English

Improved Exploration in Factored Average-Reward MDPs

Machine Learning 2021-03-12 v3 Machine Learning

Abstract

We consider a regret minimization task under the average-reward criterion in an unknown Factored Markov Decision Process (FMDP). More specifically, we consider an FMDP where the state-action space X\mathcal X and the state-space S\mathcal S admit the respective factored forms of X=i=1nXi\mathcal X = \otimes_{i=1}^n \mathcal X_i and S=i=1mSi\mathcal S=\otimes_{i=1}^m \mathcal S_i, and the transition and reward functions are factored over X\mathcal X and S\mathcal S. Assuming known factorization structure, we introduce a novel regret minimization strategy inspired by the popular UCRL2 strategy, called DBN-UCRL, which relies on Bernstein-type confidence sets defined for individual elements of the transition function. We show that for a generic factorization structure, DBN-UCRL achieves a regret bound, whose leading term strictly improves over existing regret bounds in terms of the dependencies on the size of Si\mathcal S_i's and the involved diameter-related terms. We further show that when the factorization structure corresponds to the Cartesian product of some base MDPs, the regret of DBN-UCRL is upper bounded by the sum of regret of the base MDPs. We demonstrate, through numerical experiments on standard environments, that DBN-UCRL enjoys substantially improved regret empirically over existing algorithms that have frequentist regret guarantees.

Cite

@article{arxiv.2009.04575,
  title  = {Improved Exploration in Factored Average-Reward MDPs},
  author = {Mohammad Sadegh Talebi and Anders Jonsson and Odalric-Ambrym Maillard},
  journal= {arXiv preprint arXiv:2009.04575},
  year   = {2021}
}

Comments

23 pages. To appear in Proceedings of the 24th International Conference on Artificial Intelligence and Statistics (AISTATS) 2021

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