pkg/fizhi/fizhi_step_diag.F

C $Header:  $
C $Name:  $
                                                                                       
#include "CPP_OPTIONS.h"
      subroutine fizhi_step_diag(myThid,p,uphy,vphy,thphy,sphy,qq,
     .  radswt,radswg,swgclr,osr,osrclr,st4,dst4,tgz,tg0,radlwg,lwgclr,
     .  turbu,turbv,turbt,turbq,moistu,moistv,moistt,moistq,
     .  lwdt,swdt,lwdtclr,swdtclr,im1,im2,jm1,jm2,Nrphys,Nsx,Nsy,bi,bj)
C***********************************************************************
      implicit none

#include "diagnostics.h"

      integer myThid,im1,im2,jm1,jm2,Nrphys,Nsx,Nsy,bi,bj
      real radswt(im2,jm2)

      integer  i,j,L,m
      real getcon
      real cp, pstd, tstd, akap, pkstd, thstd, grav, delp

      cp = getcon('CP')
      pstd = getcon('PSTD')
      tstd = getcon('TSTD')
      akap = getcon('KAPPA')
      pkstd = pstd**akap
      thstd = tstd/pkstd
      grav = getcon('GRAVITY')

C **********************************************************************        
C ****                  Compute 2-D Diagnostics                     ****        
C **********************************************************************        
                                                                                
      do j=jm1,jm2
      do i=im1,im2
      pinv(i,j) = 1.0 / p(i,j)                                    
      enddo                                                             
      enddo                                                             

c Analysis Increment of Surface Pressure (mb/day)
c -----------------------------------------------
      if( ipiau.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ipiau) = qdiag(i,j,ipiau) + tend%iau%dp(i,j)*86400
      enddo
      enddo
      endif
                                                                  
c Incident Solar Radiation (W/m**2)
c ---------------------------------
      if (iradswt.ne.0) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iradswt) = qdiag(i,j,iradswt) + radswt(i,j)
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Net Solar Radiation at the Ground (W/m**2)
c ------------------------------------------
      if (iradswg.ne.0) then                                                    
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iradswg) = qdiag(i,j,iradswg) + coup%sw%radswg(i,j)*radswt(i,j)         
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Net Clear Sky Solar Radiation at the Ground (W/m**2)
c ----------------------------------------------------
      if (iswgclr.ne.0) then                                                    
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iswgclr) = qdiag(i,j,iswgclr) + coup%sw%swgclr(i,j)*radswt(i,j)         
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Outgoing Solar Radiation at Ptop (W/m**2)
c -----------------------------------------
      if (iosr.ne.0) then                                                    
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iosr) = qdiag(i,j,iosr) + (1.0-coup%sw%osr(i,j))*radswt(i,j)         
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Outgoing Clear Sky Solar Radiation at Ptop (W/m**2)
c ---------------------------------------------------
      if (iosrclr.ne.0) then                                                    
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iosrclr) = qdiag(i,j,iosrclr) + (1.0-coup%sw%osrclr(i,j))*radswt(i,j)         
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Upward Longwave Flux at the Ground (W/m**2)
c -------------------------------------------
      if (ilwgup.ne.0) then                                                    
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ilwgup) =  qdiag(i,j,ilwgup) + coup%lw%st4(i,j) 
     .                   +   coup%lw%dst4(i,j)*(coup%land%tgz(i,j)-coup%lw%tg0(i,j))
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Net Longwave Flux at the Ground (W/m**2)
c ----------------------------------------
      if (iradlwg.ne.0) then                                                    
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iradlwg) =  qdiag(i,j,iradlwg) + coup%lw%radlwg(i,j) 
     .                   +   coup%lw%dst4(i,j)*(coup%land%tgz(i,j)-coup%lw%tg0(i,j))
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Net Longwave Flux at the Ground Clear Sky (W/m**2)
c --------------------------------------------------
      if (ilwgclr.ne.0) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ilwgclr) =  qdiag(i,j,ilwgclr) + coup%lw%lwgclr(i,j) 
     .                   +   coup%lw%dst4(i,j)*(coup%land%tgz(i,j)-coup%lw%tg0(i,j))
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Total Surface Pressure Tendency (mb/day)
c ----------------------------------------
      if( idpdt.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idpdt) = qdiag(i,j,idpdt) + (updt%p(i,j)-curr%p(i,j))*fact
      enddo
      enddo
      endif
                                                                  
c Averaged P-Field (mb)
c ---------------------
      if( ips.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ips) = qdiag(i,j,ips) + curr%p(i,j)+ptop
      enddo
      enddo
      endif

c Averaged SLP-Field (mb)
c ----------------------
      if( islp.ne.0 ) then
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      tmp2(i,j,L) = curr%t(i,j,L) * (1.+0.609*curr%q(i,j,L,1))
      enddo
      enddo
      enddo
      call slprs ( tmp1(1,1,2),curr%p,ptop,coup%earth%phis_cmp,tmp2,dsig,coup%earth%lw_cmp,im,jm,lm )
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,islp) = qdiag(i,j,islp) + tmp1(i,j,2)
      enddo
      enddo
      endif

      npiau   = npiau   + 1
      nradswt = nradswt + 1                                                     
      nradswg = nradswg + 1                                                     
      nswgclr = nswgclr + 1                                                     
      nosr    = nosr    + 1
      nosrclr = nosrclr + 1
      nradlwg = nradlwg + 1
      nlwgclr = nlwgclr + 1
      nlwgup  = nlwgup  + 1
      ndpdt   = ndpdt   + 1                                              
      nps     = nps     + 1
      nslp    = nslp    + 1
                                                                                
