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ZTE Communications ›› 2013, Vol. 11 ›› Issue (3): 1-2.

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Guest Editorial: Physical Layer Security forWireless and Quantum Communications

Jinhong Yuan1, Yixian Yang2, and Nanrun Zhou3   

  1. 1. University of New South Wales, Australia
    2. Beijing University of Posts and Telecommunications, China
    3. Nanchang University, China
  • 出版日期:2013-09-25 发布日期:2013-09-25
  • 作者简介:Jinhong Yuan received his BE and PhD degrees in electronics engineering from Beijing Institute of Technology in 1991 and 1997. From 1997 to 1999, he was a research fellow at the School of Electrical Engineering, University of Sydney, Australia. In 2000, he joined the School of Electrical Engineering and Telecommunications, University of New South Wales, Australia, and is currently a professor of telecommunications at that school. Dr. Yuan has authored two books, two book chapters, and more than 200 papers for telecommunications journals and conferences. He has also authored 40 industry reports. He is a co-inventor of one patent on MIMO systems and two patents on low-density parity-check (LDPC) codes. He has co-authored three papers that have won Best Paper Awards or Best Poster Awards. His published work list is available at http://www2. ee.unsw.edu.au/wcl/JYuan.html. Dr. Yuan is currently the NSW Chair of the joint Communications/Signal Processions/Ocean Engineering Chapter of IEEE. He is also an associate editor for IEEE Transactions on Communications. His research interests include error-control coding and information theory, communication theory, and wireless communications.

    Professor Yixian Yang is the Director of Information Security Center, Beijing University of Posts and Telecommunications. He is also chief of the National Engineering Laboratory for Disaster Backup and Recovery, National Key Laboratory for Network and Information Defense. He received his PhD degree in electrical engineering and communication systems from BUPT in 1988. His research interests include network coding, coding theory, cryptography, information security, internet/intranet security, communication theory, graph theory, neural networks, signal processing, software radio, wavelet theory, discrete mathematics, and e-commerce. Dr. Yang has authored more than 500 research papers in academic journals such as IEEE Transactions on Communications, and has also authored textbooks and monographs.

    Nanrun Zhou received his BSc degree in Physics Education and his MSc degree in Theoretical Physics from Jiangxi Normal University in 2000 and 2003. He received his PhD degree in Communications and Information Systems from Shanghai Jiaotong University in 2005. In 2006, he joined the School of Information Engineering, Nanchang University, and is currently a professor and PhD supervisor at that school. From September 2011 to July 2012, he was a visiting scholar in the School of Computer Science, Beijing University of Posts and Telecommunications. Previously, he has been selected to the first and second ranks of the Jiangxi Province Baiqianwan Talents for the New Century Programme, the Young Scientists of Jiangxi Province (Jinggang Star), and the Ganpo Programme 555 for Outstanding Talent. His research interests include quantum communication, quantum cryptography, optical image encryption, and wireless communication security. He has published more than 110 papers in refereed international journals and conference proceedings.

Guest Editorial: Physical Layer Security forWireless and Quantum Communications

Jinhong Yuan1, Yixian Yang2, and Nanrun Zhou3   

  1. 1. University of New South Wales, Australia
    2. Beijing University of Posts and Telecommunications, China
    3. Nanchang University, China
  • Online:2013-09-25 Published:2013-09-25
  • About author:Jinhong Yuan received his BE and PhD degrees in electronics engineering from Beijing Institute of Technology in 1991 and 1997. From 1997 to 1999, he was a research fellow at the School of Electrical Engineering, University of Sydney, Australia. In 2000, he joined the School of Electrical Engineering and Telecommunications, University of New South Wales, Australia, and is currently a professor of telecommunications at that school. Dr. Yuan has authored two books, two book chapters, and more than 200 papers for telecommunications journals and conferences. He has also authored 40 industry reports. He is a co-inventor of one patent on MIMO systems and two patents on low-density parity-check (LDPC) codes. He has co-authored three papers that have won Best Paper Awards or Best Poster Awards. His published work list is available at http://www2. ee.unsw.edu.au/wcl/JYuan.html. Dr. Yuan is currently the NSW Chair of the joint Communications/Signal Processions/Ocean Engineering Chapter of IEEE. He is also an associate editor for IEEE Transactions on Communications. His research interests include error-control coding and information theory, communication theory, and wireless communications.

