1 |
SUBROUTINE phyredem(fichnom, rlat,rlon,pctsrf,tsol,tsoil, & |
module phyredem_m |
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tslab,seaice,qsurf,qsol,snow,albedo,alblw,evap,rain_fall,snow_fall, & |
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solsw,sollw,fder,radsol,frugs,agesno,zmea,zstd,zsig,zgam,zthe,zpic, & |
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zval, t_ancien,q_ancien,rnebcon,ratqs,clwcon,run_off_lic_0) |
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! From phylmd/phyredem.F,v 1.3 2005/05/25 13:10:09 |
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! Auteur(s) Z.X. Li (LMD/CNRS) date: 19930818 |
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! Objet: Ecriture de l'etat de démarrage ou redémarrage pour la physique |
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USE indicesol, ONLY : is_lic, is_oce, is_sic, is_ter, nbsrf |
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USE dimphy, ONLY : klev, klon, zmasq |
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USE dimsoil, ONLY : nsoilmx |
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USE temps, ONLY : itau_phy |
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USE netcdf95, ONLY : nf95_create, nf95_put_att |
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USE netcdf, ONLY : nf90_clobber, nf90_global |
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2 |
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3 |
IMPLICIT NONE |
IMPLICIT NONE |
4 |
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5 |
INCLUDE 'netcdf.inc' |
contains |
6 |
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7 |
CHARACTER(len=*) fichnom |
SUBROUTINE phyredem(fichnom, rlat, rlon, pctsrf, tsol, tsoil, tslab, & |
8 |
REAL, INTENT (IN) :: rlat(klon), rlon(klon) |
seaice, qsurf, qsol, snow, albedo, alblw, evap, rain_fall,& |
9 |
REAL :: tsol(klon,nbsrf) |
snow_fall, solsw, sollw, fder, radsol, frugs, agesno, zmea,& |
10 |
REAL :: tsoil(klon,nsoilmx,nbsrf) |
zstd, zsig, zgam, zthe, zpic, zval, t_ancien, q_ancien,& |
11 |
!IM "slab" ocean |
rnebcon, ratqs, clwcon, run_off_lic_0) |
12 |
REAL :: tslab(klon), seaice(klon) !IM "slab" ocean |
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13 |
REAL :: qsurf(klon,nbsrf) |
! From phylmd/phyredem.F, v 1.3 2005/05/25 13:10:09 |
14 |
REAL :: qsol(klon) |
! Auteur(s) Z.X. Li (LMD/CNRS) date: 19930818 |
15 |
REAL :: snow(klon,nbsrf) |
! Objet: Ecriture de l'etat de démarrage ou redémarrage pour la physique |
16 |
REAL :: albedo(klon,nbsrf) |
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17 |
!IM BEG |
USE indicesol, ONLY : is_lic, is_oce, is_sic, is_ter, nbsrf |
18 |
REAL :: alblw(klon,nbsrf) |
USE dimphy, ONLY : klev, klon, zmasq |
19 |
!IM END |
USE dimsoil, ONLY : nsoilmx |
20 |
REAL :: evap(klon,nbsrf) |
USE temps, ONLY : itau_phy |
21 |
REAL :: rain_fall(klon) |
USE netcdf95, ONLY : nf95_create, nf95_put_att |
22 |
REAL :: snow_fall(klon) |
USE netcdf, ONLY : nf90_clobber, nf90_global |
23 |
REAL :: solsw(klon) |
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24 |
REAL :: sollw(klon) |
INCLUDE 'netcdf.inc' |
25 |
REAL :: fder(klon) |
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26 |
REAL :: radsol(klon) |
CHARACTER(len=*) fichnom |
27 |
REAL :: frugs(klon,nbsrf) |
REAL, INTENT (IN) :: rlat(klon), rlon(klon) |
28 |
REAL :: agesno(klon,nbsrf) |
REAL :: tsol(klon, nbsrf) |
29 |
REAL :: zmea(klon) |
REAL :: tsoil(klon, nsoilmx, nbsrf) |
30 |
REAL, intent(in):: zstd(klon) |
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31 |
REAL, intent(in):: zsig(klon) |
REAL :: tslab(klon), seaice(klon) !IM "slab" ocean |
32 |
REAL :: zgam(klon) |
REAL :: qsurf(klon, nbsrf) |
33 |
REAL :: zthe(klon) |
REAL :: qsol(klon) |
34 |
REAL :: zpic(klon) |
REAL :: snow(klon, nbsrf) |
35 |
REAL :: zval(klon) |
REAL :: albedo(klon, nbsrf) |
36 |
REAL :: pctsrf(klon,nbsrf) |
