source: LMDZ6/trunk/libf/phylmd/dyn1d/lmdz1d.F90 @ 3409

Last change on this file since 3409 was 3316, checked in by musat, 7 years ago

Corrections de bugs pour gfortran72

File size: 47.6 KB
RevLine 
[2239]1!#ifdef CPP_1D
2!#include "../dyn3d/mod_const_mpi.F90"
3!#include "../dyn3d_common/control_mod.F90"
4!#include "../dyn3d_common/infotrac.F90"
5!#include "../dyn3d_common/disvert.F90"
[2017]6
7
[2019]8      PROGRAM lmdz1d
9
[2393]10   USE ioipsl, only: ju2ymds, ymds2ju, ioconf_calendar
11   USE phys_state_var_mod, ONLY : phys_state_var_init, phys_state_var_end, &
12       clwcon, detr_therm, &
13       qsol, fevap, z0m, z0h, agesno, &
14       du_gwd_rando, du_gwd_front, entr_therm, f0, fm_therm, &
15       falb_dir, falb_dif, &
16       ftsol, pbl_tke, pctsrf, radsol, rain_fall, snow_fall, ratqs, &
[2402]17       rnebcon, rugoro, sig1, w01, solaire_etat0, sollw, sollwdown, &
[2635]18       solsw, t_ancien, q_ancien, u_ancien, v_ancien, wake_cstar, &
19       wake_delta_pbl_TKE, delta_tsurf, wake_fip, wake_pe, &
20       wake_deltaq, wake_deltat, wake_s, wake_dens, &
21       zgam, zmax0, zmea, zpic, zsig, &
[2933]22       zstd, zthe, zval, ale_bl, ale_bl_trig, alp_bl, ql_ancien, qs_ancien, &
23       prlw_ancien, prsw_ancien, prw_ancien
[2672]24 
[2635]25   USE dimphy
26   USE surface_data, only : type_ocean,ok_veget
27   USE pbl_surface_mod, only : ftsoil, pbl_surface_init, &
28                                 pbl_surface_final
29   USE fonte_neige_mod, only : fonte_neige_init, fonte_neige_final
[2019]30
[2635]31   USE infotrac ! new
32   USE control_mod
[2393]33   USE indice_sol_mod
34   USE phyaqua_mod
[2716]35!  USE mod_1D_cases_read
36   USE mod_1D_cases_read2
[2393]37   USE mod_1D_amma_read
[2565]38   USE print_control_mod, ONLY: lunout, prt_level
[2393]39   USE iniphysiq_mod, ONLY: iniphysiq
40   USE mod_const_mpi, ONLY: comm_lmdz
[2418]41   USE physiq_mod, ONLY: physiq
[2602]42   USE comvert_mod, ONLY: presnivs, ap, bp, dpres,nivsig, nivsigs, pa, &
[2786]43                          preff, aps, bps, pseudoalt, scaleheight
[2601]44   USE temps_mod, ONLY: annee_ref, calend, day_end, day_ini, day_ref, &
45                        itau_dyn, itau_phy, start_time
[2019]46
47      implicit none
48#include "dimensions.h"
49#include "YOMCST.h"
50!!#include "control.h"
51#include "clesphys.h"
52#include "dimsoil.h"
53!#include "indicesol.h"
54
55#include "compar1d.h"
56#include "flux_arp.h"
[2332]57#include "date_cas.h"
[2019]58#include "tsoilnudge.h"
59#include "fcg_gcssold.h"
60!!!#include "fbforcing.h"
[2565]61#include "compbl.h"
[2019]62
63!=====================================================================
64! DECLARATIONS
65!=====================================================================
66
67!---------------------------------------------------------------------
68!  Externals
69!---------------------------------------------------------------------
70      external fq_sat
71      real fq_sat
72
73!---------------------------------------------------------------------
74!  Arguments d' initialisations de la physique (USER DEFINE)
75!---------------------------------------------------------------------
76
77      integer, parameter :: ngrid=1
78      real :: zcufi    = 1.
79      real :: zcvfi    = 1.
80
81!-      real :: nat_surf
82!-      logical :: ok_flux_surf
83!-      real :: fsens
84!-      real :: flat
85!-      real :: tsurf
86!-      real :: rugos
87!-      real :: qsol(1:2)
88!-      real :: qsurf
89!-      real :: psurf
90!-      real :: zsurf
91!-      real :: albedo
92!-
93!-      real :: time     = 0.
94!-      real :: time_ini
95!-      real :: xlat
96!-      real :: xlon
97!-      real :: wtsurf
98!-      real :: wqsurf
99!-      real :: restart_runoff
100!-      real :: xagesno
101!-      real :: qsolinp
102!-      real :: zpicinp
103!-
104      real :: fnday
105      real :: day, daytime
106      real :: day1
107      real :: heure
108      integer :: jour
109      integer :: mois
110      integer :: an
111 
112!---------------------------------------------------------------------
113!  Declarations related to forcing and initial profiles
114!---------------------------------------------------------------------
115
116        integer :: kmax = llm
117        integer llm700,nq1,nq2
118        INTEGER, PARAMETER :: nlev_max=1000, nqmx=1000
119        real timestep, frac
120        real height(nlev_max),tttprof(nlev_max),qtprof(nlev_max)
121        real  uprof(nlev_max),vprof(nlev_max),e12prof(nlev_max)
122        real  ugprof(nlev_max),vgprof(nlev_max),wfls(nlev_max)
123        real  dqtdxls(nlev_max),dqtdyls(nlev_max)
124        real  dqtdtls(nlev_max),thlpcar(nlev_max)
125        real  qprof(nlev_max,nqmx)
126
127!        integer :: forcing_type
128        logical :: forcing_les     = .false.
129        logical :: forcing_armcu   = .false.
130        logical :: forcing_rico    = .false.
131        logical :: forcing_radconv = .false.
132        logical :: forcing_toga    = .false.
133        logical :: forcing_twpice  = .false.
134        logical :: forcing_amma    = .false.
[2126]135        logical :: forcing_dice    = .false.
[2672]136        logical :: forcing_gabls4  = .false.
137
[2019]138        logical :: forcing_GCM2SCM = .false.
139        logical :: forcing_GCSSold = .false.
140        logical :: forcing_sandu   = .false.
141        logical :: forcing_astex   = .false.
142        logical :: forcing_fire    = .false.
[2191]143        logical :: forcing_case    = .false.
[2716]144        logical :: forcing_case2   = .false.
[2019]145        integer :: type_ts_forcing ! 0 = SST constant; 1 = SST read from a file
146!                                                            (cf read_tsurf1d.F)
147
148!vertical advection computation
149!       real d_t_z(llm), d_q_z(llm)
[2393]150!       real d_t_dyn_z(llm), dq_dyn_z(llm)
[2019]151!       real zz(llm)
152!       real zfact
153
154!flag forcings
155        logical :: nudge_wind=.true.
156        logical :: nudge_thermo=.false.
157        logical :: cptadvw=.true.
158!=====================================================================
159! DECLARATIONS FOR EACH CASE
160!=====================================================================
161!
162#include "1D_decl_cases.h"
163!
164!---------------------------------------------------------------------
[2181]165!  Declarations related to nudging
166!---------------------------------------------------------------------
167     integer :: nudge_max
168     parameter (nudge_max=9)
169     integer :: inudge_RHT=1
170     integer :: inudge_UV=2
171     logical :: nudge(nudge_max)
172     real :: t_targ(llm)
173     real :: rh_targ(llm)
174     real :: u_targ(llm)
175     real :: v_targ(llm)
176!
