URFSTG00571-WCDMA RAN12 Network Performance Parameter Mapping(Ericsson W10,NSN RU10, RU20, ALU...
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Transcript of URFSTG00571-WCDMA RAN12 Network Performance Parameter Mapping(Ericsson W10,NSN RU10, RU20, ALU...
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Description
Draft was completed.
1. The document was divided into four sheets: Parameter Mapping for High-Prio, Parameter Mapping for Low-Prio, Parameters Cannot Be Mapped onto, and Notes.2. Huawei values for the state-transition-related parameters were compared with the NSN and Ercisson values for these parameter in the Parameter Mapping for High-Prio sheet.3. Huawei values for the connected-mode-related parameters were compared with the NSN and Ercisson values for these parameter in the Parameter Mapping for High-Prio sheet.4. The Remarks column was added to the the Parameter Mapping for High-Prio sheet to explain why some parameters must be set to Huawei baseline values.5. Huawei values for the RL Max DL TX power and RL Min DL TX power parameters were compared with the AL values for these two parameters in the Parameter Mapping for High-Prio sheet.6. In the Parameter Mapping for High-Prio sheet, the SET UCONN command was changed to SET UCONNMODETIMER and the SET UIDLE command was changed to SET UIDLEMODETIMER.
The mapping priority for SlotFormatNum, PICHMode,PreambleSignatures,RACHSubChNo,and AICHTxTiming was changed from high to low.
1. The mapping rule for NSN in row 11 was deleted from the Parameter Mapping for High-Prio sheet and the Huawei baseline value was recommended.2. The parameter for NSN in row 104 was deleted from the Parameter Mapping for High-Prio sheet.
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1. In the Parameter Mapping for High-Prio sheet, the Huawei baseline value for Qrxlevmin in row 91 was changed from -50 to -58, the Huawei baseline value for Qrxlevmin in row 113 was changed from -50 to N/A, and the Huawei baseline value for Qrxlevmin in row 145 was changed from -50 to N/A.2. In the Parameter Mapping for High-Prio sheet, the AdjsQoffset1 parameter in row 142 was changed to AdjiQoffset1 and the AdjsQoffset2 parameter in row 143 was changed to AdjiQoffset2.3. In the Remarks column, remarks were added to the Compressed Mode Start Threshold for Inter-Frequency and Compressed Mode Start Threshold for Inter-RAT parameters for events 2D and 2F when Huawei values were compared with NSN and Ericsson values.
1. Mapping rules between Huawei values and Ericsson/NSN values were modified. For details, see the following document:
2. Mapping rules were added to some parameters. For details, see the following document:
1. Huawei values were compared with NSN RU20 values.2. For parameters that are at both the cell level and RNC level, Huawei baseline values are used.3. Rows 261 to 269 were newly added.4. Mapping rules for RL Max DL TX power, PCPICH Transmit Power, Max Transmit Power of Cell were added in the Notes sheet.
Newly Added Para-0311.xls
Change History-0311.xls
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1. Mapping rules were added in rows 57 to 68 when GSMcauseCPICHEcNo is set to 0 for NSN RU10. Mapping rules were added in rows 57 to 68 when GSMcauseCPICHrscp is set to Disabled for NSN RU20.2. Mapping rules for InterFreqFilterCoef, FilterCoefOf2D2F, and InterRATFilterCoef were added in rows 274 to 276.
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Version Author Date Notes
V1.00 Huang Xiangrong 2010.12.10
V1.01 Huang Xiangrong 2010.12.27
V1.02 Huang Xiangrong 2010.12.31
V1.03 Huang Xiangrong 2011.01.17
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V1.04 Huang Xiangrong 2011.01.20
V1.05 Huang Xiangrong 2011.03.04
V1.06 Huang Xiangrong 2011.06.30
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v1.07 Huang Xiangrong 2011.07.30
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URFSTG00571 - Huawei WCDMA BSC6900V900R012 Vs Ericsson W10/NSN RU10/NSN RU20/AL UA5.1
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For parameters for which this document does not provide mapping analysis, see the Baseline Parameter Values. Using other vendors' parameters values may not optimize Huawei network settings because Huawei algorithms are different from other vendors' algorithms. For values of Compressed Mode Start Threshold for Inter-Frequency, Compressed Mode End Threshold for Inter-Frequency, Compressed Mode Start Threshold for Inter-RAT, Compressed Mode End Threshold for Inter-RAT, and HCS, see the Guide to UMTS Swapping. For values for parameters realted to the multi-carrier policy, see the UMTS R12 Multi-Frequency Band and Multi-Carrier Performance Solution.
Notes about mapping:
Algorithm-related parameters for which this document does not provide mapping analysis, refer to Huawei baseline values.
Some of other vendors' values can be used directly while some values must be multiplied, divided, added, or subtracted before they can be used.
For values for network-related parameters for which this document has provided mapping analysis, refer to the actual values in the live network. For example, for the values for PCPICH Transmit Power and Max Transmit Power of Cell, check whether the (top of cabinet)TOC power or antenna power is used. Huawei uses the TOC power and therefore other vendors' values can be used they also use the TOC power. If other vendors do not use the TOC power, add the feeder loss.
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Notes about priority definition:
Principle:1. The parameters related to cell reselction initiated by UEs in idle mode, idle mode-related timers, connected mode-related timers, power control, soft handovers, inter-frequency handovers, inter-RAT handovers, and state transition have a high mapping priority. Therefore, Huawei personnel must focus on these parameters during parameter mapping.2. Compared with the Huawei inter-RAT handover mechanism, the NSN inter-RAT handover mechanism triggers more inter-RAT handovers. For details, see the following description. Therefore, Huawei personnel must inform custoers that the number of inter-RAT handovers may decrease after swapping. If customers request that the Huawei inter-RAT handover mechanism opearte in the same way as the NSN inter-RAT handover mechanism, Huawei personnel can raise the 2D or 2F threshold by 1 to 2 dB.The Ericsson inter-RAT handover mechanism is triggered by events while the Huawei inter-RAT handover mechanism is triggered by periodical measurement results. In this case, the Ericsson inter-RAT handover mechanism triggers less inter-RAT handovers than the Huanwei inter-RAT handover mechanism. This leads to decreased CS traffic in 3G cells and the increased number of inter-RAT handovers after swapping. If customers request that the Huawei inter-RAT handover mechanism opearte in the same way as the Ericsson inter-RAT handover mechanism, Huawei personnel can lower the 2D or 2F threshold by 1 to 2 dB.
To find appropriate values for PCPICH Transmit Power and Max Transmit Power of Cell, first check whether some TMAs are used. To do this, check the value for ulGain. If the value is 0, no TMAs are used. Otherwise, some TMAs may be in useIf some TMAs are used, use the following formula to calculate values for the preceding two parameters:MaxTxPower (HUAWEI) = maximumTransmissionPower + dlAttenuation(ExternalTma) + dlAttenuation(AntFeederCable) (Ericsson) PCPICHPower (HUAWEI) = primaryCpichPower + dlAttenuation(ExternalTma) + dlAttenuation(AntFeederCable) (Ericsson)If no TMAs are used, use Ericsson vlaues since Ericsson also uses the TOC power.Notes:The ulGain parameter is a NodeB-level parameter and thefore dump documents can be obtained only on a PLMN basis. After this, all RNC and NodeB parameters can be obtained.The following figure shows a base station where a TMA is used:
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Ericsson calculates the maximum transmit power of a radio link in the following way:For the RL Max DL TX power parameter, calculate the value for different sevices based on the following scripts and figure:Radio Connection Type Maximum DL Radio Link Rate MaxPower PS384/HS 3700 0 SRB 13.6 14800 0 AMR 12.2 15900 0 CS64 67700 32 PS64/64 70900 34 MultiRAB (CS64 + PS8/8) 76100 37 PS64/384 406900 48Note that parameter values in the preceding scripts are just examples, and therefore onsite personnel must check which values are used in Ericsson scripts and then calculate the value for RL Max DL TX power for different services.For example, the maximum downlink radio link rate is 67700 for the CS64 service. In addition, InterRate is set to 77600, interPwrMax is set to 38, MinimunRate is set to 15900, and minPwrMax is set to 0. Then, according to the following formula, the RL Max DL TX power parameter for this services must be set to 31.9:RL Max DL TX power = (interPwrMax-minPwrMax)/(InterRate - MinimunRate)x(Maximum DL Radio Link Rate - MinimunRate)
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The NSN inter-RAT handover measurement mechanism operates in the following way:During the inter-RAT handover measurement procedure, the RNC determines whether to enable UEs to stop being in compressed mode after event 1E is reported based on the values for ISHOCancellation, ISHOClcauseCPICHEcNo, ISHOClcauseCPICHrscp, and MaxNumISHOClPerAS.For example, the RNC enables a UE to stop being in compressed mode after event 1E is reported when the following three conditions are met:1. MaxNumISHOClPerAS is set to 1 or a smaller value.2. ISHOCancellation is set to Enabled.3. ISHOClcauseCPICHEcNo is set to Enabled or ISHOClcauseCPICHrscp is set to Enabled.However, the Huawei algorithm neables a UE to stop being in compressed mode after event 2F is reported. Compared with the Huawei inter-RAT handover measurement mechanism, the NSN inter-RAT handover measurement mechanism triggers more inter-RAT handovers.
Cancellation of inter-system handover because of event 1EThe RNC stops inter-system measurements when event 1E occurs for at least one cellof the active set. Event 1E can be configured for the following measurements on thePrimary CPICH:• CPICH RSCP: received signal code power (RSCP)• CPICH Ec/No: received energy per chip divided by the power density in the band,that is CPICH RSCP/UTRA Carrier RSSIThe parameters ISHOClcauseCPICHEcNo and/or ISHOClcauseCPICHrscp indicatewhether inter-system measurement cancellation in the UE is enabled or not for situationswhen a primary CPICH (active set cell) increases beyond the absolute threshold(Event 1E).
Inter-System handover cancellation because of measurement event 1E can be performedonly when all of the following conditions are met:• The Inter-System Handover Cancellation feature is enabled by theISHOCancellation parameter.
• The ISHOClcauseCPICHEcNo or ISHOClcauseCPICHrscp parameter has beenset to ‘enabled’ for one or more cells in the active set.
• The number of inter-system cancellations that have been performed for the correspondingUE with the current active set is less than the value specified for theMaxNumISHOClPerAS parameter.
• Inter-System measurements were started in the UE because of event 1F (for CPICHEc/No or CPICH RSCP) triggered measurement report.• Event 1E triggered measurement report was received during inter-system measurementphase.
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URFSTG00571 - Huawei WCDMA BSC6900V900R012 Vs Ericsson W10/NSN RU10/NSN RU20/AL UA5.1
For parameters for which this document does not provide mapping analysis, see the Baseline Parameter Values. Using other vendors' parameters values may not optimize Huawei network settings because Huawei algorithms are different from other vendors' algorithms. For values of Compressed Mode Start Threshold for Inter-Frequency, Compressed Mode End Threshold for Inter-Frequency, Compressed Mode Start Threshold for Inter-RAT, Compressed Mode End
Guide to UMTS Swapping. For values for parameters realted to the multi-UMTS R12 Multi-Frequency Band and Multi-Carrier Performance Solution.
Algorithm-related parameters for which this document does not provide mapping analysis, refer to
Some of other vendors' values can be used directly while some values must be multiplied, divided, added, or subtracted before they can be used.
For values for network-related parameters for which this document has provided mapping analysis, refer to the actual values in the live network. For example, for the values for PCPICH
Transmit Power of Cell, check whether the (top of cabinet)TOC power or antenna power is used. Huawei uses the TOC power and therefore other vendors' values can be used they also use the TOC power. If other vendors do not use the TOC power,
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1. The parameters related to cell reselction initiated by UEs in idle mode, idle mode-related timers, connected mode-related timers, power control, soft handovers, inter-frequency handovers, inter-RAT handovers, and state transition have a high mapping priority. Therefore, Huawei
2. Compared with the Huawei inter-RAT handover mechanism, the NSN inter-RAT handover mechanism triggers more inter-RAT handovers. For details, see the following description. Therefore, Huawei personnel must inform custoers that the number of inter-RAT handovers may decrease after swapping. If customers request that the Huawei inter-RAT handover mechanism opearte in the same way as the NSN inter-RAT handover mechanism, Huawei personnel can raise the 2D or 2F threshold by 1 to 2 dB.The Ericsson inter-RAT handover mechanism is triggered by events while the Huawei inter-RAT handover mechanism is triggered by periodical measurement results. In this case, the Ericsson inter-RAT handover mechanism triggers less inter-RAT handovers than the Huanwei inter-RAT handover mechanism. This leads to decreased CS traffic in 3G cells and the increased number of inter-RAT handovers after swapping. If customers request that the Huawei inter-RAT handover mechanism opearte in the same way as the Ericsson inter-RAT handover mechanism,
Max Transmit Power of Cell, first check whether some TMAs are used. To do , no TMAs are used. Otherwise, some TMAs may be in use
If some TMAs are used, use the following formula to calculate values for the preceding two parameters:MaxTxPower (HUAWEI) = maximumTransmissionPower + dlAttenuation(ExternalTma) + dlAttenuation(AntFeederCable) (Ericsson) PCPICHPower (HUAWEI) = primaryCpichPower + dlAttenuation(ExternalTma) + dlAttenuation(AntFeederCable) (Ericsson)If no TMAs are used, use Ericsson vlaues since Ericsson also uses the TOC power.
parameter is a NodeB-level parameter and thefore dump documents can be obtained only on a PLMN basis. After this, all RNC
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Ericsson calculates the maximum transmit power of a radio link in the following way: parameter, calculate the value for different sevices based on the following scripts and figure:
Radio Connection Type Maximum DL Radio Link Rate MaxPower
Note that parameter values in the preceding scripts are just examples, and therefore onsite personnel must check which values are used in for different services.
For example, the maximum downlink radio link rate is 67700 for the CS64 service. In addition, InterRate is set to 77600, interPwrMax is set to . Then, according to the following formula, the RL Max DL TX power parameter
RL Max DL TX power = (interPwrMax-minPwrMax)/(InterRate - MinimunRate)x(Maximum DL Radio Link Rate - MinimunRate)
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The NSN inter-RAT handover measurement mechanism operates in the following way:During the inter-RAT handover measurement procedure, the RNC determines whether to enable UEs to stop being in compressed mode after
ISHOClcauseCPICHEcNo, ISHOClcauseCPICHrscp, and
For example, the RNC enables a UE to stop being in compressed mode after event 1E is reported when the following three conditions are met:
is set to Enabled.However, the Huawei algorithm neables a UE to stop being in compressed mode after event 2F is reported. Compared with the Huawei inter-RAT handover measurement mechanism, the NSN inter-RAT handover measurement mechanism triggers more inter-RAT handovers.
The RNC stops inter-system measurements when event 1E occurs for at least one cellof the active set. Event 1E can be configured for the following measurements on the
CPICH Ec/No: received energy per chip divided by the power density in the band,
The parameters ISHOClcauseCPICHEcNo and/or ISHOClcauseCPICHrscp indicatewhether inter-system measurement cancellation in the UE is enabled or not for situationswhen a primary CPICH (active set cell) increases beyond the absolute threshold
Inter-System handover cancellation because of measurement event 1E can be performed
The ISHOClcauseCPICHEcNo or ISHOClcauseCPICHrscp parameter has been
The number of inter-system cancellations that have been performed for the corresponding
Inter-System measurements were started in the UE because of event 1F (for CPICH
Event 1E triggered measurement report was received during inter-system measurement
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NE Mapping Priority Parameter Type
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
Parameter Property
Cell-Level or RNC-Level
Inter RNC Cell UpdateIntra RNC Cell UpdateOpen Loop Power ControlOpen Loop Power ControlPhysical Channel ManagementPhysical Channel ManagementPhysical Channel ManagementIntra Node B Softer HandoverOpen Loop Power ControlAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionAccess Class Restriction
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RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELLHigh
Access Class RestrictionAccess Class RestrictionAccess Class RestrictionAdmission ControlLoad MeasurementHSDPA Power ControlInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard 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-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on Coverage
Inter-RAT Handover Based on Coverage
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RNC Radio CELLHigh
RNC Radio CELLHigh
RNC Radio CELLHigh
RNC Radio CELLHigh
RNC Radio CELLHigh
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High None
RNC Radio CELL High None
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
Inter-RAT Handover Based on Coverage
Inter-RAT Handover Based on Coverage
Inter-RAT Handover Based on Coverage
Inter-RAT Handover Based on Coverage
Inter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer Handover
Intra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer Handover
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RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
Intra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateOpen Loop Power ControlOpen Loop Power Control3GPP SpecificationsConnection with TMA (Tower Mounted Amplifier)3GPP SpecificationsSystem Information Broadcasting3GPP Specifications3GPP Specifications3GPP Specifications3GPP Specifications3GPP Specifications3GPP Specifications3GPP Specifications3GPP Specifications3GPP Specifications3GPP SpecificationsInter-RAT Handover Based on CoverageIntra RNC Cell UpdateIntra RNC Cell Update
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RNC Radio CELLHigh
RNC Radio CELLHigh
RNC Radio CELL High
RNC Radio CELL High None
RNC Radio CELL High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
Inter RNC Soft HandoverDirect Signaling Connection Re-establishment (DSCR)
Inter RNC Soft HandoverDirect Signaling Connection Re-establishment (DSCR)Intra Node B Softer Handover
Open Loop Power ControlInner Loop Power ControlPaging UE in Idle, CELL_PCH, URA_PCH State (Type 1)3GPP Specifications3GPP Specifications3GPP Specifications3GPP SpecificationsInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on Coverage
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RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
Intra Node B Softer HandoverIntra RNC Cell UpdateIntra RNC Cell UpdateInter RNC Cell UpdateInter RNC Cell UpdateInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer Handover
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RNC Radio RNC High
RNC Radio RNC High None
RNC Radio RNC High None
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio RNC High
RNC Equipment RNC High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio RNC High
Intra Node B Softer Handover
Intra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra RNC Cell UpdateIntra RNC Cell UpdateOpen Loop Power ControlOpen Loop Power ControlOpen Loop Power ControlOpen Loop Power ControlOpen Loop Power ControlOpen Loop Power ControlOpen Loop Power ControlSystem Information BroadcastingSystem Information BroadcastingSystem Information BroadcastingOpen Loop Power Control3GPP Specifications3GPP SpecificationsIntra RNC Cell UpdateIntra RNC Cell UpdateIntra Node B Softer Handover
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RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High None
RNC Radio RNC High
RNC Radio RNC High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High None
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
Intra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer Handover
Intra Node B Softer HandoverIntra Node B Softer HandoverIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer HandoverIntra Node B Softer Handover
Intra Node B Softer HandoverIntra Node B Softer HandoverAccess Class RestrictionAccess Class RestrictionAccess Class RestrictionInter-RAT Handover Based on CoverageHSDPA State TransitionHSDPA State TransitionHSDPA State Transition3.4/6.8/13.6/27.2 kbit/s RRC Connection and RAB Assignment
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RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC
High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio CELLHigh
RNC Radio CELLHigh
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
3.4/6.8/13.6/27.2 kbit/s RRC Connection and RAB Assignment3.4/6.8/13.6/27.2 kbit/s RRC Connection and RAB Assignment3.4/6.8/13.6/27.2 kbit/s RRC Connection and RAB AssignmentUE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, CELL-FACH)UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, UE State in Connected Mode (CELL-DCH, CELL-PCH, URA-PCH, Open Loop Power ControlAdmission Control
Open Loop Power ControlInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoverageInter Frequency Hard Handover Based on CoveragePhysical Channel ManagementPhysical Channel Management
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RNC Radio CELL High
RNC Radio CELL High None
RNC Radio CELL High
RNC Radio CELL High None
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELLHigh
RNC Radio CELL High
RNC Radio CELL High
RNC Radio CELL High
RNC Radio RNC High
RNC Radio RNC High
RNC Radio RNCHigh
RNC Radio CELL High
RNC Radio CELLHigh
RNC Radio CELL High
3GPP Specifications
3GPP Specifications
3GPP SpecificationsIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateIntra RNC Cell UpdateInter-RAT Handover Based on CoverageInter-RAT Handover Based on DL QoSInter-RAT Handover Based on CoverageInter-RAT Handover Based on CoverageHSDPA Introduction PackageHSDPA Mobility ManagementHSDPA Mobility ManagementHSDPA Mobility ManagementHSUPA Mobility ManagementInter Frequency Hard Handover Based on Coverage
Inter-RAT Handover Based on CoverageInter-RAT Handover Based on Coverage
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Parameter ID Parameter Name Meaning MML Command
Qoffset1sn Qoffset1sn ADD U2GNCELL -50~50
Qrxlevmin Min RX Level ADD U2GNCELL -58~-13
BCHPower ADD UBCH -350~150
MaxTxPower ADD UCELLSETUP 0~500
NInsyncInd ADD UCELLSETUP 1~256
NOutsyncInd ADD UCELLSETUP 1~256
TRlFailure ADD UCELLSETUP 0~255
CIO ADD UCELLSETUP -20~20
PCPICHPower -100~500
IsAccessClass0Barred
IsAccessClass1Barred
IsAccessClass2Barred
IsAccessClass3Barred
IsAccessClass4Barred
IsAccessClass5Barred
IsAccessClass6Barred
IsAccessClass7Barred
IsAccessClass8Barred
IsAccessClass9Barred
Parameter Value Range
Offset between the neighboring GSM cell and WCDMA cell.Minimum RX level of the GSM cell.
BCH Transmit Power
Offset of the BCH transmit power from the PCPICH transmit power in a
Max Transmit Power of Cell
Sum of the maximum transmit power of all DL channels in a cell.
Num of Continuous in Sync Ind
This parameter defines the times of successive in-sync indications required
Num of Continuous Out of Sync Ind
This parameter defines the times of successive in-sync indications required
Radio Link Failure Timer Length
Radio link failure timer duration. When the radio link set is in the
Cell Oriented Cell Individual Offset
This parameter works with the offset of neighboring cell-
PCPICH Transmit Power
TX power of the PCPICH in a cell. This parameter should be set based
ADD UCELLQUICKSETUP
CellReservedForOperatorUse
Cell reserved for operator use
Indicating whether the cell is reserved for operators. If the status of cell is
ADD UCELLACCESSSTRICT
RESERVED, NOT_RESERVED
Access class 0 barred indicator
Indicating whether the UE allocated with Access Class 0 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 1 barred indicator
Indicating whether the UE allocated with Access Class 1 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 2 barred indicator
Indicating whether the UE allocated with Access Class 2 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 3 barred indicator
Indicating whether the UE allocated with Access Class 3 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 4 barred indicator
Indicating whether the UE allocated with Access Class 4 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 5 barred indicator
Indicating whether the UE allocated with Access Class 5 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 6 barred indicator
Indicating whether the UE allocated with Access Class 6 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 7 barred indicator
Indicating whether the UE allocated with Access Class 7 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 8 barred indicator
Indicating whether the UE allocated with Access Class 8 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
Access class 9 barred indicator
Indicating whether the UE allocated with Access Class 9 can be allowed to
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
IsAccessClass10Barred
Access class 10 barred indicator
Indicating whether the UE allocated with Access Class 10 can be allowed
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
IsAccessClass11Barred
Access class 11 barred indicator
Indicating whether the UE allocated with Access Class 11 can be allowed
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
IsAccessClass12Barred
Access class 12 barred indicator
Indicating whether the UE allocated with Access Class 12 can be allowed
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
IsAccessClass13Barred
Access class 13 barred indicator
Indicating whether the UE allocated with Access Class 13 can be allowed
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
IsAccessClass14Barred
Access class 14 barred indicator
Indicating whether the UE allocated with Access Class 14 can be allowed
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
IsAccessClass15Barred
Access class 15 barred indicator
Indicating whether the UE allocated with Access Class 15 can be allowed
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
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IdleCellBarred
IdleTbarred
BackgroundNoise Background noise ADD UCELLCAC 0~621
HspaPower -500~0
PrdReportInterval
HystFor2D 2D Hysteresis 0~29
HystFor2F 2F Hysteresis 0~29
TimeToTrig2D
TimeToTrig2F
-24~0
-24~0
-24~0
-24~0
-24~0
InterFreqHThd2FEcN0 -24~0
-115~-25
-115~-25
-115~-25
-115~-25
-115~-25
-115~-25
Hystfor2D 2D Hysteresis 0~29
Hystfor2F 2F Hysteresis 0~29
TrigTime2D
TrigTime2F
TrigTime3A
-24~0
Cell barred indicator for SIB3
Indicating whether the UE in idle mode is allowed to access the cell. When the
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
IdleIntraFreqReselection
Intra-freq cell reselection ind for SIB3
Indicating whether the UE in idle mode is allowed to reselect another
ADD UCELLACCESSSTRICT
ALLOWED, NOT_ALLOWED
Time barred for SIB3
This parameter is valid when [Cell barred indicator for SIB3] is BARRED.
ADD UCELLACCESSSTRICT
D10, D20, D40, D80, D160, D320, D640, D1280
If [Auto-Adaptive Background Noise Update Switch] is set to OFF, it is
The Offset of HSPA Total Power
This parameter specifies the offset between the total HSPA power and
ADD UCELLHSDPAInter-frequency
Measure Periodical Measurement Report Period
Interval between periodic reporting for the inter-frequency
ADD UCELLINTERFREQHOCOV
NON_PERIODIC_REPORT(Non periodical reporting), D250~1
Hysteresis for triggering event 2D.
ADD UCELLINTERFREQHOCOV
Hysteresis for triggering event 2F.
ADD UCELLINTERFREQHOCOV
Event 2D Trigger Delay
Interval time between detection of event 2D and sending of the
ADD UCELLINTERFREQHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Event 2F Trigger Delay
Interval time between detection of event 2F and sending of the
ADD UCELLINTERFREQHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
InterFreqCSThd2DEcN0
Inter-freq CS Measure Start Ec/No THD
Ec/No threshold of triggering the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqCSThd2FEcN0
Inter-freq CS Measure Stop Ec/No THD
Ec/No threshold of stopping the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqR99PsThd2DEcN0
Inter-freq R99 PS Measure Start Ec/No THD
Ec/No threshold of triggering the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqHThd2DEcN0
Inter-freq H Measure Start Ec/No THD
Ec/No threshold of triggering the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqR99PsThd2FEcN0
Inter-freq R99 PS Measure Stop Ec/No THD
Ec/No threshold of stopping the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
Inter-freq H Measure Stop Ec/No THD
Ec/No threshold of stopping the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqCSThd2DRSCP
Inter-freq CS Measure Start RSCP THD
RSCP threshold of triggering the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqCSThd2FRSCP
Inter-freq CS Measure Stop RSCP THD
RSCP threshold of stopping the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqR99PsThd2DRSCP
Inter-freq R99 PS Measure Start RSCP THD
RSCP threshold of triggering the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqHThd2DRSCP
Inter-freq H Measure Start RSCP THD
RSCP threshold of triggering the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqR99PsThd2FRSCP
Inter-freq R99 PS Measure Stop RSCP THD
RSCP threshold of stopping the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
InterFreqHThd2FRSCP
Inter-freq H Measure Stop RSCP THD
RSCP threshold of stopping the inter-frequency measurement for
ADD UCELLINTERFREQHOCOV
Hysteresis for event 2D.
ADD UCELLINTERRATHOCOV
Hysteresis for event 2F.
ADD UCELLINTERRATHOCOV
2D Event Trigger Delay Time
Interval time between detection of event 2D and sending of the
ADD UCELLINTERRATHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
2F Event Trigger Delay Time
Interval time between detection of event 2F and sending of the
ADD UCELLINTERRATHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
3A Event Trigger Delay Time
Interval time between detection of event 3A and sending of the
ADD UCELLINTERRATHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
InterRATCSThd2DEcN0
Inter-RAT CS Measure Start Ec/No THD
Threshold of triggering inter-RAT measurement for CS services when
ADD UCELLINTERRATHOCOV
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-24~0
-24~0
InterRATHThd2DEcN0 -24~0
-24~0
InterRATHThd2FEcN0 -24~0
-115~-25
-115~-25
-115~-25
-115~-25
-115~-25
-115~-25
TargetRatCsThd 0~63
TargetRatR99PsThd 0~63
TargetRatHThd 0~63
0~29
0~29
IntraRelThdFor1APS 0~29
0~29
0~29
IntraRelThdFor1BPS 0~29
HystFor1A 1A Hysteresis 0~15
HystFor1B 1B Hysteresis 0~15
HystFor1D 1D Hysteresis 0~15
TrigTime1A
TrigTime1B
TrigTime1D
MaxCellInActiveSet 1~6
InterRATCSThd2FEcN0
Inter-RAT CS Measure Stop Ec/No THD
Threshold of stopping inter-RAT measurement for CS services when
ADD UCELLINTERRATHOCOV
InterRATR99PsThd2DEcN0
Inter-RAT R99 PS Measure Start Ec/No THD
Threshold of triggering inter-RAT measurement for PS domain non-
ADD UCELLINTERRATHOCOV
Inter-RAT HSPA Measure Start Ec/No THD
Threshold of triggering inter-RAT measurement for HSPA services
ADD UCELLINTERRATHOCOV
InterRATR99PsThd2FEcN0
Inter-RAT R99 PS Measure Stop Ec/No THD
Threshold of triggering inter-RAT measurement for PS domain non-
ADD UCELLINTERRATHOCOV
Inter-RAT HSPA Measure Stop Ec/No THD
Threshold of stopping inter-RAT measurement for HSPA services
ADD UCELLINTERRATHOCOV
InterRATCSThd2DRSCP
Inter-RAT CS Measure Start RSCP THD
Threshold of triggering inter-RAT measurement for CS services when
ADD UCELLINTERRATHOCOV
InterRATCSThd2FRSCP
Inter-RAT CS Measure Stop RSCP THD
Threshold of stopping inter-RAT measurement for CS services when
ADD UCELLINTERRATHOCOV
InterRATR99PsThd2DRSCP
Inter-RAT R99 PS Measure Start RSCP THD
Threshold of triggering inter-RAT measurement for PS domain non-
ADD UCELLINTERRATHOCOV
InterRATHThd2DRSCP
Inter-RAT HSPA Measure Start RSCP THD
Threshold of triggering inter-RAT measurement for HSPA services
ADD UCELLINTERRATHOCOV
InterRATR99PsThd2FRSCP
Inter-RAT R99 PS Measure Stop RSCP THD
Threshold of stopping inter-RAT measurement for PS domain non-
ADD UCELLINTERRATHOCOV
InterRATHThd2FRSCP
Inter-RAT HSPA Measure Stop RSCP THD
Threshold of stopping inter-RAT measurement for HSPA services
ADD UCELLINTERRATHOCOV
Inter-RAT CS Handover Decision THD
Quality requirement for the cell of another RAT during inter-RAT handover
ADD UCELLINTERRATHOCOV
Inter-RAT R99 PS Handover Decision THD
Quality requirement for the cell of another RAT during inter-RAT handover
ADD UCELLINTERRATHOCOV
Inter-RAT HSPA Handover Decision THD
Quality requirement for the cell of another RAT during inter-RAT handover
ADD UCELLINTERRATHOCOV
IntraRelThdFor1ACSVP
VP Service Event 1A Relative Threshold
Relative threshold for event 1A decision when VP service is
ADD UCELLINTRAFREQHO
IntraRelThdFor1ACSNVP
CS Non-VP Service Event 1A Relative THD
Relative threshold for event 1A decision when non-VP service is
ADD UCELLINTRAFREQHO
PS Service Event 1A Relative Threshold
Relative threshold for event 1A decision when PS service is
ADD UCELLINTRAFREQHO
IntraRelThdFor1BCSVP
VP Service Event 1B Relative Threshold
Relative threshold for event 1B decision when VP service is
ADD UCELLINTRAFREQHO
IntraRelThdFor1BCSNVP
CS Non-VP Service Event 1B Relative Threshold
Relative threshold for event 1B decision when non-VP service is
ADD UCELLINTRAFREQHO
PS Service Event 1B Relative Threshold
Relative threshold for event 1B decision when PS service is
ADD UCELLINTRAFREQHOThis parameter
specifies the hysteretic value for event 1A. The value
ADD UCELLINTRAFREQHOThis parameter
specifies the hysteretic value for event 1B. The value
ADD UCELLINTRAFREQHOThis parameter
specifies the hysteretic value for event 1D. The value
ADD UCELLINTRAFREQHO
Event 1A Triggering Delay
This parameter specifies the interval time between detection
ADD UCELLINTRAFREQHO
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Event 1B Triggering Delay
This parameter specifies the interval time between detection
ADD UCELLINTRAFREQHO
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Event 1D Triggering Delay
This parameter specifies the interval time between detection
ADD UCELLINTRAFREQHO
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Max Number of Cell in Active Set
Maximum number of cells in an active set. This parameter is used to achieve
ADD UCELLINTRAFREQHO
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IdleQhyst1s 0~20
ConnQhyst1s 0~20
IdleQhyst2s 0~20, 255
ConnQhyst2s 0~20, 255
Treselections 0~31
Qqualmin Min quality level -24~0
Qrxlevmin Min Rx level -58~-13
IdleSintrasearch -16~10, 127
IdleSintersearch -16~10, 127
SsearchRat -16~10, 127
PICHPowerOffset PICH Power Offset -10~5
AICHPowerOffset AICH Power Offset -22~5
T3212 0~255
ATT
NMO MODE1, MODE2
DRXCycleLenCoef 6~9
T302 Timer 302
N302 Constant 302 0~7
T309 Timer 309 1~8
T312 Timer 312 1~15
N312 Constant 312
T313 Timer 313 0~15
N313 Constant 313
T314 Timer 314
T315 Timer 315
N315 Constant 315
CIO -50~50
Qqualmin Min Quality Level -24~0
Qrxlevmin Min RX level -58~-13
Hysteresis 1 for idle mode
The hysteresis value of the serving FDD cells in idle mode in case the
ADD UCELLSELRESEL
Hysteresis 1 for connect mode
The hysteresis value of the serving FDD cells in connected mode in
ADD UCELLSELRESEL
Hysteresis 2 for idle mode
The hysteresis value of the serving FDD cells in idle mode in case the
ADD UCELLSELRESEL
Hysteresis 2 for connect mode
The hysteresis value of the serving FDD cells in connected mode in
ADD UCELLSELRESEL
Reselection delay time
If the signal quality (CPICH Ec/No measured by the UE) of a
ADD UCELLSELRESELThe minimum
required quality threshold corresponding to
ADD UCELLSELRESELThe minimum
required RX threshold corresponding to
ADD UCELLSELRESELIntra-freq cell
reselection threshold for idle mode
Threshold for intra-frequency cell reselection in idle mode. When the
ADD UCELLSELRESELInter-freq cell
reselection threshold for idle mode
Threshold for inter-frequency cell reselection in idle mode. When the
ADD UCELLSELRESEL
Inter-RAT cell reselection threshold
Threshold for inter-RAT cell reselection. When the quality (CPICH
ADD UCELLSELRESELDifference between
the transmit power of PICH and that of PCPICH. For
ADD UCHPWROFFSET
This parameter specifies the power offset between the transmit power of
ADD UCHPWROFFSET
Periodical location update timer
Periodical location update is implemented by MS through the location
ADD UCNDOMAIN
Attach/detach allowed indication
Indicating whether attach/detach is allowed. NOT_ALLOWED
ADD UCNDOMAIN NOT_ALLOWED, ALLOWED
Network mode of operation
This parameter should be set according to the actual network
ADD UCNDOMAIN
DRX cycle length coefficient
CN domain specific Discontinuous Reception (DRX) cycle length
ADD UCNDOMAINT302 is started after the UE transmits the CELL UPDATE/URA
SET UCONNMODETIMER
D100, D200, D400, D600, D800, D1000, D1200, D1400, D1600,
Maximum number of retransmissions of CELL UPDATE/URA
SET UCONNMODETIMER
T309 is started after the UE is reselected to a cell belonging to another
SET UCONNMODETIMER
T312 is started when UE starts to establish a DCH, and stopped when
SET UCONNMODETIMER
Maximum number of successive "in sync" indications received from L1.
