Overview

This book presents a unified framework for the tractable analysis of large-scale, multi-antenna wireless networks using stochastic geometry. This mathematical analysis is essential for assessing and understanding the performance of complicated multi-antenna networks, which are one of the foundations of 5G and beyond networks to meet the ever-increasing demands for network capacity. Describing the salient properties of the framework, which makes the analysis of multi-antenna networks comparable to that of their single-antenna counterparts, the book discusses effective design approaches that do not require complex system-level simulations. It also includes various application examples with different multi-antenna network models to illustrate the framework’s effectiveness.

Full Product Details

Author:   Xianghao Yu ,  Chang Li ,  Jun Zhang ,  Khaled B. Letaief
Publisher:   Springer Verlag, Singapore
Imprint:   Springer Verlag, Singapore
Edition:   1st ed. 2019
Weight:   0.459kg
ISBN:  

9789811358791

ISBN 10:   9811358796
Pages:   178
Publication Date:   06 April 2019
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Hardback
Publisher's Status:   Active
Availability:   Manufactured on demand  
We will order this item for you from a manufactured on demand supplier.

Table of Contents

Table of Contents 1 Introduction 1 [Give the background and motivation of this book] 1.1 What is 5G Wireless Network? 1 1.2 Paving the Way for 5G Networks 3 1.2.1 High Speed: Spectral Efficiency 4 1.2.2 Green Networking: Energy Efficiency 5 1.2.3 Small Cell: Ultra Dense Networks 6 1.2.4 New Spectrum: Beyond Sub-6 GHz 7 1.3 Network Analysis via Stochastic Geometry 8 1.4 Book Outline 10   2 Fundamentals of Wireless Networks 12 [Provide some mathematical basics for network analysis] 2.1 Spatial Model of Wireless Networks 12 2.1.1 Stochastic Geometry 12 2.1.2 Point Process 14 2.1.3 Sums and Products over Point Processes 17 2.1.4 Poisson Network Model 20 2.2 Network Performance Metrics 24 2.3 Performance Analysis in Poisson Networks 28 2.3.1 Shot Noise 28 2.3.2 Interference Characterization 32 2.3.3 SINR Distribution and Coverage 37 2.4 Multi-Antenna Techniques 42 2.4.1 MIMO Transmission Schemes 47 2.4.2 Signal and Interference Distributions 52   3 A Framework for Analyzing Multi-Antenna Wireless Networks 57 [Present a general analytical framework for multi-antenna networks] 3.1 A General Framework for Analysis of Multi-Antenna Networks 57 3.1.1 Network Model 57 3.1.2 Analytical Framework 62 3.1.3 Single-Antenna vs. Multi-Antenna Networks 72 3.2 Analysis for Multi-Antenna Networks 77 3.2.1 Cellular Networks 82 3.2.2 Ad Hoc Networks 87 3.3 Properties in General Multi-Antenna Networks 92 3.3.1 Densification: Impact of BS density 92 3.3.2 MIMO: Impact of Multiple Antennas 97   4 Analysis of Multi-Antenna Wireless Networks 102 [Illustrate the effectiveness of the proposed framework via various types of networks] 4.1 Outage Probability Analysis 102 4.1.1 Densification: Impact of BS density 107 4.1.2 MIMO: Impact of Multiple Antennas 107 4.2 High Speed Ultra Dense Networks: Throughput vs. Densification 117 4.3 Green Networking: Energy Efficiency Analysis 122 4.3.1 Densification: Impact of BS density 127 4.3.2 MIMO: Impact of Multiple Antennas 132 4.4 New Spectrum: Millimeter Wave Networks 137 4.4.1 General Frameworks for Coverage Analysis of Mm-wave networks 142 4.4.2 Coverage Analysis 147 4.4.3 Impact of Directional Antenna Arrays 152   5 Optimization of Multi-Antenna Wireless Networks 157 [Present methodologies for network optimization based on the analytical framework] 5.1 Interference Management 157 5.1.1 Interference Nulling Techniques 162 5.1.2 Analysis of Coverage Probability-The Perfect CSI Case 167 5.1.3 The Coverage Probability with Limited Feedback 172 5.1.4 Optimization: Interference Coordination 177 5.2 ASE and Link Reliability Tradeoff 182 5.2.1 Heterogeneous Networks 182 5.2.2 Coverage Probability Analysis 187 5.2.3 ASE and Link Reliability Tradeoff 192 5.2.4 Optimization: Optimal BS Densities in HetNets 197   6 Conclusions 202

