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2014-10-07
Neema, Himanshu, Nine, Harmon, Graham Hemingway, Sztipanovits, Janos, Karsai, Gabor.  2009.  Rapid Synthesis of Multi-Model Simulations for Computational Experiments in C2. Armed Forces Communications and Electronics Association - George Mason University Symposium.

Abstract-Virtual evaluation of complex command and control concepts demands the use of heterogeneous simulation environments. Development challenges include how to integrate multiple simulation platforms with varying semantics and how to integrate simulation models and the complex interactions between them. While existing simulation frameworks may provide many of the required services needed to coordinate among multiple simulation platforms, they lack an overarching integration approach that connects and relates the semantics of heterogeneous domain models and their interactions. This paper outlines some of the challenges encountered in developing a command and control simulation environment and discusses our use of the GME meta-modeling tool-suite to create a model-based integration approach that allows for rapid synthesis of complex HLA-based simulation environments.

The research was conducted by Institute for Software Integrated Systems at Vanderbilt University, in collaboration with George Mason University, University of California at Berkeley, and University of Arizona.

Maroti, Miklos, Kereskenyi, Robert, Tamas Kecskes, Volgyesi, Peter, Ledeczi, Akos.  2014.  Online Collaborative Environment for Designing Complex Computational Systems. The International Conference on Computational Science (ICCS 2014).

Developers of information systems have always utilized various visual formalisms during the design process, albeit in an informal manner. Architecture diagrams, finite state machines, and signal flow graphs are just a few examples. Model Integrated Computing (MIC) is an approach that considers these design artifacts as first class models and uses them to generate the system or subsystems automatically. Moreover, the same models can be used to analyze the system and generate test cases and documentation. MIC advocates the formal definition of these formalisms, called domain-specific modeling languages (DSML), via metamodeling and the automatic configuration of modeling tools from the metamodels. However, current MIC infrastructures are based on desktop applications that support a limited number of platforms, discourage concurrent design collaboration and are not scalable. This paper presents WebGME, a cloud- and web-based cyberinfrastructure to support the collaborative modeling, analysis, and synthesis of complex, large-scale scientific and engineering information systems. It facilitates interfacing with existing external tools, such as simulators and analysis tools, it provides custom domain-specific visualization support and enables the creation of automatic code generators.