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cv3p1_closure.F @ 2221

Last change on this file since 2221 was 1403, checked in by Laurent Fairhead, 14 years ago

Merged LMDZ4V5.0-dev branch changes r1292:r1399 to trunk.

Validation:
Validation consisted in compiling the HEAD revision of the trunk,
LMDZ4V5.0-dev branch and the merged sources and running different
configurations on local and SX8 machines comparing results.

Local machine: bench configuration, 32x24x11, gfortran

IPSLCM5A configuration (comparison between trunk and merged sources):
- numerical convergence on dynamical fields over 3 days
- start files are equivalent (except for RN and PB fields)
- daily history files equivalent

MH07 configuration, new physics package (comparison between LMDZ4V5.0-dev branch and merged sources):
- numerical convergence on dynamical fields over 3 days
- start files are equivalent (except for RN and PB fields)
- daily history files equivalent

SX8 machine (brodie), 96x95x39 on 4 processors:

IPSLCM5A configuration:
- start files are equivalent (except for RN and PB fields)
- monthly history files equivalent

MH07 configuration:
- start files are equivalent (except for RN and PB fields)
- monthly history files equivalent

Changes to the makegcm and create_make_gcm scripts to take into account
main programs in F90 files

Fusion de la branche LMDZ4V5.0-dev (r1292:r1399) au tronc principal

Validation:
La validation a consisté à compiler la HEAD de le trunk et de la banche
LMDZ4V5.0-dev et les sources fusionnées et de faire tourner le modéle selon
différentes configurations en local et sur SX8 et de comparer les résultats

En local: 32x24x11, config bench/gfortran

pour une config IPSLCM5A (comparaison tronc/fusion):
- convergence numérique sur les champs dynamiques après 3 jours
- restart et restartphy égaux (à part sur RN et Pb)
- fichiers histoire égaux

pour une config nlle physique (MH07) (comparaison LMDZ4v5.0-dev/fusion):
- convergence numérique sur les champs dynamiques après 3 jours
- restart et restartphy égaux
- fichiers histoire équivalents

Sur brodie, 96x95x39 sur 4 proc:

pour une config IPSLCM5A:
- restart et restartphy égaux (à part sur RN et PB)
- pas de différence dans les fichiers histmth.nc

pour une config MH07
- restart et restartphy égaux (à part sur RN et PB)
- pas de différence dans les fichiers histmth.nc

Changement sur makegcm et create_make-gcm pour pouvoir prendre en compte des
programmes principaux en *F90

Property svn:eol-style set to native
Property svn:keywords set to Author Date Id Revision

