source: LMDZ5/branches/testing/libf/phylmd/convect2.F90 @ 3069

! $Id: convect2.F90 2408 2015-12-14 10:43:09Z dcugnet $

SUBROUTINE convect2(ncum, idcum, len, nd, ndp1, nl, minorig, nk1, icb1, t1, &
    q1, qs1, u1, v1, gz1, tv1, tp1, tvp1, clw1, h1, lv1, cpn1, p1, ph1, ft1, &
    fq1, fu1, fv1, tnk1, qnk1, gznk1, plcl1, precip1, cbmf1, iflag1, delt, &
    cpd, cpv, cl, rv, rd, lv0, g, sigs, sigd, elcrit, tlcrit, omtsnow, dtmax, &
    damp, alpha, entp, coeffs, coeffr, omtrain, cu, ma)
  ! .............................START PROLOGUE............................

  ! SCCS IDENTIFICATION:  @(#)convect2.f        1.2 05/18/00
  ! 22:06:22 /h/cm/library/nogaps4/src/sub/fcst/convect2.f_v

  ! CONFIGURATION IDENTIFICATION:  None

  ! MODULE NAME:  convect2

  ! DESCRIPTION:

  ! convect1     The Emanuel Cumulus Convection Scheme - compute tendencies

  ! CONTRACT NUMBER AND TITLE:  None

  ! REFERENCES: Programmers  K. Emanuel (MIT), Timothy F. Hogan, M. Peng
  ! (NRL)

  ! CLASSIFICATION:  Unclassified

  ! RESTRICTIONS: None

  ! COMPILER DEPENDENCIES: FORTRAN 77, FORTRAN 90

  ! COMPILE OPTIONS: Fortran 77: -Zu -Wf"-ei -o aggress"
  ! Fortran 90: -O vector3,scalar3,task1,aggress,overindex  -ei -r 2

  ! LIBRARIES OF RESIDENCE: /a/ops/lib/libfcst159.a

  ! USAGE: call convect2(ncum,idcum,len,nd,nl,minorig,
  ! &                 nk1,icb1,
  ! &                 t1,q1,qs1,u1,v1,gz1,tv1,tp1,tvp1,clw1,h1,
  ! &                 lv1,cpn1,p1,ph1,ft1,fq1,fu1,fv1,
  ! &                 tnk1,qnk1,gznk1,plcl1,
  ! &                 precip1,cbmf1,iflag1,
  ! &                 delt,cpd,cpv,cl,rv,rd,lv0,g,
  ! &                 sigs,sigd,elcrit,tlcrit,omtsnow,dtmax,damp,
  ! &                 alpha,entp,coeffs,coeffr,omtrain,cu)

  ! PARAMETERS:
  ! Name            Type         Usage            Description
  ! ----------      ----------     -------  ----------------------------

  ! ncum          Integer        Input        number of cumulus points
  ! idcum         Integer        Input        index of cumulus point
  ! len           Integer        Input        first dimension
  ! nd            Integer        Input        total vertical dimension
  ! ndp1          Integer        Input        nd + 1
  ! nl            Integer        Input        vertical dimension for
  ! convection
  ! minorig       Integer        Input        First level where convection is
  ! allow to begin
  ! nk1           Integer        Input        First level of convection
  ! ncb1          Integer        Input        Level of free convection
  ! t1            Real           Input        temperature
  ! q1            Real           Input        specific hum
  ! qs1           Real           Input        sat specific hum
  ! u1            Real           Input        u-wind
  ! v1            Real           Input        v-wind
  ! gz1           Real           Inout        geop
  ! tv1           Real           Input        virtual temp
  ! tp1           Real           Input
  ! clw1          Real           Inout        cloud liquid water
  ! h1            Real           Inout
  ! lv1           Real           Inout
  ! cpn1          Real           Inout
  ! p1            Real           Input        full level pressure
  ! ph1           Real           Input        half level pressure
  ! ft1           Real           Output       temp tend
  ! fq1           Real           Output       spec hum tend
  ! fu1           Real           Output       u-wind tend
  ! fv1           Real           Output       v-wind tend
  ! precip1       Real           Output       prec
  ! cbmf1         Real           In/Out       cumulus mass flux
  ! iflag1        Integer        Output       iflag on latitude strip
  ! delt          Real           Input        time step
  ! cpd           Integer        Input        See description below
  ! cpv           Integer        Input        See description below
  ! cl            Integer        Input        See description below
  ! rv            Integer        Input        See description below
  ! rd            Integer        Input        See description below
  ! lv0           Integer        Input        See description below
  ! g             Integer        Input        See description below
  ! sigs          Integer        Input        See description below
  ! sigd          Integer        Input        See description below
  ! elcrit        Integer        Input        See description below
  ! tlcrit        Integer        Input        See description below
  ! omtsnow       Integer        Input        See description below
  ! dtmax         Integer        Input        See description below
  ! damp          Integer        Input        See description below
  ! alpha         Integer        Input        See description below
  ! ent           Integer        Input        See description below
  ! coeffs        Integer        Input        See description below
  ! coeffr        Integer        Input        See description below
  ! omtrain       Integer        Input        See description below
  ! cu            Integer        Input        See description below

  ! COMMON BLOCKS:
  ! Block      Name     Type    Usage              Notes
  ! --------  --------   ----    ------   ------------------------

  ! FILES: None

  ! DATA BASES: None

  ! NON-FILE INPUT/OUTPUT: None

  ! ERROR CONDITIONS: None

  ! ADDITIONAL COMMENTS: None

  ! .................MAINTENANCE SECTION................................

  ! MODULES CALLED:
  ! Name           Description
  ! zilch        Zero out an array
  ! -------     ----------------------
  ! LOCAL VARIABLES AND
  ! STRUCTURES:
  ! Name     Type    Description
  ! -------  ------  -----------
  ! See Comments Below

  ! i        Integer loop index
  ! k        Integer loop index

  ! METHOD:

  ! See Emanuel, K. and M. Zivkovic-Rothman, 2000: Development and evaluation
  ! of a
  ! convective scheme for use in climate models.

  ! FILES: None

  ! INCLUDE FILES: None

  ! MAKEFILE: /a/ops/met/nogaps/src/sub/fcst/fcst159lib.mak

  ! ..............................END PROLOGUE.............................


  USE dimphy
  IMPLICIT NONE

  INTEGER kmax2, imax2, kmin2, imin2
  REAL ftmax2, ftmin2
  INTEGER kmax, imax, kmin, imin
  REAL ftmax, ftmin

