def get_potential(V_bias, n_eff):
try:
return tools.load(
os.path.join(DATAFOLDER, 'pot_descr_%d_%d_%d_3D' %
(V_bias, n_eff, RESOLUTION)))
except IOError:
V_readout = 0.
V_bi = -silicon.get_diffusion_potential(n_eff / 1e12, temperature=TEMP)
mesh = get_mesh()
potential = fields.calculate_3D_sensor_potential(
mesh, WIDTH_X, WIDTH_Y, NPIXEL_X, NPIXEL_Y, RADIUS, ND, n_eff,
V_bias, V_readout, V_bi)
min_x, max_x, min_y, max_y = GEOM_DESCR.get_array_corners()
nx = WIDTH_X * NPIXEL_X * 4
ny = WIDTH_Y * NPIXEL_Y * 4
pot_descr = fields.Description(
potential,
min_x=min_x,
max_x=max_x,
min_y=min_y,
max_y=max_y,
nx=nx, # um res.
ny=ny, # um res.
smoothing=SMOOTHING)
tools.save(
pot_descr,
os.path.join(DATAFOLDER, 'pot_descr_%d_%d_%d_3D' %
(V_bias, n_eff, RESOLUTION)))
return pot_descr
def get_w_potential():
try:
return tools.load(
os.path.join(DATAFOLDER, 'pot_w_descr_%d_3D' % RESOLUTION))
except IOError:
mesh = get_mesh()
min_x, max_x, min_y, max_y = GEOM_DESCR.get_array_corners()
nx = WIDTH_X * NPIXEL_X * 4
ny = WIDTH_Y * NPIXEL_Y * 4
w_potential = fields.calculate_3D_sensor_w_potential(mesh,
WIDTH_X,
WIDTH_Y,
NPIXEL_X,
NPIXEL_Y,
RADIUS,
nD=ND)
pot_w_descr = fields.Description(w_potential,
min_x=min_x,
max_x=max_x,
min_y=min_y,
max_y=max_y,
nx=nx,
ny=ny,
smoothing=SMOOTHING)
tools.save(pot_w_descr,
os.path.join(DATAFOLDER, 'pot_w_descr_%d_3D' % RESOLUTION))
return pot_w_descr
def get_w_potential(thickness):
try:
return tools.load(
os.path.join(DATAFOLDER, 'pot_w_descr_%d' % thickness))
except IOError:
mesh = get_mesh(n_pixel=NPIXEL,
width=WIDTH,
thickness=thickness,
resolution=RESOLUTION_1
if thickness == THICKNESS_1 else RESOLUTION_2)
w_potential = fields.calculate_planar_sensor_w_potential(
mesh=mesh,
width=WIDTH,
pitch=PITCH,
n_pixel=NPIXEL,
thickness=thickness)
pot_w_descr = fields.Description(
w_potential,
min_x=float(mesh.getFaceCenters()[0, :].min()),
max_x=float(mesh.getFaceCenters()[0, :].max()),
min_y=0,
max_y=thickness,
nx=WIDTH * NPIXEL,
ny=thickness,
smoothing=SMOOTHING)
tools.save(pot_w_descr,
os.path.join(DATAFOLDER, 'pot_w_descr_%d' % thickness))
return pot_w_descr
def get_mesh():
try:
return tools.load(
os.path.join(DATAFOLDER, 'mesh_%d_3D' % (int(RESOLUTION))))
except IOError:
mesh = geometry.mesh_3D_sensor(width_x=WIDTH_X,
width_y=WIDTH_Y,
n_pixel_x=NPIXEL_X,
n_pixel_y=NPIXEL_Y,
radius=RADIUS,
nD=ND,
resolution=RESOLUTION)
tools.save(mesh,
os.path.join(DATAFOLDER, 'mesh_%d_3D' % (int(RESOLUTION))))
return mesh
def get_potential(V_bias, n_eff, thickness):
try:
return tools.load(
os.path.join(DATAFOLDER,
'pot_descr_%d_%d_%d' % (V_bias, n_eff, thickness)))
except IOError:
V_readout = 0.
