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5G Technology : 3GPP Evolution To 5G-Advanced / edited by Harri Holma, Antti Toskala, and Takehiro Nakamura.
Format
Book
Language
English
Εdition
Second edition.
Published/Created
Chichester, England : John Wiley & Sons Ltd, [2024]
©2024
Description
1 online resource (650 pages)
Availability
Available Online
O'Reilly Online Learning: Academic/Public Library Edition
Details
Subject(s)
5G mobile communication systems
[Browse]
Editor
Holma, Harri
[Browse]
Toskala, Antti
[Browse]
Nakamura, Takehiro
[Browse]
Bibliographic references
Includes bibliographical references and index.
Source of description
Description based on print version record.
Contents
Cover
Title Page
Copyright
Contents
About the Editors
List of Contributors
Foreword
Preface
Acknowledgment
Chapter 1 Introduction
1.1 Introduction
1.2 5G Targets
1.3 5G Technology Components
1.4 5G Spectrum
1.5 5G Capabilities
1.6 5G Capacity Boost
1.7 5G Standardization and Schedule
1.8 5G Use Cases
1.9 Evolution Path from LTE to 5G
1.10 5G‐Advanced
1.11 Summary
Chapter 2 5G Targets and Standardization
2.1 Introduction
2.2 ITU
2.2.1 IMT Vision for 2020 and Beyond
2.2.2 Standardization of IMT‐2020 Radio Interface Technologies
2.3 NGMN
2.3.1 NGMN 5G Use Cases
2.3.2 NGMN 5G Requirements
2.3.3 NGMN 5G Architecture Design Principles
2.3.4 Spectrum, Intellectual Property Rights (IPR), and Further Recommendations by NGMN
2.4 3GPP Schedule and Phasing
2.5 Evolution Towards 5G‐Advanced and 6G
References
Chapter 3 Technology Components
3.1 Introduction
3.2 Spectrum Utilization
3.2.1 Frequency Bands
3.2.2 Bandwidth Options
3.2.3 Spectrum Occupancy
3.2.4 Control Channel Flexibility
3.2.5 Dynamic Spectrum Sharing
3.3 Beamforming
3.4 Flexible Physical Layer and Protocols
3.4.1 Flexible Numerology
3.4.2 Short Transmission Time and Mini‐slot
3.4.3 Self‐Contained Subframe
3.4.4 Asynchronous HARQ
3.4.5 Lean Carrier
3.4.6 Adaptive Reference Signals
3.4.7 Adaptive UE Specific Bandwidth
3.4.8 Distributed MIMO
3.4.9 Waveforms
3.4.10 Channel Coding
3.4.11 Pipeline Processing and Front‐Loaded Reference Signals
3.4.12 Connected Inactive State
3.4.13 Grant‐Free Access
3.4.14 Cell Radius of 300 km
3.5 Network Slicing
3.6 Dual Connectivity with LTE
3.7 Radio Cloud and Edge Computing
3.8 Summary
Reference
Chapter 4 Spectrum
4.1 Introduction
4.2 Millimeter Wave Spectrum Above 20 GHz.
4.3 Mid‐Band Spectrum at 3.3-5.0 GHz and at 2.6 GHz
4.4 Low‐Band Spectrum Below 3 GHz
4.5 Unlicensed Band
4.6 Shared Band
4.7 3GPP Frequency Variants
4.8 Summary
Chapter 5 5G Architecture
5.1 Introduction
5.2 5G Architecture Options
5.3 5G Core Network Architecture
5.3.1 Access and Mobility Management Function
5.3.2 Session Management Function
5.3.3 User Plane Function
5.3.4 Data Storage Architecture
5.3.5 Policy Control Function
5.3.6 Network Exposure Function
5.3.7 Network Repository Function
5.3.8 Network Slice Selection
5.3.9 Non‐3GPP Interworking Function
5.3.10 Auxiliary 5G Core Functions
5.4 5G RAN Architecture
5.4.1 NG‐Interface
5.4.2 Xn‐Interface
5.4.3 E1‐Interface
5.4.4 F1‐Interface
