pkg/fizhi/fizhi_step_diag.F

C $Header: /u/gcmpack/MITgcm/pkg/fizhi/fizhi_step_diag.F,v 1.7 2004/07/26 19:51:08 molod Exp $
C $Name:  $

#include "FIZHI_OPTIONS.h"
      subroutine fizhi_step_diag(myThid,p,uphy,vphy,thphy,sphy,qq,pk,dp,
     .  radswt,radswg,swgclr,osr,osrclr,st4,dst4,tgz,tg0,radlwg,lwgclr,
     .  turbu,turbv,turbt,turbq,moistu,moistv,moistt,moistq,
     .  lwdt,swdt,lwdtclr,swdtclr,dlwdtg,
     .  im1,im2,jm1,jm2,Nrphys,Nbi,Nbj,bi,bj,ntracer)
C***********************************************************************
      implicit none

#ifdef ALLOW_DIAGNOSTICS
#include "SIZE.h"
#include "diagnostics_SIZE.h"
#include "diagnostics.h"
#endif

      integer myThid,im1,im2,jm1,jm2,Nrphys,Nbi,Nbj,bi,bj,ntracer
      _RL p(im2,jm2,Nbi,Nbj)
      _RL uphy(im2,jm2,Nrphys,Nbi,Nbj)
      _RL vphy(im2,jm2,Nrphys,Nbi,Nbj)
      _RL thphy(im2,jm2,Nrphys,Nbi,Nbj)
      _RL sphy(im2,jm2,Nrphys,Nbi,Nbj)
      _RL qq(im2,jm2,Nrphys),pk(im2,jm2,Nrphys,Nbi,Nbj)
      _RL dp(im2,jm2,Nrphys,Nbi,Nbj)
      _RL radswt(im2,jm2,Nbi,Nbj),radswg(im2,jm2,Nbi,Nbj)
      _RL swgclr(im2,jm2,Nbi,Nbj),osr(im2,jm2,Nbi,Nbj)
      _RL osrclr(im2,jm2,Nbi,Nbj),st4(im2,jm2,Nbi,Nbj)
      _RL dst4(im2,jm2,Nbi,Nbj),tgz(im2,jm2,Nbi,Nbj)
      _RL tg0(im2,jm2,Nbi,Nbj),radlwg(im2,jm2,Nbi,Nbj)
      _RL lwgclr(im2,jm2,Nbi,Nbj)
      _RL turbu(im2,jm2,Nrphys,Nbi,Nbj)
      _RL turbv(im2,jm2,Nrphys,Nbi,Nbj)
      _RL turbt(im2,jm2,Nrphys,Nbi,Nbj)
      _RL turbq(im2,jm2,Nrphys,ntracer,Nbi,Nbj)
      _RL moistu(im2,jm2,Nrphys,Nbi,Nbj)
      _RL moistv(im2,jm2,Nrphys,Nbi,Nbj)
      _RL moistt(im2,jm2,Nrphys,Nbi,Nbj)
      _RL moistq(im2,jm2,Nrphys,ntracer,Nbi,Nbj)
      _RL lwdt(im2,jm2,Nrphys,Nbi,Nbj)
      _RL swdt(im2,jm2,Nrphys,Nbi,Nbj)
      _RL lwdtclr(im2,jm2,Nrphys,Nbi,Nbj)
      _RL swdtclr(im2,jm2,Nrphys,Nbi,Nbj)
      _RL dlwdtg(im2,jm2,Nrphys,Nbi,Nbj)

      integer  i,j,L
      _RL pinv(im2,jm2), qbar(im2,jm2)

C **********************************************************************        

#ifdef ALLOW_DIAGNOSTICS
      do j=jm1,jm2
      do i=im1,im2
      pinv(i,j) = 1.0 / p(i,j,bi,bj)
      enddo
      enddo

