SUBROUTINE thermcell_2002(ngrid,nlay,ptimestep s ,pplay,pplev,pphi s ,pu,pv,pt,po s ,pduadj,pdvadj,pdtadj,pdoadj s ,fm0,entr0 c s ,pu_therm,pv_therm s ,r_aspect,l_mix,w2di,tho) IMPLICIT NONE c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c c Réécriture à partir d'un listing papier à Habas, le 14/02/00 c c le thermique est supposé homogène et dissipé par mélange avec c son environnement. la longueur l_mix contrôle l'efficacité du c mélange c c Le calcul du transport des différentes espèces se fait en prenant c en compte: c 1. un flux de masse montant c 2. un flux de masse descendant c 3. un entrainement c 4. un detrainement c c======================================================================= c----------------------------------------------------------------------- c declarations: c ------------- #include "dimensions.h" #include "dimphy.h" #include "YOMCST.h" c arguments: c ---------- INTEGER ngrid,nlay,w2di,tho real ptimestep,l_mix,r_aspect REAL pt(ngrid,nlay),pdtadj(ngrid,nlay) REAL pu(ngrid,nlay),pduadj(ngrid,nlay) REAL pv(ngrid,nlay),pdvadj(ngrid,nlay) REAL po(ngrid,nlay),pdoadj(ngrid,nlay) REAL pplay(ngrid,nlay),pplev(ngrid,nlay+1) real pphi(ngrid,nlay) integer idetr save idetr data idetr/3/ c local: c ------ INTEGER ig,k,l,lmax(klon,klev+1),lmaxa(klon),lmix(klon) real zmax(klon),zw,zz,zw2(klon,klev+1),ztva(klon,klev),zzz real zlev(klon,klev+1),zlay(klon,klev) REAL zh(klon,klev),zdhadj(klon,klev) REAL ztv(klon,klev) real zu(klon,klev),zv(klon,klev),zo(klon,klev) REAL wh(klon,klev+1) real wu(klon,klev+1),wv(klon,klev+1),wo(klon,klev+1) real zla(klon,klev+1) real zwa(klon,klev+1) real zld(klon,klev+1) real zwd(klon,klev+1) real zsortie(klon,klev) real zva(klon,klev) real zua(klon,klev) real zoa(klon,klev) real zha(klon,klev) real wa_moy(klon,klev+1) real fraca(klon,klev+1) real fracc(klon,klev+1) real zf,zf2 real thetath2(klon,klev),wth2(klon,klev) common/comtherm/thetath2,wth2 real count_time integer isplit,nsplit,ialt parameter (nsplit=10) data isplit/0/ save isplit logical sorties real rho(klon,klev),rhobarz(klon,klev+1),masse(klon,klev) real zpspsk(klon,klev) real wmax(klon,klev),wmaxa(klon) real wa(klon,klev,klev+1) real wd(klon,klev+1) real larg_part(klon,klev,klev+1) real fracd(klon,klev+1) real xxx(klon,klev+1) real larg_cons(klon,klev+1) real larg_detr(klon,klev+1) real fm0(klon,klev+1),entr0(klon,klev),detr(klon,klev) real pu_therm(klon,klev),pv_therm(klon,klev) real fm(klon,klev+1),entr(klon,klev) real fmc(klon,klev+1) character*2 str2 character*10 str10 LOGICAL vtest(klon),down EXTERNAL SCOPY integer ncorrec,ll save ncorrec data ncorrec/0/ c c----------------------------------------------------------------------- c initialisation: c --------------- c sorties=.true. IF(ngrid.NE.klon) THEN PRINT* PRINT*,'STOP dans convadj' PRINT*,'ngrid =',ngrid PRINT*,'klon =',klon ENDIF c c----------------------------------------------------------------------- c incrementation eventuelle de tendances precedentes: c --------------------------------------------------- print*,'0 OK convect8' DO 1010 l=1,nlay DO 1015 ig=1,ngrid zpspsk(ig,l)=(pplay(ig,l)/pplev(ig,1))**RKAPPA zh(ig,l)=pt(ig,l)/zpspsk(ig,l) zu(ig,l)=pu(ig,l) zv(ig,l)=pv(ig,l) zo(ig,l)=po(ig,l) ztv(ig,l)=zh(ig,l)*(1.+0.61*zo(ig,l)) 1015 CONTINUE 1010 CONTINUE c print*,'1 OK convect8' c -------------------- c c c + + + + + + + + + + + c c c wa, fraca, wd, fracd -------------------- zlev(2), rhobarz c wh,wt,wo ... c c + + + + + + + + + + + zh,zu,zv,zo,rho c c c -------------------- zlev(1) c \\\\\\\\\\\\\\\\\\\\ c c c----------------------------------------------------------------------- c Calcul des altitudes des couches c----------------------------------------------------------------------- do l=2,nlay do ig=1,ngrid zlev(ig,l)=0.5*(pphi(ig,l)+pphi(ig,l-1))/RG enddo enddo do ig=1,ngrid zlev(ig,1)=0. zlev(ig,nlay+1)=(2.*pphi(ig,klev)-pphi(ig,klev-1))/RG enddo do l=1,nlay do ig=1,ngrid zlay(ig,l)=pphi(ig,l)/RG enddo enddo c print*,'2 OK convect8' c----------------------------------------------------------------------- c Calcul des densites c----------------------------------------------------------------------- do l=1,nlay do ig=1,ngrid rho(ig,l)=pplay(ig,l)/(zpspsk(ig,l)*RD*zh(ig,l)) enddo enddo do l=2,nlay do ig=1,ngrid rhobarz(ig,l)=0.5*(rho(ig,l)+rho(ig,l-1)) enddo enddo do k=1,nlay do l=1,nlay+1 do ig=1,ngrid wa(ig,k,l)=0. enddo enddo enddo c print*,'3 OK convect8' c------------------------------------------------------------------ c Calcul de w2, quarre de w a partir de la cape c a partir de w2, on calcule wa, vitesse de l'ascendance c c ATTENTION: Dans cette version, pour cause d'economie de memoire, c w2 est stoke dans wa c c ATTENTION: dans convect8, on n'utilise le calcule des wa c independants par couches que pour calculer l'entrainement c a la base et la hauteur max de l'ascendance. c c Indicages: c l'ascendance provenant du niveau k traverse l'interface l avec c une vitesse wa(k,l). c c -------------------- c c + + + + + + + + + + c c wa(k,l) ---- -------------------- l c /\ c /||\ + + + + + + + + + + c || c || -------------------- c || c || + + + + + + + + + + c || c || -------------------- c ||__ c |___ + + + + + + + + + + k c c -------------------- c c c c------------------------------------------------------------------ do k=1,nlay-1 do ig=1,ngrid wa(ig,k,k)=0. wa(ig,k,k+1)=2.*RG*(ztv(ig,k)-ztv(ig,k+1))/ztv(ig,k+1) s *(zlev(ig,k+1)-zlev(ig,k)) enddo do l=k+1,nlay-1 do ig=1,ngrid wa(ig,k,l+1)=wa(ig,k,l)+ s 2.*RG*(ztv(ig,k)-ztv(ig,l))/ztv(ig,l) s *(zlev(ig,l+1)-zlev(ig,l)) enddo enddo do ig=1,ngrid wa(ig,k,nlay+1)=0. enddo enddo c print*,'4 OK convect8' c Calcul de la couche correspondant a la hauteur du thermique do k=1,nlay-1 do ig=1,ngrid lmax(ig,k)=k enddo do l=nlay,k+1,-1 do ig=1,ngrid if(wa(ig,k,l).le.1.e-10) lmax(ig,k)=l-1 enddo enddo enddo c print*,'5 OK convect8' c Calcule du w max du thermique do k=1,nlay do ig=1,ngrid wmax(ig,k)=0. enddo enddo do k=1,nlay-1 do l=k,nlay do ig=1,ngrid if (l.le.lmax(ig,k)) then wa(ig,k,l)=sqrt(wa(ig,k,l)) wmax(ig,k)=max(wmax(ig,k),wa(ig,k,l)) else wa(ig,k,l)=0. endif enddo enddo enddo do k=1,nlay-1 do ig=1,ngrid pu_therm(ig,k)=sqrt(wmax(ig,k)) pv_therm(ig,k)=sqrt(wmax(ig,k)) enddo enddo c print*,'6 OK convect8' c Longueur caracteristique correspondant a la hauteur des thermiques. do ig=1,ngrid zmax(ig)=500. enddo c print*,'LMAX LMAX LMAX ' do k=1,nlay-1 do ig=1,ngrid zmax(ig)=max(zmax(ig),zlev(ig,lmax(ig,k))-zlev(ig,k)) enddo c print*,k,lmax(1,k) enddo c print*,'ZMAX ZMAX ZMAX ',zmax c call dump2d(iim,jjm-1,zmax(2:ngrid-1),'ZMAX ') c Calcul de l'entrainement. c Le rapport d'aspect relie la largeur de l'ascendance a l'epaisseur c de la couche d'alimentation en partant du principe que la vitesse c maximum dans l'ascendance est la vitesse d'entrainement horizontale. do k=1,nlay do ig=1,ngrid zzz=rho(ig,k)*wmax(ig,k)*(zlev(ig,k+1)-zlev(ig,k)) s /(zmax(ig)*r_aspect) if(w2di.eq.2) then entr(ig,k)=entr(ig,k)+ s ptimestep*(zzz-entr(ig,k))/float(tho) else entr(ig,k)=zzz endif ztva(ig,k)=ztv(ig,k) enddo enddo c print*,'7 OK convect8' do k=1,klev+1 do ig=1,ngrid zw2(ig,k)=0. fmc(ig,k)=0. larg_cons(ig,k)=0. larg_detr(ig,k)=0. wa_moy(ig,k)=0. enddo enddo c print*,'8 OK convect8' do ig=1,ngrid lmaxa(ig)=1 lmix(ig)=1 wmaxa(ig)=0. enddo do l=1,nlay-2 do ig=1,ngrid c if (zw2(ig,l).lt.1.e-10.and.ztv(ig,l).gt.ztv(ig,l+1)) then c print*,'COUCOU ',l,zw2(ig,l),ztv(ig,l),ztv(ig,l+1) if (zw2(ig,l).lt.1.e-10.and.ztv(ig,l).gt.ztv(ig,l+1) s .and.entr(ig,l).gt.1.e-10) then c print*,'COUCOU cas 1' c Initialisation de l'ascendance c lmix(ig)=1 ztva(ig,l)=ztv(ig,l) fmc(ig,l)=0. fmc(ig,l+1)=entr(ig,l) zw2(ig,l)=0. c if (.not.ztv(ig,l+1).gt.150.) then c print*,'ig,l+1,ztv(ig,l+1)' c print*, ig,l+1,ztv(ig,l+1) c stop'dans thermiques' c endif zw2(ig,l+1)=2.*RG*(ztv(ig,l)-ztv(ig,l+1))/ztv(ig,l+1) s *(zlev(ig,l+1)-zlev(ig,l)) larg_detr(ig,l)=0. else if (zw2(ig,l).ge.1.e-10.and. . fmc(ig,l)+entr(ig,l).gt.1.e-10) then c Incrementation... fmc(ig,l+1)=fmc(ig,l)+entr(ig,l) c if (.not.fmc(ig,l+1).gt.1.e-15) then c print*,'ig,l+1,fmc(ig,l+1)' c print*, ig,l+1,fmc(ig,l+1) c print*,'Fmc ',(fmc(ig,ll),ll=1,klev+1) c print*,'W2 ',(zw2(ig,ll),ll=1,klev+1) c print*,'Tv ',(ztv(ig,ll),ll=1,klev) c print*,'Entr ',(entr(ig,ll),ll=1,klev) c stop'dans thermiques' c endif ztva(ig,l)=(fmc(ig,l)*ztva(ig,l-1)+entr(ig,l)*ztv(ig,l)) s /fmc(ig,l+1) c mise a jour de la vitesse ascendante (l'air entraine de la couche c consideree commence avec une vitesse nulle). zw2(ig,l+1)=zw2(ig,l)*(fmc(ig,l)/fmc(ig,l+1))**2+ s 2.*RG*(ztva(ig,l)-ztv(ig,l))/ztv(ig,l) s *(zlev(ig,l+1)-zlev(ig,l)) endif if (zw2(ig,l+1).lt.0.) then zw2(ig,l+1)=0. lmaxa(ig)=l else wa_moy(ig,l+1)=sqrt(zw2(ig,l+1)) endif if (wa_moy(ig,l+1).gt.wmaxa(ig)) then c lmix est le niveau de la couche ou w (wa_moy) est maximum lmix(ig)=l+1 wmaxa(ig)=wa_moy(ig,l+1) endif c print*,'COUCOU cas 2 LMIX=',lmix(ig),wa_moy(ig,l+1),wmaxa(ig) enddo enddo c print*,'9 OK convect8' c print*,'WA1 ',wa_moy c determination de l'indice du debut de la mixed layer ou w decroit c calcul de la largeur de chaque ascendance dans le cas conservatif. c dans ce cas simple, on suppose que la largeur de l'ascendance provenant c d'une couche est égale à la hauteur de la couche alimentante. c La vitesse maximale dans l'ascendance est aussi prise comme estimation c de la vitesse d'entrainement horizontal dans la couche alimentante. do l=2,nlay do ig=1,ngrid if (l.le.lmaxa(ig)) then zw=max(wa_moy(ig,l),1.e-10) larg_cons(ig,l)=zmax(ig)*r_aspect s *fmc(ig,l)/(rhobarz(ig,l)*zw) endif enddo enddo do l=2,nlay do ig=1,ngrid if (l.le.lmaxa(ig)) then c if (idetr.eq.0) then c cette option est finalement en dur. larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c else if (idetr.eq.1) then c larg_detr(ig,l)=larg_cons(ig,l) c s *sqrt(l_mix*zlev(ig,l))/larg_cons(ig,lmix(ig)) c else if (idetr.eq.2) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *sqrt(wa_moy(ig,l)) c else if (idetr.eq.4) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *wa_moy(ig,l) c endif endif enddo enddo c print*,'10 OK convect8' c print*,'WA2 ',wa_moy c calcul de la fraction de la maille concernée par l'ascendance en tenant c compte de l'epluchage du thermique. do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1.) then c print*,ig,l,lmix(ig),lmaxa(ig),larg_cons(ig,l),' KKK' fraca(ig,l)=(larg_cons(ig,l)-larg_detr(ig,l)) s /(r_aspect*zmax(ig)) if(l.gt.lmix(ig)) then xxx(ig,l)=(lmaxa(ig)+1.-l) / (lmaxa(ig)+1.-lmix(ig)) if (idetr.eq.0) then fraca(ig,l)=fraca(ig,lmix(ig)) else if (idetr.eq.1) then fraca(ig,l)=fraca(ig,lmix(ig))*xxx(ig,l) else if (idetr.eq.2) then fraca(ig,l)=fraca(ig,lmix(ig))*(1.-(1.-xxx(ig,l))**2) else fraca(ig,l)=fraca(ig,lmix(ig))*xxx(ig,l)**2 endif endif c print*,ig,l,lmix(ig),lmaxa(ig),xxx(ig,l),'LLLLLLL' fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) else c wa_moy(ig,l)=0. fraca(ig,l)=0. fracc(ig,l)=0. fracd(ig,l)=1. endif enddo enddo c print*,'11 OK convect8' c print*,'Ea3 ',wa_moy c------------------------------------------------------------------ c Calcul de fracd, wd c somme wa - wd = 0 c------------------------------------------------------------------ do ig=1,ngrid fm(ig,1)=0. fm(ig,nlay+1)=0. enddo do l=2,nlay do ig=1,ngrid fm(ig,l)=fraca(ig,l)*wa_moy(ig,l)*rhobarz(ig,l) enddo do ig=1,ngrid if(fracd(ig,l).lt.0.1) then stop'fracd trop petit' else c vitesse descendante "diagnostique" wd(ig,l)=fm(ig,l)/(fracd(ig,l)*rhobarz(ig,l)) endif enddo enddo do l=1,nlay do ig=1,ngrid c masse(ig,l)=rho(ig,l)*(zlev(ig,l+1)-zlev(ig,l)) masse(ig,l)=(pplev(ig,l)-pplev(ig,l+1))/RG enddo enddo c print*,'12 OK convect8' c print*,'WA4 ',wa_moy cc------------------------------------------------------------------ c calcul du transport vertical c------------------------------------------------------------------ go to 4444 c print*,'XXXXXXXXXXXXXXX ptimestep= ',ptimestep do l=2,nlay-1 do ig=1,ngrid if(fm(ig,l+1)*ptimestep.gt.masse(ig,l) s .and.fm(ig,l+1)*ptimestep.gt.masse(ig,l+1)) then c print*,'WARN!!! FM>M ig=',ig,' l=',l,' FM=' c s ,fm(ig,l+1)*ptimestep c s ,' M=',masse(ig,l),masse(ig,l+1) endif enddo enddo do l=1,nlay do ig=1,ngrid if(entr(ig,l)*ptimestep.gt.masse(ig,l)) then c print*,'WARN!!! E>M ig=',ig,' l=',l,' E==' c s ,entr(ig,l)*ptimestep c s ,' M=',masse(ig,l) endif enddo enddo do l=1,nlay do ig=1,ngrid if(.not.fm(ig,l).ge.0..or..not.fm(ig,l).le.10.) then c print*,'WARN!!! fm exagere ig=',ig,' l=',l c s ,' FM=',fm(ig,l) endif if(.not.masse(ig,l).ge.1.e-10 s .or..not.masse(ig,l).le.1.e4) then c print*,'WARN!!! masse exagere ig=',ig,' l=',l c s ,' M=',masse(ig,l) c print*,'rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l)', c s rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l) c print*,'zlev(ig,l+1),zlev(ig,l)' c s ,zlev(ig,l+1),zlev(ig,l) c print*,'pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1)' c s ,pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1) endif if(.not.entr(ig,l).ge.0..or..not.entr(ig,l).le.10.) then c print*,'WARN!!! entr exagere ig=',ig,' l=',l c s ,' E=',entr(ig,l) endif enddo enddo 4444 continue if (w2di.eq.1) then fm0=fm0+ptimestep*(fm-fm0)/float(tho) entr0=entr0+ptimestep*(entr-entr0)/float(tho) else fm0=fm entr0=entr endif if (1.eq.1) then call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zh,zdhadj,zha) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zo,pdoadj,zoa) else call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zh,zdhadj,zha) call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zo,pdoadj,zoa) endif if (1.eq.0) then call dvthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse . ,fraca,zmax . ,zu,zv,pduadj,pdvadj,zua,zva) else call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zu,pduadj,zua) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zv,pdvadj,zva) endif do l=1,nlay do ig=1,ngrid zf=0.5*(fracc(ig,l)+fracc(ig,l+1)) zf2=zf/(1.-zf) thetath2(ig,l)=zf2*(zha(ig,l)-zh(ig,l))**2 wth2(ig,l)=zf2*(0.5*(wa_moy(ig,l)+wa_moy(ig,l+1)))**2 enddo enddo c print*,'13 OK convect8' c print*,'WA5 ',wa_moy do l=1,nlay do ig=1,ngrid pdtadj(ig,l)=zdhadj(ig,l)*zpspsk(ig,l) enddo enddo c do l=1,nlay c do ig=1,ngrid c if(abs(pdtadj(ig,l))*86400..gt.500.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdtadj=',pdtadj(ig,l) c endif c if(abs(pdoadj(ig,l))*86400..gt.1.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdoadj=',pdoadj(ig,l) c endif c enddo c enddo c print*,'14 OK convect8' c------------------------------------------------------------------ c Calculs pour les sorties c------------------------------------------------------------------ if(sorties) then do l=1,nlay do ig=1,ngrid zla(ig,l)=(1.-fracd(ig,l))*zmax(ig) zld(ig,l)=fracd(ig,l)*zmax(ig) if(1.-fracd(ig,l).gt.1.e-10) s zwa(ig,l)=wd(ig,l)*fracd(ig,l)/(1.-fracd(ig,l)) enddo enddo do l=1,nlay do ig=1,ngrid detr(ig,l)=fm(ig,l)+entr(ig,l)-fm(ig,l+1) if (detr(ig,l).lt.0.) then entr(ig,l)=entr(ig,l)-detr(ig,l) detr(ig,l)=0. c print*,'WARNING !!! detrainement negatif ',ig,l endif enddo enddo c print*,'15 OK convect8' isplit=isplit+1 c #define und goto 123 #ifdef und CALL writeg1d(1,nlay,wd,'wd ','wd ') CALL writeg1d(1,nlay,zwa,'wa ','wa ') CALL writeg1d(1,nlay,fracd,'fracd ','fracd ') CALL writeg1d(1,nlay,fraca,'fraca ','fraca ') CALL writeg1d(1,nlay,wa_moy,'wam ','wam ') CALL writeg1d(1,nlay,zla,'la ','la ') CALL writeg1d(1,nlay,zld,'ld ','ld ') CALL writeg1d(1,nlay,pt,'pt ','pt ') CALL writeg1d(1,nlay,zh,'zh ','zh ') CALL writeg1d(1,nlay,zha,'zha ','zha ') CALL writeg1d(1,nlay,zu,'zu ','zu ') CALL writeg1d(1,nlay,zv,'zv ','zv ') CALL writeg1d(1,nlay,zo,'zo ','zo ') CALL writeg1d(1,nlay,wh,'wh ','wh ') CALL writeg1d(1,nlay,wu,'wu ','wu ') CALL writeg1d(1,nlay,wv,'wv ','wv ') CALL writeg1d(1,nlay,wo,'w15uo ','wXo ') CALL writeg1d(1,nlay,zdhadj,'zdhadj ','zdhadj ') CALL writeg1d(1,nlay,pduadj,'pduadj ','pduadj ') CALL writeg1d(1,nlay,pdvadj,'pdvadj ','pdvadj ') CALL writeg1d(1,nlay,pdoadj,'pdoadj ','pdoadj ') CALL writeg1d(1,nlay,entr ,'entr ','entr ') CALL writeg1d(1,nlay,detr ,'detr ','detr ') CALL writeg1d(1,nlay,fm ,'fm ','fm ') CALL writeg1d(1,nlay,pdtadj,'pdtadj ','pdtadj ') CALL writeg1d(1,nlay,pplay,'pplay ','pplay ') CALL writeg1d(1,nlay,pplev,'pplev ','pplev ') c recalcul des flux en diagnostique... c print*,'PAS DE TEMPS ',ptimestep call dt2F(pplev,pplay,pt,pdtadj,wh) CALL writeg1d(1,nlay,wh,'wh2 ','wh2 ') #endif 123 continue ! #define troisD #ifdef troisD c if (sorties) then print*,'Debut des wrgradsfi' c print*,'16 OK convect8' call wrgradsfi(1,nlay,wd,'wd ','wd ') call wrgradsfi(1,nlay,zwa,'wa ','wa ') call wrgradsfi(1,nlay,fracd,'fracd ','fracd ') call wrgradsfi(1,nlay,fraca,'fraca ','fraca ') call wrgradsfi(1,nlay,xxx,'xxx ','xxx ') call wrgradsfi(1,nlay,wa_moy,'wam ','wam ') c print*,'WA6 ',wa_moy call wrgradsfi(1,nlay,zla,'la ','la ') call wrgradsfi(1,nlay,zld,'ld ','ld ') call wrgradsfi(1,nlay,pt,'pt ','pt ') call wrgradsfi(1,nlay,zh,'zh ','zh ') call wrgradsfi(1,nlay,zha,'zha ','zha ') call wrgradsfi(1,nlay,zua,'zua ','zua ') call wrgradsfi(1,nlay,zva,'zva ','zva ') call wrgradsfi(1,nlay,zu,'zu ','zu ') call wrgradsfi(1,nlay,zv,'zv ','zv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,wh,'wh ','wh ') call wrgradsfi(1,nlay,wu,'wu ','wu ') call wrgradsfi(1,nlay,wv,'wv ','wv ') call wrgradsfi(1,nlay,wo,'wo ','wo ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,nlay,zdhadj,'zdhadj ','zdhadj ') call wrgradsfi(1,nlay,pduadj,'pduadj ','pduadj ') call wrgradsfi(1,nlay,pdvadj,'pdvadj ','pdvadj ') call wrgradsfi(1,nlay,pdoadj,'pdoadj ','pdoadj ') call wrgradsfi(1,nlay,entr,'entr ','entr ') call wrgradsfi(1,nlay,detr,'detr ','detr ') call wrgradsfi(1,nlay,fm,'fm ','fm ') call wrgradsfi(1,nlay,fmc,'fmc ','fmc ') call wrgradsfi(1,nlay,zw2,'zw2 ','zw2 ') call wrgradsfi(1,nlay,ztva,'ztva ','ztva ') call wrgradsfi(1,nlay,ztv,'ztv ','ztv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,larg_cons,'Lc ','Lc ') call wrgradsfi(1,nlay,larg_detr,'Ldetr ','Ldetr ') c print*,'17 OK convect8' do k=1,klev/10 write(str2,'(i2.2)') k str10='wa'//str2 do l=1,nlay do ig=1,ngrid zsortie(ig,l)=wa(ig,k,l) enddo enddo CALL wrgradsfi(1,nlay,zsortie,str10,str10) do l=1,nlay do ig=1,ngrid zsortie(ig,l)=larg_part(ig,k,l) enddo enddo str10='la'//str2 CALL wrgradsfi(1,nlay,zsortie,str10,str10) enddo c print*,'18 OK convect8' c endif print*,'Fin des wrgradsfi' #endif endif c if(wa_moy(1,4).gt.1.e-10) stop c print*,'19 OK convect8' return end SUBROUTINE thermcell_cld(ngrid,nlay,ptimestep s ,pplay,pplev,pphi,zlev,debut s ,pu,pv,pt,po s ,pduadj,pdvadj,pdtadj,pdoadj s ,fm0,entr0,zqla,lmax s ,zmax_sec,wmax_sec,zw_sec,lmix_sec s ,ratqscth,ratqsdiff c s ,pu_therm,pv_therm s ,r_aspect,l_mix,w2di,tho) IMPLICIT NONE c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c c Réécriture à partir d'un listing papier à Habas, le 14/02/00 c c le thermique est supposé homogène et dissipé par mélange avec c son environnement. la longueur l_mix contrôle l'efficacité du c mélange c c Le calcul du transport des différentes espèces se fait en prenant c en compte: c 1. un flux de masse montant c 2. un flux de masse descendant c 3. un entrainement c 4. un detrainement c c======================================================================= c----------------------------------------------------------------------- c declarations: c ------------- #include "dimensions.h" #include "dimphy.h" #include "YOMCST.h" #include "YOETHF.h" #include "FCTTRE.h" c arguments: c ---------- INTEGER ngrid,nlay,w2di,tho real ptimestep,l_mix,r_aspect REAL pt(ngrid,nlay),pdtadj(ngrid,nlay) REAL pu(ngrid,nlay),pduadj(ngrid,nlay) REAL pv(ngrid,nlay),pdvadj(ngrid,nlay) REAL po(ngrid,nlay),pdoadj(ngrid,nlay) REAL pplay(ngrid,nlay),pplev(ngrid,nlay+1) real pphi(ngrid,nlay) integer idetr save idetr data idetr/3/ c local: c ------ INTEGER ig,k,l,lmaxa(klon),lmix(klon) real zsortie1d(klon) c CR: on remplace lmax(klon,klev+1) INTEGER lmax(klon),lmin(klon),lentr(klon) real linter(klon) real zmix(klon), fracazmix(klon) real alpha save alpha data alpha/1./ c RC real zmax(klon),zw,zz,zw2(klon,klev+1),ztva(klon,klev),zzz real zmax_sec(klon) real zmax_sec2(klon) real zw_sec(klon,klev+1) INTEGER lmix_sec(klon) real w_est(klon,klev+1) con garde le zmax du pas de temps precedent real zmax0(klon) save zmax0 real zmix0(klon) save zmix0 real zlev(klon,klev+1),zlay(klon,klev) real deltaz(klon,klev) REAL zh(klon,klev),zdhadj(klon,klev) real zthl(klon,klev),zdthladj(klon,klev) REAL ztv(klon,klev) real zu(klon,klev),zv(klon,klev),zo(klon,klev) real zl(klon,klev) REAL wh(klon,klev+1) real wu(klon,klev+1),wv(klon,klev+1),wo(klon,klev+1) real zla(klon,klev+1) real zwa(klon,klev+1) real zld(klon,klev+1) real zwd(klon,klev+1) real zsortie(klon,klev) real zva(klon,klev) real zua(klon,klev) real zoa(klon,klev) real zta(klon,klev) real zha(klon,klev) real wa_moy(klon,klev+1) real fraca(klon,klev+1) real fracc(klon,klev+1) real zf,zf2 real thetath2(klon,klev),wth2(klon,klev),wth3(klon,klev) real q2(klon,klev) real dtheta(klon,klev) common/comtherm/thetath2,wth2 real ratqscth(klon,klev) real sum real sumdiff real ratqsdiff(klon,klev) real count_time integer isplit,nsplit,ialt parameter (nsplit=10) data isplit/0/ save isplit logical sorties real rho(klon,klev),rhobarz(klon,klev+1),masse(klon,klev) real zpspsk(klon,klev) c real wmax(klon,klev),wmaxa(klon) real wmax(klon),wmaxa(klon) real wmax_sec(klon) real wmax_sec2(klon) real wa(klon,klev,klev+1) real wd(klon,klev+1) real larg_part(klon,klev,klev+1) real fracd(klon,klev+1) real xxx(klon,klev+1) real larg_cons(klon,klev+1) real larg_detr(klon,klev+1) real fm0(klon,klev+1),entr0(klon,klev),detr(klon,klev) real massetot(klon,klev) real detr0(klon,klev) real alim0(klon,klev) real pu_therm(klon,klev),pv_therm(klon,klev) real fm(klon,klev+1),entr(klon,klev) real fmc(klon,klev+1) real zcor,zdelta,zcvm5,qlbef real Tbef(klon),qsatbef(klon) real dqsat_dT,DT,num,denom REAL REPS,RLvCp,DDT0 real ztla(klon,klev),zqla(klon,klev),zqta(klon,klev) cCR niveau de condensation real nivcon(klon) real zcon(klon) real zqsat(klon,klev) real zqsatth(klon,klev) PARAMETER (DDT0=.01) cCR:nouvelles variables real f_star(klon,klev+1),entr_star(klon,klev) real detr_star(klon,klev) real alim_star_tot(klon),alim_star2(klon) real entr_star_tot(klon) real detr_star_tot(klon) real alim_star(klon,klev) real alim(klon,klev) real nu(klon,klev) real nu_e(klon,klev) real nu_min real nu_max real nu_r real f(klon), f0(klon) save f0 real f_old real zlevinter(klon) logical first c data first /.false./ c save first logical nuage c save nuage logical boucle logical therm logical debut logical rale integer test(klon) integer signe_zw2 cRC character*2 str2 character*10 str10 LOGICAL vtest(klon),down LOGICAL Zsat(klon) EXTERNAL SCOPY integer ncorrec,ll save ncorrec data ncorrec/0/ c c----------------------------------------------------------------------- c initialisation: c --------------- c sorties=.false. c print*,'NOUVEAU DETR PLUIE ' IF(ngrid.NE.klon) THEN PRINT* PRINT*,'STOP dans convadj' PRINT*,'ngrid =',ngrid PRINT*,'klon =',klon ENDIF c c Initialisation RLvCp = RLVTT/RCPD REPS = RD/RV cinitialisations de zqsat DO ll=1,nlay DO ig=1,ngrid zqsat(ig,ll)=0. zqsatth(ig,ll)=0. ENDDO ENDDO c con met le first a true pour le premier passage de la journée do ig=1,klon test(ig)=0 enddo if (debut) then do ig=1,klon test(ig)=1 f0(ig)=0. zmax0(ig)=0. enddo endif do ig=1,klon if ((.not.debut).and.(f0(ig).lt.1.e-10)) then test(ig)=1 endif enddo c do ig=1,klon c print*,'test(ig)',test(ig),zmax0(ig) c enddo nuage=.false. c----------------------------------------------------------------------- cAM Calcul de T,q,ql a partir de Tl et qT c --------------------------------------------------- c c Pr Tprec=Tl calcul de qsat c Si qsat>qT T=Tl, q=qT c Sinon DDT=(-Tprec+Tl+RLVCP (qT-qsat(T')) / (1+RLVCP dqsat/dt) c On cherche DDT < DDT0 c c defaut DO ll=1,nlay DO ig=1,ngrid zo(ig,ll)=po(ig,ll) zl(ig,ll)=0. zh(ig,ll)=pt(ig,ll) EndDO EndDO do ig=1,ngrid Zsat(ig)=.false. enddo c c DO ll=1,nlay c les points insatures sont definitifs DO ig=1,ngrid Tbef(ig)=pt(ig,ll) zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) qsatbef(ig)= R2ES * FOEEW(Tbef(ig),zdelta)/pplev(ig,ll) qsatbef(ig)=MIN(0.5,qsatbef(ig)) zcor=1./(1.-retv*qsatbef(ig)) qsatbef(ig)=qsatbef(ig)*zcor Zsat(ig) = (max(0.,po(ig,ll)-qsatbef(ig)) .gt. 1.e-10) EndDO DO ig=1,ngrid if (Zsat(ig).and.(1.eq.1)) then qlbef=max(0.,po(ig,ll)-qsatbef(ig)) c si sature: ql est surestime, d'ou la sous-relax DT = 0.5*RLvCp*qlbef c write(18,*),'DT0=',DT c on pourra enchainer 2 ou 3 calculs sans Do while do while (abs(DT).gt.DDT0) c il faut verifier si c,a conserve quand on repasse en insature ... Tbef(ig)=Tbef(ig)+DT zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) qsatbef(ig)= R2ES * FOEEW(Tbef(ig),zdelta)/pplev(ig,ll) qsatbef(ig)=MIN(0.5,qsatbef(ig)) zcor=1./(1.-retv*qsatbef(ig)) qsatbef(ig)=qsatbef(ig)*zcor c on veut le signe de qlbef qlbef=po(ig,ll)-qsatbef(ig) zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) zcvm5=R5LES*(1.-zdelta) + R5IES*zdelta zcor=1./(1.-retv*qsatbef(ig)) dqsat_dT=FOEDE(Tbef(ig),zdelta,zcvm5,qsatbef(ig),zcor) num=-Tbef(ig)+pt(ig,ll)+RLvCp*qlbef denom=1.+RLvCp*dqsat_dT if (denom.lt.1.e-10) then print*,'pb denom' endif DT=num/denom enddo c on ecrit de maniere conservative (sat ou non) zl(ig,ll) = max(0.,qlbef) c T = Tl +Lv/Cp ql zh(ig,ll) = pt(ig,ll)+RLvCp*zl(ig,ll) zo(ig,ll) = po(ig,ll)-zl(ig,ll) endif con ecrit zqsat zqsat(ig,ll)=qsatbef(ig) EndDO EndDO cAM fin c c----------------------------------------------------------------------- c incrementation eventuelle de tendances precedentes: c --------------------------------------------------- c print*,'0 OK convect8' DO 1010 l=1,nlay DO 1015 ig=1,ngrid zpspsk(ig,l)=(pplay(ig,l)/100000.)**RKAPPA c zpspsk(ig,l)=(pplay(ig,l)/pplev(ig,1))**RKAPPA c zh(ig,l)=pt(ig,l)/zpspsk(ig,l) zu(ig,l)=pu(ig,l) zv(ig,l)=pv(ig,l) c zo(ig,l)=po(ig,l) c ztv(ig,l)=zh(ig,l)*(1.+0.61*zo(ig,l)) cAM attention zh est maintenant le profil de T et plus le profil de theta ! c c T-> Theta ztv(ig,l)=zh(ig,l)/zpspsk(ig,l) cAM Theta_v ztv(ig,l)=ztv(ig,l)*(1.+RETV*(zo(ig,l)) s -zl(ig,l)) cAM Thetal zthl(ig,l)=pt(ig,l)/zpspsk(ig,l) c 1015 CONTINUE 1010 CONTINUE c print*,'1 OK convect8' c -------------------- c c c + + + + + + + + + + + c c c wa, fraca, wd, fracd -------------------- zlev(2), rhobarz c wh,wt,wo ... c c + + + + + + + + + + + zh,zu,zv,zo,rho c c c -------------------- zlev(1) c \\\\\\\\\\\\\\\\\\\\ c c c----------------------------------------------------------------------- c Calcul des altitudes des couches c----------------------------------------------------------------------- do l=2,nlay do ig=1,ngrid zlev(ig,l)=0.5*(pphi(ig,l)+pphi(ig,l-1))/RG enddo enddo do ig=1,ngrid zlev(ig,1)=0. zlev(ig,nlay+1)=(2.*pphi(ig,klev)-pphi(ig,klev-1))/RG enddo do l=1,nlay do ig=1,ngrid zlay(ig,l)=pphi(ig,l)/RG enddo enddo ccalcul de deltaz do l=1,nlay do ig=1,ngrid deltaz(ig,l)=zlev(ig,l+1)-zlev(ig,l) enddo enddo c print*,'2 OK convect8' c----------------------------------------------------------------------- c Calcul des densites c----------------------------------------------------------------------- do l=1,nlay do ig=1,ngrid c rho(ig,l)=pplay(ig,l)/(zpspsk(ig,l)*RD*zh(ig,l)) rho(ig,l)=pplay(ig,l)/(zpspsk(ig,l)*RD*ztv(ig,l)) enddo enddo do l=2,nlay do ig=1,ngrid rhobarz(ig,l)=0.5*(rho(ig,l)+rho(ig,l-1)) enddo enddo do k=1,nlay do l=1,nlay+1 do ig=1,ngrid wa(ig,k,l)=0. enddo enddo enddo cCr:ajout:calcul de la masse do l=1,nlay do ig=1,ngrid c masse(ig,l)=rho(ig,l)*(zlev(ig,l+1)-zlev(ig,l)) masse(ig,l)=(pplev(ig,l)-pplev(ig,l+1))/RG enddo enddo c print*,'3 OK convect8' c------------------------------------------------------------------ c Calcul de w2, quarre de w a partir de la cape c a partir de w2, on calcule wa, vitesse de l'ascendance c c ATTENTION: Dans cette version, pour cause d'economie de memoire, c w2 est stoke dans wa c c ATTENTION: dans convect8, on n'utilise le calcule des wa c independants par couches que pour calculer l'entrainement c a la base et la hauteur max de l'ascendance. c c Indicages: c l'ascendance provenant du niveau k traverse l'interface l avec c une vitesse wa(k,l). c c -------------------- c c + + + + + + + + + + c c wa(k,l) ---- -------------------- l c /\ c /||\ + + + + + + + + + + c || c || -------------------- c || c || + + + + + + + + + + c || c || -------------------- c ||__ c |___ + + + + + + + + + + k c c -------------------- c c c c------------------------------------------------------------------ cCR: ponderation entrainement des couches instables cdef des alim_star tels que alim=f*alim_star do l=1,klev do ig=1,ngrid alim_star(ig,l)=0. alim(ig,l)=0. enddo enddo c determination de la longueur de la couche d entrainement do ig=1,ngrid lentr(ig)=1 enddo con ne considere que les premieres couches instables therm=.false. do k=nlay-2,1,-1 do ig=1,ngrid if (ztv(ig,k).gt.ztv(ig,k+1).and. s ztv(ig,k+1).le.ztv(ig,k+2)) then lentr(ig)=k+1 therm=.true. endif enddo enddo c c determination du lmin: couche d ou provient le thermique do ig=1,ngrid lmin(ig)=1 enddo do ig=1,ngrid do l=nlay,2,-1 if (ztv(ig,l-1).gt.ztv(ig,l)) then lmin(ig)=l-1 endif enddo enddo c c definition de l'entrainement des couches do l=1,klev-1 do ig=1,ngrid if (ztv(ig,l).gt.ztv(ig,l+1).and. s l.ge.lmin(ig).and.l.lt.lentr(ig)) then cdef possibles pour alim_star: zdthetadz, dthetadz, zdtheta alim_star(ig,l)=MAX((ztv(ig,l)-ztv(ig,l+1)),0.) c s *(zlev(ig,l+1)-zlev(ig,l)) s *sqrt(zlev(ig,l+1)) c alim_star(ig,l)=zlev(ig,l+1)*(1.-(zlev(ig,l+1) c s /zlev(ig,lentr(ig)+2)))**(3./2.) endif enddo enddo c pas de thermique si couche 1 stable do ig=1,ngrid c if (lmin(ig).gt.1) then cCRnouveau test if (alim_star(ig,1).lt.1.e-10) then do l=1,klev alim_star(ig,l)=0. enddo endif enddo c calcul de l entrainement total do ig=1,ngrid alim_star_tot(ig)=0. entr_star_tot(ig)=0. detr_star_tot(ig)=0. enddo do ig=1,ngrid do k=1,klev alim_star_tot(ig)=alim_star_tot(ig)+alim_star(ig,k) enddo enddo c c Calcul entrainement normalise do ig=1,ngrid if (alim_star_tot(ig).gt.1.e-10) then c do l=1,lentr(ig) do l=1,klev cdef possibles pour entr_star: zdthetadz, dthetadz, zdtheta alim_star(ig,l)=alim_star(ig,l)/alim_star_tot(ig) enddo endif enddo c print*,'fin calcul alim_star' cAM:initialisations do k=1,nlay do ig=1,ngrid ztva(ig,k)=ztv(ig,k) ztla(ig,k)=zthl(ig,k) zqla(ig,k)=0. zqta(ig,k)=po(ig,k) Zsat(ig) =.false. enddo enddo do k=1,klev do ig=1,ngrid detr_star(ig,k)=0. entr_star(ig,k)=0. detr(ig,k)=0. entr(ig,k)=0. enddo enddo c print*,'7 OK convect8' do k=1,klev+1 do ig=1,ngrid zw2(ig,k)=0. fmc(ig,k)=0. cCR f_star(ig,k)=0. cRC larg_cons(ig,k)=0. larg_detr(ig,k)=0. wa_moy(ig,k)=0. enddo enddo cn print*,'8 OK convect8' do ig=1,ngrid linter(ig)=1. lmaxa(ig)=1 lmix(ig)=1 wmaxa(ig)=0. enddo nu_min=l_mix nu_max=1000. c do ig=1,ngrid c nu_max=wmax_sec(ig) c enddo do ig=1,ngrid do k=1,klev nu(ig,k)=0. nu_e(ig,k)=0. enddo enddo cCalcul de l'excès de température du à la diffusion turbulente do ig=1,ngrid do l=1,klev dtheta(ig,l)=0. enddo enddo do ig=1,ngrid do l=1,lentr(ig)-1 dtheta(ig,l)=sqrt(10.*0.4*zlev(ig,l+1)**2*1. s *((ztv(ig,l+1)-ztv(ig,l))/(zlev(ig,l+1)-zlev(ig,l)))**2) enddo enddo c do l=1,nlay-2 do l=1,klev-1 do ig=1,ngrid if (ztv(ig,l).gt.ztv(ig,l+1) s .and.alim_star(ig,l).gt.1.e-10 s .and.zw2(ig,l).lt.1e-10) then cAM ctest:on rajoute un excès de T dans couche alim c ztla(ig,l)=zthl(ig,l)+dtheta(ig,l) ztla(ig,l)=zthl(ig,l) ctest: on rajoute un excès de q dans la couche alim c zqta(ig,l)=po(ig,l)+0.001 zqta(ig,l)=po(ig,l) zqla(ig,l)=zl(ig,l) cAM f_star(ig,l+1)=alim_star(ig,l) ctest:calcul de dteta zw2(ig,l+1)=2.*RG*(ztv(ig,l)-ztv(ig,l+1))/ztv(ig,l+1) s *(zlev(ig,l+1)-zlev(ig,l)) s *0.4*pphi(ig,l)/(pphi(ig,l+1)-pphi(ig,l)) w_est(ig,l+1)=zw2(ig,l+1) larg_detr(ig,l)=0. c print*,'coucou boucle 1' else if ((zw2(ig,l).ge.1e-10).and. s (f_star(ig,l)+alim_star(ig,l)).gt.1.e-10) then c print*,'coucou boucle 2' cestimation du detrainement a partir de la geometrie du pas precedent if ((test(ig).eq.1).or.((.not.debut).and.(f0(ig).lt.1.e-10))) then detr_star(ig,l)=0. entr_star(ig,l)=0. c print*,'coucou test(ig)',test(ig),f0(ig),zmax0(ig) else c print*,'coucou debut detr' ctests sur la definition du detr if (zqla(ig,l-1).gt.1.e-10) then nuage=.true. endif w_est(ig,l+1)=zw2(ig,l)* s ((f_star(ig,l))**2) s /(f_star(ig,l)+alim_star(ig,l))**2+ s 2.*RG*(ztva(ig,l-1)-ztv(ig,l))/ztv(ig,l) s *(zlev(ig,l+1)-zlev(ig,l)) if (w_est(ig,l+1).lt.0.) then w_est(ig,l+1)=zw2(ig,l) endif if (l.gt.2) then if ((w_est(ig,l+1).gt.w_est(ig,l)).and. s (zlev(ig,l+1).lt.zmax_sec(ig)).and. s (zqla(ig,l-1).lt.1.e-10)) then detr_star(ig,l)=MAX(0.,(rhobarz(ig,l+1) s *sqrt(w_est(ig,l+1))*sqrt(nu(ig,l)*zlev(ig,l+1)) s -rhobarz(ig,l)*sqrt(w_est(ig,l))*sqrt(nu(ig,l)*zlev(ig,l))) s /(r_aspect*zmax_sec(ig))) else if ((zlev(ig,l+1).lt.zmax_sec(ig)).and. s (zqla(ig,l-1).lt.1.e-10)) then detr_star(ig,l)=-f0(ig)*f_star(ig,lmix(ig)) s /(rhobarz(ig,lmix(ig))*wmaxa(ig))* s (rhobarz(ig,l+1)*sqrt(w_est(ig,l+1)) s *((zmax_sec(ig)-zlev(ig,l+1))/((zmax_sec(ig)-zlev(ig,lmix(ig))))) s **2. s -rhobarz(ig,l)*sqrt(w_est(ig,l)) s *((zmax_sec(ig)-zlev(ig,l))/((zmax_sec(ig)-zlev(ig,lmix(ig))))) s **2.) else detr_star(ig,l)=0.002*f0(ig)*f_star(ig,l) s *(zlev(ig,l+1)-zlev(ig,l)) endif else detr_star(ig,l)=0. endif detr_star(ig,l)=detr_star(ig,l)/f0(ig) if (nuage) then entr_star(ig,l)=0.4*detr_star(ig,l) else entr_star(ig,l)=0.4*detr_star(ig,l) endif if ((detr_star(ig,l)).gt.f_star(ig,l)) then detr_star(ig,l)=f_star(ig,l) c entr_star(ig,l)=0. endif if ((l.lt.lentr(ig))) then entr_star(ig,l)=0. c detr_star(ig,l)=0. endif c print*,'ok detr_star' endif cprise en compte du detrainement dans le calcul du flux f_star(ig,l+1)=f_star(ig,l)+alim_star(ig,l)+entr_star(ig,l) s -detr_star(ig,l) ctest c if (f_star(ig,l+1).lt.0.) then c f_star(ig,l+1)=0. c entr_star(ig,l)=0. c detr_star(ig,l)=f_star(ig,l)+alim_star(ig,l) c endif ctest sur le signe de f_star if (f_star(ig,l+1).gt.1.e-10) then c then ctest c if (((f_star(ig,l+1)+detr_star(ig,l)).gt.1.e-10)) then cAM on melange Tl et qt du thermique con rajoute un excès de T dans la couche alim c if (l.lt.lentr(ig)) then c ztla(ig,l)=(f_star(ig,l)*ztla(ig,l-1)+ c s (alim_star(ig,l)+entr_star(ig,l))*(zthl(ig,l)+dtheta(ig,l))) c s /(f_star(ig,l+1)+detr_star(ig,l)) c else ztla(ig,l)=(f_star(ig,l)*ztla(ig,l-1)+ s (alim_star(ig,l)+entr_star(ig,l))*zthl(ig,l)) s /(f_star(ig,l+1)+detr_star(ig,l)) c s /(f_star(ig,l+1)) c endif con rajoute un excès de q dans la couche alim c if (l.lt.lentr(ig)) then c zqta(ig,l)=(f_star(ig,l)*zqta(ig,l-1)+ c s (alim_star(ig,l)+entr_star(ig,l))*(po(ig,l)+0.001)) c s /(f_star(ig,l+1)+detr_star(ig,l)) c else zqta(ig,l)=(f_star(ig,l)*zqta(ig,l-1)+ s (alim_star(ig,l)+entr_star(ig,l))*po(ig,l)) s /(f_star(ig,l+1)+detr_star(ig,l)) c s /(f_star(ig,l+1)) c endif cAM on en deduit thetav et ql du thermique cCR test c Tbef(ig)=ztla(ig,l)*zpspsk(ig,l) Tbef(ig)=ztla(ig,l)*zpspsk(ig,l) zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) qsatbef(ig)= R2ES * FOEEW(Tbef(ig),zdelta)/pplev(ig,l) qsatbef(ig)=MIN(0.5,qsatbef(ig)) zcor=1./(1.