5 |
contains |
contains |
6 |
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|
7 |
SUBROUTINE bilan_dyn(ps, masse, pk, flux_u, flux_v, teta, phi, ucov, vcov, & |
SUBROUTINE bilan_dyn(ps, masse, pk, flux_u, flux_v, teta, phi, ucov, vcov, & |
8 |
trac, dt_app, dt_cum) |
trac) |
9 |
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10 |
! From LMDZ4/libf/dyn3d/bilan_dyn.F, version 1.5 2005/03/16 |
! From LMDZ4/libf/dyn3d/bilan_dyn.F, version 1.5 2005/03/16 10:12:17 |
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! 10:12:17 fairhead |
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11 |
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12 |
! Sous-programme consacré à des diagnostics dynamiques de base |
! Sous-programme consacré à des diagnostics dynamiques de base. |
13 |
! De façon générale, les moyennes des scalaires Q sont pondérées par |
! De façon générale, les moyennes des scalaires Q sont pondérées |
14 |
! la masse. Les flux de masse sont, eux, simplement moyennés. |
! par la masse. Les flux de masse sont, eux, simplement moyennés. |
15 |
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16 |
USE histcom, ONLY: histbeg_totreg, histdef, histend, histvert |
USE comconst, ONLY: cpp |
17 |
USE calendar, ONLY: ymds2ju |
USE comgeom, ONLY: constang_2d, cu_2d, cv_2d |
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USE histwrite_m, ONLY: histwrite |
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18 |
USE dimens_m, ONLY: iim, jjm, llm |
USE dimens_m, ONLY: iim, jjm, llm |
19 |
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USE histwrite_m, ONLY: histwrite |
20 |
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use init_dynzon_m, only: ncum, fileid, znom, ntr, nq, nom |
21 |
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use massbar_m, only: massbar |
22 |
USE paramet_m, ONLY: iip1, jjp1 |
USE paramet_m, ONLY: iip1, jjp1 |
23 |
USE comconst, ONLY: cpp |
|
24 |
USE comvert, ONLY: presnivs |
real, intent(in):: ps(iip1, jjp1) |
25 |
USE comgeom, ONLY: constang_2d, cu_2d, cv_2d, rlatv |
real, intent(in):: masse(iip1, jjp1, llm), pk(iip1, jjp1, llm) |
26 |
USE temps, ONLY: annee_ref, day_ref, itau_dyn |
real, intent(in):: flux_u(iip1, jjp1, llm) |
27 |
USE inigrads_m, ONLY: inigrads |
real, intent(in):: flux_v(iip1, jjm, llm) |
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USE nr_util, ONLY: pi |
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! Arguments: |
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real, intent(in):: dt_app, dt_cum |
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real ps(iip1, jjp1) |
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real masse(iip1, jjp1, llm), pk(iip1, jjp1, llm) |
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real flux_u(iip1, jjp1, llm) |
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real flux_v(iip1, jjm, llm) |
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28 |
real, intent(in):: teta(iip1, jjp1, llm) |
real, intent(in):: teta(iip1, jjp1, llm) |
29 |
real phi(iip1, jjp1, llm) |
real, intent(in):: phi(iip1, jjp1, llm) |
30 |
real ucov(iip1, jjp1, llm) |
real, intent(in):: ucov(:, :, :) ! (iip1, jjp1, llm) |
31 |
real vcov(iip1, jjm, llm) |
real, intent(in):: vcov(iip1, jjm, llm) |
32 |
real, intent(in):: trac(:, :, :) ! (iim + 1, jjm + 1, llm) |
real, intent(in):: trac(:, :, :) ! (iim + 1, jjm + 1, llm) |
33 |
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34 |
! Local: |
! Local: |
35 |
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36 |
integer:: icum = 0 |
integer:: icum = 0 |
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integer, save:: ncum |
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logical:: first = .true. |
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real zz, zqy, zfactv(jjm, llm) |
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integer, parameter:: nQ = 7 |
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character(len=4), parameter:: nom(nQ) = (/'T ', 'gz ', 'K ', 'ang ', & |
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'u ', 'ovap', 'un '/) |
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character(len=5), parameter:: unites(nQ) = (/'K ', 'm2/s2', 'm2/s2', & |
