Unsupervised Single Image Super-resolution Under Complex Noise
- URL: http://arxiv.org/abs/2107.00986v1
- Date: Fri, 2 Jul 2021 11:55:40 GMT
- Title: Unsupervised Single Image Super-resolution Under Complex Noise
- Authors: Zongsheng Yue, Qian Zhao, Jianwen Xie, Lei Zhang and Deyu Meng
- Abstract summary: This paper proposes a model-based unsupervised SISR method to deal with the general SISR task with unknown degradations.
The proposed method can evidently surpass the current state of the art (SotA) method (about 1dB PSNR) not only with a slighter model (0.34M vs. 2.40M) but also faster speed.
- Score: 60.566471567837574
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: While the researches on single image super-resolution (SISR), especially
equipped with deep neural networks (DNNs), have achieved tremendous successes
recently, they still suffer from two major limitations. Firstly, the real image
degradation is usually unknown and highly variant from one to another, making
it extremely hard to train a single model to handle the general SISR task.
Secondly, most of current methods mainly focus on the downsampling process of
the degradation, but ignore or underestimate the inevitable noise
contamination. For example, the commonly-used independent and identically
distributed (i.i.d.) Gaussian noise distribution always largely deviates from
the real image noise (e.g., camera sensor noise), which limits their
performance in real scenarios. To address these issues, this paper proposes a
model-based unsupervised SISR method to deal with the general SISR task with
unknown degradations. Instead of the traditional i.i.d. Gaussian noise
assumption, a novel patch-based non-i.i.d. noise modeling method is proposed to
fit the complex real noise. Besides, a deep generator parameterized by a DNN is
used to map the latent variable to the high-resolution image, and the
conventional hyper-Laplacian prior is also elaborately embedded into such
generator to further constrain the image gradients. Finally, a Monte Carlo EM
algorithm is designed to solve our model, which provides a general inference
framework to update the image generator both w.r.t. the latent variable and the
network parameters. Comprehensive experiments demonstrate that the proposed
method can evidently surpass the current state of the art (SotA) method (about
1dB PSNR) not only with a slighter model (0.34M vs. 2.40M) but also faster
speed.
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