Multi-IRS Aided ISAC System: Multi-Path Exploitation Versus Reduction

TL;DR

This paper explores a multi-IRS aided ISAC system that balances communication and sensing performance, revealing fundamental tradeoffs and optimizing system design under element constraints.

Contribution

It proposes a hybrid multi-IRS architecture with active sensors, analyzes the tradeoff between sensing and communication, and derives optimal design strategies for system parameters.

Findings

Increasing IRSs improves communication DoFs but raises CRB, indicating a tradeoff.

Optimal system design depends on the total IRS elements and sensing/communication priorities.

Simulation results confirm theoretical tradeoffs and the effectiveness of proposed schemes.

Abstract

This paper investigates a multi-intelligent reflecting surface (IRS) aided integrated sensing and communication (ISAC) system, where multiple IRSs are strategically deployed not only to assist the communication from a multi-antenna base station (BS) to a multi-antenna communication user (CU), but also enable the sensing service for a point target in the non-line-of-sight (NLoS) region of the BS. First, we propose a hybrid multi-IRS architecture, which consists of several passive IRSs and one semi-passive IRS equipped with both active sensors and reflecting elements. To be specific, the active sensors are exploited to receive the echo signals for estimating the target's angle information, and the multiple reflecting paths provided by multi-IRS are employed to improve the degree of freedoms (DoFs) of communication. Under the given budget on the number of total IRSs elements, we theoretically show that increasing the number of deployed IRSs is beneficial for improving DoFs of spatial multiplexing for communication while increasing the Cramer-Rao bound (CRB) of target estimation, which unveils a fundamental tradeoff between the sensing and communication performance. To characterize the rate-CRB tradeoff, we study a rate maximization problem, by optimizing the BS transmit covariance matrix, IRSs phase-shifts, and the number of deployed IRSs, subject to a maximum CRB constraint. Analytical results reveal that the communication-oriented design becomes optimal when the total number of IRSs elements exceeds a certain threshold, wherein the relationships of the rate and CRB with the number of IRS elements/sensors, transmit power, and the number of deployed IRSs are theoretically derived and demystified. Simulation results validate our theoretical findings and also demonstrate the superiority of our proposed designs over the benchmark schemes.