*           rr_flux_uz.F
*
*           Rick Romea
*           Jan. 24, 2000	 
*
*     Zonal nonlinear advective flux term:  -dwu/dz
*     Units :     cm/s/s
*     MOM2 Grid:  U   
*
*******************************************************************

      SUBROUTINE RR_flux_uz_init(id)
	IMPLICIT NONE
      INCLUDE 'ferret_cmn/EF_Util.cmn'
      INTEGER id

      CALL ef_set_desc             (id,
     .'-d(wu)/dz advective momentum: flux-form (cm/s^2);MOM2 U Grid')
      CALL ef_set_num_args         (id, 3)
      CALL ef_set_axis_inheritance (id, IMPLIED_BY_ARGS, 
     .                                  IMPLIED_BY_ARGS, 
     .                                  IMPLIED_BY_ARGS, 
     .                                  IMPLIED_BY_ARGS)
      CALL ef_set_piecemeal_ok     (id, NO, NO, NO, NO)

      ! Define first argument (U)

      CALL ef_set_arg_name         (id, ARG1, 'U')
      CALL ef_set_arg_desc         (id, ARG1,
     . 'Zonal velocity, on the MOM2 U Grid. ')
      CALL ef_set_arg_unit         (id, ARG1, 'cm/sec')
      CALL ef_set_arg_type         (id, ARG1, FLOAT_ARG)
      CALL ef_set_axis_influence   (id, ARG1, YES, YES, YES, YES)
      CALL ef_set_axis_extend      (id, ARG1, X_AXIS,-1,+1)
      CALL ef_set_axis_extend      (id, ARG1, Y_AXIS,-1,+1)
      CALL ef_set_axis_extend      (id, ARG1, Z_AXIS,0,+1)

      ! Define second argumen (W)

      CALL ef_set_arg_name         (id, ARG2, 'W')
      CALL ef_set_arg_desc         (id, ARG2,
     . 'Vertical velocity, at T cell bottom on the MOM2 Grid. ')
      CALL ef_set_arg_unit         (id, ARG2, 'cm/sec')
      CALL ef_set_arg_type         (id, ARG2, FLOAT_ARG)
      CALL ef_set_axis_influence   (id, ARG2, NO, NO, NO, YES)
      CALL ef_set_axis_extend      (id, ARG2, X_AXIS,-1,+1)
      CALL ef_set_axis_extend      (id, ARG2, Y_AXIS,-1,+1)
      CALL ef_set_axis_extend      (id, ARG2, Z_AXIS,0,+1)

      ! Define third argument (TEMP)

      CALL ef_set_arg_name         (id, ARG3, 'TEMP')
      CALL ef_set_arg_desc         (id, ARG3,
     . 'Potential temperature, required to access MOM2 T Grid. ')
      CALL ef_set_arg_unit         (id, ARG3, 'deg-C')
      CALL ef_set_arg_type         (id, ARG3, FLOAT_ARG)
      CALL ef_set_axis_influence   (id, ARG3, NO, NO, YES, YES)
      CALL ef_set_axis_extend      (id, ARG3, X_AXIS,-1,+1)
      CALL ef_set_axis_extend      (id, ARG3, Y_AXIS,-1,+1)
      CALL ef_set_axis_extend      (id, ARG3, Z_AXIS,0,+1)

      END




      SUBROUTINE RR_flux_uz_compute(id, arg_1, arg_2, arg_3, result)
      IMPLICIT NONE
      INCLUDE 'ferret_cmn/EF_Util.cmn'
      INCLUDE 'ferret_cmn/EF_mem_subsc.cmn'

      INTEGER        id

      REAL           bad_flag(EF_MAX_ARGS)
      REAL           bad_flag_result
      REAL           arg_1 (mem1lox:mem1hix, mem1loy:mem1hiy, 
     .                      mem1loz:mem1hiz, mem1lot:mem1hit)
      REAL           arg_2 (mem2lox:mem2hix, mem2loy:mem2hiy, 
     .                      mem2loz:mem2hiz, mem2lot:mem2hit)
      REAL           arg_3 (mem3lox:mem3hix, mem3loy:mem3hiy, 
     .                      mem3loz:mem3hiz, mem3lot:mem3hit)
      REAL           result (memreslox:memreshix,memresloy:memreshiy,
     .                       memresloz:memreshiz,memreslot:memreshit)

