A Method to Extract Image Features and Lineaments Based on a Multi-hillshade Continuous Wavelet Transform

IF 2.8 3区 地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY Mathematical Geosciences Pub Date : 2024-06-03 DOI:10.1007/s11004-024-10146-5
Man Hyok Song, Jin Gyong Ho, Chol Kim, Yong O. Chol, Song Lyu
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Abstract

This paper presents a new method for extracting the image features and lineaments related to local extrema of an image or a digital elevation model (DEM) such as ridges and valleys based on the continuous wavelet transform (CWT) of a set of variously illuminated hillshades. The method originates from the principle that a hillshade can exactly reflect the lineaments nearly perpendicular to the illumination direction of the hillshade, but not other ones. The method consists of four steps: (1) preparation of a set of differently illuminated hillshades of the input data, (2) detection of directional edges nearly perpendicular to the illumination direction from each hillshade based on the CWT, (3) a combination of multidirectional edges into an omnidirectional feature image, and (4) identification of lineaments through linkage and linearization of image feature lines. CWT coefficients of each hillshade are used to calculate the gradient and its direction of the hillshade. For each hillshade, directional edge pixels where the gradient direction is parallel to the illumination direction are selectively detected to form accurate and solitary image feature lines related to local extrema of the input data. Directional edges of each hillshade are easily classified into positive and negative edges using the hillshade gradient. As they have similar directions, they are easily linked to form longer line raster objects, which are converted into vector objects, that is, directional lineaments. The multidirectional edges and lineaments given from all the hillshades are combined to form an omnidirectional feature image and a group of omnidirectional lineaments. Its application to real DEMs shows the demonstrated advantages of the proposed method over other methods and the similarity between detected lineaments and fault lines in the study area.

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基于多阴影连续小波变换的图像特征和线条提取方法
本文提出了一种新方法,基于一组不同光照山影的连续小波变换(CWT),提取与图像或数字高程模型(DEM)的局部极值(如山脊和山谷)相关的图像特征和线状物。该方法的原理是,山影可以精确反映几乎垂直于山影光照方向的线状物,而不能反映其他线状物。该方法包括四个步骤(1) 从输入数据中准备一组不同光照的山影;(2) 根据 CWT 从每个山影中检测出几乎垂直于光照方向的方向边缘;(3) 将多方向边缘组合成全方向特征图像;(4) 通过图像特征线的链接和线性化识别线状物。每个山影的 CWT 系数用于计算山影的梯度及其方向。对于每个阴影,选择性地检测梯度方向与光照方向平行的方向边缘像素,以形成与输入数据的局部极值相关的精确和单独的图像特征线。利用阴影梯度,可以很容易地将每个阴影的方向边缘划分为正边缘和负边缘。由于它们具有相似的方向,因此很容易将它们连接起来,形成较长的线状栅格对象,并将其转换为矢量对象,即方向线状物。将所有山影给出的多方向边缘和线状物组合起来,就形成了一个全方向特征图像和一组全方向线状物。在实际 DEM 中的应用表明,与其他方法相比,所提议的方法具有明显的优势,而且所检测到的线状物与研究区域的断层线具有相似性。
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来源期刊
Mathematical Geosciences
Mathematical Geosciences 地学-地球科学综合
CiteScore
5.30
自引率
15.40%
发文量
50
审稿时长
>12 weeks
期刊介绍: Mathematical Geosciences (formerly Mathematical Geology) publishes original, high-quality, interdisciplinary papers in geomathematics focusing on quantitative methods and studies of the Earth, its natural resources and the environment. This international publication is the official journal of the IAMG. Mathematical Geosciences is an essential reference for researchers and practitioners of geomathematics who develop and apply quantitative models to earth science and geo-engineering problems.
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