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Spectrum Sharing in Wireless Networks

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Spectrum Sharing in Wireless Networks: Fairness, Efficiency, and Security provides a broad overview of wireless network spectrum sharing in seven distinct sections: The first section examines the big picture and basic principles, explaining the concepts of spectrum sharing, hardware/software function requirements for efficient sharing, and future trends of sharing strategies. The second section contains more than 10 chapters that discuss differing approaches to efficient spectrum sharing. The authors introduce a new coexistence and sharing scheme for multi-hop networks, describe the space-time sharing concept, introduce LTE-U, and examine sharing in broadcast and unicast environments. They then talk about different cooperation strategies to achieve mutual benefits for primary users (PU) and secondary users (SU), discuss protocols in a spectrum sharing context, and provide different game theory models between PUs and SUs. The third section explains how to model the interactions of PUs and SUs, using an efficient calculation method to determine spectrum availability. Additionally, this section explains how to use scheduling models to achieve efficient SU traffic delivery. The subject of the fourth section is MIMO-oriented design. It focuses on how directional antennas and MIMO antennas greatly enhance wireless network performance. The authors include a few chapters on capacity/rate calculations as well as beamforming issues under MIMO antennas. Power control is covered in the fifth section which also describes the interference-aware power allocation schemes among cognitive radio users and the power control schemes in cognitive radios. The sixth section provides a comprehensive look at security issues, including different types of spectrum sharing attacks and threats as well as corresponding countermeasure schemes. The seventh and final section covers issues pertaining to military applications and examines how the military task protects its data flows when sharing the spectrum with civilian applications.
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Table of Contents