  INTEGER ncum
  INTEGER len
  INTEGER idcum(len)
  INTEGER nd
  INTEGER ndp1
  INTEGER nl
  INTEGER minorig
  INTEGER nk1(len)
  INTEGER icb1(len)
  REAL t1(len, nd)
  REAL q1(len, nd)
  REAL qs1(len, nd)
  REAL u1(len, nd)
  REAL v1(len, nd)
  REAL gz1(len, nd)
  REAL tv1(len, nd)
  REAL tp1(len, nd)
  REAL tvp1(len, nd)
  REAL clw1(len, nd)
  REAL h1(len, nd)
  REAL lv1(len, nd)
  REAL cpn1(len, nd)
  REAL p1(len, nd)
  REAL ph1(len, ndp1)
  REAL ft1(len, nd)
  REAL fq1(len, nd)
  REAL fu1(len, nd)
  REAL fv1(len, nd)
  REAL tnk1(len)
  REAL qnk1(len)
  REAL gznk1(len)
  REAL precip1(len)
  REAL cbmf1(len)
  REAL plcl1(len)
  INTEGER iflag1(len)
  REAL delt
  REAL cpd
  REAL cpv
  REAL cl
  REAL rv
  REAL rd
  REAL lv0
  REAL g
  REAL sigs ! SIGS IS THE FRACTION OF PRECIPITATION FALLING OUTSIDE
  REAL sigd ! SIGD IS THE FRACTIONAL AREA COVERED BY UNSATURATED DNDRAFT
  REAL elcrit ! ELCRIT IS THE AUTOCONVERSION THERSHOLD WATER CONTENT (gm/gm)
  REAL tlcrit ! TLCRIT IS CRITICAL TEMPERATURE BELOW WHICH THE AUTO-
  ! CONVERSION THRESHOLD IS ASSUMED TO BE ZERO
  REAL omtsnow ! OMTSNOW IS THE ASSUMED FALL SPEED (P/s) OF SNOW
  REAL dtmax ! DTMAX IS THE MAXIMUM NEGATIVE TEMPERATURE PERTURBATION
  ! A LIFTED PARCEL IS ALLOWED TO HAVE BELOW ITS LFC.
  REAL damp
  REAL alpha
  REAL entp ! ENTP IS THE COEFFICIENT OF MIXING IN THE ENTRAINMENT FORMULATION
  REAL coeffs ! COEFFS IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION OF
  ! SNOW
  REAL coeffr ! COEFFR IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION OF
  ! RAIN
  REAL omtrain ! OMTRAIN IS THE ASSUMED FALL SPEED (P/s) OF RAIN
  REAL cu ! CU IS THE COEFFICIENT GOVERNING CONVECTIVE MOMENTUM TRANSPORT

  REAL ma(len, nd)


  ! *** ELCRIT IS THE AUTOCONVERSION THERSHOLD WATER CONTENT (gm/gm) ***
  ! ***  TLCRIT IS CRITICAL TEMPERATURE BELOW WHICH THE AUTO-        ***
  ! ***       CONVERSION THRESHOLD IS ASSUMED TO BE ZERO             ***
  ! ***     (THE AUTOCONVERSION THRESHOLD VARIES LINEARLY            ***
  ! ***               BETWEEN 0 C AND TLCRIT)                        ***
  ! ***   ENTP IS THE COEFFICIENT OF MIXING IN THE ENTRAINMENT       ***
  ! ***                       FORMULATION                            ***
  ! ***  SIGD IS THE FRACTIONAL AREA COVERED BY UNSATURATED DNDRAFT  ***
  ! ***  SIGS IS THE FRACTION OF PRECIPITATION FALLING OUTSIDE       ***
  ! ***                        OF CLOUD                              ***
  ! ***        OMTRAIN IS THE ASSUMED FALL SPEED (P/s) OF RAIN       ***
  ! ***     OMTSNOW IS THE ASSUMED FALL SPEED (P/s) OF SNOW          ***
  ! ***  COEFFR IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION   ***
  ! ***                          OF RAIN                             ***
  ! ***  COEFFS IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION   ***
  ! ***                          OF SNOW                             ***
  ! ***     CU IS THE COEFFICIENT GOVERNING CONVECTIVE MOMENTUM      ***
  ! ***                         TRANSPORT                            ***
  ! ***    DTMAX IS THE MAXIMUM NEGATIVE TEMPERATURE PERTURBATION    ***
  ! ***        A LIFTED PARCEL IS ALLOWED TO HAVE BELOW ITS LFC      ***
  ! ***    ALPHA AND DAMP ARE PARAMETERS THAT CONTROL THE RATE OF    ***
  ! ***                 APPROACH TO QUASI-EQUILIBRIUM                ***
  ! ***   (THEIR STANDARD VALUES ARE  0.20 AND 0.1, RESPECTIVELY)    ***
  ! ***                   (DAMP MUST BE LESS THAN 1)                 ***

  ! Local arrays.

  REAL work(ncum)
  REAL t(ncum, klev)
  REAL q(ncum, klev)
  REAL qs(ncum, klev)
  REAL u(ncum, klev)
  REAL v(ncum, klev)
  REAL gz(ncum, klev)
  REAL h(ncum, klev)
  REAL lv(ncum, klev)
  REAL cpn(ncum, klev)
  REAL p(ncum, klev)
  REAL ph(ncum, klev)
  REAL ft(ncum, klev)
  REAL fq(ncum, klev)
  REAL fu(ncum, klev)
  REAL fv(ncum, klev)
  REAL precip(ncum)
  REAL cbmf(ncum)
  REAL plcl(ncum)
  REAL tnk(ncum)
  REAL qnk(ncum)
  REAL gznk(ncum)
  REAL tv(ncum, klev)
  REAL tp(ncum, klev)
  REAL tvp(ncum, klev)
  REAL clw(ncum, klev)
  ! real det(ncum,klev)
  REAL dph(ncum, klev)
  ! real wd(ncum)
  ! real tprime(ncum)
  ! real qprime(ncum)
  REAL ah0(ncum)
  REAL ep(ncum, klev)
  REAL sigp(ncum, klev)
  INTEGER nent(ncum, klev)
  REAL water(ncum, klev)
  REAL evap(ncum, klev)
  REAL mp(ncum, klev)
  REAL m(ncum, klev)
  REAL qti
  REAL wt(ncum, klev)
  REAL hp(ncum, klev)
  REAL lvcp(ncum, klev)
  REAL elij(ncum, klev, klev)
  REAL ment(ncum, klev, klev)
  REAL sij(ncum, klev, klev)
  REAL qent(ncum, klev, klev)
  REAL uent(ncum, klev, klev)
  REAL vent(ncum, klev, klev)
  REAL qp(ncum, klev)
  REAL up(ncum, klev)
  REAL vp(ncum, klev)
  REAL cape(ncum)
  REAL capem(ncum)
  REAL frac(ncum)
  REAL dtpbl(ncum)
  REAL tvpplcl(ncum)
  REAL tvaplcl(ncum)
  REAL dtmin(ncum)
  REAL w3d(ncum, klev)
  REAL am(ncum)
  REAL ents(ncum)
  REAL uav(ncum)
  REAL vav(ncum)

  INTEGER iflag(ncum)
  INTEGER nk(ncum)
  INTEGER icb(ncum)
  INTEGER inb(ncum)
  INTEGER inb1(ncum)
  INTEGER jtt(ncum)

  INTEGER nn, i, k, n, icbmax, nlp, j
  INTEGER ij
  INTEGER nn2, nn3
  REAL clmcpv
  REAL clmcpd
  REAL cpdmcp
  REAL cpvmcpd
  REAL eps
  REAL epsi
  REAL epsim1
  REAL tg, qg, s, alv, tc, ahg, denom, es, rg, ginv, rowl
  REAL delti
  REAL tca, elacrit
  REAL by, defrac
  ! real byp
  REAL byp(ncum)
  LOGICAL lcape(ncum)
  REAL dbo
  REAL bf2, anum, dei, altem, cwat, stemp
  REAL alt, qp1, smid, sjmax, sjmin
  REAL delp, delm
  REAL awat, coeff, afac, revap, dhdp, fac, qstm, rat
  REAL qsm, sigt, b6, c6
  REAL dpinv, cpinv
  REAL fqold, ftold, fuold, fvold
  REAL wdtrain(ncum), xxx
  REAL bsum(ncum, klev)
  REAL asij(ncum)
  REAL smin(ncum)
  REAL scrit(ncum)
  ! real amp1,ad
  REAL amp1(ncum), ad(ncum)
  LOGICAL lwork(ncum)
  INTEGER num1, num2

  ! print*,'cpd en entree de convect2 ',cpd
  nlp = nl + 1

  rowl = 1000.0
  ginv = 1.0/g
  delti = 1.0/delt

  ! Define some thermodynamic variables.

  clmcpv = cl - cpv
  clmcpd = cl - cpd
  cpdmcp = cpd - cpv
  cpvmcpd = cpv - cpd
  eps = rd/rv
  epsi = 1.0/eps
  epsim1 = epsi - 1.0

  ! Compress the fields.

