PROGRAM MAIN C----------------------------------------------------------------------- C MAIN PROGRAM C C SIMULATION OF EXTENSIVE AIR SHOWERS C PREPARES INITIALIZATIONS C GENERATES SHOWERS IN THE SHOWER LOOP C TREATES PARTICLES IN THE PARTICLE LOOP C PERFORMS PRINTING OF TABLES AT END OF SHOWER AND AT END OF RUN C----------------------------------------------------------------------- IMPLICIT DOUBLE PRECISION (A-H,O-Z) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> parameter (xct=1) parameter (yct=2) parameter (zct=3) parameter (ctthet=4) parameter (ctphi=5) parameter (ctdiam=6) parameter (ctfoc=7) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> *KEEP,BAL. COMMON /BAL/ EBAL DOUBLE PRECISION EBAL(10) *KEEP,BUFFS. COMMON /BUFFS/ RUNH,RUNE,EVTH,EVTE,DATAB,LH INTEGER MAXBUF,MAXLEN PARAMETER (MAXBUF=39*7) PARAMETER (MAXLEN=12) REAL RUNH(MAXBUF),EVTH(MAXBUF),EVTE(MAXBUF), * RUNE(MAXBUF),DATAB(MAXBUF) INTEGER LH CHARACTER*4 CRUNH,CRUNE,CEVTH,CEVTE EQUIVALENCE (RUNH(1),CRUNH), (RUNE(1),CRUNE) EQUIVALENCE (EVTH(1),CEVTH), (EVTE(1),CEVTE) *KEEP,CHISTA. COMMON /CHISTA/ IHYCHI,IKACHI,IMUCHI,INNCHI,INUCHI,IPICHI INTEGER IHYCHI(124),IKACHI(124),IMUCHI(124), * INNCHI(124),INUCHI(124),IPICHI(124) *KEEP,CONST. COMMON /CONST/ PI,PI2,OB3,TB3,ENEPER DOUBLE PRECISION PI,PI2,OB3,TB3,ENEPER *KEEP,CURVE. COMMON /CURVE/ CHAPAR,DEP,ERR,NSTP DOUBLE PRECISION CHAPAR(1100),DEP(1100),ERR(1100) INTEGER NSTP *KEEP,ELADPM. COMMON /ELADPM/ ELMEAN,ELMEAA,IELDPM,IELDPA DOUBLE PRECISION ELMEAN(37),ELMEAA(37) INTEGER IELDPM(37,13),IELDPA(37,13) *KEEP,ELASTY. COMMON /ELASTY/ ELAST,IELIS,IELHM,IELNU,IELPI DOUBLE PRECISION ELAST INTEGER IELIS(20),IELHM(20),IELNU(20),IELPI(20) *KEEP,GENER. COMMON /GENER/ GEN,ALEVEL DOUBLE PRECISION GEN,ALEVEL *KEEP,IRET. COMMON /IRET/ IRET1,IRET2 INTEGER IRET1,IRET2 *KEEP,ISTA. COMMON /ISTA/ IFINET,IFINNU,IFINKA,IFINPI,IFINHY INTEGER IFINET,IFINNU,IFINKA,IFINPI,IFINHY *KEEP,LONGI. COMMON /LONGI/ APLONG,HLONG,PLONG,SPLONG,THSTEP,THSTPI, * NSTEP,LLONGI,FLGFIT DOUBLE PRECISION APLONG(0:1040,9),HLONG(0:1024),PLONG(0:1040,9), * SPLONG(0:1040,9),THSTEP,THSTPI INTEGER NSTEP LOGICAL LLONGI,FLGFIT *KEEP,MPARTI. COMMON /MPARTI/ MPARTO DOUBLE PRECISION MPARTO(10,25),MPHOTO(10),MPOSIT(10),MELECT(10), * MNU(10),MMUP(10),MMUM(10),MPI0(10),MPIP(10), * MPIM(10),MK0L(10),MKPL(10),MKMI(10),MNEUTR(10), * MPROTO(10),MPROTB(10),MK0S(10),MHYP(10), * MNEUTB(10),MDEUT(10),MTRIT(10),MALPHA(10), * MOTHER(10) EQUIVALENCE (MPARTO(1, 1),MPHOTO(1)), (MPARTO(1, 2),MPOSIT(1)), * (MPARTO(1, 3),MELECT(1)), (MPARTO(1, 4),MNU(1)) , * (MPARTO(1, 5),MMUP(1)) , (MPARTO(1, 6),MMUM(1)) , * (MPARTO(1, 7),MPI0(1)) , (MPARTO(1, 8),MPIP(1)) , * (MPARTO(1, 9),MPIM(1)) , (MPARTO(1,10),MK0L(1)) , * (MPARTO(1,11),MKPL(1)) , (MPARTO(1,12),MKMI(1)) , * (MPARTO(1,13),MNEUTR(1)), (MPARTO(1,14),MPROTO(1)), * (MPARTO(1,15),MPROTB(1)), (MPARTO(1,16),MK0S(1)) , * (MPARTO(1,18),MHYP(1)) , (MPARTO(1,19),MDEUT(1)) , * (MPARTO(1,20),MTRIT(1)) , (MPARTO(1,21),MALPHA(1)), * (MPARTO(1,22),MOTHER(1)), (MPARTO(1,25),MNEUTB(1)) *KEEP,MULT. COMMON /MULT/ EKINL,MSMM,MULTMA,MULTOT DOUBLE PRECISION EKINL INTEGER MSMM,MULTMA(37,13),MULTOT(37,13) *KEEP,MUPART. COMMON /MUPART/ AMUPAR,BCUT,CMUON,FMUBRM,FMUORG DOUBLE PRECISION AMUPAR(14),BCUT,CMUON(11) LOGICAL FMUBRM,FMUORG *KEEP,NCOUNT. COMMON /NCOUNT/ NCOUN INTEGER NCOUN(8) *KEEP,NKGI. COMMON /NKGI/ SEL,SELLG,STH,ZEL,ZELLG,ZSL,DIST, * DISX,DISY,DISXY,DISYX,DLAX,DLAY,DLAXY,DLAYX, * OBSATI,RADNKG,RMOL,TLEV,TLEVCM,IALT DOUBLE PRECISION SEL(10),SELLG(10),STH(10),ZEL(10),ZELLG(10), * ZSL(10),DIST(10), * DISX(-10:10),DISY(-10:10), * DISXY(-10:10,2),DISYX(-10:10,2), * DLAX (-10:10,2),DLAY (-10:10,2), * DLAXY(-10:10,2),DLAYX(-10:10,2), * OBSATI(2),RADNKG,RMOL(2),TLEV(10),TLEVCM(10) INTEGER IALT(2) *KEEP,NKGS. COMMON /NKGS/ CZX,CZY,CZXY,CZYX,SAH,SL,ZNE DOUBLE PRECISION CZX(-10:10,2),CZY(-10:10,2),CZXY(-10:10,2), * CZYX(-10:10,2),SAH(10),SL(10),ZNE(10) *KEEP,NPARTI. COMMON /NPARTI/ NPARTO,MUOND DOUBLE PRECISION NPARTO(10,25),NPHOTO(10),NPOSIT(10),NELECT(10), * NNU(10),NMUP(10),NMUM(10),NPI0(10),NPIP(10), * NPIM(10),NK0L(10),NKPL(10),NKMI(10),NNEUTR(10), * NPROTO(10),NPROTB(10),NK0S(10),NHYP(10), * NNEUTB(10),NDEUT(10),NTRIT(10),NALPHA(10), * NOTHER(10),MUOND EQUIVALENCE (NPARTO(1, 1),NPHOTO(1)), (NPARTO(1, 2),NPOSIT(1)), * (NPARTO(1, 3),NELECT(1)), (NPARTO(1, 4),NNU(1)) , * (NPARTO(1, 5),NMUP(1)) , (NPARTO(1, 6),NMUM(1)) , * (NPARTO(1, 7),NPI0(1)) , (NPARTO(1, 8),NPIP(1)) , * (NPARTO(1, 9),NPIM(1)) , (NPARTO(1,10),NK0L(1)) , * (NPARTO(1,11),NKPL(1)) , (NPARTO(1,12),NKMI(1)) , * (NPARTO(1,13),NNEUTR(1)), (NPARTO(1,14),NPROTO(1)), * (NPARTO(1,15),NPROTB(1)), (NPARTO(1,16),NK0S(1)) , * (NPARTO(1,18),NHYP(1)) , (NPARTO(1,19),NDEUT(1)) , * (NPARTO(1,20),NTRIT(1)) , (NPARTO(1,21),NALPHA(1)), * (NPARTO(1,22),NOTHER(1)), (NPARTO(1,25),NNEUTB(1)) *KEEP,OBSPAR. COMMON /OBSPAR/ OBSLEV,THCKOB,XOFF,YOFF,THETAP,PHIP, * THETPR,PHIPR,NOBSLV DOUBLE PRECISION OBSLEV(10),THCKOB(10),XOFF(10),YOFF(10), * THETAP,THETPR(2),PHIP,PHIPR(2) INTEGER NOBSLV *KEEP,PAM. COMMON /PAM/ PAMA,SIGNUM DOUBLE PRECISION PAMA(6000),SIGNUM(6000) *KEEP,PARPAR. COMMON /PARPAR/ CURPAR,SECPAR,PRMPAR,OUTPAR,C, * E00,E00PN,PTOT0,PTOT0N,THICKH,ITYPE,LEVL DOUBLE PRECISION CURPAR(14),SECPAR(14),PRMPAR(14),OUTPAR(14), * C(50),E00,E00PN,PTOT0,PTOT0N,THICKH INTEGER ITYPE,LEVL *KEEP,PARPAE. DOUBLE PRECISION GAMMA,COSTHE,PHI,H,T,X,Y,CHI,BETA,GCM,ECM EQUIVALENCE (CURPAR(2),GAMMA), (CURPAR(3),COSTHE), * (CURPAR(4), PHI ), (CURPAR(5), H ), * (CURPAR(6), T ), (CURPAR(7), X ), * (CURPAR(8), Y ), (CURPAR(9), CHI ), * (CURPAR(10),BETA), (CURPAR(11),GCM ), * (CURPAR(12),ECM ) *KEEP,PBALA. COMMON /PBALA/ PBAL DOUBLE PRECISION PBAL(10) *KEEP,PRIMSP. COMMON /PRIMSP/ PSLOPE,LLIMIT,ULIMIT,LL,UL,SLEX,ISPEC DOUBLE PRECISION PSLOPE,LLIMIT,ULIMIT,LL,UL,SLEX INTEGER ISPEC *KEEP,RANDPA. COMMON /RANDPA/ FAC,U1,U2,RD,NSEQ,ISEED,KNOR DOUBLE PRECISION FAC,U1,U2 REAL RD(3000) INTEGER ISEED(103,10),NSEQ LOGICAL KNOR *KEEP,RECORD. COMMON /RECORD/ IRECOR INTEGER IRECOR *KEEP,REJECT. COMMON /REJECT/ AVNREJ, * ALTMIN,ANEXP,THICKA,THICKD,CUTLN,EONCUT, * FNPRIM DOUBLE PRECISION AVNREJ(10) REAL ALTMIN(10),ANEXP(10),THICKA(10),THICKD(10), * CUTLN,EONCUT