E-Book, Englisch, 214 Seiten
Jayakody / Srinivasan / Sharma 5G Enabled Secure Wireless Networks
1. Auflage 2019
ISBN: 978-3-030-03508-2
Verlag: Springer International Publishing
Format: PDF
Kopierschutz: 1 - PDF Watermark
E-Book, Englisch, 214 Seiten
ISBN: 978-3-030-03508-2
Verlag: Springer International Publishing
Format: PDF
Kopierschutz: 1 - PDF Watermark
This book covers issues related to 5G network security. The authors start by providing details on network architecture and key requirements. They then outline the issues concerning security policies and various solutions that can handle these policies. Use of SDN-NFV technologies for security enhancement is also covered. The book includes intelligent solutions by utilizing the features of artificial intelligence and machine learning to improve the performance of the 5G security protocols and models. Optimization of security models is covered as a separate section with a detailed information on the security of 5G-based edge, fog, and osmotic computing. This book provides detailed guidance and reference material for academicians, professionals, and researchers.Presents extensive information and data on research and challenges in 5G networks;
Covers basic architectures, models, security frameworks, and software-defined solutions for security issues in 5G networks;
Provides solutions that can help in the growth of new startups as well as research directions concerning the future of 5G networks.
DushanthaNalin K. Jayakody received the Ph. D. degree in Electronics, Electrical, and Communications Engineering in 2014, from the University College Dublin, Ireland. He received his MSc degree in Electronics and Communications Engineering from the Department of Electrical and Electronics Engineering, Eastern Mediterranean University, Turkey (under the University full graduate scholarship) and ranked as the first merit position holder of the department, and B. E. electronics engineering degree (with first-class honors) from Pakistan and was ranked as the merit position holder of the University (under SAARC Scholarship.). From 2014 - 2016, he was a Postdoc Research Fellow at the Institute of computer science, University of Tartu, Estonia and Department of Informatics, University of Bergen, Norway. From summer 2016, he is a Professor at the School of Computer Science& Robotics, National Research Tomsk Polytechnic University, Russia, where he also serves as the Director of Tomsk Infocomm Lab. DrJayakody has received the best paper award from the IEEE International Conference on Communication, Management and Information Technology (ICCMIT) in 2017. Dr. Jayakody has published over 80 international peer reviewed journal and conference papers. His research interests include PHY layer prospective of 5G communications, Cooperative wireless communications, device to device communications, LDPC codes, Unmanned Ariel Vehicle etc. Dr. Jayakody is a Senior Member of IEEE and he has served as workshop chair, session chair or technical program committee member for various international conferences, such as IEEE PIMRC 2013/2014, IEEE WCNC 2014-2018, IEEE VTC 2015-2018 etc. He currently serves as anArea Editor of Elsevier Physical Communications Journal, MDPI Information journal and Wiley Internet of Technology Letters. Also, he serves as a reviewer for various IEEE Transactions and other journals. Kathiravan Srinivasan, received his B.E., in Electronics and Communication Engineering and M.E., in Communication Systems Engineering from Anna University, Chennai, India. He also received his Ph.D., in Information and Communication Engineering from Anna University Chennai, India. He is presently working as an Associate Professor in the School of Information Technology and Engineering at Vellore Institute of Technology (VIT), India. He was previously working as a faculty in the Department of Computer Science and Information Engineering and also as the Deputy Director- Office of International Affairs at National Ilan University, Taiwan. He has won the Best Conference Paper Award at 2018 IEEE International Conference on Applied System Innovation, Chiba, Tokyo, April 13-17, 2018. Further, he has also received the Best Service Award, Department of Computer Science & Information Engineering, National Ilan University, Taiwan. In 2017, he has won Best Paper Award at 2017 IEEE International Conference on Applied System Innovation, Sapporo, Japan, May 13-17, 2017 and Best Paper Award at International Conference on Communication, Management and Information Technology (ICCMIT 2017), Warsaw, Poland. In 2016, he received the Best Service Award as the Deputy Director at Office of International Affairs, National Ilan University. He is presently serving as the Associate Editor for IEEE Access and Editorial Board Member and reviewer for various SCI, SCIE and Scopus Indexed Journals. He has played an active role in organizing several International Conferences, Seminars and Lectures. He has been a key note speaker in many International Conferences and IEEE events Vishal Sharma received the Ph.D. and B.Tech. degrees in computer science and engineering from Thapar University (2016) and Punjab Technical University (2012), respectively. He worked at Thapar University as a Lecturer from Apr'16-Oct'16. From Nov. 2016 to Sept. 2017, he was a joint post-doctoral researcher in MobiSec Lab. at Department of Information Security Engineering, Soonchunhyang University, and Soongsil University, Republic of Korea. Dr. Sharma is now a Research Assistant Professor in the Department of Information Security Engineering under Industry-Academia Cooperation Foundation, Soonchunhyang University, Republic of Korea. Dr. Sharma received three best paper awards from the IEEE International Conference on Communication, Management and Information Technology (ICCMIT), Warsaw, Poland in April 2017; from CISC-S'17 South Korea in June 2017; and from IoTaas Taiwan in September 2017. He is the member of IEEE, a professional member of ACM and past Chair for ACM Student Chapter (TU)-Patiala. He has authored/coauthored more than 70 journal/conference articles and book chapters. He serves as the program committee member for the Journal of Wireless Mobile Networks, Ubiquitous Computing, and Dependable Applications (JoWUA). He was the track chair of MobiSec'16,AIMS-FSS'16 and web chair of MobiSec'18, and PC member and reviewer of MIST'16 and MIST'17, respectively. He was the TPC member of ITNAC-IEEE TCBD'17 and is serving as TPC member of ICCMIT'18, CoCoNet'18, ProvSec-Workshop'18 and ITNAC-IEEE TCBD'18. Dr. Sharma is serving as the guest editor for special issues in Drones-MDPI, WCMC-Hindawi, AutoSoft and Sensors-MDPI. Also, he serves as a reviewer for various IEEE Transactions and other journals. His areas of research and interests are 5G networks, UAVs, estimation theory, and artificial intelligence.
