Quality Prediction and Yield Improvement in Process Manufacturing Based on Data Analytics

Quality management is important for maximizing yield in continuous-flow manufacturing. However, it is more difficult to manage quality in continuous-flow manufacturing than in discrete manufacturing because partial defects can significantly affect the quality of an entire lot of final product. In th...

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Bibliographic Details
Published in:Processes 2020-09, Vol.8 (9), p.1068
Main Authors: Jun, Ji-hye, Chang, Tai-Woo, Jun, Sungbum
Format: Article
Language:English
Subjects:
Algorithms
Artificial intelligence
Classification
Continuous flow
Data analysis
Data mining
Deep learning
Defects
Internet of Things
Labeling
Machine learning
Manufacturing
Neural networks
Powder metallurgy
Product quality
Quality management
Repair & maintenance
Semi-supervised learning
Sensors
Time series
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Summary:Quality management is important for maximizing yield in continuous-flow manufacturing. However, it is more difficult to manage quality in continuous-flow manufacturing than in discrete manufacturing because partial defects can significantly affect the quality of an entire lot of final product. In this paper, a comprehensive framework that consists of three steps is proposed to predict defects and improve yield by using semi-supervised learning, time-series analysis, and classification model. In Step 1, semi-supervised learning using both labeled and unlabeled data is applied to generate quality values. In addition, feature values are predicted in time-series analysis in Step 2. Finally, in Step 3, we predict quality values based on the data obtained in Step 1 and Step 2 and calculate yield values with the use of the predicted value. Compared to a conventional production plan, the suggested plan increases yield by up to 8.7%. The production plan proposed in this study is expected to contribute to not only the continuous manufacturing process but the discrete manufacturing process. In addition, it can be used in early diagnosis of equipment failure.
ISSN:2227-9717
2227-9717
DOI:10.3390/pr8091068