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37 |
REAL :: t_ancien(klon,klev), q_ancien(klon,klev) |
REAL :: alblw(klon, nbsrf) |
38 |
REAL :: clwcon(klon,klev), rnebcon(klon,klev), ratqs(klon,klev) |
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39 |
REAL :: run_off_lic_0(klon) |
REAL :: evap(klon, nbsrf) |
40 |
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REAL :: rain_fall(klon) |
41 |
INTEGER :: nid, nvarid, idim2, idim3 |
REAL :: snow_fall(klon) |
42 |
INTEGER :: ierr |
REAL :: solsw(klon) |
43 |
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REAL :: sollw(klon) |
44 |
INTEGER :: isoil, nsrf |
REAL :: fder(klon) |
45 |
CHARACTER (7) :: str7 |
REAL :: radsol(klon) |
46 |
CHARACTER (2) :: str2 |
REAL :: frugs(klon, nbsrf) |
47 |
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REAL :: agesno(klon, nbsrf) |
48 |
!------------------------------------------------------------ |
REAL :: zmea(klon) |
49 |
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REAL, intent(in):: zstd(klon) |
50 |
PRINT *, 'Call sequence information: phyredem' |
REAL, intent(in):: zsig(klon) |
51 |
CALL nf95_create(fichnom,nf90_clobber,nid) |
REAL :: zgam(klon) |
52 |
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REAL :: zthe(klon) |
53 |
call nf95_put_att(nid, nf90_global, 'title', 'Fichier redémarrage physique') |
REAL :: zpic(klon) |
54 |
call nf95_put_att(nid, nf90_global, "itau_phy", itau_phy) |
REAL :: zval(klon) |
55 |
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REAL :: pctsrf(klon, nbsrf) |
56 |
ierr = nf_def_dim(nid,'points_physiques',klon,idim2) |
REAL :: t_ancien(klon, klev), q_ancien(klon, klev) |
57 |
ierr = nf_def_dim(nid,'horizon_vertical',klon*klev,idim3) |
REAL :: clwcon(klon, klev), rnebcon(klon, klev), ratqs(klon, klev) |
58 |
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REAL :: run_off_lic_0(klon) |
59 |
ierr = nf_def_var(nid,'longitude',nf_float,1,idim2,nvarid) |
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60 |
ierr = nf_put_att_text(nid,nvarid,'title',32, & |
INTEGER :: nid, nvarid, idim2, idim3 |
61 |
'Longitudes de la grille physique') |
INTEGER :: ierr |
62 |
ierr = nf_enddef(nid) |
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63 |
ierr = nf_put_var_real(nid,nvarid,rlon) |
INTEGER :: isoil, nsrf |
64 |
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CHARACTER (7) :: str7 |
65 |
ierr = nf_redef(nid) |
CHARACTER (2) :: str2 |
66 |
ierr = nf_def_var(nid,'latitude',nf_float,1,idim2,nvarid) |
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67 |
ierr = nf_put_att_text(nid,nvarid,'title',31, & |
!------------------------------------------------------------ |
68 |
'Latitudes de la grille physique') |
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69 |
ierr = nf_enddef(nid) |
PRINT *, 'Call sequence information: phyredem' |
70 |
ierr = nf_put_var_real(nid,nvarid,rlat) |
CALL nf95_create(fichnom, nf90_clobber, nid) |
71 |
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72 |
! PB ajout du masque terre/mer |
call nf95_put_att(nid, nf90_global, 'title', & |
73 |
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'Fichier redémarrage physique') |
74 |
ierr = nf_redef(nid) |
call nf95_put_att(nid, nf90_global, "itau_phy", itau_phy) |
75 |
ierr = nf_def_var(nid,'masque',nf_float,1,idim2,nvarid) |
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76 |
ierr = nf_put_att_text(nid,nvarid,'title',16,'masque terre mer') |
ierr = nf_def_dim(nid, 'points_physiques', klon, idim2) |
77 |
ierr = nf_enddef(nid) |
ierr = nf_def_dim(nid, 'horizon_vertical', klon*klev, idim3) |
78 |
ierr = nf_put_var_real(nid,nvarid,zmasq) |
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79 |
! BP ajout des fraction de chaque sous-surface |
ierr = nf_def_var(nid, 'longitude', nf_float, 1, idim2, nvarid) |
80 |
