The functional stability of technological processes and formation of individual strategy for management of operation of production centers

Abstract

The article studies the characteristics of the behavior of complex technical systems that implement the property of functional stability of these systems. The mathematical model describing technological processes at the industrial enterprise is resulted, the definition of functionally stable production process of the industrial enterprise and the criterion of maintenance of its functional stability with use of pseudoinversion is formulated. The conditions for ensuring the functional stability of the technological process are given and practical recommendations for the application of these conditions for decision-making in the practical implementation of production processes are described. Ensuring the functional stability of production processes is now one of the most important tasks. Currently, many different methods have been proposed to ensure a high level of functional stability, but this issue requires constant improvement and development of new approaches. In order to improve and develop methods of organizing production processes that ensure the functional stability of technological processes through the implementation of individual strategy of operation of relevant production centers, an approach to the formation of management strategy of production center, which provides functional stability of the technological process. The individual strategy of planning of operation of technical systems depending on their actual condition taking into account features of the given concrete system is investigated.

Keywords: technological process, pseudoinversion, functional stability, minimax, individual operation management strategy.

References
1. Sobchuk V.V., Musienko A.P., Ilyin O.Y. Analysis of the use of a hierarchical structure to ensure the functional stability of the automated enterprise management system // Scientific journal "Telecommunication and information technologies". K .: DUT, 2018. No 4 (61). P. 53 - 61.
2. Sobchuk V.V., Koval M.O., Musienko A.P., Matsko O.Y. Method of diagnosing hidden failures in the information system based on the use of a two-level system of functional stability // Scientific journal "Telecommunication and information technologies". К.: ДУТ, 2019. № 1 (62). P. 22 - 31.
3. Barabash O.V., Lukova-Chuyko N.P., Musienko A.P., Sobchuk V.V. Ensuring the functional stability of information networks based on the development of a method of counteracting DDoS attacks // Modern information systems. Kharkiv: National Technical University "Kharkiv Polytechnic Institute", 2018. Volume 2. № 1. P. 56-63.
4. Sobchuk V.V., Laptev O.A., Salanda I.P., Sachuk Y.V. Mathematical model of information network structure on the basis of non-stationary hierarchical and stationary hypernetwork // Collection of scientific works of the Military Institute of Kyiv Taras Shevchenko National University. K.: WINDOW, 2019. Issue. 64. P. 124 - 132.
5. Kuchuk N.G., Lukova-Chuiko N.V., Sobchuk V.V. Optimization of bandwidth of communication channels of hyperconvective system // Scientific periodical "Control, navigation and communication systems". — Poltava: PNTU, 2019. Vip 3 (55). Р. 120–125.
6. Sobchuk V.V. Methods of creating a single information space at a production enterprise with a functionally stable production process // Scientific periodical "Control, navigation and communication systems". — Poltava: PNTU, 2019. Vip. 6 (58). Р. 84 - 91.
7. Sobchuk V., Pichkur V. On conditions for ensuring of functional stability of information systems in a manufacturing enterprise // Abstracts of XIX International Scientific and Practical Conference. Brussels, Belgium. April 08-09, 2021. P. 219-221.
8. Abramov V. State prediction and condition-based maintenance of complex engineering systems under heavy-duty service // Reliability and Quality of Complex Systems. № 3 (31), 2020. P. 5–14.
9. Albert, Arthur. Regression and the Moore-Penrose pseudoinverse. Burlington, MA: Elsevier, 1972. – 195 p.
10. Bellman R., Dreyfus S. Applied problems of dynamic programming. Moscow: Nauka. 1965. — 458 p.
11. Mashkov O.A., Sobchuk V.V., Barabash O.V., Dakhno N.B., Shevchenko H.V., Maisak T.V. Improvement of variational-gradient method in dynamic systems of automated control for integro-differential models // Mathematical Modeling and Computing, 2019, Vol. 6, no. 2, P. 344-357.
12. Barabash O.V., Dakhno N.B., Shevchenko H.V., Majsak T.V. Dynamic Models of Decision Support Systems for Controlling UAV by Two-Step Variational-Gradient Method // Proceedings of 2017 IEEE 4th International Conference “Actual Problems of Unmanned Aerial Vehicles Developments (APUAVD)”, October 17-19, 2017, Kyiv, Ukraine. National Aviation University, 2017, P. 108-111.
13. Barabash O.V., Bodrov S.V., Musienko A.P. Analysis of the construction of a network of video surveillance of customs observation posts based on a functionally stable system // Scientific and practical journal "Communication". Kyiv, DUT, 2014. № 2. P. 8-11.
14. Mashkov O.A., Barabash O.V. Assessment of functional stability of distributed information and control systems // Physical and mathematical modeling and information technology: Collection of scientific works. Lviv, Center for Mathematical Modeling of the Institute of Applied Problems of Mechanics and Mathematics named after J.S. Hairdresser of the National Academy of Sciences of Ukraine, 2005. Issue. 1. P. 159-165.
15. Barabash O.V., Durnyak B.V., Mashkov O.A., Obidin D.M. Ensuring the functional stability of complex technical systems // Modeling and information technology: Coll. Science. Kyiv, Institute of Modeling Problems in Energy named after G.Ye. Pukhova NAS of Ukraine, 2012. Issue. 64. P. 36-41.