Abstract
Change detection (CD) aims to identify differences in scenes observed at different times. Hyperspectral image (HSI) is preferred for the understanding of land surface changes, since it can provide essential and unique features for CD. However, due to the high-dimensionality and limited data, the HSI-CD task is challenged. While model-driven CD methods are hard to achieve high accuracy due to the weak detection performance for fine changes, data-driven CD methods are hard to be generalized due to the limited datasets. The state-of-art method is to combine a single model-driven method with a data-driven convolutional neural network (CNN). Wherein the pseudolabels can be generated automatically by the model-driven method and then fed to CNN for training. However, the final detection accuracy is limited by the model-driven method which produces pseudolabels with one-sidedness and low accuracy. Therefore, the generation of credible pseudolabels is anticipated and crucial for such a combination. Herein, a novel strategy, the combination of two complementary model-driven methods, structural similarity (SSIM) and change vector analysis (CVA), is proposed to generate credible labels for training a subsequent CNN. The results show that the final accuracy is higher than that of SSIM and CVA. The main contributions of this article are threefold: First, a new paradigm for generating credible labels is proposed. Second, SSIM is used for the first time for HSI-CD tasks. Third, an unsupervised end-to-end framework is presented for the HSI-CD. Experimental results demonstrate the effectiveness of the proposed framework.
Highlights
C HANGE detection (CD) aims to identifying the differences between bitemporal images obtained over the same geographical region at different times
Different from the pseudolabels generated from a single modeldriven CD method, the proposed framework balances the credits of pseudolabels generated from two selectively model-driven CD methods, changed vector analysis (CVA) and structural similarity (SSIM) [16]
Rather than propose a modified network based on the existed architectures, we focus on exploring a new paradigm to solve the task of Hyperspectral image (HSI)-CD
Summary
C HANGE detection (CD) aims to identifying the differences between bitemporal images obtained over the same geographical region at different times. With end-to-end structure, deep learning methods can obtain depth features and global information from bitemporal images, which can be used to give change maps directly [14]. The second step is to train the formulated CNN Such approaches intend to use the learning ability of the CNN and obtain a better result than the model-driven method. It is meaningful to explore the combination of model-driven methods and deep learning methods for the achievement of HSI-CD concisely and efficiently Another challenge of the HSI-CD task is the great difficulty of detecting edge regions in the image, especially for low- and medium-resolution remote sensing images. Different from the pseudolabels generated from a single modeldriven CD method, the proposed framework balances the credits of pseudolabels generated from two selectively model-driven CD methods, changed vector analysis (CVA) and structural similarity (SSIM) [16].
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