ThresholdSearchCyl¶
- <meta solver="ThresholdSearchCyl">¶
Corresponding Python class:
meta.shockley.ThresholdSearchCyl
.Solver for threshold search of semiconductor laser in cylindrical geometry.
This solver performs thermo-electrical computations followed by determination ot threshold current and optical analysis in order to determine the threshold of a semiconductor laser. The search is performed by
scipy
root finding algorithm in order to determine the voltage and electric current ensuring no optical loss in the laser cavity.- Attributes:
name (
required
) – Solver name.
- Contents:
- <geometry>¶
Geometry settings for all solvers.
- Attributes:
thermal (
required
) – Geometry used by the thermal solver. (cylindrical geometry)electrical (
required
) – Geometry used by the electrical, diffusion, and gain solvers. (cylindrical geometry)optical (
required
) – Geometry used by the optical solver. (cylindrical geometry)
- <mesh>¶
Mesh settings for all solvers.
- Attributes:
thermal (
required
) – Mesh used by the thermal solver. (mesh)electrical (
required
) – Mesh used by the electrical solver. (mesh)diffusion – Mesh used by the carriers diffusion solver. (mesh)
optical – Mesh used by the optical solver. (mesh)
empty-elements – Should empty regions (e.g. air) be included into electrical computations? (
default
,include
, orexclude
, default isdefault
)
- <optical>¶
Configuration of the optical solver
- Attributes:
m – Angular mode number m (0 for LP0x, 1 for LP1x, etc.). (int, default 0)
n – Radial mode number n (1 for LPx1, 2 for LPx2, etc.). (int, default 1)
lam0 (
required
) – Approximate wavelength, around which the solution is searched. The refractive and group indexes are computed for this wavelength (float (nm))maxlam – Maximum wavelength considered for the optical mode search. (float (nm))
dlam – Step, by which the wavelength is swept while searching for the approximate mode. (float (nm), default 0.02 nm)
vlam – “Vertical wavelength” i.e. the wavelength what would be in the absence of lateral confinement; setting this value helps to find modes in very long resonators. (float (nm))
vat – Horizontal position of at which the vertical part of the field is calculated. (float (µm))
emission – Direction of the useful light emission. Necessary for the over-threshold model to correctly compute the output power. (
top
orbottom
, default istop
)
- <root>¶
Configuration of the root-finder used in threshold search.
- Attributes:
bcond (
required
) – Number of the voltage boundary condition to vary during the threshold search. (int)vmin – Minimum voltage to search threshold for. It should be below the threshold. (float)
vmax – Maximum voltage to search threshold for. It should be above the threshold. (float)
vtol – Tolerance on voltage in the root search. (float (V), default 1e-05 V)
maxiter – Maximum number of root finding iterations. (int, default 50)
- <voltage>¶
Voltage boundary conditions. See subsection Boundary conditions.
- <temperature>¶
Temperature boundary conditions. See subsection Boundary conditions.
- <heatflux>¶
Heat Flux boundary conditions. See subsection Boundary conditions.
- <convection>¶
Convective boundary conditions. See subsection Boundary conditions.
This boundary condition does not have value attribute. Use coeff for convection coefficient and ambient for ambient temperature instead.
- <radiation>¶
Radiative boundary conditions. See subsection Boundary conditions.
This boundary condition does not have value attribute. Use emissivity for surface emissivity and ambient for ambient temperature instead.
- <junction>¶
Configuration of the effective model of p-n junction.
- Attributes:
beta# – Junction coefficients. This is an inverse of the junction thermal voltage. (float (1/V))
js# – Reverse bias current densities. (float (A/m2))
pnjcond – Initial vertical conductivity of the junctions. (float (S/m), default 5.0 S/m)
- <contacts>¶
Properties of the contact layers.
- Attributes:
pcond – p-contact conductivity. (float (S/m), default 5.0 S/m)
ncond – n-contact conductivity. (float (S/m), default 50.0 S/m)
- <loop>¶
Configuration of the self-consistent thermo-electric loop.
