fv_diagnostics.F90

!***********************************************************************
!*                   GNU Lesser General Public License
!*
!* This file is part of the FV3 dynamical core.
!*
!* The FV3 dynamical core is free software: you can redistribute it
!* and/or modify it under the terms of the
!* GNU Lesser General Public License as published by the
!* Free Software Foundation, either version 3 of the License, or
!* (at your option) any later version.
!*
!* The FV3 dynamical core is distributed in the hope that it will be
!* useful, but WITHOUT ANY WARRANTY; without even the implied warranty
!* of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
!* See the GNU General Public License for more details.
!*
!* You should have received a copy of the GNU Lesser General Public
!* License along with the FV3 dynamical core.
!* If not, see <http://www.gnu.org/licenses/>.
!***********************************************************************

!!This code is badly in need of refactoring as it has grown too
!! complicated and the logic too cumbersome --- lmh 22nov19

module fv_diagnostics_mod

#ifdef OVERLOAD_R4
 use constantsR4_mod,    only: grav, rdgas, rvgas, pi=>pi_8, kappa, WTMAIR, WTMCO2, WTMH2O, &
                               hlv, cp_air, cp_vapor, TFREEZE
#else
 use constants_mod,      only: grav, rdgas, rvgas, pi=>pi_8, kappa, WTMAIR, WTMCO2, WTMH2O, &
                               hlv, cp_air, cp_vapor, TFREEZE
#endif
 use fv_arrays_mod,      only: radius ! scaled for small earth
 use fms_mod,            only: write_version_number
 use time_manager_mod,   only: time_type, get_date, get_time
 use mpp_domains_mod,    only: domain2d, mpp_update_domains, DGRID_NE, NORTH, EAST
 use diag_manager_mod,   only: diag_axis_init, register_diag_field, &
                               register_static_field, send_data, diag_grid_init, &
                               diag_field_add_attribute
 use fv_arrays_mod,      only: fv_atmos_type, fv_grid_type, fv_diag_type, fv_grid_bounds_type, &
                               R_GRID
 use fv_mapz_mod,        only: E_Flux
 use fv_operators_mod,   only: mappm
 use fv_mp_mod,          only: mp_reduce_sum, mp_reduce_min, mp_reduce_max, is_master
 use fv_eta_mod,         only: get_eta_level, gw_1d
 use fv_grid_utils_mod,  only: g_sum
 use a2b_edge_mod,       only: a2b_ord2, a2b_ord4
 use fv_surf_map_mod,    only: zs_g

 use tracer_manager_mod, only: get_tracer_names, get_number_tracers, get_tracer_index
 use field_manager_mod,  only: MODEL_ATMOS
 use mpp_mod,            only: mpp_error, FATAL, stdlog, mpp_pe, mpp_root_pe, mpp_sum, mpp_max, NOTE, input_nml_file
 use sat_vapor_pres_mod, only: compute_qs, lookup_es

 use fv_arrays_mod, only: max_step
 use gfdl_mp_mod, only: wqs, mqs3d, c_liq, rad_ref, cld_eff_rad

 use fv_diag_column_mod, only: fv_diag_column_init, sounding_column, debug_column

 implicit none
 private

 interface range_check
    module procedure  range_check_3d
    module procedure  range_check_2d
 end interface range_check

 real, parameter:: missing_value = -1.e10
 real, parameter:: missing_value2 = -1.e3 ! for variables with many missing values
 real, parameter:: missing_value3 = 1.e10 ! for variables where we look for smallest values
 real :: ginv
 real :: pk0
 logical master
 character(len=3) :: gn = ''

! private (to this module) diag:

 type(time_type) :: fv_time
 type(fv_diag_type), pointer :: idiag

 logical :: module_is_initialized=.false.
 logical :: prt_minmax =.false.
 logical :: m_calendar
 integer  sphum, liq_wat, ice_wat, cld_amt    ! GFDL physics
 integer  rainwat, snowwat, graupel, o3mr, aerosol
 integer :: istep, mp_top
 real    :: ptop
 real, parameter    ::     rad2deg = 180./pi
 logical :: do_diag_sonde, do_diag_debug
 integer :: sound_freq
 logical :: prt_sounding = .false.
 integer :: user_prt_level = 1
 integer, parameter :: PRT_LEVEL_0 = 0
 integer, parameter :: PRT_LEVEL_1 = 1
 integer, parameter :: PRT_LEVEL_2 = 2
 integer, parameter :: PRT_LEVEL_3 = 3

! tracers
 character(len=128)   :: tname
 character(len=256)   :: tlongname, tunits
 real :: sphum_ll_fix = 0.
 real :: qcly0 ! initial value for terminator test

 public :: fv_diag_init, fv_time, fv_diag, prt_mxm, prt_maxmin, range_check

 public :: prt_mass, prt_minmax, ppme, fv_diag_init_gn, z_sum, sphum_ll_fix, eqv_pot, qcly0, gn
 public :: prt_height, prt_gb_nh_sh, interpolate_vertical, rh_calc, get_height_field, get_height_given_pressure
 public :: cs3_interpolator, get_vorticity
! needed by fv_nggps_diag
 public :: max_vv, max_uh, bunkers_vector, helicity_relative_CAPS
 public :: nplev, levs, id_plev
 public :: max_vorticity
 public :: Mw_air!_0d, Mw_air_3d

 interface Mw_air
    module procedure Mw_air_0d
    module procedure Mw_air_3d
 end interface Mw_air

 integer, parameter :: MAX_PLEVS = 31
 integer :: nplev = 31 !< # of levels in plev interpolated standard level output, with levels given by levs. 31 by default
 integer :: levs(MAX_PLEVS) !< levels for plev interpolated standard level output, in hPa (mb) in increasing order. Extended GFS std levels by default.
 integer :: k100, k200, k300, k500
 integer :: nplev_ave
 integer :: levs_ave(MAX_PLEVS) !< Interfaces of layer averages for nplev_ave regridded output, in hPa (mb) in increasing order. 50,400,850,1000 by default.

 integer :: yr_init, mo_init, dy_init, hr_init, mn_init, sec_init
 integer :: id_dx, id_dy
 integer :: id_plev = 0

 real              :: vrange(2), vsrange(2), wrange(2), trange(2), slprange(2), rhrange(2), psrange(2), skrange(2)

 !Fields needed for diagnostics
 real, allocatable :: w_mr(:)
 real, allocatable :: phalf(:)
 real, allocatable :: zsurf(:,:)
 real, allocatable :: pt1(:)

 ! integer :: id_d_grid_ucomp, id_d_grid_vcomp   ! D grid winds
 ! integer :: id_c_grid_ucomp, id_c_grid_vcomp   ! C grid winds

 namelist /fv_diag_plevs_nml/ nplev, levs, levs_ave, k100, k200, k500

! version number of this module
! Include variable "version" to be written to log file.
#include<file_version.h>

!Constants
#include<fv_diagnostics.h>

contains

 subroutine fv_diag_init(Atm, axes, Time, npx, npy, npz, p_ref)
    type(fv_atmos_type), intent(inout), target :: Atm(:)
    integer, intent(out) :: axes(4)
    type(time_type), intent(in) :: Time
    integer,         intent(in) :: npx, npy, npz
    real, intent(in):: p_ref


    real, allocatable :: grid_xt(:), grid_yt(:), grid_xe(:), grid_ye(:), grid_xn(:), grid_yn(:)
    real, allocatable :: grid_x(:),  grid_y(:)
    real, allocatable :: a3(:,:,:)
    real              :: pfull(npz)
    real              :: hyam(npz), hybm(npz)

    !These id_* are not needed later since they are for static data which is not used elsewhere
    integer :: id_bk, id_pk, id_area, id_lon, id_lat, id_lont, id_latt, id_phalf, id_pfull
    integer :: id_hyam, id_hybm
    integer :: id_plev_ave_edges, id_plev_ave
    integer :: i, j, k, m, n, ntileMe, id_xt, id_yt, id_x, id_y, id_xe, id_ye, id_xn, id_yn
    integer :: isd, ied, jsd, jed, isc, iec, jsc, jec

    logical :: used

    character(len=64) :: plev
    character(len=64) :: field
    integer              :: ntprog
    integer              :: unit

    integer :: ncnst
    integer :: axe2(3)
    integer :: axe_ave(3)

    character(len=64) :: errmsg
#ifdef GFS_PHYS
    character(len=*), parameter :: massdef_str = " (GFS moist-mass)"
#else
    character(len=*), parameter :: massdef_str = ""
#endif
    logical :: exists
    integer :: nlunit, ios

    real, allocatable :: dx(:,:), dy(:,:)

    call write_version_number ( 'FV_DIAGNOSTICS_MOD', version )

    idiag => Atm(1)%idiag

! For total energy diagnostics:
    idiag%steps = 0
    idiag%efx = 0.;       idiag%efx_sum = 0.
    idiag%mtq = 0.;       idiag%mtq_sum = 0.

    ncnst = Atm(1)%ncnst
    m_calendar = Atm(1)%flagstruct%moist_phys

    sphum   = get_tracer_index (MODEL_ATMOS, 'sphum')
    liq_wat = get_tracer_index (MODEL_ATMOS, 'liq_wat')
    ice_wat = get_tracer_index (MODEL_ATMOS, 'ice_wat')

    rainwat = get_tracer_index (MODEL_ATMOS, 'rainwat')
    snowwat = get_tracer_index (MODEL_ATMOS, 'snowwat')
    graupel = get_tracer_index (MODEL_ATMOS, 'graupel')
    o3mr    = get_tracer_index (MODEL_ATMOS, 'o3mr')
    cld_amt = get_tracer_index (MODEL_ATMOS, 'cld_amt')
    aerosol = get_tracer_index (MODEL_ATMOS, 'aerosol')

! valid range for some fields

!!!  This will need mods for more than 1 tile per pe  !!!

    vsrange = (/ -200.,  200. /)  ! surface (lowest layer) winds

    vrange = (/ -330.,  330. /)  ! winds
    wrange = (/ -100.,  100. /)  ! vertical wind
   rhrange = (/  -10.,  150. /)  ! RH
#ifdef HIWPP
    trange = (/    5.,  350. /)  ! temperature
#else
    trange = (/  100.,  350. /)  ! temperature
#endif
    slprange = (/800.,  1200./)  ! sea-level-pressure
    skrange  = (/ -10000000.0,  10000000.0 /)  ! dissipation estimate for SKEB
#ifdef SW_DYNAMICS
    psrange = (/.01, 1.e7 /)
#else
    psrange = (/40000.0, 110000.0/)
#endif

    ginv = 1./GRAV
     if (Atm(1)%grid_number == 1) fv_time = Time

    allocate ( phalf(npz+1) )
    call get_eta_level(Atm(1)%npz, p_ref, pfull, phalf, Atm(1)%ak, Atm(1)%bk, 0.01)

    mp_top = 1
    do k=1,npz
       if ( pfull(k) > 30.e2 ) then
            mp_top = k
            exit
       endif
    enddo
    if ( (user_prt_level >= PRT_LEVEL_2 .or. Atm(1)%flagstruct%fv_debug) .and. is_master() ) then
       write(*,'(2x, A, G20.8, A, G20.8)') 'radar reflectivity: mp_top=', mp_top, 'pfull=', pfull(mp_top)
    endif

!   allocate(grid_xt(npx-1), grid_yt(npy-1), grid_xe(npx), grid_ye(npy-1), grid_xn(npx-1), grid_yn(npy))
    allocate(grid_xt(npx-1), grid_yt(npy-1))
    grid_xt = (/ (i, i=1,npx-1) /)
    grid_yt = (/ (j, j=1,npy-1) /)
!   grid_xe = (/ (i, i=1,npx) /)
!   grid_ye = (/ (j, j=1,npy-1) /)
!   grid_xn = (/ (i, i=1,npx-1) /)
!   grid_yn = (/ (j, j=1,npy) /)

    allocate(grid_x(npx), grid_y(npy))
    grid_x = (/ (i, i=1,npx) /)
    grid_y = (/ (j, j=1,npy) /)

    n=1
    isc = Atm(n)%bd%isc; iec = Atm(n)%bd%iec
    jsc = Atm(n)%bd%jsc; jec = Atm(n)%bd%jec

    isd = Atm(n)%bd%isd; ied = Atm(n)%bd%ied
    jsd = Atm(n)%bd%jsd; jed = Atm(n)%bd%jed

    ! Send diag_manager the grid informtaion
    call diag_grid_init(DOMAIN=Atm(n)%domain, &
         &              GLO_LON=rad2deg*Atm(n)%gridstruct%grid(isc:iec+1,jsc:jec+1,1), &
         &              GLO_LAT=rad2deg*Atm(n)%gridstruct%grid(isc:iec+1,jsc:jec+1,2), &
         &              AGLO_LON=rad2deg*Atm(n)%gridstruct%agrid(isc-1:iec+1,jsc-1:jec+1,1), &
         &              AGLO_LAT=rad2deg*Atm(n)%gridstruct%agrid(isc-1:iec+1,jsc-1:jec+1,2))

    ntileMe = size(Atm(:))
    if (ntileMe > 1) call mpp_error(FATAL, "fv_diag_init can only be called with one grid at a time.")

!    do n = 1, ntileMe
    n = 1
       field = 'grid'

       id_xt = diag_axis_init('grid_xt',grid_xt,'degrees_E','x','T-cell longitude', &
                           set_name=trim(field),Domain2=Atm(n)%Domain, tile_count=n)
       id_yt = diag_axis_init('grid_yt',grid_yt,'degrees_N','y','T-cell latitude',  &
                           set_name=trim(field), Domain2=Atm(n)%Domain, tile_count=n)
!  Don't need these right now
!      id_xe = diag_axis_init ('grid_xe',grid_xe,'degrees_E','x','E-cell longitude', &
!                              set_name=trim(field),Domain2=Domain, tile_count=n)
!      id_ye = diag_axis_init ('grid_ye',grid_ye,'degrees_N','y','E-cell latitude',  &
!                              set_name=trim(field), Domain2=Domain, tile_count=n)
!      id_xn = diag_axis_init ('grid_xn',grid_xn,'degrees_E','x','N-cell longitude', &
!                              set_name=trim(field),Domain2=Domain, aux='geolon_n, geolat_n', tile_count=n)
!      id_yn = diag_axis_init ('grid_yn',grid_yn,'degrees_N','y','N-cell latitude',  &
!                              set_name=trim(field), Domain2=Domain, tile_count=n)

       id_x = diag_axis_init('grid_x',grid_x,'degrees_E','x','cell corner longitude', &
                           set_name=trim(field),Domain2=Atm(n)%Domain, tile_count=n, domain_position=EAST)
       id_y = diag_axis_init('grid_y',grid_y,'degrees_N','y','cell corner latitude',  &
                           set_name=trim(field), Domain2=Atm(n)%Domain, tile_count=n, domain_position=NORTH)

!    end do
!   deallocate(grid_xt, grid_yt, grid_xe, grid_ye, grid_xn, grid_yn)
    deallocate(grid_xt, grid_yt)
    deallocate(grid_x,  grid_y )

    id_phalf = diag_axis_init('phalf', phalf, 'mb', 'z', &
            'ref half pressure level', direction=-1, set_name="dynamics")
    id_pfull = diag_axis_init('pfull', pfull, 'mb', 'z', &
            'ref full pressure level', direction=-1, set_name="dynamics", edges=id_phalf)

!---- register static fields -------

    id_bk    = register_static_field ( "dynamics", 'bk', (/id_phalf/), &
         'vertical coordinate sigma value', 'none' )

    id_pk    = register_static_field ( "dynamics", 'pk', (/id_phalf/), &
         'pressure part of the hybrid coordinate', 'pascal' )

    id_hyam    = register_static_field ( "dynamics", 'hyam', (/id_pfull/), &
         'vertical coordinate A value', '1E-5 Pa' )

    id_hybm    = register_static_field ( "dynamics", 'hybm', (/id_pfull/), &
         'vertical coordinate B value', 'none' )

!--- Send static data

    if ( id_bk > 0 )    used = send_data ( id_bk,Atm(1)%bk, Time )
    if ( id_pk > 0 )    used = send_data ( id_pk,Atm(1)%ak, Time )
    if ( id_hyam > 0 ) then
         do k=1,npz
            hyam(k) = 0.5 * ( Atm(1)%ak(k) + Atm(1)%ak(k+1) ) * 1.E-5
         enddo
         used = send_data ( id_hyam, hyam, Time )
    endif
    if ( id_hybm > 0 ) then
         do k=1,npz
            hybm(k) = 0.5 * ( Atm(1)%bk(k) + Atm(1)%bk(k+1) )
         enddo
         used = send_data ( id_hybm, hybm, Time )
    endif

!   Approach will need modification if we wish to write values on other than A grid.
    axes(1) = id_xt
    axes(2) = id_yt
    axes(3) = id_pfull
    axes(4) = id_phalf

! DEFAULT Selected pressure levels; change with fv_diag_plevs_nml
    levs = 0
    levs(1:nplev) = (/1,2,3,5,7,10,20,30,50,70,100,150,200,250,300,350,400,450,500,550,600,650,700,750,800,850,900,925,950,975,1000/)
    k100 = 11
    k200 = 13
    k300 = 15
    k500 = 19
    levs_ave = 0
    levs_ave(1:4) = (/50,400,850,1000/)
    read(input_nml_file, nml=fv_diag_plevs_nml,iostat=ios)
    if (nplev > MAX_PLEVS) then
       if (is_master()) then
          print*, ' fv_diagnostics: nplev = ', nplev, ' is too large'
          print*, '                 If you need more than ', MAX_PLEVS, ' levels do vertical'
          print*, '                 remapping OFF line to reduce load on the model.'
          call mpp_error(FATAL, ' fv_diagnostics: Stopping model because nplev > MAX_PLEVS')
       endif
    endif
    levs(nplev+1:MAX_PLEVS) = -1.
    if (abs(levs(k100)-100.) > 10.) then
       !call mpp_error(NOTE, "fv_diag_plevs_nml: k100 set incorrectly, finding closest entry in plevs")
       k100 = minloc(abs(levs(1:nplev)-100),1)
    endif
    if (abs(levs(k200)-200.) > 10.) then
       !call mpp_error(NOTE, "fv_diag_plevs_nml: k200 set incorrectly, finding closest entry in plevs")
       k200 = minloc(abs(levs(1:nplev)-200),1)
    endif
    if (abs(levs(k300)-300.) > 10.) then
       !call mpp_error(NOTE, "fv_diag_plevs_nml: k300 set incorrectly, finding closest entry in plevs")
       k300 = minloc(abs(levs(1:nplev)-300),1)
    endif
    if (abs(levs(k500)-500.) > 10.) then
       !call mpp_error(NOTE, "fv_diag_plevs_nml: k500 set incorrectly, finding closest entry in plevs")
       k500 = minloc(abs(levs(1:nplev)-500),1)
    endif

    nplev_ave = 0
    if (levs_ave(1) > 0 ) then
       do i=1,MAX_PLEVS-1
          if (levs_ave(i+1) <= 0) then
             exit
          endif
          if (levs_ave(i) >= levs_ave(i+1)) then
             call mpp_error(FATAL, "fv_diag_plevs_nml: levs_ave is not monotonically increasing.")
          end if
          nplev_ave = nplev_ave + 1
       enddo
    end if

    id_plev = diag_axis_init('plev', levs(1:nplev)*1.0, 'mb', 'z', &
            'actual pressure level', direction=-1, set_name="dynamics")

    axe2(1) = id_xt
    axe2(2) = id_yt
    axe2(3) = id_plev

    id_plev_ave_edges = diag_axis_init('plev_ave_edges', levs_ave(1:nplev_ave+1)*1.0, 'mb', 'z', &
            'averaging layer pressure interface', direction=-1, set_name="dynamics")
    id_plev_ave = diag_axis_init('plev_ave', (levs_ave(1:nplev_ave)+levs_ave(2:nplev_ave+1))*0.5, 'mb', 'z', &
            'averaging layer pressure level', direction=-1, set_name="dynamics", edges=id_plev_ave_edges)

    axe_ave(1) = id_xt
    axe_ave(2) = id_yt
    axe_ave(3) = id_plev_ave

!---- register time independent fields -------

!    do n = 1, ntileMe
    n = 1
       field= 'dynamics'
       id_lon  = register_static_field ( trim(field), 'grid_lon', (/id_x,id_y/),  &
                                         'longitude', 'degrees_E' )
       id_lat  = register_static_field ( trim(field), 'grid_lat', (/id_x,id_y/),  &
                                         'latitude', 'degrees_N' )
       id_lont = register_static_field ( trim(field), 'grid_lont', (/id_xt,id_yt/),  &
                                         'longitude', 'degrees_E' )
       id_latt = register_static_field ( trim(field), 'grid_latt', (/id_xt,id_yt/),  &
                                         'latitude', 'degrees_N' )
       id_area = register_static_field ( trim(field), 'area', axes(1:2),  &
                                         'cell area', 'm**2' )
       if (id_area > 0) then
         call diag_field_add_attribute (id_area, 'cell_methods', 'area: sum')
       endif
       id_dx = register_static_field( trim(field), 'dx', (/id_xt,id_y/), &
            'dx', 'm')
       id_dy = register_static_field( trim(field), 'dy', (/id_x,id_yt/), &
            'dy', 'm')
       id_zsurf = register_static_field ( trim(field), 'zsurf', axes(1:2),  &
                                         'surface height', 'm', interp_method='conserve_order1' )
       id_zs = register_static_field ( trim(field), 'zs', axes(1:2),  &
                                        'Original Mean Terrain', 'm' )
! 3D hybrid_z fields:
       id_ze = register_static_field ( trim(field), 'ze', axes(1:3),  &
                                        'Hybrid_Z_surface', 'm' )
       id_oro = register_static_field ( trim(field), 'oro', axes(1:2),  &
                                        'Land/Water Mask', 'none' )
       id_sgh = register_static_field ( trim(field), 'sgh', axes(1:2),  &
                                        'Terrain Standard deviation', 'm' )
!       id_ts = register_static_field ( trim(field), 'ts', axes(1:2),  &
!                                        'Skin temperature', 'K' )

!--------------------
! Initial conditions:
!--------------------
       ic_ps  = register_static_field ( trim(field), 'ps_ic', axes(1:2),  &
                                         'initial surface pressure', 'Pa' )
       ic_ua = register_static_field ( trim(field), 'ua_ic', axes(1:3),        &
            'initial zonal wind', 'm/s' )
       ic_va = register_static_field ( trim(field), 'va_ic', axes(1:3),        &
            'initial meridional wind', 'm/s' )
       ic_ppt= register_static_field ( trim(field), 'ppt_ic', axes(1:3),        &
            'initial potential temperature', 'K' )
       ic_sphum  = register_static_field ( trim(field), 'sphum_ic', axes(1:2),  &
                                         'initial surface pressure', 'Pa' ) !not used

!    end do

    master = (mpp_pe()==mpp_root_pe())

    n=1
    isc = Atm(n)%bd%isc; iec = Atm(n)%bd%iec
    jsc = Atm(n)%bd%jsc; jec = Atm(n)%bd%jec

    allocate ( zsurf(isc:iec,jsc:jec) )

    do j=jsc,jec
       do i=isc,iec
          zsurf(i,j) = ginv * Atm(n)%phis(i,j)
       enddo
    enddo

!--- Send time independent data

!    do n = 1, ntileMe
    n = 1
       isc = Atm(n)%bd%isc; iec = Atm(n)%bd%iec
       jsc = Atm(n)%bd%jsc; jec = Atm(n)%bd%jec
       if (id_lon  > 0) used = send_data(id_lon,  rad2deg*Atm(n)%gridstruct%grid(isc:iec+1,jsc:jec+1,1), Time)
       if (id_lat  > 0) used = send_data(id_lat,  rad2deg*Atm(n)%gridstruct%grid(isc:iec+1,jsc:jec+1,2), Time)
       if (id_lont > 0) used = send_data(id_lont, rad2deg*Atm(n)%gridstruct%agrid(isc:iec,jsc:jec,1), Time)
       if (id_latt > 0) used = send_data(id_latt, rad2deg*Atm(n)%gridstruct%agrid(isc:iec,jsc:jec,2), Time)
       if (id_area > 0) used = send_data(id_area, Atm(n)%gridstruct%area(isc:iec,jsc:jec), Time)

       allocate(dx(isc:iec+1,jsc:jec+1), dy(isc:iec+1,jsc:jec+1))
       dx(isc:iec,jsc:jec+1) = Atm(n)%gridstruct%dx(isc:iec,jsc:jec+1)
       dy(isc:iec+1,jsc:jec) = Atm(n)%gridstruct%dy(isc:iec+1,jsc:jec)
       if (id_dx > 0) used = send_data(id_dx, dx, Time)
       if (id_dy > 0) used = send_data(id_dy, dy, Time)
       deallocate(dx, dy)

       if (id_zsurf > 0) then
          used = send_data(id_zsurf, zsurf, Time)
          call prt_mxm('ZS', zsurf, isc, iec, jsc, jec, 0,   1, 1.0, &
               Atm(n)%gridstruct%area_64, Atm(n)%domain,PRT_LEVEL_0)
       endif

       if ( Atm(n)%flagstruct%fv_land ) then
         if (id_zs  > 0) used = send_data(id_zs , zs_g, Time)
         if (id_oro > 0) used = send_data(id_oro, Atm(n)%oro(isc:iec,jsc:jec), Time)
         if (id_sgh > 0) used = send_data(id_sgh, Atm(n)%sgh(isc:iec,jsc:jec), Time)
       endif

       if ( Atm(n)%flagstruct%ncep_ic ) then
         if (id_ts > 0) used = send_data(id_ts, Atm(n)%ts(isc:iec,jsc:jec), Time)
       endif

       if ( Atm(n)%flagstruct%hybrid_z .and. id_ze > 0 ) &
                      used = send_data(id_ze, Atm(n)%ze0(isc:iec,jsc:jec,1:npz), Time)

       if (ic_ps > 0) used = send_data(ic_ps, Atm(n)%ps(isc:iec,jsc:jec)*ginv, Time)

       if(ic_ua > 0) used=send_data(ic_ua, Atm(n)%ua(isc:iec,jsc:jec,:), Time)
       if(ic_va > 0) used=send_data(ic_va, Atm(n)%va(isc:iec,jsc:jec,:), Time)

       pk0 = 1000.E2 ** kappa
       if(ic_ppt> 0) then
! Potential temperature
          allocate ( pt1(npz) )
          allocate ( a3(isc:iec,jsc:jec,npz) )
#ifdef TEST_GWAVES
          call gw_1d(npz, 1000.E2, Atm(n)%ak, Atm(n)%ak, Atm(n)%ak(1), 10.E3, pt1)
#else
          pt1 = 0.
#endif
          do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a3(i,j,k) =  (Atm(n)%pt(i,j,k)/Atm(n)%pkz(i,j,k) - pt1(k)) * pk0
             enddo
          enddo
          enddo
          used=send_data(ic_ppt, a3, Time)
          deallocate ( a3 )
          deallocate ( pt1 )
       endif
!    end do

!--------------------------------------------------------------
! Register main prognostic fields: ps, (u,v), t, omega (dp/dt)
!--------------------------------------------------------------

    allocate(id_tracer(ncnst))
    allocate(id_tracer_dmmr(ncnst))
    allocate(id_tracer_dvmr(ncnst))
    allocate(id_tracer_burden(ncnst))
    allocate(w_mr(ncnst))
    id_tracer(:)      = 0
    id_tracer_dmmr(:) = 0
    id_tracer_dvmr(:) = 0
    id_tracer_burden(:) = 0
    w_mr(:) = 0.E0

    allocate(conv_vmr_mmr(ncnst))
    conv_vmr_mmr(:) = .false.

    allocate(id_u_levs(nplev))
    allocate(id_v_levs(nplev))
    allocate(id_t_levs(nplev))
    allocate(id_h_levs(nplev))
    allocate(id_q_levs(nplev))
    allocate(id_ql_levs(nplev))
    allocate(id_qi_levs(nplev))
    allocate(id_qr_levs(nplev))
    allocate(id_qs_levs(nplev))
    allocate(id_qg_levs(nplev))
    allocate(id_cf_levs(nplev))
    allocate(id_omg_levs(nplev))
    allocate(id_w_levs(nplev))
    allocate(id_vort_levs(nplev))
    allocate(id_rh_levs(nplev))
    allocate(id_dp_levs(nplev))
    allocate(id_theta_levs(nplev))
    allocate(id_theta_e_levs(nplev))
    id_u_levs(:)   = 0
    id_v_levs(:)   = 0
    id_t_levs(:)   = 0
    id_h_levs(:)   = 0
    id_q_levs(:)   = 0
    id_ql_levs(:)   = 0
    id_qi_levs(:)   = 0
    id_qr_levs(:)   = 0
    id_qs_levs(:)   = 0
    id_qg_levs(:)   = 0
    id_cf_levs(:)   = 0
    id_omg_levs(:) = 0
    id_w_levs(:) = 0
    id_vort_levs(:) = 0
    id_rh_levs(:) = 0
    id_dp_levs(:) = 0
    id_theta_levs(:) = 0
    id_theta_e_levs(:) = 0

!    do n = 1, ntileMe
    n = 1
       field= 'dynamics'

#ifdef DYNAMICS_ZS
       id_zsurf_t = register_diag_field ( trim(field), 'zsurf_t', axes(1:2), Time,           &
                                       'surface height', 'm', interp_method='conserve_order1')
#endif
!-------------------
! Surface pressure
!-------------------
       id_ps = register_diag_field ( trim(field), 'ps', axes(1:2), Time,           &
            'surface pressure', 'Pa', missing_value=missing_value, range=psrange)

!-------------------
! Mountain torque
!-------------------
       id_mq = register_diag_field ( trim(field), 'mq', axes(1:2), Time,           &
            'mountain torque', 'Hadleys per unit area', missing_value=missing_value )
!-------------------
! Angular momentum
!-------------------
       idiag%id_aam = register_diag_field ( trim(field), 'aam', axes(1:2), Time,           &
            'angular momentum', 'kg*m^2/s', missing_value=missing_value )
       idiag%id_amdt = register_diag_field ( trim(field), 'amdt', axes(1:2), Time,           &
            'angular momentum error', 'kg*m^2/s^2', missing_value=missing_value )

!-------------------
! Precipitation from GFDL MP
!-------------------
       id_pret = register_diag_field ( trim(field), 'pret', axes(1:2), Time,           &
            'total precipitation', 'mm/day', missing_value=missing_value )
       id_prew = register_diag_field ( trim(field), 'prew', axes(1:2), Time,           &
            'water precipitation', 'mm/day', missing_value=missing_value )
       id_prer = register_diag_field ( trim(field), 'prer', axes(1:2), Time,           &
            'rain precipitation', 'mm/day', missing_value=missing_value )
       id_prei = register_diag_field ( trim(field), 'prei', axes(1:2), Time,           &
            'ice precipitation', 'mm/day', missing_value=missing_value )
       id_pres = register_diag_field ( trim(field), 'pres', axes(1:2), Time,           &
            'snow precipitation', 'mm/day', missing_value=missing_value )
       id_preg = register_diag_field ( trim(field), 'preg', axes(1:2), Time,           &
            'graupel precipitation', 'mm/day', missing_value=missing_value )
!-------------------
! Cloud effective radius
!-------------------
       id_qcw = register_diag_field ( trim(field), 'qcw', axes(1:3), Time,           &
            'cloud water water content', 'g/m^2', missing_value=missing_value )
       if (id_qcw > 0) allocate(Atm(n)%inline_mp%qcw(isc:iec,jsc:jec,npz))
       id_qcr = register_diag_field ( trim(field), 'qcr', axes(1:3), Time,           &
            'rain water content', 'g/m^2', missing_value=missing_value )
       if (id_qcr > 0) allocate(Atm(n)%inline_mp%qcr(isc:iec,jsc:jec,npz))
       id_qci = register_diag_field ( trim(field), 'qci', axes(1:3), Time,           &
            'cloud ice water content', 'g/m^2', missing_value=missing_value )
       if (id_qci > 0) allocate(Atm(n)%inline_mp%qci(isc:iec,jsc:jec,npz))
       id_qcs = register_diag_field ( trim(field), 'qcs', axes(1:3), Time,           &
            'snow water content', 'g/m^2', missing_value=missing_value )
       if (id_qcs > 0) allocate(Atm(n)%inline_mp%qcs(isc:iec,jsc:jec,npz))
       id_qcg = register_diag_field ( trim(field), 'qcg', axes(1:3), Time,           &
            'graupel water content', 'g/m^2', missing_value=missing_value )
       if (id_qcg > 0) allocate(Atm(n)%inline_mp%qcg(isc:iec,jsc:jec,npz))
       id_rew = register_diag_field ( trim(field), 'rew', axes(1:3), Time,           &
            'cloud water effective radius', 'micron', missing_value=missing_value )
       if (id_rew > 0) allocate(Atm(n)%inline_mp%rew(isc:iec,jsc:jec,npz))
       id_rer = register_diag_field ( trim(field), 'rer', axes(1:3), Time,           &
            'rain effective radius', 'micron', missing_value=missing_value )
       if (id_rer > 0) allocate(Atm(n)%inline_mp%rer(isc:iec,jsc:jec,npz))
       id_rei = register_diag_field ( trim(field), 'rei', axes(1:3), Time,           &
            'cloud ice effective radius', 'micron', missing_value=missing_value )
       if (id_rei > 0) allocate(Atm(n)%inline_mp%rei(isc:iec,jsc:jec,npz))
       id_res = register_diag_field ( trim(field), 'res', axes(1:3), Time,           &
            'snow effective radius', 'micron', missing_value=missing_value )
       if (id_res > 0) allocate(Atm(n)%inline_mp%res(isc:iec,jsc:jec,npz))
       id_reg = register_diag_field ( trim(field), 'reg', axes(1:3), Time,           &
            'graupel effective radius', 'micron', missing_value=missing_value )
       if (id_reg > 0) allocate(Atm(n)%inline_mp%reg(isc:iec,jsc:jec,npz))
       id_cld = register_diag_field ( trim(field), 'cld', axes(1:3), Time,           &
            'cloud fraction', '%', missing_value=missing_value )
       if (id_cld > 0) allocate(Atm(n)%inline_mp%cld(isc:iec,jsc:jec,npz))
!-------------------
! Microphysical process diagnostic from GFDL MP
!-------------------
       id_mppcw = register_diag_field ( trim(field), 'mppcw', axes(1:2), Time,           &
            'Condensation (to Cloud Water) Rate', 'mm/day', missing_value=missing_value )
       id_mppew = register_diag_field ( trim(field), 'mppew', axes(1:2), Time,           &
            'Evaporation (of Cloud Water) Rate', 'mm/day', missing_value=missing_value )
       id_mppe1 = register_diag_field ( trim(field), 'mppe1', axes(1:2), Time,           &
            'Instant Evaporation (of Cloud Water) Rate', 'mm/day', missing_value=missing_value )
       id_mpper = register_diag_field ( trim(field), 'mpper', axes(1:2), Time,           &
            'Evaporation (of Rain) Rate', 'mm/day', missing_value=missing_value )
       id_mppdi = register_diag_field ( trim(field), 'mppdi', axes(1:2), Time,           &
            'Deposition (to Cloud Ice) Rate', 'mm/day', missing_value=missing_value )
       id_mppd1 = register_diag_field ( trim(field), 'mppd1', axes(1:2), Time,           &
            'Instant Deposition (to Cloud Ice) Rate', 'mm/day', missing_value=missing_value )
       id_mppds = register_diag_field ( trim(field), 'mppds', axes(1:2), Time,           &
            'Deposition (to Snow) Rate', 'mm/day', missing_value=missing_value )
       id_mppdg = register_diag_field ( trim(field), 'mppdg', axes(1:2), Time,           &
            'Deposition (to Graupel) Rate', 'mm/day', missing_value=missing_value )
       id_mppsi = register_diag_field ( trim(field), 'mppsi', axes(1:2), Time,           &
            'Sublimation (of Cloud Ice) Rate', 'mm/day', missing_value=missing_value )
       id_mpps1 = register_diag_field ( trim(field), 'mpps1', axes(1:2), Time,           &
            'Instant Sublimation (of Cloud Ice) Rate', 'mm/day', missing_value=missing_value )
       id_mppss = register_diag_field ( trim(field), 'mppss', axes(1:2), Time,           &
            'Sublimation (of Snow) Rate', 'mm/day', missing_value=missing_value )
       id_mppsg = register_diag_field ( trim(field), 'mppsg', axes(1:2), Time,           &
            'Sublimation (of Graupel) Rate', 'mm/day', missing_value=missing_value )
       id_mppfw = register_diag_field ( trim(field), 'mppfw', axes(1:2), Time,           &
            'Freezing (of Cloud Water) Rate', 'mm/day', missing_value=missing_value )
       id_mppfr = register_diag_field ( trim(field), 'mppfr', axes(1:2), Time,           &
            'Freezing (of Rain) Rate', 'mm/day', missing_value=missing_value )
       id_mppmi = register_diag_field ( trim(field), 'mppmi', axes(1:2), Time,           &
            'Melting (of Cloud Ice) Rate', 'mm/day', missing_value=missing_value )
       id_mppms = register_diag_field ( trim(field), 'mppms', axes(1:2), Time,           &
            'Melting (of Snow) Rate', 'mm/day', missing_value=missing_value )
       id_mppmg = register_diag_field ( trim(field), 'mppmg', axes(1:2), Time,           &
            'Melting (of Graupel) Rate', 'mm/day', missing_value=missing_value )
       id_mppm1 = register_diag_field ( trim(field), 'mppm1', axes(1:2), Time,           &
            'Sedimentational Melting (of Cloud Ice) Rate', 'mm/day', missing_value=missing_value )
       id_mppm2 = register_diag_field ( trim(field), 'mppm2', axes(1:2), Time,           &
            'Sedimentational Melting (of Snow) Rate', 'mm/day', missing_value=missing_value )
       id_mppm3 = register_diag_field ( trim(field), 'mppm3', axes(1:2), Time,           &
            'Sedimentational Melting (of Graupel) Rate', 'mm/day', missing_value=missing_value )
       id_mppar = register_diag_field ( trim(field), 'mppar', axes(1:2), Time,           &
            'Autoconversion (to Rain) Rate', 'mm/day', missing_value=missing_value )
       id_mppas = register_diag_field ( trim(field), 'mppas', axes(1:2), Time,           &
            'Autoconversion (to Snow) Rate', 'mm/day', missing_value=missing_value )
       id_mppag = register_diag_field ( trim(field), 'mppag', axes(1:2), Time,           &
            'Autoconversion (to Graupel) Rate', 'mm/day', missing_value=missing_value )
       id_mpprs = register_diag_field ( trim(field), 'mpprs', axes(1:2), Time,           &
            'Riming (to Snow) Rate', 'mm/day', missing_value=missing_value )
       id_mpprg = register_diag_field ( trim(field), 'mpprg', axes(1:2), Time,           &
            'Riming (to Graupel) Rate', 'mm/day', missing_value=missing_value )
       id_mppxr = register_diag_field ( trim(field), 'mppxr', axes(1:2), Time,           &
            'Accretion (to Rain) Rate', 'mm/day', missing_value=missing_value )
       id_mppxs = register_diag_field ( trim(field), 'mppxs', axes(1:2), Time,           &
            'Accretion (to Snow) Rate', 'mm/day', missing_value=missing_value )
       id_mppxg = register_diag_field ( trim(field), 'mppxg', axes(1:2), Time,           &
            'Accretion (to Graupel) Rate', 'mm/day', missing_value=missing_value )
!-------------------
!! 3D Tendency terms from GFDL MP and physics
!-------------------
       if (Atm(n)%flagstruct%write_3d_diags) then