      INTEGER        res_lo_ss (4)
      INTEGER        res_hi_ss (4)
      INTEGER        res_incr  (4)

      INTEGER        arg_lo_ss (4,EF_MAX_ARGS)
      INTEGER        arg_hi_ss (4,EF_MAX_ARGS)
      INTEGER        arg_incr  (4,EF_MAX_ARGS)

      INTEGER        i,  j,  k,  l
      INTEGER        i1, j1, k1, l1
      INTEGER        i2, j2, k2, l2

      REAL*8         yU(1024)
      REAL*8         xU(1024)
      REAL*8         zW(1024)
      REAL*8         yT(1024)
      REAL*8         xT(1024)

      INTEGER        ilat
      INTEGER        ilon
      INTEGER        iZ

      REAL           dxt, dyt, dxu, dyu
      REAL           dus, dun, duw, due
      REAL           adv_fb, adv_vbu
      REAL           csu, cst
      INCLUDE 'rr_parameters.h'

      dxt(i) = SNGL (xU(i)   - xU(i-1)) * Longitude_to_cm
      dyt(j) = SNGL (yU(j)   - yU(j-1)) * Latitude_to_cm
      dxu(i) = SNGL (xT(i+1) - xT(i))   * Longitude_to_cm
      dyu(j) = SNGL (yT(j+1) - yT(j))   * Latitude_to_cm
      dus(j) = SNGL (yU(j)   - yT(j))   * Latitude_to_cm
      dun(j) = SNGL (yT(j+1) - yU(j))   * Latitude_to_cm
      duw(i) = SNGL (xU(i)   - xT(i))   * Longitude_to_cm
      due(i) = SNGL (xT(i+1) - xU(i))   * Longitude_to_cm
      cst(j) = cos(SNGL(yT(j)) * Degrees_to_radians) 
      csu(j) = cos(SNGL(yU(j)) * Degrees_to_radians) 
      adv_vbu(i,j,k,l,iLat,iLon,iZ) =
     . ( arg_2(i,  j,  k,l) * dus(iLat) * duw(iLon) * cst(iLat)
     . + arg_2(i+1,j,  k,l) * dus(iLat) * due(iLon) * cst(iLat) 
     . + arg_2(i,  j+1,k,l) * dun(iLat) * duw(iLon) * cst(iLat+1)
     . + arg_2(i+1,j+1,k,l) * dun(iLat) * due(iLon) * cst(iLat+1)
     .                   ) / dyu(iLat) / dxu(iLon) / csu(iLat)
      adv_fb(i1,j1,k1,l1,i2,j2,k2,l2, iLat,iLon,iZ) = 
     .       	         adv_vbu(i2,j2,k2,l2,iLat,iLon,iZ)
     .                  * (arg_1(i1,j1,k1,l1) + arg_1(i1,j1,k1+1,l1))

      CALL ef_get_res_subscripts (id, res_lo_ss, res_hi_ss, res_incr)
      CALL ef_get_arg_subscripts (id, arg_lo_ss, arg_hi_ss, arg_incr)
      CALL ef_get_bad_flags      (id, bad_flag,  bad_flag_result)
      CALL ef_get_coordinates    (id, ARG1, X_AXIS, 
     .                            arg_lo_ss(X_AXIS,ARG1),
     .                            arg_hi_ss(X_AXIS,ARG1), xU)
      CALL ef_get_coordinates    (id, ARG1, Y_AXIS, 
     .                            arg_lo_ss(Y_AXIS,ARG1),
     .                            arg_hi_ss(Y_AXIS,ARG1), yU)
      CALL ef_get_coordinates    (id, ARG2, Z_AXIS, 
     .                            arg_lo_ss(Z_AXIS,ARG2),
     .                            arg_hi_ss(Z_AXIS,ARG2), zW)
      CALL ef_get_coordinates    (id, ARG3, X_AXIS, 
     .                            arg_lo_ss(X_AXIS,ARG3),
     .                            arg_hi_ss(X_AXIS,ARG3), xT)
      CALL ef_get_coordinates    (id, ARG3, Y_AXIS, 
     .                            arg_lo_ss(Y_AXIS,ARG3),
     .                            arg_hi_ss(Y_AXIS,ARG3), yT)

