source: LMDZ5/branches/testing/libf/phylmd/calcul_STDlev.h @ 1707

c
c $Header$
c
cIM on initialise les variables 
c
        missing_val=nf90_fill_real
c
cIM freq_moyNMC = frequences auxquelles on moyenne les champs accumules 
cIM               sur les niveaux de pression standard du NMC
      DO n=1, nout
       freq_moyNMC(n)=freq_outNMC(n)/freq_calNMC(n)
      ENDDO
c
        CALL ini_undefSTD(itap,freq_outNMC)
c
cIM on interpole les champs sur les niveaux STD de pression 
cIM a chaque pas de temps de la physique
c
c-------------------------------------------------------c
c positionnement de l'argument logique a .false.        c
c pour ne pas recalculer deux fois la meme chose !      c
c a cet effet un appel a plevel_new a ete deplace       c
c a la fin de la serie d'appels                         c
c la boucle 'DO k=1, nlevSTD' a ete internalisee        c
c dans plevel_new, d'ou la creation de cette routine... c
c-------------------------------------------------------c
c
        CALL plevel_new(klon,klev,nlevSTD,.true.,pplay,rlevSTD,
     &              t_seri,tlevSTD)
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             u_seri,ulevSTD)
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             v_seri,vlevSTD)
c

c
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zphi/RG,philevSTD)
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             qx(:,:,ivap),qlevSTD)
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_rh*100.,rhlevSTD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=u_seri(i,l)*v_seri(i,l)
         ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,uvSTD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=v_seri(i,l)*q_seri(i,l)
         ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,vqSTD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=v_seri(i,l)*t_seri(i,l)
         ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,vTSTD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=omega(i,l)*qx(i,l,ivap)
         ENDDO !i 
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,wqSTD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=v_seri(i,l)*zphi(i,l)/RG
         ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,vphiSTD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=omega(i,l)*t_seri(i,l)
         ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,wTSTD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=u_seri(i,l)*u_seri(i,l)
         ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,u2STD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=v_seri(i,l)*v_seri(i,l)
         ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,v2STD)
c
        DO l=1, klev
         DO i=1, klon
          zx_tmp_fi3d(i,l)=t_seri(i,l)*t_seri(i,l)
         ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,T2STD)

c
      zx_tmp_fi3d(:,:)=wo(:,:,1) * dobson_u * 1e3 / zmasse / rmo3 * rmd
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,O3STD)
c
      if (read_climoz == 2) THEN
      zx_tmp_fi3d(:,:)=wo(:,:,2) * dobson_u * 1e3 / zmasse / rmo3 * rmd
        CALL plevel_new(klon,klev,nlevSTD,.false.,pplay,rlevSTD,
     &             zx_tmp_fi3d,O3daySTD)
      endif
c
        DO l=1, klev
        DO i=1, klon
         zx_tmp_fi3d(i,l)=paprs(i,l)
        ENDDO !i
        ENDDO !l
        CALL plevel_new(klon,klev,nlevSTD,.true.,zx_tmp_fi3d,rlevSTD,
     &             omega,wlevSTD)
c
cIM on somme les valeurs toutes les freq_calNMC secondes
c
       CALL undefSTD(itap,freq_calNMC, read_climoz)
c
cIM on moyenne a la fin du mois ou du jour (toutes les freq_outNMC secondes)
c
       CALL moy_undefSTD(itap,freq_outNMC,freq_moyNMC)
c
       CALL plevel(klon,klev,.true.,pplay,50000.,
     &              zphi/RG,geo500)

cIM on interpole a chaque pas de temps le SWup(clr) et SWdn(clr) a 200 hPa
c
      CALL plevel(klon,klevp1,.true.,paprs,20000.,
     $     swdn0,SWdn200clr)
      CALL plevel(klon,klevp1,.false.,paprs,20000.,
     $     swdn,SWdn200)
      CALL plevel(klon,klevp1,.false.,paprs,20000.,
     $     swup0,SWup200clr)
      CALL plevel(klon,klevp1,.false.,paprs,20000.,
     $     swup,SWup200)
c
      CALL plevel(klon,klevp1,.false.,paprs,20000.,
     $     lwdn0,LWdn200clr)
      CALL plevel(klon,klevp1,.false.,paprs,20000.,
     $     lwdn,LWdn200)
      CALL plevel(klon,klevp1,.false.,paprs,20000.,
     $     lwup0,LWup200clr)
      CALL plevel(klon,klevp1,.false.,paprs,20000.,
     $     lwup,LWup200)
c
      twriteSTD(:,:,1)=tsumSTD(:,:,1)
      qwriteSTD(:,:,1)=qsumSTD(:,:,1)
      rhwriteSTD(:,:,1)=rhsumSTD(:,:,1)
      phiwriteSTD(:,:,1)=phisumSTD(:,:,1)
      uwriteSTD(:,:,1)=usumSTD(:,:,1)
      vwriteSTD(:,:,1)=vsumSTD(:,:,1)
      wwriteSTD(:,:,1)=wsumSTD(:,:,1)

