real function isagmbf(M0,MHF,A0,tanb,sgnmu,xcgv,MT,MODE,pno) C C Calculate supergravity spectra for ISAJET using as inputs C M0 = M_0 = common scalar mass at GUT scale C MHF = M_(1/2) = common gaugino mass at GUT scale C A0 = A_0 = trilinear soft breaking parameter at GUT scale C TANB = tan(beta) = ratio of vacuum expectation values v_1/v_2 C SGNMU = sgn(mu) = +-1 = sign of Higgsino mass term C MT = M_t = mass of t quark C M0 = Lambda = ratio of vevs / C MHF = M_Mes = messenger scale C A0 = n_5 = number of messenger fields C IMODEL = 1 for SUGRA model C = 2 for GMSB model C = 7 for AMSB model C C Uses Runge-Kutta method to integrate RGE's from M_Z to M_GUT C and back, putting in correct thresholds. For the first iteration C only the first 6 couplings are included and a common threshold C is used. C C See /SUGMG/ for definitions of couplings and masses. C IMPLICIT NONE COMMON/SSLUN/LOUT INTEGER LOUT SAVE /SSLUN/ C SUSY parameters C AMGLSS = gluino mass C AMULSS = up-left squark mass C AMELSS = left-selectron mass C AMERSS = right-slepton mass C AMNiSS = sneutrino mass for generation i C TWOM1 = Higgsino mass = - mu C RV2V1 = ratio v2/v1 of vev's C AMTLSS,AMTRSS = left,right stop masses C AMT1SS,AMT2SS = light,heavy stop masses C AMBLSS,AMBRSS = left,right sbottom masses C AMB1SS,AMB2SS = light,heavy sbottom masses C AMLLSS,AMLRSS = left,right stau masses C AML1SS,AML2SS = light,heavy stau masses C AMZiSS = signed mass of Zi C ZMIXSS = Zi mixing matrix C AMWiSS = signed Wi mass C GAMMAL,GAMMAR = Wi left, right mixing angles C AMHL,AMHH,AMHA = neutral Higgs h0, H0, A0 masses C AMHC = charged Higgs H+ mass C ALFAH = Higgs mixing angle C AAT = stop trilinear term C THETAT = stop mixing angle C AAB = sbottom trilinear term C THETAB = sbottom mixing angle C AAL = stau trilinear term C THETAL = stau mixing angle C AMGVSS = gravitino mass COMMON/SSPAR/AMGLSS,AMULSS,AMURSS,AMDLSS,AMDRSS,AMSLSS $,AMSRSS,AMCLSS,AMCRSS,AMBLSS,AMBRSS,AMB1SS,AMB2SS $,AMTLSS,AMTRSS,AMT1SS,AMT2SS,AMELSS,AMERSS,AMMLSS,AMMRSS $,AMLLSS,AMLRSS,AML1SS,AML2SS,AMN1SS,AMN2SS,AMN3SS $,TWOM1,RV2V1,AMZ1SS,AMZ2SS,AMZ3SS,AMZ4SS,ZMIXSS(4,4) $,AMW1SS,AMW2SS $,GAMMAL,GAMMAR,AMHL,AMHH,AMHA,AMHC,ALFAH,AAT,THETAT $,AAB,THETAB,AAL,THETAL,AMGVSS,MTQ,MBQ,MLQ,FBMA, $VUQ,VDQ REAL AMGLSS,AMULSS,AMURSS,AMDLSS,AMDRSS,AMSLSS $,AMSRSS,AMCLSS,AMCRSS,AMBLSS,AMBRSS,AMB1SS,AMB2SS $,AMTLSS,AMTRSS,AMT1SS,AMT2SS,AMELSS,AMERSS,AMMLSS,AMMRSS $,AMLLSS,AMLRSS,AML1SS,AML2SS,AMN1SS,AMN2SS,AMN3SS $,TWOM1,RV2V1,AMZ1SS,AMZ2SS,AMZ3SS,AMZ4SS,ZMIXSS $,AMW1SS,AMW2SS $,GAMMAL,GAMMAR,AMHL,AMHH,AMHA,AMHC,ALFAH,AAT,THETAT $,AAB,THETAB,AAL,THETAL,AMGVSS,MTQ,MBQ,MLQ,FBMA,VUQ,VDQ REAL AMZISS(4) EQUIVALENCE (AMZISS(1),AMZ1SS) SAVE /SSPAR/ C Standard model parameters C AMUP,...,AMTP = quark masses C AME,AMMU,AMTAU = lepton masses C AMW,AMZ = W,Z masses C GAMW,GAMZ = W,Z widths C ALFAEM,SN2THW,ALFA3 = SM couplings C ALQCD4 = 4 flavor lambda COMMON/SSSM/AMUP,AMDN,AMST,AMCH,AMBT,AMTP,AME,AMMU,AMTAU $,AMW,AMZ,GAMW,GAMZ,ALFAEM,SN2THW,ALFA2,ALFA3,ALQCD4 REAL AMUP,AMDN,AMST,AMCH,AMBT,AMTP,AME,AMMU,AMTAU $,AMW,AMZ,GAMW,GAMZ,ALFAEM,SN2THW,ALFA2,ALFA3,ALQCD4 SAVE /SSSM/ C XSUGIN contains the inputs to SUGRA: C XSUGIN(1) = M_0 XSUGIN(2) = M_(1/2) XSUGIN(3) = A_0 C XSUGIN(4) = tan(beta) XSUGIN(5) = sgn(mu) XSUGIN(6) = M_t C XSUGIN(7) = SUG BC scale C XGMIN(1) = LAM XGMIN(2) = M_MES XGMIN(3) = XN5 C XGMIN(4) = tan(beta) XGMIN(5) = sgn(mu) XGMIN(6) = M_t C XGMIN(7) = CGRAV XGMIN(8) =RSL XGMIN(9) = DEL_HD C XGMIN(10) = DEL_HU XGMIN(11) = DY XGMIN(12) = N5_1 C XGMIN(13) = N5_2 XGMIN(14) = N5_3 C XNRIN(1) = M_N3 XNRIN(2) = M_MAJ XNRIN(3) = ANSS C XNRIN(4) = M_N3SS C XISAIN contains the MSSMi inputs in natural order. COMMON /SUGXIN/ XISAIN(24),XSUGIN(7),XGMIN(14),XNRIN(4) REAL XISAIN,XSUGIN,XGMIN,XNRIN SAVE /SUGXIN/ C Frozen couplings from RG equations: C GSS( 1) = g_1 GSS( 2) = g_2 GSS( 3) = g_3 C GSS( 4) = y_tau GSS( 5) = y_b GSS( 6) = y_t C GSS( 7) = M_1 GSS( 8) = M_2 GSS( 9) = M_3 C GSS(10) = A_tau GSS(11) = A_b GSS(12) = A_t C GSS(13) = M_h1^2 GSS(14) = M_h2^2 GSS(15) = M_er^2 C GSS(16) = M_el^2 GSS(17) = M_dnr^2 GSS(18) = M_upr^2 C GSS(19) = M_upl^2 GSS(20) = M_taur^2 GSS(21) = M_taul^2 C GSS(22) = M_btr^2 GSS(23) = M_tpr^2 GSS(24) = M_tpl^2 C GSS(25) = mu GSS(26) = B GSS(27) = Y_N C GSS(28) = M_nr GSS(29) = A_n C Masses: C MSS( 1) = glss MSS( 2) = upl MSS( 3) = upr C MSS( 4) = dnl MSS( 5) = dnr MSS( 6) = stl C MSS( 7) = str MSS( 8) = chl MSS( 9) = chr C MSS(10) = b1 MSS(11) = b2 MSS(12) = t1 C MSS(13) = t2 MSS(14) = nuel MSS(15) = numl C MSS(16) = nutl MSS(17) = el- MSS(18) = er- C MSS(19) = mul- MSS(20) = mur- MSS(21) = tau1 C MSS(22) = tau2 MSS(23) = z1ss MSS(24) = z2ss C MSS(25) = z3ss MSS(26) = z4ss MSS(27) = w1ss C MSS(28) = w2ss MSS(29) = hl0 MSS(30) = hh0 C MSS(31) = ha0 MSS(32) = h+ C Unification: C MGUTSS = M_GUT GGUTSS = g_GUT AGUTSS = alpha_GUT COMMON /SUGMG/ MSS(32),GSS(29),MGUTSS,GGUTSS,AGUTSS,FTGUT, $FBGUT,FTAGUT,FNGUT REAL MSS,GSS,MGUTSS,GGUTSS,AGUTSS,FTGUT,FBGUT,FTAGUT,FNGUT SAVE /SUGMG/ COMMON /SUGPAS/ XTANB,MSUSY,AMT,MGUT,MU,G2,GP,V,VP,XW, $A1MZ,A2MZ,ASMZ,FTAMZ,FBMZ,B,SIN2B,FTMT,G3MT,VEV,HIGFRZ, $FNMZ,AMNRMJ,NOGOOD,IAL3UN,ITACHY,MHPNEG,ASM3, $VUMT,VDMT,ASMTP,ASMSS,M3Q REAL XTANB,MSUSY,AMT,MGUT,MU,G2,GP,V,VP,XW, $A1MZ,A2MZ,ASMZ,FTAMZ,FBMZ,B,SIN2B,FTMT,G3MT,VEV,HIGFRZ, $FNMZ,AMNRMJ,ASM3,VUMT,VDMT,ASMTP,ASMSS,M3Q INTEGER NOGOOD,IAL3UN,ITACHY,MHPNEG SAVE /SUGPAS/ C XNUSUG contains non-universal GUT scale soft terms for SUGRA: C XNUSUG(1)=M1 XNUSUG(2)=M2 XNUSUG(3)=M3 C