Foreword xxiPreface xxvAuthor Bios xxviiList of Contributors xxxiList of Abbreviations xxxviiIntroduction 1Part I Physical Layer for 5G Radio Interface Technologies 131 Emerging Technologies in Software, Hardware, and Management Aspects Toward the 5G Era: Trends and Challenges 15Ioannis-Prodromos Belikaidis, Andreas Georgakopoulos, Evangelos Kosmatos, Stavroula Vassaki, Orestis-Andreas Liakopoulos, Vassilis Foteinos, Panagiotis Vlacheas, and Panagiotis Demestichas1.1 Introduction 151.2 5G Requirements and Technology Trends 171.3 Status and Challenges in Hardware and Software Development 201.4 5G Network Management Aspects Enhanced with Machine Learning 381.5 Conclusion 45References 452 Waveform Design for 5G and Beyond 51Ali Fatih Demir, Mohamed Elkourdi,Mostafa Ibrahim, and Huseyin Arslan2.1 Introduction 512.2 Fundamentals of the 5G Waveform Design 522.3 Major Waveform Candidates for 5G and Beyond 582.4 Summary 702.5 Conclusions 73References 733 Full-Duplex System Design for 5G Access 77Shu-ping Yeh, Jingwen Bai, PingWang, Feng Xue, Yang-seok Choi, Shilpa Talwar, Sung-en Chiu, and Vinod Kristem3.1 Introduction 773.2 Self-Interference Cancellation 793.3 FD System Design: Opportunities and Challenges 823.4 Designing the FD System 843.5 System-Level Performance Analysis 1083.6 Conclusions and Future Directions 125References 1304 Nonorthogonal Multiple Access for 5G 135Linglong Dai, Bichai Wang, Ruicheng Jiao, Zhiguo Ding, Shuangfeng Han, and Chih-Lin I4.1 Introduction 1354.2 Basic Principles and Advantages of NOMA 1374.3 Power-Domain NOMA 1424.4 Code-Domain NOMA 1554.5 Other NOMA Schemes 1704.6 Comparison and Trade-Off Analysis of NOMA Solutions 1784.7 Performance Evaluations and Transmission Experiments of NOMA 1814.8 Opportunities and Future Research Trends 1854.9 Conclusions 189References 1895 Code Design for Multiuser MIMO 205Guanghui Song, Yuhao Chi, Kui Cai, Ying Li, and Jun Cheng5.1 Introduction 2065.2 Multiuser Repetition-Aided IRA Coding Scheme 2075.3 Iterative Decoding and EXIT Analysis 2095.4 Code Optimization Procedure 2175.5 Numerical Results and Comparisons 2185.6 Conclusion 230References 2316 Physical Layer Techniques for 5G Wireless Security 237Batu K. Chalise, Himal A. Suraweera, Gan Zheng, and Risto Wichman6.1 Introduction 2376.2 5G Physical Layer Architecture 2416.3 Secure Full-Duplex Receiver Jamming 2476.4 Secure Full-Duplex Bidirectional Communications 2556.5 Secure Full-Duplex Relay Communications 2596.6 Future Directions and Open Issues 2666.7 Conclusion 268References 2697 Codebook-Based Beamforming Protocols for 5G Millimeter Wave Communications 275Anggrit Dewangkara Yudha Pinangkis, Kishor Chandra, and R. Venkatesha Prasad7.1 Introduction 2757.2 Beamforming Architecture 2787.3 Beam Searching Algorithm 2807.4 Codebook Design 2867.5 Beamforming Evaluation 2907.6 Conclusion 291References 293Part II Radio Access Technology for 5G Networks 2998 Universal Access in 5G Networks: Potential Challenges and Opportunities for Urban and Rural Environments 301Syed Ali Hassan, Muhammad Shahmeer Omar,Muhammad Ali Imran, Junaid Qadir, and Dushantha Nalin K. Jayakody8.1 Introduction 3018.2 Access for Urban Environments 3028.3 Providing Access to Rural Areas 3128.4 Conclusions 320References 3219 Network Slicing for 5G Networks 327Xavier Costa-Pérez, Andrés Garcia-Saavedra, Fabio Giust, Vincenzo Sciancalepore, Xi Li, Zarrar Yousaf, and Marco Liebsch9.1 Introduction 3279.2 End-to-End Network Slicing 3289.3 Network Slicing MANO 3349.4 Network Slicing at the Mobile Edge 3439.5 Network Slicing at the Mobile Transport 3499.6 Network Slicing at the Mobile Cloud 3589.7 Acknowledgment 364References 36510 The Evolution Toward Ethernet-Based Converged 5G RAN 371Jouni Korhonen10.1 Introduction to RAN Transport Network 37210.2 Evolving RAN Toward 5G Requirements 38410.3 Ethernet-Based 5G RAN 39910.4 Summary 418References 41811 Energy-Efficient 5G Networks Using Joint Energy Harvesting and Scheduling 427Ahmad Alsharoa, Abdulkadir Celik, and Ahmed E. Kamal11.1 Introduction 42711.2 System Model 43211.3 Problem Formulation and Solution 43611.4 Low-Complexity Algorithm 43911.5 Simulation Results 44111.6 Chapter Summary 445References 446Part III 5G Network Interworking and Core Network Advancements 45312 Characterizing and Learning the Mobile Data Traffic in Cellular Network 455Rongpeng Li, Zhifeng Zhao, Chen Qi, and Honggang Zhang12.1 Understanding the Traffic Nature: A Revisiting to alpha-Stable Models 45512.2 The Traffic Predictability in Cellular Networks 47012.3 The Prediction of Application-Level Traffic 47612.4 Related Works 49012.5 Conclusion 493References 49313 Network Softwarization View of 5G Networks 499Takashi Shimizu, Akihiro Nakao, and Kohei Satoh13.1 Introduction 49913.2 Key Concept of 5G 50013.3 Network Softwarization View of 5G Networks 50113.4 Brief History of Network Softwarization and Slicing 50313.5 Issues for Slicing Towards 5G 50413.6 Information-Centric Network (ICN) Enabled by Network Softwarization 50913.7 Studies in ITU-T SG13 Focus Group on IMT-2020 51513.8 Conclusion 515References 51514 Machine-Type Communication in the 5G Era: Massive and Ultrareliable Connectivity Forces of Evolution, Revolution, and Complementarity 519Renaud Di Francesco and Peter Karlsson14.1 Overview 51914.2 Introduction 52014.3 Demand Analysis 52214.4 Reviewing the Standardization Path So Far 53214.5 Conclusion on Machine-Type 5G 537References 538Part IV Vertical 5G Applications 54315 Social-Aware Content Delivery in Device-to-Device Underlay Networks 545Chen Xu, Caixia Gao, Zhenyu Zhou, ShahidMumtaz, and Jonathan Rodriguez15.1 Introduction 54515.2 Related Works 54815.3 System Model 55215.4 Problem Formulation 55715.5 Social Network-Based Content Delivery Matching Algorithm for D2D Underlay Networks 55815.6 Numerical Results 56515.7 Conclusions 569References 57016 Service-Oriented Architecture for IoT Home Area Networking in 5G 577Mohd Rozaini Abd Rahim, Rozeha A. Rashid, AhmadM. Rateb, Mohd Adib Sarijari, Ahmad Shahidan Abdullah, Abdul Hadi Fikri Abdul Hamid, Hamdan Sayuti, and Norsheila Fisal16.1 Introduction 57716.2 Service-Oriented Architecture 57916.3 Related Work 58116.4 Service-Oriented Architecture for Home Area Network (SoHAN) 58416.5 Performance Evaluation 59116.6 Conclusion 596References 59717 Provisioning Unlicensed LAA Interface for Smart Grid Applications 603Saba Al-Rubaye and John Cosmas17.1 Introduction 60317.2 Smart Grid Architecture-Based 5G Communications 60517.3 Bandwidth UtilizationMethod 60817.4 System Implementation and Simulation Platform 61517.5 Summary and Conclusions 620References 621Part V R&D and 5G Standardization 62518 5G Communication System: A Network Operator Perspective 627Bruno Jacobfeuerborn and Frank H. P. Fitzek18.1 Introduction 62718.2 Softwarization for the 5G Communication System 63418.3 5G Holistic Testbed 64218.4 5G as Game Changer in the Value Chain 64718.5 Conclusion 64718.6 Acknowledgments 648References 64919 Toward All-IT 5G End-to-End Infrastructure 653Alex Jinsung Choi, Jinhyo Park, Sungho Jo, and Sangsoo Jeong19.1 Introduction 65319.2 Development Status and Lesson Learned 65519.3 Infrastructure Evolution of SK Telecom for 5G: ATSCALE 66419.4 Detailed Architecture and Key Enabling Technology 66819.5 Value Proposition 68319.6 Summary and Conclusion 687References 68720 Standardization: The Road to 5G 691M. P. Galante and G. Romano20.1 The Role of Standardization 69120.2 The Main Standardization Bodies 69320.3 5G Standardization Process 69420.4 ITU-R 69720.5 3GPP 699References 705Index 709