File size: 17.9 KB

Line
1	!
2	! $Id: cv3p1_closure.F 1403 2010-07-01 09:02:53Z emillour $
3	!
4	SUBROUTINE cv3p1_closure(nloc,ncum,nd,icb,inb
5	: ,pbase,plcl,p,ph,tv,tvp,buoy
6	: ,Supmax,ok_inhib,Ale,Alp
7	o ,sig,w0,ptop2,cape,cin,m,iflag,coef
8	: ,Plim1,Plim2,asupmax,supmax0
9	: ,asupmaxmin,cbmf)
10
11	*
12	***************************************************************
13	* *
14	* CV3P1_CLOSURE *
15	* Ale & Alp Closure of Convect3 *
16	* *
17	* written by : Kerry Emanuel *
18	* vectorization: S. Bony *
19	* modified by : Jean-Yves Grandpeix, 18/06/2003, 19.32.10 *
20	* Julie Frohwirth, 14/10/2005 17.44.22 *
21	***************************************************************
22	*
23	implicit none
24
25	#include "cvthermo.h"
26	#include "cv3param.h"
27	#include "YOMCST2.h"
28	#include "YOMCST.h"
29	#include "conema3.h"
30	#include "iniprint.h"
31
32	c input:
33	integer ncum, nd, nloc
34	integer icb(nloc), inb(nloc)
35	real pbase(nloc),plcl(nloc)
36	real p(nloc,nd), ph(nloc,nd+1)
37	real tv(nloc,nd),tvp(nloc,nd), buoy(nloc,nd)
38	real Supmax(nloc,nd)
39	logical ok_inhib ! enable convection inhibition by dryness
40	real Ale(nloc),Alp(nloc)
41
42	c input/output:
43	real sig(nloc,nd), w0(nloc,nd), ptop2(nloc)
44
45	c output:
46	real cape(nloc),cin(nloc)
47	real m(nloc,nd)
48	real Plim1(nloc),Plim2(nloc)
49	real asupmax(nloc,nd),supmax0(nloc)
50	real asupmaxmin(nloc)
51	integer iflag(nloc)
52	c
53	c local variables:
54	integer il, i, j, k, icbmax, i0(nloc)
55	real deltap, fac, w, amu
56	real rhodp
57	real Pbmxup
58	real dtmin(nloc,nd), sigold(nloc,nd)
59	real coefmix(nloc,nd)
60	real pzero(nloc),ptop2old(nloc)
61	real cina(nloc),cinb(nloc)
62	integer ibeg(nloc)
63	integer nsupmax(nloc)
64	real supcrit,temp(nloc,nd)
65	real P1(nloc),Pmin(nloc),plfc(nloc)
66	real asupmax0(nloc)
67	logical ok(nloc)
68	real siglim(nloc,nd),wlim(nloc,nd),mlim(nloc,nd)
69	real wb2(nloc)
70	real cbmflim(nloc),cbmf1(nloc),cbmfmax(nloc),cbmf(nloc)
71	real cbmflast(nloc)
72	real coef(nloc)
73	real xp(nloc),xq(nloc),xr(nloc),discr(nloc),b3(nloc),b4(nloc)
74	real theta(nloc),bb(nloc)
75	real term1,term2,term3
76	real alp2(nloc) ! Alp with offset
77	real wb,sigmax
78	data wb /2./, sigmax /0.1/
79
80	CHARACTER (LEN=20) :: modname='cv3p1_closure'
81	CHARACTER (LEN=80) :: abort_message
82	c
83	c print *,' -> cv3p1_closure, Ale ',ale(1)
84	c
85
86	c -------------------------------------------------------
87	c -- Initialization
88	c -------------------------------------------------------
89
90	c
91	c
92	do il = 1,ncum
93	alp2(il) = max(alp(il),1.e-5)
94	cIM
95	alp2(il) = max(alp(il),1.e-12)
96	enddo
97	c
98	PBMXUP=50. ! PBMXUP+PBCRIT = cloud depth above which mixed updraughts
99	c exist (if any)
100
101	if(prt_level.GE.20)
102	. print*,'cv3p1_param nloc ncum nd icb inb nl',nloc,ncum,nd,
103	. icb(nloc),inb(nloc),nl