    Professor Yixian Yang is the Director of Information Security Center, Beijing University of Posts and Telecommunications. He is also chief of the National Engineering Laboratory for Disaster Backup and Recovery, National Key Laboratory for Network and Information Defense. He received his PhD degree in electrical engineering and communication systems from BUPT in 1988. His research interests include network coding, coding theory, cryptography, information security, internet/intranet security, communication theory, graph theory, neural networks, signal processing, software radio, wavelet theory, discrete mathematics, and e-commerce. Dr. Yang has authored more than 500 research papers in academic journals such as IEEE Transactions on Communications, and has also authored textbooks and monographs.

    Nanrun Zhou received his BSc degree in Physics Education and his MSc degree in Theoretical Physics from Jiangxi Normal University in 2000 and 2003. He received his PhD degree in Communications and Information Systems from Shanghai Jiaotong University in 2005. In 2006, he joined the School of Information Engineering, Nanchang University, and is currently a professor and PhD supervisor at that school. From September 2011 to July 2012, he was a visiting scholar in the School of Computer Science, Beijing University of Posts and Telecommunications. Previously, he has been selected to the first and second ranks of the Jiangxi Province Baiqianwan Talents for the New Century Programme, the Young Scientists of Jiangxi Province (Jinggang Star), and the Ganpo Programme 555 for Outstanding Talent. His research interests include quantum communication, quantum cryptography, optical image encryption, and wireless communication security. He has published more than 110 papers in refereed international journals and conference proceedings.

摘要: This special issue is dedicated to security problems in wireless and quantum communications. Papers for this issue were invited, and after peer review, eight were selected for publication. The first part of this issue comprises four papers on recent advances in physical layer security for wireless networks. The second part comprises another four papers on quantum communications.

Wireless networks have become pervasive in order to guarantee global digital connectivity, and wireless devices have quickly evolved into multimedia smartphones running applications that demand high-speed data connections. Multiuser multiple-input multiple-output (MIMO) wireless techniques meet this demand by achieving high spectral efficiency. Security is also regarded as critical in wireless multiuser networks because users rely on these networks to transmit sensitive data. Because of the broadcast nature of the physical medium, wireless multiuser communication is very susceptible to eavesdropping, and it is essential to protect transmitted information. Wireless communications have traditionally been secured by network layer key-based cryptography. However, in large, dynamic wireless networks, classical cryptography might not be suitable. Classical cryptography tends to cause problems in terms of key distribution and management (for symmetric cryptosystems) and computational complexity (for asymmetric cryptosystems). Moreover, classical cryptography is potentially vulnerable because it relies on the unproven assumption that certain mathematical functions are difficult to invert. Recently, methods have been proposed to provide an additional level of protection and to achieve perfect secrecy without encryption keys. These methods, collectively referred to as physical layer security, exploit the randomness inherent in noisy channels. Physical layer security has been identified as the highest form of security and will be a critical part of future communication networks. The core principle of physical layer security is to restrict the amount of useful information that can be extracted at the symbol/signal level by an unauthorized receiver. This is achieved by carefully designing intelligent and appropriate coding and precoding techniques that exploit the wireless medium’s channel state information. As opposed to classic cryptography, physical layer security is based on information-theoretic principles and does not rely on secret keys or the limited computational capacity of the eavesdropper. Over the past few years, the information-theoretic aspect of secrecy at the physical layer has attracted significant interest and promises to significantly affect both the theory and practical design of future wireless networks.

In“Location Verification Systems in Emerging Wireless Networks,”Yan and Malaney discuss location-based techniques and applications. They show that in recent years, there has been an explosion of activity related to location-verification techniques in wireless networks. This work has focused on intelligent transport system (ITS) because of the mission-critical nature of vehicle location verification within ITS. The authors review recent research on wireless location verification related to the vehicular networks. In particular, they focus on location verification systems that rely on formal mathematical classification frameworks and show how many systems are either partly or fully encompassed by such frameworks.

