opencl_fdtd/fdtd.py

"""
Example code for running an OpenCL FDTD simulation

See main() for simulation setup.
"""

import sys
import time

import numpy
import h5py

from fdtd.simulation import Simulation
from masque import Pattern, shapes
import gridlock
import pcgen


def perturbed_l3(a: float, radius: float, **kwargs) -> Pattern:
    """
    Generate a masque.Pattern object containing a perturbed L3 cavity.

    :param a: Lattice constant.
    :param radius: Hole radius, in units of a (lattice constant).
    :param kwargs: Keyword arguments:
        hole_dose, trench_dose, hole_layer, trench_layer: Shape properties for Pattern.
                Defaults *_dose=1, hole_layer=0, trench_layer=1.
        shifts_a, shifts_r: passed to pcgen.l3_shift; specifies lattice constant (1 -
                multiplicative factor) and radius (multiplicative factor) for shifting
                holes adjacent to the defect (same row). Defaults are 0.15 shift for
                first hole, 0.075 shift for third hole, and no radius change.
        xy_size: [x, y] number of mirror periods in each direction; total size is
                2 * n + 1 holes in each direction. Default [10, 10].
        perturbed_radius: radius of holes perturbed to form an upwards-driected beam
                (multiplicative factor). Default 1.1.
        trench width: Width of the undercut trenches. Default 1.2e3.
    :return: masque.Pattern object containing the L3 design
    """

    default_args = {'hole_dose':    1,
                    'trench_dose':  1,
                    'hole_layer':   0,
                    'trench_layer': 1,
                    'shifts_a':     (0.15, 0, 0.075),
                    'shifts_r':     (1.0, 1.0, 1.0),
                    'xy_size':      (10, 10),
                    'perturbed_radius': 1.1,
                    'trench_width': 1.2e3,
                    }
    kwargs = {**default_args, **kwargs}

    xyr = pcgen.l3_shift_perturbed_defect(mirror_dims=kwargs['xy_size'],
                                          perturbed_radius=kwargs['perturbed_radius'],
                                          shifts_a=kwargs['shifts_a'],
                                          shifts_r=kwargs['shifts_r'])
    xyr *= a
    xyr[:, 2] *= radius

    pat = Pattern()
    pat.name = 'L3p-a{:g}r{:g}rp{:g}'.format(a, radius, kwargs['perturbed_radius'])
    pat.shapes += [shapes.Circle(radius=r, offset=(x, y),
                                 dose=kwargs['hole_dose'],
                                 layer=kwargs['hole_layer'])
                   for x, y, r in xyr]

    maxes = numpy.max(numpy.fabs(xyr), axis=0)
    pat.shapes += [shapes.Polygon.rectangle(
        lx=(2 * maxes[0]), ly=kwargs['trench_width'],
        offset=(0, s * (maxes[1] + a + kwargs['trench_width'] / 2)),
        dose=kwargs['trench_dose'], layer=kwargs['trench_layer'])
                   for s in (-1, 1)]
    return pat


def main():
    max_t = 8000            # number of timesteps

    dx = 40                 # discretization (nm/cell)
    pml_thickness = 8       # (number of cells)

    wl = 1550               # Excitation wavelength and fwhm
    dwl = 200

    # Device design parameters
    xy_size = numpy.array([10, 10])
    a = 430
    r = 0.285
    th = 170

    # refractive indices
    n_slab = 3.408  # InGaAsP(80, 50) @ 1550nm
    n_air = 1.0   # air

    # Half-dimensions of the simulation grid
    xy_max = (xy_size + 1) * a * [1, numpy.sqrt(3)/2]
    z_max = 1.6 * a
    xyz_max = numpy.hstack((xy_max, z_max)) + pml_thickness * dx

    # Coordinates of the edges of the cells. The fdtd package can only do square grids at the moment.
    half_edge_coords = [numpy.arange(dx/2, m + dx, step=dx) for m in xyz_max]
    edge_coords = [numpy.hstack((-h[::-1], h)) for h in half_edge_coords]

    # #### Create the grid, mask, and draw the device ####
    grid = gridlock.Grid(edge_coords, initial=n_air**2, num_grids=3)
    grid.draw_slab(surface_normal=gridlock.Direction.z,
                   center=[0, 0, 0],
                   thickness=th,
                   eps=n_slab**2)
    mask = perturbed_l3(a, r)

    grid.draw_polygons(surface_normal=gridlock.Direction.z,
                       center=[0, 0, 0],
                       thickness=2 * th,
                       eps=n_air**2,
                       polygons=mask.as_polygons())

    print(grid.shape)
    # #### Create the simulation grid ####
    sim = Simulation(grid.grids)

