pkg/mom_common/mom_calc_visc.F

C $Header: /u/gcmpack/MITgcm/pkg/mom_common/mom_calc_visc.F,v 1.20 2005/10/12 20:24:22 jmc Exp $
C $Name:  $

#include "MOM_COMMON_OPTIONS.h"


      SUBROUTINE MOM_CALC_VISC(
     I        bi,bj,k,
     O        viscAh_Z,viscAh_D,viscA4_Z,viscA4_D,
     O        harmonic,biharmonic,useVariableViscosity,
     I        hDiv,vort3,tension,strain,KE,hFacZ,
     I        myThid)

      IMPLICIT NONE
C
C     Calculate horizontal viscosities (L is typical grid width)
C     harmonic viscosity=
C       viscAh (or viscAhD on div pts and viscAhZ on zeta pts)
C       +0.25*L**2*viscAhGrid/deltaT
C       +sqrt((viscC2leith/pi)**6*grad(Vort3)**2
C             +(viscC2leithD/pi)**6*grad(hDiv)**2)*L**3
C       +(viscC2smag/pi)**2*L**2*sqrt(Tension**2+Strain**2)
C
C     biharmonic viscosity=
C       viscA4 (or viscA4D on div pts and viscA4Z on zeta pts)
C       +0.25*0.125*L**4*viscA4Grid/deltaT (approx)
C       +0.125*L**5*sqrt((viscC4leith/pi)**6*grad(Vort3)**2
C                        +(viscC4leithD/pi)**6*grad(hDiv)**2)
C       +0.125*L**4*(viscC4smag/pi)**2*sqrt(Tension**2+Strain**2)
C
C     Note that often 0.125*L**2 is the scale between harmonic and
C     biharmonic (see Griffies and Hallberg (2000))
C     This allows the same value of the coefficient to be used
C     for roughly similar results with biharmonic and harmonic
C
C     LIMITERS -- limit min and max values of viscosities
C     viscAhRemax is min value for grid point harmonic Reynolds num
C      harmonic viscosity>sqrt(2*KE)*L/viscAhRemax
C
C     viscA4Remax is min value for grid point biharmonic Reynolds num
C      biharmonic viscosity>sqrt(2*KE)*L**3/8/viscA4Remax
C
C     viscAhgridmax is CFL stability limiter for harmonic viscosity
C      harmonic viscosity<0.25*viscAhgridmax*L**2/deltaT
C
C     viscA4gridmax is CFL stability limiter for biharmonic viscosity
C      biharmonic viscosity<viscA4gridmax*L**4/32/deltaT (approx)
C
C     viscAhgridmin and viscA4gridmin are lower limits for viscosity:
C      harmonic viscosity>0.25*viscAhgridmax*L**2/deltaT
C      biharmonic viscosity>viscA4gridmax*L**4/32/deltaT (approx)
C
C     RECOMMENDED VALUES
C     viscC2Leith=1-3
C     viscC2LeithD=1-3
C     viscC4Leith=1-3
C     viscC4LeithD=1.5-3
C     viscC2smag=2.2-4 (Griffies and Hallberg,2000) 
C               0.2-0.9 (Smagorinsky,1993)
C     viscC4smag=2.2-4 (Griffies and Hallberg,2000) 
C     viscAhRemax>=1, (<2 suppresses a computational mode)
C     viscA4Remax>=1, (<2 suppresses a computational mode)
C     viscAhgridmax=1
C     viscA4gridmax=1
C     viscAhgrid<1
C     viscA4grid<1
C     viscAhgridmin<<1
C     viscA4gridmin<<1

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

C     == Routine arguments ==
      INTEGER bi,bj,k
      _RL viscAh_Z(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_D(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_Z(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_D(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL hDiv(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL vort3(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL tension(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL strain(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL KE(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RS hFacZ(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      INTEGER myThid
      LOGICAL harmonic,biharmonic,useVariableViscosity

C     == Local variables ==
      INTEGER I,J
      _RL smag2fac, smag4fac
      _RL leith2fac, leith4fac
      _RL leithD2fac, leithD4fac
      _RL viscAhRe_max, viscA4Re_max
      _RL Alin,grdVrt,grdDiv, keZpt
      _RL recip_dt,L2,L3,L4,L5,L2rdt,L4rdt
      _RL Uscl,U4scl
      _RL divDx(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL divDy(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL vrtDx(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL vrtDy(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_ZMax(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_DMax(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_ZMax(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_DMax(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_ZMin(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_DMin(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_ZMin(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_DMin(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_ZLth(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_DLth(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_ZLth(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_DLth(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_ZLthD(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_DLthD(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_ZLthD(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_DLthD(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_ZSmg(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscAh_DSmg(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_ZSmg(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL viscA4_DSmg(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      LOGICAL calcLeith,calcSmag

      useVariableViscosity=
     &      (viscAhGrid.NE.0.)
     &  .OR.(viscA4Grid.NE.0.)
     &  .OR.(viscC2leith.NE.0.)
     &  .OR.(viscC2leithD.NE.0.)
     &  .OR.(viscC4leith.NE.0.)
     &  .OR.(viscC4leithD.NE.0.)
     &  .OR.(viscC2smag.NE.0.)
     &  .OR.(viscC4smag.NE.0.)

      harmonic=
     &      (viscAh.NE.0.)
     &  .OR.(viscAhD.NE.0.)
     &  .OR.(viscAhZ.NE.0.)
     &  .OR.(viscAhGrid.NE.0.)
     &  .OR.(viscC2leith.NE.0.)
     &  .OR.(viscC2leithD.NE.0.)
     &  .OR.(viscC2smag.NE.0.)

      IF ((harmonic).and.(viscAhremax.ne.0.)) THEN
        viscAhre_max=sqrt(2. _d 0)/viscAhRemax
      ELSE
        viscAhre_max=0. _d 0
      ENDIF

      biharmonic=
     &      (viscA4.NE.0.)
     &  .OR.(viscA4D.NE.0.)
     &  .OR.(viscA4Z.NE.0.)
     &  .OR.(viscA4Grid.NE.0.)
     &  .OR.(viscC4leith.NE.0.)
     &  .OR.(viscC4leithD.NE.0.)
     &  .OR.(viscC4smag.NE.0.)

      IF ((biharmonic).and.(viscA4remax.ne.0.)) THEN
        viscA4re_max=0.125 _d 0*sqrt(2. _d 0)/viscA4Remax
      ELSE
        viscA4re_max=0. _d 0
      ENDIF

      calcleith=
     &      (viscC2leith.NE.0.)
     &  .OR.(viscC2leithD.NE.0.)
     &  .OR.(viscC4leith.NE.0.)
     &  .OR.(viscC4leithD.NE.0.)

      calcsmag=
     &      (viscC2smag.NE.0.)
     &  .OR.(viscC4smag.NE.0.)

