5G/5G-Advanced
The New Generation Wireless Access Technology
- 3rd Edition - November 21, 2023
- Imprint: Academic Press
- Authors: Erik Dahlman, Stefan Parkvall, Johan Skold
- Language: English
- Paperback ISBN:9 7 8 - 0 - 4 4 3 - 1 3 1 7 3 - 8
- eBook ISBN:9 7 8 - 0 - 4 4 3 - 1 3 1 7 4 - 5
5G Advanced: The Next Generation Wireless Access Technology, Third Edition follows the authors' highly celebrated books on 3G and 4G by providing a new level of insight into 5G N… Read more
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Request a sales quote5G Advanced: The Next Generation Wireless Access Technology, Third Edition follows the authors' highly celebrated books on 3G and 4G by providing a new level of insight into 5G NR. After an initial discussion of the background to 5G, including requirements, spectrum aspects and the standardization timeline, all technology features of the first phase of NR are described in detail. Included is a detailed description of the NR physical-layer structure and higher-layer protocols, RF and spectrum aspects and co-existence and interworking with LTE.
This book provides a good understanding of NR and the different NR technology components, giving insight into why a certain solution was selected.
- Covers the entire Release 17 in detail
- Includes the core elements of Release 18
- Contains three new chapters: NTN - describing NR operation over satellites (non-terrestrial networks) with a discussion on satellite communication, changes introduced in NR to support NTN operation (e.g., timing advance changes, HARQ enhancements); RedCap- describing NR reduced capability for (high-end) IoT applications; Broadcast- describing the NR broadcast operation
R&D engineers working in cellular communication systems, radio air-interface technologies, cellular telecommunication protocols, advanced radio access technologies for 4G/5G systems, or broadband cellular standards, Postgraduate students and university researchers in mobile and wireless communications
- Cover image
- Title page
- Table of Contents
- Copyright
- Preface
- Acknowledgments
- Abbreviations and acronyms
- Chapter 1 What is 5G?
- Abstract
- 1.1 The evolution of mobile communication – From 1G to 5G
- 1.2 3GPP and the standardization of mobile communication
- 1.3 The new generation – 5G NR
- References
- Chapter 2 5G standardization
- Abstract
- 2.1 Overview of standardization and regulation
- 2.2 ITU-R activities from 3G to 6G
- 2.3 5G and IMT-2020
- 2.4 3GPP standardization
- References
- Chapter 3 Spectrum for 5G
- Abstract
- 3.1 Spectrum for mobile systems
- 3.2 Frequency bands for NR
- References
- Chapter 4 LTE overview
- Abstract
- 4.1 LTE release 8 – Basic radio access
- 4.2 LTE evolution
- 4.3 Spectrum flexibility
- 4.4 Multi-antenna enhancements
- 4.5 Densification, small cells, and heterogeneous deployments
- 4.6 Device enhancements
- 4.7 New scenarios
- References
- Chapter 5 NR overview
- Abstract
- 5.1 NR basics in release 15
- 5.2 NR evolution and 5G advanced
- References
- Chapter 6 Radio-interface architecture
- Abstract
- 6.1 Overall system architecture
- 6.2 Radio protocol architecture
- 6.3 Scheduling
- 6.4 Quality-of-service handling
- 6.5 Radio resource control
- 6.6 Mobility
- References
- Chapter 7 Overall transmission structure
- Abstract
- 7.1 Transmission scheme
- 7.2 Time-domain structure
- 7.3 Frequency-domain structure
- 7.4 Bandwidth parts
- 7.5 Frequency-domain location of NR carriers
- 7.6 Carrier aggregation
- 7.7 Supplementary uplink
- 7.8 Duplex schemes
- 7.9 Antenna ports
- 7.10 Quasi-colocation
- Chapter 8 Channel measurements
- Abstract
- 8.1 Channel-state-information reference signals – CSI-RS
- 8.2 Device measurements and reporting
- 8.3 Sounding reference signals – SRS
- References
- Chapter 9 Transport-channel processing
- Abstract
- 9.1 Overview
- 9.2 Channel coding
- 9.3 Rate matching and physical-layer hybrid-ARQ functionality
- 9.4 Scrambling
- 9.5 Modulation
- 9.6 Layer mapping
- 9.7 Uplink DFT precoding
- 9.8 Multi-antenna precoding
- 9.9 Resource mapping
- 9.10 Downlink reserved resources
- 9.11 Reference signals
- References
- Chapter 10 Physical-layer control signaling
- Abstract
- 10.1 Downlink
- 10.2 Uplink
- References
- Chapter 11 Multi-antenna transmission
- Abstract
- 11.1 Introduction
- 11.2 NR downlink multi-antenna precoding
- 11.3 NR uplink multi-antenna precoding
- Chapter 12 Beam management
- Abstract
- 12.1 Initial beam establishment
- 12.2 Beam adjustment
- 12.3 Beam indication and TCI
- 12.4 Beam recovery
- 12.5 Multi-TRP operation
- Chapter 13 Retransmission protocols
- Abstract
- 13.1 Hybrid-ARQ with soft combining
- 13.2 RLC
- 13.3 PDCP
- References
- Chapter 14 Scheduling
- Abstract
- 14.1 Dynamic downlink scheduling
- 14.2 Dynamic uplink scheduling
- 14.3 Scheduling and dynamic TDD
- 14.4 Transmissions without a dynamic grant – semi-persistent scheduling and configured grants
- 14.5 Power-saving mechanisms
- References
- Chapter 15 Uplink power and timing control
- Abstract
- 15.1 Uplink power control
- 15.2 Uplink timing control
- References
