eRAN Feature Documentation Product Version: eRAN12.1 Library Version: 12 Date: 2019-02-20 For any question, please contact us. Copyright © Huawei Technologies Co., Ltd. 2019. All rights reserved. Scheduling Contents 6.2.1.12 Scheduling eRAN Scheduling Feature Parameter Description Issue 07 Date 2017-12-06 HUAWEI TECHNOLOGIES CO., LTD. Copyright © Huawei Technologies Co., Ltd. 2019. All rights reserved. No part of this document may be reproduced or transmitted in any form or by any means without prior written consent of Huawei Technologies Co., Ltd. Trademarks and Permissions and other Huawei trademarks are trademarks of Huawei Technologies Co., Ltd. All other trademarks and trade names mentioned in this document are the property of their respective holders. Notice The purchased products, services and features are stipulated by the contract made between Huawei and the customer. All or part of the products, services and features described in this document may not be within the purchase scope or the usage scope. Unless otherwise specified in the contract, all statements, information, and recommendations in this document are provided "AS IS" without warranties, guarantees or representations of any kind, either express or implied. The information in this document is subject to change without notice. Every effort has been made in the preparation of this document to ensure accuracy of the contents, but all statements, information, and recommendations in this document do not constitute a warranty of any kind, express or implied. Huawei Technologies Co., Ltd. Address: Huawei Industrial Base Bantian, Longgang Shenzhen 518129 People's Republic of China Website: http://www.huawei.com Email: support@huawei.com 6.2.1.12 Contents 1 About This Document 1.1 Scope 1.2 Intended Audience 1.3 Change History 1.4 Differences Between eNodeB Types 2 Overview 2.1 Introduction 2.2 Scheduler Principles 2.2.1 Inputs 2.2.2 Basic Functions 2.2.3 Outputs 2.3 Features Involved in Scheduling 2.4 Benefits 3 DL Scheduling 3.1 DL Scheduling Procedure 3.2 Control-Plane Information Scheduling 3.3 DL Scheduling for Retransmissions 3.3.1 Overview 3.3.2 HARQ Retransmissions 3.3.3 Maximum Number of HARQ Retransmissions 3.3.4 Resource Allocation for HARQ Retransmissions 3.4 DL Scheduling for Initial Transmissions 3.4.1 Selecting UEs for DL Scheduling 3.4.2 DL Scheduling Resource Acquisition 3.4.2.1 Overview 3.4.2.2 Frequency Diversity Scheduling 3.4.2.3 Frequency Selective Scheduling 3.4.2.4 Doppler Measurements 3.4.3 MCS Selection During DL Scheduling 3.4.4 Determining the Number and Positions of RBs for DL Scheduling 3.4.4.1 Number and Positions of RBs for DL Scheduling 3.4.4.2 PDSCH Efficiency Improvement 3.4.4.2.1 MCS Selection with Prioritized RBs 3.4.4.2.2 MCS Selection for Transmission of Small-Amount Data 3.4.4.2.3 Adaptive Power Allocation for Cell-Edge UEs 3.4.4.2.4 PDCCH and PDSCH Resource Balancing 3.4.4.3 RB Blocking at Micro eNodeBs 3.5 Scheduling Termination for Abnormal UEs 3.6 Manual Blocking of PDSCH RBs 4 DL Enhanced Scheduling 4.1 DL CQI Adjustment 4.1.1 Overview 4.1.2 Principles for DL CQI Adjustment 4.1.3 Target IBLER for DL CQI Adjustment 4.1.4 Step for CQI Adjustment 4.1.5 Period for DL CQI Adjustment 4.1.6 Initial Value of CQI Adjustment 4.2 DL Dynamic Scheduling 4.2.1 Overview 4.2.2 GBR Service Priority Calculation 4.2.3 Non-GBR Service Priority Calculation 4.2.4 Resource Proportions for GBR and Non-GBR Services 4.2.5 DL AMBR Control over Non-GBR Services 4.2.6 Delayed Scheduling of DL RLC Status Reports 4.3 DL Non-GBR Packet Bundling 4.4 DL RB Allocation 4.5 DL Traffic-Model-based Scheduling 5 UL Scheduling 5.1 UL Scheduling Procedure 5.2 UL Scheduling Triggering 5.3 UL Scheduling for Retransmissions 5.3.1 Overview 5.3.2 Retransmission Mode 5.3.3 Retransmission Upon Detection of PUSCH DTX 5.3.4 Maximum Number of UL HARQ Retransmissions 5.3.5 Resource Allocation for HARQ Retransmissions 5.4 UL Scheduling for Initial Transmissions 5.4.1 Selecting UEs for UL Scheduling 5.4.1.1 PDCCH and PUSCH Resource Balancing 5.4.1.2 UL Scheduling for UEs with Aperiodic CQI Reporting 5.4.1.3 Proactive Scheduling for Uplink Signaling 5.4.1.4 Scheduling Termination for Abnormal UEs 5.4.2 UL Scheduling Resource Acquisition 5.4.2.1 PUSCH Resources 5.4.2.2 Frequency Selective Scheduling 5.4.2.3 Determining the Number of RBs for UL Scheduling 5.4.2.3.1 Scheduler-controlled Power 5.4.2.3.2 Optimization of UL RLC Segment Reduction 5.4.3 Determining MCSs for UL Scheduling 5.4.3.1 Overview 5.4.3.2 SINR Adjustment 5.4.3.2.1 Target IBLER Adaptation 5.4.3.2.2 PAMC-based SINR Adjustment 5.4.3.2.3 SINR Adjustment Upon Detection of PUSCH DTX 5.4.3.2.4 SRI Detection 5.4.3.3 Initial MCS Selection 5.4.3.4 MCS Adjustment 5.5 UL Multi-Cluster 5.6 Manual Blocking of PUSCH RBs 6 UL Enhanced Scheduling 6.1 UL QoS Management 6.1.1 Service Rate Control on the eNodeB 6.1.2 UE Parameter Configurations for UL QoS 6.1.3 QoS Rate Guarantee for a Multi-Service UE 6.2 UL Preallocation 6.2.1 Preallocation Modes 6.2.2 Parameter Settings for Preallocation 6.2.2.1 Cell-level Preallocation Configurations 6.2.2.2 QCI-level Preallocation Configurations 6.3 Uplink Traffic Model Based Scheduling 7 Related Features 7.1 LBFD-001006 AMC 7.2 LBFD-002005 DL Asynchronous HARQ 7.3 LBFD-002006 UL Synchronous HARQ 7.4 LBFD-002025 Basic Scheduling 7.5 LBFD-060102 Enhanced UL Frequency Selective Scheduling 7.6 LBFD-060103 Enhanced DL Frequency Selective Scheduling 7.7 LBFD-070102 MBR>GBR Configuration 7.8 LBFD-070106 PDSCH Efficiency Improvement 7.9 LBFD-00101501 CQI Adjustment 7.10 LBFD-00101502 Dynamic Scheduling 7.11 LOFD-001109 DL Non-GBR Packet Bundling 7.12 LOFD-110205 Traffic Model Based Performance Optimization 7.13 LBFD-121102 eRAN12.1 Introduction Package 8 Network Impact 8.1 LBFD-001006 AMC 8.2 LBFD-002005 DL Asynchronous HARQ 8.3 LBFD-002006 UL Synchronous HARQ 8.4 LBFD-002025 Basic Scheduling 8.5 LBFD-060102 Enhanced UL Frequency Selective Scheduling 8.6 LBFD-060103 Enhanced DL Frequency Selective Scheduling 8.7 LBFD-070102 MBR>GBR Configuration 8.8 LBFD-070106 PDSCH Efficiency Improvement 8.9 LBFD-00101501 CQI Adjustment 8.10 LBFD-00101502 Dynamic Scheduling 8.11 LOFD-001109 DL Non-GBR Packet Bundling 8.12 LOFD-110205 Traffic Model Based Performance Optimization 8.13 LBFD-121102 eRAN12.1 Introduction Package 9 Engineering Guidelines for Basic DL Scheduling Features 9.1 When to Use 9.1.1 LBFD-002025 Basic Scheduling 9.1.2 LBFD-060103 Enhanced DL Frequency Selective Scheduling 9.1.3 LBFD-070102 MBR>GBR Configuration 9.1.4 LBFD-070106 PDSCH Efficiency Improvement 9.2 Required Information 9.3 Planning 9.4 Deploying Basic Scheduling 9.4.1 Requirements 9.4.2 Precautions 9.4.3 Data Preparation 9.4.3.1 Required Data 9.4.3.2 Scenario-specific Data 9.4.3.2.1 DL HARQ Retransmission 9.4.3.2.2 Static MCS Timer for Handovers 9.4.3.2.3 RB Blocking at Micro eNodeBs 9.4.4 Activation 9.4.5 Activation Observation 9.4.6 Reconfiguration 9.4.7 Deactivation 9.5 Deploying Enhanced DL Frequency Selective Scheduling 9.5.1 Requirements 9.5.2 Precautions 9.5.3 Data Preparation 9.5.4 Activation 9.5.5 Activation Observation 9.5.6 Reconfiguration 9.5.7 Deactivation 9.6 Deploying MBR>GBR Configuration 9.6.1 Requirements 9.6.2 Precautions 9.6.3 Data Preparation 9.6.4 Activation 9.6.5 Activation Observation 9.6.6 Reconfiguration 9.6.7 Deactivation 9.7 Deploying PDSCH Efficiency Improvement 9.7.1 Requirements 9.7.2 Precautions 9.7.3 Data Preparation 9.7.4 Activation 9.7.5 Activation Observation 9.7.6 Reconfiguration 9.7.7 Deactivation 9.8 Performance Monitoring 9.9 Parameter Optimization 9.10 Possible Issues 10 Engineering Guidelines for Enhanced DL Scheduling Features 10.1 When to Use 10.1.1 LBFD-00101501 CQI Adjustment 10.1.2 LBFD-00101502 Dynamic Scheduling 10.1.3 LOFD-001109 DL Non-GBR Packet Bundling 10.1.4 LOFD-110205 Traffic Model Based Performance Optimization 10.2 Required Information 10.3 Planning 10.4 Deploying CQI Adjustment 10.4.1 Requirements 10.4.2 Precautions 10.4.3 Data Preparation 10.4.3.1 Required Data 10.4.3.2 Scenario-specific Data 10.4.3.2.1 DL Target IBLER Adaptation 10.4.3.2.2 Optimized CQI Adjustment Value 10.4.3.2.3 Step for CQI Adjustment 10.4.3.2.4 Initial Value of CQI Adjustment 10.4.4 Activation 10.4.5 Activation Observation 10.4.6 Reconfiguration 10.4.7 Deactivation 10.5 Deploying Dynamic Scheduling 10.5.1 Requirements 10.5.2 Precautions 10.5.3 Data Preparation 10.5.3.1 Required Data 10.5.3.2 Scenario-specific Data 10.5.3.2.1 QCI Configurations for DL Non-GBR Services 10.5.3.2.2 Doppler Measurement Level Selection 10.5.3.2.3 RBG Allocation Policy 10.5.3.2.4 EPF Scheduling Enhancement 10.5.3.2.5 Scheduling Termination for Abnormal UEs 10.5.3.2.6 Stopping Aperiodic CQI Reporting When No Scheduling Is Performed 10.5.3.2.7 DL AMBR Control over Non-GBR Services 10.5.3.2.8 Delayed Scheduling of DL RLC Status Reports 10.5.4 Activation 10.5.5 Activation Observation 10.5.6 Reconfiguration 10.5.7 Deactivation 10.6 Deploying DL Non-GBR Packet Bundling 10.6.1 Requirements 10.6.2 Precautions 10.6.3 Data Preparation 10.6.4 Activation 10.6.5 Activation Observation 10.6.6 Reconfiguration 10.6.7 Deactivation 10.7 Deploying the Traffic Model Based Performance Optimization Feature 10.7.1 Requirements 10.7.2 Precautions 10.7.3 Data Preparation 10.7.4 Activation 10.7.5 Activation Observation 10.7.6 Reconfiguration 10.7.7 Deactivation 10.8 Performance Monitoring 10.9 Parameter Optimization 10.10 Possible Issues 11 Engineering Guidelines for Basic UL Scheduling Features 11.1 When to Use 11.1.1 LBFD-002025 Basic Scheduling 11.1.2 LBFD-060102 Enhanced UL Frequency Selective Scheduling 11.1.3 LBFD-070102 MBR>GBR Configuration 11.2 Required Information 11.3 Planning 11.4 Deploying Basic Scheduling 11.4.1 Requirements 11.4.2 Precautions 11.4.3 Data Preparation 11.4.4 Activation 11.4.5 Activation Observation 11.4.6 Reconfiguration 11.4.7 Deactivation 11.5 Deploying Enhanced UL Frequency Selective Scheduling 11.5.1 Requirements 11.5.2 Precautions 11.5.3 Data Preparation 11.5.3.1 Required Data 11.5.3.2 Scenario-specific Data 11.5.3.2.1 UL Frequency Selective Scheduling Based on the Estimated UE Speed 11.5.3.2.2 Interference-based Frequency Selective Scheduling 11.5.4 Activation 11.5.5 Activation Observation 11.5.6 Reconfiguration 11.5.7 Deactivation 11.6 Deploying MBR>GBR Configuration 11.6.1 Requirements 11.6.2 Precautions 11.6.3 Data Preparation 11.6.4 Activation 11.6.5 Activation Observation 11.6.6 Reconfiguration 11.6.7 Deactivation 11.7 Performance Monitoring 11.8 Parameter Optimization 11.9 Possible Issues 12 Engineering Guidelines for Enhanced UL Scheduling Features 12.1 When to Use 12.1.1 LBFD-00101502 Dynamic Scheduling 12.1.2 LOFD-110205 Traffic Model Based Performance Optimization 12.2 Required Information 12.3 Deploying Dynamic Scheduling 12.3.1 Requirements 12.3.2 Precautions 12.3.3 Data Preparation 12.3.3.1 Required Data 12.3.3.2 Scenario-specific Data 12.3.3.2.1 QCI Configurations for UL Non-GBR Services 12.3.3.2.2 UL Min-GBR Guarantee 12.3.3.2.3 Logical Channel Group 12.3.3.2.4 SINR Adjustment 12.3.3.2.5 UL Preallocation 12.3.3.2.6 Setting the SRI False Alarm Detection Threshold 12.3.3.2.7 Scheduling Termination for Abnormal UEs 12.3.3.2.8 Scheduler-controlled Power 12.3.3.2.9 PDCCH and PUSCH Resource Balancing 12.3.3.2.10 UL RLC Segment Reduction 12.3.3.2.11 PUCCH RB Occupation by PUSCH 12.3.3.2.12 Proactive Scheduling for Uplink Signaling 12.3.3.2.13 Data Amount Adaptation in UL SR-based Scheduling 12.3.4 Activation 12.3.5 Activation Observation 12.3.6 Reconfiguration 12.3.7 Deactivation 12.4 Deploying the Traffic Model Based Performance Optimization Feature 12.4.1 Requirements 12.4.2 Precautions 12.4.3 Data Preparation 12.4.4 Activation 12.4.5 Activation Observation 12.4.6 Reconfiguration 12.4.7 Deactivation 12.5 Performance Monitoring 12.6 Parameter Optimization 12.7 Possible Issues 13 Parameters 14 Counters 15 Glossary 16 Reference Documents 1 About This Document 1.1 Scope This document describes scheduling, including its technical principles, related features, network impact, and engineering guidelines. This document covers the following features: • LBFD-001006 AMC • LBFD-002005 DL Asynchronous HARQ • LBFD-002006 UL Synchronous HARQ • LBFD-002025 Basic Scheduling • LBFD-060102 Enhanced UL Frequency Selective Scheduling • LBFD-060103 Enhanced DL Frequency Selective Scheduling • LBFD-070102 MBR>GBR Configuration • LBFD-070106 PDSCH Efficiency Improvement • LBFD-00101501 CQI Adjustment • LBFD-00101502 Dynamic Scheduling • LOFD-001109 DL Non-GBR Packet Bundling • LOFD-110205 Traffic Model Based Performance Optimization • LBFD-121102 eRAN12.1 Introduction Package Feature compatibility with specific terminal models is not presented in this document. For compatibility information, contact Huawei engineers. Any parameters, alarms, counters, or managed objects (MOs) described herein apply only to the corresponding software release. For future software releases, refer to the corresponding updated product documentation. This document applies only to LTE FDD. Any "LTE" in this document refers to LTE FDD, and "eNodeB" refers to LTE FDD eNodeB. 1.2 Intended Audience This document is intended for personnel who: • Need to understand the features described herein • Work with Huawei products 1.3 Change History This section provides information about the changes in different document versions. There are two types of changes: • Feature change Changes in features and parameters of a specified version as well as the affected entities • Editorial change Changes in wording or addition of information and any related parameters affected by editorial changes. Editorial change does not specify the affected entities. eRAN12.1 07 (2017-12-06) This issue includes the following changes. Change Type Change Description Parameter Change Affected Entity Feature change None None N/A Editorial change Revised descriptions in this document to improve None readability. N/A eRAN12.1 06 (2017-10-23) This issue includes the following changes. Change Type Change Description Parameter Change Affected Entity Feature change None None N/A Editorial change Revised descriptions in this document to improve None readability. N/A Change Type Change Description Parameter Change Affected Entity eRAN12.1 05 (2017-08-30) This issue includes the following changes. Change Type Change Description Parameter Change Affected Entity Feature change None None N/A Editorial change Revised descriptions in this document to improve None readability. N/A eRAN12.1 04 (2017-06-29) This issue includes the following changes. Change Type Change Description Parameter Change Affected Entity Feature change None None N/A Editorial change Revised descriptions in this document to improve None readability. N/A eRAN12.1 03 (2017-05-31) This issue includes the following changes. Change Type Change Description Parameter Change Affected Entity Feature change None None N/A Editorial change Revised descriptions in this document to improve None readability. N/A eRAN12.1 02 (2017-04-26) This issue includes the following changes. Change Type Change Description Parameter Change Affected Entity Feature change None None N/A Editorial change Revised descriptions in this document to improve None readability. N/A eRAN12.1 01 (2017-03-08) This issue includes the following changes. Change Type Change Description Parameter Change Affected Entity Feature change Added the UL Multi-Cluster function. For details, see 5.5 UL Multi-Cluster. Added the UlMultiClusterSwitch option to the CellAlgoSwitch.UlSchExtSwitch parameter. Macro, micro, and LampSite eNodeBs Editorial change Revised descriptions in this document to improve None readability. N/A eRAN12.1 Draft A (2016-12-30) Draft A (2016-12-30) of eRAN12.1 introduces the following changes to Issue 02 (2016-04-20) of eRAN11.1. Change Type Change Description Feature change Added efficiency improvement for adaptive DL HARQ. For details, see 3.3.4 Resource Allocation for HARQ Retransmissions. Added the PAMC function. For details, see: Parameter Change Affected Entity • Added the PreciseMcsAdaptSwitch option to Macro, micro, and LampSite eNodeBs the CellAlgoSwitch.CqiAdjAlgoSwitch parameter. • Added the CellDlschAlgo.DlFirstHarqTxTbsIncNum parameter. Added the UlPAMCSwitch option to the CellAlgoSwitch.UlSchExtSwitch parameter. Macro, micro, and LampSite eNodeBs Added flexible target IBLER adaptation. For details, see 4.1.3 Target IBLER for DL CQI Adjustment. Added the following parameters: Macro, micro, and LampSite eNodeBs Changed CQI Adjustment and Dynamic Scheduling from optional features into basic features. For details, see 1.1 Scope. None Macro, micro, and LampSite eNodeBs Added the PreciseMcsAdaptSwitch option to the CellAlgoSwitch.CqiAdjAlgoSwitch parameter. Macro, micro, and LampSite eNodeBs • 5.4.3.2.2 PAMC-based SINR Adjustment • 5.4.3.3 Initial MCS Selection • CellDlschAlgo.LowIblerTargetTbsIdxThld • CellDlschAlgo.HighIblerTargetTbsIdxThld Change Type Change Description Parameter Change Affected Entity Added SRI detection optimization. For details, see 5.4.3.2.4 SRI Detection. Added the SriDetectEnhanceSW option to the CellPucchAlgo.SriAlgoSwitch parameter. Macro, micro, and LampSite eNodeBs Added the feature LBFD-121102 eRAN12.1 Introduction Package. None Macro, micro, and LampSite eNodeBs Added adaptive power allocation for cell-edge UEs. For details, see 3.4.4.2.3 Adaptive Power Allocation for Cell-Edge UEs. Added the AdptCellEdgePwrAllocSw option to the CellAlgoSwitch.CellDlCoverEnhanceSwitch parameter. Macro, micro, and LampSite eNodeBs Added data volume adaptation in SR-based scheduling. For details, see 5.2 UL Scheduling Triggering. Added the CellUlschAlgo.UlSrSchDataVolAdptOptUpThd parameter. Macro, micro, and LampSite eNodeBs Added search direction randomization for the sliding window in UL frequency selective scheduling. For details, see 5.4.2.2 Frequency Selective Scheduling. Added the UlFssWindSearchDirRandSw option to the Macro, micro, and CellAlgoSwitch.UlSchExtSwitch parameter. LampSite eNodeBs Added optimized calculation of the number of RBs for cell-edge UEs. For details, see 5.4.2.3.1 Scheduler-controlled Power. Added the eNodeBAlgoSwitch.UlResManageOptSw Macro, micro, and parameter and its option UL_RBCALC_OPT_SWITCH LampSite eNodeBs (UlRbCalcOptSwitch). Enhanced preallocation for sparse-packet services. For details, see: Added the EnhancedSchForSparseSwitch option to the CellAlgoSwitch.UlSchExtSwitch parameter. Macro, micro, and LampSite eNodeBs Added delayed scheduling of DL RLC status reports. For details, see 4.2.6 Delayed Scheduling of DL RLC Status Reports. Added the DlRLCStateReportSchDelaySw option to the CellAlgoSwitch.DlSchSwitch parameter. Macro, micro, and LampSite eNodeBs Added CQI reliability optimization. For details, see 3.4.3 MCS Selection During DL Scheduling. Added the following options to the CellCqiAdjAlgo.CqiOptSwitch parameter: Macro, micro, and LampSite eNodeBs Added adaptive compensation for the initial value of CQI adjustment. For details, see 4.1.6 Initial Value of CQI Adjustment. • 6.2.1 Preallocation Modes • 6.2.2.1 Cell-level Preallocation Configurations • PUSCH_CQI_FALSE_DETECTION_SW • PUCCH_CQI_FALSE_DETECTION_SW Editorial change Added MCS selection for the transmission of small-amount data. For details, see 3.4.4.2.2 MCS Selection for Transmission of Small-Amount Data. Added the SmallPktMcsSelectAlgoSw option to the CellAlgoSwitch.DlSchSwitch parameter. Macro, micro, and LampSite eNodeBs Added setting of the validity duration of subband CQIs reported by UEs in frequency selective scheduling and optimization of the period of triggering aperiodic CQI reporting from UEs in frequency selective scheduling. For details, see 3.4.2.3 Frequency Selective Scheduling. Added the following parameters: Macro, micro, and LampSite eNodeBs • CellDlschAlgo.FSUEAperCQITrigPeriod • CellDlschAlgo.FSUESbCQIValidityPeriod Moved UL interference randomization from None LBFD-060102 Enhanced UL Frequency Selective Scheduling, which is described in this document, to LBFD-00202202 Uplink Static Inter-Cell Interference Coordination, which is described in ICIC. Macro, micro, and LampSite eNodeBs Moved DL interference randomization from LBFD-00101502 Dynamic Scheduling, which is described in this document, to LBFD-00202201 Downlink Static Inter-Cell Interference Coordination, which is described in ICIC. None Macro, micro, and LampSite eNodeBs Moved the descriptions of the following features from this document to Modulation Schemes Feature Parameter Description: None N/A • LBFD-001005 Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM • LOFD-001006 UL 64QAM 1.4 Differences Between eNodeB Types Feature Support by Macro, Micro, and LampSite eNodeBs Feature ID Feature Name Supported by Macro eNodeBs Supported by Micro eNodeBs Supported by LampSite eNodeBs LBFD-001006 AMC Yes Yes Yes LBFD-002005 DL Asynchronous HARQ Yes Yes Yes LBFD-002006 UL Synchronous HARQ Yes Yes Yes Feature ID Feature Name Supported by Macro eNodeBs Supported by Micro eNodeBs Supported by LampSite eNodeBs LBFD-002025 Basic Scheduling Yes Yes Yes LBFD-060102 Enhanced UL Frequency Selective Scheduling Yes Yes No LBFD-060103 Enhanced DL Frequency Selective Scheduling Yes Yes Yes LBFD-070102 MBR>GBR Configuration Yes Yes Yes LBFD-070106 PDSCH Efficiency Improvement Yes Yes Yes LBFD-00101501 CQI Adjustment Yes Yes Yes LBFD-00101502 Dynamic Scheduling Yes Yes Yes LOFD-001109 DL Non-GBR Packet Bundling Yes Yes Yes LOFD-110205 Traffic Model Based Performance Optimization Yes Yes Yes LBFD-121102 eRAN12.1 Introduction Package Yes Yes Yes Function Implementation in Macro, Micro, and LampSite eNodeBs Function Difference Inputs to the DL scheduler Micro eNodeBs do not support inter-cell interference coordination (ICIC). Inputs to the UL scheduler Micro eNodeBs do not support ICIC. UL scheduling procedure Micro and LampSite eNodeBs do not support uplink coordinated multipoint reception (UL CoMP). Doppler measurement Micro eNodeBs do not support Doppler measurement. Target IBLER adaptation Micro eNodeBs do not support target IBLER adaptation. RB blocking RB blocking is specific to micro eNodeBs and is not supported by macro eNodeBs. 2 Overview 2.1 Introduction The LTE system adopts shared-channel transmissions in which time-frequency resources are dynamically shared by UEs. eNodeBs perform scheduling to allocate timefrequency resources for uplink (UL) and downlink (DL) transmissions. Schedulers Schedulers are located at the Media Access Control (MAC) layer. The basic function of a scheduler is to allocate appropriate system resources to UEs in each subframe for UL and DL transmissions, without which the UEs would be unable to transmit and receive data. Huawei schedulers are designed to achieve a balance between single-UE performance and overall network capacity and provide end-to-end quality of service (QoS) management solutions for better QoS experience. RB A resource block (RB) is 180 kHz wide, comprising 12 subcarriers, and lasts for one 0.5 ms timeslot. The minimum scheduling unit consists of two RBs, comprising 12 subcarriers and 1 subframe (lasting for 1 ms). Figure 2-1 shows a minimum scheduling unit. Figure 2-1 Minimum scheduling unit Multiple RBs can be allocated to one UE in each transmission time interval (TTI). The maximum number of available RBs in the frequency domain in a cell depends on the cell bandwidth, as listed in Table 2-1. Table 2-1 Available RBs per bandwidth Bandwidth (MHz) Number of Available RBs 1.4 6 3 15 5 25 10 50 15 75 20 100 MCS Modulation and coding schemes (MCSs) are selected during scheduling. Each MCS represents a particular combination of a modulation scheme and a channel code rate. The modulation schemes include quadrature phase shift keying (QPSK), 16 quadrature amplitude modulation (16QAM), and 64QAM. Among them: • QPSK modulates two information bits into each modulation symbol. • 16QAM modulates four information bits into each modulation symbol. • 64QAM modulates six information bits into each modulation symbol. Channel code rates, which are typically less than 1, indicate the proportion of information bits among physical channel bits after redundancy has been applied. Modulation orders represent the number of information bits modulated into each modulation symbol. A high-order modulation scheme and a high code rate can be used when channel conditions are favorable. The higher the modulation order and code rate, the higher the transmission efficiency. However, a higher-order modulation scheme requires a higher signal-tonoise ratio (SNR) than a lower-order modulation scheme to achieve the same block error rate (BLER). 2.2 Scheduler Principles In an LTE system, schedulers are located at the MAC layer. Schedulers allocate resources on the physical shared channel (PSCH) for UEs and select appropriate MCSs for the transmission of system information and user data. Figure 2-2 shows the DL scheduler and Figure 2-3 shows the UL scheduler. Figure 2-2 DL scheduler Figure 2-3 UL scheduler 2.2.1 Inputs UE-related Inputs • UE capability The UE capability is indicated by one of eight UE categories specified in section 4.1 in 3GPP TS 36.306 V10.1.0 (2011-03). The maximum numbers of bits and layers that can be transmitted in each TTI depend on the UE category. • UE measurement gaps A UE measurement gap refers to the time during which the UE can perform inter-frequency or inter-RAT measurements at another frequency. For details, see Overview of Mobility Management in Connected Mode Feature Parameter Description. • Sync status This input indicates whether the UE is in the in-sync or out-of-sync state. For details, see Connection Management Feature Parameter Description. Data-related Inputs • Data buffer status (DL) This input indicates the amount of to-be-scheduled data in the Radio Link Control (RLC) buffer. • Scheduling request (UL) A scheduling request (SR) is 1-bit information that a UE sends to the eNodeB to request UL resources for data transmission. • Buffer status report (UL) A UE sends a buffer status report (BSR) to the eNodeB to indicate the amount of data in the UL buffer of the UE. • HARQ feedback HARQ feedback can be acknowledgment (ACK), negative acknowledgment (NACK), or discontinuous transmission (DTX). These indicate whether data has been correctly transmitted or retransmitted. While signaling scheduling and semi-persistent scheduling have the highest priority, Huawei eNodeBs allocate the second highest priority to scheduling of HARQ retransmissions. QoS Parameters Bearer QoS requirements are transmitted from the evolved packet core (EPC) to the eNodeB through the S1 Application Part (S1AP). The main QoS parameters of EPS bearers are as follows: • QoS class identifier (QCI) • Guaranteed bit rate (GBR) • Maximum bit rate (MBR) of GBR services • Aggregate maximum bit rate (AMBR) of non-GBR services The standard QoS attributes are as follows: • Resource type (GBR or non-GBR) • Priority • Packet delay budget (PDB) • Packet error loss rate For details, see section 6.1.7 in 3GPP TS 23.203 V10.3.0 (2011-03). Huawei eNodeBs support extended QCIs. For details, see QoS Management Feature Parameter Description. Channel State Inputs • DL schedulers schedule UEs based on the channel state information (CSI). UEs estimate the channel state based on the instantaneous DL channel quality. The CSI includes: ◾ Rank indication (RI) In spatial multiplexing transmission mode, UEs report RI to the eNodeB, providing information about the channel rank that the DL scheduler uses for DL transmissions. ◾ Precoding matrix indication (PMI) In closed-loop spatial multiplexing transmission mode, UEs report PMI to the eNodeB, recommending a precoding matrix to the DL scheduler. ◾ Channel quality indicator (CQI) UEs report CQIs to the eNodeB, providing information about DL channel quality that the DL scheduler can use for link adaptation. Huawei eNodeBs support both periodic and aperiodic CSI reporting and determine which reporting mode is to be used. For details, see Channel State Management Feature Parameter Description. • UL schedulers schedule UEs based on UL signal to interference plus noise ratios (SINRs), which indicate UL channel conditions. The eNodeB obtains SINRs by measuring sounding reference signals (SRSs) and demodulation reference signals (DMRSs). DL Power The DL transmit (TX) power is shared by all UEs in a cell. According to 3GPP Release 8, DL TX power is determined by the cell-specific reference signal (RS) energy per resource element (EPRE), PA, and PB. The eNodeB sends UEs the information element (IE) PDSCH-ConfigCommon that contains cell-specific RS EPRE and PB, and the IE PDSCH-ConfigDedicated that contains PA. Power Headroom Report A power headroom report (PHR) indicates the power status of a UE. Power headroom is the difference between the maximum allowed TX power and the used TX power in the UL. UEs send PHRs to the eNodeB periodically or in event-triggered mode. The power headroom of a UE ranges from –23 dB to +40 dB in a PHR. Based on the PHR, the UL scheduler calculates the number of RBs required to maintain the maximum power spectrum density, which is specified by the UL power control module. For details, see Power Control Feature Parameter Description. MIMO Transmission Mode The multiple-input multiple-output (MIMO) transmission mode is an input to the DL scheduler. Chapter 7 in 3GPP TS 36.213 defines nine MIMO transmission modes. For details about how to select a MIMO transmission mode, see MIMO Feature Parameter Description. MU-MIMO Scheme The multi-user MIMO (MU-MIMO) scheme is an input to the UL scheduler. It indicates the MIMO scheme to be used in UL scheduling. For details, see MIMO Feature Parameter Description. ICIC-related Inputs Inter-cell interference coordination (ICIC) divides the channel bandwidth of each cell involved into a center band and an edge band. This input determines whether to schedule UEs in the center band or edge band. For details about band selection, see Adaptive ICIC Feature Parameter Description. 2.2.2 Basic Functions Schedulers perform the following basic functions: • Priority calculation Based on the inputs, priority calculation determines the scheduling priorities of bearers and UEs to be scheduled. This satisfies the QoS requirements of UEs and maximizes system throughput. • MCS selection Based on the inputs, MCS selection determines an MCS for each UE to be scheduled. • Resource allocation Based on the data volume and the selected MCS, resource allocation determines the number of RBs to be allocated to each UE as well as the position of each RB. 2.2.3 Outputs Schedulers determine the following: • UEs to be scheduled • MCS • Number of RBs to be allocated, position of each RB, and transport block sizes (TBSs) • MIMO mode 2.3 Features Involved in Scheduling Function Feature ID Feature Name Description User selection LBFD-002025 Basic Scheduling Includes three scheduling policies: • Maximum carrier-to-interference ratio (max C/I) • Round robin (RR) • Proportional fair (PF) LBFD-00101502 Dynamic Scheduling Includes the scheduling policy enhanced proportional fair (EPF), which offers the following benefits: • Helps meet QoS requirements of services with various QCIs. • Provides differentiated services for UEs. • Helps achieve an optimal balance between fairness among UEs and cell throughput while meeting QoS requirements. MCS selection Scheduling resource allocation Others LBFD-070102 MBR>GBR Configuration Allows the MBR to be greater than the GBR for GBR bearers, reducing service interruptions and improving resource utilization and user experience. LOFD-001109 DL Non-GBR Packet Bundling Enables the eNodeB to collect multiple DL data packets before sending them, thereby reducing PDCCH overhead and meeting service delay requirements. LOFD-110205 Traffic Model Based Performance Optimization Preferentially schedules the users performing small-packet services and having good signal quality in user data transmission, reducing the user wait time. This feature increases user-perceived data rates and improves user experience while basically maintaining cell capacity. LBFD-001006 AMC Adaptively selects an optimal MCS based on channel quality to increase overall spectral efficiency. LBFD-00101501 CQI Adjustment Provides accurate CQIs to be used for DL scheduling, increasing DL throughput. LBFD-070106 PDSCH Efficiency Improvement Improves physical downlink shared channel (PDSCH) resource utilization if idle RBs are available, increasing DL throughput. LBFD-060103 Enhanced DL Frequency Selective Scheduling Improves system performance based on channel quality differences between subbands. LBFD-060102 Enhanced UL Frequency Selective Scheduling Reduces the impact of UL interference on UE performance and increases cell throughput and enhances cell edge coverage based on fast fading and interference distribution on sub-bands. LBFD-002005 DL Asynchronous HARQ Provides a fast-retransmission mechanism implemented at the MAC and physical layers, increasing DL user throughput and reducing DL transmission delay. LBFD-002006 UL Synchronous HARQ Provides a fast-retransmission mechanism implemented at the MAC and physical layers, increasing UL user throughput and reducing UL transmission delay. 2.4 Benefits Scheduling offers the following benefits: • Ensures satisfactory system throughput and fairness in resource scheduling. • Ensures that the QoS requirements of GBR and non-GBR services are fulfilled when both GBR and non-GBR services need to be scheduled in a TTI. • Enhanced scheduling improves system capacity and network performance. 3 DL Scheduling 3.1 DL Scheduling Procedure Actions in the DL scheduling procedure are performed sequentially based on their priorities. Figure 3-1 shows the actions and their priorities in the DL scheduling procedure in a TTI. Figure 3-1 Actions and their priorities in the DL scheduling procedure In the preceding procedure, the eNodeB takes the following actions: 1. Schedules common control information. For details, see 3.2 Control-Plane Information Scheduling. 2. Performs semi-persistent scheduling. For details, see VoLTE Feature Parameter Description. 3. Schedules dedicated control information. For details, see 3.2 Control-Plane Information Scheduling. 4. Schedules HARQ retransmission data. For details, see 3.3 DL Scheduling for Retransmissions. 5. Schedules initial transmissions. For details, see 3.4 DL Scheduling for Initial Transmissions. 3.2 Control-Plane Information Scheduling During scheduling in each subframe, control-plane messages are scheduled before user-plane data. Control-plane information consists of common control information and dedicated control information. Common Control Information Common control information includes broadcast messages (such as SIB1 and other system information), paging messages, and random access (RA) responses. (SIB is short for system information block.) Scheduling common control information uses QPSK and low coding rates for reliable transmission. 3GPP specifications define three downlink allocation modes: • Resource allocation type 0 • Resource allocation type 1 • Resource allocation type 2 Resource allocation type 2 is used for allocating resources to common control information. In this allocation mode, the allocated resources are classified into distributed virtual resource blocks (DVRBs) and localized virtual resource blocks (LVRBs). • DVRBs are non-contiguous resource blocks. They increase the coverage of common control information in the cell. However, the amount of system resources occupied by common control information increases, which decreases UE throughput. • LVRBs are contiguous resource blocks. They decrease the amount of system resources occupied by common control information, which increases UE throughput. However, the coverage of common control information in the cell decreases. LVRB allocation mode is currently used. Dedicated Control Information Dedicated control information includes the information carried on signaling radio bearer 0 (SRB0), SRB1, and SRB2. 3.3 DL Scheduling for Retransmissions 3.3.1 Overview This section describes the basic feature LBFD-002005 DL Asynchronous HARQ. Huawei schedulers use adaptive asynchronous HARQ, in which a UE sends HARQ feedback four TTIs after the initial transmission from the eNodeB and, if the feedback is an NACK, the eNodeB retransmits the data at least four TTIs after receiving the NACK. 3.3.2 HARQ Retransmissions Figure 3-2 shows the HARQ retransmission procedure in a TTI. Figure 3-2 Procedure for HARQ retransmissions HARQ retransmissions cannot be performed for a UE in any of the following scenarios: • The UE is in a measurement gap or enters a measurement gap when it sends HARQ feedback. • The UE enters sleep time in DRX and the HARQ operating status is discontinuous transmission (DTX). • The UE is not synchronized with the eNodeB or a radio link failure (RLF) occurs. HARQ retransmissions are scheduled after control-plane messages. The scheduling priorities of different HARQ retransmissions are determined by the wait time. A longer wait time indicates a higher scheduling priority. If all retransmissions have the same wait time, a retransmission is randomly selected. If DRX is enabled, the wait time is determined by the DrxParaGroup.DrxReTxTimer parameter. If the wait time of a HARQ retransmission exceeds the specified wait time, the HARQ retransmission is discarded, ensuring effective retransmissions. For details about DRX, see DRX and Signaling Control Feature Parameter Description. 3.3.3 Maximum Number of HARQ Retransmissions The maximum number of DL HARQ retransmissions is specified by the CellDlschAlgo.DlHarqMaxTxNum parameter. • If this parameter is set to a small value, HARQ retransmissions consume few radio resources but radio link reliability decreases. • If this parameter is set to a large value, radio link reliability increases but HARQ retransmissions consume a lot of radio resources. DL HARQ retransmissions are stopped when the number of DL HARQ retransmissions reaches the value of the CellDlschAlgo.DlHarqMaxTxNum parameter. 3.3.4 Resource Allocation for HARQ Retransmissions The eNodeB adaptively selects MCSs for HARQ retransmissions. Due to the use of soft combining with HARQ, HARQ retransmissions can use MCSs with higher indexes than initial transmissions based on CQI adjustment. The TBS used for HARQ retransmissions is the same as the TBS used for initial transmissions. When ICIC is enabled, resources at center bands are preferentially allocated to cell center users and resources at edge bands are preferentially allocated to cell edge users. If the resources at center or edge bands are insufficient, resources of the entire band can be used for allocation. To efficiently utilize soft combining, efficiency improvement for adaptive DL HARQ can be activated to increase the TBS index for the first DL HARQ retransmission. This function is controlled by the PreciseMcsAdaptSwitch(PreciseMcsAdaptSwitch) option of the CellAlgoSwitch.CqiAdjAlgoSwitch parameter. The amount of the increase is determined by the CellDlschAlgo.DlFirstHarqTxTbsIncNum parameter. If consecutive demodulation failures occur in the HARQ retransmission process, HARQ retransmissions can use a lowered TBS index. The TBS used for HARQ retransmissions is the same as the TBS used for the initial transmission. Therefore, more RBs are allocated for HARQ retransmissions, which can reduce DL throughput. The DlRetxTbsIndexAdjOptSwitch option of the CellAlgoSwitch.CqiAdjAlgoSwitch parameter specifies whether HARQ retransmissions use a lowered TBS index. • When the DlRetxTbsIndexAdjOptSwitch option is selected, HARQ retransmissions at the (DLHARQMAXTXNUM–1)th and DLHARQMAXTXNUMth times use a lowered TBS index. This increases the benefits of soft combining in HARQ retransmissions, reducing the DL residual block error rate (RBLER) and service drop rate. NOTE: DLHARQMAXTXNUM indicates the maximum number of consecutive HARQ retransmissions and is specified by the CellDlschAlgo.DlHarqMaxTxNum parameter. • When the DlRetxTbsIndexAdjOptSwitch option is deselected, HARQ retransmissions do not use a lowered TBS index. 3.4 DL Scheduling for Initial Transmissions DL scheduling for initial transmissions performs the following operations: • Acquires DL scheduling resources. • Selects UEs to be scheduled. • Determines MCSs to be used. • Determines the number and positions of RBs to be allocated. 3.4.1 Selecting UEs for DL Scheduling This section describes LBFD-002025 Basic Scheduling and LBFD-00101502 Dynamic Scheduling. Huawei eNodeBs support four scheduling policies: • Maximum carrier-to-interference ratio (Max C/I) • Round robin (RR) • Proportional fair (PF) • Enhanced proportional fair (EPF) Max C/I, RR, and PF are provided by LBFD-002025 Basic Scheduling. EPF is provided by LBFD-00101502 Dynamic Scheduling. Figure 3-3 shows the relationships between the four policies. Figure 3-3 Relationships between the scheduling policies The differences between the scheduling policies lie in the consideration factors, which are described as follows: • Max C/I The Max C/I algorithm only takes channel quality into account when allocating air interface resources and schedules services with the best channel quality at that moment. This algorithm maximizes system throughput. However, it cannot ensure that UEs in the same cell are equally scheduled because all UEs in a cell cannot experience the same channel conditions. A UE cannot be scheduled if it is constantly experiencing poor channel conditions. As a result, user experience is poor. This scheduling algorithm does not ensure that QoS of services can be maintained. • RR The RR algorithm allows UEs to take turns using shared resources. Compared with Max C/I, RR ensures scheduling fairness between UEs in a cell. However, it cannot maximize the system throughput. This scheduling algorithm does not ensure that QoS of services can be maintained. • PF The PF algorithm is a compromise between Max C/I and RR. This algorithm takes the scheduling fairness, channel quality, and number of transmitted bits into account. However, this algorithm does not take QoS requirements into account and therefore cannot ensure satisfactory user experience. • EPF The EPF algorithm is an enhanced version of the PF algorithm. Compared with PF, EPF considers user experience and ensures that QoS requirements are fulfilled. In addition, six capacity factors are available for scheduling priority selection oriented towards capacity or resource fairness in EPF. For details about the selection, see 4.2 DL Dynamic Scheduling. An operator can select an appropriate scheduling policy by setting the CellDlschAlgo.DlschStrategy parameter. For example, an operator can select Max C/I to achieve high system throughput for a peak throughput test. 3.4.2 DL Scheduling Resource Acquisition 3.4.2.1 Overview A basic function of DL scheduling is to obtain DL scheduling resources on the PDSCH. If power allocation is enabled in the DL, DL scheduling needs to obtain resources based on power control. For details about power control, see Power Control Feature Parameter Description. Huawei eNodeBs support two DL resource allocation modes: • Frequency diversity scheduling • Frequency selective scheduling The FreqSelSwitch option of the CellAlgoSwitch.DlSchSwitch parameter is used to specify whether to use frequency selective scheduling. Frequency diversity scheduling is used by default. 3.4.2.2 Frequency Diversity Scheduling Frequency diversity scheduling does not consider the differences in the frequency-domain channel quality for UEs. The eNodeB calculates the scheduling priorities based on the wideband CQIs reported by UEs. Based on the priority calculation results, the eNodeB allocates DL resources to the UEs from a low frequency band to a high frequency band, as shown in Figure 3-4. Figure 3-4 DL resource allocation in frequency diversity scheduling 3.4.2.3 Frequency Selective Scheduling This section describes the basic feature LBFD-060103 Enhanced DL Frequency Selective Scheduling. Frequency selective scheduling considers the differences in the frequency-domain channel quality for UEs and brings gains. The eNodeB calculates the subband-specific scheduling priorities of UEs based on subband CQIs reported by the UEs and schedules the UEs based on the priorities so that resources in the subbands with the optimum channel quality are allocated to the UEs. As shown in Figure 3-5, resource block groups (RBGs) a and c are allocated to UE 1 and RBG b is allocated to UE 2 because UE 1 and UE 2 have the highest scheduling priority in the scheduling queue corresponding to the allocated RBGs. Figure 3-5 DL resource allocation in frequency selective scheduling Frequency selective scheduling requires accurate subband CQIs for scheduling priority calculation and resource allocation. To obtain subband CQI information from UEs, the eNodeB triggers aperiodic CQI reporting. The following describes the parameters and factors affecting aperiodic CQI reporting: • The CellDlschAlgo.FSUESbCQIValidityPeriod parameter specifies the validity period of subband CQIs aperiodically reported by UEs in frequency selective scheduling. A larger value of this parameter results in a higher probability that frequency selective scheduling is selected for UEs. The CellDlschAlgo.FSUEAperCQITrigPeriod parameter specifies the interval at which aperiodic CQI reporting is triggered for UEs in frequency selective scheduling. A larger value of this parameter results in a smaller number of aperiodic CQI reports, reducing the gains of frequency selective scheduling. If the CellDlschAlgo.FSUEAperCQITrigPeriod parameter value is not greater than the CellDlschAlgo.FSUESbCQIValidityPeriod parameter value, there is a high probability that frequency selective scheduling is selected for UEs. • Uplink load affects the interval of aperiodic CQI reporting. If the uplink load is high, the eNodeB prolongs the subband CQI reporting period and adjusts the CQI reporting mode of UEs. The prolonged CQI reporting period and the changed CQI reporting mode decrease frequency selective scheduling gains. • Subband CQIs reported by fast moving UEs cannot reflect channel quality changes in a timely manner. Therefore, frequency selective scheduling works for slowly moving UEs but not for fast moving UEs. • If the time since a UE's last downlink DRB scheduling is greater than or equal to the threshold specified by the CellDlschAlgo.NoSchStopACqiThd parameter, the UE stops aperiodic CQI reporting in the current TTI. Setting this parameter to a small value reduces the number of unnecessary aperiodic CQI reports and thereby increases uplink throughput. NOTE: For more details about aperiodic CQI reporting, see MIMO Feature Parameter Description. The eNodeB periodically checks channel quality fluctuations and the moving speed of each UE. It starts frequency selective scheduling when the triggering conditions are met, and stops the scheduling when the triggering conditions are not fulfilled. The CellDlschAlgo.FreqSelJudgePeriod parameter determines the scheduling evaluation period. The smaller the value of this parameter is, the faster DL frequency selective scheduling is triggered for the UEs meeting the triggering conditions, boosting the improvements in DL spectral efficiency. However, more aperiodic CQI reports are required to trigger DL frequency selective scheduling, and interference to UL transmission arises. If fast frequency selective scheduling is enabled, it is recommended that fast Doppler measurement reporting also be enabled. The number of PDCCH symbols, together with the CellAlgoSwitch.DlSchSwitch and CellPdcchAlgo.PdcchSymNumSwitch parameters, affects the triggering of DL frequency selective scheduling. The initial number of PDCCH symbols is specified by the CellPdcchAlgo.InitPdcchSymNum parameter. Table 3-1 describes how the number of PDCCH symbols affects DL frequency selective scheduling under different settings of the CellPdcchAlgo.PdcchSymNumSwitch parameter and FreqSelSwitch under the CellAlgoSwitch.DlSchSwitch parameter. Table 3-1 Impact of the number of PDCCH symbols on the triggering of DL frequency selective scheduling FreqSelSwitch PdcchSymNumSwitch Number of PDCCH Symbols Triggering DL Frequency Selective Scheduling? On On Maximum number of PDCCH symbols for a constant period of time Yes NOTE: For details about the maximum number, see section 6.7 "Physical control format indicator channel" in 3GPP TS 36.211. Off Others No ECFIADAPTIONON Any adaptively assigned number Yes Off Any permanently assigned number Yes N/A N/A No 3.4.2.4 Doppler Measurements Huawei eNodeBs perform Doppler measurements to obtain UE speed information. The FreqSelJudgeIgnorDopplerSwitch option of the CellAlgoSwitch.DlschSwitch parameter determines whether to use Doppler measurements. • If the FreqSelJudgeIgnorDopplerSwitch option is selected, DL frequency selective scheduling ignores Doppler measurement levels. This parameter setting applies to hotspots where UEs move at low speeds, reducing the negative impact of inaccurate Doppler measurements. • If the FreqSelJudgeIgnorDopplerSwitch option is deselected, DL frequency selective scheduling uses Doppler measurement levels. This parameter setting applies to common cells. A Doppler measurement period can be either fast or slow. The period type is determined by the FastReportDopSwitch option of the CellUlschAlgo.DopAlgoSwitch parameter. • If the FastReportDopSwitch option is selected, a fast Doppler measurement period is used. • If the FastReportDopSwitch option is deselected, a slow Doppler measurement period is used. Huawei eNodeBs support Doppler measurement level selection. Doppler measurement levels are specified by the CellUlschAlgo.DopMeasLevel parameter. • If the parameter is set to CLASS_0, the eNodeB performs Doppler measurements on physical uplink shared channel (PUSCH) demodulation reference signals (DMRSs) whose SINR is greater than or equal to 5 dB. • If the parameter is set to CLASS_1, the eNodeB performs Doppler measurements on PUSCH DMRSs whose SINR is greater than or equal to –5 dB. Doppler measurements of level 1 provide more UE speed information. NOTE: • The LBBPc board of a macro eNodeB does not support Doppler measurement level selection. • Micro eNodeBs do not support Doppler measurement level selection. 3.4.3 MCS Selection During DL Scheduling The following is the procedure for selecting an MCS for a UE during DL scheduling: 1. If the serving cell of the UE is not established on an LBBPc, the eNodeB determines whether to optimize UE-reported CQIs based on the settings of the PUSCH_CQI_FALSE_DETECTION_SW and PUCCH_CQI_FALSE_DETECTION_SW options of the CellCqiAdjAlgo.CqiOptSwitch parameter. • If the PUSCH_CQI_FALSE_DETECTION_SW option is selected, the eNodeB optimizes the CQIs reported on the PUSCH. • If the PUCCH_CQI_FALSE_DETECTION_SW option is selected, the eNodeB optimizes the CQIs reported on the PUCCH. • If both the PUSCH_CQI_FALSE_DETECTION_SW and PUCCH_CQI_FALSE_DETECTION_SW options are deselected, the eNodeB does not optimize the reported CQIs. 2. The eNodeB selects the CQI type. • If frequency diversity scheduling is used, the eNodeB considers the wideband CQI reported by the UE. • If frequency selective scheduling is used, the eNodeB considers the subband CQIs reported by the UE. 3. The eNodeB determines whether to adjust the CQI reported by the UE based on the setting of the CqiAdjAlgoSwitch option of the CellAlgoSwitch.CqiAdjAlgoSwitch parameter. • If this switch is on, the eNodeB adjusts the CQI reported by the UE. • If this switch is off, the eNodeB does not adjust the CQI reported by the UE. 4. The eNodeB maps the CQI reported by the UE to a transport block size index (ITBS) and then maps the ITBS to an IMCS, which identifies the MCS used for the UE. For details about the mapping from ITBS to IMCS, see section 7.1.7 in 3GPP TS 36.213 V10.1.0 (2011-03). The eNodeB temporarily uses a fixed MCS for a UE that is in a handover procedure or has just been handed over to the target cell. A UE experiences poor channel quality during a handover or immediately after a handover. To ensure stable data transmissions in this situation, the eNodeB uses different MCSs before and after the timer specified by the CellDlschAlgo.HoStaticMcsTimer parameter expires in the target cell. • Before the timer expires, the eNodeB uses a fixed MCS for the UE. • After the timer expires, the eNodeB dynamically selects an MCS for the UE. If the transport block allocated to a UE is occupied by broadcast signals or synchronization signals, the coding rate increases when the TBS remains unchanged. The eNodeB selects another MCS based on resource usage to maximize system throughput. 3.4.4 Determining the Number and Positions of RBs for DL Scheduling 3.4.4.1 Number and Positions of RBs for DL Scheduling The amount of data to be scheduled in a TTI determines the number of RBs to be scheduled for UEs. Before determining the user data to be scheduled, a Huawei scheduler estimates the Radio Link Control (RLC) and MAC header overheads. This enables the scheduler to allocate scheduling resources as precisely as possible, maximizing the resource utilization efficiency. The scheduler then obtains the amount of data to be scheduled and the IMCS, and estimates the number of RBs to schedule based on section 7.1.7 in 3GPP TS 36.213 V10.1.0 (2011-03). Based on the remaining power of the cell, the scheduler determines the number of RBs to schedule for the UE. The scheduler selects the positions of the RBs based on the scheduling mode: frequency diversity scheduling or frequency selective scheduling. 3.4.4.2 PDSCH Efficiency Improvement This section describes the basic feature LBFD-070106 PDSCH Efficiency Improvement. The PDSCH efficiency improvement feature improves PDSCH resource utilization when idle RBs are available, thereby increasing downlink throughput. 3.4.4.2.1 MCS Selection with Prioritized RBs The function of MCS selection with prioritized RBs reduces the MCS index and increases the number of RBs. When the air interface resources are sufficient, the function of MCS selection with prioritized RBs reduces packet retransmissions and the scheduling delay of small-traffic service packets. This function increases user rates but decreases DL spectral efficiency. Policy for MCS Selection with Prioritized RBs The policy for MCS selection with prioritized RBs applies to single-UE and multi-UE scenarios. • In single-UE scenarios, the UE can be either of the following: ◾ A single online UE with limited capabilities. ◾ A single UE that has only one service to be scheduled and the percentage of TTIs with expected remaining RBs is less than the CellDlschAlgo.RBPriMcsSelectRatioThd parameter value in a measurement period. • In multi-UE scenarios, MCS selection with prioritized RBs applies to the last UE to be scheduled in the current TTI, which can be either of the following: ◾ The last UE with limited capabilities to be scheduled in the current TTI. ◾ The last UE to be scheduled in the current TTI when the percentage of TTIs with expected remaining RBs is less than the CellDlschAlgo.RBPriMcsSelectRatioThd parameter value in a measurement period. The CellDlschAlgo.RBPriMcsSelectStrategy parameter determines the policy for MCS selection with prioritized RBs. • When this parameter is set to SINGLEUSER_STRATEGY(Single User Strategy), MCS selection with prioritized RBs is performed only in single-UE scenarios. • When this parameter is set to MULTIUSER_STRATEGY(Multiple User Strategy), MCS selection with prioritized RBs can be performed in either single-UE scenarios or multi-UE scenarios. • When this parameter is set to MULTIUSR_LOWMCSLIMIT_STRATEGY(Multiple User Lower MCS Limited Strategy), enhanced MCS selection with prioritized RBs can be performed in either single-UE scenarios or multi-UE scenarios. Enhanced MCS selection with prioritized RBs allows the MCS index to be decreased by a maximum of three. This processing mechanism reduces the air interface transmission delay of small-traffic services for more users, without increasing the neighboring cell interference caused by an increasing number of RBs in the local cell. Selection Ratio for MCS Selection with Prioritized RBs The eNodeB obtains the ratio of TTIs during which the MCS index is reduced for scheduling to the total DL subframes in the last measurement period. If the ratio is less than a threshold, MCS selection with prioritized RBs will be enabled in the next measurement period. NOTE: The MCS index can be reduced for scheduling of a service in a TTI only if the service is the only service to be scheduled for initial transmission in the TTI. The eNodeB queries the TBS table based on the RBs that can be allocated to the associated UE and the traffic volume to be transmitted. If the obtained TBS index is less than the default TBS index, the eNodeB marks the TTI a TTI with a reduced MCS index. The CellDlschAlgo.RBPriMcsSelectRatioThd parameter is used to specify the threshold for enabling MCS selection with prioritized RBs. • If this parameter is set to 0, the function of MCS selection with prioritized RBs is disabled when the data volume is insufficient. • If this parameter is set to 100, the function of MCS selection with prioritized RBs is always enabled when the data volume is insufficient. This parameter is used to control the interference to neighboring cells that is caused by the increasing RBs in the serving cell. When this parameter is set to a large value, the delay for small-traffic services in the serving cell decreases significantly but the interference to neighboring cells is also high. When this parameter is set to a small value, the delay for small-traffic services in the serving cell decreases insignificantly and the interference to neighboring cells is low. 3.4.4.2.2 MCS Selection for Transmission of Small-Amount Data The TBS selected for the initial transmission may be greater than the amount of to-be-transmitted data. This occurs if the RBG allocation policy is adaptive allocation or to round up the number of allocated RBGs to the nearest integer and the amount of downlink data to be initially transmitted is small. In this situation, the SmallPktMcsSelectAlgoSw option of the CellAlgoSwitch.DlSchSwitch parameter can be selected to enable MCS selection for transmission of small-amount data. When this option is selected, the eNodeB selects an MCS with a smaller index while maintaining the number of allocated RBGs, reducing the IBLER and the number of retransmissions and increasing user-perceived downlink data rates. 3.4.4.2.3 Adaptive Power Allocation for Cell-Edge UEs This function aims to increase the throughput of cell-edge UEs, for which the indexes of selected MCSs are less than 7, in light-load wide-coverage scenarios. This function is controlled by the AdptCellEdgePwrAllocSw option of the CellAlgoSwitch.CellDlCoverEnhanceSwitch parameter. If the channels are not additive white Gaussian noise (AWGN) channels and radio resources are insufficient, this function reallocates RBs and reselects an MCS for a cell-edge UE after RB allocation for initial transmission. This increases the TBS for the UE without changing total power for it. 3.4.4.2.4 PDCCH and PDSCH Resource Balancing When a cell serves a large number of UEs in RRC_CONNECTED mode with a high proportion of small-packet data transmission and PDCCH resources are insufficient, the number of UEs scheduled per TTI in the downlink is limited and PDSCH resource utilization deteriorates. In this situation, the function of PDCCH and PDSCH resource balancing is recommended. With this function, the scheduler randomly selects a UE with large-packet data transmission and reserves PDCCH resources for the selected UE. When scheduling the last UE in the downlink, the scheduler allocates PDSCH resources to the selected UE, improving DL RB utilization and throughput. This function involves the following parameters: • CellDlschAlgo.DataThdInPdcchPdschBal specifies the data volume threshold for determining UEs with large-packet data transmission. • CellDlschAlgo.UeNumThdInPdcchPdschBal specifies the UE number threshold for triggering this function in a cell. Note the following when using this function: • In RAN sharing scenarios, the scheduler selects a UE only from those served by the high-priority operator in the current TTI if large-packet bearers are selected. • In carrier aggregation (CA) scenarios, the scheduler considers only the data volume of the bearer on the current carrier if large-packet bearers are selected. • In DRX scenarios, the scheduler considers only UEs in the active time if large-packet bearers are selected. If a UE enters sleep time, the eNodeB removes it from the candidate list. 3.4.4.3 RB Blocking at Micro eNodeBs A macro cell may experience interference from a micro cell (under a micro eNodeB) if the micro eNodeB is deployed near the center of the intra-frequency macro cell (under a macro eNodeB). This causes macro cell signal quality to deteriorate and affect user experience. Meanwhile, the micro cell may also experience interference from the macro cell, shrinking micro cell coverage. If the RB blocking function is enabled, the micro eNodeB blocks multiple consecutive RBs in ascending order of frequency when allocating DL resources. The number of blocked RBs is indicated by BlockRbNumber. These blocked RBs cannot be scheduled for DL initial transmissions and retransmissions (including semi-persistent scheduling). These blocked RBs can be used only for transmission of common control information. With RB blocking enabled, user experience may degrade in the micro cell, but user experience of UEs suffering interference improves in the macro cell. The formula for calculating BlockRbNumber is as follows: BlockRbNumber = ceiling (Total number of RBs available to the DL bandwidth of the micro cell x Predefined proportion of blocked RBs to total RBs in the micro cell) NOTE: Blocked RBs that are used to transmit common control information are still counted as blocked RBs. An operator can use the CellDlschAlgo.MicRbBlockRatio parameter to specify whether to use RB blocking based on requirements. Scenarios of Micro eNodeB deployment are described as follows: • Micro eNodeB not deployed If the micro eNodeB absorbs only a few users, it is recommended that this micro eNodeB not be deployed near the center of the macro cell. • Micro eNodeB deployed with RB blocking disabled If the micro eNodeB absorbs many users, this function is not recommended. The micro cell can share the load with the macro cell so user experience is not affected even though the macro cell still experience interference from the micro cell. • Micro eNodeB deployed with RB blocking enabled If the micro eNodeB absorbs certain users, this function is recommended. RB blocking of the micro eNodeB must be used together with frequency selective scheduling of the macro eNodeB. This influences the macro and micro eNodeBs in the following ways. eNodeB Type Influence Macro eNodeB DL throughput is improved for users who experience interference from the micro cell. Micro eNodeB eNodeB Type Influence • If users have high data traffic and good user experience, their DL throughput may decrease with the functions enabled. • If users have low data traffic and low RB resource usage, user experience is not affected with the functions enabled. 3.5 Scheduling Termination for Abnormal UEs This function prevents overuse of system resources by UEs in extremely weak coverage areas or with radio link failures. In addition, it reduces the RBLER in the system. When AbnUeSchSwitch under the CellAlgoSwitch.CellSchStrategySwitch parameter is on, the DL scheduler in the eNodeB evaluates link faults based on the HARQ feedback transmitted on the PUCCH of format 1a, 1b, or 1bcs in response to the downlink transmission. If the HARQ feedback indicates a consecutive number of DTXs that exceeds the value of the CellDlschAlgo.DlSchAbnUeThd parameter, the DL scheduler determines that the UE has encountered a link fault. The scheduler then stops DL scheduling for initial transmissions and retransmissions to the UE. If the UE is working in the carrier aggregation (CA) state, this function takes effect in the primary serving cell (PCell) of the UE but does not take effect in any secondary serving cell (SCell). The scheduler resumes DL scheduling for the UE if any of the following conditions is met: • The PUSCH cyclic redundancy check (CRC) succeeds once. • The CRC for aperiodic CQI reports succeeds once. • The eNodeB receives four consecutive CQI reports with non-DTXs over the PUCCH. 3.6 Manual Blocking of PDSCH RBs If certain PDSCH RBs experience strong interference from a definite external source or are unavailable because of spectrum planning, these RBs can be manually blocked so that the eNodeB will not use them during DL scheduling. The parameters in the CellRbReserve MO determine the RB blocking mode and the locations and quantity of these RBs. This RB blocking function does not take effect on control channels or common channels. This function reduces the number of available RBs and therefore affects broadcast of system information related to enhanced Machine Type Communication (eMTC) and transmission of MTC physical downlink control channel (MPDCCH). As a result, eMTC fails to take effect. 4 DL Enhanced Scheduling DL enhanced scheduling is an enhancement to DL basic scheduling. DL enhanced scheduling adjusts the selected MCSs based on DL channel quality and HARQ feedback. In this way, DL enhanced scheduling increases the DL capacity and better satisfies the QoS requirements of DL services. 4.1 DL CQI Adjustment This section describes the basic feature LBFD-00101501 CQI Adjustment. 4.1.1 Overview The eNodeB selects an MCS for data transmission to a UE based on the UE-reported CQI. If the reported CQI does not reflect the channel quality at the time of scheduling, the IBLER will not approach the target optimum value. Therefore, the eNodeB must check the difference between the reported channel quality and the actual channel quality based on HARQ feedback and adjusts the CQI accordingly. Accuracy of reported CQIs is affected by the following factors: • CQI reporting is delayed n TTIs. If the delay is longer than the channel coherence time, the CQI reported by the UE is inconsistent with the channel quality at the time of scheduling. NOTE: The value n is determined by the processing capability of the eNodeB, transmission delay over the radio interface, and the CQI reporting period. • The CQI reporting period is far greater than the scheduling period, which leads to a difference between the CQI at the reporting time and the CQI at the scheduling time. 4.1.2 Principles for DL CQI Adjustment The CqiAdjAlgoSwitch option of the CellAlgoSwitch.CqiAdjAlgoSwitch parameter determines whether to enable the DL CQI adjustment algorithm. • If this option is deselected, the DL CQI adjustment algorithm is disabled and the eNodeB selects MCSs based on the reported CQIs. • If this option is selected, the DL CQI adjustment algorithm is enabled and the eNodeB selects MCSs based on the adjusted CQIs. The principles for the adjustment are as follows: ◾ The IBLER increases if channel quality does not meet the requirements of the MCS selected by the scheduler. To lower the IBLER, the eNodeB decreases the CQI value based on HARQ-NACKs. The decrease is the CQI adjustment value. ◾ The IBLER decreases if channel quality is higher than the minimum requirements of the MCS selected by the eNodeB. In this situation, the eNodeB increases the CQI value based on HARQ-ACKs. The increase is the CQI adjustment value. CQI adjustment enables the IBLER to approach the target value and increases DL throughput. The target IBLER determines the CQI adjustment value. Figure 4-1 illustrates the DL CQI adjustment algorithm. Figure 4-1 DL CQI adjustment algorithm 4.1.3 Target IBLER for DL CQI Adjustment If the target IBLER is set too low, the eNodeB selects MCSs for DL data packets in a conservative manner, reducing transmission efficiency. If the target IBLER is set too high, the eNodeB selects MCSs for DL data packets in an aggressive manner, increasing the number of DL retransmissions. The target IBLER value for CQI adjustment is 10% by default. Increasing the target IBLER value improves spectral efficiency in certain scenarios (for example, at cell edge or small-packet services at non-edge locations). It typically increases the capacity of heavily loaded cells. eNodeBs support target IBLER adaptation. Target IBLER adaptation is enabled when operators set DlEnVarIblerTargetSwitch and DlVarIBLERtargetSwitch under the CellAlgoSwitch.CqiAdjAlgoSwitch parameter on. Figure 4-2 shows how target IBLER adaptation works under different switch settings. Figure 4-2 Target IBLER adaptation under different switch settings The target IBLER adaptation policies are as follows: • The target IBLER changes based on channel quality fluctuations (indicated by CQIs). ◾ When the CellDlschAlgo.LowIblerTargetTbsIdxThld parameter is set to 255: ◾ If the channel quality fluctuates greatly, the target IBLER changes to 30%. ◾ If the channel quality fluctuates moderately, the target IBLER changes based on the UE location and the proportion of small-packet services. ◾ If the channel quality fluctuates slightly, the target IBLER changes to 5%. ◾ When the CellDlschAlgo.LowIblerTargetTbsIdxThld parameter is set to a value other than 255: ◾ If the channel quality fluctuates greatly: ◾ If the TBS index for the UE does not exceed the value of the CellDlschAlgo.HighIblerTargetTbsIdxThld parameter, the target IBLER changes to 30%. ◾ Otherwise, the target IBLER changes to 10%. ◾ If the channel quality fluctuates slightly: ◾ If the TBS index for the UE is not less than the value of the CellDlschAlgo.LowIblerTargetTbsIdxThld parameter, the target IBLER changes to 5%. ◾ Otherwise, the target IBLER changes to 10%. ◾ If the channel quality fluctuates moderately, the target IBLER changes based on the UE location and the proportion of small-packet services. • The target IBLER changes to different values based on the UE location and proportion of small-packet services. ◾ For UEs running small-packet services at non-edge locations and cell edge UEs, the target IBLER increases to 30%. ◾ For UEs running non-small-packet services at non-edge locations, the target IBLER decreases to 10%. NOTE: Target IBLER adaptation does not apply to UEs running services with a QCI of 1. 4.1.4 Step for CQI Adjustment The step by which the CQI value is increased or decreased each time is referred to as the CQI adjustment step. It depends on the initial step, variable step, and IBLER. The initial step for CQI adjustment is specified by the CellDlschAlgo.CqiAdjInitialStep parameter. The initial step is used in the event of initial access and incoming handovers. The variable step for CQI adjustment is determined by the StepVarySwitch option of the CellAlgoSwitch.CqiAdjAlgoSwitch parameter. • When the StepVarySwitch option is deselected, ◾ If the IBLER is less than 5%, the CQI adjustment step is the initial step. ◾ If the IBLER is greater than or equal to 5%, the CQI adjustment step is fixed at 0.1. • When the StepVarySwitch option is selected, The CQI adjustment step is equal to the initial step at the beginning and then adjusted as follows: ◾ If the UE has sparse DL services (specifically, the probability that the UE is scheduled in the downlink within 100 ms is less than 10%), The CQI adjustment step is constantly changing based on the difference between the current IBLER value and the target IBLER value. A larger difference leads to a larger CQI adjustment step, which speeds up convergence to the target IBLER value. ◾ If the UE has dense DL services, The CQI adjustment step is fixed at 0.1. After the CQI adjustment step is restored to the initial step, CQI adjustment using the initial step cannot match channel state changes if the channel state changes drastically. To address this mismatch, the eNodeB supports adaptive CQI adjustment. This function is controlled by the AdaptiveStepVarySwitch option of the CellAlgoSwitch.CqiAdjAlgoSwitch parameter. When this option is selected, the eNodeB adjusts the CQI based on the HARQ feedback for downlink transmissions. This function does not take effect on UEs with QCI-1 services. • If the HARQ feedback for downlink transmissions is constantly ACKs, the eNodeB uses a large step to increase the CQI. • If the HARQ feedback for downlink transmissions is constantly NACKs, the eNodeB uses a large step to decrease the CQI. 4.1.5 Period for DL CQI Adjustment If the cell serves a massive number of online users, the CQI adjustment period is prolonged and the CQI adjustment algorithm may receive multiple HARQ feedback messages in a CQI adjustment period. The DlCqiAdjDeltaOptSwitch option of the CellAlgoSwitch.CqiAdjAlgoSwitch parameter specifies how to calculate the CQI adjustment value. • When this option is deselected, the CQI adjustment algorithm considers all the received HARQ feedback messages in a CQI adjustment period as one feedback message, based on which the CQI adjustment value is calculated. This calculation method causes slow CQI adjustment. • When this option is selected, the CQI adjustment algorithm calculates the CQI adjustment value based on each HARQ feedback message received in a CQI adjustment period. This calculation method causes fast CQI adjustment. 4.1.6 Initial Value of CQI Adjustment An eNodeB calculates a CQI adjustment value for a UE based on HARQ feedback. It sets the initial value for the UE during initial access or during the incoming handover of the UE. The larger the initial value is, the more aggressive the initial MCS is for the UE. The smaller the initial value is, the more conservative the initial MCS is for the UE. The initial CQI adjustment value is specified by the CellCqiAdjAlgo.InitDeltaCqi parameter. When the PreciseMcsAdaptSwitch option of the CellAlgoSwitch.CqiAdjAlgoSwitch parameter is selected, the eNodeB compensates for the CQI adjustment value for UEs. The eNodeB applies compensation to the CQI adjustment value when the CellCqiAdjAlgo.InitDeltaCqi parameter is set to a value smaller than –1 and the UE reports consecutive ACKs as feedback on DL HARQ. This function does not take effect on UEs with QCI-1 services. 4.2 DL Dynamic Scheduling 4.2.1 Overview This section describes the basic feature LBFD-00101502 Dynamic Scheduling. A scheduler uses the EPF scheduling algorithm to provide end-to-end QoS. This algorithm calculates the service scheduling priorities and ensures service rates. 4.2.2 GBR Service Priority Calculation The GBR service priority calculation is dependent on the setting of the DlMbrCtrlSwitch option of the CellAlgoSwitch.DlSchSwitch parameter: • When the DlMbrCtrlSwitch option is deselected, The eNodeB preferentially guarantees the GBR of GBR services and maximizes spectral efficiency. The priority of a GBR service is calculated using the following formula: where indicates the channel quality. indicates the PDB of the GBR service. • When the DlMbrCtrlSwitch option is selected, The rates of GBR services range from the GBR to the MBR. In this situation, resource allocation does not distinguish between GBR and non-GBR services. Therefore, the same formula is used to calculate the priorities of GBR and non-GBR services. For details, see 4.2.3 Non-GBR Service Priority Calculation. The guaranteed rate and maximum rate of the services with QCI 1 are twice the GBR and MBR, respectively. This design aims to guarantee the QoS of low-rate small-packet services. NOTE: When a cell serves multiple UEs and UE capabilities are limited (the maximum traffic volume received by UEs per TTI is lower than the maximum air interface capacity), there is a possibility that the GBR or MBR of some services cannot be guaranteed while spare air interface resources are available in the serving cell, if the GBR or MBR is set to a large value. 4.2.3 Non-GBR Service Priority Calculation The priority of a non-GBR service is determined by the channel quality, historical transmission rate, QCI, and weight. The total rate of all non-GBR services of a UE cannot exceed the per UE aggregate maximum bit rate (UE-AMBR). The priority of a non-GBR service is calculated using the following formula: where • indicates the channel quality. • indicates the capacity adjustment factor for EPF. ◾ When the factor is set to 1, the scheduling priority selection is oriented towards resource fairness. ◾ When the factor is set to a value smaller than 1, the scheduling priority selection is oriented towards rate fairness. ◾ When the factor is set to a value greater than 1, the scheduling priority selection is oriented towards capacity. • indicates the historical transmission rate. Its calculation is dependent on the setting of the EpfEnhancedSwitch option of the CellAlgoSwitch.DlSchSwitch parameter. ◾ When the EpfEnhancedSwitch option is deselected, ◾ When the EpfEnhancedSwitch option is selected, indicates the average scheduled rate. The scheduler obtains through filtering. indicates the result of the transmitted data volume divided by the data transmission duration. • indicates the weight factor for the scheduling priority corresponding to the QCI of the non-GBR service. A larger value of the weight factor results in a higher scheduling priority. For details about the weight factor, see QoS Management Feature Parameter Description. • indicates the delay for the non-GBR service packets to wait for scheduling on the eNodeB side. This delay factor can be used for calculating the scheduling priority of non-GBR services only when the DL non-GBR packet bundling switch has been turned on. For details, see 4.3 DL Non-GBR Packet Bundling. 4.2.4 Resource Proportions for GBR and Non-GBR Services When both GBR and non-GBR services are running on a network, schedulers preferentially guarantee GBR services, which have a higher priority than non-GBR services. • The schedulers guarantee the GBR, packet error loss rate (PELR), and packet delay budget (PDB) of GBR services. In addition, a GBR service can be scheduled multiple times. The scheduler checks the GBR service rate at regular intervals and increases or decreases the number of times the GBR service is scheduled. This ensures a stable GBR service rate. • The schedulers adopt a best-effort policy and guarantee the PELR but not the GBR for non-GBR services. If the radio resources of a cell become insufficient and the proportion of GBR services is large, it is possible that non-GBR services are not scheduled and get starved. To prevent non-GBR service starvation when a large number of GBR and non-GBR services are both running, operators can set the following parameters: • CellDlschAlgo.NonGbrResourceRatio. This parameter specifies the proportion of resources reserved for non-GBR services. NOTE: This parameter is a cell-level parameter and applies only to DL non-GBR services. The prioritized bit rate (PBR) mechanism and scheduling request (SR) preferential scheduling mechanism are used for UL non-GBR services to ensure that there are always resources to be allocated. • QciPara.DlMinGbr. This parameter specifies the minimum DL guaranteed bit rate of non-GBR services with the specified QCI. 4.2.5 DL AMBR Control over Non-GBR Services A per UE aggregate maximum bit rate (UE-AMBR) is defined in the EPC for the total rate of all DL non-GBR services on each UE. The eNodeB controls the total number of bits sent to a UE within a period to be not greater than the UE-AMBR multiplied by the period. This period is specified by the CellDlschAlgo.AmbrCtrlTcycle parameter. A larger value of this parameter results in a larger volume of data scheduled at a time within a period. This reduces the wait time during scheduling and therefore leads to higher userperceived data rates for UEs with low UE-AMBRs. It is recommended that UE-AMBR control be enabled on the eNodeB and the CellDlschAlgo.AmbrCtrlTcycle parameter be set to its default value to ensure fairness between UEs. Set the parameter to larger values if network resources are sufficient and an operator accepts less precise control or does not plan to use UE-AMBR control. 4.2.6 Delayed Scheduling of DL RLC Status Reports This function works when PDCCH CCE insufficiency occurs at major incidents, for example, when the PRB usage, the number of RRC_CONNECTED UEs, and the PDCCH CCE usage are greater than 80%, 200, and 70%, respectively. Certain RLC ACK status reports are not transmitted until DL packet bundling occurs. These reports were originally to be separately transmitted and their wait time has not expired. This function is controlled by the DlRLCStateReportSchDelaySw option of the CellAlgoSwitch.DlSchSwitch parameter. In the preceding scenario, this function increases userperceived DL data rates. The increases in the data rates have a strong positive correlation with the percentage of data amount of DL RLC ACK status reports. The higher the percentage, the larger the increase. 4.3 DL Non-GBR Packet Bundling This section describes the optional feature LOFD-001109 DL Non-GBR Packet Bundling. The formula for calculating the scheduling priority of a non-GBR service is as follows: In this formula, indicates the delay for the non-GBR service packets to wait for scheduling on the eNodeB side. For details, see 4.2.3 Non-GBR Service Priority Calculation. The NonGbrBundlingSwitch option of the CellAlgoSwitch.DlSchSwitch parameter determines whether to enable DL Non-GBR Packet Bundling. • When this option is deselected, the delay factor is not considered in scheduling priority calculation for non-GBR services. • When this option is selected, the delay factor is considered in the calculation. The eNodeB bundles multiple DL data packets before sending them when using DL Non-GBR Packet Bundling. This feature increases control channel resource usage if control channel congestion occurs, and helps optimize the delay performance of the non-GBR service packets. NOTE: The optimization on the overall transmission delay performance of non-GBR service packets indicates the improvement on the delay distribution of DL data packets waiting to be scheduled, but does not necessarily indicate a decrease in the average scheduling delay for all DL data packets. When multiple data packets are bundled for transmission, the scheduling delay for packets allowing large delay decreases, but that for packets allowing small delay may increase. Therefore, the average delay for all these packets may either increase or decrease. If the DL scheduling delay decreases, the traffic volume in the DL TCP small-packet send window increases. If the DL scheduling delay increases, the traffic volume in the window decreases. 4.4 DL RB Allocation If the number of RBs required by the scheduled UE is not an integer number of RBGs, you can use the CellDlschAlgo.RbgAllocStrategy parameter to control the number of RBGs allocated to the scheduled UE. • When this parameter is set to ROUND_DOWN, ◾ If the number of required RBs is less than one RBG, a required number of RBs are allocated to the scheduled UE. (Resource allocation type 1 is used.) ◾ If the number of required RBs is greater than one RBG, the number of RBGs to be allocated is rounded down to the nearest integer. In this situation, RBs are efficiently used, but the number of scheduling times also increases and the DL data rates decrease. • When this parameter is set to ROUND_UP, the number of RBGs to be allocated is rounded up to the nearest integer, regardless of whether the number of required RBs is greater or less than one RBG. In this situation, a few RBs are wasted, but the number of scheduling times also decreases and the DL data rates increase. • When this parameter is set to ADAPTIVE, ◾ If the number of required RBs is less than one RBG, a required number of RBs are allocated to the scheduled UE. (Resource allocation type 1 is used.) ◾ If the number of required RBs is greater than one RBG, the number of RBGs to be allocated is rounded up to the nearest integer. Compared with round-up, this mode prevents RB waste when the number of required RBs is less than one RBG. Services with QCI 1 (such as VoLTE services) receive a special treatment: If the CellDlschAlgo.RbgAllocStrategy parameter is set to ROUND_DOWN, the parameter value ADAPTIVE takes effect. 4.5 DL Traffic-Model-based Scheduling This section describes LOFD-110205 Traffic Model Based Performance Optimization. With this feature, the eNodeB preferentially schedules the UEs running small-amount data services and experiencing good signal quality to reduce user wait time. This feature increases the perceived data rates and improves user experience while basically maintaining cell capacity. Specifically, in scenarios with a heavy traffic load (for example, the RB usage is greater than 60%), the user-perceived data rate increases by 5% to 20%. This feature works in cells with a bandwidth of at least 5 MHz. This feature is controlled by the DlPacketLenAwareSchSw option of the CellAlgoSwitch.DlSchSwitch parameter. This feature is enabled only when this option is selected. 