5G NR : architecture, technology, implementation, and operation of 3GPP New Radio standards / Sassan Ahmadi.

Format:

Book

Author/Creator:

Ahmadi, Sassan, author.

Language:

English

Subjects (All):

Wireless communication systems.

Cell phone systems--Standards.

Cell phone systems.

Physical Description:

1 online resource (936 pages)

Edition:

1st edition

Other Title:

Architecture, technology, implementation, and operation of 3GPP new radio standards

Fifth generation new radio

Place of Publication:

London, United Kingdom : Academic Press is an imprint of Elsevier, [2019]

System Details:

text file

Summary:

5G NR: Architecture, Technology, Implementation, and Operation of 3GPP New Radio Standards is an in-depth, systematic, technical reference on 3GPP’s New Radio standards (Release 15 and beyond), covering the underlying theory, functional descriptions, practical considerations, and implementation of the 5G new radio access technology. The book describes the design and operation of individual components and shows how they are integrated into the overall system and operate from a system’s perspective. Uniquely, this book gives detailed information on RAN protocol layers, transports, network architectures, and services, as well as practical implementation and deployment issues, making it suitable for researchers and engineers who are designing and developing 5G systems. Reflecting on the author's 30 plus years of experience in signal processing, microelectronics, and wireless communication system design, this book is ideal for professional engineers, researchers, and graduate students who are working and researching in cellular communication systems and protocols as well as mobile broadband wireless standards. Features strong focus on practical considerations, implementation, and deployment issues Takes a top-down approach to explain system operation and functional interconnection Covers all functional components, features, and interfaces based on clear protocol structure and block diagrams Describes RF and transceiver design considerations in sub-6 GHz and mmWave bands Covers network slicing, SDN/NFV/MEC networks and cloud, and virtualized RAN architectures Comprehensive coverage of NR multiantenna techniques and beamformed operation A consistent and integrated coverage reflecting the author’s decades of experience in developing 3G, 4G, and 5G technologies and writing two successful books in these areas

Contents:

Front Cover

5G NR

Copyright Page

Contents

Acknowledgments

List of Abbreviations

Introduction and Background

1 Introduction to 5G

2 Use Cases and Deployment Scenarios

2.1 Use Cases

2.2 Deployment Scenarios

3 Key Performance Indicators, Architectural, System, and Service Requirements

3.1 Definition of the Performance Metrics

3.2 Test Environments

3.3 High-Level Architectural Requirements

3.4 System Performance Requirements

3.5 Service Requirements

4 ITU-R IMT-2020 Standardization Activities

5 3GPP 5G Standardization Activities

6 Spectrum and Regulations

7 Future Outlook

References

ITU-R Specifications

3GPP Specifications

Articles, Books, White Papers, and Application Notes

1 5G Network Architecture

1.1 Design Principles and Prominent Network Topologies

1.1.1 Network and Service Requirements

1.1.2 Virtualization of Network Functions

1.1.2.1 Architectural Aspects

1.1.2.2 Functional Aspects

1.1.2.3 Operational Aspects

1.1.2.4 Legacy Support and Interworking Aspects

1.1.3 Separation of Control and User Planes (Software-Defined Networks)

1.1.3.1 Architectural Aspects

1.1.4 Network Slicing

1.1.5 Heterogeneous and Ultra-dense Networks

1.1.6 Cloud-RAN and Virtual-RAN

1.1.6.1 Architectural Aspects

1.1.6.2 Fronthaul Transport and Functional Split Options

1.1.6.3 Backhaul Transport Options

1.1.7 Mobile Edge Computing

1.1.7.1 Service and Deployment Scenarios

1.1.7.2 Architectural Aspects

1.1.8 Network Sharing

1.2 Reference Architectures

1.2.1 Access Network

1.2.1.1 Reference Architecture: Network Entities and Interfaces

1.2.1.1.1 Xn Control-Plane/User-Plane Functions and Procedures

1.2.1.1.2 F1 Control-Plane/User-Plane Functions and Procedures

1.2.1.1.3 E1 Control-Plane Functions and Procedures.

1.2.1.1.4 NG Control-Plane/User-Plane Functions and Procedures

1.2.1.2 Bearers and Identifiers

1.2.1.2.1 Radio Bearers and Packet Data Unit Sessions

1.2.1.2.2 Radio Network Identifiers

1.2.1.3 User-Plane and Control-Plane Protocol Stacks

1.2.2 Core Network

1.2.2.1 Reference Architecture: Network Entities and Interfaces

1.2.2.2 PDN Sessions and 5GC Identifiers

1.2.2.3 User-Plane and Control-Plane Protocol Stacks

1.2.2.3.1 Control-Plane Protocol Stacks

1.2.2.3.2 User-Plane Protocol Stacks

1.3 Dual Connectivity and Multi-connectivity Schemes

1.4 LTE-NR Interworking and Deployment Scenarios

1.4.1 RAN-Level and CN-Level Interworking

1.4.2 5G Deployments Scenarios and Architecture Options

1.5 Network Aspects of Mobility and Power Management

1.5.1 Mobility Management

1.5.2 Network-Controlled Power Management

1.6 Quality-of-Service Framework

1.7 Security Framework

ETSI Specifications

2 New Radio Access Layer 2/3 Aspects and System Operation

2.1 Overview of Layer 2 and Layer 3 Functions

2.2 Layer 2 Functions and Services

2.2.1 Medium Access Control Sublayer

2.2.2 Radio Link Control Sublayer

2.2.3 Packet Data Convergence Protocol Sublayer

2.2.3.1 PDCP Services and Functions

2.2.3.2 Header Compression Function

2.2.3.3 Ciphering and Integrity Protection Functions

2.2.4 Service Data Adaptation Protocol Sublayer

2.3 Layer 3 Functions and Services

2.3.1 Radio Resource Control Sublayer

2.3.2 System Information

2.3.3 User Equipment States and State Transitions

2.3.3.1 Idle Mode Procedures

2.3.3.2 Inactive Mode Procedures

2.3.3.3 Connected Mode Procedures

2.3.4 User Equipment Capability

2.4 Discontinuous Reception and Power-Saving Schemes.

2.5 Mobility Management, Handover, and UE Measurements

2.5.1 Network-Controlled Mobility

2.5.1.1 Control-Plane Handover Procedures

2.5.1.2 User-Plane Handover Procedures

2.5.2 UE-Based Mobility

2.5.3 Paging

2.5.4 Measurements

2.6 UE and Network Identifiers

2.7 Random-Access Procedure (L2/L3 Aspects)

2.8 Multi-radio Dual Connectivity (L2/L3 Aspects)

2.9 Carrier Aggregation (L2/L3 Aspects)

IETF Specifications

3 New Radio Access Physical Layer Aspects (Part 1)

3.1 Channel Models and Propagation Characteristics

3.1.1 Characteristics of Wireless Channels

3.1.1.1 Path Loss Models

3.1.1.2 Delay Spread

3.1.1.3 Doppler Spread

3.1.1.4 Angular Spread

3.1.1.5 Blockage

3.1.1.6 Oxygen Absorption

3.1.1.7 LoS Path Loss Probability

3.1.2 Two- and Three-Dimensional Channel Models

3.2 Waveforms

3.2.1 OFDM Basics and Transmission Characteristics

3.2.1.1 Cyclic Prefix

3.2.1.2 Pre- and Post-processing Signal-to-Noise Ratio

