5G and beyond wireless communication networks / Haijian Sun, University of Georgia Athens, GA, USA , Rose Qingyang, Utah State University, Logan, UT, USA, Hu, Yi Qian, Univ of Nebraska-Lincoln, Omaha, NE, USA.
2024
TK5103.25
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Details
Title
5G and beyond wireless communication networks / Haijian Sun, University of Georgia Athens, GA, USA , Rose Qingyang, Utah State University, Logan, UT, USA, Hu, Yi Qian, Univ of Nebraska-Lincoln, Omaha, NE, USA.
Author
Edition
First edition.
ISBN
9781119089506 (epub)
1119089506
9781119089490 (adobe pdf)
1119089492
9781119089452 (cloth)
9781119089469 electronic book
1119089468 electronic book
1119089506
9781119089490 (adobe pdf)
1119089492
9781119089452 (cloth)
9781119089469 electronic book
1119089468 electronic book
Published
Hoboken, NJ, USA : John Wiley & Sons, Ltd, [2024]
Language
English
Description
1 online resource : illustrations (some color)
Other Standard Identifiers
10.1002/9781119089469 doi
Call Number
TK5103.25
System Control No.
(OCoLC)1396064968
Summary
"A comprehensive and up-to-date survey of 5G technologies and applications In 5G Wireless Communication Networks, a team of distinguished researchers delivers an expert treatment of the technical details of modern 5G wireless networks and the performance gains they make possible. The book examines the recent progress in research and development in the area, covering related topics on fundamental 5G requirements and its enabling technologies. The authors survey 5G service architecture and summarize enabling technologies, including highly dense small cell and heterogeneous networks, device-to-device communications underlaying cellular networks, fundamentals of non-orthogonal multiple access in 5G new radio and its applications"-- Provided by publisher.
Bibliography, etc. Note
Includes bibliographical references and index.