BIG PICTURE Physical Aspects of Spectrum Sharing Michael Fitch Introduction Radio Technology Aspects of Sharing Types of Spectrum Sharing Spectrum Management Traffic Patterns References Perspective on the Design of Opportunistic Spectrum Sharing Haythem Bany Salameh Introduction Network Architecture Spectrum Sharing Problem Statement and Objectives Issues in Designing Spectrum Sharing Mechanisms Tradeoffs in Selecting the Operating Channel State-of-the-Art Spectrum Sharing Protocols in CRNs Complementary Approaches and Optimizations Summary and Open Research Problems References APPROACHES TO SPECTRUM SHARING New Coexistence and Sharing Paradigms for Multihop Secondary Networks Xu Yuan, Brian Jalaian, Y. Thomas Hou, Wenjing Lou, Scott F. Midkiff, and Sastry Kompella Introduction Transparent Coexistence Paradigm Cooperative Sharing Paradigm Summary Acknowledgments References Space-Time Spectrum Sharing in Cognitive Radio Networks Zhiqing Wei, Zhiyong Feng, and Qixun Zhang Introduction System Model Temporal Spectrum Opportunity in Gray Region Spatial Spectrum Opportunity in White Region The Bounds of Three Regions Numerical Results Conclusion References LTE in the Unlicensed Band (LTE-U) David Tung Chong Wong, Qian Chen, Francois Chin, and Xiaoming Peng Introduction Overview of Traditional LTE in the Licensed Band Overview of Traditional Wi-Fi in the Unlicensed Band LTE in the Unlicensed Band Conclusions References Spectrum Sharing in Broadcast and Unicast Hybrid Cellular Networks Hongxiang Li System Model Hybrid System Analysis Collaborative Hybrid System Numerical Results Structured Dirty Paper Coding Conclusion References Cooperation-Based Dynamic Spectrum Sharing in CRNs Ning Zhang, Haibo Zhou, Shaohua Wu, Ying Wang, Jon W. Mark, and Xuemin (Sherman) Shen Introduction Cooperation-Based Dynamic Spectrum Sharing Cooperative Spectrum Sensing in Multi-Channel Environments Cooperative Cognitive Radio Networking Conclusion References Cooperation in Cognitive Radio Networks Junni Zou Secondary Users Relaying for Primary Users Primary Users Relaying for Secondary Users Summary References Cross-Layer Design for Spectrum Efficiency Mohammad Robat Mili and Farokh Marvasti Introduction System Model Maximization of the Ergodic Capacity Minimization of the Bit Error Rate (BER) Chapter Conclusion References Spectrum-Aware Routing in Cognitive Radio Vehicular Ad Hoc Networks (CRVANETs): Challenges and Solutions Ahmed M. Ahmed, Ala Abu Alkheir, and Hussein T. Mouftah Introduction Channel Acquisition Techniques The Routing Problem Simulating End-to-End Protocols in CRAHNs Open Research Issues Conclusions References The Spectrum Sharing Games Pu Yuan, Yong Xiao, Guoan Bi, and Shan Luo Introduction A Non-Cooperative Spectrum Sharing Game A Cooperative Spectrum Sharing Game Spectrum Sharing with Priorities References Game-Theoretic Opportunistic Spectrum Sharing Yuhua Xu and Alagan Anpalagan Introduction Game Theory and Distributed Learning Graphical Game for Spatial Opportunistic Spectrum Sharing Robust Game for Dynamic Opportunistic Spectrum Sharing Future Directions and Challenges References An Adaptive Game Theoretic Framework for Self-Coexistence among Cognitive Radio Enabled Smart Grid Networks Deepak K. Tosh and Shamik Sengupta Introduction Challenges and Related Works Self-Coexistence among DSA-Enabled Smart Grid Networks Self-Coexistence Using Multi-Stage Interaction Games Simulation Model and Results Conclusions Acknowledgment References MODELING ISSUES Performance Modeling of Opportunistic Spectrum Sharing Shensheng Tang Introduction System Models Performance Analysis Performance Metrics Conclusions References Calculation Methods for Spectrum Availability Andreas Achtzehn and Petri Mahoenen Incumbent-Newcomer Relationship Interference Temperature-Based Primary Protection Model Service-Level-Based Primary Protection Model Spectrum Availability Metrics Conclusions References How to Use Novel Methods for Improving the Performance of Wireless Cognitive Networks Barbaros Preveze Introduction Simulation Program How to Improve Network Performance by Modifications Done on the Algorithms of the System Network Performance Improvement by Using Novel Buffer Management Algorithm Theoretical Calculation of the Effects of Novel Algorithm on the Overall System Performance Results and Discussion Conclusion References Low-Complexity and High-Efficient Scheduling Schemes for Spectrum-Sharing Based Secondary Transmissions Haiyang Ding, Tangwen Xu, Daniel B. da Costa, Jianhua Ge, Yinfa Zhang, Wulin Liu, and Ya-Ni Zhang Energy-Efficient and Low-Complexity Schemes for Non-Cooperative Uplink Cognitive Cellular Networks An Improved Scheduling Scheme for Uplink Cognitive Cellular Networks High-Efficient and Low-Complexity Relay Selection Strategies for Cooperative Cognitive Relaying Systems Efficient Relay Selection Strategies for Multi-Relay Cognitive Cooperative Transmissions Distributed Link Scheduling for Single-Relay Secondary Relaying Transmission References MIMO-ORIENTED DESIGN Capacity Scaling of MIMO Broadcast Channels with Finite-Rate Feedback Ali Tajer and Xiaodong Wang Introduction System Model Scheduling Algorithm (Nr = 1) Throughput Scaling Analysis Simulation Results Conclusions Appendix A: Proof of Lemma 1 Appendix B: Proof of Lemma 2 Appendix C: Proof of Lemma 3 Appendix D: Proof of Lemma 4 References On the Achievable Sum-Rate of MIMO Bidirectional Underlay Cognitive Cooperative Networks Ahmad Alsharoa, Hakim Ghazzai, and Mohamed-Slim Alouini Introduction System Model and Problem Formulation Problem Solutions Results and Discussion Summary References Robust Beamforming Optimization for the Secondary Transmission in a Spectrum Sharing Cognitive Radio Network Yongwei Huang Introduction System Model and Problem Formulation A Polynomial-Time Approximation Algorithm for the Robust Beamforming Problem Another Randomized Approximation Algorithm via Complex-Valued S-Lemma and Convex Relaxation Simulation Results Conclusion Acknowledgment References POWER CONTROL Interference-Aware Power Allocation in Spectrum Sharing Cognitive Radio Gosan Noh and Daesik Hong Introduction System Model and Assumptions Interference-Aware Power Allocation for Capacity Maximization Capacity Analysis Numerical Results Conclusion Appendix A: Proof of Lemma 1 Appendix B: Proof of Theorem 1 Appendix C: Proof of Theorem 2 Appendix D: Proof of Lemma 3 Appendix E: Proof of Theorem 2 References Energy-Efficient Power Control for Spectrum Sharing in Next-Generation Wireless Networks Xiangping Zhai, Liang Zheng, and Chee Wei Tan Introduction Power Control in Single MNO Power Control in Multiple MNOs Joint Power Control and Admission Control for Feasibility Open Issues References SECURITY Spectrum Sharing Vulnerability and Threat Assessment Timothy X. Brown and Douglas C. Sicker Introduction Security in Spectrum Sharing Spectrum Sharing Vulnerabilities Spectrum Sharing Threats Security Controls Conclusion References Security Measures for Efficient Spectrum Sharing Ethan Gaebel and Wenjing Lou Regulatory Limitations and Terminology What's at Stake Architectural Considerations Current Standards Attacks and Defenses Conclusion References Pragmatic Security Issues and Solutions for Spectrum Sharing in Wireless Networks Lei Li and Chunxiao Chigan Introduction Security Issues Relevant to the Relaying Strategy Detection and Mitigation of Relay-Featured Security Threats Secure Coexistence Issues in Cognitive Radio Networks Fairness-Based Coexistence Network Design Security Issues Relevant to Ineligible Access of Cognitive Radio Networks Authentication Mechanisms Simulator for Cognitive Radio Networks and Its Security Potential Security Issues References MILITARY APPLICATIONS The Spectrum in Defense: From Commodity to Maneuver Space Jesse Bourque Jr. Introduction Situation Electromagnetic Spectrum Control Electromagnetic Spectrum Operations The "Shift" Compliance and Chaos Models of Spectrum From Electronic Warfare to Spectrum Warfare Training for Effective EMS Operations The Way Ahead