In“Wireless Physical Layer Security with Imperfect Channel State Information: A Survey,”Bao He et al. provide a comprehensive survey of physical layer security in wireless networks with imperfect channel state information (CSI) at communication nodes. The authors describe the main information-theoretic ways that secrecy is measured when CSI is imperfect. They also describe signal processing enhancements for secure transmission. These enhancements include secure on-off transmission, beamforming with artificial noise, and secure communication assisted by relay nodes or cognitive radio systems. The authors discuss the recent development of physical layer security in large, decentralized wireless networks as well as open problems and future research directions.

In“Methodologies of Secret-Key Agreement Using Wireless Channel Characteristics,”Ali and Sivaraman give an overview of current research on shared secret-key agreement between two parties. This agreement is based on the wireless channel characteristics of the radio. The authors discuss the advantages of shared secret-key agreement over traditional cryptographic mechanisms and describe the theory behind this technique. They also describe the key agreement process, threat model, and typical performance metrics. A shared secret-key agreement comprises four processes: sampling, quantization, information reconciliation, and privacy application. The authors also discuss existing challenges and future research directions.

In“An Introduction to Transmit Antenna Selection in MIMO Wiretap Channels,”Yang et al. propose transmit antenna selection as a low-complexity, enecgy-efficient way of improving physical layer security in multiple-input multiple-output wiretap channels. The authors describe a general framework for analyzing the exact and asymptotic secrecy of transmit antenna selection. This framework includes receive maximal ratio combining, selection combining, or generalized selection combining. The results show that secrecy is significantly increased when the number of transmit antennas is increased.

Significant progress has been made in quantum communications as a result of increased support from governments and enterprises. There is a practical need for quantum communication, and it will significantly alter future communications. Quantum cryptography can benefit from the properties of quantum systems, e.g. entangled systems. Quantum entanglement lies at the heart of quantum information processing and communication. For a long time, entanglement was seen merely as a fancy feature that makes quantum mechanics counterintuitive. Quantum information theory has recently shown how quantum correlations are tremendously important to the formulation of new methods of information transfer and for algorithms based on quantum computers. Quantum correlation makes quantum information processing powerful and interesting. In a quantum many-particle system, classifying and quantifying correlations in a multipartite quantum state and determining how much knowledge about the quantum system can be acquired from subsystems are fundamental problems. The main task of quantum information processing and communication is the delivery of quantum states. The main focus of quantum information processing and communication is the delivery of quantum states. A quantum carrier or quantum channel can perform miracles compared with conventional signal processing and communication. In practice, it is very difficult to deliver entangled photons over long distances because of channel loss and detector noise. Quantum error correction coding is necessary for practical, reliable quantum information processing and can be performed in a noisy or real channel or in an imperfect processor.

In“Reducible Discord in Generic Three-Qubit Pure W States,”Zhihui Li et al. show that quantum correlation in generic three-qubit pure W states can be given by the two-qubit discord of these states. The authors show that reducing discord in the generalized three-qubit pure W state is complicated.

In“Two-Way Cooperative Quantum Communication with Partial Entanglement Analysis,”Ying Guo et al. describe an improved cooperative two-way quantum communication scheme. This scheme works in a forward-and-backward manner and is based on the five-qubit entangled Brown state. It allows Alice and Bob to simultaneously exchange arbitrary unknown states with the help of trusted Charlie. The authors show how to transfer arbitrary unknown states in a secure cooperative manner using encryption performed by trusted Charlie.

In “A Coding and Automatic Error-Correction Circuit Based on the Five-Particle Entangled State,”Xiaoqing Zhou et al. propose a quantum-coding and error-correction circuit for the five particle entangled state. This circuit can correct the bit-reversed or phase-flip error of one and two quantum states. The authors also simplify the design of a multiple quantum error-correction circuit.

