model/src/ini_spherical_polar_grid.F

C $Header: /u/gcmpack/models/MITgcmUV/model/src/ini_spherical_polar_grid.F,v 1.19 2001/09/26 18:09:15 cnh Exp $
C $Name:  $

#include "CPP_OPTIONS.h"

#undef  USE_BACKWARD_COMPATIBLE_GRID

CBOP
C     !ROUTINE: INI_SPHERICAL_POLAR_GRID
C     !INTERFACE:
      SUBROUTINE INI_SPHERICAL_POLAR_GRID( myThid )
C     !DESCRIPTION: \bv
C     /==========================================================\
C     | SUBROUTINE INI_SPHERICAL_POLAR_GRID                      |
C     | o Initialise model coordinate system arrays              |
C     |==========================================================|
C     | These arrays are used throughout the code in evaluating  |
C     | gradients, integrals and spatial avarages. This routine  |
C     | is called separately by each thread and initialise only  |
C     | the region of the domain it is "responsible" for.        |
C     | Under the spherical polar grid mode primitive distances  |
C     | in X and Y are in degrees. Distance in Z are in m or Pa  |
C     | depending on the vertical gridding mode.                 |
C     \==========================================================/
C     \ev

C     !USES:
      IMPLICIT NONE
C     === Global variables ===
#include "SIZE.h"
#include "EEPARAMS.h"
#include "PARAMS.h"
#include "GRID.h"

C     !INPUT/OUTPUT PARAMETERS:
C     == Routine arguments ==
C     myThid -  Number of this instance of INI_CARTESIAN_GRID
      INTEGER myThid
CEndOfInterface

C     !LOCAL VARIABLES:
C     == Local variables ==
C     xG, yG - Global coordinate location.
C     xBase  - South-west corner location for process.
C     yBase
C     zUpper - Work arrays for upper and lower 
C     zLower   cell-face heights.
C     phi    - Temporary scalar
C     iG, jG - Global coordinate index. Usually used to hold
C              the south-west global coordinate of a tile.
C     bi,bj  - Loop counters
C     zUpper - Temporary arrays holding z coordinates of
C     zLower   upper and lower faces.
C     xBase  - Lower coordinate for this threads cells
C     yBase
C     lat, latN, - Temporary variables used to hold latitude
C     latS         values.
C     I,J,K
      INTEGER iG, jG
      INTEGER bi, bj
      INTEGER  I,  J
      _RL lat, dlat, dlon, xG0, yG0


C     "Long" real for temporary coordinate calculation
C      NOTICE the extended range of indices!!
      _RL xGloc(1-Olx:sNx+Olx+1,1-Oly:sNy+Oly+1)
      _RL yGloc(1-Olx:sNx+Olx+1,1-Oly:sNy+Oly+1)

C     The functions iGl, jGl return the "global" index with valid values beyond
C     halo regions
C     cnh wrote:
C     >    I dont understand why we would ever have to multiply the
C     >    overlap by the total domain size e.g
C     >    OLx*Nx, OLy*Ny.
C     >    Can anybody explain? Lines are in ini_spherical_polar_grid.F.
C     >    Surprised the code works if its wrong, so I am puzzled.        
C     jmc replied:
C     Yes, I can explain this since I put this modification to work
C     with small domain (where Oly > Ny, as for instance, zonal-average
C     case):
C     This has no effect on the acuracy of the evaluation of iGl(I,bi)
C     and jGl(J,bj) since we take mod(a+OLx*Nx,Nx) and mod(b+OLy*Ny,Ny).
C     But in case a or b is negative, then the FORTRAN function "mod"
C     does not return the matematical value of the "modulus" function,
C     and this is not good for your purpose.
C     This is why I add +OLx*Nx and +OLy*Ny to be sure that the 1rst 
C     argument of the mod function is positive.
      INTEGER iGl,jGl
      iGl(I,bi) = 1+mod(myXGlobalLo-1+(bi-1)*sNx+I+Olx*Nx-1,Nx)
      jGl(J,bj) = 1+mod(myYGlobalLo-1+(bj-1)*sNy+J+Oly*Ny-1,Ny)
CEOP


C     For each tile ...
      DO bj = myByLo(myThid), myByHi(myThid)
       DO bi = myBxLo(myThid), myBxHi(myThid)

C--     "Global" index (place holder)
        jG = myYGlobalLo + (bj-1)*sNy
        iG = myXGlobalLo + (bi-1)*sNx