LOGICAL FNPRIM *KEEP,RESON. COMMON /RESON/ RDRES,RESRAN,IRESPAR REAL RDRES(2),RESRAN(1000) INTEGER IRESPAR *KEEP,RUNPAR. COMMON /RUNPAR/ FIXHEI,THICK0,HILOECM,HILOELB, * STEPFC,NRRUN,NSHOW,PATAPE,MONIIN, * MONIOU,MDEBUG,NUCNUC, * CETAPE, * SHOWNO,ISHW,NOPART,NRECS,NBLKS,MAXPRT,NDEBDL, * N1STTR,MDBASE, * DEBDEL,DEBUG,FDECAY,FEGS,FIRSTI,FIXINC,FIXTAR, * FIX1I,FMUADD,FNKG,FPRINT,FDBASE * ,GHEISH,GHESIG COMMON /RUNPAC/ DSN,HOST,USER DOUBLE PRECISION FIXHEI,THICK0,HILOECM,HILOELB REAL STEPFC INTEGER NRRUN,NSHOW,PATAPE,MONIIN,MONIOU,MDEBUG,NUCNUC, * SHOWNO,ISHW,NOPART,NRECS,NBLKS,MAXPRT,NDEBDL, * N1STTR,MDBASE INTEGER CETAPE CHARACTER*79 DSN CHARACTER*20 HOST,USER LOGICAL DEBDEL,DEBUG,FDECAY,FEGS,FIRSTI,FIXINC,FIXTAR, * FIX1I,FMUADD,FNKG,FPRINT,FDBASE * ,GHEISH,GHESIG *KEEP,STACKF. COMMON /STACKF/ STACK,STACKP,EXST,NSHIFT,NOUREC,ICOUNT,NTO,NFROM INTEGER MAXSTK PARAMETER (MAXSTK = 12*340*2) DOUBLE PRECISION STACK(MAXSTK) INTEGER STACKP,EXST,NSHIFT,NOUREC,ICOUNT,NTO,NFROM *KEEP,STATI. COMMON /STATI/ SABIN,SBBIN,INBIN,IPBIN,IKBIN,IHBIN DOUBLE PRECISION SABIN(37),SBBIN(37) INTEGER INBIN(37),IPBIN(37),IKBIN(37),IHBIN(37) *KEEP,THNVAR. COMMON /THNVAR/ STACKINT,INT_ICOUNT,THINNING INTEGER MAXICOUNT PARAMETER (MAXICOUNT=20000) DOUBLE PRECISION STACKINT(MAXICOUNT,13) INTEGER INT_ICOUNT LOGICAL THINNING *KEEP,VERS. COMMON /VERS/ VERNUM,MVDATE,VERDAT DOUBLE PRECISION VERNUM INTEGER MVDATE CHARACTER*18 VERDAT *KEEP,CEREN1. COMMON /CEREN1/ CERELE,CERHAD,ETADSN,WAVLGL,WAVLGU,CYIELD, * CERSIZ,LCERFI DOUBLE PRECISION CERELE,CERHAD,ETADSN,WAVLGL,WAVLGU,CYIELD REAL CERSIZ LOGICAL LCERFI *KEEP,CEREN2. COMMON /CEREN2/ PHOTCM,XCER,YCER,UEMIS,VEMIS,CARTIM,ZEMIS, * DCERX,DCERY,ACERX,ACERY, * XCMAX,YCMAX,EPSX,EPSY, * DCERXI,DCERYI,FCERX,FCERY, * XSCATT,YSCATT,CERXOS,CERYOS, * NCERX,NCERY,ICERML REAL PHOTCM,XCER,YCER,UEMIS,VEMIS,CARTIM,ZEMIS, * DCERX,DCERY,ACERX,ACERY, * XCMAX,YCMAX,EPSX,EPSY, * DCERXI,DCERYI,FCERX,FCERY, * XSCATT,YSCATT,CERXOS(20),CERYOS(20) INTEGER NCERX,NCERY,ICERML *KEEP,CEREN3. COMMON /CEREN3/ CERCNT,DATAB2,LHCER INTEGER MAXBF2 PARAMETER (MAXBF2 = 39 * 7) DOUBLE PRECISION CERCNT REAL DATAB2(MAXBF2) INTEGER LHCER *KEEP,CEREN4. COMMON /CEREN4/ NRECER INTEGER NRECER c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> *keep,certel. common /certel/ cormxd,cord,coralp,ctpars,omega, + photn,photnp,phpt,pht,vphot, + vchi,veta,vzeta,vchim,vetam,vzetam, + lambda,mu,nu,nctels,ncph double precision cormxd,cord,coralp,ctpars(20,7),omega(20,3,3), + photn(3),photnp(3),phpt(3),pht,vphot(3), + vchi(3),veta(3),vzeta(3),vchim,vetam,vzetam, + lambda,mu,nu integer nctels,ncph(5) double precision xg,yg,zg,xgp,ygp,zgp,up,vp,wp,xpcut,ypcut,zpcut equivalence (photn(1) ,xg) ,(photn(2) ,yg) ,(photn(3) ,zg) , + (photnp(1),xgp) ,(photnp(2),ygp) ,(photnp(3),zgp), + (phpt(1) ,xpcut),(phpt(2) ,ypcut),(phpt(3) ,zpcut), + (vphot(1) ,up) ,(vphot(2) ,vp) ,(vphot(3) ,wp) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C Modificacion hecha por Aitor (5-feb-98) common /aitor/ aitoth double precision aitoth C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c Angles for the "spinning" of a particle around the c main axis of the CT common /spinang/ spinxi double precision spinxi C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> *KEND. INTEGER JNBIN(37),JPBIN(37),JKBIN(37),JHBIN(37) DOUBLE PRECISION CHI2,FPARAM(6) DOUBLE PRECISION MPART2(10,25),MPHOT2(10),MPOSI2(10),MELEC2(10), * MNU2(10),MMUP2(10),MMUM2(10),MPI02(10),MPIP2(10), * MPIM2(10),MK0L2(10),MKPL2(10),MKMI2(10), * MNETR2(10),MPROT2(10),MPRTB2(10),MK0S2(10), * MHYP2(10),MNETB2(10),MDEUT2(10),MTRIT2(10), * MALPH2(10),MOTH2(10) EQUIVALENCE (MPART2(1, 1),MPHOT2(1)), (MPART2(1, 2),MPOSI2(1)), * (MPART2(1, 3),MELEC2(1)), (MPART2(1, 4),MNU2(1)) , * (MPART2(1, 5),MMUP2(1)) , (MPART2(1, 6),MMUM2(1)) , * (MPART2(1, 7),MPI02(1)) , (MPART2(1, 8),MPIP2(1)) , * (MPART2(1, 9),MPIM2(1)) , (MPART2(1,10),MK0L2(1)) , * (MPART2(1,11),MKPL2(1)) , (MPART2(1,12),MKMI2(1)) , * (MPART2(1,13),MNETR2(1)), (MPART2(1,14),MPROT2(1)), * (MPART2(1,15),MPRTB2(1)), (MPART2(1,16),MK0S2(1)) , * (MPART2(1,18),MHYP2(1)) , (MPART2(1,19),MDEUT2(1)), * (MPART2(1,20),MTRIT2(1)), (MPART2(1,21),MALPH2(1)), * (MPART2(1,22),MOTH2 (1)), (MPART2(1,25),MNETB2(1)) C VARIABLES BEING USED FOR RUNTIME REAL TDIFF INTEGER ILEFTA,ILEFTB,TIME EXTERNAL TIME C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> double precision ctdiams(20) C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> double precision theprim, phiprim double precision spinthe, spinphi C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C----------------------------------------------------------------------- CERELE = 0.D0 CERHAD = 0.D0 NRECER = 0 C INITIALIZE AND READ RUN STEERING CARDS CALL START IF ( CERSIZ .LE. 0. ) THEN ICRSIZ = 0 ELSE ICRSIZ = 1 ENDIF C RESET COUNTER FOR WORDS WRITTEN TO TAPE IRECOR = 0 C RESET COUNTER FOR AVERAGE HIGHT OF 1ST INTERACTION CHISUM = 0.D0 CHISM2 = 0.D0 C SET ARRAYS FOR SCALES OF KINETIC ENERGY-INTERACTION TABLE SABIN(1) = 0.D0 SBBIN(1) = 0.1D0 DO 13 J = 2,37 SABIN(J) = 10.D0**((J-4.D0)/3.D0) SBBIN(J) = 10.D0**((J-3.D0)/3.D0) 13 CONTINUE C CHECK AND SET PRIMARY PARAMETERS CALL INPRM do 161 i=1,nctels ctdiams(i) = ctpars(i,ctdiam) 161 continue C INITIALIZE NKG ROUTINES CALL ININKG C RESET COUNTERS FOR NUCLEON, PION AND KAON TABLE FOR ALL SHOWERS C RESET ENERGY-MULTIPLICITY & ENERGY-ELASTICITY MATRIX FOR ALL SHOWERS DO 17 J = 1,37 JNBIN(J) = 0 JPBIN(J) = 0 JKBIN(J) = 0 JHBIN(J) = 0 ELMEAA(J) = 0.D0 DO 17 L = 1,13 MULTOT(J,L) = 0 IELDPA(J,L) = 0 17 CONTINUE C RESET OTHER ARRAYS FOR ALL SHOWERS DO 99 J = 1,20 IELNU(J) = 0 IELPI(J) = 0 IELIS(J) = 0 IELHM(J) = 0 99 CONTINUE C RESET ARRAYS FOR INTERACTION LENGTH STATISTICS DO 90 J = 1,124 IHYCHI(J) = 0 IKACHI(J) = 0 IMUCHI(J) = 0 INUCHI(J) = 0 IPICHI(J) = 0 INNCHI(J) = 0 90 CONTINUE C RESET ARRAY FOR MEAN VALUES AND STANDARD DEVIATION DO 477 K = 1,25 DO 477 J = 1,10 MPARTO(J,K) = 0.D0 MPART2(J,K) = 0.D0 477 CONTINUE C RESET ARRAYS FOR LONGITUDINAL DISTRIBUTION IF ( LLONGI ) THEN DO 478 K = 1,9 DO 4781 J = 0,NSTEP APLONG(J,K) = 0.D0 SPLONG(J,K) = 0.D0 4781 CONTINUE 478 CONTINUE ENDIF C STEERING OF