5 UL Scheduling 5.1 UL Scheduling Procedure The actions in the UL scheduling procedure are performed sequentially based on priorities. Figure 5-1 shows the priorities in the UL scheduling procedure in a TTI. Figure 5-1 Priorities in the UL scheduling procedure NOTE: Micro base stations do not support UL CoMP. When there is data to be scheduled and resources are available for scheduling, the UL scheduling procedure is the same as the DL scheduling procedure. For details, see 3.1 DL Scheduling Procedure. 1. Allocates resources for message 3 (Msg3). Scheduling for Msg3 is indicated in RARs and does not require messages on the physical downlink control channel (PDCCH). For details, see 5.4 UL Scheduling for Initial Transmissions. 2. Performs UL semi-persistent scheduling. For details, see VoLTE Feature Parameter Description. 3. Schedule UEs in the TTI bundling state. For details, see VoLTE Feature Parameter Description. 4. Allocates resources for HARQ retransmissions. For details, see 5.3 UL Scheduling for Retransmissions. 5. Allocates resources to UEs that have sent SRs. For details, see 5.4 UL Scheduling for Initial Transmissions. 6. Allocates resources for UE's UL control information. For details, see 5.4 UL Scheduling for Initial Transmissions. 7. Schedules UEs with unsatisfied UL GBR. For details, see 6.1 UL QoS Management. 8. Schedules UEs running non-GBR services with UL bit rates lower than the UEs' UL Min-GBRs. For details, see 6.1.1 Service Rate Control on the eNodeB. 9. Schedules UEs running non-GBR services with UL bit rates lower than the UEs' UL AMBRs. For details, see 6.1 UL QoS Management. 10. Schedules CQI-only UEs. For details, see 5.4.1.2 UL Scheduling for UEs with Aperiodic CQI Reporting. 11. Schedules UEs that have been paired for UL MU-MIMO. For details, see MIMO Feature Parameter Description. 12. Selects UEs to be configured with UL CoMP from the ones that have been scheduled. For details, see UL CoMP Feature Parameter Description. 5.2 UL Scheduling Triggering The procedure for triggering UL scheduling is as follows: 1. Before transmitting data, a UE sends the eNodeB a scheduling request (SR) using the scheduling request indicator (SRI) on the PUCCH to request UL resources for data transmission. 2. Upon receiving the SR, the eNodeB responds to the SR and schedules the UE. (This type of UE is referred to as an SR UE.) 3. The SR UE uses the UL resources allocated by the eNodeB to transmit MAC protocol data units (PDUs), including the buffer status report (BSR). 4. If the BSR received at the eNodeB indicates a data size greater than zero, the eNodeB continues scheduling the SR UE and data transmission on the SR UE proceeds. To guarantee the scheduling priority of voice services for voice and data combined services, set the CellUlSchAlgo.UlDelaySchStrategy parameter to VOIP_AND_DATA_DELAYSCH. For details, see VoLTE Feature Parameter Description. The UlEnhancedSrSchSwitch option of the CellAlgoSwitch.UlSchSwitch parameter specifies whether to enable UL SR-based scheduling optimization. • When the UlEnhancedSrSchSwitch option is deselected, ◾ If the maximum number of retransmission attempts is reached but the SR UE still fails to transmit data, the BSR fails to be sent and scheduling fails to start on the SR UE. In this situation, the eNodeB attempts to schedule the SR UE again and performs the attempt twice. This process is referred to as re-scheduling for SR UEs. ◾ If the eNodeB falsely detects an SR from an SR UE in the dormant state of DRX mode, the eNodeB will schedule the SR UE three consecutive times and associated data transmissions will all fail when the maximum number of retransmissions is reached. In this situation, the BLER increases. • When the UlEnhancedSrSchSwitch option is selected, The eNodeB determines whether to stop re-scheduling an SR UE based on the PUSCH DTX detection result. ◾ If the PUSCH DTX state is detected in initial transmission from an SR UE, the eNodeB stops re-scheduling the SR UE. ◾ If the PUSCH DTX state is not detected in initial transmission from an SR UE, the eNodeB continues re-scheduling the SR UE. ◾ Re-scheduling of SR UEs in DRX mode is performed only when the On Duration Timer is running. This reduces the impact of false SR detections in sleep time on the BLER. The amount of data to be scheduled in SR-based scheduling is determined by related parameters as follows: • If the CellUlschAlgo.UlSrSchDataVolAdptOptUpThd parameter is set to a non-zero value, it takes effect only if the cell is not established on LBBPc and the eNodeB determines the amount as follows: ◾ If the value of the CellUlschAlgo.UlSrSchDataVolAdptOptUpThd parameter is greater than the value of the CellUlschAlgo.UlSrSchDateLen parameter, the amount is calculated based on the amount of data scheduled during the last SR-based scheduling and falls into the range of [CellUlschAlgo.UlSrSchDateLen,CellUlschAlgo.UlSrSchDataVolAdptOptUpThd]. ◾ If the value of the CellUlschAlgo.UlSrSchDataVolAdptOptUpThd parameter is less than or equal to the value of the CellUlschAlgo.UlSrSchDateLen parameter, the eNodeB uses the CellUlschAlgo.UlSrSchDateLen parameter value as the amount. • If the CellUlschAlgo.UlSrSchDataVolAdptOptUpThd parameter is set to 0, the amount is controlled by the SrSchDataAdptSw option of the CellAlgoSwitch.UlSchSwitch parameter and the eNodeB determines the amount as follows: ◾ If the SrSchDataAdptSw option is deselected, the eNodeB uses the CellUlschAlgo.UlSrSchDateLen parameter value as the specific amount of data. ◾ If the SrSchDataAdptSw option is selected, the eNodeB uses the CellUlschAlgo.UlSrSchDateLen parameter value as the minimum amount of data. The eNodeB adaptively determines the final amount of data based on the previous amount of data scheduled during the last SR-based scheduling. If the previous amount of data is greater than 700 bits, the amount can be used to calculate the amount of data to be scheduled in the current SR-based scheduling. The maximum amount of data to be scheduled in SR-based scheduling is always 16,550 bits. 5.3 UL Scheduling for Retransmissions 5.3.1 Overview This section describes the basic feature LBFD-002006 UL Synchronous HARQ. Synchronous HARQ is a basic feature for UL scheduling. An eNodeB sends HARQ feedback to the initial transmission four TTIs after delivering a UL grant for the initial transmission to a UE and then determines whether the UE needs to perform a retransmission. 5.3.2 Retransmission Mode Huawei eNodeBs support UL synchronous non-adaptive HARQ and synchronous adaptive HARQ. UL Synchronous Non-Adaptive HARQ In synchronous non-adaptive HARQ, the RB positions and MCS for retransmissions are identical to those for the initial transmission. If the RB positions conflict with the positions of physical random access channel (PRACH) and PUCCH resources, the retransmission is suspended, affecting UL throughput. UL Synchronous Adaptive HARQ In synchronous adaptive HARQ, if data to be retransmitted is allocated resources that conflict with other UL resources, the eNodeB adaptively adjusts the number of RBs, their positions, and the MCS for retransmission. In this way, UL resources are scheduled in a timely manner to reduce UL transmission delay and increase UL throughput. Automatic Switching Between UL Synchronous Adaptive HARQ and Synchronous Non-Adaptive HARQ Huawei eNodeBs also support automatic switching between the adaptive and non-adaptive modes. Operators can specify the retransmission mode by setting the CellUlschAlgo.AdaptHarqSwitch parameter. The automatic switching between the two modes is used by default. Figure 5-2 shows the principle of automatic switching between UL synchronous adaptive HARQ and synchronous non-adaptive HARQ. Figure 5-2 Automatic switching between the retransmission modes for UL scheduling As defined in 3GPP TS 36.213, the MCS for UL synchronous adaptive HARQ remains unchanged for initial transmissions and retransmissions. MCSs with indexes 29 to 31 are used, corresponding to different redundancy versions. 5.3.3 Retransmission Upon Detection of PUSCH DTX When the PuschDtxSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is selected, the result of PUSCH data reception on the eNodeB can be ACK, NACK, or DTX. • If the result is ACK, the transmission for the packet ends. • If the result is NACK, the UE retransmits the packet. • If the result is DTX, the scheduling policy for the HARQ process is determined by the CellUlSchAlgo.PuschDtxSchStrategy parameter. ◾ If this parameter is set to NEW_TX, retransmission of the packet is stopped and the eNodeB sends UL initial-transmission scheduling information to the UE over the PDCCH. ◾ If this parameter is set to ADAPTIVE_RETX, the eNodeB uses an adaptive HARQ retransmission for the UE. That is, the eNodeB sends the same UL scheduling information to the UE over the PDCCH as that in the initial transmission, including the indicated MCS and number of RBs. If DRX has been activated, the adaptive HARQ retransmission is scheduled only when the On Duration Timer specified by the DrxParaGroup.onDurationTimer parameter is running. ◾ If this parameter is set to EN_ADAPTIVE_RETX and DRX has not been activated, the scheduling policy is the same as that when the parameter is set to ADAPTIVE_RETX. However, if DRX has been activated, the adaptive HARQ retransmission is scheduled only during the active time of the UE. All the preceding policies reduce the number of invalid uplink retransmissions due to missing PDCCH detection by the UE. NOTE: When the LBBPc board is configured and the SRSCfg.SrsCfgInd parameter is set to BOOLEAN_FALSE(False), PUSCH DTX detection is not supported. When the LBBPc board is configured and four or eight receive antennas are used, PUSCH DTX detection is not supported. When the LBBPc board is configured, PUSCH DTX detection is not supported for UEs in the MU-MIMO state. If SRSCfg.SrsCfgInd is set to BOOLEAN_FALSE(False) on the BTS3202E, PUSCH DTX detection is not supported. 5.3.4 Maximum Number of UL HARQ Retransmissions The maximum number of UL HARQ retransmissions is specified by the CellUlschAlgo.UlHarqMaxTxNum parameter. • If this parameter is set to a small value, HARQ retransmissions consume few radio resources but radio link reliability decreases. • If this parameter is set to a large value, radio link reliability increases but HARQ retransmissions consume a lot of radio resources. ◾ When this parameter is set to 7, Set both RlcPdcpParaGroup.EnodeBAmReorderingTimer and RlcPdcpParaGroup.EnodeBUmReorderingTimer to 50 ms or larger. ◾ When this parameter is set to 8, Set both RlcPdcpParaGroup.EnodeBAmReorderingTimer and RlcPdcpParaGroup.EnodeBUmReorderingTimer to 60 ms or larger. NOTE: The value of the t-Reordering timer is 40 ms by default, whether the RLC entity works in acknowledged mode (AM) or unacknowledged mode (UM). If the maximum number of retransmissions is set to 7 or 8, the t-Reordering timer with the default value cannot cover the whole retransmission period, which results in the following: • In AM, the transmitter initiates invalid HARQ retransmissions and the receiver triggers repeated status reports, wasting resources. • In UM, the transmitter initiates invalid HARQ retransmissions and discards a large number of packets. 5.3.5 Resource Allocation for HARQ Retransmissions If consecutive demodulation failures occur in the HARQ retransmission process, the last two HARQ retransmissions can use a reduced code rate when the cell serves less than 150 RRC_CONNECTED UEs and idle RBs are available. The TBS in HARQ retransmissions is the same as the TBS in initial transmissions. Therefore, more RBs are allocated for HARQ retransmissions, which can reduce UL throughput. The UlLast2RetransSchOptSwitch option of the CellAlgoSwitch.UlSchSwitch parameter specifies whether UL HARQ retransmissions use a reduced code rate. • When this option is selected, the (ULHARQMAXTXNUM-1)th and ULHARQMAXTXNUMth HARQ retransmissions use a reduced code rate to increase the gains of combining in HARQ retransmissions and decrease the UL RBLER and service drop rate. NOTE: ULHARQMAXTXNUM indicates the maximum number of consecutive HARQ retransmissions and is specified by the CellUlschAlgo.UlHarqMaxTxNum parameter. • When this option is deselected, HARQ retransmissions do not use a reduced code rate. In adaptive HARQ retransmissions for voice services, the MCS selection policy for voice services is specified by the UlVoipRblerControlSwitch option of the CellUlSchAlgo.UlEnhencedVoipSchSw parameter. • When this option is selected, the scheduler selects MCSs with smaller indexes for voice services than for data services. As a result, the RBLER and packet loss rate of voice services are lower than those of data services. • When this option is deselected, the scheduler adopts the same policy to select the MCSs for voice and data services. If the UlLast2RetransSchOptSwitch and UlVoipRblerControlSwitch options are both selected, the eNodeB increases the number of RBs for scheduling and reduces the code rate for voice services in the last two HARQ retransmissions, and increases the number of RBs for scheduling in the event of conflicts between retransmissions and measurement gaps. 5.4 UL Scheduling for Initial Transmissions UL dynamic scheduling for initial transmission performs the following operations: • Selects UEs for UL scheduling. • Obtains scheduling resources. • Determines the MCSs to be used. • Determines the number of RBs to be allocated and their positions. 5.4.1 Selecting UEs for UL Scheduling Huawei eNodeB supports four scheduling policies (Max C/I, RR, PF, and EPF) for UL scheduling. These policies are identical to those for DL scheduling. For details, see 4.2 DL Dynamic Scheduling. The only difference is the input for indicating the channel quality, which is SINR for the UL and CQI for the DL. QoS guarantee provided by EPF also depends on the LBFD-070102 MBR>GBR Configuration feature. For details, see 6.1 UL QoS Management. The following functions can be used in the policies used in selecting UEs for UL scheduling: • 5.4.1.1 PDCCH and PUSCH Resource Balancing • 5.4.1.2 UL Scheduling for UEs with Aperiodic CQI Reporting • 5.4.1.3 Proactive Scheduling for Uplink Signaling • 5.4.1.4 Scheduling Termination for Abnormal UEs 5.4.1.1 PDCCH and PUSCH Resource Balancing When a cell serves a large number of UEs in RRC_CONNECTED mode with a high proportion of cell edge users or users having small-packet data transmission, the number of UEs for UL scheduling per TTI is limited and UL throughput/PUSCH resource utilization is reduced if PDCCH resources are insufficient. In this situation, PDCCH and PUSCH resource balancing is recommended. This function works as follows: The scheduler randomly selects a UE with large-packet data transmission at the cell center and reserves PDCCH resources for the UE. The scheduler ensures that the selected UE can be scheduled, improving uplink RB utilization and throughput. This function involves the following parameters: • CellUlschAlgo.DataThdInPdcchPuschBal This parameter specifies the data volume threshold that defines a UE with large-packet data transmission. • CellUlschAlgo.UeNumThdInPdcchPuschBal This parameter specifies the threshold, which is the number of UEs served by a cell, for enabling this function. Note the following when using this function in various scenarios: • In RAN sharing scenarios, this function is not recommended because there is a probability that the operator-specific resource occupation ratio is not strictly applied due to random selection of the UE with large-packet data transmission. • It is good practice to select the SchedulerCtrlPowerSwitch option of the CellAlgoSwitch.UlSchSwitch parameter when using this function, thereby preventing UEs with large-packet data transmission from occupying too many resources. 5.4.1.2 UL Scheduling for UEs with Aperiodic CQI Reporting The eNodeB schedules UEs with aperiodic CQI reporting. For details about the triggering of aperiodic CQI reporting, see Channel State Management Feature Parameter Description. Specifically, if the UE has data to be scheduled for uplink initial transmission when reporting aperiodic CQIs, the eNodeB schedules the UE in associated aperiodic CQI mode; if the UE has no data to be scheduled for uplink initial transmission when reporting aperiodic CQIs, the eNodeB schedules the UE in CQI-only mode. The CQI-only mode increases UL overhead and UL interference. To minimize these adverse impacts, set the CellUlschAlgo.AperiodicCsiUlTxMode parameter to specify the UL transmission mode of aperiodic CQIs. • When this parameter is set to CsiOnly, For a UE that has only DL aperiodic CQIs to be transmitted, the eNodeB immediately schedules the UE on the PUSCH for the transmission of CQIs indicating DL channel quality. • When this parameter is set to CsiWiUlService, For a UE that has only DL aperiodic CQIs to be transmitted, the eNodeB does not allow only CQIs to be transmitted on the PUSCH but allows CQIs and UL service data to be simultaneously scheduled and transmitted on the PUSCH within a specified time after aperiodic CQI reporting is triggered. This scheme reduces the number of times of aperiodic CQI reporting in CQI-only mode and decreases UL interference. However, reporting of aperiodic CQIs together with UL service data is not so prompt as when the CellUlschAlgo.AperiodicCsiUlTxMode parameter is set to CsiOnly, and therefore the DL IBLER slightly increases if UL data services of the UE are sparse. 5.4.1.3 Proactive Scheduling for Uplink Signaling After an eNodeB sends a UE an RRC configuration message that requires a response message from the UE, the UE cannot send a response message if the eNodeB fails to receive the scheduling request from the UE. Consequently, the RRC configuration fails and an RRC connection reestablishment is triggered. In a worse situation, issues such as E-RAB setup failure and service drop may occur. eNodeBs prevent RRC configuration failures, caused by UEs' failure to respond, by allowing proactive scheduling for uplink signaling. The proactive scheduling function is controlled by the SrbProbeSchSwitch(SrbProbeSchSwitch) option of the CellAlgoSwitch.UlSchExtSwitch parameter. When the option is selected, the eNodeB proactively schedules the UE if the eNodeB does not receive a scheduling request from the UE within 300 ms of delivering the RRC configuration message. The proactive scheduling ensures that the UE can transmit a response message to the eNodeB, improving network stability. 5.4.1.4 Scheduling Termination for Abnormal UEs This function prevents overuse of system resources by UEs in weak coverage areas or without a radio connection to the E-UTRAN. In addition, this function reduces the residual BLER in the system. When the AbnUeSchSwitch option of the CellAlgoSwitch.CellSchStrategySwitch parameter is selected, the UL scheduler determines whether the UE link is abnormal based on UL demodulation performance. Specifically, if the number of successive times that the UL CRC for a UE fails exceeds the value of CellUlschAlgo.UlSchAbnUeThd, the UL scheduler determines that demodulation performance is poor and the UE link is abnormal. In this situation, the eNodeB clears the data buffered for the UE to stop UL scheduling for the UE. The eNodeB attempts to schedule the UE if it receives two consecutive SRs from the UE. If the CRC for the UE succeeds, the UL scheduler clears the abnormal state of the UE link and the UE can be scheduled normally. If the CRC fails, the UE link continues to be in the abnormal state. 5.4.2 UL Scheduling Resource Acquisition One of the basic functions of UL scheduling is to obtain physical uplink shared channel (PUSCH) resources. 5.4.2.1 PUSCH Resources The PUSCH, PUCCH, and PRACH share the UL bandwidth resources. Available PUSCH resources vary with scenarios: • If a cell serves more than one UE, the amount of available PUSCH resources is equal to the amount of UL resources across the entire channel bandwidth minus the amount of resources occupied by the PUCCH and PRACH. • If the PuschUsePucchRbSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is selected and the cell serves only one UE, the amount of available PUSCH resources is equal to the amount of UL resources across the entire channel bandwidth minus the amount of resources occupied by the PRACH. That is, the PUSCH is allowed to occupy the PUCCH RBs. The following are additional descriptions of UL bandwidth sharing among the PUSCH, PUCCH, and PRACH: • The PUCCH occupies RBs at two ends of a cell bandwidth, and the number of RBs is dependent on the amount of resources used to carry information on the PUCCH. The information includes HARQ feedback to DL dynamic scheduling, CQIs indicating DL channel quality, the number of UEs in semi-persistent scheduling mode, and scheduling request indicators (SRIs). For details about the PUCCH, see Physical Channel Resource Management Feature Parameter Description. • The PRACH periodically occupies six RBs in the uplink at an interval specified by a related parameter. • According to section 5.3.3 in 3GPP TS 36.211 V10.0.0 (2011-03), continuous UL resources are allocated and the number of allocated RBs is , , and , where are not minus integers. • In PUSCH resource allocation, the eNodeB dynamically determines whether to perform frequency selective scheduling or frequency non-selective scheduling on UEs based on the number of UEs in a cell, RB usage, and CPU usage. 5.4.2.2 Frequency Selective Scheduling Principles Frequency selective scheduling is performed based on channel quality or interference. Figure 5-3 shows how an eNodeB determines to perform channel-quality- or interferencebased frequency selective scheduling. Figure 5-3 Selection of the frequency selective scheduling type • Channel-quality-based frequency selective scheduling The eNodeB selects the most suitable frequency resources for each UE based on the channel quality differences between subbands. Figure 5-4 shows how resources are allocated in UL frequency selective scheduling. The eNodeB determines the sliding window size based on the number of RBs required by each UE and selects available resources that are expected to produce the largest gains. Figure 5-4 Resource allocation in UL frequency selective scheduling After the sliding window size is set, the scheduler checks the setting of UlFssWindSearchDirRandSw under the CellAlgoSwitch.UlSchExtSwitch parameter to determine the resource search direction for the sliding window. ◾ If the UlFssWindSearchDirRandSw option is deselected, the direction used starts from the low- to the high-frequency end of the spectrum. ◾ If the UlFssWindSearchDirRandSw option is selected, the direction varies as follows: ◾ The direction used starts from the high- to the low-frequency end for cells whose PCI modulo 2 is 0. ◾ The direction used starts from the low- to the high-frequency end for cells whose PCI modulo 2 is 1. • Interference-based frequency selective scheduling Interference-based frequency selective scheduling considers the interference differences between subbands. The eNodeB determines the sliding window size based on the number of RBs required by each UE and selects available resources that experience minimum interference. Only the UEs whose UL SINR is lower than the CellUlSchAlgo.UlInBasedFssSinrThld parameter value are selected for interference-based frequency selective scheduling. NOTE: Operators are advised to retain the default value for the CellUlSchAlgo.UlInBasedFssSinrThld parameter. Modifications to the parameter value are not recommended. To improve the UL performance of low-speed UEs in cells established on BBPs other than LBBPc, select the UlEnhancedDopplerSwitch option of the CellAlgoSwitch.UlSchSwitch parameter for these cells. When the UlEnhancedDopplerSwitch option is selected, the eNodeB determines whether UEs are moving at low speeds based on Doppler measurements. For UEs moving at low speeds, the eNodeB uses comparatively more suitable SINR filtering coefficients and MCSs in frequency selective scheduling, increasing spectral efficiency and throughput of the UEs. NOTE: Channel quality or interference measurement, which frequency selective scheduling is dependent on, is based on DMRS or SRS symbols. When data symbols and DMRS or SRS symbols differ greatly in the interference they experience (typically inter-system interference), frequency selective scheduling may fail to select the optimal RBs, affecting network performance. Start and Stop Although frequency selective scheduling can track channel quality fluctuations or interference to produce gains, it also produces frequency band fragments, causing insufficient RB utilization. The implementation of frequency selective scheduling is complex and involves high overheads. To reduce the negative impacts, the eNodeB checks the number of synchronized UEs in its served cell within each TTI and starts or stops UL frequency selective scheduling accordingly. Figure 5-5 shows how a macro eNodeB determines whether to use frequency selective scheduling. Figure 5-5 Procedure for determining whether to use frequency selective scheduling The following table provides additional information about the marked steps in the procedure. Mark Additional Information a For details about how a specific type of frequency selective scheduling is determined, see Figure 5-3. The eNodeB implements frequency selective scheduling as described in Principles. b If the number of UEs for which frequency selective scheduling is used has exceeded a specified threshold, resource allocation based on interference randomization is used. For details about interference randomization, see ICIC Feature Parameter Description. c If the number of UEs for which frequency selective scheduling is used has exceeded a specified threshold, non-frequency-selective scheduling is used. RB resources are sequentially allocated to UEs from the high-frequency end to the low-frequency end. A micro eNodeB determines whether to use UL frequency selective scheduling as follows: • If the UlEnhancedFssSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is deselected: ◾ The micro eNodeB disables UL frequency selective scheduling in the cells that each serve more than 15 synchronized UEs. The micro eNodeB then performs interference-randomization-based scheduling or non-frequency-selective scheduling as a macro eNodeB does at points "b" and "c" indicated in Figure 5-5. ◾ The micro eNodeB performs UL frequency selective scheduling as described in Principles in the cells that each serve less than 15 synchronized UEs. • If the UlEnhancedFssSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is selected, the micro eNodeB performs UL frequency selective scheduling as described in Principles, regardless of the number of synchronized UEs in a cell. 5.4.2.3 Determining the Number of RBs for UL Scheduling The UL scheduler determines the number of RBs required by a UE in the current TTI based on: • Buffer status reported by the UE • Token bucket status for QoS assurance • Power headroom status • Setting of CellUlschAlgo.MaxUlSchRbNum • Maximum number of RBs supported by a single carrier The eNodeB determines the positions of RBs to be allocated based on factors such as the UL SINR measured by the eNodeB and system resource usage. 5.4.2.3.1 Scheduler-controlled Power The power control module of an eNodeB sets a target value for convergence of the power spectrum density (PSD) for each UE to maintain the maximum number of allocatable RBs under the PSD. This maximum number of allocatable RBs is called the number of power-limited RBs. The SchedulerCtrlPowerSwitch option of the CellAlgoSwitch.UlSchSwitch parameter determines whether the number of RBs allocated by the scheduler can be greater than the number of power-limited RBs. • If the SchedulerCtrlPowerSwitch option is deselected, the number of RBs allocated by the scheduler cannot be greater than the number of power-limited RBs. The PSD maintains at the level limited by power control. • If the SchedulerCtrlPowerSwitch option is selected, the number of RBs allocated by the scheduler can be greater than the number of power-limited RBs. In this situation: ◾ If the number of RBs allocated to a UE exceeds the number of power-limited RBs, the PSD for the UE's data transmission is lower than the power-controllimited PSD because of the maximum UE transmit power restriction. The low PSD results in a decreased SINR. However, the scheduler maintains the actual SINR to a level that will not decrease the UE throughput. ◾ If the UL_RBCALC_OPT_SWITCH option of the eNodeBAlgoSwitch.UlResManageOptSw parameter is deselected, the scheduler maintains the SINR at a level not lower than –1 dB whenever possible. ◾ If the UL_RBCALC_OPT_SWITCH option of the eNodeBAlgoSwitch.UlResManageOptSw parameter is selected, the scheduler optimizes RB quantity calculation in case of power insufficiency. The calculation is based on channel quality fluctuation, and the lower limit of the SINR varies with channel quality. The variable lower limit of the SNIR helps increase UL UE throughput. ◾ A UE's PSD varies rapidly with time, causing the SINR to change rapidly too. As a result, the number of RBs calculated based on the buffer status is inaccurate for MBB services. Some RBs are wasted, affecting the system capacity if the uplink load is heavy. To prevent inaccurate RB number calculation, select the UlDataFitterRbCalcSwitch option of the CellAlgoSwitch.UlSchExtSwitch parameter. When this option is selected, the scheduler determines an accurate number of to-be-allocated RBs based on the UE buffer status, channel quality for the UE, normalized UE power margin, and receiver demodulation performance. This calculation method meets the transmission data volume requirement, saves RBs, and increases the system capacity. ◾ The scheduler selects four to-be-scheduled UEs of the highest priority and estimates the required amount of resources to ensure that at least four UEs can fully exploit the available PUSCH RBs and thereby to increase the throughput of multiple UEs. When the UlSchCtrlPwrUserSetOptSw option of the CellAlgoSwitch.UlSchExtSwitch parameter is selected, the selection range includes only the UEs that either have no resources preallocated to them or have been preallocated resources only for voice services. The scheduler does not select UEs that have been preallocated resources for non-voice services, preventing such UEs from preempting resources of higher-priority UEs. 5.4.2.3.2 Optimization of UL RLC Segment Reduction The RLC header and MAC header are added to the data packets transmitted at the RLC layer on the UE side. When estimating the data volume to be scheduled for a UE, the scheduler determines the overheads of the RLC header and MAC header based on the value of the CellUlschAlgo.HeadOverheadForUlSch parameter. With the same MCS, the spectral efficiency achieved when a small number of RBs are allocated is lower than that achieved when a large number of RBs are allocated. When the UlSmallRBSpectralEffOptSw option of the CellAlgoSwitch.UlSchSwitch parameter is selected, the scheduler changes the small number of RBs to be allocated, ensuring that the TBS can meet the requirements of data transmission as much as possible. The preceding two measures reduce the number of UL RLC segments, lowering the service transmission delay and PDCCH overheads. 5.4.3 Determining MCSs for UL Scheduling 5.4.3.1 Overview The SINR of a UE reflects the uplink channel quality of the UE. eNodeBs select MCSs for UL scheduling based on SINRs. The process of determining MCSs for UL scheduling consists of three parts: SINR adjustment, initial MCS selection, and MCS adjustment, as shown in Figure 5-6. Figure 5-6 Process of determining MCSs for UL scheduling 5.4.3.2 SINR Adjustment The SINR at the measurement time changes significantly compared with that at the scheduling time for a moving UE. This is due to the impact of channel fading on a moving UE's signals. If the SINR cannot indicate the channel quality at the scheduling time, the IBLER does not approach the target IBLER. Therefore, an eNodeB needs to determine the deviation of the measured SINR from the actual channel quality based on HARQ-ACKs and HARQ-NACKs to uplink data and adjusts the SINR accordingly. SINR adjustment is enabled when the SinrAdjustSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is selected. The CellUlschAlgo.SinrAdjustTargetIbler parameter specifies the target IBLER. SINR adjustment is similar to DL CQI adjustment. For details, see 4.1 DL CQI Adjustment. 5.4.3.2.1 Target IBLER Adaptation On live networks, the requirements for IBLER vary with scenarios and UE locations. Therefore, target IBLER adaptation is required. The UlIblerAdjustSwitch option of the CellAlgoSwitch.UlSchSwitch parameter determines whether to enable UL target IBLER adaptation. • When the UlIblerAdjustSwitch option is deselected, UL target IBLER adaptation is disabled. The UL target IBLER is specified by the CellUlschAlgo.SinrAdjustTargetIbler parameter. The default value is 10%. • When the UlIblerAdjustSwitch option is selected, the UL target IBLER adapts according to the rules listed in Table 5-1. Table 5-1 Target IBLER adaptation rules If... Then... If... Then... The SinrFlunIBlerAdaptSwitch option of the CellUlschAlgo.UlTargetIBlerAdaptType parameter is selected The target IBLER value is 1%, 5%, 10%, or 30% adaptively, depending on the UE's distance to the eNodeB and the channel quality fluctuation, which is reflected by the SINR of the UE. • If the SINR fluctuation is significant or the UE is far away from the eNodeB, a large target IBLER value will be used. • If the UE is close to the eNodeB and the SINR is stable, a small target IBLER value will be used. The SinrJumpIBlerAdaptSwitch option of the CellUlschAlgo.UlTargetIBlerAdaptType parameter is selected In the event of a sudden and transient SINR change (for 1 to 3 TTIs), the target IBLER value is: • 100% if the SINR change is greater than an upper threshold • 50% if the SINR change is greater than a lower threshold but less than the upper threshold The CellUlschAlgo.UlIBlerAdaptBigTrafficSw parameter is set to ON If UL large-packet data transmission lasts for more than 1s on only one UE in the cell, the target IBLER adaptation function takes effect only for this UE. NOTE: UL target IBLER adaptation does not take effect for UEs running services with QCI 1. 5.4.3.2.2 PAMC-based SINR Adjustment PAMC uses AMC to maximize UL perceived throughput. It is controlled by the UlPAMCSwitch(UlPAMCSwitch) option of the CellAlgoSwitch.UlSchExtSwitch parameter. This function introduces a cell-level SINR adjustment value, based on which each UE that has just accessed a network can now obtain a more accurate initial UE-level SINR adjustment value for subsequent initial MCS selection. These UEs used to use a fixed initial SINR adjustment value, and therefore the adjusted SINR could not promptly approach the expected value when the UEs are scheduled infrequently because of low traffic volume. This slow change in the adjusted SINR causes failure to accurately indicate UL channel quality, affecting UL UE throughput. Figure 5-7 shows the process of PAMC. Figure 5-7 Process of PAMC NOTE: • PAMC does not work with LBBPc boards. • PAMC cannot be used with UEs that use any of the following: TTI bundling, VoLTE, single-user MIMO (SU-MIMO), and push to talk (PTT). • PAMC does not take effect in cells whose Cell.UlCyclicPrefix is set to EXTENDED_CP(Extended). 5.4.3.2.3 SINR Adjustment Upon Detection of PUSCH DTX When the PuschDtxSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is selected, the result of PUSCH data reception on the eNodeB can be ACK, NACK, or DTX. If the result is DTX, the eNodeB does not perform UL SINR adjustment. NOTE: When LBBPc boards are used, the implementation of PUSCH DTX has restrictions. For details, see 5.3.3 Retransmission Upon Detection of PUSCH DTX. 5.4.3.2.4 SRI Detection There is a low probability that an eNodeB and a UE will stay in different DRX states because of false SRI detection when there is no UL data being transmitted. The BLER increases both in the UL and DL. When there is UL data transmission, the BLER is not affected. To minimize the probability of false SRI detection, operators are advised to set the CellUlschAlgo.SriFalseDetThdSwitch parameter to ON. The probability of false SRI detection, which may rise because of inaccurate measurements of interference and noise on the PUCCH, can also be lowered by selecting the SriDetectEnhanceSW(SriDetectEnhanceSW) option of the CellPucchAlgo.SriAlgoSwitch parameter. Note that LBBPc boards do not support this function. 5.4.3.3 Initial MCS Selection On each scheduling occasion, an MCS is selected initially and then adjusted. The selection is based on the measured SINR of the UE-occupied bandwidth and the eNodeB demodulation performance. If the UlPAMCSwitch option of the CellAlgoSwitch.UlSchExtSwitch parameter is selected, initial MCS selection considers not only the adjusted SINR, but also the number of allocated PRBs and SINR fluctuation. This improves the MCS selection accuracy. Figure 5-8 shows the process of PAMC. Figure 5-8 Process of PAMC NOTE: For UEs that have accessed a cell before PAMC is enabled in this cell, PAMC take effects on initial MCS selection for these UEs only after they re-access the cell. To ensure the initial access performance, Huawei eNodeBs use a fixed small-index MCS for Msg3 transmission during UE access. 5.4.3.4 MCS Adjustment After the initial MCS selection, the eNodeB can adjust the MCS based on the cell-specific SRS subframe configuration, UL control information on the PUSCH, and UE capabilities, as shown in Figure 5-6. The adjustment procedure is as follows: 1. If cell-specific SRS or UL control information needs to be transmitted when RBs are scheduled for UL data transmission of a UE, the eNodeB needs to adjust the MCS. The symbols in which cell-specific SRS is transmitted are unavailable for PUSCH transmission and the UL control information transmission on the PUSCH reduces the resources for data transmission, resulting in a higher PUSCH coding rate and accordingly a higher IBLER for initial data transmission. The MCS must be adjusted accordingly to ensure that the scheduled data is correctly demodulated. UL control information transmitted on the PUSCH includes ACKs, RIs, and CQIs. An MCS for UL control information is selected based on the result of the MCS used for data transmission minus an index offset. A higher index offset indicates a higher transmission reliability for UL control information, but more resources are used by the UL control information. If the UL control information has a high bit error rate (BER) in adverse radio conditions, higher index offsets can be specified as follows: • If the CellUciOnPuschPara.CellUciOnPuschParaValid parameter is set to TRUE, the index offsets for ACKs, RIs, and CQIs are specified by the cell-level parameters CellUciOnPuschPara.DeltaOffsetAckIndex, CellUciOnPuschPara.DeltaOffsetRiIndex, and CellUciOnPuschPara.DeltaOffsetCqiIndex, respectively. • If the CellUciOnPuschPara.CellUciOnPuschParaValid parameter is set to FALSE, the index offsets for ACKs, RIs, and CQIs are specified by the eNodeBlevel parameters PuschParam.DeltaOffsetAckIndex, PuschParam.DeltaOffsetRiIndex, and PuschParam.DeltaOffsetCqiIndex, respectively. NOTE: These eNodeB-level parameters will be removed in later versions. You are advised to use the cell-level parameters for more flexible MCS adjustment. 2. UE capabilities must also be considered because the highest-order MCS supported may vary for different UEs. 5.5 UL Multi-Cluster The UL Multi-Cluster function is introduced to address the low UL PRB resource efficiency when there are multiple non-contiguous PRB segments as a result of multi-UE scheduling but these segments cannot be allocated to a single UE. This allocation failure is due to the previous restriction that the UL PRBs allocated to a single UE must be contiguous. UL Multi-Cluster has been introduced to 3GPP TS 36.213 since Release 10. This function is enabled when the UlMultiClusterSwitch option of the CellAlgoSwitch.UlSchExtSwitch parameter is selected. With this function, the UL scheduler can allocate a maximum of two non-contiguous PRB clusters to a single UE. Each cluster consists of an integer multiple of RBGs that are contiguous. This type of resource allocation takes effect when all the allowing conditions are met: • The UE is capable of UL Multi-Cluster. • The maximum number of contiguous idle PRBs in the UL band does not meet the UE requirements. • There is sufficient power headroom at the UE. This requirement is set to prevent the impact of maximum power reduction (MPR) on the UE transmit power. The UL Multi-Cluster function fully utilizes UL frequency spectrum fragments to increase UL PRB usage and therefore the UL peak throughput of UEs. This function is recommended when there are UL frequency spectrum fragments, for example, in the case of PUCCH Flexible Configuration and manual blocking of certain PRBs. It is not recommended when UL interference is distributed in an extremely unbalanced manner and there are large UL interference differences between separate idle PRB segments. NOTE: • A UE is considered to be capable of UL Multi-Cluster if both the multiClusterPUSCH-WithinCC-r10 and nonContiguousUL-RA-WithinCC-Info-r10 IEs are "supported" in the UE capability message transmitted during initial access. • Only macro and LampSite eNodeBs equipped with UBBPe boards support the UL Multi-Cluster function. 5.6 Manual Blocking of PUSCH RBs If certain PUSCH RBs experience strong interference from a definite external source or are unavailable because of spectrum planning, these RBs can be manually blocked so that the eNodeB will not use them during UL scheduling. The parameters in the CellRbReserve MO determine the RB blocking mode and the locations and quantity of these RBs. This RB blocking function does not take effect on control channels or common channels. It is recommended that the blocked PUSCH RBs do not overlap PUCCH or PRACH RBs. If the CellRbReserve.RbRsvMode parameter is set to RB_MASKING_WITH_SRS(RB_MASKING_WITH_SRS), this RB blocking function is incompatible with UL frequency hopping. In addition, this function causes a decrease in the amount of available SRS resources, affecting UL link adaptation and frequency-selective scheduling performance. This function does not work with eMTC or UL coordinated resource allocation (CRA). 6 UL Enhanced Scheduling As an enhancement to UL basic scheduling, UL enhanced scheduling selects a high-order MCS when the UL channel quality is high to increase the UL capacity, transmits the same data block over consecutive N subframes to increase the UL coverage and satisfy the QoS requirements for UL services. 6.1 UL QoS Management A Huawei scheduler meets the end-to-end QoS requirements. Unlike DL QoS, UL QoS is ensured by using related parameters sent from the eNodeB to UEs. The eNodeB can obtain accurate information about the data volumes of DL services and perform DL scheduling based on the data volumes and service priorities. However, the eNodeB cannot obtain accurate information about the data volumes of UL services. Therefore, the eNodeB performs UL scheduling based on the scheduling priority, data volumes, and service priorities of each UE. Because of this scheduling difference, the UL QoS requirements are differentiated for different services of each UE. 6.1.1 Service Rate Control on the eNodeB This section describes the following features: • LBFD-00101502 Dynamic Scheduling • LBFD-070102 MBR>GBR Configuration There are two types of service bearers: • GBR bearers ◾ The UL scheduler preferentially guarantees bit rates for GBR services. ◾ With the bit rates of GBR services guaranteed, the UL scheduler schedules GBR and non-GBR services with the same priority and ensures that the bit rate of each GBR service does not exceed the relevant MBR. • Non-GBR bearers ◾ The UL scheduler in the eNodeB applies a best-effort policy to non-GBR services. ◾ The UL scheduler ensures that the total bit rate of non-GBR services on a UE does not exceed the aggregate maximum bit rate (AMBR) for the UE. GBR service priority calculation is dependent on the setting of the UlMbrCtrlSwitch option of the CellAlgoSwitch.UlSchSwitch parameter: • If the UlMbrCtrlSwitch option is deselected, the total bit rate of GBR services does not exceed the sum of GBRs. • If the UlMbrCtrlSwitch option is selected, the total bit rate of GBR services does not exceed the sum of MBRs. A special treatment takes effect on bearers with a QCI of 1: The guaranteed rate and maximum rate of these services are twice the GBR and MBR, respectively. This design aims to guarantee the QoS of low-rate small-packet services. If the UlMinGbrSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is selected, the eNodeB guarantees the QCI-specific minimum GBR (Min-GBR) for non-GBR services, when possible. The Min-GBR is specified by the QciPara.UlMinGbr parameter. The eNodeB controls non-GBR service rates as follows: • When radio resources are sufficient, ◾ If the Min-GBR of non-GBR services is less than or equal to the prioritized bit rate (PBR), the service rate can reach the Min-GBR. ◾ If the Min-GBR of non-GBR services is greater than the PBR, the service rate may not reach the Min-GBR, especially for low-priority non-GBR services. This is because UEs guarantee the PBRs in descending order of logical-channel priorities. • When radio resources are insufficient, GBR services are preferentially scheduled, and the Min-GBR of non-GBR services may not be guaranteed. UL service rate control at the eNodeB adopts the token bucket algorithm. The bucket size is equal to the guaranteed rate for all services. The token injection rate is equal to the service rate. The number of tokens in the bucket indicates whether the service rate meets requirements. After determining whether the service rate meets requirements, the eNodeB calculates the UE scheduling priority by using the following formula: where: • • • indicates the channel quality. indicates the historical number of bits transmitted by the UE per unit of time. indicates the weight of the scheduling priority corresponding to the QCI of the service. A larger weight results in a higher scheduling priority. For details about the weight setting, see QoS Management Feature Parameter Description. • indicates the capacity adjustment factor for EPF. ◾ When the factor is set to 1, the scheduling priority calculation is oriented towards UE fairness in resources. ◾ When the factor is set to a value smaller than 1, the scheduling priority calculation is oriented towards UE fairness in rates. ◾ When the factor is set to a value greater than 1, the scheduling priority calculation is oriented towards capacity. 6.1.2 UE Parameter Configurations for UL QoS PBR According to 3GPP specifications, the PBR must be preferentially ensured on the UL logical channels. This is because of the following reasons: • The PBR prevents the service rate from dropping to zero on low-priority logical channels due to resource congestion. • The PRB ensures that UEs on low-priority logical channels are scheduled even if resource congestion occurs. The value range of the PBR for logical channels is specified in section 6.3.2 in 3GPP TS 36.331 V10.1.0 (2011-03). Table 6-1 lists the PBR configuration principle for GBR services and non-GBR services. Table 6-1 PBR configuration principle Logical Channel Type PBR DCCH (SRB1 and SRB2) infinity QCI 1, QCI 65, QCI 66 16 KB/s QCI 5, QCI 69 8 KB/s QCI 2 to QCI 4 Configurable. The parameter is QciPara.PrioritisedBitRate. QCI 6 to QCI 9 Other QCIs Logical Channel Priority Logical channels carry services for UEs. Differentiation between services with different QCIs is achieved by setting the QciPara.LogicalChannelPriority parameter. Table 6-2 lists the recommended logical channel priorities for services with different QCIs. Table 6-2 Recommended logical channel priorities for services with different QCIs QCI Category QCI Service Type Logical Channel Priority Service Priority Standardized 1 to 4 QCI 5 GBR service 6 to 10 N/A 6 to 9 IMS signaling Non-GBR services N/A 12 and 13 High-priority non-GBR services 14 and 15 Low-priority non-GBR services Setting Notes • A larger logical channel priority value indicates a lower scheduling priority. • To satisfy the QoS requirements of signaling with QCI 5 and GBR services, it is recommended that: ◾ The logical channel priority for signaling with QCI 5 and GBR services be set to a value in the range of 6 to 10. QCI Category QCI Service Type Logical Channel Priority Service Priority 69 PTT control-plane signaling 4 N/A 65 PTT voice service (GBR type) 5 N/A 7 N/A 70 Other PTT services (Non-GBR type) 11 N/A 10 to 64 67 and 68 71 to 254 Non-GBR services 9 and 10 N/A 11 to 13 High-priority non-GBR services 14 to 16 Low-priority non-GBR services 66 Extended QCI Setting Notes ◾ The logical channel priority for non-GBR services be set to a value in the range of 11 to 15. • Non-GBR services excluding non-GBR PTT services can be divided into low-priority non-GBR services and high-priority non-GBR services as follows: ◾ High-priority non-GBR services are those for which the logical channel priority is 11, 12, or 13. ◾ Low-priority non-GBR services are those for which the logical channel priority is 14, 15, or 16. • In this table, LCG_PROFILE_0 is used as an example. Logical Channel Group A UE can report the total amount of buffered data for multiple services with different QCIs, but not for each individual service. This reduces system resource consumption. These services must be mapped to the same logical channel. The eNodeB supports four logical channel groups. The GlobalProcSwitch.LcgProfile parameter specifies logical channel group profiles. The following describes the parameter values and grouping principles: • LCG_PROFILE_0 An eNodeB assigns only one logical channel group to non-GBR services. Table 6-3 Logical channel groups in LCG_PROFILE_0 Category Subdivision Logical Channel Type Logical Channel Group Control-plane signaling RRC control-plane signaling SRB1 and SRB2 0 IMS signaling QCI 5 PTT control-plane signaling QCI 69 PTT voice service QCI 65 VoLTE service QCI 1 PTT voice service QCI 66 Other GBR services QCI 2 to QCI 4 2 Other PTT services QCI 70 3 Other non-GBR services QCI 6 to QCI 9, QCI 10 to QCI 64, QCI 67, QCI 68, and QCI 71 to QCI 254 GBR service Non-GBR services 1 • LCG_PROFILE_1 An eNodeB assigns two logical channel groups to non-GBR services. VoLTE services and PTT services, together with control-plane signaling, are assigned logical channel group 0. You are advised not to configure VoLTE services to ensure the scheduling priority of control-plane signaling. Table 6-4 Logical channel groups in LCG_PROFILE_1 Category Subdivision Logical Channel Type Logical Channel Group Control-plane signaling RRC control-plane signaling SRB1 and SRB2 0 IMS signaling QCI 5 PTT control-plane signaling QCI 69 PTT voice service QCI 65 and QCI 66 VoLTE service QCI 1 Other GBR services QCI 2 to QCI 4 High-priority non-GBR services QCI 6 to QCI 9, QCI 10 to QCI 64, QCI 67, 2 QCI 68, and QCI 70 to QCI 254 3 GBR service data Non-GBR service data Low-priority non-GBR services 1 • LCG_PROFILE_2 An eNodeB assigns two logical channel groups to non-GBR services. PTT voice service data with QCI 66 and VoLTE service data, together with GBR services, are assigned logical channel group 1. If VoLTE services and PTT voice services are configured, you are advised not to configure other GBR services to fulfill the QoS requirements of VoLTE services and PTT services. Table 6-5 Logical channel groups in LCG_PROFILE_2 Category Subdivision Logical Channel Type Logical Channel Group Control-plane signaling RRC control-plane signaling SRB1 and SRB2 0 IMS signaling QCI 5 Category GBR service data Non-GBR service data Subdivision Logical Channel Type PTT control-plane signaling QCI 69 PTT voice service QCI 65 VoLTE service QCI 1 PTT voice service QCI 66 Other GBR services QCI 2 to QCI 4 High-priority non-GBR services QCI 6 to QCI 9, QCI 10 to QCI 64, QCI 67, 2 QCI 68, and QCI 70 to QCI 254 3 Low-priority non-GBR services Logical Channel Group 1 6.1.3 QoS Rate Guarantee for a Multi-Service UE The UL scheduler assembles packets for a UE at the MAC layer and determines the data volume to be transmitted for each service. The MAC entity of the UE knows only the PBR settings for each service but does not know the settings of QCI, GBR, MBR, and AMBR. The UE first assembles packets for the services that do not meet the PBR in descending order of the logical channel priorities, and then assembles packets for all services in descending order of the logical channel priorities. For details, see section 5.4.3 in 3GPP TS 36.321 (2011-03). When processing multiple services, the UE transmits high-priority service data first and then low-priority service data. The low-priority service rate does not exceed the PBR. The UL scheduler does not guarantee or control service-specific rates. It guarantees only the total rate as follows based on the setting of the UlMbrCtrlSwitch option of the CellAlgoSwitch.UlSchSwitch parameter: • When the UE is processing multiple GBR services (no service data on the default bearer), ◾ If the UlMbrCtrlSwitch option is deselected, the UL scheduler allocates air interface resources by using a best-effort policy to ensure that the total rate of GBR services on the UE reaches but does not exceed the sum of GBRs. ◾ If the UlMbrCtrlSwitch option is selected, the UL scheduler allocates air interface resources by using a best-effort policy to ensure that the total rate of GBR services on the UE reaches but does not exceed the sum of MBRs. • When the UE is processing multiple non-GBR services, the UL scheduler allocates air interface resources by using a best-effort policy to ensure that the total rate of non-GBR services on the UE reaches but does not exceed the AMBR. • When the UE is processing GBR and non-GBR services, ◾ If the UlMbrCtrlSwitch option is deselected, the UL scheduler allocates air interface resources by using a best-effort policy to ensure that the total rate of services on the UE reaches but does not exceed the sum of GBRs plus the AMBR. ◾ If the UlMbrCtrlSwitch option is selected, the UL scheduler allocates air interface resources by using a best-effort policy to ensure that the total rate of services on the UE reaches but does not exceed the sum of MBRs plus the AMBR. 6.2 UL Preallocation During UL preallocation, eNodeBs proactively send UL scheduling indications to UEs. UL preallocation takes effect only when the CellUlschAlgo.UlschStrategy parameter is set to ULSCH_STRATEGY_EPF. 6.2.1 Preallocation Modes Preallocation can work in the following modes: • Normal mode • Smart mode • Voice mode Parameter settings for preallocation can be either cell level or QCI level. The eNodeB preferentially selects the preallocation mode based on QCI-level preallocation configuration, if it is available. NOTE: Voice preallocation can be configured only at the cell level. Figure 6-1 shows the relationship between the preallocation modes. Figure 6-1 Relationship between the preallocation modes NOTE: If the EnhancedSchForSparseSwitch option of the CellAlgoSwitch.UlSchExtSwitch parameter is selected, the preallocation of sparse-packet services is irrelevant to the UE quantity (50) described in Figure 6-1. Normal Preallocation Normal preallocation is controlled by the PreAllocationSwitch(PreAllocationSwitch) option of the CellAlgoSwitch.UlSchSwitch parameter. The preallocation duration does not take effect for normal preallocation, and preallocation cannot be performed in DRX mode. Smart Preallocation Smart preallocation is controlled by the SmartPreAllocationSwitch(SmartPreAllocationSwitch) option of the CellAlgoSwitch.UlSchSwitch parameter on condition that the PreAllocationSwitch(PreAllocationSwitch) option of this parameter has been turned on. Smart preallocation is triggered by DL services and cannot be performed before UL TCP services start, such as web browsing. This results in increased service start delay. Throughput when smart preallocation is enabled is slightly less than that when normal preallocation is enabled. The preallocation duration is specified by the CellUlschAlgo.SmartPreAllocationDuration and CellUlschAlgo.SmartPreAllocDuraForSparse parameters, and smart preallocation can be performed in DRX mode. The preallocation duration for sparse packets, which are ping service packets, is determined by the larger one between the values of the CellUlschAlgo.SmartPreAllocationDuration and CellUlschAlgo.SmartPreAllocDuraForSparse parameters. • If both the CellUlschAlgo.SmartPreAllocationDuration and CellUlschAlgo.SmartPreAllocDuraForSparse parameters are set to 0, smart preallocation is disabled. • The larger the values of the CellUlschAlgo.SmartPreAllocationDuration and CellUlschAlgo.SmartPreAllocDuraForSparse parameters, the higher the UE power consumption. NOTE: Currently, preallocation of sparse-packet services only works for ping services. To strike a tradeoff between network throughput and UE power consumption, and ensure that ping responses accurately reflect the packet round-trip delay on live networks, it is recommended that the CellUlschAlgo.SmartPreAllocationDuration parameter be set to a small value (such as 50 ms) and the CellUlschAlgo.SmartPreAllocDuraForSparse parameter be set to a value greater than the interval of ping services (such as 1500 ms). Voice Preallocation Voice preallocation is controlled by the UlVoipPreAllocationSwitch(UlVoipPreAllocationSwitch) option of the CellUlschAlgo.UlEnhencedVoipSchSw parameter on condition that the PreAllocationSwitch(PreAllocationSwitch) option of the CellAlgoSwitch.UlSchSwitch parameter has been turned on. The voice preallocation duration consists of the talk spurts of VoIP users, and UEs in the DRX state support voice preallocation. The minimum interval of voice preallocation is set to 20 ms and cannot be changed. For a UE in the DRX state, the voice preallocation duration is the smaller one between 20 ms and the value of the DrxParaGroup.DrxInactivityTimer parameter. Factors Affecting Preallocation Cell-level preallocation depends on the DRX state of UEs and the preallocation status of UEs configured with an SPID. • UEs in the DRX state do not support normal preallocation but support smart preallocation and voice preallocation. NOTE: For details about the DRX state, see DRX and Signaling Control Feature Parameter Description. • The eNodeB can control the preallocation status of UEs configured with an SPID. If a UE configured with an SPID does not support the preallocation status, the UE does not support preallocation. NOTE: For details about preallocation for UEs with an SPID, see Flexible User Steering Feature Parameter Description. 6.2.2 Parameter Settings for Preallocation Cell-level Parameter Settings The parameters in MOs CellAlgoSwitch, CellUlschAlgo, and QciPara must be set for preallocation. The PreAllocationSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is the overall switch that determines whether to enable preallocation. Cell- and QCI-level preallocation functions can take effect only if this option has been selected. QCI-level Parameter Settings The parameters in MOs CellQciPara and CellPreallocGroup must be set for preallocation. QCI-level preallocation is dependent on the setting of the cell-level switch PreAllocationSwitch. • If this switch is off, QCI-level preallocation does not take effect. • If this switch is on, QCI-level preallocation allows different preallocation parameters for services with QCI 1 to QCI 9, and the parameter settings comply with the minimum delay principle. 6.2.2.1 Cell-level Preallocation Configurations The total resources for preallocation are specified by the CellUlschAlgo.PreAllocationBandwidthRatio parameter. This parameter determines the maximum proportion of the total RBs available for preallocation in a TTI to the system bandwidth. NOTE: If the EnhancedSchForSparseSwitch option of the CellAlgoSwitch.UlSchExtSwitch parameter is selected, the CellUlschAlgo.PreAllocationBandwidthRatio parameter does not take effect on sparse-packet services. This allows all PUSCH RBs to be preallocated for sparse-packet services in a TTI. The amount of data that can be preallocated to a UE in a preallocation queue is specified by the CellUlschAlgo.PreAllocationSize parameter. The amount of voice data that can be preallocated to a UE in a preallocation queue is specified by the larger value between the CellUlschAlgo.PreAllocationSize parameter and the voice packet size. The voice packet size depends on the coding rate of the VoIP user. For details, see VoLTE Feature Parameter Description. The data volume for smart preallocation on a UE varies depending on common services and sparse-packet services. • For common services, the data volume for smart preallocation is specified by the CellUlschAlgo.PreAllocationSize parameter. • For sparse-packet services, the data volume for smart preallocation is specified by the CellUlschAlgo.PreallocationSizeForSparse parameter. If the preallocation function is enabled, and PUSCH resources are still available after UEs with unsatisfied GBR, UEs with unsatisfied Min-GBR, and UEs with satisfied Min-GBR but unsatisfied AMBR are scheduled, then a UE with unsatisfied AMBR is placed in the preallocation queue provided the following conditions are met: • The UE is not scheduled within the current TTI. • The UE meets the requirement for the minimum interval between preallocations. The minimum interval between preallocations is specified by the CellUlschAlgo.PreAllocationMinPeriod parameter. If the interval is 1, UEs can be preallocated in each TTI. If the interval is 2, UEs can be preallocated once every two TTIs. If smart preallocation is enabled the minimum interval between preallocations for sparse-packet services is specified by the CellUlschAlgo.PreAllocMinPeriodForSparse parameter. If this parameter is set to a value other than SAME_AS_OTHER_SERVICE, the minimum interval between preallocations for sparse-packet services is determined by the setting of this parameter. If this parameter is set to SAME_AS_OTHER_SERVICE, the minimum interval between preallocations for sparse-packet services is determined by the setting of the CellUlschAlgo.PreAllocationMinPeriod parameter. • The UE has not undergone semi-persistent scheduling. • The UE has a preallocation weight greater than 0. The preallocation weight is specified by the QciPara.PreAllocationWeight parameter, which is QCI-specific. The preallocation weight of a UE is determined by the preallocation weight of the services with the highest-priority QCI. The resource preallocation priorities of UEs in the preallocation queue are determined by the number of preallocations and the preallocation weight. A UE with a smaller number of preallocations and a greater preallocation weight has a higher priority. If UEs have the same priority and preallocation weight, the eNodeB randomly selects UEs for preallocation. NOTE: UL preallocation increases the number of times the eNodeB proactively schedules UEs and quickens responses to UE service requests. However, UL preallocation may increase PDCCH overheads and UL interference, and also prolong the UL data transmission duration. As a result, the calculated average UL throughput decreases, given an unchanged UL total traffic volume. The average UL throughput equals the UL traffic volume divided by the UL data transmission duration. However, the eNodeB cannot measure the duration when the data packets are buffered on the UE side. Therefore, the calculated result can be used for reference only and cannot be used for the accurate evaluation of data rates experienced by users. When the switch for dynamic adjustment on the number of orthogonal frequency division multiplexing (OFDM) symbols occupied by the PDCCH is turned on, the ratio of the OFDM symbols occupied by the PDCCH to the total OFDM symbols is increased. Smart preallocation achieves a better tradeoff than normal preallocation among system gains, PDCCH overhead, and UL interference. When a small TCP window is configured on the server, the DL web browsing rate is sensitive to the UL loopback TCP packet delay. Compared with UL normal preallocation, UL smart preallocation increases the delay and therefore decreases the DL web browsing rate. UL smart preallocation also increases the start delay for services initiated by upstream devices. 6.2.2.2 QCI-level Preallocation Configurations In QCI-level preallocation, preallocation parameter groups are configured based on QCI levels. A preallocation parameter group includes the configurations of the preallocation mode, data volume, minimum preallocation interval, and preallocation duration. Figure 6-2 shows the association between QCI levels and preallocation parameter groups. A QCI associates with only one preallocation parameter group. Figure 6-2 QCI-level preallocation configurations Preallocation Procedure The eNodeB traverses the QCIs of all bearers that have been established on a UE. • If one or more QCIs are configured with valid values of PreallocationParaGroupId, The eNodeB preferentially uses QCI-level preallocation configurations for the UE. If multiple QCIs are configured with valid values of PreallocationParaGroupId, the eNodeB selects preallocation configurations for the UE based on the minimum delay principle. The specific rules are as follows: ◾ Rule of preallocation mode selection The eNodeB preferentially uses the configurations for normal preallocation. If the configurations for normal preallocation are unavailable, the eNodeB uses the configurations for smart preallocation. ◾ Rule of parameter selection in normal preallocation If multiple sets of normal preallocation configurations are available, the minimum preallocation interval equals the minimum one among the configurations and the data volume for preallocation equals the maximum one among the configurations. ◾ Rule of parameter selection in smart preallocation If multiple sets of smart preallocation configurations are available, the minimum preallocation interval equals the minimum one among the configurations, the data volume for preallocation equals the maximum one among the configurations, and the smart preallocation duration equals the maximum one among the configurations. • If none of QCIs is configured with a valid value of PreallocationParaGroupId, The eNodeB uses cell-level preallocation configurations for the UE. 6.3 Uplink Traffic Model Based Scheduling This section describes LOFD-110205 Traffic Model Based Performance Optimization. With this feature, the eNodeB preferentially schedules the UEs running small-amount data services and experiencing good signal quality to reduce user wait time. This feature increases the perceived data rates and improves user experience while basically maintaining cell capacity. Specifically, in scenarios with a heavy traffic load (for example, the RB usage is greater than 60%), the user-perceived data rate increases by 5% to 20%. This feature works in cells with a bandwidth of at least 5 MHz. This feature is controlled by the UlPacketLenAwareSchSw option of the parameter CellAlgoSwitch.UlSchExtSwitch. • When this option is deselected, this feature is disabled. • When this option is selected, this feature is enabled. 7 Related Features 7.1 LBFD-001006 AMC Prerequisite Features None Mutually Exclusive Features None Impacted Features None 7.2 LBFD-002005 DL Asynchronous HARQ Prerequisite Features None Mutually Exclusive Features None Impacted Features Feature ID Feature Name Description LBFD-002017 DRX When DRX is enabled, the wait time for HARQ retransmission is specified by the DrxParaGroup.DrxReTxTimer parameter. 7.3 LBFD-002006 UL Synchronous HARQ Prerequisite Features None Mutually Exclusive Features None Impacted Features None 7.4 LBFD-002025 Basic Scheduling Prerequisite Features None Mutually Exclusive Features Feature ID Feature/Function Name Description LOFD-070208 Coordinated Scheduling based Power Control None N/A Frequency hopping The UL Multi-Cluster function under basic scheduling does not work with frequency hopping. NOTE: Frequency hopping is enabled when the CellUlschAlgo.UlHoppingType parameter is set to a value other than Hopping_OFF. Impacted Features Feature ID Feature Name Description LOFD-001048 TTI Bundling The UL Multi-Cluster function does not take effect on UEs in the TTI bundling state. 7.5 LBFD-060102 Enhanced UL Frequency Selective Scheduling Prerequisite Features None Mutually Exclusive Features Feature ID Feature Name Description LBFD-121102 eRAN12.1 Introduction Package The UlEnhancedDopplerSwitch option of the CellAlgoSwitch.UlSchSwitch parameter for the Enhanced UL Frequency Selective Scheduling feature and the PAMC function in the eRAN12.1 Introduction Package feature cannot take effect at the same time. Impacted Features None 7.6 LBFD-060103 Enhanced DL Frequency Selective Scheduling Prerequisite Features None Mutually Exclusive Features None Impacted Features None 7.7 LBFD-070102 MBR>GBR Configuration Prerequisite Features None Mutually Exclusive Features None Impacted Features None 7.8 LBFD-070106 PDSCH Efficiency Improvement Prerequisite Features None Mutually Exclusive Features Feature ID Feature Name Description LOFD-070208 Coordinated Scheduling based Power Control CSPC and eCSPC work in high-interference scenarios while adaptive power allocation for cell-edge UEs works in low-interference scenarios. They work in different scenarios and therefore adaptive power allocation for cell-edge UEs is incompatible with CSPC and eCSPC. (CSPC and eCSPC work in centralized Cloud BB networks and IP RAN networks, respectively.) LOFD-001007 High Speed Mobility LOFD-001008 Ultra High Speed Mobility Adaptive power allocation for cell-edge UEs reduces UEs' channel tracking capabilities in high-speed and ultra-high-speed scenarios, causing these features to produce negative gains. LOFD-001002 UL 2x2 MU-MIMO LOFD-001058 UL 2x4 MU-MIMO LAOFD-120201 DL CoMP (Trial) DL CoMP aims to improve the performance of cell-edge UEs in high-interference scenarios while adaptive power allocation for cell-edge UEs aims to improve the performance of cell-edge UEs in low-interference wide-coverage scenarios. They work in different scenarios and therefore are mutually exclusive. Feature ID Feature/Function Name Description N/A Target IBLER adaptation When both target IBLER adaptation and adaptive power allocation for cell-edge UEs are enabled, the performance of cell-edge UEs may further improve. MRFD-090202 GSM and LTE FDD Dynamic Spectrum Sharing (LTE FDD) After this feature is enabled, the shared spectrum may experience high GSM interference. Adaptive power allocation for cell-edge UEs takes effect only for UEs scheduled in the LTE-only spectrum. LOFD-070208 Coordinated Scheduling based Power Control In the TTIs when adaptive power allocation for cell-edge UEs takes effect, the power on some RBs is increased, affecting interference estimation in intraeNodeB CSPC. N/A Carrier aggregation Adaptive power allocation for cell-edge UEs works normally for UEs in their PCells. However, there is a low probability that this function takes effect for UEs in their SCells. LEOFD-110301 DL 256QAM Adaptive power allocation for cell-edge UEs does not take effect for UEs for which 256QAM is used in the downlink. MU-MIMO and adaptive power allocation for cell-edge UEs both require MCS adjustment for UEs and therefore are mutually exclusive. Impacted Features Feature ID Feature/Function Name Description LOFD-003029 SFN LOFD-070205 Adaptive SFN/SDMA These SFN features combine physical cells into an SFN cell, and the signal quality improves for the UEs located at the edges of the physical cells. Adaptive power allocation for cell-edge UEs stops taking effect for these UEs. 7.9 LBFD-00101501 CQI Adjustment Prerequisite Features None Mutually Exclusive Features None Impacted Features None 7.10 LBFD-00101502 Dynamic Scheduling Prerequisite Features Feature ID Feature Name Description LBFD-002008 Radio Bearer Management If RlcPdcpParaGroup.RlcParaAdaptSwitch is set to OFF(Off) in all RLC/PDCP parameter groups with RLC transmission mode set to AM, DLRLCStateReportSchDelaySw (DLRLCStateReportSchDelaySw) under the CellAlgoSwitch.DlSchSwitch parameter must be off. Feature ID Feature Name Description LBFD-121102 eRAN12.1 Introduction Package UL target IBLER adaptation in the Dynamic Scheduling feature cannot work together with PAMC in the eRAN12.1 Introduction Package feature. Mutually Exclusive Features Impacted Features Feature ID Feature Name Description LBFD-002017 DRX UL preallocation is affected by the DRX state of UEs. UEs in the DRX state do not support normal preallocation but support smart preallocation and voice preallocation. LOFD-001059 UL Pre-allocation Based on SPID UL preallocation is affected by this feature. If a UE configured with an SPID does not support the preallocation status, the UE does not support preallocation. 7.11 LOFD-001109 DL Non-GBR Packet Bundling Prerequisite Features None Mutually Exclusive Features None Impacted Features Function Description Non-GBR services and VoLTE When UEs are processing non-GBR services and VoLTE services, enabling the feature LOFD-001109 DL Non-GBR Packet services Bundling has the following impact: • The VoLTE service quality may slightly decrease, while still being satisfactory. • The DL non-GBR throughput increases if the non-GBR service scheduling probability is low before this feature is enabled because VoLTE services take precedence and occupy more PDCCH resources. The non-GBR DL throughput increases with the number of users using VoIP services with satisfactory quality. The throughput increase also depends on the non-GBR user distribution, traffic volume, system bandwidth, and other factors. 7.12 LOFD-110205 Traffic Model Based Performance Optimization Prerequisite Features None Mutually Exclusive Features None Impacted Features None 7.13 LBFD-121102 eRAN12.1 Introduction Package Prerequisite Features None Mutually Exclusive Features Feature ID Feature Name Description LBFD-00101502 Dynamic Scheduling UL target IBLER adaptation in the Dynamic Scheduling feature cannot work together with PAMC in the eRAN12.1 Introduction Package feature. LBFD-060102 Enhanced UL Frequency Selective Scheduling The UlEnhancedDopplerSwitch option of the CellAlgoSwitch.UlSchSwitch parameter for the Enhanced UL Frequency Selective Scheduling feature and the PAMC function in the eRAN12.1 Introduction Package feature cannot take effect at the same time. LOFD-120202 Intra-eNodeB and Inter-eNodeB Uplink Interference UL IC cannot work together with PAMC in the Cancellation eRAN12.1 Introduction Package feature. Impacted Features Feature ID Feature Name Description LOFD-081206 Uplink Coordinated Scheduling If the coordinated resource allocation (CRA) function in the Uplink Coordinated Scheduling feature has been enabled, the PAMC function results in a decrease in the number of interferencesensitive UEs and therefore reduces the gains of the CRA function. 8 Network Impact This chapter describes the impact of scheduling-related features on network performance. 8.1 LBFD-001006 AMC System Capacity This feature increases spectral efficiency. Network Performance No impact. 8.2 LBFD-002005 DL Asynchronous HARQ System Capacity This feature increases the cell DL throughput and reduces the DL transmission delay. Network Performance When HARQ retransmissions use a lowered TBS index, the DL RBLER and call drop rate decrease but DL throughput may also decrease. When the maximum number of DL HARQ retransmissions retains the default value, DL throughput decreases slightly. The smaller the maximum number of DL HARQ retransmissions, the greater the DL throughput loss. 8.3 LBFD-002006 UL Synchronous HARQ System Capacity This feature increases the network UL throughput and reduces the UL transmission delay. Network Performance When UL HARQ retransmissions increase the RBs for scheduling and reduce the code rate, the UL RBLER, call drop rate, and packet loss rate of voice services decrease but UL throughput may be reduced. When the maximum number of UL HARQ retransmissions retains the default value, UL throughput decreases slightly. The smaller the maximum number of UL HARQ retransmissions, the greater the UL throughput loss. 8.4 LBFD-002025 Basic Scheduling System Capacity • The Max C/I algorithm sacrifices the fairness between UEs within a cell for the maximal cell throughput. A UE that is constantly experiencing poor channel conditions cannot be scheduled. As a result, user experience is poor. • The RR algorithm ensures scheduling fairness between UEs in a cell. However, it decreases the cell throughput. • The PF algorithm is a compromise between Max C/I and RR, but it does not ensure that the QoS of user services can be maintained. If the CellUlschAlgo.MaxUlSchRbNum parameter is set to a value other than 255 and the value is less than the expected number of RBs to be allocated in the UL, the number of RBs that can be allocated to a UE is restricted, affecting UL capacity. • If the CellUlschAlgo.MaxUlSchRbNum parameter is set to a small value, the maximum number of RBs that can be allocated in UL scheduling is small. • If the CellUlschAlgo.MaxUlSchRbNum parameter is set to a large value, the maximum number of RBs that can be allocated in UL scheduling is large. However, the maximum number will not exceed the number limited by the UL bandwidth. When there are UL frequency spectrum fragments, the UL Multi-Cluster function helps increase the UL PRB usage of cells. Network Performance • If the CellUlschAlgo.MaxUlSchRbNum parameter is set to a value other than 255 and the value is less than the expected number of RBs to be allocated in the UL, the peak UL throughput of UEs decreases and the user-perceived data rates of UEs with large-packet data transmissions also decrease. • If the CellUlschAlgo.MaxUlSchRbNum parameter is set to a value less than 4, the access success rate, handover success rate, and RRC connection reestablishment success rate decrease, and the service drop rate increases. When there are UL frequency spectrum fragments, the UL Multi-Cluster function helps increase the UL peak throughput of UEs. 8.5 LBFD-060102 Enhanced UL Frequency Selective Scheduling System Capacity Enabling this feature for a cell serving lots of users reduces UL interference with UEs and increases the MCS index, increasing UL cell throughput. The feature yields significant gains when UL PRB usage is less than 70%. The feature yields insignificant gains when UL PRB usage is greater than or equal to 70%. Enhanced UL frequency selective scheduling provides UEs in the cell with more opportunities to be scheduled by frequency selective scheduling. It yields larger gains of UL frequency selective scheduling and improves spectral efficiency for uplink transmission. When optimized UL frequency selective scheduling based on the estimated UE speed is enabled, low-speed UEs that perform continuous UL data transmission for a long period of time (for example, longer than 20s) can achieve larger gains of frequency selective scheduling at far or medium distances from cell center. This improves throughput and spectral efficiency, increasing network capacity. When the UlFssWindSearchDirRandSw option of the CellAlgoSwitch.UlSchExtSwitch parameter is selected, the UL throughput of UEs for which SRS has not been configured increases. Network Performance When the interference on the PUSCH in a cell is less than –110 dBm, UL interference-based frequency selective scheduling does not always select the band where interference is lower. UL throughput may decrease. When SRS transmission is disabled, UL interference-based frequency selective scheduling reduces UL RBLER and therefore increases UL throughput. When SRS transmission is enabled, UL interference-based frequency selective scheduling may increase UL RBLER and therefore decrease UL throughput. 8.6 LBFD-060103 Enhanced DL Frequency Selective Scheduling System Capacity This feature increases the DL cell throughput. This feature shortens the period of a frequency selective scheduling decision and enables fast reporting of Doppler measurements, accelerating the process of entering DL frequency selective scheduling for low-speed UEs to further improve spectral efficiency and increase the perceivable DL user rates. Aperiodic CQI reporting will become frequent if the period of a frequency selective scheduling decision is shortened. This raises the number of consumed UL RBs and increasing UL interference. In this situation, the perceivable UL user rates and the selected UL MCS may decrease, and the UL residual BLER may increase. To minimize the impact, enable the enhanced UL frequency selective scheduling function and set the cell resource allocation policy to FS_INRANDOM_ADAPTIVE (adaptive switchover between frequency selective allocation and interference-randomization-based non-frequency-selective allocation). For details, see 11.5 Deploying Enhanced UL Frequency Selective Scheduling. If the UL MCS decreases, the number of fragmented UL voice packets for cell edge users may increase. If there are too many fragmented UL voice packets, the packet loss rate for voice services may increase. To mitigate the adverse impact, enable related voice service optimization functions. For details, see VoLTE Feature Parameter Description. Network Performance After downlink frequency selective scheduling takes effect, the CPU usage increases. A longer validity period of subband CQIs aperiodically reported by UEs in frequency selective scheduling results in a higher probability that valid subband CQIs are used for frequency selective scheduling and therefore higher DL throughput gains. However, with the period increased, the accuracy and timeliness of aperiodically reported CQIs decrease, reducing the average accuracy of MCS selection for DL transmission and potentially affecting DL throughput. A shorter period results in more accurate aperiodically reported CQIs but a lower probability that valid subband CQIs are used for frequency selective scheduling, causing a decrease in the DL throughput gains of frequency selective scheduling. A longer period of triggering aperiodic CQI reporting in frequency selective scheduling results in a smaller number of aperiodically reported CQIs and a lower probability that frequency selective scheduling is selected for UEs, affecting the DL throughput gains of frequency selective scheduling. A shorter period results in a higher probability that frequency selective scheduling is selected for UEs. However, a larger number of aperiodic CQI reports increases UL RB consumption and UL interference, potentially affecting UL performance. 8.7 LBFD-070102 MBR>GBR Configuration System Capacity GBR bearers consume more resources when system congestion occurs. The resources available for non-GBR bearers are reduced. In this situation, throughput on the non-GBR bearers declines, and even cell throughput also declines. With this feature, the services carried on the GBR bearers will reach rates that are greater than the GBR but do not exceed the MBR, if the allocated resources are sufficient. Network Performance No impact. 