS, WN8.0M5137C35 ifRxPackets_BE WBTS, WN8.0M5138C0 ipsecSaNotFound WBTS, WN8.0M5137C31 ifRxPackets_AF2 WBTS, WN8.0M5137C32 ifRxOctets_AF1 WBTS, WN8.0M5137C33 ifRxPackets_AF1 WBTS, WN8.0M5137C34 ifRxOctets_BE WBTS, WN8.0M5120C0 CES_OutOfSyncPackets WBTS, WN8.0M5119C1 CES_Packets_Rx WBTS, WN8.0M5120C2 CES_EarlyPackets WBTS, WN8.0M5120C1 CES_LostPackets WBTS, WN8.0M5119C0 CES_Packets_Tx WBTS, WN8.0M5121C3 CES_LatePackets_PW WBTS, WN8.0M5121C0 CES_OutOfSyncPackets_PW WBTS, WN8.0M5110C14 ethIfOutDiscShaping_AF3 WBTS, WN8.0M5120C3 CES_LatePackets WBTS, WN8.0M5110C13 ethIfOutDiscShaping_AF2 WBTS, WN8.0M5121C2 CES_LBit_Packets_PW WBTS, WN8.0M5121C1 CES_LostPackets_PW WBTS, WN8.0M5110C15 ethIfOutDiscShaping_AF4 WBTS, WN8.0M5110C8 EthUnknownPSNHdr_15 WBTS, WN8.0M5110C9 EthIfUas_15 WBTS, WN8.0M5110C10 EthIfSes_15 WBTS, WN8.0M5110C12 ethIfOutDiscShaping_AF1 WBTS, WN8.0M5110C4 EthIfInPktErr_15 WBTS, WN8.0M5110C6 EthIfOutDiscShaping_15 WBTS, WN8.0M5110C7 EthIfInUnknownVLAN_15 WBTS, WN8.0M5118C33 ifRxPackets_AF1 WBTS, WN8.0M5118C32 ifRxOctets_AF1 WBTS, WN8.0M5118C31 ifRxPackets_AF2 WBTS, WN8.0M5118C30 ifRxOctets_AF2 WBTS, WN8.0M5004C3 AVG_RL_SETUP_QUEUING_TIME WBTS, WN8.0M5004C2 PEAK_RL_OPER_PER_SECOND WBTS, WN8.0M5004C1 PEAK_RL_SETUPS_PER_SECOND WBTS, WN8.0

M5004C0 REJECT_RL_SETUPS_CONGESTION WBTS, WN8.0M5118C35 ifRxPackets_BE WBTS, WN8.0M5118C34 ifRxOctets_BE WBTS, WN8.0M5118C20 ifOctets_BE WBTS, WN8.0M5118C22 ifDroppedOctets_BE WBTS, WN8.0M5118C21 ifPackets_BE WBTS, WN8.0M5118C24 ifRxOctets_EF WBTS, WN8.0M5118C23 ifDroppedPackets_BE WBTS, WN8.0M5118C26 ifRxOctets_AF4 WBTS, WN8.0M5118C25 ifRxPackets_EF WBTS, WN8.0M5118C28 ifRxOctets_AF3 WBTS, WN8.0M5118C27 ifRxPackets_AF4 WBTS, WN8.0M5118C29 ifRxPackets_AF3 WBTS, WN8.0M5137C17 ifPackets_AF1 WBTS, WN8.0M5137C18 ifDroppedOctets_AF1 WBTS, WN8.0M5137C19 ifDroppedPackets_AF1 WBTS, WN8.0M5137C20 ifOctets_BE WBTS, WN8.0M5137C21 ifPackets_BE WBTS, WN8.0M5137C22 ifDroppedOctets_BE WBTS, WN8.0M5137C23 ifDroppedPackets_BE WBTS, WN8.0M5137C24 ifRxOctets_EF WBTS, WN8.0M5137C25 ifRxPackets_EF WBTS, WN8.0M5137C26 ifRxOctets_AF4 WBTS, WN8.0M5118C11 ifDroppedPackets_AF3 WBTS, WN8.0M5118C10 ifDroppedOctets_AF3 WBTS, WN8.0M5118C15 ifDroppedPackets_AF2 WBTS, WN8.0M5118C14 ifDroppedOctets_AF2 WBTS, WN8.0M5118C13 ifPackets_AF2 WBTS, WN8.0M5118C12 ifOctets_AF2 WBTS, WN8.0M5118C19 ifDroppedPackets_AF1 WBTS, WN8.0M5118C18 ifDroppedOctets_AF1 WBTS, WN8.0M5118C17 ifPackets_AF1 WBTS, WN8.0M5118C16 ifOctets_AF1 WBTS, WN8.0M5118C5 ifPackets_AF4 WBTS, WN8.0M5118C6 ifDroppedOctets_AF4 WBTS, WN8.0M5118C7 ifDroppedPackets_AF4 WBTS, WN8.0M5118C8 ifOctets_AF3 WBTS, WN8.0M5118C1 ifPackets_EF WBTS, WN8.0M5118C2 ifDroppedOctets_EF WBTS, WN8.0M5118C3 ifDroppedPackets_EF WBTS, WN8.0M5118C4 ifOctets_AF4 WBTS, WN8.0M5118C0 ifOctets_EF WBTS, WN8.0M5137C6 ifDroppedOctets_AF4 WBTS, WN8.0M5112C5 vcBdlInBwUtiClass1 WBTS, WN8.0M5137C5 ifPackets_AF4 WBTS, WN8.0M5112C7 vcBdlInBwUtiClass3 WBTS, WN8.0M5112C6 vcBdlInBwUtiClass2 WBTS, WN8.0M5137C2 ifDroppedOctets_EF WBTS, WN8.0M5137C1 ifPackets_EF WBTS, WN8.0M5137C4 ifOctets_AF4 WBTS, WN8.0M5137C3 ifDroppedPackets_EF WBTS, WN8.0M5136C34 ifRxOctets_BE WBTS, WN8.0M5114C0 PwtUnknownPWHdr_15 WBTS, WN8.0M5136C33 ifRxPackets_AF1 WBTS, WN8.0

M5112C13 vcBdlInPeakThrput WBTS, WN8.0M5137C0 ifOctets_EF WBTS, WN8.0M5136C35 ifRxPackets_BE WBTS, WN8.0M5114C1 PwtPktRecv_15 WBTS, WN8.0M5112C9 vcBdlInBwUtiClass5 WBTS, WN8.0M5118C9 ifPackets_AF3 WBTS, WN8.0M5112C8 vcBdlInBwUtiClass4 WBTS, WN8.0M5112C12 vcBdlOutPeakThrput WBTS, WN8.0M5112C10 vcBdlBwConfig WBTS, WN8.0M5117C9 cacAvgReservedBitRate WBTS, WN8.0M5117C10 cacMaxCommittedBitRate WBTS, WN8.0M5117C7 cacMaxReservedBitRate WBTS, WN8.0M5117C8 cacMinReservedBitRate WBTS, WN8.0M5117C5 ifIpDroppedPacketsRateLimiting WBTS, WN8.0M5117C6 ifIpDroppedPacketsFiltering WBTS, WN8.0M5117C3 ifOutOctets15 WBTS, WN8.0M5117C4 ifInErrors15 WBTS, WN8.0M5111C10 vcOutBwConfig WBTS, WN8.0M5111C9 vcInBwUtiClass5 WBTS, WN8.0M5137C16 ifOctets_AF1 WBTS, WN8.0M5137C15 ifDroppedPackets_AF2 WBTS, WN8.0M5137C14 ifDroppedOctets_AF2 WBTS, WN8.0M5137C13 ifPackets_AF2 WBTS, WN8.0M5137C12 ifOctets_AF2 WBTS, WN8.0M5137C11 ifDroppedPackets_AF3 WBTS, WN8.0M5112C4 vcBdlOutBwUtiClass5 WBTS, WN8.0M5137C10 ifDroppedOctets_AF3 WBTS, WN8.0M5112C3 vcBdlOutBwUtiClass4 WBTS, WN8.0M5137C9 ifPackets_AF3 WBTS, WN8.0M5112C2 vcBdlOutBwUtiClass3 WBTS, WN8.0M5137C8 ifOctets_AF3 WBTS, WN8.0M5112C1 vcBdlOutBwUtiClass2 WBTS, WN8.0M5137C7 ifDroppedPackets_AF4 WBTS, WN8.0M5112C0 vcBdlOutBwUtiClass1 WBTS, WN8.0M5111C13 vcInPeakThrput WBTS, WN8.0M5117C12 ifIpOutDropOctets WBTS, WN8.0M5111C12 vcOutPeakThrput WBTS, WN8.0M5117C11 ifIpOutDropPackets WBTS, WN8.0M5111C11 vcInBwConfig WBTS, WN8.0M5111C8 vcInBwUtiClass4 WBTS, WN8.0M5115C10 Max_AAL2_buff_delay_pri_q_3 WBTS, WN8.0M5115C11 Max_AAL2_buff_delay_pri_q_4 WBTS, WN8.0M5116C0 topSLS15 WBTS, WN8.0M5116C1 topMinPhaseError15 WBTS, WN8.0M5116C2 topAvePhaseError15 WBTS, WN8.0M5116C3 topMaxPhaseError15 WBTS, WN8.0M5116C4 topRxSyncMsg15 WBTS, WN8.0M5136C16 ifOctets_AF1 WBTS, WN8.0M5136C15 ifDroppedPackets_AF2 WBTS, WN8.0M5136C18 ifDroppedOctets_AF1 WBTS, WN8.0M5136C17 ifPackets_AF1 WBTS, WN8.0M5136C20 ifOctets_BE WBTS, WN8.0M5136C19 ifDroppedPackets_AF1 WBTS, WN8.0M5136C22 ifDroppedOctets_BE WBTS, WN8.0

M5110C25 EthIfInBlocksDiscRateLimiting WBTS, WN8.0M5136C21 ifPackets_BE WBTS, WN8.0M5117C1 ifInOctets15 WBTS, WN8.0M5111C1 vcOutBwUtiClass2 WBTS, WN8.0M5117C0 ifInPackets15 WBTS, WN8.0M5111C0 vcOutBwUtiClass1 WBTS, WN8.0M5111C3 vcOutBwUtiClass4 WBTS, WN8.0M5117C2 ifOutPackets15 WBTS, WN8.0M5111C2 vcOutBwUtiClass3 WBTS, WN8.0M5111C5 vcInBwUtiClass1 WBTS, WN8.0M5111C4 vcOutBwUtiClass5 WBTS, WN8.0M5136C14 ifDroppedOctets_AF2 WBTS, WN8.0M5111C7 vcInBwUtiClass3 WBTS, WN8.0M5136C13 ifPackets_AF2 WBTS, WN8.0M5111C6 vcInBwUtiClass2 WBTS, WN8.0M5115C0 Drop_byte_AAL2_pri_overf_q_1 WBTS, WN8.0M5115C1 Drop_byte_AAL2_pri_overf_q_2 WBTS, WN8.0M5110C23 ethIfOutDiscShaping_Q1 WBTS, WN8.0M5110C24 ethIfOutDiscShaping_Q6 WBTS, WN8.0M5115C4 Avg_AAL2_buff_delay_pri_q_1 WBTS, WN8.0M5115C5 Avg_AAL2_buff_delay_pri_q_2 WBTS, WN8.0M5115C2 Drop_byte_AAL2_pri_overf_q_3 WBTS, WN8.0M5115C3 Drop_byte_AAL2_pri_overf_q_4 WBTS, WN8.0M5136C29 ifRxPackets_AF3 WBTS, WN8.0M5136C28 ifRxOctets_AF3 WBTS, WN8.0M5136C27 ifRxPackets_AF4 WBTS, WN8.0M5136C26 ifRxOctets_AF4 WBTS, WN8.0M5136C32 ifRxOctets_AF1 WBTS, WN8.0M5136C31 ifRxPackets_AF2 WBTS, WN8.0M5136C30 ifRxOctets_AF2 WBTS, WN8.0M5115C9 Max_AAL2_buff_delay_pri_q_2 WBTS, WN8.0M5110C11 EthIfInDiscRateLimiting WBTS, WN8.0M5115C8 Max_AAL2_buff_delay_pri_q_1 WBTS, WN8.0M5110C18 ethIfInVlanMismatch WBTS, WN8.0M5115C7 Avg_AAL2_buff_delay_pri_q_4 WBTS, WN8.0M5110C17 ethIfOutDiscShaping_BE WBTS, WN8.0M5115C6 Avg_AAL2_buff_delay_pri_q_3 WBTS, WN8.0M5110C16 ethIfOutDiscShaping_EF WBTS, WN8.0M5136C25 ifRxPackets_EF WBTS, WN8.0M5110C22 ethIfOutDiscShaping_Q2 WBTS, WN8.0M5136C24 ifRxOctets_EF WBTS, WN8.0M5110C21 ethIfOutDiscShaping_Q3 WBTS, WN8.0M5136C23 ifDroppedPackets_BE WBTS, WN8.0M5110C20 ethIfOutDiscShaping_Q4 WBTS, WN8.0M5110C19 ethIfOutDiscShaping_Q5 WBTS, WN8.0M5000C169 HSDPA_USERS_2_6_IN_CELLS WBTS, WN8.0M5000C170 HSDPA_USERS_3_1_IN_CELLS WBTS, WN8.0M5002C34 HSUPA_DATA_SPI_12 WBTS, WN8.0M5002C32 HSUPA_DATA_SPI_10 WBTS, WN8.0M5002C33 HSUPA_DATA_SPI_11 WBTS, WN8.0M5002C30 HSUPA_DATA_SPI_8 WBTS, WN8.0M5002C31 HSUPA_DATA_SPI_9 WBTS, WN8.0M5002C28 HSUPA_DATA_SPI_6 WBTS, WN8.0M5002C29 HSUPA_DATA_SPI_7 WBTS, WN8.0

M5002C26 HSUPA_DATA_SPI_4 WBTS, WN8.0M5002C27 HSUPA_DATA_SPI_5 WBTS, WN8.0M5002C25 HSUPA_DATA_SPI_3 WBTS, WN8.0M5008C45 CONFIGURED_CCCH_PS_WBTS WBTS, WN8.0M5008C44 USED_CCCH_PS_WBTS WBTS, WN8.0M5008C43 CONF_HSUPA_THR WBTS, WN8.0M5008C42 CONF_HSDPA_THR WBTS, WN8.0M5008C41 CONF_HSUPA_USERS WBTS, WN8.0M5008C40 CONF_HSDPA_USERS WBTS, WN8.0M5008C39 NUM_BB_SUBUNITS WBTS, WN8.0M5008C38 MAX_USED_BB_SUBUNITS WBTS, WN8.0M5000C168 HSDPA_USERS_2_5_IN_CELLS WBTS, WN8.0M5008C37 AVG_USED_BB_SUBUNITS WBTS, WN8.0M5000C167 HSDPA_USERS_2_4_IN_CELLS WBTS, WN8.0M5008C36 MIN_USED_BB_SUBUNITS WBTS, WN8.0M5000C166 HSDPA_USERS_2_3_IN_CELLS WBTS, WN8.0M5000C165 HSDPA_USERS_2_2_IN_CELLS WBTS, WN8.0M5000C164 HSDPA_USERS_1_6_IN_CELLS WBTS, WN8.0M5000C163 HSDPA_USERS_1_5_IN_CELLS WBTS, WN8.0M5000C162 HSDPA_USERS_1_4_IN_CELLS WBTS, WN8.0M5000C161 HSDPA_USERS_1_3_IN_CELLS WBTS, WN8.0M5000C160 HSDPA_USERS_0_6_IN_CELLS WBTS, WN8.0M5000C159 HSDPA_USERS_0_5_IN_CELLS WBTS, WN8.0M5002C21 HS_TOTAL_DATA WBTS, WN8.0M5002C22 HSUPA_DATA_SPI_0 WBTS, WN8.0M5002C23 HSUPA_DATA_SPI_1 WBTS, WN8.0M5002C24 HSUPA_DATA_SPI_2 WBTS, WN8.0M5002C17 HS_DATA_ACK_SPI_12 WBTS, WN8.0M5002C18 HS_DATA_ACK_SPI_13 WBTS, WN8.0M5002C19 HS_DATA_ACK_SPI_14 WBTS, WN8.0M5002C20 HS_DATA_ACK_SPI_15 WBTS, WN8.0M5002C15 HS_DATA_ACK_SPI_10 WBTS, WN8.0M5002C16 HS_DATA_ACK_SPI_11 WBTS, WN8.0M5122C5 Bypassed_FramesRx WBTS, WN8.0M5122C4 Bypassed_FramesTx WBTS, WN8.0M5126C0 avgRTT_15Min WBTS, WN8.0M5122C1 Protected_ESPFramesRx WBTS, WN8.0M5000C158 HSDPA_USERS_0_4_IN_CELLS WBTS, WN8.0M5122C0 Protected_ESPFramesTx WBTS, WN8.0M5000C157 HSUPA_UL_PWR_SAMPLE_COUNTER WBTS, WN8.0M5122C3 Discarded_ESPFramesRx WBTS, WN8.0M5122C2 Discarded_ESPFramesTx WBTS, WN8.0M5008C46 LICENSED_CCCH_PS_WBTS WBTS, WN8.0M5000C154 HSUPA_UL_PWR_MIN WBTS, WN8.0M5000C153 HSUPA_AVE_MACD_THR WBTS, WN8.0M5009C1 HSUPA_MACE_DATA_OPID WBTS, WN8.0M5000C156 HSUPA_UL_PWR_AVG WBTS, WN8.0M5009C0 HSDPA_MACHS_DATA_OPID WBTS, WN8.0M5000C155 HSUPA_UL_PWR_MAX WBTS, WN8.0M5000C150 HSUPA_DL_PWR_DIST_CLASS_06 WBTS, WN8.0M5000C149 HSUPA_DL_PWR_DIST_CLASS_05 WBTS, WN8.0M5000C152 HSUPA_MAX_MACD_THR WBTS, WN8.0M5000C151 HSUPA_MIN_MACD_THR WBTS, WN8.0M5002C12 HS_DATA_ACK_SPI_7 WBTS, WN8.0

M5002C13 HS_DATA_ACK_SPI_8 WBTS, WN8.0M5002C10 HS_DATA_ACK_SPI_5 WBTS, WN8.0M5002C11 HS_DATA_ACK_SPI_6 WBTS, WN8.0M5000C191 UPH_SERVING_11 WBTS, WN8.0M5000C192 UPH_SERVING_12 WBTS, WN8.0M5002C14 HS_DATA_ACK_SPI_9 WBTS, WN8.0M5000C189 UPH_SERVING_09 WBTS, WN8.0M5000C190 UPH_SERVING_10 WBTS, WN8.0M5002C5 HS_DATA_ACK_SPI_0 WBTS, WN8.0M5008C24 MAX_HSDPA_PS_UTIL_RAT WBTS, WN8.0M5008C25 MIN_HSUPA_PS_UTIL_RAT WBTS, WN8.0M5002C8 HS_DATA_ACK_SPI_3 WBTS, WN8.0M5002C9 HS_DATA_ACK_SPI_4 WBTS, WN8.0M5002C6 HS_DATA_ACK_SPI_1 WBTS, WN8.0M5002C7 HS_DATA_ACK_SPI_2 WBTS, WN8.0M5008C19 MIN_BTS_HSDPA_USERS WBTS, WN8.0M5008C18 MAX_BTS_HSUPA_USERS WBTS, WN8.0M5008C17 AVG_BTS_HSUPA_USERS WBTS, WN8.0M5008C16 MIN_BTS_HSUPA_USERS WBTS, WN8.0M5008C23 AVG_HSDPA_PS_UTIL_RAT WBTS, WN8.0M5008C22 MIN_HSDPA_PS_UTIL_RAT WBTS, WN8.0M5008C21 MAX_BTS_HSDPA_USERS WBTS, WN8.0M5008C20 AVG_BTS_HSDPA_USERS WBTS, WN8.0M5000C185 UPH_SERVING_05 WBTS, WN8.0M5000C184 UPH_SERVING_04 WBTS, WN8.0M5000C183 UPH_SERVING_03 WBTS, WN8.0M5000C182 UPH_SERVING_02 WBTS, WN8.0M5000C188 UPH_SERVING_08 WBTS, WN8.0M5000C187 UPH_SERVING_07 WBTS, WN8.0M5000C186 UPH_SERVING_06 WBTS, WN8.0M5113C2 Pseudowire_packet_loss WBTS, WN8.0M5002C0 CCH_DATA_CELL_UL WBTS, WN8.0M5002C1 CCH_DATA_CELL_DL WBTS, WN8.0M5002C2 EDCH_DATA_SCELL_UL WBTS, WN8.0M5002C3 EDCH_DATA_NSC_S_EDCH_UL WBTS, WN8.0M5002C4 EDCH_DATA_NSC_NS_EDCH_UL WBTS, WN8.0M5000C179 HS_DSCH_CREDIT_RDCT_BUF_FULL WBTS, WN8.0M5000C180 UPH_SERVING_00 WBTS, WN8.0M5000C181 UPH_SERVING_01 WBTS, WN8.0M5008C35 MAX_HSUPA_SU_USG WBTS, WN8.0M5114C2 PwtPktTransm_15 WBTS, WN8.0M5114C3 PwtPktLost_15 WBTS, WN8.0M5113C0 PwUas_15 WBTS, WN8.0M5113C1 PwSes_15 WBTS, WN8.0M5008C28 LIC_HW_CAP_UTIL_RAT WBTS, WN8.0M5008C27 MAX_HSUPA_PS_UTIL_RAT WBTS, WN8.0M5008C30 LIC_HSUPA_THR WBTS, WN8.0M5008C29 LIC_HSDPA_THR WBTS, WN8.0M5008C32 LIC_NUM_HSUPA_USERS WBTS, WN8.0M5008C31 LIC_NUM_HSDPA_USERS WBTS, WN8.0M5008C34 AVG_HSUPA_SU_USG WBTS, WN8.0M5008C33 MIN_HSUPA_SU_USG WBTS, WN8.0M5000C172 HSDPA_USERS_3_3_IN_CELLS WBTS, WN8.0M5000C171 HSDPA_USERS_3_2_IN_CELLS WBTS, WN8.0

M5000C174 HSDPA_USERS_3_5_IN_CELLS WBTS, WN8.0M5000C173 HSDPA_USERS_3_4_IN_CELLS WBTS, WN8.0M5000C176 HS_DSCH_CREDIT_RDCT_DUE_DLY WBTS, WN8.0M5000C175 HSDPA_USERS_3_6_IN_CELLS WBTS, WN8.0M5008C26 AVG_HSUPA_PS_UTIL_RAT WBTS, WN8.0M5000C178 HS_DSCH_CREDIT_RDCT_FRM_LOSS WBTS, WN8.0M5000C177 HS_DSCH_CREDIT_RDCT_SVRE_DLY WBTS, WN8.0M5000C385 UNHAPPY_RES_FRACT_LOAD_02 WBTS, WN8.0M5000C384 UNHAPPY_RES_FRACT_LOAD_01 WBTS, WN8.0M5000C387 UNHAPPY_RES_FRACT_LOAD_04 WBTS, WN8.0M5000C386 UNHAPPY_RES_FRACT_LOAD_03 WBTS, WN8.0M5000C381 RES_FRACT_LOAD_CLASS_19 WBTS, WN8.0M5000C380 RES_FRACT_LOAD_CLASS_18 WBTS, WN8.0M5000C383 UNHAPPY_RES_FRACT_LOAD_00 WBTS, WN8.0M5000C382 RES_FRACT_LOAD_CLASS_20 WBTS, WN8.0M5000C197 UPH_SERVING_17 WBTS, WN8.0M5000C198 UPH_SERVING_18 WBTS, WN8.0M5000C193 UPH_SERVING_13 WBTS, WN8.0M5000C194 UPH_SERVING_14 WBTS, WN8.0M5000C195 UPH_SERVING_15 WBTS, WN8.0M5000C196 UPH_SERVING_16 WBTS, WN8.0M5126C8 txTwampMessages WBTS, WN8.0M5126C9 lostTwampMessages WBTS, WN8.0M5126C1 maxRTT_15Min WBTS, WN8.0M5126C2 minRTT_15Min WBTS, WN8.0M5127C2 pppTxPackets WBTS, WN8.0M5127C3 pppRxPackets WBTS, WN8.0M5127C0 pppTxOctets WBTS, WN8.0M5127C1 pppRxOctets WBTS, WN8.0M5127C4 pppDiscardedPackets WBTS, WN8.0M5128C0 pppTxOctets WBTS, WN8.0M5002C36 HSUPA_DATA_SPI_14 WBTS, WN8.0M5002C35 HSUPA_DATA_SPI_13 WBTS, WN8.0M5002C38 UE_HSUPA_TP00 WBTS, WN8.0M5002C37 HSUPA_DATA_SPI_15 WBTS, WN8.0M5002C40 UE_HSUPA_TP02 WBTS, WN8.0M5002C39 UE_HSUPA_TP01 WBTS, WN8.0M5002C42 UE_HSUPA_TP04 WBTS, WN8.0M5002C41 UE_HSUPA_TP03 WBTS, WN8.0M5002C44 UE_HSUPA_TP06 WBTS, WN8.0M5002C43 UE_HSUPA_TP05 WBTS, WN8.0M5123C2 ifDroppedOctets_EF WBTS, WN8.0M5123C3 ifDroppedPackets_EF WBTS, WN8.0M5123C4 ifOctets_AF4 WBTS, WN8.0M5123C5 ifPackets_AF4 WBTS, WN8.0M5121C4 CES_EarlyPackets_PW WBTS, WN8.0M5121C5 CES_MinDelay_PW WBTS, WN8.0M5121C6 CES_MaxDelay_PW WBTS, WN8.0M5121C7 CES_Avg_Delay_PW WBTS, WN8.0M5123C0 ifOctets_EF WBTS, WN8.0M5123C1 ifPackets_EF WBTS, WN8.0M5000C258 FRACT_LOAD_DISTR_CLASS_13 WBTS, WN8.0M5000C256 FRACT_LOAD_DISTR_CLASS_11 WBTS, WN8.0M5000C257 FRACT_LOAD_DISTR_CLASS_12 WBTS, WN8.0

M5000C254 FRACT_LOAD_DISTR_CLASS_09 WBTS, WN8.0M5000C255 FRACT_LOAD_DISTR_CLASS_10 WBTS, WN8.0M5000C252 FRACT_LOAD_DISTR_CLASS_07 WBTS, WN8.0M5000C253 FRACT_LOAD_DISTR_CLASS_08 WBTS, WN8.0M5000C250 FRACT_LOAD_DISTR_CLASS_05 WBTS, WN8.0M5000C251 FRACT_LOAD_DISTR_CLASS_06 WBTS, WN8.0M5000C249 FRACT_LOAD_DISTR_CLASS_04 WBTS, WN8.0M5000C269 SAMPLE_HS_PDSCH_PWR_CLASS_02 WBTS, WN8.0M5000C267 HSUPA_NUMBER_OF_UNHAPPY_BITS WBTS, WN8.0M5000C268 SAMPLE_HS_PDSCH_PWR_CLASS_01 WBTS, WN8.0M5000C263 FRACT_LOAD_DISTR_CLASS_18 WBTS, WN8.0M5000C264 FRACT_LOAD_DISTR_CLASS_19 WBTS, WN8.0M5000C265 FRACT_LOAD_DISTR_CLASS_20 WBTS, WN8.0M5000C266 HSUPA_NUMBER_OF_HAPPY_BITS WBTS, WN8.0M5000C259 FRACT_LOAD_DISTR_CLASS_14 WBTS, WN8.0M5000C260 FRACT_LOAD_DISTR_CLASS_15 WBTS, WN8.0M5000C261 FRACT_LOAD_DISTR_CLASS_16 WBTS, WN8.0M5000C262 FRACT_LOAD_DISTR_CLASS_17 WBTS, WN8.0M5006C7 AVG_USED_R99_CE_UL WBTS, WN8.0M5006C6 MAX_USED_R99_CE_UL WBTS, WN8.0M5006C5 MIN_USED_R99_CE_DL WBTS, WN8.0M5006C10 BTS_R99_CE_UTIL_UL_CLASS_2 WBTS, WN8.0M5000C236 UPH_NON_SERVING_24 WBTS, WN8.0M5006C11 BTS_R99_CE_UTIL_UL_CLASS_3 WBTS, WN8.0M5000C237 UPH_NON_SERVING_25 WBTS, WN8.0M5006C8 MIN_USED_R99_CE_UL WBTS, WN8.0M5000C234 UPH_NON_SERVING_22 WBTS, WN8.0M5006C9 BTS_R99_CE_UTIL_UL_CLASS_1 WBTS, WN8.0M5000C235 UPH_NON_SERVING_23 WBTS, WN8.0M5006C14 BTS_R99_CE_UTIL_UL_CLASS_6 WBTS, WN8.0M5006C12 BTS_R99_CE_UTIL_UL_CLASS_4 WBTS, WN8.0M5000C238 UPH_NON_SERVING_26 WBTS, WN8.0M5006C13 BTS_R99_CE_UTIL_UL_CLASS_5 WBTS, WN8.0M5000C229 UPH_NON_SERVING_17 WBTS, WN8.0M5000C232 UPH_NON_SERVING_20 WBTS, WN8.0M5000C233 UPH_NON_SERVING_21 WBTS, WN8.0M5000C230 UPH_NON_SERVING_18 WBTS, WN8.0M5000C231 UPH_NON_SERVING_19 WBTS, WN8.0M5000C245 FRACT_LOAD_DISTR_CLASS_00 WBTS, WN8.0M5000C246 FRACT_LOAD_DISTR_CLASS_01 WBTS, WN8.0M5000C247 FRACT_LOAD_DISTR_CLASS_02 WBTS, WN8.0M5000C248 FRACT_LOAD_DISTR_CLASS_03 WBTS, WN8.0M5000C239 UPH_NON_SERVING_27 WBTS, WN8.0M5000C240 UPH_NON_SERVING_28 WBTS, WN8.0M5000C241 UPH_NON_SERVING_29 WBTS, WN8.0M5000C242 UPH_NON_SERVING_30 WBTS, WN8.0M5000C243 UPH_NON_SERVING_31 WBTS, WN8.0M5000C244 NON_SERVING_ERGCH_COMMANDS WBTS, WN8.0M5006C28 HSPA_USER_UTIL_UL_CLASS_2 WBTS, WN8.0M5006C29 HSPA_USER_UTIL_UL_CLASS_3 WBTS, WN8.0M5006C26 MIN_USED_CSOHSPA_CE WBTS, WN8.0M5006C27 HSPA_USER_UTIL_UL_CLASS_1 WBTS, WN8.0M5006C25 AVG_USED_CSOHSPA_CE WBTS, WN8.0M5000C211 UPH_SERVING_31 WBTS, WN8.0

