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Cooperative Motion Planning for Persistent 3D Visual Coverage With Multiple Quadrotor UAVs

Hongpeng Wang, Shangyuan Song, Qiang-Hui Guo, Dian Xu, Xiaoyang Zhang, P. Wang

2023IEEE Transactions on Automation Science and Engineering24 citationsDOI

Abstract

In this paper, we address the multiple quadrotor UAVs trajectory planning optimization problem for large-scale, persistent, high-depth visual coverage tasks in three-dimensional (3-D) terrain environment. To minimize the overall energy expenditure of the UAVs for accomplishing a task, we set up an air-to-ground collaborative system which introduces base stations to hold and recharge UAVs. The system is formulated as an integer programming, and solved by a novel hierarchical reinforcement learning trajectory planning algorithm (RL-TP), in which the paths are obtained by reinforcement learning method, and then the trajectories are obtained by Bézier curve method. Both simulation and physical experiments show that RL-TP can effectively improve the efficiency and persistence of aerial visual coverage task. <italic xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">Note to Practitioners</i> —While the multi-rotor UAV has been an important means for field monitoring, it suffers the problem of short battery life a lot. To make it more efficient and persistent, we use multiple UAVs and introduce ground base stations to charge the UAVs. The scenario is formulated as an air-to-ground collaborative system, and the motion planning strategy is to minimize the energy consumption. We propose a hierarchical collaborative coverage reinforcement learning trajectory planning algorithm (RL-TP) to solve it. We carry out both simulation and physical field experiments, and compare RL-TP with other popular methods. The experimental results show that the system is feasible and RL-TP performs well in both time efficiency and energy consumption. In future research, we will introduce unmanned ground vehicles to replace the stationary ground base stations to make the air-to-ground collaborative system more powerful and flexible.

Topics & Concepts

Reinforcement learningMotion planningComputer scienceTrajectoryTerrainTask (project management)Artificial intelligenceReal-time computingSimulationMathematical optimizationRobotEngineeringMathematicsSystems engineeringAstronomyPhysicsEcologyBiologyRobotic Path Planning AlgorithmsUAV Applications and OptimizationRobotics and Sensor-Based Localization