A constrained differential evolution algorithm to solve UAV path planning in disaster scenarios

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Disasters have caused significant losses to humans in the past decades. It is essential to learn about the disaster situation so that rescue works can be conducted as soon as possible. Unmanned aerial vehicle (UAV) is a very useful and effective tool to improve the capacity of disaster situational awareness for responders. In the paper, UAV path planning is modelled as the optimization problem, in which fitness functions include travelling distance and risk of UAV, three constraints involve the height of UAV, angle of UAV, and limited UAV slope. An adaptive selection mutation constrained differential evolution algorithm is put forward to solve the problem. In the proposed algorithm, individuals are selected depending on their fitness values and constraint violations. The better the individual is, the higher the chosen probability it has. These selected individuals are used to make mutation, and the algorithm searches around the best individual among the selected individuals. The well-designed mechanism improves the exploitation and maintains the exploration. The experimental results have indicated that the proposed algorithm is competitive compared with the state-of-art algorithms, which makes it more suitable in the disaster scenario.

论文关键词:UAV path planning,Disaster emergency management,Differential evolution algorithm,Constrained optimization

论文评审过程:Received 1 April 2020, Revised 4 June 2020, Accepted 30 June 2020, Available online 3 July 2020, Version of Record 6 July 2020.

论文官网地址:https://doi.org/10.1016/j.knosys.2020.106209