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lmdz_scm.F90 @ 5144

Last change on this file since 5144 was 5144, checked in by abarral, 7 weeks ago
Put YOMCST.h into modules
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1	MODULE lmdz_scm
2	PRIVATE ! -- We'd love to put IMPLICIT NONE; here...
3	PUBLIC scm
4	CONTAINS
5	SUBROUTINE scm
6	USE ioipsl, ONLY: ju2ymds, ymds2ju, ioconf_calendar, getin
7	USE phys_state_var_mod, ONLY: phys_state_var_init, phys_state_var_end, &
8	clwcon, detr_therm, &
9	qsol, fevap, z0m, z0h, agesno, &
10	du_gwd_rando, du_gwd_front, entr_therm, f0, fm_therm, &
11	falb_dir, falb_dif, &
12	ftsol, beta_aridity, pbl_tke, pctsrf, radsol, rain_fall, snow_fall, ratqs, &
13	rnebcon, rugoro, sig1, w01, solaire_etat0, sollw, sollwdown, &
14	solsw, solswfdiff, t_ancien, q_ancien, u_ancien, v_ancien, rneb_ancien, &
15	wake_delta_pbl_TKE, delta_tsurf, wake_fip, wake_pe, &
16	wake_deltaq, wake_deltat, wake_s, awake_s, wake_dens, &
17	awake_dens, cv_gen, wake_cstar, &
18	zgam, zmax0, zmea, zpic, zsig, &
19	zstd, zthe, zval, ale_bl, ale_bl_trig, alp_bl, ql_ancien, qs_ancien, &
20	prlw_ancien, prsw_ancien, prw_ancien, &
21	u10m, v10m, ale_wake, ale_bl_stat, ratqs_inter_
22
23	USE dimphy
24	USE surface_data, ONLY: type_ocean, ok_veget
25	USE pbl_surface_mod, ONLY: ftsoil, pbl_surface_init, &
26	pbl_surface_final
27	USE fonte_neige_mod, ONLY: fonte_neige_init, fonte_neige_final
28
29	USE infotrac
30	USE control_mod
31	USE indice_sol_mod
32	USE phyaqua_mod
33	USE mod_1D_cases_read_std
34	USE lmdz_print_control, ONLY: lunout, prt_level
35	USE iniphysiq_mod, ONLY: iniphysiq
36	USE mod_const_mpi, ONLY: comm_lmdz
37	USE physiq_mod, ONLY: physiq
38	USE comvert_mod, ONLY: presnivs, ap, bp, dpres, nivsig, nivsigs, pa, &
39	preff, aps, bps, pseudoalt, scaleheight
40	USE temps_mod, ONLY: annee_ref, calend, day_end, day_ini, day_ref, &
41	itau_dyn, itau_phy, start_time, year_len
42	USE phys_cal_mod, ONLY: year_len_phys_cal_mod => year_len
43	USE lmdz_1dutils, ONLY: fq_sat, conf_unicol, dyn1deta0, dyn1dredem, disvert0
44
45	USE lmdz_cppkeys_wrapper, ONLY: CPPKEY_OUTPUTPHYSSCM
46	USE lmdz_clesphys
47	USE lmdz_flux_arp, ONLY: fsens, flat, betaevap, ust, tg, ok_flux_surf, ok_prescr_ust, ok_prescr_beta, ok_forc_tsurf
48	USE lmdz_compbl, ONLY: iflag_pbl, iflag_pbl_split, iflag_order2_sollw, ifl_pbltree
49	USE lmdz_fcs_gcssold, ONLY: imp_fcg_gcssold, ts_fcg_gcssold, Tp_fcg_gcssold, Tp_ini_gcssold, xTurb_fcg_gcssold
50	USE lmdz_tsoilnudge, ONLY: nudge_tsoil, isoil_nudge, Tsoil_nudge, tau_soil_nudge
51	USE lmdz_yomcst
52
53	INCLUDE "dimensions.h"
54	INCLUDE "dimsoil.h"
55	INCLUDE "compar1d.h"
56	INCLUDE "date_cas.h"
57
58	!=====================================================================
59	! DECLARATIONS
60	!=====================================================================
61
62	!---------------------------------------------------------------------
63	! Arguments d' initialisations de la physique (USER DEFINE)
64	!---------------------------------------------------------------------
65
66	INTEGER, parameter :: ngrid = 1
67	REAL :: zcufi = 1.
68	REAL :: zcvfi = 1.
69	REAL :: fnday
70	REAL :: day, daytime
71	REAL :: day1
72	REAL :: heure
73	INTEGER :: jour
74	INTEGER :: mois
75	INTEGER :: an
76
77	!---------------------------------------------------------------------
78	! Declarations related to forcing and initial profiles
79	!---------------------------------------------------------------------
80
81	INTEGER :: kmax = llm
82	INTEGER llm700, nq1, nq2
83	INTEGER, PARAMETER :: nlev_max = 1000, nqmx = 1000
84	REAL timestep, frac
85	REAL height(nlev_max), tttprof(nlev_max), qtprof(nlev_max)
86	real uprof(nlev_max), vprof(nlev_max), e12prof(nlev_max)
87	real ugprof(nlev_max), vgprof(nlev_max), wfls(nlev_max)
88	real dqtdxls(nlev_max), dqtdyls(nlev_max)
89	real dqtdtls(nlev_max), thlpcar(nlev_max)
90	real qprof(nlev_max, nqmx)
