def setUp(self):
surface1 = Surface(HemisphereGM(2.),
opt.perfect_mirror,
rotation=general_axis_rotation(
N.r_[1, 0, 0], N.pi / 2.))
surface2 = Surface(HemisphereGM(2.),
opt.perfect_mirror,
location=N.array([0, -2, 0]),
rotation=general_axis_rotation(
N.r_[1, 0, 0], -N.pi / 2.))
self._bund = RayBundle()
self._bund.set_directions(N.c_[[0, 1, 0]])
self._bund.set_vertices(N.c_[[0, -1, 0]])
self._bund.set_energy(N.r_[[1]])
self._bund.set_ref_index(N.r_[[1]])
assembly = Assembly()
object1 = AssembledObject()
object2 = AssembledObject()
object1.add_surface(surface1)
object2.add_surface(surface2)
assembly.add_object(object1)
assembly.add_object(object2)
self.engine = TracerEngine(assembly)
def z_rot(x_ang,y_ang,z_ang):
"""
Returns the rotation matrix of a rotation about each coordinate axes done one after another. Input in Radians.
"""
#remove my
mx = N.matrix(general_axis_rotation(r_[1,0,0],x_ang))
my = N.matrix(general_axis_rotation(r_[0,1,0],y_ang))
mz = N.matrix(general_axis_rotation(r_[0,0,1],z_ang))
M1 = my*mx
M2 = mz*M1
return M2
def rotation_matrix(x_ang, y_ang, z_ang):
"""
Returns the rotation matrix of a rotation about each coordinate axes done one after another. Input in Radians.
"""
#remove my
mx = N.matrix(general_axis_rotation(r_[1, 0, 0], x_ang))
my = N.matrix(general_axis_rotation(r_[0, 1, 0], y_ang))
mz = N.matrix(general_axis_rotation(r_[0, 0, 1], z_ang))
M1 = my * mx
M2 = mz * M1
return M2
def setUp(self):
self.x = 1/(math.sqrt(2))
dir = N.c_[[0,self.x,-self.x],[0,1,0]]
position = N.c_[[0,0,1],[0,0,1]]
self._bund = RayBundle(position, dir, energy=N.ones(2))
rot1 = general_axis_rotation([1,0,0],N.pi/4)
rot2 = general_axis_rotation([1,0,0],N.pi/(-4))
surf1 = Surface(FlatGeometryManager(), opt.perfect_mirror, rotation=rot1)
surf2 = Surface(FlatGeometryManager(), opt.perfect_mirror, rotation=rot2)
self.assembly = Assembly()
object = AssembledObject()
object.add_surface(surf1)
object.add_surface(surf2)
self.assembly.add_object(object)
self.engine = TracerEngine(self.assembly)
def setUp(self):
surface1 = Surface(HemisphereGM(2.), opt.perfect_mirror,
rotation=general_axis_rotation(N.r_[1,0,0], N.pi/2.))
surface2 = Surface(HemisphereGM(2.), opt.perfect_mirror,
location=N.array([0,-2,0]),
rotation=general_axis_rotation(N.r_[1,0,0], -N.pi/2.))
self._bund = RayBundle()
self._bund.set_directions(N.c_[[0,1,0]])
self._bund.set_vertices(N.c_[[0,-1,0]])
self._bund.set_energy(N.r_[[1]])
self._bund.set_ref_index(N.r_[[1]])
assembly = Assembly()
object1 = AssembledObject()
object2 = AssembledObject()
object1.add_surface(surface1)
object2.add_surface(surface2)
assembly.add_object(object1)
assembly.add_object(object2)
self.engine = TracerEngine(assembly)
def setUp(self):
surface = Surface(HemisphereGM(1.), opt.perfect_mirror,
rotation=general_axis_rotation(N.r_[1,0,0], N.pi))
self._bund = RayBundle(energy=N.ones(3))
self._bund.set_directions(N.c_[[0,1,0],[0,1,0],[0,-1,0]])
self._bund.set_vertices(N.c_[[0,-2.,0.001],[0,0,0.001],[0,2,0.001]])
assembly = Assembly()
object = AssembledObject()
object.add_surface(surface)
assembly.add_object(object)
self.engine = TracerEngine(assembly)
def setUp(self):
self.x = 1 / (math.sqrt(2))
dir = N.c_[[0, self.x, -self.x], [0, 1, 0]]
position = N.c_[[0, 0, 1], [0, 0, 1]]
self._bund = RayBundle(position, dir, energy=N.ones(2))
rot1 = general_axis_rotation([1, 0, 0], N.pi / 4)
rot2 = general_axis_rotation([1, 0, 0], N.pi / (-4))
surf1 = Surface(FlatGeometryManager(),
opt.perfect_mirror,
rotation=rot1)
surf2 = Surface(FlatGeometryManager(),
opt.perfect_mirror,
rotation=rot2)
self.assembly = Assembly()
object = AssembledObject()
object.add_surface(surf1)
object.add_surface(surf2)
self.assembly.add_object(object)
self.engine = TracerEngine(self.assembly)
def setUp(self):
surface = Surface(HemisphereGM(1.),
opt.perfect_mirror,
rotation=general_axis_rotation(N.r_[1, 0, 0], N.pi))
self._bund = RayBundle(energy=N.ones(3))
self._bund.set_directions(N.c_[[0, 1, 0], [0, 1, 0], [0, -1, 0]])
self._bund.set_vertices(N.c_[[0, -2., 0.001], [0, 0, 0.001],
[0, 2, 0.001]])
assembly = Assembly()
object = AssembledObject()
object.add_surface(surface)
assembly.add_object(object)
self.engine = TracerEngine(assembly)
def setUp(self):
self.assembly = Assembly()
surface1 = Surface(HemisphereGM(3.), optics_callables.perfect_mirror,
location=N.array([0,0,-1.]),
rotation=general_axis_rotation(N.r_[1,0,0], N.pi))
surface2 = Surface(HemisphereGM(3.), optics_callables.perfect_mirror,
location=N.array([0,0,1.]))
