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Global relaxation procedures for a reduced form of the Navier-Stokes equations

  • S. G. Rubin
Invited Lectures
Part of the Lecture Notes in Physics book series (LNP, volume 218)

Keywords

Shock Wave AIAA Paper Transonic Flow Inviscid Flow Primitive Variable 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

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References

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    Rubin, S.G. and Lin, A. (1980), “Marching with the PNS Equations, Israel Journal of Technology 18, pp. 211–222.Google Scholar
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    Rubin, S.G. and Reddy, D.R. (1983), “Global PNS Solutions for Laminar and Turbulent Flow,” AIAA Paper No. 83-1911, see also University of Cincinnati Report No. AFL-84-101.Google Scholar
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    Ramakrishnan, S.V. and Rubin, S.G. (1984), “Global Pressure Relaxation for Compressible Flows with Full Pressure Coupling and Shock Waves.” University of Cincinnati, Report No. AFL-84-100.Google Scholar
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    Swanson, R.C., Rubin, S.G. and Khosla, P.K. (1983), “Calculation of Afterbody Flows with a Composite Velocity Formulation,” AIAA Paper No. 83-1736.Google Scholar
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    Rubin, S.G., Celestina, M. and Khosla, P.K. (1984), “Second-Order Composite Velocity Solution for Large Reynolds Number Flow,” AIAA Paper No. 84-0172.Google Scholar
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    Brandt, A. (1979), “Multi-Level Adaptive Computations in Fluid Dynamics,” AIAA Paper No. 79-1455.Google Scholar
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Copyright information

© Springer-Verlag 1985

Authors and Affiliations

  • S. G. Rubin
    • 1
  1. 1.University of CincinnatiCincinnati

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