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phyaqua_mod.F90 @ 4283

Last change on this file since 4283 was 4253, checked in by lguez, 20 months ago

Replace nf_def_var by nf90_def_var

The immediate motivation is a bug fix: nf_def_var was called with a
scalar instead of array actual argument for dummy array argument
vdims. The simplest way to correct this bug is to replace by a call to
nf90_def_var.

Property copyright set to
Name of program: LMDZ
Creation date: 1984
Version: LMDZ5
License: CeCILL version 2
Holder: Laboratoire de m\'et\'eorologie dynamique, CNRS, UMR 8539
See the license file in the root directory
Property svn:keywords set to Id

File size: 31.7 KB

Line
1	!
2	! $Id: phyaqua_mod.F90 4253 2022-09-20 14:09:48Z jghattas $
3	!
4	MODULE phyaqua_mod
5	! Routines complementaires pour la physique planetaire.
6	IMPLICIT NONE
7
8	CONTAINS
9
10	SUBROUTINE iniaqua(nlon,year_len,iflag_phys)
11
12	! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
13	! Creation d'un etat initial et de conditions aux limites
14	! (resp startphy.nc et limit.nc) pour des configurations idealisees
15	! du modele LMDZ dans sa version terrestre.
16	! iflag_phys est un parametre qui controle
17	! iflag_phys = N
18	! de 100 a 199 : aqua planetes avec SST forcees
19	! N-100 determine le type de SSTs
20	! de 200 a 299 : terra planetes avec Ts calcule
21
22	! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
23
24	USE dimphy, ONLY: klon
25	USE geometry_mod, ONLY : latitude
26	USE surface_data, ONLY: type_ocean, ok_veget
27	USE pbl_surface_mod, ONLY: pbl_surface_init
28	USE fonte_neige_mod, ONLY: fonte_neige_init
29	USE phys_state_var_mod
30	USE time_phylmdz_mod, ONLY: day_ref, ndays, pdtphys, &
31	day_ini,day_end
32	USE indice_sol_mod
33	USE nrtype, ONLY: pi
34	! USE ioipsl
35	USE mod_phys_lmdz_para, ONLY: is_master
36	USE mod_phys_lmdz_transfert_para, ONLY: bcast
37	USE mod_grid_phy_lmdz
38	USE ioipsl_getin_p_mod, ONLY : getin_p
39	USE phys_cal_mod , ONLY: calend, year_len_phy => year_len
40	IMPLICIT NONE
41
42	include "YOMCST.h"
43	include "clesphys.h"
44	include "dimsoil.h"
45
46	INTEGER, INTENT (IN) :: nlon, year_len, iflag_phys
47	! IM ajout latfi, lonfi
48	! REAL, INTENT (IN) :: lonfi(nlon), latfi(nlon)
49
50	INTEGER type_profil, type_aqua
51
52	! Ajouts initialisation des surfaces
53	REAL :: run_off_lic_0(nlon)
54	REAL :: qsolsrf(nlon, nbsrf), snsrf(nlon, nbsrf)
55	REAL :: tsoil(nlon, nsoilmx, nbsrf)
56	REAL :: tslab(nlon), seaice(nlon)
57	REAL fder(nlon)
58
59
60
61	! Arguments :
62	! -----------
63
64	! integer radpas
65	INTEGER it, unit, i, k, itap
66
67	REAL rugos, albedo
68	REAL tsurf
69	REAL time, timestep, day, day0
70	REAL qsol_f
71	REAL rugsrel(nlon)
72	LOGICAL alb_ocean
73
74	CHARACTER *80 ans, file_forctl, file_fordat, file_start
75	CHARACTER *100 file, var
76	CHARACTER *2 cnbl
77
78	REAL phy_nat(nlon, year_len)
79	REAL phy_alb(nlon, year_len)
80	REAL phy_sst(nlon, year_len)
81	REAL phy_bil(nlon, year_len)
82	REAL phy_rug(nlon, year_len)
83	REAL phy_ice(nlon, year_len)
84	REAL phy_fter(nlon, year_len)
85	REAL phy_foce(nlon, year_len)
86	REAL phy_fsic(nlon, year_len)
87	REAL phy_flic(nlon, year_len)
88
89	INTEGER, SAVE :: read_climoz = 0 ! read ozone climatology
90	!$OMP THREADPRIVATE(read_climoz)
91
92	! -------------------------------------------------------------------------
93	! declaration pour l'appel a phyredem
94	! -------------------------------------------------------------------------
95
96	! real pctsrf(nlon,nbsrf),ftsol(nlon,nbsrf)
97	REAL falbe(nlon, nbsrf), falblw(nlon, nbsrf)
98	! real pbl_tke(nlon,llm,nbsrf)
99	! real rain_fall(nlon),snow_fall(nlon)
100	! real solsw(nlon), sollw(nlon),radsol(nlon)
101	! real t_ancien(nlon,llm),q_ancien(nlon,llm),rnebcon(nlon,llm)
102	! real ratqs(nlon,llm)
103	! real clwcon(nlon,llm)
104
105	INTEGER longcles
106	PARAMETER (longcles=20)
107	REAL clesphy0(longcles)
108
109
110	! -----------------------------------------------------------------------
111	! dynamial tendencies :
112	! ---------------------
113
114	INTEGER l, ierr, aslun
115
116	REAL paire
117
118	! Local
119	CHARACTER (LEN=20) :: modname='phyaqua'
120	CHARACTER (LEN=80) :: abort_message
121
122
123	! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
124	! INITIALISATIONS
125	! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
126
127	! -----------------------------------------------------------------------
128	! Initialisations des constantes
129	! -------------------------------
130
131	!IF (calend .EQ. "earth_360d") Then
132	year_len_phy = year_len
133	!END IF
134
135	if (year_len.ne.360) then
136	write (,) year_len
137	write (,) 'iniaqua: 360 day calendar is required !'
