igsm/src/hordiff_all.F


#include "ctrparam.h"

!       ==========================================================
!
!       HORDIFF.F:  subroutine for calculating horizontal
!                       diffusion of Q.
!
!       ----------------------------------------------------------
!
!       Revision History:
!
!       When    Who             What
!       ----    ----------      -------
!       080100  Chien Wang      repack based on CliChem3 & M24x11,
!                                 and add cpp.
!
!       ==========================================================

      SUBROUTINE HORDIFFALL(DTDIF)
#include "BD2G04.COM"
      COMMON U,V,T,P,Q  
      DIMENSION VT(IM0,JM0,LM0),TT(IM0,JM0,LM0),PT(IM0,JM0), 
     &  QT(IM0,JM0,LM0),PU(IM0,JM0),FD(IM0,JM0),DQDY(JM0,LM0)
     &  ,DTDY(JM0,LM0),DUDY(JM0,LM0),DVDY(JM0,LM0)
     & ,UT(IM0,JM0,LM0)
      COMMON/HDFLUX/VQHD(JM0,LM0),VTHD(JM0,LM0),VUHD(JM0,LM0),
     &             VVHD(JM0,LM0)
      logical first
      data first /.true./
      I=1
      JMM1=JM0-1
      FDIFU=5.0E5
      FDIFU=2.50E5

      FDIFF=5.0E5

      FDIFFQ=5.0E5
      FDIFFQ=1.00E6

      if(first)then
        print *,' HOR DIFF for Q and T'
        print *,' FDIFF=',FDIFF,' FDIFFQ=',FDIFFQ
        print *,' HOR DIFF for U and V'
        print *,' FDIFU=',FDIFU
        print *,'IM0=',IM0,' JM0=',JM0,' LM0=',LM0
        print *,'IM=',IM,' JM=',JM,' LM=',LM
        first=.false.
      endif
      DO 50 J=1,JM0                                            
 50   FD(I,J)=P(I,J)*DXYP(J)    
      DO 57 L=1,LM0         
      DO 57 J=1,JM0            
       AJL(J,L,56)=AJL(J,L,56)-Q (I,J,L)*P(I,J)
      TT (I,J,L)=T (I,J,L)*FD(I,J) 
 57   QT (I,J,L)=Q (I,J,L)*FD(I,J) 
      DO 100 L=1,LM0
      DO 100 J=2,JM0
        DQDY(J,L)=(Q (1,J,L)-Q (1,J-1,L))/DYV(J)
        DTDY(J,L)=(T (1,J,L)-T (1,J-1,L))/DYV(J)
  100 CONTINUE
      DO 200 L=1,LM0
       PSAV=0.5*(P(1,1)+P(1,2))
       !CAS FLUXQL=FDIFF*DQDY(2,L)*DXV(2)*PSAV*DTDIF
       FLUXQL=FDIFFQ*DQDY(2,L)*DXV(2)*PSAV*DTDIF
       FLUXQL=DMAX1( -0.5*QT(1,2,L), DMIN1(0.5*QT(1,1,L),FLUXQL))
       FLUXTL=FDIFF*DTDY(2,L)*DXV(2)*PSAV*DTDIF
       QT (1,1,L)=QT (1,1,L)+FLUXQL
       TT (1,1,L)=TT (1,1,L)+FLUXTL
       DO 210 J=2,JMM1
         PSAV=0.5*(P(1,J)+P(1,J+1))
         !CAS FLUXQR=FDIFF*DQDY(J+1,L)*DXV(J+1)*PSAV*DTDIF
         FLUXQR=FDIFFQ*DQDY(J+1,L)*DXV(J+1)*PSAV*DTDIF
         FLUXQR=DMAX1( -0.5*QT(1,J+1,L), DMIN1(0.5*QT(1,J,L),FLUXQR))
         FLUXTR=FDIFF*DTDY(J+1,L)*DXV(J+1)*PSAV*DTDIF
         QT (1,J,L)=QT (1,J,L)+(FLUXQR-FLUXQL)
         TT (1,J,L)=TT (1,J,L)+(FLUXTR-FLUXTL)
         VQHD(J,L)=-FLUXQL/(DXV(J)*0.5*(P(1,J)+P(1,J-1))*DTDIF) 
         VTHD(J,L)=-FLUXTL/(DXV(J)*0.5*(P(1,J)+P(1,J-1))*DTDIF) 
         FLUXQL=FLUXQR
         FLUXTL=FLUXTR
  210  CONTINUE
         QT (1,JM,L)=QT (1,JM,L)-FLUXQR
         TT (1,JM,L)=TT (1,JM,L)-FLUXTR
         J=JM
         VQHD(J,L)=-FLUXQL/(DXV(J)*0.5*(P(1,J)+P(1,J-1))*DTDIF) 
         VTHD(J,L)=-FLUXTL/(DXV(J)*0.5*(P(1,J)+P(1,J-1))*DTDIF) 
  200 CONTINUE
      DO 300 L=1,LM0
      DO 300 J=1,JM0
        Q (I,J,L)=QT (I,J,L)/FD(I,J)
        T (I,J,L)=TT (I,J,L)/FD(I,J)
       AJL(J,L,56)=AJL(J,L,56)+Q (I,J,L)*P(I,J)
  300 CONTINUE
      DOPK=1.  
