Mean field game and its applications in wireless networks / Reginald A. Banez, Lixin Li, Chungang Yang, Zhu Han.
Banez, Reginald A., author.; Li, Lixin, author.; Yang, Chungang, 1982- author.; Han, Zhu, 1974- author.
2021
TK5102.83 .B36 2021
Available Online

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Title Mean field game and its applications in wireless networks / Reginald A. Banez, Lixin Li, Chungang Yang, Zhu Han.
Author Banez, Reginald A., author.
ISBN 9783030869052 (electronic bk.)
3030869059 (electronic bk.)
9783030869045
3030869040
DOI https://doi.org/10.1007/978-3-030-86905-2
Published Cham : Springer, [2021]
Copyright ©2021
Language English
Description 1 online resource : illustrations (chiefly color)
Other Standard Identifiers 10.1007/978-3-030-86905-2 doi
Call Number TK5102.83 .B36 2021
Dewey Decimal Classification 621.38401/5118
Summary This book covers the basic theory of mean field game (MFG) and its applications in wireless networks. It starts with an overview of the current and future state-of-the-art in 5G and 6G wireless networks. Then, a tutorial is presented for MFG, mean-field-type game (MFTG), and prerequisite fields of study such as optimal control theory and differential games. This book also includes a literature survey of MFG-based research in wireless network technologies such as ultra-dense networks (UDNs), device-to-device (D2D) communications, internet-of-things (IoT), unmanned aerial vehicles (UAVs), and mobile edge networks (MENs). Several applications of MFG and MFTG in UDNs, social networks, and multi-access edge computing networks (MECNs) are introduced as well. Applications of MFG covered in this book are divided in three parts. The first part covers three single-population MFG research works or case studies in UDNs including ultra-dense D2D networks, ultra-dense UAV networks, and dense-user MECNs. The second part centers on a multiple-population MFG (MPMFG) modeling of belief and opinion evolution in social networks. It focuses on a recently developed MPMFG framework and its application in analyzing the behavior of users in a multiple-population social network. Finally, the last part concentrates on an MFTG approach to computation offloading in MECN. The computation offloading algorithms are designed for energy- and time-efficient offloading of computation-intensive tasks in an MECN. This book targets advanced-level students, professors, researchers, scientists, and engineers in the fields of communications and networks. Industry managers and government employees working in these same fields will also find this book useful.
Access Note Access limited to authorized users.
Digital File Characteristics text file
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Source of Description Online resource; title from PDF title page (SpringerLink, viewed November 15, 2021).
Added Author Li, Lixin, author.
Yang, Chungang, 1982- author.
Han, Zhu, 1974- author.
Series Wireless networks (Springer (Firm))
Available in Other Form Mean field game and its applications in wireless networks.
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Intro
Preface
Contents
Acronyms
1 Overview of Mean Field Games in Wireless Networks
1.1 Background and Requirements
1.1.1 Technical Requirements
1.1.2 Enabling Technologies
1.2 5G/6G Wireless Networks
1.2.1 Ultra-Dense Networks
1.2.2 Device-to-Device Communications
1.2.3 Internet-of-Things
1.2.4 Unmanned Aerial Vehicle Networks
1.2.5 Mobile Edge Networks
1.3 Introduction to Mean Field Games
1.4 Research Works on Mean Field Games in Wireless Networks
1.4.1 Single-Population Mean Field Games for Ultra-Dense Networks

1.4.2 Multiple-Population Mean Field Game for Social Networks
1.4.3 Mean-Field-Type Game for Multi-Access Edge Computing Networks
1.5 Organization and Summary
References
2 Introduction to Mean Field Games and Mean-Field-Type Games
2.1 Introduction
2.1.1 Basic Concepts of Game Theory
2.1.1.1 Extensive-Form and Strategic-Form Games
2.1.1.2 Pure Strategies and Mixed Strategies
2.1.1.3 Nash Equilibrium
2.1.2 Mean Field Games and Related Fields of Study
2.2 Optimal Control Theory
2.2.1 Deterministic Optimal Control
2.2.1.1 Dynamic Programming Principle

2.2.1.2 Hamilton-Jacobi-Bellman Equation
2.2.2 Stochastic Optimal Control
2.2.2.1 Stochastic Process and Stochastic Differential Equations
2.2.2.2 Ito Stochastic Differentiation Rule
2.2.2.3 Stochastic Optimal Control Problem
2.2.2.4 Dynamic Programming Principle
2.2.2.5 Hamilton-Jacobi-Bellman Equation
2.3 Differential Games
2.3.1 Deterministic Differential Games
2.3.2 Stochastic Differential Games
2.4 Mean Field Games
2.4.1 Background and Motivation
2.4.2 Analytic Solution
2.4.3 Numerical Methods
2.4.4 Linear-Quadratic Mean Field Games

2.4.5 Multiple-Population Mean Field Games
2.5 Mean-Field-Type Games
2.5.1 Background
2.5.2 Linear-Quadratic Mean-Field-Type Control
2.5.3 Linear-Quadratic Mean-Field-Type Games
References
3 A Survey of Mean Field Game Applications in Wireless Networks
3.1 Ultra-Dense Networks
3.1.1 Overview of Ultra-Dense Networks
3.1.2 Research Opportunities and Challenges
3.1.3 Proposed Mean Field Game Solutions
3.1.3.1 Interference Management
3.1.3.2 Propagation Modeling
3.1.3.3 Energy Efficiency
3.1.3.4 Scheduling
3.1.4 Summary

3.2 Device-to-Device Communications and Internet-of-Things
3.2.1 Overview of Device-to-Device Communications and Internet-of-Things
3.2.2 Research Opportunities and Challenges
3.2.3 Proposed Mean Field Game Solutions
3.2.3.1 Interference Management and Power Control
3.2.3.2 Proximity Services
3.2.3.3 Network Security
3.2.4 Summary
3.3 Unmanned Aerial Vehicle Networks
3.3.1 Overview of Unmanned Aerial Vehicle Networks
3.3.2 Research Opportunities and Challenges
3.3.3 Proposed Mean Field Game Solutions
3.3.3.1 Channel Modeling
3.3.3.2 Energy Efficiency

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