libf/phylmd/phystokenc.f90

!
! $Header: /home/cvsroot/LMDZ4/libf/phylmd/phystokenc.F,v 1.2 2004/06/22 11:45:35 lmdzadmin Exp $
!
c
c
      SUBROUTINE phystokenc (
     I                   pdtphys,rlon,rlat,
     I                   pt,pmfu, pmfd, pen_u, pde_u, pen_d, pde_d,
     I                   pfm_therm,pentr_therm,
     I                   pcoefh,yu1,yv1,ftsol,pctsrf,
     I                   frac_impa,frac_nucl,
     I                   pphis,paire,dtime,itap)
      USE histwrite_m
      use histcom
      use dimens_m
      use indicesol
      use dimphy
      use conf_gcm_m
      use tracstoke
      IMPLICIT none

c======================================================================
c Auteur(s) FH
c Objet: Moniteur general des tendances traceurs
c

c======================================================================
c======================================================================

c Arguments:
c
c   EN ENTREE:
c   ==========
c
c   divers:
c   -------
c
      real, intent(in):: pdtphys ! pas d'integration pour la physique (seconde)
c
      integer physid
      integer, intent(in):: itap
      save physid
      integer ndex2d(iim*(jjm+1)),ndex3d(iim*(jjm+1)*klev)

c   convection:
c   -----------
c
      REAL pmfu(klon,klev)  ! flux de masse dans le panache montant
      REAL pmfd(klon,klev)  ! flux de masse dans le panache descendant
      REAL pen_u(klon,klev) ! flux entraine dans le panache montant
      REAL pde_u(klon,klev) ! flux detraine dans le panache montant
      REAL pen_d(klon,klev) ! flux entraine dans le panache descendant
      REAL pde_d(klon,klev) ! flux detraine dans le panache descendant
        real pt(klon,klev),t(klon,klev)
c
      REAL, intent(in):: rlon(klon), rlat(klon)
      real, intent(in):: dtime
      REAL zx_tmp_3d(iim,jjm+1,klev),zx_tmp_2d(iim,jjm+1)

c   Couche limite:
c   --------------
c
      REAL pcoefh(klon,klev)    ! coeff melange CL
      REAL yv1(klon)
      REAL yu1(klon),pphis(klon),paire(klon)

c   Les Thermiques : (Abderr 25 11 02)
c   ---------------
      REAL pfm_therm(klon,klev+1)
        real fm_therm1(klon,klev)
      REAL pentr_therm(klon,klev)
      REAL entr_therm(klon,klev)
      REAL fm_therm(klon,klev)
c
c   Lessivage:
c   ----------
c
      REAL frac_impa(klon,klev)
      REAL frac_nucl(klon,klev)
c
c Arguments necessaires pour les sources et puits de traceur
C
      real ftsol(klon,nbsrf)  ! Temperature du sol (surf)(Kelvin)
      real pctsrf(klon,nbsrf) ! Pourcentage de sol f(nature du sol)
c======================================================================
c
      INTEGER i, k
c
      REAL mfu(klon,klev)  ! flux de masse dans le panache montant
      REAL mfd(klon,klev)  ! flux de masse dans le panache descendant
      REAL en_u(klon,klev) ! flux entraine dans le panache montant
      REAL de_u(klon,klev) ! flux detraine dans le panache montant
      REAL en_d(klon,klev) ! flux entraine dans le panache descendant
      REAL de_d(klon,klev) ! flux detraine dans le panache descendant
      REAL coefh(klon,klev) ! flux detraine dans le panache descendant

      REAL pyu1(klon),pyv1(klon)
      REAL pftsol(klon,nbsrf),ppsrf(klon,nbsrf)
      real pftsol1(klon),pftsol2(klon),pftsol3(klon),pftsol4(klon)
      real ppsrf1(klon),ppsrf2(klon),ppsrf3(klon),ppsrf4(klon)

      REAL dtcum

      integer iadvtr,irec
      real zmin,zmax
      logical ok_sync
 
      save t,mfu,mfd,en_u,de_u,en_d,de_d,coefh,dtcum
        save fm_therm,entr_therm
      save iadvtr,irec
      save pyu1,pyv1,pftsol,ppsrf

      data iadvtr,irec/0,1/
c
c   Couche limite:
c======================================================================

      ok_sync = .true.