138	stop
139	endif
140
141	type_aqua = iflag_phys/100
142	type_profil = iflag_phys - type_aqua*100
143	PRINT *, 'iniaqua:type_aqua, type_profil', type_aqua, type_profil
144
145	IF (klon/=nlon) THEN
146	WRITE (, ) 'iniaqua: klon=', klon, ' nlon=', nlon
147	abort_message= 'probleme de dimensions dans iniaqua'
148	CALL abort_physic(modname,abort_message,1)
149	END IF
150	CALL phys_state_var_init(read_climoz)
151
152
153	read_climoz = 0
154	day0 = 217.
155	day = day0
156	it = 0
157	time = 0.
158
159	! -----------------------------------------------------------------------
160	! initialisations de la physique
161	! -----------------------------------------------------------------------
162
163	day_ini = day_ref
164	day_end = day_ini + ndays
165
166	nbapp_rad = 24
167	CALL getin_p('nbapp_rad', nbapp_rad)
168
169	! ---------------------------------------------------------------------
170	! Creation des conditions aux limites:
171	! ------------------------------------
172	! Initialisations des constantes
173	! Ajouter les manquants dans planete.def... (albedo etc)
174	co2_ppm = 348.
175	CALL getin_p('co2_ppm', co2_ppm)
176
177	solaire = 1365.
178	CALL getin_p('solaire', solaire)
179
180	! CALL getin('albedo',albedo) ! albedo is set below, depending on
181	! type_aqua
182	alb_ocean = .TRUE.
183	CALL getin_p('alb_ocean', alb_ocean)
184
185	WRITE (, ) 'iniaqua: co2_ppm=', co2_ppm
186	WRITE (, ) 'iniaqua: solaire=', solaire
187	WRITE (, ) 'iniaqua: alb_ocean=', alb_ocean
188
189	radsol = 0.
190	qsol_f = 10.
191
192	! Conditions aux limites:
193	! -----------------------
194
195	qsol(:) = qsol_f
196	rugsrel = 0.0 ! (rugsrel = rugoro)
197	rugoro = 0.0
198	u_ancien = 0.0
199	v_ancien = 0.0
200	agesno = 50.0
201	! Relief plat
202	zmea = 0.
203	zstd = 0.
204	zsig = 0.
205	zgam = 0.
206	zthe = 0.
207	zpic = 0.
208	zval = 0.
209
210	! Une seule surface
211	pctsrf = 0.
212	IF (type_aqua==1) THEN
213	rugos = 1.E-4
214	albedo = 0.19
215	pctsrf(:, is_oce) = 1.
216	ELSE IF (type_aqua==2) THEN
217	rugos = 0.03
218	albedo = 0.1
219	pctsrf(:, is_ter) = 1.
220	END IF
221
222	CALL getin_p('rugos', rugos)
223
224	WRITE (, ) 'iniaqua: rugos=', rugos
225	zmasq(:) = pctsrf(:, is_ter)
226
227	! pctsrf_pot(:,is_oce) = 1. - zmasq(:)
228	! pctsrf_pot(:,is_sic) = 1. - zmasq(:)
229
230	! Si alb_ocean on calcule un albedo oceanique moyen
231	! if (alb_ocean) then
232	! Voir pourquoi on avait ca.
233	! CALL ini_alb_oce(phy_alb)
234	! else
235	phy_alb(:, :) = albedo ! albedo land only (old value condsurf_jyg=0.3)
236	! endif !alb_ocean
237
238	DO i = 1, year_len
239	! IM Terraplanete phy_sst(:,i) = 260.+50.cos(rlatd(:))*2
240	! IM ajout calcul profil sst selon le cas considere (cf. FBr)
241
242	phy_nat(:, i) = 1.0 ! 0=ocean libre, 1=land, 2=glacier, 3=banquise
243	phy_bil(:, i) = 1.0 ! ne sert que pour les slab_ocean
244	phy_rug(:, i) = rugos ! longueur rugosite utilisee sur land only
245	phy_ice(:, i) = 0.0 ! fraction de glace (?)
246	phy_fter(:, i) = pctsrf(:, is_ter) ! fraction de glace (?)
247	phy_foce(:, i) = pctsrf(:, is_oce) ! fraction de glace (?)
248	phy_fsic(:, i) = pctsrf(:, is_sic) ! fraction de glace (?)
249	phy_flic(:, i) = pctsrf(:, is_lic) ! fraction de glace (?)
250	END DO
251	! IM calcul profil sst
252	CALL profil_sst(nlon, latitude, type_profil, phy_sst)
253
254	IF (grid_type==unstructured) THEN
255	CALL writelim_unstruct(klon, phy_nat, phy_alb, phy_sst, phy_bil, phy_rug, phy_ice, &
256	phy_fter, phy_foce, phy_flic, phy_fsic)
257	ELSE
258
259	CALL writelim(klon, phy_nat, phy_alb, phy_sst, phy_bil, phy_rug, phy_ice, &
260	phy_fter, phy_foce, phy_flic, phy_fsic)
261	ENDIF
262
263	! ---------------------------------------------------------------------
264	! Ecriture de l'etat initial:
265	! ---------------------------
266
267
268	! Ecriture etat initial physique
269
270	timestep = pdtphys
271	radpas = nint(rday/timestep/float(nbapp_rad))
272
273	DO i = 1, longcles
274	clesphy0(i) = 0.