  DO k = 1, nl + 1
    nn = 0
    DO i = 1, len
      IF (iflag1(i)==0) THEN
        nn = nn + 1
        t(nn, k) = t1(i, k)
        q(nn, k) = q1(i, k)
        qs(nn, k) = qs1(i, k)
        u(nn, k) = u1(i, k)
        v(nn, k) = v1(i, k)
        gz(nn, k) = gz1(i, k)
        h(nn, k) = h1(i, k)
        lv(nn, k) = lv1(i, k)
        cpn(nn, k) = cpn1(i, k)
        p(nn, k) = p1(i, k)
        ph(nn, k) = ph1(i, k)
        tv(nn, k) = tv1(i, k)
        tp(nn, k) = tp1(i, k)
        tvp(nn, k) = tvp1(i, k)
        clw(nn, k) = clw1(i, k)
      END IF
    END DO
    ! print*,'100 ncum,nn',ncum,nn
  END DO
  nn = 0
  DO i = 1, len
    IF (iflag1(i)==0) THEN
      nn = nn + 1
      cbmf(nn) = cbmf1(i)
      plcl(nn) = plcl1(i)
      tnk(nn) = tnk1(i)
      qnk(nn) = qnk1(i)
      gznk(nn) = gznk1(i)
      nk(nn) = nk1(i)
      icb(nn) = icb1(i)
      iflag(nn) = iflag1(i)
    END IF
  END DO
  ! print*,'150 ncum,nn',ncum,nn

  ! Initialize the tendencies, det, wd, tprime, qprime.

  DO k = 1, nl
    DO i = 1, ncum
      ! det(i,k)=0.0
      ft(i, k) = 0.0
      fu(i, k) = 0.0
      fv(i, k) = 0.0
      fq(i, k) = 0.0
      dph(i, k) = ph(i, k) - ph(i, k+1)
      ep(i, k) = 0.0
      sigp(i, k) = sigs
    END DO
  END DO
  DO i = 1, ncum
    ! wd(i)=0.0
    ! tprime(i)=0.0
    ! qprime(i)=0.0
    precip(i) = 0.0
    ft(i, nl+1) = 0.0
    fu(i, nl+1) = 0.0
    fv(i, nl+1) = 0.0
    fq(i, nl+1) = 0.0
  END DO

  ! Compute icbmax.

  icbmax = 2
  DO i = 1, ncum
    icbmax = max(icbmax, icb(i))
  END DO


  ! =====================================================================
  ! --- FIND THE REST OF THE LIFTED PARCEL TEMPERATURES
  ! =====================================================================

  ! ---       The procedure is to solve the equation.
  ! cp*tp+L*qp+phi=cp*tnk+L*qnk+gznk.

  ! ***  Calculate certain parcel quantities, including static energy   ***


  DO i = 1, ncum
    ah0(i) = (cpd*(1.-qnk(i))+cl*qnk(i))*tnk(i) + qnk(i)*(lv0-clmcpv*(tnk(i)- &
      273.15)) + gznk(i)
  END DO


  ! ***  Find lifted parcel quantities above cloud base    ***


  DO k = minorig + 1, nl
    DO i = 1, ncum
      IF (k>=(icb(i)+1)) THEN
        tg = t(i, k)
        qg = qs(i, k)
        alv = lv0 - clmcpv*(t(i,k)-273.15)

        ! First iteration.

        s = cpd + alv*alv*qg/(rv*t(i,k)*t(i,k))
        s = 1./s
        ahg = cpd*tg + (cl-cpd)*qnk(i)*t(i, k) + alv*qg + gz(i, k)
        tg = tg + s*(ah0(i)-ahg)
        tg = max(tg, 35.0)
        tc = tg - 273.15
        denom = 243.5 + tc
        IF (tc>=0.0) THEN
          es = 6.112*exp(17.67*tc/denom)
        ELSE
          es = exp(23.33086-6111.72784/tg+0.15215*log(tg))
        END IF
        qg = eps*es/(p(i,k)-es*(1.-eps))

        ! Second iteration.

        s = cpd + alv*alv*qg/(rv*t(i,k)*t(i,k))
        s = 1./s
        ahg = cpd*tg + (cl-cpd)*qnk(i)*t(i, k) + alv*qg + gz(i, k)
        tg = tg + s*(ah0(i)-ahg)
        tg = max(tg, 35.0)
        tc = tg - 273.15
        denom = 243.5 + tc
        IF (tc>=0.0) THEN
          es = 6.112*exp(17.67*tc/denom)
        ELSE
          es = exp(23.33086-6111.72784/tg+0.15215*log(tg))
        END IF
        qg = eps*es/(p(i,k)-es*(1.-eps))

        alv = lv0 - clmcpv*(t(i,k)-273.15)
        ! print*,'cpd dans convect2 ',cpd
        ! print*,'tp(i,k),ah0(i),cl,cpd,qnk(i),t(i,k),gz(i,k),alv,qg,cpd'
        ! print*,tp(i,k),ah0(i),cl,cpd,qnk(i),t(i,k),gz(i,k),alv,qg,cpd
        tp(i, k) = (ah0(i)-(cl-cpd)*qnk(i)*t(i,k)-gz(i,k)-alv*qg)/cpd
        ! if (.not.cpd.gt.1000.) then
        ! print*,'CPD=',cpd
        ! stop
        ! endif
        clw(i, k) = qnk(i) - qg
        clw(i, k) = max(0.0, clw(i,k))
        rg = qg/(1.-qnk(i))
        tvp(i, k) = tp(i, k)*(1.+rg*epsi)
      END IF
    END DO
  END DO

  ! =====================================================================
  ! --- SET THE PRECIPITATION EFFICIENCIES AND THE FRACTION OF
  ! --- PRECIPITATION FALLING OUTSIDE OF CLOUD
  ! --- THESE MAY BE FUNCTIONS OF TP(I), P(I) AND CLW(I)
  ! =====================================================================

  DO k = minorig + 1, nl
    DO i = 1, ncum
      IF (k>=(nk(i)+1)) THEN
        tca = tp(i, k) - 273.15
        IF (tca>=0.0) THEN
          elacrit = elcrit
        ELSE
          elacrit = elcrit*(1.0-tca/tlcrit)
        END IF
        elacrit = max(elacrit, 0.0)
        ep(i, k) = 1.0 - elacrit/max(clw(i,k), 1.0E-8)
        ep(i, k) = max(ep(i,k), 0.0)
        ep(i, k) = min(ep(i,k), 1.0)
        sigp(i, k) = sigs
      END IF
    END DO
  END DO

  ! =====================================================================
  ! --- CALCULATE VIRTUAL TEMPERATURE AND LIFTED PARCEL
  ! --- VIRTUAL TEMPERATURE
  ! =====================================================================

