Degradation-Consistent Learning via Bidirectional Diffusion for Low-Light Image Enhancement

TL;DR

This paper introduces a bidirectional diffusion framework for low-light image enhancement that models degradation processes in both directions, improving structural consistency and visual quality over existing methods.

Contribution

It proposes a novel bidirectional diffusion optimization mechanism with adaptive feature interaction and reflection-aware correction, enhancing degradation modeling and image restoration quality.

Findings

Outperforms state-of-the-art methods in benchmarks

Improves structural consistency and detail preservation

Generalizes well across diverse degradation scenarios

Abstract

Low-light image enhancement aims to improve the visibility of degraded images to better align with human visual perception. While diffusion-based methods have shown promising performance due to their strong generative capabilities. However, their unidirectional modelling of degradation often struggles to capture the complexity of real-world degradation patterns, leading to structural inconsistencies and pixel misalignments. To address these challenges, we propose a bidirectional diffusion optimization mechanism that jointly models the degradation processes of both low-light and normal-light images, enabling more precise degradation parameter matching and enhancing generation quality. Specifically, we perform bidirectional diffusion-from low-to-normal light and from normal-to-low light during training and introduce an adaptive feature interaction block (AFI) to refine feature representation. By leveraging the complementarity between these two paths, our approach imposes an implicit symmetry constraint on illumination attenuation and noise distribution, facilitating consistent degradation learning and improving the models ability to perceive illumination and detail degradation. Additionally, we design a reflection-aware correction module (RACM) to guide color restoration post-denoising and suppress overexposed regions, ensuring content consistency and generating high-quality images that align with human visual perception. Extensive experiments on multiple benchmark datasets demonstrate that our method outperforms state-of-the-art methods in both quantitative and qualitative evaluations while generalizing effectively to diverse degradation scenarios. Code at https://github.com/hejh8/BidDiff