SUBROUTINE ALISK2 C ================= C C Simplified routine ALISET for Kantorovich iteration C C Evaluation of all nexcessary ALI parameters + radiative rates C (the routine is analogous to RATES) C C INCLUDE 'IMPLIC.FOR' INCLUDE 'BASICS.FOR' INCLUDE 'ATOMIC.FOR' INCLUDE 'MODELQ.FOR' INCLUDE 'ODFPAR.FOR' INCLUDE 'ALIPAR.FOR' INCLUDE 'ARRAY1.FOR' INCLUDE 'ITERAT.FOR' DIMENSION RBNU(MDEPTH) C DIMENSION EHKL(MFREQL) C C zero the rates and other quantities C DO ID=1,ND FCOOLI(ID)=0. FLFIX(ID)=0. FLEXP(ID)=0. FPRD(ID)=0. FLRD(ID)=0. PRADT(ID)=0. PRADA(ID)=0. DO ITR=1,NTRANS RRU(ITR,ID)=0. RRD(ITR,ID)=0. END DO END DO PRD0=0. C LROSS=NDRE.LE.0.AND.ITER.EQ.1.OR.LFIN IF(HMIX0.GT.0.) LROSS=.TRUE. IF(LROSS) THEN DO ID=1,ND ABROSD(ID)=0. SUMDPL(ID)=0. END DO END IF C DO 100 IJ=1,NFREQ IF(IJX(IJ).EQ.-1) GO TO 100 FR=FREQ(IJ) W0=W0E(IJ) CALL OPACF1(IJ) CALL RTEFR1(IJ) CALL ALIFRK(IJ) IF(LROSS) CALL ROSSTD(IJ) if(ioptab.lt.0) go to 100 IF(IJEX(IJ).GT.0) THEN IJE=IJEX(IJ) DO ID=1,ND ABSOEX(IJE,ID)=ABSO1(ID) EMISEX(IJE,ID)=EMIS1(ID) SCATEX(IJE,ID)=SCAT1(ID) END DO END IF C C --------------------- C Continuum transitions C --------------------- C DO ID=1,ND RBNU(ID)=(RAD1(ID)+BNUE(IJ))*EXP(-HKT1(ID)*FR) DO 10 IBFT=1,NTRANC ITR=ITRBF(IBFT) SG=CROSS(IBFT,IJ) IF(SG.LE.0.) GO TO 10 II=ILOW(ITR) JJ=IUP(ITR) IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 10 JC=ITRA(JJ,II) IF(IFWOP(II).GE.0) THEN ICDW=MCDW(ITR) IF(ICDW.GE.1) SG=SG*DWF1(ICDW,ID) ELSE IMER=IMRG(II) SG=SGMG(IMER,ID) ENDIF SGW0=SG*W0 RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RAD1(ID) RRD(ITR,ID)=RRD(ITR,ID)+SGW0*RBNU(ID) 10 CONTINUE END DO C C ---------------- C Line transitions C ---------------- C IF(ISPODF.EQ.0) THEN IF(IJLIN(IJ).GT.0) THEN C C the "primary" line at the given frequency C ITR=IJLIN(IJ) II=ILOW(ITR) JJ=IUP(ITR) DO 50 ID=1,ND IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 50 SGW0=PRFLIN(ID,IJ)*W0 RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RAD1(ID) RRD(ITR,ID)=RRD(ITR,ID)+SGW0*RBNU(ID) 50 CONTINUE END IF IF(NLINES(IJ).LE.0) GO TO 100 C C the "overlapping" lines at the given frequency C DO 90 ILINT=1,NLINES(IJ) ITR=ITRLIN(ILINT,IJ) if(linexp(itr)) go to 90 II=ILOW(ITR) JJ=IUP(ITR) IJ0=IFR0(ITR) DO IJT=IJ0,IFR1(ITR) IF(FREQ(IJT).LE.FR) THEN IJ0=IJT GO TO 70 END IF END DO 70 IJ1=IJ0-1 A1=(FR-FREQ(IJ0))/(FREQ(IJ1)-FREQ(IJ0))*W0 A2=W0-A1 DO 80 ID=1,ND IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 80 SGW0=A1*PRFLIN(ID,IJ1)+A2*PRFLIN(ID,IJ0) RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RAD1(ID) RRD(ITR,ID)=RRD(ITR,ID)+SGW0*RBNU(ID) 80 CONTINUE 90 CONTINUE C C Opacity sampling option C ELSE IF(NLINES(IJ).LE.0) GO TO 100 DO 190 ILINT=1,NLINES(IJ) ITR=ITRLIN(ILINT,IJ) KJ=IJ-IFR0(ITR)+KFR0(ITR) INDXPA=IABS(INDEXP(ITR)) II=ILOW(ITR) JJ=IUP(ITR) IF(INDXPA.NE.3 .AND. INDXPA.NE.4) THEN DO 150 ID=1,ND IF(IPZERO(II,ID).NE.0.OR.IPZERO(JJ,ID).NE.0) GO TO 150 SGW0=PRFLIN(ID,KJ)*W0 RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RAD1(ID) RRD(ITR,ID)=RRD(ITR,ID)+SGW0*RBNU(ID) 150 CONTINUE ELSE DO 160 ID=1,ND IF(IPZERO(II,ID).NE.0.OR. * IPZERO(JJ,ID).NE.0) GO TO 160 KJD=JIDI(ID) SG=EXP(XJID(ID)*SIGFE(KJD,KJ)+(UN-XJID(ID))* * SIGFE(KJD+1,KJ)) SGW0=SG*W0 RRU(ITR,ID)=RRU(ITR,ID)+SGW0*RAD1(ID) RRD(ITR,ID)=RRD(ITR,ID)+SGW0*RBNU(ID) 160 CONTINUE END IF 190 CONTINUE END IF 100 CONTINUE C C multiply some quantities by frequency-independent constants C DO ID=1,ND FCO OL(ID)=REINT(ID)*FCOOLI(ID)-REDIF(ID)*FLFIX(ID) IF(CRSW(ID).NE.UN) THEN DO ITR=1,NTRANS RRU(ITR,ID)=RRU(ITR,ID)*CRSW(ID) RRD(ITR,ID)=RRD(ITR,ID)*CRSW(ID) END DO END IF END DO C C radiation pressure C PRDX=1. DO ID=1,ND PRADT(ID)=PRADT(ID)*PCK PRADA(ID)=PRADA(ID)*PCK if(prada(id).gt.0.) PRDR=PRADT(ID)/PRADA(ID) IF(PRDR.LT.PRDX) PRDX=PRDR END DO PRD0=PRD0/DENS1(1)*DM(1)*PCK IF(LFIN) WRITE(10,1100) PRDX,ITER 1100 FORMAT(' PRAD MIN RATIO ',F10.6,I4) C C Rosseland mean opacity C IF(LROSS) THEN DO ID=1,ND ABROSD(ID)=SUMDPL(ID)/(ABROSD(ID)*DENS(ID)) END DO END IF RETURN END