A novel multimode processmonitoring method integrating LCGMMwith modified LFDA

doi:10.1016/j.cjche.2015.09.007

摘要/Abstract

摘要： Complex processes often work with multiple operation regions, it is critical to develop effective monitoring approaches to ensure the safety of chemical processes. In this work, a discriminant local consistency Gaussianmixture model (DLCGMM) for multimode process monitoring is proposed for multimode process monitoring by integrating LCGMMwith modified local Fisher discriminant analysis (MLFDA).Different fromFisher discriminant analysis (FDA) that aims to discover the global optimal discriminant directions, MLFDA is capable of uncovering multimodality and local structure of the data by exploiting the posterior probabilities of observations within clusters calculated fromthe results of LCGMM. This may enableMLFDA to capturemoremeaningful discriminant information hidden in the high-dimensional multimode observations comparing to FDA. Contrary to most existing multimode process monitoring approaches, DLCGMMperforms LCGMMandMFLDA iteratively, and the optimal subspaces with multi-Gaussianity and the optimal discriminant projection vectors are simultaneously achieved in the framework of supervised and unsupervised learning. Furthermore, monitoring statistics are established on each cluster that represents a specific operation condition and two global Bayesian inference-based faultmonitoring indexes are established by combining with all themonitoring results of all clusters. The efficiency and effectiveness of the proposed method are evaluated through UCI datasets, a simulated multimode model and the Tennessee Eastman benchmark process.

关键词: Multimode process monitoring, Discriminant local consistency Gaussian, mixture model, Modified local Fisher discriminant analysis, Global fault detection index, Tennessee Eastman process

Abstract: Complex processes often work with multiple operation regions, it is critical to develop effective monitoring approaches to ensure the safety of chemical processes. In this work, a discriminant local consistency Gaussianmixture model (DLCGMM) for multimode process monitoring is proposed for multimode process monitoring by integrating LCGMMwith modified local Fisher discriminant analysis (MLFDA).Different fromFisher discriminant analysis (FDA) that aims to discover the global optimal discriminant directions, MLFDA is capable of uncovering multimodality and local structure of the data by exploiting the posterior probabilities of observations within clusters calculated fromthe results of LCGMM. This may enableMLFDA to capturemoremeaningful discriminant information hidden in the high-dimensional multimode observations comparing to FDA. Contrary to most existing multimode process monitoring approaches, DLCGMMperforms LCGMMandMFLDA iteratively, and the optimal subspaces with multi-Gaussianity and the optimal discriminant projection vectors are simultaneously achieved in the framework of supervised and unsupervised learning. Furthermore, monitoring statistics are established on each cluster that represents a specific operation condition and two global Bayesian inference-based faultmonitoring indexes are established by combining with all themonitoring results of all clusters. The efficiency and effectiveness of the proposed method are evaluated through UCI datasets, a simulated multimode model and the Tennessee Eastman benchmark process.

Key words: Multimode process monitoring, Discriminant local consistency Gaussian, mixture model, Modified local Fisher discriminant analysis, Global fault detection index, Tennessee Eastman process

Shijin Ren, Zhihuan Song, Maoyun Yang, Jianguo Ren . A novel multimode processmonitoring method integrating LCGMMwith modified LFDA[J]. Chinese Journal of Chemical Engineering, 2015, 23(12): 1970-1980.

Shijin Ren, Zhihuan Song, Maoyun Yang, Jianguo Ren . A novel multimode processmonitoring method integrating LCGMMwith modified LFDA[J]. Chin.J.Chem.Eng., 2015, 23(12): 1970-1980.

参考文献

[1] Y.J.Wang, M.X. Jia, Z.Z. Mao,Weak fault monitoring method for batch process based on multi-model SDKPCA, Chemom. Intell. Lab. Syst. 118 (2012) 1-12.

[2] Z.Q. Ge, Z.H. Song, F.R. Gao, Review of recent research on data-based process monitoring, Ind. Eng. Chem. Res. 52 (2013) 3543-3562.

