Cartografía de calizas con datos hiperespectrales AISA Eagle II en una zona montañosa con vegetación densa: cómo orientar geológicamente la corrección atmosférica

IF 0.4 Q4 REMOTE SENSING

Revista de Teledeteccion Pub Date : 2018-06-29 DOI:10.4995/RAET.2018.8998

J. Buzzi, E. Costa, A. Riaza, O. Fernández, D. García-Sellés, J. Corbera

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Abstract

Carbonated rocks are crucial targets for oil exploration, outcropping often in large areas with minimum spectral differences among geological units. The typical carbonate spectral absorptions in 2200 nm and 2300 nm, are excluded from the wavelength range of AISA Eagle II. AISA Eagle II hyperspectral data are processed in flight lines of 1024 swath pixels in the visible to near-infrared wavelength range (400 to 970 nm). The flight has a spatial resolution of 1 m and records a total of 128 channels with a spectral resolution of 4,8 nm. The area of study is a carbonate rocky mountain densely vegetated, covered by variably dense trees and bushes. Masking vegetation cover and shade effects is prior to any geological analysis using hyperspectral image processing. Carbonate units occur in mountain slopes, with small areas of ridges of rock outcrops and wide fans of loose material. The background soil of different geological units differ spectrally only by overall reflectance. Instead, limestone rocky outcrops display spectral responses with smooth typical iron oxide absorptions that distinguish them apart from loose boulders of limestone. Trying to enhance spectral differences in the visible wavelength range among carbonate geological units, an atmospheric correction using field spectra from geologically selected targets in a limestone quarry was performed. This way, it was possible to map apart lithologically similar detrital units dominated by carbonate in a river plain. The limy river bottom displays spectra with a straight line in the visible wavelength range due to abundant organic matter and small grain size. The spectra of the upper terraces record spectral absorption features related to iron oxide contents similar to the rock outcrops in ridges of mountains. The use of field spectra from geologically selected targets improves the mapping capability of hyperspectral imagery in areas with geological units with a homogeneous spectral response.

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用AISA Eagle II高光谱数据绘制植被茂密山区的石灰岩地图：如何在地质上指导大气校正

碳酸盐岩是石油勘探的重要目标，其出露面积大，地质单元间光谱差异小。在AISA Eagle II的波长范围内，排除了典型的2200nm和2300nm的碳酸盐光谱吸收。AISA Eagle II高光谱数据是在可见光到近红外波长范围(400至970 nm)的1024条像素的飞行线上处理的。该飞行的空间分辨率为1 m，共记录了128个通道，光谱分辨率为4.8 nm。研究区域是一个植被茂密的碳酸盐岩岩石山，被不同密度的树木和灌木覆盖。掩盖植被覆盖和阴影效应是在使用高光谱图像处理进行任何地质分析之前。碳酸盐单元出现在山坡上，有小范围的岩石隆起和大面积的松散物质扇。不同地质单元背景土壤的光谱差异仅在于全反射。相反，石灰岩岩石露头显示出平滑的典型氧化铁吸收光谱响应，将它们与松散的石灰岩巨石区分开来。为了增强碳酸盐岩地质单元之间可见波长范围的光谱差异，利用石灰岩采石场地质选择目标的场光谱进行了大气校正。这样，就有可能在河流平原上划分出岩性相似的以碳酸盐为主的碎屑单元。由于有机质丰富，粒度小，河底可见光谱呈直线分布。上阶地的光谱记录了与氧化铁含量有关的光谱吸收特征，类似于山脊的岩石露头。利用地质选择目标的场光谱，提高了具有均匀光谱响应的地质单元区域的高光谱成像的成图能力。

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来源期刊

Revista de Teledeteccion REMOTE SENSING-

CiteScore

1.80

自引率

14.30%

发文量

审稿时长

10 weeks