diff --git a/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/dwsph.f b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/dwsph.f new file mode 100644 index 0000000..6d48a79 --- /dev/null +++ b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/dwsph.f @@ -0,0 +1,85 @@ +C +C======================================================================= +C + SUBROUTINE DWSPH(JTYP,JE,X,TLT,ISPEED) +C +C This routine recomputes the T-matrix elements taking into account the +C mean square displacements. +C +C When the argument X is tiny, no vibrations are taken into account +C +C Last modified : 25 Apr 2013 +C + USE DIM_MOD +C + USE TRANS_MOD +C + DIMENSION GNT(0:N_GAUNT) +C + COMPLEX TLT(0:NT_M,4,NATM,NE_M),SL1,ZEROC +C + COMPLEX*16 FFL(0:2*NL_M) +C + DATA PI4,EPS /12.566371,1.0E-10/ +C + ZEROC=(0.,0.) +C + IF(X.GT.EPS) THEN +C +C Standard case: vibrations +C + IF(ISPEED.LT.0) THEN + NSUM_LB=ABS(ISPEED) + ENDIF +C + COEF=PI4*EXP(-X) + NL2=2*LMAX(JTYP,JE)+2 + IBESP=5 + MG1=0 + MG2=0 +C + CALL BESPHE(NL2,IBESP,X,FFL) +C + DO L=0,LMAX(JTYP,JE) + XL=FLOAT(L+L+1) + SL1=ZEROC +C + DO L1=0,LMAX(JTYP,JE) + XL1=FLOAT(L1+L1+1) + CALL GAUNT(L,MG1,L1,MG2,GNT) + L2MIN=ABS(L1-L) + IF(ISPEED.GE.0) THEN + L2MAX=L1+L + ELSEIF(ISPEED.LT.0) THEN + L2MAX=L2MIN+2*(NSUM_LB-1) + ENDIF + SL2=0. +C + DO L2=L2MIN,L2MAX,2 + XL2=FLOAT(L2+L2+1) + C=SQRT(XL1*XL2/(PI4*XL)) + SL2=SL2+C*GNT(L2)*REAL(DREAL(FFL(L2))) + ENDDO +C + SL1=SL1+SL2*TL(L1,1,JTYP,JE) + ENDDO +C + TLT(L,1,JTYP,JE)=COEF*SL1 +C + ENDDO +C + ELSE +C +C Argument X tiny: no vibrations +C + DO L=0,LMAX(JTYP,JE) +C + TLT(L,1,JTYP,JE)=TL(L,1,JTYP,JE) +C + ENDDO +C + ENDIF +C + RETURN +C + END diff --git a/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/facdif.f b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/facdif.f new file mode 100644 index 0000000..2ac7683 --- /dev/null +++ b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/facdif.f @@ -0,0 +1,26 @@ +C +C======================================================================= +C + SUBROUTINE FACDIF(COSTH,JAT,JE,FTHETA) +C +C This routine computes the plane wave scattering factor +C + USE DIM_MOD +C + USE TRANS_MOD +C + DIMENSION PL(0:100) +C + COMPLEX FTHETA +C + FTHETA=(0.,0.) + NL=LMAX(JAT,JE)+1 + CALL POLLEG(NL,COSTH,PL) + DO 20 L=0,NL-1 + FTHETA=FTHETA+(2*L+1)*TL(L,1,JAT,JE)*PL(L) + 20 CONTINUE + FTHETA=FTHETA/VK(JE) +C + RETURN +C + END diff --git a/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/facdif1.f b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/facdif1.f new file mode 100644 index 0000000..62ac3f8 --- /dev/null +++ b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/facdif1.f @@ -0,0 +1,113 @@ +C +C======================================================================= +C + SUBROUTINE FACDIF1(VKE,RJ,RJK,THRJ,PHIRJ,BETA,GAMMA,L,M,FSPH,JAT,J + &E,*) +C +C This routine computes a spherical wave scattering factor +C +C Last modified : 03/04/2006 +C + USE DIM_MOD + USE APPROX_MOD + USE EXPFAC_MOD + USE TRANS_MOD + USE TYPCAL_MOD , I2 => IPHI, I3 => IE, I4 => ITHETA, I5 => IMOD, I + &6 => IPOL, I7 => I_CP, I8 => I_EXT, I9 => I_TEST +C + DIMENSION PLMM(0:100,0:100) + DIMENSION D(1-NL_M:NL_M-1,1-NL_M:NL_M-1,0:NL_M-1) +C + COMPLEX HLM(0:NO_ST_M,0:NL_M-1),HLN(0:NO_ST_M,0:NL_M-1),FSPH,RHOJ + COMPLEX HLM1,HLM2,HLM3,HLM4,ALMU,BLMU,SLP,SNU,SMU,VKE + COMPLEX RHOJK +C +C + DATA PI/3.141593/ +C + A=1. + INTER=0 + IF(ITL.EQ.1) VKE=VK(JE) + RHOJ=VKE*RJ + RHOJK=VKE*RJK + HLM1=(1.,0.) + HLM2=(1.,0.) + HLM3=(1.,0.) + HLM4=(1.,0.) + IEM=1 + CSTH=COS(BETA) + IF((IFTHET.EQ.0).OR.(THRJ.LT.0.0001)) THEN + INTER=1 + BLMU=SQRT(4.*PI/FLOAT(2*L+1))*CEXP((0.,-1.)*M*(PHIRJ-PI)) + ENDIF + CALL PLM(CSTH,PLMM,LMAX(JAT,JE)) + IF(ISPHER.EQ.0) NO1=0 + IF(ISPHER.EQ.1) THEN + IF(NO.EQ.8) THEN + NO1=LMAX(JAT,JE)+1 + ELSE + NO1=NO + ENDIF + CALL POLHAN(ISPHER,NO1,LMAX(JAT,JE),RHOJ,HLM) + IF(IEM.EQ.0) THEN + HLM4=HLM(0,L) + ENDIF + IF(RJK.GT.0.0001) THEN + NDUM=0 + CALL POLHAN(ISPHER,NDUM,LMAX(JAT,JE),RHOJK,HLN) + ENDIF + CALL DJMN(THRJ,D,L) + A1=ABS(D(0,M,L)) + IF(((A1.LT.0.0001).AND.(IFTHET.EQ.1)).AND.