Abstract
Smart manufacturing , industry 4.0 concepts and models for new product development and testing are examined here. Smart manufacturing is the evolution of the manufacturing environment where the integration of information, technology and innovation drive a better, faster and more efficient production system operating at the highest level of quality and output. Smart manufacturing is an operating model where machines interact to one another and share data at every point. It is the use of intelligence at a fully-integrated level to allow companies to connect the customers’ needs to supply chain to the production equipment and to the operators . Reference architectures provide common and consistent definitions in the system of interest, its decompositions , and design patterns, and provide a common terminology to discuss the specification of implementations so that options may be compared. Smart Grid Architecture Model, (SGAM), is presented as a generic model for different architecture models as RAMI 4.0. The V-model is a general reference model for systems design and validation suitable for presenting specification phases and associated test phases. The individual tests-acceptance tests, system tests and integration tests-are executed against the corresponding specification documents, user requirements and system specifications or technical specifications.
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References
Bartheye, O., Chaudron, L.: Algebraic models of the self-orientation concept for autonomous systems. In: 2015 AAAI Spring Symposium Series, pp. 14–21 (2015)
Benson, D.B.: Bialgebras: some foundations for distributed and concurrent computation. Fundam. Informaticae 12, 427–486 (1989)
Blasiak, P.: Combinatorial route to algebra: the art of composition & decomposition. Discrete Math. Theor. Comput. Sci. 12(2), 381–400 (2010)
Blute, R.: Hopf Algebas and linear logic. Math. Struct. Comput. Sci. 6, 189–217 (1996)
Blute, R., Cockett J.R.B., Seely R.A.G.: Differential categories. Math. Struct. Comput. Sci. 16, 1049–1083 (2006)
Blute, R., Cockett, J.R.B., Seely, R.A.G.: Cartesian differential categories. Theor. Appl. Categories 22, 622–672 (2009)
Blute, R., Ehrhard, T., Tasson, C.: A convenient differential category. arXiv preprint arXiv:1006.3140 (2010)
Blute, R., Scott, P.: The shuffle Hopf algebra and noncommutative full completeness. J. Symbolic Logic 63, 1413–1435 (1998)
Bryner, M.: Smart manufacturing: the next revolution. Chem. Eng. Prog. 108(10), 4–12 (2012)
Davis, J., Edgar, T.F., Porter, J., Bernaden, J., Sarli, M.: Smart manufacturing, manufacturing intelligence and demand-dynamic performance. Comp. Chem. Eng. 47, 134–144 (2012)
Ehrhard, T., Regnier, L.: Differential interaction nets. Theoret. Comput. Sci. 364(2), 166–195 (2006)
Estefan, J.A.: Survey of model-based systems engineering (MBSE) methodologies. Incose MBSE Focus Group. 25(8) (2007)
Fang, X., Misra, S., Xue, G., Yang, D.: Smart grid, the new and improved power grid: a survey. IEEE Commun. Surv. Tutorials 14(4), 944–980 (2012)
Figueroa, H., Gracia-Bondia, J.M., Varilly, J.C.: FaĂ di Bruno Hopf algebras. arXiv preprint math/0508337 (2005)
Gausemeier, J., Möhringer, S.: New guideline VDI 2206—a flexible procedure model for the design of mechatronic systems. In: Norell, M. (ed.), Proceedings of the 14th International Conference on Engineering Design (ICED), Stockholm (2003)
Guo, L.: What is a Rota-Baxter algebra. Notices of the AMS, 56(11) (2009)
Hermann, M., Pentek, T., Otto, B.: Design principles for industrie 4.0 scenarios. In: 49th Hawaii International Conference on System Sciences (HICSS) IEEE, pp. 3928–3937 (2016)
Hwang, J.S.: The fourth industrial revolution (industry 4.0): Intelligent manufacturing. SMT (surface mount technology) Magazine, 10–15 (2016)
Iordache, O.: Self-Evolvable Systems. Machine Learning in Social Media. Springer, Berlin (2012)
Iordache, O.: Polytope Projects. Taylor & Francis CRC Press, Boca Raton (2013)
Joni, S.A., Rota, G.C.: Coalgebras and bialgebras in combinatorics. Stud. Appl. Math. 61(2), 93–139 (1979)
Kagermann, H., Wahlster, W., Helbig, J. (eds.): Recommendations for Implementing the Strategic Initiative industrie 4.0: Final Report of the Industrie 4.0 Working Group (2013)
Katzenbach, A., Bergholz., W., Rolinger, A.: Knowledge-based design—an integrated approach, the future of product development. In: Krause, F.L. (ed.), Proceedings of the 17th CIRP Design Conference, pp. 13–22 (2007)
Lee, J., Bagheri, B., Kao, H.A.: A cyber-physical systems architecture for industry 4.0-based manufacturing systems. Manufact. Lett. 31(3), 18–23 (2015)
OMG.: Object management group, software & systems process engineering meta-model specification 2.0 (2008)
Schmitt, W.R.: Incidence Hopf algebras. J. Pure Appl. Algebra 96(3), 299–330 (1994)
Schwab, K.: The Fourth Industrial Revolution. World Economic Forum, Geneva (2016)
Strang, D., Anderl, R.: Assembly process driven component data model in cyber-physical production systems. In: World Congress on Engineering and Computer Science, vol. 2, pp. 22–24, (2014)
Sweedler, M.E.: Hopf Algebras, Mathematics Lecture Note Series. W. A. Benjamin Inc, New York (1969)
Uslar, M., Engel, D.: Towards generic domain reference designation: how to learn from smart grid interoperability. In: Poster Proceedings of DACH Energy Informatics 2015, 1–12 (2015)
Zuehlke, D.: Smart factory–from vision to reality in factory technologies. IFAC Proc. 41(2), 14101–14108 (2008)
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Iordache, O. (2017). Industrial Systems. In: Implementing Polytope Projects for Smart Systems. Studies in Systems, Decision and Control, vol 92. Springer, Cham. https://doi.org/10.1007/978-3-319-52551-8_8
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