English

A generative flow for conditional sampling via optimal transport

Machine Learning 2023-07-11 v1 Machine Learning Optimization and Control Computation

Abstract

Sampling conditional distributions is a fundamental task for Bayesian inference and density estimation. Generative models, such as normalizing flows and generative adversarial networks, characterize conditional distributions by learning a transport map that pushes forward a simple reference (e.g., a standard Gaussian) to a target distribution. While these approaches successfully describe many non-Gaussian problems, their performance is often limited by parametric bias and the reliability of gradient-based (adversarial) optimizers to learn these transformations. This work proposes a non-parametric generative model that iteratively maps reference samples to the target. The model uses block-triangular transport maps, whose components are shown to characterize conditionals of the target distribution. These maps arise from solving an optimal transport problem with a weighted L2L^2 cost function, thereby extending the data-driven approach in [Trigila and Tabak, 2016] for conditional sampling. The proposed approach is demonstrated on a two dimensional example and on a parameter inference problem involving nonlinear ODEs.

Keywords

Cite

@article{arxiv.2307.04102,
  title  = {A generative flow for conditional sampling via optimal transport},
  author = {Jason Alfonso and Ricardo Baptista and Anupam Bhakta and Noam Gal and Alfin Hou and Isa Lyubimova and Daniel Pocklington and Josef Sajonz and Giulio Trigila and Ryan Tsai},
  journal= {arXiv preprint arXiv:2307.04102},
  year   = {2023}
}

Comments

18 pages, 5 figures

R2 v1 2026-06-28T11:25:18.329Z