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,bi,bj)= qdiag(i,j,iradswt,bi,bj) +
     .                                                 radswt(i,j,bi,bj)
      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,bi,bj) = qdiag(i,j,iradswg,bi,bj) + 
     .                               radswg(i,j,bi,bj)*radswt(i,j,bi,bj)
      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,bi,bj) = qdiag(i,j,iswgclr,bi,bj) + 
     .                               swgclr(i,j,bi,bj)*radswt(i,j,bi,bj)
      enddo
      enddo
      endif
                                                                                
c Outgoing Solar Radiation at top (W/m**2)
c -----------------------------------------
      if (iosr.ne.0) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iosr,bi,bj) = qdiag(i,j,iosr,bi,bj) + 
     .                            (1.0-osr(i,j,bi,bj))*radswt(i,j,bi,bj)
      enddo
      enddo
      endif
                                                                                
c Outgoing Clear Sky Solar Radiation at top (W/m**2)
c ---------------------------------------------------
      if (iosrclr.ne.0) then
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,iosrclr,bi,bj) = qdiag(i,j,iosrclr,bi,bj) + 
     .                         (1.0-osrclr(i,j,bi,bj))*radswt(i,j,bi,bj)         
      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,bi,bj) = qdiag(i,j,ilwgup,bi,bj) + st4(i,j,bi,bj) 
     .                 + dst4(i,j,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj))
      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,bi,bj) =  qdiag(i,j,iradlwg,bi,bj) + 
     .                                              radlwg(i,j,bi,bj) + 
     .                  dst4(i,j,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj))
      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,bi,bj) = qdiag(i,j,ilwgclr,bi,bj) + 
     .                                               lwgclr(i,j,bi,bj) + 
     .                   dst4(i,j,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj))
      enddo
      enddo
      endif
                                                                                
      nradswt = nradswt + 1
      nradswg = nradswg + 1
      nswgclr = nswgclr + 1
      nosr    = nosr    + 1
      nosrclr = nosrclr + 1
      nradlwg = nradlwg + 1
      nlwgclr = nlwgclr + 1
      nlwgup  = nlwgup  + 1
                                                                                
C **********************************************************************        
      do L=1,Nrphys

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,bi,bj) = qdiag(i,j,idiabu+L-1,bi,bj)
     .            + ( moistu (i,j,L,bi,bj) + turbu(i,j,L,bi,bj) )*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,bi,bj) = qdiag(i,j,idiabv+L-1,bi,bj)
     .            + ( moistv (i,j,L,bi,bj) + turbv(i,j,L,bi,bj) )*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,bi,bj) = qdiag(i,j,idiabt+L-1,bi,bj) +
     .   ( turbt(i,j,L,bi,bj) + moistt(i,j,L,bi,bj) +
     .      lwdt(i,j,L,bi,bj) +
     .      dlwdtg(i,j,L,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj)) +
     .      swdt(i,j,L,bi,bj)*radswt(i,j,bi,bj) )
     .      * pk(i,j,L,bi,bj)*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,bi,bj) =   qdiag(i,j,idiabq+L-1,bi,bj) +
     . ( turbq(i,j,L,1,bi,bj) + moistq(i,j,L,1,bi,bj) ) * 
     .                                      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,bi,bj) = qdiag(i,j,iradlw+l-1,bi,bj) + 
     . ( lwdt(i,j,l,bi,bj) + 
     .            dlwdtg (i,j,L,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj)) )
     .                      * pk(i,j,l,bi,bj)*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,bi,bj) = qdiag(i,j,ilwclr+l-1,bi,bj) +
     . ( lwdtclr(i,j,l,bi,bj) + 
     .             dlwdtg(i,j,L,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj)) )
     .                      * pk(i,j,l,bi,bj)*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,bi,bj) = qdiag(i,j,iradsw+l-1,bi,bj) +
     .  + swdt(i,j,l,bi,bj)*radswt(i,j,bi,bj)*
     .                   pk(i,j,l,bi,bj)*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,bi,bj) = qdiag(i,j,iswclr+l-1,bi,bj) +
     .           swdtclr(i,j,l,bi,bj)*radswt(i,j,bi,bj)*
     .                           pk(i,j,l,bi,bj)*pinv(i,j)*86400
      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,bi,bj) = qdiag(i,j,iuwnd+L-1,bi,bj) + 
     .                                                 uphy(i,j,L,bi,bj)
      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,bi,bj) = qdiag(i,j,ivwnd+L-1,bi,bj) + 
     .                                                 vphy(i,j,L,bi,bj)
      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,bi,bj) = qdiag(i,j,itmpu+L-1,bi,bj) + 
     .                               thphy(i,j,L,bi,bj)*pk(i,j,L,bi,bj)
      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,bi,bj) = qdiag(i,j,itke+L-1,bi,bj) + 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,bi,bj) = qdiag(i,j,isphu+L-1,bi,bj) + 
     .                                            sphy(i,j,L,bi,bj)*1000
      enddo
      enddo
      endif
                                                                                