C--   First find coordinate of tile corner (meaning outer corner of halo)
        xG0 = thetaMin
C       Find the X-coordinate of the outer grid-line of the "real" tile
        DO i=1, iG-1
         xG0 = xG0 + delX(i)
        ENDDO
C       Back-step to the outer grid-line of the "halo" region
        DO i=1, Olx
         xG0 = xG0 - delX( 1+mod(Olx*Nx-1+iG-i,Nx) )
        ENDDO
C       Find the Y-coordinate of the outer grid-line of the "real" tile
        yG0 = phiMin
        DO j=1, jG-1
         yG0 = yG0 + delY(j)
        ENDDO
C       Back-step to the outer grid-line of the "halo" region
        DO j=1, Oly
         yG0 = yG0 - delY( 1+mod(Oly*Ny-1+jG-j,Ny) )
        ENDDO

C--     Calculate coordinates of cell corners for N+1 grid-lines
        DO J=1-Oly,sNy+Oly +1
         xGloc(1-Olx,J) = xG0
         DO I=1-Olx,sNx+Olx
c         xGloc(I+1,J) = xGloc(I,J) + delX(1+mod(Nx-1+iG-1+i,Nx))
          xGloc(I+1,J) = xGloc(I,J) + delX( iGl(I,bi) )
         ENDDO
        ENDDO
        DO I=1-Olx,sNx+Olx +1
         yGloc(I,1-Oly) = yG0
         DO J=1-Oly,sNy+Oly
c         yGloc(I,J+1) = yGloc(I,J) + delY(1+mod(Ny-1+jG-1+j,Ny))
          yGloc(I,J+1) = yGloc(I,J) + delY( jGl(J,bj) )
         ENDDO
        ENDDO

C--     Make a permanent copy of [xGloc,yGloc] in [xG,yG]
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
          xG(I,J,bi,bj) = xGloc(I,J)
          yG(I,J,bi,bj) = yGloc(I,J)
         ENDDO
        ENDDO

C--     Calculate [xC,yC], coordinates of cell centers
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
C         by averaging
          xC(I,J,bi,bj) = 0.25*( 
     &     xGloc(I,J)+xGloc(I+1,J)+xGloc(I,J+1)+xGloc(I+1,J+1) )
          yC(I,J,bi,bj) = 0.25*( 
     &     yGloc(I,J)+yGloc(I+1,J)+yGloc(I,J+1)+yGloc(I+1,J+1) )
         ENDDO
        ENDDO

C--     Calculate [dxF,dyF], lengths between cell faces (through center)
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
C         by averaging
c         dXF(I,J,bi,bj) = 0.5*(dXG(I,J,bi,bj)+dXG(I,J+1,bi,bj))
c         dYF(I,J,bi,bj) = 0.5*(dYG(I,J,bi,bj)+dYG(I+1,J,bi,bj))
C         by formula
          lat = yC(I,J,bi,bj)
          dlon = delX( iGl(I,bi) )
          dlat = delY( jGl(J,bj) )
          dXF(I,J,bi,bj) = rSphere*COS(deg2rad*lat)*dlon*deg2rad
#ifdef    USE_BACKWARD_COMPATIBLE_GRID
          dXF(I,J,bi,bj) = delX(iGl(I,bi))*deg2rad*rSphere*
     &                     COS(yc(I,J,bi,bj)*deg2rad)
#endif    /* USE_BACKWARD_COMPATIBLE_GRID */
          dYF(I,J,bi,bj) = rSphere*dlat*deg2rad
         ENDDO
        ENDDO

C--     Calculate [dxG,dyG], lengths along cell boundaries
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
C         by averaging
c         dXG(I,J,bi,bj) = 0.5*(dXF(I,J,bi,bj)+dXF(I,J-1,bi,bj))
c         dYG(I,J,bi,bj) = 0.5*(dYF(I,J,bi,bj)+dYF(I-1,J,bi,bj))
C         by formula
          lat = 0.5*(yGloc(I,J)+yGloc(I+1,J))
          dlon = delX( iGl(I,bi) )
          dlat = delY( jGl(J,bj) )
          dXG(I,J,bi,bj) = rSphere*COS(deg2rad*lat)*dlon*deg2rad
          if (dXG(I,J,bi,bj).LT.1.) dXG(I,J,bi,bj)=0.
          dYG(I,J,bi,bj) = rSphere*dlat*deg2rad
         ENDDO
        ENDDO

