Optimized punching shear design in steel fiber-reinforced slabs: machine learning vs. evolutionary prediction models

Asad S. Albostami; Safaa A. Mohamad; Saif  Alzabeebee; Rwayda Kh. S. Al Hamd; Baidaa Al-Bander

doi:10.1016/j.engstruct.2024.119150

Optimized punching shear design in steel fiber-reinforced slabs: machine learning vs. evolutionary prediction models

Asad S. Albostami, Safaa A. Mohamad, Saif Alzabeebee, Rwayda Kh. S. Al Hamd^*, Baidaa Al-Bander

^*Corresponding author for this work

Department of Built Environment and Life Sciences

Research output: Contribution to journal › Article › peer-review

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Abstract

This research paper focuses on utilizing Artificial Neural Networks (ANN), Multi-Objective Genetic Algorithm Evolutionary Polynomial Regression (MOGA-EPR), and Gene Expression Programming (GEP) to predict the punching shear strength of Steel Fibre-Reinforced Concrete (SFRC) slabs.
In order to formulate predictions, research and analysis were carried out making use of a dataset, this dataset included several parameters that impact on punching shear strength, including SFRC slabs longitudinally and transversely, using ANN, GEP, and MOGA-EPR methods. The developed models exhibited very good performance, as the soft computing techniques (GEP and MOGA-EPR) achieved R² values of 0.91 to 0.93, while the ANN technique was higher at 0.95. Furthermore, two case studies were incorporated to carry out cost analyses of the models in real-world applications. It was shown that the efficiency of the Machine Learning (ML) models in reducing the costs of materials is relatively high, as they were capable of better predictions than the standard methods employed by the codes.

Original language	English
Article number	119150
Number of pages	17
Journal	Engineering Structures
Volume	322
Issue number	Part B
Early online date	30 Oct 2024
DOIs	https://doi.org/10.1016/j.engstruct.2024.119150
Publication status	Published - 1 Jan 2025

Keywords

Machine learning
Soft computing
Artificial neural networks
Multi-objective genetic algorithm evolutionary polynomial regression
Gene expression programming
Punching shear
Steel fibre reinforced concrete

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10.1016/j.engstruct.2024.119150Licence: CC BY

AlHamd_OptimizedPunchingShearDesign_Published_2024Final published version, 5.85 MBLicence: CC BY

Cite this

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title = "Optimized punching shear design in steel fiber-reinforced slabs: machine learning vs. evolutionary prediction models",

abstract = "This research paper focuses on utilizing Artificial Neural Networks (ANN), Multi-Objective Genetic Algorithm Evolutionary Polynomial Regression (MOGA-EPR), and Gene Expression Programming (GEP) to predict the punching shear strength of Steel Fibre-Reinforced Concrete (SFRC) slabs. In order to formulate predictions, research and analysis were carried out making use of a dataset, this dataset included several parameters that impact on punching shear strength, including SFRC slabs longitudinally and transversely, using ANN, GEP, and MOGA-EPR methods. The developed models exhibited very good performance, as the soft computing techniques (GEP and MOGA-EPR) achieved R² values of 0.91 to 0.93, while the ANN technique was higher at 0.95. Furthermore, two case studies were incorporated to carry out cost analyses of the models in real-world applications. It was shown that the efficiency of the Machine Learning (ML) models in reducing the costs of materials is relatively high, as they were capable of better predictions than the standard methods employed by the codes.",

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AU - Alzabeebee, Saif

AU - Al Hamd, Rwayda Kh. S.

AU - Al-Bander, Baidaa

N1 - © 2024 The Author(s). Published by Elsevier Ltd. This is an open access article under the CC BY license ( http://creativecommons.org/licenses/by/4.0/ ). Data availability statement: All the data are in the manuscript.

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N2 - This research paper focuses on utilizing Artificial Neural Networks (ANN), Multi-Objective Genetic Algorithm Evolutionary Polynomial Regression (MOGA-EPR), and Gene Expression Programming (GEP) to predict the punching shear strength of Steel Fibre-Reinforced Concrete (SFRC) slabs. In order to formulate predictions, research and analysis were carried out making use of a dataset, this dataset included several parameters that impact on punching shear strength, including SFRC slabs longitudinally and transversely, using ANN, GEP, and MOGA-EPR methods. The developed models exhibited very good performance, as the soft computing techniques (GEP and MOGA-EPR) achieved R² values of 0.91 to 0.93, while the ANN technique was higher at 0.95. Furthermore, two case studies were incorporated to carry out cost analyses of the models in real-world applications. It was shown that the efficiency of the Machine Learning (ML) models in reducing the costs of materials is relatively high, as they were capable of better predictions than the standard methods employed by the codes.

AB - This research paper focuses on utilizing Artificial Neural Networks (ANN), Multi-Objective Genetic Algorithm Evolutionary Polynomial Regression (MOGA-EPR), and Gene Expression Programming (GEP) to predict the punching shear strength of Steel Fibre-Reinforced Concrete (SFRC) slabs. In order to formulate predictions, research and analysis were carried out making use of a dataset, this dataset included several parameters that impact on punching shear strength, including SFRC slabs longitudinally and transversely, using ANN, GEP, and MOGA-EPR methods. The developed models exhibited very good performance, as the soft computing techniques (GEP and MOGA-EPR) achieved R² values of 0.91 to 0.93, while the ANN technique was higher at 0.95. Furthermore, two case studies were incorporated to carry out cost analyses of the models in real-world applications. It was shown that the efficiency of the Machine Learning (ML) models in reducing the costs of materials is relatively high, as they were capable of better predictions than the standard methods employed by the codes.

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JF - Engineering Structures

IS - Part B

M1 - 119150

ER -

Optimized punching shear design in steel fiber-reinforced slabs: machine learning vs. evolutionary prediction models

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