Abstract
Predicting the range of achievable strength and stiffness from stabilized soil mixtures is critical for engineering design and construction, especially for organic soils, which are often considered “unsuitable” due to their high compressibility and the lack of knowledge about their mechanical behavior after stabilization. This study investigates the mechanical behavior of stabilized organic soils using machine learning (ML) methods. ML algorithms were developed and trained using a database from a comprehensive experimental study (see Part I), including more than one thousand unconfined compression tests on organic clay samples stabilized by wet soil mixing (WSM) technique. Three different ML methods were adopted and compared, including two artificial neural networks (ANN) and a linear regression method. ANN models proved reliable in the prediction of the stiffness and strength of stabilized organic soils, significantly outperforming linear regression models. Binder type, mixing ratio, soil organic and water content, sample size, aging, temperature, relative humidity, and carbonation were the control variables (input parameters) incorporated into the ML models. The impacts of these factors were evaluated through rigorous ANN-based parametric analyses. Additionally, the nonlinear relations of stiffness and strength with these parameters were developed, and their optimum ranges were identified through the ANN models. Overall, the robust ML approach presented in this paper can significantly improve the mixture design for organic soil stabilization and minimize the experimental cost for implementing WSM in engineering projects.
Highlights
Organic soils are widely accessible yet often avoided in construction projects due to their high compressibility and lack of knowledge about proper stabilization techniques and the behavior of stabilized organic soils
Narendra et al [66] proposed a generic mathematical model using artificial neural networks (ANN) based on multilayer perceptron (MLP), radial basis function (RBF), and genetic programming (GP) developed based on laboratory tests conducted on stabilized inorganic clays with varying water contents, cement contents, and curing
Is 13 MPa for E and 0.11 MPa for unconfined compression strength (UCS). These results show that RBF models successfully captured the correlations between the control the response variables
Summary
Organic soils are widely accessible yet often avoided in construction projects due to their high compressibility and lack of knowledge about proper stabilization techniques and the behavior of stabilized organic soils. DSM is a cost-effective method for organic soil improvement using binders; as an evolving field, it still requires further knowledge and understanding through experimental and numerical investigations [18]. Mechanical properties (stiffness and strength) of stabilized soils are related to several soil and binder mixture properties and experimental factors (control variables). Investigating the effects of these variables and their interactions becomes increasingly complicated as the number of variables increases For such a high-dimensional system, machine learning. Effects of various control variables on the mechanical behavior of stabilized organic soils were investigated using ML methods. An ANN-based sensitivity analysis method was adopted to investigate each control variable’s impact and identify their optimum range for maximizing the strength and stiffness of stabilized organic soils
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