Application of Basic Machine-Learning Classifiers for Automatic Anomaly Detection in Shewhart Control Charts

Aleksander Woźniak; Klaudia  Krawiec; Roger Książek

doi:10.7494/dmms.2024.18.6345

Authors

Aleksander Woźniak AGH University of Krakow, Faculty of Energy and Fuels
Klaudia Krawiec AGH University of Krakow, Faculty of Management
Roger Książek AGH University of Krakow, Faculty of Management

DOI:

https://doi.org/10.7494/dmms.2024.18.6345

Abstract

In today’s dynamic technological environment, innovation plays a crucial role – especially for manufacturing enterprises that constantly strive to improve the quality of their products. This article examines the quality-management issue in a company producing car rims. It was identified that real-time quality control can sometimes be unreliable due to controller fatigue, leading to erroneous data interpretation or delayed responses to deviations in the production process. The study aimed to investigate the possibility of eliminating or significantly reducing these errors by employing a tool that is based on artificial intelligence. The article covers the preparation of training data, the training of classifiers, and the evaluation
of their effectiveness in analyzing control charts in real time. The adopted hypothesis assumes that machine-learning classifiers can be effective methods of support for quality controllers. The research began with collecting measurement data from the machine and dividing it into training and test sets. The obtained results were evaluated using standard quality measures for machine-learning models. The results showed that the use of artificial intelligence can bring significant benefits in improving quality supervision in the production process of car rims.

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Application of Basic Machine-Learning Classifiers for Automatic Anomaly Detection in Shewhart Control Charts

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