! $Id: cv_routines.f90 5303 2024-10-30 17:34:05Z ymeurdesoif $ SUBROUTINE cv_param(nd) USE cvthermo_mod_h USE cvparam_mod_h IMPLICIT NONE ! ------------------------------------------------------------ ! Set parameters for convectL ! (includes microphysical parameters and parameters that ! control the rate of approach to quasi-equilibrium) ! ------------------------------------------------------------ ! *** 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) *** INTEGER nd CHARACTER (LEN=20) :: modname = 'cv_routines' CHARACTER (LEN=80) :: abort_message ! noff: integer limit for convection (nd-noff) ! minorig: First level of convection noff = 2 minorig = 2 nl = nd - noff nlp = nl + 1 nlm = nl - 1 elcrit = 0.0011 tlcrit = -55.0 entp = 1.5 sigs = 0.12 sigd = 0.05 omtrain = 50.0 omtsnow = 5.5 coeffr = 1.0 coeffs = 0.8 dtmax = 0.9 cu = 0.70 betad = 10.0 damp = 0.1 alpha = 0.2 delta = 0.01 ! cld RETURN END SUBROUTINE cv_param SUBROUTINE cv_prelim(len, nd, ndp1, t, q, p, ph, lv, cpn, tv, gz, h, hm) USE cvthermo_mod_h USE cvparam_mod_h IMPLICIT NONE ! ===================================================================== ! --- CALCULATE ARRAYS OF GEOPOTENTIAL, HEAT CAPACITY & STATIC ENERGY ! ===================================================================== ! inputs: INTEGER len, nd, ndp1 REAL t(len, nd), q(len, nd), p(len, nd), ph(len, ndp1) ! outputs: REAL lv(len, nd), cpn(len, nd), tv(len, nd) REAL gz(len, nd), h(len, nd), hm(len, nd) ! local variables: INTEGER k, i REAL cpx(len, nd) DO k = 1, nlp DO i = 1, len lv(i, k) = lv0 - clmcpv*(t(i,k)-t0) cpn(i, k) = cpd*(1.0-q(i,k)) + cpv*q(i, k) cpx(i, k) = cpd*(1.0-q(i,k)) + cl*q(i, k) tv(i, k) = t(i, k)*(1.0+q(i,k)*epsim1) END DO END DO ! gz = phi at the full levels (same as p). DO i = 1, len gz(i, 1) = 0.0 END DO DO k = 2, nlp DO i = 1, len gz(i, k) = gz(i, k-1) + hrd*(tv(i,k-1)+tv(i,k))*(p(i,k-1)-p(i,k))/ph(i, & k) END DO END DO ! h = phi + cpT (dry static energy). ! hm = phi + cp(T-Tbase)+Lq DO k = 1, nlp DO i = 1, len h(i, k) = gz(i, k) + cpn(i, k)*t(i, k) hm(i, k) = gz(i, k) + cpx(i, k)*(t(i,k)-t(i,1)) + lv(i, k)*q(i, k) END DO END DO RETURN END SUBROUTINE cv_prelim SUBROUTINE cv_feed(len, nd, t, q, qs, p, hm, gz, nk, icb, icbmax, iflag, tnk, & qnk, gznk, plcl) USE cvparam_mod_h IMPLICIT NONE ! ================================================================ ! Purpose: CONVECTIVE FEED ! ================================================================ ! inputs: INTEGER len, nd REAL t(len, nd), q(len, nd), qs(len, nd), p(len, nd) REAL hm(len, nd), gz(len, nd) ! outputs: INTEGER iflag(len), nk(len), icb(len), icbmax REAL tnk(len), qnk(len), gznk(len), plcl(len) ! local variables: INTEGER i, k INTEGER ihmin(len) REAL work(len) REAL pnk(len), qsnk(len), rh(len), chi(len) ! ------------------------------------------------------------------- ! --- Find level of minimum moist static energy ! --- If level of minimum moist static energy coincides with ! --- or is lower than minimum allowable parcel origin level, ! --- set iflag to 6. ! ------------------------------------------------------------------- DO i = 1, len work(i) = 1.0E12 ihmin(i) = nl END DO DO k = 2, nlp DO i = 1, len IF ((hm(i,k)work(i)) .AND. (k<=ihmin(i))) THEN work(i) = hm(i, k) nk(i) = k END IF END DO END DO ! ------------------------------------------------------------------- ! --- Check whether parcel level temperature and specific humidity ! --- are reasonable ! ------------------------------------------------------------------- DO i = 1, len IF (((t(i,nk(i))<250.0) .OR. (q(i,nk(i))<=0.0) .OR. (p(i,ihmin(i))< & 400.0)) .AND. (iflag(i)==0)) iflag(i) = 7 END DO ! ------------------------------------------------------------------- ! --- Calculate lifted condensation level of air at parcel origin level ! --- (Within 0.2% of formula of Bolton, MON. WEA. REV.,1980) ! ------------------------------------------------------------------- DO i = 1, len tnk(i) = t(i, nk(i)) qnk(i) = q(i, nk(i)) gznk(i) = gz(i, nk(i)) pnk(i) = p(i, nk(i)) qsnk(i) = qs(i, nk(i)) rh(i) = qnk(i)/qsnk(i) rh(i) = min(1.0, rh(i)) chi(i) = tnk(i)/(1669.0-122.0*rh(i)-tnk(i)) plcl(i) = pnk(i)*(rh(i)**chi(i)) IF (((plcl(i)<200.0) .OR. (plcl(i)>=2000.0)) .AND. (iflag(i)==0)) iflag(i & ) = 8 END DO ! ------------------------------------------------------------------- ! --- Calculate first level above lcl (=icb) ! ------------------------------------------------------------------- DO i = 1, len icb(i) = nlm END DO DO k = minorig, nl DO i = 1, len IF ((k>=(nk(i)+1)) .AND. (p(i,k)=nlm) .AND. (iflag(i)==0)) iflag(i) = 9 END DO ! Compute icbmax. icbmax = 2 DO i = 1, len icbmax = max(icbmax, icb(i)) END DO RETURN END SUBROUTINE cv_feed SUBROUTINE cv_undilute1(len, nd, t, q, qs, gz, p, nk, icb, icbmax, tp, tvp, & clw) USE cvparam_mod_h USE cvthermo_mod_h IMPLICIT NONE ! inputs: INTEGER len, nd INTEGER nk(len), icb(len), icbmax REAL t(len, nd), q(len, nd), qs(len, nd), gz(len, nd) REAL p(len, nd) ! outputs: REAL tp(len, nd), tvp(len, nd), clw(len, nd) ! local variables: INTEGER i, k REAL tg, qg, alv, s, ahg, tc, denom, es, rg REAL ah0(len), cpp(len) REAL tnk(len), qnk(len), gznk(len), ticb(len), gzicb(len) ! ------------------------------------------------------------------- ! --- Calculates the lifted parcel virtual temperature at nk, ! --- the actual temperature, and the adiabatic ! --- liquid water content. The procedure is to solve the equation. ! cp*tp+L*qp+phi=cp*tnk+L*qnk+gznk. ! ------------------------------------------------------------------- DO i = 1, len tnk(i) = t(i, nk(i)) qnk(i) = q(i, nk(i)) gznk(i) = gz(i, nk(i)) ticb(i) = t(i, icb(i)) gzicb(i) = gz(i, icb(i)) END DO ! *** Calculate certain parcel quantities, including static energy *** DO i = 1, len ah0(i) = (cpd*(1.