Learning models of plant behavior for anomaly detection and condition monitoring

A.J. Brown; V.M. Catterson; M. Fox; D. Long; S.D.J. McArthur

Learning models of plant behavior for anomaly detection and condition monitoring

A.J. Brown, V.M. Catterson, M. Fox, D. Long, S.D.J. McArthur

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4 Citations (Scopus)

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Abstract

Providing engineers and asset managers with a too] which can diagnose faults within transformers can greatly assist decision making on such issues as maintenance, performance and safety. However, the onus has always been on personnel to accurately decide how serious a problem is and how urgently maintenance is required. In dealing with the large volumes of data involved, it is possible that faults may not be noticed until serious damage has occurred. This paper proposes the integration of a newly developed anomaly detection technique with an existing diagnosis system. By learning a Hidden Markov Model of healthy transformer behavior, unexpected operation, such as when a fault develops, can be flagged for attention. Faults can then be diagnosed using the existing system and maintenance scheduled as required, all at a much earlier stage than would previously have been possible.

Original language	English
Pages (from-to)	61-67
Number of pages	7
Journal	Engineering Intelligent Systems for Electrical Engineering and Communications
Volume	15
Issue number	2
Publication status	Published - Jun 2007

Keywords

cooperative systems
decision support systems
Hidden Markov models
intelligent systems
learning systems
monitoring
partial discharges
power systems
power transformers

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Learning Models of Plant Behaviour for Anomaly Detection and Condition Monitoring 1 Submitted manuscript, 502 KB

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title = "Learning models of plant behavior for anomaly detection and condition monitoring",

abstract = "Providing engineers and asset managers with a too] which can diagnose faults within transformers can greatly assist decision making on such issues as maintenance, performance and safety. However, the onus has always been on personnel to accurately decide how serious a problem is and how urgently maintenance is required. In dealing with the large volumes of data involved, it is possible that faults may not be noticed until serious damage has occurred. This paper proposes the integration of a newly developed anomaly detection technique with an existing diagnosis system. By learning a Hidden Markov Model of healthy transformer behavior, unexpected operation, such as when a fault develops, can be flagged for attention. Faults can then be diagnosed using the existing system and maintenance scheduled as required, all at a much earlier stage than would previously have been possible.",

keywords = "cooperative systems, decision support systems, Hidden Markov models, intelligent systems, learning systems, monitoring, partial discharges, power systems, power transformers",

author = "A.J. Brown and V.M. Catterson and M. Fox and D. Long and S.D.J. McArthur",

note = "Also presented at: International Conference on Intelligent Systems Applications to Power Systems, Toki Messe, Niigata, 5-8 Nov 2007.",

year = "2007",

month = jun,

language = "English",

volume = "15",

pages = "61--67",

journal = "Engineering Intelligent Systems for Electrical Engineering and Communications",

issn = "1472-8915",

publisher = "CRL Publishing",

number = "2",

}

TY - JOUR

T1 - Learning models of plant behavior for anomaly detection and condition monitoring

AU - Brown, A.J.

AU - Catterson, V.M.

AU - Fox, M.

AU - Long, D.

AU - McArthur, S.D.J.

N1 - Also presented at: International Conference on Intelligent Systems Applications to Power Systems, Toki Messe, Niigata, 5-8 Nov 2007.

PY - 2007/6

Y1 - 2007/6

N2 - Providing engineers and asset managers with a too] which can diagnose faults within transformers can greatly assist decision making on such issues as maintenance, performance and safety. However, the onus has always been on personnel to accurately decide how serious a problem is and how urgently maintenance is required. In dealing with the large volumes of data involved, it is possible that faults may not be noticed until serious damage has occurred. This paper proposes the integration of a newly developed anomaly detection technique with an existing diagnosis system. By learning a Hidden Markov Model of healthy transformer behavior, unexpected operation, such as when a fault develops, can be flagged for attention. Faults can then be diagnosed using the existing system and maintenance scheduled as required, all at a much earlier stage than would previously have been possible.

AB - Providing engineers and asset managers with a too] which can diagnose faults within transformers can greatly assist decision making on such issues as maintenance, performance and safety. However, the onus has always been on personnel to accurately decide how serious a problem is and how urgently maintenance is required. In dealing with the large volumes of data involved, it is possible that faults may not be noticed until serious damage has occurred. This paper proposes the integration of a newly developed anomaly detection technique with an existing diagnosis system. By learning a Hidden Markov Model of healthy transformer behavior, unexpected operation, such as when a fault develops, can be flagged for attention. Faults can then be diagnosed using the existing system and maintenance scheduled as required, all at a much earlier stage than would previously have been possible.

KW - cooperative systems

KW - decision support systems

KW - Hidden Markov models

KW - intelligent systems

KW - learning systems

KW - monitoring

KW - partial discharges

KW - power systems

KW - power transformers

M3 - Article

SN - 1472-8915

VL - 15

SP - 61

EP - 67

JO - Engineering Intelligent Systems for Electrical Engineering and Communications

JF - Engineering Intelligent Systems for Electrical Engineering and Communications

IS - 2

ER -

Learning models of plant behavior for anomaly detection and condition monitoring

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