A hierarchical reinforcement learning approach for optimal path tracking of wheeled mobile robots

Abstract

Robust motion control is fundamental to autonomous mobile robots. In the past few years, reinforcement learning (RL) has attracted considerable attention in the feedback control of wheeled mobile robot. However, it is still difficult for RL to solve problems with large or continuous state spaces, which is common in robotics. To improve the generalization ability of RL, this paper presents a novel hierarchical RL approach for optimal path tracking of wheeled mobile robots. In the proposed approach, a graph Laplacian-based hierarchical approximate policy iteration (GHAPI) algorithm is developed, in which the basis functions are constructed automatically using the graph Laplacian operator. In GHAPI, the state space of an Markov decision process is divided into several subspaces and approximate policy iteration is carried out on each subspace. Then, a near-optimal path-tracking control strategy can be obtained by GHAPI combined with proportional-derivative (PD) control. The performance of the proposed approach is evaluated by using a P3-AT wheeled mobile robot. It is demonstrated that the GHAPI-based PD control can obtain better near-optimal control policies than previous approaches.