177!---------------------------------------------------------------------
[2019]178!  Declarations related to vertical discretization:
179!---------------------------------------------------------------------
180      real :: pzero=1.e5
181      real :: play (llm),zlay (llm),sig_s(llm),plev(llm+1)
[2672]182      real :: playd(llm),zlayd(llm),ap_amma(llm+1),bp_amma(llm+1)
[2019]183
184!---------------------------------------------------------------------
185!  Declarations related to variables
186!---------------------------------------------------------------------
187
188      real :: phi(llm)
189      real :: teta(llm),tetal(llm),temp(llm),u(llm),v(llm),w(llm)
[2335]190      REAL rot(1, llm) ! relative vorticity, in s-1
[2019]191      real :: rlat_rad(1),rlon_rad(1)
192      real :: omega(llm+1),omega2(llm),rho(llm+1)
193      real :: ug(llm),vg(llm),fcoriolis
194      real :: sfdt, cfdt
195      real :: du_phys(llm),dv_phys(llm),dt_phys(llm)
196      real :: dt_dyn(llm)
[2920]197      real :: dt_cooling(llm),d_t_adv(llm),d_t_nudge(llm)
[2181]198      real :: d_u_nudge(llm),d_v_nudge(llm)
[2191]199      real :: du_adv(llm),dv_adv(llm)
[2373]200      real :: du_age(llm),dv_age(llm)
[2019]201      real :: alpha
202      real :: ttt
203
204      REAL, ALLOCATABLE, DIMENSION(:,:):: q
205      REAL, ALLOCATABLE, DIMENSION(:,:):: dq
206      REAL, ALLOCATABLE, DIMENSION(:,:):: dq_dyn
207      REAL, ALLOCATABLE, DIMENSION(:,:):: d_q_adv
[2181]208      REAL, ALLOCATABLE, DIMENSION(:,:):: d_q_nudge
[2933]209!      REAL, ALLOCATABLE, DIMENSION(:):: d_th_adv
[2019]210
211!---------------------------------------------------------------------
212!  Initialization of surface variables
213!---------------------------------------------------------------------
214      real :: run_off_lic_0(1)
215      real :: fder(1),snsrf(1,nbsrf),qsurfsrf(1,nbsrf)
216      real :: tsoil(1,nsoilmx,nbsrf)
[2244]217!     real :: agesno(1,nbsrf)
[2019]218
219!---------------------------------------------------------------------
220!  Call to phyredem
221!---------------------------------------------------------------------
222      logical :: ok_writedem =.true.
[2126]223      real :: sollw_in = 0.
224      real :: solsw_in = 0.
[2019]225     
226!---------------------------------------------------------------------
227!  Call to physiq
228!---------------------------------------------------------------------
229      logical :: firstcall=.true.
230      logical :: lastcall=.false.
[2418]231      real :: phis(1)    = 0.0
232      real :: dpsrf(1)
[2019]233
234!---------------------------------------------------------------------
235!  Initializations of boundary conditions
236!---------------------------------------------------------------------
237      integer, parameter :: yd = 360
238      real :: phy_nat (yd) = 0.0 ! 0=ocean libre,1=land,2=glacier,3=banquise
239      real :: phy_alb (yd)  ! Albedo land only (old value condsurf_jyg=0.3)
240      real :: phy_sst (yd)  ! SST (will not be used; cf read_tsurf1d.F)
241      real :: phy_bil (yd) = 1.0 ! Ne sert que pour les slab_ocean
242      real :: phy_rug (yd) ! Longueur rugosite utilisee sur land only
243      real :: phy_ice (yd) = 0.0 ! Fraction de glace
244      real :: phy_fter(yd) = 0.0 ! Fraction de terre
245      real :: phy_foce(yd) = 0.0 ! Fraction de ocean
246      real :: phy_fsic(yd) = 0.0 ! Fraction de glace
247      real :: phy_flic(yd) = 0.0 ! Fraction de glace
248
249!---------------------------------------------------------------------
250!  Fichiers et d'autres variables
251!---------------------------------------------------------------------
252      integer :: k,l,i,it=1,mxcalc
[2565]253      integer :: nsrf
[2181]254      integer jcode
[2019]255      INTEGER read_climoz
[2611]256!
257      integer :: it_end ! iteration number of the last call
[2019]258!Al1
259      integer ecrit_slab_oc !1=ecrit,-1=lit,0=no file
260      data ecrit_slab_oc/-1/
[2611]261!
262!     if flag_inhib_forcing = 0, tendencies of forcing are added
263!                           <> 0, tendencies of forcing are not added
264      INTEGER :: flag_inhib_forcing = 0
[2019]265
266!=====================================================================
267! INITIALIZATIONS
268!=====================================================================
[2373]269      du_phys(:)=0.
270      dv_phys(:)=0.
271      dt_phys(:)=0.
272      dt_dyn(:)=0.
273      dt_cooling(:)=0.
[2920]274      d_t_adv(:)=0.
[2373]275      d_t_nudge(:)=0.
276      d_u_nudge(:)=0.
277      d_v_nudge(:)=0.
278      du_adv(:)=0.
279      dv_adv(:)=0.
280      du_age(:)=0.
281      dv_age(:)=0.
282     
[2019]283! Initialization of Common turb_forcing
284       dtime_frcg = 0.
285       Turb_fcg_gcssold=.false.
286       hthturb_gcssold = 0.
287       hqturb_gcssold = 0.
288
[3223]289
290
291
[2019]292!---------------------------------------------------------------------
293! OPTIONS OF THE 1D SIMULATION (lmdz1d.def => unicol.def)
294!---------------------------------------------------------------------
295!Al1
296        call conf_unicol
297!Al1 moves this gcssold var from common fcg_gcssold to
298        Turb_fcg_gcssold = xTurb_fcg_gcssold
299! --------------------------------------------------------------------
300        close(1)
301!Al1
302        write(*,*) 'lmdz1d.def lu => unicol.def'
303
304! forcing_type defines the way the SCM is forced:
305!forcing_type = 0 ==> forcing_les = .true.
306!             initial profiles from file prof.inp.001
307!             no forcing by LS convergence ;
308!             surface temperature imposed ;
309!             radiative cooling may be imposed (iflag_radia=0 in physiq.def)
310!forcing_type = 1 ==> forcing_radconv = .true.
311!             idem forcing_type = 0, but the imposed radiative cooling
312!             is set to 0 (hence, if iflag_radia=0 in physiq.def,
313!             then there is no radiative cooling at all)
314!forcing_type = 2 ==> forcing_toga = .true.
315!             initial profiles from TOGA-COARE IFA files
316!             LS convergence and SST imposed from TOGA-COARE IFA files
317!forcing_type = 3 ==> forcing_GCM2SCM = .true.
318!             initial profiles from the GCM output
319!             LS convergence imposed from the GCM output
320!forcing_type = 4 ==> forcing_twpice = .true.
321!             initial profiles from TWP-ICE cdf file
322!             LS convergence, omega and SST imposed from TWP-ICE files
323!forcing_type = 5 ==> forcing_rico = .true.
324!             initial profiles from RICO files
325!             LS convergence imposed from RICO files
326!forcing_type = 6 ==> forcing_amma = .true.
327!             initial profiles from AMMA nc file
328!             LS convergence, omega and surface fluxes imposed from AMMA file 
[2126]329!forcing_type = 7 ==> forcing_dice = .true.
330!             initial profiles and large scale forcings in dice_driver.nc
331!             Different stages: soil model alone, atm. model alone
332!             then both models coupled
[2672]333!forcing_type = 8 ==> forcing_gabls4 = .true.
334!             initial profiles and large scale forcings in gabls4_driver.nc
[2332]335!forcing_type >= 100 ==> forcing_case = .true.
