c c $Header$ c SUBROUTINE physiq (nlon,nlev,nqmax , . debut,lafin,rjourvrai,rjour_ecri,gmtime,pdtphys, . paprs,pplay,pphi,pphis,paire,presnivs,clesphy0, . u,v,t,qx, . omega, cufi, cvfi, . d_u, d_v, d_t, d_qx, d_ps) USE ioipsl USE histcom USE writephys IMPLICIT none c====================================================================== c c Auteur(s) Z.X. Li (LMD/CNRS) date: 19930818 c c Objet: Moniteur general de la physique du modele cAA Modifications quant aux traceurs : cAA - uniformisation des parametrisations ds phytrac cAA - stockage des moyennes des champs necessaires cAA en mode traceur off-line c====================================================================== c modif ( P. Le Van , 12/10/98 ) c c Arguments: c c nlon----input-I-nombre de points horizontaux c nlev----input-I-nombre de couches verticales c nqmax---input-I-nombre de traceurs (y compris vapeur d'eau) = 1 c debut---input-L-variable logique indiquant le premier passage c lafin---input-L-variable logique indiquant le dernier passage c rjour---input-R-numero du jour de l'experience c gmtime--input-R-temps universel dans la journee (0 a 86400 s) c pdtphys-input-R-pas d'integration pour la physique (seconde) c paprs---input-R-pression pour chaque inter-couche (en Pa) c pplay---input-R-pression pour le mileu de chaque couche (en Pa) c pphi----input-R-geopotentiel de chaque couche (g z) (reference sol) c pphis---input-R-geopotentiel du sol c paire---input-R-aire de chaque maille c presnivs-input_R_pressions approximat. des milieux couches ( en PA) c u-------input-R-vitesse dans la direction X (de O a E) en m/s c v-------input-R-vitesse Y (de S a N) en m/s c t-------input-R-temperature (K) c qx------input-R-humidite specifique (kg/kg) et d'autres traceurs c d_t_dyn-input-R-tendance dynamique pour "t" (K/s) c d_q_dyn-input-R-tendance dynamique pour "q" (kg/kg/s) c omega---input-R-vitesse verticale en Pa/s c cufi----input-R-resolution des mailles en x (m) c cvfi----input-R-resolution des mailles en y (m) c c d_u-----output-R-tendance physique de "u" (m/s/s) c d_v-----output-R-tendance physique de "v" (m/s/s) c d_t-----output-R-tendance physique de "t" (K/s) c d_qx----output-R-tendance physique de "qx" (kg/kg/s) c d_ps----output-R-tendance physique de la pression au sol c====================================================================== #include "dimensions.h" integer jjmp1 parameter (jjmp1=jjm+1-1/jjm) #include "dimphy.h" #include "regdim.h" #include "indicesol.h" #include "dimsoil.h" #include "clesphys.h" #include "control.h" #include "temps.h" c====================================================================== LOGICAL check ! Verifier la conservation du modele en eau PARAMETER (check=.FALSE.) LOGICAL ok_stratus ! Ajouter artificiellement les stratus PARAMETER (ok_stratus=.FALSE.) c====================================================================== c Parametres lies au coupleur OASIS: #include "oasis.h" INTEGER,SAVE :: npas, nexca logical rnpb parameter(rnpb=.true.) c PARAMETER (npas=1440) c PARAMETER (nexca=48) EXTERNAL fromcpl, intocpl, inicma c ocean = type de modele ocean a utiliser: force, slab, couple character*6 ocean SAVE ocean c parameter (ocean = 'force ') c parameter (ocean = 'couple') logical ok_ocean c====================================================================== c Clef controlant l'activation du cycle diurne: ccc LOGICAL cycle_diurne ccc PARAMETER (cycle_diurne=.FALSE.) c====================================================================== c Modele thermique du sol, a activer pour le cycle diurne: ccc LOGICAL soil_model ccc PARAMETER (soil_model=.FALSE.) logical ok_veget save ok_veget c parameter (ok_veget = .true.) c parameter (ok_veget = .false.) c====================================================================== c Dans les versions precedentes, l'eau liquide nuageuse utilisee dans c le calcul du rayonnement est celle apres la precipitation des nuages. c Si cette cle new_oliq est activee, ce sera une valeur moyenne entre c la condensation et la precipitation. Cette cle augmente les impacts c radiatifs des nuages. ccc LOGICAL new_oliq ccc PARAMETER (new_oliq=.FALSE.) c====================================================================== c Clefs controlant deux parametrisations de l'orographie: cc LOGICAL ok_orodr ccc PARAMETER (ok_orodr=.FALSE.) ccc LOGICAL ok_orolf ccc PARAMETER (ok_orolf=.FALSE.) c====================================================================== LOGICAL ok_journe ! sortir le fichier journalier save ok_journe c PARAMETER (ok_journe=.true.) c LOGICAL ok_mensuel ! sortir le fichier mensuel save ok_mensuel c PARAMETER (ok_mensuel=.true.) c LOGICAL ok_instan ! sortir le fichier instantane save ok_instan c PARAMETER (ok_instan=.true.) c LOGICAL ok_region ! sortir le fichier regional PARAMETER (ok_region=.FALSE.) c====================================================================== c INTEGER ivap ! indice de traceurs pour vapeur d'eau PARAMETER (ivap=1) INTEGER iliq ! indice de traceurs pour eau liquide PARAMETER (iliq=2) INTEGER nvm ! nombre de vegetations PARAMETER (nvm=8) REAL veget(klon,nvm) ! couverture vegetale SAVE veget c c c Variables argument: c INTEGER nlon INTEGER nlev INTEGER nqmax REAL rjourvrai, rjour_ecri REAL gmtime REAL pdtphys LOGICAL debut, lafin REAL paprs(klon,klev+1) REAL pplay(klon,klev) REAL pphi(klon,klev) REAL pphis(klon) REAL paire(klon) REAL presnivs(klev) REAL znivsig(klev) REAL zsurf(nbsrf) real cufi(klon), cvfi(klon) REAL u(klon,klev) REAL v(klon,klev) REAL t(klon,klev) REAL qx(klon,klev,nqmax) REAL t_ancien(klon,klev), q_ancien(klon,klev) SAVE t_ancien, q_ancien LOGICAL ancien_ok SAVE ancien_ok REAL d_t_dyn(klon,klev) REAL d_q_dyn(klon,klev) REAL omega(klon,klev) REAL d_u(klon,klev) REAL d_v(klon,klev) REAL d_t(klon,klev) REAL d_qx(klon,klev,nqmax) REAL d_ps(klon) INTEGER longcles PARAMETER ( longcles = 20 ) REAL clesphy0( longcles ) c c Variables quasi-arguments c REAL xjour SAVE xjour c c c Variables propres a la physique c REAL dtime SAVE dtime ! pas temporel de la physique c INTEGER radpas SAVE radpas ! frequence d'appel rayonnement c REAL radsol(klon) SAVE radsol ! bilan radiatif au sol c REAL rlat(klon) SAVE rlat ! latitude pour chaque point c REAL rlon(klon) SAVE rlon ! longitude pour chaque point c cc INTEGER iflag_con cc SAVE iflag_con ! indicateur de la convection c INTEGER itap SAVE itap ! compteur pour la physique c REAL co2_ppm SAVE co2_ppm ! concentration du CO2 c REAL solaire SAVE solaire ! constante solaire c REAL ftsol(klon,nbsrf) SAVE ftsol ! temperature du sol c REAL ftsoil(klon,nsoilmx,nbsrf) SAVE ftsoil ! temperature dans le sol c REAL fevap(klon,nbsrf) SAVE fevap ! evaporation REAL fluxlat(klon,nbsrf) SAVE fluxlat c REAL deltat(klon) SAVE deltat ! ecart avec la SST de reference c REAL fqsol(klon,nbsrf) SAVE fqsol ! humidite du sol c REAL fsnow(klon,nbsrf) SAVE fsnow ! epaisseur neigeuse c REAL falbe(klon,nbsrf) SAVE falbe ! albedo par type de surface REAL falblw(klon,nbsrf) SAVE falblw ! albedo par type de surface c c c Parametres de l'Orographie a l'Echelle Sous-Maille (OESM): c REAL zmea(klon) SAVE zmea ! orographie moyenne c REAL zstd(klon) SAVE zstd ! deviation standard de l'OESM c REAL zsig(klon) SAVE zsig ! pente de l'OESM c REAL zgam(klon) save zgam ! anisotropie de l'OESM c REAL zthe(klon) SAVE zthe ! orientation de l'OESM c REAL zpic(klon) SAVE zpic ! Maximum de l'OESM c REAL zval(klon) SAVE zval ! Minimum de l'OESM c REAL rugoro(klon) SAVE rugoro ! longueur de rugosite de l'OESM c REAL zulow(klon),zvlow(klon),zustr(klon), zvstr(klon) c REAL zuthe(klon),zvthe(klon) SAVE zuthe SAVE zvthe INTEGER igwd,idx(klon),itest(klon) c REAL agesno(klon,nbsrf) SAVE agesno ! age de la neige c REAL alb_neig(klon) SAVE alb_neig ! albedo de la neige cKE43 c Variables liees a la convection de K. Emanuel (sb): c REAL ema_workcbmf(klon) ! cloud base mass flux SAVE ema_workcbmf REAL ema_cbmf(klon) ! cloud base mass flux SAVE ema_cbmf REAL ema_pcb(klon) ! cloud base pressure SAVE ema_pcb REAL ema_pct(klon) ! cloud top pressure SAVE ema_pct REAL bas, top ! cloud base and top levels SAVE bas SAVE top REAL Ma(klon,klev) ! undilute upward mass flux SAVE Ma REAL ema_work1(klon, klev), ema_work2(klon, klev) SAVE ema_work1, ema_work2 REAL wdn(klon), tdn(klon), qdn(klon) c Variables locales pour la couche limite (al1): c cAl1 REAL pblh(klon) ! Hauteur de couche limite cAl1 SAVE pblh c34EK c c Variables locales: c REAL cdragh(klon) ! drag coefficient pour T and Q REAL cdragm(klon) ! drag coefficient pour vent cAA cAA Pour phytrac cAA REAL ycoefh(klon,klev) ! coef d'echange pour phytrac REAL yu1(klon) ! vents dans la premiere couche U REAL yv1(klon) ! vents dans la premiere couche V LOGICAL offline ! Controle du stockage ds "physique" PARAMETER (offline=.false.) INTEGER physid REAL pfrac_impa(klon,klev)! Produits des coefs lessivage impaction save pfrac_impa REAL pfrac_nucl(klon,klev)! Produits des coefs lessivage nucleation save pfrac_nucl REAL pfrac_1nucl(klon,klev)! Produits des coefs lessi nucl (alpha = 1) save pfrac_1nucl REAL frac_impa(klon,klev) ! fractions d'aerosols lessivees (impaction) REAL frac_nucl(klon,klev) ! idem (nucleation) cAA REAL rain_fall(klon) ! pluie REAL snow_fall(klon) ! neige save snow_fall, rain_fall REAL evap(klon), devap(klon) ! evaporation et sa derivee REAL sens(klon), dsens(klon) ! chaleur sensible et sa derivee REAL dlw(klon) ! derivee infra rouge REAL bils(klon) ! bilan de chaleur au sol REAL fder(klon) ! Derive de flux (sensible et latente) save fder REAL ve(klon) ! integr. verticale du transport meri. de l'energie REAL vq(klon) ! integr. verticale du transport meri. de l'eau REAL ue(klon) ! integr. verticale du transport zonal de l'energie REAL uq(klon) ! integr. verticale du transport zonal de l'eau c REAL frugs(klon,nbsrf) ! longueur de rugosite save frugs REAL zxrugs(klon) ! longueur de rugosite c c Conditions aux limites c INTEGER julien c INTEGER lmt_pas SAVE lmt_pas ! frequence de mise a jour REAL pctsrf(klon,nbsrf) SAVE pctsrf ! sous-fraction du sol REAL albsol(klon) SAVE albsol ! albedo du sol total REAL albsollw(klon) SAVE albsollw ! albedo du sol total REAL albsol1(klon) SAVE albsol1 ! albedo du sol total REAL albsollw1(klon) SAVE albsollw1 ! albedo du sol total REAL wo(klon,klev) SAVE wo ! ozone c====================================================================== c c Declaration des procedures appelees c EXTERNAL angle ! calculer angle zenithal du soleil EXTERNAL alboc ! calculer l'albedo sur ocean EXTERNAL albsno ! calculer albedo sur neige EXTERNAL ajsec ! ajustement sec EXTERNAL clmain ! couche limite EXTERNAL condsurf ! lire les conditions aux limites EXTERNAL conlmd ! convection (schema LMD) cKE43 EXTERNAL conema3 ! convect4.3 EXTERNAL fisrtilp ! schema de condensation a grande echelle (pluie) cAA EXTERNAL fisrtilp_tr ! schema de condensation a grande echelle (pluie) c ! stockage des coefficients necessaires au c ! lessivage OFF-LINE et ON-LINE cAA EXTERNAL hgardfou ! verifier les temperatures EXTERNAL nuage ! calculer les proprietes radiatives EXTERNAL o3cm ! initialiser l'ozone EXTERNAL orbite ! calculer l'orbite terrestre EXTERNAL ozonecm ! prescrire l'ozone EXTERNAL phyetat0 ! lire l'etat initial de la physique EXTERNAL phyredem ! ecrire l'etat de redemarrage de la physique EXTERNAL radlwsw ! rayonnements solaire et infrarouge EXTERNAL suphec ! initialiser certaines constantes EXTERNAL transp ! transport total de l'eau et de l'energie EXTERNAL ecribina ! ecrire le fichier binaire global EXTERNAL ecribins ! ecrire le fichier binaire global EXTERNAL ecrirega ! ecrire le fichier binaire regional EXTERNAL ecriregs ! ecrire le fichier binaire regional c c Variables locales c real clwcon(klon,klev),rnebcon(klon,klev) real clwcon0(klon,klev),rnebcon0(klon,klev) save rnebcon, clwcon REAL rhcl(klon,klev) ! humiditi relative ciel clair REAL dialiq(klon,klev) ! eau liquide nuageuse