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5G New Radio : A Beam-Based Air Interface
5G New Radio : A Beam-Based Air Interface
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ISBN No.: 9781119582380
Pages: 480
Year: 202006
Format: Trade Cloth (Hard Cover)
Price: $ 198.65
Dispatch delay: Dispatched between 7 to 15 days
Status: Available

List of Contributors xiii Preface xv Acknowledgments xvii Abbreviations xix 1 Introduction and Background 1 Mihai Enescu and Karri Ranta-aho 1.1 Why 5G? 1 1.2 Requirements and Targets 2 1.2.1 System Requirements 3 1.2.2 5G Spectrum 7 1.3 Technology Components and Design Considerations 10 1.


3.1 Waveform 12 1.3.2 Multiple Access 13 1.3.3 Scalable/Multi Numerology 13 1.3.3.


1 Motivation for Multiple Numerologies 13 1.3.3.2 5G NR Numerologies 13 1.3.4 Multi-antenna 17 1.3.5 Interworking with LTE and Other Technologies 18 1.


3.6 5G Beam Based Technologies Across Release 15 and Release 16 19 1.3.6.1 Integrated Access and Backhaul 19 1.3.6.2 NR Operation on Unlicensed Frequency Bands (NR-U) 20 1.


3.6.3 Ultra-Reliable and Low Latency Communications 21 1.3.6.4 Vehicular-to-everything (V2X) 21 1.3.6.


5 Positioning 22 1.3.6.6 System Enhancements 22 2 Network Architecture and NR Radio Protocols 25 Dawid Koziol and Helka-Liina Määttänen 2.1 Architecture Overview 25 2.2 Core Network Architecture 26 2.2.1 Overview 26 2.


2.2 Service Request Procedure 29 2.3 Radio Access Network 31 2.3.1 NR Standalone RAN Architecture 31 2.3.2 Additional Architectural Options 32 2.3.


3 CU-DU and UP-CP Split 37 2.4 NR Radio Interface Protocols 41 2.4.1 Overall Protocol Structure 41 2.4.2 Main Functions of NR Radio Protocols 44 2.4.3 SDAP Layer 47 2.


4.4 PDCP Layer 47 2.4.4.1 PDCP Packet Transmission 48 2.4.4.2 PDCP Duplication 49 2.


4.4.3 Access Stratum (AS) Security 50 2.4.4.4 Robust Header Compression (ROHC) 50 2.4.5 RLC 50 2.


4.5.1 Segmentation and Concatenation 51 2.4.5.2 RLC Reordering 51 2.4.5.


3 ARQ Retransmissions and Status Reporting 52 2.4.6 MAC Protocol 53 2.4.6.1 Overview 53 2.4.6.


2 Multiplexing and Demultiplexing 53 2.4.6.3 Logical Channel Prioritization 54 2.4.6.4 Hybrid Automatic Repeat Request (HARQ) 57 2.4.


6.5 BWP Operation 58 2.4.6.6 Scheduling Request 60 2.4.6.7 Semi Persistent Scheduling and Configured Grants 60 2.


4.6.8 Discontinuous Reception (DRX) 60 2.4.6.9 Buffer Status Reports 62 2.4.6.


10 Timing Advance Operation 62 2.4.6.11 MAC Control Elements 63 2.4.7 Radio Resource Control (RRC) 67 2.4.7.


1 Overview 67 2.4.7.2 RRC State Machine 68 2.4.7.3 Cells, Cell Groups, and Signaling Radio Bearers 70 2.4.


7.4 System Information 71 2.4.7.5 Unified Access Control (UAC) 78 2.4.7.6 Connection Control 79 2.


4.7.7 NAS Information Transfer 87 2.4.7.8 UE Assistance Information 87 2.4.7.


9 RRC PDU Structure 89 3 PHY Layer 95 Mihai Enescu, Youngsoo Yuk, Fred Vook, Karri Ranta-aho, Jorma Kaikkonen, Sami Hakola, Emad Farag, Stephen Grant, and Alexandros Manolakos 3.1 Introduction (Mihai Enescu, Nokia Bell Labs, Finland) 95 3.2 NRWaveforms (Youngsoo Yuk, Nokia Bell Labs, Korea) 96 3.2.1 Advanced CP-OFDM Waveforms for Multi-Service Support 96 3.2.2 Low PAPR Waveform for Coverage Enhancement 102 3.2.


