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An Approximation Theory Framework for Measure-Transport Sampling Algorithms

Numerical Analysis 2024-09-19 v4 Numerical Analysis Statistics Theory Statistics Theory

Abstract

This article presents a general approximation-theoretic framework to analyze measure transport algorithms for probabilistic modeling. A primary motivating application for such algorithms is sampling -- a central task in statistical inference and generative modeling. We provide a priori error estimates in the continuum limit, i.e., when the measures (or their densities) are given, but when the transport map is discretized or approximated using a finite-dimensional function space. Our analysis relies on the regularity theory of transport maps and on classical approximation theory for high-dimensional functions. A third element of our analysis, which is of independent interest, is the development of new stability estimates that relate the distance between two maps to the distance~(or divergence) between the pushforward measures they define. We present a series of applications of our framework, where quantitative convergence rates are obtained for practical problems using Wasserstein metrics, maximum mean discrepancy, and Kullback--Leibler divergence. Specialized rates for approximations of the popular triangular Kn{\"o}the-Rosenblatt maps are obtained, followed by numerical experiments that demonstrate and extend our theory.

Keywords

Cite

@article{arxiv.2302.13965,
  title  = {An Approximation Theory Framework for Measure-Transport Sampling Algorithms},
  author = {Ricardo Baptista and Bamdad Hosseini and Nikola B. Kovachki and Youssef M. Marzouk and Amir Sagiv},
  journal= {arXiv preprint arXiv:2302.13965},
  year   = {2024}
}
R2 v1 2026-06-28T08:50:50.452Z