104	do k=1,nl
105	do il=1,ncum
106	m(il,k)=0.0
107	enddo
108	enddo
109
110	c -------------------------------------------------------
111	c -- Reset sig(i) and w0(i) for i>inb and i<icb
112	c -------------------------------------------------------
113
114	c update sig and w0 above LNB:
115
116	do 100 k=1,nl-1
117	do 110 il=1,ncum
118	if ((inb(il).lt.(nl-1)).and.(k.ge.(inb(il)+1)))then
119	sig(il,k)=beta*sig(il,k)
120	: +2.alphabuoy(il,inb(il))*ABS(buoy(il,inb(il)))
121	sig(il,k)=AMAX1(sig(il,k),0.0)
122	w0(il,k)=beta*w0(il,k)
123	endif
124	110 continue
125	100 continue
126
127	c if(prt.level.GE.20) print*,'cv3p1_param apres 100'
128	c compute icbmax:
129
130	icbmax=2
131	do 200 il=1,ncum
132	icbmax=MAX(icbmax,icb(il))
133	200 continue
134	! if(prt.level.GE.20) print*,'cv3p1_param apres 200'
135
136	c update sig and w0 below cloud base:
137
138	do 300 k=1,icbmax
139	do 310 il=1,ncum
140	if (k.le.icb(il))then
141	sig(il,k)=betasig(il,k)-2.alpha*buoy(il,icb(il))
142	$ *buoy(il,icb(il))
143	sig(il,k)=amax1(sig(il,k),0.0)
144	w0(il,k)=beta*w0(il,k)
145	endif
146	310 continue
147	300 continue
148	if(prt_level.GE.20) print*,'cv3p1_param apres 300'
149	c -------------------------------------------------------------
150	c -- Reset fractional areas of updrafts and w0 at initial time
151	c -- and after 10 time steps of no convection
152	c -------------------------------------------------------------
153
154	do 400 k=1,nl-1
155	do 410 il=1,ncum
156	if (sig(il,nd).lt.1.5.or.sig(il,nd).gt.12.0)then
157	sig(il,k)=0.0
158	w0(il,k)=0.0
159	endif
160	410 continue
161	400 continue
162	if(prt_level.GE.20) print*,'cv3p1_param apres 400'
163	c
164	c -------------------------------------------------------------
165	Cjyg1
166	C -- Calculate adiabatic ascent top pressure (ptop)
167	c -------------------------------------------------------------
168	C
169	c
170	cc 1. Start at first level where precipitations form
171	do il = 1,ncum
172	Pzero(il) = Plcl(il)-PBcrit
173	enddo
174	c
175	cc 2. Add offset
176	do il = 1,ncum
177	Pzero(il) = Pzero(il)-PBmxup
178	enddo
179	do il=1,ncum
180	ptop2old(il)=ptop2(il)
181	enddo
182	c
183	do il = 1,ncum
184	cCR:c est quoi ce 300??
185	P1(il) = Pzero(il)-300.
186	enddo
187
188	c compute asupmax=abs(supmax) up to lnm+1
189
190	DO il=1,ncum
191	ok(il)=.true.
192	nsupmax(il)=inb(il)
193	ENDDO
194
195	DO i = 1,nl
196	DO il = 1,ncum
197	IF (i .GT. icb(il) .AND. i .LE. inb(il)) THEN
198	IF (P(il,i) .LE. Pzero(il) .and.
199	$ supmax(il,i) .lt. 0 .and. ok(il)) THEN
200	nsupmax(il)=i
201	ok(il)=.false.
202	ENDIF ! end IF (P(i) ...
203	ENDIF ! end IF (icb+1 le i le inb)
204	ENDDO
205	ENDDO
206
207	if(prt_level.GE.20) print*,'cv3p1_param apres 2.'
208	DO i = 1,nl
209	DO il = 1,ncum
210	asupmax(il,i)=abs(supmax(il,i))
211	ENDDO
212	ENDDO
213
214	c
215	DO il = 1,ncum
216	asupmaxmin(il)=10.