(INTER.EQ.0)) RETURN 1 + & + ENDIF + MUMAX=MIN0(L,NO1) + SMU=(0.,0.) + DO 10 MU=0,MUMAX + IF(MOD(MU,2).EQ.0) THEN + B=1. + ELSE + B=-1. + IF(SIN(BETA).LT.0.) THEN + A=-1. + ENDIF + ENDIF + IF(ISPHER.LE.1) THEN + ALMU=(1.,0.) + C=1. + ENDIF + IF(ISPHER.EQ.0) GOTO 40 + IF(INTER.EQ.0) BLMU=CMPLX(D(M,0,L)) + IF(MU.GT.0) THEN + C=B*FLOAT(L+L+1)/EXPF(MU,L) + ALMU=(D(M,MU,L)*CEXP((0.,-1.)*MU*GAMMA)+B* + * CEXP((0.,1.)*MU*GAMMA)*D(M,-MU,L))/BLMU + ELSE + C=1. + ALMU=CMPLX(D(M,0,L))/BLMU + ENDIF + 40 SNU=(0.,0.) + NU1=INT(0.5*(NO1-MU)+0.0001) + NUMAX=MIN0(NU1,L-MU) + DO 20 NU=0,NUMAX + SLP=(0.,0.) + LPMIN=MAX0(MU,NU) + DO 30 LP=LPMIN,LMAX(JAT,JE) + IF(ISPHER.EQ.1) THEN + HLM1=HLM(NU,LP) + IF(RJK.GT.0.0001) HLM3=HLN(0,LP) + ENDIF + SLP=SLP+FLOAT(2*LP+1)*TL(LP,1,JAT,JE)*HLM1*PLMM(LP,MU)*HLM3 + 30 CONTINUE + IF(ISPHER.EQ.1) THEN + HLM2=HLM(MU+NU,L) + ENDIF + SNU=SNU+SLP*HLM2 + 20 CONTINUE + SMU=SMU+SNU*C*ALMU*A*B + 10 CONTINUE + FSPH=SMU/(VKE*HLM4) +C + RETURN +C + END diff --git a/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/plotfd.f b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/plotfd.f new file mode 100644 index 0000000..bc73cf4 --- /dev/null +++ b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/plotfd.f @@ -0,0 +1,106 @@ +C +C======================================================================= +C + SUBROUTINE PLOTFD(A,LMX,ITL,NL,NAT,NE) +C +C This routine prepares the output for a plot of the scattering factor +C + USE DIM_MOD +C + USE APPROX_MOD + USE FDIF_MOD + USE INIT_L_MOD , L => LI, I2 => INITL, I3 => NNL, I4 => LF1, I5 => + & LF2, I10 => ISTEP_LF + USE INIT_J_MOD + USE OUTFILES_MOD + USE OUTUNITS_MOD + USE PARCAL_MOD , N3 => NPHI, N4 => NE, N5 => NTHETA, N6 => NEPS + USE TYPCAL_MOD , I7 => IFTHET, I8 => IMOD, I9 => IPOL, I12 => I_CP + &, I13 => I_EXT, I14 => I_TEST + USE VALIN_MOD , U1 => THLUM, U2 => PHILUM, U3 => ELUM, N7 => NONVO + &L + USE VALFIN_MOD +C +C +C + DIMENSION LMX(NATM,NE_M) +C + COMPLEX FSPH,VKE +C +C +C + DATA PI,CONV/3.141593,0.512314/ +C + OPEN(UNIT=IUO3, FILE=OUTFILE3, STATUS='UNKNOWN') + IF(ISPHER.EQ.0) THEN + L=0 + LMAX=0 + ELSE + LMAX=L + ENDIF + PHITOT=360. + THTOT=360.*ITHETA*(1-IPHI)+180.