C **********************************************************************        
C ****                  Compute 3-D Diagnostics                     ****        
C **********************************************************************        
                                                                                
      do L=1,Nrphys

      if( itiau.ne.0 .or. ivavetiau.ne.0 .or. idiabt.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      dtiau(i,j,L) = ( tend%iau%dt(i,j,L) + curr%t(i,j,L)*tend%iau%dp(i,j)
     .               * ( sig(L)*akap*curr%p(i,j)/(sig(L)*curr%p(i,j)+ptop) - 1.0) )
      enddo
      enddo
      endif

      if( iqiau.ne.0 .or. ivaveqiau.ne.0 .or. idiabq.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      dqiau(i,j,L) = tend%iau%dq(i,j,L) - curr%q(i,j,L,1)*tend%iau%dp(i,j)
      enddo
      enddo
      endif

c Total Diabatic U-Tendency (m/sec/day)
c -------------------------------------
      if( idiabu.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idiabu+L-1) =   qdiag  (i,j,idiabu+L-1)
     .                      + ( tend%iau%du (i,j,L)
     .                        + tend%turb%du(i,j,L) )*86400
      enddo
      enddo
      endif
                                                                  
c Total Diabatic V-Tendency (m/sec/day)
c -------------------------------------
      if( idiabv.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idiabv+L-1) =   qdiag  (i,j,idiabv+L-1)
     .                      + ( tend%iau%dv (i,j,L)
     .                        + tend%turb%dv(i,j,L) )*86400
      enddo
      enddo
      endif

c Total Diabatic T-Tendency (deg/day)
c -----------------------------------
      if( idiabt.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idiabt+L-1) =   qdiag(i,j,idiabt+L-1) 
     .                      + ( dtiau(i,j,L) + tend%turb%dt(i,j,L) + tend%lw%dt(i,j,L)
     .                        + coup%lw%dlwdtg(i,j,L)*(coup%land%tgc(i,j)-coup%lw%tg0c(i,j))
     .                        + tend%sw%dt(i,j,L)*radswc(i,j) 
     .                        + tend%moist%dt(i,j,L) )
     .                        * pkn(i,j,L)*pinv(i,j)*86400
      enddo
      enddo
      endif
                                                                  
c Total Diabatic Q-Tendency (g/kg/day)
c ------------------------------------
      if( idiabq.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idiabq+L-1) =   qdiag(i,j,idiabq+L-1)
     .                      + ( dqiau(i,j,L) + tend%turb%dq(i,j,L,1) + tend%moist%dq(i,j,L,1) )
     .                      *    pinv(i,j)*86400*1000
      enddo
      enddo
      endif
    
c Analysis U-Wind Increment (m/sec/day)
c -------------------------------------
      if( iuiau.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iuiau+L-1) = qdiag (i,j,iuiau+L-1) + tend%iau%du(i,j,L)*86400
      enddo
      enddo
      endif

c Analysis V-Wind Increment (m/sec/day)
c -------------------------------------
      if( iviau.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iviau+L-1) = qdiag (i,j,iviau+L-1) + tend%iau%dv(i,j,L)*86400
      enddo
      enddo
      endif

c Analysis Temperature Tendency (deg/day)
c ---------------------------------------
      if( itiau.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,itiau+L-1) = qdiag(i,j,itiau+L-1)
     .                     + dtiau(i,j,L) * pkn(i,j,L)*pinv(i,j)*86400
      enddo
      enddo
      endif
                                                                  
c Analysis Moisture Tendency (g/kg/day)
c -------------------------------------
      if( iqiau.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iqiau+L-1) = qdiag(i,j,iqiau+L-1)
     .                     + dqiau(i,j,L) * pinv(i,j)*86400*1000
      enddo
      enddo
      endif
    
c Longwave Heating (deg/day)
c --------------------------
      if (iradlw.ne.0) then                                                     
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iradlw+l-1) = qdiag(i,j,iradlw+l-1)
     .                      + ( tend%lw%dt(i,j,l)
     .                      +   coup%lw%dlwdtg (i,j,L)*(coup%land%tgc(i,j)-coup%lw%tg0c(i,j)))
     .                      * pkn(i,j,l)*pinv(i,j)*86400
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Longwave Heating Clear-Sky (deg/day)
c ------------------------------------
      if (ilwclr.ne.0) then                                                     
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ilwclr+l-1) = qdiag(i,j,ilwclr+l-1)
     .                      + ( tend%lw%dtclr(i,j,l)
     .                      +   coup%lw%dlwdtg(i,j,L)*(coup%land%tgc(i,j)-coup%lw%tg0c(i,j)))
     .                      * pkn(i,j,l)*pinv(i,j)*86400
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Solar Radiative Heating (deg/day)
c ---------------------------------
      if (iradsw.ne.0) then                                                     
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iradsw+l-1) = qdiag(i,j,iradsw+l-1)
     .                      + tend%sw%dt(i,j,l)*radswc(i,j)                        
     .                      * pkn(i,j,l)*pinv(i,j)*86400
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Clear Sky Solar Radiative Heating (deg/day)
c -------------------------------------------
      if (iswclr.ne.0) then                                                     
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iswclr+l-1) = qdiag(i,j,iswclr+l-1)
     .                      + tend%sw%dtclr(i,j,l)*radswc(i,j)                        
     .                      * pkn(i,j,l)*pinv(i,j)*86400
      enddo                                                                     
      enddo                                                                     
      endif                                                                     
                                                                                
c Total U-Tendency (m/sec/day)
c ----------------------------
      if( idudt.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idudt+L-1) =  qdiag(i,j,idudt+L-1) 
     .                     + ( updt%u(i,j,L)-curr%u(i,j,L) )*fact
      enddo
      enddo
      endif
                                                                  
c Total V-Tendency (m/sec/day)
c ----------------------------
      if( idvdt.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idvdt+L-1) =  qdiag(i,j,idvdt+L-1) 
     .                     + ( updt%v(i,j,L)-curr%v(i,j,L) )*fact
      enddo
      enddo
      endif

c Total T-Tendency (deg/day)
c --------------------------
      if( idtdt.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idtdt+L-1) =  qdiag(i,j,idtdt+L-1)
     .                     + ( updt%t(i,j,L)*pknp1(i,j,L) - curr%t(i,j,L)*pkn(i,j,L) )*fact
      enddo
      enddo
      endif

c Total Q-Tendency (g/kg/day)
c ---------------------------
      if( idqdt.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,idqdt+L-1) =  qdiag(i,j,idqdt+L-1)
     .                     + ( updt%q(i,j,L,1)-curr%q(i,j,L,1) )*fact*1000
      enddo
      enddo
      endif