          id_qv_dt_gfdlmp = register_diag_field ( trim(field), 'qv_dt_gfdlmp', axes(1:3), Time,           &
               'water vapor specific humidity tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
          if (id_qv_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%qv_dt(isc:iec,jsc:jec,npz))
          id_ql_dt_gfdlmp = register_diag_field ( trim(field), 'ql_dt_gfdlmp', axes(1:3), Time,           &
               'total liquid water tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
          if (id_ql_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%ql_dt(isc:iec,jsc:jec,npz))
          id_qi_dt_gfdlmp = register_diag_field ( trim(field), 'qi_dt_gfdlmp', axes(1:3), Time,           &
               'total ice water tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
          if (id_qi_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%qi_dt(isc:iec,jsc:jec,npz))

          id_liq_wat_dt_gfdlmp = register_diag_field ( trim(field), 'liq_wat_dt_gfdlmp', axes(1:3), Time,           &
               'liquid water tracer tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
          if (id_liq_wat_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%liq_wat_dt(isc:iec,jsc:jec,npz))
          id_ice_wat_dt_gfdlmp = register_diag_field ( trim(field), 'ice_wat_dt_gfdlmp', axes(1:3), Time,           &
               'ice water tracer tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
          if (id_ice_wat_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%ice_wat_dt(isc:iec,jsc:jec,npz))

          id_qr_dt_gfdlmp = register_diag_field ( trim(field), 'qr_dt_gfdlmp', axes(1:3), Time,           &
               'rain water tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
          if (id_qr_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%qr_dt(isc:iec,jsc:jec,npz))
          id_qg_dt_gfdlmp = register_diag_field ( trim(field), 'qg_dt_gfdlmp', axes(1:3), Time,           &
               'graupel tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
          if (id_qg_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%qg_dt(isc:iec,jsc:jec,npz))
          id_qs_dt_gfdlmp = register_diag_field ( trim(field), 'qs_dt_gfdlmp', axes(1:3), Time,           &
               'snow water tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
          if (id_qs_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%qs_dt(isc:iec,jsc:jec,npz))
          id_T_dt_gfdlmp = register_diag_field ( trim(field), 'T_dt_gfdlmp', axes(1:3), Time,           &
               'temperature tendency from GFDL MP', 'K/s', missing_value=missing_value )
          if (id_T_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%T_dt(isc:iec,jsc:jec,npz))
          id_u_dt_gfdlmp = register_diag_field ( trim(field), 'u_dt_gfdlmp', axes(1:3), Time,           &
               'zonal wind tendency from GFDL MP', 'm/s/s', missing_value=missing_value )
          if (id_u_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%u_dt(isc:iec,jsc:jec,npz))
          id_v_dt_gfdlmp = register_diag_field ( trim(field), 'v_dt_gfdlmp', axes(1:3), Time,           &
               'meridional wind tendency from GFDL MP', 'm/s/s', missing_value=missing_value )
          if (id_v_dt_gfdlmp > 0) allocate(Atm(n)%inline_mp%v_dt(isc:iec,jsc:jec,npz))

          id_T_dt_phys = register_diag_field ( trim(field), 'T_dt_phys', axes(1:3), Time,           &
               'temperature tendency from physics', 'K/s', missing_value=missing_value )
          if (id_T_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_t_dt(isc:iec,jsc:jec,npz))
          id_u_dt_phys = register_diag_field ( trim(field), 'u_dt_phys', axes(1:3), Time,           &
               'zonal wind tendency from physics', 'm/s/s', missing_value=missing_value )
          if (id_u_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_u_dt(isc:iec,jsc:jec,npz))
          id_v_dt_phys = register_diag_field ( trim(field), 'v_dt_phys', axes(1:3), Time,           &
               'meridional wind tendency from physics', 'm/s/s', missing_value=missing_value )
          if (id_v_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_v_dt(isc:iec,jsc:jec,npz))



          id_qv_dt_phys = register_diag_field ( trim(field), 'qv_dt_phys', axes(1:3), Time,           &
               'water vapor specific humidity tendency from physics', 'kg/kg/s', missing_value=missing_value )
          if (id_qv_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_qv_dt(isc:iec,jsc:jec,npz))
          id_ql_dt_phys = register_diag_field ( trim(field), 'ql_dt_phys', axes(1:3), Time,           &
               'total liquid water tendency from physics', 'kg/kg/s', missing_value=missing_value )
          if (id_ql_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_ql_dt(isc:iec,jsc:jec,npz))
          id_qi_dt_phys = register_diag_field ( trim(field), 'qi_dt_phys', axes(1:3), Time,           &
               'total ice water tendency from physics', 'kg/kg/s', missing_value=missing_value )
          if (id_qi_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_qi_dt(isc:iec,jsc:jec,npz))

          id_liq_wat_dt_phys = register_diag_field ( trim(field), 'liq_wat_dt_phys', axes(1:3), Time,           &
               'liquid water tracer tendency from physics', 'kg/kg/s', missing_value=missing_value )
          if (id_liq_wat_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_liq_wat_dt(isc:iec,jsc:jec,npz))
          id_ice_wat_dt_phys = register_diag_field ( trim(field), 'ice_wat_dt_phys', axes(1:3), Time,           &
               'ice water tracer tendency from physics', 'kg/kg/s', missing_value=missing_value )
          if (id_ice_wat_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_ice_wat_dt(isc:iec,jsc:jec,npz))

          id_qr_dt_phys = register_diag_field ( trim(field), 'qr_dt_phys', axes(1:3), Time,           &
               'rain water tendency from physics', 'kg/kg/s', missing_value=missing_value )
          if (id_qr_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_qr_dt(isc:iec,jsc:jec,npz))
          id_qg_dt_phys = register_diag_field ( trim(field), 'qg_dt_phys', axes(1:3), Time,           &
               'graupel tendency from physics', 'kg/kg/s', missing_value=missing_value )
          if (id_qg_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_qg_dt(isc:iec,jsc:jec,npz))
          id_qs_dt_phys = register_diag_field ( trim(field), 'qs_dt_phys', axes(1:3), Time,           &
               'snow water tendency from physics', 'kg/kg/s', missing_value=missing_value )
          if (id_qs_dt_phys > 0) allocate (Atm(n)%phys_diag%phys_qs_dt(isc:iec,jsc:jec,npz))

          idiag%id_T_dt_sg = register_diag_field ( trim(field), 'T_dt_sg', axes(1:3), Time,           &
               'temperature tendency from 2dz subgrid mixing', 'K/s', missing_value=missing_value )
          if ((idiag%id_t_dt_sg > 0) .and. (.not. allocated(Atm(n)%sg_diag%t_dt))) then
             allocate (Atm(n)%sg_diag%t_dt(isc:iec,jsc:jec,1:npz))
             Atm(n)%sg_diag%t_dt = 0.0
          endif
          idiag%id_u_dt_sg = register_diag_field ( trim(field), 'u_dt_sg', axes(1:3), Time,           &
               'zonal wind tendency from 2dz subgrid mixing', 'm/s/s', missing_value=missing_value )
          if ((idiag%id_u_dt_sg > 0) .and. (.not. allocated(Atm(n)%sg_diag%u_dt))) then
             allocate (Atm(n)%sg_diag%u_dt(isc:iec,jsc:jec,1:npz))
             Atm(n)%sg_diag%u_dt = 0.0
          endif
          idiag%id_v_dt_sg = register_diag_field ( trim(field), 'v_dt_sg', axes(1:3), Time,           &
               'meridional wind tendency from 2dz subgrid mixing', 'm/s/s', missing_value=missing_value )
          if ((idiag%id_v_dt_sg > 0) .and. (.not. allocated(Atm(n)%sg_diag%v_dt))) then
             allocate (Atm(n)%sg_diag%v_dt(isc:iec,jsc:jec,1:npz))
             Atm(n)%sg_diag%v_dt = 0.0
          endif
          idiag%id_qv_dt_sg = register_diag_field ( trim(field), 'qv_dt_sg', axes(1:3), Time,           &
               'water vapor tendency from 2dz subgrid mixing', 'kg/kg/s', missing_value=missing_value )
          if ((idiag%id_qv_dt_sg > 0) .and. (.not. allocated(Atm(n)%sg_diag%qv_dt))) then
             allocate (Atm(n)%sg_diag%qv_dt(isc:iec,jsc:jec,1:npz))
             Atm(n)%sg_diag%qv_dt = 0.0
          endif

          ! Nudging tendencies
          id_t_dt_nudge = register_diag_field('dynamics', &
               't_dt_nudge', axes(1:3), Time, &
               'temperature tendency from nudging', &
               'K/s', missing_value=missing_value)
          if ((id_t_dt_nudge > 0) .and. (.not. allocated(Atm(n)%nudge_diag%nudge_t_dt))) then
             allocate (Atm(n)%nudge_diag%nudge_t_dt(isc:iec,jsc:jec,npz))
             Atm(n)%nudge_diag%nudge_t_dt(isc:iec,jsc:jec,1:npz) = 0.0
          endif
          id_ps_dt_nudge = register_diag_field('dynamics', &
               'ps_dt_nudge', axes(1:2), Time, &
               'surface pressure tendency from nudging', &
               'Pa/s', missing_value=missing_value)
          if ((id_ps_dt_nudge > 0) .and. (.not. allocated(Atm(n)%nudge_diag%nudge_ps_dt))) then
             allocate (Atm(n)%nudge_diag%nudge_ps_dt(isc:iec,jsc:jec))
             Atm(n)%nudge_diag%nudge_ps_dt(isc:iec,jsc:jec) = 0.0
          endif
          id_delp_dt_nudge = register_diag_field('dynamics', &
               'delp_dt_nudge', axes(1:3), Time, &
               'pressure thickness tendency from nudging', &
               'Pa/s', missing_value=missing_value)
          if ((id_delp_dt_nudge > 0) .and. (.not. allocated(Atm(n)%nudge_diag%nudge_delp_dt))) then
             allocate (Atm(n)%nudge_diag%nudge_delp_dt(isc:iec,jsc:jec,npz))
             Atm(n)%nudge_diag%nudge_delp_dt(isc:iec,jsc:jec,1:npz) = 0.0
          endif
          id_u_dt_nudge = register_diag_field('dynamics', &
               'u_dt_nudge', axes(1:3), Time, &
               'zonal wind tendency from nudging', &
               'm/s/s', missing_value=missing_value)
          if ((id_u_dt_nudge > 0) .and. (.not. allocated(Atm(n)%nudge_diag%nudge_u_dt))) then
             allocate (Atm(n)%nudge_diag%nudge_u_dt(isc:iec,jsc:jec,npz))
             Atm(n)%nudge_diag%nudge_u_dt(isc:iec,jsc:jec,1:npz) = 0.0
          endif
          id_v_dt_nudge = register_diag_field('dynamics', &
               'v_dt_nudge', axes(1:3), Time, &
               'meridional wind tendency from nudging', &
               'm/s/s', missing_value=missing_value)
          if ((id_v_dt_nudge > 0) .and. (.not. allocated(Atm(n)%nudge_diag%nudge_v_dt))) then
             allocate (Atm(n)%nudge_diag%nudge_v_dt(isc:iec,jsc:jec,npz))
             Atm(n)%nudge_diag%nudge_v_dt(isc:iec,jsc:jec,1:npz) = 0.0
          endif
          id_qv_dt_nudge = register_diag_field('dynamics', &
               'qv_dt_nudge', axes(1:3), Time, &
               'specific humidity tendency from nudging', &
               'kg/kg/s', missing_value=missing_value)
          if ((id_qv_dt_nudge > 0) .and. (.not. allocated(Atm(n)%nudge_diag%nudge_qv_dt))) then
             allocate (Atm(n)%nudge_diag%nudge_qv_dt(isc:iec,jsc:jec,npz))
             Atm(n)%nudge_diag%nudge_qv_dt(isc:iec,jsc:jec,1:npz) = 0.0
          endif

          id_t_dt_diabatic = register_diag_field ( trim(field), 'T_dt_diabatic', axes(1:3), Time,           &
               'temperature tendency from diabatic processes (t_dt_phys + t_dt_gfdlmp)', 'K/s', missing_value=missing_value )
          if (id_t_dt_diabatic > 0) then
             if (.not. allocated(Atm(n)%phys_diag%phys_t_dt)) then
                allocate(Atm(n)%phys_diag%phys_t_dt(isc:iec,jsc:jec,npz))
             endif
             if (.not. allocated(Atm(n)%inline_mp%t_dt)) then
                allocate(Atm(n)%inline_mp%t_dt(isc:iec,jsc:jec,npz))
             endif
          endif
          id_qv_dt_diabatic = register_diag_field ( trim(field), 'qv_dt_diabatic', axes(1:3), Time,           &
               'temperature tendency from diabatic processes (qv_dt_phys + qv_dt_gfdlmp)', 'kg/kg/s', missing_value=missing_value )
          if (id_qv_dt_diabatic > 0) then
             if (.not. allocated(Atm(n)%phys_diag%phys_qv_dt)) then
                allocate(Atm(n)%phys_diag%phys_qv_dt(isc:iec,jsc:jec,npz))
             endif
             if (.not. allocated(Atm(n)%inline_mp%qv_dt)) then
                allocate(Atm(n)%inline_mp%qv_dt(isc:iec,jsc:jec,npz))
             endif
          endif
       endif

!
      do i=1,nplev
        write(plev,'(I5)') levs(i)
! Height:
        id_h_levs(i)   = register_diag_field(trim(field), 'z'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb height', 'm', missing_value=missing_value)
! u-wind:
        id_u_levs(i)   = register_diag_field(trim(field), 'u'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb u', 'm/s', missing_value=missing_value)
! v-wind:
        id_v_levs(i)   = register_diag_field(trim(field), 'v'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb v', 'm/s', missing_value=missing_value)
! Temperature (K):
        id_t_levs(i)   = register_diag_field(trim(field), 't'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb temperature', 'K', missing_value=missing_value)
! specific humidity:
        id_q_levs(i)   = register_diag_field(trim(field), 'q'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb specific humidity', 'kg/kg', missing_value=missing_value)
! cloud water mass mixing ratio:
        id_ql_levs(i)   = register_diag_field(trim(field), 'ql'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb cloud water mass mixing ratio', 'kg/kg', missing_value=missing_value)
! cloud ice mass mixing ratio:
        id_qi_levs(i)   = register_diag_field(trim(field), 'qi'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb cloud ice mass mixing ratio', 'kg/kg', missing_value=missing_value)
! rain mass mixing ratio:
        id_qr_levs(i)   = register_diag_field(trim(field), 'qr'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb rain mass mixing ratio', 'kg/kg', missing_value=missing_value)
! snow mass mixing ratio:
        id_qs_levs(i)   = register_diag_field(trim(field), 'qs'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb snow mass mixing ratio', 'kg/kg', missing_value=missing_value)
! graupel mass mixing ratio:
        id_qg_levs(i)   = register_diag_field(trim(field), 'qg'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb graupel mass mixing ratio', 'kg/kg', missing_value=missing_value)
! cloud fraction:
        id_cf_levs(i)   = register_diag_field(trim(field), 'cf'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb cloud fraction', '1', missing_value=missing_value)
! Omega (Pa/sec):
        id_omg_levs(i) = register_diag_field(trim(field), 'omg'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb omega', 'Pa/s', missing_value=missing_value)
! w (m/s)
        id_w_levs(i)   = register_diag_field(trim(field), 'w'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb vertical velocity', 'm/s', missing_value=missing_value)
! vort (1/s)
        id_vort_levs(i)   = register_diag_field(trim(field), 'vort'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb vertical vorticity', '1/s', missing_value=missing_value)
! rh (%)
        id_rh_levs(i)   = register_diag_field(trim(field), 'rh'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb relative humidity', '%', missing_value=missing_value)
! dp (K)
        id_dp_levs(i)   = register_diag_field(trim(field), 'dp'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb dew point', 'K', missing_value=missing_value)
! theta (K)
        id_theta_levs(i)   = register_diag_field(trim(field), 'theta'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb potential temperature', 'K', missing_value=missing_value)
! theta_e (K)
        id_theta_e_levs(i)   = register_diag_field(trim(field), 'theta_e'//trim(adjustl(plev)), axes(1:2), Time, &
                                    trim(adjustl(plev))//'-mb equivalent potential temperature', 'K', missing_value=missing_value)
      enddo

       if (Atm(n)%flagstruct%write_3d_diags) then
          id_u_plev = register_diag_field ( trim(field), 'u_plev', axe2(1:3), Time,        &
               'zonal wind', 'm/sec', missing_value=missing_value, range=vrange )
          id_v_plev = register_diag_field ( trim(field), 'v_plev', axe2(1:3), Time,        &
               'meridional wind', 'm/sec', missing_value=missing_value, range=vrange )
          if (Atm(n)%flagstruct%is_ideal_case) then
             id_t_plev = register_diag_field ( trim(field), 't_plev', axe2(1:3), Time,        &
                  'temperature', 'K', missing_value=missing_value )
          else
             id_t_plev = register_diag_field ( trim(field), 't_plev', axe2(1:3), Time,        &
                  'temperature', 'K', missing_value=missing_value, range=trange )
          endif
          id_h_plev = register_diag_field ( trim(field), 'h_plev', axe2(1:3), Time,        &
               'height', 'm', missing_value=missing_value )
          id_q_plev = register_diag_field ( trim(field), 'q_plev', axe2(1:3), Time,        &
               'specific humidity', 'kg/kg', missing_value=missing_value )
          id_ql_plev = register_diag_field ( trim(field), 'ql_plev', axe2(1:3), Time,        &
               'cloud water mass mixing ratio', 'kg/kg', missing_value=missing_value )
          id_qi_plev = register_diag_field ( trim(field), 'qi_plev', axe2(1:3), Time,        &
               'cloud ice mass mixing ratio', 'kg/kg', missing_value=missing_value )
          id_qr_plev = register_diag_field ( trim(field), 'qr_plev', axe2(1:3), Time,        &
               'rain mass mixing ratio', 'kg/kg', missing_value=missing_value )
          id_qs_plev = register_diag_field ( trim(field), 'qs_plev', axe2(1:3), Time,        &
               'snow mass mixing ratio', 'kg/kg', missing_value=missing_value )
          id_qg_plev = register_diag_field ( trim(field), 'qg_plev', axe2(1:3), Time,        &
               'graupel mass mixing ratio', 'kg/kg', missing_value=missing_value )
          id_cf_plev = register_diag_field ( trim(field), 'cf_plev', axe2(1:3), Time,        &
               'cloud fraction', '1', missing_value=missing_value )
          id_omg_plev = register_diag_field ( trim(field), 'omg_plev', axe2(1:3), Time,        &
               'omega', 'Pa/s', missing_value=missing_value )
          id_w_plev = register_diag_field ( trim(field), 'w_plev', axe2(1:3), Time,        &
               'vertical velocity', 'm/s', missing_value=missing_value )
          id_vort_plev = register_diag_field ( trim(field), 'vort_plev', axe2(1:3), Time,        &
               'vertical vorticity', '1/s', missing_value=missing_value )
          id_rh_plev = register_diag_field ( trim(field), 'rh_plev', axe2(1:3), Time,        &
               'relative humidity', '%', missing_value=missing_value )
          id_dp_plev = register_diag_field ( trim(field), 'dp_plev', axe2(1:3), Time,        &
               'dew point', 'K', missing_value=missing_value )
          id_theta_plev = register_diag_field ( trim(field), 'theta_plev', axe2(1:3), Time,        &
               'potential temperature', 'K', missing_value=missing_value )
          id_theta_e_plev = register_diag_field ( trim(field), 'theta_e_plev', axe2(1:3), Time,        &
               'equivalent potential temperature', 'K', missing_value=missing_value )
       endif

      !Layer averages for temperature, moisture, etc.
        id_t_plev_ave   = register_diag_field(trim(field), 't_plev_ave', axe_ave(1:3), Time, &
                                    'layer-averaged temperature', 'K', missing_value=missing_value)
        id_q_plev_ave   = register_diag_field(trim(field), 'q_plev_ave', axe_ave(1:3), Time, &
                                    'layer-averaged specific humidity', 'kg/kg', missing_value=missing_value)
        id_qv_dt_gfdlmp_plev_ave = register_diag_field ( trim(field), 'qv_dt_gfdlmp_plev_ave', axe_ave(1:3), Time,           &
               'layer-averaged water vapor specific humidity tendency from GFDL MP', 'kg/kg/s', missing_value=missing_value )
        if (id_qv_dt_gfdlmp_plev_ave > 0 .and. .not. allocated(Atm(n)%inline_mp%qv_dt) ) allocate(Atm(n)%inline_mp%qv_dt(isc:iec,jsc:jec,npz))
        id_t_dt_gfdlmp_plev_ave = register_diag_field ( trim(field), 't_dt_gfdlmp_plev_ave', axe_ave(1:3), Time,           &
               'layer-averaged temperature tendency from GFDL MP', 'K/s', missing_value=missing_value )
        if (id_t_dt_gfdlmp_plev_ave > 0 .and. .not. allocated(Atm(n)%inline_mp%t_dt) ) allocate(Atm(n)%inline_mp%t_dt(isc:iec,jsc:jec,npz))
        id_qv_dt_phys_plev_ave = register_diag_field ( trim(field), 'qv_dt_phys_plev_ave', axe_ave(1:3), Time,           &
               'layer-averaged water vapor specific humidity tendency from physics', 'kg/kg/s', missing_value=missing_value )
        if (id_qv_dt_phys_plev_ave > 0 .and. .not. allocated(Atm(n)%phys_diag%phys_qv_dt) ) allocate(Atm(n)%phys_diag%phys_qv_dt(isc:iec,jsc:jec,npz))
        id_t_dt_phys_plev_ave = register_diag_field ( trim(field), 't_dt_phys_plev_ave', axe_ave(1:3), Time,           &
               'layer-averaged temperature tendency from physics', 'K/s', missing_value=missing_value )
        if (id_t_dt_phys_plev_ave > 0 .and. .not. allocated(Atm(n)%phys_diag%phys_t_dt) ) allocate(Atm(n)%phys_diag%phys_t_dt(isc:iec,jsc:jec,npz))

      ! flag for calculation of geopotential
      if ( any(id_h_levs > 0) .or. id_h_plev>0 .or. id_hght3d>0) then
           id_any_hght = 1
      else
           id_any_hght = 0
      endif
!-----------------------------
! mean temp between 300-500 mb
!-----------------------------
      id_tm = register_diag_field (trim(field), 'tm', axes(1:2),  Time,   &
                                   'mean 300-500 mb temp', 'K', missing_value=missing_value, range=(/140.0,400.0/) )

!-------------------
! Sea-level-pressure
!-------------------
       id_slp = register_diag_field (trim(field), 'slp', axes(1:2),  Time,   &
                                     'sea-level pressure', 'mb', missing_value=missing_value,  &
                                      range=slprange )
!----------------------------------
! Bottom level pressure for masking
!----------------------------------
       id_pmask = register_diag_field (trim(field), 'pmask', axes(1:2),  Time,   &
                                     'masking pressure at lowest level', 'mb',   &
                                      missing_value=missing_value )
!------------------------------------------
! Fix for Bottom level pressure for masking
!------------------------------------------
       id_pmaskv2 = register_diag_field(TRIM(field), 'pmaskv2', axes(1:2), Time,&
            & 'masking pressure at lowest level', 'mb', missing_value=missing_value)

!-------------------
! Hurricane scales:
!-------------------
! Net effects: ~ intensity * freq
       id_c15 = register_diag_field (trim(field), 'cat15', axes(1:2),  Time,   &
                                     'de-pression < 1000', 'mb', missing_value=missing_value)
       id_c25 = register_diag_field (trim(field), 'cat25', axes(1:2),  Time,   &
                                     'de-pression < 980', 'mb', missing_value=missing_value)
       id_c35 = register_diag_field (trim(field), 'cat35', axes(1:2),  Time,   &
                                     'de-pression < 964', 'mb', missing_value=missing_value)
       id_c45 = register_diag_field (trim(field), 'cat45', axes(1:2),  Time,   &
                                     'de-pression < 944', 'mb', missing_value=missing_value)
! Frequency:
       id_f15 = register_diag_field (trim(field), 'f15', axes(1:2),  Time,   &
                                     'Cat15 frequency', 'none', missing_value=missing_value)
       id_f25 = register_diag_field (trim(field), 'f25', axes(1:2),  Time,   &
                                     'Cat25 frequency', 'none', missing_value=missing_value)
       id_f35 = register_diag_field (trim(field), 'f35', axes(1:2),  Time,   &
                                     'Cat35 frequency', 'none', missing_value=missing_value)
       id_f45 = register_diag_field (trim(field), 'f45', axes(1:2),  Time,   &
                                     'Cat45 frequency', 'none', missing_value=missing_value)
!-------------------
! A grid winds (lat-lon)
!-------------------
       if (Atm(n)%flagstruct%write_3d_diags) then
          id_ua = register_diag_field ( trim(field), 'ucomp', axes(1:3), Time,        &
               'zonal wind', 'm/sec', missing_value=missing_value, range=vrange )
          id_va = register_diag_field ( trim(field), 'vcomp', axes(1:3), Time,        &
               'meridional wind', 'm/sec', missing_value=missing_value, range=vrange)
          if ( .not. Atm(n)%flagstruct%hydrostatic )                                        &
               id_w = register_diag_field ( trim(field), 'w', axes(1:3), Time,        &
               'vertical wind', 'm/sec', missing_value=missing_value, range=wrange )
          if (Atm(n)%flagstruct%is_ideal_case) then
             id_pt   = register_diag_field ( trim(field), 'temp', axes(1:3), Time,       &
                  'temperature', 'K', missing_value=missing_value )
          else
             id_pt   = register_diag_field ( trim(field), 'temp', axes(1:3), Time,       &
                  'temperature', 'K', missing_value=missing_value, range=trange )
          endif
          id_ppt  = register_diag_field ( trim(field), 'theta', axes(1:3), Time,       &
               'potential temperature', 'K', missing_value=missing_value )
          id_theta_e = register_diag_field ( trim(field), 'theta_e', axes(1:3), Time,       &
               'equivalent potential temperature', 'K', missing_value=missing_value )
          id_omga = register_diag_field ( trim(field), 'omega', axes(1:3), Time,      &
               'omega', 'Pa/s', missing_value=missing_value )
          idiag%id_divg  = register_diag_field ( trim(field), 'divg', axes(1:3), Time,      &
               'instantaneous divergence', '1/s', missing_value=missing_value )
          idiag%id_divg_mean  = register_diag_field ( trim(field), 'divg_mean', axes(1:3), Time,      &
               'timestep-mean divergence', '1/s', missing_value=missing_value )
! diagnotic output for skeb testing
          id_diss = register_diag_field ( trim(field), 'diss_est', axes(1:3), Time,    &
               'Dissipation estimate', 'J/kg/s', missing_value=missing_value, range=skrange )
          id_diss_heat = register_diag_field ( trim(field), 'diss_heat', axes(1:3), Time,    &
               'Dissipative heating rate', 'K/s', missing_value=missing_value )

          id_hght3d  = register_diag_field( trim(field), 'hght', axes(1:3), Time, &
               'height', 'm', missing_value=missing_value )

          id_rh = register_diag_field ( trim(field), 'rh', axes(1:3), Time,        &
               'Relative Humidity', '%', missing_value=missing_value )
          !            'Relative Humidity', '%', missing_value=missing_value, range=rhrange )
          id_delp = register_diag_field ( trim(field), 'delp', axes(1:3), Time,        &
               'pressure thickness'//massdef_str, 'pa', missing_value=missing_value )
#ifdef GFS_PHYS
          id_delp_total = register_diag_field ( trim(field), 'delp_total', axes(1:3), Time,        &
               'FV3 pressure thickness (dry air + all water species)', 'pa', missing_value=missing_value )
#endif
          if ( .not. Atm(n)%flagstruct%hydrostatic )                                        &
               id_delz = register_diag_field ( trim(field), 'delz', axes(1:3), Time,        &
               'height thickness', 'm', missing_value=missing_value )
          if( Atm(n)%flagstruct%hydrostatic ) then
             id_pfhy = register_diag_field ( trim(field), 'pfhy', axes(1:3), Time,        &
                  'hydrostatic pressure'//massdef_str, 'pa', missing_value=missing_value )
          else
             id_pfnh = register_diag_field ( trim(field), 'pfnh', axes(1:3), Time,        &
                  'non-hydrostatic pressure'//massdef_str, 'pa', missing_value=missing_value )
             id_ppnh = register_diag_field ( trim(field), 'ppnh', axes(1:3), Time,        &
                  'non-hydrostatic pressure perturbation', 'pa', missing_value=missing_value )
          endif
          !--------------------
          ! 3D Condensate
          !--------------------
          id_qn = register_diag_field ( trim(field), 'qn', axes(1:3), Time,       &
               'cloud condensate', 'kg/m/s^2', missing_value=missing_value )
          id_qp = register_diag_field ( trim(field), 'qp', axes(1:3), Time,       &
               'precip condensate', 'kg/m/s^2', missing_value=missing_value )
          ! fast moist phys tendencies:
          id_qdt = register_diag_field ( trim(field), 'qdt', axes(1:3), Time,       &
               'Dqv/Dt: fast moist phys', 'kg/kg/sec', missing_value=missing_value )
          id_dbz = register_diag_field ( trim(field), 'reflectivity', axes(1:3), time, &
               'Stoelinga simulated reflectivity', 'dBz', missing_value=missing_value)

          !--------------------
          ! Relative vorticity
          !--------------------
          id_vort = register_diag_field ( trim(field), 'vort', axes(1:3), Time,       &
               'vorticity', '1/s', missing_value=missing_value )
          !--------------------
          ! Potential vorticity
          !--------------------
          id_pv = register_diag_field ( trim(field), 'pv', axes(1:3), Time,       &
               'potential vorticity', '1/s', missing_value=missing_value )
          id_pv350K = register_diag_field ( trim(field), 'pv350K', axes(1:2), Time,       &
                '350-K potential vorticity; needs x350 scaling', '(K m**2) / (kg s)', missing_value=missing_value)
          id_pv550K = register_diag_field ( trim(field), 'pv550K', axes(1:2), Time,       &
                '550-K potential vorticity; needs x550 scaling', '(K m**2) / (kg s)', missing_value=missing_value)

!--------------------
! 3D flux terms
!--------------------
       id_uq = register_diag_field ( trim(field), 'uq', axes(1:3), Time,        &
            'zonal moisture flux', 'Kg/Kg*m/sec', missing_value=missing_value )
       id_vq = register_diag_field ( trim(field), 'vq', axes(1:3), Time,        &
            'meridional moisture flux', 'Kg/Kg*m/sec', missing_value=missing_value )

       id_ut = register_diag_field ( trim(field), 'ut', axes(1:3), Time,        &
            'zonal heat flux', 'K*m/sec', missing_value=missing_value )
       id_vt = register_diag_field ( trim(field), 'vt', axes(1:3), Time,        &
            'meridional heat flux', 'K*m/sec', missing_value=missing_value )

       id_uu = register_diag_field ( trim(field), 'uu', axes(1:3), Time,        &
            'zonal flux of zonal wind', '(m/sec)^2', missing_value=missing_value )
       id_uv = register_diag_field ( trim(field), 'uv', axes(1:3), Time,        &
            'zonal flux of meridional wind', '(m/sec)^2', missing_value=missing_value )
       id_vv = register_diag_field ( trim(field), 'vv', axes(1:3), Time,        &
            'meridional flux of meridional wind', '(m/sec)^2', missing_value=missing_value )

       if(.not.Atm(n)%flagstruct%hydrostatic) then
          id_uw = register_diag_field ( trim(field), 'uw', axes(1:3), Time, &
               'vertical zonal momentum flux', 'N/m**2', missing_value=missing_value )
          id_vw = register_diag_field ( trim(field), 'vw', axes(1:3), Time, &
               'vertical meridional momentum flux', 'N/m**', missing_value=missing_value )
          id_wq = register_diag_field ( trim(field), 'wq', axes(1:3), Time,        &
               'vertical moisture flux', 'Kg/Kg*m/sec', missing_value=missing_value )
          id_wt = register_diag_field ( trim(field), 'wt', axes(1:3), Time,        &
               'vertical heat flux', 'K*m/sec', missing_value=missing_value )
          id_ww = register_diag_field ( trim(field), 'ww', axes(1:3), Time,        &
               'vertical flux of vertical wind', '(m/sec)^2', missing_value=missing_value )
       endif

!--------------------
! vertical integral of 3D flux terms
!--------------------
       id_iuq = register_diag_field ( trim(field), 'uq_vi', axes(1:2), Time,        &
            'vertical integral of uq', 'Kg/Kg*m/sec*Pa', missing_value=missing_value )
       id_ivq = register_diag_field ( trim(field), 'vq_vi', axes(1:2), Time,        &
            'vertical integral of vq', 'Kg/Kg*m/sec*Pa', missing_value=missing_value )

       id_iut = register_diag_field ( trim(field), 'ut_vi', axes(1:2), Time,        &
            'vertical integral of ut', 'K*m/sec*Pa', missing_value=missing_value )
       id_ivt = register_diag_field ( trim(field), 'vt_vi', axes(1:2), Time,        &
            'vertical integral of vt', 'K*m/sec*Pa', missing_value=missing_value )

       id_iuu = register_diag_field ( trim(field), 'uu_vi', axes(1:2), Time,        &
            'vertical integral of uu', '(m/sec)^2*Pa', missing_value=missing_value )
       id_iuv = register_diag_field ( trim(field), 'uv_vi', axes(1:2), Time,        &
            'vertical integral of uv', '(m/sec)^2*Pa', missing_value=missing_value )
       id_ivv = register_diag_field ( trim(field), 'vv_vi', axes(1:2), Time,        &
            'vertical integral of vv', '(m/sec)^2*Pa', missing_value=missing_value )

       if(.not.Atm(n)%flagstruct%hydrostatic) then
          id_iwq = register_diag_field ( trim(field), 'wq_vi', axes(1:2), Time,        &
               'vertical integral of wq', 'Kg/Kg*m/sec*Pa', missing_value=missing_value )
          id_iwt = register_diag_field ( trim(field), 'wt_vi', axes(1:2), Time,        &
               'vertical integral of wt', 'K*m/sec*Pa', missing_value=missing_value )
          id_iuw = register_diag_field ( trim(field), 'uw_vi', axes(1:2), Time,        &
               'vertical integral of uw', '(m/sec)^2*Pa', missing_value=missing_value )
          id_ivw = register_diag_field ( trim(field), 'vw_vi', axes(1:2), Time,        &
               'vertical integral of vw', '(m/sec)^2*Pa', missing_value=missing_value )
          id_iww = register_diag_field ( trim(field), 'ww_vi', axes(1:2), Time,        &
               'vertical integral of ww', '(m/sec)^2*Pa', missing_value=missing_value )
       endif

       endif

! Total energy (only when moist_phys = .T.)
       idiag%id_te    = register_diag_field ( trim(field), 'te', axes(1:2), Time,      &
            'Total Energy', 'J/m/s^2', missing_value=missing_value )
! Total Kinetic energy
       id_ke    = register_diag_field ( trim(field), 'ke', axes(1:2), Time,      &
            'Total KE', 'm^2/s^2', missing_value=missing_value )
       idiag%id_ws     = register_diag_field ( trim(field), 'ws', axes(1:2), Time,        &
            'Terrain W', 'm/s', missing_value=missing_value )
       id_maxdbz = register_diag_field ( trim(field), 'max_reflectivity', axes(1:2), time, &
                'Stoelinga simulated maximum (composite) reflectivity', 'dBz', missing_value=missing_value)
       id_basedbz = register_diag_field ( trim(field), 'base_reflectivity', axes(1:2), time, &
                'Stoelinga simulated base (1 km AGL) reflectivity', 'dBz', missing_value=missing_value)
       id_dbz4km = register_diag_field ( trim(field), '4km_reflectivity', axes(1:2), time, &
                'Stoelinga simulated base reflectivity', 'dBz', missing_value=missing_value)
       id_dbztop = register_diag_field ( trim(field), 'echo_top', axes(1:2), time, &
                'Echo top ( <= 18.5 dBz )', 'm', missing_value=missing_value2)
       id_dbz_m10C = register_diag_field ( trim(field), 'm10C_reflectivity', axes(1:2), time, &
                'Reflectivity at -10C level', 'm', missing_value=missing_value)
       id_40dbzht = register_diag_field ( trim(field), '40dBz_height', axes(1:2), time, &
                'Height of 40 dBz reflectivity', 'm', missing_value=missing_value)

