Huawei Parameter

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BSC6900 UMTS V900R012C01Parameter Reference

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Purpose

This document provides information about the BSC6900 parameters, including the meaning, value, and usage of the parameters.

Intended Audience

•Network planners

•Field engineers

•System engineers

•Shift operators

Organization

Each parameter is described in the following aspects.

Description

MO

Parameter ID

Parameter Name

NE

MML Command

Meaning

IsKey

Mandatory

Feature ID

Feature Name

Value Type

GUI Value Range

Actual Value Range

Unit

Default Value

Recommended Value

Impact

Parameter Relationship

Access

Service Interrupted After Modification

Interruption Scope

Interruption Duration (min)

Caution

Validation of Modification

Impact on Radio Network Performance

Introduced in Version

Attribute

This document provides information about the BSC6900 parameters, including the meaning, value, and usage of the parameters.

Each parameter is described in the following aspects.

Remarks

Managed object of NE

Simple string for identifying a parameter

Name of the parameter

NEs on which the parameter is set

Commands for setting the parameter

Definition, purpose, and protocols of the parameter

Whether the parameter is used to identify an MO instance

Whether the parameter is mandatory for creating an MO instance

ID of the feature that uses the parameter

Name of the feature that uses the parameter

Parameter value type

Parameter value range displayed on the GUI

Actual parameter value range corresponding to the GUI Value Range

Parameter value unit

Parameter values recommended for different scenarios

Parameter impact scope, that is, objects specified when the parameter is set

Whether this parameter is Read & Write or Read Only.

Whether modifying the parameter value interrupts the ongoing services

Initial parameter value assigned by the system. There is no default value for a mandatory parameter. None indicates that there is no default value. For a bit field parameter, the value ON of a sub-parameter means that the bit representing the sub-parameter is set to 1, and the value OFF means that the bit is set to 0.Generally, it is displayed on the configuration window of an ADD command but not displayed on the configuration window of a MOD/RMV/DSP/LST command.

Relationship between this parameter and other parameters. For example, to use this parameter, you need to set related switches and parameters.

Possible interruption scope

Possible interruption duration (unit: minute)

Cautions to be taken during the modification

How this parameter takes effect and whether the equipment needs to be restarted after the modification

Impact of the parameter on radio network performance

Product version in which the parameter is introduced

Whether the parameter is a radio parameter, a transport parameter, or an equipment parameter

MO Parameter ID Parameter Name MML Command Meaning

UDPUCFGDATA MaccPageRepeatTimes Repeat Times of Macc Paging SET UDPUCFGDATA(OptionalThis parameter defines the time

GPS RNCID RNC ID ADD GPS(Mandatory) ID of the RNC where a GPS rece

GPS CellId Cell ID ADD GPS(Mandatory) ID of the cell to which a GPS r

LICENSE SETOBJECT Set Object License SET LICENSE(Optional) Product application mode

LICENSE ISPRIMARYPLMN Primary Operator Flag SET LICENSE(Optional) Primary operator flag. YES indi

LICENSE CNOPERATORINDEX Cn Operator Index SET LICENSE(Optional) Operator index

LICENSE CsErlang Voice Erlang-Erlang SET LICENSE(Optional) Number of Erlangs for voice se

LICENSE Psthroughput PS throughput only-kbps SET LICENSE(Optional) Max throughput of PS

LICENSE HSDPAthroughput HSDPA Throughput-kbps SET LICENSE(Optional) The total HSDPA traffic of all

SCPICH CellId Cell ID ADD USCPICH(Mandatory) ID of a cell. For detailed inf

SCPICH ScpichPhyId SCPICH ID ADD USCPICH(Optional) Uniquely identifying a SCPICH i

SCPICH ScpichPower SCPICH transmit power[0.1dB ADD USCPICH(Optional) TX power of the SCPICH in a ce

U2GNCELL RNCId RNC ID ID of an RNC

U2GNCELL CellId Cell ID Uniquely identifying a WCDMA

U2GNCELL GSMCellIndex GSM Cell Index Unique ID of a GSM cell

U2GNCELL CIOOffset Neighboring Cell-Oriented CIO

U2GNCELL Qoffset1sn Qoffset1sn

U2GNCELL Qrxlevmin Min RX Level

U2GNCELL TpenaltyHcsReselect HCS Cell Reselect Penalty Ti

U2GNCELL TempOffset1 HCS Cell Reselect TempOffse

U2GNCELL BlindHoFlag Blind Handover Flag

U2GNCELL BlindHOPrio Blind Handover Priority

U2GNCELL DRDEcN0Threshhold DRD Ec/No Threshold DRD Ec/No threshold for determ

U2GNCELL SIB11Ind SIB11 Indicator

U2GNCELL SIB12Ind SIB12 Indicator

U2GNCELL NPrioFlag Neighboring Cell Priority Flag

U2GNCELL NPrio Priority of Neighboring Cell

U2GNCELL MBDRFlag Flag of MBDR Cell

U2GNCELL MBDRPrio MBDR Cell Periority

UACALGO AcRstrctSwitch AC Restriction Switch SET UACALGO(Optional) OFF indicates that the AC algor

UACALGO AcRstrctPercent AC Restriction Percent SET UACALGO(Mandatory) Access restriction ratio. When

UACALGO AcIntervalOfCell AC Restriction Interval Of Cell SET UACALGO(Mandatory) Interval of automatic access cl

UACALGO AcRstrctIntervalLen AC Restriction Interval length SET UACALGO(Mandatory) Interval of access classes restr

UACALGO IuAcIntervalOfCell AC Restriction Interval of Cell SET UACALGO(Optional) When the Iu interface is faulty

UADMCTRL AFSetObj AFSetObj SET UADMCTRL(Mandatory) The activity factor at the radio

UADMCTRL UlSrbActFactor UL AF of SRB SET UADMCTRL(Optional) UL activity factor of SRB.Signa

UADMCTRL DlSrbActFactor DL AF of SRB SET UADMCTRL(Optional) DL activity factor of SRB. Sign

UADMCTRL UlAmrConvAF UL AF of R99 AMR conv servi SET UADMCTRL(Optional) UL activity factor of the R99 A

UADMCTRL DlAmrConvAF DL AF of R99 AMR conv servi SET UADMCTRL(Optional) DL activity factor of the R99 A

UADMCTRL UlNonAmrConvAF UL AF of R99 non AMR conv s SET UADMCTRL(Optional) UL activity factor of the R99 n

UADMCTRL DlNonAmrConvAF DL AF of R99 non AMR conv s SET UADMCTRL(Optional) DL activity factor of the R99 n

UADMCTRL UlStreamAF UL AF of R99 Streaming servi SET UADMCTRL(Optional) UL activity factor of the R99 s

UADMCTRL DlStreamAF DL AF of R99 Streaming servi SET UADMCTRL(Optional) DL activity factor of the R99 s

UADMCTRL UlInteractAF UL AF of R99 interactive servi SET UADMCTRL(Optional) UL activity factor of the R99 i

UADMCTRL DlInteractAF DL AF of R99 interactive servi SET UADMCTRL(Optional) DL activity factor of the R99 i

UADMCTRL UlBackgroundAF UL AF of R99 background servSET UADMCTRL(Optional) UL activity factor of the R99 b

UADMCTRL DlBackgroundAF DL AF of R99 background servSET UADMCTRL(Optional) DL activity factor of the R99 b

UADMCTRL MbmsAF AF of MBMS service SET UADMCTRL(Optional) Activity factor of the MBMS ser

UADMCTRL HsupaConvAF AF of hsupa conv service SET UADMCTRL(Optional) UL activity factor of the HSUPA

UADMCTRL HsdpaConvAF AF of hsdpa conv service SET UADMCTRL(Optional) DL activity factor of the HSUPA

UADMCTRL HsupaStreamAF AF of hsupa streaming service SET UADMCTRL(Optional) UL activity factor of the HSUPA

UADMCTRL HsdpaStreamAF AF of hsdpa streaming service SET UADMCTRL(Optional) DL activity factor of the HSUPA

UADMCTRL HsupaInteractAF AF of hsupa interactive service SET UADMCTRL(Optional) UL activity factor of the HSUPA

UADMCTRL HsdpaInteractAF AF of hsdpa interactive service SET UADMCTRL(Optional) DL activity factor of the HSUPA

UADMCTRL HsupaBackGroundAF AF of hsupa background servi SET UADMCTRL(Optional) UL activity factor of the HSUPA

UADMCTRL HsdpaBackGroundAF AF of hsdpa background servi SET UADMCTRL(Optional) DL activity factor of the HSUPA

UAICH CellId Cell ID ID of a cell. For detailed inf

UAICH PRACHPhyChId PRACH ID ADD UAICH(Optional) Uniquely identifying a PRACH i

UAICH PhyChId AICH ID Uniquely identifying an AICH in

UAICH AICHTxTiming AICH Transmission Timing ADD UAICH(Optional)

MOD U2GNCELL(Mandatory)RMV U2GNCELL(Mandatory)MOD U2GNCELL(Mandatory)RMV U2GNCELL(Mandatory)MOD U2GNCELL(Mandatory)RMV U2GNCELL(Mandatory)ADD U2GNCELL(Optional)MOD U2GNCELL(Optional)

Cell individual offset for the GSM cell. This parameter is used for decision making for the inter-RAT handover. A larger value of the parameter indicates the higher the handover priority of the GSM cell. A smaller the value of the parameter indicates the lower the handover priority of the GSM cell.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)As for the impact on network performance:The larger the value of the parameter, the lower the probability of selecting neighboring cells. The smaller the value the parameter, the higher the probability of doing so.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)Minimum RX level of the GSM cell.Before the UE camps on the cell, take the measurement of the signal quality in the cell. If the quality is better than this parameter, this indicates that the cell can obtain better QoS and the UE is allowed to camp on this cell. Otherwise, the UE cannot obtain good QoS in this cell and does not camp on the cell.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)Specifies the penalty time for cell reselection. If this parameter is set to a greater value, the penalty time for HCS cell reselection is prolonged. If this parameter is set to a smaller value, the penalty time for HCS cell reselection is shortened. When the UE is in idle mode, the ping-pong reselections between HCS cells reduces if this parameter is set to a greater value. In this case, however, the hierarchical cell structure cannot be deployed effectively.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)Cell offset used for CPICH RSCP measurement value in HCS cell selection. If this parameter is set to a greater value, the probability for selecting a neighboring cell reduces. If this parameter is set to a smaller value, the probability for selecting a neighboring cell increases. If this parameter is set to "INFINITY", a neighboring cell is not selected.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)Whether to perform blind handover.The value FALSE indicates that the cell is not considered as a candidate cell for blind handover. Therefore, blind over to this cell cannot be triggered.ADD U2GNCELL(Mandatory)

MOD U2GNCELL(Mandatory)Priority of the neighboring cell for blind handover.The value 0 represents the highest priority. Priorities 0 to 15 are assigned to concentric neighboring cells, which can ensure successful blind handover. Priorities 16 to 30 are assigned to the neighboring cells, which cannot ensure successful blind handover.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)ADD U2GNCELL(Optional)MOD U2GNCELL(Optional)

Indicates whether to send the system information block 11 (SIB11) including neighboring cell information. The value "FALSE" indicates that the neighboring information is not included in the SIB11. The value "TRUE" indicates that the neighboring information is included in the SIB11.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)Indicates whether to send the SIB12 indication including the neighboring cell information. The value "FALSE" indicates that the neighboring information is not included in the SIB12. The value "TRUE" indicates that the neighboring information is included in the SIB12.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)Priority flag of neighboring cellsThe value TRUE indicates that the neighboring cell priority is valid, and the value FALSE indicates that the neighboring cell priority is invalid. In the algorithm of neighboring cell combination, the cell with an invalid priority is the last one to be considered as the measurement object.ADD U2GNCELL(Mandatory)

MOD U2GNCELL(Mandatory)A smaller value of this parameter indicates a higher priority assigned to the neighboring cell. The neighboring cell with a higher priority is more possibly delivered as the measurement object. For example, the neighboring cell with priority 1 is more possible to be selected as the measurement object than the neighboring cell with priority 2. This parameter is valid when "NPrioFlag" is set to TRUE.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)Whether the cell supports the measure-based directed retry (MBDR) algorithm. The value TRUE indicates that the cell supports the MBDR algorithm, and the value FALSE indicates that the cell does not support the MBDR algorithm.ADD U2GNCELL(Optional)

MOD U2GNCELL(Optional)Priority of a MBDR cell. This parameter is valid only when the "MBDRFlag" parameter is set to TRUE. It indicates the tiptop priority when the value is set to 0, and the lowest priority when the value is set to 15. The higher the priority, the easier it is for the MBDR cell to be delivered as the measurement object and the easier to be selected to the handover target cell when there are many of cells meet the quality condition. Attention, when there does not have cell meet the quality condition base on the MBDR measurement result, if there exists a cell which has the priority of 0, and the type of the measurement report is periodic, then it can be selected to blind handover target cell.

ADD UAICH(Mandatory)RMV UAICH(Mandatory)

ADD UAICH(Optional)RMV UAICH(Mandatory) This parameter specifies the transmission timing information of an AICH relative to uplink PRACH.

"0" indicates that there are 7680 chips offset between the access preamble of the PRACH and AICH. "1" indicates that there are 12800 chips offset between them. For detailed information of this parameter, refer to 3GPP TS 25.211.

UAICH STTDInd STTD Indicator ADD UAICH(Optional) This parameter indicates wheth

UAICHPWROFFSET CellId Cell ID MOD UAICHPWROFFSET(MandID of a cell. For detailed inf

UAICHPWROFFSET AICHPowerOffset AICH Power Offset MOD UAICHPWROFFSET(MandThis parameter specifies the p

UAMRC DlThdE1 DL E1 Event Relative Thresho SET UAMRC(Optional) Threshold E1 of DL AMR speech

UAMRC DlThdE2 DL E2 Event Relative Thresho SET UAMRC(Optional) Threshold E2 of DL AMR speech

UAMRC DlThdF1 DL F1 Event Relative Threshol SET UAMRC(Optional) Threshold F1 of DL AMR speech

UAMRC DlThdF2 DL F2 Event Relative Threshol SET UAMRC(Optional) Threshold F2 of DL AMR speech

UAMRC UlModeChangeTimerLen UL Mode Change Timer Lengt SET UAMRC(Optional) To adjust the UL AMR speech r

UAMRC DlModeChangeTimerLen DL Mode Change Waiting TimeSET UAMRC(Optional) The AMRC needs to check whethe

UAMRC GoldMaxMode Max Mode Of Narrowband AMRSET UAMRC(Optional) Maximum rate of the narrowban

UAMRC SilverMaxMode Max Mode of Narrowband AMRCSET UAMRC(Optional) Maximum rate of the narrowban

UAMRC CopperMaxMode Max Mode of Narrowband AMRSET UAMRC(Optional) Maximum rate of the narrowba

UAMRCWB DlThdE1 DL E1 Event Relative Thresho SET UAMRCWB(Optional) Threshold E1 of DL wideband AM

UAMRCWB DlThdE2 DL E2 Event Relative Thresho SET UAMRCWB(Optional) Threshold E2 of DL wideband AM

UAMRCWB DlThdF1 DL F1 Event Relative Threshol SET UAMRCWB(Optional) Threshold F1 of DL wideband AM

UAMRCWB DlThdF2 DL F2 Event Relative Threshol SET UAMRCWB(Optional) Threshold F2 of DL wideband AM

UAMRCWB UlModeChangeTimerLen UL Mode Change Timer Lengt SET UAMRCWB(Optional) To adjust the UL wideband AMR

UAMRCWB DlModeChangeTimerLen DL Mode Change Waiting TimeSET UAMRCWB(Optional) The AMRC needs to check whethe

UAMRCWB GoldMaxMode Max Mode Of Wideband AMRC SET UAMRCWB(Optional) Maximum rate of the wideband

UAMRCWB SilverMaxMode Max Mode of Wideband AMRC fSET UAMRCWB(Optional) Maximum rate of the wideband

UAMRCWB CopperMaxMode Max Mode of Wideband AMRC SET UAMRCWB(Optional) Maximum rate of the wideband

UBCH CellId Cell ID ID of a cell. For detailed inf

UBCH TrChId BCH ID ADD UBCH(Optional) Uniquely identifying a BCH in a

UBCH BCHPower BCH Transmit Power ADD UBCH(Optional) Offset of the BCH transmit pow

UCACALGOSWITCH CacSwitch CAC algorithm switch SET UCACALGOSWITCH(Opti

UCACALGOSWITCH RsvdPara1 Reserved parameter 1 SET UCACALGOSWITCH(OptiReserved Parameter1.

UCACALGOSWITCH RsvdPara2 Reserved parameter 2 SET UCACALGOSWITCH(OptiReserved parameter 2.

UCACALGOSWITCH RsvdPara3 Reserved parameter 3 SET UCACALGOSWITCH(OptiReserved parameter 3.

UCALLSHOCKCTRL CallShockCtrlSwitch Call Shock Control Switch SET UCALLSHOCKCTRL(Optio

UCALLSHOCKCTRL RegByFachSwitch Register Bear by Fach Switch SET UCALLSHOCKCTRL(Optio

UCALLSHOCKCTRL CallShockJudgePeriod Call Shock Judge Period time SET UCALLSHOCKCTRL(Optio

UCALLSHOCKCTRL SysTotalRrcNumThd System Call Shock Trigger Thr SET UCALLSHOCKCTRL(Optio

UCALLSHOCKCTRL SysAmrRrcNum AMR_RRC Number per SecondSET UCALLSHOCKCTRL(OptioThe parameter specifies the nu

UCALLSHOCKCTRL SysHighPriRrcNum HiPri_RRC Number per SecondSET UCALLSHOCKCTRL(OptioThe parameter specifies the nu

UCALLSHOCKCTRL SysRrcRejNum Max RRC_REJ Number per SecSET UCALLSHOCKCTRL(OptioThe parameter specifies the m

UCALLSHOCKCTRL NBTotalRrcNumThd NodeB Call Shock Trigger Thr SET UCALLSHOCKCTRL(Optio

UCALLSHOCKCTRL NBAmrRrcNum AMR_RRC Number per SecondSET UCALLSHOCKCTRL(OptioThe parameter specifies the nu

UCALLSHOCKCTRL NBHighPriRrcNum HiPri_RRC Number per Secon SET UCALLSHOCKCTRL(OptioThe parameter specifies the nu

UCALLSHOCKCTRL CellTotalRrcNumThd Cell Call Shock Trigger Thresh SET UCALLSHOCKCTRL(Optio

UCALLSHOCKCTRL CellAmrRrcNum AMR_RRC Number per Second SET UCALLSHOCKCTRL(OptioThe parameter specifies the num

UCALLSHOCKCTRL CellHighPriRrcNum HiPri_RRC Number per Second SET UCALLSHOCKCTRL(OptioThe parameter specifies the num

UCBSADDR CnOpIndex Cn Operator Index Represent an index for a CN o

UCBSAREA AreaId CBS Area ID ID of a CBS area.

UCBSAREA CnOpIndex CN Operator Index ADD UCBSAREA(Mandatory) Represent an index for a CN o

UCBSAREA AreaType CBS Area NameCBS Area Typ Type of a CBS area.

UCBSAREA LAC Location Area Code Code of a location area, where

UCBSAREA CellId Cell ID ID of a cell. For details on th

UCBSMSG MsgIndex CBS Message Index Represent an index for a CB

UCBSMSG MsgTypeId CBS Message ID ADD UCBSMSG(Mandatory) Channel ID for a CBS message

UCBSMSG GeographicalScope Geography Scope ADD UCBSMSG(Mandatory) Geographical coverage of a C

UCBSMSG Priority CBS Message Priority ADD UCBSMSG(Optional) Priority for sending simplifie

UCBSMSG RepetPeriod CBS Message Repeat Period Interval between sending of

UCBSMSG NumOfBrdcstReq Number of Emergency Broadc Number of transmitted CBS m

UCBSMSG CodeType Coding Scheme ADD UCBSMSG(Mandatory) Coding scheme of a CBS mes

UCBSMSG AreaID CBS Area ID Area for transmitting a CBS m

UCBSMSG EmergencyType Emergency Broadcasting Type ADD UCBSMSG(Mandatory) Type of emergency CBS mess

UCBSMSG CBSMsg Message Content ADD UCBSMSG(Optional)

UCBSMSG CBSMsg CBS Message Content MOD UCBSMSG(Optional) Content of a normal CBS mess

UCELL CellId Cell ID ID of a cell. For detailed inf

UCELL CellName Cell Name Identifying a cell name

UCELL MaxTxPower Max Transmit Power of Cell Sum of the maximum transmit po

ADD UBCH(Mandatory)RMV UBCH(Mandatory)

The parameter values are described as follows: NODEB_CREDIT_CAC_SWITCH: The system performs CAC based on the usage state of NodeB credit. When the NodeB's credit is not enough, the system rejects new access requests.

NODEB_LEVEL indicates that the RNC will perform flow control for the RRC connection requests at NodeB level.CELL_LEVEL indicates that the RNC will perform flow control for the RRC connection requests at cell level.When ON is selected, RNC will perform flow control at cell level or NodeB level, the RRC connection for registration is set up on the FACH instead of on the DCH.When OFF is selected, the channel setup strategy of RRC connection request for registration can be set by running the SET URRCESTCAUSE command.The parameter specifies the period of entering flow control at SPU subsystem level, NodeB level, or cell level.In the period, if the number of RRC connection requests that the SPU subsystem, NodeB, or cell receives exceed relative trigger threshold (the threshold can be set by "SysTotalRrcNumThd", "NBTotalRrcNumThd", or "CellTotalRrcNumThd"), RNC will perform flow control for the RRC establishment request.If the number of admitted RRC connection requests for AMR exceeds the value of "SysAmrRrcNum", RNC will perform flow control.If other services cause RRC connection requests, RNC will not perform flow control.

If the number of admitted RRC connection requests for AMR exceeds the value of "NBAmrRrcNum", RNC will perform flow control.If other services cause RRC connection requests, RNC will not perform flow control.

If the number of admitted RRC connection requests for AMR exceeds the value of "CellAmrRrcNum", RNC will perform flow control.If other services cause RRC connection requests, RNC will not perform flow control.

MOD UCBSADDR(Mandatory)RMV UCBSADDR(Mandatory)ADD UCBSAREA(Mandatory)RMV UCBSAREA(Mandatory)

ADD UCBSAREA(Mandatory)RMV UCBSAREA(Mandatory)ADD UCBSAREA(Mandatory)RMV UCBSAREA(Mandatory)ADD UCBSAREA(Mandatory)RMV UCBSAREA(Mandatory)MOD UCBSMSG(Mandatory)RMV UCBSMSG(Mandatory)

ADD UCBSMSG(Optional)MOD UCBSMSG(Optional)ADD UCBSMSG(Optional)MOD UCBSMSG(Optional)

ADD UCBSMSG(Mandatory)MOD UCBSMSG(Optional)

If "Emergency Broadcasting Type" is set to "Hurricane", this parameter is defined as "Hurricane".If "Emergency Broadcasting Type" is set to "Other", this parameter is defined by customers.

MOD UCELLSETUP(Mandatory)RMV UCELL(Mandatory)ADD UCELLSETUP(Mandatory)ADD UCELLQUICKSETUP(Mandatory)ADD UCELLQUICKSETUP(Optional)MOD UCELL(Optional)

UCELL BandInd Band Indicator Indicating the selected frequen

UCELL PeerIsValid Peer Cell Is Valid Or Not Indicating peer cell is valid or n

UCELL PeerCellId Peer Cell ID Indicating the corresponding

UCELL CnOpGrpIndex Cn Operator Group Index Represent an index for a CN

UCELL UARFCNUplinkInd UL Frequency Ind Indicating whether the UL freq

UCELL UARFCNUplink Uplink UARFCN

UCELL UARFCNDownlink Downlink UARFCN

UCELL TCell Time Offset Difference between the System

UCELL NInsyncInd Num of Continuous in Sync In This parameter defines the time

UCELL NOutsyncInd Num of Continuous Out of Syn This parameter defines the time

UCELL TRlFailure Radio Link Failure Timer Leng Radio link failure timer durati

UCELL PScrambCode DL Primary Scrambling Code Sequence Number of a DL primar

UCELL TxDiversityInd TX Diversity Indication This parameter indicates whethe

UCELL SpgId Service Priority Group Identity Indicating which service priorit

UCELL LoCell Local Cell ID Uniquely identifying a local ce

UCELL LAC Location Area Code Identifies a location area cod

UCELL SAC Service Area Code MCC,MNC,LAC and SAC together c

UCELL CfgRacInd RAC Configuration Indication This parameter indicates whet

UCELL RAC Routing Area Code Identifying a routing area in a

UCELL STTDSupInd STTD Support Indicator This parameter indicates wheth

UCELL CP1SupInd CP1 Support Indicator This parameter indicates wheth

UCELL ClosedLoopTimeAdjustMode Closed Loop Time Adjust Mod The parameter takes for adjust

UCELL DpchDivModforOther DPCH Tx Diversity Mode for O Specifies the TX diversity m

UCELL FdpchDivModforOther FDPCH Tx Diversity Mode for

UCELL DpchDivModforMIMO DPCH Tx Diversity Mode for Specifies the TX diversity on

UCELL FdpchDivModforMIMO FDPCH Tx Diversity Mode for

UCELL DivModforDCHSDPA Tx Diversity Mode for DC-HS

UCELL CIO Cell Oriented Cell Individual Of This parameter works with the of

UCELL VPLimitInd Cell VP Limit Indicator This switch defines whether a v

UCELL URANUM URA number ADD UCELLQUICKSETUP(ManNumber of UTRAN Registration

UCELL URA1 URA ID 1 ADD UCELLQUICKSETUP(ManA cell can belongs to multiple








UCELL SupBmc CBS support ADD UCELLQUICKSETUP(OptiIndicating whether the cell su

UCELL CBSOpIndex CBS Operator Index ADD UCELLQUICKSETUP(ManA CBS Operator of the cell

UCELL CBSSAC CBS SAC ADD UCELLQUICKSETUP(ManCBS service area which the cel

UCELL PCPICHPower PCPICH Transmit Power TX power of the PCPICH in a ce

UCELL PSCHPower PSCH Transmit Power MOD UCELL(Optional) Offset of the PSCH transmit po

UCELL SSCHPower SSCH Transmit Power MOD UCELL(Optional) Offset of the SSCH transmit po

UCELL ScpichPower SCPICH transmit power[0.1dB MOD UCELL(Optional) TX power of the SCPICH in a ce

UCELL BCHPower BCH Transmit Power MOD UCELL(Optional) Offset of the BCH transmit pow

UCELLACCESSSTRICT CellId Cell ID ID of a cell. For detailed inf

UCELLACCESSSTRICT CellReservedForOperatorUse Cell reserved for operator use Indicating whether the cell is

UCELLACCESSSTRICT CellReservationExtension Cell reservation extension Indicating whether the cell is

UCELLACCESSSTRICT IsAccessClass0Barred Access class 0 barred indicato Indicating whether the UE allo










UCELLACCESSSTRICT IsAccessClass10Barred Access class 10 barred indicat Indicating whether the UE allo


ADD UCELLQUICKSETUP(Mandatory)MOD UCELLSETUP(Optional)ADD UCELLQUICKSETUP(Optional)MOD UCELL(Optional)ADD UCELLQUICKSETUP(Mandatory)MOD UCELL(Mandatory)ADD UCELLSETUP(Mandatory)ADD UCELLQUICKSETUP(Mandatory)ADD UCELLSETUP(Optional)MOD UCELLSETUP(Optional)ADD UCELLQUICKSETUP(Optional)MOD UCELLSETUP(Optional)

Band7: Uplink UARFCN = Downlink UARFCN - 225For detailed information of this parameter, refer to 3GPP TS 25.433.ADD UCELLQUICKSETUP(Optional)

MOD UCELLSETUP(Optional)BandIndNotUsed:[0-16383]Downlink UARFCN of a cell.For detailed information of this parameter, refer to 3GPP TS 25.433.ADD UCELLQUICKSETUP(Mandatory)

MOD UCELLSETUP(Optional)ADD UCELLSETUP(Optional)MOD UCELL(Optional)ADD UCELLSETUP(Optional)MOD UCELL(Optional)ADD UCELLSETUP(Optional)MOD UCELL(Optional)ADD UCELLQUICKSETUP(Mandatory)MOD UCELLSETUP(Optional)ADD UCELLSETUP(Mandatory)MOD UCELLSETUP(Optional)ADD UCELLQUICKSETUP(Mandatory)MOD UCELLSETUP(Optional)ADD UCELLQUICKSETUP(Mandatory)MOD UCELLSETUP(Optional)ADD UCELLSETUP(Mandatory)ADD UCELLQUICKSETUP(Mandatory)ADD UCELLSETUP(Mandatory)ADD UCELLQUICKSETUP(Mandatory)ADD UCELLSETUP(Mandatory)ADD UCELLQUICKSETUP(Mandatory)ADD UCELLSETUP(Mandatory)ADD UCELLQUICKSETUP(Mandatory)ADD UCELLSETUP(Mandatory)MOD UCELLSETUP(Optional)ADD UCELLSETUP(Mandatory)MOD UCELLSETUP(Optional)ADD UCELLSETUP(Mandatory)MOD UCELLSETUP(Mandatory)ADD UCELLSETUP(Mandatory)MOD UCELLSETUP(Optional)ADD UCELLSETUP(Mandatory)MOD UCELLSETUP(Optional)

Specifies the TX diversity mode on F-DPCH for the non-MIMO users and non-DC-HSDPA users.According to the protocol 3GPP TS 25.211, the F-DPCH can use STTD TX diversity mode only. For details on this parameter, see 3GPP TS 25.211.ADD UCELLSETUP(Mandatory)

MOD UCELLSETUP(Optional)ADD UCELLSETUP(Mandatory)MOD UCELLSETUP(Optional)

Specifies the TX diversity mode on F-DPCH for the MIMO users.According to the protocol 3GPP TS 25.211, the F-DPCH can use STTD TX diversity mode only. For details on this parameter, see 3GPP TS 25.211.ADD UCELLSETUP(Mandatory)

MOD UCELLSETUP(Optional)Specifies the TX diversity mode for the DC-HSDPA users.According to the protocol 3GPP TS 25.211, the DC-HSDPA feature can use STTD TX diversity mode only. For details, see 3GPP TS 25.211.ADD UCELLSETUP(Optional)

MOD UCELLSETUP(Optional)ADD UCELLQUICKSETUP(Optional)MOD UCELLSETUP(Optional)

ADD UCELLQUICKSETUP(Optional)MOD UCELL(Optional)

MOD UCELLACCESSSTRICT(Mandatory)RMV UCELLACCESSSTRICT(Mandatory)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)





UCELLACCESSSTRICT IdleCellBarred Cell barred indicator for SIB3 Indicating whether the UE in id

UCELLACCESSSTRICT IdleIntraFreqReselection Intra-freq cell reselection ind f Indicating whether the UE in id

UCELLACCESSSTRICT IdleTbarred Time barred for SIB3 This parameter is valid when [C

UCELLACCESSSTRICT ConnCellBarred Cell barred indicator for SIB4 Indicating whether the UE in co

UCELLACCESSSTRICT ConnIntraFreqReselection Intra-freq cell reselection ind f Indicating whether the UE in id

UCELLACCESSSTRICT ConnTbarred Time barred for SIB4 This parameter is valid when [C

UCELLACINFO CellId Cell ID MOD UCELLACINFO(MandatoID of a cell. For detailed inf

UCELLACINFO LAC Location Area Code MOD UCELLACINFO(Optional Identifies a location area cod

UCELLACINFO SAC Service Area Code MOD UCELLACINFO(Optional MCC,MNC,LAC and SAC together c

UCELLACINFO CfgRacInd RAC Configuration Indication MOD UCELLACINFO(Optional This parameter indicates whet

UCELLACINFO RAC Routing Area Code MOD UCELLACINFO(MandatoIdentifying a routing area in a

UCELLALGOSWITCH CellId Cell ID ID of a cell. For detailed inf

UCELLALGOSWITCH NBMCacAlgoSwitch Cell CAC algorithm switch

UCELLALGOSWITCH NBMUlCacAlgoSelSwitch Uplink CAC algorithm switch

UCELLALGOSWITCH NBMDlCacAlgoSelSwitch Downlink CAC algorithm switc

UCELLALGOSWITCH NBMLdcAlgoSwitch Cell LDC algorithm switch

UCELLALGOSWITCH NBMMachsResetAlgoSelSwitc Mac-hs Reset algorithm switch

UCELLALGOSWITCH HspaPlusSwitch Cell Hspa Plus function switch

UCELLALGOSWITCH HspaEnhSwitch Cell Hspa Enhanced function s If E_F_DPCH are selected, the

UCELLALGOSWITCH CellCapacityAutoHandleSwitc Cell Capability Auto Handle Sw

UCELLALGOSWITCH NbmLdcUeSelSwitch Inter-freq Handover Select Use

UCELLALGOSWITCH RsvdPara1 Reserved parameter 1

UCELLALGOSWITCH RsvdPara2 Reserved parameter 2 Reserved parameter 2

UCELLALGOSWITCH RsvdPara3 Reserved parameter 3 Reserved parameter 3

UCELLAMRC CellId Cell ID ID of a cell. For detailed inf

UCELLAMRC GoldMaxMode Max Mode Of Narrowband AMR Maximum rate of the narrowban

UCELLAMRC SilverMaxMode Max Mode of Narrowband AMRC Maximum rate of the narrowban

UCELLAMRC CopperMaxMode Max Mode of Narrowband AMR Maximum rate of the narrowba

UCELLAMRCWB CellId Cell ID ID of a cell. For detailed inf

UCELLAMRCWB GoldMaxMode Max Mode Of Wideband AMRC Maximum rate of the wideband

UCELLAMRCWB SilverMaxMode Max Mode of Wideband AMRC f Maximum rate of the wideband

UCELLAMRCWB CopperMaxMode Max Mode of Wideband AMRC Maximum rate of the wideband

UCELLCAC CellId Cell ID ID of a cell. For detailed inf

UCELLCAC CellEnvType Cell environment type Defining the radio environment t

UCELLCAC UlNonCtrlThdForAMR UL threshold of Conv AMR ser

UCELLCAC UlNonCtrlThdForNonAMR UL threshold of Conv non_AMR

UCELLCAC UlNonCtrlThdForOther UL threshold of other services

UCELLCAC DlConvAMRThd DL threshold of Conv AMR ser

UCELLCAC DlConvNonAMRThd DL threshold of Conv non_AMR

UCELLCAC DlOtherThd DL threshold of other services

UCELLCAC UlNonCtrlThdForHo UL handover access threshold The percentage of the handover

UCELLCAC DlHOThd DL handover access threshold The percentage of the handover

UCELLCAC UlCellTotalThd UL total power threshold Admission threshold of total cel

UCELLCAC DlCellTotalThd DL total power threshold Admission threshold of the total

UCELLCAC UlCCHLoadFactor UL common channel load reserv

UCELLCAC DlCCHLoadRsrvCoeff DL common channel load reserv Different admission policies a

UCELLCAC UlTotalEqUserNum UL total equivalent user numbe When the algorithm 2 is used,

UCELLCAC DlTotalEqUserNum DL total equivalent user numbe When the algorithm 2 is used,

UCELLCAC HsupaLowPriorityUserPBRThdLow priority HSUPA user PBR Threshold of all the HSUPA use

UCELLCAC HsupaEqualPriorityUserPBRT Equal priority HSUPA user PB Threshold of all the HSUPA use

UCELLCAC HsupaHighPriorityUserPBRTh High priority HSUPA user PBR Threshold of all the HSUPA use

UCELLCAC UlHsDpcchRsvdFactor UL HS-DPCCH reserve factor If the HS-DPCCH carries ACK/NA

UCELLCAC HsdpaStrmPBRThd Hsdpa streaming PBR thresho Average throughput admission t

UCELLCAC HsdpaBePBRThd HSDPA best effort PBR thresh Average throughput admission

UCELLCAC MaxHsdpaUserNum Maximum HSDPA user numbe Maximum number of users suppo

UCELLCAC MaxUlTxPowerforConv Max UL TX power of conversati Maximum UL transmit power for

UCELLCAC MaxUlTxPowerforStr Max UL TX power of streaming Maximum UL transmit power for

ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Mandatory)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Mandatory)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Mandatory)ADD UCELLACCESSSTRICT(Mandatory)MOD UCELLACCESSSTRICT(Optional)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Mandatory)ADD UCELLACCESSSTRICT(Optional)MOD UCELLACCESSSTRICT(Mandatory)

MOD UCELLALGOSWITCH(Mandatory)RMV UCELLALGOSWITCH(Mandatory)ADD UCELLALGOSWITCH(Optional)MOD UCELLALGOSWITCH(Optional)If switches above are selected, the corresponding algorithms will be enabled; otherwise, disabled."ADD UCELLALGOSWITCH(Mandatory)MOD UCELLALGOSWITCH(Optional)

ALGORITHM_SECOND: The equivalent user number algorithm will be used in uplink CAC.ALGORITHM_THIRD: The loose call admission control algorithm will be used in uplink CAC.ADD UCELLALGOSWITCH(Mandatory)

MOD UCELLALGOSWITCH(Optional)ALGORITHM_SECOND: The equivalent user number algorithm will be used in downlink CAC.ALGORITHM_THIRD: The loose call admission control algorithm will be used in downlink CAC.ADD UCELLALGOSWITCH(Optional)

MOD UCELLALGOSWITCH(Optional)CELL_CREDIT_LDR:Credit reshuffling algorithm. When the cell credit is heavily loaded, this algorithm reduces the credit load of the cell by using BE service rate reduction, uncontrollable real-time service QoS renegotiation, CS should be inter-RAT, PS should be inter-RAT handover, CS should not be inter-RATand and PS should not be inter-RAT handover.If INTRA_FREQUENCY_LDB, PUC, ULOLC, DLOLC, ULLDR, UDLLDR, OLC_EVENTMEAS, CELL_CODE_LDR and CELL_CREDIT_LDR are selected, the corresponding algorithms will be enabled; otherwise, disabled.ADD UCELLALGOSWITCH(Optional)

MOD UCELLALGOSWITCH(Optional)ALGORITHM_REQUIRED: Always reset the mac-hs no matter the cells in question are in the same NodeB or not.ALGORITHM_DEPEND_ON_LCG: Reset the mac-hs only when the cells in question are in the different local cell group.ADD UCELLALGOSWITCH(Optional)

MOD UCELLALGOSWITCH(Optional)This parameter is used to select a feature related to HSPA+. If a feature is selected, it indicates that the corresponding algorithm is enabled. If a feature is not selected, it indicates that the corresponding algorithm is disabled. Note that other factors such as license and the physical capability of NodeB restrict whether a feature can be used even if this feature is selected. The EFACH/MIMO switch determines whether the cell supports the E-FACH/MIMO feature but does not affect the establishment of the E-FACH and the MIMO cell.ADD UCELLALGOSWITCH(Optional)

MOD UCELLALGOSWITCH(Optional)ADD UCELLALGOSWITCH(Optional)MOD UCELLALGOSWITCH(Optional)

TX_DIVERSITY_ON_TO_OFF:When TX Diversity is on to off,the algorithms of cell capacity auto handle is open.TX_DIVERSITY_OFF_TO_ON:When TX Diversity is off to on,the algorithms of cell capacity auto handle is open.ADD UCELLALGOSWITCH(Optional)

MOD UCELLALGOSWITCH(Optional)NBM_LDC_MATCH_UE_ONLY: When inter-freq handover select user occurs, only consider Ues supported by target cell.NBM_LDC_MATCH_UE_FIRST: When inter-freq handover select user occurs, first consider Ues supported by target cell.ADD UCELLALGOSWITCH(Optional)

MOD UCELLALGOSWITCH(Optional)The algorithms with the above values represent are as follow:RSVDBIT1~RSVDBIT16:Reserved Switch.ADD UCELLALGOSWITCH(Optional)

MOD UCELLALGOSWITCH(Optional)ADD UCELLALGOSWITCH(Optional)MOD UCELLALGOSWITCH(Optional)RMV UCELLAMRC(Mandatory)MOD UCELLAMRC(Mandatory)ADD UCELLAMRC(Optional)MOD UCELLAMRC(Optional)ADD UCELLAMRC(Optional)MOD UCELLAMRC(Optional)ADD UCELLAMRC(Optional)MOD UCELLAMRC(Optional)MOD UCELLAMRCWB(Mandatory)RMV UCELLAMRCWB(Mandatory)ADD UCELLAMRCWB(Optional)MOD UCELLAMRCWB(Optional)ADD UCELLAMRCWB(Optional)MOD UCELLAMRCWB(Optional)ADD UCELLAMRCWB(Optional)MOD UCELLAMRCWB(Optional)MOD UCELLCAC(Mandatory)RMV UCELLCAC(Mandatory)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)

The percentage of the conversational AMR service threshold to the 100% uplink load. It is applicable to algorithm 1 and algorithm 2. The parameter is used for controlling the AMR service admission. That is, when a AMR service is accessing, the RNC evaluates the measurement value of the uplink load after the service is accessed. If the UL load of a cell is higher than this threshold after the access of a AMR speech service, this service will be rejected. If the UL load of a cell will not be higher than this threshold, this service will be admitted. The UL load factor thresholds include parameters of [UL threshold of Conv AMR service], [UL threshold of Conv non_AMR service], [UL handover access threshold] and [UL threshold of other services]. The four parameters can be used to limit the proportion between the conversational service, handover user and other services in a specific cell, and to guarantee the access priority of the conversational AMR service.ADD UCELLCAC(Optional)

MOD UCELLCAC(Optional)The percentage of the conversational non-AMR service threshold to the 100% uplink load. It is applicable to algorithm 1 and algorithm 2. The parameter is used for controlling the non-AMR service admission. That is, when a non-AMR service is accessing, the RNC evaluates the measurement value of the uplink load after the service is accessed. If the UL load of a cell is higher than this threshold after the access of a non-AMR speech service, this service will be rejected. If the UL load of a cell will not be higher than this threshold, this service will be admitted. The UL load factor thresholds include parameters of [UL threshold of Conv AMR service], [UL threshold of Conv non_AMR service], [UL handover access threshold] and [UL threshold of other services]. The four parameters can be used to limit the proportion between the conversational service, handover user and other services in a specific cell, and to guarantee the access priority of the conversational non-AMR service.ADD UCELLCAC(Optional)

MOD UCELLCAC(Optional)The percentage of other service thresholds to the 100% uplink load. The services refer to other admissions except the conversational AMR service, conversational non-AMR service, and handover scenarios. It is applicable to algorithm 1 and algorithm 2. The parameter is used for controlling other service admissions. That is, when a service is accessing, the RNC evaluates the measurement value of the uplink load after the service is accessed. If the UL load of a cell is higher than this threshold after the access of a service, this service will be rejected. If the UL load of a cell will not be higher than this threshold, this service will be admitted. The UL load factor thresholds include parameters of [UL threshold of Conv AMR service], [UL threshold of Conv non_AMR service], [UL handover access threshold] and [UL threshold of other services]. The four parameters can be used to limit the proportion between the conversational service, handover user and other services in a specific cell, and to guarantee the access priority of other services.ADD UCELLCAC(Optional)

MOD UCELLCAC(Optional)The percentage of the conversational AMR service threshold to the 100% downlink load. It is applicable to algorithm 1 and algorithm 2. The parameter is used for controlling the AMR service admission. That is, when an AMR service is accessing, the RNC evaluates the measurement value of the downlink load after the service is accessed. If the DL load of a cell is higher than this threshold after the access of an AMR speech service, this service will be rejected. If the DL load of a cell will not be higher than this threshold, this service will be admitted. The DL load factor thresholds include parameters of [DL threshold of Conv AMR service], [DL threshold of Conv non_AMR service], [DL handover access threshold] and [DL threshold of other services]. The four parameters can be used to limit the proportion between the conversational service, handover user and other services in a specific cell, and to guarantee the access priority of the conversational AMR service.ADD UCELLCAC(Optional)

MOD UCELLCAC(Optional)The percentage of the conversational non-AMR service threshold to the 100% downlink load. It is applicable to algorithm 1 and algorithm 2. The parameter is used for controlling the non-AMR service admission. That is, when a non-AMR service is accessing, the RNC evaluates the measurement value of the downlink load after the service is accessed. If the DL load of a cell is higher than this threshold after the access of a non-AMR speech service, this service will be rejected. If the DL load of a cell will not be higher than this threshold, this service will be admitted. The DL load factor thresholds include parameters of [DL threshold of Conv AMR service], [DL threshold of Conv non_AMR service], [DL handover access threshold] and [DL threshold of other services]. The four parameters can be used to limit the proportion between the conversational service, handover user and other services in a specific cell, and to guarantee the access priority of the conversational non-AMR service.ADD UCELLCAC(Optional)

MOD UCELLCAC(Optional)The percentage of other service thresholds to the 100% downlink load. The services refer to other admissions except the conversational AMR service, conversational non-AMR service, and handover scenarios. It is applicable to algorithm 1 and algorithm 2. The parameter is used for controlling other service admissions. That is, when a service is accessing, the RNC evaluates the measurement value of the downlink load after the service is accessed. If the DL load of a cell is higher than this threshold after the access of a service, this service will be rejected. If the DL load of a cell will not be higher than this threshold, this service will be admitted. The DL load factor thresholds include parameters of [DL threshold of Conv AMR service], [DL threshold of Conv non_AMR service], [DL handover access threshold] and [DL threshold of other services]. The four parameters can be used to limit the proportion between the conversational service, handover user and other services in a specific cell, and to guarantee the access priority of other services.ADD UCELLCAC(Optional)

MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)

The admission control decision is only for dedicated channels. For common channels, some resources instead of a special admission procedure are reserved.In the UL, according to the current load factor and the characteristics of the new call, the UL CAC algorithm predicts the new traffic channels load factor with the assumption of admitting the new call, then plus with the premeditated common channel UL load factor to get the predicted UL load factor. Then, compare it with the UL admission threshold. If the value is not higher than the threshold, the call is admitted; otherwise, rejected.ADD UCELLCAC(Optional)

MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)

UCELLCAC MaxUlTxPowerforInt Max UL TX power of interactive The maximum UL transmit power

UCELLCAC MaxUlTxPowerforBac Max UL TX power of backgroun The maximum UL transmit power

UCELLCAC BackgroundNoise Background noise If [Auto-Adaptive Background N

UCELLCAC DefPcpichEcNo Default PCPICH Ec/No When the RNC is performing dow

UCELLCAC BGNSwitch Auto-adaptive background nois When the parameter is 'OFF', t

UCELLCAC BGNAdjustTimeLen Background noise update cont Only when the measured backgro

UCELLCAC BGNEqUserNumThd Equivalent user number thresh When the number of uplink equi

UCELLCAC MaxHsupaUserNum Maximum HSUPA user numbe Maximum number of users suppo

UCELLCAC DlHSUPARsvdFactor Dl HSUPA reserved factor Reserved DL power factor for H

UCELLCAC DlMBMSRsvdFactor DL MBMS reserved factor Reserved DL power factor for

UCELLCAC MtchRsvPwr MTCH reserve power Available guarantee power of

UCELLCAC MtchRsvSf MTCH reserve SF Available guarantee codes of

UCELLCAC MtchMaxPwr MTCH maximal power Available guarantee codes of

UCELLCAC MtchMaxSf MTCH maximal SF Maximum code limit of all the

UCELLCAC UlHoCeResvSf UL handover credit reserved S Uplink Credit Reserved by Spr

UCELLCAC DlHoCeCodeResvSf DL handover credit and code Some cell resources can be res

UCELLCAC BgnStartTime Background noise update start

UCELLCAC BgnEndTime Background noise update end

UCELLCAC BgnUpdateThd Background noise update trigg The difference of RTWP that tri

UCELLCAC BgnAbnormalThd Background noise abnormal th This parameter is applied when

UCELLCAC MAXEFACHUserNum Maximum EFACH user numbe The parameter indicates the

UCELLCAC CellUlEquNumCapacity Cell Uplink Capacity of Equal Used to check whether the numbe

UCELLCAC HsdpaMaxGBPThd Threshold of Maximum Guaran Threshold of the maximum guar

UCELLCAC HsupaMaxGBPThd Threshold of Maximum Guaran Threshold of the maximum guar

UCELLCBSDRX CellId Cell ID ID of a cell. For detailed inf

UCELLCBSSAC CellId Cell ID Uniquely identifying a cell. Fo

UCELLCBSSAC CnOpIndex Cn Operator Index Represent an index for a CN o

UCELLCMCF CellId Cell ID Unique ID of a cell

UCELLCMCF CmcfCellType CM Cell Type

UCELLCMCF DlSFTurnPoint DL SF Threshold

UCELLCMCF UlSFTurnPoint UL SF threshold

UCELLDCCC CellId Cell ID ID of a cell. For detailed inf

UCELLDCCC BePwrMargin BE Event F Reporting Power M The relative power margin of sin

UCELLDCCC CombPwrMargin Comb Event F Reporting Powe The relative power margin of com

UCELLDCCC UlFullCvrRate Uplink Full Coverage Bit Rate Maximum UL rate when coverage

UCELLDCCC DlFullCvrRate Downlink Full Coverage Bit Ra Maximum DL rate during network

UCELLDISTANCEREDIRECT CellId Cell ID Unique ID of a cell

UCELLDISTANCEREDIRECT RedirSwitch Redirection Switch This parameter specifies whethe

UCELLDISTANCEREDIRECT DelayThs Propagation delay threshold Redirection algorithm works on

UCELLDISTANCEREDIRECT RedirFactorOfLDR Redirection Factor Of LDR When the UL load state or DL lo

UCELLDISTANCEREDIRECT RedirFactorOfNorm Redirection Factor Of Normal When the load of the serving ce

UCELLDRD CellId Cell ID Unique ID of a cell

UCELLDRD DRMaxGSMNum Maximum Times of Inter-RAT D Maximum number of inter-RAT RA

UCELLDRD ServiceDiffDrdSwitch Service Steering DRD Switch Whether the service steering D

UCELLDRD LdbDRDSwitchDCH Load balance DRD switch for

UCELLDRD LdbDRDSwitchHSDPA Load balance DRD switch for

UCELLDRD LdbDRDchoice Load Balancing DRD Choice

UCELLDRD LdbDRDLoadRemainThdDCH Dl load balance DRD power re Downlink load threshold to tri

UCELLDRD LdbDRDLoadRemainThdHSD Dl load balance DRD power re Downlink load threshold to tr

UCELLDRD CodeBalancingDrdSwitch Code Balancing DRD Switch Whether to apply the code

UCELLDRD CodeBalancingDrdMinSFThd Minimum SF Threshold for Co One of the triggering conditio

UCELLDRD CodeBalancingDrdCodeRateT Code Occupancy Thres for Co One of the triggering conditio

UCELLDRD ReDirBandInd ReDirection target band indica Frequency band of the target UL

UCELLDRD ReDirUARFCNUplinkInd Redirection Target UL Frequen Whether the target UL UARFCN

UCELLDRD ReDirUARFCNUplink Redirection target uplink UA

UCELLDRD ReDirUARFCNDownlink Redirection target downlink Target DL UARFCN for the RRC

UCELLDRD ULLdbDRDSwitchDcHSDPA Uplink load balance DRD Swi This parameter specifies wheth

UCELLDRD ULLdbDRDLoadRemainThdD Uplink load balance DRD rema This parameter specifies the th

UCELLDRDMIMO CellId Cell ID Unique ID of a cell

UCELLDRDMIMO LegacyHDrdSwitchOfSTTD DRD Switch for LegacyH unde Whether to enable DRD for tec

UCELLDRDMIMO LegacyHDrdSwitchOfSCPICH DRD Switch for LegacyH unde Whether to enable DRD for tec

ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Mandatory)MOD UCELLCAC(Mandatory)

(1) This parameter, along with the [Algorithm stop time], is used to limit the validation time of the background noise automatic update algorithm. If [Algorithm stop time] is greater than [Algorithm start time], and the background noise automatic update algorithm is enabled, then the algorithm is activated during the period of [Algorithm stop time] to [Algorithm start time] each day. In other periods, the algorithm fails. If [Algorithm stop time] is less than [Algorithm start time], and the background noise automatic update algorithm is enabled, then the algorithm is activated during the period of [Algorithm stop time] each day to [Algorithm start time] of the next day. In other periods, the algorithm fails.(2) Input format: HH&MM&SSADD UCELLCAC(Mandatory)

MOD UCELLCAC(Mandatory)(1) This parameter, along with the [Algorithm start time], is used to limit the validation time of the background noise automatic update algorithm. If [Algorithm stop time] is greater than [Algorithm start time], and the background noise automatic update algorithm is enabled, then the algorithm is activated during the period of [Algorithm stop time] to [Algorithm start time] each day. In other periods, the algorithm fails. If [Algorithm stop time] is less than [Algorithm start time], and the background noise automatic update algorithm is enabled, then the algorithm is activated during the period of [Algorithm stop time] each day to [Algorithm start time] of the next day. In other periods, the algorithm fails(2) Input format: HH&MM&SSADD UCELLCAC(Optional)

MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCAC(Optional)MOD UCELLCAC(Optional)ADD UCELLCBSDRX(Mandatory)RMV UCELLCBSDRX(Mandatory)MOD UCELLCBSSAC(Mandatory)RMV UCELLCBSSAC(Mandatory)ADD UCELLCBSSAC(Mandatory)MOD UCELLCBSSAC(Mandatory)RMV UCELLCMCF(Mandatory)MOD UCELLCMCF(Mandatory)ADD UCELLCMCF(Optional)MOD UCELLCMCF(Optional)

CM type of the cell.The CM parameters are configured on the basis of the CM type of the cell. That is, the CM sequence number is determined after the CM type of the cell is determined.ADD UCELLCMCF(Optional)

MOD UCELLCMCF(Optional)When the downlink spreading factor is greater than or equal to the value of this parameter, the SF/2 mode is preferred. Otherwise, the high-layer scheduling mode is preferred.The SF/2 mode consumes more system resources and therefore this mode is recommended only for low-rate users. The high-layer scheduling mode requires variable multiplexing positions of transport channels and is applicable to a relatively narrow range. In addition, this approach affects the transmission rate of users. Therefore, this mode is recommended only when the SF/2 approach is unavailable or there are high-rate users.ADD UCELLCMCF(Optional)

MOD UCELLCMCF(Optional)When the uplink spreading factor is greater than or equal to the value of this parameter, the SF/2 mode is preferred. Otherwise, the high-layer scheduling mode is preferred.The SF/2 mode consumes more system resources and therefore this mode is recommended only for low-rate users. The high-layer scheduling mode requires variable multiplexing positions of transport channels and is applicable to a relatively narrow range. In addition, this approach affects the transmission rate of users. Therefore, this mode is recommended only when the SF/2 approach is unavailable or there are high-rate users.RMV UCELLDCCC(Mandatory)

MOD UCELLDCCC(Mandatory)ADD UCELLDCCC(Optional)MOD UCELLDCCC(Optional)ADD UCELLDCCC(Optional)MOD UCELLDCCC(Optional)ADD UCELLDCCC(Optional)MOD UCELLDCCC(Optional)ADD UCELLDCCC(Optional)MOD UCELLDCCC(Optional)MOD UCELLDISTANCEREDIRECTION(Mandatory)RMV UCELLDISTANCEREDIRECTION(Mandatory)ADD UCELLDISTANCEREDIRECTION(Optional)MOD UCELLDISTANCEREDIRECTION(Optional)ADD UCELLDISTANCEREDIRECTION(Optional)MOD UCELLDISTANCEREDIRECTION(Optional)ADD UCELLDISTANCEREDIRECTION(Optional)MOD UCELLDISTANCEREDIRECTION(Optional)ADD UCELLDISTANCEREDIRECTION(Optional)MOD UCELLDISTANCEREDIRECTION(Optional)MOD UCELLDRD(Mandatory)RMV UCELLDRD(Mandatory)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)

- ON: The load balancing DRD algorithm will be applied. - OFF: The load balancing DRD algorithm will not be applied.ADD UCELLDRD(Optional)

MOD UCELLDRD(Optional)- ON: The load balancing DRD algorithm will be applied. - OFF: The load balancing DRD algorithm will not be applied.ADD UCELLDRD(Optional)

MOD UCELLDRD(Optional)- Power: Power(Downlink none-HSDPA power is used for DCH services, and downlink HSDPA guarantee power is used for HSDPA services) will be applied to the load balancing DRD algorithm. - UserNumber: User number(Downlink R99 equivalent user number is used for DCH services, and downlink HSDPA user number is used for HSDPA services) will be applied to the load balancing DRD algorithm.ADD UCELLDRD(Optional)

MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)

BAND6: UL UARFCN = DL UARFCN - 225BAND7: UL UARFCN = DL UARFCN - 225ADD UCELLDRD(Optional)

MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)ADD UCELLDRD(Optional)MOD UCELLDRD(Optional)MOD UCELLDRDMIMO(Mandatory)RMV UCELLDRDMIMO(Mandatory)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)

UCELLDRDMIMO CQIRefValueOfSTTD CQI reference value for STTD Reference CQI for determining

UCELLDRDMIMO CQIRefValueOfSCPICH CQI reference value for P an Reference CQI for determining

UCELLDRDMIMO ExcellentCQIThdOfSTTD Excellent CQI Threshold for CQI threshold for determining t

UCELLDRDMIMO GoodCQIThdOfSTTD Good CQI Threshold for STTD CQI threshold for determining t

UCELLDRDMIMO BadCQIThdOfSTTD Bad CQI Threshold for STTD CQI threshold for determining t

UCELLDRDMIMO ExcellentCQIThdOfSCPICH Excellent CQI Threshold for CQI threshold for determining t

UCELLDRDMIMO GoodCQIThdOfSCPICH Good CQI Threshold for P an CQI threshold for determining t

UCELLDRDMIMO BadCQIThdOfSCPICH Bad CQI Threshold for P and CQI threshold for determining t

UCELLDSACMANUALPARA CellId Cell ID ID of a cell. For detailed inf

UCELLDSACMANUALPARA CnOpIndex CN Operator index Specifies the index of the tele

UCELLDSACMANUALPARA CsRestriction Restriction for CS Specifies whether to impose th

UCELLDSACMANUALPARA PsRestriction Restriction for PS Specifies whether to impose th

UCELLDSACMANUALPARA RestrictionType Restriction Type Specifies the mode of restricti

UCELLDSACMANUALPARA AcRestriction AC Restriction Indicator Specifies the access classes th

UCELLDSACMANUALPARA NumberOfACs Number of restrained AC every Specifies the number of access c

UCELLDSACMANUALPARA AcRange Range of restrained AC Specifies the access classes tha

UCELLDSACMANUALPARA AcRstrctIntervalLen Interval of DSAC Restriction Specifies the interval delay be

UCELLDYNSHUTDOWN CellId Cell ID ID of a cell. For detailed inf

UCELLDYNSHUTDOWN DynShutdownSwitch Cell Dynamic ShutDown Switc When the "Cell Dynamic ShutDow

UCELLDYNSHUTDOWN StartTime1 First Cell Dynamic ShutDown In Start time of the first interval

UCELLDYNSHUTDOWN EndTime1 First Cell Dynamic ShutDown I End time of the first interval w

UCELLDYNSHUTDOWN StartTime2 Second Cell Dynamic ShutDown Start time of the second interv

UCELLDYNSHUTDOWN EndTime2 Second Cell Dynamic ShutDown End time of the second interval

UCELLDYNSHUTDOWN StartTime3 Third Cell Dynamic ShutDown I Start time of the third interval

UCELLDYNSHUTDOWN EndTime3 Third Cell Dynamic ShutDown End time of the third interval

UCELLDYNSHUTDOWN DynShutDownType Cell Dynamic ShutDown Type When DynShutDownType is Force

UCELLDYNSHUTDOWN TotalUserNumThd Cell Dynamic ShutDown Total The cell is shut down automat

UCELLDYNSHUTDOWN HsdpaUserNumThd Cell Dynamic ShutDown Hsdpa The cell is shut down automat

UCELLDYNSHUTDOWN HsupaUserNumThd Cell Dynamic ShutDown Hsupa The cell is shut down automat

UCELLDYNSHUTDOWN NCellLdrRemainThd Cell Dynamic ShutDown Neigh The cell is shut down automati

UCELLEFACH CellId Cell ID ID of a cell. For detailed inf

UCELLEFACH EFACHDTCHGBP EFACH DTCH GBP This parameter specifies the

UCELLEFACH BcchHsscchPower BCCH HS-SCCH Power

UCELLEFACH BcchHspdschPower BCCH HS-PDSCH Power This parameter specifies the

UCELLEFACH CCCHGBR CCCH MAC-c Flow GBR The MAC-c on Iub interface wi

UCELLEFACH CCCHMBR CCCH MAC-c Flow MBR The MAC-c on Iub interface wi

UCELLEFACH SRBGBR SRB MAC-c Flow GBR The MAC-c on Iub interface wi

UCELLEFACH SRBMBR SRB MAC-c Flow MBR The MAC-c on Iub interface wi

UCELLEFACH CONVGBR Conversational MAC-c Flow The MAC-c on Iub interface wi

UCELLEFACH CONVMBR Conversational MAC-c Flow The MAC-c on Iub interface wi

UCELLEFACH STREAMGBR Streaming MAC-c Flow GBR The MAC-c on Iub interface wi

UCELLEFACH STREAMMBR Streaming MAC-c Flow MBR The MAC-c on Iub interface wi

UCELLEFACH INTERACTGBR Interactive MAC-c Flow GBR The MAC-c on Iub interface wi

UCELLEFACH INTERACTMBR Interactive MAC-c Flow MBR The MAC-c on Iub interface wi

UCELLEFACH BGGBR Background MAC-c Flow GBR The MAC-c flow on the Iub int

UCELLEFACH BGMBR Background MAC-c Flow MBR The MAC-c flow on Iub interfa

UCELLEFACH IMSGBR IMS MAC-c Flow GBR The MAC-c on Iub interface wi

UCELLEFACH IMSMBR IMS MAC-c Flow MBR The MAC-c on Iub interface wi

UCELLFRC CellId Cell ID Unique ID of a cell

UCELLFRC UlBeTraffDecThs UL BE traffic DCH decision thr Rate threshold for the decision

UCELLFRC DlBeTraffDecThs DL BE traffic DCH decision thr Rate threshold for the decision

UCELLFRC AllowedSaveCodeResource Allowing Code Resource Savin This parameter specifies wheth

UCELLFRC EcN0Ths Ec/N0 threshold Threshold for determining the si

UCELLFRC EcN0EffectTime Ec/N0 effective time Time duration when the reported

UCELLFREQUENCY RNCId RNC ID MOD UCELLFREQUENCY(OptiID of an RNC

UCELLFREQUENCY CellId Cell ID MOD UCELLFREQUENCY(ManID of a cell. For detailed inf

UCELLFREQUENCY BandInd Band Indicator MOD UCELLFREQUENCY(ManIndicating the selected frequen

UCELLFREQUENCY UARFCNUplinkInd UL Frequency Ind MOD UCELLFREQUENCY(OptiIndicating whether the UL freq

UCELLFREQUENCY UARFCNUplink Uplink UARFCN MOD UCELLFREQUENCY(Opti

UCELLFREQUENCY UARFCNDownlink Downlink UARFCN MOD UCELLFREQUENCY(Opti

UCELLGPSFRMTIMING StartFlag GPS Frame Timing Active Fla When the parameter is set to

ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)ADD UCELLDRDMIMO(Optional)MOD UCELLDRDMIMO(Optional)MOD UCELLDSACMANUALPARA(Mandatory)RMV UCELLDSACMANUALPARA(Mandatory)MOD UCELLDSACMANUALPARA(Mandatory)RMV UCELLDSACMANUALPARA(Mandatory)ADD UCELLDSACMANUALPARA(Mandatory)MOD UCELLDSACMANUALPARA(Optional)ADD UCELLDSACMANUALPARA(Mandatory)MOD UCELLDSACMANUALPARA(Optional)ADD UCELLDSACMANUALPARA(Mandatory)MOD UCELLDSACMANUALPARA(Optional)ADD UCELLDSACMANUALPARA(Mandatory)MOD UCELLDSACMANUALPARA(Mandatory)ADD UCELLDSACMANUALPARA(Mandatory)MOD UCELLDSACMANUALPARA(Mandatory)ADD UCELLDSACMANUALPARA(Mandatory)MOD UCELLDSACMANUALPARA(Mandatory)ADD UCELLDSACMANUALPARA(Mandatory)MOD UCELLDSACMANUALPARA(Mandatory)MOD UCELLDYNSHUTDOWN(Mandatory)RMV UCELLDYNSHUTDOWN(Mandatory)ADD UCELLDYNSHUTDOWN(Mandatory)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Mandatory)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Mandatory)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Mandatory)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Mandatory)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Mandatory)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Mandatory)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Optional)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Optional)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Optional)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Optional)MOD UCELLDYNSHUTDOWN(Optional)ADD UCELLDYNSHUTDOWN(Optional)MOD UCELLDYNSHUTDOWN(Optional)MOD UCELLEFACH(Mandatory)RMV UCELLEFACH(Mandatory)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)

This parameter specifies the power offset between HS-SCCH and P-CPICH when BCCH is mapped onto the EFACH.When UE is in Enhanced CELL_FACH state, the data on the BCCH is also sent on the HS-PDSCH. Meanwhile, the HS-SCCH shall send signaling related to HS-PDSCH. This parameter specifies the transmission power of the HS-SCCH at the time.ADD UCELLEFACH(Optional)

MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLEFACH(Optional)MOD UCELLEFACH(Optional)ADD UCELLFRC(Mandatory)MOD UCELLFRC(Mandatory)ADD UCELLFRC(Optional)MOD UCELLFRC(Optional)ADD UCELLFRC(Optional)MOD UCELLFRC(Optional)ADD UCELLFRC(Optional)MOD UCELLFRC(Optional)ADD UCELLFRC(Optional)MOD UCELLFRC(Optional)ADD UCELLFRC(Optional)MOD UCELLFRC(Optional)

Band7: Uplink UARFCN = Downlink UARFCN - 225For detailed information of this parameter, refer to 3GPP TS 25.433.BandIndNotUsed:[0-16383]Downlink UARFCN of a cell.For detailed information of this parameter, refer to 3GPP TS 25.433.ADD UCELLGPSFRMTIMING(Optional)

MOD UCELLGPSFRMTIMING(Optional)

UCELLHCS CellId Cell ID ID of a cell. For detailed inf

UCELLHCS UseOfHcs Use of HCS Indicating whether HCS is used

UCELLHCS HCSPrio HCS priority level HCS priority of the cell belon

UCELLHCS SsearchHCS HCS cell reselection threshold Intra-system HCS cell reselecti

UCELLHCS SHCSRat HCS inter-rat reselection thres Inter-system HCS cell reselecti

UCELLHCS Qhcs Quality threshold for HCS rese Quality threshold of HCS cell re

UCELLHCS TCRmax Time for evaluating max cell re Maximum duration of cell resele

UCELLHCS CRMaxNum Max number of cell reselection Maximum number of cell reselect

UCELLHCS TCrmaxHyst Time before revert to low-mobi Time before reverting to low-m

UCELLHCS SlimitSearchRat HCS search inter-rat limit thre The UE does not start the inter

UCELLHCSHO CellId Cell ID Unique ID of a cell

UCELLHCSHO SpdEstSwitch Algorithm Switch for UE Speed

UCELLHCSHO TFastSpdEst Time Window for UE Fast Spe

UCELLHCSHO NFastSpdEst Threshold for UE Fast Speed

UCELLHCSHO TCycleSlow Period for UE Slow Speed Dec

UCELLHCSHO TSlowSpdEst Time Window for UE Slow Spe

UCELLHCSHO NSlowSpdEst Threshold for UE Slow Speed

UCELLHCSHO TRelateLength Time Window For Ping-Pong Ha

UCELLHOCOMM CellId Cell ID Unique ID of a cell

UCELLHOCOMM InterFreqRATSwitch Inter-Frequency and Inter-RAT

UCELLHOCOMM CoexistMeasThdChoice Inter-Freq and Inter-RAT Coex

UCELLHOCOMM CSServiceHOSwitch Inter-RAT CS Handover Switc

UCELLHOCOMM PSServiceHOSwitch Inter-RAT PS Handover Switc

UCELLHSDPA CellId Cell ID ID of a cell. For detailed inf

UCELLHSDPA AllocCodeMode Allocate Code Mode If Manual is chosen, paramet

UCELLHSDPA HsPdschCodeNum Code Number for HS-PDSCH The parameter specifies the nu

UCELLHSDPA HsPdschMaxCodeNum Code Max Number for HS-PD The parameter determines the

UCELLHSDPA HsPdschMinCodeNum Code Min Number for HS-PD The parameter specifies the

UCELLHSDPA HsScchCodeNum Code Number for HS-SCCH This parameter decides the max

UCELLHSDPA HspaPower The Offset of HSPA Total Pow This parameter specifies the

UCELLHSDPA HsPdschMPOConstEnum HS-PDSCH MPO Constant

UCELLHSDPA CodeAdjForHsdpaSwitch Code Adjust Switch for HSDP This parameter specifies code

UCELLHSDPA CodeAdjForHsdpaUserNumTh User Number for Code Adjust H-based code tree reshuffle use

UCELLHSDPA HCodeAdjPunshTimerLength Punish Timer Length for Code This parameter is used for sett

UCELLHSDPA MIMOMPOConstant MIMO MPO Constant[dB] Measure power offset (MPO) co

UCELLHSUPA CellId Cell ID ID of a cell. For detailed inf

UCELLHSUPA EagchCodeNum Code Number for E-AGCH The parameter specifies the n

UCELLHSUPA ErgchEhichCodeNum Code Number for E-RGCH/E-

UCELLHSUPA MaxTargetUlLoadFactor Maximum Target Uplink Load F The parameter specifies the ta

UCELLHSUPA NonServToTotalEdchPwrRatio Target Non-serving E-DCH to This parameter specifies the r

UCELLID RNCId RNC ID MOD UCELLID(Optional) ID of an RNC

UCELLID SrcCellID Source Cell ID MOD UCELLID(Mandatory) Cell ID before modification

UCELLID DesCellID Destination Cell ID MOD UCELLID(Mandatory) New cell ID

UCELLINTERFREQHOCOV CellId Cell ID Unique ID of a cell

UCELLINTERFREQHOCOV InterFreqReportMode Inter-frequency Measure Repo

UCELLINTERFREQHOCOV InterFreqFilterCoef Inter-frequency Measure Filter

UCELLINTERFREQHOCOV PrdReportInterval Inter-frequency Measure Perio

UCELLINTERFREQHOCOV HystFor2B 2B Hysteresis

UCELLINTERFREQHOCOV HystFor2D 2D Hysteresis

UCELLINTERFREQHOCOV HystFor2F 2F Hysteresis

UCELLINTERFREQHOCOV HystForPrdInterFreq HHO Hysteresis

UCELLINTERFREQHOCOV WeightForUsedFreq Weight for Used frequency

UCELLINTERFREQHOCOV TimeToTrig2B Event 2B Trigger Delay

UCELLINTERFREQHOCOV TimeToTrig2D Event 2D Trigger Delay

UCELLINTERFREQHOCOV TimeToTrig2F Event 2F Trigger Delay

UCELLINTERFREQHOCOV TimeToTrigForPrdInterFreq HHO Period Trigger Delay

UCELLINTERFREQHOCOV InterFreqCSThd2DEcN0 Inter-freq CS Measure Start

UCELLINTERFREQHOCOV InterFreqCSThd2FEcN0 Inter-freq CS Measure Stop E

UCELLINTERFREQHOCOV InterFreqR99PsThd2DEcN0 Inter-freq R99 PS Measure St

UCELLINTERFREQHOCOV InterFreqHThd2DEcN0 Inter-freq H Measure Start Ec

UCELLINTERFREQHOCOV InterFreqR99PsThd2FEcN0 Inter-freq R99 PS Measure St

MOD UCELLHCS(Mandatory)RMV UCELLHCS(Mandatory)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)ADD UCELLHCS(Optional)MOD UCELLHCS(Optional)MOD UCELLHCSHO(Mandatory)RMV UCELLHCSHO(Mandatory)ADD UCELLHCSHO(Optional)MOD UCELLHCSHO(Optional)

The value OFF indicates that the UE speed estimation is not allowed in this cell.Note: The UE speed estimation cannot be triggered even if this switch is set to ON in either of the following cases: The cell is not configured as a HCS cell through the "ADD UCELLHCS" or "MOD UCELLHCS" command. The algorithm switch for the RNC-oriented UE speed estimation is not set to ON through "SET UCORRMALGOSWITCH".ADD UCELLHCSHO(Optional)

MOD UCELLHCSHO(Optional)Time window for estimating whether the UE is in high-mobility state.The start point of the estimation is the moment of the last reporting of event 1D, and the backdated time length is determined by this parameter. If the parameter is set to 0, the RNC does not decide whether the UE is in high-mobility state.ADD UCELLHCSHO(Optional)

MOD UCELLHCSHO(Optional)Threshold for determining whether the UE is in high-mobility state.After the UE reports event 1D, the UE is considered in high-mobility state if the number of changes of the best cell during "TFastSpdEst" is greater than this threshold. The smaller the value is, the more possible the UE is determined in high-mobility state.ADD UCELLHCSHO(Optional)

MOD UCELLHCSHO(Optional)Period for determine whether the UE is in low-mobility state. The RNC periodically determines whether the UE is in low-mobility state. The smaller the value is, the more frequently the state estimation is triggered. If the parameter is set to 0, the RNC does not determine whether the UE is in low-mobility state.ADD UCELLHCSHO(Optional)

MOD UCELLHCSHO(Optional)Time window for deciding whether the UE is in low-mobility state. Every time the slow speed period timer expires, the RNC estimates whether the UE is in low-mobility state. This parameter specifies the duration of the timer. If this parameter is set to 0, the RNC does not determine whether the UE is in low-mobility state.ADD UCELLHCSHO(Optional)

MOD UCELLHCSHO(Optional)Threshold for determining whether the UE is in low-mobility state. After the UE reports event 1D, the UE is considered in low-mobility state if the number of changes of the best cell is smaller than this threshold within the period of "TSlowSpdEst". The greater the value is, the more possible the UE is determined in low-mobility state.ADD UCELLHCSHO(Optional)

MOD UCELLHCSHO(Optional)Time window for determining whether ping-pong handover occurs in the best cell during the UE speed estimation. In the speed estimation algorithm, an algorithm is adopted to avoid inaccurate estimation caused by frequent handovers of best cells. That is, during the latest "TRELATELENGTH", if more than one event 1D of a certain cell occurs, the event 1D record is restored to the state when the 1st event 1D occurs during the latest "TRELATELENGTH". The given time length is set by this parameter. If this parameter is set too great, the RNC may mistakenly determine that ping-pong handover to the best cell occurs. If this parameter is set too small, ping-pong handover cannot be prevented. Thus, it is recommended that this parameter be set according to the cell radius.MOD UCELLHOCOMM(Mandatory)

RMV UCELLHOCOMM(Mandatory)ADD UCELLHOCOMM(Optional)MOD UCELLHOCOMM(Optional)

When INTERRAT is selected, only GSM neighboring cells are measured and inter-RAT handover is performed. When SIMINTERFREQRAT is selected, both inter-frequency and inter-RAT cells are measured, and the handover is performed according to the type of the cell that first meets the handover decision criteria.ADD UCELLHOCOMM(Optional)

MOD UCELLHOCOMM(Optional)When COEXIST_MEAS_THD_CHOICE_INTERRAT is selected, event 2D/2F measurement thresholds oriented towards inter-RAT configuration are selected.The factors such as the event 2D/2F measurement thresholds for inter-frequency measurement and inter-RAT measurement, inter-frequency and inter-RAT handover decision thresholds, and current handover policy should be considered during setting. For example, if the event 2D threshold for inter-RAT measurement is higher than that for inter-frequency measurement, and inter-frequency neighboring cells are preferred when inter-RAT and inter-frequency neighboring cells coexist, then COEXIST_MEAS_THD_CHOICE_INTERFREQ should be selected.ADD UCELLHOCOMM(Optional)

MOD UCELLHOCOMM(Optional)Based on the Service Handover Indicator of a service and the related parameter configurations on the network side, related measurements and inter-RAT handover are triggered immediately once a service is set up. This switch is set to ON only when service handover is required. Generally, the switch is set to OFF.Note that the service handover is triggered only when the Service Handover Indicator is set to HO_TO_GSM_SHOULD_BE_PERFORM and the inter-RAT handover switch for the corresponding service is set to ON. Both conditions are mandatory. For hybrid services, the service handover is not triggered.ADD UCELLHOCOMM(Optional)

MOD UCELLHOCOMM(Optional)Based on the Service Handover Indicator of a service and the related parameter configurations on the network side, related measurements and inter-RAT handover are triggered immediately once a service is set up. This switch is set to ON only when service handover is required. Generally, the switch is set to OFF.Note that the service handover is triggered only when the Service Handover Indicator is set to HO_TO_GSM_SHOULD_BE_PERFORM and the inter-RAT handover switch for the corresponding service is set to ON. Both conditions are mandatory. For hybrid services, the service handover is not triggered.MOD UCELLHSDPA(Mandatory)

RMV UCELLHSDPA(Mandatory)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)

This parameter named Measure Power Offset Constant is used to compute measurement power offset. Measurement power offset is used by UE to obtain total received HS-PDSCH power. The calculation for Measure Power Offset is as shown below:Measure Power Offset = Max(-6, Min(13,CellMaxPower - PcpichPower - Measure Power OffsetConstant)). For details of the IE "Measure Power Offset", refer to 3GPP TS 25.214.ADD UCELLHSDPA(Optional)

MOD UCELLHSDPA(Optional)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Mandatory)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)ADD UCELLHSDPA(Optional)MOD UCELLHSDPA(Optional)MOD UCELLHSUPA(Mandatory)RMV UCELLHSUPA(Mandatory)ADD UCELLHSUPA(Optional)MOD UCELLHSUPA(Optional)ADD UCELLHSUPA(Optional)MOD UCELLHSUPA(Optional)

The parameter specifies the number of codes (SF=128) used by the E-DCH Relative Grant Channel (E-RGCH)/E-DCH Hybrid ARQ Indicator Channel (E-HICH). The E-RGCH is used to adjust the uplink power available for the UE. The E-HICH is used to provide feedback on the ACK/NACK information, which indicates whether the data that the RNC receives from the E-DCH is correct or not. The E-RGCH and E-HICH are dedicated channels shared by multiple UEs. They share the OVSF channel code with SF=128 and use the orthogonal signature sequence to differentiate subscribers. For details about this parameter, refer to 3GPP TS 25.433.ADD UCELLHSUPA(Optional)

MOD UCELLHSUPA(Optional)ADD UCELLHSUPA(Optional)MOD UCELLHSUPA(Optional)

MOD UCELLINTERFREQHOCOV(Mandatory)RMV UCELLINTERFREQHOCOV(Mandatory)ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)

The advantage of the periodical measurement report mode is that it can repeatedly perform direct retry on the same cell when the handover fails, and that the following algorithms can be flexibly developed. For the cell-oriented algorithm parameters, the UE need not be informed through signaling but the cell need be updated only when the handover decision is performed in the RNC. The disadvantage of the periodical measurement report mode is that it requires large amount of signaling and increases the load on the air interface and for signaling processing. As for the impact on network performance,the two measurement report modes have both advantages and disadvantages. Currently, the traditional periodical report mode is preferred.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)This parameter specifies the Layer 3 filter coefficient for the inter-frequency measurementThis parameter has the same physical significance and measurement model as the layer 3 filter coefficient for the intra-frequency measurement. The difference is that the report period of the inter-frequency measurement is 480 ms while the report period of the intra-frequency measurement is 200 ms. In practice, the setting of this parameter can be adjusted according to performance statistics.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Interval between periodic reporting for the inter-frequency handover. In periodic reporting mode, the inter-frequency handover attempts is reported at the preset interval. It is not recommended that this parameter be set to "NON_PERIODIC_REPORT" since the UE behavior may be unknown. This parameter has impact on the Uu signaling flow. If the interval is too short and the frequency is too high, the RNC may have high load when processing signaling. If the interval is too long, the network cannot detect the signal changes in time. This may delay the inter-frequency handover, thus causing call drops.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Hysteresis for triggering event 2B.The value of this parameter is associated with the slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change and thus event 2B may not be triggered in time.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)When "InterFreqReportMode" is set to PERIODICAL_REPORTING, the hysteresis in active set quality measurement is used to prevent the ping-pong reporting of event 2D (triggered when the estimated quality of the frequency in use is lower than the threshold) and event 2F (triggered when the estimated quality of the frequency in use is higher than the threshold). Event 2D is used to enable the compression mode and event 2F is used to disable the compression mode. To prevent the compression mode from being frequently enabled and disabled, you can set "Hystfor2D" and "Hystfor2F" to be greater than their recommended values according to the statistics of the ping-pong inter-frequency handover.To set "Hystfor2D" and "Hystfor2F", you should consider the radio environment (with slow fading characteristics), actual handover distance, and moving speed of the UE. The value of this parameter ranges from 2 dB to 5 dB. In addition, filter coefficient and trigger delay must be considered in setting this parameter.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)When "InterFreqReportMode" is set to PERIODICAL_REPORTING, the hysteresis in active set quality measurement is used to prevent the ping-pong reporting of event 2D (triggered when the estimated quality of the frequency in use is lower than the threshold) and event 2F (triggered when the estimated quality of the frequency in use is higher than the threshold). Event 2D is used to enable the compression mode and event 2F is used to disable the compression mode. To prevent the compression mode from being frequently enabled and disabled, you can set "Hystfor2D" and "Hystfor2F" to be greater than their recommended values according to the statistics of the ping-pong inter-frequency handover.To set "Hystfor2D" and "Hystfor2F", you should consider the radio environment (with slow fading characteristics), actual handover distance, and moving speed of the UE. The value of this parameter ranges from 2 dB to 5 dB. In addition, filter coefficient and trigger delay must be considered in setting this parameter.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Hysteresis in the inter-frequency hard handover triggered by the periodic measurement report.This parameter is used to estimate the inter-frequency handover on the RNC side. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change and thus the handover may not be triggered in time.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)The parameter WeightForUsedFreq is the frequency weighting factor used to calculate the quality of the current frequency. If this parameter is set to a greater value, the higher quality of the active set is obtained. If this parameter is set to 0, the general quality of the active set is considered the quality of the best cell in this set. For details about this parameter, see the subsection of frequency quality estimation in the section of inter-frequency measurement in 3GPP TS 25.331. This parameter is used for event-triggered reporting of inter-frequency handovers for events 2D, 2F, 2B and 2C, but not used for periodical reporting of inter-frequency handovers.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Interval time between the detection of event 2B and sending of measurement report. This parameter correlates with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Interval time between detection of event 2D and sending of the measurement report. This parameter correlates with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Interval time between detection of event 2F and sending of the measurement report.This parameter correlates with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Interval between reception of periodical reports and triggering of the inter-frequency handover. Only the inter-frequency cell in which the signal quality is above a certain threshold in all periodic reports during a time equal to this parameter can be selected as the target cell for the inter-frequency handover. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)For the cell in which the UEs are moving at various speeds, set this parameter to -14 dB. The emulation result shows that the call drop rate remains low for the UEs moving at a speed of 120 km/h when this parameter is set to -14 dB.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)When Ec/No is used as the measurement quantity for CS services, the UE reports event 2F when the measured Ec/No value is higher than the value of this parameter. Then, the RNC sends the signaling to disable the compression mode and stop the inter-frequency measurement. Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.ADD UCELLINTERFREQHOCOV(Optional)



MOD UCELLINTERFREQHOCOV(Optional)When Ec/No is used as the measurement quantity for PS non-HSPA services, the UE reports event 2F when the measured Ec/No value is higher than the value of this parameter. Then, the RNC sends the signaling to disable the compression mode and stop the inter-frequency measurement.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.