-retv*qsatbef(ig)) qsatbef(ig)=qsatbef(ig)*zcor Zsat(ig) = (max(0.,zqta(ig,l)-qsatbef(ig)) .gt. 1.e-10) if (Zsat(ig).and.(1.eq.1)) then qlbef=max(0.,zqta(ig,l)-qsatbef(ig)) DT = 0.5*RLvCp*qlbef c write(17,*)'DT0=',DT do while (abs(DT).gt.DDT0) c print*,'aie' Tbef(ig)=Tbef(ig)+DT zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) qsatbef(ig)= R2ES * FOEEW(Tbef(ig),zdelta)/pplev(ig,l) qsatbef(ig)=MIN(0.5,qsatbef(ig)) zcor=1./(1.-retv*qsatbef(ig)) qsatbef(ig)=qsatbef(ig)*zcor qlbef=zqta(ig,l)-qsatbef(ig) zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) zcvm5=R5LES*(1.-zdelta) + R5IES*zdelta zcor=1./(1.-retv*qsatbef(ig)) dqsat_dT=FOEDE(Tbef(ig),zdelta,zcvm5,qsatbef(ig),zcor) num=-Tbef(ig)+ztla(ig,l)*zpspsk(ig,l)+RLvCp*qlbef denom=1.+RLvCp*dqsat_dT if (denom.lt.1.e-10) then print*,'pb denom' endif DT=num/denom c write(17,*)'DT=',DT enddo zqla(ig,l) = max(0.,zqta(ig,l)-qsatbef(ig)) zqla(ig,l) = max(0.,qlbef) c zqla(ig,l)=0. endif c zqla(ig,l) = max(0.,zqta(ig,l)-qsatbef(ig)) c c on ecrit de maniere conservative (sat ou non) c T = Tl +Lv/Cp ql cCR rq utilisation de humidite specifique ou rapport de melange? ztva(ig,l) = ztla(ig,l)*zpspsk(ig,l)+RLvCp*zqla(ig,l) ztva(ig,l) = ztva(ig,l)/zpspsk(ig,l) con rajoute le calcul de zha pour diagnostiques (temp potentielle) zha(ig,l) = ztva(ig,l) c if (l.lt.lentr(ig)) then c ztva(ig,l) = ztva(ig,l)*(1.+RETV*(zqta(ig,l) c s -zqla(ig,l))-zqla(ig,l)) + 0.1 c else ztva(ig,l) = ztva(ig,l)*(1.+RETV*(zqta(ig,l) s -zqla(ig,l))-zqla(ig,l)) c endif c ztva(ig,l) = ztla(ig,l)*zpspsk(ig,l)+RLvCp*zqla(ig,l) c s /(1.-retv*zqla(ig,l)) c ztva(ig,l) = ztva(ig,l)/zpspsk(ig,l) c ztva(ig,l) = ztva(ig,l)*(1.+RETV*(zqta(ig,l) c s /(1.-retv*zqta(ig,l)) c s -zqla(ig,l)/(1.-retv*zqla(ig,l))) c s -zqla(ig,l)/(1.-retv*zqla(ig,l))) c write(13,*)zqla(ig,l),zqla(ig,l)/(1.-retv*zqla(ig,l)) con ecrit zqsat zqsatth(ig,l)=qsatbef(ig) c enddo c DO ig=1,ngrid c if (zw2(ig,l).ge.1.e-10.and. c s f_star(ig,l)+entr_star(ig,l).gt.1.e-10) then c mise a jour de la vitesse ascendante (l'air entraine de la couche c consideree commence avec une vitesse nulle). c c if (f_star(ig,l+1).gt.1.e-10) then zw2(ig,l+1)=zw2(ig,l)* c s ((f_star(ig,l)-detr_star(ig,l))**2) c s /f_star(ig,l+1)**2+ s ((f_star(ig,l))**2) s /(f_star(ig,l+1)+detr_star(ig,l))**2+ c s /(f_star(ig,l+1))**2+ s 2.*RG*(ztva(ig,l)-ztv(ig,l))/ztv(ig,l) s *(zlev(ig,l+1)-zlev(ig,l)) c s *(f_star(ig,l)/f_star(ig,l+1))**2 endif endif c if (zw2(ig,l+1).lt.0.) then linter(ig)=(l*(zw2(ig,l+1)-zw2(ig,l)) s -zw2(ig,l))/(zw2(ig,l+1)-zw2(ig,l)) zw2(ig,l+1)=0. c print*,'linter=',linter(ig) c else if ((zw2(ig,l+1).lt.1.e-10).and.(zw2(ig,l+1).ge.0.)) then c linter(ig)=l+1 c print*,'linter=l',zw2(ig,l),zw2(ig,l+1) else wa_moy(ig,l+1)=sqrt(zw2(ig,l+1)) c wa_moy(ig,l+1)=zw2(ig,l+1) endif if (wa_moy(ig,l+1).gt.wmaxa(ig)) then c lmix est le niveau de la couche ou w (wa_moy) est maximum lmix(ig)=l+1 wmaxa(ig)=wa_moy(ig,l+1) endif enddo enddo print*,'fin calcul zw2' c c Calcul de la couche correspondant a la hauteur du thermique do ig=1,ngrid lmax(ig)=lentr(ig) enddo do ig=1,ngrid do l=nlay,lentr(ig)+1,-1 if (zw2(ig,l).le.1.e-10) then lmax(ig)=l-1 endif enddo enddo c pas de thermique si couche 1 stable do ig=1,ngrid if (lmin(ig).gt.1) then lmax(ig)=1 lmin(ig)=1 lentr(ig)=1 endif enddo c c Determination de zw2 max do ig=1,ngrid wmax(ig)=0. enddo do l=1,nlay do ig=1,ngrid if (l.le.lmax(ig)) then if (zw2(ig,l).lt.0.)then print*,'pb2 zw2<0' endif zw2(ig,l)=sqrt(zw2(ig,l)) wmax(ig)=max(wmax(ig),zw2(ig,l)) else zw2(ig,l)=0. endif enddo enddo c Longueur caracteristique correspondant a la hauteur des thermiques. do ig=1,ngrid zmax(ig)=0. zlevinter(ig)=zlev(ig,1) enddo do ig=1,ngrid c calcul de zlevinter zlevinter(ig)=(zlev(ig,lmax(ig)+1)-zlev(ig,lmax(ig)))* s linter(ig)+zlev(ig,lmax(ig))-lmax(ig)*(zlev(ig,lmax(ig)+1) s -zlev(ig,lmax(ig))) cpour le cas ou on prend tjs lmin=1 c zmax(ig)=max(zmax(ig),zlevinter(ig)-zlev(ig,lmin(ig))) zmax(ig)=max(zmax(ig),zlevinter(ig)-zlev(ig,1)) zmax0(ig)=zmax(ig) write(11,*)'ig,lmax,linter',ig,lmax(ig),linter(ig) write(12,*)'ig,zlevinter,zmax',ig,zmax(ig),zlevinter(ig) enddo cCalcul de zmax_sec et wmax_sec call fermeture_seche(ngrid,nlay s ,pplay,pplev,pphi,zlev,rhobarz,f0,zpspsk s ,alim,zh,zo,lentr,lmin,nu_min,nu_max,r_aspect s ,zmax_sec2,wmax_sec2) print*,'avant fermeture' c Fermeture,determination de f c en lmax f=d-e do ig=1,ngrid c entr_star(ig,lmax(ig))=0. c f_star(ig,lmax(ig)+1)=0. c detr_star(ig,lmax(ig))=f_star(ig,lmax(ig))+entr_star(ig,lmax(ig)) c s +alim_star(ig,lmax(ig)) enddo c do ig=1,ngrid alim_star2(ig)=0. enddo ccalcul de entr_star_tot do ig=1,ngrid do k=1,lmix(ig) entr_star_tot(ig)=entr_star_tot(ig) c s +entr_star(ig,k) s +alim_star(ig,k) c s -detr_star(ig,k) detr_star_tot(ig)=detr_star_tot(ig) c s +alim_star(ig,k) s -detr_star(ig,k) s +entr_star(ig,k) enddo enddo do ig=1,ngrid if (alim_star_tot(ig).LT.1.e-10) then f(ig)=0. else c do k=lmin(ig),lentr(ig) do k=1,lentr(ig) alim_star2(ig)=alim_star2(ig)+alim_star(ig,k)**2 s /(rho(ig,k)*(zlev(ig,k+1)-zlev(ig,k))) enddo if ((zmax_sec(ig).gt.1.e-10).and.(1.eq.1)) then f(ig)=wmax_sec(ig)/(max(500.,zmax_sec(ig))*r_aspect s *alim_star2(ig)) f(ig)=f(ig)+(f0(ig)-f(ig))*exp((-ptimestep/ s zmax_sec(ig))*wmax_sec(ig)) else f(ig)=wmax(ig)/(max(500.,zmax(ig))*r_aspect*alim_star2(ig)) f(ig)=f(ig)+(f0(ig)-f(ig))*exp((-ptimestep/ s zmax(ig))*wmax(ig)) endif endif f0(ig)=f(ig) enddo print*,'apres fermeture' c Calcul de l'entrainement do ig=1,ngrid do k=1,klev alim(ig,k)=f(ig)*alim_star(ig,k) enddo enddo cCR:test pour entrainer moins que la masse c do ig=1,ngrid c do l=1,lentr(ig) c if ((alim(ig,l)*ptimestep).gt.(0.9*masse(ig,l))) then c alim(ig,l+1)=alim(ig,l+1)+alim(ig,l) c s -0.9*masse(ig,l)/ptimestep c alim(ig,l)=0.9*masse(ig,l)/ptimestep c endif c enddo c enddo c calcul du détrainement do ig=1,klon do k=1,klev detr(ig,k)=f(ig)*detr_star(ig,k) if (detr(ig,k).lt.0.) then c print*,'detr1<0!!!' endif enddo do k=1,klev entr(ig,k)=f(ig)*entr_star(ig,k) if (entr(ig,k).lt.0.) then c print*,'entr1<0!!!' endif enddo enddo c c do ig=1,ngrid c do l=1,klev c if (((detr(ig,l)+entr(ig,l)+alim(ig,l))*ptimestep).gt. c s (masse(ig,l))) then c print*,'d2+e2+a2>m2','ig=',ig,'l=',l,'lmax(ig)=',lmax(ig),'d+e+a=' c s,(detr(ig,l)+entr(ig,l)+alim(ig,l))*ptimestep,'m=',masse(ig,l) c endif c enddo c enddo c Calcul des flux do ig=1,ngrid do l=1,lmax(ig) c do l=1,klev c fmc(ig,l+1)=f(ig)*f_star(ig,l+1) fmc(ig,l+1)=fmc(ig,l)+alim(ig,l)+entr(ig,l)-detr(ig,l) c print*,'??!!','ig=',ig,'l=',l,'lmax=',lmax(ig),'lmix=',lmix(ig), c s 'e=',entr(ig,l),'d=',detr(ig,l),'a=',alim(ig,l),'f=',fmc(ig,l), c s 'f+1=',fmc(ig,l+1) if (fmc(ig,l+1).lt.0.) then print*,'fmc1<0',l+1,lmax(ig),fmc(ig,l+1) fmc(ig,l+1)=fmc(ig,l) detr(ig,l)=alim(ig,l)+entr(ig,l) c fmc(ig,l+1)=0. c print*,'fmc1<0',l+1,lmax(ig),fmc(ig,l+1) endif c if ((fmc(ig,l+1).gt.fmc(ig,l)).and.(l.gt.lentr(ig))) then c f_old=fmc(ig,l+1) c fmc(ig,l+1)=fmc(ig,l) c detr(ig,l)=detr(ig,l)+f_old-fmc(ig,l+1) c endif c if ((fmc(ig,l+1).gt.fmc(ig,l)).and.(l.gt.lentr(ig))) then c f_old=fmc(ig,l+1) c fmc(ig,l+1)=fmc(ig,l) c detr(ig,l)=detr(ig,l)+f_old-fmc(ig,l) c endif crajout du test sur alpha croissant cif test c if (1.eq.0) then if (l.eq.klev) then print*,'THERMCELL PB ig=',ig,' l=',l stop endif ! if ((zw2(ig,l+1).gt.1.e-10).and.(zw2(ig,l).gt.1.e-10).and. ! s (l.ge.lentr(ig)).and. if ((zw2(ig,l+1).gt.1.e-10).and.(zw2(ig,l).gt.1.e-10).and. s (l.ge.lentr(ig)) ) then if ( ((fmc(ig,l+1)/(rhobarz(ig,l+1)*zw2(ig,l+1))).gt. s (fmc(ig,l)/(rhobarz(ig,l)*zw2(ig,l))))) then f_old=fmc(ig,l+1) fmc(ig,l+1)=fmc(ig,l)*rhobarz(ig,l+1)*zw2(ig,l+1) s /(rhobarz(ig,l)*zw2(ig,l)) detr(ig,l)=detr(ig,l)+f_old-fmc(ig,l+1) c detr(ig,l)=(fmc(ig,l+1)-fmc(ig,l))/(0.4-1.) c entr(ig,l)=0.4*detr(ig,l) c entr(ig,l)=fmc(ig,l+1)-fmc(ig,l)+detr(ig,l) endif endif if ((fmc(ig,l+1).gt.fmc(ig,l)).and.(l.gt.lentr(ig))) then f_old=fmc(ig,l+1) fmc(ig,l+1)=fmc(ig,l) detr(ig,l)=detr(ig,l)+f_old-fmc(ig,l+1) endif if (detr(ig,l).gt.fmc(ig,l)) then detr(ig,l)=fmc(ig,l) entr(ig,l)=fmc(ig,l+1)-alim(ig,l) endif if (fmc(ig,l+1).lt.0.) then detr(ig,l)=detr(ig,l)+fmc(ig,l+1) fmc(ig,l+1)=0. print*,'fmc2<0',l+1,lmax(ig) endif ctest pour ne pas avoir f=0 et d=e/=0 c if (fmc(ig,l+1).lt.1.e-10) then c detr(ig,l+1)=0. c entr(ig,l+1)=0. c zqla(ig,l+1)=0. c zw2(ig,l+1)=0. c lmax(ig)=l+1 c zmax(ig)=zlev(ig,lmax(ig)) c endif if (zw2(ig,l+1).gt.1.e-10) then if ((((fmc(ig,l+1))/(rhobarz(ig,l+1)*zw2(ig,l+1))).gt. s 1.)) then f_old=fmc(ig,l+1) fmc(ig,l+1)=rhobarz(ig,l+1)*zw2(ig,l+1) zw2(ig,l+1)=0. zqla(ig,l+1)=0. detr(ig,l)=detr(ig,l)+f_old-fmc(ig,l+1) lmax(ig)=l+1 zmax(ig)=zlev(ig,lmax(ig)) print*,'alpha>1',l+1,lmax(ig) endif endif c write(1,*)'ig,l,fm(ig,l)',ig,l,fm(ig,l) cendif test c endif enddo enddo do ig=1,ngrid c if (fmc(ig,lmax(ig)+1).ne.0.) then fmc(ig,lmax(ig)+1)=0. entr(ig,lmax(ig))=0. detr(ig,lmax(ig))=fmc(ig,lmax(ig))+entr(ig,lmax(ig)) s +alim(ig,lmax(ig)) c endif enddo ctest sur le signe de fmc do ig=1,ngrid do l=1,klev+1 if (fmc(ig,l).lt.0.) then print*,'fm1<0!!!','ig=',ig,'l=',l,'a=',alim(ig,l-1),'e=' s ,entr(ig,l-1),'f=',fmc(ig,l-1),'d=',detr(ig,l-1),'f+1=',fmc(ig,l) endif enddo enddo ctest de verification do ig=1,ngrid do l=1,lmax(ig) if ((abs(fmc(ig,l+1)-fmc(ig,l)-alim(ig,l)-entr(ig,l)+detr(ig,l))) s .gt.1.e-4) then c print*,'pbcm!!','ig=',ig,'l=',l,'lmax=',lmax(ig),'lmix=',lmix(ig), c s 'e=',entr(ig,l),'d=',detr(ig,l),'a=',alim(ig,l),'f=',fmc(ig,l), c s 'f+1=',fmc(ig,l+1) endif if (detr(ig,l).lt.0.) then print*,'detrdemi<0!!!' endif enddo enddo c cRC cCR def de zmix continu (profil parabolique des vitesses) do ig=1,ngrid if (lmix(ig).gt.1.) then c test if (((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))-(zlev(ig,lmix(ig)+1))) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))-(zlev(ig,lmix(ig))))).gt.1e-10) s then c zmix(ig)=((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))**2-(zlev(ig,lmix(ig)+1))**2) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))**2-(zlev(ig,lmix(ig)))**2)) s /(2.*((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))-(zlev(ig,lmix(ig)+1))) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))-(zlev(ig,lmix(ig)))))) else zmix(ig)=zlev(ig,lmix(ig)) print*,'pb zmix' endif else zmix(ig)=0. endif ctest if ((zmax(ig)-zmix(ig)).le.0.) then zmix(ig)=0.9*zmax(ig) c print*,'pb zmix>zmax' endif enddo do ig=1,klon zmix0(ig)=zmix(ig) enddo c c calcul du nouveau lmix correspondant do ig=1,ngrid do l=1,klev if (zmix(ig).ge.zlev(ig,l).and. s zmix(ig).lt.zlev(ig,l+1)) then lmix(ig)=l endif enddo enddo c cne devrait pas arriver!!!!! do ig=1,ngrid do l=1,klev if (detr(ig,l).gt.(fmc(ig,l)+alim(ig,l))+entr(ig,l)) then print*,'detr2>fmc2!!!','ig=',ig,'l=',l,'d=',detr(ig,l), s 'f=',fmc(ig,l),'lmax=',lmax(ig) c detr(ig,l)=fmc(ig,l)+alim(ig,l)+entr(ig,l) c entr(ig,l)=0. c fmc(ig,l+1)=0. c zw2(ig,l+1)=0. c zqla(ig,l+1)=0. print*,'pb!fm=0 et f_star>0',l,lmax(ig) c lmax(ig)=l endif enddo enddo do ig=1,ngrid do l=lmax(ig)+1,klev+1 c fmc(ig,l)=0. c detr(ig,l)=0. c entr(ig,l)=0. c zw2(ig,l)=0. c zqla(ig,l)=0. enddo enddo cCalcul du detrainement lors du premier passage c print*,'9 OK convect8' c print*,'WA1 ',wa_moy c determination de l'indice du debut de la mixed layer ou w decroit c calcul de la largeur de chaque ascendance dans le cas conservatif. c dans ce cas simple, on suppose que la largeur de l'ascendance provenant c d'une couche est égale à la hauteur de la couche alimentante. c La vitesse maximale dans l'ascendance est aussi prise comme estimation c de la vitesse d'entrainement horizontal dans la couche alimentante. do l=2,nlay do ig=1,ngrid if (l.le.lmax(ig).and.(test(ig).eq.1)) then zw=max(wa_moy(ig,l),1.e-10) larg_cons(ig,l)=zmax(ig)*r_aspect s *fmc(ig,l)/(rhobarz(ig,l)*zw) endif enddo enddo do l=2,nlay do ig=1,ngrid if (l.le.lmax(ig).and.(test(ig).eq.1)) then c if (idetr.eq.0) then c cette option est finalement en dur. if ((l_mix*zlev(ig,l)).lt.0.)then print*,'pb l_mix*zlev<0' endif cCR: test: nouvelle def de lambda c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) if (zw2(ig,l).gt.1.e-10) then larg_detr(ig,l)=sqrt((l_mix/zw2(ig,l))*zlev(ig,l)) else larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) endif c else if (idetr.eq.1) then c larg_detr(ig,l)=larg_cons(ig,l) c s *sqrt(l_mix*zlev(ig,l))/larg_cons(ig,lmix(ig)) c else if (idetr.eq.2) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *sqrt(wa_moy(ig,l)) c else if (idetr.eq.4) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *wa_moy(ig,l) c endif endif enddo enddo c print*,'10 OK convect8' c print*,'WA2 ',wa_moy c cal1cul de la fraction de la maille concernée par l'ascendance en tenant c compte de l'epluchage du thermique. c c do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1..and.(test(ig).eq.1)) then c print*,ig,l,lmix(ig),lmaxa(ig),larg_cons(ig,l),' KKK' fraca(ig,l)=(larg_cons(ig,l)-larg_detr(ig,l)) s /(r_aspect*zmax(ig)) c test fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) else c wa_moy(ig,l)=0. fraca(ig,l)=0. fracc(ig,l)=0. fracd(ig,l)=1. endif enddo enddo cCR: calcul de fracazmix do ig=1,ngrid if (test(ig).eq.1) then fracazmix(ig)=(fraca(ig,lmix(ig)+1)-fraca(ig,lmix(ig)))/ s (zlev(ig,lmix(ig)+1)-zlev(ig,lmix(ig)))*zmix(ig) s +fraca(ig,lmix(ig))-zlev(ig,lmix(ig))*(fraca(ig,lmix(ig)+1) s -fraca(ig,lmix(ig)))/(zlev(ig,lmix(ig)+1)-zlev(ig,lmix(ig))) endif enddo c do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1..and.(test(ig).eq.1)) then if (l.gt.lmix(ig)) then ctest if (zmax(ig)-zmix(ig).lt.1.e-10) then c print*,'pb xxx' xxx(ig,l)=(lmax(ig)+1.-l)/(lmax(ig)+1.-lmix(ig)) else xxx(ig,l)=(zmax(ig)-zlev(ig,l))/(zmax(ig)-zmix(ig)) endif if (idetr.eq.0) then fraca(ig,l)=fracazmix(ig) else if (idetr.eq.1) then fraca(ig,l)=fracazmix(ig)*xxx(ig,l) else if (idetr.eq.2) then fraca(ig,l)=fracazmix(ig)*(1.-(1.-xxx(ig,l))**2) else fraca(ig,l)=fracazmix(ig)*xxx(ig,l)**2 endif c print*,ig,l,lmix(ig),lmaxa(ig),xxx(ig,l),'LLLLLLL' fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) endif endif enddo enddo print*,'fin calcul fraca' c print*,'11 OK convect8' c print*,'Ea3 ',wa_moy c------------------------------------------------------------------ c Calcul de fracd, wd c somme wa - wd = 0 c------------------------------------------------------------------ do ig=1,ngrid fm(ig,1)=0. fm(ig,nlay+1)=0. enddo do l=2,nlay do ig=1,ngrid if (test(ig).eq.1) then fm(ig,l)=fraca(ig,l)*wa_moy(ig,l)*rhobarz(ig,l) cCR:test if (alim(ig,l-1).lt.1e-10.and.fm(ig,l).gt.fm(ig,l-1) s .and.l.gt.lmix(ig)) then fm(ig,l)=fm(ig,l-1) c write(1,*)'ajustement fm, l',l endif c write(1,*)'ig,l,fm(ig,l)',ig,l,fm(ig,l) cRC endif enddo do ig=1,ngrid if(fracd(ig,l).lt.0.1.and.(test(ig).eq.1)) then stop'fracd trop petit' else c vitesse descendante "diagnostique" wd(ig,l)=fm(ig,l)/(fracd(ig,l)*rhobarz(ig,l)) endif enddo enddo do l=1,nlay+1 do ig=1,ngrid if (test(ig).eq.0) then fm(ig,l)=fmc(ig,l) endif enddo enddo cfin du first do l=1,nlay do ig=1,ngrid c masse(ig,l)=rho(ig,l)*(zlev(ig,l+1)-zlev(ig,l)) masse(ig,l)=(pplev(ig,l)-pplev(ig,l+1))/RG enddo enddo print*,'12 OK convect8' c print*,'WA4 ',wa_moy cc------------------------------------------------------------------ c calcul du transport vertical c------------------------------------------------------------------ go to 4444 c print*,'XXXXXXXXXXXXXXX ptimestep= ',ptimestep do l=2,nlay-1 do ig=1,ngrid if(fm(ig,l+1)*ptimestep.gt.masse(ig,l) s .and.fm(ig,l+1)*ptimestep.gt.masse(ig,l+1)) then print*,'WARN!!! FM>M ig=',ig,' l=',l,' FM=' s ,fm(ig,l+1)*ptimestep s ,' M=',masse(ig,l),masse(ig,l+1) endif enddo enddo do l=1,nlay do ig=1,ngrid if((alim(ig,l)+entr(ig,l))*ptimestep.gt.masse(ig,l)) then print*,'WARN!!! E>M ig=',ig,' l=',l,' E==' s ,(entr(ig,l)+alim(ig,l))*ptimestep s ,' M=',masse(ig,l) endif enddo enddo do l=1,nlay do ig=1,ngrid if(.not.fm(ig,l).ge.0..or..not.fm(ig,l).le.10.) then c print*,'WARN!!! fm exagere ig=',ig,' l=',l c s ,' FM=',fm(ig,l) endif if(.not.masse(ig,l).ge.1.e-10 s .or..not.masse(ig,l).le.1.e4) then c print*,'WARN!!! masse exagere ig=',ig,' l=',l c s ,' M=',masse(ig,l) c print*,'rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l)', c s rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l) c print*,'zlev(ig,l+1),zlev(ig,l)' c s ,zlev(ig,l+1),zlev(ig,l) c print*,'pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1)' c s ,pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1) endif if(.not.alim(ig,l).ge.0..or..not.alim(ig,l).le.10.) then c print*,'WARN!!! entr exagere ig=',ig,' l=',l c s ,' E=',entr(ig,l) endif enddo enddo 4444 continue cCR:redefinition du entr cCR:test:on ne change pas la def du entr mais la def du fm do l=1,nlay do ig=1,ngrid if (test(ig).eq.1) then detr(ig,l)=fm(ig,l)+alim(ig,l)-fm(ig,l+1) if (detr(ig,l).lt.0.) then c entr(ig,l)=entr(ig,l)-detr(ig,l) fm(ig,l+1)=fm(ig,l)+alim(ig,l) detr(ig,l)=0. c write(11,*)'l,ig,entr',l,ig,entr(ig,l) c print*,'WARNING !!! detrainement negatif ',ig,l endif endif enddo enddo cRC if (w2di.eq.1) then fm0=fm0+ptimestep*(fm-fm0)/float(tho) entr0=entr0+ptimestep*(alim+entr-entr0)/float(tho) else fm0=fm entr0=alim+entr detr0=detr alim0=alim c zoa=zqta c entr0=alim endif if (1.eq.1) then c call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse c . ,zh,zdhadj,zha) c call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse c . ,zo,pdoadj,zoa) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse, . zthl,zdthladj,zta) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse, . po,pdoadj,zoa) else call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zh,zdhadj,zha) call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zo,pdoadj,zoa) endif if (1.eq.0) then call dvthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse . ,fraca,zmax . ,zu,zv,pduadj,pdvadj,zua,zva) else call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zu,pduadj,zua) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zv,pdvadj,zva) endif cCalcul des moments c do l=1,nlay c do ig=1,ngrid c zf=0.5*(fracc(ig,l)+fracc(ig,l+1)) c zf2=zf/(1.