C--     The following arrays are not defined in some parts of the halo
C       region. We set them to zero here for safety. If they are ever
C       referred to, especially in the denominator then it is a mistake!
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
          dXC(I,J,bi,bj) = 0.
          dYC(I,J,bi,bj) = 0.
          dXV(I,J,bi,bj) = 0.
          dYU(I,J,bi,bj) = 0.
          rAw(I,J,bi,bj) = 0.
          rAs(I,J,bi,bj) = 0.
         ENDDO
        ENDDO

C--     Calculate [dxC], zonal length between cell centers
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx+1,sNx+Olx ! NOTE range
C         by averaging
          dXC(I,J,bi,bj) = 0.5D0*(dXF(I,J,bi,bj)+dXF(I-1,J,bi,bj))
C         by formula
c         lat = 0.5*(yC(I,J,bi,bj)+yC(I-1,J,bi,bj))
c         dlon = 0.5*(delX( iGl(I,bi) ) + delX( iGl(I-1,bi) ))
c         dXC(I,J,bi,bj) = rSphere*COS(deg2rad*lat)*dlon*deg2rad
C         by difference
c         lat = 0.5*(yC(I,J,bi,bj)+yC(I-1,J,bi,bj))
c         dlon = (xC(I,J,bi,bj)+xC(I-1,J,bi,bj))
c         dXC(I,J,bi,bj) = rSphere*COS(deg2rad*lat)*dlon*deg2rad
         ENDDO
        ENDDO

C--     Calculate [dyC], meridional length between cell centers
        DO J=1-Oly+1,sNy+Oly ! NOTE range
         DO I=1-Olx,sNx+Olx
C         by averaging
          dYC(I,J,bi,bj) = 0.5*(dYF(I,J,bi,bj)+dYF(I,J-1,bi,bj))
C         by formula
c         dlat = 0.5*(delY( jGl(J,bj) ) + delY( jGl(J-1,bj) ))
c         dYC(I,J,bi,bj) = rSphere*dlat*deg2rad
C         by difference
c         dlat = (yC(I,J,bi,bj)+yC(I,J-1,bi,bj))
c         dYC(I,J,bi,bj) = rSphere*dlat*deg2rad
         ENDDO
        ENDDO

C--     Calculate [dxV,dyU], length between velocity points (through corners)
        DO J=1-Oly+1,sNy+Oly ! NOTE range
         DO I=1-Olx+1,sNx+Olx ! NOTE range
C         by averaging (method I)
          dXV(I,J,bi,bj) = 0.5*(dXG(I,J,bi,bj)+dXG(I-1,J,bi,bj))
          dYU(I,J,bi,bj) = 0.5*(dYG(I,J,bi,bj)+dYG(I,J-1,bi,bj))
C         by averaging (method II)
c         dXV(I,J,bi,bj) = 0.5*(dXG(I,J,bi,bj)+dXG(I-1,J,bi,bj))
c         dYU(I,J,bi,bj) = 0.5*(dYC(I,J,bi,bj)+dYC(I-1,J,bi,bj))
         ENDDO
        ENDDO

C--     Calculate vertical face area (tracer cells)
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
          lat=0.5*(yGloc(I,J)+yGloc(I+1,J))
          dlon=delX( iGl(I,bi) )
          dlat=delY( jGl(J,bj) )
          rA(I,J,bi,bj) = rSphere*rSphere*dlon*deg2rad
     &        *abs( sin((lat+dlat)*deg2rad)-sin(lat*deg2rad) )
#ifdef    USE_BACKWARD_COMPATIBLE_GRID
          lat=yC(I,J,bi,bj)-delY( jGl(J,bj) )*0.5 _d 0
          lon=yC(I,J,bi,bj)+delY( jGl(J,bj) )*0.5 _d 0
          rA(I,J,bi,bj) = dyF(I,J,bi,bj)
     &    *rSphere*(SIN(lon*deg2rad)-SIN(lat*deg2rad))
#endif    /* USE_BACKWARD_COMPATIBLE_GRID */
         ENDDO
        ENDDO