SET UCONNMODETIMER
D1, D2, D4, D10, D20, D50, D100, D200, D400, D600, D800, D1000
T313 is started after the UE detects consecutive N313 "out of sync"
SET UCONNMODETIMER
Maximum number of successive "out of sync" indications received from L1.
SET UCONNMODETIMER
D1, D2, D4, D10, D20, D50, D100, D200
T314 is started when the criteria for radio link failure are fulfilled and only
SET UCONNMODETIMER
D0, D2, D4, D6, D8, D12, D16, D20
T315 is started when the criteria for radio link failure are fulfilled, and only
SET UCONNMODETIMER
D0, D10, D30, D60, D180, D600, D1200, D1800
Maximum number of successive "in sync" indications received from L1
SET UCONNMODETIMER
D1, D2, D4, D10, D20, D50, D100, D200, D400, D600, D800, D1000
Cell Individual Offset
It is set according to the topographic feature.
ADD UEXT2GCELLThis parameter defines the CPICH Ec/No access threshold of the cell.
ADD UEXT3GCELLThis parameter defines the CPICH RSCP access threshold of the
ADD UEXT3GCELL
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CellCapContainerFdd
CellCapContainerFdd
CIO -20~20
VPLimitInd VPLimitInd ADD UCELLSETUP TRUE, FALSE
MaxFachPower ADD UFACH -350~150
FddTpcDlStepSize SET UFRC
DrxCycleLenCoef SET UFRC 3~9
T300 Timer 300
N300 Constant 300 0~7
T312 Timer 312 1~15
N312 Constant 312
PrdReportInterval
HystFor2D 2D Hysteresis 0~29
HystFor2F 2F Hysteresis 0~29
TimeToTrig2D
TimeToTrig2F
-24~0
-24~0
-24~0
-24~0
-24~0
InterFreqHThd2FEcN0 -24~0
-115~-25
-115~-25
-115~-25
-115~-25
-115~-25
-115~-25
Cell Capability Container
1)DELAY_ACTIVATION_SUPPORT (delay activation support
ADD UEXT3GCELL
DELAY_ACTIVATION_SUPPORT(delay activation support indication),
Cell Capability Container
1)DELAY_ACTIVATION_SUPPORT (delay activation support
ADD UEXT3GCELL
DELAY_ACTIVATION_SUPPORT(delay activation support indication),
Cell oriented Cell Individual Offset
The CIO value specified in this parameter cooperates with the
ADD UEXT3GCELLIndicates whether the videophone (VP) service is limited in a cell.
Max Transmit Power of FACH
The offset between the FACH transmit power and P-CPICH transmit
FDD DL power control step size
Step of the closed-loop power control performed on DL DPCH in Frequency
STEPSIZE_0.5DB, STEPSIZE_1DB, STEPSIZE_1.5DB, STEPSIZE_2DB
Paging DRX cycle coefficient
UTRAN-specific Discontinuous Reception (DRX) cycle length T300 is started when UE sends the RRC CONNECTION
SET UIDLEMODETIMER
D100, D200, D400, D600, D800, D1000, D1200, D1400, D1600,
Maximum number of retransmissions of the RRC CONNECTION
SET UIDLEMODETIMER
T312 is started when UE starts to establish a DCH, and stopped when
SET UIDLEMODETIMER
Maximum number of successive "in sync" indications received from L1.
SET UIDLEMODETIMER
D1, D2, D4, D10, D20, D50, D100, D200, D400, D600, D800, D1000
Inter-frequency Measure Periodical Measurement Report Period
Interval between periodic reporting for the inter-frequency
SET UINTERFREQHOCOV
NON_PERIODIC_REPORT(Non periodical reporting), D250~1
Hysteresis for triggering event 2D.
SET UINTERFREQHOCOV
Hysteresis for triggering event 2F.
SET UINTERFREQHOCOV
Event 2D Trigger Delay
Interval time between detection of event 2D and sending of the
SET UINTERFREQHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Event 2F Trigger Delay
Interval time between detection of event 2F and sending of the
SET UINTERFREQHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
InterFreqCSThd2DEcN0
Inter-freq CS Measure Start Ec/No THD
Ec/No threshold of triggering the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqCSThd2FEcN0
Inter-freq CS Measure Stop Ec/No THD
Ec/No threshold of stopping the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqR99PsThd2DEcN0
Inter-freq R99 PS Measure Start Ec/No THD
Ec/No threshold of triggering the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqHThd2DEcN0
Inter-freq H Measure Start Ec/No THD
Ec/No threshold of triggering the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqR99PsThd2FEcN0
Inter-freq R99 PS Measure Stop Ec/No THD
Ec/No threshold of stopping the inter-frequency measurement for
SET UINTERFREQHOCOVInter-freq H
Measure Stop Ec/No THD
Ec/No threshold of stopping the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqCSThd2DRSCP
Inter-freq CS Measure Start RSCP THD
RSCP threshold of triggering the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqCSThd2FRSCP
Inter-freq CS Measure Stop RSCP THD
RSCP threshold of stopping the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqR99PsThd2DRSCP
Inter-freq R99 PS Measure Start RSCP THD
RSCP threshold of triggering the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqHThd2DRSCP
Inter-freq H Measure Start RSCP THD
RSCP threshold of triggering the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqR99PsThd2FRSCP
Inter-freq R99 PS Measure Stop RSCP THD
RSCP threshold of stopping the inter-frequency measurement for
SET UINTERFREQHOCOV
InterFreqHThd2FRSCP
Inter-freq H Measure Stop RSCP THD
RSCP threshold of stopping the inter-frequency measurement for
SET UINTERFREQHOCOV
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CIOOffset -20~20
IdleQoffset1sn IdleQoffset1sn -50~50
IdleQoffset2sn IdleQoffset2sn -50~50
Qqualmin Min Quality Level -24~0
Qrxlevmin Min RX Level -58~-13
Hystfor2D 2D Hysteresis 0~29
Hystfor2F 2F Hysteresis 0~29
TrigTime2D
TrigTime2F
-24~0
-24~0
-24~0
InterRATHThd2DEcN0 -24~0
-24~0
InterRATHThd2FEcN0 -24~0
-115~-25
-115~-25
-115~-25
-115~-25
-115~-25
-115~-25
TargetRatCsThd 0~63
TargetRatR99PsThd 0~63
TargetRatHThd 0~63
0~29
0~29
IntraRelThdFor1APS 0~29
0~29
0~29
Neighboring Cell Oriented CIO
Neighboring cell oriented CIO.
ADD UINTERFREQNCELLCell offset used for
CPICH RSCP measurement value in cell selection or
ADD UINTERFREQNCELLCell offset used for
CPICH Ec/No measurement value in cell selection or
ADD UINTERFREQNCELLMinimum CPICH
Ec/No for the neighboring cell on cell reselection. The
ADD UINTERFREQNCELLMinimum CPICH
RSCP for the neighboring cell on cell reselection. The
ADD UINTERFREQNCELL
Hysteresis for event 2D.
SET UINTERRATHOCOV
Hysteresis for event 2F.
SET UINTERRATHOCOV
2D Event Trigger Delay Time
Interval time between detection of event 2D and sending of the
SET UINTERRATHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
2F Event Trigger Delay Time
Interval time between detection of event 2F and sending of the
SET UINTERRATHOCOV
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
InterRATCSThd2DEcN0
Inter-RAT CS Measure Start Ec/No THD
Threshold of triggering inter-RAT measurement for CS services when
SET UINTERRATHOCOV
InterRATCSThd2FEcN0
Inter-RAT CS Measure Stop Ec/No THD
Threshold of stopping inter-RAT measurement for CS services when
SET UINTERRATHOCOV
InterRATR99PsThd2DEcN0
Inter-RAT R99 PS Measure Start Ec/No THD
Threshold of triggering inter-RAT measurement for PS domain non-
SET UINTERRATHOCOVInter-RAT HSPA
Measure Start Ec/No THD
Threshold of triggering inter-RAT measurement for HSPA services
SET UINTERRATHOCOV
InterRATR99PsThd2FEcN0
Inter-RAT R99 PS Measure Stop Ec/No THD
Threshold of triggering inter-RAT measurement for PS domain non-
SET UINTERRATHOCOVInter-RAT HSPA
Measure Stop Ec/No THD
Threshold of stopping inter-RAT measurement for HSPA services
SET UINTERRATHOCOV
InterRATCSThd2DRSCP
Inter-RAT CS Measure Start RSCP THD
Threshold of triggering inter-RAT measurement for CS services when
SET UINTERRATHOCOV
InterRATCSThd2FRSCP
Inter-RAT CS Measure Stop RSCP THD
Threshold of stopping inter-RAT measurement for CS services when
SET UINTERRATHOCOV
InterRATR99PsThd2DRSCP
Inter-RAT R99 PS Measure Start RSCP THD
Threshold of triggering inter-RAT measurement for PS domain non-
SET UINTERRATHOCOV
InterRATHThd2DRSCP
Inter-RAT HSPA Measure Start RSCP THD
Threshold of triggering inter-RAT measurement for HSPA services
SET UINTERRATHOCOV
InterRATR99PsThd2FRSCP
Inter-RAT R99 PS Measure Stop RSCP THD
Threshold of stopping inter-RAT measurement for PS domain non-
SET UINTERRATHOCOV
InterRATHThd2FRSCP
Inter-RAT HSPA Measure Stop RSCP THD
Threshold of stopping inter-RAT measurement for HSPA services
SET UINTERRATHOCOVInter-RAT CS
Handover Decision THD
Quality requirement for the cell of another RAT during inter-RAT handover
SET UINTERRATHOCOVInter-RAT R99 PS
Handover Decision THD
Quality requirement for the cell of another RAT during inter-RAT handover
SET UINTERRATHOCOVInter-RAT HSPA
Handover Decision THD
Quality requirement for the cell of another RAT during inter-RAT handover
SET UINTERRATHOCOV
IntraRelThdFor1ACSVP
VP Service Event 1A Relative Threshold
Relative threshold for event 1A decision when VP service is
SET UINTRAFREQHO
IntraRelThdFor1ACSNVP
CS Non-VP Service Event 1A Relative THD
Relative threshold for event 1A decision when non-VP service is
SET UINTRAFREQHOPS Service Event
1A Relative Threshold
Relative threshold for event 1A decision when PS service is
SET UINTRAFREQHO
IntraRelThdFor1BCSVP
VP Service Event 1B Relative Threshold
Relative threshold for event 1B decision when VP service is
SET UINTRAFREQHO
IntraRelThdFor1BCSNVP
CS Non-VP Service Event 1B Relative Threshold
Relative threshold for event 1B decision when non-VP service is
SET UINTRAFREQHO
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IntraRelThdFor1BPS 0~29
HystFor1A 1A Hysteresis 0~15
HystFor1B 1B Hysteresis 0~15
HystFor1D 1D Hysteresis 0~15
Weight Weighted factor 0~20
TrigTime1A
TrigTime1B
TrigTime1D
CIOOffset -20~20
CellsForbidden1A
CellsForbidden1B
IdleQoffset1sn IdleQoffset1sn -50~50
IdleQoffset2sn IdleQoffset2sn -50~50
PCHPower PCH Power ADD UPCH -350~150
PCPICHPower ADD UPCPICH -100~500
Constantvalue -35~-10
PreambleRetransMax 1~64
PowerRampStep 1~8
PowerOffsetPpm Power Offset ADD UPRACHTFC -5~10
PSCHPower ADD UPSCH -350~150
NB01min 0~50
NB01max 0~50
Mmax Max Preamble Loop 1~32
SSCHPower ADD USSCH -350~150
RlRstrTmr RL restoration timer 1~300000
CNProtclVer CN protocol version
ConnQoffset1sn ConnQoffset1sn -50~50
ConnQoffset2sn ConnQoffset2sn -50~50
FilterCoef
PS Service Event 1B Relative Threshold
Relative threshold for event 1B decision when PS service is
SET UINTRAFREQHO
This parameter specifies the hysteretic value for event 1A. The value
SET UINTRAFREQHO
This parameter specifies the hysteretic value for event 1B. The value
SET UINTRAFREQHO
This parameter specifies the hysteretic value for event 1D. The value
SET UINTRAFREQHO
Used for calculating the relative threshold of the soft handover based on
SET UINTRAFREQHO
Event 1A Triggering Delay
This parameter specifies the interval time between detection
SET UINTRAFREQHO
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Event 1B Triggering Delay
This parameter specifies the interval time between detection
SET UINTRAFREQHO
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Event 1D Triggering Delay
This parameter specifies the interval time between detection
SET UINTRAFREQHO
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Neighboring Cell Oriented CIO
Neighboring cell oriented CIO.
ADD UINTRAFREQNCELL
Affect 1A Threshold Flag
Determines whether event 1A threshold is affected when the cell is added to the
ADD UINTRAFREQNCELL AFFECT,
NOT_AFFECTAffect 1B Threshold Flag
Flag of whether adding a cell into the active set will affect the relative
ADD UINTRAFREQNCELL AFFECT,
NOT_AFFECTCell offset used for CPICH RSCP measurement value in cell selection or
ADD UINTRAFREQNCELLCell offset used for
CPICH Ec/No measurement value in cell selection or
ADD UINTRAFREQNCELLOffset of the PCH
transmit power from the PCPICH transmit power in a
PCPICH Transmit Power
TX power of the PCPICH in a cell. This parameter should be set based Constant Value for
Calculating Initial TX Power
This parameter specifies a constant used at calculation of the initial transmit
ADD UPRACHBASIC
Max Preamble Retransmission
The maximum number of preambles transmitted in a
ADD UPRACHBASIC
Power Increase Step
The power ramp step of the random access preambles transmitted before
ADD UPRACHBASIC
The power offset between the last access preamble and the message
PSCH Transmit Power
Offset of the PSCH transmit power from the PCPICH transmit power in a
Random Back-off Lower Limit
Lower limit of random access back-off delay. For details, refer to the
ADD URACH
Random Back-off Upper Limit
Upper limit of random access back-off delay. For details, refer to the
ADD URACHThe parameter specifies the maximum number of preambles to be
ADD URACH
SSCH Transmit Power
Offset of the SSCH transmit power from the PCPICH transmit power in a A timer to RNC wait for radio link restoration indication in the
SET USTATETIMERProtocol version
supported by the CN.
ADD UCNNODE(Mandatory) R99, R4, R5, R6,
R7, R8Cell offset used for CPICH RSCP measurement value in cell selection or
ADD UINTERFREQNCELLCell offset used for
CPICH Ec/No measurement value in cell selection or
ADD UINTERFREQNCELL
Intra-frequency L3 Filter Coefficient
This parameter specifies the Layer 3 filter coefficient for the intra-frequency
SET UINTRAFREQHO
D0, D1, D2, D3, D4, D5, D6, D7, D8, D9, D11, D13, D15, D17, D19
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ReportIntervalfor1A
ReportIntervalfor1C
HystFor1C 1C Hysteresis 0~15
TrigTime1C
MaxCellInActiveSet 1~6
ConnQoffset1sn ConnQoffset1sn -50~50
ConnQoffset2sn ConnQoffset2sn -50~50
ConnSintrasearch -16~10, 127
ConnSintersearch -16~10, 127
IntraFreqFilterCoef
ReportIntervalfor1A
ReportIntervalfor1C
HystFor1C 1C Hysteresis 0~15
Weight Weighted factor 0~20
TrigTime1C
ConnCellBarred
ConnTbarred
CIOOffset ADD U2GNCELL -50~50
PsInactTmrForCon 0~14400
IntraFreqMeasQuantity
Intra-frequency Measurement Quantity
Quantity of the triggered measurements for intra-frequency
SET UINTRAFREQHO
CPICH_EC/NO, CPICH_RSCP
PeriodMRReportNumfor1A
Event 1A to Periodical Report Number
Maximum number of reporting event 1A after the reporting mode is
SET UINTRAFREQHO
D1~0 D2~1 D4~2 D8~3 D16~4 D32~5 D64~6 INFINITYEvent 1A to
Periodical Report Period
Interval at which event 1A is reported after the reporting mode is changed to
SET UINTRAFREQHO
NON_PERIODIC_REPORT, D250~1 D500~2 D1000~3 D2000~4 D4000~5
PeriodMRReportNumfor1C
Event 1C to Periodical Report Number
Maximum number of reporting event 1C after the reporting mode is
SET UINTRAFREQHO
D1~0 D2~1 D4~2 D8~3 D16~4 D32~5 D64~6 INFINITYEvent 1C to
Periodical Report Period
Interval at which event 1A is reported after the reporting mode is changed to
SET UINTRAFREQHO
NON_PERIODIC_REPORT, D250~1 D500~2 D1000~3 D2000~4 D4000~5
This parameter specifies the hysteretic value for event 1C. The value
SET UINTRAFREQHO
Event 1C Triggering Delay
This parameter specifies the interval time between detection
SET UINTRAFREQHO
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Max Number of Cell in Active Set
Maximum number of cells in an active set. This parameter is used to achieve
SET UINTRAFREQHO
Cell offset used for CPICH RSCP measurement value in cell selection or
ADD UINTRAFREQNCELLCell offset used for
CPICH Ec/No measurement value in cell selection or
ADD UINTRAFREQNCELLIntra-freq cell
reselection threshold for connect mode
Threshold for intra-frequency cell reselection in connected mode.
ADD UCELLSELRESELInter-freq cell
reselection threshold for connect mode
Threshold for inter-frequency cell reselection in connected mode.
ADD UCELLSELRESEL
Intra-frequency L3 Filter Coefficient
This parameter specifies the Layer 3 filter coefficient for the intra-frequency
ADD UCELLINTRAFREQHO
D0, D1, D2, D3, D4, D5, D6, D7, D8, D9, D11, D13, D15, D17, D19
IntraFreqMeasQuantity
Intra-frequency Measurement Quantity
Quantity of the triggered measurements for intra-frequency
ADD UCELLINTRAFREQHO CPICH_EC/NO,
CPICH_RSCPPeriodMRReportNumfor1A
Event 1A to Periodical Report Number
Maximum number of reporting event 1A after the reporting mode is
ADD UCELLINTRAFREQHO
D1~0 D2~1 D4~2 D8~3 D16~4 D32~5 D64~6 INFINITYEvent 1A to
Periodical Report Period
Interval at which event 1A is reported after the reporting mode is changed to
ADD UCELLINTRAFREQHO
NON_PERIODIC_REPORT, D250~1 D500~2 D1000~3 D2000~4 D4000~5
PeriodMRReportNumfor1C
Event 1C to Periodical Report Number
Maximum number of reporting event 1C after the reporting mode is
ADD UCELLINTRAFREQHO
D1~0 D2~1 D4~2 D8~3 D16~4 D32~5 D64~6 INFINITYEvent 1C to
Periodical Report Period
Interval at which event 1A is reported after the reporting mode is changed to
ADD UCELLINTRAFREQHO
NON_PERIODIC_REPORT, D250~1 D500~2 D1000~3 D2000~4 D4000~5
This parameter specifies the hysteretic value for event 1C. The value
ADD UCELLINTRAFREQHOUsed for calculating
the relative threshold of the soft handover based on
ADD UCELLINTRAFREQHO
Event 1C Triggering Delay
This parameter specifies the interval time between detection
ADD UCELLINTRAFREQHO
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Cell barred indicator for SIB4
Indicating whether the UE in connected mode is allowed to access
ADD UCELLACCESSSTRICT
BARRED, NOT_BARRED
ConnIntraFreqReselection
Intra-freq cell reselection ind for SIB4
Indicating whether the UE in idle mode is allowed to reselect another
ADD UCELLACCESSSTRICT
ALLOWED, NOT_ALLOWED
Time barred for SIB4
This parameter is valid when [Cell barred indicator for SIB4] is BARRED.
ADD UCELLACCESSSTRICT
D10(10 seconds), D20(20 seconds), D40(40 seconds), D80(80 seconds),
Neighboring Cell-Oriented CIO
Cell individual offset for the GSM cell.
DRA_HSDPA_STATE_TRANS_SWITCH
Dynamic Resource Allocation Switch
Dynamic resource allocation switch group.
SET UCORRMALGOSWITCH
DRA_AQM_SWITCH, DRA_BASE_ADM_CE_BE_TTI_L2_O
DRA_HSUPA_STATE_TRANS_SWITCH
Dynamic Resource Allocation Switch
Dynamic resource allocation switch group.
SET UCORRMALGOSWITCH
DRA_AQM_SWITCH, DRA_BASE_ADM_CE_BE_TTI_L2_O
DRA_PS_BE_STATE_TRANS_SWITCH
Dynamic Resource Allocation Switch
Dynamic resource allocation switch group.
SET UCORRMALGOSWITCH
DRA_AQM_SWITCH, DRA_BASE_ADM_CE_BE_TTI_L2_O
Conversational service T1
When detecting that the Ps' Conversational User had no data to
SET UPSINACTTIMER
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PsInactTmrForStr 0~14400
PsInactTmrForInt 0~14400
PsInactTmrForBac 0~14400
D2FTvmTimeToTrig BE D2F/R 4B Time
F2PTvmTimeToTrig BE F2P 4B Time
1~65535
BeF2DTvmThd
BeF2DTvmTimeToTrig BE F/R2D 4A Time
CellReSelectTimer 1~65535
1~65535
1~65535
RlMaxDlPwr -350~150
RlMinDlPwr -350~150
-24~0
-24~0
TargetFreqHThdEcN0 -24~0
TargetFreqCsThdRscp -115~-25
-115~-25
TargetFreqHThdRscp -115~-25
-24~0
TargetFreqHThdEcN0 -24~0
-24~0
TargetFreqCsThdRscp -115~-25
TargetFreqHThdRscp -115~-25
-115~-25
Tcell Time Offset ADD UCELLSETUP
PScrambCode ADD UCELLSETUP 0~511
Streaming service T1
When detecting that the Ps' Streaming User had no data to transfer for a long
SET UPSINACTTIMER
Interactive service T1
When detecting that the Ps' Interactive User had no data to transfer for a long
SET UPSINACTTIMER
Background service T1
When detecting that the Ps' Background User had no data to transfer for a long
SET UPSINACTTIMER
When the traffic volume is below the 4B threshold and remains so for the
SET UUESTATETRANS
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
When the traffic volume is below the 4B threshold and remains so for the
SET UUESTATETRANS
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
BeF2PStateTransTimer
BE FACH or E_FACH to PCH Transition Timer
Timer for state transition from FACH or E_FACH to PCH of BE
SET UUESTATETRANSTIMER
BE F/R2D 4A Threshold
This parameter specifies the threshold of the traffic volume of 4A event for triggering
SET UUESTATETRANS
D16, D32, D64, D128, D256, D512, D1024, D2k, D3k, D4k, D6k, D8k, D12k, D16k, D24k,
This parameter specifies the occurrence time of 4A event for
SET UUESTATETRANS
D0, D10, D20, D40, D60, D80, D100, D120, D160, D200, D240, D320, D640,
Cell Reselection Timer
Length of the cell reselection frequency timer. This parameter is
SET UUESTATETRANSTIMER
BeD2FStateTransTimer
BE DCH to FACH Transition Timer
Timer for state transition from DCH to FACH of BE services, used to
SET UUESTATETRANSTIMER
BeH2FStateTransTimer
BE HS-DSCH to FACH Transition Timer
Timer for state transition from HS-DSCH to FACH of BE services, used
SET UUESTATETRANSTIMER
RL Max DL TX power
This parameter specifies the maximum DL RL power to be
ADD UCELLRLPWR
RL Min DL TX power
This parameter specifies the minimum DL RL power to be
ADD UCELLRLPWR
TargetFreqCsThdEcN0
Inter-freq CS Target Frequency Trigger Ec/No THD
Threshold of the target frequency for triggering inter-frequency
SET UINTERFREQHOCOV
TargetFreqR99PsThdEcN0
Inter-freq R99 PS Target Frequency Trigger Ec/No THD
Threshold of the target frequency for triggering inter-frequency
SET UINTERFREQHOCOVInter-freq HSPA
Target Frequency Trigger Ec/No THD
Threshold of the target frequency for triggering inter-frequency
SET UINTERFREQHOCOVInter-freq CS Target
Frequency Trigger RSCP THD
Threshold of the target frequency for triggering inter-frequency
SET UINTERFREQHOCOV
TargetFreqR99PsThdRscp
Inter-freq R99 PS Target Frequency Trigger RSCP THD
Threshold of the target frequency for triggering inter-frequency
SET UINTERFREQHOCOVInter-freq HSPA
Target Frequency Trigger RSCP THD
Threshold of the target frequency for triggering inter-frequency
SET UINTERFREQHOCOV
TargetFreqCsThdEcN0
Inter-freq CS Target Frequency Trigger Ec/No THD
Threshold of the target frequency for triggering inter-frequency
ADD UCELLINTERFREQHOCOV
Inter-freq HSPA Target Frequency Trigger Ec/No THD
Threshold of the target frequency for triggering inter-frequency
ADD UCELLINTERFREQHOCOV
TargetFreqR99PsThdEcN0
Inter-freq R99 PS Target Frequency Trigger Ec/No THD
Threshold of the target frequency for triggering inter-frequency
ADD UCELLINTERFREQHOCOV
Inter-freq CS Target Frequency Trigger RSCP THD
Threshold of the target frequency for triggering inter-frequency
ADD UCELLINTERFREQHOCOV
Inter-freq HSPA Target Frequency Trigger RSCP THD
Threshold of the target frequency for triggering inter-frequency
ADD UCELLINTERFREQHOCOV
TargetFreqR99PsThdRscp
Inter-freq R99 PS Target Frequency Trigger RSCP THD
Threshold of the target frequency for triggering inter-frequency
ADD UCELLINTERFREQHOCOV
Difference between the System Frame Number (SFN) and NodeB Frame
CHIP0, CHIP256, CHIP512, CHIP768, CHIP1024, CHIP1280,
DL Primary Scrambling Code
Sequence Number of a DL primary scrambling code in a cell. For detailed
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LAC Location Area Code ADD UCELLSETUP 1~65533, 65535
SAC Service Area Code ADD UCELLSETUP 0~65535
RAC Routing Area Code ADD UCELLSETUP 0~255
CellId Cell ID ADD UCELLSETUP 0~65535
UARFCNDownlink Downlink UARFCN ADD UCELLSETUP 0~16383
Qhyst1spch 0~40, 255
Qhyst1sfach 0~40, 255
Qhyst2spch 0~40, 255
Qhyst2sfach 0~40, 255
Treselectionspch 0~31, 255
Treselectionsfach 0~31, 255
TimeToTrigForVerify 0~64000
0~65535
HsScchCodeNum 1~15
HoSwitch HandOver Switch
HoSwitch HandOver Switch
HoSwitch HandOver Switch
InterFreqFilterCoef
FilterCoefOf2D2F
InterRATFilterCoef
Identifies a location area code for a Public Land Mobile Network (PLMN) of MCC,MNC,LAC and SAC together compose the Service Area ID Identifying a routing area in a location area for a Public Land Mobile ID of a cell. For detailed information about this parameter, see Depending on the value of [Band indication], as shown below:Hysteresis 1 for UE
in CELL_PCH or URA_PCH state
This parameter indicates that in the CELL_PCH or URA_PCH
ADD UCELLSELRESEL
Hysteresis 1for UE in CELL_FACH state
This parameter indicates that in the CELL_FACH connection mode,
ADD UCELLSELRESEL
Hysteresis 2 for UE in CELL_PCH or URA_PCH state
This parameter indicates that in the CELL_PCH or URA_PCH
ADD UCELLSELRESEL
Hysteresis 2 for UE in CELL_FACH state
This parameter indicates that in the CELL_FACH connection mode,
ADD UCELLSELRESEL
Reselection delay time for UE in PCH state
This parameter indicates the UE reselection delay in the CELL_PCH or
ADD UCELLSELRESEL
Reselection delay time for UE in CELL_FACH state
This parameter indicates the UE reselection delay in the CELL_FACH
ADD UCELLSELRESEL
InterRATPeriodReportInterval
Inter-RAT Period Reporting Interval
Interval that the UE reports inter-RAT measurement results to the RNC.
ADD UCELLINTERRATHOCOV
NON_PERIODIC_REPORT(Non periodical reporting), D250~1 Time to Trigger
Handover to Verified GSM Cell
Time delay for triggering handovers to GSM cells with verified
ADD UCELLINTERRATHOCOV
InterRATPingPongTimer
Inter-RAT Ping-Pong Timer
Length of the timer to avoid ping-pong handovers between 2G and 3G
ADD UCELLINTERRATHOCOV
Code Number for HS-SCCH
This parameter decides the maximum number of subscribers that
ADD UCELLHSDPA
HandOver switch group.
SET UCORRMALGOSWITCH
HO_ALGO_HCS_SPEED_EST_SWITCH, HO_ALGO_LDR_A
HandOver switch group.
SET UCORRMALGOSWITCH
HO_ALGO_HCS_SPEED_EST_SWITCH, HO_ALGO_LDR_A
HandOver switch group.1) HO_ALGO_HCS_SPEED_EST_SWITCH: When the switch
SET UCORRMALGOSWITCH
HO_ALGO_HCS_SPEED_EST_SWITCH, HO_ALGO_LDR_AInter-frequency
Measure Filter Coeff
This parameter specifies the Layer 3 filter coefficient for the inter-frequency
ADD UCELLINTERFREQHONCOV
D0, D1, D2, D3, D4, D5, D6, D7, D8, D9, D11, D13, D15, D17, D19
2D/2F Filter Coefficient
L3 filtering coefficient for event 2D or event 2F measurement
ADD UCELLINTERRATHOCOV
D0, D1, D2, D3, D4, D5, D6, D7, D8, D9, D11, D13, D15, D17, D19
Inter-RAT Filter Coefficient
This parameter specifies the Layer 3 filter coefficient for the inter-RAT
ADD UCELLINTERRATHOCOV
D0, D1, D2, D3, D4, D5, D6, D7, D8, D9, D11, D13, D15, D17, D19
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Ericsson
W10
Baseline Value Remarks Parameter ID Meaning
0 qOffset1sn
-50 qRxLevMin
-20 bchPower
430
5 nInSyncInd
50 nOutSyncInd
50 rlFailureT
0 individualOffset
330 primaryCpichPower
NOT_RESERVED
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
NOT_BARRED accessClassNBarred
Signal strength offset between source and target cells. Minimum required (acceptable) RX level in the cell.
BCH power is the power to be used for transmitting on the BCH, relative to
maximumTransmissionPower
Maximum transmission power. This is the maximum power for Number of frames to be considered for in-sync detection.Number of frames to be considered for out-of-sync detection. Guard period before sending RL Failure. This offset is added to the measured quantity before the UE evaluates if an Power to be used for transmitting the PCPICH.
cellReserved
Indicates if this cell shall be reserved for operator use. If it is reserved, there Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level Specifies which access classes are barred for the feature Cell Level
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None
ALLOWED
D320
61
0
D500
4 hysteresis2d
4 hysteresis2f
D320 timeToTrigger2dEcno
D1280 timeToTrigger2fEcno
-14
-12
-14
-14
-12
-12
-95
-92
-95
-95
-92
-92
4 hysteresis2d
4 hysteresis2f
D320 timeToTrigger2dEcno
D1280 timeToTrigger2fEcno
D0 timeToTrigger3a
-14
Huawei suggests 0, it can improve power usage efficency and HSPA
Hysteresis for event 2d.Hysteresis for event 2f.Time between detection of event 2d and sending of the measurement Time between detection of event 2d and sending of the measurement
usedFreqThresh2dEcno+serviceOffset2dEcno usedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcno
usedFreqThresh2dEcno+serviceOffset2dEcno
usedFreqThresh2dEcno+serviceOffset2dEcno usedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcnousedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcno
usedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscp
usedFreqThresh2dRscp+serviceOffset2dRscp
usedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscp Hysteresis for event
2d.Hysteresis for event 2f.Time between detection of event 2d and sending of the measurement Time between detection of event 2d and sending of the measurement
Time between detection of event 3a and sending of the measurement
usedFreqThresh2dEcno+serviceOffset2dEcno
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-12
-15
-15
-13
-13
-100
-97
-110
-110
-107
-107
16 gsmThresh3a
16 gsmThresh3a
16 gsmThresh3a
6
6
6
12
12
12
0
0
8
D320 timeToTrigger1a
D640 timeToTrigger1b
D640 timeToTrigger1d
3 maxActiveSet
usedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcno
usedFreqThresh2dEcno+serviceOffset2dEcno
usedFreqThresh2dEcno+serviceOffset2dEcno
usedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcnousedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcno
usedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscp
usedFreqThresh2dRscp+serviceOffset2dRscp
usedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscp
Threshold for event 3a for GSM. Range is valid for GSM carrier RSSI. Threshold for event 3a for GSM. Range is valid for GSM carrier RSSI. Threshold for event 3a for GSM. Range is valid for GSM carrier RSSI.
reportingRange1a
Used by UE functions for intra-frequency measurement
reportingRange1a
Used by UE functions for intra-frequency measurement
reportingRange1a
Used by UE functions for intra-frequency measurement
reportingRange1b
Used by UE functions for intra-frequency measurement
reportingRange1b
Used by UE functions for intra-frequency measurement
reportingRange1b
Used by UE functions for intra-frequency measurement
hysteresis1a
Hysteresis used in addition-window in evaluation criteria for event 1a to
hysteresis1b
Hysteresis used in the drop window in evaluation criteria for event type 1b.
hysteresis1d
Hysteresis used in drop window in evaluation criteria for event type 1d.Time between detection of event 1a and sending of the measurement Time between detection of event 1b and sending of the measurement
Time between detection of event 1d and sending of the measurement
Maximum number of cells in active set.
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2 qHyst1
2 qHyst1
1 qHyst2
1 qHyst2
1 treSelection
-18 qQualMin
-58 qRxLevMin
5 sIntraSearch
4 sInterSearch
2 sRatSearch
-7 pichPower
-6 aichPower
10 t3212
ALLOWED att
MODE2
6 utranDrxCycleLength
D2000
3
5
6
D1
3 OK
D50
D0
D0
D1
0
-18 qQualMin
qRxLevMin
Cell reselection hysteresis used in UE functions in idle and connected Cell reselection hysteresis used in UE functions in idle and connected The hysteresis value of the serving cell. The hysteresis value of the serving cell. Control of cell selection/reselection. Time-to-trigger for cell reselection. Minimum required (acceptable) quality level in the cell (dB). Used to set Minimum required (acceptable) RX level in the cell.
