source: LMDZ6/branches/Amaury_dev/libf/phylmd/simu_airs.F90 @ 5119

Last change on this file since 5119 was 5119, checked in by abarral, 4 months ago

enforce PRIVATE by default in several modules, expose PUBLIC as needed
move eigen.f90 to obsolete/
(lint) aslong the way

File size: 35.6 KB
Line 
1module m_simu_airs
2
3  USE lmdz_print_control, ONLY: prt_level, lunout
4  USE lmdz_abort_physic, ONLY: abort_physic
5
6  IMPLICIT NONE
7
8  REAL, PARAMETER :: tau_thresh = 0.05 ! seuil nuages detectables
9  REAL, PARAMETER :: p_thresh = 445.   ! seuil nuages hauts
10  REAL, PARAMETER :: em_min = 0.2      ! seuils nuages semi-transp
11  REAL, PARAMETER :: em_max = 0.85
12  REAL, PARAMETER :: undef = 999.
13
14CONTAINS
15
16  REAL function search_tropopause(P, T, alt, N) result(P_tropo)
17    ! this function searches for the tropopause pressure in [hPa].
18    ! The search is based on ideology described in
19    ! Reichler et al., Determining the tropopause height from gridded data,
20    ! GRL, 30(20) 2042, doi:10.1029/2003GL018240, 2003
21
22    INTEGER N, i, i_lev, first_point, exit_flag, i_dir
23    REAL P(N), T(N), alt(N), slope(N)
24    REAL P_min, P_max, slope_limit, slope_2km, &
25            delta_alt_limit, tmp, delta_alt
26    PARAMETER(P_min = 75.0, P_max = 470.0)   ! hPa
27    PARAMETER(slope_limit = 0.002)         ! 2 K/km converted to K/m
28    PARAMETER(delta_alt_limit = 2000.0)    ! 2000 meters
29
30    do i = 1, N - 1
31      slope(i) = -(T(i + 1) - T(i)) / (alt(i + 1) - alt(i))
32    END DO
33    slope(N) = slope(N - 1)
34
35    IF (P(1)>P(N)) THEN
36      i_dir = 1
37      i = 1
38    else
39      i_dir = -1
40      i = N
41    end if
42
43    first_point = 0
44    exit_flag = 0
45    do while(exit_flag==0)
46      IF (P(i)>=P_min.AND.P(i)<=P_max) THEN
47        IF (first_point>0) THEN
48          delta_alt = alt(i) - alt(first_point)
49          IF (delta_alt>=delta_alt_limit) THEN
50            slope_2km = (T(first_point) - T(i)) / delta_alt
51            IF (slope_2km<slope_limit) THEN
52              exit_flag = 1
53            else
54              first_point = 0
55            end if
56          end if
57        end if
58        IF (first_point==0.AND.slope(i)<slope_limit) first_point = i
59      end if
60      i = i + i_dir
61      IF (i<=1.OR.i>=N) exit_flag = 1
62    END DO
63
64    IF (first_point<=0) P_tropo = 65.4321
65    IF (first_point==1) P_tropo = 64.5432
66    IF (first_point>1) THEN
67      tmp = (slope_limit - slope(first_point)) / (slope(first_point + 1) - &
68              slope(first_point)) * (P(first_point + 1) - P(first_point))
69      P_tropo = P(first_point) + tmp
70      ! PRINT*, 'P_tropo= ', tmp, P(first_point), P_tropo
71    end if
72
73    ! Ajout Marine
74    IF (P_tropo < 60. .OR. P_tropo > 470.) THEN
75      P_tropo = 999.
76    endif
77
78  END FUNCTION search_tropopause
79
80
81  SUBROUTINE cloud_structure(len_cs, rneb_cs, temp_cs, &
82          emis_cs, iwco_cs, &
83          pres_cs, dz_cs, rhodz_cs, rad_cs, &
84          cc_tot_cs, cc_hc_cs, cc_hist_cs, &
85          cc_Cb_cs, cc_ThCi_cs, cc_Anv_cs, &
86          pcld_hc_cs, tcld_hc_cs, &
87          em_hc_cs, iwp_hc_cs, deltaz_hc_cs, &
88          pcld_Cb_cs, tcld_Cb_cs, em_Cb_cs, &
89          pcld_ThCi_cs, tcld_ThCi_cs, em_ThCi_cs, &
90          pcld_Anv_cs, tcld_Anv_cs, em_Anv_cs, &
91          em_hist_cs, iwp_hist_cs, deltaz_hist_cs, rad_hist_cs)
92
93    INTEGER :: i, n, nss
94
95    INTEGER, INTENT(IN) :: len_cs
96    REAL, DIMENSION(:), INTENT(IN) :: rneb_cs, temp_cs
97    REAL, DIMENSION(:), INTENT(IN) :: emis_cs, iwco_cs, rad_cs
98    REAL, DIMENSION(:), INTENT(IN) :: pres_cs, dz_cs, rhodz_cs
99
100    REAL, INTENT(OUT) :: cc_tot_cs, cc_hc_cs, cc_hist_cs, &
101            cc_Cb_cs, cc_ThCi_cs, cc_Anv_cs, &
102            pcld_hc_cs, tcld_hc_cs, em_hc_cs, iwp_hc_cs, &
103            pcld_Cb_cs, tcld_Cb_cs, em_Cb_cs, &
104            pcld_ThCi_cs, tcld_ThCi_cs, em_ThCi_cs, &
105            pcld_Anv_cs, tcld_Anv_cs, em_Anv_cs, &
106            em_hist_cs, iwp_hist_cs, &
107            deltaz_hc_cs, deltaz_hist_cs, rad_hist_cs
108
109    REAL, DIMENSION(len_cs) :: rneb_ord
110    REAL :: rneb_min
111
112    REAL, DIMENSION(:), ALLOCATABLE :: s, s_hc, s_hist, rneb_max
113    REAL, DIMENSION(:), ALLOCATABLE :: sCb, sThCi, sAnv
114    REAL, DIMENSION(:), ALLOCATABLE :: iwp_ss, pcld_ss, tcld_ss, &
115            emis_ss
116    REAL, DIMENSION(:), ALLOCATABLE :: deltaz_ss, rad_ss
117
118    CHARACTER (len = 50) :: modname = 'simu_airs.cloud_structure'
119    CHARACTER (len = 160) :: abort_message
120
121    WRITE(lunout, *) 'dans cloud_structure'
122
123    CALL ordonne(len_cs, rneb_cs, rneb_ord)
124
125
126    ! Definition des sous_sections
127
128    rneb_min = rneb_ord(1)
129    nss = 1
130
131    do i = 2, size(rneb_cs)
132      IF (rneb_ord(i) > rneb_min) THEN
133        nss = nss + 1
134        rneb_min = rneb_ord(i)
135      endif
136    enddo
137
138    allocate (s(nss))
139    allocate (s_hc(nss))
140    allocate (s_hist(nss))
141    allocate (rneb_max(nss))
142    allocate (emis_ss(nss))
143    allocate (pcld_ss(nss))
144    allocate (tcld_ss(nss))
145    allocate (iwp_ss(nss))
146    allocate (deltaz_ss(nss))
147    allocate (rad_ss(nss))
148    allocate (sCb(nss))
149    allocate (sThCi(nss))
150    allocate (sAnv(nss))
151
152    rneb_min = rneb_ord(1)
153    n = 1
154    s(1) = rneb_ord(1)
155    s_hc(1) = rneb_ord(1)
156    s_hist(1) = rneb_ord(1)
157    sCb(1) = rneb_ord(1)
158    sThCi(1) = rneb_ord(1)
159    sAnv(1) = rneb_ord(1)
160
161    rneb_max(1) = rneb_ord(1)
162
163    do i = 2, size(rneb_cs)
164      IF (rneb_ord(i) > rneb_min) THEN
165        n = n + 1
166        s(n) = rneb_ord(i) - rneb_min
167        s_hc(n) = rneb_ord(i) - rneb_min
168        s_hist(n) = rneb_ord(i) - rneb_min
169        sCb(n) = rneb_ord(i) - rneb_min
170        sThCi(n) = rneb_ord(i) - rneb_min
171        sAnv(n) = rneb_ord(i) - rneb_min
172
173        rneb_max(n) = rneb_ord(i)
174        rneb_min = rneb_ord(i)
175      endif
176    enddo
177
178    ! Appel de sous_section
179
180    do i = 1, nss
181      CALL sous_section(len_cs, rneb_cs, temp_cs, &
182              emis_cs, iwco_cs, &
183              pres_cs, dz_cs, rhodz_cs, rad_cs, rneb_ord, &
184              rneb_max(i), s(i), s_hc(i), s_hist(i), &
185              sCb(i), sThCi(i), sAnv(i), &
186              emis_ss(i), &
187              pcld_ss(i), tcld_ss(i), iwp_ss(i), deltaz_ss(i), rad_ss(i))
188    enddo
189
190    ! Caracteristiques de la structure nuageuse
191
192    cc_tot_cs = 0.