217	Pmin(il)=100.
218	!IM ??
219	asupmax0(il)=0.
220	ENDDO
221
222	cc 3. Compute in which level is Pzero
223
224	cIM bug i0 = 18
225	DO il = 1,ncum
226	i0(il) = nl
227	ENDDO
228
229	DO i = 1,nl
230	DO il = 1,ncum
231	IF (i .GT. icb(il) .AND. i .LE. inb(il)) THEN
232	IF (P(il,i) .LE. Pzero(il) .AND. P(il,i) .GE. P1(il)) THEN
233	IF (Pzero(il) .GT. P(il,i) .AND.
234	$ Pzero(il) .LT. P(il,i-1)) THEN
235	i0(il) = i
236	ENDIF
237	ENDIF
238	ENDIF
239	ENDDO
240	ENDDO
241	if(prt_level.GE.20) print*,'cv3p1_param apres 3.'
242
243	cc 4. Compute asupmax at Pzero
244
245	DO i = 1,nl
246	DO il = 1,ncum
247	IF (i .GT. icb(il) .AND. i .LE. inb(il)) THEN
248	IF (P(il,i) .LE. Pzero(il) .AND. P(il,i) .GE. P1(il)) THEN
249	asupmax0(il) =
250	$ ((Pzero(il)-P(il,i0(il)-1))*asupmax(il,i0(il))
251	$ -(Pzero(il)-P(il,i0(il)))*asupmax(il,i0(il)-1))
252	$ /(P(il,i0(il))-P(il,i0(il)-1))
253	ENDIF
254	ENDIF
255	ENDDO
256	ENDDO
257
258
259	DO i = 1,nl
260	DO il = 1,ncum
261	IF (P(il,i) .EQ. Pzero(il)) THEN
262	asupmax(i,il) = asupmax0(il)
263	ENDIF
264	ENDDO
265	ENDDO
266	if(prt_level.GE.20) print*,'cv3p1_param apres 4.'
267
268	cc 5. Compute asupmaxmin, minimum of asupmax
269
270	DO i = 1,nl
271	DO il = 1,ncum
272	IF (i .GT. icb(il) .AND. i .LE. inb(il)) THEN
273	IF (P(il,i) .LE. Pzero(il) .AND. P(il,i) .GE. P1(il)) THEN
274	IF (asupmax(il,i) .LT. asupmaxmin(il)) THEN
275	asupmaxmin(il)=asupmax(il,i)
276	Pmin(il)=P(il,i)
277	ENDIF
278	ENDIF
279	ENDIF
280	ENDDO
281	ENDDO
282
283	DO il = 1,ncum
284	!IM
285	if(prt_level.GE.20) THEN
286	print*,'cv3p1_closure il asupmax0 asupmaxmin',il,asupmax0(il),
287	$ asupmaxmin(il) ,Pzero(il),Pmin(il)
288	endif
289	IF (asupmax0(il) .LT. asupmaxmin(il)) THEN
290	asupmaxmin(il) = asupmax0(il)
291	Pmin(il) = Pzero(il)
292	ENDIF
293	ENDDO
294	if(prt_level.GE.20) print*,'cv3p1_param apres 5.'
295
296	c
297	c Compute Supmax at Pzero
298	c
299	DO i = 1,nl
300	DO il = 1,ncum
301	IF (i .GT. icb(il) .AND. i .LE. inb(il)) THEN
302	IF (P(il,i) .LE. Pzero(il)) THEN
303	Supmax0(il) = ((P(il,i )-Pzero(il))*aSupmax(il,i-1)
304	$ -(P(il,i-1)-Pzero(il))*aSupmax(il,i ))
305	$ /(P(il,i)-P(il,i-1))
306	GO TO 425
307	ENDIF ! end IF (P(i) ...
308	ENDIF ! end IF (icb+1 le i le inb)
309	ENDDO
310	ENDDO
311
312	425 continue
313	if(prt_level.GE.20) print*,'cv3p1_param apres 425.'
314
315	cc 6. Calculate ptop2
316	c
317	DO il = 1,ncum
318	IF (asupmaxmin(il) .LT. Supcrit1) THEN
319	Ptop2(il) = Pmin(il)
320	ENDIF
321
322	IF (asupmaxmin(il) .GT. Supcrit1
323	$ .AND. asupmaxmin(il) .LT. Supcrit2) THEN
324	Ptop2(il) = Ptop2old(il)
325	ENDIF
326
327	IF (asupmaxmin(il) .GT. Supcrit2) THEN
328	Ptop2(il) = Ph(il,inb(il))
329	ENDIF
330	ENDDO
331	c
332	if(prt_level.GE.20) print*,'cv3p1_param apres 6.'
333
334	cc 7. Compute multiplying factor for adiabatic updraught mass flux
335	c
336	c
337	IF (ok_inhib) THEN