  DO k = minorig + 1, nl
    DO i = 1, ncum
      IF (k>=(icb(i)+1)) THEN
        tvp(i, k) = tvp(i, k)*(1.0-qnk(i)+ep(i,k)*clw(i,k))
        ! print*,'i,k,tvp(i,k),qnk(i),ep(i,k),clw(i,k)'
        ! print*, i,k,tvp(i,k),qnk(i),ep(i,k),clw(i,k)
      END IF
    END DO
  END DO
  DO i = 1, ncum
    tvp(i, nlp) = tvp(i, nl) - (gz(i,nlp)-gz(i,nl))/cpd
  END DO


  ! =====================================================================
  ! --- NOW INITIALIZE VARIOUS ARRAYS USED IN THE COMPUTATIONS
  ! =====================================================================

  DO i = 1, ncum*nlp
    nent(i, 1) = 0
    water(i, 1) = 0.0
    evap(i, 1) = 0.0
    mp(i, 1) = 0.0
    m(i, 1) = 0.0
    wt(i, 1) = omtsnow
    hp(i, 1) = h(i, 1)
    ! if(.not.cpn(i,1).gt.900.) then
    ! print*,'i,lv(i,1),cpn(i,1)'
    ! print*, i,lv(i,1),cpn(i,1)
    ! k=(i-1)/ncum+1
    ! print*,'i,k',mod(i,ncum),k,'  cpn',cpn(mod(i,ncum),k)
    ! stop
    ! endif
    lvcp(i, 1) = lv(i, 1)/cpn(i, 1)
  END DO

  DO i = 1, ncum*nlp*nlp
    elij(i, 1, 1) = 0.0
    ment(i, 1, 1) = 0.0
    sij(i, 1, 1) = 0.0
  END DO

  DO k = 1, nlp
    DO j = 1, nlp
      DO i = 1, ncum
        qent(i, k, j) = q(i, j)
        uent(i, k, j) = u(i, j)
        vent(i, k, j) = v(i, j)
      END DO
    END DO
  END DO

  DO i = 1, ncum
    qp(i, 1) = q(i, 1)
    up(i, 1) = u(i, 1)
    vp(i, 1) = v(i, 1)
  END DO
  DO k = 2, nlp
    DO i = 1, ncum
      qp(i, k) = q(i, k-1)
      up(i, k) = u(i, k-1)
      vp(i, k) = v(i, k-1)
    END DO
  END DO

  ! =====================================================================
  ! --- FIND THE FIRST MODEL LEVEL (INB1) ABOVE THE PARCEL'S
  ! --- HIGHEST LEVEL OF NEUTRAL BUOYANCY
  ! --- AND THE HIGHEST LEVEL OF POSITIVE CAPE (INB)
  ! =====================================================================

  DO i = 1, ncum
    cape(i) = 0.0
    capem(i) = 0.0
    inb(i) = icb(i) + 1
    inb1(i) = inb(i)
  END DO

  ! Originial Code

  ! do 530 k=minorig+1,nl-1
  ! do 520 i=1,ncum
  ! if(k.ge.(icb(i)+1))then
  ! by=(tvp(i,k)-tv(i,k))*dph(i,k)/p(i,k)
  ! byp=(tvp(i,k+1)-tv(i,k+1))*dph(i,k+1)/p(i,k+1)
  ! cape(i)=cape(i)+by
  ! if(by.ge.0.0)inb1(i)=k+1
  ! if(cape(i).gt.0.0)then
  ! inb(i)=k+1
  ! capem(i)=cape(i)
  ! endif
  ! endif
  ! 520    continue
  ! 530  continue
  ! do 540 i=1,ncum
  ! byp=(tvp(i,nl)-tv(i,nl))*dph(i,nl)/p(i,nl)
  ! cape(i)=capem(i)+byp
  ! defrac=capem(i)-cape(i)
  ! defrac=max(defrac,0.001)
  ! frac(i)=-cape(i)/defrac
  ! frac(i)=min(frac(i),1.0)
  ! frac(i)=max(frac(i),0.0)
  ! 540   continue

  ! K Emanuel fix

  ! call zilch(byp,ncum)
  ! do 530 k=minorig+1,nl-1
  ! do 520 i=1,ncum
  ! if(k.ge.(icb(i)+1))then
  ! by=(tvp(i,k)-tv(i,k))*dph(i,k)/p(i,k)
  ! cape(i)=cape(i)+by
  ! if(by.ge.0.0)inb1(i)=k+1
  ! if(cape(i).gt.0.0)then
  ! inb(i)=k+1
  ! capem(i)=cape(i)
  ! byp(i)=(tvp(i,k+1)-tv(i,k+1))*dph(i,k+1)/p(i,k+1)
  ! endif
  ! endif
  ! 520    continue
  ! 530  continue
  ! do 540 i=1,ncum
  ! inb(i)=max(inb(i),inb1(i))
  ! cape(i)=capem(i)+byp(i)
  ! defrac=capem(i)-cape(i)
  ! defrac=max(defrac,0.001)
  ! frac(i)=-cape(i)/defrac
  ! frac(i)=min(frac(i),1.0)
  ! frac(i)=max(frac(i),0.0)
  ! 540   continue

  ! J Teixeira fix

  CALL zilch(byp, ncum)
  DO i = 1, ncum
    lcape(i) = .TRUE.
  END DO
  DO k = minorig + 1, nl - 1
    DO i = 1, ncum
      IF (cape(i)<0.0) lcape(i) = .FALSE.
      IF ((k>=(icb(i)+1)) .AND. lcape(i)) THEN
        by = (tvp(i,k)-tv(i,k))*dph(i, k)/p(i, k)
        byp(i) = (tvp(i,k+1)-tv(i,k+1))*dph(i, k+1)/p(i, k+1)
        cape(i) = cape(i) + by
        IF (by>=0.0) inb1(i) = k + 1
        IF (cape(i)>0.0) THEN
          inb(i) = k + 1
          capem(i) = cape(i)
        END IF
      END IF
    END DO
  END DO
  DO i = 1, ncum
    cape(i) = capem(i) + byp(i)
    defrac = capem(i) - cape(i)
    defrac = max(defrac, 0.001)
    frac(i) = -cape(i)/defrac
    frac(i) = min(frac(i), 1.0)
    frac(i) = max(frac(i), 0.0)
  END DO

  ! =====================================================================
  ! ---   CALCULATE LIQUID WATER STATIC ENERGY OF LIFTED PARCEL
  ! =====================================================================

  DO k = minorig + 1, nl
    DO i = 1, ncum
      IF ((k>=icb(i)) .AND. (k<=inb(i))) THEN
        hp(i, k) = h(i, nk(i)) + (lv(i,k)+(cpd-cpv)*t(i,k))*ep(i, k)*clw(i, k &
          )
      END IF
    END DO
  END DO

  ! =====================================================================
  ! ---  CALCULATE CLOUD BASE MASS FLUX AND RATES OF MIXING, M(I),
  ! --- AT EACH MODEL LEVEL
  ! =====================================================================

  ! tvpplcl = parcel temperature lifted adiabatically from level
  ! icb-1 to the LCL.
  ! tvaplcl = virtual temperature at the LCL.