REAL diafra(klon,klev) ! fraction nuageuse REAL cldliq(klon,klev) ! eau liquide nuageuse REAL cldfra(klon,klev) ! fraction nuageuse REAL cldtau(klon,klev) ! epaisseur optique REAL cldemi(klon,klev) ! emissivite infrarouge c C§§§ PB REAL fluxq(klon,klev, nbsrf) ! flux turbulent d'humidite REAL fluxt(klon,klev, nbsrf) ! flux turbulent de chaleur REAL fluxu(klon,klev, nbsrf) ! flux turbulent de vitesse u REAL fluxv(klon,klev, nbsrf) ! flux turbulent de vitesse v c REAL zxfluxt(klon, klev) REAL zxfluxq(klon, klev) REAL zxfluxu(klon, klev) REAL zxfluxv(klon, klev) C§§§ REAL heat(klon,klev) ! chauffage solaire REAL heat0(klon,klev) ! chauffage solaire ciel clair REAL cool(klon,klev) ! refroidissement infrarouge REAL cool0(klon,klev) ! refroidissement infrarouge ciel clair REAL topsw(klon), toplw(klon), solsw(klon), sollw(klon) real sollwdown(klon) ! downward LW flux at surface REAL topsw0(klon), toplw0(klon), solsw0(klon), sollw0(klon) REAL albpla(klon) c Le rayonnement n'est pas calcule tous les pas, il faut donc c sauvegarder les sorties du rayonnement SAVE heat,cool,albpla,topsw,toplw,solsw,sollw,sollwdown SAVE topsw0,toplw0,solsw0,sollw0, heat0, cool0 INTEGER itaprad SAVE itaprad c REAL conv_q(klon,klev) ! convergence de l'humidite (kg/kg/s) REAL conv_t(klon,klev) ! convergence de la temperature(K/s) c REAL cldl(klon),cldm(klon),cldh(klon) !nuages bas, moyen et haut REAL cldt(klon),cldq(klon) !nuage total, eau liquide integree c REAL zxtsol(klon), zxqsol(klon), zxsnow(klon), zxfluxlat(klon) c REAL dist, rmu0(klon), fract(klon) REAL zdtime, zlongi c CHARACTER*2 str2 CHARACTER*2 iqn c REAL qcheck REAL z_avant(klon), z_apres(klon), z_factor(klon) LOGICAL zx_ajustq c REAL za, zb REAL zx_t, zx_qs, zdelta, zcor, zfra, zlvdcp, zlsdcp real zqsat(klon,klev) INTEGER i, k, iq, ig, j, nsrf, ll REAL t_coup PARAMETER (t_coup=234.0) c REAL zphi(klon,klev) REAL zx_tmp_x(iim), zx_tmp_yjjmp1 REAL zx_relief(iim,jjmp1) REAL zx_aire(iim,jjmp1) cKE43 c Variables locales pour la convection de K. Emanuel (sb): c REAL upwd(klon,klev) ! saturated updraft mass flux REAL dnwd(klon,klev) ! saturated downdraft mass flux REAL dnwd0(klon,klev) ! unsaturated downdraft mass flux REAL tvp(klon,klev) ! virtual temp of lifted parcel REAL cape(klon) ! CAPE SAVE cape REAL pbase(klon) ! cloud base pressure SAVE pbase REAL bbase(klon) ! cloud base buoyancy SAVE bbase REAL rflag(klon) ! flag fonctionnement de convect INTEGER iflagctrl(klon) ! flag fonctionnement de convect c -- convect43: INTEGER ntra ! nb traceurs pour convect4.3 REAL pori_con(klon) ! pressure at the origin level of lifted parcel REAL plcl_con(klon),dtma_con(klon),dtlcl_con(klon) REAL dtvpdt1(klon,klev), dtvpdq1(klon,klev) REAL dplcldt(klon), dplcldr(klon) c? . condm_con(klon,klev),conda_con(klon,klev), c? . mr_con(klon,klev),ep_con(klon,klev) c? . ,sadiab(klon,klev),wadiab(klon,klev) c -- c34EK c c Variables du changement c c con: convection c lsc: condensation a grande echelle (Large-Scale-Condensation) c ajs: ajustement sec c eva: evaporation de l'eau liquide nuageuse c vdf: couche limite (Vertical DiFfusion) REAL d_t_con(klon,klev),d_q_con(klon,klev) REAL d_u_con(klon,klev),d_v_con(klon,klev) REAL d_t_lsc(klon,klev),d_q_lsc(klon,klev),d_ql_lsc(klon,klev) REAL d_t_ajs(klon,klev), d_q_ajs(klon,klev) REAL d_t_eva(klon,klev),d_q_eva(klon,klev) REAL rneb(klon,klev) c REAL pmfu(klon,klev), pmfd(klon,klev) REAL pen_u(klon,klev), pen_d(klon,klev) REAL pde_u(klon,klev), pde_d(klon,klev) INTEGER kcbot(klon), kctop(klon), kdtop(klon) REAL pmflxr(klon,klev+1), pmflxs(klon,klev+1) REAL prfl(klon,klev+1), psfl(klon,klev+1) c INTEGER ibas_con(klon), itop_con(klon) REAL rain_con(klon), rain_lsc(klon) REAL snow_con(klon), snow_lsc(klon) REAL d_ts(klon,nbsrf) c REAL d_u_vdf(klon,klev), d_v_vdf(klon,klev) REAL d_t_vdf(klon,klev), d_q_vdf(klon,klev) c REAL d_u_oro(klon,klev), d_v_oro(klon,klev) REAL d_t_oro(klon,klev) REAL d_u_lif(klon,klev), d_v_lif(klon,klev) REAL d_t_lif(klon,klev) REAL ratqs(klon,klev),ratqss(klon,klev),ratqsc(klon,klev) real ratqsbas,ratqshaut save ratqsbas,ratqshaut, ratqs real zpt_conv(klon,klev) c Parametres lies au nouveau schema de nuages (SB, PDF) real fact_cldcon real facttemps logical ok_newmicro save ok_newmicro save fact_cldcon,facttemps real facteur integer iflag_cldcon save iflag_cldcon logical ptconv(klon,klev) c c Variables liees a l'ecriture de la bande histoire physique c INTEGER ecrit_mth SAVE ecrit_mth ! frequence d'ecriture (fichier mensuel) c INTEGER ecrit_day SAVE ecrit_day ! frequence d'ecriture (fichier journalier) c INTEGER ecrit_ins SAVE ecrit_ins ! frequence d'ecriture (fichier instantane) c INTEGER ecrit_reg SAVE ecrit_reg ! frequence d'ecriture c integer itau_w ! pas de temps ecriture = itap + itau_phy c c c Variables locales pour effectuer les appels en serie c REAL t_seri(klon,klev), q_seri(klon,klev) REAL ql_seri(klon,klev),qs_seri(klon,klev) REAL u_seri(klon,klev), v_seri(klon,klev) c REAL tr_seri(klon,klev,nbtr) REAL d_tr(klon,klev,nbtr) REAL zx_rh(klon,klev) INTEGER length PARAMETER ( length = 100 ) REAL tabcntr0( length ) c INTEGER ndex2d(iim*jjmp1),ndex3d(iim*jjmp1*klev) REAL zx_tmp_fi2d(klon) REAL zx_tmp_2d(iim,jjmp1), zx_tmp_3d(iim,jjmp1,klev) REAL zx_lon(iim,jjmp1), zx_lat(iim,jjmp1) c INTEGER nid_day, nid_mth, nid_ins SAVE nid_day, nid_mth, nid_ins c INTEGER nhori, nvert REAL zsto, zout real zjulian save zjulian character*20 modname character*80 abort_message logical ok_sync real date0 integer idayref C essai writephys integer fid_day, fid_mth, fid_ins parameter (fid_ins = 1, fid_day = 2, fid_mth = 3) integer prof2d_on, prof3d_on, prof2d_av, prof3d_av parameter (prof2d_on = 1, prof3d_on = 2, . prof2d_av = 3, prof3d_av = 4) character*30 nom_fichier character*10 varname character*40 vartitle character*20 varunits C Variables liees au bilan d'energie et d'enthalpi INTEGER if_ebil ! level for energy conserv. dignostics SAVE if_ebil REAL ztsol(klon) REAL h_vcol_tot, h_dair_tot, h_qw_tot, h_ql_tot $ , h_qs_tot, qw_tot, ql_tot, qs_tot , ec_tot SAVE h_vcol_tot, h_dair_tot, h_qw_tot, h_ql_tot $ , h_qs_tot, qw_tot, ql_tot, qs_tot , ec_tot REAL d_h_vcol, d_h_dair, d_qt, d_qw, d_ql, d_qs, d_ec REAL d_h_vcol_phy REAL fs_bound, fq_bound SAVE d_h_vcol_phy REAL zero_v(klon) CHARACTER*15 ztit INTEGER ip_ebil ! PRINT level for energy conserv. diag. SAVE ip_ebil DATA ip_ebil/2/ c c Declaration des constantes et des fonctions thermodynamiques c #include "YOMCST.h" #include "YOETHF.h" #include "FCTTRE.h" c====================================================================== modname = 'physiq' IF (if_ebil.ge.1) THEN DO i=1,klon zero_v(i)=0. END DO END IF ok_sync=.TRUE. IF (nqmax .LT. 2) THEN PRINT*, 'eaux vapeur et liquide sont indispensables' CALL ABORT ENDIF IF (debut) THEN CALL suphec ! initialiser constantes et parametres phys. ENDIF c====================================================================== xjour = rjourvrai c c Si c'est le debut, il faut initialiser plusieurs choses c ******** c IF (debut) THEN C IF (if_ebil.ge.1) d_h_vcol_phy=0. c c appel a la lecture du run.def physique c call conf_phys(ocean, ok_veget, ok_journe, ok_mensuel, . ok_instan, fact_cldcon, facttemps,ok_newmicro, . iflag_cldcon,ratqsbas,ratqshaut, if_ebil) DO k = 2, nvm ! pas de vegetation DO i = 1, klon veget(i,k) = 0.0 ENDDO ENDDO DO i = 1, klon veget(i,1) = 1.0 ! il n'y a que du desert ENDDO PRINT*, 'Pas de vegetation; desert partout' c c c Initialiser les compteurs: c frugs = 0. itap = 0 itaprad = 0 c CALL phyetat0 ("startphy.nc",dtime,co2_ppm,solaire, . rlat,rlon,pctsrf, ftsol,ftsoil,deltat,fqsol,fsnow, . falbe, fevap, rain_fall,snow_fall,solsw, sollwdown, . dlw,radsol,frugs,agesno,clesphy0, . zmea,zstd,zsig,zgam,zthe,zpic,zval,rugoro,tabcntr0, . t_ancien, q_ancien, ancien_ok, rnebcon, ratqs,clwcon ) c radpas = NINT( 86400./dtime/nbapp_rad) c CALL printflag( tabcntr0,radpas,ok_ocean,ok_oasis ,ok_journe, , ok_instan, ok_region ) c IF (ABS(dtime-pdtphys).GT.0.001) THEN PRINT*, 'Pas physique n est pas correcte',dtime,pdtphys abort_message=' See above ' call abort_gcm(modname,abort_message,1) ENDIF IF (nlon .NE. klon) THEN PRINT*, 'nlon et klon ne sont pas coherents', nlon, klon abort_message=' See above ' call abort_gcm(modname,abort_message,1) ENDIF IF (nlev .NE. klev) THEN PRINT*, 'nlev et klev ne sont pas coherents', nlev, klev abort_message=' See above ' call abort_gcm(modname,abort_message,1) ENDIF c IF (dtime*FLOAT(radpas).GT.21600..AND.cycle_diurne) THEN PRINT*, 'Nbre d appels au rayonnement insuffisant' PRINT*, "Au minimum 4 appels par jour si cycle diurne" abort_message=' See above ' call abort_gcm(modname,abort_message,1) ENDIF PRINT*, "Clef pour la convection, iflag_con=", iflag_con c cKE43 c Initialisation pour la convection de K.E. (sb): IF (iflag_con.GE.3) THEN PRINT*, "*** Convection de Kerry Emanuel 4.3 " PRINT*, "On va utiliser le melange convectif des traceurs qui" PRINT*, "est calcule dans convect4.3" PRINT*, " !!! penser aux logical flags de phytrac" DO i = 1, klon ema_cbmf(i) = 0. ema_pcb(i) = 0. ema_pct(i) = 0. ema_workcbmf(i) = 0. ENDDO ENDIF c34EK IF (ok_orodr) THEN DO i=1,klon rugoro(i) = MAX(1.0e-05, zstd(i)*zsig(i)/2.0) ENDDO CALL SUGWD(klon,klev,paprs,pplay) DO i=1,klon zuthe(i)=0. zvthe(i)=0. if(zstd(i).gt.10.)then zuthe(i)=(1.-zgam(i))*cos(zthe(i)) zvthe(i)=(1.-zgam(i))*sin(zthe(i)) endif ENDDO ENDIF c c lmt_pas = NINT(86400./dtime * 1.0) ! tous les jours PRINT*,'La frequence de lecture surface est de ', lmt_pas c ecrit_mth = NINT(86400./dtime *ecritphy) ! tous les ecritphy jours IF (ok_mensuel) THEN PRINT*, 'La frequence de sortie mensuelle est de ', ecrit_mth ENDIF ecrit_day = NINT(86400./dtime *1.0) ! tous les jours IF (ok_journe) THEN PRINT*, 'La frequence de sortie journaliere est de ',ecrit_day ENDIF ccc ecrit_ins = NINT(86400./dtime *0.5) ! 2 fois par jour ccc ecrit_ins = NINT(86400./dtime *0.25) ! 4 fois par jour ecrit_ins = NINT(86400./dtime/12.) ! toutes les deux heures ecrit_ins = NINT(86400./dtime/48.) ! a chaque pas de temps IF (ok_instan) THEN PRINT*, 'La frequence de sortie instant. est de ', ecrit_ins ENDIF ecrit_reg = NINT(86400./dtime *0.25) ! 4 fois par jour IF (ok_region) THEN PRINT*, 'La frequence de sortie region est de ', ecrit_reg ENDIF c c Initialiser le couplage si necessaire c npas = 0 nexca = 0 if (ocean == 'couple') then npas = itaufin/ iphysiq nexca = 86400 / dtime write(*,*)' ##### Ocean couple #####' write(*,*)' Valeurs des pas de temps' write(*,*)' npas = ', npas write(*,*)' nexca = ', nexca endif c c c Gestion calendrier c IF (ok_journe) THEN c idayref = day_ref CALL ymds2ju(annee_ref, 1, idayref, 0.0, zjulian) c CALL gr_fi_ecrit(1,klon,iim,jjmp1,rlon,zx_lon) DO i = 1, iim zx_lon(i,1) = rlon(i+1) zx_lon(i,jjmp1) = rlon(i+1) ENDDO DO ll=1,klev znivsig(ll)=float(ll) ENDDO CALL gr_fi_ecrit(1,klon,iim,jjmp1,rlat,zx_lat) write(*,*)'zx_lon = ',zx_lon(:,1) write(*,*)'zx_lat = ',zx_lat(1,:) CALL histbeg("histday", iim,zx_lon(:,1), jjmp1,zx_lat(1,:), . 