Autoren/Hrsg.
Weitere Infos & Material
1;Foreword;6
2;Preface;8
3;Acknowledgment;11
4;Contents;13
5;5G Security: Concepts and Challenges;17
5.1;Abbreviations;17
5.2;1 Overview;19
5.2.1;1.1 Introduction;19
5.2.2;1.2 Evolution of Cellular Technologies;19
5.2.2.1;First Generation;20
5.2.2.2;Second Generation;20
5.2.2.3;Third Generation;21
5.2.2.4;Fourth Generation;22
5.2.2.5;Fifth Generation;22
5.2.3;1.3 The Significance of 5G Security;23
5.2.4;1.4 The Need for Security;24
5.3;2 5G Security Standardization;24
5.3.1;2.1 Internet Engineering Task Force;25
5.4;3 Security Characteristics of 5G;26
5.4.1;3.1 Drivers of 5G;26
5.4.2;3.2 Significance of Security and Privacy;27
5.4.2.1;Modern Confide Models;27
5.4.2.2;Security for New Relevance Transmission Models;27
5.4.2.3;Emerging Risk Prospects;28
5.4.2.4;Raised Privacy Concerns;28
5.5;4 Network Planning;29
5.5.1;4.1 Objectives;29
5.5.2;4.2 Planning Inputs;30
5.5.2.1;Traffic Models;30
5.5.2.2;Potential Site Locations;31
5.5.2.3;BS Model;31
5.5.2.4;Propagation Prediction Models;31
5.5.3;4.3 Planning Outputs;32
5.5.4;4.4 Types of Network Planning;32
5.5.4.1;Rollout Network Planning;32
5.5.4.2;Incremental Network Planning;32
5.6;5 5G Roadmap;33
5.6.1;5.1 Need for Roadmap;33
5.6.2;5.2 Roadmap Process;34
5.7;6 Existing Concepts of 5G;34
5.7.1;6.1 Multiple Input and Multiple Output;34
5.7.2;6.2 Cognitive Radio Network;35
5.8;7 Security Models;36
5.8.1;7.1 Identity Management;37
5.8.2;7.2 UE Security;37
5.8.3;7.3 Radio Network Security;38
5.8.4;7.4 Flexible and Scalable Security;38
5.8.5;7.5 Network Slicing Security;38
5.8.6;7.6 Vitality Effective Security;39
5.8.7;7.7 Cloud Security;39
5.9;8 Security Protocols;40
5.9.1;8.1 Informal Security Protocols;40
5.9.1.1;Dolev-Yao Adversary;40
5.9.1.2;Threat Model;40
5.9.1.3;Security Properties;41
5.9.1.4;Authentication Properties for Protocols;41
5.9.1.5;Channels;42
5.9.1.6;Attack Scenarios;44
5.10;9 Channel Security;44
5.10.1;9.1 Introduction;44
5.10.2;9.2 Physical Layer Security Coding;45
5.10.2.1;LDPC Codes;45
5.10.2.2;Polar Codes;46
5.10.2.3;Lattice Codes;47
5.10.3;9.3 Massive MIMO;48
5.10.3.1;Passive Eavesdropper Scenarios;48
5.10.3.2;Active Eavesdropper Scenarios;48
5.10.4;9.4 Millimeter Wave (mmWave) Communications;50
5.10.5;9.5 Heterogeneous Networks;51
5.10.5.1;Physical Layer Security in Heterogeneous Networks;51
5.10.6;9.6 Non-orthogonal Multiple Access (NOMA);52
5.10.6.1;Physical Layer Security of NOMA;52
5.10.7;9.7 Full Duplex Technology;53
5.10.7.1;Full Duplex Receiver;53
5.10.7.2;Full Duplex Base Station;54
5.10.7.3;Full Duplex Eavesdropper;54
5.11;References;56
6;5G Applications and Architectures;60
6.1;Brief Summary;60
6.2;1 Brief Introduction to 5G;61
6.3;2 Applications;61
6.4;3 Novel Architectures and Implications;62
6.5;4 Cross-Layer Design;67
6.6;5 SDN-NFV-Based Models;69
6.6.1;5.1 Software-Defined Network (SDN);69
6.6.2;5.2 Network function virtualization (NFV);74
6.6.2.1;NFV Infrastructure;74
6.6.2.2;Virtualized Network Framework (VNF);74
6.6.2.3;Management and Network Orchestration (MNO);74
6.6.2.4;OSS"026E30F BSS Layer;76
6.7;6 Service Architectures and Potential Direction;76
6.7.1;6.1 Industry Initiatives;76
6.8;7 Conclusion;78
6.9;Appendix;79