-qnk(i))+cl*qnk(i))*tnk(i) + qnk(i)*(lv0-clmcpv*(tnk(i)- & 273.15)) + gznk(i) cpp(i) = cpd*(1.-qnk(i)) + qnk(i)*cpv END DO ! *** Calculate lifted parcel quantities below cloud base *** DO k = minorig, icbmax - 1 DO i = 1, len tp(i, k) = tnk(i) - (gz(i,k)-gznk(i))/cpp(i) tvp(i, k) = tp(i, k)*(1.+qnk(i)*epsi) END DO END DO ! *** Find lifted parcel quantities above cloud base *** DO i = 1, len tg = ticb(i) qg = qs(i, icb(i)) alv = lv0 - clmcpv*(ticb(i)-t0) ! First iteration. s = cpd + alv*alv*qg/(rrv*ticb(i)*ticb(i)) s = 1./s ahg = cpd*tg + (cl-cpd)*qnk(i)*ticb(i) + alv*qg + gzicb(i) tg = tg + s*(ah0(i)-ahg) tg = max(tg, 35.0) tc = tg - t0 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,icb(i))-es*(1.-eps)) ! Second iteration. s = cpd + alv*alv*qg/(rrv*ticb(i)*ticb(i)) s = 1./s ahg = cpd*tg + (cl-cpd)*qnk(i)*ticb(i) + alv*qg + gzicb(i) tg = tg + s*(ah0(i)-ahg) tg = max(tg, 35.0) tc = tg - t0 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,icb(i))-es*(1.-eps)) alv = lv0 - clmcpv*(ticb(i)-273.15) tp(i, icb(i)) = (ah0(i)-(cl-cpd)*qnk(i)*ticb(i)-gz(i,icb(i))-alv*qg)/cpd clw(i, icb(i)) = qnk(i) - qg clw(i, icb(i)) = max(0.0, clw(i,icb(i))) rg = qg/(1.-qnk(i)) tvp(i, icb(i)) = tp(i, icb(i))*(1.+rg*epsi) END DO DO k = minorig, icbmax DO i = 1, len tvp(i, k) = tvp(i, k) - tp(i, k)*qnk(i) END DO END DO RETURN END SUBROUTINE cv_undilute1 SUBROUTINE cv_trigger(len, nd, icb, cbmf, tv, tvp, iflag) USE cvparam_mod_h IMPLICIT NONE ! ------------------------------------------------------------------- ! --- Test for instability. ! --- If there was no convection at last time step and parcel ! --- is stable at icb, then set iflag to 4. ! ------------------------------------------------------------------- ! inputs: INTEGER len, nd, icb(len) REAL cbmf(len), tv(len, nd), tvp(len, nd) ! outputs: INTEGER iflag(len) ! also an input ! local variables: INTEGER i DO i = 1, len IF ((cbmf(i)==0.0) .AND. (iflag(i)==0) .AND. (tvp(i, & icb(i))<=(tv(i,icb(i))-dtmax))) iflag(i) = 4 END DO RETURN END SUBROUTINE cv_trigger SUBROUTINE cv_compress(len, nloc, ncum, nd, iflag1, nk1, icb1, cbmf1, plcl1, & tnk1, qnk1, gznk1, t1, q1, qs1, u1, v1, gz1, h1, lv1, cpn1, p1, ph1, tv1, & tp1, tvp1, clw1, iflag, nk, icb, cbmf, plcl, tnk, qnk, gznk, t, q, qs, u, & v, gz, h, lv, cpn, p, ph, tv, tp, tvp, clw, dph) USE cvparam_mod_h USE print_control_mod, ONLY: lunout IMPLICIT NONE ! inputs: INTEGER len, ncum, nd, nloc INTEGER iflag1(len), nk1(len), icb1(len) REAL cbmf1(len), plcl1(len), tnk1(len), qnk1(len), gznk1(len) REAL t1(len, nd), q1(len, nd), qs1(len, nd), u1(len, nd), v1(len, nd) REAL gz1(len, nd), h1(len, nd), lv1(len, nd), cpn1(len, nd) REAL p1(len, nd), ph1(len, nd+1), tv1(len, nd), tp1(len, nd) REAL tvp1(len, nd), clw1(len, nd) ! outputs: INTEGER iflag(nloc), nk(nloc), icb(nloc) REAL cbmf(nloc), plcl(nloc), tnk(nloc), qnk(nloc), gznk(nloc) REAL t(nloc, nd), q(nloc, nd), qs(nloc, nd), u(nloc, nd), v(nloc, nd) REAL