M5000C210 UPH_SERVING_30 WBTS, WN8.0M5000C209 UPH_SERVING_29 WBTS, WN8.0M5000C218 UPH_NON_SERVING_06 WBTS, WN8.0M5000C217 UPH_NON_SERVING_05 WBTS, WN8.0M5006C34 HSPA_USER_UTIL_DL_CLASS_2 WBTS, WN8.0M5000C216 UPH_NON_SERVING_04 WBTS, WN8.0M5006C33 HSPA_USER_UTIL_DL_CLASS_1 WBTS, WN8.0M5000C215 UPH_NON_SERVING_03 WBTS, WN8.0M5006C32 HSPA_USER_UTIL_UL_CLASS_6 WBTS, WN8.0M5000C214 UPH_NON_SERVING_02 WBTS, WN8.0M5006C31 HSPA_USER_UTIL_UL_CLASS_5 WBTS, WN8.0M5000C213 UPH_NON_SERVING_01 WBTS, WN8.0M5006C30 HSPA_USER_UTIL_UL_CLASS_4 WBTS, WN8.0M5000C212 UPH_NON_SERVING_00 WBTS, WN8.0M5006C15 BTS_R99_CE_UTIL_DL_CLASS_1 WBTS, WN8.0M5006C16 BTS_R99_CE_UTIL_DL_CLASS_2 WBTS, WN8.0M5006C17 BTS_R99_CE_UTIL_DL_CLASS_3 WBTS, WN8.0M5006C18 BTS_R99_CE_UTIL_DL_CLASS_4 WBTS, WN8.0M5000C220 UPH_NON_SERVING_08 WBTS, WN8.0M5000C219 UPH_NON_SERVING_07 WBTS, WN8.0M5000C222 UPH_NON_SERVING_10 WBTS, WN8.0M5000C221 UPH_NON_SERVING_09 WBTS, WN8.0M5006C24 MAX_USED_CSOHSPA_CE WBTS, WN8.0M5000C228 UPH_NON_SERVING_16 WBTS, WN8.0M5006C23 MIN_AVAIL_CSOHSPA_CE WBTS, WN8.0M5000C227 UPH_NON_SERVING_15 WBTS, WN8.0M5006C20 BTS_R99_CE_UTIL_DL_CLASS_6 WBTS, WN8.0M5000C224 UPH_NON_SERVING_12 WBTS, WN8.0M5006C19 BTS_R99_CE_UTIL_DL_CLASS_5 WBTS, WN8.0M5000C223 UPH_NON_SERVING_11 WBTS, WN8.0M5006C22 AVG_AVAIL_CSOHSPA_CE WBTS, WN8.0M5000C226 UPH_NON_SERVING_14 WBTS, WN8.0M5006C21 MAX_AVAIL_CSOHSPA_CE WBTS, WN8.0M5000C225 UPH_NON_SERVING_13 WBTS, WN8.0M5008C7 MIN_USED_CE_UL_WBTS WBTS, WN8.0M5008C8 AVG_USED_CE_UL_WBTS WBTS, WN8.0M5008C6 MAX_USED_CE_DL_WBTS WBTS, WN8.0M5008C11 AVG_USED_CE_R99_DL WBTS, WN8.0M5008C12 MAX_USED_CE_R99_DL WBTS, WN8.0M5008C9 MAX_USED_CE_UL_WBTS WBTS, WN8.0M5008C10 MIN_USED_CE_R99_DL WBTS, WN8.0M5008C15 MAX_USED_CE_R99_UL WBTS, WN8.0M5008C14 AVG_USED_CE_R99_UL WBTS, WN8.0M5008C13 MIN_USED_CE_R99_UL WBTS, WN8.0M5006C35 HSPA_USER_UTIL_DL_CLASS_3 WBTS, WN8.0M5006C36 HSPA_USER_UTIL_DL_CLASS_4 WBTS, WN8.0M5006C37 HSPA_USER_UTIL_DL_CLASS_5 WBTS, WN8.0M5006C38 HSPA_USER_UTIL_DL_CLASS_6 WBTS, WN8.0M5008C0 HSDPA_MAX_MACHS_THR WBTS, WN8.0M5008C1 HSDPA_AVG_MACHS_THR WBTS, WN8.0M5000C200 UPH_SERVING_20 WBTS, WN8.0M5000C199 UPH_SERVING_19 WBTS, WN8.0M5008C3 HSUPA_AVG_MACE_THR WBTS, WN8.0M5000C202 UPH_SERVING_22 WBTS, WN8.0

M5008C2 HSUPA_MAX_MACE_THR WBTS, WN8.0M5000C201 UPH_SERVING_21 WBTS, WN8.0M5008C5 AVG_USED_CE_DL_WBTS WBTS, WN8.0M5000C204 UPH_SERVING_24 WBTS, WN8.0M5008C4 MIN_USED_CE_DL_WBTS WBTS, WN8.0M5000C203 UPH_SERVING_23 WBTS, WN8.0M5000C206 UPH_SERVING_26 WBTS, WN8.0M5000C205 UPH_SERVING_25 WBTS, WN8.0M5000C208 UPH_SERVING_28 WBTS, WN8.0M5000C207 UPH_SERVING_27 WBTS, WN8.0M5130C0 txRstpBpdus WBTS, WN8.0M5130C1 rxRstpBpdus WBTS, WN8.0M5130C2 portStateTransitions WBTS, WN8.0M5131C0 topFreqSynchSLS WBTS, WN8.0M5131C1 topMinFreqSynchError WBTS, WN8.0M5128C2 pppTxPackets WBTS, WN8.0M5128C4 pppDiscardedPackets WBTS, WN8.0M5128C3 pppRxPackets WBTS, WN8.0M5129C0 ethIfOutDiscShaping WBTS, WN8.0M5128C1 pppRxOctets WBTS, WN8.0M5003C18 HS_DSCH_FP_FRMS_W_OTH_ERR WBTS, WN8.0M5003C19 MACE_PDU_LOST WBTS, WN8.0M5003C16 HS_DSCH_OK_FP_FRMS WBTS, WN8.0M5003C17 HS_DSCH_FP_FRMS_W_CRC WBTS, WN8.0M5003C20 HSDSCH_DATA_FROM_IUB WBTS, WN8.0M5003C11 CCH_FP_FRMS_W_OTH_ERR WBTS, WN8.0M5003C15 DCH_FP_REC_FRMS_W_OTH_ERR WBTS, WN8.0M5003C14 DCH_FP_REC_FRMS_W_DELAY WBTS, WN8.0M5003C13 DCH_FP_REC_FRMS_W_CRC_ERR WBTS, WN8.0M5003C12 DCH_OK_FP_DATA_FRMS WBTS, WN8.0M5135C2 ifOutPackets15 WBTS, WN8.0M5135C1 ifInOctets15 WBTS, WN8.0M5135C3 ifOutOctets15 WBTS, WN8.0M5134C10 cacMaxCommittedBitRate WBTS, WN8.0M5134C11 ifIpOutDropPackets WBTS, WN8.0M5134C12 ifIpOutDropOctets WBTS, WN8.0M5135C0 ifInPackets15 WBTS, WN8.0M5134C7 cacMaxReservedBitRate WBTS, WN8.0M5134C8 cacMinReservedBitRate WBTS, WN8.0M5134C9 cacAvgReservedBitRate WBTS, WN8.0M5134C4 ifInErrors15 WBTS, WN8.0M5134C3 ifOutOctets15 WBTS, WN8.0M5134C2 ifOutPackets15 WBTS, WN8.0M5134C1 ifInOctets15 WBTS, WN8.0M5133C1 ifIpDroppedPacketsFiltering WBTS, WN8.0M5134C0 ifInPackets15 WBTS, WN8.0M5131C4 topRxFreqSyncMsg WBTS, WN8.0M5133C0 ifIpDroppedPacketsRateLimiting WBTS, WN8.0M5131C2 topAvgsFreqSynchError WBTS, WN8.0M5131C3 topMaxFreqSynchError WBTS, WN8.0M5136C12 ifOctets_AF2 WBTS, WN8.0M5136C4 ifOctets_AF4 WBTS, WN8.0M5136C5 ifPackets_AF4 WBTS, WN8.0M5136C6 ifDroppedOctets_AF4 WBTS, WN8.0

M5136C7 ifDroppedPackets_AF4 WBTS, WN8.0M5136C8 ifOctets_AF3 WBTS, WN8.0M5136C9 ifPackets_AF3 WBTS, WN8.0M5136C10 ifDroppedOctets_AF3 WBTS, WN8.0M5136C11 ifDroppedPackets_AF3 WBTS, WN8.0M5136C3 ifDroppedPackets_EF WBTS, WN8.0M5136C2 ifDroppedOctets_EF WBTS, WN8.0M5136C1 ifPackets_EF WBTS, WN8.0M5135C8 cacMinReservedBitRate WBTS, WN8.0M5135C9 cacAvgReservedBitRate WBTS, WN8.0M5135C4 ifInErrors15 WBTS, WN8.0M5135C7 cacMaxReservedBitRate WBTS, WN8.0M5135C12 ifIpOutDropOctets WBTS, WN8.0M5136C0 ifOctets_EF WBTS, WN8.0M5135C10 cacMaxCommittedBitRate WBTS, WN8.0M5135C11 ifIpOutDropPackets WBTS, WN8.0M5002C83 SAMPLE_ACTIVE_HSDPA_SPI_8 WBTS, WN8.0M5002C82 SAMPLE_ACTIVE_HSDPA_SPI_7 WBTS, WN8.0M5002C85 SAMPLE_ACTIVE_HSDPA_SPI_10 WBTS, WN8.0M5002C84 SAMPLE_ACTIVE_HSDPA_SPI_9 WBTS, WN8.0M5002C87 SAMPLE_ACTIVE_HSDPA_SPI_12 WBTS, WN8.0M5002C86 SAMPLE_ACTIVE_HSDPA_SPI_11 WBTS, WN8.0M5002C89 SAMPLE_ACTIVE_HSDPA_SPI_14 WBTS, WN8.0M5002C88 SAMPLE_ACTIVE_HSDPA_SPI_13 WBTS, WN8.0M5002C81 SAMPLE_ACTIVE_HSDPA_SPI_6 WBTS, WN8.0M5002C80 SAMPLE_ACTIVE_HSDPA_SPI_5 WBTS, WN8.0M5002C74 ACTIVE_HSDPA_ALL WBTS, WN8.0M5002C73 ACTIVE_HSDPA_SPI_15 WBTS, WN8.0M5002C72 ACTIVE_HSDPA_SPI_14 WBTS, WN8.0M5002C71 ACTIVE_HSDPA_SPI_13 WBTS, WN8.0M5002C78 SAMPLE_ACTIVE_HSDPA_SPI_3 WBTS, WN8.0M5002C77 SAMPLE_ACTIVE_HSDPA_SPI_2 WBTS, WN8.0M5002C76 SAMPLE_ACTIVE_HSDPA_SPI_1 WBTS, WN8.0M5002C75 SAMPLE_ACTIVE_HSDPA_SPI_0 WBTS, WN8.0M5002C70 ACTIVE_HSDPA_SPI_12 WBTS, WN8.0M5002C79 SAMPLE_ACTIVE_HSDPA_SPI_4 WBTS, WN8.0M5002C109 SAMPLE_ALLOC_HSDPA_SPI_0 WBTS, WN8.0M5002C108 ALLOC_HSDPA_ALL WBTS, WN8.0M5002C105 ALLOC_HSDPA_SPI_13 WBTS, WN8.0M5002C104 ALLOC_HSDPA_SPI_12 WBTS, WN8.0M5002C107 ALLOC_HSDPA_SPI_15 WBTS, WN8.0M5002C106 ALLOC_HSDPA_SPI_14 WBTS, WN8.0M5002C101 ALLOC_HSDPA_SPI_9 WBTS, WN8.0M5002C100 ALLOC_HSDPA_SPI_8 WBTS, WN8.0M5002C103 ALLOC_HSDPA_SPI_11 WBTS, WN8.0M5002C102 ALLOC_HSDPA_SPI_10 WBTS, WN8.0M5002C99 ALLOC_HSDPA_SPI_7 WBTS, WN8.0M5002C98 ALLOC_HSDPA_SPI_6 WBTS, WN8.0M5002C97 ALLOC_HSDPA_SPI_5 WBTS, WN8.0M5002C96 ALLOC_HSDPA_SPI_4 WBTS, WN8.0M5002C95 ALLOC_HSDPA_SPI_3 WBTS, WN8.0M5002C94 ALLOC_HSDPA_SPI_2 WBTS, WN8.0M5002C93 ALLOC_HSDPA_SPI_1 WBTS, WN8.0M5002C92 ALLOC_HSDPA_SPI_0 WBTS, WN8.0

M5002C91 SAMPLE_ACTIVE_HSDPA_ALL WBTS, WN8.0M5002C90 SAMPLE_ACTIVE_HSDPA_SPI_15 WBTS, WN8.0M5000C396 UNHAPPY_RES_FRACT_LOAD_13 WBTS, WN8.0M5000C397 UNHAPPY_RES_FRACT_LOAD_14 WBTS, WN8.0M5002C45 UE_HSUPA_TP07 WBTS, WN8.0M5002C46 UE_HSUPA_TP08 WBTS, WN8.0M5002C47 UE_HSUPA_TP09 WBTS, WN8.0M5002C48 UE_HSUPA_TP10 WBTS, WN8.0M5002C49 UE_HSUPA_TP11 WBTS, WN8.0M5002C126 MC_HSDPA_DATA_ACK_PRI WBTS, WN8.0M5002C128 MC_HSDPA_ORIG_DATA_PRI WBTS, WN8.0M5000C389 UNHAPPY_RES_FRACT_LOAD_06 WBTS, WN8.0M5002C127 MC_HSDPA_DATA_ACK_SEC WBTS, WN8.0M5000C388 UNHAPPY_RES_FRACT_LOAD_05 WBTS, WN8.0M5002C130 HSDPA_ORIG_DATA WBTS, WN8.0M5000C391 UNHAPPY_RES_FRACT_LOAD_08 WBTS, WN8.0M5002C129 MC_HSDPA_ORIG_DATA_SEC WBTS, WN8.0M5000C390 UNHAPPY_RES_FRACT_LOAD_07 WBTS, WN8.0M5000C393 UNHAPPY_RES_FRACT_LOAD_10 WBTS, WN8.0M5000C392 UNHAPPY_RES_FRACT_LOAD_09 WBTS, WN8.0M5000C395 UNHAPPY_RES_FRACT_LOAD_12 WBTS, WN8.0M5000C394 UNHAPPY_RES_FRACT_LOAD_11 WBTS, WN8.0M5002C64 ACTIVE_HSDPA_SPI_6 WBTS, WN8.0M5002C65 ACTIVE_HSDPA_SPI_7 WBTS, WN8.0M5002C66 ACTIVE_HSDPA_SPI_8 WBTS, WN8.0M5002C67 ACTIVE_HSDPA_SPI_9 WBTS, WN8.0M5002C60 ACTIVE_HSDPA_SPI_2 WBTS, WN8.0M5002C61 ACTIVE_HSDPA_SPI_3 WBTS, WN8.0M5002C62 ACTIVE_HSDPA_SPI_4 WBTS, WN8.0M5002C63 ACTIVE_HSDPA_SPI_5 WBTS, WN8.0M5000C426 CAPABLE_DC_MIMO_USERS_SUM WBTS, WN8.0M5000C425 ACTIVE_DC_MIMO_USERS_1C_SUM WBTS, WN8.0M5000C428 TTI_DCMIMO_HSDPA_USER_PC_1C_S WBTS, WN8.0M5000C427 TTI_DCMIMO_HSDPA_USER_PC_1C_D WBTS, WN8.0M5002C69 ACTIVE_HSDPA_SPI_11 WBTS, WN8.0M5000C422 MAX_EFACH_USERS WBTS, WN8.0M5002C68 ACTIVE_HSDPA_SPI_10 WBTS, WN8.0M5000C421 EFACH_UE_SUM WBTS, WN8.0M5000C424 ACTIVE_DC_MIMO_USERS_2C_SUM WBTS, WN8.0M5000C423 DND_CEDCH_RSRC WBTS, WN8.0M5000C420 SUM_OPER_TIME_HSFACH_DRX WBTS, WN8.0M5000C419 SUM_OPER_TIME_HSFACH_RX WBTS, WN8.0M5002C55 C_DATA_VOL_UL_EFACH WBTS, WN8.0M5002C56 U_DATA_TR_TIME_UL_EFACH WBTS, WN8.0M5002C53 C_DATA_TR_TIME_DL_EFACH WBTS, WN8.0M5002C54 U_DATA_VOL_UL_EFACH WBTS, WN8.0M5002C51 C_DATA_VOL_DL_EFACH WBTS, WN8.0M5002C52 U_DATA_TR_TIME_DL_EFACH WBTS, WN8.0M5000C418 HSDPA_USERS_FOUR_TTI WBTS, WN8.0M5002C50 U_DATA_VOL_DL_EFACH WBTS, WN8.0M5000C417 HSDPA_USERS_THREE_TTI WBTS, WN8.0M5000C416 HSDPA_USERS_TWO_TTI WBTS, WN8.0M5000C415 HSDPA_USERS_ONE_TTI WBTS, WN8.0M5000C403 UNHAPPY_RES_FRACT_LOAD_20 WBTS, WN8.0

M5000C402 UNHAPPY_RES_FRACT_LOAD_19 WBTS, WN8.0M5002C59 ACTIVE_HSDPA_SPI_1 WBTS, WN8.0M5000C401 UNHAPPY_RES_FRACT_LOAD_18 WBTS, WN8.0M5002C58 ACTIVE_HSDPA_SPI_0 WBTS, WN8.0M5000C400 UNHAPPY_RES_FRACT_LOAD_17 WBTS, WN8.0M5002C57 C_DATA_TR_TIME_UL_EFACH WBTS, WN8.0M5000C399 UNHAPPY_RES_FRACT_LOAD_16 WBTS, WN8.0M5000C398 UNHAPPY_RES_FRACT_LOAD_15 WBTS, WN8.0M5124C9 cacAvgReservedBitRate WBTS, WN8.0M5124C7 cacMaxReservedBitRate WBTS, WN8.0M5124C8 cacMinReservedBitRate WBTS, WN8.0M5001C4 MAX_USED_CE_UL WBTS, WN8.0M5001C5 MIN_USED_CE_DL WBTS, WN8.0M5001C2 AVG_AVAIL_CE WBTS, WN8.0M5001C3 MAX_USED_CE_DL WBTS, WN8.0M5001C8 AVG_USED_CE_UL WBTS, WN8.0M5001C9 MAX_HSUPA_CE_UL WBTS, WN8.0M5001C6 MIN_USED_CE_UL WBTS, WN8.0M5001C7 AVG_USED_CE_DL WBTS, WN8.0M5001C10 MIN_HSUPA_CE_UL WBTS, WN8.0M5001C11 AVG_HSUPA_CE_UL WBTS, WN8.0M5124C2 ifOutPackets WBTS, WN8.0M5124C1 ifInOctets WBTS, WN8.0M5124C0 ifInPackets WBTS, WN8.0M5124C6 ifIpDroppedPacketsFiltering WBTS, WN8.0M5124C5 ifIpDroppedPacketsRateLimiting WBTS, WN8.0M5124C4 ifInErrors WBTS, WN8.0M5124C3 ifOutOctets WBTS, WN8.0M5005C1 CQI_COMPENS_DIST_CL_1 WBTS, WN8.0M5005C2 CQI_COMPENS_DIST_CL_2 WBTS, WN8.0M5000C429 TTI_DCMIMO_HSDPA_USER_SC_1C_D WBTS, WN8.0M5000C430 TTI_DCMIMO_HSDPA_USER_SC_1C_S WBTS, WN8.0M5000C431 TTI_DCMIMO_HSDPA_USER_2C_D_D WBTS, WN8.0M5000C432 TTI_DCMIMO_HSDPA_USER_2C_D_S WBTS, WN8.0M5000C433 TTI_DCMIMO_HSDPA_USER_2C_S_D WBTS, WN8.0M5000C434 TTI_DCMIMO_HSDPA_USER_2C_S_S WBTS, WN8.0M5000C437 U_DATA_FRAMES_DL_EFACH WBTS, WN8.0M5000C438 C_DATA_FRAMES_DL_EFACH WBTS, WN8.0M5001C0 MAX_AVAIL_CE WBTS, WN8.0M5001C1 MIN_AVAIL_CE WBTS, WN8.0M5124C11 ifIpOutDropPackets WBTS, WN8.0M5124C10 cacMaxCommittedBitRate WBTS, WN8.0M5125C0 rxEthernetPackets WBTS, WN8.0M5124C12 ifIpOutDropOctets WBTS, WN8.0M5125C2 txEthernetPackets WBTS, WN8.0M5125C1 rxEthernetOctets WBTS, WN8.0M5005C0 CQI_COMPENS_DIST_CL_0 WBTS, WN8.0M5125C3 txEthernetOctets WBTS, WN8.0M5001C26 BTS_CE_TOTAL_UTIL_DL_CLASS_6 WBTS, WN8.0M5001C27 BTS_CE_HSPA_UTIL_UL_CLASS_1 WBTS, WN8.0M5001C24 BTS_CE_TOTAL_UTIL_DL_CLASS_4 WBTS, WN8.0M5001C25 BTS_CE_TOTAL_UTIL_DL_CLASS_5 WBTS, WN8.0M5001C22 BTS_CE_TOTAL_UTIL_DL_CLASS_2 WBTS, WN8.0M5001C23 BTS_CE_TOTAL_UTIL_DL_CLASS_3 WBTS, WN8.0

M5005C12 CQI_COMPENS_DIST_CL_12 WBTS, WN8.0M5001C30 BTS_CE_HSPA_UTIL_UL_CLASS_4 WBTS, WN8.0M5001C31 BTS_CE_HSPA_UTIL_UL_CLASS_5 WBTS, WN8.0M5001C28 BTS_CE_HSPA_UTIL_UL_CLASS_2 WBTS, WN8.0M5001C29 BTS_CE_HSPA_UTIL_UL_CLASS_3 WBTS, WN8.0M5005C3 CQI_COMPENS_DIST_CL_3 WBTS, WN8.0M5005C11 CQI_COMPENS_DIST_CL_11 WBTS, WN8.0M5005C10 CQI_COMPENS_DIST_CL_10 WBTS, WN8.0M5005C9 CQI_COMPENS_DIST_CL_9 WBTS, WN8.0M5005C8 CQI_COMPENS_DIST_CL_8 WBTS, WN8.0M5005C7 CQI_COMPENS_DIST_CL_7 WBTS, WN8.0M5005C6 CQI_COMPENS_DIST_CL_6 WBTS, WN8.0M5005C5 CQI_COMPENS_DIST_CL_5 WBTS, WN8.0M5005C4 CQI_COMPENS_DIST_CL_4 WBTS, WN8.0M5001C13 MIN_HSUPA_CE_DL WBTS, WN8.0M5001C14 AVG_HSUPA_CE_DL WBTS, WN8.0M5001C15 BTS_CE_TOTAL_UTIL_UL_CLASS_1 WBTS, WN8.0M5001C16 BTS_CE_TOTAL_UTIL_UL_CLASS_2 WBTS, WN8.0M5001C12 MAX_HSUPA_CE_DL WBTS, WN8.0M5001C21 BTS_CE_TOTAL_UTIL_DL_CLASS_1 WBTS, WN8.0M5001C17 BTS_CE_TOTAL_UTIL_UL_CLASS_3 WBTS, WN8.0M5001C18 BTS_CE_TOTAL_UTIL_UL_CLASS_4 WBTS, WN8.0M5001C19 BTS_CE_TOTAL_UTIL_UL_CLASS_5 WBTS, WN8.0M5001C20 BTS_CE_TOTAL_UTIL_UL_CLASS_6 WBTS, WN8.0M5005C14 CQI_COMPENS_DIST_CL_14 WBTS, WN8.0M5005C13 CQI_COMPENS_DIST_CL_13 WBTS, WN8.0M5005C20 CQI_COMPENS_DIST_CL_20 WBTS, WN8.0M5005C19 CQI_COMPENS_DIST_CL_19 WBTS, WN8.0M5005C22 CQI_COMPENS_DIST_CL_22 WBTS, WN8.0M5005C21 CQI_COMPENS_DIST_CL_21 WBTS, WN8.0M5005C16 CQI_COMPENS_DIST_CL_16 WBTS, WN8.0M5005C15 CQI_COMPENS_DIST_CL_15 WBTS, WN8.0M5005C18 CQI_COMPENS_DIST_CL_18 WBTS, WN8.0M5005C17 CQI_COMPENS_DIST_CL_17 WBTS, WN8.0M5106C1 totCellsEgressVC WBTS, WN8.0M5106C0 totCellsIngressVC WBTS, WN8.0M5105C4 discCells WBTS, WN8.0M5105C3 discHec WBTS, WN8.0M5105C2 uas WBTS, WN8.0M5105C1 totCellsEgress WBTS, WN8.0M5105C8 totUbrCellsEgress WBTS, WN8.0M5105C7 totUbrCellsIngress WBTS, WN8.0M5105C6 totCbrCellsEgress WBTS, WN8.0M5105C5 totCbrCellsIngress WBTS, WN8.0M5005C28 CQI_COMPENS_DIST_CL_28 WBTS, WN8.0M5002C120 SAMPLE_ALLOC_HSDPA_SPI_11 WBTS, WN8.0M5005C29 CQI_COMPENS_DIST_CL_29 WBTS, WN8.0M5002C121 SAMPLE_ALLOC_HSDPA_SPI_12 WBTS, WN8.0M5005C26 CQI_COMPENS_DIST_CL_26 WBTS, WN8.0M5005C27 CQI_COMPENS_DIST_CL_27 WBTS, WN8.0M5005C32 CQI_COMPENS_DIST_CL_32 WBTS, WN8.0M5002C124 SAMPLE_ALLOC_HSDPA_SPI_15 WBTS, WN8.0M5002C125 SAMPLE_ALLOC_HSDPA_ALL WBTS, WN8.0M5107C0 totCellsIngressVP WBTS, WN8.0

M5005C30 CQI_COMPENS_DIST_CL_30 WBTS, WN8.0M5002C122 SAMPLE_ALLOC_HSDPA_SPI_13 WBTS, WN8.0M5005C31 CQI_COMPENS_DIST_CL_31 WBTS, WN8.0M5002C123 SAMPLE_ALLOC_HSDPA_SPI_14 WBTS, WN8.0M5002C133 U_DATA_VOL_DL_DEC_PRIO_AAR WBTS, WN8.0M5002C134 U_DATA_VOL_UL_DEF_PRIO_AAR WBTS, WN8.0M5002C131 U_DATA_VOL_DL_DEF_PRIO_AAR WBTS, WN8.0M5002C132 U_DATA_VOL_DL_INC_PRIO_AAR WBTS, WN8.0M5005C24 CQI_COMPENS_DIST_CL_24 WBTS, WN8.0M5005C25 CQI_COMPENS_DIST_CL_25 WBTS, WN8.0M5005C23 CQI_COMPENS_DIST_CL_23 WBTS, WN8.0M5101C3 BBE_15 WBTS, WN8.0M5000C295 HSUPA_PWR_RATIO_DISTR_CLASS_03 WBTS, WN8.0M5101C2 SES_15 WBTS, WN8.0M5000C294 HSUPA_PWR_RATIO_DISTR_CLASS_02 WBTS, WN8.0M5000C297 HSUPA_PWR_RATIO_DISTR_CLASS_05 WBTS, WN8.0M5105C0 totCellsIngress WBTS, WN8.0M5000C296 HSUPA_PWR_RATIO_DISTR_CLASS_04 WBTS, WN8.0M5000C299 UNHAPPY_FRACT_LOAD_DISTR_C_00 WBTS, WN8.0M5000C298 AVG_HSUPA_DL_PWR_CONTR_CHN WBTS, WN8.0M5000C300 UNHAPPY_FRACT_LOAD_DISTR_C_01 WBTS, WN8.0M5001C32 BTS_CE_HSPA_UTIL_DL_CLASS_1 WBTS, WN8.0M5001C34 BTS_CE_HSPA_UTIL_DL_CLASS_3 WBTS, WN8.0M5001C33 BTS_CE_HSPA_UTIL_DL_CLASS_2 WBTS, WN8.0M5001C36 BTS_CE_HSPA_UTIL_DL_CLASS_5 WBTS, WN8.0M5001C35 BTS_CE_HSPA_UTIL_DL_CLASS_4 WBTS, WN8.0M5101C1 ES_15 WBTS, WN8.0M5101C0 UAS_15 WBTS, WN8.0M5005C37 MAX_DC_HSUPA_USERS WBTS, WN8.0M5005C38 ACTIVE_DCHSUPA_USERS_2C_SUM WBTS, WN8.0M5005C39 ACTIVE_DCHSUPA_USERS_1C_SUM WBTS, WN8.0M5005C40 PIC_ACTIVE WBTS, WN8.0M5002C110 SAMPLE_ALLOC_HSDPA_SPI_1 WBTS, WN8.0M5005C41 PIC_INACTIVE WBTS, WN8.0M5002C111 SAMPLE_ALLOC_HSDPA_SPI_2 WBTS, WN8.0M5005C42 N_SPI_PROMO_DL_AAR WBTS, WN8.0M5002C112 SAMPLE_ALLOC_HSDPA_SPI_3 WBTS, WN8.0M5002C113 SAMPLE_ALLOC_HSDPA_SPI_4 WBTS, WN8.0M5002C114 SAMPLE_ALLOC_HSDPA_SPI_5 WBTS, WN8.0M5002C115 SAMPLE_ALLOC_HSDPA_SPI_6 WBTS, WN8.0M5002C116 SAMPLE_ALLOC_HSDPA_SPI_7 WBTS, WN8.0M5002C117 SAMPLE_ALLOC_HSDPA_SPI_8 WBTS, WN8.0M5002C118 SAMPLE_ALLOC_HSDPA_SPI_9 WBTS, WN8.0M5005C33 CQI_COMPENS_DIST_CL_33 WBTS, WN8.0M5002C119 SAMPLE_ALLOC_HSDPA_SPI_10 WBTS, WN8.0M5005C34 CQI_COMPENS_DIST_CL_34 WBTS, WN8.0M5005C35 CQI_COMPENS_DIST_CL_35 WBTS, WN8.0M5005C36 DC_HSUPA_UE_SUM WBTS, WN8.0M5000C289 MAX_CPC_CONFIGURED_USERS WBTS, WN8.0M5000C288 SUM_CPC_CONFIGURED_USERS WBTS, WN8.0M5000C286 MAX_ACTIVE_CPC_USERS WBTS, WN8.0M5000C285 SUM_ACTIVE_CPC_USERS WBTS, WN8.0M5000C284 RETRANS_MAC_EHS_64QAM WBTS, WN8.0M5000C283 ORIG_TRANS_MAC_EHS_64QAM WBTS, WN8.0

