Rate-Splitting Multiple Access for Secure Near-Field Integrated Sensing and Communication

TL;DR

This paper introduces a novel RSMA-based secure transmit scheme for near-field ISAC that enhances beamfocusing, reduces hardware costs, and improves secrecy and sensing accuracy through joint interference management and artificial noise.

Contribution

It proposes the first RSMA-enabled secure transmit scheme for near-field ISAC, optimizing beamfocusing and secrecy with reduced RF chains and improved performance.

Findings

Achieves near full-digital beamfocusing with 16-fold fewer RF chains.

Outperforms conventional schemes in secrecy and sensing accuracy.

Provides high-precision sensing with negligible secrecy loss.

Abstract

Near-field integrated sensing and communication (ISAC) leverages distance-dependent channel variations for joint distance and angle estimation. However, full-digital architectures have prohibitive hardware costs, making hybrid analog-digital (HAD) designs the primary alternative. Nevertheless, such architectures compromise beamfocusing precision and lead to energy leakage, which exacerbates inter-user interference and increases eavesdropping risks. To address these challenges, this paper proposes a rate-splitting multiple access (RSMA)-enhanced secure transmit scheme for near-field ISAC. For the first time, it exploits the common stream in RSMA to concurrently (i) flexibly manage interference, (ii) act as artificial noise to suppress eavesdropping, and (iii) serve as sensing sequences. The objective is to maximize the minimum secrecy rate while satisfying the angle and distance Cramer-Rao Bound (CRB) constraints. This results in a hard, non-convex optimization problem, and we employ block coordinate descent to decompose it into three sub-problems with lower computational complexity. In the first stage of optimizing fully digital beamfocusers, we develop an iterative solution using weighted minimum mean-squared error (WMMSE), quadratic transform, and Taylor expansion methods, thus avoiding conventional semidefinite relaxation. In the second and third stages, the analog and digital beamfocusers are optimized in closed form. Simulation results show that the proposed scheme (1) achieves near full-digital beamfocusing performance with a 16-fold reduction in RF chains, (2) provides superior secrecy performance compared to conventional beamfocusing-only and far-field security schemes, and (3) enables high-accuracy sensing with negligible loss in secrecy performance.