      FD(I,1)=2.*FD(I,1)      
      FD(I,JM)=2.*FD(I,JM)     
      DO 65 J=2,JM           
      FDU=.5*(FD(I,J)+FD(I,J-1))   
      DO 65 L=1,LM
      VT(I,J,L)=V(I,J,L)*FDU  
 65   UT(I,J,L)=U(I,J,L)*FDU  
      DO 110 L=1,LM0
      DO 110 J=3,JM0
        DUDY(J,L)=(U (1,J,L)-U (1,J-1,L))/DYP(J)
        DVDY(J,L)=(V (1,J,L)-V (1,J-1,L))/DYP(J)
  110 CONTINUE
      DO 400 L=1,LM0
       PSAV=P(1,2)
       FLUXVL=FDIFU*DVDY(3,L)*DXP(2)*PSAV*DTDIF
       FLUXUL=FDIFU*DUDY(3,L)*DXP(2)*PSAV*DTDIF
       VT (1,2,L)=VT (1,2,L)+FLUXVL
       UT (1,2,L)=UT (1,2,L)+FLUXUL
       DO 410 J=3,JMM1
         PSAV=P(1,J)
         FLUXVR=FDIFU*DVDY(J+1,L)*DXP(J)*PSAV*DTDIF
         FLUXUR=FDIFU*DUDY(J+1,L)*DXP(J)*PSAV*DTDIF
         VT (1,J,L)=VT (1,J,L)+(FLUXVR-FLUXVL)
         UT (1,J,L)=UT (1,J,L)+(FLUXUR-FLUXUL)
         VVHD(J-1,L)=-FLUXVL/(DXP(J-1)*P(1,J-1)*DTDIF) 
         VUHD(J-1,L)=-FLUXUL/(DXP(J-1)*P(1,J-1)*DTDIF) 
         FLUXVL=FLUXVR
         FLUXUL=FLUXUR
  410  CONTINUE
         VT (1,JM,L)=VT (1,JM,L)-FLUXVR
         UT (1,JM,L)=UT (1,JM,L)-FLUXUR
         J=JM
         VVHD(J-1,L)=-FLUXVL/(DXP(J-1)*P(1,J-1)*DTDIF) 
         VUHD(J-1,L)=-FLUXUL/(DXP(J-1)*P(1,J-1)*DTDIF) 
  400 CONTINUE
      DO 75 J=2,JM           
      RFDU=2./(FD(I,J)+FD(I,J-1))   
      DO 75 L=1,LM0
      V(I,J,L)=VT(I,J,L)*RFDU  
      U(I,J,L)=UT(I,J,L)*RFDU  
#if ( defined HR_DATA )
       if(L.le.4)then
        uyzhr(L,J)=U(I,J,L)
        vyzhr(L,J)=V(I,J,L)
       endif
#endif
 75   CONTINUE
      RETURN 
      END
1	jscott	1.1
2			#include "ctrparam.h"
3
4			! ==========================================================
5			!
