Changeset 2848 for LMDZ5

Timestamp:

Apr 13, 2017, 7:07:54 PM (8 years ago)

Author:

jyg

Message:

Changes in module add_phys_tend_mod.F90: (i)
vertical integrations are performed in subroutine
integr_v; (ii) the new subroutine diag_phys_tend
makes it possible to check water and energy
conservation of a set of tendencies added to any
atmospheric state.

File:

• LMDZ5/trunk/libf/phylmd/add_phys_tend_mod.F90 (modified) (4 diffs)

LMDZ5/trunk/libf/phylmd/add_phys_tend_mod.F90

@@ -223 +223 @@
 
   if (fl_ebil .GT. 0) then
-  ! Reset variables
-    zqw_col(:,:) = 0.
-    zql_col(:,:) = 0.
-    zqs_col(:,:) = 0.
-    zek_col(:,:) = 0.
-    zh_dair_col(:,:) = 0.
-    zh_qw_col(:,:) = 0.
-    zh_ql_col(:,:) = 0.
-    zh_qs_col(:,:) = 0.
+    ! ------------------------------------------------
+    ! Compute vertical sum for each atmospheric column
+    ! ------------------------------------------------
+    n=1   ! begining of time step
 
     zcpvap = rcpv
     zcwat = rcw
     zcice = rcs
-!JLD    write (*,*) "rcpd, zcpvap, zcwat, zcice ",rcpd, zcpvap, zcwat, zcice
-  
-    ! ------------------------------------------------
-    ! Compute vertical sum for each atmospheric column
-    ! ------------------------------------------------
-    n=1   ! begining of time step
-    DO k = 1, klev
-      DO i = 1, klon
-        ! Watter mass
-        zqw_col(i,n) = zqw_col(i,n) + q_seri(i, k)*zairm(i, k)
-        zql_col(i,n) = zql_col(i,n) + ql_seri(i, k)*zairm(i, k)
-        zqs_col(i,n) = zqs_col(i,n) + qs_seri(i, k)*zairm(i, k)
-        ! Kinetic Energy
-        zek_col(i,n) = zek_col(i,n) + 0.5*(u_seri(i,k)**2+v_seri(i,k)**2)*zairm(i, k)
-        ! Air enthalpy : dry air, water vapour, liquid, solid
-        zh_dair_col(i,n) = zh_dair_col(i,n) + rcpd*(1.-q_seri(i,k)-ql_seri(i,k)-qs_seri(i,k))* &
-          zairm(i, k)*t_seri(i, k)
-        zh_qw_col(i,n) = zh_qw_col(i,n) +  zcpvap*t_seri(i, k)         *q_seri(i, k)*zairm(i, k)    !jyg
-        zh_ql_col(i,n) = zh_ql_col(i,n) + (zcpvap*t_seri(i, k) - rlvtt)*ql_seri(i, k)*zairm(i, k)   !jyg
-        zh_qs_col(i,n) = zh_qs_col(i,n) + (zcpvap*t_seri(i, k) - rlstt)*qs_seri(i, k)*zairm(i, k)   !jyg
-      END DO
-    END DO
-    ! compute total air enthalpy
-    zh_col(:,n) = zh_dair_col(:,n) + zh_qw_col(:,n) + zh_ql_col(:,n) + zh_qs_col(:,n)
+
+    CALL integr_v(klon, klev, zcpvap, &
+                  t_seri, q_seri, ql_seri, qs_seri, u_seri, v_seri, zairm, &
+                    zqw_col(:,n), zql_col(:,n), zqs_col(:,n), zek_col(:,n), zh_dair_col(:,n), &
+                    zh_qw_col(:,n), zh_ql_col(:,n), zh_qs_col(:,n), zh_col(:,n))
 