[3] I.K. Ben,M. Limam, C.Weihs, Variablewindowadaptive kernel principal component analysis for nonlinear nonstationary process monitoring, Comput. Ind. Eng. 61 (2011) 437-466.

[4] J. Yu, A nonlinear kernel Gaussian mixture model based inferential monitoring approach for fault detection and diagnosis of chemical processes, Chem. Eng. Sci. 68 (2012) 506-519.

[5] X. Xiang, H.B. Shi,Multimode processmonitoring based on fuzzy C-means in locality preserving projection subspace, Chin. J. Chem. Eng. 20 (6) (2012) 1174-1179.

[6] C.D. Tong, A. Palazoglu, X.F. Yan, An adaptive multimode process monitoring strategy based on mode clustering and mode unfolding, J. Process Control 23 (2013) 1497-1507.

[7] X.G. Deng, X.M. Tian, Sparse kernel locality preserving projection and its application in nonlinear Process Fault Detection, Chin. J. Chem. Eng. 21 (2) (2013) 163-170.

[8] J.L. Liu, D. Cai, X.F. He, Gaussian mixture model with local consistency, Proceedings of the 24th Conference on Artificial Intelligence, Atlanta, Georgia, USA, 2010.

[9] Y. Zhang, Enhanced statistical analysis of nonlinear processes using KPCA, KICA and SVM, Chem. Eng. Sci. 64 (2009) 801-811.

[10] P. Teppola, S.P. Mujunen, P. Minkkinen, Adaptive fuzzy C-means clustering in process monitoring, Chemom. Intell. Lab. Syst. 45 (1999) 23-38.

[11] Z.B. Zhu, Z.H. Song, Fault diagnosis based on imbalance modified kernel Fisher discriminant analysis, Chem. Eng. Res. Des. 88 (8) (2010) 936-951.

[12] G.R., S.Y. Liu, J.D. Shao, Fault diagnosis by locality preserving discriminant analysis and its kernel variation, Comput. Chem. Eng. 49 (2013) 105-113.

[13] J. Camacho, J. Picó, Multi-phase principal component analysis for batch processes modelling, Chemom. Intell. Lab. Syst. 81 (2006) 127-136.

[14] S.J. Zhang, Z.L. Wang, F. Qian, FS-SVDD based on LTSA and its application to chemical process monitoring, Chin. J. Chem. Eng. 61 (8) (2010) 1894-1901.

[15] J. Yu, Localized Fisher discriminant analysis based complex chemical process monitoring, AICHE J. 57 (7) (2011) 1817-1828.

[16] B.R. Bakshi, Multiscale PCA with application to multivariate statistical process monitoring, AICHE J. 44 (1998) 1596-1610.

[17] C.H. Zhao, Y. Yao, F.R.Gao, F.L.Wang, Statistical analysis and onlinemonitoring formultimode processwith between-mode transitions,Chem. Eng. Sci. 65 (2010) 5961-5975.

[18] D.H. Hwang, C.H. Han, Real-time monitoring for a process with multiple operating modes, Control. Eng. Pract. 7 (1999) 891-902.

[19] S.C. Tan, C.P. Lim, M.V.C. Rao, A hybrid neural network model for rule generation and its application to process fault detection and diagnosis, Eng. Appl. Artif. Intell. 20 (2007) 203-213.

[20] S.J. Qin, Recursive PLS algorithm for adaptive data monitoring, Comput. Chem. Eng. 22 (1998) 503-514.

[21] X.Q. Liu, U. Kruger, T. Littler,Moving window kernel PCA for adaptive monitoring of nonlinear processes, Chemom. Intell. Lab. Syst. 96 (2009) 132-143.

[22] Z.Q. Ge, Z.H. Song, Online monitoring of nonlinear multiple mode processes based on adaptive local model approach, Control. Eng. Pract. 16 (2008) 1427-1437.

[23] Z.Q. Ge, Z.H. Song, Mixture Bayesian regularization method of PPCA for multimode process monitoring, AICHE J. 56 (2010) 2838-2849.

