Fault isolation for a complex decentralized waste water treatment facility

Decentralized waste water treatment facilities monitor many features that are complexly related. The ability to detect the onset of a fault and to identify variables accurately that have shifted because of the fault are vital to maintaining proper system operation and high quality produced water. Va...

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Veröffentlicht in:	Journal of the Royal Statistical Society Series C: Applied Statistics 2020-08, Vol.69 (4), p.931-951
Hauptverfasser:	Klanderman, Molly C., Newhart, Kathryn B., Cath, Tzahi Y., Hering, Amanda S.
Format:	Artikel
Sprache:	eng
Schlagworte:	Bayesian analysis Change agents Change detection Change point detection Decentralization Fault detection Fault isolation Fused lasso Medical diagnosis Multivariate analysis Multivariate statistical process monitoring Operators Original Articles Parameter estimation Parameter identification Regularization Retrospective monitoring Simulation Variables Wastewater treatment Water quality Water treatment
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container_end_page	951
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container_title	Journal of the Royal Statistical Society Series C: Applied Statistics
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creator	Klanderman, Molly C. Newhart, Kathryn B. Cath, Tzahi Y. Hering, Amanda S.
description	Decentralized waste water treatment facilities monitor many features that are complexly related. The ability to detect the onset of a fault and to identify variables accurately that have shifted because of the fault are vital to maintaining proper system operation and high quality produced water. Various multivariate methods have been proposed to perform fault detection and isolation, but the methods require data to be independent and identically distributed when the process is in control, and most require a distributional assumption. We propose a distribution-free retrospective change-point-detection method for auto-correlated and non-stationary multivariate processes. We detrend the data by using observations from an incontrol time period to account for expected changes due to external or user-controlled factors. Next, we perform the fused lasso, which penalizes differences in consecutive observations, to detect faults and to identify shifted variables. To account for auto-correlation, the regularization parameter is chosen by using an estimated effective sample size in the extended Bayesian information criterion. We demonstrate the performance of our method compared with a competitor in simulation. Finally, we apply our method to waste water treatment facility data with a known fault, and the variables identified by our proposed method are consistent with the operators' diagnosis of the fault's cause.
doi_str_mv	10.1111/rssc.12429
format	Article
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The ability to detect the onset of a fault and to identify variables accurately that have shifted because of the fault are vital to maintaining proper system operation and high quality produced water. Various multivariate methods have been proposed to perform fault detection and isolation, but the methods require data to be independent and identically distributed when the process is in control, and most require a distributional assumption. We propose a distribution-free retrospective change-point-detection method for auto-correlated and non-stationary multivariate processes. We detrend the data by using observations from an incontrol time period to account for expected changes due to external or user-controlled factors. Next, we perform the fused lasso, which penalizes differences in consecutive observations, to detect faults and to identify shifted variables. To account for auto-correlation, the regularization parameter is chosen by using an estimated effective sample size in the extended Bayesian information criterion. We demonstrate the performance of our method compared with a competitor in simulation. Finally, we apply our method to waste water treatment facility data with a known fault, and the variables identified by our proposed method are consistent with the operators' diagnosis of the fault's cause.</abstract><cop>Oxford</cop><pub>Wiley</pub><doi>10.1111/rssc.12429</doi><tpages>21</tpages></addata></record>
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source	Wiley Online Library Journals Frontfile Complete; EBSCOhost Business Source Complete; Oxford University Press Journals All Titles (1996-Current)
subjects	Bayesian analysis Change agents Change detection Change point detection Decentralization Fault detection Fault isolation Fused lasso Medical diagnosis Multivariate analysis Multivariate statistical process monitoring Operators Original Articles Parameter estimation Parameter identification Regularization Retrospective monitoring Simulation Variables Wastewater treatment Water quality Water treatment
title	Fault isolation for a complex decentralized waste water treatment facility
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