338	c
339	DO i = 1,nl
340	DO il = 1,ncum
341	IF (i .le. nl) THEN
342	coefmix(il,i) = (min(ptop2(il),ph(il,i))-ph(il,i))
343	$ /(ph(il,i+1)-ph(il,i))
344	coefmix(il,i) = min(coefmix(il,i),1.)
345	ENDIF
346	ENDDO
347	ENDDO
348	c
349	c
350	ELSE ! when inhibition is not taken into account, coefmix=1
351	c
352
353	c
354	DO i = 1,nl
355	DO il = 1,ncum
356	IF (i .le. nl) THEN
357	coefmix(il,i) = 1.
358	ENDIF
359	ENDDO
360	ENDDO
361	c
362	ENDIF ! ok_inhib
363	if(prt_level.GE.20) print*,'cv3p1_param apres 7.'
364	c -------------------------------------------------------------------
365	c -------------------------------------------------------------------
366	c
367
368	Cjyg2
369	C
370	c==========================================================================
371	C
372	c
373	c -------------------------------------------------------------
374	c -- Calculate convective inhibition (CIN)
375	c -------------------------------------------------------------
376
377	c do i=1,nloc
378	c print*,'avant cine p',pbase(i),plcl(i)
379	c enddo
380	c do j=1,nd
381	c do i=1,nloc
382	c print*,'avant cine t',tv(i),tvp(i)
383	c enddo
384	c enddo
385	CALL cv3_cine (nloc,ncum,nd,icb,inb
386	: ,pbase,plcl,p,ph,tv,tvp
387	: ,cina,cinb,plfc)
388	c
389	DO il = 1,ncum
390	cin(il) = cina(il)+cinb(il)
391	ENDDO
392	if(prt_level.GE.20) print*,'cv3p1_param apres cv3_cine'
393	c -------------------------------------------------------------
394	c --Update buoyancies to account for Ale
395	c -------------------------------------------------------------
396	c
397	CALL cv3_buoy (nloc,ncum,nd,icb,inb
398	: ,pbase,plcl,p,ph,Ale,Cin
399	: ,tv,tvp
400	: ,buoy )
401	if(prt_level.GE.20) print*,'cv3p1_param apres cv3_buoy'
402
403	c -------------------------------------------------------------
404	c -- Calculate convective available potential energy (cape),
405	c -- vertical velocity (w), fractional area covered by
406	c -- undilute updraft (sig), and updraft mass flux (m)
407	c -------------------------------------------------------------
408
409	do 500 il=1,ncum
410	cape(il)=0.0
411	500 continue
412
413	c compute dtmin (minimum buoyancy between ICB and given level k):
414
415	do k=1,nl
416	do il=1,ncum
417	dtmin(il,k)=100.0
418	enddo
419	enddo
420
421	do 550 k=1,nl
422	do 560 j=minorig,nl
423	do 570 il=1,ncum
424	if ( (k.ge.(icb(il)+1)).and.(k.le.inb(il)).and.
425	: (j.ge.icb(il)).and.(j.le.(k-1)) )then
426	dtmin(il,k)=AMIN1(dtmin(il,k),buoy(il,j))
427	endif
428	570 continue
429	560 continue
430	550 continue
431
432	c the interval on which cape is computed starts at pbase :
433
434	do 600 k=1,nl
435	do 610 il=1,ncum
436
437	if ((k.ge.(icb(il)+1)).and.(k.le.inb(il))) then
438
439	deltap = MIN(pbase(il),ph(il,k-1))-MIN(pbase(il),ph(il,k))
440	cape(il)=cape(il)+rrdbuoy(il,k-1)deltap/p(il,k-1)
441	cape(il)=AMAX1(0.0,cape(il))