      l1 = arg_lo_ss(T_AXIS,ARG1) 
      l2 = arg_lo_ss(T_AXIS,ARG2) 
      DO l = res_lo_ss(T_AXIS), res_hi_ss(T_AXIS)
         ilat = 2  
         j1 = arg_lo_ss(Y_AXIS,ARG1) + 1
         j2 = arg_lo_ss(Y_AXIS,ARG2) + 1
         DO j = res_lo_ss(Y_AXIS), res_hi_ss(Y_AXIS)
            iLon = 2
            i1 = arg_lo_ss(X_AXIS,ARG1) + 1
            i2 = arg_lo_ss(X_AXIS,ARG2) + 1
            DO i = res_lo_ss(X_AXIS), res_hi_ss(X_AXIS)
               iZ = 1
               k1 = arg_lo_ss(Z_AXIS,ARG1)
               k2 = arg_lo_ss(Z_AXIS,ARG2)
               DO k = res_lo_ss(Z_AXIS), res_hi_ss(Z_AXIS)

                  IF (arg_1(i1,  j1,  k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_1(i1+1,j1,  k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_1(i1-1,j1,  k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_1(i1,  j1+1,k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_1(i1+1,j1+1,k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_1(i1-1,j1+1,k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_1(i1,  j1-1,k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_1(i1+1,j1-1,k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_1(i1-1,j1-1,k1,l1) .EQ. bad_flag(ARG1) .OR.
     .                arg_2(i2,  j2,  k2,l2) .EQ. bad_flag(ARG2) .OR.
     .                arg_2(i2+1,j2,  k2,l2) .EQ. bad_flag(ARG2) .OR.
     .                arg_2(i2-1,j2,  k2,l2) .EQ. bad_flag(ARG2) .OR.
     .                arg_2(i2,  j2+1,k2,l2) .EQ. bad_flag(ARG2) .OR.
     .                arg_2(i2+1,j2+1,k2,l2) .EQ. bad_flag(ARG2) .OR.
     .                arg_2(i2-1,j2+1,k2,l2) .EQ. bad_flag(ARG2) .OR.
     .                arg_2(i2,  j2-1,k2,l2) .EQ. bad_flag(ARG2) .OR.
     .                arg_2(i2+1,j2-1,k2,l2) .EQ. bad_flag(ARG2) .OR.
     .                arg_2(i2-1,j2-1,k2,l2) .EQ. bad_flag(ARG2)) THEN
                     result(i,j,k,l) = bad_flag_result
                   ELSE
                     IF(iZ.EQ.1)THEN
			result(i,j,k,l) =  -1. *   ! added
     .                     adv_fb(i1,j1,k1,l1,i2,j2,k2,l2, iLat,iLon,iZ) 
     .                       /2./(zW(iZ)*Meters_to_cm)*sec_per_month
	               ELSE
			   result(i,j,k,l) =  -1. *  ! added
     .              -(adv_fb(i1,j1,k1-1,l1,i2,j2,k2-1,l2,iLat,iLon,iZ-1)
     .              - adv_fb(i1,j1,k1,  l1,i2,j2,k2,  l2, iLat,iLon,iZ))
     .                       /2./(zW(iZ-1)-zW(iZ))/Meters_to_cm 
     .                              * sec_per_month
                     ENDIF
                  ENDIF
	          iZ = iZ + 1
                  k1 = k1 + arg_incr(Z_AXIS,ARG1)
                  k2 = k2 + arg_incr(Z_AXIS,ARG2)
               ENDDO
               iLon = iLon + 1
               i1 = i1 + arg_incr(X_AXIS,ARG1)
               i2 = i2 + arg_incr(X_AXIS,ARG2)
            ENDDO
            iLat = iLat + 1
            j1 = j1 + arg_incr(Y_AXIS,ARG1)
            j2 = j2 + arg_incr(Y_AXIS,ARG2)
         ENDDO
         l1 = l1 + arg_incr(T_AXIS,ARG1)
         l2 = l2 + arg_incr(T_AXIS,ARG2)
      ENDDO               
      END