!--------------------------
! Extra surface diagnostics:
!--------------------------
! Surface (lowest layer) vorticity: for tropical cyclones diag.
       id_vorts = register_diag_field ( trim(field), 'vorts', axes(1:2), Time,       &
            'surface vorticity', '1/s', missing_value=missing_value )
       id_us = register_diag_field ( trim(field), 'us', axes(1:2), Time,        &
            'surface u-wind', 'm/sec', missing_value=missing_value, range=vsrange )
       id_vs = register_diag_field ( trim(field), 'vs', axes(1:2), Time,        &
            'surface v-wind', 'm/sec', missing_value=missing_value, range=vsrange )
       id_tq = register_diag_field ( trim(field), 'tq', axes(1:2), Time,        &
            'Total water path', 'kg/m**2', missing_value=missing_value )
       id_iw = register_diag_field ( trim(field), 'iw', axes(1:2), Time,        &
            'Ice water path', 'kg/m**2', missing_value=missing_value )
       id_lw = register_diag_field ( trim(field), 'lw', axes(1:2), Time,        &
            'Liquid water path', 'kg/m**2', missing_value=missing_value )
       id_ts = register_diag_field ( trim(field), 'ts', axes(1:2), Time,  &
                                        'Skin temperature', 'K' )
       id_tb = register_diag_field ( trim(field), 'tb', axes(1:2), Time,  &
                                        'lowest layer temperature', 'K' )
       id_ctt = register_diag_field( trim(field), 'ctt', axes(1:2), Time,  &
                                        'cloud_top temperature', 'K', missing_value=missing_value3 )
       id_ctp = register_diag_field( trim(field), 'ctp', axes(1:2), Time,  &
                                        'cloud_top pressure', 'hPa' , missing_value=missing_value3 )
       id_ctz = register_diag_field( trim(field), 'ctz', axes(1:2), Time,  &
                                        'cloud_top height', 'hPa' , missing_value=missing_value2 )
       id_cape = register_diag_field( trim(field), 'cape', axes(1:2), Time,  &
                                        'Convective available potential energy (surface-based)', 'J/kg' , missing_value=missing_value )
       id_cin = register_diag_field( trim(field), 'cin', axes(1:2), Time,  &
                                        'Convective inhibition (surface-based)', 'J/kg' , missing_value=missing_value )
       id_brn = register_diag_field( trim(field), 'BRN', axes(1:2), Time,  &
                                        'Bulk Richardson Number', 'nondim' , missing_value=missing_value )
       id_shear06 = register_diag_field( trim(field), 'shear06', axes(1:2), Time,  &
                                        '0--6 km shear', 'm/s' , missing_value=missing_value )
!--------------------------
! Vertically integrated tracers for GFDL MP
!--------------------------
       id_intqv = register_diag_field ( trim(field), 'intqv', axes(1:2), Time,        &
            'Vertically Integrated Water Vapor', 'kg/m**2', missing_value=missing_value )
       id_intql = register_diag_field ( trim(field), 'intql', axes(1:2), Time,        &
            'Vertically Integrated Cloud Water', 'kg/m**2', missing_value=missing_value )
       id_intqi = register_diag_field ( trim(field), 'intqi', axes(1:2), Time,        &
            'Vertically Integrated Cloud Ice', 'kg/m**2', missing_value=missing_value )
       id_intqr = register_diag_field ( trim(field), 'intqr', axes(1:2), Time,        &
            'Vertically Integrated Rain', 'kg/m**2', missing_value=missing_value )
       id_intqs = register_diag_field ( trim(field), 'intqs', axes(1:2), Time,        &
            'Vertically Integrated Snow', 'kg/m**2', missing_value=missing_value )
       id_intqg = register_diag_field ( trim(field), 'intqg', axes(1:2), Time,        &
            'Vertically Integrated Graupel', 'kg/m**2', missing_value=missing_value )

       id_acl = register_diag_field ( trim(field), 'acl', axes(1:2), Time,        &
            'Column-averaged Cl mixing ratio', 'kg/kg', missing_value=missing_value )
       id_acl2 = register_diag_field ( trim(field), 'acl2', axes(1:2), Time,        &
            'Column-averaged Cl2 mixing ratio', 'kg/kg', missing_value=missing_value )
       id_acly = register_diag_field ( trim(field), 'acly', axes(1:2), Time,        &
            'Column-averaged total chlorine mixing ratio', 'kg/kg', missing_value=missing_value )

! Cubed_2_latlon interpolation is more accurate, particularly near the poles, using
! winds speed (a scalar), rather than wind vectors or kinetic energy directly.
       id_s200 = register_diag_field ( trim(field), 's200', axes(1:2), Time,       &
                           '200-mb wind_speed', 'm/s', missing_value=missing_value )
       id_sl12 = register_diag_field ( trim(field), 'sl12', axes(1:2), Time,       &
                           '12th L wind_speed', 'm/s', missing_value=missing_value )
       id_sl13 = register_diag_field ( trim(field), 'sl13', axes(1:2), Time,       &
                           '13th L wind_speed', 'm/s', missing_value=missing_value )
! Selceted (HIWPP) levels of non-precip condensates:
       id_qn200 = register_diag_field ( trim(field), 'qn200', axes(1:2), Time,       &
               '200mb condensate', 'kg/m/s^2', missing_value=missing_value )
       id_qn500 = register_diag_field ( trim(field), 'qn500', axes(1:2), Time,       &
               '500mb condensate', 'kg/m/s^2', missing_value=missing_value )
       id_qn850 = register_diag_field ( trim(field), 'qn850', axes(1:2), Time,       &
               '850mb condensate', 'kg/m/s^2', missing_value=missing_value )

       id_rain5km = register_diag_field ( trim(field), 'rain5km', axes(1:2), Time,       &
                           '5-km AGL liquid water', 'kg/kg', missing_value=missing_value )
!--------------------------
! w on height or pressure levels
!--------------------------
       if( .not. Atm(n)%flagstruct%hydrostatic ) then
          id_w5km = register_diag_field ( trim(field), 'w5km', axes(1:2), Time,       &
                           '5-km AGL w-wind', 'm/s', missing_value=missing_value )
          id_w2500m = register_diag_field ( trim(field), 'w2500m', axes(1:2), Time,       &
                           '2.5-km AGL w-wind', 'm/s', missing_value=missing_value )
          id_w1km = register_diag_field ( trim(field), 'w1km', axes(1:2), Time,       &
                           '1-km AGL w-wind', 'm/s', missing_value=missing_value )

          id_wmaxup = register_diag_field ( trim(field), 'wmaxup', axes(1:2), Time,       &
                           'column-maximum updraft (below 100 mb)', 'm/s', missing_value=missing_value )
          id_wmaxdn = register_diag_field ( trim(field), 'wmaxdn', axes(1:2), Time,       &
                           'column-maximum downdraft (below 100 mb)', 'm/s', missing_value=missing_value )

       endif

! helicity
       id_x850 = register_diag_field ( trim(field), 'x850', axes(1:2), Time,       &
                           '850-mb vertical comp. of helicity', 'm/s**2', missing_value=missing_value )

! Storm Relative Helicity
       id_srh1 = register_diag_field ( trim(field), 'srh01', axes(1:2), Time,       &
                           '0-1 km Storm Relative Helicity', 'm/s**2', missing_value=missing_value )
       id_srh3 = register_diag_field ( trim(field), 'srh03', axes(1:2), Time,       &
                           '0-3 km Storm Relative Helicity', 'm/s**2', missing_value=missing_value )
       id_ustm = register_diag_field ( trim(field), 'ustm', axes(1:2), Time,       &
                           'u Component of Storm Motion', 'm/s', missing_value=missing_value )
       id_vstm = register_diag_field ( trim(field), 'vstm', axes(1:2), Time,       &
                           'v Component of Storm Motion', 'm/s', missing_value=missing_value )

       id_srh25 = register_diag_field ( trim(field), 'srh25', axes(1:2), Time,       &
                           '2-5 km Storm Relative Helicity', 'm/s**2', missing_value=missing_value )

       if( .not. Atm(n)%flagstruct%hydrostatic ) then
          id_uh03 = register_diag_field ( trim(field), 'uh03', axes(1:2), Time,       &
                           '0-3 km Updraft Helicity', 'm/s**2', missing_value=missing_value )
          id_uh25 = register_diag_field ( trim(field), 'uh25', axes(1:2), Time,       &
                           '2-5 km Updraft Helicity', 'm/s**2', missing_value=missing_value )
       endif
! TC test winds at 100 m
       if( .not. Atm(n)%flagstruct%hydrostatic )                                          &
       id_w100m = register_diag_field ( trim(field), 'w100m', axes(1:2), Time,       &
                        '100-m AGL w-wind', 'm/s', missing_value=missing_value )
       id_u100m = register_diag_field ( trim(field), 'u100m', axes(1:2), Time,       &
                        '100-m AGL u-wind', 'm/s', missing_value=missing_value )
       id_v100m = register_diag_field ( trim(field), 'v100m', axes(1:2), Time,       &
                        '100-m AGL v-wind', 'm/s', missing_value=missing_value )
       id_wind100m = register_diag_field ( trim(field), 'wind100m', axes(1:2), Time,       &
                        '100-m AGL windspeed', 'm/s', missing_value=missing_value )

!--------------------------
! relative humidity (CMIP definition):
!--------------------------
       id_rh10_cmip = register_diag_field ( trim(field), 'rh10_cmip', axes(1:2), Time,       &
                           '10-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh50_cmip = register_diag_field ( trim(field), 'rh50_cmip', axes(1:2), Time,       &
                           '50-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh100_cmip = register_diag_field ( trim(field), 'rh100_cmip', axes(1:2), Time,       &
                           '100-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh250_cmip = register_diag_field ( trim(field), 'rh250_cmip', axes(1:2), Time,       &
                           '250-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh300_cmip = register_diag_field ( trim(field), 'rh300_cmip', axes(1:2), Time,       &
                           '300-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh500_cmip = register_diag_field ( trim(field), 'rh500_cmip', axes(1:2), Time,       &
                           '500-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh700_cmip = register_diag_field ( trim(field), 'rh700_cmip', axes(1:2), Time,       &
                           '700-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh850_cmip = register_diag_field ( trim(field), 'rh850_cmip', axes(1:2), Time,       &
                           '850-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh925_cmip = register_diag_field ( trim(field), 'rh925_cmip', axes(1:2), Time,       &
                           '925-mb relative humidity (CMIP)', '%', missing_value=missing_value )
       id_rh1000_cmip = register_diag_field ( trim(field), 'rh1000_cmip', axes(1:2), Time,       &
                           '1000-mb relative humidity (CMIP)', '%', missing_value=missing_value )


       if (Atm(n)%flagstruct%write_3d_diags) then
          do i=1, ncnst
             !--------------------
             ! Tracer diagnostics:
             !--------------------
             call get_tracer_names ( MODEL_ATMOS, i, tname, tlongname, tunits )
             id_tracer(i) = register_diag_field ( field, trim(tname),  &
                  axes(1:3), Time, trim(tlongname), &
                  trim(tunits), missing_value=missing_value)
             if (master) then
                if (id_tracer(i) > 0) then
                   unit = stdlog()
                   write(unit,'(a,a,a,a)') &
                        & 'Diagnostics available for tracer ',trim(tname), &
                        ' in module ', trim(field)
                end if
             endif

             !vmr/mmr
             if ( trim(tunits) .eq. 'vmr' ) then
                conv_vmr_mmr(i) = .true.
             end if

             !----------------------------------
             ! ESM Tracer dmmr/dvmr diagnostics:
             !   for specific elements only
             !----------------------------------
             !---co2
             if (trim(tname).eq.'co2') then
                !                w_mr(:) = WTMCO2
                w_mr(i) = WTMCO2
                id_tracer_dmmr(i) = register_diag_field ( field, trim(tname)//'_dmmr',  &
                     axes(1:3), Time, trim(tlongname)//" (dry mmr)",           &
                     trim(tunits), missing_value=missing_value)
                id_tracer_dvmr(i) = register_diag_field ( field, trim(tname)//'_dvmr',  &
                     axes(1:3), Time, trim(tlongname)//" (dry vmr)",           &
                     'mol/mol', missing_value=missing_value)
             else
                if (conv_vmr_mmr(i)) then
                   id_tracer_dvmr(i) = register_diag_field ( field, trim(tname)//'_dvmr',  &
                        axes(1:3), Time, trim(tlongname)//" (dry vmr)",           &
                        'mol/mol', missing_value=missing_value)
                   id_tracer_burden(i) = register_diag_field ( field, trim(tname)//'_burden',  &
                        axes(1:3), Time, trim(tlongname)//" burden",           &
                        'mol/m2', missing_value=missing_value)
                else
                   id_tracer_dmmr(i) = register_diag_field ( field, trim(tname)//'_dmmr',  &
                        axes(1:3), Time, trim(tlongname)//" (dry mmr)",           &
                        trim(tunits), missing_value=missing_value)
                   id_tracer_burden(i) = register_diag_field ( field, trim(tname)//'_burden',  &
                        axes(1:3), Time, trim(tlongname)//" burden",           &
                        'kg/m2', missing_value=missing_value)
                end if
             endif
             unit = stdlog()
             if (id_tracer_dmmr(i) > 0) then
                write(unit,'(a,a,a,a)') 'Diagnostics available for '//trim(tname)//' dry mmr ', &
                     trim(tname)//'_dmmr', ' in module ', trim(field)
             end if
             if (id_tracer_dvmr(i) > 0) then
                write(unit,'(a,a,a,a)') 'Diagnostics available for '//trim(tname)//' dry vmr ', &
                     trim(tname)//'_dvmr', ' in module ', trim(field)
             end if
             !---end co2

          enddo
       endif

       if ( Atm(1)%flagstruct%consv_am .or. id_mq > 0 .or. idiag%id_amdt > 0 )  then
          allocate ( idiag%zxg(isc:iec,jsc:jec) )
          ! Initialize gradient of terrain for mountain torque computation:
          call init_mq(Atm(n)%phis, Atm(n)%gridstruct, &
               npx, npy, isc, iec, jsc, jec, Atm(n)%ng)
       endif

!    end do


    call prt_mass(npz, Atm(n)%ncnst, isc, iec, jsc, jec, Atm(n)%ng, Atm(n)%flagstruct%nwat,    &
                      Atm(n)%ps, Atm(n)%delp, Atm(n)%q, Atm(n)%gridstruct%area_64, Atm(n)%domain)

    !Model initialization time (not necessarily the time this simulation is started,
    ! conceivably a restart could be done
    if (m_calendar) then
       call get_date(Atm(n)%Time_init, yr_init, mo_init, dy_init, hr_init, mn_init, sec_init)
    else
       call get_time(Atm(n)%Time_init, sec_init, dy_init)
       yr_init = 0 ; mo_init = 0 ; hr_init = 0 ; mn_init = 0
    endif

    module_is_initialized=.true.
    istep = 0

    call fv_diag_column_init(Atm(n), yr_init, mo_init, dy_init, hr_init, do_diag_debug, do_diag_sonde, sound_freq, m_calendar)

 end subroutine fv_diag_init


 subroutine init_mq(phis, gridstruct, npx, npy, is, ie, js, je, ng)
    integer, intent(in):: npx, npy, is, ie, js, je, ng
    real, intent(in):: phis(is-ng:ie+ng, js-ng:je+ng)
    type(fv_grid_type), intent(IN), target :: gridstruct

! local:
    real zs(is-ng:ie+ng, js-ng:je+ng)
    real zb(is-ng:ie+ng, js-ng:je+ng)
    real pdx(3,is:ie,js:je+1)
    real pdy(3,is:ie+1,js:je)
    integer i, j, n

    real, pointer :: rarea(:,:)
    real, pointer, dimension(:,:) :: dx, dy
    real(kind=R_GRID), pointer, dimension(:,:,:) :: en1, en2, vlon, vlat
    real, pointer, dimension(:,:,:) :: agrid

    rarea => gridstruct%rarea
    dx    => gridstruct%dx
    dy    => gridstruct%dy
    en1   => gridstruct%en1
    en2   => gridstruct%en2
    agrid => gridstruct%agrid
    vlon  => gridstruct%vlon
    vlat  => gridstruct%vlat

!   do j=js,je
!      do i=is,ie
    do j=js-ng,je+ng
       do i=is-ng,ie+ng
          zs(i,j) = phis(i,j) / grav
       enddo
    enddo
!   call mpp_update_domains( zs, domain )

!   call a2b_ord2(zs, zb, gridstruct, npx, npy, is, ie, js, je, ng)
    call a2b_ord4(zs, zb, gridstruct, npx, npy, is, ie, js, je, ng)

    do j=js,je+1
       do i=is,ie
          do n=1,3
             pdx(n,i,j) = 0.5*(zb(i,j)+zb(i+1,j))*dx(i,j)*en1(n,i,j)
          enddo
       enddo
    enddo
    do j=js,je
       do i=is,ie+1
          do n=1,3
             pdy(n,i,j) = 0.5*(zb(i,j)+zb(i,j+1))*dy(i,j)*en2(n,i,j)
          enddo
       enddo
    enddo

! Compute "volume-mean" gradient by Green's theorem
    do j=js,je
       do i=is,ie
          idiag%zxg(i,j) = vlon(i,j,1)*(pdx(1,i,j+1)-pdx(1,i,j)-pdy(1,i,j)+pdy(1,i+1,j))  &
                         + vlon(i,j,2)*(pdx(2,i,j+1)-pdx(2,i,j)-pdy(2,i,j)+pdy(2,i+1,j))  &
                         + vlon(i,j,3)*(pdx(3,i,j+1)-pdx(3,i,j)-pdy(3,i,j)+pdy(3,i+1,j))
! dF/d(lamda) = radius*cos(agrid(i,j,2)) * dF/dx, F is a scalar
!                                                       ________________________
          idiag%zxg(i,j) =  idiag%zxg(i,j)*rarea(i,j) * radius*cos(agrid(i,j,2))
!                                                       ^^^^^^^^^^^^^^^^^^^^^^^^
       enddo
    enddo

 end subroutine init_mq

 subroutine fv_diag(Atm, zvir, Time, print_freq)

    type(fv_atmos_type), intent(inout) :: Atm(:)
    type(time_type),     intent(in) :: Time
    real,                intent(in):: zvir
    integer,             intent(in):: print_freq

    integer :: isc, iec, jsc, jec, n, ntileMe
    integer :: isd, ied, jsd, jed, npz, itrac
    integer :: ngc, nwater

    real, allocatable :: a2(:,:),a3(:,:,:),a4(:,:,:), wk(:,:,:), wz(:,:,:), ucoor(:,:,:), vcoor(:,:,:)
    real, allocatable :: ustm(:,:), vstm(:,:), ptmp(:,:,:), qtmp(:,:,:), dz(:,:,:), lsm(:,:)
    real, allocatable :: slp(:,:), depress(:,:), ws_max(:,:), tc_count(:,:)
    real, allocatable :: u2(:,:), v2(:,:), x850(:,:), var1(:,:), var2(:,:), var3(:,:)
    real, allocatable :: dmmr(:,:,:), dvmr(:,:,:)
    real height(2)
    real:: plevs_ln(nplev), plevs(nplev)
    integer:: idg(nplev), id1(nplev)
    real    :: tot_mq, tmp, sar, slon, slat
    real    :: a1d(Atm(1)%npz)
!   real    :: t_gb, t_nh, t_sh, t_eq, area_gb, area_nh, area_sh, area_eq
    logical :: do_cs_intp
    logical :: used
    logical :: bad_range
    integer i,j,k, yr, mon, dd, hr, mn, days, seconds, nq, theta_d
    character(len=128)   :: tname
    real, parameter:: ws_0 = 16.   ! minimum max_wind_speed within the 7x7 search box
    real, parameter:: ws_1 = 20.
    real, parameter:: vort_c0= 2.2e-5
    logical, allocatable :: storm(:,:), cat_crt(:,:)
    real :: tmp2, pvsum, e2, einf, qm, mm, maxdbz, allmax, rgrav, cv_vapor
    real, allocatable :: cvm(:)
    integer :: Cl, Cl2, k1, k2

    !!! CLEANUP: does it really make sense to have this routine loop over Atm% anymore? We assume n=1 below anyway

! cat15: SLP<1000; srf_wnd>ws_0; vort>vort_c0
! cat25: SLP< 980; srf_wnd>ws_1; vort>vort_c0
! cat35: SLP< 964; srf_wnd>ws_1; vort>vort_c0
! cat45: SLP< 944; srf_wnd>ws_1; vort>vort_c0

    height(1) = 5.E3      ! for computing 5-km "pressure"
    height(2) = 0.        ! for sea-level pressure

    do i=1,nplev
       plevs(i) = levs(i) * 1.e2
       plevs_ln(i) = log( plevs(i) )
    enddo

    ntileMe = size(Atm(:))
    n = 1
    isc = Atm(n)%bd%isc; iec = Atm(n)%bd%iec
    jsc = Atm(n)%bd%jsc; jec = Atm(n)%bd%jec
    ngc = Atm(n)%ng
    npz = Atm(n)%npz
    ptop = Atm(n)%ak(1)
    nq = size (Atm(n)%q,4)

    isd = Atm(n)%bd%isd; ied = Atm(n)%bd%ied
    jsd = Atm(n)%bd%jsd; jed = Atm(n)%bd%jed

    if( id_c15>0 ) then
        allocate (   storm(isc:iec,jsc:jec) )
        allocate ( depress(isc:iec,jsc:jec) )
        allocate (  ws_max(isc:iec,jsc:jec) )
        allocate ( cat_crt(isc:iec,jsc:jec) )
        allocate (tc_count(isc:iec,jsc:jec) )
    endif

    if( id_x850>0 ) then
        allocate ( x850(isc:iec,jsc:jec) )
    endif

    fv_time = Time

    if ( m_calendar ) then
         call get_date(fv_time, yr, mon, dd, hr, mn, seconds)
         if( print_freq == 0 ) then
                 prt_minmax = .false.
         elseif( print_freq < 0 ) then
                 istep = istep + 1
                 prt_minmax = mod(istep, -print_freq) == 0
         else
                 prt_minmax = mod(hr, print_freq) == 0 .and. mn==0 .and. seconds==0
         endif

         if ( sound_freq == 0 .or. .not. do_diag_sonde ) then
            prt_sounding = .false.
         else
            prt_sounding = mod(hr, sound_freq) == 0 .and. mn == 0 .and. seconds == 0
         endif
     else
         call get_time (fv_time, seconds,  days)
         if( print_freq == 0 ) then
                 prt_minmax = .false.
         elseif( print_freq < 0 ) then
                 istep = istep + 1
                 prt_minmax = mod(istep, -print_freq) == 0
         else
                 prt_minmax = mod(seconds, 3600*print_freq) == 0
         endif

         if ( sound_freq == 0 .or. .not. do_diag_sonde ) then
            prt_sounding = .false.
         else
            prt_sounding = mod(seconds, 3600*sound_freq) == 0
         endif

     endif

     if(prt_minmax) then
         if ( m_calendar ) then
              if(master) write(*,'(A,I6,5I3)') ' Simulation Time: ', yr, mon, dd, hr, mn, seconds
         else
              if(master) write(*,'(A,2I5)') ' Simulation Time: ', Days, seconds
         endif
     endif

    allocate ( a2(isc:iec,jsc:jec) )

    if( prt_minmax ) then


        call prt_mass(npz, nq, isc, iec, jsc, jec, ngc, Atm(n)%flagstruct%nwat,    &
                      Atm(n)%ps, Atm(n)%delp, Atm(n)%q, Atm(n)%gridstruct%area_64, Atm(n)%domain)

        !call prt_mxm('ZS (m) ', zsurf,     isc, iec, jsc, jec, 0,   1, 1.0, Atm(n)%gridstruct%area_64, Atm(n)%domain)
        call prt_mxm('PS (Pa) ', Atm(n)%ps, isc, iec, jsc, jec, ngc, 1, 0.01, Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)

#ifdef HIWPP
        if (.not. Atm(n)%gridstruct%bounded_domain ) then
        allocate(var2(isc:iec,jsc:jec))
        !hemispheric max/min pressure
        do j=jsc,jec
        do i=isc,iec
           slat = rad2deg*Atm(n)%gridstruct%agrid(i,j,2)
           if (slat >= 0.) then
              a2(i,j) = Atm(n)%ps(i,j)
              var2(i,j) = 101300.
           else
              a2(i,j) = 101300.
              var2(i,j) = Atm(n)%ps(i,j)
           endif
        enddo
        enddo
        call prt_mxm('NH PS', a2, isc, iec, jsc, jec, 0, 1, 0.01, Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
        call prt_mxm('SH PS', var2, isc, iec, jsc, jec, 0, 1, 0.01, Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)

        deallocate(var2)
        endif
#endif

#ifndef SW_DYNAMICS
        if (Atm(n)%flagstruct%consv_te > 1.e-5) then
           idiag%steps = idiag%steps + 1
           idiag%efx_sum = idiag%efx_sum + E_Flux
           if ( idiag%steps <= max_step ) idiag%efx(idiag%steps) = E_Flux
           if (master)  then
              write(*,'(2x, A, 2A, G20.8)') '   Energy_Deficit (W/m**2)', trim(gn), ' = ', E_Flux
           endif


        endif
#endif
        call prt_mxm('UA_Top (m/s)', Atm(n)%ua(isc:iec,jsc:jec,1),    &
                        isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
        call prt_mxm('UA_Bottom (m/s)', Atm(n)%ua(isc:iec,jsc:jec,npz),    &
                        isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
        call prt_mxm('UA (m/s)', Atm(n)%ua, isc, iec, jsc, jec, ngc, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)
        call prt_mxm('VA_Top (m/s)', Atm(n)%va(isc:iec,jsc:jec,1),    &
                        isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
        call prt_mxm('VA_Bottom (m/s)', Atm(n)%va(isc:iec,jsc:jec,npz),    &
                        isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
        call prt_mxm('VA (m/s)', Atm(n)%va, isc, iec, jsc, jec, ngc, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)

        if ( .not. Atm(n)%flagstruct%hydrostatic ) then
          call prt_mxm('W_Top (m/s)', Atm(n)%w(isc:iec,jsc:jec,1), isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
          call prt_mxm('W_Bottom (m/s)', Atm(n)%w(isc:iec,jsc:jec,npz), isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
          call prt_mxm('W (m/s)', Atm(n)%w , isc, iec, jsc, jec, ngc, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)
          do j=jsc,jec
             do i=isc,iec
                a2(i,j) = -Atm(n)%w(i,j,npz)/Atm(n)%delz(i,j,npz)
             enddo
          enddo
          call prt_mxm('W/dz_Bottom (1/s)', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_3)

          if ( Atm(n)%flagstruct%hybrid_z ) call prt_mxm('Hybrid_ZTOP (km)', Atm(n)%ze0(isc:iec,jsc:jec,1), &
                                                 isc, iec, jsc, jec, 0, 1, 1.E-3, Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_3)
          call prt_mxm('DZ_Top (m)', Atm(n)%delz(isc:iec,jsc:jec,1),    &
                          isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_3)
          call prt_mxm('DZ_Bottom (m)', Atm(n)%delz(isc:iec,jsc:jec,npz),    &
                          isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_3)
          call prt_mxm('DZ (m)', Atm(n)%delz(isc:iec,jsc:jec,1:npz),    &
                          isc, iec, jsc, jec, 0, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
        endif

#ifndef SW_DYNAMICS
        call prt_mxm('TA_Top (K)', Atm(n)%pt(isc:iec,jsc:jec,  1), isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
        call prt_mxm('TA_Bottom (K)', Atm(n)%pt(isc:iec,jsc:jec,npz), isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
        call prt_mxm('TA (K)', Atm(n)%pt,   isc, iec, jsc, jec, ngc, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)
        call prt_mxm('OM (pa/s)', Atm(n)%omga, isc, iec, jsc, jec, ngc, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
#endif

    elseif ( Atm(n)%flagstruct%range_warn ) then
         if (ptop < 200.e2) call range_check('DELP', Atm(n)%delp, isc, iec, jsc, jec, ngc, npz, Atm(n)%gridstruct%agrid,    &
                                              0.01*ptop, 200.E2, bad_range, Time)
         call range_check('UA', Atm(n)%ua, isc, iec, jsc, jec, ngc, npz, Atm(n)%gridstruct%agrid,   &
                           -250., 250., bad_range, Time)
         call range_check('VA', Atm(n)%va, isc, iec, jsc, jec, ngc, npz, Atm(n)%gridstruct%agrid,   &
                           -250., 250., bad_range, Time)
#ifndef SW_DYNAMICS
         if (Atm(n)%flagstruct%is_ideal_case) then
            call range_check('TA', Atm(n)%pt, isc, iec, jsc, jec, ngc, npz, Atm(n)%gridstruct%agrid,   &
                           100., 500., bad_range, Time) !DCMIP ICs have very wide range of temperatures
         else
            call range_check('TA', Atm(n)%pt, isc, iec, jsc, jec, ngc, npz, Atm(n)%gridstruct%agrid,   &
                           150., 350., bad_range, Time)
         endif
         call range_check('Qv', Atm(n)%q(:,:,:,sphum), isc, iec, jsc, jec, ngc, npz, Atm(n)%gridstruct%agrid,   &
                          -1.e-8, 1.e20, bad_range, Time)
#endif

      endif

    allocate ( u2(isc:iec,jsc:jec) )
    allocate ( v2(isc:iec,jsc:jec) )
    allocate ( wk(isc:iec,jsc:jec,npz) )
    if ( any(id_tracer_dmmr > 0) .or. any(id_tracer_dvmr > 0) ) then
        allocate ( dmmr(isc:iec,jsc:jec,1:npz) )
        allocate ( dvmr(isc:iec,jsc:jec,1:npz) )
    endif

!    do n = 1, ntileMe
    n = 1

    ! ! D grid wind diagnostics
    ! if (id_d_grid_ucomp > 0) used = send_data(id_d_grid_ucomp, Atm(n)%u(isc:iec,jsc:jec+1,1:npz), Time)
    ! if (id_d_grid_vcomp > 0) used = send_data(id_d_grid_vcomp, Atm(n)%v(isc:iec+1,jsc:jec,1:npz), Time)

    ! ! C grid wind diagnostics
    ! if (id_c_grid_ucomp > 0) used = send_data(id_c_grid_ucomp, Atm(n)%uc(isc:iec+1,jsc:jec,1:npz), Time)
    ! if (id_c_grid_vcomp > 0) used = send_data(id_c_grid_vcomp, Atm(n)%vc(isc:iec,jsc:jec+1,1:npz), Time)

#ifdef DYNAMICS_ZS
       do j=jsc,jec
       do i=isc,iec
          zsurf(i,j) = ginv * Atm(n)%phis(i,j)
       enddo
       enddo

       if(id_zsurf_t > 0)  used=send_data(id_zsurf_t, zsurf, Time)
       call prt_mxm('ZS', zsurf,     isc, iec, jsc, jec, 0,   1, 1.0, Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)
#endif
       if(id_ps > 0) used=send_data(id_ps, Atm(n)%ps(isc:iec,jsc:jec), Time)

       if (Atm(n)%flagstruct%do_inline_mp) then
          if(id_pret > 0) used=send_data(id_pret, &
             Atm(n)%inline_mp%prew(isc:iec,jsc:jec)+&
             Atm(n)%inline_mp%prer(isc:iec,jsc:jec)+&
             Atm(n)%inline_mp%prei(isc:iec,jsc:jec)+&
             Atm(n)%inline_mp%pres(isc:iec,jsc:jec)+&
             Atm(n)%inline_mp%preg(isc:iec,jsc:jec), Time)
          if(id_prew > 0) used=send_data(id_prew, Atm(n)%inline_mp%prew(isc:iec,jsc:jec), Time)
          if(id_prer > 0) used=send_data(id_prer, Atm(n)%inline_mp%prer(isc:iec,jsc:jec), Time)
          if(id_prei > 0) used=send_data(id_prei, Atm(n)%inline_mp%prei(isc:iec,jsc:jec), Time)
          if(id_pres > 0) used=send_data(id_pres, Atm(n)%inline_mp%pres(isc:iec,jsc:jec), Time)
          if(id_preg > 0) used=send_data(id_preg, Atm(n)%inline_mp%preg(isc:iec,jsc:jec), Time)
       endif
       if(id_mppcw > 0) used=send_data(id_mppcw, Atm(n)%inline_mp%mppcw(isc:iec,jsc:jec), Time)
       if(id_mppew > 0) used=send_data(id_mppew, Atm(n)%inline_mp%mppew(isc:iec,jsc:jec), Time)
       if(id_mppe1 > 0) used=send_data(id_mppe1, Atm(n)%inline_mp%mppe1(isc:iec,jsc:jec), Time)
       if(id_mpper > 0) used=send_data(id_mpper, Atm(n)%inline_mp%mpper(isc:iec,jsc:jec), Time)
       if(id_mppdi > 0) used=send_data(id_mppdi, Atm(n)%inline_mp%mppdi(isc:iec,jsc:jec), Time)
       if(id_mppd1 > 0) used=send_data(id_mppd1, Atm(n)%inline_mp%mppd1(isc:iec,jsc:jec), Time)
       if(id_mppds > 0) used=send_data(id_mppds, Atm(n)%inline_mp%mppds(isc:iec,jsc:jec), Time)
       if(id_mppdg > 0) used=send_data(id_mppdg, Atm(n)%inline_mp%mppdg(isc:iec,jsc:jec), Time)
       if(id_mppsi > 0) used=send_data(id_mppsi, Atm(n)%inline_mp%mppsi(isc:iec,jsc:jec), Time)
       if(id_mpps1 > 0) used=send_data(id_mpps1, Atm(n)%inline_mp%mpps1(isc:iec,jsc:jec), Time)
       if(id_mppss > 0) used=send_data(id_mppss, Atm(n)%inline_mp%mppss(isc:iec,jsc:jec), Time)
       if(id_mppsg > 0) used=send_data(id_mppsg, Atm(n)%inline_mp%mppsg(isc:iec,jsc:jec), Time)
       if(id_mppfw > 0) used=send_data(id_mppfw, Atm(n)%inline_mp%mppfw(isc:iec,jsc:jec), Time)
       if(id_mppfr > 0) used=send_data(id_mppfr, Atm(n)%inline_mp%mppfr(isc:iec,jsc:jec), Time)
       if(id_mppmi > 0) used=send_data(id_mppmi, Atm(n)%inline_mp%mppmi(isc:iec,jsc:jec), Time)
       if(id_mppms > 0) used=send_data(id_mppms, Atm(n)%inline_mp%mppms(isc:iec,jsc:jec), Time)
       if(id_mppmg > 0) used=send_data(id_mppmg, Atm(n)%inline_mp%mppmg(isc:iec,jsc:jec), Time)
       if(id_mppm1 > 0) used=send_data(id_mppm1, Atm(n)%inline_mp%mppm1(isc:iec,jsc:jec), Time)
       if(id_mppm2 > 0) used=send_data(id_mppm2, Atm(n)%inline_mp%mppm2(isc:iec,jsc:jec), Time)
       if(id_mppm3 > 0) used=send_data(id_mppm3, Atm(n)%inline_mp%mppm3(isc:iec,jsc:jec), Time)
       if(id_mppar > 0) used=send_data(id_mppar, Atm(n)%inline_mp%mppar(isc:iec,jsc:jec), Time)
       if(id_mppas > 0) used=send_data(id_mppas, Atm(n)%inline_mp%mppas(isc:iec,jsc:jec), Time)
       if(id_mppag > 0) used=send_data(id_mppag, Atm(n)%inline_mp%mppag(isc:iec,jsc:jec), Time)
       if(id_mpprs > 0) used=send_data(id_mpprs, Atm(n)%inline_mp%mpprs(isc:iec,jsc:jec), Time)
       if(id_mpprg > 0) used=send_data(id_mpprg, Atm(n)%inline_mp%mpprg(isc:iec,jsc:jec), Time)
       if(id_mppxr > 0) used=send_data(id_mppxr, Atm(n)%inline_mp%mppxr(isc:iec,jsc:jec), Time)
       if(id_mppxs > 0) used=send_data(id_mppxs, Atm(n)%inline_mp%mppxs(isc:iec,jsc:jec), Time)
       if(id_mppxg > 0) used=send_data(id_mppxg, Atm(n)%inline_mp%mppxg(isc:iec,jsc:jec), Time)

