347 lines
13 KiB
Python
347 lines
13 KiB
Python
# TODO update tutorials
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from typing import Sequence, Mapping
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import numpy
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from numpy import pi
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from masque import (
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layer_t, Pattern, Ref, Label, Builder, Port, Polygon,
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Library, ILibraryView,
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)
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from masque.utils import ports2data
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from masque.file.gdsii import writefile, check_valid_names
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import pcgen
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import basic_shapes
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from basic_shapes import GDS_OPTS
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LATTICE_CONSTANT = 512
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RADIUS = LATTICE_CONSTANT / 2 * 0.75
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def ports_to_data(pat: Pattern) -> Pattern:
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"""
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Bake port information into the pattern.
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This places a label at each port location on layer (3, 0) with text content
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'name:ptype angle_deg'
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"""
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return ports2data.ports_to_data(pat, layer=(3, 0))
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def data_to_ports(lib: Mapping[str, Pattern], name: str, pat: Pattern) -> Pattern:
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"""
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Scan the Pattern to determine port locations. Same port format as `ports_to_data`
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"""
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return ports2data.data_to_ports(layers=[(3, 0)], library=lib, pattern=pat, name=name)
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def perturbed_l3(
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lattice_constant: float,
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hole: str,
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hole_lib: Mapping[str, Pattern],
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trench_layer: layer_t = (1, 0),
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shifts_a: Sequence[float] = (0.15, 0, 0.075),
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shifts_r: Sequence[float] = (1.0, 1.0, 1.0),
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xy_size: tuple[int, int] = (10, 10),
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perturbed_radius: float = 1.1,
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trench_width: float = 1200,
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) -> Pattern:
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"""
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Generate a `Pattern` representing a perturbed L3 cavity.
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Args:
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lattice_constant: Distance between nearest neighbor holes
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hole: name of a `Pattern` containing a single hole
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hole_lib: Library which contains the `Pattern` object for hole.
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Necessary because we need to know how big it is...
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trench_layer: Layer for the trenches, default `(1, 0)`.
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shifts_a: passed to `pcgen.l3_shift`; specifies lattice constant
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(1 - multiplicative factor) for shifting holes adjacent to
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the defect (same row). Default `(0.15, 0, 0.075)` for first,
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second, third holes.
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shifts_r: passed to `pcgen.l3_shift`; specifies radius for perturbing
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holes adjacent to the defect (same row). Default 1.0 for all holes.
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Provided sequence should have same length as `shifts_a`.
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xy_size: `(x, y)` number of mirror periods in each direction; total size is
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`2 * n + 1` holes in each direction. Default (10, 10).
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perturbed_radius: radius of holes perturbed to form an upwards-driected beam
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(multiplicative factor). Default 1.1.
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trench width: Width of the undercut trenches. Default 1200.
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Returns:
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`Pattern` object representing the L3 design.
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"""
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print('Generating perturbed L3...')
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# Get hole positions and radii
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xyr = pcgen.l3_shift_perturbed_defect(mirror_dims=xy_size,
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perturbed_radius=perturbed_radius,
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shifts_a=shifts_a,
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shifts_r=shifts_r)
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# Build L3 cavity, using references to the provided hole pattern
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pat = Pattern()
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pat.refs[hole] += [
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Ref(scale=r, offset=(lattice_constant * x,
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lattice_constant * y))
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for x, y, r in xyr]
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# Add rectangular undercut aids
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min_xy, max_xy = pat.get_bounds_nonempty(hole_lib)
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trench_dx = max_xy[0] - min_xy[0]
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pat.shapes[trench_layer] += [
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Polygon.rect(ymin=max_xy[1], xmin=min_xy[0], lx=trench_dx, ly=trench_width),
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Polygon.rect(ymax=min_xy[1], xmin=min_xy[0], lx=trench_dx, ly=trench_width),
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]
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# Ports are at outer extents of the device (with y=0)
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extent = lattice_constant * xy_size[0]
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pat.ports = dict(
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input=Port((-extent, 0), rotation=0, ptype='pcwg'),
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output=Port((extent, 0), rotation=pi, ptype='pcwg'),
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)
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ports_to_data(pat)
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return pat
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def waveguide(
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lattice_constant: float,
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hole: str,
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length: int,
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mirror_periods: int,
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) -> Pattern:
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"""
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Generate a `Pattern` representing a photonic crystal line-defect waveguide.
