Exemplo n.º 1
0
 def __init__(
     self,
     circuit: Subcircuit,
     start: float = 1.5e-6,
     stop: float = 1.6e-6,
     num: int = 2000,
     mode="wl",
 ):
     super().__init__(circuit)
     if start > stop:
         raise ValueError("simulation 'start' value must be less than 'stop' value.")
     if mode == "wl":
         tmp_start = start
         tmp_stop = stop
         start = wl2freq(tmp_stop)
         stop = wl2freq(tmp_start)
     elif mode == "freq":
         pass
     else:
         err = "mode '{}' is not one of 'freq' or 'wl'".format(mode)
         raise ValueError(err)
     if start > stop:
         raise ValueError(
             "starting frequency cannot be greater than stopping frequency"
         )
     self.freq = np.linspace(start, stop, num)
     self.wl = freq2wl(self.freq)
Exemplo n.º 2
0
def sweep_simulation(circuit,
                     iport="input",
                     oport="output",
                     start=1500e-9,
                     stop=1600e-9,
                     num=2000,
                     logscale=True,
                     **kwargs):
    """ Plot Sparameter circuit transmission over wavelength

    Args:
        num: number of sampled points
    """
    circuit = pp.call_if_func(circuit)

    simulation = SweepSimulation(circuit, start, stop, num)
    result = simulation.simulate()

    f, s = result.data(iport, oport)
    w = freq2wl(f) * 1e9

    if logscale:
        s = 20 * np.log10(abs(s))
        ylabel = "|S| (dB)"
    else:
        ylabel = "|S|"

    f, ax = plt.subplots()
    ax.plot(w, s)
    plt.xlabel("wavelength (nm)")
    plt.ylabel(ylabel)
    plt.title(circuit.name)
    return ax
Exemplo n.º 3
0
def get_transmission(circuit,
                     iport="input",
                     oport="output",
                     start=1500e-9,
                     stop=1600e-9,
                     num=2000):

    circuit = pp.call_if_func(circuit)

    simulation = SweepSimulation(circuit, start, stop, num)
    result = simulation.simulate()

    f, s = result.data(iport, oport)
    w = freq2wl(f) * 1e9
    return dict(wavelength_nm=w, s=s)
Exemplo n.º 4
0
    def s_parameters(self, freq):
        """Get the s-parameters of SCEE Model.

        Parameters
        ----------
        freq : np.ndarray
            A frequency array to calculate s-parameters over (in Hz).

        Returns
        -------
        s : np.ndarray
            Returns the calculated s-parameter matrix.
        """
        # convert wavelength to frequency
        wl = freq2wl(freq) * 1e9

        return self.model.sparams(wl)
Exemplo n.º 5
0
    def simulate(self,
                 mode: Optional[str] = None,
                 **kwargs) -> Tuple[np.array, np.array]:
        """Runs the sweep simulation for the circuit.

        Parameters
        ----------
        dB :
            Returns the power ratios in deciBels when True.
        mode :
            Whether to return frequencies or wavelengths for the corresponding
            power ratios. Defaults to whatever values were passed in upon
            instantiation. Either 'freq' or 'wl'.
        """
        freqs, power_ratios = super().simulate(**kwargs, freqs=self.freqs)

        mode = mode if mode else self.mode
        if mode == "wl":
            return (freq2wl(freqs), power_ratios)

        return (freqs, power_ratios)
Exemplo n.º 6
0
def sweep_simulation(circuit,
                     iport="input",
                     oport="output",
                     start=1500e-9,
                     stop=1600e-9,
                     logscale=True,
                     **kwargs):
    """ Run a simulation on the circuit
    """
    circuit = pp.call_if_func(circuit)

    simulation = SweepSimulation(circuit, start, stop)
    result = simulation.simulate()

    f, s = result.data(iport, oport)
    w = freq2wl(f) * 1e9
    if logscale:
        s = 20 * np.log10(abs(s))
    plt.plot(w, s)
    plt.title(circuit.name)
    plt.tight_layout()
    plt.show()
Exemplo n.º 7
0
    def monte_carlo_s_parameters(self, freq):
        """Get the s-parameters of SCEE Model with slightly changed parameters.

        Parameters
        ----------
        freq : np.ndarray
            A frequency array to calculate s-parameters over (in Hz).