      IF (iadvtr.eq.0) THEN
        CALL initphysto('phystoke',
     . rlon,rlat,dtime, dtime*istphy,dtime*istphy,nqmx,physid)
      ENDIF
c
      ndex2d = 0
      ndex3d = 0
      i=itap 
      CALL gr_fi_ecrit(1,klon,iim,jjm+1,pphis,zx_tmp_2d)
      CALL histwrite(physid,"phis",i,zx_tmp_2d)
c
      i=itap
      CALL gr_fi_ecrit(1,klon,iim,jjm+1,paire,zx_tmp_2d)
      CALL histwrite(physid,"aire",i,zx_tmp_2d)

      iadvtr=iadvtr+1
c
      if (mod(iadvtr,istphy).eq.1.or.istphy.eq.1) then
        print*,'reinitialisation des champs cumules 
     s          a iadvtr=',iadvtr
         do k=1,klev
            do i=1,klon
               mfu(i,k)=0.
               mfd(i,k)=0.
               en_u(i,k)=0.
               de_u(i,k)=0.
               en_d(i,k)=0.
               de_d(i,k)=0.
               coefh(i,k)=0.
                t(i,k)=0.
                fm_therm(i,k)=0.
               entr_therm(i,k)=0.
            enddo
         enddo
         do i=1,klon
            pyv1(i)=0.
            pyu1(i)=0.
         end do
         do k=1,nbsrf
             do i=1,klon
               pftsol(i,k)=0.
               ppsrf(i,k)=0.
            enddo
         enddo

         dtcum=0.
      endif

      do k=1,klev
         do i=1,klon
            mfu(i,k)=mfu(i,k)+pmfu(i,k)*pdtphys
            mfd(i,k)=mfd(i,k)+pmfd(i,k)*pdtphys
            en_u(i,k)=en_u(i,k)+pen_u(i,k)*pdtphys
            de_u(i,k)=de_u(i,k)+pde_u(i,k)*pdtphys
            en_d(i,k)=en_d(i,k)+pen_d(i,k)*pdtphys
            de_d(i,k)=de_d(i,k)+pde_d(i,k)*pdtphys
            coefh(i,k)=coefh(i,k)+pcoefh(i,k)*pdtphys
                t(i,k)=t(i,k)+pt(i,k)*pdtphys
       fm_therm(i,k)=fm_therm(i,k)+pfm_therm(i,k)*pdtphys
       entr_therm(i,k)=entr_therm(i,k)+pentr_therm(i,k)*pdtphys
         enddo
      enddo
         do i=1,klon
            pyv1(i)=pyv1(i)+yv1(i)*pdtphys
            pyu1(i)=pyu1(i)+yu1(i)*pdtphys
         end do
         do k=1,nbsrf
             do i=1,klon
               pftsol(i,k)=pftsol(i,k)+ftsol(i,k)*pdtphys
               ppsrf(i,k)=ppsrf(i,k)+pctsrf(i,k)*pdtphys
            enddo
         enddo

      dtcum=dtcum+pdtphys

      IF(mod(iadvtr,istphy).eq.0) THEN 
c
c   normalisation par le temps cumule
         do k=1,klev
            do i=1,klon
               mfu(i,k)=mfu(i,k)/dtcum
               mfd(i,k)=mfd(i,k)/dtcum
               en_u(i,k)=en_u(i,k)/dtcum
               de_u(i,k)=de_u(i,k)/dtcum
               en_d(i,k)=en_d(i,k)/dtcum
               de_d(i,k)=de_d(i,k)/dtcum
               coefh(i,k)=coefh(i,k)/dtcum
c Unitel a enlever
              t(i,k)=t(i,k)/dtcum       
               fm_therm(i,k)=fm_therm(i,k)/dtcum
               entr_therm(i,k)=entr_therm(i,k)/dtcum
            enddo
         enddo
         do i=1,klon
            pyv1(i)=pyv1(i)/dtcum
            pyu1(i)=pyu1(i)/dtcum
         end do
         do k=1,nbsrf
             do i=1,klon
               pftsol(i,k)=pftsol(i,k)/dtcum
               pftsol1(i) = pftsol(i,1)
               pftsol2(i) = pftsol(i,2)
               pftsol3(i) = pftsol(i,3)
               pftsol4(i) = pftsol(i,4)

               ppsrf(i,k)=ppsrf(i,k)/dtcum
               ppsrf1(i) = ppsrf(i,1)
               ppsrf2(i) = ppsrf(i,2)
               ppsrf3(i) = ppsrf(i,3)
               ppsrf4(i) = ppsrf(i,4)

            enddo
         enddo
c
c   ecriture des champs
c
         irec=irec+1

ccccc
         CALL gr_fi_ecrit(klev,klon,iim,jjm+1, t, zx_tmp_3d)
         CALL histwrite(physid,"t",itap,zx_tmp_3d)

