Ensemble Machine Learning-Based Approach for Predicting of FRP–Concrete Interfacial Bonding

Developments in fiber-reinforced polymer (FRP) composite materials have created a huge impact on civil engineering techniques. Bonding properties of FRP led to its wide usage with concrete structures for interfacial bonding. FRP materials show great promise for rehabilitation of existing infrastruct...

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Bibliographic Details
Published in:Mathematics (Basel) 2022-01, Vol.10 (2), p.231
Main Authors: Kim, Bubryur, Lee, Dong-Eun, Hu, Gang, Natarajan, Yuvaraj, Preethaa, Sri, Rathinakumar, Arun Pandian
Format: Article
Language:English
Subjects:
Accuracy
Algorithms
Artificial intelligence
bond strength
Bonding strength
boosting algorithms
Comparative studies
Concrete
Concrete structures
ensemble methods
Experiments
Fiber reinforced concretes
Fiber reinforced plastics
Fiber reinforced polymers
Fracture mechanics
Fuzzy logic
Gene expression
Genetic algorithms
Histograms
Interfacial bonding
Machine learning
Material properties
Mathematics
Model testing
Neural networks
Performance evaluation
Performance measurement
Polymer matrix composites
Polymers
Prediction models
Regression analysis
Rehabilitation
shear bond test
Shear strength
Shear tests
Structural engineering
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Summary:Developments in fiber-reinforced polymer (FRP) composite materials have created a huge impact on civil engineering techniques. Bonding properties of FRP led to its wide usage with concrete structures for interfacial bonding. FRP materials show great promise for rehabilitation of existing infrastructure by strengthening concrete structures. Existing machine learning-based models for predicting the FRP–concrete bond strength have not attained maximum performance in evaluating the bond strength. This paper presents an ensemble machine learning approach capable of predicting the FRP–concrete interfacial bond strength. In this work, a dataset holding details of 855 single-lap shear tests on FRP–concrete interfacial bonds extracted from the literature is used to build a bond strength prediction model. Test results hold data of different material properties and geometrical parameters influencing the FRP–concrete interfacial bond. This study employs CatBoost algorithm, an improved ensemble machine learning approach used to accurately predict bond strength of FRP–concrete interface. The algorithm performance is compared with those of other ensemble methods (i.e., histogram gradient boosting algorithm, extreme gradient boosting algorithm, and random forest). The CatBoost algorithm outperforms other ensemble methods with various performance metrics (i.e., lower root mean square error (2.310), lower covariance (21.8%), lower integral absolute error (8.8%), and higher R-square (96.1%)). A comparative study is performed between the proposed model and best performing bond strength prediction models in the literature. The results show that FRP–concrete interfacial bonding can be effectively predicted using proposed ensemble method.
ISSN:2227-7390
2227-7390
DOI:10.3390/math10020231