Optimized machine‐learning methods for predicting the long‐term viscoelastic behavior of heterogeneous concrete mixtures

Long‐term creep compliance is one of the most important mechanical properties for evaluating the long‐term behavior of concrete structures. This paper aims to optimize machine‐learning models to predict this viscoelastic property. The most relevant dataset available in the literature is considered,...

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Bibliographic Details
Published in:Structural concrete : journal of the FIB 2023-12, Vol.24 (6), p.7466-7481
Main Authors: Nguyen‐Sy, Tuan, Thai, Minh‐Quan, Vu, Minh‐Ngoc
Format: Article
Language:English
Subjects:
Compliance
Concrete structures
Datasets
heterogeneous concrete mixtures
Influents
long‐term creep compliance
Machine learning
Mechanical properties
Model accuracy
viscoelastic
Viscoelasticity
XGBoost
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Summary:Long‐term creep compliance is one of the most important mechanical properties for evaluating the long‐term behavior of concrete structures. This paper aims to optimize machine‐learning models to predict this viscoelastic property. The most relevant dataset available in the literature is considered, cleaned, and preprocessed to optimize the outcome. The advanced XGBoost model, which is to be the most effective shallow machine‐learning model for modeling tabular datasets, is employed in this study to maximize model accuracy. Short‐term creep compliances of a given sample at typical ages are used as input features to model the long‐term creep compliance of concrete. This approach outperforms standard machine‐learning approaches that do not include short‐term creep as an input feature. Indeed, the short‐term behavior of concrete strongly influents its long‐term one. The optimized machine model presented herein is accurate and useful for practical applications. It uses input features that are easy to obtain to predict long‐term creep compliance up to several decades, which is difficult and expensive to measure.
ISSN:1464-4177
1751-7648
DOI:10.1002/suco.202300246