In“Optimal Rate for Constant-Fidelity Entanglement in Quantum Communication Networks,”Xutao Yu et al. describe how to achieve constant fidelity entanglement over long distances in quantum networks. The authors discuss the rate capacities of constant fidelity entanglement for both elementary and multihop links. In particular, the authors focus on the rate capacity of constant fidelity entanglement in quantum communication networks when the number of nodes in a multihop link tends towards infinity. The authors draw the concepts of classical ad hoc networks to optimize the rate capacity of one typical structure of a quantum repeater. The rate capacities of the recursive entanglement scheme (simultaneous entanglement scheme) and adjacent entanglement scheme are Ω(1/en ) and Ω(1/n ), respectively.

We thank all authors for their valuable contributions and all reviewers for their timely and constructive comments on submitted papers. We hope the content of this issue is informative and helpful to all readers.

关键词: Physical Layer Security, Wireless Communications, Quantum Communications

Abstract: This special issue is dedicated to security problems in wireless and quantum communications. Papers for this issue were invited, and after peer review, eight were selected for publication. The first part of this issue comprises four papers on recent advances in physical layer security for wireless networks. The second part comprises another four papers on quantum communications.

Wireless networks have become pervasive in order to guarantee global digital connectivity, and wireless devices have quickly evolved into multimedia smartphones running applications that demand high-speed data connections. Multiuser multiple-input multiple-output (MIMO) wireless techniques meet this demand by achieving high spectral efficiency. Security is also regarded as critical in wireless multiuser networks because users rely on these networks to transmit sensitive data. Because of the broadcast nature of the physical medium, wireless multiuser communication is very susceptible to eavesdropping, and it is essential to protect transmitted information. Wireless communications have traditionally been secured by network layer key-based cryptography. However, in large, dynamic wireless networks, classical cryptography might not be suitable. Classical cryptography tends to cause problems in terms of key distribution and management (for symmetric cryptosystems) and computational complexity (for asymmetric cryptosystems). Moreover, classical cryptography is potentially vulnerable because it relies on the unproven assumption that certain mathematical functions are difficult to invert. Recently, methods have been proposed to provide an additional level of protection and to achieve perfect secrecy without encryption keys. These methods, collectively referred to as physical layer security, exploit the randomness inherent in noisy channels. Physical layer security has been identified as the highest form of security and will be a critical part of future communication networks. The core principle of physical layer security is to restrict the amount of useful information that can be extracted at the symbol/signal level by an unauthorized receiver. This is achieved by carefully designing intelligent and appropriate coding and precoding techniques that exploit the wireless medium’s channel state information. As opposed to classic cryptography, physical layer security is based on information-theoretic principles and does not rely on secret keys or the limited computational capacity of the eavesdropper. Over the past few years, the information-theoretic aspect of secrecy at the physical layer has attracted significant interest and promises to significantly affect both the theory and practical design of future wireless networks.

In“Location Verification Systems in Emerging Wireless Networks,”Yan and Malaney discuss location-based techniques and applications. They show that in recent years, there has been an explosion of activity related to location-verification techniques in wireless networks. This work has focused on intelligent transport system (ITS) because of the mission-critical nature of vehicle location verification within ITS. The authors review recent research on wireless location verification related to the vehicular networks. In particular, they focus on location verification systems that rely on formal mathematical classification frameworks and show how many systems are either partly or fully encompassed by such frameworks.

In“Wireless Physical Layer Security with Imperfect Channel State Information: A Survey,”Bao He et al. provide a comprehensive survey of physical layer security in wireless networks with imperfect channel state information (CSI) at communication nodes. The authors describe the main information-theoretic ways that secrecy is measured when CSI is imperfect. They also describe signal processing enhancements for secure transmission. These enhancements include secure on-off transmission, beamforming with artificial noise, and secure communication assisted by relay nodes or cognitive radio systems. The authors discuss the recent development of physical layer security in large, decentralized wireless networks as well as open problems and future research directions.

