def create_surfaces(self, cs): #cs=coordinate Systems
surface_objects = []
for i in range(self.surfaces.shape[0]):
if (self.get_sufval("shape", i) == "Conic"):
#hier noch cc einfuegen
shape_ = Conic.p(cs[i],
cc=float(self.get_sufval("conic", i)),
curv=float(self.get_sufval("curvature", i)))
#print(self.get_sufval("curvature",i))
else:
shape_ = None
if (self.get_sufval("aperture", i) == "Circular"):
aperture_ = CircularAperture(
cs[i],
minradius=float(self.get_sufval("minrad", i)),
maxradius=float(self.get_sufval("maxrad", i)))
#print(float(self.get_sufval("maxrad",i)).__class__.__name__)
else:
aperture_ = None
self.SurfNameList.append(self.get_sufval("name", i))
surface_objects.append(
Surface.p(cs[i], shape=shape_, aperture=aperture_))
return surface_objects
def create():
from pyrateoptics.raytracer.surface_shape import Conic
from pyrateoptics.raytracer.surface import Surface
from pyrateoptics.raytracer.aperture import CircularAperture
lc = LocalCoordinates.p(name="----LCglobal----")
lc2 = LocalCoordinates.p(name="----LCap----", tiltx=0.1, decx=0.2)
lc3 = LocalCoordinates.p(name="----LCsh----", tiltx=-0.1, decx=-0.2)
lc.addChild(lc2)
lc.addChild(lc3)
ap = CircularAperture.p(lc2)
sh = Conic.p(lc3, curv=0.01, cc=-1)
su = Surface.p(lc, sh, ap, name="mysurface")
return su
def initApCircular(self, minradius=0., maxradius=1.0, **kwargs):
apclass = None
if "surface" in kwargs:
apclass = kwargs["surface"].aperture
minradius = apclass.annotations["minradius"]
maxradius = apclass.annotations["maxradius"]
else:
apclass = CircularAperture.p(
self.__obj.LocalCoordinatesLink.Proxy.getLC(),
minradius=minradius,
maxradius=maxradius)
self.__obj.addProperty("App::PropertyFloat", "minradius", "Aperture",
"minradius").minradius = minradius
self.__obj.addProperty("App::PropertyFloat", "maxradius", "Aperture",
"maxradius").maxradius = maxradius
self.__obj.apertureclass = apclass
def initApCircular(self, semidiameter=1.0, tx=0., ty=0., **kwargs):
apclass = None
if "surface" in kwargs:
apclass = kwargs["surface"].aperture
semidiameter = apclass.semidiameter
tx = apclass.tx
ty = apclass.ty
else:
apclass = CircularAperture.p(
self.__obj.LocalCoordinatesLink.Proxy.getLC(),
semidiameter=semidiameter,
tx=tx,
ty=ty)
self.__obj.addProperty("App::PropertyFloat", "semidiameter",
"Aperture",
"semidiameter").semidiameter = semidiameter
self.__obj.addProperty("App::PropertyFloat", "tx", "Aperture",
"decentration x").tx = tx
self.__obj.addProperty("App::PropertyFloat", "ty", "Aperture",
"decentration y").ty = ty
self.__obj.apertureclass = apclass
refname=lc4.name)
lc5ap = s.addLocalCoordinateSystem(LocalCoordinates(name="oaparaap",
decz=0,
decy=35),
refname=lc5.name)
lc6 = s.addLocalCoordinateSystem(LocalCoordinates(name="image2",
decz=55,
tiltx=1 * math.pi / 32),
refname=lc5.name)
lc7 = s.addLocalCoordinateSystem(LocalCoordinates(name="image3", decz=5),
refname=lc6.name)
objectsurf = Surface(lc0)
m1surf = Surface(lc1,
shape=surfShape.Conic(lc1, curv=-0.01),
apert=CircularAperture(lc1, 20.))
