Abstract
This paper presents a proposal for a change in the aircraft development process to cope with the increasing complexity of products and pressure from the market to develop aircraft faster. The key process change is a deviation from the traditionally linear development approach and the inclusion of an out-of-cycle component development phase, where components of an aircraft are developed preemptively, outside of a program development effort. These so-called smart components are then adapted to the specific needs of a program within the more linear cycle. Furthermore, it describes a metamodel for modeling the so-called smart components based on proven MBSE principles and exemplifies this approach with a small case study.
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Notes
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A manifest file describes not only the location of the model, but also the inputs and outputs mapped to parameters and characteristics and a solver that can be used to execute the model.
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References
Chase, J., Darot, J., Evans, A., Evans, S., Fernandes, P., Markish, J., Speller, T.: The business case for the very large aircraft, p. 589 (2001). https://doi.org/10.2514/6.2001-589
Crnkovic, I., Chaudron, M., Larsson, S.: Component-based development process and component lifecycle. In: 2006 International Conference on Software Engineering Advances (ICSEA 2006), p. 44, October 2006. https://doi.org/10.1109/ICSEA.2006.261300
Dragoni, N., Giallorenzo, S., Lafuente, A.L., Mazzara, M., Montesi, F., Mustafin, R., Safina, L.: Microservices: yesterday, today, and tomorrow, pp. 195–216. Springer, Cham (2017). https://doi.org/10.1007/978-3-319-67425-4_12
ECMA: Standard 335 - Common Language Infrastructure (CLI) - Partitions I to VI. ECMA International, 6th edn. (2012)
Estefan, J.: Survey of Model-Based Systems Engineering (MBSE) methodologies. Technical report, International Council on Systems Engineering (2007)
Evans, J.W., Groen, F.J., Wang, L., Austin, R., Witulski, A., Cornford, S.L., Feather, M., Lindsey, N.: Towards a framework for reliability and safety analysis of complex space missions (2017). https://doi.org/10.2514/6.2017-1099
Guenov, M.D., Nunez, M., Molina-Cristóbal, A., Datta, V.C., Riaz, A.: Aircadia–an interactive tool for the composition and exploration of aircraft computational studies at early design stage. In: 29th Congress of the International Council of the Aeronautical Sciences, St Petersburg, pp. 7–12 (2014)
International Council on Systems Engineering (INCOSE): A World in Motion - Systems Engineering Vision 2025, July 2014
International Organization for Standardization: ISO/IEC 80000 - Quantities and units. Standard, International Organization for Standardization, Geneva, CH, November 2009
Kulkarni, T., DeBruin, K., Nelessen, A., Reilley, K.A., Peak, R., Edwards, S.J., Mavris, D.N.: A model based systems engineering approach towards developing a rapid analysis and trades environment (2016). https://doi.org/10.2514/6.2016-5472
Murman, E.M., Walton, M., Rebentisch, E.: Challenges in the better, faster, cheaper era of aeronautical design, engineering and manufacturing. Aeronaut. J. 104(1040), 481–489 (2000)
Object Management Group: OMG Systems Modeling Language (OMG SysML), v1.2. OMG, Needham, MA (2008)
OMG: OMG Object Constraint Language (OCL), Version 2.3.1, January 2012
Reichwein, A., Paredis, C.: Overview of architecture frameworks and modeling languages for model-based systems engineering. In: Proceedings of ASME. pp. 1–9 (2011)
Rodriguez, A.: Restful web services: the basics (2008). http://www.gregbulla.com/TechStuff/Docs/ws-restful-pdf.pdf
Roques, P.: MBSE with the ARCADIA method and the Capella tool. In: 8th European Congress on Embedded Real Time Software and Systems (ERTS 2016), Toulouse, France, January 2016
Sadraey, M.H.: Aircraft Design: A Systems Engineering Approach. Wiley, New York (2012)
Stark, J.: Product Lifecycle Management: Volume 1: 21st Century Paradigm for Product Realisation. Springer, Cham (2016). https://doi.org/10.1007/978-3-319-17440-2
Steinberg, D., Budinsky, F., Merks, E., Paternostro, M.: EMF: Eclipse Modeling Framework, 2nd edn. Pearson Education, London (2008)
Torngren, M., Chen, D.J., Crnkovic, I.: Component-based vs. model-based development: a comparison in the context of vehicular embedded systems. In: 31st EUROMICRO Conference on Software Engineering and Advanced Applications, pp. 432–440, August 2005. https://doi.org/10.1109/EUROMICRO.2005.18
Viyović, V., Maksimović, M., Perisić, B.: Sirius: a rapid development of DSM graphical editor. In: IEEE 18th International Conference on Intelligent Engineering Systems, INES 2014. pp. 233–238, July 2014. https://doi.org/10.1109/INES.2014.6909375
Zhao, Y.: Why 787 slips were inevitable? Rutgers University, New York (2013)
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Helle, P., Feo-Arenis, S., Mitschke, A., Schramm, G. (2020). Smart Component Modeling for Complex System Development. In: Boy, G., Guegan, A., Krob, D., Vion, V. (eds) Complex Systems Design & Management. CSDM 2019. Springer, Cham. https://doi.org/10.1007/978-3-030-34843-4_10
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