       if (id_qcw > 0 .and. id_qcr > 0 .and. id_qci > 0 .and. id_qcs > 0 .and. id_qcg > 0 .and. &
           id_rew > 0 .and. id_rer > 0 .and. id_rei > 0 .and. id_res > 0 .and. id_reg > 0 .and. id_cld > 0) then
         allocate(lsm(isc:iec,jsc:jec))
         allocate(dz(isc:iec,jsc:jec,1:npz))
         allocate(ptmp(isc:iec,jsc:jec,1:npz))
         allocate(qtmp(isc:iec,jsc:jec,1:npz))
         do j=jsc,jec
           do i=isc,iec
             lsm(i,j) = min (1.,abs(Atm(n)%phis(i,j))/(10.*grav))
           enddo
           if (.not. Atm(n)%flagstruct%hydrostatic) then
               dz(isc:iec,j,1:npz) = Atm(n)%delz(isc:iec,j,1:npz)
           else
               dz(isc:iec,j,1:npz) = (Atm(n)%peln(isc:iec,1:npz,j)-Atm(n)%peln (isc:iec,2:npz+1,j))*rdgas/grav*Atm(n)%pt(isc:iec,j,1:npz)
           endif
           ptmp(isc:iec,j,1:npz) = -Atm(n)%delp(isc:iec,j,1:npz)/(grav*dz(isc:iec,j,1:npz))*rdgas*Atm(n)%pt(isc:iec,j,1:npz)
           if (aerosol .gt. 0) then
             qtmp(isc:iec,j,1:npz) = Atm(n)%q(isc:iec,j,1:npz,aerosol)
           else
             qtmp(isc:iec,j,1:npz) = 0.0
           endif
           call cld_eff_rad (isc, iec, 1, npz, lsm(isc:iec,j), ptmp(isc:iec,j,1:npz), Atm(n)%delp(isc:iec,j,1:npz), Atm(n)%pt(isc:iec,j,1:npz), &
             Atm(n)%q(isc:iec,j,1:npz,sphum), Atm(n)%q(isc:iec,j,1:npz,liq_wat), Atm(n)%q(isc:iec,j,1:npz,ice_wat), &
             Atm(n)%q(isc:iec,j,1:npz,rainwat), Atm(n)%q(isc:iec,j,1:npz,snowwat), Atm(n)%q(isc:iec,j,1:npz,graupel), &
             qtmp(isc:iec,j,1:npz), Atm(n)%inline_mp%qcw(isc:iec,j,1:npz), Atm(n)%inline_mp%qci(isc:iec,j,1:npz), &
             Atm(n)%inline_mp%qcr(isc:iec,j,1:npz), Atm(n)%inline_mp%qcs(isc:iec,j,1:npz), Atm(n)%inline_mp%qcg(isc:iec,j,1:npz), &
             Atm(n)%inline_mp%rew(isc:iec,j,1:npz), Atm(n)%inline_mp%rei(isc:iec,j,1:npz), Atm(n)%inline_mp%rer(isc:iec,j,1:npz), &
             Atm(n)%inline_mp%res(isc:iec,j,1:npz), Atm(n)%inline_mp%reg(isc:iec,j,1:npz), Atm(n)%inline_mp%cld(isc:iec,j,1:npz), &
             Atm(n)%q(isc:iec,j,1:npz,cld_amt))
         enddo
         deallocate(lsm)
         deallocate(dz)
         deallocate(ptmp)
         deallocate(qtmp)
       endif

       if (id_qcw > 0) used=send_data(id_qcw, Atm(n)%inline_mp%qcw(isc:iec,jsc:jec,1:npz), Time)
       if (id_qci > 0) used=send_data(id_qci, Atm(n)%inline_mp%qci(isc:iec,jsc:jec,1:npz), Time)
       if (id_qcr > 0) used=send_data(id_qcr, Atm(n)%inline_mp%qcr(isc:iec,jsc:jec,1:npz), Time)
       if (id_qcs > 0) used=send_data(id_qcs, Atm(n)%inline_mp%qcs(isc:iec,jsc:jec,1:npz), Time)
       if (id_qcg > 0) used=send_data(id_qcg, Atm(n)%inline_mp%qcg(isc:iec,jsc:jec,1:npz), Time)
       if (id_rew > 0) used=send_data(id_rew, Atm(n)%inline_mp%rew(isc:iec,jsc:jec,1:npz), Time)
       if (id_rei > 0) used=send_data(id_rei, Atm(n)%inline_mp%rei(isc:iec,jsc:jec,1:npz), Time)
       if (id_rer > 0) used=send_data(id_rer, Atm(n)%inline_mp%rer(isc:iec,jsc:jec,1:npz), Time)
       if (id_res > 0) used=send_data(id_res, Atm(n)%inline_mp%res(isc:iec,jsc:jec,1:npz), Time)
       if (id_reg > 0) used=send_data(id_reg, Atm(n)%inline_mp%reg(isc:iec,jsc:jec,1:npz), Time)
       if (id_cld > 0) used=send_data(id_cld, Atm(n)%inline_mp%cld(isc:iec,jsc:jec,1:npz), Time)

       if (id_qv_dt_gfdlmp > 0) used=send_data(id_qv_dt_gfdlmp, Atm(n)%inline_mp%qv_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_ql_dt_gfdlmp > 0) used=send_data(id_ql_dt_gfdlmp, Atm(n)%inline_mp%ql_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qi_dt_gfdlmp > 0) used=send_data(id_qi_dt_gfdlmp, Atm(n)%inline_mp%qi_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_liq_wat_dt_gfdlmp > 0) used=send_data(id_liq_wat_dt_gfdlmp, Atm(n)%inline_mp%liq_wat_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_ice_wat_dt_gfdlmp > 0) used=send_data(id_ice_wat_dt_gfdlmp, Atm(n)%inline_mp%ice_wat_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qr_dt_gfdlmp > 0) used=send_data(id_qr_dt_gfdlmp, Atm(n)%inline_mp%qr_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qg_dt_gfdlmp > 0) used=send_data(id_qg_dt_gfdlmp, Atm(n)%inline_mp%qg_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qs_dt_gfdlmp > 0) used=send_data(id_qs_dt_gfdlmp, Atm(n)%inline_mp%qs_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_t_dt_gfdlmp > 0)  used=send_data(id_t_dt_gfdlmp,  Atm(n)%inline_mp%t_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_u_dt_gfdlmp > 0)  used=send_data(id_u_dt_gfdlmp,  Atm(n)%inline_mp%u_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_v_dt_gfdlmp > 0)  used=send_data(id_v_dt_gfdlmp,  Atm(n)%inline_mp%v_dt(isc:iec,jsc:jec,1:npz), Time)

       if (id_qv_dt_phys > 0) used=send_data(id_qv_dt_phys, Atm(n)%phys_diag%phys_qv_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_ql_dt_phys > 0) used=send_data(id_ql_dt_phys, Atm(n)%phys_diag%phys_ql_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qi_dt_phys > 0) used=send_data(id_qi_dt_phys, Atm(n)%phys_diag%phys_qi_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_liq_wat_dt_phys > 0) used=send_data(id_liq_wat_dt_phys, Atm(n)%phys_diag%phys_liq_wat_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_ice_wat_dt_phys > 0) used=send_data(id_ice_wat_dt_phys, Atm(n)%phys_diag%phys_ice_wat_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qr_dt_phys > 0) used=send_data(id_qr_dt_phys, Atm(n)%phys_diag%phys_qr_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qs_dt_phys > 0) used=send_data(id_qs_dt_phys, Atm(n)%phys_diag%phys_qs_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qg_dt_phys > 0) used=send_data(id_qg_dt_phys, Atm(n)%phys_diag%phys_qg_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_t_dt_phys > 0)  used=send_data(id_t_dt_phys,  Atm(n)%phys_diag%phys_t_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_u_dt_phys > 0)  used=send_data(id_u_dt_phys,  Atm(n)%phys_diag%phys_u_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_v_dt_phys > 0)  used=send_data(id_v_dt_phys,  Atm(n)%phys_diag%phys_v_dt(isc:iec,jsc:jec,1:npz), Time)

       if (id_t_dt_nudge > 0) used=send_data(id_t_dt_nudge,  Atm(n)%nudge_diag%nudge_t_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_ps_dt_nudge > 0) used=send_data(id_ps_dt_nudge,  Atm(n)%nudge_diag%nudge_ps_dt(isc:iec,jsc:jec), Time)
       if (id_delp_dt_nudge > 0) used=send_data(id_delp_dt_nudge,  Atm(n)%nudge_diag%nudge_delp_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_u_dt_nudge > 0) used=send_data(id_u_dt_nudge,  Atm(n)%nudge_diag%nudge_u_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_v_dt_nudge > 0) used=send_data(id_v_dt_nudge,  Atm(n)%nudge_diag%nudge_v_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qv_dt_nudge > 0) used=send_data(id_qv_dt_nudge,  Atm(n)%nudge_diag%nudge_qv_dt(isc:iec,jsc:jec,1:npz), Time)

       if (idiag%id_t_dt_sg > 0) used=send_data(idiag%id_t_dt_sg,  Atm(n)%sg_diag%t_dt(isc:iec,jsc:jec,1:npz), Time)
       if (idiag%id_u_dt_sg > 0) used=send_data(idiag%id_u_dt_sg,  Atm(n)%sg_diag%u_dt(isc:iec,jsc:jec,1:npz), Time)
       if (idiag%id_v_dt_sg > 0) used=send_data(idiag%id_v_dt_sg,  Atm(n)%sg_diag%v_dt(isc:iec,jsc:jec,1:npz), Time)
       if (idiag%id_qv_dt_sg > 0) used=send_data(idiag%id_qv_dt_sg,  Atm(n)%sg_diag%qv_dt(isc:iec,jsc:jec,1:npz), Time)

       if (id_t_dt_diabatic > 0) used=send_data(id_t_dt_diabatic, Atm(n)%phys_diag%phys_t_dt(isc:iec,jsc:jec,1:npz) + &
                                                Atm(n)%inline_mp%t_dt(isc:iec,jsc:jec,1:npz), Time)
       if (id_qv_dt_diabatic > 0) used=send_data(id_qv_dt_diabatic, Atm(n)%phys_diag%phys_qv_dt(isc:iec,jsc:jec,1:npz) + &
                                                Atm(n)%inline_mp%qv_dt(isc:iec,jsc:jec,1:npz), Time)

       if(id_c15>0 .or. id_c25>0 .or. id_c35>0 .or. id_c45>0) then
          call wind_max(isc, iec, jsc, jec ,isd, ied, jsd, jed, Atm(n)%ua(isc:iec,jsc:jec,npz),   &
                        Atm(n)%va(isc:iec,jsc:jec,npz), ws_max, Atm(n)%domain)
          do j=jsc,jec
             do i=isc,iec
                if( abs(Atm(n)%gridstruct%agrid(i,j,2)*rad2deg)<45.0 .and.     &
                    Atm(n)%phis(i,j)*ginv<500.0 .and. ws_max(i,j)>ws_0 ) then
                    storm(i,j) = .true.
                else
                    storm(i,j) = .false.
                endif
             enddo
          enddo
       endif

       if ( id_vorts>0  .or. ANY(id_vort_levs>0) .or. id_vort_plev>0  &
            .or. id_vort>0 .or. id_pv>0 .or. id_pv350k>0 .or. id_pv550k>0 &
            .or. id_rh>0 .or. id_x850>0 .or. id_uh03>0 .or. id_uh25>0 &
            .or. id_srh1 > 0 .or. id_srh3 > 0 .or. id_srh25 > 0 &
            .or. id_ustm > 0 .or. id_vstm > 0) then
          call get_vorticity(isc, iec, jsc, jec, isd, ied, jsd, jed, npz, Atm(n)%u, Atm(n)%v, wk, &
               Atm(n)%gridstruct%dx, Atm(n)%gridstruct%dy, Atm(n)%gridstruct%rarea)

          if(id_vort >0) used=send_data(id_vort,  wk, Time)
          if(id_vorts>0) used=send_data(id_vorts, wk(isc:iec,jsc:jec,npz), Time)

          if(id_c15>0) then
             do j=jsc,jec
                do i=isc,iec
                   if ( storm(i,j) )    &
                   storm(i,j) = (Atm(n)%gridstruct%agrid(i,j,2)>0. .and. wk(i,j,npz)> vort_c0) .or. &
                                (Atm(n)%gridstruct%agrid(i,j,2)<0. .and. wk(i,j,npz)<-vort_c0)
                enddo
             enddo
          endif

          call make_plevs( wk, plevs_ln, Atm(n)%peln(isc:iec,1:npz+1,jsc:jec), &
                        npz, -1, id_vort_plev, id_vort_levs, nplev, Atm(n)%bd, Time)

          if(id_c15>0 .or. id_x850>0) then
             call interpolate_vertical(isc, iec, jsc, jec, npz,   &
                                       850.e2, Atm(n)%peln, wk, a2)
             if ( id_x850>0 ) x850(:,:) = a2(:,:)

             if(id_c15>0) then
             do j=jsc,jec
                do i=isc,iec
                   if ( storm(i,j) )    &
                     storm(i,j) = (Atm(n)%gridstruct%agrid(i,j,2)>0. .and. a2(i,j)> vort_c0) .or.     &
                                  (Atm(n)%gridstruct%agrid(i,j,2)<0. .and. a2(i,j)<-vort_c0)
                enddo
             enddo
             endif

          endif

          if( .not. Atm(n)%flagstruct%hydrostatic ) then

             if ( id_uh03 > 0 ) then
                call updraft_helicity(isc, iec, jsc, jec, ngc, npz, zvir, sphum, a2, &
                     Atm(n)%w, wk, Atm(n)%delz, Atm(n)%q,   &
                     Atm(n)%flagstruct%hydrostatic, Atm(n)%pt, Atm(n)%peln, Atm(n)%phis, grav, 0., 3.e3)
                used = send_data ( id_uh03, a2, Time )
                if(prt_minmax) then
                   do j=jsc,jec
                      do i=isc,iec
                         tmp = rad2deg * Atm(n)%gridstruct%agrid(i,j,1)
                         tmp2 = rad2deg * Atm(n)%gridstruct%agrid(i,j,2)
                         if (  tmp2<25. .or. tmp2>50.    &
                              .or. tmp<235. .or. tmp>300. ) then
                            a2(i,j) = 0.
                         endif
                      enddo
                   enddo
                   call prt_mxm('UH over CONUS', a2, isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)
                endif
             endif
             if ( id_uh25 > 0 ) then
                call updraft_helicity(isc, iec, jsc, jec, ngc, npz, zvir, sphum, a2, &
                     Atm(n)%w, wk, Atm(n)%delz, Atm(n)%q,   &
                     Atm(n)%flagstruct%hydrostatic, Atm(n)%pt, Atm(n)%peln, Atm(n)%phis, grav, 2.e3, 5.e3)
                used = send_data ( id_uh25, a2, Time )
             endif
          endif


          if ( id_srh1 > 0 .or. id_srh3 > 0 .or. id_srh25 > 0 .or. id_ustm > 0 .or. id_vstm > 0) then
              allocate(ustm(isc:iec,jsc:jec), vstm(isc:iec,jsc:jec))

              call bunkers_vector(isc, iec, jsc, jec, ngc, npz, zvir, sphum, ustm, vstm, &
                   Atm(n)%ua, Atm(n)%va, Atm(n)%delz, Atm(n)%q,   &
                   Atm(n)%flagstruct%hydrostatic, Atm(n)%pt, Atm(n)%peln, Atm(n)%phis, grav)

              if ( id_ustm > 0 ) then
                 used = send_data ( id_ustm, ustm, Time )
              endif
              if ( id_vstm > 0 ) then
                 used = send_data ( id_vstm, vstm, Time )
              endif

              if ( id_srh1 > 0 ) then
                 call helicity_relative_CAPS(isc, iec, jsc, jec, ngc, npz, zvir, sphum, a2, ustm, vstm, &
                      Atm(n)%ua, Atm(n)%va, Atm(n)%delz, Atm(n)%q,   &
                      Atm(n)%flagstruct%hydrostatic, Atm(n)%pt, Atm(n)%peln, Atm(n)%phis, grav, 0., 1.e3)
                 used = send_data ( id_srh1, a2, Time )
                 if(prt_minmax) then
                    do j=jsc,jec
                       do i=isc,iec
                          tmp = rad2deg * Atm(n)%gridstruct%agrid(i,j,1)
                          tmp2 = rad2deg * Atm(n)%gridstruct%agrid(i,j,2)
                          if (  tmp2<25. .or. tmp2>50.    &
                               .or. tmp<235. .or. tmp>300. ) then
                             a2(i,j) = 0.
                          endif
                       enddo
                    enddo
                    call prt_mxm('SRH (0-1 km) over CONUS', a2, isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
                 endif
              endif

              if ( id_srh3 > 0 ) then
                 call helicity_relative_CAPS(isc, iec, jsc, jec, ngc, npz, zvir, sphum, a2, ustm, vstm, &
                      Atm(n)%ua, Atm(n)%va, Atm(n)%delz, Atm(n)%q,   &
                      Atm(n)%flagstruct%hydrostatic, Atm(n)%pt, Atm(n)%peln, Atm(n)%phis, grav, 0., 3e3)
                 used = send_data ( id_srh3, a2, Time )
                 if(prt_minmax) then
                    do j=jsc,jec
                       do i=isc,iec
                          tmp = rad2deg * Atm(n)%gridstruct%agrid(i,j,1)
                          tmp2 = rad2deg * Atm(n)%gridstruct%agrid(i,j,2)
                          if (  tmp2<25. .or. tmp2>50.    &
                               .or. tmp<235. .or. tmp>300. ) then
                             a2(i,j) = 0.
                          endif
                       enddo
                    enddo
                    call prt_mxm('SRH (0-3 km) over CONUS', a2, isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
                 endif
              endif

              if ( id_srh25 > 0 ) then
                 call helicity_relative_CAPS(isc, iec, jsc, jec, ngc, npz, zvir, sphum, a2, ustm, vstm, &
                      Atm(n)%ua, Atm(n)%va, Atm(n)%delz, Atm(n)%q,   &
                      Atm(n)%flagstruct%hydrostatic, Atm(n)%pt, Atm(n)%peln, Atm(n)%phis, grav, 2.e3, 5e3)
                 used = send_data ( id_srh25, a2, Time )
                 if(prt_minmax) then
                    do j=jsc,jec
                       do i=isc,iec
                          tmp = rad2deg * Atm(n)%gridstruct%agrid(i,j,1)
                          tmp2 = rad2deg * Atm(n)%gridstruct%agrid(i,j,2)
                          if (  tmp2<25. .or. tmp2>50.    &
                               .or. tmp<235. .or. tmp>300. ) then
                             a2(i,j) = 0.
                          endif
                       enddo
                    enddo
                    call prt_mxm('SRH (2-5 km) over CONUS', a2, isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
                 endif
              endif

              deallocate(ustm, vstm)
          endif


          if ( id_pv > 0 .or. id_pv350K >0 .or. id_pv550K >0 ) then
              if (allocated(a3)) deallocate(a3)
              allocate ( a3(isc:iec,jsc:jec,npz+1) )
            ! Modified pv_entropy to get potential temperature at layer interfaces (last variable)
            ! The values are needed for interpolate_z
             ! Note: this is expensive computation.
              call pv_entropy(isc, iec, jsc, jec, ngc, npz, wk,    &
                              Atm(n)%gridstruct%f0, Atm(n)%pt, Atm(n)%pkz, Atm(n)%delp, grav, a3)
              if ( id_pv > 0) then
                used = send_data ( id_pv, wk, Time )
              endif
              if( id_pv350K > 0 .or. id_pv550K >0 ) then
                !"pot temp" from pv_entropy is only semi-finished; needs p0^kappa (pk0)
                do k=1,npz+1
                  do j=jsc,jec
                    do i=isc,iec
                      a3(i,j,k) = a3(i,j,k) * pk0
                    enddo
                  enddo
                enddo
                !wk as input, which stores pv from pv_entropy;
                !use z interpolation, both potential temp and z increase monotonically with height
                !interpolate_vertical will apply log operation to 350, and also assumes a different vertical order
                call interpolate_z(isc, iec, jsc, jec, npz, 350., a3, wk, a2)
                used = send_data( id_pv350K, a2, Time)
                !interpolate_vertical will apply log operation to 350, and also assumes a different vertical order
                call interpolate_z(isc, iec, jsc, jec, npz, 550., a3, wk, a2)
                used = send_data( id_pv550K, a2, Time)
              endif
                deallocate ( a3 )
              if (prt_minmax) call prt_mxm('PV', wk, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)
          endif

       endif

       ! Relative Humidity
       if ( id_rh > 0 .or. ANY(id_rh_levs>0) .or. id_rh_plev>0 .or. ANY(id_dp_levs>0) .or. id_dp_plev>0) then
          ! Compute FV mean pressure
          do k=1,npz
             do j=jsc,jec
                do i=isc,iec
                   a2(i,j) = Atm(n)%delp(i,j,k)/(Atm(n)%peln(i,k+1,j)-Atm(n)%peln(i,k,j))
                enddo
             enddo
             call mqs3d(iec-isc+1, jec-jsc+1, 1, Atm(n)%pt(isc:iec,jsc:jec,k), a2, &
                        Atm(n)%q(isc:iec,jsc:jec,k,sphum), wk(isc:iec,jsc:jec,k))
             do j=jsc,jec
                do i=isc,iec
                   wk(i,j,k) = 100.*Atm(n)%q(i,j,k,sphum)/wk(i,j,k)
                enddo
             enddo
          enddo
          used = send_data ( id_rh, wk, Time )
          if(prt_minmax) then
             call prt_mxm('RH_Top (%)', wk(isc:iec,jsc:jec,1), isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
             call prt_mxm('RH_Bottom (%)', wk(isc:iec,jsc:jec,npz), isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
             call prt_mxm('RH (%)', wk, isc, iec, jsc, jec, 0, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)
             call interpolate_vertical(isc, iec, jsc, jec, npz, 200.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
             if (.not. Atm(n)%gridstruct%bounded_domain) then
                tmp = 0.
                sar = 0.
                do j=jsc,jec
                   do i=isc,iec
                      slat = Atm(n)%gridstruct%agrid(i,j,2)*rad2deg
                      sar = sar + Atm(n)%gridstruct%area(i,j)
                      tmp = tmp + a2(i,j)*Atm(n)%gridstruct%area(i,j)
                   enddo
                enddo
                call mp_reduce_sum(sar)
                call mp_reduce_sum(tmp)
                if ( sar > 0. .and. user_prt_level >= PRT_LEVEL_2) then
                   if (master) write(*,'(2x, A, G20.8)') 'RH200 = ', tmp/sar
                endif
             endif
          endif

          call make_plevs( wk(isc:iec,jsc:jec,:), plevs_ln, Atm(n)%peln(isc:iec,1:npz+1,jsc:jec), &
                           npz, 0, id_rh_plev, id_rh_levs, nplev, Atm(n)%bd, Time)

          if (ANY(id_dp_levs>0) .or. id_dp_plev>0) then
             if (allocated(a3)) deallocate(a3)
             allocate(a3(isc:iec,jsc:jec,1:npz))
             !compute dew point (K) !DEW POINT CALCULATION
             !using formula at https://cals.arizona.edu/azmet/dewpoint.html
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                tmp = ( log(max(wk(i,j,k)*1.e-2,1.e-2)) + 17.27 * ( Atm(n)%pt(i,j,k) - 273.14 )/ ( -35.84 + Atm(n)%pt(i,j,k)) ) / 17.27
                a3(i,j,k) = 273.14 + 237.3*tmp/ ( 1. - tmp )
             enddo
             enddo
             enddo
             call make_plevs( a3(isc:iec,jsc:jec,:), plevs_ln, Atm(n)%peln(isc:iec,1:npz+1,jsc:jec), &
                              npz, 1, id_dp_plev, id_dp_levs, nplev, Atm(n)%bd, Time)
             deallocate(a3)

          endif
       endif



       ! rel hum (CMIP definition) at selected press levels  (for IPCC)
       if (id_rh10_cmip>0  .or. id_rh50_cmip>0  .or. id_rh100_cmip>0 .or. &
           id_rh250_cmip>0 .or. id_rh300_cmip>0 .or. id_rh500_cmip>0 .or. &
           id_rh700_cmip>0 .or. id_rh850_cmip>0 .or. id_rh925_cmip>0 .or. &
           id_rh1000_cmip>0) then
           ! compute mean pressure
           do k=1,npz
               do j=jsc,jec
               do i=isc,iec
                   a2(i,j) = Atm(n)%delp(i,j,k)/(Atm(n)%peln(i,k+1,j)-Atm(n)%peln(i,k,j))
               enddo
               enddo
               call mqs3d (iec-isc+1, jec-jsc+1, 1, Atm(n)%pt(isc:iec,jsc:jec,k), a2, &
                           Atm(n)%q(isc:iec,jsc:jec,k,sphum), wk(isc:iec,jsc:jec,k))
               do j=jsc,jec
               do i=isc,iec
                   wk(i,j,k) = 100.*Atm(n)%q(i,j,k,sphum)/wk(i,j,k)
               enddo
               enddo
           enddo
           if (id_rh10_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 10.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh10_cmip, a2, Time)
           endif
           if (id_rh50_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 50.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh50_cmip, a2, Time)
           endif
           if (id_rh100_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 100.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh100_cmip, a2, Time)
           endif
           if (id_rh250_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 250.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh250_cmip, a2, Time)
           endif
           if (id_rh300_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 300.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh300_cmip, a2, Time)
           endif
           if (id_rh500_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 500.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh500_cmip, a2, Time)
           endif
           if (id_rh700_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 700.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh700_cmip, a2, Time)
           endif
           if (id_rh850_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 850.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh850_cmip, a2, Time)
           endif
           if (id_rh925_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 925.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh925_cmip, a2, Time)
           endif
           if (id_rh1000_cmip>0) then
               call interpolate_vertical(isc, iec, jsc, jec, npz, 1000.e2, Atm(n)%peln, wk(isc:iec,jsc:jec,:), a2)
               used=send_data(id_rh1000_cmip, a2, Time)
           endif
       endif

       if(id_c25>0 .or. id_c35>0 .or. id_c45>0) then
          do j=jsc,jec
             do i=isc,iec
                if ( storm(i,j) .and. ws_max(i,j)>ws_1 ) then
                     cat_crt(i,j) = .true.
                else
                     cat_crt(i,j) = .false.
                endif
             enddo
          enddo
       endif



       if( id_slp>0 .or. id_tm>0 .or. id_any_hght>0 .or. id_hght3d>0 .or. id_c15>0 .or. id_ctz>0 ) then

          allocate ( wz(isc:iec,jsc:jec,npz+1) )
          call get_height_field(isc, iec, jsc, jec, ngc, npz, Atm(n)%flagstruct%hydrostatic, Atm(n)%delz,  &
                                wz, Atm(n)%pt, Atm(n)%q, Atm(n)%peln, zvir)
          if( prt_minmax )   &
          call prt_mxm('ZTOP (m)',wz(isc:iec,jsc:jec,1), isc, iec, jsc, jec, 0, 1, 1.E-3, Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_1)

          if (id_hght3d > 0) then
             used = send_data(id_hght3d, 0.5*(wz(isc:iec,jsc:jec,1:npz)+wz(isc:iec,jsc:jec,2:npz+1)), Time)
          endif

          if(id_slp > 0) then
! Cumpute SLP (pressure at height=0)
          allocate ( slp(isc:iec,jsc:jec) )
          call get_pressure_given_height(isc, iec, jsc, jec, ngc, npz, wz, 1, height(2),   &
                                        Atm(n)%pt(:,:,npz), Atm(n)%peln, slp, 0.01)

          if ( Atm(n)%flagstruct%range_warn ) then
             call range_check('SLP', slp, isc, iec, jsc, jec, 0, Atm(n)%gridstruct%agrid,    &
                  slprange(1), slprange(2), bad_range, Time)
          endif
          used = send_data (id_slp, slp, Time)
             if( prt_minmax ) then
                call prt_mxm('SLP (Pa)', slp, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_0)
                call prt_maxmin('SLP', slp, isc, iec, jsc, jec, 0, 1, 1., PRT_LEVEL_2)
                if ( .not. Atm(n)%gridstruct%bounded_domain ) then
! US Potential Landfall TCs (PLT):
                 do j=jsc,jec
                    do i=isc,iec
                       a2(i,j) = 1015.
                       slon = rad2deg*Atm(n)%gridstruct%agrid(i,j,1)
                       slat = rad2deg*Atm(n)%gridstruct%agrid(i,j,2)
                       if ( slat>15. .and. slat<40. .and. slon>270. .and. slon<290. ) then
                            a2(i,j) = slp(i,j)
                       endif
                    enddo
                 enddo
                 call prt_mxm('SLP_ATL (Pa)', a2, isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_2)
                endif
             endif
          endif

! Compute H3000 and/or H500
          if( id_tm>0 .or. id_any_hght>0 .or. id_ppt>0 .or. ANY(id_theta_levs>0) .or. id_theta_plev>0) then

             allocate( a3(isc:iec,jsc:jec,nplev) )

             idg(:) = id_h_levs(:)

             !Determine which levels have been registered and need writing out
             if ( id_tm>0 ) then
                  idg(k300) = 1  ! 300-mb
                  idg(k500) = 1  ! 500-mb
             else
                  idg(k300) = id_h_levs(k300)
                  idg(k500) = id_h_levs(k500)
             endif

             call get_height_given_pressure(isc, iec, jsc, jec, npz, wz, nplev, idg, plevs_ln, Atm(n)%peln, a3)
             ! reset
             idg(k300) = id_h_levs(k300)
             idg(k500) = id_h_levs(k500)

             do i=1,nplev
                if (idg(i)>0) used=send_data(idg(i), a3(isc:iec,jsc:jec,i), Time)
             enddo

             if (id_h_plev>0)  then
               id1(:) = 1
               call get_height_given_pressure(isc, iec, jsc, jec, npz, wz, nplev, id1, plevs_ln, Atm(n)%peln, a3)
               used=send_data(id_h_plev, a3(isc:iec,jsc:jec,:), Time)
             endif

             if( prt_minmax ) then

                if(id_h_levs(k100)>0 .or. (id_h_plev>0 .and. k100>0))  &
                call prt_mxm('Z100 (m)',a3(isc:iec,jsc:jec,k100),isc,iec,jsc,jec,0,1,1.E-3,Atm(n)%gridstruct%area_64,Atm(n)%domain, PRT_LEVEL_2)

                if(id_h_levs(k500)>0 .or. (id_h_plev>0 .and. k500>0))  then
                   if (Atm(n)%gridstruct%bounded_domain) then
                      call prt_mxm('Z500 (m)',a3(isc:iec,jsc:jec,k500),isc,iec,jsc,jec,0,1,1.,Atm(n)%gridstruct%area_64,Atm(n)%domain, PRT_LEVEL_1)
                   else
                      call prt_gb_nh_sh('Z500', isc,iec, jsc,jec, a3(isc,jsc,k500), Atm(n)%gridstruct%area_64(isc:iec,jsc:jec),   &
                                        Atm(n)%gridstruct%agrid_64(isc:iec,jsc:jec,2), PRT_LEVEL_1)
                   endif
                endif

             endif

             ! mean virtual temp 300mb to 500mb
             if( id_tm>0 ) then
                if ( (id_h_levs(k500) <= 0 .or. id_h_levs(k300) <= 0) .and. (id_h_plev>0 .and. (k300<=0 .or. k500<=0))) then
                   call mpp_error(NOTE, "Could not find levs for 300--500 mb mean temperature, setting to missing_value")
                   a2 = missing_value
                else
                 do j=jsc,jec
                    do i=isc,iec
                       a2(i,j) = grav*(a3(i,j,k500)-a3(i,j,k300))/(rdgas*(plevs_ln(k300)-plevs_ln(k500)))
                    enddo
                 enddo
              endif
                used = send_data ( id_tm, a2, Time )
             endif

            if(id_c15>0 .or. id_c25>0 .or. id_c35>0 .or. id_c45>0) then
             do j=jsc,jec
                do i=isc,iec
! Minimum warm core:
                   if ( storm(i,j) ) then
                        if( a2(i,j)<254.0 .or. Atm(n)%pt(i,j,npz)<281.0 ) Then
                              storm(i,j) = .false.
                            cat_crt(i,j) = .false.
                        endif
                   endif
                enddo
             enddo
! Cat 1-5:
             do j=jsc,jec
                do i=isc,iec
                   if ( storm(i,j) .and. slp(i,j)<1000.0 ) then
                         depress(i,j) = 1000. - slp(i,j)
                        tc_count(i,j) = 1.
                   else
                         depress(i,j) = 0.
                        tc_count(i,j) = 0.
                   endif
                enddo
             enddo
             used = send_data(id_c15, depress, Time)
             if(id_f15>0) used = send_data(id_f15, tc_count, Time)
             if(prt_minmax) then
                do j=jsc,jec
                   do i=isc,iec
                      slon = rad2deg*Atm(n)%gridstruct%agrid(i,j,1)
                      slat = rad2deg*Atm(n)%gridstruct%agrid(i,j,2)
! Western Pac: negative; positive elsewhere
                      if ( slat>0. .and. slat<40. .and. slon>110. .and. slon<180. ) then
                           depress(i,j) = -depress(i,j)
                      endif
                   enddo
                enddo
                call prt_mxm('Depress', depress, isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
                do j=jsc,jec
                   do i=isc,iec
                      if ( Atm(n)%gridstruct%agrid(i,j,2)<0.) then
! Excluding the SH cyclones
                           depress(i,j) = 0.
                      endif
                   enddo
                enddo
                call prt_mxm('NH Deps', depress, isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)

! ATL basin cyclones
                do j=jsc,jec
                   do i=isc,iec
                      tmp = rad2deg * Atm(n)%gridstruct%agrid(i,j,1)
                      if ( tmp<280. ) then
                           depress(i,j) = 0.
                      endif
                   enddo
                enddo
                call prt_mxm('ATL Deps', depress, isc, iec, jsc, jec, 0,   1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
             endif
          endif

! Cat 2-5:
            if(id_c25>0) then
             do j=jsc,jec
                do i=isc,iec
                   if ( cat_crt(i,j) .and. slp(i,j)<980.0 ) then
                        depress(i,j) = 980. - slp(i,j)
                       tc_count(i,j) = 1.
                   else
                        depress(i,j) = 0.
                       tc_count(i,j) = 0.
                   endif
                enddo
             enddo
             used = send_data(id_c25, depress, Time)
             if(id_f25>0) used = send_data(id_f25, tc_count, Time)
            endif

! Cat 3-5:
            if(id_c35>0) then
             do j=jsc,jec
                do i=isc,iec
                   if ( cat_crt(i,j) .and. slp(i,j)<964.0 ) then
                        depress(i,j) = 964. - slp(i,j)
                       tc_count(i,j) = 1.
                   else
                        depress(i,j) = 0.
                       tc_count(i,j) = 0.
                   endif
                enddo
             enddo
             used = send_data(id_c35, depress, Time)
             if(id_f35>0) used = send_data(id_f35, tc_count, Time)
            endif

! Cat 4-5:
            if(id_c45>0) then
             do j=jsc,jec
                do i=isc,iec
                   if ( cat_crt(i,j) .and. slp(i,j)<944.0 ) then
                        depress(i,j) = 944. - slp(i,j)
                       tc_count(i,j) = 1.
                   else
                        depress(i,j) = 0.
                       tc_count(i,j) = 0.
                   endif
                enddo
             enddo
             used = send_data(id_c45, depress, Time)
             if(id_f45>0) used = send_data(id_f45, tc_count, Time)
            endif

            if (id_c15>0) then
                deallocate(depress)
                deallocate(cat_crt)
                deallocate(storm)
                deallocate(ws_max)
                deallocate(tc_count)
            endif

            if(id_slp>0 )  deallocate( slp )

           deallocate( a3 ) !needed because a3 may need to be re-allocated later with a different number of vertical levels
        endif

        deallocate ( wz )
       endif

! Temperature:
       idg(:) = id_t_levs(:)

       do_cs_intp = .false.
       do i=1,nplev
          if ( idg(i)>0 ) then
               do_cs_intp = .true.
               exit
          endif
       enddo

       !Height calculation no longer needed??
       if (.not. allocated(wz)) allocate ( wz(isc:iec,jsc:jec,npz+1) )
       call get_height_field(isc, iec, jsc, jec, ngc, npz, Atm(n)%flagstruct%hydrostatic, Atm(n)%delz,  &
                             wz, Atm(n)%pt, Atm(n)%q, Atm(n)%peln, zvir)

       if ( do_cs_intp ) then  ! log(pe) as the coordinate for temp re-construction
          if(.not. allocated (a3) ) allocate( a3(isc:iec,jsc:jec,nplev) )
          call cs3_interpolator(isc,iec,jsc,jec,npz, Atm(n)%pt(isc:iec,jsc:jec,:), nplev,    &
                                plevs_ln(1:nplev), Atm(n)%peln, idg, a3, 1)
          do i=1,nplev
             if (idg(i)>0) used=send_data(idg(i), a3(isc:iec,jsc:jec,i), Time)
          enddo
          if ( id_t_levs(k100)>0 .and. prt_minmax ) then
             call prt_mxm('T100 (K)', a3(isc:iec,jsc:jec,k100), isc, iec, jsc, jec, 0, 1, 1.,   &
                          Atm(n)%gridstruct%area_64, Atm(n)%domain)
             if (.not. Atm(n)%gridstruct%bounded_domain)  then
                tmp = 0.
                sar = 0.
                !            Compute mean temp at 100 mb near EQ
                do j=jsc,jec
                   do i=isc,iec
                      slat = Atm(n)%gridstruct%agrid(i,j,2)*rad2deg
                      if( (slat>-10.0 .and. slat<10.) ) then
                         sar = sar + Atm(n)%gridstruct%area(i,j)
                         tmp = tmp + a3(i,j,k100)*Atm(n)%gridstruct%area(i,j)
                      endif
                   enddo
                enddo
                call mp_reduce_sum(sar)
                call mp_reduce_sum(tmp)
                if ( sar > 0. .and. user_prt_level >= PRT_LEVEL_2) then
                   if (master) write(*,'(2x, A, G20.8)') 'Tropical [10s,10n] mean T100 = ', tmp/sar
                else
                   if (master) write(*,*) 'Warning: problem computing tropical mean T100'
                endif
             endif
          endif
          if ( id_t_levs(k200) > 0 .and. prt_minmax ) then
             call prt_mxm('T200 (K)', a3(isc:iec,jsc:jec,k200), isc, iec, jsc, jec, 0, 1, 1.,   &
                          Atm(n)%gridstruct%area_64, Atm(n)%domain)
             if (.not. Atm(n)%gridstruct%bounded_domain) then
                tmp = 0.
                sar = 0.
                do j=jsc,jec
                   do i=isc,iec
                      slat = Atm(n)%gridstruct%agrid(i,j,2)*rad2deg
                      if( (slat>-20 .and. slat<20) ) then
                         sar = sar + Atm(n)%gridstruct%area(i,j)
                         tmp = tmp + a3(i,j,k200)*Atm(n)%gridstruct%area(i,j)
                      endif
                   enddo
                enddo
                call mp_reduce_sum(sar)
                call mp_reduce_sum(tmp)
                if ( sar > 0.  .and. user_prt_level >= PRT_LEVEL_2) then
                   if (master) write(*,'(2x, A, G20.8)') 'Tropical [-20.,20.] mean T200 = ', tmp/sar
                endif
             endif
          endif
          deallocate( a3 )
       endif

       if (id_t_plev>0) then
         if(.not. allocated (a3) ) allocate( a3(isc:iec,jsc:jec,nplev) )
         id1(:) = 1
         call cs3_interpolator(isc,iec,jsc,jec,npz, Atm(n)%pt(isc:iec,jsc:jec,:), nplev,    &
                               plevs_ln(1:nplev), Atm(n)%peln, id1, a3, 1)
         used=send_data(id_t_plev, a3(isc:iec,jsc:jec,:), Time)
         deallocate( a3 )
       endif

       if(id_mq > 0)  then
          do j=jsc,jec
             do i=isc,iec
! zxg * surface pressure * 1.e-18--> Hadleys per unit area
! Unit Hadley = 1.E18 kg m**2 / s**2
                a2(i,j) = -1.e-18 * Atm(n)%ps(i,j)*idiag%zxg(i,j)
             enddo
          enddo
          used = send_data(id_mq, a2, Time)
          if( prt_minmax  .and. user_prt_level >= PRT_LEVEL_2) then
              tot_mq  = g_sum( Atm(n)%domain, a2, isc, iec, jsc, jec, ngc, Atm(n)%gridstruct%area_64, 0)
              idiag%mtq_sum = idiag%mtq_sum + tot_mq
              if ( idiag%steps <= max_step ) idiag%mtq(idiag%steps) = tot_mq
              if(master) write(*,'(2x, A, G20.8)') 'Total (global) mountain torque (Hadleys)=', tot_mq
          endif
       endif

       if (id_ts > 0) used = send_data(id_ts, Atm(n)%ts(isc:iec,jsc:jec), Time)

       if ( id_tq>0 ) then
          nwater = Atm(1)%flagstruct%nwat
          a2 = 0.
          do k=1,npz
          do j=jsc,jec
             do i=isc,iec
!                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,1)*Atm(n)%delp(i,j,k)
                a2(i,j) = a2(i,j) + sum(Atm(n)%q(i,j,k,1:nwater))*Atm(n)%delp(i,j,k)
             enddo
          enddo
          enddo
          used = send_data(id_tq, a2*ginv, Time)
       endif

