itau_w = itau_phy + itap + start_time * day_step / iphysiq ! ug On transmet le pas de temps à iophy pour que les méthodes histwrite y aient accès: itau_iophy = itau_w ndex2d = 0 ndex3d = 0 !!! Champs 1D !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! CALL histwrite_phy(o_phis, pphis) CALL histwrite_phy(o_aire, airephy) DO i=1, klon zx_tmp_fi2d(i)=pctsrf(i,is_ter)+pctsrf(i,is_lic) ENDDO CALL histwrite_phy(o_contfracATM, zx_tmp_fi2d) CALL histwrite_phy(o_contfracOR, pctsrf(:,is_ter)) CALL histwrite_phy(o_aireTER, paire_ter) !!! Champs 2D !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! CALL histwrite_phy(o_flat, zxfluxlat) CALL histwrite_phy(o_slp, slp) CALL histwrite_phy(o_tsol, zxtsol) CALL histwrite_phy(o_t2m, zt2m) CALL histwrite_phy(o_t2m_min, zt2m) CALL histwrite_phy(o_t2m_max, zt2m) DO i=1, klon zx_tmp_fi2d(i)=SQRT(zu10m(i)*zu10m(i)+zv10m(i)*zv10m(i)) ENDDO CALL histwrite_phy(o_wind10m, zx_tmp_fi2d) DO i=1, klon zx_tmp_fi2d(i)=SQRT(zu10m(i)*zu10m(i)+zv10m(i)*zv10m(i)) ENDDO CALL histwrite_phy(o_wind10max, zx_tmp_fi2d) DO i = 1, klon zx_tmp_fi2d(i) = pctsrf(i,is_sic) ENDDO CALL histwrite_phy(o_sicf, zx_tmp_fi2d) CALL histwrite_phy(o_q2m, zq2m) CALL histwrite_phy(o_ustar, zustar) CALL histwrite_phy(o_u10m, zu10m) CALL histwrite_phy(o_v10m, zv10m) DO i = 1, klon zx_tmp_fi2d(i) = paprs(i,1) ENDDO CALL histwrite_phy(o_psol, zx_tmp_fi2d) CALL histwrite_phy(o_mass, zmasse) CALL histwrite_phy(o_qsurf, zxqsurf) IF (.NOT. ok_veget) THEN CALL histwrite_phy(o_qsol, qsol) ENDIF DO i = 1, klon zx_tmp_fi2d(i) = rain_fall(i) + snow_fall(i) ENDDO CALL histwrite_phy(o_precip, zx_tmp_fi2d) CALL histwrite_phy(o_ndayrain, nday_rain) DO i = 1, klon zx_tmp_fi2d(i) = rain_lsc(i) + snow_lsc(i) ENDDO CALL histwrite_phy(o_plul, zx_tmp_fi2d) DO i = 1, klon zx_tmp_fi2d(i) = rain_con(i) + snow_con(i) ENDDO CALL histwrite_phy(o_pluc, zx_tmp_fi2d) CALL histwrite_phy(o_snow, snow_fall) CALL histwrite_phy(o_msnow, snow_o) CALL histwrite_phy(o_fsnow, zfra_o) CALL histwrite_phy(o_evap, evap) CALL histwrite_phy(o_tops, topsw) CALL histwrite_phy(o_tops0, topsw0) CALL histwrite_phy(o_topl, toplw) CALL histwrite_phy(o_topl0, toplw0) zx_tmp_fi2d(1 : klon) = swup ( 1 : klon, klevp1 ) CALL histwrite_phy(o_SWupTOA, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = swup0 ( 1 : klon, klevp1 ) CALL histwrite_phy(o_SWupTOAclr, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = swdn ( 1 : klon, klevp1 ) CALL histwrite_phy(o_SWdnTOA, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = swdn0 ( 1 : klon, klevp1 ) CALL histwrite_phy(o_SWdnTOAclr, zx_tmp_fi2d) zx_tmp_fi2d(:) = topsw(:)-toplw(:) CALL histwrite_phy(o_nettop, zx_tmp_fi2d) CALL histwrite_phy(o_SWup200, SWup200) CALL histwrite_phy(o_SWup200clr, SWup200clr) CALL histwrite_phy(o_SWdn200, SWdn200) CALL histwrite_phy(o_SWdn200clr, SWdn200clr) CALL histwrite_phy(o_LWup200, LWup200) CALL histwrite_phy(o_LWup200clr, LWup200clr) CALL histwrite_phy(o_LWdn200, LWdn200) CALL histwrite_phy(o_LWdn200clr, LWdn200clr) CALL histwrite_phy(o_sols, solsw) CALL histwrite_phy(o_sols0, solsw0) CALL histwrite_phy(o_soll, sollw) CALL histwrite_phy(o_radsol, radsol) CALL histwrite_phy(o_soll0, sollw0) zx_tmp_fi2d(1 : klon) = swup ( 1 : klon, 1 ) CALL histwrite_phy(o_SWupSFC, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = swup0 ( 1 : klon, 1 ) CALL histwrite_phy(o_SWupSFCclr, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = swdn ( 1 : klon, 1 ) CALL histwrite_phy(o_SWdnSFC, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = swdn0 ( 1 : klon, 1 ) CALL histwrite_phy(o_SWdnSFCclr, zx_tmp_fi2d) zx_tmp_fi2d(1:klon)=sollwdown(1:klon)-sollw(1:klon) CALL histwrite_phy(o_LWupSFC, zx_tmp_fi2d) CALL histwrite_phy(o_LWdnSFC, sollwdown) sollwdownclr(1:klon) = -1.