[24] X.Z. Xu, L. Xie, S.Q. Wang, Multi-mode process monitoring method based on PCA mixture model, Comput. Electr. Eng. 62 (3) (2011) 743-752.

[25] Y.X. Ma, H.B. Shi, Multimode process monitoring based on aligned mixture factor analysis, Ind. Eng. Chem. Res. 53 (2) (2013) 786-799.

[26] J.F. Shen, J.J. Bu, B. Ju, T. Jiang, H. Wu, L.J. Li, Refining Gaussian mixture model based on enhanced manifold learning, Neurocomputing 87 (2012) 19-25.

[27] J. Yu, A nonlinear kernel Gaussian mixture model based inferential monitoring approach for fault detection and diagnosis of chemical processes, Chem. Eng. Sci. 68 (1) (2012) 506-519.

[28] Z.Q. Ge, Z.H. Song, Online batch process monitoring based on multi-model ICA-PCA method, Proceedings of the 7th World Congress on Intelligent Control and Automation, Chongqing, China 2008, pp. 260-264.

[29] S.J. Zhao, J. Zhang, Y.M. Xu, Monitoring of processes with multiple operation modes through multiple principal component analysis models, Ind. Eng. Chem. Res. 43 (2004) 7025-7035.

[30] J.B. Yu, Hidden Markov models combining local and global information for nonlinear and multimodal process monitoring, J. Process Control 20 (2010) 344-359.

[31] S. Miyamoto, M. Mukaidono, Fuzzy c-means as a regularization and maximum entropy approach, Proceedings of the IFSA 1997, Prague, Czech Republic, 1997.

[32] Z.B. Zhu, Z.H. Song, A. Palazoglu, Process pattern construction andmulti-modemonitoring, J. Process Control 22 (1) (2011) 247-262.

[33] X.G. Deng, X.M. Tian, Multimode process fault detection using local neighborhood similarity analysis, Chin. J. Chem. Eng. 22 (11-12) (2014) 1260-1267.

[34] H.H. Ma, Y. Hu, H.B. Shi, A novel local neighborhood standardization strategy and its application in fault detection of multimode processes, Chemom. Intell. Lab. Syst. 118 (2012) 287-300.

[35] Y.J. Liu, T. Chen, Y. Yao, Nonlinear process monitoring and fault isolation using extended maximum variance unfolding, J. Process Control 24 (2014) 880-891.

[36] B. Song, Y.X. Ma, H.B. Shi, Multimode process monitoring using improved dynamic neighborhood preserving embedding, Chemom. Intell. Lab. Syst. 135 (2014) 17-30.

[37] L.L. Jia, Process monitoring with global-local preserving projections, Ind. Eng. Chem. Res. 53 (18) (2014) 7696-7705.

[38] J. Yu, S.J. Qin, Multimode process monitoring with Bayesian inference-based finite Gaussian mixture models, AICHE J. 54 (2008) 1811-1829.

[39] J. Yu, S.J. Qin, Multiway Gaussian mixture model based multiphase batch process monitoring, Ind. Eng. Chem. Res. 48 (2009) 8585-8594.

[40] S. Roweis, L. Saul, Nonlinear dimensionality reduction by locally linear embedding, Science 29 (5500) (2000) 2323-2326.

[41] W.H. Yang, D.Q. Dai, H. Yan, Feature extraction and uncorrelated discriminant analysis for high-dimensional data, IEEE Trans. Knowl. Data Eng. 20 (2008) 601-614.

[42] Z.Q. Ge, F.R. Gao, Z.H. Song, Two-dimensional bayesian monitoring method for nonlinear multimode process, Chem. Eng. Sci. 66 (2011) 5173-5183.

[43] P.R. Lyman, C. Georgakist, Plant-wide control of the Tennessee Eastman problem, Comput. Chem. Eng. 19 (3) (1995) 321-331.

[44] Y.S. Ng, R. Srinivasan, An adjoined multi-model approach for monitoring batch and transient operations, Comput. Chem. Eng. 33 (4) (2009) 887-902.