1,iim,1,jjmp1, itau_phy, zjulian, dtime, . nhori, nid_day) write(*,*)'Journee ', itau_phy, zjulian CALL histvert(nid_day, "presnivs", "Vertical levels", "mb", . klev, presnivs, nvert) c call histvert(nid_day, 'sig_s', 'Niveaux sigma','-', c . klev, znivsig, nvert) c zsto = dtime zout = dtime * FLOAT(ecrit_day) C Essai writephys c nom_fichier = 'histday1' c call writephy_ini(fid_day,nom_fichier,klon,iim,jjmp1,klev, c . rlon,rlat, presnivs, c . zjulian, dtime) c call writephy_def(prof2d_on, fid_day, "once", zsto, zout, 0) c call writephy_def(prof3d_on, fid_day, "once", zsto, zout, c . klev) c call writephy_def(prof2d_av, fid_day, "ave(X)", zsto, zout, 0) c call writephy_def(prof3d_av, fid_day, "ave(X)", zsto, zout, c . klev) c CALL histdef(nid_day, "phis", "Surface geop. height", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "once", zsto,zout) c CALL histdef(nid_day, "aire", "Grid area", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "once", zsto,zout) c c Champs 2D: c CALL histdef(nid_day, "tsol", "Surface Temperature", "K", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "tter", "Surface Temperature", "K", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "tlic", "Surface Temperature", "K", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "toce", "Surface Temperature", "K", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "tsic", "Surface Temperature", "K", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "psol", "Surface Pressure", "Pa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "precip","Precipitation Totale liq+sol" . , "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "snow", "Snow fall", "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "snow_mass", "Snow Mass", "kg/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "evap", "Evaporation", "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "tops", "Solar rad. at TOA", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "topl", "IR rad. at TOA", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "sols", "Net Solar rad. at surf.", . "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "soll", "Net IR rad. at surface", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "solldown", "Down. IR rad. at surface", . "W/m2", iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "bils", "Surf. total heat flux", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "sens", "Sensible heat flux", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "fder", "Heat flux derivation", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "frtu", "Zonal wind stress", "Pa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "frtv", "Meridional wind stress", "Pa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c C §§§ PB flux pour chauqe sous surface C DO nsrf = 1, nbsrf C call histdef(nid_day, "pourc_"//clnsurf(nsrf), $ "Fraction"//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C call histdef(nid_day, "tsol_"//clnsurf(nsrf), $ "Fraction"//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C call histdef(nid_day, "sens_"//clnsurf(nsrf), $ "Sensible heat flux "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) c call histdef(nid_day, "lat_"//clnsurf(nsrf), $ "Latent heat flux "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C call histdef(nid_day, "taux_"//clnsurf(nsrf), $ "Zonal wind stress"//clnsurf(nsrf),"Pa", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) call histdef(nid_day, "tauy_"//clnsurf(nsrf), $ "Meridional xind stress "//clnsurf(nsrf), "Pa", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C call histdef(nid_day, "albe_"//clnsurf(nsrf), $ "Albedo surf. "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C call histdef(nid_day, "rugs_"//clnsurf(nsrf), $ "Latent heat flux "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C§§§ END DO CALL histdef(nid_day, "sicf", "Sea-ice fraction", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "cldl", "Low-level cloudiness", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "cldm", "Mid-level cloudiness", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "cldh", "High-level cloudiness", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "cldt", "Total cloudiness", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "cldq", "Cloud liquid water path", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c c Champs 3D: c CALL histdef(nid_day, "temp", "Air temperature", "K", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "ovap", "Specific humidity", "Kg/Kg", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "geop", "Geopotential height", "m", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "vitu", "Zonal wind", "m/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "vitv", "Meridional wind", "m/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "vitw", "Vertical wind", "m/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_day, "pres", "Air pressure", "Pa", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histend(nid_day) c ndex2d = 0 ndex3d = 0 c ENDIF ! fin de test sur ok_journe c IF (ok_mensuel) THEN c idayref = day_ref CALL ymds2ju(annee_ref, 1, idayref, 0.0, zjulian) c CALL gr_fi_ecrit(1,klon,iim,jjmp1,rlon,zx_lon) DO i = 1, iim zx_lon(i,1) = rlon(i+1) zx_lon(i,jjmp1) = rlon(i+1) ENDDO DO ll=1,klev znivsig(ll)=float(ll) ENDDO CALL gr_fi_ecrit(1,klon,iim,jjmp1,rlat,zx_lat) CALL histbeg("histmth.nc", iim,zx_lon(:,1), jjmp1,zx_lat(1,:), . 1,iim,1,jjmp1, itau_phy, zjulian, dtime, . nhori, nid_mth) write(*,*)'Mensuel ', itau_phy, zjulian CALL histvert(nid_mth, "presnivs", "Vertical levels", "mb", . klev, presnivs, nvert) c call histvert(nid_mth, 'sig_s', 'Niveaux sigma','-', c . klev, znivsig, nvert) c zsto = dtime zout = dtime * ecrit_mth c CALL histdef(nid_mth, "phis", "Surface geop. height", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "once", zsto,zout) c CALL histdef(nid_mth, "aire", "Grid area", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "once", zsto,zout) c c Champs 2D: c CALL histdef(nid_mth, "tsol", "Surface Temperature", "K", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "psol", "Surface Pressure", "Pa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "qsol", "Surface humidity", "mm", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "precip", "Precipitation Totale liq+sol", . "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "plul", "Large-scale Precip.", "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "pluc", "Convective Precip.", "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "snow", "Snow fall", "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "snow_mass", "Snow Mass", "kg/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "evap", "Evaporation", "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "tops", "Solar rad. at TOA", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "topl", "IR rad. at TOA", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "sols", "Solar rad. at surf.", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "soll", "IR rad. at surface", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "solldown", "Down. IR rad. at surface", . "W/m2", iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "tops0", "Solar rad. at TOA", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "topl0", "IR rad. at TOA", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "sols0", "Solar rad. at surf.", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "soll0", "IR rad. at surface", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "bils", "Surf. total heat flux", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "sens", "Sensible heat flux", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "fder", "Heat flux derivation", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "frtu", "Zonal wind stress", "Pa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "frtv", "Meridional wind stress", "Pa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c DO nsrf = 1, nbsrf C call histdef(nid_mth, "pourc_"//clnsurf(nsrf), $ "Fraction "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C call histdef(nid_mth, "tsol_"//clnsurf(nsrf), $ "Fraction "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C call histdef(nid_mth, "sens_"//clnsurf(nsrf), $ "Sensible heat flux "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) c call histdef(nid_mth, "lat_"//clnsurf(nsrf), $ "Latent heat flux "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) C call histdef(nid_mth, "taux_"//clnsurf(nsrf), $ "Zonal wind stress"//clnsurf(nsrf), "Pa", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) call histdef(nid_mth, "tauy_"//clnsurf(nsrf), $ "Meridional xind stress "//clnsurf(nsrf), "Pa", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) c call histdef(nid_mth, "albe_"//clnsurf(nsrf), $ "Albedo surf. "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) c call histdef(nid_mth, "rugs_"//clnsurf(nsrf), $ "Latent heat flux "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "ave(X)", zsto,zout) c CALL histdef(nid_mth, "ages_"//clnsurf(nsrf), "Snow age","day", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) END DO C CALL histdef(nid_mth, "sicf", "Sea-ice fraction", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "albs", "Surface albedo", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) CALL histdef(nid_mth, "albslw", "Surface albedo LW", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "cdrm", "Momentum drag coef.", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "cdrh", "Heat drag coef.", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "cldl", "Low-level cloudiness", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "cldm", "Mid-level cloudiness", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "cldh", "High-level cloudiness", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "cldt", "Total cloudiness", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "cldq", "Cloud liquid water path", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "ue", "Zonal energy transport", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "ve", "Merid energy transport", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "uq", "Zonal humidity transport", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "vq", "Merid humidity transport", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) cKE43 IF (iflag_con .GE. 3) THEN ! sb c CALL histdef(nid_mth, "cape", "Conv avlbl pot ener", "J/Kg", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "pbase", "Cld base pressure", "hPa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "ptop", "Cld top pressure", "hPa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "fbase", "Cld base mass flux", "Kg/m2/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "ave(X)", zsto,zout) c c ENDIF c34EK c c Champs 3D: c CALL histdef(nid_mth, "temp", "Air temperature", "K", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "ovap", "Specific humidity", "Kg/Kg", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "geop", "Geopotential height", "m", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "vitu", "Zonal wind", "m/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "vitv", "Meridional wind", "m/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "vitw", "Vertical wind", "m/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "pres", "Air pressure", "Pa", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "rneb", "Cloud fraction", "-", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "rhum", "Relative humidity", "-", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "clwcon", "Cloud Liquid water content" . , "kg/kg", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "oliq", "Liquid water content", "kg/kg", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtdyn", "Dynamics dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dqdyn", "Dynamics dQ", "Kg/Kg/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtcon", "Convection dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "ducon", "Convection du", "m/s2", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dqcon", "Convection dQ", "Kg/Kg/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtlsc", "Condensation dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dqlsc", "Condensation dQ", "Kg/Kg/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtvdf", "Boundary-layer dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dqvdf", "Boundary-layer dQ", "Kg/Kg/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dteva", "Reevaporation dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dqeva", "Reevaporation dQ", "Kg/Kg/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) CALL histdef(nid_mth, "ptconv", "POINTS CONVECTIFS"," ", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) CALL histdef(nid_mth, "ratqs", "RATQS"," ", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtajs", "Dry adjust. dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) CALL histdef(nid_mth, "dqajs", "Dry adjust. dQ", "Kg/Kg/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtswr", "SW radiation dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtsw0", "SW radiation dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtlwr", "LW radiation dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dtlw0", "LW radiation dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "duvdf", "Boundary-layer dU", "m/s2", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dvvdf", "Boundary-layer dV", "m/s2", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c IF (ok_orodr) THEN CALL histdef(nid_mth, "duoro", "Orography dU", "m/s2", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dvoro", "Orography dV", "m/s2", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c ENDIF C IF (ok_orolf) THEN CALL histdef(nid_mth, "dulif", "Orography dU", "m/s2", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dvlif", "Orography dV", "m/s2", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) ENDIF C CALL histdef(nid_mth, "ozone", "Ozone concentration", "-", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c if (nqmax.GE.3) THEN DO iq=1,nqmax-2 IF (iq.LE.99) THEN WRITE(str2,'(i2.2)') iq CALL histdef(nid_mth, "trac"//str2, "Tracer No."