def pushButton_4_clicked(self):
'''
Slot for pushButton_4. Scatter plot.
'''
# just plot the rays from the selected sources
qindices = self.listWidget.selectedIndexes()
rays = []
for qi in qindices:
source = self.sources[qi.row()]
for ray in self.detector.rays:
if ray.tag is source:
rays.append(ray)
# color bounce option
colorBounces = self.checkBox_3.isChecked()
# create window
window = QWidget()
window.setWindowTitle('Scatter Plot')
l = QVBoxLayout(window)
canv = MplCanvas(window, width=5, height=5, dpi=100)
scatterHist(rays, figure=canv.figure, colorBounces=colorBounces)
l.addWidget(canv)
window.show()
self.figures.append(window)
def pushButton_4_clicked(self):
'''
Slot for pushButton_4. Scatter plot.
'''
# just plot the rays from the selected sources
qindices = self.listWidget.selectedIndexes()
rays = []
for qi in qindices:
source = self.sources[qi.row()]
for ray in self.detector.rays:
if ray.tag is source:
rays.append(ray)
# color bounce option
colorBounces = self.checkBox_3.isChecked()
# create window
window = QWidget()
window.setWindowTitle('Scatter Plot')
l = QVBoxLayout(window)
canv = MplCanvas(window, width=5, height=5, dpi=100)
scatterHist(rays, figure=canv.figure, colorBounces=colorBounces)
l.addWidget(canv)
window.show()
self.figures.append(window)
module = Module(radii=[5.151, 3.799],
seglen=30.0,
base=[0, 0, 0],
focal=200,
angles=None,
conic=False)
detector = Detector(width=0.96,
height=0.96,
normal=[0, 0, 1],
center=[0, 0, 200.0 + 30.0],
reso=[128, 128])
source_distance = -2187.5
offaxis_angle_arcmin = 1.0
source = Source(
type='point',
center=[
source_distance * np.sin(np.deg2rad(offaxis_angle_arcmin / 60.0)),
0.0, source_distance
],
color=[0, 1, 1])
rays = source.generateRays(module.targetFront, 2000)
module.passRays(rays, robust=True)
detector.catchRays(rays)
plot(detector)
scatterHist(rays)
plt.show()
from foxsisim.plotting import plot
import matplotlib.pyplot as plt
if __name__ == '__main__':
# create module/detector/source objects using defaults
module = Module()
detector = Detector()
source = Source()
# generate 1000 rays at source
rays = source.generateRays(module.targetFront, 1000)
# pass rays through module
module.passRays(rays, robust=True)
# catch rays at detector
detector.catchRays(rays)
# plot detector pixels
plot(detector)
# create scatter plot
detectorRays = detector.rays
fig2 = plt.figure(figsize=(5,5))
scatterHist(detectorRays,fig2)
# show
plt.show()
from foxsisim.plotting import plot
import matplotlib.pyplot as plt
if __name__ == '__main__':
# create module/detector/source objects using defaults
module = Module()
detector = Detector()
source = Source()
# generate 1000 rays at source
rays = source.generateRays(module.targetFront, 1000)
# pass rays through module
module.passRays(rays, robust=True)
# catch rays at detector
detector.catchRays(rays)
# plot detector pixels
plot(detector)
# create scatter plot
detectorRays = detector.rays
fig2 = plt.figure(figsize=(5, 5))
scatterHist(detectorRays, fig2)
# show
plt.show()
# In[4]:
rays = source.generateRays(module.targetFront, 10)
module.passRays(rays, robust=True)
detector.catchRays(rays)
# In[5]:
plot(detector)
# In[6]:
scatterHist(rays)
# In[7]:
for ray in rays:
print("x=%f, y=%f, bounce=%i, dead=%i" % (ray.des[0], ray.des[1], ray.bounces, ray.dead))
# In[8]:
np.sum([ray.dead for ray in rays])
# In[9]:
from foxsisim.plotting import plot
import numpy as np
if __name__ == '__main__':
# create module of 7 shells
module = Module(radii=[5.151, 3.799],
seglen=30.0,
base=[0,0,0],
focal=200,
angles=None,
conic=False)
detector = Detector(width=0.96,
height=0.96,
normal=[0,0,1],
center=[0,0,200.0+30.0],
reso =[128,128])
source_distance = -2187.5
offaxis_angle_arcmin = 1.0
source = Source(type='point',
center=[ source_distance * np.sin(np.deg2rad(offaxis_angle_arcmin/60.0)) , 0.0 , source_distance ],
color=[0,1,1])
rays = source.generateRays(module.targetFront, 2000)
module.passRays(rays, robust=True)
detector.catchRays(rays)
plot(detector)
scatterHist(rays)
from datetime import datetime
tstart = datetime.now()
print('pasing rays')
# pass rays through module
module.passRays(rays, robust=True)
# catch rays at detector
detector.catchRays(rays)
rays_on_detector = len(detector.rays)
print('Number of rays on Detector ' + str(rays_on_detector))
print('Time total: ' + str((datetime.now() - tstart).seconds) + ' seconds')
print('Time per ray (s): ' +
str(rays_on_detector / float((datetime.now() - tstart).seconds)))
drays = [ray for ray in rays if ray.des[2] == 230.0]
scatterHist(drays)
#plt.show()
plt.savefig('photons_on_detec.png')
plt.figure()
plt.hist([ray.energy for ray in detector.rays],
normed=True,
label='rays on detector',
color='r')
plt.xlabel('Energy [keV]')
plt.title('Histogram caught rays on detector')
plt.legend()
plt.show()
plt.savefig('output_spect_on_detec.png')