m2surf = Surface(lc2,
shape=surfShape.Conic(lc2, curv=0.01),
apert=CircularAperture(lc2, 12.7))
m3surf = Surface(lc3,
shape=surfShape.Conic(lc3, curv=-0.006),
apert=CircularAperture(lc3, 12.7))
image1 = Surface(lc4)
oapara = Surface(lc3,
shape=surfShape.Conic(lc5, curv=0.01, cc=-1.),
apert=CircularAperture(lc5ap, 30.0))
image2 = Surface(lc6, apert=CircularAperture(lc6, 20.0))
image3 = Surface(lc7, apert=CircularAperture(lc7, 20.0))
elem = OpticalElement(lc0, name="TMA")
lc1 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf1",
decz=-10.0,
tiltx=30. * degree),
refname=lccomprism.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf2",
decz=10.0,
tiltx=-30. * degree),
refname=lccomprism.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="image", decz=50.0),
refname=lccomprism.name)
stopsurf = Surface.p(lc0)
frontsurf = Surface.p(lc1,
shape=Conic.p(lc1, curv=0),
aperture=CircularAperture.p(lc1, maxradius=20.0))
rearsurf = Surface.p(lc2,
shape=Conic.p(lc2, curv=0),
aperture=CircularAperture.p(lc2, maxradius=20.0))
image = Surface.p(lc3)
elem = OpticalElement.p(lc0, name="prism")
glass = ModelGlass.p(lc1)
elem.addMaterial("glass", glass)
elem.addSurface("stop", stopsurf, (None, None))
elem.addSurface("surf1", frontsurf, (None, "glass"))
elem.addSurface("surf2", rearsurf, ("glass", None))
elem.addSurface("image", image, (None, None))
dropletradius),
refname=lc0.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1",
decz=-dropletradius),
refname=lccomprism.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2",
decz=dropletradius),
refname=lccomprism.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf3", decz=0),
refname=lccomprism.name)
lc4 = s.addLocalCoordinateSystem(LocalCoordinates(name="image",
decz=-2. * dropletradius),
refname=lccomprism.name)
stopsurf = Surface(lc0, apert=CircularAperture(lc0, 7 * dropletradius))
frontsurf = Surface(lc1,
shape=Asphere(lc1, curv=1. / dropletradius),
apert=CircularAperture(lc1, dropletradius))
rearsurf = Surface(lc2,
shape=Asphere(lc2, curv=-1. / dropletradius),
apert=CircularAperture(lc2, dropletradius))
midsurf = Surface(lc3,
shape=Asphere(lc3, curv=0),
apert=CircularAperture(lc3, dropletradius))
image = Surface(lc4, apert=CircularAperture(lc4, 7. * dropletradius))
elem = OpticalElement(lc0, name="droplet")
try:
decz=-100,
decy=-35),
refname=lc4.name)
lc5ap = s.addLocalCoordinateSystem(LocalCoordinates(name="oaparaap",
decz=0,
decy=35),
refname=lc5.name)
lc6 = s.addLocalCoordinateSystem(LocalCoordinates(name="image2",
decz=55,
tiltx=1 * math.pi / 32),
refname=lc5.name)
objectsurf = Surface(lc0)
m1surf = Surface(lc1,
shape=Conic(lc1, curv=-0.01),
aperture=CircularAperture(lc1, maxradius=20.))
m2surf = Surface(lc2,
shape=Conic(lc2, curv=0.01),
aperture=CircularAperture(lc2, maxradius=12.7))
m3surf = Surface(lc3,
shape=Conic(lc3, curv=-0.006),
aperture=CircularAperture(lc3, maxradius=20.7))
image1 = Surface(lc4)
oapara = Surface(lc3,
shape=Conic(lc5, curv=0.01, cc=-1.),
aperture=CircularAperture(lc5ap, maxradius=30.0))
image2 = Surface(lc6, aperture=CircularAperture(lc6, maxradius=20.0))
elem = OpticalElement(lc0, name="TMA")
# elem.addMaterial("crystal", crystal)
lc0 = s.addLocalCoordinateSystem(LocalCoordinates(name="stop", decz=0.0),
refname=s.rootcoordinatesystem.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1", decz=-1.048),
refname=lc0.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2", decz=4.0),
refname=lc1.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf3", decz=2.5),
refname=lc2.name)
lc4 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=97.2),
refname=lc3.name)
stopsurf = Surface(lc0, name="stopsurf")
frontsurf = Surface(lc1,
name="frontsurf",
shape=Conic(lc1, curv=1. / 62.8, name='conic1'),
aperture=CircularAperture(lc1, maxradius=12.7))
cementsurf = Surface(lc2,
name="cementsurf",
shape=Conic(lc2, curv=-1. / 45.7, name='conic2'),
aperture=CircularAperture(lc2, maxradius=12.7))
rearsurf = Surface(lc3,
name="rearsurf",
shape=Conic(lc3, curv=-1. / 128.2, name='conic3'),
aperture=CircularAperture(lc3, maxradius=12.7))
image = Surface(lc4, name="imagesurf")
elem = OpticalElement(lc0, name="thorlabs_AC_254-100-A")
rnd_data1 = np.random.random((3, 3)) # np.eye(3)
rnd_data2 = np.random.random((3, 3)) # np.zeros((3, 3))#
rnd_data3 = np.random.random((3, 3)) # np.eye(3)
# definition of optical system
s = OpticalSystem()
deg = math.pi/180.