       Cl  = get_tracer_index (MODEL_ATMOS, 'Cl')
       Cl2 = get_tracer_index (MODEL_ATMOS, 'Cl2')
       if (Cl > 0 .and. Cl2 > 0) then
        allocate(var2(isc:iec,jsc:jec))
          var2 = 0.
          do k=1,npz
          do j=jsc,jec
          do i=isc,iec
             var2(i,j) = var2(i,j) + Atm(n)%delp(i,j,k)
          enddo
          enddo
          enddo

          if ( id_acl > 0 ) then
             a2 = 0.
             einf = 0.
             qm = 0.
             do k=1,npz
                do j=jsc,jec
                   do i=isc,iec
                      a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,Cl)*Atm(n)%delp(i,j,k) ! moist mass
                   enddo
                enddo
             enddo
             !Convert to mean mixing ratio
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) / var2(i,j)
             enddo
             enddo
             used = send_data(id_acl, a2, Time)
          endif
          if ( id_acl2 > 0 ) then
             a2 = 0.
             einf = 0.
             qm = 0.
             do k=1,npz
                do j=jsc,jec
                   do i=isc,iec
                      a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,Cl2)*Atm(n)%delp(i,j,k) ! moist mass
                   enddo
                enddo
             enddo
             !Convert to mean mixing ratio
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) / var2(i,j)
             enddo
             enddo
             used = send_data(id_acl2, a2, Time)
          endif
          if ( id_acly > 0 ) then
             a2 = 0.
             einf = 0.
             qm = 0.
             e2 = 0.
             do k=1,npz
                do j=jsc,jec
                   do i=isc,iec
                      mm = (Atm(n)%q(i,j,k,Cl)+2.*Atm(n)%q(i,j,k,Cl2))*Atm(n)%delp(i,j,k) ! moist mass
                      a2(i,j) = a2(i,j) + mm
                      qm = qm + mm*Atm(n)%gridstruct%area_64(i,j)
                   enddo
                enddo
             enddo
             !Convert to mean mixing ratio
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) / var2(i,j)
             enddo
             enddo
             used = send_data(id_acly, a2, Time)
             do j=jsc,jec
                do i=isc,iec
                   e2 = e2 + ((a2(i,j) - qcly0)**2)*Atm(n)%gridstruct%area_64(i,j)
                   einf = max(einf, abs(a2(i,j) - qcly0))
                enddo
             enddo
             if (prt_minmax .and. .not. Atm(n)%gridstruct%bounded_domain .and. user_prt_level >= PRT_LEVEL_2) then
                call mp_reduce_sum(qm)
                call mp_reduce_max(einf)
                call mp_reduce_sum(e2)
                if (master) then
                   write(*,'(2x, A)') ' TERMINATOR TEST: '
                   write(*,'(2x, A, G20.8)') '      chlorine mass: ', qm/(4.*pi*RADIUS*RADIUS)
                   write(*,'(2x, A, G20.8)') '             L2 err: ', sqrt(e2)/sqrt(4.*pi*RADIUS*RADIUS)/qcly0
                   write(*,'(2x, A, G20.8)') '            max err: ', einf/qcly0
                endif
             endif
          endif

          deallocate(var2)

       endif

       if ( id_iw>0 ) then
          a2 = 0.
          if (ice_wat > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%delp(i,j,k) *       &
                                    Atm(n)%q(i,j,k,ice_wat)
             enddo
             enddo
             enddo
          endif
          if (snowwat > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%delp(i,j,k) *      &
                                    Atm(n)%q(i,j,k,snowwat)
             enddo
             enddo
             enddo
          endif
          if (graupel > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%delp(i,j,k) *      &
                                    Atm(n)%q(i,j,k,graupel)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_iw, a2*ginv, Time)
       endif
       if ( id_lw>0 ) then
          a2 = 0.
          if (liq_wat > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,liq_wat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          if (rainwat > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,rainwat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_lw, a2*ginv, Time)
       endif

!--------------------------
! Vertically integrated tracers for GFDL MP
!--------------------------
       if ( id_intqv>0 ) then
          a2 = 0.
          if (sphum > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,sphum)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_intqv, a2*ginv, Time)
       endif
       if ( id_intql>0 ) then
          a2 = 0.
          if (liq_wat > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,liq_wat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_intql, a2*ginv, Time)
       endif
       if ( id_intqi>0 ) then
          a2 = 0.
          if (ice_wat > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,ice_wat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_intqi, a2*ginv, Time)
       endif
       if ( id_intqr>0 ) then
          a2 = 0.
          if (rainwat > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,rainwat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_intqr, a2*ginv, Time)
       endif
       if ( id_intqs>0 ) then
          a2 = 0.
          if (snowwat > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,snowwat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_intqs, a2*ginv, Time)
       endif
       if ( id_intqg>0 ) then
          a2 = 0.
          if (graupel > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%q(i,j,k,graupel)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_intqg, a2*ginv, Time)
       endif

! Cloud top temperature & cloud top press:
       if ( (id_ctt>0 .or. id_ctp>0 .or. id_ctz>0).and. Atm(n)%flagstruct%nwat==6) then
            allocate ( var1(isc:iec,jsc:jec) )
            allocate ( var2(isc:iec,jsc:jec) )
!$OMP parallel do default(shared) private(tmp)
            do j=jsc,jec
               do i=isc,iec
                  do k=2,npz
                     tmp = atm(n)%q(i,j,k,liq_wat)+atm(n)%q(i,j,k,rainwat)+atm(n)%q(i,j,k,ice_wat)+  &
                           atm(n)%q(i,j,k,snowwat)+atm(n)%q(i,j,k,graupel)
                     if( tmp>5.e-6 ) then
                         a2(i,j) = Atm(n)%pt(i,j,k)
                         var1(i,j) = 0.01*Atm(n)%pe(i,k,j)
                         var2(i,j) = wz(i,j,k) - wz(i,j,npz+1) ! height AGL
                         exit
                     elseif( k==npz ) then
                        a2(i,j) = missing_value3
                        var1(i,j) = missing_value3
                        var2(i,j) = missing_value2
                     endif
                  enddo
               enddo
            enddo
          if ( id_ctt>0 ) then
               used = send_data(id_ctt, a2, Time)
               if(prt_minmax) call prt_mxm('Cloud_top_T (K)', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
          endif
          if ( id_ctp>0 ) then
               used = send_data(id_ctp, var1, Time)
               if(prt_minmax) call prt_mxm('Cloud_top_P (mb)', var1, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
          endif
          deallocate ( var1 )
          if ( id_ctz>0 ) then
               used = send_data(id_ctz, var2, Time)
               if(prt_minmax) call prt_mxm('Cloud_top_Z (m)', var2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
          endif
          deallocate ( var2 )
       endif

! Condensates:
       if ( id_qn>0 .or. id_qn200>0 .or. id_qn500>0 .or. id_qn850>0 ) then
!$OMP parallel do default(shared)
          do k=1,npz
          do j=jsc,jec
          do i=isc,iec
             wk(i,j,k) = 0.
          enddo
          enddo
          enddo
          if (liq_wat > 0) then
!$OMP parallel do default(shared)
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                wk(i,j,k) = wk(i,j,k) + Atm(n)%q(i,j,k,liq_wat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          if (ice_wat > 0) then
!$OMP parallel do default(shared)
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                wk(i,j,k) = wk(i,j,k) + Atm(n)%q(i,j,k,ice_wat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          if ( id_qn>0 ) used = send_data(id_qn, wk, Time)
          if ( id_qn200>0 ) then
            call interpolate_vertical(isc, iec, jsc, jec, npz, 200.e2, Atm(n)%peln, wk, a2)
            used=send_data(id_qn200, a2, Time)
          endif
          if ( id_qn500>0 ) then
            call interpolate_vertical(isc, iec, jsc, jec, npz, 500.e2, Atm(n)%peln, wk, a2)
            used=send_data(id_qn500, a2, Time)
          endif
          if ( id_qn850>0 ) then
            call interpolate_vertical(isc, iec, jsc, jec, npz, 850.e2, Atm(n)%peln, wk, a2)
            used=send_data(id_qn850, a2, Time)
          endif
       endif
! Total 3D condensates
       if ( id_qp>0 ) then
!$OMP parallel do default(shared)
          do k=1,npz
          do j=jsc,jec
          do i=isc,iec
             wk(i,j,k) = 0.
          enddo
          enddo
          enddo
          if (rainwat > 0) then
!$OMP parallel do default(shared)
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                wk(i,j,k) = wk(i,j,k) + Atm(n)%q(i,j,k,rainwat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          if (snowwat > 0) then
!$OMP parallel do default(shared)
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                wk(i,j,k) = wk(i,j,k) + Atm(n)%q(i,j,k,snowwat)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          if (graupel > 0) then
!$OMP parallel do default(shared)
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                wk(i,j,k) = wk(i,j,k) + Atm(n)%q(i,j,k,graupel)*Atm(n)%delp(i,j,k)
             enddo
             enddo
             enddo
          endif
          used = send_data(id_qp, wk, Time)
       endif

       if(id_us > 0 .and. id_vs > 0) then
          u2(:,:) = Atm(n)%ua(isc:iec,jsc:jec,npz)
          v2(:,:) = Atm(n)%va(isc:iec,jsc:jec,npz)
          do j=jsc,jec
             do i=isc,iec
                a2(i,j) = sqrt(u2(i,j)**2 + v2(i,j)**2)
             enddo
          enddo
          used=send_data(id_us, u2, Time)
          used=send_data(id_vs, v2, Time)
          if(prt_minmax) call prt_mxm('Surf_Wind_Speed (m/s)', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
       endif

       if(id_tb > 0) then
          a2(:,:) = Atm(n)%pt(isc:iec,jsc:jec,npz)
          used=send_data(id_tb, a2, Time)
          if( prt_minmax )   &
          call prt_mxm('T_Bottom (K)', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
       endif

       if(id_ua > 0) used=send_data(id_ua, Atm(n)%ua(isc:iec,jsc:jec,:), Time)
       if(id_va > 0) used=send_data(id_va, Atm(n)%va(isc:iec,jsc:jec,:), Time)

       if(id_ke > 0) then
          a2(:,:) = 0.
          do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a2(i,j) = a2(i,j) + Atm(n)%delp(i,j,k)*(Atm(n)%ua(i,j,k)**2+Atm(n)%va(i,j,k)**2)
             enddo
          enddo
          enddo
! Mass weighted KE
          do j=jsc,jec
             do i=isc,iec
                a2(i,j) = 0.5*a2(i,j)/(Atm(n)%ps(i,j)-ptop)
             enddo
          enddo
          used=send_data(id_ke, a2, Time)
          if(prt_minmax) then
             tot_mq  = g_sum( Atm(n)%domain, a2, isc, iec, jsc, jec, ngc, Atm(n)%gridstruct%area_64, 1)
             if (master .and. user_prt_level >= PRT_LEVEL_3) write(*,*) 'SQRT(2.*KE; m/s)=', sqrt(2.*tot_mq)
          endif
       endif

#ifdef GFS_PHYS
       if(id_delp > 0 .or. id_cape > 0 .or. id_cin > 0 .or. &
            ((.not. Atm(n)%flagstruct%hydrostatic) .and. (id_pfnh > 0 .or. id_ppnh > 0)) .or. &
            id_brn > 0 .or. id_shear06 > 0) then
          do k=1,npz
            do j=jsc,jec
            do i=isc,iec
              wk(i,j,k) = Atm(n)%delp(i,j,k)*(1.-sum(Atm(n)%q(i,j,k,2:Atm(n)%flagstruct%nwat)))
            enddo
            enddo
          enddo
          if (id_delp > 0) used=send_data(id_delp, wk, Time)
       endif
       if(id_delp_total > 0) used=send_data(id_delp_total, Atm(n)%delp(isc:iec,jsc:jec,:), Time)
#else
       if(id_delp > 0) used=send_data(id_delp, Atm(n)%delp(isc:iec,jsc:jec,:), Time)
#endif

       !!! Compute pressure and variables requiring pressure (CAPE, CIN, BRN; latter needs shear06 too)

       if ( id_pfnh > 0 .or. id_ppnh > 0 .or. &
            id_cape > 0 .or. id_cin > 0  .or. &
            id_brn > 0  .or. id_shear06 > 0 ) then

          allocate(a3(isc:iec,jsc:jec,npz))

          if (Atm(n)%flagstruct%hydrostatic .or. id_pfhy > 0) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
#ifdef GFS_PHYS
                wk(i,j,k) = 0.5 *(Atm(n)%pe(i,k,j)+Atm(n)%pe(i,k+1,j))
#else
                wk(i,j,k) = Atm(n)%delp(i,j,k)/(Atm(n)%peln(i,k+1,j)-Atm(n)%peln(i,k,j))
#endif
             enddo
             enddo
             enddo
             used=send_data(id_pfhy, wk, Time)
          endif


          if ( .not. Atm(n)%flagstruct%hydrostatic ) then
             do k=1,npz
             do j=jsc,jec
             do i=isc,iec
#ifdef GFS_PHYS
                wk(i,j,k) = -wk(i,j,k)/(Atm(n)%delz(i,j,k)*grav)*rdgas*          &
                     Atm(n)%pt(i,j,k)*(1.+zvir*Atm(n)%q(i,j,k,sphum))
#else
                 wk(i,j,k) = -Atm(n)%delp(i,j,k)/(Atm(n)%delz(i,j,k)*grav)*rdgas*          &
                              Atm(n)%pt(i,j,k)*(1.+zvir*Atm(n)%q(i,j,k,sphum))

#endif
             enddo
             enddo
             enddo
             used=send_data(id_pfnh, wk, Time)
             if (prt_minmax) then
                call prt_mxm(' PFNH (mb)', wk(isc:iec,jsc:jec,1), isc, iec, jsc, jec, 0, npz, 1.E-2, Atm(n)%gridstruct%area_64, Atm(n)%domain, PRT_LEVEL_3)
             endif

             if (id_ppnh > 0) then
                do k=1,npz
                do j=jsc,jec
                do i=isc,iec
#ifdef GFS_PHYS
                   wk(i,j,k) = wk(i,j,k)/(1.-sum(Atm(n)%q(i,j,k,2:Atm(n)%flagstruct%nwat))) !Correction for moist mass
#endif
                   tmp = Atm(n)%delp(i,j,k)/(Atm(n)%peln(i,k+1,j)-Atm(n)%peln(i,k,j))
                   a3(i,j,k) = wk(i,j,k) - tmp
               enddo
               enddo
               enddo
               used=send_data(id_ppnh, a3, Time)
            endif

         end if

         !TODO: ONLY defined for non-hydrostatic for now; requires hydrostatic re-calculation of delz -- lmh 15 feb 24
         if (id_cape > 0 .or. id_cin > 0 .or. id_brn > 0 .or. id_shear06 > 0) then
          !wk here contains layer-mean pressure

            if (Atm(n)%flagstruct%hydrostatic) then
               call mpp_error(NOTE, " CAPE, CIN, BRN, shear06 currently not implemented for hydrostatic dynamics.")
            else

              allocate(var2(isc:iec,jsc:jec))

              call eqv_pot(a3, Atm(n)%pt, Atm(n)%delp, Atm(n)%delz, Atm(n)%peln, Atm(n)%pkz, Atm(n)%q(isd,jsd,1,sphum),    &
                   isc, iec, jsc, jec, ngc, npz, Atm(n)%flagstruct%hydrostatic, Atm(n)%flagstruct%moist_phys)

!$OMP parallel do default(shared)
              do j=jsc,jec
              do i=isc,iec
                 a2(i,j) = 0.
                 var2(i,j) = 0.

                 call getcape(npz, wk(i,j,:), Atm(n)%pt(i,j,:), -Atm(n)%delz(i,j,:), Atm(n)%q(i,j,:,sphum), a3(i,j,:), a2(i,j), var2(i,j), source_in=1)
              enddo
              enddo

              if (id_cape > 0) then
                 if (prt_minmax) then
                    call prt_mxm('CAPE (J/kg)', a2, isc,iec,jsc,jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
                 endif
                 used=send_data(id_cape, a2, Time)
              endif
              if (id_cin > 0) then
                 if (prt_minmax) then
                    call prt_mxm('CIN (J/kg)', var2, isc,iec,jsc,jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
                 endif
                 used=send_data(id_cin, var2, Time)
              endif

              if (id_brn > 0 .or. id_shear06 > 0) then
                 call compute_brn(Atm(n)%ua,Atm(n)%va,Atm(n)%delp,Atm(n)%delz,a2,Atm(n)%bd,npz,Time)
              endif

              deallocate(var2)
           endif

       endif
       deallocate(a3)
    endif

    if((.not. Atm(n)%flagstruct%hydrostatic) .and. id_delz > 0) then
       do k=1,npz
       do j=jsc,jec
       do i=isc,iec
          wk(i,j,k) = -Atm(n)%delz(i,j,k)
       enddo
       enddo
       enddo
       used=send_data(id_delz, wk, Time)
    endif


! pressure for masking p-level fields
! incorrectly defines a2 to be ps (in mb).
       if (id_pmask>0) then
            do j=jsc,jec
            do i=isc,iec
                a2(i,j) = exp((Atm(n)%peln(i,npz+1,j)+Atm(n)%peln(i,npz+1,j))*0.5)*0.01
               !a2(i,j) = Atm(n)%delp(i,j,k)/(Atm(n)%peln(i,k+1,j)-Atm(n)%peln(i,k,j))*0.01
            enddo
            enddo
            used=send_data(id_pmask, a2, Time)
       endif
! fix for pressure for masking p-level fields
! based on lowest-level pfull
! define pressure at lowest level the same as interpolate_vertical (in mb)
       if (id_pmaskv2>0) then
            do j=jsc,jec
            do i=isc,iec
                a2(i,j) = exp((Atm(n)%peln(i,npz,j)+Atm(n)%peln(i,npz+1,j))*0.5)*0.01
            enddo
            enddo
            used=send_data(id_pmaskv2, a2, Time)
       endif

       if ( id_u100m>0 .or. id_v100m>0 .or. id_wind100m>0 .or.  id_w100m>0 .or. id_w5km>0 .or. id_w2500m>0 &
            & .or. id_w1km>0 .or. id_basedbz>0 .or. id_dbz4km>0 .or. id_40dbzht>0) then
          if (.not.allocated(wz)) allocate ( wz(isc:iec,jsc:jec,npz+1) )
          if ( Atm(n)%flagstruct%hydrostatic) then
             rgrav = 1. / grav
!$OMP parallel do default(none) shared(isc,iec,jsc,jec,wz,npz,Atm,n,rgrav)
            do j=jsc,jec
               do i=isc,iec
                  wz(i,j,npz+1) = 0.
!                  wz(i,j,npz+1) = Atm(n)%phis(i,j)/grav
               enddo
               do k=npz,1,-1
                  do i=isc,iec
                     wz(i,j,k) = wz(i,j,k+1) - (rdgas*rgrav)*Atm(n)%pt(i,j,k)*(Atm(n)%peln(i,k,j) - Atm(n)%peln(i,k+1,j))
                  enddo
               enddo
            enddo
          else
!$OMP parallel do default(none) shared(isc,iec,jsc,jec,wz,npz,Atm,n)
            do j=jsc,jec
               do i=isc,iec
                  wz(i,j,npz+1) = 0.
!                  wz(i,j,npz+1) = Atm(n)%phis(i,j)/grav
               enddo
               do k=npz,1,-1
                  do i=isc,iec
                     wz(i,j,k) = wz(i,j,k+1) - Atm(n)%delz(i,j,k)
                  enddo
               enddo
            enddo
         endif
       endif

       if ( id_rain5km>0 ) then
            rainwat = get_tracer_index (MODEL_ATMOS, 'rainwat')
            call interpolate_z(isc, iec, jsc, jec, npz, 5.e3, wz, Atm(n)%q(isc:iec,jsc:jec,:,rainwat), a2)
            used=send_data(id_rain5km, a2, Time)
            if(prt_minmax) call prt_mxm('rain5km', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
       endif
       if ( id_w5km>0 ) then
            call interpolate_z(isc, iec, jsc, jec, npz, 5.e3, wz, Atm(n)%w(isc:iec,jsc:jec,:), a2)
            used=send_data(id_w5km, a2, Time)
            if(prt_minmax) call prt_mxm('W5km', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
       endif
       if ( id_w2500m>0 ) then
            call interpolate_z(isc, iec, jsc, jec, npz, 2.5e3, wz, Atm(n)%w(isc:iec,jsc:jec,:), a2)
            used=send_data(id_w2500m, a2, Time)
            if(prt_minmax) call prt_mxm('W2500m', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
       endif
       if ( id_w1km>0 ) then
            call interpolate_z(isc, iec, jsc, jec, npz, 1.e3, wz, Atm(n)%w(isc:iec,jsc:jec,:), a2)
            used=send_data(id_w1km, a2, Time)
            if(prt_minmax) call prt_mxm('W1km', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
       endif
       if ( id_w100m>0 ) then
            call interpolate_z(isc, iec, jsc, jec, npz, 100., wz, Atm(n)%w(isc:iec,jsc:jec,:), a2)
            used=send_data(id_w100m, a2, Time)
            if(prt_minmax) call prt_mxm('w100m', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
       endif

       if ( id_u100m>0 .or. id_wind100m>0 ) then
            call interpolate_z(isc, iec, jsc, jec, npz, 100., wz, Atm(n)%ua(isc:iec,jsc:jec,:), u2)
            if (id_u100m>0) then
               used=send_data(id_u100m, u2, Time)
               if(prt_minmax) call prt_mxm('u100m', u2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
            endif
       endif
       if ( id_v100m>0 .or. id_wind100m>0 ) then
            call interpolate_z(isc, iec, jsc, jec, npz, 100., wz, Atm(n)%va(isc:iec,jsc:jec,:), v2)
            if (id_v100m > 0) then
               used=send_data(id_v100m, v2, Time)
               if(prt_minmax) call prt_mxm('v100m', v2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
            endif
       endif
       if ( id_wind100m > 0) then
          do j=jsc,jec
             do i=isc,iec
                a2(i,j) = sqrt(u2(i,j)**2 + v2(i,j)**2)
             enddo
          enddo
          used=send_data(id_wind100m, a2, Time)
          if(prt_minmax) call prt_mxm('wind100m', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
       endif

       if ( rainwat > 0 .and. (id_dbz>0 .or. id_maxdbz>0 .or. id_basedbz>0 .or. id_dbz4km>0 &
            & .or. id_dbztop>0 .or. id_dbz_m10C>0 .or. id_40dbzht>0)) then

          if (.not. allocated(a3)) allocate(a3(isc:iec,jsc:jec,npz))

!          call dbzcalc_smithxue(Atm(n)%q, Atm(n)%pt, Atm(n)%delp, Atm(n)%peln, Atm(n)%delz, &
          call rad_ref(Atm(n)%bd%is, Atm(n)%bd%ie, Atm(n)%bd%js, Atm(n)%bd%je, &
               Atm(n)%bd%isd, Atm(n)%bd%ied, Atm(n)%bd%jsd, Atm(n)%bd%jed, &
               Atm(n)%q, Atm(n)%pt, Atm(n)%delp, Atm(n)%peln, Atm(n)%delz, &
               a3, a2, allmax, npz, Atm(n)%ncnst, Atm(n)%flagstruct%hydrostatic, &
               zvir, Atm(n)%flagstruct%do_inline_mp, &
               sphum, liq_wat, ice_wat, rainwat, snowwat, graupel, mp_top) ! GFDL MP has constant N_0 intercept

          if (id_dbz > 0) used=send_data(id_dbz, a3, time)
          if (id_maxdbz > 0) used=send_data(id_maxdbz, a2, time)

          if (id_basedbz > 0) then
             !interpolate to 1km dbz
             call cs_interpolator(isc, iec, jsc, jec, npz, a3, 1000., wz, a2, -20.)
             used=send_data(id_basedbz, a2, time)
             if(prt_minmax) call prt_mxm('Base_dBz', a2, isc, iec, jsc, jec, 0, 1, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
          endif

          if (id_dbz4km > 0) then
             !interpolate to 1km dbz
             call cs_interpolator(isc, iec, jsc, jec, npz, a3, 4000., wz, a2, -20.)
             used=send_data(id_dbz4km, a2, time)
          endif
          if (id_dbztop > 0) then
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = missing_value2
             do k=2,npz
                if (wz(i,j,k) >= 25000. ) cycle ! nothing above 25 km
                if (a3(i,j,k) >= 18.5 ) then
                   a2(i,j) = wz(i,j,k)
                   exit
                endif
             enddo
             enddo
             enddo
             used=send_data(id_dbztop, a2, time)
          endif
          if (id_dbz_m10C > 0) then
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = missing_value
             do k=npz,1,-1
                if (wz(i,j,k) >= 25000. ) exit ! nothing above 25 km
                if (Atm(n)%pt(i,j,k) <= 263.14 ) then
                   a2(i,j) = a3(i,j,k)
                   exit
                endif
             enddo
             enddo
             enddo
             used=send_data(id_dbz_m10C, a2, time)
          endif
          if (id_40dbzht > 0) then
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) = missing_value
             do k=1,npz
                if (wz(i,j,k) >= 25000.) cycle
                if (a3(i,j,k) >= 40.) then
                   a2(i,j) = wz(i,j,k)
                   exit
                endif
             enddo
             enddo
             enddo
             used=send_data(id_40dbzht, a2, time)
          endif

          if (prt_minmax .and. user_prt_level >= PRT_LEVEL_1) then
             call mpp_max(allmax)
             if (master) write(*,'(2x, A16, G20.8, A4)') 'max reflectivity = ', allmax, ' dBZ'
          endif

          deallocate(a3)
       endif

!-------------------------------------------------------
! Applying cubic-spline as the intepolator for (u,v,T,q)
!-------------------------------------------------------
! u-winds:
       call make_plevs( Atm(n)%ua(isc:iec,jsc:jec,:), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, -1, id_u_plev, id_u_levs, nplev, Atm(n)%bd, Time)

! v-winds:
       call make_plevs( Atm(n)%va(isc:iec,jsc:jec,:), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, -1, id_v_plev, id_v_levs, nplev, Atm(n)%bd, Time)

! Specific humidity
       call make_plevs( Atm(n)%q(isc:iec,jsc:jec,:,sphum), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, 0, id_q_plev, id_q_levs, nplev, Atm(n)%bd, Time)

! cloud water mass mixing ratio
!NOTE: Can set this up for *ANY* tracers

       if (liq_wat > 0) call make_plevs( Atm(n)%q(isc:iec,jsc:jec,:,liq_wat), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, 0, id_ql_plev, id_ql_levs, nplev, Atm(n)%bd, Time)

       if (ice_wat > 0) call make_plevs( Atm(n)%q(isc:iec,jsc:jec,:,ice_wat), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, 0, id_qi_plev, id_qi_levs, nplev, Atm(n)%bd, Time)

       if (rainwat > 0) call make_plevs( Atm(n)%q(isc:iec,jsc:jec,:,rainwat), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, 0, id_qr_plev, id_qr_levs, nplev, Atm(n)%bd, Time)

       if (snowwat > 0) call make_plevs( Atm(n)%q(isc:iec,jsc:jec,:,snowwat), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, 0, id_qs_plev, id_qs_levs, nplev, Atm(n)%bd, Time)

       if (graupel > 0) call make_plevs( Atm(n)%q(isc:iec,jsc:jec,:,graupel), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, 0, id_qg_plev, id_qg_levs, nplev, Atm(n)%bd, Time)

! cloud fraction
       if (cld_amt > 0) call make_plevs( Atm(n)%q(isc:iec,jsc:jec,:,cld_amt), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, 0, id_cf_plev, id_cf_levs, nplev, Atm(n)%bd, Time)

! Omega
       call make_plevs( Atm(n)%omga(isc:iec,jsc:jec,:), plevs, Atm(n)%pe(isc:iec,1:npz+1,jsc:jec), &
                        npz, -1, id_omg_plev, id_omg_levs, nplev, Atm(n)%bd, Time)

       !!! BEGIN LAYER-AVERAGED DIAGNOSTICS
       allocate(a3(isc:iec,jsc:jec,nplev_ave))
       if (allocated(a2)) deallocate(a2)
       allocate(a2(isc:iec,nplev_ave+1))

       !Use logp to interpolate temperature
       do k=1,nplev_ave+1
          a2(:,k) = log(real(levs_ave(k))*100.)
       enddo
       if ( id_t_plev_ave > 0) then
          do j=jsc,jec
             call mappm(npz, Atm(n)%peln(isc:iec,1:npz+1,j), Atm(n)%pt(isc:iec,j,:), nplev_ave, a2, a3(isc:iec,j,:), isc, iec, 1, 4)
          enddo
          if (id_t_plev_ave > 0) used=send_data(id_t_plev_ave, a3, Time)
       endif
       if ( id_t_dt_gfdlmp_plev_ave > 0 ) then
          do j=jsc,jec
             call mappm(npz, Atm(n)%peln(isc:iec,1:npz+1,j), Atm(n)%inline_mp%t_dt(isc:iec,j,:), nplev_ave, a2, a3(isc:iec,j,:), isc, iec, 1, 4)
          enddo
          if (id_t_dt_gfdlmp_plev_ave > 0) used=send_data(id_t_dt_gfdlmp_plev_ave, a3, Time)
       endif
       if ( id_t_dt_phys_plev_ave > 0 ) then
          do j=jsc,jec
             call mappm(npz, Atm(n)%peln(isc:iec,1:npz+1,j), Atm(n)%phys_diag%phys_t_dt(isc:iec,j,:), nplev_ave, a2, a3(isc:iec,j,:), isc, iec, 1, 4)
          enddo
          if (id_t_dt_phys_plev_ave > 0) used=send_data(id_t_dt_phys_plev_ave, a3, Time)
       endif

       !Using full pressure to interpolate other scalars
       do k=1,nplev_ave+1
          a2(:,k) = real(levs_ave(k))*100.
       enddo
       if ( id_q_plev_ave > 0 ) then
          do j=jsc,jec
             call mappm(npz, Atm(n)%pe(isc:iec,1:npz+1,j), Atm(n)%q(isc:iec,j,:,sphum), nplev_ave, a2, a3(isc:iec,j,:), isc, iec, 0, 8)
          enddo
          if (id_q_plev_ave > 0) used=send_data(id_q_plev_ave, a3, Time)
       endif
       if ( id_qv_dt_gfdlmp_plev_ave > 0 ) then
          do j=jsc,jec
             call mappm(npz, Atm(n)%pe(isc:iec,1:npz+1,j), Atm(n)%inline_mp%qv_dt(isc:iec,j,:), nplev_ave, a2, a3(isc:iec,j,:), isc, iec, 0, 8)
          enddo
          if (id_qv_dt_gfdlmp_plev_ave > 0) used=send_data(id_qv_dt_gfdlmp_plev_ave, a3, Time)
       endif
       if ( id_qv_dt_phys_plev_ave > 0 ) then
          do j=jsc,jec
             call mappm(npz, Atm(n)%pe(isc:iec,1:npz+1,j), Atm(n)%phys_diag%phys_qv_dt(isc:iec,j,:), nplev_ave, a2, a3(isc:iec,j,:), isc, iec, 0, 8)
          enddo
          if (id_qv_dt_phys_plev_ave > 0) used=send_data(id_qv_dt_phys_plev_ave, a3, Time)
       endif


       deallocate(a2)
       deallocate(a3)
       !!! END LAYER AVERAGED DIAGNOSTICS

       if (allocated(a2)) deallocate(a2)
       allocate ( a2(isc:iec,jsc:jec) )

       if ( id_sl12>0 ) then   ! 13th level wind speed (~ 222 mb for the 32L setup)
            do j=jsc,jec
               do i=isc,iec
                  a2(i,j) = sqrt(Atm(n)%ua(i,j,12)**2 + Atm(n)%va(i,j,12)**2)
               enddo
            enddo
            used=send_data(id_sl12, a2, Time)
       endif
       if ( id_sl13>0 ) then   ! 13th level wind speed (~ 222 mb for the 32L setup)
            do j=jsc,jec
               do i=isc,iec
                  a2(i,j) = sqrt(Atm(n)%ua(i,j,13)**2 + Atm(n)%va(i,j,13)**2)
               enddo
            enddo
            used=send_data(id_sl13, a2, Time)
       endif

       if ( .not. Atm(n)%flagstruct%hydrostatic ) then
          call make_plevs( Atm(n)%w(isc:iec,jsc:jec,:), plevs_ln, Atm(n)%peln(isc:iec,1:npz+1,jsc:jec), &
                           npz, -1, id_w_plev, id_w_levs, nplev, Atm(n)%bd, Time)
       endif


       if ( (.not.Atm(n)%flagstruct%hydrostatic) .and. id_x850>0) then
            call interpolate_vertical(isc, iec, jsc, jec, npz,   &
                                      850.e2, Atm(n)%peln, Atm(n)%w(isc:iec,jsc:jec,:), a2)

            x850(:,:) = x850(:,:)*a2(:,:)
            used=send_data(id_x850, x850, Time)
            deallocate ( x850 )
       endif


       if ( .not.Atm(n)%flagstruct%hydrostatic .and. id_w>0  ) then
          used=send_data(id_w, Atm(n)%w(isc:iec,jsc:jec,:), Time)
       endif
       if ( .not. Atm(n)%flagstruct%hydrostatic .and. (id_wmaxup>0 .or. id_wmaxdn>0) ) then
          allocate(var2(isc:iec,jsc:jec))
          do j=jsc,jec
          do i=isc,iec
             a2(i,j) = 0.
             var2(i,j) = 0.
             do k=3,npz
                if (Atm(n)%pe(i,k,j) <= 100.e2) continue ! lmh 10apr2020: changed to current SPC standard
                a2(i,j) = max(a2(i,j),Atm(n)%w(i,j,k))
                var2(i,j) = min(var2(i,j),Atm(n)%w(i,j,k))
             enddo
          enddo
          enddo
          if (id_wmaxup > 0) then
             used=send_data(id_wmaxup, a2, Time)
          endif
          if (id_wmaxdn > 0) then
             used=send_data(id_wmaxdn, var2, Time)
          endif
          deallocate(var2)
       endif

       if(id_pt   > 0) used=send_data(id_pt  , Atm(n)%pt  (isc:iec,jsc:jec,:), Time)
       if(id_omga > 0) used=send_data(id_omga, Atm(n)%omga(isc:iec,jsc:jec,:), Time)
       if(id_diss > 0) used=send_data(id_diss, Atm(n)%diss_est(isc:iec,jsc:jec,:), Time)
       if(id_diss_heat > 0) used=send_data(id_diss_heat, Atm(n)%heat_source(isc:iec,jsc:jec,:), Time)

       allocate( a3(isc:iec,jsc:jec,npz) )
       if(id_theta_e > 0 .or. ANY(id_theta_e_levs > 0) .or. id_theta_e_plev > 0) then
          if ( Atm(n)%flagstruct%adiabatic .and. Atm(n)%flagstruct%kord_tm>0 ) then
             do k=1,npz
                do j=jsc,jec
                   do i=isc,iec
                      a3(i,j,k) = Atm(n)%pt(i,j,k)
                   enddo
                enddo
             enddo
          else
             call eqv_pot(a3, Atm(n)%pt, Atm(n)%delp, Atm(n)%delz, Atm(n)%peln, Atm(n)%pkz, Atm(n)%q(isd,jsd,1,sphum),    &
                  isc, iec, jsc, jec, ngc, npz, Atm(n)%flagstruct%hydrostatic, Atm(n)%flagstruct%moist_phys)
          endif

          call make_plevs( a3, plevs_ln, Atm(n)%peln(isc:iec,1:npz+1,jsc:jec), &
               npz, 1, id_theta_e_plev, id_theta_e_levs, nplev, Atm(n)%bd, Time)

          if (id_theta_e > 0) then
             if( prt_minmax ) call prt_mxm('Theta_E', a3, isc, iec, jsc, jec, 0, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
             used=send_data(id_theta_e, a3, Time)
          end if
          theta_d = get_tracer_index (MODEL_ATMOS, 'theta_d')
          if ( theta_d>0 ) then
             if( prt_minmax ) then
                ! Check level-34 ~ 300 mb
                a2(:,:) = 0.
                do k=1,npz
                do j=jsc,jec
                do i=isc,iec
                   a2(i,j) = a2(i,j) + Atm(n)%delp(i,j,k)*(Atm(n)%q(i,j,k,theta_d)-a3(i,j,k))**2
                enddo
                enddo
                enddo
                call prt_mxm('PT_SUM', a2, isc, iec, jsc, jec, 0, 1, 1.e-5, Atm(n)%gridstruct%area_64, Atm(n)%domain)

                do k=1,npz
                do j=jsc,jec
                do i=isc,iec
                   a3(i,j,k) =  Atm(n)%q(i,j,k,theta_d)/a3(i,j,k) - 1.
                enddo
                enddo
                enddo
                call prt_mxm('Theta_Err (%)', a3, isc, iec, jsc, jec, 0, npz, 100., Atm(n)%gridstruct%area_64, Atm(n)%domain)
                !           if ( master ) write(*,*) 'PK0=', pk0, 'KAPPA=', kappa
             endif
          endif

       endif

       if(id_ppt> 0 .or. ANY(id_theta_levs>0) .or. id_theta_plev>0) then
! Potential temperature perturbation for gravity wave test_case
          allocate ( pt1(npz) )
          if( .not. allocated(a3) ) allocate ( a3(isc:iec,jsc:jec,npz) )
#ifdef TEST_GWAVES
          call gw_1d(npz, 1000.E2, Atm(n)%ak, Atm(n)%ak, Atm(n)%ak(1), 10.E3, pt1)
#else
          pt1 = 0.
#endif
          if (.not. Atm(n)%flagstruct%hydrostatic) then
           do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                wk(i,j,k) =  (Atm(n)%pt(i,j,k)*exp(-kappa*log(-Atm(n)%delp(i,j,k)/(Atm(n)%delz(i,j,k)*grav)*rdgas*          &
                      Atm(n)%pt(i,j,k)*(1.+zvir*Atm(n)%q(i,j,k,sphum)))) - pt1(k)) * pk0
!                 Atm(n)%pkz(i,j,k) = exp(kappa*log(-Atm(n)%delp(i,j,k)/(Atm(n)%delz(i,j,k)*grav)*rdgas*          &
!                      Atm(n)%pt(i,j,k)*(1.+zvir*Atm(n)%q(i,j,k,sphum))))
             enddo
             enddo
           enddo
          else
          do k=1,npz
          do j=jsc,jec
             do i=isc,iec
!               wk(i,j,k) =  (Atm(n)%pt(i,j,k)-300.)/Atm(n)%pkz(i,j,k) * pk0
                wk(i,j,k) =  (Atm(n)%pt(i,j,k)/Atm(n)%pkz(i,j,k) - pt1(k)) * pk0
             enddo
          enddo
          enddo
          endif
          if (id_ppt > 0) then
             used=send_data(id_ppt, wk, Time)

             if( prt_minmax ) then
                call prt_mxm('PoTemp', wk, isc, iec, jsc, jec, 0, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
             endif
          endif

          call make_plevs( wk, plevs_ln, Atm(n)%peln(isc:iec,1:npz+1,jsc:jec), &
                           npz, 1, id_theta_plev, id_theta_levs, nplev, Atm(n)%bd, Time)

          if( allocated(a3) ) deallocate ( a3 )
          deallocate ( pt1 )
       endif

        do itrac=1, Atm(n)%ncnst
          call get_tracer_names (MODEL_ATMOS, itrac, tname)
          if (itrac.gt.nq) then
            used = send_data (id_tracer(itrac), Atm(n)%qdiag(isc:iec,jsc:jec,:,itrac), Time )
          else
            used = send_data (id_tracer(itrac), Atm(n)%q(isc:iec,jsc:jec,:,itrac), Time )
          endif
          if (itrac .le. nq) then
            if( prt_minmax ) call prt_mxm(trim(tname), Atm(n)%q(:,:,1,itrac),     &
                              isc, iec, jsc, jec, ngc, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
          else
            if( prt_minmax ) call prt_mxm(trim(tname), Atm(n)%qdiag(:,:,1,itrac), &
                              isc, iec, jsc, jec, ngc, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
          endif
!-------------------------------
! ESM TRACER diagnostics output:
! jgj: per SJ email (jul 17 2008): q_dry = q_moist/(1-sphum)
! mass mixing ratio: q_dry = mass_tracer/mass_dryair = mass_tracer/(mass_air - mass_water) ~ q_moist/(1-sphum)
! co2_mmr = (wco2/wair) * co2_vmr
! Note: There is a check to ensure tracer number one is sphum