      enddo

      ndiabu = ndiabu + 1
      ndiabv = ndiabv + 1
      ndiabt = ndiabt + 1
      ndiabq = ndiabq + 1
      nradlw = nradlw + 1                                                     
      nlwclr = nlwclr + 1                                                     
      nradsw = nradsw + 1                                                     
      nswclr = nswclr + 1                                                     
      nuwnd  = nuwnd  + 1
      nvwnd  = nvwnd  + 1                           
      ntmpu  = ntmpu  + 1                           
      ntke   = ntke   + 1
      nsphu  = nsphu  + 1

C **********************************************************************        

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) + 
     .             moistt(i,j,L,bi,bj)*pk(i,j,l,bi,bj)*dp(i,j,L,bi,bj)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivdtmoist,bi,bj) = qdiag(i,j,ivdtmoist,bi,bj) + 
     .      qbar(i,j)*pinv(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) + 
     .             turbt(i,j,L,bi,bj)*pk(i,j,l,bi,bj)*dp(i,j,L,bi,bj)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivdtturb,bi,bj) = qdiag(i,j,ivdtturb,bi,bj) + 
     .      qbar(i,j)*pinv(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) + ( lwdt(i,j,L,bi,bj) +
     .  dlwdtg(i,j,L,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj)) )
     .             *pk(i,j,l,bi,bj)*dp(i,j,L,bi,bj)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivdtradlw,bi,bj) = qdiag(i,j,ivdtradlw,bi,bj) + 
     .      qbar(i,j)*pinv(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) + 
     .             swdt(i,j,L,bi,bj)*pk(i,j,l,bi,bj)*dp(i,j,L,bi,bj)
      enddo
      enddo
      enddo
      do j=jm1,jm2
      do i=im1,im2
      qdiag(i,j,ivdtradsw,bi,bj) = qdiag(i,j,ivdtradsw,bi,bj) + 
     . qbar(i,j)*radswt(i,j,bi,bj)*pinv(i,j)*pinv(i,j)*86400
      enddo
      enddo
      endif

      nvdtmoist = nvdtmoist + 1
      nvdtturb  = nvdtturb  + 1
      nvdtradlw = nvdtradlw + 1
      nvdtradsw = nvdtradsw + 1
 