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ierr = nf_put_att_text(nid, nvarid, 'title', 32, & |
81 |
! 1. fraction de terre |
'Longitudes de la grille physique') |
82 |
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ierr = nf_enddef(nid) |
83 |
ierr = nf_redef(nid) |
ierr = nf_put_var_real(nid, nvarid, rlon) |
84 |
ierr = nf_def_var(nid,'FTER',nf_float,1,idim2,nvarid) |
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85 |
ierr = nf_put_att_text(nid,nvarid,'title',21,'fraction de continent') |
ierr = nf_redef(nid) |
86 |
ierr = nf_enddef(nid) |
ierr = nf_def_var(nid, 'latitude', nf_float, 1, idim2, nvarid) |
87 |
ierr = nf_put_var_real(nid,nvarid,pctsrf(1:klon,is_ter)) |
ierr = nf_put_att_text(nid, nvarid, 'title', 31, & |
88 |
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'Latitudes de la grille physique') |
89 |
! 2. Fraction de glace de terre |
ierr = nf_enddef(nid) |
90 |
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ierr = nf_put_var_real(nid, nvarid, rlat) |
91 |
ierr = nf_redef(nid) |
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92 |
ierr = nf_def_var(nid,'FLIC',nf_float,1,idim2,nvarid) |
! PB ajout du masque terre/mer |
93 |
ierr = nf_put_att_text(nid,nvarid,'title',24,'fraction glace de terre') |
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94 |
ierr = nf_enddef(nid) |
ierr = nf_redef(nid) |
95 |
ierr = nf_put_var_real(nid,nvarid,pctsrf(1:klon,is_lic)) |
ierr = nf_def_var(nid, 'masque', nf_float, 1, idim2, nvarid) |
96 |
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ierr = nf_put_att_text(nid, nvarid, 'title', 16, 'masque terre mer') |
97 |
! 3. fraction ocean |
ierr = nf_enddef(nid) |
98 |
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ierr = nf_put_var_real(nid, nvarid, zmasq) |
99 |
ierr = nf_redef(nid) |
! BP ajout des fraction de chaque sous-surface |
100 |
ierr = nf_def_var(nid,'FOCE',nf_float,1,idim2,nvarid) |
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101 |
ierr = nf_put_att_text(nid,nvarid,'title',14,'fraction ocean') |
! 1. fraction de terre |
102 |
ierr = nf_enddef(nid) |
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103 |
ierr = nf_put_var_real(nid,nvarid,pctsrf(1:klon,is_oce)) |
ierr = nf_redef(nid) |
104 |
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ierr = nf_def_var(nid, 'FTER', nf_float, 1, idim2, nvarid) |
105 |
! 4. Fraction glace de mer |
ierr = nf_put_att_text(nid, nvarid, 'title', 21, 'fraction de continent') |
106 |
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ierr = nf_enddef(nid) |
107 |
ierr = nf_redef(nid) |
ierr = nf_put_var_real(nid, nvarid, pctsrf(1:klon, is_ter)) |
108 |
ierr = nf_def_var(nid,'FSIC',nf_float,1,idim2,nvarid) |
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109 |
ierr = nf_put_att_text(nid,nvarid,'title',18,'fraction glace mer') |
! 2. Fraction de glace de terre |
110 |
ierr = nf_enddef(nid) |
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111 |
ierr = nf_put_var_real(nid,nvarid,pctsrf(1:klon,is_sic)) |
ierr = nf_redef(nid) |
112 |
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ierr = nf_def_var(nid, 'FLIC', nf_float, 1, idim2, nvarid) |
113 |
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ierr = nf_put_att_text(nid, nvarid, 'title', 24, 'fraction glace de terre') |
114 |
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ierr = nf_enddef(nid) |
115 |
DO nsrf = 1, nbsrf |
ierr = nf_put_var_real(nid, nvarid, pctsrf(1:klon, is_lic)) |
116 |
IF (nsrf<=99) THEN |
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117 |
WRITE (str2,'(i2.2)') nsrf |
! 3. fraction ocean |
118 |
ierr = nf_redef(nid) |
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119 |
ierr = nf_def_var(nid,'TS'//str2,nf_float,1,idim2,nvarid) |
ierr = nf_redef(nid) |
120 |
ierr = nf_put_att_text(nid,nvarid,'title',28, & |
ierr = nf_def_var(nid, 'FOCE', nf_float, 1, idim2, nvarid) |
121 |
'Temperature de surface No.'//str2) |
