Class Radiation

class Radiation

Public Types

enum Solver_Type

Values:

enumerator InvalidSolver

enumerator SingleGroupSolver

enumerator SGFLDSolver

enumerator MGFLDSolver

Public Functions

Radiation(amrex::Amr *Parent, class Castro *castro, int restart = 0)

Parameters:

Parent –
castro –
restart –

inline ~Radiation()

void regrid(int level, const amrex::BoxArray &grids, const amrex::DistributionMapping &dmap)

Parameters:

level –
grids –
dmap –

void close(int level)

Parameters:: level –

void restart(int level, const amrex::BoxArray &grids, const amrex::DistributionMapping &dmap, const std::string &dir, std::istream &is)

Parameters:

level –
grids –
dmap –
dir –
is –

void checkPoint(int level, const std::string &dir, std::ostream &os, amrex::VisMF::How how)

Parameters:

level –
dir –
os –
how –

void set_current_group(int igroup)

access to group information

Parameters:: igroup –

inline amrex::Real group_center(int i)

Parameters:: i –

inline amrex::Real group_weight(int i)

Parameters:: i –

inline amrex::Real deltaEnergyRatMax(int lev)

diagnostics for adjusting timestep

Parameters:: lev –

inline amrex::Real deltaTRatMax(int lev)

Parameters:: lev –

inline amrex::Real deltaEnergyTol()

inline amrex::Real deltaTTol()

inline amrex::FluxRegister *consRegister(int level)

access to conservation flux register for energy diagnostics

Parameters:: level –

void post_init(int level)

Parameters:: level –

void pre_timestep(int level)

Parameters:: level –

void init_flux(int level, int ncycle)

Parameters:

level –
ncycle –

void deferred_sync_setup(int level)

Parameters:: level –

void deferred_sync(int level, amrex::MultiFab &rhs, int indx)

Parameters:

level –
rhs –
indx –

void single_group_update(int level, int iteration, int ncycle)

Parameters:

level –
iteration –
ncycle –

void MGFLD_implicit_update(int level, int iteration, int ncycle)

Parameters:

level –
iteration –
ncycle –

void write_groups(ostream &os)

Parameters:: os –

void reflux(int level)

Parameters:: level –

void compute_limiter(int level, const amrex::BoxArray &grids, const amrex::MultiFab &Sborder, const amrex::MultiFab &Erborder, amrex::MultiFab &lamborder)

Parameters:

level –
grids –
&Sborder –
&Erborder –
&lamborder –

void estimate_gamrPr(const amrex::FArrayBox &state, const amrex::FArrayBox &Er, amrex::FArrayBox &gPr, const amrex::Real *dx, const amrex::Box &box)

Parameters:

state –
Er –
gPr –
dx –
box –

void EstTimeStep(amrex::Real &estdt, int level)

Parameters:

estdt –
level –

void filter_prim(int level, amrex::MultiFab &State)

Parameters:

level –
State –

void compute_exchange(amrex::MultiFab &exch, amrex::MultiFab &Er, amrex::MultiFab &fkp, int igroup = -1)

Parameters:

exch –
Er –
fkp –
igroup –

void compute_eta(amrex::MultiFab &eta, amrex::MultiFab &etainv, amrex::MultiFab &state, amrex::MultiFab &temp, amrex::MultiFab &fkp, amrex::MultiFab &Er, amrex::Real delta_t, amrex::Real c, amrex::Real underrel, int lag_planck, int igroup = 0)

Parameters:

eta –
etainv –
state –
temp –
fkp –
Er –
delta_t –
c –
underrel –
lag_planck –
igroup –

void internal_energy_update(amrex::Real &relative, amrex::Real &absolute, amrex::MultiFab &frhoes, amrex::MultiFab &frhoem, amrex::MultiFab &eta, amrex::MultiFab &etainv, amrex::MultiFab &dflux_old, amrex::MultiFab &dflux_new, amrex::MultiFab &exchange, amrex::Real delta_t)

Parameters:

relative –
absolute –
frhoes –
frhoem –
eta –
etainv –
dflux_old –
dflux_new –
exchange –
delta_t –

void internal_energy_update(amrex::Real &relative, amrex::Real &absolute, amrex::MultiFab &frhoes, amrex::MultiFab &frhoem, amrex::MultiFab &eta, amrex::MultiFab &etainv, amrex::MultiFab &dflux_old, amrex::MultiFab &dflux_new, amrex::MultiFab &exchange, amrex::MultiFab &Dterm, amrex::Real delta_t)