5.5 Network Slicing
5.5.1 Interworking with LTE
5.6 Summary
Chapter 6 5G Physical Layer
6.1 Introduction
6.2 5G Multiple Access Principle
6.3 Physical Channels and Signals
6.4 Basic Structures for 5G Frame Structure
6.5 5G Channel Structures and Beamforming Basics
6.6 Random Access
6.7 Downlink User Data Transmission
6.8 Uplink User Data Transmission
6.9 Uplink Signaling Transmission
6.10 Downlink Signaling Transmission
6.11 Physical Layer Procedures
6.11.1 HARQ Procedure
6.11.2 Uplink Power Control
6.11.3 Timing Advance
6.12 5G MIMO and Beamforming Operation
6.12.1 Downlink MIMO Transmission Schemes
6.12.2 Beam Management Framework
6.12.2.1 Initial Beam Acquisition
6.12.2.2 Beam Measurement and Reporting
6.12.2.3 Beam Indication: QCL and Transmission Configuration Indicator (TCI)
6.12.2.4 Beam Recovery
6.12.3 CSI Framework
6.12.3.1 Reporting Settings
6.12.3.2 Resource Settings
6.12.3.3 Reporting Configurations
6.12.3.4 Report Quantity Configurations
6.12.4 CSI Components.
6.12.4.1 Channel Quality Indicator (CQI)
6.12.4.2 Precoding Matrix Indicator (PMI)
6.12.4.3 Resource Indicators: CRI, SSBRI, RI, LI
6.12.5 Uplink MIMO Transmission Schemes
6.12.5.1 Codebook‐Based Uplink Transmission
6.12.5.2 Non‐Codebook‐Based Uplink Transmission
6.13 Channel Coding with 5G
6.13.1 Channel Coding for Data Channel
6.13.1.1 5G LDPC Code Design
6.13.1.2 5G LDPC Coding Chain
6.13.2 Channel Coding for Control Channels
6.13.2.1 5G Polar Coding Design
6.14 Dual Connectivity
6.15 5G Data Rates
6.16 Physical Layer Measurements
6.17 UE Capability
6.18 Summary
Chapter 7 5G Radio Protocols
7.1 Introduction
7.2 5G Radio Protocol Layers
7.3 SDAP
7.3.1 Overview
7.3.2 QoS Flow Remapping
7.3.3 MDBV
7.3.4 Header
7.4 PDCP
7.4.1 Overview
7.4.2 Reordering
7.4.3 Security
7.4.4 Header Compression
7.4.5 Duplicates and Status Reports
7.4.6 Duplication
7.5 RLC
7.5.1 Overview
7.5.2 Segmentation
7.5.3 Error Correction
7.5.4 Transmissions Modes
7.5.5 Duplication
7.6 MAC Layer
7.6.1 Overview
7.6.2 Logical Channels
7.6.3 Random Access Procedure
7.6.4 HARQ and Transmissions
7.6.5 Scheduling Request
7.6.6 Logical Channel Prioritization and Multiplexing
7.6.7 BSR
7.6.8 PHR
7.6.9 DRX
7.6.10 Bandwidth Parts
7.6.11 BFD and Recovery
7.6.12 Other Functions
7.6.13 MAC PDU Structure
7.7 The RRC Protocol
7.7.1 Overview
7.7.2 Broadcast of System Information
7.7.2.1 Validity and Change of System Information
7.7.3 Paging
7.7.4 Overview of Idle and Inactive Mode Mobility
7.7.4.1 Cell Selection and Reselection Process
7.7.4.2 Intra‐frequency and Equal‐Priority Reselections
7.7.4.3 Inter‐Frequency/RAT Reselections
7.7.4.4 Cell Selection and Reselection Measurements.
7.7.4.5 Reselection Evaluation Altered by UE Mobility
7.7.5 RRC Connection Control and Mobility
7.7.5.1 RRC Connection Control
7.7.5.2 RRC Connection Setup from IDLE and INACTIVE
7.7.5.3 Mobility and Measurements in Connected Mode
7.7.6 RRC Support of Upper Layers
7.7.6.1 NAS Message Transfer
7.7.6.2 Network Slicing
7.7.6.3 UE Capability Transfer
7.7.7 Different Versions of Release 15 RRC Specifications
7.8 Radio Protocols in RAN Architecture