UCELLINTERFREQHOCOV InterFreqHThd2FEcN0 Inter-freq H Measure Stop Ec

UCELLINTERFREQHOCOV InterFreqCSThd2DRSCP Inter-freq CS Measure Start

UCELLINTERFREQHOCOV InterFreqCSThd2FRSCP Inter-freq CS Measure Stop

UCELLINTERFREQHOCOV InterFreqR99PsThd2DRSCP Inter-freq R99 PS Measure S

UCELLINTERFREQHOCOV InterFreqHThd2DRSCP Inter-freq H Measure Start R

UCELLINTERFREQHOCOV InterFreqR99PsThd2FRSCP Inter-freq R99 PS Measure S

UCELLINTERFREQHOCOV InterFreqHThd2FRSCP Inter-freq H Measure Stop R

UCELLINTERFREQHOCOV TargetFreqCsThdEcN0 Inter-freq CS Target Frequenc Threshold of the target freque

UCELLINTERFREQHOCOV TargetFreqHThdEcN0 Inter-freq HSPA Target Frequ Threshold of the target freque

UCELLINTERFREQHOCOV TargetFreqR99PsThdEcN0 Inter-freq R99 PS Target Fre Threshold of the target freque

UCELLINTERFREQHOCOV TargetFreqCsThdRscp Inter-freq CS Target Frequen Threshold of the target freque

UCELLINTERFREQHOCOV TargetFreqHThdRscp Inter-freq HSPA Target Frequ Threshold of the target freque

UCELLINTERFREQHOCOV TargetFreqR99PsThdRscp Inter-freq R99 PS Target Fre Threshold of the target freque

UCELLINTERFREQHOCOV UsedFreqCSThdEcN0 Inter-freq CS Used frequency

UCELLINTERFREQHOCOV UsedFreqR99PsThdEcN0 Inter-freq R99 PS Used freque

UCELLINTERFREQHOCOV UsedFreqHThdEcN0 Inter-freq H Used frequency t

UCELLINTERFREQHOCOV UsedFreqCSThdRSCP Inter-freq CS Used frequency

UCELLINTERFREQHOCOV UsedFreqR99PsThdRSCP Inter-freq R99 PS Used frequ

UCELLINTERFREQHOCOV UsedFreqHThdRSCP Inter-freq H Used frequency t

UCELLINTERFREQHOCOV InterFreqMeasTime Inter-freq Measure Timer Leng

UCELLINTERFREQHOCOV PeriodFor2B 2B Event Retry Period Sets the interval between the f

UCELLINTERFREQHOCOV AmntOfRpt2B 2B Event Retry Max Times

UCELLINTERFREQHOCOV TimeToInterfreqHO Inter-freq Coverage Handover

UCELLINTERFREQHONCOV CellId Cell ID Unique ID of a cell

UCELLINTERFREQHONCOV InterFreqFilterCoef Inter-frequency Measure Filter

UCELLINTERFREQHONCOV Hystfor2C 2C Hysteresis

UCELLINTERFREQHONCOV TrigTime2C Event 2C Trigger Delay

UCELLINTERFREQHONCOV InterFreqCovHOThdEcN0 Inter-Freq Measure Target Fr

UCELLINTERFREQHONCOV InterFreqMeasTime Inter-freq Measure Timer Leng

UCELLINTERFREQHONCOV PeriodFor2C 2C Event Retry Period

UCELLINTERFREQHONCOV AmntOfRpt2C Event 2C Retry Max Times

UCELLINTERRATHOCOV CellId Cell ID Unique ID of a cell

UCELLINTERRATHOCOV InterRatReportMode Inter-RAT Report Mode

UCELLINTERRATHOCOV FilterCoefOf2D2F 2D/2F Filter Coefficient

UCELLINTERRATHOCOV MeasQuantityOf3A 3A Measure Quantity

UCELLINTERRATHOCOV InterRATFilterCoef Inter-RAT Filter Coefficient

UCELLINTERRATHOCOV WeightForUsedFreq Weight for Used Frequency

UCELLINTERRATHOCOV InterRATPeriodReportInterval Inter-RAT Period Reporting Int

UCELLINTERRATHOCOV Hystfor2D 2D Hysteresis

UCELLINTERRATHOCOV Hystfor2F 2F Hysteresis

UCELLINTERRATHOCOV Hystfor3A 3A Hysteresis

UCELLINTERRATHOCOV HystforInterRAT Inter-RAT Hysteresis

UCELLINTERRATHOCOV TrigTime2D 2D Event Trigger Delay Time

UCELLINTERRATHOCOV TrigTime2F 2F Event Trigger Delay Time

UCELLINTERRATHOCOV TrigTime3A 3A Event Trigger Delay Time

UCELLINTERRATHOCOV TimeToTrigForNonVerify Time to Trigger Handover to N

UCELLINTERRATHOCOV TimeToTrigForVerify Time to Trigger Handover to V

UCELLINTERRATHOCOV BSICVerify BSIC Verify Switch

UCELLINTERRATHOCOV InterRATCSThd2DEcN0 Inter-RAT CS Measure Start

UCELLINTERRATHOCOV InterRATCSThd2FEcN0 Inter-RAT CS Measure Stop E

UCELLINTERRATHOCOV InterRATR99PsThd2DEcN0 Inter-RAT R99 PS Measure St

UCELLINTERRATHOCOV InterRATHThd2DEcN0 Inter-RAT HSPA Measure Star

UCELLINTERRATHOCOV InterRATR99PsThd2FEcN0 Inter-RAT R99 PS Measure St

UCELLINTERRATHOCOV InterRATHThd2FEcN0 Inter-RAT HSPA Measure Sto

UCELLINTERRATHOCOV InterRATCSThd2DRSCP Inter-RAT CS Measure Start

UCELLINTERRATHOCOV InterRATCSThd2FRSCP Inter-RAT CS Measure Stop

UCELLINTERRATHOCOV InterRATR99PsThd2DRSCP Inter-RAT R99 PS Measure S

UCELLINTERRATHOCOV InterRATHThd2DRSCP Inter-RAT HSPA Measure Sta

UCELLINTERRATHOCOV InterRATR99PsThd2FRSCP Inter-RAT R99 PS Measure S

UCELLINTERRATHOCOV InterRATHThd2FRSCP Inter-RAT HSPA Measure St

UCELLINTERRATHOCOV TargetRatCsThd Inter-RAT CS Handover Decis

ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)

When Ec/No is used as the measurement quantity for HSPA services, the UE reports event 2F when the measured Ec/No value is higher than the value of this parameter. Then, the RNC sends the signaling to disable the compression mode and stop the inter-frequency measurement. Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.When the signals at the entrance to an elevator or a subway change too fast to perform handover, set this parameter to -90 dBm to enable the compression mode earlier.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F. When the signals at the entrance to an elevator or a subway change too fast to perform handover, set this parameter to -85 dBm to enable the compression mode earlier.ADD UCELLINTERFREQHOCOV(Optional)





MOD UCELLINTERFREQHOCOV(Optional)ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)

Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of Ec/No for CS services.For CS services, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of Ec/No for non-HSPA services in PS domain.For non-HSPA services in PS domain, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of Ec/No for HSPA services.For HSPA services, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of RSCP for CS services.For CS services, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of RSCP for non-HSPA services in PS domain.For non-HSPA services in PS domain, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of RSCP for HSPA services.For HSPA services, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)If the inter-frequency handover is not performed before this timer expires, the inter-frequency measurement is stopped and the compression mode is disabled (if enabled before). The value 0 indicates that this timer is not to be started.This parameter is used to prevent the long duration of the inter-frequency measurement state (compression mode) due to unavailability of a target cell that meets the handover criteria.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)ADD UCELLINTERFREQHOCOV(Optional)MOD UCELLINTERFREQHOCOV(Optional)

If this parameter is set to a greater value, the number of inter-frequency handover re-attempts increases and the possibility of successfully handing over the UE to the target cell whose load becomes normal increases. When the number of inter-frequency handover re-attempts reaches the threshold, the RNC sends another inter-frequency measurement control message to allow the UE to be handed over to other cells of this frequency.If the measurement control is released, the inter-frequency handover re-attempt is stopped.ADD UCELLINTERFREQHOCOV(Optional)

MOD UCELLINTERFREQHOCOV(Optional)If the inter-frequency coverage handover priority of the cell reporting the MR is equal to the highest priority of the target cell defined in the measurement control list, the inter-frequency handover is triggered. If the inter-frequency coverage handover priority of the cell reporting the MR is lower than the highest priority of the target cell defined in the measurement control list, the inter-freq coverage handover delay timer is enabled. When the timer expires, the inter-freq handover is triggered.MOD UCELLINTERFREQHONCOV(Mandatory)

RMV UCELLINTERFREQHONCOV(Mandatory)ADD UCELLINTERFREQHONCOV(Optional)MOD UCELLINTERFREQHONCOV(Optional)

This parameter specifies the Layer 3 filter coefficient for the inter-frequency measurementThis parameter has the same physical significance and measurement model as the layer 3 filter coefficient for the intra-frequency measurement. The difference is that the report period of the inter-frequency measurement is 480 ms while the report period of the intra-frequency measurement is 200 ms. In practice, the setting of this parameter can be adjusted according to performance statistics.ADD UCELLINTERFREQHONCOV(Optional)

MOD UCELLINTERFREQHONCOV(Optional)Hysteresis used for event 2C.The value of this parameter is associated with the slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change and thus event 2C may not be triggered in time.ADD UCELLINTERFREQHONCOV(Optional)

MOD UCELLINTERFREQHONCOV(Optional)The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change.The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLINTERFREQHONCOV(Optional)

MOD UCELLINTERFREQHONCOV(Optional)Threshold of the target frequency quality for triggering inter-frequency handover. This parameter is used for measurement control on event 2C. When the target frequency quality is higher than this threshold, event 2C is triggered.ADD UCELLINTERFREQHONCOV(Optional)

MOD UCELLINTERFREQHONCOV(Optional)If the inter-frequency handover is not performed before this timer expires, the inter-frequency measurement is stopped and the compression mode is disabled (if enabled before). The value 0 indicates that this timer is not to be started.This parameter is used to prevent the long duration of the inter-frequency measurement state (compression mode) due to unavailability of a target cell that meets the handover criteria.ADD UCELLINTERFREQHONCOV(Optional)

MOD UCELLINTERFREQHONCOV(Optional)Interval between the handover re-attempts for event 2C. If the inter-frequency handover for event 2C fails, the RNC reties the inter-frequency handover. This parameter specifies the interval between the handover re-attempts for event 2C. If this parameter is set to a smaller value, handover re-attempts increase when the inter-frequency handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced. The RNC load, however, increases.ADD UCELLINTERFREQHONCOV(Optional)

MOD UCELLINTERFREQHONCOV(Optional)Maximum number of handover attempts for event 2C. This parameter specifies the maximum number of handover re-attempts for event 2C when the measurement control message is valid. If this parameter is set to a greater value, inter-frequency handover re-attempts increase and the possibility of successfully handing over the UE to the target cell whose load becomes normal increases. When the number of re-attempts reaches the preset value, the RNC does not attempt to perform the handover. Alternatively, when the measurement control is cancelled, the handover re-attempt is stopped immediately.MOD UCELLINTERRATHOCOV(Mandatory)

RMV UCELLINTERRATHOCOV(Mandatory)ADD UCELLINTERRATHOCOV(Optional)MOD UCELLINTERRATHOCOV(Optional)

The advantage of periodical reporting is that it can be used for repeated handover re-attempts on the same cell when the handover fails, and that subsequent algorithms can be flexibly developed. In addition, for the cell-oriented algorithm parameters, the RNC updates the parameters when making internal handover decision and the system needs not to inform the UEs of the parameter change through signaling messages after the handovers. The drawback of periodical reporting is that it requires large amount of signaling and increases the load on the air interface and for signaling processing.The two reporting modes have both advantage and drawback. Currently, the traditional periodical reporting mode is preferred.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)In cells where the average moving speed of UEs is medium, there is a comparatively smaller shadow fading square error. Therefore, the recommended value is 3. In cells where the average moving speed of UEs is high, there is a comparatively small shadow fading square error. Therefore, the recommended value is 2.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)When CPICH_RSCP is selected, it indicates that the RSCP measurement quantity is used for event 3A measurement. The physical unit is dBm.When AUTO is selected, it indicates that the Ec/No measurement quantity is used for event 3A measurement if the RNC receives Ec/No 2D firstly. If the RNC receives the RSCP 2D firstly, the RSCP measurement quantity is used for event 3A measurement.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)In cells where the average moving speed of UEs is medium, there is a comparatively smaller shadow fading square error. Therefore, the recommended value is 3. In cells where the average moving speed of UEs is high, there is a comparatively small shadow fading square error. Therefore, the recommended value is 2.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)This parameter is used for event 3A evaluation. For detailed information of this parameter, refer to 3GPP TS 25.133.To set this parameter, see the method for setting the intra-frequency handover weighting factor "Weight".ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)The adjustment should be made according to the configured GSM RSSI measurement compressed mode sequence. According to the current configured GSM RSSI measurement compressed mode sequence, the RSSI measurement of eight GSM cells can be finished in 480 ms. Therefore, the RSSI measurement of 16 GSM cells can be finished in 1000 ms. According to 3GPP specifications, the number of inter-RAT neighboring cells should not exceed 32. Therefore, the parameter value can be set to 2000 ms if the number of neighboring GSM cells exceeds 16.The setting of this parameter has impact on the Uu signaling traffic. If the period is too short and the reporting frequency is too high, the RNC may have high load in processing signaling. If the period is too long, the network cannot detect the signal changes in time, which may delay the inter-RAT handover and thus cause call drops.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)This parameter is used to avoid the ping-pong reporting of event 2D (the estimated quality of the currently used frequency is below a certain threshold). The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of ping-pong reporting or wrong decision is lower, but the event may not be triggered in time. If this parameter is set to a smaller value, ping-pong reporting of event 2D is likely to occur.The setting of this parameter should consider the radio conditions (slow fading), actual handover distance, and moving speed of the UE. The value of this parameter ranges from 2 dB to 5 dB. In addition, filter coefficient and triggering delay must be considered in setting this parameter.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)The inter-RAT measurement hysteresis in periodical reporting mode is used to prevent the ping-pong reporting of event 2D (the estimated quality of the currently used frequency is below a certain threshold) and event 2F (the estimated quality of the currently used frequency is above a certain threshold). Event 2D is used to enable the compressed mode and event 2F is used to disable the compressed mode. "Hystfor2D" can be increased slightly based on the recommended value, considering inter-frequency handover statistics. Hystfor2D can also be increased slightly to prevent the compressed mode from being frequently enabled and disabled and to avoid unnecessary active set updates. The setting of this parameter should consider the radio conditions (slow fading), actual handover distance, and moving speed of the UE. The value of this parameter ranges from 2 dB to 5 dB. In addition, filter coefficient and triggering delay must be considered in setting this parameter.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change. If this parameter is set to a larger value, the cell of another RAT where the UE needs to be handed over to must be of good quality. Therefore, the criteria for triggering the inter-RAT handover decision is hard to be fulfilled, and the call drop rate will increase.The emulation result shows that in a cell where the average moving speed of UEs is high (for example, a cell that covers highways), this parameter can be set to a smaller value 1.5 dB, because in the cell the terrain is flat, barriers are fewer, and thus the shadow fading variation is small. In a cell where the average moving speed of UEs is low, this parameter can be set to a larger value 3.0 dB, because there are usually many tall buildings and thus the shadow fading variation is comparatively high.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change. If this parameter is set to a larger value, the cell of another RAT where the UE needs to be handed over to must be of good quality. Therefore, the criteria for triggering the inter-RAT handover decision is hard to be fulfilled, and the call drop rate will increase.The emulation result shows that in a cell where the average moving speed of UEs is high (for example, a cell that covers highways), this parameter can be set to a smaller value 1.5 dB, because in the cell the terrain is flat, barriers are fewer, and thus the shadow fading variation is small. In a cell where the average moving speed of UEs is low, this parameter can be set to a larger value 3.0 dB, because there are usually many tall buildings and thus the shadow fading variation is comparatively high.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation result shows that the hysteresis setting can effectively reduce the average number of handovers and the number of incorrect handovers, thus preventing unnecessary handovers. The emulation result also shows that the UE at different data rates may react differently to the delay for triggering the event. For the fast-moving UE, the call drop rate is more sensitive to the delay, whereas, for the slow-moving UE, the call drop rate is less sensitive to the delay. This can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation result shows that the hysteresis setting can effectively reduce the average number of handovers and the number of incorrect handovers, thus preventing unnecessary handovers. The emulation result also shows that the UE at different data rates may react differently to the delay for triggering the event. For the fast-moving UE, the call drop rate is more sensitive to the delay, whereas, for the slow-moving UE, the call drop rate is less sensitive to the delay. This can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)The inter-frequency measurement reporting period is 480 ms. Therefore, the trigger delay time shorter than 480 ms is invalid.If the parameter is set to a larger value, handover is unlikely to be triggered. However, call drops may increase as the parameter value increases.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Time delay for triggering handovers to GSM cells with non-verified BSIC.During the period of time specified by this parameter, if the signal quality in a neighboring GSM cell fulfills inter-RAT handover criteria and the neighboring GSM cell is not verified, an inter-RAT handover is triggered. When this parameter value is 65535, the RNC does not perform inter-RAT handovers to non-verified GSM cells. If this parameter is set to a larger value, the average number of handovers decreases, but call drops may occur.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Considering that the UE is on the edge of the system, this parameter should be set to a comparatively low value. In situations where a GSM cell is verified, the performance of the GSM cell is generally regarded as good. In this case, the parameter can be set to 0, which indicates that the handover is performed immediately.If this parameter is set to a larger value, the average number of handovers decreases, but call drops may occur.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Switch for verifying the Base Station Identity Code (BSIC). This parameter is used to control cells where inter-RAT measurement reports are triggered. When the parameter is set to "REQUIRED", the measurement reporting is triggered after the BSIC of the measured cell is decoded correctly. When the parameter is set to "NOT_REQUIRE", the measurement reporting is triggered regardless of whether the BSIC of the measured cell is decoded correctly. This parameter is valid for both periodical reporting mode and event-triggered reporting mode. However, to ensure handover reliability, it is recommended that the system reports only the cells whose BSIC is decoded correctly, that is, the recommended value of the parameter is "REQUIRED". If the parameter is set to "NOT_REQUIRED", handovers are likely to be triggered, but the handover reliability is lower than that in the situation the parameter is set to "REQUIRED".ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Event 2D and event 2F are used to enable and disable the compressed mode respectively in inter-RAT measurement. The requirements on the signal quality and inter-RAT handover policies vary with the service type. Therefore, the thresholds of enabling and disabling inter-RAT measurement are distinguished by CS, PS, and signaling. To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)If the cell is a micro cell, the default value should be modified according to the link budgeting result. Event 2D and event 2F are used to enable and disable the compressed mode respectively. When the cell is located in the center of the frequency coverage or the inter-frequency measurement quantity uses both Ec/No and RSCP, then the Ec/No value is used as the criterion for events 2D and 2F. To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F.ADD UCELLINTERRATHOCOV(Optional)





MOD UCELLINTERRATHOCOV(Optional)To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F. In most cases, users want to be maintained within a 3G network. Therefore, the start threshold of the inter-RAT measurement is set smaller than that of the inter-frequency measurement in order to trigger inter-frequency easily. In scenarios where inter-frequency neighboring cells are unavailable or where inter-frequency coverage is insufficient, the inter-RAT measurement start threshold should be set relatively larger in order to trigger inter-RAT measurement easily, thus reducing call drops.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Threshold of stopping inter-RAT measurement for CS services when measurement quantity is RSCP. When RSCP is used as the measurement quantity for CS services, the UE reports event 2F when the measured RSCP value is larger than this threshold. Then, the RNC sends the signaling to disable the compressed mode and stop the inter-RAT measurement.ADD UCELLINTERRATHOCOV(Optional)



MOD UCELLINTERRATHOCOV(Optional)Threshold of stopping inter-RAT measurement for PS domain non-HSPA services when the measurement quantity is RSCP. When RSCP is used as the measurement quantity for PS domain non-HSPA services, the UE reports event 2F when the measured RSCP value is larger than this threshold. Then, the RNC sends the signaling to disable the compressed mode and stop the inter-RAT measurement.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Threshold of stopping inter-RAT measurement for HSPA services when measurement quantity is RSCP. When RSCP is used as the measurement quantity for HSPA services, the UE reports event 2F when the measured RSCP value is larger than this threshold. Then, the RNC sends the signaling to disable the compressed mode and stop the inter-RAT measurement.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.

UCELLINTERRATHOCOV TargetRatR99PsThd Inter-RAT R99 PS Handover D

UCELLINTERRATHOCOV TargetRatHThd Inter-RAT HSPA Handover De

UCELLINTERRATHOCOV UsedFreqCsThdEcN0 Inter-RAT CS Used Frequency

UCELLINTERRATHOCOV UsedFreqR99PsThdEcN0 Inter-RAT R99 PS Used Frequ

UCELLINTERRATHOCOV UsedFreqHThdEcN0 Inter-RAT HSPA Used Frequen

UCELLINTERRATHOCOV UsedFreqCsThdRscp Inter-RAT CS Used Frequenc

UCELLINTERRATHOCOV UsedFreqR99PsThdRscp Inter-RAT R99 PS Used Freq

UCELLINTERRATHOCOV UsedFreqHThdRscp Inter-RAT HSPA Used Freque

UCELLINTERRATHOCOV InterRATMeasTime Inter-RAT Measure Timer Leng

UCELLINTERRATHOCOV InterRATPingPongTimer Inter-RAT Ping-Pong Timer

UCELLINTERRATHOCOV InterRATPingPongHyst Inter-RAT Ping-Pong Hysteres

UCELLINTERRATHOCOV PeriodFor3A 3A Event Retry Period

UCELLINTERRATHOCOV AmntOfRpt3A 3A Event Maximum Retry Tim

UCELLINTERRATHOCOV InterRatPhyChFailNum Inter-RAT HO Physical Channe

UCELLINTERRATHOCOV PenaltyTimeForPhyChFail Inter-RAT HO Physical Channel

UCELLINTERRATHONCOV CellId Cell ID Unique ID of a cell

UCELLINTERRATHONCOV InterRATFilterCoef Inter-RAT Filter Coefficient

UCELLINTERRATHONCOV Hystfor3C 3C Hysteresis

UCELLINTERRATHONCOV TrigTime3C Event 3C Trigger Delay

UCELLINTERRATHONCOV BSICVerify BSIC Verify Switch

UCELLINTERRATHONCOV InterRATNCovHOCSThd Inter-RAT CS Handover Decis

UCELLINTERRATHONCOV InterRATNCovHOPSThd Inter-RAT PS Handover Decis

UCELLINTERRATHONCOV InterRATHOAttempts Inter-RAT Handover Max Atte Maximum number of inter-RAT ha

UCELLINTERRATHONCOV InterRATMeasTime Inter-RAT Measure Timer Leng

UCELLINTERRATHONCOV CSHOOut2GloadThd CS Domain Reloc GSM Load This parameter specifies the

UCELLINTERRATHONCOV PSHOOut2GloadThd PS Domain Reloc GSM Load This parameter specifies the

UCELLINTERRATHONCOV PeriodFor3C Event 3C Retry Period

UCELLINTERRATHONCOV AmntOfRpt3C Event 3C Retry Max Times

UCELLINTERRATHONCOV InterRatPhyChFailNum Inter-RAT HO Physical Channe

UCELLINTERRATHONCOV PenaltyTimeForPhyChFail Inter-RAT HO Physical Channel

UCELLINTRAFREQHO RNCId RNC ID ID of an RNC

UCELLINTRAFREQHO CellId Cell ID Unique ID of a cell

UCELLINTRAFREQHO IntraFreqFilterCoef Intra-frequency L3 Filter Coeffi

UCELLINTRAFREQHO IntraFreqMeasQuantity Intra-frequency Measurement Quantity of the triggered measu

UCELLINTRAFREQHO PeriodMRReportNumfor1A Event 1A to Periodical Report Maximum number of reporting ev

UCELLINTRAFREQHO ReportIntervalfor1A Event 1A to Periodical Report Interval at which event 1A is r

UCELLINTRAFREQHO PeriodMRReportNumfor1C Event 1C to Periodical Report Maximum number of reporting ev

UCELLINTRAFREQHO ReportIntervalfor1C Event 1C to Periodical Report Interval at which event 1A is

UCELLINTRAFREQHO PeriodMRReportNumfor1J Event 1J to Periodical Report Maximum number of reporting ev

UCELLINTRAFREQHO ReportIntervalfor1J Event 1J to Periodical Report Interval at which event 1J is r

UCELLINTRAFREQHO IntraRelThdFor1ACSVP VP Service Event 1A Relative

UCELLINTRAFREQHO IntraRelThdFor1ACSNVP CS Non-VP Service Event 1A

UCELLINTRAFREQHO IntraRelThdFor1APS PS Service Event 1A Relative

UCELLINTRAFREQHO IntraRelThdFor1BCSVP VP Service Event 1B Relative

UCELLINTRAFREQHO IntraRelThdFor1BCSNVP CS Non-VP Service Event 1B R

UCELLINTRAFREQHO IntraRelThdFor1BPS PS Service Event 1B Relative

UCELLINTRAFREQHO IntraAblThdFor1FEcNo Event 1F Absolute Ec/No Thre

UCELLINTRAFREQHO IntraAblThdFor1FRSCP Event 1F Absolute RSCP Thre

UCELLINTRAFREQHO HystFor1A 1A Hysteresis This parameter specifies the hy

UCELLINTRAFREQHO HystFor1B 1B Hysteresis This parameter specifies the hy

UCELLINTRAFREQHO HystFor1C 1C Hysteresis This parameter specifies the hy

UCELLINTRAFREQHO HystFor1D 1D Hysteresis This parameter specifies the hy

UCELLINTRAFREQHO HystFor1F 1F Hysteresis This parameter specifies the hy

UCELLINTRAFREQHO HystFor1J 1J Hysteresis This parameter specifies the hy

UCELLINTRAFREQHO Weight Weighted factor Used for calculating the relati

UCELLINTRAFREQHO TrigTime1A Event 1A Triggering Delay

UCELLINTRAFREQHO TrigTime1B Event 1B Triggering Delay

UCELLINTRAFREQHO TrigTime1C Event 1C Triggering Delay

UCELLINTRAFREQHO TrigTime1D Event 1D Triggering Delay

UCELLINTRAFREQHO TrigTime1F Event 1F Triggering Delay

UCELLINTRAFREQHO TrigTime1J Event 1J Triggering Delay

ADD UCELLINTERRATHOCOV(Optional)MOD UCELLINTERRATHOCOV(Optional)

The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Impact on network performance:If this parameter is set to a larger value, event 3A is likely to be triggered. However, handover is likely to be triggered when the frequency quality in the current system is acceptable for the UE if the value of this parameter is set too large.ADD UCELLINTERRATHOCOV(Optional)






MOD UCELLINTERRATHOCOV(Optional)Impact on network performance:If the parameter is set to a smaller value, the UE cannot finish inter-RAT handover. If the parameter is set to a larger value, the compressed mode will not be disabled, thus affecting UE measurement. In actual networks, statistics can be made to obtain the delay for a successful inter-RAT handover, thus to get a proper value of "InterRATMeasTime" that satisfies most UEs.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Length of the timer to avoid ping-pong handovers between 2G and 3G networks.When a UE in the CS domain is handed over from a 2G network to a 3G network, the system increases the hysteresis used for event 3A to prevent the ping-pong handover between the 2G network and the 3G network in the period specified by this parameter. During the penalty time, the previous periodical report will be changed to the event 3A report. The value 0 indicates that the system does not take measures to avoid ping-pong handover between 2G and 3G networks.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Hysteresis to avoid ping-pong handover between 2G and 3G networks. When a UE in the CS domain is handed over from a 2G network to a 3G network, the system increases the hysteresis used for event 3A to prevent the ping-pong handover between the 2G network and the 3G network in the handover penalty period specified by "InterRATPingPongTimer". During the penalty time, event-triggered reporting is used for inter-RAT measurement. The value 0 indicates that the system does not take measures to avoid ping-pong handover between 2G and 3G networks.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Interval between handover attempts for event 3A. This parameter specifies the interval between handover attempts for event 3A. If this parameter is set to a smaller value, handover attempts increase when the inter-RAT handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced, thus lowering the probability of call drops. More handover re-attempts, however, cause the increase in the RNC load.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Maximum number of handover attempts after inter-RAT handover triggered by event 3A fails.This parameter specifies the maximum number of handover re-attempts for event 3A when the measurement control is valid. If this parameter is set to a greater value, the number of inter-RAT handover re-attempts increases and the possibility of successfully handing over the UE to the target cell whose load becomes normal increases. After reaching the value specified by this parameter, the RNC makes no further handover attempt to the target cell. If the compressed mode is disabled, the handover re-attempt will be aborted.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Maximum number of inter-RAT handover failures allowed due to physical channel failure. When the number of inter-RAT handover failures due to physical channel failure exceeds the threshold, a penalty is given to the UE. During the time specified by "PenaltyTimeForInterRatPhyChFail[/para], the UE is not allowed to make inter-RAT handover attempts.For details about the physical channel failure, see 3GPP TS 25.331.ADD UCELLINTERRATHOCOV(Optional)

MOD UCELLINTERRATHOCOV(Optional)Duration of the penalty for inter-RAT handover failure due to physical channel failure. The UE is not allowed to make inter-RAT handover attempts within the penalty time.For details about the physical channel failure, see 3GPP TS 25.331.MOD UCELLINTERRATHONCOV(Mandatory)

RMV UCELLINTERRATHONCOV(Mandatory)ADD UCELLINTERRATHONCOV(Optional)MOD UCELLINTERRATHONCOV(Optional)

In cells where the average moving speed of UEs is medium, there is a comparatively smaller shadow fading square error. Therefore, the recommended value is 3. In cells where the average moving speed of UEs is high, there is a comparatively small shadow fading square error. Therefore, the recommended value is 2.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)The value of this parameter is associated with the slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change. If this parameter is set to a too large value, the cell of another RAT where the UE needs to be handed over to must be of good quality. Therefore, the criterion for triggering the inter-RAT handover decision is hard to be fulfilled, and the call drop rate increases. The emulation result shows that in a cell where the average moving speed of UEs is high (for example, a cell that covers highways), this parameter can be set to a smaller value 1.5 dB, because in the cell the terrain is flat, barriers are fewer, and thus the shadow fading variation is small. In a cell where the average moving speed of UEs is low, this parameter can be set to a larger value 3.0 dB, because there are usually many tall buildings and thus the shadow fading variation is comparatively high.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)The inter-frequency measurement reporting period is 480 ms. Therefore, the trigger delay time shorter than 480 ms is invalid. If the parameter is set to a larger value, handover is unlikely to be triggered. However, call drops may increase as the parameter value increases.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)Switch for verifying the Base Station Identity Code (BSIC). This parameter is used to control cells where inter-RAT measurement reports are triggered. When the parameter is set to "REQUIRED", the measurement reporting is triggered after the BSIC of the measured cell is decoded correctly. When the parameter is set to "NOT_REQUIRE", the measurement reporting is triggered regardless of whether the BSIC of the measured cell is decoded correctly. This parameter is valid for both periodical reporting mode and event-triggered reporting mode. However, to ensure handover reliability, it is recommended that the system reports only the cells whose BSIC is decoded correctly, that is, the recommended value of the parameter is "REQUIRED". If the parameter is set to "NOT_REQUIRED", handovers are likely to be triggered, but the handover reliability is lower than that in the situation the parameter is set to "REQUIRED".ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)ADD UCELLINTERRATHONCOV(Optional)MOD UCELLINTERRATHONCOV(Optional)

Impact on network performance:If the parameter is set to a smaller value, the UE cannot finish inter-RAT handover. If the parameter is set to a larger value, the compressed mode will not be disabled, thus affecting UE measurement. In actual networks, statistics can be made to obtain the delay for a successful inter-RAT handover, thus to get a proper value of "InterRATMeasTime" that satisfies most UEs.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)ADD UCELLINTERRATHONCOV(Optional)MOD UCELLINTERRATHONCOV(Optional)ADD UCELLINTERRATHONCOV(Optional)MOD UCELLINTERRATHONCOV(Optional)

Interval between the handover re-attempts for event 3C. This parameter specifies the interval between the handover re-attempts for event 3C. If this parameter is set to a smaller value, handover re-attempts increase when the inter-RAT handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced, thus lowering the probability of call drops. More handover re-attempts, however, cause the increase in the RNC load.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)Maximum number of handover re-attempts for event 3C. This parameter specifies the maximum number of handover attempts for event 3C when the measurement control message is valid. If this parameter is set to a greater value, the number of inter-RAT handover re-attempts increases and the possibility of successfully handing over the UE to the target cell whose load becomes normal increases. After reaching the value specified by this parameter, the RNC makes no further handover attempt to the target cell. If the compressed mode is disabled, the handover re-attempt will be aborted.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)Maximum number of inter-RAT handover failures allowed due to physical channel failure. When the number of inter-RAT handover failures due to physical channel failure exceeds the threshold, a penalty is given to the UE. During the time specified by "PenaltyTimeForInterRatPhyChFail[/para], the UE is not allowed to make inter-RAT handover attempts.For details about the physical channel failure, see 3GPP TS 25.331.ADD UCELLINTERRATHONCOV(Optional)

MOD UCELLINTERRATHONCOV(Optional)Duration of the penalty for inter-RAT handover failure due to physical channel failure. The UE is not allowed to make inter-RAT handover attempts within the penalty time.For details about the physical channel failure, see 3GPP TS 25.331.RMV UCELLINTRAFREQHO(Mandatory)

MOD UCELLINTRAFREQHO(Mandatory)RMV UCELLINTRAFREQHO(Mandatory)MOD UCELLINTRAFREQHO(Mandatory)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)

The input measurement value to L3 filter has been filtered by L1 filter, where the impact of fast fading is almost eliminated. In this case, smooth filtering should be applied through L3 filter, to eliminate the effect of shadow fading and peaks caused by fast fading, thus the filtered measurement value can reflect the variation of the actual measurement value, and provide more reliable measurement result for event judgement.Note that this parameter has great impact on the overall performance of the handover. Therefore, set this parameter with caution.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)

Relative threshold for event 1A decision when VP service is performed. If this parameter is set to a greater value, the probability of triggering event 1A increases. If this parameter is set to a smaller value, the probability of triggering event 1A reduces. For details on the definition of event 1A, see 3GPP TS 25.331.The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. you are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied.If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. you are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)Relative threshold for event 1A decision when PS service is performed. If this parameter is set to a greater value, the probability of triggering event 1A increases. If this parameter is set to a smaller value, the probability of triggering event 1A reduces. For details on the definition of event 1A, see 3GPP TS 25.331. The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. You are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)Relative threshold for event 1B decision when VP service is performed. If this parameter is set to a smaller value, the probability of triggering event 1B increases. If this parameter is set to a greater value, the probability of triggering event 1B reduces. For details on the definition of event 1B, see 3GPP TS 25.331. The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. You are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)Relative threshold for event 1B decision when non-VP service is performed in CS domain. If this parameter is set to a smaller value, the probability of triggering event 1B increases. If this parameter is set to a greater value, the probability of triggering event 1B reduces. For details on the definition of event 1B, see 3GPP TS 25.331. The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. You are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)Relative threshold for event 1B decision when PS service is performed. If this parameter is set to a smaller value, the probability of triggering event 1B increases. If this parameter is set to a greater value, the probability of triggering event 1B reduces. For details on the definition of event 1B, see 3GPP TS 25.331. The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. You are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)Ec/No absolute threshold for event 1F in the SHO algorithm. This parameter must be set to the value that guarantees the quality of basic services. In addition, the value of this parameter affects event 1F triggering. Event 1F refers to the event reported when an urgent blind handover is triggered. If event 1F is reported in a cell belonging to the active set, the signal quality of the active set is poor. Under this situation, blind handover is triggered to prevent call drops. The urgent blind handover is triggered in a special occasion that requires on-site measurements on the pilot strength and signal quality in the best cell of the cell where the UE is located. Generally, this function need not be enabled, so the parameter is set to the lowest value by default, indicating that the blind handover is not triggered.If this parameter is set to a greater value, the probability of triggering event 1F increases. If this parameter is set to a smaller value, the probability of triggering event 1F reduces. For details on the definition of event 1F, see 3GPP TS 25.331.If this parameter is set to a greater value, the probability of triggering blind handover increases. If this parameter is set to a smaller value, the probability of triggering blind handover reduces. In actual scenarios, this parameter should be set according to the handover strategy and network coverage.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)RSCP absolute threshold for event 1F in the SHO algorithm. This parameter must be set to the value that guarantees the quality of basic services. In addition, the value of this parameter affects event 1F triggering. Event 1F refers to the event reported when an urgent blind handover is triggered. If event 1F is reported in a cell belonging to the active set, the signal quality of the active set is poor. Under this situation, blind handover is triggered to prevent call drops.The urgent blind handover is triggered in a special occasion that requires on-site measurements on the pilot strength and signal quality in the best cell of the cell where the UE is located. Generally, this function need not be enabled, so the parameter is set to the lowest value by default, indicating that the blind handover is not triggered.If this parameter is set to a greater value, the probability of triggering event 1F increases. If this parameter is set to a smaller value, the probability of triggering event 1F reduces. For details on the definition of event 1F, see 3GPP TS 25.331.If this parameter is set to a greater value, the probability of triggering blind handover increases. If this parameter is set to a smaller value, the probability of triggering blind handover reduces. In actual scenarios, this parameter should be set according to the handover strategy and network coverage.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)

Setting an appropriate triggering delay effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.If the handover cannot be triggered in time, the time-to-trigger parameter for event 1A needs to be changed to 200 ms or 100 ms, and the delay for event 1B needs to be changed to 1280 ms or 2560 ms. If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)Setting an appropriate interval time effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.If the handover cannot be triggered in time, the time-to-trigger parameter for event 1A needs to be changed to 200 ms or 100 ms, and the delay for event 1B needs to be changed to 1280 ms or 2560 ms.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)- reducing the impact of shadow fading on event decisions.Setting an appropriate interval time effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.ADD UCELLINTRAFREQHO(Optional)



MOD UCELLINTRAFREQHO(Optional)- reducing the impact of shadow fading on event decisions.Setting an appropriate interval time effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.

UCELLINTRAFREQHO SHOQualmin Min Quality THD for SHO

UCELLINTRAFREQHO MaxCellInActiveSet Max Number of Cell in Active Maximum number of cells in an a

UCELLINTRAFREQHO BlindHORSCP1FThreshold Event 1F Blind Handover Trigg

UCELLLDB CellId Cell ID ID of a cell. For detailed inf

UCELLLDB PCPICHPowerPace Pilot power adjustment step Pilot power adjustment step inc

UCELLLDB CellOverrunThd Cell overload threshold If the cell downlink load excee

UCELLLDB CellUnderrunThd Cell under load threshold If the cell downlink load is low

UCELLLDM CellId Cell ID ID of a cell. For detailed inf

UCELLLDM UlLdrTrigThd UL LDR trigger threshold If the ratio of UL load of the

UCELLLDM UlLdrRelThd UL LDR release threshold If the ratio of UL load of the

UCELLLDM DlLdrTrigThd DL LDR trigger threshold If the ratio of DL load of the

UCELLLDM DlLdrRelThd DL LDR release threshold If the ratio of DL load of the

UCELLLDM UlOlcTrigThd UL OLC trigger threshold If the ratio of UL load of the

UCELLLDM UlOlcRelThd UL OLC release threshold If the ratio of UL load of the

UCELLLDM DlOlcTrigThd DL OLC trigger threshold If the ratio of DL load of the

UCELLLDM DlOlcRelThd DL OLC release threshold If the ratio of DL load of the

UCELLLDM DlLdTrnsHysTime DL State Trans Hysteresis thr If the DL load state of the cell

UCELLLDM HsupAuRetrnsLdTrigThd HSUPA auto retransmit load tri HSUPA auto retransmit load tri

UCELLLDM HsupAuRetrnsLdRelThd HSUPA auto retransmit load re HSUPA auto retransmit load re

UCELLLDR CellId Cell ID ID of a cell. For detailed inf

UCELLLDR DlLdrFirstAction DL LDR first action

UCELLLDR DlLdrSecondAction DL LDR second action This parameter has the same co

UCELLLDR DlLdrThirdAction DL LDR third action This parameter has the same co

UCELLLDR DlLdrFourthAction DL LDR fourth action This parameter has the same co

UCELLLDR DlLdrFifthAction DL LDR fifth action This parameter has the same co

UCELLLDR DlLdrSixthAction DL LDR sixth action This parameter has the same co

UCELLLDR DlLdrSeventhAction DL LDR seventh action This parameter has the same co

UCELLLDR DlLdrEighthAction DL LDR eighth action This parameter has the same co

UCELLLDR DlLdrNinthAction DL LDR ninth action This parameter has the same co

UCELLLDR DlLdrTenthAction DL LDR tenth action This parameter has the same co

UCELLLDR DlLdrBERateReductionRabNu DL LDR-BE rate reduction RA Number of RABs selected in a DL

UCELLLDR DlLdrPsRTQosRenegRabNum DL LDR un-ctrl RT Qos re-ne Number of RABs selected in a D

UCELLLDR DlCSInterRatShouldBeHOUe DL CS should be HO user num Number of users selected in a

UCELLLDR DlPSInterRatShouldBeHOUe DL PS should be HO user num Number of users selected in a

UCELLLDR DlLdrAMRRateReductionRab DL LDR-AMR rate reduction The mechanism of the LDR is th

UCELLLDR DlCSInterRatShouldNotHOU DL CS should not be HO user Number of users selected in a

UCELLLDR DlPSInterRatShouldNotHOUe DL PS should not be HO user Number of users selected in a

UCELLLDR UlLdrFirstAction UL LDR first action

UCELLLDR UlLdrSecondAction UL LDR second action This parameter has the same co

UCELLLDR UlLdrThirdAction UL LDR third action This parameter has the same co

UCELLLDR UlLdrFourthAction UL LDR fourth action This parameter has the same co

UCELLLDR UlLdrFifthAction UL LDR fifth action This parameter has the same co

UCELLLDR UlLdrSixthAction UL LDR sixth action This parameter has the same co

UCELLLDR UlLdrSeventhAction UL LDR seventh action This parameter has the same co

UCELLLDR UlLdrEighthAction UL LDR eighth action This parameter has the same co

UCELLLDR UlLdrBERateReductionRabNu UL LDR-BE rate reduction RA Number of RABs selected in a UL

UCELLLDR UlLdrPsRTQosRenegRabNum UL LDR un-ctrl RT Qos re-ne Number of RABs selected in a U

UCELLLDR UlCSInterRatShouldBeHOUe UL CS should be HO user num Number of users selected in a

UCELLLDR UlPSInterRatShouldBeHOUe UL PS should be HO user num Number of users selected in a

UCELLLDR UlLdrAMRRateReductionRab UL LDR-AMR rate reduction The mechanism of the LDR is th

UCELLLDR UlCSInterRatShouldNotHOU UL CS should not be HO user Number of users selected in a

UCELLLDR UlPSInterRatShouldNotHOUe UL PS should not be HO user Number of users selected in a

UCELLLDR UlInterFreqHoCellLoadSpace UL HO load space threshold The inter-frequency neighboring

UCELLLDR DlInterFreqHoCellLoadSpace DL HO load space threshold The inter-frequency neighboring

UCELLLDR UlInterFreqHoBWThd UL HO maximum bandwidth The UE can be selected to proc

UCELLLDR DlInterFreqHoBWThd DL HO maximum bandwidth The UE can be selected to proc

UCELLLDR MbmsDecPowerRabThd MBMS descend power rab thre When the priority of the RAB o

UCELLLDR CellLdrSfResThd Cell LDR SF reserved threshol This parameter specifies the Ce

UCELLLDR LdrCodePriUseInd LDR code priority indicator FALSE means not considering the

UCELLLDR MaxUserNumCodeAdj Max user number of code adju This parameter specifies the n

UCELLLDR UlLdrCreditSfResThd Ul LDR credit SF reserved thr Reserved SF threshold in uplink

ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)

Impact on network performance:This parameter should be adjusted, based on the planned Ec/No that the cell soft handover area is expected to reach. If this parameter is set to a greater value, the probability for adding a neighboring cell to the active set decreases. In this case, the service quality of the cell to be added is guaranteed. If this parameter is set to a smaller value, the probability for adding a neighboring cell to the active set increases. In this case, however, the service quality of the cell to be added is not guaranteed.ADD UCELLINTRAFREQHO(Optional)

MOD UCELLINTRAFREQHO(Optional)ADD UCELLINTRAFREQHO(Optional)MOD UCELLINTRAFREQHO(Optional)

Threshold of the quality of the cell reporting event 1F for triggering blind handover. The blind handover is triggered only when the signal quality in the cell, which reports event 1F, exceeds this parameter. Otherwise, the report is discarded. This parameter is used to raise the success rate of blind handovers. If all the signals in the cell reporting event 1F are of poor quality, the user may be located at the edge of coverage area. Under this situation, triggering blind handover rashly may cause call drops.MOD UCELLLDB(Mandatory)

RMV UCELLLDB(Mandatory)ADD UCELLLDB(Optional)MOD UCELLLDB(Optional)ADD UCELLLDB(Optional)MOD UCELLLDB(Optional)ADD UCELLLDB(Optional)MOD UCELLLDB(Optional)MOD UCELLLDM(Mandatory)RMV UCELLLDM(Mandatory)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)ADD UCELLLDM(Optional)MOD UCELLLDM(Optional)MOD UCELLLDR(Mandatory)RMV UCELLLDR(Mandatory)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)

The inter-frequency load handover has no impact on the QoS of users and can balance the cell load, so the inter-frequency load handover usually serves as the first action.The BE service rate reduction is effective only when the DCCC algorithm is enabled.ADD UCELLLDR(Optional)

MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)

The inter-frequency load handover has no impact on the QoS of users and can balance the cell load, so the inter-frequency load handover usually serves as the first action.The BE service rate decreasing is effective only when the DCCC algorithm is enabled.ADD UCELLLDR(Optional)

MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)

UCELLLDR DlLdrCreditSfResThd Dl LDR credit SF reserved thr Reserved SF threshold in downl

UCELLLDR LdrCodeUsedSpaceThd InterFreq HO code used ratio Code resource usage difference

UCELLLDR CodeCongSelInterFreqHoInd Code congestion select inter-fr This switch is valid only when

UCELLLDR GoldUserLoadControlSwitch Gold user load control switch Indicates whether gold users in

UCELLLDR InterFreqLdHoForbidenTC Forbidden Traffic Class for int This parameter specifies the fo

UCELLLDR UlTtiCreditSfResThd Ul TTI HO Credit SF reserved The threshold of the reserved SF

UCELLLDR InterFreqLDHOMethodSelecti InterFreq Load Handover Meth This parameter specifies loa

UCELLMBDRINTERFREQ CellId Cell ID Unique ID of a cell

UCELLMBDRINTERFREQ InterFreqActiveType MBDR Switch MBDR switch

UCELLMBDRINTERFREQ InterFreqUlMbdrTrigThreshold UL Theshold This parameter is the relative

UCELLMBDRINTERFREQ InterFreqDlMbdrTrigThreshold DL Theshold This parameter is the relative

UCELLMBDRINTERFREQ InterFreqFilterCoef Inter-frequency Measure Filter

UCELLMBDRINTERFREQ InterFreqReportMode Inter-frequency Measure Repo

UCELLMBDRINTERFREQ InterFreqMeasQuantity Inter-freq Measure Quantity

UCELLMBDRINTERFREQ PrdReportInterval Inter-frequency Measure Perio

UCELLMBDRINTERFREQ TimeToTrigForPrdInterFreq HHO Period Trigger Delay

UCELLMBDRINTERFREQ HystForPrdInterFreq HHO Hysteresis

UCELLMBDRINTERFREQ Hystfor2C 2C Hysteresis

UCELLMBDRINTERFREQ TrigTime2C Event 2C Trigger Delay

UCELLMBDRINTERFREQ HOThdEcN0 Inter-freq measure target freq

UCELLMBDRINTERFREQ HOThdRscp Inter-freq measure target fre

UCELLMBDRINTERFREQ MaxAttNum Inter-Freq DRD Max Attempt T

UCELLMBDRINTERFREQ InterFreqMeasTime Inter-freq Measure Timer Leng

UCELLMBDRINTERRAT CellId Cell ID Unique ID of a cell

UCELLMBDRINTERRAT InterRatActiveType MBDR switch MBDR switch

UCELLMBDRINTERRAT InterRatUlMbdrTrigThreshold UL Theshold This parameter is the relative

UCELLMBDRINTERRAT InterRatDlMbdrTrigThreshold DL Theshold This parameter is the relative

UCELLMBDRINTERRAT InterRATFilterCoef Inter-RAT Filter Coefficient

UCELLMBDRINTERRAT InterRatReportMode Inter-RAT Report Mode

UCELLMBDRINTERRAT InterRATPeriodReportInterval Inter-RAT Period Reporting Int

UCELLMBDRINTERRAT BSICVerify BSIC Verify Switch

UCELLMBDRINTERRAT TimeToTrigForNonVerify Time to Trigger Handover to N

UCELLMBDRINTERRAT TimeToTrigForVerify Time to Trigger Handover to V

UCELLMBDRINTERRAT Hystfor3C 3C Hysteresis

UCELLMBDRINTERRAT TrigTime3C Event 3C Trigger Delay

UCELLMBDRINTERRAT InterRATHOThd Inter-RAT CS Handover Decis

UCELLMBDRINTERRAT MaxAttNum Inter-RAT DRD Max Attempt T This parameter specifies the m

UCELLMBDRINTERRAT UserPercentage UserPercentage

UCELLMBDRINTERRAT InterRATMeasTime Inter-RAT Measure Timer Leng

UCELLMBDRINTERRAT PenaltyTimer Inter-RAT Penalty timer length Strech for penalty of inter-RAT

UCELLMBMSFACH CellId Cell ID ID of a cell. For detailed inf

UCELLMBMSFACH ServiceType Service Type This parameter specifies the t

UCELLMBMSFACH ServiceBitRate Service Bit Rate This parameter specifies the r

UCELLMBMSFACH FachMaxPower Fach Max Power ADD UCELLMBMSFACH(OptioThis parameter specifies the m

UCELLMBMSFACH MtchMinPerc0 Mtch Minimal Power Percent forADD UCELLMBMSFACH(OptioThis parameter specifies the m

UCELLMBMSFACH MtchMinPerc15 Mtch Minimal Power Percent forADD UCELLMBMSFACH(OptioThis parameter specifies the m

UCELLMBMSFACH ToAWS Time of Arrival Window StartpoADD UCELLMBMSFACH(OptioStart point of the arrival windo

UCELLMBMSFACH ToAWE Time of Arrival Window Endpoi ADD UCELLMBMSFACH(OptioEnd point of the arrival window

UCELLMBMSPARA CellId Cell ID ID of a cell. For detailed inf

UCELLMBMSPARA MbmsTransMode Mbms Transfer Mode This parameter specifies the t

UCELLMBMSPARA NCountingThd Counting Threshold When the number of UEs respond

UCELLMBMSPARA NPtpToPtmOffset Ptp To Ptm Offset

UCELLMBMSSA CellId Cell ID ID of a cell. For detailed inf

UCELLMBMSSA CnOpIndex Cn Operator Index ADD UCELLMBMSSA(MandatoRepresent an index for a CN o

UCELLMBMSSA MbmsSaId MBMS SA ID MBMS SA ID. For detailed infor

UCELLMBMSSCCPCH CellId Cell ID ID of a cell. For detailed inf

UCELLMBMSSCCPCH ServiceType Service Type This parameter specifies the t

UCELLMBMSSCCPCH ServiceBitRate Service Bit Rate This parameter specifies the r

UCELLMBMSSCCPCH STTDInd STTD Indicator This parameter indicates wheth

UCELLMCCH CellId Cell ID ID of a cell. For detailed inf

UCELLMCCH MichId MICH ID ADD UCELLMCCH(Mandatory Physical channel ID of the MI

ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)ADD UCELLLDR(Optional)MOD UCELLLDR(Optional)MOD UCELLMBDRINTERFREQ(Mandatory)RMV UCELLMBDRINTERFREQ(Mandatory)ADD UCELLMBDRINTERFREQ(Optional)MOD UCELLMBDRINTERFREQ(Optional)ADD UCELLMBDRINTERFREQ(Optional)MOD UCELLMBDRINTERFREQ(Optional)ADD UCELLMBDRINTERFREQ(Optional)MOD UCELLMBDRINTERFREQ(Optional)ADD UCELLMBDRINTERFREQ(Optional)MOD UCELLMBDRINTERFREQ(Optional)

This parameter specifies the Layer 3 filter coefficient for the inter-frequency measurementThis parameter has the same physical significance and measurement model as the layer 3 filter coefficient for the intra-frequency measurement. The difference is that the report period of the inter-frequency measurement is 480 ms while the report period of the intra-frequency measurement is 200 ms. In practice, the setting of this parameter can be adjusted according to performance statistics.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)- Periodical report modeWhen the quality of the inter-frequency cell reported by the UE meets the criteria for inter-frequency handover, the delay trigger timer is started. If the quality of the cell always meets the criteria for inter-frequency handover before timeout, the inter-frequency handover is triggered after the delay trigger timer expires.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)- CPICH_RSCP: to use the RSCP measurement quantity for event 2C or Inter-Frequency periodical measurement. The physical unit is dBm. - BOTH:both quantities of the target cell must be satisfied when performing the handover judgement.Valid when the Inter-Frequency measurement chooses PERIODICAL_REPORTING Mode. Recommended value (default value): BOTH(PERIODICAL_REPORTING Mode), CPICH_RSCP(EVENT_TRIGGER Mode)ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)Interval between periodic reporting for the inter-frequency handover. In periodic reporting mode, the inter-frequency handover attempts is reported at the preset interval. It is not recommended that this parameter be set to "NON_PERIODIC_REPORT" since the UE behavior may be unknown. This parameter has impact on the Uu signaling flow. If the interval is too short and the frequency is too high, the RNC may have high load when processing signaling. If the interval is too long, the network cannot detect the signal changes in time. This may delay the inter-frequency handover, thus causing call drops.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)Interval between reception of periodical reports and triggering of the inter-frequency handover. Only the inter-frequency cell in which the signal quality is above a certain threshold in all periodic reports during a time equal to this parameter can be selected as the target cell for the inter-frequency handover. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)Hysteresis in the inter-frequency hard handover triggered by the periodic measurement report.This parameter is used to estimate the inter-frequency handover on the RNC side. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change and thus the handover may not be triggered in time.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)Hysteresis used for event 2C.The value of this parameter is associated with the slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change and thus event 2C may not be triggered in time.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change.The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)If the mode is set to event mode, this parameter is used to set measurement control on the event 2C.If the mode is set to periodical mode, this parameter is used to estimate the periodical reports and only if quality of the target frequency is beyond the threshold, the DRD procedure is triggered.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)If the mode is set to event mode, this parameter is used to set measurement control on the event 2C.If the mode is set to periodical mode, this parameter is used to estimate the periodical reports and only if quality of the target frequency is beyond the threshold, the DRD procedure is triggered.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)The maximum number of attempts to perform inter-freq handoversThis parameter specifies the maximum number of attempts for the RNC to perform inter-freq handover after inter-freq handover failure. The handover attempts should involve the cells that have not been tried but satisfy the handover conditions.ADD UCELLMBDRINTERFREQ(Optional)

MOD UCELLMBDRINTERFREQ(Optional)After inter-frequency measurement starts, if no inter-frequency handover is performed when this timer expires, the inter-frequency measurement is stopped. In addition, the compressed mode is deactivated, if any. The value 0 indicates that the timer is not to be enabled. This parameter is used to prevent the long inter-frequency measurement state (compressed mode) due to unavailable measurement of the target cells that meet the handover requirements.MOD UCELLMBDRINTERRAT(Mandatory)

RMV UCELLMBDRINTERRAT(Mandatory)ADD UCELLMBDRINTERRAT(Optional)MOD UCELLMBDRINTERRAT(Optional)ADD UCELLMBDRINTERRAT(Optional)MOD UCELLMBDRINTERRAT(Optional)ADD UCELLMBDRINTERRAT(Optional)MOD UCELLMBDRINTERRAT(Optional)ADD UCELLMBDRINTERRAT(Optional)MOD UCELLMBDRINTERRAT(Optional)

In cells where the average moving speed of UEs is medium, there is a comparatively smaller shadow fading square error. Therefore, the recommended value is 3. In cells where the average moving speed of UEs is high, there is a comparatively small shadow fading square error. Therefore, the recommended value is 2.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)When the quality of the GSM cell reported by the UE meets the criteria for inter-RAT handover, the delay trigger timer is started. If the quality of the GSM cell always meets the criteria for inter-RAT handover before timeout, the inter-RAT handover is triggered after the delay trigger timer expires.For the GSM cell whose BSIC can be decoded correctly, a shorter delay trigger time should be set to indicate the high priority attribute of the GSM cell. For the GSM cell whose BSIC is not verified, a longer delay trigger time should be set to indicate the low priority attribute of the GSM cell. In this manner, the BSIC can be decoded faster.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)The adjustment should be made according to the configured GSM RSSI measurement compressed mode sequence. According to the current configured GSM RSSI measurement compressed mode sequence, the RSSI measurement of eight GSM cells can be finished in 480 ms. Therefore, the RSSI measurement of 16 GSM cells can be finished in 1000 ms. According to 3GPP specifications, the number of inter-RAT neighboring cells should not exceed 32. Therefore, the parameter value can be set to 2000 ms if the number of neighboring GSM cells exceeds 16.The setting of this parameter has impact on the Uu signaling traffic. If the period is too short and the reporting frequency is too high, the RNC may have high load in processing signaling. If the period is too long, the network cannot detect the signal changes in time, which may delay the inter-RAT handover and thus cause call drops.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)Switch for verifying the Base Station Identity Code (BSIC). This parameter is used to control cells where inter-RAT measurement reports are triggered. When the parameter is set to "REQUIRED", the measurement reporting is triggered after the BSIC of the measured cell is decoded correctly. When the parameter is set to "NOT_REQUIRE", the measurement reporting is triggered regardless of whether the BSIC of the measured cell is decoded correctly. This parameter is valid for both periodical reporting mode and event-triggered reporting mode. However, to ensure handover reliability, it is recommended that the system reports only the cells whose BSIC is decoded correctly, that is, the recommended value of the parameter is "REQUIRED". If the parameter is set to "NOT_REQUIRED", handovers are likely to be triggered, but the handover reliability is lower than that in the situation the parameter is set to "REQUIRED".ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)Time delay for triggering handovers to GSM cells with non-verified BSIC.During the period of time specified by this parameter, if the signal quality in a neighboring GSM cell fulfills inter-RAT handover criteria and the neighboring GSM cell is not verified, an inter-RAT handover is triggered. When this parameter value is 65535, the RNC does not perform inter-RAT handovers to non-verified GSM cells. If this parameter is set to a larger value, the average number of handovers decreases, but call drops may occur.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)Considering that the UE is on the edge of the system, this parameter should be set to a comparatively low value. In situations where a GSM cell is verified, the performance of the GSM cell is generally regarded as good. In this case, the parameter can be set to 0, which indicates that the handover is performed immediately.If this parameter is set to a larger value, the average number of handovers decreases, but call drops may occur.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)The value of this parameter is associated with the slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change. If this parameter is set to a too large value, the cell of another RAT where the UE needs to be handed over to must be of good quality. Therefore, the criterion for triggering the inter-RAT handover decision is hard to be fulfilled, and the call drop rate increases. The emulation result shows that in a cell where the average moving speed of UEs is high (for example, a cell that covers highways), this parameter can be set to a smaller value 1.5 dB, because in the cell the terrain is flat, barriers are fewer, and thus the shadow fading variation is small. In a cell where the average moving speed of UEs is low, this parameter can be set to a larger value 3.0 dB, because there are usually many tall buildings and thus the shadow fading variation is comparatively high.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)The inter-frequency measurement reporting period is 480 ms. Therefore, the trigger delay time shorter than 480 ms is invalid. If the parameter is set to a larger value, handover is unlikely to be triggered. However, call drops may increase as the parameter value increases.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)The sensitivity of a GSM mobile phone is -102 dBm, so the outdoor reception level should not be lower than -90 dBm, considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise.The values of inter-RAT handover decision thresholds vary with the handover policy. To have UEs hand over only to the GSM cells with high quality, you can set the inter-RAT handover decision threshold to a comparatively high value, for example -85 dBm.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)ADD UCELLMBDRINTERRAT(Optional)MOD UCELLMBDRINTERRAT(Optional)

The ratio of the users which could launch the handover to inter-RAT neighbour cell.When the parameter is ALL_USER, it means all of the users could be handover to the inter-RAT neighbour cell. When the parameter is HALF, it means only 1/2 of the users could be handover to the inter-RAT neighbour cell. When the parameter is THIRD, it means only 1/3 of the users could be handover to the inter-RAT neighbour cell. When the parameter is QUARTER, it means only 1/4 of the users could be handover to the inter-RAT neighbour cell.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)As for the impact on network performance,If the InterRATMeasTime is excessively low, the UE cannot finish inter-RAT handovers. If InterRATMeasTime is excessively high, it cannot help improve the service quality. In actual networks, statistics can be made to obtain the delay for a successful inter-RAT handover so as to get a proper value of InterRATMeasTime that satisfies most UEs. If the parameter is set to a great value, the services may not be set up successfully.ADD UCELLMBDRINTERRAT(Optional)

MOD UCELLMBDRINTERRAT(Optional)ADD UCELLMBMSFACH(Mandatory)RMV UCELLMBMSFACH(Mandatory)ADD UCELLMBMSFACH(Mandatory)RMV UCELLMBMSFACH(Mandatory)ADD UCELLMBMSFACH(Mandatory)RMV UCELLMBMSFACH(Mandatory)

MOD UCELLMBMSPARA(Mandatory)RMV UCELLMBMSPARA(Mandatory)ADD UCELLMBMSPARA(Optional)MOD UCELLMBMSPARA(Optional)ADD UCELLMBMSPARA(Optional)MOD UCELLMBMSPARA(Optional)ADD UCELLMBMSPARA(Optional)MOD UCELLMBMSPARA(Optional)

This parameter specifies the NPTP-PTM offset. During recounting in PTP mode, if the number of PTP users is larger than or equal to NPTP-PTM, the transmission mode transits to PTM. The value of NPTP-PTM = "Counting Threshold" + "Ptp To Ptm Offset". The transition between PTP and PTM affects user experience. Thus, to minimize ping-pong effect, the transition between PTP and PTM uses a threshold other than "Counting Threshold". The two thresholds are used only to avoid ping-pong effect, so the difference between the two should not be too large. Because the value of "Counting Threshold" is small, it is recommended that the default value of this parameter be used.ADD UCELLMBMSSA(Mandatory)

RMV UCELLMBMSSA(Mandatory)

ADD UCELLMBMSSA(Mandatory)RMV UCELLMBMSSA(Mandatory)MOD UCELLMBMSSCCPCH(Mandatory)RMV UCELLMBMSSCCPCH(Mandatory)MOD UCELLMBMSSCCPCH(Mandatory)RMV UCELLMBMSSCCPCH(Mandatory)MOD UCELLMBMSSCCPCH(Mandatory)RMV UCELLMBMSSCCPCH(Mandatory)ADD UCELLMBMSSCCPCH(Optional)MOD UCELLMBMSSCCPCH(Optional)MOD UCELLMCCH(Mandatory)RMV UCELLMCCH(Mandatory)

UCELLMCCH MichPower MICH Power TX power of the MICH. The grea

UCELLMCCH MichSttdInd MICH STTD Indicator The value indicates whether th

UCELLMCCH PhyChIdforMcch SCCPCH ID for MCCH ADD UCELLMCCH(Mandatory ID of the physical channel ca

UCELLMCCH FachIdforMcch FACH ID for MCCH ADD UCELLMCCH(Mandatory ID of the transport channel ca

UCELLMCCH FlcAlgoSwitch Flc Algo Switch Switch of the FLC algorithm. T

UCELLMCDRD CellId Cell ID Unique ID of a cell

UCELLMCDRD BlindDrdExceptHRetrySwitch Aperiodic DRD Retry Switch

UCELLMCDRD HRetryTimerLength DRD Measurement Period Retr Specifies the time length of th

UCELLMCDRD PrdReportInterval Inter-Frequency Periodic Meas

UCELLMCDRD TargetFreqThdRscp Target Frequency RSCP Trigge RSCP Threshold for the target c

UCELLMCDRD TargetFreqThdEcN0 Target Frequency EcNo Trigge Ec/No Threshold for the target

UCELLMCDRD DrdFaiPenaltyPeriodNum DRD Measurement Failure Pun Number of retry periods in the

UCELLMCLDR CellId Cell ID Unique ID of a cell

UCELLMCLDR InterFreqMeasTime Inter-freq Measure Timer Leng

UCELLMCLDR PrdReportInterval Inter-freq Measure Periodical

UCELLMCLDR TargetFreqThdRscp Inter-freq Target Frequency Estimate the signal quality of

UCELLMCLDR TargetFreqThdEcN0 Inter-freq Target Frequency T Estimate the signal quality of

UCELLMEAS CellId Cell ID ID of a cell. For detailed inf

UCELLMEAS IntraFreqMeasInd Intra-freq Meas Ctrl Info Ind Indicating whether the intra-f

UCELLMEAS InterFreqInterRatMeasInd Inter-freq and Inter-RAT Meas C Indicating whether the inter-f

UCELLMEAS FACHMeasInd FACH Measurement Indicator Whether the UE in the CELL_

UCELLNAME RNCId RNC ID MOD UCELLNAME(Optional) ID of an RNC

UCELLNAME CellId Cell ID MOD UCELLNAME(MandatoryID of a cell. For detailed inf

UCELLNAME CellName Cell Name MOD UCELLNAME(MandatoryIdentifying a cell name

UCELLNFREQPRIOINFO CellId Cell ID ID of a cell. For detailed inf

UCELLNFREQPRIOINFO EARFCN E-UTRA Absolute Radio Freq E-UTRA Absolute Radio Freque

UCELLNFREQPRIOINFO NPriority Absolute Priority Level of th

UCELLNFREQPRIOINFO ThdToHigh RSRP Threshold for High-prio-

UCELLNFREQPRIOINFO ThdToLow RSRP Threshold for Low-prio-f

UCELLNFREQPRIOINFO EMeasBW Measurement Bandwidth

UCELLNFREQPRIOINFO EQrxlevmin Minimum Required RSRP Thres

UCELLNFREQPRIOINFO EDetectInd E-UTRA Monitoring Indication

UCELLNFREQPRIOINFO BlacklstCellNumber Number of Cells in the Blackl

UCELLNFREQPRIOINFO BCellID1 ID of Cell 1 in the Blacklist
















UCELLOLC CellId Cell ID ID of a cell. For detailed inf

UCELLOLC DlOlcFTFRstrctTimes DL OLC fast TF restrict times

UCELLOLC UlOlcFTFRstrctTimes UL OLC fast TF restrict times

UCELLOLC DlOlcFTFRstrctRabNum DL OLC fast TF restrict RAB

UCELLOLC UlOlcFTFRstrctRabNum UL OLC fast TF restrict RAB

UCELLOLC RateRstrctCoef DL TF rate restrict coefficient DL fast TF restriction refers t

UCELLOLC RecoverCoef DL TF rate recover coefficient DL fast TF restriction refers t

UCELLOLC RateRstrctTimerLen DL TF rate restrict timer length DL fast TF restriction refers t

UCELLOLC RateRecoverTimerLen DL TF rate recover timer lengt DL fast TF restriction refers t

UCELLOLC DlOlcTraffRelRabNum DL OLC traff release RAB num

UCELLOLC UlOlcTraffRelRabNum UL OLC traff release RAB num

UCELLOLC SeqOfUserRel Sequence of user release ADD UCELLOLC(Optional) This parameter indicates whethe

ADD UCELLMCCH(Optional)MOD UCELLMCCH(Optional)ADD UCELLMCCH(Optional)MOD UCELLMCCH(Optional)

ADD UCELLMCCH(Optional)MOD UCELLMCCH(Optional)MOD UCELLMCDRD(Mandatory)RMV UCELLMCDRD(Mandatory)ADD UCELLMCDRD(Optional)MOD UCELLMCDRD(Optional)

If this parameter is set to "ON", the DRD retry for blind handover is performed in aperiodic mode.If this switch is set to "OFF", the DRD retry for blind handover is not performed in aperiodic mode.ADD UCELLMCDRD(Optional)

MOD UCELLMCDRD(Optional)ADD UCELLMCDRD(Optional)MOD UCELLMCDRD(Optional)

Interval between sending of periodic measurement reports.This parameter has impact on the Uu signaling flow. If this parameter is set to a small value, the RNC may have high load when processing signaling. If this parameter is set to a great value, the network cannot detect the signal changes in time. This may delay the inter-frequency handover.ADD UCELLMCDRD(Optional)

MOD UCELLMCDRD(Optional)ADD UCELLMCDRD(Optional)MOD UCELLMCDRD(Optional)ADD UCELLMCDRD(Optional)MOD UCELLMCDRD(Optional)MOD UCELLMCLDR(Mandatory)RMV UCELLMCLDR(Mandatory)ADD UCELLMCLDR(Optional)MOD UCELLMCLDR(Optional)

After inter-frequency measurement starts, if no inter-frequency handover is performed when this timer expires, the inter-frequency measurement and the compressed mode (if started) are stopped. This parameter is used to prevent the long inter-frequency measurement state (compressed mode) due to unavailable measurement of the target cells that meet the handover requirements.ADD UCELLMCLDR(Optional)

MOD UCELLMCLDR(Optional)The interval between two reports is the configured value. This parameter has impact on the Uu signaling flow. If the interval is too short and the frequency is too high, the RNC may have burden in processing signaling. If the interval is too long, the network cannot detect the signal change in time, which may delay the inter-frequency handover.ADD UCELLMCLDR(Optional)

MOD UCELLMCLDR(Optional)ADD UCELLMCLDR(Optional)MOD UCELLMCLDR(Optional)MOD UCELLMEAS(Mandatory)RMV UCELLMEAS(Mandatory)ADD UCELLMEAS(Optional)MOD UCELLMEAS(Optional)ADD UCELLMEAS(Optional)MOD UCELLMEAS(Optional)ADD UCELLMEAS(Optional)MOD UCELLMEAS(Optional)

MOD UCELLNFREQPRIOINFO(Mandatory)RMV UCELLNFREQPRIOINFO(Mandatory)MOD UCELLNFREQPRIOINFO(Mandatory)RMV UCELLNFREQPRIOINFO(Mandatory)ADD UCELLNFREQPRIOINFO(Mandatory)MOD UCELLNFREQPRIOINFO(Optional)

The greater the value of this parameter is, the easier the UE reselects a cell on this frequency, the smaller the value of this parameter is, the harder the UE reselects a cell on this frequency. For details on this parameter, see 3GPP TS 25.304.ADD UCELLNFREQPRIOINFO(Optional)

MOD UCELLNFREQPRIOINFO(Optional)The greater the value of this parameter is, the harder the UE reselects a cell on the target frequency, the smaller the value of this parameter is, the easier the UE reselects a cell on the target frequency.For details on this parameter, see 3GPP TS 25.304.ADD UCELLNFREQPRIOINFO(Optional)

MOD UCELLNFREQPRIOINFO(Optional)The greater the value of this parameter is, the harder the UE reselects a cell on the target frequency, the smaller the value of this parameter is, the easier the UE reselects a cell on the target frequency. For details on this parameter, see 3GPP TS 25.304.ADD UCELLNFREQPRIOINFO(Optional)

MOD UCELLNFREQPRIOINFO(Optional)In the UTRA system, the cell bandwidth is 5 MHz. For details on this parameter, see 3GPP TS 25.331.ADD UCELLNFREQPRIOINFO(Optional)

MOD UCELLNFREQPRIOINFO(Optional)The greater the value of this parameter is, the harder the UE reselects a cell on this frequency, the smaller the value of this parameter is, the easier the UE reselects a cell on this frequency. For details on this parameter, see 3GPP TS 25.304.ADD UCELLNFREQPRIOINFO(Optional)

MOD UCELLNFREQPRIOINFO(Optional)The value TRUE indicates that UEs in Idle mode can detect E-UTRA cells and report the result to the non-access stratum (NAS). For details on this parameter, see 3GPP TS 25.331.ADD UCELLNFREQPRIOINFO(Optional)

MOD UCELLNFREQPRIOINFO(Optional)Cells in the blacklist of the E-UTRA frequency are not used as target cells for cell reselection. For details on this parameter, see 3GPP TS 25.331.ADD UCELLNFREQPRIOINFO(Mandatory)

MOD UCELLNFREQPRIOINFO(Optional)Cell in the blacklist is not used as target cell for cell reselection. Physical cell ID are used to distinguish cell in the specified frequency. For details on this parameter, see 3GPP TS 36.331.ADD UCELLNFREQPRIOINFO(Mandatory)















MOD UCELLNFREQPRIOINFO(Optional)Cell in the blacklist is not used as target cell for cell reselection. Physical cell ID are used to distinguish cell in the specified frequency. For details on this parameter, see 3GPP TS 36.331.MOD UCELLOLC(Mandatory)

RMV UCELLOLC(Mandatory)ADD UCELLOLC(Optional)MOD UCELLOLC(Optional)

The mechanism of the OLC is that an action is performed in each [OLC period] and some services are selected based on the action rules to perform this action. This parameter defines the maximum number of downlink OLC fast TF restriction performed in entering/exiting the OLC status.After the overload is triggered, the RNC immediately executes OLC by first executing fast TF restriction. The internal counter is incremented by 1 with each execution. If the number of overloads does not exceed the OLC action threshold, the system lowers the BE service rate by lowering TF to relieve the overload. If the number of overloads exceeds the OLC action threshold, the previous operation has no obvious effect on alleviating the overload and the system has to release users to solve the overload problem. The lower the parameters are, the more likely the users are released, resulting in negative effect on the system performance. If the parameters are excessively high, the overload status is released slowly.ADD UCELLOLC(Optional)

MOD UCELLOLC(Optional)After the overload is triggered, the RNC immediately executes OLC by first executing fast TF restriction. The internal counter is incremented by 1 with each execution. If the number of overloads does not exceed the OLC action threshold, the system lowers the BE service rate by lowering TF to relieve the overload. If the number of overloads exceeds the OLC action threshold, the previous operation has no obvious effect on alleviating the overload and the system has to release users to solve the overload problem.The lower the parameters are, the more likely the users are released, resulting in negative effect on the system performance. If the parameters are excessively high, the overload status is released slowly.ADD UCELLOLC(Optional)

MOD UCELLOLC(Optional)The mechanism of the OLC is that an action is performed in each [OLC period] and some services are selected based on the action rules to perform this action. This parameter defines the maximum number of RABs selected in executing downlink OLC fast restriction.Selection of RABs of the OLC is based on the service priorities and ARP values and bearing priority indication. The RAB of low priority is under control. In the actual system, UlOlcFTFRstrctRabNum and DlOlcFTFRstrctRabNum can be set on the basis of the actual circumstances. If the high-rate subscribers occupy a high proportion, set UlOlcFTFRstrctRabNum and DlOlcFTFRstrctRabNum to comparatively low values. If the high-rate subscribers occupy a low proportion, set UlOlcFTFRstrctRabNum and DlOlcFTFRstrctRabNum to comparatively high values. The higher the parameters are, the more users are involved in fast TF restriction under the same conditions, the quicker the cell load decreases, and the more user QoS is affected.ADD UCELLOLC(Optional)

MOD UCELLOLC(Optional)Selection of RABs of the OLC is based on the service priorities and ARP values and bearing priority indication. The RAB of low priority is under control. In the actual system, UlOlcFTFRstrctRabNum and DlOlcFTFRstrctRabNum can be set on the basis of the actual circumstances. If the high-rate subscribers occupy a high proportion, set UlOlcFTFRstrctRabNum and DlOlcFTFRstrctRabNum to comparatively low values. If the high-rate subscribers occupy a low proportion, set UlOlcFTFRstrctRabNum and DlOlcFTFRstrctRabNum to comparatively high values.The higher the parameters are, the more users are involved in fast TF restriction under the same conditions, the quicker the cell load decreases, and the more user QoS is affected.ADD UCELLOLC(Optional)

MOD UCELLOLC(Optional)ADD UCELLOLC(Optional)MOD UCELLOLC(Optional)ADD UCELLOLC(Optional)MOD UCELLOLC(Optional)ADD UCELLOLC(Optional)MOD UCELLOLC(Optional)ADD UCELLOLC(Optional)MOD UCELLOLC(Optional)

The mechanism of the OLC is that an action is performed in each [OLC period] and some services are selected based on the action rules to perform this action. This parameter defines the maximum number of RABs released in executing downlink OLC service release.For the users of a single service, the releasing of RABs means the complete releasing of the users. The releasing of RABs causes call drops, so UlOlcFTFRstrctTimes or DlOlcFTFRstrctTimes should be set to a low value. Higher values of the parameter get the cell load to decrease more obviously, but the QoS will be affected.ADD UCELLOLC(Optional)

MOD UCELLOLC(Optional)The mechanism of the OLC is that an action is performed in each [OLC period] and some services are selected based on the action rules to perform this action. This parameter defines the maximum number of RABs released in executing uplink OLC service release.For the users of a single service, the releasing of RABs means the complete releasing of the users. The releasing of RABs causes call drops, so UlOlcFTFRstrctTimes or DlOlcFTFRstrctTimes should be set to a low value. Higher values of the parameter get the cell load to decrease more obviously, but the QoS will be affected.

UCELLOLC MbmsOlcRelNum MBMS services number releas ADD UCELLOLC(Optional)

UCELLOLC TransCchUserNum Transfer Common Channel Us

UCELLOLC FACHPwrReduceValue Fach power reduce value This parameter defines the re

UCELLPUC CellId Cell ID ID of a cell. For detailed inf

UCELLPUC SpucLight Load level division threshold 2

UCELLPUC SpucHeavy Load level division threshold 1

UCELLPUC SpucHyst Load level division hysteresis Hysteresis used to determine th

UCELLPUC OffSinterLight Sintersearch offset 1 Offset of Sintersearch when cen

UCELLPUC OffSinterHeavy Sintersearch offset 2 Offset of Sintersearch when cen

UCELLPUC OffQoffset1Light Qoffset1 offset 1 Offset of Qoffset1 when neighbor

UCELLPUC OffQoffset2Light Qoffset2 offset 1 Offset of Qoffset2 when neighbor

UCELLPUC OffQoffset1Heavy Qoffset1 offset 2 Offset of Qoffset1 when neighbor

UCELLPUC OffQoffset2Heavy Qoffset2 offset 2 Offset of Qoffset2 when neighbor

UCELLQOSHO CellId Cell ID Unique ID of a cell

UCELLQOSHO DlRscpQosHyst Down Link RSCP Used-Freq T

UCELLQOSHO DLQosMcTimerLen Down Link Qos Measure Timer

UCELLQOSHO ULQosMcTimerLen Up Link Qos Measure Timer L

UCELLQOSHO UsedFreqMeasQuantityForQo 3A Used-Freq Measure Quantit

UCELLQUALITYMEAS CellId Cell ID ID of a cell. For detailed inf

UCELLQUALITYMEAS UlAmrTrigTime6A1 AMR Trigger Time 6A1 Duration when the measured val

UCELLQUALITYMEAS UlAmrTrigTime6A2 AMR Trigger Time 6A2 Duration when the measured val

UCELLQUALITYMEAS UlAmrTrigTime6B1 AMR Trigger Time 6B1 Duration when the measured val

UCELLQUALITYMEAS UlAmrTrigTime6B2 AMR Trigger Time 6B2 Duration when the measured val

UCELLQUALITYMEAS UlAmrTrigTime6D AMR Trigger Time 6D Duration when the measured val

UCELLQUALITYMEAS UlVpTrigTime6A1 VP Trigger Time 6A1 Duration when the measured val

UCELLQUALITYMEAS UlVpTrigTime6B1 VP Trigger Time 6B1 Duration when the measured val

UCELLQUALITYMEAS UlVpTrigTime6D VP Trigger Time 6D Duration when the measured val

UCELLQUALITYMEAS UlBeTrigTime6A1 BE Trigger Time 6A1 Duration when the measured val

UCELLQUALITYMEAS UlBeTrigTime6B1 BE Trigger Time 6B1 Duration when the measured val

UCELLQUALITYMEAS UlBeTrigTime6A2 BE Trigger Time 6A2 Duration when the measured val

UCELLQUALITYMEAS UlBeTrigTime6B2 BE Trigger Time 6B2 Duration when the measured val

UCELLQUALITYMEAS UlBeTrigTime6D BE Trigger Time 6D Duration when the measured val

UCELLQUALITYMEAS UlMeasFilterCoef UL Measurement Filter Coeffic Smooth filtering coefficient fo

UCELLQUALITYMEAS DlMeasFilterCoef DL TCP Measurement Filter Coe Smooth filtering coefficient fo

UCELLQUALITYMEAS DlAmrTrigTimeE AMR Trigger Time of Event E Duration from when the AMR TX

UCELLQUALITYMEAS ChoiceRptUnitForAmrE AMR Reporting Period Unit for This parameter specifies the re

UCELLQUALITYMEAS TenMsecForAmrE AMR Event E Reporting Perio This parameter is valid when th

UCELLQUALITYMEAS MinForAmrE AMR Event E Reporting Period This parameter is valid when th

UCELLQUALITYMEAS DlVpTrigTimeE VP Trigger Time of Event E Duration from when the VP TX po

UCELLQUALITYMEAS ChoiceRptUnitForVpE VP Reporting Period Unit for E This parameter specifies the re

UCELLQUALITYMEAS TenMsecForVpE VP Event E Reporting Period This parameter is valid when th

UCELLQUALITYMEAS MinForVpE VP Event E Reporting Period This parameter is valid when th

UCELLQUALITYMEAS DlBeTrigTimeE BE Trigger Time of Event E Duration from when the BE TX p

UCELLQUALITYMEAS ChoiceRptUnitForBeE BE Reporting Period Unit for E This parameter specifies the re

UCELLQUALITYMEAS TenMsecForBeE BE Event E Reporting Period This parameter is valid when th

UCELLQUALITYMEAS MinForBeE BE Event E Reporting Period This parameter is valid when th

UCELLQUALITYMEAS DlBeTrigTimeF BE Trigger Time of Event F Duration within which the measu

UCELLQUALITYMEAS ChoiceRptUnitForBeF BE Reporting Period Unit for E This parameter specifies the re

UCELLQUALITYMEAS TenMsecForBeF BE Event F Reporting Period This parameter is valid when th

UCELLQUALITYMEAS MinForBeF BE Event F Reporting Period This parameter is valid when th

UCELLREDIRECTION CellId Cell ID Unique ID of a cell

UCELLREDIRECTION TrafficType Traffic class Traffic class whose RRC redire

UCELLREDIRECTION RedirSwitch Redirection Switch

UCELLREDIRECTION RedirFactorOfNorm Redirection Factor Of Normal Possibility of redirecting the U

UCELLREDIRECTION RedirFactorOfLDR Redirection Factor Of LDR Possibility of redirecting the

UCELLREDIRECTION RedirBandInd ReDirection target band indica Frequency band of the target UL

UCELLREDIRECTION ReDirUARFCNUplinkInd Redirection Target UL Frequen Whether the target UL UARFCN

UCELLREDIRECTION ReDirUARFCNUplink Redirection target uplink UA

UCELLREDIRECTION ReDirUARFCNDownlink Redirection target downlink Target DL UARFCN for the RRC

UCELLRLACTTIME CellId Cell ID Uniquely identifying a cell. Fo

UCELLRLPWR CellId Cell ID ID of a cell. For detailed inf

MBMS service release is an extreme method in reducing the cell load and recovering the system when the cell is overloaded and congested.The mechanism of the OLC is that an action is performed in each [OLC period] and some services are selected based on the action rules to perform this action. This parameter defines the maximum number of MBMS services released in executing downlink OLC service release.ADD UCELLOLC(Optional)

MOD UCELLOLC(Optional)The mechanism of the OLC is that an action is performed in each [OLC period] and some services are selected based on the action rules to perform this action. This parameter defines the maximum number of users selected in executing reconfiguration to the CCH.If the parameter value is too high, the OLC action may fluctuate greatly and over control may occur (the state of overload and congestion turns into another extreme--under load). If the parameter value is too low, the OLC action has a slow response and the effect is not apparent, affecting the OLC performance.ADD UCELLOLC(Optional)

MOD UCELLOLC(Optional)MOD UCELLPUC(Mandatory)RMV UCELLPUC(Mandatory)ADD UCELLPUC(Optional)MOD UCELLPUC(Optional)

If the load of a cell is equal to or lower than this threshold, the load level of this cell is light. If the load level of a cell is light, the PUC algorithm will configure selection/reselection parameters for this cell to lead the UE to reselect this cell rather than the previous inter-frequency neighboring cell with heavy load.ADD UCELLPUC(Optional)

MOD UCELLPUC(Optional)If the load of a cell is equal to or higher than this threshold, the load level of this cell is heavy.If the load level of a cell is heavy, the PUC algorithm will configure selection/reselection parameters for this cell to lead the UE camping on this cell to reselect another inter-frequency neighboring cell with light load.ADD UCELLPUC(Optional)

MOD UCELLPUC(Optional)ADD UCELLPUC(Optional)MOD UCELLPUC(Optional)ADD UCELLPUC(Optional)MOD UCELLPUC(Optional)ADD UCELLPUC(Optional)MOD UCELLPUC(Optional)ADD UCELLPUC(Optional)MOD UCELLPUC(Optional)ADD UCELLPUC(Optional)MOD UCELLPUC(Optional)ADD UCELLPUC(Optional)MOD UCELLPUC(Optional)RMV UCELLQOSHO(Mandatory)ADD UCELLQOSHO(Mandatory)MOD UCELLQOSHO(Optional)ADD UCELLQOSHO(Optional)

As for the impact on network performance:The larger the value of the parameter is, the more easily event 2B, inter-frequency handover based on Qos, and event 3A, inter-RAT handover based on Qos, can be triggered, and thus the more timely the handover to the target cell can be performed.MOD UCELLQOSHO(Optional)

ADD UCELLQOSHO(Optional)It reduces the influence of long time compressed mode to the serving cell.The compressed mode may be stopped ahead of time, which can cause the result that the UE fails to initiate inter-frequency or inter-RAT handover, and thus can lead to call drops.MOD UCELLQOSHO(Optional)

ADD UCELLQOSHO(Optional)It reduces the influence of long time compressed mode to the serving cell.The compressed mode may be stopped ahead of time, which can cause the result that the UE fails to initiate inter-frequency or inter-RAT handover, and thus can lead to call drops.MOD UCELLQOSHO(Optional)

ADD UCELLQOSHO(Optional)As for the impact on network performance:When the UE moves to the cell border, and there is a intra-frequency neighboring cell in the moving direction, CPCICH Ec/No varies faster than RSCP and the quality of the current cell should be evaluated according to CPCICH Ec/No. When there is no intra-frequency neighboring cell in the direction, CPCICH RSCP varies faster than Ec/No and the quality should be evaluated according to CPCICH RSCP. If the measurement quantity is not properly selected, the handover may not be performed timely, thus resulting in call drops.MOD UCELLQUALITYMEAS(Mandatory)

RMV UCELLQUALITYMEAS(Mandatory)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Mandatory)ADD UCELLQUALITYMEAS(Mandatory)MOD UCELLQUALITYMEAS(Mandatory)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Mandatory)ADD UCELLQUALITYMEAS(Mandatory)MOD UCELLQUALITYMEAS(Mandatory)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Mandatory)ADD UCELLQUALITYMEAS(Mandatory)MOD UCELLQUALITYMEAS(Mandatory)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Optional)ADD UCELLQUALITYMEAS(Optional)MOD UCELLQUALITYMEAS(Mandatory)ADD UCELLQUALITYMEAS(Mandatory)MOD UCELLQUALITYMEAS(Mandatory)MOD UCELLREDIRECTION(Mandatory)RMV UCELLREDIRECTION(Mandatory)MOD UCELLREDIRECTION(Mandatory)RMV UCELLREDIRECTION(Mandatory)ADD UCELLREDIRECTION(Optional)MOD UCELLREDIRECTION(Optional)

- Only_To_Inter_Frequency indicates that only RRC redirection to inter-frequency cells is allowed.- Only_To_Inter_Frequency indicates that only RRC redirection to inter-RAT cells is allowed.ADD UCELLREDIRECTION(Optional)

MOD UCELLREDIRECTION(Optional)ADD UCELLREDIRECTION(Optional)MOD UCELLREDIRECTION(Optional)ADD UCELLREDIRECTION(Optional)MOD UCELLREDIRECTION(Optional)ADD UCELLREDIRECTION(Optional)MOD UCELLREDIRECTION(Optional)ADD UCELLREDIRECTION(Optional)MOD UCELLREDIRECTION(Optional)

BAND6: UL UARFCN = DL UARFCN - 225BAND7: UL UARFCN = DL UARFCN - 225ADD UCELLREDIRECTION(Optional)

MOD UCELLREDIRECTION(Optional)ADD UCELLRLACTTIME(Mandatory)RMV UCELLRLACTTIME(Mandatory)MOD UCELLRLPWR(Mandatory)RMV UCELLRLPWR(Mandatory)

UCELLRLPWR CNDomainId CN domain ID Identifying the type of a CN.

