! $Id: aaam_bud.F90 2408 2015-12-14 10:43:09Z aborella $ SUBROUTINE aaam_bud(iam, nlon, nlev, rjour, rsec, rea, rg, ome, plat, plon, & phis, dragu, liftu, phyu, dragv, liftv, phyv, p, u, v, aam, torsfc) USE dimphy USE mod_grid_phy_lmdz, ONLY: nbp_lon, nbp_lat, klon_glo IMPLICIT NONE ! ====================================================================== ! Auteur(s): F.Lott (LMD/CNRS) date: 20031020 ! Object: Compute different terms of the axial AAAM Budget. ! No outputs, every AAM quantities are written on the IAM ! File. ! Modif : I.Musat (LMD/CNRS) date : 20041020 ! Outputs : axial components of wind AAM "aam" and total surface torque ! "torsfc", ! but no write in the iam file. ! WARNING: Only valid for regular rectangular grids. ! REMARK: CALL DANS PHYSIQ AFTER lift_noro: ! CALL aaam_bud (27,klon,klev,rjourvrai,gmtime, ! C ra,rg,romega, ! C rlat,rlon,pphis, ! C zustrdr,zustrli,zustrph, ! C zvstrdr,zvstrli,zvstrph, ! C paprs,u,v) ! ====================================================================== ! Explicit Arguments: ! ================== ! iam-----input-I-File number where AAMs and torques are written ! It is a formatted file that has been opened ! in physiq.F ! nlon----input-I-Total number of horizontal points that get into physics ! nlev----input-I-Number of vertical levels ! rjour -R-Jour compte depuis le debut de la simu (run.def) ! rsec -R-Seconde de la journee ! rea -R-Earth radius ! rg -R-gravity constant ! ome -R-Earth rotation rate ! plat ---input-R-Latitude en degres ! plon ---input-R-Longitude en degres ! phis ---input-R-Geopotential at the ground ! dragu---input-R-orodrag stress (zonal) ! liftu---input-R-orolift stress (zonal) ! phyu----input-R-Stress total de la physique (zonal) ! dragv---input-R-orodrag stress (Meridional) ! liftv---input-R-orolift stress (Meridional) ! phyv----input-R-Stress total de la physique (Meridional) ! p-------input-R-Pressure (Pa) at model half levels ! u-------input-R-Horizontal wind (m/s) ! v-------input-R-Meridional wind (m/s) ! aam-----output-R-Axial Wind AAM (=raam(3)) ! torsfc--output-R-Total surface torque (=tmou(3)+tsso(3)+tbls(3)) ! Implicit Arguments: ! =================== ! nbp_lon--common-I: Number of longitude intervals ! (nbp_lat-1)--common-I: Number of latitude intervals ! klon-common-I: Number of points seen by the physics ! nbp_lon*(nbp_lat-2)+2 for instance ! klev-common-I: Number of vertical layers ! ====================================================================== ! Local Variables: ! ================ ! dlat-----R: Latitude