Validate, simulate, and implement ARINC653 systems using the AADL

Julien Delange; Laurent Pautet; Alain Plantec; Mickael Kerboeuf; Frank Singhoff; Fabrice Kordon

doi:10.1145/1647420.1647435

Validate, simulate, and implement ARINC653 systems using the AADL

Julien Delange
, Laurent Pautet
, Alain Plantec
, Mickael Kerboeuf
, Frank Singhoff
, Fabrice Kordon

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Safety-critical systems are widely used in different domains and lead to an increasing complexity. Such systems rely on specific services such space and time isolation as in the ARINC653 avionics standard. Their criticality requires a carefully driven design based on an appropriate development process and dedicated tools to detect and avoid problems as early as possible. Model Driven Engineering (MDE) approaches are now considered as valuable approach for building safety-critical systems. The Architecture Analysis and Design Language (AADL) proposes a component-based language suitable to operate MDE that fits with safety-critical systems needs. This paper presents an approach for the modeling, verification and implementation of ARINC653 systems using AADL. It details a modeling approach exploiting the new features of AADL version 2 for the design of ARINC653 architectures. It also proposes modeling patterns to represent other safety mechanisms such as the use of Ravenscar for critical applications. This approach is fully backed by tools with Ocarina (AADL toolsuite), POK (AADL/ARINC653 runtime) and Cheddar (scheduling verification). Thus, it assists system engineers to simulate and validate non functional requirements such as scheduling or resources dimensioning.

Original language	English
Title of host publication	SIGAda 2009 - Proceedings of the ACM International Conference on Ada and Related Technologies
Pages	31-44
Number of pages	14
DOIs	https://doi.org/10.1145/1647420.1647435
Publication status	Published - 1 Dec 2009
Externally published	Yes
Event	ACM International Conference on Ada and Related Technologies, SIGAda 2009 - Saint Petersburg, FL, United States Duration: 1 Nov 2009 → 5 Nov 2009

Publication series

Name	Proceedings of the ACM SIGAda Annual International Conference; SIGAda

Conference

Conference	ACM International Conference on Ada and Related Technologies, SIGAda 2009
Country/Territory	United States
City	Saint Petersburg, FL
Period	1/11/09 → 5/11/09

Keywords

AADL
ARINC653
Cheddar
Code generation
Model based engineering
Ocarina
POK
Schedulability
Simulation

Access to Document

10.1145/1647420.1647435

Cite this

Delange, J., Pautet, L., Plantec, A., Kerboeuf, M., Singhoff, F., & Kordon, F. (2009). Validate, simulate, and implement ARINC653 systems using the AADL. In SIGAda 2009 - Proceedings of the ACM International Conference on Ada and Related Technologies (pp. 31-44). Article 1647435 (Proceedings of the ACM SIGAda Annual International Conference; SIGAda). https://doi.org/10.1145/1647420.1647435

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title = "Validate, simulate, and implement ARINC653 systems using the AADL",

abstract = "Safety-critical systems are widely used in different domains and lead to an increasing complexity. Such systems rely on specific services such space and time isolation as in the ARINC653 avionics standard. Their criticality requires a carefully driven design based on an appropriate development process and dedicated tools to detect and avoid problems as early as possible. Model Driven Engineering (MDE) approaches are now considered as valuable approach for building safety-critical systems. The Architecture Analysis and Design Language (AADL) proposes a component-based language suitable to operate MDE that fits with safety-critical systems needs. This paper presents an approach for the modeling, verification and implementation of ARINC653 systems using AADL. It details a modeling approach exploiting the new features of AADL version 2 for the design of ARINC653 architectures. It also proposes modeling patterns to represent other safety mechanisms such as the use of Ravenscar for critical applications. This approach is fully backed by tools with Ocarina (AADL toolsuite), POK (AADL/ARINC653 runtime) and Cheddar (scheduling verification). Thus, it assists system engineers to simulate and validate non functional requirements such as scheduling or resources dimensioning.",

keywords = "AADL, ARINC653, Cheddar, Code generation, Model based engineering, Ocarina, POK, Schedulability, Simulation",

author = "Julien Delange and Laurent Pautet and Alain Plantec and Mickael Kerboeuf and Frank Singhoff and Fabrice Kordon",

year = "2009",

month = dec,

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doi = "10.1145/1647420.1647435",

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series = "Proceedings of the ACM SIGAda Annual International Conference; SIGAda",

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Delange, J, Pautet, L, Plantec, A, Kerboeuf, M, Singhoff, F & Kordon, F 2009, Validate, simulate, and implement ARINC653 systems using the AADL. in SIGAda 2009 - Proceedings of the ACM International Conference on Ada and Related Technologies., 1647435, Proceedings of the ACM SIGAda Annual International Conference; SIGAda, pp. 31-44, ACM International Conference on Ada and Related Technologies, SIGAda 2009, Saint Petersburg, FL, United States, 1/11/09. https://doi.org/10.1145/1647420.1647435

Validate, simulate, and implement ARINC653 systems using the AADL. / Delange, Julien; Pautet, Laurent; Plantec, Alain et al.
SIGAda 2009 - Proceedings of the ACM International Conference on Ada and Related Technologies. 2009. p. 31-44 1647435 (Proceedings of the ACM SIGAda Annual International Conference; SIGAda).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Delange, Julien

AU - Pautet, Laurent

AU - Plantec, Alain

AU - Kerboeuf, Mickael

AU - Singhoff, Frank

AU - Kordon, Fabrice

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SN - 9781605584751

T3 - Proceedings of the ACM SIGAda Annual International Conference; SIGAda

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EP - 44

BT - SIGAda 2009 - Proceedings of the ACM International Conference on Ada and Related Technologies

T2 - ACM International Conference on Ada and Related Technologies, SIGAda 2009

Y2 - 1 November 2009 through 5 November 2009

ER -

Validate, simulate, and implement ARINC653 systems using the AADL

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Publication series

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Keywords

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