Abstract
Image enhancement (IE) technology can help enhance the brightness of remote-sensing images to obtain better interpretation and visualization effects. Convolutional neural networks (CNN), such as the Low-light CNN (LLCNN) and Super-resolution CNN (SRCNN), have achieved great success in image enhancement, image super resolution, and other image-processing applications. Therefore, we adopt CNN to propose a new neural network architecture with end-to-end strategy for low-light remote-sensing IE, named remote-sensing CNN (RSCNN). In RSCNN, an upsampling operator is adopted to help learn more multi-scaled features. With respect to the lack of labeled training data in remote-sensing image datasets for IE, we use real natural image patches to train firstly and then perform fine-tuning operations with simulated remote-sensing image pairs. Reasonably designed experiments are carried out, and the results quantitatively show the superiority of RSCNN in terms of structural similarity index (SSIM) and peak signal-to-noise ratio (PSNR) over conventional techniques for low-light remote-sensing IE. Furthermore, the results of our method have obvious qualitative advantages in denoising and maintaining the authenticity of colors and textures.
Highlights
Remote-sensing images play a significant role in large-scale spatial analysis and visualization, including climate change detection [1], urban 3D modelling [2], and global surface monitoring [3]
The experiment is first carried out on Dataset1, and 9 different methods are compared with remote-sensing CNN (RSCNN)
structural similarity index (SSIM) of Dynamic Histogram Equalization (DHE) and CLAHE are significantly improved compared to ordinary Histogram Equalization (HE), and the peak signal-to-noise ratio (PSNR) result of DHE is the best
Summary
Remote-sensing images play a significant role in large-scale spatial analysis and visualization, including climate change detection [1], urban 3D modelling [2], and global surface monitoring [3]. [4], have a great negative impact on the visibility and interpretability of remote-sensing images. It is a great necessity to enhance the contrast and brightness of low-light images automatically when we want to achieve a high-quality remote-sensing image dataset with large scale and long time series. The purpose of image enhancement (IE) is to improve the visual interpretation of images and to provide better clues for further processing and analyzing [4,5,6]. Many low-light IE methods have been proposed and achieved great success in image processing and remote-sensing fields. Histogram Equalization (HE) [7] and its variants such as Dynamic Histogram Equalization (DHE) [8], Brightness Protecting Dynamic Histogram
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
