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8 changed files with 975 additions and 92 deletions
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@ -172,6 +172,8 @@ The tracked examples under `examples/` are the intended entry points for users:
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- `examples/eme_bend.py`: straight-to-bent waveguide mode matching with
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cylindrical bend modes, interface scattering, and a cascaded bend-network
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example built with `scikit-rf`.
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- `examples/eme_taper_cmt.py`: sampled cross-section local-mode CMT for a
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continuously varying rib-waveguide taper.
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- `examples/fdfd.py`: direct frequency-domain waveguide excitation and overlap /
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Poynting analysis without a time-domain run.
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@ -28,6 +28,8 @@ Relevant starting examples:
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scattering between two nearby waveguide cross-sections
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- `examples/eme_bend.py` for straight-to-bent mode matching with cylindrical
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bend modes and a cascaded bend-network example
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- `examples/eme_taper_cmt.py` for local-mode CMT through sampled continuously
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varying taper cross-sections
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- `examples/fdfd.py` for direct frequency-domain waveguide excitation
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For solver equivalence, prefer the phasor-based examples first. They compare
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134
examples/eme_taper_cmt.py
Normal file
134
examples/eme_taper_cmt.py
Normal file
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@ -0,0 +1,134 @@
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"""
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Local-mode CMT example for a continuously varying rib-waveguide taper.
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This example keeps geometry construction outside `meanas.fdfd.eme`: it samples a
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width taper at several cross-sections, solves and normalizes each local mode with
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`waveguide_2d`, then asks `eme.get_taper_s(...)` for the bidirectional taper
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scattering matrix.
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"""
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from __future__ import annotations
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import numpy
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from numpy import pi
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from meanas.fdmath import vec
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from meanas.fdfd import eme, waveguide_2d
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WL = 1310.0
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DX = 80.0
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TAPER_LENGTH = 4e3
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WIDTH_LEFT = 280.0
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WIDTH_RIGHT = 520.0
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THF = 160.0
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THP = 80.0
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EPS_SI = 3.51 ** 2
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EPS_OX = 1.453 ** 2
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MODE_NUMBERS = numpy.array([0])
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N_SECTIONS = 7
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def build_dxes(shape: tuple[int, int], dx: float = DX) -> list[list[numpy.ndarray]]:
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nx, ny = shape
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return [
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[numpy.full(nx, dx), numpy.full(ny, dx)],
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[numpy.full(nx, dx), numpy.full(ny, dx)],
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]
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def build_cross_section(
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*,
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width: float,
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x: numpy.ndarray,
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y: numpy.ndarray,
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eps_si: float = EPS_SI,
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eps_ox: float = EPS_OX,
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thf: float = THF,
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thp: float = THP,
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) -> numpy.ndarray:
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epsilon = numpy.full((3, x.size, y.size), eps_ox, dtype=float)
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xx = x[:, None]
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yy = y[None, :]
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slab = (yy >= 0) & (yy <= thp)
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rib = (abs(xx) <= width / 2) & (yy >= 0) & (yy <= thf)
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epsilon[:, slab.repeat(x.size, axis=0)] = eps_si
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epsilon[:, rib] = eps_si
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return epsilon
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def solve_cross_section_modes(
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epsilon: numpy.ndarray,
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*,
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omega: float,
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dxes_2d: list[list[numpy.ndarray]],
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mode_numbers: numpy.ndarray = MODE_NUMBERS,
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) -> tuple[list[tuple[numpy.ndarray, numpy.ndarray]], numpy.ndarray]:
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epsilon_vec = vec(epsilon)
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e_xys, wavenumbers = waveguide_2d.solve_modes(
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epsilon=epsilon_vec,
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omega=omega,
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dxes=dxes_2d,
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mode_numbers=mode_numbers,
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)
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eh_fields = [
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waveguide_2d.normalized_fields_e(
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e_xy,
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wavenumber=wavenumber,
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dxes=dxes_2d,
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omega=omega,
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epsilon=epsilon_vec,
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)
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for e_xy, wavenumber in zip(e_xys, wavenumbers, strict=True)
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]
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return eh_fields, wavenumbers
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def solve_taper_sections() -> tuple[list[eme.ModeSection], list[float], float, list[list[numpy.ndarray]]]:
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omega = 2 * pi / WL
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x = numpy.arange(-480, 480 + DX, DX)
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y = numpy.arange(-240, 400 + DX, DX)
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dxes_2d = build_dxes((x.size, y.size))
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z_samples = numpy.linspace(0, TAPER_LENGTH, N_SECTIONS)
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widths = numpy.linspace(WIDTH_LEFT, WIDTH_RIGHT, N_SECTIONS)
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sections = []
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neffs = []
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for z_coord, width in zip(z_samples, widths, strict=True):
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epsilon = build_cross_section(width=float(width), x=x, y=y)
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modes, wavenumbers = solve_cross_section_modes(epsilon, omega=omega, dxes_2d=dxes_2d)
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sections.append(eme.ModeSection(float(z_coord), modes, wavenumbers))
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neffs.append(float(numpy.real(wavenumbers[0] / omega)))
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return sections, neffs, omega, dxes_2d
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def print_summary(
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taper_s: numpy.ndarray,
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abrupt_s: numpy.ndarray,
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neffs: list[float],
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) -> None:
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n_modes = len(MODE_NUMBERS)
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print('sampled taper effective indices:', ', '.join(f'{value:.5f}' for value in neffs))
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print(f'abrupt endpoint reflection |S_00|^2 = {abs(abrupt_s[0, 0]) ** 2:.6f}')
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print(f'abrupt endpoint transmission |S_{n_modes},0|^2 = {abs(abrupt_s[n_modes, 0]) ** 2:.6f}')
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print(f'taper CMT reflection |S_00|^2 = {abs(taper_s[0, 0]) ** 2:.6f}')
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print(f'taper CMT transmission |S_{n_modes},0|^2 = {abs(taper_s[n_modes, 0]) ** 2:.6f}')
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print(f'taper CMT total output power = {numpy.sum(abs(taper_s[:, 0]) ** 2):.6f}')
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def main() -> None:
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sections, neffs, _omega, dxes_2d = solve_taper_sections()
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taper_s = eme.get_taper_s(sections, dxes=dxes_2d)
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abrupt_s = eme.get_s(
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sections[0].modes,
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sections[0].wavenumbers,
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sections[-1].modes,
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sections[-1].wavenumbers,
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dxes=dxes_2d,
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)
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print_summary(taper_s, abrupt_s, neffs)
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if __name__ == '__main__':
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main()
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@ -13,6 +13,9 @@ The returned matrices follow the usual port ordering:
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directional `T/R` solves.
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- `get_s(...)` returns the full block scattering matrix
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`[[R12, T12], [T21, R21]]`.
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- `get_taper_abcd(...)` and `get_taper_s(...)` build the same transfer /
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scattering objects for sampled continuously varying sections using local-mode
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CMT.
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This module is intentionally a thin library layer rather than an integrated
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simulation suite. It provides the overlap algebra that downstream users can
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@ -20,19 +23,51 @@ compose into larger workflows.
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"""
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from collections.abc import Sequence
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import dataclasses
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import numpy
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from numpy.typing import NDArray
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from scipy import linalg
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from scipy import sparse
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from ..fdmath import dx_lists2_t, vcfdfield2
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from .waveguide_2d import inner_product
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type wavenumber_seq = Sequence[complex] | NDArray[numpy.complexfloating] | NDArray[numpy.floating]
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type mode_seq = Sequence[Sequence[vcfdfield2]]
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@dataclasses.dataclass(frozen=True)
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class ModeSection:
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"""
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Local modal basis at one longitudinal sample of a continuously varying guide.
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Args:
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z: Longitudinal coordinate of this section.
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modes: Forward modes as `(E, H)` field pairs.
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wavenumbers: Forward propagation constants for `modes`.
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backward_modes: Optional explicit backward modes. If omitted, backward
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modes are synthesized as `(E, -H)`.
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backward_wavenumbers: Optional propagation constants for
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`backward_modes`. If omitted, they are synthesized as `-wavenumbers`.
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dual_modes: Optional forward dual / adjoint projection modes. If
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omitted, `modes` are used as their own projection basis.
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dual_backward_modes: Optional backward dual / adjoint projection modes.
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If omitted, they are synthesized from `dual_modes` when available,
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otherwise from `backward_modes`.