UCELLRLPWR MaxBitRate Max bit rate of service This parameter denotes the rate

UCELLRLPWR RlMaxDlPwr RL Max DL TX power

UCELLRLPWR RlMinDlPwr RL Min DL TX power

UCELLRLPWR DlSF Downlink spreading factor This parameter refers to the d

UCELLSELRESEL CellId Cell ID ID of a cell. For detailed inf

UCELLSELRESEL QualMeas Cell Sel-reselection quality m Measurement quantity of cell s

UCELLSELRESEL IdleQhyst1s Hysteresis 1 for idle mode

UCELLSELRESEL ConnQhyst1s Hysteresis 1 for connect mode

UCELLSELRESEL IdleQhyst2s Hysteresis 2 for idle mode

UCELLSELRESEL ConnQhyst2s Hysteresis 2 for connect mode

UCELLSELRESEL Treselections Reselection delay time

UCELLSELRESEL Qqualmin Min quality level The minimum required quality th

UCELLSELRESEL Qrxlevmin Min Rx level The minimum required RX thresh

UCELLSELRESEL QrxlevminExtSup Min Rx level Extend Support Indicating whether the actual

UCELLSELRESEL DeltaQrxlevmin Delta Min Rx level Actual minimum required RX le

UCELLSELRESEL MaxAllowedUlTxPower Max allowed UE UL TX power The maximum allowed uplink tra

UCELLSELRESEL IdleSintrasearch Intra-freq cell reselection thre Threshold for intra-frequency c

UCELLSELRESEL IdleSintersearch Inter-freq cell reselection thre Threshold for inter-frequency c

UCELLSELRESEL ConnSintrasearch Intra-freq cell reselection thr Threshold for intra-frequency c

UCELLSELRESEL ConnSintersearch Inter-freq cell reselection thr Threshold for inter-frequency c

UCELLSELRESEL SsearchRat Inter-RAT cell reselection thre Threshold for inter-RAT cell re

UCELLSELRESEL SpeedDependentScalingFacto Speed dependent scaling factor For a high-mobility UE, multipl

UCELLSELRESEL InterFreqTreselScalingFactor Inter-frequency scaling factor f This parameter is used to incre

UCELLSELRESEL InterRatTreselScalingFactor Inter-RAT scaling factor for re This parameter is used to incre

UCELLSELRESEL NonhcsInd Non-HCS indicator Indicating whether the non-HC

UCELLSELRESEL Tcrmaxnonhcs Non-HCS max TCR Maximum duration of non-HCS ce

UCELLSELRESEL Ncrnonhcs Non-HCS NCR Maximum number of non-HCS cell

UCELLSELRESEL Tcrmaxhystnonhcs Non-HCS TCR max hysteresis Hysteresis time before non-HC

UCELLSELRESEL Qhyst1spch Hysteresis 1 for UE in CELL

UCELLSELRESEL Qhyst1sfach Hysteresis 1for UE in CELL_F

UCELLSELRESEL Qhyst2spch Hysteresis 2 for UE in CELL

UCELLSELRESEL Qhyst2sfach Hysteresis 2 for UE in CELL_

UCELLSELRESEL Treselectionspch Reselection delay time for UE This parameter indicates the U

UCELLSELRESEL Treselectionsfach Reselection delay time for U This parameter indicates the U

UCELLSELRESEL SPriority Absolute priority level of the se

UCELLSELRESEL ThdPrioritySearch1 RSCP threshold for low-prio-fr

UCELLSELRESEL ThdPrioritySearch2 Ec/No threshold for low-prio-fr

UCELLSELRESEL ThdServingLow RSCP threshold for low-prio-fr

UCELLSIBSWITCH CellId Cell ID ID of a cell. For detailed inf

UCELLSIBSWITCH SibCfgBitMap SIB Switch Determine whether some system i

UCELLURA CellId Cell ID ID of a cell. For detailed inf

UCELLURA URAId URA ID Identity of the UTRAN registra

UCHPWROFFSET CellId Cell ID ID of a cell. For detailed inf

UCHPWROFFSET PICHPowerOffset PICH Power Offset ADD UCHPWROFFSET(OptionDifference between the transmi

UCHPWROFFSET AICHPowerOffset AICH Power Offset ADD UCHPWROFFSET(OptionThis parameter specifies the p

UCIDCHG CellIDChgSwitch Cell ID Changing Switch SET UCIDCHG(Optional) Indicating whether to use chang

UCIDCHG CellIDChgPeriod Cell ID Changing Period time l SET UCIDCHG(Optional) Indicate the period of cell ID c

UCMCF DlSFTurnPoint DL SF Threshold SET UCMCF(Optional)

UCMCF UlSFTurnPoint UL SF threshold SET UCMCF(Optional)

UCMCF CmcfCellType CM Cell Type SET UCMCF(Optional)

UCMCF DlSFLimitCMInd Dl SF Limit CM Ind SET UCMCF(Optional) Whether the CM is limited by t

UCMCF LimitCMDlSFThd Dl SF Threshold to Limit CM SET UCMCF(Mandatory)

UCMCF HsdpaCMPermissionInd CM Permission Ind on HSDPA SET UCMCF(Optional)

UCMCF HsupaCMPermissionInd CM Permission Ind on HSUPA SET UCMCF(Optional)

UCMCF EHSPACMPermissionInd CM Permission Ind on HSPA+ SET UCMCF(Optional)

UCNDOMAIN CNDomainId CN domain ID Identifying the type of a CN.

UCNDOMAIN T3212 Periodical location update time Periodical location update is

UCNDOMAIN ATT Attach/detach allowed indicati Indicating whether attach/det

UCNDOMAIN NMO Network mode of operation This parameter should be set

UCNDOMAIN DRXCycleLenCoef DRX cycle length coefficient CN domain specific Discontinu

MOD UCELLRLPWR(Mandatory)RMV UCELLRLPWR(Mandatory)MOD UCELLRLPWR(Mandatory)RMV UCELLRLPWR(Mandatory)ADD UCELLRLPWR(Mandatory)MOD UCELLRLPWR(Optional)

This parameter specifies the maximum DL RL power to be assigned.This parameter should fulfill the coverage requirement of the network planning, and the value is relative to [PCPICH transmit power]. For detailed information of this parameter, refer to 3GPP TS 25.433.ADD UCELLRLPWR(Mandatory)

MOD UCELLRLPWR(Optional)This parameter specifies the minimum DL RL power to be assigned.This parameter should consider the maximum downlink transmit power and the dynamic range of power control, and the value is relative to [PCPICH transmit power]. Since the dynamic range of power control is set to 15 dB, this parameter is recommended as [RL Max DL TX power] - 15 dB. For detailed information of this parameter, refer to 3GPP TS 25.433.ADD UCELLRLPWR(Mandatory)

MOD UCELLRLPWR(Optional)MOD UCELLSELRESEL(Mandatory)RMV UCELLSELRESEL(Mandatory)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)

The hysteresis value of the serving FDD cells in idle mode in case the quality measurement for cell selection and reselection is set to CPICH RSCP. It is related to the slow fading feature of the area where the cell is located. The greater the slow fading variance is, the greater this parameter. According to the R regulation, the current serving cell involves in cell selection after the measurement value is added with the hysteresis value. The measurement hysteresis aims to prevent the ping-pong effect of the cell reselection, which is caused by the slow fading when the UE is on the edge of the cell. The ping-pong effect may trigger frequent location updates (idle mode), URA updates (URA_PCH), or cell updates (CELL_FACH, CELL_PCH), and thus increase the load of network signaling and the consumption of UE batteries. Set a proper measurement hysteresis to reduce as much as possible effect of the slow fading as well as ensuring timely cell updates of the UE. According to the CPICH RSCP emulation report of inter-frequency hard handovers, the measurement hysteresis ranges 4 dBm to 5 dBm and is set to 4 dBm by default when the slow fading variance is 8 dB and the relative distance is 20 m. In the cells where the slow fading variance is low and the average moving speed of UEs is high, for example the suburbs and countryside, reduce the measurement hysteresis to guarantee timely location updates of UEs. The higher the measurement hysteresis is, the less likely it is for various types of cell reselections to occur, and the better the slow fading resistance capability is, but the slower the system reacts to the environment changes. For detailed information of this parameter, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)The hysteresis value of the serving FDD cells in connected mode in case the quality measurement for cell selection and reselection is set to CPICH RSCP. It is related to the slow fading feature of the area where the cell is located. The greater the slow fading variance is, the greater this parameter. According to the R regulation, the current serving cell involves in cell selection after the measurement value is added with the hysteresis value. The measurement hysteresis aims to prevent the ping-pong effect of the cell reselection, which is caused by the slow fading when the UE is on the edge of the cell. The ping-pong effect may trigger frequent location updates (idle mode), URA updates (URA_PCH), or cell updates (CELL_FACH, CELL_PCH), and thus increase the load of network signaling and the consumption of UE batteries. Set a proper measurement hysteresis to reduce as much as possible effect of the slow fading as well as ensuring timely cell updates of the UE. According to the CPICH RSCP emulation report of inter-frequency hard handovers, the measurement hysteresis ranges 4 dBm to 5 dBm and is set to 4 dBm by default when the slow fading variance is 8 dB and the relative distance is 20 m. In the cells where the slow fading variance is low and the average moving speed of UEs is high, for example the suburbs and countryside, reduce the measurement hysteresis to guarantee timely location updates of UEs. The higher the measurement hysteresis is, the less likely it is for various types of cell reselections to occur, and the better the slow fading resistance capability is, but the slower the system reacts to the environment changes. For detailed information of this parameter, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)The hysteresis value of the serving FDD cells in idle mode in case the quality measurement for cell selection and reselection is set to CPICH Ec/No. It is related to the slow fading feature of the area where the cell is located. The greater the slow fading variance is, the greater this parameter. It is optional. If it is not configured, [Hysteresis 1] will be adopted as the value. This parameter is not configured when its value is 255. According to the R regulation, the current serving cell involves in cell selection after the measurement value is added with the hysteresis value. The measurement hysteresis aims to prevent the ping-pong effect of the cell reselection, which is caused by the slow fading when the UE is on the edge of the cell. The ping-pong effect may trigger frequent location updates (idle mode), URA updates (URA_PCH), or cell updates (CELL_FACH, CELL_PCH), and thus increase the load of network signaling and the consumption of UE batteries. Set a proper measurement hysteresis to reduce as much as possible effect of the slow fading as well as ensuring timely cell updates of the UE. According to the CPICH RSCP emulation report of inter-frequency hard handovers, the measurement hysteresis ranges 4 dBm to 5 dBm and is set to 4 dBm by default when the slow fading variance is 8 dB and the relative distance is 20 m. In the cells where the slow fading variance is low and the average moving speed of UEs is high, for example the suburbs and countryside, reduce the measurement hysteresis to guarantee timely location updates of UEs. The higher the measurement hysteresis is, the less likely it is for various types of cell reselections to occur, and the better the slow fading resistance capability is, but the slower the system reacts to the environment changes. For detailed information of this parameter, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)The hysteresis value of the serving FDD cells in connected mode in case the quality measurement for cell selection and reselection is set to CPICH Ec/No. It is related to the slow fading feature of the area where the cell is located. The greater the slow fading variance is, the greater this parameter. This parameter is not configured when its value is 255. According to the R regulation, the current serving cell involves in cell selection after the measurement value is added with the hysteresis value. The measurement hysteresis aims to prevent the ping-pong effect of the cell reselection, which is caused by the slow fading when the UE is on the edge of the cell. The ping-pong effect may trigger frequent location updates (idle mode), URA updates (URA_PCH), or cell updates (CELL_FACH, CELL_PCH), and thus increase the load of network signaling and the consumption of UE batteries. Set a proper measurement hysteresis to reduce as much as possible effect of the slow fading as well as ensuring timely cell updates of the UE. According to the CPICH RSCP emulation report of inter-frequency hard handovers, the measurement hysteresis ranges 4 dBm to 5 dBm and is set to 4 dBm by default when the slow fading variance is 8 dB and the relative distance is 20 m. In the cells where the slow fading variance is low and the average moving speed of UEs is high, for example the suburbs and countryside, reduce the measurement hysteresis to guarantee timely location updates of UEs. The higher the measurement hysteresis is, the less likely it is for various types of cell reselections to occur, and the better the slow fading resistance capability is, but the slower the system reacts to the environment changes. For detailed information of this parameter, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)3. Consider the difference between cells that cover different areas, for example the cells covering highways and cells covering densely populated areas. TIf the parameter is set to a comparatively low value, the ping-pong reselections may be caused. The parameter can be increased in populated area and reduced in high-speed movement. If the parameter is set to a comparatively high value, the cell reselection delay may become excessively high, and thus cell reselections may be affected. For detailed information, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Mandatory)MOD UCELLSELRESEL(Mandatory)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)

This parameter indicates that in the CELL_PCH or URA_PCH connection mode, the measurement hysteresis of the UE is 1. It is used when CPICH RSCP is used in cell selection and reselection measurement. This parameter is not configured when the value is 255.Otherwise, the greater the parameter value is, the harder the cell selection happens. For detailed information, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)This parameter indicates that in the CELL_FACH connection mode, the measurement hysteresis of the UE is 1. It is used when CPICH RSCP is used in cell selection and reselection measurement. This parameter is not configured when the value is 255.Otherwise, the greater the parameter value is, the harder the cell selection happens. For detailed information, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)This parameter indicates that in the CELL_PCH or URA_PCH connection mode, the measurement hysteresis of the UE is 2. It is used when CPICH EcNo is used in cell selection and reselection measurement. This parameter is not configured when the value is 255.Otherwise, the greater the parameter value is, the harder the cell selection happens. For detailed information, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)This parameter indicates that in the CELL_FACH connection mode, the measurement hysteresis of the UE is 2. It is used when CPICH EcNo is used in cell selection and reselection measurement. This parameter is not configured when the value is 255.Otherwise, the greater the parameter value is, the harder the cell selection happens. For detailed information, refer to 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)ADD UCELLSELRESEL(Optional)MOD UCELLSELRESEL(Optional)

The greater the absolute priority level of the serving cell is, the harder the UE performs cell reselection, the smaller the absolute priority level of the serving cell is, the easier the UE performs cell reselection. For details on this parameter, see 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)The greater the value of this parameter is, the easier the UE measures cells for priority-based cell reselection, the smaller the value of this parameter is, the harder the UE measures cells for priority-based cell reselection. For details on this parameter, see 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)The greater the value of this parameter is, the easier the UE measures cells for priority-based cell reselection, the smaller the value of this parameter is, the harder the UE measures cells for priority-based cell reselection. For details on this parameter, see 3GPP TS 25.304.ADD UCELLSELRESEL(Optional)

MOD UCELLSELRESEL(Optional)The greater the value of this parameter is, the easier the UE performs priority-based cell reselection, the smaller the value of this parameter is, the harder the UE performs priority-based cell reselection. For details on this parameter, see 3GPP TS 25.304.MOD UCELLSIBSWITCH(Mandatory)

RMV UCELLSIBSWITCH(Mandatory)ADD UCELLSIBSWITCH(Optional)MOD UCELLSIBSWITCH(Optional)ADD UCELLURA(Mandatory)RMV UCELLURA(Mandatory)ADD UCELLURA(Mandatory)RMV UCELLURA(Mandatory)ADD UCHPWROFFSET(Mandatory)RMV UCHPWROFFSET(Mandatory)

When the downlink spreading factor is greater than or equal to the value of this parameter, the SF/2 mode is preferred. Otherwise, the high-layer scheduling mode is preferred.The SF/2 mode consumes more system resources and therefore this mode is recommended only for low-rate users. The high-layer scheduling mode requires variable multiplexing positions of transport channels and is applicable to a relatively narrow range. In addition, this approach affects the transmission rate of users. Therefore, this mode is recommended only when the SF/2 approach is unavailable or there are high-rate users.When the uplink spreading factor is greater than or equal to the value of this parameter, the SF/2 mode is preferred. Otherwise, the high-layer scheduling mode is preferred.The SF/2 mode consumes more system resources and therefore this mode is recommended only for low-rate users. The high-layer scheduling mode requires variable multiplexing positions of transport channels and is applicable to a relatively narrow range. In addition, this approach affects the transmission rate of users. Therefore, this mode is recommended only when the SF/2 approach is unavailable or there are high-rate users.CM type of the cell.The CM parameters are configured on the basis of the CM type of the cell. That is, the CM sequence number is determined after the CM type of the cell is determined.

Downlink SF threshold for enabling compressed mode (CM).When the parameter "DlSFLimitCMInd" is set to TRUE and the current downlink SF is smaller than or equal to the value of this parameter, the active set quality measurement is not allowed, that is, the CM cannot be enabled. When the parameter "DlSFLimitCMInd" is set to TRUE and the current downlink SF is greater than the value of this parameter, the active set quality measurement is allowed, that is, the CM can be enabled.Whether the compressed mode (CM) can coexist with the HSDPA service. If this parameter is set to TRUE: 1. the RNC can enable the CM for HSDPA services. 2. The HSDPA services can be enabled when the CM is enabled. If this parameter is set to FALSE: 1. the CM for HSDPA services can be enabled only after the H2D (HS-DSCH to DCH) channel switch. 2. The HSDPA services cannot be enabled when the CM is enabled.This switch is used for the compatibility of the HSDPA terminals that do not support CM when HSDPA is enabled.Whether the compressed mode (CM) can coexist with the HSUPA service. If this parameter is set to Permit: 1. the RNC can enable the CM for HSUPA services. 2. The HSUPA services can be enabled when the CM is enabled. If this parameter is set to Limited: 1. the CM for HSUPA services can be enabled only after the E2D (E-DCH to DCH) channel switch. 2. The HSUPA services cannot be enabled when the CM is enabled. If this parameter is set to BasedonUECap, the RNC determines whether CM can be enabled for HSUPA services and whether HSUPA services can be enabled when the CM is enabled by considering the UE capability.This switch is used for the compatibility of the HSUPA terminals that do not support CM when HSUPA is enabled.If this parameter is set to TRUE: 1. the RNC can enable the CM for HSPA+ services. 2. The HSPA+ services can be enabled when the CM is enabled. If this parameter is set to FALSE: 1. the CM for HSPA+ services can be enabled only after the uplink and downlink H2D (HS-DSCH to DCH) channel switch. 2. The HSPA+ services cannot be enabled when the CM is enabled.This switch is used for the compatibility of the HSPA+ terminals that do not support CM when HSPA+ is enabled.MOD UCNDOMAIN(Mandatory)

RMV UCNDOMAIN(Mandatory)ADD UCNDOMAIN(Optional)MOD UCNDOMAIN(Optional)ADD UCNDOMAIN(Optional)MOD UCNDOMAIN(Optional)ADD UCNDOMAIN(Optional)MOD UCNDOMAIN(Optional)ADD UCNDOMAIN(Optional)MOD UCNDOMAIN(Optional)

UCNNODE CnOpIndex Cn Operator Index Represent an index for a CN o

UCNNODE CNDomainId CN domain ID Identifying the type of a CN.

UCNNODE Switch3GPP25415CR0125 Switch3GPP25415CR0125 This parameter is valid only

UCNNODE RsvdPara1 Reserved parameter 1 Reserved parameter 1.

UCNNODE RsvdPara2 Reserved parameter 2 Reserved parameter 2.

UCNOPALLCELLBLK CnOpIndex Cn Operator Index Represent an index for a CN o

UCNOPALLCELLBLK DomainType Blocked Domain Type This parameter specifies the b

UCNOPALLCELLBLK ProcessDuration Processing Duration This parameter specifies the pr

UCNOPERATOR OperatorType Operator Type

UCNOPERATOR CnOperatorName Cn Operator Name Cn Operator Name.

UCNOPERATOR MCC MCC ADD UCNOPERATOR(MandatoMobile country code. This para

UCNOPERATOR MNC MNC ADD UCNOPERATOR(MandatoMobile network code. This para

UCNOPERATOR CnOpIndex Cn Operator Index ADD UCNOPERATOR(Optiona

UCNOPERATOR CnOpIndex Cn Operator Index MOD UCNOPERATOR(MandatRepresent an index for a CN o

UCNOPERATOR CnOpIndex Cn Operator Index RMV UCNOPERATOR(MandatRepresent an index for a CN o

UCNOPERGROUP CnOpGrpIndex Cn Operator Group Index Represent an index for a CN

UCNOPERGROUP CnOpGrpName Cn Operator Group Name Cn Operator Group Name.

UCNOPERGROUP CnOpNum Operator Number ADD UCNOPERGROUP(MandaIdentify Operator Number in O

UCNOPERGROUP CnOpIndex1 Operator 1 Index ADD UCNOPERGROUP(MandaRepresent an index for a CN o




UCNOPERGROUP CnOpIndexComm Common Operator Index ADD UCNOPERGROUP(OptionRepresent an index for a Co

UCOIFTIMER ZeroRateUpFailToRelTimerLe Release 0 kbit/s Timer Length SET UCOIFTIMER(Optional) For the PS BE service at a rate

UCOIFTIMER ChannelRetryTimerLen Channel Retry Timer Length SET UCOIFTIMER(Optional) This parameter specifies the va

UCOIFTIMER ChannelRetryHoTimerLen Channel Retry Ho Timer Lengt SET UCOIFTIMER(Optional)

UCOIFTIMER RabModifyTimerLen Rab Modify Timer Length SET UCOIFTIMER(Optional) The timer is started when the

UCONNMODETIMER T302 Timer 302 SET UCONNMODETIMER(OptiT302 is started after the UE

UCONNMODETIMER N302 Constant 302 SET UCONNMODETIMER(OptiMaximum number of retransmi


UCONNMODETIMER N304 Constant 304 SET UCONNMODETIMER(OptiMaximum number of retransmis

UCONNMODETIMER T305 Timer 305 SET UCONNMODETIMER(OptiT305 is started after the UE r

UCONNMODETIMER T307 Timer 307 SET UCONNMODETIMER(OptiT307 is started after T305 has


UCONNMODETIMER N308 Constant 308 SET UCONNMODETIMER(OptiMaximum number of retrans

UCONNMODETIMER T309 Timer 309 SET UCONNMODETIMER(Opti

UCONNMODETIMER T312 Timer 312 SET UCONNMODETIMER(OptiT312 is started when UE starts

UCONNMODETIMER N312 Constant 312 SET UCONNMODETIMER(OptiMaximum number of successive

UCONNMODETIMER T313 Timer 313 SET UCONNMODETIMER(OptiT313 is started after the UE de

UCONNMODETIMER N313 Constant 313 SET UCONNMODETIMER(OptiMaximum number of successive "



UCONNMODETIMER N315 Constant 315 SET UCONNMODETIMER(OptiMaximum number of successive "

UCONNMODETIMER T316 Timer 316 SET UCONNMODETIMER(OptiT316 is started after the UE de

UCONNMODETIMER T381 Timer 381 SET UCONNMODETIMER(OptiT381 is started after the

UCONNMODETIMER N381 Constant 381 SET UCONNMODETIMER(OptiMaximum number of resend t

UCONNMODETIMER T323 Timer 323 SET UCONNMODETIMER(OptiIf the UE checks that no PS/

UCORRMALGOSWITCH CfgSwitch Channel Configuration Strateg SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH DraSwitch Dynamic Resource Allocation SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH CsSwitch CS Algorithm Switch SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH PcSwitch Power Control Switch SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH CmpSwitch Compatibility Switch SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH MapSwitch Service Mapping Strategy Swit SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH PsSwitch PS Rate Negotiation Switch SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH DrSwitch Direct Retry Switch SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH HoSwitch HandOver Switch SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH SrnsrSwitch SRNSR Algorithm Switch SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH CmcfSwitch CMCF Algorithm Switch SET UCORRMALGOSWITCH(Op

UCORRMALGOSWITCH ReservedSwitch0 CORRM Algorithm Reserved SSET UCORRMALGOSWITCH(OpCORRM algorithm reserved switc

UCORRMALGOSWITCH ReservedSwitch1 CORRM Algorithm Reserved SSET UCORRMALGOSWITCH(OpCORRM algorithm reserved switc

UCORRMALGOSWITCH ReservedU32Para0 CORRM Algorithm Reserved USET UCORRMALGOSWITCH(OpCORRM algorithm reserved U32 p

MOD UCNNODE(Mandatory)RMV UCNNODE(Mandatory)ADD UCNNODE(Mandatory)MOD UCNNODE(Mandatory)ADD UCNNODE(Optional)MOD UCNNODE(Optional)ADD UCNNODE(Optional)MOD UCNNODE(Optional)ADD UCNNODE(Optional)MOD UCNNODE(Optional)MOD UCNOPALLCELLBLK(Mandatory)RMV UCNOPALLCELLBLK(Mandatory)ADD UCNOPALLCELLBLK(Mandatory)MOD UCNOPALLCELLBLK(Mandatory)ADD UCNOPALLCELLBLK(Mandatory)MOD UCNOPALLCELLBLK(Optional)ADD UCNOPERATOR(Mandatory)MOD UCNOPERATOR(Mandatory)

Outer Operator: In order to support mobility between two RNCs, we define the operator switched over to the target RNC as an outer operator. The outer operator is not a primary or secondary operator of the source RNC.Common operator: PLMN-id indicated in the system broadcast information as defined for conventional networks, which non-supporting UEs understand as the serving operator. If there are multiple operators in the operator group to which the cell belongs, you are advised to configure the operators as common operators.ADD UCNOPERATOR(Mandatory)

MOD UCNOPERATOR(Mandatory)

If "OperatorType" is set to OUTER, the value range of "Operator Index" is 5-31. If "OperatorType" is set to COMM, the value range of "Operator Index" is 5-31.

MOD UCNOPERGROUP(Mandatory)RMV UCNOPERGROUP(Mandatory)ADD UCNOPERGROUP(Mandatory)MOD UCNOPERGROUP(Optional)

Pingpang will happen when the reconfiguration is triggered immediately when handover succeeds, because handover procedure is frequently.In order to avoid the pingpang, this timer will start after handover procedure is performed, and the reconfiguration will not be triggered until the timer expires.

T309 is started after the UE is reselected to a cell belonging to another radio access system in connected mode, or the CELL CHANGE ORDER FROM UTRAN message is received. It is stopped after the UE is successfully connected in the new cell. The UE will continue the connection to UTRAN upon expiry. Protocol default value is 5.

T314 is started when the criteria for radio link failure are fulfilled and only radio bearers (RBs) associated with T314 exist.T314 is stopped after the Cell Update procedure has been completed. Protocol default value is 12.In case of the RL failure when the UE is in CELL_DCH state, If the RL cannot be successfully reconfigured by CELL UPDATE CONFIRM before the expiry of the corresponding T314 (or T315), CELL UPDATE will be resent for RL reconfiguration (this operation relates to T302 and N302). T314 should be set greater than T302*N302. In case of the expiry of T314, the corresponding service RBs will be removed.T315 is started when the criteria for radio link failure are fulfilled, and only the radio bearer associated with T315 exists.T315 is stopped after the Cell Update procedure has been completed. Protocol default value is 180.In case of the RL failure when the UE is in CELL_DCH state, T315 (or T314) is started and CELL UPDATE is sent. If the RL cannot be successfully reconfigured by CELL UPDATE CONFIRM before the expiry of the corresponding T315 (or T314), CELL UPDATE will be resent for RL reconfiguration (this operation relates to T302 and N302). T315 should be set greater than T302*N302. In case of the expiry of T315, the corresponding service RBs will be removed.

16) CFG_PTT_SWITCH: When this switch is on, the RNC identifies the PTT user based on the QoS attributes in the RAB assignment request message. Then, the PTT users are subject to special processing. 17) CFG_RAB_REL_RMV_HSPAPLUS_SWITCH: When this switch is on and if an RAB release is performed, the RNC decides whether to fall back a certain HSPA(HSPA+) feature based on the requirement of remaining traffic carried by the UE. That is, if an HSPA+ feature is required by the previously released RAB connection but is not required in the initial bearer policy of the remaining traffic, the RNC falls back the feature to save the transmission resources. The HSPA+ features that support the fallback are MIMO, 64QAM, MIMO+64QAM, UL 16QAM, DC-HSDPA, and UL TTI 2ms.18) DRA_VOICE_SAVE_CE_SWITCH: when the switch is on, the TTI selection based on the voice service type (including VoIP and CS over HSPA) is supported when the service is initially established.19) DRA_VOICE_TTI_RECFG_SWITCH: when the switch is on, the TTI adjustment based on the voice service type (including VoIP and CS over HSPA) is supported.2) CS_HANDOVER_TO_UTRAN_DEFAULT_CFG_SWITCH: When the switch is on, the default configurations of signaling and RABs, which are stipulated in 3GPP 25.331, are used for relocation of the UE from GSM to WCDMA. When the switch is not on, the default configurations are not used. Instead, the complete information of RB, TrCH, and PhyCH, which are in the HANDOVER TO UTRAN COMMAND message is used. 3) CS_IUUP_V2_SUPPORT_SWITCH: When the switch is on and the "Support IUUP Version 2" license is activated, the RNC supports the TFO/TRFO function.10) PC_SIG_DCH_OLPC_SWITCH: When the switch is on, SIG DCH is involved in UL OLPC as service DCH is. If the current link has only SIG DCH, SIG DCH is always involved in UL OLPC. 11) PC_UL_SIRERR_HIGH_REL_UE_SWITCH: When the switch is on, the UE is unconditionally released if the SIR error is high and the cell is overloaded. Otherwise, the UE is not released.14) CMP_UU_SERV_CELL_CHG_WITH_RB_MOD_SWITCH: When the switch is on, channel transition is in the same procedure as the change of the serving cell. When the switch is not on, the serving cell is changed after the UE performs channel transition and delivers reconfiguration of physical channels.15) CMP_UU_VOIP_UP_PROC_AS_NORMAL_PS_SWITCH: By default, the switch is on. In this case, the Alternative E-bit is not configured for L2.6) MAP_PS_STREAM_ON_HSUPA_SWITCH: When the switch is on, a PS streaming service is mapped on the E-DCH if the UL maximum rate of the service is greater than or equal to the HSUPA threshold for streaming services. 7) MAP_SRB_6800_WHEN_RAB_ON_HSDSCH_SWITCH: When the switch is on, the signaling is transmitted at a rate of 6.8 kbit/s if all the downlink traffic is on the HSDPA channel.5) PS_STREAM_IU_QOS_NEG_SWITCH: When the switch is on, the Iu QoS Negotiation function is applied to the PS STREAM service if Alternative RAB Parameter Values IE is present in the RANAP RAB ASSIGNMENT REQUEST or RELOCATION REQUEST message.6) PS_BE_STRICT_IU_QOS_NEG_SWITCH: When the switch is on, the strict Iu QoS Negotiation function is applied to the PS BE service,RNC select Iu max bit rate based on UE capacity,cell capacity,max bitrate and alternative RAB parameter values in RANAP RAB ASSIGNMENT REQUEST or RELOCATION REQUEST message. When the switch is not on, the loose Iu QoS Negotiation function is applied to the PS BE service,RNC select Iu max bit rate based on UE capacity,max bitrate and alternative RAB parameter values in RANAP RAB ASSIGNMENT REQUEST or RELOCATION REQUEST message,not consider cell capacity,this can avoid Iu QoS Renegotiation between different cell.The switch is valid when PS_BE_IU_QOS_NEG_SWITCH is set to ON.2) DR_RAB_SING_DRD_SWITCH(DRD switch for single RAB): When the switch is on, DRD is performed for single service if retry is required.3) DR_RAB_COMB_DRD_SWITCH(DRD switch for combine RAB): When the switch is on, DRD is performed for combined services if retry is required.19) HO_MC_SIGNAL_SWITCH: When the switch is on, quality measurement on the active set is delivered after signaling setup but before service setup. If the UE is at the cell verge or receives weak signals after accessing the network, the RNC can trigger inter-frequency or inter-RAT handover when the UE sets up the RRC. 20) HO_MC_SNA_RESTRICTION_SWITCH: When the switch is on, the RNC controls the UEs in the connected state based on the configurations on the CN. The UEs can only access and move in authorized cells.3) SRNSR_DSCR_PROPG_DELAY_SWITCH: When the switch is on, the RNC initiates static relocation or DSCR if the delay over a link cannot meet QoS requirements (the SRNC and the CRNC are separated). Thus, delay over the link is reduced on the network side and the QoS is enhanced. Based on PsBeProcType of "ADD UNRNC", the RNC decides whether to initiate relocation or DSCR.4) SRNSR_DSCR_SEPRAT_DUR_SWITCH: When the switch is on, the RNC initiates static relocation or DSCR if the duration of separation between the SRNC and the CRNC exceeds a configured threshold. Based on PsBeProcType of "ADD UNRNC", the RNC decides whether to initiate relocation or DSCR.3) CMCF_UL_PRECFG_TOLERANCE_SWITCH: When the switch is on, the compressed mode of the UE in the compressed mode pre-configuration state can be different from that required by current traffic.4) CMCF_WITHOUT_UE_CAP_REPORT_SWITCH: When the RNC starts inter-frequency or inter-RAT measurement, the RNC checks the information of whether the compressed mode is required for measurement on the frequency band of the cells in measurement list. The information should be reported by the UE in RRC connect setup complete message. When the switch is on and no such information has been reported, the RNC starts the compressed mode and then delivers the measurement.

UCORRMALGOSWITCH ReservedU32Para1 CORRM Algorithm Reserved USET UCORRMALGOSWITCH(OpCORRM algorithm reserved U32 p

UCORRMALGOSWITCH ReservedU8Para0 CORRM Algorithm Reserved USET UCORRMALGOSWITCH(OpCORRM algorithm reserved U8 pa

UCORRMALGOSWITCH ReservedU8Para1 CORRM Algorithm Reserved USET UCORRMALGOSWITCH(OpCORRM algorithm reserved U8 pa

UCTCH CellId Cell ID ID of a cell. For detailed inf

UCTCH FachId FACH ID Uniquely identifying a FACH be

UCZ CnOpIndex Cn Operator Index Represent an index for a CN o

UCZ LAC Location Area Code ADD UCZ(Mandatory) Identifies a location area cod

UCZ SAC Service Area Code ADD UCZ(Mandatory) MCC,MNC,LAC and SAC together c

UCZ CZ Classified Zone ID Uniquely identifying a classifi

UDCCC UlDcccRateThd Uplink Bit Rate Threshold for SET UDCCC(Optional) For a BE service that has a lo

UDCCC DlDcccRateThd Downlink Bit Rate Threshold SET UDCCC(Optional) For a BE service that has a lo

UDCCC LittleRateThd Low Activity Bit Rate Threshol SET UDCCC(Optional) When the BE service rate decre

UDCCC DcccStg DCCC Strategy SET UDCCC(Optional) Strategy for adjustment of th

UDCCC HsupaDcccStg HSUPA DCCC Strategy SET UDCCC(Optional) Strategy of the UE for rate a

UDCCC BePwrMargin BE Event F Reporting Power MSET UDCCC(Optional) The relative power margin of sin

UDCCC CombPwrMargin Comb Event F Reporting PoweSET UDCCC(Optional) The relative power margin of com

UDCCC UlRateUpAdjLevel Uplink Rate Increase Adjust LeSET UDCCC(Optional) This parameter determines whet

UDCCC UlRateDnAdjLevel Uplink Rate Decrease Adjust L SET UDCCC(Optional) This parameter determines whet

UDCCC UlMidRateCalc Uplink Mid Bit Rate Calculate SET UDCCC(Optional) This parameter determines whe

UDCCC UlMidRateThd Uplink Mid Bit Rate Threshold SET UDCCC(Mandatory) Threshold of the UL intermedia

UDCCC DlRateUpAdjLevel Downlink Rate Increase Adjust SET UDCCC(Optional) This parameter determines whet

UDCCC DlRateDnAdjLevel Downlink Rate Decrease AdjusSET UDCCC(Optional) This parameter determines whet

UDCCC DlMidRateCalc Downlink Mid Bit Rate Calcula SET UDCCC(Optional) This parameter determines whet

UDCCC DlMidRateThd Downlink Mid Bit Rate ThreshoSET UDCCC(Mandatory) Threshold of the DL intermedia

UDCCC FailTimeTh DCCC Rate Up Fail Time Thre SET UDCCC(Optional) This parameter specifies the th

UDCCC MoniTimeLen DCCC Rate Up Fail Monitor Ti SET UDCCC(Optional) Length of the period within wh

UDCCC DcccUpPenaltyLen DCCC Rate Up Fail Penalty T SET UDCCC(Optional) Length of the penalty period wi

UDCCC UlFullCvrRate Uplink Full Coverage Bit Rate SET UDCCC(Optional) Maximum UL rate when coverage

UDCCC DlFullCvrRate Downlink Full Coverage Bit Ra SET UDCCC(Optional) Maximum DL rate during network

UDCCC DchThrouMeasPeriod DCH Throu Meas Period SET UDCCC(Optional) This parameter specifies the p

UDISTANCEREDIRECTION RedirSwitch Redirection Switch SET UDISTANCEREDIRECTIONThis parameter specifies whethe

UDISTANCEREDIRECTION DelayThs Propagation delay threshold SET UDISTANCEREDIRECTIONRedirection algorithm works on

UDISTANCEREDIRECTION RedirFactorOfLDR Redirection Factor Of LDR SET UDISTANCEREDIRECTIONWhen the UL load state or DL lo

UDISTANCEREDIRECTION RedirFactorOfNorm Redirection Factor Of Normal SET UDISTANCEREDIRECTIONWhen the load of the serving ce

UDPUCFGDATA DlR99CongCtrlSwitch Switch Of DL R99 Congestion SET UDPUCFGDATA(OptionalWhen the switch is on, the con

UDPUCFGDATA TpeSwitch TPE Switch SET UDPUCFGDATA(Optional

UDPUCFGDATA ServicePriAdjCoef Service Priority Adjusting CoeffSET UDPUCFGDATA(OptionalSpecifies the coefficient for a

UDPUCFGDATA CellCountersMeasOBJCtrlSwit Performance Measurement SwSET UDPUCFGDATA(OptionalThis parameter specifies whet

UDPUCFGDATA RsvdPara1 Reserved Parameter1 SET UDPUCFGDATA(OptionalThis parameter is saved for th
















UDRD DRMaxGSMNum Maximum Times of Inter-RAT DSET UDRD(Optional) Maximum number of inter-RAT RA

UDRD ServiceDiffDrdSwitch Service Steering DRD Switch SET UDRD(Optional) Whether the service steering DR

UDRD LdbDRDSwitchDCH Load balance DRD switch for SET UDRD(Optional)

UDRD LdbDRDSwitchHSDPA Load balance DRD switch for SET UDRD(Optional)

UDRD LdbDRDchoice Load Balancing DRD Choice SET UDRD(Optional)

UDRD ConnectFailRrcRedirSwitch RRC Redirection Switch for Ad SET UDRD(Optional)

UDRD LdbDRDOffsetDCH Load balance DRD offset for SET UDRD(Optional) Threshold of remnant load offs

ADD UCTCH(Mandatory)RMV UCTCH(Mandatory)ADD UCTCH(Mandatory)RMV UCTCH(Mandatory)ADD UCZ(Mandatory)RMV UCZ(Mandatory)

ADD UCZ(Mandatory)RMV UCZ(Mandatory)

1) TPE_DOWNLINK_SWITCH: When the switch is on, the Downlink TCP Accelerator function is supported.2) TPE_UPLINK_SWITCH: When the switch is on, the Uplink TCP Accelerator function is supported.

- ON: The load balancing DRD algorithm will be applied.(If cell-level DRD parameters are configured, the status of cell level load balance DRD switch for DCH should also be considered.)- OFF: The load balancing DRD algorithm will not be applied.- ON: The load balancing DRD algorithm will be applied.(If cell-level DRD parameters are configured, the status of cell level load balance DRD switch for DCH should also be considered.)- OFF: The load balancing DRD algorithm will not be applied.- Power: Power(Downlink none-HSDPA power is used for DCH services, and downlink HSDPA guarantee power is used for HSDPA services) will be applied to the load balancing DRD algorithm. - UserNumber: User number(Downlink R99 equivalent user number is used for DCH services, and downlink HSDPA user number is used for HSDPA services) will be applied to the load balancing DRD algorithm.- Only_To_Inter_Frequency indicates that only RRC redirection to inter-frequency cells is allowed.- Allowed_To_Inter_RAT indicates that both RRC redirection to inter-frequency cells and redirection to inter-RAT cells are allowed.

UDRD LdbDRDOffsetHSDPA Load balance DRD offset for SET UDRD(Optional) Threshold of remnant load offs

UDRD LdbDRDLoadRemainThdDCH Dl load balance DRD power re SET UDRD(Optional) Downlink load threshold to tri

UDRD LdbDRDLoadRemainThdHSD Dl load balance DRD power re SET UDRD(Optional) Downlink load threshold to tr

UDRD LdbDRDTotalPwrProThd Load balance DRD total power SET UDRD(Optional) Threshold of the total downlin

UDRD CodeBalancingDrdSwitch Code Balancing DRD Switch SET UDRD(Optional) Whether to apply the code

UDRD DeltaCodeOccupiedRate Delta of Code Occupancy SET UDRD(Optional) Threshold of code occupancy of

UDRD CodeBalancingDrdMinSFThd Minimum SF Threshold for Co SET UDRD(Optional) One of the triggering conditio

UDRD CodeBalancingDrdCodeRateT Code Occupancy Thres for Co SET UDRD(Optional) One of the triggering conditio

UDRD ReDirBandInd ReDirection target band indica SET UDRD(Optional) Frequency band of the target UL

UDRD ReDirUARFCNUplinkInd Redirection Target UL FrequenSET UDRD(Optional) Whether the target UL UARFCN

UDRD ReDirUARFCNUplink Redirection target uplink UA SET UDRD(Optional)

UDRD ReDirUARFCNDownlink Redirection target downlink SET UDRD(Optional) Target DL UARFCN for the RRC

UDRD ULLdbDRDSwitchDcHSDPA Uplink load balance DRD Swi SET UDRD(Optional) This parameter specifies wheth

UDRD ULLdbDRDOffsetDcHSDPA Uplink load balance DRD Offs SET UDRD(Optional) If the difference of the remaini

UDRD ULLdbDRDLoadRemainThdD Uplink load balance DRD remaSET UDRD(Optional) This parameter specifies the th

UDRD BasedOnMeasHRetryDRDSwitMeasurement-Based DRD Swi SET UDRD(Optional) Controls the validity of the m

UDRDMIMO LegacyHDrdSwitchOfSTTD DRD Switch for LegacyH unde SET UDRDMIMO(Optional) Whether to enable DRD for tec

UDRDMIMO LegacyHDrdSwitchOfSCPICH DRD Switch for LegacyH unde SET UDRDMIMO(Optional) Whether to enable DRD for tec

UDRDMIMO CQIRefValueOfSTTD CQI reference value for STTD SET UDRDMIMO(Optional) Reference CQI for determining

UDRDMIMO CQIRefValueOfSCPICH CQI reference value for P an SET UDRDMIMO(Optional) Reference CQI for determining

UDRDMIMO ExcellentCQIThdOfSTTD Excellent CQI Threshold for SET UDRDMIMO(Optional) CQI threshold for determining t

UDRDMIMO GoodCQIThdOfSTTD Good CQI Threshold for STTD SET UDRDMIMO(Optional) CQI threshold for determining t

UDRDMIMO BadCQIThdOfSTTD Bad CQI Threshold for STTD SET UDRDMIMO(Optional) CQI threshold for determining t

UDRDMIMO ExcellentCQIThdOfSCPICH Excellent CQI Threshold for SET UDRDMIMO(Optional) CQI threshold for determining t

UDRDMIMO GoodCQIThdOfSCPICH Good CQI Threshold for P an SET UDRDMIMO(Optional) CQI threshold for determining t

UDRDMIMO BadCQIThdOfSCPICH Bad CQI Threshold for P and SET UDRDMIMO(Optional) CQI threshold for determining t

UDRDMIMO CQIMeasFilterCoef CQI Measurement Filter Coeffi SET UDRDMIMO(Optional) Filtering coefficient in CQI me

UDRDMIMO CQITrigTimeE CQI Trigger Time Of Event E SET UDRDMIMO(Optional) The duration that the CQI keeps

UDRDMIMO ChoiceRptUnitForCQIE CQI Reporting Period Unit For SET UDRDMIMO(Optional) Unit for the CQI reporting peri

UDRDMIMO TenMsecForCQIE CQI Event E Reporting Period SET UDRDMIMO(Optional) CQI is reported periodically aft

UDRDMIMO MinForCQIE CQI Event E Reporting Period SET UDRDMIMO(Mandatory) CQI is reported periodically af

UDRDMIMO CQITrigTimeF CQI Trigger Time Of Event F SET UDRDMIMO(Optional) The duration that the CQI keeps

UDRDMIMO ChoiceRptUnitForCQIF CQI Reporting Period Unit For SET UDRDMIMO(Optional) Unit for the CQI reporting peri

UDRDMIMO TenMsecForCQIF CQI Event F Reporting Period SET UDRDMIMO(Optional) CQI is reported periodically aft

UDRDMIMO MinForCQIF CQI Event F Reporting Period SET UDRDMIMO(Mandatory) CQI is reported periodically af

UDSACAUTOALGO DsacAutoSwitch Switch for auto DSAC SET UDSACAUTOALGO(OptioWhether to enable the automati

UDSACAUTOALGO CsRestriction Restriction for CS SET UDSACAUTOALGO(MandaWhether to impose the access

UDSACAUTOALGO PsRestriction Restriction for PS SET UDSACAUTOALGO(MandaWhether to impose the access r

UDSACAUTOALGO NumberOfACs Number of restrained Access CSET UDSACAUTOALGO(MandaSpecifies the number of access c

UDSACAUTOALGO AcRange Range of restrained Access Cl SET UDSACAUTOALGO(MandaSpecifies the restricted access

UDSACAUTOALGO AcIntervalOfCells Access Class Restriction inter SET UDSACAUTOALGO(MandaSpecifies the interval between

UDSACAUTOALGO AcRstrctIntervalLen Interval length of Domain Spec SET UDSACAUTOALGO(MandaSpecifies the interval delay be

UDTXDRXPARA TrafficClass Traffic class SET UDTXDRXPARA(MandatoTraffic class whose DTX_DRX p

UDTXDRXPARA EdchTtiType Edch TTI type SET UDTXDRXPARA(MandatoE-DCH TTI type

UDTXDRXPARA Dtxvalid DTX Parameter Switch SET UDTXDRXPARA(OptionalWhether the parameters related

UDTXDRXPARA InactThsForCycle2 Threshold For DPCCH TransmiSET UDTXDRXPARA(OptionalNumber of consecutive EDCH TTI

UDTXDRXPARA DtxLongPreamble Number of Preamble Timeslots SET UDTXDRXPARA(OptionalNumber of preamble timeslots

UDTXDRXPARA MacInactiveThreshold MAC Inactivity Threshold SET UDTXDRXPARA(OptionalPeriod during which no data is

UDTXDRXPARA CqiDtxTimer CQI Activity Timer SET UDTXDRXPARA(OptionalNumber of subframes transmitte

UDTXDRXPARA DpcchBurst1 DPCCH Transmission Burst 1 SET UDTXDRXPARA(OptionalNumber of consecutive subfram

UDTXDRXPARA DpcchBurst2 DPCCH Transmission Burst 2 SET UDTXDRXPARA(OptionalNumber of consecutive subfram

UDTXDRXPARA Drxvalid DRX Parameter Switch SET UDTXDRXPARA(OptionalWhether the parameters related

UDTXDRXPARA DrxCycle DRX Cycle SET UDTXDRXPARA(OptionalSize of patterns (that is, the

UDTXDRXPARA InactThsForDrxCycle DRX Inactivity Threshold SET UDTXDRXPARA(OptionalNumber of consecutive subfra

UDTXDRXPARA InactThsForGrantMonitoring Inactivity Threshold for UE Gra SET UDTXDRXPARA(OptionalNumber of subframes that the U

UDTXDRXPARA DrxGrantMonitoring UE DRX Grant Monitoring DeciSET UDTXDRXPARA(OptionalWhether the UE monitors the t

UDTXDRXPARA CQIFbCkinInDTXDRXmode CQI Feedback Cycke in DTX SET UDTXDRXPARA(OptionalCQI feedback cycle in DTX-DRX

UDTXDRXPARA DtxCycle1 DPCCH Transmission Cycle 1 SET UDTXDRXPARA(OptionalSize of patterns, that is, the

UDTXDRXPARA DtxCycle2 DPCCH Transmission Cycle 2 SET UDTXDRXPARA(OptionalSize of patterns, that is, the

UDTXDRXPARA MacDtxCycle MAC Transmission Cycle SET UDTXDRXPARA(OptionalDTX cycle at the MAC layer wh

UEDCHRATEADJUSTSET EdchRateAdjustSet HSUPA UpLink Rate Adjust SeSET UEDCHRATEADJUSTSET(HSUPA traffic uplink rate adju

BAND6: UL UARFCN = DL UARFCN - 225BAND7: UL UARFCN = DL UARFCN - 225

UEDCHTTIRECFG PriorityOpt Highest User Priority Guarante SET UEDCHTTIRECFG(OptionThis parameter is used only for

UEDCHTTIRECFG BeThd6A1 6A1 threshold for BE SET UEDCHTTIRECFG(OptionThreshold for triggering event

UEDCHTTIRECFG BeThd6B1 6B1 threshold for BE SET UEDCHTTIRECFG(OptionThreshold for triggering event

UEDCHTTIRECFG BeThd6A2 6A2 threshold for BE SET UEDCHTTIRECFG(OptionThreshold for triggering event

UEDCHTTIRECFG BeThd6B2 6B2 threshold for BE SET UEDCHTTIRECFG(OptionThreshold for triggering event

UEXT2GCELL GSMCellIndex GSM Cell Index Unique ID of a GSM cell

UEXT2GCELL GSMCellName GSM Cell Name A name identifying a GSM cell

UEXT2GCELL NBscIndex Neighboring BSC Index The Index of neighboring BSC t

UEXT2GCELL LdPrdRprtSwitch Switch of Periodic Load Report Inquiring load of GSM cell when

UEXT2GCELL MCC Mobile country code The code of the country to wh

UEXT2GCELL MNC Mobile network code The code of the mobile commun

UEXT2GCELL CnOpGrpIndex CN Operator Group Index Indicating a Cn Operator Grou

UEXT2GCELL LAC Location Area Code

UEXT2GCELL CfgRacInd RAC Configuration Indication This parameter identifies whe

UEXT2GCELL RAC Routing area code This parameter defines a routi

UEXT2GCELL CID GSM cell ID Identifying a GSM cell.

UEXT2GCELL NCC Network Color Code Uniquely identifying the differ

UEXT2GCELL BCC BS Color Code Uniquely identifying a neighbor

UEXT2GCELL BcchArfcn Inter-RAT Cell Frequency Num

UEXT2GCELL BandInd Inter-RAT Cell Frequency Band When the inter-RAT cell frequ

UEXT2GCELL RatCellType Inter-RAT cell type Identifying the type of the in

UEXT2GCELL UseOfHcs Use of HCS This parameter indicates whet

UEXT2GCELL HCSPrio HCS Priority Level This parameter indicates the HCS

UEXT2GCELL Qhcs Quality Threshold for HCS Res Quality threshold for HCS resel

UEXT2GCELL NcMode Network Control Mode Indicating the network control

UEXT2GCELL SuppRIMFlag Inter-RAT cell support RIM indi Identifying whether the inter-R

UEXT2GCELL SuppPSHOFlag Inter-RAT cell support PS HO i Identifying whether the inter-R

UEXT2GCELL CIO Cell Individual Offset

UEXT3GCELL NRncId Neighboring RNC ID Identifying a Neighboring RNC

UEXT3GCELL CellId Cell ID of Neighboring RNC Uniquely identifying a neighbo

UEXT3GCELL CellHostType Cell Host Type Specifies the host type of a c

UEXT3GCELL CellName Cell Name ADD UEXT3GCELL(MandatoryIdentifying a cell name

UEXT3GCELL CnOpGrpIndex CN Operator Group Index ADD UEXT3GCELL(MandatoryThis parameter specifies the in

UEXT3GCELL PScrambCode DL Primary Scrambling Code Primary downlink scrambling c

UEXT3GCELL BandInd Band Indicator This parameter specifies the s

UEXT3GCELL UARFCNUplinkInd UL Frequency Ind

UEXT3GCELL UARFCNUplink Uplink UARFCN

UEXT3GCELL UARFCNDownlink Downlink UARFCN

UEXT3GCELL TxDiversityInd TX Diversity Indication This parameter indicates whethe

UEXT3GCELL LAC Location Area Code This parameter identifies a loc

UEXT3GCELL CfgRacInd RAC Configuration Indication This parameter identifies whe

UEXT3GCELL RAC Routing area code This parameter indicates the r

UEXT3GCELL QqualminInd Min Quality Level Ind This parameter indicates whet

UEXT3GCELL Qqualmin Min Quality Level

UEXT3GCELL QrxlevminInd Min RX Level Ind This parameter indicates whet

UEXT3GCELL Qrxlevmin Min RX level

UEXT3GCELL QrxlevminExtSup Min Rx level Extend Support This parameter indicates wheth

UEXT3GCELL DeltaQrxlevmin Delta Min Rx level The actual minimum required R

UEXT3GCELL MaxAllowedUlTxPowerInd Max Allowed UE UL TX Power This parameter indicates whet

UEXT3GCELL MaxAllowedUlTxPower Max Allowed UE UL TX Power This parameter specifies the m

UEXT3GCELL UseOfHcs Use of HCS This parameter indicates whet

UEXT3GCELL HCSPrio HCS Priority Level This parameter indicates the HCS

UEXT3GCELL Qhcs Quality Threshold for HCS Res Quality threshold for HCS resel

UEXT3GCELL SuppDpcmodeChgFlag Support DPC mode Change in This parameter indicates whet

UEXT3GCELL STTDSupInd STTD Support Indicator This parameter indicates wheth

UEXT3GCELL CP1SupInd CP1 Support Indicator This parameter indicates wheth

UEXT3GCELL ClosedLoopTimeAdjustMode Closed Loop Time Adjust Mod The parameter takes for adjust

UEXT3GCELL DpchDivModforOther DPCH Tx Diversity Mode for O Specifies the TX diversity m

UEXT3GCELL FdpchDivModforOther FDPCH Tx Diversity Mode for

UEXT3GCELL DpchDivModforMIMO DPCH Tx Diversity Mode for Specifies the TX diversity on

UEXT3GCELL FdpchDivModforMIMO FDPCH Tx Diversity Mode for

RMV UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Mandatory)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)

Location Area Code (LAC) of the GSM cell. Note: H'0000 and H'FFFE are reserved values.ADD UEXT2GCELL(Mandatory)

MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Mandatory)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)

GSM480Frequency number: (305-341)ADD UEXT2GCELL(Optional)

MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Mandatory)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Optional)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Optional)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Optional)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Optional)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Optional)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Optional)MOD UEXT2GCELL(Optional)ADD UEXT2GCELL(Optional)MOD UEXT2GCELL(Optional)

As for the impact on network performance:The larger the value of the parameter is, the easier it is to be handed over to the GSM network. The smaller the value of the parameter is, the harder it is to be handed over to the GSM network.RMV UEXT3GCELL(Mandatory)

MOD UEXT3GCELL(Mandatory)RMV UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Mandatory)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)

ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)

FALSE indicates that the UL frequency need not be reconfigured. It is configured automatically based on the relationship between UL and DL frequencies. NULL indicates that the UL frequency remains unchanged.ADD UEXT3GCELL(Optional)

MOD UEXT3GCELL(Optional)Special frequencies noneBandIndNotUsed [0-16383]ADD UEXT3GCELL(Optional)

MOD UEXT3GCELL(Optional)Special frequencies noneBandIndNotUsed [0-16383]ADD UEXT3GCELL(Mandatory)

MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Mandatory)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Mandatory)

The larger the value of the parameter is, the more difficult it is for the UE to camp on the cell. The smaller the value of the parameter is, the easier it is for the UE to camp on the cell. But if the value is excessively small, it is possible that the UE cannot receive the system messages carried by PCCPCH.When this parameter is not set to any value, the UE adopts the corresponding value of the current serving cell, added through the ADD UCELLSELRESEL command. Generally, this parameter is not set to any value.ADD UEXT3GCELL(Optional)

MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Mandatory)

The larger the value of the parameter is, the more difficult it is for the UE to camp on the cell. The smaller the value of the parameter is, the easier it is for the UE to camp on the cell. But if the value is excessively small, it is possible that the UE cannot receive the system messages carried by PCCPCH.When this parameter is not set to any value, the UE adopts the corresponding value of the current serving cell, added through the ADD UCELLSELRESEL command. Generally, this parameter is not set to any value.ADD UEXT3GCELL(Optional)

MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Mandatory)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Mandatory)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Mandatory)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)

Specifies the TX diversity mode on F-DPCH for the non-MIMO users and non-DC-HSDPA users.According to the protocol 3GPP TS 25.211, the F-DPCH can use STTD TX diversity mode only. For details on this parameter, see 3GPP TS 25.211.ADD UEXT3GCELL(Optional)

MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)

Specifies the TX diversity mode on F-DPCH for the MIMO users.According to the protocol 3GPP TS 25.211, the F-DPCH can use STTD TX diversity mode only. For details on this parameter, see 3GPP TS 25.211.

UEXT3GCELL DivModforDCHSDPA Tx Diversity Mode for DC-HS

UEXT3GCELL CellCapContainerFdd Cell Capability Container

UEXT3GCELL OverLayMobilityFlag OverLay Network Mobility Flag ADD UEXT3GCELL(Optional)

UEXT3GCELL HarqPreaCap HARQ Preamble Capability Ind This parameter indicates whet

UEXT3GCELL CIO Cell oriented Cell Individual Of The CIO value specified in thi

UEXT3GCELL EFachSupInd EFachSupInd E_FACH support indicator. When

UEXT3GCELL APFlag APFlag Access point (AP) cell indicato

UEXT3GCELL VPLimitInd VPLimitInd Indicates whether the videophone

UFACH CellId Cell ID ID of a cell. For detailed inf

UFACH PhyChId SCCPCH ID ADD UFACH(Mandatory) Uniquely identifying a common

UFACH TrChId FACH ID Uniquely identifying a FACH in

UFACH RateMatchingAttr Rate Matching Attribute ADD UFACH(Optional) The rate matching factor of a t

UFACH ToAWS Time of Arrival Window StartpoADD UFACH(Mandatory) A positive value relative to Ti

UFACH ToAWE Time of Arrival Window Endpoi ADD UFACH(Mandatory) A positive value relative to La

UFACH MaxFachPower Max Transmit Power of FACH ADD UFACH(Optional) The offset between the FACH t

UFACH MaxCmchPi Max Common Channel Priorit ADD UFACH(Optional) Maximum common channel prio

UFACH MinCmchPi Min Common Channel Priority ADD UFACH(Optional) Minimum common channel prior

UFACH SigRbInd Bearing Signal Indication ADD UFACH(Optional) Indicating whether the FACH be

UFACH ChCodingType Channel Code Type ADD UFACH(Optional) The coding type of a transport

UFACH CodingRate Coding Rate ADD UFACH(Optional) The coding rate of a transport

UFACHBANDWIDTH TrafficClass Traffic class SET UFACHBANDWIDTH(MandThis parameter specifies the tr

UFACHBANDWIDTH UserPriority User Priority SET UFACHBANDWIDTH(MandUser priority that is defined

UFACHBANDWIDTH BandWidthForFACH Bandwidth of Fach SET UFACHBANDWIDTH(OptiThis parameter specifies the m

UFACHDYNTFS CellId Cell ID ID of a cell. For detailed inf

UFACHDYNTFS TrChId FACH ID Uniquely identifying a FACH in

UFACHDYNTFS RLCSize RLC Size This parameter defines the RLC

UFACHDYNTFS TFsNumber Number of TFs ADD UFACHDYNTFS(MandatoThis parameter defines the num

UFACHDYNTFS TbNumber1 TB Number of TF1 ADD UFACHDYNTFS(OptionalThis parameter defines the numb



UFACHLOCH CellId Cell ID ID of a cell. For detailed inf

UFACHLOCH TrChId FACH ID Uniquely identifying a FACH in

UFDPCHPARA FdpchPO2 F-DPCH Power Offset SET UFDPCHPARA(Optional) Offset between TPC command p

UFDPCHRLPWR FdpchMaxRefPwr FDPCH Maximum Reference SET UFDPCHRLPWR(OptionaThis parameter specifies the m

UFDPCHRLPWR FdpchMinRefPwr FDPCH Minimum Reference P SET UFDPCHRLPWR(OptionaThis parameter specifies the m

UFRC DefaultConstantValue Default Constant Value SET UFRC(Optional)

UFRC PwrCtrlAlg Power control algorithm select SET UFRC(Optional) This parameter specifies how

UFRC UlTpcStepSize UL Closed Loop Power ControlSET UFRC(Optional) Step of the closed-loop power

UFRC FddTpcDlStepSize FDD DL power control step siz SET UFRC(Optional) Step of the closed-loop power

UFRC DpcMode DL power control mode SET UFRC(Optional)

UFRC DlSaveCodeResourceSwitch DL AMR-NB Code-Resource-SaSET UFRC(Optional) This parameter specifies wheth

UFRC DlDpchPlSaveMode DL DPCH puncturing limit in t SET UFRC(Optional) This parameter specifies the p

UFRC DrxCycleLenCoef Paging DRX cycle coefficient SET UFRC(Optional)

UFRC UlBeTraffInitBitrate UL BE traffic Initial bit rate SET UFRC(Optional) UL initial access rate of PS ba

UFRC DlBeTraffInitBitrate DL BE traffic Initial bit rate SET UFRC(Optional) DL initial access rate of PS ba

UFRC UlStrTransModeOnHsupa Streaming traffic transmissi SET UFRC(Optional) E-DCH data transfer mode of st

UFRC Hsupa10msSchPrdForNonGra HSUPA TTI 10ms schedule periSET UFRC(Optional) Time interval of sending HSUPA

UFRC Hsupa2msSchPrdForNonGran HSUPA TTI 2ms schedule perioSET UFRC(Optional) Time interval of sending HSUPA

UFRC Hsupa10msSchPrdForGrant HSUPA TTI 10ms schedule periSET UFRC(Optional) Time interval of sending HSUP

UFRC Hsupa2msSchPrdForGrant HSUPA TTI 2ms schedule perioSET UFRC(Optional) Time interval of sending HSUP

UFRC HsupaInitialRate Initial rate of HSUPA BE traffic SET UFRC(Optional) HSUPA BE traffic initial bit rat

UFRC DlBeH2DInitialRate DL Rate of HSDPA BE on DC SET UFRC(Optional) DL initial access rate used w

UFRC ImsBearEnhancedSwitch IMS Bearer Enhancement Swit SET UFRC(Optional)

UFRC ImsInitialAccessRate Ims initial rate SET UFRC(Mandatory)

UFRC VoipHsupaTti HSUPA TTI type of VOIP traffi SET UFRC(Optional) TTI type used for VoIP servic

UFRC StreamHsupa2msTtiRateThs Rate Threshold of Streaming SET UFRC(Optional) Rate threshold of 2ms TTI on

UFRC BeHsupa2msTtiRateThs Rate threshold of BE on 2ms SET UFRC(Optional) This parameter specifies the r

UFRC EcN0Ths Ec/N0 threshold SET UFRC(Optional) Threshold for determining the si

UFRC EcN0EffectTime Ec/N0 effective time SET UFRC(Optional) Time duration when the reported

UFRC MacPduMaxSizeForDlL2Enha Cell_DCH DL L2 enhance max SET UFRC(Optional) This parameter specifies the

UFRC RlcPduMaxSizeForUlL2Enhan Cell_DCH UL L2 enhance max SET UFRC(Optional) This parameter specifies the

ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)

Specifies the TX diversity mode for the DC-HSDPA users.According to the protocol 3GPP TS 25.211, the DC-HSDPA feature can use STTD TX diversity mode only. For details, see 3GPP TS 25.211.ADD UEXT3GCELL(Mandatory)

MOD UEXT3GCELL(Optional)17) FDPCH_SLOT_FORMAT_SUPPORT (F-DPCH slot format support indicator): when the indicator is TRUE, it indicates that the cell supports F-DPCH slot format, which depends on FDPCH. If F-DPCH slot format is set to support in the cell, it should support FDPCH too.18) HSPAPLUS_DL_64QAM_SUPPORT (downlink 64QAM support indicator): when the indicator is TRUE, it indicates that the cell supports downlink 64QAM.This flag is valid when the OVERLAY switch is set to ON. When the flag is set to NOT_FORBIDDEN, this means that, when using the H service, the UE can deliver the intra-frequency measurement and handover to the DRNC cell, which can be used as the target cell of inter-frequency handover. When the flag is set to FORBIDDEN, this means that, when using the H service, the UE cannot deliver the intra-frequency measurement and handover to the neighboring cell, which cannot be used as the target cell of inter-frequency handover.Note that the H+CS combined service is considered as the CS service.ADD UEXT3GCELL(Optional)

MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Mandatory)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UEXT3GCELL(Optional)MOD UEXT3GCELL(Optional)ADD UFACH(Mandatory)RMV UFACH(Mandatory)

ADD UFACH(Mandatory)RMV UFACH(Mandatory)

ADD UFACHDYNTFS(Mandatory)RMV UFACHDYNTFS(Mandatory)ADD UFACHDYNTFS(Mandatory)RMV UFACHDYNTFS(Mandatory)ADD UFACHDYNTFS(Mandatory)RMV UFACHDYNTFS(Mandatory)

ADD UFACHLOCH(Mandatory)RMV UFACHLOCH(Mandatory)ADD UFACHLOCH(Mandatory)RMV UFACHLOCH(Mandatory)

Here, CPICH_RSCP is the received signal code power of the P-CPICH measured by the UE. A small value of DPCCH_Power_Offset might lead to uplink synchronization failure at cell edges during link setup, thus affecting the uplink coverage. A large value of DPCCH_Power_Offset, however, has instantaneous interference on uplink reception, thus affecting the uplink reception performance. For details, see 3GPP TS 25.331.

- TPC_AUTO_ADJUST, an automatic adjustment mode, indicates that the value of DPC_MODE can be modified by sending the ACTIVE SET UPDATE message to the UE.For details, see 3GPP TS 25.214.

UTRAN-specific Discontinuous Reception (DRX) cycle length coefficient. In connected mode, the UE uses the shorter one between CN-specific DRX cycle length coefficient and UTRAN-specific DRX cycle length coefficient. In idle mode, the UE can use the DRX mode to receive paging indications so as to reduce power consumption; in this case, the UE needs to monitor only one paging indication in one paging occasion during each DRX cycle. A value too small causes the UE to check the paging channel frequently, thus having great power consumption. A value too large makes the response of the UE to the paging slow and the core network repeatedly page the UE, thus increasing the downlink interference.

- ON: If the IMS signaling is carried on the DCH, the maximum rate of IMS signaling adopts the value of "IMS Initial Rate[kbit/s]". - OFF: The maximum rate of IMS signaling does not adopt the value of "IMS Initial Rate[kbit/s]".- If the IMS signaling is carried on the DCH in the downlink, the initial rate adopts the larger value between this parameter and the CN-assigned bit rate. - If the IMS signaling is carried on the HSPA, the MBR adopts the larger value between this parameter and the RAB-assigned bit rate.

UFRC RlcPduMinSizeForUlL2Enhan Cell_DCH UL L2 enhance min SET UFRC(Optional) This parameter specifies the

UFRC MacPduMaxSizeForEFach Cell_FACH L2 enhance max P SET UFRC(Optional) Maximum size of PDUs transmi

UFRC MIMOor64QAMSwitch Prefered MIMO or 64QAM charSET UFRC(Optional) According to the R8 protocol,

UFRC DtxDrxEnablingDelay Delay Time for DTX_DRX to TaSET UFRC(Optional) Delay time for DTX_DRX being e

UFRC RetryCapability HSPA Technologies Retried b SET UFRC(Optional) This parameter specifies which

UFRC DpcchSlotFmtForHspa Prefered DPCCH slot format f SET UFRC(Optional) Whether the DPCCH slot format

UFRC CSVoiceHsupaTti HSUPA TTI type of CS voice traSET UFRC(Optional) TTI type used for CS services

UFRC CSVoiceHspaUlRelDelay CS Voice Hspa Ul Relative De SET UFRC(Optional) Relative delay for jitter corr

UFRC CSVoiceHspaDlRelDelay CS Voice Hspa Dl Relative De SET UFRC(Optional) Relative delay for jitter corre

UFRC UlIMSTransModeOnHsupa IMS signalling transmission SET UFRC(Optional) E-DCH data transfer mode of IM

UFRC UlSRBTransModeOnHsupa SRB transmission mode on H SET UFRC(Optional) E-DCH data transfer mode of S

UFRC MIMO64QAMorDCHSDPASwitPrefered MIMO_64QAM or DC SET UFRC(Optional) This parameter specifies the

UFRC PTTArpPriorityLevel PTT ARP Priority SET UFRC(Optional) Identifies the PTT traffic. The

UFRC PTTArpPreEmptCap PTT ARP Preemption Capabili SET UFRC(Optional) Identifies the PTT traffic. The

UFRC PTTArpPreEmptVuln PTT ARP Preemption VulnerabiSET UFRC(Optional) Identifies the PTT traffic. The

UFRC PTTArpQueuingAllowed PTT ARP Queuing Allowed SET UFRC(Optional) Identifies the PTT traffic. The

UFRC PTTDrxCycleLenCoef DRX cycle coefficient of PTT u SET UFRC(Optional) UTRAN-specific Discontinuous

UFRC PTTHsupaTti PTT HSUPA TTI type SET UFRC(Optional) TTI type used for the PTT ser

UFRC DefaultSPIWeight Default SPI Weight SET UFRC(Optional) This parameter is used to spec

UFRCCHLTYPEPARA CSVoiceChlType CS voice channel type SET UFRCCHLTYPEPARA(OptChannel type of CS voice servi

UFRCCHLTYPEPARA VoipChlType VOIP channel type SET UFRCCHLTYPEPARA(Opt

UFRCCHLTYPEPARA PTTChlType PTT channel type SET UFRCCHLTYPEPARA(Opt

UFRCCHLTYPEPARA ImsChlType IMS channel type SET UFRCCHLTYPEPARA(Opt

UFRCCHLTYPEPARA SrbChlType Type of Channel Preferably CaSET UFRCCHLTYPEPARA(Opt

UFRCCHLTYPEPARA SrbChlTypeRrcEffectFlag Effective Flag of Signaling R SET UFRCCHLTYPEPARA(OptWhether the configured type of

UFRCCHLTYPEPARA UlBeTraffDecThs UL BE traffic DCH decision thr SET UFRCCHLTYPEPARA(OptRate threshold for the decision

UFRCCHLTYPEPARA DlBeTraffDecThs DL BE traffic DCH decision thr SET UFRCCHLTYPEPARA(OptRate threshold for the decision

UFRCCHLTYPEPARA DlStrThsOnHsdpa DL streaming traffic threshol SET UFRCCHLTYPEPARA(OptRate threshold for decision to

UFRCCHLTYPEPARA DlBeTraffThsOnHsdpa DL BE traffic threshold on HS SET UFRCCHLTYPEPARA(OptRate threshold for decision to

UFRCCHLTYPEPARA UlStrThsOnHsupa UL streaming traffic threshol SET UFRCCHLTYPEPARA(OptRate threshold for decision to

UFRCCHLTYPEPARA UlBeTraffThsOnHsupa UL BE traffic threshold on HS SET UFRCCHLTYPEPARA(OptThis parameter specifies the r

UHCSHO TFastSpdEst Time Window for UE Fast Spe SET UHCSHO(Optional)

UHCSHO NFastSpdEst Threshold for UE Fast Speed SET UHCSHO(Optional)

UHCSHO TCycleSlow Period for UE Slow Speed Dec SET UHCSHO(Optional)

UHCSHO TSlowSpdEst Time Window for UE Slow Spe SET UHCSHO(Optional)

UHCSHO NSlowSpdEst Threshold for UE Slow Speed SET UHCSHO(Optional)

UHCSHO TRelateLength Time Window For Ping-Pong HaSET UHCSHO(Optional)

UHOCOMM DivCtrlField Softer Handover Combination ISET UHOCOMM(Optional)

UHOCOMM HspaTimerLen HSPA Hysteresis Timer Lengt SET UHOCOMM(Optional) HSPA serving cell change is usu

UHOCOMM CoexistMeasThdChoice Inter-Freq and Inter-RAT Coex SET UHOCOMM(Optional)

UHOCOMM MaxEdchCellInActiveSet Max Number of Cell in EDCH ASET UHOCOMM(Optional) This parameter determines the

UHOCOMM IFAntiPingpangTimerLength The Timer Length of Anti Pin SET UHOCOMM(Optional) After the coverage based handov

UHSSCCHLESSOPPARA TrafficClass Traffic class SET UHSSCCHLESSOPPARA(Traffic class whose HS-SCCH L

UHSSCCHLESSOPPARA UseMacehs Mac-ehs Flag SET UHSSCCHLESSOPPARA(Whether the MAC-ehs entity is

UHSSCCHLESSOPPARA AlignMode Align Type SET UHSSCCHLESSOPPARA(Whether the configured HS-SCC

UHSSCCHLESSOPPARA TbIndexNum Configured TBS Count for H SET UHSSCCHLESSOPPARA(ONumber of Mac-hs transport b

UHSSCCHLESSOPPARA TbSizeIndex1 TB Size Index 1 SET UHSSCCHLESSOPPARA(OIndex of the Mac-hs transport

UHSSCCHLESSOPPARA HspdcchSecondCodeSupp1 Support second code Flag for SET UHSSCCHLESSOPPARA(OWhether the Mac-hs transport







UIDLEMODETIMER T300 Timer 300 SET UIDLEMODETIMER(OptioT300 is started when UE sen

UIDLEMODETIMER N300 Constant 300 SET UIDLEMODETIMER(OptioMaximum number of retrans

UIDLEMODETIMER T312 Timer 312 SET UIDLEMODETIMER(OptioT312 is started when UE starts

UIDLEMODETIMER N312 Constant 312 SET UIDLEMODETIMER(OptioMaximum number of successive

UIMEITAC TAC_FUNC The function of the TAC The function of the TAC.If Fa

UIMEITAC TAC TAC Type Allocation Code (TAC) is pa

UIMEITAC Description Description Description UE type.

- HSDPA: Uplink is preferably carried on the DCH, and downlink is preferably carried on the HS-DSCH. - HSPA: Uplink is preferably carried on the E-DCH, and downlink is preferably carried on the HS-DSCH.- HSDPA: Uplink is preferably carried on DCH, and downlink is preferably carried on HS-DSCH.- HSPA: Uplink is preferably carried on E-DCH, and downlink is preferably carried on HS-DSCH. - HSDPA: Uplink is preferably carried on the DCH, and downlink is preferably carried on the HS-DSCH. - HSPA: Uplink is preferably carried on the E-DCH, and downlink is preferably carried on the HS-DSCH.- HSUPA: Uplink is preferably carried on E-DCH, and downlink is preferably carried on DCH.- HSPA: Uplink is preferably carried on E-DCH, and downlink is preferably carried on HS-DSCH.

Time window for estimating whether the UE is in high-mobility state.The start point of the estimation is the moment of the last reporting of event 1D, and the backdated time length is determined by this parameter. If the parameter is set to 0, the RNC does not decide whether the UE is in high-mobility state.Threshold for determining whether the UE is in high-mobility state.After the UE reports event 1D, the UE is considered in high-mobility state if the number of changes of the best cell during "TFastSpdEst" is greater than this threshold. The smaller the value is, the more possible the UE is determined in high-mobility state.Period for determine whether the UE is in low-mobility state. The RNC periodically determines whether the UE is in low-mobility state. The smaller the value is, the more frequently the state estimation is triggered. If the parameter is set to 0, the RNC does not determine whether the UE is in low-mobility state.Time window for deciding whether the UE is in low-mobility state. Every time the slow speed period timer expires, the RNC estimates whether the UE is in low-mobility state. This parameter specifies the duration of the timer. If this parameter is set to 0, the RNC does not determine whether the UE is in low-mobility state.Threshold for determining whether the UE is in low-mobility state. After the UE reports event 1D, the UE is considered in low-mobility state if the number of changes of the best cell is smaller than this threshold within the period of "TSlowSpdEst". The greater the value is, the more possible the UE is determined in low-mobility state.Time window for determining whether ping-pong handover occurs in the best cell during the UE speed estimation. In the speed estimation algorithm, an algorithm is adopted to avoid inaccurate estimation caused by frequent handovers of best cells. That is, during the latest "TRELATELENGTH", if more than one event 1D of a certain cell occurs, the event 1D record is restored to the state when the 1st event 1D occurs during the latest "TRELATELENGTH". The given time length is set by this parameter. If this parameter is set too great, the RNC may mistakenly determine that ping-pong handover to the best cell occurs. If this parameter is set too small, ping-pong handover cannot be prevented. Thus, it is recommended that this parameter be set according to the cell radius.There are two combination methods for uplink combination of soft handover: one is maximum ratio combination at the NodeB Rake receiver, which gives the highest combination gain; the other is selective combination at the RNC, which gives a relatively smaller combination gain. The default value of the indication switch is MAY, which means the NodeB decides whether to implement maximum ratio combination according to its own physical conditions; when MUST is selected, the NodeB is forced to carry out maximum ratio combination which is usually used in tests; when MUST_NOT is selected, the NodeB is forbidden to carry out maximum ratio combination.Consider the working status (test/normal operation) and the propagation environment when deciding whether to implement softer combination and to adopt which kind of softer combination.

When COEXIST_MEAS_THD_CHOICE_INTERRAT is selected, event 2D/2F measurement thresholds oriented towards inter-RAT configuration are selected.The factors such as the event 2D/2F measurement thresholds for inter-frequency measurement and inter-RAT measurement, inter-frequency and inter-RAT handover decision thresholds, and current handover policy should be considered during setting. For example, if the event 2D threshold for inter-RAT measurement is higher than that for inter-frequency measurement, and inter-frequency neighboring cells are preferred when inter-RAT and inter-frequency neighboring cells coexist, then COEXIST_MEAS_THD_CHOICE_INTERFREQ should be selected.

MOD UIMEITAC(Mandatory)RMV UIMEITAC(Mandatory)MOD UIMEITAC(Mandatory)RMV UIMEITAC(Mandatory)ADD UIMEITAC(Mandatory)MOD UIMEITAC(Optional)

UIMEITAC FastDormancy Fast Dormancy Switch The switch of Fast Dormancy fu

UIMEITAC PROCESSSWITCH Process switch

UIMSIIDNNSCNIDMAP CnOpIndex Cn Operator Index Represent an index for a CN o

UIMSISNAMAP ImsiMin The start of IMSI The minimum of one IMSI rang

UIMSISNAMAP ImsiMax The end of IMSI The maximum of one IMSI ran

UIMSISNAMAP MCC Mobile country code The code of the country to wh

UIMSISNAMAP MNC Mobile network code The code of the mobile commun

UIMSISNAMAP SnaExistInd SNAC Configuration Indication

UIMSISNAMAP SNAC Sharing Network Area Code Sharing Network Area Code.

