tidy3d.components.medium.AbstractMedium#
- class AbstractMedium[source]#
Bases:
ABC
,Tidy3dBaseModel
A medium within which electromagnetic waves propagate.
- Parameters:
attrs (dict = {}) – Dictionary storing arbitrary metadata for a Tidy3D object. This dictionary can be freely used by the user for storing data without affecting the operation of Tidy3D as it is not used internally. Note that, unlike regular Tidy3D fields,
attrs
are mutable. For example, the following is allowed for setting anattr
obj.attrs['foo'] = bar
. Also note that Tidy3D` will raise aTypeError
ifattrs
contain objects that can not be serialized. One can check ifattrs
are serializable by callingobj.json()
.name (Optional[str] = None) – Optional unique name for medium.
frequency_range (Optional[Tuple[float, float]] = None) – [units = (Hz, Hz)]. Optional range of validity for the medium.
allow_gain (bool = False) – Allow the medium to be active. Caution: simulations with a gain medium are unstable, and are likely to diverge.Simulations where ‘allow_gain’ is set to ‘True’ will still be charged even if diverged. Monitor data up to the divergence point will still be returned and can be useful in some cases.
nonlinear_spec (Union[NonlinearSpec, NonlinearSusceptibility] = None) – Nonlinear spec applied on top of the base medium properties.
modulation_spec (Optional[ModulationSpec] = None) – Modulation spec applied on top of the base medium properties.
heat_spec (Union[FluidSpec, SolidSpec, NoneType] = None) – Specification of the medium heat properties. They are used for solving the heat equation via the
HeatSimulation
interface. Such simulations can be used for investigating the influence of heat propagation on the properties of optical systems. Once the temperature distribution in the system is found usingHeatSimulation
object,Simulation.perturbed_mediums_copy()
can be used to convert mediums with perturbation models defined into spatially dependent custom mediums. Otherwise, theheat_spec
does not directly affect the running of an opticalSimulation
.
Attributes
Whether the medium is custom.
Whether the medium is fully anisotropic.
Whether the medium is nonlinear.
Whether the medium is a PEC.
Whether the medium is spatially uniform.
Whether any component of the medium is time modulated.
To ensure a stable FDTD simulation, it is essential to select an appropriate time step size in accordance with the CFL condition.
Methods
eps_comp
(row, col, frequency)Single component of the complex-valued permittivity tensor as a function of frequency.
eps_complex_to_eps_loss_tangent
(eps_complex)Convert complex permittivity to permittivity and loss tangent.
eps_complex_to_eps_sigma
(eps_complex, freq)Convert complex permittivity at frequency
freq
to permittivity and conductivity values.eps_complex_to_nk
(eps_c)Convert complex permittivity to n, k values.
eps_diagonal
(frequency)Main diagonal of the complex-valued permittivity tensor as a function of frequency.
eps_loss_tangent_to_eps_complex
(eps_real, ...)Convert permittivity and loss tangent to complex permittivity.
eps_model
(frequency)Complex-valued permittivity as a function of frequency.
eps_sigma_to_eps_complex
(eps_real, sigma, freq)convert permittivity and conductivity to complex permittivity at freq
loss_tangent_model
(frequency)Permittivity and loss tangent as a function of frequency.
nk_model
(frequency)Real and imaginary parts of the refactive index as a function of frequency.
nk_to_eps_complex
(n[, k])Convert n, k to complex permittivity.
nk_to_eps_sigma
(n, k, freq)Convert
n
,k
at frequencyfreq
to permittivity and conductivity values.plot
(freqs[, ax])Plot n, k of a
Medium
as a function of frequency.sel_inside
(bounds)Return a new medium that contains the minimal amount data necessary to cover a spatial region defined by
bounds
.sigma_model
(freq)Complex-valued conductivity as a function of frequency.
Inherited Common Usage
- name#
- frequency_range#
- allow_gain#
- nonlinear_spec#
- modulation_spec#
- heat_spec#
- property is_spatially_uniform#
Whether the medium is spatially uniform.
- property is_time_modulated#
Whether any component of the medium is time modulated.
- property is_nonlinear#
Whether the medium is nonlinear.
- property is_custom#
Whether the medium is custom.
- property is_fully_anisotropic#
Whether the medium is fully anisotropic.
- abstract eps_model(frequency)[source]#
Complex-valued permittivity as a function of frequency.
- Parameters:
frequency (float) – Frequency to evaluate permittivity at (Hz).
- Returns:
Complex-valued relative permittivity evaluated at
frequency
.- Return type:
complex
- nk_model(frequency)[source]#
Real and imaginary parts of the refactive index as a function of frequency.
- Parameters:
frequency (float) – Frequency to evaluate permittivity at (Hz).
- Returns:
Real part (n) and imaginary part (k) of refractive index of medium.
- Return type:
Tuple[float, float]
- loss_tangent_model(frequency)[source]#
Permittivity and loss tangent as a function of frequency.
- Parameters:
frequency (float) – Frequency to evaluate permittivity at (Hz).
