Driver/DriverMain
allowDtSTSDominate [BOOLEAN] [FALSE]
allow a situation in which dt_STS becomes larger than dt_Hydro
(dt_advection) (assuming that diffusion dt is smaller than advection dt)
upto advection one, but not faster than the advection advancement. This
will be useful in solving PDE systems that are hyperbolic + parabolic.
FALSE will use the STS algorithm to even accelerate advection time
advancement, which in turn, will use larger advection dt than advection
dt from CFL limits. This will be useful in solving only hyperbolic PDE
systems in general. When hyperbolic + parabolic PDE system is to be
solved, then we suggest that users use less agressive super time
stepping method by using useSTSforDiffusion = TRUE.
dr_abortPause [INTEGER] [2]
Valid Values: 0 to INFTY
When Driver_abortFlash is called to abnormally end execution, and
dr_abortPause is grater than zero, the FLASH Driver_abortFlash code will
sleep for dr_abortPause seconds after writing explanatory messages (to
standard output and, possibly, to log files) but before calling
MPI_ABORT. See also eachProcWritesOwnAbortLog for controlling the
generation of per-processor log files.
dr_dtMinBelowAction [INTEGER] [1]
Valid Values: 0, 1
Action to take when computed new timestep is below dr_dtMinContinue. Use
0 for none (abort immediately), 1 for "write checkpoint then abort"
dr_dtMinContinue [REAL] [0.0]
Valid Values: 0.0 to INFTY
Minimum computed timestep to continue the simulation
dr_numPosdefVars [INTEGER] [4]
Valid Values: 0 to 4
number of variables for positive-definite time step limiter
dr_posdefDtFactor [REAL] [1.0]
Valid Values: -1.0, 0.0 to INFTY
Scaling factor for dt limit from positive-definite time step limiter.
Similar to CFL factor. If set to -1, use CFL factor from Hydro.
dr_posdefVar_1 [STRING] ["none"]
Valid Values: Unconstrained
variable
dr_posdefVar_2 [STRING] ["none"]
Valid Values: Unconstrained
variable
dr_posdefVar_3 [STRING] ["none"]
Valid Values: Unconstrained
variable
dr_posdefVar_4 [STRING] ["none"]
Valid Values: Unconstrained
variable
dr_printTStepLoc [BOOLEAN] [TRUE]
dr_shortenLastStepBeforeTMax [BOOLEAN] [FALSE]
If TRUE, make the dt for the last time step shorter if necassary so as
to avoid overshooting tmax.
dr_tstepSlowStartFactor [REAL] [0.1]
Valid Values: 0.0 to INFTY
The initial dt is set to be at most the timestep computed by CFL
conditions applied to certain operators multiplied with this factor.
dr_usePosdefComputeDt [BOOLEAN] [FALSE]
turns positive-definite time step limiter on.
drift_break_inst [INTEGER] [0]
Valid Values: Unconstrained
drift_trunc_mantissa [INTEGER] [2]
Valid Values: Unconstrained
number of mantissa bits to exclude from hash (3 bits ~ 1 sigdig)
drift_tuples [BOOLEAN] [FALSE]
should block data be written in python tuples format
drift_verbose_inst [INTEGER] [0]
Valid Values: Unconstrained
dtinit [REAL] [1.E-10]
Valid Values: Unconstrained
Initial timestep
dtmax [REAL] [1.E5]
Valid Values: Unconstrained
Maximum timestep
dtmin [REAL] [1.E-10]
Valid Values: Unconstrained
Minimum timestep
eachProcWritesOwnAbortLog [BOOLEAN] [FALSE]
Should each process writes messages to its own log file when
Driver_abortFlash gets called to abnormally end execution? If true, each
process in which Driver_abortFlash is called will attempt to write an
explanatory message to its own log file, whether that file already
existed or needs to be newly created. If false, the Driver_abortFlash
message will appear only in the regular log file (if the Logfile code
unit is used), and normally only when Driver_abortFlash is called by the
process with PE 0.
iProcs [INTEGER] [1]
Valid Values: Unconstrained
number of procs in the i dir
initializeParticleAtRestart [BOOLEAN] [false]
initialize particles at restart instead of reading particles from
checkpoint
jProcs [INTEGER] [1]
Valid Values: Unconstrained
number of procs in the j dir
kProcs [INTEGER] [1]
Valid Values: Unconstrained
number of procs in the k dir
meshCopyCount [INTEGER] [1]
Valid Values: Unconstrained
The number of copies of full computational mesh that
nbegin [INTEGER] [1]
Valid Values: 1 to INFTY
First timestep
nend [INTEGER] [100]
Valid Values: Unconstrained
Maximum number of timesteps to take
nstepTotalSTS [INTEGER] [5]
Valid Values: Unconstrained
nuSTS [REAL] [0.1]
Valid Values: Unconstrained
nu stability parameter for super time stepping algorithm
restart [BOOLEAN] [FALSE]
Is this a restart run?
sweepOrder [INTEGER] [123]
Valid Values: 123, 132, 213, 231, 312, 321
Determine the order of the directional sweeps
threadBlockListBuild [BOOLEAN] CONSTANT [TRUE]
threadDriverBlockList [BOOLEAN] [TRUE]
threadDriverWithinBlock [BOOLEAN] [TRUE]
threadRayTraceBuild [BOOLEAN] CONSTANT [TRUE]
threadWithinBlockBuild [BOOLEAN] CONSTANT [TRUE]
tinitial [REAL] [0.0]
Valid Values: Unconstrained
Initial simulation time
tmax [REAL] [0.2]
Valid Values: Unconstrained
Maximum simulation time
tstep_change_factor [REAL] [2.0]
Valid Values: 0.0+ to INFTY
The initial time step dt is multiplied with this factor at every
timestep, until it is limited by CFL condition, allowing users to
specify a very conservative initial dt and letting it grow by specifying
a tstep_change_factor > 1.0.
useSTS [BOOLEAN] [FALSE]
Do we want to use super time stepping (STS) algorithm?
useSTSforDiffusion [BOOLEAN] [FALSE]
TRUE will use the STS algorithm to accelerate diffusion time advancement
wall_clock_time_limit [REAL] [604800.]
Valid Values: -1.0, 0.0 to INFTY
Total wall clock time limit (seconds). Use -1.0 for no limit.
zFinal [REAL] [0.0]
Valid Values: Unconstrained
The final redshift in a simulation. The simulation will stop
zInitial [REAL] [-1.0]
Valid Values: Unconstrained
The initial redshift in a simulation. < 0 if not being used.
Grid/GridMain
bndPriorityOne [INTEGER] [1]
Valid Values: 1, 2, 3
indicates which direction (IAXIS, JAXIS, or KAXIS) gets top priority
when applying boundary conditions in corner guardcells We define three
values for edges left, center, right, of which center represents
interior, while left and right represent the corresponding guardcells.
We define a corner where more than one dimension has its its guardcells,
so the application must determine which direction gets to fill them. In
2-D, there are four corners: (left,left), (left,right), (right,left) and
(right,right). In 3-D case, the following corners are possible :
(left,left,left),(left,left,center),
(left,left,right),(left,center,left),
(left,center,right),(left,right,left),
(left,right,center),(left,right,right)
(center,left,left),(center,left,right),
(center,right,left),(center,right,right),
(right,left,left),(right,left,center),
(right,left,right),(right,center,left),
(right,center,right),(right,right,left),
(right,right,center),(right,right,right)
bndPriorityThree [INTEGER] [3]
Valid Values: 1, 2, 3
the least priority dimension in applying boundary conditions
bndPriorityTwo [INTEGER] [2]
Valid Values: 1, 2, 3
the second priority dimension in applying boundary conditions
convertToConsvdForMeshCalls [BOOLEAN] [FALSE]
indicates if appropriate variables are converted from primitive to
conserved form during propagation before control is passed to Paramesh
for refinement, derefinement, or guardcell filling. This is the old way
of ensuring that solution variables are in the correct form for
interpolation. It involves unnecessary conversions back and forth and
should be obsoleted by the newer mechanism enabled by runtime parameter
"convertToConsvdInMeshInterp". The name is a replacement for the old
"conserved_var" which many people have found to be very confusing
terminology.
eosMode [STRING] ["dens_ie_recal_gather"]
Valid Values: "dens_ie", "dens_pres", "dens_temp", "dens_ie_all",
"dens_ie_scatter", "dens_ie_gather", "dens_ie_sele_gather",
"dens_temp_equi", "dens_temp_all", "dens_temp_gather",
"dens_ie_recal_gather", "dens_ie_mat_gather_pradscale"
determines how to operate on thermodynamic quantities. Possible values
are "dens_ie", where density and internal energy are supplied and
pressure and temperature are returned; "dens_pres", where density and
pressure are given and energy and temperature are computed; and
"dens_temp", where density and temperature are given and pressure and
energy are computed. Other values may also be available as, depending on
whether a multiTemp Eos is used and on implementation of additional
physics. For 3T simulations, the best choice is "dens_ie_recal_gather",
since this mode will ensure that total energy is conserved when
refinement changes occur.
eosModeInit [STRING] ["dens_ie"]
Valid Values: "dens_ie", "dens_pres", "dens_temp", "dens_ie_all",
"dens_ie_scatter", "dens_ie_gather", "dens_temp_equi", "dens_temp_all",
"dens_temp_gather", "eos_nop"
determines how to operate on thermodynamic quantities for the initial
conditions. A call to Simulation_initBlock sets initial conditions on
each block, and an eos call follows which ensures the initial values are
thermodynamically consistent. The value of eosModeInit determines the
mode in which these eos calls operate. Possible values are "dens_ie",
where density and internal energy are supplied and pressure and
temperature are returned; "dens_pres", where density and pressure are
given and energy and temperature are computed; and "dens_temp", where
density and temperature are given and pressure and energy are computed.
Other values may also be available as, depending on whether a multiTemp
Eos is used and on implementation of additional physics.
geometry [STRING] ["cartesian"]
Valid Values: "cartesian", "polar", "cylindrical", "spherical"
Grid geometry
geometryOverride [BOOLEAN] [FALSE]
whether to bypass some geometry sanity checks - use at your own risk.
gr_bcEnableApplyMixedGds [BOOLEAN] [TRUE]
whether to enable the Grid_bcApplyToRegionMixedGds interface for
implementing boundary conditions with access to the variables of mixed
GDSs (in particlular, cell-centered UNK varsiables and face variables).
This only has an effect if the GridBoundaryConditions subunit is
included and the simulation actually supplies an implementation of
Grid_bcApplyToRegionMixedGds.
reduceGcellFills [BOOLEAN] [FALSE]
smalle [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for energy
smallx [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for abundances
unbiased_geometry [BOOLEAN] [FALSE]
attempt to remove floating point bias from geometry discretization. Not
implemented in FLASH3.
xl_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower (left) boundary condition in x dir
xmax [REAL] [1.]
Valid Values: Unconstrained
physical domain upper bound in x dir
xmin [REAL] [0.]
Valid Values: Unconstrained
physical domain lower bound in x dir
xr_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper (right) boundary condition in x dir
yl_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower boundary condition in y dir
ymax [REAL] [1.]
Valid Values: Unconstrained
physical domain upper bound in y dir
ymin [REAL] [0.]
Valid Values: Unconstrained
physical domain lower bound in y dir
yr_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper boundary condition in y dir
zl_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower boundary condition in z dir
zmax [REAL] [1.]
Valid Values: Unconstrained
physical domain lower bound in x dir
zmin [REAL] [0.]
Valid Values: Unconstrained
physical domain lower bound in z dir
zr_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper boundary condition in z dir
Grid/GridMain/Chombo
verbosity [INTEGER] [0]
Valid Values: 0 to INFTY
Grid/GridMain/Chombo/AMR
BRMeshRefineBlockFactor [INTEGER] [8]
Valid Values: 1 to INFTY
BRMeshRefineBufferSize [INTEGER] [1]
Valid Values: 0 to INFTY
BRMeshRefineFillRatio [REAL] [0.75]
Valid Values: 0.0 to 1.0
QuadCFInterp [BOOLEAN] [False]
Whether to use quadratic coarse-fine boundary interpolation.
convertToConsvdForMeshCalls [BOOLEAN] [TRUE]
indicates if appropriate variables are converted from primitive to
conserved form during propagation before control is passed to Chombo for
refinement, derefinement, or guardcell filling.
convertToConsvdInMeshInterp [BOOLEAN] [FALSE]
indicates if appropriate variables are converted to conserved form
during propagation within the interpolation routines invoked by Chombo.
This applies to interpolation (both "prolongation" and "restriction") in
the course of refinement, derefinement, or guardcell filling. This is
not yet implemented, but needs to get implemented soon because manually
converting in several different FLASH Fortran Grid leads to the
possibility of overlooking at least one FLASH Fortran Grid subroutine.
derefine_cutoff_1 [REAL] [0.2]
Valid Values: Unconstrained
threshold value to trigger derefinement for refine_var_1
derefine_cutoff_2 [REAL] [0.2]
Valid Values: Unconstrained
threshold value to trigger derefinement for refine_var_2
derefine_cutoff_3 [REAL] [0.2]
Valid Values: Unconstrained
threshold value to trigger derefinement for refine_var_3
derefine_cutoff_4 [REAL] [0.2]
Valid Values: Unconstrained
threshold value to trigger derefinement for refine_var_4
earlyBlockDistAdjustment [BOOLEAN] [TRUE]
If true, let Paramesh redistribute blocks across processors early, so
that the block distribution chosen by Paramesh will be in effect when
time evolution begins after restart. If earlyBlockDistAdjustment is
false, the block distribution enacted by the IO unit when it read a
checkpoint file will normally still be in effect when time evolution
begins after a restart. This flag is ignored if not restarting from a
checkpoint.
enableMaskedGCFill [BOOLEAN] [FALSE]
When enableMaskedGCFill is FALSE, Grid_fillGuardCells is forced to
always ignore optional mask arguments when present in calls. This is the
default behavior. Set enableMaskedGCFill TRUE to enable masked guard
cell filling.
flux_correct [BOOLEAN] [true]
turns on or off flux correction
gr_lrefineMaxRedDoByLogR [BOOLEAN] [FALSE]
Softly force effectively a lower lrefine_max depending on distance from
center. See gr_lrefineMaxRedRadiusFact.
gr_lrefineMaxRedDoByTime [BOOLEAN] [FALSE]
Lower the effective lrefine_max as a function of time. See runtime
parameters gr_lrefineMaxRedTRef, gr_lrefineMaxRedTimeScale, and
gr_lrefineMaxRedLogBase.
gr_lrefineMaxRedLogBase [REAL] [10.0]
Valid Values: 1.0 to INFTY
Logarithm base for determining when repeated reductions in effective
lrefine_max should happen. The nth reduction will happen at
t=gr_lrefineMaxRedTRef+gr_lrefineMaxRedTimeScale*gr_lrefineMaxRedLogBase**(n-1).
gr_lrefineMaxRedRadiusFact [REAL] [0.0]
Valid Values: 0.0 to INFTY
factor that determines a minimum resolution (and thus maximum refinement
level) based on distance from a center. See x_refine_center,
y_refine_center, z_refine_center for the center coordinates. This is
approximately (linearly) equivalent to requiring a minimum *angular*
resolution, within the limits set by the global lrefine_min and
lrefine_max. Only used when gr_lrefineMaxRedDoByLogR is TRUE.
gr_lrefineMaxRedTRef [REAL] [0.0]
Valid Values: Unconstrained
reference time for time-based max level reduction. The effective
reduction of lrefine_max only kicks in for times greater than
gr_lrefineMaxRedTRef. The first time lrefine_max is effectively lowered
actually happens at t=gr_lrefineMaxRedTRef+gr_lrefineMaxRedTimeScale.
gr_lrefineMaxRedTimeScale [REAL] [1.0]
Valid Values: TINY to INFTY
the time scale for effectively lowering lrefine_max: The first reduction
takes place at t=gr_lrefineMaxRedTRef+gr_lrefineMaxRedTimeScale.
iGridSize [INTEGER] [16]
Valid Values: 1 to INFTY
Global number of interior cells in the i direction
interpol_order [INTEGER] [2]
Valid Values: 0, 1, 2
the default interpolation order when using "monotonic" interpolation
routines
jGridSize [INTEGER] [16]
Valid Values: 1 to INFTY
Global number of interior cells in the j direction
kGridSize [INTEGER] [16]
Valid Values: 1 to INFTY
Global number of interior cells in the k direction
lrefine_del [INTEGER] [0]
Valid Values: 0 to INFTY
Try to reduce the maximum refinement level by this number of levels on a
restart.
lrefine_max [INTEGER] [1]
Valid Values: 1 to INFTY
maximum AMR refinement level
lrefine_min [INTEGER] [1]
Valid Values: 1
minimum AMR refinement level
maxBlockSize [INTEGER] [16]
Valid Values: 0 to INFTY
max_particles_per_blk [INTEGER] [100]
Valid Values: Unconstrained
integer if the number of particles in a block exceeds this, it must
refine when particle count is a refinement criterion
min_particles_per_blk [INTEGER] [1]
Valid Values: Unconstrained
integer if the number of particles in a block is below this, it must
derefine when particle count is a refinement criterion
nrefs [INTEGER] [2]
Valid Values: Unconstrained
refine/derefine AMR grid every nrefs timesteps
refRatio [INTEGER] [2]
Valid Values: 0 to INFTY
The integer refinement jump between levels
refine_cutoff_1 [REAL] [0.8]
Valid Values: Unconstrained
threshold value to trigger refinement for refine_var_1
refine_cutoff_2 [REAL] [0.8]
Valid Values: Unconstrained
threshold value to trigger refinement for refine_var_2
refine_cutoff_3 [REAL] [0.8]
Valid Values: Unconstrained
threshold value to trigger refinement for refine_var_3
refine_cutoff_4 [REAL] [0.8]
Valid Values: Unconstrained
threshold value to trigger refinement for refine_var_4
refine_filter_1 [REAL] [0.01]
Valid Values: Unconstrained
prevents error calculations to determine refinement from diverging
numerically for refine_var_1
refine_filter_2 [REAL] [0.01]
Valid Values: Unconstrained
prevents error calculations to determine refinement from diverging
numerically for refine_var_1
refine_filter_3 [REAL] [0.01]
Valid Values: Unconstrained
prevents error calculations to determine refinement from diverging
numerically for refine_var_3
refine_filter_4 [REAL] [0.01]
Valid Values: Unconstrained
prevents error calculations to determine refinement from diverging
numerically for refine_var_4
refine_on_particle_count [BOOLEAN] [FALSE]
if true, the count of particles in blocks act as a refinement criterion
refine_var_1 [STRING] ["none"]
Valid Values: Unconstrained
indicates 1st variable on which to refine
refine_var_2 [STRING] ["none"]
Valid Values: Unconstrained
indicates 2nd variable on which to refine
refine_var_3 [STRING] ["none"]
Valid Values: Unconstrained
indicates 3rd variable on which to refine
refine_var_4 [STRING] ["none"]
Valid Values: Unconstrained
indicates 4th variable on which to refine
refine_var_count [INTEGER] [4]
Valid Values: Unconstrained
count of maximum allowed variable to be used
restrictBeforeGhostExchange [BOOLEAN] [True]
Whether to restrict all data before
small [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value ... DEV: for what?
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
tagRadius [INTEGER] [2]
Valid Values: 0 to INFTY
x_refine_center [REAL] [0.0]
Valid Values: Unconstrained
First coordinate of center for distance-based refinement patterns
y_refine_center [REAL] [0.0]
Valid Values: Unconstrained
Second coordinate of center for distance-based refinement patterns
z_refine_center [REAL] [0.0]
Valid Values: Unconstrained
Third coordinate of center for distance-based refinement patterns
Grid/GridMain/Chombo/UG
compute_grid_size [BOOLEAN] [true]
compute grid size in the case of non-fixed-block size, non fixed block
size mode means block dims are not specified at compile time
flux_correct [BOOLEAN] [false]
turns flux correction on or off in UG always false since all blocks on
same level
iGridSize [INTEGER] [1]
Valid Values: Unconstrained
Global number of interior cells in the i direction ONLY needed when
running in NON_FIXED_BLOCKSIZE mode (ie. don't need for Paramesh or
simple Uniform Grid)
iguard [INTEGER] [4]
Valid Values: Unconstrained
number of guardcells in i direction. Not yet in use.
jGridSize [INTEGER] [1]
Valid Values: Unconstrained
Global number of interior cells in the j direction ONLY needed when
running in NON_FIXED_BLOCKSIZE mode (ie. don't need for Paramesh or
simple Uniform Grid)
jguard [INTEGER] [4]
Valid Values: Unconstrained
number of guardcells in j direction, this is only implemented for nfbs
kGridSize [INTEGER] [1]
Valid Values: Unconstrained
Global number of interior cells in the k direction ONLY needed when
running in NON_FIXED_BLOCKSIZE mode (ie. don't need for Paramesh or
simple Uniform Grid)
kguard [INTEGER] [4]
Valid Values: Unconstrained
number of guardcells in k direction
nblockx [INTEGER] [1]
Valid Values: Unconstrained
number of blocks along X - ignored by UG Grid
nblocky [INTEGER] [1]
Valid Values: Unconstrained
number of blocks along Y - ignored by UG Grid
nblockz [INTEGER] [1]
Valid Values: Unconstrained
number of blocks along Z - ignored by UG Grid
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
Grid/GridMain/Samrai
__doc__
The Samrai Unit is not yet implemented!!!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
combineEfficiency [REAL] [0.9]
Valid Values: Unconstrained
effTolerance [REAL] [0.8]
Valid Values: Unconstrained
flux_correct [BOOLEAN] [true]
iGridSize [INTEGER] [32]
Valid Values: Unconstrained
iProcs [INTEGER] [1]
Valid Values: Unconstrained
iguard [INTEGER] [4]
Valid Values: Unconstrained
imaxPatchSize [INTEGER] [64]
Valid Values: Unconstrained
iminPatchSize [INTEGER] [1]
Valid Values: Unconstrained
jGridSize [INTEGER] [32]
Valid Values: Unconstrained
jProcs [INTEGER] [1]
Valid Values: Unconstrained
jguard [INTEGER] [4]
Valid Values: Unconstrained
jmaxPatchSize [INTEGER] [64]
Valid Values: Unconstrained
jminPatchSize [INTEGER] [1]
Valid Values: Unconstrained
kGridSize [INTEGER] [32]
Valid Values: Unconstrained
kProcs [INTEGER] [1]
Valid Values: Unconstrained
kguard [INTEGER] [4]
Valid Values: Unconstrained
kmaxPatchSize [INTEGER] [64]
Valid Values: Unconstrained
kminPatchSize [INTEGER] [1]
Valid Values: Unconstrained
maxPatches [INTEGER] [10000]
Valid Values: Unconstrained
priority_dir1 [INTEGER] [1]
Valid Values: Unconstrained
priority_dir2 [INTEGER] [2]
Valid Values: Unconstrained
refine_ratio [INTEGER] [2]
Valid Values: Unconstrained
Grid/GridMain/UG
compute_grid_size [BOOLEAN] [true]
compute grid size in the case of non-fixed-block size, non fixed block
size mode means block dims are not specified at compile time
flux_correct [BOOLEAN] [false]
turns flux correction on or off in UG always false since all blocks on
same level
iGridSize [INTEGER] [1]
Valid Values: Unconstrained
Global number of interior cells in the i direction ONLY needed when
running in NON_FIXED_BLOCKSIZE mode (ie. don't need for Paramesh or
simple Uniform Grid)
iguard [INTEGER] [6]
Valid Values: Unconstrained
number of guardcells in i direction, not yet used. Meant for nofbs.
jGridSize [INTEGER] [1]
Valid Values: Unconstrained
Global number of interior cells in the j direction ONLY needed when
running in NON_FIXED_BLOCKSIZE mode (ie. don't need for Paramesh or
simple Uniform Grid)
jguard [INTEGER] [6]
Valid Values: Unconstrained
number of guardcells in j direction, not yet used. Meant for nofbs.
kGridSize [INTEGER] [1]
Valid Values: Unconstrained
Global number of interior cells in the k direction ONLY needed when
running in NON_FIXED_BLOCKSIZE mode (ie. don't need for Paramesh or
simple Uniform Grid)
kguard [INTEGER] [6]
Valid Values: Unconstrained
number of guardcells in k direction, not yet used. Meant for nofbs.
nblockx [INTEGER] [1]
Valid Values: Unconstrained
number of blocks along X - ignored by UG Grid
nblocky [INTEGER] [1]
Valid Values: Unconstrained
number of blocks along Y - ignored by UG Grid
nblockz [INTEGER] [1]
Valid Values: Unconstrained
number of blocks along Z - ignored by UG Grid
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
Grid/GridMain/paramesh
convertToConsvdInMeshInterp [BOOLEAN] [TRUE]
indicates if appropriate variables are converted to conserved form
during propagation within the interpolation routines invoked by
Paramesh. This applies to interpolation (both "prolongation" and
"restriction") in the course of refinement, derefinement, or guardcell
filling. This is the newer way of ensuring that solution variables are
interpolated in the correct form. It avoids unnecessary conversions back
and force and should replace the old mechanism enabled by runtime
parameter "convertToConsvdForMeshCalls". However, it is only available
with PARAMESH 3 or later.
derefine_cutoff_1 [REAL] [0.2]
Valid Values: Unconstrained
threshold value to trigger derefinement for refine_var_1
derefine_cutoff_2 [REAL] [0.2]
Valid Values: Unconstrained
threshold value to trigger derefinement for refine_var_2
derefine_cutoff_3 [REAL] [0.2]
Valid Values: Unconstrained
threshold value to trigger derefinement for refine_var_3
derefine_cutoff_4 [REAL] [0.2]
Valid Values: Unconstrained
threshold value to trigger derefinement for refine_var_4
earlyBlockDistAdjustment [BOOLEAN] [TRUE]
If true, let Paramesh redistribute blocks across processors early, so
that the block distribution chosen by Paramesh will be in effect when
time evolution begins after restart. If earlyBlockDistAdjustment is
false, the block distribution enacted by the IO unit when it read a
checkpoint file will normally still be in effect when time evolution
begins after a restart. This flag is ignored if not restarting from a
checkpoint.
flux_correct [BOOLEAN] [true]
turns on or off flux correction
gr_lrefineMaxByTime [BOOLEAN] [FALSE]
This parameter activates the ability to manually specify values for
lrefine_max as a function of time. You can change the value of
lrefine_max a total of 20 times. The parameters gr_lrefmaxTime_N (where
N is a number from 1 to 20) tell FLASH the times at which lrefine_max
changes will occur. The analogous parameters gr_lrefmaxTimeValue_N
(where N is a number from 1 to 20) tell FLASH the value of lrefine_max
to use at time gr_lrefmaxTime_N. For example, specifying the following
lines in your flash.par file tells FLASH to use an lrefine_max value of
10 at t = 1.0e-09 s and a value of 11 at t = 2.0e-09 s:
gr_lrefmaxTime_1 = 1.0e-09 gr_lrefmaxTimeValue_1 = 10 gr_lrefmaxTime_2 =
2.0e-09 gr_lrefmaxTimeValue_2 = 10 . NOTE: the time values must be in
sequential order!
gr_lrefineMaxRedDoByLogR [BOOLEAN] [FALSE]
Softly force effectively a lower lrefine_max depending on distance from
center. See gr_lrefineMaxRedRadiusFact.
gr_lrefineMaxRedDoByTime [BOOLEAN] [FALSE]
Lower the effective lrefine_max as a function of time. See runtime
parameters gr_lrefineMaxRedTRef, gr_lrefineMaxRedTimeScale, and
gr_lrefineMaxRedLogBase.
gr_lrefineMaxRedLogBase [REAL] [10.0]
Valid Values: 1.0 to INFTY
Logarithm base for determining when repeated reductions in effective
lrefine_max should happen. The nth reduction will happen at
t=gr_lrefineMaxRedTRef+gr_lrefineMaxRedTimeScale*gr_lrefineMaxRedLogBase**(n-1).
gr_lrefineMaxRedRadiusFact [REAL] [0.0]
Valid Values: 0.0 to INFTY
factor that determines a minimum resolution (and thus maximum refinement
level) based on distance from a center. See x_refine_center,
y_refine_center, z_refine_center for the center coordinates. This is
approximately (linearly) equivalent to requiring a minimum *angular*
resolution, within the limits set by the global lrefine_min and
lrefine_max. Only used when gr_lrefineMaxRedDoByLogR is TRUE.
gr_lrefineMaxRedTRef [REAL] [0.0]
Valid Values: Unconstrained
reference time for time-based max level reduction. The effective
reduction of lrefine_max only kicks in for times greater than
gr_lrefineMaxRedTRef. The first time lrefine_max is effectively lowered
actually happens at t=gr_lrefineMaxRedTRef+gr_lrefineMaxRedTimeScale.
gr_lrefineMaxRedTimeScale [REAL] [1.0]
Valid Values: TINY to INFTY
the time scale for effectively lowering lrefine_max: The first reduction
takes place at t=gr_lrefineMaxRedTRef+gr_lrefineMaxRedTimeScale.
gr_lrefmaxTimeValue_1 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_10 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_11 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_12 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_13 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_14 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_15 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_16 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_17 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_18 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_19 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_2 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_20 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_3 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_4 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_5 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_6 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_7 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_8 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTimeValue_9 [INTEGER] [-1]
Valid Values: Unconstrained
gr_lrefmaxTime_1 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_10 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_11 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_12 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_13 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_14 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_15 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_16 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_17 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_18 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_19 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_2 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_20 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_3 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_4 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_5 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_6 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_7 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_8 [REAL] [-1.0]
Valid Values: Unconstrained
gr_lrefmaxTime_9 [REAL] [-1.0]
Valid Values: Unconstrained
gr_restrictAllMethod [INTEGER] [3]
Valid Values: 0 to 3
select a method to use for data restriction all the way up the tree of
blocks. This this global data restriction is usually done when
IO_output is called, before the actual writing of plot or checkpoint
data, so that non-leaf blocks in plot and checkpoint files will have
meaningful data. Data restrictions that happen as part of guard cell
filling or within multigrid solvers are not affected by this setting.
For PARAMESH 2, this runtime parameter is currently ignored. With
PARAMESH 4, the following values are recognized: 0: No restriction is
done. 1: The original method, implemented in gr_restrictTree. 2: New
method, implemented using mpi_amr_restrict_fulltree. 3: New method,
implemented using Grid_restrictByLevels.
interpol_order [INTEGER] [2]
Valid Values: 0, 1, 2
the default interpolation order when using "monotonic" interpolation
routines
lrefine_del [INTEGER] [0]
Valid Values: 0 to INFTY
Try to reduce the maximum refinement level by this number of levels on a
restart.
lrefine_max [INTEGER] [1]
Valid Values: 1 to INFTY
maximum AMR refinement level
lrefine_min [INTEGER] [1]
Valid Values: 1 to INFTY
minimum AMR refinement level
lrefine_min_init [INTEGER] [1]
Valid Values: 1 to INFTY
minimum AMR refinement level for initialization
max_particles_per_blk [INTEGER] [100]
Valid Values: Unconstrained
integer if the number of particles in a block exceeds this, it must
refine when particle count is a refinement criterion
min_particles_per_blk [INTEGER] [1]
Valid Values: Unconstrained
integer if the number of particles in a block is below this, it may
derefine when particle count is a refinement criterion
nblockx [INTEGER] [1]
Valid Values: Unconstrained
num initial blocks in x dir
nblocky [INTEGER] [1]
Valid Values: Unconstrained
num initial blocks in y dir
nblockz [INTEGER] [1]
Valid Values: Unconstrained
num initial blocks in z dir
nrefs [INTEGER] [2]
Valid Values: Unconstrained
refine/derefine AMR grid every nrefs timesteps
refine_cutoff_1 [REAL] [0.8]
Valid Values: Unconstrained
threshold value to trigger refinement for refine_var_1
refine_cutoff_2 [REAL] [0.8]
Valid Values: Unconstrained
threshold value to trigger refinement for refine_var_2
refine_cutoff_3 [REAL] [0.8]
Valid Values: Unconstrained
threshold value to trigger refinement for refine_var_3
refine_cutoff_4 [REAL] [0.8]
Valid Values: Unconstrained
threshold value to trigger refinement for refine_var_4
refine_filter_1 [REAL] [0.01]
Valid Values: Unconstrained
prevents error calculations to determine refinement from diverging
numerically for refine_var_1
refine_filter_2 [REAL] [0.01]
Valid Values: Unconstrained
prevents error calculations to determine refinement from diverging
numerically for refine_var_1
refine_filter_3 [REAL] [0.01]
Valid Values: Unconstrained
prevents error calculations to determine refinement from diverging
numerically for refine_var_3
refine_filter_4 [REAL] [0.01]
Valid Values: Unconstrained
prevents error calculations to determine refinement from diverging
numerically for refine_var_4
refine_on_particle_count [BOOLEAN] [FALSE]
if true, the count of particles in blocks act as a refinement criterion
refine_var_1 [STRING] ["none"]
Valid Values: Unconstrained
indicates 1st variable on which to refine
refine_var_2 [STRING] ["none"]
Valid Values: Unconstrained
indicates 2nd variable on which to refine
refine_var_3 [STRING] ["none"]
Valid Values: Unconstrained
indicates 3rd variable on which to refine
refine_var_4 [STRING] ["none"]
Valid Values: Unconstrained
indicates 4th variable on which to refine
refine_var_count [INTEGER] [4]
Valid Values: Unconstrained
count of maximum allowed variable to be used
small [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value ... DEV: for what?
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
x_refine_center [REAL] [0.0]
Valid Values: Unconstrained
First coordinate of center for distance-based refinement patterns
y_refine_center [REAL] [0.0]
Valid Values: Unconstrained
Second coordinate of center for distance-based refinement patterns
z_refine_center [REAL] [0.0]
Valid Values: Unconstrained
Third coordinate of center for distance-based refinement patterns
Grid/GridMain/paramesh/Paramesh2
msgbuf [INTEGER] [1]
Valid Values: Unconstrained
triggers consolication of MPI messages in PM2. 1 indicates to
"consolidate". PM2 specific, should always stay at 1
Grid/GridMain/paramesh/Paramesh2/quadratic_cartesian
grid_monotone_hack [BOOLEAN] [TRUE]
If .true., apply radical monotonicity constraints to interpolants (i.e.,
completely flatten them if they violate monotonicity)
Grid/GridMain/paramesh/paramesh4
enableMaskedGCFill [BOOLEAN] [TRUE]
When enableMaskedGCFill is FALSE, Grid_fillGuardCells is forced to
always ignore optional mask arguments when present in calls. This is the
default behavior. Set enableMaskedGCFill TRUE to enable masked guard
cell filling. It has been set to TRUE here for testing purposes.
gr_sanitizeDataMode [INTEGER] [1]
Valid Values: 0, 1, 2, 3, 4
What to do when gr_sanitizeDataAfterInterp is called to check for
acceptable values in the dens, ener, and eint cell-centered variables
after a Grid operation may have resulted in grid interpolation. 0: Do
nothing. 1: Check (if variable is not masked out) and report (see
sanitizeVerbosity). 2: Check (ignoring variable mask) and report (see
sanitizeVerbosity). 3: Check (if variable is not masked out) and fix
(apply floor value). 4: Check (if variable is not masked out) and abort
if cell is found below floor value.
gr_sanitizeVerbosity [INTEGER] [5]
Valid Values: 0, 1, 4, 5
How to write information about unacceptable values in the dens, ener,
and eint cell-centered variables if gr_sanitizeDataAfterInterp finds
value that are below the acceptable floor. This reporting is in addition
to other actions selected with gr_sanitizeDataMode=3 or 4. 0: Be quiet.
1: Only write a log file message per block if unacceptable value found
on MASTER_PE. 4: As 1, and each proc writes a line to standard output
for each block with bad values. 5: As 4, and each proc writes lines
showing the values in all cells of the block (in 1D/2D) or a 2D slice
(in 3D).
Grid/GridMain/paramesh/paramesh4/Paramesh4dev
gr_pmrpAdvanceAllLevels [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter advance_all_levels
gr_pmrpAmrErrorChecking [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter amr_error_checking
gr_pmrpCartesianPm [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter cartesian_pm This will be
adjusted by FLASH at runtime if necessary, so don't worry much.
gr_pmrpConserve [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter conserve
gr_pmrpConsvFluxDensities [BOOLEAN] [TRUE]
sets value for PARAMESH runtime parameter consv_flux_densities This will
be adjusted by FLASH at runtime if necessary, so don't worry much.
gr_pmrpConsvFluxes [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter consv_fluxes This will be
adjusted by FLASH at runtime if necessary, so don't worry much.
gr_pmrpCurvilinear [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter curvilinear. This will be
adjusted by FLASH at runtime if necessary, so don't worry much.
gr_pmrpCurvilinearConserve [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter curvilinear_conserve. This
will be adjusted by FLASH at runtime if necessary, so don't worry much.
However, if you manually set gr_pmrpCurvilinear to TRUE, you probably
should also set gr_pmrpCurvilinearConserve TRUE.
gr_pmrpCylindricalPm [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter cylindrical_pm This will be
adjusted by FLASH at runtime if necessary, so don't worry much.
gr_pmrpDiagonals [BOOLEAN] [TRUE]
sets value for PARAMESH runtime parameter diagonals
gr_pmrpDivergenceFree [INTEGER] [1]
Valid Values: -1, 0, 1
sets value for PARAMESH runtime parameter divergence_free. 0 means
FALSE, 1 means TRUE. -1 means: let FLASH determine the value based on
how it has been set up; currently that means to check whether a
preprocessor symbol DIVERGENCE_FREE is defined.
gr_pmrpEdgeValue [BOOLEAN] [TRUE]
sets value for PARAMESH runtime parameter edge_value This will be
adjusted by FLASH at runtime if necessary, so don't worry much.
gr_pmrpEdgeValueInteg [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter edge_value_integ This will be
adjusted by FLASH at runtime if necessary, so don't worry much.
gr_pmrpEmptyCells [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter empty_cells
gr_pmrpForceConsistency [BOOLEAN] [TRUE]
sets value for PARAMESH runtime parameter force_consistency
gr_pmrpIfaceOff [INTEGER] [0]
Valid Values: 0 to INFTY
sets value for PARAMESH runtime parameter iface_off
gr_pmrpL2p5d [INTEGER] [0]
Valid Values: -1, 0, 1
sets value for PARAMESH runtime parameter l2p5d. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpLsingularLine [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter lsingular_line
gr_pmrpMaxblocks [INTEGER] [-1]
Valid Values: -1, 0 to INFTY
sets value for PARAMESH runtime parameter maxblocks. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpMflags [INTEGER] [1]
Valid Values: Unconstrained
sets value for PARAMESH runtime parameter mflags
gr_pmrpNboundaries [INTEGER] [2]
Valid Values: 2 to INFTY
sets value for PARAMESH runtime parameter nboundaries
gr_pmrpNdim [INTEGER] CONSTANT [1]
Valid Values: Unconstrained
sets value for PARAMESH runtime parameter ndim.
gr_pmrpNedgevar1 [INTEGER] [-1]
Valid Values: -1, 0 to INFTY
sets value for PARAMESH runtime parameter nedgevar1. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpNfacevar [INTEGER] [-1]
Valid Values: -1, 0 to INFTY
sets value for PARAMESH runtime parameter nfacevar
gr_pmrpNfieldDivf [INTEGER] [-1]
Valid Values: -1, 0 to INFTY
sets value for PARAMESH runtime parameter nfield_divf. -1 means: let
FLASH determine the value based on how it has been set up.
gr_pmrpNfluxvar [INTEGER] [-1]
Valid Values: -1, 0 to INFTY
sets value for PARAMESH runtime parameter nfluxvar. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpNguard [INTEGER] [-1]
Valid Values: -1, 0 to INFTY
sets value for PARAMESH runtime parameter nguard. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpNguardWork [INTEGER] [-1]
Valid Values: -1, 0 to INFTY
sets value for PARAMESH runtime parameter nguard_work. -1 means: let
FLASH determine the value based on how it has been set up.
gr_pmrpNoPermanentGuardcells [BOOLEAN] [TRUE]
sets value for PARAMESH runtime parameter no_permanent_guardcells
gr_pmrpNvar [INTEGER] [-1]
Valid Values: -1, 0 to INFTY
sets value for PARAMESH runtime parameter nvar. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpNvarWork [INTEGER] [1]
Valid Values: 0 to INFTY
sets value for PARAMESH runtime parameter nvar_work
gr_pmrpNvarcorn [INTEGER] [0]
Valid Values: 0 to INFTY
sets value for PARAMESH runtime parameter nvarcorn
gr_pmrpNvaredge [INTEGER] [0]
Valid Values: 0 to INFTY
sets value for PARAMESH runtime parameter nvaredge
gr_pmrpNxb [INTEGER] [-1]
Valid Values: -1, 2, 4, 6, 8, 10, 12, 14, 16 to INFTY
sets value for PARAMESH runtime parameter nxb. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpNyb [INTEGER] [1]
Valid Values: -1, 1, 2, 4, 6, 8, 10, 12, 14, 16 to INFTY
sets value for PARAMESH runtime parameter nyb. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpNzb [INTEGER] [-1]
Valid Values: -1, 2, 4, 6, 8, 10, 12, 14, 16 to INFTY
sets value for PARAMESH runtime parameter nzb. -1 means: let FLASH
determine the value based on how it has been set up.
gr_pmrpOutputDir [STRING] ["./"]
Valid Values: Unconstrained
gr_pmrpPolarPm [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter polar_pm This will be adjusted
by FLASH at runtime if necessary, so don't worry much.
gr_pmrpPredCorr [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter pred_corr
gr_pmrpSphericalPm [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter spherical_pm This will be
adjusted by FLASH at runtime if necessary, so don't worry much.
gr_pmrpTimingMpi [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter timing_mpi
gr_pmrpTimingMpix [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter timing_mpix
gr_pmrpVarDt [BOOLEAN] [FALSE]
sets value for PARAMESH runtime parameter var_dt
Grid/GridMain/paramesh/paramesh4/Paramesh4dev/flash_avoid_orrery
use_flash_surr_blks_fill [BOOLEAN] [TRUE]
use_reduced_orrery [BOOLEAN] [TRUE]
Grid/GridParticles
gr_ptNumToReduce [INTEGER] [10]
Valid Values: Unconstrained
integer if particles are to be removed at runtime, how many
gr_ptRemove [BOOLEAN] [FALSE]
boolean. This is a switch which determines the action if the number
gr_ptRemoveAlgo [INTEGER] [2]
Valid Values: Unconstrained
integer The algorithm used in determining which particles to remove
keepLostParticles [BOOLEAN] [FALSE]
Grid/GridParticles/GridParticlesMove
gr_ptMaxPerProcBlockFactor [REAL] [0.70]
Valid Values: 0.0 to 1.0
When the effective max_particles_per_blk is lowered on a processor
because refinement criteria based on the number of particles PER
PROCESSOR are used, then the new effective max_particles_per_blk is set
to (gr_ptMaxPerProcBlockFactor * pt_maxPerProc). In addition, when the
effective min_particles_per_blk is lowered on a processor because
refinement criteria based on the number of particles PER PROCESSOR are
used, then the new effective min_particles_per_blk is set to (0.5^NDIM *
gr_ptMaxPerProcBlockFactor * pt_maxPerProc).
gr_ptMaxPerProcBlockNoFuzz [INTEGER] [3]
Valid Values: 0 to INFTY
A safety margin for estimating the size of basically unpredictable
changes of the number of blocks on a processor when remeshing happens.
gr_ptMaxPerProcLowerThresh [REAL] [0.0625]
Valid Values: 0.0 to 1.0
A threshold. When the number of particles on a processor gets above
(ptMaxPerProcLowerThresh * number of blocks on the processor), the
effective min_particles_per_blk for blocks on this processor may be
lowered.
gr_ptMaxPerProcUpperThresh [REAL] [0.25]
Valid Values: 0.0 to 1.0
A threshold. When the number of particles on a processor gets above
(ptMaxPerProcUpperThresh * number of blocks on the processor), the
effective max_particles_per_blk for blocks on this processor may be
lowered.
gr_ptNumToReduce [INTEGER] [10]
Valid Values: Unconstrained
integer if particles are to be removed at runtime, how many
gr_ptRefineOnPtMaxPerProc [BOOLEAN] [FALSE]
controls whether refinement criteria based on the number of particles
PER PROCESSOR are used. These work by strengthening refinement criteria
requested through the max_particles_per_blk and min_particles_per_blk
RPs. Requires RP refine_on_particle_count to be TRUE.
gr_ptRemove [BOOLEAN] [FALSE]
boolean. This is a switch which determines the action if the number
gr_ptRemoveAlgo [INTEGER] [2]
Valid Values: Unconstrained
integer The algorithm used in determining which particles to remove
gr_ptSieveCheckFreq [INTEGER] [1]
Valid Values: Unconstrained
integer the frequency for checking the convergence of the
Grid/GridSolvers/BHTree/Wunsch
gr_bhPhysMACComm [BOOLEAN] [FALSE]
- if true, physical MACs are used for calculation during communication
of block trees
gr_bhPhysMACTW [BOOLEAN] [FALSE]
- if true, physical MACs are used for calculation during tree walk
gr_bhTWMaxQueueSize [INTEGER] [10000]
Valid Values: 1 to INFTY
- maximum number of elements in the priority queue
gr_bhTreeLimAngle [REAL] [0.5]
Valid Values: 0 to INFTY
- limit opening angle (if only geometric MAC is used)
gr_bhTreeMaxcellmass [REAL] [1.0d99]
Valid Values: Unconstrained
For debugging: maximum mass allowed in a cell of block-trees
gr_bhTreeMincellmass [REAL] [1.0d-99]
Valid Values: Unconstrained
For debugging: minimum mass allowed in a cell of block-trees
gr_bhTreeSafeBox [REAL] [1.2]
Valid Values: -INFTY to INFTY
- relative (w.r.t. to the block size) size of a cube around each block
in which the target cell cannot be located in tree walk during
interaction of the target cell with this block
gr_bhUseUnifiedTW [BOOLEAN] [TRUE]
- if true, the unified tree walk (Barnes-Hut type) is used; otherwise,
MAC for long distance interaction (with non-leaf block) is evaluated
only once for all cells in the block
Grid/GridSolvers/BiPCGStab
bipcgs_max_cycles [INTEGER] [1000]
Valid Values: Unconstrained
bipcgs_max_residual_norm [REAL] [1.E-6]
Valid Values: Unconstrained
bipcgs_print_norm [BOOLEAN] [FALSE]
Grid/GridSolvers/HYPRE
gr_hypreAbsTol [REAL] [0.0]
Valid Values: Unconstrained
If > 0.0, directly sets a_tol (absolute tolerance) for the HYPRE
iterative solver. Convergence criteria: <= max( a_tol^2,
r_tol^2 * ). Note: default for a_tol is 0.0, so relative
residual criteria is used unless user specifies a_tol, or sets r_tol =
0.0, which means absolute tol only is checked. See also
gr_hypreSolverAutoAbsTolFact, for another way of setting a_tol.
