Journal of Applied Mathematics

  • J. Appl. Math.
  • Volume 2012, Special Issue (2012), Article ID 783101, 30 pages.

The Technique of MIEELDLD in Computational Aeroacoustics

A. R. Appadu

Full-text: Open access

Abstract

The numerical simulation of aeroacoustic phenomena requires high-order accurate numerical schemes with low dispersion and low dissipation errors. A technique has recently been devised in a Computational Fluid Dynamics framework which enables optimal parameters to be chosen so as to better control the grade and balance of dispersion and dissipation in numerical schemes (Appadu and Dauhoo, 2011; Appadu, 2012a; Appadu, 2012b; Appadu, 2012c). This technique has been baptised as the Minimized Integrated Exponential Error for Low Dispersion and Low Dissipation (MIEELDLD) and has successfully been applied to numerical schemes discretising the 1-D, 2-D, and 3-D advection equations. In this paper, we extend the technique of MIEELDLD to the field of computational aeroacoustics and have been able to construct high-order methods with Low Dispersion and Low Dissipation properties which approximate the 1-D linear advection equation. Modifications to the spatial discretization schemes designed by Tam and Webb (1993), Lockard et al. (1995), Zingg et al. (1996), Zhuang and Chen (2002), and Bogey and Bailly (2004) have been obtained, and also a modification to the temporal scheme developed by Tam et al. (1993) has been obtained. These novel methods obtained using MIEELDLD have in general better dispersive properties as compared to the existing optimised methods.

Article information

Source
J. Appl. Math., Volume 2012, Special Issue (2012), Article ID 783101, 30 pages.

Dates
First available in Project Euclid: 17 October 2012

Permanent link to this document
https://projecteuclid.org/euclid.jam/1350488782

Digital Object Identifier
doi:10.1155/2012/783101

Mathematical Reviews number (MathSciNet)
MR2915728

Zentralblatt MATH identifier
1244.76071

Citation

Appadu, A. R. The Technique of MIEELDLD in Computational Aeroacoustics. J. Appl. Math. 2012, Special Issue (2012), Article ID 783101, 30 pages. doi:10.1155/2012/783101. https://projecteuclid.org/euclid.jam/1350488782


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