      IF (deltaTmom.NE.0.) THEN
       recip_dt=1. _d 0/deltaTmom
      ELSE
       recip_dt=0. _d 0
      ENDIF

      IF (calcsmag) THEN
        smag2fac=(viscC2smag/pi)**2
        smag4fac=0.125 _d 0*(viscC4smag/pi)**2
      ELSE
        smag2fac=0. _d 0
        smag4fac=0. _d 0
      ENDIF

      IF (calcleith) THEN
        IF (useFullLeith) THEN
         leith2fac =(viscC2leith /pi)**6
         leithD2fac=(viscC2leithD/pi)**6
         leith4fac =0.015625 _d 0*(viscC4leith /pi)**6
         leithD4fac=0.015625 _d 0*(viscC4leithD/pi)**6
        ELSE
         leith2fac =(viscC2leith /pi)**3
         leithD2fac=(viscC2leithD/pi)**3
         leith4fac =0.125 _d 0*(viscC4leith /pi)**3
         leithD4fac=0.125 _d 0*(viscC4leithD/pi)**3
        ENDIF
      ELSE
        leith2fac=0. _d 0
        leith4fac=0. _d 0
        leithD2fac=0. _d 0
        leithD4fac=0. _d 0
      ENDIF

#ifdef ALLOW_AUTODIFF_TAMC
       DO j=1-Oly,sNy+Oly
        DO i=1-Olx,sNx+Olx
          viscAh_D(i,j)=viscAhD
          viscAh_Z(i,j)=viscAhZ
          viscA4_D(i,j)=viscA4D
          viscA4_Z(i,j)=viscA4Z
c
          visca4_zsmg(i,j) = 0. _d 0
          viscah_zsmg(i,j) = 0. _d 0
c
          viscAh_Dlth(i,j) = 0. _d 0
          viscA4_Dlth(i,j) = 0. _d 0
          viscAh_DlthD(i,j)= 0. _d 0
          viscA4_DlthD(i,j)= 0. _d 0
c
          viscAh_DSmg(i,j) = 0. _d 0
          viscA4_DSmg(i,j) = 0. _d 0
c
          viscAh_ZLth(i,j) = 0. _d 0
          viscA4_ZLth(i,j) = 0. _d 0
          viscAh_ZLthD(i,j)= 0. _d 0
          viscA4_ZLthD(i,j)= 0. _d 0
        ENDDO
       ENDDO
#endif


C     - Viscosity
      IF (useVariableViscosity) THEN
cph(
#ifndef ALLOW_AUTODIFF_TAMC
cph)

C-     Initialise to zero gradient of vorticity & divergence:
       DO j=1-Oly,sNy+Oly
        DO i=1-Olx,sNx+Olx
          divDx(i,j) = 0.
          divDy(i,j) = 0.
          vrtDx(i,j) = 0.
          vrtDy(i,j) = 0.
        ENDDO
       ENDDO

       IF (calcleith) THEN
C      horizontal gradient of horizontal divergence:

C-       gradient in x direction:
#ifndef ALLOW_AUTODIFF_TAMC
         IF (useCubedSphereExchange) THEN
C        to compute d/dx(hDiv), fill corners with appropriate values:
           CALL FILL_CS_CORNER_TR_RL( .TRUE., hDiv, bi,bj, myThid )
         ENDIF
#endif
         DO j=2-Oly,sNy+Oly-1
          DO i=2-Olx,sNx+Olx-1
            divDx(i,j) = (hDiv(i,j)-hDiv(i-1,j))*recip_DXC(i,j,bi,bj)
          ENDDO
         ENDDO

C-       gradient in y direction:
#ifndef ALLOW_AUTODIFF_TAMC
         IF (useCubedSphereExchange) THEN
C        to compute d/dy(hDiv), fill corners with appropriate values:
           CALL FILL_CS_CORNER_TR_RL(.FALSE., hDiv, bi,bj, myThid )
         ENDIF
#endif
         DO j=2-Oly,sNy+Oly-1
          DO i=2-Olx,sNx+Olx-1
            divDy(i,j) = (hDiv(i,j)-hDiv(i,j-1))*recip_DYC(i,j,bi,bj)
          ENDDO
         ENDDO

C      horizontal gradient of vertical vorticity:
C-       gradient in x direction:
         DO j=2-Oly,sNy+Oly
          DO i=2-Olx,sNx+Olx-1
            vrtDx(i,j) = (vort3(i+1,j)-vort3(i,j))
     &                  *recip_DXG(i,j,bi,bj)
     &                  *maskS(i,j,k,bi,bj)
          ENDDO
         ENDDO
C-       gradient in y direction:
         DO j=2-Oly,sNy+Oly-1
          DO i=2-Olx,sNx+Olx
            vrtDy(i,j) = (vort3(i,j+1)-vort3(i,j))
     &                  *recip_DYG(i,j,bi,bj)
     &                  *maskW(i,j,k,bi,bj)
          ENDDO
         ENDDO

       ENDIF

       DO j=2-Oly,sNy+Oly-1
        DO i=2-Olx,sNx+Olx-1
CCCCCCCCCCCCCCC Divergence Point CalculationsCCCCCCCCCCCCCCCCCCCC

C These are (powers of) length scales 
         IF (useAreaViscLength) THEN
          L2=rA(i,j,bi,bj)
         ELSE
          L2=2. _d 0/((recip_DXF(I,J,bi,bj)**2+recip_DYF(I,J,bi,bj)**2))
         ENDIF
         L3=(L2**1.5)
         L4=(L2**2)
         L5=(L2**2.5)

         L2rdt=0.25 _d 0*recip_dt*L2

         IF (useAreaViscLength) THEN
          L4rdt=0.125 _d 0*recip_dt*rA(i,j,bi,bj)**2
         ELSE
          L4rdt=recip_dt/( 6. _d 0*(recip_DXF(I,J,bi,bj)**4
     &                            +recip_DYF(I,J,bi,bj)**4)
     &                   +8. _d 0*((recip_DXF(I,J,bi,bj)
     &                             *recip_DYF(I,J,bi,bj))**2) )
         ENDIF

C Velocity Reynolds Scale
         IF ( viscAhRe_max.GT.0. .AND. KE(i,j).GT.0. ) THEN
           Uscl=sqrt(KE(i,j)*L2)*viscAhRe_max
         ELSE
           Uscl=0.
         ENDIF
         IF ( viscA4Re_max.GT.0. .AND. KE(i,j).GT.0. ) THEN
           U4scl=sqrt(KE(i,j))*L3*viscA4Re_max
         ELSE
           U4scl=0.
         ENDIF

         IF (useFullLeith.and.calcleith) THEN
C This is the vector magnitude of the vorticity gradient squared
          grdVrt=0.25 _d 0*( (vrtDx(i,j+1)*vrtDx(i,j+1)
     &                        + vrtDx(i,j)*vrtDx(i,j) )
     &                     + (vrtDy(i+1,j)*vrtDy(i+1,j)
     &                        + vrtDy(i,j)*vrtDy(i,j) )  )