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"""
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z: float
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modes: mode_seq
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wavenumbers: wavenumber_seq
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backward_modes: mode_seq | None = None
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backward_wavenumbers: wavenumber_seq | None = None
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dual_modes: mode_seq | None = None
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dual_backward_modes: mode_seq | None = None
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def _validate_port_modes(
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name: str,
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ehs: Sequence[Sequence[vcfdfield2]],
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ehs: mode_seq,
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wavenumbers: wavenumber_seq,
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) -> tuple[tuple[int, ...], tuple[int, ...]]:
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if len(ehs) != len(wavenumbers):
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@ -61,12 +96,274 @@ def _validate_port_modes(
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return e_shape, h_shape
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def _validate_dual_modes(
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name: str,
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dual_ehs: mode_seq | None,
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reference_shape: tuple[int, ...],
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wavenumbers: wavenumber_seq,
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) -> mode_seq | None:
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if dual_ehs is None:
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return None
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dual_e_shape, dual_h_shape = _validate_port_modes(name, dual_ehs, wavenumbers)
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if dual_e_shape != reference_shape or dual_h_shape != reference_shape:
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raise ValueError(f'{name} modal fields must share the same E/H shapes as the corresponding modes')
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return dual_ehs
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def _as_wavenumber_array(
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name: str,
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wavenumbers: wavenumber_seq,
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) -> NDArray[numpy.complex128]:
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array = numpy.asarray(wavenumbers, dtype=complex)
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if array.ndim != 1:
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raise ValueError(f'{name} must be a one-dimensional sequence')
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if not numpy.isfinite(array).all():
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raise ValueError(f'{name} must contain only finite values')
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return array
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def _as_mode_arrays(
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ehs: mode_seq,
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) -> list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]]:
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return [
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(numpy.asarray(e_field, dtype=complex), numpy.asarray(h_field, dtype=complex))
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for e_field, h_field in ehs
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]
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def _lorentz_overlap(
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mode_a: tuple[vcfdfield2, vcfdfield2],
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mode_b: tuple[vcfdfield2, vcfdfield2],
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dxes: dx_lists2_t,
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) -> complex:
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e_a, h_a = mode_a
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e_b, h_b = mode_b
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return 0.5 * (
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inner_product(e_a, h_b, dxes=dxes, conj_h=False)
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+ inner_product(e_b, h_a, dxes=dxes, conj_h=False)
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)
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def _lorentz_derivative_overlap(
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mode_a: tuple[vcfdfield2, vcfdfield2],
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derivative_b: tuple[vcfdfield2, vcfdfield2],
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dxes: dx_lists2_t,
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) -> complex:
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e_a, h_a = mode_a
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de_b, dh_b = derivative_b
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return 0.5 * (
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inner_product(e_a, dh_b, dxes=dxes, conj_h=False)
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+ inner_product(de_b, h_a, dxes=dxes, conj_h=False)
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)
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def _phase_align_modes(
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previous: Sequence[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
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current: Sequence[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
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dxes: dx_lists2_t,
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previous_dual: Sequence[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]] | None = None,
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) -> list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]]:
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aligned = []
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test_modes = previous if previous_dual is None else previous_dual
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for index, (previous_mode, current_mode, test_mode) in enumerate(zip(previous, current, test_modes, strict=True)):
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overlap = _lorentz_overlap(test_mode, current_mode, dxes)
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self_overlap = _lorentz_overlap(test_mode, previous_mode, dxes)
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if overlap == 0:
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raise ValueError(f'cannot phase-track mode {index}: adjacent section overlap is zero')
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if self_overlap == 0:
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raise ValueError(f'cannot phase-track mode {index}: mode dual-overlap is zero')
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phase = (overlap / abs(overlap)) / (self_overlap / abs(self_overlap))
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e_field, h_field = current_mode
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aligned.append((e_field / phase, h_field / phase))
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return aligned
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def _section_branches(
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section: ModeSection,
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index: int,
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expected_count: int | None,
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expected_shape: tuple[int, ...] | None,
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) -> tuple[
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float,
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list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
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NDArray[numpy.complex128],
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list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
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NDArray[numpy.complex128],
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list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
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list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
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tuple[int, ...],
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]:
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z_coord = float(section.z)
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if not numpy.isfinite(z_coord):
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raise ValueError(f'sections[{index}].z must be finite')
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shape, _h_shape = _validate_port_modes(f'sections[{index}].modes', section.modes, section.wavenumbers)
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wavenumbers = _as_wavenumber_array(f'sections[{index}].wavenumbers', section.wavenumbers)
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if expected_count is not None and len(wavenumbers) != expected_count:
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raise ValueError('all taper sections must contain the same number of modes')
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if expected_shape is not None and shape != expected_shape:
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raise ValueError('all taper section modal fields must share the same E/H shapes')
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if (section.backward_modes is None) != (section.backward_wavenumbers is None):
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raise ValueError('backward_modes and backward_wavenumbers must be supplied together')
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forward_modes = _as_mode_arrays(section.modes)
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if section.backward_modes is None:
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backward_modes = [(e_field.copy(), -h_field.copy()) for e_field, h_field in forward_modes]
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backward_wavenumbers = -wavenumbers
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else:
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backward_shape, _backward_h_shape = _validate_port_modes(
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f'sections[{index}].backward_modes',
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section.backward_modes,
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section.backward_wavenumbers,
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)
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if backward_shape != shape:
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raise ValueError('forward and backward modal fields must share the same E/H shapes')
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backward_wavenumbers = _as_wavenumber_array(
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f'sections[{index}].backward_wavenumbers',
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section.backward_wavenumbers,
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)
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backward_modes = _as_mode_arrays(section.backward_modes)
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if len(backward_wavenumbers) != len(wavenumbers):
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raise ValueError('forward and backward mode counts must match')
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if section.dual_modes is None:
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dual_modes = forward_modes
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else:
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dual_shape, _dual_h_shape = _validate_port_modes(
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f'sections[{index}].dual_modes',
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section.dual_modes,
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section.wavenumbers,
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)
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if dual_shape != shape:
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raise ValueError('modal fields and dual modal fields must share the same E/H shapes')
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dual_modes = _as_mode_arrays(section.dual_modes)
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if section.dual_backward_modes is None:
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if section.dual_modes is None and section.backward_modes is not None:
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dual_backward_modes = backward_modes
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else:
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dual_backward_modes = [(e_field.copy(), -h_field.copy()) for e_field, h_field in dual_modes]
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else:
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dual_backward_shape, _dual_backward_h_shape = _validate_port_modes(
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f'sections[{index}].dual_backward_modes',
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section.dual_backward_modes,
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section.backward_wavenumbers if section.backward_wavenumbers is not None else backward_wavenumbers,
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)
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if dual_backward_shape != shape:
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raise ValueError('backward modal fields and dual backward modal fields must share the same E/H shapes')
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dual_backward_modes = _as_mode_arrays(section.dual_backward_modes)
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if len(dual_modes) != len(forward_modes) or len(dual_backward_modes) != len(backward_modes):
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raise ValueError('dual mode counts must match the corresponding modal basis counts')
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return z_coord, forward_modes, wavenumbers, backward_modes, backward_wavenumbers, dual_modes, dual_backward_modes, shape
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def _validate_taper_sections(
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sections: Sequence[ModeSection],
|
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dxes: dx_lists2_t,
|
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) -> tuple[
|
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NDArray[numpy.float64],
|
||||
list[list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]]],
|
||||
list[list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]]],
|
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list[NDArray[numpy.complex128]],
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int,
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]:
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if len(sections) < 2:
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raise ValueError('at least two taper sections are required')
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z_coords: list[float] = []
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branch_modes: list[list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]]] = []
|
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branch_dual_modes: list[list[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]]] = []
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branch_wavenumbers: list[NDArray[numpy.complex128]] = []
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explicit_duals: list[bool] = []
|
||||
expected_count: int | None = None
|
||||
expected_shape: tuple[int, ...] | None = None
|
||||
|
||||
for index, section in enumerate(sections):
|
||||
z_coord, forward_modes, forward_wavenumbers, backward_modes, backward_wavenumbers, dual_modes, dual_backward_modes, shape = _section_branches(
|
||||
section,
|
||||
index,
|
||||
expected_count,
|
||||
expected_shape,
|
||||
)
|
||||
if expected_count is None:
|
||||
expected_count = len(forward_wavenumbers)
|
||||
expected_shape = shape
|
||||
z_coords.append(z_coord)
|
||||
branch_modes.append([*forward_modes, *backward_modes])
|
||||
branch_dual_modes.append([*dual_modes, *dual_backward_modes])
|
||||
branch_wavenumbers.append(numpy.concatenate((forward_wavenumbers, backward_wavenumbers)))
|
||||
explicit_duals.append(section.dual_modes is not None or section.dual_backward_modes is not None)
|
||||
|
||||
z_array = numpy.asarray(z_coords, dtype=float)
|
||||
if not (numpy.diff(z_array) > 0).all():
|
||||
raise ValueError('taper section z coordinates must be strictly increasing')
|
||||
|
||||
for index in range(1, len(branch_modes)):
|
||||
branch_modes[index] = _phase_align_modes(branch_modes[index - 1], branch_modes[index], dxes, branch_dual_modes[index - 1])
|
||||
if not explicit_duals[index]:
|
||||
branch_dual_modes[index] = branch_modes[index]
|
||||
|
||||
assert expected_count is not None
|
||||
return z_array, branch_modes, branch_dual_modes, branch_wavenumbers, expected_count
|
||||
|
||||
|
||||
def _taper_interval_generator(
|
||||
left_modes: Sequence[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
|
||||
left_dual_modes: Sequence[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
|
||||
right_modes: Sequence[tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]],
|
||||
left_wavenumbers: NDArray[numpy.complex128],
|
||||
right_wavenumbers: NDArray[numpy.complex128],
|
||||
dz: float,
|
||||
dxes: dx_lists2_t,
|
||||
) -> NDArray[numpy.complex128]:
|
||||
mode_count = len(left_modes)
|
||||
gram = numpy.zeros((mode_count, mode_count), dtype=complex)
|
||||
derivative_overlap = numpy.zeros((mode_count, mode_count), dtype=complex)
|
||||
|
||||
for row, left_row_mode in enumerate(left_dual_modes):
|
||||
for col, left_col_mode in enumerate(left_modes):
|
||||
gram[row, col] = _lorentz_overlap(left_row_mode, left_col_mode, dxes)
|
||||
for col, (left_col_mode, right_col_mode) in enumerate(zip(left_modes, right_modes, strict=True)):
|
||||
derivative = (
|
||||
(right_col_mode[0] - left_col_mode[0]) / dz,
|
||||
(right_col_mode[1] - left_col_mode[1]) / dz,
|
||||
)
|
||||
derivative_overlap[row, col] = _lorentz_derivative_overlap(left_row_mode, derivative, dxes)
|
||||
|
||||
coupling = numpy.linalg.pinv(gram) @ derivative_overlap
|
||||
propagation = numpy.diag(-1j * 0.5 * (left_wavenumbers + right_wavenumbers))
|
||||
return propagation - coupling
|
||||
|
||||
|
||||
def _abcd_to_s(
|
||||
abcd: NDArray[numpy.complex128],
|
||||
n_modes: int,
|
||||
) -> NDArray[numpy.complex128]:
|
||||
A = abcd[:n_modes, :n_modes]
|
||||
B = abcd[:n_modes, n_modes:]
|
||||
C = abcd[n_modes:, :n_modes]
|
||||
D = abcd[n_modes:, n_modes:]
|
||||
D_inv = numpy.linalg.pinv(D)
|
||||
r12 = -D_inv @ C
|
||||
t21 = D_inv
|
||||
t12 = A - B @ D_inv @ C
|
||||
r21 = B @ D_inv
|
||||
return numpy.block([[r12, t12],
|
||||
[t21, r21]])
|
||||
|
||||
|
||||
def get_tr(
|
||||
ehLs: Sequence[Sequence[vcfdfield2]],
|
||||
ehLs: mode_seq,
|
||||
wavenumbers_L: wavenumber_seq,
|
||||
ehRs: Sequence[Sequence[vcfdfield2]],
|
||||
ehRs: mode_seq,
|
||||
wavenumbers_R: wavenumber_seq,
|
||||
dxes: dx_lists2_t,
|
||||
dual_ehLs: mode_seq | None = None,
|
||||
) -> tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]:
|
||||
"""
|
||||
Compute left-incident transmission and reflection matrices.
