Continuous World Coverage Path Planning for Fixed-Wing UAVs using Deep Reinforcement Learning
This addresses the need for power-efficient continuous motion planning in UAV applications like precision agriculture and search and rescue, representing an incremental improvement over traditional discrete methods.
The paper tackled the problem of continuous coverage path planning for fixed-wing UAVs by minimizing power consumption and ensuring complete coverage, achieving effective energy-efficient strategies in experiments on generated and hand-crafted scenarios.
Unmanned Aerial Vehicle (UAV) Coverage Path Planning (CPP) is critical for applications such as precision agriculture and search and rescue. While traditional methods rely on discrete grid-based representations, real-world UAV operations require power-efficient continuous motion planning. We formulate the UAV CPP problem in a continuous environment, minimizing power consumption while ensuring complete coverage. Our approach models the environment with variable-size axis-aligned rectangles and UAV motion with curvature-constrained Bézier curves. We train a reinforcement learning agent using an action-mapping-based Soft Actor-Critic (AM-SAC) algorithm employing a self-adaptive curriculum. Experiments on both procedurally generated and hand-crafted scenarios demonstrate the effectiveness of our method in learning energy-efficient coverage strategies.