The decision on when measurements on intra-frequencies The decision on when measurements on inter-frequencies The decision on when measurements on GSM frequencies
PICH power is the power to be used for transmitting on the physical AICH power, to be used for transmitting on AICH, relative to the Core Network DRX cycle length coefficient (k) for UEs in idle mode,
Indicates to the UE whether IMSI attach/detach is allowed. (Some
nmo
Network operation mode that indicates whether the Gs interface between
Huawei suggests 6, because paging delay is big when this parameter is
The DRX cycle length coefficient (k) for UEs in URA_PCH.
NOK:50, Avoid call drop,
Minimum required (acceptable) quality level in the cell (dB). Used to set
无
Minimum required (acceptable) RX level in the cell.
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None hsdschSupport
None edchSupport
0 individualOffset
0
10 maxFach1Power
STEPSIZE_1DB
6 utranDrxCycleLength
D2000
3
6
D1
D500
4 hysteresis2d
4 hysteresis2f
D320 timeToTrigger2dEcno
D1280 timeToTrigger2fEcno
-14
-12
-14
-14
-12
-12
-95
-92
-95
-95
-92
-92
Capability information indicating if HS is supported in the Capability information indicating if HS is supported in the This offset is added to the measured quantity before the UE evaluates if an
serviceRestrictions.csVideoCalls
Indicates which services are restricted in this cell.
Maximum power, to be used for transmitting the first FACH channel, We suggest
1dB.HW Power control performance for 1dB step is Huawei suggests 6, because paging delay is big when this parameter is
The DRX cycle length coefficient (k) for UEs in URA_PCH.
Hysteresis for event 2d.Hysteresis for event 2f.Time between detection of event 2d and sending of the measurement Time between detection of event 2d and sending of the measurement
usedFreqThresh2dEcno+serviceOffset2dEcno usedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcno
usedFreqThresh2dEcno+serviceOffset2dEcno
usedFreqThresh2dEcno+serviceOffset2dEcno usedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcnousedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcno
usedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscp
usedFreqThresh2dRscp+serviceOffset2dRscp
usedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscp
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0 individualOffset
0 qOffset1sn
0 qOffset2sn
-18 qQualMin
qRxLevMin
4 hysteresis2d
4 hysteresis2f
D320 timeToTrigger2dEcno
D1280 timeToTrigger2fEcno
-14
-12
-15
-15
-13
-13
-100
-97
-110
-110
-107
-107
16 gsmThresh3a
16 gsmThresh3a
16 gsmThresh3a
6
6
6
12
12
This offset is added to the measured quantity before the UE evaluates if an
Signal strength offset between source and target cells. Signal strength offset between source and target cells. used when Minimum required (acceptable) quality level in the cell (dB). Used to set
无
Minimum required (acceptable) RX level in the cell. Hysteresis for event 2d.Hysteresis for event 2f.Time between detection of event 2d and sending of the measurement Time between detection of event 2d and sending of the measurement
usedFreqThresh2dEcno+serviceOffset2dEcno usedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcnousedFreqThresh2dEcno+serviceOffset2dEcno usedFreqThresh2dEcno+serviceOffset2dEcno usedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcnousedFreqThresh2dEcno+serviceOffset2dEcno+usedFreqRelThresh2fEcnousedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscpusedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscpusedFreqThresh2dRscp+serviceOffset2dRscp+usedFreqRelThresh2fRscp
Threshold for event 3a for GSM. Range is valid for GSM carrier RSSI. Threshold for event 3a for GSM. Range is valid for GSM carrier RSSI. Threshold for event 3a for GSM. Range is valid for GSM carrier RSSI.
6=3dB,use huawei default
reportingRange1a
Used by UE functions for intra-frequency measurement
6=3dB,use huawei default
reportingRange1a
Used by UE functions for intra-frequency measurement
reportingRange1a
Used by UE functions for intra-frequency measurement
reportingRange1b
Used by UE functions for intra-frequency measurement
reportingRange1b
Used by UE functions for intra-frequency measurement
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12
0
0
8
0 w1a
D320 timeToTrigger1a
D640 timeToTrigger1b
D640 timeToTrigger1d
0 individualOffset
AFFECT
AFFECT
0 qOffset1sn
0 qOffset2sn
-20 pchPower
330 primaryCpichPower
-20
20 preambleRetransMax
2 powerOffsetP0
powerOffsetPpm
-50 primarySchPower
0
0
8 maxPreambleCycle 1..32
-50 secondarySchPower
11000
None
0 qOffset1sn
0 qOffset2sn
D3 filterCoefficient1
reportingRange1b
Used by UE functions for intra-frequency measurement
hysteresis1a
Hysteresis used in addition-window in evaluation criteria for event 1a to
hysteresis1b
Hysteresis used in the drop window in evaluation criteria for event type 1b.
hysteresis1d
Hysteresis used in drop window in evaluation criteria for event type 1d.Weight factor to include active set cells other than the best in evaluation Time between detection of event 1a and sending of the measurement
HW suggests D1280 to avoid PingPang handover.
Time between detection of event 1b and sending of the measurement
Time between detection of event 1d and sending of the measurement This offset is added to the measured quantity before the UE evaluates if an
Signal strength offset between source and target cells. Signal strength offset between source and target cells. used when
Maximum power to be used for transmitting the PCH, relative to the Power to be used for transmitting the PCPICH.
constantValueCprach
Constant value used by the UE to calculate the initial power on PRACH Maximum number of preambles in one preamble ramping cycle.
Power step when no acquisition indicator is received.In signaling
transmission mode, set PowerOffsetPpm to
Power step between preamble and the message part.Primary SCH power, relative to the primaryCpichPower
Secondary SCH power, relative to the primaryCpichPower
dchRcLostT / hsDschRcLostT
Timer that is started when all radio links for a connection are lost. At time-out, the Signal strength offset between source and target cells. Signal strength offset between source and target cells. used when Coefficient for layer 3 filtering before intra-frequency reporting
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CPICH_EC/NO measQuantity1
D16 amountOfReporting1a
D4000 4s is enough
D16 amountOfReporting1c
D4000 4s is enough
8 hysteresis1c
D640
3 maxActiveSet
0 qOffset1sn
0 qOffset2sn
5 sIntraSearch
4 sInterSearch
D3 filterCoefficient1
CPICH_EC/NO
D16 amountOfReporting1a
D4000
D16 amountOfReporting1c
D4000
8 hysteresis1c
0 w1a
D640
None
NOT_ALLOWED
D1280
0 individualOffset
20 inactivityTimerPch
Used by UE functions for intra-frequency measurements (in This parameter specifies the number of reporting times of event 1A reportingInterval1a Interval of event-triggered periodical reporting in case of 'cell addition failure' This parameter specifies the number of reporting times of event 1C
reportingInterval1c
Interval of event-triggered periodical reporting in case of 'cell addition failure'
Used by UE functions for intra-frequency measurement
timeToTrigger1c
Time between detection of event 1c and sending of the measurement Maximum number of cells in active set.
Signal strength offset between source and target cells. Signal strength offset between source and target cells. used when
The decision on when measurements on intra-frequencies The decision on when measurements on inter-frequencies Coefficient for layer 3 filtering before intra-frequency reporting
measQuantity1
Used by UE functions for intra-frequency measurements (in This parameter specifies the number of reporting times of event 1A
reportingInterval1a
Interval of event-triggered periodical reporting in case of 'cell addition failure' This parameter specifies the number of reporting times of event 1C
reportingInterval1c
Interval of event-triggered periodical reporting in case of 'cell addition failure'
Used by UE functions for intra-frequency measurement Weight factor to include active set cells other than the best in evaluation
timeToTrigger1c
Time between detection of event 1c and sending of the measurement
This offset is added to the measured quantity before the UE evaluates if an
DRA_AQM_SWITCH:OFF, DRA_BASE_ADM_CE_BE_TTI_L2_O
HW suggests DRA_HSDPA_DL_FLOW_CONTROL_SWITCH:OFF
DRA_AQM_SWITCH:OFF, DRA_BASE_ADM_CE_BE_TTI_L2_O
HW suggests DRA_HSDPA_DL_FLOW_CONTROL_SWITCH:OFF
DRA_AQM_SWITCH:OFF, DRA_BASE_ADM_CE_BE_TTI_L2_O
HW suggests DRA_HSDPA_DL_FLOW_CONTROL_SWITCH:OFF
Time after which a connection in URA_PCH state is switched down to
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20 inactivityTimerPch
20 inactivityTimerPch
20 inactivityTimerPch
D5000
D5000
65535 inactivityTimer
D1024
D0
180
5 downswitchTimer
5 OK,5->20 hsdschInactivityTimer
None
None
-12
-12
-12
-92
-92
-92
-12
-12
-12
-92
-92
-92
None tCell
None primaryScramblingCode
Time after which a connection in URA_PCH state is switched down to Time after which a connection in URA_PCH state is switched down to Time after which a connection in URA_PCH state is switched down to HW suggests a
bigger trigger timer to prevent PingPang D2F HW suggests a bigger value to prevent PingPong F2P.because there are big delay for data transmission if UE is in PCH status, so
Time after which an inactive connection in CELL_FACH state is
ulRlcBufUpswitch/dlRlcBufUpswitch
Uplink RLC buffer threshold for upswitching from FACH/RACH to dedicated channel.
HW suggests D0 because it can speed up data transmission and
Time after which a downlink radio bearer on DCH with low throughput is Time after which a connection with low throughput is downswitched from
NonUsedFreqThresh4_2bEcno+ serviceOffset2dEcno
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bEcno+ serviceOffset2dEcno
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bEcno+ serviceOffset2dEcno
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bRscp+ serviceOffset2dRscp
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bRscp+ serviceOffset2dRscp
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bRscp+ serviceOffset2dRscp
Defines the threshold for event 2b for the non-used frequency when NonUsedFreqThresh4_
2bEcno+ serviceOffset2dEcno
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bEcno+ serviceOffset2dEcno
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bEcno+ serviceOffset2dEcno
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bRscp+ serviceOffset2dRscp
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bRscp+ serviceOffset2dRscp
Defines the threshold for event 2b for the non-used frequency when
Threshold for InterFrequency HO should be discussed in
NonUsedFreqThresh4_2bRscp+ serviceOffset2dRscp
Defines the threshold for event 2b for the non-used frequency when
Timing delay used for defining start of SCH, CPICH and the downlink The primary downlink scrambling code to be used in the external cell.
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None lac
None sac
None rac
None cId
None uarfcnDl
255
255
255
255
255
255
D1000
0
0
4 numHsScchCodes
fddIFHOSupp
fddGsmHOSupp
fddGsmHOSupp
filterCoeff4_2b
D3 filterCoefficient2
D3 gsmFilterCoefficient3
The Location Area Code of the external GSM cell. MBMS Service Area Code.Routing Area Code of a routing area. An RA is used by UTRAN to page Cell identity. Unique in the RNC. Downlink UTRA Absolute Radio Frequency Channel Number. Specifies
Parameter that determines how many HS-SCCH’s that shall be
HO_ALGO_HCS_SPEED_EST_SWITCH:OFF, HO_ALGO_LDR_A
We suggest HO_MC_SIGNAL_SWITCH:OFF, HO_ALGO_OVERL
Indicates if the RNC supports IFHO.
HO_ALGO_HCS_SPEED_EST_SWITCH:OFF, HO_ALGO_LDR_A
We suggest HO_MC_SIGNAL_SWITCH:OFF, HO_ALGO_OVERL
Indicates if the RNC supports Inter RAT Handover. HO_ALGO_HCS_S
PEED_EST_SWITCH:OFF, HO_ALGO_LDR_A
We suggest HO_MC_SIGNAL_SWITCH:OFF, HO_ALGO_OVERL
Indicates if the RNC supports Inter RAT Handover.
For low speed(5km/h):Range is D4~D6, the recommended
Coefficient for layer 3 filtering before inter-frequency reporting
Coefficient for layer 3 filtering before inter-frequency measurement Coefficient for layer 3 filtering of GSM quality before inter-RAT reporting
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Ericsson
W10
Parameter Value Range Recommended Value Mapping Rule Remark
-50..50 7 Use the Ericsson value.
-115..-25 100 Use the Ericsson value.
-350..150 -31 Use the Ericsson value.
0..500 400
1..256 3
1..256 10
0..255 10
-50..50 0 Use the Ericsson value.
-100..500 300
NOT_RESERVED
Check which value is used in the live network. For details, see the Notes sheet.
If the Ericsson value is smaller than the Huawei baseline value, use the Ericsson value. Otherwise, use the Huawei baseline value.If the Ericsson value is larger than the Huawei baseline value, use the Ericsson value. Otherwise, use the Huawei baseline value.If the Ericsson value is larger than the Huawei baseline value, use the Ericsson value. Otherwise, use the Huawei baseline value.
Check which value is used in the live network. For details, see the Notes sheet.
NOT_RESERVED;RESERVED
Huawei E//RESERVED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the first Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the second Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the third Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the fourth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the fifth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the sixth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the seventh Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the eighth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the ninth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the tenth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the eleventh Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the twelfth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the thirteenth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the fourteenth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the fifteenth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True),FALSE(OR True)
FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE,FALSE
Use the sixteenth Ericsson value.Huawei EBARRED 1NOT_BARRED 0
document.xls 文档密级:
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Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
0..29 0 Use the Ericsson value.
0..29 0 Use the Ericsson value.
320 huawei<===>D(ERICSSON)
1280 huawei<===>D(ERICSSON)
0..29 0 Use the Ericsson value.
0..29 0 Use the Ericsson value.
320 huawei<===>D(ERICSSON)
1280 huawei<===>D(ERICSSON)
0..15 6 Use the Ericsson value.
Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.
0..0 10..10 20..20 40..40 60..60 80..80 100..100 120..120 160..160 200..200 240..240 320..320 640..640 1280..1280 2560..2560 5000..5000
0..0 10..10 20..20 40..40 60..60 80..80 100..100 120..120 160..160 200..200 240..240 320..320 640..640 1280..1280 2560..2560 5000..5000
If the sum of the value of serviceOffset2dEcno for <es:userLabel>Speech</es:userLabel> and the value of If the sum of the value of serviceOffset2dEcno for <es:userLabel>Speech</es:userLabel>, the value of If the sum of the value of serviceOffset2dEcno for <es:userLabel>Packet 64/64</es:userLabel> and the If the sum of the value of serviceOffset2dEcno for <es:userLabel>Packet 64/64</es:userLabel> and the If the sum of the value of serviceOffset2dEcno for <es:userLabel>Packet 64/64</es:userLabel>, the value of If the sum of the value of serviceOffset2dEcno for <es:userLabel>Packet 64/64</es:userLabel>, the value of If the sum of the value of serviceOffset2dRscp for <es:userLabel>Speech</es:userLabel> and the value of If the sum of the value of serviceOffset2dRscp for <es:userLabel>Speech</es:userLabel>, the value of If the sum of the value of serviceOffset2dRscp for <es:userLabel>Packet 64/64</es:userLabel> and the If the sum of the value of serviceOffset2dRscp for <es:userLabel>Packet 64/64</es:userLabel> and the If the sum of the value of serviceOffset2dRscp for <es:userLabel>Packet 64/64</es:userLabel>, the value of If the sum of the value of serviceOffset2dRscp for <es:userLabel>Packet 64/64</es:userLabel>, the value of
0..0 10..10 20..20 40..40 60..60 80..80 100..100 120..120 160..160 200..200 240..240 320..320 640..640 1280..1280 2560..2560 5000..5000
0..0 10..10 20..20 40..40 60..60 80..80 100..100 120..120 160..160 200..200 240..240 320..320 640..640 1280..1280 2560..2560 5000..5000
If the sum of the value of serviceOffset2dEcno for <es:userLabel>Speech</es:userLabel> and the value of
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-115..0 -95
-115..0 -95
-115..0 -95
0..29 6 Use the Ericsson value.
0..29 6 Use the Ericsson value.
0..29 6 Use the Ericsson value.
0..29 6 Use the Ericsson value.
0..29 6 Use the Ericsson value.
0..29 10 Use the Ericsson value.
0..15 0 Use the Ericsson value.
0..15 0 Use the Ericsson value.
0..15 15 Use the Huawei baseline value.
0..15 11
0..15 12
0..15 14 Use the Huawei baseline value.
2..4 3 Use the Huawei baseline value.
If the sum of the value of serviceOffset2dEcno for <es:userLabel>Speech</es:userLabel>, the value of If the sum of the value of serviceOffset2dEcno for <es:userLabel>Packet 64/64</es:userLabel> and the If the sum of the value of serviceOffset2dEcno for <es:userLabel>Packet 64/64</es:userLabel> and the If the sum of the value of serviceOffset2dEcno for <es:userLabel>Packet 64/64</es:userLabel>, the value of If the sum of the value of serviceOffset2dEcno for <es:userLabel>Packet 64/64</es:userLabel>, the value of If the sum of the value of serviceOffset2dRscp for <es:userLabel>Speech</es:userLabel> and the value of If the sum of the value of serviceOffset2dRscp for <es:userLabel>Speech</es:userLabel>, the value of If the sum of the value of serviceOffset2dRscp for <es:userLabel>Packet 64/64</es:userLabel> and the If the sum of the value of serviceOffset2dRscp for <es:userLabel>Packet 64/64</es:userLabel> and the If the sum of the value of serviceOffset2dRscp for <es:userLabel>Packet 64/64</es:userLabel>, the value of If the sum of the value of serviceOffset2dRscp for <es:userLabel>Packet 64/64</es:userLabel>, the value of If the Ericsson value is smaller than -110, use the value 0; If the Ericsson value is larger than -47, use the value 63.If the Ericsson value is smaller than -110, use the value 0; If the Ericsson value is larger than -47, use the value 63.If the Ericsson value is smaller than -110, use the value 0; If the Ericsson value is larger than -47, use the value 63.
Huawei E
Huawei E
The Ericsson value is 3 as well.
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0..40 4 Huawei<=>E/2
0..40 4 Huawei<=>E/2
0..40 4 Huawei<=>E/2
0..40 4 Huawei<=>E/2
0..31 2 Use the Ericsson value.
-24..0 100 Use the Ericsson value.
-115..-25 100
0..27 0
0..27 0
-32..20 4 Huawei<=>E/2
-10..5 -7 Use the Ericsson value.
-22..5 -6 Use the Ericsson value.
0..255 10 Use the Ericsson value.
0 1
MODE_I,MODE_II MODE_II Use the Ericsson value.
3..9 5 Use the Ericsson value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
-24..0 100
-115..-25 100 Use the Ericsson value.
If rxlevnminExtSup is set to True and (Ericsson value - 1)/2 is smaller than the Huawei value, use the following formula:Huawei E127 0Huawei E127 0
Huawei E// ALLOWED IMSI attach
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Huawei ECPICH_ECNO 2
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0 OFF
0 OFF
-50..50 0 Use the Ericsson value.
FALSE;True 0 Use the Ericsson value.
-350..150 18
Use the Huawei baseline value.
3..9 5 Use the Ericsson value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
0..29 0 Use the Huawei baseline value.
0..29 0 Use the Huawei baseline value.
320 Use the Huawei baseline value.
1280 Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
HUAWEI ERICSSONHSDSCH_SUPPORT-0 0 HSDSCH_SUPPORT-1 1
HUAWEI ERICSSONEDCH_SUPPORT-0 0 EDCH_SUPPORT-1 1
If the Ericsson value is larger than the Huawei baseline value, use the Ericsson value. Otherwise, use the Huawei baseline value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter.
0..0 10..10 20..20 40..40 60..60 80..80 100..100 120..120 160..160 200..200 240..240 320..320 640..640 1280..1280 2560..2560 5000..5000
0..0 10..10 20..20 40..40 60..60 80..80 100..100 120..120 160..160 200..200 240..240 320..320 640..640 1280..1280 2560..2560 5000..5000
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-50..50 0 Use the Ericsson value.
-50..50 7 Use the Ericsson value.
-50..50 0 Use the Ericsson value.
-24..0 100 Use the Ericsson value.
-115..-25 100 Use the Ericsson value.
0..29 0 Use the Huawei baseline value.
0..29 0 Use the Huawei baseline value.
320 Use the Huawei baseline value.
1280 Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
-115..0 -95 Use the Huawei baseline value.
-115..0 -95 Use the Huawei baseline value.
-115..0 -95 Use the Huawei baseline value.
0..29 6 Use the Huawei baseline value.
0..29 6 Use the Huawei baseline value.
0..29 6 Use the Huawei baseline value.
0..29 6 Use the Huawei baseline value.
0..29 6 Use the Huawei baseline value.
0..0 10..10 20..20 40..40 60..60 80..80 100..100 120..120 160..160 200..200 240..240 320..320 640..640 1280..1280 2560..2560 5000..5000
0..0 10..10 20..20 40..40 60..60 80..80 100..100 120..120 160..160 200..200 240..240 320..320 640..640 1280..1280 2560..2560 5000..5000
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0..29 10 Use the Huawei baseline value.
0..15 0 Use the Huawei baseline value.
0..15 0 Use the Huawei baseline value.
0..15 15 Use the Huawei baseline value.
0..20 0 Use the Huawei baseline value.
0..15 11 Use the Huawei baseline value.
0..15 12 Use the Huawei baseline value.
0..15 14 Use the Huawei baseline value.
-50..50 0 Use the Ericsson value.
Use the Huawei baseline value.
Use the Huawei baseline value.
-50..50 7 Use the Ericsson value.
-50..50 0 Use the Ericsson value.
-350..150 -4 Use the Ericsson value.
-100..500 300
-35..-10 -19 Use the Ericsson value.
1..64 8 Use the Ericsson value.
1..8 3 Use the Ericsson value.
-5..10 -4 Use the Huawei baseline value.
-350..150 -18 Use the Ericsson value.
Use the Huawei baseline value.
Use the Huawei baseline value.
4 Use the Ericsson value.
-350..150 -35 Use the Ericsson value.
0..100 50
Use the Huawei baseline value.
-50..50 7 Use the Huawei baseline value.
-50..50 0 Use the Huawei baseline value.
2 HUAWEI<==>D(ERICSSON)
Ericsson does not have such a parameter.Ericsson does not have such a parameter.
Check which value is used in the live network. For details, see the Notes sheet.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Ericsson does not have such a parameter, but the Ericsson value for this parameter can be obtained by tracing system messages of UEs in idle state. With the traced value, onsite personnel can determine which value can map onto the Ericsson value.
Maximum number of preamble ramping cycle.
If the Ericsson value for dchRcLostT or hsDschRcLostTis larger than the Huawei baseline value, use the Ericsson value.
Ericsson does not have such a parameter.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
0..9 11..11 13..13 15..15 17..17 19..19
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0 CPICH_EC_NO Use the Huawei baseline value.
Infinity Use the Huawei baseline value.
0..7 3 Use the Huawei baseline value.
Infinity Use the Huawei baseline value.
0..7 3 Use the Huawei baseline value.
0..15 2 Use the Huawei baseline value.
0..15 11 Use the Huawei baseline value.
2..4 3 Use the Huawei baseline value.
-50..50 7 Use the Huawei baseline value.
-50..50 0 Use the Huawei baseline value.
0..27 0 Use the Huawei baseline value.
0..27 0 Use the Huawei baseline value.
2 Use the Ericsson value.
0 CPICH_EC_NO Use the Huawei baseline value.
Infinity Use the Huawei baseline value.
0..7 3 Use the Huawei baseline value.
Infinity Use the Huawei baseline value.
0..7 3 Use the Huawei baseline value.
0..15 2 Use the Huawei baseline value.
0..20 0 Use the Huawei baseline value.
0..15 11 Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
-50..50 0 Use the Ericsson value.
0..240 30 Use the Huawei baseline value.
1, 2, 4, 8, 16, 32, 64, INFINITY
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
1, 2, 4, 8, 16, 32, 64, INFINITY
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
The Ericsson value is 3 as well.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
0..9 11..11 13..13 15..15 17..17 19..19
1, 2, 4, 8, 16, 32, 64, INFINITY
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
1, 2, 4, 8, 16, 32, 64, INFINITY
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
The Ericsson value is 0 as well.
Because the Ericsson value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the Ericsson buffering mechanism. If the Ericsson value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.
HUAWEI E//OFF downswitchTimer=0
Ericsson does not have such a parameter.HUAWEI E//
OFF downswitchTimer=0
Ericsson does not have such a parameter.HUAWEI E//
OFF downswitchTimer=0
Ericsson does not have such a parameter.
You should consider whether the PCH state transition switch has been turned on when setting a value for this parameter. It is recommended that the Huawei baseline value be used because we do not know whether the PCH state transition switch has been turned on.
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0..240 30 Use the Huawei baseline value.
0..240 30 Use the Huawei baseline value.
0..240 30 Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
1..1440 120 Use the Huawei baseline value.
256
Use the Huawei baseline value.
Use the Huawei baseline value.
20 0..2000 Use the Ericsson value.
2 1..255 7200..7200 Use the Ericsson value.
Use the Huawei baseline value.
-24..0 -13 Use the Huawei baseline value.
-24..0 -13 Use the Huawei baseline value.
-24..0 -13 Use the Huawei baseline value.
-115..25 -105 Use the Huawei baseline value.
-115..25 -105 Use the Huawei baseline value.
-115..25 -105 Use the Huawei baseline value.
-24..0 -13
-24..0 -13
-24..0 -13
-115..25 -105
-115..25 -105
-115..25 -105
0..9 0
0..511 0 Use the Ericsson value.
You should consider whether the PCH state transition switch has been turned on when setting a value for this parameter. It is recommended that the Huawei baseline value be used because we do not know whether the PCH state transition switch has been turned on.
You should consider whether the PCH state transition switch has been turned on when setting a value for this parameter. It is recommended that the Huawei baseline value be used because we do not know whether the PCH state transition switch has been turned on.
You should consider whether the PCH state transition switch has been turned on when setting a value for this parameter. It is recommended that the Huawei baseline value be used because we do not know whether the PCH state transition switch has been turned on.
Ericsson does not have such a parameter.Ericsson does not have such a parameter.8..8 16..16 32..32
64..64 128..128 256..256 512..512 1024..1024 2048..2048 3072..3072 4096..4096 6144..6144 8192..8192
Find the Ericsson values for ulRlcBufUpswitch and dlRlcBufUpswitch, select the larger value, and choose a Huawei value closest to the larger value.
Ericsson does not have such a parameter.Ericsson does not have such a parameter.
Check which value is used in the live network. For details, see the Notes sheet.
Use the sum of the value of serviceOffset2dEcno for <es:userLabel>Speech 12200</es:userLabel> and the Use the sum of the value of serviceOffset2dEcno for <es:userLabel>384/384</es:userLabel> and the value of Use the sum of the value of serviceOffset2dEcno for <es:userLabel>384/384</es:userLabel> and the value of Use the sum of the value of serviceOffset2dRscp for <es:userLabel>Speech 12200</es:userLabel> and the Use the sum of the value of serviceOffset2dRscp for <es:userLabel>384/384</es:userLabel> and the value of Use the sum of the value of serviceOffset2dRscp for <es:userLabel>384/384</es:userLabel> and the value of Huawei E//CHIP0 0
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0 Use the Ericsson value.
0..65535 0 Use the Ericsson value.
0..255 0 Use the Ericsson value.
0..65535 0 Use the Ericsson value.
0..16383 0 Use the Ericsson value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
1..4 1 Use the Ericsson value.
0;1 -
0;1 -
0;1 -
2 HUAWEI<==>D(ERICSSON)
2HUAWEI<==>D(ERICSSON)
1 HUAWEI<==>D(ERICSSON)
1..65533 65535..65535
Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.Ericsson does not have such a parameter.
Huawei ERICSSONHO_INTER_FREQ_HARD_HO_SWITCH-0 0 Huawei ERICSSON HO_INTER_RAT_CS_OUT_SWITCH-0 0 Huawei ERICSSON HO_INTER_RAT_PS_OUT_SWITCH-0 0
0..9 11..11 13..13 15..15 17..17 19..19
0..9 11..11 13..13 15..15 17..17 19..19
0..9 11..11 13..13 15..15 17..17 19..19
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NSN
RU10
Parameter ID Meaning
AdjgQoffset1 0 dB
AdjgQrxlevMin -115 dBm
PtxPrimaryCCPCH -5dbm
PtxCellMax 43 dBm
PtxPrimaryCPICH 33 dBm
Cell_Reserved
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
ACBarredList 0
Parameter Value Range
Recommended Value
This parameter is used in the cell re-selection and ranking between WCDMA and GSM cells. The value of this parameter is subtracted from the measured GSM carrier RSSI of the neighbouring cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
Determines the minimum required RSSI level which the measurement result of the GSM neighbour cell must exceed before the cell re-selection becomes possible./nThis parameter is part of System Information Block 11&12.
-115...-25 dBm, step 2 dBm
This is the transmission power of the primary CCPCH relative to the CPICH transmission power. The P-CCPCH is a fixed rate (15 ksps, SF = 256) downlink physical channel used to carry the BCH. It is a pure data channel and characterized by a fixed channelisation code (Cch,256,1). The P-CCPCH is broadcast over the entire cell and it is not transmitted during the first 256 chips of each slot, where Primary SCH and Secondary SCH are transmitted. Note: Changing the parameter value will start the cell shutdown procedure in the BTS.
-35...15 dB, step 0.1 dB
This parameter defines the maximum transmission power of the cell. The maximum transmission power is the maximum value for the linear sum of the power of all downlink physical channels that is allowed to be used in a cell. The maximum transmission power of the cell is the minimum of the two parameters: PtxCellMax and MaxDLPowerCapability (the maximum BTS power capability). The RNC signals the BTS the minimum value as the maximum transmission power in Maximum Transmission Power IE (TS 25.433). The RNC uses the minimum value as the maximum transmission power of the cell. If HSDPA static resource allocation is active, the value of the PtxMaxHSDPA parameter added with the value of the PtxTargetHSDPA parameter must not exceed the cell maximum transmission power defined by the minimum of the following parameters: PtxCellMax and MaxDLPowerCapability. Otherwise Rthe NC internally limits the HSDPA power.
0...50 dBm, step 0.1 dBm
This is the transmission power of the primary common pilot channel. The P-CPICH physical channel carries the common pilots of the cell, which is defined in the cell setup. The transmission power of the CPICH physical channel defines the actual cell size, which means that the power is determined by radio network planning. This parameter is used, for example, for neighbour measurements - critical for the network performance. The default value is 5-10% of the maximum transmitting power of WCDMA BTS, which can be, for example, 43 dBm/carrier. Note: Changing the parameter value will start the cell shutdown procedure in the BTS. Note: The cell is blocked if the WCDMA BTS does not support the used value. Typical supported range is (Cell max power - 18dB)..(Cell max power - 3dB). This parameter is part of System Information Block 5.
-10...50 dBm, step 0.1 dBm
Defines whether the cell is reserved for operator use or not. A reserved cell is a cell on which camping is not allowed, except for particular UEs, if so indicated./nWhen cell status is 'not barred' and 'not reserved' for operator use the UE may select//re-select this cell during the cell selection and cell re-selection procedures in Idle mode and in Connected mode./nWhen cell status is 'not barred' and 'reserved' for operator use, the UEs assigned to Access Class 11 or 15 may select//re-select this cell if in the home PLMN. UEs assigned to Access Class in the range 0 to 9 and 12 to 14 shall behave as if cell status 'barred' is indicated./nThis parameter is part of System Information Block 3.
Reserved (0), Not reserved (1)
Not reserved (1)
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
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CellBarred
IntraFreq_Cell_Reselect_Ind Allowed (0)
Tbarred 40 s (2)
PrxNoise -101.9 dBm
PtxMaxHSDPA 38.5 dBm
InterFreqMeasRepInterval 0.5 s (2)
HHoEcNoTimeHysteresis 100 ms (6)
HHoEcNoCancelTime 100 ms (6)
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoCancel -24~0 -9dbm
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoCancel -24~0 -9dbm
HHoEcNoCancel -24~0 -9dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpCancel -115~-25 -102dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpCancel -115~-25 -102dbm
HHoRscpCancel -115~-25 -102dbm
HHoEcNoTimeHysteresis 100 ms (6)
HHoEcNoCancelTime
HHoEcNoThreshold -24~0 -12dbm
Defines whether the cell is barred or not./nA barred cell is a cell where a UE is not allowed to camp on. Emergency calls shall be allowed in all cells whose barred status is 'not barred'. When cell status is 'barred', the UE is not permitted to select//re-select the cell, not even for emergency calls./nThis parameter is part of System Information Block 3.
Barred (0), Not barred (1)
Not barred (1)
Defines whether intra-frequency cell re-selection is allowed or not when the cell is barred./nWhen a cell's status is 'barred', the UE is not permitted to select//re-select this cell, except in some cases for an emergency call. If the 'Intra-frequency cell re-selection indicator' is set to value 'allowed', the UE may select another cell on the same frequency if selection//re-selection criteria are fulfilled. If the 'Intra-frequency cell re-selection indicator' is set to 'not allowed' the UE shall not re-select even a different cell on the same frequency as the barred cell. For emergency call, the Intra-frequency cell re-selection indicator IE' shall be ignored. 'Intra-frequency cell re-selection indicator' is part of SIB3//4 in the case the 'cell barred' indicator is true./nThis parameter is part of System Information Block 3.
Allowed (0), Not allowed (1)
When the cell is barred, the UE must check between the time interval ‘Cell barred period’, whether the status of the barred cell has changed./nThis parameter is part of the System Information Block 3.
10 s (0), 20 s (1), 40 s (2), 80 s (3), 160 s (4), 320 s (5), 640 s (6), 1280 s (7)
Defines the noise level in the BTS digital receiver when there is no load (thermal noise + noise figure). This parameter is needed in noise rise calculations.
-130...-50 dBm, step 0.1 dBm
The parameter defines the maximum allowed HSDPA transmission power.
-10...50 dBm, step 0.1 dBm
This parameter determines the measurement reporting interval for periodical inter-frequency measurements.