*ITHETA*IPHI + NPHI=(NFTHET+1)*IPHI+(1-IPHI) + NTHT=(NFTHET+1)*ITHETA*(1-IPHI)+(NFTHET/2+1)*ITHETA*IPHI+ + * (1-ITHETA) + NE=NFTHET*IE + (1-IE) + WRITE(IUO3,1) ISPHER,NL,NAT,L,NTHT,NPHI,NE,E0,EFIN + DO 10 JT=1,NTHT + DTHETA=THETA1+FLOAT(JT-1)*THTOT/FLOAT(MAX0(NTHT-1,1)) + RTHETA=DTHETA*PI/180. + TEST=SIN(RTHETA) + IF(TEST.GE.0.) THEN + POZ=PI + EPS=1. + ELSE + POZ=0. + EPS=-1. + ENDIF + BETA=RTHETA*EPS + IF(ABS(TEST).LT.0.0001) THEN + NPHIM=1 + ELSE + NPHIM=NPHI + ENDIF + DO 20 JP=1,NPHIM + DPHI=PHI1+FLOAT(JP-1)*PHITOT/FLOAT(MAX0(NPHI-1,1)) + RPHI=DPHI*PI/180. + GAMMA=POZ-RPHI + DO 30 JE=1,NE + IF(NE.EQ.1) THEN + ECIN=E0 + ELSE + ECIN=E0+FLOAT(JE-1)*(EFIN-E0)/FLOAT(NE-1) + ENDIF + IF(ITL.EQ.0) VKE=SQRT(ECIN-ABS(VINT))*CONV*A*(1.,0.) + DO 40 JAT=1,NAT + IF(L.GT.LMX(JAT,JE)) GOTO 90 + DO 50 M=-LMAX,LMAX + CALL FACDIF1(VKE,R1,R2,THETA0,PHI0,BETA,GAMMA,L,M,FSPH,J + &AT,JE,*60) + GOTO 70 + 60 WRITE(IUO1,80) + STOP + 70 REFTH=REAL(FSPH) + XIMFTH=AIMAG(FSPH) + WRITE(IUO3,5) JE,JAT,L,M,REFTH,XIMFTH,DTHETA,DPHI,ECIN + 50 CONTINUE + GOTO 40 + 90 WRITE(IUO1,100) JAT + STOP + 40 CONTINUE + 30 CONTINUE + 20 CONTINUE + 10 CONTINUE + CLOSE(IUO3) + 1 FORMAT(5X,I1,2X,I2,2X,I4,2X,I2,2X,I3,2X,I3,2X,I3,2X,F8.2,2X,F8.2) + 5 FORMAT(1X,I3,1X,I4,1X,I2,1X,I3,1X,F6.3,1X,F6.3,1X,F6.2,1X,F6.2,1X, + &F8.2) + 80 FORMAT(15X,'<<<<< WRONG VALUE OF THETA0 : THE DENOMINATOR ','IS Z + &ERO >>>>>') + 100 FORMAT(15X,'<<<<< THE VALUE OF L EST IS TOO LARGE FOR ATOM',' : ' + &,I2,' >>>>>') +C + RETURN +C + END diff --git a/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/weight_sum.f b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/weight_sum.f new file mode 100644 index 0000000..0db9ffc --- /dev/null +++ b/src/msspec/spec/fortran/phd_ce_noso_nosp_nosym/weight_sum.f @@ -0,0 +1,335 @@ +C +C======================================================================= +C + SUBROUTINE WEIGHT_SUM(ISOM,I_EXT,I_EXT_A,JEL) +C +C This subroutine performs a weighted sum of the results +C corresponding to different directions of the detector. +C The directions and weights are read from an external input file +C +C JEL is the electron undetected (i.e. for which the outgoing +C directions are integrated over the unit sphere). It is always +C 1 for one electron spectroscopies (PHD). For APECS, It can be +C 1 (photoelectron) or 2 (Auger electron) or even 0 (no electron +C detected) +C +C Last modified : 31 Jan 2007 +C + USE DIM_MOD + USE INFILES_MOD + USE INUNITS_MOD + USE OUTUNITS_MOD +C +C + PARAMETER(N_MAX=5810,NPM=20) +C + REAL*4 W(N_MAX),W_A(N_MAX),ECIN(NE_M) + REAL*4 DTHETA(N_MAX),DPHI(N_MAX),DTHETAA(N_MAX),DPHIA(N_MAX) + REAL*4 SR_1,SF_1,SR_2,SF_2 + REAL*4 SUMR_1(NPM,NE_M,N_MAX),SUMR_2(NPM,NE_M,N_MAX) + REAL*4 SUMF_1(NPM,NE_M,N_MAX),SUMF_2(NPM,NE_M,N_MAX) +C + CHARACTER*3 SPECTRO,SPECTRO2 + CHARACTER*5 LIKE + CHARACTER*13 OUTDATA +C +C +C +C + DATA JVOL,JTOT/0,-1/ + DATA LIKE /'-like'/ +C + REWIND IUO2 +C + READ(IUO2,15) SPECTRO,OUTDATA + IF(SPECTRO.NE.'APC') THEN + READ(IUO2,9) ISPIN,IDICHR,I_SO,ISFLIP,ICHKDIR,IPHI,ITHETA,IE + READ(IUO2,8) NPHI,NTHETA,NE,NPLAN,ISOM + SPECTRO2='XAS' + ELSE + READ(IUO2,9) ISPIN,IDICHR,I_SO,ISFLIP,ICHKDIR,IPHI,ITHETA,IE + READ(IUO2,9) ISPIN_A,IDICHR_A,I_SO_A,ISFLIP_A,ICHKDIR_A,IPHI_A,I + &THETA_A,IE_A + READ(IUO2,8) NPHI,NTHETA,NE,NPLAN,ISOM + READ(IUO2,8) NPHI_A,NTHETA_A + IF(JEL.EQ.1) THEN + SPECTRO2='AED' + ELSEIF(JEL.EQ.2) THEN + SPECTRO2='PHD' + ELSEIF(JEL.EQ.0) THEN + SPECTRO2='XAS' + ENDIF + ENDIF +C + IF(NPLAN.GT.NPM) THEN + WRITE(IUO1,4) NPLAN+2 + STOP + ENDIF +C +C Reading the number of angular points +C + IF(SPECTRO.NE.'APC') THEN + OPEN(UNIT=IUI6, FILE=INFILE6, STATUS='OLD') + READ(IUI6,1) N_POINTS + READ(IUI6,5) I_DIM,N_DUM1,N_DUM2 + N_POINTS_A=1 + ELSE + IF(JEL.EQ.1) THEN + OPEN(UNIT=IUI6, FILE=INFILE6, STATUS='OLD') + READ(IUI6,1) N_POINTS + READ(IUI6,5) I_DIM,N_DUM1,N_DUM2 + IF(I_EXT_A.EQ.0) THEN + N_POINTS_A=NTHETA_A*NPHI_A + ELSE + OPEN(UNIT=IUI9, FILE=INFILE9, STATUS='OLD') + READ(IUI9,1) N_POINTS_A + READ(IUI9,5) I_DIM,N_DUM1,N_DUM2 + ENDIF + NTHETA0=NTHETA_A + NPHI0=NPHI_A + ELSEIF(JEL.EQ.2) THEN + OPEN(UNIT=IUI9, FILE=INFILE9, STATUS='OLD') + READ(IUI9,1) N_POINTS_A + READ(IUI9,5) I_DIM,N_DUM1,N_DUM2 + IF(I_EXT.EQ.0) THEN + N_POINTS=NTHETA*NPHI + ELSE + OPEN(UNIT=IUI6, FILE=INFILE6, STATUS='OLD') + READ(IUI6,1) N_POINTS + READ(IUI6,5) I_DIM,N_DUM1,N_DUM2 + ENDIF + NTHETA0=NTHETA + NPHI0=NPHI + ELSEIF(JEL.EQ.0) THEN + OPEN(UNIT=IUI6, FILE=INFILE6, STATUS='OLD') + OPEN(UNIT=IUI9, FILE=INFILE9, STATUS='OLD') + READ(IUI6,1) N_POINTS + READ(IUI9,1) N_POINTS_A + READ(IUI6,5) I_DIM,N_DUM1,N_DUM2 + READ(IUI9,5) I_DIM,N_DUM1,N_DUM2 + ENDIF + ENDIF +C + IF(SPECTRO.NE.'APC') THEN + NANGLE=1 + ELSE + IF(JEL.EQ.1) THEN + NANGLE=N_POINTS_A + ELSEIF(JEL.EQ.2) THEN + NANGLE=N_POINTS + ELSEIF(JEL.EQ.0) THEN + NANGLE=1 + ENDIF + ENDIF +C +C Initialization of the arrays +C + DO JE=1,NE + DO JANGLE=1,NANGLE + DO JPLAN=1,NPLAN+2 + SUMR_1(JPLAN,JE,JANGLE)=0. + SUMF_1(JPLAN,JE,JANGLE)=0. + IF(IDICHR.GT.0) THEN + SUMR_2(JPLAN,JE,JANGLE)=0. + SUMF_2(JPLAN,JE,JANGLE)=0. + ENDIF + ENDDO + ENDDO + ENDDO +C +C Reading of the data to be angle integrated +C + DO JE=1,NE +C + DO JANGLE=1,N_POINTS + IF(I_EXT.NE.0) READ(IUI6,2) TH,PH,W(JANGLE) + DO JANGLE_A=1,N_POINTS_A + IF((I_EXT_A.NE.0).AND.(JANGLE.EQ.1)) THEN + READ(IUI9,2) THA,PHA,W_A(JANGLE_A) + ENDIF +C + DO JPLAN=1,NPLAN+2 +C + IF(IDICHR.EQ.0) THEN + IF(SPECTRO.NE.'APC') THEN + READ(IUO2,3) JDUM,DTHETA(JANGLE),DPHI(JANGLE),ECIN(JE) + &,SR_1,SF_1 + ELSE + READ(IUO2,13) JDUM,DTHETA(JANGLE),DPHI(JANGLE),ECIN(JE + &),DTHETAA(JANGLE_A),DPHIA(JANGLE_A),SR_1,SF_1 + ENDIF + ELSE + IF(SPECTRO.NE.'APC') THEN + READ(IUO2,23) JDUM,DTHETA(JANGLE),DPHI(JANGLE),ECIN(JE + &),SR_1,SF_1,SR_2,SF_2 + ELSE + READ(IUO2,24) JDUM,DTHETA(JANGLE),DPHI(JANGLE),ECIN(JE + &),DTHETAA(JANGLE_A),DPHIA(JANGLE_A),SR_1,SF_1,SR_2,SF_2 + ENDIF + ENDIF +C + IF(JEL.EQ.1) THEN + SUMR_1(JPLAN,JE,JANGLE_A)=SUMR_1(JPLAN,JE,JANGLE_A)+SR_1 + &*W(JANGLE) + SUMF_1(JPLAN,JE,JANGLE_A)=SUMF_1(JPLAN,JE,JANGLE_A)+SF_1 + &*W(JANGLE) + ELSEIF(JEL.EQ.2) THEN + SUMR_1(JPLAN,JE,JANGLE)=SUMR_1(JPLAN,JE,JANGLE)+SR_1*W_A + &(JANGLE_A) + SUMF_1(JPLAN,JE,JANGLE)=SUMF_1(JPLAN,JE,JANGLE)+SF_1*W_A + &(JANGLE_A) + ELSEIF(JEL.EQ.0) THEN + SUMR_1(JPLAN,JE,1)=SUMR_1(JPLAN,JE,1)+SR_1*W(JANGLE)*W_A + &(JANGLE_A) + SUMF_1(JPLAN,JE,1)=SUMF_1(JPLAN,JE,1)+SF_1*W(JANGLE)*W_A + &(JANGLE_A) + ENDIF + IF(IDICHR.GT.0) THEN + IF(JEL.EQ.1) THEN + SUMR_2(JPLAN,JE,JANGLE_A)=SUMR_2(JPLAN,JE,JANGLE_A)+SR + &_2*W(JANGLE) + SUMF_2(JPLAN,JE,JANGLE_A)=SUMF_2(JPLAN,JE,JANGLE_A)+SF + &_2*W(JANGLE) + ELSEIF(JEL.EQ.2) THEN + SUMR_2(JPLAN,JE,JANGLE)=SUMR_2(JPLAN,JE,JANGLE)+SR_2*W + &_A(JANGLE_A) + SUMF_2(JPLAN,JE,JANGLE)=SUMF_2(JPLAN,JE,JANGLE)+SF_2*W + &_A(JANGLE_A) + ELSEIF(JEL.EQ.0) THEN + SUMR_2(JPLAN,JE,1)=SUMR_2(JPLAN,JE,1)+SR_2*W(JANGLE)*W + &_A(JANGLE_A) + SUMF_2(JPLAN,JE,1)=SUMF_2(JPLAN,JE,1)+SF_2*W(JANGLE)*W + &_A(JANGLE_A) + ENDIF + ENDIF +C + ENDDO +C + ENDDO + IF(I_EXT_A.NE.0) THEN + REWIND IUI9 + READ(IUI9,1) NDUM + READ(IUI9,1) NDUM + ENDIF + ENDDO +C + IF(I_EXT.NE.0) THEN + REWIND IUI6 + READ(IUI6,1) NDUM + READ(IUI6,1) NDUM + ENDIF + ENDDO +C + CLOSE(IUI6) + CLOSE(IUI9) + REWIND IUO2 +C + WRITE(IUO2,16) SPECTRO2,LIKE,SPECTRO,OUTDATA + IF((SPECTRO.NE.'APC').OR.(JEL.EQ.0)) THEN + WRITE(IUO2,19) ISPIN,IDICHR,I_SO,ISFLIP + WRITE(IUO2,18) NE,NPLAN,ISOM + ELSEIF(JEL.EQ.1) THEN + WRITE(IUO2,20) ISPIN_A,IDICHR_A,I_SO_A,ISFLIP_A,ICHKDIR_A,IPHI_A + &,ITHETA_A,IE_A + WRITE(IUO2,21) NPHI0,NTHETA0,NE,NPLAN,ISOM + ELSEIF(JEL.EQ.2) THEN + WRITE(IUO2,20) ISPIN,IDICHR,I_SO,ISFLIP,ICHKDIR,IPHI,ITHETA,IE + WRITE(IUO2,21) NPHI0,NTHETA0,NE,NPLAN,ISOM + ENDIF +C + DO JE=1,NE + DO JANGLE=1,NANGLE + IF(SPECTRO.EQ.'APC') THEN + IF(JEL.EQ.1) THEN + THETA=DTHETAA(JANGLE) + PHI=DPHIA(JANGLE) + ELSEIF(JEL.EQ.2) THEN + THETA=DTHETA(JANGLE) + PHI=DPHI(JANGLE) + ENDIF + ENDIF +C + DO JPLAN=1,NPLAN + IF(IDICHR.EQ.0) THEN + IF((SPECTRO.NE.'APC').OR.(JEL.EQ.0)) THEN + WRITE(IUO2,33) JPLAN,ECIN(JE),SUMR_1(JPLAN,JE,JANGLE),SU + &MF_1(JPLAN,JE,JANGLE) + ELSE + WRITE(IUO2,34) JPLAN,THETA,PHI,ECIN(JE),SUMR_1(JPLAN,JE, + &JANGLE),SUMF_1(JPLAN,JE,JANGLE) + ENDIF + ELSE + IF((SPECTRO.NE.'APC').OR.(JEL.EQ.0)) THEN + WRITE(IUO2,43) JPLAN,ECIN(JE),SUMR_1(JPLAN,JE,JANGLE),SU + &MF_1(JPLAN,JE,JANGLE),SUMR_2(JPLAN,JE,JANGLE),SUMF_2(JPLAN,JE,JANG + &LE) + ELSE + WRITE(IUO2,44) JPLAN,THETA,PHI,ECIN(JE),SUMR_1(JPLAN,JE, + &JANGLE),SUMF_1(JPLAN,JE,JANGLE),SUMR_2(JPLAN,JE,JANGLE),SUMF_2(JPL + &AN,JE,JANGLE) + ENDIF + ENDIF + ENDDO +C + IF(IDICHR.EQ.0) THEN + IF((SPECTRO.NE.'APC').OR.