Abstract
High-resolution (HR) Mars images have great significance for studying the land-form features of Mars and analyzing the climate on Mars. Nowadays, the mainstream image super-resolution methods are based on deep learning or CNNs, which are better than traditional methods. However, these deep learning based methods obtain low-resolution(LR) images usually by using an ideal down-sampling method (e.g. bicubic interpolation). There are two limitations in the existing SR methods: 1) The paired LR-HR data by using such methods can achieve a satisfactory results when tested on an ideal datasets. But, these methods always fail in real Mars image super-resolution, since real Mars images rarely obey an ideal down-sampling rule. 2) The LR images obtained by ideal down-sampling methods have no noise while real Mars images usually have noise, which leads to the super-resolved images are not realistic in texture details. To solve the above-mentioned problems, in this article, we propose a novel two-step framework for Mars image super-resolution. Specifically, to address limitation 1), we focus on designing a new degradation framework by estimating blur-kernels. To address limitation 2), a Generative Adversarial Network (GAN) is trained to generate noise distribution. Extensive experiments on the Mars32k dataset demonstrate the effectiveness of the proposed method, and we achieve better qualitative and quantitative results compared to other SOTA methods.
Highlights
Among the eight major planets, Mars is the most similar to the Earth, and it is considered the most likely to give birth to life
2) The LR images obtained by bicubic interpolation have no noise while real Mars images usually have noise, which leads to the super-resolved images are not realistic in texture details
To address limitation 1), we focus on designing a new degradation framework by estimating blur-kernels
Summary
Among the eight major planets, Mars is the most similar to the Earth, and it is considered the most likely to give birth to life. Where k and n indicate super-resolution (SR) kernel and noise respectively, and the goal is to recover HR images IHR from the given LR images ILR These deep learning based super-resolution methods usually can not achieve satisfied results when applied to real Mars images. To address the second limitation, we use a noise extraction algorithm to collect noise from the original images and add it to the down-sampled images (LR) In this way, the burden of feature extraction is reduced as the model has rich prior information from real Mars images.
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