         CALL gr_fi_ecrit(klev,klon,iim,jjm+1, mfu, zx_tmp_3d)
      CALL histwrite(physid,"mfu",itap,zx_tmp_3d)
        CALL gr_fi_ecrit(klev,klon,iim,jjm+1, mfd, zx_tmp_3d)
      CALL histwrite(physid,"mfd",itap,zx_tmp_3d)
        CALL gr_fi_ecrit(klev,klon,iim,jjm+1, en_u, zx_tmp_3d)
      CALL histwrite(physid,"en_u",itap,zx_tmp_3d)
        CALL gr_fi_ecrit(klev,klon,iim,jjm+1, de_u, zx_tmp_3d)
      CALL histwrite(physid,"de_u",itap,zx_tmp_3d)
        CALL gr_fi_ecrit(klev,klon,iim,jjm+1, en_d, zx_tmp_3d)
      CALL histwrite(physid,"en_d",itap,zx_tmp_3d)
        CALL gr_fi_ecrit(klev,klon,iim,jjm+1, de_d, zx_tmp_3d)       
      CALL histwrite(physid,"de_d",itap,zx_tmp_3d)
        CALL gr_fi_ecrit(klev,klon,iim,jjm+1, coefh, zx_tmp_3d)         
      CALL histwrite(physid,"coefh",itap,zx_tmp_3d)     

c ajou...
        do k=1,klev
           do i=1,klon
         fm_therm1(i,k)=fm_therm(i,k)   
           enddo
        enddo

      CALL gr_fi_ecrit(klev,klon,iim,jjm+1, fm_therm1, zx_tmp_3d)
      CALL histwrite(physid,"fm_th",itap,zx_tmp_3d)
c
      CALL gr_fi_ecrit(klev,klon,iim,jjm+1, entr_therm, zx_tmp_3d)
      CALL histwrite(physid,"en_th",itap,zx_tmp_3d)
cccc
       CALL gr_fi_ecrit(klev,klon,iim,jjm+1,frac_impa,zx_tmp_3d)
        CALL histwrite(physid,"frac_impa",itap,zx_tmp_3d)

        CALL gr_fi_ecrit(klev,klon,iim,jjm+1,frac_nucl,zx_tmp_3d)
        CALL histwrite(physid,"frac_nucl",itap,zx_tmp_3d)
 
        CALL gr_fi_ecrit(1, klon,iim,jjm+1, pyu1,zx_tmp_2d)
      CALL histwrite(physid,"pyu1",itap,zx_tmp_2d)
        
        CALL gr_fi_ecrit(1, klon,iim,jjm+1, pyv1,zx_tmp_2d)
      CALL histwrite(physid,"pyv1",itap,zx_tmp_2d)
        
        CALL gr_fi_ecrit(1,klon,iim,jjm+1, pftsol1, zx_tmp_2d)
      CALL histwrite(physid,"ftsol1",itap,zx_tmp_2d)
         CALL gr_fi_ecrit(1,klon,iim,jjm+1, pftsol2, zx_tmp_2d)
      CALL histwrite(physid,"ftsol2",itap,zx_tmp_2d)
          CALL gr_fi_ecrit(1,klon,iim,jjm+1, pftsol3, zx_tmp_2d)
      CALL histwrite(physid,"ftsol3",itap,zx_tmp_2d)
         CALL gr_fi_ecrit(1,klon,iim,jjm+1, pftsol4, zx_tmp_2d)
      CALL histwrite(physid,"ftsol4",itap,zx_tmp_2d)