275	END DO
276	clesphy0(1) = float(iflag_con)
277	clesphy0(2) = float(nbapp_rad)
278	! IF( cycle_diurne ) clesphy0(3) = 1.
279	clesphy0(3) = 1. ! cycle_diurne
280	clesphy0(4) = 1. ! soil_model
281	clesphy0(5) = 1. ! new_oliq
282	clesphy0(6) = 0. ! ok_orodr
283	clesphy0(7) = 0. ! ok_orolf
284	clesphy0(8) = 0. ! ok_limitvrai
285
286
287	! =======================================================================
288	! Profils initiaux
289	! =======================================================================
290
291	! On initialise les temperatures de surfaces comme les sst
292	DO i = 1, nlon
293	ftsol(i, :) = phy_sst(i, 1)
294	tsoil(i, :, :) = phy_sst(i, 1)
295	tslab(i) = phy_sst(i, 1)
296	END DO
297
298	falbe(:, :) = albedo
299	falblw(:, :) = albedo
300	rain_fall(:) = 0.
301	snow_fall(:) = 0.
302	solsw(:) = 0.
303	sollw(:) = 0.
304	radsol(:) = 0.
305
306	! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
307	! intialisation bidon mais pas grave
308	t_ancien(:, :) = 0.
309	q_ancien(:, :) = 0.
310	! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
311	rnebcon = 0.
312	ratqs = 0.
313	clwcon = 0.
314	pbl_tke = 1.E-8
315
316	! variables supplementaires pour appel a plb_surface_init
317	fder(:) = 0.
318	seaice(:) = 0.
319	run_off_lic_0 = 0.
320	fevap = 0.
321
322
323	! Initialisations necessaires avant phyredem
324	type_ocean = 'force'
325	CALL fonte_neige_init(run_off_lic_0)
326	qsolsrf(:, :) = qsol(1) ! humidite du sol des sous surface
327	snsrf(:, :) = 0. ! couverture de neige des sous surface
328	z0m(:, :) = rugos ! couverture de neige des sous surface
329	z0h=z0m
330
331
332	CALL pbl_surface_init(fder, snsrf, qsolsrf, tsoil)
333
334	PRINT *, 'iniaqua: before phyredem'
335
336	pbl_tke(:,:,:) = 1.e-8
337	falb1 = albedo
338	falb2 = albedo
339	zmax0 = 0.
340	f0 = 0.
341	sig1 = 0.
342	w01 = 0.
343	wake_deltat = 0.
344	wake_deltaq = 0.
345	wake_s = 0.
346	wake_dens = 0.
347	wake_cstar = 0.
348	wake_pe = 0.
349	wake_fip = 0.
350	fm_therm = 0.
351	entr_therm = 0.
352	detr_therm = 0.
353	ale_bl = 0.
354	ale_bl_trig =0.
355	alp_bl =0.
356	treedrg(:,:,:)=0.
357
358	u10m = 0.
359	v10m = 0.
360
361	ql_ancien = 0.
362	qs_ancien = 0.
363	u_ancien = 0.
364	v_ancien = 0.
365	prw_ancien = 0.
366	prlw_ancien = 0.
367	prsw_ancien = 0.
368
369	ale_wake = 0.
370	ale_bl_stat = 0.
371
372
373	!ym error : the sub surface dimension is the third not second : forgotten for iniaqua
374	! falb_dir(:,is_ter,:)=0.08; falb_dir(:,is_lic,:)=0.6
375	! falb_dir(:,is_oce,:)=0.5; falb_dir(:,is_sic,:)=0.6
376	falb_dir(:,:,is_ter)=0.08; falb_dir(:,:,is_lic)=0.6
377	falb_dir(:,:,is_oce)=0.5; falb_dir(:,:,is_sic)=0.6
378
379	!ym falb_dif has been forgotten, initialize with defaukt value found in phyetat0 or 0 ?
380	!ym probably the uninitialized value was 0 for standard (regular grid) case
381	falb_dif(:,:,:)=0
382
383
384	CALL phyredem('startphy.nc')
385
386	PRINT *, 'iniaqua: after phyredem'
387	CALL phys_state_var_end
388
389	RETURN
390	END SUBROUTINE iniaqua
391
392
393	! ====================================================================
394	! ====================================================================
395	SUBROUTINE zenang_an(cycle_diurne, gmtime, rlat, rlon, rmu0, fract)
396	USE dimphy
397	IMPLICIT NONE
398	! ====================================================================
399	! =============================================================
400	! CALL zenang(cycle_diurne,gmtime,rlat,rlon,rmu0,fract)
401	! Auteur : A. Campoy et F. Hourdin
402	! Objet : calculer les valeurs moyennes du cos de l'angle zenithal
403	! et l'ensoleillement moyen entre gmtime1 et gmtime2
404	! connaissant la declinaison, la latitude et la longitude.
405
406	! Dans cette version particuliere, on calcule le rayonnement
407	! moyen sur l'année à chaque latitude.
408	! angle zenithal calculé pour obtenir un
409	! Fit polynomial de l'ensoleillement moyen au sommet de l'atmosphere
410	! en moyenne annuelle.
411	! Spécifique de la terre. Utilisé pour les aqua planetes.
412
413	! Rque : Different de la routine angle en ce sens que zenang
414	! fournit des moyennes de pmu0 et non des valeurs
415	! instantanees, du coup frac prend toutes les valeurs
416	! entre 0 et 1.
