SUBROUTINE cv3_vertmix(len, nd, iflag, plim1, plim2, p, ph, t, q, u, v, w, & wi, nk, tmix, thmix, qmix, qsmix, umix, vmix, plcl) ! ************************************************************** ! * ! CV3_VERTMIX Brassage adiabatique d'une couche d'epaisseur * ! arbitraire. * ! * ! written by : Grandpeix Jean-Yves, 28/12/2001, 13.14.24 * ! modified by : Filiberti M-A 06/2005 vectorisation * ! ************************************************************** IMPLICIT NONE ! ============================================================== ! vertmix : determine theta et r du melange obtenu en brassant ! adiabatiquement entre plim1 et plim2, avec une ponderation w. ! =============================================================== include "cvthermo.h" include "YOETHF.h" include "YOMCST.h" include "FCTTRE.h" ! input : INTEGER nd, len INTEGER nk(len), iflag(len) REAL t(len, nd), q(len, nd), w(nd) REAL u(len, nd), v(len, nd) REAL p(len, nd), ph(len, nd+1) REAL plim1(len), plim2(len) ! output : REAL tmix(len), thmix(len), qmix(len), wi(len, nd) REAL umix(len), vmix(len) REAL qsmix(len) REAL plcl(len) ! internal variables : INTEGER j1(len), j2(len), niflag7 REAL a, b REAL ahm(len), dpw(len), coef(len) REAL p1(len, nd), p2(len, nd) REAL rdcp(len), a2(len), b2(len), pnk(len) REAL rh(len), chi(len) REAL cpn REAL x, y, p0, p0m1, zdelta, zcor INTEGER i, j DO j = 1, nd DO i = 1, len IF (plim1(i)<=ph(i,j)) j1(i) = j IF (plim2(i)>=ph(i,j+1) .AND. plim2(i)=j1(i) .AND. j<=j2(i)) THEN p1(i, j) = min(ph(i,j), plim1(i)) p2(i, j) = max(ph(i,j+1), plim2(i)) ! CRtest:couplage thermiques: deja normalise ! wi(i,j) = w(j) ! print*,'wi',wi(i,j) wi(i, j) = w(j)*(p1(i,j)-p2(i,j))*coef(i) dpw(i) = dpw(i) + wi(i, j) END IF END DO END DO ! CR:print ! do i=1,len ! print*,'plim',plim1(i),plim2(i) ! enddo DO j = 1, nd DO i = 1, len IF (j>=j1(i) .AND. j<=j2(i)) THEN wi(i, j) = wi(i, j)/dpw(i) ahm(i) = ahm(i) + (cpd*(1.-q(i,j))+q(i,j)*cpv)*t(i, j)*wi(i, j) qmix(i) = qmix(i) + q(i, j)*wi(i, j) umix(i) = umix(i) + u(i, j)*wi(i, j) vmix(i) = vmix(i) + v(i, j)*wi(i, j) END IF END DO END DO DO i = 1, len rdcp(i) = (rrd*(1.-qmix(i))+qmix(i)*rrv)/(cpd*(1.-qmix(i))+qmix(i)*cpv) END DO DO j = 1, nd DO i = 1, len IF (j>=j1(i) .AND. j<=j2(i)) THEN ! c x=(.5*(p1(i,j)+p2(i,j))*p0m1)**rdcp(i) y = (.5*(p1(i,j)+p2(i,j))/pnk(i))**rdcp(i) ! c a2(i)=a2(i)+(cpd*(1.-qmix(i))+qmix(i)*cpv)*x*wi(i,j) b2(i) = b2(i) + (cpd*(1.-qmix(i))+qmix(i)*cpv)*y*wi(i, j) END IF END DO END DO DO i = 1, len tmix(i) = ahm(i)/b2(i) thmix(i) = tmix(i)*(p0/pnk(i))**rdcp(i) ! print*,'thmix ahm',ahm(i),b2(i) ! print*,'thmix t',tmix(i),p0 ! print*,'thmix p',pnk(i),rdcp(i) ! print*,'thmix',thmix(i) ! c thmix(i) = ahm(i)/a2(i) ! c tmix(i)= thmix(i)*(pnk(i)*p0m1)**rdcp(i) zdelta = max(0., sign(1.,rtt-tmix(i))) qsmix(i) = r2es*foeew(tmix(i), zdelta)/(pnk(i)*100.) qsmix(i) = min(0.5, qsmix(i)) zcor = 1./(1.-retv*qsmix(i)) qsmix(i) = qsmix(i)*zcor END DO ! ------------------------------------------------------------------- ! --- Calculate lifted condensation level of air at parcel origin level ! --- (Within 0.2% of formula of Bolton, MON. WEA. REV.,1980) ! ------------------------------------------------------------------- a = 1669.0 ! convect3 b = 122.0 ! convect3 niflag7 = 0 DO i = 1, len IF (iflag(i)/=7) THEN ! modif sb Jun7th 2002 rh(i) = qmix(i)/qsmix(i) chi(i) = tmix(i)/(a-b*rh(i)-tmix(i)) ! convect3 ! ATTENTION, la LIGNE DESSOUS A ETE RAJOUTEE ARBITRAIREMENT ET ! MASQUE UN PB POTENTIEL chi(i) = max(chi(i), 0.) rh(i) = max(rh(i), 0.) 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 ELSE niflag7 = niflag7 + 1 plcl(i) = plim2(i) END IF ! iflag=7 ! print*,'NIFLAG7 =',niflag7 END DO RETURN END SUBROUTINE cv3_vertmix