-zf) c thetath2(ig,l)=zf2*(zha(ig,l)-zh(ig,l))**2 c wth2(ig,l)=zf2*(0.5*(wa_moy(ig,l)+wa_moy(ig,l+1)))**2 c enddo c enddo c print*,'13 OK convect8' c print*,'WA5 ',wa_moy do l=1,nlay do ig=1,ngrid c pdtadj(ig,l)=zdhadj(ig,l)*zpspsk(ig,l) pdtadj(ig,l)=zdthladj(ig,l)*zpspsk(ig,l) enddo enddo c do l=1,nlay c do ig=1,ngrid c if(abs(pdtadj(ig,l))*86400..gt.500.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdtadj=',pdtadj(ig,l) c endif c if(abs(pdoadj(ig,l))*86400..gt.1.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdoadj=',pdoadj(ig,l) c endif c enddo c enddo print*,'14 OK convect8' c------------------------------------------------------------------ c Calculs pour les sorties c------------------------------------------------------------------ ccalcul de fraca pour les sorties do l=2,klev do ig=1,klon if (zw2(ig,l).gt.1.e-10) then fraca(ig,l)=fm(ig,l)/(rhobarz(ig,l)*zw2(ig,l)) else fraca(ig,l)=0. endif enddo enddo if(sorties) then do l=1,nlay do ig=1,ngrid zla(ig,l)=(1.-fracd(ig,l))*zmax(ig) zld(ig,l)=fracd(ig,l)*zmax(ig) if(1.-fracd(ig,l).gt.1.e-10) s zwa(ig,l)=wd(ig,l)*fracd(ig,l)/(1.-fracd(ig,l)) enddo enddo c CR calcul du niveau de condensation c initialisation do ig=1,ngrid nivcon(ig)=0. zcon(ig)=0. enddo do k=nlay,1,-1 do ig=1,ngrid if (zqla(ig,k).gt.1e-10) then nivcon(ig)=k zcon(ig)=zlev(ig,k) endif c if (zcon(ig).gt.1.e-10) then c nuage=.true. c else c nuage=.false. c endif enddo enddo do l=1,nlay do ig=1,ngrid zf=fraca(ig,l) zf2=zf/(1.-zf) thetath2(ig,l)=zf2*(zha(ig,l)-zh(ig,l)/zpspsk(ig,l))**2 wth2(ig,l)=zf2*(zw2(ig,l))**2 c print*,'wth2=',wth2(ig,l) wth3(ig,l)=zf2*(1-2.*fraca(ig,l))/(1-fraca(ig,l)) s *zw2(ig,l)*zw2(ig,l)*zw2(ig,l) q2(ig,l)=zf2*(zqta(ig,l)*1000.-po(ig,l)*1000.)**2 ctest: on calcul q2/po=ratqsc c if (nuage) then ratqscth(ig,l)=sqrt(q2(ig,l))/(po(ig,l)*1000.) c else c ratqscth(ig,l)=0. c endif enddo enddo ccalcul du ratqscdiff sum=0. sumdiff=0. ratqsdiff(:,:)=0. do ig=1,ngrid do l=1,lentr(ig) sum=sum+alim_star(ig,l)*zqta(ig,l)*1000. enddo enddo do ig=1,ngrid do l=1,lentr(ig) zf=fraca(ig,l) zf2=zf/(1.-zf) sumdiff=sumdiff+alim_star(ig,l) s *(zqta(ig,l)*1000.-sum)**2 c ratqsdiff=ratqsdiff+alim_star(ig,l)* c s (zqta(ig,l)*1000.-po(ig,l)*1000.)**2 enddo enddo do l=1,klev do ig=1,ngrid ratqsdiff(ig,l)=sqrt(sumdiff)/(po(ig,l)*1000.) c write(11,*)'ratqsdiff=',ratqsdiff(ig,l) enddo enddo cdeja fait c do l=1,nlay c do ig=1,ngrid c detr(ig,l)=fm(ig,l)+entr(ig,l)-fm(ig,l+1) c if (detr(ig,l).lt.0.) then c entr(ig,l)=entr(ig,l)-detr(ig,l) c detr(ig,l)=0. c print*,'WARNING !!! detrainement negatif ',ig,l c endif c enddo c enddo c print*,'15 OK convect8' isplit=isplit+1 c #define und goto 123 #ifdef und CALL writeg1d(1,nlay,wd,'wd ','wd ') CALL writeg1d(1,nlay,zwa,'wa ','wa ') CALL writeg1d(1,nlay,fracd,'fracd ','fracd ') CALL writeg1d(1,nlay,fraca,'fraca ','fraca ') CALL writeg1d(1,nlay,wa_moy,'wam ','wam ') CALL writeg1d(1,nlay,zla,'la ','la ') CALL writeg1d(1,nlay,zld,'ld ','ld ') CALL writeg1d(1,nlay,pt,'pt ','pt ') CALL writeg1d(1,nlay,zh,'zh ','zh ') CALL writeg1d(1,nlay,zha,'zha ','zha ') CALL writeg1d(1,nlay,zu,'zu ','zu ') CALL writeg1d(1,nlay,zv,'zv ','zv ') CALL writeg1d(1,nlay,zo,'zo ','zo ') CALL writeg1d(1,nlay,wh,'wh ','wh ') CALL writeg1d(1,nlay,wu,'wu ','wu ') CALL writeg1d(1,nlay,wv,'wv ','wv ') CALL writeg1d(1,nlay,wo,'w15uo ','wXo ') CALL writeg1d(1,nlay,zdhadj,'zdhadj ','zdhadj ') CALL writeg1d(1,nlay,pduadj,'pduadj ','pduadj ') CALL writeg1d(1,nlay,pdvadj,'pdvadj ','pdvadj ') CALL writeg1d(1,nlay,pdoadj,'pdoadj ','pdoadj ') CALL writeg1d(1,nlay,entr ,'entr ','entr ') CALL writeg1d(1,nlay,detr ,'detr ','detr ') CALL writeg1d(1,nlay,fm ,'fm ','fm ') CALL writeg1d(1,nlay,pdtadj,'pdtadj ','pdtadj ') CALL writeg1d(1,nlay,pplay,'pplay ','pplay ') CALL writeg1d(1,nlay,pplev,'pplev ','pplev ') c recalcul des flux en diagnostique... c print*,'PAS DE TEMPS ',ptimestep call dt2F(pplev,pplay,pt,pdtadj,wh) CALL writeg1d(1,nlay,wh,'wh2 ','wh2 ') #endif 123 continue ! #define troisD #ifdef troisD c if (sorties) then print*,'Debut des wrgradsfi' c print*,'16 OK convect8' c call wrgradsfi(1,nlay,wd,'wd ','wd ') c call wrgradsfi(1,nlay,zwa,'wa ','wa ') call wrgradsfi(1,nlay,fracd,'fracd ','fracd ') call wrgradsfi(1,nlay,fraca,'fraca ','fraca ') c call wrgradsfi(1,nlay,xxx,'xxx ','xxx ') c call wrgradsfi(1,nlay,wa_moy,'wam ','wam ') c print*,'WA6 ',wa_moy c call wrgradsfi(1,nlay,zla,'la ','la ') c call wrgradsfi(1,nlay,zld,'ld ','ld ') call wrgradsfi(1,nlay,pt,'pt ','pt ') call wrgradsfi(1,nlay,zh,'zh ','zh ') call wrgradsfi(1,nlay,zha,'zha ','zha ') call wrgradsfi(1,nlay,zua,'zua ','zua ') call wrgradsfi(1,nlay,zva,'zva ','zva ') call wrgradsfi(1,nlay,zu,'zu ','zu ') call wrgradsfi(1,nlay,zv,'zv ','zv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,wh,'wh ','wh ') call wrgradsfi(1,nlay,wu,'wu ','wu ') call wrgradsfi(1,nlay,wv,'wv ','wv ') call wrgradsfi(1,nlay,wo,'wo ','wo ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,nlay,zdhadj,'zdhadj ','zdhadj ') call wrgradsfi(1,nlay,pduadj,'pduadj ','pduadj ') call wrgradsfi(1,nlay,pdvadj,'pdvadj ','pdvadj ') call wrgradsfi(1,nlay,pdoadj,'pdoadj ','pdoadj ') call wrgradsfi(1,nlay,entr,'entr ','entr ') call wrgradsfi(1,nlay,detr,'detr ','detr ') call wrgradsfi(1,nlay,fm,'fm ','fm ') call wrgradsfi(1,nlay,fmc,'fmc ','fmc ') call wrgradsfi(1,nlay,zw2,'zw2 ','zw2 ') call wrgradsfi(1,nlay,w_est,'w_est ','w_est ') con sort les moments call wrgradsfi(1,nlay,thetath2,'zh2 ','zh2 ') call wrgradsfi(1,nlay,wth2,'w2 ','w2 ') call wrgradsfi(1,nlay,wth3,'w3 ','w3 ') call wrgradsfi(1,nlay,q2,'q2 ','q2 ') call wrgradsfi(1,nlay,dtheta,'dT ','dT ') c call wrgradsfi(1,nlay,zw_sec,'zw_sec ','zw_sec ') call wrgradsfi(1,nlay,ztva,'ztva ','ztva ') call wrgradsfi(1,nlay,ztv,'ztv ','ztv ') call wrgradsfi(1,nlay,nu,'nu ','nu ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,zoa,'zoa ','zoa ') c call wrgradsfi(1,nlay,larg_cons,'Lc ','Lc ') c call wrgradsfi(1,nlay,larg_detr,'Ldetr ','Ldetr ') cAM:nouveaux diagnostiques call wrgradsfi(1,nlay,zthl,'zthl ','zthl ') call wrgradsfi(1,nlay,zta,'zta ','zta ') call wrgradsfi(1,nlay,zl,'zl ','zl ') call wrgradsfi(1,nlay,zdthladj,'zdthladj ', s 'zdthladj ') call wrgradsfi(1,nlay,ztla,'ztla ','ztla ') call wrgradsfi(1,nlay,zqta,'zqta ','zqta ') call wrgradsfi(1,nlay,zqla,'zqla ','zqla ') call wrgradsfi(1,nlay,deltaz,'deltaz ','deltaz ') cCR:nouveaux diagnostiques call wrgradsfi(1,nlay,entr_star ,'entr_star ','entr_star ') call wrgradsfi(1,nlay,detr_star ,'detr_star ','detr_star ') call wrgradsfi(1,nlay,f_star ,'f_star ','f_star ') call wrgradsfi(1,nlay,zqsat ,'zqsat ','zqsat ') call wrgradsfi(1,nlay,zqsatth ,'qsath ','qsath ') call wrgradsfi(1,nlay,alim_star ,'alim_star ','alim_star ') call wrgradsfi(1,nlay,alim ,'alim ','alim ') call wrgradsfi(1,1,f,'f ','f ') call wrgradsfi(1,1,alim_star_tot,'a_s_t ','a_s_t ') call wrgradsfi(1,1,alim_star2,'a_2 ','a_2 ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,1,zmax_sec,'z_sec ','z_sec ') c call wrgradsfi(1,1,zmax_sec2,'zz_se ','zz_se ') call wrgradsfi(1,1,zmix,'zmix ','zmix ') call wrgradsfi(1,1,nivcon,'nivcon ','nivcon ') call wrgradsfi(1,1,zcon,'zcon ','zcon ') zsortie1d(:)=lmax(:) call wrgradsfi(1,1,zsortie1d,'lmax ','lmax ') call wrgradsfi(1,1,wmax,'wmax ','wmax ') call wrgradsfi(1,1,wmax_sec,'w_sec ','w_sec ') zsortie1d(:)=lmix(:) call wrgradsfi(1,1,zsortie1d,'lmix ','lmix ') zsortie1d(:)=lentr(:) call wrgradsfi(1,1,zsortie1d,'lentr ','lentr ') c print*,'17 OK convect8' do k=1,klev/10 write(str2,'(i2.2)') k str10='wa'//str2 do l=1,nlay do ig=1,ngrid zsortie(ig,l)=wa(ig,k,l) enddo enddo CALL wrgradsfi(1,nlay,zsortie,str10,str10) do l=1,nlay do ig=1,ngrid zsortie(ig,l)=larg_part(ig,k,l) enddo enddo str10='la'//str2 CALL wrgradsfi(1,nlay,zsortie,str10,str10) enddo c print*,'18 OK convect8' c endif print*,'Fin des wrgradsfi' #endif endif c if(wa_moy(1,4).gt.1.e-10) stop print*,'19 OK convect8' return end SUBROUTINE thermcell_eau(ngrid,nlay,ptimestep s ,pplay,pplev,pphi s ,pu,pv,pt,po s ,pduadj,pdvadj,pdtadj,pdoadj s ,fm0,entr0 c s ,pu_therm,pv_therm s ,r_aspect,l_mix,w2di,tho) IMPLICIT NONE c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c c Réécriture à partir d'un listing papier à Habas, le 14/02/00 c c le thermique est supposé homogène et dissipé par mélange avec c son environnement. la longueur l_mix contrôle l'efficacité du c mélange c c Le calcul du transport des différentes espèces se fait en prenant c en compte: c 1. un flux de masse montant c 2. un flux de masse descendant c 3. un entrainement c 4. un detrainement c c======================================================================= c----------------------------------------------------------------------- c declarations: c ------------- #include "dimensions.h" #include "dimphy.h" #include "YOMCST.h" #include "YOETHF.h" #include "FCTTRE.h" c arguments: c ---------- INTEGER ngrid,nlay,w2di,tho real ptimestep,l_mix,r_aspect REAL pt(ngrid,nlay),pdtadj(ngrid,nlay) REAL pu(ngrid,nlay),pduadj(ngrid,nlay) REAL pv(ngrid,nlay),pdvadj(ngrid,nlay) REAL po(ngrid,nlay),pdoadj(ngrid,nlay) REAL pplay(ngrid,nlay),pplev(ngrid,nlay+1) real pphi(ngrid,nlay) integer idetr save idetr data idetr/3/ c local: c ------ INTEGER ig,k,l,lmaxa(klon),lmix(klon) real zsortie1d(klon) c CR: on remplace lmax(klon,klev+1) INTEGER lmax(klon),lmin(klon),lentr(klon) real linter(klon) real zmix(klon), fracazmix(klon) c RC real zmax(klon),zw,zz,zw2(klon,klev+1),ztva(klon,klev),zzz real zlev(klon,klev+1),zlay(klon,klev) REAL zh(klon,klev),zdhadj(klon,klev) real zthl(klon,klev),zdthladj(klon,klev) REAL ztv(klon,klev) real zu(klon,klev),zv(klon,klev),zo(klon,klev) real zl(klon,klev) REAL wh(klon,klev+1) real wu(klon,klev+1),wv(klon,klev+1),wo(klon,klev+1) real zla(klon,klev+1) real zwa(klon,klev+1) real zld(klon,klev+1) real zwd(klon,klev+1) real zsortie(klon,klev) real zva(klon,klev) real zua(klon,klev) real zoa(klon,klev) real zta(klon,klev) real zha(klon,klev) real wa_moy(klon,klev+1) real fraca(klon,klev+1) real fracc(klon,klev+1) real zf,zf2 real thetath2(klon,klev),wth2(klon,klev) common/comtherm/thetath2,wth2 real count_time integer isplit,nsplit,ialt parameter (nsplit=10) data isplit/0/ save isplit logical sorties real rho(klon,klev),rhobarz(klon,klev+1),masse(klon,klev) real zpspsk(klon,klev) c real wmax(klon,klev),wmaxa(klon) real wmax(klon),wmaxa(klon) real wa(klon,klev,klev+1) real wd(klon,klev+1) real larg_part(klon,klev,klev+1) real fracd(klon,klev+1) real xxx(klon,klev+1) real larg_cons(klon,klev+1) real larg_detr(klon,klev+1) real fm0(klon,klev+1),entr0(klon,klev),detr(klon,klev) real pu_therm(klon,klev),pv_therm(klon,klev) real fm(klon,klev+1),entr(klon,klev) real fmc(klon,klev+1) real zcor,zdelta,zcvm5,qlbef real Tbef(klon),qsatbef(klon) real dqsat_dT,DT,num,denom REAL REPS,RLvCp,DDT0 real ztla(klon,klev),zqla(klon,klev),zqta(klon,klev) PARAMETER (DDT0=.01) cCR:nouvelles variables real f_star(klon,klev+1),entr_star(klon,klev) real entr_star_tot(klon),entr_star2(klon) real f(klon), f0(klon) real zlevinter(klon) logical first data first /.false./ save first cRC character*2 str2 character*10 str10 LOGICAL vtest(klon),down LOGICAL Zsat(klon) EXTERNAL SCOPY integer ncorrec,ll save ncorrec data ncorrec/0/ c c----------------------------------------------------------------------- c initialisation: c --------------- c sorties=.true. IF(ngrid.NE.klon) THEN PRINT* PRINT*,'STOP dans convadj' PRINT*,'ngrid =',ngrid PRINT*,'klon =',klon ENDIF c c Initialisation RLvCp = RLVTT/RCPD REPS = RD/RV c c----------------------------------------------------------------------- cAM Calcul de T,q,ql a partir de Tl et qT c --------------------------------------------------- c c Pr Tprec=Tl calcul de qsat c Si qsat>qT T=Tl, q=qT c Sinon DDT=(-Tprec+Tl+RLVCP (qT-qsat(T')) / (1+RLVCP dqsat/dt) c On cherche DDT < DDT0 c c defaut DO ll=1,nlay DO ig=1,ngrid zo(ig,ll)=po(ig,ll) zl(ig,ll)=0. zh(ig,ll)=pt(ig,ll) EndDO EndDO do ig=1,ngrid Zsat(ig)=.false. enddo c c DO ll=1,nlay c les points insatures sont definitifs DO ig=1,ngrid Tbef(ig)=pt(ig,ll) zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) qsatbef(ig)= R2ES * FOEEW(Tbef(ig),zdelta)/pplev(ig,ll) qsatbef(ig)=MIN(0.5,qsatbef(ig)) zcor=1./(1.-retv*qsatbef(ig)) qsatbef(ig)=qsatbef(ig)*zcor Zsat(ig) = (max(0.,po(ig,ll)-qsatbef(ig)) .gt. 0.00001) EndDO DO ig=1,ngrid if (Zsat(ig)) then qlbef=max(0.,po(ig,ll)-qsatbef(ig)) c si sature: ql est surestime, d'ou la sous-relax DT = 0.5*RLvCp*qlbef c on pourra enchainer 2 ou 3 calculs sans Do while do while (DT.gt.DDT0) c il faut verifier si c,a conserve quand on repasse en insature ... Tbef(ig)=Tbef(ig)+DT zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) qsatbef(ig)= R2ES * FOEEW(Tbef(ig),zdelta)/pplev(ig,ll) qsatbef(ig)=MIN(0.5,qsatbef(ig)) zcor=1./(1.-retv*qsatbef(ig)) qsatbef(ig)=qsatbef(ig)*zcor c on veut le signe de qlbef qlbef=po(ig,ll)-qsatbef(ig) c dqsat_dT zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) zcvm5=R5LES*(1.-zdelta) + R5IES*zdelta zcor=1./(1.-retv*qsatbef(ig)) dqsat_dT=FOEDE(Tbef(ig),zdelta,zcvm5,qsatbef(ig),zcor) num=-Tbef(ig)+pt(ig,ll)+RLvCp*qlbef denom=1.+RLvCp*dqsat_dT DT=num/denom enddo c on ecrit de maniere conservative (sat ou non) zl(ig,ll) = max(0.,qlbef) c T = Tl +Lv/Cp ql zh(ig,ll) = pt(ig,ll)+RLvCp*zl(ig,ll) zo(ig,ll) = po(ig,ll)-zl(ig,ll) endif EndDO EndDO cAM fin c c----------------------------------------------------------------------- c incrementation eventuelle de tendances precedentes: c --------------------------------------------------- print*,'0 OK convect8' DO 1010 l=1,nlay DO 1015 ig=1,ngrid zpspsk(ig,l)=(pplay(ig,l)/pplev(ig,1))**RKAPPA c zh(ig,l)=pt(ig,l)/zpspsk(ig,l) zu(ig,l)=pu(ig,l) zv(ig,l)=pv(ig,l) c zo(ig,l)=po(ig,l) c ztv(ig,l)=zh(ig,l)*(1.+0.61*zo(ig,l)) cAM attention zh est maintenant le profil de T et plus le profil de theta ! c c T-> Theta ztv(ig,l)=zh(ig,l)/zpspsk(ig,l) cAM Theta_v ztv(ig,l)=ztv(ig,l)*(1.+RETV*(zo(ig,l)) s -zl(ig,l)) cAM Thetal zthl(ig,l)=pt(ig,l)/zpspsk(ig,l) c 1015 CONTINUE 1010 CONTINUE c print*,'1 OK convect8' c -------------------- c c c + + + + + + + + + + + c c c wa, fraca, wd, fracd -------------------- zlev(2), rhobarz c wh,wt,wo ... c c + + + + + + + + + + + zh,zu,zv,zo,rho c c c -------------------- zlev(1) c \\\\\\\\\\\\\\\\\\\\ c c c----------------------------------------------------------------------- c Calcul des altitudes des couches c----------------------------------------------------------------------- do l=2,nlay do ig=1,ngrid zlev(ig,l)=0.5*(pphi(ig,l)+pphi(ig,l-1))/RG enddo enddo do ig=1,ngrid zlev(ig,1)=0. zlev(ig,nlay+1)=(2.*pphi(ig,klev)-pphi(ig,klev-1))/RG enddo do l=1,nlay do ig=1,ngrid zlay(ig,l)=pphi(ig,l)/RG enddo enddo c print*,'2 OK convect8' c----------------------------------------------------------------------- c Calcul des densites c----------------------------------------------------------------------- do l=1,nlay do ig=1,ngrid c rho(ig,l)=pplay(ig,l)/(zpspsk(ig,l)*RD*zh(ig,l)) rho(ig,l)=pplay(ig,l)/(zpspsk(ig,l)*RD*ztv(ig,l)) enddo enddo do l=2,nlay do ig=1,ngrid rhobarz(ig,l)=0.5*(rho(ig,l)+rho(ig,l-1)) enddo enddo do k=1,nlay do l=1,nlay+1 do ig=1,ngrid wa(ig,k,l)=0. enddo enddo enddo c print*,'3 OK convect8' c------------------------------------------------------------------ c Calcul de w2, quarre de w a partir de la cape c a partir de w2, on calcule wa, vitesse de l'ascendance c c ATTENTION: Dans cette version, pour cause d'economie de memoire, c w2 est stoke dans wa c c ATTENTION: dans convect8, on n'utilise le calcule des wa c independants par couches que pour calculer l'entrainement c a la base et la hauteur max de l'ascendance. c c Indicages: c l'ascendance provenant du niveau k traverse l'interface l avec c une vitesse wa(k,l). c c -------------------- c c + + + + + + + + + + c c wa(k,l) ---- -------------------- l c /\ c /||\ + + + + + + + + + + c || c || -------------------- c || c || + + + + + + + + + + c || c || -------------------- c ||__ c |___ + + + + + + + + + + k c c -------------------- c c c c------------------------------------------------------------------ cCR: ponderation entrainement des couches instables cdef des entr_star tels que entr=f*entr_star do l=1,klev do ig=1,ngrid entr_star(ig,l)=0. enddo enddo c determination de la longueur de la couche d entrainement do ig=1,ngrid lentr(ig)=1 enddo con ne considere que les premieres couches instables do k=nlay-1,1,-1 do ig=1,ngrid if (ztv(ig,k).gt.ztv(ig,k+1).and. s ztv(ig,k+1).lt.ztv(ig,k+2)) then lentr(ig)=k endif enddo enddo c determination du lmin: couche d ou provient le thermique do ig=1,ngrid lmin(ig)=1 enddo do ig=1,ngrid do l=nlay,2,-1 if (ztv(ig,l-1).gt.ztv(ig,l)) then lmin(ig)=l-1 endif enddo enddo c c definition de l'entrainement des couches do l=1,klev-1 do ig=1,ngrid if (ztv(ig,l).gt.ztv(ig,l+1).and. s l.ge.lmin(ig).and.l.le.lentr(ig)) then entr_star(ig,l)=(ztv(ig,l)-ztv(ig,l+1))* s (zlev(ig,l+1)-zlev(ig,l)) endif enddo enddo c pas de thermique si couche 1 stable do ig=1,ngrid if (lmin(ig).gt.1) then do l=1,klev entr_star(ig,l)=0. enddo endif enddo c calcul de l entrainement total do ig=1,ngrid entr_star_tot(ig)=0. enddo do ig=1,ngrid do k=1,klev entr_star_tot(ig)=entr_star_tot(ig)+entr_star(ig,k) enddo enddo c do k=1,klev do ig=1,ngrid ztva(ig,k)=ztv(ig,k) enddo enddo cRC cAM:initialisations do k=1,nlay do ig=1,ngrid ztva(ig,k)=ztv(ig,k) ztla(ig,k)=zthl(ig,k) zqla(ig,k)=0. zqta(ig,k)=po(ig,k) Zsat(ig) =.false. enddo enddo c c print*,'7 OK convect8' do k=1,klev+1 do ig=1,ngrid zw2(ig,k)=0. fmc(ig,k)=0. cCR f_star(ig,k)=0. cRC larg_cons(ig,k)=0. larg_detr(ig,k)=0. wa_moy(ig,k)=0. enddo enddo c print*,'8 OK convect8' do ig=1,ngrid linter(ig)=1. lmaxa(ig)=1 lmix(ig)=1 wmaxa(ig)=0. enddo cCR: do l=1,nlay-2 do ig=1,ngrid if (ztv(ig,l).gt.ztv(ig,l+1) s .and.entr_star(ig,l).gt.1.e-10 s .and.zw2(ig,l).lt.1e-10) then cAM ztla(ig,l)=zthl(ig,l) zqta(ig,l)=po(ig,l) zqla(ig,l)=zl(ig,l) cAM f_star(ig,l+1)=entr_star(ig,l) ctest:calcul de dteta zw2(ig,l+1)=2.