This article focuses on the approaches of selecting cost-effective solutions to configurations of hardware components in digital systems (in particular, smart machines) by the combinatorial optimization method. A search for the solution to the application of cross-functional or special-purpose hardware components for LoT devices is a multi-criteria objective. The proposed selection algorithm for the configuration of hardware components feeds on rigorous formalization and ranking of qualitative indicators, parameters and key features of the components in question. The authors have applied the algorithm in the MatLab environment in order to choose the best configuration of hardware components for the smart machine intended to be a core of an intelligent control unit for an analysis of AC network parameters and control over the actuating electromechanical devices. The results of the analysis have become a ground for the development of the special-purpose controller for an intelligent module of the smart machine. The synthetic solution to a configuration of the smart controller provides an analysis of monitoring data. It can also make it possible for the smart machine to transfer data via a service interface to an external automation controller, which remotely disconnects the machine at the command of a user. The result of the design procedure is the advisable configuration of the special-purpose smart machine controller intended to analyze the AC network parameters obtained using the proposed design methodology.
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K. Christidis, M. Devetsikiotis, Blockchains and Smart Contracts for the Internet of Things, IEEE ACCESS, n. 4, 2016, pp. 2292 – 2303.
https://doi.org/10.1109/access.2016.2566339

A.I. Vlasov, O.N. Berdyugina, A.I. Krivoshein. Technological Platform for Innovative Social Infrastructure Development based on Smart Machines and Principles of Internet of Things, 2018 Global Smart Industry Conference (GloSIC), 2018, pp. 1 – 7.
https://doi.org/10.1109/glosic.2018.8570062

G. Prause and S. Atari, On sustainable production networks for Industry 4.0, Entrepreneurship and Sustainability Issues, vol. 4 no. 4, 2017, pp. 421 – 431.
https://doi.org/10.9770/jesi.2017.4.4(2)

Fund “Center of Strategical Developments “North-West”, “Intelligent” Environments, “Intelligent” Systems, “Intelligent” Productions: Series of Reports (Green Books) within the Framework of the Project Industrial and Technological Foresight of the Russian Federation, issue 4. Saint Petersburg, 2012.

A.I. Vlasov, V.V. Echeistov, A.I. Krivoshein, V.A. Shakhnov, S.S. Filin, V.S. Migalin, An information system of predictive maintenance analytical support of industrial equipment, Journal of Applied Engineering Science, vol. 16 n. 4, 2018, pp. 515 – 522.
https://doi.org/10.5937/jaes16-18405

A.I. Vlasov, P.V. Grigoriev, A.I. Krivoshein, V.A. Shakhnov, S.S. Filin, V.S. Migalin, Smart management of technologies: predictive maintenance of industrial equipment using wireless sensor networks, Entrepreneurship and sustainability issues, vol. 6 n. 2, 2018, pp. 489 – 502.
https://doi.org/10.9770/jesi.2018.6.2(2)

Intel 4004. Аccess mode: https://ru.bmstu.wiki/Intel_4004

B. B. Bray, Intel Microprocessors: 8086/8088, 80186/80188, 80286, 80386, 80486, Pentium, Pentium Pro Processor, Pentium 4. Architecture, programming and interfaces (M.: BKHV-Peterburg, 2005).

G.M. Alakoz, L.A. Vol'Pert, G.F. Strautmanis, Basic principles of sequential computation by means of 1-bit MIMD processors, Automatic Control and Computer Sciences, vol. 31 n.2, 1997, pp. 1–10.

F. Malerba, R. Nelson, L. Orsenigo, S. Winter, History-friendly models of industry evolution: the computer industry, Industrial and Corporate Change, vol. 8 n. 1, 1999, p. 3.
https://doi.org/10.1093/icc/8.1.3

A. Plebe, G. Grasso, The brain in silicon: history, and skepticism, IFIP Advances in Information and Communication Technology, vol. 487, 2016, pp. 273 – 286.
https://doi.org/10.1007/978-3-319-47286-7_19

A.A. Saralieva, Comparison of INTEL and AMD processors, Worldscience: collection of articles of the winners in the VIII International Scientific and Practical Conference: 2 parts, 2017. pp. 92 – 94.

