Extracting the Spectrum by Spatial Filtering
Abstract
We show that the spectrum of a flow field can be extracted within a local region by straightforward filtering in physical space. We find that for a flow with a certain level of regularity, the filtering kernel must have a sufficient number of vanishing moments in order for the "filtering spectrum" to be meaningful. Our derivation follows a similar analysis by Perrier et al. 1995 for the wavelet spectrum, where we show that the filtering kernel has to have at least vanishing moments in order to correctly extract a spectrum with . For example, any flow with a spectrum shallower than can be extracted by a straightforward average on grid-cells of a stencil. We construct two new "simple stencil" kernels, and , with only two and three fixed stencil weight coefficients, respectively, and that have sufficient vanishing moments to allow for extracting spectra steeper than . We demonstrate our results using synthetic fields, 2D turbulence from a Direct Numerical Simulation, and 3D turbulence from the JHU Database. Our method guarantees energy conservation and can extract spectra of non-quadratic quantities self-consistently, such as kinetic energy in variable density flows, which the wavelet spectrum cannot. The method can be useful in both simulations and experiments when a straightforward Fourier analysis is not justified, such as within coherent flow structures covering non-rectangular regions, in multi-phase flows, or in geophysical flows on Earth's curved surface.
Cite
@article{arxiv.1811.08259,
title = {Extracting the Spectrum by Spatial Filtering},
author = {Mahmoud Sadek and Hussein Aluie},
journal= {arXiv preprint arXiv:1811.08259},
year = {2018}
}
Comments
32 pages, 8 figures, accepted in Physical Review Fluids