248 lines
7.2 KiB
Fortran
248 lines
7.2 KiB
Fortran
SUBROUTINE RATSP1
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C =================
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C
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C Evaluation of "preconditioned" radiative rates
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C
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INCLUDE 'IMPLIC.FOR'
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INCLUDE 'BASICS.FOR'
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INCLUDE 'ATOMIC.FOR'
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INCLUDE 'MODELQ.FOR'
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INCLUDE 'ODFPAR.FOR'
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INCLUDE 'ALIPAR.FOR'
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INCLUDE 'ARRAY1.FOR'
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INCLUDE 'ITERAT.FOR'
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PARAMETER(PGRD=4.1916825D-10)
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DIMENSION EHK(MDEPTH)
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C DIMENSION EHKL(MFREQL)
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C
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C zero the rates
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C
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DO ID=1,ND
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PRADT(ID)=0.
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PRADA(ID)=0.
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FLRD(ID)=0.
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DO ITR=1,NTRANS
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RRU(ITR,ID)=0.
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RRD(ITR,ID)=0.
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END DO
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DO ITRP=1,NTRPRD
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PJBAR(ITRP,ID)=0.
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END DO
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END DO
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PRD0=0.
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C
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LROSS=NDRE.LE.0.AND.ITER.EQ.1.OR.LFIN
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IF(HMIX0.GT.0.) LROSS=.TRUE.
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IF(LROSS) THEN
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DO ID=1,ND
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ABROSD(ID)=0.
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SUMDPL(ID)=0.
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END DO
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END IF
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C
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DO 500 IJ=1,NFREQ
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IF(IJX(IJ).EQ.-1) GO TO 500
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FR=FREQ(IJ)
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W0=W0E(IJ)
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WW=W(IJ)
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CALL OPACF1(IJ)
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CALL RTEFR1(IJ)
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IF(LROSS) CALL ROSSTD(IJ)
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FLUXW=W(IJ)*RAD1(1)*FH(IJ)
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GRADF(1,IJ)=FLUXW*ABSO1(1)/DENS(1)*PGRD
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FLRD(1)=FLRD(1)+WW*FH(IJ)*RAD1(1)-WW*HEXTRD(IJ)
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DO ID=2,ND
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DT=UN/(ABSOT(ID)+ABSOT(ID-1))/DELDMZ(ID-1)
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FL=(RAD1(ID)*FAK1(ID)-RAD1(ID-1)*FAK1(ID-1))*DT
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FLRD(ID)=FLRD(ID)+WW*FL
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END DO
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if(ioptab.lt.0) go to 500
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C
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C ---------------------
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C Continuum transitions
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C ---------------------
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C
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DO ID=1,ND
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EHK(ID)=EXP(-HKT1(ID)*FR)
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if(ilpsct.eq.0) then
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ALAB(ID)=ALI1(ID)/(ABSO1(ID)-ELSCAT(ID))
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else
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ALAB(ID)=ALI1(ID)/ABSO1(ID)
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end if
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DO 10 IBFT=1,NTRANC
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ITR=ITRBF(IBFT)
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SG=CROSS(IBFT,IJ)
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IF(SG.LE.0.) GO TO 10
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II=ILOW(ITR)
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JJ=IUP(ITR)
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IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 10
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JC=ITRA(JJ,II)
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IF(IFWOP(II).GE.0) THEN
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ICDW=MCDW(ITR)
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IF(ICDW.GE.1) SG=SG*DWF1(ICDW,ID)
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ELSE
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IMER=IMRG(II)
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SG=SGMG(IMER,ID)
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ENDIF
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SGW0=SG*W0
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RLAM=SG*ALAB(ID)
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ELIN=EMTRA(ITR,ID)*EHK(ID)
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RADRES=RAD1(ID)-RLAM*BNUE(IJ)*ELIN
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BNURES=BNUE(IJ)*(UN-RLAM*(ABTRA(ITR,ID)-ELIN))
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RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RADRES
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RRD(ITR,ID)=RRD(ITR,ID)+SGW0*(RADRES+BNURES)*EHK(ID)
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10 CONTINUE
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END DO
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C
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C ----------------
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C Line transitions
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C ----------------
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C
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IF(ISPODF.EQ.0) THEN
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IF(IJLIN(IJ).GT.0) THEN
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C
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C the "primary" line at the given frequency
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C
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ITR=IJLIN(IJ)
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II=ILOW(ITR)
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JJ=IUP(ITR)
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DO 50 ID=1,ND
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IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 50
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SG=PRFLIN(ID,IJ)
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SGW0=SG*W0
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RLAM=SG*ALAB(ID)
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ELIN=EMTRA(ITR,ID)*EHK(ID)
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RADRES=RAD1(ID)-RLAM*BNUE(IJ)*ELIN
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BNURES=BNUE(IJ)*(UN-RLAM*(ABTRA(ITR,ID)-ELIN))
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RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RADRES
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RRD(ITR,ID)=RRD(ITR,ID)+SGW0*(RADRES+BNURES)*EHK(ID)
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50 CONTINUE
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c
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itrprd=iprd(itr)
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if(itrprd.gt.0) then
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s=un/(0.02654*osc0(itr))
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do id=1,nd
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sg=prflin(id,ij)*s