442	sigold(il,k)=sig(il,k)
443
444
445	cjyg Coefficient coefmix limits convection to levels where a sufficient
446	c fraction of mixed draughts are ascending.
447	siglim(il,k)=coefmix(il,k)alpha1dtmin(il,k)*ABS(dtmin(il,k))
448	siglim(il,k)=amax1(siglim(il,k),0.0)
449	siglim(il,k)=amin1(siglim(il,k),0.01)
450	cc fac=AMIN1(((dtcrit-dtmin(il,k))/dtcrit),1.0)
451	fac = 1.
452	wlim(il,k)=fac*SQRT(cape(il))
453	amu=siglim(il,k)*wlim(il,k)
454	rhodp = 0.007p(il,k)(ph(il,k)-ph(il,k+1))/tv(il,k)
455	mlim(il,k)=amu*rhodp
456	c print*, 'siglim ', k,siglim(1,k)
457	endif
458
459	610 continue
460	600 continue
461	if(prt_level.GE.20) print*,'cv3p1_param apres 600'
462
463	do 700 il=1,ncum
464	!IM beg
465	if(prt_level.GE.20) THEN
466	print*,'cv3p1_closure il icb mlim ph ph+1 ph+2',il,
467	$icb(il),mlim(il,icb(il)+1),ph(il,icb(il)),
468	$ph(il,icb(il)+1),ph(il,icb(il)+2)
469	endif
470
471	if (icb(il)+1.le.inb(il)) then
472	!IM end
473	mlim(il,icb(il))=0.5*mlim(il,icb(il)+1)
474	: *(ph(il,icb(il))-ph(il,icb(il)+1))
475	: /(ph(il,icb(il)+1)-ph(il,icb(il)+2))
476	!IM beg
477	endif !(icb(il.le.inb(il))) then
478	!IM end
479	700 continue
480	if(prt_level.GE.20) print*,'cv3p1_param apres 700'
481
482	cjyg1
483	c------------------------------------------------------------------------
484	cc Correct mass fluxes so that power used to overcome CIN does not
485	cc exceed Power Available for Lifting (PAL).
486	c------------------------------------------------------------------------
487	c
488	do il = 1,ncum
489	cbmflim(il) = 0.
490	cbmf(il) = 0.
491	enddo
492	c
493	cc 1. Compute cloud base mass flux of elementary system (Cbmf0=Cbmflim)
494	c
495	do k= 1,nl
496	do il = 1,ncum
497	!old IF (k .ge. icb(il) .and. k .le. inb(il)) THEN
498	!IM IF (k .ge. icb(il)+1 .and. k .le. inb(il)) THEN
499	IF (k .ge. icb(il) .and. k .le. inb(il) !cor jyg
500	$ .and. icb(il)+1 .le. inb(il)) THEN !cor jyg
501	cbmflim(il) = cbmflim(il)+MLIM(il,k)
502	ENDIF
503	enddo
504	enddo
505	if(prt_level.GE.20) print*,'cv3p1_param apres cbmflim'
506
507	cc 1.5 Compute cloud base mass flux given by Alp closure (Cbmf1), maximum
508	cc allowed mass flux (Cbmfmax) and final target mass flux (Cbmf)
509	cc Cbmf is set to zero if Cbmflim (the mass flux of elementary cloud) is
510	c-- exceedingly small.
511	c
512	DO il = 1,ncum
513	wb2(il) = sqrt(2.*max(Ale(il)+cin(il),0.))
514	ENDDO
515	c
516	DO il = 1,ncum
517	cbmf1(il) = alp2(il)/(0.5wbwb-Cin(il))
518	if(cbmf1(il).EQ.0.AND.alp2(il).NE.0.) THEN
519	write(lunout,*)
520	& 'cv3p1_closure cbmf1=0 and alp NE 0 il alp2 alp cin ',il,
521	. alp2(il),alp(il),cin(il)
522	abort_message = ''
523	CALL abort_gcm (modname,abort_message,1)
524	endif
525	cbmfmax(il) = sigmaxwb2(il)100.*p(il,icb(il))
526	: /(rrd*tv(il,icb(il)))
527	ENDDO
528	c
529	DO il = 1,ncum
530	IF (cbmflim(il) .gt. 1.e-6) THEN
531	cATTENTION TEST CR