193    cc_hc_cs = 0.
194    cc_hist_cs = 0.
195
196    cc_Cb_cs = 0.
197    cc_ThCi_cs = 0.
198    cc_Anv_cs = 0.
199
200    em_hc_cs = 0.
201    iwp_hc_cs = 0.
202    deltaz_hc_cs = 0.
203
204    em_hist_cs = 0.
205    iwp_hist_cs = 0.
206    deltaz_hist_cs = 0.
207    rad_hist_cs = 0.
208
209    pcld_hc_cs = 0.
210    tcld_hc_cs = 0.
211
212    pcld_Cb_cs = 0.
213    tcld_Cb_cs = 0.
214    em_Cb_cs = 0.
215
216    pcld_ThCi_cs = 0.
217    tcld_ThCi_cs = 0.
218    em_ThCi_cs = 0.
219
220    pcld_Anv_cs = 0.
221    tcld_Anv_cs = 0.
222    em_Anv_cs = 0.
223
224    do i = 1, nss
225
226      cc_tot_cs = cc_tot_cs + s(i)
227      cc_hc_cs = cc_hc_cs + s_hc(i)
228      cc_hist_cs = cc_hist_cs + s_hist(i)
229
230      cc_Cb_cs = cc_Cb_cs + sCb(i)
231      cc_ThCi_cs = cc_ThCi_cs + sThCi(i)
232      cc_Anv_cs = cc_Anv_cs + sAnv(i)
233
234      iwp_hc_cs = iwp_hc_cs + s_hc(i) * iwp_ss(i)
235      em_hc_cs = em_hc_cs + s_hc(i) * emis_ss(i)
236      deltaz_hc_cs = deltaz_hc_cs + s_hc(i) * deltaz_ss(i)
237
238      iwp_hist_cs = iwp_hist_cs + s_hist(i) * iwp_ss(i)
239      em_hist_cs = em_hist_cs + s_hist(i) * emis_ss(i)
240      deltaz_hist_cs = deltaz_hist_cs + s_hist(i) * deltaz_ss(i)
241      rad_hist_cs = rad_hist_cs + s_hist(i) * rad_ss(i)
242
243      pcld_hc_cs = pcld_hc_cs + s_hc(i) * pcld_ss(i)
244      tcld_hc_cs = tcld_hc_cs + s_hc(i) * tcld_ss(i)
245
246      pcld_Cb_cs = pcld_Cb_cs + sCb(i) * pcld_ss(i)
247      tcld_Cb_cs = tcld_Cb_cs + sCb(i) * tcld_ss(i)
248      em_Cb_cs = em_Cb_cs + sCb(i) * emis_ss(i)
249
250      pcld_ThCi_cs = pcld_ThCi_cs + sThCi(i) * pcld_ss(i)
251      tcld_ThCi_cs = tcld_ThCi_cs + sThCi(i) * tcld_ss(i)
252      em_ThCi_cs = em_ThCi_cs + sThCi(i) * emis_ss(i)
253
254      pcld_Anv_cs = pcld_Anv_cs + sAnv(i) * pcld_ss(i)
255      tcld_Anv_cs = tcld_Anv_cs + sAnv(i) * tcld_ss(i)
256      em_Anv_cs = em_Anv_cs + sAnv(i) * emis_ss(i)
257
258    enddo
259
260    deallocate(s)
261    deallocate (s_hc)
262    deallocate (s_hist)
263    deallocate (rneb_max)
264    deallocate (emis_ss)
265    deallocate (pcld_ss)
266    deallocate (tcld_ss)
267    deallocate (iwp_ss)
268    deallocate (deltaz_ss)
269    deallocate (rad_ss)
270    deallocate (sCb)
271    deallocate (sThCi)
272    deallocate (sAnv)
273
274    CALL normal_undef(pcld_hc_cs, cc_hc_cs)
275    CALL normal_undef(tcld_hc_cs, cc_hc_cs)
276    CALL normal_undef(iwp_hc_cs, cc_hc_cs)
277    CALL normal_undef(em_hc_cs, cc_hc_cs)
278    CALL normal_undef(deltaz_hc_cs, cc_hc_cs)
279
280    CALL normal_undef(iwp_hist_cs, cc_hist_cs)
281    CALL normal_undef(em_hist_cs, cc_hist_cs)
282    CALL normal_undef(deltaz_hist_cs, cc_hist_cs)
283    CALL normal_undef(rad_hist_cs, cc_hist_cs)
284
285    CALL normal_undef(pcld_Cb_cs, cc_Cb_cs)
286    CALL normal_undef(tcld_Cb_cs, cc_Cb_cs)
287    CALL normal_undef(em_Cb_cs, cc_Cb_cs)
288
289    CALL normal_undef(pcld_ThCi_cs, cc_ThCi_cs)
290    CALL normal_undef(tcld_ThCi_cs, cc_ThCi_cs)
291    CALL normal_undef(em_ThCi_cs, cc_ThCi_cs)
292
293    CALL normal_undef(pcld_Anv_cs, cc_Anv_cs)
294    CALL normal_undef(tcld_Anv_cs, cc_Anv_cs)
295    CALL normal_undef(em_Anv_cs, cc_Anv_cs)
296
297
298    ! Tests
299
300    IF (cc_tot_cs > maxval(rneb_cs) .AND. &
301            abs(cc_tot_cs - maxval(rneb_cs)) > 1.e-4)  THEN
302      WRITE(abort_message, *) 'cc_tot_cs > max rneb_cs', cc_tot_cs, maxval(rneb_cs)
303      CALL abort_physic(modname, abort_message, 1)
304    endif
305
306    IF (iwp_hc_cs < 0.) THEN
307      abort_message = 'cloud_structure: iwp_hc_cs < 0'
308      CALL abort_physic(modname, abort_message, 1)
309    endif
310
311  END SUBROUTINE  cloud_structure
312
313
314  SUBROUTINE normal_undef(num, den)
315
316    REAL, INTENT(IN) :: den
317    REAL, INTENT(INOUT) :: num
318
319    IF (den /= 0) THEN
320      num = num / den
321    else
322      num = undef
323    endif
324
325  END SUBROUTINE  normal_undef
326
327
328  SUBROUTINE normal2_undef(res, num, den)
329
330    REAL, INTENT(IN) :: den
331    REAL, INTENT(IN) :: num
332    REAL, INTENT(OUT) :: res
333
334    IF (den /= 0.) THEN
335      res = num / den
336    else
337      res = undef
338    endif
339
340  END SUBROUTINE  normal2_undef
341
342
343  SUBROUTINE sous_section(len_cs, rneb_cs, temp_cs, &
344          emis_cs, iwco_cs, &
345          pres_cs, dz_cs, rhodz_cs, rad_cs, rneb_ord, &
346          rnebmax, stot, shc, shist, &
347          sCb, sThCi, sAnv, &
348          emis, pcld, tcld, iwp, deltaz, rad)
