Justification of the Courant-Friedrichs Conjecture for the Problem about Flow around Wedge ( Mathematics Research Developments )

Publication series :Mathematics Research Developments

Author: Alexander M. Blokhin   D.L. Tkachev and Evgeniya Mishchenko (Sobolev Institute of Mathematics   Siberian Branch of the Russian Academy of Sciences   Novosibirsk   Russia)  

Publisher: Nova Science Publishers, Inc.‎

Publication year: 2013

E-ISBN: 9781626181700

Subject: O354.5 shock (wave)

Keyword: Mathematics

Language: ENG

Access to resources Favorite

Disclaimer: Any content in publications that violate the sovereignty, the constitution or regulations of the PRC is not accepted or approved by CNPIEC.

Description

The classical problem about a steady-state supersonic flow of an inviscid non-heat-conductive gas around an infinite plane wedge under the assumption that the angle at the vertex of the wedge is less than some limit value is considered. The gas is supposed to be in the state of thermodynamical equilibrium and admits the existence of a state equation. As is well-known, the problem has two discontinuous solutions, one of which is associated with a strong shock wave (the gas velocity behind the shock wave is less than the sound speed) and the second one corresponds to the weak shock wave (the gas velocity behind the shock wave is, in general, larger than the sound speed) (Courant R, Friedrichs K.O. Supersonic flow and shock waves. N. Y.: Interscience Publ. Inc., 1948). One of the possible explanations of this phenomenon was given by Courant and Friedrichs. They conjectured that the solution corresponding to the strong shock wave is instable in the sense of Lyapunov, whereas the solution corresponding to the weak shock wave is stable. This conjecture has been confirmed in a number of studies in which either particular cases were considered or the proposed argumentation was given at the qualitative (mostly, physical) level of rigor. In this monograph, the Courant-Friedrichs conjecture is strictly mathematically justified at the linear level. The mechanism of generating the instability for the case of a strong shock is explained. The smoothness of the solution essentially depends

The users who browse this book also browse