DocumentCode
1402311
Title
Physical Layer Security in Multibeam Satellite Systems
Author
Zheng, Gan ; Arapoglou, Pantelis-Daniel ; Ottersten, Björn
Author_Institution
Interdiscipl. Centre for Security, Univ. of Luxembourg, Luxembourg-Kirchberg, Luxembourg
Volume
11
Issue
2
fYear
2012
fDate
2/1/2012 12:00:00 AM
Firstpage
852
Lastpage
863
Abstract
Security threats introduced due to the vulnerability of the transmission medium may hinder the proliferation of Ka band multibeam satellite systems for civil and military data applications. This paper sets the analytical framework and then studies physical layer security techniques for fixed legitimate receivers dispersed throughout multiple beams, each possibly surrounded by multiple (passive) eavesdroppers. The design objective is to minimize via transmit beamforming the costly total transmit power on board the satellite, while satisfying individual intended users´ secrecy rate constraints. Assuming state-of-the-art satellite channel models, when perfect channel state information (CSI) about the eavesdroppers is available at the satellite, a partial zero-forcing approach is proposed for obtaining a low-complexity sub-optimal solution. For the optimal solution, an iterative algorithm combining semi-definite programming relaxation and the gradient-based method is devised by studying the convexity of the problem. Furthermore, the use of artificial noise as an additional degree-of-freedom for protection against eavesdroppers is explored. When only partial CSI about the eavesdroppers is available, we study the problem of minimizing the eavesdroppers´ received signal to interference-plus-noise ratios. Simulation results demonstrate substantial performance improvements over existing approaches.
Keywords
array signal processing; communication complexity; computer network security; gradient methods; iterative methods; mathematical programming; satellite communication; telecommunication network reliability; wireless channels; CSI; Ka band multibeam satellite systems; artificial noise; channel state information; civil data applications; fixed legitimate receiver; gradient-based method; iterative algorithm; low-complexity suboptimal solution; military data applications; multiple eavesdroppers; partial zero-forcing approach; physical layer security; satellite channel models; security threats; semidefinite programming relaxation; signal-interference-plus-noise ratios; transmission medium vulnerability; transmit beamforming; user secrecy rate constraints; Array signal processing; Covariance matrix; Interference; Receivers; Satellite broadcasting; Satellites; Security; Multibeam satellite; artificial noise; physical-layer security; semi-definite programming;
fLanguage
English
Journal_Title
Wireless Communications, IEEE Transactions on
Publisher
ieee
ISSN
1536-1276
Type
jour
DOI
10.1109/TWC.2011.120911.111460
Filename
6108297
Link To Document