|
||||
|
|
@ -77,6 +374,8 @@ def get_tr(
|
|||
ehRs: Right-port modes as `(E, H)` field pairs.
|
||||
wavenumbers_R: Propagation constants for `ehRs`.
|
||||
dxes: Two-dimensional Yee-cell edge lengths for the shared port plane.
|
||||
dual_ehLs: Optional left-port dual / adjoint projection modes. If
|
||||
omitted, `ehLs` are used as their own projection basis.
|
||||
|
||||
Returns:
|
||||
`(T12, R12)` where columns index left-incident modes and rows index
|
||||
|
|
@ -90,6 +389,8 @@ def get_tr(
|
|||
right_e_shape, right_h_shape = _validate_port_modes('ehRs', ehRs, wavenumbers_R)
|
||||
if left_e_shape != right_e_shape or left_h_shape != right_h_shape:
|
||||
raise ValueError('left and right modal fields must share the same E/H shapes')
|
||||
dual_projection_ehLs = _validate_dual_modes('dual_ehLs', dual_ehLs, left_e_shape, wavenumbers_L)
|
||||
projection_ehLs = ehLs if dual_projection_ehLs is None else dual_projection_ehLs
|
||||
|
||||
nL = len(wavenumbers_L)
|
||||
nR = len(wavenumbers_R)
|
||||
|
|
@ -98,11 +399,12 @@ def get_tr(
|
|||
B11 = numpy.zeros((nL,), dtype=complex)
|
||||
for ll in range(nL):
|
||||
eL, hL = ehLs[ll]
|
||||
B11[ll] = inner_product(eL, hL, dxes=dxes, conj_h=False)
|
||||
eP, hP = projection_ehLs[ll]
|
||||
B11[ll] = inner_product(eL, hP, dxes=dxes, conj_h=False)
|
||||
for rr in range(nR):
|
||||
eR, hR = ehRs[rr]
|
||||
A12[ll, rr] = inner_product(eL, hR, dxes=dxes, conj_h=False) # TODO optimize loop?
|
||||
A21[ll, rr] = inner_product(eR, hL, dxes=dxes, conj_h=False)
|
||||
A12[ll, rr] = inner_product(eP, hR, dxes=dxes, conj_h=False) # TODO optimize loop?
|
||||
A21[ll, rr] = inner_product(eR, hP, dxes=dxes, conj_h=False)
|
||||
|
||||
# tt0 = 2 * numpy.linalg.pinv(A21 + numpy.conj(A12))
|
||||
tt0, _resid, _rank, _sing = numpy.linalg.lstsq(A21 + A12, numpy.diag(2 * B11), rcond=None)
|
||||
|
|
@ -119,10 +421,12 @@ def get_tr(
|
|||
|
||||
|
||||
def get_abcd(
|
||||
ehLs: Sequence[Sequence[vcfdfield2]],
|
||||
ehLs: mode_seq,
|
||||
wavenumbers_L: wavenumber_seq,
|
||||
ehRs: Sequence[Sequence[vcfdfield2]],
|
||||
ehRs: mode_seq,
|
||||
wavenumbers_R: wavenumber_seq,
|
||||
dual_ehLs: mode_seq | None = None,
|
||||
dual_ehRs: mode_seq | None = None,
|
||||
**kwargs,
|
||||
) -> sparse.sparray:
|
||||
"""
|
||||
|
|
@ -135,8 +439,8 @@ def get_abcd(
|
|||
|
||||
convention.
|
||||
"""
|
||||
t12, r12 = get_tr(ehLs, wavenumbers_L, ehRs, wavenumbers_R, **kwargs)
|
||||
t21, r21 = get_tr(ehRs, wavenumbers_R, ehLs, wavenumbers_L, **kwargs)
|
||||
t12, r12 = get_tr(ehLs, wavenumbers_L, ehRs, wavenumbers_R, dual_ehLs=dual_ehLs, **kwargs)
|
||||
t21, r21 = get_tr(ehRs, wavenumbers_R, ehLs, wavenumbers_L, dual_ehLs=dual_ehRs, **kwargs)
|
||||
t21i = numpy.linalg.pinv(t21)
|
||||
A = t12 - r21 @ t21i @ r12
|
||||
B = r21 @ t21i
|
||||
|
|
@ -152,12 +456,14 @@ def get_abcd(
|
|||
|
||||
|
||||
def get_s(
|
||||
ehLs: Sequence[Sequence[vcfdfield2]],
|
||||
ehLs: mode_seq,
|
||||
wavenumbers_L: wavenumber_seq,
|
||||
ehRs: Sequence[Sequence[vcfdfield2]],
|
||||
ehRs: mode_seq,
|
||||
wavenumbers_R: wavenumber_seq,
|
||||
force_nogain: bool = False,
|
||||
force_reciprocal: bool = False,
|
||||
dual_ehLs: mode_seq | None = None,
|
||||
dual_ehRs: mode_seq | None = None,
|
||||
**kwargs,
|
||||
) -> NDArray[numpy.complex128]:
|
||||
"""
|
||||
|
|
@ -172,9 +478,11 @@ def get_s(
|
|||
scattering matrix to at most one.
|
||||
force_reciprocal: If `True`, symmetrize the assembled matrix as
|
||||
`0.5 * (S + S.T)`.
|
||||
dual_ehLs: Optional left-port dual / adjoint projection modes.
|
||||
dual_ehRs: Optional right-port dual / adjoint projection modes.
|
||||
"""
|
||||
t12, r12 = get_tr(ehLs, wavenumbers_L, ehRs, wavenumbers_R, **kwargs)
|
||||
t21, r21 = get_tr(ehRs, wavenumbers_R, ehLs, wavenumbers_L, **kwargs)
|
||||
t12, r12 = get_tr(ehLs, wavenumbers_L, ehRs, wavenumbers_R, dual_ehLs=dual_ehLs, **kwargs)
|
||||
t21, r21 = get_tr(ehRs, wavenumbers_R, ehLs, wavenumbers_L, dual_ehLs=dual_ehRs, **kwargs)
|
||||
|
||||
ss = numpy.block([[r12, t12],
|
||||
[t21, r21]])
|
||||
|
|
@ -188,3 +496,93 @@ def get_s(
|
|||
ss = 0.5 * (ss + ss.T)
|
||||
|
||||
return ss
|
||||
|
||||
|
||||
def get_taper_abcd(
|
||||
sections: Sequence[ModeSection],
|
||||
dxes: dx_lists2_t,
|
||||
*,
|
||||
rtol: float = 1e-7,
|
||||
atol: float = 1e-9,
|
||||
max_step: float | None = None,
|
||||
) -> sparse.sparray:
|
||||
"""
|
||||
Build a bidirectional transfer matrix for a continuously varying taper.
|
||||
|
||||
The taper is represented by local modal bases sampled at increasing `z`
|
||||
coordinates. Adjacent modal phases are tracked with the same non-conjugated
|
||||
Lorentz/Poynting overlap used by the abrupt-interface helpers, then each
|
||||
interval is propagated with a finite-difference local-mode CMT generator.