increment (Radians) ! dlon-----R: Longitude increment (Radians) ! raam ---R: Wind AAM (3 Components, 1 & 2 Equatoriales; 3 Axiale) ! oaam ---R: Mass AAM (3 Components, 1 & 2 Equatoriales; 3 Axiale) ! tmou-----R: Resolved Mountain torque (3 components) ! tsso-----R: Parameterised Moutain drag torque (3 components) ! tbls-----R: Parameterised Boundary layer torque (3 components) ! LOCAL ARRAY: ! =========== ! zs ---R: Topographic height ! ps ---R: Surface Pressure ! ub ---R: Barotropic wind zonal ! vb ---R: Barotropic wind meridional ! zlat ---R: Latitude in radians ! zlon ---R: Longitude in radians ! ====================================================================== ! ARGUMENTS INTEGER iam, nlon, nlev REAL, INTENT (IN) :: rjour, rsec, rea, rg, ome REAL plat(nlon), plon(nlon), phis(nlon) REAL dragu(nlon), liftu(nlon), phyu(nlon) REAL dragv(nlon), liftv(nlon), phyv(nlon) REAL p(nlon, nlev+1), u(nlon, nlev), v(nlon, nlev) ! Variables locales: INTEGER i, j, k, l REAL xpi, hadley, hadday REAL dlat, dlon REAL raam(3), oaam(3), tmou(3), tsso(3), tbls(3) INTEGER iax ! IM ajout aam, torsfc ! aam = composante axiale du Wind AAM raam ! torsfc = composante axiale de (tmou+tsso+tbls) REAL aam, torsfc REAL zs(801, 401), ps(801, 401) REAL ub(801, 401), vb(801, 401) REAL ssou(801, 401), ssov(801, 401) REAL blsu(801, 401), blsv(801, 401) REAL zlon(801), zlat(401) CHARACTER (LEN=20) :: modname = 'aaam_bud' CHARACTER (LEN=80) :: abort_message ! PUT AAM QUANTITIES AT ZERO: IF (nbp_lon+1>801 .OR. nbp_lat>401) THEN abort_message = 'Pb de dimension dans aaam_bud' CALL abort_physic(modname, abort_message, 1) END IF xpi = acos(-1.) hadley = 1.E18 hadday = 1.E18*24.*3600. IF(klon_glo.EQ.1) THEN dlat = xpi ELSE dlat = xpi/real(nbp_lat-1) ENDIF dlon = 2.*xpi/real(nbp_lon) DO iax = 1, 3 oaam(iax) = 0. raam(iax) = 0. tmou(iax) = 0. tsso(iax) = 0. tbls(iax) = 0. END DO ! MOUNTAIN HEIGHT, PRESSURE AND BAROTROPIC WIND: ! North pole values (j=1): l = 1 ub(1, 1) = 0. vb(1, 1) = 0. DO k = 1, nlev ub(1, 1) = ub(1, 1) + u(l, k)*(p(l,k)-p(l,k+1))/rg vb(1, 1) = vb(1, 1) + v(l, k)*(p(l,k)-p(l,k+1))/rg END DO zlat(1) = plat(l)*xpi/180. DO i = 1, nbp_lon + 1 zs(i, 1) = phis(l)/rg ps(i, 1) = p(l, 1) ub(i, 1) = ub(1, 1) vb(i, 1) = vb(1, 1) ssou(i, 1) = dragu(l) + liftu(l) ssov(i, 1) = dragv(l) + liftv(l) blsu(i, 1) = phyu(l) - dragu(l) - liftu(l) blsv(i, 1) = phyv(l) - dragv(l) - liftv(l) END DO DO j = 2, nbp_lat-1 ! Values at Greenwich (Periodicity) zs(nbp_lon+1, j) = phis(l+1)/rg ps(nbp_lon+1, j) = p(l+1, 