Dynamic Conditional Optimal Transport Through Simulation-Free Flows
Abstract
We study the geometry of conditional optimal transport (COT) and prove a dynamic formulation which generalizes the Benamou-Brenier Theorem. Equipped with these tools, we propose a simulation-free flow-based method for conditional generative modeling. Our method couples an arbitrary source distribution to a specified target distribution through a triangular COT plan, and a conditional generative model is obtained by approximating the geodesic path of measures induced by this COT plan. Our theory and methods are applicable in infinite-dimensional settings, making them well suited for a wide class of Bayesian inverse problems. Empirically, we demonstrate that our method is competitive on several challenging conditional generation tasks, including an infinite-dimensional inverse problem.
Cite
Text
Kerrigan et al. "Dynamic Conditional Optimal Transport Through Simulation-Free Flows." Neural Information Processing Systems, 2024. doi:10.52202/079017-2968Markdown
[Kerrigan et al. "Dynamic Conditional Optimal Transport Through Simulation-Free Flows." Neural Information Processing Systems, 2024.](https://mlanthology.org/neurips/2024/kerrigan2024neurips-dynamic/) doi:10.52202/079017-2968BibTeX
@inproceedings{kerrigan2024neurips-dynamic,
title = {{Dynamic Conditional Optimal Transport Through Simulation-Free Flows}},
author = {Kerrigan, Gavin and Migliorini, Giosue and Smyth, Padhraic},
booktitle = {Neural Information Processing Systems},
year = {2024},
doi = {10.52202/079017-2968},
url = {https://mlanthology.org/neurips/2024/kerrigan2024neurips-dynamic/}
}