FISTA acceleration inspired network design for underwater image enhancement

IF 2.6 4区计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS Journal of Visual Communication and Image Representation Pub Date : 2024-07-08 DOI:10.1016/j.jvcir.2024.104224

Bing-Yuan Chen, Jian-Nan Su, Guang-Yong Chen, Min Gan

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Abstract

Underwater image enhancement, especially in color restoration and detail reconstruction, remains a significant challenge. Current models focus on improving accuracy and learning efficiency through neural network design, often neglecting traditional optimization algorithms’ benefits. We propose FAIN-UIE, a novel approach for color and fine-texture recovery in underwater imagery. It leverages insights from the Fast Iterative Shrink-Threshold Algorithm (FISTA) to approximate image degradation, enhancing network fitting speed. FAIN-UIE integrates the residual degradation module (RDM) and momentum calculation module (MC) for gradient descent and momentum simulation, addressing feature fusion losses with the Feature Merge Block (FMB). By integrating multi-scale information and inter-stage pathways, our method effectively maps multi-stage image features, advancing color and fine-texture restoration. Experimental results validate its robust performance, positioning FAIN-UIE as a competitive solution for practical underwater imaging applications.

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用于水下图像增强的 FISTA 加速启发网络设计

水下图像增强，尤其是色彩还原和细节重建，仍然是一项重大挑战。目前的模型侧重于通过神经网络设计提高准确性和学习效率，往往忽视了传统优化算法的优势。我们提出的 FAIN-UIE 是一种用于水下图像色彩和细节纹理恢复的新方法。它利用了快速迭代收缩阈值算法（FISTA）的观点来近似处理图像劣化，从而提高了网络拟合速度。FAIN-UIE 集成了用于梯度下降和动量模拟的残差退化模块（RDM）和动量计算模块（MC），并通过特征合并块（FMB）解决了特征融合损失问题。通过整合多尺度信息和阶段间路径，我们的方法能有效映射多阶段图像特征，推进色彩和精细纹理修复。实验结果验证了 FAIN-UIE 强大的性能，使其成为水下成像实际应用中具有竞争力的解决方案。

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来源期刊

Journal of Visual Communication and Image Representation 工程技术-计算机：软件工程

CiteScore

5.40

自引率

11.50%

发文量

188

审稿时长

9.9 months

期刊介绍： The Journal of Visual Communication and Image Representation publishes papers on state-of-the-art visual communication and image representation, with emphasis on novel technologies and theoretical work in this multidisciplinary area of pure and applied research. The field of visual communication and image representation is considered in its broadest sense and covers both digital and analog aspects as well as processing and communication in biological visual systems.