Reviews

The most remarkable aspect of the book is the reader-friendly structure and the style in which it has been written. This book is suitable for both beginners in wireless network analysis and experienced researchers who intend to work in depth on the performance analysis of multi-antenna wireless networks. The importance of this book both from the practical and from the theoretical standpoint is unquestionable. This book will be an essential part of every mathematical library. (Viktor Ohanyan, zbMATH 1447.60004, 2020)

“The most remarkable aspect of the book is the reader-friendly structure and the style in which it has been written. This book is suitable for both beginners in wireless network analysis and experienced researchers who intend to work in depth on the performance analysis of multi-antenna wireless networks. The importance of this book both from the practical and from the theoretical standpoint is unquestionable. This book will be an essential part of every mathematical library.” (Viktor Ohanyan, zbMATH 1447.60004, 2020)

Author Information

Xianghao Yu received his B.Eng. degree in Information Engineering from Southeast University, Nanjing, China, in 2014, and his Ph.D. degree in Electronic and Computer Engineering from the Hong Kong University of Science and Technology (HKUST), Kowloon, Hong Kong, in 2018. His research interests include millimeter wave communications, MIMO systems, mathematical optimization, and stochastic geometry. He was the recipient of the IEEE GLOBECOM 2017 Best Paper Award. Chang Li received his B.Eng. degree in Information and Communication Engineering from Xi’an Jiaotong University, Xi’an, China, in 2010, and his Ph.D. degree in Electrical and Computer Engineering from the Hong Kong University of Science and Technology (HKUST), Kowloon, Hong Kong, in 2016. From February 2015 to January 2016, he was a Visiting Student at the Laboratory for Information and Decision Systems (LIDS), Massachusetts Institute of Technology (MIT), Cambridge, MA, USA. He is currently a guest researcher with the Advanced Network Technologies Division (ANTD), National Institute of Standards and Technology (NIST). His research interests include network localization and navigation, heterogeneous networks, MIMO systems, green communications, and the application of stochastic geometry. Jun Zhang received his Ph.D. degree in Electrical and Computer Engineering from the University of Texas at Austin. He is currently an Assistant Professor at the Department of Electronic and Information Engineering at the Hong Kong Polytechnic University. Dr. Zhang co-authored the book Fundamentals of LTE (Prentice-Hall, 2010). He is a co-recipient of the 2016 Marconi Prize Paper Award in Wireless Communications, the 2014 Best Paper Award for the EURASIP Journal on Advances in Signal Processing, an IEEE GLOBECOM Best Paper Award in 2017, an IEEE ICC Best Paper Award in 2016, and an IEEE PIMRC Best Paper Award in 2014. One paper he co-authored received the 2016 IEEE Signal Processing Society Young Author Best Paper Award. He also received the 2016 IEEE Communications Society Asia-Pacific Best Young Researcher Award. His research interests include wireless communications and networking, mobile edge computing and edge learning, distributed optimization and learning, and big data analytics systems.  Khaled B. Letaief received his B.S. degree with distinction, M.S. and Ph.D. degrees in Electrical Engineering from Purdue University, USA. He is an internationally recognized leader in wireless communications and networks and has served as a consultant for various organizations. From 1990 to 1993, he was a faculty member at the University of Melbourne, Australia. Since 1993, he has been with HKUST, Hong Kong. While at HKUST, he has held various administrative positions, including the Dean of Engineering and Director of the Hong Kong Telecom Institute of Information Technology. He is the founding Editor-in-Chief of the prestigious IEEE Transactions on Wireless Communications. He is also the recipient of numerous distinguished awards and honors including the 2016 IEEE Marconi Prize Award in Wireless Communications, 2011 IEEE Communications Society Harold Sobol Award, 2010 Purdue University Outstanding Electrical and Computer Engineer Award, 2007 IEEE Communications Society Joseph LoCicero Publications Exemplary Award, and over 15 IEEE Best Paper Awards. Dr. Letaief is a Fellow of IEEE and a Fellow of HKIE. He is recognized by Thomson Reuters as an ISI Highly Cited Researcher. He is also known for his dedicated service to professional societies and in particular IEEE, where he has served in various leadership positions, including President of the IEEE Communications Society.

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