RAnGE: Reachability Analysis for Guaranteed Ergodicity

This paper investigates performance guarantees on coverage-based ergodic exploration methods in environments containing disturbances. Ergodic exploration methods generate trajectories for autonomous robots such that time spent in an area is proportional to the utility of exploring in the area. However, providing formal performance guarantees for ergodic exploration methods is still an open challenge due to the complexities in the problem formulation. In this work, we propose to formulate ergodic search as a differential game, in which a controller and external disturbance force seek to minimize and maximize the ergodic metric, respectively. Through an extended-state Bolza-form transform of the ergodic problem, we demonstrate it is possible to use techniques from reachability analysis to solve for optimal controllers that guarantee coverage and are robust against disturbances. Our approach leverages neural-network based methods to obtain approximate value function solutions for reachability problems that mitigate the increased computational scaling due to the extended state. As a result, we are able to compute continuous value functions for the ergodic exploration problem and provide performance guarantees for coverage under disturbances. Simulated and experimental results demonstrate the efficacy of our approach to generate robust ergodic trajectories for search and exploration with external disturbance force.