91
92	! INTEGER :: forcing_type
93	LOGICAL :: forcing_les = .FALSE.
94	LOGICAL :: forcing_armcu = .FALSE.
95	LOGICAL :: forcing_rico = .FALSE.
96	LOGICAL :: forcing_radconv = .FALSE.
97	LOGICAL :: forcing_toga = .FALSE.
98	LOGICAL :: forcing_twpice = .FALSE.
99	LOGICAL :: forcing_amma = .FALSE.
100	LOGICAL :: forcing_dice = .FALSE.
101	LOGICAL :: forcing_gabls4 = .FALSE.
102
103	LOGICAL :: forcing_GCM2SCM = .FALSE.
104	LOGICAL :: forcing_GCSSold = .FALSE.
105	LOGICAL :: forcing_sandu = .FALSE.
106	LOGICAL :: forcing_astex = .FALSE.
107	LOGICAL :: forcing_fire = .FALSE.
108	LOGICAL :: forcing_case = .FALSE.
109	LOGICAL :: forcing_case2 = .FALSE.
110	LOGICAL :: forcing_SCM = .FALSE.
111
112	!flag forcings
113	LOGICAL :: nudge_wind = .TRUE.
114	LOGICAL :: nudge_thermo = .FALSE.
115	LOGICAL :: cptadvw = .TRUE.
116
117
118	!=====================================================================
119	! DECLARATIONS FOR EACH CASE
120	!=====================================================================
121
122	INCLUDE "1D_decl_cases.h"
123
124	!---------------------------------------------------------------------
125	! Declarations related to nudging
126	!---------------------------------------------------------------------
127	INTEGER :: nudge_max
128	parameter (nudge_max = 9)
129	INTEGER :: inudge_RHT = 1
130	INTEGER :: inudge_UV = 2
131	LOGICAL :: nudge(nudge_max)
132	REAL :: t_targ(llm)
133	REAL :: rh_targ(llm)
134	REAL :: u_targ(llm)
135	REAL :: v_targ(llm)
136
137	!---------------------------------------------------------------------
138	! Declarations related to vertical discretization:
139	!---------------------------------------------------------------------
140	REAL :: pzero = 1.e5
141	REAL :: play (llm), zlay (llm), sig_s(llm), plev(llm + 1)
142	REAL :: playd(llm), zlayd(llm), ap_amma(llm + 1), bp_amma(llm + 1)
143
144	!---------------------------------------------------------------------
145	! Declarations related to variables
146	!---------------------------------------------------------------------
147
148	REAL :: phi(llm)
149	REAL :: teta(llm), tetal(llm), temp(llm), u(llm), v(llm), w(llm)
150	REAL rot(1, llm) ! relative vorticity, in s-1
151	REAL :: rlat_rad(1), rlon_rad(1)
152	REAL :: omega(llm), omega2(llm), rho(llm + 1)
153	REAL :: ug(llm), vg(llm), fcoriolis
154	REAL :: sfdt, cfdt
155	REAL :: du_phys(llm), dv_phys(llm), dt_phys(llm)
156	REAL :: w_adv(llm), z_adv(llm)
157	REAL :: d_t_vert_adv(llm), d_u_vert_adv(llm), d_v_vert_adv(llm)
158	REAL :: dt_cooling(llm), d_t_adv(llm), d_t_nudge(llm)
159	REAL :: d_u_nudge(llm), d_v_nudge(llm)
160	! REAL :: d_u_adv(llm),d_v_adv(llm)
161	REAL :: d_u_age(llm), d_v_age(llm)
162	REAL :: alpha
163	REAL :: ttt
164
165	REAL, ALLOCATABLE, DIMENSION(:, :) :: q
166	REAL, ALLOCATABLE, DIMENSION(:, :) :: dq
167	REAL, ALLOCATABLE, DIMENSION(:, :) :: d_q_vert_adv
168	REAL, ALLOCATABLE, DIMENSION(:, :) :: d_q_adv
169	REAL, ALLOCATABLE, DIMENSION(:, :) :: d_q_nudge
170	! REAL, ALLOCATABLE, DIMENSION(:):: d_th_adv
171
172	!---------------------------------------------------------------------
173	! Initialization of surface variables
174	!---------------------------------------------------------------------
175	REAL :: run_off_lic_0(1)
176	REAL :: fder(1), snsrf(1, nbsrf), qsurfsrf(1, nbsrf)
177	REAL :: tsoil(1, nsoilmx, nbsrf)
178	! REAL :: agesno(1,nbsrf)
179
180	!---------------------------------------------------------------------
181	! Call to phyredem
182	!---------------------------------------------------------------------
183	LOGICAL :: ok_writedem = .TRUE.
184	REAL :: sollw_in = 0.
185	REAL :: solsw_in = 0.
186
187	!---------------------------------------------------------------------
188	! Call to physiq
189	!---------------------------------------------------------------------
190	LOGICAL :: firstcall = .TRUE.
191	LOGICAL :: lastcall = .FALSE.
192	REAL :: phis(1) = 0.0
193	REAL :: dpsrf(1)
194
195	!---------------------------------------------------------------------
196	! Initializations of boundary conditions
197	!---------------------------------------------------------------------
198	REAL, ALLOCATABLE :: phy_nat (:) ! 0=ocean libre,1=land,2=glacier,3=banquise
199	REAL, ALLOCATABLE :: phy_alb (:) ! Albedo land only (old value condsurf_jyg=0.3)
200	REAL, ALLOCATABLE :: phy_sst (:) ! SST (will not be used; cf read_tsurf1d.F)
201	REAL, ALLOCATABLE :: phy_bil (:) ! Ne sert que pour les slab_ocean
202	REAL, ALLOCATABLE :: phy_rug (:) ! Longueur rugosite utilisee sur land only
203	REAL, ALLOCATABLE :: phy_ice (:) ! Fraction de glace
204	REAL, ALLOCATABLE :: phy_fter(:) ! Fraction de terre
205	REAL, ALLOCATABLE :: phy_foce(:) ! Fraction de ocean
206	REAL, ALLOCATABLE :: phy_fsic(:) ! Fraction de glace
207	REAL, ALLOCATABLE :: phy_flic(:) ! Fraction de glace
208
209	!---------------------------------------------------------------------
210	! Fichiers et d'autres variables
211	!---------------------------------------------------------------------
212	INTEGER :: k, l, i, it = 1, mxcalc
213	INTEGER :: nsrf
214	INTEGER jcode
215	INTEGER read_climoz
216
217	INTEGER :: it_end ! iteration number of the last call
218	!Al1,plev,play,phi,phis,presnivs,
219	INTEGER ecrit_slab_oc !1=ecrit,-1=lit,0=no file
220	data ecrit_slab_oc/-1/
221
222	! if flag_inhib_forcing = 0, tendencies of forcing are added
223	! <> 0, tendencies of forcing are not added
224	INTEGER :: flag_inhib_forcing = 0
225
226	PRINT*, 'VOUS ENTREZ DANS LE 1D FORMAT STANDARD'
227
228	!=====================================================================
229	! INITIALIZATIONS
230	!=====================================================================
231	du_phys(:) = 0.
232	dv_phys(:) = 0.
233	dt_phys(:) = 0.
234	d_t_vert_adv(:) = 0.
235	d_u_vert_adv(:) = 0.
236	d_v_vert_adv(:) = 0.
237	dt_cooling(:) = 0.
238	d_t_adv(:) = 0.
239	d_t_nudge(:) = 0.
240	d_u_nudge(:) = 0.
241	d_v_nudge(:) = 0.
242	d_u_adv(:) = 0.
243	d_v_adv(:) = 0.
244	d_u_age(:) = 0.
245	d_v_age(:) = 0.
246
247
248	! Initialization of Common turb_forcing
249	dtime_frcg = 0.
250	Turb_fcg_gcssold = .FALSE.
251	hthturb_gcssold = 0.
252	hqturb_gcssold = 0.
