fdfd_tools/meanas/fdfd/waveguide_mode.py

from typing import Dict, List
import numpy
import scipy.sparse as sparse

from .. import vec, unvec, dx_lists_t, vfield_t, field_t
from . import operators, waveguide, functional
from ..eigensolvers import signed_eigensolve, rayleigh_quotient_iteration


def solve_waveguide_mode_2d(mode_number: int,
                            omega: complex,
                            dxes: dx_lists_t,
                            epsilon: field_t,
                            mu: field_t = None,
                            mode_margin: int = 2,
                            ) -> Dict[str, complex or field_t]:
    """
    Given a 2d region, attempts to solve for the eigenmode with the specified mode number.

    :param mode_number: Number of the mode, 0-indexed.
    :param omega: Angular frequency of the simulation
    :param dxes: Grid parameters [dx_e, dx_h] as described in meanas.types
    :param epsilon: Dielectric constant
    :param mu: Magnetic permeability (default 1 everywhere)
    :param mode_margin: The eigensolver will actually solve for (mode_number + mode_margin)
        modes, but only return the target mode. Increasing this value can improve the solver's
        ability to find the correct mode. Default 2.
    :return: {'E': numpy.ndarray, 'H': numpy.ndarray, 'wavenumber': complex}
    """

    '''
    Solve for the largest-magnitude eigenvalue of the real operator
    '''
    dxes_real = [[numpy.real(dx) for dx in dxi] for dxi in dxes]
    A_r = waveguide.operator_e(numpy.real(omega), dxes_real, vec(numpy.real(epsilon)), vec(numpy.real(mu)))

    eigvals, eigvecs = signed_eigensolve(A_r, mode_number + mode_margin)
    exy = eigvecs[:, -(mode_number + 1)]

    '''
    Now solve for the eigenvector of the full operator, using the real operator's
     eigenvector as an initial guess for Rayleigh quotient iteration.
    '''
    A = waveguide.operator_e(omega, dxes, vec(epsilon), vec(mu))
    eigval, exy = rayleigh_quotient_iteration(A, exy)

    # Calculate the wave-vector (force the real part to be positive)
    wavenumber = numpy.sqrt(eigval)
    wavenumber *= numpy.sign(numpy.real(wavenumber))

    e, h = waveguide.normalized_fields_e(exy, wavenumber, omega, dxes, vec(epsilon), vec(mu))

    shape = [d.size for d in dxes[0]]
    fields = {
        'wavenumber': wavenumber,
        'E': unvec(e, shape),
        'H': unvec(h, shape),
    }

    return fields


def solve_waveguide_mode(mode_number: int,
                         omega: complex,
                         dxes: dx_lists_t,
                         axis: int,
                         polarity: int,
                         slices: List[slice],
                         epsilon: field_t,
                         mu: field_t = None,
                         ) -> Dict[str, complex or numpy.ndarray]:
    """
    Given a 3D grid, selects a slice from the grid and attempts to
     solve for an eigenmode propagating through that slice.

    :param mode_number: Number of the mode, 0-indexed
    :param omega: Angular frequency of the simulation
    :param dxes: Grid parameters [dx_e, dx_h] as described in meanas.types
    :param axis: Propagation axis (0=x, 1=y, 2=z)
    :param polarity: Propagation direction (+1 for +ve, -1 for -ve)
    :param slices: epsilon[tuple(slices)] is used to select the portion of the grid to use
        as the waveguide cross-section. slices[axis] should select only one
    :param epsilon: Dielectric constant
    :param mu: Magnetic permeability (default 1 everywhere)
    :return: {'E': List[numpy.ndarray], 'H': List[numpy.ndarray], 'wavenumber': complex}
    """
    if mu is None:
        mu = numpy.ones_like(epsilon)

    slices = tuple(slices)

    '''
    Solve the 2D problem in the specified plane
    '''
    # Define rotation to set z as propagation direction
    order = numpy.roll(range(3), 2 - axis)
    reverse_order = numpy.roll(range(3), axis - 2)

    # Find dx in propagation direction
    dxab_forward = numpy.array([dx[order[2]][slices[order[2]]] for dx in dxes])
    dx_prop = 0.5 * sum(dxab_forward)

    # Reduce to 2D and solve the 2D problem
    args_2d = {
        'dxes': [[dx[i][slices[i]] for i in order[:2]] for dx in dxes],
        'epsilon': [epsilon[i][slices].transpose(order) for i in order],
        'mu': [mu[i][slices].transpose(order) for i in order],
    }
    fields_2d = solve_waveguide_mode_2d(mode_number, omega=omega, **args_2d)

    '''
    Apply corrections and expand to 3D
    '''
    # Correct wavenumber to account for numerical dispersion.
    fields_2d['wavenumber'] = 2/dx_prop * numpy.arcsin(fields_2d['wavenumber'] * dx_prop/2)

