Path Planning of Multiple Unmanned Marine Vehicles for Adaptive Ocean Sampling Using Elite Group-Based Evolutionary Algorithms

Abstract

This paper presents elite group-based evolutionary algorithms (EGEA) for adaptive ocean sampling using multiple unmanned marine vehicles (UMVs). The EGEA integrate a group-based framework and elitist selection methods into evolutionary path planner, which combine main advantages of these two techniques.The group-based framework allows each offspring individual of evolutionary algorithm to generate its own group of new solutions with a certain probability. Two elitist selection methods, herein referred to as group individual elitist selection (GIES) and whole population elitist selection (WPES), are proposed to facilitate selecting preferable solutions to be passed on to the next generation in the procedure of evolutionary algorithms. The EGEA path planners based on simulated annealing algorithm (SA) and particle swarm optimization (PSO) are tested to find trajectories for multiple UMVs to collect maximum interested ocean information from regions under investigation. The mixed integer linear programming (MILP) is also described and evaluated with the proposed EGEA for solving the adaptive sampling problem. Simulation results show that the whole elite group-based simulated annealing algorithm (WEGSA) is able to generate trajectories with more information gain from regions of high scientific interest with constrained energy of multiple UMVs than other techniques. Monte Carlo simulations demonstrate the inherent robustness and superiority of the proposed planner based on the EGEA in comparison with other techniques.