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Improving Shallow Foundation Settlement Prediction through Intelligent Optimization Techniques

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Publicado en:Computer Modeling in Engineering & Sciences vol. 143, no. 1 (2025), p. 747
Autor principal: Fattahi, Hadi
Otros Autores: Ghaedi, Hossein, Armaghani, Danial
Publicado:
Tech Science Press
Materias:
Mean square errors
Datasets
Settlement analysis
Sensitivity analysis
Parameter sensitivity
Modelling
Optimization techniques
Root-mean-square errors
Optimization
Algorithms
Penetration tests
Foundation settlement
Machine learning
Statistical analysis
Optimization algorithms
Uncertainty
Geotechnical engineering
Estimation
Data points
Footings
Acceso en línea:Citation/Abstract
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Resumen:In contemporary geotechnical projects, various approaches are employed for forecasting the settlement of shallow foundations (Sm). However, achieving precise modeling of foundation behavior using certain techniques (such as analytical, numerical, and regression) is challenging and sometimes unattainable. This is primarily due to the inherent nonlinearity of the model, the intricate nature of geotechnical materials, the complex interaction between soil and foundation, and the inherent uncertainty in soil parameters. Therefore, these methods often introduce assumptions and simplifications, resulting in relationships that deviate from the actual problem’s reality. In addition, many of these methods demand significant investments of time and resources but neglect to account for the uncertainty inherent in soil/rock parameters. This study explores the application of innovative intelligent techniques to predict Sm to address these shortcomings. Specifically, two optimization algorithms, namely teaching-learning-based optimization (TLBO) and harmony search (HS), are harnessed for this purpose. The modeling process involves utilizing input parameters, such as the width of the footing (B), the pressure exerted on the footing (q), the count of SPT (Standard Penetration Test) blows (N), the ratio of footing embedment (Df/B), and the footing’s geometry (L/B), during the training phase with a dataset comprising 151 data points. Then, the models’ accuracy is assessed during the testing phase using statistical metrics, including the coefficient of determination (R2), mean square error (MSE), and root mean square error (RMSE), based on a dataset of 38 data points. The findings of this investigation underscore the substantial efficacy of intelligent optimization algorithms as valuable tools for geotechnical engineers when estimating Sm. In addition, a sensitivity analysis of the input parameters in Sm estimation is conducted using @RISK software, revealing that among the various input parameters, the N exerts the most pronounced influence on Sm.
ISSN:1526-1492
1526-1506
DOI:10.32604/cmes.2025.062390
Fuente:Advanced Technologies & Aerospace Database