6.9.1;NEMO;79
6.10;References;79
7;A Survey on the Security and the Evolution of Osmotic and Catalytic Computing for 5G Networks;84
7.1;1 Introduction;84
7.1.1;1.1 Applications of 5G Networks;85
7.1.2;1.2 Attacks and Threats in 5G Networks;87
7.2;2 Preliminaries: Osmotic Computing;87
7.3;3 Preliminaries: Catalytic Computing;90
7.4;4 Existing Surveys and Their Applicability;90
7.5;5 Taxonomy of Security Concerns for 5G Networks;92
7.5.1;5.1 Secure Resource Allocation in 5G;92
7.5.2;5.2 Secure Mobility Management in 5G;95
7.5.3;5.3 Secure Routing in 5G;98
7.5.4;5.4 Secure Physical Layer Formations in 5G;100
7.5.5;5.5 Secure Autonomous and Smart Services in 5G;102
7.6;6 CATMOSIS: A Generalized Model for 5G Security;104
7.7;7 Open Issues and Future Directions;106
7.8;8 Conclusions;109
7.9;References;110
8;Physical Layer Security in 5G Hybrid Heterogeneous Networks;118
8.1;1 Introduction;118
8.2;2 Background;119
8.3;3 The System Layout;120
8.4;4 System Performance Evaluation;126
8.4.1;4.1 Achievable Rates;126
8.4.2;4.2 Physical Layer Security Parameters;127
8.5;5 Simulation Results and Performance Analysis;128
8.6;6 Conclusion;133
8.7;References;134
9;Physical Layer Security of Energy Harvesting Machine-to-Machine Communication System;137
9.1;1 Introduction to Machine-to-Machine Communications;137
9.1.1;1.1 Applications of M2M Communications;138
9.1.2;1.2 Design and Performance Analysis of M2M Communications;140
9.1.3;1.3 M2M Security Challenges and State-of-the-Art Solutions;140
9.2;2 Energy Harvesting;141
9.2.1;2.1 Energy Harvesting Sources;142
9.2.2;2.2 RF Energy Harvesting;143
9.2.2.1;Recent Developments in Wireless Power Transfer;144
9.3;3 Principles of Physical Layer Security;145
9.3.1;3.1 Categorization of Eavesdroppers;145
9.3.1.1;Based on Cooperation;145
9.3.1.2;Based on Activity;146
9.3.2;3.2 Comparative Analysis of Secure Energy Harvesting Protocols;146
9.4;4 Secrecy Performance of Energy Harvesting M2M Networks;150
9.4.1;4.1 System Model;150
9.4.1.1;Assumptions;151
9.4.1.2;Dedicated Jamming;151
9.4.1.3;FD Destination-Assisted Jamming;153
9.4.2;4.2 Secrecy Outage Probability Analysis;156
9.4.2.1;Dedicated Jamming;156
9.4.2.2;FD Destination-Assisted Jamming;157
9.4.3;4.3 Results and Discussion;158
9.4.4;4.4 Conclusions;161
9.4.5;4.5 Future Research Directions;161
9.5;References;162
10;Beam-Domain Full-Duplex Massive MIMO Transmission in the Cellular System;168
10.1;1 Introduction;168
10.2;2 System and Channel Models;170
10.3;3 Beam-Domain Full-Duplex Transmission Scheme;174
10.3.1;3.1 Beam-Domain Channel Representation;174
10.3.2;3.2 Beam-Domain Full-Duplex Transmission;180
10.4;4 Practical Implementation of BDFD Scheme;184
10.4.1;4.1 K-Means-Based UE Grouping;184
10.4.2;4.2 Full-Duplex Effective Beam-Domain Channel Estimation;186
10.4.2.1;Uplink Effective Beam-Domain Channel Estimation;187
10.4.2.2;Downlink Effective Beam-Domain Channel Estimation;188
10.4.3;4.3 Beam-Domain Data Transmission and Achievable Rate with Noisy CSI;189
10.4.4;4.4 Interference Control Between Uplink and Downlink;193
10.5;5 Simulation Results;193
10.6;6 Conclusion;198
10.7;Appendix;198
10.8;References;202
11;Correction to: 5G Security: Concepts and Challenges;206
12;Index;207