PRINTOUT OF RANDOM GENERATOR SEEDS IPROUT = MIN(100,NSHOW/20) IPROUT = MAX(1,IPROUT) C TIME AT BEGINNING c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c ILEFTA = TIME() ILEFTA = 0 c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> print *,'JCIO::========================================' print *,'JCIO:: Initializing JCIO system for advanced' print *,'JCIO:: saving of data.' print *,'JCIO::========================================' c- initialize jcio system call jcinitio(dsn,nrrun) c- create file run###### call jcstartrun(runh) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C----------------------------------------------------------------------- C LOOP OVER SHOWERS DO 2 ISHW = 1,NSHOW c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c Next block of code has been modified, and comes from INPRM c---------------------------------------------------------------------- C SCATTERING OF CENTER OF CHERENKOV ARRAY RELATIVE TO SHOWER AXIS c>> Actually, XSCATT and YSCATT should be RminSCATT and RmaxSCATT ICERML = MIN(MAX(ICERML,1),20) XSCATT = ABS(XSCATT) YSCATT = ABS(YSCATT) WRITE(MONIOU,5225)ICERML,XSCATT,YSCATT 5225 FORMAT(' ** USING EACH SHOWER SEVERAL TIMES:'/ + ' USE EACH EVENT ',I2,' TIMES'/ + ' THE EVENTS ARE SCATTERED RANDOMLY IN A SECTOR OF RADII:'/ + ' Rmin = ',F10.0,' Rmax = ',F10.0) DO 4438 I=1,ICERML 5226 CALL RMMAR( RD,2,3 ) CERXOS(I) = 2.0*YSCATT*(RD(1)-0.5) CERYOS(I) = 2.0*YSCATT*(RD(2)-0.5) R=SQRT(CERXOS(I)**2+CERYOS(I)**2) IF ((R.LT.XSCATT).OR.(R.GT.YSCATT)) GOTO 5226 WRITE(MONIOU,4437) I,CERXOS(I),CERYOS(I) 4437 FORMAT(' CORE OF EVENT ',I2,' AT ',2F12.2) 4438 CONTINUE c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c Next block of code comes from INPRM c---------------------------------------------------------------------- EVTH(98) = FLOAT(ICERML) DO 480 I=1,20 EVTH( 98+I) = CERXOS(I) EVTH(118+I) = CERYOS(I) 480 CONTINUE c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> SHOWNO = SHOWNO + 1 I = ISHW IF ( ISHW .LE. MAXPRT ) THEN FPRINT = .TRUE. ELSE FPRINT = .FALSE. ENDIF c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c Create cer######,dat######,sta###### files c------------------------------------------------------------ call jcnewshower c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C RESET COUNTERS DO 447 K = 1,25 DO 447 J = 1,10 NPARTO(J,K) = 0.D0 447 CONTINUE MUOND = 0.D0 C RESET ARRAY FOR LONGITUDINAL DISTRIBUTION PER SHOWER IF ( LLONGI ) THEN DO 479 K = 1,9 DO 4791 J = 0,NSTEP PLONG(J,K) = 0.D0 4791 CONTINUE 479 CONTINUE ENDIF NRECS = 0 NBLKS = 0 DO 922 KKK = 1,10 AVNREJ(KKK) = 0.D0 922 CONTINUE IRESPAR = 0 C FIRST INTERACTION DATA FIRSTI = .TRUE. IFINET = 0 IFINNU = 0 IFINKA = 0 IFINPI = 0 IFINHY = 0 ELAST = 0.D0 C RESET COUNTERS FOR NUCLEON, PION AND KAON TABLE FOR SHOWER C RESET ENERGY-MULTIPLICITY & ENERGY-ELASTICITY MATRIX FOR SHOWER DO 11 J = 1,37 INBIN(J) = 0 IPBIN(J) = 0 IKBIN(J) = 0 IHBIN(J) = 0 ELMEAN(J) = 0.D0 DO 11 L = 1,13 MULTMA(J,L) = 0 IELDPM(J,L) = 0 11 CONTINUE DO 12 J = 1,10 PBAL(J) = 0.D0 EBAL(J) = 0.D0 12 CONTINUE C INITIALIZE PARTICLE STACK CALL ISTACK C RESET STACKINT DO J=1,MAXICOUNT DO K=1,MAXLEN STACKINT(J,K) = 0.D0 ENDDO ENDDO C INITIALIZE EVENT HEADER AND END FOR EACH EVENT DO 2123 L = 2,43 EVTH(L) = 0. 2123 CONTINUE DO 123 L = 2,MAXBUF EVTE(L) = 0. 123 CONTINUE C SHOWER BEGIN PRINTOUT IF ( FPRINT .OR. DEBUG ) WRITE(MONIOU,105) SHOWNO 105 FORMAT ('1',10('='),' SHOWER NO ',I10,' ',47('=')/) C RANDOM GENERATOR STATUS AT BEGINNING OF SHOWER CALCULATION EVTH(13) = NSEQ DO 45 L = 1,NSEQ CALL RMMAQ( ISEED(1,L), L, 'R' ) C SEED EVTH(11+L*3) = ISEED(1,L) C NUMBER OF CALLS EVTH(12+L*3) = MOD ( ISEED(2,L), 1000000 ) C NUMBER OF MILLIONS EVTH(13+L*3) = ISEED(3,L)*1000 + INT( ISEED(2,L)/1000000 ) 45 CONTINUE IF ( FPRINT .OR. DEBUG .OR. MOD(ISHW-1,IPROUT).EQ.0 ) THEN CALL PRTIME(TTIME) WRITE(MONIOU,158) SHOWNO,(L,(ISEED(J,L),J=1,3),L=1,NSEQ) 158 FORMAT(' AND RANDOM NUMBER GENERATOR AT BEGIN OF EVENT :',I8, * /,(' SEQUENCE = ',I2,' SEED = ',I9 ,' CALLS = ',I9, * ' BILLIONS = ',I9)) ENDIF C RESET KNOR KNOR = .TRUE. C GET FULL RANDOM GENERATOR STATUS (103 WORDS PER SEQUENCE) CC DO 495 L = 1,NSEQ CC CALL RMMAQ( ISEED(1,L), L, 'RV' ) CC WRITE(MONIOU,658) L,(ISEED(J,L),J=1,103) CC658 FORMAT ( ' FULL RANDOM NUMBER GENERATOR STATUS ', CC * 'FOR SEQUENCE ',I2,/(' ',10I11)) CC495 CONTINUE c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>> *** ATENTION *** ATENTION *** ATENTION *** ATENTION *** ATENTION >> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>> >> c>> In the next block (between this ATENTION comments) CORSIKA makes >> c>> three things, in this order: >> c>> >> c>> i. Set ANGLES OF INCIDENCE (different distributions of theta >> c>> for gammas -flat- and hadrons -standard. >> c>> ii. Set HEIGHT for start at THICK0 (normally = 0 => 112.8 Km) >> c>> iii. Set ENERGY of the primary. >> c>> >> c>> (The original order was ii., iii. and i.) >> c>> >> c>> JCG Wed Sep 21 10:49:14 MET DST 1998 >>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C GET PRIMARY ANGLES OF INCIDENCE IF ( FIXINC ) THEN THETAP = THETPR(1) PHIP = PHIPR(1) PRMPAR(3) = COS(THETAP) ELSE if ( prmpar(1).eq.1 ) then C>> GAMMAS >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C NOTE!! We will use a FLAT distribution for THETA: C Then, next block (original block) must be commented. c The modificated code follows this block c CALL RMMAR( RD,3,1 ) CT1 = THETPR(1) CT2 = THETPR(2) THETAP = RD(2)*(CT2 - CT1) + CT1 CTT = COS(THETAP) PRMPAR(3) = CTT else C>> HADRONS AND ELECTRONS (AND ANY OTHER BUT GAMMAS) >>>>>>>>>>>>>>>> c Choose angles at random with equal flux for all directions c with horizontal detector array (see: O.C. Allkofer & P.K.F. Grieder, c Cosmic Rays on Earth, in: Physics Data 25/1, H.Behrens & G.Ebel Ed., c (Fachinformationszentrum Karlsruhe, Germany, 1983) chpt. 1.1.2) c CALL RMMAR( RD,3,1 ) CT1 = SIN(THETPR(1))**2 CT2 = SIN(THETPR(2))**2 CTT = SQRT( 1.D0 - RD(2)*(CT2 - CT1) - CT1 ) PRMPAR(3) = CTT THETAP = ACOS(CTT) endif PHIP = RD(1) * ( PHIPR(2) - PHIPR(1) ) + PHIPR(1) ENDIF PRMPAR(4) = PHIP c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C DEFINE HEIGHT FOR START