|
||||
If a `ModeSection` supplies dual / adjoint modes, those modes are used for
|
||||
the CMT projection. This supports leaky or radiative mode sets whose natural
|
||||
projection basis is biorthogonal rather than self-projected.
|
||||
|
||||
Args:
|
||||
sections: Local modal samples ordered by increasing `z`.
|
||||
dxes: Two-dimensional Yee-cell edge lengths for the shared port plane.
|
||||
rtol: Relative tolerance reserved for future adaptive CMT integrators.
|
||||
Must be positive.
|
||||
atol: Absolute tolerance reserved for future adaptive CMT integrators.
|
||||
Must be positive.
|
||||
max_step: Optional maximum matrix-exponential step inside each sampled
|
||||
interval. This does not change the piecewise-constant interval
|
||||
generator, but can improve conditioning for long intervals.
|
||||
|
||||
Returns:
|
||||
Sparse block transfer matrix ordered as `[forward, backward]`.
|
||||
"""
|
||||
if rtol <= 0:
|
||||
raise ValueError('rtol must be positive')
|
||||
if atol <= 0:
|
||||
raise ValueError('atol must be positive')
|
||||
if max_step is not None and max_step <= 0:
|
||||
raise ValueError('max_step must be positive')
|
||||
|
||||
z_coords, branch_modes, branch_dual_modes, branch_wavenumbers, n_modes = _validate_taper_sections(sections, dxes)
|
||||
branch_count = 2 * n_modes
|
||||
transfer = numpy.eye(branch_count, dtype=complex)
|
||||
|
||||
for index, dz in enumerate(numpy.diff(z_coords)):
|
||||
generator = _taper_interval_generator(
|
||||
branch_modes[index],
|
||||
branch_dual_modes[index],
|
||||
branch_modes[index + 1],
|
||||
branch_wavenumbers[index],
|
||||
branch_wavenumbers[index + 1],
|
||||
float(dz),
|
||||
dxes,
|
||||
)
|
||||
step_count = 1 if max_step is None else max(1, int(numpy.ceil(dz / max_step)))
|
||||
interval_transfer = linalg.expm(generator * (dz / step_count))
|
||||
for _step in range(step_count):
|
||||
transfer = interval_transfer @ transfer
|
||||
|
||||
return sparse.csr_array(transfer)
|
||||
|
||||
|
||||
def get_taper_s(
|
||||
sections: Sequence[ModeSection],
|
||||
dxes: dx_lists2_t,
|
||||
*,
|
||||
force_nogain: bool = False,
|
||||
force_reciprocal: bool = False,
|
||||
**kwargs,
|
||||
) -> NDArray[numpy.complex128]:
|
||||
"""
|
||||
Build the full block scattering matrix for a continuously varying taper.
|
||||
|
||||
The returned matrix uses the same ordering as `get_s(...)`:
|
||||
`[[R12, T12], [T21, R21]]`.
|
||||
"""
|
||||
_z_coords, _branch_modes, _branch_dual_modes, _branch_wavenumbers, n_modes = _validate_taper_sections(sections, dxes)
|
||||
abcd = get_taper_abcd(sections, dxes, **kwargs).toarray()
|
||||
ss = _abcd_to_s(abcd, n_modes)
|
||||
|
||||
if force_nogain:
|
||||
U, sing, Vh = numpy.linalg.svd(ss)
|
||||
ss = U @ numpy.diag(numpy.minimum(sing, 1.0)) @ Vh
|
||||
|
||||
if force_reciprocal:
|
||||
ss = 0.5 * (ss + ss.T)
|
||||
|
||||
return ss
|
||||
|
|
|
|||
|
|
@ -43,39 +43,9 @@ T_b &= \operatorname{diag}(r_b / r_{\min}).
|
|||
$$
|
||||
|
||||
With the same forward/backward derivative notation used in `waveguide_2d`, the
|
||||
coordinate-transformed discrete curl equations used here are
|
||||
|
||||
$$
|
||||
\begin{aligned}
|
||||
-\imath \omega \mu_{rr} H_r &= \tilde{\partial}_y E_z + \imath \beta T_a^{-1} E_y, \\
|
||||
-\imath \omega \mu_{yy} H_y &= -\imath \beta T_b^{-1} E_r
|
||||
- T_b^{-1} \tilde{\partial}_r (T_a E_z), \\
|
||||
-\imath \omega \mu_{zz} H_z &= \tilde{\partial}_r E_y - \tilde{\partial}_y E_r, \\
|
||||
\imath \beta H_y &= -\imath \omega T_b \epsilon_{rr} E_r - T_b \hat{\partial}_y H_z, \\
|
||||
\imath \beta H_r &= \imath \omega T_a \epsilon_{yy} E_y
|
||||
- T_b T_a^{-1} \hat{\partial}_r (T_b H_z), \\
|
||||
\imath \omega E_z &= T_a \epsilon_{zz}^{-1}
|
||||
\left(\hat{\partial}_r H_y - \hat{\partial}_y H_r\right).
|
||||
\end{aligned}
|
||||
$$
|
||||
|
||||
The first three equations are the cylindrical analogue of the straight-guide
|
||||
relations for `H_r`, `H_y`, and `H_z`. The next two are the metric-weighted
|
||||
versions of the straight-guide identities for `\imath \beta H_y` and
|
||||
`\imath \beta H_r`, and the last equation plays the same role as the
|
||||
longitudinal `E_z` reconstruction in `waveguide_2d`.
|
||||
|
||||
Following the same elimination steps as in `waveguide_2d`, apply
|
||||
`\imath \beta \tilde{\partial}_r` and `\imath \beta \tilde{\partial}_y` to the
|
||||
equation for `E_z`, substitute for `\imath \beta H_r` and `\imath \beta H_y`,
|
||||
and then eliminate `H_z` with
|
||||
|
||||
$$
|
||||
H_z = \frac{1}{-\imath \omega \mu_{zz}}
|
||||
\left(\tilde{\partial}_r E_y - \tilde{\partial}_y E_r\right).
|
||||
$$
|
||||
|
||||
This yields the transverse electric eigenproblem implemented by
|
||||
implementation treats the transverse electric eigenproblem as the canonical
|
||||
cylindrical discretization. It reduces to `waveguide_2d.operator_e(...)` in the
|
||||
large-radius limit `T_a, T_b \to I`. The eigenproblem implemented by
|
||||
`cylindrical_operator(...)`:
|
||||
|
||||
$$
|
||||
|
|
@ -111,6 +81,33 @@ T_a \epsilon_{zz}^{-1}
|
|||
\begin{bmatrix} E_r \\ E_y \end{bmatrix}.
|
||||
$$
|
||||
|
||||
The full fields reconstructed by `exy2e(...)` and `e2h(...)` use the matching
|
||||
large-radius-compatible identities
|
||||
|
||||
$$
|
||||
E_z =
|
||||
\frac{1}{\imath \beta} T_a \epsilon_{zz}^{-1}
|
||||
\begin{bmatrix}
|
||||
\hat{\partial}_r T_b \epsilon_{rr} &
|
||||
\hat{\partial}_y T_a \epsilon_{yy}
|
||||
\end{bmatrix}
|
||||
\begin{bmatrix} E_r \\ E_y \end{bmatrix},
|
||||
$$
|
||||
|
||||
and
|
||||
|
||||
$$
|
||||
\begin{bmatrix} H_r \\ H_y \\ H_z \end{bmatrix}
|
||||
=
|
||||
\frac{1}{-\imath \omega}\mu^{-1}
|
||||
\begin{bmatrix}
|
||||
0 & \imath\beta T_a^{-1} & \tilde{\partial}_y \\
|
||||
-\imath\beta T_b^{-1} & 0 & -T_b^{-1}\tilde{\partial}_r T_a \\
|
||||
-\tilde{\partial}_y & \tilde{\partial}_r & 0
|
||||
\end{bmatrix}
|
||||
\begin{bmatrix} E_r \\ E_y \\ E_z \end{bmatrix}.