self.object = AssembledObject()
self.object.add_surface(surface1)
self.object.add_surface(surface2)
self.assembly.add_object(self.object)
dir = N.c_[[0,0,1.],[0,0,1.]]
position = N.c_[[0,0,-3.],[0,0,-1.]]
self._bund = RayBundle(position, dir, energy=N.ones(2))
def setUp(self):
self.assembly = Assembly()
surface1 = Surface(HemisphereGM(3.),
optics_callables.perfect_mirror,
location=N.array([0, 0, -1.]),
rotation=general_axis_rotation(N.r_[1, 0, 0], N.pi))
surface2 = Surface(HemisphereGM(3.),
optics_callables.perfect_mirror,
location=N.array([0, 0, 1.]))
self.object = AssembledObject()
self.object.add_surface(surface1)
self.object.add_surface(surface2)
self.assembly.add_object(self.object)
dir = N.c_[[0, 0, 1.], [0, 0, 1.]]
position = N.c_[[0, 0, -3.], [0, 0, -1.]]
self._bund = RayBundle(position, dir, energy=N.ones(2))
def test_intersect_ray2(self):
rot = general_axis_rotation([1,0,0],N.pi/4)
surface = Surface(FlatGeometryManager(), opt.perfect_mirror, rotation=rot)
assembly = Assembly()
object = AssembledObject()
object.add_surface(surface)
assembly.add_object(object)
engine = TracerEngine(assembly)
surfaces = assembly.get_surfaces()
objects = assembly.get_objects()
surfs_per_obj = [len(obj.get_surfaces()) for obj in objects]
surf_ownership = N.repeat(N.arange(len(objects)), surfs_per_obj)
ray_ownership = -1*N.ones(self._bund.get_num_rays())
surfs_relevancy = N.ones((len(surfaces), self._bund.get_num_rays()), dtype=N.bool)
params = engine.intersect_ray(self._bund, surfaces, objects, \
surf_ownership, ray_ownership, surfs_relevancy)[0]
correct_params = N.array([[False, True, False]])
N.testing.assert_array_almost_equal(params, correct_params)
def test_intersect_ray2(self):
rot = general_axis_rotation([1, 0, 0], N.pi / 4)
surface = Surface(FlatGeometryManager(),
opt.perfect_mirror,
rotation=rot)
assembly = Assembly()
object = AssembledObject()
object.add_surface(surface)
assembly.add_object(object)
engine = TracerEngine(assembly)
surfaces = assembly.get_surfaces()
objects = assembly.get_objects()
surfs_per_obj = [len(obj.get_surfaces()) for obj in objects]
surf_ownership = N.repeat(N.arange(len(objects)), surfs_per_obj)
ray_ownership = -1 * N.ones(self._bund.get_num_rays())
surfs_relevancy = N.ones((len(surfaces), self._bund.get_num_rays()),
dtype=N.bool)
params = engine.intersect_ray(self._bund, surfaces, objects, \
surf_ownership, ray_ownership, surfs_relevancy)[0]
correct_params = N.array([[False, True, False]])
N.testing.assert_array_almost_equal(params, correct_params)
def thin_bladed_receiver(width, height, absorptivity, blades):
"""
Constructs lambertian receiver consisting of thin blades.
"""
front = Surface(RectPlateGM(width, height),opt.LambertianReceiver(absorptivity),location=r_[0.,width/-2.,0.],rotation=general_axis_rotation(r_[1,0,0],N.pi/2))
n = 0
front.axis = [1,0,0]
front.tilt = N.pi/2
crit_ls = []
crit_ls.append(front)
while n < blades:
blade = Surface(RectPlateGM(width, height),opt.LambertianReceiver(absorptivity),location=r_[width/2-(n*width/(blades-1)),0.,0.],rotation=general_axis_rotation(r_[0,1,0],N.pi/-2))
blade.number = n+1
blade.axis = [0,1,0]
blade.tilt = N.pi/2
crit_ls.append(blade)
n += 1
rec_obj = AssembledObject(surfs=crit_ls)
#obj.surfaces_for_next_iteration = types.MethodType(surfaces_for_next_iteration, obj, obj.__class__)
return rec_obj, obj_ls, crit_ls
def cavity_receiver(width, height, absorptivity=1.):
"""
Constructs a lambertian receiver consisting of three faces. Returns a list of receiving faces, the assembled object
"""
front = Surface(RectPlateGM(width, height),opt.LambertianReceiver(absorptivity),location=r_[0.,0.,0.],rotation=general_axis_rotation(r_[1,0,0],N.pi/2))
left = Surface(RectPlateGM(width, height),opt.LambertianReceiver(absorptivity),location=r_[width/2,width/2,0.],rotation=general_axis_rotation(r_[0,1,0],N.pi/-2))
left.width = width
left.height = height/2.
right = Surface(RectPlateGM(width, height),opt.LambertianReceiver(absorptivity),location=r_[width/-2,width/2,0.],rotation=general_axis_rotation(r_[0,1,0],N.pi/2))
right.width = width
right.height = height/2.
rec_obj = AssembledObject(surfs=[left, front, right])
#obj.surfaces_for_next_iteration = types.MethodType(surfaces_for_next_iteration, obj, obj.__class__)
return rec_obj,[left, front, right], [left, front, right]