c Averaged U-Field (m/sec)
c ------------------------
      if( iuwnd.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iuwnd+L-1) = qdiag(i,j,iuwnd+L-1) + curr%u(i,j,L)
      enddo
      enddo
      endif

c Averaged V-Field (m/sec)
c ------------------------
      if( ivwnd.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivwnd+L-1) = qdiag(i,j,ivwnd+L-1) + curr%v(i,j,L)
      enddo
      enddo
      endif

c Averaged T-Field (deg)
c ----------------------
      if( itmpu.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,itmpu+L-1) = qdiag(i,j,itmpu+L-1) + curr%t(i,j,L)*pkn(i,j,L)
      enddo
      enddo
      endif
                                                                                
c Averaged QQ-Field (m/sec)**2
c ----------------------------
      if( itke.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,itke+L-1) = qdiag(i,j,itke+L-1) + coup%turb%qq(i,j,L)
      enddo
      enddo
      endif
                                                                                
c Averaged Q-Field (g/kg)
c -----------------------
      if( isphu.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,isphu+L-1) = qdiag(i,j,isphu+L-1) + curr%q(i,j,L,1)*1000
      enddo
      enddo
      endif
                                                                                
      enddo   ! End Level Loop

      ndiabu = ndiabu + 1
      ndiabv = ndiabv + 1
      ndiabt = ndiabt + 1
      nuiau  = nuiau  + 1
      nviau  = nviau  + 1
      ntiau  = ntiau  + 1
      nradlw = nradlw + 1                                                     
      nlwclr = nlwclr + 1                                                     
      nradsw = nradsw + 1                                                     
      nswclr = nswclr + 1                                                     
      ndudt  = ndudt  + 1                                              
      ndvdt  = ndvdt  + 1                                              
      ndtdt  = ndtdt  + 1                                              
      ndiabq = ndiabq + 1
      nqiau  = nqiau  + 1
      ndqdt  = ndqdt  + 1                                              
      nuwnd  = nuwnd  + 1
      nvwnd  = nvwnd  + 1                           
      ntmpu  = ntmpu  + 1                           
      ntke   = ntke   + 1
      nsphu  = nsphu  + 1

C **********************************************************************        
C ****         Compute Vertically Integrated Diagnostics            ****        
C **********************************************************************        

c Compute Moisture and Temperature Convergence Diagnostic
c -------------------------------------------------------
      if( ivaveut.ne.0 .or. ivavevt.ne.0  .or.
     .    ivaveuq.ne.0 .or. ivavevq.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      vintut(i,j) = 0.0
      vintvt(i,j) = 0.0
      vintuq(i,j) = 0.0
      vintvq(i,j) = 0.0
      enddo
      enddo
 
      call ctoa   ( curr%t,curr%t,dlam,dphi,im,jm,lm,0,grid%lattice )
      call ctoa   ( curr%q,curr%q,dlam,dphi,im,jm,lm,0,grid%lattice )
      call ctoa_winds ( curr%u,curr%v,tmp1,tmp2,dlam,dphi,im,jm,lm,grid%lattice )
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      vintut(i,j) = vintut(i,j) + tmp1(i,j,L)*curr%t(i,j,L)  *dsig(L)* pkn(i,j,L)
      vintvt(i,j) = vintvt(i,j) + tmp2(i,j,L)*curr%t(i,j,L)  *dsig(L)* pkn(i,j,L)
      vintuq(i,j) = vintuq(i,j) + tmp1(i,j,L)*curr%q(i,j,L,1)*dsig(L)
      vintvq(i,j) = vintvq(i,j) + tmp2(i,j,L)*curr%q(i,j,L,1)*dsig(L)
      enddo
      enddo
      enddo

      if( ivaveut.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivaveut) = qdiag(i,j,ivaveut) + vintut(i,j)
      enddo
      enddo
      endif
      if( ivavevt.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivavevt) = qdiag(i,j,ivavevt) + vintvt(i,j)
      enddo
      enddo
      endif
      if( ivaveuq.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivaveuq) = qdiag(i,j,ivaveuq) + vintuq(i,j)*1000
      enddo
      enddo
      endif
      if( ivavevq.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivavevq) = qdiag(i,j,ivavevq) + vintvq(i,j)*1000
      enddo
      enddo
      endif

      endif    ! End Convergence Diagnostic

c Total Precipitable Water (gm/cm**2)
c -----------------------------------
      if( itpw.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = 0.0
      enddo
      enddo
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = qbar(i,j) + curr%q(i,j,L,1)*dsig(L)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,itpw) = qdiag(i,j,itpw) + qbar(i,j)*10*curr%p(i,j)/grav
      enddo
      enddo
      endif
                                                                                
c Total Precipitable Analysis Increment (mm/day)
c ----------------------------------------------
      if( ivaveqiau.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = 0.0
      enddo
      enddo
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = qbar(i,j) + dqiau(i,j,L)*dsig(L)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivaveqiau) = qdiag(i,j,ivaveqiau) + qbar(i,j)*(100*86400/grav)
      enddo
      enddo
      endif

c Vertically Averaged Analysis Temperature Increment (K/day)
c ----------------------------------------------------------
      if( ivavetiau.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = 0.0
      enddo
      enddo
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = qbar(i,j) + dtiau(i,j,L)*pkn(i,j,l)*dsig(L)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivavetiau) = qdiag(i,j,ivavetiau) + qbar(i,j)*pinv(i,j)*86400
      enddo
      enddo
      endif

c Vertically Averaged Moist-T Increment (K/day)
c ---------------------------------------------
      if( ivdtmoist.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = 0.0
      enddo
      enddo
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = qbar(i,j) + tend%moist%dt(i,j,L)*pkn(i,j,l)*dsig(L)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivdtmoist) = qdiag(i,j,ivdtmoist) + qbar(i,j)*pinv(i,j)*86400
      enddo
      enddo
      endif

c Vertically Averaged Turb-T Increment (K/day)
c --------------------------------------------
      if( ivdtturb.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = 0.0
      enddo
      enddo
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = qbar(i,j) + tend%turb%dt(i,j,L)*pkn(i,j,l)*dsig(L)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivdtturb) = qdiag(i,j,ivdtturb) + qbar(i,j)*pinv(i,j)*86400
      enddo
      enddo
      endif

