def run_caribu(sources, scene_geometry, output_by_triangle=False):
"""
Calls Caribu for differents energy sources
:Parameters:
------------
- `sources` (int)
- `scene_geometry`
- `output_by_triangle` (bool)
Default 'False'. Return is done by id of geometry. If 'True', return is done by triangle.
:Returns:
---------
- 'out_moy' (dict)
A dict of intercepted variable (energy) per id
- 'out_tri' (dict) only if output_by_triangle = True, return a tuple (out_moy, out_tri)
A dict of intercepted variable (energy) per triangle
"""
c_scene = CaribuScene()
shapes = [geom2shape(k, v) for k, v in scene_geometry.items()]
idmap = c_scene.add_Shapes(shapes)
c_scene.addSources(sources)
output = c_scene.runCaribu(infinity=False)
out_moy = c_scene.output_by_id(output, idmap)
if output_by_triangle:
out_tri = c_scene.output_by_id(output, idmap, aggregate=False)
indices = c_scene.scene_ids
return out_moy, out_tri, indices
else:
return out_moy
def run_caribu(sources, scene_geometry, output_by_triangle = False):
"""
Calls Caribu for differents energy sources
:Parameters:
------------
- `sources` (int)
- `scene_geometry`
- `output_by_triangle` (bool)
Default 'False'. Return is done by id of geometry. If 'True', return is done by triangle.
:Returns:
---------
- 'out_moy' (dict)
A dict of intercepted variable (energy) per id
- 'out_tri' (dict) only if output_by_triangle = True, return a tuple (out_moy, out_tri)
A dict of intercepted variable (energy) per triangle
"""
c_scene = CaribuScene()
shapes=[geom2shape(k,v) for k,v in scene_geometry.iteritems()]
idmap = c_scene.add_Shapes(shapes)
c_scene.addSources(sources)
output = c_scene.runCaribu(infinity=False)
out_moy = c_scene.output_by_id(output, idmap)
if output_by_triangle:
out_tri = c_scene.output_by_id(output, idmap, aggregate = False)
indices = c_scene.scene_ids
return out_moy, out_tri, indices
else:
return out_moy
def caribu(scene, source = (1,(0,0,-1)), infinity=False):
c_scene = CaribuScene()
idmap = c_scene.add_Shapes(scene)
c_scene.addSources(source)
output = c_scene.runCaribu(infinity=infinity)
results = c_scene.output_by_id(output, idmap)['Eabsm2']
return c_scene, results
def caribu(scene, source=(1, (0, 0, -1)), infinity=False):
c_scene = CaribuScene()
idmap = c_scene.add_Shapes(scene)
c_scene.addSources(source)
output = c_scene.runCaribu(infinity=infinity)
results = c_scene.output_by_id(output, idmap)['Eabsm2']
return c_scene, results
def compute_exposed_area(slices):
cyl = Cylinder(radius, height, False, slices)
cyl_rotated = AxisRotated((0, 1, 0), pi / 2., cyl)
scene = {1: cyl_rotated}
sources = diffuse_source(1)
c_scene = CaribuScene()
idmap = c_scene.add_Shapes(scene)
c_scene.addSources(sources)
output = c_scene.runCaribu(infinity=False)
out = c_scene.output_by_id(output, idmap)
star = out['Ei'].values()[0]
area = out['Area'].values()[0]
exposed_area = star * area
return exposed_area
def compute_exposed_area(slices):
cyl = Cylinder(radius, height, False, slices)
cyl_rotated = AxisRotated((0,1,0), pi/2., cyl)
scene = {1: cyl_rotated}
sources = diffuse_source(1)
c_scene = CaribuScene()
idmap = c_scene.add_Shapes(scene)
c_scene.addSources(sources)
output = c_scene.runCaribu(infinity=False)
out = c_scene.output_by_id(output, idmap)
star = out['Ei'].values()[0]
area = out['Area'].values()[0]
exposed_area = star * area
return exposed_area
