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Main Authors: Choi, Jae-Hwan, Yoon, Jiwoo, Kwon, Dohyun, Choi, Jaewoong
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.14086
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author Choi, Jae-Hwan
Yoon, Jiwoo
Kwon, Dohyun
Choi, Jaewoong
author_facet Choi, Jae-Hwan
Yoon, Jiwoo
Kwon, Dohyun
Choi, Jaewoong
contents We study Neural Optimal Transport in infinite-dimensional Hilbert spaces. In non-regular settings, Semi-dual Neural OT often generates spurious solutions that fail to accurately capture target distributions. We analytically characterize this spurious solution problem using the framework of regular measures, which generalize Lebesgue absolute continuity in finite dimensions. To resolve ill-posedness, we extend the semi-dual framework via a Gaussian smoothing strategy based on Brownian motion. Our primary theoretical contribution proves that under a regular source measure, the formulation is well-posed and recovers a unique Monge map. Furthermore, we establish a sharp characterization for the regularity of smoothed measures, proving that the success of smoothing depends strictly on the kernel of the covariance operator. Empirical results on synthetic functional data and time-series datasets demonstrate that our approach effectively suppresses spurious solutions and outperforms existing baselines.
format Preprint
id arxiv_https___arxiv_org_abs_2602_14086
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Neural Optimal Transport in Hilbert Spaces: Characterizing Spurious Solutions and Gaussian Smoothing
Choi, Jae-Hwan
Yoon, Jiwoo
Kwon, Dohyun
Choi, Jaewoong
Machine Learning
We study Neural Optimal Transport in infinite-dimensional Hilbert spaces. In non-regular settings, Semi-dual Neural OT often generates spurious solutions that fail to accurately capture target distributions. We analytically characterize this spurious solution problem using the framework of regular measures, which generalize Lebesgue absolute continuity in finite dimensions. To resolve ill-posedness, we extend the semi-dual framework via a Gaussian smoothing strategy based on Brownian motion. Our primary theoretical contribution proves that under a regular source measure, the formulation is well-posed and recovers a unique Monge map. Furthermore, we establish a sharp characterization for the regularity of smoothed measures, proving that the success of smoothing depends strictly on the kernel of the covariance operator. Empirical results on synthetic functional data and time-series datasets demonstrate that our approach effectively suppresses spurious solutions and outperforms existing baselines.
title Neural Optimal Transport in Hilbert Spaces: Characterizing Spurious Solutions and Gaussian Smoothing
topic Machine Learning
url https://arxiv.org/abs/2602.14086