!f1p: update diagnostics to account for all water tracers (nwat)
          if (id_tracer_dmmr(itrac) > 0 .or. id_tracer_dvmr(itrac) > 0) then
             if (.not. conv_vmr_mmr(itrac)) then
                if (itrac .gt. nq) then
                   dmmr(:,:,:) = Atm(n)%qdiag(isc:iec,jsc:jec,1:npz,itrac)  &
                        /(1.0-sum(Atm(n)%q(isc:iec,jsc:jec,1:npz,1:Atm(n)%flagstruct%nwat),dim=4))
                else
                   dmmr(:,:,:) = Atm(n)%q(isc:iec,jsc:jec,1:npz,itrac)  &
                        /(1.0-sum(Atm(n)%q(isc:iec,jsc:jec,1:npz,1:Atm(n)%flagstruct%nwat),dim=4))
                endif
                used = send_data (id_tracer_dmmr(itrac), dmmr, Time )
                if (w_mr(itrac).gt.0) then
                   dvmr(:,:,:) = dmmr(isc:iec,jsc:jec,1:npz) * WTMAIR/w_mr(itrac)
                   used = send_data (id_tracer_dvmr(itrac), dvmr, Time )
                end if
                if( prt_minmax ) then
                   call prt_mxm(trim(tname)//'_dmmr', dmmr, &
                        isc, iec, jsc, jec, 0, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
                   call prt_mxm(trim(tname)//'_dvmr', dvmr, &
                        isc, iec, jsc, jec, 0, npz, 1., Atm(n)%gridstruct%area_64, Atm(n)%domain)
                endif

                !send burden diagnositcs
                if  (itrac .gt. nq) then
                   used = send_data (id_tracer_burden(itrac),Atm(n)%qdiag(isc:iec,jsc:jec,1:npz,itrac) * Atm(n)%delp(isc:iec,jsc:jec,1:npz)/grav, Time ) !kg/m2
                else
                   used = send_data (id_tracer_burden(itrac),Atm(n)%q(isc:iec,jsc:jec,1:npz,itrac) * Atm(n)%delp(isc:iec,jsc:jec,1:npz)/grav, Time ) !kg/m2
                end if
             else
                ! now use Mw_air function for clarity
                if (itrac.gt.nq) then
                   dvmr(:,:,:) = Atm(n)%qdiag(isc:iec,jsc:jec,1:npz,itrac) * WTMAIR/(Mw_air(sum(Atm(n)%q(isc:iec,jsc:jec,1:npz,1:Atm(n)%flagstruct%nwat),dim=4))*(1-sum(Atm(n)%q(isc:iec,jsc:jec,1:npz,1:Atm(n)%flagstruct%nwat),dim=4)))
                else
                   dvmr(:,:,:) = Atm(n)%q(isc:iec,jsc:jec,1:npz,itrac) * WTMAIR/(Mw_air(sum(Atm(n)%q(isc:iec,jsc:jec,1:npz,1:Atm(n)%flagstruct%nwat),dim=4))*(1-sum(Atm(n)%q(isc:iec,jsc:jec,1:npz,1:Atm(n)%flagstruct%nwat),dim=4)))
                end if
                used = send_data (id_tracer_dvmr(itrac), dvmr, Time )

                !send burden diagnostics
                if (itrac.gt.nq) then
                   used = send_data (id_tracer_burden(itrac),Atm(n)%qdiag(isc:iec,jsc:jec,1:npz,itrac) * Atm(n)%delp(isc:iec,jsc:jec,1:npz)/grav / Mw_air(sum(Atm(n)%q(isc:iec,jsc:jec,1:npz,1:Atm(n)%flagstruct%nwat),dim=4)) * 1.e3, Time ) !mol/m2
                else
                   used = send_data (id_tracer_burden(itrac),Atm(n)%q(isc:iec,jsc:jec,1:npz,itrac) * Atm(n)%delp(isc:iec,jsc:jec,1:npz)/grav / Mw_air(sum(Atm(n)%q(isc:iec,jsc:jec,1:npz,1:Atm(n)%flagstruct%nwat),dim=4)) * 1.e3, Time ) !mol/m2
                end if
              end if
          endif
        enddo
!----------------------------------
! compute 3D flux terms
!----------------------------------
     allocate ( a4(isc:iec,jsc:jec,npz) )

     ! zonal moisture flux
     if(id_uq > 0) then
       do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a4(i,j,k) =  Atm(n)%ua(i,j,k) * Atm(n)%q(i,j,k,sphum)
             enddo
          enddo
       enddo
       used=send_data(id_uq, a4, Time)
       if(id_iuq > 0) then
         call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
         used=send_data(id_iuq, a2, Time)
       endif
     endif
    ! meridional moisture flux
     if(id_vq > 0) then
       do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a4(i,j,k) =  Atm(n)%va(i,j,k) * Atm(n)%q(i,j,k,sphum)
             enddo
          enddo
       enddo
       used=send_data(id_vq, a4, Time)
       if(id_ivq > 0) then
         call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
         used=send_data(id_ivq, a2, Time)
       endif
     endif

     ! zonal heat flux
     if(id_ut > 0) then
       do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a4(i,j,k) =  Atm(n)%ua(i,j,k) * Atm(n)%pt(i,j,k)
             enddo
          enddo
       enddo
       used=send_data(id_ut, a4, Time)
       if(id_iut > 0) then
         call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
         used=send_data(id_iut, a2, Time)
       endif
     endif
     ! meridional heat flux
     if(id_vt > 0) then
       do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a4(i,j,k) =  Atm(n)%va(i,j,k) * Atm(n)%pt(i,j,k)
             enddo
          enddo
       enddo
       used=send_data(id_vt, a4, Time)
       if(id_ivt > 0) then
         call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
         used=send_data(id_ivt, a2, Time)
       endif
     endif

     ! zonal flux of u
     if(id_uu > 0) then
       do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a4(i,j,k) =  Atm(n)%ua(i,j,k) * Atm(n)%ua(i,j,k)
             enddo
          enddo
       enddo
       used=send_data(id_uu, a4, Time)
       if(id_iuu > 0) then
         call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
         used=send_data(id_iuu, a2, Time)
       endif
     endif
     ! zonal flux of v
     if(id_uv > 0) then
       do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a4(i,j,k) =  Atm(n)%ua(i,j,k) * Atm(n)%va(i,j,k)
             enddo
          enddo
       enddo
       used=send_data(id_uv, a4, Time)
       if(id_iuv > 0) then
         call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
         used=send_data(id_iuv, a2, Time)
       endif
     endif
    ! meridional flux of v
     if(id_vv > 0) then
       do k=1,npz
          do j=jsc,jec
             do i=isc,iec
                a4(i,j,k) =  Atm(n)%va(i,j,k) * Atm(n)%va(i,j,k)
             enddo
          enddo
       enddo
       used=send_data(id_vv, a4, Time)
       if(id_ivv > 0) then
         call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
         used=send_data(id_ivv, a2, Time)
       endif
     endif

#ifndef SW_DYNAMICS
! terms related with vertical wind ( Atm(n)%w ):
     if(.not.Atm(n)%flagstruct%hydrostatic) then
       ! vertical moisture flux
       if(id_wq > 0 .or. id_iwq > 0) then
         do k=1,npz
            do j=jsc,jec
               do i=isc,iec
                  a4(i,j,k) =  Atm(n)%w(i,j,k) * Atm(n)%q(i,j,k,sphum)
               enddo
            enddo
         enddo
         if(id_wq > 0) used=send_data(id_wq, a4, Time)
         if(id_iwq > 0) then
           call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
           used=send_data(id_iwq, a2, Time)
         endif
       endif
       ! vertical heat flux
       if(id_wt > 0 .or. id_iwt > 0) then
         do k=1,npz
            do j=jsc,jec
               do i=isc,iec
                  a4(i,j,k) =  Atm(n)%w(i,j,k) * Atm(n)%pt(i,j,k)
               enddo
            enddo
         enddo
         if(id_wt > 0) used=send_data(id_wt, a4, Time)
         if(id_iwt > 0) then
           call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
           used=send_data(id_iwt, a2, Time)
         endif
       endif
      ! zonal flux of w
       if(id_uw > 0 .or. id_iuw > 0) then
         do k=1,npz
            do j=jsc,jec
               do i=isc,iec
                  a4(i,j,k) =  Atm(n)%ua(i,j,k) * Atm(n)%w(i,j,k)
               enddo
            enddo
         enddo
         if (id_uw > 0) used=send_data(id_uw, a4, Time)
         if(id_iuw > 0) then
           call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
           used=send_data(id_iuw, a2, Time)
         endif
       endif
       ! meridional flux of w
       if(id_vw > 0 .or. id_ivw > 0) then
         do k=1,npz
            do j=jsc,jec
               do i=isc,iec
                  a4(i,j,k) =  Atm(n)%va(i,j,k) * Atm(n)%w(i,j,k)
               enddo
            enddo
         enddo
         if (id_vw > 0) used=send_data(id_vw, a4, Time)
         if(id_ivw > 0) then
           call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
           used=send_data(id_ivw, a2, Time)
         endif
       endif
       ! vertical flux of w
       if(id_ww > 0 .or. id_iww > 0) then
         do k=1,npz
            do j=jsc,jec
               do i=isc,iec
                  a4(i,j,k) =  Atm(n)%w(i,j,k) * Atm(n)%w(i,j,k)
               enddo
            enddo
         enddo
         if (id_ww > 0) used=send_data(id_ww, a4, Time)
         if(id_iww > 0) then
           call z_sum(isc, iec, jsc, jec, npz, 0, Atm(n)%delp(isc:iec,jsc:jec,1:npz), a4, a2)
           used=send_data(id_iww, a2, Time)
         endif
       endif
     endif

     deallocate ( a4 )
#endif

! Maximum overlap cloud fraction
      if ( .not. Atm(n)%gridstruct%bounded_domain )  then
        if ( cld_amt > 0 .and. prt_minmax ) then
          a2(:,:) = 0.
          do k=1,npz
             do j=jsc,jec
             do i=isc,iec
                a2(i,j) =  max(a2(i,j), Atm(n)%q(i,j,k,cld_amt) )
             enddo
             enddo
          enddo
          call prt_gb_nh_sh('Max_cld',isc,iec, jsc,jec, a2, Atm(n)%gridstruct%area_64(isc:iec,jsc:jec),   &
                            Atm(n)%gridstruct%agrid_64(isc:iec,jsc:jec,2), PRT_LEVEL_1)
        endif
      endif


      if (do_diag_debug) then
         call debug_column(Atm(n)%pt, Atm(n)%delp, Atm(n)%delz, Atm(n)%u, Atm(n)%v, Atm(n)%w, Atm(n)%q, &
              Atm(n)%npz, Atm(n)%ncnst, sphum, Atm(n)%flagstruct%nwat, zvir, ptop, Atm(n)%flagstruct%hydrostatic, Atm(n)%bd, Time)
      endif

      if (prt_sounding) then
         if (allocated(a3)) deallocate(a3)
         allocate(a3(isc:iec,jsc:jec,npz))
         call eqv_pot(a3, Atm(n)%pt, Atm(n)%delp, Atm(n)%delz, Atm(n)%peln, Atm(n)%pkz, Atm(n)%q(isd,jsd,1,sphum),    &
              isc, iec, jsc, jec, ngc, npz, Atm(n)%flagstruct%hydrostatic, Atm(n)%flagstruct%moist_phys)
         call sounding_column(Atm(n)%pt, Atm(n)%delp, Atm(n)%delz, Atm(n)%u, Atm(n)%v, Atm(n)%q, Atm(n)%peln, Atm(n)%pkz, a3, Atm(n)%phis, &
              Atm(n)%npz, Atm(n)%ncnst, sphum, Atm(n)%flagstruct%nwat, Atm(n)%flagstruct%hydrostatic, zvir, Atm(n)%ng, Atm(n)%bd, Time)
         deallocate(a3)
      endif


   ! enddo  ! end ntileMe do-loop

    deallocate ( a2 )
    deallocate ( u2 )
    deallocate ( v2 )
    deallocate ( wk )

    if (allocated(a3)) deallocate(a3)
    if (allocated(wz)) deallocate(wz)
    if (allocated(dmmr)) deallocate(dmmr)
    if (allocated(dvmr)) deallocate(dvmr)

 end subroutine fv_diag

 subroutine wind_max(isc, iec, jsc, jec ,isd, ied, jsd, jed, us, vs, ws_max, domain)
 integer isc, iec, jsc, jec
 integer isd, ied, jsd, jed
 real, intent(in), dimension(isc:iec,jsc:jec):: us, vs
 real, intent(out) :: ws_max(isc:iec,jsc:jec)
 type(domain2d), intent(INOUT) :: domain
! Local
 real :: wx(isc:iec,jsd:jed), ws(isd:ied,jsd:jed)
 integer:: i,j

 ws = 0.   ! fill corners with zeros
 do j=jsc,jec
    do i=isc,iec
       ws(i,j) = sqrt(us(i,j)**2 + vs(i,j)**2)
    enddo
 enddo

 call mpp_update_domains( ws, domain )

 do j=jsd,jed
    do i=isc,iec
       wx(i,j) = max(ws(i-3,j), ws(i-2,j), ws(i-1,j), ws(i,j), ws(i+1,j), ws(i+2,j), ws(i+3,j))
    enddo
 enddo

 do j=jsc,jec
    do i=isc,iec
       ws_max(i,j) = max(wx(i,j-3), wx(i,j-2), wx(i,j-1), wx(i,j), wx(i,j+1), wx(i,j+2), wx(i,j+3))
    enddo
 enddo

 end subroutine wind_max


 subroutine get_vorticity(isc, iec, jsc, jec ,isd, ied, jsd, jed, npz, u, v, vort, dx, dy, rarea)
 integer isd, ied, jsd, jed, npz
 integer isc, iec, jsc, jec
 real, intent(in)  :: u(isd:ied, jsd:jed+1, npz), v(isd:ied+1, jsd:jed, npz)
 real, intent(out) :: vort(isc:iec, jsc:jec, npz)
 real, intent(IN) :: dx(isd:ied,jsd:jed+1)
 real, intent(IN) :: dy(isd:ied+1,jsd:jed)
 real, intent(IN) :: rarea(isd:ied,jsd:jed)
! Local
 real :: utmp(isc:iec, jsc:jec+1), vtmp(isc:iec+1, jsc:jec)
 integer :: i,j,k

      do k=1,npz
         do j=jsc,jec+1
            do i=isc,iec
               utmp(i,j) = u(i,j,k)*dx(i,j)
            enddo
         enddo
         do j=jsc,jec
            do i=isc,iec+1
               vtmp(i,j) = v(i,j,k)*dy(i,j)
            enddo
         enddo

         do j=jsc,jec
            do i=isc,iec
               vort(i,j,k) = rarea(i,j)*(utmp(i,j)-utmp(i,j+1)-vtmp(i,j)+vtmp(i+1,j))
            enddo
         enddo
      enddo

 end subroutine get_vorticity

 subroutine get_height_field(is, ie, js, je, ng, km, hydrostatic, delz, wz, pt, q, peln, zvir)
  integer, intent(in):: is, ie, js, je, km, ng
  real, intent(in):: peln(is:ie,km+1,js:je)
  real, intent(in):: pt(is-ng:ie+ng,js-ng:je+ng,km)
  real, intent(in)::  q(is-ng:ie+ng,js-ng:je+ng,km,*) ! water vapor
  real, intent(in):: delz(is:,js:,1:)
  real, intent(in):: zvir
  logical, intent(in):: hydrostatic
  real, intent(out):: wz(is:ie,js:je,km+1)
!
  integer i,j,k
  real gg

      gg  = rdgas * ginv

      do j=js,je
         do i=is,ie
            wz(i,j,km+1) = zsurf(i,j)
         enddo
      if (hydrostatic ) then
         do k=km,1,-1
            do i=is,ie
               wz(i,j,k) = wz(i,j,k+1) + gg*pt(i,j,k)*(1.+zvir*q(i,j,k,sphum))  &
                          *(peln(i,k+1,j)-peln(i,k,j))
            enddo
         enddo
      else
         do k=km,1,-1
            do i=is,ie
               wz(i,j,k) = wz(i,j,k+1)  - delz(i,j,k)
            enddo
         enddo
      endif
      enddo

 end subroutine get_height_field

 subroutine range_check_3d(qname, q, is, ie, js, je, n_g, km, pos, q_low, q_hi, bad_range, Time)
      character(len=*), intent(in)::  qname
      integer, intent(in):: is, ie, js, je
      integer, intent(in):: n_g, km
      real, intent(in)::    q(is-n_g:ie+n_g, js-n_g:je+n_g, km)
      real, intent(in):: pos(is-n_g:ie+n_g, js-n_g:je+n_g,2)
      real, intent(in):: q_low, q_hi
      logical, optional, intent(out):: bad_range
      type(time_type), optional, intent(IN) :: Time
!
      real qmin, qmax
      integer i,j,k
      integer year, month, day, hour, minute, second

      if ( present(bad_range) ) bad_range = .false.
      qmin = q(is,js,1)
      qmax = qmin

      do k=1,km
      do j=js,je
         do i=is,ie
            if( q(i,j,k) < qmin ) then
                qmin = q(i,j,k)
            elseif( q(i,j,k) > qmax ) then
                qmax = q(i,j,k)
            endif
          enddo
      enddo
      enddo

      call mp_reduce_min(qmin)
      call mp_reduce_max(qmax)

      if( qmin<q_low .or. qmax>q_hi ) then
          if(master) write(*,*) 'Range_check Warning:', qname, ' max = ', qmax, ' min = ', qmin
          if (present(Time)) then
             if (m_calendar) then
                call get_date(Time, year, month, day, hour, minute, second)
                if (master) write(*,999) year, month, day, hour, minute, second
999             format(' Range violation on: ', I4, '/', I02, '/', I02, ' ', I02, ':', I02, ':', I02)
             else
                call get_time(Time, second, day)
                year = 0 ; month = 0 ; hour = 0 ; minute = 0
                if (master) write(*,996) day, second
996             format(' Range violation on: ', I6, ' days ', I05, ' seconds')
             endif
          endif
          if ( present(bad_range) ) then
               bad_range = .true.
          endif
      endif

      if ( present(bad_range) ) then
! Print out where the bad value(s) is (are)
         if ( bad_range .EQV. .false. ) return
         do k=1,km
            do j=js,je
               do i=is,ie
                  if( q(i,j,k)<q_low .or. q(i,j,k)>q_hi ) then
                      write(*,998) k,i,j, pos(i,j,1)*rad2deg, pos(i,j,2)*rad2deg, qname, q(i,j,k)
!                      write(*,*) 'Warn_K=',k,'(i,j)=',i,j, pos(i,j,1)*rad2deg, pos(i,j,2)*rad2deg, q(i,j,k)
998                   format('Warn_K=',I4,' (i,j)=',2I5,' (lon,lat)=',f7.3,1x,f7.3,1x, A,' =',f10.5)
997                   format('     K=',I4,3x,f10.5)
                      if ( k/= 1 ) write(*,997) k-1, q(i,j,k-1)
                      if ( k/=km ) write(*,997) k+1, q(i,j,k+1)
                  endif
               enddo
            enddo
         enddo
         call mpp_error(NOTE,'==> Error from range_check: data out of bound')
      endif

 end subroutine range_check_3d

 subroutine range_check_2d(qname, q, is, ie, js, je, n_g, pos, q_low, q_hi, bad_range, Time)
      character(len=*), intent(in)::  qname
      integer, intent(in):: is, ie, js, je
      integer, intent(in):: n_g
      real, intent(in)::    q(is-n_g:ie+n_g, js-n_g:je+n_g)
      real, intent(in):: pos(is-n_g:ie+n_g, js-n_g:je+n_g,2)
      real, intent(in):: q_low, q_hi
      logical, optional, intent(out):: bad_range
      type(time_type), optional, intent(IN) :: Time
!
      real qmin, qmax
      integer i,j
      integer year, month, day, hour, minute, second

      if ( present(bad_range) ) bad_range = .false.
      qmin = q(is,js)
      qmax = qmin

      do j=js,je
         do i=is,ie
            if( q(i,j) < qmin ) then
                qmin = q(i,j)
            elseif( q(i,j) > qmax ) then
                qmax = q(i,j)
            endif
          enddo
      enddo

      call mp_reduce_min(qmin)
      call mp_reduce_max(qmax)

      if( qmin<q_low .or. qmax>q_hi ) then
          if(master) write(*,*) 'Range_check Warning:', qname, ' max = ', qmax, ' min = ', qmin
          if (present(Time)) then
             if (m_calendar) then
                call get_date(Time, year, month, day, hour, minute, second)
                if (master) write(*,999) year, month, day, hour, minute, second
999             format(' Range violation on: ', I4, '/', I02, '/', I02, ' ', I02, ':', I02, ':', I02)
             else
                call get_time(Time, second, day)
                year = 0 ; month = 0 ; hour = 0 ; minute = 0
                if (master) write(*,996) day, second
996             format(' Range violation on: ', I6, ' days ', I05, ' seconds')
             endif
          endif
          if ( present(bad_range) ) then
               bad_range = .true.
          endif
      endif

      if ( present(bad_range) ) then
! Print out where the bad value(s) is (are)
         if ( bad_range .EQV. .false. ) return
         do j=js,je
            do i=is,ie
               if( q(i,j)<q_low .or. q(i,j)>q_hi ) then
                   write(*,995) i, j, pos(i,j,1)*rad2deg, pos(i,j,2)*rad2deg, qname, q(i,j)
!                   write(*,*) 'Warn_(i,j)=',i,j, pos(i,j,1)*rad2deg, pos(i,j,2)*rad2deg, q(i,j)
!                      write(*,998) k,i,j, pos(i,j,1)*rad2deg, pos(i,j,2)*rad2deg, qname, q(i,j,k)

995                format('Warn_2D: (i,j)=',2I5,' (lon,lat)=',f7.3,1x,f7.3,1x, A,' =',G10.5)
               endif
            enddo
         enddo
         call mpp_error(NOTE,'==> Error from range_check: data out of bound')
      endif

 end subroutine range_check_2d

 subroutine prt_maxmin(qname, q, is, ie, js, je, n_g, km, fac, prt_level)
      character(len=*), intent(in)::  qname
      integer, intent(in):: is, ie, js, je
      integer, intent(in):: n_g, km
      integer, intent(in), OPTIONAL ::  prt_level
      real, intent(in)::    q(is-n_g:ie+n_g, js-n_g:je+n_g, km)
      real, intent(in)::    fac

      real qmin, qmax
      integer i,j,k
      character(len=16) :: display_name

      if (present(prt_level)) then
         if (prt_level > user_prt_level) return
      endif

      !mpp_root_pe doesn't appear to recognize nested grid
      master = (mpp_pe()==mpp_root_pe()) .or. is_master()

      qmin = q(is,js,1)
      qmax = qmin

      do k=1,km
      do j=js,je
         do i=is,ie
!           qmin = min(qmin, q(i,j,k))
!           qmax = max(qmax, q(i,j,k))
            if( q(i,j,k) < qmin  ) then
                qmin = q(i,j,k)
            elseif( q(i,j,k) > qmax ) then
                qmax = q(i,j,k)
            endif
          enddo
      enddo
      enddo

      call mp_reduce_min(qmin)
      call mp_reduce_max(qmax)

      if(master) then
         j = min(len(trim(qname)),16)
         display_name = qname(1:j)
         write(*,'(2x, A16, A, A1, A5, G20.8, A5, G20.8)') display_name, trim(gn), ':', ' max=', qmax*fac, 'min=',qmin*fac
      endif

 end subroutine prt_maxmin

 subroutine prt_mxm(qname, q, is, ie, js, je, n_g, km, fac, area, domain, prt_level)
      character(len=*), intent(in)::  qname
      integer, intent(in):: is, ie, js, je
      integer, intent(in):: n_g, km
      real, intent(in)::    q(is-n_g:ie+n_g, js-n_g:je+n_g, km)
      real, intent(in)::    fac
      integer, intent(in), OPTIONAL ::  prt_level
! BUG !!!
!     real, intent(IN)::    area(is-n_g:ie+n_g, js-n_g:je+n_g, km)
      real(kind=R_GRID), intent(IN)::    area(is-3:ie+3, js-3:je+3)
      type(domain2d), intent(INOUT) :: domain
!
      real qmin, qmax, gmean
      integer i,j,k
      character(len=16) :: display_name

      if (present(prt_level)) then
         if (prt_level > user_prt_level) return
      endif

      !mpp_root_pe doesn't appear to recognize nested grid
      master = (mpp_pe()==mpp_root_pe()) .or. is_master()
      qmin = q(is,js,1)
      qmax = qmin
      gmean = 0.

      do k=1,km
      do j=js,je
         do i=is,ie
!           qmin = min(qmin, q(i,j,k))
!           qmax = max(qmax, q(i,j,k))
            if( q(i,j,k) < qmin ) then
                qmin = q(i,j,k)
            elseif( q(i,j,k) > qmax ) then
                qmax = q(i,j,k)
            endif
          enddo
      enddo
      enddo

      call mp_reduce_min(qmin)
      call mp_reduce_max(qmax)

! SJL: BUG!!!
!     gmean = g_sum(domain, q(is,js,km), is, ie, js, je, 3, area, 1)
      gmean = g_sum(domain, q(is:ie,js:je,km), is, ie, js, je, 3, area, 1)

      if(master) then
         j = min(len(trim(qname)),16)
         display_name = qname(1:j)
         write(6,'(2x,A16,A,A1,3G20.8)') display_name, trim(gn), ':', qmax*fac, qmin*fac, gmean*fac
      endif

 end subroutine prt_mxm

 !Added nwat == 1 case for water vapor diagnostics
 subroutine prt_mass(km, nq, is, ie, js, je, n_g, nwat, ps, delp, q, &
                     area, domain, prt_level_in)

 integer, intent(in):: is, ie, js, je
 integer, intent(in):: nq, n_g, km, nwat
 real, intent(in)::   ps(is-n_g:ie+n_g, js-n_g:je+n_g)
 real, intent(in):: delp(is-n_g:ie+n_g, js-n_g:je+n_g, km)
 real, intent(in)::  q(is-n_g:ie+n_g, js-n_g:je+n_g, km, nq)
 real(kind=R_GRID), intent(IN):: area(is-n_g:ie+n_g,js-n_g:je+n_g)
 type(domain2d), intent(INOUT) :: domain
 integer, intent(in), OPTIONAL ::  prt_level_in
! Local:
 real psq(is:ie,js:je,nq), psqv(is:ie,js:je)
 real q_strat(is:ie,js:je)
 real qtot(nwat), qwat
 real psmo, totw, psdry
 integer k, n, kstrat
 integer ::  prt_level = 1

 if (present(prt_level_in)) prt_level = prt_level_in
 if (prt_level <= PRT_LEVEL_0) return

!Needed when calling prt_mass in fv_restart?
    sphum   = get_tracer_index (MODEL_ATMOS, 'sphum')
    liq_wat = get_tracer_index (MODEL_ATMOS, 'liq_wat')
    ice_wat = get_tracer_index (MODEL_ATMOS, 'ice_wat')

    rainwat = get_tracer_index (MODEL_ATMOS, 'rainwat')
    snowwat = get_tracer_index (MODEL_ATMOS, 'snowwat')
    graupel = get_tracer_index (MODEL_ATMOS, 'graupel')

 if (master) write(*,*) '  Mass Diagnostics:'

 if ( nwat==0 ) then
      psmo = g_sum(domain, ps(is:ie,js:je), is, ie, js, je, n_g, area, 1)
      if( master ) write(*,*) '    Total surface pressure (mb)', trim(gn), ' = ',  0.01*psmo
      call z_sum(is, ie, js, je, km, n_g, delp, q(is-n_g,js-n_g,1,1  ), psqv(is,js))
      return
 endif

 psq(:,:,:) = 0.
 call z_sum(is, ie, js, je, km, n_g, delp, q(is-n_g,js-n_g,1,sphum  ), psq(is,js,sphum  ))

 if (liq_wat > 0)  &
      call z_sum(is, ie, js, je, km, n_g, delp, q(is-n_g,js-n_g,1,liq_wat), psq(is,js,liq_wat))

 if (rainwat > 0)  &
      call z_sum(is, ie, js, je, km, n_g, delp, q(is-n_g,js-n_g,1,rainwat), psq(is,js,rainwat))

!nwat == 4 => KESSLER, ice is probably garbage...
 if (ice_wat > 0)  &
      call z_sum(is, ie, js, je, km, n_g, delp, q(is-n_g,js-n_g,1,ice_wat), psq(is,js,ice_wat))

 if (snowwat > 0) &
      call z_sum(is, ie, js, je, km, n_g, delp, q(is-n_g,js-n_g,1,snowwat), psq(is,js,snowwat))
 if (graupel > 0) &
      call z_sum(is, ie, js, je, km, n_g, delp, q(is-n_g,js-n_g,1,graupel), psq(is,js,graupel))


! Mean water vapor in the "stratosphere" (75 mb and above):
 if (prt_level >= PRT_LEVEL_2) then
    if ( phalf(2)< 75. ) then
       kstrat = 1
       do k=1,km
          if ( phalf(k+1) > 75. ) exit
          kstrat = k
       enddo
       call z_sum(is, ie, js, je, kstrat, n_g, delp, q(is-n_g,js-n_g,1,sphum), q_strat(is,js))
       psmo = g_sum(domain, q_strat(is,js), is, ie, js, je, n_g, area, 1) * 1.e6           &
            / p_sum(is, ie, js, je, kstrat, n_g, delp, area, domain)
       if(master) write(*,*) '    Mean Specific Humidity (mg/kg) above 75 mb', trim(gn), ' = ', psmo
    endif
 endif


!-------------------
! Check global means
!-------------------
 psmo = g_sum(domain, ps(is:ie,js:je), is, ie, js, je, n_g, area, 1)

 do n=1,nwat
    qtot(n) = g_sum(domain, psq(is,js,n), is, ie, js, je, n_g, area, 1)
 enddo

 totw  = sum(qtot(1:nwat))
 psdry = psmo - totw

 if( master ) then
     write(*,*) '    Total Surface Pressure (mb)   ', trim(gn), ' = ',  0.01*psmo
     write(*,*) '    Mean Dry Surface Pressure (mb)', trim(gn), ' = ',    0.01*psdry
     write(*,*) '    Total Water Vapor (kg/m**2)   ', trim(gn), ' = ',  qtot(sphum)*ginv
     if ( nwat> 2 ) then
          write(*,*) '  Micro Phys water substances (kg/m**2) '
          write(*,*) '    Total Cloud Water', trim(gn), ' = ', qtot(liq_wat)*ginv
          if (rainwat > 0) &
               write(*,*) '    Total Rain Water ', trim(gn), ' = ', qtot(rainwat)*ginv
          if (ice_wat > 0) &
               write(*,*) '    Total Cloud Ice  ', trim(gn), ' = ', qtot(ice_wat)*ginv
          if (snowwat > 0) &
               write(*,*) '    Total Snow       ', trim(gn), ' = ', qtot(snowwat)*ginv
          if (graupel > 0) &
               write(*,*) '    Total Graupel    ', trim(gn), ' = ', qtot(graupel)*ginv
          !write(*,*) '---------------------------------------------'
     elseif ( nwat==2 ) then
          write(*,*) '    GFS Condensate (kg/m^2)', trim(gn), ' = ', qtot(liq_wat)*ginv
     endif
  endif

 end subroutine prt_mass


 subroutine z_sum(is, ie, js, je, km, n_g, delp, q, sum2)
 integer, intent(in):: is, ie, js, je,  n_g, km
 real, intent(in):: delp(is-n_g:ie+n_g, js-n_g:je+n_g, km)
 real, intent(in)::    q(is-n_g:ie+n_g, js-n_g:je+n_g, km)
 real, intent(out):: sum2(is:ie,js:je)

 integer i,j,k

 do j=js,je
    do i=is,ie
       sum2(i,j) = delp(i,j,1)*q(i,j,1)
    enddo
    do k=2,km
       do i=is,ie
          sum2(i,j) = sum2(i,j) + delp(i,j,k)*q(i,j,k)
       enddo
    enddo
 enddo

 end subroutine z_sum


 real function p_sum(is, ie, js, je, km, n_g, delp, area, domain)
 integer, intent(in):: is, ie, js, je,  n_g, km
 real, intent(in):: delp(is-n_g:ie+n_g, js-n_g:je+n_g, km)
 real(kind=R_GRID), intent(IN) :: area(is-n_g:ie+n_g, js-n_g:je+n_g)
 real :: sum2(is:ie,js:je)
 integer i,j,k
 type(domain2d), intent(INOUT) :: domain