   end if ! end if (fl_ebil .GT. 0)
@@ -465 +441 @@
     ! ------------------------------------------------
     n=2   ! end of time step
-    DO k = 1, klev
-      DO i = 1, klon
-        ! Watter mass
-        zqw_col(i,n) = zqw_col(i,n) + q_seri(i, k)*zairm(i, k)
-        zql_col(i,n) = zql_col(i,n) + ql_seri(i, k)*zairm(i, k)
-        zqs_col(i,n) = zqs_col(i,n) + qs_seri(i, k)*zairm(i, k)
-        ! Kinetic Energy
-        zek_col(i,n) = zek_col(i,n) + 0.5*(u_seri(i,k)**2+v_seri(i,k)**2)*zairm(i, k)
-        ! Air enthalpy : dry air, water vapour, liquid, solid
-        zh_dair_col(i,n) = zh_dair_col(i,n) + rcpd*(1.-q_seri(i,k)-ql_seri(i,k)-qs_seri(i,k))* &
-          zairm(i, k)*t_seri(i, k)
-        zh_qw_col(i,n) = zh_qw_col(i,n) +  zcpvap*t_seri(i, k)         *q_seri(i, k)*zairm(i, k)     !jyg
-        zh_ql_col(i,n) = zh_ql_col(i,n) + (zcpvap*t_seri(i, k) - rlvtt)*ql_seri(i, k)*zairm(i, k)    !jyg
-        zh_qs_col(i,n) = zh_qs_col(i,n) + (zcpvap*t_seri(i, k) - rlstt)*qs_seri(i, k)*zairm(i, k)    !jyg
-      END DO
-    END DO
-    ! compute total air enthalpy
-    zh_col(:,n) = zh_dair_col(:,n) + zh_qw_col(:,n) + zh_ql_col(:,n) + zh_qs_col(:,n)
+
+    CALL integr_v(klon, klev, zcpvap, &
+                  t_seri, q_seri, ql_seri, qs_seri, u_seri, v_seri, zairm, &
+                    zqw_col(:,n), zql_col(:,n), zqs_col(:,n), zek_col(:,n), zh_dair_col(:,n), &
+                    zh_qw_col(:,n), zh_ql_col(:,n), zh_qs_col(:,n), zh_col(:,n))
 
