Joint Transmit and Receive Antenna Orientation Design for Secure MIMO Communications

TL;DR

This paper proposes a joint optimization of antenna orientations and transmission strategies in secure MIMO systems with rotatable antennas to improve secrecy rates against eavesdroppers.

Contribution

It introduces a novel joint design framework for transmit beamforming, artificial noise, and antenna orientations in secure MIMO communications with rotatable antennas.

Findings

The proposed scheme significantly outperforms fixed-orientation schemes in secrecy rate.

The optimization algorithm converges rapidly and effectively enhances security.

The approach extends to multi-receiver scenarios, maintaining performance gains.

Abstract

Physical layer security (PLS) is a promising paradigm for safeguarding 6G wireless networks by exploiting the inherent characteristics of wireless channels. However, the efficiency of conventional PLS is often limited by fixed orientation antennas. This paper investigates a rotatable antenna (RA)-aided secure multiple-input multiple-output (MIMO) communication system, where both the transmitter and the receiver are equipped with RAs in the presence of an eavesdropper. By dynamically optimizing the orientations of RAs, we can proactively reshape the effective MIMO channels to enhance legitimate transmission while simultaneously suppressing information leakage to the eavesdropper. We formulate a secrecy rate maximization problem by jointly optimizing the transmit beamforming, artificial noise (AN) covariance matrix, and the transmit/receive RA orientations, subject to the transmit power budget and antenna orientation constraints. To tackle the resulting highly coupled and non-convex problem, we first study a simplified single-input single-output (SISO) case to reveal the structure of the optimal RA orientation. For the general MIMO case, we develop an alternating optimization algorithm by reformulating the original problem through the minimum mean-square error framework. In particular, the transmit beamforming and AN covariance matrix are derived in semi-closed forms, while the RA orientations are updated via the Riemannian Frank-Wolfe method. The proposed design is further extended to the multi-receiver secure transmission scenario. Simulation results show that the proposed scheme converges rapidly and achieves significant secrecy rate gains over the conventional fixed-orientation scheme.