lc0 = s.addLocalCoordinateSystem(LocalCoordinates(name="stop", decz=0.0), refname=s.rootcoordinatesystem.name)
lccomprism = s.addLocalCoordinateSystem(LocalCoordinates(name="prismcenter", decz=50.0), refname=lc0.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1", decz=-10.0, tiltx=30.*deg), refname=lccomprism.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2", decz=10.0, tiltx=-30.*deg), refname=lccomprism.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=50.0), refname=lccomprism.name)
stopsurf = Surface(lc0)
frontsurf = Surface(lc1, shape=surfShape.Conic(lc1, curv=0), apert=CircularAperture(lc1, 20.0))
rearsurf = Surface(lc2, shape=surfShape.Conic(lc2, curv=0), apert=CircularAperture(lc2, 20.0))
image = Surface(lc3)
elem = OpticalElement(lc0, name="prism")
glass = ModelGlass(lc1)
elem.addMaterial("glass", glass)
elem.addSurface("stop", stopsurf, (None, None))
elem.addSurface("surf1", frontsurf, (None, "glass"))
elem.addSurface("surf2", rearsurf, ("glass", None))
elem.addSurface("image", image, (None, None))
def initDemoSystem(self):
s = OpticalSystem.p()
lc0 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="object",
decz=0.0),
refname=s.rootcoordinatesystem.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf1",
decz=2.0),
refname=lc0.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf2",
decz=3.0),
refname=lc1.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf3",
decz=5.0,
tiltx=0.0 *
math.pi / 180.0),
refname=lc2.name)
lc4 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf4",
decz=3.0),
refname=lc3.name)
lc5 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf5",
decz=3.0),
refname=lc4.name)
lc6 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf6",
decz=2.0),
refname=lc5.name)
lc7 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf7",
decz=3.0),
refname=lc6.name)
lc8 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="image",
decz=19.0),
refname=lc7.name)
objectsurf = Surface.p(lc0)
surf1 = Surface.p(lc1,
shape=Conic.p(lc1, curv=1 / -5.922),
aperture=CircularAperture.p(lc1, maxradius=10.0))
surf2 = Surface.p(lc2,
shape=Conic.p(lc2, curv=1 / -3.160),
aperture=CircularAperture.p(lc2, maxradius=10.0))
surf3 = Surface.p(lc3,
shape=Conic.p(lc3, curv=1 / 15.884),
aperture=CircularAperture.p(lc3, maxradius=10.0))
surf4 = Surface.p(lc4,
shape=Conic.p(lc4, curv=1 / -12.756),
aperture=CircularAperture.p(lc4, maxradius=10.0))
stopsurf = Surface.p(lc5,
aperture=CircularAperture.p(lc5, maxradius=10.0))
surf6 = Surface.p(lc6,
shape=Conic.p(lc6, curv=1 / 3.125),
aperture=CircularAperture.p(lc6, maxradius=10.0))
surf7 = Surface.p(lc7,
shape=Conic.p(lc7, curv=1 / 1.479),
aperture=CircularAperture.p(lc7, maxradius=10.0))
image = Surface.p(lc8)
elem = OpticalElement.p(lc0, name="lenssystem")
glass = material_isotropic.ConstantIndexGlass.p(lc0, n=1.7)
glass2 = material_isotropic.ConstantIndexGlass.p(lc0, n=1.5)
elem.addMaterial("glass", glass)
elem.addMaterial("glass2", glass2)
elem.addSurface("object", objectsurf, (None, None))
elem.addSurface("surf1", surf1, (None, "glass"))
elem.addSurface("surf2", surf2, ("glass", None))
elem.addSurface("surf3", surf3, (None, "glass"))
elem.addSurface("surf4", surf4, ("glass", None))
elem.addSurface("stop", stopsurf, (None, None))
elem.addSurface("surf6", surf6, (None, "glass2"))
elem.addSurface("surf7", surf7, ("glass2", None))
elem.addSurface("image", image, (None, None))
for mysurf in elem.surfaces.values():
print(mysurf.aperture.annotations)
s.addElement("lenssys", elem)
return s