!$OMP parallel do default(none) shared(is,ie,js,je,km,sum2,delp)
 do j=js,je
    do i=is,ie
       sum2(i,j) = delp(i,j,1)
    enddo
    do k=2,km
       do i=is,ie
          sum2(i,j) = sum2(i,j) + delp(i,j,k)
       enddo
    enddo
 enddo
 p_sum = g_sum(domain, sum2, is, ie, js, je, n_g, area, 1)

 end function p_sum



 subroutine get_pressure_given_height(is, ie, js, je, ng, km, wz, kd, height,   &
                                      ts, peln, a2, fac)

 integer,  intent(in):: is, ie, js, je, km, ng
 integer,  intent(in):: kd           ! vertical dimension of the ouput height
 real, intent(in):: wz(is:ie,js:je,km+1)
 real, intent(in):: ts(is-ng:ie+ng,js-ng:je+ng)
 real, intent(in):: peln(is:ie,km+1,js:je)
 real, intent(in):: height(kd)   ! must be monotonically decreasing with increasing k
 real, intent(out):: a2(is:ie,js:je,kd)      ! pressure (pa)
 real, optional, intent(in):: fac

! local:
 integer n, i,j,k
 real ptmp, tm


 do n=1,kd

!$OMP parallel do default(none) shared(is,ie,js,je,n,height,wz,km,peln,a2,ginv,ts,fac) &
!$OMP                          private(ptmp, tm)
    do j=js,je

       do 1000 i=is,ie

         if ( height(n) >= wz(i,j,km+1) ) then
!---------------------
! Search from top down
!---------------------
          do k=1,km
             if( height(n) < wz(i,j,k) .and. height(n) >= wz(i,j,k+1) ) then
! Found it!
                 ptmp = peln(i,k,j) + (peln(i,k+1,j)-peln(i,k,j)) *   &
                       (wz(i,j,k)-height(n)) / (wz(i,j,k)-wz(i,j,k+1))
                 a2(i,j,n) = exp(ptmp)
                 go to 500
             endif
          enddo

         else
!-----------------------------------------
! xtrapolation: mean laspe rate 6.5 deg/km
!-----------------------------------------
                tm = rdgas*ginv*(ts(i,j) + 3.25E-3*(wz(i,j,km)-height(n)))
          a2(i,j,n) = exp( peln(i,km+1,j) + (wz(i,j,km+1) - height(n))/tm )
         endif
500      if ( present(fac) ) a2(i,j,n) = fac * a2(i,j,n)
1000   continue
    enddo
 enddo

 end subroutine get_pressure_given_height


 subroutine get_height_given_pressure(is, ie, js, je, km, wz, kd, id, log_p, peln, a2)
 integer,  intent(in):: is, ie, js, je, km
 integer,  intent(in):: kd       ! vertical dimension of the ouput height
 integer,  intent(in):: id(kd)
 real, intent(in):: log_p(kd)    ! must be monotonically increasing  with increasing k
                                 ! log (p)
 real, intent(in):: wz(is:ie,js:je,km+1)
 real, intent(in):: peln(is:ie,km+1,js:je)
 real, intent(out):: a2(is:ie,js:je,kd)      ! height (m)
! local:
 real, dimension(2*km+1):: pn, gz
 integer n,i,j,k, k1, k2, l

 k2 = max(12, km/2+1)

!$OMP parallel do default(none) shared(k2,is,ie,js,je,km,kd,id,log_p,peln,a2,wz)   &
!$OMP             private(i,j,n,k,k1,l,pn,gz)
 do j=js,je
    do i=is,ie
!---------------
! Mirror method:
!---------------
       do k=1,km+1
          pn(k) = peln(i,k,j)
          gz(k) = wz(i,j,k)
       enddo
       do k=km+2, km+k2
          l = 2*(km+1) - k
          gz(k) = 2.*gz(km+1) - gz(l)
          pn(k) = 2.*pn(km+1) - pn(l)
       enddo
       k1 = 1
       do 1000 n=1,kd
          if( id(n)<0 ) goto 1000
          do k=k1,km+k2-1
             if( log_p(n) <= pn(k+1) .and. log_p(n) >= pn(k) ) then
                 a2(i,j,n) = gz(k) + (gz(k+1)-gz(k))*(log_p(n)-pn(k))/(pn(k+1)-pn(k))
                 k1 = k
                 go to 1000
             endif
          enddo
       a2(i,j,n) = missing_value
1000   continue
    enddo
 enddo

 end subroutine get_height_given_pressure

 subroutine prt_height(qname, is, ie, js, je, ng, km, press, phis, delz, peln, area, lat)
 character(len=*), intent(in)::  qname
 integer,  intent(in):: is, ie, js, je, ng, km
 real, intent(in):: press
 real, intent(in):: peln(is:ie,km+1,js:je)
 real, intent(in):: phis(is-ng:ie+ng,js-ng:je+ng)
 real, intent(in):: delz(is:,js:,1:)
 real(kind=R_GRID), intent(in), dimension(is:ie, js:je):: area, lat
! local:
 real:: a2(is:ie,js:je)      ! height (m)
 real(kind=R_GRID), dimension(2*km+1):: pn, gz
 real(kind=R_GRID):: log_p
 integer i,j,k, k2, l

 if (PRT_LEVEL_1 > user_prt_level) return

 log_p = log(press)
 k2 = max(12, km/2+1)

!$OMP parallel do default(none) shared(k2,is,ie,js,je,km,log_p,peln,phis,delz,a2)   &
!$OMP             private(i,j,k,l,pn,gz)
 do j=js,je
    do 1000 i=is,ie
!---------------
! Mirror method:
!---------------
       do k=1,km+1
          pn(k) = peln(i,k,j)
       enddo
       gz(km+1) = phis(i,j)/grav
       do k=km,1,-1
          gz(k) = gz(k+1) - delz(i,j,k)
       enddo
       do k=km+2, km+k2
          l = 2*(km+1) - k
          gz(k) = 2.*gz(km+1) - gz(l)
          pn(k) = 2.*pn(km+1) - pn(l)
       enddo

       do k=1,km+k2-1
          if( log_p <= pn(k+1) .and. log_p >= pn(k) ) then
              a2(i,j) = gz(k) + (gz(k+1)-gz(k))*(log_p-pn(k))/(pn(k+1)-pn(k))
              go to 1000
          endif
       enddo
1000   continue
 enddo
 call prt_gb_nh_sh(qname, is,ie, js,je, a2, area, lat, PRT_LEVEL_1)

 end subroutine prt_height

 subroutine prt_gb_nh_sh(qname, is,ie, js,je, a2, area, lat, prt_level)
  character(len=*), intent(in)::  qname
  integer, intent(in):: is, ie, js, je
  real, intent(in), dimension(is:ie, js:je):: a2
  real(kind=R_GRID), intent(in), dimension(is:ie, js:je):: area, lat
  integer, intent(in), OPTIONAL ::  prt_level
! Local:
  real(R_GRID), parameter:: rad2deg = 180./pi
  real(R_GRID):: slat
  real:: t_eq, t_nh, t_sh, t_gb
  real:: area_eq, area_nh, area_sh, area_gb
  integer:: i,j
  character(len=16) :: display_name

     if (present(prt_level)) then
        if (prt_level > user_prt_level) return
     endif

     t_eq = 0.   ;    t_nh = 0.;    t_sh = 0.;    t_gb = 0.
     area_eq = 0.; area_nh = 0.; area_sh = 0.; area_gb = 0.
     do j=js,je
        do i=is,ie
           slat = lat(i,j)*rad2deg
           area_gb = area_gb + area(i,j)
           t_gb = t_gb + a2(i,j)*area(i,j)
           if( (slat>-20. .and. slat<20.) ) then
                area_eq = area_eq + area(i,j)
                t_eq = t_eq + a2(i,j)*area(i,j)
           elseif( slat>=20. .and. slat<80. ) then
                area_nh = area_nh + area(i,j)
                t_nh = t_nh + a2(i,j)*area(i,j)
           elseif( slat<=-20. .and. slat>-80. ) then
                area_sh = area_sh + area(i,j)
                t_sh = t_sh + a2(i,j)*area(i,j)
           endif
        enddo
     enddo
     call mp_reduce_sum(area_gb)
     call mp_reduce_sum(   t_gb)
     call mp_reduce_sum(area_nh)
     call mp_reduce_sum(   t_nh)
     call mp_reduce_sum(area_sh)
     call mp_reduce_sum(   t_sh)
     call mp_reduce_sum(area_eq)
     call mp_reduce_sum(   t_eq)
     !Bugfix for non-global domains
     if (area_gb <= 1.) area_gb = -1.0
     if (area_nh <= 1.) area_nh = -1.0
     if (area_sh <= 1.) area_sh = -1.0
     if (area_eq <= 1.) area_eq = -1.0
     if (is_master()) then
        j = min(len(trim(qname)),16)
        display_name = qname(1:j)
        write(6,'(2x,A16,A6,G20.8,A4,G20.8)') display_name, ': GB =',t_gb/area_gb, 'NH =',t_nh/area_nh
        write(6,'(20x,A4,G20.8,A4,G20.8)') 'SH =',t_sh/area_sh, 'EQ =',t_eq/area_eq
     endif

 end subroutine prt_gb_nh_sh

 subroutine cs3_interpolator(is, ie, js, je, km, qin, kd, plevs, pe, id, qout, iv)
! iv =-1: winds
! iv = 0: positive definite scalars
! iv = 1: temperature
 integer,  intent(in):: is, ie, js, je, km, iv
 integer,  intent(in):: kd      ! vertical dimension of the ouput height
 integer,  intent(in):: id(kd)
 real, intent(in):: plevs(kd)    ! must be monotonically increasing with increasing k
 real, intent(in):: pe(is:ie,km+1,js:je)
 real, intent(in):: qin(is:ie,js:je,km)
 real, intent(out):: qout(is:ie,js:je,kd)
! local:
 real, parameter:: gcp = grav / cp_air
 real:: qe(is:ie,km+1)
 real, dimension(is:ie,km):: q2, dp
 real:: s0, a6, alpha, pbot, ts, t0, tmp
 integer:: i,j,k, n, k1

!$OMP parallel do default(none) shared(iv,id,is,ie,js,je,km,kd,plevs,qin,qout,pe,zsurf) &
!$OMP             private(k1,s0,a6,q2,dp,qe,pbot,alpha,ts,t0,tmp)
 do j=js,je

   do i=is,ie
      do k=1,km
         dp(i,k) = pe(i,k+1,j) - pe(i,k,j)
         q2(i,k) = qin(i,j,k)
      enddo
   enddo

   call cs_prof(q2, dp, qe, km, is, ie, iv)

   do i=is,ie
     k1 = 1
     do n=1,kd
        if ( id(n) > 0 ) then
          if( plevs(n) <= pe(i,1,j) ) then
! Higher than the top:
              qout(i,j,n) = qe(i,1)
          elseif ( plevs(n) >= pe(i,km+1,j) ) then
! lower than the bottom surface:
            if ( iv==1 ) then    ! Temperature
!-----------------------------------------------------------------------
! Linjiong Zhou: this idea is good, but the formula is wrong.
! lower than the bottom surface:
! mean (hydro) potential temp based on lowest 2-3 layers (NCEP method)
! temp = ptm * p**cappa = ptm * exp(cappa*log(plevs))
!               qout(i,j,n) = gcp*exp(kappa*plevs(n)) * (wz(i,j,km-2) - wz(i,j,km))  /   &
!                               ( exp(kappa*pe(i,km,j)) - exp(kappa*pe(i,km-2,j)) )
!-----------------------------------------------------------------------
! ECMWF Method: Trenberth et al., 1993
               alpha = 0.0065*rdgas/grav
               pbot = (exp(pe(i,km+1,j))-exp(pe(i,km,j)))/(pe(i,km+1,j)-pe(i,km,j))
               ts = (q2(i,km)+alpha*q2(i,km)*(exp(pe(i,km+1,j))/pbot-1))
               t0 = ts+0.0065*zsurf(i,j)
               tmp = min(t0,298.0)
               if (zsurf(i,j).ge.2000.0) then
                   if (zsurf(i,j).le.2500.0) then
                       tmp = 0.002*((2500-zsurf(i,j))*t0+(zsurf(i,j)-2000)*tmp)
                   endif
                   if (tmp-ts.lt.0) then
                       alpha = 0
                   else
                       alpha = rdgas*(tmp-ts)/(zsurf(i,j)*grav)
                   endif
               endif
               qout(i,j,n) = ts*exp(alpha*(plevs(n)-pe(i,km+1,j)))
!-----------------------------------------------------------------------
            else
               qout(i,j,n) = qe(i,km+1)
            endif
          else
            do k=k1,km
               if ( plevs(n)>=pe(i,k,j) .and. plevs(n) <= pe(i,k+1,j) ) then
! PPM distribution: f(s) = AL + s*[(AR-AL) + A6*(1-s)]         ( 0 <= s <= 1 )
                   a6 = 3.*(2.*q2(i,k) - (qe(i,k)+qe(i,k+1)))
                   s0 = (plevs(n)-pe(i,k,j)) / dp(i,k)
                   qout(i,j,n) = qe(i,k) + s0*(qe(i,k+1)-qe(i,k)+a6*(1.-s0))
                   k1 = k     ! next level
                   go to 500
               endif
            enddo
          endif
500       if ( iv==0 ) qout(i,j,n) = max(0., qout(i,j,n))
        endif
     enddo
   enddo
 enddo

! Send_data here

 end subroutine cs3_interpolator

 subroutine cs_interpolator(is, ie, js, je, km, qin, zout, wz, qout, qmin)
 integer,  intent(in):: is, ie, js, je, km
 real, intent(in):: zout, qmin
 real, intent(in):: qin(is:ie,js:je,km)
 real, intent(in):: wz(is:ie,js:je,km+1)
 real, intent(out):: qout(is:ie,js:je)
! local:
 real:: qe(is:ie,km+1)
 real, dimension(is:ie,km):: q2, dz
 real:: s0, a6
 integer:: i,j,k

!$OMP parallel do default(none) shared(qmin,is,ie,js,je,km,zout,qin,qout,wz) &
!$OMP             private(s0,a6,q2,dz,qe)
 do j=js,je

   do i=is,ie
      do k=1,km
         dz(i,k) = wz(i,j,k) - wz(i,j,k+1)
         q2(i,k) = qin(i,j,k)
      enddo
   enddo

   call cs_prof(q2, dz, qe, km, is, ie, 1)

   do i=is,ie
      if( zout >= wz(i,j,1) ) then
! Higher than the top:
          qout(i,j) = qe(i,1)
      elseif ( zout <= wz(i,j,km+1) ) then
          qout(i,j) = qe(i,km+1)
      else
          do k=1,km
             if ( zout<=wz(i,j,k) .and. zout >= wz(i,j,k+1) ) then
! PPM distribution: f(s) = AL + s*[(AR-AL) + A6*(1-s)]         ( 0 <= s <= 1 )
                  a6 = 3.*(2.*q2(i,k) - (qe(i,k)+qe(i,k+1)))
                  s0 = (wz(i,j,k)-zout) / dz(i,k)
                  qout(i,j) = qe(i,k) + s0*(qe(i,k+1)-qe(i,k)+a6*(1.-s0))
                  go to 500
             endif
          enddo
      endif
500   qout(i,j) = max(qmin, qout(i,j))
   enddo
 enddo

! Send_data here

 end subroutine cs_interpolator

 subroutine cs_prof(q2, delp, q, km, i1, i2, iv)
! Latest: Dec 2015 S.-J. Lin, NOAA/GFDL
 integer, intent(in):: i1, i2, km
 integer, intent(in):: iv
 real, intent(in)   :: q2(i1:i2,km)
 real, intent(in)   :: delp(i1:i2,km)     ! layer pressure thickness
 real, intent(out):: q(i1:i2,km+1)
!-----------------------------------------------------------------------
 real  gam(i1:i2,km)
 real   d4(i1:i2)
 real   bet, a_bot, grat
 integer i, k

  do i=i1,i2
         grat = delp(i,2) / delp(i,1)   ! grid ratio
          bet = grat*(grat+0.5)
       q(i,1) = ( (grat+grat)*(grat+1.)*q2(i,1) + q2(i,2) ) / bet
     gam(i,1) = ( 1. + grat*(grat+1.5) ) / bet
  enddo

  do k=2,km
     do i=i1,i2
           d4(i) = delp(i,k-1) / delp(i,k)
             bet =  2. + d4(i) + d4(i) - gam(i,k-1)
          q(i,k) = ( 3.*(q2(i,k-1)+d4(i)*q2(i,k)) - q(i,k-1) )/bet
        gam(i,k) = d4(i) / bet
     enddo
  enddo

  do i=i1,i2
         a_bot = 1. + d4(i)*(d4(i)+1.5)
     q(i,km+1) = (2.*d4(i)*(d4(i)+1.)*q2(i,km)+q2(i,km-1)-a_bot*q(i,km))  &
               / ( d4(i)*(d4(i)+0.5) - a_bot*gam(i,km) )
  enddo

  do k=km,1,-1
     do i=i1,i2
        q(i,k) = q(i,k) - gam(i,k)*q(i,k+1)
     enddo
  enddo

! Apply *large-scale* constraints
  do i=i1,i2
     q(i,2) = min( q(i,2), max(q2(i,1), q2(i,2)) )
     q(i,2) = max( q(i,2), min(q2(i,1), q2(i,2)) )
  enddo

  do k=2,km
     do i=i1,i2
        gam(i,k) = q2(i,k) - q2(i,k-1)
     enddo
  enddo

! Interior:
  do k=3,km-1
     do i=i1,i2
        if ( gam(i,k-1)*gam(i,k+1)>0. ) then
! Apply large-scale constraint to ALL fields if not local max/min
             q(i,k) = min( q(i,k), max(q2(i,k-1),q2(i,k)) )
             q(i,k) = max( q(i,k), min(q2(i,k-1),q2(i,k)) )
        else
          if ( gam(i,k-1) > 0. ) then
! There exists a local max
               q(i,k) = max(q(i,k), min(q2(i,k-1),q2(i,k)))
          else
! There exists a local min
               q(i,k) = min(q(i,k), max(q2(i,k-1),q2(i,k)))
               if ( iv==0 ) q(i,k) = max(0., q(i,k))
          endif
        endif
     enddo
  enddo

! Bottom:
  do i=i1,i2
     q(i,km) = min( q(i,km), max(q2(i,km-1), q2(i,km)) )
     q(i,km) = max( q(i,km), min(q2(i,km-1), q2(i,km)) )
  enddo

 end subroutine cs_prof


 subroutine interpolate_vertical(is, ie, js, je, km, plev, peln, a3, a2)

 integer,  intent(in):: is, ie, js, je, km
 real, intent(in):: peln(is:ie,km+1,js:je)
 real, intent(in):: a3(is:ie,js:je,km)
 real, intent(in):: plev
 real, intent(out):: a2(is:ie,js:je)
! local:
 real pm(km)
 real logp
 integer i,j,k

 logp = log(plev)

!$OMP parallel do default(none) shared(is,ie,js,je,km,peln,logp,a2,a3) &
!$OMP                          private(pm)
 do j=js,je
    do 1000 i=is,ie

       do k=1,km
          pm(k) = 0.5*(peln(i,k,j)+peln(i,k+1,j))
       enddo

       if( logp <= pm(1) ) then
           a2(i,j) = a3(i,j,1)
       elseif ( logp >= pm(km) ) then
           a2(i,j) = a3(i,j,km)
       else
           do k=1,km-1
              if( logp <= pm(k+1) .and. logp >= pm(k) ) then
                  a2(i,j) = a3(i,j,k) + (a3(i,j,k+1)-a3(i,j,k))*(logp-pm(k))/(pm(k+1)-pm(k))
                  go to 1000
              endif
           enddo
       endif
1000   continue
 enddo

 end subroutine interpolate_vertical


 subroutine interpolate_z(is, ie, js, je, km, zl, hght, a3, a2)

 integer,  intent(in):: is, ie, js, je, km
 real, intent(in):: hght(is:ie,js:je,km+1)  ! hght(k) > hght(k+1)
 real, intent(in):: a3(is:ie,js:je,km)
 real, intent(in):: zl
 real, intent(out):: a2(is:ie,js:je)
! local:
 real zm(km)
 integer i,j,k


!$OMP parallel do default(none) shared(is,ie,js,je,km,hght,zl,a2,a3) private(zm)
 do j=js,je
    do 1000 i=is,ie
       do k=1,km
          zm(k) = 0.5*(hght(i,j,k)+hght(i,j,k+1))
       enddo
       if( zl >= zm(1) ) then
           a2(i,j) = a3(i,j,1)
       elseif ( zl <= zm(km) ) then
           a2(i,j) = a3(i,j,km)
       else
           do k=1,km-1
              if( zl <= zm(k) .and. zl >= zm(k+1) ) then
                  a2(i,j) = a3(i,j,k) + (a3(i,j,k+1)-a3(i,j,k))*(zm(k)-zl)/(zm(k)-zm(k+1))
                  go to 1000
              endif
           enddo
       endif
1000   continue
 enddo

 end subroutine interpolate_z

 subroutine helicity_relative(is, ie, js, je, ng, km, zvir, sphum, srh,   &
                              ua, va, delz, q, hydrostatic, pt, peln, phis, grav, z_bot, z_top)
! !INPUT PARAMETERS:
   integer, intent(in):: is, ie, js, je, ng, km, sphum
   real, intent(in):: grav, zvir, z_bot, z_top
   real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,km):: pt, ua, va
   real, intent(in):: delz(is:ie,js:je,km)
   real, intent(in):: q(is-ng:ie+ng,js-ng:je+ng,km,*)
   real, intent(in):: phis(is-ng:ie+ng,js-ng:je+ng)
   real, intent(in):: peln(is:ie,km+1,js:je)
   logical, intent(in):: hydrostatic
   real, intent(out):: srh(is:ie,js:je)   ! unit: (m/s)**2
!   real, parameter:: z_crit = 3.e3   ! lowest 3-km
!---------------------------------------------------------------------------------
! SRH = 150-299 ... supercells possible with weak tornadoes
! SRH = 300-449 ... very favourable to supercells development and strong tornadoes
! SRH > 450 ... violent tornadoes
!---------------------------------------------------------------------------------
! if z_top = 1E3, the threshold for supercells is 100 (m/s)**2
! Coded by S.-J. Lin for CONUS regional climate simulations
!
   real:: rdg
   real, dimension(is:ie):: zh, uc, vc, dz, zh0
   integer i, j, k, k0, k1
   logical below(is:ie)

   rdg = rdgas / grav

!$OMP parallel do default(none) shared(is,ie,js,je,km,hydrostatic,rdg,pt,zvir,sphum, &
!$OMP                                  peln,delz,ua,va,srh,z_bot,z_top) &
!$OMP                          private(zh,uc,vc,dz,k0,k1,zh0,below)
   do j=js,je

      do i=is,ie
         uc(i) = 0.
         vc(i) = 0.
         zh(i) = 0.
         srh(i,j) = 0.
         below(i) = .true.
         zh0(i) = 0.

!        if ( phis(i,j)/grav < 1.E3 ) then
         do k=km,1,-1
            if ( hydrostatic ) then
                 dz(i) = rdg*pt(i,j,k)*(1.+zvir*q(i,j,k,sphum))*(peln(i,k+1,j)-peln(i,k,j))
            else
                 dz(i) = - delz(i,j,k)
            endif
            zh(i) = zh(i) + dz(i)
            if (zh(i) <= z_bot ) continue
            if (zh(i) > z_bot .and. below(i)) then
               uc(i) = ua(i,j,k)*dz(i)
               vc(i) = va(i,j,k)*dz(i)
               zh0(i) = zh(i) - dz(i)
               k1 = k
               below(i) = .false.
! Compute mean winds below z_top
            elseif ( zh(i) < z_top ) then
                uc(i) = uc(i) + ua(i,j,k)*dz(i)
                vc(i) = vc(i) + va(i,j,k)*dz(i)
                k0 = k
            else
                uc(i) = uc(i) / (zh(i)-dz(i) - zh0(i))
                vc(i) = vc(i) / (zh(i)-dz(i) - zh0(i))
                goto 123
            endif
         enddo
123      continue

! Lowest layer wind shear computed betw top edge and mid-layer
         k = k1
         srh(i,j) = 0.5*(va(i,j,k1)-vc(i))*(ua(i,j,k1-1)-ua(i,j,k1))  -  &
                    0.5*(ua(i,j,k1)-uc(i))*(va(i,j,k1-1)-va(i,j,k1))
         do k=k0, k1-1
            srh(i,j) = srh(i,j) + 0.5*(va(i,j,k)-vc(i))*(ua(i,j,k-1)-ua(i,j,k+1)) -  &
                                  0.5*(ua(i,j,k)-uc(i))*(va(i,j,k-1)-va(i,j,k+1))
         enddo
!        endif
      enddo  ! i-loop
   enddo   ! j-loop

 end subroutine helicity_relative

 subroutine helicity_relative_CAPS(is, ie, js, je, ng, km, zvir, sphum, srh, uc, vc,  &
                              ua, va, delz, q, hydrostatic, pt, peln, phis, grav, z_bot, z_top)
! !INPUT PARAMETERS:
   integer, intent(in):: is, ie, js, je, ng, km, sphum
   real, intent(in):: grav, zvir, z_bot, z_top
   real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,km):: pt, ua, va
   real, intent(in):: delz(is:ie,js:je,km)
   real, intent(in):: q(is-ng:ie+ng,js-ng:je+ng,km,*)
   real, intent(in):: phis(is-ng:ie+ng,js-ng:je+ng)
   real, intent(in):: peln(is:ie,km+1,js:je)
   real, intent(in):: uc(is:ie,js:je), vc(is:ie,js:je)
   logical, intent(in):: hydrostatic
   real, intent(out):: srh(is:ie,js:je)   ! unit: (m/s)**2
!---------------------------------------------------------------------------------
! SRH = 150-299 ... supercells possible with weak tornadoes
! SRH = 300-449 ... very favourable to supercells development and strong tornadoes
! SRH > 450 ... violent tornadoes
!---------------------------------------------------------------------------------
! if z_crit = 1E3, the threshold for supercells is 100 (m/s)**2
! Coded by S.-J. Lin for CONUS regional climate simulations
!
   real:: rdg
   real, dimension(is:ie):: zh, dz, zh0
   integer i, j, k, k0, k1
   logical below

   rdg = rdgas / grav

!$OMP parallel do default(none) shared(is,ie,js,je,km,hydrostatic,rdg,pt,zvir,sphum, &
!$OMP                                  peln,delz,ua,va,srh,uc,vc,z_bot,z_top) &
!$OMP                          private(zh,dz,k0,k1,zh0,below)
   do j=js,je

      do i=is,ie
         srh(i,j) = 0.
         zh(i) = 0.
         zh0 = 0.
         below = .true.

         do k=km,1,-1
            if ( hydrostatic ) then
                 dz(i) = rdg*pt(i,j,k)*(1.+zvir*q(i,j,k,sphum))*(peln(i,k+1,j)-peln(i,k,j))
            else
                 dz(i) = -delz(i,j,k)
            endif

            zh(i) = zh(i) + dz(i)
            if (zh(i) <= z_bot ) continue
            if (zh(i) > z_bot .and. below) then
               zh0(i) = zh(i) - dz(i)
               k1 = k
               below = .false.
! Compute mean winds below z_top
            elseif ( zh(i) < z_top ) then
                k0 = k
            else
                goto 123
            endif

         enddo
123      continue

! Lowest layer wind shear computed betw top edge and mid-layer
         k = k1
         srh(i,j) = 0.5*(va(i,j,k1)-vc(i,j))*(ua(i,j,k1-1)-ua(i,j,k1))  -  &
                    0.5*(ua(i,j,k1)-uc(i,j))*(va(i,j,k1-1)-va(i,j,k1))
         do k=k0, k1-1
            srh(i,j) = srh(i,j) + 0.5*(va(i,j,k)-vc(i,j))*(ua(i,j,k-1)-ua(i,j,k+1)) -  &
                                  0.5*(ua(i,j,k)-uc(i,j))*(va(i,j,k-1)-va(i,j,k+1))
         enddo
      enddo  ! i-loop
   enddo   ! j-loop

 end subroutine helicity_relative_CAPS


 subroutine bunkers_vector(is, ie, js, je, ng, km, zvir, sphum, uc, vc,  &
                           ua, va, delz, q, hydrostatic, pt, peln, phis, grav)

   integer, intent(in):: is, ie, js, je, ng, km, sphum
   real, intent(in):: grav, zvir
   real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,km):: pt, ua, va
   real, intent(in):: delz(is:ie,js:je,km)
   real, intent(in):: q(is-ng:ie+ng,js-ng:je+ng,km,*)
   real, intent(in):: phis(is-ng:ie+ng,js-ng:je+ng)
   real, intent(in):: peln(is:ie,km+1,js:je)
   logical, intent(in):: hydrostatic
   real, intent(out):: uc(is:ie,js:je), vc(is:ie,js:je)

   real:: rdg
   real :: zh, dz, usfc, vsfc, u6km, v6km, umn, vmn
   real :: ushr, vshr, shrmag
   integer i, j, k
   real, parameter :: bunkers_d = 7.5 ! Empirically derived parameter
   logical :: has_sfc, has_6km

   rdg = rdgas / grav

!$OMP parallel do default(none) shared(is,ie,js,je,km,hydrostatic,rdg,pt,zvir,sphum, &
!$OMP                                  peln,delz,ua,va,uc,vc) &
!$OMP                           private(zh,dz,usfc,vsfc,u6km,v6km,umn,vmn, &
!$OMP                                  ushr,vshr,shrmag)
   do j=js,je
      do i=is,ie
         zh = 0.
         usfc = 0.
         vsfc = 0.
         u6km = 0.
         v6km = 0.
         umn = 0.
         vmn = 0.

         usfc = ua(i,j,km)
         vsfc = va(i,j,km)

         do k=km,1,-1
            if ( hydrostatic ) then
                 dz = rdg*pt(i,j,k)*(1.+zvir*q(i,j,k,sphum))*(peln(i,k+1,j)-peln(i,k,j))
            else
                 dz = -delz(i,j,k)
            endif
            zh = zh + dz

            if (zh < 6000) then
                u6km = ua(i,j,k)
                v6km = va(i,j,k)

                umn = umn + ua(i,j,k)*dz
                vmn = vmn + va(i,j,k)*dz
            else
                goto 123
            endif

         enddo
123      continue

         u6km = u6km + (ua(i,j,k) - u6km) / dz * (6000. - (zh - dz))
         v6km = v6km + (va(i,j,k) - v6km) / dz * (6000. - (zh - dz))

         umn = umn / (zh - dz)
         vmn = vmn / (zh - dz)

         ushr = u6km - usfc
         vshr = v6km - vsfc
         shrmag = sqrt(ushr * ushr + vshr * vshr)
         uc(i,j) = umn + bunkers_d * vshr / shrmag
         vc(i,j) = vmn - bunkers_d * ushr / shrmag

      enddo  ! i-loop
   enddo   ! j-loop

 end subroutine bunkers_vector


 subroutine updraft_helicity(is, ie, js, je, ng, km, zvir, sphum, uh,   &
                             w, vort, delz, q, hydrostatic, pt, peln, phis, grav, z_bot, z_top)
! !INPUT PARAMETERS:
   integer, intent(in):: is, ie, js, je, ng, km, sphum
   real, intent(in):: grav, zvir, z_bot, z_top
   real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,km):: pt, w
   real, intent(in), dimension(is:ie,js:je,km):: vort
   real, intent(in):: delz(is:ie,js:je,km)
   real, intent(in):: q(is-ng:ie+ng,js-ng:je+ng,km,*)
   real, intent(in):: phis(is-ng:ie+ng,js-ng:je+ng)
   real, intent(in):: peln(is:ie,km+1,js:je)
   logical, intent(in):: hydrostatic
   real, intent(out):: uh(is:ie,js:je)   ! unit: (m/s)**2
! Coded by S.-J. Lin for CONUS regional climate simulations
! Modified for UH by LMH
!
   real:: rdg
   real, dimension(is:ie):: zh, dz, zh0
   integer i, j, k
   logical below(is:ie)

   rdg = rdgas / grav

!$OMP parallel do default(none) shared(is,ie,js,je,km,hydrostatic,rdg,pt,zvir,sphum, &
!$OMP                                  peln,delz,w,vort,uh,z_bot,z_top) &
!$OMP                          private(zh,dz,zh0,below)
   do j=js,je

      do i=is,ie
         zh(i) = 0.
         uh(i,j) = 0.
         below(i) = .true.
         zh0(i) = 0.

!        if ( phis(i,j)/grav < 1.E3 ) then
         do k=km,1,-1
            if ( hydrostatic ) then
                 dz(i) = rdg*pt(i,j,k)*(1.+zvir*q(i,j,k,sphum))*(peln(i,k+1,j)-peln(i,k,j))
            else
                 dz(i) = - delz(i,j,k)
            endif
            zh(i) = zh(i) + dz(i)
            if (zh(i) <= z_bot ) continue
            if (zh(i) > z_bot .and. below(i)) then
               uh(i,j) = vort(i,j,k)*w(i,j,k)*(zh(i) - z_bot)
               below(i) = .false.
! Compute mean winds below z_top
            elseif ( zh(i) < z_top ) then
               uh(i,j) = uh(i,j) + vort(i,j,k)*w(i,j,k)*dz(i)
            else
               uh(i,j) = uh(i,j) + vort(i,j,k)*w(i,j,k)*(z_top - (zh(i)-dz(i)) )
               goto 123
            endif
         enddo
123      continue

      enddo  ! i-loop
   enddo   ! j-loop

 end subroutine updraft_helicity



 subroutine pv_entropy(is, ie, js, je, ng, km, vort, f_d, pt, pkz, delp, grav, te)

! !INPUT PARAMETERS:
   integer, intent(in)::  is, ie, js, je, ng, km
   real, intent(in):: grav
   real, intent(in):: pt(is-ng:ie+ng,js-ng:je+ng,km)
   real, intent(in):: pkz(is:ie,js:je,km)
   real, intent(in):: delp(is-ng:ie+ng,js-ng:je+ng,km)
   real, intent(in):: f_d(is-ng:ie+ng,js-ng:je+ng)

! vort is relative vorticity as input. Becomes PV on output
   real, intent(inout):: vort(is:ie,js:je,km)
! output potential temperature at the interface so it can be used for diagnostics
   real, intent(out):: te(is:ie,js:je,km+1)

! !DESCRIPTION:
!        EPV = 1/r * (vort+f_d) * d(S)/dz; where S is a conservative scalar
!        r the fluid density, and S is chosen to be the entropy here: S = log(pt)
!        pt == potential temperature.
! Computation are performed assuming the input is on "x-y-z" Cartesian coordinate.
! The approximation made here is that the relative vorticity computed on constant
! z-surface is not that different from the hybrid sigma-p coordinate.
! See page 39, Pedlosky 1979: Geophysical Fluid Dynamics
!
! The following simplified form is strictly correct only if vort is computed on
! constant z surfaces. In addition hydrostatic approximation is made.
!        EPV = - GRAV * (vort+f_d) / del(p) * del(pt) / pt
! where del() is the vertical difference operator.
!
! Note that this differs by a factor of pk0/theta from the usual definition of PV
!
! programmer: S.-J. Lin, shian-jiann.lin@noaa.gov
!
!EOP
!---------------------------------------------------------------------
!BOC
      real w3d(is:ie,js:je,km)
      real t2(is:ie,km), delp2(is:ie,km)
      real te2(is:ie,km+1)
      integer i, j, k

#ifdef SW_DYNAMICS
!$OMP parallel do default(none) shared(is,ie,js,je,vort,grav,f_d,delp)
        do j=js,je
          do i=is,ie
            vort(i,j,1) = grav * (vort(i,j,1)+f_d(i,j)) / delp(i,j,1)
          enddo
        enddo
#else
! Compute PT at layer edges.
!$OMP parallel do default(none) shared(is,ie,js,je,km,pt,pkz,w3d,delp,te) &
!$OMP                          private(t2, delp2, te2) !fix from wfc 27aug2020
     do j=js,je
        do k=1,km
          do i=is,ie
               t2(i,k) = pt(i,j,k) / pkz(i,j,k)
              w3d(i,j,k) = t2(i,k)
            delp2(i,k) = delp(i,j,k)
          enddo
        enddo

        call ppme(t2, te2, delp2, ie-is+1, km)

        do k=1,km+1
           do i=is,ie
              te(i,j,k) = te2(i,k)
           enddo
        enddo
     enddo

!$OMP parallel do default(none) shared(is,ie,js,je,km,vort,f_d,te,w3d,delp,grav)
     do k=1,km
        do j=js,je
          do i=is,ie
! Entropy is the thermodynamic variable in the following form
            vort(i,j,k) = (vort(i,j,k)+f_d(i,j)) * ( te(i,j,k)-te(i,j,k+1) )  &
                          / ( w3d(i,j,k)*delp(i,j,k) )  * grav
          enddo
        enddo
     enddo
#endif

 end subroutine pv_entropy


 subroutine ppme(p,qe,delp,im,km)

  integer, intent(in):: im, km
  real, intent(in)::    p(im,km)
  real, intent(in):: delp(im,km)
  real, intent(out)::qe(im,km+1)

! local arrays.
      real dc(im,km),delq(im,km), a6(im,km)
      real c1, c2, c3, tmp, qmax, qmin
      real a1, a2, s1, s2, s3, s4, ss3, s32, s34, s42
      real a3, b2, sc, dm, d1, d2, f1, f2, f3, f4
      real qm, dq
      integer i, k, km1

      km1 = km - 1

      do k=2,km
       do i=1,im
         a6(i,k) = delp(i,k-1) + delp(i,k)
       enddo
      enddo

      do k=1,km1
       do i=1,im
         delq(i,k) = p(i,k+1) - p(i,k)
       enddo
      enddo

      do k=2,km1
       do i=1,im
         c1 = (delp(i,k-1)+0.5*delp(i,k))/a6(i,k+1)
         c2 = (delp(i,k+1)+0.5*delp(i,k))/a6(i,k)
         tmp = delp(i,k)*(c1*delq(i,k) + c2*delq(i,k-1)) /    &
                                    (a6(i,k)+delp(i,k+1))
         qmax = max(p(i,k-1),p(i,k),p(i,k+1)) - p(i,k)
         qmin = p(i,k) - min(p(i,k-1),p(i,k),p(i,k+1))
         dc(i,k) = sign(min(abs(tmp),qmax,qmin), tmp)
       enddo
      enddo

!****6***0*********0*********0*********0*********0*********0**********72
! 4th order interpolation of the provisional cell edge value
!****6***0*********0*********0*********0*********0*********0**********72

   do k=3,km1
      do i=1,im
         c1 = delq(i,k-1)*delp(i,k-1) / a6(i,k)
         a1 = a6(i,k-1) / (a6(i,k) + delp(i,k-1))
         a2 = a6(i,k+1) / (a6(i,k) + delp(i,k))
         qe(i,k) = p(i,k-1) + c1 + 2./(a6(i,k-1)+a6(i,k+1)) *        &
                   ( delp(i,k)*(c1*(a1 - a2)+a2*dc(i,k-1)) -         &
                                delp(i,k-1)*a1*dc(i,k  ) )
      enddo
   enddo

! three-cell parabolic subgrid distribution at model top

   do i=1,im
! three-cell PP-distribution
! Compute a,b, and c of q = aP**2 + bP + c using cell averages and delp
! a3 = a / 3
! b2 = b / 2
      s1 = delp(i,1)
      s2 = delp(i,2) + s1
!
      s3 = delp(i,2) + delp(i,3)
      s4 = s3 + delp(i,4)
      ss3 =  s3 + s1
      s32 = s3*s3
      s42 = s4*s4
      s34 = s3*s4
! model top
      a3 = (delq(i,2) - delq(i,1)*s3/s2) / (s3*ss3)
!
      if(abs(a3) .gt. 1.e-14) then
         b2 =  delq(i,1)/s2 - a3*(s1+s2)
         sc = -b2/(3.*a3)
         if(sc .lt. 0. .or. sc .gt. s1) then
             qe(i,1) = p(i,1) - s1*(a3*s1 + b2)
         else
             qe(i,1) = p(i,1) - delq(i,1)*s1/s2
         endif
      else
! Linear
         qe(i,1) = p(i,1) - delq(i,1)*s1/s2
      endif
      dc(i,1) = p(i,1) - qe(i,1)
! compute coef. for the off-centered area preserving cubic poly.
      dm = delp(i,1) / (s34*ss3*(delp(i,2)+s3)*(s4+delp(i,1)))
      f1 = delp(i,2)*s34 / ( s2*ss3*(s4+delp(i,1)) )
      f2 = (delp(i,2)+s3) * (ss3*(delp(i,2)*s3+s34+delp(i,2)*s4)   &
            + s42*(delp(i,2)+s3+s32/s2))
      f3 = -delp(i,2)*( ss3*(s32*(s3+s4)/(s4-delp(i,2))            &
            + (delp(i,2)*s3+s34+delp(i,2)*s4))                     &
            + s42*(delp(i,2)+s3) )
      f4 = ss3*delp(i,2)*s32*(delp(i,2)+s3) / (s4-delp(i,2))
      qe(i,2) = f1*p(i,1)+(f2*p(i,2)+f3*p(i,3)+f4*p(i,4))*dm
   enddo

! Bottom
! Area preserving cubic with 2nd deriv. = 0 at the surface
   do i=1,im
      d1 = delp(i,km)
      d2 = delp(i,km1)
      qm = (d2*p(i,km)+d1*p(i,km1)) / (d1+d2)
      dq = 2.*(p(i,km1)-p(i,km)) / (d1+d2)
      c1 = (qe(i,km1)-qm-d2*dq) / (d2*(2.*d2*d2+d1*(d2+3.*d1)))
      c3 = dq - 2.0*c1*(d2*(5.*d1+d2)-3.*d1**2)
      qe(i,km  ) = qm - c1*d1*d2*(d2+3.*d1)
      qe(i,km+1) = d1*(8.*c1*d1**2-c3) + qe(i,km)
   enddo

 end subroutine ppme

!#######################################################################

subroutine rh_calc (pfull, t, qv, rh, do_cmip)

   real, intent (in),  dimension(:,:) :: pfull, t, qv
   real, intent (out), dimension(:,:) :: rh
   real, dimension(size(t,1),size(t,2)) :: esat
   logical, intent(in), optional :: do_cmip

   real, parameter :: d622 = rdgas/rvgas
   real, parameter :: d378 = 1.-d622

   logical :: do_simple = .false.