*lwdn0(1:klon,1) zx_tmp_fi2d(1:klon)=sollwdownclr(1:klon)-sollw0(1:klon) CALL histwrite_phy(o_LWupSFCclr, zx_tmp_fi2d) CALL histwrite_phy(o_LWdnSFCclr, sollwdownclr) CALL histwrite_phy(o_bils, bils) CALL histwrite_phy(o_bils_diss, bils_diss) CALL histwrite_phy(o_bils_ec, bils_ec) CALL histwrite_phy(o_bils_tke, bils_tke) CALL histwrite_phy(o_bils_kinetic, bils_kinetic) CALL histwrite_phy(o_bils_latent, bils_latent) CALL histwrite_phy(o_bils_enthalp, bils_enthalp) zx_tmp_fi2d(1:klon)=-1*sens(1:klon) CALL histwrite_phy(o_sens, zx_tmp_fi2d) CALL histwrite_phy(o_fder, fder) CALL histwrite_phy(o_ffonte, zxffonte) CALL histwrite_phy(o_fqcalving, zxfqcalving) CALL histwrite_phy(o_fqfonte, zxfqfonte) zx_tmp_fi2d=0. do nsrf=1,nbsrf zx_tmp_fi2d(:)=zx_tmp_fi2d(:)+pctsrf(:,nsrf)*fluxu(:,1,nsrf) enddo CALL histwrite_phy(o_taux, zx_tmp_fi2d) zx_tmp_fi2d=0. do nsrf=1,nbsrf zx_tmp_fi2d(:)=zx_tmp_fi2d(:)+pctsrf(:,nsrf)*fluxv(:,1,nsrf) enddo CALL histwrite_phy(o_tauy, zx_tmp_fi2d) DO nsrf = 1, nbsrf ! IF(nsrf.GE.2) THEN zx_tmp_fi2d(1 : klon) = pctsrf( 1 : klon, nsrf)*100. CALL histwrite_phy(o_pourc_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = pctsrf( 1 : klon, nsrf) CALL histwrite_phy(o_fract_srf(nsrf), zx_tmp_fi2d) ! ENDIF !nsrf.GT.2 zx_tmp_fi2d(1 : klon) = fluxu( 1 : klon, 1, nsrf) CALL histwrite_phy(o_taux_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = fluxv( 1 : klon, 1, nsrf) CALL histwrite_phy(o_tauy_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = ftsol( 1 : klon, nsrf) CALL histwrite_phy(o_tsol_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = evap_pot( 1 : klon, nsrf) CALL histwrite_phy(o_evappot_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = ustar(1 : klon, nsrf) CALL histwrite_phy(o_ustar_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = u10m(1 : klon, nsrf) CALL histwrite_phy(o_u10m_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = v10m(1 : klon, nsrf) CALL histwrite_phy(o_v10m_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = t2m(1 : klon, nsrf) CALL histwrite_phy(o_t2m_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = fevap(1 : klon, nsrf) CALL histwrite_phy(o_evap_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = fluxt( 1 : klon, 1, nsrf) CALL histwrite_phy(o_sens_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = fluxlat( 1 : klon, nsrf) CALL histwrite_phy(o_lat_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = fsollw( 1 : klon, nsrf) CALL histwrite_phy(o_flw_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = fsolsw( 1 : klon, nsrf) CALL histwrite_phy(o_fsw_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = wfbils( 1 : klon, nsrf) CALL histwrite_phy(o_wbils_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = wfbilo( 1 : klon, nsrf) CALL histwrite_phy(o_wbilo_srf(nsrf), zx_tmp_fi2d) IF (iflag_pbl>1) THEN CALL histwrite_phy(o_tke_srf(nsrf), pbl_tke(:,1:klev,nsrf)) CALL histwrite_phy(o_tke_max_srf(nsrf), pbl_tke(:,1:klev,nsrf)) ENDIF ENDDO CALL histwrite_phy(o_cdrm, cdragm) CALL histwrite_phy(o_cdrh, cdragh) CALL histwrite_phy(o_cldl, cldl) CALL histwrite_phy(o_cldm, cldm) CALL histwrite_phy(o_cldh, cldh) CALL histwrite_phy(o_cldt, cldt) CALL histwrite_phy(o_cldq, cldq) zx_tmp_fi2d(1:klon) = flwp(1:klon) CALL