0.5 s (2), 1 s (3), 2 s (4), 3 s (5), 4 s (6)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than the threshold HHoEcNoThreshold. The parameter HHoEcNoTimeHysteresis determines the time period during which the CPICH Ec/No of the active set cell must stay worse than the threshold HHoEcNoThreshold before the UE can trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. The parameter HHoEcNoCancelTime determines the time period during which the CPICH Ec/No of the active set cell must stay better than the threshold HHoEcNoCancel before the UE can trigger the reporting event 1E. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than the threshold HHoEcNoThreshold. The parameter HHoEcNoTimeHysteresis determines the time period during which the CPICH Ec/No of the active set cell must stay worse than the threshold HHoEcNoThreshold before the UE can trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. The parameter HHoEcNoCancelTime determines the time period during which the CPICH Ec/No of the active set cell must stay better than the threshold HHoEcNoCancel before the UE can trigger the reporting event 1E. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
1280 ms (13)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
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HHoEcNoCancel -24~0 -9dbm
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoCancel -24~0 -9dbm
HHoEcNoCancel -24~0 -9dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpCancel -115~-25 -102dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpCancel -115~-25 -102dbm
HHoRscpCancel -115~-25 -102dbm
AdjgRxLevMinHO 8
AdjgRxLevMinHO 8
AdjgRxLevMinHO 8
AdditionWindow 4 dB
AdditionWindow 4 dB
AdditionWindow 4 dB
DropWindow 6 dB
DropWindow 6 dB
DropWindow 6 dB
AdditionTime 100 ms (6)
DropTime 640 ms (12)
MaxActiveSetSize 2...3, step 1 3
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
-110...-47 dBm, step 1 dBm
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
-110...-47 dBm, step 1 dBm
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
-110...-47 dBm, step 1 dBm
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
When a monitored cell enters the reporting range (addition window), the cell must continuously stay within the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to add the cell into the active set (event 1A). The length of this period is controlled by the parameter Addition Time. This parameter is part of System Information Block 11/12.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
When an active set cell leaves the reporting range (drop window), the cell must continuously stay outside the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to remove the cell from the active set (event 1B). The length of this period is controlled by the parameter Drop Time. This parameter is part of System Information Block 11/12.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
This parameter determines the maximum number of cells which can participate in a soft/softer handover. Reporting deactivation threshold indicates the maximum number of cells allowed in the active set in order for the event 1A to trigger. The RNC calculates the deactivation threshold from the parameter MaxActiveSetSize: Reporting Deactivation Threshold = MaxActiveSetSize - 1 Reporting Deactivation Threshold parameter is part of System Information Block 11/12. Replacement activation threshold information element indicates the minimum number of cells allowed in the active set in order for the event 1C to trigger. The threshold equals to the maximum size of the active set which is controlled with the parameter MaxActiveSetSize. Replacement Activation Threshold parameter is part of System Information Block 11/12.
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Qhyst1 0 dB
Qhyst1 0 dB
Qhyst2 2 dB
Qhyst2 2 dB
Treselection 0...31 s, step 1 s 2 s
QqualMin -18 dB
QrxlevMin -115 dBm
Sintrasearch 10db
Sintersearch 8 dB
Ssearch_RAT 4 dB
PTxPICH -8 dB
PtxAICH -8 dB
CS_T3212 0 decihours
CSAttachDetachAllowed
PS_NMO
UTRAN_DRX_length 320 ms (5)
T302
N302 0...7, step 1 7
T309 1...8 s, step 1 s 8
T312conn 1...15 s, step 1 s 6 s
N312 4 (2)
T313 0...15 s, step 1 s 3 s
N313 20 (4)
T314 4s (2)
T315 180 s (4)
N315 1 (0)
Qhyst1 is used for TDD and GSM cells, and for FDD cells when cell selection and re-selection quality measure is set to CPICH RSCP./nThis parameter is part of System Information Block 3.
0...40 dB, step 2 dB
Qhyst1 is used for TDD and GSM cells, and for FDD cells when cell selection and re-selection quality measure is set to CPICH RSCP./nThis parameter is part of System Information Block 3.
0...40 dB, step 2 dB
Qhyst2 is used for TDD and GSM cells, and for FDD cells when cell selection and re-selection quality measure is set to CPICH ECNO./nThis parameter is part of System Information Block 3.
0...40 dB, step 2 dB
Qhyst2 is used for TDD and GSM cells, and for FDD cells when cell selection and re-selection quality measure is set to CPICH ECNO./nThis parameter is part of System Information Block 3.
0...40 dB, step 2 dB
The UE triggers the reselection of a new cell if the cell reselection criteria are fulfilled during the time interval Treselection./nThis parameter is part of System Information Block 3.
The minimum required quality level in the cell (Ec//No)./nThis parameter is part of System Information Block 3.
-24...0 dB, step 1 dB
Determines the minimum required RSSI level which the measurement result of the GSM neighbour cell must exceed before the cell re-selection becomes possible./nThis parameter is part of System Information Block 11&12.
-115...-25 dBm, step 2 dBm
The threshold for intra-frequency measurements, and for the HCS measurement rules./nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
0...20 dB, step 2 dB
The threshold for inter-frequency measurements, and for the HCS measurement rules. /nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
0...20 dB, step 2 dB
The RAT-specific threshold for inter-RAT measurement rules./nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
0...20 dB, step 2 dB
This is the transmission power of the PICH channel. It carries the paging indicators which tell the UE to read the paging message from the associated secondary CCPCH. The transmission power value is relative to the CPICH transmission power. It may depend on the number of paging indicators (PI) per frame. The following table shows the recommended values for the different cases N. PI per frame (NP), Repetition of PICH bits, Power relative to CPICH (dB): 18, 16, -10 36, 8, -10 72, 4, -8 144, 2, -5 This parameter is part of System Information Block 5.
-10...5 dB, step 1 dB
This is the transmission power of one Aquisition Indicator (AI) compared to CPICH power. If a WCDMA BTS transmits a large number of AIs, then the total power of AICH increases. The AICH consists of a repeated sequence of 15 consecutive Access Slots (AS), each one 5120 chips in length. Each access slot consists of two parts: an Acquisition Indicator (AI) part consisting of 32 real-valued symbols, and a second part, 1024 chips in length, which has no transmission and is not formally part of the AICH. This second part of the slot is reserved for possible use by CSICH, or possible future use by other physical channels. The spreading factor (SF) used for the channelisation of the AICH is 256, and the phase reference for the AICH is the P-CPICH. This parameter is part of System Information Block 5.
-22...5 dB, step 1 dB
The timeout value, in decihours (6 min), for periodic location updating. Given only for CS domain. (Part of CS domain specific NAS System information in SIB1). /nThe value 0 is used for an infinite timeout value, that is, periodic location updating is not used./nThis parameter is part of System Information Block 1.
0...255 decihours, step 1 decihours
Defines whether IMSI attach and detach are allowed or not. /n0 = MSs shall not apply IMSI attach and detach procedure, /n1 = MSs shall apply IMSI attach and detach procedure. /nParameter is given only for CS domain. (Part of CS domain specific NAS System information in SIB1.)
IMSI attach/detach not allowed (0), IMSI attach/detach allowed (1)
IMSI attach/detach allowed (1)
In Operation Mode I it is possible to have combined CS and PS side paging via SGSN. In Operation Mode II the combined paging procedure is not possible (and neither are combined attach procedures). Used only for the PS domain. NMO is part of PS CN domain specific NAS System information in System Information Block 1.
Network Mode of Operation I (0), Network Mode ofOperation II (1)
Network Mode ofOperation II (1)
The DRX cycle length used by UTRAN to count paging occasions for discontinuous reception./n(The duration of the DRX cycle is 2 <power> k frames, where 'k' is the used DRX cycle length coefficient for UTRAN.)
80 ms (3), 160 ms (4), 320 ms (5), 640 ms (6), 1280 ms (7), 2560 ms (8), 5120 ms (9)
The CELL UPDATE/URA UPDATE retransmission timer (MS timer). This parameter is part of System Information Block 1.
1000 ms (5), 1200 ms (6), 1400 ms (7), 1600 ms (8), 1800 ms (9), 2000 ms (10), 3000 ms (11), 4000 ms (12), 6000 ms (13), 8000 ms (14)
2000 ms (10)
CELL UPDATE/URA UPDATE retransmission counter (MS counter). This parameter is part of System Information Block 1.
The timer for supervising successful connection establishment in case of an inter-RAT cell re-selection (MS timer).
The timer for supervising successful establishment of a physical channel (MS timer used in idle mode).
This parameter defines the maximum number of 'in sync' indications received from L1 during the establishment of a physical channel (UE counter used in idle mode)./nThis parameter is part of System Information Block 1.
1 (0), 2 (1), 4 (2), 10 (3), 20 (4), 50 (5), 100 (6), 200 (7), 400 (8), 600 (9), 800 (10), 1000 (11)
The radio link failure timer (MS timer). This parameter is part of System Information Block 1.
This parameter defines the maximum number of successive "out of sync" indications received from L1 (MS counter). This parameter is part of System Information Block 1.
1 (0), 2 (1), 4 (2), 10 (3), 20 (4), 50 (5), 100 (6), 200 (7)
The RRC connection re-establishment timer usedfor service-types allowing notably shorter re-establishmenttimes than the UE-timer T315. Currentlythis timer is used for CS service bearers only.UEs prior 3GPP REL6 use this timer also for supervisingthe RRC connection re-establishment ofstandalone (NAS) signaling connection towardsboth the CN domains.This parameter is part of System Information Block1.
0s (0), 2s (1), 4s (2), 6s (3), 8s (4), 12s (5), 16s (6),20s (7)
The RRC connection re-establishment timer for AM bearers (UE timer). This parameter is part of System Information Block 1.
0 s (0), 10 s (1), 30 s (2), 60 s (3), 180 s (4), 600 s (5), 1200 s (6), 1800 s (7)
This parameter defines the maximum number of successive "in sync" indications received from L1 while T313 is being activated (UE counter). This parameter is part of System Information Block 1.
1 (0), 2 (1), 4 (2), 10 (3), 20 (4), 50 (5), 100 (6), 200 (7)
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PtxSCCPCH1 0 dB
1.0 dB (1)
UTRAN_DRX_length 320 ms (5)
T300
N300 0...7, step 1 3
T312 1...15 s, step 1 s 6 s
N312 4 (2)
InterFreqMeasRepInterval 0.5 s (2)
HHoEcNoTimeHysteresis 100 ms (6)
HHoEcNoCancelTime 100 ms (6)
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoCancel -24~0 -9dbm
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoCancel -24~0 -9dbm
HHoEcNoCancel -24~0 -9dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpCancel -115~-25 -102dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpCancel -115~-25 -102dbm
HHoRscpCancel -115~-25 -102dbm
This is the transmission power of the S-CCPCH channel, which carries: - a PCH (containing PCCH), a FACH (containing DCCH/BCCH/CCCH) and a FACH (containing DTCH). Or alternatively (when standalone PCH is mapped to an another S-CCPCH) carries: - a FACH (containing DCCH/BCCH/CCCH) and a FACH (containing DTCH). In both cases the spreading factor of this S-CCPCH is 64 (60 ksps) and proposed default value is 0 dB. The transmission power value is relative to the CPICH transmission power.
-35...15 dB, step 0.1 dB
DownlinkInnerLoopPCStepSize
The DL inner loop PC step size is used in normal mode by the WCDMA BTS to calculate the power increase/decrease when receiving TPC commands.
0.5 dB (0), 1.0 dB (1), 1.5 dB (2), 2.0 dB (3)
The DRX cycle length used by UTRAN to count paging occasions for discontinuous reception./n(The duration of the DRX cycle is 2 <power> k frames, where 'k' is the used DRX cycle length coefficient for UTRAN.)
80 ms (3), 160 ms (4), 320 ms (5), 640 ms (6), 1280 ms (7), 2560 ms (8), 5120 ms (9)
The RRC CONNECTION REQUEST retransmission timer (MS timer)./nThis parameter is part of System Information Block 1.
100 ms (0), 200 ms (1), 400 ms (2), 600 ms (3), 800 ms (4), 1000 ms (5), 1200 ms (6), 1400 ms (7), 1600 ms (8), 1800 ms (9), 2000 ms (10), 3000 ms (11), 4000 ms (12), 6000 ms (13), 8000 ms (14)
2000 ms (10)
RRC CONNECTION REQUEST retransmission counter (MS counter)./nThis parameter is part of System Information Block 1.
The timer for supervising successful establishment of a physical channel (MS timer used in idle mode).
This parameter defines the maximum number of 'in sync' indications received from L1 during the establishment of a physical channel (UE counter used in idle mode)./nThis parameter is part of System Information Block 1.
1 (0), 2 (1), 4 (2), 10 (3), 20 (4), 50 (5), 100 (6), 200 (7), 400 (8), 600 (9), 800 (10), 1000 (11)
This parameter determines the measurement reporting interval for periodical inter-frequency measurements.
0.5 s (2), 1 s (3), 2 s (4), 3 s (5), 4 s (6)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than the threshold HHoEcNoThreshold. The parameter HHoEcNoTimeHysteresis determines the time period during which the CPICH Ec/No of the active set cell must stay worse than the threshold HHoEcNoThreshold before the UE can trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. The parameter HHoEcNoCancelTime determines the time period during which the CPICH Ec/No of the active set cell must stay better than the threshold HHoEcNoCancel before the UE can trigger the reporting event 1E. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
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AdjiQoffset1 0 dB
AdjiQoffset2 0 dB
AdjiQqualMin -18 dB
AdjiQrxlevMin -115 dBm
HHoEcNoTimeHysteresis 100 ms (6)
HHoEcNoCancelTime
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoCancel -24~0 -12dbm
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoThreshold -24~0 -12dbm
HHoEcNoCancel -24~0 -9dbm
HHoEcNoCancel -24~0 -9dbm
HHoRscpThreshold -24~0 -9dbm
HHoRscpCancel -24~0 -9dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpThreshold -115~-25 -105dbm
HHoRscpCancel -115~-25 -102dbm
HHoRscpCancel -115~-25 -102dbm
AdjgRxLevMinHO 8
AdjgRxLevMinHO 8
AdjgRxLevMinHO 8
AdditionWindow 4 dB
AdditionWindow 4 dB
AdditionWindow 4 dB
DropWindow 6 dB
DropWindow 6 dB
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH RSCP of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH Ec//No of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
The minimum required quality level in the cell (Ec//No)./nThis parameter is part of System Information Block 3.
-24...0 dB, step 1 dB
Determines the minimum required RSSI level which the measurement result of the GSM neighbour cell must exceed before the cell re-selection becomes possible./nThis parameter is part of System Information Block 11&12.
-115...-25 dBm, step 2 dBm
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than the threshold HHoEcNoThreshold. The parameter HHoEcNoTimeHysteresis determines the time period during which the CPICH Ec/No of the active set cell must stay worse than the threshold HHoEcNoThreshold before the UE can trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. The parameter HHoEcNoCancelTime determines the time period during which the CPICH Ec/No of the active set cell must stay better than the threshold HHoEcNoCancel before the UE can trigger the reporting event 1E. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
1280 ms (13)
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
-110...-47 dBm, step 1 dBm
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
-110...-47 dBm, step 1 dBm
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
-110...-47 dBm, step 1 dBm
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
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DropWindow 6 dB
0...2, step 0.1 0
AdditionTime 100 ms (6)
DropTime 640 ms (12)
AdjsDERR No (0), Yes (1) No (0)
AdjsDERR No (0), Yes (1) No (0)
AdjsQoffset1 0 dB
AdjsQoffset2 0 dB
PtxSCCPCH1 0 dB
PtxPrimaryCPICH 33 dBm
PRACHRequiredReceivedCI -25 dB
PRACH_preamble_retrans 1...64, step 1 8
1...8 dB, step 1 dB 2 dB
2 dB
PtxPrimarySCH -3 dB
RACH_Tx_NB01min 0...50, step 1 0
RACH_Tx_NB01max 0...50, step 1 50
RACH_tx_Max 1...32, step 1 8
PtxSecSCH -3 dB
CNDomainVersion -
AdjiQoffset1 0 dB
AdjiQoffset2 0 dB
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
0...14.5 dB, step 0.5 dB
ActiveSetWeightingCoefficient
Active Set Weighting Coefficient (W) is used to weight either the measurement result of the best active set cell (M_best) or the sum of measurement results of all active set cells (M_sum) when the UE calculates the reporting range for the events 1A (cell addition) and 1B (dropping of cell). The formula is: W * M_sum + ( 1 - W )* M_best This parameter is part of System Information Block 11/12.
When a monitored cell enters the reporting range (addition window), the cell must continuously stay within the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to add the cell into the active set (event 1A). The length of this period is controlled by the parameter Addition Time. This parameter is part of System Information Block 11/12.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
When an active set cell leaves the reporting range (drop window), the cell must continuously stay outside the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to remove the cell from the active set (event 1B). The length of this period is controlled by the parameter Drop Time. This parameter is part of System Information Block 11/12.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
This parameter indicates whether the neighbouring cell is forbidden to affect the reporting range (addition/drop window) calculation, if it belongs to the active set.
This parameter indicates whether the neighbouring cell is forbidden to affect the reporting range (addition/drop window) calculation, if it belongs to the active set.
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH RSCP of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH Ec//No of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
This is the transmission power of the S-CCPCH channel, which carries: - a PCH (containing PCCH), a FACH (containing DCCH/BCCH/CCCH) and a FACH (containing DTCH). Or alternatively (when standalone PCH is mapped to an another S-CCPCH) carries: - a FACH (containing DCCH/BCCH/CCCH) and a FACH (containing DTCH). In both cases the spreading factor of this S-CCPCH is 64 (60 ksps) and proposed default value is 0 dB. The transmission power value is relative to the CPICH transmission power.
-35...15 dB, step 0.1 dB
This is the transmission power of the primary common pilot channel. The P-CPICH physical channel carries the common pilots of the cell, which is defined in the cell setup. The transmission power of the CPICH physical channel defines the actual cell size, which means that the power is determined by radio network planning. This parameter is used, for example, for neighbour measurements - critical for the network performance. The default value is 5-10% of the maximum transmitting power of WCDMA BTS, which can be, for example, 43 dBm/carrier. Note: Changing the parameter value will start the cell shutdown procedure in the BTS. Note: The cell is blocked if the WCDMA BTS does not support the used value. Typical supported range is (Cell max power - 18dB)..(Cell max power - 3dB). This parameter is part of System Information Block 5.
-10...50 dBm, step 0.1 dBm
This UL required received C/I value is used by the UE to calculate the initial output power on PRACH according to the Open loop power control procedure. This parameter defines the value of the IE Constant value, which is part of System Information Block 5. The value of the parameter depends on the propagation channel. Note: If the operator perceives a difference in DL and UL linklosses, for example when MHA is used in BTS, then this parameter can be used to compensate for it in the power of the first transmitted preamble on the PRACH.
-35...-10 dB, step 1 dB
The maximum number of preambles allowed in one preamble ramping cycle. PRACH Preamble Retrans Max is part of "PRACH power offset" which is part of "PRACH system information list" which is part of System Information Block 5&6.
PowerRampStepPRACHpreamble
The power ramp step on PRACH preamble when no acquisition indicator (AI) is detected by the UE. This parameter is part of System Information Block 5.
PowerOffsetLastPreamblePRACHmessage
The power offset between the last transmitted preamble and the control part of the PRACH message (added to the preamble power to receive the power of the message control part). This parameter is part of System Information Block 5.
-5...10 dB, step 1 dB
This is the transmission power of the primary synchronisation channel. The power level is relative to the [FDD-primary CPICH power]. The primary SCH consists of a modulated code 256 chips in length: the Primary Synchronisation Code (PSC) transmitted once every slot. The PSC is the same for every cell in the system, and it enables the downlink slot synchronisation in the cell. Note: Changing the parameter value will start the cell shutdown procedure in the BTS.
-35...15 dB, step 0.1 dB
In case that a negative acknowledgement has been received by UE on AICH a backoff timer TBO1 is started to determine when the next RACH transmission attempt will be started. The backoff timer TBO1 is set to an integer number NBO1 of 10 ms time intervals, randomly drawn within an interval 0 <= NB01min <= NBO1 <= NB01max (with uniform distribution). After TB01 has been expired, the next RACH attempt will be started. NB01min and NB01max may be set equal when a fixed delay is desired, and even to zero when no delay other than the one due to persistency is desired. NB01min is given as an integer between 0 and 50 which gives the Lower bound of the waiting time in 10ms steps. NB01min is part of "RACH transmission parameters" which is part of "PRACH system information list" which is part of System Information Block 5&6.
In case that a negative acknowledgement has been received by UE on AICH a backoff timer TBO1 is started to determine when the next RACH transmission attempt will be started. The backoff timer TBO1 is set to an integer number NBO1 of 10 ms time intervals, randomly drawn within an interval 0 <= NB01min <= NBO1 <= NB01max (with uniform distribution). After TB01 has been expired, the next RACH attempt will be started. NB01min and NB01max may be set equal when a fixed delay is desired, and even to zero when no delay other than the one due to persistency is desired. NB01max is given as an integer between 0 and 50 which gives the Upper bound of the waiting time in 10ms steps. NB01max is part of "RACH transmission parameters" which is part of "PRACH system information list" which is part of SIB5/6. This parameter is part of System Information Block 5.
Maximum number of RACH preamble cycles defines how many times the PRACH pre-amble ramping procedure can be repeated before UE MAC reports a failure on RACH transmission to higher layers. Maximum number of RACH preamble cycles is part of "RACH transmission parameters" which is part of "PRACH system information list" which is part of SIB5/6. This parameter is part of System Information Block 5.
This is the transmission power of the secondary synchronisation channel related to the Primary CPICH transmission power. The secondary SCH consists of repeatedly transmitting a length 15 sequence of modulated codes 256 chips in length. These are the Secondary Synchronisation Codes (SSC), transmitted in parallel with the primary SCH. This sequence on the secondary SCH enables the downlink frame synchronisation, and indicates, to which code group the cell downlink scrambling code belongs. Each SSC is chosen from a set of 16 different codes 256 chips in length. Note: Changing the parameter value will start the cell shutdown procedure in the BTS.
-35...15 dB, step 0.1 dB
The code that uniquely identifies the Release version of the Core Network connected to the RNC.
R99 (1), Rel4 (2), Rel5 (3), Rel6 (4)
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH RSCP of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH Ec//No of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
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AdditionReportingInterval 0.5 s (2)
0.5 s (2)
ReplacementWindow 2 dB
ReplacementTime 100 ms (6)
MaxActiveSetSize 2...3, step 1 3
AdjsQoffset1 0 dB
AdjsQoffset2 0 dB
Sintrasearch 10db
Sintersearch 8 dB
AdditionReportingInterval 0.5 s (2)
0.5 s (2)
ReplacementWindow 2 dB
0...2, step 0.1 0
CellBarred
IntraFreq_Cell_Reselect_Ind Allowed (0)
Tbarred 40 s (2)
ToCellFACHinTest No (0), Yes (1) Yes (1)
ToCellFACHinTest No (0), Yes (1) Yes (1)
ToCellFACHinTest No (0), Yes (1) Yes (1)
When a monitored cell enters the reporting range and triggers event 1A (cell addition), the UE transmits a Measurement Report to the RNC. If the RNC is not able to add the monitored cell to the active set, the UE continues reporting after the initial report by reverting to periodical measurement reporting. The parameter Addition Reporting Interval determines the interval between periodical measurement reports when such reporting is triggered by the event 1A. This parameter is part of System Information Block 11/12.
gui ==> internalNo periodical reporting ==> 00.25 s. Not allowed ==> 10.5 s ==> 21 s ==> 32 s ==> 44 s ==> 58 s ==> 616 s ==> 7
ReplacementReportingInterval
When the number of cells in the active set has reached the maximum, and a monitored cell becomes better than an active set cell, the UE transmits a When the number of cells in the active set has reachedthe maximum, and a monitored cell becomes betterthan an active set cell, the UE transmits a MeasurementReport to the RNC in order to replace the active cellwith the monitored cell (event 1C). If the RNC is notable to replace the active cell with the monitored cell,the UE continues reporting after the initial report byreverting to periodical measurement reporting. Theparameter Replacement Reporting Interval determinesthe interval of periodical measurement reports whensuch reporting is triggered by the event 1C.
gui ==> internalNo periodical reporting ==> 00.25 s. Not allowed ==> 10.5 s ==> 21 s ==> 32 s ==> 44 s ==> 58 s ==> 616 s ==> 7
When the number of cells in the active set has reached the maximum specified by the parameter MaxActiveSetSize and a monitored cell becomes better than an active set cell, the UE transmits a Measurement Report to the RNC in order to replace the active cell with the monitored cell (event 1C). The parameter Replacement Window determines the margin by which the CPICH Ec/No measurement result of the monitored cell (MNew) must exceed the CPICH Ec/No measurement result of the an active set cell (MInAS) before the UE can send the event 1C triggered Measurement Report to the RNC: MNew >= MInAs + ReplacementWindow / 2 This parameter is part of System Information Block 11/12.
0...7.5 dB, step 0.5 dB
When the number of cells in the active set has reachedthe maximum, and a monitored cell enters the reportingrange (replacement window), the monitored cell mustcontinuously stay within the reporting range for a givenperiod of time before the UE can send a MeasurementReport to the RNC in order to replace an active set cellwith the monitored cell (event 1C). The length of thisperiod is controlled by the parameter ReplacementTime.
gui ==> internal0 ms ==> 010 ms ==> 120 ms ==> 240 ms ==> 360 ms ==> 480 ms ==> 5100 ms ==> 6120 ms ==> 7160 ms ==> 8200 ms ==> 9240 ms ==> 10320 ms ==> 11640 ms ==> 121280 ms ==> 132560 ms ==> 145000 ms ==> 15
This parameter determines the maximum number of cells which can participate in a soft/softer handover. Reporting deactivation threshold indicates the maximum number of cells allowed in the active set in order for the event 1A to trigger. The RNC calculates the deactivation threshold from the parameter MaxActiveSetSize: Reporting Deactivation Threshold = MaxActiveSetSize - 1 Reporting Deactivation Threshold parameter is part of System Information Block 11/12. Replacement activation threshold information element indicates the minimum number of cells allowed in the active set in order for the event 1C to trigger. The threshold equals to the maximum size of the active set which is controlled with the parameter MaxActiveSetSize. Replacement Activation Threshold parameter is part of System Information Block 11/12.
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH RSCP of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH Ec//No of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
-50...50 dB, step 1 dB
The threshold for intra-frequency measurements, and for the HCS measurement rules./nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
0...20 dB, step 2 dB
The threshold for inter-frequency measurements, and for the HCS measurement rules. /nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
0...20 dB, step 2 dB
When a monitored cell enters the reporting range and triggers event 1A (cell addition), the UE transmits a Measurement Report to the RNC. If the RNC is not able to add the monitored cell to the active set, the UE continues reporting after the initial report by reverting to periodical measurement reporting. The parameter Addition Reporting Interval determines the interval between periodical measurement reports when such reporting is triggered by the event 1A. This parameter is part of System Information Block 11/12.
gui ==> internalNo periodical reporting ==> 00.25 s. Not allowed ==> 10.5 s ==> 21 s ==> 32 s ==> 44 s ==> 58 s ==> 616 s ==> 7
ReplacementReportingInterval
When the number of cells in the active set has reached the maximum, and a monitored cell becomes better than an active set cell, the UE transmits a When the number of cells in the active set has reachedthe maximum, and a monitored cell becomes betterthan an active set cell, the UE transmits a MeasurementReport to the RNC in order to replace the active cellwith the monitored cell (event 1C). If the RNC is notable to replace the active cell with the monitored cell,the UE continues reporting after the initial report byreverting to periodical measurement reporting. Theparameter Replacement Reporting Interval determinesthe interval of periodical measurement reports whensuch reporting is triggered by the event 1C.
gui ==> internalNo periodical reporting ==> 00.25 s. Not allowed ==> 10.5 s ==> 21 s ==> 32 s ==> 44 s ==> 58 s ==> 616 s ==> 7
When the number of cells in the active set has reached the maximum specified by the parameter MaxActiveSetSize and a monitored cell becomes better than an active set cell, the UE transmits a Measurement Report to the RNC in order to replace the active cell with the monitored cell (event 1C). The parameter Replacement Window determines the margin by which the CPICH Ec/No measurement result of the monitored cell (MNew) must exceed the CPICH Ec/No measurement result of the an active set cell (MInAS) before the UE can send the event 1C triggered Measurement Report to the RNC: MNew >= MInAs + ReplacementWindow / 2 This parameter is part of System Information Block 11/12.
0...7.5 dB, step 0.5 dB
ActiveSetWeightingCoefficient
Active Set Weighting Coefficient (W) is used to weight either the measurement result of the best active set cell (M_best) or the sum of measurement results of all active set cells (M_sum) when the UE calculates the reporting range for the events 1A (cell addition) and 1B (dropping of cell). The formula is: W * M_sum + ( 1 - W )* M_best This parameter is part of System Information Block 11/12.
When the number of cells in the active set has reached the maximum, and a monitored cell enters the reporting range (replacement window), the monitored cell must continuously stay within the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to replace an active set cell with the monitored cell (event 1C). The length of this period is controlled by the parameter Replacement Time. This parameter is part of System Information Block 11/12.
Defines whether the cell is barred or not./nA barred cell is a cell where a UE is not allowed to camp on. Emergency calls shall be allowed in all cells whose barred status is 'not barred'. When cell status is 'barred', the UE is not permitted to select//re-select the cell, not even for emergency calls./nThis parameter is part of System Information Block 3.
Barred (0), Not barred (1)
Not barred (1)
Defines whether intra-frequency cell re-selection is allowed or not when the cell is barred./nWhen a cell's status is 'barred', the UE is not permitted to select//re-select this cell, except in some cases for an emergency call. If the 'Intra-frequency cell re-selection indicator' is set to value 'allowed', the UE may select another cell on the same frequency if selection//re-selection criteria are fulfilled. If the 'Intra-frequency cell re-selection indicator' is set to 'not allowed' the UE shall not re-select even a different cell on the same frequency as the barred cell. For emergency call, the Intra-frequency cell re-selection indicator IE' shall be ignored. 'Intra-frequency cell re-selection indicator' is part of SIB3//4 in the case the 'cell barred' indicator is true./nThis parameter is part of System Information Block 3.
Allowed (0), Not allowed (1)
When the cell is barred, the UE must check between the time interval ‘Cell barred period’, whether the status of the barred cell has changed./nThis parameter is part of the System Information Block 3.
10 s (0), 20 s (1), 40 s (2), 80 s (3), 160 s (4), 320 s (5), 640 s (6), 1280 s (7)
When the test timer expires, the UE is switched to Cell_FACH state when the value of the parameter ToCellFACHinTest is 'Yes'. If the ToCellFACHinTest parameter value is 'No', an Iu Release procedure is initiated in the Cell_DCH state, and the UE is switched directly to idle mode.0 (No), 1 (Yes)
When the test timer expires, the UE is switched to Cell_FACH state when the value of the parameter ToCellFACHinTest is 'Yes'. If the ToCellFACHinTest parameter value is 'No', an Iu Release procedure is initiated in the Cell_DCH state, and the UE is switched directly to idle mode.0 (No), 1 (Yes)
When the test timer expires, the UE is switched to Cell_FACH state when the value of the parameter ToCellFACHinTest is 'Yes'. If the ToCellFACHinTest parameter value is 'No', an Iu Release procedure is initiated in the Cell_DCH state, and the UE is switched directly to idle mode.0 (No), 1 (Yes)
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0...20 s, step 1 s
2000 ms
MSActivitySupervision 29 minutes
0(0ms)
30 min
3s
3s
Tcell -
PriScrCode 0...511, step 1 -
InactivityTimerDownlinkDCH128InactivityTimerDownlinkDCH16InactivityTimerDownlinkDCH256InactivityTimerDownlinkDCH32InactivityTimerDownlinkDCH320InactivityTimerDownlinkDCH384InactivityTimerDownlinkDCH64InactivityTimerDownlinkDCH8InactivityTimerUplinkDCH128InactivityTimerUplinkDCH16InactivityTimerUplinkDCH256InactivityTimerUplinkDCH32InactivityTimerUplinkDCH320InactivityTimerUplinkDCH384InactivityTimerUplinkDCH64SignallingLinkInactivityTimerCellDCHtestTmrMACdflowthroughputTimetoTriggerEDCHMACdFlowThroughputTimetoTrigger
The time indicating how long the radio and transmission resources are reserved after silence detection on downlink DCH before release procedures. Default values: 8 kbps: 5 s 16 kbps: 5 s 32 kbps: 5 s 64 kbps: 3 s 128 kbps: 2 s 256 kbps: 2 s 320 kbps: 2 s 384 kbps: 2 s
UL_DL_activation_timer
This timer is used on MAC -c to detect idle periods on data transmission (NRT RBs and SRBs) for the UE, which is in Cell_FACH state. Based on this timer the MAC -c shall give the No_Data indication to the RRC, which further can change the state of the RRC from Cell_FACH state to the Cell_PCH state (or URA_PCH state).
50...10000 ms, step 50 ms
This timer is used in RRC states Cell_PCH and URA_PCH for supervising the inactivity of NRT RAB(s).If the parameter value is set to zero, state transition to Cell_PCH / URA_PCH state is not allowed. When inactivity is detected in Cell_FACH state, the UE will be switched to the idle mode. Range and step: 0 ... 1440 min, step 1 min
0...1440 minutes, step 1 minutes
TrafVolThresholdULLowTrafVolThresholdDLLowNASsignVolThrULNASsignVolThrDL
This parameter defines, in bytes, the threshold of data in the RLC buffers of SRB0, SRB1, SRB2, SRB3, SRB4 and all NRT RBs that triggers the uplink traffic volume measurement report, when the UE is in Cell_FACH state. Otherwise, UE sends data on RACH.This parameter is sent to the UE using an RRC:MEASUREMENT CONTROL message.
gui ==> internal8 bytes ==> 816 bytes ==> 1632 bytes ==> 3264 bytes ==> 64128 bytes ==> 128256 bytes ==> 256512 bytes ==> 5121 KB ==> 1024
TrafVolTimeToTriggerULTrafVolTimeToTriggerDL
This parameter defines, in ms, the period of time between the timing of event detection and the timing ofsending a traffic volume measurement report.This parameter is sent to the UE using an RRC: MEASUREMENT CONTROL message.
gui ==> internal0 ms ==> 010 ms ==> 1020 ms ==> 2040 ms ==> 4060 ms ==> 6080 ms ==> 80100 ms ==> 100120 ms ==> 120160 ms ==> 160200 ms ==> 200240 ms ==> 240320 ms ==> 320640 ms ==> 6401280 ms ==> 12802560 ms ==> 25605000 ms ==> 5000
CellReselectionObservingTime
The timer is set when the first Cell Update message due to 'cell reselection' is received while UE is in CELL_FACH or CELL_PCH state. In expiry of the timer, the counter MaxCellReselections is reset. Below is an example of target RRC state selection when value 3 is used for MaxCellReselections: Velocity Cell radius Cell Update Target RRC state km/h km frequency 50 10 12 minutes CELL_PCH 50 20 24 minutes CELL_PCH 75 10 8 minutes URA_PCH 75 20 16 minutes CELL_PCH 100 10 6 minutes URA_PCH 100 20 12 minutes CELL_PCH
1...60 min, step 1 minEDCHMACdFlowThroughput
AveWinMACdflowthroughputAveWin
This parameter defines the size of the sliding averaging window for the throughput measurement of the E-DCH NRT MAC-d flow. The throughput measurement measures the number of bits transmitted by the E-DCH MAC-d flow during the sliding measurement window.The value 0 of the parameter means that the E-DCH MAC-d flow throughput measurement is not performed.
