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Main Authors: Cheng, Zheng, Wang, Wenri, Chen, Guangyong, Ju, Yakun, Cheng, Yihua, Liu, Zhisong, Meng, Yanda, Song, Jintao
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.04123
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author Cheng, Zheng
Wang, Wenri
Chen, Guangyong
Ju, Yakun
Cheng, Yihua
Liu, Zhisong
Meng, Yanda
Song, Jintao
author_facet Cheng, Zheng
Wang, Wenri
Chen, Guangyong
Ju, Yakun
Cheng, Yihua
Liu, Zhisong
Meng, Yanda
Song, Jintao
contents Underwater image enhancement (UIE) techniques aim to improve visual quality of images captured in aquatic environments by addressing degradation issues caused by light absorption and scattering effects, including color distortion, blurring, and low contrast. Current mainstream solutions predominantly employ multi-scale feature extraction (MSFE) mechanisms to enhance reconstruction quality through multi-resolution feature fusion. However, our extensive experiments demonstrate that high-quality image reconstruction does not necessarily rely on multi-scale feature fusion. Contrary to popular belief, our experiments show that single-scale feature extraction alone can match or surpass the performance of multi-scale methods, significantly reducing complexity. To comprehensively explore single-scale feature potential in underwater enhancement, we propose an innovative Single-Scale Decomposition Network (SSD-Net). This architecture introduces an asymmetrical decomposition mechanism that disentangles input image into clean layer along with degradation layer. The former contains scene-intrinsic information and the latter encodes medium-induced interference. It uniquely combines CNN's local feature extraction capabilities with Transformer's global modeling strengths through two core modules: 1) Parallel Feature Decomposition Block (PFDB), implementing dual-branch feature space decoupling via efficient attention operations and adaptive sparse transformer; 2) Bidirectional Feature Communication Block (BFCB), enabling cross-layer residual interactions for complementary feature mining and fusion. This synergistic design preserves feature decomposition independence while establishing dynamic cross-layer information pathways, effectively enhancing degradation decoupling capacity.
format Preprint
id arxiv_https___arxiv_org_abs_2508_04123
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Excavate the potential of Single-Scale Features: A Decomposition Network for Water-Related Optical Image Enhancement
Cheng, Zheng
Wang, Wenri
Chen, Guangyong
Ju, Yakun
Cheng, Yihua
Liu, Zhisong
Meng, Yanda
Song, Jintao
Computer Vision and Pattern Recognition
Image and Video Processing
Underwater image enhancement (UIE) techniques aim to improve visual quality of images captured in aquatic environments by addressing degradation issues caused by light absorption and scattering effects, including color distortion, blurring, and low contrast. Current mainstream solutions predominantly employ multi-scale feature extraction (MSFE) mechanisms to enhance reconstruction quality through multi-resolution feature fusion. However, our extensive experiments demonstrate that high-quality image reconstruction does not necessarily rely on multi-scale feature fusion. Contrary to popular belief, our experiments show that single-scale feature extraction alone can match or surpass the performance of multi-scale methods, significantly reducing complexity. To comprehensively explore single-scale feature potential in underwater enhancement, we propose an innovative Single-Scale Decomposition Network (SSD-Net). This architecture introduces an asymmetrical decomposition mechanism that disentangles input image into clean layer along with degradation layer. The former contains scene-intrinsic information and the latter encodes medium-induced interference. It uniquely combines CNN's local feature extraction capabilities with Transformer's global modeling strengths through two core modules: 1) Parallel Feature Decomposition Block (PFDB), implementing dual-branch feature space decoupling via efficient attention operations and adaptive sparse transformer; 2) Bidirectional Feature Communication Block (BFCB), enabling cross-layer residual interactions for complementary feature mining and fusion. This synergistic design preserves feature decomposition independence while establishing dynamic cross-layer information pathways, effectively enhancing degradation decoupling capacity.
title Excavate the potential of Single-Scale Features: A Decomposition Network for Water-Related Optical Image Enhancement
topic Computer Vision and Pattern Recognition
Image and Video Processing
url https://arxiv.org/abs/2508.04123