Abstract
Joint analysis of spatial and spectral features has always been an important method for change detection in hyperspectral images. However, many existing methods cannot extract effective spatial features from the data itself. Moreover, when combining spatial and spectral features, a rough uniform global combination ratio is usually required. To address these problems, in this paper, we propose a novel attention-based spatial and spectral network with PCA-guided self-supervised feature extraction mechanism to detect changes in hyperspectral images. The whole framework is divided into two steps. First, a self-supervised mapping from each patch of the difference map to the principal components of the central pixel of each patch is established. By using the multi-layer convolutional neural network, the main spatial features of differences can be extracted. In the second step, the attention mechanism is introduced. Specifically, the weighting factor between the spatial and spectral features of each pixel is adaptively calculated from the concatenated spatial and spectral features. Then, the calculated factor is applied proportionally to the corresponding features. Finally, by the joint analysis of the weighted spatial and spectral features, the change status of pixels in different positions can be obtained. Experimental results on several real hyperspectral change detection data sets show the effectiveness and advancement of the proposed method.
Highlights
Change detection (CD) has been a popular research and application in the field of remote sensing in recent years, which aims to acquire the change information from multitemporal images in the same geographical area
To verify the superiority of the proposed ASSCDN, eight approaches are selected for comparison, including four widely used methods: change vector analysis (CVA) [61], KNN, SVM, and robust change vector analysis (RCVA) [39], and four deep learning-based methods: deep change vector analysis (DCVA) [50], deep slow feature analysis (DSFA) [51], GETNET [6], and three-directions spectral-spatial convolution neural network (TDSSC) [20]
The CD results were acquired by different approaches on Barbara and Bay datasets, as shown in Figures 8 and 9, and the results of the quantitative evaluation are listed in Tables 2 and 3
Summary
Change detection (CD) has been a popular research and application in the field of remote sensing in recent years, which aims to acquire the change information from multitemporal images in the same geographical area. With the advances in sensing and imaging technology, hyperspectral images (HSIs) have attracted increasing attention and been widely utilized in earth observation applications [4,6]. Some characteristics of HSIs should be noticed: unlike multispectral images and SAR images, HSIs typically have hundreds of spectral bands, and this rich spectral information helps detect finer changes for CD. HSIs bring some key advantages, redundant spectral bands may introduce interference information as adjacent bands have similar spectral values, which are continuously measured by the hyperspectral sensor [4]. For HSIs, spatial feature extraction is more challenging than multispectral image as the serious
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