*RG*(ztv(ig,l)-ztv(ig,l+1))/ztv(ig,l+1) s *(zlev(ig,l+1)-zlev(ig,l)) s *0.4*pphi(ig,l)/(pphi(ig,l+1)-pphi(ig,l)) larg_detr(ig,l)=0. else if ((zw2(ig,l).ge.1e-10).and. s (f_star(ig,l)+entr_star(ig,l).gt.1.e-10)) then f_star(ig,l+1)=f_star(ig,l)+entr_star(ig,l) c cAM on melange Tl et qt du thermique ztla(ig,l)=(f_star(ig,l)*ztla(ig,l-1)+entr_star(ig,l) s *zthl(ig,l))/f_star(ig,l+1) zqta(ig,l)=(f_star(ig,l)*zqta(ig,l-1)+entr_star(ig,l) s *po(ig,l))/f_star(ig,l+1) c c ztva(ig,l)=(f_star(ig,l)*ztva(ig,l-1)+entr_star(ig,l) c s *ztv(ig,l))/f_star(ig,l+1) c cAM on en deduit thetav et ql du thermique Tbef(ig)=ztla(ig,l)*zpspsk(ig,l) zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) qsatbef(ig)= R2ES * FOEEW(Tbef(ig),zdelta)/pplev(ig,l) qsatbef(ig)=MIN(0.5,qsatbef(ig)) zcor=1./(1.-retv*qsatbef(ig)) qsatbef(ig)=qsatbef(ig)*zcor Zsat(ig) = (max(0.,zqta(ig,l)-qsatbef(ig)) .gt. 0.00001) endif enddo DO ig=1,ngrid if (Zsat(ig)) then qlbef=max(0.,zqta(ig,l)-qsatbef(ig)) DT = 0.5*RLvCp*qlbef do while (DT.gt.DDT0) Tbef(ig)=Tbef(ig)+DT zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) qsatbef(ig)= R2ES * FOEEW(Tbef(ig),zdelta)/pplev(ig,l) qsatbef(ig)=MIN(0.5,qsatbef(ig)) zcor=1./(1.-retv*qsatbef(ig)) qsatbef(ig)=qsatbef(ig)*zcor qlbef=zqta(ig,l)-qsatbef(ig) zdelta=MAX(0.,SIGN(1.,RTT-Tbef(ig))) zcvm5=R5LES*(1.-zdelta) + R5IES*zdelta zcor=1./(1.-retv*qsatbef(ig)) dqsat_dT=FOEDE(Tbef(ig),zdelta,zcvm5,qsatbef(ig),zcor) num=-Tbef(ig)+ztla(ig,l)*zpspsk(ig,l)+RLvCp*qlbef denom=1.+RLvCp*dqsat_dT DT=num/denom enddo zqla(ig,l) = max(0.,zqta(ig,l)-qsatbef(ig)) endif c on ecrit de maniere conservative (sat ou non) c T = Tl +Lv/Cp ql ztva(ig,l) = ztla(ig,l)*zpspsk(ig,l)+RLvCp*zqla(ig,l) ztva(ig,l) = ztva(ig,l)/zpspsk(ig,l) ztva(ig,l) = ztva(ig,l)*(1.+RETV*(zqta(ig,l) s -zqla(ig,l))-zqla(ig,l)) enddo DO ig=1,ngrid if (zw2(ig,l).ge.1.e-10.and. s f_star(ig,l)+entr_star(ig,l).gt.1.e-10) then c mise a jour de la vitesse ascendante (l'air entraine de la couche c consideree commence avec une vitesse nulle). c zw2(ig,l+1)=zw2(ig,l)*(f_star(ig,l)/f_star(ig,l+1))**2+ s 2.*RG*(ztva(ig,l)-ztv(ig,l))/ztv(ig,l) s *(zlev(ig,l+1)-zlev(ig,l)) endif c determination de zmax continu par interpolation lineaire if (zw2(ig,l+1).lt.0.) then linter(ig)=(l*(zw2(ig,l+1)-zw2(ig,l)) s -zw2(ig,l))/(zw2(ig,l+1)-zw2(ig,l)) zw2(ig,l+1)=0. lmaxa(ig)=l else wa_moy(ig,l+1)=sqrt(zw2(ig,l+1)) endif if (wa_moy(ig,l+1).gt.wmaxa(ig)) then c lmix est le niveau de la couche ou w (wa_moy) est maximum lmix(ig)=l+1 wmaxa(ig)=wa_moy(ig,l+1) endif enddo enddo c c Calcul de la couche correspondant a la hauteur du thermique do ig=1,ngrid lmax(ig)=lentr(ig) enddo do ig=1,ngrid do l=nlay,lentr(ig)+1,-1 if (zw2(ig,l).le.1.e-10) then lmax(ig)=l-1 endif enddo enddo c pas de thermique si couche 1 stable do ig=1,ngrid if (lmin(ig).gt.1) then lmax(ig)=1 lmin(ig)=1 endif enddo c c Determination de zw2 max do ig=1,ngrid wmax(ig)=0. enddo do l=1,nlay do ig=1,ngrid if (l.le.lmax(ig)) then zw2(ig,l)=sqrt(zw2(ig,l)) wmax(ig)=max(wmax(ig),zw2(ig,l)) else zw2(ig,l)=0. endif enddo enddo c Longueur caracteristique correspondant a la hauteur des thermiques. do ig=1,ngrid zmax(ig)=500. zlevinter(ig)=zlev(ig,1) enddo do ig=1,ngrid c calcul de zlevinter zlevinter(ig)=(zlev(ig,lmax(ig)+1)-zlev(ig,lmax(ig)))* s linter(ig)+zlev(ig,lmax(ig))-lmax(ig)*(zlev(ig,lmax(ig)+1) s -zlev(ig,lmax(ig))) zmax(ig)=max(zmax(ig),zlevinter(ig)-zlev(ig,lmin(ig))) enddo c Fermeture,determination de f do ig=1,ngrid entr_star2(ig)=0. enddo do ig=1,ngrid if (entr_star_tot(ig).LT.1.e-10) then f(ig)=0. else do k=lmin(ig),lentr(ig) entr_star2(ig)=entr_star2(ig)+entr_star(ig,k)**2 s /(rho(ig,k)*(zlev(ig,k+1)-zlev(ig,k))) enddo c Nouvelle fermeture f(ig)=wmax(ig)/(zmax(ig)*r_aspect*entr_star2(ig)) s *entr_star_tot(ig) ctest if (first) then f(ig)=f(ig)+(f0(ig)-f(ig))*exp(-ptimestep/zmax(ig) s *wmax(ig)) endif endif f0(ig)=f(ig) first=.true. enddo c Calcul de l'entrainement do k=1,klev do ig=1,ngrid entr(ig,k)=f(ig)*entr_star(ig,k) enddo enddo c Calcul des flux do ig=1,ngrid do l=1,lmax(ig)-1 fmc(ig,l+1)=fmc(ig,l)+entr(ig,l) enddo enddo cRC c print*,'9 OK convect8' c print*,'WA1 ',wa_moy c determination de l'indice du debut de la mixed layer ou w decroit c calcul de la largeur de chaque ascendance dans le cas conservatif. c dans ce cas simple, on suppose que la largeur de l'ascendance provenant c d'une couche est égale à la hauteur de la couche alimentante. c La vitesse maximale dans l'ascendance est aussi prise comme estimation c de la vitesse d'entrainement horizontal dans la couche alimentante. do l=2,nlay do ig=1,ngrid if (l.le.lmaxa(ig)) then zw=max(wa_moy(ig,l),1.e-10) larg_cons(ig,l)=zmax(ig)*r_aspect s *fmc(ig,l)/(rhobarz(ig,l)*zw) endif enddo enddo do l=2,nlay do ig=1,ngrid if (l.le.lmaxa(ig)) then c if (idetr.eq.0) then c cette option est finalement en dur. larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c else if (idetr.eq.1) then c larg_detr(ig,l)=larg_cons(ig,l) c s *sqrt(l_mix*zlev(ig,l))/larg_cons(ig,lmix(ig)) c else if (idetr.eq.2) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *sqrt(wa_moy(ig,l)) c else if (idetr.eq.4) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *wa_moy(ig,l) c endif endif enddo enddo c print*,'10 OK convect8' c print*,'WA2 ',wa_moy c calcul de la fraction de la maille concernée par l'ascendance en tenant c compte de l'epluchage du thermique. c cCR def de zmix continu (profil parabolique des vitesses) do ig=1,ngrid if (lmix(ig).gt.1.) then zmix(ig)=((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))**2-(zlev(ig,lmix(ig)+1))**2) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))**2-(zlev(ig,lmix(ig)))**2)) s /(2.*((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))-(zlev(ig,lmix(ig)+1))) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))-(zlev(ig,lmix(ig)))))) else zmix(ig)=0. endif enddo c c calcul du nouveau lmix correspondant do ig=1,ngrid do l=1,klev if (zmix(ig).ge.zlev(ig,l).and. s zmix(ig).lt.zlev(ig,l+1)) then lmix(ig)=l endif enddo enddo c do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1.) then c print*,ig,l,lmix(ig),lmaxa(ig),larg_cons(ig,l),' KKK' fraca(ig,l)=(larg_cons(ig,l)-larg_detr(ig,l)) s /(r_aspect*zmax(ig)) c test fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) else c wa_moy(ig,l)=0. fraca(ig,l)=0. fracc(ig,l)=0. fracd(ig,l)=1. endif enddo enddo cCR: calcul de fracazmix do ig=1,ngrid fracazmix(ig)=(fraca(ig,lmix(ig)+1)-fraca(ig,lmix(ig)))/ s (zlev(ig,lmix(ig)+1)-zlev(ig,lmix(ig)))*zmix(ig) s +fraca(ig,lmix(ig))-zlev(ig,lmix(ig))*(fraca(ig,lmix(ig)+1) s -fraca(ig,lmix(ig)))/(zlev(ig,lmix(ig)+1)-zlev(ig,lmix(ig))) enddo c do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1.) then if (l.gt.lmix(ig)) then xxx(ig,l)=(zmax(ig)-zlev(ig,l))/(zmax(ig)-zmix(ig)) if (idetr.eq.0) then fraca(ig,l)=fracazmix(ig) else if (idetr.eq.1) then fraca(ig,l)=fracazmix(ig)*xxx(ig,l) else if (idetr.eq.2) then fraca(ig,l)=fracazmix(ig)*(1.-(1.-xxx(ig,l))**2) else fraca(ig,l)=fracazmix(ig)*xxx(ig,l)**2 endif c print*,ig,l,lmix(ig),lmaxa(ig),xxx(ig,l),'LLLLLLL' fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) endif endif enddo enddo c print*,'11 OK convect8' c print*,'Ea3 ',wa_moy c------------------------------------------------------------------ c Calcul de fracd, wd c somme wa - wd = 0 c------------------------------------------------------------------ do ig=1,ngrid fm(ig,1)=0. fm(ig,nlay+1)=0. enddo do l=2,nlay do ig=1,ngrid fm(ig,l)=fraca(ig,l)*wa_moy(ig,l)*rhobarz(ig,l) cCR:test if (entr(ig,l-1).lt.1e-10.and.fm(ig,l).gt.fm(ig,l-1) s .and.l.gt.lmix(ig)) then fm(ig,l)=fm(ig,l-1) c write(1,*)'ajustement fm, l',l endif c write(1,*)'ig,l,fm(ig,l)',ig,l,fm(ig,l) cRC enddo do ig=1,ngrid if(fracd(ig,l).lt.0.1) then stop'fracd trop petit' else c vitesse descendante "diagnostique" wd(ig,l)=fm(ig,l)/(fracd(ig,l)*rhobarz(ig,l)) endif enddo enddo do l=1,nlay do ig=1,ngrid c masse(ig,l)=rho(ig,l)*(zlev(ig,l+1)-zlev(ig,l)) masse(ig,l)=(pplev(ig,l)-pplev(ig,l+1))/RG enddo enddo c print*,'12 OK convect8' c print*,'WA4 ',wa_moy cc------------------------------------------------------------------ c calcul du transport vertical c------------------------------------------------------------------ go to 4444 c print*,'XXXXXXXXXXXXXXX ptimestep= ',ptimestep do l=2,nlay-1 do ig=1,ngrid if(fm(ig,l+1)*ptimestep.gt.masse(ig,l) s .and.fm(ig,l+1)*ptimestep.gt.masse(ig,l+1)) then c print*,'WARN!!! FM>M ig=',ig,' l=',l,' FM=' c s ,fm(ig,l+1)*ptimestep c s ,' M=',masse(ig,l),masse(ig,l+1) endif enddo enddo do l=1,nlay do ig=1,ngrid if(entr(ig,l)*ptimestep.gt.masse(ig,l)) then c print*,'WARN!!! E>M ig=',ig,' l=',l,' E==' c s ,entr(ig,l)*ptimestep c s ,' M=',masse(ig,l) endif enddo enddo do l=1,nlay do ig=1,ngrid if(.not.fm(ig,l).ge.0..or..not.fm(ig,l).le.10.) then c print*,'WARN!!! fm exagere ig=',ig,' l=',l c s ,' FM=',fm(ig,l) endif if(.not.masse(ig,l).ge.1.e-10 s .or..not.masse(ig,l).le.1.e4) then c print*,'WARN!!! masse exagere ig=',ig,' l=',l c s ,' M=',masse(ig,l) c print*,'rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l)', c s rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l) c print*,'zlev(ig,l+1),zlev(ig,l)' c s ,zlev(ig,l+1),zlev(ig,l) c print*,'pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1)' c s ,pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1) endif if(.not.entr(ig,l).ge.0..or..not.entr(ig,l).le.10.) then c print*,'WARN!!! entr exagere ig=',ig,' l=',l c s ,' E=',entr(ig,l) endif enddo enddo 4444 continue if (w2di.eq.1) then fm0=fm0+ptimestep*(fm-fm0)/float(tho) entr0=entr0+ptimestep*(entr-entr0)/float(tho) else fm0=fm entr0=entr endif if (1.eq.1) then c call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse c . ,zh,zdhadj,zha) c call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse c . ,zo,pdoadj,zoa) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zthl,zdthladj,zta) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,po,pdoadj,zoa) else call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zh,zdhadj,zha) call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zo,pdoadj,zoa) endif if (1.eq.0) then call dvthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse . ,fraca,zmax . ,zu,zv,pduadj,pdvadj,zua,zva) else call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zu,pduadj,zua) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zv,pdvadj,zva) endif do l=1,nlay do ig=1,ngrid zf=0.5*(fracc(ig,l)+fracc(ig,l+1)) zf2=zf/(1.-zf) thetath2(ig,l)=zf2*(zha(ig,l)-zh(ig,l))**2 wth2(ig,l)=zf2*(0.5*(wa_moy(ig,l)+wa_moy(ig,l+1)))**2 enddo enddo c print*,'13 OK convect8' c print*,'WA5 ',wa_moy do l=1,nlay do ig=1,ngrid c pdtadj(ig,l)=zdhadj(ig,l)*zpspsk(ig,l) pdtadj(ig,l)=zdthladj(ig,l)*zpspsk(ig,l) enddo enddo c do l=1,nlay c do ig=1,ngrid c if(abs(pdtadj(ig,l))*86400..gt.500.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdtadj=',pdtadj(ig,l) c endif c if(abs(pdoadj(ig,l))*86400..gt.1.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdoadj=',pdoadj(ig,l) c endif c enddo c enddo c print*,'14 OK convect8' c------------------------------------------------------------------ c Calculs pour les sorties c------------------------------------------------------------------ if(sorties) then do l=1,nlay do ig=1,ngrid zla(ig,l)=(1.-fracd(ig,l))*zmax(ig) zld(ig,l)=fracd(ig,l)*zmax(ig) if(1.-fracd(ig,l).gt.1.e-10) s zwa(ig,l)=wd(ig,l)*fracd(ig,l)/(1.-fracd(ig,l)) enddo enddo do l=1,nlay do ig=1,ngrid detr(ig,l)=fm(ig,l)+entr(ig,l)-fm(ig,l+1) if (detr(ig,l).lt.0.) then entr(ig,l)=entr(ig,l)-detr(ig,l) detr(ig,l)=0. c print*,'WARNING !!! detrainement negatif ',ig,l endif enddo enddo c print*,'15 OK convect8' isplit=isplit+1 c #define und goto 123 #ifdef und CALL writeg1d(1,nlay,wd,'wd ','wd ') CALL writeg1d(1,nlay,zwa,'wa ','wa ') CALL writeg1d(1,nlay,fracd,'fracd ','fracd ') CALL writeg1d(1,nlay,fraca,'fraca ','fraca ') CALL writeg1d(1,nlay,wa_moy,'wam ','wam ') CALL writeg1d(1,nlay,zla,'la ','la ') CALL writeg1d(1,nlay,zld,'ld ','ld ') CALL writeg1d(1,nlay,pt,'pt ','pt ') CALL writeg1d(1,nlay,zh,'zh ','zh ') CALL writeg1d(1,nlay,zha,'zha ','zha ') CALL writeg1d(1,nlay,zu,'zu ','zu ') CALL writeg1d(1,nlay,zv,'zv ','zv ') CALL writeg1d(1,nlay,zo,'zo ','zo ') CALL writeg1d(1,nlay,wh,'wh ','wh ') CALL writeg1d(1,nlay,wu,'wu ','wu ') CALL writeg1d(1,nlay,wv,'wv ','wv ') CALL writeg1d(1,nlay,wo,'w15uo ','wXo ') CALL writeg1d(1,nlay,zdhadj,'zdhadj ','zdhadj ') CALL writeg1d(1,nlay,pduadj,'pduadj ','pduadj ') CALL writeg1d(1,nlay,pdvadj,'pdvadj ','pdvadj ') CALL writeg1d(1,nlay,pdoadj,'pdoadj ','pdoadj ') CALL writeg1d(1,nlay,entr ,'entr ','entr ') CALL writeg1d(1,nlay,detr ,'detr ','detr ') CALL writeg1d(1,nlay,fm ,'fm ','fm ') CALL writeg1d(1,nlay,pdtadj,'pdtadj ','pdtadj ') CALL writeg1d(1,nlay,pplay,'pplay ','pplay ') CALL writeg1d(1,nlay,pplev,'pplev ','pplev ') c recalcul des flux en diagnostique... c print*,'PAS DE TEMPS ',ptimestep call dt2F(pplev,pplay,pt,pdtadj,wh) CALL writeg1d(1,nlay,wh,'wh2 ','wh2 ') #endif 123 continue ! #define troisD #ifdef troisD c if (sorties) then print*,'Debut des wrgradsfi' c print*,'16 OK convect8' call wrgradsfi(1,nlay,wd,'wd ','wd ') call wrgradsfi(1,nlay,zwa,'wa ','wa ') call wrgradsfi(1,nlay,fracd,'fracd ','fracd ') call wrgradsfi(1,nlay,fraca,'fraca ','fraca ') call wrgradsfi(1,nlay,xxx,'xxx ','xxx ') call wrgradsfi(1,nlay,wa_moy,'wam ','wam ') c print*,'WA6 ',wa_moy call wrgradsfi(1,nlay,zla,'la ','la ') call wrgradsfi(1,nlay,zld,'ld ','ld ') call wrgradsfi(1,nlay,pt,'pt ','pt ') call wrgradsfi(1,nlay,zh,'zh ','zh ') call wrgradsfi(1,nlay,zha,'zha ','zha ') call wrgradsfi(1,nlay,zua,'zua ','zua ') call wrgradsfi(1,nlay,zva,'zva ','zva ') call wrgradsfi(1,nlay,zu,'zu ','zu ') call wrgradsfi(1,nlay,zv,'zv ','zv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,wh,'wh ','wh ') call wrgradsfi(1,nlay,wu,'wu ','wu ') call wrgradsfi(1,nlay,wv,'wv ','wv ') call wrgradsfi(1,nlay,wo,'wo ','wo ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,nlay,zdhadj,'zdhadj ','zdhadj ') call wrgradsfi(1,nlay,pduadj,'pduadj ','pduadj ') call wrgradsfi(1,nlay,pdvadj,'pdvadj ','pdvadj ') call wrgradsfi(1,nlay,pdoadj,'pdoadj ','pdoadj ') call wrgradsfi(1,nlay,entr,'entr ','entr ') call wrgradsfi(1,nlay,detr,'detr ','detr ') call wrgradsfi(1,nlay,fm,'fm ','fm ') call wrgradsfi(1,nlay,fmc,'fmc ','fmc ') call wrgradsfi(1,nlay,zw2,'zw2 ','zw2 ') call wrgradsfi(1,nlay,ztva,'ztva ','ztva ') call wrgradsfi(1,nlay,ztv,'ztv ','ztv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,larg_cons,'Lc ','Lc ') call wrgradsfi(1,nlay,larg_detr,'Ldetr ','Ldetr ') cAM:nouveaux diagnostiques call wrgradsfi(1,nlay,zthl,'zthl ','zthl ') call wrgradsfi(1,nlay,zta,'zta ','zta ') call wrgradsfi(1,nlay,zl,'zl ','zl ') call wrgradsfi(1,nlay,zdthladj,'zdthladj ', s 'zdthladj ') call wrgradsfi(1,nlay,ztla,'ztla ','ztla ') call wrgradsfi(1,nlay,zqta,'zqta ','zqta ') call wrgradsfi(1,nlay,zqla,'zqla ','zqla ') cCR:nouveaux diagnostiques call wrgradsfi(1,nlay,entr_star ,'entr_star ','entr_star ') call wrgradsfi(1,nlay,f_star ,'f_star ','f_star ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,1,zmix,'zmix ','zmix ') zsortie1d(:)=lmax(:) call wrgradsfi(1,1,zsortie1d,'lmax ','lmax ') call wrgradsfi(1,1,wmax,'wmax ','wmax ') zsortie1d(:)=lmix(:) call wrgradsfi(1,1,zsortie1d,'lmix ','lmix ') zsortie1d(:)=lentr(:) call wrgradsfi(1,1,zsortie1d,'lentr ','lentr ') c print*,'17 OK convect8' do k=1,klev/10 write(str2,'(i2.2)') k str10='wa'//str2 do l=1,nlay do ig=1,ngrid zsortie(ig,l)=wa(ig,k,l) enddo enddo CALL wrgradsfi(1,nlay,zsortie,str10,str10) do l=1,nlay do ig=1,ngrid zsortie(ig,l)=larg_part(ig,k,l) enddo enddo str10='la'//str2 CALL wrgradsfi(1,nlay,zsortie,str10,str10) enddo c print*,'18 OK convect8' c endif print*,'Fin des wrgradsfi' #endif endif c if(wa_moy(1,4).gt.1.e-10) stop c print*,'19 OK convect8' return end SUBROUTINE thermcell(ngrid,nlay,ptimestep s ,pplay,pplev,pphi s ,pu,pv,pt,po s ,pduadj,pdvadj,pdtadj,pdoadj s ,fm0,entr0 c s ,pu_therm,pv_therm s ,r_aspect,l_mix,w2di,tho) IMPLICIT NONE c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c c Réécriture à partir d'un listing papier à Habas, le 14/02/00 c c le thermique est supposé homogène et dissipé par mélange avec c son environnement. la longueur l_mix contrôle l'efficacité du c mélange c c Le calcul du transport des différentes espèces se fait en prenant c en