AT THICK0 (IN G/CM**2) (112.8 KM FOR THICK0=0) PRMPAR(5) = HEIGH(THICK0) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C GET PRIMARY ENERGY INTO PRMPAR(2) IF ( ISPEC .EQ. 0 ) THEN PRMPAR(2) = LLIMIT ELSE CALL RMMAR( RD,1,1 ) IF ( PSLOPE .NE. -1.D0 ) THEN PRMPAR(2) = ( RD(1)*UL + ( 1.D0-RD(1) )*LL )**SLEX ELSE PRMPAR(2) = LLIMIT * LL**RD(1) ENDIF ENDIF c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>> *** ATENTION *** ATENTION *** ATENTION *** ATENTION *** ATENTION >> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>> Modification: this is no longer needed >>>>>>>>>>>>>>>>>>>>>>>>>>>> c>> (Superseeded by Sphere algorithm, see cerenkov.f) >>>>>>>>>>>>>>>>> c>> JCG Wed Sep 21 10:49:14 MET DST 1998 >>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> cc Btw, we now modify the "shadow area" of the telescopes, cc to cover the angle theta. c do 160 i=1,nctels c ctpars(i,ctdiam) = ctdiams(i)/cos(thetap) c write (MONIOU,*) c * 'New region for CT',i,' = ',ctpars(i,ctdiam) c 160 continue C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c Here we calculate the angles spinphi and spinthe, which are the c phi and theta angles of the particle, with respect to the direction c where the CT is pointing to. spinthe is the angular displacement c of the new direction respect to the original (CT); spinphi=0 means c that the new direction is towards the zenith, spinphi=+-180 means c towards the horizont. c See the document "simulation.tex" c First, save the "CT" orientation c (moved from a couple of lines below, marked with [*]) EVTH(11) = THETAP EVTH(12) = PHIP CALL RMMAR( RD,3,1 ) c Then, calculate the new direction relative to the CT direction spinphi = RD(1)*PI spinthe = RD(2)*spinxi*pi/180 c And then, RE-calculate the GLOBAL direction in CORSIKA c We use formulae for spherical triangles theprim = acos( cos(THETAP)*cos(spinthe)+ $ sin(THETAP)*sin(spinthe)*cos(spinphi) ) phiprim = asin( sin(spinthe)*sin(spinphi)/sin(theprim) ) THETAP = theprim EVTH(140) = spinthe if (RD(3).gt.0.5) then PHIP = PHIP - phiprim EVTH(141) = -spinphi else PHIP = PHIP + phiprim EVTH(141) = spinphi endif PRMPAR(3) = COS(THETAP) PRMPAR(4) = PHIP C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>> Modification (HZA trick) cancelled >>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>> JCG Wed Sep 21 10:49:14 MET DST 1998 >>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C Modificacion hecha por Aitor c aitoth = THETAP C>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C CALCULATE COORDINATE CORRECTION FOR TOP OF ATMOSPHERE CALL COORIN( PRMPAR(5) ) C COUNTER FOR PARTICLE OUTPUT LH = 0 C COUNTER FOR CERENKOV OUTPUT IF ( LCERFI ) LHCER = 0 C CALCULATE BUNCH SIZE FOR CERENKOV PHOTONS IF NOT SET IN DATAC IF ( ICRSIZ .EQ. 0 ) THEN CALL GETBUS( NINT(PRMPAR(1)),SNGL(PRMPAR(2)),SNGL(PRMPAR(3)), * CERSIZ ) WRITE(MONIOU,*)'CERENKOV BUNCH SIZE IS CALCULATED TO=',CERSIZ ENDIF C GET GAMMA FACTOR FROM ENERGY C FOR GAMMAS PRMPAR(2) STAYS = ENERGY IF ( PRMPAR(1) .NE. 1.D0 ) * PRMPAR(2) = PRMPAR(2) / PAMA(NINT(PRMPAR(1))) C SET PRIMARY TO CURRENT PARTICLE DO 3 J = 1,8 CURPAR(J) = PRMPAR(J) NCOUN(J) = 0 3 CONTINUE C SET WEIGHT C CALCULATE FIRST INTERACTION POINT IF HADRONIC GEN = 0.D0 H = HEIGH(THICK0) CALL BOX2 IF ( FIX1I ) THEN CHI = THICK(FIXHEI) / PRMPAR(3) H = FIXHEI FDECAY = .FALSE. ELSE H = HEIGH ( CHI*PRMPAR(3) + THICK0 ) ENDIF CHISUM = CHISUM + CHI CHISM2 = CHISM2 + CHI**2 ALEVEL = H C INITIALIZE COORDINATE CORRECTIONS FOR HADRONIC PRIMARIES C FOR EM PRIMARIES IT IS DONE IN EGS HH = MAX( H, 0.D0 ) IF ( CURPAR(1) .GT. 3.D0 ) CALL COORIN( HH ) IF ( FMUADD ) THEN IF ( CURPAR(1) .EQ. 5 .OR. CURPAR(1) .EQ. 6) THEN DO J = 1,MAXLEN AMUPAR(J) = CURPAR(J) ENDDO AMUPAR(5) = PRMPAR(5) IF(DEBUG)WRITE(MDEBUG,*)'MAIN : MUON STORED IN AMUPAR' FMUORG = .TRUE. ENDIF ENDIF C SET TARGET FLAG IF SELECTED FOR FIRST INTERACTION IF ( N1STTR .GT. 0 ) THEN FIXTAR = .TRUE. FDECAY = .FALSE. EVTH(6) = REAL(N1STTR) ELSE FIXTAR = .FALSE. EVTH(6) = 0.0 ENDIF C INITIALIZE ARRAYS FOR NKG FOR EACH SHOWER IF ( FNKG ) CALL STANKG C STORE FIRST PARTICLE IN HEADER AND PRINT IT OUT EVTH( 2) = REAL(SHOWNO) EVTH( 3) = CURPAR(1) IF ( CURPAR(1) .EQ. 1.D0 ) THEN C PRIMARY ENERGY FOR PHOTONS E00 = GAMMA E00PN = GAMMA INUCL = 1 ELSE E00 = GAMMA * PAMA(NINT(CURPAR(1))) INUCL = INT(MAX(1.D0,CURPAR(1)/100.D0)) E00PN = E00 / INUCL ENDIF EVTH(147) = 0. IF ( FEGS ) THEN C PARAMETER FOR ELECTRON AND PHOTON REJECT (CONVERT ENERGY TO MEV) EONCUT = .5E-9*SQRT(E00*1000.D0) CUTLN = LOG(EONCUT) ENDIF EVTH( 4) = E00 EVTH( 5) = THICK0 EVTH( 7) = H PTOT0 = SQRT( E00**2 - PAMA(NINT(CURPAR(1)))**2 ) PTOT0N = PTOT0 / INUCL ST = SQRT(1.D0-COSTHE**2) EVTH( 8) = PTOT0 * ST * COS(PHI) EVTH( 9) = PTOT0 * ST * SIN(PHI) EVTH(10) = PTOT0 * COSTHE c c [*] one block from here sent above c EVTH(85) = CERSIZ IF ( CURPAR(1) .GT. 3.D0 ) THEN IF ( FPRINT .OR. DEBUG ) WRITE(MONIOU,102) (CURPAR(J),J = 1,8) 102 FORMAT (/' PRIMARY PARAMETERS AT FIRST INTERACTION POINT'/ * 16X,1P,8E10.3) ELSE IF ( FPRINT .OR. DEBUG ) WRITE(MONIOU,132) 132 FORMAT (/' PRIMARY PARTICLE IS ELECTROMAGNETIC') ENDIF C WRITE EVENT HEADER INTO BUFFER C FOR EM PARTICLES EVTH IS WRITTEN TO BUFFER IN EGS (IF ACTIVE) IF ( EVTH(3) .GT. 3.0 .OR. .NOT. FEGS ) THEN CALL TOBUF ( EVTH,0 ) IF ( LCERFI ) CALL TOBUFC( EVTH,0 ) ENDIF C PRINT HEADER FOR HIGH ENERGY PARTICLES IF ( FPRINT .OR. DEBUG ) WRITE(MONIOU,103) 103 FORMAT(/' TYPE GAMMA COSTHETA ', * ' PHI HEIGHT TIME X-CM Y-CM ', * ' GEN LEVEL E ON STACK'/) NOPART = 0 IF ( CURPAR(1) .LE. 3.D0 .OR. * (CURPAR(1) .GE. 5.D0 .AND. CURPAR(1) .LE. 7.D0) ) THEN C GIVE PARTICLE TO EGS OR NKG IF ELECTROMAGNETIC C AND TAKE THEN NEXT PARTICLE FROM STACK C FLAG FOR NO PRIMARY INTERACTION IS SET FOR ALL BUT ELM. PRIMARIES IF ( CURPAR(1) .LE. 3.D0 ) THEN FNPRIM = .FALSE. ELSE FNPRIM = .TRUE. H = PRMPAR(5) ENDIF CALL BOX3 IF ( FEGS ) THEN CHISUM = CHISUM + THICK(DBLE(EVTH(7))) CHISM2 = CHISM2 + THICK(DBLE(EVTH(7)))**2 ENDIF FIRSTI = .FALSE. GOTO 4 ELSE C HADRONIC PARTICLES FNPRIM = .TRUE. C FILL LONGITUDINAL DISTRIBUTION FOR THE PRIMARY PARTICLE C THE PARTICLE IS TRACKED FROM THICK0 DOWN TO THICK0+CHI*PRMPAR(3) C COUNT THE PARTICLES FOR THE LONGITUDINAL DEVELOPMENT IF ( LLONGI ) THEN LPCT1 = INT( THICK0 * THSTPI ) LPCT2 = INT( (THICK0 + PRMPAR(3)*CHI) * THSTPI ) LPCT2 = MIN(NSTEP,LPCT2) C GAMMAS, ELECTRONS AND POSITRONS ARE NOT TRANSPORTED HERE, SEE EGS C MUONS ARE TRANSPORTED IN MUTRAC C HADRONS IF ( ITYPE .GE. 7 .AND. ITYPE .LE. 41 ) THEN DO 5004 L = LPCT1,LPCT2 PLONG(L,6) = PLONG(L,6) + 1. 