3 Considerations on the Waveform for above 52.6 GHz 104 3.3 Antenna Architectures in 5G (Fred Vook, Nokia Bell Labs, USA) 105 3.3.1 Beamforming 105 3.3.2 Antenna Array Architectures 108 3.3.


3 Antenna Panels 110 3.3.4 Antenna Virtualization 111 3.3.5 Antenna Ports 113 3.3.6 Beamforming for a Beam-Based Air Interface 115 3.4 Frame Structure and Resource Allocation (Karri Ranta-aho, Nokia Bell Labs, Finland) 115 3.


4.1 Resource Grid 115 3.4.2 Data Scheduling and HARQ 118 3.4.3 Frequency Domain Resource Allocation and Bandwidth Part 119 3.4.4 Time Domain Resource Allocation 123 3.


5 Synchronization Signals and Broadcast Channels in NR Beam-Based System (Jorma Kaikkonen, Sami Hakola, Nokia Bell Labs, Finland) 125 3.5.1 SS/PBCH Block 125 3.5.2 Synchronization Signal Structure 126 3.5.3 Broadcast Channels 128 3.5.


3.1 PBCH 128 3.5.3.2 SIB1 129 3.5.3.3 Delivery of Other Broadcast Information and Support of Beamforming 135 3.


6 Physical Random Access Channel (PRACH) (Emad Farag, Nokia Bell Labs, USA) 139 3.6.1 Introduction 139 3.6.2 Preamble Sequence 140 3.6.2.1 Useful Properties of Zhadoff-Chu Sequences 140 3.


6.2.2 Unrestricted Preamble Sequences 142 3.6.2.3 Restricted Preamble Sequences 144 3.6.3 Preamble Formats 147 3.


6.3.1 Long Sequence Preamble Formats 148 3.6.3.2 Short Sequence Preamble Formats 149 3.6.4 PRACH Occasion 150 3.


6.5 PRACH Baseband Signal Generation 155 3.7 CSI-RS (Stephen Grant, Ericsson, USA) 159 3.7.1 Overview 159 3.7.1.1 CSI-RS Use Cases 159 3.


7.1.2 Key Differences with LTE 161 3.7.2 Physical Layer Design 162 3.7.2.1 Mapping to Physical Resources 162 3.


7.2.2 Antenna Port Mapping 167 3.7.2.3 Sequence Generation and Mapping 167 3.7.2.


4 Time Domain Behavior 168 3.7.2.5 Multiplexing with Other Signals 169 3.7.3 Zero Power CSI-RS 170 3.7.4 Interference Measurement Resources (CSI-IM) 170 3.


7.5 CSI-RS Resource Sets 171 3.7.5.1 CSI-RS for Tracking 171 3.7.5.2 CSI-RS for L1-RSRP Measurement 173 3.


8 PDSCH and PUSCH DM-RS, Qualcomm Technologies, Inc. (Alexandros Manolakos, Qualcomm Technologies, Inc, USA) 176 3.8.1 Overview 176 3.8.1.1 What is DM-RS Used for? 176 3.8.


1.2 Key Differences from LTE 176 3.8.2 Physical Layer Design 178 3.8.2.1 Mapping to Physical Resources 178 3.8.


2.2 Default DM-RS Pattern for PDSCH and PUSCH 189 3.8.2.3 Sequence Generation and Scrambling 193 3.8.3 Procedures and Signaling 200 3.8.


3.1 Physical Resource Block Bundling 200 3.8.3.2 DM-RS to PDSCH and PUSCH EPRE Ratio 205 3.8.3.3 Antenna Port DCI Signaling 207 3.


8.3.4 Quasi-Colocation Considerations for DM-RS of PDSCH 209 3.9 Phrase- Tracking RS (Youngsoo Yuk, Nokia Bell Labs, Korea) 210 3.9.1 Phase Noise and its Modeling 210 3.9.1.