  DO i = 1, ncum
    dtpbl(i) = 0.0
    tvpplcl(i) = tvp(i, icb(i)-1) - rd*tvp(i, icb(i)-1)*(p(i,icb(i)-1)-plcl(i &
      ))/(cpn(i,icb(i)-1)*p(i,icb(i)-1))
    tvaplcl(i) = tv(i, icb(i)) + (tvp(i,icb(i))-tvp(i,icb(i)+1))*(plcl(i)-p(i &
      ,icb(i)))/(p(i,icb(i))-p(i,icb(i)+1))
  END DO

  ! -------------------------------------------------------------------
  ! --- Interpolate difference between lifted parcel and
  ! --- environmental temperatures to lifted condensation level
  ! -------------------------------------------------------------------

  ! dtpbl = average of tvp-tv in the PBL (k=nk to icb-1).

  DO k = minorig, icbmax
    DO i = 1, ncum
      IF ((k>=nk(i)) .AND. (k<=(icb(i)-1))) THEN
        dtpbl(i) = dtpbl(i) + (tvp(i,k)-tv(i,k))*dph(i, k)
      END IF
    END DO
  END DO
  DO i = 1, ncum
    dtpbl(i) = dtpbl(i)/(ph(i,nk(i))-ph(i,icb(i)))
    dtmin(i) = tvpplcl(i) - tvaplcl(i) + dtmax + dtpbl(i)
  END DO

  ! -------------------------------------------------------------------
  ! --- Adjust cloud base mass flux
  ! -------------------------------------------------------------------

  DO i = 1, ncum
    work(i) = cbmf(i)
    cbmf(i) = max(0.0, (1.0-damp)*cbmf(i)+0.1*alpha*dtmin(i))
    IF ((work(i)==0.0) .AND. (cbmf(i)==0.0)) THEN
      iflag(i) = 3
    END IF
  END DO

  ! -------------------------------------------------------------------
  ! --- Calculate rates of mixing,  m(i)
  ! -------------------------------------------------------------------

  CALL zilch(work, ncum)

  DO j = minorig + 1, nl
    DO i = 1, ncum
      IF ((j>=(icb(i)+1)) .AND. (j<=inb(i))) THEN
        k = min(j, inb1(i))
        dbo = abs(tv(i,k+1)-tvp(i,k+1)-tv(i,k-1)+tvp(i,k-1)) + &
          entp*0.04*(ph(i,k)-ph(i,k+1))
        work(i) = work(i) + dbo
        m(i, j) = cbmf(i)*dbo
      END IF
    END DO
  END DO
  DO k = minorig + 1, nl
    DO i = 1, ncum
      IF ((k>=(icb(i)+1)) .AND. (k<=inb(i))) THEN
        m(i, k) = m(i, k)/work(i)
      END IF
    END DO
  END DO


  ! =====================================================================
  ! --- CALCULATE ENTRAINED AIR MASS FLUX (ment), TOTAL WATER MIXING
  ! --- RATIO (QENT), TOTAL CONDENSED WATER (elij), AND MIXING
  ! --- FRACTION (sij)
  ! =====================================================================


  DO i = minorig + 1, nl
    DO j = minorig + 1, nl
      DO ij = 1, ncum
        IF ((i>=(icb(ij)+1)) .AND. (j>=icb(ij)) .AND. (i<=inb(ij)) .AND. (j<= &
            inb(ij))) THEN
          qti = qnk(ij) - ep(ij, i)*clw(ij, i)
          bf2 = 1. + lv(ij, j)*lv(ij, j)*qs(ij, j)/(rv*t(ij,j)*t(ij,j)*cpd)
          anum = h(ij, j) - hp(ij, i) + (cpv-cpd)*t(ij, j)*(qti-q(ij,j))
          denom = h(ij, i) - hp(ij, i) + (cpd-cpv)*(q(ij,i)-qti)*t(ij, j)
          dei = denom
          IF (abs(dei)<0.01) dei = 0.01
          sij(ij, i, j) = anum/dei
          sij(ij, i, i) = 1.0
          altem = sij(ij, i, j)*q(ij, i) + (1.-sij(ij,i,j))*qti - qs(ij, j)
          altem = altem/bf2
          cwat = clw(ij, j)*(1.-ep(ij,j))
          stemp = sij(ij, i, j)
          IF ((stemp<0.0 .OR. stemp>1.0 .OR. altem>cwat) .AND. j>i) THEN
            anum = anum - lv(ij, j)*(qti-qs(ij,j)-cwat*bf2)
            denom = denom + lv(ij, j)*(q(ij,i)-qti)
            IF (abs(denom)<0.01) denom = 0.01
            sij(ij, i, j) = anum/denom
            altem = sij(ij, i, j)*q(ij, i) + (1.-sij(ij,i,j))*qti - qs(ij, j)
            altem = altem - (bf2-1.)*cwat
          END IF
          IF (sij(ij,i,j)>0.0 .AND. sij(ij,i,j)<0.9) THEN
            qent(ij, i, j) = sij(ij, i, j)*q(ij, i) + (1.-sij(ij,i,j))*qti
            uent(ij, i, j) = sij(ij, i, j)*u(ij, i) + &
              (1.-sij(ij,i,j))*u(ij, nk(ij))
            vent(ij, i, j) = sij(ij, i, j)*v(ij, i) + &
              (1.-sij(ij,i,j))*v(ij, nk(ij))
            elij(ij, i, j) = altem
            elij(ij, i, j) = max(0.0, elij(ij,i,j))
            ment(ij, i, j) = m(ij, i)/(1.-sij(ij,i,j))
            nent(ij, i) = nent(ij, i) + 1
          END IF
          sij(ij, i, j) = max(0.0, sij(ij,i,j))
          sij(ij, i, j) = min(1.0, sij(ij,i,j))
        END IF
      END DO
    END DO

    ! ***   If no air can entrain at level i assume that updraft detrains
    ! ***
    ! ***   at that level and calculate detrained air flux and properties
    ! ***

    DO ij = 1, ncum
      IF ((i>=(icb(ij)+1)) .AND. (i<=inb(ij)) .AND. (nent(ij,i)==0)) THEN
        ment(ij, i, i) = m(ij, i)
        qent(ij, i, i) = q(ij, nk(ij)) - ep(ij, i)*clw(ij, i)
        uent(ij, i, i) = u(ij, nk(ij))
        vent(ij, i, i) = v(ij, nk(ij))
        elij(ij, i, i) = clw(ij, i)
        sij(ij, i, i) = 1.0
      END IF
    END DO
  END DO

  DO i = 1, ncum
    sij(i, inb(i), inb(i)) = 1.0
  END DO

  ! =====================================================================
  ! ---  NORMALIZE ENTRAINED AIR MASS FLUXES
  ! ---  TO REPRESENT EQUAL PROBABILITIES OF MIXING
  ! =====================================================================


  CALL zilch(bsum, ncum*nlp)
  DO ij = 1, ncum
    lwork(ij) = .FALSE.
  END DO
  DO i = minorig + 1, nl

    num1 = 0
    DO ij = 1, ncum
      IF ((i>=icb(ij)+1) .AND. (i<=inb(ij))) num1 = num1 + 1
    END DO
    IF (num1<=0) GO TO 789

    DO ij = 1, ncum
      IF ((i>=icb(ij)+1) .AND. (i<=inb(ij))) THEN
        lwork(ij) = (nent(ij,i)/=0)
        qp1 = q(ij, nk(ij)) - ep(ij, i)*clw(ij, i)
        anum = h(ij, i) - hp(ij, i) - lv(ij, i)*(qp1-qs(ij,i))
        denom = h(ij, i) - hp(ij, i) + lv(ij, i)*(q(ij,i)-qp1)
        IF (abs(denom)<0.01) denom = 0.01
        scrit(ij) = anum/denom
        alt = qp1 - qs(ij, i) + scrit(ij)*(q(ij,i)-qp1)
        IF (scrit(ij)<0.0 .OR. alt<0.0) scrit(ij) = 1.0
        asij(ij) = 0.0
        smin(ij) = 1.0
      END IF
    END DO
    DO j = minorig, nl

      num2 = 0
      DO ij = 1, ncum
        IF ((i>=icb(ij)+1) .AND. (i<=inb(ij)) .AND. (j>=icb( &
          ij)) .AND. (j<=inb(ij)) .AND. lwork(ij)) num2 = num2 + 1
      END DO
      IF (num2<=0) GO TO 783

