English

Efficiently Solving Discounted MDPs with Predictions on Transition Matrices

Machine Learning 2025-02-24 v1

Abstract

We study infinite-horizon Discounted Markov Decision Processes (DMDPs) under a generative model. Motivated by the Algorithm with Advice framework Mitzenmacher and Vassilvitskii 2022, we propose a novel framework to investigate how a prediction on the transition matrix can enhance the sample efficiency in solving DMDPs and improve sample complexity bounds. We focus on the DMDPs with NN state-action pairs and discounted factor γ\gamma. Firstly, we provide an impossibility result that, without prior knowledge of the prediction accuracy, no sampling policy can compute an ϵ\epsilon-optimal policy with a sample complexity bound better than O~((1γ)3Nϵ2)\tilde{O}((1-\gamma)^{-3} N\epsilon^{-2}), which matches the state-of-the-art minimax sample complexity bound with no prediction. In complement, we propose an algorithm based on minimax optimization techniques that leverages the prediction on the transition matrix. Our algorithm achieves a sample complexity bound depending on the prediction error, and the bound is uniformly better than O~((1γ)4Nϵ2)\tilde{O}((1-\gamma)^{-4} N \epsilon^{-2}), the previous best result derived from convex optimization methods. These theoretical findings are further supported by our numerical experiments.

Keywords

Cite

@article{arxiv.2502.15345,
  title  = {Efficiently Solving Discounted MDPs with Predictions on Transition Matrices},
  author = {Lixing Lyu and Jiashuo Jiang and Wang Chi Cheung},
  journal= {arXiv preprint arXiv:2502.15345},
  year   = {2025}
}
R2 v1 2026-06-28T21:52:35.077Z