Abstract
Cloud and cloud shadow detection is one of the most important tasks for optical remote sensing image preprocessing. It is not an easy task due to the variety and complexity of underlying surfaces, such as the low-albedo objects (water and mountain shadow) and the high-albedo objects (snow and ice). In this study, an end-to-end multiscale 3D-CNN method is proposed for cloud and cloud shadow detection in high resolution multispectral imagery. Specifically, a multiscale learning module is designed to extract cloud and cloud shadow contextual information of different levels. In order to make full use of band information, four band-combination images are inputted into the multiscale 3D-CNN. A joint spectral-spatial information of 3D-convolution layer is developed to fully explore the joint spatial-spectral correlations feature in the input data. Overall, in the experiments undertaken in this paper, the proposed method achieved a mean overall accuracy of 97.27% for cloud detection, with a mean precision of 96.02% and a mean recall of 95.86%. For cloud shadow detection, the proposed method achieved a mean precision of 95.92% and a mean recall of 92.86%. Experimental results on two validation datasets (GF-1 WFV validation data and ZY-3 validation data) show that the proposed multiscale-3D-CNN method achieved good performance with limited spectral ranges.
Highlights
Optical high-resolution remote sensing images are widely used for environment monitoring, geographical mapping, and change detection [1]
In this paper, the multi-scale 3D-convolutional neural networks (CNN) is proposed for cloud and cloud shadow detection using high resolution multispectral images
The proposed multiscale 3D-CNN has greatly improved the accuracy of cloud shadow detection while achieving good accuracy of cloud detection
Summary
Optical high-resolution remote sensing images (such as SPOT/Gaofen-1) are widely used for environment monitoring, geographical mapping, and change detection [1]. A variety of cloud\shadow detection methods for remote sensing imagery have been proposed [4] These methods can broadly be categorized into threshold based methods and image classification methods [5]. Image classification based on feature extraction and machine learning is an effective method for cloud and cloud shadow detection. The 2D-CNN based methods cannot fully extract the joint spatial-spectral correlations feature [29], which can be critical for cloud and cloud shadow detection. An end-to-end multiscale-3D-CNN architecture is proposed for cloud and cloud shadow detection in high resolution multispectral imagery. In order to fully explore the joint spatial-spectral correlations feature, a spectral-spatial information of 3D-convolution layer is developed for high resolution multispectral imagery.
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