349
350    INTEGER, INTENT(IN) :: len_cs
351    REAL, DIMENSION(len_cs), INTENT(IN) :: rneb_cs, temp_cs
352    REAL, DIMENSION(len_cs), INTENT(IN) :: emis_cs, iwco_cs, &
353            rneb_ord
354    REAL, DIMENSION(len_cs), INTENT(IN) :: pres_cs, dz_cs, rad_cs
355    REAL, DIMENSION(len_cs), INTENT(IN) :: rhodz_cs
356    REAL, DIMENSION(len_cs) :: tau_cs, w
357    REAL, INTENT(IN) :: rnebmax
358    REAL, INTENT(INOUT) :: stot, shc, shist
359    REAL, INTENT(INOUT) :: sCb, sThCi, sAnv
360    REAL, INTENT(OUT) :: emis, pcld, tcld, iwp, deltaz, rad
361
362    INTEGER :: i, ideb, ibeg, iend, nuage, visible
363    REAL :: som, som_tau, som_iwc, som_dz, som_rad, tau
364
365    CHARACTER (len = 50) :: modname = 'simu_airs.sous_section'
366    CHARACTER (len = 160) :: abort_message
367
368
369    ! Ponderation: 1 pour les nuages, 0 pour les trous
370
371    do i = 1, len_cs
372      IF (rneb_cs(i) >= rnebmax) THEN
373        w(i) = 1.
374      else
375        w(i) = 0.
376      endif
377    enddo
378
379    ! Calcul des epaisseurs optiques a partir des emissivites
380
381    som = 0.
382    do i = 1, len_cs
383      IF (emis_cs(i) == 1.) THEN
384        tau_cs(i) = 10.
385      else
386        tau_cs(i) = -log(1. - emis_cs(i))
387      endif
388      som = som + tau_cs(i)
389    enddo
390
391    ideb = 1
392    nuage = 0
393    visible = 0
394
395
396    ! Boucle sur les nuages
397    do while (ideb /= 0 .AND. ideb <= len_cs)
398
399
400      ! Definition d'un nuage de la sous-section
401
402      CALL topbot(ideb, w, ibeg, iend)
403      ideb = iend + 1
404
405      IF (ibeg > 0) THEN
406        nuage = nuage + 1
407
408        ! On determine les caracteristiques du nuage
409        ! (ep. optique, ice water path, pression, temperature)
410
411        CALL caract(ibeg, iend, temp_cs, tau_cs, iwco_cs, &
412                pres_cs, dz_cs, rhodz_cs, rad_cs, pcld, tcld, &
413                som_tau, som_iwc, som_dz, som_rad)
414
415        ! On masque le nuage s'il n'est pas detectable
416
417        CALL masque(ibeg, iend, som_tau, visible, w)
418
419      endif
420
421      ! Fin boucle nuages
422    enddo
423
424
425    ! Analyse du nuage detecte
426
427    CALL topbot(1, w, ibeg, iend)
428
429    IF (ibeg > 0) THEN
430      CALL caract(ibeg, iend, temp_cs, tau_cs, iwco_cs, &
431              pres_cs, dz_cs, rhodz_cs, rad_cs, pcld, tcld, &
432              som_tau, som_iwc, som_dz, som_rad)
433
434      tau = som_tau
435      emis = 1. - exp(-tau)
436      iwp = som_iwc
437      deltaz = som_dz
438      rad = som_rad
439
440      IF (pcld > p_thresh) THEN
441        shc = 0.
442        shist = 0.
443        sCb = 0.
444        sThCi = 0.
445        sAnv = 0.
446
447      else
448
449        IF (emis < em_min .OR. emis > em_max  &
450                .OR. tcld > 230.) THEN
451          shist = 0.
452        endif
453
454        IF (emis < 0.98) THEN
455          sCb = 0.
456        endif
457
458        IF (emis > 0.5 .OR. emis < 0.1) THEN
459          sThCi = 0.
460        endif
461
462        IF (emis <= 0.5 .OR. emis >= 0.98) THEN
463          sAnv = 0.
464        endif
465
466      endif
467
468    else
469
470      tau = 0.
471      emis = 0.
472      iwp = 0.
473      deltaz = 0.
474      pcld = 0.
475      tcld = 0.
476      stot = 0.
477      shc = 0.
478      shist = 0.
479      rad = 0.
480      sCb = 0.
481      sThCi = 0.
482      sAnv = 0.
483
484    endif
485
486
487    ! Tests
488
489    IF (iwp < 0.) THEN
490      WRITE(abort_message, *) 'ideb iwp =', ideb, iwp
491      CALL abort_physic(modname, abort_message, 1)
492    endif
493
494    IF (deltaz < 0.) THEN
495      WRITE(abort_message, *)'ideb deltaz =', ideb, deltaz
496      CALL abort_physic(modname, abort_message, 1)
497    endif
498
499    IF (emis < 0.048 .AND. emis /= 0.) THEN
500      WRITE(abort_message, *) 'ideb emis =', ideb, emis
501      CALL abort_physic(modname, abort_message, 1)
502    endif
503
504  END SUBROUTINE  sous_section
505
506
507  SUBROUTINE masque(ibeg, iend, som_tau, &
508          visible, w)
509
510    INTEGER, INTENT(IN) :: ibeg, iend
511    REAL, INTENT(IN) :: som_tau
512
513    INTEGER, INTENT(INOUT) :: visible
514    REAL, DIMENSION(:), INTENT(INOUT) :: w
515
516    INTEGER :: i
517
518
519
520    ! Masque
521
522    ! Cas ou il n'y a pas de nuage visible au-dessus
523
524    IF (visible == 0) THEN
525      IF (som_tau < tau_thresh) THEN
526        do i = ibeg, iend
527          w(i) = 0.
