Compact representation of wall-bounded turbulence using compressive sampling
Compact representation of wall-bounded turbulence using compressive sampling
Compressive sampling is well-known to be a useful tool used to resolve the energetic content of signals that admit a sparse representation. The broadband temporal spectrum acquired from point measurements in wall-bounded turbulence has precluded the prior use of compressive sampling in this kind of flow, however it is shown here that the frequency content of flow fields that have been Fourier transformed in the homogeneous spatial (wall-parallel) directions is approximately sparse, giving rise to a compact representation of the velocity field. As such, compressive sampling is an ideal tool for reducing the amount of information required to approximate the velocity field. Further, success of the compressive sampling approach provides strong evidence that this representation is both physically meaningful and indicative of special properties of wall turbulence. Another advantage of compressive sampling over periodic sampling becomes evident at high Reynolds numbers, since the number of samples required to resolve a given bandwidth with compressive sampling scales as the logarithm of the dynamically significant bandwidth instead of linearly for periodic sampling. The combination of the Fourier decomposition in the wall-parallel directions, the approximate sparsity in frequency, and empirical bounds on the convection velocity leads to a compact representation of an otherwise broadband distribution of energy in the space defined by streamwise and spanwise wavenumber, frequency, and wall-normal location. The data storage requirements for reconstruction of the full field using compressive sampling are shown to be significantly less than for periodic sampling, in which the Nyquist criterion limits the maximum frequency that can be resolved. Conversely, compressive sampling maximizes the frequency range that can be recovered if the number of samples is limited, resolving frequencies up to several times higher than the mean sampling rate. It is proposed that the approximate sparsity in frequency and the corresponding structure in the spatial domain can be exploited to design simulation schemes for canonical wall turbulence with significantly reduced computational expense compared with current techniques
1-21
Bourguignon, J.-L.
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Tropp, J.A.
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Sharma, A.S.
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McKeon, B.J.
2e685015-292a-42a7-8c9e-7cc27cf2da67
22 January 2014
Bourguignon, J.-L.
d0af4ac3-8e59-4a9b-bcf7-8318ca124a97
Tropp, J.A.
1ac64eb2-cb87-4b6a-9ae3-fd487c5b0d81
Sharma, A.S.
cdd9deae-6f3a-40d9-864c-76baf85d8718
McKeon, B.J.
2e685015-292a-42a7-8c9e-7cc27cf2da67
Bourguignon, J.-L., Tropp, J.A., Sharma, A.S. and McKeon, B.J.
(2014)
Compact representation of wall-bounded turbulence using compressive sampling.
Physics of Fluids, 26 (15109), .
(doi:10.1063/1.4862303).
Abstract
Compressive sampling is well-known to be a useful tool used to resolve the energetic content of signals that admit a sparse representation. The broadband temporal spectrum acquired from point measurements in wall-bounded turbulence has precluded the prior use of compressive sampling in this kind of flow, however it is shown here that the frequency content of flow fields that have been Fourier transformed in the homogeneous spatial (wall-parallel) directions is approximately sparse, giving rise to a compact representation of the velocity field. As such, compressive sampling is an ideal tool for reducing the amount of information required to approximate the velocity field. Further, success of the compressive sampling approach provides strong evidence that this representation is both physically meaningful and indicative of special properties of wall turbulence. Another advantage of compressive sampling over periodic sampling becomes evident at high Reynolds numbers, since the number of samples required to resolve a given bandwidth with compressive sampling scales as the logarithm of the dynamically significant bandwidth instead of linearly for periodic sampling. The combination of the Fourier decomposition in the wall-parallel directions, the approximate sparsity in frequency, and empirical bounds on the convection velocity leads to a compact representation of an otherwise broadband distribution of energy in the space defined by streamwise and spanwise wavenumber, frequency, and wall-normal location. The data storage requirements for reconstruction of the full field using compressive sampling are shown to be significantly less than for periodic sampling, in which the Nyquist criterion limits the maximum frequency that can be resolved. Conversely, compressive sampling maximizes the frequency range that can be recovered if the number of samples is limited, resolving frequencies up to several times higher than the mean sampling rate. It is proposed that the approximate sparsity in frequency and the corresponding structure in the spatial domain can be exploited to design simulation schemes for canonical wall turbulence with significantly reduced computational expense compared with current techniques
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Published date: 22 January 2014
Organisations:
Aerodynamics & Flight Mechanics Group
Identifiers
Local EPrints ID: 364748
URI: http://eprints.soton.ac.uk/id/eprint/364748
ISSN: 1070-6631
PURE UUID: 628ba145-19c2-43a4-91ef-0c61fdbcd758
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Date deposited: 12 May 2014 10:57
Last modified: 15 Mar 2024 03:46
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Author:
J.-L. Bourguignon
Author:
J.A. Tropp
Author:
A.S. Sharma
Author:
B.J. McKeon
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