8.8 LBFD-070106 PDSCH Efficiency Improvement System Capacity The function of MCS selection with prioritized RBs and the function of MCS selection for transmission of small-amount data reduce the number of retransmissions and the scheduling delay of small-traffic services. These functions increase UEs' data rates but decrease DL spectral efficiency. PDCCH and PDSCH resource balancing increases DL RB utilization and DL throughput for a cell serving more than 200 UEs in RRC_CONNECTED mode with PDCCH resource congestion (PDCCH CCE usage greater than 70%) and low PDSCH resource usage (DL PRB usage less than 80%). Network Performance PDCCH and PDSCH resource balancing increases the scheduling priority of UEs with DL large-packet data transmission, but it also increases the scheduling delay of UEs with DL small-packet data transmission. If the incremental amplitude of the DL transmission delay is greater than that of the DL traffic volume, the average user-perceived DL data rates will decrease in the cell. PDCCH and PDSCH resource balancing improves DL RB utilization in applicable scenarios. However, this function increases DL interference and the value of the "Service Drop Rate (All)" KPI may slightly increase. In light-load wide-coverage scenarios, adaptive power allocation for cell-edge UEs increases the throughput of cell-edge UEs allocated limited radio resources. If the load of a cell is light, for example the PRB usage is less than 20%, air interface delay is reduced for a larger number of UEs with small-traffic services when the setting of the CellDlschAlgo.RBPriMcsSelectStrategy parameter is changed from SINGLEUSER_STRATEGY to MULTIUSR_LOWMCSLIMIT_STRATEGY. (This parameter is used in the MCS selection with prioritized RBs function.) However, the IBLER increases for UEs with poor channel quality, for example in a suburb, and the scheduling delay and packet loss rate also increase for these UEs, especially UEs running voice services. This is due to the limitation that the MCS index can be reduced by 3 at most. 8.9 LBFD-00101501 CQI Adjustment System Capacity This feature, using a closed-loop mechanism to dynamically compensate for inaccurate CQIs reported by UEs, optimizes MCS selection and increases overall throughput. Using adaptive target IBLER values can improve the spectral efficiency for UEs using small-packet services in the cell center or at medium distances from the cell center and cell edge UEs. Increasing the target IBLER can also improve the capacity of heavily loaded cells. However, a higher target IBLER value will increase the number of retransmissions, which may prolong the data transmission duration. As a result, the perceived throughput may decrease. The enhanced function of DL target IBLER adaptation increases DL throughput when the channel quality fluctuates or when the proportion of small-packet data transmission is high. However, this enhanced function may increase the RBLER. The optimized algorithm for calculating the DL CQI adjustment value prevents delayed CQI adjustment due to a prolonged CQI adjustment period when the cell serves a massive number of users. This algorithm improves IBLER convergence and DL throughput. The initial step in DL CQI adjustment is configurable. Decreasing the initial step increases the handover success rate and reduces the DL RBLER, but may reduce DL throughput of UEs in the event of initial access and handovers. Increasing the initial step may decrease the handover success rate and raise the DL RBLER, but can increase DL throughput of UEs in the event of initial access and handovers. Network Performance Target IBLER adaptation may cause the user-perceived DL throughput KPI to decrease when there is a relatively high proportion of small-packet services. That is because this KPI does not take certain UEs in the cell center into consideration when spectral efficiency has increased and scheduling time has been shortened. It is recommended that network performance be evaluated based on the DL UE throughput calculated with time conversion considering small packets. This throughput is equal to L.Thrp.bits.DL divided by L.Thrp.Time.DL.SmallPktConverted. 8.10 LBFD-00101502 Dynamic Scheduling System Capacity • This feature helps achieve a tradeoff between UE fairness and cell throughput while meeting QoS requirements. • UL normal or smart preallocation has the following impacts on network performance: ◾ The Service Uplink Average Throughput KPI is affected. Counter ID Counter Name Counter Description KPI 1526728259 L.Thrp.bits.UL Total uplink traffic volume of PDCP PDUs in a cell Service Uplink Average Throughput = L.Thrp.bits.UL/L.Thrp.Time.UL After normal or smart preallocation is enabled, the number of times the eNodeB proactively schedules UEs increases if the value of L.Thrp.bits.UL is the same before and after normal or smart preallocation is enabled. Therefore, packets are scheduled more frequently and the wait time of UL packets in the UE buffer is reduced. 1526728260 L.Thrp.Time.UL Total uplink PDCP data reception duration in a cell • On the UE side, the user-perceived data rates increase because the time reduction in data buffering on UEs is greater than the time increment in UL data scheduling. • On the E-UTRAN side, the Service Uplink Average Throughput KPI decreases. This is because the value of L.Thrp.Time.UL increases when the number of times that the eNodeB proactively schedules UEs increases. In summary, the Service Uplink Average Throughput KPI cannot be used for estimating the impact of preallocation on user-perceived data rates, because L.Thrp.Time.UL does not measure the duration when UL data is buffered on UEs. Specially, when a UE is in the DRX state: • If UL normal preallocation has been enabled: The eNodeB proactively exits the preallocation mode for the UE and the Service Uplink Average Throughput KPI increases. • If UL smart preallocation has been enabled: The eNodeB retains the smart preallocation mode for the UE and the Service Uplink Average Throughput KPI is not affected. ◾ The number of RBs increases for UL frequency selective scheduling and also for UL CoMP if UL CoMP is used. ◾ UL ROHC will yield few gains in resource saving if the eNodeB increases the scheduled packet size to a value greater than the voice packet size. • When PUSCH DTX detection is enabled, the UL scheduler stops invalid retransmissions and performs initial transmissions based on the PUSCH DTX detection result, saving UL resources and increasing throughput. • When scheduling termination for abnormal UEs is enabled, the eNodeB does not schedule UEs with abnormal links, saving system resources. This function increases cell throughput when resources are insufficient. • If the scheduler-controlled power function is enabled, the MCS index selected for UL transmission and the UL throughput increase in scenarios where the UL PRB usage is low and UL interference is light. It is recommended that the scheduler-controlled power function be disabled in scenarios that meet the following conditions to prevent possible UL capacity decrease: ◾ The percentage of UEs with UL path loss greater than or equal to 120 dB is greater than 70%. The percentage can be calculated using the following formula: Percentage = Sum of the values of L.Traffic.User.PL7 to L.Traffic.User.PL10/Sum of the values of L.Traffic.User.PL0 to L.Traffic.User.PL10. ◾ The PUSCH PRB usage is greater than 80%. ◾ The values of L.UL.Interference.Avg for the local cell and its neighboring cells are all lower than –116 dBm. ◾ The value of L.Traffic.SUNPT.UL.Avg is greater than 10. If the scheduler-controlled power function is enabled in scenarios that meet the preceding conditions, the UL capacity and throughput decrease because a smaller number of UEs are scheduled. To reduce this negative effect, enable the function of RB number calculation based on UL data volume matching. This function increases the CCE usage. • After PDCCH and PUSCH resource balancing is enabled, UL network capacity increases in scenarios where the cell serves a large number of UEs and UL RB utilization is low due to PDCCH resource insufficiency. • After PUCCH RB occupation by PUSCH is enabled, the UL peak rate of a single UE increases. • When data amount adaptation in SR-based scheduling is enabled: ◾ If the UL PRB usage is less than or equal to 90%, this function increases UL UE throughput. ◾ If the UL PRB usage is greater than 90% and the CellUlschAlgo.UlSrSchDataVolAdptOptUpThd parameter is set to 2000, this function increases UL traffic volume and UL cell throughput. Network Performance • Dynamic scheduling helps meet the QoS requirements of services with various QCIs and provides differentiated services for UEs. • For the logical channel priority settings of QCI 1 to QCI 5: ◾ If the logical channel priority of QCI 1 is lower than that of QCI 2 to QCI 4, CS service packet loss may occur in hybrid services of QCI 1 and QCI 2 to QCI 4. ◾ If the logical channel priority of QCI 1 is higher than that of QCI 5, the scheduling delay of QCI 5 may slightly increase in multi-bearer service scenarios for QCI 1 and QCI 5. ◾ If the logical channel priority of QCI 1 is higher than that of QCI 5 and the preallocation weight for QCI 1 is 0 (indicating that preallocation is disabled when the bearer for QCI 1 is available), CS service packet loss may occur due to missing detection of scheduling requests. • UL normal or UL smart preallocation affects user experience. By increasing the number of times that the eNodeB proactively schedules UEs, UL normal preallocation or UL smart preallocation shortens the duration when UL data is buffered on UEs, increases the speed of response to UE service requests, and improves user experience. Compared with UL normal preallocation, UL smart preallocation decreases signaling overheads on the PDCCH and UL interference. However, UL smart preallocation increases UL delay, and decreases the web browsing rate when a small TCP window is configured on the server. UL normal preallocation or smart preallocation also shortens the average RRC connection setup duration (indicated by L.RRC.ConnSetup.TimeAvg) and average E-RAB setup duration (indicated by L.E-RAB.Est.TimeAvg). With UL normal preallocation or smart preallocation, the eNodeB prevents the E-RAB setup signaling reception failures caused by missing detection of SRs sent from UEs. That is, UL normal preallocation or smart preallocation helps increase the E-RAB setup success rate. UL normal preallocation or smart preallocation consumes more Uu resources, increasing CCE usage and RB usage. An increased UL RB usage results in increased UL interference, causing KPIs related to accessibility, mobility, and retainability to deteriorate. Additionally, the packet loss rate of voice services increases. Compared with UL normal preallocation and smart preallocation, UL voice preallocation increases the opportunity that voice services are scheduled, reducing the delay of voice services. Specially, when a UE is in the DRX state: ◾ If UL normal preallocation has been enabled: The eNodeB proactively exits the preallocation mode for the UE, and user experience of the UE cannot be improved. ◾ If UL smart preallocation has been enabled: The eNodeB retains the smart preallocation mode for the UE, and therefore can improve the user experience of the UE. However, this also consumes more power of the UE, and the amount of power consumption has a positive correlation with the duration of UL smart preallocation. • Scheduling termination for abnormal UEs reduces the residual block error rate (RBLER). However, this function results in a longer scheduling delay, lower perceivable throughput, and higher service drop probability for UEs under weak coverage. • PDCCH and PUSCH resource balancing increases UL cell throughput and UL RB usage in scenarios where the cell serves a large number of UEs and UL RB usage is low due to PDCCH resource insufficiency. However, this function may increase UL interference. PDCCH and PUSCH resource balancing preferentially selects cell center users for scheduling, thereby reducing the UL CCE usage. • UL IBLER adjustment increases UL user throughput. • UL RLC segment reduction deteriorates the call drop rate slightly. • PUCCH RB occupation by PUSCH increases the PUCCH interference and causes network KPIs to slightly deteriorate. Therefore, the function is not recommended on commercial networks. • When DL frequency selective scheduling is used, a smaller value of the CellDlschAlgo.NoSchStopACqiThd parameter results in a smaller number of aperiodic CQI reports, reducing UL interference, increasing UL UE data rates, and decreasing the DL throughput of UEs to which DL frequency selective scheduling is applied. • When the scheduler-controlled power function and normal or smart preallocation are enabled, prediction of UE selection helps increase throughput of cell center UEs with large amounts of UL data. • Active scheduling of UL signaling helps increase the E-RAB setup success rate and the RRC connection reestablishment success rate, and slightly improves other control-plane KPIs. • When the CellUlschAlgo.PuschDtxSchStrategy parameter is set to EN_ADAPTIVE_RETX, the UL RBLER is slightly higher than when it is set to ADAPTIVE_RETX or NEW_TX. • After DL AMBR control over non-GBR services is enabled: ◾ In multi-user scenarios, the larger the value of the CellDlschAlgo.AmbrCtrlTcycle parameter is, the sooner small-packet services of DL AMBR-restricted UEs are scheduled. The scheduling wait time is reduced and user-perceived DL data rates increase more noticeably. ◾ If the CellDlschAlgo.AmbrCtrlTcycle is set to a large value, single-user TCP packet injection may cause the TCP service sending window to become unstable. As a result, the incoming traffic volume is insufficient and UE throughput decreases. ◾ When the CellDlschAlgo.AmbrCtrlTcycle parameter is set to AMBR_1000_MS(AMBR_1000_MS), DL AMBR control does not take effect. • Delayed scheduling of DL RLC status reports increases user-perceived DL data rates at major incidents in which PDCCH CCE resources are insufficient. 8.11 LOFD-001109 DL Non-GBR Packet Bundling System Capacity For a cell with insufficient PDCCH resources but sufficient PDSCH resources, enabling this feature enhances utilization of control channel resources and improves the distribution of scheduling wait time for downlink packets while meeting the QoS requirements. Network Performance No impact. 8.12 LOFD-110205 Traffic Model Based Performance Optimization System Capacity • Impact on the downlink Enabling this feature in the downlink does not have significant impact on the system capacity. The cell throughput remains roughly the same. • Impact on the uplink Enabling this feature in the uplink does not have significant impact on the system capacity. The cell throughput remains roughly the same. In uplink heavy-load scenarios (for example, the PRB usage is greater than 90% and the CCE usage is greater than 65%), this feature may increase UL cell throughput due to the fact that UEs in or near the cell center have more opportunities to be scheduled by the eNodeB. Network Performance This feature raises the scheduling priorities of users using only small-packet services with favorable channel quality. If PRB usage is greater than 60%, this feature improves the spectral efficiency and enables the eNodeB to use high MCS indexes for data transmission, reducing cell PRB usage by around 2%. • Impact on the downlink In scenarios with a relatively heavy traffic load (for example, PRB usage greater than 60%), enabling this feature in the downlink helps to raise the downlink perceived data rate by 5% to 20%. For details about the method of monitoring DL user-perceived data rates, see 10.8 Performance Monitoring. In heavy-load scenarios (for example, PRB usage higher than 80%), the values of the counters L.Traffic.DL.PktDelay.Time.QCI.1 to L.Traffic.DL.PktDelay.Time.QCI.9 might increase, but the value of L.Thrp.Time.DL.RmvLastTTI might decrease. Besides, in heavy-load scenarios, the values of the counters L.RLC.FirstPacketDelay.NonGBR.Index0 to L.RLC.FirstPacketDelay.NonGBR.Index4 might increase. Since some users near the cell center and users with little amount of data in the RLC buffer constantly have higher priority in scheduling, the delay of the first packet for other users will increase. • Impact on the uplink In scenarios with a relatively heavy traffic load (for example, PRB usage greater than 60%), enabling this feature in the uplink helps to raise the uplink perceived data rate by 5% to 20%. For details about the method of monitoring UL user-perceived data rates, see 12.5 Performance Monitoring. There is a high probability that this feature: • Reduces the number of online synchronization users and the average number of scheduled users per TTI. This feature accelerates service data transmission of users. • Decreases the number of TTIs for UEs in active DRX mode and increases the number of TTIs for UEs in dormant DRX mode. After transmitting service data, UEs promptly exit the synchronization state or enter the dormant state. In packet injection scenarios, this feature may affect user fairness during RB allocation. 8.13 LBFD-121102 eRAN12.1 Introduction Package System Capacity No impact. Network Performance • PAMC This function increases the UL IBLER by 0%–40%, but it improves user-perceived UL throughput by 5%–15%. • Efficiency improvement for adaptive DL HARQ ◾ This function efficiently utilizes HARQ combining gains in heavily loaded cells, reduces the number of PRBs used for retransmissions, and therefore increases user-perceived DL data rates. ◾ Increasing the TBS index for retransmissions lifts the demodulation threshold, which may cause the DL RBLER to rise. However, when interference is present, this function reduces the number of PRBs used for retransmissions and therefore lowers overall interference. As a result, the DL RBLER may decrease. ◾ This function sets aside a number of PRBs, which would have been allocated for retransmissions, for initial transmissions. This may increase the number of initial transmissions and therefore reduce average DL cell throughput. The larger the value of the CellDlschAlgo.DlFirstHarqTxTbsIncNum parameter (which specifies the amount of the increase in the TBS index for the first DL HARQ retransmission), the greater the gain in user-perceived DL data rates in heavily loaded cells. However, the DL RBLER may rise. • Flexible target IBLER adaptation This function increases user-perceived DL data rates, but it may cause the DL IBLER and RBLER to rise. • Adaptive compensation for the initial value of CQI adjustment This function increases user-perceived DL data rates, but it may cause the DL IBLER and RBLER to rise. 9 Engineering Guidelines for Basic DL Scheduling Features This chapter provides engineering guidelines for basic DL scheduling features. The following features are not described in this chapter because they are enabled by default and do not involve configurable parameters: • LBFD-001006 AMC • LBFD-002005 DL Asynchronous HARQ 9.1 When to Use 9.1.1 LBFD-002025 Basic Scheduling The basic scheduling policies are Max C/I, PF, and RR. The following are suggestions for selecting scheduling policies: • To achieve the maximum system capacity, use the Max C/I policy. This policy prioritizes UEs with better channel quality. The Max C/I policy achieves high spectral efficiency but does not ensure QoS or scheduling fairness for UEs. • To achieve a balance between system capacity and scheduling fairness, use the PF policy. This policy is a tradeoff between Max C/I and RR, but does not meet QoS requirements of UEs. • To achieve scheduling fairness, use the RR policy. This policy schedules each UE the same number of times, but results in low system capacity. 9.1.2 LBFD-060103 Enhanced DL Frequency Selective Scheduling There are two DL resource allocation modes: frequency diversity scheduling and frequency selective scheduling. Frequency diversity scheduling is used by default. Frequency selective scheduling considers the differences in channel quality for UEs, thereby bringing scheduling gains. You are advised to enable fast decisions on DL frequency selective scheduling after enabling DL frequency selective scheduling. This fast decision function shortens the period of a frequency selective scheduling decision and enables fast reporting of Doppler measurements. In this way, the process of entering DL frequency selective scheduling for lowspeed UEs is accelerated, improving DL spectral efficiency. In hotspots where UEs move at a low speed, such as stadiums and business districts, select the FreqSelJudgeIgnorDopplerSwitch option of the DL schedule switch parameter to eliminate measurement errors, further increasing the proportion of UEs entering DL frequency selective scheduling. In cells serving both high- and low-speed UEs, you are advised to deselect the FreqSelJudgeIgnorDopplerSwitch option of the DL schedule switch parameter. You are advised to enable the PDCCH symbol adaptation function after enabling DL frequency selective scheduling. For details about setting the PDCCH symbol adaptation function, see Physical Channel Resource Management Feature Parameter Description. DL frequency selective scheduling is not recommended if UEs are moving at a high speed or work on non-fading channels. 9.1.3 LBFD-070102 MBR>GBR Configuration Activate this feature only when the rate-adaptive GBR services are to be deployed. (The rates range from the GBR to the MBR.) 9.1.4 LBFD-070106 PDSCH Efficiency Improvement The PDCCH and PDSCH resource balancing function is recommended when the following conditions are met: • The number of UEs in RRC_CONNECTED mode is large. For example, the number is greater than 200. • PDCCH congestion occurs. For example, the PDCCH CCE usage is greater than 70%. • The PDSCH resource usage is low. For example, the DL PRB usage is less than 80%. In light-load wide-coverage scenarios in areas such as suburbs, deserts, and oceans, it is recommended that adaptive power allocation for cell-edge UEs be enabled. 9.2 Required Information None 9.3 Planning None 9.4 Deploying Basic Scheduling 9.4.1 Requirements Operating Environment • Macro eNodeB N/A • Micro eNodeB RB blocking of the micro eNodeB must be used together with frequency selective scheduling of the macro eNodeB. Transmission Networking N/A License N/A 9.4.2 Precautions None 9.4.3 Data Preparation This section describes the data that you need to collect for setting parameters. Required data is data that you must collect for all scenarios. Collect scenario-specific data when necessary for a specific feature deployment scenario. 9.4.3.1 Required Data The following table describes the parameter that must be set in a CellDlschAlgo MO to specify the DL scheduling policy. Parameter Name Parameter ID Setting Notes Downlink scheduling Strategy CellDlschAlgo.DlschStrategy Select Max C/I, RR, or PF as a basic scheduling policy. 9.4.3.2 Scenario-specific Data 9.4.3.2.1 DL HARQ Retransmission The following table describes the parameter that must be set in a CellDlschAlgo MO to specify the maximum number of DL HARQ transmissions. Parameter Name Parameter ID Setting Notes Parameter Name Parameter ID Setting Notes Downlink HARQ Maximum Transmission Number CellDlschAlgo. DlHarqMaxTxNum This parameter specifies the maximum number of HARQ transmissions in the DL. The default value is 5. The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure efficiency improvement for adaptive DL HARQ. Parameter Name Parameter ID Setting Notes CQI Adjust Algorithm Switch CellAlgoSwitch.CqiAdjAlgoSwitch You are advised to select the PreciseMcsAdaptSwitch (PreciseMcsAdaptSwitch) option in heavy traffic scenarios where DL PRB usage exceeds 50% and DL IBLER is greater than 9% and less than 30%. The following table describes the parameter that must be set in a CellDlschAlgo MO to specify the amount of the increase in the TBS index for the first DL HARQ retransmission. Parameter Name Parameter ID Setting Notes DL First HARQ Tx TBS Index Increase Num CellDlschAlgo. DlFirstHarqTxTbsIncNum This parameter specifies the amount of the increase in the TBS index for the first DL HARQ retransmission. The default value is 0. The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the function of increasing the number of RBs to lower the TBS index for DL HARQ retransmissions. Parameter Name Parameter ID Setting Notes CQI Adjust Algorithm Switch CellAlgoSwitch.CqiAdjAlgoSwitch To reduce the packet loss rate of voice services and improve user experience with voice services in the cell, you are advised to select the DlRetxTbsIndexAdjOptSwitch(DlRetxTbsIndexAdjOptSwitch) option of this parameter. However, if this option is selected, DL throughput of data services in the cell may decrease. The default value is recommended. When the maximum number of DL HARQ retransmissions retains the default value, DL throughput decreases slightly. The smaller the maximum number of DL HARQ retransmissions, the greater the DL throughput loss. 9.4.3.2.2 Static MCS Timer for Handovers The following table describes the parameter that must be set in a CellDlschAlgo MO to specify the duration within which the eNodeB uses an MCS with a low index for scheduling before and after handovers. Parameter Name Parameter ID Setting Notes Handover UE Static MCS Scheduling Timer CellDlschAlgo.HoStaticMcsTimer This parameter specifies a period of time during which an MCS with a small index is used for DL scheduling before and after a handover. The eNodeB starts this timer when it determines that the UE enters a handover area or has been handed over to the target cell. After the timer expires, DL scheduling uses an MCS selected based on the adjusted CQI. If the timer is set to 0 ms, DL scheduling always uses an MCS selected based on the adjusted CQI for handovers. 9.4.3.2.3 RB Blocking at Micro eNodeBs In macro-micro coordination scenarios, RB blocking must be enabled on the micro eNodeB to improve service experience of users in macro cells experiencing interference from the micro eNodeB. The blocking results in slight deterioration in user experience in the micro cell. The following table describes the parameter that must be set in a CellDlschAlgo MO to configure RB blocking on a micro eNodeB. Parameter Name Parameter ID Setting Notes Micro Rb Block Ratio CellDlschAlgo.MicRbBlockRatio This parameter specifies the ratio of blocked DL RBs to total DL RBs in the micro cell. (The parameter value is expressed in percentage.) A larger value of this parameter results in higher DL throughput in the macro cell but lower DL throughput in the micro cell. A smaller value of this parameter indicates lower DL throughput in the macro cell but higher DL throughput in the micro cell. In macro-micro coordination scenarios, increase the value of this parameter to improve service experience of users experiencing interference from the micro eNodeB in the macro cell at the cost of decreased user experience in the micro cell. • In common scenarios, the default value 0 is recommended. • If the micro eNodeB is deployed near the center of the macro cell and does not take over many UEs from the macro cell, the value 24 is recommended. 9.4.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Setting the DL scheduling policy Run the MOD CELLDLSCHALGO command with the Downlink scheduling Strategy parameter specified. • Setting the maximum number of DL HARQ retransmissions Run the MOD CELLDLSCHALGO command with the Downlink HARQ Maximum Transmission Number parameter specified. • Enabling efficiency improvement for adaptive DL HARQ ◾ Run the MOD CELLALGOSWITCH command with the PreciseMcsAdaptSwitch(PreciseMcsAdaptSwitch) option of the CQI Adjust Algorithm Switch parameter selected. ◾ Run the MOD CELLDLSCHALGO command with the DL First HARQ Tx TBS Index Increase Num parameter specified. • Enabling the function of increasing the number of RBs to lower the TBS index for DL HARQ retransmissions Run the MOD CELLALGOSWITCH command with the DlRetxTbsIndexAdjOptSwitch option of the CQI Adjust Algorithm Switch parameter selected. • Setting the static MCS timer for handovers Run the MOD CELLDLSCHALGO command with the Handover UE Static MCS Scheduling Timer parameter specified. • Setting the percentage of blocked RBs Run the MOD CELLDLSCHALGO command with the Micro Rb Block Ratio parameter specified. MML Command Examples • Setting the DL scheduling policy to PF MOD CELLDLSCHALGO: LOCALCELLID=0, DLSCHSTRATEGY=DLSCH_PRI_TYPE_PF; • Setting the maximum number of DL HARQ retransmissions to 5 MOD CELLDLSCHALGO: LOCALCELLID=0, DLHARQMAXTXNUM=5; • Enabling efficiency improvement for adaptive DL HARQ and setting the amount of the increase in the TBS index for the first DL HARQ retransmission to 3 MOD CELLALGOSWITCH:LOCALCELLID=0,CQIADJALGOSWITCH=PreciseMcsAdaptSwitch-1; MOD CELLDLSCHALGO:LOCALCELLID=0,DLFIRSTHARQTXTBSINCNUM=3; • Enabling the function of increasing the number of RBs to lower the TBS index for DL HARQ retransmissions MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=DlRetxTbsIndexAdjOptSwitch-1; • Setting the static MCS timer for handovers MOD CELLDLSCHALGO: LOCALCELLID=0, HOSTATICMCSTIMER=60; • Setting the percentage of blocked RBs to 24% MOD CELLDLSCHALGO: LOCALCELLID=0, MICRBBLOCKRATIO=24; 9.4.5 Activation Observation This section uses a cell with 20 MHz bandwidth and commercial UEs as an example to describe how to verify the activation of DL scheduling. Observing Max C/I for DL Scheduling To observe whether Max C/I has been activated for DL scheduling, perform the following steps: 1. Enable two UEs to access a cell. Perform DL packet injection on the default bearer of each UE to ensure that the DL cell throughput reaches its maximum. 2. On the U2000 client, start channel quality monitoring, MCS-based count monitoring, and throughput monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > MCS Count Monitoring. • To start throughput monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Throughput Monitoring. 3. Adjust the locations of the two UEs in the cell so that UE 1 experiences good DL channel quality and UE 2 experiences poor DL channel quality. Check the DL channel quality monitoring results for each UE. For example, the CQI for UE 1 is 15, and the CQI for UE 2 is 8. 4. Check the MCS-based count monitoring results for the number of DL RBs allocated to each UE. Then check the throughput monitoring results for the DL throughput of each UE. If UE 1 occupies a majority of the total DL cell throughput and has been allocated more RBs than UE 2, Max C/I has been activated successfully. Observing RR for DL Scheduling To observe whether RR has been activated for DL scheduling, perform the following steps: 1. Enable two UEs to access a cell in the cell center. Perform a DL service on the default bearer of each UE. 2. On the U2000 client, start channel quality monitoring and MCS-based count monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > MCS Count Monitoring. 3. Check the DL channel quality monitoring results for each UE. For example, the CQI for both UEs is 15. 4. Check the MCS-based count monitoring results for the number of times each UE is scheduled in the DL. If the results are approximately the same for both UEs, RR has been activated successfully. Observing PF for DL Scheduling To observe whether PF has been activated for DL scheduling, perform the following steps: 1. Enable two UEs to access a cell. Perform a DL service on the default bearer of each UE. 2. On the U2000 client, start channel quality monitoring and MCS-based count monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > MCS Count Monitoring. 3. Adjust the locations of the two UEs in the cell so that UE 1 experiences good DL channel quality and UE 2 experiences poor DL channel quality. Check the channel quality monitoring results for the DL channel quality of each UE. For example, the CQI for UE 1 is 15, and the CQI for UE 2 is 8. 4. Check the MCS-based count monitoring results for the number of DL RBs allocated to each UE. If the results are approximately the same for both UEs, PF has been activated successfully. 9.4.6 Reconfiguration None 9.4.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Setting the maximum number of DL HARQ retransmissions Run the MOD CELLDLSCHALGO command with the Downlink HARQ Maximum Transmission Number parameter specified. • Disabling efficiency improvement for adaptive DL HARQ Run the MOD CELLALGOSWITCH command with the PreciseMcsAdaptSwitch(PreciseMcsAdaptSwitch) option of the CQI Adjust Algorithm Switch parameter deselected. • Disabling the function of increasing the number of RBs to lower the TBS index for DL HARQ retransmissions Run the MOD CELLALGOSWITCH command with the DlRetxTbsIndexAdjOptSwitch option of the CQI Adjust Algorithm Switch parameter deselected. • Setting the percentage of blocked RBs Run the MOD CELLDLSCHALGO command with the Micro Rb Block Ratio parameter specified. MML Command Examples • Setting the maximum number of DL HARQ retransmissions to 1 MOD CELLDLSCHALGO: LOCALCELLID=0, DLHARQMAXTXNUM=1; • Disabling efficiency improvement for adaptive DL HARQ MOD CELLALGOSWITCH:LOCALCELLID=0,CQIADJALGOSWITCH=PreciseMcsAdaptSwitch-0; • Disabling the function of increasing the number of RBs to lower the TBS index for DL HARQ retransmissions MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=DlRetxTbsIndexAdjOptSwitch-0; • Disabling RB Blocking MOD CELLDLSCHALGO: LOCALCELLID=0, MICRBBLOCKRATIO=0; 9.5 Deploying Enhanced DL Frequency Selective Scheduling 9.5.1 Requirements There is no requirement for the operating environment, transmission networking, and license. 9.5.2 Precautions Online reconfiguration of DL frequency selective scheduling is not supported. UEs need to access the network again when the status of the switch for DL frequency selective scheduling is changed. 9.5.3 Data Preparation The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure DL frequency selective scheduling. Table 9-1 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes DL schedule switch CellAlgoSwitch.DlSchSwitch The FreqSelSwitch option of this parameter determines whether to enable frequency selective scheduling. If this option is selected, data is transmitted on the frequency band of favorable channel quality. It is recommended that the FreqSelSwitch option be deselected. If the FreqSelSwitch option is selected for a low-mobility hotspot cell, it is recommended that the FreqSelJudgeIgnorDopplerSwitch option also be selected for the cell. The following table describes the parameters that must be set in a CellDlschAlgo MO to configure the period of determining frequency selective scheduling, the period of triggering aperiodic CQI reporting in frequency selective scheduling, and the validity period of subband CQIs aperiodically reported by UEs in frequency selective scheduling. Table 9-2 Parameters that must be set in a CellDlschAlgo MO Parameter Name Parameter ID Setting Notes Frequency Select Judge Period CellDlschAlgo.FreqSelJudgePeriod If the FreqSelSwitch option is selected, it is recommended that this parameter be set to 1. FS UE Aperiodic CQI Triggering Period CellDlschAlgo.FSUEAperCQITrigPeriod If the FreqSelSwitch option is selected, it is recommended that this parameter be set to 2. FS UE Aperiodic Subband CQI Validity Period CellDlschAlgo.FSUESbCQIValidityPeriod If the FreqSelSwitch option is selected, it is recommended that this parameter be set to 10. The following table describes the parameters that must be set in a CellUlschAlgo MO to specify the Doppler measurement reporting mode and the transmission mode of aperiodic CQI reports. Table 9-3 Parameters that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Setting Notes Doppler Algo Switch CellUlschAlgo.DopAlgoSwitch If the CellDlschAlgo.FreqSelJudgePeriod parameter is set to a value less than 10, it is recommended that the FastReportDopSwitch option be selected. Parameter Name Parameter ID Setting Notes Aperiodic CSI Uplink Transmit Mode CellUlschAlgo.AperiodicCsiUlTxMode The value CsiWiUlService(CsiWiUlService) is recommended in enhanced DL frequency selective scheduling scenarios, and the value CsiOnly (CsiOnly) is recommended in other scenarios. 9.5.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands 1. Run the MOD CELLALGOSWITCH command to enable DL frequency selective scheduling. 2. Run the MOD CELLDLSCHALGO command to set the interval at which the eNodeB evaluates frequency selective scheduling. 3. Run the MOD CELLULSCHALGO command to set the fast Doppler measurement reporting switch and the mode of transmitting aperiodic CQI reports. 4. Run the MOD CELLDLSCHALGO command to set the period of triggering aperiodic CQI reporting in frequency selective scheduling and the validity period of subband CQIs aperiodically reported by UEs in frequency selective scheduling. MML Command Examples //Enabling DL frequency selective scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=FreqSelSwitch-1&FreqSelJudgeIgnorDopplerSwitch-1; //Setting the evaluation interval to 1s MOD CELLDLSCHALGO: LOCALCELLID=0, FREQSELJUDGEPERIOD=1; //Turning on the fast Doppler measurement reporting switch and setting the mode of transmitting aperiodic CQI reports MOD CELLULSCHALGO: LOCALCELLID=0, DOPALGOSWITCH=FastReportDopSwitch-1, APERIODICCSIULTXMODE=CsiWiUlService; //Setting the period of triggering aperiodic CQI reporting in frequency selective scheduling to 10 ms and the validity period of subband CQI s aperiodically reported by UEs in frequency selective scheduling to 20 ms MOD CELLDLSCHALGO:LOCALCELLID=0,FSUEAPERCQITRIGPERIOD=10,FSUESBCQIVALIDITYPERIOD=20; 9.5.5 Activation Observation This section uses a cell with a bandwidth of 20 MHz and commercial UEs as an example to describe how to verify the activation of DL frequency selective scheduling. Observing DL Frequency Selective Scheduling (Using Performance Counters) To observe whether DL frequency selective scheduling has taken effect, check the value of L.ChMeas.PRB.DL.FSS.Avg. If this counter value is not 0, DL frequency selective scheduling has taken effect. To observe whether DL frequency selective scheduling has produced gains, calculate the average number of bits included in each RB. If this average number increases, DL frequency selective scheduling has produced gains. Average number of bits included in each RB = L.Thrp.bits.DL/ L.ChMeas.PRB.DL.Used.Avg/counter_period In the formula, counter_period indicates the measurement period for L.Thrp.bits.DL in unit of ms. Table 9-4 Counters related to DL frequency selective scheduling Counter Name Description L.ChMeas.PRB.DL.FSS.Avg Average number of PRBs allocated for downlink frequency selective scheduling L.Thrp.bits.DL Total downlink traffic volume for PDCP SDUs in a cell L.ChMeas.PRB.DL.Used.Avg Average number of PRBs used on the PDSCH Observing DL Frequency Selective Scheduling (Using the U2000) To observe whether DL frequency selective scheduling has taken effect, perform the following steps: 1. Enable a UE to access a cell. Ensure the UE's DL channel is a fading channel, which is a prerequisite for DL frequency selective scheduling to take effect. If this activation observation test is to be performed in the lab, use a channel simulator in the DL. 2. On the U2000 client, start a cell RB usage monitoring task for the UE. Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose Cell Performance Monitoring > Usage of RB Monitoring. 3. Check the number of RBs used in DL frequency selective scheduling. Figure 9-1 shows an example. If the value of Downlink Freq Select Used RB Num is not zero, DL frequency selective scheduling has taken effect. Figure 9-1 RB usage monitoring for downlink frequency selective scheduling 9.5.6 Reconfiguration None 9.5.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Disabling DL frequency selective scheduling Run the MOD CELLALGOSWITCH command with the FreqSelSwitch option of the DL schedule switch parameter deselected. • Disabling the function of ignoring Doppler measurements in DL frequency selective scheduling Run the MOD CELLALGOSWITCH command with the FreqSelJudgeIgnorDopplerSwitch option of the DL schedule switch parameter deselected. • Disabling fast evaluation of DL frequency selective scheduling Run the MOD CELLDLSCHALGO command with the Frequency Select Judge Period parameter specified. Run the MOD CELLULSCHALGO command with the FastReportDopSwitch option of the Doppler Algo Switch parameter deselected. • Setting transmission mode for aperiodic CQI reporting Run the MOD CELLULSCHALGO command with the Aperiodic CSI Uplink Transmit Mode parameter specified. • Setting the period of triggering aperiodic CQI reporting in frequency selective scheduling and the validity period of subband CQIs aperiodically reported by UEs in frequency selective scheduling Run the MOD CELLDLSCHALGO command to set the period of triggering aperiodic CQI reporting in frequency selective scheduling and the validity period of subband CQIs aperiodically reported by UEs in frequency selective scheduling. MML Command Examples • Disabling DL frequency selective scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=FreqSelSwitch-0; • Disabling the function of ignoring Doppler measurements in DL frequency selective scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=FreqSelJudgeIgnorDopplerSwitch-0; • Disabling fast evaluation of DL frequency selective scheduling //Setting the decision period to 10s MOD CELLDLSCHALGO: LOCALCELLID=0, FREQSELJUDGEPERIOD=10; //Disabling fast reporting of Doppler measurements MOD CELLULSCHALGO: LOCALCELLID=0, DOPALGOSWITCH=FastReportDopSwitch-0; • Setting transmission mode for aperiodic CQI reporting MOD CELLULSCHALGO: LOCALCELLID=0, APERIODICCSIULTXMODE=CsiOnly; • Setting the period of triggering aperiodic CQI reporting in frequency selective scheduling and the validity period of subband CQIs aperiodically reported by UEs in frequency selective scheduling MOD CELLDLSCHALGO:LOCALCELLID=0,FSUEAPERCQITRIGPERIOD=2,FSUESBCQIVALIDITYPERIOD=10; 9.6 Deploying MBR>GBR Configuration 9.6.1 Requirements There is no requirement for the operating environment, transmission networking, and license. 9.6.2 Precautions None 9.6.3 Data Preparation The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the MBR>GBR Configuration feature. Parameter Name Parameter ID Setting Notes DL schedule switch CellAlgoSwitch.DlSchSwitch The DlMbrCtrlSwitch option of the parameter specifies whether to enable the MBR>GBR Configuration feature. 9.6.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the DlMbrCtrlSwitch option of the DL schedule switch parameter selected. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=DlMbrCtrlSwitch-1; 9.6.5 Activation Observation This section describes the activation observation procedure using a commercial UE in a cell with a 20 MHz bandwidth. 1. Provision a DL GBR service for one UE. Set the GBR and MBR to 20 Mbit/s and 40 Mbit/s, respectively. Initiate a service with the data rate greater than the MBR on the UE. 2. Start throughput monitoring on the U2000: Choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Throughput Monitoring. 3. Start RB usage monitoring on the U2000: Choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > Cell Performance Monitoring > Usage of RB Monitoring. 4. Disable the MBR>GBR Configuration feature. The GBR service rate approaches the GBR (20 Mbit/s) even when the cell has vacant RBs, as shown in Figure 9-2. Figure 9-2 Example of RB usage and throughput monitoring (MBR>GBR Configuration disabled) 5. Enable the MBR>GBR Configuration feature. The GBR service rate can range from the GBR to the MBR when the cell has vacant RBs. See Figure 9-3. Figure 9-3 Example of RB usage and throughput monitoring (MBR>GBR Configuration enabled) 9.6.6 Reconfiguration None 9.6.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the DlMbrCtrlSwitch option of the DL schedule switch parameter deselected. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=DlMbrCtrlSwitch-0; 9.7 Deploying PDSCH Efficiency Improvement 9.7.1 Requirements To use adaptive power allocation for cell-edge UEs, ensure that the eNodeB type is macro and there is no strong inter-RAT interference. 9.7.2 Precautions None 9.7.3 Data Preparation The following table describes the parameters that must be set in a CellDlschAlgo MO to configure the function of MCS selection with prioritized RBs. Parameter Name Parameter ID Setting Notes RB Priority MCS Select Strategy CellDlschAlgo.RBPriMcsSelectStrategy The value MULTIUSR_LOWMCSLIMIT_STRATEGY (Multiple User Lower MCS Limited Strategy) is recommended. RB Priority MCS Select Ratio Threshold CellDlschAlgo.RBPriMcsSelectRatioThd Set this parameter to its recommended value. The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure MCS selection for transmission of small-amount data. Parameter Name Parameter ID DL schedule switch CellAlgoSwitch.DlSchSwitch Setting Notes • It is recommended that the SmallPktMcsSelectAlgoSw (SmallPktMcsSelectAlgoSw) option of this parameter be deselected if the CellDlschAlgo.RbgAllocStrategy parameter is set to ROUND_DOWN(Round Down). • It is recommended that the SmallPktMcsSelectAlgoSw (SmallPktMcsSelectAlgoSw) option of this parameter be selected if the CellDlschAlgo.RbgAllocStrategy parameter is set to ROUND_UP(Round Up) or ADAPTIVE (Adaptive). The following table describes the parameters that must be set in a CellDlschAlgo MO to configure the function of PDCCH and PDSCH resource balancing. NOTE: PDCCH and PDSCH resource balancing takes effect only when the values of the CellDlschAlgo.DataThdInPdcchPdschBal and CellDlschAlgo.UeNumThdInPdcchPdschBal parameters are both greater than 0. Parameter Name Parameter ID Setting Notes Data Threshold In Pdcch And Pdsch CellDlschAlgo.DataThdInPdcchPdschBal Balance It is recommended that this parameter be set to 36000 in heavy traffic scenarios. Ue Num Threshold In Pdcch And Pdsch Balance It is recommended that this parameter be set to 300 in heavy traffic scenarios. CellDlschAlgo.UeNumThdInPdcchPdschBal The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure adaptive power allocation for cell-edge UEs. Parameter Name Parameter ID Setting Notes Downlink Cell Coverage Enhancement Switch CellAlgoSwitch.CellDlCoverEnhanceSwitch It is recommended that the AdptCellEdgePwrAllocSw (AdptCellEdgePwrAllocSw) option of this parameter be selected in light-load wide-coverage scenarios. 9.7.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Enabling MCS selection with prioritized RBs Run the MOD CELLDLSCHALGO command with the RB Priority MCS Select Strategy and RB Priority MCS Select Ratio Threshold parameters specified. • Enabling MCS selection for transmission of small-amount data Run the MOD CELLALGOSWITCH command with the SmallPktMcsSelectAlgoSw option of the DL schedule switch parameter selected. • Enabling PDCCH and PDSCH resource balancing Run the MOD CELLDLSCHALGO command with the Data Threshold In Pdcch And Pdsch Balance and Ue Num Threshold In Pdcch And Pdsch Balance parameters specified. • Enabling adaptive power allocation for cell-edge UEs Run the MOD CELLALGOSWITCH command with the AdptCellEdgePwrAllocSw option of the Downlink Cell Coverage Enhancement Switch parameter selected. MML Command Examples • Configuring the function of MCS selection with prioritized RBs with the RB Priority MCS Select Strategy parameter set to MULTIUSR_LOWMCSLIMIT_STRATEGY and the RB Priority MCS Select Ratio Threshold parameter set to 10 MOD CELLDLSCHALGO:LOCALCELLID=0,RBPRIMCSSELECTSTRATEGY=MULTIUSR_LOWMCSLIMIT_STRATEGY,RBPRIMCSSELECTRATIOTHD=10; • Enabling MCS selection for transmission of small-amount data MOD CELLALGOSWITCH:LOCALCELLID=0,DLSCHSWITCH=SmallPktMcsSelectAlgoSw-1; • Enabling PDCCH and PDSCH resource balancing MOD CELLDLSCHALGO:LOCALCELLID=0,DATATHDINPDCCHPDSCHBAL=36000,UENUMTHDINPDCCHPDSCHBAL=300; • Enabling adaptive power allocation for cell-edge UEs MOD CELLALGOSWITCH:LOCALCELLID=0,CellDlCoverEnhanceSwitch=AdptCellEdgePwrAllocSw-1; 9.7.5 Activation Observation Observing MCS Selection with Prioritized RBs 1. Before enabling MCS selection with prioritized RBs, check the DL IBLER and the DL average MCS. 2. Check the DL IBLER and the DL average MCS after enabling MCS selection with prioritized RBs. If the two values decrease, MCS selection with prioritized RBs has taken effect. IBLER = (L.Traffic.DL.SCH.QPSK.ErrTB.Ibler + L.Traffic.DL.SCH.16QAM.ErrTB.Ibler + L.Traffic.DL.SCH.64QAM.ErrTB.Ibler)/(L.Traffic.DL.SCH.QPSK.TB + L.Traffic.DL.SCH.16QAM.TB + L.Traffic.DL.SCH.64QAM.TB) Average MCS index for the DL = (L.ChMeas.PDSCH.MCS.0 x 0 + L.ChMeas.PDSCH.MCS.1 x 1 + ... + L.ChMeas.PDSCH.MCS.28 x 28)/sum(L.ChMeas.PDSCH.MCS.0... L.ChMeas.PDSCH.MCS.28) Observing PDCCH and PDSCH Resource Balancing 1. Check the average number of users in the cell. When the number of users reaches the value of CellDlschAlgo.UeNumThdInPdcchPdschBal and the volume of traffic data to be scheduled on user bearers is greater than or equal to the value of CellDlschAlgo.DataThdInPdcchPdschBal, the trigger condition for PDCCH and PDSCH resource balancing applies. 2. Check the PDCCH resource utilization. When the number of OFDM symbols occupied by the PDCCH reaches the maximum and CCE usage reaches around 80%, PDCCH resource congestion occurs. CCE usage = (L.ChMeas.CCE.CommUsed + L.ChMeas.CCE.ULUsed + L.ChMeas.CCE.DLUsed)/L.ChMeas.CCE.Avail 3. Check the downlink PDSCH resource utilization. If the RB usage is not high, PDCCH and PDSCH resources are imbalanced in the cell. RB usage = L.ChMeas.PRB.DL.Used.Avg/L.ChMeas.PRB.DL.Avail Table 9-5 Counters related to PDCCH and PDSCH resource balancing Counter Name Description L.Traffic.User.Avg Average number of users in a cell L.ChMeas.PDCCH.SymNum.1~4 Number of times that the PDCCH occupies x OFDM symbols (x ranging from 1 to 4) L.ChMeas.CCE.CommUsed Number of PDCCH CCEs used for common DCI L.ChMeas.CCE.ULUsed Number of PDCCH CCEs used for uplink DCI L.ChMeas.CCE.DLUsed Number of PDCCH CCEs used for downlink DCI L.ChMeas.CCE.Avail Number of available PDCCH CCEs L.ChMeas.PRB.DL.Used.Avg Average number of used PDSCH PRBs L.ChMeas.PRB.DL.Avail Number of available downlink PRBs 4. Compare the RB usage within the same period of service time before and after PDCCH and PDSCH resource balancing is enabled. If the RB usage increases, this function has taken effect. Observing Adaptive Power Allocation for Cell-Edge UEs 1. Before enabling the function, obtain the percentage of PRBs scheduled for PDSCH transmission using rank 1 and MCSs of indexes 0 to 6. The formula for calculating the percentage is as follows: Percentage of PRBs scheduled for PDSCH transmission using rank 1 and MCSs of indexes 0 to 6 = Sum of L.ChMeas.PRB.DL.RANK1.MCS.0 to L.ChMeas.PRB.DL.RANK1.MCS.6/Sum of L.ChMeas.PRB.DL.RANK1.MCS.0 to L.ChMeas.PRB.DL.RANK1.MCS.28 2. Check that the percentage decreases after the function is enabled. The decrease indicates that the function has taken effect. 9.7.6 Reconfiguration None 9.7.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Disabling MCS selection with prioritized RBs Run the MOD CELLDLSCHALGO command with the RB Priority MCS Select Ratio Threshold parameter set to 0. • Disabling MCS selection for transmission of small-amount data Run the MOD CELLALGOSWITCH command with the SmallPktMcsSelectAlgoSw option of the DL schedule switch parameter deselected. • Disabling PDCCH and PDSCH resource balancing Run the MOD CELLDLSCHALGO command with the Data Threshold In Pdcch And Pdsch Balance and Ue Num Threshold In Pdcch And Pdsch Balance parameters specified. • Disabling adaptive power allocation for cell-edge UEs Run the MOD CELLALGOSWITCH command with the AdptCellEdgePwrAllocSw option of the Downlink Cell Coverage Enhancement Switch parameter deselected. MML Command Examples • Disabling MCS selection with prioritized RBs MOD CELLDLSCHALGO: LOCALCELLID=0, RBPRIMCSSELECTRATIOTHD=0; • Disabling MCS selection for transmission of small-amount data MOD CELLALGOSWITCH:LOCALCELLID=0,DLSCHSWITCH=SmallPktMcsSelectAlgoSw-0; • Disabling PDCCH and PDSCH resource balancing MOD CELLDLSCHALGO: LOCALCELLID=0, DATATHDINPDCCHPDSCHBAL=0, UENUMTHDINPDCCHPDSCHBAL=0; • Disabling adaptive power allocation for cell-edge UEs MOD CELLALGOSWITCH:LOCALCELLID=0,CellDlCoverEnhanceSwitch=AdptCellEdgePwrAllocSw-0; 9.8 Performance Monitoring DL Scheduling In DL scheduling, the features helping improve DL spectral efficiency may cause the value of L.Traffic.ActiveUser.DL.Avg to decrease. MBR>GBR Configuration Observe the resource occupation ratio on the PDSCH and throughput of GBR services with different QCIs. • Calculate the resource occupation ratio on the PDSCH using the following formula: L.ChMeas.PRB.DL.Used.Avg/L.ChMeas.PRB.DL.Avail • Observe throughput of GBR services with different QCIs: ◾ L.Thrp.bits.DL.QCI.1 ◾ L.Thrp.bits.DL.QCI.2 ◾ L.Thrp.bits.DL.QCI.3 ◾ L.Thrp.bits.DL.QCI.4 Set GBR and MBR to different values for the to-be-observed GBR bearer in the EPC. If the resource occupation ratio on the PDSCH is low (for example, 50%) and there is a GBR service whose data rate is greater than the configured GBR, check that the data rate of the GBR service increases after the MBR>GBR Configuration feature is activated. 9.9 Parameter Optimization N/A 9.10 Possible Issues N/A 10 Engineering Guidelines for Enhanced DL Scheduling Features This chapter provides engineering guidelines for the following features: • LBFD-00101501 CQI Adjustment • LBFD-00101502 Dynamic Scheduling • LOFD-001109 DL Non-GBR Packet Bundling • LOFD-110205 Traffic Model Based Performance Optimization 10.1 When to Use 10.1.1 LBFD-00101501 CQI Adjustment CQI adjustment is recommended for use. It is an enhanced feature for DL scheduling. This feature uses a closed-loop MCS adjustment mechanism to correct UE-reported CQIs and combat channel condition changes during the time between CQI reporting and scheduling. In addition, CQI adjustment enables the DL IBLER to converge on the target value and therefore increases DL throughput. DlVarIBLERtargetSwitch controls whether to use adaptive target IBLER values. If this switch is on, the throughput of cell edge users can be increased and the spectral efficiency of users performing small-TB services can be improved. The enhanced function of DL target IBLER adaptation increases DL throughput when the channel quality fluctuates or when the proportion of small-packet data transmission is high. However, this enhanced function may increase the RBLER. 10.1.2 LBFD-00101502 Dynamic Scheduling You are advised to enable dynamic scheduling to strike a balance between scheduling fairness, cell capacity, and service QoS satisfaction. 10.1.3 LOFD-001109 DL Non-GBR Packet Bundling DL Non-GBR Packet Bundling applies to scenarios where PDCCH resources are insufficient (for example, the PDCCH CCE usage is approximately greater than 70%) while PDSCH resources are still available (for example, the DL RB usage is approximately less than 95%). 10.1.4 LOFD-110205 Traffic Model Based Performance Optimization This feature is recommended when the cell traffic load is high (PRB usage > 60%). You are advised to enable the Traffic Model Based Performance Optimization feature in the uplink and downlink at the same time. For details about deploying this feature in the uplink, see 12.4 Deploying the Traffic Model Based Performance Optimization Feature. 10.2 Required Information None 10.3 Planning None 10.4 Deploying CQI Adjustment 10.4.1 Requirements Operating Environment N/A Transmission Networking N/A License N/A 10.4.2 Precautions None 10.4.3 Data Preparation This section describes the data that you need to collect for setting parameters. Required data is data that you must collect for all scenarios. Collect scenario-specific data when necessary for a specific feature deployment scenario. 10.4.3.1 Required Data The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure CQI adjustment for a cell. Parameter Name Parameter ID Setting Notes CQI Adjust Algorithm Switch CellAlgoSwitch.CqiAdjAlgoSwitch In common operations, you are advised to select the CqiAdjAlgoSwitch option of this parameter. For setting suggestions, see 10.1.1 LBFD-00101501 CQI Adjustment. 10.4.3.2 Scenario-specific Data 10.4.3.2.1 DL Target IBLER Adaptation The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure DL target IBLER adaptation. Parameter Name Parameter ID Setting Notes CQI Adjust Algorithm Switch CellAlgoSwitch.CqiAdjAlgoSwitch If the channel quality fluctuates greatly, you are advised to select the DlEnVarIblerTargetSwitch(DlEnVarIblerTargetSwitch) option of this parameter. To increase the throughput of cell edge UEs and improve the spectral efficiency for UEs running services of small TBs, you are advised to select the DlVarIBLERtargetSwitch option of this parameter. The following table describes the parameters that must be set in a CellDlschAlgo MO to configure flexible target IBLER adaptation. Parameter Name Parameter ID Setting Notes TBS Index Threshold for Low Target IBLER CellDlschAlgo.LowIblerTargetTbsIdxThld Set this parameter to its recommended value. TBS Index Threshold for High Target IBLER CellDlschAlgo.HighIblerTargetTbsIdxThld Set this parameter to its recommended value. 10.4.3.2.2 Optimized CQI Adjustment Value The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure DL CQI adjustment optimization for a cell. Parameter Name Parameter ID Setting Notes CQI Adjust Algorithm Switch CellAlgoSwitch.CqiAdjAlgoSwitch DlCqiAdjDeltaOptSwitch under this parameter specifies whether to use the optimized method for calculating the CQI adjustment value. When this switch is set to ON, the DL IBLER convergence and DL throughput are improved. It is good practice to set this switch to ON to prevent delayed CQI adjustment due to a prolonged CQI adjustment period when the cell serves a massive number of users. 10.4.3.2.3 Step for CQI Adjustment The following table describes the parameter that must be set in a CellDlschAlgo MO to configure the initial step for CQI adjustment. Parameter Name Parameter ID Setting Notes CQI Adjustment Initial Step CellDlschAlgo.CqiAdjInitialStep This parameter specifies the initial step for the CQI Adjustment feature. Decreasing the initial step increases the handover success rate and reduces the DL RBLER, but may reduce DL throughput of UEs in the event of initial access and handovers. Increasing the initial step may decrease the handover success rate and raise the DL RBLER, but can increase DL throughput of UEs in the event of initial access and handovers. The default value is recommended. The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure CQI adjustment step adaptation. Parameter Name Parameter ID CQI Adjust Algorithm Switch CellAlgoSwitch.CqiAdjAlgoSwitch Setting Notes • The StepVarySwitch option of this parameter specifies whether to enable variable-step-based CQI adjustment. The default value is recommended. • The AdaptiveStepVarySwitch option of this parameter specifies whether to enable adaptive CQI adjustment step variation. It is recommended that the AdaptiveStepVarySwitch option be selected if IBLERs need to approach the target IBLER quickly. 10.4.3.2.4 Initial Value of CQI Adjustment The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure adaptive compensation for the initial value of CQI adjustment. Parameter Name Parameter ID Setting Notes CQI Adjust Algorithm Switch CellAlgoSwitch.CqiAdjAlgoSwitch The PreciseMcsAdaptSwitch(PreciseMcsAdaptSwitch) option of this parameter specifies whether to enable adaptive compensation for the initial value of CQI adjustment. Parameter Name Parameter ID Setting Notes The default value is recommended. 10.4.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Enabling CQI adjustment Run the MOD CELLALGOSWITCH command with the CqiAdjAlgoSwitch option of the CQI Adjust Algorithm Switch parameter selected. • Enabling DL target IBLER adaptation Run the MOD CELLALGOSWITCH command with the DlVarIBLERtargetSwitch option of the CQI Adjust Algorithm Switch parameter selected. • Enabling the enhanced function of DL target IBLER adaptation Run the MOD CELLALGOSWITCH command with the DlEnVarIblerTargetSwitch option of the CQI Adjust Algorithm Switch parameter selected. • Enabling flexible target IBLER adaptation Run the MOD CELLDLSCHALGO command with the TBS Index Threshold for Low Target IBLER and TBS Index Threshold for High Target IBLER parameters specified. • Enabling DL CQI adjustment optimization Run the MOD CELLALGOSWITCH command with the DlCqiAdjDeltaOptSwitch option of the CQI Adjust Algorithm Switch parameter selected. • Setting the initial step for CQI adjustment Run the MOD CELLDLSCHALGO command with the CQI Adjustment Initial Step parameter specified. • Enabling adaptive compensation for the initial value of CQI adjustment Run the MOD CELLALGOSWITCH command with the PreciseMcsAdaptSwitch(PreciseMcsAdaptSwitch) option of the CQI Adjust Algorithm Switch parameter selected. • Enabling the function of adaptive CQI adjustment step variation Run the MOD CELLALGOSWITCH command with the AdaptiveStepVarySwitch option of the CQI Adjust Algorithm Switch parameter selected. MML Command Examples //Enabling CQI adjustment MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=CqiAdjAlgoSwitch-1; //Enabling DL target IBLER adaptation MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=DlVarIBLERtargetSwitch-1; //Enabling the enhanced function of DL target IBLER adaptation MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=DlEnVarIblerTargetSwitch-1; //Enabling flexible target IBLER adaptation MOD CELLDLSCHALGO:LOCALCELLID=0,LowIblerTargetTbsIdxThld=21,HighIblerTargetTbsIdxThld=5; //Enabling optimized CQI adjustment value MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=DlCqiAdjDeltaOptSwitch-1; //Setting the initial step for CQI adjustment MOD CELLDLSCHALGO: LOCALCELLID=0, CQIADJINITIALSTEP=1; //Enabling adaptive compensation for the initial value of CQI adjustment MOD CELLALGOSWITCH:LOCALCELLID=0,CQIADJALGOSWITCH=PreciseMcsAdaptSwitch-1; //Enabling the function of adaptive CQI adjustment step variation MOD CELLALGOSWITCH:LOCALCELLID=0,CQIADJALGOSWITCH=AdaptiveStepVarySwitch-1; 10.4.5 Activation Observation This section describes the procedures for verifying the activation of CQI adjustment. The following examples show test results for commercial UEs in cells with a bandwidth of 20 MHz. Observing CQI Adjustment (Using Performance Counters) Observe the counters listed in Table 10-1, and use the following formula to calculate the downlink IBLER. Check that the downlink IBLER approaches the default value 10%. Table 10-1 Counters related to CQI adjustment Counter Name Description L.Traffic.DL.SCH.QPSK.ErrTB.Ibler Number of downlink error TBs after initial transmission in QPSK modulation mode L.Traffic.DL.SCH.16QAM.ErrTB.Ibler Number of downlink error TBs after initial transmission in 16QAM modulation mode L.Traffic.DL.SCH.64QAM.ErrTB.Ibler Number of downlink error TBs after initial transmission in 64QAM modulation mode L.Traffic.DL.SCH.QPSK.TB Number of TBs initially transmitted on the downlink SCH in QPSK modulation mode L.Traffic.DL.SCH.16QAM.TB Number of TBs initially transmitted on the downlink SCH in the 16QAM modulation mode L.Traffic.DL.SCH.64QAM.TB Number of TBs initially transmitted on the downlink SCH in the 64QAM modulation mode Observing CQI Adjustment (Using the U2000) 1. Enable a UE to access a cell in the cell center. 2. On the U2000 client, start channel quality monitoring and BLER monitoring on the UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start BLER monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree, choose LTE > User Performance Monitoring > BLER Monitoring. 3. Perform DL packet injection on the UE so that the UE is scheduled about 1000 times per second in the DL. At the same time, move the UE gradually to the cell edge. 4. Check the DL channel quality and DL IBLER monitoring results. The CQI is approximately 11, and the value of Downlink IBLER(Permillage) fluctuates around 100, which means that the DL IBLER converges on the default value 10%. The results indicate that CQI adjustment has been activated. Observing Target IBLER Adaptation (Using the U2000) 1. Enable a UE to access a cell in the cell center. 2. On the U2000 client, start BLER monitoring on the UE. a. Choose Monitor > Signaling Trace > Signaling Trace Management. b. In the navigation tree, choose LTE > User Performance Monitoring > BLER Monitoring. 3. Perform DL packet injection on the UE. At the same time, move the UE gradually to the cell edge. Check the BLER monitoring results. The DL IBLER approaches 30%. The results indicate that target IBLER adaptation has been activated. If the configured initial DL target IBLER is 15%, check whether the DL IBLER approaches 15%. If the DL IBLER approaches 15%, the parameter setting has taken effect. Observing the Enhanced Function of DL Target IBLER Adaptation (Using the U2000) 1. Enable a UE to access a cell in the cell center. 2. On the U2000 client, start BLER monitoring on the UE. Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose LTE > User Performance Monitoring > BLER Monitoring. 3. Set DlEnVarIblerTargetSwitch on and set DlVarIBLERtargetSwitch off. 4. Perform DL packet injection on the UE. At the same time, move the UE gradually to the cell edge. Check the BLER monitoring results. The DL IBLER approaches 30%. The results indicate that enhanced target IBLER adaptation has been activated. 10.4.6 Reconfiguration None 10.4.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Disabling DL CQI adjustment optimization Run the MOD CELLALGOSWITCH command with the DlCqiAdjDeltaOptSwitch option of the CQI Adjust Algorithm Switch parameter deselected. • Setting the initial step for CQI adjustment Run the MOD CELLDLSCHALGO command with the CQI Adjustment Initial Step parameter specified. • Disabling flexible target IBLER adaptation Run the MOD CELLDLSCHALGO command with the TBS Index Threshold for Low Target IBLER parameter specified. • Disabling the enhanced function of DL target IBLER adaptation Run the MOD CELLALGOSWITCH command with the DlEnVarIblerTargetSwitch option of the CQI Adjust Algorithm Switch parameter deselected. • Disabling the function of adaptive CQI adjustment step variation Run the MOD CELLALGOSWITCH command with the AdaptiveStepVarySwitch option of the CQI Adjust Algorithm Switch parameter deselected. • Disabling DL target IBLER adaptation Run the MOD CELLALGOSWITCH command with the DlVarIBLERtargetSwitch option of the CQI Adjust Algorithm Switch parameter deselected. • Disabling adaptive compensation for the initial value of CQI adjustment Run the MOD CELLALGOSWITCH command with the PreciseMcsAdaptSwitch option of the CQI Adjust Algorithm Switch parameter deselected. • Disabling CQI adjustment Run the MOD CELLALGOSWITCH command to disable CQI adjustment. MML Command Examples //Disabling DL CQI adjustment optimization MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=DlCqiAdjDeltaOptSwitch-0; //Setting the initial step for CQI adjustment MOD CELLDLSCHALGO: LOCALCELLID=0, CQIADJINITIALSTEP=0; //Disabling flexible target IBLER adaptation MOD CELLDLSCHALGO:LOCALCELLID=0,LowIblerTargetTbsIdxThld=255; //Disabling the enhanced function of DL target IBLER adaptation MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=DlEnVarIblerTargetSwitch-0; //Disabling the function of adaptive CQI adjustment step variation MOD CELLALGOSWITCH:LOCALCELLID=0,CQIADJALGOSWITCH=AdaptiveStepVarySwitch-0; //Disabling DL target IBLER adaptation MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=DlVarIBLERtargetSwitch-0; MOD CELLCQIADJALGO: LOCALCELLID=0, InitDlIblerTarget=10; //Disabling adaptive compensation for the initial value of CQI adjustment MOD CELLALGOSWITCH:LOCALCELLID=0,CQIADJALGOSWITCH=PreciseMcsAdaptSwitch-0; //Disabling CQI adjustment MOD CELLALGOSWITCH: LOCALCELLID=0, CQIADJALGOSWITCH=CqiAdjAlgoSwitch-0; 10.5 Deploying Dynamic Scheduling 10.5.1 Requirements Operating Environment • Before enabling DL frequency selective scheduling, enable the function of dynamic adjustment on the number of OFDM symbols occupied by the PDCCH. For details, see Physical Channel Resource Management Feature Parameter Description. • Doppler measurement level selection LBBPc boards of macro base stations do not support Doppler measurement level selection. Micro base stations do not support Doppler measurement level selection. • The EPF enhancement function requires UL smart preallocation or UL preallocation to be enabled. In addition, it is recommended that the RrcConnStateTimer.UeInactiveTimer parameter be set to a value greater than or equal to 20, further improving the gains yielded by the EPF enhancement function in user-perceived data rates. Transmission Networking N/A License N/A 10.5.2 Precautions Online reconfiguration of DL frequency selective scheduling is not supported. UEs need to access the network again when the status of the switch for DL frequency selective scheduling is changed. 10.5.3 Data Preparation This section describes the data that you need to collect for setting parameters. Required data is data that you must collect for all scenarios. Collect scenario-specific data when necessary for a specific feature deployment scenario. 10.5.3.1 Required Data The following table describes the parameters that must be set in a CellDlschAlgo MO to set the DL scheduling policy for each cell, reserved resource proportion for non-GBR services, and capacity adjustment factor for DL EPF scheduling. Table 10-2 Parameters that must be set in a CellDlschAlgo MO Parameter Name Parameter ID Setting Notes Downlink scheduling Strategy CellDlschAlgo.DlschStrategy It is recommended that this parameter be set to DLSCH_PRI_TYPE_EPF(EPF). Reserved resource ratio for non-GBR services CellDlschAlgo.NonGbrResourceRatio The default value is recommended. Downlink EPF capacity factor CellDlschAlgo.DlEpfCapacityFactor • When this parameter is set to EPF_CAPC_FACTOR_1(1), a balance between UE fairness and cell capacity can be achieved. • If cell capacity maximization is preferred, you are advised to set this parameter to a larger value. However, the amounts of resources allocated to UEs are of great difference. • If resource allocation fairness between UEs is preferred, you are advised to set this parameter to a smaller value. However, the cell capacity is decreased. 10.5.3.2 Scenario-specific Data 10.5.3.2.1 QCI Configurations for DL Non-GBR Services The following table describes the parameters that must be set in the QciPara MO to specify QCI parameters for DL non-GBR services. Parameter Name Parameter ID Setting Notes QoS Class Identifier QciPara.Qci Set this parameter according to operator policies. Downlink MinGBR QciPara.DlMinGbr In common operations, the default value is recommended. NOTE: • If this parameter is set to a large value, the Min-GBR (minimum guaranteed bit rate) of high-priority non-GBR services can be guaranteed but the Min-GBR of low-priority non-GBR services may fail to be guaranteed when resources are insufficient. • If this parameter is set to a small value, the response time for non-GBR services may be affected. The following table describes the parameter that must be set in the GlobalProcSwitch MO to specify whether QCI-related parameters take effect. Parameter Name Parameter ID Setting Notes QCI Parameter Effect Flag GlobalProcSwitch.QciParaEffectFlag Set this parameter to ON. 10.5.3.2.2 Doppler Measurement Level Selection The following table describes the parameter that must be set in a CellUlschAlgo MO to specify the Doppler measurement level for each cell that supports enhanced scheduling. Parameter Name Parameter ID Setting Notes Doppler Measurement Level CellUlschAlgo.DopMeasLevel You are advised to set this parameter to the recommended value. Setting this parameter to CLASS_1(CLASS_1) can increase DL frequency selective scheduling gains when frequency selective scheduling is used in the DL. This parameter does not take effect if an LBBPc board is configured. 10.5.3.2.3 RBG Allocation Policy The following table describes the parameter that must be set in a CellDlschAlgo MO to configure the RBG resource allocation policy. Parameter Name Parameter ID Setting Notes RBG Resource Allocation Strategy CellDlschAlgo.RbgAllocStrategy It is recommended that this parameter be set to ADAPTIVE(Adaptive). 10.5.3.2.4 EPF Scheduling Enhancement The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure DL EPF scheduling enhancement for a cell. Parameter Name Parameter ID Setting Notes DL schedule switch CellAlgoSwitch.DlSchSwitch The EpfEnhancedSwitch option of this parameter specifies whether to enable DL EPF scheduling enhancement. The default value is recommended. 10.5.3.2.5 Scheduling Termination for Abnormal UEs The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the function of scheduling termination for abnormal UEs. Parameter Name Parameter ID Setting Notes Cell Schedule Strategy Switch CellAlgoSwitch.CellSchStrategySwitch You are advised to select the AbnUeSchSwitch option of this parameter. The function controlled by this option prevents UEs with abnormal links from overusing system resources, improving resource utilization and reducing the residual BLER in the system. The following table describes the parameter that must be set in a CellDlschAlgo MO to configure the threshold for scheduling termination for abnormal UEs in the DL. Parameter Name Parameter ID Setting Notes Downlink Schedule Abnormal Ue Threshold CellDlschAlgo.DlSchAbnUeThd This parameter is valid only when the AbnUeSchSwitch option of the CellAlgoSwitch.CellSchStrategySwitch parameter is selected. The default value is recommended. 10.5.3.2.6 Stopping Aperiodic CQI Reporting When No Scheduling Is Performed The following table describes the parameter that must be set in a CellDlschAlgo MO to configure the threshold for stopping aperiodic CQI reporting in downlink frequency selective scheduling. The threshold is a period of time in which a UE is not scheduled. Parameter Name Parameter ID Setting Notes No Scheduling Stop Triggering ACqi Thd CellDlschAlgo.NoSchStopACqiThd This parameter is valid only when the FreqSelSwitch(FreqSelSwitch) option of the CellAlgoSwitch.DlSchSwitch parameter is selected. The default value 40 is recommended. The unit is ms. 10.5.3.2.7 DL AMBR Control over Non-GBR Services The following table describes the parameter that must be set in a CellDlSchAlgo MO to configure the period of controlling the downlink AMBR for non-GBR services of a UE. Parameter Name Parameter ID DL UE-AMBR Judge Period CellDlschAlgo.AmbrCtrlTcycle Setting Notes • In most cases, you are advised to set this parameter to the default value AMBR_50_MS(AMBR_50_MS). • If the UE-AMBRs of a large number of UEs on the network are low and the network is not congested, you can increase the value of this parameter. The recommended maximum value is AMBR_500_MS(AMBR_500_MS). • If UE-AMBR control is not required, set this parameter to AMBR_1000_MS(AMBR_1000_MS). 10.5.3.2.8 Delayed Scheduling of DL RLC Status Reports The following table describes the parameter that must be set in a CellAlgoSwitch MO to enable delayed scheduling of DL RLC status reports. Parameter Name Parameter ID Setting Notes DL schedule switch CellAlgoSwitch.DlSchSwitch The DlRLCStateReportSchDelaySw option of this parameter specifies whether to enable delayed scheduling of DL RLC status reports. In most cases, you are advised to deselect this option. Select this option to increase user-perceived DL data rates when all the following conditions are met: Parameter Name Parameter ID Setting Notes • The RlcPdcpParaGroup.RlcParaAdaptSwitch parameter is set to ON(On). • The DL PRB usage, number of RRC_CONNECTED UEs in the cell, and the PDCCH CCE usage are greater than 80%, 200, and 70%, respectively, in big events. 10.5.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Setting the DL scheduling policy Run the MOD CELLDLSCHALGO command with the Downlink scheduling Strategy, Reserved resource ratio for non-GBR services, and Downlink EPF capacity factor parameters specified. • Configuring the QCI for DL non-GBR services 1. Run the MOD QCIPARA command to set QCI parameters for DL non-GBR services. The parameters include QoS Class Identifier and Downlink MinGBR. 2. Run the MOD GLOBALPROCSWITCH command with the QCI Parameter Effect Flag parameter set to ON(On). • Setting the Doppler measurement level Run the MOD CELLULSCHALGO command with the Doppler Measurement Level parameter specified. • Setting the RBG allocation policy Run the MOD CELLDLSCHALGO command with the RBG Resource Allocation Strategy parameter specified. • Enabling EPF scheduling enhancement Run the MOD CELLALGOSWITCH command with the EpfEnhancedSwitch option of the DL schedule switch parameter selected. • Enabling the function of scheduling termination for abnormal UEs Run the MOD CELLALGOSWITCH command with the AbnUeSchSwitch option of the Cell Schedule Strategy Switch parameter selected. Run the MOD CELLDLSCHALGO command with the Downlink Schedule Abnormal Ue Threshold parameter specified. • Setting the threshold for stopping aperiodic CQI reporting Run the MOD CELLDLSCHALGO command with the No Scheduling Stop Triggering ACqi Thd parameter specified. • Enabling delayed scheduling of DL RLC status reports Run the MOD CELLALGOSWITCH command with the DLRLCStateReportSchDelaySw option of the DL schedule switch parameter selected. MML Command Examples • Setting the DL scheduling policy MOD CELLDLSCHALGO: LOCALCELLID=0, DLSCHSTRATEGY=DLSCH_PRI_TYPE_EPF, NONGBRRESOURCERATIO=0, DLEPFCAPACITYFACTOR=EPF_CAPC_FACTOR_1; • Configuring the QCI for DL non-GBR services MOD QCIPARA: QCI=QCI6, DLMINGBR=MinGbrRate_1_KB; MOD GLOBALPROCSWITCH: QciParaEffectFlag=ON; • Setting the Doppler measurement level MOD CELLULSCHALGO: LOCALCELLID=0, DOPMEASLEVEL=CLASS_0; • Setting the RBG allocation policy MOD CELLDLSCHALGO: LOCALCELLID=0, RBGALLOCSTRATEGY=ROUND_DOWN; • Enabling EPF scheduling enhancement MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=EpfEnhancedSwitch-1; • Enabling the function of scheduling termination for abnormal UEs MOD CELLALGOSWITCH: LOCALCELLID=0, CELLSCHSTRATEGYSWITCH=AbnUeSchSwitch-1; MOD CELLDLSCHALGO: LOCALCELLID=0, DLSCHABNUETHD=15; • Setting the threshold for stopping aperiodic CQI reporting MOD CELLDLSCHALGO: LOCALCELLID=0, NOSCHSTOPACQITHD=5; • Enabling delayed scheduling of DL RLC status reports MOD CELLALGOSWITCH:LOCALCELLID=0,DlSchSwitch=DLRLCStateReportSchDelaySw-1; 10.5.5 Activation Observation This section describes the procedures for verifying the activation of DL dynamic scheduling. The following examples show test results for commercial UEs in cells with a bandwidth of 20 MHz. Observing EPF for DL Scheduling (Using Performance Counters) To observe whether EPF has taken effect for DL scheduling, observe the values of counters listed in Table 10-3 and observe the traffic volume and duration of services with different QCIs. Table 10-3 Counters related to DL enhanced scheduling Counter Name Description L.Thrp.bits.DL.QCI.1~9 Downlink traffic volume of PDCP SDUs of services with a QCI of x in a cell L.Thrp.Time.DL.QCI.1~9 Transmission duration of downlink PDCP SDUs for services with a QCI of x in a cell If the value of L.Thrp.bits.DL.QCI.6 is higher than that of L.Thrp.bits.DL.QCI.9 within the same period of service time, EPF has taken effect for DL scheduling. Observing EPF for DL Scheduling (Using the U2000) To observe whether EPF has taken effect for DL scheduling, perform the following steps: 1. Enable two UEs to access a cell in the cell center. 2. On the U2000 client, start channel quality monitoring and MCS-based count monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree, choose LTE > User Performance Monitoring > MCS Count Monitoring. 3. Check the channel quality monitoring results of each UE. For example, the CQI for both UEs is 15. 4. Run the LST QCIPARA command to query the DL scheduling weight factors for QCIs 6 and 9. 5. Perform a DL service with QCI 6 on UE 1 and a DL service with QCI 9 on UE 2. 6. Check the MCS-based count monitoring results for the number of DL RBs allocated to each UE. If the ratio of the number for UE 1 to the number for UE 2 is approximately equal to the ratio of the weight factor for QCI 6 to the weight factor for QCI 9, EPF for DL scheduling has been activated successfully. Observing the Round-Up Function for RBGs To observe whether the round-up function for RBGs has taken effect, perform the following steps: 1. Start RB usage monitoring on the U2000: Choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > Cell Performance Monitoring > Usage of RB Monitoring. 2. Enable a large number of UEs (such as 20 UEs) to access a cell. Originate traffic bursts in the cell and keep the RB usage at a low level (such as 50%). Record the actual RB usage. 3. Set the GBR round-up switch to ON. If the RB usage rises, the round-up function for RBGs has taken effect. Observing the EPF Scheduling Enhancement Function To observe whether the EPF scheduling enhancement function has taken effect, perform the following steps: 1. In mobile broadband (MBB) scenarios, calculate throughput using the following formula: Throughput = L.Thrp.bits.DL/L.Thrp.Time.DL 2. Set the switch of the EPF scheduling enhancement function to ON. 3. Compare the throughput before and after the switch is set to ON. If the throughput increases, the EPF scheduling enhancement function has taken effect. 10.5.6 Reconfiguration None 10.5.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Disabling EPF scheduling enhancement Run the MOD CELLALGOSWITCH command with the EpfEnhancedSwitch option of the DL schedule switch parameter deselected. • Disabling the function of scheduling termination for abnormal UEs Run the MOD CELLALGOSWITCH command with the AbnUeSchSwitch option of the Cell Schedule Strategy Switch parameter deselected. • Disabling delayed scheduling of DL RLC status reports Run the MOD CELLALGOSWITCH command with the DLRLCStateReportSchDelaySw option of the DL schedule switch parameter deselected. MML Command Examples • Disabling EPF scheduling enhancement MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=EpfEnhancedSwitch-0; • Disabling the function of scheduling termination for abnormal UEs MOD CELLALGOSWITCH: LOCALCELLID=0, CELLSCHSTRATEGYSWITCH=AbnUeSchSwitch-0; • Disabling delayed scheduling of DL RLC status reports MOD CELLALGOSWITCH:LOCALCELLID=0, DlSchSwitch=DLRLCStateReportSchDelaySw-0; 10.6 Deploying DL Non-GBR Packet Bundling 10.6.1 Requirements Operating Environment N/A Transmission Networking N/A License Operators must purchase and activate the following license. Feature ID Feature Name Model License Control Item NE Sales Unit LOFD-001109 DL Non-GBR Packet Bundling LT1S0DLNPB00 DL Non-GBR Packet Bundling (FDD) eNodeB per cell 10.6.2 Precautions None 10.6.3 Data Preparation The following table describes the parameter that must be set in the CellAlgoSwitch MO to enable DL non-GBR packet bundling for each cell. Parameter Name Parameter ID Setting Notes DL schedule switch CellAlgoSwitch.DlSchSwitch The NonGbrBundlingSwitch option of this parameter specifies whether to enable DL non-GBR packet bundling. 10.6.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the NonGbrBundlingSwitch(NonGbrBundlingSwitch) option of the DL schedule switch parameter selected. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=NonGbrBundlingSwitch-1; 10.6.5 Activation Observation This section uses a cell with 10 MHz bandwidth and six test UEs as an example to describe how to observe the effectiveness of DL Non-GBR Packet Bundling. Scenario 1: Cell Delay Distribution Improvement Expected 1. Change the cell bandwidth to 10 MHz, and change the number of PDCCH symbols of the cell to 1. MOD CELL: LOCALCELLID=0, ULBANDWIDTH=CELL_BW_N50, DLBANDWIDTH=CELL_BW_N50; MOD CELLPDCCHALGO: LOCALCELLID=0, INITPDCCHSYMNUM=1, PDCCHSYMNUMSWITCH=OFF; 2. Use six test UEs to attach to the cell from the cell center, and move them to the cell edge. Then, inject 500,000 downlink packets of 100 bytes each to each UE. The scripts for packet injection on the server on the eNodeB side are as follows: iperf -c UEIP -u -b 500k -l 100 -t 999999 -i 1 3. On the U2000, start the following monitoring tasks for the test UEs: • MCS-based count monitoring Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose User Performance Monitoring > MCS Count Monitoring. • Cell DCI monitoring Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose Cell Performance Monitoring > DCI Statistic Monitoring. • Cell RB usage monitoring Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose Cell Performance Monitoring > Usage of RB Monitoring. • Cell data radio bearer (DRB) monitoring Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose Cell Performance Monitoring > DRB Statistic Monitoring. 