c Vertically Averaged RADLW Temperature Increment (K/day)
c -------------------------------------------------------
      if( ivdtradlw.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = 0.0
      enddo
      enddo
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = qbar(i,j) + ( tend%lw%dt(i,j,L)
     .          + coup%lw%dlwdtg(i,j,L)*(coup%land%tgc(i,j)-coup%lw%tg0c(i,j)) )*pkn(i,j,l)*dsig(L)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivdtradlw) = qdiag(i,j,ivdtradlw) + qbar(i,j)*pinv(i,j)*86400
      enddo
      enddo
      endif

c Vertically Averaged RADSW Temperature Increment (K/day)
c -------------------------------------------------------
      if( ivdtradsw.ne.0 ) then
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = 0.0
      enddo
      enddo
      do L=1,Nrphys
      do j=jm1,jm2
      do i=im1,im2
      qbar(i,j) = qbar(i,j) + tend%sw%dt(i,j,L)*pkn(i,j,l)*dsig(L)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivdtradsw) = qdiag(i,j,ivdtradsw) + qbar(i,j)*radswc(i,j)*pinv(i,j)*86400
      enddo
      enddo
      endif

      nvaveut   = nvaveut   + 1
      nvavevt   = nvavevt   + 1
      nvaveuq   = nvaveuq   + 1
      nvavevq   = nvavevq   + 1
      ntpw      = ntpw      + 1
      nvaveqiau = nvaveqiau + 1
      nvavetiau = nvavetiau + 1
      nvdtmoist = nvdtmoist + 1
      nvdtturb  = nvdtturb  + 1
      nvdtradlw = nvdtradlw + 1
      nvdtradsw = nvdtradsw + 1
 
C *****************************************************************     
C ****                  Release Workspace                      ****     
C *****************************************************************     

      deallocate (  dlam )
      deallocate (  dphi )
      deallocate (  dsig )
      deallocate (   sig )
      deallocate (  sige )

      deallocate (  pinv  )
      deallocate (  tmp1  )
      deallocate (  tmp2  )
      deallocate (   qbar )
      deallocate ( vintuq )
      deallocate ( vintvq )
      deallocate ( vintut )
      deallocate ( vintvt )
      deallocate (    pkn )
      deallocate (  pknp1 )
      deallocate (  dtiau )
      deallocate (  dqiau )