- Returns:
Real part of permittivity and loss tangent.
- Return type:
Tuple[float, float]
- eps_diagonal(frequency)[source]#
Main diagonal of the complex-valued permittivity tensor as a function of frequency.
- Parameters:
frequency (float) – Frequency to evaluate permittivity at (Hz).
- Returns:
The diagonal elements of the relative permittivity tensor evaluated at
frequency
.- Return type:
complex
- eps_comp(row, col, frequency)[source]#
Single component of the complex-valued permittivity tensor as a function of frequency.
- Parameters:
row (int) – Component’s row in the permittivity tensor (0, 1, or 2 for x, y, or z respectively).
col (int) – Component’s column in the permittivity tensor (0, 1, or 2 for x, y, or z respectively).
frequency (float) – Frequency to evaluate permittivity at (Hz).
- Returns:
Element of the relative permittivity tensor evaluated at
frequency
.- Return type:
complex
- abstract property n_cfl#
To ensure a stable FDTD simulation, it is essential to select an appropriate time step size in accordance with the CFL condition. The maximal time step size is inversely proportional to the speed of light in the medium, and thus proportional to the index of refraction. However, for dispersive medium, anisotropic medium, and other more complicated media, there are complications in deciding on the choice of the index of refraction.
This property computes the index of refraction related to CFL condition, so that the FDTD with this medium is stable when the time step size that doesn’t take material factor into account is multiplied by
n_cfl
.
- plot(freqs, ax=None)[source]#
Plot n, k of a
Medium
as a function of frequency.- Parameters:
freqs (float) – Frequencies (Hz) to evaluate the medium properties at.
ax (matplotlib.axes._subplots.Axes = None) – Matplotlib axes to plot on, if not specified, one is created.
- Returns:
The supplied or created matplotlib axes.
- Return type:
matplotlib.axes._subplots.Axes
- static nk_to_eps_complex(n, k=0.0)[source]#
Convert n, k to complex permittivity.
- Parameters:
n (float) – Real part of refractive index.
k (float = 0.0) – Imaginary part of refrative index.
- Returns:
Complex-valued relative permittivity.
- Return type:
complex
- static eps_complex_to_nk(eps_c)[source]#
Convert complex permittivity to n, k values.
- Parameters:
eps_c (complex) – Complex-valued relative permittivity.
- Returns:
Real and imaginary parts of refractive index (n & k).
- Return type:
Tuple[float, float]
- static nk_to_eps_sigma(n, k, freq)[source]#
Convert
n
,k
at frequencyfreq
to permittivity and conductivity values.- Parameters:
n (float) – Real part of refractive index.
k (float = 0.0) – Imaginary part of refrative index.
frequency (float) – Frequency to evaluate permittivity at (Hz).
- Returns:
Real part of relative permittivity & electric conductivity.
- Return type:
Tuple[float, float]
- static eps_sigma_to_eps_complex(eps_real, sigma, freq)[source]#
convert permittivity and conductivity to complex permittivity at freq
- Parameters:
eps_real (float) – Real-valued relative permittivity.
sigma (float) – Conductivity.
freq (float) – Frequency to evaluate permittivity at (Hz). If not supplied, returns real part of permittivity (limit as frequency -> infinity.)
- Returns:
Complex-valued relative permittivity.
- Return type:
complex
- static eps_complex_to_eps_sigma(eps_complex, freq)[source]#
Convert complex permittivity at frequency
freq
to permittivity and conductivity values.- Parameters:
eps_complex (complex) – Complex-valued relative permittivity.
freq (float) – Frequency to evaluate permittivity at (Hz).
- Returns:
Real part of relative permittivity & electric conductivity.
- Return type:
Tuple[float, float]
- static eps_complex_to_eps_loss_tangent(eps_complex)[source]#
Convert complex permittivity to permittivity and loss tangent.
- Parameters:
eps_complex (complex) – Complex-valued relative permittivity.
- Returns:
Real part of relative permittivity & loss tangent
- Return type:
Tuple[float, float]
- static eps_loss_tangent_to_eps_complex(eps_real, loss_tangent)[source]#
Convert permittivity and loss tangent to complex permittivity.
- Parameters:
eps_real (float) – Real part of relative permittivity
loss_tangent (float) – Loss tangent
- Returns:
eps_complex – Complex-valued relative permittivity.
- Return type:
complex
- sigma_model(freq)[source]#
Complex-valued conductivity as a function of frequency.
- Parameters:
freq (float) – Frequency to evaluate conductivity at (Hz).
- Returns:
Complex conductivity at this frequency.
- Return type:
complex
- property is_pec#
Whether the medium is a PEC.
- sel_inside(bounds)[source]#
Return a new medium that contains the minimal amount data necessary to cover a spatial region defined by
bounds
.- Parameters:
bounds (Tuple[float, float, float], Tuple[float, float float]) – Min and max bounds packaged as
(minx, miny, minz), (maxx, maxy, maxz)
.- Returns:
Medium with reduced data.
- Return type:
- __hash__()#
Hash method.