histwrite_phy(o_lwp, zx_tmp_fi2d) zx_tmp_fi2d(1:klon) = fiwp(1:klon) CALL histwrite_phy(o_iwp, zx_tmp_fi2d) CALL histwrite_phy(o_ue, ue) CALL histwrite_phy(o_ve, ve) CALL histwrite_phy(o_uq, uq) CALL histwrite_phy(o_vq, vq) IF(iflag_con.GE.3) THEN ! sb CALL histwrite_phy(o_cape, cape) CALL histwrite_phy(o_pbase, ema_pcb) CALL histwrite_phy(o_ptop, ema_pct) CALL histwrite_phy(o_fbase, ema_cbmf) IF (iflag_con /= 30) THEN CALL histwrite_phy(o_plcl, plcl) CALL histwrite_phy(o_plfc, plfc) CALL histwrite_phy(o_wbeff, wbeff) ENDIF CALL histwrite_phy(o_cape_max, cape) CALL histwrite_phy(o_upwd, upwd) CALL histwrite_phy(o_Ma, Ma) CALL histwrite_phy(o_dnwd, dnwd) CALL histwrite_phy(o_dnwd0, dnwd0) zx_tmp_fi2d=float(itau_con)/float(itap) CALL histwrite_phy(o_ftime_con, zx_tmp_fi2d) IF (iflag_thermals>=1) THEN zx_tmp_fi3d=dnwd+dnwd0+upwd+fm_therm(:,1:klev) ELSE zx_tmp_fi3d=dnwd+dnwd0+upwd ENDIF CALL histwrite_phy(o_mc, zx_tmp_fi3d) ENDIF !iflag_con .GE. 3 CALL histwrite_phy(o_prw, prw) CALL histwrite_phy(o_s_pblh, s_pblh) CALL histwrite_phy(o_s_pblt, s_pblt) CALL histwrite_phy(o_s_lcl, s_lcl) CALL histwrite_phy(o_s_therm, s_therm) ! ANCIENNE METHODE DO iff=1,nfiles ll=0 DO k=1, nlevSTD bb2=clevSTD(k) IF(bb2.EQ."850".OR.bb2.EQ."700".OR. $ bb2.EQ."500".OR.bb2.EQ."200".OR. $ bb2.EQ."100".OR. $ bb2.EQ."50".OR.bb2.EQ."10") THEN ! a refaire correctement !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! ll=ll+1 CALL histwrite_phy(o_uSTDlevs(ll),uwriteSTD(:,k,iff), iff) CALL histwrite_phy(o_vSTDlevs(ll),vwriteSTD(:,k,iff), iff) CALL histwrite_phy(o_wSTDlevs(ll),wwriteSTD(:,k,iff), iff) CALL histwrite_phy(o_zSTDlevs(ll),phiwriteSTD(:,k,iff), iff) CALL histwrite_phy(o_qSTDlevs(ll),qwriteSTD(:,k,iff), iff) CALL histwrite_phy(o_tSTDlevs(ll),twriteSTD(:,k,iff), iff) ! IF (o_uSTDlevs(ll)%flag(iff)<=lev_files(iff)) THEN ! CALL histwrite_phy(nid_files(iff),clef_stations(iff), ! $o_uSTDlevs(ll)%name, ! & itau_w,uwriteSTD(:,k,iff)) ! ENDIF ! IF (o_vSTDlevs(ll)%flag(iff)<=lev_files(iff)) THEN ! CALL histwrite_phy(nid_files(iff),clef_stations(iff), ! $o_vSTDlevs(ll)%name, ! & itau_w,vwriteSTD(:,k,iff)) ! ENDIF ! IF (o_wSTDlevs(ll)%flag(iff)<=lev_files(iff)) THEN ! CALL histwrite_phy(nid_files(iff),clef_stations(iff), ! $o_wSTDlevs(ll)%name, ! & itau_w,wwriteSTD(:,k,iff)) ! ENDIF ! IF (o_zSTDlevs(ll)%flag(iff)<=lev_files(iff)) THEN ! CALL histwrite_phy(nid_files(iff),clef_stations(iff), ! $o_zSTDlevs(ll)%name, ! & itau_w,phiwriteSTD(:,k,iff)) ! ENDIF ! IF (o_qSTDlevs(ll)%flag(iff)<=lev_files(iff)) THEN ! CALL histwrite_phy(nid_files(iff),clef_stations(iff), ! $o_qSTDlevs(ll)%name, ! & itau_w, qwriteSTD(:,k,iff)) ! ENDIF ! IF (o_tSTDlevs(ll)%flag(iff)<=lev_files(iff)) THEN ! CALL histwrite_phy(nid_files(iff),clef_stations(iff), ! $o_tSTDlevs(ll)%name, ! & itau_w, twriteSTD(:,k,iff)) ! ENDIF ENDIF !(bb2.EQ."850".OR.bb2.EQ."700".OR. ENDDO ENDDO ! /ANCIENNE METHODE DO i=1, klon IF (pctsrf(i,is_oce).GT.epsfra.OR. $ pctsrf(i,is_sic).GT.epsfra) THEN zx_tmp_fi2d(i) = (ftsol(i, is_oce) * pctsrf(i,is_oce)+ $ ftsol(i, is_sic) * pctsrf(i,is_sic))/ $ (pctsrf(i,is_oce)+pctsrf(i,is_sic)) ELSE zx_tmp_fi2d(i) = 273.15 ENDIF ENDDO CALL histwrite_phy(o_t_oce_sic, zx_tmp_fi2d) ! Couplage convection-couche limite IF (iflag_con.GE.3) THEN IF (iflag_coupl>=1) THEN CALL histwrite_phy(o_ale_bl, ale_bl) CALL histwrite_phy(o_alp_bl, alp_bl) ENDIF !iflag_coupl>=1 ENDIF !