compte: c 1. un flux de masse montant c 2. un flux de masse descendant c 3. un entrainement c 4. un detrainement c c======================================================================= c----------------------------------------------------------------------- c declarations: c ------------- #include "dimensions.h" #include "dimphy.h" #include "YOMCST.h" c arguments: c ---------- INTEGER ngrid,nlay,w2di,tho real ptimestep,l_mix,r_aspect REAL pt(ngrid,nlay),pdtadj(ngrid,nlay) REAL pu(ngrid,nlay),pduadj(ngrid,nlay) REAL pv(ngrid,nlay),pdvadj(ngrid,nlay) REAL po(ngrid,nlay),pdoadj(ngrid,nlay) REAL pplay(ngrid,nlay),pplev(ngrid,nlay+1) real pphi(ngrid,nlay) integer idetr save idetr data idetr/3/ c local: c ------ INTEGER ig,k,l,lmaxa(klon),lmix(klon) real zsortie1d(klon) c CR: on remplace lmax(klon,klev+1) INTEGER lmax(klon),lmin(klon),lentr(klon) real linter(klon) real zmix(klon), fracazmix(klon) c RC real zmax(klon),zw,zz,zw2(klon,klev+1),ztva(klon,klev),zzz real zlev(klon,klev+1),zlay(klon,klev) REAL zh(klon,klev),zdhadj(klon,klev) REAL ztv(klon,klev) real zu(klon,klev),zv(klon,klev),zo(klon,klev) REAL wh(klon,klev+1) real wu(klon,klev+1),wv(klon,klev+1),wo(klon,klev+1) real zla(klon,klev+1) real zwa(klon,klev+1) real zld(klon,klev+1) real zwd(klon,klev+1) real zsortie(klon,klev) real zva(klon,klev) real zua(klon,klev) real zoa(klon,klev) real zha(klon,klev) real wa_moy(klon,klev+1) real fraca(klon,klev+1) real fracc(klon,klev+1) real zf,zf2 real thetath2(klon,klev),wth2(klon,klev) common/comtherm/thetath2,wth2 real count_time integer isplit,nsplit,ialt parameter (nsplit=10) data isplit/0/ save isplit logical sorties real rho(klon,klev),rhobarz(klon,klev+1),masse(klon,klev) real zpspsk(klon,klev) c real wmax(klon,klev),wmaxa(klon) real wmax(klon),wmaxa(klon) real wa(klon,klev,klev+1) real wd(klon,klev+1) real larg_part(klon,klev,klev+1) real fracd(klon,klev+1) real xxx(klon,klev+1) real larg_cons(klon,klev+1) real larg_detr(klon,klev+1) real fm0(klon,klev+1),entr0(klon,klev),detr(klon,klev) real pu_therm(klon,klev),pv_therm(klon,klev) real fm(klon,klev+1),entr(klon,klev) real fmc(klon,klev+1) cCR:nouvelles variables real f_star(klon,klev+1),entr_star(klon,klev) real entr_star_tot(klon),entr_star2(klon) real f(klon), f0(klon) real zlevinter(klon) logical first data first /.false./ save first cRC character*2 str2 character*10 str10 LOGICAL vtest(klon),down EXTERNAL SCOPY integer ncorrec,ll save ncorrec data ncorrec/0/ c c----------------------------------------------------------------------- c initialisation: c --------------- c sorties=.true. IF(ngrid.NE.klon) THEN PRINT* PRINT*,'STOP dans convadj' PRINT*,'ngrid =',ngrid PRINT*,'klon =',klon ENDIF c c----------------------------------------------------------------------- c incrementation eventuelle de tendances precedentes: c --------------------------------------------------- print*,'0 OK convect8' DO 1010 l=1,nlay DO 1015 ig=1,ngrid zpspsk(ig,l)=(pplay(ig,l)/pplev(ig,1))**RKAPPA zh(ig,l)=pt(ig,l)/zpspsk(ig,l) zu(ig,l)=pu(ig,l) zv(ig,l)=pv(ig,l) zo(ig,l)=po(ig,l) ztv(ig,l)=zh(ig,l)*(1.+0.61*zo(ig,l)) 1015 CONTINUE 1010 CONTINUE print*,'1 OK convect8' c -------------------- c c c + + + + + + + + + + + c c c wa, fraca, wd, fracd -------------------- zlev(2), rhobarz c wh,wt,wo ... c c + + + + + + + + + + + zh,zu,zv,zo,rho c c c -------------------- zlev(1) c \\\\\\\\\\\\\\\\\\\\ c c c----------------------------------------------------------------------- c Calcul des altitudes des couches c----------------------------------------------------------------------- do l=2,nlay do ig=1,ngrid zlev(ig,l)=0.5*(pphi(ig,l)+pphi(ig,l-1))/RG enddo enddo do ig=1,ngrid zlev(ig,1)=0. zlev(ig,nlay+1)=(2.*pphi(ig,klev)-pphi(ig,klev-1))/RG enddo do l=1,nlay do ig=1,ngrid zlay(ig,l)=pphi(ig,l)/RG enddo enddo c print*,'2 OK convect8' c----------------------------------------------------------------------- c Calcul des densites c----------------------------------------------------------------------- do l=1,nlay do ig=1,ngrid rho(ig,l)=pplay(ig,l)/(zpspsk(ig,l)*RD*zh(ig,l)) enddo enddo do l=2,nlay do ig=1,ngrid rhobarz(ig,l)=0.5*(rho(ig,l)+rho(ig,l-1)) enddo enddo do k=1,nlay do l=1,nlay+1 do ig=1,ngrid wa(ig,k,l)=0. enddo enddo enddo c print*,'3 OK convect8' c------------------------------------------------------------------ c Calcul de w2, quarre de w a partir de la cape c a partir de w2, on calcule wa, vitesse de l'ascendance c c ATTENTION: Dans cette version, pour cause d'economie de memoire, c w2 est stoke dans wa c c ATTENTION: dans convect8, on n'utilise le calcule des wa c independants par couches que pour calculer l'entrainement c a la base et la hauteur max de l'ascendance. c c Indicages: c l'ascendance provenant du niveau k traverse l'interface l avec c une vitesse wa(k,l). c c -------------------- c c + + + + + + + + + + c c wa(k,l) ---- -------------------- l c /\ c /||\ + + + + + + + + + + c || c || -------------------- c || c || + + + + + + + + + + c || c || -------------------- c ||__ c |___ + + + + + + + + + + k c c -------------------- c c c c------------------------------------------------------------------ cCR: ponderation entrainement des couches instables cdef des entr_star tels que entr=f*entr_star do l=1,klev do ig=1,ngrid entr_star(ig,l)=0. enddo enddo c determination de la longueur de la couche d entrainement do ig=1,ngrid lentr(ig)=1 enddo con ne considere que les premieres couches instables do k=nlay-2,1,-1 do ig=1,ngrid if (ztv(ig,k).gt.ztv(ig,k+1).and. s ztv(ig,k+1).le.ztv(ig,k+2)) then lentr(ig)=k endif enddo enddo c determination du lmin: couche d ou provient le thermique do ig=1,ngrid lmin(ig)=1 enddo do ig=1,ngrid do l=nlay,2,-1 if (ztv(ig,l-1).gt.ztv(ig,l)) then lmin(ig)=l-1 endif enddo enddo c c definition de l'entrainement des couches do l=1,klev-1 do ig=1,ngrid if (ztv(ig,l).gt.ztv(ig,l+1).and. s l.ge.lmin(ig).and.l.le.lentr(ig)) then entr_star(ig,l)=(ztv(ig,l)-ztv(ig,l+1))* s (zlev(ig,l+1)-zlev(ig,l)) endif enddo enddo c pas de thermique si couches 1->5 stables do ig=1,ngrid if (lmin(ig).gt.5) then do l=1,klev entr_star(ig,l)=0. enddo endif enddo c calcul de l entrainement total do ig=1,ngrid entr_star_tot(ig)=0. enddo do ig=1,ngrid do k=1,klev entr_star_tot(ig)=entr_star_tot(ig)+entr_star(ig,k) enddo enddo c print*,'fin calcul entr_star' do k=1,klev do ig=1,ngrid ztva(ig,k)=ztv(ig,k) enddo enddo cRC c print*,'7 OK convect8' do k=1,klev+1 do ig=1,ngrid zw2(ig,k)=0. fmc(ig,k)=0. cCR f_star(ig,k)=0. cRC larg_cons(ig,k)=0. larg_detr(ig,k)=0. wa_moy(ig,k)=0. enddo enddo c print*,'8 OK convect8' do ig=1,ngrid linter(ig)=1. lmaxa(ig)=1 lmix(ig)=1 wmaxa(ig)=0. enddo cCR: do l=1,nlay-2 do ig=1,ngrid if (ztv(ig,l).gt.ztv(ig,l+1) s .and.entr_star(ig,l).gt.1.e-10 s .and.zw2(ig,l).lt.1e-10) then f_star(ig,l+1)=entr_star(ig,l) ctest:calcul de dteta zw2(ig,l+1)=2.*RG*(ztv(ig,l)-ztv(ig,l+1))/ztv(ig,l+1) s *(zlev(ig,l+1)-zlev(ig,l)) s *0.4*pphi(ig,l)/(pphi(ig,l+1)-pphi(ig,l)) larg_detr(ig,l)=0. else if ((zw2(ig,l).ge.1e-10).and. s (f_star(ig,l)+entr_star(ig,l).gt.1.e-10)) then f_star(ig,l+1)=f_star(ig,l)+entr_star(ig,l) ztva(ig,l)=(f_star(ig,l)*ztva(ig,l-1)+entr_star(ig,l) s *ztv(ig,l))/f_star(ig,l+1) zw2(ig,l+1)=zw2(ig,l)*(f_star(ig,l)/f_star(ig,l+1))**2+ s 2.*RG*(ztva(ig,l)-ztv(ig,l))/ztv(ig,l) s *(zlev(ig,l+1)-zlev(ig,l)) endif c determination de zmax continu par interpolation lineaire if (zw2(ig,l+1).lt.0.) then ctest if (abs(zw2(ig,l+1)-zw2(ig,l)).lt.1e-10) then print*,'pb linter' endif linter(ig)=(l*(zw2(ig,l+1)-zw2(ig,l)) s -zw2(ig,l))/(zw2(ig,l+1)-zw2(ig,l)) zw2(ig,l+1)=0. lmaxa(ig)=l else if (zw2(ig,l+1).lt.0.) then print*,'pb1 zw2<0' endif wa_moy(ig,l+1)=sqrt(zw2(ig,l+1)) endif if (wa_moy(ig,l+1).gt.wmaxa(ig)) then c lmix est le niveau de la couche ou w (wa_moy) est maximum lmix(ig)=l+1 wmaxa(ig)=wa_moy(ig,l+1) endif enddo enddo print*,'fin calcul zw2' c c Calcul de la couche correspondant a la hauteur du thermique do ig=1,ngrid lmax(ig)=lentr(ig) enddo do ig=1,ngrid do l=nlay,lentr(ig)+1,-1 if (zw2(ig,l).le.1.e-10) then lmax(ig)=l-1 endif enddo enddo c pas de thermique si couches 1->5 stables do ig=1,ngrid if (lmin(ig).gt.5) then lmax(ig)=1 lmin(ig)=1 endif enddo c c Determination de zw2 max do ig=1,ngrid wmax(ig)=0. enddo do l=1,nlay do ig=1,ngrid if (l.le.lmax(ig)) then if (zw2(ig,l).lt.0.)then print*,'pb2 zw2<0' endif zw2(ig,l)=sqrt(zw2(ig,l)) wmax(ig)=max(wmax(ig),zw2(ig,l)) else zw2(ig,l)=0. endif enddo enddo c Longueur caracteristique correspondant a la hauteur des thermiques. do ig=1,ngrid zmax(ig)=0. zlevinter(ig)=zlev(ig,1) enddo do ig=1,ngrid c calcul de zlevinter zlevinter(ig)=(zlev(ig,lmax(ig)+1)-zlev(ig,lmax(ig)))* s linter(ig)+zlev(ig,lmax(ig))-lmax(ig)*(zlev(ig,lmax(ig)+1) s -zlev(ig,lmax(ig))) zmax(ig)=max(zmax(ig),zlevinter(ig)-zlev(ig,lmin(ig))) enddo print*,'avant fermeture' c Fermeture,determination de f do ig=1,ngrid entr_star2(ig)=0. enddo do ig=1,ngrid if (entr_star_tot(ig).LT.1.e-10) then f(ig)=0. else do k=lmin(ig),lentr(ig) entr_star2(ig)=entr_star2(ig)+entr_star(ig,k)**2 s /(rho(ig,k)*(zlev(ig,k+1)-zlev(ig,k))) enddo c Nouvelle fermeture f(ig)=wmax(ig)/(max(500.,zmax(ig))*r_aspect s *entr_star2(ig))*entr_star_tot(ig) ctest c if (first) then c f(ig)=f(ig)+(f0(ig)-f(ig))*exp(-ptimestep/zmax(ig) c s *wmax(ig)) c endif endif c f0(ig)=f(ig) c first=.true. enddo print*,'apres fermeture' c Calcul de l'entrainement do k=1,klev do ig=1,ngrid entr(ig,k)=f(ig)*entr_star(ig,k) enddo enddo c Calcul des flux do ig=1,ngrid do l=1,lmax(ig)-1 fmc(ig,l+1)=fmc(ig,l)+entr(ig,l) enddo enddo cRC c print*,'9 OK convect8' c print*,'WA1 ',wa_moy c determination de l'indice du debut de la mixed layer ou w decroit c calcul de la largeur de chaque ascendance dans le cas conservatif. c dans ce cas simple, on suppose que la largeur de l'ascendance provenant c d'une couche est égale à la hauteur de la couche alimentante. c La vitesse maximale dans l'ascendance est aussi prise comme estimation c de la vitesse d'entrainement horizontal dans la couche alimentante. do l=2,nlay do ig=1,ngrid if (l.le.lmaxa(ig)) then zw=max(wa_moy(ig,l),1.e-10) larg_cons(ig,l)=zmax(ig)*r_aspect s *fmc(ig,l)/(rhobarz(ig,l)*zw) endif enddo enddo do l=2,nlay do ig=1,ngrid if (l.le.lmaxa(ig)) then c if (idetr.eq.0) then c cette option est finalement en dur. if ((l_mix*zlev(ig,l)).lt.0.)then print*,'pb l_mix*zlev<0' endif larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c else if (idetr.eq.1) then c larg_detr(ig,l)=larg_cons(ig,l) c s *sqrt(l_mix*zlev(ig,l))/larg_cons(ig,lmix(ig)) c else if (idetr.eq.2) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *sqrt(wa_moy(ig,l)) c else if (idetr.eq.4) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *wa_moy(ig,l) c endif endif enddo enddo c print*,'10 OK convect8' c print*,'WA2 ',wa_moy c calcul de la fraction de la maille concernée par l'ascendance en tenant c compte de l'epluchage du thermique. c cCR def de zmix continu (profil parabolique des vitesses) do ig=1,ngrid if (lmix(ig).gt.1.) then c test if (((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))-(zlev(ig,lmix(ig)+1))) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))-(zlev(ig,lmix(ig))))).gt.1e-10) s then c zmix(ig)=((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))**2-(zlev(ig,lmix(ig)+1))**2) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))**2-(zlev(ig,lmix(ig)))**2)) s /(2.*((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))-(zlev(ig,lmix(ig)+1))) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))-(zlev(ig,lmix(ig)))))) else zmix(ig)=zlev(ig,lmix(ig)) print*,'pb zmix' endif else zmix(ig)=0. endif ctest if ((zmax(ig)-zmix(ig)).lt.0.) then zmix(ig)=0.99*zmax(ig) c print*,'pb zmix>zmax' endif enddo c c calcul du nouveau lmix correspondant do ig=1,ngrid do l=1,klev if (zmix(ig).ge.zlev(ig,l).and. s zmix(ig).lt.zlev(ig,l+1)) then lmix(ig)=l endif enddo enddo c do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1.) then c print*,ig,l,lmix(ig),lmaxa(ig),larg_cons(ig,l),' KKK' fraca(ig,l)=(larg_cons(ig,l)-larg_detr(ig,l)) s /(r_aspect*zmax(ig)) c test fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) else c wa_moy(ig,l)=0. fraca(ig,l)=0. fracc(ig,l)=0. fracd(ig,l)=1. endif enddo enddo cCR: calcul de fracazmix do ig=1,ngrid fracazmix(ig)=(fraca(ig,lmix(ig)+1)-fraca(ig,lmix(ig)))/ s (zlev(ig,lmix(ig)+1)-zlev(ig,lmix(ig)))*zmix(ig) s +fraca(ig,lmix(ig))-zlev(ig,lmix(ig))*(fraca(ig,lmix(ig)+1) s -fraca(ig,lmix(ig)))/(zlev(ig,lmix(ig)+1)-zlev(ig,lmix(ig))) enddo c do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1.) then if (l.gt.lmix(ig)) then ctest if (zmax(ig)-zmix(ig).lt.1.e-10) then c print*,'pb xxx' xxx(ig,l)=(lmaxa(ig)+1.-l)/(lmaxa(ig)+1.-lmix(ig)) else xxx(ig,l)=(zmax(ig)-zlev(ig,l))/(zmax(ig)-zmix(ig)) endif if (idetr.eq.0) then fraca(ig,l)=fracazmix(ig) else if (idetr.eq.1) then fraca(ig,l)=fracazmix(ig)*xxx(ig,l) else if (idetr.eq.2) then fraca(ig,l)=fracazmix(ig)*(1.-(1.-xxx(ig,l))**2) else fraca(ig,l)=fracazmix(ig)*xxx(ig,l)**2 endif c print*,ig,l,lmix(ig),lmaxa(ig),xxx(ig,l),'LLLLLLL' fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) endif endif enddo enddo print*,'fin calcul fraca' c print*,'11 OK convect8' c print*,'Ea3 ',wa_moy c------------------------------------------------------------------ c Calcul de fracd, wd c somme wa - wd = 0 c------------------------------------------------------------------ do ig=1,ngrid fm(ig,1)=0. fm(ig,nlay+1)=0. enddo do l=2,nlay do ig=1,ngrid fm(ig,l)=fraca(ig,l)*wa_moy(ig,l)*rhobarz(ig,l) cCR:test if (entr(ig,l-1).lt.1e-10.and.fm(ig,l).gt.fm(ig,l-1) s .and.l.gt.lmix(ig)) then fm(ig,l)=fm(ig,l-1) c write(1,*)'ajustement fm, l',l endif c write(1,*)'ig,l,fm(ig,l)',ig,l,fm(ig,l) cRC enddo do ig=1,ngrid if(fracd(ig,l).lt.0.1) then stop'fracd trop petit' else c vitesse descendante "diagnostique" wd(ig,l)=fm(ig,l)/(fracd(ig,l)*rhobarz(ig,l)) endif enddo enddo do l=1,nlay do ig=1,ngrid c masse(ig,l)=rho(ig,l)*(zlev(ig,l+1)-zlev(ig,l)) masse(ig,l)=(pplev(ig,l)-pplev(ig,l+1))/RG enddo enddo print*,'12 OK convect8' c print*,'WA4 ',wa_moy cc------------------------------------------------------------------ c calcul du transport vertical c------------------------------------------------------------------ go to 4444 c print*,'XXXXXXXXXXXXXXX ptimestep= ',ptimestep do l=2,nlay-1 do ig=1,ngrid if(fm(ig,l+1)*ptimestep.gt.masse(ig,l) s .and.fm(ig,l+1)*ptimestep.gt.masse(ig,l+1)) then c print*,'WARN!!! FM>M ig=',ig,' l=',l,' FM=' c s ,fm(ig,l+1)*ptimestep c s ,' M=',masse(ig,l),masse(ig,l+1) endif enddo enddo do l=1,nlay do ig=1,ngrid if(entr(ig,l)*ptimestep.gt.masse(ig,l)) then c print*,'WARN!!! E>M ig=',ig,' l=',l,' E==' c s ,entr(ig,l)*ptimestep c s ,' M=',masse(ig,l) endif enddo enddo do l=1,nlay do ig=1,ngrid if(.not.fm(ig,l).ge.0..or..not.fm(ig,l).le.10.) then c print*,'WARN!!! fm exagere ig=',ig,' l=',l c s ,' FM=',fm(ig,l) endif if(.not.masse(ig,l).ge.1.e-10 s .or..not.masse(ig,l).le.1.e4) then c print*,'WARN!!! masse exagere ig=',ig,' l=',l c s ,' M=',masse(ig,l) c print*,'rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l)', c s rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l) c print*,'zlev(ig,l+1),zlev(ig,l)' c s ,zlev(ig,l+1),zlev(ig,l) c print*,'pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1)' c s ,pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1) endif if(.not.entr(ig,l).ge.0..or..not.entr(ig,l).le.10.) then c print*,'WARN!!! entr exagere ig=',ig,' l=',l c s ,' E=',entr(ig,l) endif enddo enddo 4444 continue cCR:redefinition du entr do l=1,nlay do ig=1,ngrid detr(ig,l)=fm(ig,l)+entr(ig,l)-fm(ig,l+1) if (detr(ig,l).lt.0.) then entr(ig,l)=entr(ig,l)-detr(ig,l) detr(ig,l)=0. c print*,'WARNING !!! detrainement negatif ',ig,l endif enddo enddo cRC if (w2di.eq.1) then fm0=fm0+ptimestep*(fm-fm0)/float(tho) entr0=entr0+ptimestep*(entr-entr0)/float(tho) else fm0=fm entr0=entr endif if (1.eq.1) then call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zh,zdhadj,zha) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zo,pdoadj,zoa) else call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zh,zdhadj,zha) call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zo,pdoadj,zoa) endif if (1.eq.0) then call dvthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse . ,fraca,zmax . ,zu,zv,pduadj,pdvadj,zua,zva) else call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zu,pduadj,zua) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zv,pdvadj,zva) endif do l=1,nlay do ig=1,ngrid zf=0.5*(fracc(ig,l)+fracc(ig,l+1)) zf2=zf/(1.-zf) thetath2(ig,l)=zf2*(zha(ig,l)-zh(ig,l))**2 wth2(ig,l)=zf2*(0.5*(wa_moy(ig,l)+wa_moy(ig,l+1)))**2 enddo enddo c print*,'13 OK convect8' c print*,'WA5 ',wa_moy do l=1,nlay do ig=1,ngrid pdtadj(ig,l)=zdhadj(ig,l)*zpspsk(ig,l) enddo enddo c do l=1,nlay c do ig=1,ngrid c if(abs(pdtadj(ig,l))*86400..gt.500.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdtadj=',pdtadj(ig,l) c endif c if(abs(pdoadj(ig,l))*86400..gt.1.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdoadj=',pdoadj(ig,l) c endif c enddo c enddo print*,'14 OK convect8' c------------------------------------------------------------------ c Calculs pour les sorties c------------------------------------------------------------------ if(sorties) then do l=1,nlay do ig=1,ngrid zla(ig,l)=(1.-fracd(ig,l))*zmax(ig) zld(ig,l)=fracd(ig,l)*zmax(ig) if(1.-fracd(ig,l).gt.1.e-10) s zwa(ig,l)=wd(ig,l)*fracd(ig,l)/(1.