ierr = nf_put_att_text(nid, nvarid, 'title', 14, 'fraction ocean') |
122 |
ierr = nf_enddef(nid) |
ierr = nf_enddef(nid) |
123 |
ELSE |
ierr = nf_put_var_real(nid, nvarid, pctsrf(1:klon, is_oce)) |
124 |
PRINT *, 'Trop de sous-mailles' |
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125 |
STOP 1 |
! 4. Fraction glace de mer |
126 |
END IF |
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127 |
ierr = nf_put_var_real(nid,nvarid,tsol(1,nsrf)) |
ierr = nf_redef(nid) |
128 |
END DO |
ierr = nf_def_var(nid, 'FSIC', nf_float, 1, idim2, nvarid) |
129 |
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ierr = nf_put_att_text(nid, nvarid, 'title', 18, 'fraction glace mer') |
130 |
DO nsrf = 1, nbsrf |
ierr = nf_enddef(nid) |
131 |
DO isoil = 1, nsoilmx |
ierr = nf_put_var_real(nid, nvarid, pctsrf(1:klon, is_sic)) |
132 |
IF (isoil<=99 .AND. nsrf<=99) THEN |
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133 |
WRITE (str7,'(i2.2,"srf",i2.2)') isoil, nsrf |
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134 |
ierr = nf_redef(nid) |
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135 |
ierr = nf_def_var(nid,'Tsoil'//str7,nf_float,1,idim2,nvarid) |
DO nsrf = 1, nbsrf |
136 |
ierr = nf_put_att_text(nid,nvarid,'title',29, & |
IF (nsrf<=99) THEN |
137 |
'Temperature du sol No.'//str7) |
WRITE (str2, '(i2.2)') nsrf |
138 |
ierr = nf_enddef(nid) |
ierr = nf_redef(nid) |
139 |
ELSE |
ierr = nf_def_var(nid, 'TS'//str2, nf_float, 1, idim2, nvarid) |
140 |
PRINT *, 'Trop de couches' |
ierr = nf_put_att_text(nid, nvarid, 'title', 28, & |
141 |
STOP 1 |
'Temperature de surface No.'//str2) |
142 |
END IF |
ierr = nf_enddef(nid) |
143 |
ierr = nf_put_var_real(nid,nvarid,tsoil(1,isoil,nsrf)) |
ELSE |
144 |
END DO |
PRINT *, 'Trop de sous-mailles' |
145 |
END DO |
STOP 1 |
146 |
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END IF |
147 |
!IM "slab" ocean |
ierr = nf_put_var_real(nid, nvarid, tsol(1, nsrf)) |
148 |
ierr = nf_redef(nid) |
END DO |
149 |
ierr = nf_def_var(nid,'TSLAB',nf_float,1,idim2,nvarid) |
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150 |
ierr = nf_put_att_text(nid,nvarid,'title',33, & |
DO nsrf = 1, nbsrf |
151 |
'Ecart de la SST (pour slab-ocean)') |
DO isoil = 1, nsoilmx |
152 |
ierr = nf_enddef(nid) |
IF (isoil<=99 .AND. nsrf<=99) THEN |
153 |
ierr = nf_put_var_real(nid,nvarid,tslab) |
WRITE (str7, '(i2.2, "srf", i2.2)') isoil, nsrf |
154 |
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ierr = nf_redef(nid) |
155 |
ierr = nf_redef(nid) |
ierr = nf_def_var(nid, 'Tsoil'//str7, nf_float, 1, idim2, nvarid) |
156 |
ierr = nf_def_var(nid,'SEAICE',nf_float,1,idim2,nvarid) |
ierr = nf_put_att_text(nid, nvarid, 'title', 29, & |
157 |
ierr = nf_put_att_text(nid,nvarid,'title',33, & |
'Temperature du sol No.'//str7) |
158 |
'Glace de mer kg/m2 (pour slab-ocean)') |
ierr = nf_enddef(nid) |
159 |
ierr = nf_enddef(nid) |
ELSE |
160 |
ierr = nf_put_var_real(nid,nvarid,seaice) |
PRINT *, 'Trop de couches' |
161 |
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STOP 1 |
162 |
DO nsrf = 1, nbsrf |
END IF |
163 |
IF (nsrf<=99) THEN |
ierr = nf_put_var_real(nid, nvarid, tsoil(1, isoil, nsrf)) |
164 |
WRITE (str2,'(i2.2)') nsrf |
END DO |
165 |
ierr = nf_redef(nid) |
END DO |
166 |
ierr = nf_def_var(nid,'QS'//str2,nf_float,1,idim2,nvarid) |
|
167 |
ierr = nf_put_att_text(nid,nvarid,'title',25, & |
!IM "slab" ocean |
168 |
'Humidite de surface No.'//str2) |
ierr = nf_redef(nid) |
169 |
ierr = nf_enddef(nid) |
ierr = nf_def_var(nid, 'TSLAB', nf_float, 1, idim2, nvarid) |
170 |
ELSE |
ierr = nf_put_att_text(nid, nvarid, 'title', 33, & |
171 |
PRINT *, 'Trop de sous-mailles' |
'Ecart de la SST (pour slab-ocean)') |
172 |
STOP 1 |
ierr = nf_enddef(nid) |
173 |
END IF |
ierr = nf_put_var_real(nid, nvarid, tslab) |
174 |
ierr = nf_put_var_real(nid,nvarid,qsurf(1,nsrf)) |
|
175 |
END DO |
ierr = nf_redef(nid) |