        CALL gr_fi_ecrit(1,klon,iim,jjm+1, ppsrf1, zx_tmp_2d)
      CALL histwrite(physid,"psrf1",itap,zx_tmp_2d)
        CALL gr_fi_ecrit(1,klon,iim,jjm+1, ppsrf2, zx_tmp_2d)
      CALL histwrite(physid,"psrf2",itap,zx_tmp_2d)
        CALL gr_fi_ecrit(1,klon,iim,jjm+1, ppsrf3, zx_tmp_2d)
      CALL histwrite(physid,"psrf3",itap,zx_tmp_2d)
        CALL gr_fi_ecrit(1,klon,iim,jjm+1, ppsrf4, zx_tmp_2d)
      CALL histwrite(physid,"psrf4",itap,zx_tmp_2d)

      if (ok_sync) call histsync(physid)
c     if (ok_sync) call histsync
        
c
cAA Test sur la valeur des coefficients de lessivage 
c
         zmin=1e33
         zmax=-1e33
         do k=1,klev
            do i=1,klon
                  zmax=max(zmax,frac_nucl(i,k))
                  zmin=min(zmin,frac_nucl(i,k))
            enddo
         enddo
         Print*,'------ coefs de lessivage (min et max) --------'
         Print*,'facteur de nucleation ',zmin,zmax
         zmin=1e33
         zmax=-1e33
         do k=1,klev
            do i=1,klon
                  zmax=max(zmax,frac_impa(i,k))
                  zmin=min(zmin,frac_impa(i,k))
            enddo
         enddo
         Print*,'facteur d impaction ',zmin,zmax

      ENDIF 

c   reinitialisation des champs cumules
        go to 768
      if (mod(iadvtr,istphy).eq.1) then
         do k=1,klev
            do i=1,klon
               mfu(i,k)=0.
               mfd(i,k)=0.
               en_u(i,k)=0.
               de_u(i,k)=0.
               en_d(i,k)=0.
               de_d(i,k)=0.
               coefh(i,k)=0.
               t(i,k)=0.
               fm_therm(i,k)=0.
               entr_therm(i,k)=0.
            enddo
         enddo
         do i=1,klon
            pyv1(i)=0.
            pyu1(i)=0.
         end do
         do k=1,nbsrf
             do i=1,klon
               pftsol(i,k)=0.
               ppsrf(i,k)=0.
            enddo
         enddo

         dtcum=0.
      endif

      do k=1,klev
         do i=1,klon
            mfu(i,k)=mfu(i,k)+pmfu(i,k)*pdtphys
            mfd(i,k)=mfd(i,k)+pmfd(i,k)*pdtphys
            en_u(i,k)=en_u(i,k)+pen_u(i,k)*pdtphys
            de_u(i,k)=de_u(i,k)+pde_u(i,k)*pdtphys
            en_d(i,k)=en_d(i,k)+pen_d(i,k)*pdtphys
            de_d(i,k)=de_d(i,k)+pde_d(i,k)*pdtphys
            coefh(i,k)=coefh(i,k)+pcoefh(i,k)*pdtphys
                t(i,k)=t(i,k)+pt(i,k)*pdtphys
       fm_therm(i,k)=fm_therm(i,k)+pfm_therm(i,k)*pdtphys
       entr_therm(i,k)=entr_therm(i,k)+pentr_therm(i,k)*pdtphys
         enddo
      enddo
         do i=1,klon
            pyv1(i)=pyv1(i)+yv1(i)*pdtphys
            pyu1(i)=pyu1(i)+yu1(i)*pdtphys
         end do
         do k=1,nbsrf
             do i=1,klon
               pftsol(i,k)=pftsol(i,k)+ftsol(i,k)*pdtphys
               ppsrf(i,k)=ppsrf(i,k)+pctsrf(i,k)*pdtphys
            enddo
         enddo

