English

Near-Optimal Sample Complexity for MDPs via Anchoring

Optimization and Control 2025-06-16 v2 Data Structures and Algorithms

Abstract

We study a new model-free algorithm to compute ε\varepsilon-optimal policies for average reward Markov decision processes, in the weakly communicating case. Given a generative model, our procedure combines a recursive sampling technique with Halpern's anchored iteration, and computes an ε\varepsilon-optimal policy with sample and time complexity O~(SAhsp2/ε2)\widetilde{O}(|\mathcal{S}||\mathcal{A}|\|h^*\|_{\text{sp}}^{2}/\varepsilon^{2}) both in high probability and in expectation. To our knowledge, this is the best complexity among model-free algorithms, matching the known lower bound up to a factor hsp\|h^*\|_{\text{sp}}. Although the complexity bound involves the span seminorm hsp\|h^*\|_{\text{sp}} of the unknown bias vector, the algorithm requires no prior knowledge and implements a stopping rule which guarantees with probability 1 that the procedure terminates in finite time. We also analyze how these techniques can be adapted for discounted MDPs.

Keywords

Cite

@article{arxiv.2502.04477,
  title  = {Near-Optimal Sample Complexity for MDPs via Anchoring},
  author = {Jongmin Lee and Mario Bravo and Roberto Cominetti},
  journal= {arXiv preprint arXiv:2502.04477},
  year   = {2025}
}
R2 v1 2026-06-28T21:35:27.213Z