-fracd(ig,l)) enddo enddo cdeja fait c do l=1,nlay c do ig=1,ngrid c detr(ig,l)=fm(ig,l)+entr(ig,l)-fm(ig,l+1) c if (detr(ig,l).lt.0.) then c entr(ig,l)=entr(ig,l)-detr(ig,l) c detr(ig,l)=0. c print*,'WARNING !!! detrainement negatif ',ig,l c endif c enddo c enddo c print*,'15 OK convect8' isplit=isplit+1 c #define und goto 123 #ifdef und CALL writeg1d(1,nlay,wd,'wd ','wd ') CALL writeg1d(1,nlay,zwa,'wa ','wa ') CALL writeg1d(1,nlay,fracd,'fracd ','fracd ') CALL writeg1d(1,nlay,fraca,'fraca ','fraca ') CALL writeg1d(1,nlay,wa_moy,'wam ','wam ') CALL writeg1d(1,nlay,zla,'la ','la ') CALL writeg1d(1,nlay,zld,'ld ','ld ') CALL writeg1d(1,nlay,pt,'pt ','pt ') CALL writeg1d(1,nlay,zh,'zh ','zh ') CALL writeg1d(1,nlay,zha,'zha ','zha ') CALL writeg1d(1,nlay,zu,'zu ','zu ') CALL writeg1d(1,nlay,zv,'zv ','zv ') CALL writeg1d(1,nlay,zo,'zo ','zo ') CALL writeg1d(1,nlay,wh,'wh ','wh ') CALL writeg1d(1,nlay,wu,'wu ','wu ') CALL writeg1d(1,nlay,wv,'wv ','wv ') CALL writeg1d(1,nlay,wo,'w15uo ','wXo ') CALL writeg1d(1,nlay,zdhadj,'zdhadj ','zdhadj ') CALL writeg1d(1,nlay,pduadj,'pduadj ','pduadj ') CALL writeg1d(1,nlay,pdvadj,'pdvadj ','pdvadj ') CALL writeg1d(1,nlay,pdoadj,'pdoadj ','pdoadj ') CALL writeg1d(1,nlay,entr ,'entr ','entr ') CALL writeg1d(1,nlay,detr ,'detr ','detr ') CALL writeg1d(1,nlay,fm ,'fm ','fm ') CALL writeg1d(1,nlay,pdtadj,'pdtadj ','pdtadj ') CALL writeg1d(1,nlay,pplay,'pplay ','pplay ') CALL writeg1d(1,nlay,pplev,'pplev ','pplev ') c recalcul des flux en diagnostique... c print*,'PAS DE TEMPS ',ptimestep call dt2F(pplev,pplay,pt,pdtadj,wh) CALL writeg1d(1,nlay,wh,'wh2 ','wh2 ') #endif 123 continue #define troisD #ifdef troisD c if (sorties) then print*,'Debut des wrgradsfi' c print*,'16 OK convect8' call wrgradsfi(1,nlay,wd,'wd ','wd ') call wrgradsfi(1,nlay,zwa,'wa ','wa ') call wrgradsfi(1,nlay,fracd,'fracd ','fracd ') call wrgradsfi(1,nlay,fraca,'fraca ','fraca ') call wrgradsfi(1,nlay,xxx,'xxx ','xxx ') call wrgradsfi(1,nlay,wa_moy,'wam ','wam ') c print*,'WA6 ',wa_moy call wrgradsfi(1,nlay,zla,'la ','la ') call wrgradsfi(1,nlay,zld,'ld ','ld ') call wrgradsfi(1,nlay,pt,'pt ','pt ') call wrgradsfi(1,nlay,zh,'zh ','zh ') call wrgradsfi(1,nlay,zha,'zha ','zha ') call wrgradsfi(1,nlay,zua,'zua ','zua ') call wrgradsfi(1,nlay,zva,'zva ','zva ') call wrgradsfi(1,nlay,zu,'zu ','zu ') call wrgradsfi(1,nlay,zv,'zv ','zv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,wh,'wh ','wh ') call wrgradsfi(1,nlay,wu,'wu ','wu ') call wrgradsfi(1,nlay,wv,'wv ','wv ') call wrgradsfi(1,nlay,wo,'wo ','wo ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,nlay,zdhadj,'zdhadj ','zdhadj ') call wrgradsfi(1,nlay,pduadj,'pduadj ','pduadj ') call wrgradsfi(1,nlay,pdvadj,'pdvadj ','pdvadj ') call wrgradsfi(1,nlay,pdoadj,'pdoadj ','pdoadj ') call wrgradsfi(1,nlay,entr,'entr ','entr ') call wrgradsfi(1,nlay,detr,'detr ','detr ') call wrgradsfi(1,nlay,fm,'fm ','fm ') call wrgradsfi(1,nlay,fmc,'fmc ','fmc ') call wrgradsfi(1,nlay,zw2,'zw2 ','zw2 ') call wrgradsfi(1,nlay,ztva,'ztva ','ztva ') call wrgradsfi(1,nlay,ztv,'ztv ','ztv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,larg_cons,'Lc ','Lc ') call wrgradsfi(1,nlay,larg_detr,'Ldetr ','Ldetr ') cCR:nouveaux diagnostiques call wrgradsfi(1,nlay,entr_star ,'entr_star ','entr_star ') call wrgradsfi(1,nlay,f_star ,'f_star ','f_star ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,1,zmix,'zmix ','zmix ') zsortie1d(:)=lmax(:) call wrgradsfi(1,1,zsortie1d,'lmax ','lmax ') call wrgradsfi(1,1,wmax,'wmax ','wmax ') zsortie1d(:)=lmix(:) call wrgradsfi(1,1,zsortie1d,'lmix ','lmix ') zsortie1d(:)=lentr(:) call wrgradsfi(1,1,zsortie1d,'lentr ','lentr ') c print*,'17 OK convect8' do k=1,klev/10 write(str2,'(i2.2)') k str10='wa'//str2 do l=1,nlay do ig=1,ngrid zsortie(ig,l)=wa(ig,k,l) enddo enddo CALL wrgradsfi(1,nlay,zsortie,str10,str10) do l=1,nlay do ig=1,ngrid zsortie(ig,l)=larg_part(ig,k,l) enddo enddo str10='la'//str2 CALL wrgradsfi(1,nlay,zsortie,str10,str10) enddo c print*,'18 OK convect8' c endif print*,'Fin des wrgradsfi' #endif endif c if(wa_moy(1,4).gt.1.e-10) stop print*,'19 OK convect8' return end subroutine dqthermcell(ngrid,nlay,ptimestep,fm,entr, . masse,q,dq,qa) implicit none c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c calcul du dq/dt une fois qu'on connait les ascendances c c======================================================================= #include "dimensions.h" #include "dimphy.h" integer ngrid,nlay real ptimestep real masse(ngrid,nlay),fm(ngrid,nlay+1) real entr(ngrid,nlay) real q(ngrid,nlay) real dq(ngrid,nlay) real qa(klon,klev),detr(klon,klev),wqd(klon,klev+1) integer ig,k c calcul du detrainement do k=1,nlay do ig=1,ngrid detr(ig,k)=fm(ig,k)-fm(ig,k+1)+entr(ig,k) ctest if (detr(ig,k).lt.0.) then entr(ig,k)=entr(ig,k)-detr(ig,k) detr(ig,k)=0. c print*,'detr2<0!!!','ig=',ig,'k=',k,'f=',fm(ig,k), c s 'f+1=',fm(ig,k+1),'e=',entr(ig,k),'d=',detr(ig,k) endif if (fm(ig,k+1).lt.0.) then c print*,'fm2<0!!!' endif if (entr(ig,k).lt.0.) then c print*,'entr2<0!!!' endif enddo enddo c calcul de la valeur dans les ascendances do ig=1,ngrid qa(ig,1)=q(ig,1) enddo do k=2,nlay do ig=1,ngrid if ((fm(ig,k+1)+detr(ig,k))*ptimestep.gt. s 1.e-5*masse(ig,k)) then qa(ig,k)=(fm(ig,k)*qa(ig,k-1)+entr(ig,k)*q(ig,k)) s /(fm(ig,k+1)+detr(ig,k)) else qa(ig,k)=q(ig,k) endif if (qa(ig,k).lt.0.) then c print*,'qa<0!!!' endif if (q(ig,k).lt.0.) then c print*,'q<0!!!' endif enddo enddo do k=2,nlay do ig=1,ngrid c wqd(ig,k)=fm(ig,k)*0.5*(q(ig,k-1)+q(ig,k)) wqd(ig,k)=fm(ig,k)*q(ig,k) if (wqd(ig,k).lt.0.) then c print*,'wqd<0!!!' endif enddo enddo do ig=1,ngrid wqd(ig,1)=0. wqd(ig,nlay+1)=0. enddo do k=1,nlay do ig=1,ngrid dq(ig,k)=(detr(ig,k)*qa(ig,k)-entr(ig,k)*q(ig,k) s -wqd(ig,k)+wqd(ig,k+1)) s /masse(ig,k) c if (dq(ig,k).lt.0.) then c print*,'dq<0!!!' c endif enddo enddo return end subroutine dvthermcell(ngrid,nlay,ptimestep,fm,entr,masse . ,fraca,larga . ,u,v,du,dv,ua,va) implicit none c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c calcul du dq/dt une fois qu'on connait les ascendances c c======================================================================= #include "dimensions.h" #include "dimphy.h" integer ngrid,nlay real ptimestep real masse(ngrid,nlay),fm(ngrid,nlay+1) real fraca(ngrid,nlay+1) real larga(ngrid) real entr(ngrid,nlay) real u(ngrid,nlay) real ua(ngrid,nlay) real du(ngrid,nlay) real v(ngrid,nlay) real va(ngrid,nlay) real dv(ngrid,nlay) real qa(klon,klev),detr(klon,klev) real wvd(klon,klev+1),wud(klon,klev+1) real gamma0,gamma(klon,klev+1) real dua,dva integer iter integer ig,k c calcul du detrainement do k=1,nlay do ig=1,ngrid detr(ig,k)=fm(ig,k)-fm(ig,k+1)+entr(ig,k) enddo enddo c calcul de la valeur dans les ascendances do ig=1,ngrid ua(ig,1)=u(ig,1) va(ig,1)=v(ig,1) enddo do k=2,nlay do ig=1,ngrid if ((fm(ig,k+1)+detr(ig,k))*ptimestep.gt. s 1.e-5*masse(ig,k)) then c On itère sur la valeur du coeff de freinage. c gamma0=rho(ig,k)*(zlev(ig,k+1)-zlev(ig,k)) gamma0=masse(ig,k) s *sqrt( 0.5*(fraca(ig,k+1)+fraca(ig,k)) ) s *0.5/larga(ig) c gamma0=0. c la première fois on multiplie le coefficient de freinage c par le module du vent dans la couche en dessous. dua=ua(ig,k-1)-u(ig,k-1) dva=va(ig,k-1)-v(ig,k-1) do iter=1,5 gamma(ig,k)=gamma0*sqrt(dua**2+dva**2) ua(ig,k)=(fm(ig,k)*ua(ig,k-1) s +(entr(ig,k)+gamma(ig,k))*u(ig,k)) s /(fm(ig,k+1)+detr(ig,k)+gamma(ig,k)) va(ig,k)=(fm(ig,k)*va(ig,k-1) s +(entr(ig,k)+gamma(ig,k))*v(ig,k)) s /(fm(ig,k+1)+detr(ig,k)+gamma(ig,k)) c print*,k,ua(ig,k),va(ig,k),u(ig,k),v(ig,k),dua,dva dua=ua(ig,k)-u(ig,k) dva=va(ig,k)-v(ig,k) enddo else ua(ig,k)=u(ig,k) va(ig,k)=v(ig,k) gamma(ig,k)=0. endif enddo enddo do k=2,nlay do ig=1,ngrid wud(ig,k)=fm(ig,k)*u(ig,k) wvd(ig,k)=fm(ig,k)*v(ig,k) enddo enddo do ig=1,ngrid wud(ig,1)=0. wud(ig,nlay+1)=0. wvd(ig,1)=0. wvd(ig,nlay+1)=0. enddo do k=1,nlay do ig=1,ngrid du(ig,k)=((detr(ig,k)+gamma(ig,k))*ua(ig,k) s -(entr(ig,k)+gamma(ig,k))*u(ig,k) s -wud(ig,k)+wud(ig,k+1)) s /masse(ig,k) dv(ig,k)=((detr(ig,k)+gamma(ig,k))*va(ig,k) s -(entr(ig,k)+gamma(ig,k))*v(ig,k) s -wvd(ig,k)+wvd(ig,k+1)) s /masse(ig,k) enddo enddo return end subroutine dqthermcell2(ngrid,nlay,ptimestep,fm,entr,masse,frac . ,q,dq,qa) implicit none c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c calcul du dq/dt une fois qu'on connait les ascendances c c======================================================================= #include "dimensions.h" #include "dimphy.h" integer ngrid,nlay real ptimestep real masse(ngrid,nlay),fm(ngrid,nlay+1) real entr(ngrid,nlay),frac(ngrid,nlay) real q(ngrid,nlay) real dq(ngrid,nlay) real qa(klon,klev),detr(klon,klev),wqd(klon,klev+1) real qe(klon,klev),zf,zf2 integer ig,k c calcul du detrainement do k=1,nlay do ig=1,ngrid detr(ig,k)=fm(ig,k)-fm(ig,k+1)+entr(ig,k) enddo enddo c calcul de la valeur dans les ascendances do ig=1,ngrid qa(ig,1)=q(ig,1) qe(ig,1)=q(ig,1) enddo do k=2,nlay do ig=1,ngrid if ((fm(ig,k+1)+detr(ig,k))*ptimestep.gt. s 1.e-5*masse(ig,k)) then zf=0.5*(frac(ig,k)+frac(ig,k+1)) zf2=1./(1.-zf) qa(ig,k)=(fm(ig,k)*qa(ig,k-1)+zf2*entr(ig,k)*q(ig,k)) s /(fm(ig,k+1)+detr(ig,k)+entr(ig,k)*zf*zf2) qe(ig,k)=(q(ig,k)-zf*qa(ig,k))*zf2 else qa(ig,k)=q(ig,k) qe(ig,k)=q(ig,k) endif enddo enddo do k=2,nlay do ig=1,ngrid c wqd(ig,k)=fm(ig,k)*0.5*(q(ig,k-1)+q(ig,k)) wqd(ig,k)=fm(ig,k)*qe(ig,k) enddo enddo do ig=1,ngrid wqd(ig,1)=0. wqd(ig,nlay+1)=0. enddo do k=1,nlay do ig=1,ngrid dq(ig,k)=(detr(ig,k)*qa(ig,k)-entr(ig,k)*qe(ig,k) s -wqd(ig,k)+wqd(ig,k+1)) s /masse(ig,k) enddo enddo return end subroutine dvthermcell2(ngrid,nlay,ptimestep,fm,entr,masse . ,fraca,larga . ,u,v,du,dv,ua,va) implicit none c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c calcul du dq/dt une fois qu'on connait les ascendances c c======================================================================= #include "dimensions.h" #include "dimphy.h" integer ngrid,nlay real ptimestep real masse(ngrid,nlay),fm(ngrid,nlay+1) real fraca(ngrid,nlay+1) real larga(ngrid) real entr(ngrid,nlay) real u(ngrid,nlay) real ua(ngrid,nlay) real du(ngrid,nlay) real v(ngrid,nlay) real va(ngrid,nlay) real dv(ngrid,nlay) real qa(klon,klev),detr(klon,klev),zf,zf2 real wvd(klon,klev+1),wud(klon,klev+1) real gamma0,gamma(klon,klev+1) real ue(klon,klev),ve(klon,klev) real dua,dva integer iter integer ig,k c calcul du detrainement do k=1,nlay do ig=1,ngrid detr(ig,k)=fm(ig,k)-fm(ig,k+1)+entr(ig,k) enddo enddo c calcul de la valeur dans les ascendances do ig=1,ngrid ua(ig,1)=u(ig,1) va(ig,1)=v(ig,1) ue(ig,1)=u(ig,1) ve(ig,1)=v(ig,1) enddo do k=2,nlay do ig=1,ngrid if ((fm(ig,k+1)+detr(ig,k))*ptimestep.gt. s 1.e-5*masse(ig,k)) then c On itère sur la valeur du coeff de freinage. c gamma0=rho(ig,k)*(zlev(ig,k+1)-zlev(ig,k)) gamma0=masse(ig,k) s *sqrt( 0.5*(fraca(ig,k+1)+fraca(ig,k)) ) s *0.5/larga(ig) s *1. c s *0.5 c gamma0=0. zf=0.5*(fraca(ig,k)+fraca(ig,k+1)) zf=0. zf2=1./(1.-zf) c la première fois on multiplie le coefficient de freinage c par le module du vent dans la couche en dessous. dua=ua(ig,k-1)-u(ig,k-1) dva=va(ig,k-1)-v(ig,k-1) do iter=1,5 c On choisit une relaxation lineaire. gamma(ig,k)=gamma0 c On choisit une relaxation quadratique. gamma(ig,k)=gamma0*sqrt(dua**2+dva**2) ua(ig,k)=(fm(ig,k)*ua(ig,k-1) s +(zf2*entr(ig,k)+gamma(ig,k))*u(ig,k)) s /(fm(ig,k+1)+detr(ig,k)+entr(ig,k)*zf*zf2 s +gamma(ig,k)) va(ig,k)=(fm(ig,k)*va(ig,k-1) s +(zf2*entr(ig,k)+gamma(ig,k))*v(ig,k)) s /(fm(ig,k+1)+detr(ig,k)+entr(ig,k)*zf*zf2 s +gamma(ig,k)) c print*,k,ua(ig,k),va(ig,k),u(ig,k),v(ig,k),dua,dva dua=ua(ig,k)-u(ig,k) dva=va(ig,k)-v(ig,k) ue(ig,k)=(u(ig,k)-zf*ua(ig,k))*zf2 ve(ig,k)=(v(ig,k)-zf*va(ig,k))*zf2 enddo else ua(ig,k)=u(ig,k) va(ig,k)=v(ig,k) ue(ig,k)=u(ig,k) ve(ig,k)=v(ig,k) gamma(ig,k)=0. endif enddo enddo do k=2,nlay do ig=1,ngrid wud(ig,k)=fm(ig,k)*ue(ig,k) wvd(ig,k)=fm(ig,k)*ve(ig,k) enddo enddo do ig=1,ngrid wud(ig,1)=0. wud(ig,nlay+1)=0. wvd(ig,1)=0. wvd(ig,nlay+1)=0. enddo do k=1,nlay do ig=1,ngrid du(ig,k)=((detr(ig,k)+gamma(ig,k))*ua(ig,k) s -(entr(ig,k)+gamma(ig,k))*ue(ig,k) s -wud(ig,k)+wud(ig,k+1)) s /masse(ig,k) dv(ig,k)=((detr(ig,k)+gamma(ig,k))*va(ig,k) s -(entr(ig,k)+gamma(ig,k))*ve(ig,k) s -wvd(ig,k)+wvd(ig,k+1)) s /masse(ig,k) enddo enddo return end SUBROUTINE thermcell_sec(ngrid,nlay,ptimestep s ,pplay,pplev,pphi,zlev s ,pu,pv,pt,po s ,pduadj,pdvadj,pdtadj,pdoadj s ,fm0,entr0 c s ,pu_therm,pv_therm s ,r_aspect,l_mix,w2di,tho) IMPLICIT NONE c======================================================================= c c Calcul du transport verticale dans la couche limite en presence c de "thermiques" explicitement representes c c Réécriture à partir d'un listing papier à Habas, le 14/02/00 c c le thermique est supposé homogène et dissipé par mélange avec c son environnement. la longueur l_mix contrôle l'efficacité du c mélange c c Le calcul du transport des différentes espèces se fait en prenant c en compte: c 1. un flux de masse montant c 2. un flux de masse descendant c 3. un entrainement c 4. un detrainement c c======================================================================= c----------------------------------------------------------------------- c declarations: c ------------- #include "dimensions.h" #include "dimphy.h" #include "YOMCST.h" c arguments: c ---------- INTEGER ngrid,nlay,w2di,tho real ptimestep,l_mix,r_aspect REAL pt(ngrid,nlay),pdtadj(ngrid,nlay) REAL pu(ngrid,nlay),pduadj(ngrid,nlay) REAL pv(ngrid,nlay),pdvadj(ngrid,nlay) REAL po(ngrid,nlay),pdoadj(ngrid,nlay) REAL pplay(ngrid,nlay),pplev(ngrid,nlay+1) real pphi(ngrid,nlay) integer idetr save idetr data idetr/3/ c local: c ------ INTEGER ig,k,l,lmaxa(klon),lmix(klon) real zsortie1d(klon) c CR: on remplace lmax(klon,klev+1) INTEGER lmax(klon),lmin(klon),lentr(klon) real linter(klon) real zmix(klon), fracazmix(klon) c RC real zmax(klon),zw,zz,zw2(klon,klev+1),ztva(klon,klev),zzz real zlev(klon,klev+1),zlay(klon,klev) REAL zh(klon,klev),zdhadj(klon,klev) REAL ztv(klon,klev) real zu(klon,klev),zv(klon,klev),zo(klon,klev) REAL wh(klon,klev+1) real wu(klon,klev+1),wv(klon,klev+1),wo(klon,klev+1) real zla(klon,klev+1) real zwa(klon,klev+1) real zld(klon,klev+1) real zwd(klon,klev+1) real zsortie(klon,klev) real zva(klon,klev) real zua(klon,klev) real zoa(klon,klev) real zha(klon,klev) real wa_moy(klon,klev+1) real fraca(klon,klev+1) real fracc(klon,klev+1) real zf,zf2 real thetath2(klon,klev),wth2(klon,klev) common/comtherm/thetath2,wth2 real count_time integer isplit,nsplit,ialt parameter (nsplit=10) data isplit/0/ save isplit logical sorties real rho(klon,klev),rhobarz(klon,klev+1),masse(klon,klev) real zpspsk(klon,klev) c real wmax(klon,klev),wmaxa(klon) real wmax(klon),wmaxa(klon) real wa(klon,klev,klev+1) real wd(klon,klev+1) real larg_part(klon,klev,klev+1) real fracd(klon,klev+1) real xxx(klon,klev+1) real larg_cons(klon,klev+1) real larg_detr(klon,klev+1) real fm0(klon,klev+1),entr0(klon,klev),detr(klon,klev) real pu_therm(klon,klev),pv_therm(klon,klev) real fm(klon,klev+1),entr(klon,klev) real fmc(klon,klev+1) cCR:nouvelles variables real f_star(klon,klev+1),entr_star(klon,klev) real entr_star_tot(klon),entr_star2(klon) real f(klon), f0(klon) real zlevinter(klon) logical first data first /.false./ save first cRC character*2 str2 character*10 str10 LOGICAL vtest(klon),down EXTERNAL SCOPY integer ncorrec,ll save ncorrec data ncorrec/0/ c c----------------------------------------------------------------------- c initialisation: c --------------- c sorties=.true. IF(ngrid.NE.klon) THEN PRINT* PRINT*,'STOP dans convadj' PRINT*,'ngrid =',ngrid PRINT*,'klon =',klon ENDIF c c----------------------------------------------------------------------- c incrementation eventuelle de tendances precedentes: c --------------------------------------------------- c print*,'0 OK convect8' DO 1010 l=1,nlay DO 1015 ig=1,ngrid zpspsk(ig,l)=(pplay(ig,l)/pplev(ig,1))**RKAPPA zh(ig,l)=pt(ig,l)/zpspsk(ig,l) zu(ig,l)=pu(ig,l) zv(ig,l)=pv(ig,l) zo(ig,l)=po(ig,l) ztv(ig,l)=zh(ig,l)*(1.+0.61*zo(ig,l)) 1015 CONTINUE 1010 CONTINUE c print*,'1 OK convect8' c -------------------- c c c + + + + + + + + + + + c c c wa, fraca, wd, fracd -------------------- zlev(2), rhobarz c wh,wt,wo ... c c + + + + + + + + + + + zh,zu,zv,zo,rho c c c -------------------- zlev(1) c \\\\\\\\\\\\\\\\\\\\ c c c----------------------------------------------------------------------- c Calcul des altitudes des couches c----------------------------------------------------------------------- do l=2,nlay do ig=1,ngrid zlev(ig,l)=0.5*(pphi(ig,l)+pphi(ig,l-1))/RG enddo enddo do ig=1,ngrid zlev(ig,1)=0. zlev(ig,nlay+1)=(2.