logging.basicConfig(level=logging.DEBUG)
wavelength = 0.5876e-3
# definition of optical system
s = OpticalSystem()
lc0 = s.addLocalCoordinateSystem(LocalCoordinates(name="stop", decz=0.0), refname=s.rootcoordinatesystem.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1", decz=-1.048), refname=lc0.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2", decz=4.0), refname=lc1.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf3", decz=2.5), refname=lc2.name)
lc4 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=97.2), refname=lc3.name)
stopsurf = Surface(lc0)
frontsurf = Surface(lc1, shape=surfShape.Conic(lc1, curv=1./62.8), apert=CircularAperture(lc1, 12.7))
cementsurf = Surface(lc2, shape=surfShape.Conic(lc2, curv=-1./45.7), apert=CircularAperture(lc2, 12.7))
rearsurf = Surface(lc3, shape=surfShape.Conic(lc3, curv=-1./128.2), apert=CircularAperture(lc3, 12.7))
image = Surface(lc4)
elem = OpticalElement(lc0, name="thorlabs_AC_254-100-A")
bk7 = ConstantIndexGlass(lc1, n=1.5168)
sf5 = ConstantIndexGlass(lc2, n=1.6727)
elem.addMaterial("BK7", bk7)
elem.addMaterial("SF5", sf5)
elem.addSurface("stop", stopsurf, (None, None))
elem.addSurface("front", frontsurf, (None, "BK7"))
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1",
decz=-10.0,
tiltx=30. * degree),
refname=lccomprism.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2",
decz=10.0,
tiltx=-30. * degree),
refname=lccomprism.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=50.0),
refname=lccomprism.name)
stopsurf = Surface(lc0)
frontsurf = Surface(lc1,
shape=surfShape.Conic(lc1, curv=0),
apert=CircularAperture(lc1, 20.0))
rearsurf = Surface(lc2,
shape=surfShape.Conic(lc2, curv=0),
apert=CircularAperture(lc2, 20.0))
image = Surface(lc3)
elem = OpticalElement(lc0, name="prism")
glass = ModelGlass(lc1)
elem.addMaterial("glass", glass)
elem.addSurface("stop", stopsurf, (None, None))
elem.addSurface("surf1", frontsurf, (None, "glass"))
elem.addSurface("surf2", rearsurf, ("glass", None))
elem.addSurface("image", image, (None, None))
decz=43.083,
tiltx=-si * 50.668 *
degree,
tiltThenDecenter=False),
refname=lc0.name)
objsurf = Surface(lc0)
D1surf = Surface(lcD1)
#S1surf = Surface(lcS1, shape=Conic(lcS1, curv=si*1./108.187, cc=0), apert=CircularAperture(lcS1, 100.0))
S1surf = Surface(lcS1,
shape=Biconic(lcS1,
curvy=si * 1. / 108.187,
curvx=si * 1. / 73.105,
coefficients=[(0., 0.), (-si * 5.542e-7, -0.08),
(-si * 8.176e-11, -1.379)]),
apert=CircularAperture(lcS1, 40.0))
D1Psurf = Surface(lcD1prime)
D2surf = Surface(lcD2)
#S2surf = Surface(lcS2, shape=Conic(lcS2, curv=si*1./69.871, cc=-0.1368), apert=CircularAperture(lcS2, 60.0))
S2surf = Surface(lcS2,
shape=Biconic(lcS2,
curvy=si * 1. / 69.871,
curvx=si * 1. / 60.374,
ccy=-0.1368,
ccx=-0.123,
coefficients=[(0., 0.),
(si * 7.233e-11, 29.075),
(si * 4.529e-12, -2.085)]),
apert=CircularAperture(lcS2, 40.0))
D2Psurf = Surface(lcD2prime)
D3surf = Surface(lcD3)
lc5ap = s.addLocalCoordinateSystem(
LocalCoordinates.p(name="oaparaap", decz=0, decy=35),
refname=lc5.name)
lc6 = s.addLocalCoordinateSystem(
LocalCoordinates.p(name="image2", decz=52.8, tiltx=1*math.pi/32),
refname=lc5.name)
lc7 = s.addLocalCoordinateSystem(
LocalCoordinates.p(name="image3", decz=5), refname=lc6.name)
objectsurf = Surface.p(lc0)
m1surf = Surface.p(lc1, shape=Conic.p(lc1, curv=-0.01))
m2surf = Surface.p(lc2, shape=Conic.p(lc2, curv=0.01))
m3surf = Surface.p(lc3, shape=Conic.p(lc3, curv=-0.006))
image1 = Surface.p(lc4)
oapara = Surface.p(lc3, shape=Conic.p(lc5, curv=0.01, cc=-1.))
