Journal
IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS
Volume 64, Issue 5, Pages 4315-4324Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TIE.2017.2668986
Keywords
Aluminum electrolytic production; fault diagnosis; kernel partial least squares (KPLS); optimal preference matrix (OPM); Tennessee Eastman (TE) process
Categories
Funding
- National Science Foundation (NSF) [ECCS 1053717]
- National Natural Science Foundation of China [51374268, 51375520, 51404051, 61503050]
- Application Development Major Projects of Chongqing [cstc2013yykfC0034]
- Training Plan of Science and Technology Talent of Chongqing [cstc2013kjrc-qnrc40008]
- Program for Innovation Team Building at Institutions of Higher Education [KJTD201324]
- Achievement Transfer Program of the Institutions of Higher Education in Chongqing [KJZH14218]
- Chongqing Research Program of Basic Research
- Frontier Technology [cstc2015jcyjBX0099]
- Div Of Electrical, Commun & Cyber Sys
- Directorate For Engineering [1053717] Funding Source: National Science Foundation
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In the standard kernel partial least squares (KPLS), the mapped data in the feature space need to be centralized before extraction of newscore vectors. However, each vector of the centralized variables is often uniformly distributed, and some original features that can reflect the contribution of each variable to fault diagnosis might be lost. As a result, it might lead to misleading interpretations of the principal components and to increasing the false alarm rate for fault detection. To cope with these difficulties, a novel data-driven framework using KPLS based on an optimal preference matrix (OPM) is presented in this paper. In fault monitoring, an OPM is proposed to change the distribution of the variable and to readjust the eigenvalues of the covariance matrix. To obtain the OPM, the objective function can be determined in terms of the squared prediction error and Hotelling's T-squared (T2) statistics. Two optimization algorithms, genetic algorithm and particle swarm optimization algorithm, are extended to maximize effectiveness of the OPM. Compared with traditional methods, the proposed method can overcome the drawback of original features loss of the centralized mapped data in the feature subspace and improve the accuracy of fault diagnosis. Also, few extra computation costs are needed in fault detection. Extensive experimental results on both the Tennessee Eastman benchmark process and the case study of the aluminum electrolytic production process give credible fault diagnosis.
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