3.2.1.3 Peak-to-Average Power Ratio

3.2.1.4 Error Vector Magnitude

3.2.1.5 Carrier Frequency Offset

3.2.1.6 Phase Noise

3.2.2 DFT-S-OFDM Basics and Transmission Characteristics

3.2.3 Other Waveform Candidates

3.2.3.1 Filtered-OFDM

3.2.3.2 Filter Bank Multicarrier

3.2.3.3 Universal Filtered Multicarrier

3.2.3.4 Generalized Frequency Division Multiplexing

3.2.3.5 Faster Than Nyquist Signal Processing

3.2.3.6 Comparison of the Candidate Waveforms

3.3 Multiple-Access Schemes

3.3.1 Orthogonal Frequency Division Multiple Access

3.3.2 Single-Carrier Frequency Division Multiple Access

3.3.3 Non-orthogonal Multiple-Access Schemes

3.3.3.1 Sparse Code Multiple Access

3.3.3.2 Power-Domain Non-orthogonal Multiple Access.

3.3.3.3 Scrambling-Based and Spreading-Based NOMA Schemes

3.4 Duplex Schemes

3.4.1 Frequency and Time Division Duplex Schemes

3.4.2 Half-Duplex and Flexible-Duplex Schemes

3.4.3 Full-Duplex Schemes

3.5 Operating Frequency Bands

3.6 Frame Structure and Numerology

3.7 Time-Frequency Resources

3.7.1 Physical Resource Blocks

3.7.2 Bandwidth Part

3.7.3 Resource Allocation

3.7.3.1 Resource Allocation in Time Domain

3.7.3.2 Resource Allocation in Frequency Domain

3.7.3.3 Physical Resource Block Bundling

3.7.4 Resource Allocation for Grant-Free/Semi-persistent Scheduling

4 New Radio Access Physical Layer Aspects (Part 2)

4.1 Downlink Physical Layer Functions and Procedures

4.1.1 Overall Description of Downlink Physical Layer

4.1.2 Reference Signals

4.1.2.1 Demodulation Reference Signals

4.1.2.2 Phase Tracking Reference Signals

4.1.2.3 Channel State Information Reference Signals

4.1.2.4 Tracking Reference Signals

4.1.3 Control Channels

4.1.3.1 Physical Broadcast Channel

4.1.3.2 Physical Downlink Control Channel

4.1.3.2.1 Structure and Physical Layer Processing of PDCCH

4.1.3.2.2 UE Group-Common Signaling

4.1.3.2.3 Downlink Control Information Formats

DCI Format 0_0

DCI Format 0_1

DCI Format 1_0

DCI Format 1_1

DCI Format 2_0

DCI Format 2_1

DCI Format 2_2

DCI Format 2_3

4.1.3.2.4 Common and UE-Specific Search Spaces

4.1.3.2.5 Dynamic and Semi-persistent Scheduling

4.1.4 Synchronization Signals

4.1.4.1 Primary Synchronization Sequence

4.1.4.2 Secondary Synchronization Sequence

4.1.4.3 Synchronization Signal Blocks

4.1.5 Physical Downlink Shared Channel

4.1.6 CSI Measurement and Reporting and Beam Management.

4.1.6.1 CSI Measurement and Reporting

4.1.6.2 Beam Management

4.1.7 Channel Coding and Modulation Schemes

4.1.7.1 Principles of Polar Coding

4.1.7.2 NR Polar Coding

4.1.7.3 Principles of Low Density Parity Check Coding

4.1.7.4 NR Low Density Parity Check Coding

4.1.7.5 Modulation Schemes and MCS Determination

4.1.8 HARQ Operation and Protocols

4.1.8.1 HARQ Principles

4.1.8.2 UE Processing Times, HARQ Protocol and Timing

4.1.8.3 Semi-static/Dynamic Codebook HARQ-ACK Multiplexing

4.1.9 Downlink MIMO Schemes

4.1.9.1 Capacity of MIMO Channels

4.1.9.2 Single-User and Multi-user MIMO

4.1.9.3 Analog, Digital, and Hybrid Beamforming

4.1.9.3.1 Analog Beamforming

4.1.9.3.2 Digital Beamforming

4.1.9.3.3 Hybrid Beamforming

4.1.9.4 Full-Dimension MIMO

4.1.9.5 Large-Scale (Massive) MIMO Systems

4.1.9.6 NR Multi-antenna Transmission Schemes

4.2 Uplink Physical Layer Functions and Procedures

4.2.1 Overall Description of Uplink Physical Layer

4.2.2 Reference Signals

4.2.2.1 Demodulation Reference Signals

4.2.2.1.1 PUSCH DM-RS

4.2.2.1.2 PUCCH DM-RS

4.2.2.2 Phase-Tracking Reference Signals

4.2.2.3 Sounding Reference Signal

4.2.3 Control Channels

4.2.3.1 Physical Uplink Control Channel

4.2.3.1.1 PUCCH Format 0 Structure and Physical Processing

4.2.3.1.2 PUCCH Format 1 Structure and Physical Processing

4.2.3.1.3 PUCCH Format 2 Structure and Physical Processing

4.2.3.1.4 PUCCH Formats 3 and 4 Structure and Physical Processing

4.2.3.2 Physical Random-Access Channel

4.2.3.2.1 Four-Step Random-Access Procedure

4.2.3.2.2 Two-Step Random-Access Procedure

4.2.4 Physical Uplink Shared Channel

4.2.5 Uplink MIMO Schemes

4.2.6 Link Adaptation and Power Control

Articles, Books, White Papers, and Application Notes.

5 New Radio Access RF and Transceiver Design Considerations.

Notes:

Includes bibliographical references and index.

Description based on print version record.

ISBN:

9780128134023

012813402X

OCLC:

1125343542