528        enddo
529      else
530        visible = 1
531      endif
532
533      ! Cas ou il y a un nuage visible au-dessus
534
535    else
536
537      do i = ibeg, iend
538        w(i) = 0.
539      enddo
540
541    endif
542
543  END SUBROUTINE  masque
544
545
546  SUBROUTINE caract(ibeg, iend, temp_cs, tau_cs, iwco_cs, &
547          pres_cs, dz_cs, rhodz_cs, rad_cs, pcld, tcld, &
548          som_tau, som_iwc, som_dz, som_rad)
549
550    INTEGER, INTENT(IN) :: ibeg, iend
551    REAL, DIMENSION(:), INTENT(IN) :: tau_cs, iwco_cs, temp_cs
552    REAL, DIMENSION(:), INTENT(IN) :: pres_cs, dz_cs, rad_cs
553    REAL, DIMENSION(:), INTENT(IN) :: rhodz_cs
554    REAL, INTENT(OUT) :: som_tau, som_iwc, som_dz, som_rad
555    REAL, INTENT(OUT) :: pcld, tcld
556
557    INTEGER :: i, ibase, imid
558
559    CHARACTER (len = 50) :: modname = 'simu_airs.caract'
560    CHARACTER (len = 160) :: abort_message
561
562    ! Somme des epaisseurs optiques et des contenus en glace sur le nuage
563
564    som_tau = 0.
565    som_iwc = 0.
566    som_dz = 0.
567    som_rad = 0.
568    ibase = -100
569
570    do i = ibeg, iend
571
572      som_tau = som_tau + tau_cs(i)
573
574      som_dz = som_dz + dz_cs(i)
575      som_iwc = som_iwc + iwco_cs(i) * 1000 * rhodz_cs(i)  ! en g/m2
576      som_rad = som_rad + rad_cs(i) * dz_cs(i)
577
578      IF (som_tau > 3. .AND. ibase == -100) THEN
579        ibase = i - 1
580      endif
581
582    enddo
583
584    IF (som_dz /= 0.) THEN
585      som_rad = som_rad / som_dz
586    else
587      WRITE(*, *) 'som_dez = 0 stop '
588      WRITE(*, *) 'ibeg, iend =', ibeg, iend
589      do i = ibeg, iend
590        WRITE(*, *) dz_cs(i), rhodz_cs(i)
591      enddo
592      abort_message = 'see above'
593      CALL abort_physic(modname, abort_message, 1)
594    endif
595
596    ! Determination de Pcld et Tcld
597
598    IF (ibase < ibeg) THEN
599      ibase = ibeg
600    endif
601
602    imid = (ibeg + ibase) / 2
603
604    pcld = pres_cs(imid) / 100.        ! pcld en hPa
605    tcld = temp_cs(imid)
606
607  END SUBROUTINE  caract
608
609  SUBROUTINE topbot(ideb, w, ibeg, iend)
610
611    INTEGER, INTENT(IN) :: ideb
612    REAL, DIMENSION(:), INTENT(IN) :: w
613    INTEGER, INTENT(OUT) :: ibeg, iend
614
615    INTEGER :: i, itest
616
617    itest = 0
618    ibeg = 0
619    iend = 0
620
621    do i = ideb, size(w)
622
623      IF (w(i) == 1. .AND. itest == 0) THEN
624        ibeg = i
625        itest = 1
626      endif
627
628    enddo
629
630    i = ibeg
631    do while (w(i) == 1. .AND. i <= size(w))
632      i = i + 1
633    enddo
634    iend = i - 1
635
636  END SUBROUTINE  topbot
637
638  SUBROUTINE ordonne(len_cs, rneb_cs, rneb_ord)
639
640    INTEGER, INTENT(IN) :: len_cs
641    REAL, DIMENSION(:), INTENT(IN) :: rneb_cs
642    REAL, DIMENSION(:), INTENT(OUT) :: rneb_ord
643
644    INTEGER :: i, j, ind_min
645
646    REAL, DIMENSION(len_cs) :: rneb
647    REAL :: rneb_max
648
649    do i = 1, size(rneb_cs)
650      rneb(i) = rneb_cs(i)
651    enddo
652
653    do j = 1, size(rneb_cs)
654
655      rneb_max = 100.
656
657      do i = 1, size(rneb_cs)
658        IF (rneb(i) < rneb_max) THEN
659          rneb_max = rneb(i)
660          ind_min = i
661        endif
662      enddo
663
664      rneb_ord(j) = rneb_max
665      rneb(ind_min) = 100.
666
667    enddo
668
669  END SUBROUTINE  ordonne
670
671
672  SUBROUTINE sim_mesh(rneb_1D, temp_1D, emis_1D, &
673          iwcon_1D, rad_1D, &
674          pres, dz, &
675          rhodz_1D, cc_tot_mesh, cc_hc_mesh, cc_hist_mesh, pcld_hc_mesh, &
676          tcld_hc_mesh, &
677          em_hc_mesh, iwp_hc_mesh, deltaz_hc_mesh, &
678          cc_Cb_mesh, cc_ThCi_mesh, cc_Anv_mesh, &
679          pcld_Cb_mesh, tcld_Cb_mesh, em_Cb_mesh, &
680          pcld_ThCi_mesh, tcld_ThCi_mesh, em_ThCi_mesh, &
681          pcld_Anv_mesh, tcld_Anv_mesh, em_Anv_mesh, &
682          em_hist_mesh, iwp_hist_mesh, deltaz_hist_mesh, rad_hist_mesh)
683
684    USE dimphy
685
686    REAL, DIMENSION(klev), INTENT(IN) :: rneb_1D, temp_1D, emis_1D, &
687            iwcon_1D, rad_1D
688    REAL, DIMENSION(klev), INTENT(IN) :: pres, dz, rhodz_1D
689    REAL, INTENT(OUT) :: cc_tot_mesh, cc_hc_mesh, cc_hist_mesh
690    REAL, INTENT(OUT) :: cc_Cb_mesh, cc_ThCi_mesh, cc_Anv_mesh
691    REAL, INTENT(OUT) :: em_hc_mesh, pcld_hc_mesh, tcld_hc_mesh, &
692            iwp_hc_mesh
693
694    REAL, INTENT(OUT) :: pcld_Cb_mesh, tcld_Cb_mesh, em_Cb_mesh
695    REAL, INTENT(OUT) :: pcld_ThCi_mesh, tcld_ThCi_mesh, &
696            em_ThCi_mesh
697    REAL, INTENT(OUT) :: pcld_Anv_mesh, tcld_Anv_mesh, em_Anv_mesh
698
699    REAL, INTENT(OUT) :: em_hist_mesh, iwp_hist_mesh, rad_hist_mesh
700    REAL, INTENT(OUT) :: deltaz_hc_mesh, deltaz_hist_mesh