176 |
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ierr = nf_def_var(nid, 'SEAICE', nf_float, 1, idim2, nvarid) |
177 |
ierr = nf_redef(nid) |
ierr = nf_put_att_text(nid, nvarid, 'title', 33, & |
178 |
ierr = nf_def_var(nid,'QSOL',nf_float,1,idim2,nvarid) |
'Glace de mer kg/m2 (pour slab-ocean)') |
179 |
ierr = nf_put_att_text(nid,nvarid,'title',20,'Eau dans le sol (mm)') |
ierr = nf_enddef(nid) |
180 |
ierr = nf_enddef(nid) |
ierr = nf_put_var_real(nid, nvarid, seaice) |
181 |
ierr = nf_put_var_real(nid,nvarid,qsol) |
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182 |
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DO nsrf = 1, nbsrf |
183 |
DO nsrf = 1, nbsrf |
IF (nsrf<=99) THEN |
184 |
IF (nsrf<=99) THEN |
WRITE (str2, '(i2.2)') nsrf |
185 |
WRITE (str2,'(i2.2)') nsrf |
ierr = nf_redef(nid) |
186 |
ierr = nf_redef(nid) |
ierr = nf_def_var(nid, 'QS'//str2, nf_float, 1, idim2, nvarid) |
187 |
ierr = nf_def_var(nid,'ALBE'//str2,nf_float,1,idim2,nvarid) |
ierr = nf_put_att_text(nid, nvarid, 'title', 25, & |
188 |
ierr = nf_put_att_text(nid,nvarid,'title',23, & |
'Humidite de surface No.'//str2) |
189 |
'albedo de surface No.'//str2) |
ierr = nf_enddef(nid) |
190 |
ierr = nf_enddef(nid) |
ELSE |
191 |
ELSE |
PRINT *, 'Trop de sous-mailles' |
192 |
PRINT *, 'Trop de sous-mailles' |
STOP 1 |
193 |
STOP 1 |
END IF |
194 |
END IF |
ierr = nf_put_var_real(nid, nvarid, qsurf(1, nsrf)) |
195 |
ierr = nf_put_var_real(nid,nvarid,albedo(1,nsrf)) |
END DO |
196 |
END DO |
|
197 |
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ierr = nf_redef(nid) |
198 |
!IM BEG albedo LW |
ierr = nf_def_var(nid, 'QSOL', nf_float, 1, idim2, nvarid) |
199 |
DO nsrf = 1, nbsrf |
ierr = nf_put_att_text(nid, nvarid, 'title', 20, 'Eau dans le sol (mm)') |
200 |
IF (nsrf<=99) THEN |
ierr = nf_enddef(nid) |
201 |
WRITE (str2,'(i2.2)') nsrf |
ierr = nf_put_var_real(nid, nvarid, qsol) |
202 |
ierr = nf_redef(nid) |
|
203 |
ierr = nf_def_var(nid,'ALBLW'//str2,nf_float,1,idim2,nvarid) |
DO nsrf = 1, nbsrf |
204 |
ierr = nf_put_att_text(nid,nvarid,'title',23, & |
IF (nsrf<=99) THEN |
205 |
'albedo LW de surface No.'//str2) |
WRITE (str2, '(i2.2)') nsrf |
206 |
ierr = nf_enddef(nid) |
ierr = nf_redef(nid) |
207 |
ELSE |
ierr = nf_def_var(nid, 'ALBE'//str2, nf_float, 1, idim2, nvarid) |
208 |
PRINT *, 'Trop de sous-mailles' |
ierr = nf_put_att_text(nid, nvarid, 'title', 23, & |
209 |
STOP 1 |
'albedo de surface No.'//str2) |
210 |
END IF |
ierr = nf_enddef(nid) |
211 |
ierr = nf_put_var_real(nid,nvarid,alblw(1,nsrf)) |
ELSE |
212 |
END DO |
PRINT *, 'Trop de sous-mailles' |
213 |
!IM END albedo LW |
STOP 1 |
214 |
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END IF |
215 |
DO nsrf = 1, nbsrf |
ierr = nf_put_var_real(nid, nvarid, albedo(1, nsrf)) |
216 |
IF (nsrf<=99) THEN |
END DO |
217 |
WRITE (str2,'(i2.2)') nsrf |
|
218 |
ierr = nf_redef(nid) |
!IM BEG albedo LW |
219 |
ierr = nf_def_var(nid,'EVAP'//str2,nf_float,1,idim2,nvarid) |
DO nsrf = 1, nbsrf |
220 |
ierr = nf_put_att_text(nid,nvarid,'title',28, & |
IF (nsrf<=99) THEN |
221 |
'Evaporation de surface No.'//str2) |
WRITE (str2, '(i2.2)') nsrf |
222 |
ierr = nf_enddef(nid) |
ierr = nf_redef(nid) |
223 |
ELSE |
ierr = nf_def_var(nid, 'ALBLW'//str2, nf_float, 1, idim2, nvarid) |
224 |
PRINT *, 'Trop de sous-mailles' |
ierr = nf_put_att_text(nid, nvarid, 'title', 23, & |
225 |
STOP 1 |
'albedo LW de surface No.'//str2) |
226 |
END IF |
ierr = nf_enddef(nid) |
227 |
ierr = nf_put_var_real(nid,nvarid,evap(1,nsrf)) |
ELSE |
228 |
END DO |
PRINT *, 'Trop de sous-mailles' |
229 |
|
STOP 1 |
230 |
|
END IF |
231 |
DO nsrf = 1, nbsrf |
ierr = nf_put_var_real(nid, nvarid, alblw(1, nsrf)) |
232 |
IF (nsrf<=99) THEN |
END DO |
233 |
WRITE (str2,'(i2.2)') nsrf |
!IM END albedo LW |
234 |
ierr = nf_redef(nid) |
|
235 |
ierr = nf_def_var(nid,'SNOW'//str2,nf_float,1,idim2,nvarid) |