      twriteSTD(:,:,2)=tsumSTD(:,:,2)
      qwriteSTD(:,:,2)=qsumSTD(:,:,2)
      rhwriteSTD(:,:,2)=rhsumSTD(:,:,2)
      phiwriteSTD(:,:,2)=phisumSTD(:,:,2)
      uwriteSTD(:,:,2)=usumSTD(:,:,2)
      vwriteSTD(:,:,2)=vsumSTD(:,:,2)
      wwriteSTD(:,:,2)=wsumSTD(:,:,2)

      twriteSTD(:,:,3)=tlevSTD(:,:)
      qwriteSTD(:,:,3)=qlevSTD(:,:)
      rhwriteSTD(:,:,3)=rhlevSTD(:,:)
      phiwriteSTD(:,:,3)=philevSTD(:,:)
      uwriteSTD(:,:,3)=ulevSTD(:,:)
      vwriteSTD(:,:,3)=vlevSTD(:,:)
      wwriteSTD(:,:,3)=wlevSTD(:,:)

      twriteSTD(:,:,4)=tlevSTD(:,:)
      qwriteSTD(:,:,4)=qlevSTD(:,:)
      rhwriteSTD(:,:,4)=rhlevSTD(:,:)
      phiwriteSTD(:,:,4)=philevSTD(:,:)
      uwriteSTD(:,:,4)=ulevSTD(:,:)
      vwriteSTD(:,:,4)=vlevSTD(:,:)
      wwriteSTD(:,:,4)=wlevSTD(:,:)
c
cIM initialisation 5eme fichier de sortie 
      twriteSTD(:,:,5)=tlevSTD(:,:)
      qwriteSTD(:,:,5)=qlevSTD(:,:)
      rhwriteSTD(:,:,5)=rhlevSTD(:,:)
      phiwriteSTD(:,:,5)=philevSTD(:,:)
      uwriteSTD(:,:,5)=ulevSTD(:,:)
      vwriteSTD(:,:,5)=vlevSTD(:,:)
      wwriteSTD(:,:,5)=wlevSTD(:,:)
c
cIM initialisation 6eme fichier de sortie 
      twriteSTD(:,:,6)=tlevSTD(:,:)
      qwriteSTD(:,:,6)=qlevSTD(:,:)
      rhwriteSTD(:,:,6)=rhlevSTD(:,:)
      phiwriteSTD(:,:,6)=philevSTD(:,:)
      uwriteSTD(:,:,6)=ulevSTD(:,:)
      vwriteSTD(:,:,6)=vlevSTD(:,:)
      wwriteSTD(:,:,6)=wlevSTD(:,:)
cIM for NMC files
      DO n=1, nlevSTD3
       DO k=1, nlevSTD
        if(rlevSTD3(n).EQ.rlevSTD(k)) THEN
         twriteSTD3(:,n)=tlevSTD(:,k)
         qwriteSTD3(:,n)=qlevSTD(:,k)
         rhwriteSTD3(:,n)=rhlevSTD(:,k)
         phiwriteSTD3(:,n)=philevSTD(:,k)
         uwriteSTD3(:,n)=ulevSTD(:,k)
         vwriteSTD3(:,n)=vlevSTD(:,k)
         wwriteSTD3(:,n)=wlevSTD(:,k)
        endif !rlevSTD3(n).EQ.rlevSTD(k)
       ENDDO 
      ENDDO 
c
      DO n=1, nlevSTD8
       DO k=1, nlevSTD
        if(rlevSTD8(n).EQ.rlevSTD(k)) THEN
         tnondefSTD8(:,n)=tnondef(:,k,2)
         twriteSTD8(:,n)=tsumSTD(:,k,2)
         qwriteSTD8(:,n)=qsumSTD(:,k,2)
         rhwriteSTD8(:,n)=rhsumSTD(:,k,2)
         phiwriteSTD8(:,n)=phisumSTD(:,k,2)
         uwriteSTD8(:,n)=usumSTD(:,k,2)
         vwriteSTD8(:,n)=vsumSTD(:,k,2)
         wwriteSTD8(:,n)=wsumSTD(:,k,2)
        endif !rlevSTD8(n).EQ.rlevSTD(k)
       ENDDO 
      ENDDO