1 research outputs found
Learning Spatial-Spectral Prior for Super-Resolution of Hyperspectral Imagery
Recently, single gray/RGB image super-resolution reconstruction task has been
extensively studied and made significant progress by leveraging the advanced
machine learning techniques based on deep convolutional neural networks
(DCNNs). However, there has been limited technical development focusing on
single hyperspectral image super-resolution due to the high-dimensional and
complex spectral patterns in hyperspectral image. In this paper, we make a step
forward by investigating how to adapt state-of-the-art residual learning based
single gray/RGB image super-resolution approaches for computationally efficient
single hyperspectral image super-resolution, referred as SSPSR. Specifically,
we introduce a spatial-spectral prior network (SSPN) to fully exploit the
spatial information and the correlation between the spectra of the
hyperspectral data. Considering that the hyperspectral training samples are
scarce and the spectral dimension of hyperspectral image data is very high, it
is nontrivial to train a stable and effective deep network. Therefore, a group
convolution (with shared network parameters) and progressive upsampling
framework is proposed. This will not only alleviate the difficulty in feature
extraction due to high-dimension of the hyperspectral data, but also make the
training process more stable. To exploit the spatial and spectral prior, we
design a spatial-spectral block (SSB), which consists of a spatial residual
module and a spectral attention residual module. Experimental results on some
hyperspectral images demonstrate that the proposed SSPSR method enhances the
details of the recovered high-resolution hyperspectral images, and outperforms
state-of-the-arts. The source code is available at
\url{https://github.com/junjun-jiang/SSPSRComment: Accepted for publication at IEEE Transactions on Computational
Imagin