[2191]336!             initial profiles and large scale forcings in cas.nc
337!             LS convergence, omega and SST imposed from CINDY-DYNAMO files
[2332]338!             101=cindynamo
339!             102=bomex
[2716]340!forcing_type >= 100 ==> forcing_case2 = .true.
341!             temporary flag while all the 1D cases are not whith the same cas.nc forcing file
342!             103=arm_cu2 ie arm_cu with new forcing format
343!             104=rico2 ie rico with new forcing format
[2019]344!forcing_type = 40 ==> forcing_GCSSold = .true.
345!             initial profile from GCSS file
346!             LS convergence imposed from GCSS file
347!forcing_type = 50 ==> forcing_fire = .true.
348!             forcing from fire.nc
349!forcing_type = 59 ==> forcing_sandu = .true.
350!             initial profiles from sanduref file: see prof.inp.001
351!             SST varying with time and divergence constante: see ifa_sanduref.txt file
352!             Radiation has to be computed interactively
353!forcing_type = 60 ==> forcing_astex = .true.
354!             initial profiles from file: see prof.inp.001
355!             SST,divergence,ug,vg,ufa,vfa varying with time : see ifa_astex.txt file
356!             Radiation has to be computed interactively
357!forcing_type = 61 ==> forcing_armcu = .true.
358!             initial profiles from file: see prof.inp.001
359!             sensible and latent heat flux imposed: see ifa_arm_cu_1.txt
360!             large scale advective forcing & radiative tendencies applied below 1000m: see ifa_arm_cu_2.txt
361!             use geostrophic wind ug=10m/s vg=0m/s. Duration of the case 53100s
362!             Radiation to be switched off
363!
[2983]364      if (forcing_type <=0) THEN
[2019]365       forcing_les = .true.
366      elseif (forcing_type .eq.1) THEN
367       forcing_radconv = .true.
368      elseif (forcing_type .eq.2) THEN
369       forcing_toga    = .true.
370      elseif (forcing_type .eq.3) THEN
371       forcing_GCM2SCM = .true.
372      elseif (forcing_type .eq.4) THEN
373       forcing_twpice = .true.
374      elseif (forcing_type .eq.5) THEN
375       forcing_rico = .true.
376      elseif (forcing_type .eq.6) THEN
377       forcing_amma = .true.
[2126]378      elseif (forcing_type .eq.7) THEN
379       forcing_dice = .true.
[2672]380      elseif (forcing_type .eq.8) THEN
381       forcing_gabls4 = .true.
[2332]382      elseif (forcing_type .eq.101) THEN ! Cindynamo starts 1-10-2011 0h
[2191]383       forcing_case = .true.
[2332]384       year_ini_cas=2011
385       mth_ini_cas=10
386       day_deb=1
387       heure_ini_cas=0.
388       pdt_cas=3*3600.         ! forcing frequency
389      elseif (forcing_type .eq.102) THEN ! Bomex starts 24-6-1969 0h
390       forcing_case = .true.
391       year_ini_cas=1969
392       mth_ini_cas=6
393       day_deb=24
394       heure_ini_cas=0.
395       pdt_cas=1800.         ! forcing frequency
[2716]396      elseif (forcing_type .eq.103) THEN ! Arm_cu starts 21-6-1997 11h30
397       forcing_case2 = .true.
398       year_ini_cas=1997
399       mth_ini_cas=6
400       day_deb=21
401       heure_ini_cas=11.5
402       pdt_cas=1800.         ! forcing frequency
403      elseif (forcing_type .eq.104) THEN ! rico starts 16-12-2004 0h
404       forcing_case2 = .true.
405       year_ini_cas=2004
406       mth_ini_cas=12
407       day_deb=16
408       heure_ini_cas=0.
409       pdt_cas=1800.         ! forcing frequency
[2920]410      elseif (forcing_type .eq.105) THEN ! bomex starts 16-12-2004 0h
411       forcing_case2 = .true.
412       year_ini_cas=1969
413       mth_ini_cas=6
414       day_deb=24
415       heure_ini_cas=0.
416       pdt_cas=1800.         ! forcing frequency
[2983]417      elseif (forcing_type .eq.106) THEN ! ayotte_24SC starts 6-11-1992 0h
418       forcing_case2 = .true.
419       year_ini_cas=1992
420       mth_ini_cas=11
421       day_deb=6
422       heure_ini_cas=10.
423       pdt_cas=86400.        ! forcing frequency
[2019]424      elseif (forcing_type .eq.40) THEN
425       forcing_GCSSold = .true.
426      elseif (forcing_type .eq.50) THEN
427       forcing_fire = .true.
428      elseif (forcing_type .eq.59) THEN
429       forcing_sandu   = .true.
430      elseif (forcing_type .eq.60) THEN
431       forcing_astex   = .true.
432      elseif (forcing_type .eq.61) THEN
433       forcing_armcu = .true.
434       IF(llm.NE.19.AND.llm.NE.40) stop 'Erreur nombre de niveaux !!'
435      else
436       write (*,*) 'ERROR : unknown forcing_type ', forcing_type
437       stop 'Forcing_type should be 0,1,2,3,4,5,6 or 40,59,60,61'
438      ENDIF
439      print*,"forcing type=",forcing_type
440
441! if type_ts_forcing=0, the surface temp of 1D simulation is constant in time
442! (specified by tsurf in lmdz1d.def); if type_ts_forcing=1, the surface temperature
443! varies in time according to a forcing (e.g. forcing_toga) and is passed to read_tsurf1d.F
444! through the common sst_forcing.
445
446        type_ts_forcing = 0
[2126]447        if (forcing_toga.or.forcing_sandu.or.forcing_astex .or. forcing_dice)                 &
[2019]448     &    type_ts_forcing = 1
[2181]449!
450! Initialization of the logical switch for nudging
451     jcode = iflag_nudge
452     do i = 1,nudge_max
453       nudge(i) = mod(jcode,10) .ge. 1
454       jcode = jcode/10
455     enddo
[2019]456!---------------------------------------------------------------------
457!  Definition of the run
458!---------------------------------------------------------------------
459
[2221]460      call conf_gcm( 99, .TRUE. )
[2019]461!-----------------------------------------------------------------------
462!   Choix du calendrier
463!   -------------------
464
465!      calend = 'earth_365d'
466      if (calend == 'earth_360d') then
467        call ioconf_calendar('360d')
468        write(*,*)'CALENDRIER CHOISI: Terrestre a 360 jours/an'
469      else if (calend == 'earth_365d') then
470        call ioconf_calendar('noleap')
471        write(*,*)'CALENDRIER CHOISI: Terrestre a 365 jours/an'
472      else if (calend == 'earth_366d') then
473        call ioconf_calendar('all_leap')
474        write(*,*)'CALENDRIER CHOISI: Terrestre bissextile'
475      else if (calend == 'gregorian') then
476        call ioconf_calendar('gregorian') ! not to be used by normal users
477        write(*,*)'CALENDRIER CHOISI: Gregorien'
478      else
479        write (*,*) 'ERROR : unknown calendar ', calend
480        stop 'calend should be 360d,earth_365d,earth_366d,gregorian'
481      endif
482!-----------------------------------------------------------------------
483!
484!c Date :
485!      La date est supposee donnee sous la forme [annee, numero du jour dans
486!      l annee] ; l heure est donnee dans time_ini, lu dans lmdz1d.def.
487!      On appelle ymds2ju pour convertir [annee, jour] en [jour Julien].
488!      Le numero du jour est dans "day". L heure est traitee separement.
489!      La date complete est dans "daytime" (l'unite est le jour).
490      if (nday>0) then
491         fnday=nday
492      else
493         fnday=-nday/float(day_step)
494      endif
[2332]495      print *,'fnday=',fnday
[2716]496!     start_time doit etre en FRACTION DE JOUR
[2465]497      start_time=time_ini/24.