(iflag_con.GE.3) ! Wakes IF (iflag_con.EQ.3) THEN IF (iflag_wake>=1) THEN CALL histwrite_phy(o_ale_wk, ale_wake) CALL histwrite_phy(o_alp_wk, alp_wake) CALL histwrite_phy(o_ale, ale) CALL histwrite_phy(o_alp, alp) CALL histwrite_phy(o_cin, cin) CALL histwrite_phy(o_WAPE, wake_pe) CALL histwrite_phy(o_wake_h, wake_h) CALL histwrite_phy(o_wake_s, wake_s) CALL histwrite_phy(o_wake_deltat, wake_deltat) CALL histwrite_phy(o_wake_deltaq, wake_deltaq) CALL histwrite_phy(o_wake_omg, wake_omg) zx_tmp_fi3d(1:klon,1:klev)=d_t_wake(1:klon,1:klev) & /pdtphys CALL histwrite_phy(o_dtwak, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_wake(1:klon,1:klev) & /pdtphys CALL histwrite_phy(o_dqwak, zx_tmp_fi3d) ENDIF ! iflag_wake>=1 CALL histwrite_phy(o_Vprecip, Vprecip) CALL histwrite_phy(o_ftd, ftd) CALL histwrite_phy(o_fqd, fqd) ELSEIF (iflag_con.EQ.30) THEN ! sortie RomP convection descente insaturee iflag_con=30 CALL histwrite_phy(o_Vprecip, Vprecip) CALL histwrite_phy(o_wdtrainA, wdtrainA) CALL histwrite_phy(o_wdtrainM, wdtrainM) ENDIF !(iflag_con.EQ.3.or.iflag_con.EQ.30) !!! nrlmd le 10/04/2012 IF (iflag_trig_bl>=1) THEN CALL histwrite_phy(o_n2, n2) CALL histwrite_phy(o_s2, s2) CALL histwrite_phy(o_proba_notrig, proba_notrig) CALL histwrite_phy(o_random_notrig, random_notrig) CALL histwrite_phy(o_ale_bl_stat, ale_bl_stat) CALL histwrite_phy(o_ale_bl_trig, ale_bl_trig) ENDIF !(iflag_trig_bl>=1) IF (iflag_clos_bl>=1) THEN CALL histwrite_phy(o_alp_bl_det, alp_bl_det) CALL histwrite_phy(o_alp_bl_fluct_m, alp_bl_fluct_m) CALL histwrite_phy(o_alp_bl_fluct_tke, alp_bl_fluct_tke) CALL histwrite_phy(o_alp_bl_conv, alp_bl_conv) CALL histwrite_phy(o_alp_bl_stat, alp_bl_stat) ENDIF !(iflag_clos_bl>=1) !!! fin nrlmd le 10/04/2012 IF (type_ocean=='slab ') THEN CALL histwrite_phy(o_slab_bils, slab_wfbils) ENDIF !type_ocean == force/slab CALL histwrite_phy(o_weakinv, weak_inversion) CALL histwrite_phy(o_dthmin, dthmin) CALL histwrite_phy(o_cldtau, cldtau) CALL histwrite_phy(o_cldemi, cldemi) CALL histwrite_phy(o_pr_con_l, pmflxr(:,1:klev)) CALL histwrite_phy(o_pr_con_i, pmflxs(:,1:klev)) CALL histwrite_phy(o_pr_lsc_l, prfl(:,1:klev)) CALL histwrite_phy(o_pr_lsc_i, psfl(:,1:klev)) CALL histwrite_phy(o_re, re) CALL histwrite_phy(o_fl, fl) DO i=1, klon zx_tmp_fi2d(i)=MIN(100.,rh2m(i)*100.) ENDDO CALL histwrite_phy(o_rh2m, zx_tmp_fi2d) DO i=1, klon zx_tmp_fi2d(i)=MIN(100.,rh2m(i)*100.) ENDDO CALL histwrite_phy(o_rh2m_min, zx_tmp_fi2d) DO i=1, klon zx_tmp_fi2d(i)=MIN(100.,rh2m(i)*100.) ENDDO CALL histwrite_phy(o_rh2m_max, zx_tmp_fi2d) CALL histwrite_phy(o_qsat2m, qsat2m) CALL histwrite_phy(o_tpot, tpot) CALL histwrite_phy(o_tpote, tpote) zx_tmp_fi2d(1 : klon) = fsolsw( 1 : klon, is_ter) CALL histwrite_phy(o_SWnetOR, zx_tmp_fi2d) zx_tmp_fi2d(1:klon) = solsw(1:klon)/(1.-albsol1(1:klon)) CALL histwrite_phy(o_SWdownOR, zx_tmp_fi2d) CALL histwrite_phy(o_LWdownOR, sollwdown) CALL histwrite_phy(o_snowl, snow_lsc) CALL histwrite_phy(o_solldown, sollwdown) CALL histwrite_phy(o_dtsvdfo, d_ts(:,is_oce)) CALL histwrite_phy(o_dtsvdft, d_ts(:,is_ter)) CALL histwrite_phy(o_dtsvdfg, d_ts(:,is_lic)) CALL histwrite_phy(o_dtsvdfi, d_ts(:,is_sic)) CALL histwrite_phy(o_rugs, zxrugs) ! OD550 per species IF (new_aod .and. (.not. aerosol_couple)) THEN IF (ok_ade.OR.ok_aie) THEN CALL histwrite_phy(o_od550aer, od550aer) CALL histwrite_phy(o_od865aer, od865aer) CALL histwrite_phy(o_absvisaer, absvisaer) CALL histwrite_phy(o_od550lt1aer, od550lt1aer) CALL histwrite_phy(o_sconcso4, sconcso4) CALL histwrite_phy(o_sconcoa, sconcoa) CALL histwrite_phy(o_sconcbc, sconcbc) CALL histwrite_phy(o_sconcss, sconcss) CALL