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基于高分辨率卫星图像光照强度的城市区域目标阴影指数

Object-Based Shadow Index via Illumination Intensity from High Resolution Satellite Images over Urban Areas.

作者信息

Fu Haoyang, Zhou Tingting, Sun Chenglin

机构信息

Coherent Light and Atomic and Molecular Spectroscopy Laboratory, College of Physics, Jilin University, Changchun 130012, China.

出版信息

Sensors (Basel). 2020 Feb 17;20(4):1077. doi: 10.3390/s20041077.

DOI:10.3390/s20041077
PMID:32079156
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7070997/
Abstract

For multi-spectral remote sensing imagery, accurate shadow extraction is of great significance for overcoming the information loss caused by high buildings and the solar incidence angle in urban remote sensing. However, diverse solar illumination conditions, similarities between shadows, and other dark land features bring uncertainties and deviations to shadow extraction processes and results. In this paper, we classify shadows as either strong or weak based on the ratio between ambient light intensity and direct light intensity, and use the fractal net evolution approach (FNEA), which is a multi-scale segmentation method based on spectral and shape heterogeneity, to reduce the interference of salt and pepper noise and relieve the error of misdiagnosing land covers with high reflectivity in shaded regions as unshaded ones. Subsequently, an object-based shadow index (OSI) is presented according to the illumination intensities of different reflectance features, as well as using the normalized difference water index (NDWI) and near infrared (NIR) band to highlight shadows and eliminate water body interference. The data from three high-spatial-resolution satellites-WorldView-2 (WV-2), WorldView-3 (WV-3), and GaoFen-2 (GF-2)-were used to test the methods and verify the robustness of the OSI. The results show that the OSI index performed well regarding both strong and weak shadows with the user accuracy and the producer accuracy both above 90%, while the four other existing indexes that were tested were not effective at diverse solar illumination conditions. In addition, all the disturbances from water body were excluded well when using the OSI, except for the GF-2 data in weak shadows.

摘要

对于多光谱遥感影像而言,准确提取阴影对于克服城市遥感中由高层建筑和太阳入射角导致的信息损失具有重要意义。然而,多样的太阳光照条件、阴影与其他暗地物特征之间的相似性,给阴影提取过程和结果带来了不确定性和偏差。在本文中,我们基于环境光强度与直射光强度的比值将阴影分为强阴影和弱阴影,并使用分形网络演化方法(FNEA),这是一种基于光谱和形状异质性的多尺度分割方法,以减少椒盐噪声的干扰,并缓解将阴影区域中高反射率的土地覆盖误判为非阴影区域的误差。随后,根据不同反射率特征的光照强度,提出了一种基于对象的阴影指数(OSI),并利用归一化差异水体指数(NDWI)和近红外(NIR)波段来突出阴影并消除水体干扰。使用来自三颗高空间分辨率卫星——WorldView - 2(WV - 2)、WorldView - 3(WV - 3)和高分二号(GF - 2)的数据对这些方法进行测试,并验证OSI的稳健性。结果表明,OSI指数在强阴影和弱阴影方面均表现良好,用户精度和生产者精度均高于90%,而测试的其他四个现有指数在不同的太阳光照条件下效果不佳。此外,使用OSI时,除了弱阴影中的GF - 2数据外,所有水体干扰都能被很好地排除。

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