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Main Authors: Kunpeng, Li, Chenguang, Wan, Zhisong, Qu, Kyungtak, Lim, Grandgirard, Virginie, Garbet, Xavier, Hua, Yu, Soon, Ong Yew
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.05700
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author Kunpeng, Li
Chenguang, Wan
Zhisong, Qu
Kyungtak, Lim
Grandgirard, Virginie
Garbet, Xavier
Hua, Yu
Soon, Ong Yew
author_facet Kunpeng, Li
Chenguang, Wan
Zhisong, Qu
Kyungtak, Lim
Grandgirard, Virginie
Garbet, Xavier
Hua, Yu
Soon, Ong Yew
contents High-fidelity modeling of turbulent flows requires capturing complex spatiotemporal dynamics and multi-scale intermittency, posing a fundamental challenge for traditional knowledge-based systems. While deep generative models, such as diffusion models and Flow Matching, have shown promising performance, they are fundamentally constrained by their discrete, pixel-based nature. This limitation restricts their applicability in turbulence computing, where data inherently exists in a functional form. To address this gap, we propose Functional Optimal Transport Conditional Flow Matching (FOT-CFM), a generative framework defined directly in infinite-dimensional function space. Unlike conventional approaches defined on fixed grids, FOT-CFM treats physical fields as elements of an infinite-dimensional Hilbert space, and learns resolution-invariant generative dynamics directly at the level of probability measures. By integrating Optimal Transport (OT) theory, we construct deterministic, straight-line probability paths between noise and data measures in Hilbert space. This formulation enables simulation-free training and significantly accelerates the sampling process. We rigorously evaluate the proposed system on a diverse suite of chaotic dynamical systems, including the Navier-Stokes equations, Kolmogorov Flow, and Hasegawa-Wakatani equations, all of which exhibit rich multi-scale turbulent structures. Experimental results demonstrate that FOT-CFM achieves superior fidelity in reproducing high-order turbulent statistics and energy spectra compared to state-of-the-art baselines.
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publishDate 2026
record_format arxiv
spellingShingle Optimal-Transport-Guided Functional Flow Matching for Turbulent Field Generation in Hilbert Space
Kunpeng, Li
Chenguang, Wan
Zhisong, Qu
Kyungtak, Lim
Grandgirard, Virginie
Garbet, Xavier
Hua, Yu
Soon, Ong Yew
Machine Learning
High-fidelity modeling of turbulent flows requires capturing complex spatiotemporal dynamics and multi-scale intermittency, posing a fundamental challenge for traditional knowledge-based systems. While deep generative models, such as diffusion models and Flow Matching, have shown promising performance, they are fundamentally constrained by their discrete, pixel-based nature. This limitation restricts their applicability in turbulence computing, where data inherently exists in a functional form. To address this gap, we propose Functional Optimal Transport Conditional Flow Matching (FOT-CFM), a generative framework defined directly in infinite-dimensional function space. Unlike conventional approaches defined on fixed grids, FOT-CFM treats physical fields as elements of an infinite-dimensional Hilbert space, and learns resolution-invariant generative dynamics directly at the level of probability measures. By integrating Optimal Transport (OT) theory, we construct deterministic, straight-line probability paths between noise and data measures in Hilbert space. This formulation enables simulation-free training and significantly accelerates the sampling process. We rigorously evaluate the proposed system on a diverse suite of chaotic dynamical systems, including the Navier-Stokes equations, Kolmogorov Flow, and Hasegawa-Wakatani equations, all of which exhibit rich multi-scale turbulent structures. Experimental results demonstrate that FOT-CFM achieves superior fidelity in reproducing high-order turbulent statistics and energy spectra compared to state-of-the-art baselines.
title Optimal-Transport-Guided Functional Flow Matching for Turbulent Field Generation in Hilbert Space
topic Machine Learning
url https://arxiv.org/abs/2604.05700