English

Approximation and Structured Prediction with Sparse Wasserstein Barycenters

Numerical Analysis 2023-02-13 v1 Numerical Analysis

Abstract

We develop a general theoretical and algorithmic framework for sparse approximation and structured prediction in P2(Ω)\mathcal{P}_2(\Omega) with Wasserstein barycenters. The barycenters are sparse in the sense that they are computed from an available dictionary of measures but the approximations only involve a reduced number of atoms. We show that the best reconstruction from the class of sparse barycenters is characterized by a notion of best nn-term barycenter which we introduce, and which can be understood as a natural extension of the classical concept of best nn-term approximation in Banach spaces. We show that the best nn-term barycenter is the minimizer of a highly non-convex, bi-level optimization problem, and we develop algorithmic strategies for practical numerical computation. We next leverage this approximation tool to build interpolation strategies that involve a reduced computational cost, and that can be used for structured prediction, and metamodelling of parametrized families of measures. We illustrate the potential of the method through the specific problem of Model Order Reduction (MOR) of parametrized PDEs. Since our approach is sparse, adaptive and preserves mass by construction, it has potential to overcome known bottlenecks of classical linear methods in hyperbolic conservation laws transporting discontinuities. It also paves the way towards MOR for measure-valued PDE problems such as gradient flows.

Keywords

Cite

@article{arxiv.2302.05356,
  title  = {Approximation and Structured Prediction with Sparse Wasserstein Barycenters},
  author = {Minh-Hieu Do and Jean Feydy and Olga Mula},
  journal= {arXiv preprint arXiv:2302.05356},
  year   = {2023}
}
R2 v1 2026-06-28T08:37:13.092Z