A Model-based Execution Framework for Interpreting Control Software

Bianca Wiesmayr; Alois Zoitl; Antonio Garmendia; Manuel Wimmer

doi:10.1109/ETFA45728.2021.9613716

A Model-based Execution Framework for Interpreting Control Software

Bianca Wiesmayr
, Alois Zoitl
, Antonio Garmendia
, Manuel Wimmer

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

Abstract

Industrial standards define domain-specific languages that are frequently used for developing control software. For instance, IEC 61499 standardizes a graphical modeling language that includes a platform-independent application model. The application is composed of Function Blocks. A runtime can execute the model by implementing the semantics that is described in the standard in natural language. By defining an interpreter for IEC 61499 models, we can directly execute them without prior code generation. This enables providing feedback directly on the model level. We present an interpreter for Basic Function Blocks, which encapsulate a state-based Execution Control Chart. An existing EMF meta-model for IEC 61499 was extended with an operational semantics implemented in Java and Xtend. The test cases are defined either in Java or as an interface model. Such a model is standardized in IEC 61499 as Service Sequences. We evaluate our interpreter by executing the Basic Function Blocks that are defined in the standard and compare our results to those of the open-source runtime 4diac FORTE. As a practical use case, we show how developers can use the interpreter for unit testing self-defined Basic Function Blocks.

Originalsprache	Englisch
Titel	ETFA 2021- IEEE 26th International Conference on Emerging Technologies and Factory Automation, September 7-10, 2021, Vasteras, Sweden, virtual event
Verlag	IEEE
Seiten	1-8
Seitenumfang	8
ISBN (elektronisch)	9781728129891
ISBN (Print)	978-1-7281-2989-1
DOIs	https://doi.org/10.1109/ETFA45728.2021.9613716
Publikationsstatus	Veröffentlicht - Dez. 2021

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Dieser Output leistet einen Beitrag zu folgendem(n) Ziel(en) für nachhaltige Entwicklung

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202017 Embedded Systems
102002 Augmented Reality
102006 Computer Supported Cooperative Work (CSCW)
102015 Informationssysteme
102020 Medizinische Informatik
102022 Softwareentwicklung
102034 Cyber-Physical Systems
201132 Computational Engineering
201305 Verkehrstechnik
207409 Navigationssysteme
502032 Qualitätsmanagement
502050 Wirtschaftsinformatik
503015 Fachdidaktik Technische Wissenschaften

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Digital Transformation

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10.1109/ETFA45728.2021.9613716

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paper

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Christian Doppler Laboratory for Mastering Variability in Software-intensive Cyber-physical Production Systems (CDL VaSiCS)
Bauer, P. (Forscher*in), Fadhlillah, H. (Forscher*in), Gutierrez, A. (Forscher*in), Kutsia, E. (Forscher*in), Sharma, S. (Forscher*in), Sonnleithner, L. (Forscher*in), Unterdechler, M. (Forscher*in), Rabiser, R. (Projektleiter*in) & Zoitl, A. (Projektleiter*in)
01.02.2021 → 31.01.2028
Projekt: Geförderte Forschung › CDG - Christian Doppler Forschungsgesellschaft
Christian Doppler Laboratory for Model-Integrated Smart Production
Eisenberg, M. (Forscher*in), Gemeinhardt, F. (Forscher*in), Govindasami, H. S. (Forscher*in), Jayaraman, R. (Forscher*in), Mitter, A. (Forscher*in), Sindelar, R. (Forscher*in), Sint, S. (Forscher*in), Taspinar, B. (Forscher*in) & Wimmer, M. (Projektleiter*in)
01.01.2017 → 31.12.2023
Projekt: Geförderte Forschung › CDG - Christian Doppler Forschungsgesellschaft

