Physics-based computational methods for aero-acoustics
Physics-based computational methods for aero-acoustics
This paper provides a review of several physics-based methods developed for predicting sound propagation in flows. The basic principle of physics-based methods is to incorporate some known properties of the underlying physics into the numerical model. For instance, instead of using standard polynomials or Chebyshev polynomials to interpolate the solution, physics-based methods generally use canonical solutions such as Green’s functions or plane waves to construct a local description of the solution. The methods described in this paper include the Green’s function discretisation, the partition of unity finite element method and the wave-based discontinuous Galerkin method. The principles of these methods are described and their performance and shortcomings are discussed. A key issue that emerges in several of these methods is that the canonical solutions are only valid for uniform coefficients, while the methods are intended to be used with strongly inhomogeneous propagation media.
computational aero-acoustics, physics-based, plane waves, green’s functions
183-192
Gabard, G.
bfd82aee-20f2-4e2c-ad92-087dc8ff6ce7
Astley, R.J.
4b0af3c5-9fc5-4f66-ac24-3a109c92e929
Kennedy, G.
9e416eb6-43c0-416c-bbe3-853bca90ee8c
March 2010
Gabard, G.
bfd82aee-20f2-4e2c-ad92-087dc8ff6ce7
Astley, R.J.
4b0af3c5-9fc5-4f66-ac24-3a109c92e929
Kennedy, G.
9e416eb6-43c0-416c-bbe3-853bca90ee8c
Gabard, G., Astley, R.J. and Kennedy, G.
(2010)
Physics-based computational methods for aero-acoustics.
[in special issue: IUTAM Symposium on Computational Aero-Acoustics for Aircraft Noise Prediction]
Procedia Engineering, 6, .
(doi:10.1016/j.proeng.2010.09.020).
Abstract
This paper provides a review of several physics-based methods developed for predicting sound propagation in flows. The basic principle of physics-based methods is to incorporate some known properties of the underlying physics into the numerical model. For instance, instead of using standard polynomials or Chebyshev polynomials to interpolate the solution, physics-based methods generally use canonical solutions such as Green’s functions or plane waves to construct a local description of the solution. The methods described in this paper include the Green’s function discretisation, the partition of unity finite element method and the wave-based discontinuous Galerkin method. The principles of these methods are described and their performance and shortcomings are discussed. A key issue that emerges in several of these methods is that the canonical solutions are only valid for uniform coefficients, while the methods are intended to be used with strongly inhomogeneous propagation media.
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Published date: March 2010
Venue - Dates:
IUTAM Symposium on Computational Aero-Acoustics for Aircraft Noise Prediction, Southampton, United Kingdom, 2010-03-29 - 2010-03-31
Keywords:
computational aero-acoustics, physics-based, plane waves, green’s functions
Identifiers
Local EPrints ID: 173003
URI: http://eprints.soton.ac.uk/id/eprint/173003
PURE UUID: df3fb19d-1c81-4c1d-b9c1-071049077e47
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Date deposited: 01 Feb 2011 12:00
Last modified: 14 Mar 2024 02:30
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Contributors
Author:
G. Gabard
Author:
R.J. Astley
Author:
G. Kennedy
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