On the average secrecy capacity for indoor visible light communication systems

For visible light communication (VLC), the light signals are transmitted without optical fibers or any sort of wave-guiding. Due to the inherent broadcast nature, physical-layer security emerges as a promising method to protect information delivery from eavesdropping. As for the secrecy capacity of VLC channel, there exist two features. In one way, the limited optical power makes the common capacity expressions in radio-frequency (RF) communication unapplicable for VLC. In another way, several correlated geometrical parameters directly alters the Lambertian model of indoor VLC channel, which gives the secrecy capacity more meanings. However, the issue considering both aspects has not been studied recently. In this paper, from the practical scenarios, we extract a typical geometrical model to reveal the mobility principles of the legitimate receiver and the eavesdroppers. Then, we character two typical distributions of the geometrical parameter. Correspondingly, we derive the upper and lower bounds on the average secrecy capacity, which have the closed forms. Finally, simulation results show that our upper and lower bounds are tight at high optical signal-to-noise rates (OSNRs). Moreover, the geometrical features of VLC systems and distribution parameters of the receiver mobility are effectively reveal by the bounds.

[1]  Mohamed-Slim Alouini,et al.  Free-Space Optical Communications: Capacity Bounds, Approximations, and a New Sphere-Packing Perspective , 2016, IEEE Transactions on Communications.

[2]  Harald Haas,et al.  Indoor optical wireless communication: potential and state-of-the-art , 2011, IEEE Communications Magazine.

[3]  Zabih Ghassemlooy,et al.  Indoor Gigabit optical wireless communications: Challenges and possibilities , 2010, 2010 12th International Conference on Transparent Optical Networks.

[4]  Matthieu R. Bloch,et al.  Physical-Layer Security: From Information Theory to Security Engineering , 2011 .

[5]  Claude E. Shannon,et al.  Communication theory of secrecy systems , 1949, Bell Syst. Tech. J..

[6]  Stefan M. Moser,et al.  Capacity Results of an Optical Intensity Channel With Input-Dependent Gaussian Noise , 2012, IEEE Transactions on Information Theory.

[7]  Frédérique E. Oggier,et al.  The secrecy capacity of the MIMO wiretap channel , 2007, 2008 IEEE International Symposium on Information Theory.

[8]  Chung Shue Chen,et al.  Indoor MIMO Visible Light Communications: Novel Angle Diversity Receivers for Mobile Users , 2015, IEEE Journal on Selected Areas in Communications.

[9]  Lutz H.-J. Lampe,et al.  Physical-Layer Security for MISO Visible Light Communication Channels , 2015, IEEE Journal on Selected Areas in Communications.

[10]  Gregory W. Wornell,et al.  Secure Transmission With Multiple Antennas I: The MISOME Wiretap Channel , 2010, IEEE Transactions on Information Theory.

[11]  Yunfei Chen,et al.  Physical-Layer Security Over Non-Small-Scale Fading Channels , 2016, IEEE Transactions on Vehicular Technology.

[12]  C. E. SHANNON,et al.  A mathematical theory of communication , 1948, MOCO.

[13]  Dominic C. O'Brien,et al.  High data rate multiple input multiple output (MIMO) optical wireless communications using white led lighting , 2009, IEEE Journal on Selected Areas in Communications.

[14]  H. Vincent Poor,et al.  Secrecy Capacity Region of a Multiple-Antenna Gaussian Broadcast Channel With Confidential Messages , 2007, IEEE Transactions on Information Theory.

[15]  Gregory W. Wornell,et al.  Secure Transmission With Multiple Antennas—Part II: The MIMOME Wiretap Channel , 2010, IEEE Transactions on Information Theory.

[16]  Amitav Mukherjee Secret-Key Agreement for Security in Multi-Emitter Visible Light Communication Systems , 2016, IEEE Communications Letters.

[17]  Martin E. Hellman,et al.  The Gaussian wire-tap channel , 1978, IEEE Trans. Inf. Theory.

[18]  Steve Hranilovic,et al.  Capacity Bounds for Wireless Optical Intensity Channels With Gaussian Noise , 2010, IEEE Transactions on Information Theory.

[19]  Thomas M. Cover,et al.  Elements of Information Theory , 2005 .

[20]  Jiangzhou Wang,et al.  Tight Bounds on Channel Capacity for Dimmable Visible Light Communications , 2013, Journal of Lightwave Technology.

[21]  Zhiguo Ding,et al.  On Secure VLC Systems With Spatially Random Terminals , 2017, IEEE Communications Letters.

[22]  Rui Jiang,et al.  A Tight Upper Bound on Channel Capacity for Visible Light Communications , 2016, IEEE Communications Letters.

[23]  Yeong Min Jang,et al.  Priority-based resource allocation scheme for visible light communication , 2010, 2010 Second International Conference on Ubiquitous and Future Networks (ICUFN).

[24]  Masao Nakagawa,et al.  Fundamental analysis for visible-light communication system using LED lights , 2004, IEEE Transactions on Consumer Electronics.

[25]  Amos Lapidoth,et al.  On the capacity of free-space optical intensity channels , 2009, IEEE Trans. Inf. Theory.

[26]  Nan Liu,et al.  Towards the Secrecy Capacity of the Gaussian MIMO Wire-Tap Channel: The 2-2-1 Channel , 2007, IEEE Transactions on Information Theory.

[27]  Shlomo Shamai,et al.  A Note on the Secrecy Capacity of the Multiple-Antenna Wiretap Channel , 2007, IEEE Transactions on Information Theory.

[28]  A. D. Wyner,et al.  The wire-tap channel , 1975, The Bell System Technical Journal.

[29]  Wei Xu,et al.  Secrecy-Oriented Transmitter Optimization for Visible Light Communication Systems , 2016, IEEE Photonics Journal.