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'ang ', 'm/s ', 'kg/kg', 'un '/) |
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real:: time = 0. |
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37 |
integer:: itau = 0 |
integer:: itau = 0 |
38 |
real ww |
real qy, factv(jjm, llm) |
39 |
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|
40 |
! Variables dynamiques intermédiaires |
! Variables dynamiques intermédiaires |
41 |
REAL vcont(iip1, jjm, llm), ucont(iip1, jjp1, llm) |
REAL vcont(iip1, jjm, llm), ucont(iip1, jjp1, llm) |
42 |
REAL ang(iip1, jjp1, llm), unat(iip1, jjp1, llm) |
REAL ang(iip1, jjp1, llm), unat(iip1, jjp1, llm) |
43 |
REAL massebx(iip1, jjp1, llm), masseby(iip1, jjm, llm) |
REAL massebx(iip1, jjp1, llm), masseby(iip1, jjm, llm) |
44 |
REAL w(iip1, jjp1, llm), ecin(iip1, jjp1, llm), convm(iip1, jjp1, llm) |
REAL ecin(iip1, jjp1, llm) |
45 |
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46 |
! Champ contenant les scalaires advectés |
! Champ contenant les scalaires advectés |
47 |
real Q(iip1, jjp1, llm, nQ) |
real Q(iip1, jjp1, llm, nQ) |
54 |
real, save:: Q_cum(iip1, jjp1, llm, nQ) |
real, save:: Q_cum(iip1, jjp1, llm, nQ) |
55 |
real, save:: flux_uQ_cum(iip1, jjp1, llm, nQ) |
real, save:: flux_uQ_cum(iip1, jjp1, llm, nQ) |
56 |
real, save:: flux_vQ_cum(iip1, jjm, llm, nQ) |
real, save:: flux_vQ_cum(iip1, jjm, llm, nQ) |
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real dQ(iip1, jjp1, llm, nQ) |
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57 |
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58 |
! champs de tansport en moyenne zonale |
! champs de tansport en moyenne zonale |
59 |
integer itr |
integer itr |
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integer, parameter:: ntr = 5 |
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character(len=10), save:: znom(ntr, nQ) |
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character(len=26), save:: znoml(ntr, nQ) |
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character(len=12), save:: zunites(ntr, nQ) |
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60 |
integer, parameter:: iave = 1, itot = 2, immc = 3, itrs = 4, istn = 5 |
integer, parameter:: iave = 1, itot = 2, immc = 3, itrs = 4, istn = 5 |
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character(len=3), parameter:: ctrs(ntr) = (/' ', 'TOT', 'MMC', 'TRS', & |
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'STN'/) |
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61 |
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62 |
real zvQ(jjm, llm, ntr, nQ), zvQtmp(jjm, llm) |
real vq(jjm, llm, ntr, nQ), vqtmp(jjm, llm) |
63 |
real zavQ(jjm, 2: ntr, nQ), psiQ(jjm, llm + 1, nQ) |
real avq(jjm, 2: ntr, nQ), psiQ(jjm, llm + 1, nQ) |
64 |
real zmasse(jjm, llm) |
real zmasse(jjm, llm) |
65 |
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real v(jjm, llm), psi(jjm, llm + 1) |
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real zv(jjm, llm), psi(jjm, llm + 1) |
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66 |
integer i, j, l, iQ |
integer i, j, l, iQ |
67 |
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! Initialisation du fichier contenant les moyennes zonales. |
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integer, save:: fileid |
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integer thoriid, zvertiid |
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real zjulian |
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integer zan, dayref |
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real rlong(jjm), rlatg(jjm) |
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68 |
!----------------------------------------------------------------- |
!----------------------------------------------------------------- |
69 |
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!!print *, "Call sequence information: bilan_dyn" |
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! Initialisation |
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time = time + dt_app |
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itau = itau + 1 |
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first_call: if (first) then |
