Real-Time Predictive Maintenance – Model-Based, Simulation-Based and Machine Learning Based Diagnosis

David Kaufmann; Florian Steffen Klück; Franz Wotawa; Iulia-Dana Nica; Hermann Felbinger; Adil Mukhtar; Petr Blaha; Matus Kozovsky; Zdenek Havranek; Martin Dosedel

doi:10.13052/rp-9788770226639

Real-Time Predictive Maintenance – Model-Based, Simulation-Based and Machine Learning Based Diagnosis

David Kaufmann, Florian Steffen Klück, Franz Wotawa, Iulia-Dana Nica, Hermann Felbinger, Adil Mukhtar, Petr Blaha, Matus Kozovsky, Zdenek Havranek, Martin Dosedel

Institute of Software Engineering and Artificial Intelligence (7160)

Publikation: Beitrag in Buch/Bericht/Konferenzband › Beitrag in Buch/Bericht › Begutachtung

Abstract

Predictive maintenance focuses on forecasting faulty or unwanted behaviour and defines appropriate countermeasures to be taken. Diagnosis, i.e., the detection of failures, the identification of faults, and repair provides useful foundations for predictive maintenance. In this article, we show how diagnosis, and in particular model-based, simulation-based and machine learning based diagnosis, can be used in practice. For this purpose, we introduce a simplified DC e-motor simulation model with the capability of fault injection to be used to show the efficiency of the introduced diagnosis methods based on the model’s behaviour. A simulation run of the system under test with pre-defined injected faults during runtime is used to validate the results obtained by the diagnosis methods. The results outline a promising application of these diagnosis methods for industrial applications, since each algorithm shows a time efficient and reliable diagnosis in relation to find the root cause of an observed faulty behaviour within the model. Further, the root cause analysis, performed with the introduced diagnosis methods, offers an excellent starting point for future development of self-adapting systems.

Originalsprache	englisch
Titel	Artificial Intelligence for Digitising Industry
Redakteure/-innen	Ovidiu Vermessen, Reiner John, Cristina De Luca, Marcello Coppola
Herausgeber (Verlag)	River Publishers
Kapitel	1.5
Seiten	63-81
ISBN (elektronisch)	9788770226639
ISBN (Print)	9788770226646
DOIs	https://doi.org/10.13052/rp-9788770226639
Publikationsstatus	Veröffentlicht - Sept. 2021

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10.13052/rp-9788770226639Lizenz: CC BY-NC 4.0

AI4DI - Künstliche Intelligenz für digitalisierende Industrie
Wotawa, F. (Teilnehmer (Co-Investigator))
1/05/19 → 31/12/22
Projekt: Forschungsprojekt

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Kaufmann, D., Klück, F. S., Wotawa, F., Nica, I.-D., Felbinger, H., Mukhtar, A., Blaha, P., Kozovsky, M., Havranek, Z., & Dosedel, M. (2021). Real-Time Predictive Maintenance – Model-Based, Simulation-Based and Machine Learning Based Diagnosis. in O. Vermessen, R. John, C. De Luca, & M. Coppola (Hrsg.), Artificial Intelligence for Digitising Industry (S. 63-81). River Publishers. https://doi.org/10.13052/rp-9788770226639

Real-Time Predictive Maintenance – Model-Based, Simulation-Based and Machine Learning Based Diagnosis. / Kaufmann, David; Klück, Florian Steffen; Wotawa, Franz et al.
Artificial Intelligence for Digitising Industry. Hrsg. / Ovidiu Vermessen; Reiner John; Cristina De Luca; Marcello Coppola. River Publishers, 2021. S. 63-81.

Publikation: Beitrag in Buch/Bericht/Konferenzband › Beitrag in Buch/Bericht › Begutachtung

Kaufmann, D, Klück, FS, Wotawa, F , Nica, I-D, Felbinger, H, Mukhtar, A, Blaha, P, Kozovsky, M, Havranek, Z & Dosedel, M 2021, Real-Time Predictive Maintenance – Model-Based, Simulation-Based and Machine Learning Based Diagnosis. in O Vermessen, R John, C De Luca & M Coppola (Hrsg.), Artificial Intelligence for Digitising Industry. River Publishers, S. 63-81. https://doi.org/10.13052/rp-9788770226639

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title = "Real-Time Predictive Maintenance – Model-Based, Simulation-Based and Machine Learning Based Diagnosis",

abstract = "Predictive maintenance focuses on forecasting faulty or unwanted behaviour and defines appropriate countermeasures to be taken. Diagnosis, i.e., the detection of failures, the identification of faults, and repair provides useful foundations for predictive maintenance. In this article, we show how diagnosis, and in particular model-based, simulation-based and machine learning based diagnosis, can be used in practice. For this purpose, we introduce a simplified DC e-motor simulation model with the capability of fault injection to be used to show the efficiency of the introduced diagnosis methods based on the model{\textquoteright}s behaviour. A simulation run of the system under test with pre-defined injected faults during runtime is used to validate the results obtained by the diagnosis methods. The results outline a promising application of these diagnosis methods for industrial applications, since each algorithm shows a time efficient and reliable diagnosis in relation to find the root cause of an observed faulty behaviour within the model. Further, the root cause analysis, performed with the introduced diagnosis methods, offers an excellent starting point for future development of self-adapting systems.",

