A new fault classification approach applied to Tennessee Eastman benchmark process

被引:39
|
作者
D'Angelo, Marcos F. S. V. [1 ]
Palhares, Reinaldo M. [2 ]
Camargos Filho, Murilo C. O. [1 ]
Maia, Renato D. [1 ]
Mendes, Joao B. [1 ]
Ekel, Petr Ya. [3 ]
机构
[1] Univ Estadual Montes Claros, Dept Comp Sci, Av Rui Braga Sn, BR-39401089 Montes Claros, Brazil
[2] Univ Fed Minas Gerais, Dept Elect Engn, Av Antonio Carlos 6627, BR-31270901 Belo Horizonte, MG, Brazil
[3] Pontificia Univ Catolica Minas Gerais, Grad Program Elect Engn, Av Dom Jose Gaspar 500, BR-30535610 Belo Horizonte, MG, Brazil
来源
APPLIED SOFT COMPUTING | 2016年 / 49卷
关键词
Fault detection and isolation; Fuzzy/Bayesian approach; Immune/neural formulation; Tennessee Eastman benchmark process; ARTIFICIAL IMMUNE-SYSTEM; QUANTITATIVE MODEL; EXPERT-SYSTEM; DIAGNOSIS; IDENTIFICATION; OBSERVERS; ALGORITHM; DESIGN;
D O I
10.1016/j.asoc.2016.08.040
中图分类号
TP18 [人工智能理论];
学科分类号
081104 ; 0812 ; 0835 ; 1405 ;
摘要
This study presents a data-based methodology for fault detection and isolation in dynamic systems based on fuzzy/Bayesian approach for change point detection associated with a hybrid immune/neural formulation for pattern classification applied to the Tennessee Eastman benchmark process. The fault is detected when a change occurs in the signals from the sensors and classified into one of the classes by the immune/neural formulation. The change point detection system is based on fuzzy set theory associated with the MetropolisHastings algorithm and the classification system, the main contribution of this paper is based on a representation which combines the ClonALG algorithm with the Kohonen neural network. (C) 2016 Elsevier B.V. All rights reserved.
引用
收藏
页码:676 / 686
页数:11
相关论文
共 50 条
  • [1] Fault classification on Tennessee Eastman process: PCA and SVM
    Jing, Chen
    Gao, Xin
    Zhu, Xiangping
    Lang, Shuangqing
    2014 INTERNATIONAL CONFERENCE ON MECHATRONICS AND CONTROL (ICMC), 2014, : 2194 - 2197
  • [2] Fault detection in the Tennessee Eastman benchmark process with nonlinear singular spectrum analysis
    Krishnannair, S.
    Aldrich, C.
    IFAC PAPERSONLINE, 2017, 50 (01): : 8005 - 8010
  • [3] The Tennessee Eastman problem as a process monitoring benchmark
    Howell, J
    Chen, J
    Zhang, J
    (SAFEPROCESS'97): FAULT DETECTION, SUPERVISION AND SAFETY FOR TECHNICAL PROCESSES 1997, VOLS 1-3, 1998, : 223 - 228
  • [4] PLS modelling and fault detection on the Tennessee Eastman benchmark
    Wilson, DJH
    Irwin, GW
    INTERNATIONAL JOURNAL OF SYSTEMS SCIENCE, 2000, 31 (11) : 1449 - 1457
  • [5] Adversarial Attacks and Defenses in Fault Detection and Diagnosis: A Comprehensive Benchmark on the Tennessee Eastman Process
    Pozdnyakov, Vitaliy
    Kovalenko, Aleksandr
    Makarov, Ilya
    Drobyshevskiy, Mikhail
    Lukyanov, Kirill
    IEEE OPEN JOURNAL OF THE INDUSTRIAL ELECTRONICS SOCIETY, 2024, 5 : 428 - 440
  • [6] Towards distributed diagnosis of the Tennessee Eastman process benchmark
    Chen, J
    Howell, J
    CONTROL ENGINEERING PRACTICE, 2002, 10 (09) : 971 - 987
  • [7] A New Multi-Objective Decision-Making Approach Applied to the Tennessee Eastman Process
    Tidriri, Khaoula
    Tiplica, Teodor
    Chatti, Nizar
    Verron, Sylvain
    IFAC PAPERSONLINE, 2018, 51 (24): : 1212 - 1219
  • [8] Bayesian Classifiers Applied to the Tennessee Eastman Process
    dos Santos, Edimilson Batista
    Ebecken, Nelson F. F.
    Hruschka, Estevam R., Jr.
    Elkamel, Ali
    Madhuranthakam, Chandra M. R.
    RISK ANALYSIS, 2014, 34 (03) : 485 - 497
  • [9] Generalized transformer in fault diagnosis of Tennessee Eastman process
    Lei Zhang
    Zhihuan Song
    Qinghua Zhang
    Zhiping Peng
    Neural Computing and Applications, 2022, 34 : 8575 - 8585
  • [10] Generalized transformer in fault diagnosis of Tennessee Eastman process
    Zhang, Lei
    Song, Zhihuan
    Zhang, Qinghua
    Peng, Zhiping
    Neural Computing and Applications, 2022, 34 (11) : 8575 - 8585
12345