Abstract
Co-registering the Sentinel-1 Synthetic Aperture Radar (SAR) and Sentinel-2 optical data of the European Space Agency (ESA) is of great importance for many remote sensing applications. However, we find that there are evident misregistration shifts between the Sentinel-1 SAR and Sentinel-2 optical images that are directly downloaded from the official website. To address that, this paper presents a fast and effective registration method for the two types of images. In the proposed method, a block-based scheme is first designed to extract evenly distributed interest points. Then, the correspondences are detected by using the similarity of structural features between the SAR and optical images, where the three-dimensional (3D) phase correlation (PC) is used as the similarity measure for accelerating image matching. Lastly, the obtained correspondences are employed to measure the misregistration shifts between the images. Moreover, to eliminate the misregistration, we use some representative geometric transformation models such as polynomial models, projective models, and rational function models for the co-registration of the two types of images, and we compare and analyze their registration accuracy under different numbers of control points and different terrains. Six pairs of the Sentinel-1 SAR L1 and Sentinel-2 optical L1C images covering three different terrains are tested in our experiments. Experimental results show that the proposed method can achieve precise correspondences between the images, and the third-order polynomial achieves the most satisfactory registration results. Its registration accuracy of the flat areas is less than 1.0 10 m pixel, that of the hilly areas is about 1.5 10 m pixels, and that of the mountainous areas is between 1.7 and 2.3 10 m pixels, which significantly improves the co-registration accuracy of the Sentinel-1 SAR and Sentinel-2 optical images.
Highlights
Sentinel-1 and 2 are special satellite series of European Copernicus program created by the European Space Agency (ESA)
The Sentinel-1 interferometric wide swath (IW) L1 ground range detected (GRD) 10 m productions are provided in geolocated tiles of about 25,000 × 16,000 pixels in geographic longitude/latitude coordinates using the World Geodetic System 84 (WGS84) datum
Based on the above matching approach and geometric transformation models, this paper proposes a technical solution to measure the misregistration shifts and improve the co-registration accuracy between the Sentinel Synthetic Aperture Radar (SAR) and optical images
Summary
Sentinel-1 and 2 are special satellite series of European Copernicus program created by the European Space Agency (ESA). This paper presents a fast and robust matching method for the directly downloaded Sentinel-1 and Sentinel-2 images, which is used to measure their misregistration shifts and determine an optimum geometric transformation model for their co-registration. The proposed matching scheme can insure the uniform distribution of correspondences via the block extraction strategy, handle nonlinear radiometric differences using the similarity of structure features, and accelerate image matching because of the use of 3D PC These correspondences are used to measure and analyze the misregistration shifts between the Sentinel SAR and optical images. We design a block-based matching scheme based on structural features to detect evenly distributed correspondences between the Sentinel-1 SAR L1 images and the Sentinel-2 optical L1C images, which is computationally effective and is robust to nonlinear radiometric differences. We conclude with a discussion of the results and recommendations for future work
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