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Args:
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lattice_constant: Distance between nearest neighbor holes
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hole: name of a `Pattern` containing a single hole
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length: Distance (number of mirror periods) between the input and output ports.
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Ports are placed at lattice sites.
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mirror_periods: Number of hole rows on each side of the line defect
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Returns:
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`Pattern` object representing the waveguide.
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"""
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# Generate hole locations
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xy = pcgen.waveguide(length=length, num_mirror=mirror_periods)
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# Build the pattern
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pat = Pattern()
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pat.refs[hole] += [
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Ref(offset=(lattice_constant * x,
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lattice_constant * y))
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for x, y in xy]
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# Ports are at outer edges, with y=0
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extent = lattice_constant * length / 2
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pat.ports = dict(
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left=Port((-extent, 0), rotation=0, ptype='pcwg'),
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right=Port((extent, 0), rotation=pi, ptype='pcwg'),
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)
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ports_to_data(pat)
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return pat
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def bend(
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lattice_constant: float,
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hole: str,
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mirror_periods: int,
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) -> Pattern:
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"""
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Generate a `Pattern` representing a 60-degree counterclockwise bend in a photonic crystal
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line-defect waveguide.
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Args:
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lattice_constant: Distance between nearest neighbor holes
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hole: name of a `Pattern` containing a single hole
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mirror_periods: Minimum number of mirror periods on each side of the line defect.
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Returns:
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`Pattern` object representing the waveguide bend.
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Ports are named 'left' (input) and 'right' (output).
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"""
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# Generate hole locations
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xy = pcgen.wgbend(num_mirror=mirror_periods)
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# Build the pattern
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pat= Pattern()
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pat.refs[hole] += [
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Ref(offset=(lattice_constant * x,
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lattice_constant * y))
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for x, y in xy]
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# Figure out port locations.
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extent = lattice_constant * mirror_periods
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pat.ports = dict(
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left=Port((-extent, 0), rotation=0, ptype='pcwg'),
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right=Port((extent / 2,
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extent * numpy.sqrt(3) / 2),
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rotation=pi * 4 / 3, ptype='pcwg'),
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)
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ports_to_data(pat)
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return pat
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def y_splitter(
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lattice_constant: float,
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hole: str,
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mirror_periods: int,
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) -> Pattern:
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"""
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Generate a `Pattern` representing a photonic crystal line-defect waveguide y-splitter.
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Args:
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lattice_constant: Distance between nearest neighbor holes
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hole: name of a `Pattern` containing a single hole
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mirror_periods: Minimum number of mirror periods on each side of the line defect.
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Returns:
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`Pattern` object representing the y-splitter.
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Ports are named 'in', 'top', and 'bottom'.
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"""
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# Generate hole locations
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xy = pcgen.y_splitter(num_mirror=mirror_periods)
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# Build pattern
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pat = Pattern()
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pat.refs[hole] += [
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Ref(offset=(lattice_constant * x,
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lattice_constant * y))
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for x, y in xy]
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# Determine port locations
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extent = lattice_constant * mirror_periods
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pat.ports = {
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'in': Port((-extent, 0), rotation=0, ptype='pcwg'),
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'top': Port((extent / 2, extent * numpy.sqrt(3) / 2), rotation=pi * 4 / 3, ptype='pcwg'),
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'bot': Port((extent / 2, -extent * numpy.sqrt(3) / 2), rotation=pi * 2 / 3, ptype='pcwg'),
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}
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ports_to_data(pat)
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return pat
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def main(interactive: bool = True) -> None:
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# Generate some basic hole patterns
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shape_lib = {
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'smile': basic_shapes.smile(RADIUS),
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'hole': basic_shapes.hole(RADIUS),
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}
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# Build some devices
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a = LATTICE_CONSTANT
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devices = {}
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devices['wg05'] = waveguide(lattice_constant=a, hole='hole', length=5, mirror_periods=5)
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devices['wg10'] = waveguide(lattice_constant=a, hole='hole', length=10, mirror_periods=5)
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devices['wg28'] = waveguide(lattice_constant=a, hole='hole', length=28, mirror_periods=5)
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devices['wg90'] = waveguide(lattice_constant=a, hole='hole', length=90, mirror_periods=5)
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devices['bend0'] = bend(lattice_constant=a, hole='hole', mirror_periods=5)
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devices['ysplit'] = y_splitter(lattice_constant=a, hole='hole', mirror_periods=5)
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devices['l3cav'] = perturbed_l3(lattice_constant=a, hole='smile', hole_lib=shape_lib, xy_size=(4, 10)) # uses smile :)
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# Turn our dict of devices into a Library.
