Abstract
In this paper, an intelligent modeling approach is presented to predict the shear strength of the internal reinforced concrete (RC) beam‐column joints and used to analyze the sensitivity of the influence factors on the shear strength. The proposed approach is established based on the famous boosting‐family ensemble machine learning (ML) algorithms, i.e., gradient boosting regression tree (GBRT), which generates a strong predictive model by integrating several weak predictors, which are obtained by the well‐known individual ML algorithms, e.g., DT, ANN, and SVM. The strong model is boosted as each weak predictor has its own weight in the final combination according to the performance. Compared with the conventional mechanical‐driven shear strength models, e.g., the well‐known modified compression field theory (MCFT), the proposed model can avoid the complicated derivation process of shear mechanism and calibration of the involved empirical parameters; thus, it provides a more convenient, fast, and robust alternative way for predicting the shear strength of the internal RC joints. To train and test the GBRT model, a total of 86 internal RC joint specimens are collected from the literatures, and four traditional ML models and the MCFT model are also employed as comparisons. The results indicate that the GBRT model is superior to both the traditional ML models and MCFT model, as its degree‐of‐fitting is the highest and the predicting dispersion is the lowest. Finally, the model is used to investigate the influences of different parameters on the shear strength of the internal RC joint, and the sensitivity and importance of the corresponding parameters are obtained.
Highlights
Reinforced concrete (RC) beam-column joint or connection is one of the most critical and vulnerable components in RC structures. e failure of the RC beam-column joints could seriously affect the overall safety of the structures
Apart from the experimental and numerical studies, numerous theoretical models were proposed to evaluate the performance of the RC beam-column joints, for instance, Advances in Civil Engineering the well-known modified compression field theory (MCFT) [4], the strut-and-tie method (STM) [5], etc. ese models are derived based on the shear mechanisms of fundamental RC elements and can be widely used to evaluate the behavior of any type of shear-dominated RC members, including the beam-column joints [6]
We aim to develop a gradient boosting regression tree (GBRT)-based intelligent method for predicting the shear strength of the RC beam-column joints and make comparisons between the proposed data-driven model and some traditional machine learning (ML)-based models as well as the conventional mechanical-driven MCFT model
Summary
Reinforced concrete (RC) beam-column joint or connection is one of the most critical and vulnerable components in RC structures. e failure of the RC beam-column joints could seriously affect the overall safety of the structures. E failure of the RC beam-column joints could seriously affect the overall safety of the structures It will suffer from the shear failure if there are insufficient transverse reinforcements and/or the material properties are deteriorated due to the aging effects. E experimental study is the most direct and classical way, which can be traced back to 1970s [1] It is costly in both time and money and difficult to operate. E numerical simulation, e.g., finite element method (FEM), is widely adopted for its low cost [2, 3] It usually has several simplifications and some of the mechanisms are hard to be reflected in the FEM framework, e.g., multistress state behavior, shear behavior, and interfacial bond-slip behavior. A detailed review of the theoretical and empirical models for the RC joints can be found in [7]
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