    # Conducting boundaries and pmls in every direction
    c_args = []
    pml_args = []
    for d in (0, 1, 2):
        for p in (-1, 1):
            c_args += [{'direction': d, 'polarity': p}]
            pml_args += [{'direction': d, 'polarity': p, 'epsilon_eff': n_slab**2}]
    sim.init_conductors(c_args)
    sim.init_cpml(pml_args)

    # Source parameters and function
    w = 2 * numpy.pi * dx / wl
    fwhm = dwl * w * w / (2 * numpy.pi * dx)
    alpha = (fwhm ** 2) / 8 * numpy.log(2)
    delay = 7/numpy.sqrt(2 * alpha)

    def field_source(i):
        t0 = i * sim.dt - delay
        return numpy.sin(w * t0) * numpy.exp(-alpha * t0**2)

    # #### Run a bunch of iterations ####
    # event = sim.whatever([prev_event]) indicates that sim.whatever should be queued immediately and run
    #  once prev_event is finished.
    output_file = h5py.File('simulation_output.h5', 'w')
    start = time.perf_counter()
    for t in range(max_t):
        event = sim.cpml_E([])
        sim.update_E([event]).wait()

        sim.E[1][tuple(grid.shape//2)] += field_source(t)
        event = sim.conductor_E([])
        event = sim.cpml_H([event])
        event = sim.update_H([event])
        sim.conductor_H([event]).wait()

        print('iteration {}: average {} iterations per sec'.format(t, (t+1)/(time.perf_counter()-start)))
        sys.stdout.flush()

        # Save field slices
        if (t % 20 == 0 and (max_t - t < 1000 or t < 1000)) or t == max_t-1:
            print('saving E-field')
            for j, f in enumerate(sim.E):
                a = f.get()
                output_file['/E{}_t{}'.format('xyz'[j], t)] = a[:, :, round(a.shape[2]/2)]

if __name__ == '__main__':
    main()
Initial commit 2016-03-30 15:00:00 -07:00			`"""`
			`Example code for running an OpenCL FDTD simulation`

			`See main() for simulation setup.`
			`"""`

			`import sys`
			`import time`

			`import numpy`
			`import h5py`

			`from fdtd.simulation import Simulation`
			`from masque import Pattern, shapes`
			`import gridlock`
			`import pcgen`


			`def perturbed_l3(a: float, radius: float, **kwargs) -> Pattern:`
			`"""`
			`Generate a masque.Pattern object containing a perturbed L3 cavity.`

			`:param a: Lattice constant.`
			`:param radius: Hole radius, in units of a (lattice constant).`
			`:param kwargs: Keyword arguments:`
			`hole_dose, trench_dose, hole_layer, trench_layer: Shape properties for Pattern.`
			`Defaults *_dose=1, hole_layer=0, trench_layer=1.`
			`shifts_a, shifts_r: passed to pcgen.l3_shift; specifies lattice constant (1 -`
			`multiplicative factor) and radius (multiplicative factor) for shifting`
			`holes adjacent to the defect (same row). Defaults are 0.15 shift for`
			`first hole, 0.075 shift for third hole, and no radius change.`
			`xy_size: [x, y] number of mirror periods in each direction; total size is`
			`2 * n + 1 holes in each direction. Default [10, 10].`
			`perturbed_radius: radius of holes perturbed to form an upwards-driected beam`
			`(multiplicative factor). Default 1.1.`
			`trench width: Width of the undercut trenches. Default 1.2e3.`
			`:return: masque.Pattern object containing the L3 design`
			`"""`

			`default_args = {'hole_dose': 1,`
			`'trench_dose': 1,`
			`'hole_layer': 0,`
			`'trench_layer': 1,`
			`'shifts_a': (0.15, 0, 0.075),`
			`'shifts_r': (1.0, 1.0, 1.0),`
			`'xy_size': (10, 10),`
			`'perturbed_radius': 1.1,`
			`'trench_width': 1.2e3,`
			`}`
			`kwargs = {default_args, kwargs}`

			`xyr = pcgen.l3_shift_perturbed_defect(mirror_dims=kwargs['xy_size'],`
			`perturbed_radius=kwargs['perturbed_radius'],`
			`shifts_a=kwargs['shifts_a'],`
			`shifts_r=kwargs['shifts_r'])`
			`xyr *= a`
			`xyr[:, 2] *= radius`

			`pat = Pattern()`
			`pat.name = 'L3p-a{:g}r{:g}rp{:g}'.format(a, radius, kwargs['perturbed_radius'])`
			`pat.shapes += [shapes.Circle(radius=r, offset=(x, y),`
			`dose=kwargs['hole_dose'],`
			`layer=kwargs['hole_layer'])`
			`for x, y, r in xyr]`