Currently only used when gr_hypreSolverType is "HYPRE_PCG".
gr_hypreCfTol [REAL] [0.0]
Valid Values: Unconstrained
If > 0.0, enable in the iterative HYPRE solver an pptional test to see
if adequate progress is being made. The average convergence factor is
recorded and compared against the tolerance 'cf_tol'. The weighting
factor is intended to pay more attention to the test when an accurate
estimate for average convergence factor is available. Currently only
used when gr_hypreSolverType is "HYPRE_PCG". Example suggested values:
something like 0.5, 0.8, 0.9, 0.95, 0.99.
gr_hypreFloor [REAL] [1.0e-12]
Valid Values: Unconstrained
floor value for using HYPRE to advance diffusion.
gr_hypreInfoLevel [INTEGER] [1]
Valid Values: Unconstrained
: Flag to output solver specific information such as Relative Residue,
num-iterations.
gr_hypreMagFloor [REAL] [0.0]
Valid Values: Unconstrained
floor value for using HYPRE to advance magnetic diffusion.
gr_hypreMaxIter [INTEGER] [500]
Valid Values: Unconstrained
Max iterations of linear solver.
gr_hypreMaxIterMag [INTEGER] [500]
Valid Values: Unconstrained
Max iterations of linear solver for magnetic diffusion.
gr_hypreMinIter [INTEGER] [0]
Valid Values: Unconstrained
Min iterations of linear solver (only for GMRES).
gr_hyprePCType [STRING] ["HYPRE_AMG"]
Valid Values: "HYPRE_NONE", "HYPRE_ILU", "HYPRE_AMG", "HYPRE_PARASAILS",
"hypre_ilu", "hypre_amg", "hypre_parasails", "hypre_none"
gr_hyprePrintSolveInfo [BOOLEAN] [FALSE]
: Flag to output solver specific information such as Relative Residue,
num-iterations.
gr_hypreRecomputeResidual [BOOLEAN] [FALSE]
If TRUE, don't trust the convergence test until we've recomputed the
residual from scratch. This is expensive in the usual case where an the
norm is the energy norm. This calculation is coded on the assumption
that the accuracy of the residual r is only a concern for problems where
CG takes many iterations. Currently only used when gr_hypreSolverType is
"HYPRE_PCG".
gr_hypreRecomputeResidualP [INTEGER] [-1]
Valid Values: Unconstrained
If > 0, recompute the residual every gr_hypreRecomputeResidualP
iterations. Currently only used when gr_hypreSolverType is "HYPRE_PCG".
gr_hypreRelChange [BOOLEAN] [FALSE]
At user request, don't treat an approximation of the solution x in the
HYPRE iterative solver as converged unless x didn't change much in the
last iteration. Currently only used when gr_hypreSolverType is
"HYPRE_PCG".
gr_hypreRelTol [REAL] [1.0e-8]
Valid Values: Unconstrained
Relative tolerence r_tol of HYPRE linear solver.
gr_hypreRelTolMag [REAL] [1.0e-8]
Valid Values: Unconstrained
Relative tolerence r_tol of HYPRE linear solver for magnetic diffusion.
gr_hypreSlopeLimType [STRING] ["HYPRESL_MC"]
Valid Values: "HYPRESL_MC", "HYPRESL_MINMOD", "HYPRESL_VANLEER",
"HYPRESL_NONE", "hypresl_mc", "hypresl_minmod", "hypresl_vanleer",
"hypresl_none"
: Type of slope limiter to be used on transverse temperature gradients.
gr_hypreSolverAutoAbsTolFact [REAL] [0.0]
Valid Values: Unconstrained
If not 0.0, automatically set a_tol (absolute tolerance) for the HYPRE
iterative solver. If also gr_hypreAbsTol > 0, then the maximum of
gr_hypreAbsTol and the automatically determined value is taken. See
description of gr_hypreAbsTol for the use if a_tool in the HYPRE solver.
If gr_hypreSolverAutoAbsTolFact > 0, then set f =
gr_hypreSolverAutoAbsTolFact. If gr_hypreSolverAutoAbsTolFact < 0, then
set f = |gr_hypreSolverAutoAbsTolFact|*gr_hypreRelTol. In either case,
the automatically determined value for a_tol is
f*sqrt(). Here is a rough
estimate of the smallest possible value of the inverse of the diagonal
part of the matrix C representing the preconditioner. In that estimate,
bfloor is a vector that represents a worst-case tolerable error in b
(the RHS of the equation to be solved, A*x=b). Currently, bfloor is set
to a vector whose every element is set to gr_hypreFloor. If
gr_hypreAbsTol > 0 in addition to gr_hypreSolverAutoAbsTolFact .ne. 0.0,
then the maximum of gr_hypreAbsTol and the automatically determined
value is taken. Currently only used when gr_hypreSolverType is
"HYPRE_PCG".
gr_hypreSolverType [STRING] ["HYPRE_PCG"]
Valid Values: "HYPRE_PCG", "HYPRE_AMG", "HYPRE_GMRES", "HYPRE_BICGSTAB",
"HYPRE_SPLIT", "hypre_pcg", "hypre_amg", "hypre_gmres",
"hypre_bicgstab", "hypre_split"
: Type of HYPRE solver to be used.
gr_hypreUse2Norm [BOOLEAN] [FALSE]
whether to use L2 norm for exit condition in iterative solver (instead
of L1 norm). Currently only used when gr_hypreSolverType is "HYPRE_PCG".
gr_hypreUseFloor [BOOLEAN] [TRUE]
whether to apply gr_hypreFloor to floor results from HYPRE. Should
probably be TRUE when using HYPRE to advance diffusion, FALSE otherwise.
However, flooring will always be turned off when using the HYPRE
implementation of Grid_solvePoisson, independent of the value of the
gr_hypreUseFloor runtime parameter.
gr_hypreUseMagFloor [BOOLEAN] [FALSE]
whether to apply gr_hypreMagFloor to floor results from HYPRE (magnetic
diffusion).
useMagHarmonicAvg [BOOLEAN] [FALSE]
Flag to use harmonic average of resistivity at cell faces.
useViscHarmonicAvg [BOOLEAN] [FALSE]
Flag to use harmonic average of resistivity at cell faces.
Grid/GridSolvers/HYPRE/Unified
gr_hypreMagZ_AbsTol [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreMagZ_CfTol [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreMagZ_Floor [REAL] [1.0e-12]
Valid Values: Unconstrained
gr_hypreMagZ_FloorType [INTEGER] [0]
Valid Values: Unconstrained
gr_hypreMagZ_InfoLevel [INTEGER] [1]
Valid Values: Unconstrained
gr_hypreMagZ_MaxIter [INTEGER] [500]
Valid Values: Unconstrained
gr_hypreMagZ_MinIter [INTEGER] [0]
Valid Values: Unconstrained
gr_hypreMagZ_PCType [STRING] ["HYPRE_AMG"]
Valid Values: "HYPRE_NONE", "HYPRE_ILU", "HYPRE_AMG", "HYPRE_PARASAILS",
"hypre_ilu", "hypre_amg", "hypre_parasails", "hypre_none"
gr_hypreMagZ_PrintSolveInfo [BOOLEAN] [FALSE]
gr_hypreMagZ_RecomputeResidual [BOOLEAN] [FALSE]
gr_hypreMagZ_RecomputeResidualP [INTEGER] [-1]
Valid Values: Unconstrained
gr_hypreMagZ_RelChange [BOOLEAN] [FALSE]
gr_hypreMagZ_RelTol [REAL] [1.e-10]
Valid Values: Unconstrained
gr_hypreMagZ_SlopeLimType [STRING] ["HYPRESL_MC"]
Valid Values: "HYPRESL_MC", "HYPRESL_MINMOD", "HYPRESL_VANLEER",
"HYPRESL_NONE", "hypresl_mc", "hypresl_minmod", "hypresl_vanleer",
"hypresl_none"
gr_hypreMagZ_SolverAutoAbsTolFact [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreMagZ_SolverType [STRING] ["HYPRE_GMRES"]
Valid Values: "HYPRE_PCG", "HYPRE_AMG", "HYPRE_GMRES", "HYPRE_BICGSTAB",
"HYPRE_SPLIT", "hypre_pcg", "hypre_amg", "hypre_gmres",
"hypre_bicgstab", "hypre_split"
gr_hypreMagZ_Use2Norm [BOOLEAN] [FALSE]
gr_hypreMag_AbsTol [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreMag_CfTol [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreMag_Floor [REAL] [1.0e-12]
Valid Values: Unconstrained
gr_hypreMag_FloorType [INTEGER] [0]
Valid Values: Unconstrained
gr_hypreMag_InfoLevel [INTEGER] [1]
Valid Values: Unconstrained
gr_hypreMag_MaxIter [INTEGER] [500]
Valid Values: Unconstrained
gr_hypreMag_MinIter [INTEGER] [0]
Valid Values: Unconstrained
gr_hypreMag_PCType [STRING] ["HYPRE_AMG"]
Valid Values: "HYPRE_NONE", "HYPRE_ILU", "HYPRE_AMG", "HYPRE_PARASAILS",
"hypre_ilu", "hypre_amg", "hypre_parasails", "hypre_none"
gr_hypreMag_PrintSolveInfo [BOOLEAN] [FALSE]
gr_hypreMag_RecomputeResidual [BOOLEAN] [FALSE]
gr_hypreMag_RecomputeResidualP [INTEGER] [-1]
Valid Values: Unconstrained
gr_hypreMag_RelChange [BOOLEAN] [FALSE]
gr_hypreMag_RelTol [REAL] [1.e-10]
Valid Values: Unconstrained
gr_hypreMag_SlopeLimType [STRING] ["HYPRESL_MC"]
Valid Values: "HYPRESL_MC", "HYPRESL_MINMOD", "HYPRESL_VANLEER",
"HYPRESL_NONE", "hypresl_mc", "hypresl_minmod", "hypresl_vanleer",
"hypresl_none"
gr_hypreMag_SolverAutoAbsTolFact [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreMag_SolverType [STRING] ["HYPRE_GMRES"]
Valid Values: "HYPRE_PCG", "HYPRE_AMG", "HYPRE_GMRES", "HYPRE_BICGSTAB",
"HYPRE_SPLIT", "hypre_pcg", "hypre_amg", "hypre_gmres",
"hypre_bicgstab", "hypre_split"
gr_hypreMag_Use2Norm [BOOLEAN] [FALSE]
gr_hypreViscosity_AbsTol [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreViscosity_CfTol [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreViscosity_Floor [REAL] [1.0e-12]
Valid Values: Unconstrained
gr_hypreViscosity_FloorType [INTEGER] [0]
Valid Values: Unconstrained
gr_hypreViscosity_InfoLevel [INTEGER] [1]
Valid Values: Unconstrained
gr_hypreViscosity_MaxIter [INTEGER] [500]
Valid Values: Unconstrained
gr_hypreViscosity_MinIter [INTEGER] [0]
Valid Values: Unconstrained
gr_hypreViscosity_PCType [STRING] ["HYPRE_AMG"]
Valid Values: "HYPRE_NONE", "HYPRE_ILU", "HYPRE_AMG", "HYPRE_PARASAILS",
"hypre_ilu", "hypre_amg", "hypre_parasails", "hypre_none"
gr_hypreViscosity_PrintSolveInfo [BOOLEAN] [FALSE]
gr_hypreViscosity_RecomputeResidual [BOOLEAN] [FALSE]
gr_hypreViscosity_RecomputeResidualP [INTEGER] [-1]
Valid Values: Unconstrained
gr_hypreViscosity_RelChange [BOOLEAN] [FALSE]
gr_hypreViscosity_RelTol [REAL] [1.0e-8]
Valid Values: Unconstrained
gr_hypreViscosity_SlopeLimType [STRING] ["HYPRESL_MC"]
Valid Values: "HYPRESL_MC", "HYPRESL_MINMOD", "HYPRESL_VANLEER",
"HYPRESL_NONE", "hypresl_mc", "hypresl_minmod", "hypresl_vanleer",
"hypresl_none"
gr_hypreViscosity_SolverAutoAbsTolFact [REAL] [0.0]
Valid Values: Unconstrained
gr_hypreViscosity_SolverType [STRING] ["HYPRE_PCG"]
Valid Values: "HYPRE_PCG", "HYPRE_AMG", "HYPRE_GMRES", "HYPRE_BICGSTAB",
"HYPRE_SPLIT", "hypre_pcg", "hypre_amg", "hypre_gmres",
"hypre_bicgstab", "hypre_split"
gr_hypreViscosity_Use2Norm [BOOLEAN] [FALSE]
Grid/GridSolvers/IsoBndMultipole
mpole_lmax [INTEGER] [0]
Valid Values: Unconstrained
Maximum multipole moment to use
octant [BOOLEAN] [false]
In 3d cartesian geometry, assume symmetry about left-facing volume faces
quadrant [BOOLEAN] [false]
In 2d cylindrical coords, assume symmetry about grid bottom to evolve a
quadrant
Grid/GridSolvers/Multigrid
mg_maxCorrections [INTEGER] [100]
Valid Values: Unconstrained
Maximum number of correction V-cycles to employ.
mg_maxResidualNorm [REAL] [1.E-6]
Valid Values: Unconstrained
Apply V-cycle corrections until this residual norm is reached or
mg_maxCorrections V-cycles have been performed.
mg_printNorm [BOOLEAN] [TRUE]
If .true., print the ratio of the residual norm to the source norm as
each V-cycle is completed.
quadrant [BOOLEAN] [false]
True if only one quadrant is being calculated in 2-d cylindrical
coordinates
Grid/GridSolvers/Multigrid/PfftTopLevelSolve
maxDirectSolveLevel [INTEGER] [9999]
Valid Values: 1 to 9999
Level that will be used to perform direct FFT solve.
xl_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower (left) boundary condition in x dir
xr_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper (right) boundary condition in x dir
yl_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower boundary condition in y dir
yr_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper boundary condition in y dir
zl_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower boundary condition in z dir
zr_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper boundary condition in z dir
Grid/GridSolvers/MultigridMC
gr_mgDiffOpDiscretize [INTEGER] [2]
Valid Values: 2, 4
Spatial Differential operator discretization: gr_mgDiffOpDiscretize=2
for 2nd order central; gr_mgDiffOpDiscretize=4 for 4th order central.
Grid/GridSolvers/MultigridMC/poisson
mgrid_max_iter_change [REAL] [1.E-3]
Valid Values: Unconstrained
Maximum change in the norm of the residual from one iteration to the
next
mgrid_max_residual_norm [REAL] [1.E-6]
Valid Values: Unconstrained
Maximum ratio of the norm of the residual to that of the right-hand side
mgrid_max_vcycles [INTEGER] [100]
Valid Values: Unconstrained
Maximum number of V-cycles to take
mgrid_npossmooth [INTEGER] [8]
Valid Values: Unconstrained
mgrid_npresmooth [INTEGER] [2]
Valid Values: Unconstrained
mgrid_print_norm [BOOLEAN] [FALSE]
If .true., print residual norm to stdout after each V-cycle
mgrid_smooth_tol [REAL] [1.E-10]
Valid Values: Unconstrained
Convergence criterion for the smoother
mgrid_smoother [INTEGER] [1]
Valid Values: 1, 2
Type of smoother, either RBGS=1 or ZEBRA=2.
mgrid_solve_max_iter [INTEGER] [5000]
Valid Values: Unconstrained
Maximum number of iterations for solution on
quadrant [BOOLEAN] [FALSE]
In 2d cylindrical coords, assume symmetry about the y=0 axis to evolve a
quadrant
Grid/GridSolvers/MultigridMC/poisson/PfftTopLevelSolve
maxDirectSolveLevel [INTEGER] [9999]
Valid Values: 1 to 9999
Level that will be used to perform direct FFT solve.
xl_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower (left) boundary condition in x dir
xr_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper (right) boundary condition in x dir
yl_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower boundary condition in y dir
yr_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper boundary condition in y dir
zl_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
lower boundary condition in z dir
zr_mg_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
upper boundary condition in z dir
Grid/GridSolvers/Multipole
mpole_3daxisymmetric [BOOLEAN] [false]
In 3d cartesian geometry, use only m=0 multipole moments
mpole_dumpMoments [BOOLEAN] [false]
Should the Moment array be dumped at each timestep?
mpole_lmax [INTEGER] [0]
Valid Values: Unconstrained
Maximum multipole moment to use
mpole_r12 [REAL] [0.0]
Valid Values: Unconstrained
mpole_r23 [REAL] [1.0]
Valid Values: Unconstrained
mpole_rscale1 [REAL] [1.0]
Valid Values: Unconstrained
mpole_rscale2 [REAL] [1.0]
Valid Values: Unconstrained
mpole_rscale3 [REAL] [1.0]
Valid Values: Unconstrained
mpole_scaleType1 [INTEGER] [1]
Valid Values: Unconstrained
mpole_scaleType2 [INTEGER] [1]
Valid Values: Unconstrained
mpole_scaleType3 [INTEGER] [1]
Valid Values: Unconstrained
mpole_subSample [INTEGER] [1]
Valid Values: 1 to 12
Integer which controls the sub-sampling in the mpole_potential routine
and mpole_moments routine. Set to smaller numbers to make potential
calculations (slightly) less smooth and faster. Was hardcoded in Flash2
as Nint6 = 6 in mpole_potential and Nint=2 in mpole_moments Defines the
3 zones (r12,r23 are fractions of rMax) Scaling factor for each zones.
Scaling Type for each of the regions, can be Constant, Logarthmic
mpole_useMatrixMPI [BOOLEAN] [false]
Switch added during the DAT to calculate MPI_allreduce in a matrix
fashion & Set to .false. to retain the previous behaviour
octant [BOOLEAN] [false]
In 3d cartesian geometry, assume symmetry about left-facing volume faces
quadrant [BOOLEAN] [false]
In 2d cylindrical coords, assume symmetry about grid bottom to evolve a
quadrant
Grid/GridSolvers/Multipole_new
mpole_2DSymmetryPlane [BOOLEAN] [false]
In 2D coordinates, assume a plane of symmetry at the grid bottom. Can be
used for symmetrical problems to reduce computational domain.
mpole_3DAxisymmetry [BOOLEAN] [false]
Assumes rotational invariance around the main (z) axis in 3D cartesian
geometry domains, even if this holds only approximately. In effect it
uses only M=0 multipole moments.
mpole_DumpMoments [BOOLEAN] [false]
Should the Moment array be dumped at each timestep? Use this option only
with care, as the moments will be printed for each radial bin.
mpole_IgnoreInnerZone [BOOLEAN] [false]
If this is set .true., the inner zone will not be recognized and all
inner zone radii will be treated statistically. This can be used only if
Lmax is sufficiently low.
mpole_InnerZoneResolution [REAL] [0.1]
Valid Values: 0.0 to INFTY
The resolution spacing for the inner zone in units of the inner zone
atomic radius. Two inner zone radii will be considered different if they
are more than the resolution spacing apart. A very tiny number will
result in a complete separation of all inner zone radii into separate
bins. However, the resolution cannot be set to exactly zero, because its
inverse value needs to be calculated at some point in the code.
mpole_InnerZoneSize [INTEGER] [16]
Valid Values: 1 to INFTY
The size (radius) defining the inner zone in terms of the inner zone
atomic radius. This value needs to be an integer, as it will be used to
define dimensions of certain arrays.
mpole_Lmax [INTEGER] [0]
Valid Values: 0 to INFTY
Maximum multipole moment to use
mpole_MaxRadialZones [INTEGER] [1]
Valid Values: 1 to INFTY
The maximum number of radial zones to be used
mpole_MultiThreading [BOOLEAN] [true]
If set .true., the code will run in multithreaded mode
mpole_PrintRadialInfo [BOOLEAN] [false]
Should the Multipole solver print out detailed radial bin information at
each timestep?
mpole_ZoneExponent_1 [REAL] [1.0]
Valid Values: -INFTY to INFTY
The exponent value 't' in the radial equation r(Q) = s * dr * Q^t or the
radial equation r(Q) = s * dr * (e^(Qt)-1)/(e^t-1), defining the maximum
radius of the Q-th radial bin for the 1st zone.
mpole_ZoneExponent_2 [REAL] [1.0]
Valid Values: -INFTY to INFTY
Idem for the 2nd radial zone.
mpole_ZoneExponent_3 [REAL] [1.0]
Valid Values: -INFTY to INFTY
Idem for the 3rd radial zone.
mpole_ZoneExponent_4 [REAL] [1.0]
Valid Values: -INFTY to INFTY
Idem for the 4th radial zone.
mpole_ZoneRadiusFraction_1 [REAL] [1.0]
Valid Values: 0.0 to 1.0
The fraction of the maximum radius defining the 1st radial zone limit.
The total number of fractions given must match the maximum number of
radial zones specified and the fractions must be in increasing order and
less than 1. as we move from the 1st zone upwards. The last zone must
always have a fraction of exactly 1. If not, the code will enforce it.
mpole_ZoneRadiusFraction_2 [REAL] [1.0]
Valid Values: 0.0 to 1.0
Idem for the 2nd radial zone.
mpole_ZoneRadiusFraction_3 [REAL] [1.0]
Valid Values: 0.0 to 1.0
Idem for the 3rd radial zone.
mpole_ZoneRadiusFraction_4 [REAL] [1.0]
Valid Values: 0.0 to 1.0
Idem for the 4th radial zone.
mpole_ZoneScalar_1 [REAL] [1.0]
Valid Values: 0.0 to INFTY
The scalar value 's' in the radial equation r(Q) = s * dr * Q^t or the
radial equation r(Q) = s * dr * (e^(Qt)-1)/(e^t-1), defining the maximum
radius of the Q-th radial bin for the 1st zone.
mpole_ZoneScalar_2 [REAL] [1.0]
Valid Values: 0.0 to INFTY
Idem for the 2nd radial zone.
mpole_ZoneScalar_3 [REAL] [1.0]
Valid Values: 0.0 to INFTY
Idem for the 3rd radial zone.
mpole_ZoneScalar_4 [REAL] [1.0]
Valid Values: 0.0 to INFTY
Idem for the 4th radial zone.
mpole_ZoneType_1 [STRING] ["exponential"]
Valid Values: Unconstrained
String value containing the zone type for the 1st zone. If set to
'exponential' then the radial equation r(Q) = s * dr * Q^t is used. If
set to 'logarithmic' the radial equation r(Q) = s * dr *
(e^(Qt)-1)/(e^t-1) is used.
mpole_ZoneType_2 [STRING] ["exponential"]
Valid Values: Unconstrained
Idem for the 2nd radial zone.
mpole_ZoneType_3 [STRING] ["exponential"]
Valid Values: Unconstrained
Idem for the 3rd radial zone.
mpole_ZoneType_4 [STRING] ["logarithmic"]
Valid Values: Unconstrained
Idem for the 4th radial zone.
Grid/GridSolvers/Pfft
gr_pfftDiffOpDiscretize [INTEGER] [1]
Valid Values: 1, 2
specifies the approach for discretizing the Laplacian differential
operator: 2 for second-order finite difference approximation, 1 for
spectral. This choice is ignored by solver implementations that have
one approach hardwired. Currently the HomBcTrigSolver and
SimplePeriodicSolver implementations honor this runtime parameter.
pfft_setupOnce [BOOLEAN] [TRUE]
This parameter tells Pfft whether it should retain trig tables and other
mapping information for the entire simulation or not
Grid/GridSolvers/unitTest
gr_testTolL2 [REAL] [1.E-10]
Valid Values: 0.0 to INFTY
Maximum L2 error norm that is tolerable
gr_testTolLinf [REAL] [1.E-10]
Valid Values: 0.0 to INFTY
Maximum Linf error norm that is tolerable
Grid/GridStructures
sb_NumBodies [INTEGER] [1]
Valid Values: Unconstrained
sb_debug [BOOLEAN] [False]
sb_ptNumX [INTEGER] [1]
Valid Values: Unconstrained
sb_ptNumY [INTEGER] [1]
Valid Values: Unconstrained
sb_ptNumZ [INTEGER] [1]
Valid Values: Unconstrained
IO/IOMain
alwaysComputeUserVars [BOOLEAN] [true]
Allows the user to force the computation of user variables (i.e. those
computed by Grid_computeUserVars) for all checkpoint files. Defaults to
true. If set to false, lone calls to IO_writeCheckpoint will not call
Grid_computeUserVars. Plotfiles always call Grid_computeUserVars.
alwaysRestrictCheckpoint [BOOLEAN] [true]
Allows the user to choose whether checkpoint file data is always
restricted, so all ancestor blocks have valid data. The default is true.
It can be set to false for debugging purposes, in which case only the
data from IO_output will be guaranteed to have fully restricted data.
See the User's guide for more information.
appendParRestart [BOOLEAN] [FALSE]
If true, append flash.par with parameters for restart
basenm [STRING] ["flash_"]
Valid Values: Unconstrained
Base name for checkpoint files
checkpointFileIntervalStep [INTEGER] [0]
Valid Values: Unconstrained
Checkpoint after this many steps
checkpointFileIntervalTime [REAL] [1.]
Valid Values: Unconstrained
Checkpoint after this much time
checkpointFileIntervalZ [REAL] [HUGE(1.)]
Valid Values: Unconstrained
checkpointFileNumber [INTEGER] [0]
Valid Values: Unconstrained
Initial checkpoint file number (used for restarts as well)
chkGuardCellsInput [BOOLEAN] CONSTANT [FALSE]
if true guardcells are read from the checkpoint file. Default is false
where only interior cells are read. Currently only implemented with hdf5
parallel paramesh IO implementation
chkGuardCellsOutput [BOOLEAN] CONSTANT [FALSE]
if true guardcells are written the checkpoint file. Default is false
where only interior cells are written. Currently only implemented with
hdf5 parallel paramesh IO implementation
corners [BOOLEAN] [FALSE]
does nothing. However, it is part of the checkpoint file specification,
so we retain the checkpoint entry, but force it to be .false.. It was
used in FLASH2 to interpolate the data to the zone corners before
storing the data in the plotfile (for creating improved iso-surfaces).
fileFormatVersion [INTEGER] [9]
Valid Values: Unconstrained
Integer value specifying the file format type
forcedPlotFileNumber [INTEGER] [0]
Valid Values: Unconstrained
ignoreForcedPlot [BOOLEAN] [false]
io_writeMscalarIntegrals [BOOLEAN] [FALSE]
Should density integrals for all mass scalars be written to the
stats_file (.dat file)? This runtime parameter is handled in the
default IO_writeIntegralQuantities implementation in IOMain, and may
have no effect if a simulation overrides that implementation.
memory_stat_freq [INTEGER] [100000]
Valid Values: Unconstrained
Specify the number of timesteps between memory statistic dumps to
flash.log !!NOT Yet Implemented in F3
outputSplitNum [INTEGER] [1]
Valid Values: Unconstrained
Split checkpoint, plotfiles, particle plots into this many files per
dump Not fully implemented, only hdf5 parallel. use at own risk
output_directory [STRING] [""]
Valid Values: Unconstrained
output dir for checkpoint file, can be absolute or relative path
plotFileIntervalStep [INTEGER] [0]
Valid Values: Unconstrained
Write a plotfile after this many steps
plotFileIntervalTime [REAL] [1.]
Valid Values: Unconstrained
Write a plotfile after this much time
plotFileIntervalZ [REAL] [HUGE(1.)]
Valid Values: Unconstrained
Write a plotfile after this change in z
plotFileNumber [INTEGER] [0]
Valid Values: Unconstrained
Initial plot file number
plot_grid_var_1 [STRING] ["none"]
Valid Values: Unconstrained
Allows user to output specific scratch grid vars Up to 12 choices are
allowed. If plot_grid_var_X is set to "none" then no variable will be
saved. The parameter should have the same name as the variable
corresponding to it. For exampe, if a variable is declared GRID_VAR
vrtz, to write that grid variable to a plotfile a parameter should be
declared as PARAMETER plot_grid_var_X STRING "vrtz"
plot_grid_var_10 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_11 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_12 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_2 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_3 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_4 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_5 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_6 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_7 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_8 [STRING] ["none"]
Valid Values: Unconstrained
plot_grid_var_9 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_1 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_10 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_11 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_12 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_2 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_3 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_4 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_5 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_6 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_7 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_8 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_9 [STRING] ["none"]
Valid Values: Unconstrained
plot_var_, for N=1..MAX_PLOT_VARS [STRING] ["none"]
Valid Values: Unconstrained
(automatically generated by setup)
plotfileGridQuantityDP [BOOLEAN] [false]
If true, this sets the grid variables (unk, facevars, etc.) to be output
in double precision in plotfiles. Default value is false.
plotfileMetadataDP [BOOLEAN] [false]
Sets the floating point grid metadata fields to be written in double
precision if true in plotfiles. Default value is false
prof_file [STRING] ["profile.dat"]
Valid Values: Unconstrained
!!NOT yet implemented yet in F3
rolling_checkpoint [INTEGER] [10000]
Valid Values: Unconstrained
Checkpoint file number cycling span. Only the last rolling_checkpoint
files are kept.
rss_limit [REAL] [-1.0]
Valid Values: Unconstrained
Maximum value (in MB) of largest resident set size (rss) before we
checkpoint and exit. Negative for no limit. Only active if memory
statistics are being kept.
stats_file [STRING] ["flash.dat"]
Valid Values: Unconstrained
Name of the file integral quantities are written to (.dat file)
summaryOutputOnly [BOOLEAN] [false]
Makes FLASH write integrated quantities, i.e. summary data, only. FLASH
will only write a checkpoint, plot, or particle file if the user creates
a .dump_plotfile, .dump_checkpoint, .dump_restart, or
.dump_particle_file file. A .kill file will still kill FLASH.
typeMatchedXfer [BOOLEAN] [true]
Ensures that floating point data transfers are type matched when using
HDF5. This prevents HDF5 reverting to independent parallel I/O.
useCollectiveHDF5 [BOOLEAN] [true]
If true, all non-header, non-list datasets will be written using HDF5's
collective output mode otherwise, the independent access mode is used.
Default value is true.
useLegacyLabels [BOOLEAN] [true]
If true, this stores mesh labels e.g. 'dens', 'pres' in a IO library
dataspace of 4 characters. We may want to set it to false to use larger
labels e.g. 'density'
wall_clock_checkpoint [REAL] [43200.]
Valid Values: Unconstrained
Checkpoint after XX seconds (wallclock time) This is useful to ensure
that the job outputs a restart file before a queue window closes.
wr_integrals_freq [INTEGER] [1]
Valid Values: Unconstrained
Number of timesteps between writing to flash.dat
IO/IOMain/hdf5/parallel/PM
chkGuardCellsInput [BOOLEAN] [false]
if true guardcells are read from the checkpoint file. Default is false
where only interior cells are read. Currently only implemented with hdf5
parallel paramesh IO implementation.
chkGuardCellsOutput [BOOLEAN] [false]
if true guardcells are written the checkpoint file. Default is false
where only interior cells are written. Currently only implemented with
hdf5 parallel paramesh IO implementation.
IO/IOMain/hdf5/parallel/PM_argonne
packMeshChkReadHDF5 [BOOLEAN] [false]
packMeshChkWriteHDF5 [BOOLEAN] [false]
packMeshPlotWriteHDF5 [BOOLEAN] [true]
If true, this specifies that we pack the
IO/IOMain/pnetcdf/typeSelection
asyncMeshChkReadPnet [BOOLEAN] [false]
asyncMeshChkWritePnet [BOOLEAN] [false]
asyncMeshPlotWritePnet [BOOLEAN] [false]
If true, this uses non blocking I/O writes
IO/IOParticles
particleFileIntervalStep [INTEGER] [0]
Valid Values: Unconstrained
write a particle file after this many steps
particleFileIntervalTime [REAL] [1.]
Valid Values: Unconstrained
Write a particle plot after this much time
particleFileIntervalZ [REAL] [HUGE(1.)]
Valid Values: Unconstrained
write a particle file after this change in redshift
particleFileNumber [INTEGER] [0]
Valid Values: Unconstrained
Initial particle plot file number
writeParticleAll [BOOLEAN] [true]
Write the complete particles array to a particle file.
writeParticleSubset [BOOLEAN] [false]
Write user-defined subset(s) of the particles array to
Particles
useParticles [BOOLEAN] [FALSE]
Whether to advance particles [TRUE] or not [FALSE]
Particles/ParticlesInitialization
pt_resetTag [BOOLEAN] [FALSE]
Particles/ParticlesInitialization/Lattice
__doc__
Lattice uniformly distributes the particles throughout physical domain
pt_initialRadius [REAL] [-1.0]
Valid Values: Unconstrained
maximum distance from center of domain for particle initialization -- by
default = -1.0 (i.e. no minimum)
pt_initialXMax [REAL] [1.0]
Valid Values: Unconstrained
maximum value in x for particle initialization -- by default = xmax
pt_initialXMin [REAL] [0.0]
Valid Values: Unconstrained
minimum value in x for particle initialization -- by default = xmin
pt_initialYMax [REAL] [1.0]
Valid Values: Unconstrained
maximum value in y for particle initialization -- by default = ymax
pt_initialYMin [REAL] [0.0]
Valid Values: Unconstrained
minimum value in y for particle initialization -- by default = ymin
pt_initialZMax [REAL] [1.0]
Valid Values: Unconstrained
maximum value in z for particle initialization -- by default = zmax
pt_initialZMin [REAL] [0.0]
Valid Values: Unconstrained
minimum value in z for particle initialization -- by default = zmin
pt_numX [INTEGER] [1]
Valid Values: Unconstrained
pt_numY [INTEGER] [1]
Valid Values: Unconstrained
pt_numZ [INTEGER] [1]
Valid Values: Unconstrained
Particles/ParticlesInitialization/WithDensity
pt_numParticlesWanted [INTEGER] [100]
Valid Values: Unconstrained
Number of tracer particles to use (not guaranteed to get exactly this
many)
pt_pRand [INTEGER] [1]
Valid Values: Unconstrained
A number which affects the initial seed for the random number generator.
We set the default value to 1 to make it more likely that the initial
seed is within the integer range given by the IBM XL documentation which
is "A valid seed must be a whole number between 1.0 and 2147483647.0
(2.0**31-1)", as long as the number of MPI tasks is less than that
value.
Particles/ParticlesInitialization/WithDensity/RejectionMethod
__doc__
This is completely untested, don't use without further work
Particles/ParticlesMain
particle_attribute_1 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_10 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_2 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_3 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_4 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_5 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_6 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_7 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_8 [STRING] ["none"]
Valid Values: Unconstrained
particle_attribute_9 [STRING] ["none"]
Valid Values: Unconstrained
pt_dtChangeTolerance [REAL] [0.4]
Valid Values: 0.0 to INFTY
EstiMidpoint does predictor step if time step change is less than this
percentage. Set to 0 to always do Euler, set to huge number to always
use estim. midpoints
pt_dtFactor [REAL] [0.5]
Valid Values: Unconstrained
Factor multiplying dx/|v| in setting particle timestep limit
pt_logLevel [INTEGER] [700]
Valid Values: 0 to INFTY
controls the level of logging for some conditions. See Particles.h for
relevant PT_LOGLEVEL_* definitions.
pt_maxPerProc [INTEGER] [1000]
Valid Values: Unconstrained
Maximum number of particles per processor -- too small will cause a
crash at reallocation
pt_numAtOnce [INTEGER] [1]
Valid Values: Unconstrained
To be used when reading the particles from some file
pt_small [REAL] [1.0E-10]
Valid Values: Unconstrained
If velocities are greater than this, then time stepping may be limited
useParticles [BOOLEAN] [TRUE]
Whether to advance particles [TRUE] or not [FALSE]
Particles/ParticlesMain/active/DPD
pt_dpdLambda [REAL] [0.65]
Valid Values: Unconstrained
pt_dpdUpdateCycle [INTEGER] [1]
Valid Values: Unconstrained
Particles/ParticlesMain/active/Sink
jeans_ncells_deref [REAL] [64.0]
Valid Values: Unconstrained
jeans_ncells_ref [REAL] [32.0]
Valid Values: Unconstrained
refineOnJeansLength [BOOLEAN] [TRUE]
refineOnSinkParticles [BOOLEAN] [TRUE]
sink_AdvanceSerialComputation [BOOLEAN] [TRUE]
sink_EwaldFieldNx [INTEGER] [64]
Valid Values: Unconstrained
number of x cells in Ewald correction field
sink_EwaldFieldNy [INTEGER] [64]
Valid Values: Unconstrained
number of y cells in Ewald correction field
sink_EwaldFieldNz [INTEGER] [64]
Valid Values: Unconstrained
number of z cells in Ewald correction field
sink_EwaldFileName [STRING] ["sink_ewald.txt"]
Valid Values: Unconstrained
Filename for storing the Ewald field (used on restart)
sink_EwaldSeriesN [INTEGER] [5]
Valid Values: Unconstrained
Ewald series max integer n, h
sink_GasAccretionChecks [BOOLEAN] [TRUE]
sink_accretion_radius [REAL] [1.0e14]
Valid Values: Unconstrained
accretion radius of sink particle
sink_convergingFlowCheck [BOOLEAN] [TRUE]
sink_density_thresh [REAL] [1.0e-14]
Valid Values: Unconstrained
density threshold for sink creation and accretion
sink_dt_factor [REAL] [0.5]
Valid Values: Unconstrained
glocal timestep safety factor for sinks
sink_integrator [STRING] ["leapfrog"]
Valid Values: Unconstrained
time step integrator (euler, leapfrog)
sink_jeansCheck [BOOLEAN] [TRUE]
sink_maxSinks [INTEGER] [1024]
Valid Values: Unconstrained
maximum number of sink particles
sink_merging [BOOLEAN] [FALSE]
activate/deactivate sink particle merging
sink_negativeEtotCheck [BOOLEAN] [TRUE]
sink_offDomainSupport [BOOLEAN] [FALSE]
sink_potentialMinCheck [BOOLEAN] [TRUE]
sink_softening_radius [REAL] [1.0e14]
Valid Values: Unconstrained
gravitational softening radius
sink_softening_type_gas [STRING] ["linear"]
Valid Values: Unconstrained
gravitational softening gas--sinks
sink_softening_type_sinks [STRING] ["spline"]
Valid Values: Unconstrained
gravitational softening sinks--sinks
sink_subdt_factor [REAL] [0.01]
Valid Values: Unconstrained
timestep safety factor for subcycling
useSinkParticles [BOOLEAN] [FALSE]
switch sink particles on/off
Particles/ParticlesMain/active/charged/HybridPIC
pt_picCdensMin [REAL] [0.0]
Valid Values: Unconstrained
Minimum charge density as a fraction of the initial
pt_picGam [REAL] [-1.0]
Valid Values: Unconstrained
Adiabatic exponent for electrons
pt_picNsub [INTEGER] [3]
Valid Values: Unconstrained
number of B-field update subcycles (must be odd)
pt_picPcharge_1 [REAL] [1.0]
Valid Values: Unconstrained
Charge of particle species 1 [e]
pt_picPcharge_2 [REAL] [1.0]
Valid Values: Unconstrained
Charge of particle species 2 [e]
pt_picPdensity_1 [REAL] [1.0]
Valid Values: 0 to INFTY
Initial number density for particle species 1 [m^-3]
pt_picPdensity_2 [REAL] [0.0]
Valid Values: 0 to INFTY
Initial number density for particle species 2 [m^-3]
pt_picPmass_1 [REAL] [1.0]
Valid Values: 0 to INFTY
Mass of particle species 1 [amu]
pt_picPmass_2 [REAL] [1.0]
Valid Values: 0 to INFTY
Mass of particle species 2 [amu]
pt_picPname_1 [STRING] ["H+"]
Valid Values: Unconstrained
Name of species number 1
pt_picPname_2 [STRING] ["H+ beam"]
Valid Values: Unconstrained
Name of species number 2
pt_picPpc_1 [INTEGER] [0]
Valid Values: Unconstrained
Macro particles per cell of species 1
pt_picPpc_2 [INTEGER] [0]
Valid Values: Unconstrained
Macro particles per cell of species 2
pt_picPtemp_1 [REAL] [1.5e5]
Valid Values: 0 to INFTY
Initial temperature for particle species 1 [K]
pt_picPtemp_2 [REAL] [0.0]
Valid Values: 0 to INFTY
Initial temperature for particle species 2 [K]
pt_picPvelx_1 [REAL] [0.0]
Valid Values: Unconstrained
Initial x bulk velocity for particle species 1 [m/s]
pt_picPvelx_2 [REAL] [0.0]
Valid Values: Unconstrained
Initial x bulk velocity for particle species 1 [m/s]
pt_picPvely_1 [REAL] [0.0]
Valid Values: Unconstrained
Initial y bulk velocity for particle species 1 [m/s]
pt_picPvely_2 [REAL] [0.0]
Valid Values: Unconstrained
Initial y bulk velocity for particle species 1 [m/s]
pt_picPvelz_1 [REAL] [0.0]
Valid Values: Unconstrained
Initial z bulk velocity for particle species 1 [m/s]
pt_picPvelz_2 [REAL] [0.0]
Valid Values: Unconstrained
Initial z bulk velocity for particle species 1 [m/s]
pt_picResistivity [REAL] [0.0]
Valid Values: Unconstrained
pt_picResistivityHyper [REAL] [0.0]
Valid Values: Unconstrained
pt_picRng_seed [INTEGER] [0]
Valid Values: Unconstrained
Seed for the RNG if >= 0; if < 0, do not explicitly initialize the RNG
seed for the hybrid PIC implementation.
pt_picTe [REAL] [0.0]
Valid Values: 0 to INFTY
Initial electron temperature [K]
Particles/ParticlesMain/passive/EstiMidpoint2
pt_dtChangeToleranceDown [REAL] [0.8]
Valid Values: 0.00 to 1.01
controls Euler vs. estimated midpoint step in
EstiMidpoint2Passive/Particles_advance when time step increases.
pt_dtChangeToleranceUp [REAL] [5.0]
Valid Values: 0.00 to INFTY
controls Euler vs. estimated midpoint step in
EstiMidpoint2Passive/Particles_advance when time step increases.
Particles/ParticlesMapping/meshWeighting/CIC
smearLen [INTEGER] [1]
Valid Values: Unconstrained
PhysicalConstants/PhysicalConstantsMain
pc_unitsBase [STRING] ["CGS"]
Valid Values: Unconstrained
Base Unit system for Physical Constants -- can be "CGS" or "MKS"
Simulation/SimulationMain
basenm [STRING] ["flash_"]
Valid Values: Unconstrained
Base name for output files
Simulation/SimulationMain/Blast2
gamma [REAL] [1.6667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for gas - for initialization
refine_var_1 [STRING] ["pres"]
Valid Values: Unconstrained
first variable on which to refine
refine_var_2 [STRING] ["dens"]
Valid Values: Unconstrained
second variable on which to refine
sim_pLeft [REAL] [1000.]
Valid Values: Unconstrained
Pressure in the left part of the grid
sim_pMid [REAL] [0.01]
Valid Values: Unconstrained
Pressure in the middle of the grid
sim_pRight [REAL] [100.]
Valid Values: Unconstrained
Pressure in the righ part of the grid
sim_posnL [REAL] [0.1]
Valid Values: Unconstrained
Point of intersection between the left shock plane and x-axis
sim_posnR [REAL] [0.9]
Valid Values: Unconstrained
Point of intersection between the right shock plane and the x-axis
sim_rhoLeft [REAL] [1.]
Valid Values: Unconstrained
Density in the left part of the grid
sim_rhoMid [REAL] [1.]
Valid Values: Unconstrained
Density in the middle of the grid
sim_rhoRight [REAL] [1.]
Valid Values: Unconstrained
Density in the right part of the grid
sim_uLeft [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the left part of the grid
sim_uMid [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the middle of the grid
sim_uRight [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the right part of the grid
sim_xangle [REAL] [0.]
Valid Values: Unconstrained
Angle made by diaphragm normal w/x-axis (deg)
sim_yangle [REAL] [90.]
Valid Values: Unconstrained
Angle made by diaphragm normal w/y-axis (deg)
Simulation/SimulationMain/CCSN
model_file [STRING] ["file.dat"]
Valid Values: Unconstrained
Name of input file with 1D model
nsub [INTEGER] [4]
Valid Values: Unconstrained
number of sub-sampling points for mapping of 1D model
vel_mult [REAL] [1.0]
Valid Values: Unconstrained
multiplier on initial 1D radial velocity
Simulation/SimulationMain/Cellular
noiseAmplitude [REAL] [1.0e-2]
Valid Values: Unconstrained
amplitude of the white noise added to the perturbation
noiseDistance [REAL] [5.0]
Valid Values: Unconstrained
distances above and below r_init get noise added
radiusPerturb [REAL] [25.6]
Valid Values: Unconstrained
distance below which the perturbation is applied
rhoAmbient [REAL] [1.0e7]
Valid Values: 0 to INFTY
density of the cold upstream material
rhoPerturb [REAL] [4.236e7]
Valid Values: Unconstrained
density of the post shock material
tempAmbient [REAL] [2.0e8]
Valid Values: 0 to INFTY
temperature of the cold upstream material
tempPerturb [REAL] [4.423e9]
Valid Values: Unconstrained
temperature of the post shock material
usePseudo1d [BOOLEAN] [FALSE]
.true. for a 1d initial configuration, with the copied along the y and z
directions .false. for a spherical configuration
velxAmbient [REAL] [0.0]
Valid Values: Unconstrained
x-velocity of the cold upstream material
velxPerturb [REAL] [2.876E+08]
Valid Values: Unconstrained
x-velocity of the post shock material
xCenterPerturb [REAL] [0.0]
Valid Values: Unconstrained
xc12 [REAL] [1.0]
Valid Values: 0.0 to 1.0
mass fraction of c12
xhe4 [REAL] [0.0]
Valid Values: 0.0 to 1.0
mass fraction of he4
xo16 [REAL] [0.0]
Valid Values: 0.0 to 1.0
mass fraction of o16
yCenterPerturb [REAL] [0.0]
Valid Values: Unconstrained
zCenterPerturb [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/Chemistry_Test
sim_c_den [REAL] [1.0e-21]
Valid Values: Unconstrained
sim_c_temp [REAL] [1000.0]
Valid Values: Unconstrained
sim_contrast [REAL] [0.1]
Valid Values: Unconstrained
sim_cool_time [REAL] [0.1]
Valid Values: Unconstrained
sim_fracDeuterium [REAL] [0.0]
Valid Values: Unconstrained
sim_fracHelium [REAL] [0.240]
Valid Values: Unconstrained
sim_fracHydrogen [REAL] [0.760]
Valid Values: Unconstrained
sim_meta [REAL] [0.0]
Valid Values: Unconstrained
sim_nblockx [REAL] [1.0]
Valid Values: Unconstrained
sim_nblocky [REAL] [1.0]
Valid Values: Unconstrained
sim_nblockz [REAL] [1.0]
Valid Values: Unconstrained
sim_pchem_time [REAL] [0.1]
Valid Values: Unconstrained
sim_xD [REAL] [0.0]
Valid Values: Unconstrained
sim_xD2 [REAL] [0.0]
Valid Values: Unconstrained
sim_xD2P [REAL] [0.0]
Valid Values: Unconstrained
sim_xDM [REAL] [0.0]
Valid Values: Unconstrained
sim_xDP [REAL] [0.0]
Valid Values: Unconstrained
sim_xELEC [REAL] [0.0]
Valid Values: Unconstrained
sim_xH [REAL] [0.760]
Valid Values: Unconstrained
sim_xH2 [REAL] [0.0]
Valid Values: Unconstrained
sim_xH2P [REAL] [0.0]
Valid Values: Unconstrained
sim_xHD [REAL] [0.0]
Valid Values: Unconstrained
sim_xHDP [REAL] [0.0]
Valid Values: Unconstrained
sim_xHM [REAL] [0.0]
Valid Values: Unconstrained
sim_xHP [REAL] [0.0]
Valid Values: Unconstrained
sim_xHe [REAL] [0.240]
Valid Values: Unconstrained
sim_xHeP [REAL] [0.0]
Valid Values: Unconstrained
sim_xHePP [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/ConductionDelta
cond_K0 [REAL] [1.0]
Valid Values: Unconstrained
coefficient K0 for conductivity K = rho c_v K0 T^n , where n is given by
cond_TemperatureExponent.
cond_TemperatureExponent [REAL] [1.0]
Valid Values: Unconstrained
Temperature exponent n. For n=0 you get constant conductivity. See D.
Mihalas & B. W. Mihalas 1984 p 551. For n=6, e.g., you get nonlinear
conduction as in Fig 103.1(b) there.
iniCondTemperatureExponent [REAL] [-999.0]
Valid Values: Unconstrained
exponent for computing the temperature curve used as initial condition.
Set to 0 to get a Gaussian. Set to -999.0 to get the value of
cond_TemperatureExponent.
orientation [INTEGER] [1]
Valid Values: 0, 1, 2, 3
1/2/3 -- planar source is oriented along x/y/z axis, 0 --
three-dimensional point source
rho_init [REAL] [1.]
Valid Values: Unconstrained
background density
sim_Q [REAL] [1.0]
Valid Values: Unconstrained
factor used for scaling the initial temperature distribution
sim_tempBackground [REAL] [0.0]
Valid Values: Unconstrained
constant temperature background, the Gaussian peak gets added to this
sim_xctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center X-coordinate
sim_yctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center Y-coordinate
sim_zctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center Z-coordinate
toffset [REAL] [.001]
Valid Values: Unconstrained
time offset for initial condition
updateHydroFluxes [BOOLEAN] [FALSE]
Simulation/SimulationMain/ConductionDeltaSaDiff
cond_K0 [REAL] [1.0]
Valid Values: Unconstrained
coefficient K0 for conductivity K = rho c_v K0 T^n , where n is given by
cond_TemperatureExponent.
cond_TemperatureExponent [REAL] [1.0]
Valid Values: Unconstrained
Temperature exponent n. For n=0 you get constant conductivity. See D.
Mihalas & B. W. Mihalas 1984 p 551. For n=6, e.g., you get nonlinear
conduction as in Fig 103.1(b) there.
iniCondTemperatureExponent [REAL] [-999.0]
Valid Values: Unconstrained
exponent for computing the temperature curve used as initial condition.