//str2, "-", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) ELSE PRINT*, "Trop de traceurs" CALL abort ENDIF ENDDO ENDIF c cKE43 IF (iflag_con.GE.3) THEN ! (sb) c CALL histdef(nid_mth, "upwd", "saturated updraft", "Kg/m2/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dnwd", "saturated downdraft","Kg/m2/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth, "dnwd0", "unsat. downdraft", "Kg/m2/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c CALL histdef(nid_mth,"Ma","undilute adiab updraft","Kg/m2/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "ave(X)", zsto,zout) c c ENDIF c34EK CALL histend(nid_mth) c ndex2d = 0 ndex3d = 0 c ENDIF ! fin de test sur ok_mensuel c c IF (ok_instan) THEN c idayref = day_ref CALL ymds2ju(annee_ref, 1, idayref, 0.0, zjulian) c CALL gr_fi_ecrit(1,klon,iim,jjmp1,rlon,zx_lon) DO i = 1, iim zx_lon(i,1) = rlon(i+1) zx_lon(i,jjmp1) = rlon(i+1) ENDDO DO ll=1,klev znivsig(ll)=float(ll) ENDDO CALL gr_fi_ecrit(1,klon,iim,jjmp1,rlat,zx_lat) CALL histbeg("histins", iim,zx_lon(:,1), jjmp1,zx_lat(1,:), . 1,iim,1,jjmp1, itau_phy, zjulian, dtime, . nhori, nid_ins) write(*,*)'Inst ', itau_phy, zjulian CALL histvert(nid_ins, "presnivs", "Vertical levels", "mb", . klev, presnivs, nvert) c call histvert(nid_ins, 'sig_s', 'Niveaux sigma','-', c . klev, znivsig, nvert) c c zsto = dtime * ecrit_ins zout = dtime * ecrit_ins C CALL histdef(nid_ins, "phis", "Surface geop. height", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "once", zsto,zout) c CALL histdef(nid_ins, "aire", "Grid area", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "once", zsto,zout) c c Champs 2D: c CALL histdef(nid_ins, "tsol", "Surface Temperature", "K", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "psol", "Surface Pressure", "Pa", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "plul", "Large-scale Precip.", "mm/day", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "pluc", "Convective Precip.", "mm/day", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) CALL histdef(nid_ins, "qsol", "Surface humidity", "mm", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "cdrm", "Momentum drag coef.", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "cdrh", "Heat drag coef.", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "precip", "Precipitation Totale liq+sol", . "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "snow", "Snow fall", "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "snow_mass", "Snow Mass", "kg/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "topl", "OLR", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "evap", "Evaporation", "kg/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "sols", "Solar rad. at surf.", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "soll", "IR rad. at surface", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "solldown", "Down. IR rad. at surface", . "W/m2", iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "bils", "Surf. total heat flux", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "sens", "Sensible heat flux", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "fder", "Heat flux derivation", "W/m2", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "dtsvdfo", "Boundary-layer dTs(o)", "K/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "dtsvdft", "Boundary-layer dTs(t)", "K/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "dtsvdfg", "Boundary-layer dTs(g)", "K/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "dtsvdfi", "Boundary-layer dTs(g)", "K/s", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) DO nsrf = 1, nbsrf C call histdef(nid_ins, "pourc_"//clnsurf(nsrf), $ "Fraction"//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "inst(X)", zsto,zout) call histdef(nid_ins, "sens_"//clnsurf(nsrf), $ "Sensible heat flux "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "inst(X)", zsto,zout) c call histdef(nid_ins, "tsol_"//clnsurf(nsrf), $ "Surface Temperature"//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "inst(X)", zsto,zout) c call histdef(nid_ins, "lat_"//clnsurf(nsrf), $ "Latent heat flux "//clnsurf(nsrf), "W/m2", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "inst(X)", zsto,zout) C call histdef(nid_ins, "taux_"//clnsurf(nsrf), $ "Zonal wind stress"//clnsurf(nsrf),"Pa", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "inst(X)", zsto,zout) call histdef(nid_ins, "tauy_"//clnsurf(nsrf), $ "Meridional xind stress "//clnsurf(nsrf), "Pa", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "inst(X)", zsto,zout) c call histdef(nid_ins, "albe_"//clnsurf(nsrf), $ "Albedo "//clnsurf(nsrf), "-", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "inst(X)", zsto,zout) c call histdef(nid_ins, "rugs_"//clnsurf(nsrf), $ "rugosite "//clnsurf(nsrf), "-", $ iim,jjmp1,nhori, 1,1,1, -99, 32, $ "inst(X)", zsto,zout) C§§§ END DO CALL histdef(nid_ins, "rugs", "rugosity", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "albs", "Surface albedo", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) CALL histdef(nid_ins, "albslw", "Surface albedo LW", "-", . iim,jjmp1,nhori, 1,1,1, -99, 32, . "inst(X)", zsto,zout) c c c Champs 3D: c CALL histdef(nid_ins, "temp", "Temperature", "K", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "vitu", "Zonal wind", "m/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "vitv", "Merid wind", "m/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "geop", "Geopotential height", "m", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "pres", "Air pressure", "Pa", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "dtvdf", "Boundary-layer dT", "K/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "inst(X)", zsto,zout) c CALL histdef(nid_ins, "dqvdf", "Boundary-layer dQ", "Kg/Kg/s", . iim,jjmp1,nhori, klev,1,klev,nvert, 32, . "inst(X)", zsto,zout) c CALL histend(nid_ins) c ndex2d = 0 ndex3d = 0 c ENDIF c$$$PB Positionner date0 pour initialisation de ORCHIDEE date0 = zjulian C date0 = day_ini WRITE(*,*) 'physiq date0 : ',date0 c c c c Prescrire l'ozone dans l'atmosphere c c cc DO i = 1, klon cc DO k = 1, klev cc CALL o3cm (paprs(i,k)/100.,paprs(i,k+1)/100., wo(i,k),20) cc ENDDO cc ENDDO c c ENDIF c c **************** Fin de IF ( debut ) *************** c c c Mettre a zero des variables de sortie (pour securite) c DO i = 1, klon d_ps(i) = 0.0 ENDDO DO k = 1, klev DO i = 1, klon d_t(i,k) = 0.0 d_u(i,k) = 0.0 d_v(i,k) = 0.0 ENDDO ENDDO DO iq = 1, nqmax DO k = 1, klev DO i = 1, klon d_qx(i,k,iq) = 0.0 ENDDO ENDDO ENDDO c c Ne pas affecter les valeurs entrees de u, v, h, et q c DO k = 1, klev DO i = 1, klon t_seri(i,k) = t(i,k) u_seri(i,k) = u(i,k) v_seri(i,k) = v(i,k) q_seri(i,k) = qx(i,k,ivap) ql_seri(i,k) = qx(i,k,iliq) qs_seri(i,k) = 0. ENDDO ENDDO IF (nqmax.GE.3) THEN DO iq = 3, nqmax DO k = 1, klev DO i = 1, klon tr_seri(i,k,iq-2) = qx(i,k,iq) ENDDO ENDDO ENDDO ELSE DO k = 1, klev DO i = 1, klon tr_seri(i,k,1) = 0.0 ENDDO ENDDO ENDIF C IF (if_ebil.ge.1) THEN DO i = 1, klon ztsol(i) = 0. ENDDO DO nsrf = 1, nbsrf DO i = 1, klon ztsol(i) = ztsol(i) + ftsol(i,nsrf)*pctsrf(i,nsrf) ENDDO ENDDO ztit='after dynamic' CALL diagetpq(paire,ztit,ip_ebil,1,1,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) C Comme les tendances de la physique sont ajoute dans la dynamique, C on devrait avoir que la variation d'entalpie par la dynamique C est egale a la variation de la physique au pas de temps precedent. C Donc la somme de ces 2 variations devrait etre nulle. call diagphy(paire,ztit,ip_ebil e , zero_v, zero_v, zero_v, zero_v, zero_v e , zero_v, zero_v, zero_v, ztsol e , d_h_vcol+d_h_vcol_phy, d_qt, 0. s , fs_bound, fq_bound ) END IF c Diagnostiquer la tendance dynamique c IF (ancien_ok) THEN DO k = 1, klev DO i = 1, klon d_t_dyn(i,k) = (t_seri(i,k)-t_ancien(i,k))/dtime d_q_dyn(i,k) = (q_seri(i,k)-q_ancien(i,k))/dtime ENDDO ENDDO ELSE DO k = 1, klev DO i = 1, klon d_t_dyn(i,k) = 0.0 d_q_dyn(i,k) = 0.0 ENDDO ENDDO ancien_ok = .TRUE. ENDIF c c Ajouter le geopotentiel du sol: c DO k = 1, klev DO i = 1, klon zphi(i,k) = pphi(i,k) + pphis(i) ENDDO ENDDO c c Verifier les temperatures c CALL hgardfou(t_seri,ftsol,'debutphy') c c Incrementer le compteur de la physique c itap = itap + 1 julien = MOD(NINT(xjour),360) c c Mettre en action les conditions aux limites (albedo, sst, etc.). c Prescrire l'ozone et calculer l'albedo sur l'ocean. c IF (MOD(itap-1,lmt_pas) .EQ. 0) THEN PRINT *,' PHYS cond julien ',julien CALL ozonecm( FLOAT(julien), rlat, paprs, wo) ENDIF c c Re-evaporer l'eau liquide nuageuse c DO k = 1, klev ! re-evaporation de l'eau liquide nuageuse DO i = 1, klon zlvdcp=RLVTT/RCPD/(1.0+RVTMP2*q_seri(i,k)) c zlsdcp=RLSTT/RCPD/(1.0+RVTMP2*q_seri(i,k)) zlsdcp=RLVTT/RCPD/(1.0+RVTMP2*q_seri(i,k)) zdelta = MAX(0.,SIGN(1.,RTT-t_seri(i,k))) zb = MAX(0.0,ql_seri(i,k)) za = - MAX(0.0,ql_seri(i,k)) . * (zlvdcp*(1.