A New Feedback DE-ELM with Time Delay-Based EFSM Approach for Fault Prediction of Non-Linear Processes

Yuan Xu; Zi Qian Zhou; Qun Xiong Zhu

doi:10.1002/cjce.22246

A New Feedback DE-ELM with Time Delay-Based EFSM Approach for Fault Prediction of Non-Linear Processes

Yuan Xu, Zi Qian Zhou, Qun Xiong Zhu

Beijing University of Chemical Technology

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

Fault prediction is a significant issue for ensuring industrial process safety and reliability. In practical processes, due to complexity and non-linearity, this leads to many difficulties for process fault prediction. Aiming to improve the fault prediction accuracy in procedure-oriented systems, a new feedback differential evolution-optimized extreme learning machine (FDE-ELM) with a time delay-based extended finite state machine (TD-EFSM) approach is proposed. The proposed method is exemplified in the complicated Tennessee Eastman (TE) benchmark process. The results show that the new joint time-delay EFSM-based FDE-ELM shows superiority not only in modelling stability but also in detection sensitivity.

Original language	English
Pages (from-to)	1603-1612
Number of pages	10
Journal	Canadian Journal of Chemical Engineering
Volume	93
Issue number	9
DOIs	https://doi.org/10.1002/cjce.22246
Publication status	Published - 1 Sept 2015
Externally published	Yes

Keywords

DE-ELM
EFSM
Fault prediction
TDMI
TE process

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10.1002/cjce.22246

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title = "A New Feedback DE-ELM with Time Delay-Based EFSM Approach for Fault Prediction of Non-Linear Processes",

abstract = "Fault prediction is a significant issue for ensuring industrial process safety and reliability. In practical processes, due to complexity and non-linearity, this leads to many difficulties for process fault prediction. Aiming to improve the fault prediction accuracy in procedure-oriented systems, a new feedback differential evolution-optimized extreme learning machine (FDE-ELM) with a time delay-based extended finite state machine (TD-EFSM) approach is proposed. The proposed method is exemplified in the complicated Tennessee Eastman (TE) benchmark process. The results show that the new joint time-delay EFSM-based FDE-ELM shows superiority not only in modelling stability but also in detection sensitivity.",

keywords = "DE-ELM, EFSM, Fault prediction, TDMI, TE process",

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AU - Zhu, Qun Xiong

PY - 2015/9/1

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N2 - Fault prediction is a significant issue for ensuring industrial process safety and reliability. In practical processes, due to complexity and non-linearity, this leads to many difficulties for process fault prediction. Aiming to improve the fault prediction accuracy in procedure-oriented systems, a new feedback differential evolution-optimized extreme learning machine (FDE-ELM) with a time delay-based extended finite state machine (TD-EFSM) approach is proposed. The proposed method is exemplified in the complicated Tennessee Eastman (TE) benchmark process. The results show that the new joint time-delay EFSM-based FDE-ELM shows superiority not only in modelling stability but also in detection sensitivity.

AB - Fault prediction is a significant issue for ensuring industrial process safety and reliability. In practical processes, due to complexity and non-linearity, this leads to many difficulties for process fault prediction. Aiming to improve the fault prediction accuracy in procedure-oriented systems, a new feedback differential evolution-optimized extreme learning machine (FDE-ELM) with a time delay-based extended finite state machine (TD-EFSM) approach is proposed. The proposed method is exemplified in the complicated Tennessee Eastman (TE) benchmark process. The results show that the new joint time-delay EFSM-based FDE-ELM shows superiority not only in modelling stability but also in detection sensitivity.

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A New Feedback DE-ELM with Time Delay-Based EFSM Approach for Fault Prediction of Non-Linear Processes

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Keywords

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