UINTERFREQHOCOV InterFreqReportMode Inter-frequency Measure Repo SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqFilterCoef Inter-frequency Measure Filter SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV PrdReportInterval Inter-frequency Measure Perio SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV HystFor2B 2B Hysteresis SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV HystFor2D 2D Hysteresis SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV HystFor2F 2F Hysteresis SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV HystForPrdInterFreq HHO Hysteresis SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV WeightForUsedFreq Weight for Used frequency SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV TimeToTrig2B Event 2B Trigger Delay SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV TimeToTrig2D Event 2D Trigger Delay SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV TimeToTrig2F Event 2F Trigger Delay SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV TimeToTrigForPrdInterFreq HHO Period Trigger Delay SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqCSThd2DEcN0 Inter-freq CS Measure Start SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqCSThd2FEcN0 Inter-freq CS Measure Stop E SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqR99PsThd2DEcN0 Inter-freq R99 PS Measure St SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqHThd2DEcN0 Inter-freq H Measure Start Ec SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqR99PsThd2FEcN0 Inter-freq R99 PS Measure St SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqHThd2FEcN0 Inter-freq H Measure Stop Ec SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqCSThd2DRSCP Inter-freq CS Measure Start SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqCSThd2FRSCP Inter-freq CS Measure Stop SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqR99PsThd2DRSCP Inter-freq R99 PS Measure S SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqHThd2DRSCP Inter-freq H Measure Start R SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqR99PsThd2FRSCP Inter-freq R99 PS Measure S SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqHThd2FRSCP Inter-freq H Measure Stop R SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV TargetFreqCsThdEcN0 Inter-freq CS Target Frequenc SET UINTERFREQHOCOV(OptThreshold of the target freque

UINTERFREQHOCOV TargetFreqR99PsThdEcN0 Inter-freq R99 PS Target Fre SET UINTERFREQHOCOV(OptThreshold of the target freque

UINTERFREQHOCOV TargetFreqHThdEcN0 Inter-freq HSPA Target Frequ SET UINTERFREQHOCOV(OptThreshold of the target freque

UINTERFREQHOCOV TargetFreqCsThdRscp Inter-freq CS Target Frequen SET UINTERFREQHOCOV(OptThreshold of the target freque

UINTERFREQHOCOV TargetFreqR99PsThdRscp Inter-freq R99 PS Target Fre SET UINTERFREQHOCOV(OptThreshold of the target freque

UINTERFREQHOCOV TargetFreqHThdRscp Inter-freq HSPA Target Frequ SET UINTERFREQHOCOV(OptThreshold of the target freque

UINTERFREQHOCOV UsedFreqCSThdEcN0 Inter-freq CS Used frequency SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV UsedFreqR99PsThdEcN0 Inter-freq R99 PS Used freque SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV UsedFreqHThdEcN0 Inter-freq H Used frequency t SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV UsedFreqCSThdRSCP Inter-freq CS Used frequency SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV UsedFreqR99PsThdRSCP Inter-freq R99 PS Used frequ SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV UsedFreqHThdRSCP Inter-freq H Used frequency t SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV InterFreqMeasTime Inter-freq Measure Timer Leng SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV PeriodFor2B 2B Event Retry Period SET UINTERFREQHOCOV(OptSets the interval between the f

UINTERFREQHOCOV AmntOfRpt2B 2B Event Retry Max Times SET UINTERFREQHOCOV(Opt

UINTERFREQHOCOV TimeToInterfreqHO Inter-freq Coverage Handover SET UINTERFREQHOCOV(Opt

UINTERFREQHONCOV InterFreqFilterCoef Inter-frequency Measure Filter SET UINTERFREQHONCOV(Op

UINTERFREQHONCOV Hystfor2C 2C Hysteresis SET UINTERFREQHONCOV(Op

UINTERFREQHONCOV TrigTime2C Event 2C Trigger Delay SET UINTERFREQHONCOV(Op

UINTERFREQHONCOV InterFreqNCovHOThdEcN0 Inter-freq measure target freq SET UINTERFREQHONCOV(Op

UINTERFREQHONCOV InterFreqMeasTime Inter-freq Measure Timer Leng SET UINTERFREQHONCOV(Op

UINTERFREQHONCOV PeriodFor2C 2C Event Retry Period SET UINTERFREQHONCOV(Op

UINTERFREQHONCOV AmntOfRpt2C Event 2C Retry Max Times SET UINTERFREQHONCOV(Op

UINTERFREQNCELL RNCId RNC ID ID of an RNC

UINTERFREQNCELL CellId Cell ID Unique ID of a cell

UINTERFREQNCELL NCellRncId RNC ID of a neighboring cell Unique RNC ID of a neighborin

UINTERFREQNCELL NCellId Neighboring Cell ID Unique ID of a neighboring cell

UINTERFREQNCELL CIOOffset Neighboring Cell Oriented CIO

ADD UIMEITAC(Optional)MOD UIMEITAC(Optional)ADD UIMEITAC(Optional)MOD UIMEITAC(Optional)

When this switch is off, the UE does not transit from CELL_PCH or URA_PCH state to CELL_DCH state even if the RNC receives a CELL UPDATE message containing a cause value of "uplink data transmission" or "paging response" of PS domain.The state transition of the UE from CELL_PCH or URA_PCH to CELL_DCH, however, can be triggered in other conditions. For example, the state transition from CELL_PCH or URA_PCH to CELL_DCH is triggered by a UE-terminated CS call.ADD UIMSIIDNNSCNIDMAP(Mandatory)

RMV UIMSIIDNNSCNIDMAP(Mandatory)ADD UIMSISNAMAP(Mandatory)RMV UIMSISNAMAP(Mandatory)ADD UIMSISNAMAP(Mandatory)RMV UIMSISNAMAP(Mandatory)ADD UIMSISNAMAP(Mandatory)RMV UIMSISNAMAP(Mandatory)ADD UIMSISNAMAP(Mandatory)RMV UIMSISNAMAP(Mandatory)ADD UIMSISNAMAP(Mandatory)RMV UIMSISNAMAP(Mandatory)

TRUE: The SNAC need be configured. FALSE: The SNAC need not be configured.UE can access any cell of the PLMN.ADD UIMSISNAMAP(Mandatory)

RMV UIMSISNAMAP(Mandatory)The advantage of the periodical measurement report mode is that it can repeatedly perform direct retry on the same cell when the handover fails, and that the following algorithms can be flexibly developed. For the cell-oriented algorithm parameters, the UE need not be informed through signaling but the cell need be updated only when the handover decision is performed in the RNC. The disadvantage of the periodical measurement report mode is that it requires large amount of signaling and increases the load on the air interface and for signaling processing. As for the impact on network performance,the two measurement report modes have both advantages and disadvantages. Currently, the traditional periodical report mode is preferred.This parameter specifies the Layer 3 filter coefficient for the inter-frequency measurementThis parameter has the same physical significance and measurement model as the layer 3 filter coefficient for the intra-frequency measurement. The difference is that the report period of the inter-frequency measurement is 480 ms while the report period of the intra-frequency measurement is 200 ms. In practice, the setting of this parameter can be adjusted according to performance statistics.Interval between periodic reporting for the inter-frequency handover. In periodic reporting mode, the inter-frequency handover attempts is reported at the preset interval. It is not recommended that this parameter be set to "NON_PERIODIC_REPORT" since the UE behavior may be unknown. This parameter has impact on the Uu signaling flow. If the interval is too short and the frequency is too high, the RNC may have high load when processing signaling. If the interval is too long, the network cannot detect the signal changes in time. This may delay the inter-frequency handover, thus causing call drops.Hysteresis for triggering event 2B.The value of this parameter is associated with the slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change and thus event 2B may not be triggered in time.When "InterFreqReportMode" is set to PERIODICAL_REPORTING, the hysteresis in active set quality measurement is used to prevent the ping-pong reporting of event 2D (triggered when the estimated quality of the frequency in use is lower than the threshold) and event 2F (triggered when the estimated quality of the frequency in use is higher than the threshold). Event 2D is used to enable the compression mode and event 2F is used to disable the compression mode. To prevent the compression mode from being frequently enabled and disabled, you can set "Hystfor2D" and "Hystfor2F" to be greater than their recommended values according to the statistics of the ping-pong inter-frequency handover.To set "Hystfor2D" and "Hystfor2F", you should consider the radio environment (with slow fading characteristics), actual handover distance, and moving speed of the UE. The value of this parameter ranges from 2 dB to 5 dB. In addition, filter coefficient and trigger delay must be considered in setting this parameter.When "InterFreqReportMode" is set to PERIODICAL_REPORTING, the hysteresis in active set quality measurement is used to prevent the ping-pong reporting of event 2D (triggered when the estimated quality of the frequency in use is lower than the threshold) and event 2F (triggered when the estimated quality of the frequency in use is higher than the threshold). Event 2D is used to enable the compression mode and event 2F is used to disable the compression mode. To prevent the compression mode from being frequently enabled and disabled, you can set "Hystfor2D" and "Hystfor2F" to be greater than their recommended values according to the statistics of the ping-pong inter-frequency handover.To set "Hystfor2D" and "Hystfor2F", you should consider the radio environment (with slow fading characteristics), actual handover distance, and moving speed of the UE. The value of this parameter ranges from 2 dB to 5 dB. In addition, filter coefficient and trigger delay must be considered in setting this parameter.Hysteresis in the inter-frequency hard handover triggered by the periodic measurement report.This parameter is used to estimate the inter-frequency handover on the RNC side. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change and thus the handover may not be triggered in time.The parameter WeightForUsedFreq is the frequency weighting factor used to calculate the quality of the current frequency. If this parameter is set to a greater value, the higher quality of the active set is obtained. If this parameter is set to 0, the general quality of the active set is considered the quality of the best cell in this set. For details about this parameter, see the subsection of frequency quality estimation in the section of inter-frequency measurement in 3GPP TS 25.331. This parameter is used for event-triggered reporting of inter-frequency handovers for events 2D, 2F, 2B and 2C, but not used for periodical reporting of inter-frequency handovers.Interval time between the detection of event 2B and sending of measurement report. This parameter correlates with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.Interval time between detection of event 2D and sending of the measurement report. This parameter correlates with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.Interval time between detection of event 2F and sending of the measurement report.This parameter correlates with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.Interval between reception of periodical reports and triggering of the inter-frequency handover. Only the inter-frequency cell in which the signal quality is above a certain threshold in all periodic reports during a time equal to this parameter can be selected as the target cell for the inter-frequency handover. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.For the cell in which the UEs are moving at various speeds, set this parameter to -14 dB. The emulation result shows that the call drop rate remains low for the UEs moving at a speed of 120 km/h when this parameter is set to -14 dB.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.When Ec/No is used as the measurement quantity for CS services, the UE reports event 2F when the measured Ec/No value is higher than the value of this parameter. Then, the RNC sends the signaling to disable the compression mode and stop the inter-frequency measurement. Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.For the cell in which the UEs are moving at various speeds, set this parameter to -14 dB. The emulation result shows that the call drop rate remains low for the UEs moving at a speed of 120 km/h when this parameter is set to -14 dB.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.For the cell in which the UEs are moving at various speeds, set this parameter to -14 dB. The emulation result shows that the call drop rate remains low for the UEs moving at a speed of 120 km/h when this parameter is set to -14 dB.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.When Ec/No is used as the measurement quantity for PS non-HSPA services, the UE reports event 2F when the measured Ec/No value is higher than the value of this parameter. Then, the RNC sends the signaling to disable the compression mode and stop the inter-frequency measurement.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.When Ec/No is used as the measurement quantity for HSPA services, the UE reports event 2F when the measured Ec/No value is higher than the value of this parameter. Then, the RNC sends the signaling to disable the compression mode and stop the inter-frequency measurement. Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.When the signals at the entrance to an elevator or a subway change too fast to perform handover, set this parameter to -90 dBm to enable the compression mode earlier.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F. When the signals at the entrance to an elevator or a subway change too fast to perform handover, set this parameter to -85 dBm to enable the compression mode earlier.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.When the signals at the entrance to an elevator or a subway change too fast to perform handover, set this parameter to -90 dBm to enable the compression mode earlier.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F.When the signals at the entrance to an elevator or a subway change too fast to perform handover, set this parameter to -90 dBm to enable the compression mode earlier.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F. When the signals at the entrance to an elevator or a subway change too fast to perform handover, set this parameter to -85 dBm to enable the compression mode earlier.Event 2D and event 2F are used to enable and disable the compression mode respectively. To enable the compression mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compression mode, increase the difference between the thresholds of triggering event 2D and event 2F. When the signals at the entrance to an elevator or a subway change too fast to perform handover, set this parameter to -85 dBm to enable the compression mode earlier.

Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of Ec/No for CS services.For CS services, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of Ec/No for non-HSPA services in PS domain.For non-HSPA services in PS domain, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of Ec/No for HSPA services.For HSPA services, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of RSCP for CS services.For CS services, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of RSCP for non-HSPA services in PS domain.For non-HSPA services in PS domain, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.Threshold of used frequency quality for triggering inter-frequency measurement based on measurement quantity of RSCP for HSPA services.For HSPA services, if the value of "Inter-frequency Measurement Report Mode" is set to EVENT_TRIGGER, this parameter is used to set the measurement control of event 2B. One of the necessary conditions for triggering event 2B can be met only when the quality of the target frequency is smaller than this threshold. In addition, event 2B is triggered only when both the necessary conditions are met. After handover, even if the inter-frequency measurement is triggered again, it is very difficult to hand over the UE again to the cell of currently used frequency. That is, this parameter is usually set smaller than the start threshold for event 2F or equal to the threshold of event 2D.If the inter-frequency handover is not performed before this timer expires, the inter-frequency measurement is stopped and the compression mode is disabled (if enabled before). The value 0 indicates that this timer is not to be started.This parameter is used to prevent the long duration of the inter-frequency measurement state (compression mode) due to unavailability of a target cell that meets the handover criteria.

If this parameter is set to a greater value, the number of inter-frequency handover re-attempts increases and the possibility of successfully handing over the UE to the target cell whose load becomes normal increases. When the number of inter-frequency handover re-attempts reaches the threshold, the RNC sends another inter-frequency measurement control message to allow the UE to be handed over to other cells of this frequency.If the measurement control is released, the inter-frequency handover re-attempt is stopped.If the inter-frequency coverage handover priority of the cell reporting the MR is equal to the highest priority of the target cell defined in the measurement control list, the inter-frequency handover is triggered. If the inter-frequency coverage handover priority of the cell reporting the MR is lower than the highest priority of the target cell defined in the measurement control list, the inter-freq coverage handover delay timer is enabled. When the timer expires, the inter-freq handover is triggered.This parameter specifies the Layer 3 filter coefficient for the inter-frequency measurementThis parameter has the same physical significance and measurement model as the layer 3 filter coefficient for the intra-frequency measurement. The difference is that the report period of the inter-frequency measurement is 480 ms while the report period of the intra-frequency measurement is 200 ms. In practice, the setting of this parameter can be adjusted according to performance statistics.Hysteresis used for event 2C.The value of this parameter is associated with the slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change and thus event 2C may not be triggered in time.The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change.The emulation results show that setting this interval can effectively reduce the average number of handovers and the number of incorrect handovers, preventing unnecessary handovers. In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to this interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to this interval. Therefore, for the cell with most of the fast-moving UEs, this parameter can be set to a smaller value, whereas for the cell with most of the slow-moving UEs, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.This parameter is used to set measurement control on the event 2C.The event 2C is triggered when the signal quality of the target frequency is above this threshold.If the inter-frequency handover is not performed before this timer expires, the inter-frequency measurement is stopped and the compression mode is disabled (if enabled before). The value 0 indicates that this timer is not to be started.This parameter is used to prevent the long duration of the inter-frequency measurement state (compression mode) due to unavailability of a target cell that meets the handover criteria.Interval between the handover re-attempts for event 2C. If the inter-frequency handover for event 2C fails, the RNC reties the inter-frequency handover. This parameter specifies the interval between the handover re-attempts for event 2C. If this parameter is set to a smaller value, handover re-attempts increase when the inter-frequency handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced. The RNC load, however, increases.Maximum number of handover attempts for event 2C. This parameter specifies the maximum number of handover re-attempts for event 2C when the measurement control message is valid. If this parameter is set to a greater value, inter-frequency handover re-attempts increase and the possibility of successfully handing over the UE to the target cell whose load becomes normal increases. When the number of re-attempts reaches the preset value, the RNC does not attempt to perform the handover. Alternatively, when the measurement control is cancelled, the handover re-attempt is stopped immediately.RMV UINTERFREQNCELL(Mandatory)

MOD UINTERFREQNCELL(Mandatory)RMV UINTERFREQNCELL(Mandatory)MOD UINTERFREQNCELL(Mandatory)RMV UINTERFREQNCELL(Mandatory)MOD UINTERFREQNCELL(Mandatory)RMV UINTERFREQNCELL(Mandatory)MOD UINTERFREQNCELL(Mandatory)ADD UINTERFREQNCELL(Optional)MOD UINTERFREQNCELL(Optional)

This parameter specifies the neighboring cell oriented Cell Individual Offset (CIO). The sum of the value of this parameter, the value of the cell oriented CIO, and the actual measurement quantity is used for the event evaluation of the UE or used for the handover decision procedure on the RNC side. In a handover algorithm, this parameter is used for moving the border of a cell. In the case of an event-based intra-frequency measurement or inter-RAT measurement, the UE determines whether to trigger an event according to the sum of the value of this parameter, the value of the cell oriented CIO, and the actual measurement quantity. The UE does not consider the value of this parameter when evaluating an inter-frequency measurement event. In the case of a periodical inter-frequency measurement or inter-RAT measurement, the RNC determines whether to initiate a handover according to the sum of the value of this parameter, the value of the cell.

UINTERFREQNCELL SIB11Ind SIB11 Indicator

UINTERFREQNCELL IdleQoffset1sn IdleQoffset1sn

UINTERFREQNCELL IdleQoffset2sn IdleQoffset2sn

UINTERFREQNCELL SIB12Ind SIB12 Indicator

UINTERFREQNCELL ConnQoffset1sn ConnQoffset1sn Cell offset used for CPICH RSC

UINTERFREQNCELL ConnQoffset2sn ConnQoffset2sn Cell offset used for CPICH Ec/

UINTERFREQNCELL TpenaltyHcsReselect HCS Cell Reselect Penalty Ti

UINTERFREQNCELL TempOffset1 HCS Cell Reselect TempOffse

UINTERFREQNCELL TempOffset2 HCS Cell Reselect TempOffse

UINTERFREQNCELL HOCovPrio Priority of Coverage-Based In

UINTERFREQNCELL BlindHoFlag Blind Handover Flag

UINTERFREQNCELL BlindHOQualityCondition Blind Handover Quality Condit

UINTERFREQNCELL NPrioFlag Neighboring Cell Priority Flag

UINTERFREQNCELL NPrio Priority of Neighboring Cell The priority that corresponds t

UINTERFREQNCELL DRDEcN0Threshhold Drd Ec/N0 Threshold DRD Ec/No threshold for determi

UINTERFREQNCELL MBDRFlag Flag of MBDR Cell

UINTERFREQNCELL MBDRPrio MBDR Cell Periority

UINTERFREQNCELL DrdOrLdrFlag DrdOrLdrFlag

UINTERFREQNCELL InterNCellQualReqFlag Neighboring Cell Quality Guara

UINTERFREQNCELL Qqualmin Min Quality Level

UINTERFREQNCELL Qrxlevmin Min RX Level Minimum CPICH RSCP for the nei

UINTERRATHOCOV InterRatReportMode Inter-RAT Report Mode SET UINTERRATHOCOV(Optio

UINTERRATHOCOV FilterCoefOf2D2F 2D/2F Filter Coefficient SET UINTERRATHOCOV(Optio

UINTERRATHOCOV MeasQuantityOf3A 3A Measure Quantity SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATFilterCoef Inter-RAT Filter Coefficient SET UINTERRATHOCOV(Optio

UINTERRATHOCOV WeightForUsedFreq Weight for Used Frequency SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATPeriodReportInterval Inter-RAT Period Reporting Int SET UINTERRATHOCOV(Optio

UINTERRATHOCOV Hystfor2D 2D Hysteresis SET UINTERRATHOCOV(Optio

UINTERRATHOCOV Hystfor2F 2F Hysteresis SET UINTERRATHOCOV(Optio

UINTERRATHOCOV Hystfor3A 3A Hysteresis SET UINTERRATHOCOV(Optio

UINTERRATHOCOV HystforInterRAT Inter-RAT Hysteresis SET UINTERRATHOCOV(Optio

UINTERRATHOCOV TrigTime2D 2D Event Trigger Delay Time SET UINTERRATHOCOV(Optio

UINTERRATHOCOV TrigTime2F 2F Event Trigger Delay Time SET UINTERRATHOCOV(Optio

UINTERRATHOCOV TrigTime3A 3A Event Trigger Delay Time SET UINTERRATHOCOV(Optio

UINTERRATHOCOV TimeToTrigForNonVerify Time to Trigger Handover to N SET UINTERRATHOCOV(Optio

UINTERRATHOCOV TimeToTrigForVerify Time to Trigger Handover to V SET UINTERRATHOCOV(Optio

UINTERRATHOCOV BSICVerify BSIC Verify Switch SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATCSThd2DEcN0 Inter-RAT CS Measure Start SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATCSThd2FEcN0 Inter-RAT CS Measure Stop E SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATR99PsThd2DEcN0 Inter-RAT R99 PS Measure St SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATHThd2DEcN0 Inter-RAT HSPA Measure Star SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATR99PsThd2FEcN0 Inter-RAT R99 PS Measure St SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATHThd2FEcN0 Inter-RAT HSPA Measure Sto SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATCSThd2DRSCP Inter-RAT CS Measure Start SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATCSThd2FRSCP Inter-RAT CS Measure Stop SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATR99PsThd2DRSCP Inter-RAT R99 PS Measure S SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATHThd2DRSCP Inter-RAT HSPA Measure Sta SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATR99PsThd2FRSCP Inter-RAT R99 PS Measure S SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATHThd2FRSCP Inter-RAT HSPA Measure St SET UINTERRATHOCOV(Optio

UINTERRATHOCOV TargetRatCsThd Inter-RAT CS Handover Decis SET UINTERRATHOCOV(Optio

UINTERRATHOCOV TargetRatR99PsThd Inter-RAT R99 PS Handover D SET UINTERRATHOCOV(Optio

UINTERRATHOCOV TargetRatHThd Inter-RAT HSPA Handover De SET UINTERRATHOCOV(Optio

UINTERRATHOCOV UsedFreqCsThdEcN0 Inter-RAT CS Used Frequency SET UINTERRATHOCOV(Optio

UINTERRATHOCOV UsedFreqR99PsThdEcN0 Inter-RAT R99 PS Used Frequ SET UINTERRATHOCOV(Optio

UINTERRATHOCOV UsedFreqHThdEcN0 Inter-RAT HSPA Used FrequenSET UINTERRATHOCOV(Optio

UINTERRATHOCOV UsedFreqCsThdRscp Inter-RAT CS Used Frequenc SET UINTERRATHOCOV(Optio

UINTERRATHOCOV UsedFreqR99PsThdRscp Inter-RAT R99 PS Used Freq SET UINTERRATHOCOV(Optio

UINTERRATHOCOV UsedFreqHThdRscp Inter-RAT HSPA Used Freque SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATMeasTime Inter-RAT Measure Timer LengSET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATPingPongTimer Inter-RAT Ping-Pong Timer SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRATPingPongHyst Inter-RAT Ping-Pong Hysteres SET UINTERRATHOCOV(Optio

ADD UINTERFREQNCELL(Optional)MOD UINTERFREQNCELL(Optional)

Indicates whether to send the system information block 11 (SIB11) including neighboring cell information. The value "FALSE" indicates that the neighboring information is not included in the SIB11. The value "TRUE" indicates that the neighboring information is included in the SIB11.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Mandatory)Note that in FDD mode, this parameter is valid only when SIB11 Indicator is set as TRUE.For details, see 3GPP TS 25.331.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Mandatory)Note that in FDD mode, this parameter is valid only when SIB11 Indicator is set as TRUE.For details, see 3GPP TS 25.331.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Optional)Indicates whether to send the SIB12 indication including the neighboring cell information. The value "FALSE" indicates that the neighboring information is not included in the SIB12. The value "TRUE" indicates that the neighboring information is included in the SIB12.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Mandatory)ADD UINTERFREQNCELL(Optional)MOD UINTERFREQNCELL(Mandatory)ADD UINTERFREQNCELL(Optional)MOD UINTERFREQNCELL(Optional)

Specifies the penalty time for cell reselection. If this parameter is set to a greater value, the penalty time for HCS cell reselection is prolonged. If this parameter is set to a smaller value, the penalty time for HCS cell reselection is shortened. When the UE is in idle mode, the ping-pong reselections between HCS cells reduces if this parameter is set to a greater value. In this case, however, the hierarchical cell structure cannot be deployed effectively.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Mandatory)Cell offset used for CPICH RSCP measurement value in HCS cell selection. If this parameter is set to a greater value, the probability for selecting a neighboring cell reduces. If this parameter is set to a smaller value, the probability for selecting a neighboring cell increases. If this parameter is set to "INFINITY", a neighboring cell is not selected.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Mandatory)Cell offset used for CPICH Ec/No measurement value in HCS cell selection. If this parameter is set to a greater value, the probability for cell reselection reduces. If this parameter is set to a smaller value, the probability for cell reselection increases. If this parameter is set to "INFINITY", a neighboring cell is not selected.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Optional)Priority for neighboring cell supporting coverage-based inter-frequency handover. The value "0" indicates that the coverage-based inter-frequency handover is not supported. The value "1" indicates that the cell is assigned with the highest priority for the handover. The value "3" indicates that the cell is assigned with the lowest priority for the handover. If a higher priority is assigned to a cell, the probability for selecting the cell as the measurement object and the target cell for the handover increases. For example, the cell with priority 1 has more chance to select as the measurement object and the target cell for the handover than the cell with priority 2.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Optional)Whether to perform blind handover.The value FALSE indicates that the cell is not considered as a candidate cell for blind handover. Therefore, blind over to this cell cannot be triggered.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Optional)Quality condition for triggering the blind handover. If this parameter is not set to -115, a conditional blind handover can be triggered in an inter-frequency neighboring cell with the same coverage. If this parameter is set to -115, a direct blind handover can be triggered in an inter-frequency neighboring cell with the larger coverage.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Optional)Priority flag of neighboring cellsThe value TRUE indicates that the neighboring cell priority is valid, and the value FALSE indicates that the neighboring cell priority is invalid. In the algorithm of neighboring cell combination, the cell with an invalid priority is the last one to be considered as the measurement object.ADD UINTERFREQNCELL(Mandatory)

MOD UINTERFREQNCELL(Mandatory)ADD UINTERFREQNCELL(Optional)MOD UINTERFREQNCELL(Optional)ADD UINTERFREQNCELL(Optional)MOD UINTERFREQNCELL(Optional)

Whether the cell supports the measure-based directed retry (MBDR) algorithm. The value TRUE indicates that the cell supports the MBDR algorithm, and the value FALSE indicates that the cell does not support the MBDR algorithm.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Optional)Priority of a MBDR cell. This parameter is valid only when the "MBDRFlag" parameter is set to TRUE. It indicates the tiptop priority when the value is set to 0, and the lowest priority when the value is set to 15. The higher the priority, the easier it is for the MBDR cell to be delivered as the measurement object and the easier to be selected to the handover target cell when there are many of cells meet the quality condition. Attention, when there does not have cell meet the quality condition base on the MBDR measurement result, if there exists a cell which has the priority of 0, and the type of the measurement report is periodic, then it can be selected to blind handover target cell.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Optional)Specify the flags of the cells that the DRD measurement or LDR measurement is performed. The value "TRUE" indicates that the cell can be considered as the measurement object in the DRD measurement algorithm or LDR measurement algorithm. The value "FALSE" indicates that the cell is invalid.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Optional)Indicates whether the signal quality in neighboring cells is guaranteed. If the parameters Qqualmin and Qrxlevmin for the neighboring cell related to SIB11 and SIB12 are set to different values from those for the serving cell, this parameter should be set to "TRUE". Cell reselection is performed only when the signal quality in the expected neighboring cell is above Qqualmin and Qrxlevmin.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Mandatory)"UE_TXPWR_MAX_RACH", also named as "MaxAllowedULTxPower", refers to the maximum uplink transmit power when the UE accesses a cell."P_MAX" refers to the maximum RF output power of the UE.ADD UINTERFREQNCELL(Optional)

MOD UINTERFREQNCELL(Mandatory)The advantage of periodical reporting is that it can be used for repeated handover re-attempts on the same cell when the handover fails, and that subsequent algorithms can be flexibly developed. In addition, for the cell-oriented algorithm parameters, the RNC updates the parameters when making internal handover decision and the system needs not to inform the UEs of the parameter change through signaling messages after the handovers. The drawback of periodical reporting is that it requires large amount of signaling and increases the load on the air interface and for signaling processing.The two reporting modes have both advantage and drawback. Currently, the traditional periodical reporting mode is preferred.In cells where the average moving speed of UEs is medium, there is a comparatively smaller shadow fading square error. Therefore, the recommended value is 3. In cells where the average moving speed of UEs is high, there is a comparatively small shadow fading square error. Therefore, the recommended value is 2.When CPICH_RSCP is selected, it indicates that the RSCP measurement quantity is used for event 3A measurement. The physical unit is dBm.When AUTO is selected, it indicates that the Ec/No measurement quantity is used for event 3A measurement if the RNC receives Ec/No 2D firstly. If the RNC receives the RSCP 2D firstly, the RSCP measurement quantity is used for event 3A measurement.In cells where the average moving speed of UEs is medium, there is a comparatively smaller shadow fading square error. Therefore, the recommended value is 3. In cells where the average moving speed of UEs is high, there is a comparatively small shadow fading square error. Therefore, the recommended value is 2.This parameter is used for event 3A evaluation. For detailed information of this parameter, refer to 3GPP TS 25.133.To set this parameter, see the method for setting the intra-frequency handover weighting factor "Weight".The adjustment should be made according to the configured GSM RSSI measurement compressed mode sequence. According to the current configured GSM RSSI measurement compressed mode sequence, the RSSI measurement of eight GSM cells can be finished in 480 ms. Therefore, the RSSI measurement of 16 GSM cells can be finished in 1000 ms. According to 3GPP specifications, the number of inter-RAT neighboring cells should not exceed 32. Therefore, the parameter value can be set to 2000 ms if the number of neighboring GSM cells exceeds 16.The setting of this parameter has impact on the Uu signaling traffic. If the period is too short and the reporting frequency is too high, the RNC may have high load in processing signaling. If the period is too long, the network cannot detect the signal changes in time, which may delay the inter-RAT handover and thus cause call drops.This parameter is used to avoid the ping-pong reporting of event 2D (the estimated quality of the currently used frequency is below a certain threshold). The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of ping-pong reporting or wrong decision is lower, but the event may not be triggered in time. If this parameter is set to a smaller value, ping-pong reporting of event 2D is likely to occur.The setting of this parameter should consider the radio conditions (slow fading), actual handover distance, and moving speed of the UE. The value of this parameter ranges from 2 dB to 5 dB. In addition, filter coefficient and triggering delay must be considered in setting this parameter.The inter-RAT measurement hysteresis in periodical reporting mode is used to prevent the ping-pong reporting of event 2D (the estimated quality of the currently used frequency is below a certain threshold) and event 2F (the estimated quality of the currently used frequency is above a certain threshold). Event 2D is used to enable the compressed mode and event 2F is used to disable the compressed mode. "Hystfor2D" can be increased slightly based on the recommended value, considering inter-frequency handover statistics. Hystfor2D can also be increased slightly to prevent the compressed mode from being frequently enabled and disabled and to avoid unnecessary active set updates. The setting of this parameter should consider the radio conditions (slow fading), actual handover distance, and moving speed of the UE. The value of this parameter ranges from 2 dB to 5 dB. In addition, filter coefficient and triggering delay must be considered in setting this parameter.The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change. If this parameter is set to a larger value, the cell of another RAT where the UE needs to be handed over to must be of good quality. Therefore, the criteria for triggering the inter-RAT handover decision is hard to be fulfilled, and the call drop rate will increase.The emulation result shows that in a cell where the average moving speed of UEs is high (for example, a cell that covers highways), this parameter can be set to a smaller value 1.5 dB, because in the cell the terrain is flat, barriers are fewer, and thus the shadow fading variation is small. In a cell where the average moving speed of UEs is low, this parameter can be set to a larger value 3.0 dB, because there are usually many tall buildings and thus the shadow fading variation is comparatively high.If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change. If this parameter is set to a larger value, the cell of another RAT where the UE needs to be handed over to must be of good quality. Therefore, the criteria for triggering the inter-RAT handover decision is hard to be fulfilled, and the call drop rate will increase.The emulation result shows that in a cell where the average moving speed of UEs is high (for example, a cell that covers highways), this parameter can be set to a smaller value 1.5 dB, because in the cell the terrain is flat, barriers are fewer, and thus the shadow fading variation is small. In a cell where the average moving speed of UEs is low, this parameter can be set to a larger value 3.0 dB, because there are usually many tall buildings and thus the shadow fading variation is comparatively high.The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation result shows that the hysteresis setting can effectively reduce the average number of handovers and the number of incorrect handovers, thus preventing unnecessary handovers. The emulation result also shows that the UE at different data rates may react differently to the delay for triggering the event. For the fast-moving UE, the call drop rate is more sensitive to the delay, whereas, for the slow-moving UE, the call drop rate is less sensitive to the delay. This can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change. The emulation result shows that the hysteresis setting can effectively reduce the average number of handovers and the number of incorrect handovers, thus preventing unnecessary handovers. The emulation result also shows that the UE at different data rates may react differently to the delay for triggering the event. For the fast-moving UE, the call drop rate is more sensitive to the delay, whereas, for the slow-moving UE, the call drop rate is less sensitive to the delay. This can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value. The value of this parameter can be adjusted according to the actual network statistics.The inter-frequency measurement reporting period is 480 ms. Therefore, the trigger delay time shorter than 480 ms is invalid.If the parameter is set to a larger value, handover is unlikely to be triggered. However, call drops may increase as the parameter value increases.Time delay for triggering handovers to GSM cells with non-verified BSIC.During the period of time specified by this parameter, if the signal quality in a neighboring GSM cell fulfills inter-RAT handover criteria and the neighboring GSM cell is not verified, an inter-RAT handover is triggered. When this parameter value is 65535, the RNC does not perform inter-RAT handovers to non-verified GSM cells. If this parameter is set to a larger value, the average number of handovers decreases, but call drops may occur.Considering that the UE is on the edge of the system, this parameter should be set to a comparatively low value. In situations where a GSM cell is verified, the performance of the GSM cell is generally regarded as good. In this case, the parameter can be set to 0, which indicates that the handover is performed immediately.If this parameter is set to a larger value, the average number of handovers decreases, but call drops may occur.Switch for verifying the Base Station Identity Code (BSIC). This parameter is used to control cells where inter-RAT measurement reports are triggered. When the parameter is set to "REQUIRED", the measurement reporting is triggered after the BSIC of the measured cell is decoded correctly. When the parameter is set to "NOT_REQUIRE", the measurement reporting is triggered regardless of whether the BSIC of the measured cell is decoded correctly. This parameter is valid for both periodical reporting mode and event-triggered reporting mode. However, to ensure handover reliability, it is recommended that the system reports only the cells whose BSIC is decoded correctly, that is, the recommended value of the parameter is "REQUIRED". If the parameter is set to "NOT_REQUIRED", handovers are likely to be triggered, but the handover reliability is lower than that in the situation the parameter is set to "REQUIRED".Event 2D and event 2F are used to enable and disable the compressed mode respectively in inter-RAT measurement. The requirements on the signal quality and inter-RAT handover policies vary with the service type. Therefore, the thresholds of enabling and disabling inter-RAT measurement are distinguished by CS, PS, and signaling. To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F.If the cell is a micro cell, the default value should be modified according to the link budgeting result. Event 2D and event 2F are used to enable and disable the compressed mode respectively. When the cell is located in the center of the frequency coverage or the inter-frequency measurement quantity uses both Ec/No and RSCP, then the Ec/No value is used as the criterion for events 2D and 2F. To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F.Event 2D and event 2F are used to enable and disable the compressed mode respectively in inter-RAT measurement. The requirements on the signal quality and inter-RAT handover policies vary with the service type. Therefore, the thresholds of enabling and disabling inter-RAT measurement are distinguished by CS, PS, and signaling. To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F.Event 2D and event 2F are used to enable and disable the compressed mode respectively in inter-RAT measurement. The requirements on the signal quality and inter-RAT handover policies vary with the service type. Therefore, the thresholds of enabling and disabling inter-RAT measurement are distinguished by CS, PS, and signaling. To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F.If the cell is a micro cell, the default value should be modified according to the link budgeting result. Event 2D and event 2F are used to enable and disable the compressed mode respectively. When the cell is located in the center of the frequency coverage or the inter-frequency measurement quantity uses both Ec/No and RSCP, then the Ec/No value is used as the criterion for events 2D and 2F. To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F.If the cell is a micro cell, the default value should be modified according to the link budgeting result. Event 2D and event 2F are used to enable and disable the compressed mode respectively. When the cell is located in the center of the frequency coverage or the inter-frequency measurement quantity uses both Ec/No and RSCP, then the Ec/No value is used as the criterion for events 2D and 2F. To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F.To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F. In most cases, users want to be maintained within a 3G network. Therefore, the start threshold of the inter-RAT measurement is set smaller than that of the inter-frequency measurement in order to trigger inter-frequency easily. In scenarios where inter-frequency neighboring cells are unavailable or where inter-frequency coverage is insufficient, the inter-RAT measurement start threshold should be set relatively larger in order to trigger inter-RAT measurement easily, thus reducing call drops.Threshold of stopping inter-RAT measurement for CS services when measurement quantity is RSCP. When RSCP is used as the measurement quantity for CS services, the UE reports event 2F when the measured RSCP value is larger than this threshold. Then, the RNC sends the signaling to disable the compressed mode and stop the inter-RAT measurement.To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F. In most cases, users want to be maintained within a 3G network. Therefore, the start threshold of the inter-RAT measurement is set smaller than that of the inter-frequency measurement in order to trigger inter-frequency easily. In scenarios where inter-frequency neighboring cells are unavailable or where inter-frequency coverage is insufficient, the inter-RAT measurement start threshold should be set relatively larger in order to trigger inter-RAT measurement easily, thus reducing call drops.To enable the compressed mode earlier, increase the threshold of triggering event 2D; otherwise, decrease the threshold of triggering event 2D. To prevent the frequent enabling and disabling of the compressed mode, increase the difference between the thresholds of triggering event 2D and event 2F. In most cases, users want to be maintained within a 3G network. Therefore, the start threshold of the inter-RAT measurement is set smaller than that of the inter-frequency measurement in order to trigger inter-frequency easily. In scenarios where inter-frequency neighboring cells are unavailable or where inter-frequency coverage is insufficient, the inter-RAT measurement start threshold should be set relatively larger in order to trigger inter-RAT measurement easily, thus reducing call drops.Threshold of stopping inter-RAT measurement for PS domain non-HSPA services when the measurement quantity is RSCP. When RSCP is used as the measurement quantity for PS domain non-HSPA services, the UE reports event 2F when the measured RSCP value is larger than this threshold. Then, the RNC sends the signaling to disable the compressed mode and stop the inter-RAT measurement.Threshold of stopping inter-RAT measurement for HSPA services when measurement quantity is RSCP. When RSCP is used as the measurement quantity for HSPA services, the UE reports event 2F when the measured RSCP value is larger than this threshold. Then, the RNC sends the signaling to disable the compressed mode and stop the inter-RAT measurement.The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.Impact on network performance:If this parameter is set to a larger value, event 3A is likely to be triggered. However, handover is likely to be triggered when the frequency quality in the current system is acceptable for the UE if the value of this parameter is set too large.Impact on network performance:If this parameter is set to a larger value, event 3A is likely to be triggered. However, handover is likely to be triggered when the frequency quality in the current system is acceptable for the UE if the value of this parameter is set too large.Impact on network performance:If this parameter is set to a larger value, event 3A is likely to be triggered. However, handover is likely to be triggered when the frequency quality in the current system is acceptable for the UE if the value of this parameter is set too large.Impact on network performance:If this parameter is set to a larger value, event 3A is likely to be triggered. However, handover is likely to be triggered when the frequency quality in the current system is acceptable for the UE if the value of this parameter is set too large.Impact on network performance:If this parameter is set to a larger value, event 3A is likely to be triggered. However, handover is likely to be triggered when the frequency quality in the current system is acceptable for the UE if the value of this parameter is set too large.Impact on network performance:If this parameter is set to a larger value, event 3A is likely to be triggered. However, handover is likely to be triggered when the frequency quality in the current system is acceptable for the UE if the value of this parameter is set too large.Impact on network performance:If the parameter is set to a smaller value, the UE cannot finish inter-RAT handover. If the parameter is set to a larger value, the compressed mode will not be disabled, thus affecting UE measurement. In actual networks, statistics can be made to obtain the delay for a successful inter-RAT handover, thus to get a proper value of "InterRATMeasTime" that satisfies most UEs.Length of the timer to avoid ping-pong handovers between 2G and 3G networks.When a UE in the CS domain is handed over from a 2G network to a 3G network, the system increases the hysteresis used for event 3A to prevent the ping-pong handover between the 2G network and the 3G network in the period specified by this parameter. During the penalty time, the previous periodical report will be changed to the event 3A report. The value 0 indicates that the system does not take measures to avoid ping-pong handover between 2G and 3G networks.Hysteresis to avoid ping-pong handover between 2G and 3G networks. When a UE in the CS domain is handed over from a 2G network to a 3G network, the system increases the hysteresis used for event 3A to prevent the ping-pong handover between the 2G network and the 3G network in the handover penalty period specified by "InterRATPingPongTimer". During the penalty time, event-triggered reporting is used for inter-RAT measurement. The value 0 indicates that the system does not take measures to avoid ping-pong handover between 2G and 3G networks.

UINTERRATHOCOV PeriodFor3A 3A Event Retry Period SET UINTERRATHOCOV(Optio

UINTERRATHOCOV AmntOfRpt3A 3A Event Maximum Retry Tim SET UINTERRATHOCOV(Optio

UINTERRATHOCOV InterRatPhyChFailNum Inter-RAT HO Physical ChanneSET UINTERRATHOCOV(Optio

UINTERRATHOCOV PenaltyTimeForPhyChFail Inter-RAT HO Physical ChannelSET UINTERRATHOCOV(Optio

UINTERRATHONCOV InterRATFilterCoef Inter-RAT Filter Coefficient SET UINTERRATHONCOV(Opt

UINTERRATHONCOV Hystfor3C 3C Hysteresis SET UINTERRATHONCOV(Opt

UINTERRATHONCOV TrigTime3C Event 3C Trigger Delay SET UINTERRATHONCOV(Opt

UINTERRATHONCOV BSICVerify BSIC Verify Switch SET UINTERRATHONCOV(Opt

UINTERRATHONCOV InterRATNCovHOCSThd Inter-RAT CS Handover Decis SET UINTERRATHONCOV(Opt

UINTERRATHONCOV InterRATNCovHOPSThd Inter-RAT PS Handover Decis SET UINTERRATHONCOV(Opt

UINTERRATHONCOV InterRATHOAttempts Inter-RAT Handover Max Atte SET UINTERRATHONCOV(OptMaximum number of inter-RAT ha

UINTERRATHONCOV InterRATMeasTime Inter-RAT Measure Timer LengSET UINTERRATHONCOV(Opt

UINTERRATHONCOV SndLdInfo2GsmInd Send Load Info to GSM Ind SET UINTERRATHONCOV(OptIf this parameter is set to "O

UINTERRATHONCOV NcovHoOn2GldInd NCOV Reloc Ind Based on GS SET UINTERRATHONCOV(OptWhen this parameter is set to

UINTERRATHONCOV CSHOOut2GloadThd CS Domain Reloc GSM Load SET UINTERRATHONCOV(OptThis parameter specifies the

UINTERRATHONCOV PSHOOut2GloadThd PS Domain Reloc GSM Load SET UINTERRATHONCOV(OptThis parameter specifies the

UINTERRATHONCOV PeriodFor3C Event 3C Retry Period SET UINTERRATHONCOV(Opt

UINTERRATHONCOV AmntOfRpt3C Event 3C Retry Max Times SET UINTERRATHONCOV(Opt

UINTERRATHONCOV InterRatPhyChFailNum Inter-RAT HO Physical ChanneSET UINTERRATHONCOV(Opt

UINTERRATHONCOV PenaltyTimeForPhyChFail Inter-RAT HO Physical ChannelSET UINTERRATHONCOV(Opt

UINTRAFREQHO FilterCoef Intra-frequency L3 Filter Coeffi SET UINTRAFREQHO(Optiona

UINTRAFREQHO IntraFreqMeasQuantity Intra-frequency Measurement SET UINTRAFREQHO(OptionaQuantity of the triggered measu

UINTRAFREQHO PeriodMRReportNumfor1A Event 1A to Periodical Report SET UINTRAFREQHO(OptionaMaximum number of reporting ev

UINTRAFREQHO ReportIntervalfor1A Event 1A to Periodical Report SET UINTRAFREQHO(OptionaInterval at which event 1A is r

UINTRAFREQHO PeriodMRReportNumfor1C Event 1C to Periodical Report SET UINTRAFREQHO(OptionaMaximum number of reporting ev

UINTRAFREQHO ReportIntervalfor1C Event 1C to Periodical Report SET UINTRAFREQHO(OptionaInterval at which event 1A is

UINTRAFREQHO PeriodMRReportNumfor1J Event 1J to Periodical Report SET UINTRAFREQHO(OptionaMaximum number of reporting ev

UINTRAFREQHO ReportIntervalfor1J Event 1J to Periodical Report SET UINTRAFREQHO(OptionaInterval at which event 1J is r

UINTRAFREQHO IntraRelThdFor1ACSVP VP Service Event 1A Relative SET UINTRAFREQHO(Optiona

UINTRAFREQHO IntraRelThdFor1ACSNVP CS Non-VP Service Event 1A SET UINTRAFREQHO(Optiona

UINTRAFREQHO IntraRelThdFor1APS PS Service Event 1A Relative SET UINTRAFREQHO(Optiona

UINTRAFREQHO IntraRelThdFor1BCSVP VP Service Event 1B Relative SET UINTRAFREQHO(Optiona

UINTRAFREQHO IntraRelThdFor1BCSNVP CS Non-VP Service Event 1B RSET UINTRAFREQHO(Optiona

UINTRAFREQHO IntraRelThdFor1BPS PS Service Event 1B Relative SET UINTRAFREQHO(Optiona

UINTRAFREQHO IntraAblThdFor1FEcNo Event 1F Absolute Ec/No Thre SET UINTRAFREQHO(Optiona

UINTRAFREQHO IntraAblThdFor1FRSCP Event 1F Absolute RSCP Thre SET UINTRAFREQHO(Optiona

UINTRAFREQHO HystFor1A 1A Hysteresis SET UINTRAFREQHO(OptionaThis parameter specifies the hy

UINTRAFREQHO HystFor1B 1B Hysteresis SET UINTRAFREQHO(OptionaThis parameter specifies the hy

UINTRAFREQHO HystFor1C 1C Hysteresis SET UINTRAFREQHO(OptionaThis parameter specifies the hy

UINTRAFREQHO HystFor1D 1D Hysteresis SET UINTRAFREQHO(OptionaThis parameter specifies the hy

UINTRAFREQHO HystFor1F 1F Hysteresis SET UINTRAFREQHO(OptionaThis parameter specifies the hy

UINTRAFREQHO HystFor1J 1J Hysteresis SET UINTRAFREQHO(OptionaThis parameter specifies the hy

UINTRAFREQHO Weight Weighted factor SET UINTRAFREQHO(OptionaUsed for calculating the relati

UINTRAFREQHO TrigTime1A Event 1A Triggering Delay SET UINTRAFREQHO(Optiona

UINTRAFREQHO TrigTime1B Event 1B Triggering Delay SET UINTRAFREQHO(Optiona

UINTRAFREQHO TrigTime1C Event 1C Triggering Delay SET UINTRAFREQHO(Optiona

UINTRAFREQHO TrigTime1D Event 1D Triggering Delay SET UINTRAFREQHO(Optiona

UINTRAFREQHO TrigTime1F Event 1F Triggering Delay SET UINTRAFREQHO(Optiona

UINTRAFREQHO TrigTime1J Event 1J Triggering Delay SET UINTRAFREQHO(Optiona

UINTRAFREQHO ShoFailPeriod Max Evaluation Period of SHO SET UINTRAFREQHO(OptionaMaximum evaluation period of SHO

UINTRAFREQHO ShoFailNumForDwnGrd Threshold Number of SHO FailSET UINTRAFREQHO(OptionaMaximum number of SHO failures.

UINTRAFREQHO RelThdForDwnGrd Relative Threshold of SHO Fai SET UINTRAFREQHO(Optiona

UINTRAFREQHO DcccShoPenaltyTime Period of Penalty Timer for S SET UINTRAFREQHO(OptionaLength of penalty timer for SHO

UINTRAFREQHO SHOQualmin Min Quality THD for SHO SET UINTRAFREQHO(Optiona

UINTRAFREQHO MaxCellInActiveSet Max Number of Cell in Active SET UINTRAFREQHO(OptionaMaximum number of cells in an a

UINTRAFREQHO BlindHORSCP1FThreshold Event 1F Blind Handover Trigg SET UINTRAFREQHO(Optiona

UINTRAFREQHO BlindHOIntrafreqMRInterval Intra-Frequency Measurement RSET UINTRAFREQHO(OptionaThis parameter specifies the i

UINTRAFREQHO BlindHOIntrafreqMRAmount Intra-Frequency Masurement RSET UINTRAFREQHO(OptionaUsed in the algorithm of the lo

UINTRAFREQNCELL RNCId RNC ID ID of an RNC

UINTRAFREQNCELL CellId Cell ID Unique ID of a cell

UINTRAFREQNCELL NCellRncId RNC ID of a neighboring cell Unique RNC ID of a neighborin

Interval between handover attempts for event 3A. This parameter specifies the interval between handover attempts for event 3A. If this parameter is set to a smaller value, handover attempts increase when the inter-RAT handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced, thus lowering the probability of call drops. More handover re-attempts, however, cause the increase in the RNC load.Maximum number of handover attempts after inter-RAT handover triggered by event 3A fails.This parameter specifies the maximum number of handover re-attempts for event 3A when the measurement control is valid. If this parameter is set to a greater value, the number of inter-RAT handover re-attempts increases and the possibility of successfully handing over the UE to the target cell whose load becomes normal increases. After reaching the value specified by this parameter, the RNC makes no further handover attempt to the target cell. If the compressed mode is disabled, the handover re-attempt will be aborted.Maximum number of inter-RAT handover failures allowed due to physical channel failure. When the number of inter-RAT handover failures due to physical channel failure exceeds the threshold, a penalty is given to the UE. During the time specified by "PenaltyTimeForInterRatPhyChFail[/para], the UE is not allowed to make inter-RAT handover attempts.For details about the physical channel failure, see 3GPP TS 25.331.Duration of the penalty for inter-RAT handover failure due to physical channel failure. The UE is not allowed to make inter-RAT handover attempts within the penalty time.For details about the physical channel failure, see 3GPP TS 25.331.In cells where the average moving speed of UEs is medium, there is a comparatively smaller shadow fading square error. Therefore, the recommended value is 3. In cells where the average moving speed of UEs is high, there is a comparatively small shadow fading square error. Therefore, the recommended value is 2.The value of this parameter is associated with the slow fading. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases; however, the handover algorithm becomes slow in responding to the signal change. If this parameter is set to a too large value, the cell of another RAT where the UE needs to be handed over to must be of good quality. Therefore, the criterion for triggering the inter-RAT handover decision is hard to be fulfilled, and the call drop rate increases. The emulation result shows that in a cell where the average moving speed of UEs is high (for example, a cell that covers highways), this parameter can be set to a smaller value 1.5 dB, because in the cell the terrain is flat, barriers are fewer, and thus the shadow fading variation is small. In a cell where the average moving speed of UEs is low, this parameter can be set to a larger value 3.0 dB, because there are usually many tall buildings and thus the shadow fading variation is comparatively high.The inter-frequency measurement reporting period is 480 ms. Therefore, the trigger delay time shorter than 480 ms is invalid. If the parameter is set to a larger value, handover is unlikely to be triggered. However, call drops may increase as the parameter value increases.Switch for verifying the Base Station Identity Code (BSIC). This parameter is used to control cells where inter-RAT measurement reports are triggered. When the parameter is set to "REQUIRED", the measurement reporting is triggered after the BSIC of the measured cell is decoded correctly. When the parameter is set to "NOT_REQUIRE", the measurement reporting is triggered regardless of whether the BSIC of the measured cell is decoded correctly. This parameter is valid for both periodical reporting mode and event-triggered reporting mode. However, to ensure handover reliability, it is recommended that the system reports only the cells whose BSIC is decoded correctly, that is, the recommended value of the parameter is "REQUIRED". If the parameter is set to "NOT_REQUIRED", handovers are likely to be triggered, but the handover reliability is lower than that in the situation the parameter is set to "REQUIRED".The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.The sensitivity of a GSM mobile phone is -102 dBm. Considering a margin of 3 dB for compensation of fast fading, 5 dB for compensation of slow fading, 2 dB for compensation of interference noise, and 2 dB for compensation of ambient noise, the outdoor reception level should not be lower than -90 dBm. The parameter value can vary with the handover policy. To have UEs handed over only to GSM cells of high quality, the inter-RAT handover decision threshold can be set to a comparatively large value, for example -85 dBm.

Impact on network performance:If the parameter is set to a smaller value, the UE cannot finish inter-RAT handover. If the parameter is set to a larger value, the compressed mode will not be disabled, thus affecting UE measurement. In actual networks, statistics can be made to obtain the delay for a successful inter-RAT handover, thus to get a proper value of "InterRATMeasTime" that satisfies most UEs.

Interval between the handover re-attempts for event 3C. This parameter specifies the interval between the handover re-attempts for event 3C. If this parameter is set to a smaller value, handover re-attempts increase when the inter-RAT handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced, thus lowering the probability of call drops. More handover re-attempts, however, cause the increase in the RNC load.Maximum number of handover re-attempts for event 3C. This parameter specifies the maximum number of handover attempts for event 3C when the measurement control message is valid. If this parameter is set to a greater value, the number of inter-RAT handover re-attempts increases and the possibility of successfully handing over the UE to the target cell whose load becomes normal increases. After reaching the value specified by this parameter, the RNC makes no further handover attempt to the target cell. If the compressed mode is disabled, the handover re-attempt will be aborted.Maximum number of inter-RAT handover failures allowed due to physical channel failure. When the number of inter-RAT handover failures due to physical channel failure exceeds the threshold, a penalty is given to the UE. During the time specified by "PenaltyTimeForInterRatPhyChFail[/para], the UE is not allowed to make inter-RAT handover attempts.For details about the physical channel failure, see 3GPP TS 25.331.Duration of the penalty for inter-RAT handover failure due to physical channel failure. The UE is not allowed to make inter-RAT handover attempts within the penalty time.For details about the physical channel failure, see 3GPP TS 25.331.When a is set to 1, L3 filtering is not applied. The input measurement value to L3 filter has been filtered by L1 filter, where the impact of fast fading is almost eliminated. In this case, smooth filtering should be applied through L3 filter, to eliminate the effect of shadow fading and peaks caused by fast fading, thus the filtered measurement value can reflect the variation of the actual measurement value, and provide more reliable measurement result for event judgment.

Relative threshold for event 1A decision when VP service is performed. If this parameter is set to a greater value, the probability of triggering event 1A increases. If this parameter is set to a smaller value, the probability of triggering event 1A reduces. For details on the definition of event 1A, see 3GPP TS 25.331.The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. you are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied.If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. you are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.Relative threshold for event 1A decision when PS service is performed. If this parameter is set to a greater value, the probability of triggering event 1A increases. If this parameter is set to a smaller value, the probability of triggering event 1A reduces. For details on the definition of event 1A, see 3GPP TS 25.331. The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. You are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.Relative threshold for event 1B decision when VP service is performed. If this parameter is set to a smaller value, the probability of triggering event 1B increases. If this parameter is set to a greater value, the probability of triggering event 1B reduces. For details on the definition of event 1B, see 3GPP TS 25.331. The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. You are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.Relative threshold for event 1B decision when non-VP service is performed in CS domain. If this parameter is set to a smaller value, the probability of triggering event 1B increases. If this parameter is set to a greater value, the probability of triggering event 1B reduces. For details on the definition of event 1B, see 3GPP TS 25.331. The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. You are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.Relative threshold for event 1B decision when PS service is performed. If this parameter is set to a smaller value, the probability of triggering event 1B increases. If this parameter is set to a greater value, the probability of triggering event 1B reduces. For details on the definition of event 1B, see 3GPP TS 25.331. The relative threshold can directly affect the SHO ratio. Therefore, the threshold should be wisely chosen to achieve smooth SHOs. The value of this parameter determines the SHO area and SHO ratio. In the CDMA system, the ratio of the UE involved in soft handover should reach 30% to 40% to ensure smooth handover. Based on simulation results, when the relative threshold is set to 5 dB, the ratio of the UE involved in soft handover (the number of cells in the active set is at least 2) is about 35%. You are advised to set the relative threshold to a great value (5 dB to 7 dB) during site deployment, and to reduce the threshold when the users increase. the threshold must be higher than 3 dB to avoid the ping-pong handover. You can set different relative thresholds for event 1A and event 1B to reduce the ping-pong effect and change the soft handover ratio. In general applications, the relative thresholds for events 1A and 1B should be consistent, and you can curb the ping-pong effect through the triggering delay, L3 filtering coefficient, and hysteresis. In some specific applications, if the ping-pong effect cannot be curbed by adjusting the hysteresis values for event 1A and event 1B, you can curb it by setting a higher relative threshold for event 1B and a lower threshold for event 1A. Impact on Network Performance: If this parameter is set to a greater value, the probability of adding a cell to the active set increases. In this case, more UEs are in soft handover status; however, more forward resources are occupied. If this parameter is set to a smaller value, the probability of adding a cell to the active set reduces. Under this situation, the communication quality cannot be guaranteed, and smooth handover may be affected.Ec/No absolute threshold for event 1F in the SHO algorithm. This parameter must be set to the value that guarantees the quality of basic services. In addition, the value of this parameter affects event 1F triggering. Event 1F refers to the event reported when an urgent blind handover is triggered. If event 1F is reported in a cell belonging to the active set, the signal quality of the active set is poor. Under this situation, blind handover is triggered to prevent call drops. The urgent blind handover is triggered in a special occasion that requires on-site measurements on the pilot strength and signal quality in the best cell of the cell where the UE is located. Generally, this function need not be enabled, so the parameter is set to the lowest value by default, indicating that the blind handover is not triggered.If this parameter is set to a greater value, the probability of triggering event 1F increases. If this parameter is set to a smaller value, the probability of triggering event 1F reduces. For details on the definition of event 1F, see 3GPP TS 25.331.If this parameter is set to a greater value, the probability of triggering blind handover increases. If this parameter is set to a smaller value, the probability of triggering blind handover reduces. In actual scenarios, this parameter should be set according to the handover strategy and network coverage.RSCP absolute threshold for event 1F in the SHO algorithm. This parameter must be set to the value that guarantees the quality of basic services. In addition, the value of this parameter affects event 1F triggering. Event 1F refers to the event reported when an urgent blind handover is triggered. If event 1F is reported in a cell belonging to the active set, the signal quality of the active set is poor. Under this situation, blind handover is triggered to prevent call drops.The urgent blind handover is triggered in a special occasion that requires on-site measurements on the pilot strength and signal quality in the best cell of the cell where the UE is located. Generally, this function need not be enabled, so the parameter is set to the lowest value by default, indicating that the blind handover is not triggered.If this parameter is set to a greater value, the probability of triggering event 1F increases. If this parameter is set to a smaller value, the probability of triggering event 1F reduces. For details on the definition of event 1F, see 3GPP TS 25.331.If this parameter is set to a greater value, the probability of triggering blind handover increases. If this parameter is set to a smaller value, the probability of triggering blind handover reduces. In actual scenarios, this parameter should be set according to the handover strategy and network coverage.

Setting an appropriate triggering delay effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.If the handover cannot be triggered in time, the time-to-trigger parameter for event 1A needs to be changed to 200 ms or 100 ms, and the delay for event 1B needs to be changed to 1280 ms or 2560 ms. If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate.Setting an appropriate interval time effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.If the handover cannot be triggered in time, the time-to-trigger parameter for event 1A needs to be changed to 200 ms or 100 ms, and the delay for event 1B needs to be changed to 1280 ms or 2560 ms.- reducing the impact of shadow fading on event decisions.Setting an appropriate interval time effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.- reducing the impact of shadow fading on event decisions.Setting an appropriate interval time effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.- reducing the impact of shadow fading on event decisions.Setting an appropriate interval time effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.- reducing the impact of shadow fading on event decisions.Setting an appropriate interval time effectively reduces the average number of handovers and the number of wrong handovers, preventing unnecessary handovers.

RelThdForDwnGrd: the relative threshold for direct rate reduction. It can be configured on the OMU server.Note: If this parameter is set to smaller value, the probability of triggering SHO rate reduction becomes low; however, the intra-frequency interference caused by the cell that is not added to the active set becomes great. This may cause call drops. On the contrary, if this parameter is set to a larger value, the probability of triggering SHO rate reduction becomes high, and the signal quality is guaranteed; however, frequent triggering of SHO rate reduction may affect the user experience.

Impact on network performance:This parameter should be adjusted, based on the planned Ec/No that the cell soft handover area is expected to reach. If this parameter is set to a greater value, the probability for adding a neighboring cell to the active set decreases. In this case, the service quality of the cell to be added is guaranteed. If this parameter is set to a smaller value, the probability for adding a neighboring cell to the active set increases. In this case, however, the service quality of the cell to be added is not guaranteed.

Threshold of the quality of the cell reporting event 1F for triggering blind handover. The blind handover is triggered only when the signal quality in the cell, which reports event 1F, exceeds this parameter. Otherwise, the report is discarded. This parameter is used to raise the success rate of blind handovers. If all the signals in the cell reporting event 1F are of poor quality, the user may be located at the edge of coverage area. Under this situation, triggering blind handover rashly may cause call drops.

RMV UINTRAFREQNCELL(Mandatory)MOD UINTRAFREQNCELL(Mandatory)RMV UINTRAFREQNCELL(Mandatory)MOD UINTRAFREQNCELL(Mandatory)RMV UINTRAFREQNCELL(Mandatory)MOD UINTRAFREQNCELL(Mandatory)

UINTRAFREQNCELL NCellId Neighboring Cell ID Unique ID of a neighboring cell

UINTRAFREQNCELL CIOOffset Neighboring Cell Oriented CIO

UINTRAFREQNCELL CellsForbidden1A Affect 1A Threshold Flag Determines whether event 1A thr

UINTRAFREQNCELL CellsForbidden1B Affect 1B Threshold Flag

UINTRAFREQNCELL SIB11Ind SIB11 Indicator

UINTRAFREQNCELL IdleQoffset1sn IdleQoffset1sn

UINTRAFREQNCELL IdleQoffset2sn IdleQoffset2sn

UINTRAFREQNCELL SIB12Ind SIB12 Indicator

UINTRAFREQNCELL ConnQoffset1sn ConnQoffset1sn Cell offset used for CPICH RSC

UINTRAFREQNCELL ConnQoffset2sn ConnQoffset2sn Cell offset used for CPICH Ec/

UINTRAFREQNCELL TpenaltyHcsReselect HCS Cell Reselect Penalty Ti

UINTRAFREQNCELL TempOffset1 HCS Cell Reselect TempOffse

UINTRAFREQNCELL TempOffset2 HCS Cell Reselect TempOffse

UINTRAFREQNCELL NPrioFlag Neighboring Cell Priority Flag

UINTRAFREQNCELL NPrio Priority of Neighboring Cell Priority of neighboring cells.

UINTRAFREQNCELL MbmsNCellInd MBMS Neighboring Cell Indica Indicator of MBMS neighboring

UIPDL Seed Seed of the Pseudo-random S Seed of the pseudo-random sequ

UIPSERVICEQOS CnOpIndex Cn Operator Index Indicating a CN operator.

UIPSERVICEQOS RecIndex Record Index Indicates a matching record. Th

UIPSERVICEQOS MatchType Match Type Specifies the match type in the

UIPSERVICEQOS IPAddress IP Address Specifies the IP address in the

UIPSERVICEQOS PortNum IP Port Specifies the port number in th

UIPSERVICEQOS ProtocolType IP Protocol Type Specifies the type of the IP p

UIURGCONN NBscIndex Neighboring BSC Index Represent an index for a Nei

UIURGCONN IntraMbscInd Intra-MBSC Indication Indicating whether the Neighb

UIUTIMERANDNUM CnOpIndex Cn Operator Index SET UIUTIMERANDNUM(MandRepresent an index for a CN o

UKPIALMTHD KpiAlarmSwitch RNC Report KPI Alarm Switch SET UKPIALMTHD(Optional) RRC Report KPI Alarm Switch

UKPIALMTHD KpiAlarmChkTimes the Period of KPI Alarm Check SET UKPIALMTHD(Optional) The period of KPI alarm check,

UKPIALMTHD RrcConnEstabSuccRatioThd Threshold of RRC Connection SET UKPIALMTHD(Optional) Threshold of RRC connection set

UKPIALMTHD RrcConnEstabAttMinNum The minimum of Rrc connectio SET UKPIALMTHD(Optional) The minimum number of RRC conn

UKPIALMTHD AmrRabEstabSuccRatioThd Threshold of AMR RAB Setup SSET UKPIALMTHD(Optional) Threshold of AMR RAB setup suc

UKPIALMTHD AmrRabEstabAttMinNum Minimum Number of AMR RAB SET UKPIALMTHD(Optional) The minimum number of AMR RAB

UKPIALMTHD VpRabEstSuccRatioThd Threshold of VP RAB Setup SuSET UKPIALMTHD(Optional) Threshold of VP RAB setup succe

UKPIALMTHD VpRabEstAttMinNum Minimum Number of VP RAB EsSET UKPIALMTHD(Optional) The minimum number of VP RAB e

UKPIALMTHD HsdpaRabEstSuccRatioThd Threshold of HSDPA RAB SetuSET UKPIALMTHD(Optional) Threshold of HSDPA RAB setup s

UKPIALMTHD HsdpaRabEstAttMinNum Minimum Number of HSDPA RASET UKPIALMTHD(Optional) The minimum number of HSDPA R

UKPIALMTHD HsupaRabEstSuccRatioThd Threshold of HSUPA RAB SetuSET UKPIALMTHD(Optional) Threshold of HSUPA RAB setup s

UKPIALMTHD HsupaRabEstAttMinNum Minimum Number of HSUPA RASET UKPIALMTHD(Optional) The minimum number of HSUPA R

UKPIALMTHD PsRabEstSuccRatioThd Threshold of PS RAB Setup SuSET UKPIALMTHD(Optional) Threshold of PS RAB setup succe

UKPIALMTHD PsRabEstAttMinNum Minimum Number of PS RAB EsSET UKPIALMTHD(Optional) The minimum number of PS RAB e

UKPIALMTHD AmrRabAbnormRelRatioThd Threshold of AMR Call Drop RaSET UKPIALMTHD(Optional) Threshold of AMR call drop rati

UKPIALMTHD AmrRabRelMinNum Minimum Number of AMR Call SET UKPIALMTHD(Optional) The minimum number of AMR call

UKPIALMTHD VpRabAbnormRelRatioThd Threshold of VP Call Drop Rat SET UKPIALMTHD(Optional) Threshold of VP call drop ratio

UKPIALMTHD VpRabRelMinNum Minimum Number of VP Call R SET UKPIALMTHD(Optional) The minimum number of VP call r

UKPIALMTHD PsRabAbnormRelRatioThd Threshold of PS Call Drop Rat SET UKPIALMTHD(Optional) Threshold of PS call drop ratio

UKPIALMTHD PsRabRelMinNum Minimum Number of PS Call R SET UKPIALMTHD(Optional) The minimum number of PS call r

ULAC CnOpIndex Cn Operator Index Represent an index for a CN o

ULAC LAC Location Area Code Identifies a location area cod

ULAC PlmnValTagMin Min PLMN Value Tag ADD ULAC(Mandatory) Minimum PLMN tag value corresp

ULAC PlmnValTagMax Max PLMN Value Tag ADD ULAC(Mandatory) Maximum PLMN tag value corresp

ULASNAMAP LAC Location area code Identifying a location area wi

ULASNAMAP SNAC Sharing Network Area Code Sharing Network Area Code.

ULASNAMAP MCC Mobile country code The code of the country to wh

ULASNAMAP MNC Mobile network code The code of the mobile commun

ULDCALGOPARA LdrFirstPri first priority for load reshuffling SET ULDCALGOPARA(Optiona

ULDCALGOPARA LdrSecondPri second priority for load reshuff SET ULDCALGOPARA(Optiona

ULDCALGOPARA LdrThirdPri third priority for load reshufflin SET ULDCALGOPARA(Optiona

ULDCALGOPARA LdrFourthPri fourth priority for load reshuffli SET ULDCALGOPARA(Optiona

ULDCALGOPARA LdcSwitch load control algorithm switch SET ULDCALGOPARA(Optiona

ULDCPERIOD IntraFreqLdbPeriodTimerLen Intra-frequency LDB period tim SET ULDCPERIOD(Optional) Identifying the period of the I

ULDCPERIOD PucPeriodTimerLen PUC period timer length SET ULDCPERIOD(Optional) Identifying the potential user c

RMV UINTRAFREQNCELL(Mandatory)MOD UINTRAFREQNCELL(Mandatory)ADD UINTRAFREQNCELL(Optional)MOD UINTRAFREQNCELL(Optional)

This parameter specifies the neighboring cell oriented Cell Individual Offset (CIO). The sum of the value of this parameter, the value of the cell oriented CIO, and the actual measurement quantity is used for the event evaluation of the UE or used for the handover decision procedure on the RNC side. In a handover algorithm, this parameter is used for moving the border of a cell. In the case of an event-based intra-frequency measurement or inter-RAT measurement, the UE determines whether to trigger an event according to the sum of the value of this parameter, the value of the cell oriented CIO, and the actual measurement quantity. The UE does not consider the value of this parameter when evaluating an inter-frequency measurement event. In the case of a periodical inter-frequency measurement or inter-RAT measurement, the RNC determines whether to initiate a handover according to the sum of the value of this parameter, the value of the cell.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Optional)ADD UINTRAFREQNCELL(Optional)MOD UINTRAFREQNCELL(Optional)

Flag of whether adding a cell into the active set will affect the relative threshold of the event 1B.This parameter is a flag of whether adding the cell into the active set will affect the relative threshold of the event 1B NOT_AFFECT: Adding the cell into the active set does not affect the relative threshold of the event 1B. The cell signal will affect the UE evaluate whether event 1B should occur. AFFECT: Adding the cell into the active set affects the relative threshold of the event 1B. The cell signal will not affect the UE evaluate whether event 1B should occur.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Optional)Indicates whether to send the system information block 11 (SIB11) including neighboring cell information. The value "FALSE" indicates that the neighboring information is not included in the SIB11. The value "TRUE" indicates that the neighboring information is included in the SIB11.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Mandatory)Note that in FDD mode, this parameter is valid only when SIB11 Indicator is set as TRUE.For details, see 3GPP TS 25.331.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Mandatory)Note that in FDD mode, this parameter is valid only when SIB11 Indicator is set as TRUE.For details, see 3GPP TS 25.331.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Optional)Indicates whether to send the SIB12 indication including the neighboring cell information. The value "FALSE" indicates that the neighboring information is not included in the SIB12. The value "TRUE" indicates that the neighboring information is included in the SIB12.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Mandatory)ADD UINTRAFREQNCELL(Optional)MOD UINTRAFREQNCELL(Mandatory)ADD UINTRAFREQNCELL(Optional)MOD UINTRAFREQNCELL(Optional)

Specifies the penalty time for cell reselection. If this parameter is set to a greater value, the penalty time for HCS cell reselection is prolonged. If this parameter is set to a smaller value, the penalty time for HCS cell reselection is shortened. When the UE is in idle mode, the ping-pong reselections between HCS cells reduces if this parameter is set to a greater value. In this case, however, the hierarchical cell structure cannot be deployed effectively.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Mandatory)Cell offset used for CPICH RSCP measurement value in HCS cell selection. If this parameter is set to a greater value, the probability for selecting a neighboring cell reduces. If this parameter is set to a smaller value, the probability for selecting a neighboring cell increases. If this parameter is set to "INFINITY", a neighboring cell is not selected.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Mandatory)Cell offset used for CPICH Ec/No measurement value in HCS cell selection. If this parameter is set to a greater value, the probability for cell reselection reduces. If this parameter is set to a smaller value, the probability for cell reselection increases. If this parameter is set to "INFINITY", a neighboring cell is not selected.ADD UINTRAFREQNCELL(Optional)

MOD UINTRAFREQNCELL(Optional)Priority flag of neighboring cellsThe value TRUE indicates that the neighboring cell priority is valid, and the value FALSE indicates that the neighboring cell priority is invalid. In the algorithm of neighboring cell combination, the cell with an invalid priority is the last one to be considered as the measurement object.ADD UINTRAFREQNCELL(Mandatory)

MOD UINTRAFREQNCELL(Mandatory)ADD UINTRAFREQNCELL(Optional)MOD UINTRAFREQNCELL(Optional)ADD UIPDL(Mandatory)MOD UIPDL(Optional)MOD UIPSERVICEQOS(Mandatory)RMV UIPSERVICEQOS(Mandatory)MOD UIPSERVICEQOS(Mandatory)RMV UIPSERVICEQOS(Mandatory)ADD UIPSERVICEQOS(Mandatory)MOD UIPSERVICEQOS(Optional)ADD UIPSERVICEQOS(Mandatory)MOD UIPSERVICEQOS(Optional)ADD UIPSERVICEQOS(Mandatory)MOD UIPSERVICEQOS(Optional)ADD UIPSERVICEQOS(Mandatory)MOD UIPSERVICEQOS(Optional)RMV UIURGCONN(Mandatory)MOD UIURGCONN(Mandatory)ADD UIURGCONN(Mandatory)MOD UIURGCONN(Optional)

ADD ULAC(Mandatory)RMV ULAC(Mandatory)ADD ULAC(Mandatory)RMV ULAC(Mandatory)

ADD ULASNAMAP(Mandatory)RMV ULASNAMAP(Mandatory)ADD ULASNAMAP(Mandatory)RMV ULASNAMAP(Mandatory)ADD ULASNAMAP(Mandatory)RMV ULASNAMAP(Mandatory)ADD ULASNAMAP(Mandatory)RMV ULASNAMAP(Mandatory)If congestion is triggered by multiple resources such as credit and code at the same time, the congestion of resources specified in this parameter is processed with the first priority.

IUBLDR refers to processing of LDR action trigged by Iub bandwidth. CREDITLDR refers to processing of LDR action trigged by credit. CODELDR refers to processing of LDR action trigged by code. UULDR refers to processing of LDR action trigged by Uu.If congestion is triggered by multiple resources such as credit and code at the same time, the congestion of resources specified in this parameter is processed with the second priority.IUBLDR refers to processing of LDR action trigged by Iub bandwidth. CREDITLDR refers to processing of LDR action trigged by credit. CODELDR refers to processing of LDR action trigged by code. UULDR refers to processing of LDR action trigged by Uu.If congestion is triggered by multiple resources such as credit and code at the same time, the congestion of resources specified in this parameter is processed with the third priority.IUBLDR refers to processing of LDR action trigged by Iub bandwidth. CREDITLDR refers to processing of LDR action trigged by credit. CODELDR refers to processing of LDR action trigged by code. UULDR refers to processing of LDR action trigged by Uu.If congestion is triggered by multiple resources such as credit and code at the same time, the congestion of resources specified in this parameter is processed with the fourth priority.IUBLDR refers to processing of LDR action trigged by Iub bandwidth. CREDITLDR refers to processing of LDR action trigged by credit. CODELDR refers to processing of LDR action trigged by code. UULDR refers to processing of LDR action trigged by Uu.LC_CREDIT_LDR_SWITCH: Local cell credit congestion control algorithm. This is an RNC-oriented algorithm. When the local cell credit load is heavy, the load can be reshuffled through BE service rate reduction, renegotiation of uncontrollable real-time service QoS, and CS/PS inter-RAT handover.If NODEB_CREDIT_LDR_SWITCH, LCG_CREDIT_LDR_SWITCH and LC_CREDIT_LDR_SWITCH are selected, the corresponding algorithms are enabled; otherwise, disabled.

ULDCPERIOD LdrPeriodTimerLen LDR period timer length SET ULDCPERIOD(Optional)

ULDCPERIOD OlcPeriodTimerLen OLC period timer length SET ULDCPERIOD(Optional)

ULDM UlBasicCommMeasFilterCoeff UL basic common measure filteSET ULDM(Optional) L3 filtering coefficient. The la

ULDM ChoiceRprtUnitForUlBasicMea Time unit for UL basic meas rprSET ULDM(Optional) If you set this parameter to T

ULDM TenMsecForUlBasicMeas UL basic meas rprt cycle 10ms SET ULDM(Mandatory) UL basic common measurement r

ULDM MinForUlBasicMeas UL basic meas rprt cycle minu SET ULDM(Mandatory) UL basic common measurement r

ULDM DlBasicCommMeasFilterCoeff DL basic common measure filteSET ULDM(Optional) L3 filtering coefficient. The la

ULDM ChoiceRprtUnitForDlBasicMea Time unit for DL basic meas rprSET ULDM(Optional) If you set this parameter to T

ULDM TenMsecForDlBasicMeas DL basic meas rprt cycle 10ms SET ULDM(Mandatory) DL basic common measurement r

ULDM MinForDlBasicMeas DL basic meas rprt cycle minu SET ULDM(Mandatory) DL basic common measurement r

ULDM PeriodProtectTimerCoeff Period common measure protectSET ULDM(Optional) Period common measurement pro

ULDM LdbAvgFilterLen LDB smoothing filter length SET ULDM(Optional) Length of smoothing filter win

ULDM PucAvgFilterLen PUC smoothing filter length SET ULDM(Optional) Length of smoothing filter wind

ULDM UlLdrAvgFilterLen UL LDR smoothing filter length SET ULDM(Optional) Length of smoothing filter win

ULDM DlLdrAvgFilterLen DL LDR smoothing filter length SET ULDM(Optional) Length of smoothing filter win

ULDM UlOlcAvgFilterLen UL OLC smoothing filter length SET ULDM(Optional) Length of smoothing filter win

ULDM DlOlcAvgFilterLen DL OLC smoothing filter length SET ULDM(Optional) Length of smoothing filter win

ULDM UlCacAvgFilterLen UL CAC smoothing filter lengt SET ULDM(Optional) Length of smoothing filter win

ULDM DlCacAvgFilterLen DL CAC smoothing filter lengt SET ULDM(Optional) Length of smoothing filter win

ULDM ChoiceRprtUnitForHsdpaPwrMTime unit of HSDPA need pwr SET ULDM(Optional) If you set this parameter to T

ULDM TenMsecForHsdpaPwrMeas HSDPA need pwr meas cycle SET ULDM(Mandatory) HSDPA power requirement measu

ULDM MinForHsdpaPwrMeas HSDPA need pwr meas cycle SET ULDM(Mandatory) HSDPA power requirement measu

ULDM HsdpaNeedPwrFilterLen HSDPA need power filter len SET ULDM(Optional) Length of smoothing filter wi

ULDM ChoiceRprtUnitForHsdpaRate Time unit of HSDPA bit rate m SET ULDM(Optional) If you set this parameter to T

ULDM TenMsecForHsdpaPrvidRateMHSDPA bit rate meas cycle 1 SET ULDM(Mandatory) This parameter specifies the H

ULDM MinForHsdpaPrvidRateMeas HSDPA bit rate meas cycle mi SET ULDM(Mandatory) This parameter specifies the H

ULDM HsdpaPrvidBitRateFilterLen HSDPA bit rate filter len SET ULDM(Optional) Length of smoothing filter win

ULDM MaxMeasContInvalidTimes Max number of continuous inv SET ULDM(Optional) Max allowed number of continuo

ULDM UlOlcMeasFilterCoeff UL overload measure filter coefSET ULDM(Optional) L3 filtering coefficient. The la

ULDM ChoiceRprtUnitForUlOlcMeas Time unit for UL OLC meas rprtSET ULDM(Optional) If you set this parameter to T

ULDM TenMsecForUlOlcMeas UL OLC meas rprt cycle 10ms SET ULDM(Mandatory) Measurement report period of e

ULDM MinForUlOlcMeas UL OLC meas rprt cycle minu SET ULDM(Mandatory) Measurement report period of e

ULDM UlOlcTrigHyst UL OLC trigger hysteresis SET ULDM(Optional) UL OLC trigger hysteresis.This

ULDM DlOlcMeasFilterCoeff DL overload measure filter coefSET ULDM(Optional) L3 filtering coefficient. The la

ULDM ChoiceRprtUnitForDlOlcMeas Time unit for DL OLC meas rprtSET ULDM(Optional) If you set this parameter to T

ULDM TenMsecForDlOlcMeas DL OLC meas rprt cycle 10ms SET ULDM(Mandatory) Measurement report period of e

ULDM MinForDlOlcMeas DL OLC meas rprt cycle minu SET ULDM(Mandatory) Measurement report period of e

ULDM DlOlcTrigHyst DL OLC trigger hysteresis SET ULDM(Optional) DL OLC trigger hysteresis.This

ULDM ChoiceRprtUnitForHsupaRate Time unit of HSUPA bit rate m SET ULDM(Optional) If you set this parameter to T

ULDM TenMsecForHsupaPrvidRateMHSUPA bit rate meas cycle 1 SET ULDM(Mandatory) This parameter specifies the H

ULDM MinForHsupaPrvidRateMeas HSUPA bit rate meas cycle mi SET ULDM(Mandatory) This parameter specifies the H

ULDM HsupaPrvidBitRateFilterLen HSUPA bit rate filter len SET ULDM(Optional) Length of smoothing filter win

ULOCELL LoCell Local Cell ID Uniquely identifying a local ce

UMBMSALARMPARA MbmsInactTmr Set mbms data check timer SET UMBMSALARMPARA(ManA timer used to alarm for no m

UMBMSALARMSERVICE MbmsMCC Mobile country code mobile country code of the RN

UMBMSALARMSERVICE MbmsMNC Mobile network code mobile network code of the RN

UMBMSALARMSERVICE MbmsServiceId MBMS ServiceId MBMS Service Identity.

