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lbms.py
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lbms.py
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# -*- coding: utf-8 -*-
"""
Created on Wed Feb 18 11:59:29 2015
@author: tsaad
"""
#!/usr/bin/env python
from scipy import interpolate
import numpy as np
from numpy import pi
import time
import scipy
import scipy.io
from tkespec import compute_tke_spectrum
import isoturb
import isoturbo
import matplotlib.pyplot as plt
from fileformats import FileFormats
from filters import spectralcutoff
import isoio
#load an experimental specturm. Alternatively, specify it via a function call
cbcspec = np.loadtxt('cbc_spectrum.txt')
kcbc=cbcspec[:,0]*100
ecbc=cbcspec[:,1]*1e-6
especf = interpolate.interp1d(kcbc, ecbc,'cubic')
def cbc_specf(k):
return especf(k)
def power_spec(k):
Nu = 1*1e-3;
L = 0.1;
Li = 1;
ch = 1;
cl = 10;
p0 = 8;
c0 = pow(10,2);
Beta = 2;
Eta = Li/20.0;
ES = Nu*Nu*Nu/(Eta*Eta*Eta*Eta);
x = k*Eta
fh = np.exp(-Beta*pow(pow(x,4) + pow(ch,4), 0.25) - ch)
x = k*L
fl = pow( x/pow(x*x + cl, 0.5) , 5.0/3.0 + p0)
espec = c0*pow(k,-5.0/3.0)*pow(ES,2.0/3.0)*fl*fh
return espec
#----------------------------------------------------------------------------------------------
# __ __ ______ ________ _______ ______ __ __ _______ __ __ ________
#| \ | \ / \ | \| \ | \| \ | \| \ | \ | \| \
#| $$ | $$| $$$$$$\| $$$$$$$$| $$$$$$$\ \$$$$$$| $$\ | $$| $$$$$$$\| $$ | $$ \$$$$$$$$
#| $$ | $$| $$___\$$| $$__ | $$__| $$ | $$ | $$$\| $$| $$__/ $$| $$ | $$ | $$
#| $$ | $$ \$$ \ | $$ \ | $$ $$ | $$ | $$$$\ $$| $$ $$| $$ | $$ | $$
#| $$ | $$ _\$$$$$$\| $$$$$ | $$$$$$$\ | $$ | $$\$$ $$| $$$$$$$ | $$ | $$ | $$
#| $$__/ $$| \__| $$| $$_____ | $$ | $$ _| $$_ | $$ \$$$$| $$ | $$__/ $$ | $$
# \$$ $$ \$$ $$| $$ \| $$ | $$ | $$ \| $$ \$$$| $$ \$$ $$ | $$
# \$$$$$$ \$$$$$$ \$$$$$$$$ \$$ \$$ \$$$$$$ \$$ \$$ \$$ \$$$$$$ \$$
#----------------------------------------------------------------------------------------------
# specify whether you want to use threads or not to generate turbulence
use_threads = True
#set the number of modes you want to use to represent the velocity.
nmodes =250
# write to file
enableIO = False # enable writing to file
fileformat = FileFormats.FLAT # Specify the file format supported formats are: FLAT, IJK, XYZ
# save the velocity field as a matlab matrix (.mat)
savemat = False
# compute the mean of the fluctuations for verification purposes
computeMean = True
# input domain size in the x, y, and z directions. This value is typically
# based on the largest length scale that your data has. For the cbc data,
# the largest length scale corresponds to a wave number of 15, hence, the
# domain size is L = 2pi/15.
lx = 2.0*pi/15.0
ly = 2.0*pi/15.0
lz = 2.0*pi/15.0
# input number of cells (cell centered control volumes). This will
# determine the maximum wave number that can be represented on this grid.
# see wnn below
nx = 32 # number of cells in the x direction
ny = 32 # number of cells in the y direction
nz = 32 # number of cells in the z direction
# enter the smallest wavenumber represented by this spectrum
wn1 = 15 #determined here from cbc spectrum properties
#------------------------------------------------------------------------------
# END USER INPUT
#------------------------------------------------------------------------------
t0 = time.time()
if use_threads:
u,v,w = isoturbo.generate_isotropic_turbulence(lx,ly,lz,nx,ny,nz,nmodes,wn1,cbc_specf)
else:
u,v,w = isoturb.generate_isotropic_turbulence(lx,ly,lz,nx,ny,nz,nmodes,wn1,cbc_specf) # this doesnt support file formats yet
t1 = time.time()
print 'it took me ', t1 - t0, ' s to generate the isotropic turbulence.'
