Securing UAV Communications Via Trajectory Optimization

TL;DR

This paper proposes a novel trajectory and power optimization method for UAVs to enhance physical-layer security in ground communication, demonstrating significant secrecy rate improvements over benchmarks.

Contribution

It introduces an iterative algorithm that jointly optimizes UAV trajectory and transmit power to maximize secrecy rate, exploiting UAV mobility for security enhancement.

Findings

Significant secrecy rate improvement over benchmark schemes

Effective joint trajectory and power optimization method

Algorithm converges efficiently with iterative optimization

Abstract

Unmanned aerial vehicle (UAV) communications has drawn significant interest recently due to many advantages such as low cost, high mobility, and on-demand deployment. This paper addresses the issue of physical-layer security in a UAV communication system, where a UAV sends confidential information to a legitimate receiver in the presence of a potential eavesdropper which are both on the ground. We aim to maximize the secrecy rate of the system by jointly optimizing the UAV's trajectory and transmit power over a finite horizon. In contrast to the existing literature on wireless security with static nodes, we exploit the mobility of the UAV in this paper to enhance the secrecy rate via a new trajectory design. Although the formulated problem is non-convex and challenging to solve, we propose an iterative algorithm to solve the problem efficiently, based on the block coordinate descent and successive convex optimization methods. Specifically, the UAV's transmit power and trajectory are each optimized with the other fixed in an alternating manner until convergence. Numerical results show that the proposed algorithm significantly improves the secrecy rate of the UAV communication system, as compared to benchmark schemes without transmit power control or trajectory optimization.