C This is the vector magnitude of grad (div.v) squared
C Using it in Leith serves to damp instabilities in w.
          grdDiv=0.25 _d 0*( (divDx(i+1,j)*divDx(i+1,j)
     &                        + divDx(i,j)*divDx(i,j) )
     &                     + (divDy(i,j+1)*divDy(i,j+1)
     &                        + divDy(i,j)*divDy(i,j) )  )

          viscAh_DLth(i,j)=
     &     sqrt(leith2fac*grdVrt+leithD2fac*grdDiv)*L3
          viscA4_DLth(i,j)=
     &     sqrt(leith4fac*grdVrt+leithD4fac*grdDiv)*L5
          viscAh_DLthd(i,j)=
     &     sqrt(leithD2fac*grdDiv)*L3
          viscA4_DLthd(i,j)=
     &     sqrt(leithD4fac*grdDiv)*L5
         ELSEIF (calcleith) THEN
C but this approximation will work on cube
c (and differs by as much as 4X)
          grdVrt=max( abs(vrtDx(i,j+1)), abs(vrtDx(i,j)) ) 
          grdVrt=max( grdVrt, abs(vrtDy(i+1,j)) )
          grdVrt=max( grdVrt, abs(vrtDy(i,j))   )

c This approximation is good to the same order as above...
          grdDiv=max( abs(divDx(i+1,j)), abs(divDx(i,j)) ) 
          grdDiv=max( grdDiv, abs(divDy(i,j+1)) )
          grdDiv=max( grdDiv, abs(divDy(i,j))   )

          viscAh_Dlth(i,j)=(leith2fac*grdVrt+(leithD2fac*grdDiv))*L3
          viscA4_Dlth(i,j)=(leith4fac*grdVrt+(leithD4fac*grdDiv))*L5
          viscAh_DlthD(i,j)=((leithD2fac*grdDiv))*L3
          viscA4_DlthD(i,j)=((leithD4fac*grdDiv))*L5
         ELSE
          viscAh_Dlth(i,j)=0. _d 0
          viscA4_Dlth(i,j)=0. _d 0
          viscAh_DlthD(i,j)=0. _d 0
          viscA4_DlthD(i,j)=0. _d 0
         ENDIF


         IF (calcsmag) THEN
          viscAh_DSmg(i,j)=L2
     &       *sqrt(tension(i,j)**2
     &       +0.25 _d 0*(strain(i+1, j )**2+strain( i ,j+1)**2
     &                  +strain(i  , j )**2+strain(i+1,j+1)**2))
          viscA4_DSmg(i,j)=smag4fac*L2*viscAh_DSmg(i,j)
          viscAh_DSmg(i,j)=smag2fac*viscAh_DSmg(i,j)
         ELSE
          viscAh_DSmg(i,j)=0. _d 0
          viscA4_DSmg(i,j)=0. _d 0
         ENDIF

C  Harmonic on Div.u points
         Alin=viscAhD+viscAhGrid*L2rdt
     &          +viscAh_DLth(i,j)+viscAh_DSmg(i,j)
         viscAh_DMin(i,j)=max(viscAhGridMin*L2rdt,Uscl)
         viscAh_D(i,j)=max(viscAh_DMin(i,j),Alin)
         viscAh_DMax(i,j)=min(viscAhGridMax*L2rdt,viscAhMax)
         viscAh_D(i,j)=min(viscAh_DMax(i,j),viscAh_D(i,j))

C  BiHarmonic on Div.u points
         Alin=viscA4D+viscA4Grid*L4rdt
     &          +viscA4_DLth(i,j)+viscA4_DSmg(i,j)
         viscA4_DMin(i,j)=max(viscA4GridMin*L4rdt,U4scl)
         viscA4_D(i,j)=max(viscA4_DMin(i,j),Alin)
         viscA4_DMax(i,j)=min(viscA4GridMax*L4rdt,viscA4Max)
         viscA4_D(i,j)=min(viscA4_DMax(i,j),viscA4_D(i,j))

CCCCCCCCCCCCC Vorticity Point CalculationsCCCCCCCCCCCCCCCCCC
C These are (powers of) length scales 
         IF (useAreaViscLength) THEN
          L2=rAz(i,j,bi,bj)
         ELSE
          L2=2. _d 0/((recip_DXV(I,J,bi,bj)**2+recip_DYU(I,J,bi,bj)**2))
         ENDIF

         L3=(L2**1.5)
         L4=(L2**2)
         L5=(L2**2.5)

         L2rdt=0.25 _d 0*recip_dt*L2
         IF (useAreaViscLength) THEN
          L4rdt=0.125 _d 0*recip_dt*rAz(i,j,bi,bj)**2
         ELSE
          L4rdt=recip_dt/
     &     ( 6. _d 0*(recip_DXV(I,J,bi,bj)**4+recip_DYU(I,J,bi,bj)**4)
     &      +8. _d 0*((recip_DXV(I,J,bi,bj)*recip_DYU(I,J,bi,bj))**2))
         ENDIF

C Velocity Reynolds Scale (Pb here at CS-grid corners !)
         IF ( viscAhRe_max.GT.0. .OR. viscA4Re_max.GT.0. ) THEN
           keZpt=0.25 _d 0*( (KE(i,j)+KE(i-1,j-1))
     &                      +(KE(i-1,j)+KE(i,j-1)) )
           IF ( keZpt.GT.0. ) THEN
             Uscl = sqrt(keZpt*L2)*viscAhRe_max
             U4scl= sqrt(keZpt)*L3*viscA4Re_max
           ELSE
             Uscl =0.
             U4scl=0.
           ENDIF
         ELSE
           Uscl =0.
           U4scl=0.
         ENDIF

C This is the vector magnitude of the vorticity gradient squared
         IF (useFullLeith.and.calcleith) THEN
          grdVrt=0.25 _d 0*( (vrtDx(i-1,j)*vrtDx(i-1,j)
     &                        + vrtDx(i,j)*vrtDx(i,j) )
     &                     + (vrtDy(i,j-1)*vrtDy(i,j-1)
     &                        + vrtDy(i,j)*vrtDy(i,j) )  )

C This is the vector magnitude of grad(div.v) squared
          grdDiv=0.25 _d 0*( (divDx(i,j-1)*divDx(i,j-1)
     &                        + divDx(i,j)*divDx(i,j) )
     &                     + (divDy(i-1,j)*divDy(i-1,j)
     &                        + divDy(i,j)*divDy(i,j) )  )

          viscAh_ZLth(i,j)=
     &     sqrt(leith2fac*grdVrt+leithD2fac*grdDiv)*L3
          viscA4_ZLth(i,j)=
     &     sqrt(leith4fac*grdVrt+leithD4fac*grdDiv)*L5
          viscAh_ZLthD(i,j)=
     &     sqrt(leithD2fac*grdDiv)*L3
          viscA4_ZLthD(i,j)=
     &     sqrt(leithD4fac*grdDiv)*L5

         ELSEIF (calcleith) THEN
C but this approximation will work on cube (and differs by 4X)
          grdVrt=max( abs(vrtDx(i-1,j)), abs(vrtDx(i,j)) ) 
          grdVrt=max( grdVrt, abs(vrtDy(i,j-1)) )
          grdVrt=max( grdVrt, abs(vrtDy(i,j))   )

          grdDiv=max( abs(divDx(i,j)), abs(divDx(i,j-1)) ) 
          grdDiv=max( grdDiv, abs(divDy(i,j))   )
          grdDiv=max( grdDiv, abs(divDy(i-1,j)) )

          viscAh_ZLth(i,j)=(leith2fac*grdVrt+(leithD2fac*grdDiv))*L3
          viscA4_ZLth(i,j)=(leith4fac*grdVrt+(leithD4fac*grdDiv))*L5
          viscAh_ZLthD(i,j)=(leithD2fac*grdDiv)*L3
          viscA4_ZLthD(i,j)=(leithD4fac*grdDiv)*L5
         ELSE
          viscAh_ZLth(i,j)=0. _d 0
          viscA4_ZLth(i,j)=0. _d 0
          viscAh_ZLthD(i,j)=0. _d 0
          viscA4_ZLthD(i,j)=0. _d 0
         ENDIF