      dtcum=dtcum+pdtphys
768   continue

      RETURN
      END
1	guez	3	!
2			! $Header: /home/cvsroot/LMDZ4/libf/phylmd/phystokenc.F,v 1.2 2004/06/22 11:45:35 lmdzadmin Exp $
3			!
4			c
5			c
6			SUBROUTINE phystokenc (
7			I pdtphys,rlon,rlat,
8			I pt,pmfu, pmfd, pen_u, pde_u, pen_d, pde_d,
9			I pfm_therm,pentr_therm,
10			I pcoefh,yu1,yv1,ftsol,pctsrf,
11			I frac_impa,frac_nucl,
12			I pphis,paire,dtime,itap)
13	guez	30	USE histwrite_m
14			use histcom
15	guez	3	use dimens_m
16			use indicesol
17			use dimphy
18			use conf_gcm_m
19			use tracstoke
20			IMPLICIT none
21
22			c======================================================================
23			c Auteur(s) FH
24			c Objet: Moniteur general des tendances traceurs
25			c
26
27			c======================================================================
28			c======================================================================
29
30			c Arguments:
31			c
32			c EN ENTREE:
33			c ==========
34			c
35			c divers:
36			c -------
37			c
38	guez	12	real, intent(in):: pdtphys ! pas d'integration pour la physique (seconde)
39	guez	3	c
40	guez	7	integer physid
41			integer, intent(in):: itap
42	guez	3	save physid
43			integer ndex2d(iim(jjm+1)),ndex3d(iim(jjm+1)*klev)
44
45			c convection:
46			c -----------
47			c
48			REAL pmfu(klon,klev) ! flux de masse dans le panache montant
49			REAL pmfd(klon,klev) ! flux de masse dans le panache descendant
50			REAL pen_u(klon,klev) ! flux entraine dans le panache montant
51			REAL pde_u(klon,klev) ! flux detraine dans le panache montant
52			REAL pen_d(klon,klev) ! flux entraine dans le panache descendant
53			REAL pde_d(klon,klev) ! flux detraine dans le panache descendant
54			real pt(klon,klev),t(klon,klev)
55			c
56			REAL, intent(in):: rlon(klon), rlat(klon)
57	guez	12	real, intent(in):: dtime
58	guez	3	REAL zx_tmp_3d(iim,jjm+1,klev),zx_tmp_2d(iim,jjm+1)
59
60			c Couche limite:
61			c --------------
62			c
63			REAL pcoefh(klon,klev) ! coeff melange CL
64			REAL yv1(klon)
65			REAL yu1(klon),pphis(klon),paire(klon)
66
67			c Les Thermiques : (Abderr 25 11 02)
68			c ---------------
69			REAL pfm_therm(klon,klev+1)
70			real fm_therm1(klon,klev)
71			REAL pentr_therm(klon,klev)
72			REAL entr_therm(klon,klev)
73			REAL fm_therm(klon,klev)
74			c
75			c Lessivage:
76			c ----------
77			c
78			REAL frac_impa(klon,klev)
79			REAL frac_nucl(klon,klev)
80			c
81			c Arguments necessaires pour les sources et puits de traceur
82			C
83			real ftsol(klon,nbsrf) ! Temperature du sol (surf)(Kelvin)
84			real pctsrf(klon,nbsrf) ! Pourcentage de sol f(nature du sol)
85			c======================================================================
86			c
87			INTEGER i, k
88			c
89			REAL mfu(klon,klev) ! flux de masse dans le panache montant
90			REAL mfd(klon,klev) ! flux de masse dans le panache descendant
91			REAL en_u(klon,klev) ! flux entraine dans le panache montant