UMBMSFACH ServiceType Service Type SET UMBMSFACH(MandatoryThis parameter specifies the t

UMBMSFACH ServiceBitRate Service Bit Rate SET UMBMSFACH(MandatoryThis parameter specifies the r

UMBMSFACH FachMaxPower Fach Max Power SET UMBMSFACH(Optional) This parameter specifies the

UMBMSFACH MtchMinPerc0 Mtch Minimal Power Percent forSET UMBMSFACH(Optional) This parameter specifies the m

UMBMSFACH MtchMinPerc15 Mtch Minimal Power Percent forSET UMBMSFACH(Optional) This parameter specifies the m

UMBMSFACH ToAWS Time of Arrival Window StartpoSET UMBMSFACH(Optional) A positive value relative to Ti

UMBMSFACH ToAWE Time of Arrival Window Endpoi SET UMBMSFACH(Optional) A positive value relative to La

UMBMSPERF ChIdx Channel Index SET UMBMSPERF(Mandatory MBMS performance channel i

UMBMSPERF ChSwitch Channel Switch SET UMBMSPERF(Mandatory This switch determines whethe

UMBMSPERF MCC Mobile country code SET UMBMSPERF(Mandatory The code of the country to wh

UMBMSPERF MNC Mobile network code SET UMBMSPERF(Mandatory The code of the mobile commun

UMBMSPERF ServiceId Service ID SET UMBMSPERF(Mandatory This parameter define MBMS se

UMBMSSA CnOpIndex Cn Operator Index Represent an index for a CN o

UMBMSSA MbmsSaId MBMS SA ID MBMS SA ID. For detailed infor

Identifying the period of the LDR execution. When basic congestion occurs, execution of LDR can dynamically reduce the cell load. The lower the parameter value is, the more frequently the LDR action is executed, which decreases the load quickly. If the parameter value is excessively low, an LDR action may overlap the previous one before the previous result is displayed in LDM. The higher the parameter value is, the more likely this problem can be prevented. If the parameter value is excessively high, the LDR action may be executed rarely, failing to lower the load timely.The LDR algorithm aims to slowly reduce the cell load and control the load below the admission threshold, each LDR action takes a period (for example the inter-RAT load handover needs a delay of about 5 s if the compressed mode is needed), and there is a delay for the LDM module responds to the load decreasing (the delay is about 3 s when the L3 filter coefficient is set to 6), so the parameter value should be higher than 8s.Identifying the period of the OLC execution. When overload occurs, execution of OLC can dynamically reduce the cell load. When setting the parameter, consider the hysteresis for which the load monitoring responds to the load change. For example, when the layer 3 filter coefficient is 6, the hysteresis for which the load measurement responds to the step-function signals is about 2.8s, namely that the system can trace the load control effect about 3 s later after each load control. In this case, the OLC period timer length cannot be smaller than 3s.OlcPeriodTimerLen along with ULOLCFTFRstrctUserNum, DLOLCFTFRstrctUserNum, ULOLCFTFRSTRCTTimes, DLOLCFTFRSTRCTTimes, ULOLCTraffRelUserNum, and DLOLCTraffRelUserNum determine the time it takes to release the uplink/downlink overload. If the OLC period is excessively long, the system may respond very slowly to overload. If the OLC period is excessively short, unnecessary adjustment may occur before the previous OLC action has taken effect, and therefore the system performance is affected.

ADD ULOCELL(Mandatory)RMV ULOCELL(Mandatory)

ADD UMBMSALARMSERVICE(Mandatory)RMV UMBMSALARMSERVICE(Mandatory)ADD UMBMSALARMSERVICE(Mandatory)RMV UMBMSALARMSERVICE(Mandatory)ADD UMBMSALARMSERVICE(Mandatory)RMV UMBMSALARMSERVICE(Mandatory)

ADD UMBMSSA(Mandatory)RMV UMBMSSA(Mandatory)ADD UMBMSSA(Mandatory)RMV UMBMSSA(Mandatory)

UMBMSSCCPCH ServiceType Service Type SET UMBMSSCCPCH(MandatoThis parameter specifies the t

UMBMSSCCPCH ServiceBitRate Service Bit Rate SET UMBMSSCCPCH(MandatoThis parameter specifies the r

UMBMSSCCPCH STTDInd STTD Indicator SET UMBMSSCCPCH(OptionaThis parameter indicates wheth

UMBMSSWITCH MbmsSwitch MBMS Control Switch SET UMBMSSWITCH(MandatoON denotes enabling of the MB

UMBMSSWITCH MbmsIubSharingSwitch MBMS Iub Sharing Switch SET UMBMSSWITCH(OptionalON denotes enabling of the MB

UMBMSSWITCH MschSwitchForNonMtchMulti Msch Switch For NonMtchMult SET UMBMSSWITCH(OptionalThis parameter specifies whet

UMBMSSWITCH MschSwitchForMtchMulti Msch Switch For MtchMulti Sc SET UMBMSSWITCH(OptionalThis switch specifies whether

UMBSCCRRM MbscServiceDiffLdbSwitch Service Distribution and Load SET UMBSCCRRM(Optional) This parameter defines the swi

UMBSCCRRM Mbsc3G2GLdBlcCsDeltaThrd Load Difference Threshold Be SET UMBSCCRRM(Optional) This parameter defines the loa

UMBSCCRRM Mbsc3G2GLdBlcPsDeltaThrd PS Load Difference Threshold SET UMBSCCRRM(Optional) This parameter defines the loa

UMBSCCRRM CommonMeasurementPeriod 2G Cell Load Measurement RepSET UMBSCCRRM(Optional) This parameter defines the pe

UMBSCCRRM MbscNcovHoOn2GldInd Non-Coverage Handover BasedSET UMBSCCRRM(Optional) If the switch is ON, the load s

UMBSCCRRM LoadHoOn3G2GldInd Load-base Handover Based on SET UMBSCCRRM(Optional) If the switch is ON, the load d

UMBSCCRRM Mbsc2GLoadAdjustCoeff Adjustment Coefficient of 2G SET UMBSCCRRM(Optional) This parameter defines the adju

UMBSCCRRM MbscReqGeranInfoSwitch GERAN System Information ExSET UMBSCCRRM(Optional) If the switch is ON, the NACC

UMBSCCRRM MbscNonLdrRedirFactor Un-LDR Redirection Factor SET UMBSCCRRM(Optional) This argument is used as a fa

UMBSCCRRM MbscLdrRedirFactor LDR Redirection Factor SET UMBSCCRRM(Optional) This argument is used as a fa

UMCCHPERIODCOEF McchModPeriodCoef Mcch Mod Period Coefficient SET UMCCHPERIODCOEF(OptThis parameter specifies the co

UMCCHPERIODCOEF McchAccessPeriodCoef Mcch Access Period CoefficienSET UMCCHPERIODCOEF(OptThis parameter specifies the c

UMCCHPERIODCOEF McchRepPeriodCoef Mcch Repetition Period CoefficSET UMCCHPERIODCOEF(OptThis parameter specifies the co

UMCDRD BlindDrdExceptHRetrySwitch Aperiodic DRD Retry Switch SET UMCDRD(Optional)

UMCDRD HRetryTimerLength DRD Measurement Period RetrSET UMCDRD(Optional) Specifies the time length of th

UMCDRD PrdReportInterval Inter-Frequency Periodic Meas SET UMCDRD(Optional)

UMCDRD TargetFreqThdRscp Target Frequency RSCP TriggeSET UMCDRD(Optional) RSCP Threshold for the target c

UMCDRD TargetFreqThdEcN0 Target Frequency EcNo TriggeSET UMCDRD(Optional) Ec/No Threshold for the target

UMCDRD DrdFaiPenaltyPeriodNum DRD Measurement Failure PunSET UMCDRD(Optional) Number of retry periods in the

UMCLDR InterFreqMeasTime Inter-freq Measure Timer Leng SET UMCLDR(Optional)

UMCLDR PrdReportInterval Inter-freq Measure Periodical SET UMCLDR(Optional)

UMCLDR TargetFreqThdRscp Inter-freq Target Frequency SET UMCLDR(Optional) Estimate the signal quality of

UMCLDR TargetFreqThdEcN0 Inter-freq Target Frequency T SET UMCLDR(Optional) Estimate the signal quality of

UMGWTST TstSwitch MGWTST SWITCH SET UMGWTST(Mandatory) Indicating whether setting M

UMGWTST TstImsi MGWTST USER IMSI SET UMGWTST(Mandatory) MGWTST user IMSI in a numb

UMSCHFACH FachMaxPower Fach Max Power SET UMSCHFACH(Optional) This parameter describes Fac

UMTCH ServiceType Service Type SET UMTCH(Mandatory) This parameter specifies the t

UMTCH ServiceBitRate Service Bit Rate SET UMTCH(Mandatory) This parameter specifies the r

UMTCH MtchRohcSwitch Mtch Rohc Switch SET UMTCH(Optional) This parameter specifies whe

UNBNODESYNCMONPARA NodeSyncTime Measurement Start Time Measurement start time (HH:

UNBNODESYNCMONPARA NodeSyncPeriod Measurement Period Period of node synchronizatio

UNBSC NBscIndex Neighboring BSC Index Represent an index for a Nei

UNCELLDETECTSWITCH IntraFreqNCellDetectSwitch Intra-Frequency Neighboring CSET UNCELLDETECTSWITCH(

UNCELLDETECTSWITCH InterFreqNCellDetectSwitch Inter-Frequency Neighboring CSET UNCELLDETECTSWITCH(

UNCELLDETECTSWITCH InterRatNCellDetectSwitch Inter-Rat Neighboring Cell Det SET UNCELLDETECTSWITCH(

UNODEB TnlBearerType IUB Trans Bearer Type Transport type of the Iub interf

UNODEB TRANSDELAY IUB Trans Delay ADD UNODEB(Optional) This parameter specifies the r

UNODEB HostType NodeB Host Type

UNODEB PeerRncId Peer RNC ID This parameter specifies the

UNODEB PeerNodebId Peer NodeB ID ID configured in another RNC

UNODEB SharingType Sharing Type Of NodeB This parameter specifies the s

UNODEB CnOpIndex Cn Operator Index Represent an index for a CN o

UNODEBALGOPARA NodeBLdcAlgoSwitch NodeB LDC algorithm switch

UNODEBALGOPARA NodeBHsdpaMaxUserNum NodeB Max HSDPA User Num Maximum number of HSDPA users

UNODEBALGOPARA NodeBHsupaMaxUserNum NodeB Max HSUPA User Num Maximum number of HSUPA users

UNODEBALGOPARA HsupaCeConsumeSelection HSUPA Credit Consume Type When the dynamic CE algorithm

UNODEBALGOPARA RsvdPara1 Reserved parameter 1 Reserved Parameter1.

UNODEBALGOPARA RsvdPara2 Reserved parameter 2 Reserved parameter 2.

UNODEBALGOPARA RsvdPara3 Reserved parameter 3 Reserved parameter 3.

UNODEBESN NODEBID NodeB ID NodeB ID

UNODEBIP NODEBID NodeB ID NodeB ID

UNODEBLDR DlLdrFirstAction DL LDR first action

UNODEBLDR DlLdrSecondAction DL LDR second action This parameter has the same co

UNODEBLDR DlLdrThirdAction DL LDR third action This parameter has the same co

If this parameter is set to "ON", the DRD retry for blind handover is performed in aperiodic mode.If this switch is set to "OFF", the DRD retry for blind handover is not performed in aperiodic mode.

Interval between sending of periodic measurement reports.This parameter has impact on the Uu signaling flow. If this parameter is set to a small value, the RNC may have high load when processing signaling. If this parameter is set to a great value, the network cannot detect the signal changes in time. This may delay the inter-frequency handover.

After inter-frequency measurement starts, if no inter-frequency handover is performed when this timer expires, the inter-frequency measurement and the compressed mode (if started) are stopped. This parameter is used to prevent the long inter-frequency measurement state (compressed mode) due to unavailable measurement of the target cells that meet the handover requirements.The interval between two reports is the configured value. This parameter has impact on the Uu signaling flow. If the interval is too short and the frequency is too high, the RNC may have burden in processing signaling. If the interval is too long, the network cannot detect the signal change in time, which may delay the inter-frequency handover.

ADD UNBNODESYNCMONPARA(Mandatory)MOD UNBNODESYNCMONPARA(Optional)ADD UNBNODESYNCMONPARA(Mandatory)MOD UNBNODESYNCMONPARA(Optional)ADD UNBSC(Mandatory)RMV UNBSC(Mandatory) Controls whether the subsystem in a certain subrack supports the detection function of intra-frequency missing neighboring cells.

The value "ON" indicates that the subsystem in a certain subrack supports the detection function of intra-frequency missing neighboring cells. The value "OFF" indicates that the subsystem in a certain subrack does not support the detection function of intra-frequency missing neighboring cells.Controls whether the subsystem in a certain subrack supports the detection function of inter-frequency missing neighboring cells. The value "ON" indicates that the subsystem in a certain subrack supports the detection function of inter-frequency missing neighboring cells. The value "OFF" indicates that the subsystem in a certain subrack does not support the detection function of inter-frequency missing neighboring cells.Controls whether the subsystem in a certain subrack supports the detection function of inter-RAT missing neighboring cells. The value "ON" indicates that the subsystem in a certain subrack supports the detection function of inter-RAT missing neighboring cells. The value "OFF" indicates that the subsystem in a certain subrack does not support the detection function of inter-RAT missing neighboring cells.ADD UNODEB(Optional)

MOD UNODEB(Optional)

ADD UNODEB(Optional)MOD UNODEB(Optional)

This parameter specifies the NodeB host type in RNC Node Redundancy function. If the parameter value is SINGLEHOST, the physical NodeB is managed only by one RNC. If the parameter value is PRIMHOST or SECHOST, the physical NodeB can be managed by two RNCs.By default, the NodeB is managed by the host RNC. When the host RNC fails, the physical NodeB is managed by the secondary RNC.ADD UNODEB(Mandatory)

MOD UNODEB(Mandatory)ADD UNODEB(Mandatory)MOD UNODEB(Mandatory)ADD UNODEB(Mandatory)MOD UNODEB(Optional)ADD UNODEB(Mandatory)MOD UNODEB(Mandatory)ADD UNODEBALGOPARA(Optional)MOD UNODEBALGOPARA(Optional)

LCG_CREDIT_LDR (Cell group level credit congestion control algorithm): When the cell group level credit load is heavy, users are assembled in priority order among all the NodeBs and some users are selected for LDR action in order to reduce the cell group level credit load. IUB_OLC (Iub Overload congestion control algorithm): When the NodeB Iub load is Overload, users are assembled in priority order among all the NodeBs and some users are selected for Olc action in order to reduce the NodeB Iub load.To enable some of the algorithms above, select them. Otherwise, they are disabled.ADD UNODEBALGOPARA(Optional)

MOD UNODEBALGOPARA(Optional)ADD UNODEBALGOPARA(Optional)MOD UNODEBALGOPARA(Optional)ADD UNODEBALGOPARA(Optional)MOD UNODEBALGOPARA(Optional)ADD UNODEBALGOPARA(Optional)MOD UNODEBALGOPARA(Optional)ADD UNODEBALGOPARA(Optional)MOD UNODEBALGOPARA(Optional)ADD UNODEBALGOPARA(Optional)MOD UNODEBALGOPARA(Optional)RMV UNODEBESN(Mandatory)ADD UNODEBESN(Mandatory)RMV UNODEBIP(Mandatory)ADD UNODEBIP(Mandatory)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)

The inter-frequency load handover has no impact on the QoS of users and can balance the cell load, so the inter-frequency load handover usually serves as the first action.The BE service rate reduction is effective only when the DCCC algorithm is enabled.ADD UNODEBLDR(Optional)

MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)

UNODEBLDR DlLdrFourthAction DL LDR fourth action This parameter has the same co

UNODEBLDR DlLdrFifthAction DL LDR fifth action This parameter has the same co

UNODEBLDR DlLdrSixthAction DL LDR Sixth action This parameter has the same co

UNODEBLDR DlLdrBERateReductionRabNu DL LDR-BE rate reduction RA Number of RABs selected in a DL

UNODEBLDR DlLdrPsRTQosRenegRabNum DL LDR un-ctrl RT Qos re-ne Number of RABs selected in a D

UNODEBLDR DlCSInterRatShouldBeHOUe DL CS should be ho user num Number of users selected in a

UNODEBLDR DlPSInterRatShouldBeHOUe DL PS should be ho user num Number of users selected in a

UNODEBLDR DlCSInterRatShouldNotHOU DL CS should not be ho user Number of users selected in a

UNODEBLDR DlPSInterRatShouldNotHOUe DL PS should not be ho user Number of users selected in a

UNODEBLDR UlLdrFirstAction UL LDR first action

UNODEBLDR UlLdrSecondAction UL LDR second action This parameter has the same co

UNODEBLDR UlLdrThirdAction UL LDR third action This parameter has the same co

UNODEBLDR UlLdrFourthAction UL LDR fourth action This parameter has the same co

UNODEBLDR UlLdrFifthAction UL LDR fifth action This parameter has the same co

UNODEBLDR UlLdrSixthAction UL LDR Sixth action This parameter has the same co

UNODEBLDR UlLdrBERateReductionRabNu UL LDR-BE rate reduction RA Number of RABs selected in a UL

UNODEBLDR UlLdrPsRTQosRenegRabNum UL LDR un-ctrl RT Qos re-ne Number of RABs selected in a U

UNODEBLDR UlCSInterRatShouldBeHOUe UL CS should be ho user num Number of users selected in a

UNODEBLDR UlPSInterRatShouldBeHOUe UL PS should be ho user num Number of users selected in a

UNODEBLDR UlCSInterRatShouldNotHOU UL CS should not be ho user Number of users selected in a

UNODEBLDR UlPSInterRatShouldNotHOUe UL PS should not be ho user Number of users selected in a

UNODEBLDR UlLdrCreditSfResThd Ul LDR Credit SF reserved thr Threshold of SF reserved in upl

UNODEBLDR DlLdrCreditSfResThd Dl LDR Credit SF reserved thr Threshold of SF reserved in do

UNODEBLDR UlTtiCreditSfResThd Ul TTI HO Credit SF reserved The threshold of the reserved SF

UNODEBNAME NewNodeBName NodeB New Name MOD UNODEBNAME(MandatoUniquely identifying the name

UNODEBOLC IubDlOlcRelRabNum DL OLC released RAB number Number of RABs selected in one

UNODEBOLC IubUlOlcRelRabNum UL OLC released RAB number Number of RABs selected in one

UNRELATION RNCId RNC ID RMV UNRELATION(Optional) ID of an RNC

UNRELATION CellId Cell ID RMV UNRELATION(MandatoryID of a cell. For detailed inf

UNRELATION NCellType Neighboring Cell Type RMV UNRELATION(MandatoryNeighboring relation type to b

UNRIGLBCNIDMAP CnOpIndex Cn Operator Index Represent an index for a CN o

UNRIGLBCNIDMAP NRI Network resource identity

UNRNC NRncId Neighboring RNC ID Neighboring RNC ID.

UNRNC SHOTRIG SHO cross IUR trigger

UNRNC HHOTRIG HHO cross IUR trigger Indicating whether to trigger

UNRNC ServiceInd CN domain indication Indicating whether to support

UNRNC IurExistInd IUR Interface Existing Indicati Indicating whether to config

UNRNC RncProtclVer RNC protocol version Protocol version supported by

UNRNC SuppIurCch IUR CCH support flag Indicating whether to support

UNRNC HhoRelocProcSwitch Relocation with HHO process

UNRNC PsBeProcType Handover Type for PS BE Traff Indicating whether to replace

UNRNC IurHsdpaSuppInd Hsdpa cap ind over IUR for Indicating whether to support

UNRNC IurHsupaSuppInd Hsupa cap ind over IUR for Indicating whether to support

UNRNC IubUPPrivateInterfaceSwitch Iub Private Interface Switch of Indicating whether the Iub pr

UNRNC CSVoiceOverHspaSuppInd H2D procedure before reloc

UNRNC RsvdPara1 Reserved parameter 1 Reserved parameter 1.

UNRNC RsvdPara2 Reserved parameter 2 Reserved parameter 2.

UNRNC IubCPPrivateInterfaceSwitch Iub Private Interface Switch of Indicating whether the Iub pri

UNRNCURA NRncId Neighboring RNC ID Neighboring RNC ID.

UNRNCURA URAId URA ID URA ID.

UNRNCURA CnOpIndex Cn Operator Index ADD UNRNCURA(Mandatory) Represent an index for a CN o

UOPERATORCFGPARA CnOpIndex Cn Operator Index SET UOPERATORCFGPARA(MRepresent an index for a CN o

UOPERATORSHARINGMODERANSharingSupport RAN Sharing Support SET UOPERATORSHARINGMOWhen RAN Sharing Supported,

UOPERATORSHARINGMODEMOCNSupport MOCN Support SET UOPERATORSHARINGMOThis parameter determines wh

UOPERATORSHARINGMODEInterPlmnHoAllowedIntraRat Intra RAT Inter Plmn Ho Allow SET UOPERATORSHARINGMOThis parameter specifies wheth

UOPERATORSHARINGMODEInterPlmnHoAllowedInterRat Inter RAT Inter Plmn Ho Allow SET UOPERATORSHARINGMOThis parameter specifies wheth

UOPERATORSHARINGMODEDefaultCnOp Default CnOperator SET UOPERATORSHARINGMOThis parameter specifies the d

UOPERATORSHARINGMODEMocnControlSwitch Mocn Control Switch SET UOPERATORSHARINGMO

UOPERSCHEDULEPRIOMAP CnOpIndex CN Operator Index Index of the CN operator.

UOPERSCHEDULEPRIOMAP TrafficClass Traffic Class Traffic class. This parameter o

UOPERSCHEDULEPRIOMAP UserPriority User Priority User priority that is defined

ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)

The inter-frequency load handover has no impact on the QoS of users and can balance the cell load, so the inter-frequency load handover usually serves as the first action.The BE service rate reduction is effective only when the DCCC algorithm is enabled.ADD UNODEBLDR(Optional)

MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)ADD UNODEBLDR(Optional)MOD UNODEBLDR(Optional)

ADD UNODEBOLC(Optional)MOD UNODEBOLC(Optional)ADD UNODEBOLC(Optional)MOD UNODEBOLC(Optional)

ADD UNRIGLBCNIDMAP(Mandatory)RMV UNRIGLBCNIDMAP(Mandatory)ADD UNRIGLBCNIDMAP(Mandatory)RMV UNRIGLBCNIDMAP(Mandatory)

2. If multiple pool areas overlap, the NRI uniquely identify all the CN nodes connected to it.3. A CN node can have multiple NRIs. In one pool area, however, an NRI can only correspond to one CN node.MOD UNRNC(Mandatory)

RMV UNRNC(Mandatory)ADD UNRNC(Mandatory)MOD UNRNC(Optional)

2) HSPA_SHO_SWITCH. Indicating whether to trigger soft handover for HSPA cross the Iur interface.3) NON_HSPA_SHO_SWITCH. Indicating whether to trigger soft handover for PS(R99) cross the Iur interface.ADD UNRNC(Mandatory)

MOD UNRNC(Optional)ADD UNRNC(Mandatory)MOD UNRNC(Optional)ADD UNRNC(Mandatory)MOD UNRNC(Optional)ADD UNRNC(Mandatory)MOD UNRNC(Optional)ADD UNRNC(Optional)MOD UNRNC(Optional)ADD UNRNC(Optional)MOD UNRNC(Optional)

1) DL_DCCH_SWITCH. When it is checked, SRNC will include the IE "RB Id for handover message" in the IE "SRNS Relocation Info", the target RNC should choose the IE "DL DCCH message" and include the DL DCCH message that should be transmitted transparently to the UE by the source RNC. In that case, the target RNC is integrity protecting the message if applicable. 2) IUR_TRG_SWITCH. When it is checked, relocation execution may trigger as an implementation option from the Iur interface.ADD UNRNC(Optional)

MOD UNRNC(Optional)ADD UNRNC(Optional)MOD UNRNC(Optional)ADD UNRNC(Optional)MOD UNRNC(Optional)ADD UNRNC(Optional)MOD UNRNC(Optional)ADD UNRNC(Optional)MOD UNRNC(Optional)

set to ON, the HSPA need not be degraded to the DCH before therelocation procedure.ADD UNRNC(Optional)

MOD UNRNC(Optional)ADD UNRNC(Optional)MOD UNRNC(Optional)ADD UNRNC(Optional)MOD UNRNC(Optional)ADD UNRNCURA(Mandatory)RMV UNRNCURA(Mandatory)ADD UNRNCURA(Mandatory)RMV UNRNCURA(Mandatory)

1) COMM_MOCN_NRI_GLOBAL_CONFIG_MODE_SWITCH: When the switch is selected, the NRI of any CN node in the RNC is unique in the CS or PS domain.2) COMM_MIB_MULTI_PLMN_LIST_ALLOWED_SWITCH: When the switch is selected, the operator information configured in the MOCN cell is sent as Multi PLMN List in the system information.ADD UOPERSCHEDULEPRIOMAP(Mandatory)

RMV UOPERSCHEDULEPRIOMAP(Mandatory)ADD UOPERSCHEDULEPRIOMAP(Mandatory)RMV UOPERSCHEDULEPRIOMAP(Mandatory)ADD UOPERSCHEDULEPRIOMAP(Mandatory)RMV UOPERSCHEDULEPRIOMAP(Mandatory)

UOPERSCHEDULEPRIOMAP THPClass Traffic Handling Priority Class Traffic Handling Priority (THP

UOPERSCHEDULEPRIOMAP SPI Scheduling Priority Indicator ADD UOPERSCHEDULEPRIOMScheduling priority of interacti

UOPERSPIWEIGHT CnOpIndex CN Operator Index Index of the CN operator.

UOPERSPIWEIGHT SPI Scheduling Priority Indicator Scheduling priority of interacti

UOPERSPIWEIGHT SpiWeight SPI Weight ADD UOPERSPIWEIGHT(MandSpecifies the weight for service

UOPERTHPCLASS CnOpIndex CN Operator Index Index of the CN operator.

UOPERTHPCLASS THP1Class User Class of Traffic Handling P Priority class associated with









UOPERTHPCLASS THP10Class User Class of Traffic Handling Priority class associated with






UOPERUSERGBR CnOpIndex CN Operator Index Index of the CN operator.

UOPERUSERGBR TrafficClass Traffic Class Traffic class which includes B

UOPERUSERGBR THPClass Traffic Handling Priority Class Traffic Handling Priority (THP

UOPERUSERGBR BearType Bearer Type Bearer type of the service. R9

UOPERUSERGBR UserPriority User Priority User priority that is defined

UOPERUSERGBR UlGBR Uplink GBR for BE service Uplink guaranteed bit rate (GB

UOPERUSERGBR DlGBR Downlink GBR for BE service Downlink guaranteed bit rate (

UOPERUSERHAPPYBR CnOpIndex CN Operator Index Index of the CN operator.

UOPERUSERHAPPYBR TrafficClass Traffic class Traffic class

UOPERUSERHAPPYBR UserPriority User Priority User priority that is defined

UOPERUSERHAPPYBR THPClass Traffic Handling Priority Class Traffic Handling Priority (THP

UOPERUSERHAPPYBR HappyBR Happy bit rate ADD UOPERUSERHAPPYBR(OpDefines the happy bit rate of

UOPERUSERPRIORITY CnOpIndex CN Operator index Specifies the index of the tele

UOPERUSERPRIORITY ARP1Priority User_priority of Allocation/Rete User_priority corresponding to A









UOPERUSERPRIORITY ARP10Priority User_priority of Allocation/Rete User_priority corresponding to






UOPERUSERPRIORITY PriorityReference Integrate Priority Configured

UOPERUSERPRIORITY CarrierTypePriorInd Indicator of Carrier Type Priori Decide which carrier is prior w

UPCCPCH CellId Cell ID ID of a cell. For detailed inf

UPCCPCH PhyChId PCCPCH ID ADD UPCCPCH(Optional) Uniquely identifying a PCCPCH

UPCH CellId Cell ID ID of a cell. For detailed inf

UPCH PhyChId SCCPCH ID ADD UPCH(Mandatory) Uniquely identifying an SCCPCH

UPCH TrChId PCH ID Uniquely identifying a PCH in a

UPCH RateMatchingAttr Rate Matching Attribute ADD UPCH(Optional) The rate matching factor of a t

UPCH ToAWS Time of Arrival Window StartpoADD UPCH(Optional) Start point of the arrival windo

UPCH ToAWE Time of Arrival Window Endpoi ADD UPCH(Optional) End point of the arrival window

UPCH PCHPower PCH Power ADD UPCH(Optional) Offset of the PCH transmit pow

UPCHDYNTFS CellId Cell ID ID of a cell. For detailed inf

ADD UOPERSCHEDULEPRIOMAP(Mandatory)RMV UOPERSCHEDULEPRIOMAP(Mandatory)

ADD UOPERSPIWEIGHT(Mandatory)RMV UOPERSPIWEIGHT(Mandatory)ADD UOPERSPIWEIGHT(Mandatory)RMV UOPERSPIWEIGHT(Mandatory)

MOD UOPERTHPCLASS(Mandatory)RMV UOPERTHPCLASS(Mandatory)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)ADD UOPERTHPCLASS(Optional)MOD UOPERTHPCLASS(Optional)MOD UOPERUSERGBR(Mandatory)RMV UOPERUSERGBR(Mandatory)MOD UOPERUSERGBR(Mandatory)RMV UOPERUSERGBR(Mandatory)MOD UOPERUSERGBR(Mandatory)RMV UOPERUSERGBR(Mandatory)MOD UOPERUSERGBR(Mandatory)RMV UOPERUSERGBR(Mandatory)MOD UOPERUSERGBR(Mandatory)RMV UOPERUSERGBR(Mandatory)ADD UOPERUSERGBR(Optional)MOD UOPERUSERGBR(Optional)ADD UOPERUSERGBR(Optional)MOD UOPERUSERGBR(Optional)ADD UOPERUSERHAPPYBR(Mandatory)RMV UOPERUSERHAPPYBR(Mandatory)ADD UOPERUSERHAPPYBR(Mandatory)RMV UOPERUSERHAPPYBR(Mandatory)ADD UOPERUSERHAPPYBR(Mandatory)RMV UOPERUSERHAPPYBR(Mandatory)ADD UOPERUSERHAPPYBR(Mandatory)RMV UOPERUSERHAPPYBR(Mandatory)

MOD UOPERUSERPRIORITY(Mandatory)RMV UOPERUSERPRIORITY(Mandatory)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)ADD UOPERUSERPRIORITY(Optional)MOD UOPERUSERPRIORITY(Optional)

If the ARP is preferably used, the priority sequence is gold > silver > copper. If the ARPs are all the same, the TrafficClass is used and the priority sequence is conversational > streaming > interactive > background.If the TrafficClass is preferably used, the priority sequence is conversational > streaming > interactive > background. If the TrafficClass factors are all the same, the ARP factor is used and the priority sequence is gold > silver > copper.ADD UOPERUSERPRIORITY(Optional)

MOD UOPERUSERPRIORITY(Optional)ADD UPCCPCH(Mandatory)RMV UPCCPCH(Mandatory)

ADD UPCH(Mandatory)RMV UPCH(Mandatory)

ADD UPCH(Optional)RMV UPCH(Mandatory)

ADD UPCHDYNTFS(Mandatory)RMV UPCHDYNTFS(Mandatory)

UPCHDYNTFS TrChId PCH ID Uniquely identifying a PCH in a

UPCHDYNTFS RLCSize RLC Size This parameter defines the RLC

UPCHDYNTFS TFsNumber Number of TFs ADD UPCHDYNTFS(MandatorThis parameter defines the num

UPCHDYNTFS TbNumber1 TB Number of TF1 ADD UPCHDYNTFS(Optional) This parameter defines the num

UPCHDYNTFS TbNumber2 TB Number of TF2 ADD UPCHDYNTFS(Optional) This parameter defines the num

UPCPICH CellId Cell ID ID of a cell. For detailed inf

UPCPICH PhyChId PCPICH ID ADD UPCPICH(Optional) Uniquely identifying a PCPICH

UPCPICH PCPICHPower PCPICH Transmit Power ADD UPCPICH(Optional) TX power of the PCPICH in a ce

UPCPICH MaxPCPICHPower Max Transmit Power of PCPI ADD UPCPICH(Optional) Maximum TX power of the PCPIC

UPCPICH MinPCPICHPower Min Transmit Power of PCPIC ADD UPCPICH(Optional) Minimum TX power of the PCPICH

UPCPICHPWR CellId Cell ID MOD UPCPICHPWR(MandatorID of a cell. For detailed inf

UPCPICHPWR MaxPCPICHPower Max Transmit Power of PCPI MOD UPCPICHPWR(Optional Maximum TX power of the PCPIC

UPCPICHPWR MinPCPICHPower Min Transmit Power of PCPIC MOD UPCPICHPWR(Optional Minimum TX power of the PCPICH

UPICH CellId Cell ID ID of a cell. For detailed inf

UPICH PhyChId SCCPCH ID ADD UPICH(Mandatory) Uniquely identifying an SCCPCH

UPICH PICHId PICH ID Uniquely identifying a PICH in

UPICH PICHMode PICH Mode ADD UPICH(Optional) Indicating the number of PIs c

UPICH STTDInd STTD Indicator ADD UPICH(Optional) This parameter indicates wheth

UPICHPWROFFSET CellId Cell ID MOD UPICHPWROFFSET(MandID of a cell. For detailed inf

UPICHPWROFFSET PICHPowerOffset PICH Power Offset MOD UPICHPWROFFSET(MandDifference between the transm

UPLMNVALTAGRANGE ModType Modification Type MOD UPLMNVALTAGRANGE(MModification type.

UPLMNVALTAGRANGE CnOpIndex CN Operator index MOD UPLMNVALTAGRANGE(MSpecifies the index of the tele

UPLMNVALTAGRANGE LAC Location area code MOD UPLMNVALTAGRANGE(MIdentifying a location area wi

UPLMNVALTAGRANGE RAC Routing area code MOD UPLMNVALTAGRANGE(MIdentifying a routing area in a

UPLMNVALTAGRANGE PlmnValTagMin Min PLMN value tag MOD UPLMNVALTAGRANGE(OpThe minimum PLMN value tag co

UPLMNVALTAGRANGE PlmnValTagMax Max PLMN value tag MOD UPLMNVALTAGRANGE(OpThe maximum PLMN value tag co

UPOOLPRIMHOSTPOLICY ReHostPolicy Re-host Policy Type SET UPOOLPRIMHOSTPOLICYThis parameter specifies re-h

UPOOLPRIMHOSTPOLICY Delay Delay Time Length SET UPOOLPRIMHOSTPOLICYThis parameter specifies the de

UPOOLPRIMHOSTPOLICY AbsTime Specify Time SET UPOOLPRIMHOSTPOLICYThis parameter specifies the ti

UPRACH CellId Cell ID ID of a cell. For detailed inf

UPRACH PhyChId PRACH ID Uniquely identifying a PRACH i

UPRACH PreambleSignatures Preamble Signatures MOD UPRACH(Optional) Sequence Number of an availabl

UPRACH RACHSubChNo RACH Sub Channel No. MOD UPRACH(Optional) Sequence Number of an availabl

UPRACHACTOASCMAP CellId Cell ID ID of a cell. For detailed inf

UPRACHACTOASCMAP PhyChId PRACH ID Uniquely identifying a PRACH i

UPRACHACTOASCMAP Ac09ToAsc AC 0~9 to ASC mapping It defines the mapping of AC 0

UPRACHACTOASCMAP Ac10ToAsc AC 10 to ASC mapping It defines the mapping of AC 1






UPRACHASC CellId Cell ID ID of a cell. For detailed inf

UPRACHASC PhyChId PRACH ID Uniquely identifying a PRACH i

UPRACHASC AccessServiceClass Access Service Class Identifying an ASC

UPRACHASC AvailablesignatureStartIndex Available Signature Start Inde Identifying the available signa

UPRACHASC AvailablesignatureEndIndex Available Signature End Index Identifying the available signa

UPRACHASC AvailableSubchannelCtrlWord Available Subchannel Control Identifying the available sub c

UPRACHASC PersistScalingFactor Persist Scaling Factor ADD UPRACHASC(MandatoryIt is used to calculate the co

UPRACHBASIC CellId Cell ID ADD UPRACHBASIC(MandatoID of a cell. For detailed inf

UPRACHBASIC PhyChId PRACH ID ADD UPRACHBASIC(OptionalUniquely identifying a PRACH i

UPRACHBASIC PreambleSignatures Preamble Signatures ADD UPRACHBASIC(MandatoSequence Number of an availabl

UPRACHBASIC RACHSubChNo RACH Sub Channel No. ADD UPRACHBASIC(MandatoSequence Number of an availabl

UPRACHBASIC Constantvalue Constant Value for Calculating ADD UPRACHBASIC(Optional

UPRACHBASIC PreambleRetransMax Max Preamble Retransmission ADD UPRACHBASIC(OptionalThe maximum number of preambl

UPRACHBASIC PowerRampStep Power Increase Step ADD UPRACHBASIC(OptionalThe power ramp step of the ran

UPRACHBASIC CTFCSize CTFC Length of TFCS ADD UPRACHBASIC(OptionalMaximum number of bits of the

UPRACHSLOTFORMAT CellId Cell ID ID of a cell. For detailed inf

UPRACHSLOTFORMAT PhyChId PRACH ID Uniquely identifying a PRACH i

UPRACHSLOTFORMAT SlotFormatNum Number of PRACH Slot Forma ADD UPRACHSLOTFORMAT(MNumber of available PRACH time

UPRACHSLOTFORMAT SlotFormat1 Slot Format 1 ADD UPRACHSLOTFORMAT(OpSequence number of available P

ADD UPCHDYNTFS(Optional)RMV UPCHDYNTFS(Mandatory)ADD UPCHDYNTFS(Mandatory)RMV UPCHDYNTFS(Mandatory)

ADD UPCPICH(Mandatory)RMV UPCPICH(Mandatory)

ADD UPICH(Mandatory)RMV UPICH(Mandatory)

ADD UPICH(Optional)RMV UPICH(Mandatory)

MOD UPRACH(Mandatory)RMV UPRACH(Mandatory)MOD UPRACH(Mandatory)RMV UPRACH(Mandatory)

MOD UPRACHACTOASCMAP(Mandatory)RMV UPRACHACTOASCMAP(Mandatory)MOD UPRACHACTOASCMAP(Mandatory)RMV UPRACHACTOASCMAP(Mandatory)ADD UPRACHACTOASCMAP(Optional)MOD UPRACHACTOASCMAP(Optional)ADD UPRACHACTOASCMAP(Optional)MOD UPRACHACTOASCMAP(Optional)ADD UPRACHACTOASCMAP(Optional)MOD UPRACHACTOASCMAP(Optional)ADD UPRACHACTOASCMAP(Optional)MOD UPRACHACTOASCMAP(Optional)ADD UPRACHACTOASCMAP(Optional)MOD UPRACHACTOASCMAP(Optional)ADD UPRACHACTOASCMAP(Optional)MOD UPRACHACTOASCMAP(Optional)ADD UPRACHACTOASCMAP(Optional)MOD UPRACHACTOASCMAP(Optional)MOD UPRACHASC(Mandatory)RMV UPRACHASC(Mandatory)MOD UPRACHASC(Mandatory)RMV UPRACHASC(Mandatory)MOD UPRACHASC(Mandatory)RMV UPRACHASC(Mandatory)ADD UPRACHASC(Optional)MOD UPRACHASC(Optional)ADD UPRACHASC(Optional)MOD UPRACHASC(Optional)ADD UPRACHASC(Optional)MOD UPRACHASC(Optional)

This parameter specifies a constant used at calculation of the initial transmit power of the first preamble, to be used in the random access procedure.The formula is as follows: Preamble_Initial_Power = Primary CPICH DL TX power-CPICH_RSCP + UL interference + Constant Value. Where, Preamble_Initial_Power is the preamble initial TX power, Primary CPICH DL TX power is the downlink transmit (TX) power of PCPICH, CPICH_RSCP is the receive signaling code power of the PCPICH measured by UEs, and UL interference is the uplink interference. For detailed information of this parameter, refer to 3GPP TS 25.211.

ADD UPRACHSLOTFORMAT(Mandatory)RMV UPRACHSLOTFORMAT(Mandatory)ADD UPRACHSLOTFORMAT(Optional)RMV UPRACHSLOTFORMAT(Mandatory)




UPRACHTFC CellId Cell ID ID of a cell. For detailed inf

UPRACHTFC PhyChId PRACH ID Uniquely identifying a PRACH i

UPRACHTFC CTFC Calculated Transport Format Uniquely identifying a TFC on t

UPRACHTFC PowerOffsetPpm Power Offset ADD UPRACHTFC(Mandatory The power offset between the l

UPRACHTFC GainFactorBetaC Gain Factor BetaC ADD UPRACHTFC(Mandatory This parameter specifies the po

UPRACHTFC GainFactorBetaD Gain Factor BetaD ADD UPRACHTFC(Optional) The power occupancy factor of

UPRACHUUPARAS CellId Cell ID MOD UPRACHUUPARAS(MandID of a cell. For detailed inf

UPRACHUUPARAS PhyChId PRACH ID MOD UPRACHUUPARAS(MandUniquely identifying a PRACH i

UPRACHUUPARAS Constantvalue Constant Value for Calculating MOD UPRACHUUPARAS(Optio

UPRACHUUPARAS PowerRampStep Power Increase Step MOD UPRACHUUPARAS(OptioThe power ramp step of the ran

UPRACHUUPARAS PreambleRetransMax Max Preamble Retransmission MOD UPRACHUUPARAS(OptioThe maximum number of preambl

UPSCH CellId Cell ID ID of a cell. For detailed inf

UPSCH PhyChId PSCH ID ADD UPSCH(Optional) Uniquely identifying a PSCH in

UPSCH PSCHPower PSCH Transmit Power ADD UPSCH(Optional) Offset of the PSCH transmit po

UPSINACTTIMER PsInactTmrForCon Conversational service T1 SET UPSINACTTIMER(OptionaWhen detecting that the Ps' Co

UPSINACTTIMER ProtectTmrForCon Conversational service T2 SET UPSINACTTIMER(OptionaAfter sending release request

UPSINACTTIMER PsInactTmrForStr Streaming service T1 SET UPSINACTTIMER(OptionaWhen detecting that the Ps' St

UPSINACTTIMER ProtectTmrForStr Streaming service T2 SET UPSINACTTIMER(OptionaAfter sending release request

UPSINACTTIMER PsInactTmrForInt Interactive service T1 SET UPSINACTTIMER(OptionaWhen detecting that the Ps' Int

UPSINACTTIMER ProtectTmrForInt Interactive service T2 SET UPSINACTTIMER(OptionaAfter sending release request t

UPSINACTTIMER PsInactTmrForBac Background service T1 SET UPSINACTTIMER(OptionaWhen detecting that the Ps' Ba

UPSINACTTIMER ProtectTmrForBac Background service T2 SET UPSINACTTIMER(OptionaAfter sending release request

UPSINACTTIMER PsInactTmrForPreFstDrm FAST DORMANCY USER T1 i SET UPSINACTTIMER(OptionaThis parameter specifies the v

UPSINACTTIMER ProtectTmrForImsSig IMS signal T2 SET UPSINACTTIMER(OptionaAfter sending release request t

UPSINACTTIMER PSInactTmrForImsSig IMS signal T1 SET UPSINACTTIMER(OptionaWhen detecting that the Ps' IM

UPSINACTTIMER PsInactTmrForFstDrmDch FAST DORMANCY USER T1 i SET UPSINACTTIMER(OptionaThis parameter specifies the v

UPSINACTTIMER PsInactTmrForFstDrmFach FAST DORMANCY USER T1 i SET UPSINACTTIMER(OptionaThis parameter specifies the v

UPTTSTATETRANS PTTDH2FStateTransTimer PTT DCH/HSPA to FACH State SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTCpc2FStateTransTimer PTT CPC_HSPA to FACH State SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTDH2EFachStateTransTimePTT DCH/HSPA to E_FACH StatSET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTCpc2EFachStateTransTim PTT CPC_HSPA to E_FACH StaSET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTDH2FTvmThd PTT D/H2F 4B Threshold SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTDH2FTvmTimeToTrig PTT D/H2F 4B Time SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTDH2FTvmPTAT PTT D/H2F 4B Pending Time SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTE2FThrouMeasPeriod PTT E-DCH Throu Meas Perio SET UPTTSTATETRANS(OptioPeriod in which the E-DCH thr

UPTTSTATETRANS PTTE2FThrouThd PTT E-DCH2F 4B Threshold SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTE2FThrouTimeToTrig PTT E-DCH2F 4B Period Amo SET UPTTSTATETRANS(OptioNumber of periods in which th

UPTTSTATETRANS PTTE2FThrouPTAT PTT E-DCH2F 4B Pending PerSET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTF2PStateTransTimer PTT FACH to PCH State TransiSET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTF2PTvmThd PTT F2P 4B Threshold SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTF2PTvmTimeToTrig PTT F2P 4B Time SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTF2PTvmPTAT PTT F2P 4B Pending Time SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTF2DHTvmThd PTT F2D/HSPA 4A Threshold SET UPTTSTATETRANS(Optio

UPTTSTATETRANS PTTF2DHTvmTimeToTrig PTT F2D/HSPA 4A Time SET UPTTSTATETRANS(Optio

UQOSACT BEQosPerform QOS Switch for BE Traffic SET UQOSACT(Optional) When the parameter is set to Y

UQOSACT AMRQosPerform QOS Switch for AMR Traffic SET UQOSACT(Optional) When the parameter is set to Y

UQOSACT VPQosPerform QOS Switch for VP Traffic SET UQOSACT(Optional) When the parameter is set to Y

UQOSACT BeUlAct1 First Action for BE Uplink QOS SET UQOSACT(Optional) The first action selected by th

UQOSACT BeUlAct2 Second Action for BE Uplink SET UQOSACT(Optional) The second action selected by

UQOSACT BeUlAct3 Third Action for BE Uplink QO SET UQOSACT(Optional) The third action selected by th

UQOSACT BeUlRateAdjTimerLen Wait Timer for BE Uplink Rate SET UQOSACT(Optional)

UQOSACT BeDlAct1 First Action for BE Downlink SET UQOSACT(Optional) The first action selected by th

UQOSACT BeDlAct2 Second Action for BE Downli SET UQOSACT(Optional) The second action selected by

UQOSACT BeDlAct3 Third Action for BE Downlink SET UQOSACT(Optional) The third action selected by th

UQOSACT BeUlEvTrigInd Indicator for BE Uplink QOS E SET UQOSACT(Optional) For BE service, When the para

UQOSACT SrncBeDlRlcQosSwitch Srnc Parameter for BE Downl SET UQOSACT(Optional) When the parameter is set to Y

UQOSACT DrncBeDlRlcQosSwitch DRNC Parameter for BE DownSET UQOSACT(Optional) If the parameter is set to YES

UQOSACT UlQosAmrAdjSwitch Adjustment Switch for AMR UpSET UQOSACT(Optional) Rate adjustment switch of link

ADD UPRACHTFC(Mandatory)RMV UPRACHTFC(Mandatory)ADD UPRACHTFC(Optional)RMV UPRACHTFC(Mandatory)ADD UPRACHTFC(Mandatory)RMV UPRACHTFC(Mandatory)

This parameter specifies a constant used at calculation of the initial transmit power of the first preamble, to be used in the random access procedure.The formula is as follows: Preamble_Initial_Power = Primary CPICH DL TX power-CPICH_RSCP + UL interference + Constant Value. Where, Preamble_Initial_Power is the preamble initial TX power, Primary CPICH DL TX power is the downlink transmit (TX) power of PCPICH, CPICH_RSCP is the receive signaling code power of the PCPICH measured by UEs, and UL interference is the uplink interference. For detailed information of this parameter, refer to 3GPP TS 25.211.

ADD UPSCH(Mandatory)RMV UPSCH(Mandatory)

If the UE remains in low activity state after the timer expires, the state of the UE is changed from DCH/HSPA to the FACH. If this parameter is set to a small value, whether the UE is in low activity state cannot be determined. If this parameter is set to a great value, the dedicated channels are wasted.If the UE remains in low activity state after the timer expires, the state of the UE is changed from CPC_HSPA to FACH. If this parameter is set to a small value, whether the UE is in low activity state cannot be determined. If this parameter is set to a great value, the dedicated channels are wasted.If the UE remains in low activity state after the timer expires, the state of the UE is changed from DCH/HSPA to E_FACH. If this parameter is set to a small value, whether the UE is in low activity state cannot be determined. If this parameter is set to a great value, the dedicated channels are wasted.If the UE remains in low activity state after the timer expires, the state of the UE is changed from CPC_HSPA to E_FACH. If this parameter is set to a small value, whether the UE is in low activity state cannot be determined. If this parameter is set to a great value, the dedicated channels are wasted.Threshold for reporting the event 4B in DCH/HSPA. When the traffic of the PTT user in DCH/HSPA state is constantly lower than this threshold in a period, the UE reports the event 4B.Period during which the traffic of the PTT user is constantly lower than the event 4B threshold so that the UE reports the event 4B. When the traffic of the PTT user in DCH/HSPA state is constantly lower than the event 4B threshold in this period, the UE reports the event 4B. This parameter can prevent unnecessary reports o be triggered, caused by traffic volume variation.If this parameter is specified, the system prohibits the UE from reporting the event 4B again during the period when the event 4B is suspended. If the parameter value is too small, too many 4B events may be reported, thus increasing the RNC load. If the parameter value is too great, the event 4B may not be reported timely.

Threshold for reporting the event 4B relevant to the E-DCH throughput. When the uplink throughput of the PTT user in HSPA state is constantly lower than this threshold in a period, the UE reports the event 4B.

If this parameter is specified, the system prohibits the UE from reporting the event 4B again during the "PTT E-DCH2F 4B Pending Period Amount". If the parameter value is too small, too many 4B events may be reported, thus increasing the RNC load. If the parameter value is too great, the event 4B may not be reported timely.If the UE remains in low activity state after the timer expires, the state of the UE is changed from CELL_FACH to the CELL_PCH. If this parameter is set to a small value, whether the UE is in low activity state cannot be determined. If this parameter is set to a great value, the common channels are wasted.Threshold for reporting the event 4B. When the traffic of the PTT user in CELL_FACH state is constantly lower than this threshold in a period, the UE reports the event 4B.Period during which the traffic of the PTT user is constantly lower than the event 4B threshold so that the UE reports the event 4B. When the traffic of the PTT user in CELL_FACH state is constantly lower than the event 4B threshold in this period, the UE reports the event 4B. This parameter can prevent unnecessary reports o be triggered, caused by traffic volume variation.If this parameter is specified, the system prohibits the UE from reporting the event 4B again during the period when the event 4B is suspended. If the parameter value is too small, too many 4B events may be reported, thus increasing the RNC load. If the parameter value is too great, the event 4B may not be reported timely.Threshold for reporting the 4A event. When the traffic of the PTT user in CELL_FACH state is constantly greater than this threshold in a period, the UE reports the 4A event.Period during which the traffic of the PTT user is constantly greater than the 4A event threshold so that the UE reports the event 4B. When the traffic of the PTT user in DCH/HSPA state is constantly greater than the 4A event threshold in this period, the UE reports the 4A event. This parameter can prevent unnecessary reports o be triggered, caused by traffic volume variation.

Timer to trigger the next QoS enhancement action for UL BE services. This parameter specifies the duration of waiting for the UL QoS enhanced acknowledgement after UL rate adjustment. The timer starts when the BE UL rate adjustment procedure is triggered, and stops when the RNC receives a 6B1/6B2 event or when the timer expires.

UQOSACT AmrUlRateAdjTimerLen Wait Timer for AMR Uplink Ra SET UQOSACT(Optional)

UQOSACT UlQosAmrInterFreqHoSwitch InterFreq HO For Switch for U SET UQOSACT(Optional) Inter-frequency handover switc

UQOSACT UlQosAmrInterRatHoSwitch InterRat HO Switch for Uplink SET UQOSACT(Optional) Inter-RAT handover switch of l

UQOSACT UlQosWAmrAdjSwitch Switch of WAMR Uplink Rate SET UQOSACT(Optional) Rate adjustment switch of link

UQOSACT WAmrUlRateAdjTimerLen Wait Timer for WAMR Uplink SET UQOSACT(Optional) Timer for triggering a second

UQOSACT UlQosWAmrInterFreqHoSwitc InterFreq HO Switch for Upli SET UQOSACT(Optional) Inter-frequency handover switc

UQOSACT UlQosWAmrInterRatHoSwitch InterRat HO Switch for Uplin SET UQOSACT(Optional) Inter-RAT handover switch of

UQOSACT DlQosAmrAdjSwitch Switch of AMR Downlink Rate SET UQOSACT(Optional) Rate adjustment switch of link

UQOSACT DlQosAmrInterFreqHoSwitch InterFreq HO Switch for Down SET UQOSACT(Optional) Inter-frequency handover switc

UQOSACT DlQosAmrInterRatHoSwitch InterRat HO Switch for Downl SET UQOSACT(Optional) Inter-RAT handover switch of l

UQOSACT DlQosWAmrAdjSwitch Switch for WAMR Downlink RaSET UQOSACT(Optional) Rate adjustment switch of link

UQOSACT DlQosWAmrInterFreqHoSwitc InterFreq HO Switch for WAM SET UQOSACT(Optional) Inter-frequency handover switc

UQOSACT DlQosWAmrInterRatHoSwitch InterRat HO Switch for WAMR SET UQOSACT(Optional) Inter-RAT handover switch of

UQOSACT UlQosVpInterFreqHoSwitch InterFreq HO Switch for Uplin SET UQOSACT(Optional) Inter-frequency handover switc

UQOSACT DlQosVpInterFreqHoSwitch InterFreq HO Switch for Downl SET UQOSACT(Optional) Inter-frequency handover switc

UQOSACT BeUlQos6A1McSwitch Measurement of 6A1 Switch SET UQOSACT(Optional) Event 6A1 measurement switch

UQOSACT BeUlQos5AMcSwitch Measurement of 5A Switch SET UQOSACT(Optional) Event 5A measurement switch wh

UQOSACT BeUlQos6DMcSwitch Measurement of 6D Switch SET UQOSACT(Optional) UL event 6D measurement switch

UQOSACT BEInterIurRateUpTimer Timer for BE Inter Iur Rate SET UQOSACT(Optional) Timer for rejecting rate increa

UQOSHO DlRscpQosHyst Down Link RSCP Used-Freq T SET UQOSHO(Optional)

UQOSHO DLQosMcTimerLen Down Link Qos Measure TimerSET UQOSHO(Optional)

UQOSHO ULQosMcTimerLen Up Link Qos Measure Timer L SET UQOSHO(Optional)

UQOSHO UsedFreqMeasQuantityForQo 3A Used-Freq Measure QuantitSET UQOSHO(Optional)

UQUALITYMEAS UlAmrTrigTime6A1 AMR Trigger Time 6A1 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlAmrTrigTime6A2 AMR Trigger Time 6A2 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlAmrTrigTime6B1 AMR Trigger Time 6B1 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlAmrTrigTime6B2 AMR Trigger Time 6B2 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlAmrTrigTime6D AMR Trigger Time 6D SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlVpTrigTime6A1 VP Trigger Time 6A1 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlVpTrigTime6B1 VP Trigger Time 6B1 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlVpTrigTime6D VP Trigger Time 6D SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlBeTrigTime6A1 BE Trigger Time 6A1 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlBeTrigTime6B1 BE Trigger Time 6B1 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlBeTrigTime6A2 BE Trigger Time 6A2 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlBeTrigTime6B2 BE Trigger Time 6B2 SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlBeTrigTime6D BE Trigger Time 6D SET UQUALITYMEAS(OptionaDuration when the measured val

UQUALITYMEAS UlMeasFilterCoef UL Measurement Filter Coeffic SET UQUALITYMEAS(OptionaSmooth filtering coefficient fo

UQUALITYMEAS DlMeasFilterCoef DL TCP Measurement Filter CoeSET UQUALITYMEAS(OptionaSmooth filtering coefficient fo

UQUALITYMEAS DlAmrTrigTimeE AMR Trigger Time of Event E SET UQUALITYMEAS(OptionaDuration from when the AMR TX

UQUALITYMEAS ChoiceRptUnitForAmrE AMR Reporting Period Unit for SET UQUALITYMEAS(OptionaThis parameter specifies the re

UQUALITYMEAS TenMsecForAmrE AMR Event E Reporting Perio SET UQUALITYMEAS(OptionaThis parameter is valid when th

UQUALITYMEAS MinForAmrE AMR Event E Reporting PeriodSET UQUALITYMEAS(MandatoThis parameter is valid when th

UQUALITYMEAS DlVpTrigTimeE VP Trigger Time of Event E SET UQUALITYMEAS(OptionaDuration from when the VP TX po

UQUALITYMEAS ChoiceRptUnitForVpE VP Reporting Period Unit for E SET UQUALITYMEAS(OptionaThis parameter specifies the re

UQUALITYMEAS TenMsecForVpE VP Event E Reporting Period SET UQUALITYMEAS(OptionaThis parameter is valid when th

UQUALITYMEAS MinForVpE VP Event E Reporting Period SET UQUALITYMEAS(MandatoThis parameter is valid when th

UQUALITYMEAS DlBeTrigTimeE BE Trigger Time of Event E SET UQUALITYMEAS(OptionaDuration from when the BE TX p

UQUALITYMEAS ChoiceRptUnitForBeE BE Reporting Period Unit for E SET UQUALITYMEAS(OptionaThis parameter specifies the re

UQUALITYMEAS TenMsecForBeE BE Event E Reporting Period SET UQUALITYMEAS(OptionaThis parameter is valid when th

UQUALITYMEAS MinForBeE BE Event E Reporting Period SET UQUALITYMEAS(MandatoThis parameter is valid when th

UQUALITYMEAS DlBeTrigTimeF BE Trigger Time of Event F SET UQUALITYMEAS(OptionaDuration within which the measu

UQUALITYMEAS ChoiceRptUnitForBeF BE Reporting Period Unit for E SET UQUALITYMEAS(OptionaThis parameter specifies the re

UQUALITYMEAS TenMsecForBeF BE Event F Reporting Period SET UQUALITYMEAS(OptionaThis parameter is valid when th

UQUALITYMEAS MinForBeF BE Event F Reporting Period SET UQUALITYMEAS(MandatoThis parameter is valid when th

UQUEUEPREEMPT PreemptAlgoSwitch Preempt algorithm switch SET UQUEUEPREEMPT(OptioDetermines whether preemption i

UQUEUEPREEMPT MbmsPreemptAlgoSwitch Mbms PreemptAlgoSwitch SET UQUEUEPREEMPT(OptioIndicates whether the MBMS sup

UQUEUEPREEMPT PreemptRefArpSwitch PreemptRefArpSwitch SET UQUEUEPREEMPT(OptioIndicating whether ARP-based p

UQUEUEPREEMPT QueueAlgoSwitch Queue algorithm switch SET UQUEUEPREEMPT(OptioIndicating whether queue is sup

UQUEUEPREEMPT QueueLen Queue length SET UQUEUEPREEMPT(OptioQueue length. The total number

UQUEUEPREEMPT PollTimerLen Poll timer length SET UQUEUEPREEMPT(OptioTimer length of the queue poll.

UQUEUEPREEMPT MaxQueueTimeLen Max queuing time length SET UQUEUEPREEMPT(OptioMaximum queue time of users. Whe

Timer for triggering a second adjustment of the UL AMR mode. This parameter specifies the duration of waiting for the voice quality enhanced acknowledgement after the UL AMR mode adjustment when the associated command is delivered. The UL AMRC rate adjust timer starts when AMRC mode adjustment procedure is triggered, and stops when the next measurement report is received. If no measurement report is received when the UL AMRC timer expires, you can infer that the measured value remains in the same state as that before the previous UL AMRC mode adjustment. The previous AMRC mode adjustment is not effective, and another adjustment is required.

As for the impact on network performance:The larger the value of the parameter is, the more easily event 2B, inter-frequency handover based on Qos, and event 3A, inter-RAT handover based on Qos, can be triggered, and thus the more timely the handover to the target cell can be performed.It reduces the influence of long time compressed mode to the serving cell.The compressed mode may be stopped ahead of time, which can cause the result that the UE fails to initiate inter-frequency or inter-RAT handover, and thus can lead to call drops.It reduces the influence of long time compressed mode to the serving cell.The compressed mode may be stopped ahead of time, which can cause the result that the UE fails to initiate inter-frequency or inter-RAT handover, and thus can lead to call drops.As for the impact on network performance:When the UE moves to the cell border, and there is a intra-frequency neighboring cell in the moving direction, CPCICH Ec/No varies faster than RSCP and the quality of the current cell should be evaluated according to CPCICH Ec/No. When there is no intra-frequency neighboring cell in the direction, CPCICH RSCP varies faster than Ec/No and the quality should be evaluated according to CPCICH RSCP. If the measurement quantity is not properly selected, the handover may not be performed timely, thus resulting in call drops.

UQUEUEPREEMPT EmcPreeRefVulnSwitch Preemptvulnerability for EmergSET UQUEUEPREEMPT(OptioWhen the switch is enabled, us

URAC CnOpIndex Cn Operator Index Represent an index for a CN o

URAC LAC Location Area Code Identifies a location area cod

URAC RAC Routing Area Code Identifying a routing area in a

URAC PlmnValTagMin Min PLMN Value Tag ADD URAC(Mandatory) Minimum PLMN tag value corresp

URAC PlmnValTagMax Max PLMN Value Tag ADD URAC(Mandatory) Maximum PLMN tag value corresp

URACH CellId Cell ID ID of a cell. For detailed inf

URACH PhyChId PRACH ID ADD URACH(Optional) Uniquely identifying a PRACH i

URACH TrChId RACH ID Uniquely identifying an RACH i

URACH RateMatchingAttr Rate Matching Attribute ADD URACH(Optional) This parameter defines the rat

URACH NB01min Random Back-off Lower Limit Lower limit of random access b

URACH NB01max Random Back-off Upper Limit Upper limit of random access b

URACH Mmax Max Preamble Loop The parameter specifies the m

URACHDYNTFS CellId Cell ID ID of a cell. For detailed inf

URACHDYNTFS TrChId RACH ID Uniquely identifying an RACH i

URACHDYNTFS RLCSize RLC Size This parameter defines the RLC

URACHDYNTFS TFsNumber Number of TFs ADD URACHDYNTFS(MandatoThis parameter defines the num

URACHDYNTFS TbNumber1 TB Number of TF1 ADD URACHDYNTFS(OptionalThis parameter defines the num

URACHDYNTFS TbNumber2 TB Number of TF2 ADD URACHDYNTFS(OptionalThis parameter defines the num

URACHMEASUREPARA EcN0MaxUpAdjStep Maximum Ec/N0 Up Step SET URACHMEASUREPARA(OpThis parameter specifies the m

URACHMEASUREPARA EcN0MaxDownAdjStep Maximum Ec/N0 Down Step SET URACHMEASUREPARA(OpThis parameter specifies the m

URACHMEASUREPARA EcN0AdjStep Ec/N0 Adjustment Step SET URACHMEASUREPARA(OpThis parameter is used to count

URACHMEASUREPARA TagetRlcRetrans Target RLC Retransmission RaSET URACHMEASUREPARA(OpThis parameter specifies the t

URACHMEASUREPARA EcN0AdjTimerLen Ec/N0 Adjustment MeasuremenSET URACHMEASUREPARA(OpThis parameter specifies the a

URACHMEASUREPARA MaxEcN0Value Maximum Ec/N0 Value SET URACHMEASUREPARA(OpThis parameter specifies the m

URACHMEASUREPARA MinEcN0Value Minimum Ec/N0 Value SET URACHMEASUREPARA(OpThis parameter specifies the m

UREDIRECTION TrafficType Traffic Type SET UREDIRECTION(MandatoTraffic class whose RRC redire

UREDIRECTION RedirSwitch Redirection Switch SET UREDIRECTION(Optional

UREDIRECTION RedirFactorOfNorm Redirection Factor Of Normal SET UREDIRECTION(OptionalPossibility of redirecting the U

UREDIRECTION RedirFactorOfLDR Redirection Factor Of LDR SET UREDIRECTION(OptionalPossibility of redirecting the

UREDIRECTION RedirBandInd Redirection target band indicat SET UREDIRECTION(OptionalFrequency band of the target UL

UREDIRECTION ReDirUARFCNUplinkInd Redirection Target UL FrequenSET UREDIRECTION(OptionalWhether the target UL UARFCN

UREDIRECTION ReDirUARFCNUplink Redirection target uplink UA SET UREDIRECTION(Optional

UREDIRECTION ReDirUARFCNDownlink Redirection target downlink SET UREDIRECTION(OptionalTarget DL UARFCN for the RRC

URESERVEOVSF CellId Cell ID ID of a cell. For detailed inf

URESERVEOVSF DLOVSFSF Reserved DL code OVSF Orthogonal Variable Spreading

URESERVEOVSF DLCODENO Reserved DL code No ADD URESERVEOVSF(MandatNumber of the DL code. For det

URESERVEOVSF DLCODENO Reserved DL code No RMV URESERVEOVSF(OptionNumber of the DL code. For det

URNCALLCELLBLK DomainType Blocked Domain Type This parameter specifies the b

URNCALLCELLBLK ProcessDuration Processing Duration This parameter specifies the pr

URNCBASIC RncId RNC ID Uniquely identifying an RNC.

URNCCBCPUID CnOpIndex Cn Operator Index Represent an index for a CN o

URNCCBPARA CBSwitch CB Switch SET URNCCBPARA(Optional) switch of the inner CBS functio

URNCCBPARA CTCHSwitch CTCH switch of cell broadcast SET URNCCBPARA(Optional) CTCH switch of cell broadcast.

URNCCBPARA CodeScheme Code Scheme SET URNCCBPARA(Optional)

URNCCBPARA RepeatPeriod Repeat Period SET URNCCBPARA(Optional) Repeat Period of send Write-R

URNCCBPARA RepeatNum Repeat Number SET URNCCBPARA(Optional) Repeat Number of send Write-

URNCCELLSHUTDOWNPAR DynCellShutDownSwitch Cell Dynamic ShutDown Switc SET URNCCELLSHUTDOWNPAWhen the switch is on, the Cell

URNCCELLSHUTDOWNPAR DynCellOpenJudgeTimerlen Period Judge Timer Length fo SET URNCCELLSHUTDOWNPAWhen the cell is automatically

URNCCELLSHUTDOWNPAR DynCellShutdownProtectTimer Protect Timer Length for Cel SET URNCCELLSHUTDOWNPAWhen the cell is automatically

URNCMBMSPARA MbmsTransMode Mbms Transfer Mode SET URNCMBMSPARA(OptionThis parameter specifies the t

URNCMBMSPARA MtchMultiplexThd MTCH Multiplex Threshold SET URNCMBMSPARA(OptionThis parameter specifies the M

URNCMBMSPARA CombNCellPercent Combine Neighbour Cell PerceSET URNCMBMSPARA(OptionFor a PTM service, if the ratio

URNCMBMSPARA XOffset X Offset SET URNCMBMSPARA(OptionThis parameter specifies the X

URNCMBMSPARA NCountingThd Counting Threshold SET URNCMBMSPARA(OptionWhen the number of UEs respond

URNCMBMSPARA NPtpToPtmOffset Ptp To Ptm Offset SET URNCMBMSPARA(Option

URNCMBMSPARA UpLimitCountingTime Up Limit Counting Time SET URNCMBMSPARA(OptionThis parameter specifies the c

URNCMBMSPARA RecountingPeriod Recounting Period SET URNCMBMSPARA(OptionThis parameter specifies the i

URNCMBMSPARA PunishTime Punish Time SET URNCMBMSPARA(OptionThis parameter specifies the co

URNCMBMSPARA PtmPreemptSwitch Ptm Preempt Switch SET URNCMBMSPARA(OptionThis parameter specifies wh

URNCMBMSPARA PtmStrmPasiSwitch Ptm Stream Passivity Switch SET URNCMBMSPARA(OptionThis parameter specifies whe

ADD URAC(Mandatory)RMV URAC(Mandatory)ADD URAC(Mandatory)RMV URAC(Mandatory)ADD URAC(Mandatory)RMV URAC(Mandatory)

MOD URACH(Mandatory)RMV URACH(Mandatory)

MOD URACH(Mandatory)RMV URACH(Mandatory)

ADD URACH(Optional)MOD URACH(Optional)ADD URACH(Optional)MOD URACH(Optional)ADD URACH(Optional)MOD URACH(Optional)ADD URACHDYNTFS(Mandatory)RMV URACHDYNTFS(Mandatory)ADD URACHDYNTFS(Optional)RMV URACHDYNTFS(Mandatory)ADD URACHDYNTFS(Mandatory)RMV URACHDYNTFS(Mandatory)

- Only_To_Inter_Frequency indicates that only RRC redirection to inter-frequency cells is allowed.- Only_To_Inter_Frequency indicates that only RRC redirection to inter-RAT cells is allowed.

BAND6: UL UARFCN = DL UARFCN - 225BAND7: UL UARFCN = DL UARFCN - 225

ADD URESERVEOVSF(Mandatory)RMV URESERVEOVSF(Mandatory)ADD URESERVEOVSF(Mandatory)RMV URESERVEOVSF(Mandatory)

ADD URNCALLCELLBLK(Mandatory)MOD URNCALLCELLBLK(Optional)ADD URNCALLCELLBLK(Mandatory)MOD URNCALLCELLBLK(Optional)ADD URNCBASIC(Mandatory)MOD URNCBASIC(Optional)ADD URNCCBCPUID(Mandatory)RMV URNCCBCPUID(Mandatory)

1110 Polish1111 Language unspecified

This parameter specifies the NPTP-PTM offset. During recounting in PTP mode, if the number of PTP users is larger than or equal to NPTP-PTM, the transmission mode transits to PTM. The value of NPTP-PTM = "Counting Threshold" + "Ptp To Ptm Offset". The transition between PTP and PTM affects user experience. Thus, to minimize ping-pong effect, the transition between PTP and PTM uses a threshold other than "Counting Threshold". The two thresholds are used only to avoid ping-pong effect, so the difference between the two should not be too large. Because the value of "Counting Threshold" is small, it is recommended that the default value of this parameter be used.

URNCMBMSPARA PtmNullStrmPasiSwitch Ptm Null Stream Passivity Swi SET URNCMBMSPARA(OptionThis parameter specifies wh

URNCMBMSPARA MbmsPtpUlBitRate Mbms Ptp UpLink Bit Rate SET URNCMBMSPARA(OptionThis parameter specifies the u

URNCPOOL RncPoolIndex RncPool Index Represent an index for a RNC

URNCPOOL RncPoolName RncPool Name RNC Pool name.

URNCPOOL BeatSendingDis HeatBeat Sending Time Interva Interval for the local RNC sen

URNCPOOL BeatDectThred HeatBeat Lost Times Threshol Threshold of continuous failed

URNCPOOL BeatRecvrThred HeatBeat Recover Times Thre If the heartbeats are detected

URNCPOOL IuStatePolicyForPool Iu State Policy For RncPool

URNCPOOLMEMBER RncPoolIndex RncPool Index Represent an index for a RNC

URRCESTCAUSE RrcCause Cause of RRC connection estaSET URRCESTCAUSE(MandatCause of RRC connection esta

URRCESTCAUSE SigChType Channel type for RRC establi SET URRCESTCAUSE(Optiona

URRCESTCAUSE EFachSwitch Switch for RRC established SET URRCESTCAUSE(OptionaWhether the RRC connection is

URRCTRLSWITCH PROCESSSWITCH Process switch SET URRCTRLSWITCH(Option

URRCTRLSWITCH RsvdPara1 Reserved parameter 1 SET URRCTRLSWITCH(OptionReserved parameter 1.

USAC CnOpIndex Cn Operator Index Represent an index for a CN o

USAC LAC Location Area Code Identifies a location area cod

USAC SAC Service Area Code MCC,MNC,LAC and SAC together c

USAMBMSPARA CnOpIndex Cn Operator Index Represent an index for a CN o

USAMBMSPARA MbmsSaId MBMS SA ID MBMS SA ID. For detailed infor

USAMBMSPARA MbmsTransMode Mbms Transfer Mode This parameter specifies the t

USAMBMSPARA NCountingThd Counting Threshold When the number of UEs respond

USAMBMSPARA NPtpToPtmOffset Ptp To Ptm Offset

USAS CnOpIndex CN Operator Index ADD USAS(Mandatory) Represent an index for a CN o

USAS SASId SAS ID ID of an SAS.

USAS Dpx DSP Index ADD USAS(Mandatory) Index of a destination signalin

USATLDCPERIOD IntraFreqLdbPeriodTimerLen Intra-frequency LDB period tim SET USATLDCPERIOD(OptionIdentifying the period of the I

USATLDCPERIOD PucPeriodTimerLen PUC period timer length SET USATLDCPERIOD(OptionIdentifying the potential user c

USATLDCPERIOD LdrPeriodTimerLen LDR period timer length SET USATLDCPERIOD(Option

USATLDCPERIOD OlcPeriodTimerLen OLC period timer length SET USATLDCPERIOD(Option

USATLDM UlBasicCommMeasFilterCoeff UL basic common measure filteSET USATLDM(Optional) L3 filtering coefficient. The la

USATLDM ChoiceRprtUnitForUlBasicMea Time unit for UL basic meas rprSET USATLDM(Optional) If you set this parameter to T

USATLDM TenMsecForUlBasicMeas UL basic meas rprt cycle 10ms SET USATLDM(Mandatory) UL basic common measurement r

USATLDM MinForUlBasicMeas UL basic meas rprt cycle minu SET USATLDM(Mandatory) UL basic common measurement r

USATLDM DlBasicCommMeasFilterCoeff DL basic common measure filteSET USATLDM(Optional) L3 filtering coefficient. The la

USATLDM ChoiceRprtUnitForDlBasicMea Time unit for DL basic meas rprSET USATLDM(Optional) If you set this parameter to T

USATLDM TenMsecForDlBasicMeas DL basic meas rprt cycle 10ms SET USATLDM(Mandatory) DL basic common measurement r

USATLDM MinForDlBasicMeas DL basic meas rprt cycle minu SET USATLDM(Mandatory) DL basic common measurement r

USATLDM PeriodProtectTimerCoeff Period common measure protectSET USATLDM(Optional) Period common measurement pro

USATLDM LdbAvgFilterLen LDB smoothing filter length SET USATLDM(Optional) Length of smoothing filter win

USATLDM PucAvgFilterLen PUC smoothing filter length SET USATLDM(Optional) Length of smoothing filter wind

USATLDM UlLdrAvgFilterLen UL LDR smoothing filter length SET USATLDM(Optional) Length of smoothing filter win

USATLDM DlLdrAvgFilterLen DL LDR smoothing filter length SET USATLDM(Optional) Length of smoothing filter win

USATLDM UlOlcAvgFilterLen UL OLC smoothing filter length SET USATLDM(Optional) Length of smoothing filter win

USATLDM DlOlcAvgFilterLen DL OLC smoothing filter length SET USATLDM(Optional) Length of smoothing filter win

USATLDM UlCacAvgFilterLen UL CAC smoothing filter lengt SET USATLDM(Optional) Length of smoothing filter win

USATLDM DlCacAvgFilterLen DL CAC smoothing filter lengt SET USATLDM(Optional) Length of smoothing filter win

USATLDM ChoiceRprtUnitForHsdpaPwrMTime unit of HSDPA need pwr SET USATLDM(Optional) If you set this parameter to T

USATLDM TenMsecForHsdpaPwrMeas HSDPA need pwr meas cycle SET USATLDM(Mandatory) HSDPA power requirement measu

USATLDM MinForHsdpaPwrMeas HSDPA need pwr meas cycle SET USATLDM(Mandatory) HSDPA power requirement measu

USATLDM HsdpaNeedPwrFilterLen HSDPA need power filter len SET USATLDM(Optional) Length of smoothing filter wi

USATLDM ChoiceRprtUnitForHsdpaRate Time unit of HSDPA bit rate m SET USATLDM(Optional) If you set this parameter to T

USATLDM TenMsecForHsdpaPrvidRateMHSDPA bit rate meas cycle 1 SET USATLDM(Mandatory) This parameter specifies the H

USATLDM MinForHsdpaPrvidRateMeas HSDPA bit rate meas cycle mi SET USATLDM(Mandatory) This parameter specifies the H

USATLDM HsdpaPrvidBitRateFilterLen HSDPA bit rate filter len SET USATLDM(Optional) Length of smoothing filter win

USATLDM MaxMeasContInvalidTimes Max number of continuous inv SET USATLDM(Optional) Max allowed number of continuo

USATLDM UlOlcMeasFilterCoeff UL overload measure filter coefSET USATLDM(Optional) L3 filtering coefficient. The la

USATLDM ChoiceRprtUnitForUlOlcMeas Time unit for UL OLC meas rprtSET USATLDM(Optional) If you set this parameter to T

USATLDM TenMsecForUlOlcMeas UL OLC meas rprt cycle 10ms SET USATLDM(Mandatory) Measurement report period of e

USATLDM MinForUlOlcMeas UL OLC meas rprt cycle minu SET USATLDM(Mandatory) Measurement report period of e

USATLDM UlOlcTrigHyst UL OLC trigger hysteresis SET USATLDM(Optional) UL OLC trigger hysteresis.This

USATLDM DlOlcMeasFilterCoeff DL overload measure filter coefSET USATLDM(Optional) L3 filtering coefficient. The la

MOD URNCPOOL(Mandatory)RMV URNCPOOL(Mandatory)ADD URNCPOOL(Mandatory)MOD URNCPOOL(Optional)ADD URNCPOOL(Optional)MOD URNCPOOL(Optional)ADD URNCPOOL(Optional)MOD URNCPOOL(Optional)ADD URNCPOOL(Optional)MOD URNCPOOL(Optional)ADD URNCPOOL(Optional)MOD URNCPOOL(Optional)

If the value is IUPS, the RNC state is considered to be faulty when Iu PS interface is faulty.If the value is IUCS_IUPS, the RNC state is considered to be faulty when IU CS and IU PS interface are faulty. When IU CS or IU PS interface recovers, the RNC state is considered to be normal.ADD URNCPOOLMEMBER(Mandatory)

RMV URNCPOOLMEMBER(Mandatory)

- DCH_13.6K_SIGNALLING: The RRC connection is set up on the 13.6 kbit/s dedicated channel. - DCH_27.2K_SIGNALLING: The RRC connection is set up on the 27.2 kbit/s dedicated channel.

When it is checked, RNC will apply FAST DORMANCY function for UE whose TAC is configured in database.When it is not checked, RNC will apply FAST DORMANCY function for UE whose version is R5 or later.

ADD USAC(Mandatory)RMV USAC(Mandatory)ADD USAC(Mandatory)RMV USAC(Mandatory)ADD USAC(Mandatory)RMV USAC(Mandatory)MOD USAMBMSPARA(Mandatory)RMV USAMBMSPARA(Mandatory)MOD USAMBMSPARA(Mandatory)RMV USAMBMSPARA(Mandatory)ADD USAMBMSPARA(Optional)MOD USAMBMSPARA(Optional)ADD USAMBMSPARA(Optional)MOD USAMBMSPARA(Optional)ADD USAMBMSPARA(Optional)MOD USAMBMSPARA(Optional)

This parameter specifies the NPTP-PTM offset. During recounting in PTP mode, if the number of PTP users is larger than or equal to NPTP-PTM, the transmission mode transits to PTM. The value of NPTP-PTM = "Counting Threshold" + "Ptp To Ptm Offset". The transition between PTP and PTM affects user experience. Thus, to minimize ping-pong effect, the transition between PTP and PTM uses a threshold other than "Counting Threshold". The two thresholds are used only to avoid ping-pong effect, so the difference between the two should not be too large. Because the value of "Counting Threshold" is small, it is recommended that the default value of this parameter be used.

ADD USAS(Mandatory)RMV USAS(Mandatory)

Identifying the period of the LDR execution. When basic congestion occurs, execution of LDR can dynamically reduce the cell load. The lower the parameter value is, the more frequently the LDR action is executed, which decreases the load quickly. If the parameter value is excessively low, an LDR action may overlap the previous one before the previous result is displayed in LDM. The higher the parameter value is, the more likely this problem can be prevented. If the parameter value is excessively high, the LDR action may be executed rarely, failing to lower the load timely.The LDR algorithm aims to slowly reduce the cell load and control the load below the admission threshold, each LDR action takes a period (for example the inter-RAT load handover needs a delay of about 5 s if the compressed mode is needed), and there is a delay for the LDM module responds to the load decreasing (the delay is about 3 s when the L3 filter coefficient is set to 6), so the parameter value should be higher than 8s.Identifying the period of the OLC execution. When overload occurs, execution of OLC can dynamically reduce the cell load. When setting the parameter, consider the hysteresis for which the load monitoring responds to the load change. For example, when the layer 3 filter coefficient is 6, the hysteresis for which the load measurement responds to the step-function signals is about 2.8s, namely that the system can trace the load control effect about 3 s later after each load control. In this case, the OLC period timer length cannot be smaller than 3s.OlcPeriodTimerLen along with ULOLCFTFRstrctUserNum, DLOLCFTFRstrctUserNum, ULOLCFTFRSTRCTTimes, DLOLCFTFRSTRCTTimes, ULOLCTraffRelUserNum, and DLOLCTraffRelUserNum determine the time it takes to release the uplink/downlink overload. If the OLC period is excessively long, the system may respond very slowly to overload. If the OLC period is excessively short, unnecessary adjustment may occur before the previous OLC action has taken effect, and therefore the system performance is affected.

USATLDM ChoiceRprtUnitForDlOlcMeas Time unit for DL OLC meas rprtSET USATLDM(Optional) If you set this parameter to T

USATLDM TenMsecForDlOlcMeas DL OLC meas rprt cycle 10ms SET USATLDM(Mandatory) Measurement report period of e

USATLDM MinForDlOlcMeas DL OLC meas rprt cycle minu SET USATLDM(Mandatory) Measurement report period of e

USATLDM DlOlcTrigHyst DL OLC trigger hysteresis SET USATLDM(Optional) DL OLC trigger hysteresis.This

USCCPCH CellId Cell ID ID of a cell. For detailed inf

USCCPCH PhyChId SCCPCH ID Uniquely identifying a common

USCCPCH PCHPower PCH Power MOD USCCPCH(Optional) Offset of the PCH transmit pow

USCCPCHBASIC CellId Cell ID ADD USCCPCHBASIC(MandatID of a cell. For detailed inf

USCCPCHBASIC PhyChId SCCPCH ID ADD USCCPCHBASIC(MandatUniquely identifying an SCCPCH

USCCPCHBASIC SCCPCHOffset SCCPCH Offset ADD USCCPCHBASIC(OptionaSequential offset between the

USCCPCHBASIC ScrambCode Scrambling Code ADD USCCPCHBASIC(MandatScrambling code of the SCCPCH

USCCPCHBASIC STTDInd STTD Indicator ADD USCCPCHBASIC(OptionaThis parameter indicates wheth

USCCPCHBASIC CTFCSize CTFC Length of TFCS ADD USCCPCHBASIC(OptionaCalculated TFC (CTFC) length

USCCPCHBASIC SlotFormat Slot Format ADD USCCPCHBASIC(MandatThis parameter defines the slo

USCCPCHBASIC TFCIpresence TFCI Existing Indicator ADD USCCPCHBASIC(Mandat

USCCPCHBASIC MbmsChInd Mbms Channel Indicator ADD USCCPCHBASIC(OptionaIndicating whether the CCH c

USCCPCHTFC CellId Cell ID ID of a cell. For detailed inf

USCCPCHTFC PhyChId SCCPCH ID Uniquely identifying a common

USCCPCHTFC CTFC Calculated Transport Format Uniquely identifying a TFC on t

USCHEDULEPRIOMAP TrafficClass Traffic Class SET USCHEDULEPRIOMAP(MaTraffic class. This parameter o

USCHEDULEPRIOMAP UserPriority User Priority SET USCHEDULEPRIOMAP(MaUser priority that is defined

USCHEDULEPRIOMAP THPClass Traffic Handling Priority Class SET USCHEDULEPRIOMAP(MaTraffic Handling Priority (THP

USCHEDULEPRIOMAP SPI Scheduling Priority Indicator SET USCHEDULEPRIOMAP(MaScheduling priority of interacti

USCPICH CellId Cell ID RMV USCPICH(Optional) ID of a cell. For detailed inf

USMLC SmlcMethod UE Positioning Method SET USMLC(Optional) Method of positioning the UE

USMLC AGPSMethodType A-GPS Method Type SET USMLC(Optional) UE positioning mode when th

USMLC AGPSAddAssDataSendFlag A-GPS Additional Data Send F SET USMLC(Optional) This parameter indicates whet

USMLC UeAssAgpsAssDataSwitch UE-assisted A-GPS Data SendSET USMLC(Optional) Switch for sending A-GPS assi

USMLC UeBasAgpsAssDataSwitch UE-based A-GPS Data Send SSET USMLC(Optional) Switch for sending A-GPS assi

USMLC MaxGpsSats Maximum Num of GPS Satellit SET USMLC(Optional) Maximum number of satellites

USMLC OTDOAMethodType OTDOA Method Type SET USMLC(Optional) UE positioning mode when th

USMLC CELLIDRTTMethodType CELLID+RTT Method Type SET USMLC(Optional) UE positioning mode when th

USMLC EmergLCSSwitch Emergency LCS Switch SET USMLC(Optional) This parameter specifies wheth

USMLC InterRatHOPermit Emergency LCS Inter-Rat Han SET USMLC(Optional) This parameter specifies wheth

USMLC InterRatHOType Inter-Rat Handover Type SET USMLC(Optional) This parameter specifies the t

USMLC OptionalIESendSwitch Optional IE Send Switch SET USMLC(Optional) This parameter specifies whethe

USMLC ForcedSHOSwitch ForcedSho Switch in CELLID SET USMLC(Optional) When the CELLID+RTT method is

USMLC IntraRelThdFor1A 1A Event Relative Threshold SET USMLC(Mandatory) Relative threshold of the event

USMLC IntraRelThdFor1B 1B Event Relative Threshold SET USMLC(Mandatory) Relative threshold of the event

USMLC TrigTime1A 1A Event Trigger Delay Time SET USMLC(Mandatory) Delay to trigger the event 1A. T

USMLC TrigTime1B 1B Event Trigger Delay Time SET USMLC(Mandatory) Delay to trigger the event 1B. T

USMLC SHOQualmin Min Quality THD for SHO SET USMLC(Mandatory) Minimum quality threshold of s

USMLC LcsWorkMode Location Working Mode SET USMLC(Optional) Working mode of positioning f

USMLCCELL RNCId RNC ID ID of an RNC

USMLCCELL CellEnvironment Cell Environment Case Environment type of the cell c

USMLCCELL CellidRttActivateFlag CELLID+RTT Method Active F Flag of CELLID+RTT location a

USMLCCELL OtdoaActivateFlag OTDOA Method Active Flag Flag of OTDOA location activat

USMLCCELL AgpsActivateFlag A-GPS Method Active Flag Flag of A-GPS location activati

USPG SpgId Service priority group Identity Identifies a group of cells tha

USPG PriorityServiceForR99RT Service priority of R99 RT serv Capability of the cells with a s

USPG PriorityServiceForR99NRT Service priority of R99 NRT se Capability of the cells with a s

USPG PriorityServiceForHSDPA Service priority of HSDPA serv Capability of the cells with a

USPG PriorityServiceForHSUPA Service priority of HSUPA serv Capability of the cells with a

USPG PriorityServiceForExtRab Service priority of Other servic Capability of the cells with a

USPIWEIGHT SPI Scheduling Priority Indicator SET USPIWEIGHT(Mandatory Scheduling priority of interacti

USPIWEIGHT SpiWeight SPI Weight SET USPIWEIGHT(Mandatory Specifies the weight for service

USQICOUNT SqiGoodThres SQI Good Judgment Threshol SET USQICOUNT(Optional) When the calculated SQI is grea

USQICOUNT SqiBadThres SQI Bad Judgment Threshold SET USQICOUNT(Optional) When the calculated SQI is low

USRNSR SRNSRExpiryTime SRNS Relocation Expiry Time SET USRNSR(Optional) Sets the duration that the MS c

USRNSR SRNSRDelayOffset Estimated Non-Measurement DSET USRNSR(Optional)

USRNSR SRNSRIurReselectTimerLen SRNSR Iur Reselection Timer SET USRNSR(Optional) Sets the interval between the t

MOD USCCPCH(Mandatory)RMV USCCPCH(Mandatory)MOD USCCPCH(Mandatory)RMV USCCPCH(Mandatory)

This parameter indicates whether the SCCPCH involves the TFCI. When the downlink blind transport format detection function is used, the TFCI is unavailable. For detailed information of this parameter, refer to 3GPP TS 25.433. Note: This parameter is configured only for the SCCPCH in the formats 8 to 17.