Formatted Contents Note
Chapter 1 Introduction to 5G and Beyond Network
1.1 5G and Beyond System Requirements
1.1.1 Technical Challenges
1.2 Enabling Technologies
1.2.1 5G New Radio
1.2.1.1 Non-orthogonal Multiple Access (NOMA)
1.2.1.2 Channel Codes
1.2.1.3 Massive MIMO
1.2.1.4 Other 5G NR Techniques
1.2.2 Mobile Edge Computing (MEC)
1.2.3 Hybrid and Heterogeneous Communication Architecture for Pervasive IoTs
1.3 Book Outline
Chapter 2 5G Wireless Networks with Underlaid D2D Communications
2.1 Background
2.1.1 MU-MIMO
2.1.2 D2D Communication
2.1.3 MU-MIMO and D2D in 5G
2.2 NOMA-Aided Network with Underlaid D2D
2.3 NOMA with SIC and Problem Formation
2.3.1 NOMA with SIC
2.3.2 Problem Formation
2.4 Precoding and User Grouping Algorithm
2.4.1 Zero-Forcing Beamforming
2.4.1.1 First ZF Precoding
2.4.1.2 Second ZF Precoding
2.4.2 User Grouping and Optimal Power Allocation
2.4.2.1 First ZF Precoding
2.4.2.2 Second ZF Precoding
2.5 Numerical Results
2.6 Summary
Chapter 3 5G NOMA-Enabled Wireless Networks
3.1 Background
3.2 Error Propagation in NOMA
3.3 SIC and Problem Formulation
3.3.1 SIC with Error Propagation
3.3.2 Problem Formation
3.4 Precoding and Power Allocation
3.4.1 Precoding Design
3.4.2 Case Studies for Power Allocation
3.4.2.1 Case I
3.4.2.2 Case II
3.5 Numerical Results
3.6 Summary
Chapter 4 NOMA in Relay and IoT for 5G Wireless Networks
4.1 Outage Probability Study in a NOMA Relay System
4.1.1 Background
4.1.2 System Model
4.1.2.1 NOMA Cooperative Scheme
4.1.2.2 NOMA TDMA Scheme
4.1.3 Outage Probability Analysis
4.1.3.1 Outage Probability in NOMA Cooperative Scheme
4.1.4 Outage Probability in NOMA TDMA Scheme
4.1.5 Outage Probability with Error Propagation in SIC
4.1.5.1 Outage Probability in NOMA Cooperative Scheme with EP
4.1.5.2 Outage Probability in NOMA TDMA Scheme with EP
4.1.6 Numerical Results
4.2 NOMA in a mmWave-Based IoT Wireless System with SWIPT
4.2.1 Introduction
4.2.2 System Model
4.2.2.1 Phase 1 Transmission
4.2.2.2 Phase 2 Transmission
4.2.3 Outage Analysis
4.2.3.1 UE 1 Outage Probability
4.2.3.2 UE 2 Outage Probability
4.2.3.3 Outage at High SNR
4.2.3.4 Diversity Analysis for UE 2
4.2.4 Numerical Results
4.2.5 Summary
Chapter 5 Robust Beamforming in NOMA Cognitive Radio Networks: Bounded CSI
5.1 Background
5.1.1 Related Work and Motivation
5.1.1.1 Linear EH Model
5.1.1.2 Non-linear EH Model
5.1.2 Contributions
5.2 System and Energy Harvesting Models
5.2.1 System Model
5.2.2 Non-linear EH Model
5.2.3 Bounded CSI Error Model
5.2.3.1 NOMA Transmission
5.3 Power Minimization-Based Problem Formulation
5.3.1 Problem Formulation
5.3.2 Matrix Decomposition.
1.1 5G and Beyond System Requirements
1.1.1 Technical Challenges
1.2 Enabling Technologies
1.2.1 5G New Radio
1.2.1.1 Non-orthogonal Multiple Access (NOMA)
1.2.1.2 Channel Codes
1.2.1.3 Massive MIMO
1.2.1.4 Other 5G NR Techniques
1.2.2 Mobile Edge Computing (MEC)
1.2.3 Hybrid and Heterogeneous Communication Architecture for Pervasive IoTs
1.3 Book Outline
Chapter 2 5G Wireless Networks with Underlaid D2D Communications
2.1 Background
2.1.1 MU-MIMO
2.1.2 D2D Communication
2.1.3 MU-MIMO and D2D in 5G
2.2 NOMA-Aided Network with Underlaid D2D
2.3 NOMA with SIC and Problem Formation
2.3.1 NOMA with SIC
2.3.2 Problem Formation
2.4 Precoding and User Grouping Algorithm
2.4.1 Zero-Forcing Beamforming
2.4.1.1 First ZF Precoding
2.4.1.2 Second ZF Precoding
2.4.2 User Grouping and Optimal Power Allocation
2.4.2.1 First ZF Precoding
2.4.2.2 Second ZF Precoding
2.5 Numerical Results
2.6 Summary
Chapter 3 5G NOMA-Enabled Wireless Networks
3.1 Background
3.2 Error Propagation in NOMA
3.3 SIC and Problem Formulation
3.3.1 SIC with Error Propagation
3.3.2 Problem Formation
3.4 Precoding and Power Allocation
3.4.1 Precoding Design
3.4.2 Case Studies for Power Allocation
3.4.2.1 Case I
3.4.2.2 Case II
3.5 Numerical Results
3.6 Summary
Chapter 4 NOMA in Relay and IoT for 5G Wireless Networks
4.1 Outage Probability Study in a NOMA Relay System
4.1.1 Background
4.1.2 System Model
4.1.2.1 NOMA Cooperative Scheme
4.1.2.2 NOMA TDMA Scheme
4.1.3 Outage Probability Analysis
4.1.3.1 Outage Probability in NOMA Cooperative Scheme
4.1.4 Outage Probability in NOMA TDMA Scheme
4.1.5 Outage Probability with Error Propagation in SIC
4.1.5.1 Outage Probability in NOMA Cooperative Scheme with EP
4.1.5.2 Outage Probability in NOMA TDMA Scheme with EP
4.1.6 Numerical Results
4.2 NOMA in a mmWave-Based IoT Wireless System with SWIPT
4.2.1 Introduction
4.2.2 System Model
4.2.2.1 Phase 1 Transmission
4.2.2.2 Phase 2 Transmission
4.2.3 Outage Analysis
4.2.3.1 UE 1 Outage Probability
4.2.3.2 UE 2 Outage Probability
4.2.3.3 Outage at High SNR
4.2.3.4 Diversity Analysis for UE 2
4.2.4 Numerical Results
4.2.5 Summary
Chapter 5 Robust Beamforming in NOMA Cognitive Radio Networks: Bounded CSI
5.1 Background
5.1.1 Related Work and Motivation
5.1.1.1 Linear EH Model
5.1.1.2 Non-linear EH Model
5.1.2 Contributions
5.2 System and Energy Harvesting Models
5.2.1 System Model
5.2.2 Non-linear EH Model
5.2.3 Bounded CSI Error Model
5.2.3.1 NOMA Transmission
5.3 Power Minimization-Based Problem Formulation
5.3.1 Problem Formulation
5.3.2 Matrix Decomposition.
Source of Description
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Series
IEEE Press Series.
Available in Other Form
Print version: Sun, Haijian. 5G and beyond wireless communication networks First edition. Hoboken, NJ, USA : John Wiley & Sons, Ltd, [2024]
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