0.5...10 s, step 0.5 sinternal_value = gui_value * 2
EDCHMACdFlowThroughputAveWinMACdflowthroughputAveWin
This parameter defines the size of the sliding averaging window for the throughput measurement of the E-DCH NRT MAC-d flow. The throughput measurement measures the number of bits transmitted by the E-DCH MAC-d flow during the sliding measurement window.The value 0 of the parameter means that the E-DCH MAC-d flow throughput measurement is not performed.
0.5...10 s, step 0.5 sinternal_value = gui_value * 2
Each cell in a BTS uses a System Frame Number (SFN) counter, which is the BTS Frame Number (BFN) counter delayed by a number of chips defined by the value of Tcell. Tcell is used for defining the start of SCH, CPICH, Primary CCPCH and DL Scrambling Code(s) in a cell relative to BFN. The main purpose is to avoid having overlapping SCHs in different cells belonging to the same BTS. An SCH burst is 256 chips long. The values can be chosen as follows: 0 chips for the 1st cell of the BTS, 256 chips for the 2nd cell of the BTS, 512 chips for the 3rd cell of the BTS, etc. Note: Changing the parameter value will start the cell shutdown procedure in the BTS.
0 chips (0), 256 chips (1), 512 chips (2), 768 chips (3), 1024 chips (4), 1280 chips (5), 1536 chips (6), 1792 chips (7), 2048 chips (8), 2304 chips (9)
Identifies the downlink scrambling code of the Primary CPICH (Common Pilot Channel) of the Cell. Note: Changing the parameter value will start the cell shutdown procedure in the BTS. This parameter is part of System Information Block 11.
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LAC 1...65535, step 1 -
SAC - -
RAC 0...255, step 1 -
Cid 1...65535, step 1 -
UARFCN 0...16383, step 1 -
Qhyst1PCH 0...40,step 1 -
Qhyst1FACH 0...40,step 1 -
Qhyst2PCH 0...40,step 1 -
Qhyst2FACH 0...40,step 1 -
TreselectionFACH 0...6.2,step 0.2 -
TreselectionPCH 0...31,step 1 -
GsmMeasRepInterval 0.5 s (2), 1 s (3), 2 -
GsmMeasAveWindow 1...32 -
GsmMinHoInterval 1..60 -
MaxNbrOfHSSCCHCodes 1...3 -
GsmHandoverAMR
GsmHandoverNrtPS No (0), Yes (1)
HHoRscpFilterCoefficient
This parameter contains the Location area code (LAC) of a WCDMA cell. The coding of the Location area code (two octets) is the responsibility of administration. LAI (Location Area Identification) consists of PLMNid and LAC. If LAI has to be deleted, LAC is set as 0xFFFE. This parameter is also part of System Information Block 1 and known as IE: GSM-MAP NAS system information.
The Service Area Identifier (SAI) identifies an area consisting of one or more cells which belong to the same Location Area (LAI). The Service Area Identifier is composed of the PLMN Identifier, the Location Area Code (LAC) and the Service Area Code (SAC).
The routing area code determines the Routing area within the location area to which the cell belongs to. It is used only for PS services (part of PS domain specific NAS system information in SIB1). Routing area identification (RAI) consists of LAI and RAC, LAI consists of PLMNid and LAC. This parameter is part of System Information Block 1.
The parameter identifies the cell within a RNC. This parameter is part of System Information Block 3.
The carrier frequency is designated by the parameter UTRA Absolute Radio Frequency Channel Number (UARFCN). This parameter defines the downlink channel number. The uplink channel number is calculated by the RNC based on a duplex distance used in the RF band. The relation between UARFCN (Nd) and the corresponding carrier frequency (Fdownlink [MHz]) in RF bands I, II and V is defined with the following equations: Fdownlink = 0.2 * Nd MHz Nd = 5 * Fdownlink The relation between the UARFCN (Nd) additional channel and the corresponding carrier frequency (Fdownlink [MHz]) in RF band II is defined with the following equations: Fdownlink = (1850.1 + 0.2 * Nd) MHz Nd = 5 * (Fdownlink - 1850.1 MHz) The relation between the UARFCN (Nd) additional channel and the corresponding carrier frequency (Fdownlink [MHz]) in RF band V is defined with the following equations: Fdownlink = (670.1 + 0.2 * Nd) MHz Nd = 5 * (Fdownlink - 670.1 MHz) Downlink RF band I is 2110 - 2170 MHz. Downlink RF band II is 1930 - 1990 MHz. Downlink RF band V is 869 - 894 MHz. Allowed channel numbers (Nd) in RF band I are: 10562 - 10838. Allowed channel numbers (Nd) in RF band II are: 9663 - 9712, 9763 - 9812, 9888 - 9937. Allowed additional channel numbers (Nd) in RF band II are: 412, 437, 462, 487, 512, 537, 562, 587, 612, 637, 662, 687. Allowed channel numbers (Nd) in RF band V are: 4357 - 4458. Allowed additional channel numbers (Nd) in RF band V are: 1007, 1012, 1032, 1037, 1062, 1087. The duplex distance is 190 MHz in RF band I, 80 MHz in RF band II and 45 MHz in RF band V. This parameter is part of System Information Block 5.
The parameter is used for cell selection and reselectionin Cell_PCH/URA_PCH.Qhyst1PCH is used for TDD and GSM cells, and forFDD cells when cell selection and re-selectionquality measure is set to CPICH RSCP.This is hysteresis between WCDMA and GSMcells. Hysteresis is not needed because negativeoffset is used.
The parameter is used for cell selection and reselectionin Cell_FACH.The parameter is used for TDD and GSM cells, andfor FDD cells when cell selection and re-selectionquality measure is set to CPICH RSCP.This is hysteresis between WCDMA and GSMcells. Hysteresis is not needed because negativeoffset is used.
The parameter is used for cell selection and reselectionin Cell_PCH/URA_PCH.The parameter is used for FDD cells when cellselection and re-selection quality measure is set toCPICH Ec/No.2dB hysteresis between WCDMA cells can be usedin urban environment to avoid ping-pong.0dB hysteresis can be used in areas of high mobilitylike highways.
The parameter is used for FDD cells when cellselection and re-selection The parameter is usedfor cell selection and re-selection in Cell_FACH.The parameter is used for FDD cells when cellselection and re-selection quality measure is set toCPICH Ec/No.2dB hysteresis between WCDMA cells can be usedin urban environment to avoid ping-pong. 0dB hysteresiscan be used in areas of high mobility likehighways.
This parameter is used for cell selection and reselectionin Cell_FACH.The UE triggers the reselection of a new cell if thecell reselection criteria are fulfilled during the timeinterval TreselectionFACH.The reselection time of 2s may avoid too many cellreselections between cells and hence LA/RAupdates when crossing the LA/RA border. Thus,there are less signalling and less call failures at theLA/RA border due to the LA/RA update. The reselectiontime of 0s can be used in areas of highmobility, such as highways.
selectionin Cell_PCH/URA_PCH.The UE triggers the reselection of a new cell if thecell reselection criteria are fulfilled during the timeinterval TreselectionPCH.The reselection time of 2s may avoid too many cellreselections between cells and hence LA/RAupdates when crossing the LA/RA border. Thus,there are less signalling and less call failures at theLA/RA border due to the LA/RA update. The reselectiontime of 0s can be used in areas of highmobility, such as highways.
This parameter determines the measurementreporting interval for periodical inter-RAT (GSM)measurements.
This parameter determines the maximum numberof periodical inter-RAT (GSM) measurementreports (maximum size of the sliding averagingwindow) from which the RNC calculates theaveraged GSM RSSI values for the handoverdecision algorithm.
This parameter determines the minimum intervalbetween a successful inter-RAT handover fromGSM to UTRAN and the following inter-RAThandover attempt back to GSM related to the sameRRC connection.
This parameter defines the maximum number ofHS-SCCH codes (SF 128) that can be reserved inone cell.More than one HS-SCCH code can be used if theHSDPA code multiplexing functionality is in use.The actual number of reserved codes depends onfor example HSDPA capabilities and HSDPA codemultiplexing support (RNC and BTS).
This parameter indicates whether an inter-RAThandover to GSM is allowed for circuit switched(CS) voice services. The alternative values of theparameter are the following:- No; handover to GSM is not allowed for CS voiceservices. The handover is also prohibited if a CSvoice service is a part of multiservice.- Yes; handover to GSM is allowed for CS voice services.In case of multiservice, a handover to GSMmust be allowed for all CS and PS services whichparticipate in the multiservice before the handoveris possible.- Priority; handover to GSM is allowed for CS voiceservices. The handover is also allowed if a CS voiceservice is a part of multiservice.
No (0), Yes (1), Priority (2)
This parameter indicates whether an inter-RAThandover (cell change) to GSM/GPRS is allowedfor non-real time packet switched (PS) dataservices in CELL_DCH state of connected mode.The alternative values of the parameter are the following:- No; cell change to GSM/GPRS is not allowed fornon-real time PS data services. The handover/cellchange to GSM/GPRS is also prohibited if a nonrealtime PS data service is a part of multiservice.- Yes; cell change to GSM/GPRS is allowed fornon-real time PS data services. In case of multiservice,a handover/cell change to GSM/GPRS mustbe allowed for all CS and PS services which participatein the multiservice before the handover/cellchange is possible.The parameters GsmHandoverAMR and/orGsmHandoverCS for CS data/voice services canoverrule the value of the parameter GsmHandoverNrtPSin case of multiservice. If either CSvoice and/or data services are prioritized, the RNCshall execute the handover to GSM even if the cellchange to GSM/GPRS is not allowed for non-realtime PS data services.
In the CELL_DCH state the UE physical layer measurementperiod for intra-frequency CPICH RSCPmeasurements is 200 ms. The Filter Coefficientparameter controls the higher layer filtering ofphysical layer CPICH RSCP measurements beforethe event evaluation and measurement reporting isperformed by the UE. The CPICH RSCP measurementreports can be used to trigger off inter-frequencyor inter-RAT (GSM) measurements for thepurpose of hard handover.The higher layer filtering is described in 3GPP TS25.331 RRC Protocol Specification, section FilterCoefficient.
Filtering period of 200 ms (0), Filtering periodapproximates 300 ms (1), Filtering period approximates400 ms (2), Filtering period approximates600 ms (3), Filtering period approximates 800 ms(4), Filtering period approximates 1100 ms (5), Filteringperiod approximates 1600 ms (6)
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NSN NSN
RU10 RU20
Mapping Rule Remark Parameter ID Meaning
AdjgQoffset1
AdjgQrxlevMin
Use the NSN value. PtxPrimaryCCPCH
Use the NSN value. PtxCellMax
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the NSN value. PtxPrimaryCPICH
Cell_Reserved
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
ACBarredList
Use Nokia Siemens Networks (NSN) value.
This parameter is used in the cell re-selection and ranking between WCDMA and GSM cells. The value of this parameter is subtracted from the measured GSM carrier RSSI of the neighbouring cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
Locate the NSN value in the following order:
Determines the minimum required RSSI level which the measurement result of the GSM neighbour cell must exceed before the cell re-selection becomes possible./nThis parameter is part of System Information Block 11&12.
This is the transmission power of the primary CCPCH relative to the CPICH transmission power. The P-CCPCH is a fixed rate (15 ksps, SF = 256) downlink physical channel used to carry the BCH. It is a pure data channel and characterized by a fixed channelisation code (Cch,256,1). The P-CCPCH is broadcast over the entire cell and it is not transmitted during the first 256 chips of each slot, where Primary SCH and Secondary SCH are transmitted. Note: Changing the parameter value will start the cell shutdown procedure in the BTS.
This parameter defines the maximum transmission power of the cell. The maximum transmission power is the maximum value for the linear sum of the power of all downlink physical channels that is allowed to be used in a cell. The maximum transmission power of the cell is the minimum of the two parameters: PtxCellMax and MaxDLPowerCapability (the maximum BTS power capability). The RNC signals the BTS the minimum value as the maximum transmission power in Maximum Transmission Power IE (TS 25.433). The RNC uses the minimum value as the maximum transmission power of the cell. If HSDPA static resource allocation is active, the value of the PtxMaxHSDPA parameter added with the value of the PtxTargetHSDPA parameter must not exceed the cell maximum transmission power defined by the minimum of the following parameters: PtxCellMax and MaxDLPowerCapability. Otherwise Rthe NC internally limits the HSDPA power.
NSN does not have such a parameter.NSN does not have such a parameter.NSN does not have such a parameter.NSN does not have such a parameter.
This is the transmission power of the primary common pilot channel. The P-CPICH physical channel carries the common pilots of the cell, which is defined in the cell setup. The transmission power of the CPICH physical channel defines the actual cell size, which means that the power is determined by radio network planning. This parameter is used, for example, for neighbour measurements - critical for the network performance. The default value is 5-10% of the maximum transmitting power of WCDMA BTS, which can be, for example, 43 dBm/carrier. Note: Changing the parameter value will start the cell shutdown procedure in the BTS. Note: The cell is blocked if the WCDMA BTS does not support the used value. Typical supported range is (Cell max power - 18dB)..(Cell max power - 3dB). This parameter is part of System Information Block 5.
Huawei NSN RESERVED 0 NOT_RESERVED 1
Defines whether the cell is reserved for operator use or not. A reserved cell is a cell on which camping is not allowed, except for particular UEs, if so indicated./nWhen cell status is 'not barred' and 'not reserved' for operator use the UE may select//re-select this cell during the cell selection and cell re-selection procedures in Idle mode and in Connected mode./nWhen cell status is 'not barred' and 'reserved' for operator use, the UEs assigned to Access Class 11 or 15 may select//re-select this cell if in the home PLMN. UEs assigned to Access Class in the range 0 to 9 and 12 to 14 shall behave as if cell status 'barred' is indicated./nThis parameter is part of System Information Block 3.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
Huawei NSN NOT_BARRED 0 BARRED 1
Access Class Barred list' information defines whether access is barred for each of the 16 Access Classes (AC0...AC15). 'Access Class Barred list' uses a binary notation of 16 bits where - bit 0 indicates whether access is barred for AC0 - bit 1 indicates whether access is barred for AC1 - bit 2 indicates whether access is barred for AC2 ... - bit 15 indicates whether access is barred for AC15 If a bit is set to 1, the corresponding Access Class is 'barred'. If a bit is set to 0, the corresponding Access Class is 'not barred'. If Access Class 10 is indicated as barred in a cell, UEs with Access Class 0 to 9 or without an IMSI are not allowed to initiate emergency calls in this cell. For UEs with Access Classes 11 to 15, emergency calls are not allowed if both Access Class 10 and the relevant Access Class (11 to 15) are barred. Otherwise, emergency calls are allowed for those UEs. Note: This value is used in SIB3 only when AccessClassRegulation is disabled in a cell. If AccessClassRegulation is enabled, only Access Classes 10 to 15 can be barred with this parameter.
document.xls 文档密级:
04/17/2023 华为机密,未经许可不得扩散 第69页,共97页
CellBarred
Tbarred
Use the Huawei baseline value. PrxNoise
PtxMaxHSDPA
HHoEcNoThreshold
HHoEcNoCancel
HHoEcNoThreshold
HHoEcNoThreshold
HHoEcNoCancel
HHoEcNoCancel
HHoRscpThreshold
HHoRscpCancel
HHoRscpThreshold
HHoRscpThreshold
HHoRscpCancel
HHoRscpCancel
Use the Huawei baseline value.
HHoEcNoThreshold
Huawei NSN NOT_BARRED 1 BARRED 0
Defines whether the cell is barred or not./nA barred cell is a cell where a UE is not allowed to camp on. Emergency calls shall be allowed in all cells whose barred status is 'not barred'. When cell status is 'barred', the UE is not permitted to select//re-select the cell, not even for emergency calls./nThis parameter is part of System Information Block 3.
Huawei NSN ALLOWED 0 NOT_ALLOWED 1
IntraFreq_Cell_Reselect_Ind
Defines whether intra-frequency cell re-selection is allowed or not when the cell is barred./nWhen a cell's status is 'barred', the UE is not permitted to select//re-select this cell, except in some cases for an emergency call. If the 'Intra-frequency cell re-selection indicator' is set to value 'allowed', the UE may select another cell on the same frequency if selection//re-selection criteria are fulfilled. If the 'Intra-frequency cell re-selection indicator' is set to 'not allowed' the UE shall not re-select even a different cell on the same frequency as the barred cell. For emergency call, the Intra-frequency cell re-selection indicator IE' shall be ignored. 'Intra-frequency cell re-selection indicator' is part of SIB3//4 in the case the 'cell barred' indicator is true./nThis parameter is part of System Information Block 3.
Huawei NSN D[10*2^N] N
When the cell is barred, the UE must check between the time interval ‘Cell barred period’, whether the status of the barred cell has changed./nThis parameter is part of the System Information Block 3.
Defines the noise level in the BTS digital receiver when there is no load (thermal noise + noise figure). This parameter is needed in noise rise calculations.
Huawei NSNMaxTxPower+HspaPower<==>PtxMaxHSDPA
The parameter defines the maximum allowed HSDPA transmission power.
Locate the NSN value in the following order:WCEL > the RtFmciIdentifier value > the FMCI value > the InterFreqMeasRepInterval value Huawei NSN D500 2 D1000 3 D2000 4 D3000 5 D4000 6
InterFreqMeasRepInterval
This parameter determines the measurement reporting interval for periodical inter-frequency measurements.
Use the value 0.
Use the value 0.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoTimeHysteresis value Huawei NSN D0 0 D10 1 D20 2 D40 3 D60 4 D80 5 D100 6 D120 7 D160 8 D200 9 D240 10 D320 11 D640 12 D1280 13 D2560 14 D5000 15
HHoEcNoTimeHysteresis
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than the threshold HHoEcNoThreshold. The parameter HHoEcNoTimeHysteresis determines the time period during which the CPICH Ec/No of the active set cell must stay worse than the threshold HHoEcNoThreshold before the UE can trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoCancelTime valueIf the NSN value is larger than Huawei value, use the NSN value. Otherwise, use the Huawei baseline value. Huawei NSN D0 0 D10 1 D20 2 D40 3 D60 4 D80 5 D100 6 D120 7 D160 8 D200 9 D240 10 D320 11 D640 12 D1280 13 D2560 14 D5000 15
HHoEcNoCancelTime
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. The parameter HHoEcNoCancelTime determines the time period during which the CPICH Ec/No of the active set cell must stay better than the threshold HHoEcNoCancel before the UE can trigger the reporting event 1E. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoRscpThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpThreshol value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpThreshol value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
Use the value 0.
Use the value 0.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoTimeHysteresis value Huawei NSN D0 0 D10 1 D20 2 D40 3 D60 4 D80 5 D100 6 D120 7 D160 8 D200 9 D240 10 D320 11 D640 12 D1280 13 D2560 14 D5000 15
HHoEcNoTimeHysteresis
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than the threshold HHoEcNoThreshold. The parameter HHoEcNoTimeHysteresis determines the time period during which the CPICH Ec/No of the active set cell must stay worse than the threshold HHoEcNoThreshold before the UE can trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoCancelTime valueIf the NSN value is larger than Huawei value, use the NSN value. Otherwise, use the Huawei baseline value. Huawei NSN D0 0 D10 1 D20 2 D40 3 D60 4 D80 5 D100 6 D120 7 D160 8 D200 9 D240 10 D320 11 D640 12 D1280 13 D2560 14 D5000 15
HHoEcNoCancelTime
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. The parameter HHoEcNoCancelTime determines the time period during which the CPICH Ec/No of the active set cell must stay better than the threshold HHoEcNoCancel before the UE can trigger the reporting event 1E. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
NSN does not have such a parameter.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is 0, use the value -24. Otherwise, locate another NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
document.xls 文档密级:
04/17/2023 华为机密,未经许可不得扩散 第70页,共97页
HHoEcNoCancel
HHoEcNoThreshold
HHoEcNoThreshold
HHoEcNoCancel
HHoEcNoCancel
HHoRscpThreshold
HHoRscpCancel
HHoRscpThreshold
HHoRscpThreshold
HHoRscpCancel
HHoRscpCancel
AdjgRxLevMinHO
AdjgRxLevMinHO
AdjgRxLevMinHO
AdditionWindow
AdditionWindow
AdditionWindow
DropWindow
DropWindow
DropWindow
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
AdditionTime
DropTime
Use the Huawei baseline value.
Use the Huawei baseline value. MaxActiveSetSize
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is 0, use the value -22. Otherwise, locate another NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is 0, use the value -24. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is 0, use the value -24. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is 0, use the value -22. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is 0, use the value -22. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is 0, use the value -115. Otherwise, locate another NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoRscpThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is 0, use the value -113. Otherwise, locate another NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is 0, use the value -115. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is 0, use the value -115. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpThreshold value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is 0, use the value -113. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is 0, use the value -113. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
Locate the NSN value in the following order:WCEL > the last ADJG > the RtHopgIdentifier value > the HOPG value > the AdjgRxLevMinHO value
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
Locate the NSN value in the following order:WCEL > the last ADJG > the NRtHopgIdentifier value > the HOPG value > the AdjgRxLevMinHO value
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
Locate the NSN value in the following order:WCEL > the last ADJG > the NRtHopgIdentifier value > the HOPG value > the AdjgRxLevMinHO value
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the AdditionWindow value
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the AdditionWindow value
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the AdditionWindow value
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the DropWindow value
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the DropWindow value
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the DropWindow value
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
NSN does not have such a parameter.NSN does not have such a parameter.NSN does not have such a parameter.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the AdditionTime value Huawei NSN D0 0 D10 1 D20 2 D40 3 D60 4 D80 5 D100 6 D120 7 D160 8 D200 9 D240 10 D320 11 D640 12 D1280 13 D2560 14 D5000 15
When a monitored cell enters the reporting range (addition window), the cell must continuously stay within the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to add the cell into the active set (event 1A). The length of this period is controlled by the parameter Addition Time. This parameter is part of System Information Block 11/12.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the DropTime value Huawei NSN D0 0 D10 1 D20 2 D40 3 D60 4 D80 5 D100 6 D120 7 D160 8 D200 9 D240 10 D320 11 D640 12 D1280 13 D2560 14 D5000 15
When an active set cell leaves the reporting range (drop window), the cell must continuously stay outside the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to remove the cell from the active set (event 1B). The length of this period is controlled by the parameter Drop Time. This parameter is part of System Information Block 11/12.
NSN does not have such a parameter.
The NSN value is 3 as well.
This parameter determines the maximum number of cells which can participate in a soft/softer handover. Reporting deactivation threshold indicates the maximum number of cells allowed in the active set in order for the event 1A to trigger. The RNC calculates the deactivation threshold from the parameter MaxActiveSetSize: Reporting Deactivation Threshold = MaxActiveSetSize - 1 Reporting Deactivation Threshold parameter is part of System Information Block 11/12. Replacement activation threshold information element indicates the minimum number of cells allowed in the active set in order for the event 1C to trigger. The threshold equals to the maximum size of the active set which is controlled with the parameter MaxActiveSetSize. Replacement Activation Threshold parameter is part of System Information Block 11/12.
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Use the NSN value. Qhyst1
Use the Huawei baseline value. Qhyst1
Use the NSN value. Qhyst2
Use the Huawei baseline value. Qhyst2
Use the NSN value. Treselection
Use the NSN value. QqualMin
Use the NSN value. QrxlevMin
Use the NSN value. Sintrasearch
Use the NSN value. Sintersearch
Use the NSN value. Ssearch_RAT
Use the NSN value. PTxPICH
Use the NSN value. PtxAICH
Use the NSN value. CS_T3212
PS_NMO
Use the NSN value.
T302
N302
T309
Use the NSN value. T312conn
N312
T313
N313
T314
T315
N315
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Qhyst1 is used for TDD and GSM cells, and for FDD cells when cell selection and re-selection quality measure is set to CPICH RSCP./nThis parameter is part of System Information Block 3.
Qhyst1 is used for TDD and GSM cells, and for FDD cells when cell selection and re-selection quality measure is set to CPICH RSCP./nThis parameter is part of System Information Block 3.
Qhyst2 is used for TDD and GSM cells, and for FDD cells when cell selection and re-selection quality measure is set to CPICH ECNO./nThis parameter is part of System Information Block 3.
Qhyst2 is used for TDD and GSM cells, and for FDD cells when cell selection and re-selection quality measure is set to CPICH ECNO./nThis parameter is part of System Information Block 3.
The UE triggers the reselection of a new cell if the cell reselection criteria are fulfilled during the time interval Treselection./nThis parameter is part of System Information Block 3.
The minimum required quality level in the cell (Ec//No)./nThis parameter is part of System Information Block 3.
Determines the minimum required RSSI level which the measurement result of the GSM neighbour cell must exceed before the cell re-selection becomes possible./nThis parameter is part of System Information Block 11&12.
The threshold for intra-frequency measurements, and for the HCS measurement rules./nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
The threshold for inter-frequency measurements, and for the HCS measurement rules. /nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
The RAT-specific threshold for inter-RAT measurement rules./nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
This is the transmission power of the PICH channel. It carries the paging indicators which tell the UE to read the paging message from the associated secondary CCPCH. The transmission power value is relative to the CPICH transmission power. It may depend on the number of paging indicators (PI) per frame. The following table shows the recommended values for the different cases N. PI per frame (NP), Repetition of PICH bits, Power relative to CPICH (dB): 18, 16, -10 36, 8, -10 72, 4, -8 144, 2, -5 This parameter is part of System Information Block 5.
This is the transmission power of one Aquisition Indicator (AI) compared to CPICH power. If a WCDMA BTS transmits a large number of AIs, then the total power of AICH increases. The AICH consists of a repeated sequence of 15 consecutive Access Slots (AS), each one 5120 chips in length. Each access slot consists of two parts: an Acquisition Indicator (AI) part consisting of 32 real-valued symbols, and a second part, 1024 chips in length, which has no transmission and is not formally part of the AICH. This second part of the slot is reserved for possible use by CSICH, or possible future use by other physical channels. The spreading factor (SF) used for the channelisation of the AICH is 256, and the phase reference for the AICH is the P-CPICH. This parameter is part of System Information Block 5.
The timeout value, in decihours (6 min), for periodic location updating. Given only for CS domain. (Part of CS domain specific NAS System information in SIB1). /nThe value 0 is used for an infinite timeout value, that is, periodic location updating is not used./nThis parameter is part of System Information Block 1.
Huawei NSN ALLOWED 1 NOT_ALLOWED 0
CSAttachDetachAllowed
Defines whether IMSI attach and detach are allowed or not. /n0 = MSs shall not apply IMSI attach and detach procedure, /n1 = MSs shall apply IMSI attach and detach procedure. /nParameter is given only for CS domain. (Part of CS domain specific NAS System information in SIB1.)
HUAWEI NSNMODE1 0MODE2 1
In Operation Mode I it is possible to have combined CS and PS side paging via SGSN. In Operation Mode II the combined paging procedure is not possible (and neither are combined attach procedures). Used only for the PS domain. NMO is part of PS CN domain specific NAS System information in System Information Block 1.
UTRAN_DRX_length
The DRX cycle length used by UTRAN to count paging occasions for discontinuous reception./n(The duration of the DRX cycle is 2 <power> k frames, where 'k' is the used DRX cycle length coefficient for UTRAN.)
Huawei NSN D1000 5 D1200 6 D1400 7 D1600 8 D1800 9 D2000 10 D3000 11 D4000 12 D6000 13 D8000 14
The CELL UPDATE/URA UPDATE retransmission timer (MS timer). This parameter is part of System Information Block 1.
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
CELL UPDATE/URA UPDATE retransmission counter (MS counter). This parameter is part of System Information Block 1.
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
The timer for supervising successful connection establishment in case of an inter-RAT cell re-selection (MS timer).
The timer for supervising successful establishment of a physical channel (MS timer used in idle mode).
Huawei NSN D1 0 D2 1 D4 2 D10 3 D20 4 D50 5 D100 6 D200 7 D400 8 D600 9 D800 10 D1000 11
This parameter defines the maximum number of 'in sync' indications received from L1 during the establishment of a physical channel (UE counter used in idle mode)./nThis parameter is part of System Information Block 1.
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
The radio link failure timer (MS timer). This parameter is part of System Information Block 1.
Huawei NSN D50 N<=5 D100 6 D200 7
This parameter defines the maximum number of successive "out of sync" indications received from L1 (MS counter). This parameter is part of System Information Block 1.
The value D12 is recommended.
The RRC connection re-establishment timer usedfor service-types allowing notably shorter re-establishmenttimes than the UE-timer T315. Currentlythis timer is used for CS service bearers only.UEs prior 3GPP REL6 use this timer also for supervisingthe RRC connection re-establishment ofstandalone (NAS) signaling connection towardsboth the CN domains.This parameter is part of System Information Block1.
The value D30 is recommended.
The RRC connection re-establishment timer for AM bearers (UE timer). This parameter is part of System Information Block 1.
Huawei NSN D1 0 D50 1 D100 2 D200 3 D400 4 D600 5 D800 6 D1000 7 D2 8 D4 9 D10 10 D20 11
This parameter defines the maximum number of successive "in sync" indications received from L1 while T313 is being activated (UE counter). This parameter is part of System Information Block 1.
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Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
PtxSCCPCH1
Use the Huawei baseline value.
Use the NSN value.
T300
N300
Use the NSN value. T312
N312
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value. HHoEcNoThreshold
Use the Huawei baseline value. HHoEcNoCancel
Use the Huawei baseline value. HHoEcNoThreshold
Use the Huawei baseline value. HHoEcNoThreshold
Use the Huawei baseline value. HHoEcNoCancel
Use the Huawei baseline value. HHoEcNoCancel
Use the Huawei baseline value. HHoRscpThreshold
Use the Huawei baseline value. HHoRscpCancel
Use the Huawei baseline value. HHoRscpThreshold
Use the Huawei baseline value. HHoRscpThreshold
Use the Huawei baseline value. HHoRscpCancel
Use the Huawei baseline value. HHoRscpCancel
NSN does not have such a parameter.
NSN does not have such a parameter.
NSN does not have such a parameter.If the NSN value is larger than
the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
This is the transmission power of the S-CCPCH channel, which carries: - a PCH (containing PCCH), a FACH (containing DCCH/BCCH/CCCH) and a FACH (containing DTCH). Or alternatively (when standalone PCH is mapped to an another S-CCPCH) carries: - a FACH (containing DCCH/BCCH/CCCH) and a FACH (containing DTCH). In both cases the spreading factor of this S-CCPCH is 64 (60 ksps) and proposed default value is 0 dB. The transmission power value is relative to the CPICH transmission power.
DownlinkInnerLoopPCStepSize
The DL inner loop PC step size is used in normal mode by the WCDMA BTS to calculate the power increase/decrease when receiving TPC commands.
UTRAN_DRX_length
The DRX cycle length used by UTRAN to count paging occasions for discontinuous reception./n(The duration of the DRX cycle is 2 <power> k frames, where 'k' is the used DRX cycle length coefficient for UTRAN.)
Huawei NSN D100 0 D[100*2N] N(11>N>0) D2000 N>=11
The RRC CONNECTION REQUEST retransmission timer (MS timer)./nThis parameter is part of System Information Block 1.
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
RRC CONNECTION REQUEST retransmission counter (MS counter)./nThis parameter is part of System Information Block 1.
The timer for supervising successful establishment of a physical channel (MS timer used in idle mode).
Huawei NSN D1 0 D2 1 D4 2 D10 3 D20 4 D50 5 D100 6 D200 7 D400 8 D600 9 D800 10 D1000 11
This parameter defines the maximum number of 'in sync' indications received from L1 during the establishment of a physical channel (UE counter used in idle mode)./nThis parameter is part of System Information Block 1.
InterFreqMeasRepInterval
This parameter determines the measurement reporting interval for periodical inter-frequency measurements.
Use the value 0.
Use the value 0.
HHoEcNoTimeHysteresis
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than the threshold HHoEcNoThreshold. The parameter HHoEcNoTimeHysteresis determines the time period during which the CPICH Ec/No of the active set cell must stay worse than the threshold HHoEcNoThreshold before the UE can trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
HHoEcNoCancelTime
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. The parameter HHoEcNoCancelTime determines the time period during which the CPICH Ec/No of the active set cell must stay better than the threshold HHoEcNoCancel before the UE can trigger the reporting event 1E. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
document.xls 文档密级:
04/17/2023 华为机密,未经许可不得扩散 第73页,共97页
Use the Huawei baseline value.
AdjiQoffset1
AdjiQoffset2
AdjiQqualMin
AdjiQrxlevMin
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value. HHoEcNoThreshold
Use the Huawei baseline value. HHoEcNoCancel
Use the Huawei baseline value. HHoEcNoThreshold
Use the Huawei baseline value. HHoEcNoThreshold
Use the Huawei baseline value. HHoEcNoCancel
Use the Huawei baseline value. HHoEcNoCancel
Use the Huawei baseline value. HHoRscpThreshold
Use the Huawei baseline value. HHoRscpCancel
Use the Huawei baseline value. HHoRscpThreshold
Use the Huawei baseline value. HHoRscpThreshold
Use the Huawei baseline value. HHoRscpCancel
Use the Huawei baseline value. HHoRscpCancel
Use the Huawei baseline value. AdjgRxLevMinHO
Use the Huawei baseline value. AdjgRxLevMinHO
Use the Huawei baseline value. AdjgRxLevMinHO
Use the Huawei baseline value. AdditionWindow
Use the Huawei baseline value. AdditionWindow
Use the Huawei baseline value. AdditionWindow
Use the Huawei baseline value. DropWindow
Use the Huawei baseline value. DropWindow
NSN does not have such a parameter.
Locate the NSN value in the following order:WCEL > ADJI > the RtHopiIdentifier value > the HOPI value > the AdjiQoffset1 value
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH RSCP of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
Locate the NSN value in the following order:WCEL > ADJI > the RtHopiIdentifier value > the HOPI value > the AdjiQoffset2 value
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH Ec//No of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
Locate the NSN value in the following order:WCEL > ADJI > the RtHopiIdentifier value > the HOPI value > the AdjiQqualMin value
The minimum required quality level in the cell (Ec//No)./nThis parameter is part of System Information Block 3.
Locate the NSN value in the following order:WCEL > ADJI > the RtHopiIdentifier value > the HOPI value > the AdjiQrxlevMin value
Determines the minimum required RSSI level which the measurement result of the GSM neighbour cell must exceed before the cell re-selection becomes possible./nThis parameter is part of System Information Block 11&12.
Use the value 0.
Use the value 0.
