Secure Wireless Communication in Active RIS-Assisted DFRC System

TL;DR

This paper proposes an active RIS-assisted dual-functional radar and communication system that enhances secrecy rate and radar performance by joint beamforming and reflecting coefficient design, outperforming passive RIS in simulations.

Contribution

It introduces an optimization framework using SDR and MM techniques for active RIS in DFRC systems, addressing secrecy and radar constraints.

Findings

Active RIS improves secrecy rate over passive RIS.

The proposed algorithm effectively optimizes beamforming and reflection.

Simulation results show enhanced radar and communication performance.

Abstract

This work considers a dual-functional radar and communication (DFRC) system with an active reconfigurable intelligent surface (RIS) and a potential eavesdropper. Our purpose is to maximize the secrecy rate (SR) of the system by jointly designing the beamforming matrix at the DFRC base station (BS) and the reflecting coefficients at the active RIS, subject to the signal-to-interference-plus-noise-ratio (SINR) constraint of the radar echo and the power consumption constraints at the DFRC-BS and active RIS. An alternating optimization (AO) algorithm based on semi-definite relaxation (SDR) and majorizationminimization (MM) is applied to solve the SR-maximization problem by alternately optimizing the beamforming matrix and the reflecting coefficients. Specifically, we first apply the SDR and successive convex approximation (SCA) methods to transform the two subproblems into more tractable forms, then the MM method is applied to derive a concave surrogate function and iteratively solve the subproblems. Finally, simulation results indicate that the active RIS can better confront the impact of "multiplicative fading" and outperforms traditional passive RIS in terms of both secure data rate and radar sensing performance.