92			REAL de_u(klon,klev) ! flux detraine dans le panache montant
93			REAL en_d(klon,klev) ! flux entraine dans le panache descendant
94			REAL de_d(klon,klev) ! flux detraine dans le panache descendant
95			REAL coefh(klon,klev) ! flux detraine dans le panache descendant
96
97			REAL pyu1(klon),pyv1(klon)
98			REAL pftsol(klon,nbsrf),ppsrf(klon,nbsrf)
99			real pftsol1(klon),pftsol2(klon),pftsol3(klon),pftsol4(klon)
100			real ppsrf1(klon),ppsrf2(klon),ppsrf3(klon),ppsrf4(klon)
101
102			REAL dtcum
103
104			integer iadvtr,irec
105			real zmin,zmax
106			logical ok_sync
107
108			save t,mfu,mfd,en_u,de_u,en_d,de_d,coefh,dtcum
109			save fm_therm,entr_therm
110			save iadvtr,irec
111			save pyu1,pyv1,pftsol,ppsrf
112
113			data iadvtr,irec/0,1/
114			c
115			c Couche limite:
116			c======================================================================
117
118			ok_sync = .true.
119
120			IF (iadvtr.eq.0) THEN
121			CALL initphysto('phystoke',
122			. rlon,rlat,dtime, dtimeistphy,dtimeistphy,nqmx,physid)
123			ENDIF
124			c
125			ndex2d = 0
126			ndex3d = 0
127			i=itap
128			CALL gr_fi_ecrit(1,klon,iim,jjm+1,pphis,zx_tmp_2d)
129	guez	15	CALL histwrite(physid,"phis",i,zx_tmp_2d)
130	guez	3	c
131			i=itap
132			CALL gr_fi_ecrit(1,klon,iim,jjm+1,paire,zx_tmp_2d)
133	guez	15	CALL histwrite(physid,"aire",i,zx_tmp_2d)
134	guez	3
135			iadvtr=iadvtr+1
136			c
137			if (mod(iadvtr,istphy).eq.1.or.istphy.eq.1) then
138			print*,'reinitialisation des champs cumules
139			s a iadvtr=',iadvtr
140			do k=1,klev
141			do i=1,klon
142			mfu(i,k)=0.
143			mfd(i,k)=0.
144			en_u(i,k)=0.
145			de_u(i,k)=0.
146			en_d(i,k)=0.
147			de_d(i,k)=0.
148			coefh(i,k)=0.
149			t(i,k)=0.
150			fm_therm(i,k)=0.
151			entr_therm(i,k)=0.
152			enddo
153			enddo
154			do i=1,klon
155			pyv1(i)=0.
156			pyu1(i)=0.
157			end do
158			do k=1,nbsrf
159			do i=1,klon
160			pftsol(i,k)=0.
161			ppsrf(i,k)=0.
162			enddo
163			enddo
164
165			dtcum=0.
166			endif
167
168			do k=1,klev
169			do i=1,klon
170			mfu(i,k)=mfu(i,k)+pmfu(i,k)*pdtphys
171			mfd(i,k)=mfd(i,k)+pmfd(i,k)*pdtphys
172			en_u(i,k)=en_u(i,k)+pen_u(i,k)*pdtphys
173			de_u(i,k)=de_u(i,k)+pde_u(i,k)*pdtphys
174			en_d(i,k)=en_d(i,k)+pen_d(i,k)*pdtphys
175			de_d(i,k)=de_d(i,k)+pde_d(i,k)*pdtphys
176			coefh(i,k)=coefh(i,k)+pcoefh(i,k)*pdtphys
177			t(i,k)=t(i,k)+pt(i,k)*pdtphys
178			fm_therm(i,k)=fm_therm(i,k)+pfm_therm(i,k)*pdtphys
179			entr_therm(i,k)=entr_therm(i,k)+pentr_therm(i,k)*pdtphys
180			enddo
181			enddo
182			do i=1,klon
183			pyv1(i)=pyv1(i)+yv1(i)*pdtphys
184			pyu1(i)=pyu1(i)+yu1(i)*pdtphys
185			end do
186			do k=1,nbsrf
187			do i=1,klon
188			pftsol(i,k)=pftsol(i,k)+ftsol(i,k)*pdtphys
189			ppsrf(i,k)=ppsrf(i,k)+pctsrf(i,k)*pdtphys
190			enddo
191			enddo
192
193			dtcum=dtcum+pdtphys
194
195			IF(mod(iadvtr,istphy).eq.0) THEN
196			c
197			c normalisation par le temps cumule
198			do k=1,klev
199			do i=1,klon
200			mfu(i,k)=mfu(i,k)/dtcum
201			mfd(i,k)=mfd(i,k)/dtcum