*pphi(ig,klev)-pphi(ig,klev-1))/RG enddo do l=1,nlay do ig=1,ngrid zlay(ig,l)=pphi(ig,l)/RG enddo enddo c print*,'2 OK convect8' c----------------------------------------------------------------------- c Calcul des densites c----------------------------------------------------------------------- do l=1,nlay do ig=1,ngrid rho(ig,l)=pplay(ig,l)/(zpspsk(ig,l)*RD*zh(ig,l)) enddo enddo do l=2,nlay do ig=1,ngrid rhobarz(ig,l)=0.5*(rho(ig,l)+rho(ig,l-1)) enddo enddo do k=1,nlay do l=1,nlay+1 do ig=1,ngrid wa(ig,k,l)=0. enddo enddo enddo c print*,'3 OK convect8' c------------------------------------------------------------------ c Calcul de w2, quarre de w a partir de la cape c a partir de w2, on calcule wa, vitesse de l'ascendance c c ATTENTION: Dans cette version, pour cause d'economie de memoire, c w2 est stoke dans wa c c ATTENTION: dans convect8, on n'utilise le calcule des wa c independants par couches que pour calculer l'entrainement c a la base et la hauteur max de l'ascendance. c c Indicages: c l'ascendance provenant du niveau k traverse l'interface l avec c une vitesse wa(k,l). c c -------------------- c c + + + + + + + + + + c c wa(k,l) ---- -------------------- l c /\ c /||\ + + + + + + + + + + c || c || -------------------- c || c || + + + + + + + + + + c || c || -------------------- c ||__ c |___ + + + + + + + + + + k c c -------------------- c c c c------------------------------------------------------------------ cCR: ponderation entrainement des couches instables cdef des entr_star tels que entr=f*entr_star do l=1,klev do ig=1,ngrid entr_star(ig,l)=0. enddo enddo c determination de la longueur de la couche d entrainement do ig=1,ngrid lentr(ig)=1 enddo con ne considere que les premieres couches instables do k=nlay-2,1,-1 do ig=1,ngrid if (ztv(ig,k).gt.ztv(ig,k+1).and. s ztv(ig,k+1).le.ztv(ig,k+2)) then lentr(ig)=k endif enddo enddo c determination du lmin: couche d ou provient le thermique do ig=1,ngrid lmin(ig)=1 enddo do ig=1,ngrid do l=nlay,2,-1 if (ztv(ig,l-1).gt.ztv(ig,l)) then lmin(ig)=l-1 endif enddo enddo c c definition de l'entrainement des couches do l=1,klev-1 do ig=1,ngrid if (ztv(ig,l).gt.ztv(ig,l+1).and. s l.ge.lmin(ig).and.l.le.lentr(ig)) then entr_star(ig,l)=(ztv(ig,l)-ztv(ig,l+1))* c s (zlev(ig,l+1)-zlev(ig,l)) s *sqrt(zlev(ig,l+1)) endif enddo enddo c pas de thermique si couche 1 stable do ig=1,ngrid if (lmin(ig).gt.1) then do l=1,klev entr_star(ig,l)=0. enddo endif enddo c calcul de l entrainement total do ig=1,ngrid entr_star_tot(ig)=0. enddo do ig=1,ngrid do k=1,klev entr_star_tot(ig)=entr_star_tot(ig)+entr_star(ig,k) enddo enddo c c print*,'fin calcul entr_star' do k=1,klev do ig=1,ngrid ztva(ig,k)=ztv(ig,k) enddo enddo cRC c print*,'7 OK convect8' do k=1,klev+1 do ig=1,ngrid zw2(ig,k)=0. fmc(ig,k)=0. cCR f_star(ig,k)=0. cRC larg_cons(ig,k)=0. larg_detr(ig,k)=0. wa_moy(ig,k)=0. enddo enddo c print*,'8 OK convect8' do ig=1,ngrid linter(ig)=1. lmaxa(ig)=1 lmix(ig)=1 wmaxa(ig)=0. enddo cCR: do l=1,nlay-2 do ig=1,ngrid if (ztv(ig,l).gt.ztv(ig,l+1) s .and.entr_star(ig,l).gt.1.e-10 s .and.zw2(ig,l).lt.1e-10) then f_star(ig,l+1)=entr_star(ig,l) ctest:calcul de dteta zw2(ig,l+1)=2.*RG*(ztv(ig,l)-ztv(ig,l+1))/ztv(ig,l+1) s *(zlev(ig,l+1)-zlev(ig,l)) s *0.4*pphi(ig,l)/(pphi(ig,l+1)-pphi(ig,l)) larg_detr(ig,l)=0. else if ((zw2(ig,l).ge.1e-10).and. s (f_star(ig,l)+entr_star(ig,l).gt.1.e-10)) then f_star(ig,l+1)=f_star(ig,l)+entr_star(ig,l) ztva(ig,l)=(f_star(ig,l)*ztva(ig,l-1)+entr_star(ig,l) s *ztv(ig,l))/f_star(ig,l+1) zw2(ig,l+1)=zw2(ig,l)*(f_star(ig,l)/f_star(ig,l+1))**2+ s 2.*RG*(ztva(ig,l)-ztv(ig,l))/ztv(ig,l) s *(zlev(ig,l+1)-zlev(ig,l)) endif c determination de zmax continu par interpolation lineaire if (zw2(ig,l+1).lt.0.) then ctest if (abs(zw2(ig,l+1)-zw2(ig,l)).lt.1e-10) then c print*,'pb linter' endif linter(ig)=(l*(zw2(ig,l+1)-zw2(ig,l)) s -zw2(ig,l))/(zw2(ig,l+1)-zw2(ig,l)) zw2(ig,l+1)=0. lmaxa(ig)=l else if (zw2(ig,l+1).lt.0.) then c print*,'pb1 zw2<0' endif wa_moy(ig,l+1)=sqrt(zw2(ig,l+1)) endif if (wa_moy(ig,l+1).gt.wmaxa(ig)) then c lmix est le niveau de la couche ou w (wa_moy) est maximum lmix(ig)=l+1 wmaxa(ig)=wa_moy(ig,l+1) endif enddo enddo c print*,'fin calcul zw2' c c Calcul de la couche correspondant a la hauteur du thermique do ig=1,ngrid lmax(ig)=lentr(ig) enddo do ig=1,ngrid do l=nlay,lentr(ig)+1,-1 if (zw2(ig,l).le.1.e-10) then lmax(ig)=l-1 endif enddo enddo c pas de thermique si couche 1 stable do ig=1,ngrid if (lmin(ig).gt.1) then lmax(ig)=1 lmin(ig)=1 endif enddo c c Determination de zw2 max do ig=1,ngrid wmax(ig)=0. enddo do l=1,nlay do ig=1,ngrid if (l.le.lmax(ig)) then if (zw2(ig,l).lt.0.)then c print*,'pb2 zw2<0' endif zw2(ig,l)=sqrt(zw2(ig,l)) wmax(ig)=max(wmax(ig),zw2(ig,l)) else zw2(ig,l)=0. endif enddo enddo c Longueur caracteristique correspondant a la hauteur des thermiques. do ig=1,ngrid zmax(ig)=0. zlevinter(ig)=zlev(ig,1) enddo do ig=1,ngrid c calcul de zlevinter zlevinter(ig)=(zlev(ig,lmax(ig)+1)-zlev(ig,lmax(ig)))* s linter(ig)+zlev(ig,lmax(ig))-lmax(ig)*(zlev(ig,lmax(ig)+1) s -zlev(ig,lmax(ig))) zmax(ig)=max(zmax(ig),zlevinter(ig)-zlev(ig,lmin(ig))) enddo c print*,'avant fermeture' c Fermeture,determination de f do ig=1,ngrid entr_star2(ig)=0. enddo do ig=1,ngrid if (entr_star_tot(ig).LT.1.e-10) then f(ig)=0. else do k=lmin(ig),lentr(ig) entr_star2(ig)=entr_star2(ig)+entr_star(ig,k)**2 s /(rho(ig,k)*(zlev(ig,k+1)-zlev(ig,k))) enddo c Nouvelle fermeture f(ig)=wmax(ig)/(max(500.,zmax(ig))*r_aspect s *entr_star2(ig))*entr_star_tot(ig) ctest c if (first) then c f(ig)=f(ig)+(f0(ig)-f(ig))*exp(-ptimestep/zmax(ig) c s *wmax(ig)) c endif endif c f0(ig)=f(ig) c first=.true. enddo c print*,'apres fermeture' c Calcul de l'entrainement do k=1,klev do ig=1,ngrid entr(ig,k)=f(ig)*entr_star(ig,k) enddo enddo cCR:test pour entrainer moins que la masse do ig=1,ngrid do l=1,lentr(ig) if ((entr(ig,l)*ptimestep).gt.(0.9*masse(ig,l))) then entr(ig,l+1)=entr(ig,l+1)+entr(ig,l) s -0.9*masse(ig,l)/ptimestep entr(ig,l)=0.9*masse(ig,l)/ptimestep endif enddo enddo cCR: fin test c Calcul des flux do ig=1,ngrid do l=1,lmax(ig)-1 fmc(ig,l+1)=fmc(ig,l)+entr(ig,l) enddo enddo cRC c print*,'9 OK convect8' c print*,'WA1 ',wa_moy c determination de l'indice du debut de la mixed layer ou w decroit c calcul de la largeur de chaque ascendance dans le cas conservatif. c dans ce cas simple, on suppose que la largeur de l'ascendance provenant c d'une couche est égale à la hauteur de la couche alimentante. c La vitesse maximale dans l'ascendance est aussi prise comme estimation c de la vitesse d'entrainement horizontal dans la couche alimentante. do l=2,nlay do ig=1,ngrid if (l.le.lmaxa(ig)) then zw=max(wa_moy(ig,l),1.e-10) larg_cons(ig,l)=zmax(ig)*r_aspect s *fmc(ig,l)/(rhobarz(ig,l)*zw) endif enddo enddo do l=2,nlay do ig=1,ngrid if (l.le.lmaxa(ig)) then c if (idetr.eq.0) then c cette option est finalement en dur. if ((l_mix*zlev(ig,l)).lt.0.)then c print*,'pb l_mix*zlev<0' endif cCR: test: nouvelle def de lambda c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) if (zw2(ig,l).gt.1.e-10) then larg_detr(ig,l)=sqrt((l_mix/zw2(ig,l))*zlev(ig,l)) else larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) endif cRC c else if (idetr.eq.1) then c larg_detr(ig,l)=larg_cons(ig,l) c s *sqrt(l_mix*zlev(ig,l))/larg_cons(ig,lmix(ig)) c else if (idetr.eq.2) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *sqrt(wa_moy(ig,l)) c else if (idetr.eq.4) then c larg_detr(ig,l)=sqrt(l_mix*zlev(ig,l)) c s *wa_moy(ig,l) c endif endif enddo enddo c print*,'10 OK convect8' c print*,'WA2 ',wa_moy c calcul de la fraction de la maille concernée par l'ascendance en tenant c compte de l'epluchage du thermique. c cCR def de zmix continu (profil parabolique des vitesses) do ig=1,ngrid if (lmix(ig).gt.1.) then c test if (((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))-(zlev(ig,lmix(ig)+1))) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))-(zlev(ig,lmix(ig))))).gt.1e-10) s then c zmix(ig)=((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))**2-(zlev(ig,lmix(ig)+1))**2) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))**2-(zlev(ig,lmix(ig)))**2)) s /(2.*((zw2(ig,lmix(ig)-1)-zw2(ig,lmix(ig))) s *((zlev(ig,lmix(ig)))-(zlev(ig,lmix(ig)+1))) s -(zw2(ig,lmix(ig))-zw2(ig,lmix(ig)+1)) s *((zlev(ig,lmix(ig)-1))-(zlev(ig,lmix(ig)))))) else zmix(ig)=zlev(ig,lmix(ig)) c print*,'pb zmix' endif else zmix(ig)=0. endif ctest if ((zmax(ig)-zmix(ig)).lt.0.) then zmix(ig)=0.99*zmax(ig) c print*,'pb zmix>zmax' endif enddo c c calcul du nouveau lmix correspondant do ig=1,ngrid do l=1,klev if (zmix(ig).ge.zlev(ig,l).and. s zmix(ig).lt.zlev(ig,l+1)) then lmix(ig)=l endif enddo enddo c do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1.) then c print*,ig,l,lmix(ig),lmaxa(ig),larg_cons(ig,l),' KKK' fraca(ig,l)=(larg_cons(ig,l)-larg_detr(ig,l)) s /(r_aspect*zmax(ig)) c test fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) else c wa_moy(ig,l)=0. fraca(ig,l)=0. fracc(ig,l)=0. fracd(ig,l)=1. endif enddo enddo cCR: calcul de fracazmix do ig=1,ngrid fracazmix(ig)=(fraca(ig,lmix(ig)+1)-fraca(ig,lmix(ig)))/ s (zlev(ig,lmix(ig)+1)-zlev(ig,lmix(ig)))*zmix(ig) s +fraca(ig,lmix(ig))-zlev(ig,lmix(ig))*(fraca(ig,lmix(ig)+1) s -fraca(ig,lmix(ig)))/(zlev(ig,lmix(ig)+1)-zlev(ig,lmix(ig))) enddo c do l=2,nlay do ig=1,ngrid if(larg_cons(ig,l).gt.1.) then if (l.gt.lmix(ig)) then ctest if (zmax(ig)-zmix(ig).lt.1.e-10) then c print*,'pb xxx' xxx(ig,l)=(lmaxa(ig)+1.-l)/(lmaxa(ig)+1.-lmix(ig)) else xxx(ig,l)=(zmax(ig)-zlev(ig,l))/(zmax(ig)-zmix(ig)) endif if (idetr.eq.0) then fraca(ig,l)=fracazmix(ig) else if (idetr.eq.1) then fraca(ig,l)=fracazmix(ig)*xxx(ig,l) else if (idetr.eq.2) then fraca(ig,l)=fracazmix(ig)*(1.-(1.-xxx(ig,l))**2) else fraca(ig,l)=fracazmix(ig)*xxx(ig,l)**2 endif c print*,ig,l,lmix(ig),lmaxa(ig),xxx(ig,l),'LLLLLLL' fraca(ig,l)=max(fraca(ig,l),0.) fraca(ig,l)=min(fraca(ig,l),0.5) fracd(ig,l)=1.-fraca(ig,l) fracc(ig,l)=larg_cons(ig,l)/(r_aspect*zmax(ig)) endif endif enddo enddo c print*,'fin calcul fraca' c print*,'11 OK convect8' c print*,'Ea3 ',wa_moy c------------------------------------------------------------------ c Calcul de fracd, wd c somme wa - wd = 0 c------------------------------------------------------------------ do ig=1,ngrid fm(ig,1)=0. fm(ig,nlay+1)=0. enddo do l=2,nlay do ig=1,ngrid fm(ig,l)=fraca(ig,l)*wa_moy(ig,l)*rhobarz(ig,l) cCR:test if (entr(ig,l-1).lt.1e-10.and.fm(ig,l).gt.fm(ig,l-1) s .and.l.gt.lmix(ig)) then fm(ig,l)=fm(ig,l-1) c write(1,*)'ajustement fm, l',l endif c write(1,*)'ig,l,fm(ig,l)',ig,l,fm(ig,l) cRC enddo do ig=1,ngrid if(fracd(ig,l).lt.0.1) then stop'fracd trop petit' else c vitesse descendante "diagnostique" wd(ig,l)=fm(ig,l)/(fracd(ig,l)*rhobarz(ig,l)) endif enddo enddo do l=1,nlay do ig=1,ngrid c masse(ig,l)=rho(ig,l)*(zlev(ig,l+1)-zlev(ig,l)) masse(ig,l)=(pplev(ig,l)-pplev(ig,l+1))/RG enddo enddo c print*,'12 OK convect8' c print*,'WA4 ',wa_moy cc------------------------------------------------------------------ c calcul du transport vertical c------------------------------------------------------------------ go to 4444 c print*,'XXXXXXXXXXXXXXX ptimestep= ',ptimestep do l=2,nlay-1 do ig=1,ngrid if(fm(ig,l+1)*ptimestep.gt.masse(ig,l) s .and.fm(ig,l+1)*ptimestep.gt.masse(ig,l+1)) then c print*,'WARN!!! FM>M ig=',ig,' l=',l,' FM=' c s ,fm(ig,l+1)*ptimestep c s ,' M=',masse(ig,l),masse(ig,l+1) endif enddo enddo do l=1,nlay do ig=1,ngrid if(entr(ig,l)*ptimestep.gt.masse(ig,l)) then c print*,'WARN!!! E>M ig=',ig,' l=',l,' E==' c s ,entr(ig,l)*ptimestep c s ,' M=',masse(ig,l) endif enddo enddo do l=1,nlay do ig=1,ngrid if(.not.fm(ig,l).ge.0..or..not.fm(ig,l).le.10.) then c print*,'WARN!!! fm exagere ig=',ig,' l=',l c s ,' FM=',fm(ig,l) endif if(.not.masse(ig,l).ge.1.e-10 s .or..not.masse(ig,l).le.1.e4) then c print*,'WARN!!! masse exagere ig=',ig,' l=',l c s ,' M=',masse(ig,l) c print*,'rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l)', c s rho(ig,l),pplay(ig,l),zpspsk(ig,l),RD,zh(ig,l) c print*,'zlev(ig,l+1),zlev(ig,l)' c s ,zlev(ig,l+1),zlev(ig,l) c print*,'pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1)' c s ,pphi(ig,l-1),pphi(ig,l),pphi(ig,l+1) endif if(.not.entr(ig,l).ge.0..or..not.entr(ig,l).le.10.) then c print*,'WARN!!! entr exagere ig=',ig,' l=',l c s ,' E=',entr(ig,l) endif enddo enddo 4444 continue cCR:redefinition du entr do l=1,nlay do ig=1,ngrid detr(ig,l)=fm(ig,l)+entr(ig,l)-fm(ig,l+1) if (detr(ig,l).lt.0.) then entr(ig,l)=entr(ig,l)-detr(ig,l) detr(ig,l)=0. c print*,'WARNING !!! detrainement negatif ',ig,l endif enddo enddo cRC if (w2di.eq.1) then fm0=fm0+ptimestep*(fm-fm0)/float(tho) entr0=entr0+ptimestep*(entr-entr0)/float(tho) else fm0=fm entr0=entr endif if (1.eq.1) then call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zh,zdhadj,zha) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zo,pdoadj,zoa) else call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zh,zdhadj,zha) call dqthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse,fraca . ,zo,pdoadj,zoa) endif if (1.eq.0) then call dvthermcell2(ngrid,nlay,ptimestep,fm0,entr0,masse . ,fraca,zmax . ,zu,zv,pduadj,pdvadj,zua,zva) else call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zu,pduadj,zua) call dqthermcell(ngrid,nlay,ptimestep,fm0,entr0,masse . ,zv,pdvadj,zva) endif do l=1,nlay do ig=1,ngrid zf=0.5*(fracc(ig,l)+fracc(ig,l+1)) zf2=zf/(1.-zf) thetath2(ig,l)=zf2*(zha(ig,l)-zh(ig,l))**2 wth2(ig,l)=zf2*(0.5*(wa_moy(ig,l)+wa_moy(ig,l+1)))**2 enddo enddo c print*,'13 OK convect8' c print*,'WA5 ',wa_moy do l=1,nlay do ig=1,ngrid pdtadj(ig,l)=zdhadj(ig,l)*zpspsk(ig,l) enddo enddo c do l=1,nlay c do ig=1,ngrid c if(abs(pdtadj(ig,l))*86400..gt.500.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdtadj=',pdtadj(ig,l) c endif c if(abs(pdoadj(ig,l))*86400..gt.1.) then c print*,'WARN!!! ig=',ig,' l=',l c s ,' pdoadj=',pdoadj(ig,l) c endif c enddo c enddo c print*,'14 OK convect8' c------------------------------------------------------------------ c Calculs pour les sorties c------------------------------------------------------------------ if(sorties) then do l=1,nlay do ig=1,ngrid zla(ig,l)=(1.-fracd(ig,l))*zmax(ig) zld(ig,l)=fracd(ig,l)*zmax(ig) if(1.-fracd(ig,l).gt.1.e-10) s zwa(ig,l)=wd(ig,l)*fracd(ig,l)/(1.-fracd(ig,l)) enddo enddo cdeja fait c do l=1,nlay c do ig=1,ngrid c detr(ig,l)=fm(ig,l)+entr(ig,l)-fm(ig,l+1) c if (detr(ig,l).lt.0.) then c entr(ig,l)=entr(ig,l)-detr(ig,l) c detr(ig,l)=0. c print*,'WARNING !!! detrainement negatif ',ig,l c endif c enddo c enddo c print*,'15 OK convect8' isplit=isplit+1 c #define und goto 123 #ifdef und CALL writeg1d(1,nlay,wd,'wd ','wd ') CALL writeg1d(1,nlay,zwa,'wa ','wa ') CALL writeg1d(1,nlay,fracd,'fracd ','fracd ') CALL writeg1d(1,nlay,fraca,'fraca ','fraca ') CALL writeg1d(1,nlay,wa_moy,'wam ','wam ') CALL writeg1d(1,nlay,zla,'la ','la ') CALL writeg1d(1,nlay,zld,'ld ','ld ') CALL writeg1d(1,nlay,pt,'pt ','pt ') CALL writeg1d(1,nlay,zh,'zh ','zh ') CALL writeg1d(1,nlay,zha,'zha ','zha ') CALL writeg1d(1,nlay,zu,'zu ','zu ') CALL writeg1d(1,nlay,zv,'zv ','zv ') CALL writeg1d(1,nlay,zo,'zo ','zo ') CALL writeg1d(1,nlay,wh,'wh ','wh ') CALL writeg1d(1,nlay,wu,'wu ','wu ') CALL writeg1d(1,nlay,wv,'wv ','wv ') CALL writeg1d(1,nlay,wo,'w15uo ','wXo ') CALL writeg1d(1,nlay,zdhadj,'zdhadj ','zdhadj ') CALL writeg1d(1,nlay,pduadj,'pduadj ','pduadj ') CALL writeg1d(1,nlay,pdvadj,'pdvadj ','pdvadj ') CALL writeg1d(1,nlay,pdoadj,'pdoadj ','pdoadj ') CALL writeg1d(1,nlay,entr ,'entr ','entr ') CALL writeg1d(1,nlay,detr ,'detr ','detr ') CALL writeg1d(1,nlay,fm ,'fm ','fm ') CALL writeg1d(1,nlay,pdtadj,'pdtadj ','pdtadj ') CALL writeg1d(1,nlay,pplay,'pplay ','pplay ') CALL writeg1d(1,nlay,pplev,'pplev ','pplev ') c recalcul des flux en diagnostique... c print*,'PAS DE TEMPS ',ptimestep call dt2F(pplev,pplay,pt,pdtadj,wh) CALL writeg1d(1,nlay,wh,'wh2 ','wh2 ') #endif 123 continue ! #define troisD #ifdef troisD c if (sorties) then print*,'Debut des wrgradsfi' c print*,'16 OK convect8' call wrgradsfi(1,nlay,wd,'wd ','wd ') call wrgradsfi(1,nlay,zwa,'wa ','wa ') call wrgradsfi(1,nlay,fracd,'fracd ','fracd ') call wrgradsfi(1,nlay,fraca,'fraca ','fraca ') call wrgradsfi(1,nlay,xxx,'xxx ','xxx ') call wrgradsfi(1,nlay,wa_moy,'wam ','wam ') c print*,'WA6 ',wa_moy call wrgradsfi(1,nlay,zla,'la ','la ') call wrgradsfi(1,nlay,zld,'ld ','ld ') call wrgradsfi(1,nlay,pt,'pt ','pt ') call wrgradsfi(1,nlay,zh,'zh ','zh ') call wrgradsfi(1,nlay,zha,'zha ','zha ') call wrgradsfi(1,nlay,zua,'zua ','zua ') call wrgradsfi(1,nlay,zva,'zva ','zva ') call wrgradsfi(1,nlay,zu,'zu ','zu ') call wrgradsfi(1,nlay,zv,'zv ','zv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,wh,'wh ','wh ') call wrgradsfi(1,nlay,wu,'wu ','wu ') call wrgradsfi(1,nlay,wv,'wv ','wv ') call wrgradsfi(1,nlay,wo,'wo ','wo ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,nlay,zdhadj,'zdhadj ','zdhadj ') call wrgradsfi(1,nlay,pduadj,'pduadj ','pduadj ') call wrgradsfi(1,nlay,pdvadj,'pdvadj ','pdvadj ') call wrgradsfi(1,nlay,pdoadj,'pdoadj ','pdoadj ') call wrgradsfi(1,nlay,entr,'entr ','entr ') call wrgradsfi(1,nlay,detr,'detr ','detr ') call wrgradsfi(1,nlay,fm,'fm ','fm ') call wrgradsfi(1,nlay,fmc,'fmc ','fmc ') call wrgradsfi(1,nlay,zw2,'zw2 ','zw2 ') call wrgradsfi(1,nlay,ztva,'ztva ','ztva ') call wrgradsfi(1,nlay,ztv,'ztv ','ztv ') call wrgradsfi(1,nlay,zo,'zo ','zo ') call wrgradsfi(1,nlay,larg_cons,'Lc ','Lc ') call wrgradsfi(1,nlay,larg_detr,'Ldetr ','Ldetr ') cCR:nouveaux diagnostiques call wrgradsfi(1,nlay,entr_star ,'entr_star ','entr_star ') call wrgradsfi(1,nlay,f_star ,'f_star ','f_star ') call wrgradsfi(1,1,zmax,'zmax ','zmax ') call wrgradsfi(1,1,zmix,'zmix ','zmix ') zsortie1d(:)=lmax(:) call wrgradsfi(1,1,zsortie1d,'lmax ','lmax ') call wrgradsfi(1,1,wmax,'wmax ','wmax ') zsortie1d(:)=lmix(:) call wrgradsfi(1,1,zsortie1d,'lmix ','lmix ') zsortie1d(:)=lentr(:) call wrgradsfi(1,1,zsortie1d,'lentr ','lentr ') c print*,'17 OK convect8' do k=1,klev/10 write(str2,'(i2.2)') k str10='wa'//str2 do l=1,nlay do ig=1,ngrid zsortie(ig,l)=wa(ig,k,l) enddo enddo CALL wrgradsfi(1,nlay,zsortie,str10,str10) do l=1,nlay do ig=1,ngrid zsortie(ig,l)=larg_part(ig,k,l) enddo enddo str10='la'//str2 CALL wrgradsfi(1,nlay,zsortie,str10,str10) enddo c print*,'18 OK convect8' c endif print*,'Fin des wrgradsfi' #endif endif c if(wa_moy(1,4).gt.1.e-10) stop c print*,'19 OK convect8' return end