      call timeend (' step_diag')
      return
      end
1	C $Header: $
2	C $Name: $
3
4	#include "CPP_OPTIONS.h"
5	subroutine fizhi_step_diag(myThid,p,uphy,vphy,thphy,sphy,qq,
6	. radswt,radswg,swgclr,osr,osrclr,st4,dst4,tgz,tg0,radlwg,lwgclr,
7	. turbu,turbv,turbt,turbq,moistu,moistv,moistt,moistq,
8	. lwdt,swdt,lwdtclr,swdtclr,im1,im2,jm1,jm2,Nrphys,Nsx,Nsy,bi,bj)
9	C***********************************************************************
10	implicit none
11
12	#include "diagnostics.h"
13
14	integer myThid,im1,im2,jm1,jm2,Nrphys,Nsx,Nsy,bi,bj
15	real radswt(im2,jm2)
16
17	integer i,j,L,m
18	real getcon
19	real cp, pstd, tstd, akap, pkstd, thstd, grav, delp
20
21	cp = getcon('CP')
22	pstd = getcon('PSTD')
23	tstd = getcon('TSTD')
24	akap = getcon('KAPPA')
25	pkstd = pstd**akap
26	thstd = tstd/pkstd
27	grav = getcon('GRAVITY')
28
29	C **********************************************************************
30	C ** Compute 2-D Diagnostics **
31	C **********************************************************************
32
33	do j=jm1,jm2
34	do i=im1,im2
35	pinv(i,j) = 1.0 / p(i,j)
36	enddo
37	enddo
38
39	c Analysis Increment of Surface Pressure (mb/day)
40	c -----------------------------------------------
41	if( ipiau.ne.0 ) then
42	do j=jm1,jm2
43	do i=im1,im2
44	qdiag(i,j,ipiau) = qdiag(i,j,ipiau) + tend%iau%dp(i,j)*86400
45	enddo
46	enddo
47	endif
48
49	c Incident Solar Radiation (W/m**2)
50	c ---------------------------------
51	if (iradswt.ne.0) then
52	do j=jm1,jm2
53	do i=im1,im2
54	qdiag(i,j,iradswt) = qdiag(i,j,iradswt) + radswt(i,j)
55	enddo
56	enddo
57	endif
58
59	c Net Solar Radiation at the Ground (W/m**2)
60	c ------------------------------------------
61	if (iradswg.ne.0) then
62	do j=jm1,jm2
63	do i=im1,im2
64	qdiag(i,j,iradswg) = qdiag(i,j,iradswg) + coup%sw%radswg(i,j)*radswt(i,j)
65	enddo
66	enddo
67	endif
68
69	c Net Clear Sky Solar Radiation at the Ground (W/m**2)
70	c ----------------------------------------------------
71	if (iswgclr.ne.0) then
72	do j=jm1,jm2
73	do i=im1,im2
74	qdiag(i,j,iswgclr) = qdiag(i,j,iswgclr) + coup%sw%swgclr(i,j)*radswt(i,j)
75	enddo
76	enddo
77	endif
78
79	c Outgoing Solar Radiation at Ptop (W/m**2)
80	c -----------------------------------------
81	if (iosr.ne.0) then
82	do j=jm1,jm2
83	do i=im1,im2
84	qdiag(i,j,iosr) = qdiag(i,j,iosr) + (1.0-coup%sw%osr(i,j))*radswt(i,j)
85	enddo
86	enddo
87	endif
88
89	c Outgoing Clear Sky Solar Radiation at Ptop (W/m**2)
90	c ---------------------------------------------------
91	if (iosrclr.ne.0) then
92	do j=jm1,jm2
93	do i=im1,im2
94	qdiag(i,j,iosrclr) = qdiag(i,j,iosrclr) + (1.0-coup%sw%osrclr(i,j))*radswt(i,j)
95	enddo
96	enddo
97	endif
98
99	c Upward Longwave Flux at the Ground (W/m**2)
100	c -------------------------------------------
101	if (ilwgup.ne.0) then
102	do j=jm1,jm2
103	do i=im1,im2
104	qdiag(i,j,ilwgup) = qdiag(i,j,ilwgup) + coup%lw%st4(i,j)
105	. + coup%lw%dst4(i,j)*(coup%land%tgz(i,j)-coup%lw%tg0(i,j))
106	enddo
107	enddo
108	endif
109
110	c Net Longwave Flux at the Ground (W/m**2)
111	c ----------------------------------------
112	if (iradlwg.ne.0) then
113	do j=jm1,jm2
114	do i=im1,im2
115	qdiag(i,j,iradlwg) = qdiag(i,j,iradlwg) + coup%lw%radlwg(i,j)
116	. + coup%lw%dst4(i,j)*(coup%land%tgz(i,j)-coup%lw%tg0(i,j))
117	enddo
118	enddo
119	endif
120
121	c Net Longwave Flux at the Ground Clear Sky (W/m**2)
122	c --------------------------------------------------
123	if (ilwgclr.ne.0) then
124	do j=jm1,jm2
125	do i=im1,im2
126	qdiag(i,j,ilwgclr) = qdiag(i,j,ilwgclr) + coup%lw%lwgclr(i,j)
127	. + coup%lw%dst4(i,j)*(coup%land%tgz(i,j)-coup%lw%tg0(i,j))
128	enddo
129	enddo
130	endif
131
132	c Total Surface Pressure Tendency (mb/day)
133	c ----------------------------------------
134	if( idpdt.ne.0 ) then
135	do j=jm1,jm2
136	do i=im1,im2
137	qdiag(i,j,idpdt) = qdiag(i,j,idpdt) + (updt%p(i,j)-curr%p(i,j))*fact
138	enddo
139	enddo
140	endif
141
142	c Averaged P-Field (mb)
143	c ---------------------
144	if( ips.ne.0 ) then
145	do j=jm1,jm2
146	do i=im1,im2
147	qdiag(i,j,ips) = qdiag(i,j,ips) + curr%p(i,j)+ptop
148	enddo
149	enddo
150	endif
151
152	c Averaged SLP-Field (mb)
153	c ----------------------
154	if( islp.ne.0 ) then
155	do L=1,Nrphys
156	do j=jm1,jm2
157	do i=im1,im2
158	tmp2(i,j,L) = curr%t(i,j,L) * (1.+0.609*curr%q(i,j,L,1))
159	enddo
160	enddo
161	enddo
162	call slprs ( tmp1(1,1,2),curr%p,ptop,coup%earth%phis_cmp,tmp2,dsig,coup%earth%lw_cmp,im,jm,lm )
163	do j=jm1,jm2
164	do i=im1,im2
165	qdiag(i,j,islp) = qdiag(i,j,islp) + tmp1(i,j,2)
166	enddo
167	enddo
168	endif
169
170	npiau = npiau + 1
