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Main Authors: Lin, Yexiong, Yao, Yu, Liu, Tongliang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.23346
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author Lin, Yexiong
Yao, Yu
Liu, Tongliang
author_facet Lin, Yexiong
Yao, Yu
Liu, Tongliang
contents Flow Matching (FM) is an effective framework for training a model to learn a vector field that transports samples from a source distribution to a target distribution. To train the model, early FM methods use random couplings, which often result in crossing paths and lead the model to learn non-straight trajectories that require many integration steps to generate high-quality samples. To address this, recent methods adopt Optimal Transport (OT) to construct couplings by minimizing geometric distances, which helps reduce path crossings. However, we observe that such geometry-based couplings do not necessarily align with the model's preferred trajectories, making it difficult to learn the vector field induced by these couplings, which prevents the model from learning straight trajectories. Motivated by this, we propose Model-Aligned Coupling (MAC), an effective method that matches training couplings based not only on geometric distance but also on alignment with the model's preferred transport directions based on its prediction error. To avoid the time-costly match process, MAC proposes to select the top-$k$ fraction of couplings with the lowest error for training. Extensive experiments show that MAC significantly improves generation quality and efficiency in few-step settings compared to existing methods. Project page: https://yexionglin.github.io/mac
format Preprint
id arxiv_https___arxiv_org_abs_2505_23346
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beyond Optimal Transport: Model-Aligned Coupling for Flow Matching
Lin, Yexiong
Yao, Yu
Liu, Tongliang
Computer Vision and Pattern Recognition
Flow Matching (FM) is an effective framework for training a model to learn a vector field that transports samples from a source distribution to a target distribution. To train the model, early FM methods use random couplings, which often result in crossing paths and lead the model to learn non-straight trajectories that require many integration steps to generate high-quality samples. To address this, recent methods adopt Optimal Transport (OT) to construct couplings by minimizing geometric distances, which helps reduce path crossings. However, we observe that such geometry-based couplings do not necessarily align with the model's preferred trajectories, making it difficult to learn the vector field induced by these couplings, which prevents the model from learning straight trajectories. Motivated by this, we propose Model-Aligned Coupling (MAC), an effective method that matches training couplings based not only on geometric distance but also on alignment with the model's preferred transport directions based on its prediction error. To avoid the time-costly match process, MAC proposes to select the top-$k$ fraction of couplings with the lowest error for training. Extensive experiments show that MAC significantly improves generation quality and efficiency in few-step settings compared to existing methods. Project page: https://yexionglin.github.io/mac
title Beyond Optimal Transport: Model-Aligned Coupling for Flow Matching
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2505.23346