M5000C282 DROP_MAC_D_PDU_OTH_REASON_656 WBTS, WN8.0M5000C281 DROP_MAC_D_PDU_OTH_REASON_TOT WBTS, WN8.0M5006C4 AVG_USED_R99_CE_DL WBTS, WN8.0M5006C2 MIN_AVAIL_R99_CE WBTS, WN8.0M5006C3 MAX_USED_R99_CE_DL WBTS, WN8.0M5006C0 MAX_AVAIL_R99_CE WBTS, WN8.0M5006C1 AVG_AVAIL_R99_CE WBTS, WN8.0M5005C46 N_SPI_DEMOT_UL_AAR WBTS, WN8.0M5000C292 NUMBER_OF_DPCCH_SLOTS WBTS, WN8.0M5005C47 N_SPI_DEF_UL_AAR WBTS, WN8.0M5000C293 HSUPA_PWR_RATIO_DISTR_CLASS_01 WBTS, WN8.0M5005C44 N_SPI_DEF_DL_AAR WBTS, WN8.0M5005C45 N_SPI_PROMO_UL_AAR WBTS, WN8.0M5000C291 NUMBER_OF_NON_DTX_DPCCH_SLOTS WBTS, WN8.0M5005C43 N_SPI_DEMOT_DL_AAR WBTS, WN8.0M5000C275 SAMPLE_HS_PDSCH_PWR_CLASS_08 WBTS, WN8.0M5000C274 SAMPLE_HS_PDSCH_PWR_CLASS_07 WBTS, WN8.0M5000C277 SAMPLE_HS_PDSCH_PWR_CLASS_10 WBTS, WN8.0M5000C276 SAMPLE_HS_PDSCH_PWR_CLASS_09 WBTS, WN8.0M5000C271 SAMPLE_HS_PDSCH_PWR_CLASS_04 WBTS, WN8.0M5110C3 EthIfOutPkt_15 WBTS, WN8.0M5000C270 SAMPLE_HS_PDSCH_PWR_CLASS_03 WBTS, WN8.0M5000C273 SAMPLE_HS_PDSCH_PWR_CLASS_06 WBTS, WN8.0M5000C272 SAMPLE_HS_PDSCH_PWR_CLASS_05 WBTS, WN8.0M5110C0 EthIfInOcts_15 WBTS, WN8.0M5102C7 bbeB315 WBTS, WN8.0M5110C2 EthIfInPkt_15 WBTS, WN8.0M5110C1 EthIfOutOcts_15 WBTS, WN8.0M5102C4 uasB315 WBTS, WN8.0M5107C1 totCellsEgressVP WBTS, WN8.0M5000C278 DROP_MAC_D_PDU_BTS_OWFL_656 WBTS, WN8.0M5102C6 sesB315 WBTS, WN8.0M5102C5 esB315 WBTS, WN8.0M5003C4 CCH_DATA_FROM_IUB WBTS, WN8.0M5003C5 DCH_DATA_TO_IUB WBTS, WN8.0M5003C6 DCH_DATA_FROM_IUB WBTS, WN8.0M5003C7 EDCH_DATA_TO_IUB WBTS, WN8.0M5002C135 U_DATA_VOL_UL_INC_PRIO_AAR WBTS, WN8.0M5002C136 U_DATA_VOL_UL_DEC_PRIO_AAR WBTS, WN8.0M5003C3 CCH_DATA_TO_IUB_INTERFACE WBTS, WN8.0M5000C279 DROP_MAC_D_PDU_MAX_RETX_TOT WBTS, WN8.0M5000C280 DROP_MAC_D_PDU_MAX_RETX_656 WBTS, WN8.0M5003C8 CCH_FP_REC_DATA_FRMS WBTS, WN8.0M5003C9 CCH_FP_FRMS_W_CRC_ERROR WBTS, WN8.0M5003C10 CCH_FP_FRMS_W_DELAY WBTS, WN8.0

NE counter nameMAC-HS PDU RETRANSMISSION DISTRIBUTION - CLASS 5DROPPED MAC-D PDUS DUE TO BTS OVERFLOWMAC-HS PDU RETRANSMISSION DISTRIBUTION - CLASS 3MAC-HS PDU RETRANSMISSION DISTRIBUTION - CLASS 4TOTAL NUMBER OF MAC-D PDUSREPORTED CQI DISTRIBUTION - CLASS 0REPORTED CQI DISTRIBUTION - CLASS 2REPORTED CQI DISTRIBUTION - CLASS 3REPORTED CQI DISTRIBUTION - CLASS 4REPORTED CQI DISTRIBUTION - CLASS 5MAC-HS PDU RETRANSMISSION DISTRIBUTION - CLASS 1MAC-HS PDU RETRANSMISSION DISTRIBUTION - CLASS 2REPORTED CQI DISTRIBUTION - CLASS 1MAC-HS PDU RETRANSMISSION DISTRIBUTION - CLASS 0CQI CORRELATED FOR MIMO DUAL STREAM CLASS12CQI CORRELATED FOR MIMO DUAL STREAM CLASS13REPORTED CQI DISTRIBUTION - CLASS 10CQI CORRELATED FOR MIMO DUAL STREAM CLASS16REPORTED CQI DISTRIBUTION - CLASS 7CQI CORRELATED FOR MIMO DUAL STREAM CLASS17REPORTED CQI DISTRIBUTION - CLASS 6CQI CORRELATED FOR MIMO DUAL STREAM CLASS14REPORTED CQI DISTRIBUTION - CLASS 9CQI CORRELATED FOR MIMO DUAL STREAM CLASS15REPORTED CQI DISTRIBUTION - CLASS 8HSDPA USERS 0 IN TARGET CELL 7 IN OTHER CELLHSDPA USERS 0 IN TARGET CELL 8 IN OTHER CELLCQI CORRELATED FOR MIMO DUAL STREAM CLASS18SUM OF USERS WITH ACTIVE MIMOHSDPA USERS 1 IN TARGET CELL 7 IN OTHER CELLHSDPA USERS 1 IN TARGET CELL 8 IN OTHER CELLHSDPA USERS 2 IN TARGET CELL 7 IN OTHER CELLHSDPA USERS 4 IN TARGET CELL 0 IN OTHER CELLHSDPA USERS 4 IN TARGET CELL 1 IN OTHER CELLHSDPA USERS 4 IN TARGET CELL 2 IN OTHER CELLHSDPA USERS 4 IN TARGET CELL 3 IN OTHER CELLHSDPA USERS 4 IN TARGET CELL 4 IN OTHER CELLHSDPA USERS 4 IN TARGET CELL 5 IN OTHER CELLMC HSDPA DATA RECEIVED IN MAC-D PDUSRESIDUAL STREAM FRACTIONAL LOAD CLASS 06REPORTED CQI DISTRIBUTION - CLASS 21REPORTED CQI DISTRIBUTION - CLASS 22REPORTED CQI DISTRIBUTION - CLASS 23REPORTED CQI DISTRIBUTION - CLASS 24REPORTED CQI DISTRIBUTION - CLASS 25REPORTED CQI DISTRIBUTION - CLASS 26REPORTED CQI DISTRIBUTION - CLASS 27RESIDUAL STREAM FRACTIONAL LOAD CLASS 02REPORTED CQI DISTRIBUTION - CLASS 29RESIDUAL STREAM FRACTIONAL LOAD CLASS 03REPORTED CQI DISTRIBUTION - CLASS 28RESIDUAL STREAM FRACTIONAL LOAD CLASS 00RESIDUAL STREAM FRACTIONAL LOAD CLASS 01

REPORTED CQI DISTRIBUTION - CLASS 30SUM OF CORRECTLY RECEIVED MAC-E PDUs WITH 16QAM ULSUM OF INCORRECTLY RECEIVED MAC-E PDUs WITH 16QAM ULMC HSDPA DATA DISCARDED IN MAC-D PDUSSUM OF ACTIVE 16QAM UL USERSRESIDUAL STREAM FRACTIONAL LOAD CLASS 04RESIDUAL STREAM FRACTIONAL LOAD CLASS 05MAC-HS PDU RETRANSMISSION WITH 7 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 6 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 8 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 13 CODE BY 16QAMORIGINAL MAC-HS PDU TRANSMISSION WITH 12 CODE BY 16QAMORIGINAL MAC-HS PDU TRANSMISSION WITH 15 CODE BY 16QAMORIGINAL MAC-HS PDU TRANSMISSION WITH 14 CODE BY 16QAMORIGINAL MAC-HS PDU TRANSMISSION WITH 9 CODE BY 16QAMREPORTED CQI DISTRIBUTION - CLASS 11REPORTED CQI DISTRIBUTION - CLASS 12RESIDUAL STREAM FRACTIONAL LOAD CLASS 17ORIGINAL MAC-HS PDU TRANSMISSION WITH 11 CODE BY 16QAMRESIDUAL STREAM FRACTIONAL LOAD CLASS 16ORIGINAL MAC-HS PDU TRANSMISSION WITH 10 CODE BY 16QAMREPORTED CQI DISTRIBUTION - CLASS 15REPORTED CQI DISTRIBUTION - CLASS 16REPORTED CQI DISTRIBUTION - CLASS 13REPORTED CQI DISTRIBUTION - CLASS 14RESIDUAL STREAM FRACTIONAL LOAD CLASS 11REPORTED CQI DISTRIBUTION - CLASS 20RESIDUAL STREAM FRACTIONAL LOAD CLASS 12REPORTED CQI DISTRIBUTION - CLASS 19RESIDUAL STREAM FRACTIONAL LOAD CLASS 13REPORTED CQI DISTRIBUTION - CLASS 18RESIDUAL STREAM FRACTIONAL LOAD CLASS 14REPORTED CQI DISTRIBUTION - CLASS 17RESIDUAL STREAM FRACTIONAL LOAD CLASS 07RESIDUAL STREAM FRACTIONAL LOAD CLASS 08RESIDUAL STREAM FRACTIONAL LOAD CLASS 09RESIDUAL STREAM FRACTIONAL LOAD CLASS 10RESIDUAL STREAM FRACTIONAL LOAD CLASS 15ORIGINAL MAC-HS PDU TRANSMISSION WITH 2 CODE BY 16QAMORIGINAL MAC-HS PDU TRANSMISSION WITH 1 CODE BY 16QAMORIGINAL MAC-HS PDU TRANSMISSION WITH 4 CODE BY 16QAMORIGINAL MAC-HS PDU TRANSMISSION WITH 3 CODE BY 16QAMMAC-HS PDU RETRANSMISSION WITH 11 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 3 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 12 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 2 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 9 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 5 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 10 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 4 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 15 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 6 CODE BY 16QAMMAC-HS PDU RETRANSMISSION WITH 13 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 1 CODE BY QPSK

MAC-HS PDU RETRANSMISSION WITH 14 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 7 CODE BY 16QAMMAC-HS PDU RETRANSMISSION WITH 8 CODE BY 16QAMUNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 17UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 16UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 15UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 14HSUPA MACE PDUS WITH 2MS TTIUNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 20UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 19UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 18UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 13ORIGINAL MAC-HS PDU TRANSMISSION WITH 5 CODE BY 16QAMUNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 12DISCARDED MAC-HS PDUS DUE TO T1 TIMERTTIS WITHOUT SENDING DATA FROM USER BUFFERUNSCHEDULED TTISMAC-HS PDU RETRANSMISSION WITH 9 CODE BY 16QAMMAXIMUM MAC-D PDU BUFFER DELAYMAC-HS PDU RETRANSMISSION WITH 10 CODE BY 16QAMMINIMUM MAC-D PDU BUFFER DELAYMAC-HS PDU RETRANSMISSION WITH 11 CODE BY 16QAMAVERAGE MAC-D PDU BUFFER DELAYMAC-HS PDU RETRANSMISSION WITH 12 CODE BY 16QAMMAC-D PDUS SIZE OF 656MAC-HS PDU RETRANSMISSION WITH 13 CODE BY 16QAMFAILED CQI DECODINGMAC-HS PDU RETRANSMISSION WITH 14 CODE BY 16QAMMAC-HS PDU RETRANSMISSION WITH 15 CODE BY 16QAMRECEIVED DATA IN MAC-D PDUSDISCARDED DATA IN MAC-D PDUSMAC-E PDU RETRANSMISSIONS 0 COUNTERSUM OF HSUPA USERS WITH 10MS TTISUM OF HSUPA USERS WITH 2MS TTICELL SPECIFIC USERS DENOMINATORHSUPA USERS DENOMINATORSUM OF ACTIVE DC HSDPA USERS WITH ONE CARRIERSUM OF ACTIVE DC HSDPA USERS WITH TWO CARRIERSSUM OF CAPABLE DC HSDPA USERSHSUPA MACE PDUS WITH 10MS TTIHSUPA MACE PDU DATA WITH 10MS TTIDISCARDED MAC-HS PDUS DUE TO MAX NUMBER OF RETRANSMISSIONSHSUPA MACE PDU DATA WITH 2MS TTIDISCARDED MAC-HS PDUS DUE TO OTHER REASONMAC-E PDU RETRANSMISSIONS 5 COUNTERHS-SCCH POWER DISTRIBUTION - CLASS 4MAC-E PDU RETRANSMISSIONS 6 COUNTERHS-SCCH POWER DISTRIBUTION - CLASS 3MAC-E PDU RETRANSMISSIONS 3 COUNTERSUM OF HS-SCCH POWERMAC-E PDU RETRANSMISSIONS 4 COUNTERHS-SCCH POWER DISTRIBUTION - CLASS 5MAC-E PDU RETRANSMISSIONS 1 COUNTERHSDPA USERS 0 IN TARGET CELL 2 IN OTHER CELL

MAC-E PDU RETRANSMISSIONS 2 COUNTERHSDPA USERS 0 IN TARGET CELL 1 IN OTHER CELLHSDPA USERS 0 IN TARGET CELL 3 IN OTHER CELLMAC-E PDU RETRANSMISSIONS 9 COUNTERHS-SCCH POWER DISTRIBUTION - CLASS 0MAC-E PDU RETRANSMISSIONS 10 COUNTERMAC-E PDU RETRANSMISSIONS 7 COUNTERHS-SCCH POWER DISTRIBUTION - CLASS 2MAC-E PDU RETRANSMISSIONS 8 COUNTERHS-SCCH POWER DISTRIBUTION - CLASS 1CQI CORRELATED FOR MIMO DUAL STREAM CLASS1CQI CORRELATED FOR MIMO DUAL STREAM CLASS0MAC-EHS PDU RETRANSMISSION WITH MIMO DUAL STREAMORIGINAL MAC-EHS PDU TRANSMISSION WITH MIMO DUAL STREAMTTIS SCHEDULED FOR MIMO USERS WITH DUAL STREAMTTIS SCHEDULED FOR MIMO USERS WITH SINGLE STREAMTTI SCHEDULED DC HSDPA USER FOR SECONDARY CARRIER WITH TWO CARRIERTTI SCHEDULED DC HSDPA USER FOR PRIMARY CARRIER WITH TWO CARRIERTTI SCHEDULED DC HSDPA USER FOR SECONDARY CARRIER WITH ONE CARRIERTTI SCHEDULED DC HSDPA USER FOR PRIMARY CARRIER WITH ONE CARRIERMAC-E PDU HARQ FAILURE COUNTERMAC-HS PDU RETRANSMISSION WITH 1 CODE BY 16QAMMAC-E PDU LOST COUNTERMAC-HS PDU RETRANSMISSION WITH 5 CODE BY QPSKMAC-E PDU RETRANSMISSIONS UNKNOWN COUNTERMAC-HS PDU RETRANSMISSION WITH 4 CODE BY QPSKHSUPA DL PHYSICAL CHANNEL POWER DISTRIBUTION - CLASS 01MAC-HS PDU RETRANSMISSION WITH 3 CODE BY QPSKMAC-HS PDU RETRANSMISSION WITH 5 CODE BY 16QAMMAC-E PDU RETRANSMISSIONS 11 COUNTERMAC-HS PDU RETRANSMISSION WITH 4 CODE BY 16QAMMAC-E PDU RETRANSMISSIONS 12 COUNTERMAC-HS PDU RETRANSMISSION WITH 3 CODE BY 16QAMMAC-E PDU DTX COUNTERMAC-HS PDU RETRANSMISSION WITH 2 CODE BY 16QAMHSUPA DL PHYSICAL CHANNEL POWER DISTRIBUTION - CLASS 02MAC-HS PDU RETRANSMISSION WITH 2 CODE BY QPSKHSUPA DL PHYSICAL CHANNEL POWER DISTRIBUTION - CLASS 03MAC-HS PDU RETRANSMISSION WITH 1 CODE BY QPSKHSUPA DL PHYSICAL CHANNEL POWER DISTRIBUTION - CLASS 04CQI CORRELATED FOR MIMO DUAL STREAM CLASS11CQI CORRELATED FOR MIMO DUAL STREAM CLASS8CQI CORRELATED FOR MIMO DUAL STREAM CLASS7CQI CORRELATED FOR MIMO DUAL STREAM CLASS10CQI CORRELATED FOR MIMO DUAL STREAM CLASS9CQI CORRELATED FOR MIMO DUAL STREAM CLASS4CQI CORRELATED FOR MIMO DUAL STREAM CLASS3CQI CORRELATED FOR MIMO DUAL STREAM CLASS6CQI CORRELATED FOR MIMO DUAL STREAM CLASS5CQI CORRELATED FOR MIMO DUAL STREAM CLASS2ifPackets_BEifDroppedOctets_BEifDroppedPackets_BEifRxOctets_EF

ifRxPackets_EFORIGINAL MAC-HS PDU TRANSMISSION WITH 12 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 13 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 10 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 11 CODE BY QPSKORIGINAL MAC-HS PDU TRANSMISSION WITH 9 CODE BY QPSKifOctets_AF1ORIGINAL MAC-HS PDU TRANSMISSION WITH 8 CODE BY 16QAMifDroppedOctets_AF1ORIGINAL MAC-HS PDU TRANSMISSION WITH 6 CODE BY 16QAMifPackets_AF1ORIGINAL MAC-HS PDU TRANSMISSION WITH 7 CODE BY 16QAMifOctets_BEORIGINAL MAC-HS PDU TRANSMISSION WITH 14 CODE BY QPSKifDroppedPackets_AF1ORIGINAL MAC-HS PDU TRANSMISSION WITH 15 CODE BY QPSKifRxOctets_BEifRxPackets_BEifRxOctets_AF1ifRxPackets_AF1HSDPA USERS 1 IN TARGET CELL 0 IN OTHER CELLHSDPA USERS 1 IN TARGET CELL 1 IN OTHER CELLHSDPA USERS 1 IN TARGET CELL 2 IN OTHER CELLHSDPA USERS 2 IN TARGET CELL 0 IN OTHER CELLifRxPackets_AF4ORIGINAL MAC-HS PDU TRANSMISSION WITH 7 CODE BY QPSKifRxOctets_AF4ORIGINAL MAC-HS PDU TRANSMISSION WITH 8 CODE BY QPSKifRxPackets_AF2HSDPA USERS 2 IN TARGET CELL 1 IN OTHER CELLifRxOctets_AF2HSDPA USERS 3 IN TARGET CELL 0 IN OTHER CELLifRxPackets_AF3HSDPA USER BUFFERS WITH DATA IN THE BUFFER FOR EACH TTIifRxOctets_AF3ORIGINAL MAC-HS PDU TRANSMISSION WITH 6 CODE BY QPSKUNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 02ifDroppedOctets_AF2ifDroppedPackets_AF2ifOctets_AF2ifPackets_AF2ifDroppedOctets_AF3ifDroppedPackets_AF3UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 09UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 10UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 07UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 08UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 05UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 06UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 03UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 04UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 11ifPackets_AF3ifOctets_AF3

ifDroppedPackets_AF4ifDroppedOctets_AF4trafficSelectorMismatchespCryptographicErrors

sentESPPackets

receivedPacketMatchDefPolsentPacketMatchDefPolrecvUnprotPacketMatchProtPolreceivedPacketMatchDiscPolreceivedPacketMatchBypassPolfailedSAEstablishmentsreceivedESPpacketssentPacketBypassPolsentPacketMatchDiscPolantiReplayErrorsifRxOctets_AF3ifRxPackets_AF4ifRxOctets_AF2ifRxPackets_AF3ifRxPackets_BEipsecSaNotFoundifRxPackets_AF2ifRxOctets_AF1ifRxPackets_AF1ifRxOctets_BECES_OutOfSyncPacketsCES_Packets_RxCES_EarlyPacketsCES_LostPacketsCES_Packets_TxCES_LatePackets_PWCES_OutOfSyncPackets_PWethIfOutDiscShaping_AF3CES_LatePacketsethIfOutDiscShaping_AF2CES_LBit_Packets_PWCES_LostPackets_PWethIfOutDiscShaping_AF4EthUnknownPSNHdr_15EthIfUas_15EthIfSes_15ethIfOutDiscShaping_AF1EthIfInPktErr_15EthIfOutDiscShaping_15EthIfInUnknownVLAN_15ifRxPackets_AF1ifRxOctets_AF1ifRxPackets_AF2ifRxOctets_AF2AVERAGE RL SETUP MESSAGE QUEUING TIMEPEAK RL OPERATIONS PER SECONDPEAK RL SETUPS PER SECOND

NUMBER OF REJECTED RL SETUPS DUE TO CONGESTIONifRxPackets_BEifRxOctets_BEifOctets_BEifDroppedOctets_BEifPackets_BEifRxOctets_EFifDroppedPackets_BEifRxOctets_AF4ifRxPackets_EFifRxOctets_AF3ifRxPackets_AF4ifRxPackets_AF3ifPackets_AF1ifDroppedOctets_AF1ifDroppedPackets_AF1ifOctets_BEifPackets_BEifDroppedOctets_BEifDroppedPackets_BEifRxOctets_EFifRxPackets_EFifRxOctets_AF4ifDroppedPackets_AF3ifDroppedOctets_AF3ifDroppedPackets_AF2ifDroppedOctets_AF2ifPackets_AF2ifOctets_AF2ifDroppedPackets_AF1ifDroppedOctets_AF1ifPackets_AF1ifOctets_AF1ifPackets_AF4ifDroppedOctets_AF4ifDroppedPackets_AF4ifOctets_AF3ifPackets_EFifDroppedOctets_EFifDroppedPackets_EFifOctets_AF4ifOctets_EFifDroppedOctets_AF4vcBdlInBwUtiClass1ifPackets_AF4vcBdlInBwUtiClass3vcBdlInBwUtiClass2ifDroppedOctets_EFifPackets_EFifOctets_AF4ifDroppedPackets_EFifRxOctets_BEPwtUnknownPWHdr_15ifRxPackets_AF1

vcBdlInPeakThrputifOctets_EFifRxPackets_BEPwtPktRecv_15vcBdlInBwUtiClass5ifPackets_AF3vcBdlInBwUtiClass4vcBdlOutPeakThrputvcBdlBwConfigcacAvgReservedBitRatecacMaxCommittedBitRatecacMaxReservedBitRatecacMinReservedBitRateifIpDroppedPacketsRateLimitingifIpDroppedPacketsFilteringifOutOctets15ifInErrors15vcOutBwConfigvcInBwUtiClass5ifOctets_AF1ifDroppedPackets_AF2ifDroppedOctets_AF2ifPackets_AF2ifOctets_AF2ifDroppedPackets_AF3vcBdlOutBwUtiClass5ifDroppedOctets_AF3vcBdlOutBwUtiClass4ifPackets_AF3vcBdlOutBwUtiClass3ifOctets_AF3vcBdlOutBwUtiClass2ifDroppedPackets_AF4vcBdlOutBwUtiClass1vcInPeakThrputifIpOutDropOctetsvcOutPeakThrputifIpOutDropPacketsvcInBwConfigvcInBwUtiClass4Maximum AAL2 buffering delay priority queue 3Maximum AAL2 buffering delay priority queue 4topSLS15topMinPhaseError15topAvePhaseError15topMaxPhaseError15topRxSyncMsg15ifOctets_AF1ifDroppedPackets_AF2ifDroppedOctets_AF1ifPackets_AF1ifOctets_BEifDroppedPackets_AF1ifDroppedOctets_BE

EthIfInBlocksDiscRateLimitingifPackets_BEifInOctets15vcOutBwUtiClass2ifInPackets15vcOutBwUtiClass1vcOutBwUtiClass4ifOutPackets15vcOutBwUtiClass3vcInBwUtiClass1vcOutBwUtiClass5ifDroppedOctets_AF2vcInBwUtiClass3ifPackets_AF2vcInBwUtiClass2Dropped bytes due to AAL2 priorisation buffer overflow priority queue 1Dropped bytes due to AAL2 priorisation buffer overflow priority queue 2ethIfOutDiscShaping_Q1ethIfOutDiscShaping_Q6Average AAL2 buffering delay priority queue 1Average AAL2 buffering delay priority queue 2Dropped bytes due to AAL2 priorisation buffer overflow priority queue 3Dropped bytes due to AAL2 priorisation buffer overflow priority queue 4ifRxPackets_AF3ifRxOctets_AF3ifRxPackets_AF4ifRxOctets_AF4ifRxOctets_AF1ifRxPackets_AF2ifRxOctets_AF2Maximum AAL2 buffering delay priority queue 2EthIfInDiscRateLimitingMaximum AAL2 buffering delay priority queue 1ethIfInVlanMismatchAverage AAL2 buffering delay priority queue 4ethIfOutDiscShaping_BEAverage AAL2 buffering delay priority queue 3ethIfOutDiscShaping_EFifRxPackets_EFethIfOutDiscShaping_Q2ifRxOctets_EFethIfOutDiscShaping_Q3ifDroppedPackets_BEethIfOutDiscShaping_Q4ethIfOutDiscShaping_Q5HSDPA USERS 2 IN TARGET CELL 6 IN OTHER CELLHSDPA USERS 3 IN TARGET CELL 1 IN OTHER CELLTOTAL HSUPA DATA FOR SPI 12TOTAL HSUPA DATA FOR SPI 10TOTAL HSUPA DATA FOR SPI 11TOTAL HSUPA DATA FOR SPI 8TOTAL HSUPA DATA FOR SPI 9TOTAL HSUPA DATA FOR SPI 6TOTAL HSUPA DATA FOR SPI 7

TOTAL HSUPA DATA FOR SPI 4TOTAL HSUPA DATA FOR SPI 5TOTAL HSUPA DATA FOR SPI 3CONFIGURED CCCH PROCESSING SETS IN WBTSUSED CCCH PROCESSING SETS IN WBTSCONFIGURED HSUPA THROUGHPUTCONFIGURED HSDPA THROUGHPUTCONFIGURED HSUPA USERSCONFIGURED HSDPA USERSNUMBER OF SUBUNITS IN BASEBANDMAXIMUM NUMBER OF USED BASEBAND SUBUNITSHSDPA USERS 2 IN TARGET CELL 5 IN OTHER CELLAVERAGE NUMBER OF USED BASEBAND SUBUNITSHSDPA USERS 2 IN TARGET CELL 4 IN OTHER CELLMINIMUM NUMBER OF USED BASEBAND SUBUNITSHSDPA USERS 2 IN TARGET CELL 3 IN OTHER CELLHSDPA USERS 2 IN TARGET CELL 2 IN OTHER CELLHSDPA USERS 1 IN TARGET CELL 6 IN OTHER CELLHSDPA USERS 1 IN TARGET CELL 5 IN OTHER CELLHSDPA USERS 1 IN TARGET CELL 4 IN OTHER CELLHSDPA USERS 1 IN TARGET CELL 3 IN OTHER CELLHSDPA USERS 0 IN TARGET CELL 6 IN OTHER CELLHSDPA USERS 0 IN TARGET CELL 5 IN OTHER CELLHS_TOTAL_DATATOTAL HSUPA DATA FOR SPI 0TOTAL HSUPA DATA FOR SPI 1TOTAL HSUPA DATA FOR SPI 2TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 12TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 13TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 14TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 15TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 10TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 11Bypassed_FramesRxBypassed_FramesTxavgRTT_15MinProtected_ESPFramesRxHSDPA USERS 0 IN TARGET CELL 4 IN OTHER CELLProtected_ESPFramesTxHSUPA UL PHYSICAL CHANNEL POWER SAMPLE COUNTERDiscarded_ESPFramesRxDiscarded_ESPFramesTxLICENSED CCCH PROCESSING SETS IN WBTSHSUPA UL MINIMUM PHYSICAL CHANNEL POWERHSUPA AVERAGE MAC-D THROUGHPUTHSUPA MAC-E DATA VOLUME PER OPERATORHSUPA UL AVERAGE PHYSICAL CHANNEL POWERHSDPA MAC-HS DATA VOLUME PER OPERATORHSUPA UL MAXIMUM PHYSICAL CHANNEL POWERHSUPA DL PHYSICAL CHANNEL POWER DISTRIBUTION - CLASS 06HSUPA DL PHYSICAL CHANNEL POWER DISTRIBUTION - CLASS 05HSUPA MAXIMUM MAC-D THROUGHPUTHSUPA MINIMUM MAC-D THROUGHPUTTOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 7

TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 8TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 5TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 6UE SERVING POWER HEADROOM VALUE 11UE SERVING POWER HEADROOM VALUE 12TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 9UE SERVING POWER HEADROOM VALUE 09UE SERVING POWER HEADROOM VALUE 10TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 0MAXIMUM HSDPA PROCESSING SETS UTILIZATION RATIOMINIMUM HSUPA PROCESSING SETS UTILIZATION RATIOTOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 3TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 4TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 1TOTAL ACKNOWLEDGED DATA IN MAC-HS PDUS FOR SPI 2MINIMUM NUMBER OF HSDPA USERSMAXIMUM NUMBER OF HSUPA USERSAVERAGE NUMBER OF HSUPA USERSMINIMUM NUMBER OF HSUPA USERSAVERAGE HSDPA PROCESSING SETS UTILIZATION RATIOMINIMUM HSDPA PROCESSING SETS UTILIZATION RATIOMAXIMUM NUMBER OF HSDPA USERSAVERAGE NUMBER OF HSDPA USERSUE SERVING POWER HEADROOM VALUE 05UE SERVING POWER HEADROOM VALUE 04UE SERVING POWER HEADROOM VALUE 03UE SERVING POWER HEADROOM VALUE 02UE SERVING POWER HEADROOM VALUE 08UE SERVING POWER HEADROOM VALUE 07UE SERVING POWER HEADROOM VALUE 06Pseudowire_packet_lossCCH DATA VOLUME FOR CELL ULCCH DATA VOLUME FOR CELL DLE-DCH DATA VOLUME FOR SERVING CELL ULE-DCH DATA VOLUME FOR NON-SERVING CELL IN SERVING E-DCH RLS ULE-DCH DATA VOLUME FOR NON-SERVING CELL IN NON-SERVING E-DCH RLS ULHS-DSCH CREDIT REDUCTIONS DUE TO MAC-HS BUFFER FILLINGUE SERVING POWER HEADROOM VALUE 00UE SERVING POWER HEADROOM VALUE 01MAXIMUM HSUPA SUBUNITS USAGEPwtPktTransm_15PwtPktLost_15PwUas_15PwSes_15LICENSED HARDWARE CAPACITY UTILIZATION RATIOMAXIMUM HSUPA PROCESSING SETS UTILIZATION RATIOLICENSED HSUPA THROUGHPUTLICENSED HSDPA THROUGHPUTLICENSED NUMBER OF HSUPA USERSLICENSED NUMBER OF HSDPA USERSAVERAGE HSUPA SUBUNITS USAGEMINIMUM HSUPA SUBUNITS USAGEHSDPA USERS 3 IN TARGET CELL 3 IN OTHER CELLHSDPA USERS 3 IN TARGET CELL 2 IN OTHER CELL

HSDPA USERS 3 IN TARGET CELL 5 IN OTHER CELLHSDPA USERS 3 IN TARGET CELL 4 IN OTHER CELLHS-DSCH CREDIT REDUCTIONS DUE TO IUB DELAYHSDPA USERS 3 IN TARGET CELL 6 IN OTHER CELLAVERAGE HSUPA PROCESSING SETS UTILIZATION RATIOHS-DSCH CREDIT REDUCTIONS DUE TO FRAME LOSSHS-DSCH CREDIT REDUCTIONS DUE TO SEVERE IUB DELAYUNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 02UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 01UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 04UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 03RESIDUAL STREAM FRACTIONAL LOAD CLASS 19RESIDUAL STREAM FRACTIONAL LOAD CLASS 18UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 00RESIDUAL STREAM FRACTIONAL LOAD CLASS 20UE SERVING POWER HEADROOM VALUE 17UE SERVING POWER HEADROOM VALUE 18UE SERVING POWER HEADROOM VALUE 13UE SERVING POWER HEADROOM VALUE 14UE SERVING POWER HEADROOM VALUE 15UE SERVING POWER HEADROOM VALUE 16txTwampMessageslostTwampMessagesmaxRTT_15MinminRTT_15MinpppTxPacketspppRxPacketspppTxOctetspppRxOctetspppDiscardedPacketspppTxOctetsTOTAL HSUPA DATA FOR SPI 14TOTAL HSUPA DATA FOR SPI 13UE HSUPA THROUGHPUT CLASS 00TOTAL HSUPA DATA FOR SPI 15UE HSUPA THROUGHPUT CLASS 02UE HSUPA THROUGHPUT CLASS 01UE HSUPA THROUGHPUT CLASS 04UE HSUPA THROUGHPUT CLASS 03UE HSUPA THROUGHPUT CLASS 06UE HSUPA THROUGHPUT CLASS 05ifDroppedOctets_EFifDroppedPackets_EFifOctets_AF4ifPackets_AF4CES_EarlyPackets_PWCES_MinDelay_PWCES_MaxDelay_PWCES_Avg_Delay_PWifOctets_EFifPackets_EFFRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 13FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 11FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 12

FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 09FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 10FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 07FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 08FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 05FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 06FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 04SAMPLES IN HS-PDSCH POWER CLASS 02HSUPA NUMBER OF UNHAPPY BITSSAMPLES IN HS-PDSCH POWER CLASS 01FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 18FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 19FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 20HSUPA NUMBER OF HAPPY BITSFRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 14FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 15FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 16FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 17AVERAGE NUMBER OF USED R99 CE FOR ULMAXIMUM NUMBER OF USED R99 CE FOR ULMINIMUM NUMBER OF USED R99 CE FOR DLBTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 2UE NON-SERVING POWER HEADROOM VALUE 24BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 3UE NON-SERVING POWER HEADROOM VALUE 25MINIMUM NUMBER OF USED R99 CE FOR ULUE NON-SERVING POWER HEADROOM VALUE 22BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 1UE NON-SERVING POWER HEADROOM VALUE 23BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 6BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 4UE NON-SERVING POWER HEADROOM VALUE 26BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 5UE NON-SERVING POWER HEADROOM VALUE 17UE NON-SERVING POWER HEADROOM VALUE 20UE NON-SERVING POWER HEADROOM VALUE 21UE NON-SERVING POWER HEADROOM VALUE 18UE NON-SERVING POWER HEADROOM VALUE 19FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 00FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 01FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 02FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 03UE NON-SERVING POWER HEADROOM VALUE 27UE NON-SERVING POWER HEADROOM VALUE 28UE NON-SERVING POWER HEADROOM VALUE 29UE NON-SERVING POWER HEADROOM VALUE 30UE NON-SERVING POWER HEADROOM VALUE 31NON-SERVING E-RGCH COMMANDSBTS HSPA USER AMOUNT UTILIZATION IN UL - CLASS 2BTS HSPA USER AMOUNT UTILIZATION IN UL - CLASS 3MINIMUM NUMBER OF USED CSOHSPA R99 CEBTS HSPA USER AMOUNT UTILIZATION IN UL - CLASS 1AVERAGE NUMBER OF USED CSOHSPA R99 CEUE SERVING POWER HEADROOM VALUE 31

UE SERVING POWER HEADROOM VALUE 30UE SERVING POWER HEADROOM VALUE 29UE NON-SERVING POWER HEADROOM VALUE 06UE NON-SERVING POWER HEADROOM VALUE 05BTS HSPA USER AMOUNT UTILIZATION IN DL - CLASS 2UE NON-SERVING POWER HEADROOM VALUE 04BTS HSPA USER AMOUNT UTILIZATION IN DL - CLASS 1UE NON-SERVING POWER HEADROOM VALUE 03BTS HSPA USER AMOUNT UTILIZATION IN UL - CLASS 6UE NON-SERVING POWER HEADROOM VALUE 02BTS HSPA USER AMOUNT UTILIZATION IN UL - CLASS 5UE NON-SERVING POWER HEADROOM VALUE 01BTS HSPA USER AMOUNT UTILIZATION IN UL - CLASS 4UE NON-SERVING POWER HEADROOM VALUE 00BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 1BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 2BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 3BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 4UE NON-SERVING POWER HEADROOM VALUE 08UE NON-SERVING POWER HEADROOM VALUE 07UE NON-SERVING POWER HEADROOM VALUE 10UE NON-SERVING POWER HEADROOM VALUE 09MAXIMUM NUMBER OF USED CSOHSPA R99 CEUE NON-SERVING POWER HEADROOM VALUE 16MINIMUM NUMBER OF AVAILABLE CSOHSPA R99 CHANNEL ELEMENTSUE NON-SERVING POWER HEADROOM VALUE 15BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 6UE NON-SERVING POWER HEADROOM VALUE 12BTS R99 CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 5UE NON-SERVING POWER HEADROOM VALUE 11AVERAGE NUMBER OF AVAILABLE CSOHSPA R99 CHANNEL ELEMENTSUE NON-SERVING POWER HEADROOM VALUE 14MAXIMUM NUMBER OF AVAILABLE CSOHSPA R99 CHANNEL ELEMENTSUE NON-SERVING POWER HEADROOM VALUE 13MINIMUM USED CES FOR ULAVERAGE USED CES FOR ULMAXIMUM USED CES FOR DLAVERAGE USED CE FOR R99 DLMAXIMUM USED CE FOR R99 DLMAXIMUM USED CES FOR ULMINIMUM USED CE FOR R99 DLMAXIMUM USED CE FOR R99 ULAVERAGE USED CE FOR R99 ULMINIMUM USED CE FOR R99 ULBTS HSPA USER AMOUNT UTILIZATION IN DL - CLASS 3BTS HSPA USER AMOUNT UTILIZATION IN DL - CLASS 4BTS HSPA USER AMOUNT UTILIZATION IN DL - CLASS 5BTS HSPA USER AMOUNT UTILIZATION IN DL - CLASS 6HSDPA MAXIMUM MAC-HS THROUGHPUTHSDPA AVERAGE MAC-HS THROUGHPUTUE SERVING POWER HEADROOM VALUE 20UE SERVING POWER HEADROOM VALUE 19HSUPA AVERAGE MAC-E THROUGHPUTUE SERVING POWER HEADROOM VALUE 22

HSUPA MAXIMUM MAC-E THROUGHPUTUE SERVING POWER HEADROOM VALUE 21AVERAGE USED CES FOR DLUE SERVING POWER HEADROOM VALUE 24MINIMUM USED CES FOR DLUE SERVING POWER HEADROOM VALUE 23UE SERVING POWER HEADROOM VALUE 26UE SERVING POWER HEADROOM VALUE 25UE SERVING POWER HEADROOM VALUE 28UE SERVING POWER HEADROOM VALUE 27txRstpBpdusrxRstpBpdusportStateTransitionstopFreqSynchSLStopMinFreqSynchErrorpppTxPacketspppDiscardedPacketspppRxPacketsethIfOutDiscShapingpppRxOctetsHS-DSCH FP DATA FRAMES DISCARDED DUE TO OTHER REASONSMAC-E PDU LOSTHS-DSCH FP DATA FRAMES SUCCESSFULLY RECEIVEDHS-DSCH FP DATA FRAMES DISCARDED DUE TO HEADER CRC ERRORHS-DSCH DATA VOLUME FROM IUB-INTERFACECCH FP DATA FRAMES DISCARDED DUE TO OTHER REASONSDCH FP DATA FRAMES DISCARDED DUE TO OTHER REASONSDCH FP DATA FRAMES DISCARDED DUE TO TOO HIGH DELAYDCH FP DATA FRAMES DISCARDED DUE TO HEADER CRC ERRORDCH FP DATA FRAMES SUCCESSFULLY RECEIVEDifOutPackets15ifInOctets15ifOutOctets15cacMaxCommittedBitRateifIpOutDropPacketsifIpOutDropOctetsifInPackets15cacMaxReservedBitRatecacMinReservedBitRatecacAvgReservedBitRateifInErrors15ifOutOctets15ifOutPackets15ifInOctets15ifIpDroppedPacketsFilteringifInPackets15topRxFreqSyncMsgifIpDroppedPacketsRateLimitingtopAvgsFreqSynchErrortopMaxFreqSynchErrorifOctets_AF2ifOctets_AF4ifPackets_AF4ifDroppedOctets_AF4

ifDroppedPackets_AF4ifOctets_AF3ifPackets_AF3ifDroppedOctets_AF3ifDroppedPackets_AF3ifDroppedPackets_EFifDroppedOctets_EFifPackets_EFcacMinReservedBitRatecacAvgReservedBitRateifInErrors15cacMaxReservedBitRateifIpOutDropOctetsifOctets_EFcacMaxCommittedBitRateifIpOutDropPacketsSAMPLES FOR ACTIVE HSDPA USERS IN SPI 8SAMPLES FOR ACTIVE HSDPA USERS IN SPI 7SAMPLES FOR ACTIVE HSDPA USERS IN SPI 10SAMPLES FOR ACTIVE HSDPA USERS IN SPI 9SAMPLES FOR ACTIVE HSDPA USERS IN SPI 12SAMPLES FOR ACTIVE HSDPA USERS IN SPI 11SAMPLES FOR ACTIVE HSDPA USERS IN SPI 14SAMPLES FOR ACTIVE HSDPA USERS IN SPI 13SAMPLES FOR ACTIVE HSDPA USERS IN SPI 6SAMPLES FOR ACTIVE HSDPA USERS IN SPI 5ALL ACTIVE HSDPA USERSACTIVE HSDPA USERS IN SPI 15ACTIVE HSDPA USERS IN SPI 14ACTIVE HSDPA USERS IN SPI 13SAMPLES FOR ACTIVE HSDPA USERS IN SPI 3SAMPLES FOR ACTIVE HSDPA USERS IN SPI 2SAMPLES FOR ACTIVE HSDPA USERS IN SPI 1SAMPLES FOR ACTIVE HSDPA USERS IN SPI 0ACTIVE HSDPA USERS IN SPI 12SAMPLES FOR ACTIVE HSDPA USERS IN SPI 4SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 0ALL ALLOCATED HSDPA USERSALLOCATED HSDPA USERS IN SPI 13ALLOCATED HSDPA USERS IN SPI 12ALLOCATED HSDPA USERS IN SPI 15ALLOCATED HSDPA USERS IN SPI 14ALLOCATED HSDPA USERS IN SPI 9ALLOCATED HSDPA USERS IN SPI 8ALLOCATED HSDPA USERS IN SPI 11ALLOCATED HSDPA USERS IN SPI 10ALLOCATED HSDPA USERS IN SPI 7ALLOCATED HSDPA USERS IN SPI 6ALLOCATED HSDPA USERS IN SPI 5ALLOCATED HSDPA USERS IN SPI 4ALLOCATED HSDPA USERS IN SPI 3ALLOCATED HSDPA USERS IN SPI 2ALLOCATED HSDPA USERS IN SPI 1ALLOCATED HSDPA USERS IN SPI 0

SAMPLES FOR ALL ACTIVE HSDPA USERSSAMPLES FOR ACTIVE HSDPA USERS IN SPI 15UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 13UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 14UE HSUPA THROUGHPUT CLASS 07UE HSUPA THROUGHPUT CLASS 08UE HSUPA THROUGHPUT CLASS 09UE HSUPA THROUGHPUT CLASS 10UE HSUPA THROUGHPUT CLASS 11ACKNOWLEDGED MC HSDPA DATA FOR PRIMARY CELLORIGINAL MC HSDPA DATA FOR PRIMARY CELLUNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 06ACKNOWLEDGED MC HSDPA DATA FOR SECONDARY CELLUNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 05ORIGINAL HSDPA DATAUNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 08ORIGINAL MC HSDPA DATA FOR SECONDARY CELLUNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 07UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 10UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 09UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 12UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 11ACTIVE HSDPA USERS IN SPI 6ACTIVE HSDPA USERS IN SPI 7ACTIVE HSDPA USERS IN SPI 8ACTIVE HSDPA USERS IN SPI 9ACTIVE HSDPA USERS IN SPI 2ACTIVE HSDPA USERS IN SPI 3ACTIVE HSDPA USERS IN SPI 4ACTIVE HSDPA USERS IN SPI 5SUM OF CAPABLE DC HSDPA MIMO USERSSUM OF ACTIVE DC HSDPA MIMO USERS WITH ONE CARRIERTTI SCHEDULED DC HSDPA MIMO USER FOR PRIMARY CARRIER WITH ONE CARRIER SINGLE STREATTI SCHEDULED DC HSDPA MIMO USER FOR PRIMARY CARRIER WITH ONE CARRIER DUAL STREAMACTIVE HSDPA USERS IN SPI 11MAX NUMBER OF USERS IN EFACHACTIVE HSDPA USERS IN SPI 10SUM OF USERS IN EFACHSUM OF ACTIVE DC HSDPA MIMO USERS WITH TWO CARRIERSDENIED COMMON EDCH RESOURCESSUM OF TIME UE IN HSFACH DRXSUM OF TIME UE IN HSFACH RXCONTROL DATA VOLUME UL EFACHUSER DATA TRANSMITTED TIME UL EFACHCONTROL DATA TRANSMITTED TIME DL EFACHUSER DATA VOLUME UL EFACHCONTROL DATA VOLUME DL EFACHUSER DATA TRANSMITTED TIME DL EFACHNUMBER OF FOUR SCHEDULED HSDPA USER PER TTIUSER DATA VOLUME DL EFACHNUMBER OF THREE SCHEDULED HSDPA USER PER TTINUMBER OF TWO SCHEDULED HSDPA USER PER TTINUMBER OF ONE SCHEDULED HSDPA USER PER TTIUNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 20

UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 19ACTIVE HSDPA USERS IN SPI 1UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 18ACTIVE HSDPA USERS IN SPI 0UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 17CONTROL DATA TRANSMITTED TIME UL EFACHUNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 16UNHAPPY RESIDUAL STREAM FRACTIONAL LOAD CLASS 15cacAvgReservedBitRatecacMaxReservedBitRatecacMinReservedBitRateMAXIMUM NUMBER OF USED CE FOR ULMINIMUM NUMBER OF USED CE FOR DLAVERAGE NUMBER OF AVAILABLE CHANNEL ELEMENTSMAXIMUM NUMBER OF USED CE FOR DLAVERAGE NUMBER OF USED CE FOR ULMAXIMUM NUMBER OF USED CE FOR HSUPA ULMINIMUM NUMBER OF USED CE FOR ULAVERAGE NUMBER OF USED CE FOR DLMINIMUM NUMBER OF USED CE FOR HSUPA ULAVERAGE NUMBER OF USED CE FOR HSUPA ULifOutPacketsifInOctetsifInPacketsifIpDroppedPacketsFilteringifIpDroppedPacketsRateLimitingifInErrorsifOutOctetsCOMPENSATED CQI DISTRIBUTION - CLASS 1COMPENSATED CQI DISTRIBUTION - CLASS 2TTI SCHEDULED DC HSDPA MIMO USER FOR SECONDARY CARRIER WITH ONE CARRIER DUAL STRETTI SCHEDULED DC HSDPA MIMO USER FOR SECONDARY CARRIER WITH ONE CARRIER SINGLE STTTI SCHEDULED DC HSDPA MIMO USER WITH BOTH CARRIER DUAL STREAMTTI SCHEDULED DC HSDPA MIMO USER WITH BOTH CARRIER DUAL AND SINGLE STREAMTTI SCHEDULED DC HSDPA MIMO USER WITH BOTH CARRIER SINGLE AND DUAL STREAMTTI SCHEDULED DC HSDPA MIMO USER WITH BOTH CARRIER SINGLE STREAMNUMBER OF USER DATA FRAMES PROCESSED DL EFACHNUMBER OF CONTROL DATA FRAMES PROCESSED DL EFACHMAXIMUM NUMBER OF AVAILABLE CHANNEL ELEMENTSMINIMUM NUMBER OF AVAILABLE CHANNEL ELEMENTSifIpOutDropPacketscacMaxCommittedBitRaterxEthernetPacketsifIpOutDropOctetstxEthernetPacketsrxEthernetOctetsCOMPENSATED CQI DISTRIBUTION - CLASS 0txEthernetOctetsBTS CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 6BTS CHANNEL ELEMENT HSPA UTILIZATION IN UL - CLASS 1BTS CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 4BTS CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 5BTS CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 2BTS CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 3

COMPENSATED CQI DISTRIBUTION - CLASS 12BTS CHANNEL ELEMENT HSPA UTILIZATION IN UL - CLASS 4BTS CHANNEL ELEMENT HSPA UTILIZATION IN UL - CLASS 5BTS CHANNEL ELEMENT HSPA UTILIZATION IN UL - CLASS 2BTS CHANNEL ELEMENT HSPA UTILIZATION IN UL - CLASS 3COMPENSATED CQI DISTRIBUTION - CLASS 3COMPENSATED CQI DISTRIBUTION - CLASS 11COMPENSATED CQI DISTRIBUTION - CLASS 10COMPENSATED CQI DISTRIBUTION - CLASS 9COMPENSATED CQI DISTRIBUTION - CLASS 8COMPENSATED CQI DISTRIBUTION - CLASS 7COMPENSATED CQI DISTRIBUTION - CLASS 6COMPENSATED CQI DISTRIBUTION - CLASS 5COMPENSATED CQI DISTRIBUTION - CLASS 4MINIMUM NUMBER OF USED CE FOR HSUPA DLAVERAGE NUMBER OF USED CE FOR HSUPA DLBTS CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 1BTS CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 2MAXIMUM NUMBER OF USED CE FOR HSUPA DLBTS CHANNEL ELEMENT TOTAL UTILIZATION IN DL - CLASS 1BTS CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 3BTS CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 4BTS CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 5BTS CHANNEL ELEMENT TOTAL UTILIZATION IN UL - CLASS 6COMPENSATED CQI DISTRIBUTION - CLASS 14COMPENSATED CQI DISTRIBUTION - CLASS 13COMPENSATED CQI DISTRIBUTION - CLASS 20COMPENSATED CQI DISTRIBUTION - CLASS 19COMPENSATED CQI DISTRIBUTION - CLASS 22COMPENSATED CQI DISTRIBUTION - CLASS 21COMPENSATED CQI DISTRIBUTION - CLASS 16COMPENSATED CQI DISTRIBUTION - CLASS 15COMPENSATED CQI DISTRIBUTION - CLASS 18COMPENSATED CQI DISTRIBUTION - CLASS 17totCellsEgressVCtotCellsIngressVCdiscCellsDiscarded Cells due to HECUnavailable Seconds on ATM InterfacetotCellsEgresstotUbrCellsEgresstotUbrCellsIngresstotCbrCellsEgresstotCbrCellsIngressCOMPENSATED CQI DISTRIBUTION - CLASS 28SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 11COMPENSATED CQI DISTRIBUTION - CLASS 29SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 12COMPENSATED CQI DISTRIBUTION - CLASS 26COMPENSATED CQI DISTRIBUTION - CLASS 27COMPENSATED CQI DISTRIBUTION - CLASS 32SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 15SAMPLES FOR ALL ALLOCATED HSDPA USERStotCellsIngressVP

COMPENSATED CQI DISTRIBUTION - CLASS 30SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 13COMPENSATED CQI DISTRIBUTION - CLASS 31SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 14USER DATA VOLUME DL DECREASED PRIORITY AARUSER DATA VOLUME UL DEFAULT PRIORITY AARUSER DATA VOLUME DL DEFAULT PRIORITY AARUSER DATA VOLUME DL INCREASED PRIORITY AARCOMPENSATED CQI DISTRIBUTION - CLASS 24COMPENSATED CQI DISTRIBUTION - CLASS 25COMPENSATED CQI DISTRIBUTION - CLASS 23Background Block ErrorsHSUPA DL PWR RATIO DISTRIBUTION - CLASS 03Severely errored secondsHSUPA DL PWR RATIO DISTRIBUTION - CLASS 02HSUPA DL PWR RATIO DISTRIBUTION - CLASS 05totCellsIngressHSUPA DL PWR RATIO DISTRIBUTION - CLASS 04UNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 00AVERAGE HSUPA DL PWR CONTROL CHANNELSUNHAPPY FRACTIONAL LOAD VALUE DISTRIBUTION - CLASS 01BTS CHANNEL ELEMENT HSPA UTILIZATION IN DL - CLASS 1BTS CHANNEL ELEMENT HSPA UTILIZATION IN DL - CLASS 3BTS CHANNEL ELEMENT HSPA UTILIZATION IN DL - CLASS 2BTS CHANNEL ELEMENT HSPA UTILIZATION IN DL - CLASS 5BTS CHANNEL ELEMENT HSPA UTILIZATION IN DL - CLASS 4Errored SecondsUnavailable SecondsMAX NUMBER OF DC HSUPA USERSSUM OF ACTIVE DC HSUPA USERS USING 2CSUM OF ACTIVE DC HSUPA USERS USING 1CPIC INDICATION FOR ACTIVE STATESAMPLES FOR ALLOCATED HSDPA USERS IN SPI 1PIC INDICATION FOR INACTIVE STATESAMPLES FOR ALLOCATED HSDPA USERS IN SPI 2NUMBER OF SPI PROMOTION DL AARSAMPLES FOR ALLOCATED HSDPA USERS IN SPI 3SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 4SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 5SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 6SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 7SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 8SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 9COMPENSATED CQI DISTRIBUTION - CLASS 33SAMPLES FOR ALLOCATED HSDPA USERS IN SPI 10COMPENSATED CQI DISTRIBUTION - CLASS 34COMPENSATED CQI DISTRIBUTION - CLASS 35SUM OF DC HSUPA USERSMAXIMUM NUMBER CPC CONFIGURED USERSSUM OF CPC CONFIGURED USERSMAXIMUM NUMBER OF ACTIVE CPC USERSSUM OF ACTIVE CPC USERSRETRANSMITTED MAC-EHS PDUS BY 64QAMORIGINAL TRANSMITTED MAC-EHS PDUS BY 64QAM

DROPPED 656 BIT MAC-D PDUS DUE TO OTHER REASONDROPPED MAC-D PDUS DUE TO OTHER REASONAVERAGE NUMBER OF USED R99 CE FOR DLMINIMUM NUMBER OF AVAILABLE R99 CHANNEL ELEMENTSMAXIMUM NUMBER OF USED R99 CE FOR DLMAXIMUM NUMBER OF AVAILABLE R99 CHANNEL ELEMENTSAVERAGE NUMBER OF AVAILABLE R99 CHANNEL ELEMENTSNUMBER OF SPI DEMOTION UL AARNUMBER OF DPCCH SLOTSNUMBER OF SPI CHANGE TO DEFAULT UL AARHSUPA DL PWR RATIO DISTRIBUTION - CLASS 01NUMBER OF SPI CHANGE TO DEFAULT DL AARNUMBER OF SPI PROMOTION UL AARNUMBER OF NON DTX DPCCH SLOTSNUMBER OF SPI DEMOTION DL AARSAMPLES IN HS-PDSCH POWER CLASS 08SAMPLES IN HS-PDSCH POWER CLASS 07SAMPLES IN HS-PDSCH POWER CLASS 10SAMPLES IN HS-PDSCH POWER CLASS 09SAMPLES IN HS-PDSCH POWER CLASS 04EthIfOutPkt_15SAMPLES IN HS-PDSCH POWER CLASS 03SAMPLES IN HS-PDSCH POWER CLASS 06SAMPLES IN HS-PDSCH POWER CLASS 05EthIfInOcts_15bbeB315EthIfInPkt_15EthIfOutOcts_15uasB315totCellsEgressVPDROPPED 656 BIT MAC-D PDUS DUE TO BUFFER OVERFLOWsesB315esB315CCH DATA VOLUME FROM IUB-INTERFACEDCH DATA VOLUME TO IUB-INTERFACEDCH DATA VOLUME FROM IUB-INTERFACEE-DCH DATA VOLUME TO IUB-INTERFACEUSER DATA VOLUME UL INCREASED PRIORITY AARUSER DATA VOLUME UL DECREASED PRIORITY AARCCH DATA VOLUME TO IUB-INTERFACEDROPPED MAC-D PDUS DUE TO MAX RETXDROPPED 656 BIT MAC-D PDUS DUE TO MAX RETXCCH FP DATA FRAMES SUCCESSFULLY RECEIVEDCCH FP DATA FRAMES DISCARDED DUE TO HEADER CRC ERRORCCH FP DATA FRAMES DISCARDED DUE TO TOO HIGH DELAY

Time aggregationsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

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sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumSUMsumSUMsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumavgmaxmax

