Secure Cell-Free Integrated Sensing and Communication in the Presence of Information and Sensing Eavesdroppers

Zixiang Ren;Jie Xu;Ling Qiu;Derrick Wing Kwan Ng
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Abstract

This paper studies a secure cell-free integrated sensing and communication (ISAC) system, in which multiple ISAC transmitters collaboratively send confidential information to multiple communication users (CUs) and concurrently conduct target detection. Different from prior works investigating communication security against potential information eavesdropping, we consider the security of both communication and sensing in the presence of information and sensing eavesdroppers that aim to intercept confidential communication information and extract target information, respectively. Towards this end, we optimize the joint information and sensing transmit beamforming at these ISAC transmitters for secure cell-free ISAC. Our objective is to maximize the detection probability over a designated sensing area while ensuring the minimum signal-to-interference-plus-noise-ratio (SINR) requirements at CUs. Our formulation also takes into account the maximum tolerable signal-to-noise ratio (SNR) constraints at information eavesdroppers for ensuring the confidentiality of information transmission, and the maximum detection probability constraints at sensing eavesdroppers for preserving sensing privacy. The formulated secure joint transmit beamforming problem is highly non-convex due to the intricate interplay between the detection probabilities, beamforming vectors, and SINR constraints. Fortunately, through strategic manipulation and via applying the semidefinite relaxation (SDR) technique, we successfully obtain the globally optimal solution to the design problem by rigorously verifying the tightness of SDR. Furthermore, we present two alternative joint beamforming designs based on the sensing SNR maximization over the specific sensing area and the coordinated beamforming, respectively. Numerical results reveal the benefits of our proposed design over these alternative benchmarks.
在存在信息和传感窃听者的情况下实现安全的无蜂窝综合传感与通信
本文研究了一种安全的无蜂窝综合传感与通信(ISAC)系统,在该系统中,多个 ISAC 发射器协同向多个通信用户(CU)发送机密信息,并同时进行目标检测。与之前研究针对潜在信息窃听的通信安全的工作不同,我们考虑的是在信息和传感窃听者存在的情况下通信和传感的安全性,窃听者的目的分别是截获机密通信信息和提取目标信息。为此,我们优化了这些 ISAC 发射机的联合信息和传感发射波束成形,以实现安全的无小区 ISAC。我们的目标是最大限度地提高指定传感区域的检测概率,同时确保 CU 的信号干扰比和噪声比(SINR)达到最小要求。我们的方案还考虑了信息窃听者的最大可容忍信噪比(SNR)约束,以确保信息传输的保密性,以及感知窃听者的最大检测概率约束,以保护感知隐私。由于检测概率、波束成形向量和 SINR 约束之间错综复杂的相互作用,所提出的安全联合发射波束成形问题是高度非凸的。幸运的是,通过策略操作和应用半无限松弛(SDR)技术,我们成功地获得了设计问题的全局最优解,严格验证了 SDR 的紧密性。此外,我们还提出了两种可供选择的联合波束成形设计,分别基于特定传感区域的传感信噪比最大化和协调波束成形。数值结果表明,我们提出的设计优于这些替代基准。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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