In“Methodologies of Secret-Key Agreement Using Wireless Channel Characteristics,”Ali and Sivaraman give an overview of current research on shared secret-key agreement between two parties. This agreement is based on the wireless channel characteristics of the radio. The authors discuss the advantages of shared secret-key agreement over traditional cryptographic mechanisms and describe the theory behind this technique. They also describe the key agreement process, threat model, and typical performance metrics. A shared secret-key agreement comprises four processes: sampling, quantization, information reconciliation, and privacy application. The authors also discuss existing challenges and future research directions.

In“An Introduction to Transmit Antenna Selection in MIMO Wiretap Channels,”Yang et al. propose transmit antenna selection as a low-complexity, enecgy-efficient way of improving physical layer security in multiple-input multiple-output wiretap channels. The authors describe a general framework for analyzing the exact and asymptotic secrecy of transmit antenna selection. This framework includes receive maximal ratio combining, selection combining, or generalized selection combining. The results show that secrecy is significantly increased when the number of transmit antennas is increased.

Significant progress has been made in quantum communications as a result of increased support from governments and enterprises. There is a practical need for quantum communication, and it will significantly alter future communications. Quantum cryptography can benefit from the properties of quantum systems, e.g. entangled systems. Quantum entanglement lies at the heart of quantum information processing and communication. For a long time, entanglement was seen merely as a fancy feature that makes quantum mechanics counterintuitive. Quantum information theory has recently shown how quantum correlations are tremendously important to the formulation of new methods of information transfer and for algorithms based on quantum computers. Quantum correlation makes quantum information processing powerful and interesting. In a quantum many-particle system, classifying and quantifying correlations in a multipartite quantum state and determining how much knowledge about the quantum system can be acquired from subsystems are fundamental problems. The main task of quantum information processing and communication is the delivery of quantum states. The main focus of quantum information processing and communication is the delivery of quantum states. A quantum carrier or quantum channel can perform miracles compared with conventional signal processing and communication. In practice, it is very difficult to deliver entangled photons over long distances because of channel loss and detector noise. Quantum error correction coding is necessary for practical, reliable quantum information processing and can be performed in a noisy or real channel or in an imperfect processor.

In“Reducible Discord in Generic Three-Qubit Pure W States,”Zhihui Li et al. show that quantum correlation in generic three-qubit pure W states can be given by the two-qubit discord of these states. The authors show that reducing discord in the generalized three-qubit pure W state is complicated.

In“Two-Way Cooperative Quantum Communication with Partial Entanglement Analysis,”Ying Guo et al. describe an improved cooperative two-way quantum communication scheme. This scheme works in a forward-and-backward manner and is based on the five-qubit entangled Brown state. It allows Alice and Bob to simultaneously exchange arbitrary unknown states with the help of trusted Charlie. The authors show how to transfer arbitrary unknown states in a secure cooperative manner using encryption performed by trusted Charlie.

In “A Coding and Automatic Error-Correction Circuit Based on the Five-Particle Entangled State,”Xiaoqing Zhou et al. propose a quantum-coding and error-correction circuit for the five particle entangled state. This circuit can correct the bit-reversed or phase-flip error of one and two quantum states. The authors also simplify the design of a multiple quantum error-correction circuit.

In“Optimal Rate for Constant-Fidelity Entanglement in Quantum Communication Networks,”Xutao Yu et al. describe how to achieve constant fidelity entanglement over long distances in quantum networks. The authors discuss the rate capacities of constant fidelity entanglement for both elementary and multihop links. In particular, the authors focus on the rate capacity of constant fidelity entanglement in quantum communication networks when the number of nodes in a multihop link tends towards infinity. The authors draw the concepts of classical ad hoc networks to optimize the rate capacity of one typical structure of a quantum repeater. The rate capacities of the recursive entanglement scheme (simultaneous entanglement scheme) and adjacent entanglement scheme are Ω(1/en ) and Ω(1/n ), respectively.

We thank all authors for their valuable contributions and all reviewers for their timely and constructive comments on submitted papers. We hope the content of this issue is informative and helpful to all readers.

Key words: Physical Layer Security, Wireless Communications, Quantum Communications