DO nsrf = 1, nbsrf |
236 |
ierr = nf_put_att_text(nid,nvarid,'title',22, & |
IF (nsrf<=99) THEN |
237 |
'Neige de surface No.'//str2) |
WRITE (str2, '(i2.2)') nsrf |
238 |
ierr = nf_enddef(nid) |
ierr = nf_redef(nid) |
239 |
ELSE |
ierr = nf_def_var(nid, 'EVAP'//str2, nf_float, 1, idim2, nvarid) |
240 |
PRINT *, 'Trop de sous-mailles' |
ierr = nf_put_att_text(nid, nvarid, 'title', 28, & |
241 |
STOP 1 |
'Evaporation de surface No.'//str2) |
242 |
END IF |
ierr = nf_enddef(nid) |
243 |
ierr = nf_put_var_real(nid,nvarid,snow(1,nsrf)) |
ELSE |
244 |
END DO |
PRINT *, 'Trop de sous-mailles' |
245 |
|
STOP 1 |
246 |
|
END IF |
247 |
ierr = nf_redef(nid) |
ierr = nf_put_var_real(nid, nvarid, evap(1, nsrf)) |
248 |
ierr = nf_def_var(nid,'RADS',nf_float,1,idim2,nvarid) |
END DO |
249 |
ierr = nf_put_att_text(nid,nvarid,'title',28, & |
|
250 |
'Rayonnement net a la surface') |
|
251 |
ierr = nf_enddef(nid) |
DO nsrf = 1, nbsrf |
252 |
ierr = nf_put_var_real(nid,nvarid,radsol) |
IF (nsrf<=99) THEN |
253 |
|
WRITE (str2, '(i2.2)') nsrf |
254 |
ierr = nf_redef(nid) |
ierr = nf_redef(nid) |
255 |
ierr = nf_def_var(nid,'solsw',nf_float,1,idim2,nvarid) |
ierr = nf_def_var(nid, 'SNOW'//str2, nf_float, 1, idim2, nvarid) |
256 |
ierr = nf_put_att_text(nid,nvarid,'title',32, & |
ierr = nf_put_att_text(nid, nvarid, 'title', 22, & |
257 |
'Rayonnement solaire a la surface') |
'Neige de surface No.'//str2) |
258 |
ierr = nf_enddef(nid) |
ierr = nf_enddef(nid) |
259 |
ierr = nf_put_var_real(nid,nvarid,solsw) |
ELSE |
260 |
|
PRINT *, 'Trop de sous-mailles' |
261 |
ierr = nf_redef(nid) |
STOP 1 |
262 |
ierr = nf_def_var(nid,'sollw',nf_float,1,idim2,nvarid) |
END IF |
263 |
ierr = nf_put_att_text(nid,nvarid,'title',27, & |
ierr = nf_put_var_real(nid, nvarid, snow(1, nsrf)) |
264 |
'Rayonnement IF a la surface') |
END DO |
265 |
ierr = nf_enddef(nid) |
|
266 |
ierr = nf_put_var_real(nid,nvarid,sollw) |
|
267 |
|
ierr = nf_redef(nid) |
268 |
ierr = nf_redef(nid) |
ierr = nf_def_var(nid, 'RADS', nf_float, 1, idim2, nvarid) |
269 |
ierr = nf_def_var(nid,'fder',nf_float,1,idim2,nvarid) |
ierr = nf_put_att_text(nid, nvarid, 'title', 28, & |
270 |
ierr = nf_put_att_text(nid,nvarid,'title',14,'Derive de flux') |
'Rayonnement net a la surface') |
271 |
ierr = nf_enddef(nid) |
ierr = nf_enddef(nid) |
272 |
ierr = nf_put_var_real(nid,nvarid,fder) |
ierr = nf_put_var_real(nid, nvarid, radsol) |
273 |
|
|
274 |
ierr = nf_redef(nid) |
ierr = nf_redef(nid) |
275 |
ierr = nf_def_var(nid,'rain_f',nf_float,1,idim2,nvarid) |
ierr = nf_def_var(nid, 'solsw', nf_float, 1, idim2, nvarid) |
276 |
ierr = nf_put_att_text(nid,nvarid,'title',21,'precipitation liquide') |
ierr = nf_put_att_text(nid, nvarid, 'title', 32, & |
277 |
ierr = nf_enddef(nid) |
'Rayonnement solaire a la surface') |
278 |
ierr = nf_put_var_real(nid,nvarid,rain_fall) |
ierr = nf_enddef(nid) |
279 |
|
ierr = nf_put_var_real(nid, nvarid, solsw) |
280 |
ierr = nf_redef(nid) |
|
281 |
ierr = nf_def_var(nid,'snow_f',nf_float,1,idim2,nvarid) |
ierr = nf_redef(nid) |
282 |
ierr = nf_put_att_text(nid,nvarid,'title',20,'precipitation solide') |
ierr = nf_def_var(nid, 'sollw', nf_float, 1, idim2, nvarid) |
283 |
ierr = nf_enddef(nid) |
ierr = nf_put_att_text(nid, nvarid, 'title', 27, & |
284 |
ierr = nf_put_var_real(nid,nvarid,snow_fall) |
'Rayonnement IF a la surface') |
285 |
|
ierr = nf_enddef(nid) |
286 |
DO nsrf = 1, nbsrf |
ierr = nf_put_var_real(nid, nvarid, sollw) |
287 |
IF (nsrf<=99) THEN |
|
288 |
WRITE (str2,'(i2.2)') nsrf |
ierr = nf_redef(nid) |
289 |
ierr = nf_redef(nid) |
ierr = nf_def_var(nid, 'fder', nf_float, 1, idim2, nvarid) |
290 |
ierr = nf_def_var(nid,'RUG'//str2,nf_float,1,idim2,nvarid) |
ierr = nf_put_att_text(nid, nvarid, 'title', 14, 'Derive de flux') |
291 |
ierr = nf_put_att_text(nid,nvarid,'title',23, & |
ierr = nf_enddef(nid) |
292 |
'rugosite de surface No.'//str2) |
ierr = nf_put_var_real(nid, nvarid, fder) |