    # Adjust for propagation direction
    fields_2d['H'] *= polarity

    # Apply phase shift to H-field
    fields_2d['H'][:2] *= numpy.exp(-1j * polarity * 0.5 * fields_2d['wavenumber'] * dx_prop)
    fields_2d['E'][2]  *= numpy.exp(-1j * polarity * 0.5 * fields_2d['wavenumber'] * dx_prop)

    # Expand E, H to full epsilon space we were given
    E = numpy.zeros_like(epsilon, dtype=complex)
    H = numpy.zeros_like(epsilon, dtype=complex)
    for a, o in enumerate(reverse_order):
        E[(a, *slices)] = fields_2d['E'][o][:, :, None].transpose(reverse_order)
        H[(a, *slices)] = fields_2d['H'][o][:, :, None].transpose(reverse_order)

    results = {
        'wavenumber': fields_2d['wavenumber'],
        'H': H,
        'E': E,
    }
    return results


def compute_source(E: field_t,
                   H: field_t,
                   wavenumber: complex,
                   omega: complex,
                   dxes: dx_lists_t,
                   axis: int,
                   polarity: int,
                   slices: List[slice],
                   mu: field_t = None,
                   ) -> field_t:
    """
    Given an eigenmode obtained by solve_waveguide_mode, returns the current source distribution
    necessary to position a unidirectional source at the slice location.

    :param E: E-field of the mode
    :param H: H-field of the mode (advanced by half of a Yee cell from E)
    :param wavenumber: Wavenumber of the mode
    :param omega: Angular frequency of the simulation
    :param dxes: Grid parameters [dx_e, dx_h] as described in meanas.types
    :param axis: Propagation axis (0=x, 1=y, 2=z)
    :param polarity: Propagation direction (+1 for +ve, -1 for -ve)
    :param slices: epsilon[tuple(slices)] is used to select the portion of the grid to use
        as the waveguide cross-section. slices[axis] should select only one
    :param mu: Magnetic permeability (default 1 everywhere)
    :return: J distribution for the unidirectional source
    """
    J = numpy.zeros_like(E, dtype=complex)
    M = numpy.zeros_like(E, dtype=complex)

    src_order = numpy.roll(range(3), -axis)

#    exp_iphi = numpy.exp(1j * polarity * wavenumber * dxes[1][axis][slices[axis]])
#    rollby = -1 if polarity > 0 else 0
#    J[src_order[1]] = +exp_iphi * H[src_order[2]] * polarity / dxes[1][axis][slices[axis]]
#    J[src_order[2]] = -exp_iphi * H[src_order[1]] * polarity / dxes[1][axis][slices[axis]]
#    M[src_order[1]] = +numpy.roll(E[src_order[2]], rollby, axis=axis) / dxes[0][axis][slices[axis]]
#    M[src_order[2]] = -numpy.roll(E[src_order[1]], rollby, axis=axis) / dxes[0][axis][slices[axis]]

    s2 = [slice(None), slice(None), slice(None)]
    s2[axis] = slice(slices[axis].start, slices[axis].stop)
    s2 = (src_order, *s2)

    rollby = 1 if polarity < 0 else 0
    exp_iphi = numpy.exp(-1j * -rollby * wavenumber * dxes[1][axis][slices[axis]])
    J[s2] = numpy.roll(functional.curl_h(dxes=dxes)(H), -rollby, axis=axis+1)[s2] * exp_iphi * -polarity
    M[s2] = numpy.roll(functional.curl_e(dxes=dxes)(E), rollby, axis=axis+1)[s2]

    m2j = functional.m2j(omega, dxes, mu)
    Jm = m2j(M)

    Jtot = J + Jm
    return Jtot


def compute_overlap_e(E: field_t,
                      H: field_t,
                      wavenumber: complex,
                      omega: complex,
                      dxes: dx_lists_t,
                      axis: int,
                      polarity: int,
                      slices: List[slice],
                      mu: field_t = None,
                      ) -> field_t:
    """
    Given an eigenmode obtained by solve_waveguide_mode, calculates overlap_e for the
    mode orthogonality relation Integrate(((E x H_mode) + (E_mode x H)) dot dn)
    [assumes reflection symmetry].

    overlap_e makes use of the e2h operator to collapse the above expression into
     (vec(E) @ vec(overlap_e)), allowing for simple calculation of the mode overlap.