#endif
      return
      end
1	C $Header: /u/gcmpack/MITgcm/pkg/fizhi/fizhi_step_diag.F,v 1.7 2004/07/26 19:51:08 molod Exp $
2	C $Name: $
3
4	#include "FIZHI_OPTIONS.h"
5	subroutine fizhi_step_diag(myThid,p,uphy,vphy,thphy,sphy,qq,pk,dp,
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,dlwdtg,
9	. im1,im2,jm1,jm2,Nrphys,Nbi,Nbj,bi,bj,ntracer)
10	C***********************************************************************
11	implicit none
12
13	#ifdef ALLOW_DIAGNOSTICS
14	#include "SIZE.h"
15	#include "diagnostics_SIZE.h"
16	#include "diagnostics.h"
17	#endif
18
19	integer myThid,im1,im2,jm1,jm2,Nrphys,Nbi,Nbj,bi,bj,ntracer
20	_RL p(im2,jm2,Nbi,Nbj)
21	_RL uphy(im2,jm2,Nrphys,Nbi,Nbj)
22	_RL vphy(im2,jm2,Nrphys,Nbi,Nbj)
23	_RL thphy(im2,jm2,Nrphys,Nbi,Nbj)
24	_RL sphy(im2,jm2,Nrphys,Nbi,Nbj)
25	_RL qq(im2,jm2,Nrphys),pk(im2,jm2,Nrphys,Nbi,Nbj)
26	_RL dp(im2,jm2,Nrphys,Nbi,Nbj)
27	_RL radswt(im2,jm2,Nbi,Nbj),radswg(im2,jm2,Nbi,Nbj)
28	_RL swgclr(im2,jm2,Nbi,Nbj),osr(im2,jm2,Nbi,Nbj)
29	_RL osrclr(im2,jm2,Nbi,Nbj),st4(im2,jm2,Nbi,Nbj)
30	_RL dst4(im2,jm2,Nbi,Nbj),tgz(im2,jm2,Nbi,Nbj)
31	_RL tg0(im2,jm2,Nbi,Nbj),radlwg(im2,jm2,Nbi,Nbj)
32	_RL lwgclr(im2,jm2,Nbi,Nbj)
33	_RL turbu(im2,jm2,Nrphys,Nbi,Nbj)
34	_RL turbv(im2,jm2,Nrphys,Nbi,Nbj)
35	_RL turbt(im2,jm2,Nrphys,Nbi,Nbj)
36	_RL turbq(im2,jm2,Nrphys,ntracer,Nbi,Nbj)
37	_RL moistu(im2,jm2,Nrphys,Nbi,Nbj)
38	_RL moistv(im2,jm2,Nrphys,Nbi,Nbj)
39	_RL moistt(im2,jm2,Nrphys,Nbi,Nbj)
40	_RL moistq(im2,jm2,Nrphys,ntracer,Nbi,Nbj)
41	_RL lwdt(im2,jm2,Nrphys,Nbi,Nbj)
42	_RL swdt(im2,jm2,Nrphys,Nbi,Nbj)
43	_RL lwdtclr(im2,jm2,Nrphys,Nbi,Nbj)
44	_RL swdtclr(im2,jm2,Nrphys,Nbi,Nbj)
45	_RL dlwdtg(im2,jm2,Nrphys,Nbi,Nbj)
46
47	integer i,j,L
48	_RL pinv(im2,jm2), qbar(im2,jm2)
49
50	C **********************************************************************
51
52	#ifdef ALLOW_DIAGNOSTICS
53	do j=jm1,jm2
54	do i=im1,im2
55	pinv(i,j) = 1.0 / p(i,j,bi,bj)
56	enddo
57	enddo
58
59	c Incident Solar Radiation (W/m**2)
60	c ---------------------------------
61	if (iradswt.ne.0) then
62	do j=jm1,jm2
63	do i=im1,im2
64	qdiag(i,j,iradswt,bi,bj)= qdiag(i,j,iradswt,bi,bj) +
65	. radswt(i,j,bi,bj)
66	enddo
67	enddo
68	endif
69
70	c Net Solar Radiation at the Ground (W/m**2)
71	c ------------------------------------------
72	if (iradswg.ne.0) then
73	do j=jm1,jm2
74	do i=im1,im2
75	qdiag(i,j,iradswg,bi,bj) = qdiag(i,j,iradswg,bi,bj) +
76	. radswg(i,j,bi,bj)*radswt(i,j,bi,bj)
77	enddo
78	enddo
79	endif
80
81	c Net Clear Sky Solar Radiation at the Ground (W/m**2)
82	c ----------------------------------------------------
83	if (iswgclr.ne.0) then
84	do j=jm1,jm2
85	do i=im1,im2
86	qdiag(i,j,iswgclr,bi,bj) = qdiag(i,j,iswgclr,bi,bj) +
87	. swgclr(i,j,bi,bj)*radswt(i,j,bi,bj)
88	enddo
89	enddo
90	endif
91
92	c Outgoing Solar Radiation at top (W/m**2)
93	c -----------------------------------------
94	if (iosr.ne.0) then
95	do j=jm1,jm2