Set to 0 to get a Gaussian. Set to -999.0 to get the value of
cond_TemperatureExponent.
iniRadDiffExp [REAL] [0.0]
Valid Values: Unconstrained
orientation [INTEGER] [1]
Valid Values: 0, 1, 2, 3
1/2/3 -- planar source is oriented along x/y/z axis, 0 --
three-dimensional point source
rho_init [REAL] [1.]
Valid Values: Unconstrained
background density
sim_Q [REAL] [1.0]
Valid Values: Unconstrained
factor used for scaling the initial temperature distribution
sim_maxTol [REAL] [1.0E-3]
Valid Values: Unconstrained
Max allowed error
sim_tempBackground [REAL] [0.0]
Valid Values: Unconstrained
constant temperature background, the Gaussian peak gets added to this
sim_xctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center X-coordinate
sim_yctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center Y-coordinate
sim_zctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center Z-coordinate
toffset [REAL] [.001]
Valid Values: Unconstrained
time offset for initial condition
updateHydroFluxes [BOOLEAN] [FALSE]
Simulation/SimulationMain/Cool_Test
sim_c_den [REAL] [1.0e-21]
Valid Values: Unconstrained
sim_c_temp [REAL] [1000.0]
Valid Values: Unconstrained
sim_chem_time [REAL] [0.1]
Valid Values: Unconstrained
sim_contrast [REAL] [0.1]
Valid Values: Unconstrained
sim_cool_time [REAL] [0.1]
Valid Values: Unconstrained
sim_fracDeuterium [REAL] [0.0]
Valid Values: Unconstrained
sim_fracHelium [REAL] [0.240]
Valid Values: Unconstrained
sim_fracHydrogen [REAL] [0.760]
Valid Values: Unconstrained
sim_meta [REAL] [0.0]
Valid Values: Unconstrained
sim_nblockx [REAL] [1.0]
Valid Values: Unconstrained
sim_nblocky [REAL] [1.0]
Valid Values: Unconstrained
sim_nblockz [REAL] [1.0]
Valid Values: Unconstrained
sim_xD [REAL] [0.0]
Valid Values: Unconstrained
sim_xD2 [REAL] [0.0]
Valid Values: Unconstrained
sim_xD2P [REAL] [0.0]
Valid Values: Unconstrained
sim_xDM [REAL] [0.0]
Valid Values: Unconstrained
sim_xDP [REAL] [0.0]
Valid Values: Unconstrained
sim_xELEC [REAL] [0.0]
Valid Values: Unconstrained
sim_xH [REAL] [0.760]
Valid Values: Unconstrained
sim_xH2 [REAL] [0.0]
Valid Values: Unconstrained
sim_xH2P [REAL] [0.0]
Valid Values: Unconstrained
sim_xHD [REAL] [0.0]
Valid Values: Unconstrained
sim_xHDP [REAL] [0.0]
Valid Values: Unconstrained
sim_xHM [REAL] [0.0]
Valid Values: Unconstrained
sim_xHP [REAL] [0.0]
Valid Values: Unconstrained
sim_xHe [REAL] [0.240]
Valid Values: Unconstrained
sim_xHeP [REAL] [0.0]
Valid Values: Unconstrained
sim_xHePP [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/DoubleMachReflection
sim_pLeft [REAL] [1.0]
Valid Values: Unconstrained
Pressure in left part of grid
sim_pRight [REAL] [116.5]
Valid Values: Unconstrained
Pressure in right part of grid
sim_posn [REAL] [0.1666666666]
Valid Values: Unconstrained
Point of intersection between the shock plane and the x-axis
sim_rhoLeft [REAL] [1.4]
Valid Values: Unconstrained
Density in left part of grid
sim_rhoRight [REAL] [8.0]
Valid Values: Unconstrained
Density in right part of grid
sim_uLeft [REAL] [0.0]
Valid Values: Unconstrained
Fluid velocity in right part of grid
sim_uRight [REAL] [7.1447096]
Valid Values: Unconstrained
Fluid velocity in right part of grid
sim_vLeft [REAL] [0.0]
Valid Values: Unconstrained
Fluid velocity in right part of grid
sim_vRight [REAL] [-4.125]
Valid Values: Unconstrained
Fluid velocity in right part of grid
sim_xangle [REAL] [60.]
Valid Values: Unconstrained
Angle made by diaphragm normal w/x-axis (deg)
Simulation/SimulationMain/DustCollapse
sim_ictr [REAL] [0.5]
Valid Values: Unconstrained
sim_initDens [REAL] [1.]
Valid Values: Unconstrained
sim_initRad [REAL] [0.05]
Valid Values: Unconstrained
sim_jctr [REAL] [0.5]
Valid Values: Unconstrained
sim_kctr [REAL] [0.5]
Valid Values: Unconstrained
sim_tAmbient [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/Flame1StageNoise
frac_perturb [REAL] [.5]
Valid Values: Unconstrained
Size of burned region, scaled to domain size (generally x extent)
ignite [BOOLEAN] [FALSE]
Determines if simulation begins with a flame front in it
pseudo_1d [BOOLEAN] [FALSE]
If true a planar flame front is created, otherwise a spherical one is
planar configuration is as follows based on other parameters y ^
. | \ . | \ . | \ t . yctr + + . fuel |
\ . | ash \ | \ +-------+--------------------------> x |
frac_ptrb * x extent
rho_ambient [REAL] [2.e9]
Valid Values: Unconstrained
Density of unburned material
t_ambient [REAL] [5.0e7]
Valid Values: Unconstrained
Temperature of unburned material
theta [REAL] [0.]
Valid Values: Unconstrained
angle between surface normal to planar flame surface and x axis (see
diagram with pseudo_1d)
xctr_perturb [REAL] [1.e-4]
Valid Values: Unconstrained
Planar: unused Spherical: x coordinate of center of spherical burned
region
yctr_perturb [REAL] [1.e-4]
Valid Values: Unconstrained
Planar: pivot point of planar interface (see diagram with pseudo_1d)
Spherical: y coordinate of center of spherical burned region
zctr_perturb [REAL] [1.e-4]
Valid Values: Unconstrained
Planar: unused Spherical: z coordinate of center of spherical burned
region
Simulation/SimulationMain/FlameChannel
frac_perturb [REAL] [.5]
Valid Values: Unconstrained
Size of burned region, scaled to domain size (generally x extent)
ignite [BOOLEAN] [TRUE]
Determines if simulation begins with a flame front in it
inflowVortex [BOOLEAN] [FALSE]
is a boolean. True means no vortices, false means vortices
restart_vortex [BOOLEAN] [FALSE]
says that a vortex will be inserted upon restart
rho_ambient [REAL] [2.e9]
Valid Values: Unconstrained
Density of unburned material
sigP [REAL] [0.]
Valid Values: Unconstrained
sigT [REAL] [1.]
Valid Values: Unconstrained
sigVx [REAL] [1.]
Valid Values: Unconstrained
sigVy [REAL] [0.]
Valid Values: Unconstrained
sigVz [REAL] [0.]
Valid Values: Unconstrained
smooth_level [INTEGER] [0]
Valid Values: Unconstrained
t_ambient [REAL] [5.0e7]
Valid Values: Unconstrained
Temperature of unburned material
turbfield_filename [STRING] ["turb_vel_field.hdf5"]
Valid Values: Unconstrained
turbfield_xmax [REAL] [15.e5]
Valid Values: Unconstrained
turbfield_xmin [REAL] [0.0]
Valid Values: Unconstrained
turbfield_ymax [REAL] [7.5e5]
Valid Values: Unconstrained
turbfield_ymin [REAL] [-7.5e5]
Valid Values: Unconstrained
turbfield_zmax [REAL] [7.5e5]
Valid Values: Unconstrained
turbfield_zmin [REAL] [-7.5e5]
Valid Values: Unconstrained
useBurn [BOOLEAN] [true]
variableInflow [BOOLEAN] [FALSE]
is a boolean and allows inflow rate to match burning rate
vortexSize [REAL] [0.25]
Valid Values: Unconstrained
is the radius of an individual vortex
vortexStrength [REAL] [5.0]
Valid Values: Unconstrained
is the strength of the vortex (should be of order density)
vrms [REAL] [1.e7]
Valid Values: Unconstrained
xbegin_vortex [REAL] [0.]
Valid Values: Unconstrained
is the x coordinate that defines the left side of
xend_vortex [REAL] [0.]
Valid Values: Unconstrained
yctr_vortex [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/FlatPlate
sim_Mach [REAL] [1.0]
Valid Values: Unconstrained
sim_number [INTEGER] [1]
Valid Values: Unconstrained
sim_pAmbient [REAL] [1.0]
Valid Values: Unconstrained
sim_radius [REAL] [0.2]
Valid Values: Unconstrained
sim_rhoAmbient [REAL] [1.4]
Valid Values: Unconstrained
sim_rhoBulk [REAL] [10.]
Valid Values: Unconstrained
sim_windVelx [REAL] [1.0]
Valid Values: Unconstrained
sim_windVely [REAL] [1.0]
Valid Values: Unconstrained
sim_windVelz [REAL] [1.0]
Valid Values: Unconstrained
sim_xCtr [REAL] [0.3]
Valid Values: Unconstrained
sim_xangle [REAL] [0.]
Valid Values: 0 to 360
Angle made by diaphragm normal w/x-axis (deg)
sim_yCtr [REAL] [0.5]
Valid Values: Unconstrained
sim_yangle [REAL] [90.]
Valid Values: 0 to 360
sim_zCtr [REAL] [0.5]
Valid Values: Unconstrained
sim_zangle [REAL] [90.]
Valid Values: 0 to 360
Simulation/SimulationMain/GrayDiffRadShock
sim_M0 [REAL] [1.0]
Valid Values: Unconstrained
shock mach number
sim_P0 [REAL] [1.0]
Valid Values: Unconstrained
ratio of radiation pressure to material pressure
sim_rho [REAL] [1.0]
Valid Values: Unconstrained
referene density
sim_temp [REAL] [1.0]
Valid Values: Unconstrained
reference temperature
Simulation/SimulationMain/HeatedFoil
sim_foilRadius [REAL] [0.0064]
Valid Values: Unconstrained
[cm] The radius to use for the target
sim_foilThickness [REAL] [0.0008]
Valid Values: Unconstrained
[cm] The thickness of the foil
sim_foilZPosition [REAL] [0.0]
Valid Values: Unconstrained
< z < sim_foilZPosition + sim_foilThickness
sim_rhoFoil [REAL] [2.7]
Valid Values: Unconstrained
[g/cc] Initial foil density
sim_rhoVacu [REAL] [2.7]
Valid Values: Unconstrained
[g/cc] Initial vacuum density
sim_teleFoil [REAL] [290.11375]
Valid Values: Unconstrained
[K] Initial foil background electron temperature
sim_teleRDecayFoil [REAL] [10.0e-04]
Valid Values: Unconstrained
[cm] Sets lengthscale for temperature drop in R
sim_teleVacu [REAL] [290.11375]
Valid Values: Unconstrained
[K] Initial vacuum electron temperature
sim_teleZDecayFoil [REAL] [2.0e-04]
Valid Values: Unconstrained
[cm] Sets lengthscale for temperature drop in Z
sim_thotFoil [REAL] [0.0]
Valid Values: Unconstrained
[K] sim_thotFoil + sim_teleFoil is the peak foil electron
sim_tionFoil [REAL] [290.11375]
Valid Values: Unconstrained
[K] Initial foil ion temperature
sim_tionVacu [REAL] [290.11375]
Valid Values: Unconstrained
[K] Initial vacuum ion temperature
sim_tradFoil [REAL] [290.11375]
Valid Values: Unconstrained
[K] Initial foil radiation temperature
sim_tradVacu [REAL] [290.11375]
Valid Values: Unconstrained
[K] Initial vacuum radiation temperature
Simulation/SimulationMain/HeatexchangeIonEle
cond_K0 [REAL] [1.0]
Valid Values: Unconstrained
coefficient K0 for conductivity K = rho c_v K0 T^n , where n is given by
cond_TemperatureExponent.
cond_TemperatureExponent [REAL] [1.0]
Valid Values: Unconstrained
Temperature exponent n. For n=0 you get constant conductivity. See D.
Mihalas & B. W. Mihalas 1984 p 551. For n=6, e.g., you get nonlinear
conduction as in Fig 103.1(b) there.
initialCondTemperatureExponent [REAL] [-999.0]
Valid Values: Unconstrained
exponent for computing the temperature curve used as initial condition.
Set to 0 to get a Gaussian. Set to -999.0 to get the value of
cond_TemperatureExponent.
orientation [INTEGER] [1]
Valid Values: 0, 1, 2, 3
1/2/3 -- planar source is oriented along x/y/z axis, 0 --
three-dimensional point source
rho_init [REAL] [1.]
Valid Values: Unconstrained
background density
sim_Q [REAL] [1.0]
Valid Values: Unconstrained
factor used for scaling the initial temperature distribution
sim_analytical_maxNewton [INTEGER] [5]
Valid Values: Unconstrained
maximum number of Newton-Raphson iterations to try.
sim_analytical_tolerance [REAL] [1.e-8]
Valid Values: Unconstrained
tolerance for the Newton-Raphson iterations
sim_eleTemp [REAL] [1.0e5]
Valid Values: 0.0+ to INFTY
sim_ionTemp [REAL] [6.0e5]
Valid Values: 0.0+ to INFTY
sim_maxTolCoeff0 [REAL] [1.0e-8]
Valid Values: Unconstrained
sim_maxTolCoeff1 [REAL] [0.0001]
Valid Values: Unconstrained
sim_maxTolCoeff2 [REAL] [0.01]
Valid Values: Unconstrained
sim_maxTolCoeff3 [REAL] [0.0]
Valid Values: Unconstrained
sim_radTemp [REAL] [0.0]
Valid Values: 0.0 to INFTY
sim_schemeOrder [INTEGER] [2]
Valid Values: Unconstrained
sim_tempBackground [REAL] [0.0]
Valid Values: Unconstrained
constant temperature background, the Gaussian peak gets added to this
sim_xctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center X-coordinate
sim_yctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center Y-coordinate
sim_zctr [REAL] [0.5]
Valid Values: Unconstrained
Temperature peak center Z-coordinate
toffset [REAL] [.001]
Valid Values: Unconstrained
time offset for initial condition
updateHydroFluxes [BOOLEAN] [FALSE]
Simulation/SimulationMain/HydroStatic
sim_presRef [REAL] [1.0]
Valid Values: Unconstrained
sim_tempRef [REAL] [300.0]
Valid Values: Unconstrained
sim_xyzRef [REAL] [0.5]
Valid Values: Unconstrained
Simulation/SimulationMain/IsentropicVortex
fracPele [REAL] [0.799999]
Valid Values: Unconstrained
fraction of pressure for electrons
fracPion [REAL] [0.2]
Valid Values: Unconstrained
fraction of pressure for ions
fracPrad [REAL] [0.000001]
Valid Values: Unconstrained
fraction of pressure for radctrons
gamma [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for gas - for initialization
gammaEle [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for ele component, should be 5./3.
gammaIon [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for ion component, should be 5./3.
nx_subint [INTEGER] [10]
Valid Values: Unconstrained
number of subintervals along IAXIS
ny_subint [INTEGER] [10]
Valid Values: Unconstrained
number of subintervals along JAXIS
p_ambient [REAL] [1.0]
Valid Values: Unconstrained
Initial ambient pressure
particle_attribute_1 [STRING] ["pdens"]
Valid Values: Unconstrained
particle_attribute_2 [STRING] ["ptemp"]
Valid Values: Unconstrained
rho_ambient [REAL] [1.0]
Valid Values: Unconstrained
Initial ambient density
u_ambient [REAL] [1.0]
Valid Values: Unconstrained
Initial ambient velocity
v_ambient [REAL] [1.0]
Valid Values: Unconstrained
vortex_strength [REAL] [5.0]
Valid Values: Unconstrained
xctr [REAL] [0.0]
Valid Values: Unconstrained
x coordinate of the vortex center
yctr [REAL] [0.0]
Valid Values: Unconstrained
y coordinate of the vortex center
Simulation/SimulationMain/Jeans
amplitude [REAL] [0.01]
Valid Values: Unconstrained
delta_deref [REAL] [0.01]
Valid Values: Unconstrained
delta_ref [REAL] [0.1]
Valid Values: Unconstrained
lambdax [REAL] [1.]
Valid Values: Unconstrained
lambday [REAL] [1.]
Valid Values: Unconstrained
lambdaz [REAL] [1.]
Valid Values: Unconstrained
p0 [REAL] [1.]
Valid Values: Unconstrained
reference_density [REAL] [1.]
Valid Values: Unconstrained
rho0 [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/KHInstab
sim_dens1 [REAL] [1.5]
Valid Values: Unconstrained
Density in Upper Right region
sim_dens2 [REAL] [0.5323]
Valid Values: Unconstrained
Density in Upper Left region
sim_dens3 [REAL] [0.138]
Valid Values: Unconstrained
Density in Lower Right region
sim_dens4 [REAL] [0.5323]
Valid Values: Unconstrained
Density in Lower Left region
sim_pres1 [REAL] [1.5]
Valid Values: Unconstrained
Pressure in Upper Right region
sim_pres2 [REAL] [0.3]
Valid Values: Unconstrained
Pressure in Upper Left region
sim_pres3 [REAL] [0.029]
Valid Values: Unconstrained
Pressure in Lower Right region
sim_pres4 [REAL] [0.3]
Valid Values: Unconstrained
Pressure in Lower Left region
sim_smallP [REAL] [1e-12]
Valid Values: Unconstrained
small pres
sim_smallX [REAL] [1.e-12]
Valid Values: Unconstrained
sim_velx1 [REAL] [0.]
Valid Values: Unconstrained
Velocity in Upper Right region
sim_velx2 [REAL] [1.206]
Valid Values: Unconstrained
Velocity in Upper Left region
sim_velx3 [REAL] [1.206]
Valid Values: Unconstrained
Velocity in Lower Right region
sim_velx4 [REAL] [0.]
Valid Values: Unconstrained
Velocity in Lower Left region
sim_vely1 [REAL] [0.]
Valid Values: Unconstrained
Velocity in Upper Right region
sim_vely2 [REAL] [0.]
Valid Values: Unconstrained
Velocity in Upper Left region
sim_vely3 [REAL] [1.206]
Valid Values: Unconstrained
Velocity in Lower Right region
sim_vely4 [REAL] [1.206]
Valid Values: Unconstrained
Velocity in Lower Left region
sim_x0 [REAL] [0.8]
Valid Values: Unconstrained
initial x location for 2DRP interaction point
sim_y0 [REAL] [0.8]
Valid Values: Unconstrained
initial y location for 2dRP interaction point
Simulation/SimulationMain/LaserSlab
sim_eosCham [STRING] ["eos_gam"]
Valid Values: "eos_tab", "eos_gam"
chamber EOS type
sim_eosTarg [STRING] ["eos_tab"]
Valid Values: "eos_tab", "eos_gam"
chamber EOS type
sim_initGeom [STRING] ["slab"]
Valid Values: "slab", "sphere"
Use a spherical target if sphere, default to slab
sim_rhoCham [REAL] [2.655e-07]
Valid Values: Unconstrained
Initial chamber density
sim_rhoTarg [REAL] [2.7]
Valid Values: Unconstrained
Initial target density
sim_targetHeight [REAL] [0.0250]
Valid Values: Unconstrained
The height of the target off y-axis
sim_targetRadius [REAL] [0.0050]
Valid Values: Unconstrained
The radius to use for the target
sim_teleCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber electron temperature
sim_teleTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target electron temperature
sim_tionCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber ion temperature
sim_tionTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target ion temperature
sim_tradCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber radiation temperature
sim_tradTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target radiation temperature
sim_vacuumHeight [REAL] [0.0200]
Valid Values: Unconstrained
The thickness of the vacuum region in front of the target
sim_zminTarg [REAL] [0.0]
Valid Values: Unconstrained
target minimum zbar allowed
Simulation/SimulationMain/MGDInfinite
sim_beMassFrac [REAL] [0.33]
Valid Values: Unconstrained
sim_poliMassFrac [REAL] [0.33]
Valid Values: Unconstrained
sim_rho [REAL] [1.0]
Valid Values: Unconstrained
Initial radiation temperature
sim_tele [REAL] [1.0]
Valid Values: Unconstrained
sim_tion [REAL] [1.0]
Valid Values: Unconstrained
sim_trad [REAL] [1.0]
Valid Values: Unconstrained
sim_xeMassFrac [REAL] [0.33]
Valid Values: Unconstrained
Simulation/SimulationMain/MGDStep
sim_initGeom [STRING] ["planar"]
Valid Values: "planar", "polar"
sim_rho1 [REAL] [1.0]
Valid Values: Unconstrained
sim_rho2 [REAL] [1.0]
Valid Values: Unconstrained
sim_tele1 [REAL] [1.0]
Valid Values: Unconstrained
sim_tele2 [REAL] [1.0]
Valid Values: Unconstrained
sim_thickness [REAL] [0.1]
Valid Values: Unconstrained
Size of the "hot" region
sim_tion1 [REAL] [1.0]
Valid Values: Unconstrained
sim_tion2 [REAL] [1.0]
Valid Values: Unconstrained
sim_trad1 [REAL] [1.0]
Valid Values: Unconstrained
sim_trad2 [REAL] [1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/MacLaurin
angular_velocity [REAL] [0.]
Valid Values: Unconstrained
Dimensionless angular velocity (Omega)
density [REAL] [1.]
Valid Values: -1.0 to INFTY
Spheroid density (rho)): set to -1 to generate spheroid mass of 1.0
eccentricity [REAL] [0.]
Valid Values: 0.0 to 1.0
Eccentricity of the ellipsoid (e)
equatorial_semimajor_axis [REAL] [1.]
Valid Values: 0.1 to INFTY
Equatorial semimajor axis (a1)
nsubzones [INTEGER] [2]
Valid Values: 1 to INFTY
Number of sub-zones per dimension
xctr [REAL] [0.5]
Valid Values: Unconstrained
X-coordinate of center of spheroid
yctr [REAL] [0.5]
Valid Values: Unconstrained
Y-coordinate of center of spheroid
zctr [REAL] [0.5]
Valid Values: Unconstrained
Z-coordinate of center of spheroid
Simulation/SimulationMain/NeiTest
radius [REAL] [0.2]
Valid Values: Unconstrained
rho_ambient [REAL] [2.e-16]
Valid Values: Unconstrained
t_ambient [REAL] [1.e4]
Valid Values: Unconstrained
t_perturb [REAL] [0.2]
Valid Values: Unconstrained
vel_init [REAL] [3.e5]
Valid Values: Unconstrained
xstep [REAL] [1.5e7]
Valid Values: Unconstrained
Simulation/SimulationMain/Orbit
ext_field [BOOLEAN] [TRUE]
external field (TRUE) or self-grav (FALSE)?
num_particles [INTEGER] [2]
Valid Values: Unconstrained
ptmass [REAL] [1.]
Valid Values: Unconstrained
point mass if external field
separation [REAL] [1.]
Valid Values: Unconstrained
particle separation (2*radius)
Simulation/SimulationMain/Pancake
Lambda [REAL] [3.0857E24]
Valid Values: Unconstrained
MaxParticlePerZone [INTEGER] [10]
Valid Values: Unconstrained
Tfiducial [REAL] [100.0]
Valid Values: Unconstrained
pt_numX [INTEGER] [1]
Valid Values: Unconstrained
pt_numY [INTEGER] [1]
Valid Values: Unconstrained
pt_numZ [INTEGER] [1]
Valid Values: Unconstrained
xangle [REAL] [0.0]
Valid Values: Unconstrained
yangle [REAL] [90.0]
Valid Values: Unconstrained
zcaustic [REAL] [1.0]
Valid Values: Unconstrained
zfiducial [REAL] [100.0]
Valid Values: Unconstrained
Simulation/SimulationMain/Plasma
pt_resetTag [BOOLEAN] [TRUE]
sim_bx [REAL] [0.0]
Valid Values: Unconstrained
Initial magnetic field x-component [T]
sim_by [REAL] [0.0]
Valid Values: Unconstrained
Initial magnetic field y-component [T]
sim_bz [REAL] [0.0]
Valid Values: Unconstrained
Initial magnetic field z-component [T]
Simulation/SimulationMain/PoisTest
sim_smlRho [REAL] [1.E-10]
Valid Values: Unconstrained
smallest allowed value of density
Simulation/SimulationMain/ProtonImaging
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
Simulation/SimulationMain/RHD_Sod
sim_pLeft [REAL] [1.]
Valid Values: Unconstrained
Pressure in the left part of the grid
sim_pRight [REAL] [0.1]
Valid Values: Unconstrained
Pressure in the righ part of the grid
sim_posn [REAL] [0.5]
Valid Values: Unconstrained
sim_rhoLeft [REAL] [1.]
Valid Values: Unconstrained
Density in the left part of the grid
sim_rhoRight [REAL] [0.125]
Valid Values: Unconstrained
Density in the right part of the grid
sim_uLeft [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the left part of the grid
sim_uRight [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the right part of the grid
sim_vLeft [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the left part of the grid
sim_vRight [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the right part of the grid
sim_wLeft [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the left part of the grid
sim_wRight [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the right part of the grid
sim_xangle [REAL] [0.]
Valid Values: Unconstrained
Angle made by diaphragm normal w/x-axis (deg)
sim_yangle [REAL] [90.]
Valid Values: Unconstrained
Simulation/SimulationMain/RTFlame
dens_unburned [REAL] [1e8]
Valid Values: Unconstrained
flame_initial_position [REAL] [0.0]
Valid Values: Unconstrained
particle_attribute_1 [STRING] ["dens"]
Valid Values: Unconstrained
particle_attribute_2 [STRING] ["temp"]
Valid Values: Unconstrained
particle_attribute_4 [STRING] ["flam"]
Valid Values: Unconstrained
refine_buf [REAL] [1e5]
Valid Values: Unconstrained
Buffer to prevent refinement pattern jitter
refine_lead [REAL] [2e5]
Valid Values: Unconstrained
Distance above highest burned cell which refined region will reach
refine_region_size [REAL] [60e5]
Valid Values: Unconstrained
Total size of refine region (See source for diagram of parameter
meanings)
refine_region_stepdown_size [REAL] [45e5]
Valid Values: Unconstrained
Distance behind fully refined region that is one lower refinement level
refine_uniform_region [BOOLEAN] [FALSE]
Select whether to refine a selected region uniformly or use
standard-style refinement checks (configured with other parameters)
sim_ParticleRefineRegion [BOOLEAN] [FALSE]
sim_ParticleRefineRegionBottom [REAL] [60e5]
Valid Values: Unconstrained
sim_ParticleRefineRegionLevel [INTEGER] [2]
Valid Values: Unconstrained
sim_ParticleRefineRegionTop [REAL] [200e5]
Valid Values: Unconstrained
spert_ampl1 [REAL] [0.0]
Valid Values: Unconstrained
spert_ampl2 [REAL] [0.0]
Valid Values: Unconstrained
spert_phase1 [REAL] [0.0]
Valid Values: Unconstrained
spert_phase2 [REAL] [0.0]
Valid Values: Unconstrained
spert_wl1 [REAL] [1.0]
Valid Values: Unconstrained
spert_wl2 [REAL] [1.0]
Valid Values: Unconstrained
temp_unburned [REAL] [1e8]
Valid Values: Unconstrained
vel_pert_amp [REAL] [0.0]
Valid Values: Unconstrained
vel_pert_wavelength1 [REAL] [1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/RadSlab
sim_eosCham [STRING] ["eos_gam"]
Valid Values: "eos_tab", "eos_gam"
chamber EOS type
sim_eosTarg [STRING] ["eos_tab"]
Valid Values: "eos_tab", "eos_gam"
chamber EOS type
sim_initGeom [STRING] ["slab"]
Valid Values: "slab", "sphere"
Use a spherical target if sphere, default to slab
sim_radSourceFWHM [REAL] [1.e-9]
Valid Values: Unconstrained
fwhm of radiation source Gaussian
sim_radSourcePeak [REAL] [1.e-9]
Valid Values: Unconstrained
time at which radiation source Gaussian peaks
sim_radSourceStart [REAL] [0.]
Valid Values: Unconstrained
start time for radiation source
sim_radSourceStop [REAL] [1.e99]
Valid Values: Unconstrained
stop time for radiation source
sim_radSourceTMax [REAL] [500.]
Valid Values: Unconstrained
peak radiation temperature (eV) of the radiation source at domain
boundary
sim_radSourceTMin [REAL] [500.]
Valid Values: Unconstrained
minimum radiation temperature (eV) of the radiation source at domain
boundary
sim_radSourceType [INTEGER] [0]
Valid Values: Unconstrained
radiation source temperature type (0=constant, 1=Gaussian)
sim_rhoCham [REAL] [2.655e-07]
Valid Values: Unconstrained
Initial chamber density
sim_rhoTarg [REAL] [2.7]
Valid Values: Unconstrained
Initial target density
sim_targetHeight [REAL] [0.0250]
Valid Values: Unconstrained
The height of the target off y-axis
sim_targetRadius [REAL] [0.0050]
Valid Values: Unconstrained
The radius to use for the target
sim_teleCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber electron temperature
sim_teleTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target electron temperature
sim_tionCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber ion temperature
sim_tionTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target ion temperature
sim_tradCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber radiation temperature
sim_tradTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target radiation temperature
sim_vacuumHeight [REAL] [0.0200]
Valid Values: Unconstrained
The thickness of the vacuum region in front of the target
sim_zminTarg [REAL] [0.0]
Valid Values: Unconstrained
target minimum zbar allowed
Simulation/SimulationMain/ReinickeMeyer
sim_rfInit [REAL] [0.9]
Valid Values: Unconstrained
Initial thermal front position [cm]
Simulation/SimulationMain/SBlast
sim_A1 [REAL] [1.]
Valid Values: 1 to INFTY
Atomic weight in region 2
sim_A2 [REAL] [1.]
Valid Values: 1 to INFTY
sim_AIn [REAL] [1.]
Valid Values: 1 to INFTY
Atomic weight inside the energy source
sim_EIn [REAL] [1.]
Valid Values: 0 to INFTY
Total energy inside the energy source
sim_Z1 [REAL] [1.]
Valid Values: 1 to INFTY
Atomic number in region 1
sim_Z2 [REAL] [1.]
Valid Values: 1 to INFTY
Atomic number in region 2
sim_ZIn [REAL] [1.]
Valid Values: 1 to INFTY
Atomic number inside the energy source
sim_atmos1 [INTEGER] [0]
Valid Values: Unconstrained
sim_atmos2 [INTEGER] [0]
Valid Values: Unconstrained
sim_gamma1 [REAL] [1.4]
Valid Values: 1.1 to INFTY
gamma in region 1
sim_gamma2 [REAL] [1.4]
Valid Values: 1.1 to INFTY
gamma in region 2
sim_gammaIn [REAL] [1.4]
Valid Values: 1.1 to INFTY
gamma inside the energy source
sim_geo [INTEGER] [0]
Valid Values: Unconstrained
specifies the geometry of the problem, not the geometry of the grid
sim_h1 [REAL] [1.]
Valid Values: Unconstrained
Thickness of region 1
sim_ibound [BOOLEAN] [FALSE]
Bounday/Discontinuity present?
sim_p1 [REAL] [1.]
Valid Values: 0 to INFTY
Pressure in region 2
sim_p2 [REAL] [1.]
Valid Values: 0 to INFTY
sim_pIn [REAL] [1.]
Valid Values: 0 to INFTY
Pressure inside the energy source
sim_rIn [REAL] [0.1]
Valid Values: 0 to INFTY
radius of the energy source
sim_rho1 [REAL] [1.]
Valid Values: 0 to INFTY
Density in region 2
sim_rho2 [REAL] [1.]
Valid Values: 0 to INFTY
sim_rhoIn [REAL] [1.]
Valid Values: 0 to INFTY
Density inside the energy source
sim_sh1 [REAL] [1.]
Valid Values: Unconstrained
Scale height in region 2
sim_sh2 [REAL] [1.]
Valid Values: Unconstrained
sim_useE [BOOLEAN] [FALSE]
Use total energy to define energy source
sim_xcIn [REAL] [0.]
Valid Values: Unconstrained
x location of the center of the energy source
sim_ycIn [REAL] [0.]
Valid Values: Unconstrained
y location of the center of the energy source
sim_zcIn [REAL] [0.]
Valid Values: Unconstrained
z location of the center of the energy source
Simulation/SimulationMain/Sedov
sim_bcSetBdryVar [BOOLEAN] [FALSE]
Whether to set the "bdry" variable in unk (if it exists) to 1 in guard
cells at reflecting boundaries. Doing this will entice Hydro
implementations to lower reconstruction order in adjacent cells, and
possibly lower the CFL factor applied to timestep computation as well.
sim_centerRefineLevel [INTEGER] [1]
Valid Values: -1, 1 to INFTY
Desired refinement level at center (if "forcing")
sim_derefineRadius [REAL] [0.0]
Valid Values: 0.0 to INFTY
Radius of center region to force derefinement
sim_earliestLSTime [REAL] [0.0]
Valid Values: Unconstrained
earliest time included in Largest-{Norm,Error} summaries
sim_expEnergy [REAL] [1.]
Valid Values: Unconstrained
Explosion energy (distributed over initial explosion region)
sim_forceCenterDerefine [BOOLEAN] [FALSE]
Try to force low refinement level around explosion center?
sim_integralsLevel [INTEGER] [-1]
Valid Values: -1, 1 to INFTY
if sim_oneLevelIntegralsOnly is TRUE, this gives the requested
refinement level, either explicitly as a positive integer or as -1 for
the largest currently realized level.
sim_largestNormRadius [REAL] [HUGE(1.0)]
Valid Values: Unconstrained
outer radius bound of region for norm computation
sim_latestLSTime [REAL] [HUGE(1.0)]
Valid Values: Unconstrained
latest time included in Largest-{Norm,Error} summaries
sim_minRhoInit [REAL] [1.E-20]
Valid Values: 0.0 to INFTY
Density floor for initial condition
sim_nsubzones [INTEGER] [7]
Valid Values: 1 to INFTY
Number of `sub-zones' in cells for applying 1d profile
sim_oneLevelIntegralsOnly [BOOLEAN] [FALSE]
Whether to compute intgral quantities only on cells at one refinement
level, ignoring all finer or coarser cells
sim_pAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient pressure
sim_profFileName [STRING] ["/dev/null"]
Valid Values: Unconstrained
Name of file from which to read a 1D Sedov solution for the initial
condition. The data from the file will be rescaled, and a density floor
given by sim_minRhoInit will be applied, to construct the initial
condition. This file will only be used if tinitial > 0. Use the special
name "/dev/null" to effectively skip reading a 1D solution. Otherwise,
the given file has to be in the expected format, see sample files under
DATAFILES, AND the number of data lines (following a fixed number of
comment lines) has to match the sim_nProfile coded into the
Simulation_data source file.
sim_rInit [REAL] [0.05]
Valid Values: Unconstrained
Radius of region into which explosion energy is dumped initially, used
only if tinitial <= 0.
sim_rhoAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient density
sim_smallestNormRadius [REAL] [0.0]
Valid Values: Unconstrained
inner radius bound of region for norm computation
sim_xctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_yctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_zctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
Simulation/SimulationMain/Sedov/WriteParticleSubset
sim_expEnergy [REAL] [1.]
Valid Values: Unconstrained
Explosion energy (distributed over 2^dimen central zones)
sim_nsubzones [INTEGER] [7]
Valid Values: Unconstrained
Number of `sub-zones' in cells for applying 1d profile
sim_pAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient pressure
sim_rInit [REAL] [0.05]
Valid Values: Unconstrained
Radial position of inner edge of grid (for 1D)
sim_rhoAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient density
sim_xctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_yctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_zctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
Simulation/SimulationMain/SedovChamber
sim_expEnergy [REAL] [1.]
Valid Values: Unconstrained
Explosion energy (distributed over 2^dimen central zones)
sim_nsubzones [INTEGER] [7]
Valid Values: Unconstrained
Number of `sub-zones' in cells for applying 1d profile
sim_pAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient pressure
sim_rInit [REAL] [0.05]
Valid Values: Unconstrained
Radial position of inner edge of grid (for 1D)
sim_rhoAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient density
sim_xctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_yctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_zctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
Simulation/SimulationMain/SedovChamber/WriteParticleSubset
sim_expEnergy [REAL] [1.]
Valid Values: Unconstrained
Explosion energy (distributed over 2^dimen central zones)
sim_nsubzones [INTEGER] [7]
Valid Values: Unconstrained
Number of `sub-zones' in cells for applying 1d profile
sim_pAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient pressure
sim_rInit [REAL] [0.05]
Valid Values: Unconstrained
Radial position of inner edge of grid (for 1D)
sim_rhoAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient density
sim_xctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_yctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_zctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
Simulation/SimulationMain/SedovSelfGravity
exp_energy [REAL] [1.]
Valid Values: Unconstrained
Explosion energy (distributed over 2^dimen central zones)
p_ambient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient pressure
r_init [REAL] [0.05]
Valid Values: Unconstrained
Radial position of the inner edge of the grid
rho_ambient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient density
sim_nsubzones [INTEGER] [7]
Valid Values: Unconstrained
Number of `sub-zones' to break cells into for applying 1d profile
t_init [REAL] [0.]
Valid Values: Unconstrained
Initial time since explosion
Simulation/SimulationMain/SedovSolidWall
sim_expEnergy [REAL] [1.]
Valid Values: Unconstrained
Explosion energy (distributed over 2^dimen central zones)
sim_nsubzones [INTEGER] [7]
Valid Values: Unconstrained
Number of `sub-zones' in cells for applying 1d profile
sim_pAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient pressure
sim_rInit [REAL] [0.05]
Valid Values: Unconstrained
Radial position of inner edge of grid (for 1D)
sim_rhoAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient density
sim_xctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_yctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
sim_zctr [REAL] [0.5]
Valid Values: Unconstrained
Explosion center coordinates
Simulation/SimulationMain/ShafranovShock
diff_scaleFactThermFlux [REAL] [0.0]
Valid Values: Unconstrained
Factor applied to the temperature differences (or internal energy
differences) that are added to flux arrays by the flux-based thermal
Diffusion implementation.
gamma [REAL] [1.6667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for gas - for initialization
sim_DataPoints [INTEGER] [448]
Valid Values: Unconstrained
Number of data points in sim_InitData file
sim_InitData [STRING] ["plasma_shock.out"]
Valid Values: Unconstrained
Name of the file containing input data
sim_ShockSpeed [REAL] [1.048805969E+06]
Valid Values: Unconstrained
Shock Speed
sim_abar [REAL] [1.0]
Valid Values: Unconstrained
Fluid atomic number
sim_maxTol [REAL] [2.0E-2]
Valid Values: Unconstrained
Max allowed error ( < 2% error)
sim_zbar [REAL] [1.0]
Valid Values: Unconstrained
Fluid average ionization
Simulation/SimulationMain/ShuOsher
sim_aRho [REAL] [0.2]
Valid Values: Unconstrained
Amplitude of the density perturbation
sim_fRho [REAL] [5.0]
Valid Values: Unconstrained
Frequency of the density perturbation
sim_nsubint [INTEGER] [100]
Valid Values: Unconstrained
Number of subintervals to average over to get cell-averages.
sim_pLeft [REAL] [10.33333]
Valid Values: Unconstrained
Pressure in left part of grid
sim_pRight [REAL] [1.0]
Valid Values: Unconstrained
Pressure in right part of grid
sim_posn [REAL] [-4.0]
Valid Values: Unconstrained
Point of intersection between the shock plane and the x-axis
sim_rhoLeft [REAL] [3.857143]
Valid Values: Unconstrained
Density in left part of grid
sim_rhoRight [REAL] [1.0]
Valid Values: Unconstrained
Density in right part of grid
sim_uLeft [REAL] [2.629369]
Valid Values: Unconstrained
Fluid velocity in right part of grid
sim_uRight [REAL] [0.]
Valid Values: Unconstrained
Fluid velocity in right part of grid
Simulation/SimulationMain/SinkRotatingCloudCore
bb_cs [REAL] [1.66e4]
Valid Values: Unconstrained
bb_dens [REAL] [3.82e-18]
Valid Values: Unconstrained
bb_omega [REAL] [7.2e-13]
Valid Values: Unconstrained
bb_radius [REAL] [5.0e16]
Valid Values: Unconstrained
refine_var_thresh [STRING] ["none"]
Valid Values: Unconstrained
Simulation/SimulationMain/Sod
gamma [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for gas - for initialization
gammaIon [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for ion component, should be 5./3.
sim_abarLeft [REAL] [1.]
Valid Values: 0 to INFTY
ion mean molecular weight of material on left
sim_abarRight [REAL] [1.]
Valid Values: 0 to INFTY
ion mean molecular weight of material on right
sim_confGeometry [STRING] ["none"]
Valid Values: "cartesian", "polar", "cylindrical", "spherical", "",
"none", "NONE", "default", "DEFAULT"
Geometry of the physical problem configuration (initial condition). If
empty, "none", or "default", use the Grid (coordinate) geometry for the
physical geometry.
sim_pLeft [REAL] [1.]
Valid Values: 0 to INFTY
Pressure in the left part of the grid
sim_pRight [REAL] [0.1]
Valid Values: 0 to INFTY
Pressure in the righ part of the grid
sim_peleLeft [REAL] [-1.0]
Valid Values: Unconstrained
sim_peleRight [REAL] [-1.0]
Valid Values: Unconstrained
sim_pionLeft [REAL] [-1.0]
Valid Values: Unconstrained
sim_pionRight [REAL] [-1.0]
Valid Values: Unconstrained
sim_posn [REAL] [0.5]
Valid Values: Unconstrained
sim_pradLeft [REAL] [-1.0]
Valid Values: Unconstrained
sim_pradRight [REAL] [-1.0]
Valid Values: Unconstrained
sim_rhoLeft [REAL] [1.]
Valid Values: 0 to INFTY
Density in the left part of the grid
sim_rhoRight [REAL] [0.125]
Valid Values: 0 to INFTY
Density in the right part of the grid
sim_uLeft [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the left part of the grid
sim_uRight [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the right part of the grid
sim_xangle [REAL] [0.]
Valid Values: 0 to 360
Angle made by diaphragm normal w/x-axis (deg)
sim_yangle [REAL] [90.]
Valid Values: 0 to 360
sim_zbarLeft [REAL] [1.]
Valid Values: 0 to INFTY
ion average charge for material on left
sim_zbarRight [REAL] [1.]
Valid Values: 0 to INFTY
ion average charge for material on right
Simulation/SimulationMain/SodSpherical
sim_idir [INTEGER] [1]
Valid Values: 1, 2
the direction along which to propagate the shock. sim_idir = 1 is
horizontal. sim_idir = 2 is vertical.
sim_pLeft [REAL] [1.]
Valid Values: Unconstrained
initial pressure on the left side of the interface
sim_pRight [REAL] [0.1]
Valid Values: Unconstrained
initial pressure on the right side of the interface
sim_rhoLeft [REAL] [1.]
Valid Values: Unconstrained
initial density left of the interface
sim_rhoRight [REAL] [0.125]
Valid Values: Unconstrained
initial density right of interface
sim_shockpos [REAL] [0.4]
Valid Values: Unconstrained
distance of the shock plane from y-axis (for sim_idir=1) or x-axis (for
sim_idir=2)
Simulation/SimulationMain/SodStep
gr_pmrpNboundaries [INTEGER] CONSTANT [6]
Valid Values: Unconstrained
sets value for PARAMESH runtime parameter nboundaries
nblockx [INTEGER] [4]
Valid Values: Unconstrained
num initial blocks in x dir
nblocky [INTEGER] [4]
Valid Values: Unconstrained
num initial blocks in y dir
nblockz [INTEGER] [1]
Valid Values: Unconstrained
num initial blocks in z dir
sim_pLeft [REAL] [1.]
Valid Values: 0 to INFTY
Pressure in the left part of the grid
sim_pRight [REAL] [0.1]
Valid Values: 0 to INFTY
Pressure in the righ part of the grid
sim_posn [REAL] [0.5]
Valid Values: Unconstrained
sim_rhoLeft [REAL] [1.]
Valid Values: 0 to INFTY
Density in the left part of the grid
sim_rhoRight [REAL] [0.125]
Valid Values: 0 to INFTY
Density in the right part of the grid
sim_stepInDomain [BOOLEAN] [false]
-- whether there is a missing block in the initial domain
sim_uLeft [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the left part of the grid
sim_uRight [REAL] [0.]
Valid Values: Unconstrained
fluid velocity in the right part of the grid
sim_xangle [REAL] [0.]
Valid Values: 0 to 360
Angle made by diaphragm normal w/x-axis (deg)
sim_yangle [REAL] [90.]
Valid Values: 0 to 360
Simulation/SimulationMain/StirFromFile
MagField_z [REAL] [1.e0]
Valid Values: Unconstrained
magnitude of constant B-field in z
c_ambient [REAL] [1.e0]
Valid Values: Unconstrained
reference sound speed
magnetic [BOOLEAN] [FALSE]
using magnetic field in z direction
rho_ambient [REAL] [1.e0]
Valid Values: Unconstrained
reference density
Simulation/SimulationMain/StirTurb
c_ambient [REAL] [1.e0]
Valid Values: Unconstrained
reference sound speed
mach [REAL] [0.3]
Valid Values: Unconstrained
reference mach number
rho_ambient [REAL] [1.e0]
Valid Values: Unconstrained
reference density
Simulation/SimulationMain/WindTunnel
gr_pmrpNboundaries [INTEGER] [16]
Valid Values: 16 to INFTY
sets value for PARAMESH runtime parameter nboundaries
sim_pAmbient [REAL] [1.0]
Valid Values: Unconstrained
sim_rhoAmbient [REAL] [1.4]
Valid Values: Unconstrained
sim_windVel [REAL] [3.0]
Valid Values: Unconstrained
Simulation/SimulationMain/incompFlow/TaylorGreenVortex
uconv [REAL] [0.0]
Valid Values: Unconstrained
vconv [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/AlWire
probType [INTEGER] [1]
Valid Values: Unconstrained
sim_densVac [REAL] [1.e-6]
Valid Values: Unconstrained
sim_densWire [REAL] [2.7]
Valid Values: Unconstrained
sim_rWire [REAL] [0.1]
Valid Values: Unconstrained
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/AnisoCond
bxinit [REAL] [0.0]
Valid Values: Unconstrained
byinit [REAL] [1.0]
Valid Values: Unconstrained
bzinit [REAL] [0.0]
Valid Values: Unconstrained
rhoinit [REAL] [1.0]
Valid Values: Unconstrained
tempinit [REAL] [1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/BlastBS
Bx0 [REAL] [100.]
Valid Values: Unconstrained
Initial magnitude of Bx
Radius [REAL] [0.1]
Valid Values: Unconstrained
Radius
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Threshold value used for numerical zero
xCtr [REAL] [0.]
Valid Values: Unconstrained
x center of the computational domain
yCtr [REAL] [0.]
Valid Values: Unconstrained
y center of the computational domain
zCtr [REAL] [0.]
Valid Values: Unconstrained
z center of the computatoinal domain
Simulation/SimulationMain/magnetoHD/BrioWu
b_normal [REAL] [0.75]
Valid Values: Unconstrained
Magnetic field normal component
by_left [REAL] [1.]
Valid Values: Unconstrained
by_right [REAL] [-1.]
Valid Values: Unconstrained
bz_left [REAL] [0.]
Valid Values: Unconstrained
bz_right [REAL] [0.]
Valid Values: Unconstrained
p_left [REAL] [1.]
Valid Values: Unconstrained
p_right [REAL] [0.1]
Valid Values: Unconstrained
posn [REAL] [0.5]
Valid Values: Unconstrained
Point of intersection between the shock plane and the x-axis
rho_left [REAL] [1.]
Valid Values: Unconstrained
rho_right [REAL] [0.125]
Valid Values: Unconstrained
rx [REAL] [0.]
Valid Values: Unconstrained
ry [REAL] [1.]
Valid Values: Unconstrained
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Threshold value used for numerical zero
u_left [REAL] [0.]
Valid Values: Unconstrained
u_right [REAL] [0.]
Valid Values: Unconstrained
v_left [REAL] [0.]
Valid Values: Unconstrained
v_right [REAL] [0.]
Valid Values: Unconstrained
w_left [REAL] [0.]
Valid Values: Unconstrained
w_right [REAL] [0.]
Valid Values: Unconstrained
xangle [REAL] [0.]
Valid Values: Unconstrained
Angle made by diaphragm normal w/x-axis (deg)
xmax [REAL] [1.]
