Efficient Distribution Learning with Error Bounds in Wasserstein Distance
Abstract
The Wasserstein distance has emerged as a key metric to quantify distances between probability distributions, with applications in various fields, including machine learning, control theory, decision theory, and biological systems. Consequently, learning an unknown distribution with non-asymptotic and easy-to-compute error bounds in Wasserstein distance has become a fundamental problem in many fields. In this paper, we devise a novel algorithmic and theoretical framework to approximate an unknown probability distribution from a finite set of samples by an approximate discrete distribution while bounding the Wasserstein distance between and . Our framework leverages optimal transport, nonlinear optimization, and concentration inequalities. In particular, we show that, even if is unknown, the Wasserstein distance between and can be efficiently bounded with high confidence by solving a tractable optimization problem (a mixed integer linear program) of a size that only depends on the size of the support of . This enables us to develop intelligent clustering algorithms to optimally find the support of while minimizing the Wasserstein distance error. On a set of benchmarks, we demonstrate that our approach outperforms state-of-the-art comparable methods by generally returning approximating distributions with substantially smaller support and tighter error bounds.
Cite
@article{arxiv.2602.08063,
title = {Efficient Distribution Learning with Error Bounds in Wasserstein Distance},
author = {Eduardo Figueiredo and Steven Adams and Luca Laurenti},
journal= {arXiv preprint arXiv:2602.08063},
year = {2026}
}