gz(nloc, nd), h(nloc, nd), lv(nloc, nd), cpn(nloc, nd) REAL p(nloc, nd), ph(nloc, nd+1), tv(nloc, nd), tp(nloc, nd) REAL tvp(nloc, nd), clw(nloc, nd) REAL dph(nloc, nd) ! local variables: INTEGER i, k, nn CHARACTER (LEN=20) :: modname = 'cv_compress' CHARACTER (LEN=80) :: abort_message 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 END DO IF (nn/=ncum) THEN WRITE (lunout, *) 'strange! nn not equal to ncum: ', nn, ncum abort_message = '' CALL abort_physic(modname, abort_message, 1) END IF 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 DO k = 1, nl DO i = 1, ncum dph(i, k) = ph(i, k) - ph(i, k+1) END DO END DO RETURN END SUBROUTINE cv_compress SUBROUTINE cv_undilute2(nloc, ncum, nd, icb, nk, tnk, qnk, gznk, t, q, qs, & gz, p, dph, h, tv, lv, inb, inb1, tp, tvp, clw, hp, ep, sigp, frac) USE cvparam_mod_h USE cvthermo_mod_h IMPLICIT NONE ! --------------------------------------------------------------------- ! Purpose: ! FIND THE REST OF THE LIFTED PARCEL TEMPERATURES ! & ! COMPUTE THE PRECIPITATION EFFICIENCIES AND THE ! FRACTION OF PRECIPITATION FALLING OUTSIDE OF CLOUD ! & ! FIND THE LEVEL OF NEUTRAL BUOYANCY ! --------------------------------------------------------------------- ! inputs: INTEGER ncum, nd, nloc INTEGER icb(nloc), nk(nloc) REAL t(nloc, nd), q(nloc, nd), qs(nloc, nd), gz(nloc, nd) REAL p(nloc, nd), dph(nloc, nd) REAL tnk(nloc), qnk(nloc), gznk(nloc) REAL lv(nloc, nd), tv(nloc, nd), h(nloc, nd) ! outputs: INTEGER inb(nloc), inb1(nloc) REAL tp(nloc, nd), tvp(nloc, nd), clw(nloc, nd) REAL ep(nloc, nd), sigp(nloc, nd), hp(nloc, nd) REAL frac(nloc) ! local variables: INTEGER i, k REAL tg, qg, ahg, alv, s, tc, es, denom, rg, tca, elacrit REAL by, defrac REAL ah0(nloc), cape(nloc), capem(nloc), byp(nloc) LOGICAL lcape(nloc) ! ===================================================================== ! --- SOME INITIALIZATIONS ! ===================================================================== DO k = 1, nl DO i = 1, ncum ep(i, k) = 0.0 sigp(i, k) = sigs END DO 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)- & t0)) + 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)-t0) ! First iteration. s = cpd + alv*alv*qg/(rrv*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 - t0 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/(rrv*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 - t0 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)-t0) ! 