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pjbar(itrprd,id)=pjbar(itrprd,id)+sg*w(ij)*rad1(id)
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end do
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end if
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c
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ENDIF
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IF(NLINES(IJ).LE.0) GO TO 100
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C
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C the "overlapping" lines at the given frequency
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C
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DO 90 ILINT=1,NLINES(IJ)
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ITR=ITRLIN(ILINT,IJ)
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if(linexp(itr)) go to 90
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IJ0=IFR0(ITR)
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DO IJT=IJ0,IFR1(ITR)
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IF(FREQ(IJT).LE.FR) THEN
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IJ0=IJT
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GO TO 70
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END IF
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END DO
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70 IJ1=IJ0-1
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A1=(FR-FREQ(IJ0))/(FREQ(IJ1)-FREQ(IJ0))
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A2=UN-A1
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II=ILOW(ITR)
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JJ=IUP(ITR)
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DO 80 ID=1,ND
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IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 80
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SG=A1*PRFLIN(ID,IJ1)+A2*PRFLIN(ID,IJ0)
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SGW0=SG*W0
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RLAM=SG*ALAB(ID)
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ELIN=EMTRA(ITR,ID)*EHK(ID)
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RADRES=RAD1(ID)-RLAM*BNUE(IJ)*ELIN
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BNURES=BNUE(IJ)*(UN-RLAM*(ABTRA(ITR,ID)-ELIN))
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RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RADRES
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RRD(ITR,ID)=RRD(ITR,ID)+SGW0*(RADRES+BNURES)*EHK(ID)
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80 CONTINUE
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c
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itrprd=iprd(itr)
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if(itrprd.gt.0) then
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s=un/(0.02654*osc0(itr))
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do id=1,nd
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SG=(A1*PRFLIN(ID,IJ1)+A2*PRFLIN(ID,IJ0))*s
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pjbar(itrprd,id)=pjbar(itrprd,id)+sg*w(ij)*rad1(id)
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end do
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end if
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c
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90 CONTINUE
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100 CONTINUE
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C
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C Opacity sampling option
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C
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ELSE
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IF(NLINES(IJ).LE.0) GO TO 200
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DO 190 ILINT=1,NLINES(IJ)
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ITR=ITRLIN(ILINT,IJ)
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KJ=IJ-IFR0(ITR)+KFR0(ITR)
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INDXPA=IABS(INDEXP(ITR))
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II=ILOW(ITR)
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JJ=IUP(ITR)
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IF(INDXPA.NE.3 .AND. INDXPA.NE.4) THEN
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DO 150 ID=1,ND
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IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 150
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SG=PRFLIN(ID,KJ)
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SGW0=SG*W0
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RLAM=SG*ALAB(ID)
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ELIN=EMTRA(ITR,ID)*EHK(ID)
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RADRES=RAD1(ID)-RLAM*BNUE(IJ)*ELIN
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BNURES=BNUE(IJ)*(UN-RLAM*(ABTRA(ITR,ID)-ELIN))
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RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RADRES
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RRD(ITR,ID)=RRD(ITR,ID)+SGW0*(RADRES+BNURES)*EHK(ID)
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150 CONTINUE
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ELSE
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DO 160 ID=1,ND
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IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 160
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KJD=JIDI(ID)
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SG=EXP(XJID(ID)*SIGFE(KJD,KJ)+
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* (UN-XJID(ID))*SIGFE(KJD+1,KJ))
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SGW0=SG*W0
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RLAM=SG*ALAB(ID)
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ELIN=EMTRA(ITR,ID)*EHK(ID)
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RADRES=RAD1(ID)-RLAM*BNUE(IJ)*ELIN
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BNURES=BNUE(IJ)*(UN-RLAM*(ABTRA(ITR,ID)-ELIN))
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RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RADRES
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RRD(ITR,ID)=RRD(ITR,ID)+SGW0*(RADRES+BNURES)*EHK(ID)
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160 CONTINUE
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END IF
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190 CONTINUE
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200 CONTINUE
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END IF
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500 CONTINUE
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C
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DO ID=1,ND
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IF(CRSW(ID).NE.UN) THEN
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DO ITR=1,NTRANS
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RRU(ITR,ID)=RRU(ITR,ID)*CRSW(ID)
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RRD(ITR,ID)=RRD(ITR,ID)*CRSW(ID)
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END DO
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END IF
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END DO
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C
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C radiation pressure
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C
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PRDX=1.
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DO ID=1,ND
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PRADT(ID)=PRADT(ID)*PCK
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PRADA(ID)=PRADA(ID)*PCK
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if(prada(id).gt.0.) PRDR=PRADT(ID)/PRADA(ID)
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IF(PRDR.LT.PRDX) PRDX=PRDR
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END DO
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PRD0=PRD0/DENS1(1)*DM(1)*PCK
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IF(LFIN) WRITE(10,1100) PRDX,ITER
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1100 FORMAT(' PRAD MIN RATIO ',F10.6,I4)
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C
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C Rosseland mean opacity
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C
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IF(LROSS) THEN
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DO ID=1,ND
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ABROSD(ID)=SUMDPL(ID)/(ABROSD(ID)*DENS(ID))
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END DO
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END IF
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RETURN
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END
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