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

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sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumavgavgsumsumsumsumsumsumsumsumsummaxsummaxsumavgsumavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsummaxmaxmaxmaxmaxmaxmaxmaxsumavgsumminsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumSumSumavgSumsumSumsumSumSummaxminavgsumROUND(10*LOG(10,(AVG(POWER(10,(GREATEST(-112,HSUPA_UL_PWR_AVG)/10))/1000))*1000),3)summaxsumsummaxminsum

sumsumsumsumsumsumsumsumsummaxminsumsumsumsumminmaxavgminavgminmaxavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsumsumsumsumavgmaxmaxmaxmaxmaxavgminsumsum

sumsumsumsumavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumSumSumMaxMinSumsumsumSumSumSumsumsumavgsumavgavgavgavgavgavgsumsumsumsumsumminmaxavgsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumAvgMaxMinSumsumSumsumMinsumSumsumSumSumsumSumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumSumSumMinSumAvgsum

sumsumsumsumSumsumSumsumSumsumSumsumSumsumSumSumSumSumsumsumsumsumMaxsumMinsumSumsumSumsumAvgsumMaxsumminavgmaxavgmaxmaxminmaxavgminSumSumSumSummaxavgsumsumavgsum

maxsumavgsumminsumsumsumsumsumsumSumsumsumminSumSumSumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsumsumsummaxminavgsumsumsumsumSumsumsumSumavgmaxsumsumsumsum

sumsumsumsumsumsumsumsumminavgsummaxsumsummaxsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumavgavgavgavgavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumavgmaxminmaxminavgmaxavgmaxminavgminavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxminsummaxsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumminavgsumsummaxsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumavgsumsumsumsumsumsumsumsummaxsumsumSumsumSumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsummaxsumsumsum

sumsumAvgMinMaxMaxAvgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

Object aggregationsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsumminsumavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumSumSumAVG, SUMSumSUMsumsumsumsumsumsumSumsumsumSumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumavgmaxmax

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

maxsumsumsumsumsumsummaxAVGavgmaxmaxminsumsumsumsumAVGsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsummaxsumAVGsummaxmaxsumminavgmaxsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumavgavgsumsumsumsumsumsumsumsumsummaxsummaxsumavgsumavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumn/an/amaxmaxmaxmaxmaxmaxsumavgsumminsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumSumSumavgSumsumSumsumSumSumn/aminavgsumROUND(10*LOG(10,(AVG(POWER(10,(GREATEST(-112,HSUPA_UL_PWR_AVG)/10))/1000))*1000),3)summaxsumsummaxminsum

sumsumsumsumsumsumsumsumsummaxminsumsumsumsumminmaxavgminavgminmaxavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsumsumsumsumavgmaxmaxmaxmaxmaxavgminsumsum

sumsumsumsumavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxminSumSumSumSumSumSumsumsumavgsumavgavgavgavgavgavgsumsumsumsumsumMinMaxAvgsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumAvgMaxMinSumsumSumsumMinsumSumsumSumSumsumSumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumSumSumMinSumAvgsum

sumsumsumsumSumsumSumsumSumsumSumsumSumsumSumSumSumSumsumsumsumsumMaxsumMinsumSumsumSumsumAvgsumMaxsumminavgmaxavgmaxmaxminmaxavgminSumSumSumSummaxavgsumsumavgsum

maxsumavgsumminsumsumsumsumsumsumsumsumsumminSumSumSumsumSumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsumsumsummaxminavgsumsumsumsumSumsumsumSumavgmaxsumsumsumsum

sumsumsumsumsumsumsumsumminavgsummaxsumsummaxsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumavgavgavgavgavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumavgmaxminmaxminavgmaxavgmaxminavgminavgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxminsummaxsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumminavgsumsummaxsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

sumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumavgsumsumsumsumsumsumsumsummaxsumsumSumsumSumsumsumsumsumsumsumsumsumsumsumsumsumsumsummaxsummaxsumsumsum

sumsumAvgMinMaxMaxAvgsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsumsum

DescriptionNumber of MAC-hs PDUs correctly delivered with more than 5 retransmissions.Number of dropped MAC-d PDUs due to BTS buffer overflow. This counter includes only legacy single carrier MAC-d PDUs.Number of MAC-hs PDUs correctly delivered with 3 retransmissions.Number of MAC-hs PDUs correctly delivered with 4 retransmissions.Total number of received MAC-d PDUs. This counter includes only legacy single carrier MAC-d PDUs.Number of reported Channel Quality Indicator (CQI) values 0.Number of reported Channel Quality Indicator (CQI) values 2.Number of reported Channel Quality Indicator (CQI) values 3.Number of reported Channel Quality Indicator (CQI) values 4.Number of reported Channel Quality Indicator (CQI) values 5.Number of MAC-hs PDUs correctly delivered with 1 retransmission.Number of MAC-hs PDUs correctly delivered with 2 retransmissions.Number of reported Channel Quality Indicator (CQI) values 1.Number of MAC-hs PDUs correctly delivered without retransmissions.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 12.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 13.Number of reported Channel Quality Indicator (CQI) values 10.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values correlates into class 16.Number of reported Channel Quality Indicator (CQI) values 7.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values correlates into class 17.Number of reported Channel Quality Indicator (CQI) values 6.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 14.Number of reported Channel Quality Indicator (CQI) values 9.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values correlates into class 15.Number of reported Channel Quality Indicator (CQI) values 8.Number of scheduled HSDPA users per TTI when there are no HSDPA user in the target cell and seven HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are no HSDPA user in the target cell and eight HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values correlates into class 18.The sum of sampled number of users having MIMO dual stream mode active. This counter, divided by the denominator M5000C327, provides the average user amount during the measurement interval.Number of scheduled HSDPA users per TTI when there are one HSDPA user in the target cell and seven HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are one HSDPA user in the target cell and eight HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are two HSDPA users in the target cell and seven HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are four HSDPA user in the target cell and no HSDPA user in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are four HSDPA users in the target cell and one HSDPA user in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are four HSDPA users in the target cell and two HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are four HSDPA users in the target cell and three HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are four HSDPA users in the target cell and four HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are four HSDPA users in the target cell and five HSDPA users in the other cell.<br/>Note: The counter shows information from one Tcell group.Total amount of received Multi-Carrier HSDPA data in MAC-d PDUs. The combined MC data of primary+secondary cells is updated to the primary cell.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.25 < L <= 0.30). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of reported Channel Quality Indicator (CQI) values 21.Number of reported Channel Quality Indicator (CQI) values 22.Number of reported Channel Quality Indicator (CQI) values 23.Number of reported Channel Quality Indicator (CQI) values 24.Number of reported Channel Quality Indicator (CQI) values 25.Number of reported Channel Quality Indicator (CQI) values 26.Number of reported Channel Quality Indicator (CQI) values 27.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.05 < L <= 0.10). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of reported Channel Quality Indicator (CQI) values 29.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.10 < L <= 0.15). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of reported Channel Quality Indicator (CQI) values 28.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 0 limits (L = 0). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0 < L <= 0.05). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.

Number of reported Channel Quality Indicator (CQI) values 30.The number of correctly received MAC-e / MAC-i PDUs sent by 16QAM modulation in uplink. Applicable only for a serving cell.The number of incorrectly received MAC-e / MAC-i PDUs sent by 16QAM modulation in uplink. Applicable only for a serving cell.This counter is also applicable for MAC-i.Total amount of discarded Multi-Carrier HSDPA data in MAC-d PDUs. The combined MC data of primary+secondary cells is updated to the primary cell.The sum of sampled number of active 16QAM UL users (user configured with 16QAM and 16QAM is currently in use). Applicable only for a serving cell. This counter, divided by the denominator M5000C327, provides the average user amount during The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.15 < L <= 0.20). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.20 < L <= 0.25). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of retransmitted MAC-hs PDUs with 7 codes using QPSK modulation.Number of retransmitted MAC-hs PDUs with 6 codes using QPSK modulation.Number of retransmitted MAC-hs PDUs with 8 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 13 codes using 16QAM modulation.Number of original MAC-hs PDU transmissions with 12 codes using 16QAM modulation.Number of original MAC-hs PDU transmissions with 15 codes using 16QAM modulation.Number of original MAC-hs PDU transmissions with 14 codes using 16QAM modulation.Number of original MAC-hs PDU transmissions with 9 codes using 16QAM modulation.Number of reported Channel Quality Indicator (CQI) values 11.Number of reported Channel Quality Indicator (CQI) values 12.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.80 < L <= 0.85). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of original MAC-hs PDU transmissions with 11 codes using 16QAM modulation.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.75 < L <= 0.80). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of original MAC-hs PDU transmissions with 10 codes using 16QAM modulation.Number of reported Channel Quality Indicator (CQI) values 15.Number of reported Channel Quality Indicator (CQI) values 16.Number of reported Channel Quality Indicator (CQI) values 13.Number of reported Channel Quality Indicator (CQI) values 14.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.50 < L <= 0.55). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of reported Channel Quality Indicator (CQI) values 20.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.55 < L <= 0.60). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of reported Channel Quality Indicator (CQI) values 19.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.60 < L <= 0.65). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of reported Channel Quality Indicator (CQI) values 18.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.65 < L <= 0.70). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of reported Channel Quality Indicator (CQI) values 17.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.30 < L <= 0.35). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.35 < L <= 0.40). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.40 < L <= 0.45). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.45 < L <= 0.50). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.70 < L <= 0.75). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.Number of original MAC-hs PDU transmissions with 2 code by 16QAM modulation.Number of original MAC-hs PDU transmissions with 1 code by 16QAM modulation.Number of original MAC-hs PDU transmissions with 4 code by 16QAM modulation.Number of original MAC-hs PDU transmissions with 3 code by 16QAM modulation.Number of retransmitted MAC-hs PDUs with 11 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 3 code by QPSK modulation.Number of retransmitted MAC-hs PDUs with 12 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 2 code by QPSK modulation.Number of retransmitted MAC-hs PDUs with 9 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 5 code by QPSK modulation.Number of retransmitted MAC-hs PDUs with 10 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 4 code by QPSK modulation.Number of retransmitted MAC-hs PDUs with 15 codes using QPSK modulation.Number of retransmitted MAC-hs PDUs with 6 codes using 16QAM modulation.Number of retransmitted MAC-hs PDUs with 13 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 1 code by QPSK modulation.

Number of retransmitted MAC-hs PDUs with 14 codes using QPSK modulation.Number of retransmitted MAC-hs PDUs with 7 codes using 16QAM modulation.Number of retransmitted MAC-hs PDUs with 8 codes using 16QAM modulation.Number of scheduling periods where the Fractional Load has been in class 17 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.80 < L <= 0.85.Number of scheduling periods where the Fractional Load has been in class 16 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.75 < L <= 0.80.Number of scheduling periods where the Fractional Load has been in class 15 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.70 < L <= 0.75.Number of scheduling periods where the Fractional Load has been in class 14 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.65 < L <= 0.70.The number of 2 ms TTI MAC-e / MAC-i PDUs received by BTS. The calculation is done only for the serving cell.Number of scheduling periods where the Fractional Load has been in class 20 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.95 < L <= 1.00.Number of scheduling periods where the Fractional Load has been in class 19 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.90 < L <= 0.95.Number of scheduling periods where the Fractional Load has been in class 18 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.85 < L <= 0.90.Number of scheduling periods where the Fractional Load has been in class 13 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.60 < L <= 0.65.Number of original MAC-hs PDU transmissions with 5 code by 16QAM modulation.Number of scheduling periods where the Fractional Load has been in class 12 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.55 < L <= 0.60.Number of discarded MAC-hs PDUs due to T1 timer.Number of unscheduled TTIs when there is data in at least one of the user buffers.The number of unscheduled TTIs (HSDPA idle time) when data is not sent from the user buffers (queues).Number of retransmitted MAC-hs PDUs with 9 codes using 16QAM modulation.Maximum MAC-D PDU buffer delay.Number of retransmitted MAC-hs PDUs with 10 codes using 16QAM modulation.Minimum MAC-D PDU buffer delay.<br/>Note: If delay is less than 10 ms, the counters shows 0.Number of retransmitted MAC-hs PDUs with 11 codes using 16QAM modulation.Average MAC-D PDU buffer delay.Number of retransmitted MAC-hs PDUs with 12 codes using 16QAM modulation.Number of MAC-D PDUs size of 656.Number of retransmitted MAC-hs PDUs with 13 codes using 16QAM modulation.Number of Channel Quality Indicator (CQI) decoding failures.Number of retransmitted MAC-hs PDUs with 14 codes using 16QAM modulation.Number of retransmitted MAC-hs PDUs with 15 codes using 16QAM modulation.Amount of data received from the RNC in MAC-d PDUs. This counter includes only legacy single carrier MAC-d PDUs data.Amount of data in MAC-d PDUs discarded due to flow control buffer overflow. This counter includes only legacy single carrier MAC-d PDUs data.Number of MAC-e PDUs that are received correctly without retransmissions in E-DCH Serving Cell. This counter is also applicable for MAC-i.The sum of sampled values for the number of configured HSUPA users with 10 ms TTI. This counter, divided by the denominator M5000C326, provides the average user amount during the measurement interval.The sum of sampled values for the number of configured HSUPA users with 2 ms TTI. This counter, divided by the denominator M5000C326, provides the average user amount during the measurement interval.This is a general denominator for cell specific user calculations. The counter is needed for the user amount average calculation.The number of samples taken for counters M5000C324 sum of HSUPA users with 2 ms TTI and M5000C325 sum of HSUPA users with 10 ms TTI, needed for average calculation.The sum of sampled values for the number of active DC-HSDPA users. Active DC users use only one carrier for transmission.The sum of sampled values for the number of active DC-HSDPA users. Active DC users use both carriers for transmission.The sum of sampled values for the number of capable DC-HSDPA users.The number of 10 ms TTI MAC-e / MAC-i PDUs received by BTS. The calculation is done only for the serving cell.The total volume of MAC-e / MAC-i data received with 10 ms TTI by BTS. The calculation is done only for the serving cell.Number of discarded MAC-hs PDUs due to maximum number of retransmissions.The total volume of MAC-e / MAC-i data received with 2 ms TTI by BTS. The calculation is done only for the serving cell.Number of discarded MAC-hs PDUs due to some other reason than T1 timer or maximum number of retransmissions.Number of MAC-e PDUs that are received correctly with five retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.The HS-SCCH transmit power measurement. Number of TTIs matching to power limits of class 4 (range 0.8 ... <1.6 W).Number of MAC-e PDUs that are received correctly with six retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.The HS-SCCH transmit power measurement. Number of TTIs matching to power limits of class 3 (range 0.4 ... <0.8 W).Number of MAC-e PDUs that are received correctly with three retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.The HS-SCCH transmit power measurement. The sum of Watts in active TTIs.Number of MAC-e PDUs that are received correctly with four retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.The HS-SCCH transmit power measurement. Number of TTIs matching to power limits of class 5 (range 1.6 W or more).Number of MAC-e PDUs that are received correctly with one retransmission in E-DCH Serving Cell.This counter is also applicable for MAC-i.Number of scheduled HSDPA users per TTI when there are no HSDPA users in the target cell and two HSDPA users in the other cell (0-2).<br/>Note: The counter shows information from one Tcell group.

Number of MAC-e PDUs that are received correctly with two retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.Number of scheduled HSDPA users per TTI when there are no HSDPA users in the target cell and one HSDPA user in the other cell (0-1).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are no HSDPA users in the target cell and three HSDPA users in the other cell (0-3).<br/>Note: The counter shows information from one Tcell group.Number of MAC-e PDUs that are received correctly with nine retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.The HS-SCCH transmit power measurement. Number of TTIs matching to power limit of class 0 (lower than 0.1 W).Number of MAC-e PDUs that are received correctly with ten retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.Number of MAC-e PDUs that are received correctly with seven retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.The HS-SCCH transmit power measurement. Number of TTIs matching to power limits of class 2 (range 0.2 ... <0.4 W).Number of MAC-e PDUs that are received correctly with eight retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.The HS-SCCH transmit power measurement. Number of TTIs matching to power limits of class 1 (range 0.1 ... <0.2 W).Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values correlates into class 1.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values correlates into class 0.The number of MAC-ehs PDUs retransmitted with MIMO dual stream.The number of MAC-ehs PDUs original transmitted with MIMO dual stream.The number of TTIs scheduled for users with dual stream MIMO.The number of TTIs scheduled for users with single stream MIMO.Number of TTIs for scheduled DC-HSDPA users only, from secondary carrier when two carriers are used.Number of TTIs for scheduled DC-HSDPA users only, from primary carrier when two carriers are used.Number of TTIs for scheduled DC-HSDPA users only, from secondary carrier when one carrier is used.Number of TTIs for scheduled DC-HSDPA users only, from primary carrier when one carrier is used.Number of MAC-e PDUs that are not received correctly despite retransmission in E-DCH Serving Cell. This counter is also applicable for MAC-i.Number of retransmitted MAC-hs PDUs with 1 code by 16QAM modulation.Number of MAC-e PDUs that are received correctly but lost for an unknown reason, such as buffer overflow.Number of retransmitted MAC-hs PDUs with 5 code by QPSK modulation.Number of MAC-e PDUs that are received correctly but the number of retransmissions is unknown. This counter is also applicable for MAC-i.Number of retransmitted MAC-hs PDUs with 4 code by QPSK modulation.Number of measurement periods whose average power matches the power limits of class 1 (power < 0.1W)Number of retransmitted MAC-hs PDUs with 3 code by QPSK modulation.Number of retransmitted MAC-hs PDUs with 5 code by 16QAM modulation.Number of MAC-e PDUs that are received correctly with eleven retransmissions in E-DCH Serving Cell.This counter is also applicable for MAC-i.Number of retransmitted MAC-hs PDUs with 4 code by 16QAM modulation.Number of MAC-e PDUs that are received correctly with twelve retransmissions in E-DCH Serving Cell. This counter is also applicable for MAC-i.Number of retransmitted MAC-hs PDUs with 3 code by 16QAM modulation.Number of DTXs (no transmission) detected in E-DCH Serving Cell.Number of retransmitted MAC-hs PDUs with 2 code by 16QAM modulation.Number of measurement periods whose average power matches the power limits of class 2 (0.1W<= power < 0.2W)Number of retransmitted MAC-hs PDUs with 2 code by QPSK modulation.Number of measurement periods whose average power matches the power limits of class 3 (0.2W<= power < 0.4W)Number of retransmitted MAC-hs PDUs with 1 code by QPSK modulation.Number of measurement periods whose average power matches the power limits of class 4 (0.4W<= power < 0.8W)Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 11.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 8.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 7.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 10.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 9.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 4.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values correlates into class 3.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 6.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values and their difference correlate into class 5.Distribution of the correlated values of CQI1 and CQI2 of the two MIMO data streams. The sum of the two CQI values correlates into class 2.The number of outbound packets that were successfully transmitted within the Best Effort PHB class.The number of outbound octets within the Best Effort PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Best Effort PHB class that were dropped in the IP scheduler due to congestion.The total number of octets received by the interface, including framing characters, using Expedited Forwarding PHB class.

The number of inbound packets that were successfully received within the Expedited Forwarding PHB class.Number of original MAC-hs PDU transmissions with 12 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 13 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 10 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 11 codes using QPSK modulation.Number of original MAC-hs PDU transmissions with 9 codes using QPSK modulation.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 1 PHB class.Number of original MAC-hs PDU transmissions with 8 codes using 16QAM modulation.The number of outbound octets within the Assured Forwarding 1 PHB class that were dropped in the IP scheduler due to congestion.Number of original MAC-hs PDU transmissions with 6 codes using 16QAM modulation.The number of outbound packets that were successfully transmitted within the Assured Forwarding 1 PHB class.Number of original MAC-hs PDU transmissions with 7 codes using 16QAM modulation.The total number of octets transmitted out of the interface, including framing characters, using the Best Effort PHB class.Number of original MAC-hs PDU transmissions with 14 codes using QPSK modulation.The number of outbound packets within the Assured Forwarding 1 PHB class that were dropped in the IP scheduler due to congestion.Number of original MAC-hs PDU transmissions with 15 codes using QPSK modulation.The total number of octets received out of the interface, including framing characters, using the Best Effort PHB class.The number of inbound packets that were successfully received within the Best Effort PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 1 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 1 PHB class.Number of scheduled HSDPA users per TTI when there is one HSDPA user in the target cell and no HSDPA users in the other cell (1-0).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there is one HSDPA user in the target cell and one HSDPA user in the other cell (1-1).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there is one HSDPA user in the target cell and two HSDPA users in the other cell (1-2).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are two HSDPA users in the target cell and no HSDPA users in the other cell (2-0).<br/>Note: The counter shows information from one Tcell group.The number of inbound packets that were successfully received within the Assured Forwarding 4 PHB class.Number of original MAC-hs PDU transmissions with 7 codes using QPSK modulation.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 4 PHB class.Number of original MAC-hs PDU transmissions with 8 codes using QPSK modulation.The number of inbound packets that were successfully received within the Assured Forwarding 2 PHB class.Number of scheduled HSDPA users per TTI when there are two HSDPA users in the target cell and one HSDPA user in the other cell (2-1).<br/>Note: The counter shows information from one Tcell group.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 2 PHB class.Number of scheduled HSDPA users per TTI when there are three HSDPA users in the target cell and no HSDPA users in the other cell (3-0).<br/>Note: The counter shows information from one Tcell group.The number of inbound packets that were successfully received within the Assured Forwarding 3 PHB class.Number of user buffers with data in the buffer for each TTI.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 3 PHB class.Number of original MAC-hs PDU transmissions with 6 codes using QPSK modulation.Number of scheduling periods where the Fractional Load has been in class 2 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.05 < L <= 0.10.The number of outbound octets within the Assured Forwarding 2 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Assured Forwarding 2 PHB class that were dropped in the IP scheduler due to congestion.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 2 PHB class.The number of outbound packets that were successfully transmitted within the Assured Forwarding 2 PHB class.The number of outbound octets within the Assured Forwarding 3 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Assured Forwarding 3 PHB class that were dropped in the IP scheduler due to congestion.Number of scheduling periods where the Fractional Load has been in class 9 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.40 < L <= 0.45.Number of scheduling periods where the Fractional Load has been in class 10 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.45 < L <= 0.50.Number of scheduling periods where the Fractional Load has been in class 7 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.30 < L <= 0.35.Number of scheduling periods where the Fractional Load has been in class 8 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.35 < L <= 0.40.Number of scheduling periods where the Fractional Load has been in class 5 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.20 < L <= 0.25.Number of scheduling periods where the Fractional Load has been in class 6 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.25 < L <= 0.30.Number of scheduling periods where the Fractional Load has been in class 3 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.10 < L <= 0.15.Number of scheduling periods where the Fractional Load has been in class 4 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.15 < L <= 0.20.Number of scheduling periods where the Fractional Load has been in class 11 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0.50 < L <= 0.55.The number of outbound packets that were successfully transmitted within the Assured Forwarding 3 PHB class.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 3 PHB class.

The number of outbound packets within the Assured Forwarding 4 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound octets within the Assured Forwarding 4 PHB class that were dropped in the IP scheduler due to congestion.All received ESP packets addressed to a local tunnel endpoint with a SPI of an existing IPsec SA, the packets fit into the anti replay window, the packets could be decrypted and authenticated but the packets do not match the traffic selectors configurAll received ESP packets addressed to a local tunnel endpoint which are received with a SPI of an existing IPsec SA, the packets fit into the anti replay window but the packets could not be decrypted or authenticated correctly, shall be counted.<br/><Duration of the measurement period in minutes., Duration of the measurement period in minutes. Values summed up also in object dimension.All sent ESP packets are counted.The busiest hour of a day or a week, determined by a pre-defined formula.All received packets, either not addressed to a local tunnel endpoint or addressed to a local tunnel endpoint but not ESP or AH, that match the default policy are counted. This counts the packets not matching any user defined policy.All outgoing packets matching the default policy are to be countedAll received unprotected packets (i.e not ESP or AH), either not addressed to a local tunnel endpoint or addressed to a local tunnel endpoint, that match a protect policy are counted.All received packets, either not addressed to a local tunnel endpoint or addressed to a local tunnel endpoint but not ESP or AH, that match a discard policy are counted.<br/><br/>Note: discarded packets matching the default policy are not counted withAll received packets, either not addressed to a local tunnel endpoint or addressed to a local tunnel endpoint but not ESP or AH, that match a bypass policy are counted.All failed SA establishments are counted.All received ESP packets addressed to a local tunnel endpoint which are received with a SPI of an existing IPsec SA are counted.<br/><br/>Note: this counter includes both successfully and unsuccessfully received packets as long as the SPI existsAll outgoing packets matching a bypass policy are counted.All outgoing packets matching a discard policy are counted.<br/><br/>Note: discarded packets matching the default policy are not counted with this counter.All received ESP packets addressed to a local tunnel endpoint which are received with a SPI of an existing IPsec SA but the packets are discarded because the sequence number of the packets are outside the anti replay window are counted.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 3 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 4 PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 2 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 3 PHB class.The number of inbound packets that were successfully received within the Best Effort PHB class.All received ESP or AH packets addressed to a local tunnel endpoint with a SPI which is not related to any existing IPsec SA and therefore unknown are counted.<br/><br/>Note: AH packets are not supported by the system but should be included in tThe number of inbound packets that were successfully received within the Assured Forwarding 2 PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 1 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 1 PHB class.The total number of octets received out of the interface, including framing characters, using the Best Effort PHB class.The counter counts all packets for this pseudowire tunnel that arrived too late or to early in relation to the jitter buffer.The number of frames received over the CES interface.This counter counts all packets of the pseudowire tunnel that arrive too early in relation to the jitter buffer.The CES pseudowire function shall be capable to detect lost and misordered packets. The sequence number in the control word of each packet is used for these purposes. The pseudowire function shall reorder misordered packets. Misordered packets tThe number of frames sent over the interface using CES over PSN.The counter counts all packets for the CES pseudowire that arrived too late in relation to the jitter buffer.The counter counts all packets that arrived too late or too early in relation to the jitter buffer of the CES pseudowire.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.The counter counts all packets for this pseudowire tunnel that arrived too late in relation to the jitter buffer.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.This counter counts the packets with the L-bit set to '1' over the pseudowire.The CES pseudowire function shall be capable to detect lost and misordered packets. The sequence number in the control word of each packet is used for these purposes. The pseudowire function shall reorder misordered packets. Misordered packetsNumber of Ethernet TX packets discarded due to egress shaping per queue per interface.The number of Ethernet frames received whose PSN header is not configured or has a reserved value.Unavailable Seconds (UAS):<br/>Counts the number of seconds for which the interface is unavailable.<br/>The interface is defined unavailable from either the beginning of 10 contiguous SES and/or a defect.<br/>An interface is available again after Severely Errored Seconds (SES):<br/>Counts the number of seconds which contain a defect.<br/>Defect: LOS on Ethernet interface<br/>SES are not incremented during Unavailable Seconds (UAS)<br/>Standard: [G.826]Number of Ethernet TX packets discarded due to egress shaping per queue per interface.Number of Ethernet packets received with FCS errors.Number of Ethernet TX packets discarded due to rate shaping.Number of received Ethernet packets with an unknown VLAN ID.The number of inbound packets that were successfully received within the Assured Forwarding 1 PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 1 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 2 PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 2 PHB class.Average radio link setup request message queuing time before taken into handling in ms.Peak radio link operations handled per second, where handled means operations that are not rejected because of congestion.Peak radio link setup messages handled per second, where handled means setups that are not rejected because of congestion.

Number of rejected radio link setup requests because of congestion on MCU (signaling load too high)The number of inbound packets that were successfully received within the Best Effort PHB class.The total number of octets received out of the interface, including framing characters, using the Best Effort PHB class.The total number of octets transmitted out of the interface, including framing characters, using the Best Effort PHB class.The number of outbound octets within the Best Effort PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets that were successfully transmitted within the Best Effort PHB class.The total number of octets received by the interface, including framing characters, using Expedited Forwarding PHB class.The number of outbound packets within the Best Effort PHB class that were dropped in the IP scheduler due to congestion.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 4 PHB class.The number of inbound packets that were successfully received within the Expedited Forwarding PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 3 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 4 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 3 PHB class.The number of outbound packets that were successfully transmitted within the Assured Forwarding 1 PHB class.The number of outbound octets within the Assured Forwarding 1 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Assured Forwarding 1 PHB class that were dropped in the IP scheduler due to congestion.The total number of octets transmitted out of the interface, including framing characters, using the Best Effort PHB class.The number of outbound packets that were successfully transmitted within the Best Effort PHB class.The number of outbound octets within the Best Effort PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Best Effort PHB class that were dropped in the IP scheduler due to congestion.The total number of octets received by the interface, including framing characters, using Expedited Forwarding PHB class.The number of inbound packets that were successfully received within the Expedited Forwarding PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 4 PHB class.The number of outbound packets within the Assured Forwarding 3 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound octets within the Assured Forwarding 3 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Assured Forwarding 2 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound octets within the Assured Forwarding 2 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets that were successfully transmitted within the Assured Forwarding 2 PHB class.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 2 PHB class.The number of outbound packets within the Assured Forwarding 1 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound octets within the Assured Forwarding 1 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets that were successfully transmitted within the Assured Forwarding 1 PHB class.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 1 PHB class.The number of outbound packets that were successfully transmitted within the Assured Forwarding 4 PHB class.The number of outbound octets within the Assured Forwarding 4 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Assured Forwarding 4 PHB class that were dropped in the IP scheduler due to congestion.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 3 PHB class.The number of outbound packets that were successfully transmitted within the Expedited Forwarding PHB class.The number of outbound octets within the Expedited Forwarding PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Expedited Forwarding PHB class that were dropped in the IP scheduler due to congestion.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 4 PHB class.The total number of octets transmitted by the interface, including framing characters, using Expedited Forwarding PHB class.The number of outbound octets within the Assured Forwarding 4 PHB class that were dropped in the IP scheduler due to congestion.Total number of samples received during which the bandwidth utilization was within 0-25% of the configured bandwidth.The number of outbound packets that were successfully transmitted within the Assured Forwarding 4 PHB class.Total number of samples received during which the bandwidth utilization was within 51-75% of the configured bandwidth.Total number of samples received during which the bandwidth utilization was within 26-50% of the configured bandwidth.The number of outbound octets within the Expedited Forwarding PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets that were successfully transmitted within the Expedited Forwarding PHB class.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 4 PHB class.The number of outbound packets within the Expedited Forwarding PHB class that were dropped in the IP scheduler due to congestion.The total number of octets received out of the interface, including framing characters, using the Best Effort PHB class.The number of received Ethernet frames whose pseudowire header is not configured or has a reserved value.The number of inbound packets that were successfully received within the Assured Forwarding 1 PHB class.