4. Adjust the signal quality of the test UEs to achieve the following: • The UEs are scheduled in the DL with the MCS index of around 7 (the scheduling frequency is specified by DLSCH Code0 Num7). NOTE: The aim of adjusting the signal quality of the test UEs is to degrade the quality of the PDCCH for the UEs. After the quality of the PDCCH is degraded, an increased CCE aggregation level is used and more CCEs are consumed so that PDCCH congestion occurs. If the value of Processing Delay of PDCP SDUs with QCI9 does not increase significantly according to the monitoring results shown in Figure 10-4, PDCCH congestion has not occurred. In this situation, further decrease the signal quality of the test UEs. • The sum of the UL DCI usage (specified by UL DCI Utilization Within a Monitoring Period) and the DL DCI usage (specified by DL DCI Utilization Within a Monitoring Period) for these UEs is greater than 80%. • The DL cell RB usage is between 60% and 80%. Figure 10-1 Example of MCS count monitoring Figure 10-2 Example of cell DCI monitoring Figure 10-3 Example of RB usage monitoring 5. Collect statistics on the average delay for packets with QCI 9 for a 2-minute period. The calculation formula is as follows: Average delay for packets with QCI 9 = Processing Delay of PDCP SDUs with QCI9/Number of Succ Trans DL PDCP SDUs with QCI9 Figure 10-4 Example of DRB monitoring 6. Enable DL Non-GBR Packet Bundling. MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=NonGbrBundlingSwitch-1; 7. Collect statistics on the average delay for packets with QCI 9 for a 2-minute period. The following table provides the statistics about the delay for packets with QCI 9. Measurement Point Average Delay (ms) Maximum Delay (ms) Delay Variance (ms x ms) 3 minutes before DL Non-GBR Packet Bundling is enabled 556.03 775.31 6340.73 3 minutes after DL Non-GBR Packet Bundling is enabled 46.32 65.96 104.51 Scenario 2: TCP Throughput Increase Expected In this scenario, perform the following steps to observe whether DL Non-GBR Packet Bundling has increased the TCP throughput: 1. Change the cell bandwidth to 10 MHz, and change the number of PDCCH symbols of the cell to 1. MOD CELL: LOCALCELLID=0, ULBANDWIDTH=CELL_BW_N50, DLBANDWIDTH=CELL_BW_N50; MOD CELLPDCCHALGO: LOCALCELLID=0, INITPDCCHSYMNUM=1, PDCCHSYMNUMSWITCH=OFF; 2. Use six test UEs to attach to the cell from the cell center, and move them to the cell edge. • Inject 500,000 downlink packets of 100 bytes each to five UEs. The script for packet injection on the server is as follows: iperf -c UEIP -u -b 500k -l 100 -t 999999 -i 1 • Simulate downlink TCP traffic for the other UE. The script for packet injection on the server is as follows: iperf -c UEIP -w 512k -t 9999999 -i 1 3. On the U2000, start the following monitoring tasks for the test UEs: • MCS-based count monitoring Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose User Performance Monitoring > MCS Count Monitoring. • Cell DCI monitoring Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose Cell Performance Monitoring > DCI Statistic Monitoring. • Cell RB usage monitoring Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose Cell Performance Monitoring > Usage of RB Monitoring. • Cell DRB monitoring Choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose Cell Performance Monitoring > DRB Statistic Monitoring. 4. Start a TCP throughput monitoring task. On the U2000, choose Monitor > Signaling Trace > Signaling Trace Management. In the navigation tree, choose User Performance Monitoring > Throughput Monitoring. 5. Adjust the signal quality of the test UEs to achieve the following: The UEs are scheduled in the DL with the MCS index of around 7 (the scheduling frequency is specified by DLSCH Code0 Num7). The sum of the UL and DL DCI usages for these UEs is greater than 80%. The DRB monitoring results in this example show that the average delay for packets with QCI 9 is longer than 500 ms, which is excessive (the calculation formula: Processing Delay of PDCP SDUs with QCI9/Number of Succ Trans DL PDCP SDUs with QCI9). Figure 10-5 Example of MCS count monitoring Figure 10-6 Example of cell DCI monitoring Figure 10-7 Example of DRB monitoring 6. Observe the TCP throughput. The average TCP throughput is about 1 Mbit/s. Figure 10-8 Example of throughput monitoring for TCP service 7. Enable DL Non-GBR Packet Bundling. MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=NonGbrBundlingSwitch-1; Observe the TCP throughput. After this feature is enabled, the average TCP throughput increases to about 1.8 Mbit/s. Figure 10-9 Example of throughput monitoring for TCP service 10.6.6 Reconfiguration None 10.6.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the NonGbrBundlingSwitch(NonGbrBundlingSwitch) option of the DL schedule switch parameter deselected. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=NonGbrBundlingSwitch-0; 10.7 Deploying the Traffic Model Based Performance Optimization Feature 10.7.1 Requirements Operating Environment In CA scenarios, all CA cells must have this feature enabled. In performance analysis, all CA cells need to be observed. Transmission Networking N/A License Operators must purchase and activate the following license. Feature ID Feature Name Model License Control Item NE LOFD-110205 Traffic Model Based Performance Optimization LT1S00PLAS00 Traffic Model Based Performance eNodeB Optimization (FDD) Sales Unit per cell 10.7.2 Precautions None 10.7.3 Data Preparation The following table describes the parameters that must be set in a CellAlgoSwitch MO to configure the Traffic Model Based Performance Optimization feature. Parameter Name Parameter ID Setting Notes Local cell ID CellAlgoSwitch.LocalCellId This parameter specifies the local identifier of the cell. Set this parameter based on the network plan. Ensure that this parameter has been set in the related Cell MO. Parameter Name Parameter ID Setting Notes DL schedule switch CellAlgoSwitch.DlSchSwitch The DlPacketLenAwareSchSw(DlPacketLenAwareSchSw) option of this parameter specifies whether to enable Traffic Model Based Performance Optimization in the downlink. 10.7.4 Activation This feature can be activated using the CME or MML commands. Using the CME • Fast batch activation This feature can be batch activated using the Feature Operation and Maintenance function of the CME. For detailed operations, see the following section in the CME product documentation or online help: CME Management > CME Guidelines > Enhanced Feature Management > Feature Operation and Maintenance. • Single/batch configuration This feature can be activated for a single eNodeB or a batch of eNodeBs on the CME. For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the DlPacketLenAwareSchSw(DlPacketLenAwareSchSw) option of the DL schedule switch parameter selected to enable Traffic Model Based Performance Optimization in the downlink. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=DlPacketLenAwareSchSw-1; 10.7.5 Activation Observation 1. Check the number of users and RB usage in the cell. It is easy to observe the gains yielded by the Packet Length Awareness Performance Optimization feature when the cell traffic load is heavy. Recommended configurations: • The cell serves more than 150 users. • DL RB usage is greater than 60%. To start cell RB usage monitoring, choose Monitor > Signaling Trace > Signaling Trace Management on the U2000. In the navigation tree, choose Cell Performance Monitoring > Usage of RB Monitoring. 2. Adjust service configurations. Recommended service configurations: • Average data rate for large-packet services: around 8 Mbit/s • Average data rate for small-packet services: around 12 kbit/s • Ratio of large-packet services to small-packet services: 1:4 3. Check perceivable user throughput after activating the feature for a while. If perceivable user throughput increases by 5% or higher, the Packet Length Awareness Performance Optimization feature has taken effect. 10.7.6 Reconfiguration None 10.7.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the DlPacketLenAwareSchSw(DlPacketLenAwareSchSw) option of the DL schedule switch parameter deselected to disable Traffic Model Based Performance Optimization in the downlink. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, DLSCHSWITCH=DlPacketLenAwareSchSw-0; 10.8 Performance Monitoring DL Scheduling In DL scheduling, the features helping improve DL spectral efficiency may cause the value of L.Traffic.ActiveUser.DL.Avg to decrease. In DL scheduling, the increase in user-perceived DL data rates can be monitored using the following formula: (L.Thrp.bits.DL – L.Thrp.bits.DL.LastTTI)/L.Thrp.Time.DL.RmvLastTTI DL Non-GBR Packet Bundling Observe the resource occupation ratio on the PDCCH and PDSCH and the downlink packet processing delay. • Calculate the resource occupation ratio on the PDCCH using the following formula: (L.ChMeas.CCE.CommUsed + L.ChMeas.CCE.ULUsed + L.ChMeas.CCE.DLUsed)/L.ChMeas.CCE.Avail • Calculate the resource occupation ratio on the PDSCH using the following formula: L.ChMeas.PRB.DL.Used.Avg/L.ChMeas.PRB.DL.Avail • Calculate the downlink packet processing delay using the following formulas: ◾ L.Traffic.DL.PktDelay.Time.QCI.6/L.Traffic.DL.PktDelay.Num.QCI.6 ◾ L.Traffic.DL.PktDelay.Time.QCI.7/L.Traffic.DL.PktDelay.Num.QCI.7 ◾ L.Traffic.DL.PktDelay.Time.QCI.8/L.Traffic.DL.PktDelay.Num.QCI.8 ◾ L.Traffic.DL.PktDelay.Time.QCI.9/L.Traffic.DL.PktDelay.Num.QCI.9 If the resource occupation ratio on the PDCCH is greater than 80% but the resource occupation ratio on the PDSCH is low, PDCCH resources may be insufficient. After activating DL Non-GBR Packet Bundling, check whether the resource occupation ratio on the PDSCH increases and whether the downlink packet processing delay distribution improves. If so, DL Non-GBR Packet Bundling has taken effect. For the LBFD-00101501 CQI Adjustment feature: This feature supports quick configuration of counter collection by feature using the U2000. The measurement for the counters related to this feature can be set in a single operation. These counters are determined by the counter-feature relationships listed in the performance counter reference. For details about the operations, see "Quickly Setting Performance Measurement by Feature" in iManager U2000 MBB Network Management System Product Documentation. The LBFD-00101502 Dynamic Scheduling feature also supports the stated function. 10.9 Parameter Optimization In a lightly loaded cell where the number of UEs with small UE-AMBR values is large, increase the value of the CellDlschAlgo.AmbrCtrlTcycle parameter to increase userperceived data rates. If an operator does not plan to restrict the UE-AMBR, set the CellDlschAlgo.AmbrCtrlTcycle parameter to AMBR_1000_MS(AMBR_1000_MS). For details about this parameter and the setting suggestions, see 4.2.5 DL AMBR Control over Non-GBR Services and 10.5.3.2.7 DL AMBR Control over Non-GBR Services, respectively. 10.10 Possible Issues N/A 11 Engineering Guidelines for Basic UL Scheduling Features This chapter provides engineering guidelines for basic UL scheduling features. The following features are not described in this chapter because they are enabled by default and do not involve configurable parameters: • LBFD-001006 AMC • LBFD-002006 UL Synchronous HARQ 11.1 When to Use 11.1.1 LBFD-002025 Basic Scheduling For details about when to use LBFD-002025 Basic Scheduling, see 9.1.1 LBFD-002025 Basic Scheduling. 11.1.2 LBFD-060102 Enhanced UL Frequency Selective Scheduling It is good practice to enable the Enhanced UL Frequency Selective Scheduling feature. After this feature is enabled, the frequency selective scheduling or interference randomization technique reduces inter-UE interference and therefore increases user throughput. The function of optimized UL frequency selective scheduling based on the estimated UE speed depends on the selection of Doppler measurement level. For details about the selection of Doppler measurement level, see 10.5 Deploying Dynamic Scheduling. 11.1.3 LBFD-070102 MBR>GBR Configuration For details, see 9.1.3 LBFD-070102 MBR>GBR Configuration. 11.2 Required Information None 11.3 Planning None 11.4 Deploying Basic Scheduling 11.4.1 Requirements There is no requirement for the operating environment, transmission networking, and license. 11.4.2 Precautions None 11.4.3 Data Preparation This section describes the data that you need to collect for setting parameters. Required data is data that you must collect for all scenarios. Collect scenario-specific data when necessary for a specific feature deployment scenario. Required Data The following table describes the parameter that must be set in a CellUlschAlgo MO to specify the UL scheduling policy. Parameter Name Parameter ID Setting Notes Uplink Scheduling Strategy CellUlschAlgo.UlschStrategy Select Max C/I, RR, or PF as a basic scheduling policy. Scenario-specific Data The following table describes the parameter that must be set in a CellUlschAlgo MO to specify the maximum number of UL HARQ transmissions. Parameter Name Parameter ID Setting Notes Uplink HARQ Maximum Transmission Number CellUlschAlgo.UlHarqMaxTxNum This parameter specifies the maximum number of HARQ transmissions in the UL. This parameter takes effect only when TTI bundling is disabled. The default value is 5. The following table describes the parameters that must be set in the RlcPdcpParaGroup MO to set the eNodeB-specific timer for reordering at the receiver in AM or UM. Parameter Name Parameter ID Setting Notes Parameter Name Parameter ID AM reordering timer for eNodeB RlcPdcpParaGroup.EnodeBAmReorderingTimer Setting Notes UM reordering timer for eNodeB RlcPdcpParaGroup.EnodeBUmReorderingTimer • Set the parameter to 50 ms or a larger value when the CellUlschAlgo.UlHarqMaxTxNum parameter is set to 7. • Set the parameter to 60 ms or a larger value when CellUlschAlgo.UlHarqMaxTxNum is set to 8. The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the function of increasing the number of RBs to lower the bit rate for UL HARQ retransmissions. Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch The UlLast2RetransSchOptSwitch option of this parameter specifies whether to enable UL HARQ retransmissions to use a lowered code rate. When this option is selected, the UL RBLER and service drop rate decrease but UL throughput may also decrease. When the maximum number of UL HARQ retransmissions retains the default value, UL throughput decreases slightly. The smaller the maximum number of UL HARQ retransmissions, the greater the UL throughput loss. The default value is recommended. The following table describes the parameter that must be set in a CellUlSchAlgo MO to configure the function of optimizing retransmission scheduling for UL voice services. Parameter Name Parameter ID Setting Notes Uplink Enhanced VoIP Schedule Switch CellUlSchAlgo.UlEnhencedVoipSchSw The UlVoipRblerControlSwitch option of this parameter specifies whether to use more RBs for adaptive retransmissions of UL voice services when the optimized scheduling of the last two UL retransmissions is enabled. When this option is selected, the RBLER and packet loss rate for voice services decrease, improving voice quality. (Optional) The following table describes the parameter that must be set in a CellUlSchAlgo MO to specify the maximum number of RBs that can be allocated to each UE in the UL. Parameter Name Parameter ID Setting Notes Max Uplink Scheduling Allocation RB Number CellUlSchAlgo.MaxUlSchRbNum In most cases, retain the default value 255 so that the eNodeB does not restrict the maximum number of RBs that can be allocated to each UE in the UL. To reduce spurious emission from UEs in 10 MHz cells operating on the 900 MHz frequency to other frequencies, set this parameter to 32. The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the PAMC function. Parameter Name Parameter ID Setting Notes Uplink Schedule Extended Switch CellAlgoSwitch.UlSchExtSwitch You are advised to select the UlPAMCSwitch(UlPAMCSwitch) option of this parameter if the average UL MCS index is less than 15 and the MCSs with indexes smaller than 10 are selected on more than 10% occasions of UL scheduling. The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the UL Multi-Cluster function. Parameter Name Parameter ID Uplink Schedule Extended Switch CellAlgoSwitch.UlSchExtSwitch Setting Notes When there are UL frequency spectrum fragments, for example, in the case of PUCCH Flexible Configuration and manual blocking of certain PRBs, select the UlMultiClusterSwitch option of this parameter to enable the UL Multi-Cluster function. 11.4.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Setting the UL scheduling policy Run the MOD CELLULSCHALGO command with the Uplink Scheduling Strategy parameter specified. • Setting the maximum number of UL HARQ retransmissions Run the MOD CELLULSCHALGO command with the Uplink HARQ Maximum Transmission Number parameter specified. Run the MOD RLCPDCPPARAGROUP command with the AM reordering timer for eNodeB or UM reordering timer for eNodeB parameter specified. • Enabling the function of increasing the number of RBs and reducing the code rate for UL HARQ retransmissions Run the MOD CELLALGOSWITCH command with the UlLast2RetransSchOptSwitch option of the Uplink schedule switch parameter selected. Run the MOD CELLULSCHALGO command with the UlVoipRblerControlSwitch option of the Uplink Enhanced VoIP Schedule Switch parameter selected. • (Optional) Setting the maximum number of RBs that can be allocated to each UE in UL scheduling Run the MOD CELLULSCHALGO command with the Max Uplink Scheduling Allocation RB Number parameter specified. • Enabling the PAMC function Run the MOD CELLALGOSWITCH command with the UlPAMCSwitch(UlPAMCSwitch) option of the Uplink Schedule Extended Switch parameter selected. • Enabling the UL Multi-Cluster function Run the MOD CELLALGOSWITCH command with the UlMultiClusterSwitch(UlMultiClusterSwitch) option of the Uplink Schedule Extended Switch parameter selected. MML Command Examples • Setting the UL scheduling policy to PF MOD CELLULSCHALGO: LOCALCELLID=0, ULSCHSTRATEGY=ULSCH_STRATEGY_PF; • Setting the maximum number of UL HARQ retransmissions //Setting the maximum number of UL HARQ retransmissions to 5 MOD CELLULSCHALGO: LOCALCELLID=0, ULHARQMAXTXNUM=5; //Setting the eNodeB-specific timer for reordering at the receiver in AM MOD RLCPDCPPARAGROUP: RLCPDCPPARAGROUPID=0, RLCMODE=RlcMode_AM, ENODEBAMREORDERINGTIMER=Treordering_m50; //Setting the eNodeB-specific timer for reordering at the receiver in UM MOD RLCPDCPPARAGROUP: RLCPDCPPARAGROUPID=0, RLCMODE=RlcMode_UM, ENODEBUMREORDERINGTIMER=Treordering_m50; • Enabling the function of increasing the number of RBs and reducing the code rate for UL HARQ retransmissions MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlLast2RetransSchOptSwitch-1; MOD CELLULSCHALGO: LOCALCELLID=0, ULENHENCEDVOIPSCHSW=UlVoipRblerControlSwitch-1; • (Optional) Setting the maximum number of RBs that can be allocated to each UE in UL scheduling //To reduce spurious emission from UEs in 10 MHz cells operating on the 900 MHz frequency to other frequencies, set this parameter to 32. MOD CELLULSCHALGO: LOCALCELLID=0, MaxUlSchRbNum=32; • Enabling the PAMC function MOD CELLALGOSWITCH:LocalCellId=0,UlSchExtSwitch=UlPAMCSwitch-1; • Enabling the UL Multi-Cluster function MOD CELLALGOSWITCH:LocalCellId=0,UlSchExtSwitch=UlMultiClusterSwitch-1; 11.4.5 Activation Observation This section describes the procedures for verifying the activation of UL scheduling. The following examples show test results for commercial UEs in cells with a bandwidth of 20 MHz. Observing Max C/I for UL Scheduling (Using the U2000) To observe whether Max C/I has been activated for UL scheduling, perform the following steps: 1. Enable two UEs to access a cell. Perform UL packet injection on the default bearer of each UE to ensure that the UL cell throughput reaches its maximum. 2. On the U2000 client, start channel quality monitoring, MCS-based count monitoring, and throughput monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > MCS Count Monitoring. • To start throughput monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Throughput Monitoring. 3. Adjust the locations of the two UEs in the cell so that UE 1 experiences good UL channel quality and UE 2 experiences poor UL channel quality. Monitor channel quality for UE 1 and UE 2. For example, the SINR for UE 1 is approximately 21 dB, and the SINR for UE 2 is approximately 10 dB. 4. Check the MCS-based count monitoring results for the number of UL RBs allocated to each UE. Then check the throughput monitoring results for the UL throughput of each UE. If UE 1 occupies a majority of the total UL cell throughput and has been allocated more RBs than UE 2, Max C/I has been activated successfully. Observing RR for UL Scheduling (Using the U2000) To observe whether RR has been activated for UL scheduling, perform the following steps: 1. Enable two UEs to access a cell in the cell center. Perform a UL service on the default bearer of each UE. 2. On the U2000 client, start channel quality monitoring and MCS-based count monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > MCS Count Monitoring. 3. Monitor channel quality for UE 1 and UE 2. For example, the SINR for both UEs is approximately 21 dB. 4. Check the MCS-based count monitoring results for the number of times each UE is scheduled in the UL. If the results are approximately the same for both UEs, RR has been activated successfully. Observing PF for UL Scheduling (Using the U2000) To observe whether PF has been activated for UL scheduling, perform the following steps: 1. Enable two UEs to access a cell. Perform a UL service on the default bearer of each UE. 2. On the U2000 client, start channel quality monitoring and MCS-based count monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > MCS Count Monitoring. 3. Adjust the locations of the two UEs in the cell so that UE 1 experiences good UL channel quality and UE 2 experiences poor UL channel quality. Monitor channel quality for UE 1 and UE 2. For example, the SINR for UE 1 is approximately 21 dB, and the SINR for UE 2 is approximately 10 dB. 4. Check the MCS-based count monitoring results for the number of UL RBs allocated to each UE. If the results are approximately the same for both UEs, PF has been activated successfully. 11.4.6 Reconfiguration None 11.4.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Setting the maximum number of UL HARQ retransmissions Run the MOD CELLULSCHALGO command with the Uplink HARQ Maximum Transmission Number parameter specified. Run the MOD RLCPDCPPARAGROUP command with the AM reordering timer for eNodeB or UM reordering timer for eNodeB parameter specified. • Disabling the function of increasing the number of RBs and reducing the code rate for UL HARQ retransmissions Run the MOD CELLALGOSWITCH command with the UlLast2RetransSchOptSwitch option of the Uplink schedule switch parameter deselected. Run the MOD CELLULSCHALGO command with the UlVoipRblerControlSwitch option of the Uplink Enhanced VoIP Schedule Switch parameter deselected. • (Optional) Disabling the function of restricting the maximum number of RBs that can be allocated to each UE in the UL Run the MOD CELLULSCHALGO command with the Max Uplink Scheduling Allocation RB Number parameter specified. • Disabling the PAMC function Run the MOD CELLALGOSWITCH command with the UlPAMCSwitch(UlPAMCSwitch) option of the Uplink Schedule Extended Switch parameter deselected. • Disabling the UL Multi-Cluster function Run the MOD CELLALGOSWITCH command with the UlMultiClusterSwitch(UlMultiClusterSwitch) option of the Uplink Schedule Extended Switch parameter deselected. MML Command Examples • Setting the maximum number of UL HARQ retransmissions //Setting the maximum number of UL HARQ retransmissions to 1 MOD CELLULSCHALGO: LOCALCELLID=0, ULHARQMAXTXNUM=1; //Setting the eNodeB-specific timer for reordering at the receiver in AM MOD RLCPDCPPARAGROUP: RLCPDCPPARAGROUPID=0, RLCMODE=RlcMode_AM, ENODEBAMREORDERINGTIMER=Treordering_m40; //Setting the eNodeB-specific timer for reordering at the receiver in UM MOD RLCPDCPPARAGROUP: RLCPDCPPARAGROUPID=0, RLCMODE=RlcMode_UM, ENODEBUMREORDERINGTIMER=Treordering_m40; • Disabling the function of increasing the number of RBs and reducing the code rate for UL HARQ retransmissions MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlLast2RetransSchOptSwitch-0; MOD CELLULSCHALGO: LOCALCELLID=0, ULENHENCEDVOIPSCHSW=UlVoipRblerControlSwitch-0; • (Optional) Disabling the function of restricting the maximum number of RBs that can be allocated to each UE in the UL MOD CELLULSCHALGO: LOCALCELLID=0, MaxUlSchRbNum=255; • Disabling the PAMC function MOD CELLALGOSWITCH:LocalCellId=0,UlSchExtSwitch=UlPAMCSwitch-0; • Disabling the UL Multi-Cluster function MOD CELLALGOSWITCH:LocalCellId=0,UlSchExtSwitch=UlMultiClusterSwitch-0; 11.5 Deploying Enhanced UL Frequency Selective Scheduling 11.5.1 Requirements There is no requirement for the operating environment, transmission networking, and license. 11.5.2 Precautions None 11.5.3 Data Preparation This section describes the data that you need to collect for setting parameters. Required data is data that you must collect for all scenarios. Collect scenario-specific data when necessary for a specific feature deployment scenario. 11.5.3.1 Required Data The following parameter describes the parameter that must be set in a CellAlgoSwitch MO to configure enhanced UL frequency selective scheduling. Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch Select the UlEnhancedFssSwitch option of this parameter. The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure search direction randomization for the sliding window in UL frequency selective scheduling. Parameter Name Parameter ID Setting Notes Uplink Schedule Extended Switch CellAlgoSwitch.UlSchExtSwitch Select the UlFssWindSearchDirRandSw option of this parameter when any of the following conditions is met: • The SRSCFG.SrsCfgInd parameter is set to BOOLEAN_FALSE (False). • The SRSCFG.SrsCfgInd parameter is set to BOOLEAN_TRUE (True) and the SRSCFG.FddSrsCfgMode parameter is set to ADAPTIVEMODE(Adaptive Mode). 11.5.3.2 Scenario-specific Data 11.5.3.2.1 UL Frequency Selective Scheduling Based on the Estimated UE Speed The following table describes the parameter that must be set in a CellAlgoSwitch MO to activate UL frequency selective scheduling based on the estimated UE speed for a cell. Parameter Name Parameter ID Uplink schedule switch CellAlgoSwitch.UlSchSwitch Setting Notes Parameter Name Parameter ID Setting Notes UlEnhancedDopplerSwitch under this parameter specifies whether to enable UL frequency selective scheduling based on the estimated UE speed. It is recommended that this switch be set to OFF. 11.5.3.2.2 Interference-based Frequency Selective Scheduling The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure UL interference-based frequency selective scheduling. Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch You are advised to select the UlInterfFssSwitch(UlInterfFssSwitch) option of this parameter to enable interference-based frequency selective scheduling when SRS configuration is disabled or adaptive for the cell and the interference to the PUSCH in the cell is greater than –110 dBm. This option takes effect only when the CellUlschAlgo.UlRbAllocationStrategy parameter is set to FS_INRANDOM_ADAPTIVE(Fs InRandom Strategy). 11.5.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Enabling enhanced UL frequency selective scheduling 1. Run the MOD CELLALGOSWITCH command with the UlEnhancedFssSwitch(UlEnhancedFssSwitch) option of the Uplink schedule switch parameter selected. 2. (Optional) Run the MOD CELLALGOSWITCH command with the UlFssWindSearchDirRandSw(UlFssWindSearchDirRandSw) option of the Uplink Schedule Extended Switch parameter selected. • Enabling interference-based UL frequency selective scheduling Run the MOD CELLALGOSWITCH command with the UlInterfFssSwitch(UlInterfFssSwitch) option of the Uplink schedule switch parameter selected. • Enabling optimized UL frequency selective scheduling based on the estimated UE speed Run the MOD CELLALGOSWITCH command with the UlEnhancedDopplerSwitch(UlEnhancedDopplerSwitch) option of the Uplink schedule switch parameter selected. MML Command Examples • Enabling enhanced UL frequency selective scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlEnhancedFssSwitch-1; //(Optional) Setting UlFssWindSearchDirRandSw on MOD CELLALGOSWITCH:LOCALCELLID=0,UlSchExtSwitch=UlFssWindSearchDirRandSw-1; • Enabling interference-based UL frequency selective scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlInterfFssSwitch-1; • Enabling optimized UL frequency selective scheduling based on the estimated UE speed MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlEnhancedDopplerSwitch-1; 11.5.5 Activation Observation Observing Enhanced UL Frequency Selective Scheduling (Using Performance Counters) This section describes how to observe whether enhanced UL frequency selective scheduling has taken effect by using an example wherein a cell with a bandwidth of 20 MHz has admitted over 15 UEs. NOTE: Both basic UL frequency selective scheduling and enhanced UL frequency selective scheduling use the same counter (L.ChMeas.PRB.UL.FSS.Avg) for activation observation. Ensure that basic UL frequency selective scheduling does not take effect (more than 15 UEs admitted to the cell) when you observe enhanced UL frequency selective scheduling using L.ChMeas.PRB.UL.FSS.Avg. Check the value of the counter listed in Table 11-1. If this counter value is not zero, enhanced UL frequency selective scheduling has taken effect. Table 11-1 Counters related to enhanced UL frequency selective scheduling Counter Name Description L.ChMeas.PRB.UL.FSS.Avg Average number of PRBs allocated for uplink frequency selective scheduling. NOTE: When CellUlschAlgo.UlRbAllocationStrategy is set to FS_INRANDOM_ADAPTIVE, the value of L.ChMeas.PRB.UL.Used.Avg minus L.ChMeas.PRB.UL.FSS.Avg indicates the number of RBs that have been used for interference-randomization-based scheduling. 11.5.6 Reconfiguration None 11.5.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Disabling enhanced UL frequency selective scheduling 1. Run the MOD CELLALGOSWITCH command with the UlEnhancedFssSwitch option of the Uplink schedule switch parameter deselected. 2. (Optional) Run the MOD CELLALGOSWITCH command with the UlFssWindSearchDirRandSw option of the Uplink Schedule Extended Switch parameter deselected. • Disabling interference-based UL frequency selective scheduling Run the MOD CELLALGOSWITCH command with the UlInterfFssSwitch option of the Uplink schedule switch parameter deselected. • Disabling optimized UL frequency selective scheduling based on the estimated UE speed Run the MOD CELLALGOSWITCH command with the UlEnhancedDopplerSwitch option of the Uplink schedule switch parameter deselected. MML Command Examples • Disabling enhanced UL frequency selective scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlEnhancedFssSwitch-0; //(Optional) Setting UlFssWindSearchDirRandSw off MOD CELLALGOSWITCH:LOCALCELLID=0,UlSchExtSwitch=UlFssWindSearchDirRandSw-0; • Disabling interference-based UL frequency selective scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlInterfFssSwitch-0; • Disabling optimized UL frequency selective scheduling based on the estimated UE speed MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlEnhancedDopplerSwitch-0; 11.6 Deploying MBR>GBR Configuration 11.6.1 Requirements There is no requirement for the operating environment, transmission networking, and license. 11.6.2 Precautions None 11.6.3 Data Preparation The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the MBR>GBR Configuration feature. Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch Set UlMbrCtrlSwitch of this parameter to enable or disable the MBR>GBR Configuration feature. 11.6.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the UlMbrCtrlSwitch option of the Uplink schedule switch parameter selected. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlMbrCtrlSwitch-1; 11.6.5 Activation Observation This section describes the activation observation procedure using a commercial UE in a cell with a 20 MHz bandwidth. 1. Provision a UL GBR service for one UE. Set the GBR and MBR to 20 Mbit/s and 40 Mbit/s, respectively. Initiate a service with the data rate greater than the MBR on the UE. 2. Start throughput monitoring on the U2000: Choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Throughput Monitoring. 3. Start RB usage monitoring on the U2000: Choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > Cell Performance Monitoring > Usage of RB Monitoring. 4. Disable the MBR>GBR Configuration feature. The GBR service rate approaches the GBR (20 Mbit/s) even when the cell has vacant RBs, as shown in Figure 11-1. Figure 11-1 Example of RB usage and throughput monitoring (MBR>GBR Configuration disabled) 5. Enable the MBR>GBR Configuration feature. The GBR service rate can range from the GBR to the MBR when the cell has vacant RBs. See Figure 11-2. Figure 11-2 Example of RB usage and throughput monitoring (MBR>GBR Configuration enabled) 11.6.6 Reconfiguration None 11.6.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the UlMbrCtrlSwitch option of the Uplink schedule switch parameter deselected. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlMbrCtrlSwitch-0; 11.7 Performance Monitoring Observe the resource occupation ratio on the PUSCH and throughput of GBR services with different QCIs. • Calculate the resource occupation ratio on the PUSCH using the following formula: L.ChMeas.PRB.UL.Used.Avg/L.ChMeas.PRB.UL.Avail • Observe throughput of GBR services with different QCIs: ◾ L.Thrp.bits.UL.QCI.1 ◾ L.Thrp.bits.UL.QCI.2 ◾ L.Thrp.bits.UL.QCI.3 ◾ L.Thrp.bits.UL.QCI.4 The EPC configures the GBR and MBR specific to GBR services. If the resource occupation ratio on the PUSCH is less than or equal to 50% and there is a GBR service whose data rate is greater than the configured GBR, check whether the data rate of the GBR service increases after the MBR>GBR Configuration feature is activated. If so, the MBR>GBR Configuration feature has taken effect. 11.8 Parameter Optimization N/A 11.9 Possible Issues N/A 12 Engineering Guidelines for Enhanced UL Scheduling Features This chapter provides engineering guidelines for the following features: • LBFD-00101502 Dynamic Scheduling • LOFD-110205 Traffic Model Based Performance Optimization 12.1 When to Use 12.1.1 LBFD-00101502 Dynamic Scheduling Enhanced Scheduling Policy See 10.1.2 LBFD-00101502 Dynamic Scheduling. SINR Adjustment SINR adjustment is recommended for use. It is similar to CQI adjustment for DL scheduling. The SINR adjustment feature corrects UL SINR measurement errors and combats channel condition changes during the time between SINR measurement and scheduling. SINR adjustment enables the UL IBLER to converge on the target value, therefore increasing UL throughput. You are advised to enable target IBLER adaptation in SINR adjustment to improve UL throughput. UL Preallocation UL smart preallocation is a sub-function of UL preallocation and is recommended for use. UL preallocation increases the number of times the eNodeB proactively schedules UEs. This shortens the duration when UL data is buffered on UEs and quickens the response to UE services, thereby improving user experience. While improving user experience, UL smart preallocation minimizes UL resource consumption and impact on UL services. UL smart preallocation decreases signaling overheads on the PDCCH, UE power consumption, and UL interference. However, UL smart preallocation may reduce the web browsing rate slightly. PUSCH DTX Detection PUSCH DTX detection is recommended for use. The PUSCH DTX detection result is used for adaptive retransmissions in UL scheduling, thereby saving UL resources and increasing throughput. Scenario-specific False SRI Detection Threshold Configuration Scenario-specific false SRI detection threshold configuration is recommended for use. When scenario-specific false SRI detection threshold configuration is enabled and UEs enter the DRX state, an optimized false SRI detection threshold is used at the physical layer so that the probability of SRI false alarms is reduced. This increases the MCS index for UEs in the DRX state and decreases the increment of BLER caused by SRI false alarms. Scheduling Termination for Abnormal UEs For details about when to enable scheduling termination for abnormal UEs, see 10.1.2 LBFD-00101502 Dynamic Scheduling. PDCCH and PUSCH Resource Balancing The function of PDCCH and PDSCH resource balancing is recommended when the following conditions are met: • The number of UEs in RRC_CONNECTED mode is large. For example, the number is greater than 200. • PDCCH congestion occurs. For example the PDCCH CCE usage is greater than 70%. • The PUSCH resource usage is low. For example, the UL PRB usage is less than 80%. PUCCH RB Occupation by PUSCH PUCCH RB occupation by PUSCH increases the PUCCH interference against neighboring cells. It is recommended that this function be disabled on commercial networks. Enable this function only when testing UL throughput in a cell serving only one user. 12.1.2 LOFD-110205 Traffic Model Based Performance Optimization This feature is recommended when the cell traffic load is high (PRB usage > 60%). You are advised to enable the Traffic Model Based Performance Optimization feature in the uplink and downlink at the same time. For details about deploying this feature in the downlink, see 10.7 Deploying the Traffic Model Based Performance Optimization Feature. 12.2 Required Information None 12.3 Deploying Dynamic Scheduling 12.3.1 Requirements Operating Environment PUSCH DTX detection is not supported in the following scenarios: • The configured BBP is LBBPc and the SRSCfg.SrsCfgInd parameter is set to False. • The configured BBP is LBBPc and four or eight RX antennas are used. • The configured BBP is LBBPc and the UE is an MU-MIMO paired UE. • The SRSCfg.SrsCfgInd parameter is set to False on the BTS3202E. Transmission Networking N/A License N/A 12.3.2 Precautions None 12.3.3 Data Preparation This section describes the data that you need to collect for setting parameters. Required data is data that you must collect for all scenarios. Collect scenario-specific data when necessary for a specific feature deployment scenario. 12.3.3.1 Required Data The following table describes the parameters that must be set in a CellUlschAlgo MO to specify the UL scheduling policy. Table 12-1 Parameters that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Setting Notes Uplink Scheduling Strategy CellUlschAlgo.UlschStrategy This parameter specifies the UL scheduling policy. There are four policies: Max C/I, RR, PF, and EPF. Select EPF as the enhanced scheduling policy. Uplink EPF capacity factor CellUlschAlgo.UlEpfCapacityFactor This parameter specifies the UL EPF scheduling capacity factor. This parameter affects the scheduling priority of UEs that run GBR services with QCI 1, 2, 3, or 4 whose data rates do not meet their GBRs. This parameter also affects the scheduling priority of UEs that run non-GBR services with QCI 6, 7, 8, or 9. Under these conditions, the cell capacity and fairness can be adjusted. 12.3.3.2 Scenario-specific Data 12.3.3.2.1 QCI Configurations for UL Non-GBR Services The following table describes the parameters that must be set in the QciPara MO to specify QCI parameters for UL non-GBR services. Parameter Name Parameter ID Setting Notes QoS Class Identifier QciPara.Qci Set this parameter according to operators' policies. Prioritised Bit Rate QciPara.PrioritisedBitRate If this parameter is set to PBR_0_KBps(0KB/s), there is a risk that services with the QCI will never be scheduled. If this parameter is set to PBR_INFINITY(Infinity) and the traffic volume of services with the QCI is high, there is a risk that services with QCIs indicating lower priorities than this QCI will never be scheduled. The default value is recommended for normally operating networks. Logical Channel Priority QciPara.LogicalChannelPriority Services with relatively high priorities are preferentially scheduled. The default value is recommended for normally operating networks. The following table describes the parameter that must be set in the GlobalProcSwitch MO to specify whether QCI-related parameters take effect. Parameter Name Parameter ID Setting Notes QCI Parameter Effect Flag GlobalProcSwitch.QciParaEffectFlag Set this parameter to ON. 12.3.3.2.2 UL Min-GBR Guarantee The following tables describe the parameters that must be set in CellAlgoSwitch and QciPara MOs to enable UL Min-GBR guarantee. Table 12-2 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch UlMinGbrSwitch under this parameter specifies whether to guarantee a minimum rate for UL non-GBR services. • If this switch is off, no minimum rate is guaranteed for UL non-GBR services. In worst cases, service drops may occur. • If this switch is on, the QCI-specific Min-GBR is guaranteed for UL non-GBR services and therefore the probability of service drops decreases. However, turning on this switch may reduce cell capacity because the Min-GBR for users at cell edge is guaranteed. The default value is recommended for normally operating networks. Table 12-3 Parameter that must be set in a QciPara MO Parameter Name Parameter ID Setting Notes Uplink MinGBR QciPara.UlMinGbr If this parameter is set to a large value and resources are insufficient, highpriority non-GBR services can reach their Min-GBR but low-priority nonGBR services may not reach their Min-GBR. If this parameter is set to a small value, the response time for non-GBR services may be affected. The default value is recommended for normally operating networks. The following table describes the parameter that must be set in the GlobalProcSwitch MO to specify whether QCI-related parameters take effect. Parameter Name Parameter ID Setting Notes QCI Parameter Effect Flag GlobalProcSwitch.QciParaEffectFlag Set this parameter to ON. 12.3.3.2.3 Logical Channel Group The following table describes the parameter that must be set in the GlobalProcSwitch MO to configure logical channel groups. Table 12-4 Parameter that must be set in the GlobalProcSwitch MO Parameter Name Parameter ID Setting Notes LCG Profile GlobalProcSwitch.LcgProfile If this parameter is set to LCG_PROFILE_1, QoS requirements of high-priority non-GBR services are better fulfilled, but it may fail to meet QoS requirements of low-priority non-GBR services. When this parameter is set to LCG_PROFILE_1, do not configure VoLTE services. When this parameter is set to LCG_PROFILE_2, do not configure GBR services. 12.3.3.2.4 SINR Adjustment This section describes the parameters that must be set in CellAlgoSwitch and CellUlschAlgo MOs to configure the SINR adjustment function. Table 12-5 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Uplink schedule switch CellAlgoSwitch.UlSchSwitch Setting Notes • SinrAdjustSwitch(SinrAdjustSwitch) specifies whether to activate SINR adjustment. It is recommended that SinrAdjustSwitch(SinrAdjustSwitch) under this parameter be selected. • UlIblerAdjustSwitch specifies whether the eNodeB adaptively adjusts the UL IBLER in SINR adjustment. • PuschDtxSwitch under this parameter specifies whether the eNodeB uses PUSCH DTX detection results during UL scheduling. If this switch is turned on, the eNodeB determines whether to perform an adaptive retransmission during UL scheduling based on the PUSCH DTX detection result. The eNodeB also adjusts the CCE aggregation level of the PDCCH carrying DCI format 0 based on the same result. PUSCH DTX detection is recommended for use. • UlEnhancedSrSchSwitch(UlEnhancedSrSchSwitch) specifies whether the eNodeB performs UL SR-based scheduling optimization. If this switch is on, the eNodeB determines whether to stop SR re-scheduling based on the PUSCH DTX detection result. For a UE in DRX mode, SR re-scheduling is performed only during long DRX cycles. Table 12-6 Parameters that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Setting Notes SINR target IBLER adjustment CellUlschAlgo.SinrAdjustTargetIbler It is recommended that this parameter be set to 10. PUSCH DTX Scheduling Strategy CellUlschAlgo.PuschDtxSchStrategy This parameter is valid only when the PuschDtxSwitch option of the CellAlgoSwitch.UlSchSwitch parameter is selected. It is recommended that this parameter be set to EN_ADAPTIVE_RETX (EN_ADAPTIVE_RETX). Uplink Target IBLER Adapt Type CellUlschAlgo.UlTargetIBlerAdaptType It is recommended that SinrFlunIBlerAdaptSwitch and SinrJumpIBlerAdaptSwitch of this parameter be selected. IBLER Adapt Big Packet Switch CellUlschAlgo.UlIBlerAdaptBigTrafficSw It is recommended that this parameter be set to ON(On). 12.3.3.2.5 UL Preallocation This section describes the parameters that must be set in the CellAlgoSwitch, CellUlschAlgo, QciPara, CellQciPara, GlobalProcSwitch, and CellPreallocGroup MOs to configure preallocation. Table 12-7 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch In normal operation scenarios, you are advised to select both the PreAllocationSwitch(PreAllocationSwitch) and SmartPreAllocationSwitch(SmartPreAllocationSwitch) options of this parameter to enable UL smart preallocation. Uplink Schedule Extended Switch CellAlgoSwitch.UlSchExtSwitch You are advised to select the EnhancedSchForSparseSwitch (EnhancedSchForSparseSwitch) option. The parameters in the following tables need to be set when the PreAllocationSwitch option is selected. Table 12-8 Parameters that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Setting Notes Uplink Enhanced VoIP Schedule Switch CellUlschAlgo.UlEnhencedVoipSchSw You are advised to retain the default setting of the UlVoipPreAllocationSwitch option. System Bandwidth Ratio Used By Preschedule user per TTI CellUlschAlgo.PreAllocationBandwidthRatio If the cell bandwidth is 1.4 MHz, the recommended value of this parameter is 50. If the cell bandwidth is not 1.4 MHz, the recommended value of this parameter is 25. minimal period of pre-allocation CellUlschAlgo.PreAllocationMinPeriod The value 5 is recommended. data size of pre-allocation CellUlschAlgo.PreAllocationSize The value 80 is recommended. Smart pre-allocation duration CellUlschAlgo.SmartPreAllocationDuration This parameter takes effect only when smart preallocation is enabled. The value 50 is recommended. Sparse Smart Pre-allocation Duration CellUlschAlgo.SmartPreAllocDuraForSparse This parameter takes effect only when smart preallocation is enabled. The value 1500 is recommended. Minimal Period of Sparse Pre-allocation CellUlschAlgo.PreAllocMinPeriodForSparse The value SAME_AS_OTHER_SERVICE (SAME_AS_OTHER_SERVICE) is recommended. Data Size of Sparse Pre-allocation CellUlschAlgo.PreallocationSizeForSparse The value SAME_AS_OTHER_SERVICE (SAME_AS_OTHER_SERVICE) is recommended. Table 12-9 Parameters that must be set in a QciPara MO Parameter Name Parameter ID Setting Notes QoS Class Identifier QciPara.Qci None Pre-allocation weight QciPara.PreAllocationWeight The default value is recommended for normally operating networks. Table 12-10 Parameters that must be set in a CellQciPara MO Parameter Name Parameter ID Setting Notes QoS Class Indication CellQciPara.Qci None Preallocation Parameter Group ID CellQciPara.PreallocationParaGroupId This parameter specifies the preallocation parameter group ID that the QCI corresponds to. This parameter is consistent with the CellPreallocGroup.PreallocationParaGroupId parameter in the CellPreallocGroup MO, which includes the parameters of preallocation switch, smart preallocation switch, minimum preallocation interval, preallocation data volume, and duration of smart preallocation. The parameter values 0 to 9 are indexes of the specific preallocation parameter groups. If the corresponding preallocation parameter group does not exist, configuration of a parameter group fails and an error is returned. The parameter value 255 indicates that the QCI does not correspond to any preallocation parameter group. The recommended value is 255, which means that the QCI-level parameter group for smart preallocation is disabled. Table 12-11 Parameter that must be set in the GlobalProcSwitch MO Parameter Name Parameter ID Setting Notes QCI Parameter Effect Flag GlobalProcSwitch.QciParaEffectFlag Set this parameter to ON. Table 12-12 Parameters that must be set in a CellPreallocGroup MO Parameter Name Parameter ID Setting Notes Preallocation Parameter Group ID CellPreallocGroup. This parameter identifies a preallocation parameter group. PreallocationParaGroupId Preallocation Switch CellPreallocGroup. PreallocationSwitch Smart Preallocation Switch CellPreallocGroup. SmartPreallocationSwitch Minimal Period of Preallocation CellPreallocGroup. PreallocationMinPeriod Data Size of Preallocation CellPreallocGroup. PreallocationSize This parameter specifies whether to enable preallocation for a bearer with the specified preallocation parameter group ID. This parameter specifies whether to enable smart preallocation for a bearer with the specified preallocation parameter group ID. UL smart preallocation is enabled for the parameter group only when this parameter and the CellPreallocGroup.PreallocationSwitch parameter are both set to ON. This is a bearer-level switch and it takes effect only when the cell-level preallocation switch PreAllocationSwitch under the CellAlgoSwitch.UlSchSwitch parameter is set on. It is recommended that this switch be set to ON for normally operating networks. This parameter specifies the minimum interval between two preallocations. That is, the actual interval between two preallocations of a UE must be longer than or equal to the value of this parameter. The default value is recommended for normally operating networks. This parameter specifies the data volume of each preallocation for the bearer configured with the parameter group ID. The default value is recommended for normally operating networks. Parameter Name Parameter ID Setting Notes Smart Preallocation Duration CellPreallocGroup. This parameter specifies the duration of each smart preallocation for the bearer configured with the parameter group ID. The parameter value 50 is recommended for normally operating networks. SmartPreallocationDuration 12.3.3.2.6 Setting the SRI False Alarm Detection Threshold The following table describes parameter that must be set in a CellUlschAlgo MO to set the SRI false alarm detection threshold. Table 12-13 Parameter that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Setting Notes Sri False Detect Threshold Switch CellUlschAlgo.SriFalseDetThdSwitch This parameter specifies whether to set the SRI false alarm detection threshold specially for UEs in the discontinuous reception (DRX) state. When this parameter is set to ON(On) and UEs enter the DRX state, the SRI false alarm detection threshold with a 0.5% probability of false alarms is used at the physical layer. When this parameter is set to ON(On) and UEs exit the DRX state, the SRI false alarm detection threshold with a 1% probability of false alarms is used at the physical layer. When this parameter is set to OFF (Off), the SRI false alarm detection threshold with a 1% probability of false alarms is always used at the physical layer. 12.3.3.2.7 Scheduling Termination for Abnormal UEs The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the function of scheduling termination for abnormal UEs. Table 12-14 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes Cell Schedule Strategy Switch CellAlgoSwitch.CellSchStrategySwitch AbnUeSchSwitch specifies whether to enable the function of scheduling termination for abnormal UEs. The following table describes the parameter that must be set in a CellUlschAlgo MO to configure the threshold for scheduling termination for abnormal UEs in the UL. Table 12-15 Parameter that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Setting Notes Uplink Schedule Abnormal Ue Threshold CellUlschAlgo.UlSchAbnUeThd This parameter specifies the threshold of consecutive CRC failures when the eNodeB determines that the UE link is abnormal. The default value is recommended. 12.3.3.2.8 Scheduler-controlled Power This section describes the parameters that must be set in a CellAlgoSwitch MO and an eNodeBAlgoSwitch MO to enable the scheduler-controlled power function. Table 12-16 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch The SchedulerCtrlPowerSwitch option of this parameter specifies whether to enable the scheduler-controlled power function. When this option is deselected, the scheduler considers power control restrictions while performing scheduling. The number of RBs allocated by the scheduler does not exceed the limit defined by the power control module, ensuring a constant PSD. When this option is selected, the scheduler performs scheduling without considering power control restrictions. The number of RBs is flexibly allocated by the scheduler to make full use of PRB resources. It is recommended that this option be selected. Uplink Schedule Extended Switch CellAlgoSwitch.UlSchExtSwitch When the SchedulerCtrlPowerSwitch option is selected: • The UlDataFitterRbCalcSwitch option of this parameter specifies whether to enable the algorithm of accurate RB calculation based on uplink data volume matching to increase network capacity. It is recommended that this option be selected. • The UlSchCtrlPwrUserSetOptSw option of this parameter specifies whether to enable optimization of UE set selection. It is recommended that this option be selected. Table 12-17 Parameter that must be set in an eNodeBAlgoSwitch MO Parameter Name Parameter ID Setting Notes UL Resource Management Optimization Switch eNodeBAlgoSwitch.UlResManageOptSw The UL_RBCALC_OPT_SWITCH option of this parameter specifies whether to optimize the RB quantity calculation based on channel characteristics in the case of power limitation. It is recommended that this option be selected for throughput tests of UEs running large-packet services in the UL. 12.3.3.2.9 PDCCH and PUSCH Resource Balancing The following table describes the parameters that must be set in a CellUlschAlgo MO to configure PDCCH and PUSCH resource balancing. Table 12-18 Parameters that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Ue Num Threshold in PDCCH PUSCH Balance CellUlschAlgo.UeNumThdInPdcchPuschBal This parameter specifies the threshold of the number of cell-level users for triggering PDCCH and PUSCH resource balancing. Set this parameter based on the network plan. It is recommended that this parameter be set to 200 if the cell serves more than 200 users and UL RBs are not fully used due to insufficient PDCCH CCEs. In this way, PDCCH and PUSCH resource balancing takes effect, improving UL throughput and RB utilization. Setting Notes Data Threshold in PDCCH and PUSCH Balance CellUlschAlgo.DataThdInPdcchPuschBal This parameter specifies the threshold of the data volume for triggering PDCCH and PUSCH resource balancing. Set this parameter based on the network plan. 12.3.3.2.10 UL RLC Segment Reduction This section describes the parameters that must be set in the CellAlgoSwitch and CellUlschAlgo MOs to configure the RLC segment reduction function. Table 12-19 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch UlSmallRBSpectralEffOptSw specifies whether to optimize the spectral efficiency in small-RB allocation to reduce the size of UL RLC segments. If this switch is set to OFF, a low spectral efficiency in small-RB allocation may cause RLC segmentation. If this switch is set to ON, a low spectral efficiency in small-RB allocation does not cause RLC segmentation. Table 12-20 Parameter that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Setting Notes Head Overhead For Uplink Scheduling CellUlschAlgo.HeadOverheadForUlSch This parameter specifies the header overhead estimated by UL scheduling. The parameter values indicate different BSR and PHR overheads and RLC head overheads. 12.3.3.2.11 PUCCH RB Occupation by PUSCH The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure PUCCH RB occupation by PUSCH. Table 12-21 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch PuschUsePucchRbSwitch specifies whether PUCCH RBs can be occupied by the PUSCH. If PuschUsePucchRbSwitch is deselected, PUCCH RBs cannot be used for user data transmission in UL scheduling. If PuschUsePucchRbSwitch is selected, PUCCH RBs can be used for user data transmission in UL scheduling when the cell serves only one user. Select PuschUsePucchRbSwitch only when testing UL throughput in a cell serving only one user. Do not select PuschUsePucchRbSwitch in other scenarios. 12.3.3.2.12 Proactive Scheduling for Uplink Signaling The following table describes the parameter that must be set in a CellAlgoSwitch MO to enable proactive scheduling for uplink signaling. Table 12-22 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes Uplink Schedule Extended Switch CellAlgoSwitch.UlSchExtSwitch For details about the principles, see 5.4.1.3 Proactive Scheduling for Uplink Signaling. It is recommended that this parameter be set to the default value. 12.3.3.2.13 Data Amount Adaptation in UL SR-based Scheduling This section describes the parameters that must be set in a CellAlgoSwitch MO and a CellUlschAlgo MO to enable data amount adaptation in UL SR-based scheduling. Table 12-23 Parameter that must be set in a CellAlgoSwitch MO Parameter Name Parameter ID Setting Notes Uplink schedule switch CellAlgoSwitch.UlSchSwitch Select the SrSchDataAdptSw option of this parameter. Table 12-24 Parameter that must be set in a CellUlschAlgo MO Parameter Name Parameter ID Setting Notes UL SR Scheduling Data Vol Adapt Opt CellUlschAlgo.UlSrSchDataVolAdptOptUpThd Set this parameter to 2000 if the UL PRB usage is greater than 90%. Set Upper Thld this parameter to 0 in other situations. 12.3.4 Activation This feature can be activated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Setting the enhanced UL scheduling policy Run the MOD CELLULSCHALGO command with the Uplink Scheduling Strategy parameter specified. • Configuring the QCI for UL non-GBR services 1. Run the MOD QCIPARA command with the QoS Class Identifier, Prioritised Bit Rate, and Logical Channel Priority parameters specified. 2. Run the MOD GLOBALPROCSWITCH command with the QCI Parameter Effect Flag parameter set to ON(On). • Enabling the UL Min-GBR guarantee function 1. Run the MOD CELLALGOSWITCH command with the UlMinGbrSwitch option of the Uplink schedule switch parameter selected. 2. Run the MOD QCIPARA command with the Uplink MinGBR parameter specified. 3. Run the MOD GLOBALPROCSWITCH command with the QCI Parameter Effect Flag parameter set to ON(On). • Setting the logical channel group profile Run the MOD GLOBALPROCSWITCH command with the LCG Profile parameter specified. • Enabling SINR adjustment Run the MOD CELLALGOSWITCH command with the SinrAdjustSwitch and PuschDtxSwitch options of the Uplink schedule switch parameter selected. Run the MOD CELLULSCHALGO command with the PUSCH DTX Scheduling Strategy parameter specified. • Enabling UL target IBLER adaptation 1. Run the MOD CELLALGOSWITCH command with the UlIblerAdjustSwitch option of the Uplink schedule switch parameter selected. 2. Run the MOD CELLULSCHALGO command with the Uplink Target IBLER Adapt Type and IBLER Adapt Big Packet Switch parameters appropriately set. • Enabling scenario-specific false SRI detection threshold configuration Run the MOD CELLULSCHALGO command with the Sri False Detect Threshold Switch parameter set to ON(On). • Enabling cell-level preallocation 1. Run the MOD CELLALGOSWITCH command with the PreAllocationSwitch option of the Uplink schedule switch parameter selected. 2. Run the MOD CELLALGOSWITCH command with the SmartPreAllocationSwitch option of the Uplink schedule switch parameter selected. 3. Run the MOD CELLULSCHALGO command with the Smart Preallocation Duration, Sparse Smart Pre-allocation Duration, Minimal Period of Sparse Pre-allocation, and Data Size of Sparse Pre-allocation parameters specified. 4. Run the MOD CELLALGOSWITCH command with the EnhancedSchForSparseSwitch option of the Uplink Schedule Extended Switch parameter selected. 5. Run the MOD CELLULSCHALGO command with the UlVoipPreAllocationSwitch option of the Uplink Enhanced VoIP Schedule Switch parameter selected. • Enabling QCI-level preallocation 1. Run the ADD CELLPREALLOCGROUP command to configure a preallocation parameter group. 2. Run the MOD CELLQCIPARA command with the Preallocation Parameter Group ID parameter specified. 3. Run the MOD GLOBALPROCSWITCH command with the QCI Parameter Effect Flag parameter set to ON(On). • Enabling enhanced UL SR-based scheduling Run the MOD CELLALGOSWITCH command with the UlEnhancedSrSchSwitch option of the Uplink schedule switch parameter selected. • Enabling data amount adaptation in UL SR-based scheduling Run the MOD CELLALGOSWITCH command with the SrSchDataAdptSw option of the Uplink schedule switch parameter selected. • Enabling the function of scheduling termination for abnormal UEs 1. Run the MOD CELLALGOSWITCH command with the AbnUeSchSwitch option of the Cell Schedule Strategy Switch parameter selected. 2. Run the MOD CELLULSCHALGO command with the Uplink Schedule Abnormal Ue Threshold parameter specified. • Enabling the function of scheduler-controlled power Run MOD CELLALGOSWITCH and MOD ENODEBALGOSWITCH to configure the function of scheduler-controlled power. • Enabling PDCCH and PUSCH resource balancing Run the MOD CELLULSCHALGO command with the Ue Num Threshold in PDCCH PUSCH Balance and Data Threshold in PDCCH and PUSCH Balance parameters specified. • Enabling the function of UL RLC segment reduction 1. Run the MOD CELLALGOSWITCH command with the UlSmallRBSpectralEffOptSw option of the Uplink schedule switch parameter selected. 2. Run the MOD CELLULSCHALGO command with the Head Overhead For Uplink Scheduling parameter specified. • Enabling the function of PUCCH RB occupation by PUSCH Run the MOD CELLALGOSWITCH command with the PuschUsePucchRbSwitch option of the Uplink schedule switch parameter selected. • Enabling proactive scheduling of UL signaling Run the MOD CELLALGOSWITCH command with the SrbProbeSchSwitch option of the Uplink Schedule Extended Switch parameter selected. MML Command Examples • Setting the enhanced UL scheduling policy MOD CELLULSCHALGO: LOCALCELLID=0, ULSCHSTRATEGY=ULSCH_STRATEGY_EPF; • Configuring the QCI for UL non-GBR services MOD QCIPARA:QCI=QCI6,PRIORITISEDBITRATE=PBR_8_KBps,LOGICALCHANNELPRIORITY=9; MOD GLOBALPROCSWITCH: QciParaEffectFlag=ON; • Enabling the UL Min-GBR guarantee function //Setting UlMinGbrSwitch on MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlMinGbrSwitch-1; //Setting the UL Min-GBR MOD QCIPARA:QCI=QCI6,ULMINGBR=MinGbrRate_1_KB; MOD GLOBALPROCSWITCH: QciParaEffectFlag=ON; • Setting the logical channel group profile MOD GLOBALPROCSWITCH: LCGPROFILE=LCG_PROFILE_0; • Enabling SINR adjustment MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=SinrAdjustSwitch-1&PuschDtxSwitch-1; MOD CELLULSCHALGO:LOCALCELLID=0,PUSCHDTXSCHSTRATEGY=EN_ADAPTIVE_RETX; • Enabling UL target IBLER adaptation MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlIblerAdjustSwitch-1; MOD CELLULSCHALGO:LOCALCELLID=0,ULTARGETIBLERADAPTTYPE=SinrFlunIBlerAdaptSwitch-1&SinrJumpIBlerAdaptSwitch-1; //Enabling UL target IBLER adaptation only for UEs with constant large packets MOD CELLULSCHALGO: LOCALCELLID=0, ULIBLERADAPTBIGTRAFFICSW=ON; //Enabling UL target IBLER adaptation to take effect on all UEs in the cell MOD CELLULSCHALGO: LOCALCELLID=0, ULIBLERADAPTBIGTRAFFICSW=OFF; • Enabling scenario-specific false SRI detection threshold configuration MOD CELLULSCHALGO: LOCALCELLID=0, SRIFALSEDETTHDSWITCH=ON; • Enabling cell-level preallocation //Enabling UL preallocation MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=PreAllocationSwitch-1; //Enabling UL smart preallocation MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=PreAllocationSwitch-1&SmartPreAllocationSwitch-1; MOD CELLULSCHALGO:LOCALCELLID=0,SMARTPREALLOCATIONDURATION=50; //Optimizing the delay for services with sparse packets (such as ping services) MOD CELLULSCHALGO:LOCALCELLID=0,SMARTPREALLOCDURAFORSPARSE=1500,PREALLOCMINPERIODFORSPARSE=1ms,PREALLOCATIONSIZEFORSPARSE=2560BYTE; MOD CELLALGOSWITCH:LOCALCELLID=0,ULSCHEXTSWITCH=EnhancedSchForSparseSwitch-1; //Enabling voice preallocation MOD CELLULSCHALGO:LOCALCELLID=0,ULENHENCEDVOIPSCHSW=UlVoipPreAllocationSwitch-1; • Enabling QCI-level preallocation ADD CELLPREALLOCGROUP:LOCALCELLID=0,PREALLOCATIONPARAGROUPID=0,PREALLOCATIONSWITCH=ON,SMARTPREALLOCATIONSWITCH=ON,PREALLOCATIONMINPER IOD=5,PREALLOCATIONSIZE=80,SMARTPREALLOCATIONDURATION=50; MOD CELLQCIPARA:LOCALCELLID=0,QCI=9,PREALLOCATIONPARAGROUPID=0; MOD GLOBALPROCSWITCH: QciParaEffectFlag=ON; • Enabling enhanced UL SR-based scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlEnhancedSrSchSwitch-1; • Enabling data amount adaptation in UL SR-based scheduling MOD CELLALGOSWITCH:LOCALCELLID=0,UlSchSwitch=SrSchDataAdptSw-1; //When the UL PRB usage is greater than 90% MOD CELLULSCHALGO:LOCALCELLID=0,UlSrSchDataVolAdptOptUpThd=2000; • Enabling the function of scheduling termination for abnormal UEs MOD CELLALGOSWITCH: LOCALCELLID=0, CELLSCHSTRATEGYSWITCH=AbnUeSchSwitch-1; MOD CELLULSCHALGO: LOCALCELLID=0, ULSCHABNUETHD=15; • Enabling the function of scheduler-controlled power MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=SchedulerCtrlPowerSwitch-1; //Enabling RB number calculation based on UL data volume matching when the function of performing scheduling without considering powe r control restrictions is used MOD CELLALGOSWITCH:LOCALCELLID=0,ULSCHEXTSWITCH=UlDataFitterRbCalcSwitch-1; //Enabling optimization of UE set selection when the function of performing scheduling without considering power control restrictions is used MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHEXTSWITCH=UlSchCtrlPwrUserSetOptSw-1; //Enabling RB quantity calculation optimization in case of power limitation when scheduler-controlled power is used MOD ENODEBALGOSWITCH:UlResManageOptSw=UL_RBCALC_OPT_SWITCH-1; • Enabling PDCCH and PUSCH resource balancing MOD CELLULSCHALGO: LOCALCELLID=0, UENUMTHDINPDCCHPUSCHBAL=300, DATATHDINPDCCHPUSCHBAL=10000; • Enabling the function of UL RLC segment reduction MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlSmallRBSpectralEffOptSw-1; MOD CELLULSCHALGO: LOCALCELLID=0, HEADOVERHEADFORULSCH=48bit; • Enabling the function of PUCCH RB occupation by PUSCH MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=PuschUsePucchRbSwitch-1; • Enabling proactive scheduling of UL signaling MOD CELLALGOSWITCH:LOCALCELLID=0,UlSchExtSwitch=SrbProbeSchSwitch-1; 12.3.5 Activation Observation This section describes the procedures for verifying the activation of UL scheduling. The following examples show test results for commercial UEs in cells with a bandwidth of 20 MHz. Observing EPF for UL Scheduling (Using the U2000) To observe whether EPF has been activated for UL scheduling, perform the following steps: 1. Enable two UEs to access a cell in the cell center. 2. On the U2000 client, start channel quality monitoring and MCS-based count monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > MCS Count Monitoring. 3. Check the channel quality monitoring results of each UE. For example, the SINR for both UEs is approximately 21 dB. 4. Run the LST QCIPARA command to query the UL scheduling weight factors for QCIs 6 and 9. 5. Perform a UL service with QCI 6 on UE 1 and a UL service with QCI 9 on UE 2. 6. Check the MCS-based count monitoring results for the number of UL RBs allocated to each UE. If the ratio of the number for UE 1 to the number for UE 2 is approximately equal to the ratio of the weight factor for QCI 6 to the weight factor for QCI 9, EPF for UL scheduling has been activated successfully. Observing SINR Adjustment (Using Performance Counters) Observe the values of the counters listed in Table 12-25. The SINR adjustment function has been activated if the UL IBLER, calculated using the following formula, approaches the default value 10%: Table 12-25 Counters related to SINR adjustment Counter Name Counter Description L.Traffic.UL.SCH.QPSK.ErrTB.Ibler Number of uplink error TBs after initial transmission in QPSK modulation mode L.Traffic.UL.SCH.16QAM.ErrTB.Ibler Number of uplink error TBs after initial transmission in 16QAM modulation mode L.Traffic.UL.SCH.64QAM.ErrTB.Ibler Number of uplink error TBs after initial transmission in 64QAM modulation mode L.Traffic.UL.SCH.QPSK.TB Number of TBs initially transmitted on the uplink SCH in QPSK modulation mode L.Traffic.UL.SCH.16QAM.TB Number of TBs initially transmitted on the uplink SCH in 16QAM modulation mode L.Traffic.UL.SCH.64QAM.TB Number of TBs initially transmitted on the uplink SCH in 64QAM modulation mode Observing SINR Adjustment (Using the U2000) 1. Connect a UE to the channel simulator. Enable the UE to access a cell in the cell center through the ETU channel. 2. On the U2000 client, start channel quality monitoring and BLER monitoring on the UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start BLER monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > BLER Monitoring. 3. Perform UL packet injection on the UE so that the UE is scheduled about 1000 times per second in the UL. At the same time, move the UE gradually to the cell edge. 4. Check the UL channel quality in channel quality monitoring results, and check the UL IBLER in the BLER monitoring results. In these examples, the SINR is approximately 6.5 dB. If the value of Uplink IBLER(Permillage) fluctuates around 100 (meaning that the UL IBLER converges on the default value 10%), SINR adjustment has been activated but target IBLER adaptation has not been activated. If the value of Uplink IBLER(Permillage) is greater than 100 and fluctuates between 200 and 300, SINR adjustment and target IBLER adaptation have been activated. Observing UL Preallocation (Using Performance Counters) This section describes how to verify the activation of UL preallocation. The following examples show test results for commercial UEs in cells with a bandwidth of 20 MHz. To observe whether UL preallocation has been activated, observe the value of the counter listed in Table 12-26. UL preallocation has been activated if the L.ChMeas.PRB.UL.PreSch.Used.Avg counter produces a non-zero value. Table 12-26 Counter related to UL preallocation Counter Name Counter Description L.ChMeas.PRB.UL.PreSch.Used.Avg Average number of UL PRBs preallocated Observing UL Preallocation (Using the U2000) 1. Enable a UE to access a cell in the cell center. Do not perform UL services on the UE. 2. On the U2000 client, start channel quality monitoring and MCS-based count monitoring on each UE. The following are methods for starting these tasks: • To start channel quality monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > Quality of Channel Monitoring. • To start MCS-based count monitoring, choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > User Performance Monitoring > MCS Count Monitoring. 3. Check the UL channel quality in the channel quality monitoring results, and check the number of times the UE is scheduled in the UL in the MCS-based count monitoring results. The SINR is approximately 20.5 dB, and the UE is scheduled 200 times per second in the UL. The number of scheduling times is consistent with the default preallocation period of 5 ms. The results indicate that preallocation has been activated. Observing PDCCH and PUSCH Resource Balancing 1. Check the average number of users in the cell. When the number of users reaches the value of CellUlschAlgo.UeNumThdInPdcchPuschBal, the trigger condition for PDCCH and PUSCH resource balancing applies. 2. Check the PDCCH resource utilization. When the number of OFDM symbols occupied by the PDCCH reaches the maximum and CCE usage reaches around 80%, PDCCH resource congestion occurs. CCE usage = (L.ChMeas.CCE.CommUsed + L.ChMeas.CCE.ULUsed + L.ChMeas.CCE.DLUsed)/L.ChMeas.CCE.Avail 3. Check the PUSCH resource usage. If the RB usage is less than 50%, PDCCH and PUSCH resources are imbalanced in the cell. RB usage = L.ChMeas.PRB.UL.Used.Avg/L.ChMeas.PRB.UL.Avail Table 12-27 Counters related to PDCCH and PUSCH resource balancing Counter Name Counter Description L.Traffic.User.Avg Average number of users in a cell L.ChMeas.PDCCH.SymNum.1 to 4 Number of times that the PDCCH occupies x OFDM symbols (x ranging from 1 to 4) L.ChMeas.CCE.CommUsed Number of PDCCH CCEs used for common DCI L.ChMeas.CCE.ULUsed Number of PDCCH CCEs used for uplink DCI L.ChMeas.CCE.DLUsed Number of PDCCH CCEs used for downlink DCI L.ChMeas.CCE.Avail Number of available PDCCH CCEs L.ChMeas.PRB.UL.Used.Avg Average number of used PUSCH PRBs L.ChMeas.PRB.UL.Avail Number of available uplink PRBs 4. Compare the RB usage within the same period of service time before and after PDCCH and PUSCH resource balancing is enabled. If the RB usage increases, this function has taken effect. Observing PUCCH RB Occupation by PUSCH (Using the U2000) To observe whether the function has been activated, perform the following steps using a commercial UE in a cell with a 10 MHz bandwidth: 1. Enable one UE to access the cell at the cell center and ensure that the DL RSRP is less than or equal to –80 dBm. Perform UL services on the UE. 2. Start RB usage monitoring on the U2000: Choose Monitor > Signaling Trace > Signaling Trace Management. Then in the navigation tree on the left, choose LTE > Cell Performance Monitoring > Usage of RB Monitoring. If the RBs consumed by the UE approximately equal the maximum RBs supported by the system bandwidth (50 RBs), this function has taken effect. If this function does not take effect, the RBs consumed by the UE are less than the maximum RBs supported by the system bandwidth (50 RBs). Observing Scheduler-controlled Power To observe whether the function has been activated, perform the following steps using a commercial UE in a cell with a 10 MHz bandwidth: 1. Enable one UE to access the cell at a position not in the cell center and ensure that the DL RSRP is greater than or equal to –100 dBm. Perform continuous uploading services on the UE. 2. Start the tool for tracing UE signaling. View the PHR value reported by the UE. After scheduler-controlled power is disabled, the reported PHR value ranges from 21 to 24. If the reported PHR value is less than 20 after scheduler-controlled power is enabled, scheduler-controlled power has taken effect. 12.3.6 Reconfiguration None 12.3.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands • Disabling the UL Min-GBR guarantee function Run the MOD CELLALGOSWITCH command with the UlMinGbrSwitch option of the Uplink schedule switch parameter deselected. • Disabling SINR adjustment Run the MOD CELLALGOSWITCH command with the SinrAdjustSwitch and PuschDtxSwitch options of the Uplink schedule switch parameter deselected. • Disabling UL target IBLER adaptation Run the MOD CELLALGOSWITCH command with the UlIblerAdjustSwitch option of the Uplink schedule switch parameter deselected. • Disabling scenario-specific false SRI detection threshold configuration Run the MOD CELLULSCHALGO command with the Sri False Detect Threshold Switch parameter set to OFF(Off). • Disabling cell-level preallocation Run the MOD CELLULSCHALGO command with the UlVoipPreAllocationSwitch option of the Uplink Enhanced VoIP Schedule Switch parameter deselected. Run the MOD CELLALGOSWITCH command with the SmartPreAllocationSwitch option of the Uplink schedule switch parameter deselected. Run the MOD CELLALGOSWITCH command with the PreAllocationSwitch option of the Uplink schedule switch parameter deselected. Run the MOD CELLALGOSWITCH command with the EnhancedSchForSparseSwitch option of the Uplink Schedule Extended Switch parameter deselected. • Disabling QCI-level preallocation Run the MOD CELLQCIPARA command to disable QCI-level preallocation. • Disabling enhanced UL SR-based scheduling Run the MOD CELLALGOSWITCH command with the UlEnhancedSrSchSwitch option of the Uplink schedule switch parameter deselected. • Disabling data amount adaptation in UL SR-based scheduling Run the MOD CELLALGOSWITCH command with the SrSchDataAdptSw option of the Uplink schedule switch parameter deselected. • Disabling the function of scheduling termination for abnormal UEs Run the MOD CELLALGOSWITCH command with the AbnUeSchSwitch option of the Cell Schedule Strategy Switch parameter deselected. • Disabling the function of scheduler-controlled power Run the MOD CELLALGOSWITCH with the SchedulerCtrlPowerSwitch option of the Uplink schedule switch parameter deselected. • Disabling PDCCH and PUSCH resource balancing Run the MOD CELLULSCHALGO command with the Ue Num Threshold in PDCCH PUSCH Balance parameter specified. • Disabling the function of UL RLC segment reduction Run the MOD CELLALGOSWITCH command with the UlSmallRBSpectralEffOptSw option of the Uplink schedule switch parameter deselected. Run the MOD CELLULSCHALGO command with the Head Overhead For Uplink Scheduling parameter set to 0. • Disabling the function of PUCCH RB occupation by PUSCH Run the MOD CELLALGOSWITCH command with the PuschUsePucchRbSwitch option of the Uplink schedule switch parameter deselected. • Disabling proactive scheduling of UL signaling Run the MOD CELLALGOSWITCH command with the SrbProbeSchSwitch option of the Uplink Schedule Extended Switch parameter deselected. MML Command Examples • Disabling the UL Min-GBR guarantee function MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlMinGbrSwitch-0; • Disabling SINR adjustment MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=SinrAdjustSwitch-0&PuschDtxSwitch-0; • Disabling UL target IBLER adaptation MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlIblerAdjustSwitch-0; • Disabling scenario-specific false SRI detection threshold configuration MOD CELLULSCHALGO: LOCALCELLID=0, SRIFALSEDETTHDSWITCH=OFF; • Disabling cell-level preallocation //Disabling voice preallocation MOD CELLULSCHALGO:LOCALCELLID=0,ULENHENCEDVOIPSCHSW=UlVoipPreAllocationSwitch-0; //Disabling optimization of the delay for services with sparse packets (such as ping services) MOD CELLULSCHALGO: LOCALCELLID=0, SMARTPREALLOCDURAFORSPARSE=50, PREALLOCMINPERIODFORSPARSE=SAME_AS_OTHER_SERVICE, PREALLOCATIONSIZEF ORSPARSE=SAME_AS_OTHER_SERVICE; MOD CELLALGOSWITCH:LOCALCELLID=0,ULSCHEXTSWITCH=EnhancedSchForSparseSwitch-0; //Disabling UL smart preallocation MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=PreAllocationSwitch-1&SmartPreAllocationSwitch-0; //Disabling UL preallocation MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=PreAllocationSwitch-0; • Disabling QCI-level preallocation MOD CELLQCIPARA:LOCALCELLID=0,QCI=1,PREALLOCATIONPARAGROUPID=255; • Disabling enhanced UL SR-based scheduling MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlEnhancedSrSchSwitch-0; • Disabling data amount adaptation in UL SR-based scheduling MOD CELLALGOSWITCH:LOCALCELLID=0,UlSchSwitch=SrSchDataAdptSw-0; • Disabling the function of scheduling termination for abnormal UEs MOD CELLALGOSWITCH: LOCALCELLID=0, CELLSCHSTRATEGYSWITCH=AbnUeSchSwitch-0; • Disabling the function of scheduler-controlled power MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=SchedulerCtrlPowerSwitch-0; • Disabling PDCCH and PUSCH resource balancing MOD CELLULSCHALGO: LOCALCELLID=0, UENUMTHDINPDCCHPUSCHBAL=10000; • Disabling the function of UL RLC segment reduction MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=UlSmallRBSpectralEffOptSw-0; MOD CELLULSCHALGO: LOCALCELLID=0, HEADOVERHEADFORULSCH=0bit; • Disabling the function of PUCCH RB occupation by PUSCH MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHSWITCH=PuschUsePucchRbSwitch-0; • Disabling proactive scheduling of UL signaling MOD CELLALGOSWITCH: LOCALCELLID=0, UlSchExtSwitch=SrbProbeSchSwitch-0; 12.4 Deploying the Traffic Model Based Performance Optimization Feature 12.4.1 Requirements Operating Environment In CA scenarios, all CA cells must have this feature enabled. In performance analysis, all CA cells need to be observed. Transmission Networking N/A License Operators must purchase and activate the following license. Feature ID Feature Name Model License Control Item LOFD-110205 Traffic Model Based Performance Optimization LT1S00PLAS00 Traffic Model Based Performance Optimization (FDD) NE Sales Unit • Macro eNodeB • LampSite eNodeB • Micro eNodeB per cell 12.4.2 Precautions None 12.4.3 Data Preparation The following table describes the parameter that must be set in a CellAlgoSwitch MO to configure the Traffic Model Based Performance Optimization feature. Parameter Name Parameter ID Setting Notes Uplink Schedule Extended Switch CellAlgoSwitch.UlSchExtSwitch The UlPacketLenAwareSchSw(UlPacketLenAwareSchSw) option of this parameter specifies whether to enable Traffic Model Based Performance Optimization in the uplink. 12.4.4 Activation This feature can be activated using the CME or MML commands. Using the CME • Fast batch activation This feature can be batch activated using the Feature Operation and Maintenance function of the CME. For detailed operations, see the following section in the CME product documentation or online help: CME Management > CME Guidelines > Enhanced Feature Management > Feature Operation and Maintenance. • Single/batch configuration This feature can be activated for a single eNodeB or a batch of eNodeBs on the CME. For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the UlPacketLenAwareSchSw(UlPacketLenAwareSchSw) option of the Uplink Schedule Extended Switch parameter selected to enable Traffic Model Based Performance Optimization in the uplink. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHEXTSWITCH=UlPacketLenAwareSchSw-1; 12.4.5 Activation Observation 1. Check the number of users and RB usage in the cell. It is easy to observe the gains yielded by Packet Length Awareness Performance Optimization when the cell traffic load is heavy. Recommended configurations: • The cell serves more than 150 users. • UL RB usage is greater than 60%. To start cell RB usage monitoring, choose Monitor > Signaling Trace > Signaling Trace Management on the U2000. In the navigation tree, choose Cell Performance Monitoring > Usage of RB Monitoring. 2. Adjust service configurations. Recommended service configurations: • Average data rate for large-packet services: around 4 Mbit/s • Average data rate for small-packet services: around 12 kbit/s • Ratio of large-packet services to small-packet services: 1:4 3. Check perceivable user throughput after activating the feature for a while. If perceivable user throughput increases by 5% or higher, the Packet Length Awareness Performance Optimization feature has taken effect. 12.4.6 Reconfiguration None 12.4.7 Deactivation This feature can be deactivated using the CME or MML commands. Using the CME For detailed operations, see CME-based Feature Configuration. Using MML Commands Run the MOD CELLALGOSWITCH command with the UlPacketLenAwareSchSw(UlPacketLenAwareSchSw) option of the Uplink Schedule Extended Switch parameter deselected to disable Traffic Model Based Performance Optimization in the uplink. MML Command Examples MOD CELLALGOSWITCH: LOCALCELLID=0, ULSCHEXTSWITCH=UlPacketLenAwareSchSw-0; 12.5 Performance Monitoring In UL scheduling, the gains in UL user-perceived throughput can be monitored using the L.Thrp.bits.UE.UL.Experienced/L.Thrp.Time.UE.UL.Experienced formula. For the LBFD-00101502 Dynamic Scheduling feature: This feature supports quick configuration of counter collection by feature using the U2000. The measurement for the counters related to this feature can be set in a single operation. These counters are determined by the counter-feature relationships listed in the performance counter reference. For details about the operations, see "Quickly Setting Performance Measurement by Feature" in iManager U2000 MBB Network Management System Product Documentation. 