Turbulence spectrum: Difference between revisions
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If a measured quantity, say <math>\zeta</math>, has a spectrum, <math>\Psi(k)</math>, then this spectrum provides the wavenumber distribution of the variance of <math>\zeta</math>. | If a measured quantity, say <math>\zeta</math>, has a spectrum, <math>\Psi(k)</math>, then this spectrum provides the wavenumber distribution of the variance of <math>\zeta</math>. | ||
For example, | For example, | ||
<math>\overline{\zeta^2}=\int_0^{\infty} \Psi(k)\, \mathrm{d}k </math> | <math>\overline{\zeta^2}=\int_0^{\infty} \Psi(k)\, \mathrm{d}k </math> | ||
provides the total variance of <math>\zeta</math>, while | |||
<math>\int_{k_1}^{k_2} \Psi(k)\, \mathrm{d}k </math> | |||
provides the variance of <math>\zeta</math> that resides in the wavenumber band of <math>k_1</math> to <math>k_2</math>. | |||
* Missing the y-axi variables | * Missing the y-axi variables | ||
* Lowest frequency and wavenumber resolvable | * Lowest frequency and wavenumber resolvable | ||
Revision as of 19:27, 1 December 2021
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| Turbulence energy cascade and its expected spectral representation |
This is the common definition for Turbulence spectrum, but other definitions maybe discussed within the wiki.
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Spectra in the frequency domain are converted into the spatial domain via Taylor's Frozen Turbulence hypothesis. Convert time derivatives to spatial gradients along the direction of profiling using
<math> \frac{\partial}{\partial x} = \frac{1}{U_P} \frac{\partial}{\partial t} </math> .
Convert frequency spectra into wavenumber spectra using
<math> k = f/U_P </math> and <math> \Psi(k) = U_P \Psi(f) </math> .
If a measured quantity, say <math>\zeta</math>, has a spectrum, <math>\Psi(k)</math>, then this spectrum provides the wavenumber distribution of the variance of <math>\zeta</math>. For example,
<math>\overline{\zeta^2}=\int_0^{\infty} \Psi(k)\, \mathrm{d}k </math>
provides the total variance of <math>\zeta</math>, while
<math>\int_{k_1}^{k_2} \Psi(k)\, \mathrm{d}k </math>
provides the variance of <math>\zeta</math> that resides in the wavenumber band of <math>k_1</math> to <math>k_2</math>.
- Missing the y-axi variables
- Lowest frequency and wavenumber resolvable