498
[2019]499! Special case for arm_cu which lasts less than one day : 53100s !! (MPL 20111026)
500      IF(forcing_type .EQ. 61) fnday=53100./86400.
[2716]501      IF(forcing_type .EQ. 103) fnday=53100./86400.
[2019]502! Special case for amma which lasts less than one day : 64800s !! (MPL 20120216)
503      IF(forcing_type .EQ. 6) fnday=64800./86400.
[2126]504!     IF(forcing_type .EQ. 6) fnday=50400./86400.
[2672]505 IF(forcing_type .EQ. 8 ) fnday=129600./86400.
[2019]506      annee_ref = anneeref
507      mois = 1
508      day_ref = dayref
509      heure = 0.
510      itau_dyn = 0
511      itau_phy = 0
512      call ymds2ju(annee_ref,mois,day_ref,heure,day)
513      day_ini = int(day)
[3316]514      day_end = day_ini + int(fnday)
[2019]515
516      IF (forcing_type .eq.2) THEN
517! Convert the initial date of Toga-Coare to Julian day
518      call ymds2ju                                                          &
519     & (year_ini_toga,mth_ini_toga,day_ini_toga,heure,day_ju_ini_toga)
520
521      ELSEIF (forcing_type .eq.4) THEN
522! Convert the initial date of TWPICE to Julian day
523      call ymds2ju                                                          &
524     & (year_ini_twpi,mth_ini_twpi,day_ini_twpi,heure_ini_twpi              &
525     & ,day_ju_ini_twpi)
526      ELSEIF (forcing_type .eq.6) THEN
527! Convert the initial date of AMMA to Julian day
528      call ymds2ju                                                          &
529     & (year_ini_amma,mth_ini_amma,day_ini_amma,heure_ini_amma              &
530     & ,day_ju_ini_amma)
[2126]531      ELSEIF (forcing_type .eq.7) THEN
532! Convert the initial date of DICE to Julian day
533      call ymds2ju                                                         &
534     & (year_ini_dice,mth_ini_dice,day_ini_dice,heure_ini_dice             &
535     & ,day_ju_ini_dice)
[2672]536 ELSEIF (forcing_type .eq.8 ) THEN
537! Convert the initial date of GABLS4 to Julian day
538      call ymds2ju                                                         &
539     & (year_ini_gabls4,mth_ini_gabls4,day_ini_gabls4,heure_ini_gabls4     &
540     & ,day_ju_ini_gabls4)
[2332]541      ELSEIF (forcing_type .gt.100) THEN
[2191]542! Convert the initial date to Julian day
[2332]543      day_ini_cas=day_deb
544      print*,'time case',year_ini_cas,mth_ini_cas,day_ini_cas
[2191]545      call ymds2ju                                                         &
[2716]546     & (year_ini_cas,mth_ini_cas,day_ini_cas,heure_ini_cas*3600            &
[2191]547     & ,day_ju_ini_cas)
[2332]548      print*,'time case 2',day_ini_cas,day_ju_ini_cas
[2019]549      ELSEIF (forcing_type .eq.59) THEN
550! Convert the initial date of Sandu case to Julian day
551      call ymds2ju                                                          &
552     &   (year_ini_sandu,mth_ini_sandu,day_ini_sandu,                       &
553     &    time_ini*3600.,day_ju_ini_sandu)
554
555      ELSEIF (forcing_type .eq.60) THEN
556! Convert the initial date of Astex case to Julian day
557      call ymds2ju                                                          &
558     &   (year_ini_astex,mth_ini_astex,day_ini_astex,                        &
559     &    time_ini*3600.,day_ju_ini_astex)
560
561      ELSEIF (forcing_type .eq.61) THEN
562! Convert the initial date of Arm_cu case to Julian day
563      call ymds2ju                                                          &
564     & (year_ini_armcu,mth_ini_armcu,day_ini_armcu,heure_ini_armcu          &
565     & ,day_ju_ini_armcu)
566      ENDIF
567
[2716]568      IF (forcing_type .gt.100) THEN
569      daytime = day + heure_ini_cas/24. ! 1st day and initial time of the simulation
570      ELSE
[2019]571      daytime = day + time_ini/24. ! 1st day and initial time of the simulation
[2716]572      ENDIF
[2019]573! Print out the actual date of the beginning of the simulation :
574      call ju2ymds(daytime,year_print, month_print,day_print,sec_print)
575      print *,' Time of beginning : ',                                      &
576     &        year_print, month_print, day_print, sec_print
577
578!---------------------------------------------------------------------
579! Initialization of dimensions, geometry and initial state
580!---------------------------------------------------------------------
[2351]581!      call init_phys_lmdz(1,1,llm,1,(/1/)) ! job now done via iniphysiq
[2354]582!     but we still need to initialize dimphy module (klon,klev,etc.)  here.
583      call init_dimphy(1,llm)
[2019]584      call suphel
585      call infotrac_init
586
[3316]587      if (nqtot>nqmx) STOP 'Augmenter nqmx dans lmdz1d.F'
[2019]588      allocate(q(llm,nqtot)) ; q(:,:)=0.
589      allocate(dq(llm,nqtot))
590      allocate(dq_dyn(llm,nqtot))
591      allocate(d_q_adv(llm,nqtot))
[2181]592      allocate(d_q_nudge(llm,nqtot))
[2933]593!      allocate(d_th_adv(llm))
[2019]594
[2393]595      q(:,:) = 0.
596      dq(:,:) = 0.
597      dq_dyn(:,:) = 0.
598      d_q_adv(:,:) = 0.
599      d_q_nudge(:,:) = 0.
600
[2019]601!
602!   No ozone climatology need be read in this pre-initialization
603!          (phys_state_var_init is called again in physiq)
604      read_climoz = 0
605!
606      call phys_state_var_init(read_climoz)
607
608      if (ngrid.ne.klon) then
609         print*,'stop in inifis'
610         print*,'Probleme de dimensions :'
611         print*,'ngrid = ',ngrid
612         print*,'klon  = ',klon
613         stop
614      endif
615!!!=====================================================================
616!!! Feedback forcing values for Gateaux differentiation (al1)
617!!!=====================================================================
618!!! Surface Planck forcing bracketing call radiation
619!!      surf_Planck = 0.
620!!      surf_Conv   = 0.
621!!      write(*,*) 'Gateaux-dif Planck,Conv:',surf_Planck,surf_Conv
622!!! a mettre dans le lmdz1d.def ou autre
623!!
624!!
625      qsol = qsolinp
626      qsurf = fq_sat(tsurf,psurf/100.)
627      day1= day_ini
628      time=daytime-day
629      ts_toga(1)=tsurf ! needed by read_tsurf1d.F
630      rho(1)=psurf/(rd*tsurf*(1.+(rv/rd-1.)*qsurf))
631
632!
633!! mpl et jyg le 22/08/2012 :
634!!  pour que les cas a flux de surface imposes marchent
635      IF(.NOT.ok_flux_surf.or.max(abs(wtsurf),abs(wqsurf))>0.) THEN
636       fsens=-wtsurf*rcpd*rho(1)
637       flat=-wqsurf*rlvtt*rho(1)
638       print *,'Flux: ok_flux wtsurf wqsurf',ok_flux_surf,wtsurf,wqsurf
639      ENDIF
640      print*,'Flux sol ',fsens,flat
641!!      ok_flux_surf=.false.
642!!      fsens=-wtsurf*rcpd*rho(1)
643!!      flat=-wqsurf*rlvtt*rho(1)
644!!!!