417	! Date : premiere version le 13 decembre 1994
418	! revu pour GCM le 30 septembre 1996
419	! ===============================================================
420	! longi----INPUT : la longitude vraie de la terre dans son plan
421	! solaire a partir de l'equinoxe de printemps (degre)
422	! gmtime---INPUT : temps universel en fraction de jour
423	! pdtrad---INPUT : pas de temps du rayonnement (secondes)
424	! lat------INPUT : latitude en degres
425	! long-----INPUT : longitude en degres
426	! pmu0-----OUTPUT: angle zenithal moyen entre gmtime et gmtime+pdtrad
427	! frac-----OUTPUT: ensoleillement moyen entre gmtime et gmtime+pdtrad
428	! ================================================================
429	include "YOMCST.h"
430	! ================================================================
431	LOGICAL cycle_diurne
432	REAL gmtime
433	REAL rlat(klon), rlon(klon), rmu0(klon), fract(klon)
434	! ================================================================
435	INTEGER i
436	REAL gmtime1, gmtime2
437	REAL pi_local
438
439
440	REAL rmu0m(klon), rmu0a(klon)
441
442
443	pi_local = 4.0*atan(1.0)
444
445	! ================================================================
446	! Calcul de l'angle zenithal moyen sur la journee
447	! ================================================================
448
449	DO i = 1, klon
450	fract(i) = 1.
451	! Calcule du flux moyen
452	IF (abs(rlat(i))<=28.75) THEN
453	rmu0m(i) = (210.1924+206.6059cos(0.0174533rlat(i))**2)/1365.
454	ELSE IF (abs(rlat(i))<=43.75) THEN
455	rmu0m(i) = (187.4562+236.1853cos(0.0174533rlat(i))**2)/1365.
456	ELSE IF (abs(rlat(i))<=71.25) THEN
457	rmu0m(i) = (162.4439+284.1192cos(0.0174533rlat(i))**2)/1365.
458	ELSE
459	rmu0m(i) = (172.8125+183.7673cos(0.0174533rlat(i))**2)/1365.
460	END IF
461	END DO
462
463	! ================================================================
464	! Avec ou sans cycle diurne
465	! ================================================================
466
467	IF (cycle_diurne) THEN
468
469	! On redecompose flux au sommet suivant un cycle diurne idealise
470	! identique a toutes les latitudes.
471
472	DO i = 1, klon
473	rmu0a(i) = 2.rmu0m(i)sqrt(2.)*pi_local/(4.-pi_local)
474	rmu0(i) = rmu0a(i)abs(sin(pi_localgmtime+pi_local*rlon(i)/360.)) - &
475	rmu0a(i)/sqrt(2.)
476	END DO
477
478	DO i = 1, klon
479	IF (rmu0(i)<=0.) THEN
480	rmu0(i) = 0.
481	fract(i) = 0.
482	ELSE
483	fract(i) = 1.
484	END IF
485	END DO
486
487	! Affichage de l'angel zenitale
488	! print,'***********************************'
489	! print,'***********************************'
490	! print,'***********************************'
491	! print*,'latitude=',rlat(i),'longitude=',rlon(i)
492	! print*,'rmu0m=',rmu0m(i)
493	! print*,'rmu0a=',rmu0a(i)
494	! print*,'rmu0=',rmu0(i)
495
496	ELSE
497
498	DO i = 1, klon
499	fract(i) = 0.5
500	rmu0(i) = rmu0m(i)*2.
501	END DO
502
503	END IF
504
505	RETURN
506	END SUBROUTINE zenang_an
507
508	! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
509
510	SUBROUTINE writelim_unstruct(klon, phy_nat, phy_alb, phy_sst, phy_bil, phy_rug, &
511	phy_ice, phy_fter, phy_foce, phy_flic, phy_fsic)
512
513	USE mod_phys_lmdz_para, ONLY: is_omp_master, klon_mpi
514	USE mod_phys_lmdz_transfert_para, ONLY: gather_omp
515	#ifdef CPP_XIOS
516	USE xios
517	#endif
518	IMPLICIT NONE
519
520	include "netcdf.inc"
521
522	INTEGER, INTENT (IN) :: klon
523	REAL, INTENT (IN) :: phy_nat(klon, 360)
524	REAL, INTENT (IN) :: phy_alb(klon, 360)
525	REAL, INTENT (IN) :: phy_sst(klon, 360)
526	REAL, INTENT (IN) :: phy_bil(klon, 360)
527	REAL, INTENT (IN) :: phy_rug(klon, 360)
528	REAL, INTENT (IN) :: phy_ice(klon, 360)
529	REAL, INTENT (IN) :: phy_fter(klon, 360)
530	REAL, INTENT (IN) :: phy_foce(klon, 360)
531	REAL, INTENT (IN) :: phy_flic(klon, 360)
532	REAL, INTENT (IN) :: phy_fsic(klon, 360)
533
534	REAL :: phy_mpi(klon_mpi, 360) ! temporary variable, to store phy_***(:)
