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Autori principali: Pan, Mokai, Zhu, Kaizhen, Ma, Yuexin, Fu, Yanwei, Yu, Jingyi, Wang, Jingya, Shi, Ye
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2505.21528
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author Pan, Mokai
Zhu, Kaizhen
Ma, Yuexin
Fu, Yanwei
Yu, Jingyi
Wang, Jingya
Shi, Ye
author_facet Pan, Mokai
Zhu, Kaizhen
Ma, Yuexin
Fu, Yanwei
Yu, Jingyi
Wang, Jingya
Shi, Ye
contents Recent advances in diffusion bridge models leverage Doob's $h$-transform to establish fixed endpoints between distributions, demonstrating promising results in image translation and restoration tasks. However, these approaches often produce blurred or excessively smoothed image details and lack a comprehensive theoretical foundation to explain these shortcomings. To address these limitations, we propose UniDB, a unified and fast-sampling framework for diffusion bridges based on Stochastic Optimal Control (SOC). We reformulate the problem through an SOC-based optimization, proving that existing diffusion bridges employing Doob's $h$-transform constitute a special case, emerging when the terminal penalty coefficient in the SOC cost function tends to infinity. By incorporating a tunable terminal penalty coefficient, UniDB achieves an optimal balance between control costs and terminal penalties, substantially improving detail preservation and output quality. To avoid computationally expensive costs of iterative Euler sampling methods in UniDB, we design a training-free accelerated algorithm by deriving exact closed-form solutions for UniDB's reverse-time SDE. It is further complemented by replacing conventional noise prediction with a more stable data prediction model, along with an SDE-Corrector mechanism that maintains perceptual quality for low-step regimes, effectively reducing error accumulation. Extensive experiments across diverse image restoration tasks validate the superiority and adaptability of the proposed framework, bridging the gap between theoretical generality and practical efficiency. Our code is available online https://github.com/2769433owo/UniDB-plusplus.
format Preprint
id arxiv_https___arxiv_org_abs_2505_21528
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A Unified and Fast-Sampling Diffusion Bridge Framework via Stochastic Optimal Control
Pan, Mokai
Zhu, Kaizhen
Ma, Yuexin
Fu, Yanwei
Yu, Jingyi
Wang, Jingya
Shi, Ye
Computer Vision and Pattern Recognition
Artificial Intelligence
Machine Learning
Recent advances in diffusion bridge models leverage Doob's $h$-transform to establish fixed endpoints between distributions, demonstrating promising results in image translation and restoration tasks. However, these approaches often produce blurred or excessively smoothed image details and lack a comprehensive theoretical foundation to explain these shortcomings. To address these limitations, we propose UniDB, a unified and fast-sampling framework for diffusion bridges based on Stochastic Optimal Control (SOC). We reformulate the problem through an SOC-based optimization, proving that existing diffusion bridges employing Doob's $h$-transform constitute a special case, emerging when the terminal penalty coefficient in the SOC cost function tends to infinity. By incorporating a tunable terminal penalty coefficient, UniDB achieves an optimal balance between control costs and terminal penalties, substantially improving detail preservation and output quality. To avoid computationally expensive costs of iterative Euler sampling methods in UniDB, we design a training-free accelerated algorithm by deriving exact closed-form solutions for UniDB's reverse-time SDE. It is further complemented by replacing conventional noise prediction with a more stable data prediction model, along with an SDE-Corrector mechanism that maintains perceptual quality for low-step regimes, effectively reducing error accumulation. Extensive experiments across diverse image restoration tasks validate the superiority and adaptability of the proposed framework, bridging the gap between theoretical generality and practical efficiency. Our code is available online https://github.com/2769433owo/UniDB-plusplus.
title A Unified and Fast-Sampling Diffusion Bridge Framework via Stochastic Optimal Control
topic Computer Vision and Pattern Recognition
Artificial Intelligence
Machine Learning
url https://arxiv.org/abs/2505.21528