ADD USCCPCHTFC(Mandatory)RMV USCCPCHTFC(Mandatory)ADD USCCPCHTFC(Mandatory)RMV USCCPCHTFC(Mandatory)ADD USCCPCHTFC(Mandatory)RMV USCCPCHTFC(Mandatory)

MOD USMLCCELL(Mandatory)RMV USMLCCELL(Mandatory)ADD USMLCCELL(Optional)MOD USMLCCELL(Optional)ADD USMLCCELL(Optional)MOD USMLCCELL(Optional)ADD USMLCCELL(Optional)MOD USMLCCELL(Optional)ADD USMLCCELL(Optional)MOD USMLCCELL(Optional)MOD USPG(Mandatory)RMV USPG(Mandatory)ADD USPG(Optional)MOD USPG(Optional)ADD USPG(Optional)MOD USPG(Optional)ADD USPG(Optional)MOD USPG(Optional)ADD USPG(Optional)MOD USPG(Optional)ADD USPG(Optional)MOD USPG(Optional)

When "Transfer Delay Measured by FP Node Between SRNC and DRNC" + "Estimated Non-Measurement Delay Offset" > "Transfer Delay Provided by the QoS of the Current Traffic", the delay-based relocation will be triggered. The transfer delay of common traffic on the Iur interface needs to be considered when you set this parameter. If this parameter is set to a smaller value, the QoS of bearer traffic on the Iur interface may be affected. If this parameter is set to a greater value, the unnecessary relocation may occur."Transfer Delay Provided by the QoS of the Current Traffic" in the formula needs to be sent from the CN to the RNC through a message.

USRNSR SRNSRTrigTimer Relocation Trigger Timer Afte SET USRNSR(Optional) Sets the value of the timer for

USRNSR SrnsrSeparateDuration Duration of Triggering Static R SET USRNSR(Optional)

USRNSR SrnsRabCnDomainType SRNS Relocation-Allowed TrafSET USRNSR(Optional) Sets the relocation-allowed traff

USSCH CellId Cell ID ID of a cell. For detailed inf

USSCH PhyChId SSCH ID ADD USSCH(Optional) Uniquely identifying an SSCH i

USSCH SSCHPower SSCH Transmit Power ADD USSCH(Optional) Offset of the SSCH transmit po

USTATETIMER RrcUeRspTmr RRC UE response timer SET USTATETIMER(Optional) A timer used to wait for RRC

USTATETIMER RrcIuRelCmdTmr RRC IU release command timeSET USTATETIMER(Optional) A timer used to wait for the

USTATETIMER RrcRelRetranTmr RRC release retransmission ti SET USTATETIMER(Optional) A timer used to retransmit

USTATETIMER RrcPaingType1Tmr RRC paging type 1 response t SET USTATETIMER(Optional)

USTATETIMER RrcInitDtTmr RRC initial DT timer SET USTATETIMER(Optional) A timer used to wait for initial

USTATETIMER RrcRlcAckCmpTmr RRC RLC completion acknowl SET USTATETIMER(Optional) A timer used to wait for the a

USTATETIMER RbSetupRspTmr Wait RB setup response timer SET USTATETIMER(Optional) A timer to RNC wait for the RB

USTATETIMER UeCapEnqRspTmr UE capability enquiry responseSET USTATETIMER(Optional) A timer used to wait UE capabil

USTATETIMER RbRecfgRspTmr Wait RB reconfiguration respo SET USTATETIMER(Optional) A timer used to wait for the R

USTATETIMER RbRelRspTmr Wait RB release response tim SET USTATETIMER(Optional)

USTATETIMER RlSetupRspTmr RL setup response timer SET USTATETIMER(Optional) A timer to RNC wait for the res

USTATETIMER RlRecfgReadyTmr RL reconfiguration timer SET USTATETIMER(Optional) A timer to RNC wait for the res

USTATETIMER RlRelRspTmr RL release timer SET USTATETIMER(Optional) A timer to RNC wait for the resp

USTATETIMER RlRstrTmr RL restoration timer SET USTATETIMER(Optional) A timer to RNC wait for radio li

USTATETIMER DrlAal2EstIndTmr DRL AAL2 establishment indicaSET USTATETIMER(Optional) A timer to DRNC wait for AAL2

USTATETIMER DrlRecfgCmitTmr DRL reconfiguration commit ti SET USTATETIMER(Optional) A timer to DRNC wait for rnsap

USTATETIMER HoCellUpdateRspTmr HO cell update response timer SET USTATETIMER(Optional) A timer to RNC wait for the re

USTATETIMER HoPagingRspTmr HO paging response timer SET USTATETIMER(Optional) A timer to RNC wait for pagin

USTATETIMER HoRelocReqTmr HO relocation request timer SET USTATETIMER(Optional) A timer to RNC wait for reloca

USTATETIMER HoAsuTmr HO active set update response SET USTATETIMER(Optional) A timer to RNC wait for the res

USTATETIMER HoWtTrchRecfgRspTmr HO wait timer for TrCh or RB r SET USTATETIMER(Optional) A timer to RNC wait for the re

USTATETIMER HoPhychRecfgTmr HO PhyCh reconfiguration timeSET USTATETIMER(Optional) A timer to RNC wait for the re

USTATETIMER RelocCmdTmr Relocation Command timer SET USTATETIMER(Optional) A timer to RNC wait for the r

USTATETIMER RelocIuRelCmdTmr Relocation Iu release commandSET USTATETIMER(Optional) A timer to RNC wait for the I

USTATETIMER RelocDataFwdTmr Relocation data forwarding tim SET USTATETIMER(Optional) A timer used for data forwardin

USTATETIMER RelocAnotherTmr Relocation another request tim SET USTATETIMER(Optional) A timer to RNC wait for another

USTATETIMER RelocCommitTmr Relocation commit timer SET USTATETIMER(Optional) A timer to RNC wait for rnsap

USTATETIMER RelocMobilConfTmr Relocation mobile info confirmaSET USTATETIMER(Optional) A timer to RNC wait for mobile

USTATETIMER RelocPhychRecfgTmr Relocation PhyCh reconfigurat SET USTATETIMER(Optional) A timer to RNC wait for the res

USTATETIMER RelocUtranHoCmpTmr Relocation Inter-RAT HO complSET USTATETIMER(Optional) A timer to RNC wait for inter-

USTATETIMER RelocFailIuRelCmdTmr Relocation failed IU release SET USTATETIMER(Optional) A timer to DRNC wait for Iu re

USTATETIMER SysHoPsResumeTmr PS resume timer after SYSHO SET USTATETIMER(Optional) A timer to RNC wait for PS R

USTATETIMER RrcSecrtModeCmpTmr RRC security mode completionSET USTATETIMER(Optional) A timer to RNC wait for the r

USTATETIMER UeCntCheckRspTmr UE counter check response ti SET USTATETIMER(Optional) A timer to RNC wait for the re

USTATETIMER CmchRsrcRspTmr CMCH RSRC response timer SET USTATETIMER(Optional) A timer to RNC wait for the re

USTATETIMER IuCSRelNoRABTmr Iu CS Release protection timer SET USTATETIMER(Optional) A timer to Iu CS Release prote

USTATETIMER IuPSRelNoRABTmr Iu PS Release protection timer SET USTATETIMER(Optional) A timer to Iu PS Release prote

USTATETIMER RrcConnRejWaitTmr Wait Time In RRC Connection SET USTATETIMER(Optional) Wait time in RRC connection re

UTHPCLASS THP1Class User Class of Traffic Handling PSET UTHPCLASS(Optional) Priority class associated with









UTHPCLASS THP10Class User Class of Traffic Handling SET UTHPCLASS(Optional) Priority class associated with






UTYPRAB RabIndex Service parameter index RMV UTYPRAB(Mandatory) Index number uniquely identifyi

UTYPRABBASIC RabIndex Service parameter index Index number uniquely identifyi

Defines the value of the separation timer enabled after the SRNC is separated from the CRNC. The relocation triggers after the separation timer expires.This parameter determines the number of UEs over the Iur interface. If the parameter is set to a greater value, a large number of unnecessary Iur resources are occupied. If this parameter is set to a smaller value, the ping-pong relocation may occur.

ADD USSCH(Mandatory)RMV USSCH(Mandatory)

A timer used to wait for the response to paging type 1 in RRC procedure.

A timer to RNC wait for the RB release response from UE in the RB procedure.Refer to the Note.

ADD UTYPRABBASIC(Mandatory)MOD UTYPRABBASIC(Mandatory)

UTYPRABBASIC TrafficClass Traffic Class ADD UTYPRABBASIC(MandatoTraffic class. According to the

UTYPRABBASIC Ssd Signal Source Description ADD UTYPRABBASIC(Mandato

UTYPRABBASIC MaxBitRate Max rate Maximum bit rate of the servic

UTYPRABBASIC CNDomainId CN domain ID ADD UTYPRABBASIC(Mandato

UTYPRABBASIC BetaC Reference BetaC Power occupancy of the control

UTYPRABBASIC BetaD Reference BetaD Power occupancy of the data p

UTYPRABBASIC SHInd Service Handover Indicator

UTYPRABBASIC Req2GCap 2G Cell Capability Required f Minimum capability of the 2G c

UTYPRABBASIC UlFpMode UL FP Mode UL FP mode of this type of RA

UTYPRABBASIC AppliedDirect RAB Applied Direction Direction in which the current

UTYPRABDCCCMC RabIndex Service parameter index Index number uniquely identifyi

UTYPRABDCCCMC Direction Direction Direction that the traffic vo

UTYPRABDCCCMC Event4aThd Traffic Measurement Event 4A Threshold of triggering event 4A

UTYPRABDCCCMC Event4bThd Traffic Measurement Event 4B Threshold of triggering event 4B

UTYPRABDCCCMC TimetoTrigger4A Pending Time After Triggering Time from the moment when the

UTYPRABDCCCMC PendingTime4A Pending time after trigger 4A Number of measurement periods d

UTYPRABDCCCMC TimetoTrigger4B Pending Time After Triggering Time from the moment when the

UTYPRABDCCCMC PendingTime4B Pending time after trigger 4B Number of measurement periods d

UTYPRABDCCCMC EdchTimetoTrigger4A Number of MRs Before Trigger Number of measurement periods

UTYPRABDCCCMC EdchPendingTime4A Number of MRs Between Two Number of measurement periods

UTYPRABDCCCMC EdchTimetoTrigger4B Number of MRs Before Trigger Number of measurement periods

UTYPRABDCCCMC EdchPendingTime4B Number of MRs Between Two Number of measurement periods

UTYPRABDCCCMC DchThrouTimetoTrigger4B Number of MRs Before Trigger Number of measurement periods

UTYPRABDCCCMC DchThrouPendingTime4B Number of MRs Between Two Number of measurement periods d

UTYPRABHSPA RabIndex Service parameter index Index number uniquely identifyi

UTYPRABHSPA TrchType Transport channel type Type of transport channel

UTYPRABHSPA HsdschMacdPduSizeNum The Number of HS-DSCH MAC Number of HS-DSCH MAC-d PDU

UTYPRABHSPA HsdschMacdPduSize1 HS-DSCH MAC-D PDU size1 First MAC-d PDU size on the HS

UTYPRABHSPA HsdschMacdPduSize2 HS-DSCH MAC-D PDU size2 Second MAC-d PDU size on the H

UTYPRABHSPA HsdschMacdPduSize3 HS-DSCH MAC-D PDU size3 Third MAC-d PDU size on the HS

UTYPRABHSPA HsdschMacdPduSize4 HS-DSCH MAC-D PDU size4 Fourth MAC-d PDU size on the H

UTYPRABHSPA HsdschMacdPduSize5 HS-DSCH MAC-D PDU size5 Fifth MAC-d PDU size on the HS

UTYPRABHSPA HsdschMacdPduSize6 HS-DSCH MAC-D PDU size6 Sixth MAC-d PDU size on the HS

UTYPRABHSPA HsdschMacdPduSize7 HS-DSCH MAC-D PDU size7 Seventh MAC-d PDU size on the

UTYPRABHSPA HsdschMacdPduSize8 HS-DSCH MAC-D PDU size8 Eighth MAC-d PDU size on the H

UTYPRABHSPA EdchMacdPduSizeNum The Number of E-DCH MAC-D Number of E-DCH MAC-d PDU si

UTYPRABHSPA EdchMacdPduSize1 E-DCH MAC-D PDU size1 First MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize2 E-DCH MAC-D PDU size2 Second MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize3 E-DCH MAC-D PDU size3 Third MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize4 E-DCH MAC-D PDU size4 Fourth MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize5 E-DCH MAC-D PDU size5 Fifth MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize6 E-DCH MAC-D PDU size6 Sixth MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize7 E-DCH MAC-D PDU size7 Seventh MAC-d PDU size used b

UTYPRABHSPA EdchMacdPduSize8 E-DCH MAC-D PDU size8 Eighth MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize9 E-DCH MAC-D PDU size9 Ninth MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize10 E-DCH MAC-D PDU size10 Tenth MAC-d PDU size used by

UTYPRABHSPA EdchMacdPduSize11 E-DCH MAC-D PDU size11 Eleventh MAC-d PDU size used

UTYPRABHSPA EdchMacdPduSize12 E-DCH MAC-D PDU size12 Twelfth MAC-d PDU size used b

UTYPRABHSPA HBDelaycnd Happy bit delay time Delay time of decision for HSUP

UTYPRABOLPC RabIndex Service parameter index Index number uniquely identifyi

UTYPRABOLPC SubflowIndex Traffic Subflow Index Logical serial number of a subf

UTYPRABOLPC TrchType Transport channel type Type of uplink transport channe

UTYPRABOLPC DelayClass Delay Class Delay class number. Each delay

UTYPRABOLPC BLERQuality Target value of service DCH Target transmission quality of

UTYPRABOLPC EdchSirMaxDownStep Maximum E-DCH SIR decrease Maximum allowed SIR decrease

UTYPRABOLPC MaxEdchRetransNum Maximum Number of E-DCH PD Maximum times of HARQ retrans

UTYPRABOLPC EdchTargetLittleRetransNum Edch Little Target Number of Target number of E-DCH PDU retr

UTYPRABOLPC EdchTargetLargeRetransNum Edch Target Large Number of Target number of E-DCH PDU retr

UTYPRABQUALITYMEAS RabIndex Service parameter index Index number uniquely identifyi

UTYPRABQUALITYMEAS UlThd6A1 Uplink Event 6A1 Relative Thr

UTYPRABQUALITYMEAS UlThd6A2 Uplink Event 6A2 Relative Thr Measurement reporting threshol

- SPEECH: speech service - UNKNOWN: non-speech serviceADD UTYPRABBASIC(Mandatory)

MOD UTYPRABBASIC(Optional)- CS_DOMAIN: Circuit Switched domain service- PS_DOMAIN: Packet Switched domain serviceADD UTYPRABBASIC(Mandatory)

MOD UTYPRABBASIC(Optional)ADD UTYPRABBASIC(Mandatory)MOD UTYPRABBASIC(Optional)ADD UTYPRABBASIC(Mandatory)MOD UTYPRABBASIC(Optional)

- HO_TO_GSM_SHOULD_NOT_BE_PERFORM: Handover to the 2G network is performed when 3G signals are weak but 2G signals are strong.- HO_TO_GSM_SHALL_NOT_BE_PERFORM: Handover to the 2G network is not performed even if 3G signals are weak but 2G signals are strong.ADD UTYPRABBASIC(Mandatory)

MOD UTYPRABBASIC(Optional)ADD UTYPRABBASIC(Mandatory)MOD UTYPRABBASIC(Optional)ADD UTYPRABBASIC(Mandatory)MOD UTYPRABBASIC(Optional)ADD UTYPRABDCCCMC(Mandatory)MOD UTYPRABDCCCMC(Mandatory)ADD UTYPRABDCCCMC(Mandatory)MOD UTYPRABDCCCMC(Mandatory)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Mandatory)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)ADD UTYPRABDCCCMC(Optional)MOD UTYPRABDCCCMC(Optional)MOD UTYPRABHSPA(Mandatory)RMV UTYPRABHSPA(Mandatory)MOD UTYPRABHSPA(Mandatory)RMV UTYPRABHSPA(Mandatory)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABHSPA(Optional)MOD UTYPRABHSPA(Optional)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Mandatory)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Mandatory)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Mandatory)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Mandatory)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Optional)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Optional)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Optional)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Optional)ADD UTYPRABOLPC(Mandatory)MOD UTYPRABOLPC(Optional)ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Mandatory)ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Optional)

Measurement reporting threshold for triggering event 6A1. The event reporting mode is used.Event 6A1 is triggered when the measured value is higher than the absolute threshold 6A1. This event can trigger UL QoS operation. This parameter specifies a relative threshold. Absolute threshold of 6A1 = Max Ul Tx Power - Relative threshold of 6A1.ADD UTYPRABQUALITYMEAS(Mandatory)

MOD UTYPRABQUALITYMEAS(Optional)

UTYPRABQUALITYMEAS UlThd6B1 Uplink Event 6B1 Relative Thr Measurement reporting threshol

UTYPRABQUALITYMEAS UlThd6B2 Uplink Event 6B2 Relative Thr Measurement reporting threshol

UTYPRABQUALITYMEAS StaBlkNum5A Statistic Block Number for 5A When a DCH is set up, the UE s

UTYPRABQUALITYMEAS Thd5A Event 5A Threshold When a DCH is set up, the UE s

UTYPRABQUALITYMEAS HangBlockNum5A Interval Block Number When event 5A is triggered, a p

UTYPRABQUALITYMEAS ThdEa Event Ea Relative Threshold If DL code TX power is higher

UTYPRABQUALITYMEAS ThdEb Event Eb Relative Threshold If DL code TX power is lower t

UTYPRABRLC RabIndex Service parameter index Index number uniquely identifyi

UTYPRABRLC SubflowIndex Traffic Subflow Index Logical serial number of a subf

UTYPRABRLC TrchType Transport channel type Type of local transport channel.

UTYPRABRLC OppositeTrchType Opposite direction transport c Peer transport channel type. Whe

UTYPRABRLC DelayClass Delay Class Delay class number. Each delay

UTYPRABRLC RlcMode RLC mode selection

UTYPRABRLC AmRlcCfgPara RLC AM Mode Parameters Sel AM RLC parameter types. The pa

UTYPRABRLC TimeToMoniter Delay Time of Retransmission Delay time between retransmiss

UTYPRABRLC MoniterPrd re-TX monitor period Sampling period of the RLC ret

UTYPRABRLC ReTransRatioFilterCoef Filter Coefficient of RLC Retr Filter coefficient of RLC retra

UTYPRABRLC EventAThred Event A threshold Threshold of event A, that is,

UTYPRABRLC TimeToTriggerA Hysteresis of Event A Number of consecutive periods

UTYPRABRLC PendingTimeA Event A pending time after trig Number of pending periods after

UTYPRABRLC EventBThred Event B threshold Threshold of event B, that is,

UTYPRABRLC TimeToTriggerB Hysteresis of Event B Number of consecutive periods

UTYPRABRLC PendingTimeB Event B pending time after trig Number of pending periods after

UTYPRABRLC EventAReportDelay Event A report delay Delay from the moment when eve

UUEA EncryptionAlgo Encryption algorithm SET UUEA(Optional) The encryption algorithm supp

UUESTATETRANS CellReSelectCounter Cell Reselection Counter Thre SET UUESTATETRANS(OptionIf the times the UE in the CEL

UUESTATETRANS D2F2PTvmThd BE D2F/R or F/R2P 4B Thresh SET UUESTATETRANS(OptionThis parameter is used to check

UUESTATETRANS D2FTvmTimeToTrig BE D2F/R 4B Time SET UUESTATETRANS(OptionWhen the traffic volume is belo

UUESTATETRANS D2FTvmPTAT BE D2F/R 4B Pending Time SET UUESTATETRANS(OptionPending time after the traffic

UUESTATETRANS F2PTvmTimeToTrig BE F2P 4B Time SET UUESTATETRANS(OptionWhen the traffic volume is belo

UUESTATETRANS F2PTvmPTAT BE F2P 4B Pending Time SET UUESTATETRANS(OptionPending time after the traffic

UUESTATETRANS BeF2DTvmThd BE F/R2D 4A Threshold SET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS BeF2DTvmTimeToTrig BE F/R2D 4A Time SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS BeH2FTvmThd BE HS-DSCH2F 4B Threshold SET UUESTATETRANS(OptionThis parameter is used to check

UUESTATETRANS BeH2FTvmTimeToTrig BE HS-DSCH2F 4B Time SET UUESTATETRANS(OptionWhen the traffic volume is belo

UUESTATETRANS BeH2FTvmPTAT BE HS-DSCH2F 4B Pending T SET UUESTATETRANS(OptionPending time after the traffic

UUESTATETRANS BeF2HTvmThd BE F2HS-DSCH 4A Threshold SET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS BeF2HTvmTimeToTrig BE F2HS-DSCH 4A Time SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS RtDH2FTvmThd RT D/HSPA2F 4B Threshold SET UUESTATETRANS(OptionThis parameter is used to check

UUESTATETRANS RtDH2FTvmTimeToTrig RT D/HSPA2F 4B Time SET UUESTATETRANS(OptionWhen the traffic volume is belo

UUESTATETRANS RtDH2FTvmPTAT RT D/HSPA2F 4B Pending Ti SET UUESTATETRANS(OptionPending time after the traffic

UUESTATETRANS RtF2DHTvmThd RT F2D/HSPA 4A Threshold SET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS RtF2DHTvmTimeToTrig RT F2D/HSPA 4A Time SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS E2FThrouMeasPeriod E-DCH Throu Meas Period SET UUESTATETRANS(OptionPeriod of E-DCH throughput ra

UUESTATETRANS E2FThrouThd E-DCH2F 4B Threshold SET UUESTATETRANS(OptionThis parameter is used to check

UUESTATETRANS E2FThrouTimeToTrig E-DCH2F 4B Period Amount SET UUESTATETRANS(OptionNumber of periods before the th

UUESTATETRANS E2FThrouPTAT E-DCH2F 4B Pending Period SET UUESTATETRANS(OptionNumber of pending periods afte

UUESTATETRANS BeF2ETvmThd BE F2E-DCH 4A Threshold SET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS BeF2ETvmTimeToTrig BE F2E-DCH 4A Time SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS BeF2CpcHTvmThd BE F2CPC_HS-DSCH 4A ThreSET UUESTATETRANS(OptionThis parameter specifies the t

UUESTATETRANS BeF2CpcHTvmTimeToTrig BE F2CPC_HS-DSCH 4A Tim SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS RtF2CpcTvmThd RT F2CPC_HSPA 4A Thresho SET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS RtF2CpcTvmTimeToTrig RT F2CPC_HSPA 4A Time SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS BeF2CpcETvmThd BE F2CPC_E-DCH 4A ThreshoSET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS BeF2CpcETvmTimeToTrig BE FACH2CPC_E-DCH 4A Ti SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS BeEFach2DTvmThd BE E_FACH2D 4A Threshold SET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS BeEFach2DTvmTimeToTrig BE E_FACH2D 4A Time SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS BeEFach2HTvmThd BE E_FACH2HS-DSCH 4A ThrSET UUESTATETRANS(OptionThis parameter specifies the t

UUESTATETRANS BeEFach2HTvmTimeToTrig BE E_FACH2HS-DSCH 4A Ti SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS RtEFach2DHTvmThd RT E_FACH2D/HSPA 4A ThreSET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS RtEFach2DHTvmTimeToTrig RT E_FACH2D/HSPA 4A Tim SET UUESTATETRANS(OptionThis parameter specifies the o

ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Optional)ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Optional)ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Optional)ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Optional)ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Optional)ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Optional)ADD UTYPRABQUALITYMEAS(Mandatory)MOD UTYPRABQUALITYMEAS(Optional)MOD UTYPRABRLC(Mandatory)RMV UTYPRABRLC(Mandatory)MOD UTYPRABRLC(Mandatory)RMV UTYPRABRLC(Mandatory)MOD UTYPRABRLC(Mandatory)RMV UTYPRABRLC(Mandatory)MOD UTYPRABRLC(Mandatory)RMV UTYPRABRLC(Mandatory)MOD UTYPRABRLC(Mandatory)RMV UTYPRABRLC(Mandatory)ADD UTYPRABRLC(Mandatory)MOD UTYPRABRLC(Mandatory)

- TM: Transparent Mode. No protocol overhead is added to the higher-layer data. The erroneous protocol data units may be discarded or marked.For details, see 3GPP TS 25.322.ADD UTYPRABRLC(Mandatory)

MOD UTYPRABRLC(Mandatory)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)ADD UTYPRABRLC(Optional)MOD UTYPRABRLC(Optional)

UUESTATETRANS BeEFach2CpcTvmThd BE E_FACH2CPC 4A ThreshoSET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS BeEFach2CpcTvmTimeToTrig BE E_FACH2CPC 4A Time SET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS RtEFach2CpcTvmThd RT E_FACH2CPC_HSPA 4A ThSET UUESTATETRANS(OptionThis parameter specifies the th

UUESTATETRANS RtEFach2CpcTvmTimeToTrig RT E_FACH2CPC_HSPA 4A TSET UUESTATETRANS(OptionThis parameter specifies the o

UUESTATETRANS FastDormancyF2DHTvmThd Fast Dormancy User FACH/E SET UUESTATETRANS(OptionThis parameter specifies the t

UUESTATETRANSTIMER CellReSelectTimer Cell Reselection Timer SET UUESTATETRANSTIMER(Length of the cell reselection

UUESTATETRANSTIMER BeD2FStateTransTimer BE DCH to FACH Transition T SET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER BeF2PStateTransTimer BE FACH or E_FACH to PCH TrSET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER BeH2FStateTransTimer BE HS-DSCH to FACH TransitiSET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER RtDH2FStateTransTimer Realtime DCH or HSPA To FACSET UUESTATETRANSTIMER(Timer for state transition from

UUESTATETRANSTIMER BeE2FStateTransTimer BE E-DCH to FACH State TransSET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER BeCpc2FStateTransTimer BE CPC to FACH Transition T SET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER RtCpc2FStateTransTimer Realtime CPC to FACH TransitSET UUESTATETRANSTIMER(Timer for state transition from

UUESTATETRANSTIMER BeD2EFachStateTransTimer BE DCH to E_FACH TransitionSET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER BeH2EFachStateTransTimer BE HSPA to E_FACH TransitioSET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER RtDH2EFachStateTransTimer Realtime DCH or HSPA to E_FSET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER BeCpc2EFachStateTransTime BE CPC to E_FACH TransitionSET UUESTATETRANSTIMER(Timer for state transition fro

UUESTATETRANSTIMER RtCpc2EFachStateTransTimer Realtime CPC to E_FACH TranSET UUESTATETRANSTIMER(Timer for state transition from

UUIA IntegrityProtectAlgo Integrity protection algorithm SET UUIA(Optional) The integrity protection algor

UURA URAId URA ID Identity of the UTRAN registra

UURA CnOpIndex Cn Operator Index ADD UURA(Mandatory) Represent an index for a CN o

UUSERGBR TrafficClass Traffic Class SET UUSERGBR(Mandatory) Traffic class which includes B

UUSERGBR THPClass Traffic Handling Priority Class SET UUSERGBR(Mandatory) Traffic Handling Priority (THP

UUSERGBR BearType Bearer Type SET UUSERGBR(Mandatory) Bearer type of the service. R9

UUSERGBR UserPriority User Priority SET UUSERGBR(Mandatory) User priority that is defined

UUSERGBR UlGBR Uplink GBR for BE service SET UUSERGBR(Optional) Uplink guaranteed bit rate (GB

UUSERGBR DlGBR Downlink GBR for BE service SET UUSERGBR(Optional) Downlink guaranteed bit rate (

UUSERHAPPYBR TrafficClass Traffic class SET UUSERHAPPYBR(MandatTraffic class

UUSERHAPPYBR UserPriority User Priority SET UUSERHAPPYBR(MandatUser priority that is defined

UUSERHAPPYBR THPClass Traffic Handling Priority Class SET UUSERHAPPYBR(MandatTraffic Handling Priority (THP

UUSERHAPPYBR HappyBR Happy bit rate SET UUSERHAPPYBR(OptionaDefines the happy bit rate of

UUSERMBR SingalUlMBR Uplink MBR of Signal SET UUSERMBR(Optional) This parameter specifies the

UUSERMBR SingalDlMBR Downlink MBR of Signal SET UUSERMBR(Optional) This parameter specifies the

UUSERMBR StreamUlMBR Uplink MBR of Streaming SET UUSERMBR(Optional) This parameter specifies the

UUSERMBR StreamDlMBR Downlink MBR of Streaming SET UUSERMBR(Optional) This parameter specifies the

UUSERMBR ConverUlMBR Uplink MBR of Conversation SET UUSERMBR(Optional) This parameter specifies the

UUSERMBR ConverDlMBR Downlink MBR of Conversatio SET UUSERMBR(Optional) This parameter specifies the

UUSERPRIORITY ARP1Priority User_priority of Allocation/ReteSET UUSERPRIORITY(OptionaUser_priority corresponding to A









UUSERPRIORITY ARP10Priority User_priority of Allocation/ReteSET UUSERPRIORITY(OptionaUser_priority corresponding to






UUSERPRIORITY PriorityReference Integrate Priority Configured SET UUSERPRIORITY(Optiona

UUSERPRIORITY CarrierTypePriorInd Indicator of Carrier Type Priori SET UUSERPRIORITY(OptionaDecide which carrier is prior w

UVIPIMSI VIPIMSI IMSI IMSI of the UE

UWPSALGO NbmWpsAlgorithmSwitch Set WPS Algorithm Switch SET UWPSALGO(Optional) WPS (Wireless Priority Servic

UWPSALGO NbmWpsAlgorithmPriority Set WPS user priority SET UWPSALGO(Optional) This parameter is used to identi

ADD UURA(Mandatory)RMV UURA(Mandatory)

If the ARP is preferably used, the priority sequence is gold > silver > copper. If the ARPs are all the same, the TrafficClass is used and the priority sequence is conversational > streaming > interactive > background.If the TrafficClass is preferably used, the priority sequence is conversational > streaming > interactive > background. If the TrafficClass factors are all the same, the ARP factor is used and the priority sequence is gold > silver > copper.

ADD UVIPIMSI(Mandatory)RMV UVIPIMSI(Mandatory)

IsKey Mandatory Feature Name Value Type GUI Value Range Actual Value Range

NO NO Paging UE in Idle, CELL_PCH, Interval Type 0~2 0~2

NO YES BSC/RNC Clock Interval Type 0~4095 0~4095

NO YES Configuration Management Interval Type 0~65535 0~65535

NO NO License Management Enumeration Type UMTS(UMTS) UMTS

NO NO License Management Enumeration Type NO(NO), YES(YES) NO, YES

NO NO None Interval Type 0~3 0~3

NO NO License Management Interval Type 0~80400 0~80400



YES YES None Interval Type 0~65535 0~65535


NO NO None Interval Type -350~150 -35~15, step: 0.1


YES YES Inter-RAT Handover Based on Interval Type 0~65535 0~65535


NO NO Interval Type -50~50 -50~50

NO NO Inter RNC Cell Update Interval Type -50~50 -50~50

NO NO Interval Type -58~-13 -115~-25, step:2 Actual value

NO NO Enumeration Type D0, D10, D20, D30, D40, D50, 0, 10, 20, 30, 40, 50, 60

NO NO Enumeration Type D3~0 D6~1 D9~2 D12~3 D15~3, 6, 9, 12, 15, 18, 21, INFINIT

NO NO Enumeration Type FALSE, TRUE FALSE, TRUE

NO YES 3G/2G Common Load ManagemInterval Type 0~30 0~30

NO NO DRD Introduction Package Interval Type -24~0 -24~0

NO NO Enumeration Type FALSE(Do not send), TRUE(S FALSE, TRUE



NO YES Inter-RAT Handover Based on Interval Type 0~31 0~31

NO NO None Enumeration Type FALSE(Do not send), TRUE(S FALSE, TRUE


NO NO Access Class Restriction Enumeration Type OFF, ON OFF, ON

NO YES Access Class Restriction Interval Type 1~10 0.1~1, step:0.1

NO YES Access Class Restriction Interval Type 1~36000 10~360000, step:10

NO YES Access Class Restriction Interval Type 6~3600 6~3600

NO NO Access Class Restriction Interval Type 1~3600 1~3600

YES YES Admission Control Enumeration Type NOPRIORITY(NOPRIORITY), NOPRIORITY, GOLD, SILVE

NO NO Admission Control Interval Type 0~100 0~1, step: 0.01






















YES NO 3GPP Specifications Interval Type 0~255 0~255


NO NO Interval Type 0~1 0~1

Inter-RAT Handover Based on DL QoSInter-RAT Handover Based on Service

Intra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateInter Frequency Load BalanceHCS (Hierarchical Cell Structure)

Intra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateInter RNC Soft HandoverInter Frequency Hard Handover Based on Coverage

Open Loop Power ControlInner Loop Power Control

NO NO Physical Channel Management Enumeration Type TRUE, FALSE TRUE, FALSE


NO YES Open Loop Power Control Interval Type -22~5 -22~5

NO NO AMR/WB-AMR Speech Rates CoInterval Type 0~559 0~55.9, step: 0.1

NO NO AMR/WB-AMR Speech Rates CoInterval Type 0~559 0~55.9, step: 0.1

NO NO AMR/WB-AMR Speech Rates CoInterval Type 1~560 0.1~56, step: 0.1

NO NO AMR/WB-AMR Speech Rates CoInterval Type 1~560 0.1~56, step: 0.1

NO NO AMR/WB-AMR Speech Rates CoInterval Type 1~64000 1~64000


NO NO AMR/WB-AMR Speech Rates CoEnumeration Type NBAMR_BITRATE_4.75K, NB 4.75, 5.15, 5.90, 6.70, 7.40, 7.



NO NO Interval Type 0~559 0~55.9, step: 0.1

NO NO Interval Type 0~559 0~55.9, step: 0.1

NO NO Interval Type 1~560 0.1~56, step: 0.1

NO NO Interval Type 1~560 0.1~56, step: 0.1



NO NO Enumeration Type WBAMR_BITRATE_6.60K, WB6.60, 8.85, 12.65, 14.25, 15.85





NO NO Open Loop Power Control Interval Type -350~150 -35~15, step: 0.1

NO NO Admission Control Bit Field Type NODEB_CREDIT_CAC_SWITCH(NODEB_CREDIT_CAC_SWIT

NO NO Admission Control Bit Field Type RSVDBIT1(Reserved Switch 1)RSVDBIT1, RSVDBIT2, RSVDB

NO NO Admission Control Interval Type 0~4294967295 0~4294967295


NO NO Flow Control Bit Field Type SYS_LEVEL(SYS_LEVEL), N SYS_LEVEL, NODEB_LEVEL,

NO NO Flow Control Enumeration Type OFF, ON OFF, ON

NO NO Flow Control Interval Type 1~5 1~5











YES YES Interval Type 0~3 0~3

YES YES Warning of Disaster Interval Type 0~127 0~127


YES YES Warning of Disaster Enumeration Type LAC(Lac), RNC(Rnc), CELL(CeLAC, RNC, CELL

YES YES Warning of Disaster Interval Type 1~65533, 65535 1~65533, 65535



NO YES Warning of Disaster Interval Type 0~999 0~999

NO YES Warning of Disaster Enumeration Type CellImmediate, PLMNNormal,

NO NO Warning of Disaster Enumeration Type High, Background, Normal, DefaHigh, Background, Normal, Defa

NO NO Warning of Disaster Interval Type 1~4096 1~4096

NO NO Warning of Disaster Interval Type 0~65535 0~65535

NO YES Warning of Disaster Enumeration Type English, Italian, French, Span English, Italian, French, Span

NO YES Warning of Disaster Interval Type 0~127 0~127

NO YES Warning of Disaster Enumeration Type Earthquake, Tsunami, HurricanEarthquake, Tsunami, Hurrican

NO NO Warning of Disaster Any Type None chars with length of 0~80

NO NO Warning of Disaster Any Type None 0~80 characters


NO YES None String Type None 1~64 characters

NO NO Open Loop Power Control Interval Type 0~500 0~50, step: 0.1

AMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates ControlAMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates ControlAMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates ControlAMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates Control

AMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates ControlAMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates ControlAMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates Control

RAN Sharing Introduction PackageMOCN Introduction Package

SANormal, CellNormal

NO YES 3GPP Specifications Enumeration Type Band1, Band2, Band3, Band4, Band1, Band2, Band3, Band4,

NO NO RNC Node Redundancy Enumeration Type INVALID(Invalid), VALID(Valid Valid, Invalid

NO YES RNC Node Redundancy Interval Type 0~65535 0~65535

NO YES MOCN Introduction Package Interval Type 0~31 0~31

NO NO 3GPP Specifications Enumeration Type TRUE, FALSE TRUE, FALSE

NO NO 3GPP Specifications Interval Type 0~16383 0~16383


NO YES Physical Channel Management Enumeration Type CHIP0, CHIP256, CHIP512, C CHIP0, CHIP256, CHIP512, C

NO NO Physical Channel Management Interval Type 1~256 1~256


NO NO Physical Channel Management Interval Type 0~255 0~25.5, step: 0.1

NO YES Physical Channel Management Interval Type 0~511 0~511

NO YES Enumeration Type TRUE, FALSE TRUE, FALSE

NO YES HCS (Hierarchical Cell StructureInterval Type 1~8 1~8

NO YES 3GPP Specifications Interval Type 0~268435455 0~268435455

NO YES Interval Type 1~65533, 65535 {1~65533}, {65535}

NO YES None Interval Type 0~65535 0~65535

NO YES 3GPP Specifications Enumeration Type NOT_REQUIRE, REQUIRE NOT_REQUIRE, REQUIRE


NO YES Physical Channel Management Enumeration Type STTD_Supported, STTD_not_ STTD_Supported, STTD_not_

NO YES Physical Channel Management Enumeration Type CP1_Supported, CP1_not_SupCP1_Supported, CP1_not_Sup

NO YES Open Loop Power Control Enumeration Type OFFSET1, OFFSET2 OFFSET1, OFFSET2

NO YES Physical Channel Management Enumeration Type None, STTD, CP1 None, STTD, CP1

NO YES SRB over HSDPA Enumeration Type None, STTD None, STTD

NO YES 2×2 MIMO Enumeration Type None, STTD, CP1 None, STTD, CP1

NO YES SRB over HSDPA Enumeration Type None, STTD None, STTD

NO YES HSDPA Introduction Package Enumeration Type None, STTD None, STTD

NO NO Interval Type -20~20 -10~10, step: 0.5

NO NO Video Telephony Fallback to S Enumeration Type TRUE, FALSE TRUE, FALSE

NO YES 3GPP Specifications Enumeration Type D1, D2, D3, D4, D5, D6, D7, D D1, D2, D3, D4, D5, D6, D7, D









NO NO Cell Broadcast Service Enumeration Type TRUE, FALSE TRUE, FALSE

NO YES Cell Broadcast Service Interval Type 0~3 0~3

NO YES Cell Broadcast Service Interval Type 0~65535 0~65535




NO NO None Interval Type -350~150 -35~15, step: 0.1



NO NO Access Class Restriction Enumeration Type RESERVED, NOT_RESERVE RESERVED, NOT_RESERVE

NO NO Access Class Restriction Enumeration Type RESERVED, NOT_RESERVE RESERVED, NOT_RESERVE

NO NO Access Class Restriction Enumeration Type BARRED, NOT_BARRED BARRED, NOT_BARRED












Physical Channel ManagementRRU Redundancy

3GPP SpecificationsShared Network Support in Connected Mode






NO YES Access Class Restriction Enumeration Type BARRED, NOT_BARRED BARRED, NOT_BARRED

NO NO Access Class Restriction Enumeration Type ALLOWED, NOT_ALLOWED ALLOWED, NOT_ALLOWED

NO NO Access Class Restriction Enumeration Type D10, D20, D40, D80, D160, D 10, 20, 40, 80, 160, 320, 640,

NO YES Access Class Restriction Enumeration Type BARRED, NOT_BARRED BARRED, NOT_BARRED

NO NO Access Class Restriction Enumeration Type ALLOWED, NOT_ALLOWED ALLOWED, NOT_ALLOWED

NO NO Access Class Restriction Enumeration Type D10(10 seconds), D20(20 seco10, 20, 40, 80, 160, 320, 640,


YES NO Interval Type 1~65533, 65535 {1~65533}, {65535}


NO NO 3GPP Specifications Enumeration Type NOT_REQUIRE, REQUIRE NOT_REQUIRE, REQUIRE



NO NO Bit Field Type CRD_ADCTRL(Credit Admissi CRD_ADCTRL, HSDPA_UU_A

NO YES Admission Control Enumeration Type ALGORITHM_OFF, ALGORIT ALGORITHM_OFF, ALGORIT

NO YES Admission Control Enumeration Type ALGORITHM_OFF, ALGORIT ALGORITHM_OFF, ALGORIT

NO NO Bit Field Type INTRA_FREQUENCY_LDB(Intra INTRA_FREQUENCY_LDB, PU

NO NO HSDPA Mobility Management Enumeration Type ALGORITHM_REQUIRED, A ALGORITHM_REQUIRED, A

NO NO Bit Field Type 64QAM(Cell 64QAM Function 64QAM, MIMO, E_FACH, DT

NO NO Enumeration Type E_F_DPCH_OFF, E_F_DPCH E_F_DPCH_OFF, E_F_DPCH

NO NO Admission Control Bit Field Type TX_DIVERSITY_ON_TO_OFF(TX di

NO NO Inter Frequency Load Balance Enumeration Type NBM_LDC_ALL_UE(Select all uNBM_LDC_ALL_UE, NBM_L













NO NO Admission Control Enumeration Type TU, RA, HT TU, RA, HT

NO NO Admission Control Interval Type 0~100 0~1, step:0.01






















NO NO Open Loop Power Control Interval Type -50~33 -50~33

3GPP SpecificationsShared Network Support in Connected Mode

Admission ControlLoad Measurement

Potential User ControlOverload Control

CPC - HS-SCCH less operationDC-HSDPAHSDPA Enhanced PackageSRB over HSDPA TX_DIVERSITY_ON_TO_OFF,

TX_DIVERSITY_OFF_TO_ON

AMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates ControlAMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates ControlAMR-WB (Adaptive Multi Rate Wide Band)AMR/WB-AMR Speech Rates Control

Open Loop Power ControlAdmission Control



NO NO Interval Type 0~621 -112~-50, step:0.1

NO NO Admission Control Interval Type -30~30 -30~30

NO NO Enumeration Type OFF, ON OFF, ON










NO NO Admission Control Enumeration Type SF4(SF4), SF8(SF8), SF16(S SF4, SF8, SF16, SF32, SF64,

NO NO Admission Control Enumeration Type SF4(SF4), SF8(SF8), SF16(S SF4, SF8, SF16, SF32, SF64,

NO YES Compound Type hour, min, sec hour{0~23}, min{0~59}, sec{0~

NO YES Compound Type hour, min, sec hour{0~23}, min{0~59}, sec{0~

NO NO Interval Type 1~100 0.1~10, step:0.1

NO NO Interval Type 1~400 0.1~40, step:0.1


NO NO None Interval Type 0~100 0~1, step:0.01





NO YES Interval Type 0~3 0~3

YES YES Intra Node B Softer Handover Interval Type 0~65535 0~65535

NO NO Enumeration Type WALKING_SPEED_AND_HOTWALKING_SPEED_AND_HOT

NO NO Enumeration Type D8, D16, D32, D64, D128, D2 8, 16, 32, 64, 128, 256



NO NO Dynamic Channel Configuration Interval Type 0~100 0~10, step: 0.1


NO NO Dynamic Channel Configuration Enumeration Type D8, D16, D32, D64, D128, D1 8, 16, 32, 64, 128, 144, 256, 3



NO NO Inter-RAT Redirection Based on Enumeration Type OFF, ON OFF, ON

NO NO Inter-RAT Redirection Based on Interval Type 0~255 0~765, step: 3

NO NO Inter-RAT Redirection Based on Interval Type 0~100 0~100



NO NO Inter System Direct Retry Interval Type 0~5 0~5

NO NO Service Steering and Load Sha Enumeration Type ON, OFF ON, OFF

NO NO DRD Introduction Package Enumeration Type ON, OFF ON, OFF

NO NO HSDPA DRD Enumeration Type ON, OFF ON, OFF

NO NO DRD Introduction Package Enumeration Type Power, UserNumber Power, UserNumber

NO NO DRD Introduction Package Interval Type 0~100 0~100

NO NO HSDPA DRD Interval Type 0~100 0~100


NO NO DRD Introduction Package Enumeration Type SF4, SF8, SF16, SF32, SF64, SF4, SF8, SF16, SF32, SF64,


NO NO Enumeration Type Band1, Band2, Band3, Band4, Band1, Band2, Band3, Band4,

NO NO Inter System Redirect Enumeration Type TRUE, FALSE TRUE, FALSE

NO NO Service Steering and Load Sha Interval Type 0~16383 0~16383


NO NO Inter System Direct Retry Enumeration Type ON, OFF ON, OFF



NO NO Inter Frequency Load Balance Enumeration Type ON, OFF ON, OFF


Admission ControlLoad Measurement

Admission ControlLoad MeasurementAdmission ControlLoad MeasurementAdmission ControlLoad Measurement

Admission ControlLoad MeasurementAdmission ControlLoad MeasurementAdmission ControlLoad MeasurementAdmission ControlLoad Measurement

Load Based 3G-2G Handover Enhancement Based on Iur-g


Inter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on Coverage

DRD Introduction PackageInter System Redirect

NO NO Inter Frequency Load Balance Interval Type 0~30 0~30









YES YES Domain Specific Access Contro Interval Type 0~3 0~3

NO YES Domain Specific Access Contro Enumeration Type FALSE, TRUE FALSE, TRUE


NO YES Domain Specific Access Contro Enumeration Type RestrictionFixed, RestrictionFl RestrictionFixed, RestrictionFl

NO YES Domain Specific Access Contro Bit Field Type AC0(Access Class 0 RestrictioAC0, AC1, AC2, AC3, AC4, AC

NO YES Domain Specific Access Contro Interval Type 1~16 1~16




NO YES Multi-Carrier Switch off Based o Enumeration Type OFF(switch off), ON_1(switch OFF, ON_1, ON_2, ON_3

NO YES Multi-Carrier Switch off Based o Compound Type hour, min 00:00~23:59






NO NO Multi-Carrier Switch off Based o Enumeration Type FORCESHUTDOWN(ForceShutFORCESHUTDOWN, CONDI

NO NO Multi-Carrier Switch off Based o Interval Type 0~5 0~5



NO NO Multi-Carrier Switch off Based o Interval Type 0~100 0~1, step:0.01


NO NO Downlink Enhanced CELL_FAC Interval Type -350~150 -35~15, step:0.1



NO NO Downlink Enhanced CELL_FAC Interval Type 1~1000 1~1000















NO NO UE State in Connected Mode Enumeration Type D8, D16 8, 16


NO NO None Enumeration Type FALSE, TRUE FALSE, TRUE

NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Interval Type 0~49 -24.5~0, step: 0.5

NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Interval Type 0~65535 0~65535

YES NO None Interval Type 0~4095 0~4095


YES YES 3GPP Specifications Enumeration Type Band1, Band2, Band3, Band4, Band1, Band2, Band3, Band4,

NO NO 3GPP Specifications Enumeration Type TRUE, FALSE TRUE, FALSE



NO NO A-GPS Based LCS Enumeration Type INACTIVE, ACTIVE INACTIVE, ACTIVE


YES NO Enumeration Type USED, NOT_USED USED, NOT_USED


NO NO Interval Type -53~45 -105~91, step:2



NO NO HCS (Hierarchical Cell StructureEnumeration Type NOT_USED, D30(30 seconds), NOT_USED, 30, 60, 120, 180,

NO NO HCS (Hierarchical Cell StructureInterval Type 1~16 1~16

NO NO HCS (Hierarchical Cell StructureEnumeration Type NOT_USED, D10(10 seconds), NOT_USED, 10, 20, 30, 40, 50



NO NO HCS (Hierarchical Cell StructureEnumeration Type OFF, ON OFF, ON








NO NO Enumeration Type INTERFREQ(inter-frequency h INTERFREQ, INTERRAT, SI

NO NO Enumeration Type COEXIST_MEAS_THD_CHOICE_INCOEXIST_MEAS_THD_CHOIC

NO NO Inter-RAT Handover Based on SEnumeration Type OFF, ON OFF, ON

NO NO Inter-RAT Handover Based on SEnumeration Type OFF, ON OFF, ON


NO NO Enumeration Type Manual(Manual), Automatic(AuManual, Automatic





NO NO HSDPA Power Control Interval Type -500~0 -50~0, step:0.1

NO NO Enumeration Type Minus3.0DB(-3.0dB), Minus2.5 -3~19, step:0.5

NO NO HSDPA Static Code Allocation Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO HSDPA Static Code Allocation Interval Type 1~16 1~16

NO NO Code Resource Management Interval Type 0~300 0~300

NO NO None Enumeration Type Minus3.0DB(-3.0dB), Minus2.5 -3~19, step:0.5


NO NO HSUPA Introduction Package Interval Type 1~8 1~8


NO NO HSUPA Power Control Interval Type 0~100 0~1, step:0.01

NO NO HSUPA Power Control Interval Type 0~100 0~1, step:0.01


YES YES Multi-Carrier Switch off Based o Interval Type 0~65535 0~65535



NO NO Inter Frequency Hard Handover Enumeration Type PERIODICAL_REPORTING(PerioPERIODICAL_REPORTING,

NO NO Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11,

NO NO Inter Frequency Hard Handover Enumeration Type NON_PERIODIC_REPORT(Non pNON_PERIODIC_REPORT, 250, 5

NO NO Inter Frequency Hard Handover Interval Type 0~29 0~14.5, step:0.5




NO NO Inter Frequency Hard Handover Interval Type 0~20 0~2, step:0.1

NO NO Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120

NO NO Inter Frequency Hard Handover Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120


NO NO Inter Frequency Hard Handover Interval Type 0~64000 0~64000

NO NO Inter Frequency Hard Handover Interval Type -24~0 -24~0





Intra RNC Cell UpdateInter RNC Cell UpdateInter RNC Cell UpdateMulti Frequency Band Networking ManagementIntra RNC Cell UpdateInter RNC Cell UpdateInter RNC Cell UpdateMulti Frequency Band Networking ManagementHCS (Hierarchical Cell Structure)Multi Frequency Band Networking Management

HCS (Hierarchical Cell Structure)Multi Frequency Band Networking Management

Inter Frequency Hard Handover Based on CoverageInter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter-RAT Handover Based on Coverage

15 Codes per CellHSDPA Static Code Allocation and RNC-Controlled Dynamic Code Allocation15 Codes per CellHSDPA Static Code Allocation and RNC-Controlled Dynamic Code Allocation15 Codes per CellHSDPA Static Code Allocation and RNC-Controlled Dynamic Code Allocation15 Codes per CellHSDPA Static Code Allocation and RNC-Controlled Dynamic Code AllocationCode Resource ManagementTime and HS-PDSCH Codes Multiplex

HSDPA Introduction PackageHSDPA Power Control

Inter Frequency Hard Handover Based on DL QoSHCS (Hierarchical Cell Structure)

Inter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on DL QoS


NO NO Inter Frequency Hard Handover Interval Type -115~-25 -115~-25



















NO NO Interval Type 1~64 500~32000, step:500

NO NO Interval Type 0~63 0~62, 63: Infinity




NO NO HCS (Hierarchical Cell StructureInterval Type 0~29 0~14.5, step:0.5

NO NO HCS (Hierarchical Cell StructureEnumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120

NO NO HCS (Hierarchical Cell StructureInterval Type -24~0 -24~0


NO NO HCS (Hierarchical Cell StructureInterval Type 1~64 500~32000, step:500

NO NO HCS (Hierarchical Cell StructureInterval Type 0~63 0~62, 63: Infinity


NO NO Inter-RAT Handover Based on Enumeration Type PERIODICAL_REPORTING(PerioPERIODICAL_REPORTING,

NO NO Inter-RAT Handover Based on Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11,

NO NO Inter-RAT Handover Based on Enumeration Type CPICH_EC/NO, CPICH_RSCPCPICH_EC/NO, CPICH_RSCP


NO NO Inter-RAT Handover Based on Interval Type 0~20 0~2, step:0.1

NO NO Enumeration Type NON_PERIODIC_REPORT(Non pNON_PERIODIC_REPORT, 250, 5

NO NO Inter-RAT Handover Based on Interval Type 0~29 0~14.5, step:0.5




NO NO Inter-RAT Handover Based on Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120



NO NO Interval Type 0~64000, 65535 0~64000, 65535


NO NO Enumeration Type REQUIRED(Verify mode), NO REQUIRED, NOT_REQUIRE

NO NO Inter-RAT Handover Based on Interval Type -24~0 -24~0






NO NO Inter-RAT Handover Based on Interval Type -115~-25 -115~-25






NO NO Inter-RAT Handover Based on Interval Type 0~63 lower than -110, -110~-48(Actu

Inter Frequency Hard Handover Based on DL QoSHCS (Hierarchical Cell Structure)Inter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on DL QoSInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on DL QoS



Inter-RAT Handover Based on ServiceInter-RAT Handover Based on Load

Inter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoS

Inter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoSInter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoSInter-RAT Handover Based on ServiceInter-RAT Handover Based on Load










NO NO Inter-RAT Handover Based on Interval Type 0~65535 0~65535


NO NO Inter-RAT Handover Based on Interval Type 1~64 500~32000, step:500

NO NO Inter-RAT Handover Based on Interval Type 0~63 0~62, 63: Infinity





NO NO Interval Type 0~15 0~7.5, step:0.5



NO NO Interval Type 0~63 lower than -110, -110~-48(Actu













NO NO Enumeration Type CPICH_EC/NO, CPICH_RSC CPICH_EC/NO, CPICH_RSC

NO NO Enumeration Type D1~0 D2~1 D4~2 D8~3 D16~41, 2, 4, 8, 16, 32, 64, INFINITY

NO NO Enumeration Type NON_PERIODIC_REPORT, D25NON_PERIODIC_REPORT, 250,












NO NO Interval Type -115~-25 -115~-25

NO NO None Interval Type 0~15 0~7.5, step:0.5






NO NO Interval Type 0~20 0~2, step:0.1








Inter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on Load

Inter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadLoad Based 3G-2G Handover Enhancement Based on Iur-g


Inter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on Load

Intra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverInter RNC Soft HandoverInter Frequency Hard Handover Based on CoverageInter RNC Soft HandoverInter Frequency Hard Handover Based on Coverage

Intra Node B Softer HandoverInter RNC Soft HandoverInter RNC Soft HandoverInter Frequency Hard Handover Based on CoverageIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverInter RNC Soft HandoverInter Frequency Hard Handover Based on CoverageIntra Node B Softer HandoverInter RNC Soft Handover





NO NO Intra Frequency Load Balance Interval Type 0~100 0~10, step:0.1




NO NO Load Reshuffling Interval Type 0~100 0~1, step:0.01




NO NO Overload Control Interval Type 0~100 0~1, step:0.01




NO NO Load Measurement Interval Type 10~600000 10~600000

NO NO Load Measurement Interval Type 0~100 0~1, step:0.01

NO NO Load Measurement Interval Type 0~100 0~1, step:0.01


NO NO Load Reshuffling Enumeration Type NoAct(no action), InterFreqL NoAct, InterFreqLDHO, BERa










NO NO Load Reshuffling Interval Type 1~10 1~10







NO NO Load Reshuffling Enumeration Type NoAct(no action), InterFreqLD NoAct, InterFreqLDHO, BERa




















NO NO Enumeration Type SF4(SF4), SF8(SF8), SF16(SFSF4, SF8, SF16, SF32, SF64,

NO NO Load Reshuffling Enumeration Type FALSE(FALSE), TRUE(TRUE)FALSE, TRUE


NO NO Load Reshuffling Enumeration Type SF4(SF4), SF8(SF8), SF16(SFSF4, SF8, SF16, SF32, SF64,

Intra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft Handover

Load ReshufflingCode Resource Management



NO NO Load Reshuffling Enumeration Type FALSE(FALSE), TRUE(TRUE)FALSE, TRUE

NO NO Load Reshuffling Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO Load Reshuffling Bit Field Type R99_CONVERSATIONAL(R99 CR99_CONVERSATIONAL, R9

NO NO Load Reshuffling Enumeration Type 8SF4(8SF4), 7SF4(7SF4), 6SF8SF4, 7SF4, 6SF4, 5SF4, 4SF

NO NO Load Reshuffling Enumeration Type BLINDHO(BLINDHO), MEAS BLINDHO, MEASUREHO


NO NO None Bit Field Type CSAMR_INTERFREQ(CS AMR intCSAMR_INTERFREQ, CSNON




NO NO None Enumeration Type PERIODICAL_REPORTING(PerioPERIODICAL_REPORTING,

NO NO None Enumeration Type CPICH_EC/NO, CPICH_RSCPCPICH_EC/NO, CPICH_RSCP






NO NO None Interval Type -24~0 -24~0

NO NO None Interval Type -115~-25 -115~-25




NO NO None Bit Field Type CSAMR_INTERRAT(CS AMR intCSAMR_INTERRAT




NO NO None Enumeration Type PERIODICAL_REPORTING(PerioPERIODICAL_REPORTING,







NO NO None Interval Type 0~63 lower than -110, -110~-48(Actu


NO NO None Enumeration Type ALL_USER(All User), HALF( ALL_USER, HALF, THIRD,




NO YES MBMS Introduction Package Enumeration Type STREAMING, BACKGROUND STREAMING, BACKGROUND

NO YES MBMS Introduction Package Enumeration Type D16, D32, D64, D128, D256 16, 32, 64, 128, 256


NO NO MBMS Load Control Interval Type 0~100 0~1, step: 0.01





NO NO MBMS Phase 2 Enumeration Type PTM, PTP, ENHANCEDPTM, PTM, PTP, ENHANCEDPTM,

NO NO MBMS Enhanced Broadcast Mo Interval Type 2~10 2~10




YES YES MBMS Introduction Package Interval Type 0~65535 0~65535









Inter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoSInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoSInter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoSInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on Load


NO NO MBMS Introduction Package Interval Type -10~5 -10~5

NO NO MBMS Introduction Package Enumeration Type FALSE(Not Use), TRUE(Use) FALSE, TRUE


NO YES MBMS Introduction Package Interval Type 1~32 1~32

NO NO MBMS FLC(Frequency Layer ConEnumeration Type OFF(OFF), ON(ON) OFF, ON


NO NO Inter System Direct Retry Enumeration Type OFF, ON OFF, ON


NO NO Inter System Direct Retry Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 3000, 4

NO NO Inter System Direct Retry Interval Type -115~-25 -115~-25

NO NO Inter System Direct Retry Interval Type -24~0 -24~0




NO NO Inter Frequency Hard Handover Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 3000, 4




NO NO Load Measurement Enumeration Type REQUIRE, NOT_REQUIRE REQUIRE, NOT_REQUIRE

NO NO Load Measurement Enumeration Type NOT_REQUIRE, INTER_FREQNOT_REQUIRE, INTER_FREQ

NO NO Load Measurement Enumeration Type REQUIRE, NOT_REQUIRE, I REQUIRE, NOT_REQUIRE, I







NO NO None Interval Type 0~31 0~62, step:2

NO NO None Interval Type 0~31 0~62, step:2

NO NO None Enumeration Type D6(D6), D15(D15), D25(D25), D6, D15, D25, D50, D75, D10

NO NO None Interval Type -70~-22 -140~ -44, step:2

NO NO None Enumeration Type FALSE(FALSE), TRUE(TRUE)FALSE, TRUE

NO NO None Enumeration Type D0(D0), D1(D1), D2(D2), D3(D D0, D1, D2, D3, D4, D5, D6, D


















NO NO Overload Control Interval Type 0~100 0~100




NO NO Overload Control Interval Type 1~99 0.01~0.99, step:0.01






NO NO Overload Control Enumeration Type MBMS_REL(MBMS service), MBMS_REL, USER_REL





NO NO Potential User Control Interval Type 0~100 0~1, step:0.01



NO NO Potential User Control Interval Type -10~10 -20~20, step:2

NO NO Potential User Control Interval Type -10~10 -20~20, step:2

NO NO Potential User Control Interval Type -20~20 -20~20








NO NO Inter-RAT Handover Based on Enumeration Type CPICH_EC/NO, CPICH_RSC CPICH_EC/NO, CPICH_RSC


NO NO AMR/WB-AMR Speech Rates CoEnumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120





NO NO Inter Frequency Hard Handove Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120








NO NO Dynamic Channel Configuration Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11,


NO NO Interval Type 1~6000 10~60000, step: 10

NO NO Enumeration Type TEN_MSEC, MIN TEN_MSEC, MIN



NO NO Inter Frequency Hard Handove Interval Type 1~6000 10~60000, step: 10

NO NO Inter Frequency Hard Handove Enumeration Type TEN_MSEC, MIN TEN_MSEC, MIN


NO YES Inter Frequency Hard Handove Interval Type 1~60 1~60







NO NO Dynamic Channel Configuration Interval Type 1~6000 10~60000, step: 10



YES YES Service Steering and Load Sha Enumeration Type AMR, VP, PSR99, PSHSPA AMR, VP, PSR99, PSHSPA

NO NO Service Steering and Load Sha Enumeration Type OFF, ONLY_TO_INTER_FRE OFF, ONLY_TO_INTER_FRE



NO NO Service Steering and Load Sha Enumeration Type Band1, Band2, Band3, Band4, BAND1, BAND2, BAND3, BAN

NO NO Service Steering and Load Sha Enumeration Type FALSE, TRUE FALSE, TRUE





Inter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoS

Dynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoS

Dynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoS

Dynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoS


YES YES Admission Control Enumeration Type CS_DOMAIN, PS_DOMAIN CS_DOMAIN, PS_DOMAIN

NO YES Admission Control Interval Type 0~16000000 0~16000000

NO YES Interval Type -350~150 -35~15, step:0.1

NO YES Open Loop Power Control Interval Type -350~150 -35~15, step:0.1

NO YES Code Resource Management Enumeration Type D4(SF4), D8(SF8), D16(SF16) SF4, SF8, SF16, SF32, SF64,


NO NO Enumeration Type CPICH_ECNO(CPICH Ec/N0) CPICH_ECNO, CPICH_RSCP



NO NO Interval Type 0~20, 255 {0~40}, {255}, step:2

NO NO Interval Type 0~20, 255 {0~40}, {255}, step:2



NO NO Interval Type -58~-13 -115~-25, step:2

NO NO Intra RNC Cell Update Enumeration Type TRUE, FALSE TRUE, FALSE

NO YES Intra RNC Cell Update Interval Type -2~-1 -4~-2, step:2


NO NO Interval Type -16~10, 127 {-32~20}, {127}, step:2





NO NO Intra RNC Cell Update Interval Type 0~10, 255 {0~1}, {255}, step:0.1

NO NO Intra RNC Cell Update Interval Type 4~19, 255 {1~4.75}, {255}, step:0.25

NO NO Intra RNC Cell Update Interval Type 4~19, 255 {1~4.75}, {255}, step:0.25

NO NO Intra RNC Cell Update Enumeration Type CONFIGURED, NOT_CONFI CONFIGURED, NOT_CONFI

NO NO Intra RNC Cell Update Enumeration Type NotUsed, D30(30 seconds), D6NotUsed, 30, 60, 120, 180, 24

NO NO Intra RNC Cell Update Interval Type 1~16 1~16

NO NO Intra RNC Cell Update Enumeration Type NotUsed, D10(10 seconds), D2NotUsed, 10, 20, 30, 40, 50, 6

NO NO Interval Type 0~40, 255 {0~40}, {255}





NO NO Interval Type 0~31, 255 {0~6.2}, {255}, step:0.2

NO NO Intra RNC Cell Update Interval Type 0~7 0~7

NO NO Intra RNC Cell Update Interval Type 0~31 {0~62}, step:2

NO NO Intra RNC Cell Update Interval Type 0~7 {0~7}

NO NO Intra RNC Cell Update Interval Type 0~31 {0~62}, step:2


NO NO System Information Broadcastin Bit Field Type SIB2, SIB4, SIB12, SIB18, SI SIB2, SIB4, SIB12, SIB18, SI


YES YES 3GPP Specifications Interval Type 0~65535 0~65535




NO NO Admission Control Enumeration Type OFF, ON OFF, ON




NO NO Enumeration Type WALKING_SPEED_AND_HOTWALKING_SPEED_AND_HOT

NO NO Enumeration Type FALSE(Not Limited), TRUE(LimFALSE, TRUE

NO YES Enumeration Type D8, D16, D32, D64, D128, D2 8, 16, 32, 64, 128, 256

NO NO Enumeration Type FALSE(Forbidden), TRUE(PermFALSE, TRUE

NO NO Enumeration Type Limited, Permit, BasedOnUEC Limited, Permit, BasedOnUEC

NO NO Enumeration Type FALSE(Forbidden), TRUE(PermFALSE, TRUE

YES YES Enumeration Type CS_DOMAIN, PS_DOMAIN CS_DOMAIN, PS_DOMAIN

NO NO 3GPP Specifications Interval Type 0~255 0~1530 step:6

NO NO Enumeration Type NOT_ALLOWED, ALLOWED NOT_ALLOWED, ALLOWED

NO NO 3GPP Specifications Enumeration Type MODE1, MODE2 MODE1, MODE2

NO NO System Information Broadcastin Interval Type 6~9 6~9

Open Loop Power ControlAdmission Control

Intra RNC Cell UpdateInter RNC Cell UpdateInter RNC Cell UpdateMulti Frequency Band Networking ManagementInter RNC URA UpdateMulti Frequency Band Networking ManagementInter RNC Cell UpdateMulti Frequency Band Networking ManagementInter RNC URA UpdateMulti Frequency Band Networking ManagementHCS (Hierarchical Cell Structure)Multi Frequency Band Networking ManagementIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell Update

Intra RNC Cell UpdateInter RNC Cell UpdateInter RNC Cell UpdateMulti Frequency Band Networking ManagementInter RNC Cell UpdateMulti Frequency Band Networking ManagementIntra RNC Cell UpdateMulti Frequency Band Networking ManagementIntra RNC Cell UpdateMulti Frequency Band Networking ManagementHCS (Hierarchical Cell Structure)Multi Frequency Band Networking Management

Inter RNC URA UpdateMulti Frequency Band Networking ManagementInter RNC Cell UpdateMulti Frequency Band Networking ManagementInter RNC URA UpdateMulti Frequency Band Networking ManagementInter RNC Cell UpdateMulti Frequency Band Networking ManagementIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell Update

Inter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on CoverageHSDPA Mobility ManagementHSUPA Mobility ManagementHSDPA Mobility ManagementHSUPA Mobility ManagementInter-RAT Handover Based on CoverageInter Frequency Hard Handover Based on CoverageMOCN Introduction PackageRNC Node Redundancy

MBSC Handover based on Load EnhancementIP-Based GSM and UMTS Co-Transmission on MBSC Side


NO YES Enumeration Type CS_DOMAIN, PS_DOMAIN CS_DOMAIN, PS_DOMAIN

NO NO 3GPP Specifications Enumeration Type OFF, ON OFF, ON

NO NO 3GPP Specifications Bit Field Type RSVDBIT1_BIT1, RSVDBIT1_BEach bit can be set ON or OFF



YES YES Domain Specific Access Contro Enumeration Type PsBlk(BLOCK PS), CsAndPsB PsBlk, CsAndPsBlk


NO YES 3GPP Specifications Enumeration Type PRIM(Primary Operator), SEC PRIM, SEC, OUTER, COMM

NO YES String Type None 1~31 characters

NO YES None String Type None 3 digits

NO YES None String Type None 2~3 digits

NO NO Interval Type 0~3, 5~31 0~3, 5~31


YES YES Interval Type 0~3, 5~31 0~3, 5~31

YES YES MOCN Introduction Package Interval Type 0~31 0~31

NO YES String Type None 1~31 characters

NO YES Enumeration Type ONE(One), TWO(Two), THREE1, 2, 3, 4

NO YES Interval Type 0~3, 5~31 0~3, 5~31




NO NO MOCN Introduction Package Interval Type 5~31, 255 5~31, 255





NO NO 3GPP Specifications Enumeration Type D100, D200, D400, D600, D80 100, 200, 400, 600, 800, 1000


NO NO 3GPP Specifications Enumeration Type D100, D200, D400, D1000, D2 100, 200, 400, 1000, 2000


NO NO 3GPP Specifications Enumeration Type INFINITY, D5, D10, D30, D60, INFINITY, 5, 10, 30, 60, 120,

NO NO 3GPP Specifications Enumeration Type D5, D10, D15, D20, D30, D40, 5, 10, 15, 20, 30, 40, 50

NO NO 3GPP Specifications Enumeration Type D40, D80, D160, D320 40, 80, 160, 320




NO NO 3GPP Specifications Enumeration Type D1, D2, D4, D10, D20, D50, D 1, 2, 4, 10, 20, 50, 100, 200,


NO NO 3GPP Specifications Enumeration Type D1, D2, D4, D10, D20, D50, D 1, 2, 4, 10, 20, 50, 100, 200

NO NO 3GPP Specifications Enumeration Type D0, D2, D4, D6, D8, D12, D16 0, 2, 4, 6, 8, 12, 16, 20

NO NO 3GPP Specifications Enumeration Type D0, D10, D30, D60, D180, D6 0, 10, 30, 60, 180, 600, 1200,


NO NO 3GPP Specifications Enumeration Type D0, D10, D20, D30, D40, D50, 0, 10, 20, 30, 40, 50, INFINITY

NO NO 3GPP Specifications Enumeration Type D0, D100, D200, D300, D400, 0, 100, 200, 300, 400, 500, 60

NO NO 3GPP Specifications Enumeration Type D1, D2, D3, D4 1, 2, 3, 4

NO NO 3GPP Specifications Enumeration Type D0, D5, D10, D20, D30, D60, 0, 5, 10, 20, 30, 60, 90, 120,

NO NO Bit Field Type CFG_DL_BLIND_DETECTIONCFG_DL_BLIND_DETECTION

NO NO Bit Field Type DRA_AQM_SWITCH, DRA_BADRA_AQM_SWITCH, DRA_BA

NO NO Bit Field Type CS_AMRC_SWITCH, CS_HA CS_AMRC_SWITCH, CS_HA

NO NO Bit Field Type PC_CFG_ED_POWER_INTERPPC_CFG_ED_POWER_INTERP

NO NO Bit Field Type CMP_IU_IMS_PROC_AS_NO CMP_IU_IMS_PROC_AS_NO

NO NO Bit Field Type MAP_HSUPA_TTI_2MS_SWI MAP_HSUPA_TTI_2MS_SWI

NO NO Bit Field Type PS_BE_EXTRA_LOW_RATE_APS_BE_EXTRA_LOW_RATE_A

NO NO Bit Field Type DR_RRC_DRD_SWITCH, DR DR_RRC_DRD_SWITCH, DR

NO NO Bit Field Type HO_ALGO_HCS_SPEED_EST_HO_ALGO_HCS_SPEED_EST_

NO NO Bit Field Type SRNSR_DSCR_IUR_RESRCESRNSR_DSCR_IUR_RESRCE

NO NO Bit Field Type CMCF_DL_HLS_SWITCH, C CMCF_DL_HLS_SWITCH, C

NO NO None Bit Field Type RESERVED_SWITCH_0_BIT1,RESERVED_SWITCH_0_BIT1,

NO NO None Bit Field Type RESERVED_SWITCH_1_BIT1,RESERVED_SWITCH_1_BIT1,


RAN Sharing Introduction PackageMOCN Introduction PackageMOCN Introduction PackageRNC Node Redundancy



RAN Sharing Introduction PackageMOCN Introduction PackageRAN Sharing Introduction PackageMOCN Introduction PackageMOCN Introduction PackageRNC Node Redundancy

MOCN Introduction PackageDedicated Carrier for Each OperatorDedicated Carrier for Each OperatorRAN Sharing Introduction PackageDedicated Carrier for Each OperatorRAN Sharing Introduction PackageDedicated Carrier for Each OperatorRAN Sharing Introduction PackageDedicated Carrier for Each OperatorRAN Sharing Introduction PackageDedicated Carrier for Each OperatorRAN Sharing Introduction Package

CPC - HS-SCCH less operationDynamic Channel Configuration Control (DCCC)Dynamic Channel Configuration Control (DCCC)HCS (Hierarchical Cell Structure)

PDCP Header Compression (RoHC)Lossless SRNS RelocationOverbooking on ATM TransmissionOverbooking on IP TransmissionTFO/TrFOAMR/WB-AMR Speech Rates ControlDownlink Power BalanceHSUPA Power ControlInter RNC Soft HandoverHCS (Hierarchical Cell Structure)Streaming Traffic Class on HSUPADownlink Enhanced CELL_FACHDynamic Channel Configuration Control (DCCC)RAB Quality of Service Renegotiation over Iu InterfaceInter System Direct RetryInter System RedirectHCS (Hierarchical Cell Structure)NACC Procedure Optimization Based on Iur-g between GSM and UMTSSRNS Relocation with Cell/URA UpdateLossless SRNS RelocationInter-RAT Handover Based on DL QoS3G/2G Common Load Management





YES YES Transport Channel Managemen Interval Type 1~32 1~32


YES YES Interval Type 1~65533, 65535 {1~65533}, {65535}


YES YES LCS Classified Zones Interval Type 0~4799 0~4799



NO NO Dynamic Channel Configuration Enumeration Type D0, D8, D16, D32, D64, D128, 0, 8, 16, 32, 64, 128, 144, 256

NO NO Dynamic Channel Configuration Enumeration Type RATE_UP_AND_DOWN_ON_DRATE_UP_AND_DOWN_ON_D

NO NO HSUPA DCCC Enumeration Type RATE_UP_AND_DOWN_ON_ERATE_UP_AND_DOWN_ON_E



NO NO Dynamic Channel Configuration Enumeration Type 2_Rates, 3_Rates 2_Rates, 3_Rates


NO NO Dynamic Channel Configuration Enumeration Type AUTO_CALC, HAND_APPOIN0, 1

NO YES Dynamic Channel Configuration Enumeration Type D16, D32, D64, D128, D144, 16, 32, 64, 128, 144, 256, 384



NO NO Dynamic Channel Configuration Enumeration Type AUTO_CALC, HAND_APPOIN0, 1

NO YES Dynamic Channel Configuration Enumeration Type D16, D32, D64, D128, D144, 16, 32, 64, 128, 144, 256, 384

NO NO Dynamic Channel Configuration Interval Type 1~255 1~255






NO NO Inter-RAT Redirection Based on Enumeration Type OFF, ON OFF, ON

NO NO Inter-RAT Redirection Based on Interval Type 0~255 0~765, step: 3



NO NO Enumeration Type OFF(The switch of DL R99 congeOFF, ON

NO NO TCP Accelerator Bit Field Type TPE_DOWNLINK_SWITCH, T TPE_DOWNLINK_SWITCH, T

NO NO None Interval Type 1~100 10%~1000%, Step:10%

NO NO None Enumeration Type Qos(Enable the counters of QoQos, Spi, QosAndSpi, BothOF


















NO NO Service Steering and Load Sha Enumeration Type ON, OFF ON, OFF


NO NO HSDPA DRD Enumeration Type ON, OFF ON, OFF

NO NO DRD Introduction Package Enumeration Type UserNumber, Power Power, UserNumber

NO NO Enumeration Type OFF, Only_To_Inter_Frequenc OFF, Only_To_Inter_Frequenc


RAN Sharing Introduction PackageMOCN Introduction Package3GPP SpecificationsShared Network Support in Connected Mode

Overbooking on IP TransmissionOverbooking on ATM Transmission

Service Steering and Load Sharing in RRC Connection SetupInter System Redirect







NO NO DRD Introduction Package Enumeration Type SF4, SF8, SF16, SF32, SF64, SF4, SF8, SF16, SF32, SF64,


NO NO Enumeration Type Band1, Band2, Band3, Band4, Band1, Band2, Band3, Band4,

NO NO Inter System Redirect Enumeration Type TRUE, FALSE TRUE, FALSE

NO NO Inter System Redirect Interval Type 0~16383 0~16383

NO NO Inter System Redirect Interval Type 0~16383 0~16383

NO NO Inter System Direct Retry Enumeration Type ON, OFF ON, OFF














NO NO Inter Frequency Load Balance Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11,

NO NO Inter Frequency Load Balance Interval Type 1~6000 10~60000, step: 10

NO NO Inter Frequency Load Balance Enumeration Type TEN_MSEC, MIN TEN_MSEC, MIN


NO YES Inter Frequency Load Balance Interval Type 1~60 1~60


NO NO Inter Frequency Load Balance Enumeration Type TEN_MSEC, MIN TEN_MSEC, MIN


NO YES Inter Frequency Load Balance Interval Type 1~60 1~60

NO NO Domain Specific Access Contro Enumeration Type OFF, ON OFF, ON





NO YES Domain Specific Access Contro Interval Type 1~36000 0.01~360, step: 0.01


YES YES CPC - DTX / DRX Enumeration Type CONVERSATIONAL, STREAMCONVERSATIONAL, STREAM

YES YES HSUPA Introduction Package Enumeration Type EDCH_10MS, EDCH_2MS EDCH_10MS, EDCH_2MS

NO NO CPC - DTX / DRX Enumeration Type ON, OFF ON, OFF

NO NO CPC - DTX / DRX Enumeration Type D1, D4, D8, D16, D32, D64, D 1, 4, 8, 16, 32, 64, 128, 256

NO NO CPC - DTX / DRX Enumeration Type D2, D4, D15 2, 4, 15

NO NO CPC - DTX / DRX Enumeration Type D1, D2, D4, D8, D16, D32, D6 1, 2, 4, 8, 16, 32, 64, 128, 25

NO NO CPC - DTX / DRX Enumeration Type D0, D1, D2, D4, D8, D16, D32 0, 1, 2, 4, 8, 16, 32, 64, 128,



NO NO CPC - DTX / DRX Enumeration Type ON, OFF ON, OFF

NO NO CPC - DTX / DRX Enumeration Type D4, D5, D8, D10, D16, D20 4, 5, 8, 10, 16, 20

NO NO CPC - DTX / DRX Enumeration Type D0, D1, D2, D4, D8, D16, D32 0, 1, 2, 4, 8, 16, 32, 64, 128, 2

NO NO CPC - DTX / DRX Enumeration Type D0, D1, D2, D4, D8, D16, D32 0, 1, 2, 4, 8, 16, 32, 64, 128, 2

NO NO CPC - DTX / DRX Enumeration Type TRUE, FALSE TRUE, FALSE

NO NO CPC - DTX / DRX Enumeration Type D0, D2, D4, D8, D10, D20, D4 0, 2, 4, 8, 10, 20, 40, 80, 160,

NO NO CPC - DTX / DRX Enumeration Type D1, D4, D5, D8, D10, D16, D2 1, 4, 5, 8, 10, 16, 20

NO NO CPC - DTX / DRX Enumeration Type D4, D5, D8, D10, D16, D20, D 4, 5, 8, 10, 16, 20, 32, 40, 64,

NO NO CPC - DTX / DRX Enumeration Type D1, D4, D5, D8, D10, D16, D2 1, 4, 5, 8, 10, 16, 20

NO NO Bit Field Type RATE_8KBPS, RATE_16KBPS8, 16, 32, 64, 128, 144, 256,

DRD Introduction PackageInter System Redirect

HSUPA DCCCDynamic Channel Configuration Control (DCCC)

NO NO None Enumeration Type Gold, Silver, Copper Gold, Silver, Copper






NO YES Inter-RAT Handover Based on String Type None 1~64 characters


NO YES 3G/2G Common Load ManagemEnumeration Type OFF, ON OFF, ON

NO YES String Type None 000~999

NO YES String Type None 00~99, 000~999


NO YES Interval Type 1~65533, 65535 1~65533, 65535

NO YES SRNS Relocation Introduction Enumeration Type NOT_REQUIRE(Not configure RNOT_REQUIRE, REQUIRE






NO NO Inter-RAT Handover Based on Enumeration Type GSM900_DCS1800_BAND_USEDGSM900_DCS1800_BAND_US

NO YES Enumeration Type NO_CAPABILITY(Cell capabi NO_CAPABILITY, GSM, GPR

NO NO Enumeration Type USED(HCS cell), NOT_USED(NUSED, NOT_USED


NO NO Interval Type 0~99

NO NO Inter-RAT Handover Based on Enumeration Type NC0, NC1, NC2, RESET NC0, NC1, NC2, RESET


NO NO PS Handover Between UMTS Enumeration Type FALSE, TRUE FALSE, TRUE




NO NO RNC Node Redundancy Enumeration Type SINGLE_HOST, DOUBLE_HOSINGLE_HOST, DOUBLE_HO




NO YES Operating Multi-band Enumeration Type Band1, Band2, Band3, Band4, Band1, Band2, Band3, Band4,