      DO ij = 1, ncum
        IF ((i>=icb(ij)+1) .AND. (i<=inb(ij)) .AND. (j>=icb( &
            ij)) .AND. (j<=inb(ij)) .AND. lwork(ij)) THEN
          IF (sij(ij,i,j)>0.0 .AND. sij(ij,i,j)<0.9) THEN
            IF (j>i) THEN
              smid = min(sij(ij,i,j), scrit(ij))
              sjmax = smid
              sjmin = smid
              IF (smid<smin(ij) .AND. sij(ij,i,j+1)<smid) THEN
                smin(ij) = smid
                sjmax = min(sij(ij,i,j+1), sij(ij,i,j), scrit(ij))
                sjmin = max(sij(ij,i,j-1), sij(ij,i,j))
                sjmin = min(sjmin, scrit(ij))
              END IF
            ELSE
              sjmax = max(sij(ij,i,j+1), scrit(ij))
              smid = max(sij(ij,i,j), scrit(ij))
              sjmin = 0.0
              IF (j>1) sjmin = sij(ij, i, j-1)
              sjmin = max(sjmin, scrit(ij))
            END IF
            delp = abs(sjmax-smid)
            delm = abs(sjmin-smid)
            asij(ij) = asij(ij) + (delp+delm)*(ph(ij,j)-ph(ij,j+1))
            ment(ij, i, j) = ment(ij, i, j)*(delp+delm)*(ph(ij,j)-ph(ij,j+1))
          END IF
        END IF
      END DO
783 END DO
    DO ij = 1, ncum
      IF ((i>=icb(ij)+1) .AND. (i<=inb(ij)) .AND. lwork(ij)) THEN
        asij(ij) = max(1.0E-21, asij(ij))
        asij(ij) = 1.0/asij(ij)
        bsum(ij, i) = 0.0
      END IF
    END DO
    DO j = minorig, nl + 1
      DO ij = 1, ncum
        IF ((i>=icb(ij)+1) .AND. (i<=inb(ij)) .AND. (j>=icb( &
            ij)) .AND. (j<=inb(ij)) .AND. lwork(ij)) THEN
          ment(ij, i, j) = ment(ij, i, j)*asij(ij)
          bsum(ij, i) = bsum(ij, i) + ment(ij, i, j)
        END IF
      END DO
    END DO
    DO ij = 1, ncum
      IF ((i>=icb(ij)+1) .AND. (i<=inb(ij)) .AND. (bsum(ij, &
          i)<1.0E-18) .AND. lwork(ij)) THEN
        nent(ij, i) = 0
        ment(ij, i, i) = m(ij, i)
        qent(ij, i, i) = q(ij, nk(ij)) - ep(ij, i)*clw(ij, i)
        uent(ij, i, i) = u(ij, nk(ij))
        vent(ij, i, i) = v(ij, nk(ij))
        elij(ij, i, i) = clw(ij, i)
        sij(ij, i, i) = 1.0
      END IF
    END DO
789 END DO

  ! =====================================================================
  ! --- PRECIPITATING DOWNDRAFT CALCULATION
  ! =====================================================================

  ! ***  Check whether ep(inb)=0, if so, skip precipitating    ***
  ! ***             downdraft calculation                      ***


  ! ***  Integrate liquid water equation to find condensed water   ***
  ! ***                and condensed water flux                    ***


  DO i = 1, ncum
    jtt(i) = 2
    IF (ep(i,inb(i))<=0.0001) iflag(i) = 2
    IF (iflag(i)==0) THEN
      lwork(i) = .TRUE.
    ELSE
      lwork(i) = .FALSE.
    END IF
  END DO

  ! ***                    Begin downdraft loop                    ***


  CALL zilch(wdtrain, ncum)
  DO i = nl + 1, 1, -1

    num1 = 0
    DO ij = 1, ncum
      IF ((i<=inb(ij)) .AND. lwork(ij)) num1 = num1 + 1
    END DO
    IF (num1<=0) GO TO 899


    ! ***        Calculate detrained precipitation             ***

    DO ij = 1, ncum
      IF ((i<=inb(ij)) .AND. (lwork(ij))) THEN
        wdtrain(ij) = g*ep(ij, i)*m(ij, i)*clw(ij, i)
      END IF
    END DO

    IF (i>1) THEN
      DO j = 1, i - 1
        DO ij = 1, ncum
          IF ((i<=inb(ij)) .AND. (lwork(ij))) THEN
            awat = elij(ij, j, i) - (1.-ep(ij,i))*clw(ij, i)
            awat = max(0.0, awat)
            wdtrain(ij) = wdtrain(ij) + g*awat*ment(ij, j, i)
          END IF
        END DO
      END DO
    END IF

    ! ***    Find rain water and evaporation using provisional   ***
    ! ***              estimates of qp(i)and qp(i-1)             ***


    ! ***  Value of terminal velocity and coeffecient of evaporation for snow
    ! ***

    DO ij = 1, ncum
      IF ((i<=inb(ij)) .AND. (lwork(ij))) THEN
        coeff = coeffs
        wt(ij, i) = omtsnow

        ! ***  Value of terminal velocity and coeffecient of evaporation for
        ! rain   ***

        IF (t(ij,i)>273.0) THEN
          coeff = coeffr
          wt(ij, i) = omtrain
        END IF
        qsm = 0.5*(q(ij,i)+qp(ij,i+1))
        afac = coeff*ph(ij, i)*(qs(ij,i)-qsm)/(1.0E4+2.0E3*ph(ij,i)*qs(ij,i))
        afac = max(afac, 0.0)
        sigt = sigp(ij, i)
        sigt = max(0.0, sigt)
        sigt = min(1.0, sigt)
        b6 = 100.*(ph(ij,i)-ph(ij,i+1))*sigt*afac/wt(ij, i)
        c6 = (water(ij,i+1)*wt(ij,i+1)+wdtrain(ij)/sigd)/wt(ij, i)
        revap = 0.5*(-b6+sqrt(b6*b6+4.*c6))
        evap(ij, i) = sigt*afac*revap
        water(ij, i) = revap*revap

        ! ***  Calculate precipitating downdraft mass flux under     ***
        ! ***              hydrostatic approximation                 ***

        IF (i>1) THEN
          dhdp = (h(ij,i)-h(ij,i-1))/(p(ij,i-1)-p(ij,i))
          dhdp = max(dhdp, 10.0)
          mp(ij, i) = 100.*ginv*lv(ij, i)*sigd*evap(ij, i)/dhdp
          mp(ij, i) = max(mp(ij,i), 0.0)

          ! ***   Add small amount of inertia to downdraft              ***

          fac = 20.0/(ph(ij,i-1)-ph(ij,i))
          mp(ij, i) = (fac*mp(ij,i+1)+mp(ij,i))/(1.+fac)

          ! ***      Force mp to decrease linearly to zero
          ! ***
          ! ***      between about 950 mb and the surface
          ! ***

