English

First-Order Methods for Wasserstein Distributionally Robust MDP

Optimization and Control 2021-05-05 v2 Computer Science and Game Theory

Abstract

Markov decision processes (MDPs) are known to be sensitive to parameter specification. Distributionally robust MDPs alleviate this issue by allowing for \emph{ambiguity sets} which give a set of possible distributions over parameter sets. The goal is to find an optimal policy with respect to the worst-case parameter distribution. We propose a framework for solving Distributionally robust MDPs via first-order methods, and instantiate it for several types of Wasserstein ambiguity sets. By developing efficient proximal updates, our algorithms achieve a convergence rate of O(NA2.5S3.5log(S)log(ϵ1)ϵ1.5)O\left(NA^{2.5}S^{3.5}\log(S)\log(\epsilon^{-1})\epsilon^{-1.5} \right) for the number of kernels NN in the support of the nominal distribution, states SS, and actions AA; this rate varies slightly based on the Wasserstein setup. Our dependence on N,AN,A and SS is significantly better than existing methods, which have a complexity of O(N3.5A3.5S4.5log2(ϵ1))O\left(N^{3.5}A^{3.5}S^{4.5}\log^{2}(\epsilon^{-1}) \right). Numerical experiments show that our algorithm is significantly more scalable than state-of-the-art approaches across several domains.

Keywords

Cite

@article{arxiv.2009.06790,
  title  = {First-Order Methods for Wasserstein Distributionally Robust MDP},
  author = {Julien Grand-Clément and Christian Kroer},
  journal= {arXiv preprint arXiv:2009.06790},
  year   = {2021}
}
R2 v1 2026-06-23T18:32:34.731Z