253
254
255
256
257	!---------------------------------------------------------------------
258	! OPTIONS OF THE 1D SIMULATION (lmdz1d.def => unicol.def)
259	!---------------------------------------------------------------------
260	CALL conf_unicol
261	!Al1 moves this gcssold var from common fcg_gcssold to
262	Turb_fcg_gcssold = xTurb_fcg_gcssold
263	! --------------------------------------------------------------------
264	close(1)
265	WRITE(, ) 'lmdz1d.def lu => unicol.def'
266
267	forcing_SCM = .TRUE.
268	year_ini_cas = 1997
269	! It is possible that those parameters are run twice.
270	! A REVOIR : LIRE PEUT ETRE AN MOIS JOUR DIRECETEMENT
271
272	CALL getin('anneeref', year_ini_cas)
273	CALL getin('dayref', day_deb)
274	mth_ini_cas = 1 ! pour le moment on compte depuis le debut de l'annee
275	CALL getin('time_ini', heure_ini_cas)
276
277	PRINT*, 'NATURE DE LA SURFACE ', nat_surf
278
279	! Initialization of the LOGICAL switch for nudging
280
281	jcode = iflag_nudge
282	do i = 1, nudge_max
283	nudge(i) = mod(jcode, 10) >= 1
284	jcode = jcode / 10
285	enddo
286	!-----------------------------------------------------------------------
287	! Definition of the run
288	!-----------------------------------------------------------------------
289
290	CALL conf_gcm(99, .TRUE.)
291
292	!-----------------------------------------------------------------------
293	allocate(phy_nat (year_len)) ! 0=ocean libre,1=land,2=glacier,3=banquise
294	phy_nat(:) = 0.0
295	allocate(phy_alb (year_len)) ! Albedo land only (old value condsurf_jyg=0.3)
296	allocate(phy_sst (year_len)) ! SST (will not be used; cf read_tsurf1d.F)
297	allocate(phy_bil (year_len)) ! Ne sert que pour les slab_ocean
298	phy_bil(:) = 1.0
299	allocate(phy_rug (year_len)) ! Longueur rugosite utilisee sur land only
300	allocate(phy_ice (year_len)) ! Fraction de glace
301	phy_ice(:) = 0.0
302	allocate(phy_fter(year_len)) ! Fraction de terre
303	phy_fter(:) = 0.0
304	allocate(phy_foce(year_len)) ! Fraction de ocean
305	phy_foce(:) = 0.0
306	allocate(phy_fsic(year_len)) ! Fraction de glace
307	phy_fsic(:) = 0.0
308	allocate(phy_flic(year_len)) ! Fraction de glace
309	phy_flic(:) = 0.0
310
311
312	!-----------------------------------------------------------------------
313	! Choix du calendrier
314	! -------------------
315
316	! calend = 'earth_365d'
317	IF (calend == 'earth_360d') THEN
318	CALL ioconf_calendar('360_day')
319	WRITE(, )'CALENDRIER CHOISI: Terrestre a 360 jours/an'
320	ELSE IF (calend == 'earth_365d') THEN
321	CALL ioconf_calendar('noleap')
322	WRITE(, )'CALENDRIER CHOISI: Terrestre a 365 jours/an'
323	ELSE IF (calend == 'earth_366d') THEN
324	CALL ioconf_calendar('all_leap')
325	WRITE(, )'CALENDRIER CHOISI: Terrestre bissextile'
326	ELSE IF (calend == 'gregorian') THEN
327	stop 'gregorian calend should not be used by normal user'
328	CALL ioconf_calendar('gregorian') ! not to be used by normal users
329	WRITE(, )'CALENDRIER CHOISI: Gregorien'
330	else
331	write (, ) 'ERROR : unknown calendar ', calend
332	stop 'calend should be 360d,earth_365d,earth_366d,gregorian'
333	endif
334	!-----------------------------------------------------------------------
335
336	!c Date :
337	! La date est supposee donnee sous la forme [annee, numero du jour dans
338	! l annee] ; l heure est donnee dans time_ini, lu dans lmdz1d.def.
339	! On appelle ymds2ju pour convertir [annee, jour] en [jour Julien].
340	! Le numero du jour est dans "day". L heure est traitee separement.
341	! La date complete est dans "daytime" (l'unite est le jour).
342
343	IF (nday>0) THEN
344	fnday = nday
345	else
346	fnday = -nday / float(day_step)
347	endif
348	print *, 'fnday=', fnday
349	! start_time doit etre en FRACTION DE JOUR
350	start_time = time_ini / 24.
351
352	annee_ref = anneeref
353	mois = 1
354	day_ref = dayref
355	heure = 0.
356	itau_dyn = 0
357	itau_phy = 0
358	CALL ymds2ju(annee_ref, mois, day_ref, heure, day)
359	day_ini = int(day)
360	day_end = day_ini + int(fnday)
361
362	! Convert the initial date to Julian day
363	day_ini_cas = day_deb
364	PRINT*, 'time case', year_ini_cas, mth_ini_cas, day_ini_cas
365	CALL ymds2ju &
366	(year_ini_cas, mth_ini_cas, day_ini_cas, heure_ini_cas * 3600 &
367	, day_ju_ini_cas)
368	PRINT*, 'time case 2', day_ini_cas, day_ju_ini_cas
369	daytime = day + heure_ini_cas / 24. ! 1st day and initial time of the simulation
370
371	! Print out the actual date of the beginning of the simulation :
372	CALL ju2ymds(daytime, year_print, month_print, day_print, sec_print)
373	print *, ' Time of beginning : ', &
374	year_print, month_print, day_print, sec_print
375
376	!---------------------------------------------------------------------
377	! Initialization of dimensions, geometry and initial state
378	!---------------------------------------------------------------------
379	! CALL init_phys_lmdz(1,1,llm,1,(/1/)) ! job now done via iniphysiq
380	! but we still need to initialize dimphy module (klon,klev,etc.) here.
381	CALL init_dimphy1D(1, llm)
382	CALL suphel
383	CALL init_infotrac
384
385	IF (nqtot>nqmx) STOP 'Augmenter nqmx dans lmdz1d.F'
386	allocate(q(llm, nqtot)) ; q(:, :) = 0.
387	allocate(dq(llm, nqtot))
388	allocate(d_q_vert_adv(llm, nqtot))
389	allocate(d_q_adv(llm, nqtot))
390	allocate(d_q_nudge(llm, nqtot))
391	! allocate(d_th_adv(llm))
392
393	q(:, :) = 0.
394	dq(:, :) = 0.
395	d_q_vert_adv(:, :) = 0.
396	d_q_adv(:, :) = 0.
397	d_q_nudge(:, :) = 0.
