OldDiffusion2D Class

class electrical.olddiffusion.OldDiffusion2D(name='')

Calculates carrier pairs concentration in active region using FEM in one-dimensional cartesian space

Methods

compute_initial()

Perform the initial computation

compute_overthreshold()

Perform the overthreshold computation

compute_threshold()

Perform the threshold computation

get_total_burning()

Compute total power burned over threshold (mW).

initialize()

Initialize solver.

invalidate()

Set the solver back to uninitialized state.

Attributes

Receivers

inCurrentDensity

Receiver of the current density required for computations [kA/cm²].

inGain

Receiver of the material gain required for computations [1/cm].

inLightE

Receiver of the electric field required for computations [V/m].

inTemperature

Receiver of the temperature required for computations [K].

Providers

outCarriersConcentration

Provider of the computed carriers concentration [1/cm³].

Other

abs_accuracy

Required absolute minimal concentration accuracy

accuracy

Required relative accuracy

current_mesh

Horizontal adaptive mesh)

fem_method

Finite-element method (linear of parabolic)

geometry

Geometry provided to the solver

id

Id of the solver object.

initial

True if we start from initial computations

initialized

True if the solver has been initialized.

interpolation

Interpolation method used for injection current

maxiters

Maximum number of allowed iterations before attempting to refine mesh

maxrefines

Maximum number of allowed mesh refinements

mesh

Mesh provided to the solver

mode_burns

Power burned over threshold by each mode (mW).

Descriptions

Method Details

OldDiffusion2D.compute_initial()

Perform the initial computation

OldDiffusion2D.compute_overthreshold()

Perform the overthreshold computation

OldDiffusion2D.compute_threshold()

Perform the threshold computation

OldDiffusion2D.get_total_burning()

Compute total power burned over threshold (mW).

OldDiffusion2D.initialize()

Initialize solver.

This method manually initialized the solver and sets initialized to True. Normally calling it is not necessary, as each solver automatically initializes itself when needed.

Returns:

solver initialized state prior to this method call.

Return type:

bool

OldDiffusion2D.invalidate()

Set the solver back to uninitialized state.

This method frees the memory allocated by the solver and sets initialized to False.

Receiver Details

OldDiffusion2D.inCurrentDensity = <property object>

Receiver of the current density required for computations [kA/cm²].

You will find usage details in the documentation of the receiver class CurrentDensityReceiver2D.

Example

Connect the receiver to a provider from some other solver:

>>> solver.inCurrentDensity = other_solver.outCurrentDensity

See also

Receciver class: plask.flow.CurrentDensityReceiver2D

Provider class: plask.flow.CurrentDensityProvider2D

Data filter: plask.filter.CurrentDensityFilter2D

OldDiffusion2D.inGain = <property object>

Receiver of the material gain required for computations [1/cm]. It is required only for the overthreshold computations.

You will find usage details in the documentation of the receiver class GainReceiver2D.

Example

Connect the receiver to a provider from some other solver:

>>> solver.inGain = other_solver.outGain

See also

Receciver class: plask.flow.GainReceiver2D

Provider class: plask.flow.GainProvider2D

Data filter: plask.filter.GainFilter2D

OldDiffusion2D.inLightE = <property object>

Receiver of the electric field required for computations [V/m]. It is required only for the overthreshold computations.

You will find usage details in the documentation of the receiver class ModeLightEReceiver2D.

Example

Connect the receiver to a provider from some other solver:

>>> solver.inLightE = other_solver.outModeLightE

See also

Receciver class: plask.flow.ModeLightEReceiver2D

Provider class: plask.flow.ModeLightEProvider2D

Data filter: plask.filter.ModeLightEFilter2D

OldDiffusion2D.inTemperature = <property object>

Receiver of the temperature required for computations [K].

You will find usage details in the documentation of the receiver class TemperatureReceiver2D.

Example

Connect the receiver to a provider from some other solver:

>>> solver.inTemperature = other_solver.outTemperature

See also

Receciver class: plask.flow.TemperatureReceiver2D

Provider class: plask.flow.TemperatureProvider2D

Data filter: plask.filter.TemperatureFilter2D

Provider Details

OldDiffusion2D.outCarriersConcentration(n=0, mesh, interpolation='default') = <property object>

Provider of the computed carriers concentration [1/cm³].

Parameters:

  • type (str) – Detailed information which carriers are returned. It can be ‘majority’ to return majority carriers in given material, ‘pairs’ for the concentration of electron-hole pairs, ‘electrons’, or ‘holes’ for particular carriers type.

  • mesh (mesh) – Target mesh to get the field at.

  • interpolation (str) – Requested interpolation method.

Returns:

Data with the carriers concentration on the specified mesh [1/cm³].

You may obtain the number of different values this provider can return by testing its length.

Example

Connect the provider to a receiver in some other solver:

>>> other_solver.inCarriersConcentration = solver.outCarriersConcentration

Obtain the provided field:

>>> solver.outCarriersConcentration(0, mesh)
<plask.Data at 0x1234567>

Test the number of provided values:

>>> len(solver.outCarriersConcentration)
3

See also

Provider class: plask.flow.CarriersConcentrationProvider2D

Receciver class: plask.flow.CarriersConcentrationReceiver2D

Attribute Details

OldDiffusion2D.abs_accuracy = <property object>

Required absolute minimal concentration accuracy

OldDiffusion2D.accuracy = <property object>

Required relative accuracy

OldDiffusion2D.current_mesh = <property object>

Horizontal adaptive mesh)

OldDiffusion2D.fem_method = <property object>

Finite-element method (linear of parabolic)

OldDiffusion2D.geometry = <property object>

Geometry provided to the solver

OldDiffusion2D.id = <property object>

Id of the solver object. (read only)

Example

>>> mysolver.id
mysolver:category.type
OldDiffusion2D.initial = <property object>

True if we start from initial computations

OldDiffusion2D.initialized = <property object>

True if the solver has been initialized. (read only)

Solvers usually get initialized at the beginning of the computations. You can clean the initialization state and free the memory by calling the invalidate() method.

OldDiffusion2D.interpolation = <property object>

Interpolation method used for injection current

OldDiffusion2D.maxiters = <property object>

Maximum number of allowed iterations before attempting to refine mesh

OldDiffusion2D.maxrefines = <property object>

Maximum number of allowed mesh refinements

OldDiffusion2D.mesh = <property object>

Mesh provided to the solver

OldDiffusion2D.mode_burns = <property object>

Power burned over threshold by each mode (mW).