pkg/generic_advdiff/gad_dst3_adv_r.F

C $Header: $
C $Name: $

#include "GAD_OPTIONS.h"

      SUBROUTINE GAD_DST3_ADV_R( 
     I           bi_arg,bj_arg,k,dTarg,
     I           rTrans, wVel,
     I           tracer,
     O           wT,
     I           myThid )
C     /==========================================================\
C     | SUBROUTINE GAD_DST3_ADV_R                                |
C     | o Compute Vertical advective Flux of Tracer using        |
C     |   3rd Order DST Sceheme                                  |
C     |==========================================================|
      IMPLICIT NONE

C     == GLobal variables ==
#include "SIZE.h"
#include "GRID.h"
#include "EEPARAMS.h"
#include "PARAMS.h"
#include "GAD.h"

C     == Routine arguments ==
      INTEGER bi_arg,bj_arg,k
      _RL dTarg
      _RL rTrans(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL wVel(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr,nSx,nSy)
      _RL tracer(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr,nSx,nSy)
      _RL wT    (1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      INTEGER myThid

C     == Local variables ==
      INTEGER i,j,kp1,km1,km2,bi,bj
      _RL Rjm,Rj,Rjp,cfl,d0,d1
      _RL psiP,psiM,thetaP,thetaM

      IF (.NOT. multiDimAdvection) THEN
C      If using the standard time-stepping/advection schemes (ie. AB-II)
C      then the data-structures are all global arrays
       bi=bi_arg
       bj=bj_arg
      ELSE
C      otherwise if using the multi-dimensional advection schemes
C      then the data-structures are all local arrays except
C      for maskC(...) and wVel(...)
       bi=1
       bj=1
      ENDIF

      km2=MAX(1,k-2)
      km1=MAX(1,k-1)
      kp1=MIN(Nr,k+1)

      DO j=1-Oly,sNy+Oly
       DO i=1-Olx,sNx+Olx
        Rjp=(tracer(i,j,k,bi,bj)-tracer(i,j,kp1,bi,bj))
     &         *maskC(i,j,kp1,bi,bj)
        Rj =(tracer(i,j,km1,bi,bj)-tracer(i,j,k,bi,bj))
     &         *maskC(i,j,k,bi,bj)*maskC(i,j,km1,bi,bj)
        Rjm=(tracer(i,j,km2,bi,bj)-tracer(i,j,km1,bi,bj))
     &         *maskC(i,j,km1,bi,bj)

        cfl=abs(wVel(i,j,k,bi,bj)*dTarg*recip_drc(k))
        d0=(2.-cfl)*(1.-cfl)*oneSixth
        d1=(1.-cfl*cfl)*oneSixth
c       thetaP=0.
c       IF (Rj.NE.0.) thetaP=Rjm/Rj
        thetaP=Rjm/(1.D-20+Rj)
        psiP=d0+d1*thetaP
c       psiP=max(0.,min(min(1.,psiP),(1.-cfl)/(1.D-20+cfl)*thetaP))
        thetaM=Rjp/(1.D-20+Rj)
c       thetaM=0.
c       IF (Rj.NE.0.) thetaM=Rjp/Rj
        psiM=d0+d1*thetaM
c       psiM=max(0.,min(min(1.,psiM),(1.-cfl)/(1.D-20+cfl)*thetaM))
        wT(i,j)=
     &   0.5*(rTrans(i,j)+abs(rTrans(i,j)))
     &      *( Tracer(i,j, k ,bi,bj) + psiM*Rj )
     &  +0.5*(rTrans(i,j)-abs(rTrans(i,j)))
     &      *( Tracer(i,j,km1,bi,bj) - psiP*Rj )

       ENDDO
      ENDDO

      RETURN
      END
1	C $Header: $
2	C $Name: $
3
4	#include "GAD_OPTIONS.h"
5
6	SUBROUTINE GAD_DST3_ADV_R(
7	I bi_arg,bj_arg,k,dTarg,
8	I rTrans, wVel,
9	I tracer,
10	O wT,
11	I myThid )
12	C /==========================================================\
13	C \| SUBROUTINE GAD_DST3_ADV_R \|
14	C \| o Compute Vertical advective Flux of Tracer using \|
15	C \| 3rd Order DST Sceheme \|
16	C \|==========================================================\|
17	IMPLICIT NONE
18
19	C == GLobal variables ==
20	#include "SIZE.h"
21	#include "GRID.h"
22	#include "EEPARAMS.h"
23	#include "PARAMS.h"
24	#include "GAD.h"
25
26	C == Routine arguments ==
27	INTEGER bi_arg,bj_arg,k
28	_RL dTarg
29	_RL rTrans(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
30	_RL wVel(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr,nSx,nSy)
31	_RL tracer(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr,nSx,nSy)
32	_RL wT (1-OLx:sNx+OLx,1-OLy:sNy+OLy)
33	INTEGER myThid
34
35	C == Local variables ==
36	INTEGER i,j,kp1,km1,km2,bi,bj
37	_RL Rjm,Rj,Rjp,cfl,d0,d1
38	_RL psiP,psiM,thetaP,thetaM
39
40	IF (.NOT. multiDimAdvection) THEN
41	C If using the standard time-stepping/advection schemes (ie. AB-II)
42	C then the data-structures are all global arrays
43	bi=bi_arg
44	bj=bj_arg
45	ELSE
46	C otherwise if using the multi-dimensional advection schemes
47	C then the data-structures are all local arrays except
48	C for maskC(...) and wVel(...)
49	bi=1
50	bj=1
51	ENDIF
52
53	km2=MAX(1,k-2)
54	km1=MAX(1,k-1)
55	kp1=MIN(Nr,k+1)
56
57	DO j=1-Oly,sNy+Oly
58	DO i=1-Olx,sNx+Olx
59	Rjp=(tracer(i,j,k,bi,bj)-tracer(i,j,kp1,bi,bj))
60	& *maskC(i,j,kp1,bi,bj)
61	Rj =(tracer(i,j,km1,bi,bj)-tracer(i,j,k,bi,bj))
62	& maskC(i,j,k,bi,bj)maskC(i,j,km1,bi,bj)
63	Rjm=(tracer(i,j,km2,bi,bj)-tracer(i,j,km1,bi,bj))
64	& *maskC(i,j,km1,bi,bj)
65
66	cfl=abs(wVel(i,j,k,bi,bj)dTargrecip_drc(k))
67	d0=(2.-cfl)(1.-cfl)oneSixth
68	d1=(1.-cflcfl)oneSixth
69	c thetaP=0.
70	c IF (Rj.NE.0.) thetaP=Rjm/Rj
71	thetaP=Rjm/(1.D-20+Rj)
72	psiP=d0+d1*thetaP
73	c psiP=max(0.,min(min(1.,psiP),(1.-cfl)/(1.D-20+cfl)*thetaP))
74	thetaM=Rjp/(1.D-20+Rj)
75	c thetaM=0.
76	c IF (Rj.NE.0.) thetaM=Rjp/Rj
77	psiM=d0+d1*thetaM
78	c psiM=max(0.,min(min(1.,psiM),(1.-cfl)/(1.D-20+cfl)*thetaM))
79	wT(i,j)=
80	& 0.5*(rTrans(i,j)+abs(rTrans(i,j)))
81	& ( Tracer(i,j, k ,bi,bj) + psiMRj )
82	& +0.5*(rTrans(i,j)-abs(rTrans(i,j)))
83	& ( Tracer(i,j,km1,bi,bj) - psiPRj )
84
85	ENDDO
86	ENDDO
87
88	RETURN
89	END