202			en_u(i,k)=en_u(i,k)/dtcum
203			de_u(i,k)=de_u(i,k)/dtcum
204			en_d(i,k)=en_d(i,k)/dtcum
205			de_d(i,k)=de_d(i,k)/dtcum
206			coefh(i,k)=coefh(i,k)/dtcum
207			c Unitel a enlever
208			t(i,k)=t(i,k)/dtcum
209			fm_therm(i,k)=fm_therm(i,k)/dtcum
210			entr_therm(i,k)=entr_therm(i,k)/dtcum
211			enddo
212			enddo
213			do i=1,klon
214			pyv1(i)=pyv1(i)/dtcum
215			pyu1(i)=pyu1(i)/dtcum
216			end do
217			do k=1,nbsrf
218			do i=1,klon
219			pftsol(i,k)=pftsol(i,k)/dtcum
220			pftsol1(i) = pftsol(i,1)
221			pftsol2(i) = pftsol(i,2)
222			pftsol3(i) = pftsol(i,3)
223			pftsol4(i) = pftsol(i,4)
224
225			ppsrf(i,k)=ppsrf(i,k)/dtcum
226			ppsrf1(i) = ppsrf(i,1)
227			ppsrf2(i) = ppsrf(i,2)
228			ppsrf3(i) = ppsrf(i,3)
229			ppsrf4(i) = ppsrf(i,4)
230
231			enddo
232			enddo
233			c
234			c ecriture des champs
235			c
236			irec=irec+1
237
238			ccccc
239			CALL gr_fi_ecrit(klev,klon,iim,jjm+1, t, zx_tmp_3d)
240	guez	15	CALL histwrite(physid,"t",itap,zx_tmp_3d)
241	guez	3
242			CALL gr_fi_ecrit(klev,klon,iim,jjm+1, mfu, zx_tmp_3d)
243	guez	15	CALL histwrite(physid,"mfu",itap,zx_tmp_3d)
244	guez	3	CALL gr_fi_ecrit(klev,klon,iim,jjm+1, mfd, zx_tmp_3d)
245	guez	15	CALL histwrite(physid,"mfd",itap,zx_tmp_3d)
246	guez	3	CALL gr_fi_ecrit(klev,klon,iim,jjm+1, en_u, zx_tmp_3d)
247	guez	15	CALL histwrite(physid,"en_u",itap,zx_tmp_3d)
248	guez	3	CALL gr_fi_ecrit(klev,klon,iim,jjm+1, de_u, zx_tmp_3d)
249	guez	15	CALL histwrite(physid,"de_u",itap,zx_tmp_3d)
250	guez	3	CALL gr_fi_ecrit(klev,klon,iim,jjm+1, en_d, zx_tmp_3d)
251	guez	15	CALL histwrite(physid,"en_d",itap,zx_tmp_3d)
252	guez	3	CALL gr_fi_ecrit(klev,klon,iim,jjm+1, de_d, zx_tmp_3d)
253	guez	15	CALL histwrite(physid,"de_d",itap,zx_tmp_3d)
254	guez	3	CALL gr_fi_ecrit(klev,klon,iim,jjm+1, coefh, zx_tmp_3d)
255	guez	15	CALL histwrite(physid,"coefh",itap,zx_tmp_3d)
256	guez	3
257			c ajou...
258			do k=1,klev
259			do i=1,klon
260			fm_therm1(i,k)=fm_therm(i,k)
261			enddo
262			enddo
263
264			CALL gr_fi_ecrit(klev,klon,iim,jjm+1, fm_therm1, zx_tmp_3d)
265	guez	15	CALL histwrite(physid,"fm_th",itap,zx_tmp_3d)
266	guez	3	c
267			CALL gr_fi_ecrit(klev,klon,iim,jjm+1, entr_therm, zx_tmp_3d)
268	guez	15	CALL histwrite(physid,"en_th",itap,zx_tmp_3d)
269	guez	3	cccc
270			CALL gr_fi_ecrit(klev,klon,iim,jjm+1,frac_impa,zx_tmp_3d)
271	guez	15	CALL histwrite(physid,"frac_impa",itap,zx_tmp_3d)
272	guez	3
273			CALL gr_fi_ecrit(klev,klon,iim,jjm+1,frac_nucl,zx_tmp_3d)
274	guez	15	CALL histwrite(physid,"frac_nucl",itap,zx_tmp_3d)
275	guez	3
276			CALL gr_fi_ecrit(1, klon,iim,jjm+1, pyu1,zx_tmp_2d)
277	guez	15	CALL histwrite(physid,"pyu1",itap,zx_tmp_2d)
278	guez	3
279			CALL gr_fi_ecrit(1, klon,iim,jjm+1, pyv1,zx_tmp_2d)
280	guez	15	CALL histwrite(physid,"pyv1",itap,zx_tmp_2d)
281	guez	3
282			CALL gr_fi_ecrit(1,klon,iim,jjm+1, pftsol1, zx_tmp_2d)
283	guez	15	CALL histwrite(physid,"ftsol1",itap,zx_tmp_2d)
284	guez	3	CALL gr_fi_ecrit(1,klon,iim,jjm+1, pftsol2, zx_tmp_2d)
