An explainable prediction framework for engineering problems: case studies in reinforced concrete members modeling

Tahmassebi, A; Motamedi, M; Alavi, AH; Gandomi, AH

An explainable prediction framework for engineering problems: case studies in reinforced concrete members modeling

Tahmassebi, A Motamedi, M Alavi, AH Gandomi, AH

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Publisher:: Emerald
Publication Type:: Journal Article
Citation:: Engineering Computations: international journal for computer-aided engineering and software, 2022, 39, (2), pp. 609-626
Issue Date:: 2022-01-01

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Field	Value	Language
dc.contributor.author	Tahmassebi, A
dc.contributor.author	Motamedi, M
dc.contributor.author	Alavi, AH
dc.contributor.author	Gandomi, AH
dc.date.accessioned	2023-03-20T02:01:16Z
dc.date.available	2023-03-20T02:01:16Z
dc.date.issued	2022-01-01
dc.identifier.citation	Engineering Computations: international journal for computer-aided engineering and software, 2022, 39, (2), pp. 609-626
dc.identifier.issn	0264-4401
dc.identifier.issn	1758-7077
dc.identifier.uri	http://hdl.handle.net/10453/167687
dc.description.abstract	Purpose: Engineering design and operational decisions depend largely on deep understanding of applications that requires assumptions for simplification of the problems in order to find proper solutions. Cutting-edge machine learning algorithms can be used as one of the emerging tools to simplify this process. In this paper, we propose a novel scalable and interpretable machine learning framework to automate this process and fill the current gap. Design/methodology/approach: The essential principles of the proposed pipeline are mainly (1) scalability, (2) interpretibility and (3) robust probabilistic performance across engineering problems. The lack of interpretibility of complex machine learning models prevents their use in various problems including engineering computation assessments. Many consumers of machine learning models would not trust the results if they cannot understand the method. Thus, the SHapley Additive exPlanations (SHAP) approach is employed to interpret the developed machine learning models. Findings: The proposed framework can be applied to a variety of engineering problems including seismic damage assessment of structures. The performance of the proposed framework is investigated using two case studies of failure identification in reinforcement concrete (RC) columns and shear walls. In addition, the reproducibility, reliability and generalizability of the results were validated and the results of the framework were compared to the benchmark studies. The results of the proposed framework outperformed the benchmark results with high statistical significance. Originality/value: Although, the current study reveals that the geometric input features and reinforcement indices are the most important variables in failure modes detection, better model can be achieved with employing more robust strategies to establish proper database to decrease the errors in some of the failure modes identification.
dc.language	English
dc.publisher	Emerald
dc.relation.ispartof	Engineering Computations: international journal for computer-aided engineering and software
dc.relation.isbasedon	10.1108/EC-02-2021-0096
dc.rights	info:eu-repo/semantics/restrictedAccess
dc.rights	‘This article is (2022c) Emerald Group Publishing and permission has been granted for this version to appear here (http://doi.org/10.1108/EC-02-2021-0096). Emerald does not grant permission for this article to be further copied/distributed or hosted elsewhere without the express permission from Emerald Group Publishing Limited.'
dc.subject	0905 Civil Engineering, 0913 Mechanical Engineering, 0915 Interdisciplinary Engineering
dc.subject.classification	Applied Mathematics
dc.title	An explainable prediction framework for engineering problems: case studies in reinforced concrete members modeling
dc.type	Journal Article
utslib.citation.volume	39
utslib.for	0905 Civil Engineering
utslib.for	0913 Mechanical Engineering
utslib.for	0915 Interdisciplinary Engineering
pubs.organisational-group	/University of Technology Sydney
pubs.organisational-group	/University of Technology Sydney/Faculty of Engineering and Information Technology
utslib.copyright.status	in_progress	*
pubs.consider-herdc	false
dc.date.updated	2023-03-20T02:01:15Z
pubs.issue	2
pubs.publication-status	Published
pubs.volume	39
utslib.citation.issue	2

Abstract:

Purpose: Engineering design and operational decisions depend largely on deep understanding of applications that requires assumptions for simplification of the problems in order to find proper solutions. Cutting-edge machine learning algorithms can be used as one of the emerging tools to simplify this process. In this paper, we propose a novel scalable and interpretable machine learning framework to automate this process and fill the current gap. Design/methodology/approach: The essential principles of the proposed pipeline are mainly (1) scalability, (2) interpretibility and (3) robust probabilistic performance across engineering problems. The lack of interpretibility of complex machine learning models prevents their use in various problems including engineering computation assessments. Many consumers of machine learning models would not trust the results if they cannot understand the method. Thus, the SHapley Additive exPlanations (SHAP) approach is employed to interpret the developed machine learning models. Findings: The proposed framework can be applied to a variety of engineering problems including seismic damage assessment of structures. The performance of the proposed framework is investigated using two case studies of failure identification in reinforcement concrete (RC) columns and shear walls. In addition, the reproducibility, reliability and generalizability of the results were validated and the results of the framework were compared to the benchmark studies. The results of the proposed framework outperformed the benchmark results with high statistical significance. Originality/value: Although, the current study reveals that the geometric input features and reinforcement indices are the most important variables in failure modes detection, better model can be achieved with employing more robust strategies to establish proper database to decrease the errors in some of the failure modes identification.

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http://hdl.handle.net/10453/167687