! because Betts-Miller uses a simplified scheme for calculating the relative humidity

     if (do_simple) then
        call lookup_es (t, esat)
        rh(:,:) = pfull(:,:)
        rh(:,:) = MAX(rh(:,:),esat(:,:))  !limit where pfull ~ esat
        rh(:,:)=100.*qv(:,:)/(d622*esat(:,:)/rh(:,:))
     else
        if (present(do_cmip)) then
         call compute_qs (t, pfull, rh, q=qv, es_over_liq_and_ice = .true.)
         rh(:,:)=100.*qv(:,:)/rh(:,:)
        else
        call compute_qs (t, pfull, rh, q=qv)
        rh(:,:)=100.*qv(:,:)/rh(:,:)
     endif
     endif

end subroutine rh_calc

#ifdef SIMPLIFIED_THETA_E
subroutine eqv_pot(theta_e, pt, delp, delz, peln, pkz, q, is, ie, js, je, ng, npz, &
                   hydrostatic, moist)
! calculate the equvalent potential temperature
! Simplified form coded by SJL
    integer, intent(in):: is,ie,js,je,ng,npz
    real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,npz):: pt, delp, q
    real, intent(in), dimension(is:     ,js:     ,1: ):: delz
    real, intent(in), dimension(is:ie,npz+1,js:je):: peln
    real, intent(in):: pkz(is:ie,js:je,npz)
    logical, intent(in):: hydrostatic, moist
! Output:
    real, dimension(is:ie,js:je,npz), intent(out) :: theta_e  !< eqv pot
! local
    real, parameter:: tice = 273.16
#ifdef SIM_NGGPS
    real, parameter:: dc_vap = 0.
#else
    real, parameter:: dc_vap = cp_vapor - c_liq     ! = -2344.    isobaric heating/cooling
#endif
    real(kind=R_GRID), dimension(is:ie):: pd, rq
    real(kind=R_GRID) :: wfac
    integer :: i,j,k

    if ( moist ) then
         wfac = 1.
    else
         wfac = 0.
    endif

!$OMP parallel do default(none) shared(pk0,wfac,moist,pkz,is,ie,js,je,npz,pt,q,delp,peln,delz,theta_e,hydrostatic)  &
!$OMP  private(pd, rq)
    do k = 1,npz
       do j = js,je

        if ( hydrostatic ) then
            do i=is,ie
               rq(i) = max(0., wfac*q(i,j,k))
               pd(i) = (1.-rq(i))*delp(i,j,k) / (peln(i,k+1,j) - peln(i,k,j))
            enddo
        else
! Dry pressure: p = r R T
            do i=is,ie
               rq(i) = max(0., wfac*q(i,j,k))
               pd(i) = -rdgas*pt(i,j,k)*(1.-rq(i))*delp(i,j,k)/(grav*delz(i,j,k))
            enddo
        endif

        if ( moist ) then
            do i=is,ie
               rq(i) = max(0., q(i,j,k))
!              rh(i) = max(1.e-12, rq(i)/wqs(pt(i,j,k),den(i),rh(i)))   ! relative humidity
!              theta_e(i,j,k) = exp(rq(i)/cp_air*((hlv+dc_vap*(pt(i,j,k)-tice))/pt(i,j,k) -   &
!                                   rvgas*log(rh(i))) + kappa*log(1.e5/pd(i))) * pt(i,j,k)
! Simplified form: (ignoring the RH term)
#ifdef SIM_NGGPS
               theta_e(i,j,k) = pt(i,j,k)*exp(kappa*log(1.e5/pd(i))) *  &
                                          exp(rq(i)*hlv/(cp_air*pt(i,j,k)))
#else
               theta_e(i,j,k) = pt(i,j,k)*exp( rq(i)/(cp_air*pt(i,j,k))*(hlv+dc_vap*(pt(i,j,k)-tice)) &
                                             + kappa*log(1.e5/pd(i)) )
#endif
            enddo
        else
          if ( hydrostatic ) then
             do i=is,ie
                theta_e(i,j,k) = pt(i,j,k)*pk0/pkz(i,j,k)
             enddo
          else
             do i=is,ie
!               theta_e(i,j,k) = pt(i,j,k)*(1.e5/pd(i))**kappa
                theta_e(i,j,k) = pt(i,j,k)*exp( kappa*log(1.e5/pd(i)) )
             enddo
          endif
        endif
      enddo ! j-loop
    enddo   ! k-loop

end subroutine eqv_pot

#else
subroutine eqv_pot(theta_e, pt, delp, delz, peln, pkz, q, is, ie, js, je, ng, npz, &
                   hydrostatic, moist)
! calculate the equvalent potential temperature
! author: Xi.Chen@noaa.gov
! created on: 07/28/2015
! Modified by SJL
    integer, intent(in):: is,ie,js,je,ng,npz
    real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,npz):: pt, delp, q
    real, intent(in), dimension(is:     ,js:     ,1: ):: delz
    real, intent(in), dimension(is:ie,npz+1,js:je):: peln
    real, intent(in):: pkz(is:ie,js:je,npz)
    logical, intent(in):: hydrostatic, moist
! Output:
    real, dimension(is:ie,js:je,npz), intent(out) :: theta_e  !< eqv pot
! local
    real, parameter:: cv_vap = cp_vapor - rvgas  ! 1384.5
    real, parameter:: cappa_b = 0.2854
    real(kind=R_GRID):: cv_air, cappa, zvir
    real(kind=R_GRID):: p_mb(is:ie)
    real(kind=R_GRID) :: r, e, t_l, rdg, capa
    integer :: i,j,k

    cv_air =  cp_air - rdgas
    rdg = -rdgas/grav
    if ( moist ) then
         zvir = rvgas/rdgas - 1.
    else
         zvir = 0.
    endif

!$OMP parallel do default(none) shared(moist,pk0,pkz,cv_air,zvir,rdg,is,ie,js,je,npz,pt,q,delp,peln,delz,theta_e,hydrostatic)  &
!$OMP      private(cappa,p_mb, r, e, t_l, capa)
    do k = 1,npz
       cappa = cappa_b
      do j = js,je
! get pressure in mb
        if ( hydrostatic ) then
            do i=is,ie
               p_mb(i) = 0.01*delp(i,j,k) / (peln(i,k+1,j) - peln(i,k,j))
            enddo
        else
            do i=is,ie
               p_mb(i) = 0.01*rdg*delp(i,j,k)/delz(i,j,k)*pt(i,j,k)*(1.+zvir*q(i,j,k))
            enddo
        endif
        if ( moist ) then
          do i = is,ie
          cappa = rdgas/(rdgas+((1.-q(i,j,k))*cv_air+q(i,j,k)*cv_vap)/(1.+zvir*q(i,j,k)))
! get "dry" mixing ratio of m_vapor/m_tot in g/kg
          r = q(i,j,k)/(1.-q(i,j,k))*1000.
          r = max(1.e-10, r)
! get water vapor pressure
          e = p_mb(i)*r/(622.+r)
! get temperature at the lifting condensation level
! eq. 21 of Bolton 1980
          t_l = 2840./(3.5*log(pt(i,j,k))-log(e)-4.805)+55.
! get the equivalent potential temperature
!         theta_e(i,j,k) = pt(i,j,k)*exp( (cappa*(1.-0.28e-3*r)*log(1000./p_mb(i))) * &
!                          exp( (3.376/t_l-0.00254)*r*(1.+0.81e-3*r) )
           capa = cappa*(1. - r*0.28e-3)
           theta_e(i,j,k) = exp( (3.376/t_l-0.00254)*r*(1.+r*0.81e-3) )*pt(i,j,k)*(1000./p_mb(i))**capa
          enddo
        else
          if ( hydrostatic ) then
             do i = is,ie
                theta_e(i,j,k) = pt(i,j,k)*pk0/pkz(i,j,k)
             enddo
          else
             do i = is,ie
                theta_e(i,j,k) = pt(i,j,k)*exp( kappa*log(1000./p_mb(i)) )
             enddo
          endif
        endif
      enddo ! j-loop
    enddo   ! k-loop

end subroutine eqv_pot

#endif  SIMPLIFIED_THETA_E

  subroutine compute_brn(ua, va, delp, delz, cape, bd, npz, Time)

    type(fv_grid_bounds_type), intent(IN) :: bd
    integer, intent(IN) :: npz
    type(time_type), intent(in) :: Time
    real, dimension(bd%isd:bd%ied,bd%jsd:bd%jed, npz), intent(IN) :: ua, va, delp
    real, dimension(bd%isc:bd%iec,bd%jsc:bd%jec, npz), intent(IN) :: delz
    real, dimension(bd%isc:bd%iec,bd%jsc:bd%jec), intent(IN) :: cape
    real, dimension(bd%isc:bd%iec,bd%jsc:bd%jec) :: brn, shear06

    real, dimension(bd%isc:bd%iec,bd%jsc:bd%jec) :: u06, u005, v06, v005, ht, m06, m005
    real :: tmp1, tmp2
    logical :: used

    integer :: i,j,k

    integer :: isc,  iec,  jsc,  jec
    integer :: isd, ied, jsd, jed

    isc  = bd%is
    iec  = bd%ie
    jsc  = bd%js
    jec  = bd%je
    isd = bd%isd
    ied = bd%ied
    jsd = bd%jsd
    jed = bd%jed


    !Bulk-Richardson number: CAPE / 0.5* (U_{0--6km} - U_{0--500m})**2
    do j=jsc,jec
       do i=isc,iec
          u06(i,j) = 0.
          u005(i,j) = 0.
          v06(i,j) = 0.
          v005(i,j) = 0.
          m06(i,j) = 0.
          m005(i,j) = 0.
          ht(i,j) = -delz(i,j,npz)*0.5
       enddo
    enddo
    do k=npz,2,-1
    do j=jsc,jec
    do i=isc,iec
       if (ht(i,j) <= 6000.) then
          u06(i,j) = u06(i,j) + delp(i,j,k)*ua(i,j,k)
          v06(i,j) = v06(i,j) + delp(i,j,k)*va(i,j,k)
          m06(i,j) = m06(i,j) + delp(i,j,k)
       endif
       if (ht(i,j) <= 500.) then
          u005(i,j) = u005(i,j) + delp(i,j,k)*ua(i,j,k)
          v005(i,j) = v005(i,j) + delp(i,j,k)*va(i,j,k)
          m005(i,j) = m005(i,j) + delp(i,j,k)
       endif
       ht(i,j) = ht(i,j) - 0.5*(delz(i,j,k) + delz(i,j,k-1))
    enddo
    enddo
    enddo
    do j=jsc,jec
    do i=isc,iec
       tmp1 = u005(i,j)/m005(i,j) - u06(i,j)/m06(i,j)
       tmp2 = v005(i,j)/m005(i,j) - v06(i,j)/m06(i,j)
       shear06(i,j) = sqrt(tmp1*tmp1 + tmp2*tmp2)
       brn(i,j) = cape(i,j)/(0.5*max(0.1,shear06(i,j)*shear06(i,j)))
    enddo
    enddo

    if (id_brn > 0) used=send_data(id_brn, brn, Time)
    if (id_shear06 > 0) used=send_data(id_shear06, shear06, Time)


  end subroutine compute_brn

 subroutine max_vorticity(is, ie, js, je, ng, km, zvir, sphum, delz, q, hydrostatic, &
                          pt, peln, phis, grav, vort, maxvort, z_bot, z_top)
   integer, intent(in):: is, ie, js, je, ng, km, sphum
   real, intent(in):: grav, zvir, z_bot, z_top
   real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,km):: pt
   real, intent(in), dimension(is:ie,js:je,km):: vort
   real, intent(in):: delz(is:ie,js:je,km)
   real, intent(in):: q(is-ng:ie+ng,js-ng:je+ng,km,*)
   real, intent(in):: phis(is-ng:ie+ng,js-ng:je+ng)
   real, intent(in):: peln(is:ie,km+1,js:je)
   logical, intent(in):: hydrostatic
   real, intent(inout), dimension(is:ie,js:je):: maxvort

   real:: rdg
   real, dimension(is:ie):: zh, dz, zh0
   integer i, j, k,klevel
   logical below(is:ie)

   rdg = rdgas / grav

   do j=js,je

      do i=is,ie
         zh(i) = 0.
         below(i) = .true.
         zh0(i) = 0.

     K_LOOP:do k=km,1,-1
            if ( hydrostatic ) then
#ifdef MULTI_GASES
                 dz(i) = rdg*pt(i,j,k)*virq(q(i,j,k,1:num_gas))*(peln(i,k+1,j)-peln(i,k,j))
#else
                 dz(i) = rdg*pt(i,j,k)*(1.+zvir*q(i,j,k,sphum))*(peln(i,k+1,j)-peln(i,k,j))
#endif
            else
                 dz(i) = - delz(i,j,k)
            endif
            zh(i) = zh(i) + dz(i)
            if (zh(i) <= z_bot ) continue
            if (zh(i) > z_bot .and. below(i)) then
               maxvort(i,j) = max(maxvort(i,j),vort(i,j,k))
               below(i) = .false.
            elseif ( zh(i) < z_top ) then
               maxvort(i,j) = max(maxvort(i,j),vort(i,j,k))
            else
               maxvort(i,j) = max(maxvort(i,j),vort(i,j,k))
               EXIT K_LOOP
            endif
         enddo K_LOOP
!      maxvorthy1(i,j)=max(maxvorthy1(i,j),vort(i,j,km))
      enddo  ! i-loop
   enddo   ! j-loop


 end subroutine max_vorticity

 subroutine max_uh(is, ie, js, je, ng, km, zvir, sphum, uphmax,uphmin,   &
                  w, vort, delz, q, hydrostatic, pt, peln, phis, grav, z_bot, z_top)
! !INPUT PARAMETERS:
   integer, intent(in):: is, ie, js, je, ng, km, sphum
   real, intent(in):: grav, zvir, z_bot, z_top
   real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,km):: pt, w
   real, intent(in), dimension(is:ie,js:je,km):: vort
   real, intent(in):: delz(is:ie,js:je,km)
   real, intent(in):: q(is-ng:ie+ng,js-ng:je+ng,km,*)
   real, intent(in):: phis(is-ng:ie+ng,js-ng:je+ng)
   real, intent(in):: peln(is:ie,km+1,js:je)
   logical, intent(in):: hydrostatic
   real :: uh(is:ie,js:je)   ! unit: (m/s)**2
   real, intent(inout), dimension(is:ie,js:je):: uphmax,uphmin
! Coded by S.-J. Lin for CONUS regional climate simulations
! Modified for UH by LMH
!
   real:: rdg
   real, dimension(is:ie):: zh, dz, zh0
   integer i, j, k
   logical below(is:ie)

   rdg = rdgas / grav
   do j=js,je

      do i=is,ie
         zh(i) = 0.
         uh(i,j) = 0.
         below(i) = .true.
         zh0(i) = 0.

  K_LOOP:do k=km,1,-1
            if ( hydrostatic ) then
#ifdef MULTI_GASES
                 dz(i) = rdg*pt(i,j,k)*virq(q(i,j,k,1:num_gas))*(peln(i,k+1,j)-peln(i,k,j))
#else
                 dz(i) = rdg*pt(i,j,k)*(1.+zvir*q(i,j,k,sphum))*(peln(i,k+1,j)-peln(i,k,j))
#endif
            else
                 dz(i) = - delz(i,j,k)
            endif
            zh(i) = zh(i) + dz(i)
            if (zh(i) <= z_bot ) continue
            if (zh(i) > z_bot .and. below(i)) then
               if(w(i,j,k).lt.0)then
                  uh(i,j) = 0.
                  EXIT K_LOOP
               endif
               uh(i,j) = vort(i,j,k)*w(i,j,k)*(zh(i) - z_bot)
               below(i) = .false.
! Compute mean winds below z_top
            elseif ( zh(i) < z_top ) then
               if(w(i,j,k).lt.0)then
                  uh(i,j) = 0.
                  EXIT K_LOOP
               endif
               uh(i,j) = uh(i,j) + vort(i,j,k)*w(i,j,k)*dz(i)
            else
               if(w(i,j,k).lt.0)then
                  uh(i,j) = 0.
                  EXIT K_LOOP
               endif
               uh(i,j) = uh(i,j) + vort(i,j,k)*w(i,j,k)*(z_top - (zh(i)-dz(i)) )
               EXIT K_LOOP
            endif
         enddo K_LOOP
        if (uh(i,j) > uphmax(i,j)) then
           uphmax(i,j) = uh(i,j)
        elseif (uh(i,j) < uphmin(i,j)) then
           uphmin(i,j) = uh(i,j)
        endif
      enddo  ! i-loop
   enddo   ! j-loop

 end subroutine max_uh

 subroutine max_vv(is,ie,js,je,npz,ng,up2,dn2,pe,w)
! !INPUT PARAMETERS:
   integer, intent(in):: is, ie, js, je, ng, npz
   integer :: i,j,k
   real, intent(in), dimension(is-ng:ie+ng,js-ng:je+ng,npz):: w
   real, intent(in):: pe(is-1:ie+1,npz+1,js-1:je+1)
   real, intent(inout), dimension(is:ie,js:je):: up2,dn2
      do j=js,je
         do i=is,ie
            do k=3,npz
              if (pe(i,k,j) >= 100.e2) then
                  up2(i,j) = max(up2(i,j),w(i,j,k))
                  dn2(i,j) = min(dn2(i,j),w(i,j,k))
              endif
             enddo
         enddo
      enddo
 end subroutine max_vv

!#######################################################################

 subroutine fv_diag_init_gn(Atm)
   type(fv_atmos_type), intent(inout), target :: Atm

   if (Atm%grid_Number > 1) then
      write(gn,"(A2,I1)") " g", Atm%grid_number
   else
      gn = ""
   end if

 end subroutine fv_diag_init_gn

!-----------------------------------------------------------------------
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc
!-----------------------------------------------------------------------

    subroutine getcape( nk , p , t , dz, q, the, cape , cin, source_in )
    implicit none

    integer, intent(in) :: nk
    real, dimension(nk), intent(in) :: p,t,dz,q,the
    real, intent(out) :: cape,cin
    integer, intent(IN), OPTIONAL :: source_in

!-----------------------------------------------------------------------
!
!  getcape - a fortran90 subroutine to calculate Convective Available
!            Potential Energy (CAPE) from a sounding.
!
!  Version 1.02                           Last modified:  10 October 2008
!
!  Author:  George H. Bryan
!           Mesoscale and Microscale Meteorology Division
!           National Center for Atmospheric Research
!           Boulder, Colorado, USA
!           gbryan@ucar.edu
!
!  Disclaimer:  This code is made available WITHOUT WARRANTY.
!
!  References:  Bolton (1980, MWR, p. 1046) (constants and definitions)
!               Bryan and Fritsch (2004, MWR, p. 2421) (ice processes)
!
!-----------------------------------------------------------------------
!
!  Input:     nk - number of levels in the sounding (integer)
!
!           p - one-dimensional array of pressure (Pa) (real)
!
!           t - one-dimensional array of temperature (K) (real)
!
!           dz - one-dimensional array of height thicknesses (m) (real)
!
!           q - one-dimensional array of specific humidity (kg/kg) (real)
!
!          source - source parcel:
!                   1 = surface (default)
!                   2 = most unstable (max theta-e)
!                   3 = mixed-layer (specify ml_depth)
!
!  Output:  cape - Convective Available Potential Energy (J/kg) (real)
!
!            cin - Convective Inhibition (J/kg) (real)
!
!-----------------------------------------------------------------------
!  User options:

    real, parameter :: pinc = 10000.0   ! Pressure increment (Pa)
                                      ! (smaller number yields more accurate
                                      !  results,larger number makes code
                                      !  go faster)


    real, parameter :: ml_depth =  200.0  ! depth (m) of mixed layer
                                          ! for source=3

    integer, parameter :: adiabat = 1   ! Formulation of moist adiabat:
                                        ! 1 = pseudoadiabatic, liquid only
                                        ! 2 = reversible, liquid only
                                        ! 3 = pseudoadiabatic, with ice
                                        ! 4 = reversible, with ice

!-----------------------------------------------------------------------
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc
!-----------------------------------------------------------------------
!            No need to modify anything below here:
!-----------------------------------------------------------------------
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc
!-----------------------------------------------------------------------

    integer :: source = 1
    logical :: doit,ice,cloud,not_converged
    integer :: k,kmin,n,nloop,i,orec
    real, dimension(nk) :: pi,th,thv,z,pt,pb,pc,pn,ptv

    real :: maxthe,parea,narea,lfc
    real :: th1,p1,t1,qv1,ql1,qi1,b1,pi1,thv1,qt,dp,frac
    real :: th2,p2,t2,qv2,ql2,qi2,b2,pi2,thv2
    real :: thlast,fliq,fice,tbar,qvbar,qlbar,qibar,lhv,lhs,lhf,rm,cpm
    real*8 :: avgth,avgqv

!-----------------------------------------------------------------------

    real, parameter :: g     = 9.81
    real, parameter :: p00   = 100000.0
    real, parameter :: cp    = 1005.7
    real, parameter :: rd    = 287.04
    real, parameter :: rv    = 461.5
    real, parameter :: xlv   = 2501000.0
    real, parameter :: xls   = 2836017.0
    real, parameter :: t0    = 273.15
    real, parameter :: cpv   = 1875.0
    real, parameter :: cpl   = 4190.0
    real, parameter :: cpi   = 2118.636
    real, parameter :: lv1   = xlv+(cpl-cpv)*t0
    real, parameter :: lv2   = cpl-cpv
    real, parameter :: ls1   = xls+(cpi-cpv)*t0
    real, parameter :: ls2   = cpi-cpv

    real, parameter :: rp00  = 1.0/p00
    real, parameter :: eps   = rd/rv
    real, parameter :: reps  = rv/rd
    real, parameter :: rddcp = rd/cp
    real, parameter :: cpdrd = cp/rd
    real, parameter :: cpdg  = cp/g

    real, parameter :: converge = 0.1

    integer, parameter :: debug_level =   0

    if (present(source_in)) source = source_in

!-----------------------------------------------------------------------

!---- convert p,t to mks units; get pi,th,thv ----!

    do k=1,nk
       pi(k) = (p(k)*rp00)**rddcp
       th(k) = t(k)/pi(k)
      thv(k) = th(k)*(1.0+reps*q(k))/(1.0+q(k))
    enddo

!---- get height using the hydrostatic equation ----!

    z(nk) = 0.5*dz(nk)
    do k=nk-1,1,-1
      z(k) = z(k+1) + 0.5*(dz(k+1)+dz(k))
    enddo

!---- find source parcel ----!

  IF(source.eq.1)THEN
    ! use surface parcel
    kmin = nk

  ELSEIF(source.eq.2)THEN
    ! use most unstable parcel (max theta-e)

    IF(p(1).lt.50000.0)THEN
      ! first report is above 500 mb ... just use the first level reported
      kmin = nk
      maxthe = the(nk)
    ELSE
      ! find max thetae below 500 mb
      maxthe = 0.0
      do k=nk,1,-1
        if(p(k).ge.50000.0)then
          if( the(nk).gt.maxthe )then
            maxthe = the(nk)
            kmin = k
          endif
        endif
      enddo
    ENDIF
    if(debug_level.ge.100) print *,'  kmin,maxthe = ',kmin,maxthe

  ELSE

    print *
    print *,'  Unknown value for source'
    print *
    print *,'  source = ',source
    print *
    call mpp_error(FATAL, " Unknown CAPE source")

  ENDIF

!---- define parcel properties at initial location ----!
    narea = 0.0

  if( (source.eq.1).or.(source.eq.2) )then
    k    = kmin
    th2  = th(kmin)
    pi2  = pi(kmin)
    p2   = p(kmin)
    t2   = t(kmin)
    thv2 = thv(kmin)
    qv2  = q(kmin)
    b2   = 0.0
  elseif( source.eq.3 )then
    k    = kmin
    th2  = avgth
    qv2  = avgqv
    thv2 = th2*(1.0+reps*qv2)/(1.0+qv2)
    pi2  = pi(kmin)
    p2   = p(kmin)
    t2   = th2*pi2
    b2   = g*( thv2-thv(kmin) )/thv(kmin)
  endif

    ql2 = 0.0
    qi2 = 0.0
    qt  = qv2

    cape = 0.0
    cin  = 0.0
    lfc  = 0.0

    doit = .true.
    cloud = .false.
    if(adiabat.eq.1.or.adiabat.eq.2)then
      ice = .false.
    else
      ice = .true.
    endif

!      the = getthe(p2,t2,t2,qv2)
!      if(debug_level.ge.100) print *,'  the = ',the

!---- begin ascent of parcel ----!

      if(debug_level.ge.100)then
        print *,'  Start loop:'
        print *,'  p2,th2,qv2 = ',p2,th2,qv2
      endif

    do while( doit .and. (k.gt.1) )

        k = k-1
       b1 =  b2

       dp = p(k)-p(k-1)

      if( dp.lt.pinc )then
        nloop = 1
      else
        nloop = 1 + int( dp/pinc )
        dp = dp/float(nloop)
      endif

      do n=1,nloop

         p1 =  p2
         t1 =  t2
        pi1 = pi2
        th1 = th2
        qv1 = qv2
        ql1 = ql2
        qi1 = qi2
        thv1 = thv2

        p2 = p2 - dp
        pi2 = (p2*rp00)**rddcp

        thlast = th1
        i = 0
        not_converged = .true.

        do while( not_converged )
          i = i + 1
          t2 = thlast*pi2
          if(ice)then
            fliq = max(min((t2-233.15)/(273.15-233.15),1.0),0.0)
            fice = 1.0-fliq
          else
            fliq = 1.0
            fice = 0.0
          endif
          qv2 = min( qt , fliq*getqvs(p2,t2) + fice*getqvi(p2,t2) )
          qi2 = max( fice*(qt-qv2) , 0.0 )
          ql2 = max( qt-qv2-qi2 , 0.0 )

          tbar  = 0.5*(t1+t2)
          qvbar = 0.5*(qv1+qv2)
          qlbar = 0.5*(ql1+ql2)
          qibar = 0.5*(qi1+qi2)

          lhv = lv1-lv2*tbar
          lhs = ls1-ls2*tbar
          lhf = lhs-lhv

          rm=rd+rv*qvbar
          cpm=cp+cpv*qvbar+cpl*qlbar+cpi*qibar
          th2=th1*exp(  lhv*(ql2-ql1)/(cpm*tbar)     &
                       +lhs*(qi2-qi1)/(cpm*tbar)     &
                       +(rm/cpm-rd/cp)*alog(p2/p1) )

          if(i.gt.90) print *,i,th2,thlast,th2-thlast
          if(i.gt.100)then
            print *,'  getcape() error:  lack of convergence, stopping iteration'
            not_converged = .false.
          endif
          if( abs(th2-thlast).gt.converge )then
            thlast=thlast+0.3*(th2-thlast)
          else
            not_converged = .false.
          endif
       enddo

        ! Latest pressure increment is complete.  Calculate some
        ! important stuff:

        if( ql2.ge.1.0e-10 ) cloud = .true.

        IF(adiabat.eq.1.or.adiabat.eq.3)THEN
          ! pseudoadiabat
          qt  = qv2
          ql2 = 0.0
          qi2 = 0.0
        ELSEIF(adiabat.le.0.or.adiabat.ge.5)THEN
          print *,'  getcape(): Undefined adiabat'
          stop 10000
        ENDIF

      enddo

      thv2 = th2*(1.0+reps*qv2)/(1.0+qv2+ql2+qi2)
        b2 = g*( thv2-thv(k) )/thv(k)

!      the = getthe(p2,t2,t2,qv2)

      ! Get contributions to CAPE and CIN:

      if( (b2.ge.0.0) .and. (b1.lt.0.0) )then
        ! first trip into positive area
        !ps = p(k-1)+(p(k)-p(k-1))*(0.0-b1)/(b2-b1)
        frac = b2/(b2-b1)
        parea =  0.5*b2*dz(k)*frac
        narea = narea-0.5*b1*dz(k)*(1.0-frac)
        if(debug_level.ge.200)then
          print *,'      b1,b2 = ',b1,b2
          !print *,'      p1,ps,p2 = ',p(k-1),ps,p(k)
          print *,'      frac = ',frac
          print *,'      parea = ',parea
          print *,'      narea = ',narea
        endif
        cin  = cin  + narea
        narea = 0.0
      elseif( (b2.lt.0.0) .and. (b1.gt.0.0) )then
        ! first trip into neg area
        !ps = p(k-1)+(p(k)-p(k-1))*(0.0-b1)/(b2-b1)
        frac = b1/(b1-b2)
        parea =  0.5*b1*dz(k)*frac
        narea = -0.5*b2*dz(k)*(1.0-frac)
        if(debug_level.ge.200)then
          print *,'      b1,b2 = ',b1,b2
          !print *,'      p1,ps,p2 = ',p(k-1),ps,p(k)
          print *,'      frac = ',frac
          print *,'      parea = ',parea
          print *,'      narea = ',narea
        endif
      elseif( b2.lt.0.0 )then
        ! still collecting negative buoyancy
        parea =  0.0
        narea = narea-0.5*dz(k)*(b1+b2)
      else
        ! still collecting positive buoyancy
        parea =  0.5*dz(k)*(b1+b2)
        narea =  0.0
      endif

      cape = cape + max(0.0,parea)

      if(debug_level.ge.200)then
        write(6,102) p2,b1,b2,cape,cin,cloud
102     format(5(f13.4),2x,l1)
      endif

      if( (p(k).le.10000.0).and.(b2.lt.0.0) )then
        ! stop if b < 0 and p < 100 mb
        doit = .false.
      endif

    enddo

!---- All done ----!

    return
  end subroutine getcape

!-----------------------------------------------------------------------
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc
!-----------------------------------------------------------------------

  real function getqvs(p,t)
    implicit none

    real :: p,t,es

    real, parameter :: eps = 287.04/461.5

    es = 611.2*exp(17.67*(t-273.15)/(t-29.65))
    getqvs = eps*es/(p-es)

    return
  end function getqvs

!-----------------------------------------------------------------------
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc
!-----------------------------------------------------------------------

  real function getqvi(p,t)
    implicit none

    real :: p,t,es

    real, parameter :: eps = 287.04/461.5

    es = 611.2*exp(21.8745584*(t-273.15)/(t-7.66))
    getqvi = eps*es/(p-es)

    return
  end function getqvi

!-----------------------------------------------------------------------
!ccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccccc
!-----------------------------------------------------------------------

  !f1p: calculate molecular weight of ambient (air+h2o) air. required for vmr
  !sum_wat: sum of water tracers
  function Mw_air_0d(sum_wat) result(out)

    implicit none
    real,intent(in)                                           :: sum_wat
    real                                                      :: out

    out = WTMAIR*WTMH2O/((1-sum_wat)*WTMH2O+sum_wat*WTMAIR)
  end function Mw_air_0d

  function Mw_air_3d(sum_wat) result(out)

    implicit none
    real,dimension(:,:,:),intent(in)                                           :: sum_wat
    real, dimension(size(sum_wat,1),size(sum_wat,2),size(sum_wat,3))           :: out

    out = WTMAIR*WTMH2O/((1.-sum_wat)*WTMH2O+sum_wat*WTMAIR)
  end function Mw_air_3d

  subroutine make_plevs( field, plevs, pe, npz, iv, id_plev, id_levs, nplev, bd, Time, field_plev_out)

    type(fv_grid_bounds_type), intent(IN) :: bd
    integer, intent(IN) :: npz, nplev
    real, intent(IN) :: field(bd%is:bd%ie,bd%js:bd%je,npz) !Data domain only!!
    real, intent(IN) :: plevs(nplev) !plevs and pe *must* be the same quantity (pe, peln, theta, etc.)
    real, intent(IN) :: pe(bd%is:bd%ie,npz+1,bd%js:bd%je) !Data domain only!!
    integer, intent(IN) :: iv, id_plev, id_levs(nplev)
    type(time_type), intent(IN) :: Time
    real, intent(OUT), OPTIONAL :: field_plev_out(bd%isc:bd%iec,bd%jsc:bd%jec,nplev)

    real :: field_plev(bd%isc:bd%iec,bd%jsc:bd%jec,nplev)
    integer, dimension(nplev) :: id1
    integer :: i, used
    integer :: isc,  iec,  jsc,  jec

    isc  = bd%is
    iec  = bd%ie
    jsc  = bd%js
    jec  = bd%je

    id1(:) = 1.

    if (ANY(id_levs > 0)) then
       call cs3_interpolator(isc,iec,jsc,jec,npz, field, nplev,    &
            plevs, pe, id_levs, field_plev, iv)
       do i=1,nplev
          if (id_levs(i)>0) used=send_data(id_levs(i), field_plev(isc:iec,jsc:jec,i), Time)
       enddo
    endif

    if (id_plev > 0) then
         call cs3_interpolator(isc,iec,jsc,jec,npz, field, nplev,    &
                              plevs, pe, id1, field_plev, iv)
         used=send_data(id_plev, field_plev(isc:iec,jsc:jec,:), Time)
    endif

    if (present(field_plev_out)) then
       field_plev_out = field_plev
    endif

  end subroutine make_plevs

end module fv_diagnostics_mod