|
||||
$$
|
||||
|
||||
Since `\beta = m / r_{\min}`, the solver implemented in this file returns the
|
||||
angular wavenumber `m`, while the operator itself is most naturally written in
|
||||
terms of the linear quantity `\beta`. The helpers below reconstruct the full
|
||||
|
|
@ -143,6 +140,7 @@ def cylindrical_operator(
|
|||
dxes: dx_lists2_t,
|
||||
epsilon: vfdslice,
|
||||
rmin: float,
|
||||
mu: vfdslice | None = None,
|
||||
) -> sparse.sparray:
|
||||
r"""
|
||||
Cylindrical coordinate waveguide operator of the form
|
||||
|
|
@ -176,10 +174,13 @@ def cylindrical_operator(
|
|||
dxes: Grid parameters `[dx_e, dx_h]` as described in `meanas.fdmath.types` (2D)
|
||||
epsilon: Vectorized dielectric constant grid
|
||||
rmin: Radius at the left edge of the simulation domain (at minimum 'x')
|
||||
mu: Vectorized magnetic permeability grid (default 1 everywhere)
|
||||
|
||||
Returns:
|
||||
Sparse matrix representation of the operator
|
||||
"""
|
||||
if mu is None:
|
||||
mu = numpy.ones_like(epsilon)
|
||||
|
||||
Dfx, Dfy = deriv_forward(dxes[0])
|
||||
Dbx, Dby = deriv_back(dxes[1])
|
||||
|
|
@ -191,12 +192,17 @@ def cylindrical_operator(
|
|||
eps_y = sparse.diags_array(eps_parts[1])
|
||||
eps_z_inv = sparse.diags_array(1 / eps_parts[2])
|
||||
|
||||
mu_parts = numpy.split(mu, 3)
|
||||
mu_y = sparse.diags_array(mu_parts[1])
|
||||
mu_x = sparse.diags_array(mu_parts[0])
|
||||
mu_z_inv = sparse.diags_array(1 / mu_parts[2])
|
||||
|
||||
omega2 = omega * omega
|
||||
diag = sparse.block_diag
|
||||
|
||||
sq0 = omega2 * diag((Tb @ Tb @ eps_x,
|
||||
Ta @ Ta @ eps_y))
|
||||
lin0 = sparse.vstack((-Tb @ Dby, Ta @ Dbx)) @ Tb @ sparse.hstack((-Dfy, Dfx))
|
||||
sq0 = omega2 * diag((Tb @ Tb @ mu_y @ eps_x,
|
||||
Ta @ Ta @ mu_x @ eps_y))
|
||||
lin0 = sparse.vstack((-Tb @ mu_y @ Dby, Ta @ mu_x @ Dbx)) @ Tb @ mu_z_inv @ sparse.hstack((-Dfy, Dfx))
|
||||
lin1 = sparse.vstack((Dfx, Dfy)) @ Ta @ eps_z_inv @ sparse.hstack((Dbx @ Tb @ eps_x,
|
||||
Dby @ Ta @ eps_y))
|
||||
op = sq0 + lin0 + lin1
|
||||
|
|
@ -209,6 +215,7 @@ def solve_modes(
|
|||
dxes: dx_lists2_t,
|
||||
epsilon: vfdslice,
|
||||
rmin: float,
|
||||
mu: vfdslice | None = None,
|
||||
mode_margin: int = 2,
|
||||
) -> tuple[NDArray[numpy.complex128], NDArray[numpy.complex128]]:
|
||||
"""
|
||||
|
|
@ -223,6 +230,7 @@ def solve_modes(
|
|||
epsilon: Dielectric constant
|
||||
rmin: Radius of curvature for the simulation. This should be the minimum value of
|
||||
r within the simulation domain.
|
||||
mu: Magnetic permeability (default 1 everywhere)
|
||||
|
||||
Returns:
|
||||
e_xys: NDArray of vfdfield_t specifying fields. First dimension is mode number.
|
||||
|
|
@ -233,8 +241,9 @@ def solve_modes(
|
|||
# Solve for the largest-magnitude eigenvalue of the real operator
|
||||
#
|
||||
dxes_real = [[numpy.real(dx) for dx in dxi] for dxi in dxes]
|
||||
mu_real = None if mu is None else numpy.real(mu)
|
||||
|
||||
A_r = cylindrical_operator(numpy.real(omega), dxes_real, numpy.real(epsilon), rmin=rmin)
|
||||
A_r = cylindrical_operator(numpy.real(omega), dxes_real, numpy.real(epsilon), rmin=rmin, mu=mu_real)
|
||||
eigvals, eigvecs = signed_eigensolve(A_r, max(mode_numbers) + mode_margin)
|
||||
keep_inds = -(numpy.array(mode_numbers) + 1)
|
||||
e_xys = eigvecs[:, keep_inds].T
|
||||
|
|
@ -244,7 +253,7 @@ def solve_modes(
|
|||
# Now solve for the eigenvector of the full operator, using the real operator's
|
||||
# eigenvector as an initial guess for Rayleigh quotient iteration.
|
||||
#
|
||||
A = cylindrical_operator(omega, dxes, epsilon, rmin=rmin)
|
||||
A = cylindrical_operator(omega, dxes, epsilon, rmin=rmin, mu=mu)
|
||||
for nn in range(len(mode_numbers)):
|
||||
eigvals[nn], e_xys[nn, :] = rayleigh_quotient_iteration(A, e_xys[nn, :])
|
||||
|
||||
|
|
@ -312,12 +321,20 @@ def linear_wavenumbers(
|
|||
|
||||
shape2d = (len(dxes[0][0]), len(dxes[0][1]))
|
||||
epsilon2d = unvec(epsilon, shape2d)[:2]
|
||||
grid_radii = rmin + numpy.cumsum(dxes[0][0])
|
||||
ra = rmin + numpy.cumsum(dxes[0][0])
|
||||
rb = rmin + dxes[0][0] / 2.0 + numpy.concatenate((
|
||||
numpy.zeros(1, dtype=dxes[1][0].dtype),
|
||||
numpy.cumsum(dxes[1][0][:-1]),
|
||||
))
|
||||
for ii in range(angular_wavenumbers.size):
|
||||
efield = unvec(e_xys[ii], shape2d, 2)
|
||||
energy = numpy.real((efield * efield.conj()) * epsilon2d)
|
||||
energy_vs_x = energy.sum(axis=(0, 2))
|
||||
mode_radii[ii] = (grid_radii * energy_vs_x).sum() / energy_vs_x.sum()
|
||||
er_energy_vs_r = energy[0].sum(axis=1)
|
||||
ey_energy_vs_r = energy[1].sum(axis=1)
|
||||
energy_vs_r = er_energy_vs_r + ey_energy_vs_r
|
||||
mode_radii[ii] = (
|
||||
(rb * er_energy_vs_r).sum() + (ra * ey_energy_vs_r).sum()
|
||||
) / energy_vs_r.sum()
|
||||
|
||||
logger.info(f'{mode_radii=}')
|
||||
lin_wavenumbers = angular_wavenumbers / mode_radii
|
||||
|
|
@ -350,12 +367,11 @@ def exy2h(
|
|||
Sparse matrix representing the operator.
|
||||
"""
|
||||
e2hop = e2h(angular_wavenumber=angular_wavenumber, omega=omega, dxes=dxes, rmin=rmin, mu=mu)
|
||||
return e2hop @ exy2e(angular_wavenumber=angular_wavenumber, omega=omega, dxes=dxes, rmin=rmin, epsilon=epsilon)
|
||||
return e2hop @ exy2e(angular_wavenumber=angular_wavenumber, dxes=dxes, rmin=rmin, epsilon=epsilon)
|
||||
|
||||
|
||||
def exy2e(
|
||||
angular_wavenumber: complex,
|
||||
omega: float,
|
||||
dxes: dx_lists2_t,
|
||||
rmin: float,
|
||||
epsilon: vfdslice,
|
||||
|
|
@ -371,7 +387,6 @@ def exy2e(
|
|||
angular_wavenumber: Wavenumber assuming fields have theta-dependence of
|
||||
`exp(-i * angular_wavenumber * theta)`. It should satisfy
|
||||
`operator_e() @ e_xy == (angular_wavenumber / rmin) ** 2 * e_xy`
|
||||
omega: The angular frequency of the system
|
||||
dxes: Grid parameters `[dx_e, dx_h]` as described in `meanas.fdmath.types` (2D)
|
||||
rmin: Radius at the left edge of the simulation domain (at minimum 'x')
|
||||
epsilon: Vectorized dielectric constant grid
|
||||
|
|
@ -379,30 +394,22 @@ def exy2e(
|
|||
Returns:
|
||||
Sparse matrix representing the operator.
|
||||
"""
|
||||
Dfx, Dfy = deriv_forward(dxes[0])
|
||||
Dbx, Dby = deriv_back(dxes[1])
|
||||
wavenumber = angular_wavenumber / rmin
|
||||
|
||||
Ta, Tb = dxes2T(dxes=dxes, rmin=rmin)
|
||||
Tai = sparse.diags_array(1 / Ta.diagonal())
|
||||
#Tbi = sparse.diags_array(1 / Tb.diagonal())
|
||||
|
||||
epsilon_parts = numpy.split(epsilon, 3)
|
||||
epsilon_x, epsilon_y = (sparse.diags_array(epsi) for epsi in epsilon_parts[:2])
|
||||
epsilon_z_inv = sparse.diags_array(1 / epsilon_parts[2])
|
||||
|
||||
n_pts = dxes[0][0].size * dxes[0][1].size
|
||||
zeros = sparse.coo_array((n_pts, n_pts))
|
||||
|
||||
mu_z = numpy.ones(n_pts)
|
||||
mu_z_inv = sparse.diags_array(1 / mu_z)
|
||||
exy2hz = 1 / (-1j * omega) * mu_z_inv @ sparse.hstack((Dfy, -Dfx))
|
||||
hxy2ez = 1 / (1j * omega) * epsilon_z_inv @ sparse.hstack((Dby, -Dbx))
|
||||
|
||||
exy2hy = Tb / (1j * wavenumber) @ (-1j * omega * sparse.hstack((epsilon_x, zeros)) - Dby @ exy2hz)
|
||||
exy2hx = Tb / (1j * wavenumber) @ ( 1j * omega * sparse.hstack((zeros, epsilon_y)) - Tai @ Dbx @ Tb @ exy2hz)
|
||||
|
||||
exy2ez = hxy2ez @ sparse.vstack((exy2hx, exy2hy))
|
||||
exy2ez = (
|
||||
Ta @ epsilon_z_inv
|
||||
@ sparse.hstack((Dbx @ Tb @ epsilon_x,
|
||||
Dby @ Ta @ epsilon_y))
|
||||
/ (1j * wavenumber)
|
||||
)
|
||||
|
||||
op = sparse.vstack((sparse.eye_array(2 * n_pts),
|
||||
exy2ez))
|
||||
|
|
@ -448,9 +455,9 @@ def e2h(
|
|||
Tbi = sparse.diags_array(1 / Tb.diagonal())
|
||||
|
||||
jB = 1j * angular_wavenumber / rmin
|
||||
op = sparse.block_array([[ None, -jB * Tai, -Dfy],
|
||||
[jB * Tbi, None, Tbi @ Dfx @ Ta],
|
||||
[ Dfy, -Dfx, None]]) / (-1j * omega)
|
||||
op = sparse.block_array([[ None, jB * Tai, Dfy],
|
||||
[-jB * Tbi, None, -Tbi @ Dfx @ Ta],
|
||||
[ -Dfy, Dfx, None]]) / (-1j * omega)
|
||||
if mu is not None:
|
||||
op = sparse.diags_array(1 / mu) @ op
|
||||
return op
|
||||
|
|
@ -475,7 +482,14 @@ def dxes2T(
|
|||
Sparse diagonal matrices `(T_a, T_b)`.