     ! ------------------------------------------------
@@ -517 +480 @@
   RETURN
 END SUBROUTINE add_phys_tend
+
+SUBROUTINE diag_phys_tend (nlon, nlev, uu, vv, temp, qv, ql, qs, &
+                          zdu,zdv,zdt,zdq,zdql,zdqs,paprs,text)
+!======================================================================
+! Ajoute les tendances des variables physiques aux variables 
+! d'etat de la dynamique t_seri, q_seri ...
+! On en profite pour faire des tests sur les tendances en question.
+!======================================================================
+
+
+!======================================================================
+! Declarations
+!======================================================================
+
+USE phys_state_var_mod, ONLY : dtime, ftsol
+USE geometry_mod, ONLY: longitude_deg, latitude_deg
+USE print_control_mod, ONLY: prt_level
+USE cmp_seri_mod
+USE phys_output_var_mod, ONLY : d_qw_col, d_ql_col, d_qs_col, d_qt_col, d_ek_col, d_h_dair_col &
+  &           , d_h_qw_col, d_h_ql_col, d_h_qs_col, d_h_col
+IMPLICIT none
+  include "YOMCST.h"
+  include "clesphys.h"
+
+! Arguments :
+!------------
+INTEGER, INTENT(IN)                           :: nlon, nlev
+REAL, DIMENSION(nlon,nlev),     INTENT(IN)    :: uu, vv
+REAL, DIMENSION(nlon,nlev),     INTENT(IN)    :: temp, qv, ql, qs
+REAL, DIMENSION(nlon,nlev),     INTENT(IN)    :: zdu, zdv
+REAL, DIMENSION(nlon,nlev),     INTENT(IN)    :: zdt, zdq, zdql, zdqs
+REAL, DIMENSION(nlon,nlev+1),   INTENT(IN)    :: paprs
+CHARACTER*(*),                  INTENT(IN)    :: text
+
+! Local :
+!--------
+REAL, DIMENSION(nlon,nlev)      :: uu_n, vv_n
+REAL, DIMENSION(nlon,nlev)      :: temp_n, qv_n, ql_n, qs_n
+
+
+!
+INTEGER k, n
+
+integer debug_level
+logical, save :: first=.true.
+!$OMP THREADPRIVATE(first)
+!
+!======================================================================
+! Variables for energy conservation tests
+!======================================================================
+!
+
+! zh_col-------  total enthalpy of vertical air column
+! (air with watter vapour, liquid and solid) (J/m2)
+! zh_dair_col--- total enthalpy of dry air (J/m2)
+! zh_qw_col----  total enthalpy of watter vapour (J/m2)
+! zh_ql_col----  total enthalpy of liquid watter (J/m2)
+! zh_qs_col----  total enthalpy of solid watter  (J/m2)
+! zqw_col------  total mass of watter vapour (kg/m2)
+! zql_col------  total mass of liquid watter (kg/m2)
+! zqs_col------  total mass of solid watter (kg/m2)
+! zek_col------  total kinetic energy (kg/m2)
+!
+REAL zairm(nlon, nlev) ! layer air mass (kg/m2)
+REAL zqw_col(nlon,2)
+REAL zql_col(nlon,2)
+REAL zqs_col(nlon,2)
+REAL zek_col(nlon,2)
+REAL zh_dair_col(nlon,2)
+REAL zh_qw_col(nlon,2), zh_ql_col(nlon,2), zh_qs_col(nlon,2)
+REAL zh_col(nlon,2)
+
+!======================================================================
+! Initialisations
+
+     IF (prt_level >= 5) then
+        write (*,*) "In diag_phys_tend, after ",text
+        call flush
+     end if
+
+     debug_level=10
+     if (first) then
+        print *,"TestJLD rcpv, rcw, rcs",rcpv, rcw, rcs
+        first=.false.
+     endif
+!
+!  print *,'add_phys_tend: paprs ',paprs
+!======================================================================
+! Diagnostics for energy conservation tests
+!======================================================================
+  DO k = 1, nlev
+    ! layer air mass
+    zairm(:, k) = (paprs(:,k)-paprs(:,k+1))/rg
+  END DO
+
+  if (fl_ebil .GT. 0) then
+    ! ------------------------------------------------
+    ! Compute vertical sum for each atmospheric column
+    ! ------------------------------------------------
+    n=1   ! begining of time step
+
+    CALL integr_v(nlon, nlev, rcpv, &
+                  temp, qv, ql, qs, uu, vv, zairm, &
+                    zqw_col(:,n), zql_col(:,n), zqs_col(:,n), zek_col(:,n), zh_dair_col(:,n), &
+                    zh_qw_col(:,n), zh_ql_col(:,n), zh_qs_col(:,n), zh_col(:,n))
+
+  end if ! end if (fl_ebil .GT. 0)
+
+!======================================================================
+! Ajout des tendances sur le vent, la temperature et les diverses phases de l'eau
+!======================================================================
+
+     uu_n(:,:)=uu(:,:)+zdu(:,:)
+     vv_n(:,:)=vv(:,:)+zdv(:,:)
+     qv_n(:,:)=qv(:,:)+zdq(:,:)
+     ql_n(:,:)=ql(:,:)+zdql(:,:)
+     qs_n(:,:)=qs(:,:)+zdqs(:,:)
+     temp_n(:,:)=temp(:,:)+zdt(:,:)
+
+
+
+!======================================================================
+! Diagnostics for energy conservation tests
+!======================================================================
+
+  if (fl_ebil .GT. 0) then
