Low-Altitude ISAC with Rotatable Active and Passive Arrays

TL;DR

This paper presents a novel low-altitude ISAC system utilizing cooperative rotatable active and passive arrays, optimizing joint beamforming and rotation to enhance sum-rate and sensing accuracy in 3D environments.

Contribution

It introduces a rotation-aware geometry-based model and a penalty-based AO optimization framework for jointly designing array rotations, beamforming, and RIS configurations.

Findings

Significant sum-rate improvements over fixed-array systems.

Effective sensing performance with directional antennas.

Enhanced low-altitude target sensing and communication in interference-limited scenarios.

Abstract

This paper investigates a low-altitude integrated sensing and communication (ISAC) system that leverages cooperative rotatable active and passive arrays. We consider a downlink scenario where a base station (BS) with an active rotatable array serves multiple communication users and senses low-altitude targets, assisted by a rotatable reconfigurable intelligent surface (RIS). A rotation-aware geometry-based multipath model is developed to capture the impact of three-dimensional (3D) array orientations on both steering vectors and direction-dependent element gains. On this basis, we formulate a new optimization problem that maximizes the downlink sum rate subject to a transmit power budget, RIS unit-modulus constraints, mechanical rotation limits, and a sensing beampattern mean-squared-error (MSE) constraint. To address the resulting highly non-convex problem, we propose a penalty-based alternating-optimization (AO) framework that alternately updates the BS precoder, RIS phase shifts, and BS/RIS array rotation angles. The three blocks are efficiently handled via a convex optimization method based on quadratic-transform (QT) and majorization-minorization (MM), Riemannian conjugate gradient (RCG) on the unit-modulus manifold, and projected gradient descent (PGD) with Barzilai-Borwein step sizes, respectively. Numerical results in low-altitude geometries demonstrate that the proposed jointly rotatable BS-RIS architecture achieves significant sum-rate gains over fixed or partially rotatable baselines while guaranteeing sensing requirements, especially with directional antennas and in interference-limited regimes.