535	! on the whole physics grid
536
537	#ifdef CPP_XIOS
538	PRINT *, 'writelim: Ecriture du fichier limit'
539
540	CALL gather_omp(phy_foce, phy_mpi)
541	IF (is_omp_master) CALL xios_send_field('foce_limout',phy_mpi)
542
543	CALL gather_omp(phy_fsic, phy_mpi)
544	IF (is_omp_master) CALL xios_send_field('fsic_limout',phy_mpi)
545
546	CALL gather_omp(phy_fter, phy_mpi)
547	IF (is_omp_master) CALL xios_send_field('fter_limout',phy_mpi)
548
549	CALL gather_omp(phy_flic, phy_mpi)
550	IF (is_omp_master) CALL xios_send_field('flic_limout',phy_mpi)
551
552	CALL gather_omp(phy_sst, phy_mpi)
553	IF (is_omp_master) CALL xios_send_field('sst_limout',phy_mpi)
554
555	CALL gather_omp(phy_bil, phy_mpi)
556	IF (is_omp_master) CALL xios_send_field('bils_limout',phy_mpi)
557
558	CALL gather_omp(phy_alb, phy_mpi)
559	IF (is_omp_master) CALL xios_send_field('alb_limout',phy_mpi)
560
561	CALL gather_omp(phy_rug, phy_mpi)
562	IF (is_omp_master) CALL xios_send_field('rug_limout',phy_mpi)
563	#endif
564	END SUBROUTINE writelim_unstruct
565
566
567
568	SUBROUTINE writelim(klon, phy_nat, phy_alb, phy_sst, phy_bil, phy_rug, &
569	phy_ice, phy_fter, phy_foce, phy_flic, phy_fsic)
570
571	USE mod_phys_lmdz_para, ONLY: is_master
572	USE mod_grid_phy_lmdz, ONLY: klon_glo
573	USE mod_phys_lmdz_transfert_para, ONLY: gather
574	USE phys_cal_mod, ONLY: year_len
575	use netcdf, only: nf90_def_var, nf90_double, nf90_float
576	IMPLICIT NONE
577	include "netcdf.inc"
578
579	INTEGER, INTENT (IN) :: klon
580	REAL, INTENT (IN) :: phy_nat(klon, year_len)
581	REAL, INTENT (IN) :: phy_alb(klon, year_len)
582	REAL, INTENT (IN) :: phy_sst(klon, year_len)
583	REAL, INTENT (IN) :: phy_bil(klon, year_len)
584	REAL, INTENT (IN) :: phy_rug(klon, year_len)
585	REAL, INTENT (IN) :: phy_ice(klon, year_len)
586	REAL, INTENT (IN) :: phy_fter(klon, year_len)
587	REAL, INTENT (IN) :: phy_foce(klon, year_len)
588	REAL, INTENT (IN) :: phy_flic(klon, year_len)
589	REAL, INTENT (IN) :: phy_fsic(klon, year_len)
590
591	REAL :: phy_glo(klon_glo, year_len) ! temporary variable, to store phy_***(:)
592	! on the whole physics grid
593	INTEGER :: k
594	INTEGER ierr
595	INTEGER dimfirst(3)
596	INTEGER dimlast(3)
597
598	INTEGER nid, ndim, ntim
599	INTEGER dims(2), debut(2), epais(2)
600	INTEGER id_tim
601	INTEGER id_nat, id_sst, id_bils, id_rug, id_alb
602	INTEGER id_fter, id_foce, id_fsic, id_flic
603
604	IF (is_master) THEN
605
606	PRINT *, 'writelim: Ecriture du fichier limit'
607
608	ierr = nf_create('limit.nc', IOR(NF_CLOBBER,NF_64BIT_OFFSET), nid)
609
610	ierr = nf_put_att_text(nid, nf_global, 'title', 30, &
611	'Fichier conditions aux limites')
612	! ! ierr = NF_DEF_DIM (nid, "points_physiques", klon, ndim)
613	ierr = nf_def_dim(nid, 'points_physiques', klon_glo, ndim)
614	ierr = nf_def_dim(nid, 'time', nf_unlimited, ntim)
615
616	dims(1) = ndim
617	dims(2) = ntim
618
619	#ifdef NC_DOUBLE
620	ierr = nf90_def_var(nid, 'TEMPS', nf90_double, [ntim], id_tim)
621	#else
622	ierr = nf90_def_var(nid, 'TEMPS', nf90_float, [ntim], id_tim)
623	#endif
624	ierr = nf_put_att_text(nid, id_tim, 'title', 17, 'Jour dans l annee')
625
626	#ifdef NC_DOUBLE
627	ierr = nf90_def_var(nid, 'NAT', nf90_double, dims, id_nat)
628	#else
629	ierr = nf90_def_var(nid, 'NAT', nf90_float, dims, id_nat)
630	#endif
631	ierr = nf_put_att_text(nid, id_nat, 'title', 23, &
632	'Nature du sol (0,1,2,3)')
633
634	#ifdef NC_DOUBLE
635	ierr = nf90_def_var(nid, 'SST', nf90_double, dims, id_sst)
636	#else
637	ierr = nf90_def_var(nid, 'SST', nf90_float, dims, id_sst)
638	#endif
639	ierr = nf_put_att_text(nid, id_sst, 'title', 35, &
640	'Temperature superficielle de la mer')
641
642	#ifdef NC_DOUBLE
643	ierr = nf90_def_var(nid, 'BILS', nf90_double, dims, id_bils)
644	#else
645	ierr = nf90_def_var(nid, 'BILS', nf90_float, dims, id_bils)
646	#endif
647	ierr = nf_put_att_text(nid, id_bils, 'title', 32, &
648	'Reference flux de chaleur au sol')
