一种有效的陆地GF-1和GF-6宽波段WFV图像大气校正方法

IF 3.7 3区地球科学 Q2 ENVIRONMENTAL SCIENCES

Egyptian Journal of Remote Sensing and Space Sciences Pub Date : 2023-07-27 DOI:10.1016/j.ejrs.2023.07.011

Yi Dong , Wei Su , Fu Xuan , Jiayu Li , Feng Yin , Jianxi Huang , Yelu Zeng , Xuecao Li , Wancheng Tao

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引用次数: 0

摘要

准确的地表反射率在地表参数的准确反演中起着重要作用，大气校正在获得准确反射率方面起着决定性作用。对于GF-1 WFV和GF-6 WFV图像，有两个主要问题需要解决，包括最低点与远离最低点像素之间的光谱差异，以及用于宽成像的大气成分的空间可变性。因此，本研究使用传感器不变大气校正（SIAC）方法来关注这两个问题。我们的结果表明，与Sentinel-2反射率相比，SIAC方法将GF-1 WFV图像的相关精度从0.8868提高到0.9173，与使用FLAASH模型的结果相比，GF-6 WFV图像将相关精度从0.9530提高到0.9620。为了缓解广域各向异性，计算了方向成像角度，结果在5.6450°至33.7497°之间。此外，大气成分逐像素反演，空间变化明显。空间分辨率为500 m的反演气溶胶光学厚度（AOT）和总柱水蒸气（TCWV）与AERONET（aerosol RObotic NETwork）观测站的测量结果的相关性分别为0.9175和0.4442。这些结果表明，大气校正方法效果良好，对中国GF-1和GF-6 WFV陆地宽幅图像是有效的。

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An effective atmospheric correction method for the wide swath of Chinese GF-1 and GF-6 WFV images on lands

Accurate land surface reflectance plays an important role in the accurate inversion of surface parameters, and atmospheric correction plays a decisive role in obtaining accurate reflectance. For GF-1 WFV and GF-6 WFV images, there are two major issues to be addressed, including the spectral differences between nadir with far off-nadir pixels and the spatial variability of atmospheric components for wide imaging. Therefore, this study focuses on these two issues using the Sensor Invariant Atmospheric Correction (SIAC) method. Our results reveal that the SIAC approach improves the correlation accuracy from 0.8868 to 0.9173 for GF-1 WFV image compared with Sentinel-2 reflectance, from 0.9530 to 0.9620 for GF-6 WFV image compared with the results using FLAASH model. For alleviating wide-swathed anisotropy, the directional imaging angle is calculated with the result ranging from 5.6450° to 33.7497°. Furthermore, the atmospheric components have been inversed pixel by pixel with obvious spatial variation. And the correlation of inversed aerosol optical thickness (AOT) and total column water vapor (TCWV) with a spatial resolution of 500 m TCWV with measured results of AERONET (AErosol RObotic NETwork) observation stations are 0.9175 and 0.4442, respectively. These results reveal that the atmospheric correction method works well, which is effective for the wide swath of Chinese GF-1 WFV and GF-6 WFV images on land.

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来源期刊

Egyptian Journal of Remote Sensing and Space Sciences Multiple-

CiteScore

8.10

自引率

0.00%

发文量

审稿时长

48 weeks

期刊介绍： The Egyptian Journal of Remote Sensing and Space Sciences (EJRS) encompasses a comprehensive range of topics within Remote Sensing, Geographic Information Systems (GIS), planetary geology, and space technology development, including theories, applications, and modeling. EJRS aims to disseminate high-quality, peer-reviewed research focusing on the advancement of remote sensing and GIS technologies and their practical applications for effective planning, sustainable development, and environmental resource conservation. The journal particularly welcomes innovative papers with broad scientific appeal.