C--     Calculate vertical face area (u cells)
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx+1,sNx+Olx ! NOTE range
C         by averaging
          rAw(I,J,bi,bj) = 0.5*(rA(I,J,bi,bj)+rA(I-1,J,bi,bj))
C         by formula
c         lat=yGloc(I,J)
c         dlon=0.5*( delX( iGl(I,bi) ) + delX( iGl(I-1,bi) ) )
c         dlat=delY( jGl(J,bj) )
c         rAw(I,J,bi,bj) = rSphere*rSphere*dlon*deg2rad
c    &        *abs( sin((lat+dlat)*deg2rad)-sin(lat*deg2rad) )
         ENDDO
        ENDDO

C--     Calculate vertical face area (v cells)
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
C         by formula
          lat=yC(I,J,bi,bj)
          dlon=delX( iGl(I,bi) )
          dlat=0.5*( delY( jGl(J,bj) ) + delY( jGl(J-1,bj) ) )
          rAs(I,J,bi,bj) = rSphere*rSphere*dlon*deg2rad
     &        *abs( sin(lat*deg2rad)-sin((lat-dlat)*deg2rad) )
#ifdef    USE_BACKWARD_COMPATIBLE_GRID
          lon=yC(I,J,bi,bj)-delY( jGl(J,bj) )
          lat=yC(I,J,bi,bj)
          rAs(I,J,bi,bj) = rSphere*delX(iGl(I,bi))*deg2rad
     &    *rSphere*(SIN(lat*deg2rad)-SIN(lon*deg2rad))
#endif    /* USE_BACKWARD_COMPATIBLE_GRID */
          IF (abs(lat).GT.90..OR.abs(lat-dlat).GT.90.) rAs(I,J,bi,bj)=0.
         ENDDO
        ENDDO

C--     Calculate vertical face area (vorticity points)
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
C         by formula
          lat=yC(I,J,bi,bj)
          dlon=delX( iGl(I,bi) )
          dlat=0.5*( delY( jGl(J,bj) ) + delY( jGl(J-1,bj) ) )
          rAz(I,J,bi,bj) = rSphere*rSphere*dlon*deg2rad
     &     *abs( sin(lat*deg2rad)-sin((lat-dlat)*deg2rad) )
          IF (abs(lat).GT.90..OR.abs(lat-dlat).GT.90.) rAz(I,J,bi,bj)=0.
         ENDDO
        ENDDO

C--     Calculate trigonometric terms
        DO J=1-Oly,sNy+Oly
         DO I=1-Olx,sNx+Olx
          lat=0.5*(yGloc(I,J)+yGloc(I,J+1))
          tanPhiAtU(i,j,bi,bj)=tan(lat*deg2rad)
          lat=0.5*(yGloc(I,J)+yGloc(I+1,J))
          tanPhiAtV(i,j,bi,bj)=tan(lat*deg2rad)
         ENDDO
        ENDDO

C--     Cosine(lat) scaling
        DO J=1-OLy,sNy+OLy
         jG = myYGlobalLo + (bj-1)*sNy + J-1
         jG = min(max(1,jG),Ny)
         IF (cosPower.NE.0.) THEN
          cosFacU(J,bi,bj)=COS(yC(1,J,bi,bj)*deg2rad)
     &                    **cosPower
          cosFacV(J,bi,bj)=COS((yC(1,J,bi,bj)-0.5*delY(jG))*deg2rad)
     &                    **cosPower
          sqcosFacU(J,bi,bj)=sqrt(cosFacU(J,bi,bj))
          sqcosFacV(J,bi,bj)=sqrt(cosFacV(J,bi,bj))
         ELSE
          cosFacU(J,bi,bj)=1.
          cosFacV(J,bi,bj)=1.
          sqcosFacU(J,bi,bj)=1.
          sqcosFacV(J,bi,bj)=1.
         ENDIF
        ENDDO