96	do i=im1,im2
97	qdiag(i,j,iosr,bi,bj) = qdiag(i,j,iosr,bi,bj) +
98	. (1.0-osr(i,j,bi,bj))*radswt(i,j,bi,bj)
99	enddo
100	enddo
101	endif
102
103	c Outgoing Clear Sky Solar Radiation at top (W/m**2)
104	c ---------------------------------------------------
105	if (iosrclr.ne.0) then
106	do j=jm1,jm2
107	do i=im1,im2
108	qdiag(i,j,iosrclr,bi,bj) = qdiag(i,j,iosrclr,bi,bj) +
109	. (1.0-osrclr(i,j,bi,bj))*radswt(i,j,bi,bj)
110	enddo
111	enddo
112	endif
113
114	c Upward Longwave Flux at the Ground (W/m**2)
115	c -------------------------------------------
116	if (ilwgup.ne.0) then
117	do j=jm1,jm2
118	do i=im1,im2
119	qdiag(i,j,ilwgup,bi,bj) = qdiag(i,j,ilwgup,bi,bj) + st4(i,j,bi,bj)
120	. + dst4(i,j,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj))
121	enddo
122	enddo
123	endif
124
125	c Net Longwave Flux at the Ground (W/m**2)
126	c ----------------------------------------
127	if (iradlwg.ne.0) then
128	do j=jm1,jm2
129	do i=im1,im2
130	qdiag(i,j,iradlwg,bi,bj) = qdiag(i,j,iradlwg,bi,bj) +
131	. radlwg(i,j,bi,bj) +
132	. dst4(i,j,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj))
133	enddo
134	enddo
135	endif
136
137	c Net Longwave Flux at the Ground Clear Sky (W/m**2)
138	c --------------------------------------------------
139	if (ilwgclr.ne.0) then
140	do j=jm1,jm2
141	do i=im1,im2
142	qdiag(i,j,ilwgclr,bi,bj) = qdiag(i,j,ilwgclr,bi,bj) +
143	. lwgclr(i,j,bi,bj) +
144	. dst4(i,j,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj))
145	enddo
146	enddo
147	endif
148
149	nradswt = nradswt + 1
150	nradswg = nradswg + 1
151	nswgclr = nswgclr + 1
152	nosr = nosr + 1
153	nosrclr = nosrclr + 1
154	nradlwg = nradlwg + 1
155	nlwgclr = nlwgclr + 1
156	nlwgup = nlwgup + 1
157
158	C **********************************************************************
159	do L=1,Nrphys
160
161	c Total Diabatic U-Tendency (m/sec/day)
162	c -------------------------------------
163	if( idiabu.ne.0 ) then
164	do j=jm1,jm2
165	do i=im1,im2
166	qdiag(i,j,idiabu+L-1,bi,bj) = qdiag(i,j,idiabu+L-1,bi,bj)
167	. + ( moistu (i,j,L,bi,bj) + turbu(i,j,L,bi,bj) )*86400
168	enddo
169	enddo
170	endif
171
172	c Total Diabatic V-Tendency (m/sec/day)
173	c -------------------------------------
174	if( idiabv.ne.0 ) then
175	do j=jm1,jm2
176	do i=im1,im2
177	qdiag(i,j,idiabv+L-1,bi,bj) = qdiag(i,j,idiabv+L-1,bi,bj)
178	. + ( moistv (i,j,L,bi,bj) + turbv(i,j,L,bi,bj) )*86400
179	enddo
180	enddo
181	endif
182
183	c Total Diabatic T-Tendency (deg/day)
184	c -----------------------------------
185	if( idiabt.ne.0 ) then
186	do j=jm1,jm2
187	do i=im1,im2
188	qdiag(i,j,idiabt+L-1,bi,bj) = qdiag(i,j,idiabt+L-1,bi,bj) +
189	. ( turbt(i,j,L,bi,bj) + moistt(i,j,L,bi,bj) +
190	. lwdt(i,j,L,bi,bj) +
191	. dlwdtg(i,j,L,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj)) +
192	. swdt(i,j,L,bi,bj)*radswt(i,j,bi,bj) )
193	. * pk(i,j,L,bi,bj)pinv(i,j)86400
194	enddo
195	enddo
196	endif
