Discrete-Time Nonlinear Optimal Control Using Multi-Step Reinforcement Learning
Ningbo An, Qishao Wang, Xiaochuan Zhao, Qingyun Wang
Abstract
This paper solves the optimal control problem of discrete-time nonlinear systems by proposing a multi-step reinforcement learning (RL) algorithm. The proposed multi-step RL algorithm is established based on the discrete-time optimal Bellman equation, which takes advantage of policy iteration (PI) and value iteration (VI). Benefiting from the multi-step integration mechanism, the algorithm is accelerated. The convergence of multi-step RL is proved by mathematical induction. For real-world implementation purposes, neural network (NN) and Actor-Critic architecture are introduced to approximate the iterative value functions and control policies. A numerical simulation of Chua’s circuit illustrates the effectiveness of the proposed algorithm.