Valid Values: Unconstrained
xmin [REAL] [0.]
Valid Values: Unconstrained
yangle [REAL] [90.]
Valid Values: Unconstrained
Angle made by diaphragm normal w/y-axis (deg)
ymax [REAL] [1.]
Valid Values: Unconstrained
ymin [REAL] [0.]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/CurrentSheet
B0 [REAL] [1.0]
Valid Values: Unconstrained
Magnitude of By
U0 [REAL] [0.1]
Valid Values: Unconstrained
Amplitude of U (x-velocity)
beta [REAL] [0.2]
Valid Values: Unconstrained
Initial beta plasma
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Threshold value used for a numerical zero
Simulation/SimulationMain/magnetoHD/FieldLoop
Az_initial [REAL] [0.001]
Valid Values: Unconstrained
Strength of initial z-component of magnetic vector potential
R_fieldLoop [REAL] [0.3]
Valid Values: Unconstrained
Radius of field loop
U_initial [REAL] [2.23606796749979]
Valid Values: Unconstrained
Strength of initial vector fields
rx [REAL] [1.]
Valid Values: Unconstrained
Field loop advection angle = atan(rx/ry)
ry [REAL] [2.]
Valid Values: Unconstrained
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Threshold value used for numerical zero
velz_initial [REAL] [0.0]
Valid Values: Unconstrained
xCtr [REAL] [1.]
Valid Values: Unconstrained
x center of the computational domain
yCtr [REAL] [0.5]
Valid Values: Unconstrained
y center of the computational domain
zCtr [REAL] [0.0]
Valid Values: Unconstrained
z center of the computatoinal domain
Simulation/SimulationMain/magnetoHD/GEM_challenge
sim_B0 [REAL] [28209.479177387817]
Valid Values: Unconstrained
Initial B0
sim_B1x [REAL] [692.3647855099672]
Valid Values: Unconstrained
Initial B1x
sim_B1y [REAL] [692.3647855099672]
Valid Values: Unconstrained
Initial B1y
sim_Lx [REAL] [0.023871169783685475]
Valid Values: Unconstrained
Initial Lx
sim_Ly [REAL] [0.011935584891842738]
Valid Values: Unconstrained
Initial Ly
sim_Te [REAL] [803.384663839]
Valid Values: Unconstrained
Initial Te
sim_Ti [REAL] [4016.92331919]
Valid Values: Unconstrained
Initial Ti
sim_killdivb [BOOLEAN] [FALSE]
CT
sim_lambda [REAL] [4.662337848376069e-4]
Valid Values: Unconstrained
Initial lambda
sim_rho [REAL] [0.001]
Valid Values: Unconstrained
Initial rho
sim_rhoInf [REAL] [0.0002]
Valid Values: Unconstrained
Initial rhoInf
Simulation/SimulationMain/magnetoHD/HallDriftWaves
sim_Artwood [REAL] [1.]
Valid Values: Unconstrained
Value of the Artwood number for the densiy profile
sim_BxAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient Bx field
sim_betaAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient beta
sim_dBPert [REAL] [1.]
Valid Values: Unconstrained
Initial amplitude of the perturbation
sim_dx0 [REAL] [1.]
Valid Values: Unconstrained
scale of the density gradient
sim_modeNumb [INTEGER] [1]
Valid Values: Unconstrained
Mode of the perturbation
sim_neAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient electron density
sim_x0 [REAL] [1.]
Valid Values: Unconstrained
position of the density maximum
Simulation/SimulationMain/magnetoHD/HallWhistlerWaves
sim_BxAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient Bx field
sim_betaAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient beta
sim_dBPert [REAL] [1.]
Valid Values: Unconstrained
Initial amplitude of the perturbation
sim_modeNumb [INTEGER] [1]
Valid Values: Unconstrained
Mode of the perturbation
sim_neAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient electron density
Simulation/SimulationMain/magnetoHD/Noh
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
unit_density [REAL] [1.e-5]
Valid Values: Unconstrained
unit_length [REAL] [1.0]
Valid Values: Unconstrained
unit_velocity [REAL] [1.e7]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/NohCylindrical
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
unit_density [REAL] [1.e-5]
Valid Values: Unconstrained
unit_length [REAL] [1.0]
Valid Values: Unconstrained
unit_velocity [REAL] [1.e7]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/OrszagTang
perturbation [REAL] [0.2]
Valid Values: Unconstrained
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Threshold value used for numerical zero
Simulation/SimulationMain/magnetoHD/Resistive
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/Rotor
Radius [REAL] [0.115]
Valid Values: Unconstrained
Radius
perturbZ [REAL] [0.2]
Valid Values: Unconstrained
small perturbation of velocity fields in z-direciton
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Threshold value used for numerical zero
xCtr [REAL] [0.]
Valid Values: Unconstrained
x center of the computational domain
yCtr [REAL] [0.]
Valid Values: Unconstrained
y center of the computational domain
zCtr [REAL] [0.]
Valid Values: Unconstrained
z center of the computatoinal domain
Simulation/SimulationMain/magnetoHD/Torus
BETA [REAL] [350.]
Valid Values: Unconstrained
Plasma beta
D_Con [REAL] [1.e-4]
Valid Values: Unconstrained
Density contrast between atmosphere and Torus
R_0 [REAL] [1.0]
Valid Values: Unconstrained
"Gravitational" radius in P-W potential (for R_0 = 0 -> Newton)
R_Sphere [REAL] [1.5]
Valid Values: Unconstrained
Radius of the sink region, must be greater than R_0
R_max [REAL] [4.7]
Valid Values: Unconstrained
Radius of the Torus where pressure is maximum
R_min [REAL] [3.0]
Valid Values: Unconstrained
Minimum cylindrical radius for the Torus (inner rim)
T_Con [REAL] [100.0]
Valid Values: Unconstrained
Temperature contrast between atmosphere and Torus
den_cut [REAL] [5.0]
Valid Values: Unconstrained
Minimum density to define the last contour of the magnetic vec. pot.
den_max [REAL] [10.0]
Valid Values: Unconstrained
Maximum density of the torus (outer rim)
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/ZPinch
sim_fill_ctr [REAL] [0.0]
Valid Values: Unconstrained
center of Gaussian density profile for fill species
sim_fill_dens [REAL] [9.8e-03]
Valid Values: Unconstrained
density of fill
sim_fill_maxTemp [REAL] [1.e12]
Valid Values: Unconstrained
maximum electron and ion tempeature allowed in fill
sim_fill_minDens [REAL] [0.0]
Valid Values: Unconstrained
min density used in Gaussian
sim_fill_minTemp [REAL] [1.e-12]
Valid Values: Unconstrained
minimum electron and ion tempeature allowed in fill
sim_fill_sigma [REAL] [0.082]
Valid Values: Unconstrained
controls width of Gaussian density profile for fill species
sim_fill_tele [REAL] [23210.]
Valid Values: Unconstrained
electron temperature of fill
sim_fill_tion [REAL] [23210.]
Valid Values: Unconstrained
ion temperature of fill
sim_fill_trad [REAL] [23210.]
Valid Values: Unconstrained
radiation temperature of fill
sim_innerRadius [REAL] [0.3]
Valid Values: Unconstrained
inner radius of liner
sim_line_ctr [REAL] [1.0]
Valid Values: Unconstrained
center of Gaussian density profile for liner species
sim_line_dens [REAL] [0.6]
Valid Values: Unconstrained
density of liner
sim_line_maxTemp [REAL] [1.e12]
Valid Values: Unconstrained
maximum electron and ion tempeature allowed in liner
sim_line_minDens [REAL] [0.0]
Valid Values: Unconstrained
min density used in Gaussian
sim_line_minTemp [REAL] [1.e-12]
Valid Values: Unconstrained
minimum electron and ion tempeature allowed in liner
sim_line_sigma [REAL] [0.220]
Valid Values: Unconstrained
controls width of Gaussian density profile for liner species
sim_line_tele [REAL] [23210.]
Valid Values: Unconstrained
electron temperature of liner
sim_line_tion [REAL] [23210.]
Valid Values: Unconstrained
ion temperature of liner
sim_line_trad [REAL] [23210.]
Valid Values: Unconstrained
radiation temperature of liner
sim_pert [REAL] [0.01]
Valid Values: Unconstrained
density perturbation of liner
sim_rNearStag [REAL] [50.e-4]
Valid Values: Unconstrained
radius defining "near stagnation", increased trajectory output frequency
sim_rhoType [INTEGER] [0]
Valid Values: Unconstrained
type of initial density profile
sim_seed [INTEGER] [1]
Valid Values: Unconstrained
seed for random density perturbation (makes sims repeatable)
sim_thickness [REAL] [0.1]
Valid Values: Unconstrained
thickness of liner
sim_trajOutputInterval [REAL] [1.e-10]
Valid Values: Unconstrained
trajectory output interval (s)
sim_trajOutputIntervalNearStag [REAL] [5.e-12]
Valid Values: Unconstrained
trajectory output interval near stagnation (s)
sim_vacu_dens [REAL] [1.e-06]
Valid Values: Unconstrained
density of vacuum
sim_vacu_maxTemp [REAL] [1.e12]
Valid Values: Unconstrained
maximum electron and ion tempeature allowed in vacuum
sim_vacu_minTemp [REAL] [1.e-12]
Valid Values: Unconstrained
minimum electron and ion tempeature allowed in vacuum
sim_vacu_tele [REAL] [290.11375]
Valid Values: Unconstrained
electron temperature of vacuum
sim_vacu_tion [REAL] [290.11375]
Valid Values: Unconstrained
ion temperature of vacuum
sim_vacu_trad [REAL] [290.11375]
Valid Values: Unconstrained
radiation temperature of vacuum
Simulation/SimulationMain/magnetoHD/unitTest/1DCyltest
sim_nsteps [INTEGER] [200]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/unitTest/1DCyltest_Ceszar
sim_nsteps [INTEGER] [200]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/unitTest/AnisoCond
bxinit [REAL] [0.0]
Valid Values: Unconstrained
byinit [REAL] [10.0]
Valid Values: Unconstrained
bzinit [REAL] [0.0]
Valid Values: Unconstrained
maxTol [REAL] [1.0E-3]
Valid Values: Unconstrained
rhoinit [REAL] [1.0]
Valid Values: Unconstrained
tempinit [REAL] [1.0]
Valid Values: Unconstrained
toff [REAL] [30.0E-9]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/unitTest/HallDriftWaves
sim_Artwood [REAL] [1.]
Valid Values: Unconstrained
Value of the Artwood number for the densiy profile
sim_BxAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient Bx field
sim_betaAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient beta
sim_dBPert [REAL] [1.]
Valid Values: Unconstrained
Initial amplitude of the perturbation
sim_dx0 [REAL] [1.]
Valid Values: Unconstrained
scale of the density gradient
sim_modeNumb [INTEGER] [1]
Valid Values: Unconstrained
Mode of the perturbation
sim_neAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient electron density
sim_sliceXloc [REAL] [14.0]
Valid Values: Unconstrained
where the lineout of Bz is taken
sim_x0 [REAL] [1.]
Valid Values: Unconstrained
position of the density maximum
Simulation/SimulationMain/magnetoHD/unitTest/HallWhistlerWaves
sim_BxAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient Bx field
sim_betaAmbient [REAL] [1.E-5]
Valid Values: Unconstrained
Initial ambient beta
sim_dBPert [REAL] [1.]
Valid Values: Unconstrained
Initial amplitude of the perturbation
sim_modeNumb [INTEGER] [1]
Valid Values: Unconstrained
Mode of the perturbation
sim_neAmbient [REAL] [1.]
Valid Values: Unconstrained
Initial ambient electron density
Simulation/SimulationMain/magnetoHD/unitTest/MagDiff
bxinit [REAL] [0.0]
Valid Values: Unconstrained
byinit [REAL] [1.0]
Valid Values: Unconstrained
bzinit [REAL] [0.0]
Valid Values: Unconstrained
res_constantPerpendicular [REAL] [0.0]
Valid Values: Unconstrained
rhoinit [REAL] [1.0]
Valid Values: Unconstrained
sim_BBackground [REAL] [0.0]
Valid Values: Unconstrained
sim_gaussComp [INTEGER] [1]
Valid Values: Unconstrained
B-field component radial/x-direction Gaussian profile is applied to
sim_solnFile [STRING] ["analytic.dat"]
Valid Values: Unconstrained
tempinit [REAL] [1.0]
Valid Values: Unconstrained
toffset [REAL] [3.0e-8]
Valid Values: Unconstrained
Simulation/SimulationMain/magnetoHD/unitTest/NohCylindricalRagelike
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
unit_density [REAL] [1.e-5]
Valid Values: Unconstrained
unit_length [REAL] [1.0]
Valid Values: Unconstrained
unit_velocity [REAL] [1.e7]
Valid Values: Unconstrained
Simulation/SimulationMain/python/LaserSlab
sim_eosCham [STRING] ["eos_gam"]
Valid Values: "eos_tab", "eos_gam"
chamber EOS type
sim_eosTarg [STRING] ["eos_tab"]
Valid Values: "eos_tab", "eos_gam"
chamber EOS type
sim_initGeom [STRING] ["slab"]
Valid Values: "slab", "sphere"
Use a spherical target if sphere, default to slab
sim_radSlab [BOOLEAN] [False]
Switch to enable radiation temperature BC
sim_radSourceFWHM [REAL] [1.e-9]
Valid Values: Unconstrained
fwhm of radiation source Gaussian
sim_radSourcePeak [REAL] [1.e-9]
Valid Values: Unconstrained
time at which radiation source Gaussian peaks
sim_radSourceStart [REAL] [0.]
Valid Values: Unconstrained
start time for radiation source
sim_radSourceStop [REAL] [1.e99]
Valid Values: Unconstrained
stop time for radiation source
sim_radSourceTMax [REAL] [500.]
Valid Values: Unconstrained
peak radiation temperature (eV) of the radiation source at domain
boundary
sim_radSourceTMin [REAL] [500.]
Valid Values: Unconstrained
minimum radiation temperature (eV) of the radiation source at domain
boundary
sim_radSourceType [INTEGER] [0]
Valid Values: Unconstrained
radiation source temperature type (0=constant, 1=Gaussian)
sim_rhoCham [REAL] [2.655e-07]
Valid Values: Unconstrained
Initial chamber density
sim_rhoTarg [REAL] [2.7]
Valid Values: Unconstrained
Initial target density
sim_targetHeight [REAL] [0.0250]
Valid Values: Unconstrained
The height of the target off y-axis
sim_targetRadius [REAL] [0.0050]
Valid Values: Unconstrained
The radius to use for the target
sim_teleCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber electron temperature
sim_teleTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target electron temperature
sim_tionCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber ion temperature
sim_tionTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target ion temperature
sim_tradCham [REAL] [290.11375]
Valid Values: Unconstrained
Initial chamber radiation temperature
sim_tradTarg [REAL] [290.11375]
Valid Values: Unconstrained
Initial target radiation temperature
sim_vacuumHeight [REAL] [0.0200]
Valid Values: Unconstrained
The thickness of the vacuum region in front of the target
sim_zminTarg [REAL] [0.0]
Valid Values: Unconstrained
target minimum zbar allowed
Simulation/SimulationMain/python/magnetoHD/AlWire
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
Simulation/SimulationMain/radflaHD/BondiAccretion
ExpEner [REAL] [1.0]
Valid Values: Unconstrained
bombRad [REAL] [1.0]
Valid Values: Unconstrained
bombRadIn [REAL] [1.0]
Valid Values: Unconstrained
coremass [REAL] [1.0]
Valid Values: Unconstrained
ener_exp [REAL] [1.0]
Valid Values: Unconstrained
gconst [REAL] [0.0]
Valid Values: Unconstrained
Gravitational constant, should be G*M(rmin)/rmin**2
gdirec [STRING] ["x"]
Valid Values: Unconstrained
hole_radius [REAL] [1.0]
Valid Values: Unconstrained
mass_loss [REAL] [0.0]
Valid Values: Unconstrained
model_file [STRING] ["file.dat"]
Valid Values: Unconstrained
Name of input file with 1D model
nsub [INTEGER] [4]
Valid Values: Unconstrained
paircond [BOOLEAN] [TRUE]
point_mass [REAL] [0.0]
Valid Values: Unconstrained
r_exp_max [REAL] [0.0]
Valid Values: Unconstrained
r_exp_min [REAL] [0.0]
Valid Values: Unconstrained
r_s [REAL] [0.0]
Valid Values: Unconstrained
rho_s [REAL] [0.0]
Valid Values: Unconstrained
rho_vac [REAL] [0.0]
Valid Values: Unconstrained
rinner [REAL] [1.0]
Valid Values: Unconstrained
router [REAL] [1.0]
Valid Values: Unconstrained
rt_s [REAL] [0.0]
Valid Values: Unconstrained
Same as r_s, but for temperature instead of density.
shellcond [BOOLEAN] [TRUE]
shelldens [REAL] [1.0]
Valid Values: Unconstrained
shelltempfac [REAL] [1.0]
Valid Values: Unconstrained
sim_TradInitScaleFactor [REAL] [1.0]
Valid Values: Unconstrained
scale initial radiation temperature value by this factor.
sim_accretionRate [REAL] [1.0]
Valid Values: Unconstrained
Desired acrretion rate that will be used for the boundary conditions
sim_initializeAnalytic [BOOLEAN] [TRUE]
Initialize Hydro variables (density, velocity) to the analytical
solution?
sim_plotScaledPressures [BOOLEAN] [FALSE]
indicates whether Eo_wrapped should be called before variables are
output to plot files and checkpoints, with the appropriate mode to make
sure that radiation pressure, and related variables like pres, gamc, and
game, are scaled down by a flux limiter factor (3*lambda).
sim_tele [REAL] [1.0]
Valid Values: Unconstrained
sim_tion [REAL] [1.0]
Valid Values: Unconstrained
sim_trad [REAL] [1.0]
Valid Values: Unconstrained
staticGpot [BOOLEAN] [FALSE]
Flag for whether or not to fix the gpot in time
t_s [REAL] [0.0]
Valid Values: Unconstrained
t_vac [REAL] [0.0]
Valid Values: Unconstrained
vel_mult [REAL] [1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/radflaHD/CriticalRadShock
sim_M0 [REAL] [1.0]
Valid Values: Unconstrained
shock mach number
sim_P0 [REAL] [1.0]
Valid Values: Unconstrained
ratio of radiation pressure to material pressure
sim_rho [REAL] [1.0]
Valid Values: Unconstrained
reference density
sim_tgas [REAL] [1.0]
Valid Values: Unconstrained
gas temperature
sim_trad [REAL] [1.0]
Valid Values: Unconstrained
radiation temperature
sim_velx [REAL] [1.0]
Valid Values: Unconstrained
speed of gas
Simulation/SimulationMain/radflaHD/EnergyXchange
sim_rho [REAL] [1.0]
Valid Values: Unconstrained
Initial radiation temperature
sim_tele [REAL] [1.0]
Valid Values: Unconstrained
sim_tion [REAL] [1.0]
Valid Values: Unconstrained
sim_trad [REAL] [1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/radflaHD/RadBlastWave
gconst [REAL] [0.0]
Valid Values: Unconstrained
Gravitational constant, should be G*M(rmin)/rmin**2
gdirec [STRING] ["x"]
Valid Values: Unconstrained
hole_radius [REAL] [1.0]
Valid Values: Unconstrained
model_file [STRING] ["file.dat"]
Valid Values: Unconstrained
Name of input file with 1D model
nsub [INTEGER] [4]
Valid Values: Unconstrained
paircond [BOOLEAN] [TRUE]
point_mass [REAL] [0.0]
Valid Values: Unconstrained
r_exp_max [REAL] [0.0]
Valid Values: Unconstrained
r_exp_min [REAL] [0.0]
Valid Values: Unconstrained
r_s [REAL] [0.0]
Valid Values: Unconstrained
rho_s [REAL] [0.0]
Valid Values: Unconstrained
rho_vac [REAL] [0.0]
Valid Values: Unconstrained
shellcond [BOOLEAN] [TRUE]
sim_plotScaledPressures [BOOLEAN] [FALSE]
indicates whether Eo_wrapped should be called before variables are
output to plot files and checkpoints, with the appropriate mode to make
sure that radiation pressure, and related variables like pres, gamc, and
game, are scaled down by a flux limiter factor (3*lambda).
sim_tele [REAL] [1.0]
Valid Values: Unconstrained
sim_tion [REAL] [1.0]
Valid Values: Unconstrained
sim_trad [REAL] [1.0]
Valid Values: Unconstrained
staticGpot [BOOLEAN] [FALSE]
Flag for whether or not to fix the gpot in time
steep [REAL] [0.0]
Valid Values: Unconstrained
t_s [REAL] [0.0]
Valid Values: Unconstrained
t_vac [REAL] [0.0]
Valid Values: Unconstrained
use_PnotT [BOOLEAN] [FALSE]
Simulation/SimulationMain/radflaHD/SupernovaRad1D
ExpEner [REAL] [0.0]
Valid Values: Unconstrained
ener_exp [REAL] [0.0]
Valid Values: Unconstrained
mass_loss [REAL] [0.0]
Valid Values: Unconstrained
model_file [STRING] ["file.dat"]
Valid Values: Unconstrained
Name of input file with 1D model
nsub [INTEGER] [4]
Valid Values: Unconstrained
r_exp_max [REAL] [0.0]
Valid Values: Unconstrained
r_exp_min [REAL] [0.0]
Valid Values: Unconstrained
shelltempfac [REAL] [1.0]
Valid Values: Unconstrained
sim_steep [REAL] [1.0]
Valid Values: Unconstrained
sim_tele [REAL] [1.0]
Valid Values: Unconstrained
sim_tion [REAL] [1.0]
Valid Values: Unconstrained
sim_trad [REAL] [1.0]
Valid Values: Unconstrained
vel_mult [REAL] [1.0]
Valid Values: Unconstrained
vel_wind [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/BiCG_XYdir_2D
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Burn
compA [STRING] ["c12"]
Valid Values: Unconstrained
name of composition at -x end of domain
compB [STRING] ["n56"]
Valid Values: Unconstrained
name of composition at +x end of domain
rhoMax [REAL] [2.e8]
Valid Values: Unconstrained
density at +y end of domain
rhoMin [REAL] [2.e8]
Valid Values: Unconstrained
density at -y end of domain
tempMax [REAL] [2.e8]
Valid Values: Unconstrained
temp at +z end of domain
tempMin [REAL] [1.e6]
Valid Values: Unconstrained
temp at -z end of domain
Simulation/SimulationMain/unitTest/Cool/SutherlandDopita
eintSwitch [REAL] [0.0]
Valid Values: Unconstrained
sim_densMax [REAL] [1.e8]
Valid Values: Unconstrained
Initial distribution of density, maximum.
sim_densMin [REAL] [1.e-2]
Valid Values: Unconstrained
Initial distribution of density, minimum.
sim_initialMass [INTEGER] [-1]
Valid Values: -1 to INFTY
Distribution of initial mass. -1 to put gradient in SPEC(1) and
SPEC(NSPECIES) 0 to divide evenly throughout SPECIES i to put all mass
on SPECIES i
sim_tempMax [REAL] [1.e9]
Valid Values: Unconstrained
Initial distribution of temperature, maximum.
sim_tempMin [REAL] [1.e5]
Valid Values: Unconstrained
Initial distribution of temperature, minimum.
sim_xnMax [REAL] [1.0]
Valid Values: Unconstrained
Initial distribution of a single species, maximum.
sim_xnMin [REAL] [1.e-10]
Valid Values: Unconstrained
Initial distribution of a single species, minimum.
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
Simulation/SimulationMain/unitTest/Cosmology
eintSwitch [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Eos
eosMode [STRING] ["dens_temp"]
Valid Values: Unconstrained
The Mode for applying Eos
sim_densMax [REAL] [1.e8]
Valid Values: Unconstrained
Initial distribution of density, maximum. Even distribution between
logarithm of min/max.
sim_densMin [REAL] [1.e-2]
Valid Values: Unconstrained
Initial distribution of density, minimum. Even distribution between
logarithm of min/max.
sim_initialMass [INTEGER] [-1]
Valid Values: -1 to INFTY
Distribution of initial mass. -1 to put gradient in SPEC(1) and
SPEC(NSPECIES) 0 to divide evenly throughout SPECIES i to put all mass
on SPECIES i
sim_presMax [REAL] [1.e7]
Valid Values: Unconstrained
Initial distribution of pressure, maximum. Even distribution between
logarithm of min/max
sim_presMin [REAL] [1.e-2]
Valid Values: Unconstrained
Initial distribution of pressure, minimum. Even distribution between
logarithm of min/max
sim_tempMax [REAL] [1.e9]
Valid Values: Unconstrained
Initial distribution of temperature, maximum. Even distribution between
logarithm of min/max
sim_tempMin [REAL] [1.e5]
Valid Values: Unconstrained
Initial distribution of temperature, minimum. Even distribution between
logarithm of min/max
sim_xnMax [REAL] [1.0]
Valid Values: Unconstrained
Initial distribution of a single species, maximum. Even distribution
between logarithm of min/max
sim_xnMin [REAL] [1.e-10]
Valid Values: Unconstrained
Initial distribution of a single species, minimum. Even distribution
between logarithm of min/max
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
Simulation/SimulationMain/unitTest/Eos/timeEosUnitTest
num_eos_calls [INTEGER] [30000]
Valid Values: 1 to INFTY
Simulation/SimulationMain/unitTest/Gravity/BHTree
abar_1 [REAL] [2.0]
Valid Values: Unconstrained
abar_2 [REAL] [0.5]
Valid Values: Unconstrained
gamma_1 [REAL] [1.0001]
Valid Values: Unconstrained
gamma_2 [REAL] [1.0001]
Valid Values: Unconstrained
jeans_deref [REAL] [64.0]
Valid Values: Unconstrained
Jeans derefinement criterion. Gives number of cells accross the Jeans
length to derefine.
jeans_ref [REAL] [32.0]
Valid Values: Unconstrained
Jeans refinement criterion. Gives number of cells accross the Jeans
length to refine.
sim_nSubZones [INTEGER] [2]
Valid Values: Unconstrained
sim_pertType [INTEGER] [0]
Valid Values: Unconstrained
sim_pertamp [REAL] [0.0]
Valid Values: Unconstrained
sim_radprof_file [STRING] ["be1sm+1+4-xi10"]
Valid Values: Unconstrained
sim_solutionErrorTolerance1 [REAL] [5.e-3]
Valid Values: 0 to INFTY
the maximum relative deviation of the computed from the analytical
potential for which the test shall be considered a success. This
tolerance is applied immediately after the potential is computed
numerically for the first time.
sim_solutionErrorTolerance2 [REAL] [5.e-3]
Valid Values: 0 to INFTY
the maximum relative deviation of the computed from the analytical
potential for which the test shall be considered a success. This
tolerance is applied after each time evolution step (if the test is
configured to do time steps, by choice of the 'nend' runtime parameter
etc.).
sim_spharm_l1 [INTEGER] [0]
Valid Values: Unconstrained
sim_spharm_m1 [INTEGER] [0]
Valid Values: Unconstrained
sim_velamp [REAL] [0.0]
Valid Values: Unconstrained
sim_vx [REAL] [0.0]
Valid Values: Unconstrained
sim_vy [REAL] [0.0]
Valid Values: Unconstrained
sim_vz [REAL] [0.0]
Valid Values: Unconstrained
sim_xCenter [REAL] [0.0]
Valid Values: Unconstrained
sim_yCenter [REAL] [0.0]
Valid Values: Unconstrained
sim_zCenter [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Gravity/BHTree-cylinder
abar_1 [REAL] [2.3]
Valid Values: Unconstrained
abar_2 [REAL] [0.6]
Valid Values: Unconstrained
gamma_1 [REAL] [1.0001]
Valid Values: Unconstrained
gamma_2 [REAL] [1.0001]
Valid Values: Unconstrained
sim_dens_c [REAL] [1.6605387e-24]
Valid Values: Unconstrained
Density inside cylinder
sim_press_a [REAL] [6.853383244768104e-16]
Valid Values: Unconstrained
Pressure outside the cylinder
sim_solutionErrorTolerance1 [REAL] [1.e-3]
Valid Values: 0 to INFTY
sim_solutionErrorTolerance2 [REAL] [1.e-3]
Valid Values: 0 to INFTY
sim_temp_a [REAL] [100.0]
Valid Values: Unconstrained
Temperature outside cylinder
sim_temp_c [REAL] [10.0]
Valid Values: Unconstrained
Temperature inside cylinder
Simulation/SimulationMain/unitTest/Gravity/BHTree-jeans
abar_1 [REAL] [1.0]
Valid Values: Unconstrained
gamma_1 [REAL] [1.0001]
Valid Values: Unconstrained
sim_T0 [REAL] [1.0e4]
Valid Values: Unconstrained
sim_delta [REAL] [0.1]
Valid Values: Unconstrained
sim_hx [REAL] [3.0]
Valid Values: Unconstrained
sim_hy [REAL] [0.0]
Valid Values: Unconstrained
sim_hz [REAL] [0.0]
Valid Values: Unconstrained
sim_rho0 [REAL] [1.6605387e-24]
Valid Values: Unconstrained
sim_solutionErrorTolerance1 [REAL] [1.e-3]
Valid Values: 0 to INFTY
the maximum relative deviation of the computed from the analytical
potential for which the test shall be considered a success. This
tolerance is applied immediately after the potential is computed
numerically for the first time.
sim_solutionErrorTolerance2 [REAL] [1.e-3]
Valid Values: 0 to INFTY
the maximum relative deviation of the computed from the analytical
potential for which the test shall be considered a success. This
tolerance is applied after each time evolution step (if the test is
configured to do time steps, by choice of the 'nend' runtime parameter
etc.).
Simulation/SimulationMain/unitTest/Gravity/BHTree-layer
abar_1 [REAL] [1.0]
Valid Values: Unconstrained
gamma_1 [REAL] [1.0001]
Valid Values: Unconstrained
sim_dir [INTEGER] [3]
Valid Values: Unconstrained
sim_prof_file [STRING] ["layer_prof"]
Valid Values: Unconstrained
sim_solutionErrorTolerance1 [REAL] [1.e-3]
Valid Values: 0 to INFTY
the maximum relative deviation of the computed from the analytical
potential for which the test shall be considered a success. This
tolerance is applied immediately after the potential is computed
numerically for the first time.
sim_solutionErrorTolerance2 [REAL] [1.e-3]
Valid Values: 0 to INFTY
the maximum relative deviation of the computed from the analytical
potential for which the test shall be considered a success. This
tolerance is applied after each time evolution step (if the test is
configured to do time steps, by choice of the 'nend' runtime parameter
etc.).
sim_zMidplane [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Gravity/Poisson
sim_subSample [INTEGER] [7]
Valid Values: 1 to 12
Reflects the subsampling philosophy of Multipole. See
physics/Grid/GridSolvers/Multipole/Config/mpole_subSample
Simulation/SimulationMain/unitTest/Gravity/Poisson2
convertToConsvdInMeshInterp [BOOLEAN] [FALSE]
indicates if appropriate variables are converted to conserved form
during propagation within the interpolation routines invoked by
Paramesh. No variables should be converted back and forth in this test.
density [REAL] [10.0]
Valid Values: Unconstrained
discRadius [REAL] [1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Gravity/Poisson3
angular_velocity [REAL] [0.]
Valid Values: Unconstrained
Dimensionless angular velocity (Omega)
density [REAL] [1.]
Valid Values: -1.0 to INFTY
Spheroid density (rho): set to -1 to generate spheroid mass of 1.0
eccentricity [REAL] [0.]
Valid Values: 0.0 to 1.0
Eccentricity of the ellipsoid (e)
equatorial_semimajor_axis [REAL] [1.]
Valid Values: 0.0 to INFTY
Equatorial semimajor axis (a1)
nsubzones [INTEGER] [2]
Valid Values: 1 to INFTY
Number of sub-zones per dimension
pass_tolerance [REAL] [0.015]
Valid Values: 0.00000000000001 to 1.0
Allowed error for testing. 0.015 = 1.5 percent error
xctr [REAL] [0.5]
Valid Values: Unconstrained
X-coordinate of center of spheroid
yctr [REAL] [0.5]
Valid Values: Unconstrained
Y-coordinate of center of spheroid
zctr [REAL] [0.5]
Valid Values: Unconstrained
Z-coordinate of center of spheroid
Simulation/SimulationMain/unitTest/Gravity/Poisson3/timeMultipole
num_poisson_solves [INTEGER] [100]
Valid Values: 1 to INFTY
Simulation/SimulationMain/unitTest/Gravity/Poisson3_active
angular_velocity [REAL] [0.]
Valid Values: Unconstrained
Dimensionless angular velocity (Omega)
density [REAL] [1.]
Valid Values: -1.0 to INFTY
Spheroid density (rho): set to -1 to generate spheroid mass of 1.0
eccentricity [REAL] [0.]
Valid Values: 0.0 to 1.0
Eccentricity of the ellipsoid (e)
equatorial_semimajor_axis [REAL] [1.]
Valid Values: 0.0 to INFTY
Equatorial semimajor axis (a1)
nsubzones [INTEGER] [2]
Valid Values: 1 to INFTY
Number of sub-zones per dimension
pass_tolerance [REAL] [0.015]
Valid Values: 0.00000000000001 to 1.0
Allowed error for testing. 0.015 = 1.5 percent error
xctr [REAL] [0.5]
Valid Values: Unconstrained
X-coordinate of center of spheroid
yctr [REAL] [0.5]
Valid Values: Unconstrained
Y-coordinate of center of spheroid
zctr [REAL] [0.5]
Valid Values: Unconstrained
Z-coordinate of center of spheroid
Simulation/SimulationMain/unitTest/IO/IOMeshReplication
totalSharedVars [INTEGER] [12]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Laser_RingOn3DCylCan/AngAcc
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
Simulation/SimulationMain/unitTest/Laser_RingOn3DCylCan/NoAcc
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
Simulation/SimulationMain/unitTest/Laser_RingOn3DCylCan/RadAcc
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
Simulation/SimulationMain/unitTest/Laser_RingOn3DCylCan/RadAngAcc
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
Simulation/SimulationMain/unitTest/Laser_quadraticTube/testI
sim_lasersOrientation [STRING] [" "]
Valid Values: Unconstrained
The orientation of the lasers
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
Simulation/SimulationMain/unitTest/Laser_quadraticTube/testII
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
Simulation/SimulationMain/unitTest/Multipole
density [REAL] [1.]
Valid Values: -1.0 to INFTY
Spheroid density (rho): set to -1 to generate spheroid mass of 1.0
eccentricity [REAL] [0.]
Valid Values: 0.0 to 1.0
Eccentricity of the ellipsoid (e)
equatorialSemimajorAxis [REAL] [1.]
Valid Values: 0.0 to INFTY
Equatorial semimajor axis (a1)
nsubzones [INTEGER] [2]
Valid Values: 1 to INFTY
Number of sub-zones per dimension
passTolerance [REAL] [0.015]
Valid Values: 0.00000000000001 to 1.0
Allowed error for testing. 0.015 = 1.5 percent error
xctr [REAL] [0.5]
Valid Values: Unconstrained
X-coordinate of center of spheroid
yctr [REAL] [0.5]
Valid Values: Unconstrained
Y-coordinate of center of spheroid
zctr [REAL] [0.5]
Valid Values: Unconstrained
Z-coordinate of center of spheroid
Simulation/SimulationMain/unitTest/PFFT_BlktriFD
alpha_x [REAL] [0.]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/PFFT_PoissonParabolae
alpha_x [REAL] [0.]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [2.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [0.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/PFFT_XYdir_2D_MG
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/PFFT_XYperZneuFD
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/PFFT_XYperZneu_GenDir
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/PFFT_XYperZneu_MC
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/PFFT_XYperneu_GenDir2D
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/PFFT_XYperneu_GenDir2D_MC
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Particles
sim_addPartCount [INTEGER] [0]
Valid Values: 0 to INFTY
Number of particles to be added by each MPI task during "evolution" in
this test
sim_addPartDisp [REAL] [0.1]
Valid Values: 0.0 to INFTY
Offset from left domain side and spacing of the particles added during
"evolution" in this test, in multiples of the domain size.
sim_p_amb [REAL] [8.e5]
Valid Values: Unconstrained
Gas Pressure: Entire domain receives this ambient parameter
sim_rho_amb [REAL] [0.95e-3]
Valid Values: Unconstrained
Gas Density: Entire domain receives this ambient parameter
sim_seed [REAL] [1.0]
Valid Values: Unconstrained
Random number seed -- NOT USED please ignore
sim_vx_amb [REAL] [0.5]
Valid Values: Unconstrained
Gas x-velocity: Dominant flow velocity throughout domain
sim_vx_multiplier [REAL] [1.0]
Valid Values: Unconstrained
Half of the domain in y has x-velocity multiplied by this value
sim_vx_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in x direction: set to zero for uniform flow
sim_vy_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in y direction: set to zero for uniform flow
sim_vz_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in z direction: set to zero for uniform flow
Simulation/SimulationMain/unitTest/ParticlesAdvance
sim_maxTolCoeff0 [REAL] [1.0e-8]
Valid Values: Unconstrained
sim_maxTolCoeff1 [REAL] [0.0001]
Valid Values: Unconstrained
sim_maxTolCoeff2 [REAL] [0.01]
Valid Values: Unconstrained
sim_maxTolCoeff3 [REAL] [0.0]
Valid Values: Unconstrained
sim_schemeOrder [INTEGER] [2]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/ParticlesAdvance/HomologousPassive
sim_a0 [REAL] [1.0]
Valid Values: Unconstrained
constant component of velocity field factor a(t)
sim_a1 [REAL] [0.1]
Valid Values: Unconstrained
varying part of velocity field factor a(t)
sim_analyticParticlePositions [BOOLEAN] [FALSE]
sim_fakeMapMeshToParticles [BOOLEAN] [TRUE]
sim_p_amb [REAL] [8.e5]
Valid Values: Unconstrained
Gas Pressure: Entire domain receives this ambient parameter
sim_rho_amb [REAL] [0.95e-3]
Valid Values: Unconstrained
Gas Density: Entire domain receives this ambient parameter
sim_seed [REAL] [1.0]
Valid Values: Unconstrained
Random number seed -- NOT USED please ignore
sim_vx_amb [REAL] [0.5]
Valid Values: Unconstrained
Gas x-velocity: Dominant flow velocity throughout domain
sim_vx_multiplier [REAL] [1.0]
Valid Values: Unconstrained
Half of the domain in y has x-velocity multiplied by this value
sim_vx_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in x direction: set to zero for uniform flow
sim_vy_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in y direction: set to zero for uniform flow
sim_vz_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in z direction: set to zero for uniform flow
Simulation/SimulationMain/unitTest/ParticlesRefine
sim_densityThreshold [REAL] [0.85]
Valid Values: Unconstrained
the level of density in any cell above which the particles are used to
simulate the mass in the domain. This formulation is used only to test
refinement based on particles.
sim_minBlks [INTEGER] [40]
Valid Values: Unconstrained
parameter to ensure that refinement is taking place
sim_ptMass [REAL] [0.005]
Valid Values: Unconstrained
mass of one particles when replacing some mass in the domain with active
particles to test refinement based on particles count
sim_smlRho [REAL] [1.e-10]
Valid Values: Unconstrained
the smallest allowed value of density so that we don't have overflow in
calculations.
Simulation/SimulationMain/unitTest/Pfft
sim_jprocs [INTEGER] [1]
Valid Values: Unconstrained
sim_kprocs [INTEGER] [1]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Pfft_TransposeTest
output_grid_data [BOOLEAN] [true]
creates files for each processor that
Simulation/SimulationMain/unitTest/Pipeline
sim_channelSize [INTEGER] [50]
Valid Values: Unconstrained
The pipeline channel size to be used
sim_itemSize [INTEGER] [10]
Valid Values: Unconstrained
The number of elements in each item
sim_lowestNumItemsOnProc [INTEGER] [100]
Valid Values: Unconstrained
The lowest number of items to reach a processor
sim_maxItemsPipeline [INTEGER] [100]
Valid Values: Unconstrained
The maximum number of items that the pipeline can handle
Simulation/SimulationMain/unitTest/Poisson/BiCG/MgMCPfft
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Poisson/MgMC
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/PoissonWithFFT
lx [REAL] [0.0]
Valid Values: Unconstrained
ly [REAL] [0.0]
Valid Values: Unconstrained
ux [REAL] [1.0]
Valid Values: Unconstrained
uy [REAL] [1.0]
Valid Values: Unconstrained
xGridSize [INTEGER] [32]
Valid Values: Unconstrained
yGridSize [INTEGER] [32]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/ProtonEmission/Validation
sim_cellNumberEmittedProtons [INTEGER] [0]
Valid Values: Unconstrained
The wanted number of emitted protons per cell
sim_clockwiseB [BOOLEAN] [false]
Should B point clockwise (inward force) from each radial position?
sim_magneticFluxDensity [REAL] [0.0]
Valid Values: Unconstrained
The value of the magnetic flux density B
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
sim_xCenter [REAL] [0.5]
Valid Values: Unconstrained
The x-coordinate of the center location
sim_zCenter [REAL] [0.5]
Valid Values: Unconstrained
The z-coordinate of the center location
Simulation/SimulationMain/unitTest/ProtonImaging/CircleDeflection
sim_clockwiseB [BOOLEAN] [false]
Should B point clockwise (inward force) from each radial position?
sim_electricField [REAL] [0.0]
Valid Values: Unconstrained
The value of the electric field E
sim_electricFieldDeflection [BOOLEAN] [false]
Test the electric field deflection?
sim_magneticFluxDensity [REAL] [0.0]
Valid Values: Unconstrained
The value of the magnetic flux density B
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
sim_xCenter [REAL] [0.5]
Valid Values: Unconstrained
The x-coordinate of the center location
sim_zCenter [REAL] [0.5]
Valid Values: Unconstrained
The z-coordinate of the center location
Simulation/SimulationMain/unitTest/RayPath
sim_fileRay [STRING] ["rayIncidence.txt"]
Valid Values: Unconstrained
sim_ilBnd [REAL] [0.25]
Valid Values: Unconstrained
sim_iuBnd [REAL] [0.75]
Valid Values: Unconstrained
sim_jlBnd [REAL] [0.25]
Valid Values: Unconstrained
sim_juBnd [REAL] [0.75]
Valid Values: Unconstrained
sim_klBnd [REAL] [0.25]
Valid Values: Unconstrained
sim_kuBnd [REAL] [0.75]
Valid Values: Unconstrained
sim_numRay [INTEGER] [1]
Valid Values: Unconstrained
sim_refract [REAL] [2.0]
Valid Values: Unconstrained
sim_refractType [STRING] ["linear"]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/Roots/x3Polynomials
sim_printInfo [BOOLEAN] [false]
Should details about solving each polynomial be printed
Simulation/SimulationMain/unitTest/Roots/x4Polynomials
sim_printInfo [BOOLEAN] [false]
Should details about solving each polynomial be printed
Simulation/SimulationMain/unitTest/RungeKutta/2Dellipse
sim_RungeKuttaMethod [STRING] ["CashKarp45"]
Valid Values: Unconstrained
The method for the Runge Kutta stepper
sim_ellipseAspectRatio [REAL] [2.0]
Valid Values: Unconstrained
The ellipse aspect ratio (major:minor axis)
sim_errorFraction [REAL] [1.0e-8]
Valid Values: Unconstrained
The error fraction for the dependent variables
sim_numberOfEllipses [INTEGER] [1]
Valid Values: Unconstrained
The number of ellipses the particle has to sweep
sim_stepSize [REAL] [0.1]
Valid Values: Unconstrained
The step size
sim_x0 [REAL] [1.0]
Valid Values: Unconstrained
The initial x position of the particle
sim_y0 [REAL] [1.0]
Valid Values: Unconstrained
The initial y position of the particle
Simulation/SimulationMain/unitTest/RungeKutta/3Dcircle
sim_RungeKuttaMethod [STRING] ["Fehlberg45"]
Valid Values: Unconstrained
The method for the Runge Kutta stepper
sim_errorFraction [REAL] [1.0e-8]
Valid Values: Unconstrained
The error fraction for the dependent variables
sim_numberOfCircles [INTEGER] [1]
Valid Values: Unconstrained
The number of circles the particle has to sweep
sim_numberOfRungeKuttaSteps [INTEGER] [10]
Valid Values: Unconstrained
The number of Runge Kutta steps to be performed
sim_rx0 [REAL] [1.0]
Valid Values: Unconstrained
The initial x position of the particle
sim_ry0 [REAL] [1.0]
Valid Values: Unconstrained
The initial y position of the particle
sim_rz0 [REAL] [1.0]
Valid Values: Unconstrained
The initial z position of the particle
sim_speed [REAL] [1.0]
Valid Values: Unconstrained
The speed of the particle
sim_stepSize [REAL] [0.1]
Valid Values: Unconstrained
The step size
Simulation/SimulationMain/unitTest/RungeKutta/BinomialODE
sim_RungeKuttaMethod [STRING] ["CashKarp45"]
Valid Values: Unconstrained
The method for the Runge Kutta stepper
sim_errorFraction [REAL] [1.0e-8]
Valid Values: Unconstrained
The error fraction for the dependent variables
sim_orderODE [INTEGER] [5]
Valid Values: Unconstrained
The order of the binomial ODE
sim_stepSize [REAL] [0.1]
Valid Values: Unconstrained
The step size
sim_xLast [REAL] [10.0]
Valid Values: Unconstrained
The last x value for the independent variable
sim_xStart [REAL] [0.0]
Valid Values: Unconstrained
The starting x value for the independent variable
Simulation/SimulationMain/unitTest/SinkMomTest
refine_var_thresh [STRING] ["none"]
Valid Values: Unconstrained
sim_cs [REAL] [1.0]
Valid Values: Unconstrained
sim_dens [REAL] [1.0]
Valid Values: Unconstrained
sim_massTol [REAL] [1.e20]
Valid Values: Unconstrained
sim_momXTol [REAL] [1.e32]
Valid Values: Unconstrained
sim_momYTol [REAL] [1.e32]
Valid Values: Unconstrained
sim_momZTol [REAL] [1.e32]
Valid Values: Unconstrained
sim_radius [REAL] [1.0]
Valid Values: Unconstrained
sim_sink_mass [REAL] [0.0]
Valid Values: Unconstrained
sim_sink_vx [REAL] [0.0]
Valid Values: Unconstrained
sim_sink_vy [REAL] [0.0]
Valid Values: Unconstrained
sim_sink_vz [REAL] [0.0]
Valid Values: Unconstrained
sim_sink_x [REAL] [0.0]
Valid Values: Unconstrained
sim_sink_y [REAL] [0.0]
Valid Values: Unconstrained
sim_sink_z [REAL] [0.0]
Valid Values: Unconstrained
sim_vx [REAL] [0.0]
Valid Values: Unconstrained
sim_vy [REAL] [0.0]
Valid Values: Unconstrained
sim_vz [REAL] [0.0]
Valid Values: Unconstrained
sim_xcenter [REAL] [0.0]
Valid Values: Unconstrained
sim_ycenter [REAL] [0.0]
Valid Values: Unconstrained
sim_zcenter [REAL] [0.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/SolidBody/MultipleWithTriangles
sb_xmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_xmin [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymax [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymin [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmin [REAL] [-1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/SolidBody/MultipleWithTriangles/MovingBodies
sb_xmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_xmin [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymax [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymin [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmin [REAL] [-1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/SolidBody/MultipleWithTriangles/MovingBodies/NoComm
sb_xmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_xmin [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymax [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymin [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmin [REAL] [-1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/SolidBody/MultipleWithTriangles/MovingBodies/NoComm/Bitmap
sb_xmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_xmin [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymax [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymin [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmin [REAL] [-1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/SolidBody/Single
sb_xmax [REAL] [0.7]
Valid Values: Unconstrained
sb_xmin [REAL] [0.4]
Valid Values: Unconstrained
sb_ymax [REAL] [0.7]
Valid Values: Unconstrained
sb_ymin [REAL] [0.4]
Valid Values: Unconstrained
sb_zmax [REAL] [0.7]
Valid Values: Unconstrained
sb_zmin [REAL] [0.4]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/SolidBody/SingleWithTriangles
sb_xmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_xmin [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymax [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymin [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmin [REAL] [-1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/SolidBody/SingleWithTriangles/MovingBody
sb_xmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_xmin [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymax [REAL] [-1.0]
Valid Values: Unconstrained
sb_ymin [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmax [REAL] [-1.0]
Valid Values: Unconstrained
sb_zmin [REAL] [-1.0]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/ThomsonScattering/NoRayTracing
sim_densitySUR [REAL] [-1.0]
Valid Values: Unconstrained
Density of surrounding material
sim_densityTSM [REAL] [-1.0]
Valid Values: Unconstrained
Density of Thomson scattering material sphere
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
sim_sphereTSMcenterX [REAL] [0.0]
Valid Values: Unconstrained
Center x-coordinate of Thomson scattering material sphere
sim_sphereTSMcenterY [REAL] [0.0]
Valid Values: Unconstrained
Center y-coordinate of Thomson scattering material sphere
sim_sphereTSMcenterZ [REAL] [0.0]
Valid Values: Unconstrained
Center z-coordinate of Thomson scattering material sphere
sim_sphereTSMradius [REAL] [-1.0]
Valid Values: Unconstrained
Radius of Thomson scattering material sphere inside domain
sim_tempSURelectrons [REAL] [-1.0]
Valid Values: Unconstrained
Electron temperature (eV) of surrounding material
sim_tempSURions [REAL] [-1.0]
Valid Values: Unconstrained
Ion temperature (eV) of surrounding material
sim_tempTSMelectrons [REAL] [-1.0]
Valid Values: Unconstrained
Electron temperature (eV) of Thomson scattering material
sim_tempTSMions [REAL] [-1.0]
Valid Values: Unconstrained
Ion temperature (eV) of Thomson scattering material
sim_velXSUR [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity x-component of surrounding material
sim_velXTSM [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity x-component of Thomson scattering material
sim_velYSUR [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity y-component of surrounding material
sim_velYTSM [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity y-component of Thomson scattering material
sim_velZSUR [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity z-component of surrounding material
sim_velZTSM [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity z-component of Thomson scattering material
Simulation/SimulationMain/unitTest/ThomsonScattering/WithRayTracing
sim_densitySUR [REAL] [-1.0]
Valid Values: Unconstrained
Density of surrounding material
sim_densityTSM [REAL] [-1.0]
Valid Values: Unconstrained
Density of Thomson scattering material sphere
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
sim_sphereTSMcenterX [REAL] [0.0]
Valid Values: Unconstrained
Center x-coordinate of Thomson scattering material sphere
sim_sphereTSMcenterY [REAL] [0.0]
Valid Values: Unconstrained
Center y-coordinate of Thomson scattering material sphere
sim_sphereTSMcenterZ [REAL] [0.0]
Valid Values: Unconstrained
Center z-coordinate of Thomson scattering material sphere
sim_sphereTSMradius [REAL] [-1.0]
Valid Values: Unconstrained
Radius of Thomson scattering material sphere inside domain
sim_tempSURelectrons [REAL] [-1.0]
Valid Values: Unconstrained
Electron temperature (eV) of surrounding material
sim_tempSURions [REAL] [-1.0]
Valid Values: Unconstrained
Ion temperature (eV) of surrounding material
sim_tempTSMelectrons [REAL] [-1.0]
Valid Values: Unconstrained
Electron temperature (eV) of Thomson scattering material
sim_tempTSMions [REAL] [-1.0]
Valid Values: Unconstrained
Ion temperature (eV) of Thomson scattering material
sim_velXSUR [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity x-component of surrounding material
sim_velXTSM [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity x-component of Thomson scattering material
sim_velYSUR [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity y-component of surrounding material
sim_velYTSM [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity y-component of Thomson scattering material
sim_velZSUR [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity z-component of surrounding material
sim_velZTSM [REAL] [0.0]
Valid Values: Unconstrained
Bulk velocity z-component of Thomson scattering material
Simulation/SimulationMain/unitTest/XYZneu_3D_BiPCGSTAB
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/XYZneu_3D_HYPRE
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/XYZpoisson_SuperLU
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/XYneu_2D_HYPRE
alpha_x [REAL] [0.3141592653589793]
Valid Values: Unconstrained
alpha_y [REAL] [0.3141592653589793]
Valid Values: Unconstrained
waven_x [REAL] [1.]
