English

Efficient Distribution Learning with Error Bounds in Wasserstein Distance

Machine Learning 2026-02-10 v1

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 P\mathbb{P} from a finite set of samples by an approximate discrete distribution P^\widehat{\mathbb{P}} while bounding the Wasserstein distance between P\mathbb{P} and P^\widehat{\mathbb{P}}. Our framework leverages optimal transport, nonlinear optimization, and concentration inequalities. In particular, we show that, even if P\mathbb{P} is unknown, the Wasserstein distance between P\mathbb{P} and P^\widehat{\mathbb{P}} 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 P^\widehat{\mathbb{P}}. This enables us to develop intelligent clustering algorithms to optimally find the support of P^\widehat{\mathbb{P}} 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.

Keywords

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}
}
R2 v1 2026-07-01T10:26:54.799Z