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* Turbulence at Re=2400 with m=2 symmetry.  L=2.5D (alpha=1.25) [[File:Re2400m2a1.25.tgz]]
* Turbulence at Re=2400 with m=2 symmetry.  L=2.5D (alpha=1.25) [[File:Re2400m2a1.25.tgz]]
* Turbulence at Re=4500 in the '2+epsilon' model.  L=10D [[File:Re4500.2eps.a0.314.tgz]]
* Turbulence at Re=4500 in the '2+epsilon' model.  L=10D [[File:Re4500.2eps.a0.314.tgz]]
* Turbulence at Re=5300. L=5D, Re_tau approx 150.
* Turbulence at Re=5300. L=5D, Re_tau approx 150. [[File:Re5300.Retau150.5D.tgz]]
* Puff at Re=1900.
* Localised puff at Re=1900, L=50D.  [[File:Re1900a0.0625.tgz]]


==Relative Equilibria==
==Relative Equilibria==

Revision as of 05:23, 20 July 2015

Below are files that can be manipulated or used as initial conditions, state.cdf.in. A Main.info should be provided with each state file containing parameter settings.

  • Files may be loaded with with different parameter settings. If there is a change in resolution, data will be interpolated or truncated automatically.
  • The state file contains spectral coefficients of the velocity perturbation. Each component has dimension (N,H,2), where N is the number of radial points, H is the number of Fourier coefficients, and 2 corresponds to real and imaginary parts. Indices [1,H] in the state file correspond to indices [0:H-1] in the code; see Core_implementation#Ordering_the_Fourier_modes.
  • For visualisation, data needs converting to real space. See comments in the file matlab/Readme.txt supplied with the code.


Sample Initial Conditions

Relative Equilibria

  • S1, S2...
  • M1, M2...
  • N1, N2...