Valid Values: Unconstrained
waven_y [REAL] [1.]
Valid Values: Unconstrained
waven_z [REAL] [1.]
Valid Values: Unconstrained
Simulation/SimulationMain/unitTest/XrayImaging/BoneWater
sim_densityInside [REAL] [-1.0]
Valid Values: Unconstrained
Density of inside (Cube/Sphere) object
sim_densityOutside [REAL] [-1.0]
Valid Values: Unconstrained
Density of outside in the rest of domain
sim_doCube [BOOLEAN] [false]
Simulate the cube?
sim_doSphere [BOOLEAN] [false]
Simulate the sphere?
sim_objectRadius [REAL] [-1.0]
Valid Values: Unconstrained
Radius of object (Cube/Sphere) inside domain
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
Simulation/SimulationMain/unitTest/XrayImaging/PureSphere
sim_densityDomain [REAL] [-1.0]
Valid Values: Unconstrained
Density of the rest of the domain
sim_densitySphere [REAL] [-1.0]
Valid Values: Unconstrained
Density of sphere
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
sim_sphereRadius [REAL] [-1.0]
Valid Values: Unconstrained
Radius of sphere inside domain
Simulation/SimulationMain/unitTest/XrayImaging/PureSphere3Din2D
sim_densityDomain [REAL] [-1.0]
Valid Values: Unconstrained
Density of the rest of the domain
sim_densitySphere [REAL] [-1.0]
Valid Values: Unconstrained
Density of sphere
sim_printBlockVariables [BOOLEAN] [false]
Print what is in each block on each processor?
sim_sphereRadius [REAL] [-1.0]
Valid Values: Unconstrained
Radius of sphere inside domain
Simulation/SimulationMain/unitTest/particleTests/VParticles
sim_deltaMoveX [REAL] [0.01]
Valid Values: Unconstrained
sim_deltaMoveY [REAL] [0.01]
Valid Values: Unconstrained
sim_deltaMoveZ [REAL] [0.01]
Valid Values: Unconstrained
sim_initPosX [REAL] [0.01]
Valid Values: Unconstrained
Initial position of the particle along x
sim_initPosY [REAL] [0.01]
Valid Values: Unconstrained
sim_initPosZ [REAL] [0.01]
Valid Values: Unconstrained
sim_p_amb [REAL] [8.e5]
Valid Values: Unconstrained
Gas Pressure: Entire domain receives this ambient parameter
sim_rho_amb [REAL] [0.95e-3]
Valid Values: Unconstrained
Gas Density: Entire domain receives this ambient parameter
sim_seed [REAL] [1.0]
Valid Values: Unconstrained
Random number seed -- NOT USED please ignore
sim_vx_amb [REAL] [0.5]
Valid Values: Unconstrained
Gas x-velocity: Dominant flow velocity throughout domain
sim_vx_multiplier [REAL] [1.0]
Valid Values: Unconstrained
Half of the domain in y has x-velocity multiplied by this value
sim_vx_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in x direction: set to zero for uniform flow
sim_vy_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in y direction: set to zero for uniform flow
sim_vz_pert [REAL] [0.1]
Valid Values: Unconstrained
Scales [-1,1] random number in z direction: set to zero for uniform flow
xmax [REAL] [1.0]
Valid Values: Unconstrained
xmin [REAL] [0.0]
Valid Values: Unconstrained
ymax [REAL] [1.0]
Valid Values: Unconstrained
ymin [REAL] [0.0]
Valid Values: Unconstrained
zmax [REAL] [1.0]
Valid Values: Unconstrained
zmin [REAL] [0.0]
Valid Values: Unconstrained
diagnostics/ProtonEmission
useProtonEmission [BOOLEAN] CONSTANT [FALSE]
flag indicating whether to use the ProtonEmission unit
diagnostics/ProtonEmission/ProtonEmissionMain
pem_RungeKuttaMethod [STRING] ["CashKarp45"]
Valid Values: Unconstrained
The Runge Kutta method to be used for proton tracing.
pem_appendOldDetectorFiles [BOOLEAN] [false]
Should protons be appended to existing detector files (for restart
runs)?
pem_cellStepTolerance [REAL] [1.0e-06]
Valid Values: Unconstrained
The allowed cell fractional error (units = cell edge) for a proton path
step
pem_cellWallThicknessFactor [REAL] [1.0e-06]
Valid Values: Unconstrained
Fraction of the shortest cell edge defining the cell wall thickness
pem_detailedTiming [BOOLEAN] [false]
If true, proton creation, transport and detector file writing is timed
pem_detectorCenterX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the square detector center 1
pem_detectorCenterY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the square detector center 1
pem_detectorCenterZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the square detector center 1
pem_detectorFileNameTimeStamp [BOOLEAN] [true]
If true, a time stamp is added to each detector file name
pem_detectorNormalX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the square detector normal vector 1
pem_detectorNormalY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the square detector normal vector 1
pem_detectorNormalZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the square detector normal vector 1
pem_detectorPinholeDist2Det_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The pinhole center distance from the detector center 1
pem_detectorPinholeRadius_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The pinhole radius 1
pem_detectorSideLength_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The side length of the square detector 1
pem_detectorSideTiltingAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Side tilting angle (degrees) from tilting axis 1
pem_detectorSideTiltingAxis_1 [STRING] [" "]
Valid Values: Unconstrained
Global tilting axis to be used for side tilting 1
pem_detectorXYwriteFormat [STRING] ["es20.10"]
Valid Values: Unconstrained
Format string for writing out proton (x,y) pairs to detector file(s)
pem_emissionAmplificationFactor [REAL] [1.0]
Valid Values: Unconstrained
Globally amplifies the number of emitted protons in each cell
pem_emissionBoxCornerLX_1 [REAL] [0.0]
Valid Values: Unconstrained
The x coordinate of the lower bounding box corner 1
pem_emissionBoxCornerLY_1 [REAL] [0.0]
Valid Values: Unconstrained
The y coordinate of the lower bounding box corner 1
pem_emissionBoxCornerLZ_1 [REAL] [0.0]
Valid Values: Unconstrained
The z coordinate of the lower bounding box corner 1
pem_emissionBoxCornerUX_1 [REAL] [0.0]
Valid Values: Unconstrained
The x coordinate of the upper bounding box corner 1
pem_emissionBoxCornerUY_1 [REAL] [0.0]
Valid Values: Unconstrained
The y coordinate of the upper bounding box corner 1
pem_emissionBoxCornerUZ_1 [REAL] [0.0]
Valid Values: Unconstrained
The z coordinate of the upper bounding box corner 1
pem_emissionConeCenterX [REAL] [0.0]
Valid Values: Unconstrained
The center global x-coordinate position of the proton emission cone
pem_emissionConeCenterY [REAL] [0.0]
Valid Values: Unconstrained
The center global y-coordinate position of the proton emission cone
pem_emissionConeCenterZ [REAL] [1.0]
Valid Values: Unconstrained
The center global z-coordinate position of the proton emission cone
pem_emissionConeHalfApexAngle [REAL] [180.0]
Valid Values: Unconstrained
The proton emission half apex cone angle (in degrees, range 0-180)
pem_ignoreElectricalField [BOOLEAN] [true]
If true, the effect of the electrical field is ignored (default).
pem_ignoreMagneticField [BOOLEAN] [false]
If true, the effect of the magnetic field is ignored (default).
pem_maxProtonCount [INTEGER] [100000]
Valid Values: Unconstrained
Maximum number of protons per processor
pem_numberOfDetectors [INTEGER] [0]
Valid Values: Unconstrained
Total number of proton detectors
pem_numberOfEmissionBoxes [INTEGER] [0]
Valid Values: Unconstrained
Total number of emission boxes (if none, whole domain will emit)
pem_numberOfProtonReactions [INTEGER] [0]
Valid Values: Unconstrained
Total number of proton reactions to be used as proton sources
pem_opaqueBoundaries [BOOLEAN] [true]
If true, the protons do not go through cells belonging to boundaries
pem_printDetectors [BOOLEAN] [false]
Print details about each detector?
pem_printEmissionBoxes [BOOLEAN] [false]
Print details about each emmission box?
pem_printMain [BOOLEAN] [false]
Print details about the proton emission run?
pem_printProtons [BOOLEAN] [false]
Print details about each proton initially generated?
pem_protonDeterminism [BOOLEAN] [false]
If true, the Grid Unit will use the Sieve Algorithm to move proton
particles.
pem_randomNumberSeedIncrement [INTEGER] [1]
Valid Values: Unconstrained
Sets the seed increment for the random number generator
pem_randomNumberSeedInitial [INTEGER] [1]
Valid Values: Unconstrained
Sets the initial seeds for the random number generator
pem_screenProtonBucketSize [INTEGER] [100000]
Valid Values: Unconstrained
Bucket size for flushing out screen protons to disk.
pem_useMaxTempReactivity [BOOLEAN] [true]
If true, maximum temperature reactivity is used when T > validity limit.
pem_useMinTempReactivity [BOOLEAN] [true]
If true, minimum temperature reactivity is used when T < validity limit.
pem_useParabolicApproximation [BOOLEAN] [true]
If true, the parabolic path approximation is used (enhanced
performance).
threadProtonTrace [BOOLEAN] [true]
Use threading when tracing the protons through each block?
useProtonEmission [BOOLEAN] [true]
Use the proton emission?
diagnostics/ProtonImaging
useProtonImaging [BOOLEAN] CONSTANT [FALSE]
flag indicating whether to use the ProtonImaging unit
diagnostics/ProtonImaging/ProtonImagingMain
pi_3Din2D [BOOLEAN] [false]
Use the 3D protons in a 2D cylindrical grid proton tracing?
pi_3Din2DwedgeAngle [REAL] [0.0]
Valid Values: Unconstrained
Wedge angle (degrees, must be < 180) for 3D in 2D simulations
pi_IOaddDetectorScreens [BOOLEAN] [false]
If true, the frame of the detector screen(s) will be added to the plot
pi_IOaddProtonsCapsule2Domain [BOOLEAN] [false]
If true, the proton path from capsule to domain will be added to the
plot
pi_IOaddProtonsDomain2Screen [BOOLEAN] [false]
If true, the proton path from domain to screen will be added to the plot
pi_IOmaxBlockCrossingNumber [INTEGER] [5]
Valid Values: Unconstrained
The (estimated) maximum number of complete block crossings for each
proton
pi_IOnumberOfProtons2Plot [INTEGER] [0]
Valid Values: Unconstrained
Number of IO protons that are to be plotted
pi_RungeKuttaMethod [STRING] ["CashKarp45"]
Valid Values: Unconstrained
The Runge Kutta method to be used for proton tracing.
pi_beamApertureAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Aperture angle (conical opening, in degrees) of beam 1
pi_beamCapsuleGrainLevel_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The grain level of capsule for beam 1
pi_beamCapsuleRadius_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of spherical capsule for beam 1
pi_beamCapsuleX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the capsule center for beam 1
pi_beamCapsuleY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the capsule center for beam 1
pi_beamCapsuleZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the capsule center for beam 1
pi_beamDetector_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The target detector of the beam 1
pi_beamNoBoundaryCondition_1 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 1
pi_beamNumberOfProtons_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of protons in the beam 1
pi_beamProtonEnergy_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The energy of the protons in the beam (in MeV) 1
pi_beamTargetRadius_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of target area for beam 1
pi_beamTargetX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 1
pi_beamTargetY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 1
pi_beamTargetZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 1
pi_beamTime2Launch_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The simulation time at which the beam should launch its protons 1
pi_cellStepTolerance [REAL] [1.0e-06]
Valid Values: Unconstrained
The allowed cell fractional error (units = cell edge) for a proton path
step
pi_cellWallThicknessFactor [REAL] [1.0e-06]
Valid Values: Unconstrained
Fraction of the shortest cell edge defining the cell wall thickness
pi_detectorAlignWRTbeamNr_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Place detector screen along beam nr? If <= 0, no placing 1
pi_detectorCenterX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the square detector center 1
pi_detectorCenterY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the square detector center 1
pi_detectorCenterZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the square detector center 1
pi_detectorDGwriteFormat [STRING] ["es15.5"]
Valid Values: Unconstrained
Format string for writing out diagnostic variables to detector file(s)
pi_detectorDist2BeamCapsule_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Distance from beam capsule center (if detector placed along beam) 1
pi_detectorFileNameTimeStamp [BOOLEAN] [true]
If true, a time stamp is added to each detector file name
pi_detectorNormalX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the square detector normal vector 1
pi_detectorNormalY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the square detector normal vector 1
pi_detectorNormalZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the square detector normal vector 1
pi_detectorPinholeDist2Det_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The pinhole center distance from the detector center 1
pi_detectorPinholeRadius_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The pinhole radius 1
pi_detectorSideLength_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The side length of the square detector 1
pi_detectorSideTiltingAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Side tilting angle (degrees) from tilting axis 1
pi_detectorSideTiltingAxis_1 [STRING] [" "]
Valid Values: Unconstrained
Global tilting axis to be used for side tilting 1
pi_detectorXYwriteFormat [STRING] ["es20.10"]
Valid Values: Unconstrained
Format string for writing out proton (x,y) pairs to detector file(s)
pi_flagDomainMissingProtons [BOOLEAN] [true]
Should domain missing protons be flagged (program aborted)?
pi_ignoreElectricalField [BOOLEAN] [true]
If true, the effect of the electrical field is ignored (default).
pi_maxProtonCount [INTEGER] [100000]
Valid Values: Unconstrained
Maximum number of protons per processor
pi_numberOfBeams [INTEGER] [-1]
Valid Values: Unconstrained
Total number of proton beams
pi_numberOfDetectors [INTEGER] [-1]
Valid Values: Unconstrained
Total number of proton detectors
pi_opaqueBoundaries [BOOLEAN] [false]
If true, the protons do not go through cells belonging to boundaries
pi_printBeams [BOOLEAN] [false]
Print details about each beam?
pi_printDetectors [BOOLEAN] [false]
Print details about each detector?
pi_printMain [BOOLEAN] [false]
Print details about the proton imaging run?
pi_printProtons [BOOLEAN] [false]
Print details about each proton initially generated?
pi_protonDeterminism [BOOLEAN] [false]
If true, the Grid Unit will use Sieve Algorithm to move the proton
particle.
pi_randomNumberSeedIncrement [INTEGER] [1]
Valid Values: Unconstrained
Sets the seed increment for the random number generator
pi_randomNumberSeedInitial [INTEGER] [1]
Valid Values: Unconstrained
Sets the initial seeds for the random number generator
pi_recalculateCellData [BOOLEAN] [false]
If true, the proton imaging calculates its own cell data for each block
pi_recordOffScreenProtons [BOOLEAN] [false]
If true, the protons missing the detector screen will also be recorded.
pi_relativisticTracing [BOOLEAN] [false]
If true, the proton tracing is done using relativistic equations of
motion.
pi_screenProtonBucketSize [INTEGER] [100000]
Valid Values: Unconstrained
Bucket size for flushing out screen protons to disk.
pi_screenProtonDiagnostics [BOOLEAN] [false]
If true, calculates/records extra diagnostic values for the screen
protons.
pi_timeResolvedProtonImaging [BOOLEAN] [false]
If true, time resolved proton imaging over many timesteps is invoked.
pi_useIOprotonPlot [BOOLEAN] [false]
This flag controls whether IO proton plotting should be used
pi_useParabolicApproximation [BOOLEAN] [false]
If true, the parabolic path approximation is used (enhanced
performance).
threadProtonTrace [BOOLEAN] [true]
Use threading when tracing the protons through each block?
useProtonImaging [BOOLEAN] [true]
Use the proton imaging?
diagnostics/ProtonImaging/ProtonImagingMain/oldOneTimeStep
pi_3Din2D [BOOLEAN] [false]
Use the 3D protons in a 2D cylindrical grid proton tracing?
pi_3Din2DwedgeAngle [REAL] [0.0]
Valid Values: Unconstrained
Wedge angle (degrees, must be < 180) for 3D in 2D simulations
pi_IOaddBeamCapsules [BOOLEAN] [false]
If true, the frame of the beam capsule(s) will be added to the plot
pi_IOaddDetectorScreens [BOOLEAN] [false]
If true, the frame of the detector screen(s) will be added to the plot
pi_IOaddProtonsCapsule2Domain [BOOLEAN] [false]
If true, the proton path from capsule to domain will be added to the
plot
pi_IOaddProtonsDomain2Screen [BOOLEAN] [false]
If true, the proton path from domain to screen will be added to the plot
pi_IOmaxBlockCrossingNumber [INTEGER] [5]
Valid Values: Unconstrained
The (estimated) maximum number of complete block crossings for each
proton
pi_IOnumberOfProtons2Plot [INTEGER] [0]
Valid Values: Unconstrained
Number of IO protons that are to be plotted
pi_IOresolutionCapsuleFrame [REAL] [1.0e-02]
Valid Values: Unconstrained
The capsule frame resolution to plot the frame of the beam capsule(s)
pi_IOresolutionScreenFrame [REAL] [1.0e-02]
Valid Values: Unconstrained
The screen frame resolution to plot the frame of the detector screen(s)
pi_RungeKuttaMethod [STRING] ["CashKarp45"]
Valid Values: Unconstrained
The Runge Kutta method to be used for proton tracing.
pi_beamApertureAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Aperture angle (conical opening, in degrees) of beam 1
pi_beamApertureAngle_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Aperture angle (conical opening, in degrees) of beam 2
pi_beamApertureAngle_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Aperture angle (conical opening, in degrees) of beam 3
pi_beamApertureAngle_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Aperture angle (conical opening, in degrees) of beam 4
pi_beamApertureAngle_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Aperture angle (conical opening, in degrees) of beam 5
pi_beamApertureAngle_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Aperture angle (conical opening, in degrees) of beam 6
pi_beamCapsuleGrainLevel_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The grain level of capsule for beam 1
pi_beamCapsuleGrainLevel_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The grain level of capsule for beam 2
pi_beamCapsuleGrainLevel_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The grain level of capsule for beam 3
pi_beamCapsuleGrainLevel_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The grain level of capsule for beam 4
pi_beamCapsuleGrainLevel_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The grain level of capsule for beam 5
pi_beamCapsuleGrainLevel_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The grain level of capsule for beam 6
pi_beamCapsuleRadius_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of spherical capsule for beam 1
pi_beamCapsuleRadius_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of spherical capsule for beam 2
pi_beamCapsuleRadius_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of spherical capsule for beam 3
pi_beamCapsuleRadius_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of spherical capsule for beam 4
pi_beamCapsuleRadius_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of spherical capsule for beam 5
pi_beamCapsuleRadius_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of spherical capsule for beam 6
pi_beamCapsuleX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the capsule center for beam 1
pi_beamCapsuleX_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the capsule center for beam 2
pi_beamCapsuleX_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the capsule center for beam 3
pi_beamCapsuleX_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the capsule center for beam 4
pi_beamCapsuleX_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the capsule center for beam 5
pi_beamCapsuleX_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the capsule center for beam 6
pi_beamCapsuleY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the capsule center for beam 1
pi_beamCapsuleY_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the capsule center for beam 2
pi_beamCapsuleY_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the capsule center for beam 3
pi_beamCapsuleY_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the capsule center for beam 4
pi_beamCapsuleY_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the capsule center for beam 5
pi_beamCapsuleY_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the capsule center for beam 6
pi_beamCapsuleZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the capsule center for beam 1
pi_beamCapsuleZ_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the capsule center for beam 2
pi_beamCapsuleZ_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the capsule center for beam 3
pi_beamCapsuleZ_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the capsule center for beam 4
pi_beamCapsuleZ_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the capsule center for beam 5
pi_beamCapsuleZ_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the capsule center for beam 6
pi_beamDetector_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The target detector of the beam 1
pi_beamDetector_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The target detector of the beam 2
pi_beamDetector_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The target detector of the beam 3
pi_beamDetector_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The target detector of the beam 4
pi_beamDetector_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The target detector of the beam 5
pi_beamDetector_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The target detector of the beam 6
pi_beamNoBoundaryCondition_1 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 1
pi_beamNoBoundaryCondition_2 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 2
pi_beamNoBoundaryCondition_3 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 3
pi_beamNoBoundaryCondition_4 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 4
pi_beamNoBoundaryCondition_5 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 5
pi_beamNoBoundaryCondition_6 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 6
pi_beamNumberOfProtons_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of protons in the beam 1
pi_beamNumberOfProtons_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of protons in the beam 2
pi_beamNumberOfProtons_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of protons in the beam 3
pi_beamNumberOfProtons_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of protons in the beam 4
pi_beamNumberOfProtons_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of protons in the beam 5
pi_beamNumberOfProtons_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of protons in the beam 6
pi_beamProtonEnergy_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The energy of the protons in the beam (in MeV) 1
pi_beamProtonEnergy_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The energy of the protons in the beam (in MeV) 2
pi_beamProtonEnergy_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The energy of the protons in the beam (in MeV) 3
pi_beamProtonEnergy_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The energy of the protons in the beam (in MeV) 4
pi_beamProtonEnergy_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The energy of the protons in the beam (in MeV) 5
pi_beamProtonEnergy_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The energy of the protons in the beam (in MeV) 6
pi_beamTargetRadius_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of target area for beam 1
pi_beamTargetRadius_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of target area for beam 2
pi_beamTargetRadius_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of target area for beam 3
pi_beamTargetRadius_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of target area for beam 4
pi_beamTargetRadius_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of target area for beam 5
pi_beamTargetRadius_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of target area for beam 6
pi_beamTargetX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 1
pi_beamTargetX_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 2
pi_beamTargetX_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 3
pi_beamTargetX_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 4
pi_beamTargetX_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 5
pi_beamTargetX_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 6
pi_beamTargetY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 1
pi_beamTargetY_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 2
pi_beamTargetY_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 3
pi_beamTargetY_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 4
pi_beamTargetY_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 5
pi_beamTargetY_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 6
pi_beamTargetZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 1
pi_beamTargetZ_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 2
pi_beamTargetZ_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 3
pi_beamTargetZ_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 4
pi_beamTargetZ_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 5
pi_beamTargetZ_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 6
pi_beamTime2Launch_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The simulation time at which the beam should launch its protons 1
pi_beamTime2Launch_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The simulation time at which the beam should launch its protons 2
pi_beamTime2Launch_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The simulation time at which the beam should launch its protons 3
pi_beamTime2Launch_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The simulation time at which the beam should launch its protons 4
pi_beamTime2Launch_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The simulation time at which the beam should launch its protons 5
pi_beamTime2Launch_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The simulation time at which the beam should launch its protons 6
pi_cellStepTolerance [REAL] [1.0e-06]
Valid Values: Unconstrained
The allowed cell fractional error (units = cell edge) for a proton path
step
pi_cellWallThicknessFactor [REAL] [1.0e-06]
Valid Values: Unconstrained
Fraction of the shortest cell edge defining the cell wall thickness
pi_detectorAlignWRTbeamNr_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Place detector screen along beam nr? If <= 0, no placing 1
pi_detectorCenterX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the square detector center 1
pi_detectorCenterY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the square detector center 1
pi_detectorCenterZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the square detector center 1
pi_detectorDGwriteFormat [STRING] ["es15.5"]
Valid Values: Unconstrained
Format string for writing out diagnostic variables to detector file(s)
pi_detectorDist2BeamCapsule_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Distance from beam capsule center (if detector placed along beam) 1
pi_detectorFileNameTimeStamp [BOOLEAN] [true]
If true, a time stamp is added to each detector file name
pi_detectorNormalX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the square detector normal vector 1
pi_detectorNormalY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the square detector normal vector 1
pi_detectorNormalZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the square detector normal vector 1
pi_detectorPinholeDist2Det_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The pinhole center distance from the detector center 1
pi_detectorPinholeRadius_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The pinhole radius 1
pi_detectorSideLength_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The side length of the square detector 1
pi_detectorSideTiltingAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Side tilting angle (degrees) from tilting axis 1
pi_detectorSideTiltingAxis_1 [STRING] [" "]
Valid Values: Unconstrained
Global tilting axis to be used for side tilting 1
pi_detectorXYwriteFormat [STRING] ["es20.10"]
Valid Values: Unconstrained
Format string for writing out proton (x,y) pairs to detector file(s)
pi_flagDomainMissingProtons [BOOLEAN] [true]
Should domain missing protons be flagged (program aborted)?
pi_ignoreElectricalField [BOOLEAN] [true]
If true, the effect of the electrical field is ignored (default).
pi_maxProtonCount [INTEGER] [100000]
Valid Values: Unconstrained
Maximum number of protons per processor
pi_numberOfBeams [INTEGER] [-1]
Valid Values: Unconstrained
Total number of proton beams
pi_numberOfDetectors [INTEGER] [-1]
Valid Values: Unconstrained
Total number of proton detectors
pi_opaqueBoundaries [BOOLEAN] [false]
If true, the protons do not go through cells belonging to boundaries
pi_printBeams [BOOLEAN] [false]
Print details about each beam?
pi_printDetectors [BOOLEAN] [false]
Print details about each detector?
pi_printMain [BOOLEAN] [false]
Print details about the proton imaging run?
pi_printProtons [BOOLEAN] [false]
Print details about each proton initially generated?
pi_protonDeterminism [BOOLEAN] [false]
If true, the Grid Unit will use the Sieve Algorithm to move the proton
particle.
pi_randomNumberSeedIncrement [INTEGER] [1]
Valid Values: Unconstrained
Sets the seed increment for the random number generator
pi_randomNumberSeedInitial [INTEGER] [1]
Valid Values: Unconstrained
Sets the initial seeds for the random number generator
pi_recalculateCellData [BOOLEAN] [false]
If true, the proton imaging calculates its own cell data for each block
pi_recordOffScreenProtons [BOOLEAN] [false]
If true, the protons missing the detector screen will also be recorded.
pi_screenProtonBucketSize [INTEGER] [100000]
Valid Values: Unconstrained
Bucket size for flushing out screen protons to disk.
pi_screenProtonDiagnostics [BOOLEAN] [false]
If true, calculates/records extra diagnostic values for the screen
protons.
pi_useIOprotonPlot [BOOLEAN] [false]
This flag controls whether IO proton plotting should be used
pi_useParabolicApproximation [BOOLEAN] [false]
If true, the parabolic path approximation is used (enhanced
performance).
threadProtonTrace [BOOLEAN] [true]
Use threading when tracing the protons through each block?
useProtonImaging [BOOLEAN] [true]
Use the proton imaging?
diagnostics/ThomsonScattering
useThomsonScattering [BOOLEAN] CONSTANT [FALSE]
flag indicating whether to use the ThomsonScattering unit
diagnostics/ThomsonScattering/ThomsonScatteringMain/NoRayTracing
threadThomsonScBlockList [BOOLEAN] [true]
Use threading for Thomson scattering outer loop?
threadThomsonScWithinBlock [BOOLEAN] [true]
Use threading for Thomson scattering inner loop?
thsc_3Din2D [BOOLEAN] [false]
Use the 3D rays in a 2D cylindrical grid ray tracing?
thsc_beamDetector_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The detector associated with probe beam 1
thsc_beamDetector_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The detector associated with probe beam 2
thsc_beamDetector_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The detector associated with probe beam 3
thsc_beamDetector_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The detector associated with probe beam 4
thsc_beamDetector_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The detector associated with probe beam 5
thsc_beamDetector_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The detector associated with probe beam 6
thsc_beamDphi_1 [REAL] [40.64]
Valid Values: -45.0 to 90.0
Angle (deg) of linear polarization wrt scattering plane for beam 1
thsc_beamDphi_2 [REAL] [40.64]
Valid Values: -45.0 to 90.0
Angle (deg) of linear polarization wrt scattering plane for beam 2
thsc_beamDphi_3 [REAL] [40.64]
Valid Values: -45.0 to 90.0
Angle (deg) of linear polarization wrt scattering plane for beam 3
thsc_beamDphi_4 [REAL] [40.64]
Valid Values: -45.0 to 90.0
Angle (deg) of linear polarization wrt scattering plane for beam 4
thsc_beamDphi_5 [REAL] [40.64]
Valid Values: -45.0 to 90.0
Angle (deg) of linear polarization wrt scattering plane for beam 5
thsc_beamDphi_6 [REAL] [40.64]
Valid Values: -45.0 to 90.0
Angle (deg) of linear polarization wrt scattering plane for beam 6
thsc_beamLensX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens center for beam 1
thsc_beamLensX_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens center for beam 2
thsc_beamLensX_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens center for beam 3
thsc_beamLensX_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens center for beam 4
thsc_beamLensX_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens center for beam 5
thsc_beamLensX_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens center for beam 6
thsc_beamLensY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens center for beam 1
thsc_beamLensY_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens center for beam 2
thsc_beamLensY_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens center for beam 3
thsc_beamLensY_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens center for beam 4
thsc_beamLensY_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens center for beam 5
thsc_beamLensY_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens center for beam 6
thsc_beamLensZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens center for beam 1
thsc_beamLensZ_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens center for beam 2
thsc_beamLensZ_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens center for beam 3
thsc_beamLensZ_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens center for beam 4
thsc_beamLensZ_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens center for beam 5
thsc_beamLensZ_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens center for beam 6
thsc_beamPowerMeasureDist1_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lower distance (before target) for measuring power of beam 1
thsc_beamPowerMeasureDist1_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lower distance (before target) for measuring power of beam 2
thsc_beamPowerMeasureDist1_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lower distance (before target) for measuring power of beam 3
thsc_beamPowerMeasureDist1_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lower distance (before target) for measuring power of beam 4
thsc_beamPowerMeasureDist1_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lower distance (before target) for measuring power of beam 5
thsc_beamPowerMeasureDist1_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lower distance (before target) for measuring power of beam 6
thsc_beamPowerMeasureDist2_1 [REAL] [HUGE(1.0)]
Valid Values: Unconstrained
Upper distance (behind target) for measuring power of beam 1
thsc_beamPowerMeasureDist2_2 [REAL] [HUGE(1.0)]
Valid Values: Unconstrained
Upper distance (behind target) for measuring power of beam 2
thsc_beamPowerMeasureDist2_3 [REAL] [HUGE(1.0)]
Valid Values: Unconstrained
Upper distance (behind target) for measuring power of beam 3
thsc_beamPowerMeasureDist2_4 [REAL] [HUGE(1.0)]
Valid Values: Unconstrained
Upper distance (behind target) for measuring power of beam 4
thsc_beamPowerMeasureDist2_5 [REAL] [HUGE(1.0)]
Valid Values: Unconstrained
Upper distance (behind target) for measuring power of beam 5
thsc_beamPowerMeasureDist2_6 [REAL] [HUGE(1.0)]
Valid Values: Unconstrained
Upper distance (behind target) for measuring power of beam 6
thsc_beamTargetX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 1
thsc_beamTargetX_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 2
thsc_beamTargetX_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 3
thsc_beamTargetX_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 4
thsc_beamTargetX_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 5
thsc_beamTargetX_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target (direction) for beam 6
thsc_beamTargetY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 1
thsc_beamTargetY_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 2
thsc_beamTargetY_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 3
thsc_beamTargetY_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 4
thsc_beamTargetY_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 5
thsc_beamTargetY_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target (direction) for beam 6
thsc_beamTargetZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 1
thsc_beamTargetZ_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 2
thsc_beamTargetZ_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 3
thsc_beamTargetZ_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 4
thsc_beamTargetZ_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 5
thsc_beamTargetZ_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target (direction) for beam 6
thsc_computeSpectra [BOOLEAN] [true]
Whether to compute (and write) scattered light spectra
thsc_crossSectionFunctionType_1 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 1
thsc_crossSectionFunctionType_2 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 2
thsc_crossSectionFunctionType_3 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 3
thsc_crossSectionFunctionType_4 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 4
thsc_crossSectionFunctionType_5 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 5
thsc_crossSectionFunctionType_6 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 6
thsc_dOmegaOfDetector_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Solid angle (as seen from scattering region) covered by detector 1
thsc_detectedRayBucketSize [INTEGER] [100000]
Valid Values: Unconstrained
Bucket size for flushing out detected rays to disk.
thsc_detectedRayDiagnostics [BOOLEAN] [false]
If true, calculates/records extra diagnostic values for the detected
rays.
thsc_detectorApertureAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Aperture angle (conical opening, in degrees) of detector 1
thsc_detectorCenterX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the spectral detector center 1
thsc_detectorCenterY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the spectral detector center 1
thsc_detectorCenterZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the spectral detector center 1
thsc_detectorDGwriteFormat [STRING] ["es15.5"]
Valid Values: Unconstrained
Format string for writing out diagnostic variables to detector file(s)
thsc_detectorFileAllowOverwrite [BOOLEAN] [false]
If false, attempts to rewrite an existing detector file cause an error
thsc_detectorFileIntervalStep [INTEGER] [0]
Valid Values: Unconstrained
minimum number of time steps between detector file writes
thsc_detectorFileIntervalTime [REAL] [0.0]
Valid Values: 0.0 to INFTY
minimum time interval between detector file writes
thsc_detectorFileNameTimeStamp [BOOLEAN] [true]
If true, a time stamp is added to each detector file name
thsc_detectorTargetRadius_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Radius of target area for detector 1
thsc_detectorTargetX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the spectral detector target location 1
thsc_detectorTargetY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the spectral detector target location 1
thsc_detectorTargetZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the spectral detector target location 1
thsc_detectorWriteAnglesInDeg [BOOLEAN] [false]
If true, write out angles in degrees, otherwise use radians
thsc_detectorWriteTempInKeV [BOOLEAN] [false]
If true, write out electron and ion temperatures in keV, otherwise use
kelvin
thsc_detectorXYwriteFormat [STRING] ["es20.10"]
Valid Values: Unconstrained
Format string for writing out the first items to detector file(s)
thsc_gaussianCenterMajor_1 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 1
thsc_gaussianCenterMajor_2 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 2
thsc_gaussianCenterMajor_3 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 3
thsc_gaussianCenterMajor_4 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 4
thsc_gaussianCenterMajor_5 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 5
thsc_gaussianCenterMajor_6 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 6
thsc_gaussianCenterMinor_1 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 1
thsc_gaussianCenterMinor_2 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 2
thsc_gaussianCenterMinor_3 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 3
thsc_gaussianCenterMinor_4 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 4
thsc_gaussianCenterMinor_5 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 5
thsc_gaussianCenterMinor_6 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 6
thsc_gaussianExponent_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 1
thsc_gaussianExponent_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 2
thsc_gaussianExponent_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 3
thsc_gaussianExponent_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 4
thsc_gaussianExponent_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 5
thsc_gaussianExponent_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 6
thsc_gaussianRadiusMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 1
thsc_gaussianRadiusMajor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 2
thsc_gaussianRadiusMajor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 3
thsc_gaussianRadiusMajor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 4
thsc_gaussianRadiusMajor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 5
thsc_gaussianRadiusMajor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 6
thsc_gaussianRadiusMinor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 1
thsc_gaussianRadiusMinor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 2
thsc_gaussianRadiusMinor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 3
thsc_gaussianRadiusMinor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 4
thsc_gaussianRadiusMinor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 5
thsc_gaussianRadiusMinor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 6
thsc_gridType_1 [STRING] [" "]
Valid Values: Unconstrained
The type of shape for beam 1
thsc_gridType_2 [STRING] [" "]
Valid Values: Unconstrained
The type of shape for beam 2
thsc_gridType_3 [STRING] [" "]
Valid Values: Unconstrained
The type of shape for beam 3
thsc_gridType_4 [STRING] [" "]
Valid Values: Unconstrained
The type of shape for beam 4
thsc_gridType_5 [STRING] [" "]
Valid Values: Unconstrained
The type of shape for beam 5
thsc_gridType_6 [STRING] [" "]
Valid Values: Unconstrained
The type of shape for beam 6
thsc_ignoreElectricalField [BOOLEAN] [true]
If true, the effect of the electrical field is ignored (default).
thsc_lensSemiAxisMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 1
thsc_lensSemiAxisMajor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 2
thsc_lensSemiAxisMajor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 3
thsc_lensSemiAxisMajor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 4
thsc_lensSemiAxisMajor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 5
thsc_lensSemiAxisMajor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 6
thsc_logLevel [INTEGER] [700]
Valid Values: 0 to INFTY
controls the level of logging for some conditions. See
ThomsonScattering.h for relevant THSC_LOGLEVEL_* definitions. Not yet
used.
thsc_maxRayCount [INTEGER] [100000]
Valid Values: Unconstrained
Maximum number of rays per processor
thsc_nSubZonesI [INTEGER] [1]
Valid Values: 1 to INFTY
Number of sub-zone intervals in the X direction for Thomson scattering
thsc_nSubZonesJ [INTEGER] [1]
Valid Values: 1 to INFTY
Number of sub-zone intervals in the Y direction for Thomson scattering
thsc_nSubZonesK [INTEGER] [1]
Valid Values: 1 to INFTY
Number of sub-zone intervals in the Z direction for Thomson scattering
thsc_numberOfBeams [INTEGER] [-1]
Valid Values: Unconstrained
Total number of probe beams
thsc_numberOfDetectors [INTEGER] [-1]
Valid Values: Unconstrained
Total number of Thomson scattering detectors
thsc_numberOfPulses [INTEGER] [-1]
Valid Values: Unconstrained
Total number of probe laser pulses
thsc_numberOfSections_1 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for probe laser pulse 1
thsc_numberOfSections_2 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for probe laser pulse 2
thsc_numberOfSections_3 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for probe laser pulse 3
thsc_numberOfSections_4 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for probe laser pulse 4
thsc_numberOfSections_5 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for probe laser pulse 5
thsc_power_1_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 1
thsc_power_1_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 10
thsc_power_1_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 11
thsc_power_1_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 12
thsc_power_1_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 13
thsc_power_1_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 14
thsc_power_1_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 15
thsc_power_1_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 16
thsc_power_1_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 17
thsc_power_1_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 18
thsc_power_1_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 19
thsc_power_1_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 2
thsc_power_1_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 20
thsc_power_1_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 3
thsc_power_1_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 4
thsc_power_1_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 5
thsc_power_1_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 6
thsc_power_1_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 7
thsc_power_1_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 8
thsc_power_1_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 1 section 9
thsc_power_2_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 1
thsc_power_2_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 10
thsc_power_2_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 11
thsc_power_2_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 12
thsc_power_2_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 13
thsc_power_2_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 14
thsc_power_2_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 15
thsc_power_2_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 16
thsc_power_2_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 17
thsc_power_2_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 18
thsc_power_2_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 19
thsc_power_2_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 2
thsc_power_2_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 20
thsc_power_2_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 3
thsc_power_2_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 4
thsc_power_2_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 5
thsc_power_2_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 6
thsc_power_2_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 7
thsc_power_2_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 8
thsc_power_2_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 2 section 9
thsc_power_3_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 1
thsc_power_3_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 10
thsc_power_3_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 11
thsc_power_3_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 12
thsc_power_3_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 13
thsc_power_3_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 14
thsc_power_3_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 15
thsc_power_3_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 16
thsc_power_3_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 17
thsc_power_3_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 18
thsc_power_3_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 19
thsc_power_3_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 2
thsc_power_3_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 20
thsc_power_3_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 3
thsc_power_3_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 4
thsc_power_3_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 5
thsc_power_3_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 6
thsc_power_3_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 7
thsc_power_3_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 8
thsc_power_3_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 3 section 9
thsc_power_4_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 1
thsc_power_4_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 10
thsc_power_4_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 11
thsc_power_4_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 12
thsc_power_4_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 13
thsc_power_4_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 14
thsc_power_4_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 15
thsc_power_4_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 16
thsc_power_4_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 17
thsc_power_4_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 18
thsc_power_4_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 19
thsc_power_4_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 2
thsc_power_4_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 20
thsc_power_4_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 3
thsc_power_4_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 4
thsc_power_4_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 5
thsc_power_4_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 6
thsc_power_4_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 7
thsc_power_4_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 8
thsc_power_4_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 4 section 9
thsc_power_5_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 1
thsc_power_5_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 10
thsc_power_5_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 11
thsc_power_5_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 12
thsc_power_5_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 13
thsc_power_5_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 14
thsc_power_5_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 15
thsc_power_5_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 16
thsc_power_5_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 17
thsc_power_5_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 18
thsc_power_5_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 19
thsc_power_5_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 2
thsc_power_5_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 20
thsc_power_5_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 3
thsc_power_5_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 4
thsc_power_5_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 5
thsc_power_5_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 6
thsc_power_5_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 7
thsc_power_5_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 8
thsc_power_5_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for probe laser pulse 5 section 9
thsc_printBeams [BOOLEAN] [false]
Print details about each beam?
thsc_printDetectors [BOOLEAN] [false]
Print details about each detector?
thsc_printMain [BOOLEAN] [false]
Print details about the Thomson scattering run?
thsc_printPulses [BOOLEAN] [false]
Print details about each pulse?
thsc_pulseNumber_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for probe beam 1
thsc_pulseNumber_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for probe beam 2
thsc_pulseNumber_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for probe beam 3
thsc_pulseNumber_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for probe beam 4
thsc_pulseNumber_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for probe beam 5
thsc_pulseNumber_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for probe beam 6
thsc_recalculateCellData [BOOLEAN] [false]
If true, the Thomson scattering calculates its own cell data for each
block
thsc_semiAxisMajorTorsionAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 1
thsc_semiAxisMajorTorsionAngle_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 2
thsc_semiAxisMajorTorsionAngle_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 3
thsc_semiAxisMajorTorsionAngle_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 4
thsc_semiAxisMajorTorsionAngle_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 5
thsc_semiAxisMajorTorsionAngle_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 6
thsc_semiAxisMajorTorsionAxis_1 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam1
thsc_semiAxisMajorTorsionAxis_2 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam2
thsc_semiAxisMajorTorsionAxis_3 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam3
thsc_semiAxisMajorTorsionAxis_4 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam4
thsc_semiAxisMajorTorsionAxis_5 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam5
thsc_semiAxisMajorTorsionAxis_6 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam6
thsc_spectrumFileAllowOverwrite [BOOLEAN] [false]
If false, attempts to rewrite an existing Thomson spectrum file cause an
error
thsc_spectrumFileIntervalStep [INTEGER] [0]
Valid Values: Unconstrained
minimum number of time steps between spectrum file writes (and
computations)
thsc_spectrumFileIntervalTime [REAL] [0.0]
Valid Values: 0.0 to INFTY
minimum time interval between spectrum file writes (and computations)
thsc_spectrumFileNameTimeStamp [BOOLEAN] [true]
If true, a time stamp is added to each Thomson spectrum file name
thsc_spectrumLamsMax_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Upper wavelength in nm for spectrum of detector 1
thsc_spectrumLamsMin_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lower wavelength in nm for spectrum of detector 1
thsc_spectrumNpts_1 [INTEGER] [0]
Valid Values: 0 to INFTY
Number of wavelengths for spectrum of detector 1
thsc_spectrumUseRelativityTerm [BOOLEAN] [true]
If true, use Pogutse's factor according to Froula et al. for all spectra
thsc_targetSemiAxisMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 1
thsc_targetSemiAxisMajor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 2
thsc_targetSemiAxisMajor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 3
thsc_targetSemiAxisMajor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 4
thsc_targetSemiAxisMajor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 5
thsc_targetSemiAxisMajor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 6
thsc_targetSemiAxisMinor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 1
thsc_targetSemiAxisMinor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 2
thsc_targetSemiAxisMinor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 3
thsc_targetSemiAxisMinor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 4
thsc_targetSemiAxisMinor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 5
thsc_targetSemiAxisMinor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 6
thsc_time_1_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 1
thsc_time_1_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 10
thsc_time_1_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 11
thsc_time_1_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 12
thsc_time_1_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 13
thsc_time_1_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 14
thsc_time_1_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 15
thsc_time_1_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 16
thsc_time_1_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 17
thsc_time_1_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 18
thsc_time_1_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 19
thsc_time_1_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 2
thsc_time_1_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 20
thsc_time_1_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 3
thsc_time_1_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 4
thsc_time_1_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 5
thsc_time_1_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 6
thsc_time_1_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 7
thsc_time_1_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 8
thsc_time_1_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 1 section 9
thsc_time_2_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 1
thsc_time_2_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 10
thsc_time_2_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 11
thsc_time_2_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 12
thsc_time_2_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 13
thsc_time_2_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 14
thsc_time_2_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 15
thsc_time_2_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 16
thsc_time_2_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 17
thsc_time_2_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 18
thsc_time_2_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 19
thsc_time_2_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 2
thsc_time_2_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 20
thsc_time_2_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 3
thsc_time_2_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 4
thsc_time_2_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 5
thsc_time_2_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 6
thsc_time_2_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 7
thsc_time_2_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 8
thsc_time_2_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 2 section 9
thsc_time_3_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 1
thsc_time_3_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 10
thsc_time_3_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 11
thsc_time_3_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 12
thsc_time_3_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 13
thsc_time_3_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 14
thsc_time_3_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 15
thsc_time_3_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 16
thsc_time_3_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 17
thsc_time_3_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 18
thsc_time_3_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 19
thsc_time_3_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 2
thsc_time_3_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 20
thsc_time_3_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 3
thsc_time_3_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 4
thsc_time_3_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 5
thsc_time_3_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 6
thsc_time_3_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 7
thsc_time_3_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 8
thsc_time_3_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 3 section 9
thsc_time_4_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 1
thsc_time_4_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 10
thsc_time_4_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 11
thsc_time_4_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 12
thsc_time_4_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 13
thsc_time_4_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 14
thsc_time_4_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 15
thsc_time_4_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 16
thsc_time_4_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 17
thsc_time_4_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 18
thsc_time_4_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 19
thsc_time_4_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 2
thsc_time_4_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 20
thsc_time_4_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 3
thsc_time_4_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 4
thsc_time_4_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 5
thsc_time_4_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 6
thsc_time_4_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 7
thsc_time_4_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 8
thsc_time_4_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 4 section 9
thsc_time_5_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 1
thsc_time_5_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 10
thsc_time_5_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 11
thsc_time_5_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 12
thsc_time_5_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 13
thsc_time_5_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 14
thsc_time_5_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 15
thsc_time_5_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 16
thsc_time_5_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 17
thsc_time_5_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 18
thsc_time_5_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 19
thsc_time_5_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 2
thsc_time_5_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 20
thsc_time_5_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 3
thsc_time_5_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 4
thsc_time_5_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 5
thsc_time_5_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 6
thsc_time_5_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 7
thsc_time_5_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 8
thsc_time_5_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for probe laser pulse 5 section 9
thsc_wavelength_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Wave length [in microns] of probe beam 1
thsc_wavelength_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Wave length [in microns] of probe beam 2
thsc_wavelength_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Wave length [in microns] of probe beam 3
thsc_wavelength_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Wave length [in microns] of probe beam 4
thsc_wavelength_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Wave length [in microns] of probe beam 5
thsc_wavelength_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Wave length [in microns] of probe beam 6
useThomsonScattering [BOOLEAN] [true]
Use the unit?
