Infinite-Horizon Offline Reinforcement Learning with Linear Function Approximation: Curse of Dimensionality and Algorithm

Abstract

In this paper, we investigate the sample complexity of policy evaluation in infinite-horizon offline reinforcement learning (also known as the off-policy evaluation problem) with linear function approximation. We identify a hard regime dγ2>1, where d is the dimension of the feature vector and γ is the discount rate. In this regime, for any q∈[γ2,1], we can construct a hard instance such that the smallest eigenvalue of its feature covariance matrix is q/d and it requires (dγ2(q-γ2)2((dγ2))) samples to approximate the value function up to an additive error . Note that the lower bound of the sample complexity is exponential in d. If q=γ2, even infinite data cannot suffice. Under the low distribution shift assumption, we show that there is an algorithm that needs at most O(\ θπ 244dδ,12(d+1δ)\ ) samples (θπ is the parameter of the policy in linear function approximation) and guarantees approximation to the value function up to an additive error of with probability at least 1-δ.