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! initialisation des fichiers |
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first = .false. |
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! ncum est la frequence de stokage en pas de temps |
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ncum = dt_cum / dt_app |
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if (abs(ncum * dt_app - dt_cum) > 1e-5 * dt_app) then |
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print *, 'Problème : le pas de cumul doit être multiple du pas' |
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print *, 'dt_app = ', dt_app |
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print *, 'dt_cum = ', dt_cum |
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stop 1 |
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endif |
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call inigrads(i_f=4, x=(/0./), fx=180./pi, xmin=0., xmax=0., y=rlatv, & |
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ymin=-90., ymax=90., fy=180./pi, z=presnivs, fz=1., dt=dt_cum, & |
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file='dynzon', titlel='dyn_zon ') |
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! Initialisation du fichier contenant les moyennes zonales |
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zan = annee_ref |
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dayref = day_ref |
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CALL ymds2ju(zan, 1, dayref, 0.0, zjulian) |
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rlong = 0. |
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rlatg = rlatv*180./pi |
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call histbeg_totreg('dynzon', rlong(:1), rlatg, 1, 1, 1, jjm, itau_dyn, & |
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zjulian, dt_cum, thoriid, fileid) |
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! Appel à histvert pour la grille verticale |
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call histvert(fileid, 'presnivs', 'Niveaux sigma', 'mb', llm, presnivs, & |
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zvertiid) |
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! Appels à histdef pour la définition des variables à sauvegarder |
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do iQ = 1, nQ |
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do itr = 1, ntr |
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if (itr == 1) then |
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znom(itr, iQ) = nom(iQ) |
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znoml(itr, iQ) = nom(iQ) |
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zunites(itr, iQ) = unites(iQ) |
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else |
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znom(itr, iQ) = ctrs(itr)//'v'//nom(iQ) |
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znoml(itr, iQ) = 'transport : v * '//nom(iQ)//' '//ctrs(itr) |
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zunites(itr, iQ) = 'm/s * '//unites(iQ) |
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endif |
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enddo |
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enddo |
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! Déclarations des champs avec dimension verticale |
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do iQ = 1, nQ |
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do itr = 1, ntr |
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call histdef(fileid, znom(itr, iQ), znoml(itr, iQ), & |
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zunites(itr, iQ), 1, jjm, thoriid, llm, 1, llm, zvertiid, & |
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'ave(X)', dt_cum, dt_cum) |
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enddo |
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! Declarations pour les fonctions de courant |
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call histdef(fileid, 'psi'//nom(iQ), 'stream fn. '//znoml(itot, iQ), & |
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zunites(itot, iQ), 1, jjm, thoriid, llm, 1, llm, zvertiid, & |
