class Region(optplan.EmRegion):
"""Represents the area in which we want to consider the objective function
Effectively just the epsilon value in the desired region.
Attributes:
center: Optimization area center
extents: Width and height of the optimization region
power: Multiplier for the effects of the objective function (default 1).
"""
type = schema_utils.polymorphic_model_type("overlap.region")
center = optplan.vec3d()
extents = optplan.vec3d()
power = types.FloatType()
class KerrOverlap(optplan.EmOverlap):
"""Represents the area in which we want to have a strong Kerr nonlinearity
Effectively just the epsilon value in the desired region.
Attributes:
center: Optimization area center
extents: Width and height of the optimization region
power: The transmission power of the mode.
"""
type = schema_utils.polymorphic_model_type("overlap.kerr")
center = optplan.vec3d()
extents = optplan.vec3d()
power = types.FloatType()
class PlaneWaveSource(optplan.EmSource):
"""Represents a plane wave source.
Attributes:
type: Must be "source.plane_wave".
"""
type = schema_utils.polymorphic_model_type("source.plane_wave")
center = optplan.vec3d()
extents = optplan.vec3d()
normal = optplan.vec3d()
theta = types.FloatType()
psi = types.FloatType()
polarization_angle = types.FloatType()
overwrite_bloch_vector = types.BooleanType()
border = types.ListType(types.FloatType())
power = types.FloatType()
class StoredEnergy(optplan.Function):
"""Defines an integral for calculating the stored energy in a resonator.
Attributes:
type: Must be "function.stored_energy".
simulation: Simulation from which electric fields are obtained.
center: Centre of integration region
extents: Width and height of integration region.
epsilon: Permittivity.
"""
type = schema_utils.polymorphic_model_type("function.stored_energy")
simulation = optplan.ReferenceType(optplan.Function)
simulation_space = optplan.ReferenceType(optplan.SimulationSpaceBase)
center = optplan.vec3d()
extents = optplan.vec3d()
epsilon = optplan.ReferenceType(optplan.Function)
class BlochBoundary(schema_utils.Model):
"""Represents a Bloch boundary condition.
Attributes:
bloch_vector: 3D Bloch optplan.vector.
"""
type = schema_utils.polymorphic_model_type("bloch")
bloch_vector = optplan.vec3d(default=[0, 0, 0])
class PowerTransmission(optplan.Function):
"""Defines a function that measures amount of power passing through plane.
The amount of power is computed by summing the Poynting vector across
the desired plane.
Attributes:
field: The simulation field to use.
center: Center of plane to compute power.
extents: Extents of the plane over which to compute power.
normal: Normal direction of the plane. This determines the sign of the
power flowing through the plane.
"""
type = optplan.define_schema_type("function.poynting.plane_power")
field = optplan.ReferenceType(optplan.FdfdSimulation)
center = optplan.vec3d()
extents = optplan.vec3d()
normal = optplan.vec3d()
class GaussianSource(optplan.EmSource):
"""Represents a gaussian source.
Attributes:
type: Must be "source.gaussian_beam".
normalize_by_sim: If `True`, normalize the power by running a
simulation.
"""
type = schema_utils.polymorphic_model_type("source.gaussian_beam")
w0 = types.FloatType()
center = optplan.vec3d()
extents = optplan.vec3d()
normal = optplan.vec3d()
theta = types.FloatType()
psi = types.FloatType()
polarization_angle = types.FloatType()
overwrite_bloch_vector = types.BooleanType()
power = types.FloatType()
normalize_by_sim = types.BooleanType(default=False)
class ImportOverlap(optplan.EmOverlap):
"""Represents a imported overlap vector.
Attributes:
file_name: .mat file containing the overlap vector.
center: the center coordinate of the overlap, allows for translation
of the overlap to the specified center.
"""
type = schema_utils.polymorphic_model_type("overlap.import_field_vector")
file_name = types.StringType()
center = optplan.vec3d()
class WaveguideMode(optplan.ProblemGraphNode):
"""Represents basic information for a waveguide mode.
This class is not intended to be instantiable.
Attributes:
center: Waveguide center.
extents: Width and height of waveguide mode region.
normal: Normal direction of the waveguide. Note that this is also the
mode propagation direction.
mode_num: Mode number. The mode with largest propagation constant is
mode 0, the mode with second largest propagation constant is mode 1,
etc.
power: The transmission power of the mode.
"""
type = schema_utils.polymorphic_model_type("em.waveguide_mode")
center = optplan.vec3d()
extents = optplan.vec3d()
normal = optplan.vec3d()
mode_num = types.IntType()
power = types.FloatType()
class WaveguideModeOverlap(optplan.EmOverlap):
"""Represents a waveguide mode.
The waveguide is assumed to be axis-aligned.
Attributes:
center: Waveguide center.
extents: Width and height of waveguide mode region.
normal: Normal direction of the waveguide. Note that this is also the
mode propagation direction.
mode_num: Mode number. The mode with largest propagation constant is
mode 0, the mode with second largest propagation constant is mode 1,
etc.
power: The transmission power of the mode.
