Hybrid MARTE statecharts

Jing Liu; Ziwei Liu; Jifeng He; Frédéric Mallet; Zuohua Ding

doi:10.1007/s11704-012-1301-1

Hybrid MARTE statecharts

Jing Liu, Ziwei Liu, Jifeng He^*, Frédéric Mallet, Zuohua Ding

^*Corresponding author for this work

Software Engineering Institute

Research output: Contribution to journal › Article › peer-review

22 Scopus citations

Abstract

The specification of modeling and analysis of real-time and embedded systems (MARTE) is an extension of the unified modeling language (UML) in the domain of real-time and embedded systems. Even though MARTE time model offers a support to describe both discrete and dense clocks, the biggest effort has been put so far on the specification and analysis of discrete MARTE models. To address hybrid real-time and embedded systems, we propose to extend statecharts using both MARTE and the theory of hybrid automata. We call this extension hybrid MARTE statecharts. It provides an improvement over the hybrid automata in that: the logical time variables and the chronometric time variables are unified. The formal syntax and semantics of hybrid MARTE statecharts are given based on labeled transition systems and live transition systems. As a case study, we model the behavior of a train control system with hybrid MARTE statecharts to demonstrate the benefit.

Original language	English
Pages (from-to)	95-108
Number of pages	14
Journal	Frontiers of Computer Science
Volume	7
Issue number	1
DOIs	https://doi.org/10.1007/s11704-012-1301-1
State	Published - Feb 2013

Keywords

MARTE
UML
hybrid MARTE statechart
hybrid automata
train control system

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10.1007/s11704-012-1301-1

Cite this

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title = "Hybrid MARTE statecharts",

abstract = "The specification of modeling and analysis of real-time and embedded systems (MARTE) is an extension of the unified modeling language (UML) in the domain of real-time and embedded systems. Even though MARTE time model offers a support to describe both discrete and dense clocks, the biggest effort has been put so far on the specification and analysis of discrete MARTE models. To address hybrid real-time and embedded systems, we propose to extend statecharts using both MARTE and the theory of hybrid automata. We call this extension hybrid MARTE statecharts. It provides an improvement over the hybrid automata in that: the logical time variables and the chronometric time variables are unified. The formal syntax and semantics of hybrid MARTE statecharts are given based on labeled transition systems and live transition systems. As a case study, we model the behavior of a train control system with hybrid MARTE statecharts to demonstrate the benefit.",

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AU - Liu, Jing

AU - Liu, Ziwei

AU - He, Jifeng

AU - Mallet, Frédéric

AU - Ding, Zuohua

PY - 2013/2

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N2 - The specification of modeling and analysis of real-time and embedded systems (MARTE) is an extension of the unified modeling language (UML) in the domain of real-time and embedded systems. Even though MARTE time model offers a support to describe both discrete and dense clocks, the biggest effort has been put so far on the specification and analysis of discrete MARTE models. To address hybrid real-time and embedded systems, we propose to extend statecharts using both MARTE and the theory of hybrid automata. We call this extension hybrid MARTE statecharts. It provides an improvement over the hybrid automata in that: the logical time variables and the chronometric time variables are unified. The formal syntax and semantics of hybrid MARTE statecharts are given based on labeled transition systems and live transition systems. As a case study, we model the behavior of a train control system with hybrid MARTE statecharts to demonstrate the benefit.

AB - The specification of modeling and analysis of real-time and embedded systems (MARTE) is an extension of the unified modeling language (UML) in the domain of real-time and embedded systems. Even though MARTE time model offers a support to describe both discrete and dense clocks, the biggest effort has been put so far on the specification and analysis of discrete MARTE models. To address hybrid real-time and embedded systems, we propose to extend statecharts using both MARTE and the theory of hybrid automata. We call this extension hybrid MARTE statecharts. It provides an improvement over the hybrid automata in that: the logical time variables and the chronometric time variables are unified. The formal syntax and semantics of hybrid MARTE statecharts are given based on labeled transition systems and live transition systems. As a case study, we model the behavior of a train control system with hybrid MARTE statecharts to demonstrate the benefit.

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KW - UML

KW - hybrid MARTE statechart

KW - hybrid automata

KW - train control system

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DO - 10.1007/s11704-012-1301-1

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JO - Frontiers of Computer Science

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Hybrid MARTE statecharts

Abstract

Keywords

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