532	c if (cbmfmax(il).lt.1.e-12) then
533	cbmf(il) = min(cbmf1(il),cbmfmax(il))
534	c else
535	c cbmf(il) = cbmf1(il)
536	c endif
537	c print*,'cbmf',cbmf1(il),cbmfmax(il)
538	ENDIF
539	ENDDO
540	if(prt_level.GE.20) print*,'cv3p1_param apres cbmflim_testCR'
541	c
542	cc 2. Compute coefficient and apply correction
543	c
544	do il = 1,ncum
545	coef(il) = (cbmf(il)+1.e-10)/(cbmflim(il)+1.e-10)
546	enddo
547	if(prt_level.GE.20) print*,'cv3p1_param apres coef_plantePLUS'
548	c
549	DO k = 1,nl
550	do il = 1,ncum
551	IF ( k .ge. icb(il)+1 .AND. k .le. inb(il)) THEN
552	amu=betasig(il,k)w0(il,k)+
553	: (1.-beta)coef(il)siglim(il,k)*wlim(il,k)
554	w0(il,k) = wlim(il,k)
555	w0(il,k) =max(w0(il,k),1.e-10)
556	sig(il,k)=amu/w0(il,k)
557	sig(il,k)=min(sig(il,k),1.)
558	cc amu = 0.5(SIG(il,k)+sigold(il,k))W0(il,k)
559	M(il,k)=AMU0.007P(il,k)*(PH(il,k)-PH(il,k+1))/TV(il,k)
560	ENDIF
561	enddo
562	ENDDO
563	cjyg2
564	DO il = 1,ncum
565	w0(il,icb(il))=0.5*w0(il,icb(il)+1)
566	m(il,icb(il))=0.5*m(il,icb(il)+1)
567	$ *(ph(il,icb(il))-ph(il,icb(il)+1))
568	$ /(ph(il,icb(il)+1)-ph(il,icb(il)+2))
569	sig(il,icb(il))=sig(il,icb(il)+1)
570	sig(il,icb(il)-1)=sig(il,icb(il))
571	ENDDO
572	if(prt_level.GE.20) print*,'cv3p1_param apres w0_sig_M'
573	c
574	cc 3. Compute final cloud base mass flux and set iflag to 3 if
575	cc cloud base mass flux is exceedingly small and is decreasing (i.e. if
576	cc the final mass flux (cbmflast) is greater than the target mass flux
577	cc (cbmf)).
578	c
579	do il = 1,ncum
580	cbmflast(il) = 0.
581	enddo
582	c
583	do k= 1,nl
584	do il = 1,ncum
585	IF (k .ge. icb(il) .and. k .le. inb(il)) THEN
586	!IMpropo?? IF ((k.ge.(icb(il)+1)).and.(k.le.inb(il))) THEN
587	cbmflast(il) = cbmflast(il)+M(il,k)
588	ENDIF
589	enddo
590	enddo
591	c
592	do il = 1,ncum
593	IF (cbmflast(il) .lt. 1.e-6 .and.
594	$ cbmflast(il) .ge. cbmf(il)) THEN
595	iflag(il) = 3
596	ENDIF
597	enddo
598	c
599	do k= 1,nl
600	do il = 1,ncum
601	IF (iflag(il) .ge. 3) THEN
602	M(il,k) = 0.
603	sig(il,k) = 0.
604	w0(il,k) = 0.
605	ENDIF
606	enddo
607	enddo
608	if(prt_level.GE.20) print*,'cv3p1_param apres iflag'
609	c
610	cc 4. Introduce a correcting factor for coef, in order to obtain an effective
611	cc sigdz larger in the present case (using cv3p1_closure) than in the old
612	cc closure (using cv3_closure).
613	if (1.eq.0) then
614	do il = 1,ncum
615	cc coef(il) = 2.*coef(il)
616	coef(il) = 5.*coef(il)
617	enddo
618	c version CVS du ..2008
619	else
620	if (iflag_cvl_sigd.eq.0) then
621	ctest pour verifier qu on fait la meme chose qu avant: sid constant
622	coef(1:ncum)=1.
623	else
624	coef(1:ncum) = min(2.*coef(1:ncum),5.)
625	coef(1:ncum) = max(2.*coef(1:ncum),0.2)
626	endif
627	endif
628	c
629	if(prt_level.GE.20) print*,'cv3p1_param FIN'
630	return
631	end
632
633

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