-zdelta)+zlsdcp*zdelta) t_seri(i,k) = t_seri(i,k) + za q_seri(i,k) = q_seri(i,k) + zb ql_seri(i,k) = 0.0 d_t_eva(i,k) = za d_q_eva(i,k) = zb ENDDO ENDDO c IF (if_ebil.ge.2) THEN ztit='after reevap' CALL diagetpq(paire,ztit,ip_ebil,2,2,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) call diagphy(paire,ztit,ip_ebil e , zero_v, zero_v, zero_v, zero_v, zero_v e , zero_v, zero_v, zero_v, ztsol e , d_h_vcol, d_qt, d_ec s , fs_bound, fq_bound ) C END IF C c c Appeler la diffusion verticale (programme de couche limite) c DO i = 1, klon c if (.not. ok_veget) then c frugs(i,is_ter) = SQRT(frugs(i,is_ter)**2+rugoro(i)**2) c endif c frugs(i,is_lic) = rugoro(i) c frugs(i,is_oce) = rugmer(i) c frugs(i,is_sic) = 0.001 zxrugs(i) = 0.0 ENDDO DO nsrf = 1, nbsrf DO i = 1, klon frugs(i,nsrf) = MAX(frugs(i,nsrf),0.001) cccc frugs(i,nsrf) = MAX(frugs(i,nsrf),0.000015) ENDDO ENDDO DO nsrf = 1, nbsrf DO i = 1, klon zxrugs(i) = zxrugs(i) + frugs(i,nsrf)*pctsrf(i,nsrf) ENDDO ENDDO c C calculs necessaires au calcul de l'albedo dans l'interface c CALL orbite(FLOAT(julien),zlongi,dist) IF (cycle_diurne) THEN zdtime=dtime*FLOAT(radpas) ! pas de temps du rayonnement (s) CALL zenang(zlongi,gmtime,zdtime,rlat,rlon,rmu0,fract) ELSE rmu0 = -999.999 ENDIF fder = dlw CALL clmain(dtime,itap,date0,pctsrf, e t_seri,q_seri,u_seri,v_seri, e julien, rmu0, e ok_veget, ocean, npas, nexca, ftsol, $ soil_model,ftsoil, $ paprs,pplay,radsol, fsnow,fqsol,fevap,falbe,falblw, $ fluxlat, e rain_fall, snow_fall, solsw, sollw, sollwdown, fder, e rlon, rlat, cufi, cvfi, frugs, e debut, lafin, agesno,rugoro , s d_t_vdf,d_q_vdf,d_u_vdf,d_v_vdf,d_ts, s fluxt,fluxq,fluxu,fluxv,cdragh,cdragm, s dsens, devap, s ycoefh,yu1,yv1) c C§§§ PB C§§§ Incrementation des flux C§§ zxfluxt=0. zxfluxq=0. zxfluxu=0. zxfluxv=0. DO nsrf = 1, nbsrf DO k = 1, klev DO i = 1, klon zxfluxt(i,k) = zxfluxt(i,k) + $ fluxt(i,k,nsrf) * pctsrf( i, nsrf) zxfluxq(i,k) = zxfluxq(i,k) + $ fluxq(i,k,nsrf) * pctsrf( i, nsrf) zxfluxu(i,k) = zxfluxu(i,k) + $ fluxu(i,k,nsrf) * pctsrf( i, nsrf) zxfluxv(i,k) = zxfluxv(i,k) + $ fluxv(i,k,nsrf) * pctsrf( i, nsrf) END DO END DO END DO DO i = 1, klon sens(i) = - zxfluxt(i,1) ! flux de chaleur sensible au sol c evap(i) = - fluxq(i,1) ! flux d'evaporation au sol evap(i) = - zxfluxq(i,1) ! flux d'evaporation au sol fder(i) = dlw(i) + dsens(i) + devap(i) ENDDO DO k = 1, klev DO i = 1, klon t_seri(i,k) = t_seri(i,k) + d_t_vdf(i,k) q_seri(i,k) = q_seri(i,k) + d_q_vdf(i,k) u_seri(i,k) = u_seri(i,k) + d_u_vdf(i,k) v_seri(i,k) = v_seri(i,k) + d_v_vdf(i,k) ENDDO ENDDO c IF (if_ebil.ge.2) THEN ztit='after clmain' CALL diagetpq(paire,ztit,ip_ebil,2,2,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) call diagphy(paire,ztit,ip_ebil e , zero_v, zero_v, zero_v, zero_v, sens e , evap , zero_v, zero_v, ztsol e , d_h_vcol, d_qt, d_ec s , fs_bound, fq_bound ) END IF C c c Incrementer la temperature du sol c DO i = 1, klon zxtsol(i) = 0.0 zxfluxlat(i) = 0.0 IF ( abs( pctsrf(i, is_ter) + pctsrf(i, is_lic) + $ pctsrf(i, is_oce) + pctsrf(i, is_sic) - 1.) .GT. EPSFRA) $ THEN WRITE(*,*) 'physiq : pb sous surface au point ', i, $ pctsrf(i, 1 : nbsrf) ENDIF ENDDO DO nsrf = 1, nbsrf DO i = 1, klon c$$$ IF (pctsrf(i,nsrf) .GE. EPSFRA) THEN ftsol(i,nsrf) = ftsol(i,nsrf) + d_ts(i,nsrf) zxtsol(i) = zxtsol(i) + ftsol(i,nsrf)*pctsrf(i,nsrf) zxfluxlat(i) = zxfluxlat(i) + fluxlat(i,nsrf)*pctsrf(i,nsrf) c$$$ ENDIF ENDDO ENDDO c c Si une sous-fraction n'existe pas, elle prend la temp. moyenne c DO nsrf = 1, nbsrf DO i = 1, klon IF (pctsrf(i,nsrf) .LT. epsfra) ftsol(i,nsrf) = zxtsol(i) ENDDO ENDDO c c Calculer la derive du flux infrarouge c c$$$ DO nsrf = 1, nbsrf DO i = 1, klon c$$$ IF (pctsrf(i,nsrf) .GE. EPSFRA) THEN dlw(i) = - 4.0*RSIGMA*zxtsol(i)**3 c$$$ . *(ftsol(i,nsrf)-zxtsol(i)) c$$$ . *pctsrf(i,nsrf) c$$$ ENDIF c$$$ ENDDO ENDDO c c Appeler la convection (au choix) c DO k = 1, klev DO i = 1, klon conv_q(i,k) = d_q_dyn(i,k) . + d_q_vdf(i,k)/dtime conv_t(i,k) = d_t_dyn(i,k) . + d_t_vdf(i,k)/dtime ENDDO ENDDO IF (check) THEN za = qcheck(klon,klev,paprs,q_seri,ql_seri,paire) PRINT*, "avantcon=", za ENDIF zx_ajustq = .FALSE. IF (iflag_con.EQ.2) zx_ajustq=.TRUE. IF (zx_ajustq) THEN DO i = 1, klon z_avant(i) = 0.0 ENDDO DO k = 1, klev DO i = 1, klon z_avant(i) = z_avant(i) + (q_seri(i,k)+ql_seri(i,k)) . *(paprs(i,k)-paprs(i,k+1))/RG ENDDO ENDDO ENDIF IF (iflag_con.EQ.1) THEN stop'reactiver le call conlmd dans physiq.F' c CALL conlmd (dtime, paprs, pplay, t_seri, q_seri, conv_q, c . d_t_con, d_q_con, c . rain_con, snow_con, ibas_con, itop_con) ELSE IF (iflag_con.EQ.2) THEN CALL conflx(dtime, paprs, pplay, t_seri, q_seri, e conv_t, conv_q, zxfluxq(1,1), omega, s d_t_con, d_q_con, rain_con, snow_con, s pmfu, pmfd, pen_u, pde_u, pen_d, pde_d, s kcbot, kctop, kdtop, pmflxr, pmflxs) WHERE (rain_con < 0.) rain_con = 0. WHERE (snow_con < 0.) snow_con = 0. DO i = 1, klon ibas_con(i) = klev+1 - kcbot(i) itop_con(i) = klev+1 - kctop(i) ENDDO ELSE IF (iflag_con.GE.3) THEN c nb of tracers for the KE convection: if (nqmax .GE. 4) then ntra = nbtr else ntra = 1 endif if (iflag_con.eq.4) then ! vectorise CALL conemav (dtime,paprs,pplay,t_seri,q_seri, . u_seri,v_seri,tr_seri,nbtr, . ema_work1,ema_work2, . d_t_con,d_q_con,d_u_con,d_v_con,d_tr, . rain_con, snow_con, ibas_con, itop_con, . upwd,dnwd,dnwd0, c . Ma,cape,tvp,(/(nint(rflag(i)),i=1,size(rflag))/), . Ma,cape,tvp,iflagctrl, . pbase,bbase,dtvpdt1,dtvpdq1,dplcldt,dplcldr) else c print*,'Avant conema OUI' CALL conema3 (dtime, . paprs,pplay,t_seri,q_seri, . u_seri,v_seri,tr_seri,nbtr, . ema_work1,ema_work2, . d_t_con,d_q_con,d_u_con,d_v_con,d_tr, . rain_con, snow_con, ibas_con, itop_con, . upwd,dnwd,dnwd0,bas,top, . Ma,cape,tvp,rflag, . pbase . ,bbase,dtvpdt1,dtvpdq1,dplcldt,dplcldr . ,clwcon0) print*,'Apres conema3 ' c Calculer l'humidite relative pour diagnostique c DO k = 1, klev DO i = 1, klon zx_t = t_seri(i,k) IF (thermcep) THEN zdelta = MAX(0.,SIGN(1.,rtt-zx_t)) zx_qs = r2es * FOEEW(zx_t,zdelta)/pplay(i,k) zx_qs = MIN(0.5,zx_qs) zcor = 1./(1.-retv*zx_qs) zx_qs = zx_qs*zcor ELSE IF (zx_t.LT.t_coup) THEN zx_qs = qsats(zx_t)/pplay(i,k) ELSE zx_qs = qsatl(zx_t)/pplay(i,k) ENDIF ENDIF zqsat(i,k)=zx_qs ENDDO ENDDO c calcul des propriétés des nuages convectifs clwcon0(:,:)=fact_cldcon*clwcon0(:,:) call clouds_gno s (klon,klev,q_seri,zqsat,clwcon0,ptconv,ratqsc,rnebcon0) endif DO i = 1, klon ema_pcb(i) = pbase(i) ENDDO DO i = 1, klon ema_pct(i) = paprs(i,itop_con(i)) ENDDO DO i = 1, klon ema_cbmf(i) = ema_workcbmf(i) ENDDO ELSE PRINT*, "iflag_con non-prevu", iflag_con CALL abort ENDIF c CALL homogene(paprs, q_seri, d_q_con, u_seri,v_seri, c . d_u_con, d_v_con) DO k = 1, klev DO i = 1, klon t_seri(i,k) = t_seri(i,k) + d_t_con(i,k) q_seri(i,k) = q_seri(i,k) + d_q_con(i,k) u_seri(i,k) = u_seri(i,k) + d_u_con(i,k) v_seri(i,k) = v_seri(i,k) + d_v_con(i,k) ENDDO ENDDO c IF (if_ebil.ge.2) THEN ztit='after convect' CALL diagetpq(paire,ztit,ip_ebil,2,2,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) call diagphy(paire,ztit,ip_ebil e , zero_v, zero_v, zero_v, zero_v, zero_v e , zero_v, rain_con, snow_con, ztsol e , d_h_vcol, d_qt, d_ec s , fs_bound, fq_bound ) END IF C IF (check) THEN za = qcheck(klon,klev,paprs,q_seri,ql_seri,paire) PRINT*, "aprescon=", za zx_t = 0.0 za = 0.0 DO i = 1, klon za = za + paire(i)/FLOAT(klon) zx_t = zx_t + (rain_con(i)+snow_con(i))*paire(i)/FLOAT(klon) ENDDO zx_t = zx_t/za*dtime PRINT*, "Precip=", zx_t ENDIF IF (zx_ajustq) THEN DO i = 1, klon z_apres(i) = 0.0 ENDDO DO k = 1, klev DO i = 1, klon z_apres(i) = z_apres(i) + (q_seri(i,k)+ql_seri(i,k)) . *(paprs(i,k)-paprs(i,k+1))/RG ENDDO ENDDO DO i = 1, klon z_factor(i) = (z_avant(i)-(rain_con(i)+snow_con(i))*dtime) . /z_apres(i) ENDDO DO k = 1, klev DO i = 1, klon IF (z_factor(i).GT.(1.0+1.0E-08) .OR. . z_factor(i).LT.(1.0-1.0E-08)) THEN q_seri(i,k) = q_seri(i,k) * z_factor(i) ENDIF ENDDO ENDDO ENDIF zx_ajustq=.FALSE. c IF (nqmax.GT.2) THEN !--melange convectif de traceurs c IF (iflag_con .NE. 2 .AND. debut) THEN PRINT*, 'Pour l instant, seul conflx fonctionne ', $ 'avec traceurs', iflag_con PRINT*,' Mettre iflag_con', $ ' = 2 dans run.def et repasser' c CALL abort ENDIF c ENDIF !--nqmax.GT.2 c c Appeler l'ajustement sec c CALL ajsec(paprs, pplay, t_seri, q_seri, d_t_ajs, d_q_ajs) DO k = 1, klev DO i = 1, klon t_seri(i,k) = t_seri(i,k) + d_t_ajs(i,k) q_seri(i,k) = q_seri(i,k) + d_q_ajs(i,k) ENDDO ENDDO c IF (if_ebil.ge.2) THEN ztit='after dry_adjust' CALL diagetpq(paire,ztit,ip_ebil,2,2,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) END IF c------------------------------------------------------------------------- c Caclul des ratqs c------------------------------------------------------------------------- c print*,'calcul des ratqs' c ratqs convectifs a l'ancienne en fonction de q(z=0)-q / q c ---------------- c on ecrase le tableau ratqsc calcule par clouds_gno if (iflag_cldcon.eq.1) then do k=1,klev do i=1,klon if(ptconv(i,k)) then ratqsc(i,k)=ratqsbas s +fact_cldcon*(q_seri(i,1)-q_seri(i,k))/q_seri(i,k) else ratqsc(i,k)=0. endif enddo enddo endif c ratqs stables c ------------- do k=1,klev ratqss(:,k)=ratqsbas+(ratqshaut-ratqsbas)* s min((paprs(:,1)-pplay(:,k))/(paprs(:,1)-30000.),1.) enddo c ratqs final c ----------- if (iflag_cldcon.eq.1 .or.iflag_cldcon.eq.2) then c les ratqs sont une conbinaison de ratqss et ratqsc c ratqs final c 1e4 (en gros 3 heures), en dur pour le moment, est le temps de c relaxation des ratqs c facttemps=exp(-pdtphys/1.e4) facteur=exp(-pdtphys*facttemps) ratqs(:,:)=max(ratqs(:,:)*facteur,ratqss(:,:)) ratqs(:,:)=max(ratqs(:,:),ratqsc(:,:)) c print*,'calcul des ratqs fini' else c on ne prend que le ratqs stable pour fisrtilp ratqs(:,:)=ratqss(:,:) endif c c Appeler le processus de condensation a grande echelle c et le processus de precipitation c------------------------------------------------------------------------- CALL fisrtilp(dtime,paprs,pplay, . t_seri, q_seri,ptconv,ratqs, . d_t_lsc, d_q_lsc, d_ql_lsc, rneb, cldliq, . rain_lsc, snow_lsc, . pfrac_impa, pfrac_nucl, pfrac_1nucl, . frac_impa, frac_nucl, . prfl, psfl, rhcl) WHERE (rain_lsc < 0) rain_lsc = 0. WHERE (snow_lsc < 0) snow_lsc = 0. DO k = 1, klev DO i = 1, klon t_seri(i,k) = t_seri(i,k) + d_t_lsc(i,k) q_seri(i,k) = q_seri(i,k) + d_q_lsc(i,k) ql_seri(i,k) = ql_seri(i,k) + d_ql_lsc(i,k) cldfra(i,k) = rneb(i,k) IF (.NOT.new_oliq) cldliq(i,k) = ql_seri(i,k) ENDDO ENDDO IF (check) THEN za = qcheck(klon,klev,paprs,q_seri,ql_seri,paire) PRINT*, "apresilp=", za zx_t = 0.0 za = 0.0 DO i = 1, klon za = za + paire(i)/FLOAT(klon) zx_t = zx_t + (rain_lsc(i)+snow_lsc(i))*paire(i)/FLOAT(klon) ENDDO zx_t = zx_t/za*dtime PRINT*, "Precip=", zx_t ENDIF c IF (if_ebil.ge.2) THEN ztit='after fisrt' CALL diagetpq(paire,ztit,ip_ebil,2,2,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) call diagphy(paire,ztit,ip_ebil e , zero_v, zero_v, zero_v, zero_v, zero_v e , zero_v, rain_lsc, snow_lsc, ztsol e , d_h_vcol, d_qt, d_ec s , fs_bound, fq_bound ) END IF c c------------------------------------------------------------------- c PRESCRIPTION DES NUAGES POUR LE RAYONNEMENT c------------------------------------------------------------------- c 1. NUAGES CONVECTIFS c IF (iflag_cldcon.eq.-1) THEN ! seulement pour Tiedtke c Nuages diagnostiques pour Tiedtke CALL diagcld1(paprs,pplay, . rain_con,snow_con,ibas_con,itop_con, . diafra,dialiq) DO k = 1, klev DO i = 1, klon IF (diafra(i,k).GT.cldfra(i,k)) THEN cldliq(i,k) = dialiq(i,k) cldfra(i,k) = diafra(i,k) ENDIF ENDDO ENDDO ELSE IF (iflag_cldcon.eq.3) THEN c On prend pour les nuages convectifs le max du calcul de la c convection et du calcul du pas de temps précédent diminué d'un facteur c facttemps c facttemps=pdtphys/1.e4 facteur = pdtphys *facttemps do k=1,klev do i=1,klon rnebcon(i,k)=rnebcon(i,k)*facteur if (rnebcon0(i,k)*clwcon0(i,k).gt.rnebcon(i,k)*clwcon(i,k)) s then rnebcon(i,k)=rnebcon0(i,k) clwcon(i,k)=clwcon0(i,k) endif enddo enddo c On prend la somme des fractions nuageuses et des contenus en eau cldfra(:,:)=min(max(cldfra(:,:),rnebcon(:,:)),1.) cldliq(:,:)=cldliq(:,:)+rnebcon(:,:)*clwcon(:,:) ENDIF c c 2. NUAGES STARTIFORMES c IF (ok_stratus) THEN CALL diagcld2(paprs,pplay,t_seri,q_seri, diafra,dialiq) DO k = 1, klev DO i = 1, klon IF (diafra(i,k).GT.cldfra(i,k)) THEN cldliq(i,k) = dialiq(i,k) cldfra(i,k) = diafra(i,k) ENDIF ENDDO ENDDO ENDIF c c Precipitation totale c DO i = 1, klon rain_fall(i) = rain_con(i) + rain_lsc(i) snow_fall(i) = snow_con(i) + snow_lsc(i) ENDDO c IF (if_ebil.ge.2) THEN ztit="after diagcld" CALL diagetpq(paire,ztit,ip_ebil,2,2,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) END IF c c Calculer l'humidite relative pour diagnostique c DO k = 1, klev DO i = 1, klon zx_t = t_seri(i,k) IF (thermcep) THEN zdelta = MAX(0.,SIGN(1.,rtt-zx_t)) zx_qs = r2es * FOEEW(zx_t,zdelta)/pplay(i,k) zx_qs = MIN(0.5,zx_qs) zcor = 1./(1.