The peak ingress throughput of the VCC.The total number of octets transmitted by the interface, including framing characters, using Expedited Forwarding PHB class.The number of inbound packets that were successfully received within the Best Effort PHB class.Number of received packets on a tunnel.Total number of samples received during which the bandwidth utilization was greater than 87% of the configured bandwidth.The number of outbound packets that were successfully transmitted within the Assured Forwarding 3 PHB class.Total number of samples received during which the bandwidth utilization was within 76-87% of the configured bandwidth.The peak egress throughput of the VCC.The configured maximum bandwidth of the VCC bundle.This is the average value of reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.This is the maximum bit rate (kbps) which can be allocated by the CAC which is specified by the following configuration parameters:-<br/>If traffic shaping type is "OFF" or "WFQ", it is the subtraction of DCNCommittedBitRate and SignallingComThis is the maximum value of the reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.This is the minimum value of reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.The number of dropped packets due to rate limiting.The number of packets discarded due filter violations.The total number of octets transmitted by the interface, including framing characters.The number of inbound packets that contained errors preventing them from being deliverable to a higher-layer protocol.The configured maximum bandwidth of the VC in egress direction.Total number of samples received during which the bandwidth utilization was greater than 87% of the configured bandwidth.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 1 PHB class.The number of outbound packets within the Assured Forwarding 2 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound octets within the Assured Forwarding 2 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets that were successfully transmitted within the Assured Forwarding 2 PHB class.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 2 PHB class.The number of outbound packets within the Assured Forwarding 3 PHB class that were dropped in the IP scheduler due to congestion.Total number of samples transmitted during which the bandwidth utilization was greater than 87% of the configured bandwidth.The number of outbound octets within the Assured Forwarding 3 PHB class that were dropped in the IP scheduler due to congestion.Total number of samples transmitted during which the bandwidth utilization was within 76-87% of the configured bandwidth.The number of outbound packets that were successfully transmitted within the Assured Forwarding 3 PHB class.Total number of samples transmitted during which the bandwidth utilization was within 51-75% of the configured bandwidth.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 3 PHB class.Total number of samples transmitted during which the bandwidth utilization was within 26-50% of the configured bandwidth.The number of outbound packets within the Assured Forwarding 4 PHB class that were dropped in the IP scheduler due to congestion.Total number of samples transmitted during which the bandwidth utilization was within 0-25% of the configured bandwidth.The peak ingress throughput of the VC.The total number of octects that could not be transmitted over the interface due to congestion.The peak egress throughput of the VC.The total number of packets that could not be transmitted over the interface due to congestion.The configured maximum bandwidth of the VC in ingress direction.Total number of samples received during which the bandwidth utilization was within 76-87% of the configured bandwidth.Maximum buffering delay per AAL2 prioritisation queue.Maximum buffering delay per AAL2 prioritisation queue.The number of seconds during this interval while the timing over packet service was in synchronous state.The minimum value of the timing over packet service phase error in microseconds during the interval.The average value of the timing over packet service phase error in microseconds during the interval.The maximum value of the timing over packet service phase error in microseconds during the interval.The number of received ToP event messages. Event messages are time stamped and used for clock recovery.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 1 PHB class.The number of outbound packets within the Assured Forwarding 2 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound octets within the Assured Forwarding 1 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets that were successfully transmitted within the Assured Forwarding 1 PHB class.The total number of octets transmitted out of the interface, including framing characters, using the Best Effort PHB class.The number of outbound packets within the Assured Forwarding 1 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound octets within the Best Effort PHB class that were dropped in the IP scheduler due to congestion.

The number of ingress Ethernet 64-byte blocks discarded due to rate limiting. There is a chance of counter overflow at higher load conditions.The number of outbound packets that were successfully transmitted within the Best Effort PHB class.The total number of octects received by the interface, including framing characters.Total number of samples transmitted during which the bandwidth utilization was within 26-50% of the configured bandwidth.The number of inbound packets that were delivered to higher-layer protocols.Total number of samples transmitted during which the bandwidth utilization was within 0-25% of the configured bandwidth.Total number of samples transmitted during which the bandwidth utilization was within 76-87% of the configured bandwidth.The number of outbound packets that were successfully transmitted.Total number of samples transmitted during which the bandwidth utilization was within 51-75% of the configured bandwidth.Total number of samples received during which the bandwidth utilization was within 0-25% of the configured bandwidth.Total number of samples transmitted during which the bandwidth utilization was greater than 87% of the configured bandwidth.The number of outbound octets within the Assured Forwarding 2 PHB class that were dropped in the IP scheduler due to congestion.Total number of samples received during which the bandwidth utilization was within 51-75% of the configured bandwidth.The number of outbound packets that were successfully transmitted within the Assured Forwarding 2 PHB class.Total number of samples received during which the bandwidth utilization was within 26-50% of the configured bandwidth.Number of bytes in dropped UDP packets due to uplink AAL2 prioritisation queue buffer overflow inside VCC.Number of bytes in dropped UDP packets due to uplink AAL2 prioritisation queue buffer overflow inside VCC.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.Average buffering delay per AAL2 prioritisation queue.Average buffering delay per AAL2 prioritisation queue.Number of bytes in dropped UDP packets due to uplink AAL2 prioritisation queue buffer overflow inside VCC.Number of bytes in dropped UDP packets due to uplink AAL2 prioritisation queue buffer overflow inside VCC.The number of inbound packets that were successfully received within the Assured Forwarding 3 PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 3 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 4 PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 4 PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 1 PHB class.The number of inbound packets that were successfully received within the Assured Forwarding 2 PHB class.The total number of octets received out of the interface, including framing characters, using the Assured Forwarding 2 PHB class.Maximum buffering delay per AAL2 prioritisation queue.The number of ingress Ethernet frames discarded due to rate limiting.Maximum buffering delay per AAL2 prioritisation queue.Number of Ethernet discarded RX frames due to VLAN mismatch.Average buffering delay per AAL2 prioritisation queue.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.Average buffering delay per AAL2 prioritisation queue.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.The number of inbound packets that were successfully received within the Expedited Forwarding PHB class.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.The total number of octets received by the interface, including framing characters, using Expedited Forwarding PHB class.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.The number of outbound packets within the Best Effort PHB class that were dropped in the IP scheduler due to congestion.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.Number of Ethernet TX packets discarded due to egress shaping per queue per interface.Number of scheduled HSDPA users per TTI when there are two HSDPA users in the target cell and six HSDPA users in the other cell (2-6).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are three HSDPA users in the target cell and one HSDPA user in the other cell (3-1).<br/>Note: The counter shows information from one Tcell group.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 12.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 10.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 11.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 8.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 9.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 6.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 7.

Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 4.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 5.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 3.The number of configured CCCH PS during the measurement period. This counter is generated only for BTSs having Rel3 FSM.The used number of CCCH PS during the measurement period. This counter is generated only for BTSs having Rel3 FSM.The configured (commissioned) HSUPA BTS level throughput.The configured (commissioned) HSDPA BTS level throughput.Number of configured (commissioned) HSUPA users.Number of configured (commissioned) HSDPA users.The BTS level baseband HW capacity expressed in subunits.<br/><br/>Note: Counter unit is the smallest subunit in the BTS.<br/><br/>Note: The counter does not contain free CCCH resources included in HW price.The sample with the maximum number of used baseband subunits. This is obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>Note: Counter unit is the smallest subunit in the BTS.<br/><br/>Note: The cNumber of scheduled HSDPA users per TTI when there are two HSDPA users in the target cell and five HSDPA users in the other cell (2-5).<br/>Note: The counter shows information from one Tcell group.The average number of used baseband subunits during the measurement period, obtained by sampling with a predefined sampling period, summing up all the samples, and dividing by the number of samples during the measurement period.<br/><br/>NoNumber of scheduled HSDPA users per TTI when there are two HSDPA users in the target cell and four HSDPA users in the other cell (2-4).<br/>Note: The counter shows information from one Tcell group.The sample with the minimum number of used baseband subunits, obtained by sampling with a predefined sampling period during measurement period.<br/><br/>Note: Counter unit is the smallest subunit in the BTS.<br/><br/>Note: The counter doesNumber of scheduled HSDPA users per TTI when there are two HSDPA users in the target cell and three HSDPA users in the other cell (2-3).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are two HSDPA users in the target cell and two HSDPA users in the other cell (2-2).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there is one HSDPA user in the target cell and six HSDPA users in the other cell (1-6).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there is one HSDPA user in the target cell and five HSDPA users in the other cell (1-5).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there is one HSDPA user in the target cell and four HSDPA users in the other cell (1-4).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there is one HSDPA user in the target cell and three HSDPA users in the other cell (1-3).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are no HSDPA users in the target cell and six HSDPA users in the other cell (0-6).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are no HSDPA users in the target cell and five HSDPA users in the other cell (0-5).<br/>Note: The counter shows information from one Tcell group.Total data amount sent on MAC-hs/ehs PDUs including both first transmissions and retransmissions.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 0.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 1.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 2.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 12.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 13.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 14.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 15.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 10.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 11.The number of bypassed ESP packets in ingress direction.The number of bypassed ESP packets in egress direction.This is the calculated average Round trip time (RTT) for TWAMP messages that the BTS has sent to its remote peer during the last 15 minutes for this TWAMP session.The number of successfully decrypted ESP packets in ingress direction.Number of scheduled HSDPA users per TTI when there are no HSDPA users in the target cell and four HSDPA users in the other cell (0-4).<br/>Note: The counter shows information from one Tcell group.The number of successfully encrypted ESP packets in egress direction.Number of samples used for received HSUPA power countersThe number of dropped ESP packets in ingress direction because of failed encryption.The number of dropped ESP packets in egress direction because of failed encryption.The number of licensed CCCH PS during the measurement period. This counter is generated only for BTSs having Rel3 FSM.Minimum received HSUPA power using the average over the measurement period.<br/>Note: In case when E-DCH load factor is zero (no users in the cell), then HSUPA Power is set to minimum (Max=Min=Avg = -112 dbm).Average HSUPA MAC-d throughput [kilobits/s] using the average over the measurement period samples.Amount of received HSUPA MAC-e/i data combining 10ms TTI and 2 ms TTI users (including retransmissions) per OperID over the measurement period.Average received HSUPA power using the average over the measurement period samples.<br/>Note: In case when E-DCH load factor is zero (no users in the cell), then HSUPA Power is set to minimum (Max=Min=Avg = -112 dbm).Amount of transferred HSDPA MAC-hs/ehs data (including retransmissions) per OperID over the measurement period.Maximum received HSUPA power using the average over the measurement period.<br/>Note: In case when E-DCH load factor is zero (no users in the cell), then HSUPA Power is set to minimum (Max=Min=Avg = -112 dbm).Number of measurement periods whose average power matches the power limits of class 6 (power >= 1.6W)Number of measurement periods whose average power matches the power limits of class 5 (0.8W<= power < 1.6W)Maximum HSUPA MAC-d throughput [kilobits/s] using the average over the measurement period.Minimum HSUPA MAC-d throughput [kilobits/s] using the average over the measurement period.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 7.

Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 8.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 5.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 6.UE Power Headroom value reported by the UE in the serving radio link set is 11.UE Power Headroom value reported by the UE in the serving radio link set is 12.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 9.UE Power Headroom value reported by the UE in the serving radio link set is 9.UE Power Headroom value reported by the UE in the serving radio link set is 10.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 0.The maximum HSDPA processing sets utilization ratio calculated as percentage of the used PS from the licensed PS, obtained by sampling with a predefined sampling period during measurement period. Retransmissions are included.<br/><br/>ProcessingThe minimum HSUPA processing sets utilization ratio calculated as percentage of the used PS from the licensed PS, obtained by sampling with a predefined sampling period during measurement period.<br/><br/>Processing set utilization ratio is based oTotal data amount sent on MAC-hs PDUs positively acknowledged for SPI class 3.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 4.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 1.Total data amount sent on MAC-hs PDUs positively acknowledged for SPI class 2.The minimum number of HSDPA users, obtained by sampling with a predefined sampling period during measurement period.The maximum number of HSUPA users, obtained by sampling with a predefined sampling period during measurement period.The average number of HSUPA users, obtained by sampling with a predefined sampling period during measurement period.The minimum number of HSUPA users, obtained by sampling with a predefined sampling period during measurement period.The average HSDPA processing sets utilization ratio calculated as percentage of the used PS from the licensed PS, obtained by sampling with a predefined sampling period during measurement period. Retransmissions are included.<br/><br/>Processing The minimum HSDPA processing sets utilization ratio calculated as percentage of the used PS from the licensed PS, obtained by sampling with a predefined sampling period during measurement period. Retransmissions are included.<br/><br/>Processing The maximum number of HSDPA users, obtained by sampling with a predefined sampling period during measurement period.The average number of HSDPA users, obtained by sampling with a predefined sampling period during measurement period.UE Power Headroom value reported by the UE in the serving radio link set is 5.UE Power Headroom value reported by the UE in the serving radio link set is 4.UE Power Headroom value reported by the UE in the serving radio link set is 3.UE Power Headroom value reported by the UE in the serving radio link set is 2.UE Power Headroom value reported by the UE in the serving radio link set is 8.UE Power Headroom value reported by the UE in the serving radio link set is 7.UE Power Headroom value reported by the UE in the serving radio link set is 6.Based on pseudowire sequence numbers, an estimation of the number of lost packets will be provided guided by RFC 4717.Amount of data transferred in RACH in the uplink direction during the measurement interval.Amount of data transferred in PCH and FACH in the downlink direction during the measurement interval.Amount of MAC-e PDU data transferred in the E-DCH serving cell in the uplink direction during the measurement interval. The MAC-e header includes to the MAC-e PDU data calculation.<br/>This counter is also used for MAC-i PDU data amount calcAmount of MAC-e PDU data transferred in the E-DCH non-serving cell in the serving radiolink set in the uplink direction during the measurement interval. The MAC-e header includes to the MAC-e PDU data calculation.<br/>This counter is also usedAmount of MAC-e PDU data transferred in the E-DCH non-serving cell in the non-serving radiolink set in the uplink direction during the measurement interval. The MAC-e header includes to the MAC-e PDU data calculation.<br/>This counter is also Number of HS-DSCH credit reductions due to MAC-HS buffer filling.UE Power Headroom value reported by the UE in the serving radio link set is 0.UE Power Headroom value reported by the UE in the serving radio link set is 1.The maximum number of subunits used for HSUPA, obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>Note: Counter unit is the smallest subunit in the BTS.<br/><br/>Note: The counter does not containNumber of transmitted packets on a tunnel.Number of lost Ethernet frames carrying PWE frames. Note! This counter is not supported. Instead, the packet loss is measured by M5113C2.Unavailable Seconds (UAS):<br/>Counts the number of seconds for which the interface is unavailable.<br/>The interface is defined unavailable from either the beginning of 10 contiguous SES and/or a defect.<br/>An interface is available again after aSeverely Errored Seconds (SES):<br/>Counts the number of seconds that contain a defect.<br/>Defect: BFD down in the ingress or egress direction.<br/>SES are not incremented during Unavailable Seconds (UAS).<br/>Standard: [G.826]The percentage of BTS hardware capacity utilization calculated as the licensed capacity (HSUPA + HSDPA + R99 CE licensed capacity) related to the hardware capacity available for licensing during measurement period. <br/><br/>Note: CCCH capaciThe maximum HSUPA processing sets utilization ratio calculated as percentage of the used PS from the licensed PS, obtained by sampling with a predefined sampling period during measurement period.<br/><br/>Processing set utilization ratio is based The maximum available licensed HSUPA BTS level throughput.The maximum available licensed HSDPA BTS level throughput.The number of available licensed HSUPA users.The number of available licensed HSDPA users.The average number of subunits used for HSUPA during the measurement period, obtained by sampling with a predefined sampling period, summing up all the samples, and dividing by the number of samples collected during the measurement period.<bThe minimum number of subunits used for HSUPA, obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>Note: Counter unit is the smallest subunit in the BTS.<br/><br/>Note: The counter does not containNumber of scheduled HSDPA users per TTI when there are three HSDPA users in the target cell and three HSDPA users in the other cell (3-3).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are three HSDPA users in the target cell and two HSDPA users in the other cell (3-2).<br/>Note: The counter shows information from one Tcell group.

Number of scheduled HSDPA users per TTI when there are three HSDPA users in the target cell and five HSDPA users in the other cell (3-5).<br/>Note: The counter shows information from one Tcell group.Number of scheduled HSDPA users per TTI when there are three HSDPA users in the target cell and four HSDPA users in the other cell (3-4).<br/>Note: The counter shows information from one Tcell group.Number of HS-DSCH credit reductions due to Iub delay build-up.Number of scheduled HSDPA users per TTI when there are three HSDPA users in the target cell and six HSDPA users in the other cell (3-6).<br/>Note: The counter shows information from one Tcell group.The average HSUPA processing sets utilization ratio calculated as percentage of the used PS from the licensed PS, obtained by sampling with a predefined sampling period during measurement period.<br/><br/>Processing set utilization ratio is based oNumber of HS-DSCH credit reductions due to frame loss.Number of HS-DSCH credit reductions due to severe Iub delay build-up.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.05 < L <= 0.10). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional Load (L) has been in class 1 limits (0 < L <= 0.05) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoisThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.15 < L <= 0.20) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.10 < L <= 0.15) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.90 < L <= 0.95). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.85 < L <= 0.90). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional Load (L) has been in class 0 limits (L = 0) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal)The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.95 < L <= 1). Residual Stream Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.UE Power Headroom value reported by the UE in the serving radio link set is 17.UE Power Headroom value reported by the UE in the serving radio link set is 18.UE Power Headroom value reported by the UE in the serving radio link set is 13.UE Power Headroom value reported by the UE in the serving radio link set is 14.UE Power Headroom value reported by the UE in the serving radio link set is 15.UE Power Headroom value reported by the UE in the serving radio link set is 16.This is the number of transmitted TWAMP messages for the TWAMP session.This the number of lost TWAMP messages for the TWAMP session.This is the maximum detected Round trip time (RTT) for TWAMP messages that the BTS has sent to its remote peer during the last 15 minutes.This is the minimum detected Round trip time (RTT) for TWAMP messages that the BTS has sent to its remote peer during the last 15 minutes.The number of packets that are transmitted over the PPP Multi Link interface.The number of packets that are received over the PPP Multi Link interface.The number of octets transmitted over the PPP Multi Link interface.The number of octets received over the PPP Multi Link interface.The number of PPP packets that are discarded on the PPP Multi Link interface. This includes packets could not be re-assembled due to missing MP fragments.The number of octets transmitted over the PPP Single Link interface.Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 14Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 13The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 0 (TP <= 32 kbps).Total data volume successfully received in MAC-e / MAC-i PDUs in bytes for SPI class 15.The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 2 (64 kbps < TP <= 128 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 1 (32 kbps < TP <= 64 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 4 (256 kbps < TP <= 384 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 3 (128 kbps < TP <= 256 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created was within the limits of class 6 (512 kbps < TP <= 1024 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 5 (384 kbps < TP <= 512 kbps).The number of outbound octets within the Expedited Forwarding PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Expedited Forwarding PHB class that were dropped in the IP scheduler due to congestion.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 4 PHB class.The number of outbound packets that were successfully transmitted within the Assured Forwarding 4 PHB class.The counter counts all packets that arrived too late in relation to the jitter buffer of the CES pseudowire.This counter collects statistics for the minimum packet delay variation of CES packets for the pseudowire. The counter value is the minimum delay measured over all packets within the sampling period of 15 minutes.This counter collects statistics for the maximum packet delay variation of CES packets for the pseudowire. The counter value is the minimum delay measured over all packets within the sampling period of 15 minutes.This counter collects statistics for packet delay variation average per pseudowire. The counter value is the average delay measured over all packets within the sampling period of 15 minutes.The total number of octets transmitted by the interface, including framing characters, using Expedited Forwarding PHB class.The number of outbound packets that were successfully transmitted within the Expedited Forwarding PHB class.Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 13 (0.6 < L <= 0.65).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 11 (0.5 < L <= 0.55).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 12 (0.55 < L <= 0.6).

Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 9 (0.4 < L <= 0.45).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 10 (0.45 < L <= 0.5).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 7 (0.3 < L <= 0.35).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 8 (0.35 < L <= 0.4).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 5 (0.2 < L <= 0.25).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 6 (0.25 < L <= 0.3).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 4 (0.15 < L <= 0.2).Number of samples in HS-PDSCH within the limits of class 02 (10 % < HS-PDSCH trx pwr <= 20 %). The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of TTIs that the UE has indicated with the Happy Bit in E-DPCCH that it is unhappy for the current allocation.Number of samples in HS-PDSCH within the limits of class 01 (HS-PDSCH trx pwr <= 10 %). The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 18 (0.85 < L <= 0.9).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 19 (0.9 < L <= 0.95).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 20 (0.95 < L <= 1).Number of TTIs that the UE has indicated with the Happy Bit in E-DPCCH that it is happy for the current allocation.Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 14 (0.65 < L <= 0.7).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 15 (0.7 < L <= 0.75).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 16 (0.75 < L <= 0.8).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 17 (0.8 < L <= 0.85).The average number of used R99 CEs in UL direction. The counter includes: <br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 users, and<br/>- R99 CEs consumed for CCCHs.<br/> <br/>Note: CCCHs consume R99 CEs only in Flexi Rel. The maximum number of used R99 CEs in UL direction. The counter includes: <br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 users, and<br/>- R99 CEs consumed for CCCHs.<br/> <br/>Note: CCCHs consume R99 CEs only in Flexi Rel. 2The minimum number of used R99 CEs in DL direction. The counter includes: <br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 users, and<br/>- R99 CEs consumed for CCCHs.<br/> <br/>Note: CCCHs consume R99 CEs only in Flexi Rel. The counter shows how many utilization rate samples have been detected within the (50 - <70)% class per uplink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all availablUE Power Headroom value reported by the UE in the non-serving radio link set is 24.The counter shows how many utilization rate samples have been detected within the (70 - <80)% class per uplink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all availablUE Power Headroom value reported by the UE in the non-serving radio link set is 25.The minimum number of used R99 CEs in UL direction. The counter includes: <br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 users, and<br/>- R99 CEs consumed for CCCHs.<br/> <br/>Note: CCCHs consume R99 CEs only in Flexi Rel. UE Power Headroom value reported by the UE in the non-serving radio link set is 22.The counter shows how many utilization rate samples have been detected within the (0 - <50)% class per uplink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all available UE Power Headroom value reported by the UE in the non-serving radio link set is 23.The counter shows how many utilization rate samples have been detected within the 100% class per uplink direction. Each utilization rate sample calculates the total number of R99 Channel Elements (CE) in use divided by the number of all availablThe counter shows how many utilization rate samples have been detected within the (80 - <90)% class per uplink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all availablUE Power Headroom value reported by the UE in the non-serving radio link set is 26.The counter shows how many utilization rate samples have been detected within the (90 - <100)% class per uplink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all availabUE Power Headroom value reported by the UE in the non-serving radio link set is 17.UE Power Headroom value reported by the UE in the non-serving radio link set is 20.UE Power Headroom value reported by the UE in the non-serving radio link set is 21.UE Power Headroom value reported by the UE in the non-serving radio link set is 18.UE Power Headroom value reported by the UE in the non-serving radio link set is 19.Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The fractional load is calculated in the normal scheduling operation matches to limits defined for class 0 (L = 0).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 1 (0 < L <= 0.05).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 2 (0.05 < L <= 0.1).Rise Over Thermal in Fractional load:L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise.<br/>The fractional load is calculated in the normal scheduling operation matches<br/>to limits defined for class 3 (0.1 < L <= 0.15).UE Power Headroom value reported by the UE in the non-serving radio link set is 27.UE Power Headroom value reported by the UE in the non-serving radio link set is 28.UE Power Headroom value reported by the UE in the non-serving radio link set is 29.UE Power Headroom value reported by the UE in the non-serving radio link set is 30.UE Power Headroom value reported by the UE in the non-serving radio link set is 31.Number of non-serving E-RGCH commands sent due to power overload.The counter shows how many utilization rate samples have been detected within the (50 - <70)% class per uplink direction. Each utilization rate sample calculates the number of HSUPA users in use divided by the licensed number of HSUPA users.The counter shows how many utilization rate samples have been detected within the (70 - <80)% class per uplink direction. Each utilization rate sample calculates the number of HSUPA users in use divided by the licensed number of HSUPA users.The minimum number of used CSoHSPA Channel Elements.The counter shows how many utilization rate samples have been detected within the (0 - <50)% class per uplink direction. Each utilization rate sample calculates the number of HSUPA users in use divided by the licensed number of HSUPA users.The average number of used CSoHSPA Channel Elements.UE Power Headroom value reported by the UE in the serving radio link set is 31.

UE Power Headroom value reported by the UE in the serving radio link set is 30.UE Power Headroom value reported by the UE in the serving radio link set is 29.UE Power Headroom value reported by the UE in the non-serving radio link set is 6.UE Power Headroom value reported by the UE in the non-serving radio link set is 5.The counter shows how many utilization rate samples have been detected within the (50 - <70)% class per downlink direction. Each utilization rate sample calculates the number of HSDPA users in use divided by the licensed number of HSDPA users.UE Power Headroom value reported by the UE in the non-serving radio link set is 4.The counter shows how many utilization rate samples have been detected within the (0 - <50)% class per downlink direction. Each utilization rate sample calculates the number of HSDPA users in use divided by the licensed number of HSDPA users.UE Power Headroom value reported by the UE in the non-serving radio link set is 3.The counter shows how many utilization rate samples have been detected within the 100% class per uplink direction. Each utilization rate sample calculates the number of HSUPA users in use divided by the licensed number of HSUPA users.UE Power Headroom value reported by the UE in the non-serving radio link set is 2.The counter shows how many utilization rate samples have been detected within the (90 - <100)% class per uplink direction. Each utilization rate sample calculates the number of HSUPA users in use divided by the licensed number of HSUPA users.UE Power Headroom value reported by the UE in the non-serving radio link set is 1.The counter shows how many utilization rate samples have been detected within the (80 - <90)% class per uplink direction. Each utilization rate sample calculates the number of HSUPA users in use divided by the licensed number of HSUPA users.UE Power Headroom value reported by the UE in the non-serving radio link set is 0.The counter shows how many utilization rate samples have been detected within the (0 - <50)% class per downlink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all availabThe counter shows how many utilization rate samples have been detected within the (50 - <70)% class per downlink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all availaThe counter shows how many utilization rate samples have been detected within the (70 - <80)% class per downlink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all availaThe counter shows how many utilization rate samples have been detected within the (80 - <90)% class per downlink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all availaUE Power Headroom value reported by the UE in the non-serving radio link set is 8.UE Power Headroom value reported by the UE in the non-serving radio link set is 7.UE Power Headroom value reported by the UE in the non-serving radio link set is 10.UE Power Headroom value reported by the UE in the non-serving radio link set is 9.The maximum number of used CSoHSPA Channel Elements.UE Power Headroom value reported by the UE in the non-serving radio link set is 16.The minimum number of available CSoHSPA Channel Elements. In Flexi rel2 WCDMA BTS when baseband pooling is in use, the counter indicates minimum number of CSoHSPA Channel Elements available for the LCG at the counter sampling momUE Power Headroom value reported by the UE in the non-serving radio link set is 15.The counter shows how many utilization rate samples have been detected within the 100% class per downlink direction. Each utilization rate sample calculates the total number of R99 Channel Elements (CE) in use divided by the number of all availaUE Power Headroom value reported by the UE in the non-serving radio link set is 12.The counter shows how many utilization rate samples have been detected within the (90 - <100)% class per downlink direction. Each utilization rate sample calculates the total number of R99 Channel Elements in use divided by the number of all avaiUE Power Headroom value reported by the UE in the non-serving radio link set is 11.The average number of available CSoHSPA Channel Elements. In Flexi rel2 WCDMA BTS when baseband pooling is in use, the counter indicates average number of CSoHSPA Channel Elements available for the LCG at the counter sampling momenUE Power Headroom value reported by the UE in the non-serving radio link set is 14.The maximum number of available CSoHSPA Channel Elements. In Flexi rel2 WCDMA BTS when baseband pooling is in use, the counter indicates maximum number of CSoHSPA Channel Elements available for the LCG at the counter sampling moUE Power Headroom value reported by the UE in the non-serving radio link set is 13.The minimum amount of used CE for UL direction, obtained by sampling with a predefined sampling during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter includes:<br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 uThe average amount of used CE for UL direction, obtained by sampling with a predefined sampling during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter includes:<br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 uThe maximum amount of used CE for DL direction, obtained by sampling with a predefined sampling during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter includes:<br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 uThe average amount of CE used for R99 users in DL direction, obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter calculates all DCH and CCCH used resources. <br/><br/>IThe maximum amount of CE used for R99 users in DL direction, obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter calculates all DCH and CCCH used resources. <br/><br/>The maximum amount of used CE for UL direction, obtained by sampling with a predefined sampling during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter includes:<br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 uThe minimum amount of CE used for R99 users in DL direction, obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter calculates all DCH and CCCH used resources. <br/><br/>IThe maximum amount of CE used for R99 users in UL direction, obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter calculates all DCH and CCCH used resources. <br/><br/>The average amount of CE used for R99 users in UL direction, obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter calculates all DCH and CCCH used resources. <br/><br/>IThe minimum amount of CE used for R99 users in UL direction, obtained by sampling with a predefined sampling period during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter calculates all DCH and CCCH used resources. <br/><br/>IThe counter shows how many utilization rate samples have been detected within the (70 - <80)% class per downlink direction. Each utilization rate sample calculates the number of HSDPA users in use divided by the licensed number of HSDPA users.The counter shows how many utilization rate samples have been detected within the (80 - <90)% class per downlink direction. Each utilization rate sample calculates the number of HSDPA users in use divided by the licensed number of HSDPA users.The counter shows how many utilization rate samples have been detected within the (90 - <100)% class per downlink direction. Each utilization rate sample calculates the number of HSDPA users in use divided by the licensed number of HSDPA userThe counter shows how many utilization rate samples have been detected within the 100% class per downlink direction. Each utilization rate sample calculates the number of HSDPA users in use divided by the licensed number of HSDPA users.The maximum HSDPA MAC-hs/ehs throughput (including retransmissions) during the measurement period, obtained by sampling with a predefined sampling period during measurement period.The average HSDPA MAC-hs/ehs throughput (including retransmissions) that is the sum of the sampled data divided by the number of sampling periods during the measurement period.UE Power Headroom value reported by the UE in the serving radio link set is 20.UE Power Headroom value reported by the UE in the serving radio link set is 19.The average HSUPA MAC-e/i throughput (including retransmissions) that is the sum of the sampled data divided by the number of sampling periods during the measurement period.UE Power Headroom value reported by the UE in the serving radio link set is 22.

