C********************************************************************* SUBROUTINE LUEEVT(KFL,ECM) C...Purpose: to handle the generation of an e+e- annihilation jet event. IMPLICIT DOUBLE PRECISION(D) COMMON/LUJETS/N,K(4000,5),P(4000,5),V(4000,5) COMMON/LUDAT1/MSTU(200),PARU(200),MSTJ(200),PARJ(200) COMMON/LUDAT2/KCHG(500,3),PMAS(500,4),PARF(2000),VCKM(4,4) SAVE /LUJETS/,/LUDAT1/,/LUDAT2/ C...Check input parameters. IF(MSTU(12).GE.1) CALL LULIST(0) IF(KFL.LT.0.OR.KFL.GT.8) THEN CALL LUERRM(16,'(LUEEVT:) called with unknown flavour code') IF(MSTU(21).GE.1) RETURN ENDIF IF(KFL.LE.5) ECMMIN=PARJ(127)+2.02*PARF(100+MAX(1,KFL)) IF(KFL.GE.6) ECMMIN=PARJ(127)+2.02*PMAS(KFL,1) IF(ECM.LT.ECMMIN) THEN CALL LUERRM(16,'(LUEEVT:) called with too small CM energy') IF(MSTU(21).GE.1) RETURN ENDIF C...Check consistency of MSTJ options set. IF(MSTJ(109).EQ.2.AND.MSTJ(110).NE.1) THEN CALL LUERRM(6, & '(LUEEVT:) MSTJ(109) value requires MSTJ(110) = 1') MSTJ(110)=1 ENDIF IF(MSTJ(109).EQ.2.AND.MSTJ(111).NE.0) THEN CALL LUERRM(6, & '(LUEEVT:) MSTJ(109) value requires MSTJ(111) = 0') MSTJ(111)=0 ENDIF C...Initialize alpha_strong and total cross-section. MSTU(111)=MSTJ(108) IF(MSTJ(108).EQ.2.AND.(MSTJ(101).EQ.0.OR.MSTJ(101).EQ.1)) &MSTU(111)=1 PARU(112)=PARJ(121) IF(MSTU(111).EQ.2) PARU(112)=PARJ(122) IF(MSTJ(116).GT.0.AND.(MSTJ(116).GE.2.OR.ABS(ECM-PARJ(151)).GE. &PARJ(139).OR.10*MSTJ(102)+KFL.NE.MSTJ(119))) CALL LUXTOT(KFL,ECM, &XTOT) IF(MSTJ(116).GE.3) MSTJ(116)=1 PARJ(171)=0. C...Add initial e+e- to event record (documentation only). NTRY=0 100 NTRY=NTRY+1 IF(NTRY.GT.100) THEN CALL LUERRM(14,'(LUEEVT:) caught in an infinite loop') RETURN ENDIF MSTU(24)=0 NC=0 IF(MSTJ(115).GE.2) THEN NC=NC+2 CALL LU1ENT(NC-1,11,0.5*ECM,0.,0.) K(NC-1,1)=21 CALL LU1ENT(NC,-11,0.5*ECM,PARU(1),0.) K(NC,1)=21 ENDIF C...Radiative photon (in initial state). MK=0 ECMC=ECM IF(MSTJ(107).GE.1.AND.MSTJ(116).GE.1) CALL LURADK(ECM,MK,PAK, &THEK,PHIK,ALPK) IF(MK.EQ.1) ECMC=SQRT(ECM*(ECM-2.*PAK)) IF(MSTJ(115).GE.1.AND.MK.EQ.1) THEN NC=NC+1 CALL LU1ENT(NC,22,PAK,THEK,PHIK) K(NC,3)=MIN(MSTJ(115)/2,1) ENDIF C...Virtual exchange boson (gamma or Z0). IF(MSTJ(115).GE.3) THEN NC=NC+1 KF=22 IF(MSTJ(102).EQ.2) KF=23 MSTU10=MSTU(10) MSTU(10)=1 P(NC,5)=ECMC CALL LU1ENT(NC,KF,ECMC,0.,0.) K(NC,1)=21 K(NC,3)=1 MSTU(10)=MSTU10 ENDIF C...Choice of flavour and jet configuration. CALL LUXKFL(KFL,ECM,ECMC,KFLC) IF(KFLC.EQ.0) GOTO 100 CALL LUXJET(ECMC,NJET,CUT) KFLN=21 IF(NJET.EQ.4) CALL LUX4JT(NJET,CUT,KFLC,ECMC,KFLN,X1,X2,X4, &X12,X14) IF(NJET.EQ.3) CALL LUX3JT(NJET,CUT,KFLC,ECMC,X1,X3) IF(NJET.EQ.2) MSTJ(120)=1 C...Fill jet configuration and origin. IF(NJET.EQ.2.AND.MSTJ(101).NE.5) CALL LU2ENT(NC+1,KFLC,-KFLC,ECMC) IF(NJET.EQ.2.AND.MSTJ(101).EQ.5) CALL LU2ENT(-(NC+1),KFLC,-KFLC, &ECMC) IF(NJET.EQ.3) CALL LU3ENT(NC+1,KFLC,21,-KFLC,ECMC,X1,X3) IF(NJET.EQ.4.AND.KFLN.EQ.21) CALL LU4ENT(NC+1,KFLC,KFLN,KFLN, &-KFLC,ECMC,X1,X2,X4,X12,X14) IF(NJET.EQ.4.AND.KFLN.NE.21) CALL LU4ENT(NC+1,KFLC,-KFLN,KFLN, &-KFLC,ECMC,X1,X2,X4,X12,X14) IF(MSTU(24).NE.0) GOTO 100 DO 110 IP=NC+1,N K(IP,3)=K(IP,3)+MIN(MSTJ(115)/2,1)+(MSTJ(115)/3)*(NC-1) 110 CONTINUE C...Angular orientation according to matrix element. IF(MSTJ(106).EQ.1) THEN CALL LUXDIF(NC,NJET,KFLC,ECMC,CHI,THE,PHI) CALL LUDBRB(NC+1,N,0.,CHI,0D0,0D0,0D0) CALL LUDBRB(NC+1,N,THE,PHI,0D0,0D0,0D0) ENDIF C...Rotation and boost from radiative photon. IF(MK.EQ.1) THEN DBEK=-PAK/(ECM-PAK) NMIN=NC+1-MSTJ(115)/3 CALL LUDBRB(NMIN,N,0.,-PHIK,0D0,0D0,0D0) CALL LUDBRB(NMIN,N,ALPK,0.,DBEK*SIN(THEK),0D0,DBEK*COS(THEK)) CALL LUDBRB(NMIN,N,0.,PHIK,0D0,0D0,0D0) ENDIF C...Generate parton shower. Rearrange along strings and check. IF(MSTJ(101).EQ.5) THEN CALL LUSHOW(N-1,N,ECMC) MSTJ14=MSTJ(14) IF(MSTJ(105).EQ.-1) MSTJ(14)=-1 IF(MSTJ(105).GE.0) MSTU(28)=0 CALL LUPREP(0) MSTJ(14)=MSTJ14 IF(MSTJ(105).GE.0.AND.MSTU(28).NE.0) GOTO 100 ENDIF C...Fragmentation/decay generation. Information for LUTABU. IF(MSTJ(105).EQ.1) CALL LUEXEC MSTU(161)=KFLC MSTU(162)=-KFLC RETURN END