Abstract
Landslides are one of the most devastating natural hazards causing huge loss of life and damage to properties and infrastructures and adversely affecting the socioeconomy of the country. Landslides occur in hilly and mountainous areas all over the world. Single, ensemble, and hybrid machine learning (ML) models have been used in landslide studies for better landslide susceptibility mapping and risk management. In the present study, we have used three single ML models, namely, linear discriminant analysis (LDA), logistic regression (LR), and radial basis function network (RBFN), for landslide susceptibility mapping at Pithoragarh district, as these models are easy to apply and so far they have not been used for landslide study in this area. The main objective of this study is to evaluate the performance of these single models for correctly identifying landslide susceptible zones for their further application in other areas. For this, ten important landslide affecting factors, namely, slope, aspect, curvature, elevation, land cover, lithology, geomorphology, distance to rivers, distance to roads, and overburden depth based on the local geoenvironmental conditions, were considered for the modeling. Landslide inventory of past 398 landslide events was used in the development of models. The data of past landslide events (locations) was randomly divided into a 70/30 ratio for training (70%) and validation (30%) of the models. Standard statistical measures, namely, accuracy (ACC), specificity (SPF), sensitivity (SST), positive predictive value (PPV), negative predictive value (NPV), Kappa, root mean square error (RMSE), and area under the receiver operating characteristic curve (AUC), were used to evaluate the performance of the models. Results indicated that the performance of all the models is very good (AUC > 0.90) and that of the LR model is the best (AUC = 0.926). Therefore, these single ML models can be used for the development of accurate landslide susceptibility maps. Our study demonstrated that the single models which are easy to use and can compete with the complex ensemble/hybrid models can be applied for landslide susceptibility mapping in landslide-prone areas.
Highlights
Landslides are the most common natural disasters in the hilly and mountainous areas all over the world
receiver operating characteristic (ROC) curve is one of the most common methods for evaluating the performance of methods and algorithms used for spatial modeling [40, 41]. e numerical value of the area under the ROC curve (AUC) varies between 0 and 1, which is quantitatively used for the validation and comparison of the models
Using three single machine learning (ML) models, we have modeled landslide susceptibility in one of the landslide-prone areas of the Himalayas
Summary
Landslides are the most common natural disasters in the hilly and mountainous areas all over the world. Landslides are the downward movement of rock mass/groundmass/ rock blocks by gravity [1]. Earthquakes, and slope excavation are triggering factors for the occurrence of landslides [2]. Some of the influencing factors of landslides include the topography, geology, hydrology, and land use pattern of the area [3]. Landslide events have increased in both magnitude and frequency due to climate change effect reflected in rainfall patterns [4, 5]. Advances in Civil Engineering erefore, it is desirable to identify landslide-susceptible zones for better landslide management and disaster reduction [6]
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