histwrite_phy(o_sconcdust, sconcdust) CALL histwrite_phy(o_concso4, concso4) CALL histwrite_phy(o_concoa, concoa) CALL histwrite_phy(o_concbc, concbc) CALL histwrite_phy(o_concss, concss) CALL histwrite_phy(o_concdust, concdust) CALL histwrite_phy(o_loadso4, loadso4) CALL histwrite_phy(o_loadoa, loadoa) CALL histwrite_phy(o_loadbc, loadbc) CALL histwrite_phy(o_loadss, loadss) CALL histwrite_phy(o_loaddust, loaddust) DO naero = 1, naero_spc CALL histwrite_phy(o_tausumaero(naero), & tausum_aero(:,2,naero) ) END DO endif ENDIF IF (ok_ade) THEN CALL histwrite_phy(o_topswad, topswad_aero) CALL histwrite_phy(o_topswad0, topswad0_aero) CALL histwrite_phy(o_solswad, solswad_aero) CALL histwrite_phy(o_solswad0, solswad0_aero) !====MS forcing diagnostics if (new_aod) then CALL histwrite_phy(o_swtoaas_nat, topsw_aero(:,1)) CALL histwrite_phy(o_swsrfas_nat, solsw_aero(:,1)) CALL histwrite_phy(o_swtoacs_nat, topsw0_aero(:,1)) CALL histwrite_phy(o_swsrfcs_nat, solsw0_aero(:,1)) !ant CALL histwrite_phy(o_swtoaas_ant, topsw_aero(:,2)) CALL histwrite_phy(o_swsrfas_ant, solsw_aero(:,2)) CALL histwrite_phy(o_swtoacs_ant, topsw0_aero(:,2)) CALL histwrite_phy(o_swsrfcs_ant, solsw0_aero(:,2)) !cf if (.not. aerosol_couple) then CALL histwrite_phy(o_swtoacf_nat, topswcf_aero(:,1)) CALL histwrite_phy(o_swsrfcf_nat, solswcf_aero(:,1)) CALL histwrite_phy(o_swtoacf_ant, topswcf_aero(:,2)) CALL histwrite_phy(o_swsrfcf_ant, solswcf_aero(:,2)) CALL histwrite_phy(o_swtoacf_zero,topswcf_aero(:,3)) CALL histwrite_phy(o_swsrfcf_zero,solswcf_aero(:,3)) endif endif ! new_aod !====MS forcing diagnostics ENDIF IF (ok_aie) THEN CALL histwrite_phy(o_topswai, topswai_aero) CALL histwrite_phy(o_solswai, solswai_aero) CALL histwrite_phy(o_scdnc, scdnc) CALL histwrite_phy(o_cldncl, cldncl) CALL histwrite_phy(o_reffclws, reffclws) CALL histwrite_phy(o_reffclwc, reffclwc) CALL histwrite_phy(o_cldnvi, cldnvi) CALL histwrite_phy(o_lcc, lcc) CALL histwrite_phy(o_lcc3d, lcc3d) CALL histwrite_phy(o_lcc3dcon, lcc3dcon) CALL histwrite_phy(o_lcc3dstra, lcc3dstra) CALL histwrite_phy(o_reffclwtop, reffclwtop) ENDIF ! Champs 3D: IF (ok_ade .OR. ok_aie) then CALL histwrite_phy(o_ec550aer, ec550aer) ENDIF CALL histwrite_phy(o_lwcon, flwc) CALL histwrite_phy(o_iwcon, fiwc) CALL histwrite_phy(o_temp, t_seri) CALL histwrite_phy(o_theta, theta) CALL histwrite_phy(o_ovapinit, qx(:,:,ivap)) CALL histwrite_phy(o_ovap, q_seri) CALL histwrite_phy(o_oliq, ql_seri) CALL histwrite_phy(o_geop, zphi) CALL histwrite_phy(o_vitu, u_seri) CALL histwrite_phy(o_vitv, v_seri) CALL histwrite_phy(o_vitw, omega) CALL histwrite_phy(o_pres, pplay) CALL histwrite_phy(o_paprs, paprs(:,1:klev)) DO i=1, klon zx_tmp_fi3d1(i,1)= pphis(i)/RG !020611 zx_tmp_fi3d(i,1)= pphis(i)/RG ENDDO DO k=1, klev !020611 DO k=1, klev-1 DO i=1, klon !020611 zx_tmp_fi3d(i,k+1)= zx_tmp_fi3d(i,k) - (t_seri(i,k) *RD * zx_tmp_fi3d1(i,k+1)= zx_tmp_fi3d1(i,k) - (t_seri(i,k) *RD * $ (paprs(i,k+1) - paprs(i,k))) / ( pplay(i,k) * RG ) ENDDO ENDDO CALL histwrite_phy(o_zfull,zx_tmp_fi3d1(:,2:klevp1)) !020611 $o_zfull%name,itau_w,zx_tmp_fi3d) DO i=1, klon zx_tmp_fi3d(i,1)= pphis(i)/RG - ( $ (t_seri(i,1)+zxtsol(i))/2. *RD * $ (pplay(i,1) - paprs(i,1)))/((paprs(i,1)+pplay(i,1))/2. * RG) ENDDO DO k=1, klev-1 DO i=1, klon zx_tmp_fi3d(i,k+1)= zx_tmp_fi3d(i,k) - ( $ (t_seri(i,k)+t_seri(i,k+1))/2. *RD * $ (pplay(i,k+1) - pplay(i,k))) / ( paprs(i,k) * RG ) ENDDO ENDDO CALL histwrite_phy(o_zhalf, zx_tmp_fi3d) CALL histwrite_phy(o_rneb, cldfra) CALL