XNUSUG(4)=A_tau XNUSUG(5)=A_b XNUSUG(6)=A_t C XNUSUG(7)=m_Hd XNUSUG(8)=m_Hu XNUSUG(9)=m_eR XNUSUG(10)=m_eL C XNUSUG(11)=m_dR XNUSUG(12)=m_uR XNUSUG(13)=m_uL XNUSUG(14)=m_lR C XNUSUG(15)=m_lL XNUSUG(16)=m_bR XNUSUG(17)=m_tR XNUSUG(18)=m_tL C COMMON /SUGNU/ XNUSUG(18) REAL XNUSUG SAVE /SUGNU/ COMMON/SSINF/XLAM DOUBLE PRECISION XLAM C REAL GY(7),W1(21),G(29),W2(87) C REAL G0(29) C COMPLEX*16 SSB0,SSB1 C DOUBLE PRECISION DDILOG,XLM C INTEGER IG(29) EXTERNAL SURG06,SURG26 REAL M0,MHF,A0,TANB,SGNMU,MT C REAL M0,MHF,A0,TANB,SGNMU,MT,XLAMGM,XMESGM,XN5GM C INTEGER NSTEP C REAL M2,SUALFE,SUALFS,Q,T,A1I,AGUT,A3I,A2I,MTMT,ASMT,DT, C $TGUT,TZ,GGUT,SIG2,SIG1,MH1S,MH2S,AGUTI, C $MUS,MBMZ,MB,MTAU,MZ,MW,SR2,PI,ALEM,MTAMZ, C $MTAMB,MTAMTA,MBMB,ASMB,BETA,COTB,SINB,COS2B,COSB,XC, C $MSN,MG,MT1,MT2,MB1,MB2,MW1,MW2,AMU,BTHAT,BBHAT,BLHAT,AM2 INTEGER I,IMODEL C REAL G0SAVE(26),DELG0,DELLIM,THRF,THRG,DY,QOLD C INTEGER MXITER,NSTEP0 C COMPLEX*16 ZZZ C REAL*8 REAL8 REAL xcgv REAL M0s,MHFs,A0s,TANBs,SGNMUs,xcgvs,MTs common /isasusav/ M0s,MHFs,A0s,TANBs,SGNMUs, xcgvs, MTs, MODEs INTEGER pno,MODEs integer MODE ial3un=0 do 1 i=1,18 xnusug(i)=1.e20 1 continue xnrin(2)=1.e20 IMODEL=2 XGMIN(7)=XCGV if(m0.ne.m0s.or.mhf.ne.mhfs.or.a0.ne.a0s & .or.tanb.ne.tanbs.or.sgnmu.ne.sgnmus & .or.mt.ne.mts.or.mode.ne.modes & .or.xcgvs.ne.xcgv) then m0s=m0 mhfs=mhf a0s=a0 tanbs=tanb sgnmus=sgnmu mts=mt xcgvs=xcgv modes=mode XGMIN(7)=XCGV XGMIN(8)=1. call sugra(M0,MHF,A0,TANB,SGNMU,MT,IMODEL) IF (NOGOOD.EQ.1) THEN WRITE(*,*) 'BAD POINT: TACHYONIC PARTICLES!' ELSE IF (NOGOOD.EQ.2) THEN WRITE(*,*) 'BAD POINT: NO EW SYMMETRY BREAKING!' ELSE IF (NOGOOD.EQ.3) THEN WRITE(*,*) 'BAD POINT: M(H_P)^2<0!' ELSE IF (NOGOOD.EQ.4) THEN WRITE(*,*) 'BAD POINT: YUKAWA>100!' ELSE IF (NOGOOD.EQ.5.AND.IMODEL.EQ.1) THEN WRITE(*,*) 'SUGRA BAD POINT: Z1SS NOT LSP!' ELSE IF (NOGOOD.EQ.7) THEN WRITE(*,*) 'BAD POINT: XT EWSB BAD!' ELSE IF (NOGOOD.EQ.8) THEN WRITE(*,*) 'BAD POINT: MHL^2<0!' END IF if(nogood.ne.0) then write(*,*) '!!! SUGRA/ISASUSY bad point !!!!' do 2 i=1,24 xisain(i)=0.0 isagmbf=0.0 2 continue return endif write(*,*) 'Mglu= ',xisain(1), & ' Mmg1= ',xisain(23), & ' Mmg2= ',xisain(24) write(*,*) 'xmu = ',xisain(2), & ' Mha = ',xisain(3), & ' tb= ',xisain(4) write(*,*) 'Mmq1= ',xisain(5), & ' Mmdr= ',xisain(6), & ' Mmur= ',xisain(7) write(*,*) 'Mmq2= ',xisain(10), & ' Mmsr= ',xisain(11), & ' Mmcr= ',xisain(12) write(*,*) 'Mmq3= ',xisain(15), & ' Mmbr= ',xisain(16), & ' Mmtr= ',xisain(17) write(*,*) 'Mml1= ',xisain(8), & ' Mml2= ',xisain(13), & ' Mml3= ',xisain(18) write(*,*) 'Mmer= ',xisain(9), & ' Mmmr= ',xisain(14), & ' Mmlr= ',xisain(19) write(*,*) 'Mxat= ',xisain(20), & ' Mxab= ',xisain(21), & ' Mxal= ',xisain(22) endif isagmbf=xisain(pno) return end