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@inproceedings{2ff97bde56f24b5686e70a572c1fc011,

title = "A Model-based Execution Framework for Interpreting Control Software",

abstract = "Industrial standards define domain-specific languages that are frequently used for developing control software. For instance, IEC 61499 standardizes a graphical modeling language that includes a platform-independent application model. The application is composed of Function Blocks. A runtime can execute the model by implementing the semantics that is described in the standard in natural language. By defining an interpreter for IEC 61499 models, we can directly execute them without prior code generation. This enables providing feedback directly on the model level. We present an interpreter for Basic Function Blocks, which encapsulate a state-based Execution Control Chart. An existing EMF meta-model for IEC 61499 was extended with an operational semantics implemented in Java and Xtend. The test cases are defined either in Java or as an interface model. Such a model is standardized in IEC 61499 as Service Sequences. We evaluate our interpreter by executing the Basic Function Blocks that are defined in the standard and compare our results to those of the open-source runtime 4diac FORTE. As a practical use case, we show how developers can use the interpreter for unit testing self-defined Basic Function Blocks.",

author = "Bianca Wiesmayr and Alois Zoitl and Antonio Garmendia and Manuel Wimmer",

year = "2021",

month = dec,

doi = "10.1109/ETFA45728.2021.9613716",

language = "English",

isbn = "978-1-7281-2989-1",

pages = "1--8",

booktitle = "ETFA 2021- IEEE 26th International Conference on Emerging Technologies and Factory Automation, September 7-10, 2021, Vasteras, Sweden, virtual event",

publisher = "IEEE",

}

A Model-based Execution Framework for Interpreting Control Software. / Wiesmayr, Bianca ; Zoitl, Alois; Garmendia, Antonio et al.
ETFA 2021- IEEE 26th International Conference on Emerging Technologies and Factory Automation, September 7-10, 2021, Vasteras, Sweden, virtual event. IEEE, 2021. S. 1-8.

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

TY - GEN

T1 - A Model-based Execution Framework for Interpreting Control Software

AU - Wiesmayr, Bianca

AU - Zoitl, Alois

AU - Garmendia, Antonio

AU - Wimmer, Manuel

PY - 2021/12

Y1 - 2021/12

N2 - Industrial standards define domain-specific languages that are frequently used for developing control software. For instance, IEC 61499 standardizes a graphical modeling language that includes a platform-independent application model. The application is composed of Function Blocks. A runtime can execute the model by implementing the semantics that is described in the standard in natural language. By defining an interpreter for IEC 61499 models, we can directly execute them without prior code generation. This enables providing feedback directly on the model level. We present an interpreter for Basic Function Blocks, which encapsulate a state-based Execution Control Chart. An existing EMF meta-model for IEC 61499 was extended with an operational semantics implemented in Java and Xtend. The test cases are defined either in Java or as an interface model. Such a model is standardized in IEC 61499 as Service Sequences. We evaluate our interpreter by executing the Basic Function Blocks that are defined in the standard and compare our results to those of the open-source runtime 4diac FORTE. As a practical use case, we show how developers can use the interpreter for unit testing self-defined Basic Function Blocks.

AB - Industrial standards define domain-specific languages that are frequently used for developing control software. For instance, IEC 61499 standardizes a graphical modeling language that includes a platform-independent application model. The application is composed of Function Blocks. A runtime can execute the model by implementing the semantics that is described in the standard in natural language. By defining an interpreter for IEC 61499 models, we can directly execute them without prior code generation. This enables providing feedback directly on the model level. We present an interpreter for Basic Function Blocks, which encapsulate a state-based Execution Control Chart. An existing EMF meta-model for IEC 61499 was extended with an operational semantics implemented in Java and Xtend. The test cases are defined either in Java or as an interface model. Such a model is standardized in IEC 61499 as Service Sequences. We evaluate our interpreter by executing the Basic Function Blocks that are defined in the standard and compare our results to those of the open-source runtime 4diac FORTE. As a practical use case, we show how developers can use the interpreter for unit testing self-defined Basic Function Blocks.

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U2 - 10.1109/ETFA45728.2021.9613716

DO - 10.1109/ETFA45728.2021.9613716

M3 - Conference proceedings

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BT - ETFA 2021- IEEE 26th International Conference on Emerging Technologies and Factory Automation, September 7-10, 2021, Vasteras, Sweden, virtual event

PB - IEEE

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A Model-based Execution Framework for Interpreting Control Software

Abstract

UN SDGs

Wissenschaftszweige

JKU-Schwerpunkte

Zugriff auf Dokument

Andere Dateien und Links

Projekte

Christian Doppler Laboratory for Mastering Variability in Software-intensive Cyber-physical Production Systems (CDL VaSiCS)

Christian Doppler Laboratory for Model-Integrated Smart Production

Dieses zitieren