12.6 Parameter Optimization N/A 12.7 Possible Issues N/A 13 Parameters Table 13-1 Parameters MO Parameter ID MML Command Feature ID Feature Name Description CellAlgoSwitch UlSchExtSwitch MOD CELLALGOSWITCH LST CELLALGOSWITCH LOFD-110205 / TDLOFD-110227 LOFD-001048 / TDLOFD-001048 LOFD-001016 / TDLOFD-001016 LOFD-081218 / TDLOFD-081215 LBFD-00101502 / TDLBFD-00101502 TDLBFD-002025 / LBFD-002025 TDLBFD-001006 TDLOFD-121106 Traffic Model Based Performance Optimization TTI Bundling VoIP Semipersistent Scheduling Enhanced Extended QCI Dynamic Scheduling Basic Scheduling AMC MCPTT Voice Management Meaning: Indicates whether to enable extended functions of uplink scheduling. UlPacketLenAwareSchSw: Indicates whether to optimize uplink packet length awareness performance. Packet length awareness performance is optimized in the uplink only if this option is selected. This option applies only to LTE FDD and LTE TDD. EnhExtQCITtiBundlingSwitch: Indicates whether to enable TTI bundling for push-to-talk (PTT) services with QCI 65, QCI 66, or enhanced extended QCIs. If this option is selected, the number of transmission opportunities increases within the air interface delay budget of PTT services, and uplink coverage is improved. This option applies only to LTE FDD and LTE TDD. EnhExtQCISpsSchSwitch: Indicates whether to enable semi-persistent scheduling during talk spurts of PTT services with QCI 65, QCI 66, or enhanced extended QCIs. If this option is selected, semi-persistent scheduling is applied. If this option is deselected, dynamic scheduling is applied. This option applies only to LTE FDD and LTE TDD. UlVoipRbRsvSwitch: Indicates whether to reserve PUSCH RBs for UEs running voice services in the uplink. This option does not take effect if the uplink cell bandwidth is less than 5 MHz. This option applies only to LTE FDD. UlThpEnhSwitch: Indicates whether to enable the enhanced uplink throughput improvement function. If this option is selected, the eNodeB calculates the PUCCH overhead based on the actual number of RBs occupied by the PUCCH when the number of UEs is small in the cell, which improves the uplink throughput. If this option is deselected, the eNodeB calculates the PUCCH overhead based on the current PUCCH resource configuration. This option applies only to LTE TDD. UlDataFitterRbCalcSwitch: Indicates whether to enable the algorithm of RB calculation based on uplink data volume matching. The algorithm takes effect only when this option and the SchedulerCtrlPowerSwitch option of the UlSchSwitch parameter are selected. When this algorithm takes effect, the number of required RBs is estimated based on the UE capability and the data volume to be scheduled. If this algorithm does not take effect, the number of required RBs is estimated based on the UE spectral efficiency and the data volume to be scheduled. This option applies only to LTE FDD. UlFssOptForAttach: Indicates whether to perform uplink frequency selective scheduling based on the value of Interf in the network entry phase. If this option is selected, uplink frequency selective scheduling is performed based on the interference level during network access. If this option is deselected, uplink frequency selective scheduling is performed based on the SINR during network access. This option can be selected when the ULFSSAlgoSwitch option of the UlSchSwitch parameter is selected. This option applies only to LTE TDD. SrbProbeSchSwitch: Indicates whether to proactively schedule uplink signaling. If this option is selected, the eNodeB triggers proactive scheduling of uplink signaling for once when the eNodeB determines that data correctly scheduled in the downlink is control-plane signaling that requires the uplink signaling feedback and does not receive the feedback within a specified period of time. This option applies only to LTE FDD and LTE TDD. UlSchCtrlPwrUserSetOptSw: Indicates whether to enable the algorithm of selecting UE sets for the scheduler-controlled power function. This algorithm takes effect only when this option and the SchedulerCtrlPowerSwitch option of the UlSchSwitch parameter are selected. When this algorithm takes effect, pre-scheduled UEs of a lower priority are not included in the UE set selected by the scheduler. When this algorithm MO Parameter ID MML Command Feature ID Feature Name Description does not take effect, all pre-scheduled UEs are included in the UE set selected by the scheduler. This option applies only to LTE FDD and LTE TDD. UlPttSchOptSwitch: Indicates whether to enable dynamic scheduling for PTT services with QCI 65, QCI 66, or enhanced extended QCIs. If this option is selected, for PTT service UEs that are scheduled dynamically in the uplink, the eNodeB triggers uplink dynamic scheduling when the scheduling interval is greater than the uplink voice scheduling interval threshold. This ensures timely uplink scheduling for voice service users in heavy traffic scenarios, preventing packet discarding upon the timeout of PDCP packet discarding timer. If this option is deselected, the eNodeB does not trigger uplink dynamic scheduling for PTT services in the preceding scenario. This option applies only to LTE FDD and LTE TDD. UlPttDataSizeEstSwitch: Indicates whether to estimate uplink traffic volume for dynamic scheduling of PTT services with QCI 65, QCI 66, or enhanced extended QCIs. If this option is selected, the eNodeB estimates uplink traffic volume for dynamic scheduling of PTT services, reducing the packet delay and packet loss rate and increasing voice quality of PTT services. If this option is deselected, the function does not take effect. This option applies only to LTE FDD and LTE TDD. EnhancedSchForSparseSwitch: Indicates whether ping packets are subject to the preallocation bandwidth percentage restriction and whether to change the method of calculating the number of RBs to be allocated for SR-based dynamic scheduling of ping packets. If this option is selected, ping packets are not subject to the preallocation bandwidth percentage restriction, and the number of RBs to be allocated for SRbased dynamic scheduling of ping packets is calculated based on the size of the ping packets. If this option is deselected, ping packets are subject to the preallocation bandwidth percentage restriction, and the number of RBs to be allocated for SR-based dynamic scheduling of ping packets is calculated based on the average spectral efficiency. For FDD, this option indicates only whether ping packets are subject to the preallocation bandwidth percentage restriction. This option applies only to LTE FDD and LTE TDD. UlSigSrSchDateLenAdapt: Indicates whether to enable data amount adaptation for SR-based scheduling of uplink signaling. The adaptation is enabled only if this option is selected. When the adaptation is enabled, the eNodeB adaptively allocates the amount of to-be-scheduled data and the number of RBs based on the signaling identification result in SR-based scheduling of uplink signaling. This option applies only to LTE FDD and LTE TDD. UlFssWindSearchDirRandSw: Indicates whether to randomize the search window direction in uplink frequency selective scheduling. The randomization is enabled only if this option is selected. When the randomization is enabled, the eNodeB randomly specifies a search window direction for a cell in frequency selective scheduling. This option applies only to LTE FDD. UlCellCenterMCSOptSwitch: Indicates whether to optimize MCSs for uplink transmission by UEs in the cell center. The optimization is enabled only if this option is selected. When the optimization is enabled, the throughput of full-buffer services of UEs in or near the cell center increases. This option applies only to LTE FDD and LTE TDD. PuschSchEscPucchSwitch: If this option is selected, PUCCH interference coordination takes effect, reducing PUCCH interference. This option applies only to LTE TDD. HarqMcsOptSwitch: If this option is selected, the instantaneous DMRS measurement value can be used to select an MCS index for retransmission. This option applies only to LTE TDD. MO Parameter ID MML Command Feature ID Feature Name Description PreambleSchEnhSwitch: If this option is selected, the preamble scheduling and demodulation success rates increase. If this option is deselected, the preamble scheduling and demodulation success rates do not increase. If this option is deselected in NB-IoT scenarios, the maximum backoff index included in MAC PDU is 12. If this option is selected in NB-IoT scenarios, the maximum backoff index included in MAC PDU is 7. This accommodates certain UEs not supporting higher backoff indexes. UlPAMCSwitch: If this option is selected, AMC maximizing the uplink perceived throughput takes effect and AMC adjustment and MCS index selection are performed in an optimized way. This option applies only to LTE FDD and LTE TDD. UlMultiClusterSwitch: Indicates whether to enable the uplink multi-cluster function. This function is enabled only when the option is selected. Uplink discontinuous resource allocation is supported when this function is enabled. This option applies only to LTE FDD. GUI Value Range: UlPacketLenAwareSchSw (UlPacketLenAwareSchSw), EnhExtQCITtiBundlingSwitch (EnhExtQCITtiBundlingSwitch), EnhExtQCISpsSchSwitch (EnhExtQCISpsSchSwitch), UlVoipRbRsvSwitch (UlVoipRbRsvSwitch), UlThpEnhSwitch (UlThpEnhSwitch), UlDataFitterRbCalcSwitch (UlDataFitterRbCalcSwitch), UlFssOptForAttach (UlFssOptForAttach), SrbProbeSchSwitch (SrbProbeSchSwitch), UlSchCtrlPwrUserSetOptSw (UlSchCtrlPwrUserSetOptSw), UlPttSchOptSwitch (UlPttSchOptSwitch), UlPttDataSizeEstSwitch (UlPttDataSizeEstSwitch), EnhancedSchForSparseSwitch (EnhancedSchForSparseSwitch), UlSigSrSchDateLenAdapt (UlSigSrSchDateLenAdapt), UlFssWindSearchDirRandSw (UlFssWindSearchDirRandSw), UlCellCenterMCSOptSwitch (UlCellCenterMCSOptSwitch), PuschSchEscPucchSwitch (PuschSchEscPucchSwitch), HarqMcsOptSwitch (HarqMcsOptSwitch), PreambleSchEnhSwitch (PreambleSchEnhSwitch), UlPAMCSwitch (UlPAMCSwitch), UlMultiClusterSwitch (UlMultiClusterSwitch) Unit: None Actual Value Range: UlPacketLenAwareSchSw, EnhExtQCITtiBundlingSwitch, EnhExtQCISpsSchSwitch, UlVoipRbRsvSwitch, UlThpEnhSwitch, UlDataFitterRbCalcSwitch, UlFssOptForAttach, SrbProbeSchSwitch, UlSchCtrlPwrUserSetOptSw, UlPttSchOptSwitch, UlPttDataSizeEstSwitch, EnhancedSchForSparseSwitch, UlSigSrSchDateLenAdapt, UlFssWindSearchDirRandSw, UlCellCenterMCSOptSwitch, PuschSchEscPucchSwitch, HarqMcsOptSwitch, PreambleSchEnhSwitch, UlPAMCSwitch, UlMultiClusterSwitch Default Value: UlPacketLenAwareSchSw:Off, EnhExtQCITtiBundlingSwitch:Off, EnhExtQCISpsSchSwitch:Off, UlVoipRbRsvSwitch:Off, UlThpEnhSwitch:Off, UlDataFitterRbCalcSwitch:On, UlFssOptForAttach:Off, SrbProbeSchSwitch:Off, UlSchCtrlPwrUserSetOptSw:Off, UlPttSchOptSwitch:Off, UlPttDataSizeEstSwitch:Off, EnhancedSchForSparseSwitch:Off, UlSigSrSchDateLenAdapt:Off, UlFssWindSearchDirRandSw:Off, UlCellCenterMCSOptSwitch:Off, PuschSchEscPucchSwitch:Off, HarqMcsOptSwitch:Off, PreambleSchEnhSwitch:Off, UlPAMCSwitch:Off, UlMultiClusterSwitch:Off MO Parameter ID MML Command Feature ID Feature Name Description CellAlgoSwitch CqiAdjAlgoSwitch MOD CELLALGOSWITCH LST CELLALGOSWITCH LBFD-00101501 / TDLBFD-00101501 LBFD-00101502 / TDLBFD-00101502 LBFD-002005 / TDLBFD-002005 TDLOFD-081231 CQI Adjustment Dynamic Scheduling DL Asynchronous HARQ Optimized CFICalculationbased MCS Index Selection Meaning: CqiAdjAlgoSwitch: Indicates whether to allow the eNodeB to adjust the UE-reported CQI based on the initial block error rate (IBLER). If this option is selected, the CQI adjustment algorithm is enabled. In this case, the eNodeB adjusts the UE-reported CQI based on the IBLER. If this option is deselected, the CQI adjustment algorithm is disabled. In this case, the eNodeB does not adjust the UE-reported CQI based on the IBLER. This option applies only to LTE FDD and LTE TDD. StepVarySwitch: Indicates whether to enable variable-step-based adjustment. If this option is selected, variable-step-based adjustment is enabled to accelerate the convergence of IBLER. In this case, rapid adjustment at large steps is applied if there is a large difference between the measured IBLER and target IBLER; fine-tuning at small steps is applied if the measured IBLER is close to the target IBLER. If this option is deselected, the adjustment is performed at a fixed step. This option applies only to LTE FDD and LTE TDD. DlVarIBLERtargetSwitch: Indicates whether to enable downlink target IBLER adaptation. If this option is selected, the downlink target IBLER is adaptively adjusted based on the TBS to improve spectral efficiency. If this option is deselected, the target IBLER is determined based on the setting of the DlEnVarIblerTargetSwitch option of this parameter. This option applies only to LTE FDD and LTE TDD. TddBundlingCqiAdjOptSwitch: Indicates whether to enable optimized CQI adjustment algorithm in ACK bundling mode. If this option is selected, the optimized CQI adjustment algorithm is enabled. If this option is deselected, the optimized CQI adjustment algorithm is disabled. This option applies only to LTE TDD. TddMultiplexingCqiAdjOptSwitch: Indicates whether to enable optimized CQI adjustment in ACK multiplexing mode. If this option is selected, optimized CQI adjustment is enabled. If this option is deselected, optimized CQI adjustment is disabled. This option applies only to LTE TDD. AdaptiveStepVarySwitch: Indicates whether to enable adaptive step change in CQI adjustment. This option applies only to LTE FDD and LTE TDD. If this option is selected, the CQI adjustment is performed at a large step when significant changes in the signal quality are detected, accelerating the IBLER convergence. If this option is deselected, the CQI adjustment is performed at a fixed step. DlCqiAdjDeltaOptSwitch: Indicates whether to optimize CQI adjustment amount calculation. If this option is deselected, the CQI adjustment amount is calculated using the following formula: CQI adjustment amount = (Number of ACKs for initial transmissions x CQI adjustment amount per ACK + Number of NACKs for initial transmissions x CQI adjustment amount per NACK)/(Number of NACKs for initial transmissions + Number of ACKs for initial transmissions). If this option is selected, the CQI adjustment amount is calculated using the following formula: CQI adjustment amount = Number of ACKs for initial transmissions x CQI adjustment amount per ACK + Number of NACKs for initial transmissions x CQI adjustment amount per NACK. This option applies only to LTE FDD and LTE TDD. DlEnVarIblerTargetSwitch: Indicates whether to enable enhanced downlink target IBLER adaptation. If this option is selected, the downlink target IBLER is adaptively adjusted based on CQI fluctuation and TBS. If this option is deselected, the downlink target IBLER policy is controlled by the DlVarIBLERtargetSwitch option of this parameter. This option applies only to LTE FDD and LTE TDD. DlRetxTbsIndexAdjOptSwitch: Indicates whether to optimize transport block size (TBS) index adjustment in retransmissions. If this option is MO Parameter ID MML Command Feature ID Feature Name Description selected, TBS index adjustment in retransmissions is optimized. The TBS index is lowered for the scheduling of the last two retransmissions, and the TBS index is determined based on the CQI adjustment result for the scheduling of other retransmissions. If this option is deselected, TBS index adjustment in retransmissions is not optimized. The TBS index is determined based on the CQI adjustment result for the scheduling of all retransmissions. This option applies only to LTE FDD and LTE TDD. CfiConvertOptSwitch: Indicates whether to optimize CFI conversion. If this option is selected, new CFI calculation tables for normal and special subframes are used to ensure more accurate MCS selection in normal and special subframes and facilitate IBLER convergence to the target value. If this option is deselected, the original CFI calculation tables for normal and special subframes are used. This option applies only to LTE TDD. BundlingOptThdSwitch: Indicates whether to adjust the MCS index threshold for enabling the optimized CQI adjustment algorithm in TDD bundling mode. If this option is selected, the lower MCS index threshold for enabling the optimized CQI adjustment algorithm in TDD bundling mode is changed from MCS index 6 to MCS index 0. If this option is deselected, the lower MCS index threshold for enabling the optimized CQI adjustment algorithm in TDD bundling mode is MCS index 6. This option applies only to LTE TDD. DlSpsMcsIncreaseSwitch: Indicates whether to enable MCS index increase for semi-persistent scheduling (SPS). If this option is selected, MCS index increase is enabled for SPS, reducing the number of RBs for SPS and improving cell performance when RB resources are limited. However, the VoLTE MOS value may decrease. If this option is deselected, MCS index increase is disabled for SPS, increasing the VoLTE MOS value. However, more RBs may be consumed for SPS. This option applies only to LTE FDD and LTE TDD. CqiAdjTimeEffSwitch: Indicates whether to enable validity evaluation and adjustment for CQI adjustment, and whether to trigger large-stepbased CQI adjustment when a long time has elapsed before a UE begins to perform services based on the setting of the AdaptiveStepVarySwitch option of this parameter. If this option is selected, the eNodeB evaluates the validity of all CQI adjustment values in a unified manner and adjusts these adjustment values based on the evaluation results. If this option and the AdaptiveStepVarySwitch option are selected, large-step-based CQI adjustment is triggered when a long time has elapsed before a UE begins to perform services. If this option is deselected, the eNodeB does not evaluate the validity of CQI adjustment values or adjust these values in a unified manner, and large-step-based CQI adjustment is not triggered when a long time has elapsed before a UE begins to perform services. This option applies only to LTE TDD. RptCqiFltInitSwitch: Indicates whether to adjust the initial filtered value of the reported CQI. If this option is selected, the initial filtered value of the reported CQI is determined based on the CQI value reported by the UE, and the filtering coefficient for the reported CQI in the first several reporting periods is adjusted. If this option is deselected, the initial filtered value of CQIs reported by all UEs is fixed to 4. This option applies only to LTE FDD and LTE TDD. UeSigInitCqiModSwitch: Indicates the time when the reported initial CQI takes effect. If this option is selected, the reported initial CQI takes effect when the ACK to Msg4 HARQ retransmission is received or when Msg5 is received. If this option is deselected, the reported CQI immediately takes effect. This option applies only to LTE TDD. CqiFastCompstSwitch: Indicates whether the eNodeB performs fast CQI compensation for the MO Parameter ID MML Command Feature ID Feature Name Description following UEs: UEs handed over to cells whose values of PCI modulo 3 conflict with source cells' values of PCI modulo 3, beamforming UEs in 8T8R cells, and UEs reporting aperiodic CQIs during network access under a high CAPS condition. If this option is selected, the eNodeB identifies these UEs and quickly compensates for their CQIs. If this option is deselected, the eNodeB does not identify these UEs for CQI compensation. This option applies only to LTE TDD. CfiConvertWiDrsSwitch: Indicates whether to consider the DMRS overhead when converting the control format indicator (CFI) for beamforming UEs. If this option is selected, the eNodeB considers the DMRS overhead when converting the CFI of beamforming UEs. If this option is deselected, the eNodeB does not consider the DMRS overhead when converting the CFI of beamforming UEs in open-loop TM7, TM8, or TM9 mode. This option applies only to LTE FDD and LTE TDD. IblerCqiOffsetSwitch: Indicates whether to perform CQI compensation based on the target IBLER. The eNodeB performs CQI compensation based on the target IBLER only if this option is selected. This option applies only to LTE TDD. CqiFltOptSwitch: Indicates whether to optimize CQI filtering. If this option is selected, the eNodeB determines whether to discard a UE-reported CQI based on this reported CQI and the previous HARQ retransmission IBLER, does not filter CQIs again in case of TM change, and triggers both large step increase and large step decrease during step adaptation. If this option is deselected, the eNodeB directly uses UE-reported CQIs, filters CQIs again in case of TM change, and triggers only large step increase during step adaptation. This option applies only to LTE TDD. PreciseMcsAdaptSwitch: Indicates whether to enable precise MCS adaptation. If this option is selected, the eNodeB selects the TBS with a higher index for the first downlink HARQ retransmission. In addition, when the initial CQI adjustment amount is relatively conservative, the eNodeB increases and compensates for the CQI adjustment amount. If this option is deselected, the eNodeB does not perform the preceding operations. This option applies only to LTE FDD. PilotOffCqiAdjOptSwitch: Indicates CQI adaptation optimization for CRS transmission disabling. If this option is selected, for UEs regarded as largepacket UEs when the BreathingPilotSwitch or EmimoCpsSwitch option is selected, the CQI adjustment is performed at a large step in case of significant signal quality changes. If this option is deselected, the CQI adjustment is performed at a fixed step for the preceding UEs. This option applies only to LTE FDD. GUI Value Range: CqiAdjAlgoSwitch (CqiAdjAlgoSwitch), StepVarySwitch (StepVarySwitch), DlVarIBLERtargetSwitch (DlVarIBLERtargetSwitch), TddBundlingCqiAdjOptSwitch (TddBundlingCqiAdjOptSwitch), TddMultiplexingCqiAdjOptSwitch (TddMultiplexingCqiAdjOptSwitch), AdaptiveStepVarySwitch (AdaptiveStepVarySwitch), DlCqiAdjDeltaOptSwitch(DlCqiAdjDeltaOptSwitch), DlEnVarIblerTargetSwitch (DlEnVarIblerTargetSwitch), DlRetxTbsIndexAdjOptSwitch (DlRetxTbsIndexAdjOptSwitch), CfiConvertOptSwitch(CfiConvertOptSwitch), BundlingOptThdSwitch(BundlingOptThdSwitch), DlSpsMcsIncreaseSwitch (DlSpsMcsIncreaseSwitch), CqiAdjTimeEffSwitch (CqiAdjTimeEffSwitch), RptCqiFltInitSwitch (RptCqiFltInitSwitch), UeSigInitCqiModSwitch (UeSigInitCqiModSwitch), CqiFastCompstSwitch (CqiFastCompstSwitch), CfiConvertWiDrsSwitch (CfiConvertWiDrsSwitch), IblerCqiOffsetSwitch (IblerCqiOffsetSwitch), CqiFltOptSwitch (CqiFltOptSwitch), PreciseMcsAdaptSwitch MO Parameter ID MML Command Feature ID Feature Name Description (PreciseMcsAdaptSwitch), PilotOffCqiAdjOptSwitch(PilotOffCqiAdjOptSwitch) Unit: None Actual Value Range: CqiAdjAlgoSwitch, StepVarySwitch, DlVarIBLERtargetSwitch, TddBundlingCqiAdjOptSwitch, TddMultiplexingCqiAdjOptSwitch, AdaptiveStepVarySwitch, DlCqiAdjDeltaOptSwitch, DlEnVarIblerTargetSwitch, DlRetxTbsIndexAdjOptSwitch, CfiConvertOptSwitch, BundlingOptThdSwitch, DlSpsMcsIncreaseSwitch, CqiAdjTimeEffSwitch, RptCqiFltInitSwitch, UeSigInitCqiModSwitch, CqiFastCompstSwitch, CfiConvertWiDrsSwitch, IblerCqiOffsetSwitch, CqiFltOptSwitch, PreciseMcsAdaptSwitch, PilotOffCqiAdjOptSwitch Default Value: CqiAdjAlgoSwitch:On, StepVarySwitch:Off, DlVarIBLERtargetSwitch:Off, TddBundlingCqiAdjOptSwitch:Off, TddMultiplexingCqiAdjOptSwitch:Off, AdaptiveStepVarySwitch:Off, DlCqiAdjDeltaOptSwitch:Off, DlEnVarIblerTargetSwitch:Off, DlRetxTbsIndexAdjOptSwitch:On, CfiConvertOptSwitch:Off, BundlingOptThdSwitch:Off, DlSpsMcsIncreaseSwitch:Off, CqiAdjTimeEffSwitch:Off, RptCqiFltInitSwitch:Off, UeSigInitCqiModSwitch:Off, CqiFastCompstSwitch:Off, CfiConvertWiDrsSwitch:Off, IblerCqiOffsetSwitch:Off, CqiFltOptSwitch:Off, PreciseMcsAdaptSwitch:Off, PilotOffCqiAdjOptSwitch:Off CellDlschAlgo DlFirstHarqTxTbsIncNum MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-002025 LBFD-002005 Basic Scheduling DL Asynchronous HARQ Meaning: Indicates the increase in the TBS index used for the first downlink HARQ retransmission. When this parameter is set to 0, the eNodeB does not increase the TBS index used for the first downlink HARQ retransmission. This parameter applies only to LTE FDD. This parameter takes effect only when the PreciseMcsAdaptSwitch option of the CqiAdjAlgoSwitch parameter in the CellAlgoSwitch MO is selected. GUI Value Range: 0~4 Unit: None Actual Value Range: 0~4 Default Value: 0 CellDlschAlgo LowIblerTargetTbsIdxThld MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101501 / TDLBFD-00101501 LBFD-00101502 / TDLBFD-00101502 CQI Adjustment Dynamic Scheduling Meaning: Indicates whether to enable TBS-index-based enhanced downlink target IBLER adaptation. This parameter applies only to LTE FDD and LTE TDD. The value 255 indicates that the enhanced downlink target IBLER adaptation algorithm does not adjust the target IBLER based on the TBS index. Instead, the UE number is used as the admission condition for the enhanced downlink target IBLER adaptation algorithm. Values other than 255 indicate that the enhanced downlink target IBLER adaptation algorithm adjusts the target IBLER based on the TBS index. In this situation, the CPU usage is used as the admission condition for the enhanced downlink target IBLER adaptation algorithm, and the low target IBLER value takes effect based on the TBS index when channel quality fluctuates slightly. When channel quality fluctuates slightly, the low target IBLER value takes effect only when the TBS index is greater than or equal to this parameter value and the DlEnVarIblerTargetSwitch option is selected. GUI Value Range: 0~33,255 Unit: None Actual Value Range: 0~33,255 Default Value: 255 CellDlschAlgo HighIblerTargetTbsIdxThld MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101501 / TDLBFD-00101501 LBFD-00101502 / TDLBFD-00101502 CQI Adjustment Dynamic Scheduling Meaning: Indicates the threshold for TBS index based on which the high target IBLER value takes effect when channel quality fluctuates significantly. When channel quality fluctuates significantly, the high target IBLER value takes effect only when the TBS index is less than or equal to this parameter MO Parameter ID MML Command Feature ID Feature Name Description value, the DlEnVarIblerTargetSwitch option is selected, and LowIblerTargetTbsIdxThld is not set to 255. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~33 Unit: None Actual Value Range: 0~33 Default Value: 16 CellPucchAlgo SriAlgoSwitch MOD CELLPUCCHALGO LST CELLPUCCHALGO LBFD-002003 / TDLBFD-002003 LOFD-081229 Physical Channel Management Voice Characteristic Awareness Scheduling Meaning: Indicates the working modes for SRI reporting period configuration. SriAdaptiveHoldForVoIPSW: Indicates whether to enable SRI reporting period adaptation for VoLTE UEs during resource adjustment for SRI reporting. If this option is selected, SRI reporting periods are configured based on the cell load. If the number of UEs is small, adaptively configured SRI reporting periods are shorter than the fixed long SRI reporting period, improving the MOS of VoLTE users. If this option is deselected, the fixed long SRI reporting period is retained. SriAdaptiveHoldForVoIPSW takes effect only when both PUCCH resource adjustment and SRI reporting period adaptation are enabled. This option applies only to LTE FDD and LTE TDD. SriPeriodCfgOptSW: Indicates whether to optimize SRI reporting period configuration. If this option is selected, SRI reporting periods are configured based only on the SRI reporting resource usage in the cell. When CA and VoLTE are enabled, many UEs can be assigned short SRI reporting periods, the amount of PUCCH resource increases, but the amount of available PUSCH resource decreases. If this option is deselected, SRI reporting periods are configured based on the resource usage of SRI reporting, semi-persistent ACK reporting, and dynamic ACK reporting. When CA and VoLTE are enabled, few UEs can be assigned short SRI reporting periods, the amount of PUCCH resource decreases, but the amount of available PUSCH resource increases. This option applies only to LTE FDD and LTE TDD. SriOffsetReConfigForDrxSW: indicates whether to reconfigure the SRI subframe offset for DRX. This option applies only to LTE FDD. If this option is selected, the eNodeB adjusts SRI and DRX subframe offsets for power saving. If this option is deselected, the eNodeB does not perform this function. SriPeriodOptForVoipSW: Indicates whether to perform VoLTE-based adaptive SRI period optimization. If this option is selected, the eNodeB preferentially allocates a short SRI period for VoLTE UEs, thereby improving user experience of VoLTE UEs. This option takes effect only when SriPeriodAdaptive is set to QCIADAPTIVE and SriReCfgInd is set off. This option applies only to FDD. If this option is deselected, the eNodeB does not perform this function. SriDetectEnhanceSW: Indicates whether to enable L1 detection enhancement algorithm for PUCCH SRI. When this option is selected, the PUCCH SRI detection enhancement algorithm is enabled for a cell. In this case, an optimized interference noise estimation algorithm applies to the PUCCH format1 detection. This helps effectively suppress false SRI detections. When this option is deselected, the PUCCH SRI detection enhancement algorithm is not enabled, and the original demodulation algorithm is used for PUCCH format1 detection. This option applies only to LTE FDD and LTE TDD. GUI Value Range: SriAdaptiveHoldForVoIPSW (SriAdaptiveHoldForVoIPSW), SriPeriodCfgOptSW (SriPeriodCfgOptSW), SriOffsetReConfigForDrxSW (SriOffsetReConfigForDrxSW), SriPeriodOptForVoipSW (SriPeriodOptForVoipSW), SriDetectEnhanceSW (SriDetectEnhanceSW) Unit: None MO Parameter ID MML Command Feature ID Feature Name Description Actual Value Range: SriAdaptiveHoldForVoIPSW, SriPeriodCfgOptSW, SriOffsetReConfigForDrxSW, SriPeriodOptForVoipSW, SriDetectEnhanceSW Default Value: SriAdaptiveHoldForVoIPSW:Off, SriPeriodCfgOptSW:On, SriOffsetReConfigForDrxSW:Off, SriPeriodOptForVoipSW:Off, SriDetectEnhanceSW:Off CellAlgoSwitch CellDlCoverEnhanceSwitch MOD CELLALGOSWITCH LST CELLALGOSWITCH CellUlschAlgo UlSrSchDataVolAdptOptUpThd MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the upper limit on the amount of data that can be scheduled in SR-based scheduling. This parameter, together with the UlSrSchDateLen parameter, determines the range within which this amount can be adaptively optimized. If this parameter is set to 0, adaptive optimization does not take effect. If this parameter is set to a value greater than 0 and less than the UlSrSchDateLen parameter value, this parameter takes the value of UlSrSchDateLen. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~20000 Unit: bit Actual Value Range: 0~20000 Default Value: 0 ENodeBAlgoSwitch UlResManageOptSw MOD ENODEBALGOSWITCH LST ENODEBALGOSWITCH LBFD-001006 LOFD001066/TDLOFD001066 LOFD-070222 LOFD-070223 AMC Intra-eNodeB UL CoMP Intra-eNodeB UL CoMP Phase II UL CoMP based on Coordinated BBU Meaning: Indicates whether to enable functions related to uplink resource optimization. UL_RBCALC_OPT_SWITCH: Indicates whether to enable the optimization of uplink RB quantity calculation for cell-edge UEs and optimization of uplink CoMP resource pools. These optimization functions, which can be used when the schedulercontrolled power function is used, are enabled only if this option is selected. This option applies only to LTE FDD and LTE TDD. GUI Value Range: UL_RBCALC_OPT_SWITCH (UlRbCalcOptSwitch) Unit: None Actual Value Range: UL_RBCALC_OPT_SWITCH Default Value: UL_RBCALC_OPT_SWITCH:Off CellAlgoSwitch DlSchSwitch MOD CELLALGOSWITCH LST CELLALGOSWITCH LOFD-110205 / TDLOFD-110227 LOFD-001016 / TDLOFD-001016 LBFD-00101502 / TDLBFD-00101502 LOFD-001109 / TDLOFD-001109 LOFD-001070 / TDLOFD-001070 TDLOFD-070224 / TDLOFD-070222 LBFD-002025 / TDLBFD-002025 LBFD-002031 / TDLBFD-002031 LBFD-070102 / TDLBFD-070102 Traffic Model Based Performance Optimization VoIP Semipersistent Scheduling Dynamic Scheduling DL Non-GBR Packet Bundling Symbol Power Saving Scheduling Based on Max Bit Rate Meaning: Indicates whether to enable downlink scheduling algorithms in a cell. This parameter includes the following options: FreqSelSwitch: Indicates whether to enable frequency-selective scheduling. If this option is selected, data is transmitted on the frequency band of high channel quality. This option applies only to LTE FDD and LTE TDD. SpsSchSwitch: Indicates whether to enable semipersistent scheduling during talk spurts of VoLTE services. If this option is selected, semi-persistent scheduling is applied during talk spurts of VoLTE services. If this option is deselected, dynamic scheduling is applied during talk spurts of VoLTE services. This option applies only to LTE FDD and LTE TDD. MBSFNShutDownSwitch: Indicates whether to enable Multimedia Broadcast multicast service LBFD-070106 LEOFD-121204 PDSCH Efficiency Improvement 3D Beamforming Meaning: DlCellCoverEnhanceAlgoSw: Indicates whether to enable cell coverage enhancement. Enabling this function can increase the throughput of cell edge UEs (CEUs) and improve cell coverage. AdptCellEdgePwrAllocSw: Indicates whether to enable adaptive power matching. Enabling this function in a lightly loaded wide coverage area helps improve the performance of CEUs. This function is enabled only when this option is selected. This option applies only to LTE FDD. GUI Value Range: DlCellCoverEnhanceAlgoSw (DlCellCoverEnhanceAlgoSw), AdptCellEdgePwrAllocSw (AdptCellEdgePwrAllocSw) Unit: None Actual Value Range: DlCellCoverEnhanceAlgoSw, AdptCellEdgePwrAllocSw Default Value: DlCellCoverEnhanceAlgoSw:off, AdptCellEdgePwrAllocSw:off MO Parameter ID MML Command Feature ID Feature Name Description LBFD-060202 LOFD-081218 LTROFD-111204 / TDLOFD-121106 TDLBFD-002005 LBFD-060101 LBFD-060103 / TDLBFD-080102 LEOFD-111305 LEOFD-111307 TDLOFD-121105 Basic Scheduling Support of aperiodic CQI reports MBR>GBR Configuration Enhanced DL Frequency Selective Enhanced extended QCI MCPTT Voice Management DL Asynchronous HARQ Optimization of Periodic and Aperiodic CQI Reporting Enhanced DL Frequency Selective Scheduling Virtual 4T4R eMIMO PRRC and DRX Policy for Public Safety Single Frequency Network (MBSFN) subframe shutdown. If this option is selected, MBSFN subframe shutdown is applied. If this option is deselected, MBSFN subframe shutdown is not applied. This option takes effect only if the SymbolShutdownSwitch option of the PowerSaveSwitch parameter is selected. If the MBSFNShutDownSwitch option is selected, the setting of the switch for mapping SIBs to SI messages becomes invalid. If the MBSFNShutDownSwitch option is deselected, the setting of the switch for mapping SIBs to SI messages becomes valid. The MBSFNShutDownSwitch option applies only to LTE-only base stations. This option applies only to LTE FDD and LTE TDD. NonGbrBundlingSwitch: Indicates whether to enable downlink non-GBR packet bundling. If this option is selected, delay of non-GBR services can be controlled in non-congestion scenarios. If this option is deselected, delay of non-GBR services cannot be controlled. This option applies only to LTE FDD and LTE TDD. EnAperiodicCqiRptSwitch: Indicates whether to enable enhanced aperiodic channel quality indicator (CQI) reporting. If this option is selected, the eNodeB triggers aperiodic CQI reporting for a UE based on downlink services of the UE and the interval at which the UE sends periodic CQI reports. If this option is deselected, UEs under non-frequency-selective scheduling do not trigger aperiodic CQI reporting based on downlink services and trigger an aperiodic CQI reporting if no valid periodic CQI reports are sent in eight consecutive periodic CQI reporting periods. This option applies only to LTE FDD and LTE TDD. DlMbrCtrlSwitch: Indicates whether to enable downlink scheduling based on the maximum bit rate (MBR) and guaranteed bit rate (GBR) on GBR bearers. If this option is selected, the eNodeB performs downlink scheduling on GBR bearers based on the MBR and GBR. If this option is deselected, the eNodeB performs downlink scheduling on GBR bearers based on the GBR only. This option applies only to LTE FDD and LTE TDD. MbrDlSchSwitch: Indicates whether the eNodeB performs downlink scheduling based on MBR. If this option is selected, the eNodeB prioritizes UEs based on the MBRs during downlink scheduling. This parameter applies only to LTE TDD. UeAmbrDlSchSwitch: Indicates whether the eNodeB performs downlink scheduling based on per UE aggregate maximum bit rates (UEAMBRs). If this option is selected, the eNodeB prioritizes UEs based on the UE-AMBRs during downlink scheduling. This option applies only to LTE TDD. EpfEnhancedSwitch: Indicates whether to enable enhanced proportional fair (EPF) enhancement for scheduling. EPF enhancement for scheduling is enabled only if this option is selected. This option applies only to LTE FDD and LTE TDD. AperiodicCqiTrigOptSwitch: Indicates whether to optimize triggering of aperiodic CQI reporting. If this option is selected, a UE performing initial access triggers aperiodic CQI reporting based on related trigger conditions after the DLMAC instance has been established for 200 ms and the eNodeB receives MSG5. Consider that aperiodic CQI reporting is triggered by invalid CQI reports in eight consecutive CQI reporting periods. If cyclic redundancy check (CRC) on aperiodic CQI reports fails, aperiodic CQI reporting is not repeatedly triggered when DRX is enabled; or aperiodic CQI reporting is triggered after eight TTIs when DRX is disabled. If this option is deselected, a UE performing initial access triggers aperiodic CQI reporting based on related trigger conditions after the DLMAC instance has been established for 200 ms. Consider that aperiodic CQI reporting is triggered by invalid CQI reports in eight consecutive CQI reporting periods. If CRC on aperiodic CQI reports fails, aperiodic CQI reporting MO Parameter ID MML Command Feature ID Feature Name Description is triggered after eight TTIs, regardless of the DRX status. This option applies only to LTE FDD and LTE TDD. VoipTbsBasedMcsSelSwitch: Indicates whether the modulation and coding scheme (MCS) index is selected based on the transport block size (TBS) in downlink scheduling for VoLTE services. The MCS index is selected based on the TBS in downlink dynamic scheduling for VoLTE services only if this option is selected. This option applies only to LTE FDD and LTE TDD. PagingInterfRandSwitch: Indicates whether to enable interference randomization for paging messages. If this option is selected, interference randomization is enabled for paging messages. This option applies only to LTE FDD and LTE TDD. DlSingleUsrMcsOptSwitch: Indicates conditions for lowering the MCS index for a single UE. If this option is selected, the MCS index can be lowered for a UE if the UE is the only UE to be scheduled in a transmission time interval (TTI). If this option is deselected, the MCS index can be lowered for a UE if the threshold for the function of lowering the MCS index to increase the number of RBs is reached and the UE is the only UE to be scheduled in a TTI. This option applies only to LTE FDD and LTE TDD. UeSigMcsEnhanceSwitch: Indicates whether to enable MCS optimization for UE signaling. If this option is selected, MCS optimization for UE signaling is enabled. For LTE FDD, the MCS index for UE signaling is the same as the MCS index for data. For LTE TDD, the MCS index for UE signaling is lowered based on the MCS index for data. If this option is deselected, a fixed low MCS index is used for UE signaling. This option applies only to LTE FDD and LTE TDD. SubframeSchDiffSwitch: Indicates whether to increase the number of UEs scheduled in subframes 3 and 8 when uplink-downlink configuration 2 is used. If this option is selected, the number of UEs scheduled in subframes 3 and 8 is increased when uplink-downlink configuration 2 is used. If this option is deselected, the scheduling policy used in subframes 3 and 8 is the same as that used in other downlink subframes when uplink-downlink configuration 2 is used. This option applies only to LTE TDD. TailPackagePriSchSwitch: Indicates whether to enable scheduling of downlink connected tail packages in the bearer. If this option is selected, the connected tail package is scheduled preferentially in the next TTI, which reduces the delay and increases the transmission rate. If this option is deselected, the scheduling policy of the connected tail package is the same as other downlink subframes. This option applies only to LTE TDD. SIB1InterfRandSwitch: Indicates whether to enable SIB1 interference randomization. If this option is selected, interference randomization is enabled for SIB1. This option applies only to LTE TDD. FreqSelJudgeIgnorDopplerSwitch: Indicates whether to ignore Doppler conditions. If this option is selected, Doppler conditions are ignored during frequency selective channel determination. If this option is deselected, Doppler conditions are considered during frequency selective channel determination. This parameter applies only to LTE FDD. EnhExtQCISpsSchSwitch: Indicates whether to enable semi-persistent scheduling during talk spurts of PTT services with standardized QCI 65, standardized QCI 66, or an enhanced extended QCI. If this option is selected, semi-persistent scheduling is applied. If this option is deselected, dynamic scheduling is applied. This option applies only to LTE FDD and LTE TDD. DlVoipBundlingSwitch: Indicates whether to enable active packet bundling for downlink VoLTE services. Active packet bundling is enabled for downlink VoLTE services only if this option is MO Parameter ID MML Command Feature ID Feature Name Description selected. If this option is selected, PDCCH resources can be saved for downlink data services or uplink services, thereby increasing the VoLTE capacity for VoLTE services or increasing the throughput of data services in mixed service scenarios. However, the delay in VoLTE voice packet scheduling will increase in the downlink and MOSs may decrease. You are advised to deselect this option if you prefer VoLTE performance and do not expect MOS reduction. This option applies only to LTE FDD and LTE TDD. DlPacketLenAwareSchSw: Indicates whether to enable packet length awareness performance optimization in the downlink. Packet length awareness performance optimization is enabled in the downlink only if this option is selected. This option applies only to LTE FDD and LTE TDD. RLCArqFeedbackEnhancedSwitch: Indicates whether to modify HARQ feedback results based on RLC status reports when uplink-downlink configuration 2 is used. If this option is selected, the eNodeB modifies HARQ feedback results based on RLC status reports after receiving the reports. This prevents unnecessary HARQ retransmissions. This option applies only to LTE TDD. PaReconfigOptSwitch: Indicates whether to enable PA reconfiguration optimization. The optimization is enabled when this option is selected. This option applies only to LTE FDD and LTE TDD. RankRapidRptSwitch: Indicates whether to enable fast rank reporting. If this option is selected, an aperiodic CQI reporting is immediately triggered after successful network access. If this option is deselected, an aperiodic CQI reporting is not immediately triggered after successful network access. This option applies only to LTE FDD and LTE TDD. DlRLCStateReportSchDelaySw: Indicates whether to enable optimization on the delay-based scheduling of downlink RLC status reports. The optimization is enabled when this option is selected. This option applies only to LTE FDD and LTE TDD. SmallPktMcsSelectAlgoSw: Indicates whether to enable MCS selection for small packets. If this option is selected, the scheduler selects an MCS with a lower index based on the amount of data to be initially transmitted and the allocated TBS in each TTI on condition that the allocated TBS can carry the data. The function is enabled only if this option is selected. This option applies only to LTE FDD and LTE TDD. SRB0SplitSchSw: Indicates whether to enable separate scheduling of SRB0 and contention resolution MCE. If this option is selected, SRB0 and contention resolution MCE are separately scheduled. This option applies only to LTE FDD and LTE TDD. BfUserPairPriorSwitch: Indicates whether to preferentially allocate resources to paired beamforming UEs for UE pairing features such as MU beamforming and DMIMO. If this option is selected, the eNodeB preferentially allocates resources to paired beamforming UEs for UE pairing features such as MU beamforming and DMIMO. This option applies only to LTE TDD. HarqAllocOptSwitch: Indicates whether to optimize the allocation of HARQ processes. If this option is selected, the downlink UE rate increases. This option takes effect only when DMIMO or massive MIMO is enabled. This option applies only to LTE TDD. Pusch32Switch: Indicates whether to enable the PUSCH 3-2 feedback mode. If this option is selected, UEs that support the PUSCH 3-2 feedback mode use this mode to aperiodically report CQIs. If this option is deselected, the mode cannot be used. This option applies only to LTE FDD. DlPreciseAmbrCtrlSwitch: Indicates whether to enable precise downlink AMBR control. If this option is selected, a more accurate optimization MO Parameter ID MML Command Feature ID Feature Name Description algorithm applies to the AMBR control, which achieves more accurate AMBR control. If this option is deselected, the original AMBR control algorithm is used. This option applies only to LTE FDD and LTE TDD. GUI Value Range: FreqSelSwitch(FreqSelSwitch), SpsSchSwitch(SpsSchSwitch), MBSFNShutDownSwitch (MBSFNShutDownSwitch), NonGbrBundlingSwitch(NonGbrBundlingSwitch), EnAperiodicCqiRptSwitch (EnAperiodicCqiRptSwitch), DlMbrCtrlSwitch (DlMbrCtrlSwitch), MbrDlSchSwitch (MbrDlSchSwitch), UeAmbrDlSchSwitch (UeAmbrDlSchSwitch), EpfEnhancedSwitch (EpfEnhancedSwitch), AperiodicCqiTrigOptSwitch (AperiodicCqiTrigOptSwitch), VoipTbsBasedMcsSelSwitch (VoipTbsBasedMcsSelSwitch), PagingInterfRandSwitch(PagingInterfRandSwitch), DlSingleUsrMcsOptSwitch (DlSingleUsrMcsOptSwitch), SubframeSchDiffSwitch(SubframeSchDiffSwitch), TailPackagePriSchSwitch (TailPackagePriSchSwitch), UeSigMcsEnhanceSwitch (UeSigMcsEnhanceSwitch), FreqSelJudgeIgnorDopplerSwitch (FreqSelJudgeIgnorDopplerSwitch), SIB1InterfRandSwitch(SIB1InterfRandSwitch), EnhExtQCISpsSchSwitch (EnhExtQCISpsSchSwitch), DlVoipBundlingSwitch (DlVoipBundlingSwitch), DlPacketLenAwareSchSw (DlPacketLenAwareSchSw), RLCArqFeedbackEnhancedSwitch (RLCArqFeedbackEnhancedSwitch), PaReconfigOptSwitch(PaReconfigOptSwitch), RankRapidRptSwitch(RankRapidRptSwitch), DlRLCStateReportSchDelaySw (DlRLCStateReportSchDelaySw), SmallPktMcsSelectAlgoSw (SmallPktMcsSelectAlgoSw), SRB0SplitSchSw (SRB0SplitSchSw), BfUserPairPriorSwitch (BfUserPairPriorSwitch), HarqAllocOptSwitch (HarqAllocOptSwitch), Pusch32Switch (Pusch32Switch), DlPreciseAmbrCtrlSwitch (DlPreciseAmbrCtrlSwitch) Unit: None Actual Value Range: FreqSelSwitch, SpsSchSwitch, MBSFNShutDownSwitch, NonGbrBundlingSwitch, EnAperiodicCqiRptSwitch, DlMbrCtrlSwitch, MbrDlSchSwitch, UeAmbrDlSchSwitch, EpfEnhancedSwitch, AperiodicCqiTrigOptSwitch, VoipTbsBasedMcsSelSwitch, PagingInterfRandSwitch, DlSingleUsrMcsOptSwitch, SubframeSchDiffSwitch, TailPackagePriSchSwitch, UeSigMcsEnhanceSwitch, FreqSelJudgeIgnorDopplerSwitch, SIB1InterfRandSwitch, EnhExtQCISpsSchSwitch, DlVoipBundlingSwitch, DlPacketLenAwareSchSw, RLCArqFeedbackEnhancedSwitch, PaReconfigOptSwitch, RankRapidRptSwitch, DlRLCStateReportSchDelaySw, SmallPktMcsSelectAlgoSw, SRB0SplitSchSw, BfUserPairPriorSwitch, HarqAllocOptSwitch, Pusch32Switch, DlPreciseAmbrCtrlSwitch Default Value: FreqSelSwitch:Off, SpsSchSwitch:Off, MBSFNShutDownSwitch:Off, NonGbrBundlingSwitch:Off, EnAperiodicCqiRptSwitch:Off, DlMbrCtrlSwitch:Off, MbrDlSchSwitch:Off, UeAmbrDlSchSwitch:Off, EpfEnhancedSwitch:Off, AperiodicCqiTrigOptSwitch:On, VoipTbsBasedMcsSelSwitch:On, PagingInterfRandSwitch:Off, DlSingleUsrMcsOptSwitch:Off, SubframeSchDiffSwitch:Off, TailPackagePriSchSwitch:Off, UeSigMcsEnhanceSwitch:Off, FreqSelJudgeIgnorDopplerSwitch:Off, MO Parameter ID MML Command Feature ID Feature Name Description SIB1InterfRandSwitch:On, EnhExtQCISpsSchSwitch:Off, DlVoipBundlingSwitch:Off, DlPacketLenAwareSchSw:Off, RLCArqFeedbackEnhancedSwitch:Off, PaReconfigOptSwitch:Off, RankRapidRptSwitch:Off, DlRLCStateReportSchDelaySw:Off, SmallPktMcsSelectAlgoSw:Off, SRB0SplitSchSw:Off, BfUserPairPriorSwitch:Off, HarqAllocOptSwitch:Off, Pusch32Switch:Off, DlPreciseAmbrCtrlSwitch:Off CellCqiAdjAlgo CqiOptSwitch MOD CELLCQIADJALGO LST CELLCQIADJALGO LBFD-00101501 / CQI TDLBFD-00101501 Adjustment Meaning: Indicates whether to enable optimization algorithms for CQI transmission on the PUCCH and PUSCH. PUSCH_CQI_FALSE_DETECTION_SW: Indicates whether to enable the algorithm of counteracting false detection of CQIs on the PUSCH. The algorithm effectively reduces the probability of false CQI detection. False CQI detection occurs if a UE does not report a CQI but the eNodeB detects a CQI from the UE. The algorithm is enabled only if this option is selected. This option applies only to LTE FDD and LTE TDD. PUCCH_CQI_FALSE_DETECTION_SW: Indicates whether to enable the algorithm of counteracting false detection of CQIs on the PUCCH. The algorithm is enabled only if this option is selected. This option applies only to LTE FDD and LTE TDD. GUI Value Range: PUSCH_CQI_FALSE_DETECTION_SW (PUSCH_CQI_FALSE_DETECTION_SW), PUCCH_CQI_FALSE_DETECTION_SW (PUCCH_CQI_FALSE_DETECTION_SW) Unit: None Actual Value Range: PUSCH_CQI_FALSE_DETECTION_SW, PUCCH_CQI_FALSE_DETECTION_SW Default Value: PUSCH_CQI_FALSE_DETECTION_SW:Off, PUCCH_CQI_FALSE_DETECTION_SW:Off CellDlschAlgo FSUEAperCQITrigPeriod MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD00101502/TDLBFD00101502 LBFD002031/TDLBFD002031 LBFD-060103 Dynamic Scheduling Support of aperiodic CQI reports Enhanced DL Frequency Selective Scheduling Meaning: Indicates the interval at which aperiodic CQI reporting is triggered for UEs in frequency selective scheduling. In high-load or heavy-traffic scenarios, if downlink frequency selective scheduling has a strong impact on uplink performance, the parameter value can be increased to reduce the impact at the cost of lower gains of frequency selective scheduling. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1~100 Unit: ms Actual Value Range: 1~100 Default Value: 2 CellDlschAlgo FSUESbCQIValidityPeriod MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD00101502/TDLBFD00101502 LBFD002031/TDLBFD002031 LBFD-060103 Dynamic Scheduling Support of aperiodic CQI reports Enhanced DL Frequency Selective Scheduling Meaning: Indicates the validity period of subband CQIs aperiodically reported by UEs in frequency selective scheduling. If the validity period of such a CQI expires, the CQI becomes invalid. In high-load or heavy-traffic scenarios, if UEs are motionless or move at low speeds, the parameter value can be increased at the cost of possible degraded downlink performance. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1~100 Unit: ms Actual Value Range: 1~100 Default Value: 10 DrxParaGroup DrxReTxTimer ADD DRXPARAGROUP MOD DRXPARAGROUP LST DRXPARAGROUP LBFD-002017 / TDLBFD-002017 LTROFD-111203 / TDLOFD-121105 MLOFD-121280 / TDLEOFD-121611 DRX RRC and DRX Policy for Public Safety eMTC Introduction Meaning: Indicates the length of the DRX Retransmission Timer. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: PSF1(1 PDCCH subframes), PSF2(2 PDCCH subframes), PSF4(4 PDCCH subframes), PSF6(6 PDCCH subframes), PSF8(8 PDCCH subframes), PSF16(16 PDCCH subframes), PSF24(24 PDCCH subframes), PSF33(33 PDCCH subframes), PSF40(40 PDCCH MO Parameter ID MML Command Feature ID Feature Name Description subframes), PSF64(64 PDCCH subframes), PSF80(80 PDCCH subframes), PSF96(96 PDCCH subframes), PSF112(112 PDCCH subframes), PSF128(128 PDCCH subframes), PSF160(160 PDCCH subframes), PSF320(320 PDCCH subframes) Unit: subframe Actual Value Range: PSF1, PSF2, PSF4, PSF6, PSF8, PSF16, PSF24, PSF33, PSF40, PSF64, PSF80, PSF96, PSF112, PSF128, PSF160, PSF320 Default Value: PSF8(8 PDCCH subframes) CellDlschAlgo DlHarqMaxTxNum MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD002025/TDLBFD002025 LBFD-002005 / TDLBFD-002005 Basic Scheduling DL Asynchronous HARQ Meaning: Indicates the maximum number of downlink hybrid automatic repeat request (HARQ) transmissions. For details, see 3GPP TS 36.331. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1~6 Unit: None Actual Value Range: 1~6 Default Value: 5 CellDlschAlgo DlschStrategy MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-002025 / TDLBFD-002025 LBFD-001015 / TDLBFD-001015 LBFD-00101502 / TDLBFD-00101502 Basic Scheduling Enhanced Scheduling Dynamic Scheduling Meaning: Indicates the DL scheduling policy. According to the Max C/I scheduling policy, the UE with good-quality channels are scheduled and hence the spectral efficiency is very high. The QoS and fairness among users, however, cannot be ensured. The Max C/I scheduling policy can be used to verify the maximum capacity of the system. The RR scheduling policy is the fairest scheduling policy. When RR is adopted, the system capacity is the smallest. Therefore, RR is used only to verify the upper bound of the scheduling fairness in the system. In terms of the scheduling effect, the PF scheduling policy is between the previous two policies. Therefore, PF can be used to verify the capacity, coverage, and fairness of the system. The EPF scheduling policy supports the features such as user QoS, system capacity, and channel frequency selection. The basic scheduling policy is mainly used for the performance test purpose. During common operation, the EPF scheduling policy is recommended. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: DLSCH_PRI_TYPE_EPF(EPF), DLSCH_PRI_TYPE_PF(PF), DLSCH_PRI_TYPE_MAX_CI(MAX C/I), DLSCH_PRI_TYPE_RR(RR) Unit: None Actual Value Range: DLSCH_PRI_TYPE_EPF, DLSCH_PRI_TYPE_PF, DLSCH_PRI_TYPE_MAX_CI, DLSCH_PRI_TYPE_RR Default Value: DLSCH_PRI_TYPE_EPF(EPF) CellDlschAlgo NoSchStopACqiThd MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101502 LBFD-002031 LBFD-060103 Dynamic Scheduling Support of aperiodic CQI reports Enhanced DL Frequency Selective Scheduling Meaning: Indicates the threshold for stopping aperiodic CQI reporting. If the time interval between a UE's last downlink scheduling and current downlink scheduling is greater than or equal to this threshold, the UE stops triggering CQI reporting within the current TTI. This parameter applies only to LTE FDD. GUI Value Range: 2~40 Unit: ms Actual Value Range: 2~40 Default Value: 40 CellDlschAlgo FreqSelJudgePeriod MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-060202 TDLBFD-00101502 / LBFD-00101502 LBFD-060103 Enhanced DL Frequency Selective Dynamic Scheduling Enhanced DL Frequency Selective Scheduling Meaning: Indicates the determination period for frequency selective scheduling. If FreqSelSwitch of the DlSchSwitch parameter is off, the FreqSelJudgePeriod parameter setting does not take effect. If FreqSelSwitch of the DlSchSwitch parameter is on, a smaller value of the FreqSelJudgePeriod parameter results that UEs meeting frequency selective scheduling conditions more easily enter the frequency selective scheduling mode and a higher probability that the UEs repeatedly enter and exit frequency selective scheduling mode. A larger value of the MO Parameter ID MML Command Feature ID Feature Name Description FreqSelJudgePeriod parameter results in the opposite effects when FreqSelSwitch of the DlSchSwitch parameter is on. This parameter applies only to LTE FDD networks. GUI Value Range: 1~10 Unit: s Actual Value Range: 1~10 Default Value: 10 CellPdcchAlgo PdcchSymNumSwitch MOD CELLPDCCHALGO LST CELLPDCCHALGO LBFD-002003 / TDLBFD-002003 LBFD-060103 / TDLBFD-080102 Physical Channel Management Enhanced DL Frequency Selective Scheduling Meaning: Indicates whether to enable dynamic adjustment on the number of orthogonal frequency division multiplexing (OFDM) symbols occupied by the physical downlink control channel (PDCCH). If this parameter is set to OFF(Off), the number of OFDM symbols occupied by the PDCCH is fixed and cannot be dynamically adjusted. If this parameter is set to ON(On), the number of OFDM symbols occupied by the PDCCH is dynamically adjusted based on the required number of PDCCH control channel elements (CCEs). The OFDM symbol number adjustment range can be determined by referring to the MML reference of the InitPdcchSymNum parameter. If this parameter is set to ECFIADAPTIONON(Enhanced CFI Adaption On), the number of OFDM symbols occupied by the PDCCH is dynamically adjusted based on the cell downlink throughput, and the adjustment performance is the best among the three methods. The OFDM symbol number adjustment range can be determined by referring to the MML reference of the InitPdcchSymNum parameter. If the EMTC_SWITCH option of the EmtcAlgoSwitch parameter in a CellEmtcAlgo MO is selected and the value of this parameter is changed, the value of the startSymbolBR IE is changed, and eMTC UEs that already accessed the cell will be proactively released. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: OFF(Off), ON(On), ECFIADAPTIONON(Enhanced CFI Adaption On) Unit: None Actual Value Range: OFF, ON, ECFIADAPTIONON Default Value: ECFIADAPTIONON(Enhanced CFI Adaption On) CellPdcchAlgo InitPdcchSymNum MOD CELLPDCCHALGO LST CELLPDCCHALGO LBFD-002003 / TDLBFD-002003 Physical Channel Management Meaning: Indicates the number of OFDM symbols initially occupied by the PDCCH. If the switch for dynamic adjustment of the number of OFDM symbols occupied by the PDCCH is turned off, this parameter indicates the fixed number of OFDM symbols occupied by the PDCCH. For LTE TDD cells, this parameter indicates the number of OFDM symbols initially occupied by the PDCCH in the downlink subframes in which only downlink scheduling control information is transmitted. If the switch for dynamic adjustment of the number of OFDM symbols occupied by the PDCCH is turned on and the bandwidth is 1.4 MHz or 3 MHz, the PDCCH occupies 4 or 3 OFDM symbols, respectively, and this parameter is invalid. If the switch is turned on and the bandwidth is 5 MHz, 10 MHz, 15 MHz, or 20 MHz, the eNodeB adjusts the number of OFDM symbols in the range of 1, 2, and 3 when this parameter is set to the default value 1, or in the range of 2 and 3 when this parameter is set to 2 or 3. For LTE TDD cells, if the switch is turned on and the bandwidth is 5 MHz, the eNodeB adjusts the number of OFDM symbols in the range of 2 and 3 by default, and this parameter is invalid. If the EMTC_SWITCH option of the EmtcAlgoSwitch parameter in a CellEmtcAlgo MO is selected and the value of this parameter is changed, the value of the startSymbolBR IE is changed, and eMTC UEs that already accessed the cell will be proactively released. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1~4 Unit: None Actual Value Range: 1~4 Default Value: 1 CellUlschAlgo DopAlgoSwitch MOD CELLULSCHALGO LBFD-00101502 MO Parameter ID MML Command Feature ID LST CELLULSCHALGO Feature Name Description Dynamic Scheduling Meaning: FastReportDopSwitch: Indicates whether to shorten the period that the baseband processing unit reports Doppler measurements to the MAC layer. If this option is selected, the Doppler measurement reporting period is shortened with the predefined reporting conditions. If this option is deselected, the Doppler measurements are reported at the predefined periods and with the predefined conditions. This option applies only to LTE FDD and LTE TDD. GUI Value Range: FastReportDopSwitch (FastReportDopSwitch) Unit: None Actual Value Range: FastReportDopSwitch Default Value: FastReportDopSwitch:Off CellUlschAlgo DopMeasLevel MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the Doppler measurement level, which is used for selecting a Doppler measurement policy. If this parameter is set to CLASS_0, the demodulation reference signal (DMRS) whose signal to interference plus noise ratio (SINR) is greater than or equal to 5 dB is used in Doppler measurement. If this parameter is set to CLASS_1, the DMRS whose SINR is greater than or equal to –5 dB is used in Doppler measurement. This parameter does not take effect on cells established on an LBBPc. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: CLASS_0(CLASS_0), CLASS_1(CLASS_1) Unit: None Actual Value Range: CLASS_0, CLASS_1 Default Value: CLASS_0(CLASS_0) CellDlschAlgo HoStaticMcsTimer MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-002025 / TDLBFD-002025 LBFD-00101502 / TDLBFD-00101502 Meaning: Indicates the duration within which the eNodeB performs downlink scheduling based on a low modulation and coding scheme (MCS) order in handovers. The eNodeB starts this timer after determining a UE has entered the handover area or has been handed over to the target cell. The eNodeB performs downlink scheduling based on a low MCS order during the running of this timer. After the timer expires, the eNodeB performs downlink scheduling based on a new MCS order after CQI adjustment. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~100 Unit: ms Actual Value Range: 0~100 Default Value: 10 CellDlschAlgo RBPriMcsSelectRatioThd MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101502/ Dynamic TDLBFD-00101502 Scheduling LBFD-070106 PDSCH Efficiency Improvement Meaning: Indicates the selection ratio threshold for the function of lowering the modulation and coding scheme (MCS) index to increase the number of resource blocks (RBs) with priority for UEs running services with small packets. If the threshold of TTIs within which downlink scheduling is performed and RBs are surplus is less than this parameter value, the function is enabled.The value 0 indicates that the function is disabled. The value 100 indicates that the function is always enabled. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~100 Unit: % Actual Value Range: 0~100 Default Value: 10 CellDlschAlgo RBPriMcsSelectStrategy MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101501 / TDLBFD-00101501 LBFD-00101502 / TDLBFD-00101502 LBFD-070106 Meaning: Indicates how to apply the policy of increasing the number of resource blocks (RBs) to lower the modulation and coding scheme (MCS) index. If this parameter is set to SINGLEUSER_STRATEGY, the policy is applied to a single RRC_CONNECTED UE whose capability is limited (Maximum number of DL-SCH transport block bits received within a TTI of the UE is less than the maximum TBS with the total number of PRBs). The policy is applied to a single service when the following conditions are met within a measurement period: (1) this parameter is set to SINGLEUSER_STRATEGY; (2) the service is the only service to be scheduled in the cell; (3) the proportion of the transmission time intervals Basic Scheduling Dynamic Scheduling CQI Adjustment Dynamic Scheduling PDSCH Efficiency Improvement MO Parameter ID MML Command Feature ID Feature Name Description (TTIs) in which RBs are expected to be surplus is less than a specified threshold. If this parameter is set to MULTIUSER_STRATEGY, the policy is applied to the last capability-limited UE to be scheduled. If this parameter is set to MULTIUSER_STRATEGY and the proportion of TTIs in which RBs are expected to be surplus is less than a specified threshold within a measurement period, this strategy is applied to the last UE to be scheduled. If this parameter is set to MULTIUSR_LOWMCSLIMIT_STRATEGY, the policy is applied to the last capability-limited UE to be scheduled. If this parameter is set to MULTIUSR_LOWMCSLIMIT_STRATEGY and the proportion of TTIs in which RBs are expected to be surplus is less than a specified threshold within a measurement period, this strategy is applied to the last UE to be scheduled, and the MCS index decreases by a maximum of 3. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: SINGLEUSER_STRATEGY (Single User Strategy), MULTIUSER_STRATEGY (Multiple User Strategy), MULTIUSR_LOWMCSLIMIT_STRATEGY(Multiple User Lower MCS Limited Strategy) Unit: None Actual Value Range: SINGLEUSER_STRATEGY, MULTIUSER_STRATEGY, MULTIUSR_LOWMCSLIMIT_STRATEGY Default Value: SINGLEUSER_STRATEGY(Single User Strategy) CellDlschAlgo DataThdInPdcchPdschBal MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling LBFD-070106 PDSCH Efficiency Improvement Meaning: Indicates the traffic volume threshold for determining a bearer as one with large packets in the PDCCH and PDSCH resource allocation optimization mechanism. If this parameter is set to 0, the optimization mechanism does not take effect. If this parameter is set to a non-zero value, a bearer is determined as one with large packets when the amount of to-be-scheduled data for the bearer is greater than or equal to this value. If the amounts of to-be-scheduled data for all bearers are less than the value of this parameter, the bearer with the largest amount of to-be-scheduled data among all bearers is selected as the one with large packets. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~1000000 Unit: bit Actual Value Range: 0~1000000 Default Value: 0 CellDlschAlgo UeNumThdInPdcchPdschBal MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling LBFD-070106 PDSCH Efficiency Improvement Meaning: Indicates the threshold for the number of synchronized UEs in a cell above which the PDCCH and PDSCH resource allocation optimization mechanism is activated in large traffic volume scenarios. If this parameter is set to a value ranging from 0 to 10000 (indicating a threshold from 0 UE to 10,000 UEs), the mechanism is activated when the number of synchronized UEs in the cell is greater than or equal to this parameter value. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~10000 Unit: None Actual Value Range: 0~10000 Default Value: 10000 CellAlgoSwitch CellSchStrategySwitch MOD CELLALGOSWITCH LST CELLALGOSWITCH LBFD-00101502 / TDLBFD-00101502 LBFD-002025 / TDLBFD-002025 Meaning: Indicates whether to enable a specific scheduling policy in the uplink and downlink. AbnUeSchSwitch: Indicates whether to disable scheduling of abnormal UEs. If this switch is on, abnormal UEs are not scheduled. If this switch is off, abnormal UEs are scheduled. This option applies only to LTE FDD and LTE TDD. GUI Value Range: AbnUeSchSwitch (AbnUeSchSwitch) Unit: None Actual Value Range: AbnUeSchSwitch Default Value: AbnUeSchSwitch:Off Enhanced Scheduling Basic Scheduling MO Parameter ID MML Command Feature ID Feature Name Description CellDlschAlgo DlSchAbnUeThd MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101502 / TDLBFD-00101502 LBFD-002025 / TDLBFD-002025 Enhanced Scheduling Basic Scheduling Meaning: Indicates the threshold for the number of consecutive discontinuous transmissions (DTXs) in the downlink above which the eNodeB stops scheduling the abnormal UE. The parameter value range is from 6 to 120. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 6~120 Unit: None Actual Value Range: 6~120 Default Value: 15 CellDlschAlgo CqiAdjInitialStep MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101501 / CQI TDLBFD-00101501 Adjustment Meaning: Indicates the initial step in which channel quality indicators (CQIs) are adjusted for UEs that initially access or are handed over to the network. If the periodically measured initial block error rate (IBLER) exceeds the fixed IBLER threshold, the CQI adjustment step is changed to its fixed default value 0.1. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~1000 Unit: None Actual Value Range: 0~10, step:0.01 Default Value: 10 CellCqiAdjAlgo InitDeltaCqi MOD CELLCQIADJALGO LST CELLCQIADJALGO TDLBFD00101501/LBFD00101501 Meaning: Indicates the initial CQI adjustment amount. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: -10~26 Unit: None Actual Value Range: -10~26 Default Value: -4 CellDlschAlgo NonGbrResourceRatio MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the proportion of resources reserved for non-GBR services. A proportion of resources is reserved periodically to prevent nonGBR services from failing to be allocated resources. During the periods when resources are reserved, resources are scheduled preferentially for non-GBR services. If this parameter is set to 0, resources are not reserved for non-GBR services. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~50 Unit: % Actual Value Range: 0~50 Default Value: 0 QciPara DlMinGbr ADD QCIPARA MOD QCIPARA LST QCIPARA LBFD-00101502 / TDLBFD-00101502 LOFD-00301101 / TDLOFD-00301101 LOFD-00301103 / TDLOFD-00301103 LOFD-003016 / TDLOFD-003016 Meaning: Indicates the downlink minimum guaranteed bit rate of the service. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: MinGbrRate_0_KB(0kB/s), MinGbrRate_1_KB(1kB/s), MinGbrRate_2_KB (2kB/s), MinGbrRate_4_KB(4kB/s), MinGbrRate_8_KB(8kB/s), MinGbrRate_16_KB (16kB/s), MinGbrRate_32_KB(32kB/s), MinGbrRate_64_KB(64kB/s), MinGbrRate_128_KB(128kB/s), MinGbrRate_256_KB(256kB/s), MinGbrRate_512_KB(512kB/s) Unit: kB/s Actual Value Range: MinGbrRate_0_KB, MinGbrRate_1_KB, MinGbrRate_2_KB, MinGbrRate_4_KB, MinGbrRate_8_KB, MinGbrRate_16_KB, MinGbrRate_32_KB, MinGbrRate_64_KB, MinGbrRate_128_KB, MinGbrRate_256_KB, MinGbrRate_512_KB Default Value: MinGbrRate_1_KB(1kB/s) CellDlschAlgo AmbrCtrlTcycle MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFDDynamic 00101502/TDLBFD- Scheduling 00101502 CQI Adjustment Dynamic Scheduling Transport Overbooking Transport Resource Overload Control Different Transport Paths based on QoS Grade Meaning: Indicates the interval at which the eNodeB controls the downlink UE-AMBR. When this parameter is set to AMBR_50_MS (AMBR_50_MS), AMBR_100_MS (AMBR_100_MS), AMBR_200_MS (AMBR_200_MS), or AMBR_500_MS (AMBR_500_MS), the eNodeB controls the downlink UE-AMBR at an interval of 50, 100, 200, or 500 ms in downlink scheduling. When this parameter is set to AMBR_1000_MS (AMBR_1000_MS), the eNodeB does not control the UE-AMBR. This parameter applies only to LTE FDD and LTE TDD. MO Parameter ID MML Command Feature ID Feature Name Description GUI Value Range: AMBR_50_MS(AMBR_50_MS), AMBR_100_MS(AMBR_100_MS), AMBR_200_MS(AMBR_200_MS), AMBR_500_MS(AMBR_500_MS), AMBR_1000_MS(AMBR_1000_MS) Unit: None Actual Value Range: AMBR_50_MS, AMBR_100_MS, AMBR_200_MS, AMBR_500_MS, AMBR_1000_MS Default Value: AMBR_50_MS(AMBR_50_MS) CellDlschAlgo RbgAllocStrategy MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD002025/TDLBFD002025 LBFD00101502/TDLBFD00101502 Basic Scheduling Dynamic Scheduling Meaning: For services whose QoS class identifier (QCI) is not 1: When this parameter is set to ROUND_DOWN: (1) If the number of required resource block groups (RBGs) is less than 1, the actual number of RBs are allocated to UEs at the current transmission time interval (TTI); (2) If the number of required RBGs is greater than N but less than N+1 (N is greater than or equal to 1), RBs of N RBGs are allocated to UEs in the current TTI and the other required RBs are allocated to UEs in the next TTI. Setting this parameter to ROUND_DOWN ensures full utilization of RBs, but increases scheduling times and decreases downlink data rate. If this parameter is set to ROUND_UP and the number of required RBGs is greater than N but less than N+1 (N is greater than or equal to 0), RBs of N+1 RBGs are allocated to UEs in the current TTI. Setting this parameter to ROUND_UP wastes a few RBs, but decreases scheduling times and increases downlink data rate. When this parameter is set to ADAPTIVE: (1) If the number of required RBGs is less than 1, the actual number of RBs are allocated to UEs at the current TTI; (2) If the number of required RBGs is greater than N but less than N+1 (N is greater than or equal to 1), RBs of N+1 RBGs are allocated to UEs in the current TTI. Compared with setting this parameter to ROUND_UP, setting this parameter to ADAPTIVE does not waste RBs when the number of required RBGs is less than 1. For services whose QCI is 1 (such as VoIP services): When this parameter is set to ROUND_DOWN: (1) If the number of required RBGs is less than 1, the actual number of RBs are allocated to UEs at the current TTI; (2) If the number of required RBGs is greater than N but less than N+1 (N is greater than or equal to 1), RBs of N+1 RBGs are allocated to UEs in the current TTI. If this parameter is set to ROUND_UP or ADAPTIVE, RBs are allocated to UEs in the same way that they are allocated when this parameter is set to ROUND_UP or ADAPTIVE for services whose QCI is not 1, respectively. For ping services: If the number of required RBGs is greater than N but less than N+1 (N is greater than or equal to 0), RBs of N+1 RBGs are allocated to UEs in the current TTI regardless of the actual parameter setting. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: ROUND_DOWN(Round Down), ROUND_UP(Round Up), ADAPTIVE(Adaptive) Unit: None Actual Value Range: ROUND_DOWN, ROUND_UP, ADAPTIVE Default Value: ADAPTIVE(Adaptive) CellAlgoSwitch UlSchSwitch MOD CELLALGOSWITCH LST CELLALGOSWITCH LOFD-001016 / TDLOFD-001016 LOFD-001048 / TDLOFD-001048 LBFD-00101502 / TDLBFD-00101502 LBFD-002025 / TDLBFD-002025 LBFD-070102 / TDLBFD-070102 LOFD-001002 LOFD-001058 / TDLOFD-001058 VoIP Semipersistent Scheduling TTI Bundling Dynamic Scheduling Basic Scheduling MBR>GBR Configuration UL 2x2 MUMIMO Meaning: Indicates whether to enable uplink scheduling functions for the cell. SpsSchSwitch: Indicates whether to enable semipersistent scheduling during talk spurts of VoLTE services. If this option is selected, semi-persistent scheduling is applied. If this option is deselected, dynamic scheduling is applied. This option applies only to LTE FDD and LTE TDD. SinrAdjustSwitch: Indicates whether to adjust the measured SINR based on ACK/NACK messages in the UL hybrid automatic repeat request (HARQ) processes. This option applies only to LTE FDD and LTE TDD. MO Parameter ID MML Command Feature ID Feature Name Description LBFD-001006 / TDLBFD-001006 LOFD-120205 LBFD-060102 TDLEOFD-121608 TDLEOFD-121609 TDLEOFD-121610 UL 2x4 MUMIMO AMC Uplink Coverage Improvement for Video Enhanced UL Frequency Selective Scheduling UL 2x64 MUMIMO UL 4x64 MUMIMO UL 8x64 MUMIMO PreAllocationSwitch: Indicates whether to enable preallocation in the uplink. If this option is selected: (1) If the SmartPreAllocationSwitch option is deselected and a UE is in the discontinuous reception (DRX) state, preallocation is disabled for the UE in the uplink; (2) If the SmartPreAllocationSwitch option is deselected and the UE is not in the DRX state, preallocation is enabled for the UE in the uplink; (3) If the SmartPreAllocationSwitch option is selected and the SmartPreAllocationDuration parameter value is greater than 0, smart preallocation is enabled for the UE in the uplink; (4) If the SmartPreAllocationSwitch option is selected and the SmartPreAllocationDuration parameter value is 0, preallocation is disabled for the UE in the uplink. If this option is deselected, preallocation is disabled for the UE in the uplink. If bearer-level preallocation or bearer-level smart preallocation is enabled for a QCI, cell-level preallocation and celllevel smart preallocation do not apply to UEs with the QCI. This option applies only to LTE FDD and LTE TDD. UlVmimoSwitch: Indicates whether to enable multiuser MIMO (MU-MIMO) in the uplink. If this option is selected, the eNodeB performs MU-MIMO pairing among UEs based on related principles. UEs forming a pair transmit data using the same time-frequency resources, which improves the system throughput and spectral efficiency. This option applies only to LTE FDD and LTE TDD. TtiBundlingSwitch: Indicates whether to enable transmission time interval (TTI) bundling. If TTI bundling is enabled, more transmission opportunities are available to UEs within the delay budget for VoLTE services on the Uu interface, thereby improving uplink coverage. This option applies only to LTE FDD and LTE TDD. ImIcSwitch: Indicates whether to enable the intermodulation (IM) interference cancellation for UEs. When data is transmitted in both the uplink and downlink, uplink signals generate two IM components symmetrically beside the Direct Current (DC) subcarrier on the downlink receive channel due to the nonlinearity of the UE receive channel. If this option is selected, IM component elimination is performed for UEs. If this option is deselected, IM component elimination is not performed for UEs. This option applies only to LTE FDD cells working on frequency band 20. This option applies only to LTE FDD. SmartPreAllocationSwitch: Indicates whether to enable uplink smart preallocation when the PreAllocationSwitch option is selected. If both the PreAllocationSwitch and this option are selected and the SmartPreAllocationDuration parameter in the CellPreallocGroup MO is set to a value greater than 0, uplink smart preallocation is enabled. Otherwise, uplink smart preallocation is disabled. This option applies only to LTE FDD and LTE TDD. PuschDtxSwitch: Indicates whether the eNodeB uses the PUSCH discontinuous transmission (DTX) detection result during uplink scheduling. If this option is selected for an LTE FDD cell, the eNodeB determines whether to perform adaptive retransmission, and also adjusts the CCE aggregation level of the PDCCH carrying downlink control information (DCI) format 0 based on the PUSCH DTX detection result during uplink scheduling. If an LTE FDD cell is established on an LBBPc, this option takes effect only if the cell uses less than four RX antennas and normal cyclic prefix (CP) in the uplink and the SrsCfgInd parameter in the SRSCfg MO is set to BOOLEAN_TRUE(True). Note that the LBBPc does not support PUSCH DTX detection for VMIMO UEs. For an LTE TDD cell, this option takes effect only when the uplink-downlink subframe configuration is set to SA2 or SA5. If this option takes effect, the eNodeB adjusts the CCE aggregation level based on the PUSCH DTX detection results. Note that LTE TDD cells established on LBBPc boards do not support MO Parameter ID MML Command Feature ID Feature Name Description PUSCH DTX detection. This option applies only to LTE FDD and LTE TDD. UlIblerAdjustSwitch: Indicates whether to enable the uplink IBLER adjustment algorithm. If this option is selected, the target IBLER is adjusted for UEs based on the channel quality and fluctuation to increase the cell throughput. This option applies only to LTE FDD and LTE TDD. If this option is selected independently for FDD cells with the UlTargetIBlerAdaptType option deselected, the algorithm does not take effect. UlEnhancedFssSwitch: Indicates whether to enable uplink load-based enhanced frequency selective scheduling. This option applies only to LTE FDD. UlIicsAlgoSwitch: Indicates whether to enable the uplink interference-intensity-based coordinated scheduling (UL IICS) algorithm. If this option is selected, interference can be reduced based on accurate detection of user attributes and scheduling resource coordination, increasing the cell edge throughput. This option applies only to LTE TDD. UlEnhancedSrSchSwitch: Indicates whether uplink re-scheduling is performed only when the On Duration timer for the DRX long cycle starts. Uplink re-scheduling is required if the number of HARQ retransmissions for a scheduling request (SR) reaches the maximum value but the scheduling still fails. If this option is selected, uplink rescheduling is performed only when the On Duration timer for the DRX long cycle starts. If this option is deselected, uplink re-scheduling is performed immediately when the number of HARQ retransmissions for SR reaches the maximum value but the scheduling still fails. It is recommended that this option be selected for live networks. This option applies only to LTE FDD and LTE TDD. SchedulerCtrlPowerSwitch: Indicates whether the uplink scheduler performs scheduling without considering power control restrictions. If this option is selected, the uplink scheduler performs scheduling without considering power control restrictions, ensuring full utilization of the transmit power for all UEs. If this option is deselected, the uplink scheduler considers power control restrictions while performing scheduling. In this case, the transmit power cannot be fully used for UEs at the cell edge or between the cell edge and cell center. This option applies only to LTE FDD and LTE TDD. UlMinGbrSwitch: Indicates whether to ensure uplink minimum guaranteed bit rate (GBR). If this option is selected, the minimum GBR of non-GBR services is ensured by increasing the scheduling priority of UEs whose non-GBR service rates are lower than the minimum GBR. This option applies only to LTE FDD and LTE TDD. UlMbrCtrlSwitch: Indicates whether to enable uplink scheduling based on the maximum bit rate (MBR) and guaranteed bit rate (GBR) on the GBR bearer. If this option is selected, the eNodeB performs uplink scheduling on GBR bearers based on the MBR and GBR. If this option is deselected, the eNodeB performs uplink scheduling on GBR bearers based only on the GBR. This option applies only to LTE FDD and LTE TDD. MbrUlSchSwitch: Indicates whether the eNodeB performs uplink scheduling based on the MBR. If this option is selected, the eNodeB prioritizes UEs based on the MBRs during uplink scheduling. This option applies only to LTE TDD. UeAmbrUlSchSwitch: Indicates whether the eNodeB performs uplink scheduling based on the aggregate maximum bit rate (AMBR) of UEs. If this option is selected, the eNodeB prioritizes UEs based on the AMBRs of UEs during uplink scheduling. This option applies only to LTE TDD. UlEnhancedDopplerSwitch: Indicates whether to enable enhanced uplink scheduling based on mobility speed estimation. If this option is selected, enhanced uplink scheduling based on mobility MO Parameter ID MML Command Feature ID Feature Name Description speed estimation is enabled. In enhanced uplink scheduling based on mobility speed estimation, the eNodeB uses Doppler measurement results to identify low-speed UEs to further improve uplink performance of low-speed UEs. If this option is deselected, enhanced uplink scheduling based on mobility speed is disabled. Enhanced uplink scheduling based on mobility speed takes effect only when the DopMeasLevel parameter is set to CLASS_1(CLASS_1) and the UlEnhancedDopplerSwitch option is selected. This option does not apply to cells established on LBBPc boards. This option applies only to LTE FDD. UlRaUserSchOptSw: Indicates whether the eNodeB raises the scheduling priority of UEs sending uplink access signaling, including MSG5 and the RRC Connection Reconfiguration Complete message. If this option is selected, the eNodeB raises the scheduling priority of UEs sending uplink access signaling. If this option is deselected, the eNodeB does not raise the scheduling priority of UEs sending uplink access signaling. In NB-IoT scenarios with air interface resource congestion, this option restricts the number of preambles to perform flow control on UEs accessing the cell. UlLast2RetransSchOptSwitch: Indicates whether to optimize the scheduling policy for the last two retransmissions. If this option is selected, the scheduling policy is optimized for the last two retransmissions. If the UE transmit power is not limited, adaptive retransmission is used, and the number of RBs increases in the last two retransmissions to increase the receive success rate of the last two retransmissions and decrease uplink RBLER. If this option is deselected, the scheduling policy is not optimized for the last two retransmissions. This option applies only to LTE FDD and LTE TDD. UlInterfFssSwitch: Indicates whether to enable interference-based uplink frequency-selective scheduling. This option applies only to LTE FDD. UlSmallRBSpectralEffOptSw: Indicates whether to improve the spectral efficiency of small RBs in the uplink. If this option is selected, the spectral efficiency of small RBs in the uplink is optimized, ensuring that the transmission block size calculated based on optimized spectral efficiency is not less than the traffic volume to be scheduled. If this option is deselected, the spectral efficiency of small RBs in the uplink is not optimized. This option applies only to LTE FDD and LTE TDD. PuschUsePucchRbSwitch: Indicates whether PUCCH RBs can be occupied by the PUSCH. In scenarios with a single user: If this option is selected, PUCCH RBs can be occupied by the PUSCH; if this option is deselected, PUCCH RBs cannot be occupied by the PUSCH. In scenarios with multiple users, PUCCH RBs cannot be occupied by the PUSCH regardless of the setting of this option. This option applies only to LTE FDD and LTE TDD. PuschDtxSchOptSwitch: If this option is selected, the eNodeB determines whether to perform adaptive retransmission based on the PUSCH DTX detection result during uplink scheduling. This option takes effect only when the uplink-downlink subframe configuration SA2 or SA5 is used. If an LTE TDD cell is established on an LBBPc, PUSCH DTX detection is not supported. This option applies only to LTE TDD. PrachRbReuseSwitch: If this option is selected, the PUSCH and PRACH transmissions can use the same resource. If this option is deselected, the PUSCH and PRACH transmissions cannot use the same resource. This option applies only to LTE FDD and LTE TDD. ULFSSAlgoswitch: If this option is deselected, uplink frequency-selective scheduling is disabled. If this option is selected, uplink frequency-selective scheduling is enabled. This option applies only to LTE TDD. MO Parameter ID MML Command Feature ID Feature Name Description SrSchDataAdptSw: Indicates whether to enable data amount adaptation in SR-based scheduling. Data amount adaptation in SR-based scheduling is enabled only when this option is selected. This option applies only to LTE FDD. UlFssUserThdStSwitch: If this option is selected, the UE number threshold is optimized for uplink frequency selective scheduling. If this option is deselected, the UE number threshold is not optimized for uplink frequency selective scheduling. This option applies only to LTE FDD and LTE TDD. HighOrderVMIMOSwitch: Indicates whether to enable high order VMIMO. If this option is selected, high order VMIMO is enabled. If this option is deselected, high order VMIMO is disabled. This option applies only to LTE TDD. VMIMOReduceMCSRiseRBSwitch: Indicates whether VMIMO pairing is performed for UEs whose MCS index is reduced to increase the number of RBs. If this option is selected, VMIMO is performed for UEs whose MCS index is reduced to increase the number of RBs. If this option is deselected, VMIMO is not performed for UEs whose MCS index is reduced to increase the number of RBs. This option applies only to LTE TDD. VoLTEUeVmimoSwitch: Indicates whether VMIMO pairing is performed for VoLTE UEs. If this option is selected, VMIMO pairing is performed for VoLTE UEs. If this option is deselected, VMIMO pairing is not performed for VoLTE UEs. This option applies only to LTE TDD. TtiBundlingForVideoSwitch: If this option is selected, TTI bundling is enabled for UEs running video services in weak coverage areas, improving video service coverage at the cell edge. If this option is deselected, TTI bundling is disabled for UEs running video services in weak coverage areas. This option applies only to LTE FDD. GUI Value Range: SpsSchSwitch(SpsSchSwitch), SinrAdjustSwitch(SinrAdjustSwitch), PreAllocationSwitch(PreAllocationSwitch), UlVmimoSwitch(UlVmimoSwitch), TtiBundlingSwitch(TtiBundlingSwitch), ImIcSwitch (ImIcSwitch), SmartPreAllocationSwitch (SmartPreAllocationSwitch), PuschDtxSwitch (PuschDtxSwitch), UlIblerAdjustSwitch (UlIblerAdjustSwitch), UlEnhancedFssSwitch (UlEnhancedFssSwitch), UlEnhancedSrSchSwitch (UlEnhancedSrSchSwitch), SchedulerCtrlPowerSwitch (SchedulerCtrlPowerSwitch), UlIicsAlgoSwitch (UlIicsAlgoSwitch), UlMinGbrSwitch (UlMinGbrSwitch), UlMbrCtrlSwitch (UlMbrCtrlSwitch), MbrUlSchSwitch (MbrUlSchSwitch), UeAmbrUlSchSwitch (UeAmbrUlSchSwitch), UlEnhancedDopplerSwitch (UlEnhancedDopplerSwitch), UlRaUserSchOptSw (UlRaUserSchOptSw), UlLast2RetransSchOptSwitch (UlLast2RetransSchOptSwitch), UlInterfFssSwitch (UlInterfFssSwitch), UlSmallRBSpectralEffOptSw (UlSmallRBSpectralEfficiencyOptSw), PuschUsePucchRbSwitch (PuschUsePucchRbSwitch), PuschDtxSchOptSwitch(PuschDtxSchOptSwitch), ULFSSAlgoSwitch(ULFSSAlgoSwitch), PrachRbReuseSwitch(PrachRbReuseSwitch), SrSchDataAdptSw(SrSchDataAdptSw), UlFssUserThdStSwitch(UlFssUserThdStSwitch), HighOrderVMIMOSwitch (HighOrderVMIMOSwitch), VMIMOReduceMCSRiseRBSwitch (VMIMOReduceMCSRiseRBSwitch), VoLTEUeVmimoSwitch(VoLTEUeVmimoSwitch), TtiBundlingForVideoSwitch (TtiBundlingForVideoSwitch) Unit: None Actual Value Range: SpsSchSwitch, SinrAdjustSwitch, PreAllocationSwitch, UlVmimoSwitch, TtiBundlingSwitch, ImIcSwitch, SmartPreAllocationSwitch, PuschDtxSwitch, UlIblerAdjustSwitch, UlEnhancedFssSwitch, MO Parameter ID MML Command Feature ID Feature Name Description UlEnhancedSrSchSwitch, SchedulerCtrlPowerSwitch, UlIicsAlgoSwitch, UlMinGbrSwitch, UlMbrCtrlSwitch, MbrUlSchSwitch, UeAmbrUlSchSwitch, UlEnhancedDopplerSwitch, UlRaUserSchOptSw, UlLast2RetransSchOptSwitch, UlInterfFssSwitch, UlSmallRBSpectralEffOptSw, PuschUsePucchRbSwitch, PuschDtxSchOptSwitch, ULFSSAlgoSwitch, PrachRbReuseSwitch, SrSchDataAdptSw, UlFssUserThdStSwitch, HighOrderVMIMOSwitch, VMIMOReduceMCSRiseRBSwitch, VoLTEUeVmimoSwitch, TtiBundlingForVideoSwitch Default Value: SpsSchSwitch:Off, SinrAdjustSwitch:On, PreAllocationSwitch:On, UlVmimoSwitch:Off, TtiBundlingSwitch:Off, ImIcSwitch:Off, SmartPreAllocationSwitch:On, PuschDtxSwitch:On, UlIblerAdjustSwitch:Off, UlEnhancedFssSwitch:On, UlEnhancedSrSchSwitch:On, SchedulerCtrlPowerSwitch:Off, UlIicsAlgoSwitch:Off, UlMinGbrSwitch:Off, UlMbrCtrlSwitch:Off, MbrUlSchSwitch:Off, UeAmbrUlSchSwitch:Off, UlEnhancedDopplerSwitch:On, UlRaUserSchOptSw:Off, UlLast2RetransSchOptSwitch:On, UlInterfFssSwitch:Off, UlSmallRBSpectralEffOptSw:Off, PuschUsePucchRbSwitch:Off, PuschDtxSchOptSwitch:Off, ULFSSAlgoSwitch:On, PrachRbReuseSwitch:Off, SrSchDataAdptSw:On, UlFssUserThdStSwitch:Off, HighOrderVMIMOSwitch:Off, VMIMOReduceMCSRiseRBSwitch:Off, VoLTEUeVmimoSwitch:Off, TtiBundlingForVideoSwitch:Off CellUlschAlgo UlSrSchDateLen MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the data length that the UL scheduler assigns to UEs that have sent scheduling requests. Within the data length, the UEs reports their buffer status and transmit certain data. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 16~15000 Unit: bit Actual Value Range: 16~15000 Default Value: 600 CellUlschAlgo AdaptHarqSwitch MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-002006 / TDLBFD-002006 LBFD-002025 / TDLBFD-002025 LBFD-001015 / TDLBFD-001015 LBFD-00101502 / TDLBFD-00101502 Meaning: Indicates the switch that is used to control whether to enable or disable UL adaptive HARQ. If this switch is set to ADAPTIVE_HARQ_SW_OFF, UL data is retransmitted by non-adaptive synchronous HARQ. If this switch is set to ADAPTIVE_HARQ_SW_ON, UL data is retransmitted by adaptive synchronous HARQ. If this switch is set to ADAPTIVE_HARQ_SW_SEMION, adaptive HARQ is triggered when a UL grant is delivered to an HARQ process that is previously suspended due to reasons such as resource collision, activation of a measurement gap, and PDCCH congestion. Setting this parameter to ADAPTIVE_HARQ_SW_ON helps reduce resource consumption due to retransmission, increase the cell throughput, and prevent retransmission conflicts. This, on the other hand, will increase signaling overhead and therefore consume more PDCCH resources. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: ADAPTIVE_HARQ_SW_ON (On), ADAPTIVE_HARQ_SW_OFF(Off), ADAPTIVE_HARQ_SW_SEMI_ON(SemiOn) Unit: None Actual Value Range: ADAPTIVE_HARQ_SW_ON, ADAPTIVE_HARQ_SW_OFF, ADAPTIVE_HARQ_SW_SEMI_ON Default Value: ADAPTIVE_HARQ_SW_SEMI_ON (SemiOn) CellUlschAlgo PuschDtxSchStrategy MOD CELLULSCHALGO UL Synchronous HARQ Basic Scheduling Enhanced Scheduling Dynamic Scheduling MO Parameter ID MML Command Feature ID LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Feature Name Description Meaning: Indicates the scheduling policy for the initial PUSCH transmission that is detected as discontinuous transmission (DTX) when PuschDtxSwitch of the UlSchSwitch parameter is on. If the PuschDtxSchStrategy parameter is set to NEW_TX, initial transmission instead of retransmission is performed when the initial PUSCH transmission is detected as DTX. If the PuschDtxSchStrategy parameter is set to ADAPTIVE_RETX, adaptive retransmission is performed when the initial PUSCH transmission is detected as DTX. If the PuschDtxSchStrategy parameter is set to EN_ADAPTIVE_RETX, adaptive retransmission is performed for UEs running voice services when the initial PUSCH transmission is detected as DTX in DRX scenarios regardless of whether the UEs are in DRX sleep or active time at the retransmission. This parameter applies only to LTE FDD. GUI Value Range: NEW_TX(NEW_TX), ADAPTIVE_RETX(ADAPTIVE_RETX), EN_ADAPTIVE_RETX(EN_ADAPTIVE_RETX) Unit: None Actual Value Range: NEW_TX, ADAPTIVE_RETX, EN_ADAPTIVE_RETX Default Value: ADAPTIVE_RETX (ADAPTIVE_RETX) DrxParaGroup OnDurationTimer ADD DRXPARAGROUP MOD DRXPARAGROUP LST DRXPARAGROUP LBFD-002017 / TDLBFD-002017 LEOFD-111306 LOFD-00110501 LTROFD-111203 / TDLOFD-121105 MLOFD-121280 / TDLEOFD-121611 DRX Breathing Pilot Dynamic DRX RRC and DRX Policy for Public Safety eMTC Introduction Meaning: Indicates the length of the On Duration Timer. If the configured value does not meet the restrictions of CQI reporting intervals and SRS transmission intervals, the actual value of this parameter assigned to a UE may be greater than the configured value. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: PSF1(1 PDCCH subframes), PSF2(2 PDCCH subframes), PSF3(3 PDCCH subframes), PSF4(4 PDCCH subframes), PSF5(5 PDCCH subframes), PSF6(6 PDCCH subframes), PSF8(8 PDCCH subframes), PSF10(10 PDCCH subframes), PSF20(20 PDCCH subframes), PSF30(30 PDCCH subframes), PSF40(40 PDCCH subframes), PSF50(50 PDCCH subframes), PSF60(60 PDCCH subframes), PSF80(80 PDCCH subframes), PSF100(100 PDCCH subframes), PSF200(200 PDCCH subframes), PSF300(300 PDCCH subframes), PSF400(400 PDCCH subframes), PSF500(500 PDCCH subframes), PSF600(600 PDCCH subframes), PSF800(800 PDCCH subframes), PSF1000(1000 PDCCH subframes), PSF1200(1200 PDCCH subframes), PSF1600(1600 PDCCH subframes) Unit: subframe Actual Value Range: PSF1, PSF2, PSF3, PSF4, PSF5, PSF6, PSF8, PSF10, PSF20, PSF30, PSF40, PSF50, PSF60, PSF80, PSF100, PSF200, PSF300, PSF400, PSF500, PSF600, PSF800, PSF1000, PSF1200, PSF1600 Default Value: PSF2(2 PDCCH subframes) SRSCfg SrsCfgInd MOD SRSCFG LST SRSCFG LBFD-002003 / TDLBFD-002003 TDLAOFD-081409 TDLEOFD-121615 TDLOFD-001049 Physical Channel Management DL 4-Layer MIMO Based on TM9 DL Flexible 3DBeamforming Single Streaming Beamforming Meaning: Indicates whether to configure sounding reference signal (SRS) resources for UEs in a cell. The value BOOLEAN_TRUE indicates that SRS resources are available in the cell and can be configured for UEs in the cell. The value BOOLEAN_FALSE indicates that no SRS resource is available in the cell, and therefore no UE in the cell is configured with SRS resources. This parameter does not take effect on: (1) FDD cell that is established on an LBBPc and uses four or more RX antennas. (2) FDD cell that is established on an LBBPc and uses extended cyclic prefix (CP) in the uplink. (3) TDD cell established on an LBBPc. If this parameter does not take effect on a cell but SRS resources are available in the cell, SRS resources can be configured for UEs in the cell. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: BOOLEAN_FALSE(False), BOOLEAN_TRUE(True) Unit: None Actual Value Range: BOOLEAN_FALSE, BOOLEAN_TRUE MO Parameter ID MML Command Feature ID Feature Name Description Default Value: BOOLEAN_TRUE(True) CellUlschAlgo UlHarqMaxTxNum MOD CELLULSCHALGO LST CELLULSCHALGO LBFD002025/TDLBFD002025 LBFD-002006 / TDLBFD-002006 Basic Scheduling UL Synchronous HARQ Meaning: Indicates the maximum number of uplink HARQ transmissions, excluding the HARQ transmission based on TTI bundling. For details, see 3GPP TS 36.331. When a UE runs services with a QCI of 1, the smaller value between the parameter value and 5 is used as the maximum number of uplink HARQ transmissions. When the UE does not run services with a QCI of 1, the parameter value is used as the maximum number of uplink HARQ transmissions. This parameter has coupling relationships with the ENodeBAmReorderingTimer or the ENodeBUmReorderingTimer parameter. When the UlHarqMaxTxNum parameter is set to 7, it is recommended that the ENodeBAmReorderingTimer or ENodeBAUmReorderingTimer parameter be set to a value greater than or equal to 50 ms. When the UlHarqMaxTxNum parameter is set to 8, it is recommended that the ENodeBAmReorderingTimer or ENodeBAUmReorderingTimer parameter be set to a value greater than or equal to 60 ms. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1~8 Unit: None Actual Value Range: 1~8 Default Value: 5 RlcPdcpParaGroup ENodeBAmReorderingTimer ADD RLCPDCPPARAGROUP MOD RLCPDCPPARAGROUP LST RLCPDCPPARAGROUP LBFD-002008 / TDLBFD-002008 LOFD-120204 TDLOFD-120203 MLOFD-121280 / TDLEOFD-121611 Radio Bearer Management VoLTE Coverage Enhancement Based on Extended Delay Budget Deep Coverage Improvement for VoLTE eMTC Introduction Meaning: Indicates the length of the eNodeBspecific timer for reordering at the receiver in AM. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: Treordering_m0(0), Treordering_m5(5), Treordering_m10(10), Treordering_m15(15), Treordering_m20(20), Treordering_m25(25), Treordering_m30(30), Treordering_m35(35), Treordering_m40(40), Treordering_m45(45), Treordering_m50(50), Treordering_m55(55), Treordering_m60(60), Treordering_m65(65), Treordering_m70(70), Treordering_m75(75), Treordering_m80(80), Treordering_m85(85), Treordering_m90(90), Treordering_m95(95), Treordering_m100(100), Treordering_m110(110), Treordering_m120(120), Treordering_m130(130), Treordering_m140(140), Treordering_m150(150), Treordering_m160(160), Treordering_m170(170), Treordering_m180(180), Treordering_m190(190), Treordering_m200(200), Treordering_m1600(1600) Unit: ms Actual Value Range: Treordering_m0, Treordering_m5, Treordering_m10, Treordering_m15, Treordering_m20, Treordering_m25, Treordering_m30, Treordering_m35, Treordering_m40, Treordering_m45, Treordering_m50, Treordering_m55, Treordering_m60, Treordering_m65, Treordering_m70, Treordering_m75, Treordering_m80, Treordering_m85, Treordering_m90, Treordering_m95, Treordering_m100, Treordering_m110, Treordering_m120, Treordering_m130, Treordering_m140, Treordering_m150, Treordering_m160, Treordering_m170, Treordering_m180, Treordering_m190, Treordering_m200, Treordering_m1600 Default Value: Treordering_m40(40) RlcPdcpParaGroup ENodeBUmReorderingTimer ADD RLCPDCPPARAGROUP MOD RLCPDCPPARAGROUP LST RLCPDCPPARAGROUP LBFD-002008 / TDLBFD-002008 LOFD-120204 TDLOFD-120203 MLOFD-121280 / TDLEOFD-121611 Radio Bearer Management VoLTE Coverage Enhancement Based on Extended Delay Budget Deep Coverage Improvement for VoLTE Meaning: Indicates the length of the eNodeBspecific timer for reordering at the receiver in UM. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: Treordering_m0(0), Treordering_m5(5), Treordering_m10(10), Treordering_m15(15), Treordering_m20(20), Treordering_m25(25), Treordering_m30(30), Treordering_m35(35), Treordering_m40(40), Treordering_m45(45), Treordering_m50(50), Treordering_m55(55), Treordering_m60(60), Treordering_m65(65), Treordering_m70(70), MO CellUlschAlgo Parameter ID UlEnhencedVoipSchSw MML Command MOD CELLULSCHALGO LST CELLULSCHALGO Feature ID LBFD-00101502 / TDLBFD-00101502 LOFD001016/TDLOFD001016 LOFD-001048 / TDLOFD-001048 LOFD-081229 / TDLOFD-081229 TDLBFD-111101 LBFD-081104 / TDLBFD-081105 LOFD120204/TDLOFD120203 LBFD-002025 / TDLBFD-002025 TDLOFD-111208 Feature Name Description eMTC Introduction Treordering_m75(75), Treordering_m80(80), Treordering_m85(85), Treordering_m90(90), Treordering_m95(95), Treordering_m100(100), Treordering_m110(110), Treordering_m120(120), Treordering_m130(130), Treordering_m140(140), Treordering_m150(150), Treordering_m160(160), Treordering_m170(170), Treordering_m180(180), Treordering_m190(190), Treordering_m200(200), Treordering_m1600(1600) Unit: ms Actual Value Range: Treordering_m0, Treordering_m5, Treordering_m10, Treordering_m15, Treordering_m20, Treordering_m25, Treordering_m30, Treordering_m35, Treordering_m40, Treordering_m45, Treordering_m50, Treordering_m55, Treordering_m60, Treordering_m65, Treordering_m70, Treordering_m75, Treordering_m80, Treordering_m85, Treordering_m90, Treordering_m95, Treordering_m100, Treordering_m110, Treordering_m120, Treordering_m130, Treordering_m140, Treordering_m150, Treordering_m160, Treordering_m170, Treordering_m180, Treordering_m190, Treordering_m200, Treordering_m1600 Default Value: Treordering_m40(40) Dynamic Scheduling VoIP Semipersistent Scheduling TTI Bundling Voice Characteristic Awareness Scheduling Active Scheduling of Edge Voice Users UL Compensation Scheduling VoLTE Coverage Enhancement Based on Extended Delay Budget/Deep Coverage for VoLTE Basic Scheduling Uplink Interference Coordination Meaning: Indicates whether to enhance uplink scheduling for VoIP services. This parameter includes the following options: UlVoipPreAllocationSwtich: Indicates whether to pre-schedule VoIP UEs during talk spurts when the number of online UEs in a cell exceeds 50. If this option is deselected, VoIP UEs are not prescheduled. If this option is selected, VoIP UEs are pre-scheduled. This option applies only to LTE FDD. UlVoipDelaySchSwitch: Indicates whether to schedule VoIP UEs based on delays when there are a large number of VoIP UEs in a cell and these UEs are evenly distributed. If this option is deselected, VoIP UEs are not scheduled based on delays. If this option is selected, the scheduling priorities for VoIP UEs are calculated based on delays. This option applies only to LTE TDD cells. UlVoIPLoadBasedSchSwitch: Indicates whether to enable adaptive selection of scheduling modes for VoIP UEs based on the cell load. Two scheduling modes are provided: dynamic scheduling and semi-persistent scheduling. If this option is deselected, adaptive selection of dynamic and semi-persistent scheduling cannot be performed for VoIP UEs based on the cell load. If this option is selected, dynamic and semi-persistent scheduling can be adaptively selected for VoIP UEs based on the cell load. UlVoipSchOptSwitch: Indicates whether to optimize scheduling for VoIP UEs in the uplink. If this option is deselected, scheduling is not optimized for VoIP UEs in the uplink. If this option is selected, uplink dynamic scheduling is triggered once for VoIP UEs adopting this scheduling mode when the scheduling interval is longer than the uplink scheduling interval threshold for VoIP UEs. This ensures timely uplink scheduling for VoIP UEs even when SR missing detections occur, avoiding packet losses caused by the expiration of the PDCP packet discarding timer. UlVoLTEDataSizeEstSwitch: Indicates whether to estimate the volume of traffic to be dynamically scheduled for VoIP services in the uplink. If this option is deselected, the eNodeB does not estimate the volume of traffic to be dynamically scheduled for VoLTE services in the uplink. If this option is selected, the eNodeB estimates the traffic volume to be dynamically scheduled for VoLTE services in the uplink. This shortens the VoLTE packet delay, reduces the VoLTE packet loss rate, and improves the voice quality. MO Parameter ID MML Command Feature ID Feature Name Description UlVoipServStateEnhancedSw: Indicates whether to enhance the determination of VoIP service states (either in talk spurts or silent periods) in the uplink. If this option is deselected, the determination of VoIP service states in the uplink is not enhanced. If this option is selected, the determination of VoIP service states in the uplink is enhanced. In this case, the delay in voice service state determination in the uplink is shortened, lowering the probability of voice service states being incorrectly determined in silent periods. When the UlVoipSchOptSwitch option of the same parameter is also selected, the VoIP packet losses caused by SR missing detections decrease, and the voice quality improves, especially the voice quality during initial accesses and handovers. UlVoipRblerControlSwitch: Indicates whether to optimize retransmission for uplink VoIP services. If this option is deselected, the eNodeB does not optimize retransmission for uplink VoIP services. If this option is selected, the eNodeB optimizes retransmission for uplink VoIP services when VoIP UEs perform uplink adaptive retransmissions. As a result, an MCS with a lower index is selected, reducing the VoIP packet losses caused by uplink HARQ retransmission failures. UlEdgeActiveSchSwitch: Indicates whether to enable proactive dynamic scheduling for cell edge VoLTE UEs. If this option is deselected, active dynamic scheduling is disabled for cell edge VoLTE UEs. If this option is selected, active dynamic scheduling is enabled for cell edge VoLTE UEs. In this case, the eNodeB estimates the traffic volume to be dynamically scheduled for VoLTE services in the uplink, and proactively schedules VoLTE UEs based on the estimation results if fragmentation is required due to limited uplink power. As a result, the packet delay is shortened, and the timeout-caused packet loss rate for VoLTE services is reduced, improving the voice quality. This option applies only to LTE TDD. UlMcsRestraintAfterSpsRelSw: Indicates whether to restrict the MCS for uplink dynamic scheduling after uplink semi-persistent scheduling release. If this option is deselected, the eNodeB does not restrict the MCS for uplink dynamic scheduling after uplink semi-persistent scheduling release. If this option and the SpsSchSwitch option of the UlSchSwitch parameter are selected, the eNodeB restricts the MCS for uplink dynamic scheduling after uplink semi-persistent scheduling release. In this case, the reliability of uplink dynamic scheduling transmission after uplink semipersistent scheduling release can be guaranteed, and the voice quality improves. SpsAndDrxOptSwitch: Indicates whether to optimize the cooperation between semi-persistent scheduling and DRX. If this option is deselected, power control commands for semi-persistent scheduling can be delivered during the DRX sleep time. If this option is selected, power control commands for semi-persistent scheduling can be delivered only during the DRX On Duration period, but not during the DRX sleep time. UlCallMuteRecoverSwitch: Indicates whether to enable voice mute recovery in the uplink. If this option is deselected, the eNodeB does not perform voice mute recovery. If this option is selected, the eNodeB performs voice activity detection (VAD) on UEs running voice services and performs intra-cell handovers for or releases the RRC connections of UEs on which speech absence is detected to recreate the radio bearers. UlVoipCrosslayerOptSwitch: Indicates whether to enable cross-layer optimization for VoIP services in the uplink. If this option is deselected, the eNodeB does not perform cross-layer optimization for VoIP services in the uplink. If this option is selected, the eNodeB optimizes the PDCP packet discarding timer for uplink QCI 1 services, the timer for QCI 1 service packet resequencing on the eNodeB as the receiver in UM mode, and the maximum number of transmissions on the MAC MO Parameter ID MML Command Feature ID Feature Name Description layer in the uplink. Then, based on the optimization result, the eNodeB estimates the volume of traffic to be dynamically scheduled for VoIP services in the uplink, selects an optimal MCS, and allocates an optimal number of RBs to such services. In this way, the uplink VoIP packet loss rate decreases, and the voice quality improves. UlVoLTEContinuousSchSw: Indicates whether to enable continuous scheduling for uplink VoLTE services. The continuous scheduling function is enabled only if this option is selected. When this function is enabled, the eNodeB continuously schedules VoLTE UEs during uplink talk spurts to reduce uplink scheduling delay, packet delay, and packet jitter for VoLTE UEs and improve voice quality. UlMixVoLTEOptSwitch: Indicates whether to optimize the scheduling for a UE running uplink voice and data services simultaneously. The eNodeB optimizes the scheduling for a UE running uplink voice and data services simultaneously only when this option is selected. If this option is selected, the eNodeB allocates a bandwidth suitable for scheduling of voice packets to VoLTE UEs running both voice and data services, ensuring that voice services are preferentially scheduled and lowering the packet loss rate of QCI 1 bearers when the voice service load is heavy. This option applies only to LTE FDD and LTE TDD. VoLTEPwrOptSwitch: Indicates whether to optimize power control for VoLTE UEs. If this option is selected, the power for VoLTE UEs at the cell edge quickly converges. It is recommended that this option be selected only in high-speed railway scenarios. UlVoLTEDelaySchEnhancedSw: Indicates whether to enhance delay-based dynamic scheduling prioritization for VoLTE services in the uplink. If this option is deselected, the eNodeB does not enhance delay-based dynamic scheduling prioritization for VoLTE services in the uplink. If this option is selected and the UlDelaySchStrategy parameter in the CellUlschAlgo MO is set to VOIP_AND_DATA_DELAYSCH(VoIP and Data Delay Scheduling), the eNodeB enhances delaybased dynamic scheduling prioritization for VoLTE services in the uplink. This option applies only to LTE TDD. GUI Value Range: UlVoipPreAllocationSwitch (UlVoipPreAllocationSwitch), UlVoipDelaySchSwitch(UlVoipDelaySchSwitch), UlVoIPLoadBasedSchSwitch (UlVoIPLoadBasedSchSwitch), UlVoipSchOptSwitch(UlVoipSchOptSwitch), UlVoLTEDataSizeEstSwitch (UlVoLTEDataSizeEstSwitch), UlVoipServStateEnhancedSw (UlVoipServStateEnhancedSw), UlVoipRblerControlSwitch (UlVoipRblerControlSwitch), UlEdgeActiveSchSwitch(UlEdgeActiveSchSwitch), UlMcsRestraintAfterSpsRelSw (UlMcsRestraintAfterSpsRelSw), SpsAndDrxOptSwitch(SpsAndDrxOptSwitch), UlCallMuteRecoverSwitch (UlCallMuteRecoverSwitch), UlVoipCrosslayerOptSwitch (UlVoipCrosslayerOptSwitch), UlVoLTEContinuousSchSw (UlVoLTEContinuousSchSw), UlMixVoLTEOptSwitch(UlMixVoLTEOptSwitch), VoLTEPwrOptSwitch(VoLTEPwrOptSwitch), UlVoLTEDelaySchEnhancedSw (UlVoLTEDelaySchEnhancedSw) Unit: None Actual Value Range: UlVoipPreAllocationSwitch, UlVoipDelaySchSwitch, UlVoIPLoadBasedSchSwitch, UlVoipSchOptSwitch, UlVoLTEDataSizeEstSwitch, UlVoipServStateEnhancedSw, UlVoipRblerControlSwitch, UlEdgeActiveSchSwitch, UlMcsRestraintAfterSpsRelSw, MO Parameter ID MML Command Feature ID Feature Name Description SpsAndDrxOptSwitch, UlCallMuteRecoverSwitch, UlVoipCrosslayerOptSwitch, UlVoLTEContinuousSchSw, UlMixVoLTEOptSwitch, VoLTEPwrOptSwitch, UlVoLTEDelaySchEnhancedSw Default Value: UlVoipPreAllocationSwitch:Off, UlVoipDelaySchSwitch:Off, UlVoIPLoadBasedSchSwitch:Off, UlVoipSchOptSwitch:On, UlVoLTEDataSizeEstSwitch:Off, UlVoipServStateEnhancedSw:On, UlVoipRblerControlSwitch:On, UlEdgeActiveSchSwitch:Off, UlMcsRestraintAfterSpsRelSw:Off, SpsAndDrxOptSwitch:On, UlCallMuteRecoverSwitch:Off, UlVoipCrosslayerOptSwitch:Off, UlVoLTEContinuousSchSw:Off, UlMixVoLTEOptSwitch:Off, VoLTEPwrOptSwitch:Off, UlVoLTEDelaySchEnhancedSw:Off CellUlschAlgo DataThdInPdcchPuschBal MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the traffic volume threshold of a UE above which the UE is determined as a UE with large packets in the PDCCH and PUSCH resource allocation optimization mechanism when traffic is heavy. If this parameter is set to 0, none of the UEs is determined as a UE with large packets. If this parameter is set to a value ranging from 1 to 1000000 (indicating a threshold from 1 bit to 1,000,000 bits), a UE whose traffic to be scheduled is greater than or equal to this parameter value is determined as a UE with large packets. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~1000000 Unit: bit Actual Value Range: 0~1000000 Default Value: 10000 CellUlschAlgo UeNumThdInPdcchPuschBal MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the threshold for the number of synchronized UEs in a cell above which the PDCCH and PUSCH resource allocation optimization mechanism is activated in large traffic volume scenarios. If this parameter is set to a value ranging from 0 to 10000 (indicating a threshold from 0 UE to 10,000 UEs), the mechanism is activated when the number of synchronized UEs in the cell is greater than or equal to this parameter value. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~10000 Unit: None Actual Value Range: 0~10000 Default Value: 10000 CellUlschAlgo AperiodicCsiUlTxMode MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-060103 Meaning: Indicates the transmission mode of aperiodic CSI in the uplink. If this parameter is set to CsiOnly (CsiOnly) and UEs have only aperiodic downlink CSI to transmit and do not have uplink service data to transmit, these UEs can be immediately scheduled on the PUSCH and only aperiodic downlink CSIs are transmitted on the PUSCH. If this parameter is set to CsiWiUlService (CsiWiUlService) and UEs have only aperiodic downlink CSI to transmit and do not have uplink service data to transmit, within a specified period of time after the aperiodic CSI is triggered, these UEs cannot be immediately scheduled on the PUSCH to transmit only aperiodic downlink CSIs, but the aperiodic downlink CSIs and uplink service data of these UEs can be simultaneously transmitted on the PUSCH. Meanwhile, this parameter also controls the CQI update policy when the eNodeB receives CQI of 0 from UEs. If this parameter is set to CsiOnly (CsiOnly), the eNodeB determines that the CQI is unreliable when receiving CQI of 0 from a UE. If this parameter is set to CsiWiUlService (CsiWiUlService), the eNodeB determines that the CQI is reliable when receiving a CQI of 0 with the reliable indicator set to reliable. The eNodeB Enhanced DL Frequency Selective Scheduling MO Parameter ID MML Command Feature ID Feature Name Description updates the time when the reliable CQI is received but does not use the CQI for scheduling decision. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: CsiOnly(CsiOnly), CsiWiUlService(CsiWiUlService) Unit: None Actual Value Range: CsiOnly, CsiWiUlService Default Value: CsiOnly(CsiOnly) CellUlschAlgo UlSchAbnUeThd MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / TDLBFD-00101502 LBFD-002025 / TDLBFD-002025 CellUlschAlgo UlInBasedFssSinrThld MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling LBFD-060102 Enhanced UL Frequency Selective Scheduling Meaning: Indicates the signal to interference plus noise ratio (SINR) threshold under which interference-based frequency selective resource allocation is enabled in the uplink. This parameter takes effect only when UlInterfFssSwitch of the UlSchSwitch parameter is on. This parameter applies only to LTE FDD networks. GUI Value Range: -500~500 Unit: 0.1dB Actual Value Range: -50~50 Default Value: 500 CellUlschAlgo MaxUlSchRbNum MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-001015 LBFD-002025 Enhanced Scheduling Basic Scheduling Meaning: Indicates the maximum number of RBs allocated to each UE in uplink scheduling. This parameter applies only to LTE FDD. Based on the descriptions in section 6.6.3.2 in 3GPP TS36.101, with given system bandwidth and uplink carrier frequency, changing the value of this parameter can reduce spurious emission to other frequencies in the uplink. GUI Value Range: 1~255 Unit: None Actual Value Range: 1~255 Default Value: 255 CellUlschAlgo HeadOverheadForUlSch MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the head overhead of data in uplink scheduling. This parameter value 0bit indicates that the data does not have head overhead. The parameter value 32bit indicates that the head overhead is 32 bits. This parameter can be set to 32bit in scenarios where RLC initial transmission is performed on a single service and the MAC layer does not send control units. The parameter value 48bit indicates that the head overhead is 48 bits. This parameter can be set to 48bit in scenarios where RLC initial transmission is performed on a single service and the MAC layer sends buffer status reports (BSRs) or power headroom reports (PHRs). The parameter value 64bit indicates that the head overhead is 64 bits. This parameter can be set to 64bit in scenarios where RLC initial transmission is performed on a single service and the MAC layer sends BSRs and PHRs. The parameter value 80bit indicates that the head overhead is 80 bits. This parameter can be set to 80bit in scenarios where RLC retransmission is performed on a single service and the MAC layer sends BSRs and PHRs. The parameter value 96bit indicates that the head overhead is 96 bits. This parameter can be set to 96bit in scenarios where RLC initial transmission is performed on multiple services and the MAC layer sends BSRs or PHRs. The parameter value 128bit indicates that the head overhead is 128 bits. This parameter can be set to 128bit in scenarios where RLC initial transmission Enhanced Scheduling Basic Scheduling Meaning: Indicates the threshold of consecutive cyclic redundancy check (CRC) errors in the uplink above which the eNodeB stops scheduling the abnormal UE. The parameter value range is from 6 to 120. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 6~120 Unit: None Actual Value Range: 6~120 Default Value: 15 MO Parameter ID MML Command Feature ID Feature Name Description is performed on multiple services and the MAC layer sends BSRs and PHRs. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0bit, 32bit, 48bit, 64bit, 80bit, 96bit, 128bit Unit: None Actual Value Range: 0bit, 32bit, 48bit, 64bit, 80bit, 96bit, 128bit Default Value: 0bit CellUlschAlgo SinrAdjustTargetIbler MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-001006 / TDLBFD-001006 LOFD-001006 / TDLOFD-001006 AMC UL 64QAM Meaning: Indicates the target IBLER of the SINR adjustment algorithm. A greater parameter value indicates a greater SINR adjustment value, and thus an MCS of a higher index is used. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1~99 Unit: None Actual Value Range: 0.01~0.99, step:0.01 Default Value: 10 CellUlschAlgo UlTargetIBlerAdaptType MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-001006 AMC Meaning: Indicates whether to enable SINR-fluctuation- or SINR-jump-based target IBLER adaptation. SinrFlunIBlerAdaptSwitch: Indicates whether to enable SINR-fluctuation-based target IBLER adaptation. If the UlIblerAdjustSwitch option of the UlSchSwitch parameter is selected, SINRfluctuation-based target IBLER adaptation is enabled only when the SinrFlunIBlerAdaptSwitch option is selected. This option applies only to LTE FDD and LTE TDD. SinrJumpIBlerAdaptSwitch: Indicates whether to enable SINR-jump-based target IBLER adaptation. If the UlIblerAdjustSwitch option is selected, SINRjump-based target IBLER adaptation is enabled only when the SinrJumpIBlerAdaptSwitch option is selected. This option applies only to LTE FDD. When the UlIblerAdjustSwitch option of the UlSchSwitch parameter is deselected, the two options of the UlIBlerTargetAdaptType parameter do not take effect. GUI Value Range: SinrFlunIBlerAdaptSwitch (SinrFlunIBlerAdaptSwitch), SinrJumpIBlerAdaptSwitch (SinrJumpIBlerAdaptSwitch) Unit: None Actual Value Range: SinrFlunIBlerAdaptSwitch, SinrJumpIBlerAdaptSwitch Default Value: SinrFlunIBlerAdaptSwitch:Off, SinrJumpIBlerAdaptSwitch:Off CellUlschAlgo UlIBlerAdaptBigTrafficSw MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-001006 / TDLBFD-001006 AMC Meaning: Indicates whether large-packet service identification is required in IBLER adaptation. If this parameter is set to ON(On), large-packet service identification is required in IBLER adaptation. If this parameter is set to OFF(Off), large-packet service identification is not required in IBLER adaptation. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: OFF(Off), ON(On) Unit: None Actual Value Range: OFF, ON Default Value: ON(On) Cell UlCyclicPrefix ADD CELL MOD CELL LST CELL LBFD-00100401 / TDLBFD-00100401 LOFD-001031 / TDLOFD-001031 LBFD-002009 / TDLBFD-002009 / MLBFD-12000229 Normal CP Extended CP Broadcast of system information Meaning: Indicates the UL cyclic prefix length of a cell. A cyclic prefix can be a common or extended cyclic prefix. An extended cyclic prefix is generally used in a complex environment with a strong multipath effect and long delay. In a cell, the UL cyclic prefix length can be different from the DL one. In addition, the UL or DL cyclic prefix length of a cell must be the same as that of the cell set up on the same BBP. For details, see 3GPP TS 36.211. GUI Value Range: NORMAL_CP(Normal), EXTENDED_CP(Extended) Unit: None Actual Value Range: NORMAL_CP, EXTENDED_CP Default Value: NORMAL_CP(Normal) MO Parameter ID MML Command Feature ID Feature Name Description CellUlschAlgo SriFalseDetThdSwitch MOD CELLULSCHALGO LST CELLULSCHALGO None None Meaning: Indicates whether to increase the scheduling request indicator (SRI) false detection threshold for UEs in the discontinuous reception (DRX) state. If this parameter is set to ON, the threshold increases and the SRI false detection probability decreases. If this parameter is set to OFF, both the threshold and the probability remain unchanged. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: OFF(Off), ON(On) Unit: None Actual Value Range: OFF, ON Default Value: OFF(Off) CellUciOnPuschPara CellUciOnPuschParaValid MOD CELLUCIONPUSCHPARA LST CELLUCIONPUSCHPARA None None Meaning: Indicates whether parameters except DeltaOffsetAckIndexForTtiB in the CellUciOnPuschPara MO take effect. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: FALSE(FALSE), TRUE(TRUE) Unit: None Actual Value Range: FALSE, TRUE Default Value: FALSE(FALSE) CellUciOnPuschPara DeltaOffsetAckIndex MOD CELLUCIONPUSCHPARA LST CELLUCIONPUSCHPARA LEOFD-111306 / TDLOFD-120205 Breathing Pilot Meaning: Indicates the index mapped to the MCS offset for acknowledgments (ACKs) transmitted with data on PUSCH. For details, see 3GPP TS 36.213. Some values are reserved, for example, value 15 is reserved in 3GPP TS 36.213 Release 9. When this parameter is set to a reserved value, a UE initiates an RRC connection reestablishment or fails to access the network. This parameter applies only to UEs that are not in the TTI bundling state. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~15 Unit: None Actual Value Range: 0~15 Default Value: 9 CellUciOnPuschPara DeltaOffsetRiIndex MOD CELLUCIONPUSCHPARA LST CELLUCIONPUSCHPARA None None Meaning: Indicates the index mapped to the MCS offset for RIs transmitted with data on PUSCH. For details, see 3GPP TS 36.213. Some values are reserved, for example, values 13, 14, and 15 are reserved in 3GPP TS 36.213 Release 9. If this parameter is set to a reserved value, access failure or RRC connection reestablishment will occur. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~15 Unit: None Actual Value Range: 0~15 Default Value: 5 CellUciOnPuschPara DeltaOffsetCqiIndex MOD CELLUCIONPUSCHPARA LST CELLUCIONPUSCHPARA None None Meaning: Indicates the index mapped to the MCS offset for CQIs transmitted with data on PUSCH. For details, see 3GPP TS 36.213. Some values are reserved, for example, values 0 and 1 are reserved in 3GPP TS 36.213 Release 9. If this parameter is set to a reserved value, access failure or RRC connection reestablishment will occur. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~15 Unit: None Actual Value Range: 0~15 Default Value: 12 DeltaOffsetAckIndex MOD PUSCHPARAM LST PUSCHPARAM None None Meaning: Indicates the index mapped to the MCS offset for acknowledgments (ACKs) transmitted with data on PUSCH. For details, see 3GPP TS 36.213. Some values are reserved, for example, value 15 is reserved in 3GPP TS 36.213 Release 9. When this parameter is set to a reserved value, a UE initiates an RRC connection reestablishment or fails to access the network. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~15 Unit: None Actual Value Range: 0~15 Default Value: 9 DeltaOffsetRiIndex MOD PUSCHPARAM PuschParam MO Parameter ID PuschParam MML Command Feature ID Feature Name Description LST PUSCHPARAM None None Meaning: Indicates the index mapped to the MCS offset for rank indications (RIs) transmitted with data on PUSCH. For details, see 3GPP TS 36.213. Some values are reserved, for example, values 13, 14, and 15 are reserved in 3GPP TS 36.213 Release 9. When this parameter is set to a reserved value, a UE initiates an RRC connection reestablishment or fails to access the network. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~15 Unit: None Actual Value Range: 0~15 Default Value: 5 PuschParam DeltaOffsetCqiIndex MOD PUSCHPARAM LST PUSCHPARAM None None Meaning: Indicates the index mapped to the MCS offset for channel quality indicators (CQIs) transmitted with data on PUSCH. For details, see 3GPP TS 36.213. Some values are reserved, for example, values 0 and 1 are reserved in 3GPP TS 36.213 Release 9. When this parameter is set to a reserved value, a UE initiates an RRC connection reestablishment or fails to access the network. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~15 Unit: None Actual Value Range: 0~15 Default Value: 12 CellRbReserve RbRsvMode ADD CELLRBRESERVE MOD CELLRBRESERVE LST CELLRBRESERVE MLBFD-12000103 LTE In-band Deployment Meaning: Indicates the purpose for reserving RBs. The value NB_RESERVED indicates that the specified RBs are reserved as a guardband in the uplink or to reduce the interference between LTE and NB-IoT cells in the downlink. The value NB_DEPLOYMENT indicates that the specified RBs are to be used for deploying NB-IoT. The value RB_MASKING indicates that the specified RBs are to be used for manual RB masking. The value RB_MASKING_WITH_SRS indicates that the specified RBs are to be used for manual RB and SRS masking. This parameter applies only to LTE FDD and NB-IoT. GUI Value Range: NB_RESERVED (NB_RESERVED), NB_DEPLOYMENT (NB_DEPLOYMENT), RB_MASKING (RB_MASKING), RB_MASKING_WITH_SRS (RB_MASKING_WITH_SRS) Unit: None Actual Value Range: NB_RESERVED, NB_DEPLOYMENT, RB_MASKING, RB_MASKING_WITH_SRS Default Value: None QciPara UlMinGbr ADD QCIPARA MOD QCIPARA LST QCIPARA LBFD-00101502 / TDLBFD-00101502 LOFD-00301101 / TDLOFD-00301101 LOFD-00301102 / TDLOFD-00301102 LOFD-00301103 LBFD-002025 / TDLBFD-002025 LBFD-001015 / TDLBFD-001015 Dynamic Scheduling Transport Overbooking Transport Differentiated Flow Control Transport Resource Overload Control Basic Scheduling Enhanced Scheduling Meaning: Indicates the uplink minimum guaranteed bit rate of the service. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: MinGbrRate_0_KB(0kB/s), MinGbrRate_1_KB(1kB/s), MinGbrRate_2_KB (2kB/s), MinGbrRate_4_KB(4kB/s), MinGbrRate_8_KB(8kB/s), MinGbrRate_16_KB (16kB/s), MinGbrRate_32_KB(32kB/s), MinGbrRate_64_KB(64kB/s), MinGbrRate_128_KB(128kB/s), MinGbrRate_256_KB(256kB/s), MinGbrRate_512_KB(512kB/s) Unit: kB/s Actual Value Range: MinGbrRate_0_KB, MinGbrRate_1_KB, MinGbrRate_2_KB, MinGbrRate_4_KB, MinGbrRate_8_KB, MinGbrRate_16_KB, MinGbrRate_32_KB, MinGbrRate_64_KB, MinGbrRate_128_KB, MinGbrRate_256_KB, MinGbrRate_512_KB Default Value: MinGbrRate_1_KB(1kB/s) QciPara PrioritisedBitRate ADD QCIPARA MOD QCIPARA LST QCIPARA LBFD-00101502 / TDLBFD-00101502 TDLBFD-002025 TDLBFD-001015 Dynamic Scheduling Basic Scheduling Enhanced Scheduling Meaning: Indicates the prioritized bit rate of the logical channel. The UE scheduler guarantees prioritized bit rates of logical channels in descending order of logical channel priority. For details, see 3GPP TS 36.321. This parameter applies only to LTE FDD and LTE TDD. MO Parameter ID MML Command Feature ID Feature Name Description GUI Value Range: PBR_0_KBps(0kB/s), PBR_8_KBps(8kB/s), PBR_16_KBps(16kB/s), PBR_32_KBps(32kB/s), PBR_64_KBps(64kB/s), PBR_128_KBps(128kB/s), PBR_256_KBps (256kB/s), PBR_INFINITY(Infinity) Unit: kB/s Actual Value Range: PBR_0_KBps, PBR_8_KBps, PBR_16_KBps, PBR_32_KBps, PBR_64_KBps, PBR_128_KBps, PBR_256_KBps, PBR_INFINITY Default Value: PBR_8_KBps(8kB/s) QciPara LogicalChannelPriority ADD QCIPARA MOD QCIPARA LST QCIPARA LBFD-00101502 / TDLBFD-00101502 LBFD-002025 / TDLBFD-002025 LBFD-001015 / TDLBFD-001015 Dynamic Scheduling Basic Scheduling Enhanced Scheduling Meaning: Indicates the priority of the logical channel. The UE scheduler guarantees prioritized bit rates of logical channels in descending order of logical channel priority. Resources are allocated in descending order of logical channel priority after the prioritized bit rates of all services are guaranteed. For details, see 3GPP TS 36.321. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 4~16 Unit: None Actual Value Range: 4~16 Default Value: 11 GlobalProcSwitch LcgProfile MOD GLOBALPROCSWITCH LST GLOBALPROCSWITCH LBFD-002025 / TDLBFD-002025 LBFD-00101502 / TDLBFD-00101502 LOFD-081218 TDLOFD-110230 Basic Scheduling Dynamic Scheduling Enhanced Extended QCI Enhanced QoS for MCPTT (Trial) Meaning: Indicates the logical channel group configuration. Currently, three logical channel group profiles are available. If this parameter is set to LCG_PROFILE_0, logical channel groups are as follows: - The control-plane services (SRB 1, SRB 2, QCI 5 bearers, and QCI 69 bearers) and QCI 65 bearers are assigned logical channel group 0. - VoLTE services (QCI 1 bearers) and QCI 66 bearers are assigned logical channel group 1. - Other GBR services (QCIs 2 to 4 bearers) are assigned logical channel group 2. - Non-GBR services are assigned logical channel group 3. If this parameter is set to LCG_PROFILE_1, logical channel groups are as follows: - Control-plane services, PTT voice services (QCIs 65 and 66 bearers), and VoLTE services (QCI 1 bearers) are assigned logical channel group 0. - Other GBR services are assigned logical channel group 1. - High-priority non-GBR services are assigned logical channel group 2. - Low-priority non-GBR services are assigned logical channel group 3. If this parameter is set to LCG_PROFILE_2, logical channel groups are as follows: - The control-plane services and QCI 65 bearers are assigned logical channel group 0. - VoLTE services, QCI 66 services, and other GBR services (QCIs 2 to 4 bearers) are assigned logical channel group 1. - High-priority non-GBR services are assigned logical channel group 2. - Low-priority non-GBR services are assigned logical channel group 3. Therefore, if this parameter is set to LCG_PROFILE_2, VoLTE services must be carried by QCI 1 bearers, PTT services must be carried by QCI 65 and 66 bearers, and it is recommended that QCIs 2 to 4 bearers not be used. LTE TDD does not support LCG_PROFILE_2. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: LCG_PROFILE_0, LCG_PROFILE_1, LCG_PROFILE_2 Unit: None Actual Value Range: LCG_PROFILE_0, LCG_PROFILE_1, LCG_PROFILE_2 Default Value: LCG_PROFILE_0 CellUlschAlgo UlschStrategy MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-002025 / TDLBFD-002025 Basic Scheduling Meaning: Indicates the UL scheduling policy, which determines the scheduling priority order in MO Parameter ID MML Command Feature ID Feature Name Description TDLBFD-001015 Dynamic Scheduling LBFD-00101502 / TDLBFD-00101502 Enhanced Scheduling which UEs are arranged in UL. There are four UL scheduling strategies: MAX C/I, proportional fair (PF), round Robin (RR), and enhanced proportional fair (EPF). The MAX C/I policy schedules UEs in descending order of average signal to interference plus noise ratio (SINR). The PF policy schedules UEs in ascending order of ratio of the data rate to the average SINR. The RR policy schedules each UE in sequence, and therefore each UE has an equal opportunity to be scheduled. The EPF policy schedules UEs in ascending order of priority. In EPF, the priority of an UE is calculated based on the following factors: the data rate, average SINR, QoS-satisfying data rate for each service, and service differentiation requirements of the UE. The MAX C/I, PF, and RR policies are basic UL scheduling policies and supported by the eNodeB by default, whereas the EPF policy is intended for commercial use. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: ULSCH_STRATEGY_EPF (EPF), ULSCH_STRATEGY_MAX_CI(MAX_CI), ULSCH_STRATEGY_PF(PF), ULSCH_STRATEGY_RR(RR) Unit: None Actual Value Range: ULSCH_STRATEGY_EPF, ULSCH_STRATEGY_MAX_CI, ULSCH_STRATEGY_PF, ULSCH_STRATEGY_RR Default Value: ULSCH_STRATEGY_EPF(EPF) Meaning: Indicates the duration of uplink smart preallocation triggered by downlink scheduling. If SmartPreAllocationSwitch is set to On and this parameter is set to 0, neither smart preallocation nor preallocation takes effect. If SmartPreAllocationSwitch is set to Off, this parameter is invalid. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~2000 Unit: ms Actual Value Range: 0~2000 Default Value: 50 CellUlschAlgo SmartPreAllocationDuration MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / TDLBFD-00101502 LBFD-001015 / TDLBFD-001015 CellUlschAlgo SmartPreAllocDuraForSparse MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the smart preallocation duration for sparse packets. The larger value between this parameter and the SmartPreAllocationDuration parameter is selected as the actual smart preallocation duration for sparse packets. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~2000 Unit: ms Actual Value Range: 0~2000 Default Value: 1500 DrxParaGroup DrxInactivityTimer ADD DRXPARAGROUP MOD DRXPARAGROUP LST DRXPARAGROUP LBFD-002017 / TDLBFD-002017 LEOFD-111306 LOFD-00110501 LTROFD-111203 / TDLOFD-121105 MLOFD-121280 / TDLEOFD-121611 Meaning: Indicates the length of the DRX inactivity timer. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: PSF1(1 PDCCH subframe), PSF2(2 PDCCH subframes), PSF3(3 PDCCH subframes), PSF4(4 PDCCH subframes), PSF5(5 PDCCH subframes), PSF6(6 PDCCH subframes), PSF8(8 PDCCH subframes), PSF10(10 PDCCH subframes), PSF20(20 PDCCH subframes), PSF30(30 PDCCH subframes), PSF40(40 PDCCH subframes), PSF50(50 PDCCH subframes), PSF60(60 PDCCH subframes), PSF80(80 PDCCH subframes), PSF100(100 PDCCH subframes), PSF200(200 PDCCH subframes), PSF300(300 PDCCH subframes), PSF500(500 PDCCH subframes), PSF750(750 PDCCH subframes), PSF1280(1280 PDCCH subframes), PSF1920 (1920 PDCCH subframes), PSF2560(2560 PDCCH subframes) Unit: subframe Actual Value Range: PSF1, PSF2, PSF3, PSF4, PSF5, PSF6, PSF8, PSF10, PSF20, PSF30, PSF40, PSF50, PSF60, PSF80, PSF100, PSF200, PSF300, PSF500, PSF750, PSF1280, PSF1920, PSF2560 Default Value: PSF80(80 PDCCH subframes) Dynamic Scheduling Enhanced Scheduling DRX Breathing Pilot Dynamic DRX RRC and DRX Policy for Public Safety eMTC Introduction MO Parameter ID MML Command Feature ID CellUlschAlgo PreAllocationBandwidthRatio MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Feature Name Meaning: Indicates the ratio of the maximum bandwidth resources that the uplink scheduler can allocate to preallocation UEs to the total system bandwidth. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~100 Unit: % Actual Value Range: 0~100 Default Value: 25 CellUlschAlgo PreAllocationSize MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the data amount pre-allocated to each user. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 45~1500 Unit: byte Actual Value Range: 45~1500 Default Value: 80 CellUlschAlgo PreallocationSizeForSparse MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the data amount preallocated to each UE with sparse packets. When this parameter is set to SAME_AS_OTHER_SERVICE, the PreAllocationSize parameter value is applicable to UEs with sparse packets. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: SAME_AS_OTHER_SERVICE (SAME_AS_OTHER_SERVICE), 80BYTE (80BYTE), 160BYTE(160BYTE), 320BYTE (320BYTE), 640BYTE(640BYTE), 1280BYTE (1280BYTE), 2560BYTE(2560BYTE) Unit: None Actual Value Range: SAME_AS_OTHER_SERVICE, 80BYTE, 160BYTE, 320BYTE, 640BYTE, 1280BYTE, 2560BYTE Default Value: SAME_AS_OTHER_SERVICE (SAME_AS_OTHER_SERVICE) CellUlschAlgo PreAllocationMinPeriod MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the minimum interval between two pre-allocations. That is, the actual interval between two pre-allocations of one UE must be longer than or equal to the value of this parameter. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1~40 Unit: ms Actual Value Range: 1~40 Default Value: 5 CellUlschAlgo PreAllocMinPeriodForSparse MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the minimum interval between two preallocations for a UE with sparse packets. This is, the interval between two times that a UE with sparse packets is preallocated cannot be less than this parameter value. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: SAME_AS_OTHER_SERVICE (SAME_AS_OTHER_SERVICE), 1ms(1ms), 2ms (2ms), 3ms(3ms), 4ms(4ms), 5ms(5ms) Unit: None Actual Value Range: SAME_AS_OTHER_SERVICE, 1ms, 2ms, 3ms, 4ms, 5ms Default Value: SAME_AS_OTHER_SERVICE (SAME_AS_OTHER_SERVICE) QciPara PreAllocationWeight ADD QCIPARA MOD QCIPARA LST QCIPARA LBFD-001015 / TDLBFD-001015 LBFD-00101502 / TDLBFD-00101502 Meaning: Indicates the pre-allocation weight. The pre-allocation weight of a UE is the pre-allocation weight of services carried by the highest-priority logical channel. If services carried by highestpriority logical channels have different preallocation weights, the UE takes the highest preallocation weight. When resources are insufficient, pre-allocation weights affect the pre-allocation probabilities of users. The pre-allocation probability has a positive correlation with the pre-allocation weight. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~10 Unit: None Actual Value Range: 0~1, step:0.1 Default Value: 10 UlHoppingType MOD CELLULSCHALGO Enhanced Scheduling Dynamic Scheduling Description MO Parameter ID CellUlschAlgo MML Command Feature ID Feature Name Description LST CELLULSCHALGO LBFD-002025 / TDLBFD-002025 LBFD-001015 / TDLBFD-001015 Basic Scheduling Enhanced Scheduling Meaning: Indicates whether frequency hopping (FH) is enabled or disabled and which FH type is used. Hopping_OFF: indicates that FH is disabled. Hopping_Type1: indicates that adaptive FH is enabled and FH type 1 is used. In this scenario, UEs in the cell can determine whether to use FH based on the actual situation. Hopping_Type2: indicates that adaptive FH is enabled and FH type 2 is used. In this scenario, UEs in the cell can determine whether to use FH based on the actual situation. Hopping_Type2_RANDOM: indicates that interference-randomization-based FH is enabled and FH type 2 is used. In this scenario, all UEs in the cell use FH. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: HOPPING_OFF(Hopping off), HOPPING_TYPE1(Hopping Type 1), HOPPING_TYPE2(Hopping Type 2), HOPPING_TYPE2_RANDOM(Hopping Type 2 Random) Unit: None Actual Value Range: HOPPING_OFF, HOPPING_TYPE1, HOPPING_TYPE2, HOPPING_TYPE2_RANDOM Default Value: HOPPING_OFF(Hopping off) RlcPdcpParaGroup RlcParaAdaptSwitch ADD RLCPDCPPARAGROUP MOD RLCPDCPPARAGROUP LST RLCPDCPPARAGROUP LBFD-002008 / TDLBFD-002008 Radio Bearer Management Meaning: Indicates whether to enable adaptive configuration of parameters related to Radio Link Control (RLC). If this parameter is set to ON(On), the eNodeB adaptively configures the lengths of the following timers according to the number of UEs in the cell when new UEs access the cell: (1) The polling PDU retransmission timer for the UE (2) The polling PDU retransmission timer for the eNodeB (3) The UE-specific timer for prohibiting status reporting from the receiver (4) The eNodeB-specific timer for prohibiting status reporting from the receiver If the SMALL_BAND_RLC_OPT_SWITCH option of the SmallBandOptSwitch parameter is selected, for a small-bandwidth cell (cell with a bandwidth of 5 MHz, 3 MHz, or 1.4 MHz), this adaptive configuration function is enabled regardless of the RlcParaAdaptSwitch parameter setting. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: OFF(Off), ON(On) Unit: None Actual Value Range: OFF, ON Default Value: ON(On) RrcConnStateTimer UeInactiveTimer MOD RRCCONNSTATETIMER LST RRCCONNSTATETIMER LBFD-002007 / TDLBFD-002007 RRC Connection Management Meaning: Indicates the length of the UE Inactivity Timer for UEs that do not have QCI-1 services. If the eNodeB detects that such a UE has neither received nor sent data for a period exceeding the value of this parameter, the eNodeB releases the RRC connection for the UE. If this parameter is set to 0, the UE Inactivity Timer is not used. This parameter takes effect only for such UEs that will access the network after the parameter is set. If the QciParaEffectFlag parameter in the GlobalProcSwitch MO is set to ON(On), the UeInactiveTimerForQci parameter in the QciPara MO, rather than this parameter takes effect. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~3600 Unit: s Actual Value Range: 0~3600 Default Value: 20 CellDlschAlgo DlEpfCapacityFactor MOD CELLDLSCHALGO LST CELLDLSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the capacity factor for downlink enhanced proportional fair (EPF) scheduling. This factor affects the scheduling priorities of UEs running services with the QCI of 6, 7, 8, or 9, and accordingly can be used to adjust the cell capacity and fairness among users. This parameter applies only to LTE FDD and LTE TDD. MO Parameter ID MML Command Feature ID Feature Name Description GUI Value Range: EPF_CAPC_FACTOR_1(1), EPF_CAPC_FACTOR_0DOT01(0.01), EPF_CAPC_FACTOR_0DOT5(0.5), EPF_CAPC_FACTOR_2(2), EPF_CAPC_FACTOR_3(3), EPF_CAPC_FACTOR_4(4) Unit: None Actual Value Range: EPF_CAPC_FACTOR_1, EPF_CAPC_FACTOR_0DOT01, EPF_CAPC_FACTOR_0DOT5, EPF_CAPC_FACTOR_2, EPF_CAPC_FACTOR_3, EPF_CAPC_FACTOR_4 Default Value: EPF_CAPC_FACTOR_1(1) QciPara Qci ADD QCIPARA LST QCIPARA MOD QCIPARA RMV QCIPARA LBFD-00101502 / TDLBFD-00101502 LBFD-002025 / TDLBFD-002025 LBFD-001015 / TDLBFD-001015 MLBFD-12100205 Dynamic Scheduling Basic Scheduling Enhanced Scheduling Data over User Plane Meaning: Indicates the QCI, which is an attribute of EPS bearers. Different QCIs represent different QoS specifications such as the packet delay budget, packet loss rate (PLR) and packet error rate (PER), and resource type (whether the service is a GBR service or not). For details, see Table 6.1.7 in 3GPP TS 23.203. GUI Value Range: 1,2,3,4,5,6,7,8,9,10~64,65,66,67~68,69,70,71~254 Unit: None Actual Value Range: 1,2,3,4,5,6,7,8,9,10~64,65,66,67~68,69,70,71~254 Default Value: None GlobalProcSwitch QciParaEffectFlag MOD GLOBALPROCSWITCH LST GLOBALPROCSWITCH LBFD-002008 TDLBFD-002017 LBFD-002018 / TDLBFD-002018 TDLBFD-00201801 LBFD-00201802 / TDLBFD-00201802 LBFD-00201805 / TDLBFD-00201805 LOFD-00301101 / TDLOFD-00301101 LOFD-00301102 / TDLOFD-00301102 LOFD-00301103 / TDLOFD-00301103 Radio Bearer Management DRX Mobility Management Coverage Based Intrafrequency Handover Coverage Based Interfrequency Handover Service Based Interfrequency Handover Transport Overbooking Transport Differentiated Flow Control Transport Resource Overload Control Meaning: Indicates whether parameters in QciPara, CellQciPara, and CnOperatorQciPara MOs take effect. The parameters take effect by default. If this parameter is set to OFF, parameters in StandardQci, ExtendedQci, CellStandardQci, CellExtendedQci, CnOperatorStandardQci, and CnOperatorExtendedQci MOs take effect and parameters in QciPara, CellQciPara, and CnOperatorQciPara MOs do not take effect. If this parameter is set to ON, parameters in QciPara, CellQciPara, and CnOperatorQciPara MOs take effect and parameters in StandardQci, ExtendedQci, CellStandardQci, CellExtendedQci, CnOperatorStandardQci, and CnOperatorExtendedQci MOs do not take effect. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: OFF(Off), ON(On) Unit: None Actual Value Range: OFF, ON Default Value: ON(On) CellAlgoSwitch LocalCellId DSP CELLULCAMCCLUSTER DSP CELLULICSSTATUS LST CELLALGOSWITCH MOD CELLALGOSWITCH None None Meaning: Indicates the local ID of the cell. It uniquely identifies a cell within an eNodeB. GUI Value Range: 0~255 Unit: None Actual Value Range: 0~255 Default Value: None SRSCfg FddSrsCfgMode MOD SRSCFG LST SRSCFG LBFD-002003 LEOFD-111305 Physical Channel Management Virtual 4T4R Meaning: Indicates the allocation mode of sounding reference signal (SRS) resources in LTE FDD. This parameter must be set when the SrsCfgInd parameter is set to BOOLEAN_TRUE (True). If the FddSrsCfgMode parameter is set to DEFAULTMODE(Default Mode), SRS resource allocation is activated by default after a cell is established, and SRS resources are allocated to UEs that access the cell. If this parameter is set to ADAPTIVEMODE(Adaptive Mode), SRS resource allocation can be adaptively activated or deactivated based on the cell load. After this parameter is set to ADAPTIVEMODE(Adaptive Mode), settings of parameters SrsAlgoSwitch, SrsSubframeCfg, and UserSrsPeriod do not take effect. The parameter value ADAPTIVEMODE (Adaptive Mode) is recommended in heavy-traffic scenarios where there is a large number of UEs in the cell. The parameter value ADAPTIVEMODE MO Parameter ID MML Command Feature ID Feature Name Description (Adaptive Mode) does not apply to cells established on an LBBPc. This parameter applies only to LTE FDD. GUI Value Range: DEFAULTMODE(Default Mode), ADAPTIVEMODE(Adaptive Mode) Unit: None Actual Value Range: DEFAULTMODE, ADAPTIVEMODE Default Value: ADAPTIVEMODE(Adaptive Mode) CellUlschAlgo UlRbAllocationStrategy MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling LBFD-060102 Enhanced UL Frequency Selective Scheduling Meaning: Indicates the strategy for allocating resource blocks (RBs) in the uplink of the cell. If this parameter is set to FS_NONFS_ADAPTIVE, this strategy adaptively switches between frequency selective scheduling and non-frequency selective scheduling. If this parameter is set to FS_INRANDOM_ADAPTIVE, this strategy adaptively switches between frequency selective scheduling and interference-randomization-based scheduling. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: FS_NONFS_ADAPTIVE(Fs nonFs Strategy), FS_INRANDOM_ADAPTIVE(Fs InRandom Strategy) Unit: None Actual Value Range: FS_NONFS_ADAPTIVE, FS_INRANDOM_ADAPTIVE Default Value: FS_INRANDOM_ADAPTIVE(Fs InRandom Strategy) CellUlschAlgo UlEpfCapacityFactor MOD CELLULSCHALGO LST CELLULSCHALGO LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the capacity factor for uplink enhanced proportional fair (EPF) scheduling. When the eNodeB schedules UEs with unsatisfied GBR, this factor affects the scheduling priorities of UEs running services with the QCI of 1, 2, 3, or 4. When the eNodeB schedules UEs running NonGBR services, this factor affects the scheduling priorities of UEs running services with the QCI of 6, 7, 8, or 9. In this way, this factor can be used to adjust the cell capacity and fairness among UEs. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: EPF_CAPC_FACTOR_1(1), EPF_CAPC_FACTOR_0DOT01(0.01), EPF_CAPC_FACTOR_0DOT5(0.5), EPF_CAPC_FACTOR_2(2), EPF_CAPC_FACTOR_3(3), EPF_CAPC_FACTOR_4(4) Unit: None Actual Value Range: EPF_CAPC_FACTOR_1, EPF_CAPC_FACTOR_0DOT01, EPF_CAPC_FACTOR_0DOT5, EPF_CAPC_FACTOR_2, EPF_CAPC_FACTOR_3, EPF_CAPC_FACTOR_4 Default Value: EPF_CAPC_FACTOR_1(1) CellQciPara Qci ADD CELLQCIPARA LST CELLQCIPARA MOD CELLQCIPARA RMV CELLQCIPARA LBFD-002025 / TDLBFD-002025 LBFD-00101502 / TDLBFD-00101502 Basic Scheduling Dynamic Scheduling Meaning: Indicates the QoS class identifier (QCI), which is an attribute of evolved packet system (EPS) bearers. Different QCIs indicate different QoS requirements, such as the packet delay budget, packet loss rate (PLR) and packet error rate (PER), and resource type (whether the service is a GBR service or not). For details, see Table 6.1.7 in 3GPP TS 23.203. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1,2,3,4,5,6,7,8,9,10~64,65,66,67~68,69,70,71~254 Unit: None Actual Value Range: 1,2,3,4,5,6,7,8,9,10~64,65,66,67~68,69,70,71~254 Default Value: None CellQciPara PreallocationParaGroupId ADD CELLQCIPARA MOD CELLQCIPARA LST CELLQCIPARA LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the ID of the parameter group related to preallocations. The value 255 indicates an invalid preallocation parameter group. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~9,255 Unit: None Actual Value Range: 0~9,255 Default Value: 255 MO Parameter ID MML Command Feature ID Feature Name Description CellPreallocGroup PreallocationParaGroupId ADD CELLPREALLOCGROUP LST CELLPREALLOCGROUP MOD CELLPREALLOCGROUP RMV CELLPREALLOCGROUP None None Meaning: Indicates the ID of the parameter group related to preallocations. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~9 Unit: None Actual Value Range: 0~9 Default Value: None CellPreallocGroup PreallocationSwitch ADD CELLPREALLOCGROUP MOD CELLPREALLOCGROUP LST CELLPREALLOCGROUP LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates whether to enable or disable preallocation for a bearer with a specified preallocation parameter group ID. If this parameter is set to ON(On), preallocation is enabled for this bearer. If this parameter is set to OFF(Off), preallocation is disabled for this bearer. This switch is a bearer-level switch and takes effect when the cell-level switch PreAllocationSwitch in the CellAlgoSwitch MO is turned on. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: OFF(Off), ON(On) Unit: None Actual Value Range: OFF, ON Default Value: ON(On) CellPreallocGroup SmartPreallocationSwitch ADD CELLPREALLOCGROUP MOD CELLPREALLOCGROUP LST CELLPREALLOCGROUP LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates whether smart preallocation is enabled or disabled for a bearer with a specified preallocation parameter group ID when PreAllocationSwitch is turned on. If both PreAllocationSwitch and SmartPreAllocationSwitch are turned on, and SmartPreAllocationDuration is set to a value greater than 0, uplink smart preallocation is enabled; otherwise, uplink smart preallocation is disabled. This switch is a bearerlevel switch and takes effect when the cell-level switch PreAllocationSwitch in the CellAlgoSwitch MO is turned on. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: OFF(Off), ON(On) Unit: None Actual Value Range: OFF, ON Default Value: OFF(Off) CellPreallocGroup PreallocationMinPeriod ADD CELLPREALLOCGROUP MOD CELLPREALLOCGROUP LST CELLPREALLOCGROUP LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the minimum interval between two preallocations, that is, the interval between two times that a UE is preallocated must be greater than or equal to this parameter value. When the DRX algorithm switch is on and the UE is in DRX mode, the actual value of this parameter cannot be greater than the DrxInactivityTimer parameter value. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 1~40 Unit: ms Actual Value Range: 1~40 Default Value: 5 CellPreallocGroup PreallocationSize ADD CELLPREALLOCGROUP MOD CELLPREALLOCGROUP LST CELLPREALLOCGROUP LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the data amount preallocated to each UE. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 45~1500 Unit: byte Actual Value Range: 45~1500 Default Value: 80 CellPreallocGroup SmartPreallocationDuration ADD CELLPREALLOCGROUP MOD CELLPREALLOCGROUP LST CELLPREALLOCGROUP LBFD-00101502 / Dynamic TDLBFD-00101502 Scheduling Meaning: Indicates the duration of each smart preallocation. This parameter applies only to LTE FDD and LTE TDD. GUI Value Range: 0~2000 Unit: ms Actual Value Range: 0~2000 Default Value: 0 14 Counters Table 14-1 Counters Counter ID Counter Name Counter Description Feature ID Feature Name 1526726737 L.ChMeas.PRB.UL.Used.Avg Average number of used uplink PRBs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA 1526726740 L.ChMeas.PRB.DL.Used.Avg Average number of used PDSCH PRBs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 LEOFD-111305 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA Virtual 4T4R 1526726776 L.Thrp.bits.UL.QCI.1 Uplink traffic volume for PDCP PDUs of services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726777 L.Thrp.Time.UL.QCI.1 Receive duration of uplink PDCP PDUs for services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726779 L.Thrp.bits.UL.QCI.2 Uplink traffic volume for PDCP PDUs of services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726780 L.Thrp.Time.UL.QCI.2 Receive duration of uplink PDCP PDUs for services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726782 L.Thrp.bits.UL.QCI.3 Uplink traffic volume for PDCP PDUs of services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726783 L.Thrp.Time.UL.QCI.3 Receive duration of uplink PDCP PDUs for services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726785 L.Thrp.bits.UL.QCI.4 Uplink traffic volume for PDCP PDUs of services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726786 L.Thrp.Time.UL.QCI.4 Receive duration of uplink PDCP PDUs for services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526726788 L.Thrp.bits.UL.QCI.5 Uplink traffic volume for PDCP PDUs of services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726789 L.Thrp.Time.UL.QCI.5 Receive duration of uplink PDCP PDUs for services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726791 L.Thrp.bits.UL.QCI.6 Uplink traffic volume for PDCP PDUs of services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726792 L.Thrp.Time.UL.QCI.6 Receive duration of uplink PDCP PDUs for services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726794 L.Thrp.bits.UL.QCI.7 Uplink traffic volume for PDCP PDUs of services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726795 L.Thrp.Time.UL.QCI.7 Receive duration of uplink PDCP PDUs for services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726797 L.Thrp.bits.UL.QCI.8 Uplink traffic volume for PDCP PDUs of services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726798 L.Thrp.Time.UL.QCI.8 Receive duration of uplink PDCP PDUs for services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726800 L.Thrp.bits.UL.QCI.9 Uplink traffic volume for PDCP PDUs of services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726801 L.Thrp.Time.UL.QCI.9 Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Receive duration of uplink PDCP PDUs for services with the QCI of 9 in a cell GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526726803 L.Thrp.bits.DL.QCI.1 Downlink traffic volume for PDCP SDUs of services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726804 L.Thrp.Time.DL.QCI.1 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 1 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726806 L.Thrp.bits.DL.QCI.2 Downlink traffic volume for PDCP SDUs of services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726807 L.Thrp.Time.DL.QCI.2 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 2 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726809 L.Thrp.bits.DL.QCI.3 Downlink traffic volume for PDCP SDUs of services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726810 L.Thrp.Time.DL.QCI.3 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 3 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726812 L.Thrp.bits.DL.QCI.4 Downlink traffic volume for PDCP SDUs of services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726813 L.Thrp.Time.DL.QCI.4 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 4 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726815 L.Thrp.bits.DL.QCI.5 Downlink traffic volume for PDCP SDUs of services with the QCI of 5 in a cell Radio Bearer Management Radio Bearer Management Basic Scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526726816 L.Thrp.Time.DL.QCI.5 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 5 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726818 L.Thrp.bits.DL.QCI.6 Downlink traffic volume for PDCP SDUs of services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726819 L.Thrp.Time.DL.QCI.6 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 6 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726821 L.Thrp.bits.DL.QCI.7 Downlink traffic volume for PDCP SDUs of services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726822 L.Thrp.Time.DL.QCI.7 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 7 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726824 L.Thrp.bits.DL.QCI.8 Downlink traffic volume for PDCP SDUs of services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726825 L.Thrp.Time.DL.QCI.8 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 8 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726827 L.Thrp.bits.DL.QCI.9 Downlink traffic volume for PDCP SDUs of services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726828 L.Thrp.Time.DL.QCI.9 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 9 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726833 L.PDCP.Tx.Disc.Trf.SDU.QCI.1 Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 1 in a cell GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526726839 L.PDCP.Tx.Disc.Trf.SDU.QCI.2 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726845 L.PDCP.Tx.Disc.Trf.SDU.QCI.3 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726851 L.PDCP.Tx.Disc.Trf.SDU.QCI.4 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726857 L.PDCP.Tx.Disc.Trf.SDU.QCI.5 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726863 L.PDCP.Tx.Disc.Trf.SDU.QCI.6 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726869 L.PDCP.Tx.Disc.Trf.SDU.QCI.7 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726875 L.PDCP.Tx.Disc.Trf.SDU.QCI.8 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526726881 L.PDCP.Tx.Disc.Trf.SDU.QCI.9 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727045 L.Thrp.bits.UL.QCI.1.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526727046 L.Thrp.bits.UL.QCI.2.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727047 L.Thrp.bits.UL.QCI.3.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727048 L.Thrp.bits.UL.QCI.4.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727049 L.Thrp.bits.UL.QCI.5.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727050 L.Thrp.bits.UL.QCI.6.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727051 L.Thrp.bits.UL.QCI.7.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727052 L.Thrp.bits.UL.QCI.8.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727053 L.Thrp.bits.UL.QCI.9.Max Maximum uplink traffic volume for PDCP PDUs of services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727054 L.Thrp.bits.UL.Max Maximum uplink traffic volume for PDCP PDUs of all services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727055 L.Thrp.bits.DL.QCI.1.Max Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Maximum downlink traffic volume for GSM: None PDCP SDUs of services with the UMTS: None QCI of 1 in a cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526727056 L.Thrp.bits.DL.QCI.2.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of services with the GSM: None QCI of 2 in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727057 L.Thrp.bits.DL.QCI.3.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of services with the GSM: None QCI of 3 in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727058 L.Thrp.bits.DL.QCI.4.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of services with the GSM: None QCI of 4 in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727059 L.Thrp.bits.DL.QCI.5.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of services with the GSM: None QCI of 5 in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727060 L.Thrp.bits.DL.QCI.6.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of services with the GSM: None QCI of 6 in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727061 L.Thrp.bits.DL.QCI.7.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of services with the GSM: None QCI of 7 in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727062 L.Thrp.bits.DL.QCI.8.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of services with the GSM: None QCI of 8 in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727063 L.Thrp.bits.DL.QCI.9.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of services with the GSM: None QCI of 9 in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727064 L.Thrp.bits.DL.