398
399	! No ozone climatology need be read in this pre-initialization
400	! (phys_state_var_init is called again in physiq)
401	read_climoz = 0
402	nsw = 6
403
404	CALL phys_state_var_init(read_climoz)
405
406	IF (ngrid/=klon) THEN
407	PRINT*, 'stop in inifis'
408	PRINT*, 'Probleme de dimensions :'
409	PRINT*, 'ngrid = ', ngrid
410	PRINT*, 'klon = ', klon
411	stop
412	endif
413	!!!=====================================================================
414	!!! Feedback forcing values for Gateaux differentiation (al1)
415	!!!=====================================================================
416	!!
417	qsol = qsolinp
418	qsurf = fq_sat(tsurf, psurf / 100.)
419	beta_aridity(:, :) = beta_surf
420	day1 = day_ini
421	time = daytime - day
422	ts_toga(1) = tsurf ! needed by read_tsurf1d.F
423	rho(1) = psurf / (rd * tsurf * (1. + (rv / rd - 1.) * qsurf))
424
425	!! mpl et jyg le 22/08/2012 :
426	!! pour que les cas a flux de surface imposes marchent
427	IF(.NOT.ok_flux_surf.OR.max(abs(wtsurf), abs(wqsurf))>0.) THEN
428	fsens = -wtsurf * rcpd * rho(1)
429	flat = -wqsurf * rlvtt * rho(1)
430	print *, 'Flux: ok_flux wtsurf wqsurf', ok_flux_surf, wtsurf, wqsurf
431	ENDIF
432	PRINT*, 'Flux sol ', fsens, flat
433
434	! Vertical discretization and pressure levels at half and mid levels:
435
436	pa = 5e4
437	!! preff= 1.01325e5
438	preff = psurf
439	IF (ok_old_disvert) THEN
440	CALL disvert0(pa, preff, ap, bp, dpres, presnivs, nivsigs, nivsig)
441	print *, 'On utilise disvert0'
442	aps(1:llm) = 0.5 * (ap(1:llm) + ap(2:llm + 1))
443	bps(1:llm) = 0.5 * (bp(1:llm) + bp(2:llm + 1))
444	scaleheight = 8.
445	pseudoalt(1:llm) = -scaleheight * log(presnivs(1:llm) / preff)
446	ELSE
447	CALL disvert()
448	print *, 'On utilise disvert'
449	! Nouvelle version disvert permettant d imposer ap,bp (modif L.Guez) MPL 18092012
450	! Dans ce cas, on lit ap,bp dans le fichier hybrid.txt
451	ENDIF
452
453	sig_s = presnivs / preff
454	plev = ap + bp * psurf
455	play = 0.5 * (plev(1:llm) + plev(2:llm + 1))
456	zlay = -rd * 300. * log(play / psurf) / rg ! moved after reading profiles.
457
458	IF (forcing_type == 59) THEN
459	! pour forcing_sandu, on cherche l'indice le plus proche de 700hpa#3000m
460	WRITE(, ) '***********************'
461	do l = 1, llm
462	WRITE(, ) 'l,play(l),presnivs(l): ', l, play(l), presnivs(l)
463	IF (trouve_700 .AND. play(l)<=70000) THEN
464	llm700 = l
465	print *, 'llm700,play=', llm700, play(l) / 100.
466	trouve_700 = .FALSE.
467	endif
468	enddo
469	WRITE(, ) '***********************'
470	ENDIF
471
472	!=====================================================================
473	! EVENTUALLY, READ FORCING DATA :
474	!=====================================================================
475
476	INCLUDE "1D_read_forc_cases.h"
477	PRINT, 'A d_t_adv ', d_t_adv(1:20)86400
478
479	IF (forcing_GCM2SCM) THEN
480	write (, ) 'forcing_GCM2SCM not yet implemented'
481	stop 'in initialization'
482	ENDIF ! forcing_GCM2SCM
483
484
485	!=====================================================================
486	! Initialisation de la physique :
487	!=====================================================================
488
489	! Rq: conf_phys.F90 lit tous les flags de physiq.def; conf_phys appele depuis physiq.F
490
491	! day_step, iphysiq lus dans gcm.def ci-dessus
492	! timestep: calcule ci-dessous from rday et day_step
493	! ngrid=1
494	! llm: defini dans .../modipsl/modeles/LMDZ4/libf/grid/dimension
495	! rday: defini dans suphel.F (86400.)
496	! day_ini: lu dans run.def (dayref)
497	! rlat_rad,rlon-rad: transformes en radian de rlat,rlon lus dans lmdz1d.def (en degres)
498	! airefi,zcufi,zcvfi initialises au debut de ce programme
499	! rday,ra,rg,rd,rcpd declares dans YOMCST.h et calcules dans suphel.F
500
501
502	day_step = float(nsplit_phys)*day_step/float(iphysiq)
503	write (, ) 'Time step divided by nsplit_phys (=', nsplit_phys, ')'
504	timestep = rday/day_step
505	dtime_frcg = timestep
506
507	zcufi = airefi
508	zcvfi = airefi
509
510	rlat_rad(1) = xlat*rpi/180.
511	rlon_rad(1) = xlon*rpi/180.
512
513	! iniphysiq will CALL iniaqua who needs year_len from phys_cal_mod
514	year_len_phys_cal_mod = year_len
515
516	! Ehouarn: iniphysiq requires arrays related to (3D) dynamics grid,
517	! e.g. for cell boundaries, which are meaningless in 1D; so pad these
518	! with '0.' when necessary
519
520	CALL iniphysiq(iim, jjm, llm, &
521	1, comm_lmdz, &
522	rday, day_ini, timestep, &
523	(/rlat_rad(1), 0./), (/0./), &
524	(/0., 0./), (/rlon_rad(1), 0./), &
525	(/ (/airefi, 0./), (/0., 0./) /), &
526	(/zcufi, 0., 0., 0./), &
527	(/zcvfi, 0./), &
528	ra, rg, rd,rcpd, 1)
529	PRINT*, 'apres iniphysiq'
530
531	! 2 PARAMETRES QUI DEVRAIENT ETRE LUS DANS run.def MAIS NE LE SONT PAS ICI:
532	co2_ppm = 330.0
533	solaire = 1370.0
534
535	! Ecriture du startphy avant le premier appel a la physique.
536	! On le met juste avant pour avoir acces a tous les champs
537
538	IF (ok_writedem) THEN
539	!--------------------------------------------------------------------------
540	! pbl_surface_init (called here) and pbl_surface_final (called by phyredem)
541	! need : qsol fder snow qsurf evap rugos agesno ftsoil
542	!--------------------------------------------------------------------------
543
544	type_ocean = "force"
545	run_off_lic_0(1) = restart_runoff
546	CALL fonte_neige_init(run_off_lic_0)
547
548	fder = 0.