       ENDDO ! bi
      ENDDO ! bj

      RETURN
      END
1	C $Header: /u/gcmpack/models/MITgcmUV/model/src/ini_spherical_polar_grid.F,v 1.19 2001/09/26 18:09:15 cnh Exp $
2	C $Name: $
3
4	#include "CPP_OPTIONS.h"
5
6	#undef USE_BACKWARD_COMPATIBLE_GRID
7
8	CBOP
9	C !ROUTINE: INI_SPHERICAL_POLAR_GRID
10	C !INTERFACE:
11	SUBROUTINE INI_SPHERICAL_POLAR_GRID( myThid )
12	C !DESCRIPTION: \bv
13	C /==========================================================\
14	C \| SUBROUTINE INI_SPHERICAL_POLAR_GRID \|
15	C \| o Initialise model coordinate system arrays \|
16	C \|==========================================================\|
17	C \| These arrays are used throughout the code in evaluating \|
18	C \| gradients, integrals and spatial avarages. This routine \|
19	C \| is called separately by each thread and initialise only \|
20	C \| the region of the domain it is "responsible" for. \|
21	C \| Under the spherical polar grid mode primitive distances \|
22	C \| in X and Y are in degrees. Distance in Z are in m or Pa \|
23	C \| depending on the vertical gridding mode. \|
24	C \==========================================================/
25	C \ev
26
27	C !USES:
28	IMPLICIT NONE
29	C === Global variables ===
30	#include "SIZE.h"
31	#include "EEPARAMS.h"
32	#include "PARAMS.h"
33	#include "GRID.h"
34
35	C !INPUT/OUTPUT PARAMETERS:
36	C == Routine arguments ==
37	C myThid - Number of this instance of INI_CARTESIAN_GRID
38	INTEGER myThid
39	CEndOfInterface
40
41	C !LOCAL VARIABLES:
42	C == Local variables ==
43	C xG, yG - Global coordinate location.
44	C xBase - South-west corner location for process.
45	C yBase
46	C zUpper - Work arrays for upper and lower
47	C zLower cell-face heights.
48	C phi - Temporary scalar
49	C iG, jG - Global coordinate index. Usually used to hold
50	C the south-west global coordinate of a tile.
51	C bi,bj - Loop counters
52	C zUpper - Temporary arrays holding z coordinates of
53	C zLower upper and lower faces.
54	C xBase - Lower coordinate for this threads cells
55	C yBase
56	C lat, latN, - Temporary variables used to hold latitude
57	C latS values.
58	C I,J,K
59	INTEGER iG, jG
60	INTEGER bi, bj
61	INTEGER I, J
62	_RL lat, dlat, dlon, xG0, yG0
63
64
65	C "Long" real for temporary coordinate calculation
66	C NOTICE the extended range of indices!!
67	_RL xGloc(1-Olx:sNx+Olx+1,1-Oly:sNy+Oly+1)
68	_RL yGloc(1-Olx:sNx+Olx+1,1-Oly:sNy+Oly+1)
69
70	C The functions iGl, jGl return the "global" index with valid values beyond
71	C halo regions
72	C cnh wrote:
73	C > I dont understand why we would ever have to multiply the
74	C > overlap by the total domain size e.g
75	C > OLxNx, OLyNy.
76	C > Can anybody explain? Lines are in ini_spherical_polar_grid.F.
77	C > Surprised the code works if its wrong, so I am puzzled.
78	C jmc replied:
79	C Yes, I can explain this since I put this modification to work