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs of all services GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526727354 L.Traffic.DL.SCH.QPSK.TB Number of TBs initially transmitted on the downlink SCH in QPSK modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 LBFD-001005 TDLBFD-002002 TDLBFD-001005 LBFD-00101501 Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM CQI Adjustment 1526727355 L.Traffic.DL.SCH.16QAM.TB Number of TBs initially transmitted on the downlink SCH in 16QAM modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 LBFD-001005 TDLBFD-002002 TDLBFD-001005 LBFD-00101501 Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM CQI Adjustment 1526727356 L.Traffic.DL.SCH.64QAM.TB Number of TBs initially transmitted on the downlink SCH in 64QAM modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 LBFD-001005 TDLBFD-002002 TDLBFD-001005 LBFD-00101501 Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM CQI Adjustment 1526727366 L.Traffic.UL.SCH.QPSK.TB Number of TBs initially transmitted on the uplink SCH in QPSK modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 LBFD-001005 TDLBFD-002002 TDLBFD-001005 Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727367 L.Traffic.UL.SCH.16QAM.TB Number of TBs initially transmitted on the uplink SCH in 16QAM modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 LBFD-001005 TDLBFD-002002 TDLBFD-001005 Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Transport Channel Management Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727368 L.Traffic.UL.SCH.64QAM.TB Number of TBs initially transmitted on the uplink SCH in 64QAM modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 LOFD-001006 TDLBFD-002002 TDLOFD-001006 Transport Channel Management UL 64QAM Transport Channel Management UL 64QAM 1526727378 L.Traffic.User.Avg Average number of users in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002007 TDLBFD-002007 RRC Connection Management RRC Connection Management 1526727388 L.DLPwr.Max Maximum downlink transmit power in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-070205 1526727389 L.DLPwr.Avg Average downlink transmit power in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA 1526727391 L.ChMeas.MIMO.PRB.CL.Rank1 Total number of used downlink PRBs in closed-loop rank 1 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001001 LOFD-001003 LOFD-001060 LOFD-070205 LEOFD-111305 Basic Scheduling Basic Scheduling DL 2x2 MIMO DL 4x2 MIMO DL 4x4 MIMO Adaptive SFN/SDMA Virtual 4T4R 1526727392 L.ChMeas.MIMO.PRB.CL.Rank2 Total number of used downlink PRBs in closed-loop rank 2 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001001 LOFD-001003 LOFD-001060 LOFD-070205 LEOFD-111305 Basic Scheduling Basic Scheduling DL 2x2 MIMO DL 4x2 MIMO DL 4x4 MIMO Adaptive SFN/SDMA Virtual 4T4R 1526727393 L.ChMeas.MIMO.PRB.OL.Rank1 Total number of used downlink PRBs in open-loop rank 1 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001001 LOFD-001003 LOFD-001060 LOFD-070205 TDLOFD-001001 LEOFD-111305 Basic Scheduling Basic Scheduling DL 2x2 MIMO DL 4x2 MIMO DL 4x4 MIMO Adaptive SFN/SDMA DL 2x2 MIMO Virtual 4T4R 1526727394 L.ChMeas.MIMO.PRB.OL.Rank2 Total number of used downlink PRBs in open-loop rank 2 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001001 LOFD-001003 LOFD-001060 LOFD-070205 TDLOFD-001001 LEOFD-111305 Basic Scheduling Basic Scheduling DL 2x2 MIMO DL 4x2 MIMO DL 4x4 MIMO Adaptive SFN/SDMA DL 2x2 MIMO Virtual 4T4R 1526727396 L.ChMeas.CQI.DL.0 Number of wideband CQI reports with the value of 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727397 L.ChMeas.CQI.DL.1 Number of wideband CQI reports with the value of 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727398 L.ChMeas.CQI.DL.2 Number of wideband CQI reports with the value of 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation Counter ID Counter Name Counter Description Feature ID Feature Name 1526727399 L.ChMeas.CQI.DL.3 Number of wideband CQI reports with the value of 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727400 L.ChMeas.CQI.DL.4 Number of wideband CQI reports with the value of 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727401 L.ChMeas.CQI.DL.5 Number of wideband CQI reports with the value of 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727402 L.ChMeas.CQI.DL.6 Number of wideband CQI reports with the value of 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727403 L.ChMeas.CQI.DL.7 Number of wideband CQI reports with the value of 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727404 L.ChMeas.CQI.DL.8 Number of wideband CQI reports with the value of 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727405 L.ChMeas.CQI.DL.9 Number of wideband CQI reports with the value of 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727406 L.ChMeas.CQI.DL.10 Number of wideband CQI reports with the value of 10 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727407 L.ChMeas.CQI.DL.11 Number of wideband CQI reports with the value of 11 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727408 L.ChMeas.CQI.DL.12 Number of wideband CQI reports with the value of 12 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727409 L.ChMeas.CQI.DL.13 Number of wideband CQI reports with the value of 13 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation Counter ID Counter Name Counter Description Feature ID Feature Name 1526727410 L.ChMeas.CQI.DL.14 Number of wideband CQI reports with the value of 14 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727411 L.ChMeas.CQI.DL.15 Number of wideband CQI reports with the value of 15 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526727412 L.ChMeas.PUSCH.MCS.0 Number of times MCS index 0 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727413 L.ChMeas.PUSCH.MCS.1 Number of times MCS index 1 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727414 L.ChMeas.PUSCH.MCS.2 Number of times MCS index 2 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727415 L.ChMeas.PUSCH.MCS.3 Number of times MCS index 3 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727416 L.ChMeas.PUSCH.MCS.4 Number of times MCS index 4 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727417 L.ChMeas.PUSCH.MCS.5 Number of times MCS index 5 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727418 L.ChMeas.PUSCH.MCS.6 Number of times MCS index 6 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727419 L.ChMeas.PUSCH.MCS.7 Number of times MCS index 7 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727420 L.ChMeas.PUSCH.MCS.8 Number of times MCS index 8 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727421 L.ChMeas.PUSCH.MCS.9 Number of times MCS index 9 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727422 L.ChMeas.PUSCH.MCS.10 Number of times MCS index 10 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727423 L.ChMeas.PUSCH.MCS.11 Number of times MCS index 11 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727424 L.ChMeas.PUSCH.MCS.12 Number of times MCS index 12 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727425 L.ChMeas.PUSCH.MCS.13 Number of times MCS index 13 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727426 L.ChMeas.PUSCH.MCS.14 Number of times MCS index 14 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727427 L.ChMeas.PUSCH.MCS.15 Number of times MCS index 15 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727428 L.ChMeas.PUSCH.MCS.16 Multi-mode: None Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name Number of times MCS index 16 is scheduled on the PUSCH GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727429 L.ChMeas.PUSCH.MCS.17 Number of times MCS index 17 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727430 L.ChMeas.PUSCH.MCS.18 Number of times MCS index 18 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727431 L.ChMeas.PUSCH.MCS.19 Number of times MCS index 19 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727432 L.ChMeas.PUSCH.MCS.20 Number of times MCS index 20 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727433 L.ChMeas.PUSCH.MCS.21 Number of times MCS index 21 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727434 L.ChMeas.PUSCH.MCS.22 Number of times MCS index 22 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727435 L.ChMeas.PUSCH.MCS.23 Number of times MCS index 23 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727436 L.ChMeas.PUSCH.MCS.24 Number of times MCS index 24 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727437 L.ChMeas.PUSCH.MCS.25 Multi-mode: None Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name Number of times MCS index 25 is scheduled on the PUSCH GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LBFD-001005 TDLBFD-001005 LOFD-001006 TDLOFD-001006 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM UL 64QAM UL 64QAM 1526727438 L.ChMeas.PUSCH.MCS.26 Number of times MCS index 26 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LBFD-001005 TDLBFD-001005 LOFD-001006 TDLOFD-001006 Basic Scheduling Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM UL 64QAM UL 64QAM 1526727439 L.ChMeas.PUSCH.MCS.27 Number of times MCS index 27 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LBFD-001005 TDLBFD-001005 LOFD-001006 TDLOFD-001006 Basic Scheduling Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM UL 64QAM UL 64QAM 1526727440 L.ChMeas.PUSCH.MCS.28 Number of times MCS index 28 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LBFD-001005 TDLBFD-001005 LOFD-001006 TDLOFD-001006 Basic Scheduling Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM UL 64QAM UL 64QAM 1526727441 L.ChMeas.PUSCH.MCS.29 Number of times MCS index 29 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LBFD-001005 TDLBFD-001005 LOFD-001006 TDLOFD-001006 Basic Scheduling Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM UL 64QAM UL 64QAM 1526727442 L.ChMeas.PUSCH.MCS.30 Number of times MCS index 30 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LBFD-001005 TDLBFD-001005 LOFD-001006 TDLOFD-001006 Basic Scheduling Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM UL 64QAM UL 64QAM 1526727443 L.ChMeas.PUSCH.MCS.31 Number of times MCS index 31 is scheduled on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LBFD-001005 TDLBFD-001005 LOFD-001006 TDLOFD-001006 Basic Scheduling Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM UL 64QAM UL 64QAM 1526727444 L.ChMeas.PDSCH.MCS.0 Number of times MCS index 0 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727445 L.ChMeas.PDSCH.MCS.1 Number of times MCS index 1 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727446 L.ChMeas.PDSCH.MCS.2 Number of times MCS index 2 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727447 L.ChMeas.PDSCH.MCS.3 Number of times MCS index 3 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727448 L.ChMeas.PDSCH.MCS.4 Number of times MCS index 4 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727449 L.ChMeas.PDSCH.MCS.5 Number of times MCS index 5 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727450 L.ChMeas.PDSCH.MCS.6 Number of times MCS index 6 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727451 L.ChMeas.PDSCH.MCS.7 Number of times MCS index 7 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727452 L.ChMeas.PDSCH.MCS.8 Number of times MCS index 8 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727453 L.ChMeas.PDSCH.MCS.9 Number of times MCS index 9 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727454 L.ChMeas.PDSCH.MCS.10 Number of times MCS index 10 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727455 L.ChMeas.PDSCH.MCS.11 Number of times MCS index 11 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727456 L.ChMeas.PDSCH.MCS.12 Number of times MCS index 12 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727457 L.ChMeas.PDSCH.MCS.13 Number of times MCS index 13 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727458 L.ChMeas.PDSCH.MCS.14 Number of times MCS index 14 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727459 L.ChMeas.PDSCH.MCS.15 Number of times MCS index 15 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727460 L.ChMeas.PDSCH.MCS.16 Number of times MCS index 16 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727461 L.ChMeas.PDSCH.MCS.17 Number of times MCS index 17 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727462 L.ChMeas.PDSCH.MCS.18 Number of times MCS index 18 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727463 L.ChMeas.PDSCH.MCS.19 Number of times MCS index 19 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727464 L.ChMeas.PDSCH.MCS.20 Number of times MCS index 20 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727465 L.ChMeas.PDSCH.MCS.21 Number of times MCS index 21 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727466 L.ChMeas.PDSCH.MCS.22 Number of times MCS index 22 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727467 L.ChMeas.PDSCH.MCS.23 Number of times MCS index 23 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727468 L.ChMeas.PDSCH.MCS.24 Number of times MCS index 24 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727469 L.ChMeas.PDSCH.MCS.25 Number of times MCS index 25 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727470 L.ChMeas.PDSCH.MCS.26 Number of times MCS index 26 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727471 L.ChMeas.PDSCH.MCS.27 Number of times MCS index 27 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727472 L.ChMeas.PDSCH.MCS.28 Number of times MCS index 28 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727473 L.ChMeas.PDSCH.MCS.29 Number of times MCS index 29 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727474 L.ChMeas.PDSCH.MCS.30 Number of times MCS index 30 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727475 L.ChMeas.PDSCH.MCS.31 Number of times MCS index 31 is scheduled on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM 1526727483 L.ChMeas.PRB.PUCCH.Avg Average number of used PRBs over Multi-mode: None the PUCCH GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526727849 L.Thrp.bits.UL.PLMN.QCI.1 Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526727850 L.Thrp.Time.UL.PLMN.QCI.1 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526727852 L.Thrp.bits.UL.PLMN.QCI.2 Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 2 in a cell GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526727889 L.PDCP.Tx.TotRev.Trf.SDU.QCI.1 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727891 L.PDCP.Tx.TotRev.Trf.SDU.QCI.2 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727893 L.PDCP.Tx.TotRev.Trf.SDU.QCI.3 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727895 L.PDCP.Tx.TotRev.Trf.SDU.QCI.4 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727897 L.PDCP.Tx.TotRev.Trf.SDU.QCI.5 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727899 L.PDCP.Tx.TotRev.Trf.SDU.QCI.6 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727901 L.PDCP.Tx.TotRev.Trf.SDU.QCI.7 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727903 L.PDCP.Tx.TotRev.Trf.SDU.QCI.8 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 LBFD-002025 TDLBFD-002025 Basic Scheduling 1526727905 L.PDCP.Tx.TotRev.Trf.SDU.QCI.9 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727907 L.Traffic.DL.PktDelay.Time.QCI.1 Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727908 L.Traffic.DL.PktDelay.Num.QCI.1 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727910 L.Traffic.DL.PktDelay.Time.QCI.2 Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727911 L.Traffic.DL.PktDelay.Num.QCI.2 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727913 L.Traffic.DL.PktDelay.Time.QCI.3 Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727914 L.Traffic.DL.PktDelay.Num.QCI.3 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727916 L.Traffic.DL.PktDelay.Time.QCI.4 Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727917 L.Traffic.DL.PktDelay.Num.QCI.4 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling L.Traffic.DL.PktDelay.Time.QCI.5 Counter ID Counter Name 1526727919 Counter Description Feature ID Feature Name Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727920 L.Traffic.DL.PktDelay.Num.QCI.5 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727922 L.Traffic.DL.PktDelay.Time.QCI.6 Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727923 L.Traffic.DL.PktDelay.Num.QCI.6 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727925 L.Traffic.DL.PktDelay.Time.QCI.7 Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727926 L.Traffic.DL.PktDelay.Num.QCI.7 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727928 L.Traffic.DL.PktDelay.Time.QCI.8 Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727929 L.Traffic.DL.PktDelay.Num.QCI.8 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727931 L.Traffic.DL.PktDelay.Time.QCI.9 Total processing delay of downlink PDCP SDUs for DRB services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727932 L.Traffic.DL.PktDelay.Num.QCI.9 Number of successfully transmitted downlink PDCP SDUs for DRB services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 Radio Bearer Management Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526727934 L.Traffic.DL.PktUuLoss.Loss.QCI.1 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 1 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727935 L.Traffic.DL.PktUuLoss.Tot.QCI.1 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 1 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727937 L.Traffic.DL.PktUuLoss.Loss.QCI.2 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 2 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727938 L.Traffic.DL.PktUuLoss.Tot.QCI.2 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 2 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727940 L.Traffic.DL.PktUuLoss.Loss.QCI.3 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 3 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727941 L.Traffic.DL.PktUuLoss.Tot.QCI.3 Number of downlink transmitted PDCP SDUs for services carried on DRBs with a QCI of 3 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727943 L.Traffic.DL.PktUuLoss.Loss.QCI.4 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 4 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727944 L.Traffic.DL.PktUuLoss.Tot.QCI.4 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 4 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727946 L.Traffic.DL.PktUuLoss.Loss.QCI.5 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 5 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling L.Traffic.DL.PktUuLoss.Tot.QCI.5 Counter ID Counter Name 1526727947 Counter Description Feature ID Feature Name Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 5 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727949 L.Traffic.DL.PktUuLoss.Loss.QCI.6 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 6 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727950 L.Traffic.DL.PktUuLoss.Tot.QCI.6 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 6 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727952 L.Traffic.DL.PktUuLoss.Loss.QCI.7 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 7 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727953 L.Traffic.DL.PktUuLoss.Tot.QCI.7 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 7 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727955 L.Traffic.DL.PktUuLoss.Loss.QCI.8 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 8 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727956 L.Traffic.DL.PktUuLoss.Tot.QCI.8 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 8 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727958 L.Traffic.DL.PktUuLoss.Loss.QCI.9 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 9 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727959 L.Traffic.DL.PktUuLoss.Tot.QCI.9 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 9 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727961 L.Traffic.UL.PktLoss.Loss.QCI.1 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 Radio Bearer Management Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526727962 L.Traffic.UL.PktLoss.Tot.QCI.1 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727964 L.Traffic.UL.PktLoss.Loss.QCI.2 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727965 L.Traffic.UL.PktLoss.Tot.QCI.2 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727967 L.Traffic.UL.PktLoss.Loss.QCI.3 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727968 L.Traffic.UL.PktLoss.Tot.QCI.3 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727970 L.Traffic.UL.PktLoss.Loss.QCI.4 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727971 L.Traffic.UL.PktLoss.Tot.QCI.4 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727973 L.Traffic.UL.PktLoss.Loss.QCI.5 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727974 L.Traffic.UL.PktLoss.Tot.QCI.5 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling L.Traffic.UL.PktLoss.Loss.QCI.6 Counter ID Counter Name 1526727976 Counter Description Feature ID Feature Name Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727977 L.Traffic.UL.PktLoss.Tot.QCI.6 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727979 L.Traffic.UL.PktLoss.Loss.QCI.7 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727980 L.Traffic.UL.PktLoss.Tot.QCI.7 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727982 L.Traffic.UL.PktLoss.Loss.QCI.8 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727983 L.Traffic.UL.PktLoss.Tot.QCI.8 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727985 L.Traffic.UL.PktLoss.Loss.QCI.9 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526727986 L.Traffic.UL.PktLoss.Tot.QCI.9 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728027 L.Thrp.Time.UL.PLMN.QCI.2 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier Counter ID Counter Name Counter Description Feature ID Feature Name RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728029 L.Thrp.bits.UL.PLMN.QCI.3 Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728030 L.Thrp.Time.UL.PLMN.QCI.3 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728032 L.Thrp.bits.UL.PLMN.QCI.4 Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728033 L.Thrp.Time.UL.PLMN.QCI.4 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728035 L.Thrp.bits.UL.PLMN.QCI.5 Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728036 L.Thrp.Time.UL.PLMN.QCI.5 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728038 L.Thrp.bits.UL.PLMN.QCI.6 Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728039 L.Thrp.Time.UL.PLMN.QCI.6 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728041 L.Thrp.bits.UL.PLMN.QCI.7 Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728042 L.Thrp.Time.UL.PLMN.QCI.7 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728044 L.Thrp.bits.UL.PLMN.QCI.8 Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728045 L.Thrp.Time.UL.PLMN.QCI.8 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728047 L.Thrp.bits.UL.PLMN.QCI.9 Total uplink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728048 L.Thrp.Time.UL.PLMN.QCI.9 Receive duration of uplink PDCP SDUs for a specific operator for services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728050 L.Thrp.bits.DL.PLMN.QCI.1 Total downlink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728051 L.Thrp.Time.DL.PLMN.QCI.1 Transmit duration of downlink PDCP Multi-mode: None SDUs for a specific operator for GSM: None services with the QCI of 1 in a cell UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728053 L.Thrp.bits.DL.PLMN.QCI.2 Total downlink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728054 L.Thrp.Time.DL.PLMN.QCI.2 Transmit duration of downlink PDCP Multi-mode: None SDUs for a specific operator for GSM: None services with the QCI of 2 in a cell UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728056 L.Thrp.bits.DL.PLMN.QCI.3 Total downlink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 3 in a cell Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728057 L.Thrp.Time.DL.PLMN.QCI.3 Transmit duration of downlink PDCP Multi-mode: None SDUs for a specific operator for GSM: None services with the QCI of 3 in a cell UMTS: None LTE: LBFD-002008 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728059 L.Thrp.bits.DL.PLMN.QCI.4 Total downlink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728060 L.Thrp.Time.DL.PLMN.QCI.4 Transmit duration of downlink PDCP Multi-mode: None SDUs in a cell for a specific operator GSM: None for services with the QCI of 4 in a UMTS: None cell LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728062 L.Thrp.bits.DL.PLMN.QCI.5 Total downlink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728063 L.Thrp.Time.DL.PLMN.QCI.5 Transmit duration of downlink PDCP Multi-mode: None SDUs for a specific operator for GSM: None services with the QCI of 5 in a cell UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728065 L.Thrp.bits.DL.PLMN.QCI.6 Total downlink traffic volume for PDCP SDUs for a specific operator Radio Bearer Management Multi-mode: None GSM: None UMTS: None Counter ID Counter Name Counter Description Feature ID Feature Name for services with the QCI of 6 in a cell LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728066 L.Thrp.Time.DL.PLMN.QCI.6 Transmit duration of downlink PDCP Multi-mode: None SDUs for a specific operator for GSM: None services with the QCI of 6 in a cell UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728068 L.Thrp.bits.DL.PLMN.QCI.7 Total downlink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728069 L.Thrp.Time.DL.PLMN.QCI.7 Transmit duration of downlink PDCP Multi-mode: None SDUs for a specific operator for GSM: None services with the QCI of 7 in a cell UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728071 L.Thrp.bits.DL.PLMN.QCI.8 Total downlink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 8 in a cell Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728072 L.Thrp.Time.DL.PLMN.QCI.8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Transmit duration of downlink PDCP GSM: None SDUs for a specific operator for UMTS: None services with the QCI of 8 in a cell LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728074 L.Thrp.bits.DL.PLMN.QCI.9 Total downlink traffic volume for PDCP SDUs for a specific operator for services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728075 L.Thrp.Time.DL.PLMN.QCI.9 Transmit duration of downlink PDCP Multi-mode: None SDUs for a specific operator for GSM: None services with the QCI of 9 in a cell UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728174 L.ChMeas.MIMO.PRB.CL.Rank3 Total number of used downlink PRBs in closed-loop rank 3 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001060 LOFD-070205 LEOFD-111305 Basic Scheduling Basic Scheduling DL 4x4 MIMO Adaptive SFN/SDMA Virtual 4T4R 1526728175 L.ChMeas.MIMO.PRB.CL.Rank4 Total number of used downlink PRBs in closed-loop rank 4 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001060 LOFD-070205 LEOFD-111305 Basic Scheduling Basic Scheduling DL 4x4 MIMO Adaptive SFN/SDMA Virtual 4T4R 1526728176 L.ChMeas.MIMO.PRB.OL.Rank3 Total number of used downlink PRBs in open-loop rank 3 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001060 LOFD-070205 LEOFD-111305 Basic Scheduling Basic Scheduling DL 4x4 MIMO Adaptive SFN/SDMA Virtual 4T4R 1526728177 L.ChMeas.MIMO.PRB.OL.Rank4 Total number of used downlink PRBs in open-loop rank 4 mode Multi-mode: None GSM: None Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001060 LOFD-070205 LEOFD-111305 DL 4x4 MIMO Adaptive SFN/SDMA Virtual 4T4R 1526728180 L.Traffic.DL.SCH.QPSK.ErrTB.Ibler Number of downlink error TBs after initial transmission in QPSK modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 TDLBFD-002002 LBFD-00101501 Transport Channel Management Transport Channel Management CQI Adjustment 1526728182 L.Traffic.DL.SCH.16QAM.ErrTB.Ibler Number of downlink error TBs after initial transmission in 16QAM modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 TDLBFD-002002 LBFD-00101501 Transport Channel Management Transport Channel Management CQI Adjustment 1526728184 L.Traffic.DL.SCH.64QAM.ErrTB.Ibler Number of downlink error TBs after initial transmission in 64QAM modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 TDLBFD-002002 LBFD-00101501 Transport Channel Management Transport Channel Management CQI Adjustment 1526728186 L.Traffic.UL.SCH.QPSK.ErrTB.Ibler Number of uplink error TBs after initial transmission in QPSK modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 TDLBFD-002002 Transport Channel Management Transport Channel Management 1526728188 L.Traffic.UL.SCH.16QAM.ErrTB.Ibler Number of uplink error TBs after initial transmission in 16QAM modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 TDLBFD-002002 Transport Channel Management Transport Channel Management 1526728190 L.Traffic.UL.SCH.64QAM.ErrTB.Ibler Number of uplink error TBs after initial transmission in 64QAM modulation mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002002 TDLBFD-002002 Transport Channel Management Transport Channel Management 1526728232 L.Thrp.Time.Cell.DL Total duration of downlink data transmission in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728233 L.Thrp.Time.Cell.UL Total duration of uplink data transmission in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728234 L.E-RAB.SessionTime.QCI1 Duration of data transmission for services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728235 L.E-RAB.SessionTime.QCI2 Duration of data transmission for services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 1526728236 L.E-RAB.SessionTime.QCI3 Duration of data transmission for services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728237 L.E-RAB.SessionTime.QCI4 Duration of data transmission for services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728238 L.E-RAB.SessionTime.QCI5 Duration of data transmission for services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728239 L.E-RAB.SessionTime.QCI6 Duration of data transmission for services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728240 L.E-RAB.SessionTime.QCI7 Duration of data transmission for services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728241 L.E-RAB.SessionTime.QCI8 Duration of data transmission for services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728242 L.E-RAB.SessionTime.QCI9 Duration of data transmission for services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728243 L.E-RAB.SessionTime.UE Total duration of UE data transmission time in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728259 L.Thrp.bits.UL Total uplink traffic volume for PDCP PDUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728260 L.Thrp.Time.UL Total receive duration of uplink PDCP PDUs in a cell Multi-mode: None GSM: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526728261 L.Thrp.bits.DL Total downlink traffic volume for PDCP SDUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728262 L.Thrp.Time.DL Total transmit duration of downlink PDCP SDUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728263 L.Thrp.bits.UL.PLMN Total uplink traffic volume for PDCP Multi-mode: None SDUs for a specific operator in a cell GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728264 L.Thrp.Time.UL.PLMN Total receive duration of uplink PDCP SDUs for a specific operator in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728265 L.Thrp.bits.DL.PLMN Total downlink traffic volume for PDCP SDUs for a specific operator in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728266 L.Thrp.Time.DL.PLMN Total transmit duration of downlink PDCP SDUs for a specific operator in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526728293 L.RBUsedOwn.DL.PLMN Average number of own PDSCH PRBs used by a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001036 LOFD-001037 LOFD-070205 TDLOFD-001036 TDLOFD-001037 LOFD-070206 LEOFD-111305 Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Adaptive SFN/SDMA RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing Virtual 4T4R 1526728294 L.RBUsedOwn.UL.PLMN Average number of own PUSCH PRBs used by a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001036 LOFD-001037 LOFD-070205 TDLOFD-001036 TDLOFD-001037 LOFD-070206 Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Adaptive SFN/SDMA RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526728295 L.RBUsedOther.DL.PLMN Average number of other operators' PDSCH PRBs used by a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001036 LOFD-001037 LOFD-070205 TDLOFD-001036 TDLOFD-001037 LOFD-070206 LEOFD-111305 Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Adaptive SFN/SDMA RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing Virtual 4T4R 1526728296 L.RBUsedOther.UL.PLMN Average number of other operators' PUSCH PRBs used by a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001036 LOFD-001037 LOFD-070205 TDLOFD-001036 TDLOFD-001037 LOFD-070206 Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Adaptive SFN/SDMA RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526728298 L.UL.Interference.Avg Average uplink interference and Multi-mode: None noise received by each PRB in a cell GSM: None UMTS: None LTE: LBFD-002003 TDLBFD-002003 LOFD-070205 Physical Channel Management Physical Channel Management Adaptive SFN/SDMA 1526728299 L.ChMeas.PDCCH.SymNum.1 Number of times the PDCCH occupies one symbol in a measurement period Multi-mode: None GSM: None UMTS: None LTE: LBFD-002003 TDLBFD-002003 Physical Channel Management Physical Channel Management 1526728303 L.ChMeas.CCE.CommUsed Number of PDCCH CCEs used for common DCI Multi-mode: None GSM: None Physical Channel Management Counter ID Counter Name Counter Description Feature ID Feature Name UMTS: None LTE: LBFD-002003 TDLBFD-002003 Physical Channel Management 1526728304 L.ChMeas.CCE.ULUsed Number of PDCCH CCEs used for uplink DCI in a measurement period Multi-mode: None GSM: None UMTS: None LTE: LBFD-002003 TDLBFD-002003 Physical Channel Management Physical Channel Management 1526728305 L.ChMeas.CCE.DLUsed Number of PDCCH CCEs used for downlink DCI in a measurement period Multi-mode: None GSM: None UMTS: None LTE: LBFD-002003 TDLBFD-002003 Physical Channel Management Physical Channel Management 1526728433 L.ChMeas.PRB.DL.Avail Number of available downlink PRBs Multi-mode: MRFD090202 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 LOFD-070205 TDLOFD-001075 LEOFD-111305 GSM and LTE FDD Dynamic Spectrum Sharing(LTE FDD) LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz Adaptive SFN/SDMA SFN Virtual 4T4R 1526728434 L.ChMeas.PRB.UL.Avail Number of available uplink PRBs Multi-mode: MRFD090202 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 LOFD-070205 TDLOFD-001075 GSM and LTE FDD Dynamic Spectrum Sharing(LTE FDD) LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz Adaptive SFN/SDMA SFN 1526728483 L.ChMeas.PRB.UL.FSS.Avg Average number of PRBs allocated for uplink frequency selective scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728484 L.ChMeas.PRB.DL.FSS.Avg Average number of PRBs allocated for downlink frequency selective scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LEOFD-111305 Basic Scheduling Basic Scheduling Virtual 4T4R 1526728545 L.ChMeas.PRB.UL.PreSch.Used.Avg Average number of PRBs allocated for uplink pre-scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-001059 TDLOFD-001059 Basic Scheduling Basic Scheduling UL Pre-allocation Based on SPID UL Pre-allocation Based on SPID 1526728564 L.Thrp.bits.DL.CAUser Total traffic volume for PDCP SDUs sent to activated CA UEs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728565 L.Thrp.Time.DL.CAUser Total duration for activated CA UEs transmitting downlink data at the PDCP layer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728566 L.ChMeas.PRB.UL.MCS.0 Number of PRBs on the PUSCH using MCS index 0 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name 1526728567 L.ChMeas.PRB.UL.MCS.1 Number of PRBs on the PUSCH using MCS index 1 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728568 L.ChMeas.PRB.UL.MCS.2 Number of PRBs on the PUSCH using MCS index 2 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728569 L.ChMeas.PRB.UL.MCS.3 Number of PRBs on the PUSCH using MCS index 3 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728570 L.ChMeas.PRB.UL.MCS.4 Number of PRBs on the PUSCH using MCS index 4 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728571 L.ChMeas.PRB.UL.MCS.5 Number of PRBs on the PUSCH using MCS index 5 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728572 L.ChMeas.PRB.UL.MCS.6 Number of PRBs on the PUSCH using MCS index 6 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728573 L.ChMeas.PRB.UL.MCS.7 Number of PRBs on the PUSCH using MCS index 7 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728574 L.ChMeas.PRB.UL.MCS.8 Number of PRBs on the PUSCH using MCS index 8 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728575 L.ChMeas.PRB.UL.MCS.9 Number of PRBs on the PUSCH using MCS index 9 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728576 L.ChMeas.PRB.UL.MCS.10 Number of PRBs on the PUSCH using MCS index 10 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728577 L.ChMeas.PRB.UL.MCS.11 Number of PRBs on the PUSCH using MCS index 11 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728578 L.ChMeas.PRB.UL.MCS.12 Number of PRBs on the PUSCH using MCS index 12 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728579 L.ChMeas.PRB.UL.MCS.13 Number of PRBs on the PUSCH using MCS index 13 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name 1526728580 L.ChMeas.PRB.UL.MCS.14 Number of PRBs on the PUSCH using MCS index 14 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728581 L.ChMeas.PRB.UL.MCS.15 Number of PRBs on the PUSCH using MCS index 15 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728582 L.ChMeas.PRB.UL.MCS.16 Number of PRBs on the PUSCH using MCS index 16 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728583 L.ChMeas.PRB.UL.MCS.17 Number of PRBs on the PUSCH using MCS index 17 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728584 L.ChMeas.PRB.UL.MCS.18 Number of PRBs on the PUSCH using MCS index 18 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728585 L.ChMeas.PRB.UL.MCS.19 Number of PRBs on the PUSCH using MCS index 19 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728586 L.ChMeas.PRB.UL.MCS.20 Number of PRBs on the PUSCH using MCS index 20 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728587 L.ChMeas.PRB.UL.MCS.21 Number of PRBs on the PUSCH using MCS index 21 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728588 L.ChMeas.PRB.UL.MCS.22 Number of PRBs on the PUSCH using MCS index 22 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728589 L.ChMeas.PRB.UL.MCS.23 Number of PRBs on the PUSCH using MCS index 23 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728590 L.ChMeas.PRB.UL.MCS.24 Number of PRBs on the PUSCH using MCS index 24 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728591 L.ChMeas.PRB.UL.MCS.25 Number of PRBs on the PUSCH using MCS index 25 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728592 L.ChMeas.PRB.UL.MCS.26 Number of PRBs on the PUSCH using MCS index 26 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name 1526728593 L.ChMeas.PRB.UL.MCS.27 Number of PRBs on the PUSCH using MCS index 27 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728594 L.ChMeas.PRB.UL.MCS.28 Number of PRBs on the PUSCH using MCS index 28 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728595 L.ChMeas.PRB.UL.MCS.29 Number of PRBs on the PUSCH using MCS index 29 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728596 L.ChMeas.PRB.UL.MCS.30 Number of PRBs on the PUSCH using MCS index 30 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728597 L.ChMeas.PRB.UL.MCS.31 Number of PRBs on the PUSCH using MCS index 31 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728598 L.Traffic.UL.SCH.bits.Max Maximum uplink traffic volume for MAC TBs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728599 L.ChMeas.PRB.DL.RANK1.MCS.0 Number of PRBs on the PDSCH in rank 1 mode using MCS index 0 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-001005 LOFD-001001 LOFD-001003 LOFD-001060 TDLBFD-001005 TDLOFD-001001 Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 2x2 MIMO DL 4x2 MIMO DL 4x4 MIMO Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 2x2 MIMO 1526728605 L.ChMeas.PRB.DL.RANK1.MCS.6 Number of PRBs on the PDSCH in rank 1 mode using MCS index 6 for scheduling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-001005 LOFD-001001 LOFD-001003 LOFD-001060 TDLBFD-001005 TDLOFD-001001 Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 2x2 MIMO DL 4x2 MIMO DL 4x4 MIMO Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 2x2 MIMO 1526728627 L.ChMeas.PRB.DL.RANK1.MCS.28 Number of PRBs on the PDSCH in Multi-mode: None rank 1 mode using MCS index 28 for GSM: None scheduling in a cell UMTS: None LTE: LBFD-001005 LOFD-001001 LOFD-001003 LOFD-001060 TDLBFD-001005 TDLOFD-001001 Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 2x2 MIMO DL 4x2 MIMO DL 4x4 MIMO Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 2x2 MIMO 1526728663 L.Traffic.DL.SCH.bits.Max Maximum downlink traffic volume for Multi-mode: None MAC TBs in a cell GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526728762 L.ChMeas.PRB.UL.DrbUsed.Avg Average number of PRBs used by PUSCH DRBs Basic Scheduling Basic Scheduling Adaptive SFN/SDMA Multi-mode: None GSM: None UMTS: None Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 1526728763 L.ChMeas.PRB.DL.DrbUsed.Avg Average number of PRBs used by PDSCH DRBs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 LEOFD-111305 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA Virtual 4T4R 1526728764 L.ChMeas.PRB.PUSCH.Avg Average number of used PUSCH PRBs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA 1526728765 L.ChMeas.CCE.Avail Number of available PDCCH CCEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002003 TDLBFD-002003 Physical Channel Management Physical Channel Management 1526728774 L.RRC.ConnSetup.TimeAvg Average RRC connection setup duration Multi-mode: None GSM: None UMTS: None LTE: LBFD-002007 TDLBFD-002007 RRC Connection Management RRC Connection Management 1526728776 L.E-RAB.Est.TimeAvg Average E-RAB setup duration in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management 1526728881 L.ChMeas.BF.PRB.OL.Rank1 Total number of used downlink PRBs in BF rank 1 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLOFD-001049 TDLOFD-001061 LEOFD-111305 Basic Scheduling Basic Scheduling Single Streaming Beamforming Dual Streaming Beamforming Virtual 4T4R 1526728882 L.ChMeas.BF.PRB.OL.Rank2 Total number of used downlink PRBs in BF rank 2 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLOFD-001049 TDLOFD-001061 LEOFD-111305 Basic Scheduling Basic Scheduling Single Streaming Beamforming Dual Streaming Beamforming Virtual 4T4R 1526728969 L.Traffic.ActiveUser.DL.Avg Average number of activated UEs in Multi-mode: None downlink GSM: None UMTS: None LTE: LBFD-002007 TDLBFD-002007 RRC Connection Management RRC Connection Management 1526728997 L.Thrp.Time.Cell.DL.HighPrecision Total duration of downlink data transmission in a cell (with the precision of 1 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526728998 L.Thrp.Time.Cell.UL.HighPrecision Total duration of uplink data transmission in a cell (with the precision of 1 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name 1526729005 L.Thrp.bits.DL.LastTTI Downlink traffic volume sent in the last TTI for PDCP SDUs before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729006 L.Thrp.bits.DL.LastTTI.QCI.1 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 1 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729007 L.Thrp.bits.DL.LastTTI.QCI.2 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 2 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729008 L.Thrp.bits.DL.LastTTI.QCI.3 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 3 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729009 L.Thrp.bits.DL.LastTTI.QCI.4 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 4 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729010 L.Thrp.bits.DL.LastTTI.QCI.5 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 5 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729011 L.Thrp.bits.DL.LastTTI.QCI.6 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 6 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729012 L.Thrp.bits.DL.LastTTI.QCI.7 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 7 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729013 L.Thrp.bits.DL.LastTTI.QCI.8 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 8 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729014 L.Thrp.bits.DL.LastTTI.QCI.9 Downlink traffic volume sent in the last TTI for PDCP SDUs of services with the QCI 9 before the buffer is empty Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 Radio Bearer Management Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526729015 L.Thrp.Time.DL.RmvLastTTI Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729016 L.Thrp.Time.DL.RmvLastTTI.QCI.1 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 1 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729017 L.Thrp.Time.DL.RmvLastTTI.QCI.2 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 2 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729018 L.Thrp.Time.DL.RmvLastTTI.QCI.3 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 3 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729019 L.Thrp.Time.DL.RmvLastTTI.QCI.4 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 4 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729020 L.Thrp.Time.DL.RmvLastTTI.QCI.5 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 5 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729021 L.Thrp.Time.DL.RmvLastTTI.QCI.6 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 6 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729022 L.Thrp.Time.DL.RmvLastTTI.QCI.7 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 7 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729023 L.Thrp.Time.DL.RmvLastTTI.QCI.8 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 8 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling L.Thrp.Time.DL.RmvLastTTI.QCI.9 Counter ID Counter Name 1526729024 Counter Description Feature ID Feature Name Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 9 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729025 L.Thrp.bits.DL.LastTTI.PLMN Downlink traffic volume sent in the last TTI before the buffer is empty for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729026 L.Thrp.bits.DL.LastTTI.PLMN.QCI.1 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 1 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729027 L.Thrp.bits.DL.LastTTI.PLMN.QCI.2 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 2 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729028 L.Thrp.bits.DL.LastTTI.PLMN.QCI.3 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 3 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729029 L.Thrp.bits.DL.LastTTI.PLMN.QCI.4 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 4 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729030 L.Thrp.bits.DL.LastTTI.PLMN.QCI.5 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 5 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729031 L.Thrp.bits.DL.LastTTI.PLMN.QCI.6 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 6 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729032 L.Thrp.bits.DL.LastTTI.PLMN.QCI.7 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 7 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729033 L.Thrp.bits.DL.LastTTI.PLMN.QCI.8 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 8 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729034 L.Thrp.bits.DL.LastTTI.PLMN.QCI.9 Downlink traffic volume sent in the last TTI before the buffer is empty for services with the QCI 9 for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 Radio Bearer Management RAN Sharing with Common Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729035 L.Thrp.Time.DL.RmvLastTTI.PLMN Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for a specific operator UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729036 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.1 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 1 for UMTS: None a specific operator LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729037 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.2 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 2 for UMTS: None a specific operator LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729038 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.3 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 3 for UMTS: None a specific operator LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729039 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.4 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None UMTS: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name empty for services with the QCI 4 for LTE: LBFD-002008 a specific operator LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729040 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.5 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 5 for UMTS: None a specific operator LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729041 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.6 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 6 for UMTS: None a specific operator LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729042 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.7 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 7 for UMTS: None a specific operator LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729043 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.8 Data transmit duration except the Multi-mode: None last TTI before the downlink buffer is GSM: None empty for services with the QCI 8 for UMTS: None a specific operator LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729044 L.Thrp.Time.DL.RmvLastTTI.PLMN.QCI.9 Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Data transmit duration except the GSM: None last TTI before the downlink buffer is UMTS: None empty for services with the QCI 9 for LTE: LBFD-002008 a specific operator LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729049 L.Thrp.bits.UE.UL.LastTTI Traffic volume of uplink PDCP PDUs Multi-mode: None received in the last TTI before the GSM: None UE buffer is empty UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729050 L.Thrp.Time.UE.UL.RmvLastTTI Uplink data transmit duration except the last TTI before the UE buffer is empty Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729051 L.Thrp.bits.UE.UL.LastTTI.PLMN Traffic volume of uplink PDCP PDUs Multi-mode: None received in the last TTI before the GSM: None UE buffer is empty for a specific UMTS: None operator LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526729052 L.Thrp.Time.UE.UL.RmvLastTTI.PLMN Uplink data transmit duration except the last TTI before the UE buffer is empty for a specific operator Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526729056 L.Thrp.DL.BitRate.Samp.Index0 Number of samples with the downlink throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729057 L.Thrp.DL.BitRate.Samp.Index1 Number of samples with the downlink throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 1526729058 L.Thrp.DL.BitRate.Samp.Index2 Number of samples with the downlink throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729059 L.Thrp.DL.BitRate.Samp.Index3 Number of samples with the downlink throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729060 L.Thrp.DL.BitRate.Samp.Index4 Number of samples with the downlink throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729061 L.Thrp.DL.BitRate.Samp.Index5 Number of samples with the downlink throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729062 L.Thrp.DL.BitRate.Samp.Index6 Number of samples with the downlink throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729063 L.Thrp.DL.BitRate.Samp.Index7 Number of samples with the downlink throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729064 L.Thrp.DL.BitRate.Samp.Index8 Number of samples with the downlink throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729065 L.Thrp.DL.BitRate.Samp.Index9 Number of samples with the downlink throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729066 L.Thrp.DL.BitRate.QCI1.Samp.Index0 Number of samples with the downlink QCI-1 service throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729067 L.Thrp.DL.BitRate.QCI1.Samp.Index1 Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Number of samples with the downlink QCI-1 service throughput ranging within index 1 GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526729068 L.Thrp.DL.BitRate.QCI1.Samp.Index2 Number of samples with the downlink QCI-1 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729069 L.Thrp.DL.BitRate.QCI1.Samp.Index3 Number of samples with the downlink QCI-1 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729070 L.Thrp.DL.BitRate.QCI1.Samp.Index4 Number of samples with the downlink QCI-1 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729071 L.Thrp.DL.BitRate.QCI1.Samp.Index5 Number of samples with the downlink QCI-1 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729072 L.Thrp.DL.BitRate.QCI1.Samp.Index6 Number of samples with the downlink QCI-1 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729073 L.Thrp.DL.BitRate.QCI1.Samp.Index7 Number of samples with the downlink QCI-1 service throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729074 L.Thrp.DL.BitRate.QCI1.Samp.Index8 Number of samples with the downlink QCI-1 service throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729075 L.Thrp.DL.BitRate.QCI1.Samp.Index9 Number of samples with the downlink QCI-1 service throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729076 L.Thrp.DL.BitRate.QCI2.Samp.Index0 Number of samples with the downlink QCI-2 service throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526729077 L.Thrp.DL.BitRate.QCI2.Samp.Index1 Number of samples with the downlink QCI-2 service throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729078 L.Thrp.DL.BitRate.QCI2.Samp.Index2 Number of samples with the downlink QCI-2 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729079 L.Thrp.DL.BitRate.QCI2.Samp.Index3 Number of samples with the downlink QCI-2 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729080 L.Thrp.DL.BitRate.QCI2.Samp.Index4 Number of samples with the downlink QCI-2 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729081 L.Thrp.DL.BitRate.QCI2.Samp.Index5 Number of samples with the downlink QCI-2 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729082 L.Thrp.DL.BitRate.QCI2.Samp.Index6 Number of samples with the downlink QCI-2 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729083 L.Thrp.DL.BitRate.QCI2.Samp.Index7 Number of samples with the downlink QCI-2 service throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729084 L.Thrp.DL.BitRate.QCI2.Samp.Index8 Number of samples with the downlink QCI-2 service throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729085 L.Thrp.DL.BitRate.QCI2.Samp.Index9 Number of samples with the downlink QCI-2 service throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729086 L.Thrp.DL.BitRate.QCI3.Samp.Index0 Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Number of samples with the downlink QCI-3 service throughput ranging within index 0 GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526729087 L.Thrp.DL.BitRate.QCI3.Samp.Index1 Number of samples with the downlink QCI-3 service throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729088 L.Thrp.DL.BitRate.QCI3.Samp.Index2 Number of samples with the downlink QCI-3 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729089 L.Thrp.DL.BitRate.QCI3.Samp.Index3 Number of samples with the downlink QCI-3 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729090 L.Thrp.DL.BitRate.QCI3.Samp.Index4 Number of samples with the downlink QCI-3 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729091 L.Thrp.DL.BitRate.QCI3.Samp.Index5 Number of samples with the downlink QCI-3 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729092 L.Thrp.DL.BitRate.QCI3.Samp.Index6 Number of samples with the downlink QCI-3 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729093 L.Thrp.DL.BitRate.QCI3.Samp.Index7 Number of samples with the downlink QCI-3 service throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729094 L.Thrp.DL.BitRate.QCI3.Samp.Index8 Number of samples with the downlink QCI-3 service throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729095 L.Thrp.DL.BitRate.QCI3.Samp.Index9 Number of samples with the downlink QCI-3 service throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526729096 L.Thrp.DL.BitRate.QCI4.Samp.Index0 Number of samples with the downlink QCI-4 service throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729097 L.Thrp.DL.BitRate.QCI4.Samp.Index1 Number of samples with the downlink QCI-4 service throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729098 L.Thrp.DL.BitRate.QCI4.Samp.Index2 Number of samples with the downlink QCI-4 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729099 L.Thrp.DL.BitRate.QCI4.Samp.Index3 Number of samples with the downlink QCI-4 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729100 L.Thrp.DL.BitRate.QCI4.Samp.Index4 Number of samples with the downlink QCI-4 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729101 L.Thrp.DL.BitRate.QCI4.Samp.Index5 Number of samples with the downlink QCI-4 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729102 L.Thrp.DL.BitRate.QCI4.Samp.Index6 Number of samples with the downlink QCI-4 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729103 L.Thrp.DL.BitRate.QCI4.Samp.Index7 Number of samples with the downlink QCI-4 service throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729104 L.Thrp.DL.BitRate.QCI4.Samp.Index8 Number of samples with the downlink QCI-4 service throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729105 L.Thrp.DL.BitRate.QCI4.Samp.Index9 Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Number of samples with the downlink QCI-4 service throughput ranging within index 9 GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526729106 L.Thrp.DL.BitRate.QCI5.Samp.Index0 Number of samples with the downlink QCI-5 service throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729107 L.Thrp.DL.BitRate.QCI5.Samp.Index1 Number of samples with the downlink QCI-5 service throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729108 L.Thrp.DL.BitRate.QCI5.Samp.Index2 Number of samples with the downlink QCI-5 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729109 L.Thrp.DL.BitRate.QCI5.Samp.Index3 Number of samples with the downlink QCI-5 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729110 L.Thrp.DL.BitRate.QCI5.Samp.Index4 Number of samples with the downlink QCI-5 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729111 L.Thrp.DL.BitRate.QCI5.Samp.Index5 Number of samples with the downlink QCI-5 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729112 L.Thrp.DL.BitRate.QCI5.Samp.Index6 Number of samples with the downlink QCI-5 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729113 L.Thrp.DL.BitRate.QCI5.Samp.Index7 Number of samples with the downlink QCI-5 service throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729114 L.Thrp.DL.BitRate.QCI5.Samp.Index8 Number of samples with the downlink QCI-5 service throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526729115 L.Thrp.DL.BitRate.QCI5.Samp.Index9 Number of samples with the downlink QCI-5 service throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729116 L.Thrp.DL.BitRate.QCI6.Samp.Index0 Number of samples with the downlink QCI-6 service throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729117 L.Thrp.DL.BitRate.QCI6.Samp.Index1 Number of samples with the downlink QCI-6 service throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729118 L.Thrp.DL.BitRate.QCI6.Samp.Index2 Number of samples with the downlink QCI-6 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729119 L.Thrp.DL.BitRate.QCI6.Samp.Index3 Number of samples with the downlink QCI-6 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729120 L.Thrp.DL.BitRate.QCI6.Samp.Index4 Number of samples with the downlink QCI-6 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729121 L.Thrp.DL.BitRate.QCI6.Samp.Index5 Number of samples with the downlink QCI-6 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729122 L.Thrp.DL.BitRate.QCI6.Samp.Index6 Number of samples with the downlink QCI-6 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729123 L.Thrp.DL.BitRate.QCI6.Samp.Index7 Number of samples with the downlink QCI-6 service throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729124 L.Thrp.DL.BitRate.QCI6.Samp.Index8 Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Number of samples with the downlink QCI-6 service throughput ranging within index 8 GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526729125 L.Thrp.DL.BitRate.QCI6.Samp.Index9 Number of samples with the downlink QCI-6 service throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729126 L.Thrp.DL.BitRate.QCI7.Samp.Index0 Number of samples with the downlink QCI-7 service throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729127 L.Thrp.DL.BitRate.QCI7.Samp.Index1 Number of samples with the downlink QCI-7 service throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729128 L.Thrp.DL.BitRate.QCI7.Samp.Index2 Number of samples with the downlink QCI-7 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729129 L.Thrp.DL.BitRate.QCI7.Samp.Index3 Number of samples with the downlink QCI-7 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729130 L.Thrp.DL.BitRate.QCI7.Samp.Index4 Number of samples with the downlink QCI-7 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729131 L.Thrp.DL.BitRate.QCI7.Samp.Index5 Number of samples with the downlink QCI-7 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729132 L.Thrp.DL.BitRate.QCI7.Samp.Index6 Number of samples with the downlink QCI-7 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729133 L.Thrp.DL.BitRate.QCI7.Samp.Index7 Number of samples with the downlink QCI-7 service throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526729134 L.Thrp.DL.BitRate.QCI7.Samp.Index8 Number of samples with the downlink QCI-7 service throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729135 L.Thrp.DL.BitRate.QCI7.Samp.Index9 Number of samples with the downlink QCI-7 service throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729136 L.Thrp.DL.BitRate.QCI8.Samp.Index0 Number of samples with the downlink QCI-8 service throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729137 L.Thrp.DL.BitRate.QCI8.Samp.Index1 Number of samples with the downlink QCI-8 service throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729138 L.Thrp.DL.BitRate.QCI8.Samp.Index2 Number of samples with the downlink QCI-8 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729139 L.Thrp.DL.BitRate.QCI8.Samp.Index3 Number of samples with the downlink QCI-8 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729140 L.Thrp.DL.BitRate.QCI8.Samp.Index4 Number of samples with the downlink QCI-8 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729141 L.Thrp.DL.BitRate.QCI8.Samp.Index5 Number of samples with the downlink QCI-8 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729142 L.Thrp.DL.BitRate.QCI8.Samp.Index6 Number of samples with the downlink QCI-8 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729143 L.Thrp.DL.BitRate.QCI8.Samp.Index7 Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Number of samples with the downlink QCI-8 service throughput ranging within index 7 GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526729144 L.Thrp.DL.BitRate.QCI8.Samp.Index8 Number of samples with the downlink QCI-8 service throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729145 L.Thrp.DL.BitRate.QCI8.Samp.Index9 Number of samples with the downlink QCI-8 service throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729146 L.Thrp.DL.BitRate.QCI9.Samp.Index0 Number of samples with the downlink QCI-9 service throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729147 L.Thrp.DL.BitRate.QCI9.Samp.Index1 Number of samples with the downlink QCI-9 service throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729148 L.Thrp.DL.BitRate.QCI9.Samp.Index2 Number of samples with the downlink QCI-9 service throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729149 L.Thrp.DL.BitRate.QCI9.Samp.Index3 Number of samples with the downlink QCI-9 service throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729150 L.Thrp.DL.BitRate.QCI9.Samp.Index4 Number of samples with the downlink QCI-9 service throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729151 L.Thrp.DL.BitRate.QCI9.Samp.Index5 Number of samples with the downlink QCI-9 service throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729152 L.Thrp.DL.BitRate.QCI9.Samp.Index6 Number of samples with the downlink QCI-9 service throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526729153 L.Thrp.DL.BitRate.QCI9.Samp.Index7 Number of samples with the downlink QCI-9 service throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729154 L.Thrp.DL.BitRate.QCI9.Samp.Index8 Number of samples with the downlink QCI-9 service throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729155 L.Thrp.DL.BitRate.QCI9.Samp.Index9 Number of samples with the downlink QCI-9 service throughput ranging within index 9 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729156 L.Thrp.DL.BitRate.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729157 L.Thrp.DL.BitRate.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729158 L.Thrp.DL.BitRate.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729159 L.Thrp.DL.BitRate.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 3 UMTS: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729160 L.Thrp.DL.BitRate.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729161 L.Thrp.DL.BitRate.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729162 L.Thrp.DL.BitRate.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729163 L.Thrp.DL.BitRate.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729164 L.Thrp.DL.BitRate.Samp.Index8.PLMN Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Number of operator-specific samples GSM: None with the downlink throughput ranging UMTS: None within index 8 LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729165 L.Thrp.DL.BitRate.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink throughput ranging GSM: None within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729166 L.Thrp.DL.BitRate.QCI1.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729167 L.Thrp.DL.BitRate.QCI1.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729168 L.Thrp.DL.BitRate.QCI1.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name Hybrid RAN Sharing 1526729169 L.Thrp.DL.BitRate.QCI1.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729170 L.Thrp.DL.BitRate.QCI1.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729171 L.Thrp.DL.BitRate.QCI1.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729172 L.Thrp.DL.BitRate.QCI1.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729173 L.Thrp.DL.BitRate.QCI1.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Counter ID Counter Name Counter Description Feature ID Feature Name Basic Scheduling Hybrid RAN Sharing 1526729174 L.Thrp.DL.BitRate.QCI1.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729175 L.Thrp.DL.BitRate.QCI1.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-1 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729176 L.Thrp.DL.BitRate.QCI2.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729177 L.Thrp.DL.BitRate.QCI2.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729178 L.Thrp.DL.BitRate.QCI2.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-070206 RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729179 L.Thrp.DL.BitRate.QCI2.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729180 L.Thrp.DL.BitRate.QCI2.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729181 L.Thrp.DL.BitRate.QCI2.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729182 L.Thrp.DL.BitRate.QCI2.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729183 L.Thrp.DL.BitRate.QCI2.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729184 L.Thrp.DL.BitRate.QCI2.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729185 L.Thrp.DL.BitRate.QCI2.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-2 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729186 L.Thrp.DL.BitRate.QCI3.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729187 L.Thrp.DL.BitRate.QCI3.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729188 L.Thrp.DL.BitRate.QCI3.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729189 L.Thrp.DL.BitRate.QCI3.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729190 L.Thrp.DL.BitRate.QCI3.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729191 L.Thrp.DL.BitRate.QCI3.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729192 L.Thrp.DL.BitRate.QCI3.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729193 L.Thrp.DL.BitRate.QCI3.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729194 L.Thrp.DL.BitRate.QCI3.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729195 L.Thrp.DL.BitRate.QCI3.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-3 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729196 L.Thrp.DL.BitRate.QCI4.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729197 L.Thrp.DL.BitRate.QCI4.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729198 L.Thrp.DL.BitRate.QCI4.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 2 UMTS: None LTE: LBFD-002008 Radio Bearer Management RAN Sharing with Common Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729199 L.Thrp.DL.BitRate.QCI4.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729200 L.Thrp.DL.BitRate.QCI4.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729201 L.Thrp.DL.BitRate.QCI4.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729202 L.Thrp.DL.BitRate.QCI4.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729203 L.Thrp.DL.BitRate.QCI4.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 7 UMTS: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729204 L.Thrp.DL.BitRate.QCI4.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729205 L.Thrp.DL.BitRate.QCI4.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-4 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729206 L.Thrp.DL.BitRate.QCI5.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729207 L.Thrp.DL.BitRate.QCI5.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729208 L.Thrp.DL.BitRate.QCI5.Samp.Index2.PLMN Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Number of operator-specific samples GSM: None with the downlink QCI-5 service UMTS: None throughput ranging within index 2 LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729209 L.Thrp.DL.BitRate.QCI5.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729210 L.Thrp.DL.BitRate.QCI5.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729211 L.Thrp.DL.BitRate.QCI5.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729212 L.Thrp.DL.BitRate.QCI5.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name Hybrid RAN Sharing 1526729213 L.Thrp.DL.BitRate.QCI5.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729214 L.Thrp.DL.BitRate.QCI5.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729215 L.Thrp.DL.BitRate.QCI5.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-5 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729216 L.Thrp.DL.BitRate.QCI6.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729217 L.Thrp.DL.BitRate.QCI6.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Counter ID Counter Name Counter Description Feature ID Feature Name Basic Scheduling Hybrid RAN Sharing 1526729218 L.Thrp.DL.BitRate.QCI6.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729219 L.Thrp.DL.BitRate.QCI6.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729220 L.Thrp.DL.BitRate.QCI6.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729221 L.Thrp.DL.BitRate.QCI6.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729222 L.Thrp.DL.BitRate.QCI6.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-070206 RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729223 L.Thrp.DL.BitRate.QCI6.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729224 L.Thrp.DL.BitRate.QCI6.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729225 L.Thrp.DL.BitRate.QCI6.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-6 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729226 L.Thrp.DL.BitRate.QCI7.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729227 L.Thrp.DL.BitRate.QCI7.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729228 L.Thrp.DL.BitRate.QCI7.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729229 L.Thrp.DL.BitRate.QCI7.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729230 L.Thrp.DL.BitRate.QCI7.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729231 L.Thrp.DL.BitRate.QCI7.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729232 L.Thrp.DL.BitRate.QCI7.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729233 L.Thrp.DL.BitRate.QCI7.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729234 L.Thrp.DL.BitRate.QCI7.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729235 L.Thrp.DL.BitRate.QCI7.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-7 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729236 L.Thrp.DL.BitRate.QCI8.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729237 L.Thrp.DL.BitRate.QCI8.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729238 L.Thrp.DL.BitRate.QCI8.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729239 L.Thrp.DL.BitRate.QCI8.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729240 L.Thrp.DL.BitRate.QCI8.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729241 L.Thrp.DL.BitRate.QCI8.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729242 L.Thrp.DL.BitRate.QCI8.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 6 UMTS: None LTE: LBFD-002008 Radio Bearer Management RAN Sharing with Common Carrier Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729243 L.Thrp.DL.BitRate.QCI8.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729244 L.Thrp.DL.BitRate.QCI8.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729245 L.Thrp.DL.BitRate.QCI8.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-8 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729246 L.Thrp.DL.BitRate.QCI9.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729247 L.Thrp.DL.BitRate.QCI9.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 1 UMTS: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729248 L.Thrp.DL.BitRate.QCI9.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729249 L.Thrp.DL.BitRate.QCI9.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729250 L.Thrp.DL.BitRate.QCI9.Samp.Index4.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 4 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729251 L.Thrp.DL.BitRate.QCI9.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729252 L.Thrp.DL.BitRate.QCI9.Samp.Index6.PLMN Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Number of operator-specific samples GSM: None with the downlink QCI-9 service UMTS: None throughput ranging within index 6 LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729253 L.Thrp.DL.BitRate.QCI9.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729254 L.Thrp.DL.BitRate.QCI9.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729255 L.Thrp.DL.BitRate.QCI9.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the downlink QCI-9 service GSM: None throughput ranging within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729256 L.Thrp.eNodeB.bits.DL.Max Maximum downlink traffic volume for Multi-mode: None PDCP SDUs in an eNodeB GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729257 L.Thrp.eNodeB.bits.UL.Max Maximum uplink traffic volume for PDCP SDUs in an eNodeB Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 1526729258 L.Thrp.eNodeB.bits.Max Maximum sum of the uplink and downlink traffic volume for PDCP SDUs in an eNodeB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729319 L.ChMeas.CQI.DL.SingleCW.Periodic.0 Number of periodic wideband CQI reports with the value of 0 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729320 L.ChMeas.CQI.DL.SingleCW.Periodic.1 Number of periodic wideband CQI reports with the value of 1 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729321 L.ChMeas.CQI.DL.SingleCW.Periodic.2 Number of periodic wideband CQI reports with the value of 2 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729322 L.ChMeas.CQI.DL.SingleCW.Periodic.3 Number of periodic wideband CQI reports with the value of 3 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729323 L.ChMeas.CQI.DL.SingleCW.Periodic.4 Number of periodic wideband CQI reports with the value of 4 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729324 L.ChMeas.CQI.DL.SingleCW.Periodic.5 Number of periodic wideband CQI reports with the value of 5 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729325 L.ChMeas.CQI.DL.SingleCW.Periodic.6 Number of periodic wideband CQI reports with the value of 6 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729326 L.ChMeas.CQI.DL.SingleCW.Periodic.7 Number of periodic wideband CQI reports with the value of 7 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729327 L.ChMeas.CQI.DL.SingleCW.Periodic.8 Number of periodic wideband CQI reports with the value of 8 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729328 L.ChMeas.CQI.DL.SingleCW.Periodic.9 Number of periodic wideband CQI reports with the value of 9 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation 1526729329 L.ChMeas.CQI.DL.SingleCW.Periodic.10 Number of periodic wideband CQI Multi-mode: None reports with the value of 10 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729330 L.ChMeas.CQI.DL.SingleCW.Periodic.11 Number of periodic wideband CQI Multi-mode: None reports with the value of 11 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729331 L.ChMeas.CQI.DL.SingleCW.Periodic.12 Number of periodic wideband CQI Multi-mode: None reports with the value of 12 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729332 L.ChMeas.CQI.DL.SingleCW.Periodic.13 Number of periodic wideband CQI Multi-mode: None reports with the value of 13 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729333 L.ChMeas.CQI.DL.SingleCW.Periodic.14 Number of periodic wideband CQI Multi-mode: None reports with the value of 14 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729334 L.ChMeas.CQI.DL.SingleCW.Periodic.15 Number of periodic wideband CQI Multi-mode: None reports with the value of 15 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729335 L.ChMeas.CQI.DL.SingleCW.Aperiodic.0 Number of aperiodic wideband CQI reports with the value of 0 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729336 L.ChMeas.CQI.DL.SingleCW.Aperiodic.1 Number of aperiodic wideband CQI reports with the value of 1 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729337 L.ChMeas.CQI.DL.SingleCW.Aperiodic.2 Number of aperiodic wideband CQI reports with the value of 2 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729338 L.ChMeas.CQI.DL.SingleCW.Aperiodic.3 Number of aperiodic wideband CQI reports with the value of 3 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None Dynamic Downlink Power Allocation Dynamic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729339 L.ChMeas.CQI.DL.SingleCW.Aperiodic.4 Number of aperiodic wideband CQI reports with the value of 4 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729340 L.ChMeas.CQI.DL.SingleCW.Aperiodic.5 Number of aperiodic wideband CQI reports with the value of 5 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729341 L.ChMeas.CQI.DL.SingleCW.Aperiodic.6 Number of aperiodic wideband CQI reports with the value of 6 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729342 L.ChMeas.CQI.DL.SingleCW.Aperiodic.7 Number of aperiodic wideband CQI reports with the value of 7 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729343 L.ChMeas.CQI.DL.SingleCW.Aperiodic.8 Number of aperiodic wideband CQI reports with the value of 8 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729344 L.ChMeas.CQI.DL.SingleCW.Aperiodic.9 Number of aperiodic wideband CQI reports with the value of 9 in singlecodeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729345 L.ChMeas.CQI.DL.SingleCW.Aperiodic.10 Number of aperiodic wideband CQI Multi-mode: None reports with the value of 10 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729346 L.ChMeas.CQI.DL.SingleCW.Aperiodic.11 Number of aperiodic wideband CQI Multi-mode: None reports with the value of 11 in single- GSM: None codeword transmission UMTS: None Dynamic Downlink Power Allocation Dynamic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729347 L.ChMeas.CQI.DL.SingleCW.Aperiodic.12 Number of aperiodic wideband CQI Multi-mode: None reports with the value of 12 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729348 L.ChMeas.CQI.DL.SingleCW.Aperiodic.13 Number of aperiodic wideband CQI Multi-mode: None reports with the value of 13 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729349 L.ChMeas.CQI.DL.SingleCW.Aperiodic.14 Number of aperiodic wideband CQI Multi-mode: None reports with the value of 14 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729350 L.ChMeas.CQI.DL.SingleCW.Aperiodic.15 Number of aperiodic wideband CQI Multi-mode: None reports with the value of 15 in single- GSM: None codeword transmission UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729351 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.0 Number of periodic wideband CQI reports with the value of 0 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729352 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.1 Number of periodic wideband CQI reports with the value of 1 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729353 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.2 Number of periodic wideband CQI reports with the value of 2 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729354 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.3 Number of periodic wideband CQI reports with the value of 3 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729355 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.4 Number of periodic wideband CQI reports with the value of 4 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation 1526729356 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.5 Number of periodic wideband CQI reports with the value of 5 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729357 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.6 Number of periodic wideband CQI reports with the value of 6 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729358 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.7 Number of periodic wideband CQI reports with the value of 7 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729359 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.8 Number of periodic wideband CQI reports with the value of 8 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729360 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.9 Number of periodic wideband CQI reports with the value of 9 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729361 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.10 Number of periodic wideband CQI reports with the value of 10 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729362 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.11 Number of periodic wideband CQI reports with the value of 11 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729363 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.12 Number of periodic wideband CQI reports with the value of 12 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729364 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.13 Number of periodic wideband CQI reports with the value of 13 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729365 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.14 Number of periodic wideband CQI reports with the value of 14 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729366 L.ChMeas.CQI.DL.DualCW.Code0.Periodic.15 Number of periodic wideband CQI reports with the value of 15 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation 1526729367 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.0 Number of aperiodic wideband CQI reports with the value of 0 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729368 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.1 Number of aperiodic wideband CQI reports with the value of 1 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729369 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.2 Number of aperiodic wideband CQI reports with the value of 2 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729370 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.3 Number of aperiodic wideband CQI reports with the value of 3 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729371 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.4 Number of aperiodic wideband CQI reports with the value of 4 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729372 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.5 Number of aperiodic wideband CQI reports with the value of 5 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729373 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.6 Number of aperiodic wideband CQI reports with the value of 6 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729374 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.7 Number of aperiodic wideband CQI reports with the value of 7 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002031 Support of aperiodic CQI reports 1526729375 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.8 Number of aperiodic wideband CQI reports with the value of 8 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729376 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.9 Number of aperiodic wideband CQI reports with the value of 9 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729377 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.10 Number of aperiodic wideband CQI reports with the value of 10 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729378 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.11 Number of aperiodic wideband CQI reports with the value of 11 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729379 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.12 Number of aperiodic wideband CQI reports with the value of 12 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729380 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.13 Number of aperiodic wideband CQI reports with the value of 13 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729381 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.14 Number of aperiodic wideband CQI reports with the value of 14 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729382 L.ChMeas.CQI.DL.DualCW.Code0.Aperiodic.15 Number of aperiodic wideband CQI reports with the value of 15 for codeword 0 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002031 Support of aperiodic CQI reports 1526729383 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.0 Number of periodic wideband CQI reports with the value of 0 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729384 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.1 Number of periodic wideband CQI reports with the value of 1 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729385 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.2 Number of periodic wideband CQI reports with the value of 2 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729386 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.3 Number of periodic wideband CQI reports with the value of 3 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729387 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.4 Number of periodic wideband CQI reports with the value of 4 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729388 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.5 Number of periodic wideband CQI reports with the value of 5 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729389 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.6 Number of periodic wideband CQI reports with the value of 6 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729390 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.7 Number of periodic wideband CQI reports with the value of 7 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729391 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.8 Number of periodic wideband CQI reports with the value of 8 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729392 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.9 Number of periodic wideband CQI reports with the value of 9 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729393 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.10 Number of periodic wideband CQI reports with the value of 10 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation 1526729394 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.11 Number of periodic wideband CQI reports with the value of 11 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729395 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.12 Number of periodic wideband CQI reports with the value of 12 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729396 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.13 Number of periodic wideband CQI reports with the value of 13 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729397 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.14 Number of periodic wideband CQI reports with the value of 14 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729398 L.ChMeas.CQI.DL.DualCW.Code1.Periodic.15 Number of periodic wideband CQI reports with the value of 15 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 TDLBFD-002016 Dynamic Downlink Power Allocation Dynamic Scheduling Dynamic Downlink Power Allocation 1526729399 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.0 Number of aperiodic wideband CQI reports with the value of 0 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729400 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.1 Number of aperiodic wideband CQI reports with the value of 1 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729401 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.2 Number of aperiodic wideband CQI reports with the value of 2 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729402 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.3 Number of aperiodic wideband CQI reports with the value of 3 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729403 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.4 Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Number of aperiodic wideband CQI reports with the value of 4 for codeword 1 in dual-codeword transmission GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729404 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.5 Number of aperiodic wideband CQI reports with the value of 5 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729405 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.6 Number of aperiodic wideband CQI reports with the value of 6 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729406 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.7 Number of aperiodic wideband CQI reports with the value of 7 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729407 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.8 Number of aperiodic wideband CQI reports with the value of 8 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729408 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.9 Number of aperiodic wideband CQI reports with the value of 9 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729409 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.10 Number of aperiodic wideband CQI reports with the value of 10 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729410 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.11 Number of aperiodic wideband CQI reports with the value of 11 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports Counter ID Counter Name Counter Description Feature ID Feature Name 1526729411 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.12 Number of aperiodic wideband CQI reports with the value of 12 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729412 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.13 Number of aperiodic wideband CQI reports with the value of 13 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729413 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.14 Number of aperiodic wideband CQI reports with the value of 14 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729414 L.ChMeas.CQI.DL.DualCW.Code1.Aperiodic.15 Number of aperiodic wideband CQI reports with the value of 15 for codeword 1 in dual-codeword transmission Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-00101502 LBFD-002031 TDLBFD-002016 TDLBFD-002031 Dynamic Downlink Power Allocation Dynamic Scheduling Support of aperiodic CQI reports Dynamic Downlink Power Allocation Support of aperiodic CQI reports 1526729415 L.Thrp.bits.UE.UL.SmallPkt Uplink traffic volume of PDCP PDUs Multi-mode: None scheduled for small packets GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729416 L.Thrp.Time.UE.UL.RmvSmallPkt Uplink data transmission duration except that for small packets Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729417 L.Thrp.bits.UE.UL.SmallPkt.PLMN Uplink traffic volume of PDCP PDUs Multi-mode: None scheduled for small packets for a GSM: None specific operator UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729418 L.Thrp.Time.UE.UL.RmvSmallPkt.PLMN Uplink data transmission duration except that for small packets for a specific operator Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729435 L.Thrp.UL.BitRate.Samp.Index0 Number of samples with the uplink throughput ranging within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729436 L.Thrp.UL.BitRate.Samp.Index1 Number of samples with the uplink throughput ranging within index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729437 L.Thrp.UL.BitRate.Samp.Index2 Number of samples with the uplink throughput ranging within index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729438 L.Thrp.UL.BitRate.Samp.Index3 Number of samples with the uplink throughput ranging within index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729439 L.Thrp.UL.BitRate.Samp.Index4 Number of samples with the uplink throughput ranging within index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729440 L.Thrp.UL.BitRate.Samp.Index5 Number of samples with the uplink throughput ranging within index 5 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729441 L.Thrp.UL.BitRate.Samp.Index6 Number of samples with the uplink throughput ranging within index 6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729442 L.Thrp.UL.BitRate.Samp.Index7 Number of samples with the uplink throughput ranging within index 7 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729443 L.Thrp.UL.BitRate.Samp.Index8 Number of samples with the uplink throughput ranging within index 8 Multi-mode: None GSM: None UMTS: None Radio Bearer Management Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526729444 L.Thrp.UL.BitRate.Samp.Index9 Number of samples with the uplink throughput ranging within index 9 1526729445 L.Thrp.UL.BitRate.Samp.Index0.