Litcius/Paper detail

DDQN-Based Trajectory and Resource Optimization for UAV-Aided MEC Secure Communications

Yu Ding, Huimei Han, Weidang Lu, Ye Wang, Nan Zhao, Xianbin Wang, Xiaoniu Yang

2023IEEE Transactions on Vehicular Technology47 citationsDOI

Abstract

Unmanned aerial vehicles (UAVs) have been emerged as cost-effective platforms to extend the coverage of mobile edge computing (MEC) system. However, the broadcast and line-of-sight (LoS) channels in UAV communications create opportunities for malicious eavesdroppers to intercept the offloaded information from ground users, posing a serious challenge to both communication and computing security. In this correspondence, we investigate the problem of secure transmission in UAV-aided MEC systems. Our goal is to maximize the average secure computing capacity by jointly designing the UAV trajectory, time allocation and offloading decision strategy. To this end, we propose a novel double-deep Q-learning (DDQN) based trajectory optimization and resource allocation scheme. Furthermore, the size of the original action space is reduced to boost the convergence of the proposed DDQN-based scheme. Additionally, we design a reward function to navigate the UAV towards its intended destination. Simulation results demonstrate that the proposed DDQN-based scheme outperforms the baselines in terms of average secure computing capacity.

Topics & Concepts

Computer scienceMobile edge computingResource allocationScheme (mathematics)TrajectoryTrajectory optimizationResource management (computing)Convergence (economics)Optimization problemComputer networkDistributed computingWirelessReal-time computingServerTelecommunicationsPhysicsAstronomyMathematicsEconomic growthMathematical analysisEconomicsAlgorithmUAV Applications and OptimizationIoT and Edge/Fog ComputingAdvanced Wireless Communication Technologies