Anwer Al–Dulaimi, PhD, is a System Engineering Specialist in the R&D department at EXFO, Toronto, Canada. 

Xianbin Wang, PhD, is a professor and Canada Research Chair at Western University, London (Ontario), Canada.

Chih–Lin I, PhD, is the CMCC Chief Scientist of Wireless Technologies at the China Mobile Research Institute, Beijing, China.

A reliable and focused treatment of the emergent technology of fifth generation (5G) networks

This book provides an understanding of the most recent developments in 5G, from both theoretical and industrial perspectives. It identifies and discusses technical challenges and recent results related to improving capacity and spectral efficiency on the radio interface side, and operations management on the core network side. It covers both existing network technologies and those currently in development in three major areas of 5G: spectrum extension, spatial spectrum utilization, and core network and network topology management. It explores new spectrum opportunities; the capability of radio access technology; and the operation of network infrastructure and heterogeneous QoE provisioning. 

5G Networks: Fundamental Requirements, Enabling Technologies, and Operations Management is split into five sections: Physical Layer for 5G Radio Interface Technologies; Radio Access Technology for 5G Networks; 5G Network Interworking and Core Network Advancements; Vertical 5G Applications; and R&D and 5G Standardization. It starts by introducing emerging technologies in 5G software, hardware, and management aspects before moving on to cover waveform design for 5G and beyond; code design for multi–user MIMO; network slicing for 5G networks; machine type communication in the 5G era; provisioning unlicensed LAA interface for smart grid applications; moving toward all–IT 5G end–to–end infrastructure; and more. This valuable resource:

• Provides a comprehensive reference for all layers of 5G networks
• Focuses on fundamental issues in an easy language that is understandable by a wide audience
• Includes both beginner and advanced examples at the end of each section
• Features sections on major open research challenges

5G Networks: Fundamental Requirements, Enabling Technologies, and Operations Management is an excellent book for graduate students, academic researchers, and industry professionals, involved in 5G technology.