On Robust Optimal Transport: Computational Complexity and Barycenter Computation
Abstract
We consider robust variants of the standard optimal transport, named robust optimal transport, where marginal constraints are relaxed via Kullback-Leibler divergence. We show that Sinkhorn-based algorithms can approximate the optimal cost of robust optimal transport in time, in which is the number of supports of the probability distributions and is the desired error. Furthermore, we investigate a fixed-support robust barycenter problem between discrete probability distributions with at most number of supports and develop an approximating algorithm based on iterative Bregman projections (IBP). For the specific case , we show that this algorithm can approximate the optimal barycenter value in time, thus being better than the previous complexity of the IBP algorithm for approximating the Wasserstein barycenter.
Cite
@article{arxiv.2102.06857,
title = {On Robust Optimal Transport: Computational Complexity and Barycenter Computation},
author = {Khang Le and Huy Nguyen and Quang Nguyen and Tung Pham and Hung Bui and Nhat Ho},
journal= {arXiv preprint arXiv:2102.06857},
year = {2021}
}
Comments
Advances in NeurIPS, 2021; 52 pages, 10 figures; Khang Le and Huy Nguyen contributed equally to this week