+  
+    ! ------------------------------------------------
+    ! Compute vertical sum for each atmospheric column
+    ! ------------------------------------------------
+    n=2   ! end of time step
+
+    CALL integr_v(nlon, nlev, rcpv, &
+                  temp_n, qv_n, ql_n, qs_n, uu_n, vv_n, zairm, &
+                    zqw_col(:,n), zql_col(:,n), zqs_col(:,n), zek_col(:,n), zh_dair_col(:,n), &
+                    zh_qw_col(:,n), zh_ql_col(:,n), zh_qs_col(:,n), zh_col(:,n))
+
+    ! ------------------------------------------------
+    ! Compute the changes by unit of time
+    ! ------------------------------------------------
+
+    d_qw_col(:) = (zqw_col(:,2)-zqw_col(:,1))/dtime
+    d_ql_col(:) = (zql_col(:,2)-zql_col(:,1))/dtime
+    d_qs_col(:) = (zqs_col(:,2)-zqs_col(:,1))/dtime
+    d_qt_col(:) = d_qw_col(:) + d_ql_col(:) + d_qs_col(:)
+
+    d_ek_col(:) = (zek_col(:,2)-zek_col(:,1))/dtime
+
+   print *,'zdu ', zdu
+   print *,'zdv ', zdv
+   print *,'d_ek_col, zek_col(2), zek_col(1) ',d_ek_col(1), zek_col(1,2), zek_col(1,1)
+
+    d_h_dair_col(:) = (zh_dair_col(:,2)-zh_dair_col(:,1))/dtime
+    d_h_qw_col(:) = (zh_qw_col(:,2)-zh_qw_col(:,1))/dtime
+    d_h_ql_col(:) = (zh_ql_col(:,2)-zh_ql_col(:,1))/dtime
+    d_h_qs_col(:) = (zh_qs_col(:,2)-zh_qs_col(:,1))/dtime
+
+    d_h_col = (zh_col(:,2)-zh_col(:,1))/dtime 
+
+  end if ! end if (fl_ebil .GT. 0)
+!
+
+  RETURN
+END SUBROUTINE diag_phys_tend
+
+SUBROUTINE integr_v(nlon, nlev, zcpvap, &
+                    temp, qv, ql, qs, uu, vv, zairm,  &
+                    zqw_col, zql_col, zqs_col, zek_col, zh_dair_col, &
+                    zh_qw_col, zh_ql_col, zh_qs_col, zh_col)
+
+IMPLICIT none
+  include "YOMCST.h"
+
+INTEGER,                    INTENT(IN)    :: nlon,nlev
+REAL,                       INTENT(IN)    :: zcpvap
+REAL, DIMENSION(nlon,nlev), INTENT(IN)    :: temp, qv, ql, qs, uu, vv
+REAL, DIMENSION(nlon,nlev), INTENT(IN)    :: zairm
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zqw_col
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zql_col
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zqs_col
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zek_col
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zh_dair_col
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zh_qw_col
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zh_ql_col
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zh_qs_col
+REAL, DIMENSION(nlon),      INTENT(OUT)   :: zh_col
+
+INTEGER          :: i, k
+
+
+  ! Reset variables
+    zqw_col(:) = 0.
+    zql_col(:) = 0.
+    zqs_col(:) = 0.
+    zek_col(:) = 0.
+    zh_dair_col(:) = 0.
+    zh_qw_col(:) = 0.
+    zh_ql_col(:) = 0.
+    zh_qs_col(:) = 0.
+
+!JLD    write (*,*) "rcpd, zcpvap, zcwat, zcice ",rcpd, zcpvap, zcwat, zcice
+  
+    ! ------------------------------------------------
+    ! Compute vertical sum for each atmospheric column
+    ! ------------------------------------------------
+    DO k = 1, nlev
+      DO i = 1, nlon
+        ! Watter mass
+        zqw_col(i) = zqw_col(i) + qv(i, k)*zairm(i, k)
+        zql_col(i) = zql_col(i) + ql(i, k)*zairm(i, k)
+        zqs_col(i) = zqs_col(i) + qs(i, k)*zairm(i, k)
+        ! Kinetic Energy
+        zek_col(i) = zek_col(i) + 0.5*(uu(i,k)**2+vv(i,k)**2)*zairm(i, k)
+        ! Air enthalpy : dry air, water vapour, liquid, solid
+        zh_dair_col(i) = zh_dair_col(i) + rcpd*(1.-qv(i,k)-ql(i,k)-qs(i,k))* &
+                                               zairm(i, k)*temp(i, k)
+        zh_qw_col(i) = zh_qw_col(i) +  zcpvap*temp(i, k)         *qv(i, k)*zairm(i, k)    !jyg
+        zh_ql_col(i) = zh_ql_col(i) + (zcpvap*temp(i, k) - rlvtt)*ql(i, k)*zairm(i, k)   !jyg
+        zh_qs_col(i) = zh_qs_col(i) + (zcpvap*temp(i, k) - rlstt)*qs(i, k)*zairm(i, k)   !jyg
+      END DO
+    END DO
+    ! compute total air enthalpy
+    zh_col(:) = zh_dair_col(:) + zh_qw_col(:) + zh_ql_col(:) + zh_qs_col(:)
+
+END SUBROUTINE integr_v
 
 SUBROUTINE prt_enerbil (text, itap)
@@ -624 +812 @@
       write(*,9000) text,"enerbil: snow, bil_lat, bil_sens", snow_lsc(1), rlstt * snow_lsc(1), -(rcs-rcpd)*t_seri(1,1) * snow_lsc(1)
     end if
+  CASE("convection") specific_diag
+    if ( prt_level .GE. 5) then
+      write(*,9000) text,"enerbil: rain, bil_lat, bil_sens", rain_con(1), rlvtt * rain_con(1), -(rcw-rcpd)*t_seri(1,1) * rain_con(1)
+      write(*,9000) text,"enerbil: snow, bil_lat, bil_sens", snow_con(1), rlstt * snow_con(1), -(rcs-rcpd)*t_seri(1,1) * snow_con(1)
+    end if
   END SELECT specific_diag
 
-9000 format (1x,A8,2x,A30,10E15.6)
+9000 format (1x,A8,2x,A35,10E15.6)
 
 end if ! end if (fl_ebil .GT. 0)