701
702    REAL, DIMENSION(:), ALLOCATABLE :: rneb_cs, temp_cs, emis_cs, &
703            iwco_cs
704    REAL, DIMENSION(:), ALLOCATABLE :: pres_cs, dz_cs, rad_cs, &
705            rhodz_cs
706
707    INTEGER :: i, j, l
708    INTEGER :: ltop, itop, ibot, num_cs, N_cs, len_cs, ics
709
710    REAL :: som_emi_hc, som_pcl_hc, som_tcl_hc, som_iwp_hc, som_hc, &
711            som_hist
712    REAL :: som_emi_hist, som_iwp_hist, som_deltaz_hc, &
713            som_deltaz_hist
714    REAL :: som_rad_hist
715    REAL :: som_Cb, som_ThCi, som_Anv
716    REAL :: som_emi_Cb, som_tcld_Cb, som_pcld_Cb
717    REAL :: som_emi_Anv, som_tcld_Anv, som_pcld_Anv
718    REAL :: som_emi_ThCi, som_tcld_ThCi, som_pcld_ThCi
719    REAL :: tsom_tot, tsom_hc, tsom_hist
720    REAL :: prod, prod_hh
721
722    REAL :: cc_tot_cs, cc_hc_cs, cc_hist_cs
723    REAL :: cc_Cb_cs, cc_ThCi_cs, cc_Anv_cs
724    REAL :: pcld_hc_cs, tcld_hc_cs
725    REAL :: em_hc_cs, iwp_hc_cs, deltaz_hc_cs
726    REAL :: pcld_Cb_cs, tcld_Cb_cs, em_Cb_cs
727    REAL :: pcld_ThCi_cs, tcld_ThCi_cs, em_ThCi_cs
728    REAL :: pcld_Anv_cs, tcld_Anv_cs, em_Anv_cs
729    REAL :: em_hist_cs, iwp_hist_cs, deltaz_hist_cs, rad_hist_cs
730
731    REAL, DIMENSION(klev) :: test_tot, test_hc, test_hist
732    REAL, DIMENSION(klev) :: test_pcld, test_tcld, test_em, test_iwp
733
734    CHARACTER (len = 50) :: modname = 'simu_airs.sim_mesh'
735    CHARACTER (len = 160) :: abort_message
736
737    do j = 1, klev
738      WRITE(lunout, *) 'simu_airs, j, rneb_1D =', rneb_1D(j)
739    enddo
740
741    ! Definition des structures nuageuses, de la plus haute a la plus basse
742
743    num_cs = 0
744    ltop = klev - 1
745
746    prod = 1.
747
748    som_emi_hc = 0.
749    som_emi_hist = 0.
750    som_pcl_hc = 0.
751    som_tcl_hc = 0.
752    som_iwp_hc = 0.
753    som_iwp_hist = 0.
754    som_deltaz_hc = 0.
755    som_deltaz_hist = 0.
756    som_rad_hist = 0.
757    som_hc = 0.
758    som_hist = 0.
759
760    som_Cb = 0.
761    som_ThCi = 0.
762    som_Anv = 0.
763
764    som_emi_Cb = 0.
765    som_pcld_Cb = 0.
766    som_tcld_Cb = 0.
767
768    som_emi_ThCi = 0.
769    som_pcld_ThCi = 0.
770    som_tcld_ThCi = 0.
771
772    som_emi_Anv = 0.
773    som_pcld_Anv = 0.
774    som_tcld_Anv = 0.
775
776    tsom_tot = 0.
777    tsom_hc = 0.
778    tsom_hist = 0.
779
780    do while (ltop >= 1)   ! Boucle sur toute la colonne
781
782      itop = 0
783
784      do l = ltop, 1, -1
785
786        IF (itop == 0 .AND. rneb_1D(l) > 0.001) THEN
787          itop = l
788        endif
789
790      enddo
791
792      ibot = itop
793
794      do while (rneb_1D(ibot) > 0.001 .AND. ibot >= 1)
795        ibot = ibot - 1
796      enddo
797
798      ibot = ibot + 1
799
800      IF (itop > 0) then    ! itop > 0
801
802        num_cs = num_cs + 1
803        len_cs = itop - ibot + 1
804
805        ! Allocation et definition des variables de la structure nuageuse
806        ! le premier indice denote ce qui est le plus haut
807
808        allocate (rneb_cs(len_cs))
809        allocate (temp_cs(len_cs))
810        allocate (emis_cs(len_cs))
811        allocate (iwco_cs(len_cs))
812        allocate (pres_cs(len_cs))
813        allocate (dz_cs(len_cs))
814        allocate (rad_cs(len_cs))
815        allocate (rhodz_cs(len_cs))
816
817        ics = 0
818
819        do i = itop, ibot, -1
820          ics = ics + 1
821          rneb_cs(ics) = rneb_1D(i)
822          temp_cs(ics) = temp_1D(i)
823          emis_cs(ics) = emis_1D(i)
824          iwco_cs(ics) = iwcon_1D(i)
825          rad_cs(ics) = rad_1D(i)
826          pres_cs(ics) = pres(i)
827          dz_cs(ics) = dz(i)
828          rhodz_cs(ics) = rhodz_1D(i)
829        enddo
830
831        ! Appel du sous_programme cloud_structure
832
833        CALL cloud_structure(len_cs, rneb_cs, temp_cs, emis_cs, iwco_cs, &
834                pres_cs, dz_cs, rhodz_cs, rad_cs, &
835                cc_tot_cs, cc_hc_cs, cc_hist_cs, &
836                cc_Cb_cs, cc_ThCi_cs, cc_Anv_cs, &
837                pcld_hc_cs, tcld_hc_cs, &
838                em_hc_cs, iwp_hc_cs, deltaz_hc_cs, &
839                pcld_Cb_cs, tcld_Cb_cs, em_Cb_cs, &
840                pcld_ThCi_cs, tcld_ThCi_cs, em_ThCi_cs, &
841                pcld_Anv_cs, tcld_Anv_cs, em_Anv_cs, &
842                em_hist_cs, iwp_hist_cs, deltaz_hist_cs, rad_hist_cs)
843
844        deallocate (rneb_cs)
845        deallocate (temp_cs)
846        deallocate (emis_cs)
847        deallocate (iwco_cs)
848        deallocate (pres_cs)
849        deallocate (dz_cs)
850        deallocate (rad_cs)
851        deallocate (rhodz_cs)
852
853
854        ! Pour la couverture nuageuse sur la maille
855
856        prod_hh = prod
857
858        prod = prod * (1. - cc_tot_cs)
