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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