Parameters:

relative –
absolute –
frhoes –
frhoem –
eta –
etainv –
dflux_old –
dflux_new –
exchange –
Dterm –
delta_t –

void nonconservative_energy_update(amrex::Real &relative, amrex::Real &absolute, amrex::MultiFab &frhoes, amrex::MultiFab &frhoem, amrex::MultiFab &eta, amrex::MultiFab &etainv, amrex::MultiFab &Er_new, amrex::MultiFab &dflux_old, amrex::MultiFab &dflux_new, amrex::MultiFab &temp, amrex::MultiFab &fkp, amrex::MultiFab &state, amrex::Real delta_t)

Parameters:

relative –
absolute –
frhoes –
frhoem –
eta –
etainv –
Er_new –
dflux_old –
dflux_new –
temp –
fkp –
state –
delta_t –

void state_update(amrex::MultiFab &state, amrex::MultiFab &frhoes)

Parameters:

state –
frhoes –

void getBndryData(RadBndry &bd, amrex::MultiFab &Er, amrex::Real time, int level)

Parameters:

bd –
Er –
time –
level –

void getBndryDataMG(MGRadBndry &mgbd, amrex::MultiFab &Er, amrex::Real time, int level)

multigroup version

Parameters:

mgbd –
Er –
time –
level –

void getBndryDataMG_ga(MGRadBndry &mgbd, amrex::MultiFab &Er, int level)

Parameters:

mgbd –
Er –
level –

void filBndry(amrex::BndryRegister &bdry, int level, amrex::Real time)

Parameters:

bdry –
level –
time –

void scaledGradient(int level, amrex::Array<amrex::MultiFab, AMREX_SPACEDIM> &R, amrex::MultiFab &kappa_r, int kcomp, amrex::MultiFab &Er, int igroup, int nGrow_Er = 0, int Rcomp = 0)

Computes the scaled gradient for use in flux limiters & Eddington factors

Parameters:

level –
amrex::Array<amrex::MultiFab –
R –
kappa_r –
kcomp –
Er –
igroup –
nGrow_Er –
Rcomp –

void fluxLimiter(int level, amrex::Array<amrex::MultiFab, AMREX_SPACEDIM> &lambda, int lamcomp = 0)

On input, lambda should contain scaled gradient. On output this will be overwritten with the flux limiter.

Parameters:

level –
amrex::Array<amrex::MultiFab –
lambda –
lamcomp –

void get_c_v(amrex::FArrayBox &c_v, amrex::FArrayBox &temp, amrex::FArrayBox &state, const amrex::Box &reg)

Fab versions of conversion functions.

Parameters:

c_v –
temp –
state –
reg –

void get_frhoe(amrex::MultiFab &frhoe, amrex::MultiFab &state)

MultiFab versions of conversion functions call Fab versions for eos data

Parameters:

frhoe –
state –

void get_planck_and_temp(amrex::MultiFab &fkp, amrex::MultiFab &temp, amrex::MultiFab &state, int igroup = 0, amrex::Real delta_t = 0.0)

Planck mean is only needed in the grid interiors, but must be computed separately for each fluid (fkp.nVar() == N fluids). temp contains frhoe on input

Parameters:

fkp –
temp –
state –
igroup –
delta_t –

void get_rosseland(amrex::MultiFab &kappa_r, amrex::AmrLevel *hclaw, int igroup = 0)

Rosseland mean is needed on an extended region (nGrow == 1). Fills patches with state information on extended region

Parameters:

kappa_r –
hclaw –
igroup –

void update_rosseland_from_temp(amrex::MultiFab &kappa_r, amrex::MultiFab &temp, amrex::MultiFab &state, const amrex::Geometry &geom, int igroup = 0)

For the interior opacities, temperature is assumed to be known (input)

Updates Rosseland mean in interior of level, leaves ghost values at physical or coarse-fine interfaces untouched

Parameters:

kappa_r –
temp –
state –
geom –
igroup –

void get_rosseland_v_dcf(amrex::MultiFab &kappa_r, amrex::MultiFab &v, amrex::MultiFab &dcf, amrex::Real delta_t, amrex::Real c, amrex::AmrLevel *hclaw, int igroup = 0)

