Abstract
Industries rely on a flexible manufacturing process to face high competitive market and customization constraints. It relies on an efficient production system that allows it easier to reconfigure and interact with other devices. Currently, Cyber-physical systems (CPS) are proposing an answer to the fourth industrial revolution. The CPS technology and application for production are named Cyber-physical production system (CPPS) for the last few years. It is an autonomous system and has cooperative elements connecting across all production levels, from machines to operators. This paper address how the new customization strategies affect/requires the system to be modified and develop a new drone system. Using the system Engineering approach, the elicitation of the system requirements from the different concepts of operation for customization operations in CPPS is realized. This work is instantiated on an experimental CPPS platform. It illustrates the structured requirement framework for the new customization strategy and elaborates by presenting a requirement model of the system. It is the required step to bring effective customization to the CPPS Platform.
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References
Greer, C., Burns, M., Wollman, D., Griffor, E.: Cyber-physical systems and Internet of things, National institute of standards and technology, Special Publication 1900–202 (2019)
Cardin, O.: Classification of cyber-physical production systems applications: Proposi- tion of an analysis framework. Comput. Ind. Elsevier 104, 11–21 (2019). ff10.1016/j.compind.2018.10.002.
Amza, C.G., Cantemir, D., Cantemir, I., et al.: Guidelines on Industry 4.0 and drone Entrepreneurship for VET students. Danmar Computer LLC ul.K. Hoffman- owej 19-35-016, Rzeszow (2018)
Festo Didactic: A universal Industry 4.0 training factory. A guided tour, Press release (2017). www.Festodidactic.com
Merdan, M.: Knowledge-based cyber-physical system for assembly automation, Pro- d. Manuf. Res. 7:1, 223–254
Karaköse, M: A cyberphysical system based mass-customization approach with integration of Industry 4.0 and smart city. Wirel. Commun. Mobile Comput. 2017, 9. (2017), Article ID 1058081
System Engineering and MBSE: International council of system engineering, Jan 2017. https://www.incose.org/iw2019/program/mbse-initiative
Nuseibeh, B., Easterbrook, S.: Requirements engineering: a roadmap, CSE 2000. In: Pro ceedings of the Conference on the Future of Software Engineering, pp. 35–46 (2000)
Bijan, Y., et al.: System requirement engineering- state of the methodology. Syst. Eng. 16(3), 267–276 (2013)
Companik, E., et al.: Feasibility of warehouse drone adoption and implementation. Apics Providence Chapter, May 2018
Han, J.: Cyber-physical systems with multi-unmanned aerial vehicle-based Cooperative source seeking and contour mapping. Utah State University (2016)
Konya, G., Sommerville, I.: Requirements Engineering: Processes and Techniques Chichester. Wiley, UK (1998)
Puviyarasu, S.A. et al.: A semantic interface model to support the integration of drones in a cyber-physical factory. In: International Conference on Interoperability for Enterprise Systems and Application (IESA), Springer Proceedings, Tarbes, France (2020)
Mahboob, A., et al.: Model-based system Engineering for configurable product use case scenario in virtual environment. In: 21st International Conference on Engineering Design, ICED 17, Canada (2017)
Rolland, C., Proix, C.: A natural language approach for requirement engineering. In: International Conference on Advanced Information System Engineering, Springer, Berlin, pp. 257–277 (1992). https://doi.org/10.1007/BFb0035136
Borchers, D.K.H.: Maintenance, maintainability, and system requirements en-gineering,SAE world congress and exhibition 1964. SAE Tech. Paper. 640591 (1964). https://doi.org/10.4271/640591
Friedenthal, S., Moore, A., Steiner, R.: A Practical Guide to SysML: The System Modeling Language, 3rd edn. Morgan Kaufmann, The OMG Press (2016)). ISBN 978-0-12-800202-5
Balmeli, L., Moore, A.: Requirement Modelling for System Engineering using SYSML, the system modelling language. In: International Design Engineering Technical Conference, pp. 989–994 (2004)
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Subramaniam Anbuchezhian, P., Belkadi, F., da Cunha, C., Chriette, A. (2022). A Requirement Engineering Framework for Smart Cyber-Physical Production System. In: Andersen, AL., et al. Towards Sustainable Customization: Bridging Smart Products and Manufacturing Systems. CARV MCPC 2021 2021. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-030-90700-6_43
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