| dc.description.abstract | Maximizing the life of machine is one of a manufacturer's key concerns. Machine
failures might result in production line interruptions and expensive repairs. Therefore,
manufacturing industries need solutions to save maintenance expenses, boost
equipment uptime, and enhance availability. A more efficient and economical
maintenance solution is offered by predictive maintenance. Predictive maintenance is
not based on the equipment's real state, which might result in unnecessary and wasteful.
Maintenance should be predictable to save time, costs as well as labor. To accomplish
this, it is crucial to appropriately classify all machine failure cases in advance. This
thesis proposes the Extreme Gradient Boost (XGBoost) model of machine learning
combined with Synthetic Minority Oversampling Technique – Tomek data balancing
technique to minimize error classification. Additionally, the outcomes are evaluated in
comparison to a variety of machine learning approaches, including Gaussian Naive
Bayes (GNB), Support Vector Machine (SVM), Logistics Regression (LR). The
proposed method achieve a result of 96.6% accuracy and over 50.72 % F1 score,
which demonstrating that the suggested strategies outperform other indicated
techniques in terms of predictive ability. | en_US |
