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UAV-Mounted RIS-Aided Mobile Edge Computing System: A DDQN-Based Optimization Approach

Min Wu, Shibing Zhu, Changqing Li, Jiao Zhu, Yudi Chen, Xiangyu Liu, Rui Liu

2024Drones14 citationsDOIOpen Access PDF

Abstract

Unmanned aerial vehicles (UAVs) and reconfigurable intelligent surfaces (RISs) are increasingly employed in mobile edge computing (MEC) systems to flexibly modify the signal transmission environment. This is achieved through the active manipulation of the wireless channel facilitated by the mobile deployment of UAVs and the intelligent reflection of signals by RISs. However, these technologies are subject to inherent limitations such as the restricted range of UAVs and limited RIS coverage, which hinder their broader application. The integration of UAVs and RISs into UAV–RIS schemes presents a promising approach to surmounting these limitations by leveraging the strengths of both technologies. Motivated by the above observations, we contemplate a novel UAV–RIS-aided MEC system, wherein UAV–RIS plays a pivotal role in facilitating communication between terrestrial vehicle users and MEC servers. To address this challenging non-convex problem, we propose an energy-constrained approach to maximize the system’s energy efficiency based on a double-deep Q-network (DDQN), which is employed to realize joint control of the UAVs, passive beamforming, and resource allocation for MEC. Numerical results demonstrate that the proposed optimization scheme significantly enhances the system efficiency of the UAV–RIS-aided time division multiple access (TDMA) network.

Topics & Concepts

Computer scienceMobile edge computingBeamformingSoftware deploymentTime division multiple accessResource allocationWirelessDistributed computingCellular networkServerDroneReal-time computingComputer networkTelecommunicationsGeneticsOperating systemBiologyUAV Applications and OptimizationAdvanced Wireless Communication TechnologiesEnergy Harvesting in Wireless Networks
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