80	C with small domain (where Oly > Ny, as for instance, zonal-average
81	C case):
82	C This has no effect on the acuracy of the evaluation of iGl(I,bi)
83	C and jGl(J,bj) since we take mod(a+OLxNx,Nx) and mod(b+OLyNy,Ny).
84	C But in case a or b is negative, then the FORTRAN function "mod"
85	C does not return the matematical value of the "modulus" function,
86	C and this is not good for your purpose.
87	C This is why I add +OLxNx and +OLyNy to be sure that the 1rst
88	C argument of the mod function is positive.
89	INTEGER iGl,jGl
90	iGl(I,bi) = 1+mod(myXGlobalLo-1+(bi-1)sNx+I+OlxNx-1,Nx)
91	jGl(J,bj) = 1+mod(myYGlobalLo-1+(bj-1)sNy+J+OlyNy-1,Ny)
92	CEOP
93
94
95	C For each tile ...
96	DO bj = myByLo(myThid), myByHi(myThid)
97	DO bi = myBxLo(myThid), myBxHi(myThid)
98
99	C-- "Global" index (place holder)
100	jG = myYGlobalLo + (bj-1)*sNy
101	iG = myXGlobalLo + (bi-1)*sNx
102
103	C-- First find coordinate of tile corner (meaning outer corner of halo)
104	xG0 = thetaMin
105	C Find the X-coordinate of the outer grid-line of the "real" tile
106	DO i=1, iG-1
107	xG0 = xG0 + delX(i)
108	ENDDO
109	C Back-step to the outer grid-line of the "halo" region
110	DO i=1, Olx
111	xG0 = xG0 - delX( 1+mod(Olx*Nx-1+iG-i,Nx) )
112	ENDDO
113	C Find the Y-coordinate of the outer grid-line of the "real" tile
114	yG0 = phiMin
115	DO j=1, jG-1
116	yG0 = yG0 + delY(j)
117	ENDDO
118	C Back-step to the outer grid-line of the "halo" region
119	DO j=1, Oly
120	yG0 = yG0 - delY( 1+mod(Oly*Ny-1+jG-j,Ny) )
121	ENDDO
122
123	C-- Calculate coordinates of cell corners for N+1 grid-lines
124	DO J=1-Oly,sNy+Oly +1
125	xGloc(1-Olx,J) = xG0
126	DO I=1-Olx,sNx+Olx
127	c xGloc(I+1,J) = xGloc(I,J) + delX(1+mod(Nx-1+iG-1+i,Nx))
128	xGloc(I+1,J) = xGloc(I,J) + delX( iGl(I,bi) )
129	ENDDO
130	ENDDO
131	DO I=1-Olx,sNx+Olx +1
132	yGloc(I,1-Oly) = yG0
133	DO J=1-Oly,sNy+Oly
134	c yGloc(I,J+1) = yGloc(I,J) + delY(1+mod(Ny-1+jG-1+j,Ny))
135	yGloc(I,J+1) = yGloc(I,J) + delY( jGl(J,bj) )
136	ENDDO
137	ENDDO
138
139	C-- Make a permanent copy of [xGloc,yGloc] in [xG,yG]
140	DO J=1-Oly,sNy+Oly
141	DO I=1-Olx,sNx+Olx
142	xG(I,J,bi,bj) = xGloc(I,J)
143	yG(I,J,bi,bj) = yGloc(I,J)
144	ENDDO
145	ENDDO
146
147	C-- Calculate [xC,yC], coordinates of cell centers
148	DO J=1-Oly,sNy+Oly
149	DO I=1-Olx,sNx+Olx
150	C by averaging
151	xC(I,J,bi,bj) = 0.25*(
152	& xGloc(I,J)+xGloc(I+1,J)+xGloc(I,J+1)+xGloc(I+1,J+1) )
153	yC(I,J,bi,bj) = 0.25*(
154	& yGloc(I,J)+yGloc(I+1,J)+yGloc(I,J+1)+yGloc(I+1,J+1) )
155	ENDDO
156	ENDDO
157
158	C-- Calculate [dxF,dyF], lengths between cell faces (through center)
159	DO J=1-Oly,sNy+Oly
160	DO I=1-Olx,sNx+Olx
161	C by averaging
162	c dXF(I,J,bi,bj) = 0.5*(dXG(I,J,bi,bj)+dXG(I,J+1,bi,bj))
163	c dYF(I,J,bi,bj) = 0.5*(dYG(I,J,bi,bj)+dYG(I+1,J,bi,bj))
164	C by formula
165	lat = yC(I,J,bi,bj)
166	dlon = delX( iGl(I,bi) )
