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Autori principali: Wang, Chaoyang, Liang, Yaobo, Peng, Boci, Duan, Fan, Wang, Jingdong, Tong, Yunhai
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2603.19218
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author Wang, Chaoyang
Liang, Yaobo
Peng, Boci
Duan, Fan
Wang, Jingdong
Tong, Yunhai
author_facet Wang, Chaoyang
Liang, Yaobo
Peng, Boci
Duan, Fan
Wang, Jingdong
Tong, Yunhai
contents Taming diffusion models for generative segmentation has attracted increasing attention. While existing approaches primarily focus on architectural tweaks or training heuristics, there remains a limited understanding of the intrinsic mismatch between continuous flow matching objectives and discrete perception tasks. In this work, we revisit diffusion segmentation from the perspective of vector field learning. We identify two key limitations of the commonly used flow matching objective: gradient vanishing and trajectory traversing, which result in slow convergence and poor class separation. To tackle these issues, we propose a principled vector field reshaping strategy that augments the learned velocity field with a detached distance-aware correction term. This correction introduces both attractive and repulsive interactions, enhancing gradient magnitudes near centroids while preserving the original diffusion training framework. Furthermore, we design a computationally efficient, quasi-random category encoding scheme inspired by Kronecker sequences, which integrates seamlessly with an end-to-end pixel neural field framework for pixel-level semantic alignment. Extensive experiments consistently demonstrate significant improvements over vanilla flow matching approaches, substantially narrowing the performance gap between generative segmentation and strong discriminative specialists.
format Preprint
id arxiv_https___arxiv_org_abs_2603_19218
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Rethinking Vector Field Learning for Generative Segmentation
Wang, Chaoyang
Liang, Yaobo
Peng, Boci
Duan, Fan
Wang, Jingdong
Tong, Yunhai
Computer Vision and Pattern Recognition
Taming diffusion models for generative segmentation has attracted increasing attention. While existing approaches primarily focus on architectural tweaks or training heuristics, there remains a limited understanding of the intrinsic mismatch between continuous flow matching objectives and discrete perception tasks. In this work, we revisit diffusion segmentation from the perspective of vector field learning. We identify two key limitations of the commonly used flow matching objective: gradient vanishing and trajectory traversing, which result in slow convergence and poor class separation. To tackle these issues, we propose a principled vector field reshaping strategy that augments the learned velocity field with a detached distance-aware correction term. This correction introduces both attractive and repulsive interactions, enhancing gradient magnitudes near centroids while preserving the original diffusion training framework. Furthermore, we design a computationally efficient, quasi-random category encoding scheme inspired by Kronecker sequences, which integrates seamlessly with an end-to-end pixel neural field framework for pixel-level semantic alignment. Extensive experiments consistently demonstrate significant improvements over vanilla flow matching approaches, substantially narrowing the performance gap between generative segmentation and strong discriminative specialists.
title Rethinking Vector Field Learning for Generative Segmentation
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2603.19218