Abstract
This article considers an artificial noise (AN)-aided secure MIMO wireless communication system. To enhance the system security performance, the advanced intelligent reflecting surface (IRS) is invoked, and the base station (BS), legitimate information receiver (IR) and eavesdropper (Eve) are equipped with multiple antennas. With the aim for maximizing the secrecy rate (SR), the transmit precoding (TPC) matrix at the BS, covariance matrix of AN and phase shifts at the IRS are jointly optimized subject to constrains of transmit power limit and unit modulus of IRS phase shifts. Then, the secrecy rate maximization (SRM) problem is formulated, which is a non-convex problem with multiple coupled variables. To tackle it, we propose to utilize the block coordinate descent (BCD) algorithm to alternately update the variables while keeping SR non-decreasing. Specifically, the optimal TPC matrix and AN covariance matrix are derived by Lagrangian multiplier method, and the optimal phase shifts are obtained by Majorization-Minimization (MM) algorithm. Since all variables can be calculated in closed form, the proposed algorithm is very efficient. We also extend the SRM problem to the more general multiple-IRs scenario and propose a BCD algorithm to solve it. Simulation results validate the effectiveness of system security enhancement via an IRS.
Highlights
T HE next-generation (i.e, 6G) communication is expected to be a sustainable green, cost-effective and secure communication system [1]
The path-loss exponent of the link from base station (BS) to intelligent reflecting surface (IRS) is set to be αBR = 2.2, which means that the IRS is well-located, and the path loss is negligible in this link
We propose to enhance the security performance of artificial noise (AN)-aided MIMO secure communication systems by exploiting an IRS
Summary
T HE next-generation (i.e, 6G) communication is expected to be a sustainable green, cost-effective and secure communication system [1]. Secure communication is crucially important in 6G communication networks since. Manuscript received January 17, 2020; revised June 15, 2020 and August 13, 2020; accepted September 10, 2020. Date of publication September 21, 2020; date of current version December 16, 2020. The associate editor coordinating the review of this article and approving it for publication was X.
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