About the Author

Dr. John D. Matyjas earned his PhD in electrical engineering from State University of New York at Buffalo in 2004. Currently, he is serving as the Connectivity & Dissemination Core Technical Competency Lead at the Air Force Research Laboratory (AFRL) in Rome, NY. His research interests include dynamic multiple-access communications and networking, software defined RF spectrum mutability, statistical signal processing and optimization, and neural networks. Dr. Matyjas is an IEEE senior member, chair of the IEEE Mohawk Valley Signal Processing Society, and member of Tau Beta Pi and Eta Kappa Nu. He also serves on the IEEE Transactions on Wireless Communications Editorial Advisory Board. Dr. Fei Hu is currently a professor in the Department of Electrical and Computer Engineering at the University of Alabama, Tuscaloosa, Alabama. He earned his PhD degrees at Tongji University, Shanghai, China, in the field of signal processing in 1999 and at Clarkson University, New York, USA, in electrical and computer engineering in 2002. He has published over 200 journal/conference papers and books. Dr. Hu's research has been supported by the U.S. National Science Foundation, Department of Defense, Cisco, Sprint, and other sources. His research expertise is primarily in the areas of security, signals, and sensors. Dr. Sunil Kumar is currently a professor and Thomas G. Pine faculty fellow in the Electrical and Computer Engineering Department at San Diego State University (SDSU), San Diego, California, USA. He earned his PhD in electrical and electronics engineering from the Birla Institute of Technology and Science (BITS), Pilani, India, in 1997. From 1997 to 2002, Dr. Kumar was a postdoctoral researcher and adjunct faculty at the University of Southern California, Los Angeles. He has published over 130 technical papers in journals/conferences. His research interests include the cross-layer wireless protocols and image/video processing.

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