5004 CONTINUE C CHARGED HADRONS IF ( SIGNUM(ITYPE) .NE. 0.D0 ) THEN DO 5005 L = LPCT1,LPCT2 PLONG(L,7) = PLONG(L,7) + 1. 5005 CONTINUE ENDIF C NUCLEI ELSEIF ( ITYPE .GT. 100 ) THEN DO 5006 L = LPCT1,LPCT2 PLONG(L,8) = PLONG(L,8) + 1. 5006 CONTINUE ENDIF ENDIF C CHECK OBSERVATION LEVEL PASSAGE AND UPDATE PARTICLE COORDINATES HNEW = H C FOR UPDATE WE NEED THE START ALTITUDE H H = HEIGH(THICK0) DO 251 J = 1,NOBSLV C JUMP INTO NORMAL PARTICLE TREATMENT FOR HADRONS IF ( HNEW .GT. OBSLEV(J) ) THEN H = HNEW GOTO 6 ENDIF IF ( H .LT. OBSLEV(J) ) GOTO 251 C REMEMBER NUMBER OF LEVEL FOR OUTPUT LEVL = J CALL UPDATE( OBSLEV(J),THCKOB(J),J ) IF (DEBUG) WRITE(MDEBUG,256) J,IRET1,IRET2 256 FORMAT(' MAIN : LEVEL ',I5,' IRET1,2=',2I5) C IF PARTICLE IS NOT CUTTED, BRING IT TO OUTPUT IF ( IRET2 .EQ. 0 ) THEN CALL OUTPUT ENDIF 251 CONTINUE IF (DEBUG) WRITE(MDEBUG,*) * 'MAIN : PRIMARY REACHED LOWEST OBSERVATION LEVEL' GOTO 4 ENDIF C----------------------------------------------------------------------- C NORMAL CYCLE 7 CONTINUE C IF ENERGY TOO SMALL TAKE NEXT PARTICLE IF ( GAMMA .LE. 1.D0 ) THEN IF ( CURPAR(1) .NE. 1.D0 ) THEN IF ( CURPAR(1).EQ.5.D0 .OR. CURPAR(1).EQ.6.D0 ) * FMUORG = .FALSE. GOTO 4 ENDIF C SPECIAL TREATMENT FOR PHOTONS ITYPE = 1 CHI = 0.D0 GOTO 5 ENDIF C DETERMINE PLACE OF NEXT INTERACTION CALL BOX2 C CHECK PASSAGE THROUGH OBSERVATION LEVELS AND TRACK PARTICLES TO THE C PLACE OF INTERACTION 5 CONTINUE IRET1 = 0 CALL BOX3 IF ( IRET1 .NE. 0 ) GOTO 4 6 CONTINUE IRET1 = 0 MSMM = 0 C INCREMENT PARTICLE GENERATION AND PROCESS NUCLEAR INTERACTION GEN = GEN + 1.D0 C INITIALIZE INTERMEDIATE STACK FOR ONE REACTION CALL TSTINI CALL NUCINT C TRANSFER INTERMEDIATE STACK FOR ONE REACTION CALL TSTEND C ENERGY - MULTIPLICITY STATISTICS IF ( EKINL .LE. 0.1D0 ) THEN MEN = 1 ELSE MEN = 4.D0 + 3.D0 * LOG10(EKINL) MEN = MIN( MEN, 37 ) ENDIF IF ( MSMM .LE. 1 ) THEN MMU = 1 ELSE MMU = 1.D0 + 3.D0 * LOG10(DBLE(MSMM)) MMU = MIN( MMU, 13 ) ENDIF MULTMA(MEN,MMU) = MULTMA(MEN,MMU) + 1 MULTOT(MEN,MMU) = MULTOT(MEN,MMU) + 1 IF ( DEBUG ) WRITE(MDEBUG,*) 'MAIN : EKINL,MSMM=', * SNGL(EKINL),MSMM IF ( IRET1 .EQ. 0 ) THEN IF ( DEBUG ) WRITE(MDEBUG,666) (CURPAR(II),II=1,11) 666 FORMAT(' MAIN : CURPAR=',1P,11E10.3) GOTO 7 ENDIF C GET NEXT PARTICLE FROM STACK, IF IRET=1 ALL PARTICLES ARE DONE 4 CONTINUE IRET1 = 0 CALL FSTACK IF ( FMUADD ) THEN IF ( (CURPAR(1) .EQ. 5 .OR. CURPAR(1) .EQ. 6) * .AND. IRET1 .EQ. 0 .AND. .NOT. FMUORG ) THEN DO J = 1,MAXLEN AMUPAR(J) = CURPAR(J) ENDDO IF(DEBUG)WRITE(MDEBUG,*)'MAIN : MUON STORED IN AMUPAR' FMUORG = .TRUE. ENDIF ENDIF IF ( IRET1 .EQ. 0 ) GOTO 7 C----------------------------------------------------------------------- C FINISH SHOWER AND PRINT INFORMATION CALL OUTEND * IF ( DEBUG ) WRITE(MDEBUG,442) NPARTO *442 FORMAT(' MAIN : NPARTO='/(' ',10F10.0)) IF ( FPRINT .OR. DEBUG ) THEN IOBSLV = MIN( 5, NOBSLV ) WRITE(MONIOU,54) (K,K=1,IOBSLV) 54 FORMAT (/' PARTICLES AT DETECTOR LEVEL :'/ * ' FOR LEVEL ', 5I13) WRITE(MONIOU,55) (OBSLEV(K),K=1,IOBSLV) 55 FORMAT ( ' HEIGHT IN CM ',1P, 5E13.3/) WRITE(MONIOU,776) 'PROTONS ',(NPROTO(K),K=1,IOBSLV) WRITE(MONIOU,776) 'ANTIPROTONS ',(NPROTB(K),K=1,IOBSLV) WRITE(MONIOU,776) 'NEUTRONS ',(NNEUTR(K),K=1,IOBSLV) WRITE(MONIOU,776) 'ANTINEUTRONS ',(NNEUTB(K),K=1,IOBSLV) WRITE(MONIOU,776) 'PHOTONS ',(NPHOTO(K),K=1,IOBSLV) WRITE(MONIOU,776) 'ELECTRONS ',(NELECT(K),K=1,IOBSLV) WRITE(MONIOU,776) 'POSITRONS ',(NPOSIT(K),K=1,IOBSLV) WRITE(MONIOU,776) 'NEUTRINOS ',(NNU (K),K=1,IOBSLV) WRITE(MONIOU,776) 'MU - ',(NMUM (K),K=1,IOBSLV) WRITE(MONIOU,776) 'MU + ',(NMUP (K),K=1,IOBSLV) WRITE(MONIOU,776) 'PI 0 ',(NPI0 (K),K=1,IOBSLV) WRITE(MONIOU,776) 'PI - ',(NPIM (K),K=1,IOBSLV) WRITE(MONIOU,776) 'PI + ',(NPIP (K),K=1,IOBSLV) WRITE(MONIOU,776) 'K0L ',(NK0L (K),K=1,IOBSLV) WRITE(MONIOU,776) 'K0S ',(NK0S (K),K=1,IOBSLV) WRITE(MONIOU,776) 'K - ',(NKMI (K),K=1,IOBSLV) WRITE(MONIOU,776) 'K + ',(NKPL (K),K=1,IOBSLV) WRITE(MONIOU,776) 'STR. BARYONS ',(NHYP (K),K=1,IOBSLV) WRITE(MONIOU,776) 'DEUTERONS ',(NDEUT (K),K=1,IOBSLV) WRITE(MONIOU,776) 'TRITONS ',(NTRIT (K),K=1,IOBSLV) WRITE(MONIOU,776) 'ALPHAS ',(NALPHA(K),K=1,IOBSLV) WRITE(MONIOU,776) 'OTHER PARTIC.',(NOTHER(K),K=1,IOBSLV) WRITE(MONIOU,*) WRITE(MONIOU,776) 'DECAYED MUONS',MUOND 776 FORMAT(' NO OF ',A13, '= ',5F13.0) IF ( NOBSLV .GT. 5 ) THEN IOBSLV = NOBSLV WRITE(MONIOU,54) (K,K=6,IOBSLV) WRITE(MONIOU,55) (OBSLEV(K),K=6,IOBSLV) WRITE(MONIOU,776) 'PROTONS ',(NPROTO(K),K=6,IOBSLV) WRITE(MONIOU,776) 'ANTIPROTONS ',(NPROTB(K),K=6,IOBSLV) WRITE(MONIOU,776) 'NEUTRONS ',(NNEUTR(K),K=6,IOBSLV) WRITE(MONIOU,776) 'ANTINEUTRONS ',(NNEUTB(K),K=6,IOBSLV) WRITE(MONIOU,776) 'PHOTONS ',(NPHOTO(K),K=6,IOBSLV) WRITE(MONIOU,776) 'ELECTRONS ',(NELECT(K),K=6,IOBSLV) WRITE(MONIOU,776) 'POSITRONS ',(NPOSIT(K),K=6,IOBSLV) WRITE(MONIOU,776) 'NEUTRINOS ',(NNU (K),K=6,IOBSLV) WRITE(MONIOU,776) 'MU - ',(NMUM (K),K=6,IOBSLV) WRITE(MONIOU,776) 'MU + ',(NMUP (K),K=6,IOBSLV) WRITE(MONIOU,776) 'PI 0 ',(NPI0 (K),K=6,IOBSLV) WRITE(MONIOU,776) 'PI - ',(NPIM (K),K=6,IOBSLV) WRITE(MONIOU,776) 'PI + ',(NPIP (K),K=6,IOBSLV) WRITE(MONIOU,776) 'K0L ',(NK0L (K),K=6,IOBSLV) WRITE(MONIOU,776) 'K0S ',(NK0S (K),K=6,IOBSLV) WRITE(MONIOU,776) 'K - ',(NKMI (K),K=6,IOBSLV) WRITE(MONIOU,776) 'K + ',(NKPL (K),K=6,IOBSLV) WRITE(MONIOU,776) 'STR. BARYONS ',(NHYP (K),K=6,IOBSLV) WRITE(MONIOU,776) 'DEUTERONS ',(NDEUT (K),K=6,IOBSLV) WRITE(MONIOU,776) 'TRITONS ',(NTRIT (K),K=6,IOBSLV) WRITE(MONIOU,776) 'ALPHAS ',(NALPHA(K),K=6,IOBSLV) WRITE(MONIOU,776) 'OTHER PARTIC.',(NOTHER(K),K=6,IOBSLV) WRITE(MONIOU,*) ENDIF ENDIF C ADD UP FOR MEAN VALUES DO 779 K = 1,25 DO 779 J = 1,10 MPARTO(J,K) = MPARTO(J,K) + NPARTO(J,K) MPART2(J,K) = MPART2(J,K) + NPARTO(J,K)**2 779 CONTINUE EVTE(2) = SHOWNO DO 335 K = 1,NOBSLV