			`maxes = numpy.max(numpy.fabs(xyr), axis=0)`
			`pat.shapes += [shapes.Polygon.rectangle(`
			`lx=(2 * maxes[0]), ly=kwargs['trench_width'],`
			`offset=(0, s * (maxes[1] + a + kwargs['trench_width'] / 2)),`
			`dose=kwargs['trench_dose'], layer=kwargs['trench_layer'])`
			`for s in (-1, 1)]`
			`return pat`


			`def main():`
			`max_t = 8000 # number of timesteps`

			`dx = 40 # discretization (nm/cell)`
			`pml_thickness = 8 # (number of cells)`

			`wl = 1550 # Excitation wavelength and fwhm`
			`dwl = 200`

			`# Device design parameters`
			`xy_size = numpy.array([10, 10])`
			`a = 430`
			`r = 0.285`
			`th = 170`

			`# refractive indices`
			`n_slab = 3.408 # InGaAsP(80, 50) @ 1550nm`
			`n_air = 1.0 # air`

			`# Half-dimensions of the simulation grid`
			`xy_max = (xy_size + 1) * a * [1, numpy.sqrt(3)/2]`
			`z_max = 1.6 * a`
			`xyz_max = numpy.hstack((xy_max, z_max)) + pml_thickness * dx`

			`# Coordinates of the edges of the cells. The fdtd package can only do square grids at the moment.`
			`half_edge_coords = [numpy.arange(dx/2, m + dx, step=dx) for m in xyz_max]`
			`edge_coords = [numpy.hstack((-h[::-1], h)) for h in half_edge_coords]`

			`# #### Create the grid, mask, and draw the device ####`
			`grid = gridlock.Grid(edge_coords, initial=n_air**2, num_grids=3)`
			`grid.draw_slab(surface_normal=gridlock.Direction.z,`
			`center=[0, 0, 0],`
			`thickness=th,`
			`eps=n_slab**2)`
			`mask = perturbed_l3(a, r)`
Cleaner representation of the field source 2016-06-21 18:26:16 -07:00
Initial commit 2016-03-30 15:00:00 -07:00			`grid.draw_polygons(surface_normal=gridlock.Direction.z,`
			`center=[0, 0, 0],`
			`thickness=2 * th,`
			`eps=n_air**2,`
			`polygons=mask.as_polygons())`

			`print(grid.shape)`
			`# #### Create the simulation grid ####`
			`sim = Simulation(grid.grids)`

			`# Conducting boundaries and pmls in every direction`
			`c_args = []`
			`pml_args = []`
			`for d in (0, 1, 2):`
			`for p in (-1, 1):`
			`c_args += [{'direction': d, 'polarity': p}]`
			`pml_args += [{'direction': d, 'polarity': p, 'epsilon_eff': n_slab**2}]`
			`sim.init_conductors(c_args)`
			`sim.init_cpml(pml_args)`

			`# Source parameters and function`
			`w = 2 * numpy.pi * dx / wl`
			`fwhm = dwl * w * w / (2 * numpy.pi * dx)`
			`alpha = (fwhm ** 2) / 8 * numpy.log(2)`
			`delay = 7/numpy.sqrt(2 * alpha)`
Cleaner representation of the field source 2016-06-21 18:26:16 -07:00
			`def field_source(i):`
			`t0 = i * sim.dt - delay`
			`return numpy.sin(w * t0) * numpy.exp(-alpha * t0**2)`
Initial commit 2016-03-30 15:00:00 -07:00
			`# #### Run a bunch of iterations ####`
			`# event = sim.whatever([prev_event]) indicates that sim.whatever should be queued immediately and run`
			`# once prev_event is finished.`
			`output_file = h5py.File('simulation_output.h5', 'w')`
			`start = time.perf_counter()`
			`for t in range(max_t):`
			`event = sim.cpml_E([])`
			`sim.update_E([event]).wait()`

			`sim.E[1][tuple(grid.shape//2)] += field_source(t)`
			`event = sim.conductor_E([])`
			`event = sim.cpml_H([event])`
			`event = sim.update_H([event])`
			`sim.conductor_H([event]).wait()`

			`print('iteration {}: average {} iterations per sec'.format(t, (t+1)/(time.perf_counter()-start)))`
			`sys.stdout.flush()`

			`# Save field slices`
			`if (t % 20 == 0 and (max_t - t < 1000 or t < 1000)) or t == max_t-1:`
			`print('saving E-field')`
			`for j, f in enumerate(sim.E):`
			`a = f.get()`
			`output_file['/E{}_t{}'.format('xyz'[j], t)] = a[:, :, round(a.shape[2]/2)]`

			`if __name__ == '__main__':`
			`main()`