649
650	#ifdef NC_DOUBLE
651	ierr = nf90_def_var(nid, 'ALB', nf90_double, dims, id_alb)
652	#else
653	ierr = nf90_def_var(nid, 'ALB', nf90_float, dims, id_alb)
654	#endif
655	ierr = nf_put_att_text(nid, id_alb, 'title', 19, 'Albedo a la surface')
656
657	#ifdef NC_DOUBLE
658	ierr = nf90_def_var(nid, 'RUG', nf90_double, dims, id_rug)
659	#else
660	ierr = nf90_def_var(nid, 'RUG', nf90_float, dims, id_rug)
661	#endif
662	ierr = nf_put_att_text(nid, id_rug, 'title', 8, 'Rugosite')
663
664	#ifdef NC_DOUBLE
665	ierr = nf90_def_var(nid, 'FTER', nf90_double, dims, id_fter)
666	#else
667	ierr = nf90_def_var(nid, 'FTER', nf90_float, dims, id_fter)
668	#endif
669	ierr = nf_put_att_text(nid, id_fter, 'title',10,'Frac. Land')
670	#ifdef NC_DOUBLE
671	ierr = nf90_def_var(nid, 'FOCE', nf90_double, dims, id_foce)
672	#else
673	ierr = nf90_def_var(nid, 'FOCE', nf90_float, dims, id_foce)
674	#endif
675	ierr = nf_put_att_text(nid, id_foce, 'title',11,'Frac. Ocean')
676	#ifdef NC_DOUBLE
677	ierr = nf90_def_var(nid, 'FSIC', nf90_double, dims, id_fsic)
678	#else
679	ierr = nf90_def_var(nid, 'FSIC', nf90_float, dims, id_fsic)
680	#endif
681	ierr = nf_put_att_text(nid, id_fsic, 'title',13,'Frac. Sea Ice')
682	#ifdef NC_DOUBLE
683	ierr = nf90_def_var(nid, 'FLIC', nf90_double, dims, id_flic)
684	#else
685	ierr = nf90_def_var(nid, 'FLIC', nf90_float, dims, id_flic)
686	#endif
687	ierr = nf_put_att_text(nid, id_flic, 'title',14,'Frac. Land Ice')
688
689	ierr = nf_enddef(nid)
690	IF (ierr/=nf_noerr) THEN
691	WRITE (, ) 'writelim error: failed to end define mode'
692	WRITE (, ) nf_strerror(ierr)
693	END IF
694
695
696	! write the 'times'
697	DO k = 1, year_len
698	#ifdef NC_DOUBLE
699	ierr = nf_put_var1_double(nid, id_tim, k, dble(k))
700	#else
701	ierr = nf_put_var1_real(nid, id_tim, k, float(k))
702	#endif
703	IF (ierr/=nf_noerr) THEN
704	WRITE (, ) 'writelim error with temps(k),k=', k
705	WRITE (, ) nf_strerror(ierr)
706	END IF
707	END DO
708
709	END IF ! of if (is_master)
710
711	! write the fields, after having collected them on master
712
713	CALL gather(phy_nat, phy_glo)
714	IF (is_master) THEN
715	#ifdef NC_DOUBLE
716	ierr = nf_put_var_double(nid, id_nat, phy_glo)
717	#else
718	ierr = nf_put_var_real(nid, id_nat, phy_glo)
719	#endif
720	IF (ierr/=nf_noerr) THEN
721	WRITE (, ) 'writelim error with phy_nat'
722	WRITE (, ) nf_strerror(ierr)
723	END IF
724	END IF
725
726	CALL gather(phy_sst, phy_glo)
727	IF (is_master) THEN
728	#ifdef NC_DOUBLE
729	ierr = nf_put_var_double(nid, id_sst, phy_glo)
730	#else
731	ierr = nf_put_var_real(nid, id_sst, phy_glo)
732	#endif
733	IF (ierr/=nf_noerr) THEN
734	WRITE (, ) 'writelim error with phy_sst'
735	WRITE (, ) nf_strerror(ierr)
736	END IF
737	END IF
738
739	CALL gather(phy_bil, phy_glo)
740	IF (is_master) THEN
741	#ifdef NC_DOUBLE
742	ierr = nf_put_var_double(nid, id_bils, phy_glo)
743	#else
744	ierr = nf_put_var_real(nid, id_bils, phy_glo)
745	#endif
746	IF (ierr/=nf_noerr) THEN
747	WRITE (, ) 'writelim error with phy_bil'
748	WRITE (, ) nf_strerror(ierr)
749	END IF
750	END IF
751
752	CALL gather(phy_alb, phy_glo)
753	IF (is_master) THEN
754	#ifdef NC_DOUBLE
755	ierr = nf_put_var_double(nid, id_alb, phy_glo)
756	#else
757	ierr = nf_put_var_real(nid, id_alb, phy_glo)
758	#endif
759	IF (ierr/=nf_noerr) THEN
760	WRITE (, ) 'writelim error with phy_alb'
761	WRITE (, ) nf_strerror(ierr)
762	END IF
763	END IF
764
765	CALL gather(phy_rug, phy_glo)
766	IF (is_master) THEN
767	#ifdef NC_DOUBLE
768	ierr = nf_put_var_double(nid, id_rug, phy_glo)
769	#else
770	ierr = nf_put_var_real(nid, id_rug, phy_glo)
771	#endif
772	IF (ierr/=nf_noerr) THEN
773	WRITE (, ) 'writelim error with phy_rug'
774	WRITE (, ) nf_strerror(ierr)
775	END IF
776	END IF
777
778	CALL gather(phy_fter, phy_glo)
779	IF (is_master) THEN
780	#ifdef NC_DOUBLE
781	ierr = nf_put_var_double(nid, id_fter, phy_glo)
782	#else
783	ierr = nf_put_var_real(nid, id_fter, phy_glo)
