RIS-based Communication Enhancement and Location Privacy Protection in UAV Networks

TL;DR

This paper introduces an ARIS-assisted covert communication scheme that enhances UAV communication efficiency while significantly increasing the localization error of malicious UAVs, thereby protecting source UAV privacy.

Contribution

It proposes a novel ARIS architecture with virtual partitioning and artificial noise to simultaneously optimize communication and interfere with malicious localization.

Findings

The scheme significantly increases malicious UAVs' localization error.

It maintains efficient communication between source and legitimate UAVs.

Simulation results validate the effectiveness of the proposed approach.

Abstract

With the explosive advancement of unmanned aerial vehicles (UAVs), the security of efficient UAV networks has become increasingly critical. Owing to the open nature of its communication environment, illegitimate malicious UAVs (MUs) can infer the position of the source UAV (SU) by analyzing received signals, thus compromising the SU location privacy. To protect the SU location privacy while ensuring efficient communication with legitimate receiving UAVs (RUs), we propose an Active Reconfigurable Intelligent Surface (ARIS)-assisted covert communication scheme based on virtual partitioning and artificial noise (AN). Specifically, we design a novel ARIS architecture integrated with an AN module. This architecture dynamically partitions its reflecting elements into multiple sub-regions: one subset is optimized to enhance the communication rate between the SU and RUs, while the other subset generates AN to interfere with the localization of the SU by MUs. We first derive the Cram\'er-Rao Lower Bound (CRLB) for the localization with received signal strength (RSS), based on which, we establish a joint optimization framework for communication enhancement and localization interference. Subsequently, we derive and validate the optimal ARIS partitioning and power allocation under average channel conditions. Finally, tailored optimization methods are proposed for the reflection precoding and AN design of the two partitions. Simulation results validate that, compared to baseline schemes, the proposed scheme significantly increases the localization error of the SU by MUs while maintaining efficient communication between the SU and RUs, thereby effectively protecting the SU location privacy.