Image Regression With Structure Cycle Consistency for Heterogeneous Change Detection

Change detection (CD) between heterogeneous images is an increasingly interesting topic in remote sensing. The different imaging mechanisms lead to the failure of homogeneous CD methods on heterogeneous images. To address this challenge, we propose a structure cycle consistency-based image regression method, which consists of two components: the exploration of structure representation and the structure-based regression. We first construct a similarity relationship-based graph to capture the structure information of image; here, a k-selection strategy and an adaptive-weighted distance metric are employed to connect each node with its truly similar neighbors. Then, we conduct the structure-based regression with this adaptively learned graph. More specifically, we transform one image to the domain of the other image via the structure cycle consistency, which yields three types of constraints: forward transformation term, cycle transformation term, and sparse regularization term. Noteworthy, it is not a traditional pixel value-based image regression, but an image structure regression, i.e., it requires the transformed image to have the same structure as the original image. Finally, change extraction can be achieved accurately by directly comparing the transformed and original images. Experiments conducted on different real datasets show the excellent performance of the proposed method. The source code of the proposed method will be made available at https://github.com/yulisun/AGSCC.

Automated summary

This study proposes an image regression method based on structure cycle consistency for change detection in heterogeneous images. The method captures the structure information of the image by constructing a similarity relationship-based graph and performs structure-based regression using an adaptive-weighted distance metric. Experimental results demonstrate the excellent performance of the proposed method.