Abstract
The deep convolutional neural network has achieved great success in the Single Image Super-resolution task. It is obviously that among the well-known super-resolution methods, the deep learning-based algorithms show the most advanced performance. However, the most advanced algorithms currently use complex networks with a large number of parameters, which makes it difficult to apply deep learning algorithms on mobile devices. To solve this problem, we propose a lightweight dual-residual network(LDRN) for single image super-resolution, which has better reconstruction quality than most current advanced lightweight algorithms. Due to its fewer parameters and computational expense, real-time and mobile applications of our networks can be easily realized. On the basis of the residual module, we propose a new residual unit, which uses two depthwise separable(DW) convolution to obtain better balance between feature extraction capacity and lightweight performance. We further design a dual-stream residual block, which contains a multiplication branch and an addition branch. The dual-stream residual block can improve the reconstruction performance more effectively than expanding the network width. In addition, we also designed a new up-sampling module to simplify the previous up-sampling methods. Extensive experimental results show that our network has better reconstruction performance and lightweight performance than most existing state-of-the-art algorithms. Our code is available at https://github.com/Jiangyichun-cust/pytorch-LDRN.
Highlights
S INGLE image super-resolution (SISR) is a classic problem in the field of low-level computer vision
PROPSED METHOD As we mentioned in Section I, we propose a new lightweight dual-stream residual network for SISR, called LDRN
Testing Setting: We mainly focus on the lightweight performance and reconstruction performance of the model
Summary
S INGLE image super-resolution (SISR) is a classic problem in the field of low-level computer vision. The goal of SISR is to generate high-quality super-resolution(SR) images with clear details that are as close as possible to HR images. Some high-frequency information is lost in the degradation process, so the LR image may correspond to multiple possible HR images, which makes the SISR problem ill-posed. The reconstruction-based algorithms usually require multiple frames of images to provide the necessary information and require artificially well-designed prior knowledge to constrain the reconstruction locally or nonlocally. In these methods, when the scale factor becomes larger, the reconstruction performance will drop sharply
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