859
860        ! Pour les autres variables definies sur la maille
861
862        som_emi_hc = som_emi_hc + em_hc_cs * cc_hc_cs * prod_hh
863        som_iwp_hc = som_iwp_hc + iwp_hc_cs * cc_hc_cs * prod_hh
864        som_deltaz_hc = som_deltaz_hc + deltaz_hc_cs * cc_hc_cs * prod_hh
865
866        som_emi_Cb = som_emi_Cb + em_Cb_cs * cc_Cb_cs * prod_hh
867        som_tcld_Cb = som_tcld_Cb + tcld_Cb_cs * cc_Cb_cs * prod_hh
868        som_pcld_Cb = som_pcld_Cb + pcld_Cb_cs * cc_Cb_cs * prod_hh
869
870        som_emi_ThCi = som_emi_ThCi + em_ThCi_cs * cc_ThCi_cs * prod_hh
871        som_tcld_ThCi = som_tcld_ThCi + tcld_ThCi_cs * cc_ThCi_cs * prod_hh
872        som_pcld_ThCi = som_pcld_ThCi + pcld_ThCi_cs * cc_ThCi_cs * prod_hh
873
874        som_emi_Anv = som_emi_Anv + em_Anv_cs * cc_Anv_cs * prod_hh
875        som_tcld_Anv = som_tcld_Anv + tcld_Anv_cs * cc_Anv_cs * prod_hh
876        som_pcld_Anv = som_pcld_Anv + pcld_Anv_cs * cc_Anv_cs * prod_hh
877
878        som_emi_hist = som_emi_hist + em_hist_cs * cc_hist_cs * prod_hh
879        som_iwp_hist = som_iwp_hist + iwp_hist_cs * cc_hist_cs * prod_hh
880        som_deltaz_hist = som_deltaz_hist + &
881                deltaz_hist_cs * cc_hist_cs * prod_hh
882        som_rad_hist = som_rad_hist + rad_hist_cs * cc_hist_cs * prod_hh
883
884        som_pcl_hc = som_pcl_hc + pcld_hc_cs * cc_hc_cs * prod_hh
885        som_tcl_hc = som_tcl_hc + tcld_hc_cs * cc_hc_cs * prod_hh
886
887        som_hc = som_hc + cc_hc_cs * prod_hh
888        som_hist = som_hist + cc_hist_cs * prod_hh
889
890        som_Cb = som_Cb + cc_Cb_cs * prod_hh
891        som_ThCi = som_ThCi + cc_ThCi_cs * prod_hh
892        som_Anv = som_Anv + cc_Anv_cs * prod_hh
893
894
895        ! Pour test
896
897        CALL test_bornes('cc_tot_cs     ', cc_tot_cs, 1., 0.)
898        CALL test_bornes('cc_hc_cs      ', cc_hc_cs, 1., 0.)
899        CALL test_bornes('cc_hist_cs    ', cc_hist_cs, 1., 0.)
900        CALL test_bornes('pcld_hc_cs    ', pcld_hc_cs, 1200., 0.)
901        CALL test_bornes('tcld_hc_cs    ', tcld_hc_cs, 1000., 100.)
902        CALL test_bornes('em_hc_cs      ', em_hc_cs, 1000., 0.048)
903
904        test_tot(num_cs) = cc_tot_cs
905        test_hc(num_cs) = cc_hc_cs
906        test_hist(num_cs) = cc_hist_cs
907        test_pcld(num_cs) = pcld_hc_cs
908        test_tcld(num_cs) = tcld_hc_cs
909        test_em(num_cs) = em_hc_cs
910        test_iwp(num_cs) = iwp_hc_cs
911
912        tsom_tot = tsom_tot + cc_tot_cs
913        tsom_hc = tsom_hc + cc_hc_cs
914        tsom_hist = tsom_hist + cc_hist_cs
915
916      endif                   ! itop > 0
917
918      ltop = ibot - 1
919
920    enddo                   ! fin de la boucle sur la colonne
921
922    N_CS = num_cs
923
924
925    ! Determination des variables de sortie
926
927    IF (N_CS > 0) then   ! if N_CS>0
928
929      cc_tot_mesh = 1. - prod
930
931      cc_hc_mesh = som_hc
932      cc_hist_mesh = som_hist
933
934      cc_Cb_mesh = som_Cb
935      cc_ThCi_mesh = som_ThCi
936      cc_Anv_mesh = som_Anv
937
938      CALL normal2_undef(pcld_hc_mesh, som_pcl_hc, &
939              cc_hc_mesh)
940      CALL normal2_undef(tcld_hc_mesh, som_tcl_hc, &
941              cc_hc_mesh)
942      CALL normal2_undef(em_hc_mesh, som_emi_hc, &
943              cc_hc_mesh)
944      CALL normal2_undef(iwp_hc_mesh, som_iwp_hc, &
945              cc_hc_mesh)
946      CALL normal2_undef(deltaz_hc_mesh, som_deltaz_hc, &
947              cc_hc_mesh)
948
949      CALL normal2_undef(em_Cb_mesh, som_emi_Cb, &
950              cc_Cb_mesh)
951      CALL normal2_undef(tcld_Cb_mesh, som_tcld_Cb, &
952              cc_Cb_mesh)
953      CALL normal2_undef(pcld_Cb_mesh, som_pcld_Cb, &
954              cc_Cb_mesh)
955
956      CALL normal2_undef(em_ThCi_mesh, som_emi_ThCi, &
957              cc_ThCi_mesh)
958      CALL normal2_undef(tcld_ThCi_mesh, som_tcld_ThCi, &
959              cc_ThCi_mesh)
960      CALL normal2_undef(pcld_ThCi_mesh, som_pcld_ThCi, &
961              cc_ThCi_mesh)
962
963      CALL normal2_undef(em_Anv_mesh, som_emi_Anv, &
964              cc_Anv_mesh)
965      CALL normal2_undef(tcld_Anv_mesh, som_tcld_Anv, &
966              cc_Anv_mesh)
967      CALL normal2_undef(pcld_Anv_mesh, som_pcld_Anv, &
968              cc_Anv_mesh)
969
970      CALL normal2_undef(em_hist_mesh, som_emi_hist, &
971              cc_hist_mesh)
972      CALL normal2_undef(iwp_hist_mesh, som_iwp_hist, &
973              cc_hist_mesh)
974      CALL normal2_undef(deltaz_hist_mesh, som_deltaz_hist, &
975              cc_hist_mesh)
976      CALL normal2_undef(rad_hist_mesh, som_rad_hist, &
977              cc_hist_mesh)
978
979
980      ! Tests
981
982      ! Tests
983
984      IF (cc_tot_mesh > tsom_tot .AND. &
985              abs(cc_tot_mesh - tsom_tot) > 1.e-4) THEN
986        WRITE(abort_message, *)'cc_tot_mesh > tsom_tot', cc_tot_mesh, tsom_tot
987        CALL abort_physic(modname, abort_message, 1)
988      endif
989
990      IF (cc_tot_mesh < maxval(test_tot(1:N_CS)) .AND. &
991              abs(cc_tot_mesh - maxval(test_tot(1:N_CS))) > 1.e-4) THEN
992        WRITE(abort_message, *) 'cc_tot_mesh < max', cc_tot_mesh, maxval(test_tot(1:N_CS))
993        CALL abort_physic(modname, abort_message, 1)
994      endif
995
996      IF (cc_hc_mesh > tsom_hc .AND. &
997              abs(cc_hc_mesh - tsom_hc) > 1.e-4) THEN
998        WRITE(abort_message, *) 'cc_hc_mesh > tsom_hc', cc_hc_mesh, tsom_hc
999        CALL abort_physic(modname, abort_message, 1)
1000      endif
1001
1002      IF (cc_hc_mesh < maxval(test_hc(1:N_CS)) .AND. &
1003              abs(cc_hc_mesh - maxval(test_hc(1:N_CS))) > 1.e-4) THEN
1004        WRITE(abort_message, *) 'cc_hc_mesh < max', cc_hc_mesh, maxval(test_hc(1:N_CS))
1005        CALL abort_physic(modname, abort_message, 1)
1006      endif
1007
1008      IF (cc_hist_mesh > tsom_hist .AND. &
1009              abs(cc_hist_mesh - tsom_hist) > 1.e-4) THEN
1010        WRITE(abort_message, *) 'cc_hist_mesh > tsom_hist', cc_hist_mesh, tsom_hist
1011        CALL abort_physic(modname, abort_message, 1)
1012      endif
1013
