Conceptual interoperability is a concept in simulation theory. However, it is broadly applicable for other model-based information technology domains. From the early ideas of Harkrider and Lunceford, simulation composability has been studied in more detail. Petty and Weisel formulated the current working definition: "Composability is the capability to select and assemble simulation components in various combinations into simulation systems to satisfy specific user requirements. The defining characteristic of composability is the ability to combine and recombine components into different simulation systems for different purposes." A recent RAND study provided a coherent overview of the state of composability for military simulation systems within the U.S. Department of Defense; many of its findings have much broader applicability.
The resulting challenges have produced layered views. Petty and Weisel distinguish between the idea of interoperability, coping with the technical challenges, and composability, dealing with modeling issues. Research at the Virginia Modeling, Analysis and Simulation Center (VMASC) refined these layers to define the "Levels of Conceptual Interoperability Model (LCIM)," This definition has undergone gradual improvement since the first discussion in.[1] The current version of LCIM was first documented by Turnitsa in.[2]
The different levels are characterized as follows: https://handwiki.org/wiki/index.php?curid=1306606
The LCIM shows that a layered approach to support composable services is necessary. The WS standards described earlier are not able to manage all levels, in particular not with the M&S specific upper layers. It is worth mentioning, however, that the LCIM focuses on technical support by information systems, such as command and control information systems in the military context. As Alberts and Hayes point out in,[3] the organizational and social aspects are often even more important. Tolk proposes such a layered framework for measures of merits dealing with questions like tactical or strategic alignment of objectives or even political will of coalition partners in.[4] Within this contribution, however, the focus will be on the information system aspects.
Page et al.[5] suggest defining composability as the realm of the model and interoperability as the realm of the software implementation of the model. In addition, their research introduces integratability coping with the hardware-side and configuration side of connectivity. The author supports this categorization and recommends the following distinction when dealing with issues of simulation system interoperability, to include meaningful simulation-to-simulation system interoperation:
This ideas complement the LCIM. The LCIM has been successfully applied not only in the domain of Modeling & Simulation, but generally in model-based interoperability challenges. It should be pointed out that the LCIM can be used in descriptive and in prescriptive mode.[6] It was recently recommended to extend the LCIM to an Interoperability Maturity Matrix.[7]
During an ACM SIGSIM and SCS sponsored expert discussion during the SCS Spring Simulation Multiconference in San Diego, CA, on April 11, 2013, Professor Tolk addressed Composability as a Grand Challenge of Modeling & Simulation when we are thinking about M&S and Cloud-based Simulation. He proposed the following two definitions:
He referred to the latest work of his research team that utilizes Model Theory [8]
The LCIM in this form or slight variations thereof has been applied not only in simulation, but in many other domains as well. Examples are given in more than 500 journal articles, book chapters, and conference papers referencing the LCIM ideas, such as:
Health and Human Sciences (http://aspe.hhs.gov/sp/reports/2010/erpreqlim/report.shtml);
Medical Simulation: Weininger, S., Jaffe, M.B., Robkin, M., Rausch, T., Arney, D. and Goldman, J.M., 2016. The importance of state and context in safe interoperable medical systems. IEEE Journal of Translational Engineering in Health and Medicine, 4, pp.1-10.
Internet of Things: Kolbe, Niklas, Jérémy Robert, Sylvain Kubler, and Yves Le Traon. "PROFICIENT: Productivity Tool for Semantic Interoperability in an Open IoT Ecosystem." In Proceedings of the 14th EAI International Conference on Mobile and Ubiquitous Systems: Computing, Networking and Services. 2017.
Department of Energy SmartGrid (http://www.gridwiseac.org/pdfs/interopframework_v1_1.pdf);
Enterprise Interoperability Panetto, Hervé; Molina, Arturo (September 2008). "Enterprise integration and interoperability in manufacturing systems: Trends and issues". Computers in Industry 59 (7): 641–646. doi:10.1016/j.compind.2007.12.010. ;
Geographic Information Systems Manso, Miguel-Ángel; Wachowicz, Monica (2009). "GIS Design: A Review of Current Issues in Interoperability". Geography Compass 3 (3): 1105–1124. doi:10.1111/j.1749-8198.2009.00241.x. ;
Digital Library Ecosystem "Applying the Levels of Conceptual Interoperability Model to a Digital Library Ecosystem – a Case Study". DCMI International Conference on Dublin Core and Metadata Applications: 62–72. http://dcpapers.dublincore.org/pubs/article/viewFile/3851/2036. ;
Adaptive Instructional Systems; Workshop Proceedings of the 2nd AIS Standards Workshop. Opening Address: Understanding the AIS Problem Space, by Dr. Robert Sottilare
and more.
The content is sourced from: https://handwiki.org/wiki/Conceptual_interoperability