          IF (p(ij,i)>(0.949*p(ij,1))) THEN
            jtt(ij) = max(jtt(ij), i)
            mp(ij, i) = mp(ij, jtt(ij))*(p(ij,1)-p(ij,i))/ &
              (p(ij,1)-p(ij,jtt(ij)))
          END IF
        END IF

        ! ***       Find mixing ratio of precipitating downdraft     ***

        IF (i/=inb(ij)) THEN
          IF (i==1) THEN
            qstm = qs(ij, 1)
          ELSE
            qstm = qs(ij, i-1)
          END IF
          IF (mp(ij,i)>mp(ij,i+1)) THEN
            rat = mp(ij, i+1)/mp(ij, i)
            qp(ij, i) = qp(ij, i+1)*rat + q(ij, i)*(1.0-rat) + &
              100.*ginv*sigd*(ph(ij,i)-ph(ij,i+1))*(evap(ij,i)/mp(ij,i))
            up(ij, i) = up(ij, i+1)*rat + u(ij, i)*(1.-rat)
            vp(ij, i) = vp(ij, i+1)*rat + v(ij, i)*(1.-rat)
          ELSE
            IF (mp(ij,i+1)>0.0) THEN
              qp(ij, i) = (gz(ij,i+1)-gz(ij,i)+qp(ij,i+1)*(lv(ij,i+1)+t(ij, &
                i+1)*(cl-cpd))+cpd*(t(ij,i+1)-t(ij, &
                i)))/(lv(ij,i)+t(ij,i)*(cl-cpd))
              up(ij, i) = up(ij, i+1)
              vp(ij, i) = vp(ij, i+1)
            END IF
          END IF
          qp(ij, i) = min(qp(ij,i), qstm)
          qp(ij, i) = max(qp(ij,i), 0.0)
        END IF
      END IF
    END DO
899 END DO

  ! ***  Calculate surface precipitation in mm/day     ***

  DO i = 1, ncum
    IF (iflag(i)<=1) THEN
      ! c            precip(i)=precip(i)+wt(i,1)*sigd*water(i,1)*3600.*24000.
      ! c     &                /(rowl*g)
      ! c            precip(i)=precip(i)*delt/86400.
      precip(i) = wt(i, 1)*sigd*water(i, 1)*86400/g
    END IF
  END DO


  ! ***  Calculate downdraft velocity scale and surface temperature and  ***
  ! ***                    water vapor fluctuations                      ***

  ! wd=beta*abs(mp(icb))*0.01*rd*t(icb)/(sigd*p(icb))
  ! qprime=0.5*(qp(1)-q(1))
  ! tprime=lv0*qprime/cpd

  ! ***  Calculate tendencies of lowest level potential temperature  ***
  ! ***                      and mixing ratio                        ***

  DO i = 1, ncum
    work(i) = 0.01/(ph(i,1)-ph(i,2))
    am(i) = 0.0
  END DO
  DO k = 2, nl
    DO i = 1, ncum
      IF ((nk(i)==1) .AND. (k<=inb(i)) .AND. (nk(i)==1)) THEN
        am(i) = am(i) + m(i, k)
      END IF
    END DO
  END DO
  DO i = 1, ncum
    IF ((g*work(i)*am(i))>=delti) iflag(i) = 1
    ft(i, 1) = ft(i, 1) + g*work(i)*am(i)*(t(i,2)-t(i,1)+(gz(i,2)-gz(i, &
      1))/cpn(i,1))
    ft(i, 1) = ft(i, 1) - lvcp(i, 1)*sigd*evap(i, 1)
    ft(i, 1) = ft(i, 1) + sigd*wt(i, 2)*(cl-cpd)*water(i, 2)*(t(i,2)-t(i,1))* &
      work(i)/cpn(i, 1)
    fq(i, 1) = fq(i, 1) + g*mp(i, 2)*(qp(i,2)-q(i,1))*work(i) + &
      sigd*evap(i, 1)
    fq(i, 1) = fq(i, 1) + g*am(i)*(q(i,2)-q(i,1))*work(i)
    fu(i, 1) = fu(i, 1) + g*work(i)*(mp(i,2)*(up(i,2)-u(i,1))+am(i)*(u(i, &
      2)-u(i,1)))
    fv(i, 1) = fv(i, 1) + g*work(i)*(mp(i,2)*(vp(i,2)-v(i,1))+am(i)*(v(i, &
      2)-v(i,1)))
  END DO
  DO j = 2, nl
    DO i = 1, ncum
      IF (j<=inb(i)) THEN
        fq(i, 1) = fq(i, 1) + g*work(i)*ment(i, j, 1)*(qent(i,j,1)-q(i,1))
        fu(i, 1) = fu(i, 1) + g*work(i)*ment(i, j, 1)*(uent(i,j,1)-u(i,1))
        fv(i, 1) = fv(i, 1) + g*work(i)*ment(i, j, 1)*(vent(i,j,1)-v(i,1))
      END IF
    END DO
  END DO

  ! ***  Calculate tendencies of potential temperature and mixing ratio  ***
  ! ***               at levels above the lowest level                   ***

  ! ***  First find the net saturated updraft and downdraft mass fluxes  ***
  ! ***                      through each level                          ***

  DO i = 2, nl + 1

    num1 = 0
    DO ij = 1, ncum
      IF (i<=inb(ij)) num1 = num1 + 1
    END DO
    IF (num1<=0) GO TO 1500

    CALL zilch(amp1, ncum)
    CALL zilch(ad, ncum)

    DO k = i + 1, nl + 1
      DO ij = 1, ncum
        IF ((i>=nk(ij)) .AND. (i<=inb(ij)) .AND. (k<=(inb(ij)+1))) THEN
          amp1(ij) = amp1(ij) + m(ij, k)
        END IF
      END DO
    END DO

    DO k = 1, i
      DO j = i + 1, nl + 1
        DO ij = 1, ncum
          IF ((j<=(inb(ij)+1)) .AND. (i<=inb(ij))) THEN
            amp1(ij) = amp1(ij) + ment(ij, k, j)
          END IF
        END DO
      END DO
    END DO
    DO k = 1, i - 1
      DO j = i, nl + 1
        DO ij = 1, ncum
          IF ((i<=inb(ij)) .AND. (j<=inb(ij))) THEN
            ad(ij) = ad(ij) + ment(ij, j, k)
          END IF
        END DO
      END DO
    END DO

