Wavelet decomposition of forced turbulence: Applicability of the iterative Donoho-Johnstone threshold

Jesse W. Lord; Mark P. Rast; Christopher Mckinlay; John Clyne; Pablo D. Mininni

doi:10.1063/1.3683556

Wavelet decomposition of forced turbulence: Applicability of the iterative Donoho-Johnstone threshold

Jesse W. Lord
, Mark P. Rast
, Christopher Mckinlay
, John Clyne
, Pablo D. Mininni

Visualization and Analysis Software Team

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

We examine the decomposition of forced Taylor-Green and Arn'old-Beltrami-Childress (ABC) flows into coherent and incoherent components using an orthonormal wavelet decomposition. We ask whether wavelet coefficient thresholding based on the Donoho-Johnstone criterion can extract a coherent vortex signal while leaving behind Gaussian random noise. We find that no threshold yields a strictly Gaussian incoherent component, and that the most Gaussian incoherent flow is found for data compression lower than that achieved with the fully iterated Donoho-Johnstone threshold. Moreover, even at such low compression, the incoherent component shows clear signs of large-scale spatial correlations that are signatures of the forcings used to drive the flows.

Original language	English
Article number	025102
Journal	Physics of Fluids
Volume	24
Issue number	2
DOIs	https://doi.org/10.1063/1.3683556
State	Published - Feb 3 2012

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title = "Wavelet decomposition of forced turbulence: Applicability of the iterative Donoho-Johnstone threshold",

abstract = "We examine the decomposition of forced Taylor-Green and Arn'old-Beltrami-Childress (ABC) flows into coherent and incoherent components using an orthonormal wavelet decomposition. We ask whether wavelet coefficient thresholding based on the Donoho-Johnstone criterion can extract a coherent vortex signal while leaving behind Gaussian random noise. We find that no threshold yields a strictly Gaussian incoherent component, and that the most Gaussian incoherent flow is found for data compression lower than that achieved with the fully iterated Donoho-Johnstone threshold. Moreover, even at such low compression, the incoherent component shows clear signs of large-scale spatial correlations that are signatures of the forcings used to drive the flows.",

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T2 - Applicability of the iterative Donoho-Johnstone threshold

AU - Lord, Jesse W.

AU - Rast, Mark P.

AU - Mckinlay, Christopher

AU - Clyne, John

AU - Mininni, Pablo D.

PY - 2012/2/3

Y1 - 2012/2/3

N2 - We examine the decomposition of forced Taylor-Green and Arn'old-Beltrami-Childress (ABC) flows into coherent and incoherent components using an orthonormal wavelet decomposition. We ask whether wavelet coefficient thresholding based on the Donoho-Johnstone criterion can extract a coherent vortex signal while leaving behind Gaussian random noise. We find that no threshold yields a strictly Gaussian incoherent component, and that the most Gaussian incoherent flow is found for data compression lower than that achieved with the fully iterated Donoho-Johnstone threshold. Moreover, even at such low compression, the incoherent component shows clear signs of large-scale spatial correlations that are signatures of the forcings used to drive the flows.

AB - We examine the decomposition of forced Taylor-Green and Arn'old-Beltrami-Childress (ABC) flows into coherent and incoherent components using an orthonormal wavelet decomposition. We ask whether wavelet coefficient thresholding based on the Donoho-Johnstone criterion can extract a coherent vortex signal while leaving behind Gaussian random noise. We find that no threshold yields a strictly Gaussian incoherent component, and that the most Gaussian incoherent flow is found for data compression lower than that achieved with the fully iterated Donoho-Johnstone threshold. Moreover, even at such low compression, the incoherent component shows clear signs of large-scale spatial correlations that are signatures of the forcings used to drive the flows.

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DO - 10.1063/1.3683556

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JO - Physics of Fluids

JF - Physics of Fluids

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M1 - 025102

ER -

Wavelet decomposition of forced turbulence: Applicability of the iterative Donoho-Johnstone threshold

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