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) - t0 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 ! ===================================================================== ! --- 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 ! ===================================================================== ! initialization: DO i = 1, ncum*nlp hp(i, 1) = h(i, 1) END DO 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 RETURN END SUBROUTINE cv_undilute2 SUBROUTINE cv_closure(nloc, ncum, nd, nk, icb, tv, tvp, p, ph, dph, plcl, & cpn, iflag, cbmf) USE cvthermo_mod_h USE cvparam_mod_h IMPLICIT NONE ! inputs: INTEGER ncum, nd, nloc INTEGER nk(nloc), icb(nloc) REAL tv(nloc, nd), tvp(nloc, nd), p(nloc, nd), dph(nloc, nd) REAL ph(nloc, nd+1) ! caution nd instead ndp1 to be consistent... REAL plcl(nloc), cpn(nloc, nd) ! outputs: INTEGER iflag(nloc) REAL cbmf(nloc) ! also an input ! local variables: INTEGER i, k, icbmax REAL dtpbl(nloc), dtmin(nloc), tvpplcl(nloc), tvaplcl(nloc) REAL work(nloc) ! ------------------------------------------------------------------- ! Compute icbmax. ! ------------------------------------------------------------------- icbmax = 2 DO i = 1, ncum icbmax = max(icbmax, icb(i)) END DO ! ===================================================================== ! --- CALCULATE CLOUD BASE MASS FLUX ! ===================================================================== ! 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) - rrd*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 RETURN END SUBROUTINE cv_closure SUBROUTINE cv_mixing(nloc, ncum, nd, icb, nk, inb, inb1, ph, t, q, qs, u, v, & h, lv, qnk, hp, tv, tvp, ep, clw, cbmf, m, ment, qent, uent, vent, nent, & sij, elij) USE cvparam_mod_h USE cvthermo_mod_h IMPLICIT NONE ! inputs: INTEGER ncum, nd, nloc INTEGER icb(nloc), inb(nloc), inb1(nloc), nk(nloc) REAL cbmf(nloc), qnk(nloc) REAL ph(nloc, nd+1) REAL t(nloc, nd), q(nloc, nd), qs(nloc, nd), lv(nloc, nd) REAL u(nloc, nd), v(nloc, nd), h(nloc, nd), hp(nloc, nd) REAL tv(nloc, nd), tvp(nloc, nd), ep(nloc, nd), clw(nloc, nd) ! outputs: INTEGER nent(nloc, nd) REAL m(nloc, nd), ment(nloc, nd, nd), qent(nloc, nd, nd) REAL uent(nloc, nd, nd), vent(nloc, nd, nd) REAL sij(nloc, nd, nd), elij(nloc, nd, nd) ! local variables: INTEGER i, j, k, ij INTEGER num1, num2 REAL dbo, qti, bf2, anum, denom, dei, altem, cwat, stemp REAL alt, qp1, smid, sjmin, sjmax, delp, delm REAL work(nloc), asij(nloc), smin(nloc), scrit(nloc) REAL bsum(nloc, nd) LOGICAL lwork(nloc) ! ===================================================================== ! --- INITIALIZE VARIOUS ARRAYS USED IN THE COMPUTATIONS ! ===================================================================== DO i = 1, ncum*nlp nent(i, 1) = 0 m(i, 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) elij(i, k, j) = 0.0 ment(i, k, j) = 0.0 sij(i, k, j) = 0.0 END DO END DO 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)/(rrv*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 (smid1) 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 RETURN END SUBROUTINE cv_mixing SUBROUTINE cv_unsat(nloc, ncum, nd, inb, t, q, qs, gz, u, v, p, ph, h, lv, & ep, sigp, clw, m, ment, elij, iflag, mp, qp, up, vp, wt, water, evap) USE cvparam_mod_h USE cvthermo_mod_h IMPLICIT NONE ! inputs: INTEGER