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Deep Q-Network Based Dynamic Trajectory Design for UAV-Aided Emergency Communications

Liang Wang, Kezhi Wang, Cunhua Pan, Xiaomin Chen, Nauman Aslam

2020Journal of Communications and Information Networks23 citationsDOIOpen Access PDF

Abstract

In this paper, an unmanned aerial vehicle (UAV)-aided wireless emergence communication system is studied, where a UAV is deployed to support ground user equipments (UEs) for emergence communications. We aim to maximize the number of the UEs served, the fairness, and the overall uplink data rate via optimizing the trajectory of UAV and the transmission power of UEs. We propose a deep Q-network (DQN) based algorithm, which involves the well-known deep neural network (DNN) and Q-learning, to solve the UAV trajectory problem. Then, based on the optimized UAV trajectory, we further propose a successive convex approximation (SCA) based algorithm to tackle the power control problem for each UE. Numerical simulations demonstrate that the proposed DQN based algorithm can achieve considerable performance gain over the existing benchmark algorithms in terms of fairness, the number of UEs served and overall uplink data rate via optimizing UAV's trajectory and power optimization.

Topics & Concepts

Benchmark (surveying)Computer scienceTrajectoryTelecommunications linkTransmitter power outputTrajectory optimizationWirelessReal-time computingPower (physics)Wireless networkPower controlArtificial neural networkOptimization problemTransmission (telecommunications)Artificial intelligenceAlgorithmComputer networkTelecommunicationsTransmitterChannel (broadcasting)PhysicsAstronomyGeographyGeodesyQuantum mechanicsUAV Applications and OptimizationOpportunistic and Delay-Tolerant NetworksAdvanced MIMO Systems Optimization
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