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# This provides some convenience functions in the future!
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lib = Library(devices)
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#
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# Build a circuit
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#
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# Create a `Builder`, and add the circuit to our library as "my_circuit".
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circ = Builder(library=lib, name='my_circuit')
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# Start by placing a waveguide. Call its ports "in" and "signal".
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circ.place('wg10', offset=(0, 0), port_map={'left': 'in', 'right': 'signal'})
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# Extend the signal path by attaching the "left" port of a waveguide.
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# Since there is only one other port ("right") on the waveguide we
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# are attaching (wg10), it automatically inherits the name "signal".
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circ.plug('wg10', {'signal': 'left'})
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# We could have done the following instead:
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# circ_pat = Pattern()
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# lib['my_circuit'] = circ_pat
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# circ_pat.place(lib.abstract('wg10'), ...)
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# circ_pat.plug(lib.abstract('wg10'), ...)
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# but `Builder` lets us omit some of the repetition of `lib.abstract(...)`, and uses similar
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# syntax to `Pather` and `RenderPather`, which add wire/waveguide routing functionality.
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# Attach a y-splitter to the signal path.
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# Since the y-splitter has 3 ports total, we can't auto-inherit the
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# port name, so we have to specify what we want to name the unattached
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# ports. We can call them "signal1" and "signal2".
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circ.plug('ysplit', {'signal': 'in'}, {'top': 'signal1', 'bot': 'signal2'})
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# Add a waveguide to both signal ports, inheriting their names.
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circ.plug('wg05', {'signal1': 'left'})
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circ.plug('wg05', {'signal2': 'left'})
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# Add a bend to both ports.
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# Our bend's ports "left" and "right" refer to the original counterclockwise
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# orientation. We want the bends to turn in opposite directions, so we attach
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# the "right" port to "signal1" to bend clockwise, and the "left" port
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# to "signal2" to bend counterclockwise.
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# We could also use `mirrored=(True, False)` to mirror one of the devices
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# and then use same device port on both paths.
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circ.plug('bend0', {'signal1': 'right'})
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circ.plug('bend0', {'signal2': 'left'})
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# We add some waveguides and a cavity to "signal1".
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circ.plug('wg10', {'signal1': 'left'})
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circ.plug('l3cav', {'signal1': 'input'})
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circ.plug('wg10', {'signal1': 'left'})
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# "signal2" just gets a single of equivalent length
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circ.plug('wg28', {'signal2': 'left'})
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# Now we bend both waveguides back towards each other
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circ.plug('bend0', {'signal1': 'right'})
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circ.plug('bend0', {'signal2': 'left'})
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circ.plug('wg05', {'signal1': 'left'})
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circ.plug('wg05', {'signal2': 'left'})
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# To join the waveguides, we attach a second y-junction.
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# We plug "signal1" into the "bot" port, and "signal2" into the "top" port.
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# The remaining port gets named "signal_out".
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# This operation would raise an exception if the ports did not line up
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# correctly (i.e. they required different rotations or translations of the
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# y-junction device).
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circ.plug('ysplit', {'signal1': 'bot', 'signal2': 'top'}, {'in': 'signal_out'})
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# Finally, add some more waveguide to "signal_out".
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circ.plug('wg10', {'signal_out': 'left'})
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# We can also add text labels for our circuit's ports.
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# They will appear at the uppermost hierarchy level, while the individual
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# device ports will appear further down, in their respective cells.
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ports_to_data(circ.pattern)
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# Check if we forgot to include any patterns... ooops!
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if dangling := lib.dangling_refs():
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print('Warning: The following patterns are referenced, but not present in the'
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f' library! {dangling}')
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print('We\'ll solve this by merging in shape_lib, which contains those shapes...')
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lib.add(shape_lib)
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assert not lib.dangling_refs()
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# We can visualize the design. Usually it's easier to just view the GDS.
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if interactive:
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print('Visualizing... this step may be slow')
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circ.pattern.visualize(lib)
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#Write out to GDS, only keeping patterns referenced by our circuit (including itself)
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subtree = lib.subtree('my_circuit') # don't include wg90, which we don't use
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check_valid_names(subtree.keys())
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writefile(subtree, 'circuit.gds', **GDS_OPTS)
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if __name__ == '__main__':
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main()
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