-retv*zx_qs) zx_qs = zx_qs*zcor ELSE IF (zx_t.LT.t_coup) THEN zx_qs = qsats(zx_t)/pplay(i,k) ELSE zx_qs = qsatl(zx_t)/pplay(i,k) ENDIF ENDIF zx_rh(i,k) = q_seri(i,k)/zx_qs zqsat(i,k)=zx_qs ENDDO ENDDO c c Calculer les parametres optiques des nuages et quelques c parametres pour diagnostiques: c if (ok_newmicro) then CALL newmicro (paprs, pplay,ok_newmicro, . t_seri, cldliq, cldfra, cldtau, cldemi, . cldh, cldl, cldm, cldt, cldq) else CALL nuage (paprs, pplay, . t_seri, cldliq, cldfra, cldtau, cldemi, . cldh, cldl, cldm, cldt, cldq) endif c c Appeler le rayonnement mais calculer tout d'abord l'albedo du sol. c IF (MOD(itaprad,radpas).EQ.0) THEN DO i = 1, klon albsol(i) = falbe(i,is_oce) * pctsrf(i,is_oce) . + falbe(i,is_lic) * pctsrf(i,is_lic) . + falbe(i,is_ter) * pctsrf(i,is_ter) . + falbe(i,is_sic) * pctsrf(i,is_sic) albsollw(i) = falblw(i,is_oce) * pctsrf(i,is_oce) . + falblw(i,is_lic) * pctsrf(i,is_lic) . + falblw(i,is_ter) * pctsrf(i,is_ter) . + falblw(i,is_sic) * pctsrf(i,is_sic) ENDDO ! if (debut) then ! albsol1 = albsol ! albsollw1 = albsollw ! endif ! albsol = albsol1 ! albsollw = albsollw1 CALL radlwsw ! nouveau rayonnement (compatible Arpege-IFS) e (dist, rmu0, fract, co2_ppm, solaire, e paprs, pplay,zxtsol,albsol, albsollw, t_seri,q_seri, e wo, e cldfra, cldemi, cldtau, s heat,heat0,cool,cool0,radsol,albpla, s topsw,toplw,solsw,sollw, s sollwdown, s topsw0,toplw0,solsw0,sollw0) itaprad = 0 ENDIF itaprad = itaprad + 1 c c Ajouter la tendance des rayonnements (tous les pas) c DO k = 1, klev DO i = 1, klon t_seri(i,k) = t_seri(i,k) . + (heat(i,k)-cool(i,k)) * dtime/86400. ENDDO ENDDO c IF (if_ebil.ge.2) THEN ztit='after rad' CALL diagetpq(paire,ztit,ip_ebil,2,2,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) call diagphy(paire,ztit,ip_ebil e , topsw, toplw, solsw, sollw, zero_v e , zero_v, zero_v, zero_v, ztsol e , d_h_vcol, d_qt, d_ec s , fs_bound, fq_bound ) END IF c c c Calculer l'hydrologie de la surface c c CALL hydrol(dtime,pctsrf,rain_fall, snow_fall, zxevap, c . agesno, ftsol,fqsol,fsnow, ruis) c DO i = 1, klon zxqsol(i) = 0.0 zxsnow(i) = 0.0 ENDDO DO nsrf = 1, nbsrf DO i = 1, klon zxqsol(i) = zxqsol(i) + fqsol(i,nsrf)*pctsrf(i,nsrf) zxsnow(i) = zxsnow(i) + fsnow(i,nsrf)*pctsrf(i,nsrf) ENDDO ENDDO c c Si une sous-fraction n'existe pas, elle prend la valeur moyenne c c$$$ DO nsrf = 1, nbsrf c$$$ DO i = 1, klon c$$$ IF (pctsrf(i,nsrf).LT.epsfra) THEN c$$$ fqsol(i,nsrf) = zxqsol(i) c$$$ fsnow(i,nsrf) = zxsnow(i) c$$$ ENDIF c$$$ ENDDO c$$$ ENDDO c c Calculer le bilan du sol et la derive de temperature (couplage) c DO i = 1, klon c bils(i) = radsol(i) - sens(i) - evap(i)*RLVTT c a la demande de JLD bils(i) = radsol(i) - sens(i) + zxfluxlat(i) ENDDO c cmoddeblott(jan95) c Appeler le programme de parametrisation de l'orographie c a l'echelle sous-maille: c IF (ok_orodr) THEN c c selection des points pour lesquels le shema est actif: igwd=0 DO i=1,klon itest(i)=0 c IF ((zstd(i).gt.10.0)) THEN IF (((zpic(i)-zmea(i)).GT.100.).AND.(zstd(i).GT.10.0)) THEN itest(i)=1 igwd=igwd+1 idx(igwd)=i ENDIF ENDDO c igwdim=MAX(1,igwd) c CALL drag_noro(klon,klev,dtime,paprs,pplay, e zmea,zstd, zsig, zgam, zthe,zpic,zval, e igwd,idx,itest, e t_seri, u_seri, v_seri, s zulow, zvlow, zustr, zvstr, s d_t_oro, d_u_oro, d_v_oro) c c ajout des tendances DO k = 1, klev DO i = 1, klon t_seri(i,k) = t_seri(i,k) + d_t_oro(i,k) u_seri(i,k) = u_seri(i,k) + d_u_oro(i,k) v_seri(i,k) = v_seri(i,k) + d_v_oro(i,k) ENDDO ENDDO c ENDIF ! fin de test sur ok_orodr c IF (ok_orolf) THEN c c selection des points pour lesquels le shema est actif: igwd=0 DO i=1,klon itest(i)=0 IF ((zpic(i)-zmea(i)).GT.100.) THEN itest(i)=1 igwd=igwd+1 idx(igwd)=i ENDIF ENDDO c igwdim=MAX(1,igwd) c CALL lift_noro(klon,klev,dtime,paprs,pplay, e rlat,zmea,zstd,zpic, e itest, e t_seri, u_seri, v_seri, s zulow, zvlow, zustr, zvstr, s d_t_lif, d_u_lif, d_v_lif) c c ajout des tendances DO k = 1, klev DO i = 1, klon t_seri(i,k) = t_seri(i,k) + d_t_lif(i,k) u_seri(i,k) = u_seri(i,k) + d_u_lif(i,k) v_seri(i,k) = v_seri(i,k) + d_v_lif(i,k) ENDDO ENDDO c ENDIF ! fin de test sur ok_orolf c IF (if_ebil.ge.2) THEN ztit='after orography' CALL diagetpq(paire,ztit,ip_ebil,2,2,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) END IF c c cAA cAA Installation de l'interface online-offline pour traceurs cAA c==================================================================== c Calcul des tendances traceurs c==================================================================== C Pascale : il faut quand meme apeller phytrac car il gere les sorties cKE43 des traceurs => il faut donc mettre des flags a .false. IF (iflag_con.GE.3) THEN c on ajoute les tendances calculees par KE43 c$$$ OM on onhibe la convection sur les traceurs DO iq=1, nqmax-2 ! Sandrine a -3 ??? c$$$ OM on inhibe la convection sur les traceur c$$$ DO k = 1, nlev c$$$ DO i = 1, klon c$$$ tr_seri(i,k,iq) = tr_seri(i,k,iq) + d_tr(i,k,iq) c$$$ ENDDO c$$$ ENDDO WRITE(iqn,'(i2.2)') iq CALL minmaxqfi(tr_seri(1,1,iq),0.,1.e33,'couche lim iq='//iqn) ENDDO CMAF modif pour garder info du nombre de traceurs auxquels C la physique s'applique ELSE CMAF modif pour garder info du nombre de traceurs auxquels C la physique s'applique C call phytrac (rnpb, I debut,lafin, I nqmax-2, I nlon,nlev,dtime, I t,paprs,pplay, I pmfu, pmfd, pen_u, pde_u, pen_d, pde_d, I ycoefh,yu1,yv1,ftsol,pctsrf,rlat, I frac_impa, frac_nucl, I rlon,presnivs,paire,pphis, O tr_seri) ENDIF IF (offline) THEN call phystokenc ( I nlon,nlev,pdtphys,rlon,rlat, I t,pmfu, pmfd, pen_u, pde_u, pen_d, pde_d, I ycoefh,yu1,yv1,ftsol,pctsrf, I frac_impa, frac_nucl, I pphis,paire,dtime,itap) ENDIF c c Calculer le transport de l'eau et de l'energie (diagnostique) c CALL transp (paprs,zxtsol, e t_seri, q_seri, u_seri, v_seri, zphi, s ve, vq, ue, uq) c c Accumuler les variables a stocker dans les fichiers histoire: c c c IF (if_ebil.ge.1) THEN ztit='after physic' CALL diagetpq(paire,ztit,ip_ebil,1,1,dtime e , t_seri,q_seri,ql_seri,qs_seri,u_seri,v_seri,paprs,pplay s , d_h_vcol, d_qt, d_qw, d_ql, d_qs, d_ec) C Comme les tendances de la physique sont ajoute dans la dynamique, C on devrait avoir que la variation d'entalpie par la dynamique C est egale a la variation de la physique au pas de temps precedent. C Donc la somme de ces 2 variations devrait etre nulle. call diagphy(paire,ztit,ip_ebil e , topsw, toplw, solsw, sollw, sens e , evap, rain_fall, snow_fall, ztsol e , d_h_vcol, d_qt, d_ec s , fs_bound, fq_bound ) C d_h_vcol_phy=d_h_vcol C END IF C IF (ok_journe) THEN c ndex2d = 0 ndex3d = 0 c c Champs 2D: c zsto = dtime zout = dtime * FLOAT(ecrit_day) itau_w = itau_phy + itap i = NINT(zout/zsto) CALL gr_fi_ecrit(1,klon,iim,jjmp1,pphis,zx_tmp_2d) CALL histwrite(nid_day,"phis",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) varname = 'phis' vartitle= 'Surface geop. height' varunits= '-' c call writephy(fid_day,prof2d_on,varname,pphis,vartitle, c . varunits) c i = NINT(zout/zsto) CALL gr_fi_ecrit(1,klon,iim,jjmp1,paire,zx_tmp_2d) CALL histwrite(nid_day,"aire",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) varname = 'aire' vartitle= 'Grid area' varunits= '-' c call writephy(fid_day,prof2d_on,varname,paire,vartitle, c . varunits) C CALL gr_fi_ecrit(1, klon,iim,jjmp1, zxtsol,zx_tmp_2d) CALL histwrite(nid_day,"tsol",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'tsol',zxtsol, c . 'Surface Temperature','K') c C zx_tmp_fi2d(1 : klon) = ftsol(1 : klon, is_ter) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d ,zx_tmp_2d) CALL histwrite(nid_day,"tter",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'tter',ftsol(1 : klon, is_ter), c . 'Surface Temperature','K') C zx_tmp_fi2d(1 : klon) = ftsol(1 : klon, is_lic) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_day,"tlic",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'tlic',ftsol(1 : klon, is_lic), c . 'Surface Temperature','K') C zx_tmp_fi2d(1 : klon) = ftsol(1 : klon, is_oce) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_day,"toce",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'toce',ftsol(1 : klon, is_oce), c . 'Surface Temperature','K') C zx_tmp_fi2d(1 : klon) = ftsol(1 : klon, is_sic) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_day,"tsic",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'tsic',ftsol(1 : klon, is_sic), c . 'Surface Temperature','K') C DO i = 1, klon zx_tmp_fi2d(i) = paprs(i,1) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_day,"psol",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c Essai writephys varname = 'psol' vartitle= 'pression au sol' varunits= 'hPa' c call writephy(fid_day,prof2d_av,varname,zx_tmp_fi2d,vartitle, c . varunits) c DO i = 1, klon zx_tmp_fi2d(i) = (rain_fall(i) + snow_fall(i)) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_day,"precip",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'rain',zx_tmp_fi2d, c . 'Precipitation','mm/day') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, snow_fall,zx_tmp_2d) CALL histwrite(nid_day,"snow",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'snow',snow_fall, c . 'Snow','mm/day') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, zxsnow,zx_tmp_2d) CALL histwrite(nid_day,"snow_mass",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c call writephy(fid_day,prof2d_av,'snow_mass',zxsnow, c . 'Snow cover','mm') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, evap,zx_tmp_2d) CALL histwrite(nid_day,"evap",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'evap',evap, c . 'Evaporation','mm/day') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, topsw,zx_tmp_2d) CALL histwrite(nid_day,"tops",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'tops',topsw, c . 'Solar rad. at TOA','W/m2') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, toplw,zx_tmp_2d) CALL histwrite(nid_day,"topl",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'topl',toplw, c . 'IR rad. at TOA','W/m2') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, solsw,zx_tmp_2d) CALL histwrite(nid_day,"sols",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'sols',solsw, c . 'Solar rad. at surf.','W/m2') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sollw,zx_tmp_2d) CALL histwrite(nid_day,"soll",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'soll',sollw, c . 'IR rad. at surface','W/m2') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sollwdown,zx_tmp_2d) CALL histwrite(nid_day,"solldown",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c call writephy(fid_day,prof2d_av,'solldown',sollwdown, c . 'Down. IR rad. at surface','W/m2') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, bils,zx_tmp_2d) CALL histwrite(nid_day,"bils",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'bils',bils, c . 'Surf. total heat flux','W/m2') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sens,zx_tmp_2d) CALL histwrite(nid_day,"sens",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'sens',sens, c . 'Sensible heat flux','W/m2') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, fder,zx_tmp_2d) CALL histwrite(nid_day,"fder",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'fder',fder, c . 'Heat flux derivation','W/m2') c c DO nsrf = 1, nbsrf C§§§ zx_tmp_fi2d(1 : klon) = pctsrf( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_day,"pourc_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'pourc_'//clnsurf(nsrf), c . pctsrf( 1 : klon, nsrf), c . 'Fraction'//clnsurf(nsrf),'-') C zx_tmp_fi2d(1 : klon) = ftsol( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_day,"tsol_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'tsol_'//clnsurf(nsrf), c . ftsol( 1 : klon, nsrf), c . 'Surf. Temp'//clnsurf(nsrf),'K') C zx_tmp_fi2d(1 : klon) = fluxt( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_day,"sens_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'sens_'//clnsurf(nsrf), c . fluxt( 1 : klon, 1, nsrf), c . 'Sensible heat flux '//clnsurf(nsrf),'W/m2') C zx_tmp_fi2d(1 : klon) = fluxlat( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_day,"lat_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'lat_'//clnsurf(nsrf), c . fluxlat( 1 : klon, nsrf), c . 'Latent heat flux '//clnsurf(nsrf),'W/m2') C zx_tmp_fi2d(1 : klon) = fluxu( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_day,"taux_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'taux_'//clnsurf(nsrf), c . fluxu( 1 : klon, 1, nsrf), c . 'Zonal wind stress '//clnsurf(nsrf),'Pa') C zx_tmp_fi2d(1 : klon) = fluxv( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_day,"tauy_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'tauy_'//clnsurf(nsrf), c . fluxv( 1 : klon, 1, nsrf), c . 