1 Phase Noise in mm-Wave Frequency and its Impact to OFDM System 210 3.9.1.2 Principles of Oscillator Design and Practical Phase Noise Modeling 211 3.9.2 Principle of Phase Noise Compensation 216 3.9.3 NR PT-RS Structure and Procedures 221 3.


9.3.1 PT-RS Design for Downlink 221 3.9.3.2 PT-RS Design for Uplink CP-OFDM 224 3.9.3.


3 PT-RS Design for Uplink DFT-s-OFDM 225 3.10 SRS (Stephen Grant, Ericsson, USA) 228 3.10.1 Overview 228 3.10.1.1 SRS Use Cases 228 3.10.


1.2 Key Differences with LTE 229 3.10.2 Physical Layer Design 230 3.10.2.1 Mapping to Physical Resources 230 3.10.


2.2 Antenna Port Mapping 237 3.10.2.3 Sequence Generation and Mapping 239 3.10.2.4 Multiplexing with Other UL Signals 243 3.


10.3 SRS Resource Sets 244 3.10.3.1 SRS for Downlink CSI Acquisition for Reciprocity-Based Operation 244 3.10.3.2 SRS for Uplink CSI Acquisition 245 3.


10.3.3 SRS for Uplink Beam Management 246 3.11 Power Control (Mihai Enescu, Nokia Bell Labs, Finland) 246 3.12 DL and UL Transmission Framework (Mihai Enescu, Nokia, Karri Ranta-aho, Nokia Bell Labs, Finland) 249 3.12.1 Downlink Transmission Schemes for PDSCH 249 3.12.


2 Downlink Transmit Processing 250 3.12.2.1 PHY Processing for PDSCH 250 3.12.2.2 PHY Processing for PDCCH 251 3.12.


3 Uplink Transmission Schemes for PUSCH 254 3.12.3.1 Codebook Based UL Transmission 254 3.12.3.2 Non-Codebook Based UL Transmission 255 3.12.


4 Uplink Transmit Processings 255 3.12.4.1 PHY Processing for PUSCH 255 3.12.5 Bandwidth Adaptation 256 3.12.5.


1 Overview 256 3.12.5.2 Support for Narrow-Band UE in a Wide-Band Cell 257 3.12.5.3 Saving Battery with Bandwidth Adaptation 257 3.12.


5.4 Spectrum Flexibility 260 3.12.6 Radio Network Temporary Identifiers (RNTI) 260 4 Main Radio Interface Related System Procedures 261 Jorma Kaikkonen, Sami Hakola, Emad Farag, Mihai Enescu, Claes Tidestav, Juha Karjalainen, Timo Koskela, Sebastian Faxér, Dawid Koziol, and Helka-Liina Määttänen 4.1 Initial Access (Jorma Kaikkonen, Sami Hakola, Nokia Bell Labs, Finland, Emad Farag, Nokia Bell Labs, USA) 261 4.1.1 Cell Search 261 4.1.


1.1 SS/PBCH Block Time Pattern 262 4.1.1.2 Initial Cell Selection Related Assistance Information 265 4.1.2 Random Access 265 4.1.


2.1 Introduction 265 4.1.2.2 Higher Layer Random Access Procedures 266 4.1.2.3 Random Access Use Cases 274 4.


1.2.4 Physical Layer Random Access Procedures 274 4.1.2.5 RACH in Release 16 283 4.2 Beam Management (Mihai Enescu, Nokia Bell Labs, Finland, Claes Tidestav, Ericsson, Sweden, Sami Hakola, Juha Karjalainen, Nokia Bell Labs, Finland) 287 4.2.


1 Introduction to Beam Management 287 4.2.2 Beam Management Procedures 289 4.2.2.1 Beamwidths 291 4.2.2.


2 Beam Determination 291 4.2.3 Beam Indication Framework for DL Quasi Co-location and TCI States 296 4.2.3.1 QCL 296 4.2.3.


2 TCI Framework 297 4.2.4 Beam Indication Framework for UL Transmission 303 4.2.4.1 SRS Configurations 305 4.2.4.


2 Signaling Options for SRS Used for UL Beam Management 306 4.2.4.3 Beam Reporting from a UE with Multiple Panels 306 4.2.5 Reporting of L1-RSRP 307 4.2.6 Beam Failure Detection and Recovery.



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