171	nradswt = nradswt + 1
172	nradswg = nradswg + 1
173	nswgclr = nswgclr + 1
174	nosr = nosr + 1
175	nosrclr = nosrclr + 1
176	nradlwg = nradlwg + 1
177	nlwgclr = nlwgclr + 1
178	nlwgup = nlwgup + 1
179	ndpdt = ndpdt + 1
180	nps = nps + 1
181	nslp = nslp + 1
182
183	C **********************************************************************
184	C ** Compute 3-D Diagnostics **
185	C **********************************************************************
186
187	do L=1,Nrphys
188
189	if( itiau.ne.0 .or. ivavetiau.ne.0 .or. idiabt.ne.0 ) then
190	do j=jm1,jm2
191	do i=im1,im2
192	dtiau(i,j,L) = ( tend%iau%dt(i,j,L) + curr%t(i,j,L)*tend%iau%dp(i,j)
193	. * ( sig(L)akapcurr%p(i,j)/(sig(L)*curr%p(i,j)+ptop) - 1.0) )
194	enddo
195	enddo
196	endif
197
198	if( iqiau.ne.0 .or. ivaveqiau.ne.0 .or. idiabq.ne.0 ) then
199	do j=jm1,jm2
200	do i=im1,im2
201	dqiau(i,j,L) = tend%iau%dq(i,j,L) - curr%q(i,j,L,1)*tend%iau%dp(i,j)
202	enddo
203	enddo
204	endif
205
206	c Total Diabatic U-Tendency (m/sec/day)
207	c -------------------------------------
208	if( idiabu.ne.0 ) then
209	do j=jm1,jm2
210	do i=im1,im2
211	qdiag(i,j,idiabu+L-1) = qdiag (i,j,idiabu+L-1)
212	. + ( tend%iau%du (i,j,L)
213	. + tend%turb%du(i,j,L) )*86400
214	enddo
215	enddo
216	endif
217
218	c Total Diabatic V-Tendency (m/sec/day)
219	c -------------------------------------
220	if( idiabv.ne.0 ) then
221	do j=jm1,jm2
222	do i=im1,im2
223	qdiag(i,j,idiabv+L-1) = qdiag (i,j,idiabv+L-1)
224	. + ( tend%iau%dv (i,j,L)
225	. + tend%turb%dv(i,j,L) )*86400
226	enddo
227	enddo
228	endif
229
230	c Total Diabatic T-Tendency (deg/day)
231	c -----------------------------------
232	if( idiabt.ne.0 ) then
233	do j=jm1,jm2
234	do i=im1,im2
235	qdiag(i,j,idiabt+L-1) = qdiag(i,j,idiabt+L-1)
236	. + ( dtiau(i,j,L) + tend%turb%dt(i,j,L) + tend%lw%dt(i,j,L)
237	. + coup%lw%dlwdtg(i,j,L)*(coup%land%tgc(i,j)-coup%lw%tg0c(i,j))
238	. + tend%sw%dt(i,j,L)*radswc(i,j)
239	. + tend%moist%dt(i,j,L) )
240	. * pkn(i,j,L)pinv(i,j)86400
241	enddo
242	enddo
243	endif
244
245	c Total Diabatic Q-Tendency (g/kg/day)
246	c ------------------------------------
247	if( idiabq.ne.0 ) then
248	do j=jm1,jm2
249	do i=im1,im2
250	qdiag(i,j,idiabq+L-1) = qdiag(i,j,idiabq+L-1)
251	. + ( dqiau(i,j,L) + tend%turb%dq(i,j,L,1) + tend%moist%dq(i,j,L,1) )
252	. * pinv(i,j)864001000
253	enddo
254	enddo
255	endif
256
257	c Analysis U-Wind Increment (m/sec/day)
258	c -------------------------------------
259	if( iuiau.ne.0 ) then
260	do j=jm1,jm2
261	do i=im1,im2
262	qdiag(i,j,iuiau+L-1) = qdiag (i,j,iuiau+L-1) + tend%iau%du(i,j,L)*86400
263	enddo
264	enddo
265	endif
266
267	c Analysis V-Wind Increment (m/sec/day)
268	c -------------------------------------
269	if( iviau.ne.0 ) then
270	do j=jm1,jm2
271	do i=im1,im2
272	qdiag(i,j,iviau+L-1) = qdiag (i,j,iviau+L-1) + tend%iau%dv(i,j,L)*86400
273	enddo
274	enddo
275	endif
276
277	c Analysis Temperature Tendency (deg/day)
278	c ---------------------------------------
279	if( itiau.ne.0 ) then
280	do j=jm1,jm2
281	do i=im1,im2
282	qdiag(i,j,itiau+L-1) = qdiag(i,j,itiau+L-1)
283	. + dtiau(i,j,L) * pkn(i,j,L)pinv(i,j)86400
284	enddo
285	enddo
286	endif
287
288	c Analysis Moisture Tendency (g/kg/day)
289	c -------------------------------------
290	if( iqiau.ne.0 ) then
291	do j=jm1,jm2
292	do i=im1,im2
293	qdiag(i,j,iqiau+L-1) = qdiag(i,j,iqiau+L-1)
294	. + dqiau(i,j,L) * pinv(i,j)864001000
295	enddo
296	enddo
297	endif
298
299	c Longwave Heating (deg/day)
300	c --------------------------
301	if (iradlw.ne.0) then
302	do j=jm1,jm2
303	do i=im1,im2
304	qdiag(i,j,iradlw+l-1) = qdiag(i,j,iradlw+l-1)
305	. + ( tend%lw%dt(i,j,l)
306	. + coup%lw%dlwdtg (i,j,L)*(coup%land%tgc(i,j)-coup%lw%tg0c(i,j)))
307	. * pkn(i,j,l)pinv(i,j)86400
308	enddo
309	enddo
310	endif
311
312	c Longwave Heating Clear-Sky (deg/day)
313	c ------------------------------------
314	if (ilwclr.ne.0) then
315	do j=jm1,jm2
316	do i=im1,im2
317	qdiag(i,j,ilwclr+l-1) = qdiag(i,j,ilwclr+l-1)
318	. + ( tend%lw%dtclr(i,j,l)
319	. + coup%lw%dlwdtg(i,j,L)*(coup%land%tgc(i,j)-coup%lw%tg0c(i,j)))
320	. * pkn(i,j,l)pinv(i,j)86400
321	enddo
322	enddo
323	endif
324
325	c Solar Radiative Heating (deg/day)
326	c ---------------------------------
327	if (iradsw.ne.0) then
328	do j=jm1,jm2
329	do i=im1,im2
330	qdiag(i,j,iradsw+l-1) = qdiag(i,j,iradsw+l-1)
331	. + tend%sw%dt(i,j,l)*radswc(i,j)
332	. * pkn(i,j,l)pinv(i,j)86400
333	enddo
334	enddo
335	endif
336
337	c Clear Sky Solar Radiative Heating (deg/day)
338	c -------------------------------------------
339	if (iswclr.ne.0) then
340	do j=jm1,jm2
341	do i=im1,im2
