Abstract
In this study, we employed various machine learning-based techniques in predicting factor of safety against slope failures. Different regression methods namely, multi-layer perceptron (MLP), Gaussian process regression (GPR), multiple linear regression (MLR), simple linear regression (SLR), support vector regression (SVR) were used. Traditional methods of slope analysis (e.g., first established in the first half of the twentieth century) used widely as engineering design tools. Offering more progressive design tools, such as machine learning-based predictive algorithms, they draw the attention of many researchers. The main objective of the current study is to evaluate and optimize various machine learning-based and multilinear regression models predicting the safety factor. To prepare training and testing datasets for the predictive models, 630 finite limit equilibrium analysis modelling (i.e., a database including 504 training datasets and 126 testing datasets) were employed on a single-layered cohesive soil layer. The estimated results for the presented database from GPR, MLR, MLP, SLR, and SVR were assessed by various methods. Firstly, the efficiency of applied models was calculated employing various statistical indices. As a result, obtained total scores 20, 35, 50, 10, and 35, respectively for GPR, MLR, MLP, SLR, and SVR, revealed that the MLP outperformed other machine learning-based models. In addition, SVR and MLR presented an almost equal accuracy in estimation, for both training and testing phases. Note that, an acceptable degree of efficiency was obtained for GPR and SLR models. However, GPR showed more precision. Following this, the equation of applied MLP and MLR models (i.e., in their optimal condition) was derived, due to the reliability of their results, to be used in similar slope stability problems.
Highlights
The stability of natural slopes has a significant impact on civil engineering infrastructures that rest near them
The acquired dataset was divided into training (80% of the entire dataset) and validation (20% of the entire dataset) phases to train and validate the efficiency of Gaussian process regression (GPR), multiple linear regression (MLR), multi-layer perceptron (MLP), simple linear regression (SLR), and support vector regression (SVR) approaches
The implementation of models was carried out in WEKA software, which is a prominent tool for machine learning and classification applications
Summary
The stability of natural slopes has a significant impact on civil engineering infrastructures (e.g., earth dams, and transmission roads) that rest near them. The application of soft computing predictive tools has increased, due to their capability of establishing nonlinear equations between a set of input-output data In this field, various types of artificial neural network (ANN) [10] and support vector machines (SVM) [11] have been successfully employed for simulating geotechnical problems. Jagan et al, [7] developed four common models namely, GPR, adaptive neuro-fuzzy inference system (ANFIS), relevance vector machine (RVM), and extreme learning machine (ELM) to appraise the stability number of layered slopes Their results revealed the advantage of the ELM in comparison with other developed machine learning-based tools. They have introduced various machine learning-based solutions in flood prediction in order to give insight into the most appropriate models
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