- Chapter 16 Cell search and system information
- Abstract
- 16.1 The SSB
- 16.2 SS burst set – Multiple SSBs in the time domain
- 16.3 PBCH and MIB
- 16.4 Cell-defining and non-cell-defining SSBs
- 16.5 Providing remaining system information
- References
- Chapter 17 Random access
- Abstract
- 17.1 Step 1 – Preamble transmission
- 17.2 Step 2 – Random-access response
- 17.3 Step 3/4 – Contention resolution
- 17.4 Random access for supplementary uplink
- 17.5 Random access beyond initial access
- 17.6 Two-step RACH
- References
- Chapter 18 LTE/NR interworking and coexistence
- Abstract
- 18.1 LTE/NR dual-connectivity
- 18.2 LTE/NR coexistence
- References
- Chapter 19 Interference handling in TDD networks
- Abstract
- 19.1 Remote interference management
- 19.2 Cross-link interference
- References
- Chapter 20 NR in unlicensed spectrum
- Abstract
- 20.1 Unlicensed spectrum for NR
- 20.2 Technology components for unlicensed spectrum
- 20.3 Channel access in unlicensed spectra
- 20.4 Downlink data transmission
- 20.5 Uplink data transmission
- 20.6 Downlink control signaling
- 20.7 Uplink control signaling
- 20.8 Initial access
- References
- Chapter 21 Industrial IoT and URLLC enhancements
- Abstract
- 21.1 Uplink preemption
- 21.2 Uplink collision resolution
- 21.3 Configured grants and semi-persistent scheduling
- 21.4 PUSCH resource allocation enhancements
- 21.5 Downlink control channels
- 21.6 Feedback enhancements
- 21.7 Multi-connectivity with PDCP duplication
- 21.8 IIoT and URLLC in unlicensed spectra
- 21.9 Time synchronization for time-sensitive networks
- References
- Chapter 22 RedCap and small data transmission
- Abstract
- 22.1 RedCap devices
- 22.2 Small data transmission
- References
- Chapter 23 Multicast-broadcast services
- Abstract
- 23.1 Unicast, multicast and broadcast
- 23.2 Channel structure
- 23.3 Downlink data transmission
- 23.4 Hybrid ARQ retransmissions
- 23.5 Downlink control signaling
- 23.6 Scheduling
- 23.7 Mobility
- References
- Chapter 24 Integrated access backhaul
- Abstract
- 24.1 IAB architecture
- 24.2 Spectrum for IAB
- 24.3 Initial access of an IAB node
- 24.4 IAB-node transmission timing
- 24.5 DU/MT interaction
- 24.6 IAB mobility
- 24.7 Network-controlled repeaters
- References
- Chapter 25 Non-terrestrial NR access
- Abstract
- 25.1 Satellite basics
- 25.2 NR-based NTN
- 25.3 NTN extensions on release 18
- References
- Chapter 26 Sidelink communication
- Abstract
- 26.1 NR sidelink – Transmission and deployment scenarios
- 26.2 Resources for sidelink communication
- 26.3 Sidelink physical channels
- 26.4 Resource allocation
- 26.5 Sidelink hybrid-ARQ
- 26.6 Other sidelink procedures
- 26.7 Sidelink synchronization
- 26.8 Further sidelink enhancements
- References
- Chapter 27 Positioning
- Abstract
- 27.1 Downlink-based positioning
- 27.2 Uplink-based positioning
- References
- Chapter 28 RF characteristics
- Abstract
- 28.1 Spectrum flexibility implications
- 28.2 RF requirements in different Frequency Ranges
- 28.3 Channel bandwidth and spectrum utilization
- 28.4 Overall structure of device RF requirements
- 28.5 Overall structure of base station RF requirements
- 28.6 Overview of conducted RF requirements for NR
- 28.7 Conducted output power level requirements
- 28.8 Transmitted signal quality
- 28.9 Conducted unwanted emissions requirements
- 28.10 Conducted sensitivity and dynamic range
- 28.11 Receiver susceptibility to interfering signals
- 28.12 Radiated RF requirements for NR
- 28.13 Multi-standard radio base stations
- 28.14 Operation in non-contiguous spectrum
- 28.15 Multiband-capable base stations
- References
- Chapter 29 RF technologies at mm-wave frequencies
- Abstract
- 29.1 ADC and DAC considerations
- 29.2 LO generation and phase noise aspects
- 29.3 Power amplifiers efficiency in relation to unwanted emission
- 29.4 Filtering aspects
- 29.5 Receiver noise figure, dynamic range and bandwidth dependencies
- 29.6 Summary
- References
- Chapter 30 Further 5G evolution and the first step toward 6G
- Abstract
- 30.1 General enhancements to NR
- 30.2 Duplex evolution
- 30.3 AI/ML
- 30.4 Network energy efficiency
- 30.5 Zero-energy devices and ambient IoT
- 30.6 Joint communication and sensing
- 30.7 The road to 6G
- 30.8 Concluding remarks
- References
- References
- Index
- Edition: 3
- Published: November 21, 2023
- Imprint: Academic Press
- No. of pages: 712
- Language: English
- Paperback ISBN: 9780443131738
- eBook ISBN: 9780443131745
ED
Erik Dahlman
Erik Dahlman works at Ericsson Research and are deeply involved in 4G and 5G development and standardization since the early days of 3G research.
Affiliations and expertise
Ericsson, SwedenSP
Stefan Parkvall
Stefan Parkvall works at Ericsson Research and are deeply involved in 4G and 5G development and standardization since the early days of 3G research.
Affiliations and expertise
Ericsson, SwedenJS
Johan Skold
Johan Skold works at Ericsson Research and are deeply involved in 4G and 5G development and standardization since the early days of 3G research.
Affiliations and expertise
Ericsson, SwedenRead 5G/5G-Advanced on ScienceDirect