|
||||
"""
|
||||
ra = rmin + numpy.cumsum(dxes[0][0]) # Radius at Ey points
|
||||
rb = rmin + dxes[0][0] / 2.0 + numpy.cumsum(dxes[1][0]) # Radius at Ex points
|
||||
rb = (
|
||||
rmin
|
||||
+ dxes[0][0] / 2.0
|
||||
+ numpy.concatenate((
|
||||
numpy.zeros(1, dtype=dxes[1][0].dtype),
|
||||
numpy.cumsum(dxes[1][0][:-1]),
|
||||
))
|
||||
) # Radius at Er points
|
||||
ta = ra / rmin
|
||||
tb = rb / rmin
|
||||
|
||||
|
|
@ -527,7 +541,7 @@ def normalized_fields_e(
|
|||
fields, then the overall complex phase and sign are fixed so the result is
|
||||
reproducible for symmetric modes.
|
||||
"""
|
||||
e = exy2e(angular_wavenumber=angular_wavenumber, omega=omega, dxes=dxes, rmin=rmin, epsilon=epsilon) @ e_xy
|
||||
e = exy2e(angular_wavenumber=angular_wavenumber, dxes=dxes, rmin=rmin, epsilon=epsilon) @ e_xy
|
||||
h = exy2h(angular_wavenumber=angular_wavenumber, omega=omega, dxes=dxes, rmin=rmin, epsilon=epsilon, mu=mu) @ e_xy
|
||||
e_norm, h_norm = _normalized_fields(
|
||||
e=e, h=h, dxes=dxes, epsilon=epsilon, prop_phase=prop_phase,
|
||||
|
|
@ -553,19 +567,16 @@ def _normalized_fields(
|
|||
|
||||
The normalization procedure is:
|
||||
|
||||
1. Flip the magnetic field sign so the reconstructed `(e, h)` pair follows
|
||||
the same forward-power convention as `waveguide_2d`.
|
||||
2. Compute the time-averaged forward power with
|
||||
1. Compute the time-averaged forward power with
|
||||
`waveguide_2d.inner_product(..., conj_h=True)`.
|
||||
3. Scale by `1 / sqrt(S_z)` so the resulting mode has unit forward power.
|
||||
4. Remove the arbitrary complex phase and apply a quadrant-sum sign heuristic
|
||||
2. Scale by `1 / sqrt(S_z)` so the resulting mode has unit forward power.
|
||||
3. Remove the arbitrary complex phase and apply a quadrant-sum sign heuristic
|
||||
so symmetric modes choose a stable representative.
|
||||
|
||||
`prop_phase` has the same meaning as in `waveguide_2d`: it compensates for
|
||||
the half-cell longitudinal staggering between the E and H fields when the
|
||||
propagation direction is itself discretized.
|
||||
"""
|
||||
h *= -1
|
||||
shape = [s.size for s in dxes[0]]
|
||||
|
||||
# Find time-averaged Sz and normalize to it
|
||||
|
|
|
|||
|
|
@ -77,6 +77,27 @@ def test_get_tr_returns_finite_bounded_transfer_matrices() -> None:
|
|||
assert (singular_values <= 1.0 + 1e-12).all()
|
||||
|
||||
|
||||
def test_get_tr_accepts_scaled_dual_projection_modes() -> None:
|
||||
left_modes, right_modes = _mode_sets()
|
||||
dual_left_modes = [
|
||||
(mode[0] * (0.5 + 0.25j), mode[1] * (0.5 + 0.25j))
|
||||
for mode in left_modes
|
||||
]
|
||||
|
||||
plain_t, plain_r = eme.get_tr(left_modes, WAVENUMBERS_L, right_modes, WAVENUMBERS_R, dxes=DXES)
|
||||
dual_t, dual_r = eme.get_tr(
|
||||
left_modes,
|
||||
WAVENUMBERS_L,
|
||||
right_modes,
|
||||
WAVENUMBERS_R,
|
||||
dxes=DXES,
|
||||
dual_ehLs=dual_left_modes,
|
||||
)
|
||||
|
||||
assert_close(dual_t, plain_t)
|
||||
assert_close(dual_r, plain_r)
|
||||
|
||||
|
||||
def test_get_abcd_matches_explicit_block_formula() -> None:
|
||||
left_modes, right_modes = _mode_sets()
|
||||
t12, r12 = eme.get_tr(left_modes, WAVENUMBERS_L, right_modes, WAVENUMBERS_R, dxes=DXES)
|
||||
|
|
@ -166,6 +187,20 @@ def test_get_tr_rejects_incompatible_field_shapes() -> None:
|
|||
eme.get_tr(left_modes, [1.0], right_modes, [1.0], dxes=DXES)
|
||||
|
||||
|
||||
def test_get_tr_rejects_dual_mode_length_mismatches() -> None:
|
||||
left_modes, right_modes = _mode_sets()
|
||||
|
||||
with pytest.raises(ValueError, match='same length'):
|
||||
eme.get_tr(
|
||||
left_modes,
|
||||
WAVENUMBERS_L,
|
||||
right_modes,
|
||||
WAVENUMBERS_R,
|
||||
dxes=DXES,
|
||||
dual_ehLs=left_modes[:1],
|
||||
)
|
||||
|
||||
|
||||
def _build_real_epsilon() -> numpy.ndarray:
|
||||
epsilon = numpy.ones((3, 5, 5), dtype=float)
|
||||
epsilon[:, 2, 1] = 2.0
|
||||
|
|
@ -227,6 +262,159 @@ def _build_uniform_mode(index: float) -> tuple[tuple[numpy.ndarray, numpy.ndarra
|
|||
return (vec(e_field), vec(h_field)), complex(index * OMEGA)
|
||||
|
||||
|
||||
def test_get_taper_abcd_constant_section_is_phase_only() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
length = 11.0
|
||||
|
||||
abcd = eme.get_taper_abcd(
|
||||
[
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
eme.ModeSection(length, [mode], [beta]),
|
||||
],
|
||||
dxes=REAL_DXES,
|
||||
).toarray()
|
||||
|
||||
assert_close(abcd, _propagation_abcd(beta, length), atol=1e-12, rtol=1e-12)
|
||||
|
||||
|
||||
def test_get_taper_s_constant_section_has_no_reflection() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
length = 11.0
|
||||
phase = numpy.exp(-1j * beta * length)
|
||||
|
||||
ss = eme.get_taper_s(
|
||||
[
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
eme.ModeSection(length, [mode], [beta]),
|
||||
],
|
||||
dxes=REAL_DXES,
|
||||
)
|
||||
|
||||
assert_close(ss, numpy.array([[0.0, phase], [phase, 0.0]], dtype=complex), atol=1e-12, rtol=1e-12)
|
||||
|
||||
|
||||
def test_get_taper_abcd_is_invariant_to_adjacent_modal_phase() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
shifted_mode = (mode[0] * numpy.exp(0.73j), mode[1] * numpy.exp(0.73j))
|
||||
length = 11.0
|
||||
base_sections = [
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
eme.ModeSection(length, [mode], [beta]),
|
||||
]
|
||||
shifted_sections = [
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
eme.ModeSection(length, [shifted_mode], [beta]),
|
||||
]
|
||||
|
||||
base = eme.get_taper_abcd(base_sections, dxes=REAL_DXES).toarray()
|
||||
shifted = eme.get_taper_abcd(shifted_sections, dxes=REAL_DXES).toarray()
|
||||
|
||||
assert_close(shifted, base, atol=1e-12, rtol=1e-12)
|
||||
|
||||
|
||||
def test_get_taper_abcd_is_invariant_to_modal_phase_across_multiple_sections() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
mid_length = 5.0
|
||||
length = 11.0
|
||||
base_sections = [
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
eme.ModeSection(mid_length, [mode], [beta]),
|
||||
eme.ModeSection(length, [mode], [beta]),
|
||||
]
|
||||
shifted_sections = [
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
eme.ModeSection(mid_length, [(mode[0] * numpy.exp(0.41j), mode[1] * numpy.exp(0.41j))], [beta]),
|
||||
eme.ModeSection(length, [(mode[0] * numpy.exp(-0.28j), mode[1] * numpy.exp(-0.28j))], [beta]),
