Minimax-Optimal Reward-Agnostic Exploration in Reinforcement Learning

Abstract

This paper studies reward-agnostic exploration in reinforcement learning (RL) -- a scenario where the learner is unware of the reward functions during the exploration stage -- and designs an algorithm that improves over the state of the art. More precisely, consider a finite-horizon inhomogeneous Markov decision process with S states, A actions, and horizon length H, and suppose that there are no more than a polynomial number of given reward functions of interest. By collecting an order of align* SAH32 sample episodes (up to log factor) align* without guidance of the reward information, our algorithm is able to find -optimal policies for all these reward functions, provided that is sufficiently small. This forms the first reward-agnostic exploration scheme in this context that achieves provable minimax optimality. Furthermore, once the sample size exceeds S2AH32 episodes (up to log factor), our algorithm is able to yield accuracy for arbitrarily many reward functions (even when they are adversarially designed), a task commonly dubbed as ``reward-free exploration.'' The novelty of our algorithm design draws on insights from offline RL: the exploration scheme attempts to maximize a critical reward-agnostic quantity that dictates the performance of offline RL, while the policy learning paradigm leverages ideas from sample-optimal offline RL paradigms.