Abstract
The shear strength of rockfill materials (RFM) is an important engineering parameter in the design and audit of geotechnical structures. In this paper, the predictive reliability and feasibility of random forests and Cubist models were analyzed by estimating the shear strength from the relative density, particle size, distribution (gradation), material hardness, gradation and fineness modulus, and confining (normal) stress. For this purpose, case studies of 165 rockfill samples have been applied to generate training and testing datasets to construct and validate the models. Thirteen key material properties for rockfill characterization were selected to develop the proposed models. Validation and comparison of the models have been performed using the root mean square error (RMSE), coefficient of determination (R2), and mean estimation error (MAE) between the measured and estimated values. A sensitivity analysis was also conducted to ascertain the importance of various inputs in the prediction of the output. The results demonstrated that the Cubist model has the highest prediction performance with (RMSE = 0.0959, R2 = 0.9697 and MAE = 0.0671), followed by the random forests model with (RMSE = 0.1133, R2 = 0.9548 and MAE= 0.0665), the artificial neural network (ANN) model with (RMSE = 0.1320, R2 = 0.9386 and MAE = 0.0841), and the conventional multiple linear regression technique with (RMSE = 0.1361, R2 = 0.9345 and MAE = 0.0888). The results indicated that the Cubist and random forests models are able to generate better predictive results of the shear strength of RFM than ANN and conventional regression models. The Cubist model was considered to be more promising for interpreting the complex relationships between the influential properties of RFM and the shear strengths of RFM to some extent, which can be extremely helpful in estimating the shear strength of rockfill materials.
Highlights
As multiple engineering materials, rockfill materials (RFM), have been extensively employed in the construction of dams, slopes and embankments in mining and geotechnical engineering around the world [1,2]
The findings demonstrated that the Cubist and random forests predictors are more sensitive to the value) that influences the shear strength of RFM and other hyperparameters of the random forest and indicators of normal stress and material gradation properties but are not sensitive to min uniaxial compressive strength (UCS) and max Cubist algorithms may exist for improving the performance
This paper investigates the potential of random forest and Cubist regression techniques for predicting the shear strength of RFM and identifies useful parameters that affect the prediction of rockfill shear strength
Summary
Rockfill materials (RFM), have been extensively employed in the construction of dams, slopes and embankments in mining and geotechnical engineering around the world [1,2]. This material is collected either from the alluvial deposits of a river or by blasting available rock [3,4]. The availability of information about the mechanical behavior of RFM is an important indicator in the initial stages of engineering projects, especially information concerning the shear strength of RFM, which defines the stability of a structure.
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