6			! HORDIFF.F: subroutine for calculating horizontal
7			! diffusion of Q.
8			!
9			! ----------------------------------------------------------
10			!
11			! Revision History:
12			!
13			! When Who What
14			! ---- ---------- -------
15			! 080100 Chien Wang repack based on CliChem3 & M24x11,
16			! and add cpp.
17			!
18			! ==========================================================
19
20			SUBROUTINE HORDIFFALL(DTDIF)
21			#include "BD2G04.COM"
22			COMMON U,V,T,P,Q
23			DIMENSION VT(IM0,JM0,LM0),TT(IM0,JM0,LM0),PT(IM0,JM0),
24			& QT(IM0,JM0,LM0),PU(IM0,JM0),FD(IM0,JM0),DQDY(JM0,LM0)
25			& ,DTDY(JM0,LM0),DUDY(JM0,LM0),DVDY(JM0,LM0)
26			& ,UT(IM0,JM0,LM0)
27			COMMON/HDFLUX/VQHD(JM0,LM0),VTHD(JM0,LM0),VUHD(JM0,LM0),
28			& VVHD(JM0,LM0)
29			logical first
30			data first /.true./
31			I=1
32			JMM1=JM0-1
33			FDIFU=5.0E5
34			FDIFU=2.50E5
35
36			FDIFF=5.0E5
37
38			FDIFFQ=5.0E5
39			FDIFFQ=1.00E6
40
41			if(first)then
42			print *,' HOR DIFF for Q and T'
43			print *,' FDIFF=',FDIFF,' FDIFFQ=',FDIFFQ
44			print *,' HOR DIFF for U and V'
45			print *,' FDIFU=',FDIFU
46			print *,'IM0=',IM0,' JM0=',JM0,' LM0=',LM0
47			print *,'IM=',IM,' JM=',JM,' LM=',LM
48			first=.false.
49			endif
50			DO 50 J=1,JM0
51			50 FD(I,J)=P(I,J)*DXYP(J)
52			DO 57 L=1,LM0
53			DO 57 J=1,JM0
54			AJL(J,L,56)=AJL(J,L,56)-Q (I,J,L)*P(I,J)
55			TT (I,J,L)=T (I,J,L)*FD(I,J)
56			57 QT (I,J,L)=Q (I,J,L)*FD(I,J)
57			DO 100 L=1,LM0
58			DO 100 J=2,JM0
59			DQDY(J,L)=(Q (1,J,L)-Q (1,J-1,L))/DYV(J)
60			DTDY(J,L)=(T (1,J,L)-T (1,J-1,L))/DYV(J)
61			100 CONTINUE
62			DO 200 L=1,LM0
63			PSAV=0.5*(P(1,1)+P(1,2))
64			!CAS FLUXQL=FDIFFDQDY(2,L)DXV(2)PSAVDTDIF
65			FLUXQL=FDIFFQDQDY(2,L)DXV(2)PSAVDTDIF
66			FLUXQL=DMAX1( -0.5QT(1,2,L), DMIN1(0.5QT(1,1,L),FLUXQL))
67			FLUXTL=FDIFFDTDY(2,L)DXV(2)PSAVDTDIF
68			QT (1,1,L)=QT (1,1,L)+FLUXQL
69			TT (1,1,L)=TT (1,1,L)+FLUXTL
70			DO 210 J=2,JMM1
71			PSAV=0.5*(P(1,J)+P(1,J+1))
72			!CAS FLUXQR=FDIFFDQDY(J+1,L)DXV(J+1)PSAVDTDIF
73			FLUXQR=FDIFFQDQDY(J+1,L)DXV(J+1)PSAVDTDIF
74			FLUXQR=DMAX1( -0.5QT(1,J+1,L), DMIN1(0.5QT(1,J,L),FLUXQR))
