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Technology of large-scale objects system optimization

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Języki publikacji
EN
Abstrakty
EN
The analysis of system factors determining the efficiency of large-scale objects is performed. Structural description and purposes of large-scale objects constructing are formalized. A three-level decomposition scheme for the problem of objects system optimization including the set of tasks for their system design, planning of development, adaptation and reengineering is proposed. The composition and the scheme of relationship on input and output data of the tasks between main stages of large-scale objects system optimization are determined. Based on the decomposition of the problem, its systemological analysis was carried out. This allowed to develop a technology for system optimization of large-scale objects, taking into account the relationship between the whole set of problem-related tasks.
Twórcy
  • Kharkiv National University of Radio Electronics, Nauka Ave, 14, Kharkov, 61166, Ukraine
  • Kharkiv National University of Radio Electronics, Nauka Ave, 14, Kharkov, 61166, Ukraine
Bibliografia
  • 1. Vasilyev S. N., Makarov A. A., Makarov V. L., Mahutov N. A. 2015. Management of large-scale systems development. Modern problems. Issue 2. Moscow: Publishing House Phys-Math. Literature, 477 (in Russian).
  • 2. Bezruk V. M., Chebotareva D. V., Skorik Yu. V. 2017. Multicriteria analysis and choice of telecommunications means. Kharkiv: FOP Koryak S.F., 268 (in Russian).
  • 3. Tkachenko V. I. , Smirnov Ye. B., Romanenko I. O. 2013. Information systems and troop networks. Ch. 1. Kharkiv: HUPS, 328 (in Ukrainian).
  • 4. Zhivitskaya H. 2014. Topological properties and methodology of research of complex logistic systems efficiency. ECONTECHMOD. Vol. 3(3), 23–32.
  • 5. Karpukhin A., Gritsiv D., Tkachenko A. 2014. Mathematical simulation of infocommunication networks Applying chaos theory. ECONTECHMOD. Vol. 3(3), 33–42.
  • 6. Petrov E. G., Pisklakova V. P., Beskorovainyi V. V. 1992. Geographically distributed service systems. Кiev: Тehnika, 208 (in Russian).
  • 7. Klir G. 1990. Architecture of systems problem solving. Moskva: Radio and communications, 544 (in Russian).
  • 8. Beskorovainyi V. V. 2002. Systemological analysis of the problem of geographically distributed systems structural synthesis. Automated control and automation systems. №120, 29-37 (in Russian).
  • 9. Timchenko A. А. 2000. Basics of system design and analysis of complex objects: In 2 books. Book 1. Fundamentals of CAD and system design of complex objects. Kiev: Lybid, 272 (in Ukrainian).
  • 10. Beskorovainyi V. V. 2002. Synthesis of the logical scheme for territorially distributed systems system design. Radioelectronics and Informatics. №3, 94-96 (in Russian).
  • 11. Beskorovainyi V. V. and Podoliaka K. E. 2015. Development of a systemological model of the problem for large-scale monitoring systems structural and topological reengineering. Eastern-European Journal of Eenterprise Technologies. Vol. 3(75), 37–42 (in Russian).
  • 12. Beskorovainyi V. V. and Podoliaka K. E. 2015. Development model of multicriteria problem for reengineering topological structure of large-scale monitoring system. Eastern-European Journal of Eenterprise Technologies. Vol. 4(76), 49–55 (in Russian).
  • 13. Оvezgeldiev A. O., Petrov E. G. and Petrov K. E. 2002. Synthesis and identification of multifactorial models for estimation and optimization. Кiev: Naukova dumka, 164 (in Russian).
  • 14. Kruchkovskyi V. V., Petrov E. G., Sokolova N. A. and Hodakov V. E. 2013. Introduction to the normative theory of decision-making. – Herson: Grin D.S., 284 (in Russian).
  • 15. Greco S., Ehrgott M. 2016. Multiple Criteria Decision Analysis – State of the Art Surveys. New York: Springer, 1346.
  • 16. Kaliszewski I., Miroforidis I., Podkopaev D. 2016. Multiple Criteria Decision Making by Multi-objective Optimization – A Toolbox. New York: Springer, 142.
  • 17. Beskorovainyi V. V. and Podoliaka K. E. 2015. Reengineering the topological structure of large-scale monitoring systems. ECONTECHMOD. Vol. 4 (3), 13–18.
  • 18. Beskorovainyi V. V. and Podoliaka K. E. 2015. The method for reengineering of large-scale monitoring systems topological structures. Applied Radio-electronics. Vol. 14 (3), 204-209 (in Russian).
  • 19. Beskorovainyi V. V. and Podoliaka K. E. 2015. Modifications of the directional search method for reengineering of large-scale monitoring systems topological structures. Radioelectronics and Informatics. №3 (70), 55-62 (in Russian).
  • 20.Beskorovainyi V. V. and Podoliaka K. E. 2016. Selection multicriteria decision in process of reengineering the topological structure of large-scale monitoring systems. Information Processing Systems. № 5(142), 80–86 (in Russian).
  • 21. Beskorovainyi V. V., Podoliaka K. E.,Moskalenko A. S. 2016. Multifactor estimation of variants of reengineering of large-scale objects on the basis of comparator identification. Electro-technical and computer systems. № 23 (99), 192–200 (in Russian).
  • 22. Beskorovainyi V. V.,Moskalenko A. S. 2016. Formation and selection of solutions in projects for optimization of large-scale objects. Technology of instrument making. №2, 11–14 (in Russian).
  • 23. Beskorovainyi V. V., Podoliaka K. E. 2015. Formalization of Partial Performance Criteria for Reengineering Projects of Large-Scale Monitoring Systems. Modeling processes in economics and project management using new information technologies. Kharkiv: KHNURE, 181-190 (in Ukrainian)
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-5d27c6b0-9c2f-4023-9186-5a7036fe9d27
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