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Visual Tracking by Local Superpixel Matching with Markov Random Field Read chapter Read first chapter

2016 | OriginalPaper | Chapter

Fast and Accurate Image Denoising via a Deep Convolutional-Pairs Network

Authors : Lulu Sun, Yongbing Zhang, Wangpeng An, Jingtao Fan, Jian Zhang, Haoqian Wang, Qionghai Dai

Published in: Advances in Multimedia Information Processing - PCM 2016

Publisher: Springer International Publishing

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Abstract

Most of popular image denoising approaches exploit either the internal priors or the priors learned from external clean images to reconstruct the latent image. However, it is hard for those algorithms to construct the perfect connections between the clean images and the noisy ones. To tackle this problem, we present a deep convolutional-pairs network (DCPN) for image denoising in this paper. With the observation that deeper networks improve denoising performance, we propose to use deeper networks than those employed previously for low-level image processing tasks. In our method, we attempt to build end-to-end mappings directly from a noisy image to its corresponding noise-free image by using deep convolutional layers in pair applied to image patches. Because of those mappings trained from large data, the process of denoising is much faster than other methods. DCPN is composed of three convolutional-pairs layers and one transitional layer. Two convolutional-pairs layers are used for encoding and the other one is used for decoding. Numerical experiments show that the proposed method outperforms many state-of-the-art denoising algorithms in both speed and performance.

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Footnotes
1
The source code of the proposed DCPN will be available after this paper is published.
 
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Metadata
Title
Fast and Accurate Image Denoising via a Deep Convolutional-Pairs Network
Authors
Lulu Sun
Yongbing Zhang
Wangpeng An
Jingtao Fan
Jian Zhang
Haoqian Wang
Qionghai Dai
Copyright Year
2016
Book
Advances in Multimedia Information Processing - PCM 2016

Print ISBN: 978-3-319-48889-9

Electronic ISBN: 978-3-319-48890-5

Copyright Year: 2016

DOI
https://doi.org/10.1007/978-3-319-48890-5_19