1014      IF (cc_hist_mesh < 0.) THEN
1015        WRITE(abort_message, *) 'cc_hist_mesh < 0', cc_hist_mesh
1016        CALL abort_physic(modname, abort_message, 1)
1017      endif
1018
1019      IF ((pcld_hc_mesh > maxval(test_pcld(1:N_CS)) .OR. &
1020              pcld_hc_mesh < minval(test_pcld(1:N_CS))) .AND. &
1021              abs(pcld_hc_mesh - maxval(test_pcld(1:N_CS))) > 1. .AND. &
1022              maxval(test_pcld(1:N_CS)) /= 999. &
1023              .AND. minval(test_pcld(1:N_CS)) /= 999.) THEN
1024        WRITE(abort_message, *) 'pcld_hc_mesh est faux', pcld_hc_mesh, maxval(test_pcld(1:N_CS)), &
1025                minval(test_pcld(1:N_CS))
1026        CALL abort_physic(modname, abort_message, 1)
1027      endif
1028
1029      IF ((tcld_hc_mesh > maxval(test_tcld(1:N_CS)) .OR. &
1030              tcld_hc_mesh < minval(test_tcld(1:N_CS))) .AND. &
1031              abs(tcld_hc_mesh - maxval(test_tcld(1:N_CS))) > 0.1 .AND. &
1032              maxval(test_tcld(1:N_CS)) /= 999. &
1033              .AND. minval(test_tcld(1:N_CS)) /= 999.) THEN
1034        WRITE(abort_message, *) 'tcld_hc_mesh est faux', tcld_hc_mesh, maxval(test_tcld(1:N_CS)), &
1035                minval(test_tcld(1:N_CS))
1036        CALL abort_physic(modname, abort_message, 1)
1037      endif
1038
1039      IF ((em_hc_mesh > maxval(test_em(1:N_CS)) .OR. &
1040              em_hc_mesh < minval(test_em(1:N_CS))) .AND. &
1041              abs(em_hc_mesh - maxval(test_em(1:N_CS))) > 1.e-4 .AND. &
1042              minval(test_em(1:N_CS)) /= 999. .AND. &
1043              maxval(test_em(1:N_CS)) /= 999.) THEN
1044        WRITE(abort_message, *) 'em_hc_mesh est faux', em_hc_mesh, maxval(test_em(1:N_CS)), &
1045                minval(test_em(1:N_CS))
1046        CALL abort_physic(modname, abort_message, 1)
1047      endif
1048
1049    else               ! if N_CS>0
1050
1051      cc_tot_mesh = 0.
1052      cc_hc_mesh = 0.
1053      cc_hist_mesh = 0.
1054
1055      cc_Cb_mesh = 0.
1056      cc_ThCi_mesh = 0.
1057      cc_Anv_mesh = 0.
1058
1059      iwp_hc_mesh = undef
1060      deltaz_hc_mesh = undef
1061      em_hc_mesh = undef
1062      iwp_hist_mesh = undef
1063      deltaz_hist_mesh = undef
1064      rad_hist_mesh = undef
1065      em_hist_mesh = undef
1066      pcld_hc_mesh = undef
1067      tcld_hc_mesh = undef
1068
1069      pcld_Cb_mesh = undef
1070      tcld_Cb_mesh = undef
1071      em_Cb_mesh = undef
1072
1073      pcld_ThCi_mesh = undef
1074      tcld_ThCi_mesh = undef
1075      em_ThCi_mesh = undef
1076
1077      pcld_Anv_mesh = undef
1078      tcld_Anv_mesh = undef
1079      em_Anv_mesh = undef
1080
1081    endif                  ! if N_CS>0
1082
1083  END SUBROUTINE  sim_mesh
1084
1085  SUBROUTINE test_bornes(sx, x, bsup, binf)
1086
1087    REAL, INTENT(IN) :: x, bsup, binf
1088    character*14, INTENT(IN) :: sx
1089    CHARACTER (len = 50) :: modname = 'simu_airs.test_bornes'
1090    CHARACTER (len = 160) :: abort_message
1091
1092    IF (x > bsup .OR. x < binf) THEN
1093      WRITE(abort_message, *) sx, 'est faux', sx, x
1094      CALL abort_physic(modname, abort_message, 1)
1095    endif
1096
1097  END SUBROUTINE  test_bornes
1098
1099END MODULE m_simu_airs
1100
1101
1102SUBROUTINE simu_airs &
1103        (itap, rneb_airs, temp_airs, cldemi_airs, iwcon0_airs, rad_airs, &
1104        geop_airs, pplay_airs, paprs_airs, &
1105        map_prop_hc, map_prop_hist, &
1106        map_emis_hc, map_iwp_hc, map_deltaz_hc, map_pcld_hc, map_tcld_hc, &
1107        map_emis_Cb, map_pcld_Cb, map_tcld_Cb, &
1108        map_emis_ThCi, map_pcld_ThCi, map_tcld_ThCi, &
1109        map_emis_Anv, map_pcld_Anv, map_tcld_Anv, &
1110        map_emis_hist, map_iwp_hist, map_deltaz_hist, map_rad_hist, &
1111        map_ntot, map_hc, map_hist, &
1112        map_Cb, map_ThCi, map_Anv, alt_tropo)
1113
1114  USE dimphy
1115  USE m_simu_airs
1116
1117  IMPLICIT NONE
1118
1119  include "YOMCST.h"
1120
1121  INTEGER, INTENT(IN) :: itap
1122
1123  REAL, DIMENSION(klon, klev), INTENT(IN) :: &
1124          rneb_airs, temp_airs, cldemi_airs, iwcon0_airs, &
1125          rad_airs, geop_airs, pplay_airs, paprs_airs
1126
1127  REAL, DIMENSION(klon, klev) :: &
1128          rhodz_airs, rho_airs, iwcon_airs
1129
1130  REAL, DIMENSION(klon), INTENT(OUT) :: alt_tropo
1131
1132  REAL, DIMENSION(klev) :: rneb_1D, temp_1D, &
1133          emis_1D, rad_1D, pres_1D, alt_1D, &
1134          rhodz_1D, dz_1D, iwcon_1D
1135
1136  INTEGER :: i, j
1137
1138  REAL :: cc_tot_mesh, cc_hc_mesh, cc_hist_mesh
1139  REAL :: cc_Cb_mesh, cc_ThCi_mesh, cc_Anv_mesh
1140  REAL :: pcld_hc_mesh, tcld_hc_mesh, em_hc_mesh, iwp_hc_mesh
1141  REAL :: em_hist_mesh, iwp_hist_mesh
1142  REAL :: deltaz_hc_mesh, deltaz_hist_mesh, rad_hist_mesh
1143  REAL :: pcld_Cb_mesh, tcld_Cb_mesh, em_Cb_mesh
1144  REAL :: pcld_ThCi_mesh, tcld_ThCi_mesh, em_ThCi_mesh
1145  REAL :: pcld_Anv_mesh, tcld_Anv_mesh, em_Anv_mesh
1146
1147  REAL, DIMENSION(klon), INTENT(OUT) :: map_prop_hc, map_prop_hist
1148  REAL, DIMENSION(klon), INTENT(OUT) :: map_emis_hc, map_iwp_hc
1149  REAL, DIMENSION(klon), INTENT(OUT) :: map_deltaz_hc, map_pcld_hc
1150  REAL, DIMENSION(klon), INTENT(OUT) :: map_tcld_hc
1151  REAL, DIMENSION(klon), INTENT(OUT) :: map_emis_Cb, map_pcld_Cb, map_tcld_Cb
1152  REAL, DIMENSION(klon), INTENT(OUT) :: &
1153          map_emis_ThCi, map_pcld_ThCi, map_tcld_ThCi
1154  REAL, DIMENSION(klon), INTENT(OUT) :: &
1155          map_emis_Anv, map_pcld_Anv, map_tcld_Anv
1156  REAL, DIMENSION(klon), INTENT(OUT) :: &
1157          map_emis_hist, map_iwp_hist, map_deltaz_hist, &
1158          map_rad_hist
1159  REAL, DIMENSION(klon), INTENT(OUT) :: map_ntot, map_hc, map_hist
1160  REAL, DIMENSION(klon), INTENT(OUT) :: map_Cb, map_ThCi, map_Anv
1161
1162  WRITE(*, *) 'simu_airs'
1163  WRITE(*, *) 'itap, klon, klev', itap, klon, klev
1164  WRITE(*, *) 'RG, RD =', RG, RD
1165
1166
1167  ! Definition des variables 1D
1168
1169  do i = 1, klon
1170    do j = 1, klev - 1
1171      rhodz_airs(i, j) = &
1172              (paprs_airs(i, j) - paprs_airs(i, j + 1)) / RG
1173    enddo
1174    rhodz_airs(i, klev) = 0.