645
646! Vertical discretization and pressure levels at half and mid levels:
647
648      pa   = 5e4
649!!      preff= 1.01325e5
650      preff = psurf
651      IF (ok_old_disvert) THEN
652        call disvert0(pa,preff,ap,bp,dpres,presnivs,nivsigs,nivsig)
653        print *,'On utilise disvert0'
[2786]654        aps(1:llm)=0.5*(ap(1:llm)+ap(2:llm+1))
655        bps(1:llm)=0.5*(bp(1:llm)+bp(2:llm+1))
656        scaleheight=8.
657        pseudoalt(1:llm)=-scaleheight*log(presnivs(1:llm)/preff)
[2019]658      ELSE
[2040]659        call disvert()
[2019]660        print *,'On utilise disvert'
661!       Nouvelle version disvert permettant d imposer ap,bp (modif L.Guez) MPL 18092012
662!       Dans ce cas, on lit ap,bp dans le fichier hybrid.txt
663      ENDIF
[2786]664
[2019]665      sig_s=presnivs/preff
666      plev =ap+bp*psurf
667      play = 0.5*(plev(1:llm)+plev(2:llm+1))
[2373]668      zlay=-rd*300.*log(play/psurf)/rg ! moved after reading profiles
[2019]669
670      IF (forcing_type .eq. 59) THEN
671! pour forcing_sandu, on cherche l'indice le plus proche de 700hpa#3000m
672      write(*,*) '***********************'
673      do l = 1, llm
674       write(*,*) 'l,play(l),presnivs(l): ',l,play(l),presnivs(l)
675       if (trouve_700 .and. play(l).le.70000) then
676         llm700=l
677         print *,'llm700,play=',llm700,play(l)/100.
678         trouve_700= .false.
679       endif
680      enddo
681      write(*,*) '***********************'
682      ENDIF
683
684!
685!=====================================================================
686! EVENTUALLY, READ FORCING DATA :
687!=====================================================================
688
689#include "1D_read_forc_cases.h"
690
691      if (forcing_GCM2SCM) then
692        write (*,*) 'forcing_GCM2SCM not yet implemented'
693        stop 'in initialization'
694      endif ! forcing_GCM2SCM
695
696      print*,'mxcalc=',mxcalc
[2373]697!     print*,'zlay=',zlay(mxcalc)
[2019]698      print*,'play=',play(mxcalc)
699
[2332]700!Al1 pour SST forced, appell?? depuis ocean_forced_noice
[2019]701      ts_cur = tsurf ! SST used in read_tsurf1d
702!=====================================================================
703! Initialisation de la physique :
704!=====================================================================
705
706!  Rq: conf_phys.F90 lit tous les flags de physiq.def; conf_phys appele depuis physiq.F
707!
708! day_step, iphysiq lus dans gcm.def ci-dessus
709! timestep: calcule ci-dessous from rday et day_step
710! ngrid=1
711! llm: defini dans .../modipsl/modeles/LMDZ4/libf/grid/dimension
712! rday: defini dans suphel.F (86400.)
713! day_ini: lu dans run.def (dayref)
714! rlat_rad,rlon-rad: transformes en radian de rlat,rlon lus dans lmdz1d.def (en degres)
715! airefi,zcufi,zcvfi initialises au debut de ce programme
716! rday,ra,rg,rd,rcpd declares dans YOMCST.h et calcules dans suphel.F
717      day_step = float(nsplit_phys)*day_step/float(iphysiq)
718      write (*,*) 'Time step divided by nsplit_phys (=',nsplit_phys,')'
719      timestep =rday/day_step
720      dtime_frcg = timestep
721!
722      zcufi=airefi
723      zcvfi=airefi
724!
[2403]725      rlat_rad(1)=xlat*rpi/180.
726      rlon_rad(1)=xlon*rpi/180.
[2019]727
[2347]728     ! Ehouarn: iniphysiq requires arrays related to (3D) dynamics grid,
729     ! e.g. for cell boundaries, which are meaningless in 1D; so pad these
730     ! with '0.' when necessary
[2351]731      call iniphysiq(iim,jjm,llm, &
732           1,comm_lmdz, &
733           rday,day_ini,timestep,  &
[2347]734           (/rlat_rad(1),0./),(/0./), &
735           (/0.,0./),(/rlon_rad(1),0./),  &
736           (/ (/airefi,0./),(/0.,0./) /), &
737           (/zcufi,0.,0.,0./), &
738           (/zcvfi,0./), &
739           ra,rg,rd,rcpd,1)
[2019]740      print*,'apres iniphysiq'
741
742! 2 PARAMETRES QUI DEVRAIENT ETRE LUS DANS run.def MAIS NE LE SONT PAS ICI:
743      co2_ppm= 330.0
744      solaire=1370.0
745
746! Ecriture du startphy avant le premier appel a la physique.
747! On le met juste avant pour avoir acces a tous les champs
748
749      if (ok_writedem) then
750
751!--------------------------------------------------------------------------
752! pbl_surface_init (called here) and pbl_surface_final (called by phyredem)
753! need : qsol fder snow qsurf evap rugos agesno ftsoil
754!--------------------------------------------------------------------------
755
756        type_ocean = "force"
757        run_off_lic_0(1) = restart_runoff
758        call fonte_neige_init(run_off_lic_0)
759
760        fder=0.
[2672]761        snsrf(1,:)=snowmass ! masse de neige des sous surface
[2019]762        qsurfsrf(1,:)=qsurf ! humidite de l'air des sous surface
[2244]763        fevap=0.
764        z0m(1,:)=rugos     ! couverture de neige des sous surface
[2672]765        z0h(1,:)=rugosh    ! couverture de neige des sous surface
[2019]766        agesno  = xagesno
767        tsoil(:,:,:)=tsurf
768!------ AMMA 2e run avec modele sol et rayonnement actif (MPL 23052012)
769!       tsoil(1,1,1)=299.18
770!       tsoil(1,2,1)=300.08
771!       tsoil(1,3,1)=301.88
772!       tsoil(1,4,1)=305.48
773!       tsoil(1,5,1)=308.00
774!       tsoil(1,6,1)=308.00
775!       tsoil(1,7,1)=308.00
776!       tsoil(1,8,1)=308.00
777!       tsoil(1,9,1)=308.00
778!       tsoil(1,10,1)=308.00
779!       tsoil(1,11,1)=308.00
780!-----------------------------------------------------------------------
[2244]781        call pbl_surface_init(fder, snsrf, qsurfsrf, tsoil)
[2019]782
783!------------------ prepare limit conditions for limit.nc -----------------
784!--   Ocean force
785
786        print*,'avant phyredem'
787        pctsrf(1,:)=0.
[2672]788          if (nat_surf.eq.0.) then
[2019]789          pctsrf(1,is_oce)=1.
790          pctsrf(1,is_ter)=0.
[2672]791          pctsrf(1,is_lic)=0.
792          pctsrf(1,is_sic)=0.
793        else if (nat_surf .eq. 1) then
[2019]794          pctsrf(1,is_oce)=0.
795          pctsrf(1,is_ter)=1.
[2672]796          pctsrf(1,is_lic)=0.
797          pctsrf(1,is_sic)=0.
798        else if (nat_surf .eq. 2) then
799          pctsrf(1,is_oce)=0.
800          pctsrf(1,is_ter)=0.
801          pctsrf(1,is_lic)=1.
802          pctsrf(1,is_sic)=0.
803        else if (nat_surf .eq. 3) then
804          pctsrf(1,is_oce)=0.
805          pctsrf(1,is_ter)=0.
806          pctsrf(1,is_lic)=0.
807          pctsrf(1,is_sic)=1.