HHoEcNoTimeHysteresis
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than the threshold HHoEcNoThreshold. The parameter HHoEcNoTimeHysteresis determines the time period during which the CPICH Ec/No of the active set cell must stay worse than the threshold HHoEcNoThreshold before the UE can trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
HHoEcNoCancelTime
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. The parameter HHoEcNoCancelTime determines the time period during which the CPICH Ec/No of the active set cell must stay better than the threshold HHoEcNoCancel before the UE can trigger the reporting event 1E. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH Ec/No measurement result of an active set cell becomes worse than or equal to an absolute CPICH Ec/No threshold. The parameter HHoEcNoThreshold determines the absolute CPICH Ec/No threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH Ec/No of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH Ec/No is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH Ec/No. The RNC cancels the event 1F of an active set cell if the CPICH Ec/No measurement result of the active set cell becomes better than or equal to the threshold HHoEcNoCancel and the UE transmits the corresponding event 1E triggered Measurement Report to the RNC. Note that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH Ec/No, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH Ec/No.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured CPICH RSCP is enabled, the UE transmits an event 1F triggered measurement report to the RNC when the CPICH RSCP measurement result of an active set cell becomes worse than or equal to an absolute CPICH RSCP threshold. The parameter HHoRscpThreshold determines the absolute CPICH RSCP threshold which is used by the UE to trigger the reporting event 1F. When the measured CPICH RSCP of all active set cells has become worse than or equal to the threshold in question, the RNC starts inter-frequency or inter-RAT (GSM) measurements in compressed mode for the purpose of hard handover.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
If the inter-frequency or inter-RAT (GSM) handover caused by low measured absolute CPICH RSCP is enabled, the RNC starts the inter-frequency or GSM measurement in compressed mode when all active set cells have triggered the reporting event 1F for CPICH RSCP. The RNC cancels the event 1F of an active set cell, if the CPICH RSCP measurement result of the active set cell becomes better than or equal to the threshold HHoRscpCancel and the UE transmits the corresponding event 1E triggered measurement report to the RNC. Note, that once the RNC has started the inter-frequency or inter-RAT (GSM) measurement for the purpose of hard handover due to low measured absolute CPICH RSCP, the RNC does not break off the ongoing measurement, even if one or more active set cells trigger the reporting event 1E for CPICH RSCP.
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
This parameter determines the minimum required GSM RSSI level which the averaged RSSI value of the GSMneighbour cell must exceed before the coverage (or quality) reason handover to GSM is possible.
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
Addition Window determines the relative threshold (A_Win) used by the UE to calculate the reporting range of event 1A. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best), or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of a monitored cell (M_new) enters the reporting range, the UE transmits a Measurement Report to the RNC in order to add the monitored cell into the active set: M_new >= W * M_sum + ( 1 - W )* M_best - A_Win This parameter is part of System Information Block 11/12.
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
document.xls 文档密级:
04/17/2023 华为机密,未经许可不得扩散 第74页,共97页
Use the Huawei baseline value. DropWindow
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value. AdditionTime
Use the Huawei baseline value. DropTime
Use the Huawei baseline value.
Use the Huawei baseline value.
AdjsDERR
AdjsDERR
AdjsQoffset1
AdjsQoffset2
Use the NSN value. PtxSCCPCH1
Use the NSN value. PtxPrimaryCPICH
Use the NSN value.
Use the NSN value.
Use the NSN value.
Use the Huawei baseline value.
Use the NSN value. PtxPrimarySCH
Use the NSN value.
Use the NSN value.
Use the NSN value. RACH_tx_Max
Use the NSN value. PtxSecSCH
Use the Huawei baseline value.
Use the Huawei baseline value. CNDomainVersion
Use the Huawei baseline value. AdjiQoffset1
Use the Huawei baseline value. AdjsQoffset2
Use the Huawei baseline value.
Drop Window determines the relative threshold (D_Win) which is used by the UE to calculate the reporting range of event 1B. The threshold is either relative to the CPICH Ec/No measurement result of the best active set cell (M_best) or to the sum of active set measurement results (M_sum), depending on the value of the parameter Active Set Weighting Coefficient (W). When the CPICH Ec/No measurement result of an active set cell (M_old) leaves the reporting range, the UE transmits a Measurement Report to the RNC in order to remove the cell from the active set: M_old <= W * M_sum + ( 1 - W )* M_best - D_Win This parameter is part of System Information Block 11/12.
NSN does not have such a parameter.NSN does not have such a parameter.NSN does not have such a parameter.
ActiveSetWeightingCoefficient
Active Set Weighting Coefficient (W) is used to weight either the measurement result of the best active set cell (M_best) or the sum of measurement results of all active set cells (M_sum) when the UE calculates the reporting range for the events 1A (cell addition) and 1B (dropping of cell). The formula is: W * M_sum + ( 1 - W )* M_best This parameter is part of System Information Block 11/12.
When a monitored cell enters the reporting range (addition window), the cell must continuously stay within the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to add the cell into the active set (event 1A). The length of this period is controlled by the parameter Addition Time. This parameter is part of System Information Block 11/12.
When an active set cell leaves the reporting range (drop window), the cell must continuously stay outside the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to remove the cell from the active set (event 1B). The length of this period is controlled by the parameter Drop Time. This parameter is part of System Information Block 11/12.
NSN does not have such a parameter.NSN does not have such a parameter.
Huawei NSN NOT_AFFECT, 0 AFFECT, 1
This parameter indicates whether the neighbouring cell is forbidden to affect the reporting range (addition/drop window) calculation, if it belongs to the active set.
Huawei NSN NOT_AFFECT, 0 AFFECT, 1
This parameter indicates whether the neighbouring cell is forbidden to affect the reporting range (addition/drop window) calculation, if it belongs to the active set.
Locate the NSN value in the following order:WCEL > ADJS > the RtHopsIdentifier value > the HOPS value > the AdjsQoffset1 value
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH RSCP of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
Locate the NSN value in the following order:WCEL > ADJS > the RtHopsIdentifier value > the HOPS value > the AdjsQoffset2 value
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH Ec//No of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
This is the transmission power of the S-CCPCH channel, which carries: - a PCH (containing PCCH), a FACH (containing DCCH/BCCH/CCCH) and a FACH (containing DTCH). Or alternatively (when standalone PCH is mapped to an another S-CCPCH) carries: - a FACH (containing DCCH/BCCH/CCCH) and a FACH (containing DTCH). In both cases the spreading factor of this S-CCPCH is 64 (60 ksps) and proposed default value is 0 dB. The transmission power value is relative to the CPICH transmission power.
This is the transmission power of the primary common pilot channel. The P-CPICH physical channel carries the common pilots of the cell, which is defined in the cell setup. The transmission power of the CPICH physical channel defines the actual cell size, which means that the power is determined by radio network planning. This parameter is used, for example, for neighbour measurements - critical for the network performance. The default value is 5-10% of the maximum transmitting power of WCDMA BTS, which can be, for example, 43 dBm/carrier. Note: Changing the parameter value will start the cell shutdown procedure in the BTS. Note: The cell is blocked if the WCDMA BTS does not support the used value. Typical supported range is (Cell max power - 18dB)..(Cell max power - 3dB). This parameter is part of System Information Block 5.
PRACHRequiredReceivedCI
This UL required received C/I value is used by the UE to calculate the initial output power on PRACH according to the Open loop power control procedure. This parameter defines the value of the IE Constant value, which is part of System Information Block 5. The value of the parameter depends on the propagation channel. Note: If the operator perceives a difference in DL and UL linklosses, for example when MHA is used in BTS, then this parameter can be used to compensate for it in the power of the first transmitted preamble on the PRACH.
PRACH_preamble_retrans
The maximum number of preambles allowed in one preamble ramping cycle. PRACH Preamble Retrans Max is part of "PRACH power offset" which is part of "PRACH system information list" which is part of System Information Block 5&6.
PowerRampStepPRACHpreamble
The power ramp step on PRACH preamble when no acquisition indicator (AI) is detected by the UE. This parameter is part of System Information Block 5.
PowerOffsetLastPreamblePRACHmessage
The power offset between the last transmitted preamble and the control part of the PRACH message (added to the preamble power to receive the power of the message control part). This parameter is part of System Information Block 5.
This is the transmission power of the primary synchronisation channel. The power level is relative to the [FDD-primary CPICH power]. The primary SCH consists of a modulated code 256 chips in length: the Primary Synchronisation Code (PSC) transmitted once every slot. The PSC is the same for every cell in the system, and it enables the downlink slot synchronisation in the cell. Note: Changing the parameter value will start the cell shutdown procedure in the BTS.
RACH_Tx_NB01min
In case that a negative acknowledgement has been received by UE on AICH a backoff timer TBO1 is started to determine when the next RACH transmission attempt will be started. The backoff timer TBO1 is set to an integer number NBO1 of 10 ms time intervals, randomly drawn within an interval 0 <= NB01min <= NBO1 <= NB01max (with uniform distribution). After TB01 has been expired, the next RACH attempt will be started. NB01min and NB01max may be set equal when a fixed delay is desired, and even to zero when no delay other than the one due to persistency is desired. NB01min is given as an integer between 0 and 50 which gives the Lower bound of the waiting time in 10ms steps. NB01min is part of "RACH transmission parameters" which is part of "PRACH system information list" which is part of System Information Block 5&6.
RACH_Tx_NB01max
In case that a negative acknowledgement has been received by UE on AICH a backoff timer TBO1 is started to determine when the next RACH transmission attempt will be started. The backoff timer TBO1 is set to an integer number NBO1 of 10 ms time intervals, randomly drawn within an interval 0 <= NB01min <= NBO1 <= NB01max (with uniform distribution). After TB01 has been expired, the next RACH attempt will be started. NB01min and NB01max may be set equal when a fixed delay is desired, and even to zero when no delay other than the one due to persistency is desired. NB01max is given as an integer between 0 and 50 which gives the Upper bound of the waiting time in 10ms steps. NB01max is part of "RACH transmission parameters" which is part of "PRACH system information list" which is part of SIB5/6. This parameter is part of System Information Block 5.
Maximum number of RACH preamble cycles defines how many times the PRACH pre-amble ramping procedure can be repeated before UE MAC reports a failure on RACH transmission to higher layers. Maximum number of RACH preamble cycles is part of "RACH transmission parameters" which is part of "PRACH system information list" which is part of SIB5/6. This parameter is part of System Information Block 5.
This is the transmission power of the secondary synchronisation channel related to the Primary CPICH transmission power. The secondary SCH consists of repeatedly transmitting a length 15 sequence of modulated codes 256 chips in length. These are the Secondary Synchronisation Codes (SSC), transmitted in parallel with the primary SCH. This sequence on the secondary SCH enables the downlink frame synchronisation, and indicates, to which code group the cell downlink scrambling code belongs. Each SSC is chosen from a set of 16 different codes 256 chips in length. Note: Changing the parameter value will start the cell shutdown procedure in the BTS.
NSN does not have such a parameter.
The code that uniquely identifies the Release version of the Core Network connected to the RNC.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH RSCP of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH Ec//No of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
NSN does not have such a parameter.
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Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value. ReplacementTime
Use the Huawei baseline value. MaxActiveSetSize
Use the Huawei baseline value. AdjsQoffset1
Use the Huawei baseline value. AdjsQoffset2
Use the Huawei baseline value. Sintrasearch
Use the Huawei baseline value. Sintersearch
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value. CellBarred
Use the Huawei baseline value.
Use the Huawei baseline value. Tbarred
Use the Huawei baseline value.
Use the Huawei baseline value. ToCellFACHinTest
Use the Huawei baseline value. ToCellFACHinTest
Use the Huawei baseline value. ToCellFACHinTest
Use the Huawei baseline value.
NSN does not have such a parameter.NSN does not have such a parameter.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
AdditionReportingInterval
When a monitored cell enters the reporting range and triggers event 1A (cell addition), the UE transmits a Measurement Report to the RNC. If the RNC is not able to add the monitored cell to the active set, the UE continues reporting after the initial report by reverting to periodical measurement reporting. The parameter Addition Reporting Interval determines the interval between periodical measurement reports when such reporting is triggered by the event 1A. This parameter is part of System Information Block 11/12.
NSN does not have such a parameter.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
ReplacementReportingInterval
When the number of cells in the active set has reached the maximum, and a monitored cell becomes better than an active set cell, the UE transmits a When the number of cells in the active set has reachedthe maximum, and a monitored cell becomes betterthan an active set cell, the UE transmits a MeasurementReport to the RNC in order to replace the active cellwith the monitored cell (event 1C). If the RNC is notable to replace the active cell with the monitored cell,the UE continues reporting after the initial report byreverting to periodical measurement reporting. Theparameter Replacement Reporting Interval determinesthe interval of periodical measurement reports whensuch reporting is triggered by the event 1C.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
ReplacementWindow
When the number of cells in the active set has reached the maximum specified by the parameter MaxActiveSetSize and a monitored cell becomes better than an active set cell, the UE transmits a Measurement Report to the RNC in order to replace the active cell with the monitored cell (event 1C). The parameter Replacement Window determines the margin by which the CPICH Ec/No measurement result of the monitored cell (MNew) must exceed the CPICH Ec/No measurement result of the an active set cell (MInAS) before the UE can send the event 1C triggered Measurement Report to the RNC: MNew >= MInAs + ReplacementWindow / 2 This parameter is part of System Information Block 11/12.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
When the number of cells in the active set has reachedthe maximum, and a monitored cell enters the reportingrange (replacement window), the monitored cell mustcontinuously stay within the reporting range for a givenperiod of time before the UE can send a MeasurementReport to the RNC in order to replace an active set cellwith the monitored cell (event 1C). The length of thisperiod is controlled by the parameter ReplacementTime.
The NSN value is 3 as well.
This parameter determines the maximum number of cells which can participate in a soft/softer handover. Reporting deactivation threshold indicates the maximum number of cells allowed in the active set in order for the event 1A to trigger. The RNC calculates the deactivation threshold from the parameter MaxActiveSetSize: Reporting Deactivation Threshold = MaxActiveSetSize - 1 Reporting Deactivation Threshold parameter is part of System Information Block 11/12. Replacement activation threshold information element indicates the minimum number of cells allowed in the active set in order for the event 1C to trigger. The threshold equals to the maximum size of the active set which is controlled with the parameter MaxActiveSetSize. Replacement Activation Threshold parameter is part of System Information Block 11/12.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH RSCP of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
This parameter is used in the cell re-selection and ranking between WCDMA cells. The value of this parameter is subtracted from the measured CPICH Ec//No of the neighbour cell before the UE compares the quality measure with the cell re-selection//ranking criteria./nThis parameter is part of System Information Block 11&12.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
The threshold for intra-frequency measurements, and for the HCS measurement rules./nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
The threshold for inter-frequency measurements, and for the HCS measurement rules. /nNote: If no threshold is given, MS performs measurements./nThis parameter is part of System Information Block 3.
NSN does not have such a parameter.NSN does not have such a parameter.NSN does not have such a parameter.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
AdditionReportingInterval
When a monitored cell enters the reporting range and triggers event 1A (cell addition), the UE transmits a Measurement Report to the RNC. If the RNC is not able to add the monitored cell to the active set, the UE continues reporting after the initial report by reverting to periodical measurement reporting. The parameter Addition Reporting Interval determines the interval between periodical measurement reports when such reporting is triggered by the event 1A. This parameter is part of System Information Block 11/12.
NSN does not have such a parameter.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
ReplacementReportingInterval
When the number of cells in the active set has reached the maximum, and a monitored cell becomes better than an active set cell, the UE transmits a When the number of cells in the active set has reachedthe maximum, and a monitored cell becomes betterthan an active set cell, the UE transmits a MeasurementReport to the RNC in order to replace the active cellwith the monitored cell (event 1C). If the RNC is notable to replace the active cell with the monitored cell,the UE continues reporting after the initial report byreverting to periodical measurement reporting. Theparameter Replacement Reporting Interval determinesthe interval of periodical measurement reports whensuch reporting is triggered by the event 1C.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
ReplacementWindow
When the number of cells in the active set has reached the maximum specified by the parameter MaxActiveSetSize and a monitored cell becomes better than an active set cell, the UE transmits a Measurement Report to the RNC in order to replace the active cell with the monitored cell (event 1C). The parameter Replacement Window determines the margin by which the CPICH Ec/No measurement result of the monitored cell (MNew) must exceed the CPICH Ec/No measurement result of the an active set cell (MInAS) before the UE can send the event 1C triggered Measurement Report to the RNC: MNew >= MInAs + ReplacementWindow / 2 This parameter is part of System Information Block 11/12.
The NSN value is 0 as well.ActiveSetWeightingCoefficient
Active Set Weighting Coefficient (W) is used to weight either the measurement result of the best active set cell (M_best) or the sum of measurement results of all active set cells (M_sum) when the UE calculates the reporting range for the events 1A (cell addition) and 1B (dropping of cell). The formula is: W * M_sum + ( 1 - W )* M_best This parameter is part of System Information Block 11/12.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
When the number of cells in the active set has reached the maximum, and a monitored cell enters the reporting range (replacement window), the monitored cell must continuously stay within the reporting range for a given period of time before the UE can send a Measurement Report to the RNC in order to replace an active set cell with the monitored cell (event 1C). The length of this period is controlled by the parameter Replacement Time. This parameter is part of System Information Block 11/12.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
Defines whether the cell is barred or not./nA barred cell is a cell where a UE is not allowed to camp on. Emergency calls shall be allowed in all cells whose barred status is 'not barred'. When cell status is 'barred', the UE is not permitted to select//re-select the cell, not even for emergency calls./nThis parameter is part of System Information Block 3.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
IntraFreq_Cell_Reselect_Ind
Defines whether intra-frequency cell re-selection is allowed or not when the cell is barred./nWhen a cell's status is 'barred', the UE is not permitted to select//re-select this cell, except in some cases for an emergency call. If the 'Intra-frequency cell re-selection indicator' is set to value 'allowed', the UE may select another cell on the same frequency if selection//re-selection criteria are fulfilled. If the 'Intra-frequency cell re-selection indicator' is set to 'not allowed' the UE shall not re-select even a different cell on the same frequency as the barred cell. For emergency call, the Intra-frequency cell re-selection indicator IE' shall be ignored. 'Intra-frequency cell re-selection indicator' is part of SIB3//4 in the case the 'cell barred' indicator is true./nThis parameter is part of System Information Block 3.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
When the cell is barred, the UE must check between the time interval ‘Cell barred period’, whether the status of the barred cell has changed./nThis parameter is part of the System Information Block 3.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
When the test timer expires, the UE is switched to Cell_FACH state when the value of the parameter ToCellFACHinTest is 'Yes'. If the ToCellFACHinTest parameter value is 'No', an Iu Release procedure is initiated in the Cell_DCH state, and the UE is switched directly to idle mode.0 (No), 1 (Yes)
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
When the test timer expires, the UE is switched to Cell_FACH state when the value of the parameter ToCellFACHinTest is 'Yes'. If the ToCellFACHinTest parameter value is 'No', an Iu Release procedure is initiated in the Cell_DCH state, and the UE is switched directly to idle mode.0 (No), 1 (Yes)
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
When the test timer expires, the UE is switched to Cell_FACH state when the value of the parameter ToCellFACHinTest is 'Yes'. If the ToCellFACHinTest parameter value is 'No', an Iu Release procedure is initiated in the Cell_DCH state, and the UE is switched directly to idle mode.0 (No), 1 (Yes)
For state transition, NSN mechanism is different from Huawei mechanism. NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
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Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
Use the Huawei baseline value.
InterFreqCSThd2DEcN0 + 3
InterFreqR99PsThd2DEcN0 + 3
InterFreqR99PsThd2DEcN0 + 3
InterFreqCSThd2DRSCP + 3
Tcell
Use the NSN value. PriScrCode
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
InactivityTimerDownlinkDCH128InactivityTimerDownlinkDCH16InactivityTimerDownlinkDCH256InactivityTimerDownlinkDCH32InactivityTimerDownlinkDCH320InactivityTimerDownlinkDCH384InactivityTimerDownlinkDCH64InactivityTimerDownlinkDCH8InactivityTimerUplinkDCH128InactivityTimerUplinkDCH16InactivityTimerUplinkDCH256InactivityTimerUplinkDCH32InactivityTimerUplinkDCH320InactivityTimerUplinkDCH384InactivityTimerUplinkDCH64SignallingLinkInactivityTimerCellDCHtestTmrMACdflowthroughputTimetoTriggerEDCHMACdFlowThroughputTimetoTrigger
The time indicating how long the radio and transmission resources are reserved after silence detection on downlink DCH before release procedures. Default values: 8 kbps: 5 s 16 kbps: 5 s 32 kbps: 5 s 64 kbps: 3 s 128 kbps: 2 s 256 kbps: 2 s 320 kbps: 2 s 384 kbps: 2 s
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
UL_DL_activation_timer
This timer is used on MAC -c to detect idle periods on data transmission (NRT RBs and SRBs) for the UE, which is in Cell_FACH state. Based on this timer the MAC -c shall give the No_Data indication to the RRC, which further can change the state of the RRC from Cell_FACH state to the Cell_PCH state (or URA_PCH state).
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
MSActivitySupervision
This timer is used in RRC states Cell_PCH and URA_PCH for supervising the inactivity of NRT RAB(s).If the parameter value is set to zero, state transition to Cell_PCH / URA_PCH state is not allowed. When inactivity is detected in Cell_FACH state, the UE will be switched to the idle mode. Range and step: 0 ... 1440 min, step 1 min
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
TrafVolThresholdULLowTrafVolThresholdDLLowNASsignVolThrULNASsignVolThrDL
This parameter defines, in bytes, the threshold of data in the RLC buffers of SRB0, SRB1, SRB2, SRB3, SRB4 and all NRT RBs that triggers the uplink traffic volume measurement report, when the UE is in Cell_FACH state. Otherwise, UE sends data on RACH.This parameter is sent to the UE using an RRC:MEASUREMENT CONTROL message.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
TrafVolTimeToTriggerULTrafVolTimeToTriggerDL
This parameter defines, in ms, the period of time between the timing of event detection and the timing ofsending a traffic volume measurement report.This parameter is sent to the UE using an RRC: MEASUREMENT CONTROL message.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
CellReselectionObservingTime
The timer is set when the first Cell Update message due to 'cell reselection' is received while UE is in CELL_FACH or CELL_PCH state. In expiry of the timer, the counter MaxCellReselections is reset. Below is an example of target RRC state selection when value 3 is used for MaxCellReselections: Velocity Cell radius Cell Update Target RRC state km/h km frequency 50 10 12 minutes CELL_PCH 50 20 24 minutes CELL_PCH 75 10 8 minutes URA_PCH 75 20 16 minutes CELL_PCH 100 10 6 minutes URA_PCH 100 20 12 minutes CELL_PCH
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
EDCHMACdFlowThroughputAveWinMACdflowthroughputAveWin
This parameter defines the size of the sliding averaging window for the throughput measurement of the E-DCH NRT MAC-d flow. The throughput measurement measures the number of bits transmitted by the E-DCH MAC-d flow during the sliding measurement window.The value 0 of the parameter means that the E-DCH MAC-d flow throughput measurement is not performed.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
EDCHMACdFlowThroughputAveWinMACdflowthroughputAveWin
This parameter defines the size of the sliding averaging window for the throughput measurement of the E-DCH NRT MAC-d flow. The throughput measurement measures the number of bits transmitted by the E-DCH MAC-d flow during the sliding measurement window.The value 0 of the parameter means that the E-DCH MAC-d flow throughput measurement is not performed.
NSN does not have such a parameter.NSN does not have such a parameter.NSN does not have such a parameter.NSN does not have such a parameter.
InterFreqR99PsThd2DRSCP + 3
NSN does not have such a parameter.
InterFreqR99PsThd2DRSCP + 3
NSN does not have such a parameter.
Huawei NSNCHIP0 0CHIP256 1CHIP512 2CHIP768 3CHIP1024 4CHIP1280 5CHIP1536 6CHIP1792 7CHIP2048 8CHIP2304 9
Each cell in a BTS uses a System Frame Number (SFN) counter, which is the BTS Frame Number (BFN) counter delayed by a number of chips defined by the value of Tcell. Tcell is used for defining the start of SCH, CPICH, Primary CCPCH and DL Scrambling Code(s) in a cell relative to BFN. The main purpose is to avoid having overlapping SCHs in different cells belonging to the same BTS. An SCH burst is 256 chips long. The values can be chosen as follows: 0 chips for the 1st cell of the BTS, 256 chips for the 2nd cell of the BTS, 512 chips for the 3rd cell of the BTS, etc. Note: Changing the parameter value will start the cell shutdown procedure in the BTS.
Identifies the downlink scrambling code of the Primary CPICH (Common Pilot Channel) of the Cell. Note: Changing the parameter value will start the cell shutdown procedure in the BTS. This parameter is part of System Information Block 11.
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Use the NSN value. LAC
Use the NSN value. SAC
Use the NSN value. RAC
Use the NSN value. Cid
Use the NSN value. UARFCN
Use the NSN value. Qhyst1PCH
Use the NSN value. Qhyst1FACH
Use the NSN value. Qhyst2PCH
Use the NSN value. Qhyst2FACH
Use the NSN value. TreselectionFACH
Use the NSN value. TreselectionPCH
GsmMeasRepInterva
GsmMeasAveWindo
Use the NSN value. GsmMinHoInterval
Use the NSN value. MaxNbrOfHSSCCHC
Use the Huawei baseline value.
GsmHandoverAMR
Use the Huawei baseline value.
HUAWEI<==>NSN
Use the Huawei baseline value.
This parameter contains the Location area code (LAC) of a WCDMA cell. The coding of the Location area code (two octets) is the responsibility of administration. LAI (Location Area Identification) consists of PLMNid and LAC. If LAI has to be deleted, LAC is set as 0xFFFE. This parameter is also part of System Information Block 1 and known as IE: GSM-MAP NAS system information.
The Service Area Identifier (SAI) identifies an area consisting of one or more cells which belong to the same Location Area (LAI). The Service Area Identifier is composed of the PLMN Identifier, the Location Area Code (LAC) and the Service Area Code (SAC).
The routing area code determines the Routing area within the location area to which the cell belongs to. It is used only for PS services (part of PS domain specific NAS system information in SIB1). Routing area identification (RAI) consists of LAI and RAC, LAI consists of PLMNid and LAC. This parameter is part of System Information Block 1.
The parameter identifies the cell within a RNC. This parameter is part of System Information Block 3.
The carrier frequency is designated by the parameter UTRA Absolute Radio Frequency Channel Number (UARFCN). This parameter defines the downlink channel number. The uplink channel number is calculated by the RNC based on a duplex distance used in the RF band. The relation between UARFCN (Nd) and the corresponding carrier frequency (Fdownlink [MHz]) in RF bands I, II and V is defined with the following equations: Fdownlink = 0.2 * Nd MHz Nd = 5 * Fdownlink The relation between the UARFCN (Nd) additional channel and the corresponding carrier frequency (Fdownlink [MHz]) in RF band II is defined with the following equations: Fdownlink = (1850.1 + 0.2 * Nd) MHz Nd = 5 * (Fdownlink - 1850.1 MHz) The relation between the UARFCN (Nd) additional channel and the corresponding carrier frequency (Fdownlink [MHz]) in RF band V is defined with the following equations: Fdownlink = (670.1 + 0.2 * Nd) MHz Nd = 5 * (Fdownlink - 670.1 MHz) Downlink RF band I is 2110 - 2170 MHz. Downlink RF band II is 1930 - 1990 MHz. Downlink RF band V is 869 - 894 MHz. Allowed channel numbers (Nd) in RF band I are: 10562 - 10838. Allowed channel numbers (Nd) in RF band II are: 9663 - 9712, 9763 - 9812, 9888 - 9937. Allowed additional channel numbers (Nd) in RF band II are: 412, 437, 462, 487, 512, 537, 562, 587, 612, 637, 662, 687. Allowed channel numbers (Nd) in RF band V are: 4357 - 4458. Allowed additional channel numbers (Nd) in RF band V are: 1007, 1012, 1032, 1037, 1062, 1087. The duplex distance is 190 MHz in RF band I, 80 MHz in RF band II and 45 MHz in RF band V. This parameter is part of System Information Block 5.
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
The parameter is used for cell selection and reselectionin Cell_PCH/URA_PCH.Qhyst1PCH is used for TDD and GSM cells, and forFDD cells when cell selection and re-selectionquality measure is set to CPICH RSCP.This is hysteresis between WCDMA and GSMcells. Hysteresis is not needed because negativeoffset is used.
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
The parameter is used for cell selection and reselectionin Cell_FACH.The parameter is used for TDD and GSM cells, andfor FDD cells when cell selection and re-selectionquality measure is set to CPICH RSCP.This is hysteresis between WCDMA and GSMcells. Hysteresis is not needed because negativeoffset is used.
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
The parameter is used for cell selection and reselectionin Cell_PCH/URA_PCH.The parameter is used for FDD cells when cellselection and re-selection quality measure is set toCPICH Ec/No.2dB hysteresis between WCDMA cells can be usedin urban environment to avoid ping-pong.0dB hysteresis can be used in areas of high mobilitylike highways.
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
The parameter is used for FDD cells when cellselection and re-selection The parameter is usedfor cell selection and re-selection in Cell_FACH.The parameter is used for FDD cells when cellselection and re-selection quality measure is set toCPICH Ec/No.2dB hysteresis between WCDMA cells can be usedin urban environment to avoid ping-pong. 0dB hysteresiscan be used in areas of high mobility likehighways.
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
This parameter is used for cell selection and reselectionin Cell_FACH.The UE triggers the reselection of a new cell if thecell reselection criteria are fulfilled during the timeinterval TreselectionFACH.The reselection time of 2s may avoid too many cellreselections between cells and hence LA/RAupdates when crossing the LA/RA border. Thus,there are less signalling and less call failures at theLA/RA border due to the LA/RA update. The reselectiontime of 0s can be used in areas of highmobility, such as highways.
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
selectionin Cell_PCH/URA_PCH.The UE triggers the reselection of a new cell if thecell reselection criteria are fulfilled during the timeinterval TreselectionPCH.The reselection time of 2s may avoid too many cellreselections between cells and hence LA/RAupdates when crossing the LA/RA border. Thus,there are less signalling and less call failures at theLA/RA border due to the LA/RA update. The reselectiontime of 0s can be used in areas of highmobility, such as highways.
HUAWEI NSND500 2D1000 3D2000 4D3000 5D4000 6
This parameter determines the measurementreporting interval for periodical inter-RAT (GSM)measurements.
HUAWEI<==>GsmMeasAveWindow*GsmMeasRepInterval
This parameter determines the maximum numberof periodical inter-RAT (GSM) measurementreports (maximum size of the sliding averagingwindow) from which the RNC calculates theaveraged GSM RSSI values for the handoverdecision algorithm.
This parameter determines the minimum intervalbetween a successful inter-RAT handover fromGSM to UTRAN and the following inter-RAThandover attempt back to GSM related to the sameRRC connection.
This parameter defines the maximum number ofHS-SCCH codes (SF 128) that can be reserved inone cell.More than one HS-SCCH code can be used if theHSDPA code multiplexing functionality is in use.The actual number of reserved codes depends onfor example HSDPA capabilities and HSDPA codemultiplexing support (RNC and BTS).
HUAWEI NSN HO_INTER_RAT_CS_OUT_SWITCH-0 0
This parameter indicates whether an inter-RAThandover to GSM is allowed for circuit switched(CS) voice services. The alternative values of theparameter are the following:- No; handover to GSM is not allowed for CS voiceservices. The handover is also prohibited if a CSvoice service is a part of multiservice.- Yes; handover to GSM is allowed for CS voice services.In case of multiservice, a handover to GSMmust be allowed for all CS and PS services whichparticipate in the multiservice before the handoveris possible.- Priority; handover to GSM is allowed for CS voiceservices. The handover is also allowed if a CS voiceservice is a part of multiservice.
HUAWEI NSN HO_INTER_RAT_PS_OUT_SWITCH-0 0
GsmHandoverNrtPS
This parameter indicates whether an inter-RAThandover (cell change) to GSM/GPRS is allowedfor non-real time packet switched (PS) dataservices in CELL_DCH state of connected mode.The alternative values of the parameter are the following:- No; cell change to GSM/GPRS is not allowed fornon-real time PS data services. The handover/cellchange to GSM/GPRS is also prohibited if a nonrealtime PS data service is a part of multiservice.- Yes; cell change to GSM/GPRS is allowed fornon-real time PS data services. In case of multiservice,a handover/cell change to GSM/GPRS mustbe allowed for all CS and PS services which participatein the multiservice before the handover/cellchange is possible.The parameters GsmHandoverAMR and/orGsmHandoverCS for CS data/voice services canoverrule the value of the parameter GsmHandoverNrtPSin case of multiservice. If either CSvoice and/or data services are prioritized, the RNCshall execute the handover to GSM even if the cellchange to GSM/GPRS is not allowed for non-realtime PS data services.
HHoRscpFilterCoefficient
In the CELL_DCH state the UE physical layer measurementperiod for intra-frequency CPICH RSCPmeasurements is 200 ms. The Filter Coefficientparameter controls the higher layer filtering ofphysical layer CPICH RSCP measurements beforethe event evaluation and measurement reporting isperformed by the UE. The CPICH RSCP measurementreports can be used to trigger off inter-frequencyor inter-RAT (GSM) measurements for thepurpose of hard handover.The higher layer filtering is described in 3GPP TS25.331 RRC Protocol Specification, section FilterCoefficient.
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NSN ALU
RU20 UA5.1
Mapping Rule Remark Parameter ID
0 dB Use the NSN value. qOffset1sn
-115 dBm qRxLevMin
-5dbm Use the NSN value.
43 dBm Use the NSN value. maxTxPower
nInSyncInd
nOutSyncInd
tRlFailure
cellIndividualOffset
33 dBm Use the NSN value. pcpichPower
Not reserved
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
0 accessClassBarred
Parameter Value Range
Recommended Value
-50...50 dB, step 1 dB-115...-25 dBm, step 2 dBm
Locate the NSN value in the following order:WCEL > the last ADJG > the RtHopgIdentifier value > the HOPG value > the AdjgQrxlevMin value
-35...15 dB, step 0.1 dB
bchPowerRelativeToPcpich
0...50 dBm, step 0.1 dBm
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
-10...50 dBm, step 0.1 dBmReserved (0), Not reserved (1)
Huawei NSN RESERVED reserved NOT_RESERVED Not reserved
cellReservedForOperatorUse
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
Bit 0: Access Class 0, Bit 1: Access Class 1, Bit 2: Access Class 2, Bit 3: Access Class 3, Bit 4: Access Class 4, Bit 5: Access Class 5, Bit 6: Access Class 6, Bit 7: Access Class 7, Bit 8: Access Class 8, Bit 9: Access Class 9, Bit 10: Access Class 10, Bit 11: Access Class 11, Bit 12: Access Class 12, Bit 13: Access Class 13, Bit 14: Access Class 14, Bit 15: Access Class 15
Huawei NSN NOT_BARRED 0 BARRED 1
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Not barred barredOrNot
Allowed
40 s tBarred
-101.9 dBm rtwpReference
38.5 dBm dchPowerMargin
0.5 s
hysteresis2D
hysteresis2F
640 ms timeToTrigger2D
640 ms timeToTrigger2F
-24~0 -12dbm
-24~0 -9dbm
-24~0 -12dbm
-24~0 -12dbm
-24~0 -9dbm
-24~0 -9dbm
-115~-25 -105dbm
-115~-25 -102dbm
-115~-25 -105dbm
-115~-25 -105dbm
-115~-25 -102dbm
-115~-25 -102dbm
hysteresis2D
hysteresis2F
640 ms timeToTrigger2D
640 ms timeToTrigger2F
-24~0 -12dbm
Barred (0), Not barred (1)
Huawei NSN NOT_BARRED Not barred BARRED barred
Allowed (0), Not allowed (1)
Huawei NSN ALLOWED Allowed NOT_ALLOWED Not allowed
intraFreqCellReselectInd10 s (0), 20 s
(1), 40 s (2), 80 s (3), 160 s (4), 320 s (5), 640 s (6), 1280 s (7)
Huawei NSN DN Ns
-130...-50 dBm, step 0.1 dBm
Use the Huawei baseline value.