1175  enddo
1176
1177  do i = 1, klon
1178    do j = 1, klev
1179      rho_airs(i, j) = &
1180              pplay_airs(i, j) / (temp_airs(i, j) * RD)
1181
1182      IF (rneb_airs(i, j) > 0.001) THEN
1183        iwcon_airs(i, j) = iwcon0_airs(i, j) / rneb_airs(i, j)
1184      else
1185        iwcon_airs(i, j) = 0.
1186      endif
1187
1188    enddo
1189  enddo
1190
1191  !=============================================================================
1192
1193  do i = 1, klon  ! boucle sur les points de grille
1194
1195    !=============================================================================
1196
1197    do j = 1, klev
1198
1199      rneb_1D(j) = rneb_airs(i, j)
1200      temp_1D(j) = temp_airs(i, j)
1201      emis_1D(j) = cldemi_airs(i, j)
1202      iwcon_1D(j) = iwcon_airs(i, j)
1203      rad_1D(j) = rad_airs(i, j)
1204      pres_1D(j) = pplay_airs(i, j)
1205      alt_1D(j) = geop_airs(i, j) / RG
1206      rhodz_1D(j) = rhodz_airs(i, j)
1207      dz_1D(j) = rhodz_airs(i, j) / rho_airs(i, j)
1208
1209    enddo
1210
1211    alt_tropo(i) = &
1212            search_tropopause(pres_1D / 100., temp_1D, alt_1D, klev)
1213
1214
1215    ! Appel du ss-programme sim_mesh
1216
1217    !        if (itap .EQ. 1 ) THEN
1218    CALL sim_mesh(rneb_1D, temp_1D, emis_1D, iwcon_1D, rad_1D, &
1219            pres_1D, dz_1D, rhodz_1D, &
1220            cc_tot_mesh, cc_hc_mesh, cc_hist_mesh, &
1221            pcld_hc_mesh, tcld_hc_mesh, em_hc_mesh, iwp_hc_mesh, &
1222            deltaz_hc_mesh, &
1223            cc_Cb_mesh, cc_ThCi_mesh, cc_Anv_mesh, &
1224            pcld_Cb_mesh, tcld_Cb_mesh, em_Cb_mesh, &
1225            pcld_ThCi_mesh, tcld_ThCi_mesh, em_ThCi_mesh, &
1226            pcld_Anv_mesh, tcld_Anv_mesh, em_Anv_mesh, &
1227            em_hist_mesh, iwp_hist_mesh, deltaz_hist_mesh, rad_hist_mesh)
1228
1229    WRITE(*, *) '===================================='
1230    WRITE(*, *) 'itap, i:', itap, i
1231    WRITE(*, *) 'cc_tot, cc_hc, cc_hist, pcld_hc, tcld_hc, em_hc, &
1232            iwp_hc, em_hist, iwp_hist ='
1233    WRITE(*, *) cc_tot_mesh, cc_hc_mesh, cc_hist_mesh
1234    WRITE(*, *) pcld_hc_mesh, tcld_hc_mesh, em_hc_mesh, iwp_hc_mesh
1235    WRITE(*, *)  em_hist_mesh, iwp_hist_mesh
1236
1237    !        endif
1238
1239    ! Definition des variables a ecrire dans le fichier de sortie
1240
1241    CALL normal2_undef(map_prop_hc(i), cc_hc_mesh, &
1242            cc_tot_mesh)
1243    CALL normal2_undef(map_prop_hist(i), cc_hist_mesh, &
1244            cc_tot_mesh)
1245
1246    map_emis_hc(i) = em_hc_mesh
1247    map_iwp_hc(i) = iwp_hc_mesh
1248    map_deltaz_hc(i) = deltaz_hc_mesh
1249    map_pcld_hc(i) = pcld_hc_mesh
1250    map_tcld_hc(i) = tcld_hc_mesh
1251
1252    map_emis_Cb(i) = em_Cb_mesh
1253    map_pcld_Cb(i) = pcld_Cb_mesh
1254    map_tcld_Cb(i) = tcld_Cb_mesh
1255
1256    map_emis_ThCi(i) = em_ThCi_mesh
1257    map_pcld_ThCi(i) = pcld_ThCi_mesh
1258    map_tcld_ThCi(i) = tcld_ThCi_mesh
1259
1260    map_emis_Anv(i) = em_Anv_mesh
1261    map_pcld_Anv(i) = pcld_Anv_mesh
1262    map_tcld_Anv(i) = tcld_Anv_mesh
1263
1264    map_emis_hist(i) = em_hist_mesh
1265    map_iwp_hist(i) = iwp_hist_mesh
1266    map_deltaz_hist(i) = deltaz_hist_mesh
1267    map_rad_hist(i) = rad_hist_mesh
1268
1269    map_ntot(i) = cc_tot_mesh
1270    map_hc(i) = cc_hc_mesh
1271    map_hist(i) = cc_hist_mesh
1272
1273    map_Cb(i) = cc_Cb_mesh
1274    map_ThCi(i) = cc_ThCi_mesh
1275    map_Anv(i) = cc_Anv_mesh
1276
1277  enddo         ! fin boucle sur les points de grille
1278
1279END SUBROUTINE  simu_airs
1280
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