Testing the First Order Accurate Godunov Method on Some Prototype and Applied Problems

被引:1
作者
Bocharova O.V. [1 ]
Lebedev M.G. [1 ]
机构
[1] Faculty of Computational Mathematics and Cybernetics, Moscow State University, Moscow
来源
Computational Mathematics and Modeling | 2017年 / 28卷 / 1期
关键词
first-order difference scheme; Godunov method; jet flows; testing;
D O I
10.1007/s10598-016-9342-1
中图分类号
学科分类号
摘要
The Godunov method of first order accuracy continues to attract the attention of researchers both because of its simple implementation and its sufficiently high numerical accuracy subject to relatively modest resource requirements. However, it is necessary to constantly verify that the method indeed produces acceptable accuracy. We test the method on a number of one- and two-dimensional prototype problems and compare the results with analytical and numerical solutions obtained by higher accuracy schemes. The results for the method tested are quite acceptable. We also compare the solutions of applied problems on flows in supersonic, freely expanding jets and on supersonic flow past blunt bodies. The results for these problems are also positive. © 2016, Springer Science+Business Media New York.
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页码:18 / 31
页数:13
相关论文
共 28 条
[1]  
Bocharova O.V., Lebedev M.G., Simulation of nonstationary interaction of a jet with a barrier, Matem. Modelirovanie, 19, 8, pp. 31-36, (2007)
[2]  
Lebedev M., Bocharova O., Self-oscillatory regimes of the sonic jet/flat plate interaction: Theoretical predictions vs. experimental data, West-East High Speed Flow Field Conference, 19-22 November, 2007, pp. 190-191, (2007)
[3]  
Bocharova O.V., Simulation of self-oscillatory interaction of a sonic underexpanded jet with a barrier, Uchenye Zapiski TsAGI, 41, 2, pp. 59-64, (2010)
[4]  
Bocharova O.V., Lebedev M.G., Self-oscillatory interaction regimes of a supersonic underexpanded jet with barriers, Khim. Fizika, 30, 7, pp. 40-47, (2011)
[5]  
Bocharova O.V., Simulation of self-oscillations in a supersonic jet impinging on a Harmann tube, Matem. Modelirovanie, 25, 9, pp. 75-91, (2013)
[6]  
Hartmann J., On a new method for the generation of sound waves, Physical Review, 20, 6, pp. 719-727, (1922)
[7]  
Raman G., Srinivasan K., The powered resonance tube: From Hartmann’s discovery to current active flow applications, Progress in Aerospace Science, 45, pp. 97-123, (2009)
[8]  
Godunov S.K., A difference method for numerical calculation of discontinuous solutions of the equations of hydrodynamics, Matem. Sb., 42, 3, pp. 271-306, (1959)
[9]  
Godunov S.K., Zabrodin A.V., Ivanov M.Y., Kraiko A.N., Prokopov G.P., Numerical Solution of Multidimensional Problems of Gas Dynamics [in Russian], (1976)
[10]  
Tunik Y.V., Detonation combustion of hydrogen in a Laval nozzle with a central coaxial cylinder, Izv. RAN, Mekhanika Zhidkosti i Gaza, 5, pp. 142-148, (2014)
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