! ! $Header$ ! c$OMP MASTER c IF (ok_histNMC(3)) THEN c zstophy = dtime zstohf = ecrit_hf zstomth = ecrit_mth c zout = 6 * 3600. zout = freq_outNMC(3) c idayref = day_ref CALL ymds2ju(annee_ref, 1, idayref, 0.0, zjulian) c cym CALL gr_fi_ecrit(1,klon,iim,jjmp1,rlon,zx_lon) cym DO i = 1, iim cym zx_lon(i,1) = rlon(i+1) cym zx_lon(i,jjmp1) = rlon(i+1) cym ENDDO DO ll=1,klev znivsig(ll)=float(ll) ENDDO cym CALL gr_fi_ecrit(1,klon,iim,jjmp1,rlat,zx_lat) cym CALL histbeg("histNMC.nc", iim,zx_lon(:,1), jjmp1,zx_lat(1,:), cym . 1,iim,1,jjmp1, itau_phy, zjulian, dtime, cym . nhori, nid_hfnmc) CALL histbeg_phy("histhfNMC",itau_phy, zjulian, dtime, . nhori, nid_hfnmc) c CALL histvert(nid_hfnmc, "plev", "pressure", "Pa", . nlevSTD3, rlevSTD3, nvert) ccc ccc Champs 3D interpolles sur des niveaux de pression du NMC ccc c c ATTENTION : pour AMIP2 on interpole t,u,v,wphi,q,rh c sur les niveaux du NMC et on somme & moyenne c toutes les freq_moyNMC secondes par des routines undefSTD et c moy_undefSTD pour eliminer les valeurs "undef" c de la moyenne mensuelle c ======> le "inst(X)" ci-dessous est par consequence factice ! c CALL histdef(nid_hfnmc, "tnondef", . "Valeurs non-definies","-", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "ta", . "Air temperature","K", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "zg", . "Geopotential height", "m", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "hus", . "Specific humidity","1", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "hur", . "Relative humidity", "%", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "ua", . "Eastward wind","m s-1", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "va", . "Northward wind","m s-1", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "wap", . "Lagrangian tendency of air pressure","Pa s-1", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "psbg", . "Pressure sfce below ground","%", . iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "uv", . "uv ", . "m2/s2",iim,jj_nb,nhori, nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "vq", . "vq ", . "m/s * (kg/kg)",iim,jj_nb,nhori, . nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "vT", . "vT ", . "mK/s",iim,jj_nb,nhori, . nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "wq", . "wq ", . "(Pa/s)*(kg/kg)",iim,jj_nb,nhori, . nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "vphi", . "vphi ", . "m2/s",iim,jj_nb,nhori, . nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "wT", . "wT ", . "K*Pa/s",iim,jj_nb,nhori, . nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "uxu", . "u2 ", . "m2/s2",iim,jj_nb,nhori, . nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "vxv", . "v2 ", . "m2/s2",iim,jj_nb,nhori, . nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histdef(nid_hfnmc, "TxT", . "T2 ", . "K2",iim,jj_nb,nhori, . nlevSTD3,1,nlevSTD3, nvert, 32, . "inst(X)", zout,zout) c CALL histend(nid_hfnmc) c ENDIF !(ok_histNMC(2)) THEN c c$OMP END MASTER