Saved in:
Bibliographic Details
Main Authors: Xu, Yimin, Gao, Nanxi, Shan, Zhongyun, Chao, Fei, Ji, Rongrong
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2401.13221
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914650798424064
author Xu, Yimin
Gao, Nanxi
Shan, Zhongyun
Chao, Fei
Ji, Rongrong
author_facet Xu, Yimin
Gao, Nanxi
Shan, Zhongyun
Chao, Fei
Ji, Rongrong
contents In contrast to traditional image restoration methods, all-in-one image restoration techniques are gaining increased attention for their ability to restore images affected by diverse and unknown corruption types and levels. However, contemporary all-in-one image restoration methods omit task-wise difficulties and employ the same networks to reconstruct images afflicted by diverse degradations. This practice leads to an underestimation of the task correlations and suboptimal allocation of computational resources. To elucidate task-wise complexities, we introduce a novel concept positing that intricate image degradation can be represented in terms of elementary degradation. Building upon this foundation, we propose an innovative approach, termed the Unified-Width Adaptive Dynamic Network (U-WADN), consisting of two pivotal components: a Width Adaptive Backbone (WAB) and a Width Selector (WS). The WAB incorporates several nested sub-networks with varying widths, which facilitates the selection of the most apt computations tailored to each task, thereby striking a balance between accuracy and computational efficiency during runtime. For different inputs, the WS automatically selects the most appropriate sub-network width, taking into account both task-specific and sample-specific complexities. Extensive experiments across a variety of image restoration tasks demonstrate that the proposed U-WADN achieves better performance while simultaneously reducing up to 32.3\% of FLOPs and providing approximately 15.7\% real-time acceleration. The code has been made available at \url{https://github.com/xuyimin0926/U-WADN}.
format Preprint
id arxiv_https___arxiv_org_abs_2401_13221
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Unified-Width Adaptive Dynamic Network for All-In-One Image Restoration
Xu, Yimin
Gao, Nanxi
Shan, Zhongyun
Chao, Fei
Ji, Rongrong
Computer Vision and Pattern Recognition
In contrast to traditional image restoration methods, all-in-one image restoration techniques are gaining increased attention for their ability to restore images affected by diverse and unknown corruption types and levels. However, contemporary all-in-one image restoration methods omit task-wise difficulties and employ the same networks to reconstruct images afflicted by diverse degradations. This practice leads to an underestimation of the task correlations and suboptimal allocation of computational resources. To elucidate task-wise complexities, we introduce a novel concept positing that intricate image degradation can be represented in terms of elementary degradation. Building upon this foundation, we propose an innovative approach, termed the Unified-Width Adaptive Dynamic Network (U-WADN), consisting of two pivotal components: a Width Adaptive Backbone (WAB) and a Width Selector (WS). The WAB incorporates several nested sub-networks with varying widths, which facilitates the selection of the most apt computations tailored to each task, thereby striking a balance between accuracy and computational efficiency during runtime. For different inputs, the WS automatically selects the most appropriate sub-network width, taking into account both task-specific and sample-specific complexities. Extensive experiments across a variety of image restoration tasks demonstrate that the proposed U-WADN achieves better performance while simultaneously reducing up to 32.3\% of FLOPs and providing approximately 15.7\% real-time acceleration. The code has been made available at \url{https://github.com/xuyimin0926/U-WADN}.
title Unified-Width Adaptive Dynamic Network for All-In-One Image Restoration
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2401.13221