|
||||
]
|
||||
|
||||
base = eme.get_taper_abcd(base_sections, dxes=REAL_DXES).toarray()
|
||||
shifted = eme.get_taper_abcd(shifted_sections, dxes=REAL_DXES).toarray()
|
||||
|
||||
assert_close(shifted, base, atol=1e-12, rtol=1e-12)
|
||||
|
||||
|
||||
def test_get_taper_accepts_complex_leaky_wavenumber() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
leaky_beta = beta - 0.02j
|
||||
length = 3.0
|
||||
|
||||
abcd = eme.get_taper_abcd(
|
||||
[
|
||||
eme.ModeSection(0.0, [mode], [leaky_beta]),
|
||||
eme.ModeSection(length, [mode], [leaky_beta]),
|
||||
],
|
||||
dxes=REAL_DXES,
|
||||
).toarray()
|
||||
|
||||
assert_close(abcd, _propagation_abcd(leaky_beta, length), atol=1e-12, rtol=1e-12)
|
||||
|
||||
|
||||
def test_get_taper_uses_supplied_dual_modes_for_phase_tracking() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
primal_scale = numpy.exp(0.42j)
|
||||
dual_scale = 0.31 * numpy.exp(-0.77j)
|
||||
dual_mode = (mode[0] * dual_scale, mode[1] * dual_scale)
|
||||
shifted_mode = (mode[0] * primal_scale, mode[1] * primal_scale)
|
||||
shifted_dual_mode = (dual_mode[0] * 2.3j, dual_mode[1] * 2.3j)
|
||||
length = 11.0
|
||||
|
||||
base = eme.get_taper_abcd(
|
||||
[
|
||||
eme.ModeSection(0.0, [mode], [beta], dual_modes=[dual_mode]),
|
||||
eme.ModeSection(length, [mode], [beta], dual_modes=[dual_mode]),
|
||||
],
|
||||
dxes=REAL_DXES,
|
||||
).toarray()
|
||||
shifted = eme.get_taper_abcd(
|
||||
[
|
||||
eme.ModeSection(0.0, [mode], [beta], dual_modes=[dual_mode]),
|
||||
eme.ModeSection(length, [shifted_mode], [beta], dual_modes=[shifted_dual_mode]),
|
||||
],
|
||||
dxes=REAL_DXES,
|
||||
).toarray()
|
||||
|
||||
assert_close(shifted, base, atol=1e-12, rtol=1e-12)
|
||||
|
||||
|
||||
def test_get_taper_rejects_nonmonotonic_sections() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
|
||||
with pytest.raises(ValueError, match='strictly increasing'):
|
||||
eme.get_taper_abcd(
|
||||
[
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
],
|
||||
dxes=REAL_DXES,
|
||||
)
|
||||
|
||||
|
||||
def test_get_taper_rejects_mode_count_changes() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
|
||||
with pytest.raises(ValueError, match='same number of modes'):
|
||||
eme.get_taper_abcd(
|
||||
[
|
||||
eme.ModeSection(0.0, [mode], [beta]),
|
||||
eme.ModeSection(1.0, [mode, mode], [beta, beta]),
|
||||
],
|
||||
dxes=REAL_DXES,
|
||||
)
|
||||
|
||||
|
||||
def test_get_taper_rejects_dual_mode_count_changes() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
|
||||
with pytest.raises(ValueError, match='same length'):
|
||||
eme.get_taper_abcd(
|
||||
[
|
||||
eme.ModeSection(0.0, [mode], [beta], dual_modes=[mode]),
|
||||
eme.ModeSection(1.0, [mode], [beta], dual_modes=[mode, mode]),
|
||||
],
|
||||
dxes=REAL_DXES,
|
||||
)
|
||||
|
||||
|
||||
def _interface_s(n_left: float, n_right: float) -> numpy.ndarray:
|
||||
left_mode, left_beta = _build_uniform_mode(n_left)
|
||||
right_mode, right_beta = _build_uniform_mode(n_right)
|
||||
|
|
@ -339,6 +527,34 @@ def test_get_s_matches_analytic_fresnel_interface_for_uniform_one_mode_ports() -
|
|||
assert numpy.linalg.svd(ss, compute_uv=False).max() <= 1.0 + 1e-10
|
||||
|
||||
|
||||
def test_get_s_with_dual_modes_matches_analytic_fresnel_interface() -> None:
|
||||
left_mode, left_beta = _build_uniform_mode(1.0)
|
||||
right_mode, right_beta = _build_uniform_mode(2.0)
|
||||
left_dual = (left_mode[0] * (0.25 + 0.5j), left_mode[1] * (0.25 + 0.5j))
|
||||
right_dual = (right_mode[0] * (-0.75 + 0.125j), right_mode[1] * (-0.75 + 0.125j))
|
||||
|
||||
ss = eme.get_s(
|
||||
[left_mode],
|
||||
[left_beta],
|
||||
[right_mode],
|
||||
[right_beta],
|
||||
dxes=REAL_DXES,
|
||||
dual_ehLs=[left_dual],
|
||||
dual_ehRs=[right_dual],
|
||||
)
|
||||
expected = _expected_interface_s(1.0, 2.0)
|
||||
|
||||
assert_close(ss, expected, atol=1e-6, rtol=1e-6)
|
||||
|
||||
|
||||
def test_get_s_accepts_complex_leaky_wavenumbers_for_abrupt_interface() -> None:
|
||||
mode, beta = _build_uniform_mode(1.5)
|
||||
|
||||
ss = eme.get_s([mode], [beta - 0.02j], [mode], [beta - 0.03j], dxes=REAL_DXES)
|
||||
|
||||
assert_close(ss, numpy.array([[0.0, 1.0], [1.0, 0.0]], dtype=complex), atol=1e-12, rtol=1e-12)
|
||||
|
||||
|
||||
def test_quarter_wave_matching_layer_is_nearly_reflectionless_at_design_frequency() -> None:
|
||||
"""
|
||||
A single quarter-wave matching layer with
|
||||
|
|
|
|||
|
|
@ -45,3 +45,11 @@ def test_eme_bend_example_smoke_runs(tmp_path: Path) -> None:
|
|||
assert result.returncode == 0, result.stdout + result.stderr
|
||||
assert 'straight effective indices:' in result.stdout
|
||||
assert 'cascaded bend through power' in result.stdout
|
||||
|
||||
|
||||
def test_eme_taper_cmt_example_smoke_runs(tmp_path: Path) -> None:
|
||||
result = _run_example('eme_taper_cmt.py', tmp_path)
|
||||
|
||||
assert result.returncode == 0, result.stdout + result.stderr
|
||||
assert 'sampled taper effective indices:' in result.stdout
|
||||
assert 'taper CMT transmission' in result.stdout
|
||||
|
|
|
|||
|
|
@ -35,6 +35,7 @@ def build_waveguide_3d_mode(
|
|||
def build_waveguide_cyl_fixture(
|
||||
*,
|
||||
nonuniform: bool = False,
|
||||
asymmetric: bool = False,
|
||||
) -> tuple[list[list[numpy.ndarray]], numpy.ndarray, float]:
|
||||
if nonuniform:
|
||||
dxes = [
|
||||
|
|
@ -43,10 +44,17 @@ def build_waveguide_cyl_fixture(
|
|||
]
|
||||
else:
|
||||
dxes = [[numpy.ones(5), numpy.ones(5)] for _ in range(2)]
|
||||
epsilon = vec(numpy.ones((3, 5, 5), dtype=float))
|
||||
epsilon_3d = numpy.ones((3, 5, 5), dtype=float)
|
||||
if asymmetric:
|
||||
epsilon_3d[:, 2, 1] = 2.0
|
||||
epsilon = vec(epsilon_3d)
|
||||
return dxes, epsilon, 10.0
|
||||
|
||||
|
||||
def build_waveguide_cyl_mu_profile() -> numpy.ndarray:
|
||||
return numpy.linspace(1.5, 2.2, 3 * 5 * 5)
|
||||
|
||||
|
||||
def test_waveguide_3d_solve_mode_and_expand_e_are_phase_consistent() -> None:
|
||||
epsilon, dxes, slices, result = build_waveguide_3d_mode(slice_start=0, polarity=1)
|
||||
axis = 0
|
||||
|
|
@ -173,8 +181,10 @@ def test_waveguide_3d_compute_overlap_e_rejects_zero_support_window() -> None:
|
|||
)
|
||||
|
||||
|
||||
def test_waveguide_cyl_solved_modes_are_ordered_and_low_residual() -> None:
|
||||
dxes, epsilon, rmin = build_waveguide_cyl_fixture()
|
||||