293 |
ierr = nf_enddef(nid) |
|
294 |
ELSE |
ierr = nf_redef(nid) |
295 |
PRINT *, 'Trop de sous-mailles' |
ierr = nf_def_var(nid, 'rain_f', nf_float, 1, idim2, nvarid) |
296 |
STOP 1 |
ierr = nf_put_att_text(nid, nvarid, 'title', 21, 'precipitation liquide') |
297 |
END IF |
ierr = nf_enddef(nid) |
298 |
ierr = nf_put_var_real(nid,nvarid,frugs(1,nsrf)) |
ierr = nf_put_var_real(nid, nvarid, rain_fall) |
299 |
END DO |
|
300 |
|
ierr = nf_redef(nid) |
301 |
DO nsrf = 1, nbsrf |
ierr = nf_def_var(nid, 'snow_f', nf_float, 1, idim2, nvarid) |
302 |
IF (nsrf<=99) THEN |
ierr = nf_put_att_text(nid, nvarid, 'title', 20, 'precipitation solide') |
303 |
WRITE (str2,'(i2.2)') nsrf |
ierr = nf_enddef(nid) |
304 |
ierr = nf_redef(nid) |
ierr = nf_put_var_real(nid, nvarid, snow_fall) |
305 |
ierr = nf_def_var(nid,'AGESNO'//str2,nf_float,1,idim2,nvarid) |
|
306 |
ierr = nf_put_att_text(nid,nvarid,'title',15, & |
DO nsrf = 1, nbsrf |
307 |
'Age de la neige surface No.'//str2) |
IF (nsrf<=99) THEN |
308 |
ierr = nf_enddef(nid) |
WRITE (str2, '(i2.2)') nsrf |
309 |
ELSE |
ierr = nf_redef(nid) |
310 |
PRINT *, 'Trop de sous-mailles' |
ierr = nf_def_var(nid, 'RUG'//str2, nf_float, 1, idim2, nvarid) |
311 |
STOP 1 |
ierr = nf_put_att_text(nid, nvarid, 'title', 23, & |
312 |
END IF |
'rugosite de surface No.'//str2) |
313 |
ierr = nf_put_var_real(nid,nvarid,agesno(1,nsrf)) |
ierr = nf_enddef(nid) |
314 |
END DO |
ELSE |
315 |
|
PRINT *, 'Trop de sous-mailles' |
316 |
ierr = nf_redef(nid) |
STOP 1 |
317 |
ierr = nf_def_var(nid,'ZMEA',nf_float,1,idim2,nvarid) |
END IF |
318 |
ierr = nf_enddef(nid) |
ierr = nf_put_var_real(nid, nvarid, frugs(1, nsrf)) |
319 |
ierr = nf_put_var_real(nid,nvarid,zmea) |
END DO |
320 |
|
|
321 |
ierr = nf_redef(nid) |
DO nsrf = 1, nbsrf |
322 |
ierr = nf_def_var(nid,'ZSTD',nf_float,1,idim2,nvarid) |
IF (nsrf<=99) THEN |
323 |
ierr = nf_enddef(nid) |
WRITE (str2, '(i2.2)') nsrf |
324 |
ierr = nf_put_var_real(nid,nvarid,zstd) |
ierr = nf_redef(nid) |
325 |
ierr = nf_redef(nid) |
ierr = nf_def_var(nid, 'AGESNO'//str2, nf_float, 1, idim2, nvarid) |
326 |
ierr = nf_def_var(nid,'ZSIG',nf_float,1,idim2,nvarid) |
ierr = nf_put_att_text(nid, nvarid, 'title', 15, & |
327 |
ierr = nf_enddef(nid) |
'Age de la neige surface No.'//str2) |
328 |
ierr = nf_put_var_real(nid,nvarid,zsig) |
ierr = nf_enddef(nid) |
329 |
ierr = nf_redef(nid) |
ELSE |
330 |
ierr = nf_def_var(nid,'ZGAM',nf_float,1,idim2,nvarid) |
PRINT *, 'Trop de sous-mailles' |
331 |
ierr = nf_enddef(nid) |
STOP 1 |
332 |
ierr = nf_put_var_real(nid,nvarid,zgam) |
END IF |
333 |
ierr = nf_redef(nid) |
ierr = nf_put_var_real(nid, nvarid, agesno(1, nsrf)) |
334 |
ierr = nf_def_var(nid,'ZTHE',nf_float,1,idim2,nvarid) |
END DO |
335 |
ierr = nf_enddef(nid) |
|
336 |
ierr = nf_put_var_real(nid,nvarid,zthe) |
ierr = nf_redef(nid) |
337 |
ierr = nf_redef(nid) |
ierr = nf_def_var(nid, 'ZMEA', nf_float, 1, idim2, nvarid) |
338 |
ierr = nf_def_var(nid,'ZPIC',nf_float,1,idim2,nvarid) |
ierr = nf_enddef(nid) |
339 |
ierr = nf_enddef(nid) |
ierr = nf_put_var_real(nid, nvarid, zmea) |
340 |
ierr = nf_put_var_real(nid,nvarid,zpic) |
|
341 |
ierr = nf_redef(nid) |
ierr = nf_redef(nid) |
342 |
ierr = nf_def_var(nid,'ZVAL',nf_float,1,idim2,nvarid) |
ierr = nf_def_var(nid, 'ZSTD', nf_float, 1, idim2, nvarid) |
343 |
ierr = nf_enddef(nid) |
ierr = nf_enddef(nid) |
344 |
ierr = nf_put_var_real(nid,nvarid,zval) |
ierr = nf_put_var_real(nid, nvarid, zstd) |
345 |
|
ierr = nf_redef(nid) |
346 |
ierr = nf_redef(nid) |
ierr = nf_def_var(nid, 'ZSIG', nf_float, 1, idim2, nvarid) |
347 |
ierr = nf_def_var(nid,'TANCIEN',nf_float,1,idim3,nvarid) |
ierr = nf_enddef(nid) |
348 |
ierr = nf_enddef(nid) |
ierr = nf_put_var_real(nid, nvarid, zsig) |
349 |
ierr = nf_put_var_real(nid,nvarid,t_ancien) |
ierr = nf_redef(nid) |
350 |
|
ierr = nf_def_var(nid, 'ZGAM', nf_float, 1, idim2, nvarid) |