197
198	c Total Diabatic Q-Tendency (g/kg/day)
199	c ------------------------------------
200	if( idiabq.ne.0 ) then
201	do j=jm1,jm2
202	do i=im1,im2
203	qdiag(i,j,idiabq+L-1,bi,bj) = qdiag(i,j,idiabq+L-1,bi,bj) +
204	. ( turbq(i,j,L,1,bi,bj) + moistq(i,j,L,1,bi,bj) ) *
205	. pinv(i,j)864001000
206	enddo
207	enddo
208	endif
209
210	c Longwave Heating (deg/day)
211	c --------------------------
212	if (iradlw.ne.0) then
213	do j=jm1,jm2
214	do i=im1,im2
215	qdiag(i,j,iradlw+l-1,bi,bj) = qdiag(i,j,iradlw+l-1,bi,bj) +
216	. ( lwdt(i,j,l,bi,bj) +
217	. dlwdtg (i,j,L,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj)) )
218	. * pk(i,j,l,bi,bj)pinv(i,j)86400
219	enddo
220	enddo
221	endif
222
223	c Longwave Heating Clear-Sky (deg/day)
224	c ------------------------------------
225	if (ilwclr.ne.0) then
226	do j=jm1,jm2
227	do i=im1,im2
228	qdiag(i,j,ilwclr+l-1,bi,bj) = qdiag(i,j,ilwclr+l-1,bi,bj) +
229	. ( lwdtclr(i,j,l,bi,bj) +
230	. dlwdtg(i,j,L,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj)) )
231	. * pk(i,j,l,bi,bj)pinv(i,j)86400
232	enddo
233	enddo
234	endif
235
236	c Solar Radiative Heating (deg/day)
237	c ---------------------------------
238	if (iradsw.ne.0) then
239	do j=jm1,jm2
240	do i=im1,im2
241	qdiag(i,j,iradsw+l-1,bi,bj) = qdiag(i,j,iradsw+l-1,bi,bj) +
242	. + swdt(i,j,l,bi,bj)radswt(i,j,bi,bj)
243	. pk(i,j,l,bi,bj)pinv(i,j)86400
244	enddo
245	enddo
246	endif
247
248	c Clear Sky Solar Radiative Heating (deg/day)
249	c -------------------------------------------
250	if (iswclr.ne.0) then
251	do j=jm1,jm2
252	do i=im1,im2
253	qdiag(i,j,iswclr+l-1,bi,bj) = qdiag(i,j,iswclr+l-1,bi,bj) +
254	. swdtclr(i,j,l,bi,bj)radswt(i,j,bi,bj)
255	. pk(i,j,l,bi,bj)pinv(i,j)86400
256	enddo
257	enddo
258	endif
259
260	c Averaged U-Field (m/sec)
261	c ------------------------
262	if( iuwnd.ne.0 ) then
263	do j=jm1,jm2
264	do i=im1,im2
265	qdiag(i,j,iuwnd+L-1,bi,bj) = qdiag(i,j,iuwnd+L-1,bi,bj) +
266	. uphy(i,j,L,bi,bj)
267	enddo
268	enddo
269	endif
270
271	c Averaged V-Field (m/sec)
272	c ------------------------
273	if( ivwnd.ne.0 ) then
274	do j=jm1,jm2
275	do i=im1,im2
276	qdiag(i,j,ivwnd+L-1,bi,bj) = qdiag(i,j,ivwnd+L-1,bi,bj) +
277	. vphy(i,j,L,bi,bj)
278	enddo
279	enddo
280	endif
281
282	c Averaged T-Field (deg)
283	c ----------------------
284	if( itmpu.ne.0 ) then
285	do j=jm1,jm2
286	do i=im1,im2
287	qdiag(i,j,itmpu+L-1,bi,bj) = qdiag(i,j,itmpu+L-1,bi,bj) +
288	. thphy(i,j,L,bi,bj)*pk(i,j,L,bi,bj)
289	enddo
290	enddo
291	endif
292
293	c Averaged QQ-Field (m/sec)**2
294	c ----------------------------
295	if( itke.ne.0 ) then
296	do j=jm1,jm2
297	do i=im1,im2
298	qdiag(i,j,itke+L-1,bi,bj) = qdiag(i,j,itke+L-1,bi,bj) + qq(i,j,L)
299	enddo
300	enddo
301	endif
302
303	c Averaged Q-Field (g/kg)
304	c -----------------------
305	if( isphu.ne.0 ) then
306	do j=jm1,jm2
307	do i=im1,im2
308	qdiag(i,j,isphu+L-1,bi,bj) = qdiag(i,j,isphu+L-1,bi,bj) +