(JEL.EQ.0)) THEN + WRITE(IUO2,33) JVOL,ECIN(JE),SUMR_1(NPLAN+1,JE,JANGLE),SUM + &F_1(NPLAN+1,JE,JANGLE) + WRITE(IUO2,33) JTOT,ECIN(JE),SUMR_1(NPLAN+2,JE,JANGLE),SUM + &F_1(NPLAN+2,JE,JANGLE) + ELSE + WRITE(IUO2,34) JVOL,THETA,PHI,ECIN(JE),SUMR_1(NPLAN+1,JE,J + &ANGLE),SUMF_1(NPLAN+1,JE,JANGLE) + WRITE(IUO2,34) JTOT,THETA,PHI,ECIN(JE),SUMR_1(NPLAN+2,JE,J + &ANGLE),SUMF_1(NPLAN+2,JE,JANGLE) + ENDIF + ELSE + IF((SPECTRO.NE.'APC').OR.(JEL.EQ.0)) THEN + WRITE(IUO2,43) JVOL,ECIN(JE),SUMR_1(NPLAN+1,JE,JANGLE),SUM + &F_1(NPLAN+1,JE,JANGLE),SUMR_2(NPLAN+1,JE,JANGLE),SUMF_2(NPLAN+1,JE + &,JANGLE) + WRITE(IUO2,43) JTOT,ECIN(JE),SUMR_1(NPLAN+2,JE,JANGLE),SUM + &F_1(NPLAN+2,JE,JANGLE),SUMR_2(NPLAN+2,JE,JANGLE),SUMF_2(NPLAN+2,JE + &,JANGLE) + ELSE + WRITE(IUO2,44) JVOL,THETA,PHI,ECIN(JE),SUMR_1(NPLAN+1,JE,J + &ANGLE),SUMF_1(NPLAN+1,JE,JANGLE),SUMR_2(NPLAN+1,JE,JANGLE),SUMF_2( + &NPLAN+1,JE,JANGLE) + WRITE(IUO2,44) JTOT,THETA,PHI,ECIN(JE),SUMR_1(NPLAN+2,JE,J + &ANGLE),SUMF_1(NPLAN+2,JE,JANGLE),SUMR_2(NPLAN+2,JE,JANGLE),SUMF_2( + &NPLAN+2,JE,JANGLE) + ENDIF + ENDIF +C + ENDDO + ENDDO +C + 1 FORMAT(13X,I4) + 2 FORMAT(15X,F8.3,3X,F8.3,3X,E12.6) + 3 FORMAT(2X,I3,2X,F6.2,2X,F6.2,2X,F8.2,2X,E12.6,2X,E12.6) + 4 FORMAT(//,8X,'<<<<<<<<<< DIMENSION OF THE ARRAYS TOO SMALL ','IN + &THE WEIGHT_SUM SUBROUTINE - INCREASE NPM TO ',I3,'>>>>>>>>>>') + 5 FORMAT(6X,I1,1X,I3,3X,I3) + 8 FORMAT(I4,2X,I4,2X,I4,2X,I3,2X,I1) + 9 FORMAT(9(2X,I1),2X,I2) + 13 FORMAT(2X,I3,2X,F6.2,2X,F6.2,2X,F8.2,2X,F6.2,2X,F6.2,2X,E12.6,2X,E + &12.6) + 15 FORMAT(2X,A3,11X,A13) + 16 FORMAT(2X,A3,A5,1X,A3,2X,A13) + 18 FORMAT(I4,2X,I3,2X,I1) + 19 FORMAT(4(2X,I1)) + 20 FORMAT(8(2X,I1)) + 21 FORMAT(I4,2X,I4,2X,I4,2X,I3,2X,I1) + 23 FORMAT(2X,I3,2X,F6.2,2X,F6.2,2X,F8.2,2X,E12.6,2X,E12.6,2X,E12.6,2X + &,E12.6) + 24 FORMAT(2X,I3,2X,F6.2,2X,F6.2,2X,F8.2,2X,F6.2,2X,F6.2,2X,E12.6,2X,E + &12.6,2X,E12.6,2X,E12.6) + 33 FORMAT(2X,I3,2X,F8.2,2X,E12.6,2X,E12.6) + 34 FORMAT(2X,I3,2X,F6.2,2X,F6.2,2X,F8.2,2X,E12.6,2X,E12.6) + 43 FORMAT(2X,I3,2X,F8.2,2X,E12.6,2X,E12.6,2X,E12.6,2X,E12.6) + 44 FORMAT(2X,I3,2X,F6.2,2X,F6.2,2X,F8.2,2X,E12.6,2X,E12.6,2X,E12.6,2X + &,E12.6) +C + RETURN +C + END