549	snsrf(1, :) = snowmass ! masse de neige des sous surface
550	qsurfsrf(1, :) = qsurf ! humidite de l'air des sous surface
551	fevap = 0.
552	z0m(1, :) = rugos ! couverture de neige des sous surface
553	z0h(1, :) = rugosh ! couverture de neige des sous surface
554	agesno = xagesno
555	tsoil(:, :, :) = tsurf
556	!------ AMMA 2e run avec modele sol et rayonnement actif (MPL 23052012)
557	! tsoil(1,1,1)=299.18
558	! tsoil(1,2,1)=300.08
559	! tsoil(1,3,1)=301.88
560	! tsoil(1,4,1)=305.48
561	! tsoil(1,5,1)=308.00
562	! tsoil(1,6,1)=308.00
563	! tsoil(1,7,1)=308.00
564	! tsoil(1,8,1)=308.00
565	! tsoil(1,9,1)=308.00
566	! tsoil(1,10,1)=308.00
567	! tsoil(1,11,1)=308.00
568	!-----------------------------------------------------------------------
569	CALL pbl_surface_init(fder, snsrf, qsurfsrf, tsoil)
570
571	!------------------ prepare limit conditions for limit.nc -----------------
572	!-- Ocean force
573
574	PRINT*, 'avant phyredem'
575	pctsrf(1, :) = 0.
576	IF (nat_surf==0.) THEN
577	pctsrf(1, is_oce) = 1.
578	pctsrf(1, is_ter) = 0.
579	pctsrf(1, is_lic) = 0.
580	pctsrf(1, is_sic) = 0.
581	ELSE IF (nat_surf == 1) THEN
582	pctsrf(1, is_oce) = 0.
583	pctsrf(1, is_ter) = 1.
584	pctsrf(1, is_lic) = 0.
585	pctsrf(1, is_sic) = 0.
586	ELSE IF (nat_surf == 2) THEN
587	pctsrf(1, is_oce) = 0.
588	pctsrf(1, is_ter) = 0.
589	pctsrf(1, is_lic) = 1.
590	pctsrf(1, is_sic) = 0.
591	ELSE IF (nat_surf == 3) THEN
592	pctsrf(1, is_oce) = 0.
593	pctsrf(1, is_ter) = 0.
594	pctsrf(1, is_lic) = 0.
595	pctsrf(1, is_sic) = 1.
596
597	end if
598
599
600	PRINT*, 'nat_surf,pctsrf(1,is_oce),pctsrf(1,is_ter)', nat_surf &
601	, pctsrf(1, is_oce), pctsrf(1, is_ter)
602
603	zmasq = pctsrf(1, is_ter)+pctsrf(1, is_lic)
604	zpic = zpicinp
605	ftsol = tsurf
606	falb_dir= albedo
607	falb_dif = albedo
608	rugoro = rugos
609	t_ancien(1, :)= temp(:)
610	q_ancien(1, :)= q(:, 1)
611	ql_ancien = 0.
612	qs_ancien = 0.
613	prlw_ancien = 0.
614	prsw_ancien = 0.
615	prw_ancien = 0.
616	!jyg<
617	! Etienne: comment those lines since now the TKE is inialized in 1D_read_forc_cases
618	!! pbl_tke(:,:,:)=1.e-8
619	! pbl_tke(:,:,:)=0.
620	! pbl_tke(:,2,:)=1.e-2
621	!>jyg
622	rain_fall = 0.
623	snow_fall = 0.
624	solsw = 0.
625	solswfdiff= 0.
626	sollw = 0.
627	sollwdown = rsigmatsurf*4
628	radsol = 0.
629	rnebcon= 0.
630	ratqs = 0.
631	clwcon = 0.
632	zmax0 = 0.
633	zmea = zsurf
634	zstd= 0.
635	zsig = 0.
636	zgam = 0.
637	zval = 0.
638	zthe = 0.
639	sig1= 0.
640	w01 = 0.
641
642	wake_deltaq = 0.
643	wake_deltat = 0.
644	wake_delta_pbl_TKE(:, :, :) = 0.
645	delta_tsurf = 0.
646	wake_fip = 0.
647	wake_pe = 0.
648	wake_s = 0.
649	awake_s = 0.
650	wake_dens = 0.
651	awake_dens = 0.
652	cv_gen = 0.
653	wake_cstar = 0.
654	ale_bl = 0.
655	ale_bl_trig = 0.
656	alp_bl = 0.
657	IF (ALLOCATED(du_gwd_rando)) du_gwd_rando = 0.
658	IF (ALLOCATED(du_gwd_front)) du_gwd_front = 0.
659	entr_therm = 0.
660	detr_therm = 0.
661	f0 = 0.
662	fm_therm = 0.
663	u_ancien(1, :)= u(:)
664	v_ancien(1, :)= v(:)
665	rneb_ancien(1, :)= 0.
666
667	u10m = 0.
668	v10m = 0.
669	ale_wake = 0.
670	ale_bl_stat = 0.
671	ratqs_inter_(:, :)= 0.002
672
673	!------------------------------------------------------------------------
674	! Make file containing restart for the physics (startphy.nc)
675
676	! NB: List of the variables to be written by phyredem (via put_field):
677	! rlon,rlat,zmasq,pctsrf(:,is_ter),pctsrf(:,is_lic),pctsrf(:,is_oce)
678	! pctsrf(:,is_sic),ftsol(:,nsrf),tsoil(:,isoil,nsrf),qsurf(:,nsrf)
679	! qsol,falb_dir(:,nsrf),falb_dif(:,nsrf),evap(:,nsrf),snow(:,nsrf)
680	! radsol,solsw,solswfdiff,sollw, sollwdown,fder,rain_fall,snow_fall,frugs(:,nsrf)
681	! agesno(:,nsrf),zmea,zstd,zsig,zgam,zthe,zpic,zval,rugoro
682	! t_ancien,q_ancien,,frugs(:,is_oce),clwcon(:,1),rnebcon(:,1),ratqs(:,1)
683	! run_off_lic_0,pbl_tke(:,1:klev,nsrf), zmax0,f0,sig1,w01
684	! wake_deltat,wake_deltaq,wake_s,awake_s,wake_dens,awake_dens,cv_gen,wake_cstar,
685	! wake_fip,wake_delta_pbl_tke(:,1:klev,nsrf)
686
687	! NB2: The content of the startphy.nc file depends on some flags defined in
688	! the ".def" files. However, since conf_phys is not called in lmdz1d.F90, these flags have
689	! to be set at some arbitratry convenient values.