- Attributes:
skip-thermal – Skip thermal computations. The structure is assumed to have a constant temperature inittemp. This can be used to look for the threshold under pulse laser operation. (bool, default is
no
)tfreq – Number of electrical iterations per single thermal step. As temperature tends to converge faster, it is reasonable to repeat thermal solution less frequently. (int, default 6)
inittemp – Initial temperature used for the first computation. (float (K), default 300 K)
maxterr – Maximum allowed temperature error. (float (K), default 0.05 K)
maxcerr – Maximum allowed current density error. (float (%), default 0.05 %)
- <tmatrix>¶
Matrix configuration for the thermal solver.
- Attributes:
algorithm – Algorithm used for solving set of linear positive-definite equations. (
cholesky
,gauss
, oriterative
, default ischolesky
)
- <iterative>¶
Parameters for iterative matrix solver. PLaSK uses NSPCG package for performing iterations. Please refer to its documentation for explanation of most of the settings.
- Attributes:
maxit – Maximum number of iterations. (int, default 1000)
maxerr – Maximum iteration error. (float, default 1e-6)
noconv – Desired behavior if the iterative solver does not converge. (
error
,warning
, orcontinue
, default iswarning
)accelerator – Accelerator used for iterative matrix solver. (
cg
,si
,sor
,srcg
,srsi
,basic
,me
,cgnr
,lsqr
,odir
,omin
,ores
,iom
,gmres
,usymlq
,usymqr
,landir
,lanmin
,lanres
,cgcr
, orbcgs
, default iscg
)preconditioner – Preconditioner used for iterative matrix solver. (
rich
,jac
,ljac
,ljacx
,sor
,ssor
,ic
,mic
,lsp
,neu
,lsor
,lssor
,llsp
,lneu
,bic
,bicx
,mbic
, ormbicx
, default isic
)nfact – This number initializes the frequency of partial factorizations. It specifies the number of linear system evaluations between factorizations. The default value is 1, which means that a factorization is performed at every iteration. (int, default 10)
ndeg – Degree of the polynomial to be used for the polynomial preconditioners. (int, default 1)
lvfill – Level of fill-in for incomplete Cholesky preconditioners. Increasing this value will result in more accurate factorizations at the expense of increased memory usage and factorization time. (int, default 0)
ltrunc – Truncation bandwidth to be used when approximating the inverses of matrices with dense banded matrices. An increase in this value means a more accurate factorization at the expense of increased storage. (int, default 0)
omega – Relaxation parameter. (float, default 1.0)
nsave – The number of old vectors to be saved for the truncated acceleration methods. (int, default 5)
nrestart – The number of iterations between restarts for the restarted acceleration methods. (int, default 100000)
¶ rich
Richardson’s method
jac
Jacobi method
ljac
Line Jacobi method
ljacx
Line Jacobi method (approx. inverse)
sor
Successive Overrelaxation
ssor
Symmetric SOR (can be used only with SOR accelerator)
ic
Incomplete Cholesky (default)
mic
Modified Incomplete Cholesky
lsp
Least Squares Polynomial
neu
Neumann Polynomial
lsor
Line SOR
lssor
Line SSOR
llsp
Line Least Squares Polynomial
lneu
Line Neumann Polynomial
bic
Block Incomplete Cholesky (ver. 1)
bicx
Block Incomplete Cholesky (ver. 2)
mbic
Modified Block Incomplete Cholesky (ver. 1)
mbicx
Modified Block Incomplete Cholesky (ver. 2)
¶ cg
Conjugate Gradient acceleration (default)
si
Chebyshev acceleration or Semi-Iteration
sor
Successive Overrelaxation (can use only SOR preconditioner)
srcg
Symmetric Successive Overrelaxation Conjugate Gradient Algorithm (can use only SSOR preconditioner)
srsi
Symmetric Successive Overrelaxation Semi-Iteration Algorithm (can use only SSOR preconditioner)
basic
Basic Iterative Method
me
Minimal Error Algorithm
cgnr
Conjugate Gradient applied to the Normal Equations
lsqr
Least Squares Algorithm
odir
ORTHODIR, a truncated/restarted method useful for nonsymmetric systems of equations
omin
ORTHOMIN, a common truncated/restarted method used for nonsymmetric systems
ores
ORTHORES, another truncated/restarted method for nonsymmetric systems
iom
Incomplete Orthogonalization Method
gmres
Generalized Minimal Residual Method
usymlq
Unsymmetric LQ
usymqr
Unsymmetric QR
landir
Lanczos/ORTHODIR
lanmin
Lanczos/ORTHOMIN or Biconjugate Gradient Method
lanres
Lanczos/ORTHORES or “two-sided” Lanczos Method
cgcr
Constrained Generalized Conjugate Residual Method
bcgs
Biconjugate Gradient Squared Method
- <ematrix>¶
Matrix configuration for the electrical solver.