167	dlat = delY( jGl(J,bj) )
168	dXF(I,J,bi,bj) = rSphereCOS(deg2radlat)dlondeg2rad
169	#ifdef USE_BACKWARD_COMPATIBLE_GRID
170	dXF(I,J,bi,bj) = delX(iGl(I,bi))deg2radrSphere*
171	& COS(yc(I,J,bi,bj)*deg2rad)
172	#endif /* USE_BACKWARD_COMPATIBLE_GRID */
173	dYF(I,J,bi,bj) = rSpheredlatdeg2rad
174	ENDDO
175	ENDDO
176
177	C-- Calculate [dxG,dyG], lengths along cell boundaries
178	DO J=1-Oly,sNy+Oly
179	DO I=1-Olx,sNx+Olx
180	C by averaging
181	c dXG(I,J,bi,bj) = 0.5*(dXF(I,J,bi,bj)+dXF(I,J-1,bi,bj))
182	c dYG(I,J,bi,bj) = 0.5*(dYF(I,J,bi,bj)+dYF(I-1,J,bi,bj))
183	C by formula
184	lat = 0.5*(yGloc(I,J)+yGloc(I+1,J))
185	dlon = delX( iGl(I,bi) )
186	dlat = delY( jGl(J,bj) )
187	dXG(I,J,bi,bj) = rSphereCOS(deg2radlat)dlondeg2rad
188	if (dXG(I,J,bi,bj).LT.1.) dXG(I,J,bi,bj)=0.
189	dYG(I,J,bi,bj) = rSpheredlatdeg2rad
190	ENDDO
191	ENDDO
192
193	C-- The following arrays are not defined in some parts of the halo
194	C region. We set them to zero here for safety. If they are ever
195	C referred to, especially in the denominator then it is a mistake!
196	DO J=1-Oly,sNy+Oly
197	DO I=1-Olx,sNx+Olx
198	dXC(I,J,bi,bj) = 0.
199	dYC(I,J,bi,bj) = 0.
200	dXV(I,J,bi,bj) = 0.
201	dYU(I,J,bi,bj) = 0.
202	rAw(I,J,bi,bj) = 0.
203	rAs(I,J,bi,bj) = 0.
204	ENDDO
205	ENDDO
206
207	C-- Calculate [dxC], zonal length between cell centers
208	DO J=1-Oly,sNy+Oly
209	DO I=1-Olx+1,sNx+Olx ! NOTE range
210	C by averaging
211	dXC(I,J,bi,bj) = 0.5D0*(dXF(I,J,bi,bj)+dXF(I-1,J,bi,bj))
212	C by formula
213	c lat = 0.5*(yC(I,J,bi,bj)+yC(I-1,J,bi,bj))
214	c dlon = 0.5*(delX( iGl(I,bi) ) + delX( iGl(I-1,bi) ))
215	c dXC(I,J,bi,bj) = rSphereCOS(deg2radlat)dlondeg2rad
216	C by difference
217	c lat = 0.5*(yC(I,J,bi,bj)+yC(I-1,J,bi,bj))
218	c dlon = (xC(I,J,bi,bj)+xC(I-1,J,bi,bj))
219	c dXC(I,J,bi,bj) = rSphereCOS(deg2radlat)dlondeg2rad
220	ENDDO
221	ENDDO
222
223	C-- Calculate [dyC], meridional length between cell centers
224	DO J=1-Oly+1,sNy+Oly ! NOTE range
225	DO I=1-Olx,sNx+Olx
226	C by averaging
227	dYC(I,J,bi,bj) = 0.5*(dYF(I,J,bi,bj)+dYF(I,J-1,bi,bj))
228	C by formula
229	c dlat = 0.5*(delY( jGl(J,bj) ) + delY( jGl(J-1,bj) ))
230	c dYC(I,J,bi,bj) = rSpheredlatdeg2rad
231	C by difference
232	c dlat = (yC(I,J,bi,bj)+yC(I,J-1,bi,bj))
233	c dYC(I,J,bi,bj) = rSpheredlatdeg2rad
234	ENDDO
235	ENDDO
236
237	C-- Calculate [dxV,dyU], length between velocity points (through corners)
238	DO J=1-Oly+1,sNy+Oly ! NOTE range
239	DO I=1-Olx+1,sNx+Olx ! NOTE range
240	C by averaging (method I)
241	dXV(I,J,bi,bj) = 0.5*(dXG(I,J,bi,bj)+dXG(I-1,J,bi,bj))
242	dYU(I,J,bi,bj) = 0.5*(dYG(I,J,bi,bj)+dYG(I,J-1,bi,bj))
243	C by averaging (method II)
244	c dXV(I,J,bi,bj) = 0.5*(dXG(I,J,bi,bj)+dXG(I-1,J,bi,bj))
245	c dYU(I,J,bi,bj) = 0.5*(dYC(I,J,bi,bj)+dYC(I-1,J,bi,bj))
246	ENDDO
247	ENDDO
248
249	C-- Calculate vertical face area (tracer cells)
250	DO J=1-Oly,sNy+Oly
