Abstract
In recent years, deep learning (DL) networks have been widely used in super-resolution (SR) and exhibit improved performance. In this paper, an image quality assessment (IQA)-guided single image super-resolution (SISR) method is proposed in DL architecture, in order to achieve a nice tradeoff between perceptual quality and distortion measure of the SR result. Unlike existing DL-based SR algorithms, an IQA net is introduced to extract perception features from SR results, calculate corresponding loss fused with original absolute pixel loss, and guide the adjustment of SR net parameters. To solve the problem of heterogeneous datasets used by IQA and SR networks, an interactive training model is established via cascaded network. We also propose a pairwise ranking hinge loss method to overcome the shortcomings of insufficient samples during training process. The performance comparison between our proposed method with recent SISR methods shows that the former achieves a better tradeoff between perceptual quality and distortion measure than the latter. Extensive benchmark experiments and analyses also prove that our method provides a promising and opening architecture for SISR, which is not confined to a specific network model.
Highlights
Despite the rapid development of imaging technology, imaging devices still have limited achievable resolution due to several theoretical and practical restrictions
The results suggest that enhanced deep SR network (EDSR)-VGG2,2 reaches the minimum root mean square error (RMSE) together with the maximum perceptual index (PI), whereas an opposite effect could be observed for EnhanceNet
We propose an image quality assessment (IQA)-guided single image SR (SISR) method using deep learning (DL) networks
Summary
Despite the rapid development of imaging technology, imaging devices still have limited achievable resolution due to several theoretical and practical restrictions. Deep neural networks (DNN) have been widely used in SR and have demonstrated superior performance [6, 7] Several quintessential methods, such as non-uniform interpolation, frequency domain, and machine learning-based reconstruction approaches, have been developed for SR. These methods can provide optimal or near-optimal images that increase the resolution, they cannot guarantee detail enhancement, such as loss of high-frequency information and edge blur To solve these problems, deep learning-based SR methods are developed given that the mapping relations of image feature from LR to HR can be fully explored, and the reconstruction results have remarkable robustness and stability in multiple scale spaces [8,9].
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
