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work_py.py
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work_py.py
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import sdf
import matplotlib
matplotlib.use('agg')
import matplotlib.pyplot as plt
import numpy as np
#from numpy import ma
from matplotlib import colors, ticker, cm
from matplotlib.mlab import bivariate_normal
from optparse import OptionParser
import os
import matplotlib.colors as mcolors
######## Constant defined here ########
pi = 3.1415926535897932384626
q0 = 1.602176565e-19 # C
m0 = 9.10938291e-31 # kg
v0 = 2.99792458e8 # m/s^2
kb = 1.3806488e-23 # J/K
mu0 = 4.0e-7*pi # N/A^2
epsilon0 = 8.8541878176203899e-12 # F/m
h_planck = 6.62606957e-34 # J s
wavelength= 1.0e-6
frequency = v0*2*pi/wavelength
exunit = m0*v0*frequency/q0
bxunit = m0*frequency/q0
denunit = frequency**2*epsilon0*m0/q0**2
print('electric field unit: '+str(exunit))
print('magnetic field unit: '+str(bxunit))
print('density unit nc: '+str(denunit))
font = {'family' : 'monospace',
'style' : 'normal',
'color' : 'black',
'weight' : 'normal',
'size' : 14,
}
######### Parameter you should set ###########
start = 849 # start time
stop = 849 # end time
step = 1 # the interval or step
directory = './tacc_worky_txt/'
px_y = np.loadtxt(directory+'px2d.txt')
py_y = np.loadtxt(directory+'py2d.txt')
xx_y = np.loadtxt(directory+'xx2d.txt')
yy_y = np.loadtxt(directory+'yy2d.txt')
workx2d_y = np.loadtxt(directory+'workx2d.txt')
worky2d_y = np.loadtxt(directory+'worky2d.txt')
fieldex_y = np.loadtxt(directory+'field2dex.txt')
fieldey_y = np.loadtxt(directory+'field2dey.txt')
fieldbz_y = np.loadtxt(directory+'field2dbz.txt')
gg_y = (px_y**2+py_y**2+1)**0.5
directory = './tacc_workx_txt/'
px_x = np.loadtxt(directory+'px2d.txt')
py_x = np.loadtxt(directory+'py2d.txt')
xx_x = np.loadtxt(directory+'xx2d.txt')
yy_x = np.loadtxt(directory+'yy2d.txt')
workx2d_x = np.loadtxt(directory+'workx2d.txt')
worky2d_x = np.loadtxt(directory+'worky2d.txt')
fieldex_x = np.loadtxt(directory+'field2dex.txt')
fieldey_x = np.loadtxt(directory+'field2dey.txt')
fieldbz_x = np.loadtxt(directory+'field2dbz.txt')
gg_x = (px_x**2+py_x**2+1)**0.5
color_y = np.zeros_like(px_y[:,0])
color_x = np.zeros_like(px_x[:,0])
for i in range(0,color_y.size):
color_y[i] = py_y[i,np.argmax(xx_y[0,:] > 20)]
for i in range(0,color_x.size):
color_x[i] = py_x[i,np.argmax(xx_x[0,:] > 20)]
for n in range(start,stop+step,step):
#### header data ####
# plt.subplot()
plt.scatter(workx2d_y[:,n], worky2d_y[:,n], c=abs(color_y), norm=colors.Normalize(vmin=0, vmax=25), s=50, cmap='rainbow', edgecolors='black', alpha=0.6)
plt.scatter(workx2d_x[:,n], worky2d_x[:,n], c=abs(color_x), norm=colors.Normalize(vmin=0, vmax=25), s=50, cmap='rainbow', edgecolors='black', alpha=0.6)
cbar=plt.colorbar()
cbar.set_label(r'$P_y$ for injecting time',fontdict=font)
plt.plot(np.linspace(-500,900,1001), np.zeros([1001]),':k',linewidth=1.5)
plt.plot(np.zeros([1001]), np.linspace(-500,900,1001),':k',linewidth=1.5)
plt.plot(np.linspace(-500,900,1001), np.linspace(-500,900,1001),':k',linewidth=1.5)
# plt.legend(loc='upper right')
plt.xlim(-200,600)
plt.ylim(-200,600)
plt.xlabel(r'$Work_x [m_ec^2]$',fontdict=font)
plt.ylabel(r'$Work_y [m_ec^2]$',fontdict=font)
#plt.xticks(fontsize=20); plt.yticks(fontsize=20);
#plt.title('electron at y='+str(round(y[n,0]/2/np.pi,4)),fontdict=font)
#plt.show()
#lt.figure(figsize=(100,100))
fig = plt.gcf()
fig.set_size_inches(8, 6.5)
fig.savefig('./work_py/'+str(n).zfill(4)+'.png',format='png',dpi=160)
plt.close("all")
print('finised '+str(round(100.0*(n-start+step)/(stop-start+step),4))+'%')