histwrite_phy(o_rnebcon, rnebcon) CALL histwrite_phy(o_rnebls, rneb) CALL histwrite_phy(o_rhum, zx_rh) CALL histwrite_phy(o_ozone, wo(:, :, 1) & * dobson_u * 1e3 / zmasse / rmo3 * rmd) IF (read_climoz == 2) THEN CALL histwrite_phy(o_ozone_light, wo(:, :, 2) & * dobson_u * 1e3 / zmasse / rmo3 * rmd) ENDIF CALL histwrite_phy(o_dtphy, d_t) CALL histwrite_phy(o_dqphy, d_qx(:,:,ivap)) DO nsrf=1, nbsrf zx_tmp_fi2d(1 : klon) = falb1( 1 : klon, nsrf) CALL histwrite_phy(o_albe_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = frugs( 1 : klon, nsrf) CALL histwrite_phy(o_rugs_srf(nsrf), zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = agesno( 1 : klon, nsrf) CALL histwrite_phy(o_ages_srf(nsrf), zx_tmp_fi2d) ENDDO !nsrf=1, nbsrf CALL histwrite_phy(o_alb1, albsol1) CALL histwrite_phy(o_alb2, albsol2) !FH Sorties pour la couche limite if (iflag_pbl>1) then zx_tmp_fi3d=0. do nsrf=1,nbsrf do k=1,klev zx_tmp_fi3d(:,k)=zx_tmp_fi3d(:,k) $ +pctsrf(:,nsrf)*pbl_tke(:,k,nsrf) enddo enddo CALL histwrite_phy(o_tke, zx_tmp_fi3d) CALL histwrite_phy(o_tke_max, zx_tmp_fi3d) endif CALL histwrite_phy(o_kz, coefh(:,:,is_ave)) CALL histwrite_phy(o_kz_max, coefh(:,:,is_ave)) CALL histwrite_phy(o_clwcon, clwcon0) CALL histwrite_phy(o_dtdyn, d_t_dyn) CALL histwrite_phy(o_dqdyn, d_q_dyn) CALL histwrite_phy(o_dudyn, d_u_dyn) CALL histwrite_phy(o_dvdyn, d_v_dyn) zx_tmp_fi3d(1:klon,1:klev)=d_t_con(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtcon, zx_tmp_fi3d) if(iflag_thermals.eq.1)then zx_tmp_fi3d(1:klon,1:klev)=d_t_con(1:klon,1:klev)/pdtphys + $ d_t_ajsb(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_tntc, zx_tmp_fi3d) else if(iflag_thermals.gt.1.and.iflag_wake.EQ.1)then zx_tmp_fi3d(1:klon,1:klev)=d_t_con(1:klon,1:klev)/pdtphys + $ d_t_ajs(1:klon,1:klev)/pdtphys + $ d_t_wake(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_tntc, zx_tmp_fi3d) endif zx_tmp_fi3d(1:klon,1:klev)=d_u_con(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_ducon, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_v_con(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dvcon, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_con(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dqcon, zx_tmp_fi3d) if(iflag_thermals.eq.1)then zx_tmp_fi3d(1:klon,1:klev)=d_q_con(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_tnhusc, zx_tmp_fi3d) else if(iflag_thermals.gt.1.and.iflag_wake.EQ.1)then zx_tmp_fi3d(1:klon,1:klev)=d_q_con(1:klon,1:klev)/pdtphys + $ d_q_ajs(1:klon,1:klev)/pdtphys + $ d_q_wake(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_tnhusc, zx_tmp_fi3d) endif zx_tmp_fi3d(1:klon,1:klev)=d_t_lsc(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtlsc, zx_tmp_fi3d) zx_tmp_fi3d(1:klon, 1:klev)=(d_t_lsc(1:klon,1:klev)+ $ d_t_eva(1:klon,1:klev))/pdtphys CALL histwrite_phy(o_dtlschr, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_lsc(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dqlsc, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=beta_prec(1:klon,1:klev) CALL histwrite_phy(o_beta_prec, zx_tmp_fi3d) !