The maximum HSUPA MAC-e/i throughput (including retransmissions) during the measurement period, obtained by sampling with a predefined sampling period during measurement period.UE Power Headroom value reported by the UE in the serving radio link set is 21.The average amount of used CE for DL direction, obtained by sampling with a predefined sampling during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter includes:<br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 uUE Power Headroom value reported by the UE in the serving radio link set is 24.The minimum amount of used CE for DL direction, obtained by sampling with a predefined sampling during the measurement period.<br/><br/>In Flexi Rel. 2 HW, the counter includes:<br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 uUE Power Headroom value reported by the UE in the serving radio link set is 23.UE Power Headroom value reported by the UE in the serving radio link set is 26.UE Power Headroom value reported by the UE in the serving radio link set is 25.UE Power Headroom value reported by the UE in the serving radio link set is 28.UE Power Headroom value reported by the UE in the serving radio link set is 27.The BTS shall count the number of transmitted RSTP BPDUs for each RSTP-enabled port.The BTS shall count the number of received RSTP BPDUs for each RSTP-enabled port.The BTS shall count the number of port state transitions for each RSTP-enabled port and for each configured spanning tree.The number of seconds during this interval while the timing over packet service was in synchronous state.The minimum value of the timing over packet service phase error in ppb during the interval.<br/>The unit applicable to FSM r2 is us and for FSMr3 is ppb/1000.The number of packets that are transmitted over the PPP Single Link interface.The number of PPP packets that are discarded on the PPP Single Link interface. This includes packets could not be re-assembled due to missing MP fragments.The number of packets that are received over the PPP Single Link interface.Number of transport frames/packets discarded due to egress shaping (Buffer<br/>overflow).The number of octets received over the PPP Single Link interface.Number of received FP data frames with other error reasons from high speed downlink shared channels.Number of MAC-e PDUs that are received correctly but lost for an unknown reason, such as buffer overflow. This counter is also applicable for MAC-i.Number of successfully received FP data frames from high speed downlink shared channels.Number of received FP data frames with CRC error from high speed downlink shared channels.Payload data of FP high-speed downlink shared channels received from the Iub interface to the Local Cell Group.Number of received FP data frames with other error reasons from common channels.Number of received FP data frames with other error reasons from dedicated channels.Number of received FP data frames with too high delay from dedicated channels.Number of received FP data frames with CRC error from dedicated channels.Number of successfully received FP data frames from dedicated channels.The number of outbound packets that were successfully transmitted.The total number of octets received by the interface, including framing characters.The total number of octets transmitted by the interface, including framing characters.This is the maximum bit rate (kbps) which can be allocated by the CAC which<br/>is specified by the following configuration parameters:-<br/>If traffic shaping type is "OFF" or "WFQ", it is the<br/>subtraction of DCNCommittedBitRate and SignThe total number of packets that could not be transmitted over the interface due to congestion.The total number of octects that could not be transmitted over the interface due to congestion.The number of inbound packets that were delivered to higher-layer protocols.This is the maximum value of the reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.This is the minimum value of reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.This is the average value of reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.The number of inbound packets that contained errors preventing them from being deliverable to a higher-layer protocol.The total number of octets transmitted by the interface, including framing characters.The number of outbound packets that were successfully transmitted.The total number of octects received by the interface, including framing characters.The number of packets discarded due filter violations.The number of inbound packets that were delivered to higher-layer protocols.The number of received ToP event messages. Event messages are time stamped and used for clock recovery.The number of dropped packets due to rate limiting.The average value of the timing over packet service phase error in ppb during the interval.<br/>The unit applicable to FSM r2 is us and for FSMr3 is ppb/1000.The maximum value of the timing over packet service phase error in ppb during the interval.<br/>The unit applicable to FSM r2 is us and for FSMr3 is ppb/1000.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 2 PHB class.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 4 PHB class.The number of outbound packets that were successfully transmitted within the Assured Forwarding 4 PHB class.The number of outbound octets within the Assured Forwarding 4 PHB class that were dropped in the IP scheduler due to congestion.

The number of outbound packets within the Assured Forwarding 4 PHB class that were dropped in the IP scheduler due to congestion.The total number of octets transmitted out of the interface, including framing characters, using the Assured Forwarding 3 PHB class.The number of outbound packets that were successfully transmitted within the Assured Forwarding 3 PHB class.The number of outbound octets within the Assured Forwarding 3 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Assured Forwarding 3 PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets within the Expedited Forwarding PHB class that were dropped in the IP scheduler due to congestion.The number of outbound octets within the Expedited Forwarding PHB class that were dropped in the IP scheduler due to congestion.The number of outbound packets that were successfully transmitted within the Expedited Forwarding PHB class.This is the minimum value of reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.This is the average value of reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.The number of inbound packets that contained errors preventing them from being deliverable to a higher-layer protocol.This is the maximum value of the reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.The total number of octets that could not be transmitted over the interface due to congestion.The total number of octets transmitted by the interface, including framing characters, using Expedited Forwarding PHB class.This is the maximum bit rate (kbps) which can be allocated by the CAC which<br/>is specified by the following configuration parameters:-<br/>If traffic shaping type is "OFF" or "WFQ", it is the<br/>subtraction of DCNCommittedBitRate and Sign�The total number of packets that could not be transmitted over the interface due to congestion.The number of samples for monitoring average number of active HSDPA users in SPI class 8.The number of samples for monitoring average number of active HSDPA users in SPI class 7.The number of samples for monitoring average number of active HSDPA users in SPI class 10.The number of samples for monitoring average number of active HSDPA users in SPI class 9.The number of samples for monitoring average number of active HSDPA users in SPI class 12.The number of samples for monitoring average number of active HSDPA users in SPI class 11.The number of samples for monitoring average number of active HSDPA users in SPI class 14.The number of samples for monitoring average number of active HSDPA users in SPI class 13.The number of samples for monitoring average number of active HSDPA users in SPI class 6.The number of samples for monitoring average number of active HSDPA users in SPI class 5.The sum of all active HSDPA users. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 15 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 14 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 13 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The number of samples for monitoring average number of active HSDPA users in SPI class 3.The number of samples for monitoring average number of active HSDPA users in SPI class 2.The number of samples for monitoring average number of active HSDPA users in SPI class 1.The number of samples for monitoring average number of active HSDPA users in SPI class 0.The sum of active HSDPA users in SPI 12 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The number of samples for monitoring average number of active HSDPA users in SPI class 4.The number of samples for monitoring average number of allocated HSDPA users in SPI class 0.The sum of all allocated HSDPA users. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 13 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 12 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 15 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 14 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 9 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 8 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 11 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for him.The sum of allocated HSDPA users in SPI 10 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 7 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 6 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for him.The sum of allocated HSDPA users in SPI 5 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 4 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 3 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 2 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 1 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for himThe sum of allocated HSDPA users in SPI 0 class. The allocated user is a user receiving or waiting for data whether or not it is scheduled for him.

The number of samples for monitoring average number of all active HSDPA users.The number of samples for monitoring average number of active HSDPA users in SPI class 15.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.60 < L <= 0.65) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.65 < L <= 0.70) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 7 (1024 kbps < TP <= 1536 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 8 (1536 kbps < TP <= 2048 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 9 (2048 kbps < TP <= 3072 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 10 (3072 kbps < TP <= 4096 kbps).The average Layer 1 HSUPA throughput from the time HSUPA transport channel was created within the limits of class 11 (TP > 4096 kbps).Total amount of positively acknowledged Multi-Carrier HSDPA data sent on MAC-ehs PDUs in the primary cell.Total amount of Multi-Carrier HSDPA original data (first transmissions) sent on MAC-ehs PDUs in the primary cell.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.25 < L <= 0.30) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoTotal amount of positively acknowledged Multi-Carrier HSDPA data sent on MAC-ehs PDUs in the secondary cell.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.20 < L <= 0.25) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoTotal amount of HSDPA original data (first transmissions) sent on MAC-hs/ehs PDUs. This counter includes legacy single carrier, Multi-Carrier and MIMO HSDPA data.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.35 < L <= 0.40) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoTotal amount of Multi-Carrier HSDPA original data (first transmissions) sent on MAC-ehs PDUs in the secondary cell.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.30 < L <= 0.35) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.45 < L <= 0.50) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.40 < L <= 0.45) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.55 < L <= 0.60) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.50 < L <= 0.55) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe sum of active HSDPA users in SPI 6 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 7 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 8 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 9 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 2 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 3 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 4 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of active HSDPA users in SPI 5 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of sampled values for the number of capable DC-HSDPA MIMO users. When this counter is updated the counter M5000C330 is updated as well.The sum of sampled values for the number of active DC-HSDPA MIMO users. Active DC-HSDPA MIMO users use only one carrier for transmission. This counter, divided by the denominator M5000C327, provides the average number of active DC-HSDScheduled DC-HSDPA + MIMO users only from primary carrier when one carrier and MIMO Single Stream is used. When this counter is updated the counters M5000C331 and M5000C335 are updated as well.Scheduled DC-HSDPA + MIMO users only from primary carrier when one carrier and MIMO Dual Stream is used. When this counter is updated the counters M5000C331 and M5000C336 are updated as well.The sum of active HSDPA users in SPI 11 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The maximum value for concurrent users in Enhanced Cell FACH state. Users having only DL HS_FACH (without HS in uplink) are also counted.The sum of active HSDPA users in SPI 10 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The sum of sampled number of users in Enhanced Cell FACH state. Users having only DL HS_FACH (without HS in uplink) are also counted.The sum of sampled values for the number of active DC-HSDPA MIMO users. Active DC-HSDPA MIMO users use both carriers for transmission. This counter, divided by the denominator M5000C327, provides the average number of active DC-HSDPA The number of PRACH Preambles received by BTS not granted a Common E-DCH Resource.Duration of UE in HSFACH DRX (Discontinuous Reception) stateDuration of UE in HSFACH RX (Reception) stateUL Control Data volume in Enhanced Cell FACH state.Time need to transmit UL User Data in Enhanced Cell FACH state.Time need to transmit DL Control Data in Enhanced Cell FACH state.UL User Data volume in Enhanced Cell FACH state.DL Control Data volume in Enhanced Cell FACH state.Time need to transmit DL User Data in Enhanced Cell FACH state.The number of four simultaneously scheduled HSDPA users per TTI in WCELL.DL User Data volume in Enhanced Cell FACH state.The number of three simultaneously scheduled HSDPA users per TTI in WCELL.The number of two simultaneously scheduled HSDPA users per TTI in WCELL.The number of one per TTI scheduled HSDPA users in WCELL.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.95 < L <= 1) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (Pnoise

The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.90 < L <= 0.95) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe sum of active HSDPA users in SPI 1 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.85 < L <= 0.90) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe sum of active HSDPA users in SPI 0 class. The active user means a user who has data in the BTS buffer and the data is sent to the user.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.80 < L <= 0.85) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoTime need to transmit UL Control Data in Enhanced Cell FACH state.The number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.75 < L <= 0.80) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThe number of scheduling periods where the Rise Over Thermal in Residual Stream Fractional load (L) has been in class 1 limits (0.70 < L <= 0.75) and there has been UnHappy UE in the cell. Residual Stream Fractional load is defined as L = 1 - (PnoThis is the average value of reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.This is the maximum value of the reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.This is the minimum value of reserved bit rate for CAC utilization (in kbps) measured during the measurement interval.Maximum number of used Channel Elements in Uplink direction. Counter includes all CCH, DCH, HSDPA and HSUPA used resources.HSUPA used resources includes both the Channel Elements reserved statically after HSUPA enabling and later dynaMinimum number of used Channel Elements in Downlink direction. Counter includes all CCH, DCH, HSDPA and HSUPA used resources. HSUPA used resources includes both the Channel Elements reserved statically after HSUPA enabling and laterAverage number of available Channel Elements. In Ultrasite WCDMA BTS counter is the average amount of working baseband resources (HW capacity). In Flexi WCDMA BTS when baseband pooling is not used, counter is the average amount of sum ofMaximum number of used Channel Elements in Downlink direction.Counter includes all CCH, DCH, HSDPA and HSUPA used resources. HSUPA used resources includes both the Channel Elements reserved statically after HSUPA enabling and later dyAverage number of used Channel Elements in Uplink direction. Counter includes all CCH, DCH, HSDPA and HSUPA used resources.HSUPA used resources includes both the Channel Elements reserved statically after HSUPA enabling and later dyMaximum number of used Channel Elements for HSUPA in Uplink direction. HSUPA used resources includes Channel Elements reserved for HSUPA users.<br/>Note: This counter is not supported anymore in Rel2 BTS HW with WN7.0 or later SWMinimum number of used Channel Elements in Uplink direction. Counter includes all CCH, DCH, HSDPA and HSUPA used resources. HSUPA used resources includes both the Channel Elements reserved statically after HSUPA enabling and later dAverage number of used Channel Elements in Downlink direction. Counter includes all CCH, DCH, HSDPA and HSUPA used resources. HSUPA used resources includes both the Channel Elements reserved statically after HSUPA enabling and laterMinimum number of used Channel Elements for HSUPA in Uplink direction. HSUPA used resources includes Channel Elements reserved for HSUPA users.<br/>Note: This counter is not supported anymore in Rel2 BTS HW with WN7.0 or later SW.Average number of used Channel Elements for HSUPA in Uplink direction. HSUPA used resources includes Channel Elements reserved for HSUPA users.<br/>Note: This counter is not supported anymore in Rel2 BTS HW with WN7.0 or later SW.The number of outbound packets that were successfully transmitted.The total number of octects received by the interface, including framing characters.The number of inbound packets that were delivered to higher-layer protocols.The number of packets discarded due filter violations.The number of dropped packets due to rate limiting.The number of inbound packets that contained errors preventing them from being deliverable to a higher-layer protocol.The total number of octets transmitted by the interface, including framing characters.The number of compensated Channel Quality Indicator (CQI) values 1.The number of compensated Channel Quality Indicator (CQI) values 2.Scheduled DC-HSDPA + MIMO users only from secondary carrier when one carrier and MIMO Dual Stream is used. When this counter is updated the counters M5000C332 and M5000C336 are updated as well.Scheduled DC-HSDPA + MIMO users only from secondary carrier when one carrier and MIMO Single Stream is used. When this counter is updated the counters M5000C332 and M5000C335 are updated as well.Scheduled DC-HSDPA + MIMO users when both carriers are used and MIMO Dual Stream is used in both primary and secondary cells. When this counter is updated the counters M5000C333, M5000C334 and M5000C336 are updated as well.Scheduled DC-HSDPA + MIMO users when both carriers are used and MIMO Dual Stream and Single Stream is used in primary and secondary cell respectively. When this counter is updated the counters M5000C333, M5000C334,M5000C335 and Scheduled DC-HSDPA + MIMO users when both carriers are used and MIMO Single Stream and Dual Stream is used in primary and secondary cell respectively. When this counter is updated the counters M5000C333, M5000C334,M5000C335 and Scheduled DC-HSDPA + MIMO users when both carriers are used and MIMO Single Stream is used in both primary and secondary cell. When this counter is updated the counters M5000C333, M5000C334 and M5000C335 are updated as well.Number of DL user data frames processed in order to transmit to the UE in Enhanced Cell FACH state. Sampling period is 100 ms for this counter.Number of DL control data frames processed in order to transmit to the UE in Enhanced Cell FACH state. Sampling period is 100 ms for this counter.Maximum number of available Channel Elements. In Ultrasite WCDMA BTS counter is the maximum amount of working baseband resources (HW capacity). In Flexi WCDMA BTS when baseband pooling is not used, counter is the maximum amount of sum Minimum number of available Channel Elements. In Ultrasite WCDMA BTS counter is the minimum amount of working baseband resources (HW capacity). In Flexi WCDMA BTS when baseband pooling is not used, counter is the minimum amount of sum oThe total number of packets that could not be transmitted over the interface due to congestion.This is the maximum bit rate (kbps) which can be allocated by the CAC which<br/>is specified by the following configuration parameters:-<br/>If traffic shaping type is "OFF" or "WFQ", it is the<br/>subtraction of DCNCommittedBitRate and SignThe number of ethernet packets received on the interface.The total number of octects that could not be transmitted over the interface due to congestion.The number of ethernet packets transmitted on the interface.The number of ethernet bytes received on the interface.The number of compensated Channel Quality Indicator (CQI) values 0.The number of ethernet bytes transmitted on the interface.The counter shows how many utilization rate samples have been detected within the 100% class per downlink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of all availThe counter shows how many utilization rate samples have been detected within the (0 - 20)% class per uplink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number of allThe counter shows how many utilization rate samples have been detected within the (80 - <90)% class per downlink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of alThe counter shows how many utilization rate samples have been detected within the (90 - <100)% class per downlink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of aThe counter shows how many utilization rate samples have been detected within the (50 - <70)% class per downlink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of alThe counter shows how many utilization rate samples have been detected within the (70 - <80)% class per downlink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of al

The number of compensated Channel Quality Indicator (CQI) values 12.The counter shows how many utilization rate samples have been detected within the (>60 - 80)% class per uplink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number of aThe counter shows how many utilization rate samples have been detected within the (>80 - 100)% class per uplink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number of The counter shows how many utilization rate samples have been detected within the (>20 - 40)% class per uplink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number of aThe counter shows how many utilization rate samples have been detected within the (>40 - 60)% class per uplink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number of aThe number of compensated Channel Quality Indicator (CQI) values 3.The number of compensated Channel Quality Indicator (CQI) values 11.The number of compensated Channel Quality Indicator (CQI) values 10.The number of compensated Channel Quality Indicator (CQI) values 9.The number of compensated Channel Quality Indicator (CQI) values 8The number of compensated Channel Quality Indicator (CQI) values 7.The number of compensated Channel Quality Indicator (CQI) values 6.The number of compensated Channel Quality Indicator (CQI) values 5.The number of compensated Channel Quality Indicator (CQI) values 4.Minimum number of used Channel Elements for HSUPA in Downlink direction. HSUPA used resources includes Channel Elements reserved for HSUPA users.<br/>Note: This counter is not supported anymore in Rel2 BTS HW with WN7.0 or later Average number of used Channel Elements for HSUPA in Downlink direction. HSUPA used resources includes Channel Elements reserved for HSUPA users.<br/>Note: This counter is not supported anymore in Rel2 BTS HW with WN7.0 or later SThe counter shows how many utilization rate samples have been detected within the (0 - <50)% class per uplink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of all aThe counter shows how many utilization rate samples have been detected within the (50 - <70)% class per uplink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of all Maximum number of used Channel Elements for HSUPA in Downlink direction. HSUPA used resources includes Channel Elements reserved for HSUPA users.<br/>Note: This counter is not supported anymore in Rel2 BTS HW with WN7.0 or later The counter shows how many utilization rate samples have been detected within the (0 - <50)% class per downlink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of allThe counter shows how many utilization rate samples have been detected within the (70 - <80)% class per uplink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of all The counter shows how many utilization rate samples have been detected within the (80 - <90)% class per uplink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of all The counter shows how many utilization rate samples have been detected within the (90 - <100)% class per uplink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of allThe counter shows how many utilization rate samples have been detected within the 100% class per uplink direction. Each utilization rate sample calculates the total number of Channel Elements (CE) in use divided by the number of all availabThe number of compensated Channel Quality Indicator (CQI) values 14.The number of compensated Channel Quality Indicator (CQI) values 13.The number of compensated Channel Quality Indicator (CQI) values 20.The number of compensated Channel Quality Indicator (CQI) values 19.The number of compensated Channel Quality Indicator (CQI) values 22.The number of compensated Channel Quality Indicator (CQI) values 21.The number of compensated Channel Quality Indicator (CQI) values 16.The number of compensated Channel Quality Indicator (CQI) values 15.The number of compensated Channel Quality Indicator (CQI) values 18.The number of compensated Channel Quality Indicator (CQI) values 17.Total number of ATM cells transmitted (CLP0 and 1) at an ATM Virtual Channel (VC).Total number of ATM cells received (CLP0 and 1) at an ATM Virtual Channel (VC).The number of incoming ATM cells that have been discarded due to protocol errors (for example, illegal VPI/VCI value).Count of incoming ATM cells discarded because of a Header Error Check (HEC) violation. Only PDH and SDH interfaces are covered. For the FTOA (the SDH/SONET transport submodule) this counter counts both non-correctable and correctable HECThis counter counts the number of seconds during which the ATM interface is unavailable.Total number of cells transmitted on an ATM interface.Total number of cells with the service category UBR transmitted on the ATM interface.Total number of cells with the service category UBR received on the ATM interface.Total number of cells with Service Category CBR transmitted on the ATM interface.Total number of cells with the service category CBR received on the ATM interface.The number of compensated Channel Quality Indicator (CQI) values 28.The number of samples for monitoring average number of allocated HSDPA users in SPI class 11.The number of compensated Channel Quality Indicator (CQI) values 29.The number of samples for monitoring average number of allocated HSDPA users in SPI class 12.The number of compensated Channel Quality Indicator (CQI) values 26.The number of compensated Channel Quality Indicator (CQI) values 27.The number of compensated Channel Quality Indicator (CQI) values 32.The number of samples for monitoring average number of allocated HSDPA users in SPI class 15.The number of samples for monitoring average number of all allocated HSDPA users.Total number of ATM cells received (CLP0 and 1) at an ATM Virtual Path (VP).

The number of compensated Channel Quality Indicator (CQI) values 30.The number of samples for monitoring average number of allocated HSDPA users in SPI class 13.The number of compensated Channel Quality Indicator (CQI) values 31.The number of samples for monitoring average number of allocated HSDPA users in SPI class 14.Amount of data transmitted in the downlink direction with demoted SPI, that is, any SPI value that is lower than the default SPI. The counter considers all cases of single PS NRT MAC-d queues per UE and multiple PS NRT MAC-d queues per UE in thAmount of data transmitted in the uplink direction with default SPI. Default SPI is the one that is received from RNC in NBAP RL Setup/Reconfiguration message. The counter considers all cases of single PS NRT MAC-d queues per UE in the cell aAmount of data transmitted in the downlink direction with default SPI. Default SPI is the one that is received from the RNC in NBAP RL Setup/Reconfiguration message. The counter considers all cases of single PS NRT MAC-d queues per UE and muAmount of data transmitted in the downlink direction with promoted SPI, that is, any SPI value that is higher than the default SPI. The counter considers all cases of single PS NRT MAC-d queues per UE and multiple PS NRT MAC-d queues per UE in tThe number of compensated Channel Quality Indicator (CQI) values 24.The number of compensated Channel Quality Indicator (CQI) values 25.The number of compensated Channel Quality Indicator (CQI) values 23.Background Block Errors (BBE): counts the number of errored blocks. Errored block is a block in which one or more bits are corrupted. Corruption is detected by inspecting the CRC information and/or the Frame Alignment Signal (FAS).<br/><br/>DoeNumber of samples where average transmission power compared to reference power matches the power limits of class 3 (40% <= power < 60%). The reference power is cell primary CPICH power.Severely Errored Seconds (SES): Counts the number of seconds which contain at least 30% errored blocks or one or more defects. Errored block is a block in which one or more bits are corrupted.<br/>Defect: LOS, LOF, AIS.<br/>SES is a subset oNumber of samples where average transmission power compared to reference power matches the power limits of class 2 (20% <= power < 40%). The reference power is cell primary CPICH power.Number of samples where average transmission power compared to reference power matches the power limits of class 5 (80% <= power). The reference power is cell primary CPICH power.Total number of cells received on an ATM interface.Number of samples where average transmission power compared to reference power matches the power limits of class 4 (60% <= power < 80%). The reference power is cell primary CPICH power.Number of scheduling periods where the Fractional Load has been in class 0 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is L = 0.Average HSUPA DL control channel transmission power during reporting period. Calculated as sum of average power of measuring periods divided by the number of measuring periods.Number of scheduling periods where the Fractional Load has been in class 1 limits and there has been UnHappy UE in the cell. Fractional load is defined as L = 1 - (Pnoise/Ptotal), Ptotal>=Pnoise. The class limit is 0 < L <= 0.05.The counter shows how many utilization rate samples have been detected within the (0 - 20)% class per downlink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number of aThe counter shows how many utilization rate samples have been detected within the (>40 - 60)% class per downlink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number ofThe counter shows how many utilization rate samples have been detected within the (>20 - 40)% class per downlink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number ofThe counter shows how many utilization rate samples have been detected within the (>80 - 100)% class per downlink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number oThe counter shows how many utilization rate samples have been detected within the (>60 - 80)% class per downlink direction. Each utilization rate sample calculates the number of Channel Elements (CE) in use in HSPA divided by the number ofErrored Seconds (ES): Counts the number of seconds with one or more errored blocks or at least one defect. Errored block is a block in which one or more bits are corrupted.<br/>Defect: LOS, LOF, AIS.<br/>ES are not incremented during UnavailabUnavailable Seconds (UAS): Counts the number of seconds for which the interface is unavailable.<br/>The interface is defined to be unavailable from either the beginning of 10 contiguous SES, and/or a defect.<br/>An interface is available again afteMaster HSUPA L2 is to estimate the maximum value of concurrent DC HSUPA configured users out of all samples during measurement period timestamp and update the value to this counter.Master HSUPA L2 is to determine the number of DC-HSUPA capable users using both primary and secondary carrier, sample with 100ms period and add to this counter. The counter is reset when the next measurement interval starts.Master HSUPA L2 is to estimate number of DC HSUPA capable users using only one carrier (primary), and sample with 100ms period and summed to this counter. The counter is reset when the next measurement interval starts.The number of samples for monitoring relative time of PIC active state.The number of samples for monitoring average number of allocated HSDPA users in SPI class 1.The number of samples for monitoring relative time of PIC inactive state.The number of samples for monitoring average number of allocated HSDPA users in SPI class 2.Number of SPI promotions in the downlink direction. Any SPI change where new SPI is higher than the default SPI received from the RNC in the NBAP RL Setup/Reconfiguration message is considered as promotion. The counter considers all caseThe number of samples for monitoring average number of allocated HSDPA users in SPI class 3.The number of samples for monitoring average number of allocated HSDPA users in SPI class 4.The number of samples for monitoring average number of allocated HSDPA users in SPI class 5.The number of samples for monitoring average number of allocated HSDPA users in SPI class 6.The number of samples for monitoring average number of allocated HSDPA users in SPI class 7.The number of samples for monitoring average number of allocated HSDPA users in SPI class 8.The number of samples for monitoring average number of allocated HSDPA users in SPI class 9.The number of compensated Channel Quality Indicator (CQI) values 33.The number of samples for monitoring average number of allocated HSDPA users in SPI class 10.The number of compensated Channel Quality Indicator (CQI) values 34.The number of compensated Channel Quality Indicator (CQI) values 35.Master HSUPA L2 is to determine the number of DC-HSUPA configured users, sample with 100ms period and sum the values to SUM counter.The highest number of CPC configured users in a sampling period.The sum of sampled values for the number of configured CPC users. This counter, divided by the denominator M5000C327, provides the average user amount during the measurement interval.The highest number of active CPC users in a sampling period.The sum of sampled values for the number of active CPC users. This counter, divided by the denominator M5000C327, provides the average user amount during the measurement interval.Number of retransmitted MAC-ehs PDUs using 64QAM modulation.Number of transmitted MAC-ehs PDUs using 64QAM modulation.

