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Integrated Design of Cooperative Area Coverage and Target Tracking with Multi-UAV System

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Abstract

This paper systematically studies the cooperative area coverage and target tracking problem of multiple-unmanned aerial vehicles (multi-UAVs). The problem is solved by decomposing into three sub-problems: information fusion, task assignment, and multi-UAV behavior decision-making. Specifically, in the information fusion process, we use the maximum consistency protocol to update the joint estimation states of multi-targets (JESMT) and the area detection information. The area detection information is represented by the equivalent visiting time map (EVTM), which is built based on the detection probability and the actual visiting time of the area. Then, we model the task assignment problem of multi-UAV searching and tracking multi-targets as a network flow model with upper and lower flow bounds. An algorithm named task assignment minimum-cost maximum-flow (TAMM) is proposed. Cooperative behavior decision-making uses Fisher information as the mission reward to obtain the optimal tracking action of the UAV. Furthermore, a coverage behavior decision-making algorithm based on the anti-flocking method is designed for those UAVs assigned the coverage task. Finally, a distributed multi-UAV cooperative area coverage and target tracking algorithm is designed, which integrates information fusion, task assignment, and behavioral decision-making. Numerical and hardware-in-the-loop simulation results show that the proposed method can achieve persistent area coverage and cooperative target tracking.

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Authors and Affiliations

  1. College of Intelligence Science and Technology, National University of Defense Technology, Changsha, People’s Republic of China

    Mengge Zhang, Xinning Wu, Jie Li, Xiangke Wang & Lincheng Shen

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  1. Mengge Zhang
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  2. Xinning Wu
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  3. Jie Li
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  4. Xiangke Wang
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  5. Lincheng Shen
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Correspondence to Xiangke Wang.

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Zhang, M., Wu, X., Li, J. et al. Integrated Design of Cooperative Area Coverage and Target Tracking with Multi-UAV System. J Intell Robot Syst 108, 77 (2023). https://doi.org/10.1007/s10846-023-01925-z

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