-10...50 dBm, step 0.1 dBm
Huawei NSNMaxTxPower+HspaPower<==>PtxMaxHSDPA
0.5 s (2), 1 s (3), 2 s (4), 3 s (5), 4 s (6)
Locate the NSN value in the following order:WCEL > the RtFmciIdentifier value > the FMCI value > the InterFreqMeasRepInterval value Huawei NSN D500 0.5 s D1000 1 s ……………………….. D(N*1000) N s
Use the value 0.
Use the value 0.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoTimeHysteresis value Huawei NSN D0 0 ms D10 10 ms ……………………… D(N) N ms
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoCancelTime valueIf the NSN value is larger than the Huawei value, use the NSN value. Otherwise, use the Huawei baseline value. Huawei NSN D0 0 ms D10 10 ms ……………………… D(N) N ms
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
cpichEcNoThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
cpichEcNoThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
cpichEcNoThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
cpichEcNoThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
cpichEcNoThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
cpichEcNoThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoRscpThreshold value
cpichRscpThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
cpichRscpThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpThreshol value
cpichRscpThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpThreshol value
cpichRscpThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
cpichRscpThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
cpichRscpThresholdUsedFreq2F
Use the value 0.
Use the value 0.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoTimeHysteresis value Huawei NSN D0 0 ms D10 10 ms ……………………… D(N) N ms
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoCancelTime valueIf the NSN value is larger than the Huawei value, use the NSN value. Otherwise, use the Huawei baseline value. Huawei NSN D0 0 ms D10 10 ms ……………………… D(N) N ms
Use the Huawei baseline value.
NSN does not have such a parameter.
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is Disabled, use the value -24. Otherwise, locate another NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
cpichEcNoThresholdUsedFreq2D
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-24~0 -9dbm
-24~0 -12dbm
-24~0 -12dbm
-24~0 -9dbm
-24~0 -9dbm
-115~-25 -105dbm
-115~-25 -102dbm
-115~-25 -105dbm
-115~-25 -105dbm
-115~-25 -102dbm
-115~-25 -102dbm
8
8
8
4 dB
4 dB
4 dB
6 dB
6 dB
6 dB
hysteresis1A
hysteresis1B
100 ms timeToTrigger1A
640 ms timeToTrigger1B
2...3, step 1 3 maxActiveSetSize
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is Disabled, use the value -22. Otherwise, locate another NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
cpichEcNoThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is Disabled, use the value -24. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
cpichEcNoThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is Disabled, use the value -24. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoThreshold value
cpichEcNoThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is Disabled, use the value -22. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
cpichEcNoThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHEcNo valueIf the NSN value is Disabled, use the value -22. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoEcNoCancel value
cpichEcNoThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is Disabled, use the value -115. Otherwise, locate another NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoRscpThreshold value
cpichRscpThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is Disabled, use the value -113. Otherwise, locate another NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
cpichRscpThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is Disabled, use the value -115. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpThreshold value
cpichRscpThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is Disabled, use the value -115. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpThreshold value
cpichRscpThresholdUsedFreq2D
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is Disabled, use the value -113. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
cpichRscpThresholdUsedFreq2F
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the GSMcauseCPICHrscp valueIf the NSN value is Disabled, use the value -113. Otherwise, locate another NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the HHoRscpCancel value
cpichRscpThresholdUsedFreq2F
-110...-47 dBm, step 1 dBm
Locate the NSN value in the following order:WCEL > the last ADJG > the RtHopgIdentifier value > the HOPG value > the AdjgRxLevMinHO value
-110...-47 dBm, step 1 dBm
Locate the NSN value in the following order:WCEL > the last ADJG > the NRtHopgIdentifier value > the HOPG value > the AdjgRxLevMinHO value
-110...-47 dBm, step 1 dBm
Locate the NSN value in the following order:WCEL > the last ADJG > the NRtHopgIdentifier value > the HOPG value > the AdjgRxLevMinHO value
0...14.5 dB, step 0.5 dB
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the AdditionWindow value
cpichEcNoReportingRange1A
0...14.5 dB, step 0.5 dB
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the AdditionWindow value
cpichEcNoReportingRange1A
0...14.5 dB, step 0.5 dB
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the AdditionWindow value
cpichEcNoReportingRange1A
0...14.5 dB, step 0.5 dB
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the DropWindow value
cpichEcNoReportingRange1B
0...14.5 dB, step 0.5 dB
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the DropWindow value
cpichEcNoReportingRange1B
0...14.5 dB, step 0.5 dB
Locate the NSN value in the following order:WCEL > the NrtFmcsIdentifier value > the FMCS value > the DropWindow value
cpichEcNoReportingRange1B
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the AdditionTime value Huawei NSN D0 0 ms D10 10 ms ……………………… D(N) N ms
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Locate the NSN value in the following order:WCEL > the RtFmcsIdentifier value > the FMCS value > the DropTime value Huawei NSN D0 0 ms D10 10 ms ……………………… D(N) N ms
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
The NSN value is 3 as well.
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0 dB Use the NSN value. qHyst1
0 dB qHyst1
2 dB Use the NSN value. qHyst2
2 dB qHyst2
2 s Use the NSN value. tReselection
-18 dB Use the NSN value. qQualMin
-115 dBm Use the NSN value. qRxLevMin
10db Use the NSN value. sIntraSearch
8 dB Use the NSN value. sInterSearch
4 dB Use the NSN value. sSearchRatGsm
-8 dB Use the NSN value.
-8 dB Use the NSN value.
0 decihours Use the NSN value. locUpdatePeriod
isAttachAllowed
nmo
320 ms
2000 ms t302
0...7, step 1 7 n302
1...8 s, step 1 s 8 t309
6s Use the NSN value. t312
4 (2) n312
3 s t313
20 (4) n313
4s t314
180 s t315
1 n315
cellIndividualOffset
qQualMin
qRxLevMin
0...40 dB, step 2 dB0...40 dB, step 2 dB
Use the Huawei baseline value.
0...40 dB, step 2 dB0...40 dB, step 2 dB
Use the Huawei baseline value.
0...31 s, step 1 s-24...0 dB, step 1 dB-115...-25 dBm, step 2 dBm0...20 dB, step 2 dB0...20 dB, step 2 dB0...20 dB, step 2 dB-10...5 dB, step 1 dB
pichPowerRelativeToPcpich
-22...5 dB, step 1 dB
aichPowerRelativeToPcpich
0...255 decihours, step 1 decihours
IMSI attach/detach not allowed (0), IMSI attach/detach allowed (1)
IMSI attach/detach allowed
Huawei NSN ALLOWED IMSI attach/detach allowed NOT_ALLOWED IMSI attach/detach not allowed
Network Mode of Operation I (0), Network Mode ofOperation II (1)
Network Mode ofOperation II (1)
HUAWEI NSNMODE1 Network Mode of Operation I MODE2 Network Mode of Operation II
80 ms (3), 160 ms (4), 320 ms (5), 640 ms (6), 1280 ms (7), 2560 ms (8), 5120 ms (9)
Huawei NSN 3 80 ms 4 160 ms 5 320 ms 6 640 ms 7 1280 ms 8 2560 ms 9 5120 ms
utranDrxCycLngCoef
1000 ms (5), 1200 ms (6), 1400 ms (7), 1600 ms (8), 1800 ms (9), 2000 ms (10), 3000 ms (11), 4000 ms (12), 6000 ms (13), 8000 ms (14)
Huawei NSN D1000 1000 ms D1200 1200 ms…………………………….. D(N) N ms
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
1...15 s, step 1 s
1 (0), 2 (1), 4 (2), 10 (3), 20 (4), 50 (5), 100 (6), 200 (7), 400 (8), 600 (9), 800 (10), 1000 (11)
Huawei NSN D1 0 D2 1 D4 2 D10 3 D20 4 D50 5 D100 6 D200 7 D400 8 D600 9 D800 10 D1000 11
0...15 s, step 1 s
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
1 (0), 2 (1), 4 (2), 10 (3), 20 (4), 50 (5), 100 (6), 200 (7)
Huawei NSN D50 N<=5 D100 6 D200 7
0s (0), 2s (1), 4s (2), 6s (3), 8s (4), 12s (5), 16s (6),20s (7)
The value D12 is recommended.0 s (0), 10 s (1),
30 s (2), 60 s (3), 180 s (4), 600 s (5), 1200 s (6), 1800 s (7)
The value D30 is recommended.1 (0), 2 (1), 4
(2), 10 (3), 20 (4), 50 (5), 100 (6), 200 (7)
Huawei NSN D1 0 D50 1 D100 2 D200 3 D400 4 D600 5 D800 6 D1000 7 D2 8 D4 9 D10 10 D20 11
Use the Huawei baseline value.Use the Huawei baseline value.Use the Huawei baseline value.
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cellIndividualOffset
0 dB
dlTpcStepSize
320 ms
2000 ms t300
0...7, step 1 3 n300
6 s Use the NSN value. t312
4 (2) n312
0.5 s
hysteresis2D
hysteresis2F
640 ms timeToTrigger2D
640 ms timeToTrigger2F
-24~0 -12dbm
-24~0 -9dbm
-24~0 -12dbm
-24~0 -12dbm
-24~0 -9dbm
-24~0 -9dbm
-115~-25 -105dbm
-115~-25 -102dbm
-115~-25 -105dbm
-115~-25 -105dbm
-115~-25 -102dbm
-115~-25 -102dbm
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.Use the Huawei baseline value.
NSN does not have such a parameter.
-35...15 dB, step 0.1 dB
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
sccpchPowerRelativeToPcpich
0.5 dB (0), 1.0 dB (1), 1.5 dB (2), 2.0 dB (3)
Use the Huawei baseline value.
80 ms (3), 160 ms (4), 320 ms (5), 640 ms (6), 1280 ms (7), 2560 ms (8), 5120 ms (9)
Huawei NSN 3 80 ms 4 160 ms 5 320 ms 6 640 ms 7 1280 ms 8 2560 ms 9 5120 ms
utranDrxCycLngCoef
100 ms (0), 200 ms (1), 400 ms (2), 600 ms (3), 800 ms (4), 1000 ms (5), 1200 ms (6), 1400 ms (7), 1600 ms (8), 1800 ms (9), 2000 ms (10), 3000 ms (11), 4000 ms (12), 6000 ms (13), 8000 ms (14)
Huawei NSN DN 100ms<=N<=2000ms D2000 N>2000ms
If the NSN value is larger than the Huawei baseline value, use the NSN value. Otherwise, use the Huawei baseline value.
1...15 s, step 1 s
1 (0), 2 (1), 4 (2), 10 (3), 20 (4), 50 (5), 100 (6), 200 (7), 400 (8), 600 (9), 800 (10), 1000 (11)
Huawei NSN D1 0 D2 1 D4 2 D10 3 D20 4 D50 5 D100 6 D200 7 D400 8 D600 9 D800 10 D1000 11
0.5 s (2), 1 s (3), 2 s (4), 3 s (5), 4 s (6)
Use the Huawei baseline value.
Use the value 0.
Use the value 0.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Use the Huawei baseline value.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Use the Huawei baseline value.Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2D
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2F
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2D
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2D
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2F
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2F
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2D
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2F
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2D
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2D
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2F
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2F
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0 dB qOffset1sn
0 dB qOffset2sn
-18 dB qQualMin
-115 dBm qRxLevMin
hysteresis2D
hysteresis2F
640 ms timeToTrigger2D
640 ms timeToTrigger2F
-24~0 -12dbm
-24~0 -12dbm
-24~0 -12dbm
-24~0 -12dbm
-24~0 -9dbm
-24~0 -9dbm
-24~0 -9dbm
-24~0 -9dbm
-115~-25 -105dbm
-115~-25 -105dbm
-115~-25 -102dbm
-115~-25 -102dbm
8
8
8
4 dB
4 dB
4 dB
6 dB
6 dB
Use the Huawei baseline value.
NSN does not have such a parameter.
-50...50 dB, step 1 dB
Locate the NSN value in the following order:WCEL > ADJI > the RtHopiIdentifier value > the HOPI value > the AdjiQoffset1 value
-50...50 dB, step 1 dB
Locate the NSN value in the following order:WCEL > ADJI > the RtHopiIdentifier value > the HOPI value > the AdjiQoffset2 value
-24...0 dB, step 1 dB
Locate the NSN value in the following order:WCEL > ADJI > the RtHopiIdentifier value > the HOPI value > the AdjiQqualMin value
-115...-25 dBm, step 2 dBm
Locate the NSN value in the following order:WCEL > ADJI > the RtHopiIdentifier value > the HOPI value > the AdjiQrxlevMin valueUse the value 0.
Use the value 0.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Use the Huawei baseline value.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Use the Huawei baseline value.Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2D
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2F
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2D
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2D
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2F
Use the Huawei baseline value.
cpichEcNoThresholdUsedFreq2F
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2D
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2F
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2D
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2D
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2F
Use the Huawei baseline value.
cpichRscpThresholdUsedFreq2F
-110...-47 dBm, step 1 dBm
Use the Huawei baseline value.
-110...-47 dBm, step 1 dBm
Use the Huawei baseline value.
-110...-47 dBm, step 1 dBm
Use the Huawei baseline value.
0...14.5 dB, step 0.5 dB
Use the Huawei baseline value.
cpichEcNoReportingRange1A
0...14.5 dB, step 0.5 dB
Use the Huawei baseline value.
cpichEcNoReportingRange1A
0...14.5 dB, step 0.5 dB
Use the Huawei baseline value.
cpichEcNoReportingRange1A
0...14.5 dB, step 0.5 dB
Use the Huawei baseline value.
cpichEcNoReportingRange1B
0...14.5 dB, step 0.5 dB
Use the Huawei baseline value.
cpichEcNoReportingRange1B
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6 dB
hysteresis1A
hysteresis1B
0...2, step 0.1
100 ms timeToTrigger1A
640 ms timeToTrigger1B
No (0), Yes (1) No
No (0), Yes (1) No
0 dB qOffset1sn
0 dB qOffset2sn
0 dB Use the NSN value.
33 dBm Use the NSN value. pcpichPower
-25 dB Use the NSN value. constantValue
1...64, step 1 8 Use the NSN value.
2 dB Use the NSN value. powerOffsetPO
2 dB PowerOffsetPpm
-3 dB Use the NSN value.
0...50, step 1 0 Use the NSN value. nb01Min
0...50, step 1 50 Use the NSN value. nb01Max
1...32, step 1 8 Use the NSN value. mMax
-3 dB Use the NSN value.
-
0 dB qOffset1sn
0 dB qOffset2sn
0...14.5 dB, step 0.5 dB
Use the Huawei baseline value.
cpichEcNoReportingRange1B
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
managedObject class="WCEL"中包含RtFmcsIdentifier的值对应到managedObject class="FMCS" version="×××" distName="PLMN-PLMN/RNC-××/FMCS-××模版中的ActiveSetWeightingCoefficient值。
Use the Huawei baseline value.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Use the Huawei baseline value.
0 ms (0), 10 ms (1), 20 ms (2), 40 ms (3), 60 ms (4), 80 ms (5), 100 ms (6), 120 ms (7), 160 ms (8), 200 ms (9), 240 ms (10), 320 ms (11), 640 ms (12), 1280 ms (13), 2560 ms (14), 5000 ms (15)
Use the Huawei baseline value.Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter. Huawei NSN
NOT_AFFECT NO AFFECT YES
Huawei NSNNOT_AFFECT NO AFFECT YES-50...50 dB,
step 1 dB
Locate the NSN value in the following order:WCEL > ADJS > the RtHopsIdentifier value > the HOPS value > the AdjsQoffset1 value
-50...50 dB, step 1 dB
Locate the NSN value in the following order:WCEL > ADJS > the RtHopsIdentifier value > the HOPS value > the AdjsQoffset2 value
-35...15 dB, step 0.1 dB
sccpchPowerRelativeToPcpich
-10...50 dBm, step 0.1 dBm-35...-10 dB, step 1 dB
preambleRetransMax
1...8 dB, step 1 dB-5...10 dB, step 1 dB
Use the Huawei baseline value.
-35...15 dB, step 0.1 dB
pschPowerRelativeToPcpich
-35...15 dB, step 0.1 dB
sschPowerRelativeToPcpich
Use the Huawei baseline value.
NSN does not have such a parameter.
R99 (1), Rel4 (2), Rel5 (3), Rel6 (4)
Use the Huawei baseline value.
-50...50 dB, step 1 dB
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
-50...50 dB, step 1 dB
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
Use the Huawei baseline value.
NSN does not have such a parameter.
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0.5 s repInterval1A
0.5 s repInterval1C
2 dB hysteresis1C
100 ms timeToTrigger1C
2...3, step 1 3 maxActiveSetSize
0 dB qOffset1sn
0 dB qOffset2sn
10db sIntraSearch
8 dB sInterSearch
0.5 s repInterval1A
0.5 s repInterval1C
2 dB hysteresis1C
0...2, step 0.1 0
timeToTrigger1C
Not barred barredOrNot
Allowed
40 s tBarred
No (0), Yes (1) Yes (1)
No (0), Yes (1) Yes (1)
No (0), Yes (1) Yes (1)
Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
gui ==> internalNo periodical reporting ==> 00.25 s. Not allowed ==> 10.5 s ==> 21 s ==> 32 s ==> 44 s ==> 58 s ==> 616 s ==> 7
Use the Huawei baseline value.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Use the Huawei baseline value.
NSN does not have such a parameter.
gui ==> internalNo periodical reporting ==> 00.25 s. Not allowed ==> 10.5 s ==> 21 s ==> 32 s ==> 44 s ==> 58 s ==> 616 s ==> 7
Use the Huawei baseline value.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
0...7.5 dB, step 0.5 dB
Use the Huawei baseline value.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
gui ==> internal0 ms ==> 010 ms ==> 120 ms ==> 240 ms ==> 360 ms ==> 480 ms ==> 5100 ms ==> 6120 ms ==> 7160 ms ==> 8200 ms ==> 9240 ms ==> 10320 ms ==> 11640 ms ==> 121280 ms ==> 132560 ms ==> 145000 ms ==> 15
Use the Huawei baseline value.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Use the Huawei baseline value.
The NSN value is 3 as well.
-50...50 dB, step 1 dB
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
-50...50 dB, step 1 dB
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
0...20 dB, step 2 dB
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
0...20 dB, step 2 dB
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
Use the Huawei baseline value.
NSN does not have such a parameter.Use the Huawei
baseline value.Use the Huawei baseline value.
NSN does not have such a parameter.
Use the Huawei baseline value.
NSN does not have such a parameter.
gui ==> internalNo periodical reporting ==> 00.25 s. Not allowed ==> 10.5 s ==> 21 s ==> 32 s ==> 44 s ==> 58 s ==> 616 s ==> 7
Use the Huawei baseline value.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Use the Huawei baseline value.
NSN does not have such a parameter.
gui ==> internalNo periodical reporting ==> 00.25 s. Not allowed ==> 10.5 s ==> 21 s ==> 32 s ==> 44 s ==> 58 s ==> 616 s ==> 7
Use the Huawei baseline value.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
0...7.5 dB, step 0.5 dB
Use the Huawei baseline value.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
NSN value is 0 as well.
Use the Huawei baseline value.
Because the NSN value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the NSN buffering mechanism. If the NSN value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Barred (0), Not barred (1)
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
Allowed (0), Not allowed (1)
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
intraFreqCellReselectInd10 s (0), 20 s
(1), 40 s (2), 80 s (3), 160 s (4), 320 s (5), 640 s (6), 1280 s (7)
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
Use the Huawei baseline value.Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
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2000 ms
29 minutes
0(0ms)
30 min
3s
3s
axDlTxPowerPerOls
minDlTxPower
- tCell
0...511, step 1 - Use the NSN value.
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
0...20 s, step 1 s
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
50...10000 ms, step 50 ms
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
0...1440 minutes, step 1 minutes
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
gui ==> internal8 bytes ==> 816 bytes ==> 1632 bytes ==> 3264 bytes ==> 64128 bytes ==> 128256 bytes ==> 256512 bytes ==> 5121 KB ==> 1024
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
gui ==> internal0 ms ==> 010 ms ==> 1020 ms ==> 2040 ms ==> 4060 ms ==> 6080 ms ==> 80100 ms ==> 100120 ms ==> 120160 ms ==> 160200 ms ==> 200240 ms ==> 240320 ms ==> 320640 ms ==> 6401280 ms ==> 12802560 ms ==> 25605000 ms ==> 5000
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
1...60 min, step 1 min
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
0.5...10 s, step 0.5 sinternal_value = gui_value * 2
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
0.5...10 s, step 0.5 sinternal_value = gui_value * 2
Use the Huawei baseline value.
For state transition, the NSN mechanism is different from the Huawei mechanism. The NSN mechanism imposes restrictions on the user plane and control plane. However, the Huawei baseline value is recommended.
Use the Huawei baseline value.
Use the Huawei baseline value.Use the Huawei baseline value.Use the Huawei baseline value.Use the Huawei baseline value.Use the Huawei baseline value.Use the Huawei baseline value.Use the Huawei baseline value.
InterFreqCSThd2DEcN0 + 3
NSN does not have such a parameter.
InterFreqR99PsThd2DEcN0 + 3
NSN does not have such a parameter.
InterFreqR99PsThd2DEcN0 + 3
NSN does not have such a parameter.
InterFreqCSThd2DRSCP + 3
NSN does not have such a parameter.
InterFreqR99PsThd2DRSCP + 3
NSN does not have such a parameter.
InterFreqR99PsThd2DRSCP + 3
NSN does not have such a parameter.
0 chips (0), 256 chips (1), 512 chips (2), 768 chips (3), 1024 chips (4), 1280 chips (5), 1536 chips (6), 1792 chips (7), 2048 chips (8), 2304 chips (9)
Huawei NSNCHIP0 0chipsCHIP256 256chipsCHIP512 512chipsCHIP768 768chipsCHIP1024 1024 chipsCHIP1280 1280chipsCHIP1536 1536chipsCHIP1792 1792chipsCHIP2048 2048chipsCHIP2304 2304chips
primaryScramblingCode
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- Use the NSN value. locationAreaCode
- - Use the NSN value. serviceAreaCode
0...255, step 1 - Use the NSN value. routingAreaCode
- Use the NSN value. cellId
- Use the NSN value.
0...40,step 1 - Use the NSN value.
0...40,step 1 - Use the NSN value.
0...40,step 1 - Use the NSN value.
0...40,step 1 - Use the NSN value.
0...6.2,step 0.2 - Use the NSN value.
0...31,step 1 - Use the NSN value.
0.5 s (2), 1 s (3), -
1...32 -
1..60 - Use the NSN value.
1...3 - Use the NSN value.
No (0), Yes (1)
1...65535, step 1
1...65535, step 10...16383, step 1
dlFrequencyNumber
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
Before using the NSN value, turn on the SIB4 switch by running the following command:MOD UCELLSIBSWITCH: CellId=***, SibCfgBitMap=SIB4-1;
HUAWEI NSN D500 0.5SD1000 1SD2000 2SD3000 3SD4000 4SHUAWEI<==>GsmMeasAveWindow*GsmMeasRepInterval
Use the Huawei baseline value.
No (0), Yes (1), Priority (2)
HUAWEI NSN HO_INTER_RAT_CS_OUT_SWITCH-0 NO
HUAWEI NSN HO_INTER_RAT_PS_OUT_SWITCH-0 NOUse the Huawei baseline value.
Filtering period of 200 ms (0), Filtering periodapproximates 300 ms (1), Filtering period approximates400 ms (2), Filtering period approximates600 ms (3), Filtering period approximates 800 ms(4), Filtering period approximates 1100 ms (5), Filteringperiod approximates 1600 ms (6)
HUAWEI NSN0 Filtering period approximates 200 msUse the Huawei baseline value.
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ALU
UA5.1
Meaning Parameter Value Range Recommended Value Mapping Rule Remark
0
-115
-5 Huawei = ALU x 10
45
1
256
2500
0 Use the ALU value.
35
notReserved
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TS 25.331.Offset between a cell and one of its Fdd neighbouring cells, in case the quality measure for cell selection/reselection is set to RSCP.
Integer: min = -50, max = 50
Find the value for FDDCell id from Alcatel-Lucent (ALU) RNC scripts. Then, find the value for GsmNeighbouringCell id with the previous value.
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.
Integer: min = -119, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, find the value for GsmNeighbouringCell id with the previous value.
Power on the Common Control Physical Channel relative to Pcpich power.As the Primary CCPCH needs to be available over the whole cell area and to be demodulated by all the terminals in the system, BCH power must be relatively high, in order to reach all the users within the coverage area, without creating interferences preventing the mobile from reading CPICH channel.Indeed, if P-CCPCH decoding fails, the terminals can’t access the system because they are unable to obtain the critical parameters such as random access codes or code channels used for other common channels.
Float: min = -35, max = 15, step = 0.1
TS 25.433 Maximum transmission powerMaximum Transmission Power for all downlink channels added together allowed on the cell on average, applied to the local cell Power.MaxTxPower must imperatively be smaller than MaxDlPowerCapability which is calculated and given by the NodeB via the message NBAP Resource Status Indication, where MaxDlPowerCapabilmity= PaRatio*MaxPowerAmplification + Tx Losses such as DDM Tx losses, Tx Splitter losses,…
Float: min = 0, max = 50, step = 0.1
Check which value is used in the live network.
TS 25.214 N_INSYNC_IND This parameter defines the number of successive in sync indications after which the nodeB shall trigger the Radio Link Restore procedure
Integer: min = 1, max = 256
If the ALU value is smaller than the Huawei baseline value, use the ALU value. Otherwise, use the Huawei baseline value.
TS 25.214 N_OUTSYNC_IND This parameter defines the number of consecutive out-of-sync indications after which the timer T_RLFAILURE shall be started.
The UL NBAP Synchronization Parameters (FddCell.nOutSyncInd & FddCell.tRLFailure) are strongly coupled with the DL RRC Synchronization Parameters (UeTimerCstConnectedMode.N313 & UeTimerCstConnectedMode.T313 ) changing them may impact the RRC Connection Re-establishment Quality of Service:(nOutSyncInd * 10) + tRLFailure < (N313 * 10) + T313 + PA off
Integer: min = 1, max = 256
If the ALU value is larger than the Huawei baseline value, use the ALU
TS 25.214 T_RLFAILUREThe Radio Link Failure procedure shall be triggered after a period of time T_RLFAILURE has elapsed with a persisting out-of-sync indication.
The UL NBAP Synchronization Parameters (FddCell.nOutSyncInd & FddCell.tRLFailure) are strongly coupled with the DL RRC Synchronization Parameters (UeTimerCstConnectedMode.N313 & UeTimerCstConnectedMode.T313 ) changing them may impact the RRC Connection Re-establishment Quality of Service:(nOutSyncInd * 10) + tRLFailure < (N313 * 10) + T313 + PA off
Integer: min = 0, max = 25500, step = 100
If the ALU value is larger than the Huawei baseline value, use the ALU value. Otherwise, use the Huawei baseline value.Huawei ALUTRlFailure <==> tRlFailure/100
TS 25.331 Cell individual offsetUsed to offset measured quantity value.For each cell that is monitored, an offset can be assigned with inband signalling. The offset can be either positive or negative. The offset is added to the measurement quantity before the UE evaluates if an event has occurred.
Float: min = -10, max = 10, step = 0.5
TS 25.433 Primary CPICH powerPower on the Primary Common Pilot Channel applied to the maxTxPower.CPICH Power is the power that shall be used for transmitting the CPICH in a cell.For a fixed number of users, the higher the CPICH Power, the bigger the coverage area.Reducing the CPICH Power causes part of the terminals to hand over to other cells, while increasing it invites more terminals to hand over to the cell and to make their initial access to the network in that cell.The power for other common channels is defined relatively to this CPICH Power.
Float: min = -10, max = 50, step = 0.1
Check which value is used in the live network.
TS 25.331When the parameter barredornot is indicated as "not barred" and "reserved" for operator use, UEs assigned to Access Class 11 or 15 may select/re-select this cell if in the home PLMN and UEs assigned to an Access Class in the range 0 to 9 and 12
Enum (RrcReservedIndicator) : reserved(0),notReserved(1)
Huawei ALU NOT_RESERVED notReserved RESERVED Reserved
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
TS 25.304. This list, referred to as Access Control, shall allow to prevent selected
(RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED 1 BARRED 0
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notBarred
allowed
barredS160
-106.1
20
1
1
1280
1280
-14
-14
-13
-14
-13
-13
-105
-105
-104
-105
-104
-104
1
1
1280 Huawei = D(ALU)
1280 Huawei = D(ALU)
-14
TS 25.331 Cell barredWhen cell status "barred" is indicated , the UE is not permit to select/reselect this cell, not even for emergency calls. For a status "not barred", the UE may select/reselect this cell during the cell selection and reselection procedures in idle mode and in connected mode.
Enum (RrcAccessClassBarred) : barred(0),notBarred(1)
Huawei ALU NOT_BARRED notBarre BARRED Barred
TS 25.331If it is set to "not allowed", the UE shall not reselect a cell on the same frequency as the barred cell. For emergency call, this information shall be ignored and the UE may select another intra-frequency cell.
Enum (RrcAllowedIndicator) : allowed(0),notAllowed(1)
Huawei ALU ALLOWED 0 NOT_ALLOWED 1
TS 25.331After expiry of this time interval, the UE shall check again whether the status of the barred cell has changed.
Enum (RrcTBarred) : barredS10(0),barredS20(1),barredS40(2),barredS80(3),barredS160(4),barredS320(5),barredS640(6),barredS1280(7)
Huawei ALU D10 barredS10 D20 barredS20 ………………………. D1280 barredS1280
Reference of RTWP when the BTS does not receive any radio signal for this cell. If the parameter isRtwpReferenceSelfLearning is set to TRUE, this parameter is only used to initiate the RTWP self learning feature.
Float: min = -115.0, max = -50.0, step = 0.1
Huawei = AL x 10 + 1120Power margin in
percentage of DCH power that cannot be used for HSDPA.
Integer: min = 0, max = 100
Huawei = 10log(1-dchPowerMargin) + maxTxPower(ALU) - MaxTxPower(Huawei)Use the Huawei baseline value.
ALU does not have such a parameter.
This parameter defines the hysteresis to configure for the triggering of Event 2D in Full Event Mode.
Float: min = 0.0, max = 7.5, step = 0.5
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. For example, "HoConfClass/0" indicates that the value for HoConfClass is 0. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. At last, use the ALU value multiplied by 2.
This parameter defines the hysteresis to configure for the triggering of Event 2F in Full Event Mode.
Float: min = 0.0, max = 7.5, step = 0.5
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. At last, use the ALU value multiplied by 2.
Indicates the period of time during which the condition of the Event2D has to be satisfied before sending a Measurement Report
Enum (timeToTrigger2D) : 0(0),10(1),20 (2),40 (3),60 (4),80 (5),100 (6),120 (7),160 (8),200 (9),240 (10),320 (11),640 (12),1280 (13),2560 (14),5000 (15)
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Indicates the period of time during which the condition of the Event2F has to be satisfied before sending a Measurement Report
Enum (timeToTrigger2F) : 0(0),10(1),20 (2),40 (3),60 (4),80 (5),100 (6),120 (7),160 (8),200 (9),240 (10),320 (11),640 (12),1280 (13),2560 (14),5000 (15)
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
This parameter defines the hysteresis to configure for the triggering of Event 2D in Full Event Mode.
Float: min = 0.0, max = 7.5, step = 0.5
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. At last, use the ALU value multiplied by 2.
This parameter defines the hysteresis to configure for the triggering of Event 2F in Full Event Mode.
Float: min = 0.0, max = 7.5, step = 0.5
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. At last, use the ALU value multiplied by 2.
Indicates the period of time during which the condition of the Event2D has to be satisfied before sending a Measurement Report
Enum (timeToTrigger2D) : 0(0),10(1),20 (2),40 (3),60 (4),80 (5),100 (6),120 (7),160 (8),200 (9),240 (10),320 (11),640 (12),1280 (13),2560 (14),5000 (15)
Indicates the period of time during which the condition of the Event2F has to be satisfied before sending a Measurement Report
Enum (timeToTrigger2F) : 0(0),10(1),20 (2),40 (3),60 (4),80 (5),100 (6),120 (7),160 (8),200 (9),240 (10),320 (11),640 (12),1280 (13),2560 (14),5000 (15)
Use the Huawei baseline value.
ALU does not have such a parameter.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
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-14
-13
-14
-13
-13
-105
-105
-104
-105
-104
-104
4,5
4,5
4,5
7,5
7,5
7,5
1
1
200
640
3
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Reporting Range to configure for the triggering condition of the Event 1A in Full Event Mode.For Calls : the new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id);For Cell : the new value of the parameter has to be taken into account by Cell at next update of SysInfo (see [R30]).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsConversational. At last, use the ALU value multiplied by 2.
Reporting Range to configure for the triggering condition of the Event 1A in Full Event Mode.For Calls : the new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id);For Cell : the new value of the parameter has to be taken into account by Cell at next update of SysInfo (see [R30]).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. At last, use the ALU value multiplied by 2.
Reporting Range to configure for the triggering condition of the Event 1A in Full Event Mode.For Calls : the new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id);For Cell : the new value of the parameter has to be taken into account by Cell at next update of SysInfo (see [R30]).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR. At last, use the ALU value multiplied by 2.
Reporting Range to configure for the triggering condition of the Event 1B in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsConversational. At last, use the ALU value multiplied by 2.
Reporting Range to configure for the triggering condition of the Event 1B in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsConversational. At last, use the ALU value multiplied by 2.
Reporting Range to configure for the triggering condition of the Event 1B in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to PsIbHighBR. At last, use the ALU value multiplied by 2.
This parameter defines the hysteresis to configure for the triggering of event 1A in Full Event mode
Float: min = 0.0, max = 7.5, step = 0.5
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. At last, use the ALU value multiplied by 2.
This parameter defines the hysteresis to configure for the triggering of event 1B in Full Event mode
Float: min = 0.0, max = 7.5, step = 0.5
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. At last, use the ALU value multiplied by 2.
Use the Huawei baseline value.
ALU does not have such a parameter.
This parameter defines the period during which the condition of the event 1A must be satisfied before sending a measurement report in full event mode
{0, 10, 20, 40, 60, 80, 100, 120, 160, 200, 240, 320, 640, 1280, 2560, 5000}
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. If the ALU value is smaller than the Huawei baseline value, use the ALU alue, that is, use the following formula:Huawei = D (ALU)If the ALU value is larger than the Huawei baseline value, use the Huawei baseline value.