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! ! Sorties specifiques a la separation thermiques/non thermiques if (iflag_thermals>=1) then zx_tmp_fi3d(1:klon,1:klev)=d_t_lscth(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtlscth, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_t_lscst(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtlscst, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_lscth(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dqlscth, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_lscst(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dqlscst, zx_tmp_fi3d) CALL histwrite_phy(o_plulth, plul_th) CALL histwrite_phy(o_plulst, plul_st) do k=1,klev do i=1,klon if (ptconvth(i,k)) then zx_tmp_fi3d(i,k)=1. else zx_tmp_fi3d(i,k)=0. endif enddo enddo CALL histwrite_phy(o_ptconvth, zx_tmp_fi3d) do i=1,klon zx_tmp_fi2d(1:klon)=lmax_th(:) enddo CALL histwrite_phy(o_lmaxth, zx_tmp_fi2d) endif ! iflag_thermals>=1 !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! zx_tmp_fi3d(1:klon,1:klev)=d_t_vdf(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtvdf, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_t_diss(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtdis, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_vdf(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dqvdf, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_t_eva(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dteva, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_eva(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dqeva, zx_tmp_fi3d) zpt_conv = 0. where (ptconv) zpt_conv = 1. CALL histwrite_phy(o_ptconv, zpt_conv) CALL histwrite_phy(o_ratqs, ratqs) zx_tmp_fi3d(1:klon,1:klev)=d_t_ajs(1:klon,1:klev)/pdtphys - $ d_t_ajsb(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtthe, zx_tmp_fi3d) IF (iflag_thermals>=1) THEN ! Pour l instant 0 a y reflichir pour les thermiques zx_tmp_fi2d=0. CALL histwrite_phy(o_ftime_th, zx_tmp_fi2d) CALL histwrite_phy(o_f_th, fm_therm) CALL histwrite_phy(o_e_th, entr_therm) CALL histwrite_phy(o_w_th, zw2) CALL histwrite_phy(o_q_th, zqasc) CALL histwrite_phy(o_a_th, fraca) CALL histwrite_phy(o_d_th, detr_therm) CALL histwrite_phy(o_f0_th, f0) CALL histwrite_phy(o_zmax_th, zmax_th) zx_tmp_fi3d(1:klon,1:klev)=d_q_ajs(1:klon,1:klev)/pdtphys - $ d_q_ajsb(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dqthe, zx_tmp_fi3d) ENDIF !iflag_thermals zx_tmp_fi3d(1:klon,1:klev)=d_t_ajsb(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtajs, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_ajsb(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dqajs, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=heat(1:klon,1:klev)/RDAY CALL histwrite_phy(o_dtswr, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=heat0(1:klon,1:klev)/RDAY CALL histwrite_phy(o_dtsw0, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=-1.*cool(1:klon,1:klev)/RDAY CALL histwrite_phy(o_dtlwr, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=-1.*cool0(1:klon,1:klev)/RDAY CALL histwrite_phy(o_dtlw0, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_t_ec(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtec, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_u_vdf(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_duvdf, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_v_vdf(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dvvdf, zx_tmp_fi3d) IF (ok_orodr) THEN zx_tmp_fi3d(1:klon,1:klev)=d_u_oro(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_duoro, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_v_oro(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dvoro, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_t_oro(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtoro, zx_tmp_fi3d) ENDIF IF (ok_orolf) THEN zx_tmp_fi3d(1:klon,1:klev)=d_u_lif(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dulif, zx_tmp_fi3d) ENDIF