Attention-Based UAV Trajectory Optimization for Wireless Power Transfer-Assisted IoT Systems
Li Dong, Feibo Jiang, Yubo Peng
Abstract
Unmanned aerial vehicles (UAVs) in wireless power transfer (WPT)-assisted Internet of Things (IoT) systems face the following challenges: limited resources and suboptimal trajectory planning. Reinforcement learning-based trajectory planning schemes face issues of low search efficiency and learning instability when optimizing large-scale systems. To address these issues, we present an attention-based UAV trajectory optimization (AUTO) framework based on the graph transformer, which consists of an attention trajectory optimization model (ATOM) and a trajectory lEarNing method based on actor–critic (TENMA). In ATOM, a graph encoder is used to calculate the self-attention characteristics of all IoTDs, and a trajectory decoder is developed to optimize the number and trajectories of UAVs. TENMA then trains the ATOM using an improved actor–critic method, in which the real reward of the system is applied as the baseline to reduce variances in the critic network. This method is suitable for high-quality and large-scale multi-UAV trajectory planning. Finally, we develop numerous experiments, including a hardware experiment in the field case, to verify the feasibility and efficiency of the AUTO framework.