source: LMDZ6/branches/Amaury_dev/libf/dyn3d/friction.F90 @ 5105

! $Id: friction.F90 5105 2024-07-23 17:14:34Z abarral $

!=======================================================================
SUBROUTINE friction(ucov, vcov, pdt)

  USE control_mod
  USE IOIPSL
  USE comconst_mod, ONLY: pi
  IMPLICIT NONE

  !=======================================================================

  !   Friction for the Newtonian case:
  !   --------------------------------
  !    2 possibilities (depending on flag 'friction_type'
  ! friction_type=0 : A friction that is only applied to the lowermost
  !                   atmospheric layer
  ! friction_type=1 : Friction applied on all atmospheric layer (but
  !   (default)       with stronger magnitude near the surface; see
  !                   iniacademic.F)
  !=======================================================================

  include "dimensions.h"
  include "paramet.h"
  include "comgeom2.h"
  include "iniprint.h"
  include "academic.h"

  ! arguments:
  REAL, INTENT(out) :: ucov(iip1, jjp1, llm)
  REAL, INTENT(out) :: vcov(iip1, jjm, llm)
  REAL, INTENT(in) :: pdt ! time step

  ! local variables:

  REAL :: modv(iip1, jjp1), zco, zsi
  REAL :: vpn, vps, upoln, upols, vpols, vpoln
  REAL :: u2(iip1, jjp1), v2(iip1, jjm)
  INTEGER :: i, j, l
  REAL, PARAMETER :: cfric = 1.e-5
  LOGICAL, SAVE :: firstcall = .TRUE.
  INTEGER, SAVE :: friction_type = 1
  CHARACTER(len = 20) :: modname = "friction"
  CHARACTER(len = 80) :: abort_message

  IF (firstcall) THEN
    ! ! set friction type
    CALL getin("friction_type", friction_type)
    if ((friction_type<0).or.(friction_type>1)) then
      abort_message = "wrong friction type"
      write(lunout, *)'Friction: wrong friction type', friction_type
      CALL abort_gcm(modname, abort_message, 42)
    endif
    firstcall = .FALSE.
  ENDIF

  if (friction_type==0) then
    !   calcul des composantes au carre du vent naturel
    do j = 1, jjp1
      do i = 1, iip1
        u2(i, j) = ucov(i, j, 1) * ucov(i, j, 1) * unscu2(i, j)
      enddo
    enddo
    do j = 1, jjm
      do i = 1, iip1
        v2(i, j) = vcov(i, j, 1) * vcov(i, j, 1) * unscv2(i, j)
      enddo
    enddo

    !   calcul du module de V en dehors des poles
    do j = 2, jjm
      do i = 2, iip1
        modv(i, j) = sqrt(0.5 * (u2(i - 1, j) + u2(i, j) + v2(i, j - 1) + v2(i, j)))
      enddo
      modv(1, j) = modv(iip1, j)
    enddo

    !   les deux composantes du vent au pole sont obtenues comme
    !   premiers modes de fourier de v pres du pole
    upoln = 0.
    vpoln = 0.
    upols = 0.
    vpols = 0.
    do i = 2, iip1
      zco = cos(rlonv(i)) * (rlonu(i) - rlonu(i - 1))
      zsi = sin(rlonv(i)) * (rlonu(i) - rlonu(i - 1))
      vpn = vcov(i, 1, 1) / cv(i, 1)
      vps = vcov(i, jjm, 1) / cv(i, jjm)
      upoln = upoln + zco * vpn
      vpoln = vpoln + zsi * vpn
      upols = upols + zco * vps
      vpols = vpols + zsi * vps
    enddo
    vpn = sqrt(upoln * upoln + vpoln * vpoln) / pi
    vps = sqrt(upols * upols + vpols * vpols) / pi
    do i = 1, iip1
      ! modv(i,1)=vpn
      ! modv(i,jjp1)=vps
      modv(i, 1) = modv(i, 2)
      modv(i, jjp1) = modv(i, jjm)
    enddo

    !   calcul du frottement au sol.
    do j = 2, jjm
      do i = 1, iim
        ucov(i, j, 1) = ucov(i, j, 1) &
                - cfric * pdt * 0.5 * (modv(i + 1, j) + modv(i, j)) * ucov(i, j, 1)
      enddo
      ucov(iip1, j, 1) = ucov(1, j, 1)
    enddo
    do j = 1, jjm
      do i = 1, iip1
        vcov(i, j, 1) = vcov(i, j, 1) &
                - cfric * pdt * 0.5 * (modv(i, j + 1) + modv(i, j)) * vcov(i, j, 1)
      enddo
      vcov(iip1, j, 1) = vcov(1, j, 1)
    enddo
  endif ! of if (friction_type.eq.0)

  if (friction_type==1) then
    do l = 1, llm
      ucov(:, :, l) = ucov(:, :, l) * (1. - pdt * kfrict(l))
      vcov(:, :, l) = vcov(:, :, l) * (1. - pdt * kfrict(l))
    enddo
  endif


END SUBROUTINE friction