    :param E: E-field of the mode
    :param H: H-field of the mode (advanced by half of a Yee cell from E)
    :param wavenumber: Wavenumber of the mode
    :param omega: Angular frequency of the simulation
    :param dxes: Grid parameters [dx_e, dx_h] as described in meanas.types
    :param axis: Propagation axis (0=x, 1=y, 2=z)
    :param polarity: Propagation direction (+1 for +ve, -1 for -ve)
    :param slices: epsilon[tuple(slices)] is used to select the portion of the grid to use
        as the waveguide cross-section. slices[axis] should select only one
    :param mu: Magnetic permeability (default 1 everywhere)
    :return: overlap_e for calculating the mode overlap
    """
    slices = tuple(slices)

    cross_plane = [slice(None)] * 4
    cross_plane[axis + 1] = slices[axis]
    cross_plane = tuple(cross_plane)

    # Determine phase factors for parallel slices
    a_shape = numpy.roll([-1, 1, 1], axis)
    a_E = numpy.real(dxes[0][axis]).cumsum()
    a_H = numpy.real(dxes[1][axis]).cumsum()
    iphi = -polarity * 1j * wavenumber
    phase_E = numpy.exp(iphi * (a_E - a_E[slices[axis]])).reshape(a_shape)
    phase_H = numpy.exp(iphi * (a_H - a_H[slices[axis]])).reshape(a_shape)

    # Expand our slice to the entire grid using the calculated phase factors
    Ee = phase_E * E[cross_plane]
    He = phase_H * H[cross_plane]


    # Write out the operator product for the mode orthogonality integral
    domain = numpy.zeros_like(E[0], dtype=int)
    domain[slices] = 1

    npts = E[0].size
    dn = numpy.zeros(npts * 3, dtype=int)
    dn[0:npts] = 1
    dn = numpy.roll(dn, npts * axis)

    e2h = operators.e2h(omega, dxes, mu)
    ds = sparse.diags(vec([domain]*3))
    h_cross_ = operators.poynting_h_cross(vec(He), dxes)
    e_cross_ = operators.poynting_e_cross(vec(Ee), dxes)

    overlap_e = dn @ ds @ (-h_cross_ + e_cross_ @ e2h)

    # Normalize
    dx_forward = dxes[0][axis][slices[axis]]
    norm_factor = numpy.abs(overlap_e @ vec(Ee))
    overlap_e /= norm_factor * dx_forward

    return unvec(overlap_e, E[0].shape)


def solve_waveguide_mode_cylindrical(mode_number: int,
                                     omega: complex,
                                     dxes: dx_lists_t,
                                     epsilon: vfield_t,
                                     r0: float,
                                     ) -> Dict[str, complex or field_t]:
    """
    TODO: fixup
    Given a 2d (r, y) slice of epsilon, attempts to solve for the eigenmode
     of the bent waveguide with the specified mode number.

    :param mode_number: Number of the mode, 0-indexed
    :param omega: Angular frequency of the simulation
    :param dxes: Grid parameters [dx_e, dx_h] as described in meanas.types.
        The first coordinate is assumed to be r, the second is y.
    :param epsilon: Dielectric constant
    :param r0: Radius of curvature for the simulation. This should be the minimum value of
        r within the simulation domain.
    :return: {'E': List[numpy.ndarray], 'H': List[numpy.ndarray], 'wavenumber': complex}
    """

    '''
    Solve for the largest-magnitude eigenvalue of the real operator
    '''
    dxes_real = [[numpy.real(dx) for dx in dxi] for dxi in dxes]

    A_r = waveguide.cylindrical_operator(numpy.real(omega), dxes_real, numpy.real(epsilon), r0)
    eigvals, eigvecs = signed_eigensolve(A_r, mode_number + 3)
    v = eigvecs[:, -(mode_number+1)]

    '''
    Now solve for the eigenvector of the full operator, using the real operator's
     eigenvector as an initial guess for Rayleigh quotient iteration.
    '''
    A = waveguide.cylindrical_operator(omega, dxes, epsilon, r0)
    eigval, v = rayleigh_quotient_iteration(A, v)

    # Calculate the wave-vector (force the real part to be positive)
    wavenumber = numpy.sqrt(eigval)
    wavenumber *= numpy.sign(numpy.real(wavenumber))

    # TODO: Perform correction on wavenumber to account for numerical dispersion.

    shape = [d.size for d in dxes[0]]
    v = numpy.hstack((v, numpy.zeros(shape[0] * shape[1])))
    fields = {
        'wavenumber': wavenumber,
        'E': unvec(v, shape),
#        'E': unvec(e, shape),
#        'H': unvec(h, shape),
    }

    return fields


def compute_source_q(E: field_t,
                     H: field_t,
                     wavenumber: complex,
                     omega: complex,
                     dxes: dx_lists_t,
                     axis: int,
                     polarity: int,
                     slices: List[slice],
                     mu: field_t = None,
                     ) -> field_t:
    A1f = functional.curl_h(dxes)
    A2f = functional.curl_e(dxes)

