Evaluation of machine learning techniques for capacity prediction of cold-formed steel beams subjected to bending

Q4 Engineering Rakenteiden Mekaniikka Pub Date : 2024-08-09 DOI:10.23998/rm.144743
Ayman Hamdallah, Antti Niemi, Ahmed Abdullah
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引用次数: 0

Abstract

Stiffened Cold-Formed Steel (CFS) sections often exhibit intricate nonlinear behaviors attributable to factors such as flexure effects and excessive slenderness. Traditional design methodologies, including the direct stiffness method, may inadequately capture these subtleties, potentially resulting in conservative or suboptimal designs. This study aimed to evaluate the performance of various machine learning algorithms, including simple and ensemble models, to predict the bending capacity of stiffened and unstiffened cold-formed beams in pure bending. A parametric study was conducted based on verified finite element analysis, and the machine learning algorithms were utilized to develop a unified capacity prediction method. The performance of six classical machine learning algorithms and four ensemble models were compared. The findings demonstrate that ensemble models, including AdaBoost, Gradient Boosting, Random Forest, and Extra Trees, outperform simple machine learning models in predicting the bending capacity of CFS beams. Moreover, introducing the stacking ensemble technique, using six different base models selectively, resulted in better performance than the individual baseline models. The approach addressed the nonlinearity pattern in the dataset caused by the flexure effect and excessive slenderness. The study suggests that adopting the proposed numerical and machine learning techniques could be a reliable method for predicting the structural behaviour and conducting cost-effective design of CFS beams, compared to the traditional analytical methods.
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机器学习技术对受弯冷弯型钢承载力预测的评估
加劲冷弯型钢 (CFS) 截面通常会因挠曲效应和过长的细长度等因素而表现出复杂的非线性行为。包括直接刚度法在内的传统设计方法可能无法充分捕捉这些微妙之处,从而可能导致保守或次优设计。本研究旨在评估各种机器学习算法的性能,包括简单模型和集合模型,以预测加劲和非加劲冷弯梁在纯弯曲情况下的抗弯能力。在验证有限元分析的基础上进行了参数研究,并利用机器学习算法开发了统一的承载力预测方法。比较了六种经典机器学习算法和四种集合模型的性能。研究结果表明,在预测 CFS 梁的抗弯能力方面,包括 AdaBoost、梯度提升、随机森林和 Extra Trees 在内的集合模型优于简单的机器学习模型。此外,引入堆叠集合技术,有选择地使用六个不同的基础模型,比单个基线模型的性能更好。该方法解决了数据集中由挠曲效应和过度细长引起的非线性模式。研究表明,与传统的分析方法相比,采用拟议的数值和机器学习技术是预测 CFS 梁结构行为和进行经济有效设计的可靠方法。
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来源期刊
Rakenteiden Mekaniikka
Rakenteiden Mekaniikka Engineering-Mechanical Engineering
CiteScore
0.50
自引率
0.00%
发文量
2
审稿时长
16 weeks
期刊最新文献
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