Abstract
To verify the performance of the high-resolution fully polarimetric synthetic aperture radar (SAR) sensor carried by the Xinzhou 60 remote-sensing aircraft, we used corner reflectors to calibrate the acquired data. The target mechanism in high-resolution SAR images is more complex than it is in low-resolution SAR images, the impact of the point target pointing error on the calibration results is more obvious, and the target echo signal of high-resolution images is more easily affected by speckle noise; thus, more accurate extraction of the point target position and the response energy is required. To solve this problem, this paper introduces image context information and proposes a method to precisely determine the integration region of the corner reflector using sliding windows based on the integral method. The validation indicates that the fully polarimetric SAR sensor on the Xinzhou 60 remote-sensing aircraft can accurately reflect the radiometric characteristics of the ground features and that the integral method can obtain more stable results than the peak method. The sliding window allows the position of the point target to be determined more accurately, and the response energy extracted from the image via the integral method is closer to the theoretical value, which means that the high-resolution SAR system can achieve a higher radiometric calibration accuracy. Additionally, cross-validation reveals that the airborne SAR images have similar quality levels to Sentinel-1A and Gaofen-3 images.
Highlights
IntroductionPublisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations
The mean energy value obtained via the peak method was 183.609 dB, and the mean energy value obtained via the integral method was 201.365 dB
To further improve the calibration accuracy, the positioning of the center point of the corner reflector is optimized by sliding the window, and the SCR of the corner reflector is calculated via the traditional maximum center method and the sliding window method
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Synthetic aperture radar (SAR) has all-day, all-weather Earth observation capabilities and is not subject to interference from clouds, rain, and other bad weather, which is important for applications with strict timeliness requirements, such as emergency disaster monitoring, agricultural monitoring, land resource surveys, topographic surveys, and marine dynamic environment measurement [1]. Many SAR satellites have been launched, and the resolution of spaceborne SAR satellites is continuously improving. Examples include ERS-1/2, JERS-1, and other spaceborne SAR systems, as well as ESA’s Envisat
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