351 |
ierr = nf_redef(nid) |
ierr = nf_enddef(nid) |
352 |
ierr = nf_def_var(nid,'QANCIEN',nf_float,1,idim3,nvarid) |
ierr = nf_put_var_real(nid, nvarid, zgam) |
353 |
ierr = nf_enddef(nid) |
ierr = nf_redef(nid) |
354 |
ierr = nf_put_var_real(nid,nvarid,q_ancien) |
ierr = nf_def_var(nid, 'ZTHE', nf_float, 1, idim2, nvarid) |
355 |
|
ierr = nf_enddef(nid) |
356 |
ierr = nf_redef(nid) |
ierr = nf_put_var_real(nid, nvarid, zthe) |
357 |
ierr = nf_def_var(nid,'RUGMER',nf_float,1,idim2,nvarid) |
ierr = nf_redef(nid) |
358 |
ierr = nf_put_att_text(nid,nvarid,'title',28, & |
ierr = nf_def_var(nid, 'ZPIC', nf_float, 1, idim2, nvarid) |
359 |
'Longueur de rugosite sur mer') |
ierr = nf_enddef(nid) |
360 |
ierr = nf_enddef(nid) |
ierr = nf_put_var_real(nid, nvarid, zpic) |
361 |
ierr = nf_put_var_real(nid,nvarid,frugs(1,is_oce)) |
ierr = nf_redef(nid) |
362 |
|
ierr = nf_def_var(nid, 'ZVAL', nf_float, 1, idim2, nvarid) |
363 |
ierr = nf_redef(nid) |
ierr = nf_enddef(nid) |
364 |
ierr = nf_def_var(nid,'CLWCON',nf_float,1,idim2,nvarid) |
ierr = nf_put_var_real(nid, nvarid, zval) |
365 |
ierr = nf_put_att_text(nid,nvarid,'title',28,'Eau liquide convective') |
|
366 |
ierr = nf_enddef(nid) |
ierr = nf_redef(nid) |
367 |
ierr = nf_put_var_real(nid,nvarid,clwcon) |
ierr = nf_def_var(nid, 'TANCIEN', nf_float, 1, idim3, nvarid) |
368 |
|
ierr = nf_enddef(nid) |
369 |
ierr = nf_redef(nid) |
ierr = nf_put_var_real(nid, nvarid, t_ancien) |
370 |
ierr = nf_def_var(nid,'RNEBCON',nf_float,1,idim2,nvarid) |
|
371 |
ierr = nf_put_att_text(nid,nvarid,'title',28,'Nebulosite convective') |
ierr = nf_redef(nid) |
372 |
ierr = nf_enddef(nid) |
ierr = nf_def_var(nid, 'QANCIEN', nf_float, 1, idim3, nvarid) |
373 |
ierr = nf_put_var_real(nid,nvarid,rnebcon) |
ierr = nf_enddef(nid) |
374 |
|
ierr = nf_put_var_real(nid, nvarid, q_ancien) |
375 |
ierr = nf_redef(nid) |
|
376 |
ierr = nf_def_var(nid,'RATQS',nf_float,1,idim2,nvarid) |
ierr = nf_redef(nid) |
377 |
ierr = nf_put_att_text(nid,nvarid,'title',5,'Ratqs') |
ierr = nf_def_var(nid, 'RUGMER', nf_float, 1, idim2, nvarid) |
378 |
ierr = nf_enddef(nid) |
ierr = nf_put_att_text(nid, nvarid, 'title', 28, & |
379 |
ierr = nf_put_var_real(nid,nvarid,ratqs) |
'Longueur de rugosite sur mer') |
380 |
|
ierr = nf_enddef(nid) |
381 |
! run_off_lic_0 |
ierr = nf_put_var_real(nid, nvarid, frugs(1, is_oce)) |
382 |
|
|
383 |
ierr = nf_redef(nid) |
ierr = nf_redef(nid) |
384 |
ierr = nf_def_var(nid,'RUNOFFLIC0',nf_float,1,idim2,nvarid) |
ierr = nf_def_var(nid, 'CLWCON', nf_float, 1, idim2, nvarid) |
385 |
ierr = nf_put_att_text(nid,nvarid,'title',10,'Runofflic0') |
ierr = nf_put_att_text(nid, nvarid, 'title', 28, 'Eau liquide convective') |
386 |
ierr = nf_enddef(nid) |
ierr = nf_enddef(nid) |
387 |
ierr = nf_put_var_real(nid,nvarid,run_off_lic_0) |
ierr = nf_put_var_real(nid, nvarid, clwcon) |
388 |
|
|
389 |
|
ierr = nf_redef(nid) |
390 |
|
ierr = nf_def_var(nid, 'RNEBCON', nf_float, 1, idim2, nvarid) |
391 |
|
ierr = nf_put_att_text(nid, nvarid, 'title', 28, 'Nebulosite convective') |
392 |
|
ierr = nf_enddef(nid) |
393 |
|
ierr = nf_put_var_real(nid, nvarid, rnebcon) |
394 |
|
|
395 |
|
ierr = nf_redef(nid) |
396 |
|
ierr = nf_def_var(nid, 'RATQS', nf_float, 1, idim2, nvarid) |
397 |
|
ierr = nf_put_att_text(nid, nvarid, 'title', 5, 'Ratqs') |
398 |
|
ierr = nf_enddef(nid) |
399 |
|
ierr = nf_put_var_real(nid, nvarid, ratqs) |
400 |
|
|
401 |
|
! run_off_lic_0 |
402 |
|
|
403 |
|
ierr = nf_redef(nid) |
404 |
|
ierr = nf_def_var(nid, 'RUNOFFLIC0', nf_float, 1, idim2, nvarid) |
405 |
|
ierr = nf_put_att_text(nid, nvarid, 'title', 10, 'Runofflic0') |
406 |
|
ierr = nf_enddef(nid) |
407 |
|
ierr = nf_put_var_real(nid, nvarid, run_off_lic_0) |
408 |
|
|
409 |
|
|
410 |
ierr = nf_close(nid) |
ierr = nf_close(nid) |
411 |
|
|
412 |
END SUBROUTINE phyredem |
END SUBROUTINE phyredem |
413 |
|
|
414 |
|
end module phyredem_m |