Stochastic approximation with cone-contractive operators: Sharp $\ell_\infty$-bounds for $Q$-learning
Abstract
Motivated by the study of -learning algorithms in reinforcement learning, we study a class of stochastic approximation procedures based on operators that satisfy monotonicity and quasi-contractivity conditions with respect to an underlying cone. We prove a general sandwich relation on the iterate error at each time, and use it to derive non-asymptotic bounds on the error in terms of a cone-induced gauge norm. These results are derived within a deterministic framework, requiring no assumptions on the noise. We illustrate these general bounds in application to synchronous -learning for discounted Markov decision processes with discrete state-action spaces, in particular by deriving non-asymptotic bounds on the -norm for a range of stepsizes. These results are the sharpest known to date, and we show via simulation that the dependence of our bounds cannot be improved in a worst-case sense. These results show that relative to a model-based -iteration, the -based sample complexity of -learning is suboptimal in terms of the discount factor .
Cite
@article{arxiv.1905.06265,
title = {Stochastic approximation with cone-contractive operators: Sharp $\ell_\infty$-bounds for $Q$-learning},
author = {Martin J. Wainwright},
journal= {arXiv preprint arXiv:1905.06265},
year = {2019}
}
Comments
Changes from v1: -- Part of Lemma 1 was incorrect; corrected -- proof of Lemma 2: fixed minor typo in equation (36)