Offline Reinforcement Learning via Linear-Programming with Error-Bound Induced Constraints
Abstract
Offline reinforcement learning (RL) aims to find an optimal policy for Markov decision processes (MDPs) using a pre-collected dataset. In this work, we revisit the linear programming (LP) reformulation of Markov decision processes for offline RL, with the goal of developing algorithms with optimal O(1/n) sample complexity, where n is the sample size, under partial data coverage and general function approximation, and with favorable computational tractability. To this end, we derive new error bounds for both the dual and primal-dual formulations of the LP, and incorporate them properly as constraints in the LP reformulation. We then show that under a completeness-type assumption, O(1/n) sample complexity can be achieved under standard single-policy coverage assumption, when one properly relaxes the occupancy validity constraint in the LP. This framework can readily handle both infinite-horizon discounted and average-reward MDPs, in both general function approximation and tabular cases. The instantiation to the tabular case achieves either state-of-the-art or the first sample complexities of offline RL in these settings. To further remove any completeness-type assumption, we then introduce a proper lower-bound constraint in the LP, and a variant of the standard single-policy coverage assumption. Such an algorithm leads to a O(1/n) sample complexity with dependence on the value-function gap, with only realizability assumptions. Our properly constrained LP framework advances the existing results in several aspects, in relaxing certain assumptions and achieving the optimal O(1/n) sample complexity, with simple analyses. We hope our results bring new insights into the use of LP formulations and the equivalent primal-dual minimax optimization for offline RL, through the error-bound induced constraints.
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