Toward Developing A Machine Learning Model For The Prediction Of The Bearing Capacity Of The Square Concrete-Filled Steel Columns
Abstract
In this thesis project, based on studies analyzing the research, the thesis aims to
develop a machine learning model to predict the bearing capacity of concrete-filled
steel (CFST) columns by utilizing influential extreme gradient boosting (XGBoost)
for training with a dataset containing 253 data points. In the dataset used for the
machine learning model, there are a total of eleven that cover various geometric and
material properties including the shape of the CFST (shape), the width of square steel
pipe (B), depth of square steel pipe (H), where the diameter of round steel pipe is
exchanged equivalent to the width and depth of square steel pipe, column length ( L),
the wall thickness of steel pipe (t), concrete thickness (d), cylindrical compressive
strength of concrete (f'c), compressive strength of concrete prism (fck), yield strength
of steel (fy), and load eccentricity (e), the bearing capacity of the concrete-filled steel
columns (Nu). Features are divided into nine input variables, one category instance
variable, and one output variable. Machine learning model performance in estimating
the bearing capacity of concrete-filled steel columns using MAE, RMSE, and R2
values. Furthermore, when compared to other models, the model utilizing XGBoost
performs better than the performance derived from the stated formulae, highlighting
the usefulness of forecasting bearing capacity values.