zx_tmp_fi3d(1:klon,1:klev)=d_v_lif(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dvlif, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_t_lif(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dtlif, zx_tmp_fi3d) IF (ok_hines) THEN zx_tmp_fi3d(1:klon,1:klev)=d_u_hin(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_duhin, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_v_hin(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dvhin, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_t_hin(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_dthin, zx_tmp_fi3d) ENDIF CALL histwrite_phy(o_rsu, swup) CALL histwrite_phy(o_rsd, swdn) CALL histwrite_phy(o_rlu, lwup) CALL histwrite_phy(o_rld, lwdn) CALL histwrite_phy(o_rsucs, swup0) CALL histwrite_phy(o_rsdcs, swdn0) CALL histwrite_phy(o_rlucs, lwup0) CALL histwrite_phy(o_rldcs, lwdn0) zx_tmp_fi3d(1:klon,1:klev)=d_t(1:klon,1:klev)+ $d_t_dyn(1:klon,1:klev) CALL histwrite_phy(o_tnt, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=heat(1:klon,1:klev)/RDAY - $cool(1:klon,1:klev)/RDAY CALL histwrite_phy(o_tntr, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)= (d_t_lsc(1:klon,1:klev)+ $ d_t_eva(1:klon,1:klev)+ $ d_t_vdf(1:klon,1:klev))/pdtphys CALL histwrite_phy(o_tntscpbl, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_qx(1:klon,1:klev,ivap)+ $d_q_dyn(1:klon,1:klev) CALL histwrite_phy(o_tnhus, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=d_q_lsc(1:klon,1:klev)/pdtphys+ $ d_q_eva(1:klon,1:klev)/pdtphys CALL histwrite_phy(o_tnhusscpbl, zx_tmp_fi3d) CALL histwrite_phy(o_evu, coefm(:,:,is_ave)) zx_tmp_fi3d(1:klon,1:klev)=q_seri(1:klon,1:klev)+ $ ql_seri(1:klon,1:klev) CALL histwrite_phy(o_h2o, zx_tmp_fi3d) if (iflag_con >= 3) then zx_tmp_fi3d(1:klon,1:klev)=-1 * (dnwd(1:klon,1:klev)+ $ dnwd0(1:klon,1:klev)) CALL histwrite_phy(o_mcd, zx_tmp_fi3d) zx_tmp_fi3d(1:klon,1:klev)=upwd(1:klon,1:klev) + $ dnwd(1:klon,1:klev)+ dnwd0(1:klon,1:klev) CALL histwrite_phy(o_dmc, zx_tmp_fi3d) else if (iflag_con == 2) then CALL histwrite_phy(o_mcd, pmfd) CALL histwrite_phy(o_dmc, pmfu + pmfd) end if CALL histwrite_phy(o_ref_liq, ref_liq) CALL histwrite_phy(o_ref_ice, ref_ice) if (RCO2_per.NE.RCO2_act.OR.RCH4_per.NE.RCH4_act.OR. $ RN2O_per.NE.RN2O_act.OR.RCFC11_per.NE.RCFC11_act.OR. $ RCFC12_per.NE.RCFC12_act) THEN zx_tmp_fi2d(1 : klon) = swupp ( 1 : klon, klevp1 ) CALL histwrite_phy(o_rsut4co2, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = lwupp ( 1 : klon, klevp1 ) CALL histwrite_phy(o_rlut4co2, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = swup0p ( 1 : klon, klevp1 ) CALL histwrite_phy(o_rsutcs4co2, zx_tmp_fi2d) zx_tmp_fi2d(1 : klon) = lwup0p ( 1 : klon, klevp1 ) CALL histwrite_phy(o_rlutcs4co2, zx_tmp_fi2d) CALL histwrite_phy(o_rsu4co2, swupp) CALL histwrite_phy(o_rlu4co2, lwupp) CALL histwrite_phy(o_rsucs4co2, swup0p) CALL histwrite_phy(o_rlucs4co2, lwup0p) CALL histwrite_phy(o_rsd4co2, swdnp) CALL histwrite_phy(o_rld4co2, lwdnp) CALL histwrite_phy(o_rsdcs4co2, swdn0p) CALL histwrite_phy(o_rldcs4co2, lwdn0p) endif if (nqtot.GE.3) THEN DO iq=3,nqtot CALL histwrite_phy(o_trac(iq-2), qx(:,:,iq)) ENDDO DO iq=3,nqtot zx_tmp_fi2d=0. do k=1,klev zx_tmp_fi2d(:)=zx_tmp_fi2d(:)+zmasse(:,k)*qx(:,k,iq) enddo CALL histwrite_phy(o_trac_cum(iq-2), zx_tmp_fi2d) ENDDO endif ! ENDIF ! clef_files DO iff=1,nfiles IF (ok_sync .AND. clef_files(iff)) THEN c$OMP MASTER CALL histsync(nid_files(iff)) c$OMP END MASTER ENDIF END DO