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'ave(X)', dt_cum, dt_cum) |
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enddo |
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! Declarations pour les champs de transport d'air |
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call histdef(fileid, 'masse', 'masse', & |
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'kg', 1, jjm, thoriid, llm, 1, llm, zvertiid, & |
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'ave(X)', dt_cum, dt_cum) |
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call histdef(fileid, 'v', 'v', & |
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'm/s', 1, jjm, thoriid, llm, 1, llm, zvertiid, & |
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'ave(X)', dt_cum, dt_cum) |
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! Declarations pour les fonctions de courant |
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call histdef(fileid, 'psi', 'stream fn. MMC ', 'mega t/s', & |
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1, jjm, thoriid, llm, 1, llm, zvertiid, & |
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'ave(X)', dt_cum, dt_cum) |
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! Declaration des champs 1D de transport en latitude |
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do iQ = 1, nQ |
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do itr = 2, ntr |
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call histdef(fileid, 'a'//znom(itr, iQ), znoml(itr, iQ), & |
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zunites(itr, iQ), 1, jjm, thoriid, 1, 1, 1, -99, & |
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'ave(X)', dt_cum, dt_cum) |
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enddo |
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enddo |
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CALL histend(fileid) |
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endif first_call |
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70 |
! Calcul des champs dynamiques |
! Calcul des champs dynamiques |
71 |
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72 |
! Énergie cinétique |
! Énergie cinétique |
75 |
CALL enercin(vcov, ucov, vcont, ucont, ecin) |
CALL enercin(vcov, ucov, vcont, ucont, ecin) |
76 |
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77 |
! moment cinétique |
! moment cinétique |
78 |
do l = 1, llm |
forall (l = 1: llm) |
79 |
ang(:, :, l) = ucov(:, :, l) + constang_2d |
ang(:, :, l) = ucov(:, :, l) + constang_2d |
80 |
unat(:, :, l) = ucont(:, :, l)*cu_2d |
unat(:, :, l) = ucont(:, :, l) * cu_2d |
81 |
enddo |
end forall |
82 |
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|
83 |
Q(:, :, :, 1) = teta * pk / cpp |
Q(:, :, :, 1) = teta * pk / cpp |
84 |
Q(:, :, :, 2) = phi |
Q(:, :, :, 2) = phi |
100 |
flux_uQ_cum = 0. |
flux_uQ_cum = 0. |
101 |
endif |
endif |
102 |
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103 |
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itau = itau + 1 |
104 |
icum = icum + 1 |
icum = icum + 1 |
105 |
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106 |
! Accumulation des flux de masse horizontaux |
! Accumulation des flux de masse horizontaux |
108 |
masse_cum = masse_cum + masse |
masse_cum = masse_cum + masse |
109 |
flux_u_cum = flux_u_cum + flux_u |
flux_u_cum = flux_u_cum + flux_u |
110 |
flux_v_cum = flux_v_cum + flux_v |
flux_v_cum = flux_v_cum + flux_v |
111 |
do iQ = 1, nQ |
forall (iQ = 1: nQ) Q_cum(:, :, :, iQ) = Q_cum(:, :, :, iQ) & |
112 |
Q_cum(:, :, :, iQ) = Q_cum(:, :, :, iQ) + Q(:, :, :, iQ)*masse |
+ Q(:, :, :, iQ) * masse |
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enddo |
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! FLUX ET TENDANCES |
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113 |
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114 |
! Flux longitudinal |
! Flux longitudinal |
115 |
forall (iQ = 1: nQ, i = 1: iim) flux_uQ_cum(i, :, :, iQ) & |
forall (iQ = 1: nQ, i = 1: iim) flux_uQ_cum(i, :, :, iQ) & |
122 |
= flux_vQ_cum(:, j, :, iQ) & |
= flux_vQ_cum(:, j, :, iQ) & |
123 |