690	!------------------------------------------------------------------------
691	!Al1 =============== restart option ======================================
692	iflag_physiq = 0
693	CALL getin('iflag_physiq', iflag_physiq)
694
695	IF (.NOT.restart) THEN
696	iflag_pbl = 5
697	CALL phyredem ("startphy.nc")
698	else
699	! (desallocations)
700	PRINT*, 'callin surf final'
701	CALL pbl_surface_final(fder, snsrf, qsurfsrf, tsoil)
702	PRINT*, 'after surf final'
703	CALL fonte_neige_final(run_off_lic_0)
704	endif
705
706	ok_writedem = .FALSE.
707	PRINT*,'apres phyredem'
708
709	endif ! ok_writedem
710
711	!------------------------------------------------------------------------
712	! Make file containing boundary conditions (limit.nc) Al1->restartdyn*
713	! --------------------------------------------------
714	! NB: List of the variables to be written in limit.nc
715	! (by writelim.F, SUBROUTINE of 1DUTILS.h):
716	! phy_nat,phy_alb,phy_sst,phy_bil,phy_rug,phy_ice,
717	! phy_fter,phy_foce,phy_flic,phy_fsic)
718	!------------------------------------------------------------------------
719	do i = 1, year_len
720	phy_nat(i) = nat_surf
721	phy_alb(i) = albedo
722	phy_sst(i) = tsurf ! read_tsurf1d will be used instead
723	phy_rug(i) = rugos
724	phy_fter(i) = pctsrf(1, is_ter)
725	phy_foce(i) = pctsrf(1, is_oce)
726	phy_fsic(i) = pctsrf(1, is_sic)
727	phy_flic(i) = pctsrf(1, is_lic)
728	enddo
729
730	! fabrication de limit.nc
731	CALL writelim (1, phy_nat, phy_alb, phy_sst, phy_bil,phy_rug, &
732	phy_ice, phy_fter, phy_foce, phy_flic,phy_fsic)
733
734
735	CALL phys_state_var_end
736	!Al1
737	IF (restart) THEN
738	PRINT*, 'CALL to restart dyn 1d'
739	Call dyn1deta0("start1dyn.nc", plev, play, phi, phis,presnivs, &
740	u, v, temp, q,omega2)
741
742	PRINT*, 'fnday,annee_ref,day_ref,day_ini', &
743	fnday, annee_ref,day_ref, day_ini
744	!** CALL ymds2ju(annee_ref,mois,day_ini,heure,day)
745	day = day_ini
746	day_end = day_ini + nday
747	daytime = day + time_ini/24. ! 1st day and initial time of the simulation
748
749	! Print out the actual date of the beginning of the simulation :
750	CALL ju2ymds(daytime, an, mois, jour, heure)
751	print *, ' Time of beginning : y m d h', an, mois,jour, heure/3600.
752
753	day = int(daytime)
754	time = daytime-day
755
756	PRINT,'*** intialised fields from restart1dyn *****'
757	PRINT*, 'plev,play,phi,phis,presnivs,u,v,temp,q,omega2'
758	PRINT*,'temp(1),q(1,1),u(1),v(1),plev(1),phis :'
759	PRINT*, temp(1), q(1, 1), u(1), v(1), plev(1), phis(1)
760	! raz for safety
761	do l = 1, llm
762	d_q_vert_adv(l, 1) = 0.
763	enddo
764	endif
765	!====================== end restart =================================
766	IF (ecrit_slab_oc==1) THEN
767	open(97, file = 'div_slab.dat', STATUS = 'UNKNOWN')
768	elseif (ecrit_slab_oc==0) THEN
769	open(97, file = 'div_slab.dat', STATUS = 'OLD')
770	endif
771
772	!=====================================================================
773	IF (CPPKEY_OUTPUTPHYSSCM) THEN
774	CALL iophys_ini(timestep)
775	END IF
776
777	!=====================================================================
778	! START OF THE TEMPORAL LOOP :
779	!=====================================================================
780
781	it_end = nint(fnday*day_step)
782	do while(it<=it_end)
783
784	IF (prt_level>=1) THEN
785	PRINT*, 'XXXXXXXXXXXXXXXXXXX ITAP,day,time=', &
786	it, day, time, it_end, day_step
787	PRINT*,'PAS DE TEMPS ', timestep
788	endif
789	IF (it==it_end) lastcall = .True.
790
791	!---------------------------------------------------------------------
792	! Interpolation of forcings in time and onto model levels
793	!---------------------------------------------------------------------
794
795	INCLUDE "1D_interp_cases.h"
796
797	!---------------------------------------------------------------------
798	! Geopotential :
799	!---------------------------------------------------------------------
800	phis(1)= zsurf*RG
801	! phi(1)=phis(1)+RDtemp(1)(plev(1)-play(1))/(.5*(plev(1)+play(1)))
802
803	! Calculate geopotential from the ground surface since phi and phis are added in physiq_mod
804	phi(1)= RDtemp(1)(plev(1)-play(1))/(.5*(plev(1)+play(1)))
805
806	do l = 1, llm-1
807	phi(l+1)= phi(l)+RD(temp(l)+temp(l+1)) &
808	(play(l)-play(l+1))/(play(l)+play(l+1))
809	enddo
810
811	!---------------------------------------------------------------------
812	! Vertical advection
813	!---------------------------------------------------------------------
814
815	IF (forc_w+forc_omega > 0) THEN
816
817	IF (forc_w == 1) THEN
818	w_adv = w_mod_cas
819	z_adv = phi/RG
820	ELSE
821	w_adv = omega
822	z_adv =play
823	ENDIF
824
825	teta = temp(pzero/play)*rkappa
826	do l = 2, llm-1
827	! vertical tendencies computed as d X / d t = -W d X / d z
828	d_u_vert_adv(l)= -w_adv(l)*(u(l+1)-u(l-1))/(z_adv(l+1)-z_adv(l-1))
829	d_v_vert_adv(l)= -w_adv(l)*(v(l+1)-v(l-1))/(z_adv(l+1)-z_adv(l-1))
830	! d theta / dt = -W d theta / d z, transformed into d temp / d t dividing by (pzero/play(l))**rkappa
831	d_t_vert_adv(l)= -w_adv(l)(teta(l+1)-teta(l-1))/(z_adv(l+1)-z_adv(l-1)) / (pzero/play(l))*rkappa
832	d_q_vert_adv(l, 1)= -w_adv(l)*(q(l+1, 1)-q(l-1, 1))/(z_adv(l+1)-z_adv(l-1))
833	enddo
834	d_u_adv(:)= d_u_adv(:)+d_u_vert_adv(:)
835	d_v_adv(:)= d_v_adv(:)+d_v_vert_adv(:)
836	d_t_adv(:)= d_t_adv(:)+d_t_vert_adv(:)
837	d_q_adv(:, 1)= d_q_adv(:, 1)+d_q_vert_adv(:, 1)
838
839	ENDIF
840
841	!---------------------------------------------------------------------
842	! Listing output for debug prt_level>=1
843	!---------------------------------------------------------------------
844	IF (prt_level>=1) THEN
845	print *, ' avant physiq : -------- day time ', day, time
846	WRITE(, ) 'firstcall,lastcall,phis', &
847	firstcall, lastcall, phis
848	end if
849	IF (prt_level>=5) THEN
850	WRITE(*, '(a10,2a4,4a13)') 'BEFOR1 IT=', 'it', 'l', &
851	'presniv', 'plev','play', 'phi'
852	WRITE(*, '(a10,2i4,4f13.2)') ('BEFOR1 IT= ', it, l, &
853	presnivs(l), plev(l), play(l), phi(l), l = 1, llm)
854	WRITE(*, '(a11,2a4,a11,6a8)') 'BEFOR2', 'it', 'l', &
855	'presniv', 'u','v', 'temp', 'q1', 'q2', 'omega2'
856	WRITE(*, '(a11,2i4,f11.2,5f8.2,e10.2)') ('BEFOR2 IT= ', it, l, &
857	presnivs(l), u(l), v(l), temp(l), q(l, 1), q(l, 2), omega2(l), l = 1, llm)
858	endif
859
860	!---------------------------------------------------------------------
861	! Call physiq :
862	!---------------------------------------------------------------------
863	CALL physiq(ngrid, llm, &
864	firstcall, lastcall, timestep, &
865	plev, play, phi, phis, presnivs, &
866	u, v, rot, temp, q,omega2, &
867	du_phys, dv_phys, dt_phys, dq,dpsrf)
868	firstcall = .FALSE.