285	guez	15	CALL histwrite(physid,"ftsol2",itap,zx_tmp_2d)
286	guez	3	CALL gr_fi_ecrit(1,klon,iim,jjm+1, pftsol3, zx_tmp_2d)
287	guez	15	CALL histwrite(physid,"ftsol3",itap,zx_tmp_2d)
288	guez	3	CALL gr_fi_ecrit(1,klon,iim,jjm+1, pftsol4, zx_tmp_2d)
289	guez	15	CALL histwrite(physid,"ftsol4",itap,zx_tmp_2d)
290	guez	3
291			CALL gr_fi_ecrit(1,klon,iim,jjm+1, ppsrf1, zx_tmp_2d)
292	guez	15	CALL histwrite(physid,"psrf1",itap,zx_tmp_2d)
293	guez	3	CALL gr_fi_ecrit(1,klon,iim,jjm+1, ppsrf2, zx_tmp_2d)
294	guez	15	CALL histwrite(physid,"psrf2",itap,zx_tmp_2d)
295	guez	3	CALL gr_fi_ecrit(1,klon,iim,jjm+1, ppsrf3, zx_tmp_2d)
296	guez	15	CALL histwrite(physid,"psrf3",itap,zx_tmp_2d)
297	guez	3	CALL gr_fi_ecrit(1,klon,iim,jjm+1, ppsrf4, zx_tmp_2d)
298	guez	15	CALL histwrite(physid,"psrf4",itap,zx_tmp_2d)
299	guez	3
300			if (ok_sync) call histsync(physid)
301			c if (ok_sync) call histsync
302
303			c
304			cAA Test sur la valeur des coefficients de lessivage
305			c
306			zmin=1e33
307			zmax=-1e33
308			do k=1,klev
309			do i=1,klon
310			zmax=max(zmax,frac_nucl(i,k))
311			zmin=min(zmin,frac_nucl(i,k))
312			enddo
313			enddo
314			Print*,'------ coefs de lessivage (min et max) --------'
315			Print*,'facteur de nucleation ',zmin,zmax
316			zmin=1e33
317			zmax=-1e33
318			do k=1,klev
319			do i=1,klon
320			zmax=max(zmax,frac_impa(i,k))
321			zmin=min(zmin,frac_impa(i,k))
322			enddo
323			enddo
324			Print*,'facteur d impaction ',zmin,zmax
325
326			ENDIF
327
328			c reinitialisation des champs cumules
329			go to 768
330			if (mod(iadvtr,istphy).eq.1) then
331			do k=1,klev
332			do i=1,klon
333			mfu(i,k)=0.
334			mfd(i,k)=0.
335			en_u(i,k)=0.
336			de_u(i,k)=0.
337			en_d(i,k)=0.
338			de_d(i,k)=0.
339			coefh(i,k)=0.
340			t(i,k)=0.
341			fm_therm(i,k)=0.
342			entr_therm(i,k)=0.
343			enddo
344			enddo
345			do i=1,klon
346			pyv1(i)=0.
347			pyu1(i)=0.
348			end do
349			do k=1,nbsrf
350			do i=1,klon
351			pftsol(i,k)=0.
352			ppsrf(i,k)=0.
353			enddo
354			enddo
355
356			dtcum=0.
357			endif
358
359			do k=1,klev
360			do i=1,klon
361			mfu(i,k)=mfu(i,k)+pmfu(i,k)*pdtphys
362			mfd(i,k)=mfd(i,k)+pmfd(i,k)*pdtphys
363			en_u(i,k)=en_u(i,k)+pen_u(i,k)*pdtphys
364			de_u(i,k)=de_u(i,k)+pde_u(i,k)*pdtphys
365			en_d(i,k)=en_d(i,k)+pen_d(i,k)*pdtphys
366			de_d(i,k)=de_d(i,k)+pde_d(i,k)*pdtphys
367			coefh(i,k)=coefh(i,k)+pcoefh(i,k)*pdtphys
368			t(i,k)=t(i,k)+pt(i,k)*pdtphys
369			fm_therm(i,k)=fm_therm(i,k)+pfm_therm(i,k)*pdtphys
370			entr_therm(i,k)=entr_therm(i,k)+pentr_therm(i,k)*pdtphys
371			enddo
372			enddo
373			do i=1,klon
374			pyv1(i)=pyv1(i)+yv1(i)*pdtphys
375			pyu1(i)=pyu1(i)+yu1(i)*pdtphys
376			end do
377			do k=1,nbsrf
378			do i=1,klon
379			pftsol(i,k)=pftsol(i,k)+ftsol(i,k)*pdtphys
380			ppsrf(i,k)=ppsrf(i,k)+pctsrf(i,k)*pdtphys
381			enddo
382			enddo
383
384			dtcum=dtcum+pdtphys
385			768 continue
386
387			RETURN
388			END