Reinforcement learning algorithms, though successful, tend to over-fit to training environments hampering their application to the real-world. This paper proposes WR2L -- a robust reinforcement learning algorithm with significant robust performance on low and high-dimensional control tasks. Our method formalises robust reinforcement learning as a novel min-max game with a Wasserstein constraint for a correct and convergent solver. Apart from the formulation, we also propose an efficient and scalable solver following a novel zero-order optimisation method that we believe can be useful to numerical optimisation in general. We empirically demonstrate significant gains compared to standard and robust state-of-the-art algorithms on high-dimensional MuJuCo environments.
@article{arxiv.1907.13196,
title = {Wasserstein Robust Reinforcement Learning},
author = {Mohammed Amin Abdullah and Hang Ren and Haitham Bou Ammar and Vladimir Milenkovic and Rui Luo and Mingtian Zhang and Jun Wang},
journal= {arXiv preprint arXiv:1907.13196},
year = {2019}
}