NO NO None Enumeration Type TRUE, FALSE TRUE, FALSE




NO YES Interval Type 1~65533, 65535 1~65533, 65535

NO YES SRNS Relocation Introduction Enumeration Type NOT_REQUIRE(Not configure RNOT_REQUIRE, REQUIRE


NO NO Inter RNC Cell Update Enumeration Type TRUE(Configure the minimum quTRUE, FALSE

NO YES Interval Type -24~0 -24~0

NO NO Inter RNC Cell Update Enumeration Type TRUE(Configure the minimum siTRUE, FALSE

NO YES Interval Type -58~-13 -58~-13

NO NO Inter RNC Cell Update Enumeration Type TRUE, FALSE TRUE, FALSE

NO YES Inter RNC Cell Update Interval Type -2~-1 -4~-2, Step:2

NO NO None Enumeration Type TRUE(Configure the maximum uTRUE, FALSE

NO YES Interval Type -50~33 -50~33

NO NO Enumeration Type USED(HCS cell), NOT_USED(NUSED, NOT_USED


NO NO Interval Type 0~99

NO NO None Enumeration Type FALSE, TRUE TRUE, FALSE

NO NO Physical Channel Management Enumeration Type STTD_Supported, STTD_not_ STTD_Supported, STTD_not_

NO NO Physical Channel Management Enumeration Type CP1_Supported, CP1_not_SupCP1_Supported, CP1_not_Sup

NO YES Open Loop Power Control Enumeration Type OFFSET1, OFFSET2 OFFSET1, OFFSET2

NO NO Physical Channel Management Enumeration Type None, STTD, CP1 None, STTD, CP1

NO NO SRB over HSDPA Enumeration Type None, STTD None, STTD

NO NO 2×2 MIMO Enumeration Type None, STTD, CP1 None, STTD, CP1

NO NO SRB over HSDPA Enumeration Type None, STTD None, STTD



Inter RNC Soft HandoverMOCN Mobility Management3GPP SpecificationsShared Network Support in Connected Mode

Inter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell Update

98: -(spare)99: -(spare)

NACC(Network Assisted Cell Change)NACC Procedure Optimization Based on Iur-g between GSM and UMTS


Inter RNC Soft HandoverMOCN Mobility Management

Physical Channel ManagementRRU Redundancy3GPP SpecificationsShared Network Support in Connected Mode

Intra RNC Cell UpdateInter RNC Cell Update

Intra RNC Cell UpdateInter RNC Cell Update

Intra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell Update

98: -(spare)99: -(spare)

NO NO HSDPA Introduction Package Enumeration Type None, STTD None, STTD

NO YES Bit Field Type DELAY_ACTIVATION_SUPPORT(DELAY_ACTIVATION_SUPP

NO NO None Enumeration Type FORBIDDEN, NOT_FORBIDD FORBIDDEN, NOT_FORBIDD

NO NO None Enumeration Type Mode0, Mode1 Mode0, Mode1

NO NO Interval Type -20~20 -10~10, step:0.5

NO YES Downlink Enhanced CELL_FAC Enumeration Type TRUE, FALSE TRUE, FALSE

NO NO SRNS Relocation Introduction Enumeration Type TRUE, FALSE TRUE, FALSE

NO NO None Enumeration Type TRUE, FALSE TRUE, FALSE




NO NO Transport Channel Managemen Interval Type 1~256 1~256




NO NO Logical Channel Management Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10,

NO NO Logical Channel Management Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10,

NO NO Logical Channel Management Enumeration Type FALSE, TRUE FALSE, TRUE

NO NO Transport Channel Managemen Enumeration Type NO_CODING, CONVOLUTIONNO_CODING, CONVOLUTION

NO NO Transport Channel Managemen Enumeration Type D1/2, D1/3 1/2, 1/3

YES YES Downlink Enhanced CELL_FAC Enumeration Type CONVERSATIONAL, STREAMCONVERSATIONAL, STREAM

YES YES Downlink Enhanced CELL_FAC Enumeration Type GOLD, SILVER, COPPER GOLD, SILVER, COPPER





YES YES Transport Channel Managemen Enumeration Type D1, D2, D3 1, 2, 3






NO NO Inner Loop Power Control Interval Type 0~24 0~6, step: 0.25

NO NO Open Loop Power Control Interval Type -350~150 -35~15, step:0.1

NO NO SRB over HSDPA Interval Type -350~150 -35~15, step:0.1

NO NO Open Loop Power Control Interval Type -35~-10 -35~-10

NO NO Inner Loop Power Control Enumeration Type ALGORITHM1, ALGORITHM2 ALGORITHM1, ALGORITHM2

NO NO Inner Loop Power Control Interval Type 1~2 1~2

NO NO Inner Loop Power Control Enumeration Type STEPSIZE_0.5DB, STEPSIZE 0.5, 1, 1.5, 2

NO NO Inner Loop Power Control Enumeration Type SINGLE_TPC, TPC_TRIPLET SINGLE_TPC, TPC_TRIPLET

NO NO None Enumeration Type ON, OFF OFF, ON

NO NO None Interval Type 10~25 0.4~1, step: 0.04




NO NO Streaming Traffic Class on HS Enumeration Type SCHEDULED, NON-SCHEDU SCHEDULED, NON-SCHEDU

NO NO HSUPA Introduction Package Enumeration Type D10, D20, D50, D100, D200, 10, 20, 50, 100, 200, 500, 100

NO NO HSUPA Introduction Package Enumeration Type D2, D10, D20, D50, D100, D2 2, 10, 20, 50, 100, 200, 500, 1

NO NO HSUPA Introduction Package Enumeration Type D10, D20, D50, D100, D200, 10, 20, 50, 100, 200, 500, 100

NO NO HSUPA Introduction Package Enumeration Type D2, D10, D20, D50, D100, D2 2, 10, 20, 50, 100, 200, 500, 1

NO NO HSUPA DCCC Enumeration Type D8, D16, D32, D64, D128, D1 8, 16, 32, 64, 128, 144, 256,

NO NO HSDPA Introduction Package Enumeration Type D8, D16, D32, D64, D128, D1 8, 16, 32, 64, 128, 144, 256, 3

NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type OFF, ON OFF, ON

NO YES 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type D32, D64 32, 64

NO NO VoIP over HSPA/HSPA+ Enumeration Type EDCH_TTI_10ms, EDCH_TTI EDCH_TTI_10ms, EDCH_TTI


NO NO Enumeration Type D8, D16, D32, D64, D128, D1 8, 16, 32, 64, 128, 144, 256,

NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Interval Type 0~49 -24.5~0, step:0.5


NO NO Downlink Enhanced L2 Interval Type 4~1504 4~1504


Inter RNC Soft HandoverDirect Signaling Connection Re-establishment (DSCR)


Paging UE in Idle, CELL_PCH, URA_PCH State (Type 1)Paging UE in CELL_FACH, CELL_DCH State (Type 2)

Streaming Traffic Class on HSUPAHSUPA 2ms TTIInteractive and Background Traffic Class on HSUPAHSUPA 2ms TTI



NO NO Enumeration Type MIMO, 64QAM MIMO, 64QAM

NO NO CPC - DTX / DRX Enumeration Type D0, D1, D2, D4, D8, D16, D32 0, 1, 2, 4, 8, 16, 32, 64, 128

NO NO Bit Field Type SRB_OVER_HSDPA, SRB_OVESRB_OVER_HSDPA, SRB_OVE

NO NO Enumeration Type SLOT_FORMAT_1, SLOT_FO SLOT_FORMAT_1, SLOT_FO

NO NO CS voice over HSPA/HSPA+ Enumeration Type EDCH_TTI_10ms, EDCH_TTI EDCH_TTI_10ms, EDCH_TTI

NO NO CS voice over HSPA/HSPA+ Interval Type -100~100 -100~100

NO NO CS voice over HSPA/HSPA+ Interval Type -100~100 -100~100

NO NO IMS Signaling over HSPA Enumeration Type SCHEDULED, NON-SCHEDU SCHEDULED, NON-SCHEDU

NO NO SRB over HSUPA Enumeration Type SCHEDULED, NON-SCHEDU SCHEDULED, NON-SCHEDU

NO NO Enumeration Type MIMO_64QAM, DC_HSDPA MIMO_64QAM, DC_HSDPA


NO NO None Enumeration Type NOT_TRIGGER, TRIGGER NOT_TRIGGER, TRIGGER

NO NO None Enumeration Type NOT_PRE_EMPTABLE, PRE NOT_PRE_EMPTABLE, PRE

NO NO None Enumeration Type NOT_ALLOWED, ALLOWED NOT_ALLOWED, ALLOWED


NO NO None Enumeration Type EDCH_TTI_10ms, EDCH_TTI EDCH_TTI_10ms, EDCH_TTI

NO NO Differentiated Service Based on Interval Type 1~100 1~100

NO NO CS voice over HSPA/HSPA+ Enumeration Type DCH(UL_DCH,DL_DCH), HS DCH, HSPA

NO NO VoIP over HSPA/HSPA+ Enumeration Type DCH(UL_DCH,DL_DCH), HS DCH, HSDPA, HSPA

NO NO None Enumeration Type DCH(UL_DCH,DL_DCH), HS DCH, HSDPA, HSPA

NO NO IMS Signaling over HSPA Enumeration Type DCH(UL_DCH,DL_DCH), HS DCH, HSDPA, HSPA

NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type DCH(UL_DCH,DL_DCH), HS DCH, HSDPA, HSUPA, HSPA

NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type TRUE, FALSE TRUE, FALSE













NO NO Enumeration Type MAY(NodeB chooses whether MAY, MUST, MUST_NOT


NO NO Enumeration Type COEXIST_MEAS_THD_CHOICE_INCOEXIST_MEAS_THD_CHOIC

NO NO HSUPA Mobility Management Interval Type 1~4 1~4


YES YES CPC - HS-SCCH less operation Enumeration Type CONVERSATIONAL, STREAMCONVERSATIONAL, STREAM

YES YES CPC - HS-SCCH less operation Enumeration Type NOTUSED, USED NOTUSED, USED

YES YES None Enumeration Type BIT_ALIGN(Bit aligned mode) BIT_ALIGN, OCTET_ALIGN

NO NO CPC - HS-SCCH less operation Enumeration Type D0, D1, D2, D3, D4 0, 1, 2, 3, 4

NO NO CPC - HS-SCCH less operation Enumeration Type D1, D2, D3, D4, D5, D6, D7, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11

NO NO CPC - HS-SCCH less operation Enumeration Type FALSE, TRUE FALSE, TRUE







NO NO 3GPP Specifications Enumeration Type D100, D200, D400, D600, D80 100, 200, 400, 600, 800, 1000




YES YES Fast Dormancy Enhancement Enumeration Type Fast_Dormancy, HSDPA_RB Fast_Dormancy, HSDPA_RB

YES YES Fast Dormancy Enhancement Interval Type 0~99999999 0~99999999

NO YES Fast Dormancy Enhancement String Type None 1~64 length of byte

Downlink 64 QAM2×2 MIMO

CPC - HS-SCCH less operationDC-HSDPAHSDPA Introduction PackageHSUPA Introduction Package

HSPA+ Downlink 21Mbps per UserDC-HSDPA

HSDPA Introduction PackageStreaming Traffic Class on HSDPAHSDPA Introduction PackageInteractive and Background Traffic Class on HSDPAHSUPA Introduction PackageStreaming Traffic Class on HSUPAHSUPA Introduction PackageInteractive and Background Traffic Class on HSUPA

Intra Node B Softer HandoverInter RNC Soft HandoverHSDPA Mobility ManagementHSUPA Mobility ManagementInter Frequency Hard Handover Based on CoverageInter-RAT Handover Based on Coverage

HSDPA Mobility ManagementHSUPA Mobility Management

NO NO Fast Dormancy Enhancement Enumeration Type OFF, ON ON, OFF

NO NO Fast Dormancy Enhancement Bit Field Type FD_P2D_SWITCH, RSVDBIT1_BThis parameter is set to 0 or 1


YES YES IMSI Based Handover String Type None 15-bit decimal numerals

YES YES IMSI Based Handover String Type None 15-bit decimal numerals

YES YES String Type None 000~999

YES YES String Type None 00~99, 000~999

YES YES Enumeration Type TRUE, FALSE TRUE, FALSE

YES YES Shared Network Support in Co Interval Type 0~65535 0~65535

NO NO Inter Frequency Hard Handover Enumeration Type PERIODICAL_REPORTING(PerioPERIODICAL_REPORTING,







NO NO Inter Frequency Hard Handover Interval Type 0~20 0~2, step:0.1




































NO NO HCS (Hierarchical Cell StructureInterval Type -24~0 -24~0


NO NO HCS (Hierarchical Cell StructureInterval Type 1~64 500~32000, step:500

NO NO HCS (Hierarchical Cell StructureInterval Type 0~63 0~62, 63: Infinity









Shared Network Support in Connected ModeIMSI Based Handover



Inter Frequency Hard Handover Based on DL QoSHCS (Hierarchical Cell Structure)Inter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on DL QoSInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on DL QoS












NO NO Enumeration Type D2~0 D3~1 D4~2 D6~3 D8~4 2, 3, 4, 6, 8, 10, 12, INFINITY





NO YES Inter Frequency Hard Handover Interval Type 0~63 0~63

NO NO Intra System Direct Retry Interval Type -24~0 -24~0




NO NO Inter RNC Cell Update Enumeration Type FALSE(Not Configure the QquaFALSE, TRUE

NO NO Inter RNC Cell Update Interval Type -24~0 -24~0

NO NO Inter RNC Cell Update Interval Type -58~-13 -115~-25

NO NO Inter-RAT Handover Based on Enumeration Type PERIODICAL_REPORTING(PerioPERIODICAL_REPORTING,

NO NO Inter-RAT Handover Based on Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11,

NO NO Inter-RAT Handover Based on Enumeration Type CPICH_EC/NO, CPICH_RSCPCPICH_EC/NO, CPICH_RSCP


NO NO Inter-RAT Handover Based on Interval Type 0~20 0~2, step:0.1


































NO NO Inter-RAT Handover Based on Interval Type 0~65535 0~65535


Intra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell Update

Inter Frequency Load BalanceHCS (Hierarchical Cell Structure)Inter Frequency Load BalanceHCS (Hierarchical Cell Structure)Inter RNC Soft HandoverInter Frequency Hard Handover Based on Coverage


Inter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoS

Inter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoSInter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoSInter-RAT Handover Based on ServiceInter-RAT Handover Based on Load


NO NO Inter-RAT Handover Based on Interval Type 1~64 500~32000, step:500

NO NO Inter-RAT Handover Based on Interval Type 0~63 0~62, 63: Infinity




















NO NO Enumeration Type CPICH_EC/NO, CPICH_RSC CPICH_EC/NO, CPICH_RSC





















NO NO Interval Type 0~20 0~2, step:0.1









NO NO None Interval Type -29~29 -14.5~14.5, step:0.5





NO NO Enumeration Type D250, D500 250, 500

NO NO Enumeration Type D1, D2, D4, D8 1, 2, 4, 8




Inter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadLoad Based 3G-2G Handover Enhancement Based on Iur-g


Inter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverInter RNC Soft HandoverInter Frequency Hard Handover Based on CoverageInter RNC Soft HandoverInter Frequency Hard Handover Based on Coverage

Intra Node B Softer HandoverInter RNC Soft HandoverInter RNC Soft HandoverInter Frequency Hard Handover Based on CoverageIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverInter RNC Soft HandoverInter Frequency Hard Handover Based on CoverageIntra Node B Softer HandoverInter RNC Soft Handover

Intra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft Handover

Inter Frequency Load BalanceIntra Frequency Load BalanceInter Frequency Load BalanceIntra Frequency Load Balance



NO NO Enumeration Type AFFECT, NOT_AFFECT AFFECT, NOT_AFFECT

NO NO Enumeration Type AFFECT, NOT_AFFECT AFFECT, NOT_AFFECT









NO NO Enumeration Type D2~0 D3~1 D4~2 D6~3 D8~4 2, 3, 4, 6, 8, 10, 12, INFINITY



NO NO MBMS FLC(Frequency Layer ConEnumeration Type FALSE, TRUE FALSE, TRUE

NO YES OTDOA Based LCS Interval Type 0~63 0~63



NO YES None Enumeration Type IP, Port, IPAndPort IP, Port, IPAndPort

NO YES None IP Address Type None 0.0.0.0~255.255.255.254


NO YES None Enumeration Type TCP, UDP TCP, UDP


NO YES Enumeration Type FALSE, TRUE TRUE, FALSE


NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type OFF, ON OFF, ON

NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type D1, D2, D3, D4, D5, D6, D7, D 1, 2, 3, 4, 5, 6, 7, 8, 9, 10























YES YES 3GPP Specifications Interval Type 1~65533, 65535 1~65533, 65535

YES YES Shared Network Support in Co Interval Type 0~65535 0~65535

YES YES String Type None 000~999

YES YES String Type None 00~99, 000~999

NO NO Load Reshuffling Enumeration Type IUBLDR(Iub load reshuffling), IUBLDR, CODELDR, UULDR,




NO NO Load Reshuffling Bit Field Type NODEB_CREDIT_LDR_SWITCH(NNODEB_CREDIT_LDR_SWITC

NO NO Intra Frequency Load Balance Interval Type 1~86400 1~86400

NO NO Potential User Control Interval Type 6~86400 6~86400

Inter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on DL QoSIntra Node B Softer HandoverInter RNC Soft HandoverIntra Node B Softer HandoverInter RNC Soft HandoverIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateInter RNC Soft HandoverInter Frequency Hard Handover Based on CoverageIntra Node B Softer HandoverInter RNC Soft Handover









NO NO Load Measurement Enumeration Type D0, D1, D2, D3, D4, D5, D6, D D0, D1, D2, D3, D4, D5, D6, D

NO NO Load Measurement Enumeration Type TEN_MSEC, MIN TEN_MSEC, MIN

NO YES Load Measurement Interval Type 1~6000 10~60000, step:10

NO YES Load Measurement Interval Type 1~60 1~60



























NO NO Load Measurement Interval Type 1~6000 10~60000, step:10












YES YES MBMS Introduction Package String Type None 000~999

YES YES MBMS Introduction Package String Type None 000~999









NO YES MBMS Channel Audience Rating Enumeration Type CH0(Channel 0), CH1(ChannelCH0, CH1, CH2, CH3, CH4

NO YES MBMS Channel Audience Rating Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO YES String Type None 000~999

NO YES String Type None 00~99, 000~999










NO YES MBMS Introduction Package Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO FACH Transmission Sharing fo Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO MBMS Phase 2 Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO MBMS Phase 2 Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO Enumeration Type OFF(OFF), SERVICE-BASED OFF, SERVICE-BASED, LOA




NO NO Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO Enumeration Type OFF(OFF), ON(ON) OFF, ON





NO NO MBMS Introduction Package Interval Type 7~10 7~10





NO NO Inter System Direct Retry Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 3000, 4

NO NO Inter System Direct Retry Interval Type -115~-25 -115~-25

NO NO Inter System Direct Retry Interval Type -24~0 -24~0



NO NO Inter Frequency Hard Handover Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 3000, 4



NO YES Cell Broadcast Service Enumeration Type OFF, ON OFF, ON

NO YES Cell Broadcast Service String Type None 15-bit numerical (0 to 9) string




NO NO MBMS Phase 2 Enumeration Type True, False TRUE, FALSE

NO YES 3GPP Specifications Compound Type hour, min, sec 00:00:00~23:59:59

NO YES 3GPP Specifications Interval Type 1~288 5~1440, step:5


NO NO None Enumeration Type OFF, ON OFF, ON



NO NO IP Transmission Introduction on Enumeration Type ATM_TRANS(ATM circuit transATM_TRANS, IP_TRANS, AT

NO NO ATM Transmission Introduction Interval Type 0~65535 0~65535

NO NO RNC Node Redundancy Enumeration Type SINGLEHOST(SingleHost), P SINGLEHOST, PRIMHOST,



NO YES Transmission Recourse Sharing oEnumeration Type DEDICATED(Dedicated), RA Dedicated, RANSharing, MOC


NO NO Bit Field Type IUB_LDR(IUB LDR Algorithm) IUB_LDR, NODEB_CREDIT_L

NO NO HSDPA Admission Control Interval Type 0~3840 0~3840

NO NO HSUPA Admission Control Interval Type 0~3840 0~3840

NO NO Admission Control Enumeration Type MBR, GBR MBR, GBR




NO YES NodeB Self-discovery Based on Interval Type 0~65535 0~65535

NO YES NodeB Self-discovery Based on Interval Type 0~65535 0~65535

NO NO Load Reshuffling Enumeration Type NoAct(no action), BERateRed(BNoAct, BERateRed, QoSReneg



GSM and UMTS Load Balancing Based on Iur-gGSM and UMTS Traffic Steering Based on Iur-g

GSM and UMTS Load Balancing Based on Iur-g

GSM and UMTS Load Balancing Based on Iur-gMBSC Service DistributionMBSC Handover based on Load EnhancementLoad Based 3G-2G Handover Enhancement Based on Iur-g


MBSC Load BalancingMBSC Handover based on Load EnhancementNACC Procedure OptimizationNACC Procedure Optimization Based on Iur-g between GSM and UMTSMBSC Service DistributionMBSC Handover based on Load EnhancementMBSC Service DistributionMBSC Handover based on Load Enhancement


RAN Sharing Introduction PackageMOCN Introduction PackageLoad ReshufflingOverload Control
























NO NO Load Reshuffling Enumeration Type 8SF4(8SF4), 7SF4(7SF4), 6SF8SF4, 7SF4, 6SF4, 5SF4, 4SF






NO YES None Enumeration Type IntraFreqNCell(IntraFreq NeighIntraFreqNCell, InterFreqNCell




NO YES Bit Field Type CS_SHO_SWITCH, HSPA_S CS_SHO_SWITCH, HSPA_S

NO YES Enumeration Type OFF, ON OFF, ON

NO YES 3GPP Specifications Enumeration Type SUPPORT_CS, SUPPORT_P SUPPORT_CS, SUPPORT_P


NO YES 3GPP Specifications Enumeration Type R99, R4, R5, R6, R7, R8 R99, R4, R5, R6, R7, R8

NO NO Enumeration Type NO, YES NO, YES

NO NO SRNS Relocation with Hard Ha Bit Field Type DL_DCCH_SWITCH, IUR_TR DL_DCCH_SWITCH, IUR_TR

NO NO Direct Signaling Connection Re Enumeration Type CORRM_SRNSR_PSBE_REL CORRM_SRNSR_PSBE_REL

NO NO HSDPA over Iur Enumeration Type OFF, ON OFF, ON

NO NO HSUPA over Iur Enumeration Type OFF, ON OFF, ON


NO NO HSDPA Dynamic Power Allocati Enumeration Type OFF, ON OFF, ON

NO NO 3GPP Specifications Bit Field Type RSVDBIT1_BIT1, RSVDBIT1_BThis parameter is set to 0 or 1











NO NO MOCN Introduction Package Interval Type 0~3, 255 0~3, 255

NO NO MOCN Introduction Package Bit Field Type COMM_MOCN_NRI_GLOBAL_C


YES YES Traffic Priority Mapping onto T Enumeration Type INTERACTIVE, BACKGROUN INTERACTIVE, BACKGROUN

YES YES Traffic Priority Mapping onto T Enumeration Type GOLD, SILVER, COPPER GOLD, SILVER, COPPER

RAN Sharing Introduction PackageMOCN Introduction PackageIu FlexMOCN Introduction PackageDirect Signaling Connection Re-establishment (DSCR)RNC Node RedundancyInterface Message TracingRNC Node RedundancyIntra Frequency Hard HandoverRNC Node Redundancy

Inter RNC Soft HandoverRNC Node Redundancy

Inter RNC Cell UpdateInter RNC URA Update

Direct Signaling Connection Re-establishment (DSCR)RNC Node RedundancyIntra RNC URA UpdateInter RNC URA UpdateMOCN Introduction PackageRNC Node RedundancyRAN Sharing Introduction PackageMOCN Introduction PackageMOCN Introduction PackageRAN Sharing Introduction PackageMOCN Mobility ManagementMOCN Load BanlanceMOCN Introduction PackageMOCN Mobility ManagementMOCN Introduction PackageMOCN Mobility Management

SPARE_5_SWITCH, SPARE_6_SWITCH

YES YES Traffic Priority Mapping onto T Enumeration Type High, Medium, Low High, Medium, Low

NO YES Differentiated Service Based on Interval Type 2~11 2~11


YES YES Differentiated Service Based on Interval Type 0~15 0~15



NO NO Traffic Priority Mapping onto T Enumeration Type High, Medium, Low High, Medium, Low
















YES YES Traffic Priority Mapping onto T Enumeration Type INTERACTIVE, BACKGROUNDINTERACTIVE, BACKGROUND


YES YES Traffic Priority Mapping onto T Enumeration Type R99, HSPA R99, HSPA


NO NO Traffic Priority Mapping onto T Enumeration Type D0, D8, D16, D32, D64, D128 0, 8, 16, 32, 64, 128, 144, 25



YES YES HSDPA Flow Control Enumeration Type INTERACTIVE, BACKGROUN INTERACTIVE, BACKGROUN



NO NO HSDPA Flow Control Interval Type 0~27900 0~27900


NO NO Enumeration Type Gold, Silver, Copper Gold, Silver, Copper















NO NO Enumeration Type ARP, TrafficClass ARP, TrafficClass

NO NO Enumeration Type NONE, DCH, HSPA NONE, DCH, HSPA











Queuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission Resources



YES YES Transport Channel Managemen Enumeration Type D1, D2 1~2


NO NO Transport Channel Managemen Interval Type 1 1












NO NO Paging UE in Idle, CELL_PCH, Enumeration Type V18, V36, V72, V144 18, 36, 72, 144




NO YES Admission Control Enumeration Type LAC, RAC LAC, RAC


YES YES Admission Control Interval Type 1~65533, 65535 {{1~65533}, {65535}}

NO YES Admission Control Interval Type 0~255 {0~255}

NO NO Admission Control Interval Type 1~256 {1~256}

NO NO Admission Control Interval Type 1~256 {1~256}

NO NO RNC Node Redundancy Enumeration Type REHOSTRIGHNOW(RehostRigREHOSTRIGHNOW, REHOST


NO YES RNC Node Redundancy Compound Type hour, min, sec 00:00:00~23:59:59



NO NO Open Loop Power Control Bit Field Type SIGNATURE0, SIGNATURE1, SIGNATURE0, SIGNATURE1,

NO NO 3GPP Specifications Bit Field Type SUBCHANEL0, SUBCHANEL1SUBCHANEL0, SUBCHANEL1,


YES NO Access Class Restriction Interval Type 0~255 0~255

NO NO Access Class Restriction Enumeration Type ASC0, ASC1, ASC2, ASC3, A ASC0, ASC1, ASC2, ASC3, A









YES YES System Information Broadcastin Enumeration Type ASC0, ASC1, ASC2, ASC3, A ASC0, ASC1, ASC2, ASC3, A




NO YES System Information Broadcastin Enumeration Type D0.9, D0.8, D0.7, D0.6, D0.5, 0.9, 0.8, 0.7, 0.6, 0.5, 0.4, 0.3,



NO YES Open Loop Power Control Bit Field Type SIGNATURE0, SIGNATURE1, SIGNATURE0, SIGNATURE1,

NO YES 3GPP Specifications Bit Field Type SUBCHANEL0, SUBCHANEL1SUBCHANEL0, SUBCHANEL1,


NO NO Open Loop Power Control Interval Type 1~64 1~64


NO NO Transport Channel Managemen Enumeration Type BIT2, BIT4, BIT6, BIT8, BIT12 2, 4, 6, 8, 12, 16, 24



YES YES Physical Channel Management Enumeration Type D1, D2, D3, D4 D1, D2, D3, D4


Open Loop Power ControlIntra Frequency Load Balance

Open Loop Power ControlIntra Frequency Load Balance


























NO NO Fast Dormancy Enhancement Interval Type 0~64800 0~64800









NO NO None Enumeration Type D8, D16, D32, D64, D128, D258, 16, 32, 64, 128, 256, 512, 1

NO NO None Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120

NO NO None Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 4000, 8

NO NO None Interval Type 1~10000 10~100000, step: 10

NO NO None Interval Type 0~38400 0~384000, step: 10




NO NO None Enumeration Type D8, D16, D32, D64, D128, D258, 16, 32, 64, 128, 256, 512, 1


NO NO None Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 4000, 8

NO NO None Enumeration Type D16, D32, D64, D128, D256, D16, 32, 64, 128, 256, 512, 1024



NO NO AMR/WB-AMR Speech Rates CoEnumeration Type NO, YES NO, YES

NO NO Inter Frequency Hard Handove Enumeration Type NO, YES NO, YES

NO NO Enumeration Type None, RateDegrade, InterFreq None, RateDegrade, InterFreq







NO NO Enumeration Type SINGLE, COMBINE SINGLE, COMBINE

NO NO Dynamic Channel Configuration Enumeration Type NO, YES NO, YES



Physical Channel ManagementOpen Loop Power ControlPhysical Channel ManagementOpen Loop Power Control

Inter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoS

Inter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoS

Dynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoS










NO NO Inter-RAT Handover Based on Enumeration Type NO, YES NO, YES



NO NO Inter-RAT Handover Based on Enumeration Type NO, YES NO, YES










NO NO Inter-RAT Handover Based on Enumeration Type CPICH_EC/NO, CPICH_RSC CPICH_EC/NO, CPICH_RSC














NO NO Dynamic Channel Configuration Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 11,







NO NO Inter Frequency Hard Handove Enumeration Type TEN_MSEC, MIN TEN_MSEC, MIN


NO YES Inter Frequency Hard Handove Interval Type 1~60 1~60









NO NO Queuing and Pre-Emption Enumeration Type OFF, ON OFF, ON




NO NO Queuing and Pre-Emption Interval Type 5~20 5~20

NO NO Queuing and Pre-Emption Interval Type 1~80 10~800, step:10

NO NO Queuing and Pre-Emption Interval Type 1~60 1~60, step:1

AMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoS

AMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoS

AMR/WB-AMR Speech Rates ControlInter Frequency Hard Handover Based on DL QoS



Dynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSAMR/WB-AMR Speech Rates ControlInter-RAT Handover Based on DL QoS

Dynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoS

Dynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoS

















YES YES Transport Channel Managemen Enumeration Type D1, D2 1~2



NO NO Downlink Enhanced CELL_FAC Interval Type 0~5000 0~5, step: 0.001



NO NO Downlink Enhanced CELL_FAC Interval Type 1~1000 0.1~100, step: 0.1

NO NO Downlink Enhanced CELL_FAC Interval Type 1~1000 10~10000, step: 10

NO NO Downlink Enhanced CELL_FAC Interval Type 0~49 -24.5~0, step: 0.5 Actual value

NO NO Downlink Enhanced CELL_FAC Interval Type 0~49 -24.5~0, step: 0.5 Actual value

YES YES Service Steering and Load Sha Enumeration Type AMR, VP, PSR99, PSHSPA AMR, VP, PSR99, PSHSPA

NO NO Service Steering and Load Sha Enumeration Type OFF, ONLY_TO_INTER_FRE OFF, ONLY_TO_INTER_FRE



NO NO Service Steering and Load Sha Enumeration Type Band1, Band2, Band3, Band4, BAND1, BAND2, BAND3, BAN

NO NO Service Steering and Load Sha Enumeration Type FALSE, TRUE FALSE, TRUE




YES YES Code Resource Management Enumeration Type SF4, SF8, SF16, SF32, SF64, SF4, SF8, SF16, SF32, SF64,

NO YES Code Resource Management Interval Type 0~255 0~255

NO NO Code Resource Management Interval Type 0~511 {0~511}

YES YES Domain Specific Access Contro Enumeration Type PsBlk(BLOCK PS), CsAndPsB PsBlk, CsAndPsBlk




NO NO Simplified Cell Broadcast Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO Cell Broadcast Service Enumeration Type OFF(OFF), ON(ON) OFF, ON

NO NO Simplified Cell Broadcast Enumeration Type GERMAN(German), ENGLISH(EnGERMAN, ENGLISH, ITALIA

NO NO Cell Broadcast Service Interval Type 1~4096 1~4096

NO NO Cell Broadcast Service Interval Type 0~65535 0~65535

NO NO Multi-Carrier Switch off Based o Enumeration Type OFF(switch off), ON(switch on) OFF, ON




NO NO MBMS Phase 2 Enumeration Type D16, D32, D64, D128, D256 16, 32, 64, 128, 256

NO NO MBMS Soft/Selective Combinin Interval Type 0~100 0~1, step: 0.01

NO NO MBMS Phase 2 Interval Type 1~5 1~5



NO NO MBMS Phase 2 Interval Type 2~20 2~20

NO NO MBMS Enhanced Broadcast Mo Interval Type 1~360 10~3600, step: 10

NO NO MBMS Admission Control Interval Type 0~60 0~60

NO NO MBMS Admission Control Enumeration Type ON, OFF ON, OFF



System Information BroadcastingOpen Loop Power ControlSystem Information BroadcastingOpen Loop Power ControlSystem Information BroadcastingOpen Loop Power Control



NO NO MBMS Enhanced Broadcast Mo Enumeration Type D8, D16, D32, D64, D128, D1 8, 16, 32, 64, 128, 144, 256

YES YES RNC Node Redundancy Interval Type 0 0

NO YES RNC Node Redundancy String Type None 1~20 characters

NO NO RNC Node Redundancy Interval Type 1~60 1~60

NO NO RNC Node Redundancy Interval Type 1~10 5

NO NO Interval Type 1~10 2

NO NO RNC Node Redundancy Enumeration Type NONE, IUCS, IUPS, IUCS_IU NONE, IUCS, IUPS, IUCS_IU

YES YES RNC Node Redundancy Interval Type 0 0

YES YES 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type ORIGCONVCALLEST, ORIGS ORIGCONVCALLEST, ORIGS

NO NO 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type FACH, DCH_3.4K_SIGNALLINFACH, DCH_3.4K_SIGNALLIN

NO NO Downlink Enhanced CELL_FAC Enumeration Type OFF, ON OFF, ON

NO NO Bit Field Type INVOKE_TRACE_SWITCH, S This parameter is set to 0 or 1

NO NO 3GPP Specifications Bit Field Type RSVDBIT1_BIT1, NAS_QOS_MOThis parameter is set to 0 or 1










YES YES Iupc Interface for LCS service Interval Type 0~3 0~3

NO YES Iupc Interface for LCS service Interval Type 0~186 0~186

NO NO Intra Frequency Load Balance Interval Type 1~86400 1~86400

NO NO Potential User Control Interval Type 6~86400 6~86400



































3GPP SpecificationsRNC Node Redundancy

3GPP SpecificationsUplink Flow Control of User Plane
















NO NO Transport Channel Managemen Enumeration Type BIT2, BIT4, BIT6, BIT8, BIT12 2, 4, 6, 8, 12, 16, 24

NO YES Physical Channel Management Enumeration Type D0, D1, D2, D3, D4, D5, D6, D 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10,

NO YES Physical Channel Management Enumeration Type EXISTS, NOT_EXISTS EXISTS, NOT_EXISTS

NO NO MBMS Introduction Package Enumeration Type COMMON, MCCH COMMON, MCCH




YES YES Traffic Priority Mapping onto T Enumeration Type INTERACTIVE, BACKGROUN INTERACTIVE, BACKGROUN





NO NO Bit Field Type CELLID_CENTER, CELLID_R A-GPS, OTDOA, CELLID_RT

NO NO A-GPS Based LCS Enumeration Type UE_BASED, UE_ASSISTED, UE_BASED, UE_ASSISTED,

NO NO A-GPS Based LCS Enumeration Type NODELIVERY, DELIVERY NODELIVERY, DELIVERY

NO NO A-GPS Based LCS Bit Field Type REFERENCE_TIME_FOR_GPSREFERENCE_TIME_FOR_GPS

NO NO A-GPS Based LCS Bit Field Type REFERENCE_TIME_FOR_GPSREFERENCE_TIME_FOR_GPS

NO NO A-GPS Based LCS Interval Type 4~16 4~16

NO NO Enumeration Type UE_BASED, UE_ASSISTED, UE_BASED, UE_ASSISTED,

NO NO Cell ID + RTT Function Based Enumeration Type UE_BASED, UE_ASSISTED, UE_BASED, UE_ASSISTED,

NO NO Emergency Call Enumeration Type OFF, ON OFF, ON


NO NO Enumeration Type DRD, MEAS_BASED DRD, MEAS_BASED

NO NO Bit Field Type R5_POSDATA_SWITCH, LA R5_POSDATA_SWITCH, LA

NO NO Cell ID + RTT Function Based Enumeration Type OFF, ON OFF, ON

NO YES Cell ID + RTT Function Based Interval Type 0~29 0~14.5, step: 0.5

NO YES Cell ID + RTT Function Based Interval Type 0~29 0~14.5, step: 0.5

NO YES Cell ID + RTT Function Based Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120

NO YES Cell ID + RTT Function Based Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120

NO YES Cell ID + RTT Function Based Interval Type -24~0 -24~0

NO NO Cell ID + RTT Function Based Enumeration Type RNC_CENTRIC(RNC CENTRICRNC_CENTRIC, SAS_CENTR


NO NO Cell ID + RTT Function Based Enumeration Type NLOS_ENVIRONMENT, LOS NLOS_ENVIRONMENT, LOS

NO NO Cell ID + RTT Function Based Enumeration Type INACTIVE, ACTIVE INACTIVE, ACTIVE

NO NO OTDOA Based LCS Enumeration Type INACTIVE, ACTIVE INACTIVE, ACTIVE

NO NO A-GPS Based LCS Enumeration Type INACTIVE, ACTIVE INACTIVE, ACTIVE









NO NO None Interval Type 0~500 0~5, step: 0.01

NO NO None Interval Type 0~500 0~5, step: 0.01

NO NO SRNS Relocation (UE Not Invol Interval Type 1~255 1~255



A-GPS Based LCSLCS over Iur

OTDOA Based LCSA-GPS Based LCS

OTDOA Based LCSA-GPS Based LCSOTDOA Based LCSA-GPS Based LCSOTDOA Based LCSA-GPS Based LCS

SRNS Relocation (UE Not Involved)



NO NO SRNS Relocation (UE Not Invol Enumeration Type RT(Real time service), NRT(NonRT, NRT, ALL






















NO NO SRNS Relocation with Cell/URA Interval Type 1~10000 1~10000















NO NO Encryption Interval Type 1~10000 1~10000





















YES YES Interval Type 0~6, 11~19, 21~28, 40~69, 70 0~6, 11~19, 21~28, 40~69, 70

Intra RNC Cell UpdateInter RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell Update

Intra Node B Softer HandoverInter RNC Soft HandoverInter Frequency Hard Handover Based on DL QoSIntra Frequency Hard HandoverInter Frequency Hard Handover Based on DL QoSIntra Frequency Hard Handover

Interactive QoS ClassBackground QoS ClassInteractive QoS ClassBackground QoS Class

NO YES Enumeration Type CONVERSATIONAL, STREAMCONVERSATIONAL, STREAM

NO YES Enumeration Type SPEECH, UNKNOWN SPEECH, UNKNOWN

NO YES 3.4/6.8/13.6/27.2 kbit/s RRC C Interval Type 0~256000000 0~256000000

NO YES 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type CS_DOMAIN, PS_DOMAIN CS_DOMAIN, PS_DOMAIN

NO YES Inner Loop Power Control Interval Type 1~15 1~15

NO YES Inner Loop Power Control Interval Type 1~15 1~15

NO YES Enumeration Type HO_TO_GSM_SHOULD_BE_PHO_TO_GSM_SHOULD_BE_P

NO YES Enumeration Type GSM, GPRS, EDGE GSM, GPRS, EDGE

NO YES Enumeration Type NORMAL, SILENT NORMAL, SILENT

NO YES 3.4/6.8/13.6/27.2 kbit/s RRC C Enumeration Type APPLIED_ON_UPLINK, APP APPLIED_ON_UPLINK, APP


YES YES Enumeration Type UPLINK, DOWNLINK UPLINK, DOWNLINK

NO NO Dynamic Channel Configuration Enumeration Type D16, D32, D64, D128, D256, 16, 32, 64, 128, 256, 512, 10

NO YES Dynamic Channel Configuration Enumeration Type D8, D16, D32, D64, D128, D2 8, 16, 32, 64, 128, 256, 512,


NO NO Dynamic Channel Configuration Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 4000, 8


NO NO Dynamic Channel Configuration Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 4000, 8

NO NO HSUPA DCCC Interval Type 0~1023 0~1023







YES YES Enumeration Type TRCH_HSDSCH, TRCH_EDC TRCH_HSDSCH, TRCH_EDC

NO NO HSDPA Introduction Package Enumeration Type D1, D2, D3, D4, D5, D6, D7, D 1, 2, 3, 4, 5, 6, 7, 8

NO NO HSDPA Introduction Package Interval Type 1~5000 1~5000








NO NO HSUPA Introduction Package Enumeration Type D1, D2, D3, D4, D5, D6, D7, D 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11,













NO NO HSDPA Flow Control Enumeration Type D2, D10, D20, D50, D100, D2 2, 10, 20, 50, 100, 200, 500, 1



YES YES Outer Loop Power Control Enumeration Type TRCH_DCH, TRCH_EDCH_2 TRCH_DCH, TRCH_EDCH_2


NO YES Outer Loop Power Control Interval Type -63~0 5*10^(-7)~1

NO YES HSUPA Power Control Interval Type 0~5000 0~5, step: 0.001

NO YES HSUPA Power Control Interval Type 0~15 0~15







Inter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInter-RAT Handover Based on ServiceInter-RAT Handover Based on LoadInteractive QoS ClassBackground QoS Class

Interactive QoS ClassBackground QoS ClassDynamic Channel Configuration Control (DCCC)HSUPA DCCC

Interactive QoS ClassBackground QoS ClassHSDPA Introduction PackageHSUPA Introduction Package


Background QoS ClassSatellite Transmission on Iub Interface

Interactive QoS ClassBackground QoS ClassDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoS




NO YES Dynamic Channel Configuration Interval Type 1~512 1~512

NO YES Dynamic Channel Configuration Interval Type 1~512 1~512

NO YES Interval Type 0~56 0~28, step: 0.5

NO YES Interval Type 0~56 0~28, step: 0.5



YES YES Enumeration Type TRCH_DCH, TRCH_HSDSCH TRCH_DCH, TRCH_HSDSCH

NO YES None Enumeration Type TRCH_DCH, TRCH_HSDSCH TRCH_DCH, TRCH_HSDSCH


NO YES Enumeration Type AM, UM, TM AM, UM, TM

NO YES None Enumeration Type SENDER_PARA, RECEIVE_ SENDER_PARA, RECEIVE_




NO NO Flow Control Interval Type 0~1000 0~100, step: 0.1







NO NO Encryption Bit Field Type UEA0, UEA1 For each switch of this parame

NO NO UE State in Connected Mode Interval Type 1~65535 1~65535

NO NO UE State in Connected Mode Enumeration Type D8, D16, D32, D64, D128, D258, 16, 32, 64, 128, 256, 512, 1

NO NO UE State in Connected Mode Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120

NO NO UE State in Connected Mode Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 4000, 8



NO NO UE State in Connected Mode Enumeration Type D16, D32, D64, D128, D256, D16, 32, 64, 128, 256, 512, 1024




NO NO Enumeration Type D250, D500, D1000, D2000, D 250, 500, 1000, 2000, 4000, 8

NO NO HSDPA State Transition Enumeration Type D16, D32, D64, D128, D256, D16, 32, 64, 128, 256, 512, 1024

NO NO HSDPA State Transition Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120

NO NO UE State in Connected Mode Enumeration Type D8, D16, D32, D64, D128, D258, 16, 32, 64, 128, 256, 512, 1











NO NO Enumeration Type D16, D32, D64, D128, D256, D16, 32, 64, 128, 256, 512, 1024






NO NO Downlink Enhanced CELL_FAC Enumeration Type D16, D32, D64, D128, D256, D16, 32, 64, 128, 256, 512, 1024

NO NO Downlink Enhanced CELL_FAC Enumeration Type D0, D10, D20, D40, D60, D80 0, 10, 20, 40, 60, 80, 100, 120





Dynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoSDynamic Channel Configuration Control (DCCC)Inter-RAT Handover Based on DL QoS

Inter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInter Frequency Hard Handover Based on DL QoSInter-RAT Handover Based on DL QoSInteractive QoS ClassBackground QoS ClassInteractive QoS ClassBackground QoS ClassInteractive QoS ClassBackground QoS Class

Background QoS ClassSatellite Transmission on Iub InterfaceInteractive QoS ClassBackground QoS Class

UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, CELL-FACH)HSDPA State TransitionUE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, CELL-FACH)HSDPA State TransitionUE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, CELL-FACH)HSDPA State Transition

HSUPA DCCCDynamic Channel Configuration Control (DCCC)

HSUPA DCCCDynamic Channel Configuration Control (DCCC)HSUPA DCCCDynamic Channel Configuration Control (DCCC)

CPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operation





NO NO Fast Dormancy Enhancement Enumeration Type D16, D32, D64, D128, D256, D16, 32, 64, 128, 256, 512, 1024














NO NO Integrity Protection Bit Field Type UIA1 For each switch of this parame



YES YES Traffic Priority Mapping onto T Enumeration Type INTERACTIVE, BACKGROUNDINTERACTIVE, BACKGROUND


YES YES Traffic Priority Mapping onto T Enumeration Type R99, HSPA R99, HSPA

NO YES Traffic Priority Mapping onto T Enumeration Type GOLD, SILVER, COPPER GOLD, SILVER, COPPER



YES YES HSDPA Flow Control Enumeration Type INTERACTIVE, BACKGROUN INTERACTIVE, BACKGROUN



NO NO HSDPA Flow Control Interval Type 0~27900 0~27900

NO NO Traffic Priority Mapping onto T Enumeration Type D3.4, D13.6, D27.2 3.4, 13.6, 27.2

NO NO Traffic Priority Mapping onto T Enumeration Type D3.4, D13.6, D27.2 3.4, 13.6, 27.2

NO NO Traffic Priority Mapping onto T Enumeration Type D0, D8, D16, D32, D64, D128, 0, 8, 16, 32, 64, 128, 144, 256



















NO NO Enumeration Type ARP, TrafficClass ARP, TrafficClass

NO NO Enumeration Type NONE, DCH, HSPA NONE, DCH, HSPA

YES YES Cell Broadcast Service String Type None digits with length of 6~15

NO NO Emergency Call Enumeration Type ALGORITHM_OFF(WPS AlgoritALGORITHM_OFF, ALGORIT

NO NO Emergency Call Bit Field Type PRIORITY1(WPS USER PRIORPRIORITY1, PRIORITY2, PRI

CPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operation

UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, CELL-FACH)HSDPA State Transition

CPC - DTX / DRXCPC - HS-SCCH less operationCPC - DTX / DRXCPC - HS-SCCH less operation

CPC - HS-SCCH less operationDownlink Enhanced CELL_FACHCPC - DTX / DRXCPC - HS-SCCH less operation


Queuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission ResourcesQueuing and Pre-EmptionTraffic Priority Mapping onto Transmission Resources

Unit Default Value Recommended Value Impact Parameter Relationship

None 1 1 RNC None

None None None None None


None None UMTS BSC6900 None

None YES YES BSC6900 None

None None None BSC6900 None

Erl None None BSC6900 None

kbit/s None None BSC6900 None

kbit/s None None BSC6900 None

None None None Cell None

None 5 5 Physical channel None

dB 0 0 Cell None

None None None RNC None



dB 0 0 Cell None

dB 0 0 Cell None

dBm -50 -50 Cell None

s D0 D0 Cell None

dB D3 D3 Cell This parameter is valid when "

None 0 0 Cell None

None None None Cell This paramter is valid only wh

dB -18 -18 Cell None

None 1 1 Cell None

None 0 0 Cell None

None 0 0 Cell None


None 0 0 Cell None

None 0 0 Cell None

None OFF OFF RNC None

% 2 2 RNC This parameter needs to be s

ms 50 50 RNC This parameter needs to be s

s 10 30 RNC This parameter needs to be s

s 1 1 RNC None


None 10 10 RNC This parameter is valid only













None None 50 RNC This parameter is valid only









None 4 4 Cell None


None 1 1 Cell None



dB -6 -6 Physical channel None

dB 50 50 RNC

dB 50 50 RNC

dB 120 120 RNC

dB 120 120 RNC

ms 1000 1000 RNC

ms 3000 3000 RNC

kbit/s NBAMR_BITRATE_12.20K NBAMR_BITRATE_12.20K Cell



dB 50 50 RNC

dB 50 50 RNC

dB 120 120 RNC

dB 120 120 RNC

ms 1000 1000 RNC

ms 3000 3000 RNC

kbit/s WBAMR_BITRATE_23.85K WBAMR_BITRATE_23.85K Cell




None 0 0 Transport channel None

dB -20 -20 Transport channel None

None None ON RNC None


None 0 0 RNC None

None 0 0 RNC None

None None RNC None

None ON ON RNC None

s 3 3 RNC None

None 180 180 RNC None

None 60 60 RNC None

None 60 60 RNC None


None 60 60 RNC None

None 20 20 RNC None

None 20 20 RNC None

None 45 45 RNC None

None 15 15 RNC None

None 15 15 RNC None


None None 0 RNC None


None None CELL RNC None





None None CellNormal RNC None

None Normal Normal RNC None

s 1 1 RNC None

None 10 10 RNC None

None None English RNC None


None None Earthquake RNC None


None None None RNC Not Involved



dBm 430 430 Cell None

The following relationship must be satisfied: "DlThdE1" <= "DlThdE2" < "DlThdF2" <= "DlThdF1".The following relationship must be satisfied: "DlThdE1" <= "DlThdE2" < "DlThdF2" <= "DlThdF1".The following relationship must be satisfied: "DlThdE1" <= "DlThdE2" < "DlThdF2" <= "DlThdF1".The following relationship must be satisfied: "DlThdE1" <= "DlThdE2" < "DlThdF2" <= "DlThdF1".The following relationship must be satisfied: "UlModeChangeTimerLen" <= "DlModeChangeTimerLen".The following relationship must be satisfied: "UlModeChangeTimerLen" <= "DlModeChangeTimerLen".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied: "DlThdE1" <= "DlThdE2" < "DlThdF2" <= "DlThdF1".The following relationship must be satisfied: "DlThdE1" <= "DlThdE2" < "DlThdF2" <= "DlThdF1".The following relationship must be satisfied: "DlThdE1" <= "DlThdE2" < "DlThdF2" <= "DlThdF1".The following relationship must be satisfied: "DlThdE1" <= "DlThdE2" < "DlThdF2" <= "DlThdF1".The following relationship must be satisfied: "UlModeChangeTimerLen" <= "DlModeChangeTimerLen".The following relationship must be satisfied: "UlModeChangeTimerLen" <= "DlModeChangeTimerLen".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".

NODEB_LEVEL:ONCELL_LEVEL:ON


None Invalid Invalid Cell None




None None None Cell When "UARFCNUplinkInd" is set


chip None None Cell None

None 5 5 Cell None

None 50 50 Cell None

s 50 50 Cell None




None None None NodeB None





None STTD_not_Supported STTD_not_Supported Cell This paramter is valid only whe

None CP1_not_Supported CP1_not_Supported Cell This paramter is valid only whe

None OFFSET1 OFFSET1 Cell This paramter is valid only w

None None None Cell

None None None Cell

None None None Cell

None None None Cell

None None None Cell

dB 0 0 Cell None

None 0 0 Cell None










None 0 0 Cell None



dBm 330 330 Physical channel



dB 0 0 Cell None

dB -20 -20 Transport channel None


None NOT_RESERVED NOT_RESERVED Cell None

None NOT_RESERVED NOT_RESERVED Cell None

None NOT_BARRED NOT_BARRED Cell None












This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.This paramter is set to CP1 only when "CP1SupInd" is set to CP1_Supported.This paramter is valid only when "TxDiversityInd" is set to TRUE.This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.This paramter is set to CP1 only when "CP1SupInd" is set to CP1_Supported.This paramter is valid only when "TxDiversityInd" is set to TRUE.This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.This paramter is valid only when "TxDiversityInd" is set to TRUE.This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.

"Min Transmit Power of PCPICH" <= "PCPICH Transmit Power"2. To modify the "PCPICH Transmit Power", the intra-frequency load balance algorithm of the cell should be disabled. You can use "LST UCELLALGOSWITCH" to query the switch and use "MOD UCELLALGOSWITCH" to modify the switch.






None ALLOWED ALLOWED Cell This parameter is valid only w

s D320 D320 Cell This parameter is valid only w


None NOT_ALLOWED NOT_ALLOWED Cell This parameter is valid only

s D1280 D1280 Cell This parameter is valid only









None None None Cell If the Downlink CAC algorithm

None None None Cell

None ALGORITHM_DEPEND_ON_ ALGORITHM_DEPEND_ON_ Cell None


None E_F_DPCH_OFF E_F_DPCH_OFF Cell None


None NBM_LDC_MATCH_UE_ONL NBM_LDC_MATCH_UE_ONL Cell None


None 0 0 Cell None

None 0 0 Cell None










None TU TU Cell None

% 75 75 Cell

% 75 75 Cell

% 60 60 Cell

% 80 80 Cell

% 80 80 Cell

% 75 75 Cell

% 80 80 Cell

% 85 85 Cell

% 83 83 Cell

% 90 90 Cell

% 0 0 Cell None

% 0 0 Cell None



% 100 100 Cell None

% 100 100 Cell None

% 100 100 Cell None

% 0 0 Cell None

% 70 70 Cell None

% 30 30 Cell None


dBm 24 24 Cell None

dBm 24 24 Cell None

PUC should not be adopted if cell's inter-frequency measurement control information has been configured as not required.Note:Inter-freq cell reselection threshold is set by"ADD UCELLSELRESEL".Inter-frequency measurement control information is set by "MOD UCELLMEAS".

The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".

The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".The following relationship must be satisfied:"GoldMaxMode" >= "SilverMaxMode" >= "CopperMaxMode".

MAX("UlNonCtrlThdForHo", "UlNonCtrlThdForAMR", "UlNonCtrlThdForNonAMR", "UlNonCtrlThdForOther") > "UlLdrTrigThd" > "UlLdrRelThd"(For detailed information, refer to "ADD UCELLLDM").MAX("UlNonCtrlThdForHo", "UlNonCtrlThdForAMR", "UlNonCtrlThdForNonAMR", "UlNonCtrlThdForOther") > "UlLdrTrigThd" > "UlLdrRelThd"(For detailed information, refer to "ADD UCELLLDM").MAX("UlNonCtrlThdForHo", "UlNonCtrlThdForAMR", "UlNonCtrlThdForNonAMR", "UlNonCtrlThdForOther") > "UlLdrTrigThd" > "UlLdrRelThd"(For detailed information, refer to "ADD UCELLLDM")."DlHOThd" > "DlConvAMRThd";"DlConvAMRThd" > "DlOtherThd""DlHOThd" > "DlConvNonAMRThd";"DlConvNonAMRThd" > "DlOtherThd""DlConvNonAMRThd" > "DlOtherThd";"DlOtherThd" >= "DlLdrTrigThd"(See "ADD UCELLLDM")MAX("UlNonCtrlThdForHo", "UlNonCtrlThdForAMR", "UlNonCtrlThdForNonAMR", "UlNonCtrlThdForOther") > "UlLdrTrigThd" > "UlLdrRelThd"(For detailed information, refer to "ADD UCELLLDM")."DlHOThd" > "DlConvAMRThd";"DlHOThd" > "DlConvNonAMRThd""UlOlcTrigThd"(See "ADD UCELLLDM") >= "UlCellTotalThd";"UlCellTotalThd" > "UlNonCtrlThdForHo""DlOlcTrigThd"(See "ADD UCELLLDM") >= "DlCellTotalThd";"DlCellTotalThd" >= "DlHOThd"

dBm 24 24 Cell None

dBm 24 24 Cell None

dBm 61 61 Cell None


None ON ON Cell None

s 120 120 Cell None

None 0 0 Cell None


% 0 0 Cell None

% 0 0 Cell None

% 20 20 Cell

None 16 16 Cell

% 60 60 Cell

None 40 40 Cell

None SF16 SF16 Cell

None SF32 SF32 Cell

None None 01&00&00 Cell

None None 06&00&00 Cell

dBm 5 5 Cell

dB 100 100 Cell


% 40 40 Cell None

% 100 100 Cell None

% 100 100 Cell None





None WALKING_SPEED_AND_HOTWALKING_SPEED_AND_HOTCell None

None D64 D64 Cell None



dB 10 10 Cell This parameter is available i


kbit/s D64 D64 Cell This parameter is available i



None OFF None Cell None

chip 255 None Cell None

% 50 None Cell None

% 0 None Cell None


None 2 2 Cell If this parameter is set thr

None OFF OFF Cell If this parameter is set thr



None UserNumber UserNumber Cell If this parameter is set thr

% 35 35 Cell If this parameter is set thr



None SF8 SF8 Cell If this parameter is set thr


None DependOnNCell DependOnNCell Cell If this parameter is set thr

None None None Cell If this parameter is set thr

None None None Cell

None None None Cell

None OFF ON RNC If this parameter is set thr

% 25 25 RNC If this parameter is set thr




The value of this parameter must satisfy the following relationship:"MtchMaxPwr" >= "MtchRsvPwr".The value of this parameter must satisfy the following relationship:"MtchMaxSf" >= "MtchRsvSf"The value of this parameter must satisfy the following relationship:"MtchMaxPwr" >= "MtchRsvPwr"The value of this parameter must satisfy the following relationship:"MtchMaxSf" >= "MtchRsvSf""UlHoCeResvSf" >= "UlLdrCreditSfResThd". The comparison between the spreading factors is based on the number following the acronym "SF", for example, SF32>SF8. (For detailed information, refer to "ADD UCELLLDR".)"DlHoCeCodeResvSf" >= "CellLdrSfResThd". The comparison between the spreading factors is based on the number following the acronym "SF", for example, SF32>SF8.(For detailed information, refer to "ADD UCELLLDR")The value of this parameter must satisfy the following relationship:"BgnEndTime" >"MBgnStartTime" .The value of this parameter must satisfy the following relationship:"BgnEndTime" >"MBgnStartTime" .The value of this parameter must satisfy the following relationship:"BgnAbnormalThd" >= "BgnUpdateThd"The value of this parameter must satisfy the following relationship:"BgnAbnormalThd" >= "BgnUpdateThd"

BandIndNotUsed [0-16383]BandIndNotUsed [0-16383]

None 10 10 RNC None

None 10 10 RNC None

None 25 25 RNC None

None 17 17 RNC None

None 15 15 RNC None

None 25 25 RNC None

None 20 20 RNC None

None 15 15 RNC None






None None None Cell When "RestrictionType" in "A

None None None Cell Only when "RestrictionType"

None None None Cell Only when "RestrictionType"

s None None Cell Only when "RestrictionType"



min None None Cell

min None None Cell

min None None Cell

min None None Cell

min None None Cell

min None None Cell

None CONDITIONALSHUTDOWN CONDITIONALSHUTDOWN Cell This paramter is valid only w

None 1 1 Cell This paramter is valid only w



% 20 20 Cell This paramter is valid only w


dB 10 10 Cell None


dB 0 0 Cell None

kbit/s 32 32 Cell This parameter must satisfy


kbit/s 32 32 Cell This parameter must satisfy t













kbit/s D8 D8 Cell If this parameter is set th

kbit/s D8 D8 Cell If this parameter is set th

None 0 0 Cell The code-resource-saving mod

dB 41 41 Cell If this parameter is set th

ms 5000 5000 Cell If this parameter is set thr





None None None Cell When "UARFCNUplinkInd" is set


None ACTIVE ACTIVE Cell None

The value of this parameter must fulfill the following condition: "First Cell Dynamic ShutDown Interval Start Time" < "First Cell Dynamic ShutDown Interval End Time".The value of this parameter must fulfill the following condition:"First Cell Dynamic ShutDown Interval Start Time" < "First Cell Dynamic ShutDown Interval End Time".The value of this parameter must fulfill the following condition: "Second Cell Dynamic ShutDown Interval Start Time" < "Second Cell Dynamic ShutDown Interval End Time".The value of this parameter must fulfill the following condition: "Second Cell Dynamic ShutDown Interval Start Time" < "Second Cell Dynamic ShutDown Interval End Time".The value of this parameter must fulfill the following condition: "Third Cell Dynamic ShutDown Interval Start Time" < "Third Cell Dynamic ShutDown Interval End Time".The value of this parameter must fulfill the following condition: "Third Cell Dynamic ShutDown Interval Start Time" < "Third Cell Dynamic ShutDown Interval End Time".


None NOT_USED NOT_USED Cell None

None 0 0 Cell This parameter is required wh

dB 0 0 Cell This parameter is required wh


dB/ dBm 20 20 Cell This parameter is valid only w

s D60 D60 Cell This parameter is required wh

None 8 8 Cell This parameter is required wh

s D20 D20 Cell This parameter is required wh



None OFF OFF Cell This parameter is valid wh

s 180 180 Cell

None 15 15 Cell

s 60 60 Cell None

s 240 240 Cell

None 3 3 Cell

s 10 10 Cell None


None SIMINTERFREQRAT SIMINTERFREQRAT Cell None

None COEXIST_MEAS_THD_CHOI COEXIST_MEAS_THD_CHOI Cell None

None OFF OFF Cell None



None Automatic Automatic Cell None

None 5 5 Cell This paramter is valid only wh

None 5 5 Cell

None 1 1 Cell

None 4 4 Cell None

dB 0 0 Cell None

dB 2.5dB 2.5dB Cell None



s 5 5 Cell None

dB 2.5dB None Cell None


None 1 1 Cell None

None 1 1 Cell None

% 75 75 Cell None

% 0 0 Cell None





None PERIODICAL_REPORTING PERIODICAL_REPORTING Cell None

None D3 Cell None

ms D500 D500 Cell This parameter is valid when

dB/ dBm 4 4 Cell This parameter is valid when

dB/ dBm 4 4 Cell None



None 0 0 Cell None


ms D320 D320 Cell None


ms 0 0 Cell This parameter is valid when

dB -14 -14 Cell The value of this parameter m





The value of the parameter must satisfy the function below: "NFastSpdEst"*"TSlowSpdEst" >= "NSlowSpdEst"*"TFastSpdEst".The value of the parameter must satisfy the function below: "NFastSpdEst"*"TSlowSpdEst" >= "NSlowSpdEst"*"TFastSpdEst".

The value of the parameter must meet the following condition: "NFastSpdEst"*"TSlowSpdEst" >= "NSlowSpdEst"*"TFastSpdEst"The value of the parameter must meet the following condition: "NFastSpdEst"*"TSlowSpdEst" >= "NSlowSpdEst"*"TFastSpdEst"

This paramter is valid only when "AllocCodeMode" is set to Automatic and the value of this parameter must satisfy the following relationship: "HsPdschMaxCodeNum" >= "HsPdschMinCodeNum".This paramter is valid only when "AllocCodeMode" is set to Automatic and the value of this parameter must satisfy the following relationship: "HsPdschMaxCodeNum" >= "HsPdschMinCodeNum".

for high speed(120km/h):Range is D2~D4, the recommended value is D2;universal value:Range is D3~D6, the recommended value is D3.


dBm -95 -95 Cell The value of this parameter m


















s 60 60 Cell None

ms 1 1 Cell This parameter is valid only

None 4 4 Cell This parameter is valid when

ms 0 0 Cell None


None D3 Cell None

dB 6 6 Cell None



s 60 60 Cell None

ms 4 4 Cell None

None 1 1 Cell None




None AUTO AUTO Cell This parameter is valid when


None 0 0 Cell None




dB 4 4 Cell This parameter is valid when







None REQUIRED REQUIRED Cell None













dBm 16 16 Cell None


dBm 16 16 Cell None

dBm 16 16 Cell None







s 60 60 Cell None

s 0 0 Cell None

dBm 0 0 Cell None



None 3 3 Cell None

s 30 30 Cell None



dB 0 0 Cell None



dBm 21 21 Cell None

dBm 21 21 Cell None


s 60 60 Cell None

% 80 80 Cell This parameter is valid whe


ms 4 4 Cell None

None 1 1 Cell None

None 3 3 Cell None

s 30 30 Cell None




None CPICH_EC/NO CPICH_EC/NO Cell None







dB 6 6 Cell

dB 6 6 Cell

dB 6 6 Cell

dB 12 12 Cell

dB 12 12 Cell

dB 12 12 Cell



dB 0 0 Cell None

dB 0 0 Cell None

dB 8 8 Cell None

dB 8 8 Cell None

dB 8 8 Cell None

dB 8 8 Cell None

None 0 0 Cell None







The value of this parameter must be set based on the following formula: ("IntraRelThdFor1ACSVP" - "Hystfor1A" / 2) < ("IntraRelThdFor1BCSVP" + "Hystfor1B" / 2).The value of this parameter must be set based on the following formula: ("IntraRelThdFor1ACSNVP" - "Hystfor1A" / 2) < ("IntraRelThdFor1BCSNVP" + "Hystfor1B" / 2).The value of this parameter must be set based on the following formula: ("IntraRelThdFor1APS" - "Hystfor1A"/2) < ("IntraRelThdFor1BPS" + "Hystfor1B"/2)The value of this parameter must be set based on the following formula: ("IntraRelThdFor1ACSVP" - "Hystfor1A"/2) < ("IntraRelThdFor1BCSVP" + "Hystfor1B"/2)The value of this parameter must be set based on the following formula: ("IntraRelThdFor1ACSNVP" - "Hystfor1A"/2) < ("IntraRelThdFor1BCSNVP" + "Hystfor1B"/2)The value of this parameter must be set based on the following formula: ("IntraRelThdFor1APS" - "Hystfor1A"/2) < ("IntraRelThdFor1BPS" + "Hystfor1B"/2)


None 3 3 Cell None



dB 2 2 Cell None

% 90 90 Cell

% 30 30 Cell


% 55 55 Cell

% 45 45 Cell

% 70 70 Cell

% 60 60 Cell

% 95 95 Cell

% 85 85 Cell

% 95 95 Cell

% 85 85 Cell

ms 1000 1000 Cell None

% 70 70 Cell

% 50 50 Cell


None CodeAdj CodeAdj Cell None

None InterFreqLDHO InterFreqLDHO Cell None

None BERateRed BERateRed Cell None

None NoAct NoAct Cell None







None 1 1 Cell None

None 1 1 Cell None

None 3 3 Cell None

None 1 1 Cell None

None 1 1 Cell None

None 3 3 Cell None

None 1 1 Cell None

None InterFreqLDHO InterFreqLDHO Cell None

None BERateRed BERateRed Cell None







None 1 1 Cell None

None 1 1 Cell None

None 3 3 Cell None

None 1 1 Cell None

None 1 1 Cell None

None 3 3 Cell None

None 1 1 Cell None

% 20 20 Cell None

% 20 20 Cell None

bit/s 200000 200000 Cell None

bit/s 200000 200000 Cell None

None 1 1 Cell None

None SF8 SF8 Cell The value of this parameter mu

None 0 0 Cell None

None 1 1 Cell None

None SF8 SF8 Cell The value of this parameter must

The value of this parameter must satisfy the following relationship: "CellOverrunThd" >= "CellUnderrunThd".The value of this parameter must satisfy the following relationship: "CellOverrunThd" >= "CellUnderrunThd".

"UlOlcTrigThd" > "UlLdrTrigThd";"UlNonCtrlThdForOther"(See "ADD UCELLCAC") >= "UlLdrTrigThd"."UlLdrTrigThd" >= "UlLdrRelThd";"UlOlcRelThd" >= "UlLdrRelThd"."DlOlcTrigThd" > "DlLdrTrigThd";"DlOtherThd"(See "ADD UCELLCAC") >= "DlLdrTrigThd"."DlLdrTrigThd" >= "DlLdrRelThd";"DlOlcRelThd" >= "DlLdrRelThd"."UlOlcTrigThd" >= "UlOlcRelThd";"UlOlcTrigThd" >= "UlNonCtrlThdForHo"(See "ADD UCELLCAC")."UlOlcTrigThd" >= "UlOlcRelThd";"UlOlcRelThd" >= "UlLdrRelThd"."DlOlcTrigThd" > "DlLdrTrigThd";"DlOlcTrigThd" >= "DlCellTotalThd"."DlOlcTrigThd" >= "DlOlcRelThd";"DlOlcRelThd" >= "DlLdrRelThd".

The value of this parameter must satisfy the following relationship: "HsupAuRetrnsLdTrigThd" >= "HsupAuRetrnsLdRelThd"The value of this parameter must satisfy the following relationship: "HsupAuRetrnsLdTrigThd" >= "HsupAuRetrnsLdRelThd"

None SF8 SF8 Cell The value of this parameter mu

% 13 13 Cell None

None 0 0 Cell This parameter is valid on



None SF8 2SF4 Cell None

None BLINDHO BLINDHO Cell None


None None CSAMR_INTERFREQ:OFF, C Cell None



None D3 Cell None

None EVENT_TRIGGER EVENT_TRIGGER Cell None





dB 6 6 Cell None




None 1 1 Cell None

s 3 3 Cell None


None None CSAMR_INTERRAT:OFF Cell None




None EVENT_TRIGGER EVENT_TRIGGER Cell None





dB 0 0 Cell None


dBm 21 21 Cell None

None 1 1 Cell None

None ALL_USER ALL_USER Cell None

s 3 3 Cell None

s 30 30 Cell None



kbit/s None None RNC None

dB 10 10 Cell None

% 80 80 Cell

% 50 50 Cell

ms 35 35 Cell None

ms 10 10 Cell None


None PTM PTM RNC None

None 4 4 RNC None

None 3 3 RNC None











The value of this parameter must fulfill the following condition: "MtchMinPerc0" >= "MtchMinPerc15".The value of this parameter must fulfill the following condition: "MtchMinPerc0" >= "MtchMinPerc15".

dB -7 -7 Cell None



None None None Cell This parameter is consiste



None OFF OFF Cell If this parameter is set th

s 10 10 Cell If this parameter is set th

ms D3000 D3000 RNC If this parameter is set th

dBm -92 -92 Cell If this parameter is set th

dB -12 -12 Cell If this parameter is set th

None 10 10 Cell If this parameter is set th


s 6 6 Cell None





None REQUIRE REQUIRE Cell None

None INTER_FREQ_AND_INTER_ INTER_FREQ_AND_INTER_ Cell None

None None INTER_FREQ_AND_INTER_ Cell







dB 2 2 Cell None

dB 2 2 Cell None



None 1 1 Cell None



















None 3 3 Cell None

None 3 3 Cell None

None 3 3 Cell None

None 3 3 Cell None

% 68 68 Cell None

% 130 130 Cell None



None 0 0 Cell None

None 0 0 Cell None

None MBMS_REL MBMS_REL Cell None

This parameter is required when the "InterFreqInterRatMeasInd" parameter is set to INTER_FREQ, INTER_RAT or INTER_FREQ_AND_INTER_RAT.This parameter is not required when the "InterFreqInterRatMeasInd" parameter is set to NOT_REQUIRE.

None 1 1 Cell None

None 1 1 Cell None

dB 0 0 Cell None


% 45 45 Cell

% 70 70 Cell

% 5 5 Cell

dB -2 -2 Cell None

dB 2 2 Cell None

dB -4 -4 Cell None

dB -4 -4 Cell None

dB 4 4 Cell None

dB 4 4 Cell None


dB 5 5 Cell None

s 20 20 Cell None

s 20 20 Cell None

None CPICH_RSCP CPICH_RSCP Cell This parameter is valid wh

















ms 64 64 Cell None

None TEN_MSEC TEN_MSEC Cell None


min None None Cell None

ms 64 64 Cell None




ms 64 64 Cell None




ms 64 64 Cell None







% None 0 Cell

% None AMR:50;Other:0 Cell

None None DependOnNCell Cell

None None None Cell

None None None Cell

None None None Cell



"SpucHeavy" >= "SpucLight";"SpucLight" >= "SpucHyst"."SpucHeavy" >= "SpucLight";100 >= "SpucHeavy" + "SpucHyst"."SpucLight" >= "SpucHyst";100 >= "SpucHeavy" + "SpucHyst".

1. This parameter is valid when "RedirSwitch" is set to ONLY_TO_INTER_FREQUENCY or ONLY_TO_INTER_RAT. 2. If the value of this parameter is set in both the "SET UREDIRECTION" and "ADD UCELLREDIRECTION" commands, the value set in the "ADD UCELLREDIRECTION" command prevails.1. This parameter is valid when "RedirSwitch" is set to ONLY_TO_INTER_FREQUENCY or ONLY_TO_INTER_RAT. 2. If the value of this parameter is set in both the "SET UREDIRECTION" and "ADD UCELLREDIRECTION" commands, the value set in the "ADD UCELLREDIRECTION" command prevails.1. This parameter is valid when "RedirSwitch" is set to ONLY_TO_INTER_FREQUENCY or ONLY_TO_INTER_RAT. 2. If the value of this parameter is set in both the "SET UREDIRECTION" and "ADD UCELLREDIRECTION" commands, the value set in the "ADD UCELLREDIRECTION" command prevails.1. This parameter is valid when "RedirBandInd" is not set to BandIndNotUsed. 2. If the value of this parameter is set in both the "SET UREDIRECTION" and "ADD UCELLREDIRECTION" commands, the value set in the "ADD UCELLREDIRECTION" command prevails.2. This parameter is valid when "RedirBandInd" is set to BandIndNotUsed. 3. If the value of this parameter is set in both the "SET UREDIRECTION" and "ADD UCELLREDIRECTION" commands, the value set in the "ADD UCELLREDIRECTION" command prevails.1. This parameter is valid when "RedirSwitch" is set to ONLY_TO_INTER_FREQUENCY or ONLY_TO_INTER_RAT. 2. If the value of this parameter is set in both the "SET UREDIRECTION" and "ADD UCELLREDIRECTION" commands, the value set in the "ADD UCELLREDIRECTION" command prevails.

None None None RAB None

bit/s None None RAB None

dB None None Cell The value of this parameter mu

dB None None Cell The value of this parameter mu



None CPICH_ECNO CPICH_ECNO Cell None

dB 2 2 Cell None

dB 2 2 Cell None

dB 1 1 Cell This parameter is valid only

dB 1 1 Cell This parameter is valid only

s 1 1 Cell None



None 0 0 Cell None

None None None Cell This parameter is required wh

dBm 24 24 Cell None

dB 5 5 Cell None

dB 4 4 Cell None

dB 5 5 Cell None

dB 4 4 Cell None

dB 2 2 Cell None




None NOT_CONFIGURED NOT_CONFIGURED Cell None

s NotUsed NotUsed Cell This parameter is valid only

None 8 8 Cell This parameter is valid only

s NotUsed NotUsed Cell This parameter is valid only

dB 255 255 Cell None




s 255 255 Cell None

s 255 255 Cell None

None 4 4 Cell None

dB 2 2 Cell None

dB 2 2 Cell None

dB 1 1 Cell None






dB -7 -7 Cell None

dB -6 -6 Cell None


d 10 10 RNC This parameter is valid when



None WALKING_SPEED_AND_HOTWALKING_SPEED_AND_HOTCell None

None 0 0 RNC None

None D8 D8 RNC None

None 1 1 RNC None

None BasedOnUECap BasedOnUECap RNC None

None 0 0 RNC None


min 10 10 RNC T3212 needs to be set when

None ALLOWED ALLOWED RNC ATT needs to be set when "C

None MODE2 MODE2 RNC NMO needs to be set when "C

None 6 6 RNC DRXCycleLenCoef needs to b



None None OFF RNC When "CNDomainId" in "ADD


None 0 None RNC None



min None None RNC None
















s 180 180 RNC None

s 5 5 RNC None

s 2 2 RNC None

s 5 5 RNC None

ms D2000 D2000 RNC None

None 3 3 RNC None


None 3 3 RNC None

None D30 D30 RNC None

s D30 D30 RNC None

ms D40 D40 RNC None

None 1 1 RNC None

s 5 5 RNC None

s 6 6 RNC None

None D1 D1 RNC None

s 3 3 RNC None

None D50 D50 RNC None

s D0 D0 RNC T314 should be set greater t

s D0 D0 RNC T315 should be set greater t

None D1 D1 RNC None

s D30 D30 RNC None


None D1 D1 RNC None

s INVALID INVALID RNC None

None None CFG_DL_BLIND_DETECTIONRNC None

None None DRA_AQM_SWITCH:OFF, DRRNC

None None CS_AMRC_SWITCH:OFF, C RNC None

None None PC_CFG_ED_POWER_INTERPRNC None

None None CMP_IU_IMS_PROC_AS_NORRNC None

None None MAP_HSUPA_TTI_2MS_SWITRNC None

None None PS_BE_EXTRA_LOW_RATE_ARNC PS_RAB_DOWNSIZING_SWITCH

None None DR_RRC_DRD_SWITCH:ON, RNC None

None None HO_ALGO_HCS_SPEED_EST_RNC None

None None SRNSR_DSCR_IUR_RESRCERNC None

None None CMCF_DL_HLS_SWITCH:ON RNC None

None None RESERVED_SWITCH_0_BIT1:RNC None

None None RESERVED_SWITCH_1_BIT1:RNC None

None 0 0 RNC None

For BE service,DRA_HSDPA_STATE_TRANS_SWITCH and DRA_HSUPA_STATE_TRANS_SWITCH are valid when DRA_PS_BE_STATE_TRANS_SWITCH is set to ON;For RT service,DRA_HSDPA_STATE_TRANS_SWITCH and DRA_HSUPA_STATE_TRANS_SWITCH are valid when DRA_PS_NON_BE_STATE_TRANS_SWITCH is set to ON;

None 4294967295 4294967295 RNC None

None 0 0 RNC None



None None None Physical channel None





kbit/s D64 D64 RNC

kbit/s D64 D64 RNC

kbit/s D64 D64 RNC The low activity rate adjustme

None RATE_UP_AND_DOWN_ON_ RATE_UP_AND_DOWN_ON_ RNC None

None RATE_UP_AND_DOWN_ON_ RATE_UP_AND_DOWN_ON_ RNC None



None 3_Rates 3_Rates RNC None


None HAND_APPOINT HAND_APPOINT RNC The parameter is valid when "

kbit/s D128 D128 RNC



None HAND_APPOINT HAND_APPOINT RNC This parameter is valid when

kbit/s D128 D128 RNC

None 4 4 RNC None

s 60 60 RNC None

s 30 30 RNC None



ms 100 100 RNC None

None OFF None RNC None

chip 255 None RNC None

% 50 None RNC None

% 0 None RNC None


None TPE_DOWNLINK_SWITCH:OFTPE_DOWNLINK_SWITCH:OFRNC None

% 10 10 RNC None

None Qos Qos RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 0 0 RNC None

None 2 2 RNC If this parameter is set thr

None OFF OFF RNC If this parameter is set thr



None UserNumber UserNumber RNC None

None Only_To_Inter_Frequency Only_To_Inter_Frequency RNC None

% 10 10 RNC This parameter is valid only

When the value of "UlMidRateCalc" is HAND_APPOINT, the following relationship must be satisfied:"UlDcccRateThd" <= "UlMidRateThd".When the value of "DlMidRateCalc" is HAND_APPOINT, the following relationship must be satisfied:"DlDcccRateThd" <= "DlMidRateThd".

The parameter is valid when "UlMidRateCalc" in "SET UDCCC" is set to HAND_APPOINT, and the following relationship must be satisfied:"UlDcccRateThd" <= "UlMidRateThd".

This parameter is valid when the "DlMidRateCalc" in "SET UDCCC" is set to HAND_APPOINT, and the following relationship must be satisfied:"DlDcccRateThd" <= "DlMidRateThd".







None SF8 SF8 RNC If this parameter is set thr


None DependOnNCell DependOnNCell RNC If this parameter is set thr

None None None RNC If this parameter is set thr

None None None RNC

None None None RNC

None OFF ON RNC If this parameter is set thr

% 10 10 RNC None





None 10 10 RNC None

None 10 10 RNC None

None 25 25 RNC None

None 17 17 RNC None

None 15 15 RNC None

None 25 25 RNC None

None 20 20 RNC None

None 15 15 RNC None


ms None 100 RNC None

None None TEN_MSEC RNC None

ms None 500 RNC Valid when "ChoiceRptUnitFo

min None None RNC Valid when "ChoiceRptUnitForC

ms None 100 RNC None

None None TEN_MSEC RNC None

ms None 500 RNC Valid when "ChoiceRptUnitFo

min None None RNC Valid when "ChoiceRptUnitForC

None ON ON RNC None

None 1 1 RNC When "DsacAutoSwitch"is set t

None TURE 1 RNC When "DsacAutoSwitch"is set t

None 2 2 RNC When "DsacAutoSwitch"is set t

None None AC0-1&AC1-1&AC2-1&AC3-1 RNC When "DsacAutoSwitch"is set t

s 100 100 RNC When "DsacAutoSwitch"is set t

s 10 10 RNC When "DsacAutoSwitch"is set t



None ON ON RNC None

None None None RNC This parameter is valid when "D

slot D2 D2 RNC This parameter is valid when "D



None D1 D1 RNC This parameter is valid when "D


None ON ON RNC This parameter is valid when "D




None 1 1 RNC This parameter is valid when "D

ms D2 D2 RNC This parameter is valid when "D




None None RNC None

BandIndNotUsed [0-16383]BandIndNotUsed [0-16383]

RATE_5440KBPS: not selectedRATE_11480KBPS: not selected

None Gold Gold None None

dB 3 3 None This parameter must be smalle

dB 3 3 None

dB 4 4 None

dB 4 4 None This parameter must be greate



None None None Cell If this paramter is not zero, i

None None OFF Cell None



None None None Cell This paramter is valid only



None None None Cell This paramter is valid only w





None GSM900_DCS1800_BAND_U GSM900_DCS1800_BAND_U Cell None





None NC0 NC0 Cell None

None 0 0 Cell None

None 0 0 Cell None

dB 0 0 Cell None



None SINGLE_HOST SINGLE_HOST Cell None


None None None Cell This paramter is valid only










None 0 0 Cell None

dB None None Cell This paramter is valid only wh

None 0 0 Cell None

dBm None None Cell This paramter is valid only wh


dBm None None Cell This paramter is valid only wh

None 0 0 Cell None

dBm None None Cell This paramter is valid only w




None 0 0 Cell None

None STTD_not_Supported STTD_not_Supported Cell This paramter is valid only whe

None CP1_not_Supported CP1_not_Supported Cell This paramter is valid only whe

None OFFSET1 OFFSET1 Cell This paramter is valid only w

None None None Cell

None None None Cell

None None None Cell

None None None Cell

This parameter must be greater than or equal to "BeThd6A1";This parameter must be smaller than "BeThd6A2";This parameter must be smaller than or equal to "BeThd6B2";This parameter must be greater than "BeThd6B1";

This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.This paramter is set to CP1 only when "CP1SupInd" is set to CP1_Supported.This paramter is valid only when "TxDiversityInd" is set to TRUE.This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.This paramter is set to CP1 only when "CP1SupInd" is set to CP1_Supported.This paramter is valid only when "TxDiversityInd" is set to TRUE.This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.

None None None Cell


None NOT_FORBIDDEN NOT_FORBIDDEN Cell This parameter is valid wh

None Mode0 Mode0 Cell None

dB 0 0 Cell None


None 0 0 Cell None

None 0 0 Cell None





ms 35 35 Transport channel None


dB 10 10 Cell None

None D15 D15 Transport channel None

None D14 D14 Transport channel None


None CONVOLUTIONAL CONVOLUTIONAL Transport channel None

None D1/2 D1/2 Transport channel Configured only when the "C



kbit/s None CONVERSATIONAL:7; STREARNC None



bit None None Transport channel None

None None None Transport channel None

None None Transport channel None

None 1 1 Transport channel This paramter is valid only wh

None 2 2 Transport channel This paramter is valid only wh



dB 12 12 RNC None

dB -30 -30 RNC None

dB -200 -200 RNC None

dB -22 -22 RNC None

None ALGORITHM1 ALGORITHM1 RNC None

dB 1 1 RNC This parameter can only be se

dB STEPSIZE_1DB STEPSIZE_1DB RNC None

None SINGLE_TPC SINGLE_TPC RNC None

None ON ON RNC The code-resource-saving mod


None 6 6 RNC None

kbit/s D64 D64 RNC This parameter is valid onl

kbit/s D64 D64 RNC This parameter is valid onl

None NON-SCHEDULED NON-SCHEDULED RNC None

ms D50 D50 RNC None

ms D50 D50 RNC None



kbit/s D256 D256 RNC This parameter can be used

kbit/s D128 D128 RNC None


kbit/s D32 D32 RNC This parameter is required wh

None EDCH_TTI_10ms EDCH_TTI_10ms RNC None



dB 41 41 RNC If this parameter is set thr

ms 5000 5000 Cell If this parameter is set thr

byte 502 502 RNC None

byte 302 302 RNC RlcPduMaxSizeForUlL2Enhance

This paramter is valid only when "TxDiversityInd" is set to TRUE.This paramter is set to STTD only when "STTDSupInd" is set to STTD_Supported.