7.9 Summary
Chapter 8 Deployment Aspects
8.1 Introduction
8.2 Spectrum Resources
8.2.1 Spectrum Refarming and Dynamic Spectrum Sharing
8.3 Network Density
8.4 Mobile Data Traffic Growth
8.4.1 Mobile Data Volume
8.4.2 Traffic Asymmetry
8.5 Base Station Site Solutions
8.6 Electromagnetic Field (EMF) Considerations
8.7 Network Synchronization and Coordination Requirements
8.7.1 Main Interference Scenarios in TDD System
8.7.2 TDD Frame Configuration Options
8.7.3 Cell Size and Random Access Channel
8.7.4 Guard Period and Safety Zone
8.7.5 Intra‐Frequency Operation
8.7.6 Inter‐Operator Synchronization
8.7.7 Synchronization Requirements in 3GPP
8.7.7.1 Cell Phase Synchronization Accuracy
8.7.7.2 Maximum Receive Timing Difference (MRTD) for LTE-5G Dual Connectivity
8.7.8 Synchronization from Global Navigation Satellite System (GNSS)
8.7.9 Synchronization with ToP
8.7.10 Timing Alignment Between Vendors
8.8 5G Overlay with Another Vendor LTE
8.9 Summary
Chapter 9 Transport
9.1 5G Transport Network
9.1.1 5G Transport
9.1.2 Types of 5G Transport
9.1.3 Own Versus Leased Transport
9.1.4 Common Transport
9.1.5 Mobile Backhaul Tiers
9.1.6 Logical and Physical Transport Topology
9.1.7 Standards Viewpoint
9.2 Capacity and Latency.
9.2.1 Transport Capacity Upgrades
9.2.2 Access Link
9.2.3 Distribution Tier
9.2.4 Backhaul and High Layer Fronthaul Capacity
9.2.5 Low Layer Fronthaul Capacity
9.2.6 Latency
9.2.7 QoS Marking
9.3 Technologies
9.3.1 Client Ports
9.3.2 Networking Technologies Overview
9.4 Fronthaul and Backhaul Interfaces
9.4.1 Low Layer Fronthaul
9.4.1.1 Network Solutions
9.4.1.2 Security
9.4.2 NG Interface
9.4.2.1 Connectivity
9.4.2.2 Security
9.4.3 Xn/X2 Interfaces
9.4.3.1 Connectivity
9.4.3.2 Security
9.4.3.3 Dual Connectivity
9.4.4 F1 Interface
9.4.4.1 Security on F1
9.5 Specific Topics
9.5.1 Network Slicing in Transport
9.5.2 URLLC Transport
9.5.2.1 Latency
9.5.2.2 Reliability
9.5.3 IAB (Integrated Access and Backhaul)
9.5.4 NTNs (Non‐Terrestrial Networks)
9.5.5 Time‐Sensitive Networks
Chapter 10 5G Performance
10.1 Introduction
10.2 Peak Data Rates
10.3 Practical Data Rates
10.3.1 User Data Rates at 2.5-5.0 GHz
10.3.2 User Data Rates at 28 GHz
10.3.3 User Data Rates with Fixed Wireless Access at 28 GHz
10.4 Latency
10.4.1 User Plane Latency
10.4.2 Low Latency Architecture
10.4.3 Control Plane Latency
10.5 Link Budgets
10.5.1 Link Budget for Sub‐6‐GHz TDD
10.5.2 Link Budget for Low Band FDD
10.5.3 Link Budget for Millimeter Waves
10.6 Coverage for Sub‐6‐GHz Band
10.6.1 Signal Propagation at 3.5 GHz Band
10.6.2 Beamforming Antenna Gain
10.6.3 Uplink Coverage Solutions
10.6.3.1 Low Band LTE with Dual Connectivity
10.6.3.2 Low Band 5G with Carrier Aggregation
10.6.3.3 Supplemental Uplink
10.6.3.4 Benchmarking of Uplink Solutions
10.7 Massive MIMO and Beamforming Algorithms
10.7.1 Antenna Configuration
10.7.2 Beamforming Algorithms
10.7.2.1 Grid of Beams and User‐Specific Beams.
10.7.2.2 Zero Forcing.
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ISBN
1-119-81605-X
1-119-81607-6
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