diagnostics/ThomsonScattering/ThomsonScatteringMain/WithRayTracing
threadThscRayTrace [BOOLEAN] [true]
Use threading when tracing the Thomson rays through each block?
thsc_cellTimeEnergyDeposition [BOOLEAN] [false]
If true, calculates cell energy deposition based only on time spent in
cell
thsc_cellWallThicknessFactor [REAL] [1.0e-06]
Valid Values: Unconstrained
Fraction of the shortest cell edge defining the cell wall thickness
thsc_detectorLaserBeamNumber_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The laser beam number associated with the detector 1
thsc_detectorLensSAMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for detector 1
thsc_detectorLensX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens center for detector 1
thsc_detectorLensY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens center for detector 1
thsc_detectorLensZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens center for detector 1
thsc_detectorNoRayDeflection_1 [BOOLEAN] [false]
If true, laser -> detector rays will not be deflected for detector 1
thsc_detectorNoRayPowerLoss_1 [BOOLEAN] [false]
If true, laser -> detector rays have no power loss for detector 1
thsc_detectorNumberOfRays_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of rays to be used for detector 1
thsc_detectorNumberOfSpecPoints_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of spectral points for detector 1
thsc_detectorSAMajorTorsAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major {x,y,z} semiaxis rotation angle (in degrees) for detector 1
thsc_detectorSAMajorTorsAxis_1 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} global axis to use for rotating major semiaxis for detector1
thsc_detectorScreenSpectralFlux_1 [BOOLEAN] [true]
If true, power/frequency, if false, power output for detector 1
thsc_detectorScreenWavelengths_1 [BOOLEAN] [true]
If true, wavelengths, if false, frequencies output for detector 1
thsc_detectorSkipTimeResolve_1 [BOOLEAN] [false]
If true, skip time resolve into time-tagged files for detector 1
thsc_detectorTargetSAMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for detector 1
thsc_detectorTargetSAMinor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for detector 1
thsc_detectorTargetX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target center for detector 1
thsc_detectorTargetY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target center for detector 1
thsc_detectorTargetZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target center for detector 1
thsc_detectorUseRelativityTerm_1 [BOOLEAN] [false]
Should the 1st order v/c correction of 2 * omega / omegaI be used? 1
thsc_detectorWavelengthMax_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The maximum recording spectral wavelength (in nm) for detector 1
thsc_detectorWavelengthMin_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The minimum recording spectral wavelength (in nm) for detector 1
thsc_detectorWriteFormatX [STRING] ["es20.10"]
Valid Values: Unconstrained
Format string for writing out the x-axis data to detector file(s)
thsc_detectorWriteFormatY [STRING] ["es20.10"]
Valid Values: Unconstrained
Format string for writing out the y-axis data to detector file(s)
thsc_enforcePositiveNele [BOOLEAN] [true]
Rescale the number of electrons gradient such that it is always >= 0?
thsc_enforcePositiveTele [BOOLEAN] [true]
Rescale the electron temperature gradient such that it is always >= 0?
thsc_laserCrossSecFuncType_1 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for laser beam 1
thsc_laserGaussCenterMajor_1 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for laser beam 1
thsc_laserGaussCenterMinor_1 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for laser beam 1
thsc_laserGaussExponent_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for laser beam 1
thsc_laserGaussRadiusMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for laser beam 1
thsc_laserGaussRadiusMinor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for laser beam 1
thsc_laserLensSAMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for laser beam 1
thsc_laserLensX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens center for laser beam 1
thsc_laserLensY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens center for laser beam 1
thsc_laserLensZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens center for laser beam 1
thsc_laserNoEnergyDeposition_1 [BOOLEAN] [false]
If true, no energy deposition is done for laser beam 1
thsc_laserNumberOfRays_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of rays to be used for laser beam 1
thsc_laserPolarizationAngle_1 [REAL] [-1.0]
Valid Values: Unconstrained
Polarization/scattering plane angle for laser beam (-ve -> unpolarized)1
thsc_laserPulseNumber_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for laser beam 1
thsc_laserSAMajorTorsAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major {x,y,z} semiaxis rotation angle (in degrees) for laser beam 1
thsc_laserSAMajorTorsAxis_1 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} global axis to use for rotating major semiaxis for laser beam1
thsc_laserTargetSAMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for laser beam 1
thsc_laserTargetSAMinor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for laser beam 1
thsc_laserTargetX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target center for laser beam 1
thsc_laserTargetY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target center for laser beam 1
thsc_laserTargetZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target center for laser beam 1
thsc_laserWavelength_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Wave length (in nm) of laser beam 1
thsc_maxRayCount [INTEGER] [100000]
Valid Values: Unconstrained
Maximum number of rays per processor
thsc_numberOfDetectors [INTEGER] [-1]
Valid Values: Unconstrained
Total number of Thomson scattering detectors
thsc_numberOfLaserBeams [INTEGER] [-1]
Valid Values: Unconstrained
Total number of Thomson scattering laser beams
thsc_numberOfPulses [INTEGER] [-1]
Valid Values: Unconstrained
Total number of Thomson scattering laser pulses
thsc_numberOfSections_1 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for probe laser pulse 1
thsc_power_1_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 1
thsc_power_1_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 10
thsc_power_1_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 11
thsc_power_1_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 12
thsc_power_1_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 13
thsc_power_1_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 14
thsc_power_1_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 15
thsc_power_1_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 16
thsc_power_1_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 17
thsc_power_1_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 18
thsc_power_1_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 19
thsc_power_1_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 2
thsc_power_1_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 20
thsc_power_1_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 3
thsc_power_1_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 4
thsc_power_1_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 5
thsc_power_1_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 6
thsc_power_1_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 7
thsc_power_1_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 8
thsc_power_1_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for Thomson laser pulse 1 section 9
thsc_printDetectors [BOOLEAN] [false]
Print details about each detector?
thsc_printEnergyInfo [BOOLEAN] [true]
Print details about the laser energy entering/leaving the domain?
thsc_printLaserBeams [BOOLEAN] [false]
Print details about each laser beam?
thsc_printMain [BOOLEAN] [false]
Print details about the Thomson scattering run?
thsc_printPulses [BOOLEAN] [false]
Print details about each laser pulse?
thsc_printRays [BOOLEAN] [false]
Print details about each Thomson ray currently generated?
thsc_printSpecies [BOOLEAN] [false]
Print details about the species present in the current simulation?
thsc_rayDeterminism [BOOLEAN] [false]
If true, the Grid Unit will use the Sieve Algorithm to move the ray
particle.
thsc_rayZeroPower [REAL] [1.0e-06]
Valid Values: Unconstrained
Below this value (erg/s), the Thomson ray is considered to have zero
power
thsc_recalculateCellData [BOOLEAN] [false]
If true, the Thomson scattering calculates its own cell data for each
block
thsc_time_1_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 1
thsc_time_1_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 10
thsc_time_1_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 11
thsc_time_1_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 12
thsc_time_1_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 13
thsc_time_1_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 14
thsc_time_1_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 15
thsc_time_1_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 16
thsc_time_1_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 17
thsc_time_1_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 18
thsc_time_1_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 19
thsc_time_1_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 2
thsc_time_1_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 20
thsc_time_1_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 3
thsc_time_1_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 4
thsc_time_1_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 5
thsc_time_1_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 6
thsc_time_1_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 7
thsc_time_1_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 8
thsc_time_1_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for Thomson laser pulse 1 section 9
useThomsonScattering [BOOLEAN] [true]
Use the unit?
diagnostics/XrayImaging
useXrayImaging [BOOLEAN] CONSTANT [FALSE]
Use X-ray Imaging module
diagnostics/XrayImaging/XrayImagingMain/Simple
threadXrayTrace [BOOLEAN] [true]
Use threading when tracing the X-rays through each block?
useXrayImaging [BOOLEAN] [true]
Use the X-ray imaging?
xray_3Din2D [BOOLEAN] [false]
Use 3D X-rays in a 2D cylindrical domain X-ray imaging application?
xray_XrayDeterminism [BOOLEAN] [false]
If true, the Grid Unit will use the Sieve Algorithm to move the X-ray.
xray_cellWallThicknessFactor [REAL] [1.0e-06]
Valid Values: Unconstrained
Fraction of the shortest cell edge defining the cell wall thickness
xray_detectorAlignWRTorigin_1 [BOOLEAN] [false]
Place detector normal vector along X-ray origin? 1
xray_detectorCenterX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the square detector center 1
xray_detectorCenterY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the square detector center 1
xray_detectorCenterZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the square detector center 1
xray_detectorDGwriteFormat [STRING] ["es15.5"]
Valid Values: Unconstrained
Format string for writing out diagnostic variables to detector file(s)
xray_detectorEnergyLevelCount_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of detector X-ray energy levels 1
xray_detectorEnergy_1_Fraction_1 [REAL] [-1.0]
Valid Values: Unconstrained
The X-ray energy fraction [0-1] 1 for the detector 1
xray_detectorEnergy_1_Fraction_2 [REAL] [-1.0]
Valid Values: Unconstrained
The X-ray energy fraction [0-1] 2 for the detector 1
xray_detectorEnergy_1_Fraction_3 [REAL] [-1.0]
Valid Values: Unconstrained
The X-ray energy fraction [0-1] 3 for the detector 1
xray_detectorEnergy_1_Level_1 [REAL] [-1.0]
Valid Values: Unconstrained
The X-ray energy (eV) of level 1 for the detector 1
xray_detectorEnergy_1_Level_2 [REAL] [-1.0]
Valid Values: Unconstrained
The X-ray energy (eV) of level 2 for the detector 1
xray_detectorEnergy_1_Level_3 [REAL] [-1.0]
Valid Values: Unconstrained
The X-ray energy (eV) of level 3 for the detector 1
xray_detectorFileNameTimeStamp [BOOLEAN] [true]
If true, a time stamp is added to each detector file name
xray_detectorNormalX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the square detector normal vector 1
xray_detectorNormalY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the square detector normal vector 1
xray_detectorNormalZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the square detector normal vector 1
xray_detectorOriginX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the X-ray origin 1
xray_detectorOriginY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the X-ray origin 1
xray_detectorOriginZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the X-ray origin 1
xray_detectorPerpXrays_1 [BOOLEAN] [false]
Should X-rays hit detector perpendicular on screen? 1
xray_detectorResolution_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The square detector resolution R (number of pixels = R x R) 1
xray_detectorSideLength_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The side length of the square detector 1
xray_detectorSideTiltingAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Side tilting angle (degrees) from tilting axis 1
xray_detectorSideTiltingAxis_1 [STRING] [" "]
Valid Values: Unconstrained
Global tilting axis to be used for side tilting 1
xray_detectorTime2record_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The simulation time at which the X-ray imaging should be done 1
xray_detectorXYwriteFormat [STRING] ["es20.10"]
Valid Values: Unconstrained
Format string for writing out X-ray (x,y) pairs to detector file(s)
xray_maxXrayCount [INTEGER] [100000]
Valid Values: Unconstrained
Maximum number of X-rays per processor
xray_numberOfDetectors [INTEGER] [-1]
Valid Values: Unconstrained
Total number of X-ray detectors
xray_printDetectors [BOOLEAN] [false]
Print details about each detector?
xray_printMain [BOOLEAN] [false]
Print details about the X-ray imaging run?
xray_printSpecies [BOOLEAN] [false]
Print details about the species present in the current simulation?
xray_printXrays [BOOLEAN] [false]
Print details about each X-ray initially generated?
xray_recalculateCellData [BOOLEAN] [false]
If true, the X-ray imaging calculates its own cell data for each block
xray_screenXrayBucketSize [INTEGER] [100000]
Valid Values: Unconstrained
Bucket size for flushing out screen X-rays to disk.
monitors/Debugger/DebuggerMain
doHeapCheck [BOOLEAN] [TRUE]
monitors/Logfile/LogfileMain
log_file [STRING] ["flash.log"]
Valid Values: Unconstrained
Name of log file to create
run_comment [STRING] ["FLASH 3 run"]
Valid Values: Unconstrained
Comment for run
run_number [STRING] ["1"]
Valid Values: Unconstrained
Identification number for run
monitors/Profiler/ProfilerMain
profileEvolutionOnly [BOOLEAN] [TRUE]
monitors/Timers/TimersMain/MPINative
eachProcWritesSummary [BOOLEAN] [FALSE]
Should each process write its summary to its own file? If true, each
process will write its summary to a file named timer_summary_
writeStatSummary [BOOLEAN] [TRUE]
Should timers write the max/min/avg values for timers?
numericalTools/RungeKutta/RungeKuttaMain
rk_stepSizeConfinementFactor [REAL] [0.5]
Valid Values: 0.5 to 1.0
Reduction factor for step size reduction for confined RK runs
rk_stepSizeSafetyFactor [REAL] [0.9]
Valid Values: 0.5 to 1.0
The build in safety factor for new step size estimate
numericalTools/RungeKutta/RungeKuttaMain/Implicit
rk_machepsAmplificationFactor [REAL] [1000.0]
Valid Values: Unconstrained
This x the machine epsilon value = computational epsilon value
rk_stepSizeConfinementFactor [REAL] [0.5]
Valid Values: 0.5 to 1.0
Reduction factor for step size reduction for confined RK runs
rk_stepSizeSafetyFactor [REAL] [0.9]
Valid Values: 0.5 to 1.0
The build in safety factor for new step size estimate
physics/Cosmology
useCosmology [BOOLEAN] CONSTANT [FALSE]
whether to use the Cosmology implementation or not
physics/Cosmology/CosmologyMain
CosmologicalConstant [REAL] [0.7]
Valid Values: Unconstrained
Ratio of the mass density equivalent in the cosmological constant (or
dark energy) to the closure density at the present epoch
HubbleConstant [REAL] [2.1065E-18]
Valid Values: Unconstrained
Value of the Hubble constant (\dot{a}/a) in sec^-1 at the present epoch
MaxScaleChange [REAL] [HUGE]
Valid Values: Unconstrained
Maximum permitted fractional change in the scale factor during each
timestep
OmegaBaryon [REAL] [0.05]
Valid Values: Unconstrained
Ratio of baryonic mass density to closure density at the present epoch
(must be <= OmegaMatter!)
OmegaMatter [REAL] [0.3]
Valid Values: Unconstrained
Ratio of total mass density to closure density at the present epoch
OmegaRadiation [REAL] [5.E-5]
Valid Values: Unconstrained
Ratio of total radiation density to closure density at the present epoch
computeRedshiftOnly [BOOLEAN] [FALSE]
useCosmology [BOOLEAN] [TRUE]
Are we using cosmological expansion?
physics/Cosmology/unitTest
computeDtCorrect [REAL] [169450294720534.7]
Valid Values: Unconstrained
massToLengthCorrect [REAL] [4959457362.186973]
Valid Values: Unconstrained
redshiftToTimeCorrect [REAL] [1129631001610459.]
Valid Values: Unconstrained
solveFriedmannCorrect [REAL] [1.9608074571151239E-002]
Valid Values: Unconstrained
utDt [REAL] [10000000000.00000]
Valid Values: Unconstrained
utOldScaleFactor [REAL] [1.9607958853385455E-002]
Valid Values: Unconstrained
utScaleFactor [REAL] [1.9608074569174569E-002]
Valid Values: Unconstrained
utSimTime [REAL] [1129641001610459.]
Valid Values: Unconstrained
physics/Diffuse
useDiffuse [BOOLEAN] CONSTANT [FALSE]
flags whether the Diffuse unit is being used at all
useDiffuseComputeDtSpecies [BOOLEAN] [FALSE]
flags whether Diffuse_computeDt considers species mass diffusion
useDiffuseComputeDtTherm [BOOLEAN] [FALSE]
flags whether Diffuse_computeDt considers thermal conduction
useDiffuseComputeDtVisc [BOOLEAN] [FALSE]
flags whether Diffuse_computeDt considers viscosity
useDiffuseComputeDtmagnetic [BOOLEAN] [FALSE]
physics/Diffuse/DiffuseFluxBased
diff_scaleFactThermFlux [REAL] [1.0]
Valid Values: Unconstrained
Factor applied to the temperature differences (or internal energy
differences) that are added to flux arrays by the flux-based thermal
Diffusion implementation.
geometric_mean_diff [BOOLEAN] [FALSE]
thermal_diff_method [INTEGER] [1]
Valid Values: Unconstrained
physics/Diffuse/DiffuseMain
diff_anisoCondForEle [BOOLEAN] [TRUE]
flags whether to use anisotropic heat conductivition (for electrons or
1T)
diff_anisoCondForIon [BOOLEAN] [FALSE]
If using anisotropic diffusion, apply it to ion thermal conduction?
diff_doAnisoMagDiff [BOOLEAN] [FALSE]
flags whether to do anisotropic magnetic diffusion
diff_doMagDiff [BOOLEAN] [FALSE]
flags whether to do magnetic diffusion (as opposed to flux-based)
diff_eleFlCoef [REAL] [1.0]
Valid Values: Unconstrained
Electron conduction flux limiter coefficient
diff_eleFlMode [STRING] ["fl_none"]
Valid Values: "fl_none", "fl_harmonic", "fl_minmax", "fl_larsen",
"fl_levermorepomraning1981"
Electron conduction flux limiter mode
diff_eleXlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
Electron conduction bcTypes.
diff_eleXrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_eleYlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_eleYrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_eleZlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_eleZrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_ionFlCoef [REAL] [1.0]
Valid Values: Unconstrained
Ion conduction flux limiter coefficient
diff_ionFlMode [STRING] ["fl_none"]
Valid Values: "fl_none", "fl_harmonic", "fl_minmax", "fl_larsen"
Ion conduction flux limiter mode
diff_ionXlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
Ion conduction bcTypes.
diff_ionXrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_ionYlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_ionYrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_ionZlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_ionZrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magFlCoef [REAL] [1.0]
Valid Values: Unconstrained
Magnetic diffusion flux limiter coefficient
diff_magFlMode [STRING] ["fl_none"]
Valid Values: "fl_none", "fl_harmonic", "fl_minmax", "fl_larsen",
"fl_levermorepomraning1981"
Magnetic diffusion flux limiter mode
diff_magxXlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
magnetic diffusion bcTypes for magx.
diff_magxXrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magxYlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magxYrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magxZlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magxZrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magyXlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
magnetic diffusion bcTypes for magy.
diff_magyXrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magyYlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magyYrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magyZlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magyZrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magzXlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
magnetic diffusion bcTypes for magz.
diff_magzXrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magzYlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magzYrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magzZlBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_magzZrBoundaryType [STRING] ["neumann"]
Valid Values: Unconstrained
diff_scaleFactThermSaTempDiff [REAL] [1.0]
Valid Values: Unconstrained
Factor applied to the temperature difference (or internal energy
difference) that is computed by the standalone thermal Diffusion
implementation.
diff_scaleFactThermSaTime [REAL] [1.0]
Valid Values: Unconstrained
Factor applied to the time step for which the standalone thermal
Diffusion implementation computes the temperature (or internal energy)
increase or decrease.
diff_useCrossCond [BOOLEAN] [FALSE]
flags whether to use cross term in anisotropic heat conduction
diff_useEleCond [BOOLEAN] [FALSE]
diff_useIonCond [BOOLEAN] [FALSE]
diffusion_cutoff_density [REAL] [1.e-30]
Valid Values: Unconstrained
density below which we no longer diffuse
dt_diff_factor [REAL] [0.8]
Valid Values: Unconstrained
factor that scales the timestep returned by Diffuse_computeDt
useDiffuse [BOOLEAN] [TRUE]
whether any method of the Diffuse unit should contribute to fluxes
useDiffuseComputeDtSpecies [BOOLEAN] [TRUE]
flags whether Diffuse_computeDt considers species mass diffusion
useDiffuseComputeDtTherm [BOOLEAN] [TRUE]
flags whether Diffuse_computeDt considers thermal conduction
useDiffuseComputeDtVisc [BOOLEAN] [TRUE]
flags whether Diffuse_computeDt considers viscosity
useDiffuseComputeDtmagnetic [BOOLEAN] [TRUE]
useDiffuseSpecies [BOOLEAN] [TRUE]
whether Diffuse_species [TO BE IMPLEMENTED] should contribute to fluxes
useDiffuseTherm [BOOLEAN] [TRUE]
whether Diffuse_therm should contribute to fluxes
physics/Diffuse/DiffuseMain/CG
diff_thetaImplct [REAL] [0.5]
Valid Values: 0.0 to 1.0
diff_updEint [BOOLEAN] [FALSE]
physics/Diffuse/DiffuseMain/Split
diff_XlBoundaryType [STRING] ["outflow"]
Valid Values: Unconstrained
diff_XrBoundaryType [STRING] ["outflow"]
Valid Values: Unconstrained
diff_YlBoundaryType [STRING] ["outflow"]
Valid Values: Unconstrained
diff_YrBoundaryType [STRING] ["outflow"]
Valid Values: Unconstrained
diff_ZlBoundaryType [STRING] ["outflow"]
Valid Values: Unconstrained
diff_ZrBoundaryType [STRING] ["outflow"]
Valid Values: Unconstrained
diff_thetaImplct [REAL] [0.5]
Valid Values: 0.0 to 1.0
physics/Diffuse/DiffuseMain/Unsplit
diff_ionThetaImplct [REAL] [0.5]
Valid Values: 0.0 to 1.0
Implicitness parameter for ion conduction
diff_thetaImplct [REAL] [0.5]
Valid Values: 0.0 to 1.0
diff_updEint [BOOLEAN] [FALSE]
physics/Diffuse/DiffuseMain/Unsplit/MHD
diff_conserveAngFieldMag [BOOLEAN] [FALSE]
switch for angular field conservation in magnetic diffusion
diff_magAnomIonHeat [INTEGER] [0]
Valid Values: 0 to 2
diff_magThetaImplct [REAL] [1.0]
Valid Values: 0.0 to 1.0
diff_magzOnly [BOOLEAN] [FALSE]
switch that can be used to only diffuse azimuthal magnetic field in 2d
r-z cylindrical. Can potentially be much faster
diff_minJ [REAL] [1.E-12]
Valid Values: Unconstrained
Sets a floor for the current density when calculating edge Electric
fields.
diff_splitMagZ [BOOLEAN] [FALSE]
switch to split the evolution of MAGZ_VAR into it's own HYPRE solve.
Only valid in dim<3D
diff_staggeredUpdate [BOOLEAN] [TRUE]
switch whether to interpolate edge electric fields from cell-centered
magnetic diffusion for a CT update
diff_useEdgeDerivsMag [BOOLEAN] [TRUE]
diff_useQOhmEdgeMethod [BOOLEAN] [FALSE]
is a flag to use edge-based ohmic heating calc instead of zone-based
method
physics/Eos/EosMain
eintSwitch [REAL] [0.0]
Valid Values: Unconstrained
a rarely used switch which ensures that internal energy calculations
maintain sufficient precision. Important only if energyTotal is
dominated by energyKinetic. If (energyInternal <
eintSwitch*energyKinetic) then some routines (Eos/Helmholtz,
Hydro/hy_updateSoln) will NOT calculate energyInternal by subtraction,
but rather through direct calculation.
eos_entrEleScaleChoice [INTEGER] [6]
Valid Values: 1 to 8
selects a scale variant for representing electron entropy. See code in
eos_idealGamma for the meaning of the various choices. The choice that
corresponds most closely to the Sackur-Tetrode equation in physical
units should be 3, closely followed by 2.
eos_logLevel [INTEGER] [700]
Valid Values: 0 to INFTY
Control verbosity of messages from the Eos unit. See Eos.h for relevant
EOS_LOGLEVEL_* definitions.
eos_mfASpeciesA [REAL] [1.00]
Valid Values: 0.0 to INFTY
Nucleon number for the gas (available ONLY for Eos with single species)
eos_mfASpeciesZ [REAL] [1.00]
Valid Values: 0.0 to INFTY
Proton number for the gas (available ONLY for Eos with single species)
eos_mfBSpeciesA [REAL] [1.00]
Valid Values: 0.0 to INFTY
Nucleon number for the gas (available ONLY for Eos with single species)
eos_mfBSpeciesZ [REAL] [1.00]
Valid Values: 0.0 to INFTY
Proton number for the gas (available ONLY for Eos with single species)
eos_singleSpeciesA [REAL] [1.00]
Valid Values: 0.0 to INFTY
Nucleon number for the gas (available ONLY for Eos with single species)
eos_singleSpeciesZ [REAL] [1.00]
Valid Values: 0.0 to INFTY
Proton number for the gas (available ONLY for Eos with single species)
gamma [REAL] [1.6667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for gas (available ONLY for Eos/Gamma)
gammaA [REAL] [1.6667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for gas (available ONLY for Eos/Gamma)
gammaB [REAL] [1.6667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for gas (available ONLY for Eos/Gamma)
threadEosWithinBlock [BOOLEAN] [TRUE]
physics/Eos/EosMain/Helmholtz
eos_coulombAbort [BOOLEAN] [true]
Abort if pressures become negative. Otherwise, issue a warning message
and continue
eos_coulombMult [REAL] [1.0]
Valid Values: Unconstrained
coulomb correction multiplier
eos_fluffDens [REAL] [0.0]
Valid Values: Unconstrained
material below this density has its energy replaced if its temperature
falls below smallt. This should be a small density for enery
conservation reasons. Only used in the Helmholtz/ExternalAbarZbar
implementation of Eos.
eos_forceConstantInput [BOOLEAN] [false]
Helmholtz routines can allow input EINT or PRES to change on output to
preserve equilibrium. This switch forces a constant input of EINT or
PRES
eos_maxNewton [INTEGER] [50]
Valid Values: Unconstrained
maximum number of Newton-Raphson iterations to try.
eos_tolerance [REAL] [1.e-8]
Valid Values: Unconstrained
tolerance for the Newton-Raphson iterations
larget [REAL] [1.e20]
Valid Values: Unconstrained
default upper bracket bound and used to fake temperature if it tries to
go too high. Currently, only used in the Helmholtz/ExternalAbarZbar
implementation of Eos.
physics/Eos/EosMain/Helmholtz/SpeciesBased
eos_singleSpeciesA [REAL] [1.00]
Valid Values: 0.0 to INFTY
Single-species nucleon number for the gas (only used by Eos/Helmholtz
when compiled w/o Multispecies)
eos_singleSpeciesZ [REAL] [1.00]
Valid Values: 0.0 to INFTY
Single-species proton number for the gas (only used Eos/Helmholtz when
compiled w/o Multispecies)
physics/Eos/EosMain/Tabulated
eos_tabUseGeoSpace [BOOLEAN] [TRUE]
eos_useLogTables [BOOLEAN] [TRUE]
physics/Eos/EosMain/Tabulated/Hdf5TableRead
eos_useLogTables [BOOLEAN] [TRUE]
physics/Eos/EosMain/multiTemp
eint1Switch [REAL] [-1.0]
Valid Values: Unconstrained
OBSOLETE - a switch which tries to ensure that internal energy
calculations for component 1 in a multiple-temperature setup maintain
sufficient precision. Important only if total energy for this component
is dominated by bulk kinetic energy. A value of -1 means to use the
value of eintSwitch for eint1Switch.
eint2Switch [REAL] [-1.0]
Valid Values: Unconstrained
OBSOLETE - a switch which tries to ensure that internal energy
calculations for component 2 in a multiple-temperature setup maintain
sufficient precision. See eint1Switch. A value of -1 means to use the
value of eintSwitch for eint2Switch.
eint3Switch [REAL] [-1.0]
Valid Values: Unconstrained
OBSOLETE - a switch which tries to ensure that internal energy
calculations for component 3 in a multiple-temperature setup maintain
sufficient precision. See eint1Switch. A value of -1 means to use the
value of eintSwitch for eint3Switch.
eos_combinedTempRule [INTEGER] [-10]
Valid Values: -10, 0 to 3
determines for multiTemp Eos implementations what a call to Eos will
return in the EOS_TEMP part of eosData, when Eos is called in a mode for
which EOS_TEMP is an output and different component temperatures can be
returned. 1 for ion temperature EOS_TEMPION; 2 for electron temperature
EOS_TEMPELE; 3 for radiation temperature EOS_TEMPRAD; 0 for the
temperature that would result in the same specific internal energy as
given if all components where equilibrated at the same temperature,
which may be expensive to compute; -10 for undefined, i.e., we do not
care what is returned. Currently only implemented for Multitype Eos.
eos_smallEele [REAL] [0.0]
Valid Values: Unconstrained
a floor value used for the electron component of internal energy in the
Eos unit
eos_smallEion [REAL] [0.0]
Valid Values: Unconstrained
a floor value used for the ion component of internal energy by the Eos
unit
eos_smallErad [REAL] [0.0]
Valid Values: Unconstrained
a floor value used for the radiation component of internal energy in the
Eos unit
physics/Eos/EosMain/multiTemp/Gamma
eos_forceConstantInput [BOOLEAN] [false]
Helmholtz routines can allow input EINT or PRES to change on output to
preserve equilibrium. This switch forces a constant input of EINT or
PRES
eos_maxNewton [INTEGER] [50]
Valid Values: Unconstrained
maximum number of Newton-Raphson iterations to try.
eos_singleSpeciesA [REAL] [1.00794]
Valid Values: 0.0 to INFTY
Nucleon number for the gas (for Eos tracking matter as single species)
eos_singleSpeciesZ [REAL] [1.00]
Valid Values: 0.0 to INFTY
Proton number for the gas (for Eos tracking matter as single species)
eos_tolerance [REAL] [1.e-8]
Valid Values: Unconstrained
tolerance for the Newton-Raphson iterations
gamma [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for gas
gammaEle [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for electron component
gammaIon [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for ion component
gammaRad [REAL] [1.3333333333333333]
Valid Values: 0.0 to INFTY
Ratio of specific heats for radiation component
physics/Eos/EosMain/multiTemp/Helmholtz
eos_coulombAbort [BOOLEAN] [true]
Abort if pressures become negative. Otherwise, issue a warning message
and continue
eos_coulombMult [REAL] [1.0]
Valid Values: Unconstrained
coulomb correction multiplier
eos_forceConstantInput [BOOLEAN] [false]
Helmholtz routines can allow input EINT or PRES to change on output to
preserve equilibrium. This switch forces a constant input of EINT or
PRES
eos_largeT [REAL] [1.e20]
Valid Values: Unconstrained
default upper bracket bound and used to fake temperature if it tries to
go too high. Used in some Helmholtz and Multitype implementations of
Eos.
eos_maxNewton [INTEGER] [50]
Valid Values: Unconstrained
maximum number of Newton-Raphson iterations to try.
eos_tolerance [REAL] [1.e-8]
Valid Values: Unconstrained
tolerance for the Newton-Raphson iterations
physics/Eos/EosMain/multiTemp/Helmholtz/SpeciesBased
eos_singleSpeciesA [REAL] [1.00]
Valid Values: 0.0 to INFTY
Single-species nucleon number for the gas (only used by Eos/Helmholtz
when compiled w/o Multispecies)
eos_singleSpeciesZ [REAL] [1.00]
Valid Values: 0.0 to INFTY
Single-species proton number for the gas (only used Eos/Helmholtz when
compiled w/o Multispecies)
physics/Eos/EosMain/multiTemp/Multigamma
eos_forceConstantInput [BOOLEAN] [false]
Newton-Raphson loop in Eos can allow input EINT or PRES to change on
output to preserve equilibrium. This switch forces a constant input of
EINT or PRES
eos_maxNewton [INTEGER] [50]
Valid Values: Unconstrained
maximum number of Newton-Raphson iterations to try.
eos_tolerance [REAL] [1.e-8]
Valid Values: Unconstrained
tolerance for the Newton-Raphson iterations
gammaEle [REAL] [1.6666666666666667]
Valid Values: 0.0 to INFTY
Ratio of specific heats for electron component
gammaRad [REAL] [1.3333333333333333]
Valid Values: 0.0 to INFTY
Ratio of specific heats for radiation component
physics/Eos/EosMain/multiTemp/Multitype
eos_forceConstantInput [BOOLEAN] [false]
Newton-Raphson loop in Eos can allow input EINT or PRES to change on
output to preserve equilibrium. This switch forces a constant input of
EINT or PRES
eos_largeT [REAL] [1.e14]
Valid Values: Unconstrained
default upper bracket bound and used to fake temperature if it tries to
go too high. Used in some Helmholtz and Multitype implementations of
Eos.
eos_maxFactorDown [REAL] [0.6309573]
Valid Values: Unconstrained
eos_maxFactorUp [REAL] [1.5848932]
Valid Values: Unconstrained
eos_maxNewton [INTEGER] [50]
Valid Values: Unconstrained
maximum number of Newton-Raphson iterations to try.
eos_tolerance [REAL] [1.e-8]
Valid Values: Unconstrained
tolerance for the Newton-Raphson iterations
physics/Eos/EosNuclear
bounceTime [REAL] [0.0]
Valid Values: Unconstrained
Time of bounce in seconds
eos_file [STRING]
["myshen_test_220r_180t_50y_extT_analmu_20100322_SVNr28.h5"]
Valid Values: Unconstrained
Filename of the table. Data may be found at
stellarcollapse.org/equationofstate.
postBounce [BOOLEAN] [FALSE]
Flag to specify that simulation is post-bounce
physics/Eos/unitTest
eos_testEintMode [STRING] ["dens_ie"]
Valid Values: Unconstrained
The Eos mode for getting other variables from density and a specific
internal energy.
eos_testPresMode [STRING] ["dens_pres"]
Valid Values: Unconstrained
The Eos mode for getting other variables from density and a pressure.
eos_testTempMode [STRING] ["dens_temp"]
Valid Values: Unconstrained
The Eos mode for getting other variables from density and a temperature.
physics/Gravity
grav_boundary_type [STRING] ["isolated"]
Valid Values: Unconstrained
Type of gravitational boundary condition if a Poisson solve is used for
Gravity; string-valued version of grav_boundary. Accepts: "isolated",
"periodic", "dirichlet", and maybe others, depending on the Poisson
solver used. This is declared in the stub level of the Gravity unit to
allow the Grid unit to refer to this runtime parameter even when no
Gravity implementation is included.
useGravity [BOOLEAN] [FALSE]
Whether gravity calculations should be performed.
physics/Gravity/GravityMain
useGravity [BOOLEAN] [TRUE]
Should the gravity calculations be performed?
physics/Gravity/GravityMain/Constant
gconst [REAL] [-981.]
Valid Values: Unconstrained
Gravitational acceleration constant
gdirec [STRING] ["x"]
Valid Values: Unconstrained
Direction of acceleration ("x", "y", "z")
physics/Gravity/GravityMain/PlanePar
gravsoft [REAL] [.0001]
Valid Values: Unconstrained
softening length
ptdirn [INTEGER] [1]
Valid Values: Unconstrained
x = 1, y = 2, z = 3
ptmass [REAL] [10000.]
Valid Values: Unconstrained
mass of the point
ptxpos [REAL] [1.]
Valid Values: Unconstrained
location of the point mass, in the ptdirn direction
physics/Gravity/GravityMain/PointMass
gravsoft [REAL] [0.001]
Valid Values: Unconstrained
ptmass [REAL] [10000.]
Valid Values: Unconstrained
ptxpos [REAL] [1.]
Valid Values: Unconstrained
ptypos [REAL] [-10.]
Valid Values: Unconstrained
ptzpos [REAL] [0.]
Valid Values: Unconstrained
physics/Gravity/GravityMain/Poisson
grav_temporal_extrp [BOOLEAN] [FALSE]
extrapolate or otherwise rescale
grav_unjunkPden [BOOLEAN] [TRUE]
controls whether Gravity_potentialListOfBlocks attempts to restore the
part of the "pden" ("particle density") UNK variable that is due to
particles, or leaves "pden" as it is, after a Poisson equation solve.
This only applies meaningfully when a "pden" variable is declared and
the gravitational potential is calculated by solving a Poisson equation
whose right-hand side includes a mass distribution to which both
hydrodynamic fluid density and massive particles contribute. The "pden"
variable will have been set to the sum of the fluid density ("dens"
variable) and the density resulting from mapping massive particles to
the mesh, so that is what remains in "pden" when grav_unjunkPden is set
to FALSE. Otherwise, "dens" will be subtraced from "pden" before
Gravity_potentialListOfBlocks returns, and "pden" will be left
containing only the mass density that is due to particles.
point_mass [REAL] [0.e0]
Valid Values: Unconstrained
mass of the central point-like object
point_mass_rsoft [REAL] [0.e0]
Valid Values: Unconstrained
softening radius for the point-like mass (in units of number of the
finest level cells)
updateGravity [BOOLEAN] [TRUE]
allow gravity value to be updated
physics/Gravity/GravityMain/Poisson/BHTree
grav_boundary_type [STRING] ["mixed"]
Valid Values: "isolated", "periodic", "mixed"
grav_boundary_type_x [STRING] ["isolated"]
Valid Values: "isolated", "periodic"
Gravity boundary type for the X direction, used if grav_boundary_type ==
"mixed"
grav_boundary_type_y [STRING] ["isolated"]
Valid Values: "isolated", "periodic"
Gravity boundary type for the Y direction, used if grav_boundary_type ==
"mixed"
grav_boundary_type_z [STRING] ["isolated"]
Valid Values: "isolated", "periodic"
Gravity boundary type for the Z direction, used if grav_boundary_type ==
"mixed"
grv_bhAccErr [REAL] [0.1]
Valid Values: 0 to INFTY
Maximum allowed error (either relative or absolute depending on value of
grv_bhUseRelAccErr) for the MAC.
grv_bhEwaldAlwaysGenerate [BOOLEAN] [TRUE]
If set TRUE the Ewald field will be always re-generated even if the file
with it exists.
grv_bhEwaldFName [STRING] ["ewald_coeffs"]
Valid Values: Unconstrained
File with coefficients of the Ewald field Taylor series expansion.
grv_bhEwaldFNameAccV42 [STRING] ["ewald_field_acc"]
Valid Values: Unconstrained
File to store the Ewald field for the acceleration.
grv_bhEwaldFNamePotV42 [STRING] ["ewald_field_pot"]
Valid Values: Unconstrained
File to store the Ewald field for the potential.
grv_bhEwaldFieldNxV42 [INTEGER] [32]
Valid Values: 1 to INFTY
Number of points of the Ewald field in the x-direction.
grv_bhEwaldFieldNyV42 [INTEGER] [32]
Valid Values: 1 to INFTY
Number of points of the Ewald field in the x-direction.
grv_bhEwaldFieldNzV42 [INTEGER] [32]
Valid Values: 1 to INFTY
Number of points of the Ewald field in the x-direction.
grv_bhEwaldNPer [INTEGER] [32]
Valid Values: Unconstrained
corresponds to th number of points+1 of the Taylor expansion in (one of)
periodic direction(s)
grv_bhEwaldNRefV42 [INTEGER] [-1]
Valid Values: Unconstrained
Number of refinement levels of the Ewald field. If negative, it is
calculated automatically from the minimum cell size.
grv_bhEwaldSeriesN [INTEGER] [10]
Valid Values: Unconstrained
Number of terms used in expansion to calculate the Ewald field.
grv_bhExtrnPotCenterX [REAL] [0.0]
Valid Values: Unconstrained
X-coordinate of the center of the external potention.
grv_bhExtrnPotCenterY [REAL] [0.0]
Valid Values: Unconstrained
Y-coordinate of the center of the external potention.
grv_bhExtrnPotCenterZ [REAL] [0.0]
Valid Values: Unconstrained
Z-coordinate of the center of the external potention.
grv_bhExtrnPotFile [STRING] ["external_potential.dat"]
Valid Values: Unconstrained
File including the external background potential.
grv_bhExtrnPotType [STRING] ["planez"]
Valid Values: "spherical", "planez"
Type of the external potential (spherical or plane-parallel).
grv_bhLinearInterpolOnlyV42 [BOOLEAN] [TRUE]
If set TRUE, only the linear interpolation in the Ewald field is used.
Otherwise, more expensive and accurate quadratic interpolation is used
in some cases.
grv_bhMAC [STRING] ["ApproxPartialErr"]
Valid Values: "ApproxPartialErr", "MaxPartialErr", "SumSquare"
Type of the Multipole Acceptace Criterion (MAC) used during the tree
walk.
grv_bhMPDegree [INTEGER] [2]
Valid Values: 2, 3, 4
Degree of multipole expansion used to estimate the error of a single
node contribution if the "ApproxPartErro" MAC is used. Recently, only
value 2 makes sense, because quadrupole and higher order moments are not
stored in tree nodes.
grv_bhNewton [REAL] [-1.0]
Valid Values: -INFTY to INFTY
Value for Newton's constant. Specify -1.0 to use the value from the
PhysicalConstants code unit.
grv_bhUseRelAccErr [BOOLEAN] [FALSE]
If set to TRUE, parameter grv_bhAccErr has meaning of the relative error
in acceleration. Otherwise, it is an absolute error.
grv_useExternalPotential [BOOLEAN] [FALSE]
grv_usePoissonPotential [BOOLEAN] [TRUE]
physics/Hydro
useHydro [BOOLEAN] CONSTANT [FALSE]
Whether Hydro calculations should be performed.
physics/Hydro/HydroMain
UnitSystem [STRING] ["none"]
Valid Values: Unconstrained
System of Units
cfl [REAL] [0.8]
Valid Values: Unconstrained
Courant factor
irenorm [INTEGER] [0]
Valid Values: Unconstrained
Renormalize the abundances before eos
threadHydroBlockList [BOOLEAN] [TRUE]
threadHydroWithinBlock [BOOLEAN] [TRUE]
updateHydroFluxes [BOOLEAN] [TRUE]
whether fluxes computed by Hydro should be used to update the solution
(currently, probably only used in split PPM Hydro)
useHydro [BOOLEAN] [TRUE]
Should any Hydro calculations be performed?
use_cma_advection [BOOLEAN] [FALSE]
Use the CMA advection with partial masses being primary variables; thos
parameter only affects the unsplit PPM hydro solver.
use_cma_flattening [BOOLEAN] [FALSE]
Use the flattening procedure for the abundances as described in the CMA
paper; this parameter only affects the unsplit PPM hydro solver.
use_steepening [BOOLEAN] [TRUE]
physics/Hydro/HydroMain/split/MHD_8Wave
RoeAvg [BOOLEAN] [TRUE]
hall_parameter [REAL] [0.0]
Valid Values: Unconstrained
hyperResistivity [REAL] [0.0]
Valid Values: Unconstrained
irenorm [INTEGER] [0]
Valid Values: Unconstrained
killdivb [BOOLEAN] [TRUE]
small [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value
smalle [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for energy
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smallx [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for abundances
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
physics/Hydro/HydroMain/split/PPM
charLimiting [BOOLEAN] [TRUE]
use characteristic variables for slope limiting
cvisc [REAL] [0.1]
Valid Values: Unconstrained
Artificial viscosity constant
dp_sh [REAL] [0.33]
Valid Values: Unconstrained
dp_sh_md [REAL] [0.33]
Valid Values: Unconstrained
pressure jump for multi-dimensional shock detection
epsiln [REAL] [0.33]
Valid Values: Unconstrained
PPM shock detection parameter
hy_eosModeAfter [STRING] ["dens_ie"]
Valid Values: "dens_ie", "dens_pres", "dens_temp", "dens_ie_all",
"dens_ie_scatter", "dens_ie_gather", "dens_ie_sele_gather",
"dens_ie_shocksele_gather", "dens_temp_equi", "dens_temp_all",
"dens_temp_gather", "dens_ie_recal_gather"
Eos mode to apply at the end of a hydro sweep, after hy_ppm_updateSoln
is done. Some meaningful choices are (1): == eosMode (traditional), (2):
"dens_ie" for MODE_DENS_EI (which are normally the same!).
hy_fluxRepresentation [STRING] ["fluxes"]
Valid Values: "hybrid", "fluxes", "auto"
determines the nature of the data stored in flux arrays. With this
parameter set to "fluxes", the fluxes and cell volumes used in the Hydro
method are calculated correctly using geometry measures (in units
matching those in which coordinates are represented). If
hy_fluxRepresentation is "hybrid", fluxes are calculated in a simpler
way; for example, the fluxes in Cartesian coordinates use the convention
Face Area == 1 (and thus Cell Volume == dx during the X sweep, etc.).
Both settings lead to a correct algorithm, because what is ultimately
applied in the Hydro update is of the form fluxes times dt/CellVolume,
so cell areas (thus fluxes) and volumes can be multiplied by an
arbitrary constant (as long as it is done consistently) without changing
results (except for rounding effects). The setting here must match
Paramesh's understanding of what the "fluxes" are that it is being
passed if Grid_conserveFluxes is called: If hy_fluxRepresentation is
"fluxes", then Paramesh4 should have set consv_fluxes==.true.,
consv_flux_densities==.false. If hy_fluxRepresentation is "hybrid", then
Paramesh4 should have set consv_fluxes==.false.,
consv_flux_densities==.true. Hydro_init will try to set Paramesh to the
right mode if possible, this requires Paramesh to be compiled in LIBRARY
mode. If this fails, the flux representation will be modified to
correspond to what the Grid unit supports. A third possible value for
hy_fluxRepresentation is "auto", in which case the Hydro code unit will
pick either "fluxes" or "hybrid" based on geometry and support in Grid.
hybrid_riemann [BOOLEAN] [FALSE]
use HLLE in shocks to remove odd-even decoupling
igodu [INTEGER] [0]
Valid Values: Unconstrained
Use Godunov method
iplm [INTEGER] [0]
Valid Values: Unconstrained
Use linear profiles
leveque [BOOLEAN] [FALSE]
modify states due to gravity -- leveque's way.
nriem [INTEGER] [10]
Valid Values: Unconstrained
No. of iterations in Riemann solver
omg1 [REAL] [0.75]
Valid Values: Unconstrained
PPM dissipation parameter omega1
omg2 [REAL] [10.]
Valid Values: Unconstrained
PPM dissipation parameter omega2
ppmEintCompFluxConstructionMeth [INTEGER] [0]
Valid Values: -1, 0 to 7
ppmEintFluxConstructionMeth [INTEGER] [0]
Valid Values: -1, 0 to 2, 4 to 6
selects a method for constructing energy fluxes, for internal energy,
from the results of calling the Riemann solver. Note that the eintSwitch
runtime parameter controls whether internal energy fluxes, rather than
total energy fluxes, are sometimes used for updating the energy
variables (both internal and total) in a given cell (depending on the
ratio of kinetic to internal energy in that cell).
ppmEnerCompFluxConstructionMeth [INTEGER] [0]
Valid Values: 0 to 7, 11 to 17, 20 to 27
ppmEnerFluxConstructionMeth [INTEGER] [0]
Valid Values: 0 to 2, 4 to 6, 11 to 12, 14 to 16, 20 to 27
selects a method for constructing energy fluxes, for total
(internal+kinetic) energy, from the results of calling the Riemann
solver.
ppm_modifystates [BOOLEAN] [FALSE]
modify states due to gravity -- our way.
rieman_tol [REAL] [1.0e-5]
Valid Values: Unconstrained
Converge factor for Riemann solver
small [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value ... DEV: for what?
smalle [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for energy
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smallx [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for abundances
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
vgrid [REAL] [0.]
