Variation Encoded Large-Scale Swarm Optimizers for Path Planning of Unmanned Aerial Vehicle

Different from existing studies where low-dimensional optimizers are utilized to optimize the path of an unmanned aerial vehicle UAV), this paper attempts to employ large-scale swarm optimizers to solve the path planning problem of UAV, such that the path can be subtler and smoother. To this end, a variation encoding scheme is devised to encode particles. Specifically, each dimension of a particle is encoded by a triad consisting of the relative movements of UAV along the three coordinate axes. With this encoding scheme, a large number of anchor points can be optimized to form the path and repetitive anchor points can be avoided. Subsequently, this paper embeds this encoding scheme into four representative and well-performed large-scale swarm optimizers, namely the stochastic dominant learning swarm optimizer (SDLSO), the level-based learning swarm optimizer (LLSO), the competitive swarm optimizer (CSO), and the social learning particle swarm optimizer (SL-PSO), to optimize the path of UAV. Experiments have been conducted on 16 scenes with 4 different numbers of peaks in the landscapes. Experimental results have demonstrated that the devised encoding scheme is effective to cooperate with the four large-scale swarm optimizers to solve the path planning problem of UAV and SDLSO achieves the best performance.

Automated summary

Different from previous studies, this paper uses large-scale swarm optimizers to optimize the path planning of UAV, resulting in a subtler and smoother path. The variation encoding scheme effectively avoids repetitive anchor points and optimizes a large number of anchor points. Experimental results show that SDLSO achieves the best performance when cooperating with the devised encoding scheme.