342	qdiag(i,j,iswclr+l-1) = qdiag(i,j,iswclr+l-1)
343	. + tend%sw%dtclr(i,j,l)*radswc(i,j)
344	. * pkn(i,j,l)pinv(i,j)86400
345	enddo
346	enddo
347	endif
348
349	c Total U-Tendency (m/sec/day)
350	c ----------------------------
351	if( idudt.ne.0 ) then
352	do j=jm1,jm2
353	do i=im1,im2
354	qdiag(i,j,idudt+L-1) = qdiag(i,j,idudt+L-1)
355	. + ( updt%u(i,j,L)-curr%u(i,j,L) )*fact
356	enddo
357	enddo
358	endif
359
360	c Total V-Tendency (m/sec/day)
361	c ----------------------------
362	if( idvdt.ne.0 ) then
363	do j=jm1,jm2
364	do i=im1,im2
365	qdiag(i,j,idvdt+L-1) = qdiag(i,j,idvdt+L-1)
366	. + ( updt%v(i,j,L)-curr%v(i,j,L) )*fact
367	enddo
368	enddo
369	endif
370
371	c Total T-Tendency (deg/day)
372	c --------------------------
373	if( idtdt.ne.0 ) then
374	do j=jm1,jm2
375	do i=im1,im2
376	qdiag(i,j,idtdt+L-1) = qdiag(i,j,idtdt+L-1)
377	. + ( updt%t(i,j,L)pknp1(i,j,L) - curr%t(i,j,L)pkn(i,j,L) )*fact
378	enddo
379	enddo
380	endif
381
382	c Total Q-Tendency (g/kg/day)
383	c ---------------------------
384	if( idqdt.ne.0 ) then
385	do j=jm1,jm2
386	do i=im1,im2
387	qdiag(i,j,idqdt+L-1) = qdiag(i,j,idqdt+L-1)
388	. + ( updt%q(i,j,L,1)-curr%q(i,j,L,1) )fact1000
389	enddo
390	enddo
391	endif
392
393	c Averaged U-Field (m/sec)
394	c ------------------------
395	if( iuwnd.ne.0 ) then
396	do j=jm1,jm2
397	do i=im1,im2
398	qdiag(i,j,iuwnd+L-1) = qdiag(i,j,iuwnd+L-1) + curr%u(i,j,L)
399	enddo
400	enddo
401	endif
402
403	c Averaged V-Field (m/sec)
404	c ------------------------
405	if( ivwnd.ne.0 ) then
406	do j=jm1,jm2
407	do i=im1,im2
408	qdiag(i,j,ivwnd+L-1) = qdiag(i,j,ivwnd+L-1) + curr%v(i,j,L)
409	enddo
410	enddo
411	endif
412
413	c Averaged T-Field (deg)
414	c ----------------------
415	if( itmpu.ne.0 ) then
416	do j=jm1,jm2
417	do i=im1,im2
418	qdiag(i,j,itmpu+L-1) = qdiag(i,j,itmpu+L-1) + curr%t(i,j,L)*pkn(i,j,L)
419	enddo
420	enddo
421	endif
422
423	c Averaged QQ-Field (m/sec)**2
424	c ----------------------------
425	if( itke.ne.0 ) then
426	do j=jm1,jm2
427	do i=im1,im2
428	qdiag(i,j,itke+L-1) = qdiag(i,j,itke+L-1) + coup%turb%qq(i,j,L)
429	enddo
430	enddo
431	endif
432
433	c Averaged Q-Field (g/kg)
434	c -----------------------
435	if( isphu.ne.0 ) then
436	do j=jm1,jm2
437	do i=im1,im2
438	qdiag(i,j,isphu+L-1) = qdiag(i,j,isphu+L-1) + curr%q(i,j,L,1)*1000
439	enddo
440	enddo
441	endif
442
443	enddo ! End Level Loop
444
445	ndiabu = ndiabu + 1
446	ndiabv = ndiabv + 1
447	ndiabt = ndiabt + 1
448	nuiau = nuiau + 1
449	nviau = nviau + 1
450	ntiau = ntiau + 1
451	nradlw = nradlw + 1
452	nlwclr = nlwclr + 1
453	nradsw = nradsw + 1
454	nswclr = nswclr + 1
455	ndudt = ndudt + 1
456	ndvdt = ndvdt + 1
457	ndtdt = ndtdt + 1
458	ndiabq = ndiabq + 1
459	nqiau = nqiau + 1
460	ndqdt = ndqdt + 1
461	nuwnd = nuwnd + 1
462	nvwnd = nvwnd + 1
463	ntmpu = ntmpu + 1
464	ntke = ntke + 1
465	nsphu = nsphu + 1
466
467	C **********************************************************************
468	C ** Compute Vertically Integrated Diagnostics **
469	C **********************************************************************
470
471	c Compute Moisture and Temperature Convergence Diagnostic
472	c -------------------------------------------------------
473	if( ivaveut.ne.0 .or. ivavevt.ne.0 .or.
474	. ivaveuq.ne.0 .or. ivavevq.ne.0 ) then
475	do j=jm1,jm2
476	do i=im1,im2
477	vintut(i,j) = 0.0
478	vintvt(i,j) = 0.0
479	vintuq(i,j) = 0.0
480	vintvq(i,j) = 0.0
481	enddo
482	enddo
483
484	call ctoa ( curr%t,curr%t,dlam,dphi,im,jm,lm,0,grid%lattice )
485	call ctoa ( curr%q,curr%q,dlam,dphi,im,jm,lm,0,grid%lattice )
486	call ctoa_winds ( curr%u,curr%v,tmp1,tmp2,dlam,dphi,im,jm,lm,grid%lattice )
487	do L=1,Nrphys
488	do j=jm1,jm2
489	do i=im1,im2
490	vintut(i,j) = vintut(i,j) + tmp1(i,j,L)curr%t(i,j,L) dsig(L)* pkn(i,j,L)
491	vintvt(i,j) = vintvt(i,j) + tmp2(i,j,L)curr%t(i,j,L) dsig(L)* pkn(i,j,L)
492	vintuq(i,j) = vintuq(i,j) + tmp1(i,j,L)curr%q(i,j,L,1)dsig(L)
493	vintvq(i,j) = vintvq(i,j) + tmp2(i,j,L)curr%q(i,j,L,1)dsig(L)
494	enddo
495	enddo
496	enddo
497
498	if( ivaveut.ne.0 ) then
499	do j=jm1,jm2
500	do i=im1,im2
501	qdiag(i,j,ivaveut) = qdiag(i,j,ivaveut) + vintut(i,j)
502	enddo
503	enddo
504	endif
505	if( ivavevt.ne.0 ) then
506	do j=jm1,jm2
507	do i=im1,im2
508	qdiag(i,j,ivavevt) = qdiag(i,j,ivavevt) + vintvt(i,j)
509	enddo
510	enddo
511	endif
512	if( ivaveuq.ne.0 ) then
513	do j=jm1,jm2
514	do i=im1,im2
515	qdiag(i,j,ivaveuq) = qdiag(i,j,ivaveuq) + vintuq(i,j)*1000
516	enddo
517	enddo
518	endif
519	if( ivavevq.ne.0 ) then
520	do j=jm1,jm2
521	do i=im1,im2
522	qdiag(i,j,ivavevq) = qdiag(i,j,ivavevq) + vintvq(i,j)*1000
523	enddo