Valid Values: Unconstrained
Scale factor for grid velocity
physics/Hydro/HydroMain/split/PPM/chomboCompatible
chomboLikeUpdateSoln [BOOLEAN] [true]
Use a simplified hy_ppm_updateSoln
excludeGradPresFromFlux [BOOLEAN] [false]
PLUTO like excludeGradPresFromFlux=.true., FLASH like
excludeGradPresFromFlux=.false.
physics/Hydro/HydroMain/split/PPM/multiTemp
hy_3Ttry_Arelated [BOOLEAN] [FALSE]
a code switch for hydro_1d, determines how fluxes for eint-without-PdV
are computed. TRUE: eia (Energy Internal Advected) fluxes always based
on eint fluxes calculation. FALSE: eia fluxes always calculated based on
advecting eint like any old mass scalar. Difference should matter only
for ppmEintCompFluxConstructionMeth=0,4. Eia fluxes themselves only
matter for cases B0,B1, or for E1 (with D2 or D3).
hy_3Ttry_B [INTEGER] [2]
Valid Values: 0, 1, 2, 3
How to deal with "work" term
hy_3Ttry_B_rad [INTEGER] [-1]
Valid Values: -1, 0, 1, 2, 3
How to deal with "work" term for radiation, i.e. for Erad, -1 means same
as hy_3Ttry_B
hy_3Ttry_D [REAL] [2.0]
Valid Values: 0.0, 1.0, 1.25, 1.5, 1.75, 1.875, 2.0, 3.0
How to consolidate energies. Values: 0. Do not, 1. Trust Eele, discard
Eion, 1.5 Trust Eele, discard Eion, 2. Trust combined Eint, recalibrate
both components, etc.
hy_3Ttry_E [INTEGER] [1]
Valid Values: 1, 2
How to recalibrate (if D2 or D3)
hy_3Ttry_F [INTEGER] [2]
Valid Values: 2, 3
What to consolidate/recalibrate (if E2)
hy_3Ttry_G [INTEGER] [1]
Valid Values: 0, 1
What to use for component P (if B1)
hy_3Ttry_Q [INTEGER] [0]
Valid Values: 0 to 2
Whether to implement preferential allocation of shock heating (over and
above heating through adiabatic compression) to ions; 2 for additional
debug info from rieman.
hy_3Ttry_useShockDetect [BOOLEAN] [FALSE]
a code switch for multiTemp hy_ppm_updateSoln, determines whether some
special handling (currently, code to implement correct preferention
shock heating of ions, as for hy_3Ttry_B3) is done only in cells where a
"shock has been detected". Shock detection depends on runtime parameter
dp_sh_md, see the Hydro_detectShock routine.
hy_dbgReconstConsvSele [BOOLEAN] [FALSE]
whether to reconstruct electron entropy ("Sele") in conservative form.
hy_eosModeAfter [STRING] ["dens_ie_gather"]
Valid Values: "dens_ie", "dens_pres", "dens_temp", "dens_ie_all",
"dens_ie_scatter", "dens_ie_gather", "dens_ie_sele_gather",
"dens_ie_shocksele_gather", "dens_temp_equi", "dens_temp_all",
"dens_temp_gather", "dens_ie_recal_gather"
Eos mode to apply at the end of a hydro sweep, after hy_ppm_updateSoln
is done. Some meaningful choices are (1): == eosMode (traditional), (2):
"dens_ie_sele_gather" for MODE_DENS_EI_SELE_GATHER.
physics/Hydro/HydroMain/split/RHD
reconType [INTEGER] [2]
Valid Values: Unconstrained
Order of reconstruction
small [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value
smalle [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for energy
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smallx [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for abundances
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
physics/Hydro/HydroMain/unsplit
EOSforRiemann [BOOLEAN] [FALSE]
Turn on/off calls to Eos for thermo of reconstructed face states
(MODE_DENS_PRES)
LimitedSlopeBeta [REAL] [1.0]
Valid Values: Unconstrained
Any real value specific for the Limited Slope limiter
PosKappa1 [REAL] [0.4]
Valid Values: Unconstrained
A constant value to determine shock strengths for positivity preserving
PosKappa2 [REAL] [0.4]
Valid Values: Unconstrained
A constant value to determine shock strengths for positivity preserving
RiemannSolver [STRING] ["HLLC"]
Valid Values: Unconstrained
Roe, HLL, HLLC, Marquina, MarquinaModified, Hybrid or local
Lax-Friedrichs, plus HLLD for MHD
addThermalFlux [BOOLEAN] [TRUE]
charLimiting [BOOLEAN] [TRUE]
Apply limiting for characteristic variable
conserveAngMom [BOOLEAN] [FALSE]
Conservative formulation for cylindrical coordinates regarding the
toroidal momentum
cvisc [REAL] [0.1]
Valid Values: Unconstrained
entropy [BOOLEAN] [FALSE]
Entropy Fix routine for the Roe Riemann solver
entropyFixMethod [STRING] ["HARTENHYMAN"]
Valid Values: Unconstrained
Entropy fix method for the Roe Riemann solver: Harten or HartenHyman
gp_elldel [REAL] [12.]
Valid Values: Unconstrained
gp_radius [INTEGER] [2]
Valid Values: Unconstrained
radius for GP stencil
gp_sigdel [REAL] [2.0]
Valid Values: Unconstrained
hy_3Torder [INTEGER] [-1]
Valid Values: -1, 1, 2, 3, 5
Reconstruction order for eint, eele, eion, erad in HEDP simulations
hy_cflFallbackFactor [REAL] [0.9]
Valid Values: Unconstrained
factor for scaling CFL factor when it is lowered because of fallback in
problematic cells
hy_eosModeGc [STRING] ["see eosMode"]
Valid Values: "see eosMode", "eos_nop", "dens_ie_gather",
"dens_ie_recal_gather", "dens_ie_scatter", "dens_ie_all",
"dens_ie_sele_gather", "dens_temp_equi", "dens_temp_all",
"dens_temp_gather"
Eos mode that the Hydro unit should apply to guard cells before the
first major loop, i.e., before computing Riemann input states by
reconstruction etc. The special value "see eosMode" can be used to
indicate the mode set by the runtime parameter "eosMode". Other values
are as for "eosMode".
hy_fPresInMomFlux [REAL] [1.0]
Valid Values: 0.0 to 1.0
Percentage of the pressure gradient (values range from 0 to 1) that is
treated as part of momentum fluxes
hy_fallbackLowerCFL [BOOLEAN] [FALSE]
Lower the simulation CFL if fallin back to a lower reconstruction order
in problematic cells
hy_fullSpecMsFluxHandling [BOOLEAN] [TRUE]
Are species and mass scalars updated with fluxes that have undergone the
full treatment applied to other fluxes, including fine-coarse-boundary
flux correction if that is done to fluxes of other conserved variables?
hy_useFluxEqn [BOOLEAN] [FALSE]
hybridOrderKappa [REAL] [0.]
Valid Values: Unconstrained
A constant value to determine shock strengths for hybrid order
hydroComputeDtOption [INTEGER] [-1]
Valid Values: -1, 0, 1
An option where to compute hydro dt. Choices are integer values [-1, 0,
1] as follows: -1: Hydro_computeDt.F90, the old standard way that has
most extensive supports and well-tested; 0: hy_uhd_energyFix.F90, a
light weighted version without calling a global loop Hydro_computeDt; 1:
hy_getFaceFlux.F90, another light weighted dt call during flux
calculations.
irenorm [INTEGER] [0]
Valid Values: Unconstrained
Renormalize abundances
order [INTEGER] [2]
Valid Values: 1, 2, 3, 4, 5, 6
1st order Godunov scheme, 2nd MUSCL-Hancock scheme, or 3rd PPM, 5th WENO
shockDetect [BOOLEAN] [FALSE]
Switch to use a strong compressive shock detection
shockLowerCFL [BOOLEAN] [FALSE]
Lower the simulation CFL if shocks are detected
slopeLimiter [STRING] ["vanLeer"]
Valid Values: Unconstrained
mc, vanLeer, vanLeer1.5, minmod, hybrid, limited
small [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value
smalle [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for energy
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smallx [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for abundances
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
A threshold value for an arbitrarily small number
transOrder [INTEGER] [1]
Valid Values: 0, 1, 2, 3, 4
order of approximating transeverse flux derivative in data
reconstruction
use_3dFullCTU [BOOLEAN] [TRUE]
Turn on/off the full CTU scheme that gives CFL <= 1 for 3D. Ignored in
1D and 2D.
use_PosPreserv [BOOLEAN] [FALSE]
Switch for self adjusting positivity preservation in dens, pres and eint
components
use_auxEintEqn [BOOLEAN] [TRUE]
Turn on/off solving the auxilary internal energy equation
use_avisc [BOOLEAN] [FALSE]
use_flattening [BOOLEAN] [FALSE]
Switch for PPM flattening
use_gravHalfUpdate [BOOLEAN] [TRUE]
Include gravitational accelerations to hydro coupling at n+1/2
use_hybridOrder [BOOLEAN] [FALSE]
Apply RH jump condition to check monotonicity of reconstructed values
use_steepening [BOOLEAN] [FALSE]
Switch for steepening contact discontinuities for 3rd order PPM
use_upwindTVD [BOOLEAN] [FALSE]
Turn on/off upwinding TVD slopes
wenoMethod [STRING] ["WENO5"]
Valid Values: Unconstrained
physics/Hydro/HydroMain/unsplit/MHD_StaggeredMesh
E_modification [BOOLEAN] [TRUE]
Switch for modified electric fields calculation from flux
E_upwind [BOOLEAN] [FALSE]
Switch for upwind update for induction equations
ForceHydroLimit [BOOLEAN] [FALSE]
Switch to force B=0 limit, i.e., the solver will not update B fields
VresistMax [BOOLEAN] [FALSE]
Switch to limit the maximum Resistive velocity automatically with the
current time step and cfl
conserveAngField [BOOLEAN] [FALSE]
Turn on/off alternate formulation for toroidal induction
crossFieldFlCoef [REAL] [1.0]
Valid Values: Unconstrained
Cross-field limiter coefficient
crossFieldFlMode [STRING] ["fl_none"]
Valid Values: "fl_none", "fl_harmonic", "fl_minmax", "fl_larsen"
Cross-field limiter mode
currFlCoef [REAL] [1.0]
Valid Values: Unconstrained
current limiter coefficient
currFlMode [STRING] ["fl_none"]
Valid Values: "fl_none", "fl_harmonic", "fl_minmax", "fl_larsen"
current limiter mode
energyFix [BOOLEAN] [FALSE]
Switch for an energy correction for CT scheme
hallVelocity [BOOLEAN] [FALSE]
Switch to use u_ele = u - J/(ne qe)
hy_bier1TA [REAL] [-1.0]
Valid Values: Unconstrained
Atomic number to use for 1T Biermann Battery term
hy_bier1TZ [REAL] [-1.0]
Valid Values: Unconstrained
Ionization number to use for 1T Biermann Battery term
hy_biermannCoef [REAL] [1.0]
Valid Values: Unconstrained
Coefficient of Biermann Battery flux
hy_biermannSource [BOOLEAN] [FALSE]
Switch to implement battery term as an external source
killdivb [BOOLEAN] [TRUE]
Switch for maintaing solenoidal field
killdivb8w [BOOLEAN] [FALSE]
Switch for maintaing solenoidal field using Powell's 8wave
nernstFlCoef [REAL] [1.0]
Valid Values: Unconstrained
Nernst limiter coefficient
nernstFlMode [STRING] ["fl_none"]
Valid Values: "fl_none", "fl_harmonic", "fl_minmax", "fl_larsen"
Nernst limiter mode
prolMethod [STRING] ["INJECTION_PROL"]
Valid Values: Unconstrained
Injection or Balsara's method in prolongation
useCrossField_limMode [BOOLEAN] [FALSE]
Switch to limit cross-field convection only for the components
perpendicular to the advecting velocity
useCrossMagRes [BOOLEAN] [FALSE]
Switch to turn on use of cross magnetic resistivity (added to Hall term)
useHall_limMode [BOOLEAN] [FALSE]
Switch to limit Hall convection only for the components perpendicular to
the advecting velocity
useNernst_limMode [BOOLEAN] [FALSE]
Switch to limit Nernst convection only for the components perpendicular
to the advecting velocity
useResistive_limMode [BOOLEAN] [FALSE]
Switch to limit Resistive convection only for the components
perpendicular to the advecting velocity
use_Biermann [BOOLEAN] [FALSE]
Switch to add the Battery term for B-field generation
use_Biermann1T [BOOLEAN] [FALSE]
Switch to add the 1T Battery term for B-field generation
use_Biermann3T [BOOLEAN] [FALSE]
Switch to add the 3T Battery term for B-field generation
use_CrossFIeld [BOOLEAN] [FALSE]
use_Hall [BOOLEAN] [FALSE]
Switch to add the Hall term in the induction equation
use_Nernst [BOOLEAN] [FALSE]
Switch to add nernst effect in the induction equation (and heat flux)
use_Seebeck [BOOLEAN] [FALSE]
Switch to add Seebeck effect in the induction equation (and heat flux)
physics/Hydro/HydroMain/unsplit/multiTemp
hy_3TMode [STRING] ["ragelike"]
Valid Values: "ragelike", "crashlike", "entropy"
Indictates the 3T model to use
hy_3T_rageLikeMaxIterations [INTEGER] [100]
Valid Values: Unconstrained
max number of iterations to use in the ragelike PdV & energy advections
iterations
hy_3Ttry_B [INTEGER] [0]
Valid Values: 0, 1, 2
How to deal with component energy "work" term
hy_3Ttry_B_rad [INTEGER] [-1]
Valid Values: -1, 0, 1, 2
How to deal with "work" term for radiation, i.e. for Erad, -1 means same
as hy_3Ttry_B
hy_3Ttry_D [REAL] [2.0]
Valid Values: 0.0, 2.0, 3.0
How to consolidate energies. Values: 0. Do not, 1. Trust Eele, discard
Eion, 1.5 Trust Eele, discard Eion, 2. Trust combined Eint, recalibrate
both components.
hy_3Ttry_E [INTEGER] [1]
Valid Values: 1, 2
How to recalibrate component energy (if D2)
hy_3Ttry_F [INTEGER] [2]
Valid Values: 2, 3
What to consolidate/recalibrate (if E2)
hy_3Ttry_G [INTEGER] [4]
Valid Values: 0, 1, 2, 4
What to use for component P (if B1)
hy_3Ttry_I [BOOLEAN] [FALSE]
hy_eosModeAfter [STRING] ["dens_ie_gather"]
Valid Values: "dens_ie", "dens_pres", "dens_temp", "dens_ie_all",
"dens_ie_scatter", "dens_ie_gather", "dens_ie_sele_gather",
"dens_temp_equi", "dens_temp_all", "dens_temp_gather",
"dens_ie_recal_gather"
Eos mode to apply at the end of a state advance, before Hydro returns.
This is currently ONLY used with multiTemp, and ignored otherwise! Some
meaningful choices are (1): == eosMode (traditional), (2):
"dens_ie_sele_gather" for MODE_DENS_EI_SELE_GATHER.
physics/Hydro/HydroMain/unsplit_rad
EOSforRiemann [BOOLEAN] [FALSE]
Turn on/off calls to Eos for thermo of reconstructed face states
(MODE_DENS_PRES)
LimitedSlopeBeta [REAL] [1.0]
Valid Values: Unconstrained
Any real value specific for the Limited Slope limiter
RiemannSolver [STRING] ["HLLC"]
Valid Values: Unconstrained
Roe, HLL, HLLC, Marquina, MarquinaModified, Hybrid or local
Lax-Friedrichs, plus HLLD for MHD
addThermalFlux [BOOLEAN] [TRUE]
charLimiting [BOOLEAN] [TRUE]
Apply limiting for characteristic variable
conserveAngMom [BOOLEAN] [FALSE]
Conservative formulation for cylindrical coordinates regarding the
toroidal momentum
cvisc [REAL] [0.1]
Valid Values: Unconstrained
entropy [BOOLEAN] [FALSE]
Entropy Fix routine for the Roe Riemann solver
entropyFixMethod [STRING] ["HARTENHYMAN"]
Valid Values: Unconstrained
Entropy fix method for the Roe Riemann solver: Harten or HartenHyman
hy_3Torder [INTEGER] [-1]
Valid Values: -1, 1, 2, 3, 5
Reconstruction order for eint, eele, eion, erad in HEDP simulations
hy_cflFallbackFactor [REAL] [0.9]
Valid Values: Unconstrained
factor for scaling CFL factor when it is lowered because of fallback in
problematic cells
hy_eosModeGc [STRING] ["see eosMode"]
Valid Values: "see eosMode", "eos_nop", "dens_ie_gather",
"dens_ie_recal_gather", "dens_ie_scatter", "dens_ie_all",
"dens_ie_sele_gather", "dens_temp_equi", "dens_temp_all",
"dens_temp_gather"
Eos mode that the Hydro unit should apply to guard cells before the
first major loop, i.e., before computing Riemann input states by
reconstruction etc. The special value "see eosMode" can be used to
indicate the mode set by the runtime parameter "eosMode". Other values
are as for "eosMode".
hy_fPresInMomFlux [REAL] [0.0]
Valid Values: 0.0 to 1.0
Fraction of the pressure gradient (values range from 0 to 1) that is
treated as part of momentum fluxes
hy_fallbackLowerCFL [BOOLEAN] [FALSE]
Lower the simulation CFL if fallin back to a lower reconstruction order
in problematic cells
hy_fullSpecMsFluxHandling [BOOLEAN] [TRUE]
Are species and mass scalars updated with fluxes that have undergone the
full treatment applied to other fluxes, including fine-coarse-boundary
flux correction if that is done to fluxes of other conserved variables?
hybridOrderKappa [REAL] [0.]
Valid Values: Unconstrained
A constant value to determine shock strengths for hybrid order
hydroComputeDtOption [INTEGER] [-1]
Valid Values: -1, 0, 1
An option where to compute hydro dt. Choices are integer values [-1, 0,
1] as follows: -1: Hydro_computeDt.F90, the old standard way that has
most extensive supports and well-tested; 0: hy_uhd_energyFix.F90, a
light weighted version without calling a global loop Hydro_computeDt; 1:
hy_getFaceFlux.F90, another light weighted dt call during flux
calculations.
irenorm [INTEGER] [0]
Valid Values: Unconstrained
Renormalize abundances
order [INTEGER] [2]
Valid Values: 1, 2, 3, 5, 6
1st order Godunov scheme, 2nd MUSCL-Hancock scheme, or 3rd PPM, 5th WENO
radiusGP [REAL] [2.]
Valid Values: Unconstrained
shockDetect [BOOLEAN] [FALSE]
Switch to use a strong compressive shock detection
shockLowerCFL [BOOLEAN] [FALSE]
Lower the simulation CFL if shocks are detected
sigmaGP [REAL] [3.]
Valid Values: Unconstrained
slopeLimiter [STRING] ["vanLeer"]
Valid Values: Unconstrained
mc, vanLeer, vanLeer1.5, minmod, hybrid, limited
small [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value
smalle [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for energy
smallp [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for pressure
smallt [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for temperature
smallu [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for velocity
smallx [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for abundances
smlrho [REAL] [1.E-10]
Valid Values: Unconstrained
Cutoff value for density
tiny [REAL] [1.e-16]
Valid Values: Unconstrained
A threshold value for an arbitrarily small number
transOrder [INTEGER] [1]
Valid Values: 0, 1, 2, 3, 4
order of approximating transeverse flux derivative in data
reconstruction
use_3dFullCTU [BOOLEAN] [TRUE]
Turn on/off the full CTU scheme that gives CFL <= 1 for 3D
use_auxEintEqn [BOOLEAN] [TRUE]
Turn on/off solving the auxilary internal energy equation
use_avisc [BOOLEAN] [FALSE]
use_flattening [BOOLEAN] [FALSE]
Switch for PPM flattening
use_gravHalfUpdate [BOOLEAN] [TRUE]
Include gravitational accelerations to hydro coupling at n+1/2
use_hybridOrder [BOOLEAN] [FALSE]
Apply RH jump condition to check monotonicity of reconstructed values
use_steepening [BOOLEAN] [FALSE]
Switch for steepening contact discontinuities for 3rd order PPM
use_upwindTVD [BOOLEAN] [FALSE]
Turn on/off upwinding TVD slopes
wenoMethod [STRING] ["WENO5"]
Valid Values: Unconstrained
physics/Hydro/HydroMain/unsplit_rad/multiTemp
hy_3TMode [STRING] ["ragelike"]
Valid Values: "ragelike", "crashlike", "entropy", "castrolike"
Indictates the 3T model to use
hy_3Ttry_B [INTEGER] [1]
Valid Values: 0, 1, 2
How to deal with component energy "work" term
hy_3Ttry_B_rad [INTEGER] [2]
Valid Values: -1, 0, 1, 2
How to deal with "work" term for radiation, i.e. for Erad, -1 means same
as hy_3Ttry_B
hy_3Ttry_D [REAL] [2.0]
Valid Values: 0.0, 2.0, 3.0
How to consolidate energies. Values: 0. Do not, 1. Trust Eele, discard
Eion, 1.5 Trust Eele, discard Eion, 2. Trust combined Eint, recalibrate
both components.
hy_3Ttry_E [INTEGER] [1]
Valid Values: 1, 2
How to recalibrate component energy (if D2)
hy_3Ttry_F [INTEGER] [2]
Valid Values: 2, 3
What to consolidate/recalibrate (if E2)
hy_3Ttry_G [INTEGER] [1]
Valid Values: 0, 1, 2, 4, 5
What to use for component P (if B1)
hy_eosModeAfter [STRING] ["dens_ie_gather"]
Valid Values: "dens_ie", "dens_pres", "dens_temp", "dens_ie_all",
"dens_ie_scatter", "dens_ie_gather", "dens_ie_sele_gather",
"dens_temp_equi", "dens_temp_all", "dens_temp_gather",
"dens_ie_recal_gather"
Eos mode to apply at the end of a state advance, before Hydro returns.
This is currently ONLY used with multiTemp, and ignored otherwise! Some
meaningful choices are (1): == eosMode (traditional), (2):
"dens_ie_sele_gather" for MODE_DENS_EI_SELE_GATHER.
hy_lam3ScaleFactor [REAL] [1.0]
Valid Values: 0.0 to 1.0
experimental scaling factor for lambda terms in FLA Hydro
hy_maxSmoothVarVal [REAL] [1.0]
Valid Values: Unconstrained
upper bound of value range where smoothing is applied.
hy_minSmoothVarVal [REAL] [0.0]
Valid Values: Unconstrained
lower bound of value range where smoothing is applied.
hy_mtPresRatLambda3Min [REAL] [0.0]
Valid Values: 0.0 to 1.0
experimental minimum value for the 3*lambda factor to scale updated
pressure ratios (from Eos call) in hy_uhd_ragelike with radflah.
hy_mtScaleAccel [REAL] [1.0]
Valid Values: 0.0 to 1.0
experimental scaling factor for per-component kinetic energy change
terms in hy_uhd_unsplitUpdateCastroLike
hy_mtScaleLorentz [REAL] [1.0]
Valid Values: 0.0 to 1.0
experimental scaling factor for component Lorentz coupling terms in
hy_uhd_unsplitUpdateCastroLike
hy_mtScaleWork [REAL] [1.0]
Valid Values: 0.0 to 1.0
experimental scaling factor for component work terms in
hy_uhd_unsplitUpdateCastroLike
hy_smoothCoeff [REAL] [1.0]
Valid Values: Unconstrained
smoothing coefficient, used in some SOR-like methods
hy_smoothIterations [INTEGER] [0]
Valid Values: 0 to INFTY
number of smoothing iterations, 0 means no smoothing is applied.
hy_smoothMethod [STRING] ["SMOOTH_3POINT"]
Valid Values: "SMOOTH_3POINT", "SMOOTH_SOR", "SMOOTH_HARMONIC_SOR"
smoothing method
hy_useMaxSmoothVarVal [BOOLEAN] [FALSE]
Use upper bound on values to be smoothed?
hy_useMinSmoothVarVal [BOOLEAN] [FALSE]
Use lower bound on values to be smoothed?
physics/IncompNS
useIncompNS [BOOLEAN] CONSTANT [FALSE]
Should the IncompNS unit be used?
physics/IncompNS/IncompNSMain
useIncompNS [BOOLEAN] [TRUE]
Should the IncompNS unit be used?
physics/IncompNS/IncompNSMain/constdens
cfl [REAL] [0.35]
Valid Values: Unconstrained
Courant Number
ins_WBREF [REAL] [0.00]
Valid Values: Unconstrained
ins_areaSolids [REAL] [0.00]
Valid Values: Unconstrained
ins_cflFlg [INTEGER] [1]
Valid Values: Unconstrained
ins_constantMass [BOOLEAN] [FALSE]
ins_dpdx [REAL] [0.00]
Valid Values: Unconstrained
ins_dpdy [REAL] [0.00]
Valid Values: Unconstrained
ins_dpdz [REAL] [0.00]
Valid Values: Unconstrained
ins_dtSpec [REAL] [0.001]
Valid Values: Unconstrained
ins_gravX [REAL] [0.]
Valid Values: Unconstrained
ins_gravY [REAL] [0.]
Valid Values: Unconstrained
ins_gravZ [REAL] [0.]
Valid Values: Unconstrained
ins_intSchm [INTEGER] [21]
Valid Values: Unconstrained
ins_invRe [REAL] [1.]
Valid Values: Unconstrained
inverse Reynolds number
ins_isgs [INTEGER] [0]
Valid Values: Unconstrained
Subgrid scale model flag
ins_pressureCorrect [BOOLEAN] [TRUE]
ins_sigma [REAL] [0.25]
Valid Values: Unconstrained
Viscous Condition Parameter
ins_velProlongMethod [INTEGER] [1]
Valid Values: 0, 1, 101, 102
physics/IncompNS/IncompNSStats
ins_statsRestart [BOOLEAN] [TRUE]
ins_statsStartTime [REAL] [0.0]
Valid Values: Unconstrained
ins_statsSteps [INTEGER] [1]
Valid Values: Unconstrained
physics/RadTrans
useRadTrans [BOOLEAN] [FALSE]
flag to indicate whether radiative transfer is in use
physics/RadTrans/RadTransMain
rt_dtFactor [REAL] [0.1]
Valid Values: 0.0+ to INFTY
Coefficient for RadTrans time step
rt_planckIntMethod [INTEGER] [0]
Valid Values: 0, 213, 321, 621
method for computing Planck integral
useRadTrans [BOOLEAN] [TRUE]
flag to indicate whether radiative transfer is in use
physics/RadTrans/RadTransMain/MGD
rt_computeDt [BOOLEAN] [FALSE]
When true, attempt to compute a time step associated with MGD
rt_groupBarrier [BOOLEAN] [FALSE]
Option to time group load imbalance
rt_mgdBoundEntry [STRING] ["grbd_manual"]
Valid Values: "grbd_manual"
How the group bounds will be input
rt_mgdBounds_1 [REAL] [-1.0]
Valid Values: Unconstrained
These parameters store the group boundaries for manual entry
rt_mgdBounds_10 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_100 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_101 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_11 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_12 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_13 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_14 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_15 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_16 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_17 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_18 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_19 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_2 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_20 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_21 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_22 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_23 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_24 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_25 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_26 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_27 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_28 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_29 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_3 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_30 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_31 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_32 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_33 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_34 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_35 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_36 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_37 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_38 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_39 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_4 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_40 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_41 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_42 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_43 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_44 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_45 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_46 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_47 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_48 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_49 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_5 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_50 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_51 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_52 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_53 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_54 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_55 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_56 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_57 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_58 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_59 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_6 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_60 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_61 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_62 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_63 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_64 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_65 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_66 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_67 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_68 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_69 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_7 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_70 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_71 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_72 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_73 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_74 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_75 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_76 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_77 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_78 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_79 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_8 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_80 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_81 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_82 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_83 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_84 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_85 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_86 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_87 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_88 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_89 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_9 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_90 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_91 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_92 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_93 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_94 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_95 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_96 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_97 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_98 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdBounds_99 [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdFlCoef [REAL] [1.0]
Valid Values: Unconstrained
MGD flux limiter coefficient
rt_mgdFlMode [STRING] ["fl_none"]
Valid Values: "fl_none", "fl_harmonic", "fl_minmax", "fl_larsen",
"fl_levermorepomraning1981"
MGD flux limiter mode
rt_mgdNumGroups [INTEGER] [0]
Valid Values: Unconstrained
Number of groups in the MGD calculation
rt_mgdXlBoundaryTemp [REAL] [-1.0]
Valid Values: Unconstrained
Boundary radiation temperature for MGD, in kelvin
rt_mgdXlBoundaryType [STRING] ["reflecting"]
Valid Values: "periodic", "reflecting", "vacuum", "dirichlet",
"neumann", "outflow", "outstream"
MGD bcTypes.
rt_mgdXrBoundaryTemp [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdXrBoundaryType [STRING] ["reflecting"]
Valid Values: "periodic", "reflecting", "vacuum", "dirichlet",
"neumann", "outflow", "outstream"
rt_mgdYlBoundaryTemp [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdYlBoundaryType [STRING] ["reflecting"]
Valid Values: "periodic", "reflecting", "vacuum", "dirichlet",
"neumann", "outflow", "outstream"
rt_mgdYrBoundaryTemp [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdYrBoundaryType [STRING] ["reflecting"]
Valid Values: "periodic", "reflecting", "vacuum", "dirichlet",
"neumann", "outflow", "outstream"
rt_mgdZlBoundaryTemp [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdZlBoundaryType [STRING] ["reflecting"]
Valid Values: "periodic", "reflecting", "vacuum", "dirichlet",
"neumann", "outflow", "outstream"
rt_mgdZrBoundaryTemp [REAL] [-1.0]
Valid Values: Unconstrained
rt_mgdZrBoundaryType [STRING] ["reflecting"]
Valid Values: "periodic", "reflecting", "vacuum", "dirichlet",
"neumann", "outflow", "outstream"
rt_mgdthetaImplct [REAL] [1.0]
Valid Values: 0.0 to 1.0
Implicitness factor of the solver.
rt_tempChangeRelTol [REAL] [1.e3]
Valid Values: 0.0+ to INFTY
Tolerance for maximum relative temperature change in a cell in a time
step. Currently only applied to electron temperature by ExpRelax
implementation.
rt_timeGroups [BOOLEAN] [FALSE]
Option to time individual groups (cannot be used with meshCopyCount > 1)
rt_useMGD [BOOLEAN] [FALSE]
use multigroup radiation diffusion
physics/RadTrans/RadTransMain/MGD/ExpRelax
rt_expRelaxMaxIter [INTEGER] [3]
Valid Values: 1 to INFTY
Maximum number of iterations in ExpRelax outer loop
physics/RadTrans/RadTransMain/MGD/Unified
rt_mgdthetaC [REAL] [-1.0]
Valid Values: 0.0 to 1.0, -1.0
Implicitness factor for the absorption part of the unified solver. Use
-1 to indicate that the value of rt_mgdthetaImplct should be used.
rt_mgdthetaD [REAL] [0.5]
Valid Values: 0.0 to 1.0, -1.0
Implicitness factor for the emission part of the unified solver. Use -1
to indicate that the value of rt_mgdthetaImplct should be used.
rt_tightIonCoupling [BOOLEAN] [FALSE]
Should the RadTrans implementation assume tight thermal coupling between
electrons and ions? The implementation may uses this parameter to decide
whether to use cv or cv_ele to linearize the relation beetween electron
temperature and energy internal energy.
physics/RadTrans/RadTransMain/NeutrinoLeakage
leak_doHeat [BOOLEAN] [TRUE]
Switch whether or not to include neutrino heating in calculation
leak_dx [REAL] [1.]
Valid Values: Unconstrained
Minimum radial spacing of the rays, used up to leak_radLog
leak_heatFac [REAL] [1.]
Valid Values: Unconstrained
Multiplicative factor in heating equation, f_heat.
leak_numPhi [INTEGER] [1]
Valid Values: Unconstrained
Number of longitudinal points in the leakage rays
leak_numRad [INTEGER] [0]
Valid Values: Unconstrained
Number of radial points in the leakage rays
leak_numTht [INTEGER] [1]
Valid Values: Unconstrained
Number of latitudinal points in the leakage rays
leak_phiMax [REAL] [0.0]
Valid Values: Unconstrained
Maximum longitudinal angle of the leakage rays, measured from the +x
axis (only 3D), in radians/pi
leak_radLog [REAL] [0.]
Valid Values: Unconstrained
Radius at which the radial spacing of the rays begins to increase
logarithmically
leak_radMax [REAL] [0.0]
Valid Values: Unconstrained
Maximum radius of the leakage rays
leak_reducedSteps [INTEGER] [1]
Valid Values: Unconstrained
Number of minimum time steps in between leakage calculation after
leak_reducedTime
leak_reducedTime [REAL] [1.e20]
Valid Values: Unconstrained
Time, in seconds, at which the frequency of leakage computation is
reduced
leak_subCommSize [INTEGER] [-1]
Valid Values: Unconstrained
Size of the MPI subcommunicator for leakage communication (-1 uses
meshNumProcs)
leak_thtMax [REAL] [0.0]
Valid Values: Unconstrained
Maximum latitudinal angle of the leakage rays, measured from the +y
axis, in radians/pi
threadLeakBlockList [BOOLEAN] [TRUE]
threadLeakWithinBlock [BOOLEAN] [TRUE]
physics/RayTrace
useRayTrace [BOOLEAN] CONSTANT [FALSE]
flag indicating whether to use RayTrace unit
physics/TreeRay
useTreeRay [BOOLEAN] [FALSE]
Whether TreeRay calculations should be performed.
physics/TreeRay/TreeRayMain
tr_bhErrControl [STRING] ["erad_cell"]
Valid Values: "erad_cell", "erad_tot", "mion_tot"
tr_bhMaxDist [REAL] [1e99]
Valid Values: Unconstrained
tr_bhRayRadRes [REAL] [1.0]
Valid Values: Unconstrained
tr_bhRelErr [REAL] [0.01]
Valid Values: Unconstrained
tr_boundary_type [STRING] ["periodic"]
Valid Values: Unconstrained
tr_ilFinePix [INTEGER] [4]
Valid Values: Unconstrained
tr_ilNNS [INTEGER] [25]
Valid Values: Unconstrained
tr_ilNPhi [INTEGER] [50]
Valid Values: Unconstrained
tr_ilNR [INTEGER] [50]
Valid Values: Unconstrained
tr_ilNTheta [INTEGER] [25]
Valid Values: Unconstrained
tr_nSide [INTEGER] [1]
Valid Values: Unconstrained
useTreeRay [BOOLEAN] [TRUE]
Whether TreeRay calculations should be performed.
physics/TreeRay/TreeRayMain/OpticalDepth
tr_odCDTOIndex [REAL] [1.0]
Valid Values: Unconstrained
tr_odMaxDist [REAL] [1e99]
Valid Values: Unconstrained
physics/materialProperties/Conductivity
useConductivity [BOOLEAN] CONSTANT [FALSE]
flags whether the conductivity material property is being used
physics/materialProperties/Conductivity/ConductivityMain
useConductivity [BOOLEAN] [TRUE]
flags whether the conductivity material property is being used
physics/materialProperties/Conductivity/ConductivityMain/Constant
cond_constantCross [REAL] [0.0]
Valid Values: Unconstrained
cond_constantIsochoric [REAL] [0.0]
Valid Values: Unconstrained
cond_constantParallel [REAL] [0.0]
Valid Values: Unconstrained
cond_constantPerpendicular [REAL] [0.0]
Valid Values: Unconstrained
physics/materialProperties/Conductivity/ConductivityMain/Constant-diff
diff_constant [REAL] [0.0]
Valid Values: Unconstrained
diff_constantCross [REAL] [0.0]
Valid Values: Unconstrained
diff_constantParallel [REAL] [0.0]
Valid Values: Unconstrained
diff_constantPerpendicular [REAL] [0.0]
Valid Values: Unconstrained
physics/materialProperties/Conductivity/ConductivityMain/PowerLaw
cond_DensityExponent [REAL] [0.0]
Valid Values: Unconstrained
cond_K0 [REAL] [1.0]
Valid Values: Unconstrained
coefficient K0 for conductivity K = rho c_v K0 T^n , where n is given by
cond_TemperatureExponent.
cond_TemperatureExponent [REAL] [1.0]
Valid Values: Unconstrained
Temperature exponent n. For n=0 you get constant conductivity. See D.
Mihalas & B. W. Mihalas 1984 p 551. For n=6, e.g., you get nonlinear
conduction as in Fig 103.1(b) there.
physics/materialProperties/Conductivity/ConductivityMain/PowerLaw-gray
Raddiff_K0r [REAL] [1.0]
Valid Values: Unconstrained
Raddiff_TemperatureExponent [REAL] [0.0]
Valid Values: Unconstrained
cond_K0 [REAL] [1.0]
Valid Values: Unconstrained
coefficient K0 for conductivity K = rho c_v K0 T^n , where n is given by
cond_TemperatureExponent.
cond_TemperatureExponent [REAL] [1.0]
Valid Values: Unconstrained
Temperature exponent n. For n=0 you get constant conductivity. See D.
Mihalas & B. W. Mihalas 1984 p 551. For n=6, e.g., you get nonlinear
conduction as in Fig 103.1(b) there.
physics/materialProperties/MagneticResistivity
res_addAnomRes [BOOLEAN] [FALSE]
adds anomalous resistivity to classic calculation
useMagneticResistivity [BOOLEAN] CONSTANT [FALSE]
flags whether the magnetic resistivity material property is being used
physics/materialProperties/MagneticResistivity/MagneticResistivityMain
res_maxRes [REAL] [-1.0]
Valid Values: -1.0, 0.0 to INFTY
Ceiling value applied to the magnetic resistivities; use -1.0 to
disable.
res_useVac [BOOLEAN] [false]
Flag for whether to apply vacuum conductivity models
res_vacDens [REAL] [0.0]
Valid Values: Unconstrained
cells with density at or below this value treated as vacuum
res_vacFrac [REAL] [0.5]
Valid Values: Unconstrained
cells with vacuum mass fraction greater than this value treated as
vacuum
res_vacRes [REAL] [0.0]
Valid Values: Unconstrained
vacuum resistivity added to total resistivity for vacuum cells
res_vacSpec [STRING] ["vacu"]
Valid Values: Unconstrained
cells that are this species may be treated as vacuum
resistivityForm [STRING] ["perpendicular"]
Valid Values: Unconstrained
choose the form of the resistive term used in Ohm's Law
resistivitySolver [STRING] ["explicit"]
Valid Values: Unconstrained
choose implicit or explicit solver
useMagneticResistivity [BOOLEAN] [TRUE]
flags whether the magnetic resistivity material property is being used
physics/materialProperties/MagneticResistivity/MagneticResistivityMain/Constant
res_constantCross [REAL] [0.0]
Valid Values: Unconstrained
res_constantParallel [REAL] [0.0]
Valid Values: Unconstrained
res_constantPerpendicular [REAL] [0.0]
Valid Values: Unconstrained
resistivity [REAL] [0.0]
Valid Values: Unconstrained
physics/materialProperties/MagneticResistivity/MagneticResistivityMain/DaviesWen
res_addAnomRes [BOOLEAN] [FALSE]
adds anomalous resistivity to classic calculation
res_anomCoef [REAL] [0.01]
Valid Values: Unconstrained
coefficient for anomalous resistivity
physics/materialProperties/MagneticResistivity/MagneticResistivityMain/Multitype
res_mt_materialModel [STRING] [""]
Valid Values: Unconstrained
physics/materialProperties/MagneticResistivity/MagneticResistivityMain/Vacuum
res_vacDensInsulating [REAL] [1e-20]
Valid Values: Unconstrained
res_vacuumModel [STRING] [""]
Valid Values: Unconstrained
physics/materialProperties/MassDiffusivity
useMassDiffusivity [BOOLEAN] CONSTANT [FALSE]
-- allows the mass diffusivity to be turned off at runtime, even if the
unit is included in the simulation
physics/materialProperties/Opacity
useOpacity [BOOLEAN] CONSTANT [FALSE]
flags whether the Opacity unit is being used at all
physics/materialProperties/Opacity/OpacityMain
useOpacity [BOOLEAN] [TRUE]
flags whether the Opacity unit is being used at all
physics/materialProperties/Opacity/OpacityMain/BremsstrahlungAndThomson
op_absorbScale [REAL] [1.0]
Valid Values: Unconstrained
op_emitScale [REAL] [1.0]
Valid Values: Unconstrained
op_transScale [REAL] [1.0]
Valid Values: Unconstrained
physics/materialProperties/Opacity/OpacityMain/Constant
op_absorbConst [REAL] [1.0]
Valid Values: Unconstrained
op_emitConst [REAL] [1.0]
Valid Values: Unconstrained
op_transConst [REAL] [1.0]
Valid Values: Unconstrained
physics/materialProperties/Opacity/OpacityMain/Constcm2g
op_absorbConst [REAL] [1.0]
Valid Values: Unconstrained
Constcm2g value for absorption opacity [cm^2/g]
op_emitConst [REAL] [1.0]
Valid Values: Unconstrained
Constcm2g value for emission opacity [cm^2/g]
op_transConst [REAL] [1.0]
Valid Values: Unconstrained
Constcm2g value for transport opacity [cm^2/g]
physics/materialProperties/Opacity/OpacityMain/Multispecies
opacity_ceiling [REAL] [1.e6]
Valid Values: Unconstrained
ceiling for the opacity values when reading from TOPS tables. Below the
plasma cut-off frequency TOPS sets the ceiling to 1.e10, which is too
high for FLASH
opacity_ignoreLowTemp [BOOLEAN] [TRUE]
control parameter indicating if the low temperature capability should be
ignored
opacity_writeOpacityInfo [BOOLEAN] [FALSE]
control parameter indicating if detailed info of the opacity unit should
be written out
physics/materialProperties/Opacity/OpacityMain/Multispecies/method/Integrate
opacity_RombergAccuracy [REAL] [1.E-6]
Valid Values: Unconstrained
opacity_maxQuadratureRoots [INTEGER] [50]
Valid Values: Unconstrained
opacity_printQuadratureData [BOOLEAN] [TRUE]
opacity_useQuadrature [BOOLEAN] [FALSE]
opacity_useRomberg [BOOLEAN] [TRUE]
physics/materialProperties/Opacity/OpacityMain/Multispecies/method/LowTemp
opacity_ignoreKleinNishina [BOOLEAN] [FALSE]
physics/materialProperties/Opacity/OpacityMain/Multispecies/method/Tabulated
op_tableEnergyTolerance [REAL] [1.0e-04]
Valid Values: Unconstrained
allowed difference between table/FLASH group structure
opacity_useLogTables [BOOLEAN] [TRUE]
control parameter indicating use of logarithmic opacities
physics/materialProperties/Opacity/OpacityMain/OPAL
op_absorbConst [REAL] [1.0]
Valid Values: Unconstrained
Constcm2g value for absorption opacity [cm^2/g]
op_emitConst [REAL] [1.0]
Valid Values: Unconstrained
Constcm2g value for emission opacity [cm^2/g]
op_hydrogenMassFrac [REAL] [1.0]
Valid Values: 0.0+ to 1.0
Fixed value to use for hydrogen mass fraction, used if
op_hydrogenMassFracVar does not exist
op_hydrogenMassFracVar [STRING] ["h1"]
Valid Values: Unconstrained
Variable in unk to use as hydrogen mass fraction, probably something
like "h1" or "h"
op_opalMaxLowT [REAL] [1.0e4]
Valid Values: Unconstrained
maximum temperature for which the LowT OPAL tables are to be used; above
this threshold, the HightT tables are used.
op_opalNumHydrogenAbundances [INTEGER] [10]
Valid Values: 0 to 10
number of hydrogen abundance ranges for which there are OPAL table
files.
op_opalTableAbundMax_1 [REAL] [0.1]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 1
op_opalTableAbundMax_10 [REAL] [1.0]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 10
op_opalTableAbundMax_2 [REAL] [0.2]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 2
op_opalTableAbundMax_3 [REAL] [0.30000000000000004]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 3
op_opalTableAbundMax_4 [REAL] [0.4]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 4
op_opalTableAbundMax_5 [REAL] [0.5]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 5
op_opalTableAbundMax_6 [REAL] [0.6000000000000001]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 6
op_opalTableAbundMax_7 [REAL] [0.7000000000000001]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 7
op_opalTableAbundMax_8 [REAL] [0.8]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 8
op_opalTableAbundMax_9 [REAL] [0.9]
Valid Values: 0.0 to 1.0
Upper bound of hydrogen abundance range no. 9
op_opalTableHighT_1 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 1
op_opalTableHighT_10 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 10
op_opalTableHighT_2 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 2
op_opalTableHighT_3 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 3
op_opalTableHighT_4 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 4
op_opalTableHighT_5 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 5
op_opalTableHighT_6 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 6
op_opalTableHighT_7 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 7
op_opalTableHighT_8 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 8
op_opalTableHighT_9 [STRING] ["-none-"]
Valid Values: Unconstrained
High temp OPAL table for hydrogen abundance range no. 9
op_opalTableLowT_1 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 1
op_opalTableLowT_10 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 10
op_opalTableLowT_2 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 2
op_opalTableLowT_3 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 3
op_opalTableLowT_4 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 4
op_opalTableLowT_5 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 5
op_opalTableLowT_6 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 6
op_opalTableLowT_7 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 7
op_opalTableLowT_8 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 8
op_opalTableLowT_9 [STRING] ["-none-"]
Valid Values: Unconstrained
Low temp OPAL table for hydrogen abundance range no. 9
opacity_useLogTables [BOOLEAN] CONSTANT [TRUE]
control parameter indicating use of logarithmic opacities
opacity_writeOpacityInfo [BOOLEAN] [FALSE]
control parameter indicating if detailed info of the opacity unit should
be written out
physics/materialProperties/Thermoelectric/ThermoelectricMain/Constant
thel_constantCross [REAL] [0.0]
Valid Values: Unconstrained
thel_constantNew [REAL] [0.0]
Valid Values: Unconstrained
thel_constantParallel [REAL] [0.0]
Valid Values: Unconstrained
thel_constantPerpendicular [REAL] [0.0]
Valid Values: Unconstrained
physics/materialProperties/Viscosity
useExplicitViscosity [BOOLEAN] [TRUE]
flags whether to use explicit (or implicit) viscosity solver
useViscosity [BOOLEAN] CONSTANT [FALSE]
flags whether the viscosity material property is being used
physics/materialProperties/Viscosity/ViscosityMain
useViscosity [BOOLEAN] [TRUE]
flags whether the viscosity material property is being used
viscSuppressFactor [REAL] [1.0]
Valid Values: Unconstrained
-- allows the viscosity to be suppressed
viscTempHigh [REAL] [1.5e8]
Valid Values: Unconstrained
-- turn off viscosity for temps higher than this
viscTempLow [REAL] [3.0e5]
Valid Values: Unconstrained
-- turn off viscosity for temps lower than this
physics/materialProperties/Viscosity/ViscosityMain/Constant
diff_visc_mu [REAL] [.1]
Valid Values: Unconstrained
constant dynamic viscosity (used in Constant Viscosity if
visc_whichCoefficientIsConst is 1)
diff_visc_nu [REAL] [.1]
Valid Values: Unconstrained
constant kinematic viscosity (used in Constant Viscosity if
visc_whichCoefficientIsConst is 2)
visc_whichCoefficientIsConst [INTEGER] [2]
Valid Values: 1, 2
which kind of coefficient to keep constant in Constant Viscosity
implementation; set to 1 for constant dynamic viscosity (the value of
diff_visc_mu is used); set to 2 for constant kinematic viscosity (the
value of diff_visc_nu is used).
physics/sourceTerms/Burn
useBurn [BOOLEAN] [FALSE]
shall I burn?
physics/sourceTerms/Burn/BurnMain
enucDtFactor [REAL] [1.e30]
Valid Values: Unconstrained
Limit timestep to limit total energy deposited by burning is kept
artificially high to effectively turn off limiting by default
useShockBurn [BOOLEAN] [FALSE]
Is burning allowed within shocks?
physics/sourceTerms/Burn/BurnMain/nuclearBurn
algebra [INTEGER] [1]
Valid Values: 1 to 2
choice of linear algebra package & 1 = MA28 ; 2 = GIFT
nuclearDensMax [REAL] [1.0E14]
Valid Values: 0 to INFTY
Max burning density
nuclearDensMin [REAL] [1.0E-10]
Valid Values: 0 to INFTY
Min burning density
nuclearNI56Max [REAL] [1.0]
Valid Values: 0 to INFTY
Max Ni56 mass frac. for burning
nuclearTempMax [REAL] [1.0E12]
Valid Values: 0 to INFTY
Max burning temperature
nuclearTempMin [REAL] [1.1E8]
Valid Values: 0 to INFTY
Min burning temperature
odeStepper [INTEGER] [1]
Valid Values: 1 to 2
choice of ode time stepper 1 = Bader-Deuflhard variable order 2 =
Rosenbrock 4th order
useBurnTable [BOOLEAN] [FALSE]
choice of rate evaluation FALSE = analytic rates TRUE = table
interpolation
physics/sourceTerms/Circuit
useCircuit [BOOLEAN] CONSTANT [FALSE]
flags whether the Circuit source term is being used
physics/sourceTerms/Circuit/CircuitMain
circ_cylLength [REAL] [1.0]
Valid Values: Unconstrained
Cylinder length used in B-flux calculation for 1D sims
circ_useFluxVtMethod [BOOLEAN] [TRUE]
flags whether to use magnetic flux method when calculating induced load
voltage
useCircuit [BOOLEAN] [TRUE]
flags whether the Circuit source term is being used
physics/sourceTerms/Circuit/CircuitMain/CESZAR
circ_CESZAR_V0 [REAL] [115.0e3]
Valid Values: Unconstrained
Initial potential of capacitor in CESZAR circuit
circ_cylLength [REAL] [1.0]
Valid Values: Unconstrained
Cylinder length used in B-flux calculation for 1D sims
physics/sourceTerms/Circuit/CircuitMain/Constant
circ_currConstant [REAL] [0.]