ncum, nd, nloc INTEGER inb(nloc) REAL t(nloc, nd), q(nloc, nd), qs(nloc, nd) REAL gz(nloc, nd), u(nloc, nd), v(nloc, nd) REAL p(nloc, nd), ph(nloc, nd+1), h(nloc, nd) REAL lv(nloc, nd), ep(nloc, nd), sigp(nloc, nd), clw(nloc, nd) REAL m(nloc, nd), ment(nloc, nd, nd), elij(nloc, nd, nd) ! outputs: INTEGER iflag(nloc) ! also an input REAL mp(nloc, nd), qp(nloc, nd), up(nloc, nd), vp(nloc, nd) REAL water(nloc, nd), evap(nloc, nd), wt(nloc, nd) ! local variables: INTEGER i, j, k, ij, num1 INTEGER jtt(nloc) REAL awat, coeff, qsm, afac, sigt, b6, c6, revap REAL dhdp, fac, qstm, rat REAL wdtrain(nloc) LOGICAL lwork(nloc) ! ===================================================================== ! --- PRECIPITATING DOWNDRAFT CALCULATION ! ===================================================================== ! Initializations: DO i = 1, ncum DO k = 1, nl + 1 wt(i, k) = omtsnow mp(i, k) = 0.0 evap(i, k) = 0.0 water(i, k) = 0.0 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, nl + 1 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 ! *** 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 RETURN END SUBROUTINE cv_unsat SUBROUTINE cv_yield(nloc, ncum, nd, nk, icb, inb, delt, t, q, u, v, gz, p, & ph, h, hp, lv, cpn, ep, clw, frac, m, mp, qp, up, vp, wt, water, evap, & ment, qent, uent, vent, nent, elij, tv, tvp, iflag, wd, qprime, tprime, & precip, cbmf, ft, fq, fu, fv, ma, qcondc) USE cvparam_mod_h USE cvthermo_mod_h IMPLICIT NONE ! inputs INTEGER ncum, nd, nloc INTEGER nk(nloc), icb(nloc), inb(nloc) INTEGER nent(nloc, nd) REAL delt REAL t(nloc, nd), q(nloc, nd), u(nloc, nd), v(nloc, nd) REAL gz(nloc, nd) REAL p(nloc, nd), ph(nloc, nd+1), h(nloc, nd) REAL hp(nloc, nd), lv(nloc, nd) REAL cpn(nloc, nd), ep(nloc, nd), clw(nloc, nd), frac(nloc) REAL m(nloc, nd), mp(nloc, nd), qp(nloc, nd) REAL up(nloc, nd), vp(nloc, nd) REAL wt(nloc, nd), water(nloc, nd), evap(nloc, nd) REAL ment(nloc, nd, nd), qent(nloc, nd, nd), elij(nloc, nd, nd) REAL uent(nloc, nd, nd), vent(nloc, nd, nd) REAL tv(nloc, nd), tvp(nloc, nd) ! outputs INTEGER iflag(nloc) ! also an input REAL cbmf(nloc) ! also an input REAL wd(nloc), tprime(nloc), qprime(nloc) REAL precip(nloc) REAL ft(nloc, nd), fq(nloc, nd), fu(nloc, nd), fv(nloc, nd) REAL ma(nloc, nd) REAL qcondc(nloc, nd) ! local variables INTEGER i, j, ij, k, num1 REAL dpinv, cpinv, awat, fqold, ftold, fuold, fvold, delti REAL work(nloc), am(nloc), amp1(nloc), ad(nloc) REAL ents(nloc), uav(nloc), vav(nloc), lvcp(nloc, nd) REAL qcond(nloc, nd), nqcond(nloc, nd), wa(nloc, nd) ! cld REAL siga(nloc, nd), ax(nloc, nd), mac(nloc, nd) ! cld ! -- initializations: delti = 1.0/delt DO i = 1, ncum precip(i) = 0.0 wd(i) = 0.0 tprime(i) = 0.0 qprime(i) = 0.0 DO k = 1, nl + 1 ft(i, k) = 0.0 fu(i, k) = 0.0 fv(i, k) = 0.0 fq(i, k) = 0.0 lvcp(i, k) = lv(i, k)/cpn(i, k) qcondc(i, k) = 0.0 ! cld qcond(i, k) = 0.0 ! cld nqcond(i, k) = 0.0 ! cld END DO 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 *** DO i = 1, ncum wd(i) = betad*abs(mp(i,icb(i)))*0.01*rrd*t(i, icb(i))/(sigd*p(i,icb(i))) qprime(i) = 0.5*(qp(i,1)-q(i,1)) tprime(i) = lv0*qprime(i)/cpd END DO ! *** 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 & )) ! (saturated updrafts resulting from mixing) ! cld qcond(ij, i) = qcond(ij, i) + (elij(ij,k,i)-awat) ! cld nqcond(ij, i) = nqcond(ij, i) + 1. ! cld 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 ! (saturated downdrafts resulting from mixing) ! cld DO k = i + 1, inb(ij) ! cld qcond(ij, i) = qcond(ij, i) + elij(ij, k, i) ! cld nqcond(ij, i) = nqcond(ij, i) + 1. ! cld END DO ! cld ! (particular case: no detraining level is found) ! cld IF (nent(ij,i)==0) THEN ! cld qcond(ij, i) = qcond(ij, i) + (1.-ep(ij,i))*clw(ij, i) ! cld nqcond(ij, i) = nqcond(ij, i) + 1. ! cld END IF ! cld IF (nqcond(ij,i)/=0.) THEN ! cld qcond(ij, i) = qcond(ij, i)/nqcond(ij, i) ! cld END IF ! cld 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 qcondc(i, k) = 0.0 ! cld END IF END DO END DO DO k = 1, nl + 1 DO i = 1, ncum 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 ! *** diagnose the in-cloud mixing ratio *** ! cld ! *** of condensed water *** ! cld ! ! cld DO ij = 1, ncum ! cld DO i = 1, nd ! cld mac(ij, i) = 0.0 ! cld wa(ij, i) = 0.0 ! cld siga(ij, i) = 0.0 ! cld END DO ! cld DO i = nk(ij), inb(ij) ! cld DO k = i + 1, inb(ij) + 1 ! cld mac(ij, i) = mac(ij, i) + m(ij, k) ! cld END DO ! cld END DO ! cld DO i = icb(ij), inb(ij) - 1 ! cld ax(ij, i) = 0. ! cld DO j = icb(ij), i ! cld ax(ij, i) = ax(ij, i) + rrd*(tvp(ij,j)-tv(ij,j)) & ! cld *(ph(ij,j)-ph(ij,j+1))/p(ij, j) ! cld END DO ! cld IF (ax(ij,i)>0.0) THEN ! cld wa(ij, i) = sqrt(2.*ax(ij,i)) ! cld END IF ! cld END DO ! cld DO i = 1, nl ! cld IF (wa(ij,i)>0.0) & ! cld siga(ij, i) = mac(ij, i)/wa(ij, i) & ! cld *rrd*tvp(ij, i)/p(ij, i)/100./delta ! cld siga(ij, i) = min(siga(ij,i), 1.0) ! cld qcondc(ij, i) = siga(ij, i)*clw(ij, i)*(1.-ep(ij,i)) & ! cld +(1.-siga(ij,i))*qcond(ij, i) ! cld END DO ! cld END DO ! cld RETURN END SUBROUTINE cv_yield SUBROUTINE cv_uncompress(nloc, len, ncum, nd, idcum, iflag, precip, cbmf, ft, & fq, fu, fv, ma, qcondc, iflag1, precip1, cbmf1, ft1, fq1, fu1, fv1, ma1, & qcondc1) USE cvparam_mod_h IMPLICIT NONE ! inputs: INTEGER len, ncum, nd, nloc INTEGER idcum(nloc) INTEGER iflag(nloc) REAL precip(nloc), cbmf(nloc) REAL ft(nloc, nd), fq(nloc, nd), fu(nloc, nd), fv(nloc, nd) REAL ma(nloc, nd) REAL qcondc(nloc, nd) !cld ! outputs: INTEGER iflag1(len) REAL precip1(len), cbmf1(len) REAL ft1(len, nd), fq1(len, nd), fu1(len, nd), fv1(len, nd) REAL ma1(len, nd) REAL qcondc1(len, nd) !cld ! local variables: INTEGER i, k 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) ma1(idcum(i), k) = ma(i, k) qcondc1(idcum(i), k) = qcondc(i, k) END DO END DO RETURN END SUBROUTINE cv_uncompress