Abstract
Landslides are one of the critical natural hazards that cause human, infrastructure, and economic losses. Risk of catastrophic losses due to landslides is significant given sprawled urban development near steep slopes and the increasing proximity of large populations to hilly areas. For reducing these losses, a high-resolution digital terrain model (DTM) is an essential piece of data for a qualitative or a quantitative investigation of slopes that may lead to landslides. Data acquired by a terrestrial laser scanning (TLS), called a point cloud, has been widely used to generate a DTM, since a TLS is appropriate for detecting small- to large-scale ground features on steep slopes. For an accurate DTM, TLS data should be filtered to remove non-ground points, but most current algorithms for extracting ground points from a point cloud have been developed for airborne laser scanning (ALS) data and not TLS data. Moreover, it is a challenging task to generate an accurate DTM from a steep-slope area by using existing algorithms. For these reasons, we developed an algorithm to automatically extract only ground points from the point clouds of steep terrains. Our methodology is focused on TLS datasets and utilizes the adaptive principal component analysis–triangular irregular network (PCA-TIN) approach. Our method was applied to two test areas and the results showed that the algorithm can cope well with steep slopes, giving an accurate surface model compared to conventional algorithms. Total accuracy values of the generated DTMs in the form of root mean squared errors are 1.84 cm and 2.13 cm over the areas of 5252 m2 and 1378 m2, respectively. The slope-based adaptive PCA-TIN method demonstrates great potential for TLS-derived DTM construction in steep-slope landscapes.
Highlights
Landslide, defined as a rapid downward movement of a mass of rock, earth, or artificial fill on a slope [1], has a great impact on the overall environment; including the natural environment and human society [2]
We propose a new recursive filtering algorithm for extracting ground points from terrestrial laser scanning (TLS) point clouds acquired from hilly and vegetated areas
Accuracy of the algorithm was evaluated by visual inspection and by comparing errors obtained using the produced digital terrain model (DTM) with the reference DTM
Summary
Landslide, defined as a rapid downward movement of a mass of rock, earth, or artificial fill on a slope [1], has a great impact on the overall environment; including the natural environment and human society [2]. The June 2017 landslide in Sichuan Province, China, caused more than 15 deaths and 100 people to be classified as missing [4]. Another recent landslide in August of 2017 in Sierra Leone killed an estimated 300 people; at least 300 to 1500 people are still classified as missing [5]. About half of the 120 households in Hyeongchon village were damaged and 18 people were killed [7]. These kinds of unusual landslides have been increasing in frequency and causing considerable economic loss as well as casualties
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