         IF (calcsmag) THEN
          viscAh_ZSmg(i,j)=L2
     &      *sqrt(strain(i,j)**2
     &        +0.25 _d 0*(tension( i , j )**2+tension( i ,j-1)**2
     &                   +tension(i-1, j )**2+tension(i-1,j-1)**2))
          viscA4_ZSmg(i,j)=smag4fac*L2*viscAh_ZSmg(i,j)
          viscAh_ZSmg(i,j)=smag2fac*viscAh_ZSmg(i,j)
         ENDIF

C  Harmonic on Zeta points
         Alin=viscAhZ+viscAhGrid*L2rdt
     &           +viscAh_ZLth(i,j)+viscAh_ZSmg(i,j)
         viscAh_ZMin(i,j)=max(viscAhGridMin*L2rdt,Uscl)
         viscAh_Z(i,j)=max(viscAh_ZMin(i,j),Alin)
         viscAh_ZMax(i,j)=min(viscAhGridMax*L2rdt,viscAhMax)
         viscAh_Z(i,j)=min(viscAh_ZMax(i,j),viscAh_Z(i,j))

C  BiHarmonic on Zeta points
         Alin=viscA4Z+viscA4Grid*L4rdt
     &           +viscA4_ZLth(i,j)+viscA4_ZSmg(i,j)
         viscA4_ZMin(i,j)=max(viscA4GridMin*L4rdt,U4scl)
         viscA4_Z(i,j)=max(viscA4_ZMin(i,j),Alin)
         viscA4_ZMax(i,j)=min(viscA4GridMax*L4rdt,viscA4Max)
         viscA4_Z(i,j)=min(viscA4_ZMax(i,j),viscA4_Z(i,j))
        ENDDO
       ENDDO
cph(
#else
       STOP 'useVariableViscosity not implemented for ADJOINT'
#endif /* ndef ALLOW_AUTODIFF_TAMC */
cph)
      ELSE
       DO j=1-Oly,sNy+Oly
        DO i=1-Olx,sNx+Olx
         viscAh_D(i,j)=viscAhD
         viscAh_Z(i,j)=viscAhZ
         viscA4_D(i,j)=viscA4D
         viscA4_Z(i,j)=viscA4Z
        ENDDO
       ENDDO
      ENDIF

#ifdef ALLOW_DIAGNOSTICS
      IF (useDiagnostics) THEN
       CALL DIAGNOSTICS_FILL(viscAh_D,'VISCAHD ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_D,'VISCA4D ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscAh_Z,'VISCAHZ ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_Z,'VISCA4Z ',k,1,2,bi,bj,myThid)

       CALL DIAGNOSTICS_FILL(viscAh_DMax,'VAHDMAX ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_DMax,'VA4DMAX ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscAh_ZMax,'VAHZMAX ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_ZMax,'VA4ZMAX ',k,1,2,bi,bj,myThid)

       CALL DIAGNOSTICS_FILL(viscAh_DMin,'VAHDMIN ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_DMin,'VA4DMIN ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscAh_ZMin,'VAHZMIN ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_ZMin,'VA4ZMIN ',k,1,2,bi,bj,myThid)

       CALL DIAGNOSTICS_FILL(viscAh_DLth,'VAHDLTH ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_DLth,'VA4DLTH ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscAh_ZLth,'VAHZLTH ',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_ZLth,'VA4ZLTH ',k,1,2,bi,bj,myThid)

       CALL DIAGNOSTICS_FILL(viscAh_DLthD,'VAHDLTHD'
     &   ,k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_DLthD,'VA4DLTHD'
     &   ,k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscAh_ZLthD,'VAHZLTHD'
     &   ,k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_ZLthD,'VA4ZLTHD'
     &   ,k,1,2,bi,bj,myThid)

       CALL DIAGNOSTICS_FILL(viscAh_DSmg,'VAHDSMAG',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_DSmg,'VA4DSMAG',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscAh_ZSmg,'VAHZSMAG',k,1,2,bi,bj,myThid)
       CALL DIAGNOSTICS_FILL(viscA4_ZSmg,'VA4ZSMAG',k,1,2,bi,bj,myThid)
      ENDIF
#endif

