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Traditional and machine-learning numerical models for partial-strength extended endplate connections

Traditional and machine-learning numerical models for partial-strength extended endplate connections
Traditional and machine-learning numerical models for partial-strength extended endplate connections
Steel joints with partial strength extended endplate are widely used in conventional construction and in regions with low to moderate seismicity. It was shown recently that many of the existing analytical, mechanical and empirical models fail in accurately predicting the connection behavior, yielding inconsistent predictions with large errors exceeding ±100%. The accurate characterization of the moment-rotation response of steel joints is necessary for conducting accurate structural analyses and to achieve efficient and robust designs. Accordingly, a recently collated large experimental database is used to develop more accurate numerical models. Traditional approaches, such as multivariate regression analysis, as well as machine-learning approaches, such as neural networks and decision trees, are employed to reach this objective and demonstrate the differences between the two approaches. This study outlines the procedure used to identify the significant features controlling the connections key response parameters (elastic stiffness, post-yield stiffness and plastic strength) and to regress or train the mathematical models. The models’ performance is then evaluated considering the observed error metrics and the advantages and disadvantages of each model. The new models demonstrated an improved accuracy, compared to currently available alternatives.
2366-2557
541-549
Springer Cham
Xu, Hongchao
3eeca76b-d5f1-493c-95a1-348c37ff4aa2
Ding, Zizhou
d2f57f07-1ba2-4fce-8eca-f3cfae32dd6a
Elkady, Ahmed
8e55de89-dff4-4f84-90ed-6af476e328a8
Mazzolani, F.M.
Piluso, V.
Nastri, E.
Formisano, A.
Xu, Hongchao
3eeca76b-d5f1-493c-95a1-348c37ff4aa2
Ding, Zizhou
d2f57f07-1ba2-4fce-8eca-f3cfae32dd6a
Elkady, Ahmed
8e55de89-dff4-4f84-90ed-6af476e328a8
Mazzolani, F.M.
Piluso, V.
Nastri, E.
Formisano, A.

Xu, Hongchao, Ding, Zizhou and Elkady, Ahmed (2024) Traditional and machine-learning numerical models for partial-strength extended endplate connections. Mazzolani, F.M., Piluso, V., Nastri, E. and Formisano, A. (eds.) In Proceedings of the 11th International Conference on Behaviour of Steel Structures in Seismic Areas : STESSA 2024. vol. 1, Springer Cham. pp. 541-549 . (doi:10.1007/978-3-031-62884-9_47).

Record type: Conference or Workshop Item (Paper)

Abstract

Steel joints with partial strength extended endplate are widely used in conventional construction and in regions with low to moderate seismicity. It was shown recently that many of the existing analytical, mechanical and empirical models fail in accurately predicting the connection behavior, yielding inconsistent predictions with large errors exceeding ±100%. The accurate characterization of the moment-rotation response of steel joints is necessary for conducting accurate structural analyses and to achieve efficient and robust designs. Accordingly, a recently collated large experimental database is used to develop more accurate numerical models. Traditional approaches, such as multivariate regression analysis, as well as machine-learning approaches, such as neural networks and decision trees, are employed to reach this objective and demonstrate the differences between the two approaches. This study outlines the procedure used to identify the significant features controlling the connections key response parameters (elastic stiffness, post-yield stiffness and plastic strength) and to regress or train the mathematical models. The models’ performance is then evaluated considering the observed error metrics and the advantages and disadvantages of each model. The new models demonstrated an improved accuracy, compared to currently available alternatives.

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Published date: 3 July 2024

Identifiers

Local EPrints ID: 499198
URI: http://eprints.soton.ac.uk/id/eprint/499198
DOI: doi:10.1007/978-3-031-62884-9_47
ISSN: 2366-2557
PURE UUID: 43cc60c7-4f77-4659-9c9b-3eca7d1f245d
ORCID for Ahmed Elkady: ORCID iD orcid.org/0000-0002-1214-6379

Catalogue record

Date deposited: 11 Mar 2025 17:57
Last modified: 12 Mar 2025 02:59

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Contributors

Author: Hongchao Xu
Author: Zizhou Ding
Author: Ahmed Elkady ORCID iD
Editor: F.M. Mazzolani
Editor: V. Piluso
Editor: E. Nastri
Editor: A. Formisano

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