        Returns
        -------
        s : np.ndarray
            Returns the calculated s-parameter matrix.
        """
        wl = freq2wl(freq) * 1e9

        # perturb params and get sparams
        self.model.update(**self.rand_params)
        sparams = self.model.sparams(wl)

        # restore parameters to originals
        self.model.update(**self.og_params)

        return sparams
Exemplo n.º 8
0
    ('connect2', 'n1', 'ring11', 'pass'),
    ('connect2', 'n2', 'ring12', 'in'),
    ('out3', 'n1', 'ring12', 'out'),
    ('terminator', 'n1', 'ring12', 'pass'),
])

# Run a simulation on the netlist.
simulation = SweepSimulation(circuit, 1524.5e-9, 1551.15e-9)
result = simulation.simulate()

fig = plt.figure(tight_layout=True)
gs = gridspec.GridSpec(1, 3)

ax = fig.add_subplot(gs[0, :2])
f, s = result.data('input', 'out1')
ax.plot(freq2wl(f) * 1e9, s, label='Output 1', lw='0.7')
f, s = result.data('input', 'out2')
ax.plot(freq2wl(f) * 1e9, s, label='Output 2', lw='0.7')
f, s = result.data('input', 'out3')
ax.plot(freq2wl(f) * 1e9, s, label='Output 3', lw='0.7')

ax.set_ylabel("Fractional Optical Power")
ax.set_xlabel("Wavelength (nm)")
plt.legend(loc='upper right')

ax = fig.add_subplot(gs[0, 2])
f, s = result.data('input', 'out1')
ax.plot(freq2wl(f) * 1e9, s, label='Output 1', lw='0.7')
f, s = result.data('input', 'out2')
ax.plot(freq2wl(f) * 1e9, s, label='Output 2', lw='0.7')
f, s = result.data('input', 'out3')
Exemplo n.º 9
0
        ("connect2", "n2", "ring12", "in"),
        ("out3", "n1", "ring12", "out"),
        ("terminator", "n1", "ring12", "pass"),
    ]
)

# Run a simulation on the netlist.
simulation = SweepSimulation(circuit, 1524.5e-9, 1551.15e-9)
result = simulation.simulate()

fig = plt.figure(tight_layout=True)
gs = gridspec.GridSpec(1, 3)

ax = fig.add_subplot(gs[0, :2])
f, s = result.data("input", "out1")
ax.plot(freq2wl(f) * 1e9, s, label="Output 1", lw="0.7")
f, s = result.data("input", "out2")
ax.plot(freq2wl(f) * 1e9, s, label="Output 2", lw="0.7")
f, s = result.data("input", "out3")
ax.plot(freq2wl(f) * 1e9, s, label="Output 3", lw="0.7")

ax.set_ylabel("Fractional Optical Power")
ax.set_xlabel("Wavelength (nm)")
plt.legend(loc="upper right")

ax = fig.add_subplot(gs[0, 2])
f, s = result.data("input", "out1")
ax.plot(freq2wl(f) * 1e9, s, label="Output 1", lw="0.7")
f, s = result.data("input", "out2")
ax.plot(freq2wl(f) * 1e9, s, label="Output 2", lw="0.7")
f, s = result.data("input", "out3")
Exemplo n.º 10
0
plt.ylabel("Fractional Optical Power")
plt.show()

# We're interested now in the phase offsets at our wavelength of interest.
plt.figure()

# port 0 is the input port. ports 4-7 are the output ports.
freqs = np.argmax(simulator.freqs > set_freq)
input = 0
outputs = slice(4, 8)
s = simulator.circuit.s_parameters(simulator.freqs)
offset = min(np.angle(s[freqs, outputs, input]))
angles = np.angle(s[:, outputs, input]).T - offset

for angle in angles:
    plt.plot(freq2wl(simulator.freqs) * 1e9, angle, linewidth="0.7")

plt.axvline(1550, color="k", linestyle="--", linewidth="0.5")
plt.legend([r"$\phi_4$", r"$\phi_5$", r"$\phi_6$", r"$\phi_7$"],
           loc="upper right")
plt.xlabel("Wavelength (nm)")
plt.ylabel("Phase")
plt.show()

plt.figure()
angles = np.rad2deg(np.unwrap(np.angle(s[:, outputs, input]))).T
angles = angles + ((angles[:, freqs] % 2 * np.pi) - angles[:, freqs]).reshape(
    (4, 1))

for i in range(4):
    plt.plot(freq2wl(simulator.freqs) * 1e9, angles[i])
Exemplo n.º 11
0
plt.xlabel("Frequency (Hz)")
plt.ylabel("Fractional Optical Power")
plt.show()