1) ssou(nbp_lon+1, j) = dragu(l+1) + liftu(l+1) ssov(nbp_lon+1, j) = dragv(l+1) + liftv(l+1) blsu(nbp_lon+1, j) = phyu(l+1) - dragu(l+1) - liftu(l+1) blsv(nbp_lon+1, j) = phyv(l+1) - dragv(l+1) - liftv(l+1) zlon(nbp_lon+1) = -plon(l+1)*xpi/180. zlat(j) = plat(l+1)*xpi/180. ub(nbp_lon+1, j) = 0. vb(nbp_lon+1, j) = 0. DO k = 1, nlev ub(nbp_lon+1, j) = ub(nbp_lon+1, j) + u(l+1, k)*(p(l+1,k)-p(l+1,k+1))/rg vb(nbp_lon+1, j) = vb(nbp_lon+1, j) + v(l+1, k)*(p(l+1,k)-p(l+1,k+1))/rg END DO DO i = 1, nbp_lon l = l + 1 zs(i, j) = phis(l)/rg ps(i, j) = p(l, 1) ssou(i, j) = dragu(l) + liftu(l) ssov(i, j) = dragv(l) + liftv(l) blsu(i, j) = phyu(l) - dragu(l) - liftu(l) blsv(i, j) = phyv(l) - dragv(l) - liftv(l) zlon(i) = plon(l)*xpi/180. ub(i, j) = 0. vb(i, j) = 0. DO k = 1, nlev ub(i, j) = ub(i, j) + u(l, k)*(p(l,k)-p(l,k+1))/rg vb(i, j) = vb(i, j) + v(l, k)*(p(l,k)-p(l,k+1))/rg END DO END DO END DO ! South Pole IF (nbp_lat-1>1) THEN l = l + 1 ub(1, nbp_lat) = 0. vb(1, nbp_lat) = 0. DO k = 1, nlev ub(1, nbp_lat) = ub(1, nbp_lat) + u(l, k)*(p(l,k)-p(l,k+1))/rg vb(1, nbp_lat) = vb(1, nbp_lat) + v(l, k)*(p(l,k)-p(l,k+1))/rg END DO zlat(nbp_lat) = plat(l)*xpi/180. DO i = 1, nbp_lon + 1 zs(i, nbp_lat) = phis(l)/rg ps(i, nbp_lat) = p(l, 1) ssou(i, nbp_lat) = dragu(l) + liftu(l) ssov(i, nbp_lat) = dragv(l) + liftv(l) blsu(i, nbp_lat) = phyu(l) - dragu(l) - liftu(l) blsv(i, nbp_lat) = phyv(l) - dragv(l) - liftv(l) ub(i, nbp_lat) = ub(1, nbp_lat) vb(i, nbp_lat) = vb(1, nbp_lat) END DO END IF ! MOMENT ANGULAIRE DO j = 1, nbp_lat-1 DO i = 1, nbp_lon raam(1) = raam(1) - rea**3*dlon*dlat*0.5*(cos(zlon(i))*sin(zlat(j))*cos & (zlat(j))*ub(i,j)+cos(zlon(i))*sin(zlat(j+1))*cos(zlat(j+ & 1))*ub(i,j+1)) + rea**3*dlon*dlat*0.5*(sin(zlon(i))*cos(zlat(j))*vb(i & ,j)+sin(zlon(i))*cos(zlat(j+1))*vb(i,j+1)) oaam(1) = oaam(1) - ome*rea**4*dlon*dlat/rg*0.5*(cos(zlon(i))*cos(zlat( & j))**2*sin(zlat(j))*ps(i,j)+cos(zlon(i))*cos(zlat(j+ & 1))**2*sin(zlat(j+1))*ps(i,j+1)) raam(2) = raam(2) - rea**3*dlon*dlat*0.5*(sin(zlon(i))*sin(zlat(j))*cos & (zlat(j))*ub(i,j)+sin(zlon(i))*sin(zlat(j+1))*cos(zlat(j+ & 1))*ub(i,j+1)) - rea**3*dlon*dlat*0.5*(cos(zlon(i))*cos(zlat(j))*vb(i & ,j)+cos(zlon(i))*cos(zlat(j+1))*vb(i,j+1)) oaam(2) = oaam(2) - ome*rea**4*dlon*dlat/rg*0.5*(sin(zlon(i))*cos(zlat( & j))**2*sin(zlat(j))*ps(i,j)+sin(zlon(i))*cos(zlat(j+ & 1))**2*sin(zlat(j+1))*ps(i,j+1)) raam(3) = raam(3) + rea**3*dlon*dlat*0.5*(cos(zlat(j))**2*ub(i,j)+cos( & zlat(j+1))**2*ub(i,j+1)) oaam(3) = oaam(3) + ome*rea**4*dlon*dlat/rg*0.5*(cos(zlat(j))**3*ps(i,j & )+cos(zlat(j+1))**3*ps(i,j+1)) END