RadHydro

Parameters:

kappa_r –
v –
dcf –
delta_t –
c –
hclaw –
igroup –

void get_groups(int verbose)

multigroup methods

Parameters:: verbose –

void extrapolateBorders(amrex::MultiFab &f, int indx)

Parameters:

f –
indx –

void SGFLD_compute_rosseland(amrex::MultiFab &kappa_r, const amrex::MultiFab &state)

Parameters:

kappa_r –
state –

void SGFLD_compute_rosseland(amrex::FArrayBox &kappa_r, const amrex::FArrayBox &state)

Parameters:

kappa_r –
state –

void update_dcf(amrex::MultiFab &dcf, amrex::MultiFab &etainv, amrex::MultiFab &kp, amrex::MultiFab &kr, const amrex::Geometry &geom)

Parameters:

dcf –
etainv –
kp –
kr –
geom –

void check_convergence_er(amrex::Real &relative_in, amrex::Real &absolute_in, amrex::Real &error_er, const amrex::MultiFab &Er_new, const amrex::MultiFab &Er_pi, const amrex::MultiFab &kappa_p, const amrex::MultiFab &etaTz, const amrex::MultiFab &temp_new, amrex::Real delta_t)

</ Shestakov-Bolstad>

Parameters:

relative_in –
absolute_in –
error_er –
Er_new –
Er_pi –
kappa_p –
etaTz –
temp_new –
delta_t –

void check_convergence_matt(const amrex::MultiFab &rhoe_new, const amrex::MultiFab &rhoe_star, const amrex::MultiFab &rhoe_step, const amrex::MultiFab &Er_new, const amrex::MultiFab &temp_new, const amrex::MultiFab &temp_star, const amrex::MultiFab &rho, const amrex::MultiFab &kappa_p, const amrex::MultiFab &jg, const amrex::MultiFab &dedT, amrex::Real &rel_rhoe, amrex::Real &abs_rhoe, amrex::Real &rel_FT, amrex::Real &abs_FT, amrex::Real &rel_T, amrex::Real &abs_T, amrex::Real delta_t)

Parameters:

rhoe_new –
rhoe_star –
rhoe_step –
Er_new –
temp_new –
temp_star –
rho –
kappa_p –
jg –
dedT –
rel_rhoe –
abs_rhoe –
rel_FT –
abs_FT –
rel_T –
abs_T –
delta_t –

void compute_coupling(amrex::MultiFab &coupT, const amrex::MultiFab &kappa_p, const amrex::MultiFab &Er_pi, const amrex::MultiFab &jg)

Parameters:

coupT –
kappa_p –
Er_pi –
jg –

void compute_etat(amrex::MultiFab &etaT, amrex::MultiFab &etaTz, amrex::MultiFab &eta1, amrex::MultiFab &djdT, const amrex::MultiFab &dkdT, const amrex::MultiFab &dedT, const amrex::MultiFab &Er_star, const amrex::MultiFab &rho, amrex::Real delta_t, amrex::Real ptc_tau)

Parameters:

etaT –
etaTz –
eta1 –
djdT –
dkdT –
dedT –
Er_star –
rho –
delta_t –
ptc_tau –

void eos_opacity_emissivity(const amrex::MultiFab &S_new, const amrex::MultiFab &temp_new, const amrex::MultiFab &temp_star, amrex::MultiFab &kappa_p, amrex::MultiFab &kappa_r, amrex::MultiFab &jg, amrex::MultiFab &djdT, amrex::MultiFab &dkdT, amrex::MultiFab &dedT, int level, int it, int ngrow)

Parameters:

S_new –
temp_new –
temp_star –
kappa_p –
kappa_r –
jg –
djdT –
dkdT –
dedT –
level –
it –
ngrow –

void gray_accel(amrex::MultiFab &Er_new, amrex::MultiFab &Er_pi, amrex::MultiFab &kappa_p, amrex::MultiFab &kappa_r, amrex::MultiFab &etaT, amrex::MultiFab &eta1, amrex::MultiFab &mugT, amrex::Array<amrex::MultiFab, AMREX_SPACEDIM> &lambda, RadSolve *solver, MGRadBndry &mgbd, const amrex::BoxArray &grids, int level, amrex::Real time, amrex::Real delta_t, amrex::Real ptc_tau)