V_bi = -silicon.get_diffusion_potential(n_eff / 1e12, temperature=TEMP)
# mesh = MESH_1 if thickness == THICKNESS_1 else MESH_2
mesh = get_mesh(n_pixel=NPIXEL,
width=WIDTH,
thickness=thickness,
resolution=RESOLUTION_1
if thickness == THICKNESS_1 else RESOLUTION_2)
potential = fields.calculate_planar_sensor_potential(
mesh=mesh,
width=WIDTH,
pitch=PITCH,
n_pixel=NPIXEL,
thickness=thickness,
n_eff=n_eff,
V_bias=V_bias,
V_readout=V_readout,
V_bi=V_bi)
min_x = float(mesh.getFaceCenters()[0, :].min())
max_x = float(mesh.getFaceCenters()[0, :].max())
nx = WIDTH * NPIXEL
ny = thickness
pot_descr = fields.Description(potential,
min_x=min_x,
max_x=max_x,
min_y=0,
max_y=thickness,
nx=nx,
ny=ny,
smoothing=SMOOTHING)
tools.save(
pot_descr,
os.path.join(DATAFOLDER,
'pot_descr_%d_%d_%d' % (V_bias, n_eff, thickness)))
return pot_descr
def test_save_and_load(self):
''' Check the saving and loading to disk.
'''
# Create data
mesh = geometry.mesh_planar_sensor(n_pixel=9,
width=50.,
thickness=300.,
resolution=50.,
filename='planar_mesh_example.msh')
potential = fields.calculate_planar_sensor_potential(mesh=mesh,
width=50.,
pitch=45.,
n_pixel=9,
thickness=300.,
n_eff=5e12,
V_bias=-160.,
V_readout=0.,
V_bi=1.5)
min_x = float(mesh.getFaceCenters()[0, :].min())
max_x = float(mesh.getFaceCenters()[0, :].max())
description = fields.Description(potential,
min_x=min_x,
max_x=max_x,
min_y=0,
max_y=300.,
nx=202,
ny=200)
# Force the creation of the potential and field functions
description.get_field(0, 0)
# Store and reload object
tools.save(description, 'tmp.sc')
description_2 = tools.load('tmp.sc')
self.assertTrue(np.all(description.pot_data == description_2.pot_data))
self.assertTrue(
np.all(description.potential_grid == description_2.potential_grid))
self.assertTrue(
np.all(
np.array(
description.get_field(description._xx, description._yy)) ==
np.array(
description_2.get_field(description_2._xx,
description_2._yy))))
def get_mesh(n_pixel, width, thickness, resolution):
try:
return tools.load(
os.path.join(
DATAFOLDER, 'mesh_%d_%d_%d_%d' %
(n_pixel, int(width), int(thickness), int(resolution))))
except IOError:
mesh = geometry.mesh_planar_sensor(n_pixel=n_pixel,
width=width,
thickness=thickness,
resolution=resolution)
tools.save(
mesh,
os.path.join(
DATAFOLDER, 'mesh_%d_%d_%d_%d' %
(n_pixel, int(width), int(thickness), int(resolution))))
return mesh
resolution = 251
# Unirradiated charge map
(edge_x, edge_y, charge), pot_descr = cc_planar.cc(n_eff=1.475e12,
bias=-80,
V_readout=V_readout,
temperature=temperature,
t_e_trapping=None,
t_h_trapping=None,
n_pixel=n_pixel,
width=width,
pitch=pitch,
thickness=thickness,
resolution=resolution,
smoothing=smoothing)
tools.save(obj=(edge_x, edge_y, charge), filename='charge_planar_unirrad')
# Irradiated charge map
(edge_x, edge_y, charge), pot_descr = cc_planar.cc(n_eff=8.8e12,
bias=-150,
V_readout=V_readout,
temperature=temperature,
t_e_trapping=4.82,
t_h_trapping=4.82,
n_pixel=n_pixel,
width=width,
pitch=pitch,
thickness=thickness,
resolution=resolution,
smoothing=smoothing)
tools.save(obj=(edge_x, edge_y, charge), filename='charge_planar_irrad')
