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№ 2 (16) – 2021
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THE USE OF NESTED ADAPTIVE GRIDS FOR MODELING HEAT TRANSFER PROCESSES IN INFORMATION AND CONTROL SYSTEMS OF COMPLEX EQUIPMENT SAMPLES
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https://doi.org/10.37129/2313-7509.2021.16.59-65
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O. Gumen, Doctor of Technical Sciences, Professor |
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G. Smakokovska |
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Yu. Maksymenko, Cand. of Technical Sciences |
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Cite in the List of bibliographic references (DSTU 8302:2015)
Гумен О. М., Смаковська Г. М., Максименко Ю. А. Використання вкладених адаптивних сіток для моделювання процесів теплопередачі в інформаційно-керуючих системах складних зразків техніки. Збірник наукових праць Військової академії (м. Одеса). 2021. Вип. 2(16). С. 59-65. https://doi.org/10.37129/2313-7509.2021.16.59-65
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Abstract
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Modeling of processes on the use of adaptive grids for information and control systems of complex samples of equipment is offered. Application in the simulation of various natural phenomena and processes have obtained differential equations with partial derivatives. The principle of replacing the continuous domain of the unknown function by a discrete set of points (grid) is the basis of numerical methods for solving such equations. The complex solution of such problems is a definite scientific problem, the solution of which determines the accuracy of the numerical solution in areas where the gradient of the desired function reaches large values, significantly affects the accuracy of the solution throughout the region.
The study considers the method of constructing nested adaptive difference grids for modeling heat transfer processes in information-control systems of complex samples of equipment, which are condensed in zones of rapid change of the desired function to solve two-dimensional nonstationary equation of thermal conductivity. Existing methods of constructing non-uniform grids before calculations, based on finding possible zones of high gradients are not effective in non-stationary problems, where these zones can change their position over time.
The proposed algorithm for finding zones with significant gradients of the desired function in the process of the task analyzes the behavior of the function, controls the error and builds a time variable and a non-uniform difference grid. This significantly reduces the machine time required to solve problems with significant gradients in some areas of the computational domain. The solution of the problem for the main and nested grids can be performed in parallel, which will further reduce the time to solve when using multi-core systems.
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Keywords
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computer model, finite difference method, difference mesh, nested mesh, modeling of heat transfer processes, information and control systems.
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List of bibliographic references
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Teschl G. Ordinary Differential Equations and Dynamical Systems. Graduate Studies in Mathematics. 2012. Vol. 140. DOI: http:/dx.doi.org/10.1090/gsm/140
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Годунов С. К., Рябенький В. С. Введение в теорию разностных схем. Москва, 1962. С. 272–274.
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Самарский А. А. Введение в теорию разностных схем. Москва, 1971. С. 538–550.
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Рихтмайер Р., Мортон К. Разностные методы решения краевых задач / ред.: Б. Бурдак, А. Горбунов ; пер. з англ. Б. Будак та ін. Москва : Мир, 1972. С. 381–413.
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Gumen O., Spodyniuk N., Ulewicz M., Martyn Ye. Research of thermal processes in industrial premises with energy-saving technologies of heating: Diagnostyka. 2017. Vol. 18,No. 2. P. 43–49.
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Яненко Н.Н.Методы дробных шагов решения многомерных задач математической физики. Новосибирск, 1967. С.189–193.
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Лисейкин В.Д. Обзор методов построения структурных адаптивных сеток: Журнал вычислительной математики и математической физики. 1996. Т.36, №1. С. 3–41.
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Лук’яненко С. О. Адаптивні обчислювальні методи моделювання об’єктів з розподіленими параметрами. К.: IВЦ “Видавництво «Політехніка»”. 2004. 236 с.
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Spall M.A., Holland W.R. A nested primitive equation model for oceanic applications. Journal of Physical Oceanography. 1991. № 21. P. 205–220.
-
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Martin P.J. Description of the Navy Coastal Ocean Model Version 1.0. Naval Research Laboratory Technical Report. 2000. 45 p.
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Белоцерковская М. С., Опарин А. М. Использование вложенных сеток для моделирования процесса фильтрации. Математическое моделирование. 2004. Т.16, №12. С. 3–10.
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References
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Teschl,G. (2012). OrdinaryDifferentialEquationsandDynamicalSystems. GraduateStudiesinMathematics, Vol. 140. DOI: http:/dx.doi.org/10.1090/gsm/140 [in English].
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Godunov,S. K., & Ryabenkiy,V.S. (1962). Introduction to the theory of difference schemes.Moskva [in Russian].
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Samarskiy, A. A. (1971). Introduction to the theory of difference schemes. Moskva [in Russian].
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Richtmeier, R., & Morton, K. (1972). Difference methods for solving boundary value problems (B. Burdak & A. Gorbunov, Eds.; B. Budak, A. Gorbunov, V. Kondrasheva & V. Troshchieva, Trans.). Mir [in Russian].
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Gumen, O. Spodyniuk, N., Ulewicz, M., & Martyn, Ye. (2017). Research of thermal processes in industrial premises with energy-saving technologies of heating. Diagnostyka, Vol. 18, 2(2017), 43–49 [in English].
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Yanenko, N. N. (1967). Fractional Step Methods for Solving Multidimensional Problems in Mathematical Physics. Novosibirsk [in Russian].
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Liseykin, V. D. (1996). Review of methods for constructing structural adaptive meshes. Zhurnal vyichislitelnoy matematiki i matematicheskoy fiziki. Vol. 36, 1, 3–41 [in Russian].
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Luk'yanenko, S. O. (2004). Adaptive computational methods for modeling objects with distributed parameters. Kyiv: IVTs Vidavnitstvo «PolItehnIka» [in Ukrainian].
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Spall, M. A., & Holland, W. R. (1991). A nested primitive equation model for oceanic applications. Journal of Physical Oceanography, 21, 205–220 [in English].
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Martin, P. J. (2000). Description of the Navy Coastal Ocean Model Version 1.0. Naval Research Laboratory Technical Report [in English].
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Belotserkovskaya, M. S., & Oparin, A. M. (2004). Using nested grids to simulate the filtering process. Mathematicalmodeling, Vol.16, 12, 3–10 [inRussian].
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