+ flux_v(:, j, :) * 0.5 * (Q(:, j, :, iQ) + Q(:, j + 1, :, iQ)) |
+ flux_v(:, j, :) * 0.5 * (Q(:, j, :, iQ) + Q(:, j + 1, :, iQ)) |
124 |
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! tendances |
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! convergence horizontale |
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call convflu(flux_uQ_cum, flux_vQ_cum, llm*nQ, dQ) |
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! calcul de la vitesse verticale |
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call convmas(flux_u_cum, flux_v_cum, convm) |
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CALL vitvert(convm, w) |
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do iQ = 1, nQ |
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do l = 1, llm-1 |
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do j = 1, jjp1 |
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do i = 1, iip1 |
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ww = -0.5*w(i, j, l + 1)*(Q(i, j, l, iQ) + Q(i, j, l + 1, iQ)) |
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dQ(i, j, l, iQ) = dQ(i, j, l, iQ)-ww |
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dQ(i, j, l + 1, iQ) = dQ(i, j, l + 1, iQ) + ww |
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enddo |
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enddo |
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enddo |
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enddo |
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! PAS DE TEMPS D'ECRITURE |
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125 |
writing_step: if (icum == ncum) then |
writing_step: if (icum == ncum) then |
126 |
! Normalisation |
! Normalisation |
127 |
do iQ = 1, nQ |
forall (iQ = 1: nQ) Q_cum(:, :, :, iQ) = Q_cum(:, :, :, iQ) / masse_cum |
128 |
Q_cum(:, :, :, iQ) = Q_cum(:, :, :, iQ)/masse_cum |
ps_cum = ps_cum / ncum |
129 |
enddo |
masse_cum = masse_cum / ncum |
130 |
zz = 1. / real(ncum) |
flux_u_cum = flux_u_cum / ncum |
131 |
ps_cum = ps_cum*zz |
flux_v_cum = flux_v_cum / ncum |
132 |
masse_cum = masse_cum*zz |
flux_uQ_cum = flux_uQ_cum / ncum |
133 |
flux_u_cum = flux_u_cum*zz |
flux_vQ_cum = flux_vQ_cum / ncum |
|
flux_v_cum = flux_v_cum*zz |
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flux_uQ_cum = flux_uQ_cum*zz |
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flux_vQ_cum = flux_vQ_cum*zz |
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dQ = dQ*zz |
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! A retravailler eventuellement |
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! division de dQ par la masse pour revenir aux bonnes grandeurs |
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do iQ = 1, nQ |
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dQ(:, :, :, iQ) = dQ(:, :, :, iQ)/masse_cum |
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enddo |
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134 |
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135 |
! Transport méridien |
! Transport méridien |
136 |
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137 |
! cumul zonal des masses des mailles |
! Cumul zonal des masses des mailles |
138 |
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|
139 |
zv = 0. |
v = 0. |
140 |
zmasse = 0. |
zmasse = 0. |
141 |
call massbar(masse_cum, massebx, masseby) |
call massbar(masse_cum, massebx, masseby) |
142 |
do l = 1, llm |
do l = 1, llm |
143 |
do j = 1, jjm |
do j = 1, jjm |
144 |
do i = 1, iim |
do i = 1, iim |
145 |
zmasse(j, l) = zmasse(j, l) + masseby(i, j, l) |
zmasse(j, l) = zmasse(j, l) + masseby(i, j, l) |
146 |
zv(j, l) = zv(j, l) + flux_v_cum(i, j, l) |
v(j, l) = v(j, l) + flux_v_cum(i, j, l) |
147 |
enddo |
enddo |
148 |
zfactv(j, l) = cv_2d(1, j)/zmasse(j, l) |
factv(j, l) = cv_2d(1, j) / zmasse(j, l) |
149 |
enddo |
enddo |
150 |
enddo |
enddo |
151 |
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152 |
! Transport dans le plan latitude-altitude |
! Transport dans le plan latitude-altitude |
153 |
|
|
154 |
zvQ = 0. |
vq = 0. |
155 |
psiQ = 0. |
psiQ = 0. |
156 |
do iQ = 1, nQ |
do iQ = 1, nQ |
157 |
zvQtmp = 0. |
vqtmp = 0. |
158 |
do l = 1, llm |
do l = 1, llm |