784	#endif
785	IF (ierr/=nf_noerr) THEN
786	WRITE (, ) 'writelim error with phy_fter'
787	WRITE (, ) nf_strerror(ierr)
788	END IF
789	END IF
790
791	CALL gather(phy_foce, phy_glo)
792	IF (is_master) THEN
793	#ifdef NC_DOUBLE
794	ierr = nf_put_var_double(nid, id_foce, phy_glo)
795	#else
796	ierr = nf_put_var_real(nid, id_foce, phy_glo)
797	#endif
798	IF (ierr/=nf_noerr) THEN
799	WRITE (, ) 'writelim error with phy_foce'
800	WRITE (, ) nf_strerror(ierr)
801	END IF
802	END IF
803
804	CALL gather(phy_fsic, phy_glo)
805	IF (is_master) THEN
806	#ifdef NC_DOUBLE
807	ierr = nf_put_var_double(nid, id_fsic, phy_glo)
808	#else
809	ierr = nf_put_var_real(nid, id_fsic, phy_glo)
810	#endif
811	IF (ierr/=nf_noerr) THEN
812	WRITE (, ) 'writelim error with phy_fsic'
813	WRITE (, ) nf_strerror(ierr)
814	END IF
815	END IF
816
817	CALL gather(phy_flic, phy_glo)
818	IF (is_master) THEN
819	#ifdef NC_DOUBLE
820	ierr = nf_put_var_double(nid, id_flic, phy_glo)
821	#else
822	ierr = nf_put_var_real(nid, id_flic, phy_glo)
823	#endif
824	IF (ierr/=nf_noerr) THEN
825	WRITE (, ) 'writelim error with phy_flic'
826	WRITE (, ) nf_strerror(ierr)
827	END IF
828	END IF
829
830	! close file:
831	IF (is_master) THEN
832	ierr = nf_close(nid)
833	END IF
834
835	END SUBROUTINE writelim
836
837	! !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
838
839	SUBROUTINE profil_sst(nlon, rlatd, type_profil, phy_sst)
840	USE dimphy
841	USE phys_cal_mod , ONLY: year_len
842	IMPLICIT NONE
843
844	INTEGER nlon, type_profil, i, k, j
845	REAL :: rlatd(nlon), phy_sst(nlon, year_len)
846	INTEGER imn, imx, amn, amx, kmn, kmx
847	INTEGER p, pplus, nlat_max
848	PARAMETER (nlat_max=72)
849	REAL x_anom_sst(nlat_max)
850	CHARACTER (LEN=20) :: modname='profil_sst'
851	CHARACTER (LEN=80) :: abort_message
852
853	IF (klon/=nlon) THEN
854	abort_message='probleme de dimensions dans profil_sst'
855	CALL abort_physic(modname,abort_message,1)
856	ENDIF
857	WRITE (, ) ' profil_sst: type_profil=', type_profil
858	DO i = 1, year_len
859	! phy_sst(:,i) = 260.+50.cos(rlatd(:))*2
860
861	! Rajout fbrlmd
862
863	IF (type_profil==1) THEN
864	! Méthode 1 "Control" faible plateau à l'Equateur
865	DO j = 1, klon
866	phy_sst(j, i) = 273. + 27.(1-sin(1.5rlatd(j))**2)
867	! PI/3=1.047197551
868	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
869	phy_sst(j, i) = 273.
870	END IF
871	END DO
872	END IF
873	IF (type_profil==2) THEN
874	! Méthode 2 "Flat" fort plateau à l'Equateur
875	DO j = 1, klon
876	phy_sst(j, i) = 273. + 27.(1-sin(1.5rlatd(j))**4)
877	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
878	phy_sst(j, i) = 273.
879	END IF
880	END DO
881	END IF
882
883
884	IF (type_profil==3) THEN
885	! Méthode 3 "Qobs" plateau réel à l'Equateur
886	DO j = 1, klon
887	phy_sst(j, i) = 273. + 0.527.(2-sin(1.5rlatd(j))2-sin(1.5 &
888	rlatd(j))**4)
889	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
890	phy_sst(j, i) = 273.
891	END IF
892	END DO
893	END IF
894
895	IF (type_profil==4) THEN
896	! Méthode 4 : Méthode 3 + SST+2 "Qobs" plateau réel à l'Equateur
897	DO j = 1, klon
898	phy_sst(j, i) = 273. + 0.529.(2-sin(1.5rlatd(j))2-sin(1.5 &
899	rlatd(j))**4)
900	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
901	phy_sst(j, i) = 273.
902	END IF
903	END DO
904	END IF
905
906	IF (type_profil==5) THEN
907	! Méthode 5 : Méthode 3 + +2K "Qobs" plateau réel à l'Equateur
908	DO j = 1, klon
909	phy_sst(j, i) = 273. + 2. + 0.527.(2-sin(1.5rlatd(j))*2-sin(1.5 &
910	rlatd(j))*4)
911	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
912	phy_sst(j, i) = 273. + 2.
913	END IF
914
915	END DO
916	END IF
917
918	IF (type_profil==6) THEN
919	! Méthode 6 "cst" valeur constante de SST
920	DO j = 1, klon
921	phy_sst(j, i) = 288.
922	END DO
923	END IF
924
925
926	IF (type_profil==7) THEN
927	! Méthode 7 "cst" valeur constante de SST +2
928	DO j = 1, klon
929	phy_sst(j, i) = 288. + 2.