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author = "David Kaufmann and Kl{\"u}ck, {Florian Steffen} and Franz Wotawa and Iulia-Dana Nica and Hermann Felbinger and Adil Mukhtar and Petr Blaha and Matus Kozovsky and Zdenek Havranek and Martin Dosedel",

note = "This work is conducted under the framework of the ECSEL AI4DI “Artificial Intelligence for Digitising Industry” project. The project has received funding from the ECSEL Joint Undertaking (JU) under grant agreement No 826060. The JU receives support from the European Union{\^a}A{\u }Z{\' }s Horizon 2020 research and innovation programme and Germany, Austria, Czech Republic, Italy, Latvia, Belgium, Lithuania, France, Greece, Finland, Norway. The work was co-funded by grants of Ministry of Education, Youth and Sports of the Czech Republic, by the Austrian Federal Ministry of Transport, Innovation and Technology (BMVIT) under the program “ICT of the Future” between May 2019 and April 2022 (more information can be retrieved from https://iktderzukunft.at/en/). The work was also supported by the infrastructure of RICAIP that has received funding from the European Union{\textquoteright}s Horizon 2020 research and innovation programme under grant agreement No 857306 and from Ministry of Education, Youth and Sports under OP RDE grant agreement No CZ.02.1.01/0.0/0.0/17_043/0010085.",

year = "2021",

month = sep,

doi = "10.13052/rp-9788770226639",

language = "English",

isbn = "9788770226646",

pages = "63--81",

editor = "Ovidiu Vermessen and Reiner John and {De Luca}, Cristina and Marcello Coppola",

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publisher = "River Publishers",

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AU - Kaufmann, David

AU - Klück, Florian Steffen

AU - Wotawa, Franz

AU - Nica, Iulia-Dana

AU - Felbinger, Hermann

AU - Mukhtar, Adil

AU - Blaha, Petr

AU - Kozovsky, Matus

AU - Havranek, Zdenek

AU - Dosedel, Martin

N1 - This work is conducted under the framework of the ECSEL AI4DI “Artificial Intelligence for Digitising Industry” project. The project has received funding from the ECSEL Joint Undertaking (JU) under grant agreement No 826060. The JU receives support from the European UnionâA ̆Z ́s Horizon 2020 research and innovation programme and Germany, Austria, Czech Republic, Italy, Latvia, Belgium, Lithuania, France, Greece, Finland, Norway. The work was co-funded by grants of Ministry of Education, Youth and Sports of the Czech Republic, by the Austrian Federal Ministry of Transport, Innovation and Technology (BMVIT) under the program “ICT of the Future” between May 2019 and April 2022 (more information can be retrieved from https://iktderzukunft.at/en/). The work was also supported by the infrastructure of RICAIP that has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 857306 and from Ministry of Education, Youth and Sports under OP RDE grant agreement No CZ.02.1.01/0.0/0.0/17_043/0010085.

PY - 2021/9

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N2 - Predictive maintenance focuses on forecasting faulty or unwanted behaviour and defines appropriate countermeasures to be taken. Diagnosis, i.e., the detection of failures, the identification of faults, and repair provides useful foundations for predictive maintenance. In this article, we show how diagnosis, and in particular model-based, simulation-based and machine learning based diagnosis, can be used in practice. For this purpose, we introduce a simplified DC e-motor simulation model with the capability of fault injection to be used to show the efficiency of the introduced diagnosis methods based on the model’s behaviour. A simulation run of the system under test with pre-defined injected faults during runtime is used to validate the results obtained by the diagnosis methods. The results outline a promising application of these diagnosis methods for industrial applications, since each algorithm shows a time efficient and reliable diagnosis in relation to find the root cause of an observed faulty behaviour within the model. Further, the root cause analysis, performed with the introduced diagnosis methods, offers an excellent starting point for future development of self-adapting systems.

AB - Predictive maintenance focuses on forecasting faulty or unwanted behaviour and defines appropriate countermeasures to be taken. Diagnosis, i.e., the detection of failures, the identification of faults, and repair provides useful foundations for predictive maintenance. In this article, we show how diagnosis, and in particular model-based, simulation-based and machine learning based diagnosis, can be used in practice. For this purpose, we introduce a simplified DC e-motor simulation model with the capability of fault injection to be used to show the efficiency of the introduced diagnosis methods based on the model’s behaviour. A simulation run of the system under test with pre-defined injected faults during runtime is used to validate the results obtained by the diagnosis methods. The results outline a promising application of these diagnosis methods for industrial applications, since each algorithm shows a time efficient and reliable diagnosis in relation to find the root cause of an observed faulty behaviour within the model. Further, the root cause analysis, performed with the introduced diagnosis methods, offers an excellent starting point for future development of self-adapting systems.

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KW - AI based predictive maintenance

KW - digital twin

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KW - simulation-based diagnosis

KW - reliability

KW - validation

KW - fault model

KW - fault injection

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M3 - Chapter

SN - 9788770226646

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EP - 81

BT - Artificial Intelligence for Digitising Industry

A2 - Vermessen, Ovidiu

A2 - John, Reiner

A2 - De Luca, Cristina

A2 - Coppola, Marcello

PB - River Publishers

ER -

Real-Time Predictive Maintenance – Model-Based, Simulation-Based and Machine Learning Based Diagnosis

Abstract

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AI4DI - Künstliche Intelligenz für digitalisierende Industrie

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