    DO ij = 1, ncum
      IF (i<=inb(ij)) THEN
        dpinv = 0.01/(ph(ij,i)-ph(ij,i+1))
        cpinv = 1.0/cpn(ij, i)

        ft(ij, i) = ft(ij, i) + g*dpinv*(amp1(ij)*(t(ij,i+1)-t(ij, &
          i)+(gz(ij,i+1)-gz(ij,i))*cpinv)-ad(ij)*(t(ij,i)-t(ij, &
          i-1)+(gz(ij,i)-gz(ij,i-1))*cpinv)) - sigd*lvcp(ij, i)*evap(ij, i)
        ft(ij, i) = ft(ij, i) + g*dpinv*ment(ij, i, i)*(hp(ij,i)-h(ij,i)+t(ij &
          ,i)*(cpv-cpd)*(q(ij,i)-qent(ij,i,i)))*cpinv
        ft(ij, i) = ft(ij, i) + sigd*wt(ij, i+1)*(cl-cpd)*water(ij, i+1)*(t( &
          ij,i+1)-t(ij,i))*dpinv*cpinv
        fq(ij, i) = fq(ij, i) + g*dpinv*(amp1(ij)*(q(ij,i+1)-q(ij, &
          i))-ad(ij)*(q(ij,i)-q(ij,i-1)))
        fu(ij, i) = fu(ij, i) + g*dpinv*(amp1(ij)*(u(ij,i+1)-u(ij, &
          i))-ad(ij)*(u(ij,i)-u(ij,i-1)))
        fv(ij, i) = fv(ij, i) + g*dpinv*(amp1(ij)*(v(ij,i+1)-v(ij, &
          i))-ad(ij)*(v(ij,i)-v(ij,i-1)))
      END IF
    END DO
    DO k = 1, i - 1
      DO ij = 1, ncum
        IF (i<=inb(ij)) THEN
          awat = elij(ij, k, i) - (1.-ep(ij,i))*clw(ij, i)
          awat = max(awat, 0.0)
          fq(ij, i) = fq(ij, i) + g*dpinv*ment(ij, k, i)*(qent(ij,k,i)-awat-q &
            (ij,i))
          fu(ij, i) = fu(ij, i) + g*dpinv*ment(ij, k, i)*(uent(ij,k,i)-u(ij,i &
            ))
          fv(ij, i) = fv(ij, i) + g*dpinv*ment(ij, k, i)*(vent(ij,k,i)-v(ij,i &
            ))
        END IF
      END DO
    END DO
    DO k = i, nl + 1
      DO ij = 1, ncum
        IF ((i<=inb(ij)) .AND. (k<=inb(ij))) THEN
          fq(ij, i) = fq(ij, i) + g*dpinv*ment(ij, k, i)*(qent(ij,k,i)-q(ij,i &
            ))
          fu(ij, i) = fu(ij, i) + g*dpinv*ment(ij, k, i)*(uent(ij,k,i)-u(ij,i &
            ))
          fv(ij, i) = fv(ij, i) + g*dpinv*ment(ij, k, i)*(vent(ij,k,i)-v(ij,i &
            ))
        END IF
      END DO
    END DO
    DO ij = 1, ncum
      IF (i<=inb(ij)) THEN
        fq(ij, i) = fq(ij, i) + sigd*evap(ij, i) + g*(mp(ij,i+1)*(qp(ij, &
          i+1)-q(ij,i))-mp(ij,i)*(qp(ij,i)-q(ij,i-1)))*dpinv
        fu(ij, i) = fu(ij, i) + g*(mp(ij,i+1)*(up(ij,i+1)-u(ij, &
          i))-mp(ij,i)*(up(ij,i)-u(ij,i-1)))*dpinv
        fv(ij, i) = fv(ij, i) + g*(mp(ij,i+1)*(vp(ij,i+1)-v(ij, &
          i))-mp(ij,i)*(vp(ij,i)-v(ij,i-1)))*dpinv
      END IF
    END DO
1500 END DO

  ! *** Adjust tendencies at top of convection layer to reflect  ***
  ! ***       actual position of the level zero cape             ***

  DO ij = 1, ncum
    fqold = fq(ij, inb(ij))
    fq(ij, inb(ij)) = fq(ij, inb(ij))*(1.-frac(ij))
    fq(ij, inb(ij)-1) = fq(ij, inb(ij)-1) + frac(ij)*fqold*((ph(ij, &
      inb(ij))-ph(ij,inb(ij)+1))/(ph(ij,inb(ij)-1)-ph(ij, &
      inb(ij))))*lv(ij, inb(ij))/lv(ij, inb(ij)-1)
    ftold = ft(ij, inb(ij))
    ft(ij, inb(ij)) = ft(ij, inb(ij))*(1.-frac(ij))
    ft(ij, inb(ij)-1) = ft(ij, inb(ij)-1) + frac(ij)*ftold*((ph(ij, &
      inb(ij))-ph(ij,inb(ij)+1))/(ph(ij,inb(ij)-1)-ph(ij, &
      inb(ij))))*cpn(ij, inb(ij))/cpn(ij, inb(ij)-1)
    fuold = fu(ij, inb(ij))
    fu(ij, inb(ij)) = fu(ij, inb(ij))*(1.-frac(ij))
    fu(ij, inb(ij)-1) = fu(ij, inb(ij)-1) + frac(ij)*fuold*((ph(ij, &
      inb(ij))-ph(ij,inb(ij)+1))/(ph(ij,inb(ij)-1)-ph(ij,inb(ij))))
    fvold = fv(ij, inb(ij))
    fv(ij, inb(ij)) = fv(ij, inb(ij))*(1.-frac(ij))
    fv(ij, inb(ij)-1) = fv(ij, inb(ij)-1) + frac(ij)*fvold*((ph(ij, &
      inb(ij))-ph(ij,inb(ij)+1))/(ph(ij,inb(ij)-1)-ph(ij,inb(ij))))
  END DO

  ! ***   Very slightly adjust tendencies to force exact   ***
  ! ***     enthalpy, momentum and tracer conservation     ***

  DO ij = 1, ncum
    ents(ij) = 0.0
    uav(ij) = 0.0
    vav(ij) = 0.0
    DO i = 1, inb(ij)
      ents(ij) = ents(ij) + (cpn(ij,i)*ft(ij,i)+lv(ij,i)*fq(ij,i))*(ph(ij,i)- &
        ph(ij,i+1))
      uav(ij) = uav(ij) + fu(ij, i)*(ph(ij,i)-ph(ij,i+1))
      vav(ij) = vav(ij) + fv(ij, i)*(ph(ij,i)-ph(ij,i+1))
    END DO
  END DO
  DO ij = 1, ncum
    ents(ij) = ents(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
    uav(ij) = uav(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
    vav(ij) = vav(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
  END DO
  DO ij = 1, ncum
    DO i = 1, inb(ij)
      ft(ij, i) = ft(ij, i) - ents(ij)/cpn(ij, i)
      fu(ij, i) = (1.-cu)*(fu(ij,i)-uav(ij))
      fv(ij, i) = (1.-cu)*(fv(ij,i)-vav(ij))
    END DO
  END DO

  DO k = 1, nl + 1
    DO i = 1, ncum
      IF ((q(i,k)+delt*fq(i,k))<0.0) iflag(i) = 10
    END DO
  END DO


  DO i = 1, ncum
    IF (iflag(i)>2) THEN
      precip(i) = 0.0
      cbmf(i) = 0.0
    END IF
  END DO
  DO k = 1, nl
    DO i = 1, ncum
      IF (iflag(i)>2) THEN
        ft(i, k) = 0.0
        fq(i, k) = 0.0
        fu(i, k) = 0.0
        fv(i, k) = 0.0
      END IF
    END DO
  END DO
  DO i = 1, ncum
    precip1(idcum(i)) = precip(i)
    cbmf1(idcum(i)) = cbmf(i)
    iflag1(idcum(i)) = iflag(i)
  END DO
  DO k = 1, nl
    DO i = 1, ncum
      ft1(idcum(i), k) = ft(i, k)
      fq1(idcum(i), k) = fq(i, k)
      fu1(idcum(i), k) = fu(i, k)
      fv1(idcum(i), k) = fv(i, k)
    END DO
  END DO

  DO k = 1, nd
    DO i = 1, len
      ma(i, k) = 0.
    END DO
  END DO
  DO k = nl, 1, -1
    DO i = 1, ncum
      ma(i, k) = ma(i, k+1) + m(i, k)
    END DO
  END DO

  RETURN
END SUBROUTINE convect2