EVTE(3) = EVTE(3) + NPHOTO(K) EVTE(4) = EVTE(4) + NELECT(K) + NPOSIT(K) EVTE(5) = EVTE(5) + NPROTO(K) + NPROTB(K) + NNEUTR(K) + * NNEUTB(K) + NPI0(K) + NPIM(K) + NPIP(K) + NK0L(K) + * NK0S(K) + NKMI(K) + NKPL(K) + NHYP(K) + * NDEUT(K) + NTRIT(K) + NALPHA(K) + NOTHER(K) EVTE(6) = EVTE(6) + NMUP(K) + NMUM(K) 335 CONTINUE EVTE(7) = NOPART IF ( FPRINT .OR. DEBUG ) WRITE(MONIOU,110) * IFINNU,IFINPI,IFINET,IFINKA,IFINHY, * IFINNU+IFINPI+IFINET+IFINKA+IFINHY,ELAST 110 FORMAT(/' NO OF NUCLEONS PRODUCED IN FIRST INTERACTION =',I10/ * ' NO OF PIONS PRODUCED IN FIRST INTERACTION =',I10/ * ' NO OF ETAS PRODUCED IN FIRST INTERACTION =',I10/ * ' NO OF KAONS PRODUCED IN FIRST INTERACTION =',I10/ * ' NO OF S.BARYONS PRODUCED IN FIRST INTERACTION =',I10/ * ' TOTAL MULTIPLICITY OF FIRST INTERACTION =',I10/ * ' ELASTICITY OF FIRST INTERACTION =',F10.4) C PRINT OUT NKG RESULT FOR ONE SHOWER IF SELECTED IF ( FNKG ) CALL AVAGE IF ( LLONGI ) THEN C TREAT LONGITUDINAL DISTRIBUTIONS c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c calculated here again, 'cos it's rewrite I dont know where LPCT1 = INT( THICK0 * THSTPI ) LPCT2 = INT( (THICK0 + PRMPAR(3)*CHI) * THSTPI ) LPCT2 = MIN(NSTEP,LPCT2) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> DO 980 J = LPCT1,NSTEP C ADD ELECTRONS, POSITRONS, MUONS AND NUCLEI TO THE CHARGED PARTICLES PLONG(J,7) = PLONG(J,7) + PLONG(J,2) + PLONG(J,3) * + PLONG(J,4) + PLONG(J,5) + PLONG(J,8) C ADD UP FOR MEAN VALUES OF LONGITUDINAL DISTRIBUTION DO 979 K = 1,9 APLONG(J,K) = APLONG(J,K) + PLONG(J,K) SPLONG(J,K) = SPLONG(J,K) + PLONG(J,K)**2 979 CONTINUE 980 CONTINUE C PRINT LONGITUDINAL DISTRIBUTIONS PER SHOWER IF ( FPRINT .OR. DEBUG ) WRITE(MONIOU,910) THSTEP, * 'GAMMAS','POSITRONS','ELECTRONS','MU-','MU+','HADRONS', * 'CHARGED','NUCLEI','CERENKOV', * (J*THSTEP,(PLONG(J,K),K=1,9),J=LPCT1,NSTEP) 910 FORMAT(/' ---------- LONGITUDINAL DISTRIBUTION IN STEPS OF ', * F5.0,' G/CM**2 ----------------'/ * ' DEPTH ',3A12,3A11,A12,A11,A12/ * (' ',F6.0,F13.0,2F12.0,3F11.0,F12.0,F11.0,1P,E12.5,0P) ) CJOK ADAPTED FOR HEAT CALCULATION C910 FORMAT(/ C * ' LONGITUDINAL DISTRIBUTION IN STEPS OF ',F5.0,' G/CM**2' C * /' ',92('=')/' DEPTH',8A10,A12/1P C * (' ',0P,F6.0,1P,9E11.4)) CJOK IF ( FLGFIT ) THEN C PERFORM FIT TO THE LONGITUDINAL DISTRIBUTION OF ALL CHARGED PARTICLES C IF EGS IS SELECTED THIS IS THE DISTRIBUTION WHICH IS TO BE TAKEN IF ( FEGS ) THEN DO 930 J=0,NSTEP-LPCT1 DEP(J+1) = (J+LPCT1)*THSTEP CHAPAR(J+1) = PLONG(J+LPCT1,7) 930 CONTINUE NSTP = NSTEP + 1 - LPCT1 WRITE(MONIOU,8229) 'ALL CHARGED PARTICLES' 8229 FORMAT(/' FIT OF THE CURVE ', * ' N(T) = P1*((T-P2)/(P3-P2))**((P3-T)/(P4+P5*T+P6*T**2))'/ * ' TO LONGITUDINAL DISTRIBUTION OF ',A35) C IF NKG IS SELECTED ONLY THE ELECTRON DISTRIBUTION IS AVAILABLE ELSEIF ( FNKG ) THEN DEP(1) = 0.D0 CHAPAR(1) = 0.D0 DO 931 J = 1,IALT(1) DEP(J+1) = TLEV(J) CHAPAR(J+1) = SL(J) 931 CONTINUE NSTP = IALT(1) + 1 WRITE(MONIOU,8229) 'NKG ELECTRONS' C IF NONE IS SELECTED IT DOES NOT REALLY MAKE SENSE TO FIT C BUT LET'S TAKE THEN ALL CHARGED WHICH ARE MUONS AND HADRONS ELSE DO 932 J=0,NSTEP-LPCT1 DEP(J+1) = (J+LPCT1)*THSTEP CHAPAR(J+1) = PLONG(J+LPCT1,7) 932 CONTINUE NSTP = NSTEP + 1 - LPCT1 WRITE(MONIOU,8229) 'MUONS AND CHARGED HADRONS' ENDIF IF ( NSTP .GT. 6 ) THEN C THERE ARE MORE THAN 6 STEP VALUES, A FIT SHOULD BE POSSIBLE. C DO THE FIT: NPAR AND FPARAM GIVE THE NUMBER OF PARAMETERS USED C AND THE FINAL VALUES FOR THE PARAMETERS. CHISQ GIVES THE CHI**2/DOF C FOR THE FIT. CALL LONGFT(FPARAM,CHI2) WRITE(MONIOU,8230) FPARAM,CHI2,CHI2/SQRT(FPARAM(1))*100.D0 8230 FORMAT(' PARAMETERS = ',1P,6E12.4,0P/ * ' CHI**2/DOF = ',F10.1/ * ' AV. DEVIATION IN % = ',F10.4) C STORE RESULT IN END EVENT BLOCK DO 933 K = 1,6 EVTE(255+K) = FPARAM(K) 933 CONTINUE EVTE(262) = CHI2 ELSE WRITE(MONIOU,*) 'NO LONGI. FIT POSSIBLE, ', * ' NSTP = ',NSTP,' TOO SMALL.' DO 934 K = 1,6 EVTE(255+K) = 0. 934 CONTINUE EVTE(262) = 0. ENDIF ENDIF ENDIF c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c Saves statistics to sta###### file call jcstadata(EVTH,EVTE, + NPROTO,NPROTB,NNEUTR,NNEUTB,NPHOTO,NELECT,NPOSIT, + NNU ,NMUM ,NMUP ,NPI0 ,NPIM ,NPIP ,NK0L , + NK0S ,NKMI ,NKPL ,NHYP ,NDEUT ,NTRIT ,NALPHA, + NOTHER,IFINNU,IFINPI,IFINET,IFINKA,IFINHY, + CERELE,CERHAD,PLONG,LPCT1,NSTEP,THSTEP) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C WRITE SHOWER END TO OUTPUT BUFFER c CALL TOBUF( EVTE,0 ) CALL TOBUF( EVTE,1 ) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> IF ( LCERFI ) THEN CALL OUTND2 c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c CALL TOBUFC( EVTE,0 ) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> ENDIF IF ( FPRINT .OR. DEBUG ) WRITE(MONIOU,*) * 'CERENKOV PH. FROM ELECTRONS = ',SNGL(CERELE), * ' CERENKOV PH. FROM HADRONS = ',SNGL(CERHAD) CERELE = 0.D0 CERHAD = 0.D0 NRECER = 0 IF ( FPRINT .OR. DEBUG ) WRITE(MONIOU,210) SHOWNO 210 FORMAT(/' END OF SHOWER NO ',I10) DO 19 J = 1,37 JNBIN(J) = JNBIN(J) + INBIN(J) JPBIN(J) = JPBIN(J) + IPBIN(J) JKBIN(J) = JKBIN(J) + IKBIN(J) JHBIN(J) = JHBIN(J) + IHBIN(J) 19 CONTINUE 2 CONTINUE C END OF SHOWER LOOP C----------------------------------------------------------------------- 992 CONTINUE C RESET NUMBER OF SHOWERS TO CORRECT VALUE ISHW = I RUNE(3) = REAL(ISHW) C WRITE RUN END TO OUTPUT BUFFER AND FINISH OUTPUT c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c CALL TOBUF ( RUNE,1 ) call jcendrun(rune) c IF ( LCERFI ) CALL TOBUFC( RUNE,1 ) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> C TIME SINCE BEGINNING c ILEFTB = TIME() ILEFTB = 1 c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> TDIFF = ILEFTB - ILEFTA C MEAN VALUE FOR FIRST INTERACTION ALTITUDE (G/CM**2) IF ( ISHW .GT. 1 ) THEN CHISM2 = SQRT( ABS(CHISM2-CHISUM**2/ISHW) / (ISHW-1) ) CHISUM = CHISUM / ISHW ELSE CHISM2 = 0.D0 ENDIF C OUTPUTS FOR ALL SHOWERS WRITE(MONIOU,201) ISHW,TDIFF,TDIFF/ISHW,IRECOR,IRECOR/ISHW, * CHISUM,CHISM2 201 FORMAT('1',10('='),' RUN SUMMARY ',56('=')// * ' NUMBER OF GENERATED EVENTS = ',I10,/ * ' TOTAL TIME USED = ',E10.3,' SEC'/ * ' TIME PER EVENT = ',E10.3,' SEC'/ * ' TOTAL SPACE ON PATAPE USED = ',I10,' WORDS'/ * ' SPACE PER EVENT ON PATAPE = ',I10,' WORDS'/ * ' AVERAGE HEIGHT OF 1ST INT. = ',F10.3,' +-',F10.3,' G/CM**2'/) C ENERGY - MULTIPLICITY MATRIX FOR ALL SHOWERS WRITE(MONIOU,209) (K,K=1,13), * (J,(MULTOT(J,K),K=1,13),10**((J-4.)