524	enddo
525	endif
526
527	endif ! End Convergence Diagnostic
528
529	c Total Precipitable Water (gm/cm**2)
530	c -----------------------------------
531	if( itpw.ne.0 ) then
532	do j=jm1,jm2
533	do i=im1,im2
534	qbar(i,j) = 0.0
535	enddo
536	enddo
537	do L=1,Nrphys
538	do j=jm1,jm2
539	do i=im1,im2
540	qbar(i,j) = qbar(i,j) + curr%q(i,j,L,1)*dsig(L)
541	enddo
542	enddo
543	enddo
544	do j=jm1,jm2
545	do i=im1,im2
546	qdiag(i,j,itpw) = qdiag(i,j,itpw) + qbar(i,j)10curr%p(i,j)/grav
547	enddo
548	enddo
549	endif
550
551	c Total Precipitable Analysis Increment (mm/day)
552	c ----------------------------------------------
553	if( ivaveqiau.ne.0 ) then
554	do j=jm1,jm2
555	do i=im1,im2
556	qbar(i,j) = 0.0
557	enddo
558	enddo
559	do L=1,Nrphys
560	do j=jm1,jm2
561	do i=im1,im2
562	qbar(i,j) = qbar(i,j) + dqiau(i,j,L)*dsig(L)
563	enddo
564	enddo
565	enddo
566	do j=jm1,jm2
567	do i=im1,im2
568	qdiag(i,j,ivaveqiau) = qdiag(i,j,ivaveqiau) + qbar(i,j)(10086400/grav)
569	enddo
570	enddo
571	endif
572
573	c Vertically Averaged Analysis Temperature Increment (K/day)
574	c ----------------------------------------------------------
575	if( ivavetiau.ne.0 ) then
576	do j=jm1,jm2
577	do i=im1,im2
578	qbar(i,j) = 0.0
579	enddo
580	enddo
581	do L=1,Nrphys
582	do j=jm1,jm2
583	do i=im1,im2
584	qbar(i,j) = qbar(i,j) + dtiau(i,j,L)pkn(i,j,l)dsig(L)
585	enddo
586	enddo
587	enddo
588	do j=jm1,jm2
589	do i=im1,im2
590	qdiag(i,j,ivavetiau) = qdiag(i,j,ivavetiau) + qbar(i,j)pinv(i,j)86400
591	enddo
592	enddo
593	endif
594
595	c Vertically Averaged Moist-T Increment (K/day)
596	c ---------------------------------------------
597	if( ivdtmoist.ne.0 ) then
598	do j=jm1,jm2
599	do i=im1,im2
600	qbar(i,j) = 0.0
601	enddo
602	enddo
603	do L=1,Nrphys
604	do j=jm1,jm2
605	do i=im1,im2
606	qbar(i,j) = qbar(i,j) + tend%moist%dt(i,j,L)pkn(i,j,l)dsig(L)
607	enddo
608	enddo
609	enddo
610	do j=jm1,jm2
611	do i=im1,im2
612	qdiag(i,j,ivdtmoist) = qdiag(i,j,ivdtmoist) + qbar(i,j)pinv(i,j)86400
613	enddo
614	enddo
615	endif
616
617	c Vertically Averaged Turb-T Increment (K/day)
618	c --------------------------------------------
619	if( ivdtturb.ne.0 ) then
620	do j=jm1,jm2
621	do i=im1,im2
622	qbar(i,j) = 0.0
623	enddo
624	enddo
625	do L=1,Nrphys
626	do j=jm1,jm2
627	do i=im1,im2
628	qbar(i,j) = qbar(i,j) + tend%turb%dt(i,j,L)pkn(i,j,l)dsig(L)
629	enddo
630	enddo
631	enddo
632	do j=jm1,jm2
633	do i=im1,im2
634	qdiag(i,j,ivdtturb) = qdiag(i,j,ivdtturb) + qbar(i,j)pinv(i,j)86400
635	enddo
636	enddo
637	endif
638
639	c Vertically Averaged RADLW Temperature Increment (K/day)
640	c -------------------------------------------------------
641	if( ivdtradlw.ne.0 ) then
642	do j=jm1,jm2
643	do i=im1,im2
644	qbar(i,j) = 0.0
645	enddo
646	enddo
647	do L=1,Nrphys
648	do j=jm1,jm2
649	do i=im1,im2
650	qbar(i,j) = qbar(i,j) + ( tend%lw%dt(i,j,L)
651	. + coup%lw%dlwdtg(i,j,L)(coup%land%tgc(i,j)-coup%lw%tg0c(i,j)) )pkn(i,j,l)*dsig(L)
652	enddo
653	enddo
654	enddo
655	do j=jm1,jm2
656	do i=im1,im2
657	qdiag(i,j,ivdtradlw) = qdiag(i,j,ivdtradlw) + qbar(i,j)pinv(i,j)86400
658	enddo
659	enddo
660	endif
661
662	c Vertically Averaged RADSW Temperature Increment (K/day)
663	c -------------------------------------------------------
664	if( ivdtradsw.ne.0 ) then
665	do j=jm1,jm2
666	do i=im1,im2
667	qbar(i,j) = 0.0
668	enddo
669	enddo
670	do L=1,Nrphys
671	do j=jm1,jm2
672	do i=im1,im2
673	qbar(i,j) = qbar(i,j) + tend%sw%dt(i,j,L)pkn(i,j,l)dsig(L)
674	enddo
675	enddo
676	enddo
677	do j=jm1,jm2
678	do i=im1,im2
679	qdiag(i,j,ivdtradsw) = qdiag(i,j,ivdtradsw) + qbar(i,j)radswc(i,j)pinv(i,j)*86400
680	enddo
681	enddo
682	endif
683
684	nvaveut = nvaveut + 1
685	nvavevt = nvavevt + 1
686	nvaveuq = nvaveuq + 1
687	nvavevq = nvavevq + 1
688	ntpw = ntpw + 1
689	nvaveqiau = nvaveqiau + 1
690	nvavetiau = nvavetiau + 1
691	nvdtmoist = nvdtmoist + 1
692	nvdtturb = nvdtturb + 1
693	nvdtradlw = nvdtradlw + 1
694	nvdtradsw = nvdtradsw + 1
695
696	C *****************************************************************
697	C ** Release Workspace **
698	C *****************************************************************
699
700	deallocate ( dlam )
701	deallocate ( dphi )
702	deallocate ( dsig )
703	deallocate ( sig )
704	deallocate ( sige )
705
706	deallocate ( pinv )
707	deallocate ( tmp1 )
708	deallocate ( tmp2 )
709	deallocate ( qbar )
710	deallocate ( vintuq )
711	deallocate ( vintvq )
712	deallocate ( vintut )
713	deallocate ( vintvt )
714	deallocate ( pkn )
715	deallocate ( pknp1 )
716	deallocate ( dtiau )
717	deallocate ( dqiau )
718
719	call timeend (' step_diag')
720	return
721	end