      RETURN
      END

1	heimbach	1.21	C $Header: /u/gcmpack/MITgcm/pkg/mom_common/mom_calc_visc.F,v 1.20 2005/10/12 20:24:22 jmc Exp $
2	jmc	1.14	C $Name: $
3	baylor	1.1
4			#include "MOM_COMMON_OPTIONS.h"
5
6	baylor	1.5
7	baylor	1.1	SUBROUTINE MOM_CALC_VISC(
8			I bi,bj,k,
9			O viscAh_Z,viscAh_D,viscA4_Z,viscA4_D,
10			O harmonic,biharmonic,useVariableViscosity,
11	jmc	1.12	I hDiv,vort3,tension,strain,KE,hFacZ,
12	baylor	1.1	I myThid)
13
14			IMPLICIT NONE
15	baylor	1.5	C
16			C Calculate horizontal viscosities (L is typical grid width)
17			C harmonic viscosity=
18			C viscAh (or viscAhD on div pts and viscAhZ on zeta pts)
19			C +0.25L2viscAhGrid/deltaT
20	baylor	1.17	C +sqrt((viscC2leith/pi)*6grad(Vort3)**2
21			C +(viscC2leithD/pi)*6grad(hDiv)*2)L**3
22	baylor	1.5	C +(viscC2smag/pi)*2L*2sqrt(Tension2+Strain2)
23			C
24			C biharmonic viscosity=
25			C viscA4 (or viscA4D on div pts and viscA4Z on zeta pts)
26			C +0.250.125L*4viscA4Grid/deltaT (approx)
27	baylor	1.17	C +0.125L5sqrt((viscC4leith/pi)*6grad(Vort3)**2
28			C +(viscC4leithD/pi)*6grad(hDiv)**2)
29	baylor	1.5	C +0.125L4(viscC4smag/pi)*2sqrt(Tension2+Strain2)
30			C
31			C Note that often 0.125L*2 is the scale between harmonic and
32			C biharmonic (see Griffies and Hallberg (2000))
33			C This allows the same value of the coefficient to be used
34			C for roughly similar results with biharmonic and harmonic
35			C
36			C LIMITERS -- limit min and max values of viscosities
37			C viscAhRemax is min value for grid point harmonic Reynolds num
38	baylor	1.9	C harmonic viscosity>sqrt(2KE)L/viscAhRemax
39	baylor	1.5	C
40			C viscA4Remax is min value for grid point biharmonic Reynolds num
41	baylor	1.9	C biharmonic viscosity>sqrt(2KE)L**3/8/viscA4Remax
42	baylor	1.5	C
43			C viscAhgridmax is CFL stability limiter for harmonic viscosity
44			C harmonic viscosity<0.25viscAhgridmaxL**2/deltaT
45			C
46			C viscA4gridmax is CFL stability limiter for biharmonic viscosity
47			C biharmonic viscosity<viscA4gridmaxL*4/32/deltaT (approx)
48			C
49			C viscAhgridmin and viscA4gridmin are lower limits for viscosity:
50			C harmonic viscosity>0.25viscAhgridmaxL**2/deltaT
51			C biharmonic viscosity>viscA4gridmaxL*4/32/deltaT (approx)
52			C
53			C RECOMMENDED VALUES
54	baylor	1.18	C viscC2Leith=1-3
55			C viscC2LeithD=1-3
56			C viscC4Leith=1-3
57			C viscC4LeithD=1.5-3
58	baylor	1.5	C viscC2smag=2.2-4 (Griffies and Hallberg,2000)
59			C 0.2-0.9 (Smagorinsky,1993)
60			C viscC4smag=2.2-4 (Griffies and Hallberg,2000)
61	baylor	1.9	C viscAhRemax>=1, (<2 suppresses a computational mode)
62			C viscA4Remax>=1, (<2 suppresses a computational mode)
63	baylor	1.5	C viscAhgridmax=1
64			C viscA4gridmax=1
65			C viscAhgrid<1
66			C viscA4grid<1
67			C viscAhgridmin<<1
68			C viscA4gridmin<<1
69	baylor	1.1
70			C == Global variables ==
71			#include "SIZE.h"
72			#include "GRID.h"
73			#include "EEPARAMS.h"
74			#include "PARAMS.h"
75
76			C == Routine arguments ==
77			INTEGER bi,bj,k
78			_RL viscAh_Z(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
79			_RL viscAh_D(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
80			_RL viscA4_Z(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
81			_RL viscA4_D(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
82			_RL hDiv(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
83			_RL vort3(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
84			_RL tension(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
85			_RL strain(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
86			_RL KE(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
87			_RS hFacZ(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
88			INTEGER myThid
89			LOGICAL harmonic,biharmonic,useVariableViscosity
90
91			C == Local variables ==
92			INTEGER I,J
93	baylor	1.5	_RL smag2fac, smag4fac
94	baylor	1.17	_RL leith2fac, leith4fac
95			_RL leithD2fac, leithD4fac
96	baylor	1.6	_RL viscAhRe_max, viscA4Re_max
97	jmc	1.15	_RL Alin,grdVrt,grdDiv, keZpt
98	baylor	1.1	_RL recip_dt,L2,L3,L4,L5,L2rdt,L4rdt
99	baylor	1.5	_RL Uscl,U4scl
100	jmc	1.16	_RL divDx(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
101			_RL divDy(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
102	jmc	1.20	_RL vrtDx(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
103			_RL vrtDy(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
104	baylor	1.5	_RL viscAh_ZMax(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
105			_RL viscAh_DMax(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
106			_RL viscA4_ZMax(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
107			_RL viscA4_DMax(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
108			_RL viscAh_ZMin(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
109			_RL viscAh_DMin(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
110			_RL viscA4_ZMin(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
111			_RL viscA4_DMin(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
112			_RL viscAh_ZLth(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
113			_RL viscAh_DLth(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
114			_RL viscA4_ZLth(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
115			_RL viscA4_DLth(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