159 |
do j = 1, jjm |
do j = 1, jjm |
160 |
! Calcul des moyennes zonales du transort total et de zvQtmp |
! Calcul des moyennes zonales du transport total et de vqtmp |
161 |
do i = 1, iim |
do i = 1, iim |
162 |
zvQ(j, l, itot, iQ) = zvQ(j, l, itot, iQ) & |
vq(j, l, itot, iQ) = vq(j, l, itot, iQ) & |
163 |
+ flux_vQ_cum(i, j, l, iQ) |
+ flux_vQ_cum(i, j, l, iQ) |
164 |
zqy = 0.5 * (Q_cum(i, j, l, iQ) * masse_cum(i, j, l) & |
qy = 0.5 * (Q_cum(i, j, l, iQ) * masse_cum(i, j, l) & |
165 |
+ Q_cum(i, j + 1, l, iQ) * masse_cum(i, j + 1, l)) |
+ Q_cum(i, j + 1, l, iQ) * masse_cum(i, j + 1, l)) |
166 |
zvQtmp(j, l) = zvQtmp(j, l) + flux_v_cum(i, j, l) * zqy & |
vqtmp(j, l) = vqtmp(j, l) + flux_v_cum(i, j, l) * qy & |
167 |
/ (0.5 * (masse_cum(i, j, l) + masse_cum(i, j + 1, l))) |
/ (0.5 * (masse_cum(i, j, l) + masse_cum(i, j + 1, l))) |
168 |
zvQ(j, l, iave, iQ) = zvQ(j, l, iave, iQ) + zqy |
vq(j, l, iave, iQ) = vq(j, l, iave, iQ) + qy |
169 |
enddo |
enddo |
170 |
! Decomposition |
! Decomposition |
171 |
zvQ(j, l, iave, iQ) = zvQ(j, l, iave, iQ)/zmasse(j, l) |
vq(j, l, iave, iQ) = vq(j, l, iave, iQ) / zmasse(j, l) |
172 |
zvQ(j, l, itot, iQ) = zvQ(j, l, itot, iQ)*zfactv(j, l) |
vq(j, l, itot, iQ) = vq(j, l, itot, iQ) * factv(j, l) |
173 |
zvQtmp(j, l) = zvQtmp(j, l)*zfactv(j, l) |
vqtmp(j, l) = vqtmp(j, l) * factv(j, l) |
174 |
zvQ(j, l, immc, iQ) = zv(j, l)*zvQ(j, l, iave, iQ)*zfactv(j, l) |
vq(j, l, immc, iQ) = v(j, l) * vq(j, l, iave, iQ) * factv(j, l) |
175 |
zvQ(j, l, itrs, iQ) = zvQ(j, l, itot, iQ)-zvQtmp(j, l) |
vq(j, l, itrs, iQ) = vq(j, l, itot, iQ) - vqtmp(j, l) |
176 |
zvQ(j, l, istn, iQ) = zvQtmp(j, l)-zvQ(j, l, immc, iQ) |
vq(j, l, istn, iQ) = vqtmp(j, l) - vq(j, l, immc, iQ) |
177 |
enddo |
enddo |
178 |
enddo |
enddo |
179 |
! fonction de courant meridienne pour la quantite Q |
! Fonction de courant méridienne pour la quantité Q |
180 |
do l = llm, 1, -1 |
do l = llm, 1, -1 |
181 |
do j = 1, jjm |
do j = 1, jjm |
182 |
psiQ(j, l, iQ) = psiQ(j, l + 1, iQ) + zvQ(j, l, itot, iQ) |
psiQ(j, l, iQ) = psiQ(j, l + 1, iQ) + vq(j, l, itot, iQ) |
183 |
enddo |
enddo |
184 |
enddo |
enddo |
185 |
enddo |
enddo |
186 |
|
|
187 |
! fonction de courant pour la circulation meridienne moyenne |
! Fonction de courant pour la circulation méridienne moyenne |
188 |
psi = 0. |
psi = 0. |
189 |
do l = llm, 1, -1 |
do l = llm, 1, -1 |
190 |
do j = 1, jjm |
do j = 1, jjm |
191 |
psi(j, l) = psi(j, l + 1) + zv(j, l) |
psi(j, l) = psi(j, l + 1) + v(j, l) |
192 |
zv(j, l) = zv(j, l)*zfactv(j, l) |
v(j, l) = v(j, l) * factv(j, l) |
193 |
enddo |
enddo |
194 |
enddo |
enddo |
195 |
|
|
196 |
! sorties proprement dites |
! Sorties proprement dites |
197 |
do iQ = 1, nQ |
do iQ = 1, nQ |
198 |
do itr = 1, ntr |
do itr = 1, ntr |
199 |
call histwrite(fileid, znom(itr, iQ), itau, zvQ(:, :, itr, iQ)) |
call histwrite(fileid, znom(itr, iQ), itau, vq(:, :, itr, iQ)) |
200 |
enddo |
enddo |
201 |
call histwrite(fileid, 'psi'//nom(iQ), itau, psiQ(:, :llm, iQ)) |
call histwrite(fileid, 'psi' // nom(iQ), itau, psiQ(:, :llm, iQ)) |
202 |
enddo |
enddo |
203 |
|
|
204 |
call histwrite(fileid, 'masse', itau, zmasse) |
call histwrite(fileid, 'masse', itau, zmasse) |
205 |
call histwrite(fileid, 'v', itau, zv) |
call histwrite(fileid, 'v', itau, v) |
206 |
psi = psi*1.e-9 |
psi = psi * 1e-9 |
207 |
call histwrite(fileid, 'psi', itau, psi(:, :llm)) |
call histwrite(fileid, 'psi', itau, psi(:, :llm)) |
208 |
|
|
209 |
! Moyenne verticale |
! Intégrale verticale |
210 |
|
|
211 |
forall (iQ = 1: nQ, itr = 2: ntr) zavQ(:, itr, iQ) & |
forall (iQ = 1: nQ, itr = 2: ntr) avq(:, itr, iQ) & |
212 |
= sum(zvQ(:, :, itr, iQ) * zmasse, dim=2) / sum(zmasse, dim=2) |
= sum(vq(:, :, itr, iQ) * zmasse, dim=2) / cv_2d(1, :) |
213 |
|
|
214 |
do iQ = 1, nQ |
do iQ = 1, nQ |
215 |
do itr = 2, ntr |
do itr = 2, ntr |
216 |
call histwrite(fileid, 'a'//znom(itr, iQ), itau, zavQ(:, itr, iQ)) |
call histwrite(fileid, 'a' // znom(itr, iQ), itau, avq(:, itr, iQ)) |
217 |
enddo |
enddo |
218 |
enddo |
enddo |
219 |
|
|
|
! On doit pouvoir tracer systematiquement la fonction de courant. |
|
220 |
icum = 0 |
icum = 0 |
221 |
endif writing_step |
endif writing_step |
222 |
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