[2019]808
[2672]809     end if
810
811
[2019]812        print*,'nat_surf,pctsrf(1,is_oce),pctsrf(1,is_ter)',nat_surf         &
813     &        ,pctsrf(1,is_oce),pctsrf(1,is_ter)
814
815        zmasq=pctsrf(1,is_ter)+pctsrf(1,is_lic)
816        zpic = zpicinp
817        ftsol=tsurf
[2237]818        nsw=6 ! on met le nb de bandes SW=6, pour initialiser
819              ! 6 albedo, mais on peut quand meme tourner avec
820              ! moins. Seules les 2 ou 4 premiers seront lus
821        falb_dir=albedo
822        falb_dif=albedo
[2019]823        rugoro=rugos
824        t_ancien(1,:)=temp(:)
825        q_ancien(1,:)=q(:,1)
[2933]826        ql_ancien = 0.
827        qs_ancien = 0.
828        prlw_ancien = 0.
829        prsw_ancien = 0.
830        prw_ancien = 0.
[2565]831!jyg<
832!!        pbl_tke(:,:,:)=1.e-8
833        pbl_tke(:,:,:)=0.
834        pbl_tke(:,2,:)=1.e-2
835        PRINT *, ' pbl_tke dans lmdz1d '
[2611]836        if (prt_level .ge. 5) then
837         DO nsrf = 1,4
838           PRINT *,'pbl_tke(1,:,',nsrf,') ',pbl_tke(1,:,nsrf)
839         ENDDO
840        end if
[2019]841
[2565]842!>jyg
843
[2019]844        rain_fall=0.
845        snow_fall=0.
846        solsw=0.
847        sollw=0.
[2393]848        sollwdown=rsigma*tsurf**4
[2019]849        radsol=0.
850        rnebcon=0.
851        ratqs=0.
852        clwcon=0.
[2393]853        zmax0 = 0.
[2019]854        zmea=0.
855        zstd=0.
856        zsig=0.
857        zgam=0.
858        zval=0.
859        zthe=0.
860        sig1=0.
861        w01=0.
[2393]862        wake_cstar = 0.
863        wake_deltaq = 0.
864        wake_deltat = 0.
[2565]865        wake_delta_pbl_TKE(:,:,:) = 0.
[2393]866        delta_tsurf = 0.
867        wake_fip = 0.
868        wake_pe = 0.
869        wake_s = 0.
[2635]870        wake_dens = 0.
[2393]871        ale_bl = 0.
872        ale_bl_trig = 0.
873        alp_bl = 0.
874        IF (ALLOCATED(du_gwd_rando)) du_gwd_rando = 0.
875        IF (ALLOCATED(du_gwd_front)) du_gwd_front = 0.
876        entr_therm = 0.
877        detr_therm = 0.
878        f0 = 0.
879        fm_therm = 0.
[2019]880        u_ancien(1,:)=u(:)
881        v_ancien(1,:)=v(:)
882 
883!------------------------------------------------------------------------
884! Make file containing restart for the physics (startphy.nc)
885!
886! NB: List of the variables to be written by phyredem (via put_field):
887! rlon,rlat,zmasq,pctsrf(:,is_ter),pctsrf(:,is_lic),pctsrf(:,is_oce)
888! pctsrf(:,is_sic),ftsol(:,nsrf),tsoil(:,isoil,nsrf),qsurf(:,nsrf)
[2243]889! qsol,falb_dir(:,nsrf),falb_dif(:,nsrf),evap(:,nsrf),snow(:,nsrf)
[2393]890! radsol,solsw,sollw, sollwdown,fder,rain_fall,snow_fall,frugs(:,nsrf)
[2019]891! agesno(:,nsrf),zmea,zstd,zsig,zgam,zthe,zpic,zval,rugoro
[2255]892! t_ancien,q_ancien,,frugs(:,is_oce),clwcon(:,1),rnebcon(:,1),ratqs(:,1)
893! run_off_lic_0,pbl_tke(:,1:klev,nsrf), zmax0,f0,sig1,w01
[2635]894! wake_deltat,wake_deltaq,wake_s,wake_dens,wake_cstar,
895! wake_fip,wake_delta_pbl_tke(:,1:klev,nsrf)
[2565]896!
897! NB2: The content of the startphy.nc file depends on some flags defined in
898! the ".def" files. However, since conf_phys is not called in lmdz1d.F90, these flags have
899! to be set at some arbitratry convenient values.
[2019]900!------------------------------------------------------------------------
901!Al1 =============== restart option ==========================
902        if (.not.restart) then
[2565]903          iflag_pbl = 5
[2019]904          call phyredem ("startphy.nc")
905        else
906! (desallocations)
907        print*,'callin surf final'
[2243]908          call pbl_surface_final( fder, snsrf, qsurfsrf, tsoil)
[2019]909        print*,'after surf final'
910          CALL fonte_neige_final(run_off_lic_0)
911        endif
912
913        ok_writedem=.false.
914        print*,'apres phyredem'
915
916      endif ! ok_writedem
917     
918!------------------------------------------------------------------------
919! Make file containing boundary conditions (limit.nc) **Al1->restartdyn***
920! --------------------------------------------------
921! NB: List of the variables to be written in limit.nc
922!     (by writelim.F, subroutine of 1DUTILS.h):
923!        phy_nat,phy_alb,phy_sst,phy_bil,phy_rug,phy_ice,
924!        phy_fter,phy_foce,phy_flic,phy_fsic)
925!------------------------------------------------------------------------
926      do i=1,yd
927        phy_nat(i)  = nat_surf
928        phy_alb(i)  = albedo
929        phy_sst(i)  = tsurf ! read_tsurf1d will be used instead
930        phy_rug(i)  = rugos
931        phy_fter(i) = pctsrf(1,is_ter)
932        phy_foce(i) = pctsrf(1,is_oce)
933        phy_fsic(i) = pctsrf(1,is_sic)
934        phy_flic(i) = pctsrf(1,is_lic)
935      enddo
936
937! fabrication de limit.nc
938      call writelim (1,phy_nat,phy_alb,phy_sst,phy_bil,phy_rug,             &
939     &               phy_ice,phy_fter,phy_foce,phy_flic,phy_fsic)
940
941
942      call phys_state_var_end
943!Al1
944      if (restart) then
945        print*,'call to restart dyn 1d'
946        Call dyn1deta0("start1dyn.nc",plev,play,phi,phis,presnivs,          &
947     &              u,v,temp,q,omega2)
948
949       print*,'fnday,annee_ref,day_ref,day_ini',                            &
950     &     fnday,annee_ref,day_ref,day_ini
951!**      call ymds2ju(annee_ref,mois,day_ini,heure,day)
952       day = day_ini
953       day_end = day_ini + nday
954       daytime = day + time_ini/24. ! 1st day and initial time of the simulation
955
956! Print out the actual date of the beginning of the simulation :
957       call ju2ymds(daytime, an, mois, jour, heure)
958       print *,' Time of beginning : y m d h',an, mois,jour,heure/3600.
959
960       day = int(daytime)
961       time=daytime-day
962 
963       print*,'****** intialised fields from restart1dyn *******'
964       print*,'plev,play,phi,phis,presnivs,u,v,temp,q,omega2'
965       print*,'temp(1),q(1,1),u(1),v(1),plev(1),phis :'
966       print*,temp(1),q(1,1),u(1),v(1),plev(1),phis
967! raz for safety
968       do l=1,llm
969         dq_dyn(l,1) = 0.
970       enddo
971      endif
972!Al1 ================  end restart =================================
973      IF (ecrit_slab_oc.eq.1) then
974         open(97,file='div_slab.dat',STATUS='UNKNOWN')
975       elseif (ecrit_slab_oc.eq.0) then
976         open(97,file='div_slab.dat',STATUS='OLD')
977       endif
[2181]978!