116			_RL viscAh_ZLthD(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
117			_RL viscAh_DLthD(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
118			_RL viscA4_ZLthD(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
119			_RL viscA4_DLthD(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
120			_RL viscAh_ZSmg(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
121			_RL viscAh_DSmg(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
122			_RL viscA4_ZSmg(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
123			_RL viscA4_DSmg(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
124			LOGICAL calcLeith,calcSmag
125	baylor	1.1
126			useVariableViscosity=
127			& (viscAhGrid.NE.0.)
128			& .OR.(viscA4Grid.NE.0.)
129			& .OR.(viscC2leith.NE.0.)
130			& .OR.(viscC2leithD.NE.0.)
131			& .OR.(viscC4leith.NE.0.)
132			& .OR.(viscC4leithD.NE.0.)
133			& .OR.(viscC2smag.NE.0.)
134			& .OR.(viscC4smag.NE.0.)
135
136			harmonic=
137			& (viscAh.NE.0.)
138			& .OR.(viscAhD.NE.0.)
139			& .OR.(viscAhZ.NE.0.)
140			& .OR.(viscAhGrid.NE.0.)
141			& .OR.(viscC2leith.NE.0.)
142			& .OR.(viscC2leithD.NE.0.)
143			& .OR.(viscC2smag.NE.0.)
144
145	baylor	1.9	IF ((harmonic).and.(viscAhremax.ne.0.)) THEN
146	jmc	1.10	viscAhre_max=sqrt(2. _d 0)/viscAhRemax
147	baylor	1.9	ELSE
148	jmc	1.10	viscAhre_max=0. _d 0
149	baylor	1.9	ENDIF
150	baylor	1.5
151	baylor	1.1	biharmonic=
152			& (viscA4.NE.0.)
153			& .OR.(viscA4D.NE.0.)
154			& .OR.(viscA4Z.NE.0.)
155			& .OR.(viscA4Grid.NE.0.)
156			& .OR.(viscC4leith.NE.0.)
157			& .OR.(viscC4leithD.NE.0.)
158			& .OR.(viscC4smag.NE.0.)
159
160	baylor	1.9	IF ((biharmonic).and.(viscA4remax.ne.0.)) THEN
161	jmc	1.10	viscA4re_max=0.125 _d 0*sqrt(2. _d 0)/viscA4Remax
162	baylor	1.9	ELSE
163	jmc	1.10	viscA4re_max=0. _d 0
164	baylor	1.9	ENDIF
165	baylor	1.5
166			calcleith=
167			& (viscC2leith.NE.0.)
168			& .OR.(viscC2leithD.NE.0.)
169			& .OR.(viscC4leith.NE.0.)
170			& .OR.(viscC4leithD.NE.0.)
171
172			calcsmag=
173			& (viscC2smag.NE.0.)
174			& .OR.(viscC4smag.NE.0.)
175
176	baylor	1.1	IF (deltaTmom.NE.0.) THEN
177	jmc	1.10	recip_dt=1. _d 0/deltaTmom
178	baylor	1.1	ELSE
179	jmc	1.10	recip_dt=0. _d 0
180	baylor	1.1	ENDIF
181
182	baylor	1.5	IF (calcsmag) THEN
183			smag2fac=(viscC2smag/pi)**2
184	jmc	1.10	smag4fac=0.125 _d 0(viscC4smag/pi)*2
185	baylor	1.9	ELSE
186	jmc	1.10	smag2fac=0. _d 0
187			smag4fac=0. _d 0
188	baylor	1.5	ENDIF
189	baylor	1.1
190	baylor	1.17	IF (calcleith) THEN
191			IF (useFullLeith) THEN
192	baylor	1.19	leith2fac =(viscC2leith /pi)**6
193	baylor	1.17	leithD2fac=(viscC2leithD/pi)**6
194	baylor	1.19	leith4fac =0.015625 _d 0(viscC4leith /pi)*6
195	baylor	1.17	leithD4fac=0.015625 _d 0(viscC4leithD/pi)*6
196			ELSE
197	baylor	1.19	leith2fac =(viscC2leith /pi)**3
198	baylor	1.17	leithD2fac=(viscC2leithD/pi)**3
199	baylor	1.19	leith4fac =0.125 _d 0(viscC4leith /pi)*3
200			leithD4fac=0.125 _d 0(viscC4leithD/pi)*3
201	baylor	1.17	ENDIF
202			ELSE
203			leith2fac=0. _d 0
204			leith4fac=0. _d 0
205			leithD2fac=0. _d 0
206			leithD4fac=0. _d 0
207			ENDIF
208
209	heimbach	1.21	#ifdef ALLOW_AUTODIFF_TAMC
210			DO j=1-Oly,sNy+Oly
211			DO i=1-Olx,sNx+Olx
212			viscAh_D(i,j)=viscAhD
213			viscAh_Z(i,j)=viscAhZ
214			viscA4_D(i,j)=viscA4D
215			viscA4_Z(i,j)=viscA4Z
216			c
217			visca4_zsmg(i,j) = 0. _d 0
218			viscah_zsmg(i,j) = 0. _d 0
219			c
220			viscAh_Dlth(i,j) = 0. _d 0
221			viscA4_Dlth(i,j) = 0. _d 0
222			viscAh_DlthD(i,j)= 0. _d 0
223			viscA4_DlthD(i,j)= 0. _d 0
224			c
225			viscAh_DSmg(i,j) = 0. _d 0
226			viscA4_DSmg(i,j) = 0. _d 0
227			c
228			viscAh_ZLth(i,j) = 0. _d 0
229			viscA4_ZLth(i,j) = 0. _d 0
230			viscAh_ZLthD(i,j)= 0. _d 0
231			viscA4_ZLthD(i,j)= 0. _d 0
232			ENDDO
233			ENDDO
234			#endif
235
236
237
238	baylor	1.1	C - Viscosity
239			IF (useVariableViscosity) THEN
240	heimbach	1.21	cph(
241			#ifndef ALLOW_AUTODIFF_TAMC
242			cph)
243	jmc	1.16
244	jmc	1.20	C- Initialise to zero gradient of vorticity & divergence:
245	jmc	1.16	DO j=1-Oly,sNy+Oly
246			DO i=1-Olx,sNx+Olx
247			divDx(i,j) = 0.
248			divDy(i,j) = 0.
249	jmc	1.20	vrtDx(i,j) = 0.
250			vrtDy(i,j) = 0.
251	jmc	1.16	ENDDO
252			ENDDO
253	jmc	1.20
254	jmc	1.16	IF (calcleith) THEN
255	jmc	1.20	C horizontal gradient of horizontal divergence:
256
257	jmc	1.16	C- gradient in x direction:
258			#ifndef ALLOW_AUTODIFF_TAMC
259			IF (useCubedSphereExchange) THEN
260			C to compute d/dx(hDiv), fill corners with appropriate values:
261			CALL FILL_CS_CORNER_TR_RL( .TRUE., hDiv, bi,bj, myThid )
262			ENDIF
263			#endif
264			DO j=2-Oly,sNy+Oly-1
265			DO i=2-Olx,sNx+Olx-1
266			divDx(i,j) = (hDiv(i,j)-hDiv(i-1,j))*recip_DXC(i,j,bi,bj)
267			ENDDO
268			ENDDO
269
270			C- gradient in y direction:
271			#ifndef ALLOW_AUTODIFF_TAMC
272			IF (useCubedSphereExchange) THEN
273			C to compute d/dy(hDiv), fill corners with appropriate values:
274			CALL FILL_CS_CORNER_TR_RL(.FALSE., hDiv, bi,bj, myThid )
275			ENDIF
276			#endif
277			DO j=2-Oly,sNy+Oly-1
278			DO i=2-Olx,sNx+Olx-1
279			divDy(i,j) = (hDiv(i,j)-hDiv(i,j-1))*recip_DYC(i,j,bi,bj)
280			ENDDO
281			ENDDO
282	jmc	1.20
283			C horizontal gradient of vertical vorticity:
284			C- gradient in x direction:
285			DO j=2-Oly,sNy+Oly
286			DO i=2-Olx,sNx+Olx-1
287			vrtDx(i,j) = (vort3(i+1,j)-vort3(i,j))
288			& *recip_DXG(i,j,bi,bj)
289			& *maskS(i,j,k,bi,bj)
290			ENDDO