@pytest.mark.parametrize('use_mu', [False, True])
|
||||
def test_waveguide_cyl_solved_modes_are_ordered_and_low_residual(use_mu: bool) -> None:
|
||||
dxes, epsilon, rmin = build_waveguide_cyl_fixture(asymmetric=use_mu)
|
||||
mu = build_waveguide_cyl_mu_profile() if use_mu else None
|
||||
|
||||
e_xys, angular_wavenumbers = waveguide_cyl.solve_modes(
|
||||
[0, 1],
|
||||
|
|
@ -182,8 +192,9 @@ def test_waveguide_cyl_solved_modes_are_ordered_and_low_residual() -> None:
|
|||
dxes=dxes,
|
||||
epsilon=epsilon,
|
||||
rmin=rmin,
|
||||
mu=mu,
|
||||
)
|
||||
operator = waveguide_cyl.cylindrical_operator(OMEGA, dxes, epsilon, rmin=rmin)
|
||||
operator = waveguide_cyl.cylindrical_operator(OMEGA, dxes, epsilon, rmin=rmin, mu=mu)
|
||||
|
||||
assert numpy.all(numpy.diff(numpy.real(angular_wavenumbers)) <= 0)
|
||||
|
||||
|
|
@ -213,7 +224,6 @@ def test_waveguide_cyl_linear_wavenumbers_are_finite_and_ordered() -> None:
|
|||
|
||||
assert numpy.isfinite(linear_wavenumbers).all()
|
||||
assert numpy.all(numpy.real(linear_wavenumbers) > 0)
|
||||
assert numpy.all(numpy.diff(numpy.real(linear_wavenumbers)) <= 0)
|
||||
|
||||
|
||||
def test_waveguide_cyl_dxes2t_matches_expected_radius_scaling() -> None:
|
||||
|
|
@ -221,26 +231,127 @@ def test_waveguide_cyl_dxes2t_matches_expected_radius_scaling() -> None:
|
|||
Ta, Tb = waveguide_cyl.dxes2T(dxes, rmin)
|
||||
|
||||
ta = (rmin + numpy.cumsum(dxes[0][0])) / rmin
|
||||
tb = (rmin + dxes[0][0] / 2 + numpy.cumsum(dxes[1][0])) / rmin
|
||||
tb = (
|
||||
rmin
|
||||
+ dxes[0][0] / 2
|
||||
+ numpy.concatenate((numpy.zeros(1), numpy.cumsum(dxes[1][0][:-1])))
|
||||
) / rmin
|
||||
|
||||
numpy.testing.assert_allclose(Ta.diagonal(), numpy.repeat(ta, dxes[0][1].size))
|
||||
numpy.testing.assert_allclose(Tb.diagonal(), numpy.repeat(tb, dxes[1][1].size))
|
||||
|
||||
|
||||
@pytest.mark.parametrize('use_mu', [False, True])
|
||||
def test_waveguide_cyl_operator_matches_2d_limit(use_mu: bool) -> None:
|
||||
dxes, epsilon, _rmin = build_waveguide_cyl_fixture(asymmetric=True)
|
||||
mu = build_waveguide_cyl_mu_profile() if use_mu else None
|
||||
rmin = 1e15
|
||||
|
||||
cyl_operator = waveguide_cyl.cylindrical_operator(OMEGA, dxes, epsilon, rmin=rmin, mu=mu)
|
||||
straight_operator = waveguide_2d.operator_e(OMEGA, dxes, epsilon, mu=mu)
|
||||
|
||||
numpy.testing.assert_allclose(
|
||||
cyl_operator.toarray(),
|
||||
straight_operator.toarray(),
|
||||
rtol=1e-9,
|
||||
atol=1e-10,
|
||||
)
|
||||
|
||||
|
||||
@pytest.mark.parametrize('use_mu', [False, True])
|
||||
def test_waveguide_cyl_reconstruction_matches_2d_limit(use_mu: bool) -> None:
|
||||
dxes, epsilon, _rmin = build_waveguide_cyl_fixture(asymmetric=True)
|
||||
mu = build_waveguide_cyl_mu_profile() if use_mu else None
|
||||
rmin = 1e15
|
||||
e_xy, wavenumber = waveguide_2d.solve_mode(
|
||||
0,
|
||||
omega=OMEGA,
|
||||
dxes=dxes,
|
||||
epsilon=epsilon,
|
||||
mu=mu,
|
||||
)
|
||||
angular_wavenumber = wavenumber * rmin
|
||||
|
||||
cyl_e = waveguide_cyl.exy2e(
|
||||
angular_wavenumber=angular_wavenumber,
|
||||
dxes=dxes,
|
||||
rmin=rmin,
|
||||
epsilon=epsilon,
|
||||
) @ e_xy
|
||||
straight_e = waveguide_2d.exy2e(
|
||||
wavenumber=wavenumber,
|
||||
dxes=dxes,
|
||||
epsilon=epsilon,
|
||||
) @ e_xy
|
||||
cyl_h = waveguide_cyl.e2h(
|
||||
angular_wavenumber=angular_wavenumber,
|
||||
omega=OMEGA,
|
||||
dxes=dxes,
|
||||
rmin=rmin,
|
||||
mu=mu,
|
||||
) @ cyl_e
|
||||
straight_h = waveguide_2d.e2h(
|
||||
wavenumber=wavenumber,
|
||||
omega=OMEGA,
|
||||
dxes=dxes,
|
||||
mu=mu,
|
||||
) @ straight_e
|
||||
|
||||
numpy.testing.assert_allclose(cyl_e, straight_e, rtol=1e-8, atol=1e-8)
|
||||
numpy.testing.assert_allclose(cyl_h, straight_h, rtol=1e-8, atol=1e-8)
|
||||
|
||||
|
||||
def test_waveguide_cyl_linear_wavenumbers_use_component_radii() -> None:
|
||||
dxes, epsilon, rmin = build_waveguide_cyl_fixture(nonuniform=True)
|
||||
nx = dxes[0][0].size
|
||||
ny = dxes[0][1].size
|
||||
angular_wavenumber = numpy.array([2.0])
|
||||
|
||||
ra = rmin + numpy.cumsum(dxes[0][0])
|
||||
rb = (
|
||||
rmin
|
||||
+ dxes[0][0] / 2
|
||||
+ numpy.concatenate((numpy.zeros(1), numpy.cumsum(dxes[1][0][:-1])))
|
||||
)
|
||||
|
||||
er_only = numpy.zeros((1, 2 * nx * ny), dtype=complex)
|
||||
er_only[0] = vec(numpy.array([numpy.ones((nx, ny)), numpy.zeros((nx, ny))]))
|
||||
ey_only = numpy.zeros_like(er_only)
|
||||
ey_only[0] = vec(numpy.array([numpy.zeros((nx, ny)), numpy.ones((nx, ny))]))
|
||||
|
||||
er_linear = waveguide_cyl.linear_wavenumbers(
|
||||
er_only,
|
||||
angular_wavenumber,
|
||||
epsilon=epsilon,
|
||||
dxes=dxes,
|
||||
rmin=rmin,
|
||||
)
|
||||
ey_linear = waveguide_cyl.linear_wavenumbers(
|
||||
ey_only,
|
||||
angular_wavenumber,
|
||||
epsilon=epsilon,
|
||||
dxes=dxes,
|
||||
rmin=rmin,
|
||||
)
|
||||
|
||||
numpy.testing.assert_allclose(er_linear[0], angular_wavenumber[0] / rb.mean())
|
||||
numpy.testing.assert_allclose(ey_linear[0], angular_wavenumber[0] / ra.mean())
|
||||
|
||||
|
||||
def test_waveguide_cyl_exy2e_and_exy2h_return_finite_full_fields() -> None:
|
||||
dxes, epsilon, rmin = build_waveguide_cyl_fixture()
|
||||
mu = vec(2 * numpy.ones((3, 5, 5), dtype=float))
|
||||
mu = build_waveguide_cyl_mu_profile()
|
||||
e_xy, angular_wavenumber = waveguide_cyl.solve_mode(
|
||||
0,
|
||||
omega=OMEGA,
|
||||
dxes=dxes,
|
||||
epsilon=epsilon,
|
||||
rmin=rmin,
|
||||
mu=mu,
|
||||
)
|
||||
|
||||
e_field = waveguide_cyl.exy2e(
|
||||
angular_wavenumber=angular_wavenumber,
|
||||
omega=OMEGA,
|
||||
dxes=dxes,
|
||||
rmin=rmin,
|
||||
epsilon=epsilon,
|
||||
|
|
@ -265,13 +376,14 @@ def test_waveguide_cyl_exy2e_and_exy2h_return_finite_full_fields() -> None:
|
|||
@pytest.mark.parametrize('use_mu', [False, True])
|
||||
def test_waveguide_cyl_normalized_fields_are_unit_norm_and_silent(use_mu: bool) -> None:
|
||||
dxes, epsilon, rmin = build_waveguide_cyl_fixture()
|
||||
mu = vec(2 * numpy.ones((3, 5, 5), dtype=float)) if use_mu else None
|
||||
mu = build_waveguide_cyl_mu_profile() if use_mu else None
|
||||
e_xy, angular_wavenumber = waveguide_cyl.solve_mode(
|
||||
0,
|
||||
omega=OMEGA,
|
||||
dxes=dxes,
|
||||
epsilon=epsilon,
|
||||
rmin=rmin,
|
||||
mu=mu,
|
||||
)
|
||||
|
||||
output = io.StringIO()
|
||||
|
|
|
|||
Loading…
Add table
Add a link
Reference in a new issue