image2 = Surface.p(lc6, aperture=CircularAperture.p(lc6, maxradius=20.0))
image3 = Surface.p(lc7, aperture=CircularAperture.p(lc7, maxradius=20.0))
elem = OpticalElement.p(lc0, name="TMA")
elem.addMaterial("air", air)
elem.addSurface("object", objectsurf, (None, None))
elem.addSurface("m1", m1surf, (None, None))
elem.addSurface("m2", m2surf, (None, None))
elem.addSurface("m3", m3surf, (None, None))
elem.addSurface("image1", image1, (None, None))
elem.addSurface("oapara", oapara, (None, None))
elem.addSurface("image2", image2, (None, None))
elem.addSurface("image3", image3, (None, None))
# definition of optical system
s = OpticalSystem()
dropletradius = 0.1
lc0 = s.addLocalCoordinateSystem(LocalCoordinates(name="stop", decz=0.0), refname=s.rootcoordinatesystem.name)
lccomprism = s.addLocalCoordinateSystem(LocalCoordinates(name="dropletcenter", decz=2.*dropletradius), refname=lc0.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1", decz=-dropletradius), refname=lccomprism.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2", decz=dropletradius), refname=lccomprism.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf3", decz=0), refname=lccomprism.name)
lc4 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=-2.*dropletradius), refname=lccomprism.name)
stopsurf = Surface(lc0, apert=CircularAperture(lc0, 7*dropletradius))
frontsurf = Surface(lc1, shape=Asphere(lc1, curv=1./dropletradius), apert=CircularAperture(lc1, dropletradius))
rearsurf = Surface(lc2, shape=Asphere(lc2, curv=-1./dropletradius), apert=CircularAperture(lc2, dropletradius))
midsurf = Surface(lc3, shape=Asphere(lc3, curv=0), apert=CircularAperture(lc3, dropletradius))
image = Surface(lc4, apert=CircularAperture(lc4, 7.*dropletradius))
elem = OpticalElement(lc0, name="droplet")
try:
database_basepath = "refractiveindex.info-database/database"
shelf = "3d"
book = "liquids"
refname=s.rootcoordinatesystem.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1",
decz=10.0,
tiltx=5. * math.pi / 180.0),
refname=lc0.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2",
decz=20.0,
tiltx=10. * math.pi / 180.0),
refname=lc1.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=10.0),
refname=lc2.name)
stopsurf = Surface(lc0)
surf1 = Surface(lc1,
shape=Conic(lc1, curv=1. / 24.0),
aperture=CircularAperture(lc1, maxradius=5.0))
surf2 = Surface(lc2,
shape=Conic(lc2, curv=-1. / 24.0),
aperture=CircularAperture(lc2, maxradius=5.0))
image = Surface(lc3)
elem = OpticalElement(lc0, name="grinelement")
grin_strength = 0.5
def nfunc(x, **kw):
"""
Refractive index function.
