Subspace monitoring based on full variable information

doi:10.11949/j.issn.0438-1157.20141618

CIESC Journal ›› 2015, Vol. 66 ›› Issue (4): 1395-1401.DOI: 10.11949/j.issn.0438-1157.20141618

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Subspace monitoring based on full variable information

LÜ Xiaotiao, SONG Bing, TAN Shuai, SHI Hongbo

Key Laboratory of Advanced Control and Optimization for Chemical Processes of Ministry of Education, East China University of Science and Technology, Shanghai 200237, China

Received:2014-10-27 Revised:2015-01-07 Online:2015-04-05 Published:2015-04-05
Supported by:
supported by the National Natural Science Foundation of China (61374140, 61403072).

基于全变量信息的子空间监控方法

吕小条, 宋冰, 谭帅, 侍洪波

华东理工大学化工过程先进控制和优化技术教育部重点实验室, 上海 200237

通讯作者: 侍洪波
作者简介:吕小条(1989-),女,硕士研究生。
基金资助:
国家自然科学基金项目(61374140);国家自然科学基金青年科学基金项目(61403072)。

Abstract

Abstract:

Since data collected from chemical processes always have high dimensions, modeling directly can be very complex. PCA can extract main features of the original data and obtain a more compact representation. However, the traditional PCA process monitoring scheme may cause information loss, since it only preserves principal components with large variance, which will greatly affect the performance of process monitoring. To handle this problem, a novel subspace monitoring method based on full variable information was proposed. Firstly, Based on the similarity level between each variable and principal component subspace (PCS) or residual subspace (RS), the original data space was divided into three low-dimensional subspaces, which preserved the whole process variables. Thus it could use the process information better. Secondly, the monitoring models were established respectively in each subspace, and then the Bayesian inference was introduced to integrate monitoring results of the subspaces. Finally, the feasibility and effectiveness of the FVI method were illustrated through a numerical example and the Tennessee Eastman process.

Key words: chemical process systems, subspace, information loss, monitoring model, numerical analysis

摘要：

实际化工过程采集得到的数据往往维度较高,直接建模比较复杂。主元分析(principal component analysis,PCA)方法可以提取原始数据主要特征,得到低维数据,但传统的PCA过程监控方法仅保留了方差较大的主元,会造成信息缺失,这将大大影响过程监控性能。针对这一问题,提出了一种新的基于全变量信息(full variable information,FVI)的子空间监控方法。首先,依据每个变量与主元空间(principal component subspace,PCS)和残差空间(residual subspace,RS)相似性的高低,将原始数据空间划分为3个维度较低的子空间,3个子空间保存了全部过程变量,可以更充分地利用过程信息。其次,在每个子空间中,分别建立监控模型,并利用贝叶斯推断整合子空间的监控结果。最后,通过数值仿真及Tennessee Eastman(TE)过程仿真研究验证FVI方法的有效性。

关键词: 化工过程系统, 子空间, 信息缺失, 监控模型, 数值分析

CLC Number:

TP277

LÜ Xiaotiao, SONG Bing, TAN Shuai, SHI Hongbo. Subspace monitoring based on full variable information[J]. CIESC Journal, 2015, 66(4): 1395-1401.

吕小条, 宋冰, 谭帅, 侍洪波. 基于全变量信息的子空间监控方法[J]. 化工学报, 2015, 66(4): 1395-1401.