Configured to 1 when "Number of TFs" is 1;Configured to 0 when "Number of TFs" is 2 or 3

byte 42 42 RNC RlcPduMaxSizeForUlL2Enhance

byte 42 42 RNC None

None MIMO MIMO RNC None

frame D32 D32 RNC None

None None SRB_OVER_HSDPA:ON, SRB_RNC None

None SLOT_FORMAT_1 SLOT_FORMAT_1 RNC None

None EDCH_TTI_10ms EDCH_TTI_10ms RNC None

ms 5 5 RNC None

ms 5 5 RNC None

None SCHEDULED SCHEDULED RNC None

None SCHEDULED SCHEDULED RNC None

None DC_HSDPA DC_HSDPA RNC None

None 1 1 RAB None

None NOT_TRIGGER NOT_TRIGGER RAB None

None NOT_PRE_EMPTABLE NOT_PRE_EMPTABLE RAB None

None NOT_ALLOWED NOT_ALLOWED RAB None

None 5 5 RAB None

None EDCH_TTI_2ms EDCH_TTI_2ms RAB None

% 100 100 RNC None

None DCH DCH RNC None


None HSPA HSPA RNC None



None 0 0 RNC None

kbit/s D8 D8 RNC If this parameter is set th

kbit/s D8 D8 RNC If this parameter is set th





s 180 180 Cell

None 15 15 Cell

s 60 60 Cell None

s 240 240 Cell

None 3 3 Cell

s 10 10 Cell None

None MAY MAY RNC None

s 0 0 RNC None

None COEXIST_MEAS_THD_CHOI COEXIST_MEAS_THD_CHOI Cell None

None 3 3 RNC The value of this parameter

s 30 30 RNC None





None None None RNC "TbSizeIndex1" < "TbSizeIndex

None None None RNC This parameter is valid when t








None 3 3 RNC None

s 6 6 RNC None

None D1 D1 RNC None

None None None RNC This parameter is valid when



The value of the parameter must satisfy the function below: "NFastSpdEst"*"TSlowSpdEst" >= "NSlowSpdEst"*"TFastSpdEst".The value of the parameter must satisfy the function below: "NFastSpdEst"*"TSlowSpdEst" >= "NSlowSpdEst"*"TFastSpdEst".

The value of the parameter must meet the following condition: "NFastSpdEst"*"TSlowSpdEst" >= "NSlowSpdEst"*"TFastSpdEst"The value of the parameter must meet the following condition: "NFastSpdEst"*"TSlowSpdEst" >= "NSlowSpdEst"*"TFastSpdEst"

None OFF None RNC This parameter is valid when



None None None RNC The parameter must be less t

None None None RNC The parameter must be greate






None D3 Cell None






None 0 0 Cell None





























s 60 60 Cell None

ms 1 1 Cell This parameter is valid only


ms 0 0 Cell None

None D3 Cell None

dB 6 6 Cell None


dB -16 -16 RNC None

s 60 60 Cell None

ms 4 4 Cell None

None 1 1 Cell None





dB 0 0 Cell None



None 1 1 Cell None

dB 0 0 Cell This parameter is valid when "


None 0 0 Cell None



s D0 D0 Cell None



None 2 2 Cell None

None 0 0 Cell None

dBm -92 -92 Cell This parameter is valid only w

None 0 0 Cell None

None None None Cell This parameter is valid only w


None 0 0 Cell None

None 0 0 Cell None

None 0 0 Cell None

None 0 0 Cell None

dB -24 -24 Cell This paramter is valid only wh

dBm -58 -58 Cell This paramter is valid only wh



None AUTO AUTO Cell This parameter is valid when


None 0 0 Cell None
























dBm 16 16 Cell None

dBm 16 16 Cell None

dBm 16 16 Cell None







s 60 60 Cell None

s 0 0 Cell None

dBm 0 0 Cell None



None 3 3 Cell None

s 30 30 Cell None


dB 0 0 Cell None



dBm 21 21 Cell None

dBm 21 21 Cell None


s 60 60 Cell None


None ON ON RNC None



ms 4 4 Cell None

None 1 1 Cell None

None 3 3 Cell None

s 30 30 Cell None

None D3 D3 RNC None








dB 6 6 Cell

dB 6 6 Cell

dB 6 6 Cell

dB 12 12 Cell

dB 12 12 Cell

dB 12 12 Cell



dB 0 0 Cell None

dB 0 0 Cell None

dB 8 8 Cell None

dB 8 8 Cell None

dB 8 8 Cell None

dB 8 8 Cell None

None 0 0 Cell None







s 60 60 RNC None

None 3 3 RNC None

dB 2 2 RNC None

s 30 30 RNC None


None 3 3 Cell None



None D2 D2 RNC None




The value of this parameter must be set based on the following formula: ("IntraRelThdFor1ACSVP" - "Hystfor1A" / 2) < ("IntraRelThdFor1BCSVP" + "Hystfor1B" / 2).The value of this parameter must be set based on the following formula: ("IntraRelThdFor1ACSNVP" - "Hystfor1A" / 2) < ("IntraRelThdFor1BCSNVP" + "Hystfor1B" / 2).The value of this parameter must be set based on the following formula: ("IntraRelThdFor1APS" - "Hystfor1A"/2) < ("IntraRelThdFor1BPS" + "Hystfor1B"/2)The value of this parameter must be set based on the following formula: ("IntraRelThdFor1ACSVP" - "Hystfor1A"/2) < ("IntraRelThdFor1BCSVP" + "Hystfor1B"/2)The value of this parameter must be set based on the following formula: ("IntraRelThdFor1ACSNVP" - "Hystfor1A"/2) < ("IntraRelThdFor1BCSNVP" + "Hystfor1B"/2)The value of this parameter must be set based on the following formula: ("IntraRelThdFor1APS" - "Hystfor1A"/2) < ("IntraRelThdFor1BPS" + "Hystfor1B"/2)


dB 0 0 Cell None

None AFFECT AFFECT Cell None

None AFFECT AFFECT Cell None

None 1 1 Cell None



None 0 0 Cell None



s D0 D0 Cell None



None 0 0 Cell None

None None None Cell This parameter is valid only w

None 1 1 Cell None











None ON ON RNC None

None D6 D6 RNC None

% 60 60 RNC None


% 60 60 RNC None


% 60 60 RNC None


% 60 60 RNC None


% 60 60 RNC None


% 60 60 RNC None


% 40 40 RNC None


% 40 40 RNC None


% 40 40 RNC None




None None None RNC

None None None RNC

None None None RNC LAC needs to be set when "Q




None IUBLDR IUBLDR RNC "LdrFirstPri","LdrSecondPri","L

None CREDITLDR CREDITLDR RNC "LdrFirstPri","LdrSecondPri","L

None CODELDR CODELDR RNC "LdrFirstPri","LdrSecondPri","L

None UULDR UULDR RNC "LdrFirstPri","LdrSecondPri","L

None None RNC None

s 1800 1800 RNC

s 1800 1800 RNC

The value of this parameter must satisfy the following relationship:"PlmnValTagMax" > "PlmnValTagMin".The value of this parameter must satisfy the following relationship:"PlmnValTagMax" > "PlmnValTagMin".

LCG_CREDIT_LDR_SWITCH:disabled.LC_CREDIT_LDR_SWITCH:disabled. When "ChoiceRprtUnitForDlBasicMeas" is set to TEN_MSEC,the value of this parameter must satisfy the following relationship:

"IntraFreqLdbPeriodTimerLen" x 1000 > 2 x "TenMsecForDlBasicMeas".When "ChoiceRprtUnitForDlBasicMeas" is set to TEN_MSEC,the value of this parameter must satisfy the following relationship:"PucPeriodTimerLen" x 1000 > 2 x "TenMsecForDlBasicMeas".

s 10 10 RNC

ms 3000 3000 RNC

None D6 D6 RNC None

None TEN_MSEC TEN_MSEC RNC None

ms 100 20 RNC

min 20 None RNC

None D6 D6 RNC None


ms 100 20 RNC

min 20 None RNC


None 6 32 RNC None

None 6 32 RNC None

None 5 5 RNC None

None 5 5 RNC None

None 5 5 RNC None

None 5 5 RNC None

None 5 5 RNC None

None 5 5 RNC None


ms 100 100 RNC This parameter is valid only

min 10 None RNC This parameter is valid only

None 5 5 RNC None




None 5 5 RNC None

None 3 3 RNC None

None D3 D1 RNC None



min 20 None RNC This parameter is valid only w


None D3 D1 RNC None








None 5 5 RNC None


min 2 2 None This parameter is used with

None None None MBMS Service None





dB None None RNC None

% 80 80 Cell

% 50 50 Cell










"LdrPeriodTimerLen" x 1000 > 2 x "TenMsecForUlBasicMeas";"LdrPeriodTimerLen" x 1000 > 2 x "TenMsecForDlBasicMeas"."OlcPeriodTimerLen" > 2 x "TenMsecForUlBasicMeas";"OlcPeriodTimerLen" > 2 x "TenMsecForDlBasicMeas".

"TenMsecForUlBasicMeas" < "LdrPeriodTimerLen" * 1000/2 (See "SET ULDCPERIOD" and "SET USATLDCPERIOD");"TenMsecForUlBasicMeas" < "OlcPeriodTimerLen" /2 (See "SET ULDCPERIOD" and "SET USATLDCPERIOD") ."MinForUlBasicMeas" x 60 < "LdrPeriodTimerLen"/2;"MinForUlBasicMeas" x 60000 < "OlcPeriodTimerLen"/2 .

"TenMsecForDlBasicMeas" < "LdrPeriodTimerLen" x 1000/2 (See "SET ULDCPERIOD" and "SET USATLDCPERIOD");"TenMsecForDlBasicMeas" < "OlcPeriodTimerLen"/2 (See "SET ULDCPERIOD" and "SET USATLDCPERIOD")."MinForDlBasicMeas" x 60 < "LdrPeriodTimerLen"/2;"MinForDlBasicMeas" x 60000 < "OlcPeriodTimerLen"/2 .

The value of this parameter must fulfill the following condition: "MtchMinPerc0" >= "MtchMinPerc15".The value of this parameter must fulfill the following condition: "MtchMinPerc0" >= "MtchMinPerc15".





None OFF OFF RNC This parameter is valid olny






s 3 None RNC None


None OFF None RNC This paramter is valid only



None 0 0 None None

None 50 50 None None

None 7 7 RNC

None 3 3 RNC

None 1 1 RNC

None OFF OFF Cell If this parameter is set th

s 10 10 Cell If this parameter is set th

ms D3000 D3000 RNC If this parameter is set th

dBm -92 -92 Cell If this parameter is set th

dB -12 -12 Cell If this parameter is set th

None 10 10 Cell If this parameter is set th

s 6 6 Cell None





None None None None This parameter is valid when "T

dB -30 -30 RNC None



None 0 0 RNC None

s None None NodeB None

min None None NodeB None


None OFF OFF Subsystem None



None ATM_TRANS ATM_TRANS NodeB

ms 10 10 NodeB None

None SINGLEHOST SINGLEHOST NodeB None



None None DEDICATED NodeB None



None 3840 3840 NodeB None

None 3840 3840 NodeB None

None MBR MBR NodeB None


None 0 0 NodeB None

None 0 0 NodeB None



None BERateRed BERateRed NodeB None

None NoAct NoAct NodeB None


The relationship of parameters must be set as follows:"Mcch Mod Period Coefficient" > "DRX cycle length coefficient" in "ADD UCNDOMAIN".The relationship of parameters must be set as follows:"Mcch Access Period Coefficient" > "Mcch Repetition Period Coefficient".The relationship of parameters must be set as follows:"Mcch Access Period Coefficient" > "Mcch Repetition Period Coefficient".

3. If the NodeB is configured with adjacent nodes through "ADD ADJNODE", the transmission type cannot be modified.4. If the NodeB is configured with the electrical serial number through "ADD UNODEBESN" and the transmission type is supposed to be modified to ATM transmission, the transmission type cannot be modified.




None 1 1 NodeB None

None 1 1 NodeB None

None 3 3 NodeB None

None 1 1 NodeB None

None 3 3 NodeB None

None 1 1 NodeB None

None BERateRed BERateRed NodeB None






None 1 1 NodeB None

None 1 1 NodeB None

None 3 3 NodeB None

None 1 1 NodeB None

None 3 3 NodeB None

None 1 1 NodeB None

None SF8 SF8 NodeB None

None SF8 SF8 NodeB None

None SF8 2SF4 NodeB None


None 1 1 NodeB None

None 1 1 NodeB None







None None CS_SHO_SWITCH:ON, HSPA RNC None





None NO NO RNC None


None CORRM_SRNSR_PSBE_REL CORRM_SRNSR_PSBE_REL RNC None












None NO NO RNC None

None NO NO RNC None

None YES YES RNC None


None 255 255 RNC When "MOCNSupport" in "SET

None None COMM_MOCN_NRI_GLOBAL_RNC When "MOCNSupport" in "SET


None None None RNC This parameter forms an SPI ma


None None None RNC This parameter is required wh




% None None RNC None


None High High RNC None





None Medium Medium RNC None





None Low Low RNC None










kbit/s D64 D64 RNC

kbit/s D64 D64 RNC





kbit/s 0 0 RNC None


None Gold None RNC None





None Silver None RNC None





None Copper None RNC None





None ARP ARP RNC None

None NONE NONE RNC None


None 3 3 Cell None


None None 8 Cell None

None 3 3 Cell None


ms 35 35 Cell None

ms 10 10 Cell None



For the BE users with the same "TrafficClass", "THPClass" and "BearType" values, make sure: "UlGBR" of GOLD users ("UserPriority" is set to GOLD) >= "UlGBR" of SILVER users ("UserPriority" is set to SILVER) >= "UlGBR" of COPPER users ("UserPriority" is set to COPPER).For the BE users with the same "TrafficClass", "THPClass" and "BearType" values, make sure: "DlGBR" of GOLD users ("UserPriority" is set to GOLD) >= "DlGBR" of SILVER users ("UserPriority" is set to SILVER) >= "DlGBR" of COPPER users ("UserPriority" is set to COPPER).

None 3 3 Cell None



None None Cell None

None 1 1 Cell None


None 2 2 Cell None

dBm 330 330 Physical channel


dBm 313 313 Cell



dBm 313 313 Cell




None V36 V36 Physical channel None



dB -7 -7 Cell None







None REHOSTRIGHNOW REHOSTRIGHNOW RNC None

s 0 0 RNC None

s None None RNC None



None None SIGNATURE0, SIGNATURE1, Physical channel None

None None SELECT ALL Physical channel None


None 4 None Cell None

None ASC0 ASC0 Cell The ASCs are configured th








None 4 4 Cell None


None 0 0 Cell "Available Signature Start Ind

None 7 7 Cell "Available Signature End Inde


None None None Physical channel This parameter is valid when


None 4 4 Cell None

None None SIGNATURE0, SIGNATURE1, Physical channel None

None None SELECT ALL Physical channel None



dB 2 2 Cell None

bit BIT2 BIT2 Physical channel None


None 4 4 Cell None



Configured to 1 when TFsNumber is 1;Configured to 0 when TFsNumber is 2.

"Min Transmit Power of PCPICH" <= "PCPICH Transmit Power"2. To modify the "PCPICH Transmit Power", the intra-frequency load balance algorithm of the cell should be disabled. You can use "LST UCELLALGOSWITCH" to query the switch and use "MOD UCELLALGOSWITCH" to modify the switch.

The value of this parameter must satisfy the following relationship:"Min Transmit Power of PCPICH" <= "Max Transmit Power of PCPICH".

The value of this parameter must satisfy the following relationship:"Min Transmit Power of PCPICH" <= "Max Transmit Power of PCPICH".





None 4 4 Cell None


dB None In signaling transmission modePhysical channel None

None None None Physical channel Either "Gain Factor BetaC" or

None 15 15 Physical channel Either "Gain Factor BetaC" or




dB 2 2 Cell None



None 0 0 Cell None


s 20 20 RNC

s 20 20 RNC

s 20 20 RNC

s 20 20 RNC

s 20 20 RNC

s 20 20 RNC

s 20 20 RNC

s 20 20 RNC

s 360 360 RNC None

s 20 20 RNC

s 20 20 RNC

s 4 4 RNC None

s 10 10 RNC None

s 3 3 RNC None

s 3 3 RNC None

s 3 3 RNC None

s 3 3 RNC None

byte D8 D8 RNC



ms 110 110 RNC None

bit/s 10 10 RNC None

None 1 1 RNC None

None 1 1 RNC None

s 10 10 RNC None

byte D8 D8 RNC

ms D80 D80 RNC None


byte D16 D16 RNC

ms D0 D0 RNC None


None NO NO RNC None

None NO NO RNC None

None None None RNC

None None None RNC

None None None RNC

ms 3000 3000 RNC Valid when "BEQosPerform" is

None RateDegrade RateDegrade RNC

None None None RNC

None None None RNC

None SINGLE SINGLE RNC Valid when "BEQosPerform" is

None YES YES RNC Valid when "BEQosPerform" is

None NO NO RNC Valid when "BEQosPerform" is

None NO NO RNC Valid when "AMRQosPerform" i

1. For the detection timers that do not need to configure conversational services, the related T1 and T2 must be 0 at the same time.2. For the detection timers that need to configure conversational services, the related T1 and T2 must not be 0 at the same time.1. For the detection timers that do not need to configure conversational services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure conversational services, the related T1 and T2 must not be 0 at the same time.1. For the detection timers that do not need to configure streaming services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure streaming services, the related T1 and T2 must not be 0 at the same time.1. For the detection timers that do not need to configure streaming services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure streaming services, the related T1 and T2 must not be 0 at the same time.1. For the detection timers that do not need to configure interactive services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure interactive services, the related T1 and T2 must not be 0 at the same time.1. For the detection timers that do not need to configure interactive services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure interactive services, the related T1 and T2 must not be 0 at the same time.1. For the detection timers that do not need to configure background services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure background services, the related T1 and T2 must not be 0 at the same time.1. For the detection timers that do not need to configure background services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure background services, the related T1 and T2 must not be 0 at the same time.

1. For the detection timers that do not need to configure IMS signaling services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure IMS signaling services, the related T1 and T2 must not be 0 at the same time.1. For the detection timers that do not need to configure IMS signaling services, the related T1 and T2 must be 0 at the same time. 2. For the detection timers that need to configure IMS signaling services, the related T1 and T2 must not be 0 at the same time.

The following relationship must be satisfied:"PTTDH2FTvmThd" < "PTTF2DHTvmThd".

The following relationship must be satisfied:"PTTF2PTvmThd" < "PTTF2DHTvmThd"

"PTTDH2FTvmThd" < "PTTF2DHTvmThd";"PTTF2PTvmThd" < "PTTF2DHTvmThd"

"BeUlAct2" and "BeUlAct3" must be None when "BeUlAct1" is set to None;"BeUlAct2" and "BeUlAct3" must not be equal with "BeUlAct1" when "BeUlAct1" is not set to None."BeUlAct3" must be None when "BeUlAct2" is set to None;"BeUlAct3" must not be equal with "BeUlAct2" and "BeUlAct1" when "BeUlAct2" is not set to None."BeUlAct3" must not be equal with "BeUlAct1" when "BeUlAct1" is not set to None."BeUlAct3" must not be equal with "BeUlAct2" when "BeUlAct2" is not set to None.

"BeDlAct2" and "BeDlAct3" must be None when "BeDlAct1" is set to None;"BeDlAct2" and "BeDlAct3" must not be equal with "BeDlAct1" when "BeDlAct1" is not set to None."BeDlAct3" must be None when "BeDlAct2" is set to None;"BeDlAct3" must not be equal with "BeDlAct2" and "BeDlAct1" when "BeDlAct2" is not set to None."BeDlAct3" must not be equal with "BeDlAct1" when "BeDlAct1" is not set to None."BeDlAct3" must not be equal with "BeDlAct2" when "BeDlAct2" is not set to None.

ms 3000 3000 RNC Valid when "AMRQosPerform" i




ms 3000 3000 RNC Valid when "AMRQosPerform" i









None NO NO RNC This parameter is valid when t

None NO NO RNC This parameter is valid when t

None YES YES RNC This parameter is valid when

None YES YES RNC This parameter is valid when

None NO NO RNC Valid when "BEQosPerform" is

s 20 20 RNC Valid when "BEQosPerform" is

dB 5 5 Cell None

s 20 20 Cell None

s 20 20 Cell None

None CPICH_RSCP CPICH_RSCP Cell This parameter is valid wh
















ms 64 64 Cell None




ms 64 64 Cell None




ms 64 64 Cell None




ms 64 64 Cell None






None ON ON RNC None


None 5 5 RNC None

ms 50 50 RNC

s 5 5 RNC

The value of this parameter must be set to meet the following conditions: 100 x "MaxQueueTimeLen" > "PollTimerLen".The value of this parameter must be set to meet the following conditions: 100 x "MaxQueueTimeLen" > "PollTimerLen".

None ON ON RNC None




None None None RNC

None None None RNC


None 4 4 Cell None

None 1 1 Cell None

None 1 1 Cell None

frame 0 0 Cell

frame 0 0 Cell

None 8 8 Cell None


None 1 1 Cell None





dB 5000 5000 RNC [Maximum Ec/N0 Up Step] is no

dB 3000 3000 RNC [Maximum Ec/N0 Down Step] is

dB 500 500 RNC

% 10 10 RNC None

ms 100 100 RNC None

dB 49 49 RNC [Maximum Ec/N0 Value] is lar

dB 21 21 RNC [Maximum Ec/N0 Value] is lar



% 0 0 RNC This parameter is valid wh

% None AMR:50; Other:0 RNC This parameter is valid wh

None DependOnNCell DependOnNCell RNC This parameter is valid wh

None None None RNC This parameter is valid when "

None None None RNC

None None None RNC This parameter is valid wh


None None None Cell

None None None Cell

None None None Cell


min None None RNC None



None OFF OFF RNC After running the "ADD UCBSAD


None ENGLISH ENGLISH RNC None

s 300 300 RNC None

None 0 0 RNC None


s 20 20 RNC This paramter is valid only w

s 180 180 RNC This paramter is valid only w



% 70 70 RNC None

None 3 3 RNC This parameter defines an offs

None 4 4 RNC None

None 3 3 RNC None

None 2 2 RNC The value of this parameter

s 6 6 RNC The value of this parameter

s 10 10 RNC None


None ON ON RNC None

The value of this parameter must satisfy the following relationship:"PlmnValTagMax" > "PlmnValTagMin".The value of this parameter must satisfy the following relationship:"PlmnValTagMax" > "PlmnValTagMin".

The value of this parameter must be set to meet the following conditions:"Random Back-off Upper Limit" >= "Random Back-off Lower Limit".The value of this parameter must be set to meet the following conditions:"Random Back-off Upper Limit" >= "Random Back-off Lower Limit".

1. [Maximum Ec/N0 Up Step] is not smaller than [Ec/N0 Adjustment Step].2. [Maximum Ec/N0 Down Step] is not smaller than [Ec/N0 Adjustment Step].

1. This parameter is valid when "RedirUARFCNUplinkInd" is set to TRUE. 2. This parameter is valid when "RedirBandInd" is set to BandIndNotUsed.

The value of this parameter must satisfy the following relationship:"DLOVSFSF">"DLCODENO".The value of this parameter must satisfy the following relationship:"DLOVSFSF">"DLCODENO".The value of this parameter must satisfy the following relationship:"DLOVSFSF">="DLCODENO".

None ON ON RNC None




s 1 1 RNC None

None 5 5 RNC None

None 2 2 RNC None

None IUCS_IUPS IUCS_IUPS RNC None



None None None RNC When the "RrcCause" paramet










None 4 4 RNC None

None 3 3 RNC None




s 1800 1800 RNC

s 1800 1800 RNC

s 10 10 RNC

ms 3000 3000 RNC

None D6 D6 RNC None


ms 100 20 RNC

min 20 None RNC

None D6 D6 RNC None


ms 100 20 RNC

min 20 None RNC


None 6 32 RNC None

None 6 32 RNC None

None 5 5 RNC None

None 5 5 RNC None

None 5 5 RNC None

None 5 5 RNC None

None 5 5 RNC None

None 5 5 RNC None




None 5 5 RNC None




None 5 5 RNC None

None 3 3 RNC None

None D3 D1 RNC None





None D3 D1 RNC None

When "ChoiceRprtUnitForDlBasicMeas" is set to TEN_MSEC,the value of this parameter must satisfy the following relationship:"IntraFreqLdbPeriodTimerLen" x 1000 > 2 x "TenMsecForDlBasicMeas".When "ChoiceRprtUnitForDlBasicMeas" is set to TEN_MSEC,the value of this parameter must satisfy the following relationship:"PucPeriodTimerLen" x 1000 > 2 x "TenMsecForDlBasicMeas"."LdrPeriodTimerLen" x 1000 > 2 x "TenMsecForUlBasicMeas";"LdrPeriodTimerLen" x 1000 > 2 x "TenMsecForDlBasicMeas"."OlcPeriodTimerLen" > 2 x "TenMsecForUlBasicMeas";"OlcPeriodTimerLen" > 2 x "TenMsecForDlBasicMeas".

"TenMsecForUlBasicMeas" < "LdrPeriodTimerLen" * 1000/2 (See "SET ULDCPERIOD" and "SET USATLDCPERIOD");"TenMsecForUlBasicMeas" < "OlcPeriodTimerLen" /2 (See "SET ULDCPERIOD" and "SET USATLDCPERIOD") ."MinForUlBasicMeas" x 60 < "LdrPeriodTimerLen"/2;"MinForUlBasicMeas" x 60000 < "OlcPeriodTimerLen"/2 .

"TenMsecForDlBasicMeas" < "LdrPeriodTimerLen" x 1000/2 (See "SET ULDCPERIOD" and "SET USATLDCPERIOD");"TenMsecForDlBasicMeas" < "OlcPeriodTimerLen"/2 (See "SET ULDCPERIOD" and "SET USATLDCPERIOD")."MinForDlBasicMeas" x 60 < "LdrPeriodTimerLen"/2;"MinForDlBasicMeas" x 60000 < "OlcPeriodTimerLen"/2 .










chip 50 50 Physical channel None



bit BIT4 BIT4 Physical channel None


None None EXISTS Physical channel This parameter is valid only wh

None COMMON COMMON Cell None









None None All RNC None

None UE_BASED UE_BASED RNC None

None NODELIVERY NODELIVERY RNC None



None 16 16 RNC None

None UE_ASSISTED UE_ASSISTED RNC None

None UE_ASSISTED UE_ASSISTED RNC None



None DRD DRD RNC None

None None R5_POSDATA_SWITCH RNC None


dB 12 12 RNC None

dB 18 18 RNC None



dB -20 -20 RNC None

None RNC_CENTRIC RNC_CENTRIC RNC None


None MIXED_ENVIRONMENT MIXED_ENVIRONMENT Cell This parameter is valid when

None ACTIVE ACTIVE Cell This parameter is valid when




None 1 1 RNC None

None 1 1 RNC None

None 1 1 RNC None

None 1 1 RNC None

None 1 1 RNC None


% None None RNC None

None 313 313 None "SqiGoodThres" > "SqiBadThr

None 200 200 None "SqiGoodThres" > "SqiBadThr

s 60 60 RNC None

ms 400 400 RNC This parameter is valid on

s 5 5 RNC This parameter is valid on

s 60 60 RNC None

s 30 30 RNC This parameter is valid on

None NRT NRT RNC None




ms 5000 5000 RNC None


ms 350 350 RNC None




ms 5000 5000 RNC The retransmit mechanism is us







ms 11000 11000 RNC None









ms 10000 10000 RNC None

ms 45000 45000 RNC None

ms 20000 20000 RNC None


ms 15000 15000 RNC None



ms 10000 10000 RNC None


min 10 10 RNC None




s 300 300 RNC None

s 300 300 RNC None

s 4 4 RNC None




















bit/s None None RAB None

None None None RAB This parameter must not be

None None None RAB There must be one parameter se

None None None RAB There must be one parameter se

None None HO_TO_GSM_SHOULD_NOT RAB This parameter is valid wh


None None SILENT RAB None




byte D1024 D1024 RAB The value of this parameter mu

byte None None RAB The value of this parameter mu

ms None None RAB None

ms D4000 D4000 RAB None



None 2 2 RAB None

None 16 16 RAB None

None 2 2 RAB None

None 16 16 RAB None

None 2 2 RAB None

None 16 16 RAB None



None D1 D1 RAB This parameter is required

bit 336 336 RAB This parameter is associated

bit None None RAB This parameter is associated







None D1 D1 RAB This parameter is required

bit 336 336 RAB This parameter is associated












ms D50 D50 RAB This parameter is required





None None None RAB This parameter is required whe

dB None None RAB This parameter is required

None None None RAB This parameter is required

None None None RAB

None None None RAB


dB None None RNC

dB None None RNC

1. The value of this parameter must be smaller than that of "MaxEdchRetransNum".2. The value of this parameter must be smaller than that of "EdchTargetLargeRetransNum".1. If "TrchType" is set to TRCH_EDCH_2MS or TRCH_EDCH_10MS, this parameter is required and must be set to a value smaller than or equal to "MaxEdchRetransNum".2. The value of this parameter must be greater than that of "EdchTargetLittleRetransNum".

The following relationship must be satisfied:"UlThd6A1" <= "UlThd6B1"."UlThd6A2" <= "UlThd6B2";"UlThd6A2" > "UlThd6B1".

dB None None RNC

dB None None RNC

None None 500 RNC

None None 280 RNC


dB None None RNC

dB None None RNC







None None None RAB This parameter is required whe

ms 5000 5000 RAB This parameter is required


None 1 1 RAB This parameter is required

% 160 160 RAB This parameter is required



% 80 80 RAB This parameter is required




None None UEA0-1; UEA1-1 RNC None

None 9 9 RNC None

byte D64 D64 RNC





byte D1024 D1024 RNC

ms D0 D0 RNC None

byte D64 D64 RNC




ms D0 D0 RNC None

byte D64 D64 RNC




ms D0 D0 RNC None

ms 30 30 RNC None

kbit/s 8 8 RNC None

None 2 2 RNC None

None 4 4 RNC None

byte D1024 D1024 RNC None

ms D0 D0 RNC None


ms D0 D0 RNC None


ms D0 D0 RNC None

byte D1024 D1024 RNC None

ms D0 D0 RNC None


ms D0 D0 RNC None


ms D0 D0 RNC None


ms D0 D0 RNC None

"UlThd6A1" <= "UlThd6B1";"UlThd6A2" > "UlThd6B1".The following relationship must be satisfied:"UlThd6A2" <= "UlThd6B2".The following relationship must be satisfied:"StaBlkNum5A" >= "Thd5A".The following relationship must be satisfied:"StaBlkNum5A" >= "Thd5A".

The following relationship must be satisfied:"ThdEa" <= "ThdEb".The following relationship must be satisfied:"ThdEa" <= "ThdEb".

"D2F2PTvmThd" < "F2DTvmThd";"D2F2PTvmThd" < "BeEFach2DTvmThd".

The following relationship must be satisfied:"D2F2PTvmThd" < "F2DTvmThd".

"BeH2FTvmThd" < "BeEFach2CpcTvmThd";"BeH2FTvmThd" < "BeF2CpcTvmThd".

The following relationship must be satisfied:"BeH2FTvmThd" < "BeF2HTvmThd".

"RtDH2FTvmThd" < "RtEFach2CpcTvmThd";"RtDH2FTvmThd" < "RtF2CpcTvmThd".

The following relationship must be satisfied:"RtDH2FTvmThd" < "RtF2DHTvmThd".

The following relationship must be satisfied:"BeH2FTvmThd" < "BeF2CpcTvmThd".

The following relationship must be satisfied:"RtDH2FTvmThd" < "RtF2CpcTvmThd".

The following relationship must be satisfied:"D2F2PTvmThd" < "BeEFach2DTvmThd".

The following relationship must be satisfied:"BeH2FTvmThd" < "BeEFach2HTvmThd".

The following relationship must be satisfied:"RtDH2FTvmThd" < "RtEFach2DHTvmThd".


ms D0 D0 RNC None


ms D0 D0 RNC None

byte D3k D3k RNC

s 180 180 RNC None

s 5 5 RNC None

s 65535 65535 RNC None

s 5 5 RNC None

s 180 180 RNC None

s 5 5 RNC None

s 5 5 RNC None

s 180 180 RNC None

s 5 5 RNC None

s 5 5 RNC None

s 180 180 RNC None

s 5 5 RNC None

s 180 180 RNC None

None UIA1-1 UIA1-1 RNC None







kbit/s D64 D64 RNC

kbit/s D64 D64 RNC




kbit/s 0 0 RNC None

kbit/s D3.4 D3.4 RNC None

kbit/s D3.4 D3.4 RNC None




















None ARP ARP RNC None

None NONE NONE RNC None


None ALGORITHM_OFF ALGORITHM_OFF RNC None

None None PRIORITY2-1&PRIORITY3-1& RNC None

The following relationship must be satisfied:"BeH2FTvmThd" < "BeEFach2CpcTvmThd".

The following relationship must be satisfied:"RtDH2FTvmThd" < "RtEFach2CpcTvmThd".

"RtDH2FTvmThd" < "FastDormancyF2DHTvmThd";"BeH2FTvmThd" < "FastDormancyF2DHTvmThd".

For the BE users with the same "TrafficClass", "THPClass" and "BearType" values, make sure: "UlGBR" of GOLD users ("UserPriority" is set to GOLD) >= "UlGBR" of SILVER users ("UserPriority" is set to SILVER) >= "UlGBR" of COPPER users ("UserPriority" is set to COPPER).For the BE users with the same "TrafficClass", "THPClass" and "BearType" values, make sure: "DlGBR" of GOLD users ("UserPriority" is set to GOLD) >= "DlGBR" of SILVER users ("UserPriority" is set to SILVER) >= "DlGBR" of COPPER users ("UserPriority" is set to COPPER).

Service Interrupted After Modification Interruption Scope Interruption Duration(Min) Caution Validation of Modification

No (No impact on the UE in id Not involved Not involved None The parameter modification ha

No (No impact on the UE in id Not involved Not involved The parameter cannot be modifNot involved

No (No impact on the UE in id Not involved Not involved The parameter cannot be modifNot involved

No (No impact on the UE in id Not involved Not Involved None The parameter modification ha

Not involved Not involved Not involved None The parameter modification ha






No (No impact on the UE in id Not involved Not involved None The cell should be activated af

No (No impact on the UE in id Not involved Not involved The parameter modification ha The parameter modification ha

Not involved Not involved Not involved This parameter cannot be modiNot involved




No (Impact on the UE in idle Not involved Not involved None The parameter modification ha















































No (No impact on the UE in id Not involved Not involved None Not involved





No (No impact on the UE in id Not involved Not involved If the TFO/TrFO is not configu Not involved









No (No impact on the UE in id Not involved Not involved If the TFO/TrFO is not configu Not involved

























Not involved Not involved Not involved Not involved Not involved



















Yes Cell Interruption until the cell is act The cell should be deactivated The cell should be activated af





















Not involved Not involved Not involved The cell should be deactivated The cell should be activated af























No (No impact on the UE in id Not involved Not involved The parameter modification ha The parameter modification ha








































































No (No impact on the UE in id Not involved Not involved If the value is too high, the po The parameter modification ha































No (No impact on the UE in id Not involved Not involved Not involved The parameter modification ha


























































































































No (No impact on the UE in id Not involved Not Involved None The cell should be activated af












No (No impact on the UE in id Not involved Not involved None The cell should be activated af




































































































































































































































































































































































































No (No impact on the UE in id Not involved Not involved Not involved The parameter modification ha


























































Not involved Not involved Not involved None Not involved

No (Impact on the UE in idle Not involved Not involved Not involved Not involved

No (Impact on the UE in idle Not involved Not involved Not involved Not involved


No (Impact on the UE in idle Not involved Not involved None Not involved

























No (No impact on the UE in id Not involved Not involved If the value of the parameter i Not involved



No (No impact on the UE in id Not involved Not involved T302 broadcast in the SIB1 = Not involved













No (No impact on the UE in id Not involved Not involved The time value of T314 and T3 Not involved

No (No impact on the UE in id Not involved Not involved The time value of T314 and T3 Not involved





No (No impact on the UE in id Not involved Not Involved None Not involved



























































































Not involved Not involved Not involved Before this switch is on, ensur The parameter modification ha














































No (No impact on the UE in id Not involved Not involved The parameter modification ha Not involved




























Not involved Not involved Not involved This parameter cannot be modiThe parameter modification ha




























Not involved Not involved Not involved The cell should be deactivated The cell should be activated af
































































































































Not involved Not involved Not involved Not involved




























































All the switches have multiple choices. SELECT ALL means turning on all the switches; CLEAR ALL means turning off all the switches; GRAYED ALL means keeping the original states of all the switches. The parameter modification has no impact on the equipment.When the parameter RNCAP_IMSI_HO_SWITCH is set to 1, the SNA_RESTRICTION_SWITCH check box under the Handover algorithm switch parameter in the MML command "SET UCORRMALGOSWITCH" cannot be selected at the same time.


















































































































































No (No impact on the UE in id Not involved Not involved This parameter cannot be modiNot involved

















































































No (No impact on the UE in id Not involved Not involved This parameter is used with Not involved

































































































































































































































































Not involved Not involved Not involved This parameter cannot be modiThe parameter modification ha







































































































































































Not involved Not involved Not involved After modification, the RNC sh The RNC should be reset to val

































No (No impact on the UE in id Not involved Not involved Not involved











Not involved Not involved Not Involved This parameter is not modified. Not involved

Not involved Not involved Not Involved This parameter is not modified. Not involved





































All the switches have multiple choices. SELECT ALL means turning on all the switches; CLEAR ALL means turning off all the switches; GRAYED ALL means keeping the original states of all the switches. If the SYS_INFO_UPDATE_FOR_IU_RST switch is turned off, the BARRED_CELL_FOR_CSDOMAIN_RST switch is invalid.The parameter modification has no impact on the equipment.When the parameter RNCAP_IMSI_HO_SWITCH is set to 1, the SNA_RESTRICTION_SWITCH check box under the Handover algorithm switch parameter in the MML command "SET UCORRMALGOSWITCH" cannot be selected at the same time.




























































































































































































































































No (No impact on the UE in id Not involved Not involved When this parameter is set to Not involved


















































Impact on Radio Network Performance

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

The larger the value of the parameter, the lower the probability of selecting neighboring cells. The smaller the value the parameter, the higher the probability of doing so.

None

None

None

If this cell is the neighboring cell of the serving cell for the blind handover, it is considered as the target cell for the blind handover and inter-system DRD. If the coverage of the WCDMA cell is not completely included in that of the GSM cell, the blind handover or inter-system DRD may fail, thus leading to call drops.

The RNC hands over the UE preferentially to the neighboring cell with a high priority. It is recommended that the GSM cell that includes the entire WCDMA cell be assigned with a higher priority. Otherwise, the UE may be handed over to the GSM cell that does not include the entire WCDMA cell, thus leading to call drops, handover failures, or DRD failures.

A greater value of this parameter indicates that the inter-RAT DRD is less possibly triggered. A smaller value of this parameter indicates that the inter-RAT DRD is more possibly triggered, however, with a low success rate.

None

None

When the algorithm of neighboring cell combination is enabled, the total number of the neighboring cells connected through links may exceed 32 if more than one link is in the active link set. RNC consider this parameter as a condition for neighboring cell selection. That is, a neighboring cell with a high priority is preferentially selected. If a neighboring cell is not configured with the priority identifier, the lowest priority is assigned to this cell. If a low priority is improperly assigned to the neighboring cell to be measured, the handover to this cell may fail. This leads to call drops.


None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

A greater value of this parameter indicates that this GSM cell is more possibly selected as the target cell for the handover. If the value of this parameter is too great, a GSM cell that fails to provide qualified services may be selected as the target cell for the handover, thus leading to call drops.A smaller value of this parameter indicates that this GSM cell is less possibly selected as the target cell for the handover. If the value of this parameter is too small, the MS may fail to be handed over to the GSM cell timely, thus leading to call drops.

None

None

If the value is set too small, the UEs on the cell edge cannot receive the acquisition indication properly. This problem affects the coverage of the downlink common channel and furthermore the coverage of the cell. If the value is set too great, it causes interference to other channels, occupies the downlink transmit power, and affects the cell capacity.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are greater possibilities of meeting the requirement for lowering the AMR speech rate. Thus, it is easier to lower the AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are less possibilities of meeting the requirement for stopping AMR speech rate adjustment. Thus, it is easier to lower the AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are less possibilities of meeting the requirement for raising the AMR speech rate. Thus, it is more difficult to raise the AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are greater possibilities of meeting the requirement for stopping AMR speech rate increase. Thus, it is more difficult to raise the AMR speech rate.

None

None

None

None

None

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are greater possibilities of meeting the requirement for lowering the wideband AMR speech rate. Thus, it is easier to lower the wideband AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are less possibilities of meeting the requirement for stopping wideband AMR speech rate adjustment. Thus, it is easier to lower the wideband AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are less possibilities of meeting the requirement for raising the wideband AMR speech rate. Thus, it is more difficult to raise the wideband AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are greater possibilities of meeting the requirement for stopping wideband AMR speech rate increase. Thus, it is more difficult to raise the wideband AMR speech rate.

None

None

None

None

None

None

None

If the value is set too small, the UEs on the cell edge cannot receive the system messages properly. This problem affects the coverage of the downlink common channel and furthermore the coverage of the cell. If the value is set too great, it causes interference to other channels, occupies the downlink transmit power, and affects the cell capacity.

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

It is configured in the network planning.

None

None

None

None

None

None

None

None

The higher the value is, the stricter the synchronization process becomes, and the more difficult the synchronization occurs. The lower the value is, the easier the synchronization occurs. If the link quality is poor, a simple synchronization requirement leads to waste of the UE power and increase of uplink interference.

If the value is excessively high, the link out-of-sync decision is likely to happen. If the value is excessively low, out-of-sync is not likely to happen. But if the link quality is poor, it may result in a waste of the UE power and increased uplink interference.

If the value is excessively low, there are few chances for the radio link to get synchronized. If the value is excessively high, the radio link failure process is probably delayed, and the downlink interference increases.

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

The larger the sum, the higher the handover priority of the neighboring cell. The smaller the sum, the lower the handover priority of the neighboring cell. Usually it is configured to 0. The larger the parameter, the easier of the handover to the neighboring cell. The smaller the parameter, the harder the handover to the neighboring cell.

None

None

None

None

None

None

None

None

None

None

None

None

None

If the maximum transmit power of the PCPICH is configured too large, the cell capacity will be decreased because a lot of system resources will be occupied and the interference with the downlink traffic channels will be increased.

If the value is excessively low, UEs at the edge of cells fail in network searching, resulting in influence on coverage of the downlink common channel. This finally affects the cell coverage. If the value is excessively high, the power resources are wasted, and other channels are interfered seriously, thus the cell capacity is influenced.


None


None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

If the value is too high the system load after admission may be over large, which impacts system stability and leads to system congestion. If the value is too low, the possibility of user rejects may increase, resulting in waste in idle resources.



If the value is too high the system load after admission may be over large, which impacts system stability and leads to system congestion. If the value is too low, the possibility of user rejects may increase, resulting in waste in idle resources and the failure to achieving network planning target.

If the value is too high the system load after admission may be over large, which impacts system stability and leads to system congestion. If the value is too low, the possibility of user rejects may increase, resulting in waste in idle resource and the failure to achieving the network planning target.






If the value is too high, power resources are wasted, which impacts system capacity. If the value is too low, resources can be fully used and coverage may be impacted in case of insufficient resources.

None

If the value is too high, the system load after admission may be over large, which impacts system stability and leads to system congestion. If the value is too low, the possibility of user rejects may increase, resulting in waste in idle resources.


If this value is too high, the possibility of rejecting HSUPA schedule services increases, which impacts access success rate. If the value is too low, too many HSUPA schedule users may be admitted, which impacts the admitted users and results in overload and system congestion.


If this value is too high, the possibility of rejecting HSUPA schedule services increases, which impacts access success rate. If the value is too low, too many HSUPA schedule users may be admitted, which impacts the admitted users and results in overload and system congestionRecommended.

None

If the value is too high, admission requirement of the HSDPA streaming service is strict, which improves the service quality of the HSDPA streaming service but also may lead to HSDPA capacity waste. If the value is too low, admission requirement of the HSDPA streaming service is loose, which allows more HSDPA streaming services but QoS of the HSDPA streaming service cannot be guaranteed.

If the value is too high, admission requirement of the HSDPA BE service is strict, which improves the service quality of the HSDPA BE service but also may lead to HSDPA capacity waste. If the value is too low, admission requirement of the HSDPA BE service is loose, which allows more BE services but QoS of the HSDPA BE service cannot be guaranteed.

If the value is too low, the cell HSDPA capacity may be reduces, leading to waste in HSDPA resources. If the value is too high, HSDPA services may be congested.

The larger the value of this parameter is, the wider the coverage of the corresponding services will be. When the uplink coverage is too large, the uplink coverage and downlink coverage of the service can become unbalanced. If the values of these parameters are too small, the uplink coverage will probably be smaller than the downlink coverage of the service.




None

None

None

None

None

If the value is too high, HSUPA services may be congested. If the value is too low, the cell HSDPA capacity may be reduces, leading to waste in HSUPA resources.

None

None

None

None

None

None

The backer position the value is in {SF4,SF8,SF16,SF32,SF64,SF128,SF256,SFOFF}, the less code and credit resources reserved for handover UEs. The possibility of rejecting handover UE admissions increases and performance of UEs cannot be guaranteed. The more frontal position the value is, the more the possibility of rejecting new UEs is and some idle resources are wasted.


None

None

None

None

None

With the RTWP anti-interference switch enabled, if this parameter is set to a small value, the number of equivalent users will be easy to be judged as overlarge. That is, the probability of accepting an admission request becomes low, and OLC operations will be performed. In this case, cell capacity may not be fully used. If this parameter is set to a great value, the number of equivalent users will be hard to be judged as overlarge. That is, the probability of accepting an admission request becomes high, and OLC operations may be cancelled. In this case, cell load may become heavy.

If this parameter is set to a too great value, the guaranteed power of HSDPA users is high, and the power available for DCH users is low. As a result, the capacity of the cell decreases.

If this parameter is set to a too great value, the guaranteed power of HSUPA users is high, and the power available for DCH users is low. As a result, the capacity of the cell decreases.

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

None

UE will start intra-frequency and inter-frequency measurements easily when this parameter is large. So that better cells can be selected.

UE will start inter-system measurements easily when this parameter is large. So that better cells can be selected.

None

None

None

None

None

None

If this parameter is set to a very great value, the fast-speed handover may not be triggered. That is, the UE cannot be handed over to a cell with large coverage. This leads to the decrease in the number of soft handovers. If this parameter is set to a very small value, the fast-speed handover may be triggered easily. This may lead to the great increase in the load of the cell with large coverage.

With a smaller value of this parameter, a more reliable result can be obtained from UE slow speed decision. In this case, however, higher load may be carried by the CPU.

If this parameter is set to a very great value, the slow-speed handover may not be triggered. That is, the UE cannot be handed over to a cell with small coverage. Under this situation, the load of a cell with large coverage cannot be reduced.

If this parameter is set too large, the RNC may mistakenly determine that ping-pong handover to the best cell occurs. If this parameter is set too small, ping-pong handover cannot be prevented. Thus, it is recommended that this parameter be set according to the cell radius.

None

When the value of this parameter is changed, the event 2D/2F thresholds are changed accordingly. As a result, inter-frequency or inter-RAT handover conditions are affected.

When this switch is set to ON, the number of inter-RAT handovers for CS services may increase. When this switch is set to OFF, the number of inter-RAT handovers for CS services may decrease.

When this switch is set to ON, the number of inter-RAT handovers for PS services may increase. When this switch is set to OFF, the number of inter-RAT handovers for PS services may decrease.

None

At the early stage of network deployment, or when the traffic model of subscribers in a cell is not known, the parameter can be set to Automatic to have the HSDPA channel codes automatically allocated. If the traffic model of subscribers in a cell is stable and known, the parameter can be set to Manual to select the static allocation mode. Manual allocation leads to restriction of HSDPA code resource or leaves HSDPA code resource idle.

If the parameter value is set too low, the HSDPA code resources will be limited and the HSDPA performance is affected. If the parameter value is set too high, the HSDPA code resources are wasted, thus increasing the admission rejection rate for R99 services.

None

None

In the scenarios like outdoor macro cells with power restricted, it is less likely to schedule multiple subscribers simultaneously, so two HS-SCCHs are configured. In the scenarios like indoor pico with code restricted, it is more likely to schedule multiple subscribers simultaneously, so four HS-SCCHs are configured. If excessive HS-SCCHs are configured, the code resource is wasted. If insufficient HS-SCCHs are configured, the HS-PDSCH code resource or power resource is wasted. Both affect the cell throughput rate.

If the parameter value is set too low (negative value), the total HSPA power will be too low, thus impacting the throughput of HSDPA subscribers at the border of a cell.

If the parameter value is unreasonable, the CQI in some scenarios will exceed the range of 0 to 30. As a result, the NodeB MAC-hs cannot schedule the subscriber in time or cannot schedule multiple subscribers with the difference of channel conditions.

None

None

None

None

None

If the parameter value is set too high, the downlink codes are wasted. If the parameter value is set too low, the uplink throughput of the HSUPA is restricted.


If the parameter value is set too low, there is a risk that the cell throughput will be too low. If the parameter value is set too high, there is a risk for high interference.

If the parameter value is set too low, the power of the non-serving radio link will be low and the data rate on non-serving E-DCH will be reduced, thus impacting the transport rate of the UE in soft handover state. If the parameter value is too high, the non-serving RL cannot send RG to the UE even in overloaded situation.

None

None

None

None

None

If this parameter is set to a greater value, the effect of smoothing signals and the ability of anti-fast-fading improve. However, the ability of tracing the signal change becomes low, and call drops are likely to occur because handover is not performed in time. If this parameter is set to a smaller value, the number of unnecessary hard handovers and ping-pong handovers increases.

None

None

None

None

None

If this parameter is set to a greater value, the quality of the current frequency is higher in the same condition. In this case, inter-frequency handover is not likely to be triggered. If this parameter is set to a smaller value, the quality of the current frequency is lower in the same condition. In this case, inter-frequency handover is likely to be triggered. Generally, this parameter is set to 0 or 1. Whether the handover is easy or difficult to trigger is not decided by setting this parameter.

None

None

None

None

None

None

None

None

None

1. Reducing the number of soft handovers for a slowly-moving UE2. Handing a slowly-moving UE to a cell with large coverage, thus lowering the load of a cell with small coverage.

If this parameter is set to a large value, the quick handover may be triggered easily. This may lead to the great increase in the load of the cell with a large coverage.

If this parameter is set to a very great value, the UE can be easily handed over to a cell with small coverage. This may lead to the increase in the number of soft handovers.

If only inter-frequency neighboring cells exist, inter-frequency handovers may be triggered. If only inter-RAT neighboring cells exist, inter-RAT handovers may be triggered. If both inter-frequency and inter-RAT neighboring cells exist and this parameter is set to SIMINTERFREQRAT(inter-frequency and inter-RAT handover), both inter-frequency measurement and inter-RAT measurement can be performed.The compressed mode is used in many scenarios. Therefore, user experience may be affected.

None

None

None

None

None

None

None

After handover, the inter-frequency measurement may be started again, and thus ping-pong handover may perform. In order to prevent ping-pong handover, this parameter can be set greater than the start threshold for event 2D or equal to the threshold of event 2F.






None

None

None

None

None

None

Setting this parameter to a smaller value reduces the impact of long duration of compression mode on the serving cell. In this case, however, the compression mode may be disabled before the inter-frequency handover of the UE. For the coverage-based inter-frequency handover, call drops may occur.

If this parameter is set to a smaller value, handover attempts increase when the inter-frequency handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced, thus lowering the probability of call drops. More handover re-attempts, however, cause the increase in the RNC load.

None

None

None


None

None

None


None

None

None

If this parameter is set to a larger value, call drops are likely to occur because handover is not performed in time. If this parameter is set to a smaller value, unnecessary inter-RAT handovers may increase.

If the parameter value does not match the network environment (for example, the Ec/No measurement quantity is used for event 3A measurement in areas with low RSCP), inter-RAT handover may fail.

If this parameter is set to a greater value, the effect of smoothing signals and the ability of anti-fast-fading improve. However, the ability of tracing the signal change becomes low, and call drops are likely to occur because handover is not performed in time. If this parameter is set to a smaller value, the number of unnecessary Inter-RAT handovers increases.

If this parameter is set to a greater value, the estimated general quality of the current frequency in the same condition is higher. In this case, inter-RAT handover is unlikely to be triggered. If this parameter is set to a smaller value, the estimated general quality of the current frequency in the same condition is lower. In this case, inter-frequency handover is likely to be triggered. When the parameter value is set to 0, the quality of the best cell in an active set is regarded as the general quality of an active set.

The setting of this parameter has impact on the Uu signaling traffic. If the period is too short and the reporting frequency is too high, the RNC may have high load in processing signaling. If the period is too long, the network cannot detect the signal changes in time, which may delay the inter-RAT handover and thus cause call drops.

The value of this parameter is associated with slow fading. If this parameter is set to a larger value, the cell of another RAT where the UE needs to be handed over to must be of good quality. Therefore, the criteria for triggering the inter-RAT handover decision is hard to be fulfilled, and the call drop rate will increase. If this parameter is set to a smaller value, ping-pong handover is likely to occur.


The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect decision becomes low; however, the handover algorithm becomes slow in responding to signal change.

The value of this parameter is associated with slow fading. If this parameter is set to a greater value, the probability of incorrect handover decision becomes low; however, the handover algorithm becomes slow in responding to signal change. This leads to the decrease in the number of handovers.

If the parameter is set to a larger value, handover is unlikely to be triggered. However, call drops may increase as the parameter value increases.



If the parameter is set to "NOT_REQUIRED", handovers are likely to be triggered, but the handover reliability is lower than the situation the parameter is set to "REQUIRED".

The setting of this parameter affects the proportion of the UEs in compressed mode in a cell and the success rate of the hard handover. If this parameter is set to a greater value, hard handover is likely to be triggered, but ping-pong handover may occur. If this parameter is set to a smaller value, hard handover is unlikely to be triggered, but call drops may occur.

The setting of this parameter affects the proportion of the UEs in compressed mode in a cell and the success rate of the hard handover. If the threshold for event 2F is set to a larger value, more UEs will enter compressed mode, thus affecting user experience. If the threshold for event 2F is set to a smaller value, it becomes difficult for UEs to trigger inter-RAT measurement, thus decreasing handovers.






If the threshold for event 2F is set to a larger value, more UEs will enter compressed mode, thus affecting user experience. If the threshold for event 2F is set to a smaller value, it becomes difficult for UEs to trigger inter-RAT measurement, thus decreasing handovers.





The setting of this parameter affects number of hard handovers. If this parameter is set to a smaller value, hard handover is likely to be triggered, but ping-pong handover may occur. If this parameter is set to a greater value, hard handover is unlikely to be triggered, but call drops may occur.

The advantage of the periodical reporting mode is that it can be used for repeated handover re-attempts on the same cell when the handover fails, and that the subsequent algorithms can be flexibly developed. In addition, the UE needs not to be informed when the parameters are changed. The drawback of periodical reporting is that it requires large amount of signaling and increases the load on the air interface and for signaling processing.The advantage of event-triggered reporting is that the signaling transmission and processing load are saved. Comparing the signal quality between intra-frequency and inter-frequency handovers, the ping-pong effect in handover is prevented to some extent. The drawback of event-triggered reporting is that the event is reported only once and cannot be changed to periodical reporting.

The setting of this parameter should consider the radio conditions (slow fading), actual handover distance, and moving speed of the UE.If this parameter is set to a greater value, the probability of ping-pong reporting or wrong decision is lower, but the event may not be triggered in time.The setting of this parameter should consider the radio conditions (slow fading), actual handover distance, and moving speed of the UE.If this parameter is set to a greater value, the probability of ping-pong reporting or wrong decision is lower, but the event may not be triggered in time.



If this parameter is set to a larger value, event 3A is likely to be triggered. However, handover is likely to be triggered when the frequency quality in the current system is acceptable for the UE if the value of this parameter is set too large.






If the parameter is set to a smaller value, the UE cannot finish inter-RAT handover. If the parameter is set to a larger value, the user experience is affected.

If this parameter is set to a larger value, the UEs handed out from the 2G network are unlikely to be handed back to the 2G network. If this parameter is set to a smaller value, the effect of penalty is unobvious, causing ping-pong handover between 2G and 3G networks.

If this parameter is set to a larger value, the UEs handed over from the 2G network are unlikely to be handed over back to the 2G network. If this parameter is set to a smaller value, the risk for ping-pong handovers increases.

If this parameter is set to a smaller value, handover attempts increase when the inter-RAT handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced, thus lowering the probability of call drops. More handover re-attempts, however, cause the increase in the RNC load.

If this parameter is set to a larger value, handover attempts increase when the inter-RAT handover fails. In this case, the UE can be quickly handed over to the target cell whose load is reduced, thus lowering the probability of call drops. More handover re-attempts, however, cause the increase in the RNC load.

If this parameter is set to a smaller value, many users will not be handed over to the 2G network in time. If this parameter is set to a larger value, the penalty effect is unobvious.

If this parameter is set to a larger value, many users will not be handed over to the 2G network in time. If this parameter is set to a smaller value, the penalty effect is unobvious.

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If this parameter is set to a greater value, the effect of smoothing signals and the ability of anti-fast-fading improve. However, the ability of tracing the signal change becomes low, and call drops are likely to occur because handover is not performed in time. If this parameter is set to a smaller value, the number of unnecessary soft handovers and ping-pong handovers increases.

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If this parameter is set to a greater value, the coverage area where a soft handover can be performed reduces, for an incoming UE. However, the coverage area for an outgoing UE enlarges. If the UEs which enter the area are equal to those who leave the area, the ratio of SHOs remains unchanged. If this parameter is set to a greater value, the ability of resisting signal fluctuation improves and the number of ping-pong handovers decreases. However, the handover algorithm becomes slow in responding to the signal change.




If this parameter is set to a too great value, the handover algorithm becomes slow in responding to the signal change, and thus call drops may occur. If this parameter is set to a too small value, the handover algorithm is more affected by signal fluctuation, and thus unnecessary inter-frequency blind handovers may be triggered.


If this parameter is set to a greater value, the thresholds for triggering soft handover for events 1A and 1B are greater under the same conditions. In this case, the probability for adding a cell to the active set decreases, and that for removing a cell from the active set increases. If this parameter is set to a smaller value, the probability for adding a cell to the active set increases, and that for removing a cell from the active set decreases.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.In a micro cell, the time-to-trigger parameter for different events should be shortened as required. If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.In a micro cell, the time-to-trigger parameter for different events should be shortened as required. If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.

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If the value is too great, the cell pilot may change fiercely, which is easy to lead to user call drops. If the value is too small, the cell pilot may change smoothly. However, the response speed of the cell breathing algorithm is decreased, impacting the algorithm performance.

When the cell breathing algorithm is activated, if the value is too small, the physical coverage of the cell is limited so as to avoid cell capacity waste. If the value is too great, the physical coverage is expanded and interference over other cells is increased.


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The lower the LDR trigger and release thresholds are, the easier the system enters the preliminary congestion status, the harder it is released from this status, the easier the LDR action is triggered, and the more likely the users are affected. But, the admission success rate becomes higher since the resources are preserved. The carrier shall make a trade-off between these factors.




The lower the OLC trigger threshold is, the easier the system is in the overload status. An excessively low value of the OLC trigger threshold is very detrimental to the system performance. The lower the OLC release threshold is, the harder the system releases the overload.




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The higher the parameter is, the higher the service rate of the user in handover is, and the more obviously the cell load is decreased. However, high value of the parameter gives rise to the fluctuation and congestion of the target cell load. The lower the parameter is, the smaller amplitude of the load decreases as a result of the inter-frequency load handover, and the easier it is to maintain the stability of the target cell load.


The lower the parameter value is, the bigger the scope for selecting the MBMS services is, the more cell load is decreased, the more effect there is on the MBMS service. At the same time, the cell overload is significantly decreased while the impact on the MBMS services becomes bigger. The higher the parameter value is, the smaller the scope for selecting the MBMS services is, the less cell load is decreased, the more effect there is on the MBMS services, and the quality of services with high priority, however, can be guaranteed.

The lower the code resource LDR trigger threshold is set, the easier the downlink code resource enters the initial congestion status, the easier the LDR action is triggered, and the easier the subscriber perception is affected. On the other hand, a lower code resource LDR trigger threshold causes a higher admission success rate because more code resource is reserved.

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The lower the parameter value is, the easier the credit enters the congestion status, the easier the LDR action is triggered, and the easier the user experience is affected. A lower code resource LDR trigger threshold, however, causes a higher admission success rate because the resource is reserved. The parameter should be set based on the operator's requirement.


The smaller this parameter value, the easier it is to find the qualified target cell for blind handover. Excessively small values of the parameter, however makes the target cell easily enters the congestion status. The higher the parameter value, the more difficult it is for the inter-frequency blind handover occurs, and the easier it is to guarantee the stability of the target cell.

When the value is TRUE, users can be selected for inter-frequency handover during code resource congestion, which can easily release code congestion and use multi-frequency resources. However, the risk of inter-frequency blink handover increases.

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Setting the value of this parameter smaller can reduce the long-time impact of the compressed mode on the serving cell. In this case, however, the compressed mode might be stopped earlier and as a result the UE cannot trigger inter-frequency handover. If the parameter is set to a great value, the services may not be set up successfully.

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A larger value of this parameter leads to a larger guaranteed coverage area of the MBMS service in the case of heavy load in the cell.


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A larger value of this parameter leads to a higher probability of using PTP transmission on the network. Power control is available for PTP transmission, and thus the power consumption in PTP mode is lower than that in PTM mode. In PTP mode, however, the quantities of code, CE, and other transmission resources increase with the number of users. Therefore, the setting of this parameter should take into consideration various resources, especially bottleneck resources of operators. The value of this parameter should not be too large.

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Presupposition for analysis: 8SF4 < 7SF4 < ... < SF128 < SF256If the parameter is set too big, the TTI switchove cannot be triggered until there is insufficient credit remaining. In this case, the TTI switchover is triggered too late. If the parameter is set too small, the TTI switchover may be triggered even when there is sufficient credit remaining.

the higher of the success ratio of the MBMS paging. However, more cell power resources are occupied.

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Setting the value of this parameter smaller can reduce the long-time impact of the compressed mode on the serving cell. In this case, however, the compressed mode might be stopped earlier and as a result the UE cannot trigger inter-frequency handover.

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The larger the value of the parameter is, the more easily event 2B, inter-frequency handover based on Qos, and event 3A, inter-RAT handover based on Qos, can be triggered, and thus the more timely the handover to the target cell can be performed.

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The longer the trigger time is, the greater the effect of ignoring sudden changes is. Yet the response to changes of the measured value becomes slower.













The greater the filtering coefficient is, the greater the smoothing effect is and the less the random interference is. Yet the response to changes of the measured value becomes slower.


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If the value of this parameter is set too high, delay is caused.

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If the value of this parameter is set to a too great value, the downlink transmit power on a single radio link is too high. Thus, the downlink capacity is affected. If the value of this parameter is set to a too small value, the coverage area of services is decreased, and the risk of call drops is increased.

If the value of this parameter is set to a too small value, the value range of the downlink transmit power becomes large. Thus, the possibility of downlink transmit power drift is increased. If the value of this parameter is set to a too great value, the downlink transmit power on a single radio link may exceeds the required transmit power, thus wasting the downlink power.

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If the value is set too small, the UEs on the cell edge cannot receive the paging indication properly. This problem may cause a misoperation of reading the PCH, waste the battery of the UE, affect the coverage of the downlink common channel, and finally affect the cell coverage. If the value is too great, it causes interference to other channels, occupies the downlink transmit power, and affects the cell capacity.


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When this parameter is set to TRUE, the inter-RAT cell supports PS handovers, reducing the delay of inter-RAT PS handovers.

The larger the value of the parameter is, the easier it is to be handed over to the GSM network. The smaller the value of the parameter is, the harder it is to be handed over to the GSM network.

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The larger the value of the parameter is, the more difficult it is for the UE to camp on the cell. The smaller the value of the parameter is, the easier it is for the UE to camp on the cell. But if the value is excessively small, it is possible that the UE cannot receive the system messages carried by PCCPCH.When this parameter is not set to any value, the UE adopts the corresponding value of the current serving cell, added through the ADD UCELLSELRESEL command. Generally, this parameter is not set to any value.


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If MaxFachPower is set excessively low, a UE positioned at the cell edge may fail to receive the services and signaling carried over the FACH, in a correct way. This will impact the downlink common channel coverage and thus the cell coverage.If MaxFachPower is set excessively high, other channels will be interfered and more downlink power resources will be occupied. This will consequently impact the cell capacity.

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If this parameter is set to a greater value, the probability for selecting the neighboring cell as the target cell reduces. If this parameter is set to a smaller value, the probability for selecting the neighboring cell as the target cell increases.


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If this parameter is set to a greater value, the probability of selecting the neighboring cell becomes low. If this parameter is set to a smaller value, the probability of selecting the neighboring cell becomes high.








































The setting of this parameter should consider the radio conditions (slow fading), actual handover distance, and moving speed of the UE.If this parameter is set to a greater value, the probability of ping-pong reporting or wrong decision is lower, but the event may not be triggered in time.The setting of this parameter should consider the radio conditions (slow fading), actual handover distance, and moving speed of the UE.If this parameter is set to a greater value, the probability of ping-pong reporting or wrong decision is lower, but the event may not be triggered in time.






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If this parameter is set to a greater value, the thresholds for triggering soft handover for events 1A and 1B are greater under the same conditions. In this case, the probability for adding a cell to the active set decreases, and that for removing a cell from the active set increases. If this parameter is set to a smaller value, the probability for adding a cell to the active set increases, and that for removing a cell from the active set decreases.

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If this parameter is set to a smaller value, the interval between intra-frequency measurement reports is shorter, that is, the intra-frequency measurement takes a shorter period; however, the measurement results are more affected by signal changes. This may cause incorrect handovers. If this parameter is set to a greater value, the interval between intra-frequency measurement reports is longer, and the measurement results are less affected by signal changes. This may increase the success rate of blind handovers. In this case, however, the intra-frequency measurement takes a longer period of time, and the handover may fail to be triggered timely.

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If this parameter is set to a greater value, the effect of smoothing signals and the ability of anti-fast-fading improve; however, the ability of tracing the signal change becomes low and call drops are likely to occur because handover is not performed in time. If this parameter is set to a smaller value, the number of unnecessary soft handovers and ping-pong handovers increases.Note that this parameter has great impact on the overall performance of the handover. Therefore, set this parameter with caution.

In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.In a micro cell, the time-to-trigger parameter for different events should be shortened as required. If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.In a micro cell, the time-to-trigger parameter for different events should be shortened as required. If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.

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When this parameter is set to "ON", the inter-frequency missing neighboring cells can be measured. The extra measurement may prolong the measurement period and affect the timely handover.


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Presupposition for analysis: 8SF4 < 7SF4 < ... < SF128 < SF256If the parameter is set too big, the TTI switchove cannot be triggered until there is insufficient credit remaining. In this case, the TTI switchover is triggered too late. If the parameter is set too small, the TTI switchover may be triggered even when there is sufficient credit remaining.

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If the value is set too small, the UEs on the cell edge cannot receive the paging message properly. This problem affects the coverage of the downlink common channel and furthermore the coverage of the cell. If the value is set too great, it causes interference to other channels, occupies the downlink transmit power, and affects the cell capacity.

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If MinPCPICHPower is excessively small, the cell coverage is affected.

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If MinPCPICHPower is excessively small, the cell coverage is affected.

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If the value of Max preamble retransmission is too small, the preamble power may fail to ramp to the required value. This may result in UE access failure. If it is too large, the UE will repeatedly increase the power and make access attempts, which may result in interference to other UEs.

If the value of Power ramp step is too large, the access procedure will be shortened, but it is more likely to cause power waste. If it is too small, the access procedure will be extended in time, but transmit power resources will be saved. This parameter must be set carefully. In addition, the higher the parameter value is, the smaller impact "Constant Value for Calculating Initial TX Power" has on the network performance.

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If the value is excessively low, the uplink interference may increase, and the uplink capacity may be affected. If the value is excessively high, coverage may be affected.

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If the value of this parameter is too low, whether the UE is in the stable low activity state cannot be determined. If the value of this parameter is too high, the dedicated channel resources are wasted. This parameter should be set on the basis of the PTT service model.




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If the value of this parameter is too high, congestion may occur over the common channel.

If the value of this parameter is too high, the 4A event reporting will be delayed. This may result in congestion over the common channel.

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The longer the UL AMRC timer is, the less frequently the AMRC mode is adjusted. In addition, the response to measurement reports becomes slower accordingly.

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If the value of this parameter is set too high, delay is caused.

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If the parameter value is excessively low, the UE access success rate may be reduced. If the parameter value is excessively high, the UE probably spends a long time attempting repeatedly to access, which increases the uplink interference.

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If this parameter is set to ON, pre-emption is triggered when PTM streaming bearer admission fails. That is, a lower-priority MBMS bearer or a non-MBMS bearer is released. Thus, the ongoing service is disrupted and call drop even occurs.

If this parameter is set to ON, a PTM streaming bearer might be pre-empted by an MBMS bearer of a higher priority or a non-MBMS bearer in the case of congestion. Thus, the MBMS service is disrupted, which has a relatively great impact because the PTM bearer serves more than one user.

If this parameter is set to ON, a PTM non-streaming bearer might be pre-empted by an MBMS bearer of a higher priority or a non-MBMS bearer in the case of congestion. Thus, the MBMS service is disrupted, which has a relatively great impact because the PTM bearer serves more than one user.

It is a waste of uplink resources if the uplink bandwidth of an MBMS service in PTP mode is high. Therefore, it is recommended the default value be used.

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The greater the value of this parameter is, the more easily the event 1A is triggered.

The lower the value of this parameter is, the more easily the event 1B is triggered.

The greater the value of this parameter is, the less probable the incorrect decision is. Yet the response of the event to the change of measured signals becomes slower accordingly.


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If this parameter is set to a smaller value, ping-pong relocations may occur, thus affecting network performance. If this parameter is set to a greater value, relocations may hardly occur, thus causing call drops.

Setting this parameter to a small value within the valid range makes it less likely to trigger static relocation even when the current transmission delay does not meet the QoS requirement. This affects user experience. Setting this parameter to a larger value causes frequent static relocations when the current transmission delay meets the QoS requirement. This affects RNC performance.

The parameter should be set on the basis of "Interval of Iur Resource Congestion Reporting". The difference between the previous two values cannot be too large. Individually changing a parameter will cause the time difference in the congestion reporting and the relocation triggering, and thus the algorithm cannot be efficiently performed.

If this parameter is set to a greater value, more UEs may occupy common channels on the Iur interface, and thus a large number of Iur resources are occupied. If this parameter is set to a smaller value, almost no UE occupies common channel, and thus Iur resources are wasted.

This parameter determines the number of UEs over the Iur interface. If the parameter is set to a greater value, a large number of unnecessary Iur resources are occupied. If this parameter is set to a smaller value, the ping-pong relocation may occur.

If the relocation is not allowed to be initiated by the RT or NRT service, the corresponding service may occupy more Iur resources.

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If the value of this parameter is too high, congestion may occur over the FACH channel.

If the value of this parameter is too high, the 4A event reporting will be delayed. This may result in congestion over the FACH channel.

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If the value of this parameter is too high, congestion may occur over the E-FACH channel.

If the value of this parameter is too high, the 4A event reporting will be delayed. This may result in congestion over the E-FACH channel.










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If the value of this parameter is too low, it can not judge whether the UE is in low activity state. If the value of this parameter is too high, the dedicated channel resources are wasted. This parameter should be set on the basis of the BE service model.

If the value of this parameter is too low, it can not judge whether the UE is in low activity state. If the value of this parameter is too high, the common channel resources are wasted. This parameter should be set on the basis of the BE service model.


If the value of this parameter is too low, it can not judge whether the UE is in low activity state. If the value of this parameter is too high, the dedicated channel resources are wasted. This parameter should be set on the basis of the real-time service model.







If the value of this parameter is too low, it can not judge whether the UE is in low activity state. If the value of this parameter is too high, the dedicated channel resources will be wasted. This parameter should be set on the basis of the BE service model.


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The larger the value of the parameter, the lower the probability of selecting neighboring cells. The smaller the value the parameter, the higher the probability of doing so.



A greater value of this parameter indicates that the inter-RAT DRD is less possibly triggered. A smaller value of this parameter indicates that the inter-RAT DRD is more possibly triggered, however, with a low success rate.



A greater value of this parameter indicates that this GSM cell is more possibly selected as the target cell for the handover. If the value of this parameter is too great, a GSM cell that fails to provide qualified services may be selected as the target cell for the handover, thus leading to call drops.A smaller value of this parameter indicates that this GSM cell is less possibly selected as the target cell for the handover. If the value of this parameter is too small, the MS may fail to be handed over to the GSM cell timely, thus leading to call drops.


The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are greater possibilities of meeting the requirement for lowering the AMR speech rate. Thus, it is easier to lower the AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are less possibilities of meeting the requirement for stopping AMR speech rate adjustment. Thus, it is easier to lower the AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are less possibilities of meeting the requirement for raising the AMR speech rate. Thus, it is more difficult to raise the AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are greater possibilities of meeting the requirement for stopping AMR speech rate increase. Thus, it is more difficult to raise the AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are greater possibilities of meeting the requirement for lowering the wideband AMR speech rate. Thus, it is easier to lower the wideband AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are less possibilities of meeting the requirement for stopping wideband AMR speech rate adjustment. Thus, it is easier to lower the wideband AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are less possibilities of meeting the requirement for raising the wideband AMR speech rate. Thus, it is more difficult to raise the wideband AMR speech rate.

The higher the value of this parameter is, the lower the absolute threshold is. In this case, there are greater possibilities of meeting the requirement for stopping wideband AMR speech rate increase. Thus, it is more difficult to raise the wideband AMR speech rate.



If the value is excessively high, the link out-of-sync decision is likely to happen. If the value is excessively low, out-of-sync is not likely to happen. But if the link quality is poor, it may result in a waste of the UE power and increased uplink interference.

If the value is excessively low, there are few chances for the radio link to get synchronized. If the value is excessively high, the radio link failure process is probably delayed, and the downlink interference increases.










If the value is too high the system load after admission may be over large, which impacts system stability and leads to system congestion. If the value is too low, the possibility of user rejects may increase, resulting in waste in idle resource and the failure to achieving the network planning target.






If the value is too high, power resources are wasted, which impacts system capacity. If the value is too low, resources can be fully used and coverage may be impacted in case of insufficient resources.





If this value is too high, the possibility of rejecting HSUPA schedule services increases, which impacts access success rate. If the value is too low, too many HSUPA schedule users may be admitted, which impacts the admitted users and results in overload and system congestionRecommended.



If the value is too low, the cell HSDPA capacity may be reduces, leading to waste in HSDPA resources. If the value is too high, HSDPA services may be congested.





If the value is too high, HSUPA services may be congested. If the value is too low, the cell HSDPA capacity may be reduces, leading to waste in HSUPA resources.




If this parameter is set to a too great value, the guaranteed power of HSDPA users is high, and the power available for DCH users is low. As a result, the capacity of the cell decreases.

If this parameter is set to a too great value, the guaranteed power of HSUPA users is high, and the power available for DCH users is low. As a result, the capacity of the cell decreases.






When this switch is set to ON, the number of inter-RAT handovers for CS services may increase. When this switch is set to OFF, the number of inter-RAT handovers for CS services may decrease.

When this switch is set to ON, the number of inter-RAT handovers for PS services may increase. When this switch is set to OFF, the number of inter-RAT handovers for PS services may decrease.


If the parameter value is set too low, the HSDPA code resources will be limited and the HSDPA performance is affected. If the parameter value is set too high, the HSDPA code resources are wasted, thus increasing the admission rejection rate for R99 services.


If the parameter value is set too low (negative value), the total HSPA power will be too low, thus impacting the throughput of HSDPA subscribers at the border of a cell.

If the parameter value is unreasonable, the CQI in some scenarios will exceed the range of 0 to 30. As a result, the NodeB MAC-hs cannot schedule the subscriber in time or cannot schedule multiple subscribers with the difference of channel conditions.



If the parameter value is set too low, there is a risk that the cell throughput will be too low. If the parameter value is set too high, there is a risk for high interference.






If only inter-frequency neighboring cells exist, inter-frequency handovers may be triggered. If only inter-RAT neighboring cells exist, inter-RAT handovers may be triggered. If both inter-frequency and inter-RAT neighboring cells exist and this parameter is set to SIMINTERFREQRAT(inter-frequency and inter-RAT handover), both inter-frequency measurement and inter-RAT measurement can be performed.




























































If this parameter is set to a greater value, the thresholds for triggering soft handover for events 1A and 1B are greater under the same conditions. In this case, the probability for adding a cell to the active set decreases, and that for removing a cell from the active set increases. If this parameter is set to a smaller value, the probability for adding a cell to the active set increases, and that for removing a cell from the active set decreases.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.

If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.

If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.

If the value is too great, the cell pilot may change fiercely, which is easy to lead to user call drops. If the value is too small, the cell pilot may change smoothly. However, the response speed of the cell breathing algorithm is decreased, impacting the algorithm performance.


















When the value is TRUE, users can be selected for inter-frequency handover during code resource congestion, which can easily release code congestion and use multi-frequency resources. However, the risk of inter-frequency blink handover increases.







If the parameter is set too big, the TTI switchove cannot be triggered until there is insufficient credit remaining. In this case, the TTI switchover is triggered too late. If the parameter is set too small, the TTI switchover may be triggered even when there is sufficient credit remaining.





If the value of this parameter is set to a too great value, the downlink transmit power on a single radio link is too high. Thus, the downlink capacity is affected. If the value of this parameter is set to a too small value, the coverage area of services is decreased, and the risk of call drops is increased.




The larger the value of the parameter is, the easier it is to be handed over to the GSM network. The smaller the value of the parameter is, the harder it is to be handed over to the GSM network.



If MaxFachPower is set excessively low, a UE positioned at the cell edge may fail to receive the services and signaling carried over the FACH, in a correct way. This will impact the downlink common channel coverage and thus the cell coverage.If MaxFachPower is set excessively high, other channels will be interfered and more downlink power resources will be occupied. This will consequently impact the cell capacity.












































































If this parameter is set to a greater value, the effect of smoothing signals and the ability of anti-fast-fading improve; however, the ability of tracing the signal change becomes low and call drops are likely to occur because handover is not performed in time. If this parameter is set to a smaller value, the number of unnecessary soft handovers and ping-pong handovers increases.

In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.









If the parameter is set too big, the TTI switchove cannot be triggered until there is insufficient credit remaining. In this case, the TTI switchover is triggered too late. If the parameter is set too small, the TTI switchover may be triggered even when there is sufficient credit remaining.





If the value is excessively low, the uplink interference may increase, and the uplink capacity may be affected. If the value is excessively high, coverage may be affected.













If the parameter value is excessively low, the UE access success rate may be reduced. If the parameter value is excessively high, the UE probably spends a long time attempting repeatedly to access, which increases the uplink interference.


If this parameter is set to ON, pre-emption is triggered when PTM streaming bearer admission fails. That is, a lower-priority MBMS bearer or a non-MBMS bearer is released. Thus, the ongoing service is disrupted and call drop even occurs.

If this parameter is set to ON, a PTM streaming bearer might be pre-empted by an MBMS bearer of a higher priority or a non-MBMS bearer in the case of congestion. Thus, the MBMS service is disrupted, which has a relatively great impact because the PTM bearer serves more than one user.

If this parameter is set to ON, a PTM non-streaming bearer might be pre-empted by an MBMS bearer of a higher priority or a non-MBMS bearer in the case of congestion. Thus, the MBMS service is disrupted, which has a relatively great impact because the PTM bearer serves more than one user.





If this parameter is set to a smaller value, ping-pong relocations may occur, thus affecting network performance. If this parameter is set to a greater value, relocations may hardly occur, thus causing call drops.



If this parameter is set to a greater value, more UEs may occupy common channels on the Iur interface, and thus a large number of Iur resources are occupied. If this parameter is set to a smaller value, almost no UE occupies common channel, and thus Iur resources are wasted.

This parameter determines the number of UEs over the Iur interface. If the parameter is set to a greater value, a large number of unnecessary Iur resources are occupied. If this parameter is set to a smaller value, the ping-pong relocation may occur.



If the value of this parameter is too low, it can not judge whether the UE is in low activity state. If the value of this parameter is too high, the common channel resources are wasted. This parameter should be set on the basis of the BE service model.









If the value of this parameter is too low, it can not judge whether the UE is in low activity state. If the value of this parameter is too high, the dedicated channel resources will be wasted. This parameter should be set on the basis of the BE service model.




























If only inter-frequency neighboring cells exist, inter-frequency handovers may be triggered. If only inter-RAT neighboring cells exist, inter-RAT handovers may be triggered. If both inter-frequency and inter-RAT neighboring cells exist and this parameter is set to SIMINTERFREQRAT(inter-frequency and inter-RAT handover), both inter-frequency measurement and inter-RAT measurement can be performed.


























If this parameter is set to a greater value, the thresholds for triggering soft handover for events 1A and 1B are greater under the same conditions. In this case, the probability for adding a cell to the active set decreases, and that for removing a cell from the active set increases. If this parameter is set to a smaller value, the probability for adding a cell to the active set increases, and that for removing a cell from the active set decreases.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.





















































If this parameter is set to a greater value, the effect of smoothing signals and the ability of anti-fast-fading improve; however, the ability of tracing the signal change becomes low and call drops are likely to occur because handover is not performed in time. If this parameter is set to a smaller value, the number of unnecessary soft handovers and ping-pong handovers increases.

In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.If the interval for event 1A is shortened, handovers can be triggered timely, thus reducing the call drop rate. If the interval for event 1B is prolonged, the average number of handovers and number of ping-pong handovers decrease, thus reducing the call drop rate. These adjustments, however, may cause the growth of the SHO ratio and the over use of the forward resources.

























In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.

In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.

In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.












In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.

In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.

In addition, the UE at different rates may react differently to the same interval. For the fast-moving UE, the call drop rate is more sensitive to the interval, whereas, for the slow-moving UE, the call drop rate is less sensitive to the interval. Slow moving can also reduce ping-pong handovers and incorrect handovers. Therefore, for the cell where most UEs are in fast movement, this parameter can be set to a smaller value, whereas for the cell where most UEs are in slow movement, this parameter can be set to a greater value.In addition, different events require different values of the time-to-trigger parameter: the event of adding cells to the active set (event 1A) requires a smaller value of the time-to-trigger parameter; the events of replacing cells in the active set (events 1C and 1D) require fewer ping-pong and incorrect handovers and have no great impact on the call drop rate, and therefore the time-to-trigger parameter can be set to a great value; the events of deleting cells in the active set (events 1B and 1F) require fewer ping-pong handovers, and thus the time-to-trigger parameter can be adjusted, based on the actual network statistics.





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Huawei Parameter