"""
return grin_strength * np.exp(-x[0]**2 - 4. * x[1]**2) + 1.0
decy=-30.892,
decz=43.083,
tiltx=-si * 50.668 * degree,
tiltThenDecenter=False),
refname=lc0.name)
objsurf = Surface.p(lc0)
D1surf = Surface.p(lcD1)
S1surf = Surface.p(lcS1,
shape=Biconic.p(lcS1,
curvy=si * 1. / 108.187,
curvx=si * 1. / 73.105,
coefficients=[(0., 0.),
(-si * 5.542e-7, -0.08),
(-si * 8.176e-11, -1.379)]),
aperture=CircularAperture.p(lcS1, maxradius=40.0))
D1Psurf = Surface.p(lcD1prime)
D2surf = Surface.p(lcD2)
S2surf = Surface.p(lcS2,
shape=Biconic.p(lcS2,
curvy=si * 1. / 69.871,
curvx=si * 1. / 60.374,
ccy=-0.1368,
ccx=-0.123,
coefficients=[(0., 0.),
(si * 7.233e-11, 29.075),
(si * 4.529e-12, -2.085)]),
aperture=CircularAperture.p(lcS2, maxradius=40.0))
D2Psurf = Surface.p(lcD2prime)
D3surf = Surface.p(lcD3)
S3surf = Surface.p(lcS3,
lc0 = s.addLocalCoordinateSystem(LocalCoordinates(name="stop", decz=0.0),
refname=s.rootcoordinatesystem.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1", decz=-1.048),
refname=lc0.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2", decz=4.0),
refname=lc1.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf3", decz=2.5),
refname=lc2.name)
lc4 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=97.2),
refname=lc3.name)
stopsurf = Surface(lc0, name="stopsurf")
frontsurf = Surface(lc1,
name="frontsurf",
shape=surfShape.Conic(lc1, curv=1. / 62.8, name='conic1'),
apert=CircularAperture(lc1, 12.7))
cementsurf = Surface(lc2,
name="cementsurf",
shape=surfShape.Conic(lc2, curv=-1. / 45.7,
name='conic2'),
apert=CircularAperture(lc2, 12.7))
rearsurf = Surface(lc3,
name="rearsurf",
shape=surfShape.Conic(lc3, curv=-1. / 128.2, name='conic3'),
apert=CircularAperture(lc3, 12.7))
image = Surface(lc4, name="imagesurf")
elem = OpticalElement(lc0, name="thorlabs_AC_254-100-A")
rnd_data1 = np.random.random((3, 3)) #np.eye(3)
rnd_data2 = np.random.random((3, 3)) #np.zeros((3, 3))#
# definition of optical system
s = OpticalSystem()
lc0 = s.addLocalCoordinateSystem(LocalCoordinates(name="stop", decz=1.0),
refname=s.rootcoordinatesystem.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1", decz=10.0),
refname=lc0.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2", decz=5.0),
refname=lc1.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=10.0),
refname=lc2.name)
stopsurf = Surface(lc0)
frontsurf = Surface(lc1,
shape=surfShape.Conic(lc1, curv=0),
apert=CircularAperture(lc1, 10.0))
rearsurf = Surface(lc2,
shape=surfShape.Conic(lc2, curv=0),
apert=CircularAperture(lc3, 10.0))
image = Surface(lc3)
elem = OpticalElement(lc0, name="crystalelem")
no = 1.5
neo = 1.8
myeps = np.array([[no, 0, 0], [0, no, 0], [0, 0, neo]])
crystal = AnisotropicMaterial(lc1, myeps)
elem.addMaterial("crystal", crystal)
refname=lc0.name)
lc2 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf2",
decz=5.0,
tiltx=10 * math.pi /
180.0),
refname=lc1.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="image",
decz=-5.0,
tiltx=-10 * math.pi /
180.0),
refname=lc2.name)
stopsurf = Surface.p(lc0)
frontsurf = Surface.p(lc1,
shape=Conic.p(lc1, curv=0),
aperture=CircularAperture.p(lc1, maxradius=10.0))
rearsurf = Surface.p(lc2,
shape=Conic.p(lc2, curv=0),
aperture=CircularAperture.p(lc3, maxradius=10.0))
