Enhancing Cascade Quality Prediction Method in Handling Imbalanced Dataset Using Synthetic Minority Over-Sampling Technique
Assessing the production process primarily revolves around quality. When dealing with a basic manufacturing pro-cess, quality can be easily anticipated. However, as manufacturing processes grow in complexity, it has been discov-ered through prior studies that directly predicting the quality of an in...
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Published in | Industrial Engineering & Management Systems Vol. 22; no. 4; pp. 389 - 398 |
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Main Authors | , |
Format | Journal Article |
Language | English |
Published |
대한산업공학회
01.12.2023
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Subjects | |
Online Access | Get full text |
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Summary: | Assessing the production process primarily revolves around quality. When dealing with a basic manufacturing pro-cess, quality can be easily anticipated. However, as manufacturing processes grow in complexity, it has been discov-ered through prior studies that directly predicting the quality of an intricate production system becomes challenging. This is due to the interdependency between each stage of manufacturing, where the outcomes of preceding stages impact subsequent processes. To address this issue, the Cascade Quality Prediction Method (CQPM) was developed. However, as this method employed a classification algorithm, CQPM cannot be directly applied when dealing with datasets that lack target variables for prediction or when the distribution of classes is imbalanced. This study aimed to improve the effectiveness of the CQPM in the context of multistage manufacturing. To achieve this, Hotelling’s T2 and the Synthetic Minority Over-sampling Technique (SMOTE) algorithm were incorporated during the data prepara-tion phase, especially when dealing with imbalanced class distributions and missing target variables. The results demonstrated that the inclusion of Hotelling’s T2 allowed for the application of classification algorithms. By combin-ing the CQPM approach with a random forest classifier and the SMOTE algorithm, notable improvements were ob-served in the model’s performance. The enhanced data pre-processing techniques led to impressive metric values, including 99.95% accuracy, 93.75% G-Mean, and 96.76% F-Measure. These findings indicate the potential of the proposed model framework to accurately predict quality in multistage manufacturing systems. KCI Citation Count: 0 |
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ISSN: | 1598-7248 2234-6473 |
DOI: | 10.7232/iems.2023.22.4.389 |