Valid Values: Unconstrained
Constant value for current (A)
physics/sourceTerms/Circuit/CircuitMain/FileInput
circ_calcPower [BOOLEAN] [FALSE]
flag to calculate power dissipated by the circuit element representing
the MHD domain
circ_currFile [STRING] ["current.dat"]
Valid Values: Unconstrained
Name of the file that holds the current data
physics/sourceTerms/Circuit/CircuitMain/McBride
circ_cylLength [REAL] [1.0]
Valid Values: Unconstrained
Cylinder length used in B-flux calculation for 1D sims
circ_voltFile [STRING] ["voltage.dat"]
Valid Values: Unconstrained
Name of the file that holds the voltage data
physics/sourceTerms/Cool
useCool [BOOLEAN] [FALSE]
Runtime control for turning off cooling
physics/sourceTerms/Deleptonize
useDeleptonize [BOOLEAN] [FALSE]
runtime control for turning the deleptonization on or off
physics/sourceTerms/Deleptonize/DeleptonizeMain
delep_Enu [REAL] [10.0]
Valid Values: Unconstrained
delep_rhoOne [REAL] [0.0]
Valid Values: Unconstrained
delep_rhoTwo [REAL] [0.0]
Valid Values: Unconstrained
delep_yOne [REAL] [0.0]
Valid Values: Unconstrained
delep_yTwo [REAL] [0.0]
Valid Values: Unconstrained
delep_yc [REAL] [0.0]
Valid Values: Unconstrained
threadDelepBlockList [BOOLEAN] [TRUE]
Turn on block-list threading for the Deleptonize implementation?
threadDelepWithinBlock [BOOLEAN] [TRUE]
Turn on within-block threading for the Deleptonize implementation?
useEntr [BOOLEAN] [TRUE]
physics/sourceTerms/EnergyDeposition
useEnergyDeposition [BOOLEAN] CONSTANT [FALSE]
flag indicating whether to use EnergyDeposition unit
physics/sourceTerms/EnergyDeposition/EnergyDepositionMain
useEnergyDeposition [BOOLEAN] [TRUE]
Use Energy deposition module
physics/sourceTerms/EnergyDeposition/EnergyDepositionMain/Laser
ed_RungeKuttaMethod [STRING] ["CashKarp45"]
Valid Values: Unconstrained
Specifies the Runge Kutta method to be used for ray tracing.
ed_adjustBeamsTargetIntensity [BOOLEAN] [false]
Should 1D/2D beams target intensity be adjusted to mimic circular 3D
beams?
ed_adjustBySymmetryX [BOOLEAN] [false]
Adjust ray power and ray count to account for multiple counting in x
direction?
ed_adjustBySymmetryY [BOOLEAN] [false]
Adjust ray power and ray count to account for multiple counting in y
direction?
ed_adjustBySymmetryZ [BOOLEAN] [false]
Adjust ray power and ray count to account for multiple counting in z
direction?
ed_adjustInitialRaySpeed_1 [BOOLEAN] [true]
Adjust initial ray speed when crossing domain border ? 1
ed_adjustInitialRaySpeed_2 [BOOLEAN] [true]
Adjust initial ray speed when crossing domain border ? 2
ed_adjustInitialRaySpeed_3 [BOOLEAN] [true]
Adjust initial ray speed when crossing domain border ? 3
ed_adjustInitialRaySpeed_4 [BOOLEAN] [true]
Adjust initial ray speed when crossing domain border ? 4
ed_adjustInitialRaySpeed_5 [BOOLEAN] [true]
Adjust initial ray speed when crossing domain border ? 5
ed_adjustInitialRaySpeed_6 [BOOLEAN] [true]
Adjust initial ray speed when crossing domain border ? 6
ed_beamsCheckExpandX [BOOLEAN] [false]
In ed_beamsCheck, expand domain in x for reflecting or periodic
boundaries?
ed_beamsCheckExpandY [BOOLEAN] [false]
In ed_beamsCheck, expand domain in y for reflecting or periodic
boundaries?
ed_beamsCheckExpandZ [BOOLEAN] [false]
In ed_beamsCheck, expand domain in z for reflecting or periodic
boundaries?
ed_cellStepTolerance [REAL] [1.0e-06]
Valid Values: Unconstrained
The allowed cell fractional error (unit = cell edge) for a ray path step
ed_cellTimeEnergyDeposition [BOOLEAN] [false]
If true, calculates cell energy deposition based only on time spent in
cell
ed_cellWallThicknessFactor [REAL] [1.0e-06]
Valid Values: Unconstrained
Fraction of the shortest cell edge defining the cell wall thickness
ed_computeGradNeleP [BOOLEAN] [true]
Should the phi-component of the number of electrons gradient be
computed?
ed_computeGradNeleR [BOOLEAN] [true]
Should the r-component of the number of electrons gradient be computed?
ed_computeGradNeleT [BOOLEAN] [true]
Should the theta-component of the number of electrons gradient be
computed?
ed_computeGradNeleX [BOOLEAN] [true]
Should the x-component of the number of electrons gradient be computed?
ed_computeGradNeleY [BOOLEAN] [true]
Should the y-component of the number of electrons gradient be computed?
ed_computeGradNeleZ [BOOLEAN] [true]
Should the z-component of the number of electrons gradient be computed?
ed_createRaysExpandX [BOOLEAN] [false]
In ed_createRays, expand domain in x for reflecting and periodic
boundaries?
ed_createRaysExpandY [BOOLEAN] [false]
In ed_createRays, expand domain in y for reflecting and periodic
boundaries?
ed_createRaysExpandZ [BOOLEAN] [false]
In ed_createRays, expand domain in z for reflecting and periodic
boundaries?
ed_crossSectionFunctionType_1 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 1
ed_crossSectionFunctionType_2 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 2
ed_crossSectionFunctionType_3 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 3
ed_crossSectionFunctionType_4 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 4
ed_crossSectionFunctionType_5 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 5
ed_crossSectionFunctionType_6 [STRING] [" "]
Valid Values: Unconstrained
Function type which sets the irradiance pattern for beam 6
ed_cubicInterpolationZeroDerv [BOOLEAN] [false]
Set all cubic interpolation vertex derivatives = 0 (default
monotonicity)?
ed_depoReuseMaxSteps [INTEGER] [-1]
Valid Values: -1 to INFTY
Maximum number of time steps for which a computed energy deposition rate
(stored in the ed_depoVar variable) can be reused. If 0, the rate can
still be reused in the same timestep; this can make a difference when a
split Driver implementation is used which calls EnergyDeposition more
than once per time step. Set to -1 to completely disable reuse of depo
rate.
ed_depoVarName [STRING] ["depo"]
Valid Values: Unconstrained
Name of the variable used for storing the computed deposition rate for
reuse; the default is "depo". Note that "depo" can refer to either
DEPO_VAR or DEPO_MSCALAR in the Flash code, depending on whether a
VARIABLE or a MASS_SCALAR statement is used to declare the variable.
Further note that if a VARIABLE statement is used, it can be combined
with either TYPE: PER_MASS or TYPE: PER_VOLUME to get difference
variants of reuse.
ed_enforcePositiveNele [BOOLEAN] [true]
Rescale the number of electrons gradient such that it is always >= 0?
ed_enforcePositiveTele [BOOLEAN] [true]
Rescale the electron temperature gradient such that it is always >= 0?
ed_gaussianCenterMajor_1 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 1
ed_gaussianCenterMajor_2 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 2
ed_gaussianCenterMajor_3 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 3
ed_gaussianCenterMajor_4 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 4
ed_gaussianCenterMajor_5 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 5
ed_gaussianCenterMajor_6 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the major semiaxis for beam 6
ed_gaussianCenterMinor_1 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 1
ed_gaussianCenterMinor_2 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 2
ed_gaussianCenterMinor_3 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 3
ed_gaussianCenterMinor_4 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 4
ed_gaussianCenterMinor_5 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 5
ed_gaussianCenterMinor_6 [REAL] [0.0]
Valid Values: Unconstrained
The gaussian center location along the minor semiaxis for beam 6
ed_gaussianExponent_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 1
ed_gaussianExponent_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 2
ed_gaussianExponent_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 3
ed_gaussianExponent_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 4
ed_gaussianExponent_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 5
ed_gaussianExponent_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian exponent for beam 6
ed_gaussianRadiusMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 1
ed_gaussianRadiusMajor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 2
ed_gaussianRadiusMajor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 3
ed_gaussianRadiusMajor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 4
ed_gaussianRadiusMajor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 5
ed_gaussianRadiusMajor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the major semiaxis for beam 6
ed_gaussianRadiusMinor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 1
ed_gaussianRadiusMinor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 2
ed_gaussianRadiusMinor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 3
ed_gaussianRadiusMinor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 4
ed_gaussianRadiusMinor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 5
ed_gaussianRadiusMinor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The gaussian e-folding length along the minor semiaxis for beam 6
ed_gradOrder [INTEGER] [2]
Valid Values: 1, 2
Gradient order. 1 = no gradient, 2 = first order differencing
ed_gridDeltaSemiAxisMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the major semiaxis for delta defined grids 1
ed_gridDeltaSemiAxisMajor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the major semiaxis for delta defined grids 2
ed_gridDeltaSemiAxisMajor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the major semiaxis for delta defined grids 3
ed_gridDeltaSemiAxisMajor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the major semiaxis for delta defined grids 4
ed_gridDeltaSemiAxisMajor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the major semiaxis for delta defined grids 5
ed_gridDeltaSemiAxisMajor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the major semiaxis for delta defined grids 6
ed_gridDeltaSemiAxisMinor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the minor semiaxis for delta defined grids 1
ed_gridDeltaSemiAxisMinor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the minor semiaxis for delta defined grids 2
ed_gridDeltaSemiAxisMinor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the minor semiaxis for delta defined grids 3
ed_gridDeltaSemiAxisMinor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the minor semiaxis for delta defined grids 4
ed_gridDeltaSemiAxisMinor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the minor semiaxis for delta defined grids 5
ed_gridDeltaSemiAxisMinor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The tic spacing for the minor semiaxis for delta defined grids 6
ed_gridType_1 [STRING] [" "]
Valid Values: "rectangular2D", "square2D", "delta2D", "radial2D",
"statistical2D", "regular1D", "statistical1D", " "
The type of beam grid 1
ed_gridType_2 [STRING] [" "]
Valid Values: "rectangular2D", "square2D", "delta2D", "radial2D",
"statistical2D", "regular1D", "statistical1D", " "
The type of beam grid 2
ed_gridType_3 [STRING] [" "]
Valid Values: "rectangular2D", "square2D", "delta2D", "radial2D",
"statistical2D", "regular1D", "statistical1D", " "
The type of beam grid 3
ed_gridType_4 [STRING] [" "]
Valid Values: "rectangular2D", "square2D", "delta2D", "radial2D",
"statistical2D", "regular1D", "statistical1D", " "
The type of beam grid 4
ed_gridType_5 [STRING] [" "]
Valid Values: "rectangular2D", "square2D", "delta2D", "radial2D",
"statistical2D", "regular1D", "statistical1D", " "
The type of beam grid 5
ed_gridType_6 [STRING] [" "]
Valid Values: "rectangular2D", "square2D", "delta2D", "radial2D",
"statistical2D", "regular1D", "statistical1D", " "
The type of beam grid 6
ed_gridnAngularTics_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of angular ray positions for radial type grids 1
ed_gridnAngularTics_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of angular ray positions for radial type grids 2
ed_gridnAngularTics_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of angular ray positions for radial type grids 3
ed_gridnAngularTics_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of angular ray positions for radial type grids 4
ed_gridnAngularTics_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of angular ray positions for radial type grids 5
ed_gridnAngularTics_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of angular ray positions for radial type grids 6
ed_gridnRadialTics_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of radial ray positions for radial type grids 1
ed_gridnRadialTics_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of radial ray positions for radial type grids 2
ed_gridnRadialTics_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of radial ray positions for radial type grids 3
ed_gridnRadialTics_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of radial ray positions for radial type grids 4
ed_gridnRadialTics_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of radial ray positions for radial type grids 5
ed_gridnRadialTics_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of radial ray positions for radial type grids 6
ed_gridnSemiAxisMajorTics_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of major semiaxis ray positions for rectangular type grids 1
ed_gridnSemiAxisMajorTics_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of major semiaxis ray positions for rectangular type grids 2
ed_gridnSemiAxisMajorTics_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of major semiaxis ray positions for rectangular type grids 3
ed_gridnSemiAxisMajorTics_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of major semiaxis ray positions for rectangular type grids 4
ed_gridnSemiAxisMajorTics_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of major semiaxis ray positions for rectangular type grids 5
ed_gridnSemiAxisMajorTics_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of major semiaxis ray positions for rectangular type grids 6
ed_gridnSemiAxisMinorTics_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of minor semiaxis ray positions for rectangular type grids 1
ed_gridnSemiAxisMinorTics_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of minor semiaxis ray positions for rectangular type grids 2
ed_gridnSemiAxisMinorTics_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of minor semiaxis ray positions for rectangular type grids 3
ed_gridnSemiAxisMinorTics_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of minor semiaxis ray positions for rectangular type grids 4
ed_gridnSemiAxisMinorTics_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of minor semiaxis ray positions for rectangular type grids 5
ed_gridnSemiAxisMinorTics_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
Number of minor semiaxis ray positions for rectangular type grids 6
ed_ignoreBoundaryCondition_1 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 1
ed_ignoreBoundaryCondition_2 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 2
ed_ignoreBoundaryCondition_3 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 3
ed_ignoreBoundaryCondition_4 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 4
ed_ignoreBoundaryCondition_5 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 5
ed_ignoreBoundaryCondition_6 [BOOLEAN] [false]
Option to ignore domain boundary conditions for beam 6
ed_irradVarName [STRING] ["lase"]
Valid Values: Unconstrained
Name of the variable used for storing the computed laser radiation field
energy density; the default is "lase". Note that "lase" should refer to
LASE_VAR in the Flash code, and a VARIABLE statement should be used to
declare the variable. Further note that the VARIABLE statement should
declare TYPE: PER_VOLUME.
ed_laser3Din2D [BOOLEAN] [false]
Use the 3D rays in a 2D cylindrical grid ray tracing?
ed_laser3Din2DwedgeAngle [REAL] [0.0]
Valid Values: Unconstrained
Wedge angle (degrees, must be < 180) for laser 3D in 2D simulations
ed_lensSemiAxisMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 1
ed_lensSemiAxisMajor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 2
ed_lensSemiAxisMajor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 3
ed_lensSemiAxisMajor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 4
ed_lensSemiAxisMajor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 5
ed_lensSemiAxisMajor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Lens major elliptical semiaxis length for beam 6
ed_lensX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens for beam 1
ed_lensX_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens for beam 2
ed_lensX_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens for beam 3
ed_lensX_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens for beam 4
ed_lensX_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens for beam 5
ed_lensX_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the lens for beam 6
ed_lensY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens for beam 1
ed_lensY_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens for beam 2
ed_lensY_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens for beam 3
ed_lensY_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens for beam 4
ed_lensY_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens for beam 5
ed_lensY_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the lens for beam 6
ed_lensZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens for beam 1
ed_lensZ_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens for beam 2
ed_lensZ_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens for beam 3
ed_lensZ_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens for beam 4
ed_lensZ_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens for beam 5
ed_lensZ_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the lens for beam 6
ed_maxRayCount [INTEGER] [100]
Valid Values: Unconstrained
Maximum number of rays per processor
ed_numberOfBeams [INTEGER] [-1]
Valid Values: Unconstrained
Total number of laser beams
ed_numberOfPulses [INTEGER] [-1]
Valid Values: Unconstrained
Total number of laser pulses
ed_numberOfRays_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of rays to launch per timestep for beam 1
ed_numberOfRays_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of rays to launch per timestep for beam 2
ed_numberOfRays_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of rays to launch per timestep for beam 3
ed_numberOfRays_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of rays to launch per timestep for beam 4
ed_numberOfRays_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of rays to launch per timestep for beam 5
ed_numberOfRays_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The number of rays to launch per timestep for beam 6
ed_numberOfSections_1 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for laser pulse 1
ed_numberOfSections_2 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for laser pulse 2
ed_numberOfSections_3 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for laser pulse 3
ed_numberOfSections_4 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for laser pulse 4
ed_numberOfSections_5 [INTEGER] [-1]
Valid Values: Unconstrained
The number of time/power pairs (sections) for laser pulse 5
ed_powerStepTolerance [REAL] [1.0e-06]
Valid Values: Unconstrained
The allowed power fractional error (unit = current power) for a ray path
step
ed_power_1_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 1
ed_power_1_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 10
ed_power_1_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 11
ed_power_1_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 12
ed_power_1_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 13
ed_power_1_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 14
ed_power_1_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 15
ed_power_1_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 16
ed_power_1_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 17
ed_power_1_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 18
ed_power_1_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 19
ed_power_1_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 2
ed_power_1_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 20
ed_power_1_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 3
ed_power_1_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 4
ed_power_1_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 5
ed_power_1_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 6
ed_power_1_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 7
ed_power_1_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 8
ed_power_1_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 1 section 9
ed_power_2_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 1
ed_power_2_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 10
ed_power_2_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 11
ed_power_2_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 12
ed_power_2_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 13
ed_power_2_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 14
ed_power_2_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 15
ed_power_2_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 16
ed_power_2_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 17
ed_power_2_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 18
ed_power_2_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 19
ed_power_2_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 2
ed_power_2_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 20
ed_power_2_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 3
ed_power_2_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 4
ed_power_2_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 5
ed_power_2_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 6
ed_power_2_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 7
ed_power_2_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 8
ed_power_2_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 2 section 9
ed_power_3_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 1
ed_power_3_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 10
ed_power_3_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 11
ed_power_3_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 12
ed_power_3_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 13
ed_power_3_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 14
ed_power_3_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 15
ed_power_3_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 16
ed_power_3_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 17
ed_power_3_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 18
ed_power_3_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 19
ed_power_3_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 2
ed_power_3_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 20
ed_power_3_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 3
ed_power_3_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 4
ed_power_3_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 5
ed_power_3_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 6
ed_power_3_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 7
ed_power_3_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 8
ed_power_3_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 3 section 9
ed_power_4_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 1
ed_power_4_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 10
ed_power_4_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 11
ed_power_4_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 12
ed_power_4_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 13
ed_power_4_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 14
ed_power_4_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 15
ed_power_4_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 16
ed_power_4_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 17
ed_power_4_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 18
ed_power_4_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 19
ed_power_4_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 2
ed_power_4_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 20
ed_power_4_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 3
ed_power_4_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 4
ed_power_4_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 5
ed_power_4_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 6
ed_power_4_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 7
ed_power_4_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 8
ed_power_4_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 4 section 9
ed_power_5_1 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 1
ed_power_5_10 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 10
ed_power_5_11 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 11
ed_power_5_12 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 12
ed_power_5_13 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 13
ed_power_5_14 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 14
ed_power_5_15 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 15
ed_power_5_16 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 16
ed_power_5_17 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 17
ed_power_5_18 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 18
ed_power_5_19 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 19
ed_power_5_2 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 2
ed_power_5_20 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 20
ed_power_5_3 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 3
ed_power_5_4 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 4
ed_power_5_5 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 5
ed_power_5_6 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 6
ed_power_5_7 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 7
ed_power_5_8 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 8
ed_power_5_9 [REAL] [-1.0]
Valid Values: Unconstrained
The power (W) for laser pulse 5 section 9
ed_printBeams [BOOLEAN] [false]
Print details about each beam?
ed_printMain [BOOLEAN] [false]
Print details about the main laser energy depoition run?
ed_printPulses [BOOLEAN] [false]
Print details about each pulse?
ed_printRays [BOOLEAN] [false]
Print details about each ray initially generated?
ed_pulseNumber_1 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for beam 1
ed_pulseNumber_2 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for beam 2
ed_pulseNumber_3 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for beam 3
ed_pulseNumber_4 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for beam 4
ed_pulseNumber_5 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for beam 5
ed_pulseNumber_6 [INTEGER] [-HUGE(1)]
Valid Values: Unconstrained
The pulse number to use for beam 6
ed_radial3Dcontraction_1 [BOOLEAN] [false]
Do a radial contraction distribution of rays for 3D beams ? 1
ed_radial3Dcontraction_2 [BOOLEAN] [false]
Do a radial contraction distribution of rays for 3D beams ? 2
ed_radial3Dcontraction_3 [BOOLEAN] [false]
Do a radial contraction distribution of rays for 3D beams ? 3
ed_radial3Dcontraction_4 [BOOLEAN] [false]
Do a radial contraction distribution of rays for 3D beams ? 4
ed_radial3Dcontraction_5 [BOOLEAN] [false]
Do a radial contraction distribution of rays for 3D beams ? 5
ed_radial3Dcontraction_6 [BOOLEAN] [false]
Do a radial contraction distribution of rays for 3D beams ? 6
ed_rayZeroPower [REAL] [1.0e-06]
Valid Values: Unconstrained
Below this value (erg/s), the ray is considered to have zero power
ed_saveOutOfDomainRays [BOOLEAN] [false]
Should the rays exiting the domain be saved (for diagnostics) ?
ed_semiAxisMajorTorsionAngle_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 1
ed_semiAxisMajorTorsionAngle_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 2
ed_semiAxisMajorTorsionAngle_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 3
ed_semiAxisMajorTorsionAngle_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 4
ed_semiAxisMajorTorsionAngle_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 5
ed_semiAxisMajorTorsionAngle_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Major semiaxis/{x,y,z} axis rotation angle (in degrees) for beam 6
ed_semiAxisMajorTorsionAxis_1 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam1
ed_semiAxisMajorTorsionAxis_2 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam2
ed_semiAxisMajorTorsionAxis_3 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam3
ed_semiAxisMajorTorsionAxis_4 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam4
ed_semiAxisMajorTorsionAxis_5 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam5
ed_semiAxisMajorTorsionAxis_6 [STRING] [" "]
Valid Values: Unconstrained
{x,y,z} axis to use for rotating major semiaxis for beam6
ed_targetSemiAxisMajor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 1
ed_targetSemiAxisMajor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 2
ed_targetSemiAxisMajor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 3
ed_targetSemiAxisMajor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 4
ed_targetSemiAxisMajor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 5
ed_targetSemiAxisMajor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target major elliptical semiaxis length for beam 6
ed_targetSemiAxisMinor_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 1
ed_targetSemiAxisMinor_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 2
ed_targetSemiAxisMinor_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 3
ed_targetSemiAxisMinor_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 4
ed_targetSemiAxisMinor_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 5
ed_targetSemiAxisMinor_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
Target minor elliptical semiaxis length for beam 6
ed_targetX_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target for beam 1
ed_targetX_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target for beam 2
ed_targetX_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target for beam 3
ed_targetX_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target for beam 4
ed_targetX_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target for beam 5
ed_targetX_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The x coordinate of the target for beam 6
ed_targetY_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target for beam 1
ed_targetY_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target for beam 2
ed_targetY_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target for beam 3
ed_targetY_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target for beam 4
ed_targetY_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target for beam 5
ed_targetY_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The y coordinate of the target for beam 6
ed_targetZ_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target for beam 1
ed_targetZ_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target for beam 2
ed_targetZ_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target for beam 3
ed_targetZ_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target for beam 4
ed_targetZ_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target for beam 5
ed_targetZ_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The z coordinate of the target for beam 6
ed_time_1_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 1
ed_time_1_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 10
ed_time_1_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 11
ed_time_1_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 12
ed_time_1_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 13
ed_time_1_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 14
ed_time_1_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 15
ed_time_1_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 16
ed_time_1_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 17
ed_time_1_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 18
ed_time_1_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 19
ed_time_1_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 2
ed_time_1_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 20
ed_time_1_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 3
ed_time_1_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 4
ed_time_1_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 5
ed_time_1_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 6
ed_time_1_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 7
ed_time_1_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 8
ed_time_1_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 1 section 9
ed_time_2_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 1
ed_time_2_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 10
ed_time_2_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 11
ed_time_2_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 12
ed_time_2_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 13
ed_time_2_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 14
ed_time_2_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 15
ed_time_2_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 16
ed_time_2_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 17
ed_time_2_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 18
ed_time_2_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 19
ed_time_2_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 2
ed_time_2_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 20
ed_time_2_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 3
ed_time_2_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 4
ed_time_2_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 5
ed_time_2_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 6
ed_time_2_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 7
ed_time_2_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 8
ed_time_2_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 2 section 9
ed_time_3_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 1
ed_time_3_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 10
ed_time_3_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 11
ed_time_3_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 12
ed_time_3_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 13
ed_time_3_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 14
ed_time_3_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 15
ed_time_3_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 16
ed_time_3_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 17
ed_time_3_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 18
ed_time_3_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 19
ed_time_3_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 2
ed_time_3_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 20
ed_time_3_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 3
ed_time_3_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 4
ed_time_3_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 5
ed_time_3_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 6
ed_time_3_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 7
ed_time_3_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 8
ed_time_3_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 3 section 9
ed_time_4_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 1
ed_time_4_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 10
ed_time_4_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 11
ed_time_4_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 12
ed_time_4_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 13
ed_time_4_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 14
ed_time_4_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 15
ed_time_4_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 16
ed_time_4_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 17
ed_time_4_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 18
ed_time_4_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 19
ed_time_4_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 2
ed_time_4_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 20
ed_time_4_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 3
ed_time_4_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 4
ed_time_4_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 5
ed_time_4_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 6
ed_time_4_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 7
ed_time_4_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 8
ed_time_4_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 4 section 9
ed_time_5_1 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 1
ed_time_5_10 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 10
ed_time_5_11 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 11
ed_time_5_12 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 12
ed_time_5_13 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 13
ed_time_5_14 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 14
ed_time_5_15 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 15
ed_time_5_16 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 16
ed_time_5_17 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 17
ed_time_5_18 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 18
ed_time_5_19 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 19
ed_time_5_2 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 2
ed_time_5_20 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 20
ed_time_5_3 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 3
ed_time_5_4 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 4
ed_time_5_5 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 5
ed_time_5_6 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 6
ed_time_5_7 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 7
ed_time_5_8 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 8
ed_time_5_9 [REAL] [-1.0]
Valid Values: Unconstrained
The time (s) for laser pulse 5 section 9
ed_useRayCoords2GetBlockID [BOOLEAN] [false]
If true, the Grid Unit uses ray coordinates to determine the block ID
ed_velocityStepTolerance [REAL] [1.0e-06]
Valid Values: Unconstrained
The allowed velocity fractional error for a ray path step
ed_wavelength_1 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The wave length [in microns] of beam 1
ed_wavelength_2 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The wave length [in microns] of beam 2
ed_wavelength_3 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The wave length [in microns] of beam 3
ed_wavelength_4 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The wave length [in microns] of beam 4
ed_wavelength_5 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The wave length [in microns] of beam 5
ed_wavelength_6 [REAL] [-HUGE(1.0)]
Valid Values: Unconstrained
The wave length [in microns] of beam 6
threadRayTrace [BOOLEAN] [true]
Use threading when tracing the rays through each block?
useEnergyDeposition [BOOLEAN] [true]
Use Laser energy deposition?
physics/sourceTerms/EnergyDeposition/EnergyDepositionMain/Laser/LaserComm/Async
ed_commChannelSize [INTEGER] [100]
Valid Values: 1 to INFTY
ed_commDebug [BOOLEAN] [TRUE]
ed_commLog [BOOLEAN] [FALSE]
ed_commRaysBetweenMsgTest [INTEGER] [50]
Valid Values: 1 to INFTY
physics/sourceTerms/EnergyDeposition/EnergyDepositionMain/Laser/LaserIO
ed_laserIOMaxNumberOfPositions [INTEGER] [-1]
Valid Values: Unconstrained
Maximum number of positions to store for each IO ray
ed_laserIOMaxNumberOfRays [INTEGER] [-1]
Valid Values: Unconstrained
Maximum number of IO rays to write out accross each process
ed_useLaserIO [BOOLEAN] [false]
This flag controls whether Laser IO is active
physics/sourceTerms/Flame
useFlame [BOOLEAN] CONSTANT [FALSE]
Whether the flame should be advanced.
physics/sourceTerms/Flame/FlameEffects/BurnParametric
eos_tolerance [REAL] [1.e-8]
Valid Values: Unconstrained
tolerance for the Newton-Raphson iterations
physics/sourceTerms/Flame/FlameEffects/EIP
flame_deltae [REAL] [0.0]
Valid Values: Unconstrained
sumyi_burned [REAL] [1.0]
Valid Values: Unconstrained
sumyi_unburned [REAL] [1.0]
Valid Values: Unconstrained
ye_burned [REAL] [0.5]
Valid Values: Unconstrained
ye_unburned [REAL] [0.5]
Valid Values: Unconstrained
physics/sourceTerms/Flame/FlameMain
fl_b [REAL] [3.2]
Valid Values: Unconstrained
flame width parameter in units of cells
fl_epsilon_0 [REAL] [1.0e-3]
Valid Values: Unconstrained
lower sharpening factor for sKPP, reaction \propto
(f-epsilon_0)*(1+epsilon_1-f)
fl_epsilon_1 [REAL] [1.0e-3]
Valid Values: Unconstrained
upper sharpening factor for sKPP, reaction \propto
(f-epsilon_0)*(1+epsilon_1-f)
fl_initProfileAdjustWidth [REAL] [1.0]
Valid Values: Unconstrained
multiplicative adjustment of width of initial profile. 0.8 was used for
some SNIa simulations, but should usually be default of 1.
fl_kpp_fact [REAL] [1.309]
Valid Values: Unconstrained
reaction prefactor adjustment factor for sKPP
useFlame [BOOLEAN] [TRUE]
Whether the flame should be advanced.
physics/sourceTerms/Flame/FlameSpeed/BuoyancyCompensation
approx_atwood [BOOLEAN] [false]
only used for CO configuration, not for CONe
fl_fsBuoyCompSuppress [BOOLEAN] [false]
Suppress (turn off) Buoyancy Compensation flame speed enhancement per
selected time and region
fl_fsBuoyCompSuppressTheta [REAL] [135.0]
Valid Values: Unconstrained
Extent of suppression region in degrees from south pole (-z in cart.)
fl_fsBuoyCompSuppressTime [REAL] [1.5]
Valid Values: Unconstrained
Time after which to suppress in selected region
fl_fsConstFlameSpeed [REAL] [1.0]
Valid Values: Unconstrained
fl_fsConstFlameWidth [REAL] [1.0]
Valid Values: Unconstrained
fl_fsGcdFlameSuppress [BOOLEAN] [false]
Suppress (set flamespeed to zero) flame per selected time and region
fl_fsGcdFlameSuppressTheta [REAL] [135.0]
Valid Values: Unconstrained
Extent of suppression region in degrees from south pole (-z in cart.)
fl_fsGcdFlameSuppressTime [REAL] [1.5]
Valid Values: Unconstrained
Time after which to suppress in selected region
fl_fsM [REAL] [0.06]
Valid Values: Unconstrained
factor for buoyancy-compensating enhancement of flame speed, fs =
0.5*sqrt(Atwood*g*fl_fsM*Delta)
fl_fsQuench [BOOLEAN] [true]
fl_fsQuenchDens0 [REAL] [1.0e6]
Valid Values: Unconstrained
fl_fsQuenchDens1 [REAL] [1.0e7]
Valid Values: Unconstrained
fl_fsUseConstFlameSpeed [BOOLEAN] [false]
fl_fsUseTFI [BOOLEAN] [false]
physics/sourceTerms/Flame/FlameSpeed/BuoyancyCompensation/CONe
max_c_frac [REAL] [1.0]
Valid Values: Unconstrained
max_dens [REAL] [4.e9]
Valid Values: Unconstrained
min_c_frac [REAL] [0.3]
Valid Values: Unconstrained
num_c_frac [INTEGER] [9]
Valid Values: Unconstrained
num_ldens [INTEGER] [20]
Valid Values: Unconstrained
rep_ne_frac [REAL] [0.01]
Valid Values: Unconstrained
physics/sourceTerms/Flame/FlameSpeed/Constant
fl_fsConstFlameSpeed [REAL] [1.e0]
Valid Values: Unconstrained
fl_fsConstFlameWidth [REAL] [1.e0]
Valid Values: Unconstrained
physics/sourceTerms/Flame/FlameSpeed/Constant/TFI
fl_fsUseTFI [BOOLEAN] [false]
physics/sourceTerms/Flame/FlameSpeed/LaminarOnly
fl_fsConstFlameSpeed [REAL] [1.e0]
Valid Values: Unconstrained
fl_fsConstFlameWidth [REAL] [1.e0]
Valid Values: Unconstrained
fl_fsUseConstFlameSpeed [BOOLEAN] [false]
fl_fsUseTFI [BOOLEAN] [false]
physics/sourceTerms/Flame/FlameSpeed/laminar/CONe
fl_fsCONeTableName [STRING] ["CONeFlameTable.txt"]
Valid Values: Unconstrained
name of table containing nuclear flame speed table
physics/sourceTerms/Flame/FlameSpeed/turbulent/tfi/charlette
fl_fsTFIBeta [REAL] [0.3333333]
Valid Values: Unconstrained
fl_fsTFIPrandtl [REAL] [1.e-5]
Valid Values: Unconstrained
physics/sourceTerms/Flame/FlameSpeed/turbulent/tfi/charlette/gammaInt
fl_fsTFIetol [REAL] [1.e-3]
Valid Values: Unconstrained
controls the accuracy of the integrator
physics/sourceTerms/Flame/FlameSpeed/turbulent/tfi/damkohler
fl_fsTFIBeta [REAL] [1.0]
Valid Values: Unconstrained
physics/sourceTerms/Flame/FlameSpeed/turbulent/tfi/kolmogorov
fl_fsTFIBeta [REAL] [5.0]
Valid Values: Unconstrained
fl_fsTFIViscosity [REAL] [1.0e-2]
Valid Values: Unconstrained
physics/sourceTerms/Flame/FlameSpeed/turbulent/tfi/pocheau
fl_fsTFICt [REAL] [1.333333333]
Valid Values: Unconstrained
physics/sourceTerms/Heat
useHeat [BOOLEAN] [FALSE]
runtime control for turning the heat on or off
physics/sourceTerms/Heat/HeatMain/Neutrino
Lneut [REAL] [0.0]
Valid Values: Unconstrained
Parametric neutrino luminosity
Tneut [REAL] [0.0]
Valid Values: Unconstrained
Neutrino temperature in MeV
bounce_time [REAL] [0.0]
Valid Values: Unconstrained
The time of bounce in s.
heatTimeFac [REAL] [1.0e4]
Valid Values: Unconstrained
For adjusting the heating time step size
physics/sourceTerms/Heat/HeatMain/RadioactiveDecay
ht_applyHeating [BOOLEAN] [TRUE]
Apply heating deposition to total energy?
qheat [REAL] [0.0E0]
Valid Values: Unconstrained
intensity of the transient heating
sigheat [REAL] [1.0E0]
Valid Values: Unconstrained
sigma of the transient heating
statheat [REAL] [1.0E-5]
Valid Values: Unconstrained
stationary heating
t0heat [REAL] [-1.0E0]
Valid Values: Unconstrained
switch off time of the transient
tau [REAL] [1.0E0]
Valid Values: Unconstrained
decay time of the transient
theatmin [REAL] [1.0E3]
Valid Values: Unconstrained
Min heating temperature
tstar [REAL] [-1.0E0]
Valid Values: Unconstrained
start time of the transient
useHeat [BOOLEAN] [TRUE]
x0heat [REAL] [1.0E0]
Valid Values: Unconstrained
X location of the transient heating
y0heat [REAL] [1.0E0]
Valid Values: Unconstrained
Y location of the transient heating
z0heat [REAL] [1.0E0]
Valid Values: Unconstrained
Z location of the transient heating
physics/sourceTerms/Heatexchange
useHeatexchange [BOOLEAN] CONSTANT [FALSE]
physics/sourceTerms/Heatexchange/HeatexchangeMain
hx_logLevel [INTEGER] [700]
Valid Values: 0 to INFTY
controls the level of logging for some conditions. See Heatexchange.h
for relevant HX_LOGLEVEL_* definitions.
useHeatexchange [BOOLEAN] [TRUE]
physics/sourceTerms/Heatexchange/HeatexchangeMain/ConstCoulomb
hx_coulombLog [REAL] [1.0]
Valid Values: 0.0 to INFTY
hx_couplingConst13 [REAL] [0.0]
Valid Values: 0.0 to INFTY
hx_couplingConst23 [REAL] [1.0]
Valid Values: 0.0 to INFTY
hx_dtFactor [REAL] [0.5]
Valid Values: 0.0+ to INFTY
hx_relTol [REAL] [-1.0]
Valid Values: Unconstrained
relative tolerance for temperature errors introduced by HeatExchange.
This runtime parameter affects the time step computed by
Heatexchange_computeDt. Basically, if the max (abs) temperature
adjustment that would be introduced in any nonzero component in any cell
is less than hx_relTol, then the time step limit is relaxed. Set to a
negative value to inherite the value of runtime parameter eos_tolerance.
physics/sourceTerms/Heatexchange/HeatexchangeMain/Constant
hx_couplingConst12 [REAL] [1.0]
Valid Values: 0.0 to INFTY
ion-electron heat exchange coupling constant
hx_couplingConst13 [REAL] [0.0]
Valid Values: -1.0, 0.0 to INFTY
ion-radiation heat exchange coupling constant (usually ignored)
hx_couplingConst23 [REAL] [1.0]
Valid Values: -1.0, 0.0 to INFTY
electron-radiation heat exchange coupling constant, representing
emission and absorption effects
hx_dtFactor [REAL] [0.5]
Valid Values: 0.0+ to INFTY
hx_relTol [REAL] [-1.0]
Valid Values: Unconstrained
relative tolerance for temperature errors introduced by HeatExchange.
This runtime parameter affects the time step computed by
Heatexchange_computeDt. Basically, if the max (abs) temperature
adjustment that would be introduced in any nonzero component in any cell
is less than hx_relTol, then the time step limit is relaxed. Set to a
negative value to inherite the value of runtime parameter eos_tolerance.
physics/sourceTerms/Heatexchange/HeatexchangeMain/Immediate
hx_applyToRadiation [BOOLEAN] [FALSE]
Does the Immediate Heatexchange implementation apply to radiation?
physics/sourceTerms/Heatexchange/HeatexchangeMain/LeeMore
hx_dtFactor [REAL] [0.5]
Valid Values: 0.0+ to INFTY
hx_ieTimeCoef [REAL] [1.0]
Valid Values: 0.0 to INFTY
Constant coefficient for scaling ion/ele coupling time
hx_relTol [REAL] [-1.0]
Valid Values: Unconstrained
relative tolerance for temperature errors introduced by HeatExchange.
This runtime parameter affects the time step computed by
Heatexchange_computeDt. Basically, if the max (abs) temperature
adjustment that would be introduced in any nonzero component in any cell
is less than hx_relTol, then the time step limit is relaxed. Set to a
negative value to inherite the value of runtime parameter eos_tolerance.
physics/sourceTerms/Heatexchange/HeatexchangeMain/Spitzer
hx_dtFactor [REAL] [0.5]
Valid Values: 0.0+ to INFTY
hx_ieTimeCoef [REAL] [1.0]
Valid Values: 0.0 to INFTY
Constant coefficient for scaling ion/ele coupling time
hx_relTol [REAL] [-1.0]
Valid Values: Unconstrained
relative tolerance for temperature errors introduced by HeatExchange.
This runtime parameter affects the time step computed by
Heatexchange_computeDt. Basically, if the max (abs) temperature
adjustment that would be introduced in any nonzero component in any cell
is less than hx_relTol, then the time step limit is relaxed. Set to a
negative value to inherite the value of runtime parameter eos_tolerance.
physics/sourceTerms/Ionize
useIonize [BOOLEAN] [FALSE]
Whether Ionize calculations should be performed.
physics/sourceTerms/Ionize/IonizeMain
dneimax [REAL] [1.0E12]
Valid Values: Unconstrained
Max NEI density
dneimin [REAL] [1.0E0]
Valid Values: Unconstrained
Min NEI density
tneimax [REAL] [1.0E7]
Valid Values: Unconstrained
Max NEI temperature
tneimin [REAL] [1.0E4]
Valid Values: Unconstrained
Min NEI temperature
useIonize [BOOLEAN] [TRUE]
Whether Ionize calculations should be performed.
physics/sourceTerms/Polytrope
usePolytrope [BOOLEAN] [FALSE]
Runtime switch for turning the polytropic eos on/off
physics/sourceTerms/Polytrope/PolytropeMain
polytropeDens1 [REAL] [1e99]
Valid Values: Unconstrained
polytropeDens2 [REAL] [1e99]
Valid Values: Unconstrained
polytropeDens3 [REAL] [1e99]
Valid Values: Unconstrained
polytropeDens4 [REAL] [1e99]
Valid Values: Unconstrained
polytropeDens5 [REAL] [1e99]
Valid Values: Unconstrained
polytropeGamma1 [REAL] [1.0]
Valid Values: Unconstrained
polytropeGamma2 [REAL] [1.0]
Valid Values: Unconstrained
polytropeGamma3 [REAL] [1.0]
Valid Values: Unconstrained
polytropeGamma4 [REAL] [1.0]
Valid Values: Unconstrained
polytropeGamma5 [REAL] [1.0]
Valid Values: Unconstrained
polytropeKonst [REAL] [1.0]
Valid Values: Unconstrained
press = polytropeKonst*dens^polytropeGamma1 for dens1 <= dens <= dens2
usePolytrope [BOOLEAN] [FALSE]
Runtime switch for turning the polytropic eos on/off
physics/sourceTerms/PrimordialChemistry
usePrimordialChemistry [BOOLEAN] [FALSE]
physics/sourceTerms/PrimordialChemistry/PrimordialChemistryMain
pchem_algebra [INTEGER] [2]
Valid Values: Unconstrained
pchem_ccCase [INTEGER] [1]
Valid Values: Unconstrained
pchem_doCool [INTEGER] [1]
Valid Values: Unconstrained
pchem_fracDeuterium [REAL] [0.0]
Valid Values: Unconstrained
pchem_fracHelium [REAL] [0.240]
Valid Values: Unconstrained
pchem_fracHydrogen [REAL] [0.760]
Valid Values: Unconstrained
pchem_fshh2 [REAL] [1.0]
Valid Values: Unconstrained
pchem_fshhd [REAL] [1.0]
Valid Values: Unconstrained
pchem_j21 [REAL] [0.0]
Valid Values: Unconstrained
pchem_mCool [INTEGER] [1]
Valid Values: Unconstrained
pchem_odeStepper [INTEGER] [1]
Valid Values: Unconstrained
physics/sourceTerms/PrimordialChemistry/PrimordialChemistryMain/GA08
pchem_algebra [INTEGER] [2]
Valid Values: Unconstrained
pchem_ccCase [INTEGER] [1]
Valid Values: Unconstrained
pchem_doCool [INTEGER] [1]
Valid Values: Unconstrained
pchem_dradmax [REAL] [1.0e-10]
Valid Values: Unconstrained
pchem_dradmin [REAL] [1.0e-30]
Valid Values: Unconstrained
pchem_fracDeuterium [REAL] [0.0]
Valid Values: Unconstrained
pchem_fracHelium [REAL] [0.240]
Valid Values: Unconstrained
pchem_fracHydrogen [REAL] [0.760]
Valid Values: Unconstrained
pchem_fshh2 [REAL] [1.0]
Valid Values: Unconstrained
pchem_fshhd [REAL] [1.0]
Valid Values: Unconstrained
pchem_j21 [REAL] [0.0]
Valid Values: Unconstrained
pchem_mCool [INTEGER] [1]
Valid Values: Unconstrained
pchem_massFracH [REAL] [0.76]
Valid Values: Unconstrained
pchem_noCool [REAL] [1.0]
Valid Values: Unconstrained
pchem_odeStepper [INTEGER] [1]
Valid Values: Unconstrained
pchem_rcCase [INTEGER] [1]
Valid Values: Unconstrained
pchem_tradmax [REAL] [1.0e9]
Valid Values: Unconstrained
pchem_tradmin [REAL] [50.0]
Valid Values: Unconstrained
usePrimordialChemistry [BOOLEAN] [TRUE]
physics/sourceTerms/Stir
useStir [BOOLEAN] CONSTANT [FALSE]
Runtime switch for turning stirring on/off
physics/sourceTerms/Stir/StirMain
st_computeDt [BOOLEAN] [FALSE]
whether to restrict time step based on stirring
useStir [BOOLEAN] [TRUE]
Runtime switch for turning stirring on/off
physics/sourceTerms/Stir/StirMain/FromFile
st_computeDt [BOOLEAN] [FALSE]
whether to restrict time step based on stirring
st_infilename [STRING] ["forcingfile.dat"]
Valid Values: Unconstrained
file containing the stirring time sequence
physics/sourceTerms/Stir/StirMain/Generate
st_decay [REAL] [.1]
Valid Values: Unconstrained
correlation time for driving
st_energy [REAL] [.01]
Valid Values: Unconstrained
energy input/mode
st_freq [INTEGER] [1]
Valid Values: Unconstrained
the frequency of stirring
st_reproducible [BOOLEAN] [FALSE]
st_saveReproducible [BOOLEAN] [FALSE]
st_seed [INTEGER] [2]
Valid Values: Unconstrained
random number generator seed
st_stirmax [REAL] [62.8]
Valid Values: Unconstrained
maximum stirring *wavenumber*
st_stirmin [REAL] [31.4]
Valid Values: Unconstrained
minimum stirring *wavenumber*
physics/sourceTerms/Turb
useTurb [BOOLEAN] [TRUE]
flags whether the Turbulence unit is being used
physics/sourceTerms/Turb/TurbMain
turb_c2 [REAL] [0.9]
Valid Values: Unconstrained
is the calibrated constant for determining the turbulent velocity
turb_stepSize [INTEGER] [1]
Valid Values: Unconstrained
size of stencil in computing the laplacian and curl
physics/utilities/PlasmaState
usePlasmaState [BOOLEAN] CONSTANT [FALSE]
flags whether the PlasmaState unit is being used at all
physics/utilities/PlasmaState/PlasmaStateMain
logLambdaFloor [REAL] [1.0]
Valid Values: Unconstrained
floor value for the logLambda function
useLogLambdaFloor [BOOLEAN] [TRUE]
flags whether to use a floor in the logLambda function
usePlasmaState [BOOLEAN] [TRUE]
flags whether the PlasmaState unit is being used at all