Abstract
Landslides are recognized as high-impact natural hazards in different regions around the world; therefore, they are extensively researched by experts. Landslide inventories are essential to identify areas that are likely to be affected in the future, thereby enabling interventions to prevent loss of life. Today, through combined approaches, such as remote sensing and machine learning techniques, it is possible to apply algorithms that use data derived from satellite images to produce landslide inventories. This work presents the performance of five machine learning methods—k-nearest neighbor (KNN), stochastic gradient descendent (SGD), support vector machine radial basis function (SVM RBF Kernel), support vector machine (SVM linear kernel), and AdaBoost—in landslide detection in a zone of the state of Guerrero in southern Mexico, using continuous change maps and primary landslide factors, such as slope angle, terrain orientation (aspect), and lithology, as inputs. The models were trained with 2/3 of ground truth samples of 671 slidden/non-slidden polygons. The obtained inventory maps were evaluated with the remaining 1/3 of ground truth samples by generating a confusion matrix and applying the Kappa concordance coefficient, accuracy, precision, recall, and F1 score as evaluation metrics, as well as omission and commission errors. According to the results, the AdaBoost classifier reached greater spatial and statistical coherence than the other implemented methods. The best input layer combination for detection was the continuous change maps obtained by the linear regression and image differencing detection methods, together with the slope angle, aspect, and lithology conditioning factors.
Highlights
Significant efforts have been made worldwide to collect, record, and analyze data on the occurrence and impacts of natural disasters [1]
This work aims to integrate landslide inventory maps by applying supervised machine learning (ML) classification algorithms to continuo applying supervised machine learning (ML) classification algorithms to continuous change change maps derived from change detection techniques and maps of conditioning facto maps derived from change detection techniques and maps of conditioning factors that that influence land instability
Derived maps were generated from Principal Component 1 (PC1) in principal component analysis (PCA), normalized difference vegetation index (NDVI), cloud masks, slope angle (S), aspect (A), lithology (L), and ground truth (GT) samples
Summary
Significant efforts have been made worldwide to collect, record, and analyze data on the occurrence and impacts of natural disasters [1]. The development of natural disaster databases is essential since they facilitate the evaluation of their natural and social impacts and the vulnerability of regions at different scales, which can be used to design and implement risk management or land-use planning by the corresponding authorities [2]. Geographic databases that contain information on landslides, including inventories and thematic data, represent a powerful tool for local, regional, national, or continental management and organization [3]. Inventory maps are essential components of a geographical landslide database. They provide historical information on past landslide events, including their location, type, and triggers, such as heavy rain, rapid thaw, or an earthquake. Inventories include statistics on the frequency of slope failures and provide relevant information to build models of landslide susceptibility or landslide risk [4,5,6,7,8,9,10]
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