Parameters:

Er_new –
Er_pi –
kappa_p –
kappa_r –
etaT –
eta1 –
mugT –
lambda –
solver –
mgbd –
grids –
level –
time –
delta_t –
ptc_tau –

void local_accel(amrex::MultiFab &Er_new, const amrex::MultiFab &Er_pi, const amrex::MultiFab &kappa_p, const amrex::MultiFab &etaT, const amrex::MultiFab &mugT, amrex::Real delta_t, amrex::Real ptc_tau)

Parameters:

Er_new –
Er_pi –
kappa_p –
etaT –
mugT –
delta_t –
ptc_tau –

void state_energy_update(amrex::MultiFab &state, const amrex::MultiFab &rhoe, const amrex::MultiFab &temp, const amrex::BoxArray &grids, amrex::Real &derat, amrex::Real &dT, int level)

Parameters:

state –
rhoe –
temp –
grids –
derat –
dT –
level –

void update_matter(amrex::MultiFab &rhoe_new, amrex::MultiFab &temp_new, const amrex::MultiFab &Er_new, const amrex::MultiFab &Er_pi, const amrex::MultiFab &rhoe_star, const amrex::MultiFab &rhoe_step, const amrex::MultiFab &etaT, const amrex::MultiFab &etaTz, const amrex::MultiFab &eta1, const amrex::MultiFab &coupT, const amrex::MultiFab &kappa_p, const amrex::MultiFab &jg, const amrex::MultiFab &mugT, const amrex::MultiFab &S_new, int level, amrex::Real delta_t, amrex::Real ptc_tau, int it, bool conservative_update)

Parameters:

rhoe_new –
temp_new –
Er_new –
Er_pi –
rhoe_star –
rhoe_step –
etaT –
etaTz –
eta1 –
coupT –
kappa_p –
jg –
mugT –
S_new –
level –
delta_t –
ptc_tau –
it –
conservative_update –

void bisect_matter(amrex::MultiFab &rhoe_new, amrex::MultiFab &temp_new, const amrex::MultiFab &rhoe_star, const amrex::MultiFab &temp_star, const amrex::MultiFab &S_new, const amrex::BoxArray &grids, int level)

Parameters:

rhoe_new –
temp_new –
rhoe_star –
temp_star –
S_new –
grids –
level –

void MGFLD_compute_rosseland(amrex::MultiFab &kappa_r, const amrex::MultiFab &state)

for the hyperbolic solver

Parameters:

kappa_r –
state –

void MGFLD_compute_rosseland(amrex::FArrayBox &kappa_r, const amrex::FArrayBox &state)

Parameters:

kappa_r –
state –

void MGFLD_compute_scattering(amrex::FArrayBox &kappa_s, const amrex::FArrayBox &state)

Parameters:

kappa_s –
state –

void rhstoEr(amrex::MultiFab &rhs, amrex::Real dt, int level)

Parameters:

rhs –
dt –
level –

void save_lambda_in_plotvar(int level, const amrex::Array<amrex::MultiFab, AMREX_SPACEDIM> &lambda)

</ MGFLD>

Parameters:

level –
amrex::Array<amrex::MultiFab –
lambda –

void save_lab_Er_in_plotvar(int level, const amrex::MultiFab &Snew, const amrex::MultiFab &Ecom, const amrex::MultiFab &F, int iflx)

Parameters:

level –
Snew –
Ecom –
F –
iflx –

void save_flux_in_plotvar(int level, const amrex::MultiFab &Snew, const amrex::Array<amrex::MultiFab, AMREX_SPACEDIM> &lambda, const amrex::MultiFab &Er, const amrex::MultiFab &F, int iflx, const amrex::Real lab_factor = 1.0)

Parameters:

level –
Snew –
amrex::Array<amrex::MultiFab –
lambda –
Er –
F –
iflx –
lab_factor –

void save_com_flux_in_plotvar(int level, const amrex::MultiFab &Snew, const amrex::Array<amrex::MultiFab, AMREX_SPACEDIM> &lambda, const amrex::MultiFab &Er, const amrex::MultiFab &F, int iflx)

