An online sparse estimation-based classification approach for real-time monitoring in advanced manufacturing processes fromheterogeneous sensor data.
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| Title: | An online sparse estimation-based classification approach for real-time monitoring in advanced manufacturing processes fromheterogeneous sensor data. |
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| Authors: | Bastani, Kaveh1 (AUTHOR), Rao, Prahalad K.2 (AUTHOR), Kong, Zhenyu (James)1 (AUTHOR) zkong@vt.edu |
| Source: | IIE Transactions. 2016, Vol. 48 Issue 7, p579-598. 20p. 1 Black and White Photograph, 1 Diagram, 6 Charts, 3 Graphs. |
| Subjects: | Manufacturing processes, Advanced planning & scheduling, Sparse approximations, Fibers -- Design & construction, Machine learning, Discriminant analysis |
| Abstract: | The objective of this work is to realize real-time monitoring of process conditions in advanced manufacturing using multiple heterogeneous sensor signals. To achieve this objective we propose an approach invoking the concept of sparse estimation called online sparse estimation-based classification (OSEC). The novelty of the OSEC approach is in representing data from sensor signals as an underdetermined linear system of equations and subsequently solving the underdetermined linear system using a newly developed greedy Bayesian estimation method. We apply the OSEC approach to two advanced manufacturing scenarios, namely, a fused filament fabrication additive manufacturing process and an ultraprecision semiconductor chemical-mechanical planarization process. Using the proposed OSEC approach, process drifts are detected and classifiedwith higher accuracy comparedwith popular machine learning techniques. Process drifts were detected and classified with a fidelity approaching 90% (F-score) using OSEC. In comparison, conventional signal analysis techniques--e.g., neural networks, support vector machines, quadratic discriminant analysis, naïve Bayes--were evaluated with F-score in the range of 40% to 70%. [ABSTRACT FROM AUTHOR] |
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| Database: | Engineering Source |
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