Number of dropped 656 bit MAC-d PDUs due to other reason.Number of dropped MAC-d PDUs due to other reason. This counter includes PDUs of all sizes.The average number of used R99 CEs in DL direction. The counter includes: <br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 users, and<br/>- R99 CEs consumed for CCCHs.<br/> <br/>Note: CCCHs consume R99 CEs only in Flexi Rel. The minimum number of available R99 CEs.<br/> <br/>In Flexi Rel. 2 HW and Flexi Rel. 3 HW WCDMA BTS, when baseband pooling is not used, the counter is the sum of:<br/>- minimum amount of R99 CE-licensed capacity and<br/>- R99 CE capacityThe maximum number of used R99 CEs in DL direction. The counter includes: <br/>- R99 CEs,<br/>- hybrid HSUPA resource steps used by R99 users, and<br/>- R99 CEs consumed for CCCHs.<br/> <br/>Note: CCCHs consume R99 CEs only in Flexi Rel. 2The maximum number of available R99 CEs.<br/> <br/>In Flexi Rel. 2 HW and Flexi Rel. 3 HW WCDMA BTS, when baseband pooling is not used, the counter is the sum of:<br/>- maximum amount of R99 CE-licensed capacity and<br/>- R99 CE capacityThe average number of available R99 CEs.<br/> <br/>In Flexi Rel. 2 HW and Flexi Rel. 3 HW WCDMA BTS, when baseband pooling is not used, the counter is the sum of:<br/>- average amount of R99 CE-licensed capacity and<br/>- R99 CE capacity Number of SPI demotions in the uplink direction. Any SPI change where new SPI is lower than the default SPI received from the RNC in the NBAP RL Setup/Reconfiguration message is considered as demotion. The counter considers all cases of sTotal number of DPCCH slots. Indicates all time slots, includes also DTX slots, sum over all serving Ues.Number of times the SPI is returned to its default value in the uplink direction. Any SPI change where new SPI is equal to the default SPI received from the RNC in the NBAP RL Setup/Reconfiguration message is considered by this counter. The coNumber of samples where average transmission power compared to reference power matches the power limits of class 1 (0% <= power <20%). The reference power is cell primary CPICH power.Number of times the SPI is returned to its default value in the downlink direction. Any SPI change where new SPI is equal to the default SPI received from the RNC in the NBAP RL Setup/Reconfiguration message is considered by this counter. TheNumber of SPI promotions in the uplink direction. Any SPI change where new SPI is higher than the default SPI received from the RNC in the NBAP RL Setup/Reconfiguration message is considered as promotion. The counter considers all cases ofNumber of received non-DTX DPCCH slots. Indicates the time slots that included DPCCH transmission, sum over all serving Ues.Number of SPI demotions in the downlink direction. Any SPI change where new SPI is lower than the default SPI received from the RNC in the NBAP RL Setup/Reconfiguration message is considered as demotion. The counter considers all cases oNumber of samples in HS-PDSCH within the limits of class 08 (70 % < HS-PDSCH trx pwr <= 80 %).The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of samples in HS-PDSCH within the limits of class 07 (60 % < HS-PDSCH trx pwr <= 70 %). The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of samples in HS-PDSCH within the limits of class 10 (90 % < HS-PDSCH trx pwr <= 100 %).The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of samples in HS-PDSCH within the limits of class 09 (80 % < HS-PDSCH trx pwr <= 90 %).The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of samples in HS-PDSCH within the limits of class 04 (30 % < HS-PDSCH trx pwr <= 40 %). The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of transmitted Ethernet packets on the interface.Number of samples in HS-PDSCH within the limits of class 03 (20 % < HS-PDSCH trx pwr <= 30 %).The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of samples in HS-PDSCH within the limits of class 06 (50 % < HS-PDSCH trx pwr <= 60 %). The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of samples in HS-PDSCH within the limits of class 05 (40 % < HS-PDSCH trx pwr <= 50 %). The sampled HS-DSCH power value is compared to the maximum HW trx power of the cell.Number of octets in valid frames received on the interface.Background Block Errors (BBE) on the SDH Path (B3):<br/>Counts the number of errored blocks not occurring during SES or UAS.<br/>Errored block: A block in which one or more bits are corrupted. Detected by inspecting the bit interleaved parity (BNumber of Ethernet packets received on the interface (errored and non-errored).Number of octets in valid frames transmitted on the interface.Unavailable Seconds (UAS) on the SDH Path (B3):<br/>Counts the number of seconds for which the SDH Path on the interface is unavailable.<br/>The interface is defined unavailable from either the beginning of 10 contiguous SES B3, or from the bTotal number of cells transmitted (CLP0 and 1) at an ATM Virtual Path (VP).Number of dropped 656 bit MAC-d PDUs due to BTS buffer overflow.Severely Errored Seconds (SES) on the SDH Path (B3):<br/>Counts the number of seconds which contain 30% errored blocks or at least one defect.<br/>Defect: LOS, LOF, AIS-MS, AIS-AU, LOP-AU, UNEQ-HP, PLM-HP.<br/>SES is a subset of ES.<br/>ErErrored Seconds (ES) on the SDH Path (B3): <br/>Counts the number of seconds with one or more errored blocks or at least one defect.<br/>Defect: LOS, LOF, AIS-MS, AIS-AU, LOP-AU, UNEQ-HP, PLM-HP.<br/>Errored block: A block in which one Payload data of FP common channels received from the Iub interface to the Local Cell Group.Payload data of FP dedicated channels sent to the Iub interface in the Local Cell Group.Payload data of FP dedicated channels received from the Iub interface to the Local Cell Group.Payload data of FP enhanced dedicated channels sent to the Iub interface in the Local Cell Group.Amount of data transmitted in the uplink direction with promoted SPI, that is, any SPI value that is higher than the default SPI. The counter considers all cases of single PS NRT MAC-d queues per UE in the cell and not the cases of multiple PS NRAmount of data transmitted in the uplink direction with demoted SPI, that is, any SPI value that is lower than the default SPI. The counter considers all cases of single PS NRT MAC-d queues per UE in the cell and not the cases of multiple PS NRT Payload data of FP common channels sent to the Iub interface in the Local Cell Group.Number of dropped MAC-d PDUs due to maximum number of retransmissions. This counter includes PDUs of all sizes.Number of dropped 656 bit MAC-d PDUs due to maximum number of retransmissions.Number of successfully received FP data frames from common channels.Number of received FP data frames with CRC error from common channels.Number of received FP data frames with too high delay from common channels.

Original releaseWN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN6.0 EP1WN6.0 EP1WN3.0/WP2.0WN6.0 EP1WN3.0/WP2.0WN6.0 EP1WN3.0/WP2.0WN6.0 EP1WN3.0/WP2.0WN6.0 EP1WN3.0/WP2.0WN6.0WN6.0WN6.0 EP1WN6.0 EP1WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0 EP1WN7.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN7.0WN3.0/WP2.0WN7.0WN3.0/WP2.0WN7.0WN7.0

WN3.0/WP2.0WN7.0WN7.0WN6.0 EP1WN7.0WN7.0WN7.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN7.0WN4.0/WP2.0WN7.0WN4.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN7.0WN3.0/WP2.0WN7.0WN3.0/WP2.0WN7.0WN3.0/WP2.0WN7.0WN3.0/WP2.0WN7.0WN7.0WN7.0WN7.0WN7.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0

WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN3.0/WP2.0WN6.0WN3.0/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN4.0/WP2.0WN3.2/WP2.0WN4.0/WP2.0WN3.2/WP2.0WN4.0/WP2.0WN3.2/WP2.0WN4.0/WP2.0WN5.0WN4.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN6.0WN6.0WN6.0WN6.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0WN6.0WN3.0/WP2.0WN6.0WN3.2/WP2.0WN4.0/WP2.0WN3.0WN4.0/WP2.0WN3.0WN4.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN3.0WN4.0/WP2.0WN4.0

WN4.0/WP2.0WN4.0WN4.0WN4.0/WP2.0WN3.0WN4.0/WP2.0WN4.0/WP2.0WN3.0WN4.0/WP2.0WN3.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN4.0/WP2.0WN3.0/WP2.0not supportedWN3.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN4.0WN3.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN4.0/WP2.0WN3.0/WP2.0WN4.0WN3.0/WP2.0WN4.0WN3.0/WP2.0WN4.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1

WN6.0 EP1WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN6.0 EP1WN4.0/WP2.0WN6.0 EP1WN4.0/WP2.0WN6.0 EP1WN4.0/WP2.0WN6.0 EP1WN4.0/WP2.0WN6.0 EP1WN4.0/WP2.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN4.0WN4.0WN4.0WN4.0WN6.0 EP1WN4.0/WP2.0WN6.0 EP1WN4.0/WP2.0WN6.0 EP1WN4.0WN6.0 EP1WN4.0WN6.0 EP1WN4.0/WP2.0WN6.0 EP1WN4.0/WP2.0WN6.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0 EP1WN6.0 EP1

WN6.0 EP1WN6.0 EP1WN8.0WN8.0

WN8.0

WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN6.0 EP1WN6.0 EP1WN7.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN7.0WN7.0WN7.0WN6.0 EP1WN6.0 EP1WN7.0WN4.0/WP2.0WN4.0WN4.0WN7.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN6.0WN6.0WN6.0WN6.0WN6.0 EP1WN6.0 EP1WN6.0 EP1

WN6.0 EP1WN6.0WN6.0WN5.0WN5.0WN5.0WN6.0WN5.0WN6.0WN6.0WN6.0WN6.0WN6.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN4.0WN8.0

WN8.0WN8.0WN8.0WN4.0WN8.0WN5.0WN8.0WN8.0WN8.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN5.0WN5.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN6.0 EP1WN8.0WN6.0 EP1WN8.0WN8.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0

WN8.0WN8.0WN5.0WN8.0WN5.0WN8.0WN8.0WN5.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN5.0WN5.0WN8.0WN8.0WN5.0WN5.0WN5.0WN5.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN5.0WN7.0 2.0WN5.0WN7.0WN5.0WN7.0WN5.0WN7.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN5.0WN5.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0

WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN5.0WN7.0 2.0WN5.0WN7.0 2.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN8.0 1.0WN8.0 1.0WN7.0 1.0WN8.0 1.0WN5.0WN8.0 1.0not supportedWN8.0 1.0WN8.0 1.0WN7.0 2.0WN4.0/WP2.0WN4.0/WP2.0WN7.0 EP2WN4.0/WP2.0WN7.0 EP2WN4.0/WP2.0WN4.0WN4.0WN4.0/WP2.0WN4.0/WP2.0WN5.0/WP3.0

WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0WN5.0WN5.0/WP3.0WN5.0WN5.0WN5.0/WP3.0WN7.0 2.0WN7.0 2.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0WN5.0WN7.0 2.0WN4.0not supportedWN4.0WN4.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN5.0WN5.0

WN5.0WN5.0WN5.0/WP3.0WN5.0WN7.0 2.0WN5.0/WP3.0WN5.0/WP3.0WN7.0WN7.0WN7.0WN7.0WN7.0WN7.0WN7.0WN7.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0WN7.0WN7.0WN7.0WN7.0WN7.0 1.0WN5.0/WP3.0WN5.0/WP3.0WN6.0WN5.0/WP3.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN5.0WN5.0WN5.0

WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0WN7.0 1.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN5.0WN7.0 1.0WN7.0 1.0not supportedWN7.0 1.0not supportedWN5.0

WN5.0WN5.0WN5.0WN5.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN5.0WN5.0WN5.0WN5.0not supportedWN5.0not supportedWN5.0WN7.0 1.0WN5.0WN7.0 1.0WN5.0not supportedWN5.0not supportedWN5.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 2.0WN7.0 2.0WN5.0WN5.0WN7.0 2.0WN5.0

WN7.0 2.0WN5.0WN7.0 2.0WN5.0WN7.0 2.0WN5.0WN5.0WN5.0WN5.0WN5.0WN8.0WN8.0WN8.0WN8.0WN8.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN5.0/WP3.0WN5.0WN5.0/WP3.0WN5.0/WP3.0WN5.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN8.0WN8.0WN8.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN8.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN7.0 2.0WN8.0WN7.0 2.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0

WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN7.0 2.0WN7.0 2.0WN8.0WN7.0 2.0WN8.0WN8.0WN7.0 2.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0

WN8.0WN8.0WN7.0WN7.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0 EP1WN6.0 EP1WN7.0WN6.0 EP1WN7.0WN6.0 EP1WN7.0WN6.0 EP1WN7.0WN7.0WN7.0WN7.0WN7.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN7.0WN7.0WN7.0WN7.0WN8.0not supportedWN8.0not supportedWN7.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN7.0

WN7.0WN8.0WN7.0WN8.0WN7.0WN8.0WN7.0WN7.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN4.0/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WBTS Future ReleaseWBTS Future ReleaseWN7.0WN7.0WN7.0WN7.0WN7.0WN7.0WN8.0WN8.0WN3.2/WP2.0WN3.2/WP2.0WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WN6.0 EP1WBTS Future ReleaseWN6.0 EP1WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0

WBTS Future ReleaseWN6.0WN6.0WN6.0WN6.0WBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWN4.0/WP2.0WN4.0/WP2.0WN6.0WN6.0WN4.0/WP2.0WN6.0WN6.0WN6.0WN6.0WN6.0WBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WN3.2/WP2.0WBTS Future ReleaseWN8.0WBTS Future ReleaseWN8.0WBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWN8.0WN8.0WN3.2/WP2.0

WBTS Future ReleaseWN8.0WBTS Future ReleaseWN8.0WN8.0WN8.0WN8.0WN8.0WBTS Future ReleaseWBTS Future ReleaseWBTS Future ReleaseWN3.2/WP2.0WN6.0WN3.2/WP2.0WN6.0WN6.0WN3.2/WP2.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0WN3.2/WP2.0WN3.2/WP2.0WN9.0WN9.0WN9.0WN7.0WN8.0WN7.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WN8.0WBTS Future ReleaseWN8.0WBTS Future ReleaseWBTS Future ReleaseWN9.0WN6.0WN6.0WN6.0WN6.0WN6.0WN6.0

WN5.0WN5.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN7.0 1.0WN8.0WN6.0WN8.0WN6.0WN8.0WN8.0WN6.0WN8.0WN5.0WN5.0WN5.0WN5.0WN5.0WN4.0/WP2.0WN5.0WN5.0WN5.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN4.0/WP2.0WN3.2/WP2.0WN5.0WN4.0/WP2.0WN4.0/WP2.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0WN8.0WN8.0WN5.0/WP3.0WN5.0WN5.0WN5.0/WP3.0WN5.0/WP3.0WN5.0/WP3.0

Measurement Id5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)

5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)

5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)

5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)

5123(FVLPHB)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5123(FVLPHB)5000(HSDPAW)5000(HSDPAW)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5123(FVLPHB)5123(FVLPHB)

5123(FVLPHB)5123(FVLPHB)5140(FSEPS)5140(FSEPS)5000(HSDPAW), 5001(WBTSHW), 5101(FPDH), 5105(FATM), 5106(FATMVC), 5107(FATMVP), 5102(FSDH), 5110(FETHL), 5111(FVCBU), 5112(FVCCBU), 5114(FPSN), 5113(FPWMP), 5002(CELTPW), 5003(FRPRW), 5115(FAALSCH), 5116(FTOP), 5117(FIP), 5118(FPHB), 5004(SIGLDW), 5119(FCESIF), 5120(FCESPWT), 5121(FCESPW), 5123(FVLPHB), 5124(FVLIP), 5125(FVLAN), 5005(HSPEXT), 5006(R99HW), 5008(WBTSMON), 5009(WOPST), 5009(OPSTW), 5122(FIPSEC), 5126(FTWAM), 5127(FPPPML), 5128(FPPPSL), 5129(FL2SWI), 5130(FSTP), 5131(FTOPF), 5133(FIPF), 5134(FP3MLIP), 5135(FP3SLIP), 5136(FP3MLPH), 5137(FP3SLPH), 5138(FIPSE), 5140(FSEPS)5140(FSEPS)5000(HSDPAW), 5001(WBTSHW), 5002(CELTPW), 5003(FRPRW), 5004(SIGLDW), 5005(HSPEXT), 5006(R99HW), 5009(WOPST), 5009(OPSTW)5138(FIPSE)5138(FIPSE)5138(FIPSE)5138(FIPSE)5138(FIPSE)5138(FIPSE)5140(FSEPS)5138(FIPSE)5138(FIPSE)5140(FSEPS)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5138(FIPSE)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5120(FCESPWT)5119(FCESIF)5120(FCESPWT)5120(FCESPWT)5119(FCESIF)5121(FCESPW)5121(FCESPW)5110(FETHL)5120(FCESPWT)5110(FETHL)5121(FCESPW)5121(FCESPW)5110(FETHL)5110(FETHL)5110(FETHL)5110(FETHL)5110(FETHL)5110(FETHL)5110(FETHL)5110(FETHL)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5004(SIGLDW)5004(SIGLDW)5004(SIGLDW)

5004(SIGLDW)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5118(FPHB)5137(FP3SLPH)5112(FVCCBU)5137(FP3SLPH)5112(FVCCBU)5112(FVCCBU)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5136(FP3MLPH)5114(FPSN)5136(FP3MLPH)

5112(FVCCBU)5137(FP3SLPH)5136(FP3MLPH)5114(FPSN)5112(FVCCBU)5118(FPHB)5112(FVCCBU)5112(FVCCBU)5112(FVCCBU)5117(FIP)5117(FIP)5117(FIP)5117(FIP)5117(FIP)5117(FIP)5117(FIP)5117(FIP)5111(FVCBU)5111(FVCBU)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5137(FP3SLPH)5112(FVCCBU)5137(FP3SLPH)5112(FVCCBU)5137(FP3SLPH)5112(FVCCBU)5137(FP3SLPH)5112(FVCCBU)5137(FP3SLPH)5112(FVCCBU)5111(FVCBU)5117(FIP)5111(FVCBU)5117(FIP)5111(FVCBU)5111(FVCBU)5115(FAALSCH)5115(FAALSCH)5116(FTOP)5116(FTOP)5116(FTOP)5116(FTOP)5116(FTOP)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)

5110(FETHL)5136(FP3MLPH)5117(FIP)5111(FVCBU)5117(FIP)5111(FVCBU)5111(FVCBU)5117(FIP)5111(FVCBU)5111(FVCBU)5111(FVCBU)5136(FP3MLPH)5111(FVCBU)5136(FP3MLPH)5111(FVCBU)5115(FAALSCH)5115(FAALSCH)5110(FETHL)5110(FETHL)5115(FAALSCH)5115(FAALSCH)5115(FAALSCH)5115(FAALSCH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5115(FAALSCH)5110(FETHL)5115(FAALSCH)5110(FETHL)5115(FAALSCH)5110(FETHL)5115(FAALSCH)5110(FETHL)5136(FP3MLPH)5110(FETHL)5136(FP3MLPH)5110(FETHL)5136(FP3MLPH)5110(FETHL)5110(FETHL)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)

5002(CELTPW)5002(CELTPW)5002(CELTPW)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5000(HSDPAW)5008(WBTSMON)5000(HSDPAW)5008(WBTSMON)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5122(FIPSEC)5122(FIPSEC)5126(FTWAM)5122(FIPSEC)5000(HSDPAW)5122(FIPSEC)5000(HSDPAW)5122(FIPSEC)5122(FIPSEC)5008(WBTSMON)5000(HSDPAW)5000(HSDPAW)5009(WOPST), 5009(OPSTW)5000(HSDPAW)5009(WOPST), 5009(OPSTW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)

5002(CELTPW)5002(CELTPW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)5008(WBTSMON)5008(WBTSMON)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5113(FPWMP)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5008(WBTSMON)5114(FPSN)5114(FPSN)5113(FPWMP)5113(FPWMP)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5000(HSDPAW)5000(HSDPAW)

5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5008(WBTSMON)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5126(FTWAM)5126(FTWAM)5126(FTWAM)5126(FTWAM)5127(FPPPML)5127(FPPPML)5127(FPPPML)5127(FPPPML)5127(FPPPML)5128(FPPPSL)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5123(FVLPHB)5121(FCESPW)5121(FCESPW)5121(FCESPW)5121(FCESPW)5123(FVLPHB)5123(FVLPHB)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)

5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5006(R99HW)5006(R99HW)5006(R99HW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5006(R99HW)5006(R99HW)5006(R99HW)5006(R99HW)5006(R99HW)5000(HSDPAW)

5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5006(R99HW)5006(R99HW)5006(R99HW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5006(R99HW)5000(HSDPAW)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5008(WBTSMON)5006(R99HW)5006(R99HW)5006(R99HW)5006(R99HW)5008(WBTSMON)5008(WBTSMON)5000(HSDPAW)5000(HSDPAW)5008(WBTSMON)5000(HSDPAW)

5008(WBTSMON)5000(HSDPAW)5008(WBTSMON)5000(HSDPAW)5008(WBTSMON)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5130(FSTP)5130(FSTP)5130(FSTP)5131(FTOPF)5131(FTOPF)5128(FPPPSL)5128(FPPPSL)5128(FPPPSL)5129(FL2SWI)5128(FPPPSL)5003(FRPRW)5003(FRPRW)5003(FRPRW)5003(FRPRW)5003(FRPRW)5003(FRPRW)5003(FRPRW)5003(FRPRW)5003(FRPRW)5003(FRPRW)5135(FP3SLIP)5135(FP3SLIP)5135(FP3SLIP)5134(FP3MLIP)5134(FP3MLIP)5134(FP3MLIP)5135(FP3SLIP)5134(FP3MLIP)5134(FP3MLIP)5134(FP3MLIP)5134(FP3MLIP)5134(FP3MLIP)5134(FP3MLIP)5134(FP3MLIP)5133(FIPF)5134(FP3MLIP)5131(FTOPF)5133(FIPF)5131(FTOPF)5131(FTOPF)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)

5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5136(FP3MLPH)5135(FP3SLIP)5135(FP3SLIP)5135(FP3SLIP)5135(FP3SLIP)5135(FP3SLIP)5136(FP3MLPH)5135(FP3SLIP)5135(FP3SLIP)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)

5002(CELTPW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)

5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5002(CELTPW)5000(HSDPAW)5000(HSDPAW)5124(FVLIP)5124(FVLIP)5124(FVLIP)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5124(FVLIP)5124(FVLIP)5124(FVLIP)5124(FVLIP)5124(FVLIP)5124(FVLIP)5124(FVLIP)5005(HSPEXT)5005(HSPEXT)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5001(WBTSHW)5001(WBTSHW)5124(FVLIP)5124(FVLIP)5125(FVLAN)5124(FVLIP)5125(FVLAN)5125(FVLAN)5005(HSPEXT)5125(FVLAN)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)

5005(HSPEXT)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5106(FATMVC)5106(FATMVC)5105(FATM)5105(FATM)5105(FATM)5105(FATM)5105(FATM)5105(FATM)5105(FATM)5105(FATM)5005(HSPEXT)5002(CELTPW)5005(HSPEXT)5002(CELTPW)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5002(CELTPW)5002(CELTPW)5107(FATMVP)

5005(HSPEXT)5002(CELTPW)5005(HSPEXT)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5101(FPDH)5000(HSDPAW)5101(FPDH)5000(HSDPAW)5000(HSDPAW)5105(FATM)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5001(WBTSHW)5101(FPDH)5101(FPDH)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5002(CELTPW)5005(HSPEXT)5002(CELTPW)5005(HSPEXT)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5002(CELTPW)5005(HSPEXT)5002(CELTPW)5005(HSPEXT)5005(HSPEXT)5005(HSPEXT)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)

5000(HSDPAW)5000(HSDPAW)5006(R99HW)5006(R99HW)5006(R99HW)5006(R99HW)5006(R99HW)5005(HSPEXT)5000(HSDPAW)5005(HSPEXT)5000(HSDPAW)5005(HSPEXT)5005(HSPEXT)5000(HSDPAW)5005(HSPEXT)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5110(FETHL)5000(HSDPAW)5000(HSDPAW)5000(HSDPAW)5110(FETHL)5102(FSDH)5110(FETHL)5110(FETHL)5102(FSDH)5107(FATMVP)5000(HSDPAW)5102(FSDH)5102(FSDH)5003(FRPRW)5003(FRPRW)5003(FRPRW)5003(FRPRW)5002(CELTPW)5002(CELTPW)5003(FRPRW)5000(HSDPAW)5000(HSDPAW)5003(FRPRW)5003(FRPRW)5003(FRPRW)

5000(HSDPAW), 5001(WBTSHW), 5101(FPDH), 5105(FATM), 5106(FATMVC), 5107(FATMVP), 5102(FSDH), 5110(FETHL), 5111(FVCBU), 5112(FVCCBU), 5114(FPSN), 5113(FPWMP), 5002(CELTPW), 5003(FRPRW), 5115(FAALSCH), 5116(FTOP), 5117(FIP), 5118(FPHB), 5004(SIGLDW), 5119(FCESIF), 5120(FCESPWT), 5121(FCESPW), 5123(FVLPHB), 5124(FVLIP), 5125(FVLAN), 5005(HSPEXT), 5006(R99HW), 5008(WBTSMON), 5009(WOPST), 5009(OPSTW), 5122(FIPSEC), 5126(FTWAM), 5127(FPPPML), 5128(FPPPSL), 5129(FL2SWI), 5130(FSTP), 5131(FTOPF), 5133(FIPF), 5134(FP3MLIP), 5135(FP3SLIP), 5136(FP3MLPH), 5137(FP3SLPH), 5138(FIPSE), 5140(FSEPS)

5000(HSDPAW), 5001(WBTSHW), 5002(CELTPW), 5003(FRPRW), 5004(SIGLDW), 5005(HSPEXT), 5006(R99HW), 5009(WOPST), 5009(OPSTW)

5000(HSDPAW), 5001(WBTSHW), 5101(FPDH), 5105(FATM), 5106(FATMVC), 5107(FATMVP), 5102(FSDH), 5110(FETHL), 5111(FVCBU), 5112(FVCCBU), 5114(FPSN), 5113(FPWMP), 5002(CELTPW), 5003(FRPRW), 5115(FAALSCH), 5116(FTOP), 5117(FIP), 5118(FPHB), 5004(SIGLDW), 5119(FCESIF), 5120(FCESPWT), 5121(FCESPW), 5123(FVLPHB), 5124(FVLIP), 5125(FVLAN), 5005(HSPEXT), 5006(R99HW), 5008(WBTSMON), 5009(WOPST), 5009(OPSTW), 5122(FIPSEC), 5126(FTWAM), 5127(FPPPML), 5128(FPPPSL), 5129(FL2SWI), 5130(FSTP), 5131(FTOPF), 5133(FIPF), 5134(FP3MLIP), 5135(FP3SLIP), 5136(FP3MLPH), 5137(FP3SLPH), 5138(FIPSE), 5140(FSEPS)

5000(HSDPAW), 5001(WBTSHW), 5101(FPDH), 5105(FATM), 5106(FATMVC), 5107(FATMVP), 5102(FSDH), 5110(FETHL), 5111(FVCBU), 5112(FVCCBU), 5114(FPSN), 5113(FPWMP), 5002(CELTPW), 5003(FRPRW), 5115(FAALSCH), 5116(FTOP), 5117(FIP), 5118(FPHB), 5004(SIGLDW), 5119(FCESIF), 5120(FCESPWT), 5121(FCESPW), 5123(FVLPHB), 5124(FVLIP), 5125(FVLAN), 5005(HSPEXT), 5006(R99HW), 5008(WBTSMON), 5009(WOPST), 5009(OPSTW), 5122(FIPSEC), 5126(FTWAM), 5127(FPPPML), 5128(FPPPSL), 5129(FL2SWI), 5130(FSTP), 5131(FTOPF), 5133(FIPF), 5134(FP3MLIP), 5135(FP3SLIP), 5136(FP3MLPH), 5137(FP3SLPH), 5138(FIPSE), 5140(FSEPS)

5000(HSDPAW), 5001(WBTSHW), 5101(FPDH), 5105(FATM), 5106(FATMVC), 5107(FATMVP), 5102(FSDH), 5110(FETHL), 5111(FVCBU), 5112(FVCCBU), 5114(FPSN), 5113(FPWMP), 5002(CELTPW), 5003(FRPRW), 5115(FAALSCH), 5116(FTOP), 5117(FIP), 5118(FPHB), 5004(SIGLDW), 5119(FCESIF), 5120(FCESPWT), 5121(FCESPW), 5123(FVLPHB), 5124(FVLIP), 5125(FVLAN), 5005(HSPEXT), 5006(R99HW), 5008(WBTSMON), 5009(WOPST), 5009(OPSTW), 5122(FIPSEC), 5126(FTWAM), 5127(FPPPML), 5128(FPPPSL), 5129(FL2SWI), 5130(FSTP), 5131(FTOPF), 5133(FIPF), 5134(FP3MLIP), 5135(FP3SLIP), 5136(FP3MLPH), 5137(FP3SLPH), 5138(FIPSE), 5140(FSEPS)

5000(HSDPAW), 5001(WBTSHW), 5101(FPDH), 5105(FATM), 5106(FATMVC), 5107(FATMVP), 5102(FSDH), 5110(FETHL), 5111(FVCBU), 5112(FVCCBU), 5114(FPSN), 5113(FPWMP), 5002(CELTPW), 5003(FRPRW), 5115(FAALSCH), 5116(FTOP), 5117(FIP), 5118(FPHB), 5004(SIGLDW), 5119(FCESIF), 5120(FCESPWT), 5121(FCESPW), 5123(FVLPHB), 5124(FVLIP), 5125(FVLAN), 5005(HSPEXT), 5006(R99HW), 5008(WBTSMON), 5009(WOPST), 5009(OPSTW), 5122(FIPSEC), 5126(FTWAM), 5127(FPPPML), 5128(FPPPSL), 5129(FL2SWI), 5130(FSTP), 5131(FTOPF), 5133(FIPF), 5134(FP3MLIP), 5135(FP3SLIP), 5136(FP3MLPH), 5137(FP3SLPH), 5138(FIPSE), 5140(FSEPS)

5000(HSDPAW), 5001(WBTSHW), 5101(FPDH), 5105(FATM), 5106(FATMVC), 5107(FATMVP), 5102(FSDH), 5110(FETHL), 5111(FVCBU), 5112(FVCCBU), 5114(FPSN), 5113(FPWMP), 5002(CELTPW), 5003(FRPRW), 5115(FAALSCH), 5116(FTOP), 5117(FIP), 5118(FPHB), 5004(SIGLDW), 5119(FCESIF), 5120(FCESPWT), 5121(FCESPW), 5123(FVLPHB), 5124(FVLIP), 5125(FVLAN), 5005(HSPEXT), 5006(R99HW), 5008(WBTSMON), 5009(WOPST), 5009(OPSTW), 5122(FIPSEC), 5126(FTWAM), 5127(FPPPML), 5128(FPPPSL), 5129(FL2SWI), 5130(FSTP), 5131(FTOPF), 5133(FIPF), 5134(FP3MLIP), 5135(FP3SLIP), 5136(FP3MLPH), 5137(FP3SLPH), 5138(FIPSE), 5140(FSEPS)