    J = A1f(H)
    M = A2f(-E)

    m2j = functional.m2j(omega, dxes, mu)
    Jm = m2j(M)

    Jtot = J + Jm
    return Jtot, J, M


def compute_source_e(QE: field_t,
                     omega: complex,
                     dxes: dx_lists_t,
                     axis: int,
                     polarity: int,
                     slices: List[slice],
                     epsilon: field_t,
                     mu: field_t = None,
                     ) -> field_t:
    """
    Want AQE = -iwJ, where Q is mask and normally AE = -iwJ
    ## Want (AQ-QA) E = -iwJ, where Q is a mask
    ## If E is an eigenmode, AE = 0 so just AQE = -iwJ
    Really only need E in 4 cells along axis (0, 0, Emode1, Emode2), find AE (1 iteration), then use center 2 cells as src
    Maybe better to use (0, Emode1, Emode2, Emode3), find AE (1 iteration), then use left 2 cells as src?
    """
    slices = tuple(slices)

    # Trim a cell from each end of the propagation axis
    slices_reduced = list(slices)
    for aa in range(3):
        if aa == axis:
            if polarity > 0:
                slices_reduced[axis] = slice(slices[axis].start, slices[axis].start+2)
            else:
                slices_reduced[axis] = slice(slices[axis].stop-2, slices[axis].stop)
        else:
            start = slices[aa].start
            stop = slices[aa].stop
#            if start is not None or stop is not None:
#                if start is None:
#                    start = 1
#                    stop -= 1
#                elif stop is None:
#                    stop = E.shape[aa + 1] - 1
#                    start += 1
#                else:
#                    start += 1
#                    stop -= 1
#                slices_reduced[aa] = slice(start, stop)
    slices_reduced = (slice(None), *slices_reduced)

    # Don't actually need to mask out E here since it needs to be pre-masked (QE)

    A = functional.e_full(omega, dxes, epsilon, mu)
    J4 = A(QE) / (-1j * omega)             #J4 is 4-cell result of -iwJ = A QE

    J = numpy.zeros_like(J4)
    J[slices_reduced] = J4[slices_reduced]
    return J


def compute_source_wg(E: field_t,
                      wavenumber: complex,
                      omega: complex,
                      dxes: dx_lists_t,
                      axis: int,
                      polarity: int,
                      slices: List[slice],
                      epsilon: field_t,
                      mu: field_t = None,
                      ) -> field_t:
    slices = tuple(slices)
    Etgt, _slices2 = compute_overlap_ce(E=E, wavenumber=wavenumber,
                                        dxes=dxes, axis=axis, polarity=polarity,
                                        slices=slices)

    slices4 = list(slices)
    slices4[axis] = slice(slices[axis].start - 4 * polarity, slices[axis].start)
    slices4 = tuple(slices4)

    J = compute_source_e(QE=Etgt,
                         omega=omega, dxes=dxes, axis=axis,
                         polarity=polarity, slices=slices4,
                         epsilon=epsilon, mu=mu)
    return J


def compute_overlap_ce(E: field_t,
                       wavenumber: complex,
                       dxes: dx_lists_t,
                       axis: int,
                       polarity: int,
                       slices: List[slice],
                       ) -> field_t:
    slices = tuple(slices)

    Ee = expand_wgmode_e(E=E, wavenumber=wavenumber,
                         dxes=dxes, axis=axis, polarity=polarity,
                         slices=slices)

    start, stop = sorted((slices[axis].start, slices[axis].start - 2 * polarity))

    slices2 = list(slices)
    slices2[axis] = slice(start, stop)
    slices2 = (slice(None), *slices2)

    Etgt = numpy.zeros_like(Ee)
    Etgt[slices2] = Ee[slices2]

    Etgt /= (Etgt.conj() * Etgt).sum()
    return Etgt, slices2


def expand_wgmode_e(E: field_t,
                    wavenumber: complex,
                    dxes: dx_lists_t,
                    axis: int,
                    polarity: int,
                    slices: List[slice],
                    ) -> field_t:
    slices = tuple(slices)

    # Determine phase factors for parallel slices
    a_shape = numpy.roll([1, -1, 1, 1], axis)
    a_E = numpy.real(dxes[0][axis]).cumsum()
    r_E = a_E - a_E[slices[axis]]
    iphi = polarity * -1j * wavenumber
    phase_E = numpy.exp(iphi * r_E).reshape(a_shape)

    # Expand our slice to the entire grid using the phase factors
    E_expanded = numpy.zeros_like(E)

    slices_exp = list(slices)
    slices_exp[axis] = slice(E.shape[axis + 1])
    slices_exp = (slice(None), *slices_exp)

    slices_in = (slice(None), *slices)

    E_expanded[slices_exp] = phase_E * numpy.array(E)[slices_in]
    return E_expanded