论文信息 - Comparison of statistical process monitoring methods: application to the Eastman challenge problem

Comparison of statistical process monitoring methods: application to the Eastman challenge problem

Abstract Multivariate statistical process control (MSPC) has been successfully applied to chemical procesess. In order to improve the performance of fault detection, two kinds of advanced methods, known as moving principal component analysis (MPCA) and DISSIM, have been proposed. In MPCA and DISSIM, an abnormal operation can be detected by monitoring the directions of principal components (PCs) and the degree of dissimilarity between data sets, respectively. Another important extension of MSPC was made by using multiscale PCA (MS-PCA). In the present work, the characteristics of several monitoring methods are investigated. The monitoring performances are compared with using simulated data obtained from the Tennessee Eastman process. The results show that the advanced methods can outperform the conventional method. Furthermore, the advantage of MPCA and DISSIM over conventional MSPC (cMSPC) and that of the multiscale method are combined, and the new methods known as MS-MPCA and MS-DISSIM are proposed.

[1] Weihua Li,et al. Recursive PCA for Adaptive Process Monitoring , 1999 .

[2] Keinosuke Fukunaga,et al. Application of the Karhunen-Loève Expansion to Feature Selection and Ordering , 1970, IEEE Trans. Computers.

[3] Thomas E. Marlin,et al. Multivariate statistical monitoring of process operating performance , 1991 .

[4] B. Bakshi. Multiscale PCA with application to multivariate statistical process monitoring , 1998 .

[5] J. Macgregor,et al. Monitoring batch processes using multiway principal component analysis , 1994 .

[6] John F. MacGregor,et al. Process monitoring and diagnosis by multiblock PLS methods , 1994 .

[7] E. F. Vogel,et al. A plant-wide industrial process control problem , 1993 .

[8] S. Wold,et al. Multi‐way principal components‐and PLS‐analysis , 1987 .

[9] Manabu Kano,et al. Dissimilarity of Process Data for Statistical Process Monitoring , 2000 .

[10] Thomas F. Edgar,et al. Identification of faulty sensors using principal component analysis , 1996 .

[11] Manabu Kano,et al. Process Monitoring Using Moving Principal Component Analysis. , 1999 .

[12] Barry M. Wise,et al. The process chemometrics approach to process monitoring and fault detection , 1995 .

[13] T. J. McAvov,et al. BASE CONTROL FOR THE TENNESSEE EASTMAN PROBLEM , 2001 .