- Attributes:
algorithm – Algorithm used for solving set of linear positive-definite equations. (
cholesky
,gauss
, oriterative
, default ischolesky
)
- <iterative>
Parameters for iterative matrix solver. PLaSK uses NSPCG package for performing iterations. Please refer to its documentation for explanation of most of the settings.
- Attributes:
maxit – Maximum number of iterations. (int, default 1000)
maxerr – Maximum iteration error. (float, default 1e-6)
noconv – Desired behavior if the iterative solver does not converge. (
error
,warning
, orcontinue
, default iswarning
)accelerator – Accelerator used for iterative matrix solver. (
cg
,si
,sor
,srcg
,srsi
,basic
,me
,cgnr
,lsqr
,odir
,omin
,ores
,iom
,gmres
,usymlq
,usymqr
,landir
,lanmin
,lanres
,cgcr
, orbcgs
, default iscg
)preconditioner – Preconditioner used for iterative matrix solver. (
rich
,jac
,ljac
,ljacx
,sor
,ssor
,ic
,mic
,lsp
,neu
,lsor
,lssor
,llsp
,lneu
,bic
,bicx
,mbic
, ormbicx
, default isic
)nfact – This number initializes the frequency of partial factorizations. It specifies the number of linear system evaluations between factorizations. The default value is 1, which means that a factorization is performed at every iteration. (int, default 10)
ndeg – Degree of the polynomial to be used for the polynomial preconditioners. (int, default 1)
lvfill – Level of fill-in for incomplete Cholesky preconditioners. Increasing this value will result in more accurate factorizations at the expense of increased memory usage and factorization time. (int, default 0)
ltrunc – Truncation bandwidth to be used when approximating the inverses of matrices with dense banded matrices. An increase in this value means a more accurate factorization at the expense of increased storage. (int, default 0)
omega – Relaxation parameter. (float, default 1.0)
nsave – The number of old vectors to be saved for the truncated acceleration methods. (int, default 5)
nrestart – The number of iterations between restarts for the restarted acceleration methods. (int, default 100000)
¶ rich
Richardson’s method
jac
Jacobi method
ljac
Line Jacobi method
ljacx
Line Jacobi method (approx. inverse)
sor
Successive Overrelaxation
ssor
Symmetric SOR (can be used only with SOR accelerator)
ic
Incomplete Cholesky (default)
mic
Modified Incomplete Cholesky
lsp
Least Squares Polynomial
neu
Neumann Polynomial
lsor
Line SOR
lssor
Line SSOR
llsp
Line Least Squares Polynomial
lneu
Line Neumann Polynomial
bic
Block Incomplete Cholesky (ver. 1)
bicx
Block Incomplete Cholesky (ver. 2)
mbic
Modified Block Incomplete Cholesky (ver. 1)
mbicx
Modified Block Incomplete Cholesky (ver. 2)
¶ cg
Conjugate Gradient acceleration (default)
si
Chebyshev acceleration or Semi-Iteration
sor
Successive Overrelaxation (can use only SOR preconditioner)
srcg
Symmetric Successive Overrelaxation Conjugate Gradient Algorithm (can use only SSOR preconditioner)
srsi
Symmetric Successive Overrelaxation Semi-Iteration Algorithm (can use only SSOR preconditioner)
basic
Basic Iterative Method
me
Minimal Error Algorithm
cgnr
Conjugate Gradient applied to the Normal Equations
lsqr
Least Squares Algorithm
odir
ORTHODIR, a truncated/restarted method useful for nonsymmetric systems of equations
omin
ORTHOMIN, a common truncated/restarted method used for nonsymmetric systems
ores
ORTHORES, another truncated/restarted method for nonsymmetric systems
iom
Incomplete Orthogonalization Method
gmres
Generalized Minimal Residual Method
usymlq
Unsymmetric LQ
usymqr
Unsymmetric QR
landir
Lanczos/ORTHODIR
lanmin
Lanczos/ORTHOMIN or Biconjugate Gradient Method
lanres
Lanczos/ORTHORES or “two-sided” Lanczos Method
cgcr
Constrained Generalized Conjugate Residual Method
bcgs
Biconjugate Gradient Squared Method
- <diffusion>¶
Diffusion solver configuration.
