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Aero-acoustics and noise

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== Introduction ==
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== Different Methods ==
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=== DNS ===
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=== Green's Function ===
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=== incompressible/acoustic splitting ===
==Higher Order Schemes for Aero-acoustics==
==Higher Order Schemes for Aero-acoustics==
=== Necessity ===
=== Necessity ===

Revision as of 07:45, 12 November 2005

Contents

Introduction

Different Methods

DNS

Green's Function

incompressible/acoustic splitting

Higher Order Schemes for Aero-acoustics

Necessity

Acoustic problems are governed by the linearised Euler equation and it is known from wave propagation theory that the propagation characteristics of waves governed by a system of partial different equations are encoded in the dispersion relation.The dispersion relation of a system of equation can be used to determine the isotropy,group and phase velocities of all kinds of waves supported by the system of equations.With this idea in mind it is clear that we need a finite difference scheme which has almost similar dispersion relation to the original system of equations.It is well known that the first order schemes lead to excessive dissipation error and second order schemes have a lot of dispersion errors.This motivated the study to develop a class of finite difference schemes which can be suited to the modelling of wave propagation problems.This class of finite difference schemes are usually referred to as dispersion relation preserving schemes ( DRP Schemes ).

Construction of DRP Schemes

Stability

Implementation

Boundary Conditions

Reference

  • Tam et. al , Tam,C.K.W and Webb,J.C. (1992), "Dispersion relation preserving Finite Difference Schemes for Computational Acoustics,” Journal of Computational Physics", Journal of Computational Physics, Vol. 107, pp 262–281.
  • Lele, Lele, S. K. (1992), "Compact Finite Difference Schemes with Spectral-like Resolution,” Journal of Computational Physics", Journal of Computational Physics, Vol. 103, pp 16–42.
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