"""
type = schema_utils.polymorphic_model_type("overlap.waveguide_mode")
center = optplan.vec3d()
extents = optplan.vec3d()
normal = optplan.vec3d()
mode_num = types.IntType()
power = types.FloatType()
class FieldMonitor(optplan.Monitor):
"""Defines a field monitor.
A field monitor represents a 3D vector field, e.g. the electric field or
permittivity distribution. The characteristic of a field monitor is that
is unpacks the output of a function (which is a vector) into a 3-component,
3D array, each of which represents a component of the field at a given point
in space (or in technical terms, the vector is unvec'ed).
Because 3D fields are expensive to store, a 2D slice can be specified
by a point in the slice and a normal vector in the slice.
Attributes:
type: Must be "monitor.field"
function: Name of function to monitor.
center: A point in the monitored slice.
normal: Normal of the slice plane (must be axis-aligned).
"""
type = schema_utils.polymorphic_model_type("monitor.field")
function = optplan.ReferenceType(optplan.Function)
center = optplan.vec3d()
normal = optplan.vec3d()
class WaveguideInitializer(Initializer):
"""Initializes parametrization using with a rectangular epsilon shape.
The two levels of the step function can optionally have uniformly random
initialization.
Attributes:
lower_min: minimum value of the lower (background) permittivity
lower_max: maximum value of the lower (background) permittivity
upper_min: minimum value of the upper (waveguide) permittivity
upper_max: maximum value of the upper (waveguide) permittivity
region: optplan.Region object specifying the upper permittivity (waveguide) region
sim_space: simulation object to use to generate the waveguide region
"""
type = schema_utils.polymorphic_model_type("initializer.waveguide")
lower_min = types.FloatType()
lower_max = types.FloatType()
upper_min = types.FloatType()
upper_max = types.FloatType()
center = optplan.vec3d()
extents = optplan.vec3d()
edge_coords = types.ListType(types.ListType(types.IntType))
class WaveguideModeEigSource(optplan.EmSource):
"""Represents a photonic crystal waveguide mode.
The waveguide does NOT have to be axis-aligned. The waveguide mode is
computed as a 3D eigenmode solve.
Attributes:
center: Waveguide center.
extents: Width and height of waveguide mode region.
normal: Normal direction of the waveguide. Note that this is also the
mode propagation direction.
mode_num: Mode number. The mode with largest propagation constant is
mode 0, the mode with second largest propagation constant is mode 1,
etc.
power: The transmission power of the mode.
"""
type = schema_utils.polymorphic_model_type("source.waveguide_mode_eig")
center = optplan.vec3d()
extents = optplan.vec3d()
normal = optplan.vec3d()
mode_num = types.IntType()
power = types.FloatType()
class DipoleSource(optplan.EmSource):
"""Represents a dipole source.
Attributes:
position: Position of the dipole (will snap to grid).
axis: Direction of the dipole (x:0, y:1, z:2).
phase: Phase of the dipole source (in radian).
power: Power assuming uniform dielectric space with the permittivity.
"""
type = schema_utils.polymorphic_model_type("source.dipole_source")
position = optplan.vec3d()
axis = types.IntType()
phase = types.FloatType()
power = types.FloatType()
normalize_by_sim = types.BooleanType(default=False)
class GdsEps(EpsilonSpec):
"""Defines a permittivity distribution using a GDS file.
The GDS file will be flattened so that each layer only contains polygons.
TODO(logansu): Expand description.
Attributes:
type: Must be "gds_epsilon".
gds: URI of GDS file.
mat_stack: Description of each GDS layer permittivity values and
thicknesses.
stack_normal: Direction considered the normal to the stack.
"""
type = schema_utils.polymorphic_model_type("gds")
gds = types.StringType()
mat_stack = types.ModelType(GdsMaterialStack)
stack_normal = optplan.vec3d()
class GdsMeshEps(EpsilonSpec):
"""Defines a permittivity distribution by a lits of meshes.
The meshes are drawn in order of the list. Consequently, if meshes overlap,
the mesh drawn later will take precedence.
Attributes:
gds: GDS file to use for `GdsMesh` types.
background: Default background permittivity.
mesh_list: List of meshes to draw.
stack_normal: Direction considered the normal to the stack.
"""
type = schema_utils.polymorphic_model_type("gds_mesh")
gds = types.StringType()
background = types.ModelType(Material)
mesh_list = types.ListType(types.PolyModelType(Mesh))
stack_normal = optplan.vec3d()
class AnnulusOverlap(optplan.EmOverlap):
"""Represents the annulus mode.
The waveguide is assumed to be axis-aligned.
Attributes:
normal: Normal direction of the annulus. Note that this is also the
mode propagation direction.
mode_num: Mode number. The mode with largest propagation constant is
mode 0, the mode with second largest propagation constant is mode 1,
etc.
power: The transmission power of the mode.
"""
type = schema_utils.polymorphic_model_type("overlap.annulus_mode")
# May not need the normal, we'll see
normal = optplan.vec3d()
mode_num = types.IntType()
power = types.FloatType()