979!---------------------------------------------------------------------
980!    Initialize target profile for RHT nudging if needed
981!---------------------------------------------------------------------
982      if (nudge(inudge_RHT)) then
983        call nudge_RHT_init(plev,play,temp,q(:,1),t_targ,rh_targ)
984      endif
985      if (nudge(inudge_UV)) then
986        call nudge_UV_init(plev,play,u,v,u_targ,v_targ)
987      endif
988!
[2019]989!=====================================================================
[3223]990       CALL iophys_ini
[2019]991! START OF THE TEMPORAL LOOP :
992!=====================================================================
993           
[2611]994      it_end = nint(fnday*day_step)
995!test JLD     it_end = 10
996      do while(it.le.it_end)
[2019]997
998       if (prt_level.ge.1) then
999         print*,'XXXXXXXXXXXXXXXXXXX ITAP,day,time=',                       &
[2611]1000     &             it,day,time,it_end,day_step
[2019]1001         print*,'PAS DE TEMPS ',timestep
1002       endif
1003!Al1 demande de restartphy.nc
[2611]1004       if (it.eq.it_end) lastcall=.True.
[2019]1005
1006!---------------------------------------------------------------------
1007! Interpolation of forcings in time and onto model levels
1008!---------------------------------------------------------------------
1009
1010#include "1D_interp_cases.h"
1011
1012      if (forcing_GCM2SCM) then
1013        write (*,*) 'forcing_GCM2SCM not yet implemented'
1014        stop 'in time loop'
1015      endif ! forcing_GCM2SCM
1016
1017!---------------------------------------------------------------------
1018!  Geopotential :
1019!---------------------------------------------------------------------
1020
1021        phi(1)=RD*temp(1)*(plev(1)-play(1))/(.5*(plev(1)+play(1)))
1022        do l = 1, llm-1
1023          phi(l+1)=phi(l)+RD*(temp(l)+temp(l+1))*                           &
1024     &    (play(l)-play(l+1))/(play(l)+play(l+1))
1025        enddo
1026
1027!---------------------------------------------------------------------
1028! Listing output for debug prt_level>=1
1029!---------------------------------------------------------------------
1030       if (prt_level>=1) then
1031         print *,' avant physiq : -------- day time ',day,time
1032         write(*,*) 'firstcall,lastcall,phis',                               &
1033     &               firstcall,lastcall,phis
[2611]1034       end if
1035       if (prt_level>=5) then
[2019]1036         write(*,'(a10,2a4,4a13)') 'BEFOR1 IT=','it','l',                   &
1037     &        'presniv','plev','play','phi'
1038         write(*,'(a10,2i4,4f13.2)') ('BEFOR1 IT= ',it,l,                   &
1039     &         presnivs(l),plev(l),play(l),phi(l),l=1,llm)
1040         write(*,'(a11,2a4,a11,6a8)') 'BEFOR2','it','l',                    &
1041     &         'presniv','u','v','temp','q1','q2','omega2'
1042         write(*,'(a11,2i4,f11.2,5f8.2,e10.2)') ('BEFOR2 IT= ',it,l,         &
1043     &   presnivs(l),u(l),v(l),temp(l),q(l,1),q(l,2),omega2(l),l=1,llm)
1044       endif
1045
1046!---------------------------------------------------------------------
1047!   Call physiq :
1048!---------------------------------------------------------------------
[2335]1049       call physiq(ngrid,llm, &
[2600]1050                    firstcall,lastcall,timestep, &
1051                    plev,play,phi,phis,presnivs, &
1052                    u,v, rot, temp,q,omega2, &
1053                    du_phys,dv_phys,dt_phys,dq,dpsrf)
1054                firstcall=.false.
[2019]1055
1056!---------------------------------------------------------------------
[2611]1057! Listing output for debug
[2019]1058!---------------------------------------------------------------------
[2611]1059        if (prt_level>=5) then
[2019]1060          write(*,'(a11,2a4,4a13)') 'AFTER1 IT=','it','l',                  &
1061     &        'presniv','plev','play','phi'
1062          write(*,'(a11,2i4,4f13.2)') ('AFTER1 it= ',it,l,                  &
1063     &    presnivs(l),plev(l),play(l),phi(l),l=1,llm)
1064          write(*,'(a11,2a4,a11,6a8)') 'AFTER2','it','l',                   &
1065     &         'presniv','u','v','temp','q1','q2','omega2'
1066          write(*,'(a11,2i4,f11.2,5f8.2,e10.2)') ('AFTER2 it= ',it,l,       &
1067     &    presnivs(l),u(l),v(l),temp(l),q(l,1),q(l,2),omega2(l),l=1,llm)
1068          write(*,'(a11,2a4,a11,5a8)') 'AFTER3','it','l',                   &
1069     &         'presniv','du_phys','dv_phys','dt_phys','dq1','dq2'   
1070           write(*,'(a11,2i4,f11.2,5f8.2)') ('AFTER3 it= ',it,l,            &
1071     &      presnivs(l),86400*du_phys(l),86400*dv_phys(l),                   &
1072     &       86400*dt_phys(l),86400*dq(l,1),dq(l,2),l=1,llm)
1073          write(*,*) 'dpsrf',dpsrf
1074        endif
1075!---------------------------------------------------------------------
1076!   Add physical tendencies :
1077!---------------------------------------------------------------------
1078
1079       fcoriolis=2.*sin(rpi*xlat/180.)*romega
1080       if (forcing_radconv .or. forcing_fire) then
1081         fcoriolis=0.0
1082         dt_cooling=0.0
[2920]1083         d_t_adv=0.0
[2019]1084         d_q_adv=0.0
1085       endif
[2393]1086!      print*, 'calcul de fcoriolis ', fcoriolis
[2019]1087
1088       if (forcing_toga .or. forcing_GCSSold .or. forcing_twpice            &
[2716]1089     &    .or.forcing_amma .or. forcing_type.eq.101) then
[2019]1090         fcoriolis=0.0 ; ug=0. ; vg=0.
1091       endif
[2716]1092
1093       if(forcing_rico) then
[2019]1094          dt_cooling=0.
[2716]1095       endif
[2019]1096
[2983]1097!CRio:Attention modif sp??cifique cas de Caroline
1098      if (forcing_type==-1) then
[2933]1099         fcoriolis=0.
1100!Nudging
1101       
1102!on calcule dt_cooling
1103        do l=1,llm
1104        if (play(l).ge.20000.) then
1105            dt_cooling(l)=-1.5/86400.
1106        elseif ((play(l).ge.10000.).and.((play(l).lt.20000.))) then
1107            dt_cooling(l)=-1.5/86400.*(play(l)-10000.)/(10000.)-1./86400.*(20000.-play(l))/10000.*(temp(l)-200.)
1108        else
1109            dt_cooling(l)=-1.*(temp(l)-200.)/86400.
1110        endif
1111        enddo
1112
1113      endif     
1114!RC
[3223]1115      if (forcing_sandu) then
1116         ug(1:llm)=u_mod(1:llm)
1117         vg(1:llm)=v_mod(1:llm)
1118      endif
[2933]1119
[2611]1120      IF (prt_level >= 5) print*, 'fcoriolis, xlat,mxcalc ', &
[2393]1121                                   fcoriolis, xlat,mxcalc
[2019]1122
[2393]1123!       print *,'u-ug=',u-ug
[2019]1124
1125!!!!!!!!!!!!!!!!!!!!!!!!
1126! Geostrophic wind
[3223]1127! Le calcul ci dessous est insuffisamment precis
1128!      du_age(1:mxcalc)=fcoriolis*(v(1:mxcalc)-vg(1:mxcalc))
1129!      dv_age(1:mxcalc)=-fcoriolis*(u(1:mxcalc)-ug(1:mxcalc))
[2019]1130!!!!!!!!!!!!!!!!!!!!!!!!
