radiative acceleration computed in pressure_total.cpp

tmn corrections made and removed in zone start/end

============================================================

photoionizatiion rates:

sum over rfield.SummedCon
except for threshold which does not pick up otscon

SummedCon is added together in RT_OTS_Update (in rtots.c)

rfield.SummedCon[i] = rfield.flux[0][i] + rfield.SummedDif[i];

rfield.SummedDif[i] = rfield.otscon[i] + rfield.otslin[i] + 
	rfield.ConInterOut[i]*rfield.lgOutOnly + rfield.outlin[0][i] +
	rfield.ConOTS_local_OTS_rate[i];

============================================================

routines:

RT_diffuse in rtdiffuse.c
determines local thermal emission
adds energy to outward beams
called by cloudy

RT_OTS, in rtots.c, continuously updates ots rates, called during solution by 
ConvIonizeOpacityDo

ContCreatePointers ets incontinuum resolution and binning by calling fill
the arguemnts to fill can be changed to change the continuum resolution

====================================================================

definition of incident continuum

ContSetIntensity - sets intensity of final continuum

Ffun returns the continuum interpoalted from the table.

The cell resolution can be changed by looking at the file continuum_mesh.ini

====================================================================

built in continua are stored in predcont.h, set in zerologic.c
#include "predcont.h"
The array name is EnrPredCont and there are NPREDCONT values
lines entered into em line stack in lines_continuum.c

====================================================================

otscon is updated in AddOTSCon,
which is called by HydroOTS, HeMetalOTS, 

final ots continuum is updated, averaged and set in SumContinuum

====================================================================

unit integration
rfield.ConInterOut[rfield.nflux] is the point

rtdiffuse adds 1e-10 to these two
	rfield.ConEmitLocal[rfield.nflux] = 1.e-10f * Dilution /* */ ;
	rfield.ThrowOut[rfield.nflux] = 1.e-10f * Dilution /* */;

check is done in prtcomment

====================================================================

ConLocInter = local continuum that does interact, thrown into outward beam

====================================================================

rfield.nflux - number of continuum points defined in current continuum
originally set to rfield.nupper in zero and contcreatemesh
set to realistic value in consetintensity
it is RESIZED in convinitemp 

====================================================================

incident continua
rfield.flux_total_incident[0][j] - the original incident continuum
rfield.flux[0] - outward attenuated incident continuum
	incident continuum is initally defined in ContSetIntensity

====================================================================

reflected continua
inward or reflected part of continuum, only computed in open geometry 
rfield.ConRefIncid[0][j] reflected incident continuum
rfield.ConRefDiff[j]) reflected diffuse continua
rfield.reflin[0][j] reflected lines 

====================================================================

diffuse local thermal continuum 
rfield.ConEmitLocal

====================================================================

outward continua
rfield.ThrowOut - outward beam of interactive continua,
	emitted in this zone, set in RT_diffuse, contains almost all of ConEmitLocal

rfield.ConInterOut - integrated outward beam, interacts
rfield.ConEmitOut[0] - total outward emission 
	calculated from local diffuse emission in radius_increment

parts of brems and h lyman continua added to ConEmitLocal but not ConInterOut

====================================================================

rfield.SummedCon[i] is sum of interactive fields

contains 
rfield.flux[0][i] 
rfield.otslin[i] 
rfield.otscon[i] 

====================================================================

rfield.outlin[0][i] 
outward lines, included in ionizing radiation

rfield.outcon[i] 
outward portion of continuum, incremented in metdif

====================================================================

each cell has associate with it character descriptions
of lines of continua there:  these are:
rfield.chLineLabel[j] ,
rfield.chContLabel[j] );

=================================================================

print diffuse continuum sets flag PrnLine.lgPrnDiff
prints the continuum at the points entered in the vector 
EnrPredCont[NPREDCONT], as set in zerologic.c
added to stack in lineset1

within the continuum array the labels for lines and continua are
LineLabl.chLineLabel[j] ,
/* cont label*/
LineLabl.chContLabel[j] );

====================================================================

continuous optical depths
/* following only optical depth to illuminated face */
opac.depabs[i] += (realnum)(opac.opac[i]*radius.drad_x_fillfac);
opac.depsct[i] += (realnum)(opac.scatop[i]*radius.drad_x_fillfac);

/* these are total in inward direction, large if sherical */
opac.tausct[0][i] += (realnum)(opac.scatop[i]*radius.drad_x_fillfac);
opac.TauTotal[0][i] = opac.tauabs[0][i] + opac.tausct[0][i];

these are incremeneted in radinc.c

dtrans.chDffTrns =  "OTS"
or
dtrans.chDffTrns, "OUn"
default is "OU2" set in zero.c

============================================================

hydrogenic species are discussed in hydrogen.txt

====================================================================

bounds are 
/* these are the low and high energy bounds of the continuum */
rfield.emm = 1.001e-8f;
rfield.egamry = 7.354e6f;

============================================================