291			ENDDO
292			C- gradient in y direction:
293			DO j=2-Oly,sNy+Oly-1
294			DO i=2-Olx,sNx+Olx
295			vrtDy(i,j) = (vort3(i,j+1)-vort3(i,j))
296			& *recip_DYG(i,j,bi,bj)
297			& *maskW(i,j,k,bi,bj)
298			ENDDO
299			ENDDO
300
301	jmc	1.16	ENDIF
302
303	baylor	1.1	DO j=2-Oly,sNy+Oly-1
304			DO i=2-Olx,sNx+Olx-1
305			CCCCCCCCCCCCCCC Divergence Point CalculationsCCCCCCCCCCCCCCCCCCCC
306	baylor	1.5
307	baylor	1.1	C These are (powers of) length scales
308	baylor	1.11	IF (useAreaViscLength) THEN
309	jmc	1.12	L2=rA(i,j,bi,bj)
310	baylor	1.11	ELSE
311			L2=2. _d 0/((recip_DXF(I,J,bi,bj)2+recip_DYF(I,J,bi,bj)2))
312			ENDIF
313	baylor	1.1	L3=(L2**1.5)
314			L4=(L2**2)
315	baylor	1.5	L5=(L2**2.5)
316
317	jmc	1.10	L2rdt=0.25 _d 0recip_dtL2
318	baylor	1.5
319	baylor	1.11	IF (useAreaViscLength) THEN
320	jmc	1.12	L4rdt=0.125 _d 0recip_dtrA(i,j,bi,bj)**2
321	baylor	1.11	ELSE
322			L4rdt=recip_dt/( 6. _d 0(recip_DXF(I,J,bi,bj)*4
323	jmc	1.10	& +recip_DYF(I,J,bi,bj)**4)
324			& +8. _d 0*((recip_DXF(I,J,bi,bj)
325			& recip_DYF(I,J,bi,bj))*2) )
326	baylor	1.11	ENDIF
327	baylor	1.1
328	baylor	1.5	C Velocity Reynolds Scale
329	jmc	1.15	IF ( viscAhRe_max.GT.0. .AND. KE(i,j).GT.0. ) THEN
330			Uscl=sqrt(KE(i,j)L2)viscAhRe_max
331			ELSE
332			Uscl=0.
333			ENDIF
334			IF ( viscA4Re_max.GT.0. .AND. KE(i,j).GT.0. ) THEN
335			U4scl=sqrt(KE(i,j))L3viscA4Re_max
336			ELSE
337			U4scl=0.
338			ENDIF
339	baylor	1.5
340			IF (useFullLeith.and.calcleith) THEN
341	baylor	1.1	C This is the vector magnitude of the vorticity gradient squared
342	jmc	1.20	grdVrt=0.25 _d 0( (vrtDx(i,j+1)vrtDx(i,j+1)
343			& + vrtDx(i,j)*vrtDx(i,j) )
344			& + (vrtDy(i+1,j)*vrtDy(i+1,j)
345			& + vrtDy(i,j)*vrtDy(i,j) ) )
346	baylor	1.1
347			C This is the vector magnitude of grad (div.v) squared
348			C Using it in Leith serves to damp instabilities in w.
349	jmc	1.16	grdDiv=0.25 _d 0( (divDx(i+1,j)divDx(i+1,j)
350			& + divDx(i,j)*divDx(i,j) )
351			& + (divDy(i,j+1)*divDy(i,j+1)
352			& + divDy(i,j)*divDy(i,j) ) )
353	baylor	1.5
354			viscAh_DLth(i,j)=
355	baylor	1.17	& sqrt(leith2facgrdVrt+leithD2facgrdDiv)*L3
356			viscA4_DLth(i,j)=
357			& sqrt(leith4facgrdVrt+leithD4facgrdDiv)*L5
358	baylor	1.5	viscAh_DLthd(i,j)=
359	baylor	1.17	& sqrt(leithD2facgrdDiv)L3
360			viscA4_DLthd(i,j)=
361			& sqrt(leithD4facgrdDiv)L5
362	baylor	1.5	ELSEIF (calcleith) THEN
363	baylor	1.1	C but this approximation will work on cube
364			c (and differs by as much as 4X)
365	jmc	1.20	grdVrt=max( abs(vrtDx(i,j+1)), abs(vrtDx(i,j)) )
366			grdVrt=max( grdVrt, abs(vrtDy(i+1,j)) )
367			grdVrt=max( grdVrt, abs(vrtDy(i,j)) )
368	baylor	1.5
369	jmc	1.20	c This approximation is good to the same order as above...
370	jmc	1.16	grdDiv=max( abs(divDx(i+1,j)), abs(divDx(i,j)) )
371			grdDiv=max( grdDiv, abs(divDy(i,j+1)) )
372			grdDiv=max( grdDiv, abs(divDy(i,j)) )
373	baylor	1.1
374	baylor	1.17	viscAh_Dlth(i,j)=(leith2facgrdVrt+(leithD2facgrdDiv))*L3
375			viscA4_Dlth(i,j)=(leith4facgrdVrt+(leithD4facgrdDiv))*L5
376			viscAh_DlthD(i,j)=((leithD2facgrdDiv))L3
377			viscA4_DlthD(i,j)=((leithD4facgrdDiv))L5
378	baylor	1.1	ELSE
379	jmc	1.10	viscAh_Dlth(i,j)=0. _d 0
380			viscA4_Dlth(i,j)=0. _d 0
381			viscAh_DlthD(i,j)=0. _d 0
382			viscA4_DlthD(i,j)=0. _d 0
383	baylor	1.1	ENDIF
384
385	heimbach	1.21
386	baylor	1.5	IF (calcsmag) THEN
387			viscAh_DSmg(i,j)=L2
388			& sqrt(tension(i,j)*2
389	jmc	1.10	& +0.25 _d 0(strain(i+1, j )2+strain( i ,j+1)*2
390			& +strain(i , j )2+strain(i+1,j+1)2))
391	baylor	1.5	viscA4_DSmg(i,j)=smag4facL2viscAh_DSmg(i,j)
392			viscAh_DSmg(i,j)=smag2fac*viscAh_DSmg(i,j)
393	baylor	1.1	ELSE
394	jmc	1.10	viscAh_DSmg(i,j)=0. _d 0
395			viscA4_DSmg(i,j)=0. _d 0
396	baylor	1.1	ENDIF
397
398			C Harmonic on Div.u points
399	baylor	1.5	Alin=viscAhD+viscAhGrid*L2rdt
400			& +viscAh_DLth(i,j)+viscAh_DSmg(i,j)
401			viscAh_DMin(i,j)=max(viscAhGridMin*L2rdt,Uscl)
402			viscAh_D(i,j)=max(viscAh_DMin(i,j),Alin)
403			viscAh_DMax(i,j)=min(viscAhGridMax*L2rdt,viscAhMax)
404			viscAh_D(i,j)=min(viscAh_DMax(i,j),viscAh_D(i,j))
405	baylor	1.1
406			C BiHarmonic on Div.u points
407	baylor	1.5	Alin=viscA4D+viscA4Grid*L4rdt
408			& +viscA4_DLth(i,j)+viscA4_DSmg(i,j)
409			viscA4_DMin(i,j)=max(viscA4GridMin*L4rdt,U4scl)
410			viscA4_D(i,j)=max(viscA4_DMin(i,j),Alin)
411			viscA4_DMax(i,j)=min(viscA4GridMax*L4rdt,viscA4Max)
412			viscA4_D(i,j)=min(viscA4_DMax(i,j),viscA4_D(i,j))
413	baylor	1.1
414			CCCCCCCCCCCCC Vorticity Point CalculationsCCCCCCCCCCCCCCCCCC
415			C These are (powers of) length scales
416	baylor	1.11	IF (useAreaViscLength) THEN
417	jmc	1.12	L2=rAz(i,j,bi,bj)
418	baylor	1.11	ELSE
419	jmc	1.12	L2=2. _d 0/((recip_DXV(I,J,bi,bj)2+recip_DYU(I,J,bi,bj)2))
420	baylor	1.11	ENDIF
421
422	baylor	1.1	L3=(L2**1.5)
423			L4=(L2**2)
424	baylor	1.5	L5=(L2**2.5)
425
426	jmc	1.10	L2rdt=0.25 _d 0recip_dtL2
427	baylor	1.11	IF (useAreaViscLength) THEN
428	jmc	1.14	L4rdt=0.125 _d 0recip_dtrAz(i,j,bi,bj)**2
429	baylor	1.11	ELSE
430			L4rdt=recip_dt/
431			& ( 6. _d 0(recip_DXV(I,J,bi,bj)4+recip_DYU(I,J,bi,bj)*4)
432			& +8. _d 0((recip_DXV(I,J,bi,bj)recip_DYU(I,J,bi,bj))**2))
433			ENDIF
434	baylor	1.5
435	jmc	1.15	C Velocity Reynolds Scale (Pb here at CS-grid corners !)
436			IF ( viscAhRe_max.GT.0. .OR. viscA4Re_max.GT.0. ) THEN
437			keZpt=0.25 _d 0*( (KE(i,j)+KE(i-1,j-1))
438			& +(KE(i-1,j)+KE(i,j-1)) )