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 0 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729446 L.Thrp.UL.BitRate.Samp.Index1.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 1 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729447 L.Thrp.UL.BitRate.Samp.Index2.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 2 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729448 L.Thrp.UL.BitRate.Samp.Index3.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 3 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729449 L.Thrp.UL.BitRate.Samp.Index4.PLMN Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Number of operator-specific samples GSM: None with the uplink throughput ranging UMTS: None within index 4 LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729450 L.Thrp.UL.BitRate.Samp.Index5.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 5 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729451 L.Thrp.UL.BitRate.Samp.Index6.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 6 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729452 L.Thrp.UL.BitRate.Samp.Index7.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 7 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729453 L.Thrp.UL.BitRate.Samp.Index8.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 8 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name Hybrid RAN Sharing 1526729454 L.Thrp.UL.BitRate.Samp.Index9.PLMN Number of operator-specific samples Multi-mode: None with the uplink throughput ranging GSM: None within index 9 UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729466 L.RLC.FirstPacketDelay.NonGBR.Index0 Number of times delay of the first RLC SDU for a non-GBR bearer ranges within index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-001027 LAOFD-001001 Active Queue Management (AQM) LTE-A Introduction 1526729666 L.Thrp.Time.Cell.DL.HighPrecision.PLMN Total duration of downlink data transmission for a specific operator in a cell (with the sampling period of 1 millisecond) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526729667 L.Thrp.Time.Cell.UL.HighPrecision.PLMN Total duration of uplink data transmission for a specific operator in a cell (with the sampling period of 1 millisecond) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 LOFD-001036 LOFD-001037 LBFD-002025 TDLBFD-002008 TDLOFD-001036 TDLOFD-001037 TDLBFD-002025 LOFD-070206 Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Radio Bearer Management RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Basic Scheduling Hybrid RAN Sharing 1526730102 L.ChMeas.PRB.DL.SrbUsed.Avg Average number of PRBs used by downlink signaling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LEOFD-111305 Basic Scheduling Basic Scheduling Virtual 4T4R 1526730103 L.ChMeas.PRB.DL.PagingUsed.Avg Average number of PRBs used by paging messages in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LEOFD-111305 Basic Scheduling Basic Scheduling Virtual 4T4R 1526730113 L.E-RAB.SessionTime.UE.HighPrecision.PLMN Total duration of UE data transmission for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing Counter ID Counter Name Counter Description Feature ID Feature Name LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730114 L.E-RAB.SessionTime.HighPrecision.PLMN Total duration of data transmission for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730115 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI1 Total duration of data transmission for services with the QCI of 1 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730116 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI2 Total duration of data transmission for services with the QCI of 2 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730117 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI3 Total duration of data transmission for services with the QCI of 3 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730118 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI4 Total duration of data transmission for services with the QCI of 4 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730119 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI5 Total duration of data transmission for services with the QCI of 5 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730120 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI6 Total duration of data transmission for services with the QCI of 6 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730121 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI7 Total duration of data transmission for services with the QCI of 7 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730122 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI8 Total duration of data transmission for services with the QCI of 8 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730123 L.E-RAB.SessionTime.HighPrecision.PLMN.QCI9 Total duration of data transmission for services with the QCI of 9 for a specific operator in a cell (with the precision of 100 ms) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 LOFD-070206 LOFD-001036 LOFD-001037 TDLOFD-001036 TDLOFD-001037 Basic Scheduling Hybrid RAN Sharing RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier 1526730141 L.ChMeas.RI.Rank1 Number of times rank 1 is reported Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LOFD-001001 LOFD-001003 TDLBFD-002025 TDLOFD-001001 Basic Scheduling DL 2x2 MIMO DL 4x2 MIMO Basic Scheduling DL 2x2 MIMO 1526730142 L.ChMeas.RI.Rank2 Number of times a UE reports rank 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LOFD-001001 LOFD-001003 TDLBFD-002025 TDLOFD-001001 Basic Scheduling DL 2x2 MIMO DL 4x2 MIMO Basic Scheduling DL 2x2 MIMO 1526730557 L.ChMeas.PRB.UL.PUSCH.Avail Number of available PUSCH PRBs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730558 L.Cell.DL.PDSCH.Tti.Num Number of TTIs on the PDSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730559 L.Cell.UL.PUSCH.Tti.Num Number of TTIs on the PUSCH Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730563 L.Thrp.bits.UL.PDCP.SDU.QCI.1 Uplink traffic volume for PDCP SDUs of services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730564 L.Thrp.bits.UL.PDCP.SDU.QCI.2 Uplink traffic volume for PDCP SDUs of services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730565 L.Thrp.bits.UL.PDCP.SDU.QCI.3 Uplink traffic volume for PDCP SDUs of services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730566 L.Thrp.bits.UL.PDCP.SDU.QCI.4 Uplink traffic volume for PDCP SDUs of services with the QCI of 4 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 1526730567 L.Thrp.bits.UL.PDCP.SDU.QCI.5 Uplink traffic volume for PDCP SDUs of services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730568 L.Thrp.bits.UL.PDCP.SDU.QCI.6 Uplink traffic volume for PDCP SDUs of services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730569 L.Thrp.bits.UL.PDCP.SDU.QCI.7 Uplink traffic volume for PDCP SDUs of services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730570 L.Thrp.bits.UL.PDCP.SDU.QCI.8 Uplink traffic volume for PDCP SDUs of services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730571 L.Thrp.bits.UL.PDCP.SDU.QCI.9 Uplink traffic volume for PDCP SDUs of services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730572 L.Thrp.bits.UL.PDCP.SDU Total uplink traffic volume for PDCP SDUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730573 L.Thrp.bits.DL.PDCP.PDU.QCI.1 Downlink traffic volume for PDCP PDUs of services with the QCI of 1 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730574 L.Thrp.bits.DL.PDCP.PDU.QCI.2 Downlink traffic volume for PDCP PDUs of services with the QCI of 2 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730575 L.Thrp.bits.DL.PDCP.PDU.QCI.3 Downlink traffic volume for PDCP PDUs of services with the QCI of 3 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730576 L.Thrp.bits.DL.PDCP.PDU.QCI.4 Downlink traffic volume for PDCP PDUs of services with the QCI of 4 in a cell Multi-mode: None GSM: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526730577 L.Thrp.bits.DL.PDCP.PDU.QCI.5 Downlink traffic volume for PDCP PDUs of services with the QCI of 5 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730578 L.Thrp.bits.DL.PDCP.PDU.QCI.6 Downlink traffic volume for PDCP PDUs of services with the QCI of 6 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730579 L.Thrp.bits.DL.PDCP.PDU.QCI.7 Downlink traffic volume for PDCP PDUs of services with the QCI of 7 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730580 L.Thrp.bits.DL.PDCP.PDU.QCI.8 Downlink traffic volume for PDCP PDUs of services with the QCI of 8 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730581 L.Thrp.bits.DL.PDCP.PDU.QCI.9 Downlink traffic volume for PDCP PDUs of services with the QCI of 9 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730582 L.Thrp.bits.DL.PDCP.PDU Total downlink traffic volume of PDCP PDUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730832 L.Traffic.SUNPT.DL.Avg Average number of scheduled UEs per TTI in the downlink in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730833 L.Traffic.SUNPT.DL.Max Maximum number of scheduled UEs Multi-mode: None per TTI in the downlink in a cell GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730834 L.Traffic.Board.SUNPT.DL.Max Maximum number of scheduled UEs Multi-mode: None per TTI in the downlink in cells GSM: None served by a baseband processing UMTS: None unit LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730835 L.Traffic.Board.SUNPT.ULDL.Max Maximum total number of scheduled Multi-mode: None UEs per TTI in the uplink and GSM: None downlink in cells served by a UMTS: None baseband processing unit LTE: LBFD-002025 Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 1526730836 L.Thrp.Time.UE.UL.RmvSpecificTTI Uplink data transmission duration Multi-mode: None except that for specific small packets GSM: None transmitted in the last TTI UMTS: None LTE: LBFD-002025 Basic Scheduling 1526730837 L.Thrp.bits.UE.UL.SpecificTTI Uplink traffic volume at the PDCP layer of specific small packets transmitted in the last TTI Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 Basic Scheduling 1526730838 L.Traffic.SUNPT.UL.Avg Average number of scheduled UEs per TTI in the uplink in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730839 L.Traffic.SUNPT.UL.Max Maximum number of scheduled UEs Multi-mode: None per TTI in the uplink in a cell GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730840 L.Traffic.SUNPT.ULDL.Max Maximum total number of scheduled Multi-mode: None UEs per TTI in the uplink and GSM: None downlink in a cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730841 L.Traffic.Board.SUNPT.UL.Max Maximum number of scheduled UEs Multi-mode: None per TTI in the uplink in cells served GSM: None by a baseband processing unit UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730842 L.ChMeas.PUSCH.DmrsTaSch Number of initial uplink transmissions of DMRS TA in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730843 L.ChMeas.PUSCH.DmrsTaSch.Retrans Number of uplink retransmissions of DMRS TA in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730850 L.ResOpt.SUNPTLimit.Ratio.DL Ratio of times the number of scheduled UEs per TTI in the downlink is limited in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730851 L.ResOpt.SUNPTLimit.PRB.DL Ratio of remaining downlink PRBs Multi-mode: None when the number of scheduled UEs GSM: None per TTI in the downlink is limited in a UMTS: None cell LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730852 L.ResOpt.CCELimit.PRB.DL Ratio of remaining downlink PRBs Multi-mode: None when CCE resources are limited in a GSM: None cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730853 L.ResOpt.SUNPTLimit.Ratio.UL Ratio of times the number of scheduled UEs per TTI in the uplink is limited in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730854 L.ResOpt.SUNPTLimit.PRB.UL Ratio of remaining uplink PRBs when the number of scheduled UEs per TTI in the uplink is limited in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description 1526730855 L.ResOpt.CCELimit.PRB.UL Ratio of remaining uplink PRBs Multi-mode: None when CCE resources are limited in a GSM: None cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 Feature ID Feature Name Basic Scheduling Basic Scheduling 1526730856 L.ResOpt.SUNPTLimit.CCE Ratio of remaining CCEs when the Multi-mode: None number of scheduled UEs per TTI is GSM: None limited in a cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526730872 L.Traffic.Sch.UL.Num Number of times that UEs are scheduled in a cell in the uplink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730873 L.Traffic.Sch.DL.Num Number of times that UEs are scheduled in a cell in the downlink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730879 L.Traffic.SGW.Rx.SDU.Bytes Number of bytes of SDUs that a cell receives from the S-GW Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730880 L.Traffic.SGW.Tx.SDU.Bytes Number of bytes of SDUs that a cell sends to the S-GW Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730881 L.Traffic.IntereNB.Transfer.Tx.SDU.Bytes Number of bytes of SDUs sent to target cells during inter-eNodeB handovers Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730882 L.Traffic.IntereNB.Transfer.Rx.SDU.Bytes Number of bytes of SDUs received from source cells during intereNodeB handovers Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526730883 L.ChMeas.PRB.DL.DrbUsed.Avg.VoIP Average number of PRBs used by DRBs on the PDSCH for downlink VoIP services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 LEOFD-111305 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA Virtual 4T4R 1526730884 L.ChMeas.PRB.UL.DrbUsed.Avg.VoIP Average number of PRBs used by Multi-mode: None DRBs on the PUSCH for uplink VoIP GSM: None services UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA 1526732697 L.ChMeas.PRB.PUSCH.Util.Samp.Index0 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 0 LTE-A Introduction Counter ID Counter Name Counter Description Feature ID Feature Name GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732698 L.ChMeas.PRB.PUSCH.Util.Samp.Index1 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 1 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732699 L.ChMeas.PRB.PUSCH.Util.Samp.Index2 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 2 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732700 L.ChMeas.PRB.PUSCH.Util.Samp.Index3 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 3 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732701 L.ChMeas.PRB.PUSCH.Util.Samp.Index4 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 4 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732702 L.ChMeas.PRB.PUSCH.Util.Samp.Index5 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 5 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732703 L.ChMeas.PRB.PUSCH.Util.Samp.Index6 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 6 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732704 L.ChMeas.PRB.PUSCH.Util.Samp.Index7 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 7 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732705 L.ChMeas.PRB.PUSCH.Util.Samp.Index8 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 8 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLOFD-001075 LBFD-002025 TDLBFD-002025 Basic Scheduling 1526732706 L.ChMeas.PRB.PUSCH.Util.Samp.Index9 Number of samples with the PUSCH Multi-mode: None PRB usage ranging within index 9 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling 1526732707 L.ChMeas.PRB.UL.TaSch.Used.Avg Average number of PRBs allocated for uplink TA measurement Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526732708 L.ChMeas.CCE.ULUsed.TA Number of PDCCH CCEs allocated for TA measurement Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526732727 L.ChMeas.PRB.PDSCH.Util.Samp.Index0 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 0 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732728 L.ChMeas.PRB.PDSCH.Util.Samp.Index1 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 1 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732729 L.ChMeas.PRB.PDSCH.Util.Samp.Index2 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 2 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732730 L.ChMeas.PRB.PDSCH.Util.Samp.Index3 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 3 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732731 L.ChMeas.PRB.PDSCH.Util.Samp.Index4 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 4 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732732 L.ChMeas.PRB.PDSCH.Util.Samp.Index5 Multi-mode: None LTE-A Introduction Counter ID Counter Name Counter Description Feature ID Feature Name Number of samples with the PDSCH GSM: None PRB usage ranging within index 5 UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732733 L.ChMeas.PRB.PDSCH.Util.Samp.Index6 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 6 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732734 L.ChMeas.PRB.PDSCH.Util.Samp.Index7 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 7 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732735 L.ChMeas.PRB.PDSCH.Util.Samp.Index8 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 8 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732736 L.ChMeas.PRB.PDSCH.Util.Samp.Index9 Number of samples with the PDSCH Multi-mode: None PRB usage ranging within index 9 GSM: None UMTS: None LTE: LAOFD-001001 LAOFD-001002 TDLOFD-001075 LBFD-002025 TDLBFD-002025 LEOFD-111305 LTE-A Introduction Carrier Aggregation for Downlink 2CC in 40MHz SFN Basic Scheduling Basic Scheduling Virtual 4T4R 1526732737 L.ChMeas.RI.Rank3 Number of times a UE reports rank 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LOFD-001060 TDLBFD-002025 Basic Scheduling DL 4x4 MIMO Basic Scheduling 1526732738 L.ChMeas.RI.Rank4 Number of times a UE reports rank 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LOFD-001060 TDLBFD-002025 Basic Scheduling DL 4x4 MIMO Basic Scheduling 1526732739 L.DLPSServ.EstDelay.Avg.Idle Average access delay for downlink data services successfully initiated by idle-mode UEs in the cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732740 L.DLPSServ.EstDelay.Good.Num.Idle Number of times that the access delay for a downlink data service successfully initiated by an idlemode UE in the cell is within the Good range Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526732741 L.DLPSServ.EstDelay.Medium.Num.Idle Number of times that the access delay for a downlink data service successfully initiated by an idlemode UE in the cell is within the Medium range Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732742 L.DLPSServ.EstDelay.Bad.Num.Idle Number of times that the access delay for a downlink data service successfully initiated by an idlemode UE in the cell is within the Bad range Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732743 L.Thrp.bits.DL.PerUser.In.Index0 Number of times that the downlink Multi-mode: None PS service traffic in the cell is within GSM: None the range of (0, DlUserThruputThd0) UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732744 L.Thrp.bits.DL.PerUser.In.Index1 Number of times that the downlink PS service traffic in the cell is within the range of [DlUserThruputThd0, DlUserThruputThd1) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732745 L.Thrp.bits.DL.PerUser.In.Index2 Number of times that the downlink PS service traffic in the cell is within the range of [DlUserThruputThd1, DlUserThruputThd2) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732746 L.Thrp.bits.DL.PerUser.In.Index3 Number of times that the downlink PS service traffic in the cell is within the range of [DlUserThruputThd2, DlUserThruputThd3) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732747 L.Thrp.bits.DL.PerUser.In.Index4 Number of times that the downlink PS service traffic in the cell is within the range of [DlUserThruputThd3, DlUserThruputThd4) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732748 L.Thrp.bits.DL.PerUser.In.Index5 Number of times that the downlink PS service traffic in the cell is greater than DlUserThruputThd4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732749 L.Thrp.bits.DL.PerUser.Out.Index0 Number of times that the downlink PS service throughput in the cell is within the range of (0, DlUserThruputThd0) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732750 L.Thrp.bits.DL.PerUser.Out.Index1 Number of times that the downlink PS service throughput in the cell is Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name within the range of [DlUserThruputThd0, DlUserThruputThd1) GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526732751 L.Thrp.bits.DL.PerUser.Out.Index2 Number of times that the downlink PS service throughput in the cell is within the range of [DlUserThruputThd1, DlUserThruputThd2) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732752 L.Thrp.bits.DL.PerUser.Out.Index3 Number of times that the downlink PS service throughput in the cell is within the range of [DlUserThruputThd2, DlUserThruputThd3) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732753 L.Thrp.bits.DL.PerUser.Out.Index4 Number of times that the downlink PS service throughput in the cell is within the range of [DlUserThruputThd3, DlUserThruputThd4) Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732754 L.Thrp.bits.DL.PerUser.Out.Index5 Number of times that the downlink PS service throughput in the cell is greater than DlUserThruputThd4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732755 L.Traffic.DL.EmptyBuf.PDCPLat.Num Total number of downlink PDCP Multi-mode: None SDUs that are for DRB services and GSM: None enter the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732756 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.1 Total number of downlink PDCP SDUs that are for DRB services of QCI 1 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732757 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.2 Total number of downlink PDCP SDUs that are for DRB services of QCI 2 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732758 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.3 Total number of downlink PDCP SDUs that are for DRB services of QCI 3 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732759 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.4 Total number of downlink PDCP SDUs that are for DRB services of QCI 4 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 Basic Scheduling 1526732760 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.5 Total number of downlink PDCP SDUs that are for DRB services of QCI 5 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732761 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.6 Total number of downlink PDCP SDUs that are for DRB services of QCI 6 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732762 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.7 Total number of downlink PDCP SDUs that are for DRB services of QCI 7 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732763 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.8 Total number of downlink PDCP SDUs that are for DRB services of QCI 8 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732764 L.Traffic.DL.EmptyBuf.PDCPLat.Num.QCI.9 Total number of downlink PDCP SDUs that are for DRB services of QCI 9 and enter the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732765 L.Traffic.DL.EmptyBuf.PDCPLat.Time Total transmission delay of the first PDCP SDUs of DRB services in the empty buffer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732766 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.1 Total transmission delay of the first Multi-mode: None PDCP SDUs of DRB services of QCI GSM: None 1 in the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732767 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.2 Total transmission delay of the first Multi-mode: None PDCP SDUs of DRB services of QCI GSM: None 2 in the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732768 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.3 Total transmission delay of the first Multi-mode: None PDCP SDUs of DRB services of QCI GSM: None 3 in the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732769 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.4 Multi-mode: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Total transmission delay of the first GSM: None PDCP SDUs of DRB services of QCI UMTS: None 4 in the empty buffer in a cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526732770 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.5 Total transmission delay of the first Multi-mode: None PDCP SDUs of DRB services of QCI GSM: None 5 in the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732771 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.6 Total transmission delay of the first Multi-mode: None PDCP SDUs of DRB services of QCI GSM: None 6 in the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732772 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.7 Total transmission delay of the first Multi-mode: None PDCP SDUs of DRB services of QCI GSM: None 7 in the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732773 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.8 Total transmission delay of the first Multi-mode: None PDCP SDUs of DRB services of QCI GSM: None 8 in the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732774 L.Traffic.DL.EmptyBuf.PDCPLat.Time.QCI.9 Total transmission delay of the first Multi-mode: None PDCP SDUs of DRB services of QCI GSM: None 9 in the empty buffer in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526732775 L.Thrp.bits.UE.UL.PL0 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [0, 90) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732776 L.Thrp.bits.UE.UL.PL1 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [90, 95) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732777 L.Thrp.bits.UE.UL.PL2 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [95, 100) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control Counter ID Counter Name Counter Description Feature ID Feature Name 1526732778 L.Thrp.bits.UE.UL.PL3 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [100, 105) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732779 L.Thrp.bits.UE.UL.PL4 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [105, 110) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732780 L.Thrp.bits.UE.UL.PL5 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [110, 115) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732781 L.Thrp.bits.UE.UL.PL6 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [115, 120) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732782 L.Thrp.bits.UE.UL.PL7 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [120, 125) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732783 L.Thrp.bits.UE.UL.PL8 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [125, 130) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732784 L.Thrp.bits.UE.UL.PL9 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [130, 135) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732785 L.Thrp.bits.UE.UL.PL10 Total uplink throughput of PDCP PDUs for UEs whose path loss is greater than or equal to 135 dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Basic Scheduling Uplink Power Control Uplink Power Control 1526732786 L.Thrp.Time.UE.UL.RmvSmallPkt.PL0 Data transmission duration of uplink Multi-mode: None PDCP PDUs (excluding small GSM: None packets) for UEs whose path loss UMTS: None ranges within the range of [0, 90) dB LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732787 L.Thrp.Time.UE.UL.RmvSmallPkt.PL1 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [90, 95) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732788 L.Thrp.Time.UE.UL.RmvSmallPkt.PL2 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss within [95, 100) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732789 L.Thrp.Time.UE.UL.RmvSmallPkt.PL3 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [100, 105) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732790 L.Thrp.Time.UE.UL.RmvSmallPkt.PL4 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [105, 110) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732791 L.Thrp.Time.UE.UL.RmvSmallPkt.PL5 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [110, 115) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732792 L.Thrp.Time.UE.UL.RmvSmallPkt.PL6 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [115, 120) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732793 L.Thrp.Time.UE.UL.RmvSmallPkt.PL7 Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [120, 125) dB GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732794 L.Thrp.Time.UE.UL.RmvSmallPkt.PL8 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [125, 130) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732795 L.Thrp.Time.UE.UL.RmvSmallPkt.PL9 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [130, 135) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732796 L.Thrp.Time.UE.UL.RmvSmallPkt.PL10 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss is greater than or equal to 135 dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732797 L.Thrp.bits.UE.UL.SmallPkt.PL0 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [0, 90) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732798 L.Thrp.bits.UE.UL.SmallPkt.PL1 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [90, 95) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732799 L.Thrp.bits.UE.UL.SmallPkt.PL2 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [95, 100) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732800 L.Thrp.bits.UE.UL.SmallPkt.PL3 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [100, 105) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 LBFD-002026 TDLBFD-002026 Uplink Power Control Uplink Power Control 1526732801 L.Thrp.bits.UE.UL.SmallPkt.PL4 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [105, 110) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732802 L.Thrp.bits.UE.UL.SmallPkt.PL5 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [110, 115) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732803 L.Thrp.bits.UE.UL.SmallPkt.PL6 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [115, 120) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732804 L.Thrp.bits.UE.UL.SmallPkt.PL7 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [120, 125) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732805 L.Thrp.bits.UE.UL.SmallPkt.PL8 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [125, 130) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732806 L.Thrp.bits.UE.UL.SmallPkt.PL9 Throughput of small uplink packets at the PDCP layer for UEs whose path loss ranges within [130, 135) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732807 L.Thrp.bits.UE.UL.SmallPkt.PL10 Throughput of small uplink packets at the PDCP layer for UEs whose path loss is greater than or equal to 135 dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732808 L.Traffic.User.PL0 Multi-mode: None GSM: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Number of UEs that perform services and have a path loss ranging within [0, 90) dB UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732809 L.Traffic.User.PL1 Number of UEs that perform services and have a path loss ranging within [90, 95) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732810 L.Traffic.User.PL2 Number of UEs that perform services and have a path loss ranging within [95, 100) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732811 L.Traffic.User.PL3 Number of UEs that perform services and have a path loss ranging within [100, 105) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732812 L.Traffic.User.PL4 Number of UEs that perform services and have a path loss ranging within [105, 110) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732813 L.Traffic.User.PL5 Number of UEs that perform services and have a path loss ranging within [110, 115) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732814 L.Traffic.User.PL6 Number of UEs that perform services and have a path loss ranging within [115, 120) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732815 L.Traffic.User.PL7 Number of UEs that perform services and have a path loss ranging within [120, 125) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002026 TDLBFD-002026 Uplink Power Control 1526732816 L.Traffic.User.PL8 Number of UEs that perform services and have a path loss ranging within [125, 130) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732817 L.Traffic.User.PL9 Number of UEs that perform services and have a path loss ranging within [130, 135) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526732818 L.Traffic.User.PL10 Number of UEs that perform services and have a path loss ranging within [135, 138) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526734141 L.Thrp.bits.DL.Phy Total downlink traffic volume at the physical layer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526734142 L.Thrp.bits.UL.Phy Total uplink traffic volume at the physical layer in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526734143 L.Thrp.bits.DL.Phy.Max Maximum downlink traffic volume of all services at the physical layer Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526734144 L.Thrp.bits.UL.Phy.Max Maximum uplink traffic volume of all services at the physical layer Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735160 L.E-RAB.SessionTime.UE.HighPrecision Total duration of UE data transmission time with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735161 L.E-RAB.SessionTime.HighPrecision Total duration of transmission time for services with all the QCI with the Multi-mode: None GSM: None UMTS: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name precision of 100 milliseconds in a cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526735162 L.E-RAB.SessionTime.HighPrecision.QCI1 Duration of data transmission for services with the QCI of 1 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735163 L.E-RAB.SessionTime.HighPrecision.QCI2 Duration of data transmission for services with the QCI of 2 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735164 L.E-RAB.SessionTime.HighPrecision.QCI3 Duration of data transmission for services with the QCI of 3 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735165 L.E-RAB.SessionTime.HighPrecision.QCI4 Duration of data transmission for services with the QCI of 4 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735166 L.E-RAB.SessionTime.HighPrecision.QCI5 Duration of data transmission for services with the QCI of 5 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735167 L.E-RAB.SessionTime.HighPrecision.QCI6 Duration of data transmission for services with the QCI of 6 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735168 L.E-RAB.SessionTime.HighPrecision.QCI7 Duration of data transmission for services with the QCI of 7 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735169 L.E-RAB.SessionTime.HighPrecision.QCI8 Duration of data transmission for services with the QCI of 8 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735170 L.E-RAB.SessionTime.HighPrecision.QCI9 Duration of data transmission for services with the QCI of 9 with the precision of 100 milliseconds in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name 1526735542 L.Thrp.Relay.bits.DL Total traffic volume of downlink PDCP SDUs transmitted by active RUEs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 TDLAOFD-080405 LAOFD-111202 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Out of Band Relay Introduction Out of Band Relay 1526735543 L.Thrp.Relay.Time.DL Total transmit duration of downlink PDCP SDUs transmitted by active RUEs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 TDLAOFD-080405 LAOFD-111202 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Out of Band Relay Introduction Out of Band Relay 1526735544 L.Thrp.Relay.bits.UL Total traffic volume of uplink PDCP SDUs received by active RUEs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 TDLAOFD-080405 LAOFD-111202 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Out of Band Relay Introduction Out of Band Relay 1526735545 L.Thrp.Relay.Time.UL Total transmit duration of uplink PDCP SDUs received by active RUEs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 TDLAOFD-080405 LAOFD-111202 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Out of Band Relay Introduction Out of Band Relay 1526735546 L.Traffic.DL.PktDelay.Relay.Time Total processing delay of downlink Multi-mode: None PDCP SDUs transmitted by RUEs in GSM: None a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 TDLAOFD-080405 LAOFD-111202 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Out of Band Relay Introduction Out of Band Relay 1526735547 L.Traffic.DL.PktDelay.Relay.Num Number of downlink PDCP SDUs successfully transmitted by RUEs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 TDLAOFD-080405 LAOFD-111202 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Out of Band Relay Introduction Out of Band Relay 1526735548 L.Traffic.UL.PktLoss.Relay.Loss Number of uplink PDCP SDUs discarded by RUEs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 TDLAOFD-080405 LAOFD-111202 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Out of Band Relay Introduction Out of Band Relay 1526735549 L.Traffic.UL.PktLoss.Relay.Tot Number of uplink PDCP PDUs expected to be received by RUEs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 TDLAOFD-080405 LAOFD-111202 Basic Scheduling Out of Band Relay Introduction Out of Band Relay 1526735550 L.ChMeas.PRB.Relay.DL.Used.Avg Average number of downlink PRBs used by RUEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 TDLAOFD-080405 LAOFD-111202 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA Out of Band Relay Introduction Out of Band Relay 1526735551 L.ChMeas.PRB.Relay.PUSCH.Avg Average number of uplink PRBs used by RUEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 TDLAOFD-080405 LAOFD-111202 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA Out of Band Relay Introduction Out of Band Relay 1526735568 L.Thrp.bits.DL.PDCP.Send Total PDCP-layer traffic volume of to-be-transmitted downlink data in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735569 L.Thrp.bits.DL.PDCP.Discard Total PDCP-layer traffic volume of Multi-mode: None discarded to-be-transmitted downlink GSM: None data in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735570 L.Thrp.bits.DL.RLC.Send Total RLC-layer traffic volume of downlink data in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735571 L.Thrp.bits.UL.RLC.Send Total RLC-layer traffic volume of uplink data in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735572 L.Thrp.bits.UL.PDCP.Discard Total PDCP-layer traffic volume of discarded uplink data in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526735573 L.Thrp.bits.UL.PDCP.Send Total PDCP-layer traffic volume of uplink data in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526736680 L.PDCP.Tx.Disc.Trf.SDU.PLMN.QCI.1 Number of downlink traffic SDUs discarded by the PDCP layer for services with a QCI of 1 for a specific operator in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736681 L.PDCP.Tx.Disc.Trf.SDU.PLMN.QCI.5 Number of downlink traffic SDUs discarded by the PDCP layer for services with a QCI of 5 for a specific operator in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736682 L.PDCP.Tx.TotRev.Trf.SDU.PLMN.QCI.1 Number of transmitted downlink Multi-mode: None traffic PDCP SDUs for services with GSM: None a QCI of 1 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736683 L.PDCP.Tx.TotRev.Trf.SDU.PLMN.QCI.5 Number of transmitted downlink Multi-mode: None traffic PDCP SDUs for services with GSM: None a QCI of 5 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736684 L.Traffic.UL.PktLoss.Loss.PLMN.QCI.1 Total number of discarded uplink Multi-mode: None PDCP SDUs for traffic services with GSM: None a QCI of 1 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736685 L.Traffic.UL.PktLoss.Loss.PLMN.QCI.5 Total number of discarded uplink Multi-mode: None PDCP SDUs for traffic services with GSM: None a QCI of 5 for a specific operator in a UMTS: None cell LTE: LBFD-002008 Radio Bearer Management Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736686 L.Traffic.UL.PktLoss.Tot.PLMN.QCI.1 Total number of expected uplink Multi-mode: None data packets for DRB services with a GSM: None QCI of 1 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736687 L.Traffic.UL.PktLoss.Tot.PLMN.QCI.5 Total number of expected uplink Multi-mode: None data packets for DRB services with a GSM: None QCI of 5 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736688 L.Traffic.DL.PktDelay.Num.PLMN.QCI.1 Number of successfully transmitted downlink PDCP SDUs for DRB services with a QCI of 1 for a specific operator in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736689 L.Traffic.DL.PktDelay.Num.PLMN.QCI.5 Number of successfully transmitted downlink PDCP SDUs for DRB services with a QCI of 5 for a specific operator in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736690 L.Traffic.DL.PktDelay.Time.PLMN.QCI.5 Total processing delay of downlink Multi-mode: None PDCP SDUs for DRB services with a GSM: None UMTS: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name QCI of 5 for a specific operator in a cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736691 L.Traffic.DL.PktDelay.Time.PLMN.QCI.1 Total processing delay of downlink Multi-mode: None PDCP SDUs for DRB services with a GSM: None QCI of 1 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736737 L.Traffic.DL.PktUuLoss.Loss.PLMN.QCI.1 Total number of discarded downlink Multi-mode: None PDCP SDUs for traffic services with GSM: None a QCI of 1 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736738 L.Traffic.DL.PktUuLoss.Loss.PLMN.QCI.5 Total number of discarded downlink Multi-mode: None PDCP SDUs for traffic services with GSM: None a QCI of 5 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736739 L.Traffic.DL.PktUuLoss.Tot.PLMN.QCI.1 Total number of expected downlink Multi-mode: None data packets for DRB services with a GSM: None QCI of 1 for a specific operator in a UMTS: None cell LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736740 L.Traffic.DL.PktUuLoss.Tot.PLMN.QCI.5 Multi-mode: None Counter ID Counter Name Counter Description Feature ID Feature Name Total number of expected downlink GSM: None data packets for DRB services with a UMTS: None QCI of 5 for a specific operator in a LTE: LBFD-002008 cell TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-001036 TDLOFD-001036 LOFD-001037 TDLOFD-001037 LOFD-070206 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier RAN Sharing with Dedicated Carrier Hybrid RAN Sharing 1526736791 L.Traffic.DL.PktDelay.Time Total downlink packet processing delay of DRB services with all QCIs (including extended QCIs) in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526736792 L.Traffic.DL.PktDelay.Num Total number of successfully transmitted downlink PDCP SDUs for DRB services with all QCIs (including extended QCIs) in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526736793 L.Traffic.DL.PktUuLoss.Loss Total number of downlink PDCP SDUs discarded for services carried on DRBs with all QCIs (including the QCI for PTT services and extended QCIs) in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526736794 L.Traffic.DL.PktUuLoss.Tot Total number of downlink PDCP SDUs transmitted for services carried on DRBs with all QCIs (including the QCI for PTT services and extended QCIs) in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526736795 L.Traffic.UL.PktLoss.Loss Total number of uplink PDCP SDUs discarded for services carried on DRBs with all QCIs (including the QCI for PTT services and extended QCIs) in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526736796 L.Traffic.UL.PktLoss.Tot Total number of expected uplink PDCP SDUs for services carried on DRBs with all QCIs (including the QCI for PTT services and extended QCIs) in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526736797 L.PDCP.Tx.Disc.Trf.SDU Total number of downlink PDCP SDUs discarded for services carried on DRBs with all QCIs (including the QCI for PTT services and extended QCIs) in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526736798 L.PDCP.Tx.TotRev.Trf.SDU Number of downlink PDCP SDUs transmitted for services carried on DRBs with all QCIs (including the QCI for PTT services and extended QCIs) in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 LBFD-002025 TDLBFD-002025 Basic Scheduling 1526736854 L.PDCP.Tx.TotRev.Trf.SDU.QCI.PTT Number of downlink PDCP SDUs Multi-mode: None transmitted for PTT services in a cell GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-081218 TDLOFD-110230 LTROFD-111201 TDLOFD-121103 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Enhanced Extended QCI Enhanced QoS for MCPTT (Trial) MCPTT QoS Management MCPTT QoS Management 1526736855 L.Traffic.UL.PktLoss.Loss.QCI.PTT Number of uplink PDCP SDUs discarded for PTT services in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LTROFD-111201 TDLOFD-121103 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling MCPTT QoS Management MCPTT QoS Management 1526736861 L.PDCP.Tx.Disc.Trf.SDU.QCI.PTT Number of downlink PDCP SDUs discarded for PTT services in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-081218 TDLOFD-110230 LTROFD-111201 TDLOFD-121103 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Enhanced Extended QCI Enhanced QoS for MCPTT (Trial) MCPTT QoS Management MCPTT QoS Management 1526736862 L.Traffic.UL.PktLoss.Tot.QCI.PTT Number of expected uplink PDCP SDUs for PTT services in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-081218 LTROFD-111201 TDLOFD-121103 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Enhanced Extended QCI MCPTT QoS Management MCPTT QoS Management 1526737710 L.ChMeas.CQI.DL.BorderUE.Total Accumulated value of wideband CQIs reported by CEUs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526737711 L.ChMeas.CQI.DL.BorderUE.Num Number of times wideband CQIs are Multi-mode: None reported by CEUs GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526737754 L.Thrp.bits.UL.BorderUE Uplink PDCP-layer traffic volume received for CEUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526737755 L.Thrp.bits.DL.BorderUE Downlink PDCP-layer traffic volume sent for CEUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description 1526737756 L.Thrp.bits.UL.SmallPkt.BorderUE PDCP-layer traffic volume scheduled Multi-mode: None for uplink small packets for CEUs in GSM: None a cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 Feature ID Feature Name Basic Scheduling Basic Scheduling 1526737757 L.Thrp.Time.UL.RmvSmallPkt.BorderUE Transmission duration of uplink data Multi-mode: None except small packets for CEUs in a GSM: None cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526737758 L.Thrp.bits.DL.LastTTI.BorderUE Downlink PDCP-layer traffic volume sent in the last TTI for CEUs before the buffer is empty in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526737759 L.Thrp.Time.DL.RmvLastTTI.BorderUE Data transmission duration for CEUs Multi-mode: None except the last TTI before the GSM: None downlink buffer is empty UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526737824 L.ChMeas.CCE.ULUsed.SRB Number of PDCCH CCEs used for initial transmitted uplink signaling in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526737839 L.ChMeas.PRB.TM1 Total number of used downlink PRBs in TM1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LEOFD-111305 Basic Scheduling Basic Scheduling Virtual 4T4R 1526737840 L.ChMeas.PRB.TM2 Total number of used downlink PRBs in TM2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LEOFD-111305 Basic Scheduling Basic Scheduling Virtual 4T4R 1526737841 L.ChMeas.PRB.TM3 Total number of used downlink PRBs in TM3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LEOFD-111305 Basic Scheduling Basic Scheduling Virtual 4T4R 1526737842 L.ChMeas.PRB.TM4 Total number of used downlink PRBs in TM4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LEOFD-111305 Basic Scheduling Basic Scheduling Virtual 4T4R 1526737844 L.ChMeas.PRB.TM6 Total number of used downlink PRBs in TM6 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LEOFD-111305 Basic Scheduling Basic Scheduling Virtual 4T4R 1526737849 L.Traffic.DL.PktUuLoss.Loss.QCI.PTT Total number of downlink PDCP SDUs discarded for PTT services in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LOFD-081218 TDLOFD-110230 LTROFD-111201 TDLOFD-121103 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Enhanced Extended QCI Enhanced QoS for MCPTT (Trial) MCPTT QoS Management Counter ID Counter Name Counter Description Feature ID Feature Name MCPTT QoS Management 1526737850 L.Traffic.DL.PktUuLoss.Tot.QCI.PTT Number of downlink PDCP SDUs Multi-mode: None transmitted for PTT services in a cell GSM: None over the Uu interface UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LTROFD-111201 TDLOFD-121103 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling MCPTT QoS Management MCPTT QoS Management 1526739662 L.ChMeas.DL.256QAM.CQI.DL.0 Number of wideband CQI reports Multi-mode: None with the value of 0 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739663 L.ChMeas.DL.256QAM.CQI.DL.1 Number of wideband CQI reports Multi-mode: None with the value of 1 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739664 L.ChMeas.DL.256QAM.CQI.DL.2 Number of wideband CQI reports Multi-mode: None with the value of 2 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739665 L.ChMeas.DL.256QAM.CQI.DL.3 Number of wideband CQI reports Multi-mode: None with the value of 3 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739666 L.ChMeas.DL.256QAM.CQI.DL.4 Number of wideband CQI reports Multi-mode: None with the value of 4 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739667 L.ChMeas.DL.256QAM.CQI.DL.5 Number of wideband CQI reports Multi-mode: None with the value of 5 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739668 L.ChMeas.DL.256QAM.CQI.DL.6 Number of wideband CQI reports Multi-mode: None with the value of 6 sent by downlink- GSM: None 256QAM-enabled UEs Dynamic Downlink Power Allocation Counter ID Counter Name Counter Description Feature ID Feature Name UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739669 L.ChMeas.DL.256QAM.CQI.DL.7 Number of wideband CQI reports Multi-mode: None with the value of 7 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739670 L.ChMeas.DL.256QAM.CQI.DL.8 Number of wideband CQI reports Multi-mode: None with the value of 8 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739671 L.ChMeas.DL.256QAM.CQI.DL.9 Number of wideband CQI reports Multi-mode: None with the value of 9 sent by downlink- GSM: None 256QAM-enabled UEs UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739672 L.ChMeas.DL.256QAM.CQI.DL.10 Number of wideband CQI reports with the value of 10 sent by downlink-256QAM-enabled UEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739673 L.ChMeas.DL.256QAM.CQI.DL.11 Number of wideband CQI reports with the value of 11 sent by downlink-256QAM-enabled UEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739674 L.ChMeas.DL.256QAM.CQI.DL.12 Number of wideband CQI reports with the value of 12 sent by downlink-256QAM-enabled UEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739675 L.ChMeas.DL.256QAM.CQI.DL.13 Number of wideband CQI reports with the value of 13 sent by downlink-256QAM-enabled UEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM Counter ID Counter Name Counter Description Feature ID Feature Name LEOFD-110301 TDLEOFD-110515 DL 256QAM 1526739676 L.ChMeas.DL.256QAM.CQI.DL.14 Number of wideband CQI reports with the value of 14 sent by downlink-256QAM-enabled UEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739677 L.ChMeas.DL.256QAM.CQI.DL.15 Number of wideband CQI reports with the value of 15 sent by downlink-256QAM-enabled UEs Multi-mode: None GSM: None UMTS: None LTE: LBFD-002016 LBFD-002025 TDLBFD-002016 TDLBFD-002025 LEOFD-110301 TDLEOFD-110515 Dynamic Downlink Power Allocation Basic Scheduling Dynamic Downlink Power Allocation Basic Scheduling DL 256QAM DL 256QAM 1526739682 L.ChMeas.PDSCH.DL.256QAM.MCS.0 Number of times MCS index 0 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739683 L.ChMeas.PDSCH.DL.256QAM.MCS.1 Number of times MCS index 1 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739684 L.ChMeas.PDSCH.DL.256QAM.MCS.2 Number of times MCS index 2 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739685 L.ChMeas.PDSCH.DL.256QAM.MCS.3 Number of times MCS index 3 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739686 L.ChMeas.PDSCH.DL.256QAM.MCS.4 Number of times MCS index 4 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739687 L.ChMeas.PDSCH.DL.256QAM.MCS.5 Multi-mode: None Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name Number of times MCS index 5 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739688 L.ChMeas.PDSCH.DL.256QAM.MCS.6 Number of times MCS index 6 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739689 L.ChMeas.PDSCH.DL.256QAM.MCS.7 Number of times MCS index 7 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739690 L.ChMeas.PDSCH.DL.256QAM.MCS.8 Number of times MCS index 8 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739691 L.ChMeas.PDSCH.DL.256QAM.MCS.9 Number of times MCS index 9 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739692 L.ChMeas.PDSCH.DL.256QAM.MCS.10 Number of times MCS index 10 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739693 L.ChMeas.PDSCH.DL.256QAM.MCS.11 Number of times MCS index 11 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739694 L.ChMeas.PDSCH.DL.256QAM.MCS.12 Number of times MCS index 12 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739695 L.ChMeas.PDSCH.DL.256QAM.MCS.13 Number of times MCS index 13 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739696 L.ChMeas.PDSCH.DL.256QAM.MCS.14 Number of times MCS index 14 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739697 L.ChMeas.PDSCH.DL.256QAM.MCS.15 Number of times MCS index 15 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739698 L.ChMeas.PDSCH.DL.256QAM.MCS.16 Number of times MCS index 16 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739699 L.ChMeas.PDSCH.DL.256QAM.MCS.17 Number of times MCS index 17 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739700 L.ChMeas.PDSCH.DL.256QAM.MCS.18 Number of times MCS index 18 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739701 L.ChMeas.PDSCH.DL.256QAM.MCS.19 Number of times MCS index 19 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739702 L.ChMeas.PDSCH.DL.256QAM.MCS.20 Number of times MCS index 20 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739703 L.ChMeas.PDSCH.DL.256QAM.MCS.21 Number of times MCS index 21 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739704 L.ChMeas.PDSCH.DL.256QAM.MCS.22 Number of times MCS index 22 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739705 L.ChMeas.PDSCH.DL.256QAM.MCS.23 Number of times MCS index 23 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739706 L.ChMeas.PDSCH.DL.256QAM.MCS.24 Number of times MCS index 24 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739707 L.ChMeas.PDSCH.DL.256QAM.MCS.25 Number of times MCS index 25 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739708 L.ChMeas.PDSCH.DL.256QAM.MCS.26 Number of times MCS index 26 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Counter ID Counter Name Counter Description Feature ID Feature Name LEOFD-110301 TDLEOFD-110515 DL 256QAM DL 256QAM 1526739709 L.ChMeas.PDSCH.DL.256QAM.MCS.27 Number of times MCS index 27 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739710 L.ChMeas.PDSCH.DL.256QAM.MCS.28 Number of times MCS index 28 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739711 L.ChMeas.PDSCH.DL.256QAM.MCS.29 Number of times MCS index 29 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739712 L.ChMeas.PDSCH.DL.256QAM.MCS.30 Number of times MCS index 30 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739713 L.ChMeas.PDSCH.DL.256QAM.MCS.31 Number of times MCS index 31 is selected for scheduling downlink256QAM-enabled UEs on the PDSCH in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LBFD-001005 TDLBFD-002025 TDLBFD-001005 LEOFD-110301 TDLEOFD-110515 Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM Basic Scheduling Modulation: DL/UL QPSK, DL/UL 16QAM, DL 64QAM DL 256QAM DL 256QAM 1526739788 L.Traffic.UL.PktDisorderLoss.Loss.QCI.1 Number of uplink PDCP SDUs of QCI 1 discarded because of SN disorder or changes in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526740440 L.Thrp.bits.DL.LastTTI.CAUser Downlink PDCP-layer traffic volume Multi-mode: None of CA UEs sent in the last TTI before GSM: None the buffer is empty UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LAOFD-001001 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling LTE-A Introduction 1526740441 L.Thrp.Time.DL.RmvLastTTI.CAUser Data transmission duration for CA UEs except the last TTI before the buffer is empty Radio Bearer Management Radio Bearer Management Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 LBFD-002025 TDLBFD-002025 LAOFD-001001 Basic Scheduling Basic Scheduling LTE-A Introduction 1526740488 L.Thrp.Time.UE.UL.Experienced Uplink data transmission duration from the time the UE buffer is not empty to the time the UE buffer is empty in a cell Multi-mode: None GSM: None UMTS: None LTE: LOFD-110205 LBFD-001015 Traffic Model Based Performance Optimization Enhanced Scheduling 1526740489 L.Thrp.bits.UE.UL.Experienced Uplink traffic volume of PDCP PDUs Multi-mode: None received from the time the UE buffer GSM: None is not empty to the time the UE UMTS: None buffer is empty in a cell LTE: LOFD-110205 LBFD-001015 Traffic Model Based Performance Optimization Enhanced Scheduling 1526741667 L.RBUsedOtherGroup.UL.PLMN Average number of other operator resource groups' uplink PRBs used by a specific operator in an operator resource group in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LOFD-001036 LOFD-001037 LOFD-070205 LOFD-070206 Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Adaptive SFN/SDMA Hybrid RAN Sharing 1526741668 L.RBUsedOtherGroup.DL.PLMN Average number of other operator resource groups' downlink PRBs used by a specific operator in an operator resource group in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 LOFD-001036 LOFD-001037 LOFD-070205 LOFD-070206 Basic Scheduling RAN Sharing with Common Carrier RAN Sharing with Dedicated Carrier Adaptive SFN/SDMA Hybrid RAN Sharing 1526741759 L.Thrp.Time.UL.BorderUE Total duration of receiving data from Multi-mode: None cell edge UEs in the uplink at the GSM: None PDCP layer in a cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526741760 L.Thrp.Time.DL.BorderUE Total duration of sending data to cell Multi-mode: None edge UEs in the downlink at the GSM: None PDCP layer in a cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526741763 L.ChMeas.PRB.PUSCH.Avg.BorderUE Average number of PUSCH PRBs occupied by CEUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526741767 L.ChMeas.PRB.PDSCH.Avg.BorderUE Average number of PDSCH PRBs occupied by CEUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526741811 L.Thrp.bits.UL.ExtQCI.Index0 Uplink traffic volume of PDCP PDUs Multi-mode: None of services with an extended QCI of GSM: None counter index 0 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741812 L.Thrp.bits.UL.ExtQCI.Index1 Uplink traffic volume of PDCP PDUs Multi-mode: None of services with an extended QCI of GSM: None counter index 1 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002032 TDLBFD-002032 1526741813 L.Thrp.bits.UL.ExtQCI.Index2 Uplink traffic volume of PDCP PDUs Multi-mode: None of services with an extended QCI of GSM: None counter index 2 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741814 L.Thrp.bits.UL.ExtQCI.Index3 Uplink traffic volume of PDCP PDUs Multi-mode: None of services with an extended QCI of GSM: None counter index 3 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741815 L.Thrp.bits.UL.ExtQCI.Index4 Uplink traffic volume of PDCP PDUs Multi-mode: None of services with an extended QCI of GSM: None counter index 4 UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741816 L.Thrp.Time.UL.ExtQCI.Index0 Uplink PDCP-layer transmission duration of services with an extended QCI of counter index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741817 L.Thrp.Time.UL.ExtQCI.Index1 Uplink PDCP-layer transmission duration of services with an extended QCI of counter index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741818 L.Thrp.Time.UL.ExtQCI.Index2 Uplink PDCP-layer transmission duration of services with an extended QCI of counter index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741819 L.Thrp.Time.UL.ExtQCI.Index3 Uplink PDCP-layer transmission duration of services with an extended QCI of counter index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741820 L.Thrp.Time.UL.ExtQCI.Index4 Uplink PDCP-layer transmission duration of services with an extended QCI of counter index 4 Multi-mode: None GSM: None UMTS: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741821 L.Thrp.bits.DL.ExtQCI.Index0 Downlink traffic volume of PDCP SDUs of services with an extended QCI of counter index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741822 L.Thrp.bits.DL.ExtQCI.Index1 Downlink traffic volume of PDCP SDUs of services with an extended QCI of counter index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741823 L.Thrp.bits.DL.ExtQCI.Index2 Downlink traffic volume of PDCP SDUs of services with an extended QCI of counter index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741824 L.Thrp.bits.DL.ExtQCI.Index3 Downlink traffic volume of PDCP SDUs of services with an extended QCI of counter index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741825 L.Thrp.bits.DL.ExtQCI.Index4 Downlink traffic volume of PDCP SDUs of services with an extended QCI of counter index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741826 L.Thrp.Time.DL.ExtQCI.Index0 Downlink PDCP-layer transmission duration of services with an extended QCI of counter index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741827 L.Thrp.Time.DL.ExtQCI.Index1 Downlink PDCP-layer transmission duration of services with an extended QCI of counter index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002032 1526741828 L.Thrp.Time.DL.ExtQCI.Index2 Downlink PDCP-layer transmission duration of services with an extended QCI of counter index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741829 L.Thrp.Time.DL.ExtQCI.Index3 Downlink PDCP-layer transmission duration of services with an extended QCI of counter index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741830 L.Thrp.Time.DL.ExtQCI.Index4 Downlink PDCP-layer transmission duration of services with an extended QCI of counter index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741831 L.Traffic.ActiveUser.UL.ExtQCI.Index0 Number of activated UEs with an extended QCI of counter index 0 in the uplink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741832 L.Traffic.ActiveUser.UL.ExtQCI.Index1 Number of activated UEs with an extended QCI of counter index 1 in the uplink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741833 L.Traffic.ActiveUser.UL.ExtQCI.Index2 Number of activated UEs with an extended QCI of counter index 2 in the uplink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741834 L.Traffic.ActiveUser.UL.ExtQCI.Index3 Number of activated UEs with an extended QCI of counter index 3 in the uplink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741835 L.Traffic.ActiveUser.UL.ExtQCI.Index4 Number of activated UEs with an extended QCI of counter index 4 in the uplink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 Radio Bearer Management Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741836 L.Traffic.ActiveUser.DL.ExtQCI.Index0 Number of activated UEs with an extended QCI of counter index 0 in the downlink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741837 L.Traffic.ActiveUser.DL.ExtQCI.Index1 Number of activated UEs with an extended QCI of counter index 1 in the downlink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741838 L.Traffic.ActiveUser.DL.ExtQCI.Index2 Number of activated UEs with an extended QCI of counter index 2 in the downlink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741839 L.Traffic.ActiveUser.DL.ExtQCI.Index3 Number of activated UEs with an extended QCI of counter index 3 in the downlink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741840 L.Traffic.ActiveUser.DL.ExtQCI.Index4 Number of activated UEs with an extended QCI of counter index 4 in the downlink Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002032 TDLBFD-002032 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Extended-QCI Extended-QCI 1526741888 L.Traffic.User.BorderUE.Avg Average number of CEUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526741889 L.Traffic.User.BorderUE.Max Maximum number of CEUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526741890 L.Traffic.User.IntraBoard.BorderUE.Avg Average number of intra-BBP CEUs in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526741891 L.Traffic.User.IntraBBUInterBoard.BorderUE.Avg Average number of intra-BBU interBBP CEUs in a cell Multi-mode: None GSM: None Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name UMTS: None LTE: LBFD-002025 TDLBFD-002025 1526741892 L.Traffic.User.InterBBU.BorderUE.Avg Average number of inter-BBU CEUs Multi-mode: None in a cell GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526741949 L.Thrp.bits.UE.UL.PL11 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [138,141) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741950 L.Thrp.bits.UE.UL.PL12 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [141,144) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741951 L.Thrp.bits.UE.UL.PL13 Total uplink throughput of PDCP PDUs for UEs whose path loss ranges within [144,147) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741952 L.Thrp.bits.UE.UL.PL14 Total uplink throughput of PDCP PDUs for UEs whose path loss is greater than or equal to 147 dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741953 L.Thrp.Time.UE.UL.RmvSmallPkt.PL11 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [138,141) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741954 L.Thrp.Time.UE.UL.RmvSmallPkt.PL12 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [141,144) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741955 L.Thrp.Time.UE.UL.RmvSmallPkt.PL13 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss ranges within [144,147) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 LBFD-002026 TDLBFD-002026 Uplink Power Control Uplink Power Control 1526741956 L.Thrp.Time.UE.UL.RmvSmallPkt.PL14 Data transmission duration of uplink PDCP PDUs (excluding small packets) for UEs whose path loss is greater than or equal to 147 dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741957 L.Thrp.bits.UE.UL.SmallPkt.PL11 Throughput of small uplink packets Multi-mode: None at the PDCP layer for UEs whose GSM: None path loss ranges within [138,141) dB UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741958 L.Thrp.bits.UE.UL.SmallPkt.PL12 Throughput of small uplink packets Multi-mode: None at the PDCP layer for UEs whose GSM: None path loss ranges within [141,147) dB UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741959 L.Thrp.bits.UE.UL.SmallPkt.PL13 Throughput of small uplink packets Multi-mode: None at the PDCP layer for UEs whose GSM: None path loss ranges within [144,147) dB UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741960 L.Thrp.bits.UE.UL.SmallPkt.PL14 Throughput of small uplink packets at the PDCP layer for UEs whose path loss is greater than or equal to 147 dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741961 L.Traffic.User.PL11 Number of UEs that perform services and have a path loss ranging between [138,141) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741962 L.Traffic.User.PL12 Number of UEs that perform services and have a path loss ranging between [141,144) dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741963 L.Traffic.User.PL13 Multi-mode: None GSM: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Number of UEs that perform services and have a path loss ranging between [144,147) dB UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526741964 L.Traffic.User.PL14 Number of UEs that perform services with a path loss greater than or equal to 147 dB Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 LBFD-002026 TDLBFD-002026 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Uplink Power Control Uplink Power Control 1526742092 L.Thrp.bits.UL.QCI.65 Uplink traffic volume for PDCP PDUs of services with the QCI of 65 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742093 L.Thrp.bits.UL.QCI.66 Uplink traffic volume for PDCP PDUs of services with the QCI of 66 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742094 L.Thrp.bits.UL.QCI.69 Uplink traffic volume for PDCP PDUs of services with the QCI of 69 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742095 L.Thrp.bits.UL.QCI.70 Uplink traffic volume for PDCP PDUs of services with the QCI of 70 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742096 L.Thrp.Time.UL.QCI.65 Receive duration of uplink PDCP Multi-mode: None PDUs for services with the QCI of 65 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742097 L.Thrp.Time.UL.QCI.66 Receive duration of uplink PDCP Multi-mode: None PDUs for services with the QCI of 66 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742098 L.Thrp.Time.UL.QCI.69 Receive duration of uplink PDCP Multi-mode: None PDUs for services with the QCI of 69 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742099 L.Thrp.Time.UL.QCI.70 Multi-mode: None GSM: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name Receive duration of uplink PDCP UMTS: None PDUs for services with the QCI of 70 LTE: LBFD-002008 in a cell TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526742100 L.Thrp.bits.DL.QCI.65 Downlink traffic volume for PDCP SDUs of services with the QCI of 65 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742101 L.Thrp.bits.DL.QCI.66 Downlink traffic volume for PDCP SDUs of services with the QCI of 66 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742102 L.Thrp.bits.DL.QCI.69 Downlink traffic volume for PDCP SDUs of services with the QCI of 69 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742103 L.Thrp.bits.DL.QCI.70 Downlink traffic volume for PDCP SDUs of services with the QCI of 70 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742104 L.Thrp.Time.DL.QCI.65 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 65 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742105 L.Thrp.Time.DL.QCI.66 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 66 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742106 L.Thrp.Time.DL.QCI.69 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 69 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742107 L.Thrp.Time.DL.QCI.70 Transmit duration of downlink PDCP Multi-mode: None SDUs for services with the QCI of 70 GSM: None in a cell UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742108 L.PDCP.Tx.TotRev.Trf.SDU.QCI.65 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 65 in a cell Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 1526742109 L.PDCP.Tx.TotRev.Trf.SDU.QCI.66 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 66 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742110 L.PDCP.Tx.TotRev.Trf.SDU.QCI.69 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 69 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742111 L.PDCP.Tx.TotRev.Trf.SDU.QCI.70 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 70 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742112 L.Traffic.DL.PktUuLoss.Loss.QCI.65 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 65 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742113 L.Traffic.DL.PktUuLoss.Loss.QCI.66 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 66 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742114 L.Traffic.DL.PktUuLoss.Loss.QCI.69 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 69 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742115 L.Traffic.DL.PktUuLoss.Loss.QCI.70 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 70 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742116 L.Traffic.DL.PktUuLoss.Tot.QCI.65 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 65 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742117 L.Traffic.DL.PktUuLoss.Tot.QCI.66 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 66 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742118 L.Traffic.DL.PktUuLoss.Tot.QCI.69 Number of downlink PDCP SDUs transmitted for services carried on Multi-mode: None GSM: None Radio Bearer Management Counter ID Counter Name Counter Description Feature ID Feature Name DRBs with a QCI of 69 in a cell over the Uu interface UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Basic Scheduling Basic Scheduling 1526742119 L.Traffic.DL.PktUuLoss.Tot.QCI.70 Number of downlink PDCP SDUs transmitted for services carried on DRBs with a QCI of 70 in a cell over the Uu interface Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742120 L.Traffic.UL.PktLoss.Loss.QCI.65 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 65 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742121 L.Traffic.UL.PktLoss.Loss.QCI.66 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 66 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742122 L.Traffic.UL.PktLoss.Loss.QCI.69 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 69 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742123 L.Traffic.UL.PktLoss.Loss.QCI.70 Number of uplink PDCP SDUs discarded for services carried on DRBs with a QCI of 70 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742124 L.Traffic.UL.PktLoss.Tot.QCI.65 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 65 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742125 L.Traffic.UL.PktLoss.Tot.QCI.66 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 66 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742126 L.Traffic.UL.PktLoss.Tot.QCI.69 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 69 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742127 L.Traffic.UL.PktLoss.Tot.QCI.70 Number of expected uplink PDCP SDUs for services carried on DRBs with a QCI of 70 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name TDLBFD-002025 1526742128 L.PDCP.Tx.Disc.Trf.SDU.QCI.65 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 65 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742129 L.PDCP.Tx.Disc.Trf.SDU.QCI.66 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 66 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742130 L.PDCP.Tx.Disc.Trf.SDU.QCI.69 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 69 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742131 L.PDCP.Tx.Disc.Trf.SDU.QCI.70 Number of downlink PDCP SDUs discarded for services carried on DRBs with a QCI of 70 in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526742156 L.ChMeas.PRB.UL.DrbUsed.Avg.QCI2 Average number of PRBs used by DRBs on the PUSCH for uplink QCI2 services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 LOFD-070205 Basic Scheduling Basic Scheduling Adaptive SFN/SDMA 1526742186 L.Thrp.Time.DL.SmallPktConverted Downlink data transmission duration Multi-mode: None with converted downlink smallGSM: None packet transmission duration UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526743729 L.ChMeas.BF.TM7.PRB.OL.Rank1 Total number of PRBs used for Multi-mode: None downlink beamforming in TM7 rank1 GSM: None mode UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLOFD-001049 TDLOFD-001061 Basic Scheduling Basic Scheduling Single Streaming Beamforming Dual Streaming Beamforming 1526743730 L.ChMeas.BF.TM8.PRB.OL.Rank1 Total number of PRBs used for downlink beamforming in TM8 rank 1 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLOFD-001049 TDLOFD-001061 Basic Scheduling Basic Scheduling Single Streaming Beamforming Dual Streaming Beamforming 1526743731 L.ChMeas.BF.TM8.PRB.OL.Rank2 Total number of PRBs used for downlink beamforming in TM8 rank 2 mode Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLOFD-001049 TDLOFD-001061 Basic Scheduling Basic Scheduling Single Streaming Beamforming Dual Streaming Beamforming 1526745771 L.Thrp.bits.DL.TrafficSizeBased Traffic-size-based downlink PDCPlayer traffic volume Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name LBFD-002025 TDLBFD-002025 1526745772 L.Thrp.Time.DL.TrafficSizeBased Traffic-size-based downlink PDCPlayer data transmission duration Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526745773 L.Thrp.BitRate.DL.UserExp.Bad.Num Number of times the downlink UEperceived data rate is low in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526745774 L.Thrp.BitRate.DL.UserExp.Good.Num Number of times the downlink UEperceived data rate is high in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526745980 L.ChMeas.PRB.DL.DrbUsed.Avg.QCI6 Average number of PRBs used by DRBs on the PDSCH for downlink QCI6 services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement 1526745981 L.ChMeas.PRB.DL.DrbUsed.Avg.QCI7 Average number of PRBs used by DRBs on the PDSCH for downlink QCI7 services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement 1526745982 L.ChMeas.PRB.DL.DrbUsed.Avg.QCI8 Average number of PRBs used by DRBs on the PDSCH for downlink QCI8 services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement 1526745983 L.ChMeas.PRB.DL.DrbUsed.Avg.QCI9 Average number of PRBs used by DRBs on the PDSCH for downlink QCI9 services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement 1526745984 L.ChMeas.PRB.UL.DrbUsed.Avg.QCI6 Average number of PRBs used by DRBs on the PUSCH for uplink QCI6 services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement 1526745985 L.ChMeas.PRB.UL.DrbUsed.Avg.QCI7 Average number of PRBs used by DRBs on the PUSCH for uplink QCI7 services Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement 1526745986 L.ChMeas.PRB.UL.DrbUsed.Avg.QCI8 Multi-mode: None Basic Scheduling Counter ID Counter Name Counter Description Feature ID Feature Name Average number of PRBs used by DRBs on the PUSCH for uplink QCI8 services GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 Basic Scheduling DACQ DACQ Enhancement Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement 1526745987 L.ChMeas.PRB.UL.DrbUsed.Avg.QCI9 Average number of PRBs used by DRBs on the PUSCH for uplink QCI9 services 1526745988 L.Thrp.TransferTime.DL.RmvLastTTI L.Thrp.TransferTime.DL.RmvLastTTI Multi-mode: None Downlink PDCP-layer data GSM: None transmission duration excluding the UMTS: None last TTI before the buffer is empty LTE: LBFD-002008 TDLBFD-002008 LBFD-002025 TDLBFD-002025 Radio Bearer Management Radio Bearer Management Basic Scheduling Basic Scheduling 1526746010 L.ChMeas.PRB.UL.DrbUsed.Avg.ExtQci.Index0 Average number of uplink PUSCH PRBs used by DRBs for services with an extended QCI of counter index 0 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746011 L.ChMeas.PRB.UL.DrbUsed.Avg.ExtQci.Index1 Average number of uplink PUSCH PRBs used by DRBs for services with an extended QCI of counter index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746012 L.ChMeas.PRB.UL.DrbUsed.Avg.ExtQci.Index2 Average number of uplink PUSCH PRBs used by DRBs for services with an extended QCI of counter index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746013 L.ChMeas.PRB.UL.DrbUsed.Avg.ExtQci.Index3 Average number of uplink PUSCH PRBs used by DRBs for services with an extended QCI of counter index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746014 L.ChMeas.PRB.UL.DrbUsed.Avg.ExtQci.Index4 Average number of uplink PUSCH PRBs used by DRBs for services with an extended QCI of counter index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746016 L.ChMeas.PRB.DL.DrbUsed.Avg.ExtQci.Index0 Average number of downlink PDSCH PRBs used by DRBs for Multi-mode: None GSM: None UMTS: None Basic Scheduling Basic Scheduling DACQ Counter ID Counter Name Counter Description Feature ID Feature Name services with an extended QCI of counter index 0 LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 DACQ Enhancement Extended-QCI Extended-QCI 1526746017 L.ChMeas.PRB.DL.DrbUsed.Avg.ExtQci.Index1 Average number of downlink PDSCH PRBs used by DRBs for services with an extended QCI of counter index 1 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746018 L.ChMeas.PRB.DL.DrbUsed.Avg.ExtQci.Index2 Average number of downlink PDSCH PRBs used by DRBs for services with an extended QCI of counter index 2 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746019 L.ChMeas.PRB.DL.DrbUsed.Avg.ExtQci.Index3 Average number of downlink PDSCH PRBs used by DRBs for services with an extended QCI of counter index 3 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746020 L.ChMeas.PRB.DL.DrbUsed.Avg.ExtQci.Index4 Average number of downlink PDSCH PRBs used by DRBs for services with an extended QCI of counter index 4 Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 TDLBFD-121201 TDLOFD-121206 LBFD-002032 TDLBFD-002032 Basic Scheduling Basic Scheduling DACQ DACQ Enhancement Extended-QCI Extended-QCI 1526746066 L.Traffic.DLRec.ContinusPktsLossIndex0.QCI1 Number of times the number of consecutively lost downlink QCI 1 packets falls into the Index 0 range Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526746067 L.Traffic.UL.ContinusPktsLossIndex0.QCI1 Number of times the number of consecutively lost uplink QCI 1 packets falls into the Index 0 range Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526746068 L.Traffic.DLRec.ContinusPktsLossIndex1.QCI1 Number of times the number of consecutively lost downlink QCI 1 packets falls into the Index 1 range Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526746069 L.Traffic.UL.ContinusPktsLossIndex1.QCI1 Number of times the number of consecutively lost uplink QCI 1 packets falls into the Index 1 range Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling 1526746070 L.Traffic.DLRec.ContinusPktsLossTimes.QCI1 Number of calls during which downlink QCI 1 packets are consecutively lost in a cell Multi-mode: None GSM: None UMTS: None LTE: LBFD-002025 TDLBFD-002025 Basic Scheduling Basic Scheduling Counter ID Counter Name Counter Description 1526746071 L.Traffic.UL.ContinusPktsLossTimes.QCI1 Number of calls during which uplink Multi-mode: None QCI 1 packets are consecutively lost GSM: None in a cell UMTS: None LTE: LBFD-002025 TDLBFD-002025 15 Feature ID Glossary For the acronyms, abbreviations, terms, and definitions, see Glossary. 16 Reference Documents 1. 3GPP TS 23.203: "Technical Specification Group Services and System Aspects; Policy and charging control architecture" 2. 3GPP TS 36.211: "Physical Channels and Modulation" 3. 3GPP TS 36.213: "Physical layer procedures" 4. 3GPP TS 36.306: "User Equipment (UE) radio access capabilities" 5. 3GPP TS 36.321: "Medium Access Control (MAC) protocol specification" 6. Adaptive ICIC Feature Parameter Description 7. DRX and Signaling Control Feature Parameter Description 8. Flexible User Steering Feature Parameter Description 9. MIMO Feature Parameter Description 10. Physical Channel Resource Management Feature Parameter Description 11. Power Control Feature Parameter Description 12. QoS Management Feature Parameter Description 13. TDM eICIC Feature Parameter Description 14. UL CoMP Feature Parameter Description 15. VoLTE Feature Parameter Description Feature Name Basic Scheduling Basic Scheduling