Learning Efficient and Effective Trajectories for Differential Equation-Based Image Restoration

IF 18.6

IEEE transactions on pattern analysis and machine intelligence Pub Date : 2025-07-01 DOI:10.1109/TPAMI.2025.3584921

Zhiyu Zhu;Jinhui Hou;Hui Liu;Huanqiang Zeng;Junhui Hou

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Abstract

The differential equation-based image restoration approach aims to establish learnable trajectories connecting high-quality images to a tractable distribution, e.g., low-quality images or a Gaussian distribution. In this paper, we reformulate the trajectory optimization of this kind of method, focusing on enhancing both reconstruction quality and efficiency. Initially, we navigate effective restoration paths through a reinforcement learning process, gradually steering potential trajectories toward the most precise options. Additionally, to mitigate the considerable computational burden associated with iterative sampling, we propose cost-aware trajectory distillation to streamline complex paths into several manageable steps with adaptable sizes. Moreover, we fine-tune a foundational diffusion model (FLUX) with 12B parameters by using our algorithms, producing a unified framework for handling 7 kinds of image restoration tasks. Extensive experiments showcase the significant superiority of the proposed method, achieving a maximum PSNR improvement of 2.1 dB over state-of-the-art methods, while also greatly enhancing visual perceptual quality.

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基于微分方程的图像恢复的高效学习轨迹

基于微分方程的图像恢复方法旨在建立可学习的轨迹，将高质量图像与可处理的分布（例如低质量图像或高斯分布）连接起来。在本文中，我们重新制定了这种方法的轨迹优化，重点是提高重建质量和效率。最初，我们通过强化学习过程导航有效的恢复路径，逐渐将潜在的轨迹转向最精确的选择。此外，为了减轻与迭代采样相关的相当大的计算负担，我们提出了成本感知轨迹蒸馏，将复杂的路径简化为几个具有可适应性大小的可管理步骤。此外，我们还利用我们的算法对一个包含12B个参数的基本扩散模型（FLUX）进行了微调，生成了一个处理7种图像恢复任务的统一框架。大量的实验显示了该方法的显著优势，与最先进的方法相比，最大PSNR提高了2.1 dB，同时也大大提高了视觉感知质量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE transactions on pattern analysis and machine intelligence

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