Optimal Sample Complexity for Single Time-Scale Actor-Critic with Momentum
Abstract
We establish an optimal sample complexity of for obtaining an -optimal global policy using a single-timescale actor-critic (AC) algorithm in infinite-horizon discounted Markov decision processes (MDPs) with finite state-action spaces, improving upon the prior state of the art of . Our approach applies STORM (STOchastic Recursive Momentum) to reduce variance in the critic updates. However, because samples are drawn from a nonstationary occupancy measure induced by the evolving policy, variance reduction via STORM alone is insufficient. To address this challenge, we maintain a buffer of small fraction of recent samples and uniformly sample from it for each critic update. Importantly, these mechanisms are compatible with existing deep learning architectures and require only minor modifications, without compromising practical applicability.
Cite
@article{arxiv.2602.01505,
title = {Optimal Sample Complexity for Single Time-Scale Actor-Critic with Momentum},
author = {Navdeep Kumar and Tehila Dahan and Lior Cohen and Ananyabrata Barua and Giorgia Ramponi and Kfir Yehuda Levy and Shie Mannor},
journal= {arXiv preprint arXiv:2602.01505},
year = {2026}
}
Comments
Following further internal verification, we identified foundational issues in the analytical framework, including unresolved problems in the treatment of nonstationary sampling and parts of the coupled convergence analysis under the stated assumptions. Addressing these issues requires a substantial overhaul of the theoretical framework beyond a standard revision