This parameter defines the period during which the condition of the event 1B must be satisfied before sending a measurement report in full event mode
Enum (ms){0, 10, 20, 40, 60, 80, 100, 120, 160, 200, 240, 320, 640, 1280, 2560, 5000}
Find the value for FDDCell id from ALU RNC scripts. Then, determine which handover template is used by the cell based on RadioAccessService, DedicatedConf, and HoConfClass values. After this, find the ALU value from the section where UsHoConf id is set to CsSpeech. If the ALU value is larger than the Huawei baseline value, use the ALU alue, that is, use the following formula:Huawei = D (ALU)If the ALU value is smaller than the Huawei baseline value, use the Huawei baseline value.
Use the Huawei baseline value.
ALU does not have such a parameter.
maximum active set size
Integer[1..6]
Use the Huawei baseline value.
The ALU value is 3 as well.
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10 Huawei = ALU/2
10 Huawei = ALU/2
10 Huawei = ALU/2
10 Huawei = ALU/2
31 Use the ALU value.
-16 Use the ALU value.
-115
-32 Huawei = ALU/2
-32 Huawei = ALU/2
-32 Huawei = ALU/2
-5 Use the ALU value.
N.A. Use the ALU value.
20 Use the ALU value.
Boolean true
N.A.
6 Use the ALU value.
7
5
1 Use the ALU value.
ueConst1
3
n313_200
t314_8S
t315_0S
ueConst1 Use the ALU value.
0 Use the ALU value.
-16 Use the ALU value.
-115
TS 25.331hysteresis value of the serving cell.It is used in the process of selection/reselection of cell by the UE in case the quality measure for cell selection and re-selection is set to CPICH RSCP.
Integer: min = 0, max = 40, step = 2
TS 25.331hysteresis value of the serving cell.It is used in the process of selection/reselection of cell by the UE in case the quality measure for cell selection and re-selection is set to CPICH RSCP.
Integer: min = 0, max = 40, step = 2
TS 25.331hysteresis value of the serving cell.It is used in the process of selection/reselection of cell by the UE in case the quality measure for cell selection and re-selection is set to CPICH Ec/No.
Integer: min = 0, max = 40, step = 2
TS 25.331hysteresis value of the serving cell.It is used in the process of selection/reselection of cell by the UE in case the quality measure for cell selection and re-selection is set to CPICH Ec/No.
Integer: min = 0, max = 40, step = 2
TS 25.331 TreselectionCellSelectionInfo :>tReselIt defines the time to trigger for cell reselection.
Integer: min = 0, max = 31
The minimum required quality threshold corresponding to CPICH Ec/No. The UE can camp on the cell only when the measured CPICH Ec/No is greater than the value of this parameter. The higher the parameter value is, the more difficult it is for the UE to reside in the cell. The lower parameter value is, the easier it is for the UE to reside in the cell, but it is possible that the UE cannot receive the system messages that are sent through the PCCPCH. For detailed information, refer to the 3GPP TS 25.304.
Integer: min = -24, max = 0
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.
Integer: min = -119, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, find the value for GsmNeighbouringCell id with the previous value.
TS 25.331OPTIONALCellSelectionInfo :>SintraSearchIt defines the threshold for intra-frequency measuremnt and for the HCS measurement rules.Thus, if Sx> Sintrasearch, UE need not perform intra frequency measuerement, where Sx corresponds to Squal for
Integer: min = -32, max = 20, step = 2
TS 25.331OPTIONALCellSelectionInfo :>SinterSearchIt defines the threshold for inter-frequency measurement and for the HCS (Hierarchical Cell Structure) measurement rules.Thus, if Sx> Sintersearch, UE need not perform inter frequency measurement, where Sx corresponds to Squal for FDD cell and Srxlev for TDD and GSM cells.
Integer: min = -32, max = 20, step = 2
TS 25.331Threshold to kick off measurements on RATIdcells for eventually performing an intersystem cellreselection following algorithm described in TS25.304.
Integer: min = -32, max = 20, step = 2
TS 25.433 PICH PowerPower allocated on the Pich channel.PICH power must be high enough so that PICH channel is heard by all terminals in the cell without creating interferences preventing the mobile from reading CPICH channel.But this power must be sufficient to allow the mobile to detect paging information of this channel.
Integer: min = -10, max = 5
TS 25.433 AICH PowerPower of the Acquisition Indicator Channel.AICH power must be high enough so that AICH is heard by all terminals in the cell without creating interferences preventing the mobile from reading CPICH channel.But this power must be sufficient to allow the terminal to detect Acquisition Indicator.
Float: min = -22, max = 5
ITS 24.008It corresponds to the timer T3212 in TS 24.008.This parameter indicates the time between two location update requests,0 means that no periodic location update is requested.
Integer: min = 0, max = 255This parameter
indicates if the Attach procedure is allowed.
Huawei ALU ALLOWED True NOT_ALLOWED False
TS 24.008 NMONetwork Mode of OperationIts value depends on the interface Gs existence between VLR and SGSN. It indicates to the mobile if the UE can perform a recording/update of location and routing areas in a combined way (PS and CS at the same time) or if 2 distint procedures are necessary for PS and CS domains.nmoValue0 corresponds to Network Operation Mode1 (Gs interface present) and nmoValue1 to Mode2 (Gs interface not present).
Enum (Nmo) : nmoValue0(0),nmoValue1(1)
Huawei ALU MODE1 nmoValue0 MODE2 nmoValue1
UTRAN DRX cycle length coefficientUTRAN DRX cycle length = 2^ UtranDrxCynLngCoef expressed in 10 ms radio frames
Integer: min = 3, max = 9
TS 25.331 T302This timer starts at the transmission of CELL UPDATE/URA UPDATE and stops at the reception of of CELL UPDATE CONFIRM/URA UPDATE CONFIRM. At its expiry, the mobile must retransmit CELL UPDATE/URA UPDATE if V302 =< N302, else, go to Idle mode
ueTimerConn400MS
Enum (UeTimerConnMode8) : ueTimerConn100MS (0), ueTimerConn200MS (1), ueTimerConn400MS (2), ueTimerConn600MS (3), ueTimerConn800MS (4), ueTimerConn1000MS (5), ueTimerConn1200MS (6), ueTimerConn1400MS (7), ueTimerConn1600MS (8), ueTimerConn1800MS (9), ueTimerConn2000MS (10), ueTimerConn3000MS (11), ueTimerConn4000MS (12), ueTimerConn6000MS (13), ueTimerConn8000MS (14)
Huawei ALU D100 ueTimerConn200MS ……………………………………… D8000 ueTimerConn8000MS
TS 25.331 N302Maximum number of retransmissions of the CELL UPDATE / URA UPDATE message if no answer of the network within T302
Integer: min = 0, max = 7
If the ALU value is larger than the Huawei baseline value, use the ALU value. Otherwise, use the Huawei baseline value.
TS 25.331 T309This timer starts upon reselection of a cell belonging to another radio access system from connected mode, or reception of CELL CHANGE ORDER FROM UTRAN message, and Successful establishment of a connection in the new cell. At the expiry, the UE resumes the connection to UTRAN.
Integer: min = 1, max = 8
If the ALU value is larger than the Huawei baseline value, use the ALU value. Otherwise, use the Huawei baseline value.
TS 25.331 T312This timer starts when the UE starts to establish DCH and stops when the UE detects consecutive N312 "in sync" indication from L1.. At its expiration, the criteria for physical channel establishment failure is fulfilled.
Integer: min = 0, max = 15TS 25.331 N312
Maximum number of successive "in sync" received from L1.
Enum (UeConstIdleMode) : ueConst1(0),ueConst2(1),ueConst4(2),ueConst10(3),ueConst20(4),ueConst50(5),ueConst100(6),ueConst200(7),ueConst400(8),ueConst600(9),ueConst800(10),ueConst1000(11)
Huawei ALU D1 ueConst1 D2 ueConst2 D4 ueConst4 ……………… D600 ueConst600 D800 ueConst800 D1000 ueConst1000
TS 25.331 T313This timer starts when the UE detects consecutive N313 "out of sync" indication from L1., and stops when the UE detects consecutive N315 "in sync" indication from L1. At its expiration, the criteria for Radio Link failure is fulfilled.
The UL NBAP Synchronization Parameters (FddCell.nOutSyncInd & FddCell.tRLFailure) are strongly coupled with the DL RRC Synchronization Parameters (UeTimerCstConnectedMode.N313 & UeTimerCstConnectedMode.T313 ) changing them may impact the RRC Connection Re-establishment Quality of Service:(nOutSyncInd * 10) + tRLFailure < (N313 * 10) + T313 + PA off
Integer: min = 0, max = 15
If the ALU value is larger than the Huawei baseline value, use the ALU value. Otherwise, use the Huawei baseline value.
TS 25.331 N313Maximum number of successive "out of sync" received from L1.
The UL NBAP Synchronization Parameters (FddCell.nOutSyncInd & FddCell.tRLFailure) are strongly coupled with the DL RRC Synchronization Parameters (UeTimerCstConnectedMode.N313 & UeTimerCstConnectedMode.T313 ) changing them may impact the RRC Connection Re-establishment Quality of Service:(nOutSyncInd * 10) + tRLFailure < (N313 * 10) + T313 + PA off
Enum (N313) : n313_1(0),n313_2 (1), n313_4 (2), n313_10 (3), n313_20 (4), n313_50 (5), n313_100 (6), n313_200 (7)
Huawei ALU D50 n313_1 ………………………… D50 n313_50 D100 n313_100 D200 n313_200
TS 25.331 T314 This timer starts when the criteria for radio link failure are fulfilled, and stops when the Cell Update procedure has been completed.
Enum (T314) : t314_0S(0), t314_2S (1), t314_4S (2), t314_6S (3), t314_8S (4), t314_12S (5), t314_16S (6), t314_20S (7)
Huawei ALU DN t314_Ns
TS 25.331 T315 This timer starts when the criteria for radio link failure are fulfilled, and stops when the Cell Update procedure has been completed.
Enum (T315) : t315_0S(0), t315_10S (1), t315_30S (2), t315_60S (3), t315_180S (4), t315_600S (5), t315_1200S (6), t315_1800S (7)
Huawe ALU DN t315_Ns
TS 25.331 N315Maximum number of successive "in sync" received from L1 during T313 is activated.
Enum (UeConstIdleMode) : ueConst1(0),ueConst2(1),ueConst4(2),ueConst10(3),ueConst20(4),ueConst50(5),ueConst100(6),ueConst200(7),ueConst400(8),ueConst600(9),ueConst800(10),ueConst1000(11)
TS 25.331 Cell individual offsetUsed to offset measured quantity value.For each cell that is monitored, an offset can be assigned with inband signalling. The offset can be either positive or negative. The offset is added to the measurement quantity before the UE evaluates if an event has occurred.
Float: min = -10, max = 10, step = 0.5
The minimum required quality threshold corresponding to CPICH Ec/No. The UE can camp on the cell only when the measured CPICH Ec/No is greater than the value of this parameter. The higher the parameter value is, the more difficult it is for the UE to reside in the cell. The lower parameter value is, the easier it is for the UE to reside in the cell, but it is possible that the UE cannot receive the system messages that are sent through the PCCPCH. For detailed information, refer to the 3GPP TS 25.304.
Integer: min = -24, max = 0
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.
Integer: min = -119, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, find the value for GsmNeighbouringCell id with the previous value.
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0 Use the ALU value.
-1
1
6 Use the ALU value.
7
1 Use the ALU value.
ueConst1
1
1
1280
1280
-14
-14
-13
-14
-13
-13
-105
-105
-104
-105
-104
-104
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
TS 25.331 Cell individual offsetUsed to offset measured quantity value.For each cell that is monitored, an offset can be assigned with inband signalling. The offset can be either positive or negative. The offset is added to the measurement quantity before the UE evaluates if an event has occurred.
Float: min = -10, max = 10, step = 0.5 Use the Huawei
baseline value.ALU does not have such a parameter.
Secondary CCPCH power relative to Pcpich power.Secondary CCPCH power relative to P-CPICH power configured in a cell.The S-CCPCH channel carries two different common transport channels, which are multiplexed. This doesn’t imply necessarily that the S-CCPCH power is shared into between FACH power and PCH power. Thus, it is possible that these powers are equal to the S-CCPCH power.A high power can produce interferences preventing the mobile from reading CPICH channel, for example, and reducing the required transmission power level improves downlink system capacity.
Float: min = -35, max = 15, step = 0.1
If ALU value multiplied by 10 is larger than the Huawei baseline value, use the multiplied ALU value. Otherwise, use the Huawei baseline value.
TS 25.433 FDD TPC Downlink step sizeTPC downlink step size : step size for the dowlink power adjustment
Enum (DlStepSize) : 05(0),1(1)
Use the Huawei baseline value.
Each vendor has its own algorithm for the inner loop power control parameter. However, the Huawei baseline value is recommended.
UTRAN DRX cycle length coefficientUTRAN DRX cycle length = 2^ UtranDrxCynLngCoef expressed in 10 ms radio frames
Integer: min = 3, max = 9
TS 25.331 T300This timer starts at the transmission of RRC CONNECTION REQUEST and stops at the reception of RRC CONNECTION SETUP. At its expiry, the mobile must retransmit RRC CONNECTION REQUEST if V300 =< N300, else go to Idle mode
Enum (UeTimerIdleMode8) : ueTimerIdle100MS (0), ueTimerIdle200MS (1), ueTimerIdle400MS (2), ueTimerIdle600MS (3), ueTimerIdle800MS (4), ueTimerIdle1000MS (5), ueTimerIdle1200MS (6), ueTimerIdle1400MS (7), ueTimerIdle1600MS (8), ueTimerIdle1800MS (9), ueTimerIdle2000MS (10), ueTimerIdle3000MS (11), ueTimerIdle4000MS (12), ueTimerIdle6000MS (13), ueTimerIdle8000MS (14)
ueTimerIdle1200MS
Huawei ALU D100 ueTimerIdle100MS D200 ueTimerIdle200MS D400 ueTimerIdle400MS ................................................ D2000 ueTimerIdle2000MS D3000 ueTimerIdle2000MS D4000 ueTimerIdle2000MS D6000 ueTimerIdle2000MS D8000 ueTimerIdle2000MS
TS 25.331 N300It corresponds to the maximum number of retransmissions of the RRC CONNECTION REQUEST message
Integer: min = 0, max = 7
If the ALU value is larger than the Huawei baseline value, use the ALU value. Otherwise, use the Huawei baseline value.
TS 25.331 T312This timer starts when the UE starts to establish DCH and stops when the UE detects consecutive N312 "in sync" indication from L1.. At its expiration, the criteria for physical channel establishment failure is fulfilled.
Integer: min = 0, max = 15TS 25.331 N312
Maximum number of successive "in sync" received from L1.
Enum (UeConstIdleMode) : ueConst1(0),ueConst2(1),ueConst4(2),ueConst10(3),ueConst20(4),ueConst50(5),ueConst100(6),ueConst200(7),ueConst400(8),ueConst600(9),ueConst800(10),ueConst1000(11)
Huawei ALU D1 ueConst1 D2 ueConst2 D4 ueConst4 ……………… D600 ueConst600 D800 ueConst800 D1000 ueConst1000
Use the Huawei baseline value.
ALU does not have such a parameter.
This parameter defines the hysteresis to configure for the triggering of Event 2D in Full Event Mode.
Float: min = 0.0, max = 7.5, step = 0.5
Use the Huawei baseline value.
This parameter defines the hysteresis to configure for the triggering of Event 2F in Full Event Mode.
Float: min = 0.0, max = 7.5, step = 0.5
Use the Huawei baseline value.
Indicates the period of time during which the condition of the Event2D has to be satisfied before sending a Measurement Report
Enum (timeToTrigger2D) : 0(0),10(1),20 (2),40 (3),60 (4),80 (5),100 (6),120 (7),160 (8),200 (9),240 (10),320 (11),640 (12),1280 (13),2560 (14),5000 (15)
Use the Huawei baseline value.
Indicates the period of time during which the condition of the Event2F has to be satisfied before sending a Measurement Report
Enum (timeToTrigger2F) : 0(0),10(1),20 (2),40 (3),60 (4),80 (5),100 (6),120 (7),160 (8),200 (9),240 (10),320 (11),640 (12),1280 (13),2560 (14),5000 (15)
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
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0
0
-16 Use the ALU value.
-115
1
1
1280
1280
-14
-14
-13
-14
-13
-13
-105
-105
-104
-105
-104
-104
4,5
4,5
4,5
7,5
7,5
Use the Huawei baseline value.
ALU does not have such a parameter.
TS 25.331.Offset between a cell and one of its Fdd neighbouring cells, in case the quality measure for cell selection/reselection is set to RSCP.
Integer: min = -50, max = 50
Find the value for FDDCell id from ALU RNC scripts. Then, find the value for UmtsNeighbouringRelation id with the previous value. After this, find the ALU value with the UmtsNeighbouringRelation id value.
TS 25.331Offset between a cell and one of its GSMneighbouring cells, in case the quality measure for cell selection/reselection is set to CPICH Ec/No.
Integer: min = -50, max = 50
Find the value for FDDCell id from ALU RNC scripts. Then, find the value for UmtsNeighbouringRelation id with the previous value. After this, find the ALU value with the UmtsNeighbouringRelation id value.
The minimum required quality threshold corresponding to CPICH Ec/No. The UE can camp on the cell only when the measured CPICH Ec/No is greater than the value of this parameter. The higher the parameter value is, the more difficult it is for the UE to reside in the cell. The lower parameter value is, the easier it is for the UE to reside in the cell, but it is possible that the UE cannot receive the system messages that are sent through the PCCPCH. For detailed information, refer to the 3GPP TS 25.304.
Integer: min = -24, max = 0
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.
Integer: min = -119, max = -25
Find the value for FDDCell id from ALU RNC scripts. Then, find the value for GsmNeighbouringCell id with the previous value.
This parameter defines the hysteresis to configure for the triggering of Event 2D in Full Event Mode.
Float: min = 0.0, max = 7.5, step = 0.5
Use the Huawei baseline value.
This parameter defines the hysteresis to configure for the triggering of Event 2F in Full Event Mode.
Float: min = 0.0, max = 7.5, step = 0.5
Use the Huawei baseline value.
Indicates the period of time during which the condition of the Event2D has to be satisfied before sending a Measurement Report
Enum (timeToTrigger2D) : 0(0),10(1),20 (2),40 (3),60 (4),80 (5),100 (6),120 (7),160 (8),200 (9),240 (10),320 (11),640 (12),1280 (13),2560 (14),5000 (15)
Use the Huawei baseline value.
Indicates the period of time during which the condition of the Event2F has to be satisfied before sending a Measurement Report
Enum (timeToTrigger2F) : 0(0),10(1),20 (2),40 (3),60 (4),80 (5),100 (6),120 (7),160 (8),200 (9),240 (10),320 (11),640 (12),1280 (13),2560 (14),5000 (15)
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Ec/No) in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -24, max = 0
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2D (which Measurement quantity is CPICH Rscp) in Full Event Mode . The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.
Threshold used for the triggering condition of the Event 2F (which Measurement quantity is CPICH Rscp) in Full Event Mode .The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Integer: min = -120, max = -25
Use the Huawei baseline value.Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Reporting Range to configure for the triggering condition of the Event 1A in Full Event Mode.For Calls : the new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id);For Cell : the new value of the parameter has to be taken into account by Cell at next update of SysInfo (see [R30]).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Use the Huawei baseline value.
Reporting Range to configure for the triggering condition of the Event 1A in Full Event Mode.For Calls : the new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id);For Cell : the new value of the parameter has to be taken into account by Cell at next update of SysInfo (see [R30]).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Use the Huawei baseline value.
Reporting Range to configure for the triggering condition of the Event 1A in Full Event Mode.For Calls : the new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id);For Cell : the new value of the parameter has to be taken into account by Cell at next update of SysInfo (see [R30]).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Use the Huawei baseline value.
Reporting Range to configure for the triggering condition of the Event 1B in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Use the Huawei baseline value.
Reporting Range to configure for the triggering condition of the Event 1B in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Use the Huawei baseline value.
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7,5
1
1
200
640
0
0
-1 Huawei = ALU x 10
35
-10 Use the ALU value.
32 Use the ALU value.
3 Use the ALU value.
N.A.
-5 Huawei = ALU x 10
30 Use the ALU value.
30 Use the ALU value.
4 Use the ALU value.
-5 Huawei = ALU x 10
0
0
Reporting Range to configure for the triggering condition of the Event 1B in Full Event Mode.The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Float (dB)[0.0 .. 14.5] with step = 0.5 dB
Use the Huawei baseline value.
This parameter defines the hysteresis to configure for the triggering of event 1A in Full Event mode
Float: min = 0.0, max = 7.5, step = 0.5
Use the Huawei baseline value.
This parameter defines the hysteresis to configure for the triggering of event 1B in Full Event mode
Float: min = 0.0, max = 7.5, step = 0.5
Use the Huawei baseline value.Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
This parameter defines the period during which the condition of the event 1A must be satisfied before sending a measurement report in full event mode
{0, 10, 20, 40, 60, 80, 100, 120, 160, 200, 240, 320, 640, 1280, 2560, 5000}
Use the Huawei baseline value.
This parameter defines the period during which the condition of the event 1B must be satisfied before sending a measurement report in full event mode
Enum (ms){0, 10, 20, 40, 60, 80, 100, 120, 160, 200, 240, 320, 640, 1280, 2560, 5000}
Use the Huawei baseline value.Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
TS 25.331.Offset between a cell and one of its Fdd neighbouring cells, in case the quality measure for cell selection/reselection is set to RSCP.
Integer: min = -50, max = 50
Find the value for FDDCell id from ALU RNC scripts. Then, find the value for UmtsNeighbouringRelation id with the previous value. After this, find the ALU value with the UmtsNeighbouringRelation id value.
TS 25.331Offset between a cell and one of its GSMneighbouring cells, in case the quality measure for cell selection/reselection is set to CPICH Ec/No.
Integer: min = -50, max = 50
Find the value for FDDCell id from ALU RNC scripts. Then, find the value for UmtsNeighbouringRelation id with the previous value. After this, find the ALU value with the UmtsNeighbouringRelation id value.
Secondary CCPCH power relative to Pcpich power.Secondary CCPCH power relative to P-CPICH power configured in a cell.The S-CCPCH channel carries two different common transport channels, which are multiplexed. This doesn’t imply necessarily that the S-CCPCH power is shared into between FACH power and PCH power. Thus, it is possible that these powers are equal to the S-CCPCH power.A high power can produce interferences preventing the mobile from reading CPICH channel, for example, and reducing the required transmission power level improves downlink system capacity.
Float: min = -35, max = 15, step = 0.1
TS 25.433 Primary CPICH powerPower on the Primary Common Pilot Channel applied to the maxTxPower.CPICH Power is the power that shall be used for transmitting the CPICH in a cell.For a fixed number of users, the higher the CPICH Power, the bigger the coverage area.Reducing the CPICH Power causes part of the terminals to hand over to other cells, while increasing it invites more terminals to hand over to the cell and to make their initial access to the network in that cell.The power for other common channels is defined relatively to this CPICH Power.
Float: min = -10, max = 50, step = 0.1
Check which value is used in the live network.
TS 25.331This constant value is used by the UE to calculate the initial output power on PRACH according to the Open loop power control procedure.
Integer: min = -35, max = -10TS 25.331
Maximum number of preambles in one preamble ramping cycle
Integer: min = 1, max = 64TS 25.331
Power step when no acquisition indicator is received in dB
Integer: min = 1, max = 8
'The power offset between the last transmitted preamble and the control part of the message for PRACH CTFC0.
Integer: min = -5, max = 10
Use the Huawei baseline value.
TS 25.433 Primary SCH PowerPower on the Primary Synchro Channel relative to the Pcpich power.SCH Power represents a power level relative to the FDD-CPICH power configured in a cell.With a low SCH Power transmitted by the cell, the mobile can’t obtain slot synchronisation as well as information on the group the cell belongs to. However, a high power can produce interferences preventing the mobile from reading CPICH channel, for example.
Float: min = -35, max = 15, step = 0.1
TS 25.321 Nbo1minIn case that a negative acknowledgement has been received on AICH, a backoff timer TBO1 is started. Backoff timer TBO1 is set to an integer number NBO1 of 10 ms time intervals, randomly drawn within an interval 0<NBO1min< NBO1< NBO1max (with uniform distribution).
Integer: min = 0, max = 50
TS 25.321 Nbo1maxIn case that a negative acknowledgement has been received on AICH, a backoff timer TBO1 is started. Backoff timer TBO1 is set to an integer number NBO1 of 10 ms time intervals, randomly drawn within an interval 0<NBO1min< NBO1< NBO1max (with uniform distribution).
Integer: min = 0, max = 50
TS 25.321 MmaxMaximum number of preamble cyclesTo exceed the maximum number of preamble ramping cycles Mmax involves the failure of RACH transmission.
Integer: min = 1, max = 32
TS 25.433 Secondary SCH powerPower on the Secondary Synchro Channel relative to the Pcpich power.SCH Power represents a power level relative to the FDD-CPICH power configured in a cell.With a low SCH Power transmitted by the cell, the mobile can’t obtain frame synchronisation as well as information on the group the cell belongs to. However, a high power can produce interferences preventing the mobile from reading CPICH channel, for example.
Float: min = -35, max = 15, step = 0.1 Use the Huawei
baseline value.ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
TS 25.331.Offset between a cell and one of its Fdd neighbouring cells, in case the quality measure for cell selection/reselection is set to RSCP.
Integer: min = -50, max = 50
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
TS 25.331Offset between a cell and one of its GSMneighbouring cells, in case the quality measure for cell selection/reselection is set to CPICH Ec/No.
Integer: min = -50, max = 50
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
Use the Huawei baseline value.
ALU does not have such a parameter.
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500
500
step : 1 7,5
320
3
0
0
-32
-32
500
500
step : 1 7,5
320
notBarred
allowed
barredS160
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Indicates the interval between two similar reporting for the amount reporting management of the Event1A. The value O means no periodical reporting.For Calls : the new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id);For Cell : the new value of the parameter has to be taken into account by Cell at next update of SysInfo (see [R30]).
Enum (ms){0, 250, 500, 1000, 2000, 4000, 8000, 16000}
Use the Huawei baseline value.
Because the ALU value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the ALU buffering mechanism. If the ALU value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Use the Huawei baseline value.
ALU does not have such a parameter.
Indicates the interval between two similar reporting for the amount reporting management of the Event1C.The value 0 means no periodical reporting. The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Enum (ms){0, 250, 500, 1000, 2000, 4000, 8000, 16000}
Use the Huawei baseline value.
Because the ALU value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the ALU buffering mechanism. If the ALU value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
This parameter defines the hysteresis to configure for the triggering of event 1C in Full Event mode
Use the Huawei baseline value.
Because the ALU value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the ALU buffering mechanism. If the ALU value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
This parameter defines the period during which the condition of the event 1C must be satisfied before sending a measurement report in full event mode
Enum (ms){0, 10, 20, 40, 60, 80, 100, 120, 160, 200, 240, 320, 640, 1280, 2560, 5000}
Use the Huawei baseline value.
Because the ALU value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the ALU buffering mechanism. If the ALU value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
maximum active set size
Integer[1..6]
Use the Huawei baseline value.
The ALU value is 3 as well.
TS 25.331.Offset between a cell and one of its Fdd neighbouring cells, in case the quality measure for cell selection/reselection is set to RSCP.
Integer: min = -50, max = 50
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
TS 25.331Offset between a cell and one of its GSMneighbouring cells, in case the quality measure for cell selection/reselection is set to CPICH Ec/No.
Integer: min = -50, max = 50
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
TS 25.331OPTIONALCellSelectionInfo :>SintraSearchIt defines the threshold for intra-frequency measuremnt and for the HCS measurement rules.Thus, if Sx> Sintrasearch, UE need not perform intra frequency measuerement, where Sx corresponds to Squal for
Integer: min = -32, max = 20, step = 2
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
TS 25.331OPTIONALCellSelectionInfo :>SinterSearchIt defines the threshold for inter-frequency measurement and for the HCS (Hierarchical Cell Structure) measurement rules.Thus, if Sx> Sintersearch, UE need not perform inter frequency measurement, where Sx corresponds to Squal for FDD cell and Srxlev for TDD and GSM cells.
Integer: min = -32, max = 20, step = 2
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Indicates the interval between two similar reporting for the amount reporting management of the Event1A. The value O means no periodical reporting.For Calls : the new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id);For Cell : the new value of the parameter has to be taken into account by Cell at next update of SysInfo (see [R30]).
Enum (ms){0, 250, 500, 1000, 2000, 4000, 8000, 16000}
Use the Huawei baseline value.
Because the ALU value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the ALU buffering mechanism. If the ALU value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Use the Huawei baseline value.
ALU does not have such a parameter.
Indicates the interval between two similar reporting for the amount reporting management of the Event1C.The value 0 means no periodical reporting. The new value of the parameter has to be taken into account in the life of a call, at the next RRC Measurement Control to configure or reconfigure the Event (e.g.change of Primary RL, end of SRLR, Common Id).
Enum (ms){0, 250, 500, 1000, 2000, 4000, 8000, 16000}
Use the Huawei baseline value.
Because the ALU value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the ALU buffering mechanism. If the ALU value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
This parameter defines the hysteresis to configure for the triggering of event 1C in Full Event mode
Use the Huawei baseline value.
Because the ALU value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the ALU buffering mechanism. If the ALU value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
Use the Huawei baseline value.
ALU does not have such a parameter.
This parameter defines the period during which the condition of the event 1C must be satisfied before sending a measurement report in full event mode
Enum (ms){0, 10, 20, 40, 60, 80, 100, 120, 160, 200, 240, 320, 640, 1280, 2560, 5000}
Use the Huawei baseline value.
Because the ALU value is smaller than the Huawei value, triggering event 1A or 1C is relatively difficult for Huawei. For event 1A or 1C, the Huawei buffering mechanism is different from the ALU buffering mechanism. If the ALU value is used, the number of times event 1A or 1C is reported will increase, leading to the increased call drop rate.
TS 25.331 Cell barredWhen cell status "barred" is indicated , the UE is not permit to select/reselect this cell, not even for emergency calls. For a status "not barred", the UE may select/reselect this cell during the cell selection and reselection procedures in idle mode and in connected mode.
Enum (RrcAccessClassBarred) : barred(0),notBarred(1)
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
TS 25.331If it is set to "not allowed", the UE shall not reselect a cell on the same frequency as the barred cell. For emergency call, this information shall be ignored and the UE may select another intra-frequency cell.
Enum (RrcAllowedIndicator) : allowed(0),notAllowed(1)
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
TS 25.331After expiry of this time interval, the UE shall check again whether the status of the barred cell has changed.
Enum (RrcTBarred) : barredS10(0),barredS20(1),barredS40(2),barredS80(3),barredS160(4),barredS320(5),barredS640(6),barredS1280(7)
Use the Huawei baseline value.
For connected-state-related parameters, Huawei baseline values are recommended but the multi-carrier policy must be considered as well when Huawei baseline values are used.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
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Huawei = ALU x 10
Huawei = ALU x 10
N.A.
N.A. Use the ALU value.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
maximum power NodeB can allocate to the call.
It represents a power level relative to the Pcpich power.
For the first foreseen algorithm, which allows RNC to reserve MaxDlTxPower-Delta for a call establishment, some considerations must be taken into account.
It must be adapted (fitted) as much as possible to service and to Eb/N0 requirement in order to avoid wasting power and to be received by the UE wherever it is located in the coverage area.
This power must be delivered by taking account of the power available for traffic admission for the required type of service (speech, data) by refering to the TrafficClassRatio.
List (3..3) Float: min = -35.0, max = 15.0, step = 0.1
TS 25.433 Minimum DL power
minimum power NodeB can allocate to the call.
It represents a power level relative to the Pcpich power.
It must take into account service, mobile speed, Eb/N0 requirement.
List (3..3) Float: min = -35.0, max = 15.0, step = 0.1
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
InterFreqCSThd2DEcN0 + 3
ALU does not have such a parameter.
InterFreqR99PsThd2DEcN0 + 3
ALU does not have such a parameter.
InterFreqR99PsThd2DEcN0 + 3
ALU does not have such a parameter.
InterFreqCSThd2DRSCP + 3
ALU does not have such a parameter.
InterFreqR99PsThd2DRSCP + 3
ALU does not have such a parameter.
InterFreqR99PsThd2DRSCP + 3
ALU does not have such a parameter.
25.433 T_Cell Timing delay used for defining start of SCH, CPICH and the DL scrambling code(s) in a cell relative BFN.
Integer: min = 0, max = 9
Huawei Alu CHIP0 0 CHIP256 1 CHIP512 2 CHIP768 3 CHIP1024 4 CHIP1280 5 CHIP1536 6 CHIP1792 7 CHIP2048 8 CHIP2304 9
TS 25.433Primary scrambling code used by the neighbouring cell
Integer: min = 0, max = 511
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N.A. Use the ALU value.
N.A. Use the ALU value.
N.A. Use the ALU value.
0~65535 N.A. Use the ALU value.
N.A. Use the ALU value.
TS23.003 subclause4.1
The LAI is composed of the following elements:MCC+MNC+LAC-Mobile Country Code (MCC) identifies the country in which the PLMN is located. The value of the MCC is the same as the three digit MCC contained in international mobile subscriber identity (IMSI);-Mobile Network Code (MNC) is a code identifying the PLMN in that country. The MNC takes the same value as the two or three digit MNC contained in IMSI;-Location Area Code (LAC) which is a fixed length code (of 2 octets) identifying a location area within a PLMN.
Integer: min = 0, max = 65535
TS23.003 (release 1999), V3.7.0, § 4.6, p. 15:
The Service Area Code (SAC) is a fixed length code (of 2 octets) identifying a service area within a location area and it can be coded using a full hexadecimal representation. A service area consists of one or more cells.TS 23.003 (release 1999), V3.7.0, §12.4, p.27:The Service Area Identifier (SAI) is used to uniquely identify an area consisting of one or more cells belonging to the same Location Area. The Service Area Code (SAC) together with the PLMN-Id and the LAC will constitute the Service Area Identifier.-SAI = PLMN-Id + LAC + SACFor Release 99 the broadcast (BC) domain requires that Service Area consist of one cell. This does not limit the usage of Service Area for other domains. Refer to TS 25.410 for a definition of the BC domain.
Integer: min = 0, max = 65535
TS23.003 (release 1999), subclause 4.2 p.13:Routing Area Code (RAC) is a fixed length code (of 1 octet) identifying a routing area within a location area.
Integer: min = 0, max = 255 Uniquely identifying
a cell. For detailed information of this parameter, refer to 3GPP TS 25.401.
UARFCN (UTRA Absolute Radio Frequency Channel Number of the the Down link frequency used by the cell: Nd = 5 * (Fdownlink MHz)For UMTS Band, valid values are in [10562 ,10838].For UMTS1900, valid values are 412, 437, 462, 487, 512, 537, 562, 587, 612, 637, 662, 687 U [9662;9938]
Integer: min = 0, max = 16383
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.
Use the Huawei baseline value.
ALU does not have such a parameter.