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Compact high-order schemes for the Euler equations

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Abstract

An implicit approximate factorization (AF) algorithm is constructed, which has the following characteristics.

  • • In two dimensions: The scheme is unconditionally stable, has a 3×3 stencil and at steady state has a fourth-order spatial accuracy. The temporal evolution is time accurate either to first or second order through choice of parameter.

  • • In three dimensions: The scheme has almost the same properties as in two dimensions except that it is now only conditionally stable, with the stability condition (the CFL number) being dependent on the “cell aspect ratios,”Δy/Δx andΔz/Δx. The stencil is still compact and fourth-order accuracy at steady state is maintained.

Numerical experiments on a two-dimensional shock-reflection problem show the expected improvement over lower-order schemes, not only in accuracy (measured by theL 2 error) but also in the dispersion. It is also shown how the same technique is immediately extendable to Runge-Kutta type schemes, resulting in improved stability in addition to the enhanced accuracy.

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References

  1. Beam, R. M., and Warming, R. F. (1978). An implicit factored scheme for the compressible Navier-Stokes equations.AIAA J. 16, 393–401.

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  2. Jameson, A., Schmidt, W., and Turkel, E. (1981). Numerical solutions of the Euler equations by finite-volume methods using Runge-Kutta time-stepping schemes, AIAA Paper No. 81-1259.

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  4. Shapiro, R. (1988). Prediction of dispersive errors in numerical solutions of the Euler equations, submitted for presentation at the 2nd International Conference on Hyperbolic Problems, Aachen, West Germany.

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Authors and Affiliations

  1. School of Mathematics, Tel-Aviv University, Tel-Aviv, Israel

    Saul Abarbanel

  2. Computational Method Branch, Fluid Mechanics Division, NASA Langley Research Center, 23665, Hampton, Virginia

    Ajay Kumar

Authors
  1. Saul Abarbanel
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  2. Ajay Kumar
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Abarbanel, S., Kumar, A. Compact high-order schemes for the Euler equations. J Sci Comput 3, 275–288 (1988). https://doi.org/10.1007/BF01061287

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  • DOI: https://doi.org/10.1007/BF01061287

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