def test_boundary_condition():
#beam1 = Beam(10000)
#beam1.set_point(0, 0, 0)
#beam1.set_flat_divergence(5e-3, 5e-2)
shadow_beam = run_shadow_source()
beam1 = Beam(10000)
beam1.initialize_from_arrays(
shadow_beam.getshonecol(1),
shadow_beam.getshonecol(2),
shadow_beam.getshonecol(3),
shadow_beam.getshonecol(4),
shadow_beam.getshonecol(5),
shadow_beam.getshonecol(6),
shadow_beam.getshonecol(10),
0
)
bound1=BoundaryRectangle(xmax=0.005,xmin=-0.005,ymax=0.05,ymin=-0.05)
bound2=BoundaryRectangle(xmax=0.01,xmin=-0.01,ymax=0.1,ymin=-0.1)
plane_mirror=Optical_element.initialize_as_plane_mirror(2,1,65*np.pi/180,0)
parabolic_mirror=Optical_element.initialize_as_surface_conic_paraboloid_from_focal_distances(5,2,28*np.pi/180,90*np.pi/180)
plane_mirror.rectangular_bound(bound1)
parabolic_mirror.rectangular_bound(bound2)
beam1=plane_mirror.trace_optical_element(beam1)
beam1=parabolic_mirror.trace_optical_element(beam1)
beam1.plot_xz()
plt.title("Total points plot")
beam1.plot_good_xz()
plt.title("Good points plot")
print(beam1.flag)
indices=np.where(beam1.flag>0)
print("The good number of ray are: %f" %(beam1.flag[indices].size))
plt.show()
shadow_beam=trace_shadow(shadow_beam)
assert_almost_equal(beam1.x, shadow_beam.getshonecol(1), 8)
assert_almost_equal(beam1.y, shadow_beam.getshonecol(2), 8)
assert_almost_equal(beam1.z, shadow_beam.getshonecol(3), 8)
def test_kirk_patrick_baez():
#beam=Beam.initialize_as_person()
#beam.set_flat_divergence(1e-12, 1e-12)
#beam.x = beam.x*1e-3
#beam.z = beam.z*1e-3
shadow_beam = shadow_source()
beam = Beam()
beam.initialize_from_arrays(shadow_beam.getshonecol(1),
shadow_beam.getshonecol(2),
shadow_beam.getshonecol(3),
shadow_beam.getshonecol(4),
shadow_beam.getshonecol(5),
shadow_beam.getshonecol(6),
shadow_beam.getshonecol(10), 0)
bound1 = BoundaryRectangle(xmax=2.5, xmin=-2.5, ymax=2.5, ymin=-2.5)
bound2 = BoundaryRectangle(xmax=1., xmin=-1., ymax=1., ymin=-1.)
kirk_patrick_baez = CompoundOpticalElement.initialize_as_kirkpatrick_baez(
p=10.,
q=5.,
separation=4.,
theta=89 * np.pi / 180,
bound1=bound1,
bound2=bound2)
beam = kirk_patrick_baez.trace_compound(beam)
beam.plot_good_xz(0)
indices = np.where(beam.flag > 0)
assert_almost_equal(beam.x[indices], 0., 4)
assert_almost_equal(beam.z[indices], 0., 4)
beam.retrace(50.)
beam.plot_good_xz()
print(kirk_patrick_baez.info())
print("Number of good rays: %f" % (beam.number_of_good_rays()))
#beam.histogram()
if do_plot:
plt.show()
def test_ellipsoidal_mirror(self):
print(">>>>>>>>>>>>>>> test_ellipsoidal_mirror")
#beam1=Beam(5000)
#beam1.set_point(0,0,0)
#beam1.set_flat_divergence(5e-3,5e-2)
shadow_beam = run_shadow_source()
beam1 = Beam()
beam1.initialize_from_arrays(
shadow_beam.getshonecol(1),
shadow_beam.getshonecol(2),
shadow_beam.getshonecol(3),
shadow_beam.getshonecol(4),
shadow_beam.getshonecol(5),
shadow_beam.getshonecol(6),
shadow_beam.getshonecol(10),
)
p = 20.
q = 10.
theta = 50 * np.pi / 180
spherical_mirror = Optical_element.initialize_as_surface_conic_ellipsoid_from_focal_distances(
p, q, theta)
beam1 = spherical_mirror.trace_optical_element(beam1)
if do_plot:
beam1.plot_xz()
beam1.plot_xpzp()
plt.title("Ellipsoidal mirror with p=20, q=10, theta=50")
plt.show()
shadow_beam = run_shadow_elliptical_mirror(beam1)
assert_almost_equal(beam1.vx, shadow_beam.getshonecol(4), 1)
assert_almost_equal(beam1.vy, shadow_beam.getshonecol(5), 1)
assert_almost_equal(beam1.vz, shadow_beam.getshonecol(6), 1)
def test_spherical_mirror(self):
print(">>>>>>>>>>>>>>> test_spherical_mirror")
shadow_beam = run_shadow_source()
beam1 = Beam()
beam1.initialize_from_arrays(
shadow_beam.getshonecol(1),
shadow_beam.getshonecol(2),
shadow_beam.getshonecol(3),
shadow_beam.getshonecol(4),
shadow_beam.getshonecol(5),
shadow_beam.getshonecol(6),
shadow_beam.getshonecol(10),
)
#beam1 = Beam(5000)
#beam1.set_point(0, 0, 0)
#beam1.set_flat_divergence(5e-3, 5e-2)
p = 2.
