Finding the Direction of Disturbance Propagation in a Chemical Process Using Transfer Entropy

Author

Bauer, Margret ; Cox, John W. ; Caveness, Michelle H. ; Downs, James J. ; Thornhill, Nina F.

Author_Institution

Dept. of Electron. & Electr. Eng., Univ. Coll. London

Volume

15

Issue

1

fYear

2007

Firstpage

12

Lastpage

21

Abstract

In continuous chemical processes, variations of process variables usually travel along propagation paths in the direction of the control path and process flow. This paper describes a data-driven method for identifying the direction of propagation of disturbances using historical process data. The novel concept is the application of transfer entropy, a method based on the conditional probability density functions that measures directionality of variation. It is sensitive to directionality even in the absence of an observable time delay. Its performance is studied in detail and default settings for the parameters in the algorithm are derived so that it can be applied in a large scale setting. Two industrial case studies demonstrate the method

Keywords

chemical industry; fault diagnosis; conditional probability density functions; continuous chemical process; direction of propagation; disturbance propagation; fault diagnosis; transfer entropy; Chemical processes; Chemical technology; Control systems; Electrical equipment industry; Entropy; Fault detection; Fault diagnosis; Large-scale systems; Probability density function; Process control; Causal map; control loop performance; digraph; fault diagnosis; kernel estimator; oscillation; plantwide disturbance; probability density function; process history; time series; transfer entropy;

fLanguage

English

Journal_Title

Control Systems Technology, IEEE Transactions on

Publisher

ieee

ISSN

1063-6536

Type

jour

DOI

10.1109/TCST.2006.883234

Filename

4039335