Deep Wavelet Prediction for Image Super-Resolution

Deep Wavelet Prediction for Image Super-Resolution

Recent advances have seen a surge of deep learning approaches for image super-resolution. Invariably, a network, e.g. a deep convolutional neural network (CNN) or auto-encoder is trained to learn the relationship between low and high-resolution image patches. Recognizing that a wavelet transform pro...

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Bibliographic Details
Published in:2017 IEEE Conference on Computer Vision and Pattern Recognition Workshops (CVPRW) pp. 1100 - 1109
Main Authors: Tiantong Guo, Mousavi, Hojjat Seyed, Tiep Huu Vu, Monga, Vishal
Format: Conference Proceeding
Language:English
Published: IEEE 01-07-2017
Subjects:
Image reconstruction
Machine learning
Spatial resolution
Training
Wavelet domain
Wavelet transforms
Online Access:Get full text
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Summary:Recent advances have seen a surge of deep learning approaches for image super-resolution. Invariably, a network, e.g. a deep convolutional neural network (CNN) or auto-encoder is trained to learn the relationship between low and high-resolution image patches. Recognizing that a wavelet transform provides a "coarse" as well as "detail" separation of image content, we design a deep CNN to predict the "missing details" of wavelet coefficients of the low-resolution images to obtain the Super-Resolution (SR) results, which we name Deep Wavelet Super-Resolution (DWSR). Out network is trained in the wavelet domain with four input and output channels respectively. The input comprises of 4 sub-bands of the low-resolution wavelet coefficients and outputs are residuals (missing details) of 4 sub-bands of high-resolution wavelet coefficients. Wavelet coefficients and wavelet residuals are used as input and outputs of our network to further enhance the sparsity of activation maps. A key benefit of such a design is that it greatly reduces the training burden of learning the network that reconstructs low frequency details. The output prediction is added to the input to form the final SR wavelet coefficients. Then the inverse 2d discrete wavelet transformation is applied to transform the predicted details and generate the SR results. We show that DWSR is computationally simpler and yet produces competitive and often better results than state-of-the-art alternatives.
ISSN:2160-7516
DOI:10.1109/CVPRW.2017.148