- Attributes:
fem-method – Order of the finite-element method. (
linear
orparabolic
, default isparabolic
)accuracy – Required relative accuracy. (float (%), default 0.01 %)
abs-accuracy – Required absolute minimal concentration accuracy. (float (cm-3), default 5000000000000000.0 cm-3)
maxiters – Maximum number of allowed iterations before attempting to refine mesh. (int, default 20)
maxrefines – Maximum number of allowed mesh refinements. (int, default 5)
interpolation – Current density interpolation method name. (
linear
orspline
, default isspline
)
- <gain>¶
Gain solver parameters.
- Attributes:
lifetime – Average carriers lifetime. This parameter is used for gain spectrum broadening. (float (ps), default 0.1 ps)
matrix-elem – Value of the squared matrix element in gain computations. If it is not set it is estimated automatically. (float (eV×m0))
strained – Boolean attribute indicating if the solver should consider strain in the active region. If set to yes then there must a layer with the role “substrate“ in the geometry. The strain is computed by comparing the atomic lattice constants of the substrate and the quantum wells. (bool, default is
no
)
- <optical-root>¶
Parameters of the horizontal root-finding algorithm in optical solver.
- Attributes:
method – Root finding algorithm. (
muller
,broyden
, orbrent
, default ismuller
)determinant – This parameter determines the method used to compute radial determinant. If it is set to ‘transfer’, 2x2 transfer matrix is used to ensure field continuity at the interfaces. For the ‘full’ value, one single matrix is constructed for all the interfaces and its determinant is returned. (
full
ortransfer
, default istransfer
)tolx – Maximum change of the effective frequency parameter which is allowed for convergent solution. (float, default 1e-06)
tolf-min – Minimum value of the determinant sufficient to assume convergence. (float, default 1e-07)
tolf-max – Maximum value of the determinant required to assume convergence. (float, default 2e-05)
maxstep – Maximum step in one iteration of root finding. Significant for the Broyden’s method only. (float, default 0.1)
maxiter – Maximum number of root finding iterations. (int, default 500)
alpha – Parameter ensuring sufficient decrease of determinant in each step (Broyden method only). (float, default 1e-07)
lambda – Minimum decrease ratio of one step (Broyden method only). (float, default 1e-08)
initial-range – Initial range size (Muller method only). (complex, default 0.001)
- <optical-stripe-root>¶
Parameters of root-finding algorithm for one stripe in optical solver.
- Attributes:
method – Root finding algorithm. (
muller
,broyden
, orbrent
, default ismuller
)tolx – Maximum change of the effective frequency parameter which is allowed for convergent solution. (float, default 1e-06)
tolf-min – Minimum value of the determinant sufficient to assume convergence. (float, default 1e-07)
tolf-max – Maximum value of the determinant required to assume convergence. (float, default 1e-05)
maxstep – Maximum step in one iteration of root finding. Significant for the Broyden’s method only. (float, default 0.1)
maxiter – Maximum number of root finding iterations. (int, default 500)
alpha – Parameter ensuring sufficient decrease of determinant in each step (Broyden method only). (float, default 1e-07)
lambda – Minimum decrease ratio of one step (Broyden method only). (float, default 1e-08)
initial-range – Initial range size (Muller method only). (complex, default 0.001)
- <output>¶
Settings for the solver output.
- Attributes:
optical-res-x – Number of points along the horizontal axis for the saved and plotted optical field. (int, default 800)
optical-res-y – Number of points along the vertical axis for the saved and plotted optical field. (int, default 600)