Abstract
Landslides are widely distributed worldwide and often result in tremendous casualties and economic losses, especially in the Loess Plateau of China. Taking Wuqi County in the hinterland of the Loess Plateau as the research area, using Bayesian hyperparameters to optimize random forest and extreme gradient boosting decision trees model for landslide susceptibility mapping, and the two optimized models are compared. In addition, 14 landslide influencing factors are selected, and 734 landslides are obtained according to field investigation and reports from literals. The landslides were randomly divided into training data (70%) and validation data (30%). The hyperparameters of the random forest and extreme gradient boosting decision tree models were optimized using a Bayesian algorithm, and then the optimal hyperparameters are selected for landslide susceptibility mapping. Both models were evaluated and compared using the receiver operating characteristic curve and confusion matrix. The results show that the AUC validation data of the Bayesian optimized random forest and extreme gradient boosting decision tree model are 0.88 and 0.86, respectively, which showed an improvement of 4 and 3%, indicating that the prediction performance of the two models has been improved. However, the random forest model has a higher predictive ability than the extreme gradient boosting decision tree model. Thus, hyperparameter optimization is of great significance in the improvement of the prediction accuracy of the model. Therefore, the optimized model can generate a high-quality landslide susceptibility map.
Highlights
A landslide is defined as the movement of a mass of rock, earth, or debris down a slope (Cruden, 1991)
In the evaluation of landslide susceptibility, when advanced machine learning algorithms are used for modeling, a data set consisting of positive samples and negative samples is required to train and validate the model
Yilmaz (2010) compared the influence of scarp, seed cell and point sampling strategy on landslide susceptibility mapping, and the results showed that the Scarp sampling strategy gave the best results than the point, whereas the scarp and seed cell methods can be evaluated relatively similar
Summary
A landslide is defined as the movement of a mass of rock, earth, or debris down a slope (Cruden, 1991). Landslides are widely distributed around the world, especially in the areas with more active geological activities. They are one of the most destructive geohazards and cause catastrophic consequences. An effective solution that can reduce and mitigate the damage caused by landslide disasters needs to be urgently developed. Previous studies have shown that landslide susceptibility mapping (LSM) can reduce the risk of landslides and provide an essential basis and scientific support for decision-makers to Bayesian Hyperparameter Optimized deal with landslide disaster risk management and land use policies (Fell et al, 2008; Nourani et al, 2014)
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