A. Sysoev, From SANDYBRIDGE to IVYBRIDGE: The Evolution of Embedded Platforms Based on INTEL Processors, Components and technologies, n. 11(136), 2012, pp. 130 – 136.

S. Ram, O.P. Rahi, V. Sharma, A Comprehensive literature review on slip power recovery drives, Renewable and Sustainable Energy Reviews, vol. 73, 2017, pp. 922 – 934.
https://doi.org/10.1016/j.rser.2016.11.154

P. Aksoy, A fully parallel, multi-chip, long constraint length optoelectronic viterbi decoder: design, modeling, and analysis, Ph.D. dissertation, George Mason University, Fairfax, Virginia, 2006.

I. Krivchenko, ATMEL products – general directions and development trends, Components and technologies, n. 4, 2000, pp. 28 – 32.

A.I. Vlasov, A.V. Yudin, V.A. Shakhnov, K.A. Usov, M.A. Salmina, Design methods of teaching the development of internet of things components with considering predictive maintenance on the basis of mechatronic devices, International Journal of Applied Engineering Research, vol. 12 n. 20, 2017, pp. 9390 – 9396.

How to Handle Concurrency. Аccess mode:
https://semiengineering.com/how-to-handle-concurrency/

N. B. Lukyanchikova, E. Simoen, K. Kleis, Physics of fluctuation processes and microminiaturization of silicon MOS transistors, News of higher educational institutions. Radio Physics, vol. 52 n. 9, 2009, pp. 730 – 748.

N. A. Zaitsev, I.V. Matyushkin, A.G. Krasnikov, S.N. Orlov, Y.M. Pastukhova, Role of interfaces in nanoscale MIS transistors with multilayer high-k dielectrics, Nano- and microsystem technology, n. 8(133) 2011, pp. 15 – 17.

A. Y. Anoprienko, Patterns of development of computer technology and the generalized law of Moore, Bulletin of Donetsk National Technical University, n. 2(2), 2016, pp. 3 – 17.

L. Chernyak, Three-Dimension Electronics, Open Systems. DBMS, vol. 22 n. 3, 2014, pp. 50 – 51.

A. Strogonov, S. Tsybin, A. Bystritsky, Three-dimensional integrated circuits 3D BIS, Components and technologies, n. 1(114), 2011, pp. 118 – 121.

Samsung Researchers Develop Method For Large-Scale Graphene Production.
Аccess mode: https://www.asianscientist.com/2014/04/in-the-lab/samsung-large-scale-graphene-production-2014/

Single crystals of gallium arsenide.

Аccess mode: http://www.voshod-krlz.ru/product/112

N. N. Rudenko, T.T. Silkova, Molecular electronics: present and future, Bulletin of National Technical University of Ukraine Kiev Polytechnic Institute. Radio engineering. Radio equipment construction series, n. 37, 2008, pp. 130 – 142.

N.T. Sudar, Physical Basics of Molecular Electronics (St. Petersburg: St. Petersburg Polytechnic University Publishing, 2011).

E.A. Suvorova, V.V. Rozanov, Y. Sheynin, Dynamically Reconfigurable Systems and Networks on a Chip in ASIC in 2D-3D Technologies, Nanoindustry Russia, 2018, pp. 197-197.

V.A. Bespalov, A.L. Glebov, N.A. Kononov, D.Y. Nemchin, Methods of choosing universal logic modules for FPGAS and ASIC, Russian Microelectronics, vol. 40 n. 7, 2011, pp. 497 – 501.
https://doi.org/10.1134/s1063739711070043

A. A. Kolganov, D.Y. Kudryavtsev, Application of combinatorial optimization methods for optimal choice of the component base of the technical system, Design and technology of electronic means, n. 3, 2017, pp. 16 – 20.

A.V. Attetkov, S.V. Galkin, V.S. Zarubin, Optimization Methods (Moscow: MGTU named after N.E. Bauman Publishing, 2003).

D. Popov, Optimization of coherent signals processing systems, Radio industry (Russia), n. 3, 2016, pp. 6 – 10.

A.V. Kolychev, V. A. Kernozhitskiy, Сoncept of design of systems for control of integrated engineering complexes with a possibility to integrate them into a global computer network, Radio industry (Russia), n. 1, 2017, pp. 22–25.
https://doi.org/10.21778/2413-9599-2017-1-22-25