Abstract
Deep convolutional neural networks (CNNs) have been widely used and achieved state-of-the-art performance in many image or video processing and analysis tasks. In particular, for image super-resolution (SR) processing, previous CNN-based methods have led to significant improvements, when compared with shallow learning-based methods. However, previous CNN-based algorithms with simple direct or skip connections are of poor performance when applied to remote sensing satellite images SR. In this study, a simple but effective CNN framework, namely deep distillation recursive network (DDRN), is presented for video satellite image SR. DDRN includes a group of ultra-dense residual blocks (UDB), a multi-scale purification unit (MSPU), and a reconstruction module. In particular, through the addition of rich interactive links in and between multiple-path units in each UDB, features extracted from multiple parallel convolution layers can be shared effectively. Compared with classical dense-connection-based models, DDRN possesses the following main properties. (1) DDRN contains more linking nodes with the same convolution layers. (2) A distillation and compensation mechanism, which performs feature distillation and compensation in different stages of the network, is also constructed. In particular, the high-frequency components lost during information propagation can be compensated in MSPU. (3) The final SR image can benefit from the feature maps extracted from UDB and the compensated components obtained from MSPU. Experiments on Kaggle Open Source Dataset and Jilin-1 video satellite images illustrate that DDRN outperforms the conventional CNN-based baselines and some state-of-the-art feature extraction approaches.
Highlights
In recent years, remote sensing imaging technology is developing rapidly and provides extensive applications, such as object matching and detection [1,2,3,4], land cover classification [5,6], assessment of urban economic levels, resource exploration [7], etc. [8,9]
The high-frequency components lost during information propagation can be compensated in multi-scale purification unit (MSPU). (3) The final SR image can benefit from the feature maps extracted from ultra-dense residual blocks (UDB) and the compensated components obtained from MSPU
We select several different but representative scenarios to produce a visual presentation. We crop these representative scenarios into a sub-batch with the size of 120 × 120 pixels from each reconstructed SR image and compute peak signal to noise ratio (PSNR) and structural similarity (SSIM)
Summary
Remote sensing imaging technology is developing rapidly and provides extensive applications, such as object matching and detection [1,2,3,4], land cover classification [5,6], assessment of urban economic levels, resource exploration [7], etc. [8,9]. [8,9] In these applications, high-quality or high-resolution (HR) imageries are usually desired for remote sensing image analysis and processing procedure. Compared with the general images, the quality of satellite imageries can be subject to additional factors, such as ultra-distanced imaging, atmospheric disturbance, as well as relative motion. All these factors can impair the spatial resolution or clarity of the satellite images, but video satellite imageries are more severely affected due to the over-compression. To adapt to the transmission capacity of the satellite channel, the video acquisition system has to increase the compression ratio or reduce the spatial sampling resolution.
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