Abstract
Despite yielding considerable degrees of accuracy in landslide predictions, the outcomes of different landslide susceptibility models are prone to spatial disagreement; and therefore, uncertainties. Uncertainties in the results of various landslide susceptibility models create challenges in selecting the most suitable method to manage this complex natural phenomenon. This study aimed to propose an approach to reduce uncertainties in landslide prediction, diagnosing spatial agreement in machine learning-based landslide susceptibility maps. It first developed landslide susceptibility maps of Cox’s Bazar district of Bangladesh, applying four machine learning algorithms: K-Nearest Neighbor (KNN), Multi-Layer Perceptron (MLP), Random Forest (RF), and Support Vector Machine (SVM), featuring hyperparameter optimization of 12 landslide conditioning factors. The results of all the four models yielded very high prediction accuracy, with the area under the curve (AUC) values range between 0.93 to 0.96. The assessment of spatial agreement of landslide predictions showed that the pixel-wise correlation coefficients of landslide probability between various models range from 0.69 to 0.85, indicating the uncertainty in predicted landslides by various models, despite their considerable prediction accuracy. The uncertainty was addressed by establishing a Logistic Regression (LR) model, incorporating the binary landslide inventory data as the dependent variable and the results of the four landslide susceptibility models as independent variables. The outcomes indicated that the RF model had the highest influence in predicting the observed landslide locations, followed by the MLP, SVM, and KNN models. Finally, a combined landslide susceptibility map was developed by integrating the results of the four machine learning-based landslide predictions. The combined map resulted in better spatial agreement (correlation coefficients range between 0.88 and 0.92) and greater prediction accuracy (0.97) compared to the individual models. The modelling approach followed in this study would be useful in minimizing uncertainties of various methods and improving landslide predictions.
Highlights
Due to the destructive potential of landslides, this natural phenomenon poses a serious threat to human life, property, and the environment in the areas in which they occur [1,2]
The Support Vector Machine (SVM) resulted in the highest proportion of area (38.7%) susceptible to the landslide of ‘highRe’maotne dSen‘sv. 2e0r2y0, h12i,gxhFO’ RsePvEEeRriRtEyV, IwEWhile the Random Forest (RF) algorithm yielded a rel1a4toifv2e3 ly lower proportion (23.1%) of landslide susceptible area
The spatial association in landslide prediction between various machine learning-based models was analyzed to quantify the spatial agreement of predicted landslide susceptibility
Summary
Due to the destructive potential of landslides, this natural phenomenon poses a serious threat to human life, property, and the environment in the areas in which they occur [1,2]. Access to continuous and accurate information on landslide occurrence is essential for managing the risk to this unpredictable hazard [2,3]. Mapping landslide susceptibility is a widely conceived approach to estimating the likelihood of occurrence of this complex natural phenomenon [1,3,4,5]. The development of remote sensing technologies in the last few decades enables researchers to map landslide susceptibility more efficiently, due to the availability of high spatial and temporal resolution data [3,4,6]. High-resolution remote sensing (satellite imagery) data are used to develop various thematic layers explaining the topography, land cover, geology, and hydrology, which are essential parameters for predicting landslides [4,7]. Remote sensing techniques are useful in developing accurate landslide inventory maps [3,6]
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