439			IF ( keZpt.GT.0. ) THEN
440			Uscl = sqrt(keZptL2)viscAhRe_max
441			U4scl= sqrt(keZpt)L3viscA4Re_max
442			ELSE
443			Uscl =0.
444			U4scl=0.
445			ENDIF
446			ELSE
447			Uscl =0.
448			U4scl=0.
449			ENDIF
450	baylor	1.1
451			C This is the vector magnitude of the vorticity gradient squared
452	baylor	1.5	IF (useFullLeith.and.calcleith) THEN
453	jmc	1.20	grdVrt=0.25 _d 0( (vrtDx(i-1,j)vrtDx(i-1,j)
454			& + vrtDx(i,j)*vrtDx(i,j) )
455			& + (vrtDy(i,j-1)*vrtDy(i,j-1)
456			& + vrtDy(i,j)*vrtDy(i,j) ) )
457	baylor	1.1
458			C This is the vector magnitude of grad(div.v) squared
459	jmc	1.16	grdDiv=0.25 _d 0( (divDx(i,j-1)divDx(i,j-1)
460			& + divDx(i,j)*divDx(i,j) )
461			& + (divDy(i-1,j)*divDy(i-1,j)
462			& + divDy(i,j)*divDy(i,j) ) )
463	baylor	1.5
464			viscAh_ZLth(i,j)=
465	baylor	1.17	& sqrt(leith2facgrdVrt+leithD2facgrdDiv)*L3
466			viscA4_ZLth(i,j)=
467			& sqrt(leith4facgrdVrt+leithD4facgrdDiv)*L5
468	baylor	1.5	viscAh_ZLthD(i,j)=
469	baylor	1.17	& sqrt(leithD2facgrdDiv)L3
470			viscA4_ZLthD(i,j)=
471			& sqrt(leithD4facgrdDiv)L5
472	baylor	1.5
473			ELSEIF (calcleith) THEN
474	baylor	1.1	C but this approximation will work on cube (and differs by 4X)
475	jmc	1.20	grdVrt=max( abs(vrtDx(i-1,j)), abs(vrtDx(i,j)) )
476			grdVrt=max( grdVrt, abs(vrtDy(i,j-1)) )
477			grdVrt=max( grdVrt, abs(vrtDy(i,j)) )
478	baylor	1.5
479	jmc	1.16	grdDiv=max( abs(divDx(i,j)), abs(divDx(i,j-1)) )
480			grdDiv=max( grdDiv, abs(divDy(i,j)) )
481			grdDiv=max( grdDiv, abs(divDy(i-1,j)) )
482	baylor	1.5
483	baylor	1.17	viscAh_ZLth(i,j)=(leith2facgrdVrt+(leithD2facgrdDiv))*L3
484			viscA4_ZLth(i,j)=(leith4facgrdVrt+(leithD4facgrdDiv))*L5
485			viscAh_ZLthD(i,j)=(leithD2facgrdDiv)L3
486			viscA4_ZLthD(i,j)=(leithD4facgrdDiv)L5
487	baylor	1.1	ELSE
488	jmc	1.10	viscAh_ZLth(i,j)=0. _d 0
489			viscA4_ZLth(i,j)=0. _d 0
490			viscAh_ZLthD(i,j)=0. _d 0
491			viscA4_ZLthD(i,j)=0. _d 0
492	baylor	1.1	ENDIF
493
494	baylor	1.5	IF (calcsmag) THEN
495			viscAh_ZSmg(i,j)=L2
496			& sqrt(strain(i,j)*2
497	jmc	1.10	& +0.25 _d 0(tension( i , j )2+tension( i ,j-1)*2
498			& +tension(i-1, j )2+tension(i-1,j-1)2))
499	baylor	1.5	viscA4_ZSmg(i,j)=smag4facL2viscAh_ZSmg(i,j)
500			viscAh_ZSmg(i,j)=smag2fac*viscAh_ZSmg(i,j)
501	baylor	1.1	ENDIF
502
503			C Harmonic on Zeta points
504	baylor	1.5	Alin=viscAhZ+viscAhGrid*L2rdt
505			& +viscAh_ZLth(i,j)+viscAh_ZSmg(i,j)
506			viscAh_ZMin(i,j)=max(viscAhGridMin*L2rdt,Uscl)
507			viscAh_Z(i,j)=max(viscAh_ZMin(i,j),Alin)
508			viscAh_ZMax(i,j)=min(viscAhGridMax*L2rdt,viscAhMax)
509			viscAh_Z(i,j)=min(viscAh_ZMax(i,j),viscAh_Z(i,j))
510
511			C BiHarmonic on Zeta points
512			Alin=viscA4Z+viscA4Grid*L4rdt
513			& +viscA4_ZLth(i,j)+viscA4_ZSmg(i,j)
514			viscA4_ZMin(i,j)=max(viscA4GridMin*L4rdt,U4scl)
515			viscA4_Z(i,j)=max(viscA4_ZMin(i,j),Alin)
516			viscA4_ZMax(i,j)=min(viscA4GridMax*L4rdt,viscA4Max)
517			viscA4_Z(i,j)=min(viscA4_ZMax(i,j),viscA4_Z(i,j))
518	baylor	1.1	ENDDO
519			ENDDO
520	heimbach	1.21	cph(
521			#else
522			STOP 'useVariableViscosity not implemented for ADJOINT'
523			#endif /* ndef ALLOW_AUTODIFF_TAMC */
524			cph)
525	baylor	1.1	ELSE
526			DO j=1-Oly,sNy+Oly
527			DO i=1-Olx,sNx+Olx
528			viscAh_D(i,j)=viscAhD
529			viscAh_Z(i,j)=viscAhZ
530			viscA4_D(i,j)=viscA4D
531			viscA4_Z(i,j)=viscA4Z
532			ENDDO
533			ENDDO
534			ENDIF
535
536			#ifdef ALLOW_DIAGNOSTICS
537			IF (useDiagnostics) THEN
538			CALL DIAGNOSTICS_FILL(viscAh_D,'VISCAHD ',k,1,2,bi,bj,myThid)
539			CALL DIAGNOSTICS_FILL(viscA4_D,'VISCA4D ',k,1,2,bi,bj,myThid)
540			CALL DIAGNOSTICS_FILL(viscAh_Z,'VISCAHZ ',k,1,2,bi,bj,myThid)
541			CALL DIAGNOSTICS_FILL(viscA4_Z,'VISCA4Z ',k,1,2,bi,bj,myThid)
542	baylor	1.5
543			CALL DIAGNOSTICS_FILL(viscAh_DMax,'VAHDMAX ',k,1,2,bi,bj,myThid)
544			CALL DIAGNOSTICS_FILL(viscA4_DMax,'VA4DMAX ',k,1,2,bi,bj,myThid)
545			CALL DIAGNOSTICS_FILL(viscAh_ZMax,'VAHZMAX ',k,1,2,bi,bj,myThid)
546			CALL DIAGNOSTICS_FILL(viscA4_ZMax,'VA4ZMAX ',k,1,2,bi,bj,myThid)
547
548			CALL DIAGNOSTICS_FILL(viscAh_DMin,'VAHDMIN ',k,1,2,bi,bj,myThid)
549			CALL DIAGNOSTICS_FILL(viscA4_DMin,'VA4DMIN ',k,1,2,bi,bj,myThid)
550			CALL DIAGNOSTICS_FILL(viscAh_ZMin,'VAHZMIN ',k,1,2,bi,bj,myThid)
551			CALL DIAGNOSTICS_FILL(viscA4_ZMin,'VA4ZMIN ',k,1,2,bi,bj,myThid)
552
553			CALL DIAGNOSTICS_FILL(viscAh_DLth,'VAHDLTH ',k,1,2,bi,bj,myThid)
554			CALL DIAGNOSTICS_FILL(viscA4_DLth,'VA4DLTH ',k,1,2,bi,bj,myThid)
555			CALL DIAGNOSTICS_FILL(viscAh_ZLth,'VAHZLTH ',k,1,2,bi,bj,myThid)
556			CALL DIAGNOSTICS_FILL(viscA4_ZLth,'VA4ZLTH ',k,1,2,bi,bj,myThid)
557
558	baylor	1.7	CALL DIAGNOSTICS_FILL(viscAh_DLthD,'VAHDLTHD'
559	baylor	1.8	& ,k,1,2,bi,bj,myThid)
560	baylor	1.7	CALL DIAGNOSTICS_FILL(viscA4_DLthD,'VA4DLTHD'
561	baylor	1.8	& ,k,1,2,bi,bj,myThid)
562	baylor	1.7	CALL DIAGNOSTICS_FILL(viscAh_ZLthD,'VAHZLTHD'
563	baylor	1.8	& ,k,1,2,bi,bj,myThid)
564	baylor	1.7	CALL DIAGNOSTICS_FILL(viscA4_ZLthD,'VA4ZLTHD'
565	baylor	1.8	& ,k,1,2,bi,bj,myThid)
566	baylor	1.5
567			CALL DIAGNOSTICS_FILL(viscAh_DSmg,'VAHDSMAG',k,1,2,bi,bj,myThid)
568			CALL DIAGNOSTICS_FILL(viscA4_DSmg,'VA4DSMAG',k,1,2,bi,bj,myThid)
569			CALL DIAGNOSTICS_FILL(viscAh_ZSmg,'VAHZSMAG',k,1,2,bi,bj,myThid)
570			CALL DIAGNOSTICS_FILL(viscA4_ZSmg,'VA4ZSMAG',k,1,2,bi,bj,myThid)
571	baylor	1.1	ENDIF
572			#endif
573
574			RETURN
575			END
576	baylor	1.5