'Meridional wind stress '//clnsurf(nsrf),'Pa') C zx_tmp_fi2d(1 : klon) = falbe( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_day,"albe_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'albe_'//clnsurf(nsrf), c . falbe( 1 : klon, nsrf), c . 'Albedo surf. SW'//clnsurf(nsrf),'-') c call writephy(fid_day,prof2d_av,'alblw_'//clnsurf(nsrf), c . falblw( 1 : klon, nsrf), c . 'Albedo surf. LW'//clnsurf(nsrf),'-') C zx_tmp_fi2d(1 : klon) = frugs( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_day,"rugs_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'rugs_'//clnsurf(nsrf), c . frugs( 1 : klon, nsrf), c . 'Rugosity '//clnsurf(nsrf),' - ') C END DO C c$$$ DO i = 1, klon c$$$ zx_tmp_fi2d(i) = pctsrf(i,is_sic) c$$$ ENDDO c$$$ CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) c$$$ CALL histwrite(nid_day,"sicf",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldl,zx_tmp_2d) CALL histwrite(nid_day,"cldl",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'cldl',cldl, c . 'Low-level cloudiness','-') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldm,zx_tmp_2d) CALL histwrite(nid_day,"cldm",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'cldm',cldm, c . 'Mid-level cloudiness','-') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldh,zx_tmp_2d) CALL histwrite(nid_day,"cldh",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'cldh',cldh, c . 'High-level cloudiness','-') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldt,zx_tmp_2d) CALL histwrite(nid_day,"cldt",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'cldt',cldt, c . 'Total cloudiness','-') c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldq,zx_tmp_2d) CALL histwrite(nid_day,"cldq",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c call writephy(fid_day,prof2d_av,'cldq',cldq, c . 'Cloud liquid water path','-') c c Champs 3D: c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, t_seri, zx_tmp_3d) CALL histwrite(nid_day,"temp",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c Essai writephys varname = 'temp' vartitle= 'temperature 3D' varunits= 'K' c call writephy(fid_day,prof3d_av,varname,t_seri,vartitle,varunits) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, qx(1,1,ivap), zx_tmp_3d) CALL histwrite(nid_day,"ovap",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c call writephy(fid_day,prof3d_av,'ovap',qx(1,1,ivap), c . 'Specific humidity','Kg/Kg') c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, zphi, zx_tmp_3d) CALL histwrite(nid_day,"geop",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c call writephy(fid_day,prof3d_av,'geop',zphi, c . 'Geopotential height','m') c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, u_seri, zx_tmp_3d) CALL histwrite(nid_day,"vitu",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c call writephy(fid_day,prof3d_av,'vitu',u_seri, c . 'Zonal wind','m/s') c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, v_seri, zx_tmp_3d) CALL histwrite(nid_day,"vitv",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c call writephy(fid_day,prof3d_av,'vitv',v_seri, c . 'Meridional wind','m/s') c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, omega, zx_tmp_3d) CALL histwrite(nid_day,"vitw",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c call writephy(fid_day,prof3d_av,'vitw',omega, c . 'Vertical wind','m/s') c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, pplay, zx_tmp_3d) CALL histwrite(nid_day,"pres",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c call writephy(fid_day,prof3d_av,'pres',pplay, c . 'Air pressure','Pa') c if (ok_sync) then c call writephy_sync(fid_day) call histsync(nid_day) endif ENDIF C IF (ok_mensuel) THEN c ndex2d = 0 ndex3d = 0 c c Champs 2D: c zsto = dtime zout = dtime * ecrit_mth itau_w = itau_phy + itap i = NINT(zout/zsto) CALL gr_fi_ecrit(1,klon,iim,jjmp1,pphis,zx_tmp_2d) CALL histwrite(nid_mth,"phis",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) C i = NINT(zout/zsto) CALL gr_fi_ecrit(1,klon,iim,jjmp1,paire,zx_tmp_2d) CALL histwrite(nid_mth,"aire",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zxtsol,zx_tmp_2d) CALL histwrite(nid_mth,"tsol",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c DO i = 1, klon zx_tmp_fi2d(i) = paprs(i,1) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_mth,"psol",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, zxqsol,zx_tmp_2d) CALL histwrite(nid_mth,"qsol",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c DO i = 1, klon zx_tmp_fi2d(i) = rain_fall(i) + snow_fall(i) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_mth,"precip",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c DO i = 1, klon zx_tmp_fi2d(i) = rain_lsc(i) + snow_lsc(i) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_mth,"plul",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c DO i = 1, klon zx_tmp_fi2d(i) = rain_con(i) + snow_con(i) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_mth,"pluc",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, snow_fall,zx_tmp_2d) CALL histwrite(nid_mth,"snow",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, zxsnow,zx_tmp_2d) CALL histwrite(nid_mth,"snow_mass",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, evap,zx_tmp_2d) CALL histwrite(nid_mth,"evap",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, topsw,zx_tmp_2d) CALL histwrite(nid_mth,"tops",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, toplw,zx_tmp_2d) CALL histwrite(nid_mth,"topl",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, solsw,zx_tmp_2d) CALL histwrite(nid_mth,"sols",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sollw,zx_tmp_2d) CALL histwrite(nid_mth,"soll",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sollwdown,zx_tmp_2d) CALL histwrite(nid_mth,"solldown",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, topsw0,zx_tmp_2d) CALL histwrite(nid_mth,"tops0",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, toplw0,zx_tmp_2d) CALL histwrite(nid_mth,"topl0",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, solsw0,zx_tmp_2d) CALL histwrite(nid_mth,"sols0",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sollw0,zx_tmp_2d) CALL histwrite(nid_mth,"soll0",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, bils,zx_tmp_2d) CALL histwrite(nid_mth,"bils",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sens,zx_tmp_2d) CALL histwrite(nid_mth,"sens",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, fder,zx_tmp_2d) CALL histwrite(nid_mth,"fder",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c c c DO i = 1, klon c zx_tmp_fi2d(i) = fluxu(i,1) c ENDDO c CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) c CALL histwrite(nid_mth,"frtu",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c c DO i = 1, klon c zx_tmp_fi2d(i) = fluxv(i,1) c ENDDO c CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) c CALL histwrite(nid_mth,"frtv",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c DO nsrf = 1, nbsrf C§§§ zx_tmp_fi2d(1 : klon) = pctsrf( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_mth,"pourc_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = ftsol( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_mth,"tsol_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = fluxt( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_mth,"sens_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = fluxlat( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_mth,"lat_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = fluxu( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_mth,"taux_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = fluxv( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_mth,"tauy_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = falbe( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_mth,"albe_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = frugs( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_mth,"rugs_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) c zx_tmp_fi2d(1 : klon) = agesno( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, agesno,zx_tmp_2d) CALL histwrite(nid_mth,"ages_"//clnsurf(nsrf),itau_w $ ,zx_tmp_2d,iim*jjmp1,ndex2d) END DO c$$$ DO i = 1, klon c$$$ zx_tmp_fi2d(i) = pctsrf(i,is_sic) c$$$ ENDDO c$$$ CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) c$$$ CALL histwrite(nid_mth,"sicf",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, albsol,zx_tmp_2d) CALL histwrite(nid_mth,"albs",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) CALL gr_fi_ecrit(1, klon,iim,jjmp1, albsollw,zx_tmp_2d) CALL histwrite(nid_mth,"albslw",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cdragm,zx_tmp_2d) CALL histwrite(nid_mth,"cdrm",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cdragh,zx_tmp_2d) CALL histwrite(nid_mth,"cdrh",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldl,zx_tmp_2d) CALL histwrite(nid_mth,"cldl",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldm,zx_tmp_2d) CALL histwrite(nid_mth,"cldm",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldh,zx_tmp_2d) CALL histwrite(nid_mth,"cldh",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldt,zx_tmp_2d) CALL histwrite(nid_mth,"cldt",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cldq,zx_tmp_2d) CALL histwrite(nid_mth,"cldq",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, ue,zx_tmp_2d) CALL histwrite(nid_mth,"ue",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, ve,zx_tmp_2d) CALL histwrite(nid_mth,"ve",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, uq,zx_tmp_2d) CALL histwrite(nid_mth,"uq",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, vq,zx_tmp_2d) CALL histwrite(nid_mth,"vq",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) cKE43 IF (iflag_con .GE. 3) THEN ! sb c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cape,zx_tmp_2d) CALL histwrite(nid_mth,"cape",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1,pbase,zx_tmp_2d) CALL histwrite(nid_mth,"pbase",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1,ema_pct,zx_tmp_2d) CALL histwrite(nid_mth,"ptop",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1,ema_cbmf,zx_tmp_2d) CALL histwrite(nid_mth,"fbase",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c c ENDIF c34EK c c Champs 3D: C CALL gr_fi_ecrit(klev,klon,iim,jjmp1, t_seri, zx_tmp_3d) CALL histwrite(nid_mth,"temp",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, qx(1,1,ivap), zx_tmp_3d) CALL histwrite(nid_mth,"ovap",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, zphi, zx_tmp_3d) CALL histwrite(nid_mth,"geop",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, u_seri, zx_tmp_3d) CALL histwrite(nid_mth,"vitu",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, v_seri, zx_tmp_3d) CALL histwrite(nid_mth,"vitv",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, omega, zx_tmp_3d) CALL histwrite(nid_mth,"vitw",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, pplay, zx_tmp_3d) CALL histwrite(nid_mth,"pres",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, cldfra, zx_tmp_3d) CALL histwrite(nid_mth,"rneb",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, zx_rh, zx_tmp_3d) CALL histwrite(nid_mth,"rhum",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, cldliq, zx_tmp_3d) CALL histwrite(nid_mth,"oliq",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, clwcon0, zx_tmp_3d) CALL histwrite(nid_mth,"clwcon",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_t_dyn, zx_tmp_3d) CALL histwrite(nid_mth,"dtdyn",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_q_dyn, zx_tmp_3d) CALL histwrite(nid_mth,"dqdyn",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_t_con, zx_tmp_3d) CALL histwrite(nid_mth,"dtcon",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_q_con, zx_tmp_3d) CALL histwrite(nid_mth,"dqcon",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_t_lsc, zx_tmp_3d) CALL