if (enableIO):
dx = lx/nx
dy = ly/ny
dz = lz/nz
if (use_threads):
isoio.writefileparallel(u,v,w,dx,dy,dz,fileformat)
else:
isoio.writefile('u.txt','x',dx,dy,dz,u,fileformat)
isoio.writefile('v.txt','y',dx,dy,dz,v,fileformat)
isoio.writefile('w.txt','z',dx,dy,dz,w,fileformat)
if(savemat):
data={} # CREATE empty dictionary
data['U'] = u
data['V'] = v
data['W'] = w
scipy.io.savemat('uvw.mat',data)
# compute mean velocities
if computeMean:
umean = np.mean(u)
vmean = np.mean(v)
wmean = np.mean(w)
print 'umean = ', umean
print 'vmean = ', vmean
print 'wmean = ', wmean
ufluc = umean - u
vfluc = vmean - v
wfluc = wmean - w
print 'u mean fluct = ', np.mean(ufluc)
print 'v mean fluct = ', np.mean(vfluc)
print 'w mean fluct = ', np.mean(wfluc)
ufrms = np.mean(ufluc*ufluc)
vfrms = np.mean(vfluc*vfluc)
wfrms = np.mean(wfluc*wfluc)
print 'u fluc rms = ', np.sqrt(ufrms)
print 'v fluc rms = ', np.sqrt(vfrms)
print 'w fluc rms = ', np.sqrt(wfrms)
# compute lbms bundles
ux = spectralcutoff(u,5,0,1,1)
vx = spectralcutoff(v,5,0,1,1)
wx = spectralcutoff(w,5,0,1,1)
uy = spectralcutoff(u,5,1,0,1)
vy = spectralcutoff(v,5,1,0,1)
wy = spectralcutoff(w,5,1,0,1)
uz = spectralcutoff(u,5,1,1,0)
vz = spectralcutoff(v,5,1,1,0)
wz = spectralcutoff(w,5,1,1,0)
# verify that the generated velocities fit the spectrum
knyquist, wavenumbers, tkespec = compute_tke_spectrum(u,v,w,lx,ly,lz, True)
knyquistx, wavenumbersx, tkespecx = compute_tke_spectrum(ux,vx,wx,lx,ly,lz, True)
knyquisty, wavenumbersy, tkespecy = compute_tke_spectrum(uy,vy,wy,lx,ly,lz, True)
knyquistz, wavenumbersz, tkespecz = compute_tke_spectrum(uz,vz,wz,lx,ly,lz, True)
q, ((p1,p2),(p3,p4)) = plt.subplots(2,2)
espec = cbc_specf(kcbc)
p1.plot(kcbc, espec, 'ob', kcbc, ecbc, '-')
p1.set_title('Interpolated Spectrum')
p1.grid()
p1.set_xlabel('wave number')
p1.set_ylabel('E')
p2.loglog(kcbc, ecbc, '-', wavenumbers, tkespec, 'ro-', wavenumbersx, tkespecx, 'bo-',wavenumbersy, tkespecy, 'go-',wavenumbersz, tkespecz, 'ro-' )
p2.axvline(x=knyquist, linestyle='--', color='black')
p2.set_title('Spectrum of generated turbulence')
p2.grid()
# contour plot
p3.matshow(u[:,:,nz/2])
p3.set_title('u velocity')
p4.matshow(v[:,:,nz/2])
p4.set_title('v velocity')
plt.show()