Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength
Compressive strength is the most essential mechanical characterization for concrete due to its crucial role in stating the design standards. Therefore, early, and accurate evaluation of concrete compressive strength minimizes efforts, costs, and time. In this study, we investigate the ability of art...
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my.um.eprints.357432023-11-08T11:03:29Z http://eprints.um.edu.my/35743/ Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength Hameed, Mohammed Majeed AlOmar, Mohamed Khalid Baniya, Wajdi Jaber AlSaadi, Mohammed Abdulhakim TA Engineering (General). Civil engineering (General) Compressive strength is the most essential mechanical characterization for concrete due to its crucial role in stating the design standards. Therefore, early, and accurate evaluation of concrete compressive strength minimizes efforts, costs, and time. In this study, we investigate the ability of artificial neural network (ANN) incorporated with principal component analyses (PCA) and cross-validation (CV) techniques to forecast the high-performance concrete (HPC) compression strength. The obtained results from the ANN-CVPCA model showed a good agreement between predicted and actual values. The proposed model provides high accuracy prediction of HPC compressive strength. It also provided a higher correlation coefficient (0.96) and a lower value of mean absolute error (3.43mpa), root mean square error (4.64mpa) and normalized root mean square error (0.13). Moreover, a sensitivity analysis was carried out to identify the most influential parameters and the simulated results showed that the superplasticizer, blast furnace slag, and cement parameters respectively have great effects on the compressive strength of HPC. The performance of the ANN-CVPCA model compared with other models published in previous studies and achieved the desired superiority and more stable predictions due to the existence of PCA and CV which play a significant role in increasing the generalization ability as well as avoiding redundant data and reducing the uncertainty in modeling outcomes. © 2021, The Author(s), under exclusive licence to Springer Nature Switzerland AG. Springer 2021-09 Article PeerReviewed Hameed, Mohammed Majeed and AlOmar, Mohamed Khalid and Baniya, Wajdi Jaber and AlSaadi, Mohammed Abdulhakim (2021) Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength. Asian Journal of Civil Engineering, 22 (6). pp. 1019-1031. ISSN 1563-0854, DOI https://doi.org/10.1007/s42107-021-00362-3 <https://doi.org/10.1007/s42107-021-00362-3>. 10.1007/s42107-021-00362-3 |
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TA Engineering (General). Civil engineering (General) Hameed, Mohammed Majeed AlOmar, Mohamed Khalid Baniya, Wajdi Jaber AlSaadi, Mohammed Abdulhakim Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength |
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Compressive strength is the most essential mechanical characterization for concrete due to its crucial role in stating the design standards. Therefore, early, and accurate evaluation of concrete compressive strength minimizes efforts, costs, and time. In this study, we investigate the ability of artificial neural network (ANN) incorporated with principal component analyses (PCA) and cross-validation (CV) techniques to forecast the high-performance concrete (HPC) compression strength. The obtained results from the ANN-CVPCA model showed a good agreement between predicted and actual values. The proposed model provides high accuracy prediction of HPC compressive strength. It also provided a higher correlation coefficient (0.96) and a lower value of mean absolute error (3.43mpa), root mean square error (4.64mpa) and normalized root mean square error (0.13). Moreover, a sensitivity analysis was carried out to identify the most influential parameters and the simulated results showed that the superplasticizer, blast furnace slag, and cement parameters respectively have great effects on the compressive strength of HPC. The performance of the ANN-CVPCA model compared with other models published in previous studies and achieved the desired superiority and more stable predictions due to the existence of PCA and CV which play a significant role in increasing the generalization ability as well as avoiding redundant data and reducing the uncertainty in modeling outcomes. © 2021, The Author(s), under exclusive licence to Springer Nature Switzerland AG. |
| format |
Article |
| author |
Hameed, Mohammed Majeed AlOmar, Mohamed Khalid Baniya, Wajdi Jaber AlSaadi, Mohammed Abdulhakim |
| author_facet |
Hameed, Mohammed Majeed AlOmar, Mohamed Khalid Baniya, Wajdi Jaber AlSaadi, Mohammed Abdulhakim |
| author_sort |
Hameed, Mohammed Majeed |
| title |
Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength |
| title_short |
Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength |
| title_full |
Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength |
| title_fullStr |
Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength |
| title_full_unstemmed |
Incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength |
| title_sort |
incorporation of artificial neural network with principal component analysis and cross-validation technique to predict high-performance concrete compressive strength |
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Springer |
| publishDate |
2021 |
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http://eprints.um.edu.my/35743/ |
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1783876631603970048 |
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13.18916 |