New architecture of deep recursive convolution networks for super-resolution

More existing methods of single image super-resolution (SR) often direct super-resolving the details, but when the upsampling factor is larger, it is challenging to reconstruct high-frequency details. Lately, deep convolution neural networks have made significant progress with regard to SR. However,...

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Veröffentlicht in:	Knowledge-based systems 2019-08, Vol.178, p.98-110
Hauptverfasser:	Cao, Feilong, Chen, Baijie
Format:	Artikel
Sprache:	eng
Schlagworte:	Architecture Artificial neural networks Concrete blocks Convolution Convolution neural networks Deep learning Feature extraction Image reconstruction Image resolution Neural networks Recursive methods Recursive networks Residual-feature learning Super-resolution Training
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creator	Cao, Feilong Chen, Baijie
description	More existing methods of single image super-resolution (SR) often direct super-resolving the details, but when the upsampling factor is larger, it is challenging to reconstruct high-frequency details. Lately, deep convolution neural networks have made significant progress with regard to SR. However, with an increase in networks width and depth, the information used for reconstruction is becoming increasingly weaker, and the training of neural networks is becoming more difficult. This paper proposes a novel architecture of a deep recursive convolution neural networks used to reconstruct a high-resolution image from an original low-resolution (LR) image in a step-by-step manner. The architecture consists of three parts: an embedding network, cascaded fine extraction blocks, and reconstruction networks. Concretely, a wide convolution is used to extract more features from the original LR images, cascaded fine extraction blocks are employed to extract more useful information through a step-by-step approach and remove redundant information, and a deconvolution operation is utilized to restore the features. The proposed networks adopt a residual-feature learning scheme, and the Caffe framework is chosen for training the networks. The experimental results show that the proposed method exhibits a superior performance compared with various other state-of-the-art methods.
doi_str_mv	10.1016/j.knosys.2019.04.021
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Lately, deep convolution neural networks have made significant progress with regard to SR. However, with an increase in networks width and depth, the information used for reconstruction is becoming increasingly weaker, and the training of neural networks is becoming more difficult. This paper proposes a novel architecture of a deep recursive convolution neural networks used to reconstruct a high-resolution image from an original low-resolution (LR) image in a step-by-step manner. The architecture consists of three parts: an embedding network, cascaded fine extraction blocks, and reconstruction networks. Concretely, a wide convolution is used to extract more features from the original LR images, cascaded fine extraction blocks are employed to extract more useful information through a step-by-step approach and remove redundant information, and a deconvolution operation is utilized to restore the features. 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source	ScienceDirect Journals (5 years ago - present)
subjects	Architecture Artificial neural networks Concrete blocks Convolution Convolution neural networks Deep learning Feature extraction Image reconstruction Image resolution Neural networks Recursive methods Recursive networks Residual-feature learning Super-resolution Training
title	New architecture of deep recursive convolution networks for super-resolution
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