869
870	!---------------------------------------------------------------------
871	! Listing output for debug
872	!---------------------------------------------------------------------
873	IF (prt_level>=5) THEN
874	WRITE(*, '(a11,2a4,4a13)') 'AFTER1 IT=', 'it', 'l', &
875	'presniv', 'plev','play', 'phi'
876	WRITE(*, '(a11,2i4,4f13.2)') ('AFTER1 it= ', it, l, &
877	presnivs(l), plev(l), play(l), phi(l), l = 1, llm)
878	WRITE(*, '(a11,2a4,a11,6a8)') 'AFTER2', 'it', 'l', &
879	'presniv', 'u','v', 'temp', 'q1', 'q2', 'omega2'
880	WRITE(*, '(a11,2i4,f11.2,5f8.2,e10.2)') ('AFTER2 it= ', it, l, &
881	presnivs(l), u(l), v(l), temp(l), q(l, 1), q(l, 2), omega2(l), l = 1, llm)
882	WRITE(*, '(a11,2a4,a11,5a8)') 'AFTER3', 'it', 'l', &
883	'presniv', 'du_phys','dv_phys', 'dt_phys', 'dq1', 'dq2'
884	WRITE(*, '(a11,2i4,f11.2,5f8.2)') ('AFTER3 it= ', it, l, &
885	presnivs(l), 86400du_phys(l), 86400dv_phys(l), &
886	86400dt_phys(l), 86400dq(l, 1), dq(l, 2), l = 1, llm)
887	WRITE(, ) 'dpsrf', dpsrf
888	endif
889	!---------------------------------------------------------------------
890	! Add physical tendencies :
891	!---------------------------------------------------------------------
892
893	fcoriolis= 2.sin(rpixlat/180.)*romega
894
895	IF (prt_level >= 5) PRINT*, 'fcoriolis, xlat,mxcalc ', &
896	fcoriolis, xlat, mxcalc
897
898	!---------------------------------------------------------------------
899	! Geostrophic forcing
900	!---------------------------------------------------------------------
901
902	IF (forc_geo == 0) THEN
903	d_u_age(1:mxcalc)= 0.
904	d_v_age(1:mxcalc)= 0.
905	ELSE
906	sfdt = sin(0.5fcoriolistimestep)
907	cfdt = cos(0.5fcoriolistimestep)
908
909	d_u_age(1:mxcalc)= -2.sfdt/timestep &
910	(sfdt*(u(1:mxcalc)-ug(1:mxcalc)) - &
911	cfdt*(v(1:mxcalc)-vg(1:mxcalc)))
912	!! : fcoriolis*(v(1:mxcalc)-vg(1:mxcalc))
913
914	d_v_age(1:mxcalc)= -2.sfdt/timestep &
915	(cfdt*(u(1:mxcalc)-ug(1:mxcalc)) + &
916	sfdt*(v(1:mxcalc)-vg(1:mxcalc)))
917	!! : -fcoriolis*(u(1:mxcalc)-ug(1:mxcalc))
918	ENDIF
919
920	!---------------------------------------------------------------------
921	! Nudging
922	! EV: rewrite the section to account for a time- and height-varying
923	! nudging
924	!---------------------------------------------------------------------
925	d_t_nudge(:) = 0.
926	d_u_nudge(:) = 0.
927	d_v_nudge(:) = 0.
928	d_q_nudge(:, :) = 0.