/3.),10**((J-3.)/3.),J=1,37), * 1,(INT(10**((K-1.)/3.)+1),K = 2,13), * 2,(INT(10**((K )/3.) ),K = 2,13) 209 FORMAT(//' ENERGY - MULTIPLICITY MATRIX FOR ALL SHOWERS'/ * ' ENERGY RUNS VERTICALLY, MULTIPLICITY HORIZONTALLY'//, * ' ',6X,5I9,3I8,5I7,' ENERGY RANGE (GEV)'/ * 37(/' ',I4,1X,I10,4I9,3I8,5I7,1X,1P,2E10.1,0P)// * ' MULT. ',5I9,3I8,5I7,4X,'LOWER BIN LIMIT'/ * ' RANGE ',5I9,3I8,5I7,4X,'UPPER BIN LIMIT') C GET MEAN OF ELASTICITY FOR ENERGY BINS DO 3377 J = 1,37 NELMEA = 0 DO 3378 K = 1,10 NELMEA = NELMEA + IELDPA(J,K) 3378 CONTINUE IF ( NELMEA .NE. 0 ) ELMEAA(J) = ELMEAA(J) / NELMEA 3377 CONTINUE C PRINT ENERGY - ELASTICITY MATRIX FOR ALL SHOWERS WRITE(MONIOU,408) (K,K=1,10), (J,(IELDPA(J,K),K=1,10), * ELMEAA(J),10**((J-4.D0)/3.D0),10**((J-3.)/3.D0),J=1,37), * ((K-1)*0.1D0,K=1,10),(K*0.1D0,K=1,10) 408 FORMAT (//' ENERGY - ELASTICITY MATRIX FOR ALL SHOWERS'/ * ' ENERGY RUNS VERTICALLY, ELASTICITY HORIZONTALLY'// * ' ',5X,10I9,' MEAN EL. ENERGY RANGE (GEV)'/ * 37(/' ',I4,1X,10I9,2X,1P,E10.3,2E10.1,0P)// * ' ELA. ',10F9.2,5X,'LOWER BIN LIMIT'/ * ' RANGE',10F9.2,5X,'UPPER BIN LIMIT') WRITE(MONIOU,204) 204 FORMAT (//' INTERACTIONS PER KINETIC ENERGY INTERVAL FOR ALL ', * 'SHOWERS'//' BIN LOWER LIMIT UPPER LIMIT ', * 'NUCLEON PIONS KAONS S.BARYONS TOTAL'/ * 12X,'IN GEV',9X,'IN GEV',7X, * ' EVENTS EVENTS EVENTS EVENTS '//) WRITE(MONIOU,207) (I,SABIN(I),SBBIN(I),JNBIN(I),JPBIN(I),JKBIN(I) * ,JHBIN(I),JNBIN(I)+JPBIN(I)+JKBIN(I)+JHBIN(I),I=1,37) 207 FORMAT(' ',I5,1P,2E15.4,0P,I12,3I10,I11) IF ( .NOT.GHEISH ) THEN C PRINT ELASTICITY STATISTICS WRITE(MONIOU,89) (I,(I-1)*.05,I*.05, * IELIS(I),IELHM(I),IELNU(I),IELPI(I),I = 1,20) 89 FORMAT (//' ELASTICITY STATISTICS '// * ' BIN LOW HIGH EDGE FOR ISOBARS HEAVY MESONS', * ' SINGLE NUCLEONS AND PIONS'/ * (' ',I3,' ',F4.2,' ',F4.2,' ',4I17)) ENDIF C CALCULATE MEAN VALUES AND STANDARD DEVIATIONS OF PARTICLE NUMBERS IF ( ISHW .GT. 1 ) THEN DO 879 K = 1,25 DO 879 J = 1,NOBSLV MPART2(J,K) = SQRT( abs(MPART2(J,K)-MPARTO(J,K)**2/ISHW) * /(ISHW-1) ) MPARTO(J,K) = MPARTO(J,K)/ISHW 879 CONTINUE ELSE DO 880 K = 1,25 DO 880 J = 1,NOBSLV MPART2(J,K) = 0.D0 880 CONTINUE ENDIF C PRINT MEAN VALUES AND STANDARD DEVIATIONS OF PARTICLE NUMBERS IOBSLV = MIN( 3, NOBSLV ) WRITE(MONIOU,854) (K,K=1,IOBSLV) 854 FORMAT (/ ' AVERAGE NUMBER OF PARTICLES PER EVENT :'/ * ' FROM LEVEL NUMBER ', 3(10X,I10,10X) ) WRITE(MONIOU,855) (OBSLEV(K),K=1,IOBSLV) 855 FORMAT ( ' HEIGHT IN CM',1P,3(20X,E10.3)/) WRITE(MONIOU,778)'PROTONS ',(MPROTO(K),MPROT2(K),K=1,IOBSLV) WRITE(MONIOU,778)'ANTIPROTONS ',(MPROTB(K),MPRTB2(K),K=1,IOBSLV) WRITE(MONIOU,778)'NEUTRONS ',(MNEUTR(K),MNETR2(K),K=1,IOBSLV) WRITE(MONIOU,778)'ANTINEUTRONS',(MNEUTB(K),MNETB2(K),K=1,IOBSLV) WRITE(MONIOU,778)'PHOTONS ',(MPHOTO(K),MPHOT2(K),K=1,IOBSLV) WRITE(MONIOU,778)'ELECTRONS ',(MELECT(K),MELEC2(K),K=1,IOBSLV) WRITE(MONIOU,778)'POSITRONS ',(MPOSIT(K),MPOSI2(K),K=1,IOBSLV) WRITE(MONIOU,778)'NEUTRINOS ',(MNU (K),MNU2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'MU - ',(MMUM (K),MMUM2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'MU + ',(MMUP (K),MMUP2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'PI 0 ',(MPI0 (K),MPI02 (K),K=1,IOBSLV) WRITE(MONIOU,778)'PI - ',(MPIM (K),MPIM2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'PI + ',(MPIP (K),MPIP2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'K0L ',(MK0L (K),MK0L2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'K0S ',(MK0S (K),MK0S2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'K - ',(MKMI (K),MKMI2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'K + ',(MKPL (K),MKPL2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'STR. BARYONS',(MHYP (K),MHYP2 (K),K=1,IOBSLV) WRITE(MONIOU,778)'DEUTERONS ',(MDEUT (K),MDEUT2(K),K=1,IOBSLV) WRITE(MONIOU,778)'TRITONS ',(MTRIT (K),MTRIT2(K),K=1,IOBSLV) WRITE(MONIOU,778)'ALPHAS ',(MALPHA(K),MALPH2(K),K=1,IOBSLV) WRITE(MONIOU,778)'OTHER PART. ',(MOTHER(K),MOTH2 (K),K=1,IOBSLV) WRITE(MONIOU,*) 778 FORMAT(' NO OF ',A12,' = ',3(F13.1,' +-',F13.1,' ')) IF ( NOBSLV .GT. 3 ) THEN IOBSLV = MIN( 6, NOBSLV ) WRITE(MONIOU,854) (K,K=4,IOBSLV) WRITE(MONIOU,855) (OBSLEV(K),K=4,IOBSLV) WRITE(MONIOU,778)'PROTONS ',(MPROTO(K),MPROT2(K),K=4,IOBSLV) WRITE(MONIOU,778)'ANTIPROTONS ',(MPROTB(K),MPRTB2(K),K=4,IOBSLV) WRITE(MONIOU,778)'NEUTRONS ',(MNEUTR(K),MNETR2(K),K=4,IOBSLV) WRITE(MONIOU,778)'ANTINEUTRONS',(MNEUTB(K),MNETB2(K),K=4,IOBSLV) WRITE(MONIOU,778)'PHOTONS ',(MPHOTO(K),MPHOT2(K),K=4,IOBSLV) WRITE(MONIOU,778)'ELECTRONS ',(MELECT(K),MELEC2(K),K=4,IOBSLV) WRITE(MONIOU,778)'POSITRONS ',(MPOSIT(K),MPOSI2(K),K=4,IOBSLV) WRITE(MONIOU,778)'NEUTRINOS ',(MNU (K),MNU2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'MU - ',(MMUM (K),MMUM2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'MU + ',(MMUP (K),MMUP2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'PI 0 ',(MPI0 (K),MPI02 (K),K=4,IOBSLV) WRITE(MONIOU,778)'PI - ',(MPIM (K),MPIM2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'PI + ',(MPIP (K),MPIP2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'K0L ',(MK0L (K),MK0L2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'K0S ',(MK0S (K),MK0S2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'K - ',(MKMI (K),MKMI2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'K + ',(MKPL (K),MKPL2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'STR. BARYONS',(MHYP (K),MHYP2 (K),K=4,IOBSLV) WRITE(MONIOU,778)'DEUTERONS ',(MDEUT (K),MDEUT2(K),K=4,IOBSLV) WRITE(MONIOU,778)'TRITONS ',(MTRIT (K),MTRIT2(K),K=4,IOBSLV) WRITE(MONIOU,778)'ALPHAS ',(MALPHA(K),MALPH2(K),K=4,IOBSLV) WRITE(MONIOU,778)'OTHER PART. ',(MOTHER(K),MOTH2 (K),K=4,IOBSLV) WRITE(MONIOU,*) IF ( NOBSLV .GT. 6 ) THEN IOBSLV = MIN( 9, NOBSLV ) WRITE(MONIOU,854) (K,K=7,IOBSLV) WRITE(MONIOU,855) (OBSLEV(K),K=7,IOBSLV) WRITE(MONIOU,778)'PROTONS ',(MPROTO(K),MPROT2(K),K=7,IOBSLV) WRITE(MONIOU,778)'ANTIPROTONS ',(MPROTB(K),MPRTB2(K),K=7,IOBSLV) WRITE(MONIOU,778)'NEUTRONS ',(MNEUTR(K),MNETR2(K),K=7,IOBSLV) WRITE(MONIOU,778)'ANTINEUTRONS',(MNEUTB(K),MNETB2(K),K=7,IOBSLV) WRITE(MONIOU,778)'PHOTONS ',(MPHOTO(K),MPHOT2(K),K=7,IOBSLV) WRITE(MONIOU,778)'ELECTRONS ',(MELECT(K),MELEC2(K),K=7,IOBSLV) WRITE(MONIOU,778)'POSITRONS ',(MPOSIT(K),MPOSI2(K),K=7,IOBSLV) WRITE(MONIOU,778)'NEUTRINOS ',(MNU (K),MNU2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'MU - ',(MMUM (K),MMUM2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'MU + ',(MMUP (K),MMUP2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'PI 0 ',(MPI0 (K),MPI02 (K),K=7,IOBSLV) WRITE(MONIOU,778)'PI - ',(MPIM (K),MPIM2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'PI + ',(MPIP (K),MPIP2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'K0L ',(MK0L (K),MK0L2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'K0S ',(MK0S (K),MK0S2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'K - ',(MKMI (K),MKMI2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'K + ',(MKPL (K),MKPL2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'STR. BARYONS',(MHYP (K),MHYP2 (K),K=7,IOBSLV) WRITE(MONIOU,778)'DEUTERONS ',(MDEUT (K),MDEUT2(K),K=7,IOBSLV) WRITE(MONIOU,778)'TRITONS ',(MTRIT (K),MTRIT2(K),K=7,IOBSLV) WRITE(MONIOU,778)'ALPHAS ',(MALPHA(K),MALPH2(K),K=7,IOBSLV) WRITE(MONIOU,778)'OTHER PART. ',(MOTHER(K),MOTH2 (K),K=7,IOBSLV) WRITE(MONIOU,*) IF ( NOBSLV .GT. 9 ) THEN IOBSLV = MIN( 10, NOBSLV ) WRITE(MONIOU,854) (K,K=9,IOBSLV) WRITE(MONIOU,855) (OBSLEV(K),K=9,IOBSLV) WRITE(MONIOU,778)'PROTONS ',(MPROTO(K),MPROT2(K),K=9,IOBSLV) WRITE(MONIOU,778)'ANTIPROTONS ',(MPROTB(K),MPRTB2(K),K=9,IOBSLV) WRITE(MONIOU,778)'NEUTRONS ',(MNEUTR(K),MNETR2(K),K=9,IOBSLV) WRITE(MONIOU,778)'ANTINEUTRONS',(MNEUTB(K),MNETB2(K),K=9,IOBSLV) WRITE(MONIOU,778)'PHOTONS ',(MPHOTO(K),MPHOT2(K),K=9,IOBSLV) WRITE(MONIOU,778)'ELECTRONS ',(MELECT(K),MELEC2(K),K=9,IOBSLV) WRITE(MONIOU,778)'POSITRONS ',(MPOSIT(K),MPOSI2(K),K=9,IOBSLV) WRITE(MONIOU,778)'NEUTRINOS ',(MNU (K),MNU2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'MU - ',(MMUM (K),MMUM2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'MU + ',(MMUP (K),MMUP2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'PI 0 ',(MPI0 (K),MPI02 (K),K=9,IOBSLV) WRITE(MONIOU,778)'PI - ',(MPIM (K),MPIM2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'PI + ',(MPIP (K),MPIP2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'K0L ',(MK0L (K),MK0L2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'K0S ',(MK0S (K),MK0S2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'K - ',(MKMI (K),MKMI2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'K + ',(MKPL (K),MKPL2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'STR. BARYONS',(MHYP (K),MHYP2 (K),K=9,IOBSLV) WRITE(MONIOU,778)'DEUTERONS ',(MDEUT (K),MDEUT2(K),K=9,IOBSLV) WRITE(MONIOU,778)'TRITONS ',(MTRIT (K),MTRIT2(K),K=9,IOBSLV) WRITE(MONIOU,778)'ALPHAS ',(MALPHA(K),MALPH2(K),K=9,IOBSLV) WRITE(MONIOU,778)'OTHER PART. ',(MOTHER(K),MOTH2 (K),K=9,IOBSLV) WRITE(MONIOU,*) ENDIF ENDIF ENDIF C PRINT OUT NKG RESULT FOR ALL SHOWERS IF SELECTED IF ( FNKG ) CALL MITAGE C CALCULATE MEAN VALUES AND SIGMAS OF LONGITUDINAL DISTRIBUTION IF ( LLONGI ) THEN IF ( ISHW .GT. 1 ) THEN DO 790 K = 1,9 DO 789 J = LPCT1,NSTEP SPLONG(J,K) = SQRT( abs(SPLONG(J,K)-APLONG(J,K)**2/ISHW) * /(ISHW-1) ) APLONG(J,K) = APLONG(J,K)/ISHW 789 CONTINUE 790 CONTINUE ELSE DO 990 K = 1,9 DO 989 J = LPCT1,NSTEP SPLONG(J,K) = 0.D0 989 CONTINUE 990 CONTINUE ENDIF C PRINT AVERAGE LONGITUDINAL DISTRIBUTIONS WRITE(MONIOU,911) THSTEP, * 'GAMMAS ','POSITRONS','ELECTRONS','MU- ','MU+ ', * (J*THSTEP,(APLONG(J,K),SPLONG(J,K),K=1,5),J=LPCT1,NSTEP) 911 FORMAT(/' AVERAGE LONGITUDINAL DISTRIBUTION IN STEPS OF ', * F5.0,' G/CM**2 '/' ',131('=')/ * ' DEPTH',8X,3(A10,16X),A9,15X,A9 // * (' ',F5.0,2X,1P,E11.4,'+-',E11.4,0P,1X,F12.0,'+-',F11.0, * 1X,F12.0,'+-',E11.4,1X,F11.1,'+-',F10.1, * 1X,F11.1,'+-',F10.1 )) WRITE(MONIOU,912) THSTEP, * 'HADRONS','CHARGED','NUCLEI','CERENKOV', * (J*THSTEP,(APLONG(J,K),SPLONG(J,K),K=6,9),J=LPCT1,NSTEP) 912 FORMAT(/' AVERAGE LONGITUDINAL DISTRIBUTION IN STEPS OF ', * F5.0,' G/CM**2 '/' ',115('=')/ * ' DEPTH',8X,A9,16X,A10,16X,A9,21X,A9 // * (' ',F5.0,1X,F11.1,'+-',F11.1,1X,F12.0,'+-',F12.0, * 2X,F10.1,'+-',F10.1,1X,1P,E16.6,'+-',E16.6,0P)) ENDIF IF ( FLGFIT ) THEN C PERFORM FIT TO THE LONGITUDINAL DISTRIBUTION OF ALL CHARGED PARTICLES C IF EGS IS SELECTED THIS IS THE DISTRIBUTION WHICH IS TO BE TAKEN IF ( FEGS ) THEN DO 730 J=0,NSTEP-LPCT1 DEP(J+1) = (J+LPCT1)*THSTEP CHAPAR(J+1) = APLONG(J+LPCT1,7) 730 CONTINUE NSTP = NSTEP + 1 - LPCT1 WRITE(MONIOU,8229) 'AVERAGE ALL CHARGED PARTICLES' C IF NKG IS SELECTED ONLY THE ELECTRON DISTRIBUTION IS AVAILABLE ELSEIF ( FNKG ) THEN DEP(1) = 0.D0 CHAPAR(1) = 0.D0 DO 731 J = 1,IALT(1) DEP(J+1) = TLEV(J) CHAPAR(J+1) = SEL(J)/ISHW 731 CONTINUE NSTP = IALT(1) + 1 WRITE(MONIOU,8229) 'AVERAGE NKG ELECTRONS' C IF NONE IS SELECTED IT DOES NOT REALLY MAKE SENSE TO FIT C BUT LET'S TAKE THEN ALL CHARGED WHICH ARE MUONS AND HADRONS ELSE DO 732 J=0,NSTEP-LPCT1 DEP(J+1) = (J+LPCT1)*THSTEP CHAPAR(J+1) = APLONG(J+LPCT1,7) 732 CONTINUE NSTP = NSTEP + 1 - LPCT1 WRITE(MONIOU,8229) 'AVERAGE MUONS AND CHARGED HADRONS' ENDIF IF ( NSTP .GT. 6 ) THEN C THERE ARE MORE THAN 6 STEP VALUES, A FIT SHOULD BE POSSIBLE. C DO THE FIT: NPAR AND FPARAM GIVE THE NUMBER OF PARAMETERS USED C AND THE FINAL VALUES FOR THE PARAMETERS. CHISQ GIVES THE CHI**2/DOF C FOR THE FIT. CALL LONGFT(FPARAM,CHI2) WRITE(MONIOU,8230) FPARAM,CHI2,CHI2/SQRT(FPARAM(1))*100.D0 ELSE WRITE(MONIOU,*) 'NO LONGI. FIT POSSIBLE, ', * ' NSTP = ',NSTP,' TOO SMALL.' ENDIF ENDIF C CONTROL PRINT OUTPUT OF CONSTANTS IF ( DEBUG ) THEN CALL STAEND WRITE(MDEBUG,*) 'MAIN : STAEND CALLED' ENDIF c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> call jcenddata(runh,rune) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> WRITE(MONIOU,*)' ' CALL PRTIME(TTIME) WRITE(MONIOU,101) 101 FORMAT (/' ',10('='),' END OF RUN ',67('=')) C CLOSE ALL OPEN UNITS IF ( MONIOU .NE. 6 ) CLOSE( MONIOU ) IF ( MDEBUG .NE. 6 ) CLOSE( MDEBUG ) CLOSE( EXST ) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> c CLOSE( PATAPE ) c IF ( LCERFI ) CLOSE( CETAPE ) c>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> STOP END