References 22

[1]	Song Bing (宋冰), Ma Yuxin (马玉鑫), Fang Yongfeng (方永锋), Shi Hongbo (侍洪波). Fault detection for chemical process based on LSNPE method [J]. CIESC Journal (化工学报), 2014, 65 (2): 620-627
[2]	Zhang Ni (张妮), Tian Xuemin (田学民), Cai Lianfang (蔡连芳). Non-linear process fault detection method based on RISOMAP [J]. CIESC Journal (化工学报), 2013, 64 (6): 2125-2130
[3]	Kim D S, Lee I B. Process monitoring based on probabilistic PCA [J]. Chemometrics and Intelligent Laboratory Systems, 2003, 67: 109-123
[4]	Wang Xun, Kruger Uwe, Lennox Barry. Recursive partial least squares algorithms for monitoring complex industrial processes [J]. Control Engineering Practice, 2003, 11: 613-632
[5]	Kruger Uwe, Dimitriadis Grigorios. Diagnosis of process faults in chemical systems using a local partial least squares approach [J]. American Institute of Chemical Engineers, 2008, 54: 2581-2596
[6]	Ge Zhiqiang. Improved two-level monitoring system for plant-wide processes [J]. Chemometrics and Intelligent Laboratory Systems, 2014, 132: 141-151
[7]	Qin S J. Statistical process monitoring: basics and beyond [J]. Journal of Chemometrics, 2003, 17: 480-502
[8]	Tong Chudong, Song Yu,Yan Xuefeng. Distributed statistical process monitoring based on four-subspace construction and Bayesian inference [J]. Industrial and Engineering Chemistry Research, 2013, 52 (29): 9897-9907
[9]	Ge Zhiqiang, Zhang Muguang, Song Zhihuan. Nonlinear process monitoring based on linear subspace and Bayesian inference [J]. Journal of Process Control, 2010, 20: 676-688
[10]	Ge Zhiqiang, Gao Furong, Song Zhihuan. Two-dimensional Bayesian monitoring method for nonlinear multimode processes [J]. Chemical Engineering Science, 2011, 66: 5173-5183
[11]	Ge Zhiqiang, Song Zhihuan. Distributed PCA model for plant-wide process monitoring [J]. Industrial and Engineering Chemistry Research, 2013, 52: 1947-1957
[12]	Zhang Muguang (张沐光), Song Zhihuan (宋执环). Subspace fault detection method based on independent component contribution [J].Control Theory and Applications (控制理论与应用), 2010, 27: 296-302
[13]	Zhang Yingwei, Chai Tianyou, Li Zhiming, Yang Chunyu. Modeling and monitoring of dynamic processes [J]. IEEE Transactions on Neural Networks and Learning Systems, 2012, 23 (2): 277-284
[14]	Jiang Qingchao, Yan Xuefeng, Zhao Weixiang. Fault detection and diagnosis in chemical processes using sensitive principal component analysis [J]. Industrial and Engineering Chemistry Research, 2013, 52 (4): 1635-1644
[15]	Lv Zhaomin, Jiang Qingchao, Yan Xuefeng. Batch process monitoring based on multi-subspace multi-way principal component analysis and time series Bayesian inference [J]. Industrial and Engineering Chemistry Research, 2014, 53 (15): 6457-6466
[16]	Noriah M, Ian T. Variable Selection and interpretation of covariance principal components [J]. Communications in Statistics - Simulation and Computation, 2001, 30 (2): 339-354
[17]	Bjorck A, Golub G. Numerical methods for computing angles between linear subspaces [J].Mathematics of Computation, 1973, 27: 579-594
[18]	Zhu P, Knyazev A V. Angles between subspaces and their tangents [J]. Journal of Numerical Mathematics, 2013, 21 (4): 325-340
[19]	Bishop C M. Pattern Recognition and Machine Learning [M]. Springer, 2006: 272-279
[20]	Downs J J, Vogel E F. A plant-wide industrial process control problem [J]. Computers and Chemical Engineering, 1993, 17 (3): 245-255
[21]	Ricker N L. Optimal steady-state operation of the Tennessee Eastman challenge process [J]. Computers and Chemical Engineering, 1995, 19 (9): 949-959
[22]	Wang J, He Q P. Multivariate statistical process monitoring based on statistics pattern analysis [J].Industrial and Engineering Chemistry Research, 2010, 49 (17): 7858-7869

Subspace monitoring based on full variable information

基于全变量信息的子空间监控方法

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