# We're interested now in the phase offsets at our wavelength of interest.
plt.figure()
freq, s = result.f, result.s
idx = np.argmax(freq > set_freq)
input_pin = result.pinlist['in1'].index
outputs = [result.pinlist['out' + str(n)].index for n in range(1, 5)]
offset = min(np.angle(s[idx, outputs, input_pin]))
# angles = np.unwrap(np.angle(s[:, outputs, input_pin])).T - offset
angles = np.angle(s[:, outputs, input_pin]).T - offset

for angle in angles:
    plt.plot(freq2wl(freq) * 1e9, angle, linewidth='0.7')
plt.axvline(1550, color='k', linestyle='--', linewidth='0.5')
plt.legend([r'$\phi_4$', r'$\phi_5$', r'$\phi_6$', r'$\phi_7$'],
           loc='upper right')
plt.xlabel("Wavelength (nm)")
plt.ylabel("Phase")
plt.show()

import sys

sys.exit()

plt.figure()
idx = np.argmax(freq > set_freq)
print(idx, freq2wl(freq[idx]))
angles = np.rad2deg(np.unwrap(np.angle(s[:, outputs, input_pin]))).T
Exemplo n.º 12
0
plt.xlabel("Frequency (Hz)")
plt.ylabel("Fractional Optical Power")
plt.show()

# We're interested now in the phase offsets at our wavelength of interest.
plt.figure()
freq, s = result.f, result.s
idx = np.argmax(freq > set_freq)
input_pin = result.pinlist["in1"].index
outputs = [result.pinlist["out" + str(n)].index for n in range(1, 5)]
offset = min(np.angle(s[idx, outputs, input_pin]))
# angles = np.unwrap(np.angle(s[:, outputs, input_pin])).T - offset
angles = np.angle(s[:, outputs, input_pin]).T - offset

for angle in angles:
    plt.plot(freq2wl(freq) * 1e9, angle, linewidth="0.7")
plt.axvline(1550, color="k", linestyle="--", linewidth="0.5")
plt.legend([r"$\phi_4$", r"$\phi_5$", r"$\phi_6$", r"$\phi_7$"], loc="upper right")
plt.xlabel("Wavelength (nm)")
plt.ylabel("Phase")
plt.show()

import sys

sys.exit()

plt.figure()
idx = np.argmax(freq > set_freq)
print(idx, freq2wl(freq[idx]))
angles = np.rad2deg(np.unwrap(np.angle(s[:, outputs, input_pin]))).T
angles = angles + ((angles[:, idx] % 2 * np.pi) - angles[:, idx]).reshape((4, 1))
Exemplo n.º 13
0
plt.xlabel("Frequency (Hz)")
plt.ylabel("Fractional Optical Power")
plt.show()

# We're interested now in the phase offsets at our wavelength of interest.
plt.figure()
freq, s = result.f, result.s
idx = np.argmax(freq > set_freq)
input_pin = result.pinlist["in1"].index
outputs = [result.pinlist["out" + str(n)].index for n in range(1, 5)]
offset = min(np.angle(s[idx, outputs, input_pin]))
# angles = np.unwrap(np.angle(s[:, outputs, input_pin])).T - offset
angles = np.angle(s[:, outputs, input_pin]).T - offset

for angle in angles:
    plt.plot(freq2wl(freq) * 1e9, angle, linewidth="0.7")
plt.axvline(1550, color="k", linestyle="--", linewidth="0.5")
plt.legend([r"$\phi_4$", r"$\phi_5$", r"$\phi_6$", r"$\phi_7$"],
           loc="upper right")
plt.xlabel("Wavelength (nm)")
plt.ylabel("Phase")
plt.show()

import sys

sys.exit()

plt.figure()
idx = np.argmax(freq > set_freq)
print(idx, freq2wl(freq[idx]))
angles = np.rad2deg(np.unwrap(np.angle(s[:, outputs, input_pin]))).T