DO END DO ! COUPLE DES MONTAGNES: DO j = 1, nbp_lat-1 DO i = 1, nbp_lon tmou(1) = tmou(1) - rea**2*dlon*0.5*sin(zlon(i))*(zs(i,j)-zs(i,j+1))*( & cos(zlat(j+1))*ps(i,j+1)+cos(zlat(j))*ps(i,j)) tmou(2) = tmou(2) + rea**2*dlon*0.5*cos(zlon(i))*(zs(i,j)-zs(i,j+1))*( & cos(zlat(j+1))*ps(i,j+1)+cos(zlat(j))*ps(i,j)) END DO END DO DO j = 2, nbp_lat-1 DO i = 1, nbp_lon tmou(1) = tmou(1) + rea**2*dlat*0.5*sin(zlat(j))*(zs(i+1,j)-zs(i,j))*( & cos(zlon(i+1))*ps(i+1,j)+cos(zlon(i))*ps(i,j)) tmou(2) = tmou(2) + rea**2*dlat*0.5*sin(zlat(j))*(zs(i+1,j)-zs(i,j))*( & sin(zlon(i+1))*ps(i+1,j)+sin(zlon(i))*ps(i,j)) tmou(3) = tmou(3) - rea**2*dlat*0.5*cos(zlat(j))*(zs(i+1,j)-zs(i,j))*( & ps(i+1,j)+ps(i,j)) END DO END DO ! COUPLES DES DIFFERENTES FRICTION AU SOL: l = 1 DO j = 2, nbp_lat-1 DO i = 1, nbp_lon l = l + 1 tsso(1) = tsso(1) - rea**3*cos(zlat(j))*dlon*dlat*ssou(i, j)*sin(zlat(j & ))*cos(zlon(i)) + rea**3*cos(zlat(j))*dlon*dlat*ssov(i, j)*sin(zlon(i & )) tsso(2) = tsso(2) - rea**3*cos(zlat(j))*dlon*dlat*ssou(i, j)*sin(zlat(j & ))*sin(zlon(i)) - rea**3*cos(zlat(j))*dlon*dlat*ssov(i, j)*cos(zlon(i & )) tsso(3) = tsso(3) + rea**3*cos(zlat(j))*dlon*dlat*ssou(i, j)*cos(zlat(j & )) tbls(1) = tbls(1) - rea**3*cos(zlat(j))*dlon*dlat*blsu(i, j)*sin(zlat(j & ))*cos(zlon(i)) + rea**3*cos(zlat(j))*dlon*dlat*blsv(i, j)*sin(zlon(i & )) tbls(2) = tbls(2) - rea**3*cos(zlat(j))*dlon*dlat*blsu(i, j)*sin(zlat(j & ))*sin(zlon(i)) - rea**3*cos(zlat(j))*dlon*dlat*blsv(i, j)*cos(zlon(i & )) tbls(3) = tbls(3) + rea**3*cos(zlat(j))*dlon*dlat*blsu(i, j)*cos(zlat(j & )) END DO END DO ! write(*,*) 'AAM',rsec, ! write(*,*) 'AAM',rjour+rsec/86400., ! c raam(3)/hadday,oaam(3)/hadday, ! c tmou(3)/hadley,tsso(3)/hadley,tbls(3)/hadley ! write(iam,100)rjour+rsec/86400., ! c raam(1)/hadday,oaam(1)/hadday, ! c tmou(1)/hadley,tsso(1)/hadley,tbls(1)/hadley, ! c raam(2)/hadday,oaam(2)/hadday, ! c tmou(2)/hadley,tsso(2)/hadley,tbls(2)/hadley, ! c raam(3)/hadday,oaam(3)/hadday, ! c tmou(3)/hadley,tsso(3)/hadley,tbls(3)/hadley 100 FORMAT (F12.5, 15(1X,F12.5)) ! write(iam+1,*)((zs(i,j),i=1,nbp_lon),j=1,nbp_lat) ! write(iam+1,*)((ps(i,j),i=1,nbp_lon),j=1,nbp_lat) ! write(iam+1,*)((ub(i,j),i=1,nbp_lon),j=1,nbp_lat) ! write(iam+1,*)((vb(i,j),i=1,nbp_lon),j=1,nbp_lat) ! write(iam+1,*)((ssou(i,j),i=1,nbp_lon),j=1,nbp_lat) ! write(iam+1,*)((ssov(i,j),i=1,nbp_lon),j=1,nbp_lat) ! write(iam+1,*)((blsu(i,j),i=1,nbp_lon),j=1,nbp_lat) ! write(iam+1,*)((blsv(i,j),i=1,nbp_lon),j=1,nbp_lat) aam = raam(3) torsfc = tmou(3) + tsso(3) + tbls(3) RETURN END SUBROUTINE aaam_bud