Iterative distributed minimum total-MSE approach for secure communications in MIMO interference channels
Abstract
In this paper, we consider the problem of joint transmit precoding (TPC) matrix and receive filter matrix design subject to both secrecy and per-transmitter power constraints in the MIMO interference channel, where legitimate transmitter-receiver pairs communicate in the presence of an external eavesdropper. Explicitly, we jointly design the TPC and receive filter matrices based on the minimum total mean-squared error (MT-MSE) criterion under a given and feasible information-theoretic degrees of freedom. More specifically, we formulate this problem by minimizing the total MSEs of the signals communicated between the legitimate transmitter-receiver pairs, whilst ensuring that the MSE of the signals decoded by the eavesdropper remains higher than a certain threshold. We demonstrate that the joint design of the TPC and receive filter matrices subject to both secrecy and transmit power constraints can be accomplished by an efficient iterative distributed algorithm. The convergence of the proposed iterative algorithm is characterized as well. Furthermore, the performance of the proposed algorithm, including both its secrecy rate and MSE, is characterized with the aid of numerical results. We demonstrate that the proposed algorithm outperforms the traditional interference alignment (IA) algorithm in terms of both the achievable secrecy rate and the MSE. As a benefit, secure communications can be guaranteed by the proposed algorithm for the MIMO interference channel even in the presence of a "sophisticated/strong" eavesdropper, whose number of antennas is much higher than that of each legitimate transmitter and receiver.
Cite
@article{arxiv.1510.03857,
title = {Iterative distributed minimum total-MSE approach for secure communications in MIMO interference channels},
author = {Zhengmin Kong and Shaoshi Yang and Feilong Wu and Shixin Peng and Liang Zhong and Lajos Hanzo},
journal= {arXiv preprint arXiv:1510.03857},
year = {2016}
}
Comments
16 pages, 9 figures, accepted to appear on IEEE Transactions on Information Forensics and Security, Oct. 2015