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from matplotlib import pyplot as pl
from matplotlib import animation
import sys
# read data
# time dependent data
frames=[]
# asymptotic data (located in the first block)
asym=[]
infile=open(sys.argv[1],'r')
row=[]
for line in infile:
# read first block
if len(asym)==0:
if line=='\n':
asym=row
row=[]
else:
dat=[]
for n in line.split():
dat.append(float(n))
row.append(dat)
# read other blocks
else:
if line=='\n':
frames.append(row)
row=[]
else:
dat=[]
for n in line.split():
dat.append(float(n))
row.append(dat)
infile.close()
# set up plot
fig = pl.figure()
pl.subplot(211)
axr=fig.gca()
asym_rho, = axr.plot([],[],linewidth=3.5,color='#00FF00')
rho, = axr.plot([],[],color='red')
pl.subplot(212)
axJ=fig.gca()
asym_J, = axJ.plot([],[],linewidth=3.5,color='#00FF00')
J, = axJ.plot([],[],color='red')
# plot ranges
xmax=0
maxyr=0
maxyJ=0
for frame in frames:
for i in range(len(frame)):
if frame[i][1]>xmax:
xmax=frame[i][1]
if frame[i][2]>maxyr:
maxyr=frame[i][2]
if frame[i][3]>maxyJ:
maxyJ=frame[i][3]
for i in range(len(asym)):
if asym[i][0]>xmax:
xmax=asym[i][0]
if asym[i][1]>maxyr:
maxyr=asym[i][1]
if asym[i][2]>maxyJ:
maxyJ=asym[i][2]
xmin=0
minyr=0
minyJ=0
for frame in frames:
for i in range(len(frame)):
if frame[i][1]<xmin:
xmin=frame[i][1]
if frame[i][2]<minyr:
minyr=frame[i][2]
if frame[i][3]<minyJ:
minyJ=frame[i][3]
for i in range(len(asym)):
if asym[i][0]<xmin:
xmin=asym[i][0]
if asym[i][1]<minyr:
minyr=asym[i][1]
if asym[i][2]<minyJ:
minyJ=asym[i][2]
# plot asymptotes
asym_rho_datax=[]
asym_rho_datay=[]
for i in range(len(asym)):
asym_rho_datax.append(asym[i][0])
asym_rho_datay.append(asym[i][1])
asym_rho.set_data(asym_rho_datax,asym_rho_datay)
asym_J_datax=[]
asym_J_datay=[]
for i in range(len(asym)):
asym_J_datax.append(asym[i][0])
asym_J_datay.append(asym[i][2])
asym_J.set_data(asym_J_datax,asym_J_datay)
# animate
def init_plot():
axr.set_ylim(minyr,maxyr)
axr.set_xlim(xmin,xmax)
axJ.set_ylim(minyJ,maxyJ)
axJ.set_xlim(xmin,xmax)
axr.vlines(0,minyr,maxyr,linestyles="dotted")
axJ.vlines(0,minyJ,maxyJ,linestyles="dotted")
return rho,J
def update(frame):
axr.set_title("t=% .3f fs" % (frame[0][0]))
xdata=[]
ydata=[]
for i in range(len(frame)):
xdata.append(frame[i][1])
ydata.append(frame[i][2])
rho.set_data(xdata,ydata)
xdata=[]
ydata=[]
for i in range(len(frame)):
xdata.append(frame[i][1])
ydata.append(frame[i][3])
J.set_data(xdata,ydata)
return rho,J
anim = animation.FuncAnimation(fig, update, frames=frames, blit=False, interval=100, repeat=True, init_func=init_plot)
pl.show()
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