930	END DO
931	END IF
932
933	p = 0
934	IF (type_profil==8) THEN
935	! Méthode 8 profil anomalies SST du modèle couplé AR4
936	DO j = 1, klon
937	IF (rlatd(j)==rlatd(j-1)) THEN
938	phy_sst(j, i) = 273. + x_anom_sst(pplus) + &
939	0.527.(2-sin(1.5rlatd(j))2-sin(1.5rlatd(j))**4)
940	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
941	phy_sst(j, i) = 273. + x_anom_sst(pplus)
942	END IF
943	ELSE
944	p = p + 1
945	pplus = 73 - p
946	phy_sst(j, i) = 273. + x_anom_sst(pplus) + &
947	0.527.(2-sin(1.5rlatd(j))2-sin(1.5rlatd(j))**4)
948	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
949	phy_sst(j, i) = 273. + x_anom_sst(pplus)
950	END IF
951	WRITE (, ) rlatd(j), x_anom_sst(pplus), phy_sst(j, i)
952	END IF
953	END DO
954	END IF
955
956	IF (type_profil==9) THEN
957	! Méthode 5 : Méthode 3 + -2K "Qobs" plateau réel à l'Equateur
958	DO j = 1, klon
959	phy_sst(j, i) = 273. - 2. + 0.527.(2-sin(1.5rlatd(j))*2-sin(1.5 &
960	rlatd(j))*4)
961	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
962	phy_sst(j, i) = 273. - 2.
963	END IF
964	END DO
965	END IF
966
967
968	IF (type_profil==10) THEN
969	! Méthode 10 : Méthode 3 + +4K "Qobs" plateau réel à l'Equateur
970	DO j = 1, klon
971	phy_sst(j, i) = 273. + 4. + 0.527.(2-sin(1.5rlatd(j))*2-sin(1.5 &
972	rlatd(j))*4)
973	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
974	phy_sst(j, i) = 273. + 4.
975	END IF
976	END DO
977	END IF
978
979	IF (type_profil==11) THEN
980	! Méthode 11 : Méthode 3 + 4CO2 "Qobs" plateau réel à l'Equateur
981	DO j = 1, klon
982	phy_sst(j, i) = 273. + 0.527.(2-sin(1.5rlatd(j))2-sin(1.5 &
983	rlatd(j))**4)
984	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
985	phy_sst(j, i) = 273.
986	END IF
987	END DO
988	END IF
989
990	IF (type_profil==12) THEN
991	! Méthode 12 : Méthode 10 + 4CO2 "Qobs" plateau réel à l'Equateur
992	DO j = 1, klon
993	phy_sst(j, i) = 273. + 4. + 0.527.(2-sin(1.5rlatd(j))*2-sin(1.5 &
994	rlatd(j))*4)
995	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
996	phy_sst(j, i) = 273. + 4.
997	END IF
998	END DO
999	END IF
1000
1001	IF (type_profil==13) THEN
1002	! Méthode 13 "Qmax" plateau réel à l'Equateur augmenté !
1003	DO j = 1, klon
1004	phy_sst(j, i) = 273. + 0.529.(2-sin(1.5rlatd(j))2-sin(1.5 &
1005	rlatd(j))**4)
1006	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
1007	phy_sst(j, i) = 273.
1008	END IF
1009	END DO
1010	END IF
1011
1012	IF (type_profil==14) THEN
1013	! Méthode 13 "Qmax2K" plateau réel à l'Equateur augmenté +2K !
1014	DO j = 1, klon
1015	phy_sst(j, i) = 273. + 2. + 0.529.(2-sin(1.5rlatd(j))*2-sin(1.5 &
1016	rlatd(j))*4)
1017	IF ((rlatd(j)>1.0471975) .OR. (rlatd(j)<-1.0471975)) THEN
1018	phy_sst(j, i) = 273.
1019	END IF
1020	END DO
1021	END IF
1022
1023	if (type_profil.EQ.20) then
1024	print*,'Profile SST 20'
1025	! Méthode 13 "Qmax2K" plateau réel �\| l'Equateur augmenté +2K
1026
1027	do j=1,klon
1028	phy_sst(j,i)=248.+55.(1-sin(rlatd(j))*2)
1029	enddo
1030	endif
1031
1032	if (type_profil.EQ.21) then
1033	print*,'Profile SST 21'
1034	! Méthode 13 "Qmax2K" plateau réel �\| l'Equateur augmenté +2K
1035	do j=1,klon
1036	phy_sst(j,i)=252.+55.(1-sin(rlatd(j))*2)
1037	enddo
1038	endif
1039
1040
1041
1042	END DO
1043
1044	! IM beg : verif profil SST: phy_sst
1045	amn = min(phy_sst(1,1), 1000.)
1046	amx = max(phy_sst(1,1), -1000.)
1047	imn = 1
1048	kmn = 1
1049	imx = 1
1050	kmx = 1
1051	DO k = 1, year_len
1052	DO i = 2, nlon
1053	IF (phy_sst(i,k)<amn) THEN
1054	amn = phy_sst(i, k)
1055	imn = i
1056	kmn = k
1057	END IF
1058	IF (phy_sst(i,k)>amx) THEN
1059	amx = phy_sst(i, k)
1060	imx = i
1061	kmx = k
1062	END IF
1063	END DO
1064	END DO
1065
1066	PRINT *, 'profil_sst: imn, kmn, phy_sst(imn,kmn) ', imn, kmn, amn
1067	PRINT *, 'profil_sst: imx, kmx, phy_sst(imx,kmx) ', imx, kmx, amx
1068	! IM end : verif profil SST: phy_sst
1069
1070	RETURN
1071	END SUBROUTINE profil_sst
1072
1073	END MODULE phyaqua_mod

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