q = 1.
theta = 41 * np.pi / 180
shadow_beam = run_shadow_source()
spherical_mirror = Optical_element.initialize_as_surface_conic_sphere_from_focal_distances(
p, q, theta)
beam1 = spherical_mirror.trace_optical_element(beam1)
if do_plot:
beam1.plot_xz()
beam1.plot_xpzp()
plt.title("Spherical mirror with p=2, q=1, theta=41")
plt.show()
shadow_beam = run_shadow_spherical_mirror(shadow_beam)
assert_almost_equal(beam1.x, shadow_beam.getshonecol(1), 8)
assert_almost_equal(beam1.y, shadow_beam.getshonecol(2), 8)
assert_almost_equal(beam1.z, shadow_beam.getshonecol(3), 8)
varx = np.zeros(100)
varz = np.zeros(100)
qqq = np.zeros(100)
#for i in range (0, 1):
beam = Beam(25000)
beam.set_circular_spot(1e-3)
beam.set_divergences_collimated()
shadow_beam = shadow_source()
beam = Beam()
beam.initialize_from_arrays(shadow_beam.getshonecol(1),
shadow_beam.getshonecol(2),
shadow_beam.getshonecol(3),
shadow_beam.getshonecol(4),
shadow_beam.getshonecol(5),
shadow_beam.getshonecol(6),
shadow_beam.getshonecol(10), 0)
#beam = Beam()
#beam.set_flat_divergence(0.01,0.01)
beam_prova = beam.duplicate()
p = 5.
q = 15.
theta = 88. * np.pi / 180
beta = (90. + 0.) * np.pi / 180
alpha = 87. * np.pi / 180
def test_paraboloid_mirror(self):
print(">>>>>>>>>>>>>>> test_paraboloid_mirror")
#beam1=Beam(5000)
#beam1.set_point(0,0,0)
#beam1.set_flat_divergence(5e-3,5e-2)
shadow_beam = run_shadow_source()
beam1 = Beam()
beam1.initialize_from_arrays(
shadow_beam.getshonecol(1),
shadow_beam.getshonecol(2),
shadow_beam.getshonecol(3),
shadow_beam.getshonecol(4),
shadow_beam.getshonecol(5),
shadow_beam.getshonecol(6),
shadow_beam.getshonecol(10),
)
p = 10.
q = 20.
theta = 72 * np.pi / 180
alpha = 0 * np.pi / 180
spherical_mirror = Optical_element.initialize_as_surface_conic_paraboloid_from_focal_distances(
p, q, theta, alpha)
beam1 = spherical_mirror.trace_optical_element(beam1)
if do_plot:
beam1.plot_xz()
beam1.plot_xpzp()
plt.title("Paraboloid mirror with p=10, q=20, theta=72")
print(spherical_mirror.ccc_object.get_coefficients())
plt.show()
shadow_beam = run_shadow_parabolic_mirror(shadow_beam)
assert_almost_equal(beam1.x, shadow_beam.getshonecol(1), 7)
assert_almost_equal(beam1.y, shadow_beam.getshonecol(2), 7)
assert_almost_equal(beam1.z, shadow_beam.getshonecol(3), 7)
######## This is problematic #######################################################################################
#
#def test_hyperboloid_mirror():
# #beam1=Beam(5000)
# #beam1.set_point(0,0,0)
# #beam1.set_flat_divergence(5e-3,5e-2)
#
# shadow_beam=run_shadow_source()
#
# beam1=Beam(5000)
# beam1.initialize_from_arrays(
# shadow_beam.getshonecol(1),
# shadow_beam.getshonecol(2),
# shadow_beam.getshonecol(3),
# shadow_beam.getshonecol(4),
# shadow_beam.getshonecol(5),
# shadow_beam.getshonecol(6),
# shadow_beam.getshonecol(10),
# 0
# )
#
# p=1.
# q=2.
# theta = 76*np.pi/180
# spherical_mirror=Optical_element.initialize_as_hyperboloid_from_focal_distances(p,q,theta)
# beam1=spherical_mirror.trace_surface_conic(beam1)
# beam1.plot_xz()
# beam1.plot_xpzp()
# plt.show()
#
# shadow_beam=run_shadow_hyperbolic_mirror(shadow_beam)
#
#
########################################################################################################################
return beam
if __name__ == "__main__":
beam_shadow = run_shadow()
beam1 = Beam()
# beam1.set_point(0,0,0)
# beam1.set_flat_divergence(5e-3,5e-2)
beam1.initialize_from_arrays(
beam_shadow.getshonecol(1),
beam_shadow.getshonecol(2),
beam_shadow.getshonecol(3),
beam_shadow.getshonecol(4),
beam_shadow.getshonecol(5),
beam_shadow.getshonecol(6),
beam_shadow.getshonecol(10),
)
#### Data of the plane mirron
p = 1.
q = 1.
theta = 45
alpha = 90
R = 2 * p * q / (q + p) / np.cos(theta)
spherical_mirror = Optical_element.initialize_as_spherical_mirror(
p, q, theta, alpha, R)