Parameters:

level –
Snew –
amrex::Array<amrex::MultiFab –
lambda –
Er –
F –
iflx –

Public Members

int verbose

int maxiter: iteration limit for implicit update loop

int miniter

int convergence_check_type: 0 (default): both 2 and 3, 1: rhoe, 2: residue of Eq. rhoe, 3: T

amrex::Real relInTol

amrex::Real absInTol: tolerance for inner iteration of J equation

int maxInIter: iteration limit for inner iteration of J equation

int minInIter

int skipAccelAllowed: Skip acceleration if it doesn’t help.

int matter_update_type: 0: conservative 1: non-conservative 2: C and NC interwoven The last outer iteration is always conservative.

int n_bisect: Bisection after n_bisect iterations.

amrex::Real dedT_fac: Make dedT larger for safety in Newton iteration.

int inner_convergence_check

amrex::Real delta_e_rat_dt_tol: energy change tolerance for adjusting timestep

amrex::Real delta_T_rat_dt_tol: T change tolerance for adjusting timestep.

int update_planck: after this number of iterations, lag planck

int update_rosseland: after this number of iterations, lag rosseland

int update_opacity

int update_limiter: after this number of iterations, lag limiter

int inner_update_limiter: This is for MGFLD solver. Stop updating limiter after ? inner iterations 0 means lagging by one outer iteration

amrex::Real dT: temperature step for derivative estimate

amrex::Real underfac: factor controlling progressive underrelaxation

int do_sync: perform sync (if false zero out sync source)

int do_kappa_stm_emission

amrex::Vector<std::unique_ptr<amrex::MultiFab>> plotvar

int use_dkdT: <MGFLD>

int use_WiensLaw: <Shestakov-Bolstad>

amrex::Real Tf_Wien

amrex::Vector<amrex::Real> xnu

amrex::Vector<amrex::Real> nugroup

amrex::Vector<amrex::Real> dnugroup

amrex::Vector<amrex::Real> lognugroup

amrex::Vector<amrex::Real> dlognugroup

Public Static Functions

static void read_static_params()

Public Static Attributes

static Solver_Type SolverType

static amrex::Real radtoE

static amrex::Real Etorad

static amrex::Real radfluxtoF

static int do_multigroup

static int nGroups

static int rad_hydro_combined

static int Er_Lorentz_term

static int icomp_lambda

static int icomp_kp

static int icomp_kr

static int icomp_lab_Er

static int icomp_lab_Fr

static int icomp_com_Fr

static int nplotvar

static amrex::Vector<std::string> plotvar_names

static int filter_lambda_T

static int filter_lambda_S

static int filter_prim_int

static int filter_prim_T

static int filter_prim_S

static int accelerate: controls multigroup convergence acceleration

static amrex::Real convert_MeV_erg: Physical constants for use in multigroup, made static and public so that other modules such as RadSolve can get to them easily. Values are set in the Radiation constructor.

static amrex::Real clight

static amrex::Real hPlanck

static amrex::Real kBoltz

static amrex::Real Avogadro

static amrex::Real c: Values used internally for speed of light, Stefan-Boltzmann constant, radiation constant. (For contrived test problems, these may differ from the proper physical values, so be careful if you use them!)

static amrex::Real sigma

static amrex::Real aRad

static int current_group_number

static std::string current_group_name

static int pure_hydro

Protected Attributes

amrex::Amr *parent

amrex::BCRec rad_bc: types defined in LO_BCTYPES.H, not BCTYPES.H

amrex::Real reltol

amrex::Real abstol: tolerances for implicit update loop

amrex::Vector<amrex::Real> delta_e_rat_level

amrex::Vector<amrex::Real> delta_T_rat_level

amrex::Vector<std::unique_ptr<amrex::FluxRegister>> flux_cons: arrays of flux registers flux_cons(\level) is a amrex::FluxRegister, which contains fluxes for all groups

amrex::Vector<std::unique_ptr<amrex::FluxRegister>> flux_cons_old

amrex::Vector<std::unique_ptr<amrex::FluxRegister>> flux_trial

amrex::Vector<amrex::Real> delta_t_old: for deferred sync

amrex::Vector<std::unique_ptr<amrex::MultiFab>> dflux: divergence of flux

std::string group_units

amrex::Real group_print_factor

amrex::IntVect spot