251	DO I=1-Olx,sNx+Olx
252	lat=0.5*(yGloc(I,J)+yGloc(I+1,J))
253	dlon=delX( iGl(I,bi) )
254	dlat=delY( jGl(J,bj) )
255	rA(I,J,bi,bj) = rSphererSpheredlon*deg2rad
256	& abs( sin((lat+dlat)deg2rad)-sin(lat*deg2rad) )
257	#ifdef USE_BACKWARD_COMPATIBLE_GRID
258	lat=yC(I,J,bi,bj)-delY( jGl(J,bj) )*0.5 _d 0
259	lon=yC(I,J,bi,bj)+delY( jGl(J,bj) )*0.5 _d 0
260	rA(I,J,bi,bj) = dyF(I,J,bi,bj)
261	& rSphere(SIN(londeg2rad)-SIN(latdeg2rad))
262	#endif /* USE_BACKWARD_COMPATIBLE_GRID */
263	ENDDO
264	ENDDO
265
266	C-- Calculate vertical face area (u cells)
267	DO J=1-Oly,sNy+Oly
268	DO I=1-Olx+1,sNx+Olx ! NOTE range
269	C by averaging
270	rAw(I,J,bi,bj) = 0.5*(rA(I,J,bi,bj)+rA(I-1,J,bi,bj))
271	C by formula
272	c lat=yGloc(I,J)
273	c dlon=0.5*( delX( iGl(I,bi) ) + delX( iGl(I-1,bi) ) )
274	c dlat=delY( jGl(J,bj) )
275	c rAw(I,J,bi,bj) = rSphererSpheredlon*deg2rad
276	c & abs( sin((lat+dlat)deg2rad)-sin(lat*deg2rad) )
277	ENDDO
278	ENDDO
279
280	C-- Calculate vertical face area (v cells)
281	DO J=1-Oly,sNy+Oly
282	DO I=1-Olx,sNx+Olx
283	C by formula
284	lat=yC(I,J,bi,bj)
285	dlon=delX( iGl(I,bi) )
286	dlat=0.5*( delY( jGl(J,bj) ) + delY( jGl(J-1,bj) ) )
287	rAs(I,J,bi,bj) = rSphererSpheredlon*deg2rad
288	& abs( sin(latdeg2rad)-sin((lat-dlat)*deg2rad) )
289	#ifdef USE_BACKWARD_COMPATIBLE_GRID
290	lon=yC(I,J,bi,bj)-delY( jGl(J,bj) )
291	lat=yC(I,J,bi,bj)
292	rAs(I,J,bi,bj) = rSpheredelX(iGl(I,bi))deg2rad
293	& rSphere(SIN(latdeg2rad)-SIN(londeg2rad))
294	#endif /* USE_BACKWARD_COMPATIBLE_GRID */
295	IF (abs(lat).GT.90..OR.abs(lat-dlat).GT.90.) rAs(I,J,bi,bj)=0.
296	ENDDO
297	ENDDO
298
299	C-- Calculate vertical face area (vorticity points)
300	DO J=1-Oly,sNy+Oly
301	DO I=1-Olx,sNx+Olx
302	C by formula
303	lat=yC(I,J,bi,bj)
304	dlon=delX( iGl(I,bi) )
305	dlat=0.5*( delY( jGl(J,bj) ) + delY( jGl(J-1,bj) ) )
306	rAz(I,J,bi,bj) = rSphererSpheredlon*deg2rad
307	& abs( sin(latdeg2rad)-sin((lat-dlat)*deg2rad) )
308	IF (abs(lat).GT.90..OR.abs(lat-dlat).GT.90.) rAz(I,J,bi,bj)=0.
309	ENDDO
310	ENDDO
311
312	C-- Calculate trigonometric terms
313	DO J=1-Oly,sNy+Oly
314	DO I=1-Olx,sNx+Olx
315	lat=0.5*(yGloc(I,J)+yGloc(I,J+1))
316	tanPhiAtU(i,j,bi,bj)=tan(lat*deg2rad)
317	lat=0.5*(yGloc(I,J)+yGloc(I+1,J))
318	tanPhiAtV(i,j,bi,bj)=tan(lat*deg2rad)
319	ENDDO
320	ENDDO
321
322	C-- Cosine(lat) scaling
323	DO J=1-OLy,sNy+OLy
324	jG = myYGlobalLo + (bj-1)*sNy + J-1
325	jG = min(max(1,jG),Ny)
326	IF (cosPower.NE.0.) THEN
327	cosFacU(J,bi,bj)=COS(yC(1,J,bi,bj)*deg2rad)
328	& **cosPower
329	cosFacV(J,bi,bj)=COS((yC(1,J,bi,bj)-0.5delY(jG))deg2rad)
330	& **cosPower
331	sqcosFacU(J,bi,bj)=sqrt(cosFacU(J,bi,bj))
332	sqcosFacV(J,bi,bj)=sqrt(cosFacV(J,bi,bj))
333	ELSE
334	cosFacU(J,bi,bj)=1.
335	cosFacV(J,bi,bj)=1.
336	sqcosFacU(J,bi,bj)=1.
337	sqcosFacV(J,bi,bj)=1.
338	ENDIF
339	ENDDO
340
341	ENDDO ! bi
342	ENDDO ! bj
343
344	RETURN
345	END