Distributed and Parallel Embedded Systems 1999
DOI: 10.1007/978-0-387-35570-2_17
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MCI — Multilanguage Distributed Co-Simulation Tool

Abstract: Nowadays the design of complex systems requires the cooperation of several teams belonging to different cultures and using different languages. It is necessary to dispose of new design and verification m£thot/s to handle multilanguage approaches. This paper presents a multi language co-simulation tool that allows cosimulation of multilanguage specifications for complex systems. The main idea of our approach is to allow validation of the functional completeness of the system at a behavioral level. Mel starts wi… Show more

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Cited by 12 publications
(5 citation statements)
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“…Works on requirements capture can be also found [ 64 , 65 ] and final users’ needs evaluation [ 66 , 67 ], but they are focused on generic software, often resulting inefficient. Finally, papers addressing a complete methodology focused on the design process usually investigate procedures to create equivalent models in order to load the entire scenario (including all domains) in a unique simulator [ 68 ] (for example, representing people as mobile nodes in the network simulator). We are sure that no work proposes a complete methodology which allows software architects to design their own co-simulators.…”
Section: State Of the Artmentioning
confidence: 99%
“…Works on requirements capture can be also found [ 64 , 65 ] and final users’ needs evaluation [ 66 , 67 ], but they are focused on generic software, often resulting inefficient. Finally, papers addressing a complete methodology focused on the design process usually investigate procedures to create equivalent models in order to load the entire scenario (including all domains) in a unique simulator [ 68 ] (for example, representing people as mobile nodes in the network simulator). We are sure that no work proposes a complete methodology which allows software architects to design their own co-simulators.…”
Section: State Of the Artmentioning
confidence: 99%
“…This specification is validated by the use of the GEODESIM simulator [20]. [13]. The second step consists in targeting the components of the architecture and generating a cycle accurate model, which may also be validated through cosimulation [13].…”
Section: The Codesign Toolmentioning
confidence: 99%
“…In order to validate the generated architecture, we need a cycle accurate executable architecture that can run the application. To that end, we used a cosimulation approach [9]. In this approach software processors are replaced by cycle accurate ISSs (ISS + BFM).…”
Section: A Multiprocessor Architecture Platform Based On Mfsammentioning
confidence: 99%