309	. sphy(i,j,L,bi,bj)*1000
310	enddo
311	enddo
312	endif
313
314	enddo
315
316	ndiabu = ndiabu + 1
317	ndiabv = ndiabv + 1
318	ndiabt = ndiabt + 1
319	ndiabq = ndiabq + 1
320	nradlw = nradlw + 1
321	nlwclr = nlwclr + 1
322	nradsw = nradsw + 1
323	nswclr = nswclr + 1
324	nuwnd = nuwnd + 1
325	nvwnd = nvwnd + 1
326	ntmpu = ntmpu + 1
327	ntke = ntke + 1
328	nsphu = nsphu + 1
329
330	C **********************************************************************
331
332	c Vertically Averaged Moist-T Increment (K/day)
333	c ---------------------------------------------
334	if( ivdtmoist.ne.0 ) then
335	do j=jm1,jm2
336	do i=im1,im2
337	qbar(i,j) = 0.0
338	enddo
339	enddo
340	do L=1,Nrphys
341	do j=jm1,jm2
342	do i=im1,im2
343	qbar(i,j) = qbar(i,j) +
344	. moistt(i,j,L,bi,bj)pk(i,j,l,bi,bj)dp(i,j,L,bi,bj)
345	enddo
346	enddo
347	enddo
348	do j=jm1,jm2
349	do i=im1,im2
350	qdiag(i,j,ivdtmoist,bi,bj) = qdiag(i,j,ivdtmoist,bi,bj) +
351	. qbar(i,j)pinv(i,j)pinv(i,j)*86400
352	enddo
353	enddo
354	endif
355
356	c Vertically Averaged Turb-T Increment (K/day)
357	c --------------------------------------------
358	if( ivdtturb.ne.0 ) then
359	do j=jm1,jm2
360	do i=im1,im2
361	qbar(i,j) = 0.0
362	enddo
363	enddo
364	do L=1,Nrphys
365	do j=jm1,jm2
366	do i=im1,im2
367	qbar(i,j) = qbar(i,j) +
368	. turbt(i,j,L,bi,bj)pk(i,j,l,bi,bj)dp(i,j,L,bi,bj)
369	enddo
370	enddo
371	enddo
372	do j=jm1,jm2
373	do i=im1,im2
374	qdiag(i,j,ivdtturb,bi,bj) = qdiag(i,j,ivdtturb,bi,bj) +
375	. qbar(i,j)pinv(i,j)pinv(i,j)*86400
376	enddo
377	enddo
378	endif
379
380	c Vertically Averaged RADLW Temperature Increment (K/day)
381	c -------------------------------------------------------
382	if( ivdtradlw.ne.0 ) then
383	do j=jm1,jm2
384	do i=im1,im2
385	qbar(i,j) = 0.0
386	enddo
387	enddo
388	do L=1,Nrphys
389	do j=jm1,jm2
390	do i=im1,im2
391	qbar(i,j) = qbar(i,j) + ( lwdt(i,j,L,bi,bj) +
392	. dlwdtg(i,j,L,bi,bj)*(tgz(i,j,bi,bj)-tg0(i,j,bi,bj)) )
393	. pk(i,j,l,bi,bj)dp(i,j,L,bi,bj)
394	enddo
395	enddo
396	enddo
397	do j=jm1,jm2
398	do i=im1,im2
399	qdiag(i,j,ivdtradlw,bi,bj) = qdiag(i,j,ivdtradlw,bi,bj) +
400	. qbar(i,j)pinv(i,j)pinv(i,j)*86400
401	enddo
402	enddo
403	endif
404
405	c Vertically Averaged RADSW Temperature Increment (K/day)
406	c -------------------------------------------------------
407	if( ivdtradsw.ne.0 ) then
408	do j=jm1,jm2
409	do i=im1,im2
410	qbar(i,j) = 0.0
411	enddo
412	enddo
413	do L=1,Nrphys
414	do j=jm1,jm2
415	do i=im1,im2
416	qbar(i,j) = qbar(i,j) +
417	. swdt(i,j,L,bi,bj)pk(i,j,l,bi,bj)dp(i,j,L,bi,bj)
418	enddo
419	enddo
420	enddo
421	do j=jm1,jm2
422	do i=im1,im2
423	qdiag(i,j,ivdtradsw,bi,bj) = qdiag(i,j,ivdtradsw,bi,bj) +
424	. qbar(i,j)radswt(i,j,bi,bj)pinv(i,j)pinv(i,j)86400
425	enddo
426	enddo
427	endif
428
429	nvdtmoist = nvdtmoist + 1
430	nvdtturb = nvdtturb + 1
431	nvdtradlw = nvdtradlw + 1
432	nvdtradsw = nvdtradsw + 1
433
434	#endif
435	return
436	end