1131       sfdt = sin(0.5*fcoriolis*timestep)
1132       cfdt = cos(0.5*fcoriolis*timestep)
[2393]1133!       print *,'fcoriolis,sfdt,cfdt,timestep',fcoriolis,sfdt,cfdt,timestep
[2019]1134!
1135        du_age(1:mxcalc)= -2.*sfdt/timestep*                                &
1136     &          (sfdt*(u(1:mxcalc)-ug(1:mxcalc)) -                          &
1137     &           cfdt*(v(1:mxcalc)-vg(1:mxcalc))  )
1138!!     : fcoriolis*(v(1:mxcalc)-vg(1:mxcalc))
1139!
1140       dv_age(1:mxcalc)= -2.*sfdt/timestep*                                 &
1141     &          (cfdt*(u(1:mxcalc)-ug(1:mxcalc)) +                           &
1142     &           sfdt*(v(1:mxcalc)-vg(1:mxcalc))  )
1143!!     : -fcoriolis*(u(1:mxcalc)-ug(1:mxcalc))
1144!
[2181]1145!!!!!!!!!!!!!!!!!!!!!!!!
1146!  Nudging
1147!!!!!!!!!!!!!!!!!!!!!!!!
1148      d_t_nudge(:) = 0.
1149      d_q_nudge(:,:) = 0.
1150      d_u_nudge(:) = 0.
1151      d_v_nudge(:) = 0.
1152      if (nudge(inudge_RHT)) then
1153        call nudge_RHT(timestep,plev,play,t_targ,rh_targ,temp,q(:,1),     &
1154    &                  d_t_nudge,d_q_nudge(:,1))
1155      endif
1156      if (nudge(inudge_UV)) then
1157        call nudge_UV(timestep,plev,play,u_targ,v_targ,u,v,     &
1158    &                  d_u_nudge,d_v_nudge)
1159      endif
1160!
[2019]1161!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
1162!         call  writefield_phy('dv_age' ,dv_age,llm)
1163!         call  writefield_phy('du_age' ,du_age,llm)
1164!         call  writefield_phy('du_phys' ,du_phys,llm)
1165!         call  writefield_phy('u_tend' ,u,llm)
1166!         call  writefield_phy('u_g' ,ug,llm)
1167!
1168!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
1169!! Increment state variables
1170!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
[2611]1171    IF (flag_inhib_forcing == 0) then ! if tendency of forcings should be added
1172
[2019]1173! pour les cas sandu et astex, on reclacule u,v,q,temp et teta dans 1D_nudge_sandu_astex.h
1174! au dessus de 700hpa, on relaxe vers les profils initiaux
1175      if (forcing_sandu .OR. forcing_astex) then
1176#include "1D_nudge_sandu_astex.h"
1177      else
1178        u(1:mxcalc)=u(1:mxcalc) + timestep*(                                &
1179     &              du_phys(1:mxcalc)                                       &
[2191]1180     &             +du_age(1:mxcalc)+du_adv(1:mxcalc)                       &
[2181]1181     &             +d_u_nudge(1:mxcalc) )           
[2019]1182        v(1:mxcalc)=v(1:mxcalc) + timestep*(                                 &
1183     &              dv_phys(1:mxcalc)                                       &
[2191]1184     &             +dv_age(1:mxcalc)+dv_adv(1:mxcalc)                       &
[2181]1185     &             +d_v_nudge(1:mxcalc) )
[2019]1186        q(1:mxcalc,:)=q(1:mxcalc,:)+timestep*(                              &
1187     &                dq(1:mxcalc,:)                                        &
[2181]1188     &               +d_q_adv(1:mxcalc,:)                                   &
1189     &               +d_q_nudge(1:mxcalc,:) )
[2019]1190
[2611]1191        if (prt_level.ge.3) then
[2019]1192          print *,                                                          &
[2920]1193     &    'physiq-> temp(1),dt_phys(1),d_t_adv(1),dt_cooling(1) ',         &
1194     &              temp(1),dt_phys(1),d_t_adv(1),dt_cooling(1)
[2373]1195           print* ,'dv_phys=',dv_phys
1196           print* ,'dv_age=',dv_age
1197           print* ,'dv_adv=',dv_adv
1198           print* ,'d_v_nudge=',d_v_nudge
[2019]1199           print*, v
1200           print*, vg
1201        endif
1202
1203        temp(1:mxcalc)=temp(1:mxcalc)+timestep*(                            &
1204     &              dt_phys(1:mxcalc)                                       &
[2920]1205     &             +d_t_adv(1:mxcalc)                                      &
[2181]1206     &             +d_t_nudge(1:mxcalc)                                      &
[2019]1207     &             +dt_cooling(1:mxcalc))  ! Taux de chauffage ou refroid.
1208
1209      endif  ! forcing_sandu or forcing_astex
1210
1211        teta=temp*(pzero/play)**rkappa
1212!
1213!---------------------------------------------------------------------
1214!   Nudge soil temperature if requested
1215!---------------------------------------------------------------------
1216
[2565]1217      IF (nudge_tsoil .AND. .NOT. lastcall) THEN
[2019]1218       ftsoil(1,isoil_nudge,:) = ftsoil(1,isoil_nudge,:)                     &
1219     &  -timestep/tau_soil_nudge*(ftsoil(1,isoil_nudge,:)-Tsoil_nudge)
1220      ENDIF
1221
1222!---------------------------------------------------------------------
1223!   Add large-scale tendencies (advection, etc) :
1224!---------------------------------------------------------------------
1225
1226!cc nrlmd
1227!cc        tmpvar=teta
1228!cc        call advect_vert(llm,omega,timestep,tmpvar,plev)
1229!cc
1230!cc        teta(1:mxcalc)=tmpvar(1:mxcalc)
1231!cc        tmpvar(:)=q(:,1)
1232!cc        call advect_vert(llm,omega,timestep,tmpvar,plev)
1233!cc        q(1:mxcalc,1)=tmpvar(1:mxcalc)
1234!cc        tmpvar(:)=q(:,2)
1235!cc        call advect_vert(llm,omega,timestep,tmpvar,plev)
1236!cc        q(1:mxcalc,2)=tmpvar(1:mxcalc)
1237
[2611]1238   END IF ! end if tendency of tendency should be added
1239
[2019]1240!---------------------------------------------------------------------
1241!   Air temperature :
1242!---------------------------------------------------------------------       
1243        if (lastcall) then
1244          print*,'Pas de temps final ',it
1245          call ju2ymds(daytime, an, mois, jour, heure)
1246          print*,'a la date : a m j h',an, mois, jour ,heure/3600.
1247        endif
1248
1249!  incremente day time
1250!        print*,'daytime bef',daytime,1./day_step
1251        daytime = daytime+1./day_step
1252!Al1dbg
1253        day = int(daytime+0.1/day_step)
1254!        time = max(daytime-day,0.0)
1255!Al1&jyg: correction de bug
1256!cc        time = real(mod(it,day_step))/day_step
1257        time = time_ini/24.+real(mod(it,day_step))/day_step
1258!        print*,'daytime nxt time',daytime,time
1259        it=it+1
1260
1261      enddo
1262
1263!Al1
1264      if (ecrit_slab_oc.ne.-1) close(97)
1265
1266!Al1 Call to 1D equivalent of dynredem (an,mois,jour,heure ?)
1267! -------------------------------------
1268       call dyn1dredem("restart1dyn.nc",                                    &
1269     &              plev,play,phi,phis,presnivs,                            &
1270     &              u,v,temp,q,omega2)
1271
1272        CALL abort_gcm ('lmdz1d   ','The End  ',0)
1273
1274      end
1275
1276#include "1DUTILS.h"
1277#include "1Dconv.h"
1278
[2239]1279!#endif
[2019]1280
[2716]1281
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