75			FLUXTR=FDIFFDTDY(J+1,L)DXV(J+1)PSAVDTDIF
76			QT (1,J,L)=QT (1,J,L)+(FLUXQR-FLUXQL)
77			TT (1,J,L)=TT (1,J,L)+(FLUXTR-FLUXTL)
78			VQHD(J,L)=-FLUXQL/(DXV(J)0.5(P(1,J)+P(1,J-1))*DTDIF)
79			VTHD(J,L)=-FLUXTL/(DXV(J)0.5(P(1,J)+P(1,J-1))*DTDIF)
80			FLUXQL=FLUXQR
81			FLUXTL=FLUXTR
82			210 CONTINUE
83			QT (1,JM,L)=QT (1,JM,L)-FLUXQR
84			TT (1,JM,L)=TT (1,JM,L)-FLUXTR
85			J=JM
86			VQHD(J,L)=-FLUXQL/(DXV(J)0.5(P(1,J)+P(1,J-1))*DTDIF)
87			VTHD(J,L)=-FLUXTL/(DXV(J)0.5(P(1,J)+P(1,J-1))*DTDIF)
88			200 CONTINUE
89			DO 300 L=1,LM0
90			DO 300 J=1,JM0
91			Q (I,J,L)=QT (I,J,L)/FD(I,J)
92			T (I,J,L)=TT (I,J,L)/FD(I,J)
93			AJL(J,L,56)=AJL(J,L,56)+Q (I,J,L)*P(I,J)
94			300 CONTINUE
95			DOPK=1.
96			FD(I,1)=2.*FD(I,1)
97			FD(I,JM)=2.*FD(I,JM)
98			DO 65 J=2,JM
99			FDU=.5*(FD(I,J)+FD(I,J-1))
100			DO 65 L=1,LM
101			VT(I,J,L)=V(I,J,L)*FDU
102			65 UT(I,J,L)=U(I,J,L)*FDU
103			DO 110 L=1,LM0
104			DO 110 J=3,JM0
105			DUDY(J,L)=(U (1,J,L)-U (1,J-1,L))/DYP(J)
106			DVDY(J,L)=(V (1,J,L)-V (1,J-1,L))/DYP(J)
107			110 CONTINUE
108			DO 400 L=1,LM0
109			PSAV=P(1,2)
110			FLUXVL=FDIFUDVDY(3,L)DXP(2)PSAVDTDIF
111			FLUXUL=FDIFUDUDY(3,L)DXP(2)PSAVDTDIF
112			VT (1,2,L)=VT (1,2,L)+FLUXVL
113			UT (1,2,L)=UT (1,2,L)+FLUXUL
114			DO 410 J=3,JMM1
115			PSAV=P(1,J)
116			FLUXVR=FDIFUDVDY(J+1,L)DXP(J)PSAVDTDIF
117			FLUXUR=FDIFUDUDY(J+1,L)DXP(J)PSAVDTDIF
118			VT (1,J,L)=VT (1,J,L)+(FLUXVR-FLUXVL)
119			UT (1,J,L)=UT (1,J,L)+(FLUXUR-FLUXUL)
120			VVHD(J-1,L)=-FLUXVL/(DXP(J-1)P(1,J-1)DTDIF)
121			VUHD(J-1,L)=-FLUXUL/(DXP(J-1)P(1,J-1)DTDIF)
122			FLUXVL=FLUXVR
123			FLUXUL=FLUXUR
124			410 CONTINUE
125			VT (1,JM,L)=VT (1,JM,L)-FLUXVR
126			UT (1,JM,L)=UT (1,JM,L)-FLUXUR
127			J=JM
128			VVHD(J-1,L)=-FLUXVL/(DXP(J-1)P(1,J-1)DTDIF)
129			VUHD(J-1,L)=-FLUXUL/(DXP(J-1)P(1,J-1)DTDIF)
130			400 CONTINUE
131			DO 75 J=2,JM
132			RFDU=2./(FD(I,J)+FD(I,J-1))
133			DO 75 L=1,LM0
134			V(I,J,L)=VT(I,J,L)*RFDU
135			U(I,J,L)=UT(I,J,L)*RFDU
136			#if ( defined HR_DATA )
137			if(L.le.4)then
138			uyzhr(L,J)=U(I,J,L)
139			vyzhr(L,J)=V(I,J,L)
140			endif
141			#endif
142			75 CONTINUE
143			RETURN
144			END