929
930	DO l = 1, llm
931
932	IF (nudging_u < 0) THEN
933
934	d_u_nudge(l)=(u_nudg_mod_cas(l)-u(l))*invtau_u_nudg_mod_cas(l)
935
936	ELSE
937
938	IF (play(l) < p_nudging_u .AND. nint(nudging_u) /= 0) &
939	d_u_nudge(l)=(u_nudg_mod_cas(l)-u(l))/nudging_u
940
941	ENDIF
942
943
944	IF (nudging_v < 0) THEN
945
946	d_v_nudge(l)=(v_nudg_mod_cas(l)-v(l))*invtau_v_nudg_mod_cas(l)
947
948	ELSE
949
950
951	IF (play(l) < p_nudging_v .AND. nint(nudging_v) /= 0) &
952	d_v_nudge(l)=(v_nudg_mod_cas(l)-v(l))/nudging_v
953
954	ENDIF
955
956
957	IF (nudging_t < 0) THEN
958
959	d_t_nudge(l)=(temp_nudg_mod_cas(l)-temp(l))*invtau_temp_nudg_mod_cas(l)
960
961	ELSE
962
963
964	IF (play(l) < p_nudging_t .AND. nint(nudging_t) /= 0) &
965	d_t_nudge(l)=(temp_nudg_mod_cas(l)-temp(l))/nudging_t
966
967	ENDIF
968
969
970	IF (nudging_qv < 0) THEN
971
972	d_q_nudge(l, 1)=(qv_nudg_mod_cas(l)-q(l, 1))*invtau_qv_nudg_mod_cas(l)
973
974	ELSE
975
976	IF (play(l) < p_nudging_qv .AND. nint(nudging_qv) /= 0) &
977	d_q_nudge(l, 1)=(qv_nudg_mod_cas(l)-q(l, 1))/nudging_qv
978
979	ENDIF
980
981	ENDDO
982
983	!---------------------------------------------------------------------
984	! Optional outputs
985	!---------------------------------------------------------------------
986
987	IF (CPPKEY_OUTPUTPHYSSCM) THEN
988	CALL iophys_ecrit('w_adv', klev, 'w_adv', 'K/day', w_adv)
989	CALL iophys_ecrit('z_adv', klev, 'z_adv', 'K/day', z_adv)
990	CALL iophys_ecrit('dtadv', klev, 'dtadv', 'K/day', 86400*d_t_adv)
991	CALL iophys_ecrit('dtdyn', klev, 'dtdyn', 'K/day', 86400*d_t_vert_adv)
992	CALL iophys_ecrit('qv', klev, 'qv', 'g/kg', 1000*q(:, 1))
993	CALL iophys_ecrit('qvnud', klev, 'qvnud', 'g/kg', 1000*u_nudg_mod_cas)
994	CALL iophys_ecrit('u', klev, 'u', 'm/s', u)
995	CALL iophys_ecrit('unud', klev, 'unud', 'm/s', u_nudg_mod_cas)
996	CALL iophys_ecrit('v', klev, 'v', 'm/s', v)
997	CALL iophys_ecrit('vnud', klev, 'vnud', 'm/s', v_nudg_mod_cas)
998	CALL iophys_ecrit('temp', klev, 'temp', 'K', temp)
999	CALL iophys_ecrit('tempnud', klev, 'temp_nudg_mod_cas', 'K', temp_nudg_mod_cas)
1000	CALL iophys_ecrit('dtnud', klev, 'dtnud', 'K/day', 86400*d_t_nudge)
1001	CALL iophys_ecrit('dqnud', klev, 'dqnud', 'K/day', 100086400d_q_nudge(:, 1))
1002	END IF
1003
1004	IF (flag_inhib_forcing == 0) then ! if tendency of forcings should be added
1005
1006	u(1:mxcalc)= u(1:mxcalc) + timestep*(&
1007	du_phys(1:mxcalc) &
1008	+d_u_age(1:mxcalc)+d_u_adv(1:mxcalc) &
1009	+d_u_nudge(1:mxcalc))
1010	v(1:mxcalc)= v(1:mxcalc) + timestep*(&
1011	dv_phys(1:mxcalc) &
1012	+d_v_age(1:mxcalc)+d_v_adv(1:mxcalc) &
1013	+d_v_nudge(1:mxcalc))
1014	q(1:mxcalc, :)= q(1:mxcalc, :)+timestep*(&
1015	dq(1:mxcalc, :) &
1016	+d_q_adv(1:mxcalc, :) &
1017	+d_q_nudge(1:mxcalc, :))
1018
1019	IF (prt_level>=3) THEN
1020	print *, &
1021	'physiq-> temp(1),dt_phys(1),d_t_adv(1),dt_cooling(1) ', &
1022	temp(1), dt_phys(1), d_t_adv(1), dt_cooling(1)
1023	PRINT*, 'dv_phys=', dv_phys
1024	PRINT* , 'd_v_age=', d_v_age
1025	PRINT*, 'd_v_adv=',d_v_adv
1026	PRINT*, 'd_v_nudge=', d_v_nudge
1027	PRINT*, v
1028	PRINT*, vg
1029	endif
1030
1031	temp(1:mxcalc)= temp(1:mxcalc)+timestep*(&
1032	dt_phys(1:mxcalc) &
1033	+d_t_adv(1:mxcalc) &
1034	+d_t_nudge(1:mxcalc) &
1035	+dt_cooling(1:mxcalc)) ! Taux de chauffage ou refroid.
1036
1037
1038	!=======================================================================
1039	!! CONSERVE EN ATTENDANT QUE LE CAS EN QUESTION FONCTIONNE EN STD !!
1040	!=======================================================================
1041
1042	teta = temp(pzero/play)*rkappa
1043
1044	!---------------------------------------------------------------------
1045	! Nudge soil temperature if requested
1046	!---------------------------------------------------------------------
1047
1048	IF (nudge_tsoil .AND. .NOT. lastcall) THEN
1049	ftsoil(1, isoil_nudge, :) = ftsoil(1, isoil_nudge, :) &
1050	-timestep/tau_soil_nudge*(ftsoil(1, isoil_nudge, :)-Tsoil_nudge)
1051	ENDIF
1052
1053	!---------------------------------------------------------------------
1054	! Add large-scale tendencies (advection, etc) :
1055	!---------------------------------------------------------------------
1056
1057	!cc nrlmd
1058	!cc tmpvar=teta
1059	!cc CALL advect_vert(llm,omega,timestep,tmpvar,plev)
1060	!cc
1061	!cc teta(1:mxcalc)=tmpvar(1:mxcalc)
1062	!cc tmpvar(:)=q(:,1)
1063	!cc CALL advect_vert(llm,omega,timestep,tmpvar,plev)
1064	!cc q(1:mxcalc,1)=tmpvar(1:mxcalc)
1065	!cc tmpvar(:)=q(:,2)
1066	!cc CALL advect_vert(llm,omega,timestep,tmpvar,plev)
1067	!cc q(1:mxcalc,2)=tmpvar(1:mxcalc)
1068
1069	END IF ! end if tendency of tendency should be added
1070
1071	!---------------------------------------------------------------------
1072	! Air temperature :
1073	!---------------------------------------------------------------------
1074	IF (lastcall) THEN
1075	PRINT*, 'Pas de temps final ', it
1076	CALL ju2ymds(daytime, an, mois, jour, heure)
1077	PRINT*, 'a la date : a m j h', an, mois, jour, heure/3600.
1078	endif
1079
1080	! incremente day time
1081	daytime = daytime+1./day_step
1082	day = int(daytime+0.1/day_step)
1083	! time = max(daytime-day,0.0)
1084	!Al1&jyg: correction de bug
1085	!cc time = real(mod(it,day_step))/day_step
1086	time = time_ini/24.+real(mod(it, day_step))/day_step
1087	it = it+1
1088
1089	enddo
1090
1091	IF (ecrit_slab_oc/=-1) close(97)
1092
1093	!Al1 Call to 1D equivalent of dynredem (an,mois,jour,heure ?)
1094	! ---------------------------------------------------------------------------
1095	CALL dyn1dredem("restart1dyn.nc", &
1096	plev, play, phi, phis,presnivs, &
1097	u, v, temp, q,omega2)
1098
1099	CALL abort_gcm ('lmdz1d ', 'The End ', 0)
1100
1101	END SUBROUTINE scm
1102	END MODULE lmdz_scm

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