image = Surface.p(lc3)
elem = OpticalElement.p(lc0, name="crystalelem")
no = 1.5
neo = 1.8
myeps = np.array([[no, 0, 0], [0, no, 0], [0, 0, neo]])
crystal = AnisotropicMaterial.p(lc1, myeps)
elem.addMaterial("crystal", crystal)
refname=s.rootcoordinatesystem.name)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf1",
decz=10.0,
tiltx=5. * math.pi / 180.0),
refname=lc0.name) # objectDist
lc2 = s.addLocalCoordinateSystem(LocalCoordinates(name="surf2",
decz=20.0,
tiltx=10. * math.pi / 180.0),
refname=lc1.name)
lc3 = s.addLocalCoordinateSystem(LocalCoordinates(name="image", decz=10.0),
refname=lc2.name)
stopsurf = Surface(lc0)
surf1 = Surface(lc1,
shape=surfShape.Conic(lc1, curv=1. / 24.0),
apert=CircularAperture(lc1, 5.0))
surf2 = Surface(lc2,
shape=surfShape.Conic(lc2, curv=-1. / 24.0),
apert=CircularAperture(lc2, 5.0))
image = Surface(lc3)
elem = OpticalElement(lc0, name="grinelement")
grin_strength = 0.5
def nfunc(x):
return grin_strength * np.exp(
-x[0]**2 - 4. * x[1]**2) + 1.0 #(2.5 - (x**2 + 100.0*y**4)/10.**2)
lc1 = s.addLocalCoordinateSystem(LocalCoordinates.p(name="surf1",
decz=-dropletradius),
refname=lccomprism.name) # objectDist
lc2 = s.addLocalCoordinateSystem(
LocalCoordinates.p(name="surf2", decz=dropletradius),
refname=lccomprism.name)
lc3 = s.addLocalCoordinateSystem(
LocalCoordinates.p(name="surf3", decz=0),
refname=lccomprism.name)
lc4 = s.addLocalCoordinateSystem(
LocalCoordinates.p(name="image", decz=-2.*dropletradius),
refname=lccomprism.name)
stopsurf = Surface.p(lc0,
aperture=CircularAperture.p(lc0, maxradius=7*dropletradius))
frontsurf = Surface.p(lc1, shape=Asphere.p(lc1, curv=1./dropletradius),
aperture=CircularAperture.p(lc1, maxradius=dropletradius))
rearsurf = Surface.p(lc2, shape=Asphere.p(lc2, curv=-1./dropletradius),
aperture=CircularAperture.p(lc2, maxradius=dropletradius))
midsurf = Surface.p(lc3, shape=Asphere.p(lc3, curv=0),
aperture=CircularAperture.p(lc3, maxradius=dropletradius))
image = Surface.p(lc4,
aperture=CircularAperture.p(lc4, maxradius=7.*dropletradius))
elem = OpticalElement.p(lc0, name="droplet")
database_basepath = "refractiveindex.info-database/database"
decy=35),
refname=lc5.name)
lc6 = s.addLocalCoordinateSystem(LocalCoordinates(name="image2",
decz=52.8,
tiltx=1 * math.pi / 32),
refname=lc5.name)
lc7 = s.addLocalCoordinateSystem(LocalCoordinates(name="image3", decz=5),
refname=lc6.name)
objectsurf = Surface(lc0)
m1surf = Surface(lc1, shape=surfShape.Conic(lc1, curv=-0.01))
m2surf = Surface(lc2, shape=surfShape.Conic(lc2, curv=0.01))
m3surf = Surface(lc3, shape=surfShape.Conic(lc3, curv=-0.006))
image1 = Surface(lc4)
oapara = Surface(lc3, shape=surfShape.Conic(lc5, curv=0.01, cc=-1.))
image2 = Surface(lc6, apert=CircularAperture(lc6, 20.0))
image3 = Surface(lc7, apert=CircularAperture(lc7, 20.0))
elem = OpticalElement(lc0, name="TMA")
elem.addMaterial("air", air)
elem.addSurface("object", objectsurf, (None, None))
elem.addSurface("m1", m1surf, (None, None))
elem.addSurface("m2", m2surf, (None, None))
elem.addSurface("m3", m3surf, (None, None))
elem.addSurface("image1", image1, (None, None))
elem.addSurface("oapara", oapara, (None, None))
elem.addSurface("image2", image2, (None, None))
elem.addSurface("image3", image3, (None, None))