histwrite(nid_mth,"dtlsc",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_q_lsc, zx_tmp_3d) CALL histwrite(nid_mth,"dqlsc",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_t_vdf, zx_tmp_3d) CALL histwrite(nid_mth,"dtvdf",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_q_vdf, zx_tmp_3d) CALL histwrite(nid_mth,"dqvdf",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_t_eva, zx_tmp_3d) CALL histwrite(nid_mth,"dteva",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_q_eva, zx_tmp_3d) CALL histwrite(nid_mth,"dqeva",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c zpt_conv = 0. where (ptconv) zpt_conv = 1. CALL gr_fi_ecrit(klev,klon,iim,jjmp1, zpt_conv, zx_tmp_3d) CALL histwrite(nid_mth,"ptconv",itau_w,zx_tmp_3d, . iim*(jjmp1)*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, ratqs, zx_tmp_3d) CALL histwrite(nid_mth,"ratqs",itau_w,zx_tmp_3d, . iim*(jjmp1)*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_t_ajs, zx_tmp_3d) CALL histwrite(nid_mth,"dtajs",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_q_ajs, zx_tmp_3d) CALL histwrite(nid_mth,"dqajs",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, heat, zx_tmp_3d) CALL histwrite(nid_mth,"dtswr",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, heat0, zx_tmp_3d) CALL histwrite(nid_mth,"dtsw0",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, cool, zx_tmp_3d) CALL histwrite(nid_mth,"dtlwr",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, cool0, zx_tmp_3d) CALL histwrite(nid_mth,"dtlw0",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_u_vdf, zx_tmp_3d) CALL histwrite(nid_mth,"duvdf",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_v_vdf, zx_tmp_3d) CALL histwrite(nid_mth,"dvvdf",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c IF (ok_orodr) THEN CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_u_oro, zx_tmp_3d) CALL histwrite(nid_mth,"duoro",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_v_oro, zx_tmp_3d) CALL histwrite(nid_mth,"dvoro",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c ENDIF C IF (ok_orolf) THEN CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_u_lif, zx_tmp_3d) CALL histwrite(nid_mth,"dulif",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_v_lif, zx_tmp_3d) CALL histwrite(nid_mth,"dvlif",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) ENDIF C CALL gr_fi_ecrit(klev,klon,iim,jjmp1, wo, zx_tmp_3d) CALL histwrite(nid_mth,"ozone",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c IF (nqmax.GE.3) THEN DO iq=1,nqmax-2 IF (iq.LE.99) THEN CALL gr_fi_ecrit(klev,klon,iim,jjmp1, qx(1,1,iq+2), zx_tmp_3d) WRITE(str2,'(i2.2)') iq CALL histwrite(nid_mth,"trac"//str2,itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) ELSE PRINT*, "Trop de traceurs" CALL abort ENDIF ENDDO ENDIF cKE43 IF (iflag_con.GE.3) THEN ! (sb) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, upwd, zx_tmp_3d) CALL histwrite(nid_mth,"upwd",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, dnwd, zx_tmp_3d) CALL histwrite(nid_mth,"dnwd",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, dnwd0, zx_tmp_3d) CALL histwrite(nid_mth,"dnwd0",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, Ma, zx_tmp_3d) CALL histwrite(nid_mth,"Ma",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c c ENDIF c34EK c if (ok_sync) then call histsync(nid_mth) endif ENDIF c IF (ok_instan) THEN c ndex2d = 0 ndex3d = 0 c c Champs 2D: c zsto = dtime * ecrit_ins zout = dtime * ecrit_ins itau_w = itau_phy + itap i = NINT(zout/zsto) CALL gr_fi_ecrit(1,klon,iim,jjmp1,pphis,zx_tmp_2d) CALL histwrite(nid_ins,"phis",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c i = NINT(zout/zsto) CALL gr_fi_ecrit(1,klon,iim,jjmp1,paire,zx_tmp_2d) CALL histwrite(nid_ins,"aire",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) DO i = 1, klon zx_tmp_fi2d(i) = paprs(i,1) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_ins,"psol",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c DO i = 1, klon zx_tmp_fi2d(i) = rain_fall(i) + snow_fall(i) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_ins,"precip",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c DO i = 1, klon zx_tmp_fi2d(i) = rain_lsc(i) + snow_lsc(i) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_ins,"plul",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c DO i = 1, klon zx_tmp_fi2d(i) = rain_con(i) + snow_con(i) ENDDO CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d,zx_tmp_2d) CALL histwrite(nid_ins,"pluc",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zxtsol,zx_tmp_2d) CALL histwrite(nid_ins,"tsol",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, snow_fall,zx_tmp_2d) CALL histwrite(nid_ins,"snow",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) CALL gr_fi_ecrit(1, klon,iim,jjmp1, cdragm,zx_tmp_2d) CALL histwrite(nid_ins,"cdrm",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, cdragh,zx_tmp_2d) CALL histwrite(nid_ins,"cdrh",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, toplw,zx_tmp_2d) CALL histwrite(nid_ins,"topl",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, evap,zx_tmp_2d) CALL histwrite(nid_ins,"evap",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, solsw,zx_tmp_2d) CALL histwrite(nid_ins,"sols",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sollw,zx_tmp_2d) CALL histwrite(nid_ins,"soll",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sollwdown,zx_tmp_2d) CALL histwrite(nid_ins,"solldown",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, bils,zx_tmp_2d) CALL histwrite(nid_ins,"bils",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, sens,zx_tmp_2d) CALL histwrite(nid_ins,"sens",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, fder,zx_tmp_2d) CALL histwrite(nid_ins,"fder",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, d_ts(1,is_oce),zx_tmp_2d) CALL histwrite(nid_ins,"dtsvdfo",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, d_ts(1,is_ter),zx_tmp_2d) CALL histwrite(nid_ins,"dtsvdft",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, d_ts(1,is_lic),zx_tmp_2d) CALL histwrite(nid_ins,"dtsvdfg",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, d_ts(1,is_sic),zx_tmp_2d) CALL histwrite(nid_ins,"dtsvdfi",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) DO nsrf = 1, nbsrf C§§§ zx_tmp_fi2d(1 : klon) = pctsrf( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_ins,"pourc_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = fluxt( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_ins,"sens_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = fluxlat( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_ins,"lat_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = ftsol( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_ins,"tsol_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = fluxu( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_ins,"taux_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = fluxv( 1 : klon, 1, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_ins,"tauy_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = frugs( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_ins,"rugs_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C zx_tmp_fi2d(1 : klon) = falbe( 1 : klon, nsrf) CALL gr_fi_ecrit(1, klon,iim,jjmp1, zx_tmp_fi2d , zx_tmp_2d) CALL histwrite(nid_ins,"albe_"//clnsurf(nsrf),itau_w, $ zx_tmp_2d,iim*jjmp1,ndex2d) C END DO CALL gr_fi_ecrit(1, klon,iim,jjmp1, albsol,zx_tmp_2d) CALL histwrite(nid_ins,"albs",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) CALL gr_fi_ecrit(1, klon,iim,jjmp1, albsollw,zx_tmp_2d) CALL histwrite(nid_ins,"albslw",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, zxsnow,zx_tmp_2d) CALL histwrite(nid_ins,"snow_mass",itau_w,zx_tmp_2d,iim*jjmp1, . ndex2d) c CALL gr_fi_ecrit(1, klon,iim,jjmp1, zxrugs,zx_tmp_2d) CALL histwrite(nid_ins,"rugs",itau_w,zx_tmp_2d,iim*jjmp1,ndex2d) c c Champs 3D: c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, t_seri, zx_tmp_3d) CALL histwrite(nid_ins,"temp",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, u_seri, zx_tmp_3d) CALL histwrite(nid_ins,"vitu",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, v_seri, zx_tmp_3d) CALL histwrite(nid_ins,"vitv",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, zphi, zx_tmp_3d) CALL histwrite(nid_ins,"geop",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, pplay, zx_tmp_3d) CALL histwrite(nid_ins,"pres",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_t_vdf, zx_tmp_3d) CALL histwrite(nid_ins,"dtvdf",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c CALL gr_fi_ecrit(klev,klon,iim,jjmp1, d_q_vdf, zx_tmp_3d) CALL histwrite(nid_ins,"dqvdf",itau_w,zx_tmp_3d, . iim*jjmp1*klev,ndex3d) c if (ok_sync) then call histsync(nid_ins) endif ENDIF c c c Ecrire la bande regionale (binaire grads) IF (ok_region .AND. mod(itap,ecrit_reg).eq.0) THEN CALL ecriregs(84,zxtsol) CALL ecriregs(84,paprs(1,1)) CALL ecriregs(84,topsw) CALL ecriregs(84,toplw) CALL ecriregs(84,solsw) CALL ecriregs(84,sollw) CALL ecriregs(84,rain_fall) CALL ecriregs(84,snow_fall) CALL ecriregs(84,evap) CALL ecriregs(84,sens) CALL ecriregs(84,bils) CALL ecriregs(84,pctsrf(1,is_sic)) CALL ecriregs(84,zxfluxu(1,1)) CALL ecriregs(84,zxfluxv(1,1)) CALL ecriregs(84,ue) CALL ecriregs(84,ve) CALL ecriregs(84,uq) CALL ecriregs(84,vq) c CALL ecrirega(84,u_seri) CALL ecrirega(84,v_seri) CALL ecrirega(84,omega) CALL ecrirega(84,t_seri) CALL ecrirega(84,zphi) CALL ecrirega(84,q_seri) CALL ecrirega(84,cldfra) CALL ecrirega(84,cldliq) CALL ecrirega(84,pplay) cc CALL ecrirega(84,d_t_dyn) cc CALL ecrirega(84,d_q_dyn) cc CALL ecrirega(84,heat) cc CALL ecrirega(84,cool) cc CALL ecrirega(84,d_t_con) cc CALL ecrirega(84,d_q_con) cc CALL ecrirega(84,d_t_lsc) cc CALL ecrirega(84,d_q_lsc) ENDIF c c Convertir les incrementations en tendances c DO k = 1, klev DO i = 1, klon d_u(i,k) = ( u_seri(i,k) - u(i,k) ) / dtime d_v(i,k) = ( v_seri(i,k) - v(i,k) ) / dtime d_t(i,k) = ( t_seri(i,k)-t(i,k) ) / dtime d_qx(i,k,ivap) = ( q_seri(i,k) - qx(i,k,ivap) ) / dtime d_qx(i,k,iliq) = ( ql_seri(i,k) - qx(i,k,iliq) ) / dtime ENDDO ENDDO c IF (nqmax.GE.3) THEN DO iq = 3, nqmax DO k = 1, klev DO i = 1, klon d_qx(i,k,iq) = ( tr_seri(i,k,iq-2) - qx(i,k,iq) ) / dtime ENDDO ENDDO ENDDO ENDIF c c Sauvegarder les valeurs de t et q a la fin de la physique: c DO k = 1, klev DO i = 1, klon t_ancien(i,k) = t_seri(i,k) q_ancien(i,k) = q_seri(i,k) ENDDO ENDDO c c==================================================================== c Si c'est la fin, il faut conserver l'etat de redemarrage c==================================================================== c IF (lafin) THEN itau_phy = itau_phy + itap ccc IF (ok_oasis) CALL quitcpl CALL phyredem ("restartphy.nc",dtime,radpas,co2_ppm,solaire, . rlat, rlon, pctsrf, ftsol, ftsoil, deltat, fqsol, fsnow, . falbe, fevap, rain_fall, snow_fall, . solsw, sollwdown,dlw, . radsol,frugs,agesno, . zmea,zstd,zsig,zgam,zthe,zpic,zval,rugoro, . t_ancien, q_ancien, rnebcon, ratqs, clwcon) ENDIF RETURN END FUNCTION qcheck(klon,klev,paprs,q,ql,aire) IMPLICIT none c c Calculer et imprimer l'eau totale. A utiliser pour verifier c la conservation de l'eau c #include "YOMCST.h" INTEGER klon,klev REAL paprs(klon,klev+1), q(klon,klev), ql(klon,klev) REAL aire(klon) REAL qtotal, zx, qcheck INTEGER i, k c zx = 0.0 DO i = 1, klon zx = zx + aire(i) ENDDO qtotal = 0.0 DO k = 1, klev DO i = 1, klon qtotal = qtotal + (q(i,k)+ql(i,k)) * aire(i) . *(paprs(i,k)-paprs(i,k+1))/RG ENDDO ENDDO c qcheck = qtotal/zx c RETURN END SUBROUTINE gr_fi_ecrit(nfield,nlon,iim,jjmp1,fi,ecrit) IMPLICIT none c c Tranformer une variable de la grille physique a c la grille d'ecriture c INTEGER nfield,nlon,iim,jjmp1, jjm REAL fi(nlon,nfield), ecrit(iim*jjmp1,nfield) c INTEGER i, n, ig c jjm = jjmp1 - 1 DO n = 1, nfield DO i=1,iim ecrit(i,n) = fi(1,n) ecrit(i+jjm*iim,n) = fi(nlon,n) ENDDO DO ig = 1, nlon - 2 ecrit(iim+ig,n) = fi(1+ig,n) ENDDO ENDDO RETURN END