CrossingModel

class photonforge.CrossingModel(*, t=1.0, x=0.0, r=0.0, propagation_length=.0, n_eff=0.0, n_group=None, reference_frequency=None, ports=None)[source]

Data model for a 4-port waveguide crossing.

\[\begin{split}S = \begin{bmatrix} r & x & t & x \\ x & r & x & t \\ t & x & r & x \\ x & t & x & r \\ \end{bmatrix} e^{j \phi}\end{split}\]

with dispersion modeled by:

\[\phi = \frac{2 \pi l_p}{c_0} [n_\text{eff} f_0 + n_\text{group} (f - f_0)]\]
Parameters:

  • t (complex | Sequence[complex] | Sequence[Sequence[complex]]) – Transmission coefficient.

  • x (complex | Sequence[complex] | Sequence[Sequence[complex]]) – Cross-coupling coefficient.

  • r (complex | Sequence[complex] | Sequence[Sequence[complex]]) – Reflection coefficient.

  • propagation_length (Annotated[float, units='μm']) – Propagation length \(l_p\) for dispersion modeling.

  • n_eff (complex | Sequence[complex] | Sequence[Sequence[complex]]) – Effective refractive index for dispersion modeling.

  • n_group (float | Sequence[float] | Sequence[Sequence[float]] | None) – Group index. If None, the value of n_eff is used.

  • reference_frequency (Annotated[float, minimum=0, units='Hz'] | None) – Reference frequency \(f_0\) for dispersion calculation. If None, the central frequency is used.

  • ports (Annotated[Sequence[str], maxItems=4, minItems=4] | None) – List of port names. If not set, the sorted list of port names from the component is used.

Notes

For multimode ports, a sequence of coefficients must be used, and mixed-mode coefficients are 0. Dispersion can be included in the model by setting the coefficients to a 2D array with shape (M, N), in which M is the number of modes, and N the length of the frequency sequence used in the S matrix computation.

Methods

black_box_component([port_spec, technology, ...])

Create a black-box component using this model for testing.

estimate_cost(*args, **kwargs)

Estimate the cost for S matrix computation.

s_matrix(component, frequencies[, ...])

Compute the S matrix for a component using this model.

setup_time_stepper(component, time_step[, ...])

Obtain a time stepper for a component using this model.

start(component, frequencies, **kwargs)

Start computing the S matrix response from a component.

update(*args, **kwargs)

Update this model.

Attributes

parametric_function

Function used to update a parametric component.

parametric_kwargs

Keyword arguments used to update a parametric component.

properties

Object properties.

random_variables

Random variables associated to this modles's parameters.

time_stepper

Time stepper associated with this model.
black_box_component(port_spec=None, technology=None, name=None)[source]

Create a black-box component using this model for testing.

Parameters:

  • port_spec (str | PortSpec | None) – Port specification used in the component. If None, look for "port_spec" in config.default_kwargs.

  • technology (Technology | None) – Component technology. If None, the default technology is used.

  • name (str | None) – Component name. If None a default is used.

Returns:

Component with ports and model.

Return type:

Component

start(component, frequencies, **kwargs)[source]

Start computing the S matrix response from a component.

Parameters:

  • component (Component) – Component from which to compute the S matrix.

  • frequencies (Sequence[float]) – Sequence of frequencies at which to perform the computation.

  • **kwargs (Any) – Unused.

Returns:

Model result with attributes status and s_matrix.

Return type:

SMatrix