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conflx.F @ 5306

Last change on this file since 5306 was 343, checked in by lmdz, 23 years ago
On corrige le double bug sur la vitesse verticale LF
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1	SUBROUTINE conflx (dtime,pres_h,pres_f,
2	e t, q, con_t, con_q, pqhfl, w,
3	s d_t, d_q, rain, snow,
4	s pmfu, pmfd, pen_u, pde_u, pen_d, pde_d,
5	s kcbot, kctop, kdtop, pmflxr, pmflxs)
6	c
7	IMPLICIT none
8	c======================================================================
9	c Auteur(s): Z.X. Li (LMD/CNRS) date: 19941014
10	c Objet: Schema flux de masse pour la convection
11	c (schema de Tiedtke avec qqs modifications mineures)
12	c Dec.97: Prise en compte des modifications introduites par
13	c Olivier Boucher et Alexandre Armengaud pour melange
14	c et lessivage des traceurs passifs.
15	c======================================================================
16	#include "dimensions.h"
17	#include "dimphy.h"
18	#include "YOMCST.h"
19	#include "YOETHF.h"
20	c Entree:
21	REAL dtime ! pas d'integration (s)
22	REAL pres_h(klon,klev+1) ! pression half-level (Pa)
23	REAL pres_f(klon,klev)! pression full-level (Pa)
24	REAL t(klon,klev) ! temperature (K)
25	REAL q(klon,klev) ! humidite specifique (g/g)
26	REAL w(klon,klev) ! vitesse verticale (Pa/s)
27	REAL con_t(klon,klev) ! convergence de temperature (K/s)
28	REAL con_q(klon,klev) ! convergence de l'eau vapeur (g/g/s)
29	REAL pqhfl(klon) ! evaporation (negative vers haut) mm/s
30	c Sortie:
31	REAL d_t(klon,klev) ! incrementation de temperature
32	REAL d_q(klon,klev) ! incrementation d'humidite
33	REAL pmfu(klon,klev) ! flux masse (kg/m2/s) panache ascendant
34	REAL pmfd(klon,klev) ! flux masse (kg/m2/s) panache descendant
35	REAL pen_u(klon,klev)
36	REAL pen_d(klon,klev)
37	REAL pde_u(klon,klev)
38	REAL pde_d(klon,klev)
39	REAL rain(klon) ! pluie (mm/s)
40	REAL snow(klon) ! neige (mm/s)
41	REAL pmflxr(klon,klev+1)
42	REAL pmflxs(klon,klev+1)
43	INTEGER kcbot(klon) ! niveau du bas de la convection
44	INTEGER kctop(klon) ! niveau du haut de la convection
45	INTEGER kdtop(klon) ! niveau du haut des downdrafts
46	c Local:
47	REAL pt(klon,klev)
48	REAL pq(klon,klev)
49	REAL pqs(klon,klev)
50	REAL pvervel(klon,klev)
51	LOGICAL land(klon)
52	c
53	REAL d_t_bis(klon,klev)
54	REAL d_q_bis(klon,klev)
55	REAL paprs(klon,klev+1)
56	REAL paprsf(klon,klev)
57	REAL zgeom(klon,klev)
58	REAL zcvgq(klon,klev)
59	REAL zcvgt(klon,klev)
60	cAA
61	REAL zmfu(klon,klev)
62	REAL zmfd(klon,klev)
63	REAL zen_u(klon,klev)
64	REAL zen_d(klon,klev)
65	REAL zde_u(klon,klev)
66	REAL zde_d(klon,klev)
67	REAL zmflxr(klon,klev+1)
68	REAL zmflxs(klon,klev+1)
69	cAA
70
71	c
72	INTEGER i, k
73	REAL zdelta, zqsat
74	c
75	#include "FCTTRE.h"
76	c
77	c initialiser les variables de sortie (pour securite)
78	DO i = 1, klon
79	rain(i) = 0.0
80	snow(i) = 0.0
81	kcbot(i) = 0
82	kctop(i) = 0
83	kdtop(i) = 0
84	ENDDO
85	DO k = 1, klev
86	DO i = 1, klon
87	d_t(i,k) = 0.0
88	d_q(i,k) = 0.0
89	pmfu(i,k) = 0.0
90	pmfd(i,k) = 0.0
91	pen_u(i,k) = 0.0
92	pde_u(i,k) = 0.0
93	pen_d(i,k) = 0.0
94	pde_d(i,k) = 0.0
95	zmfu(i,k) = 0.0
96	zmfd(i,k) = 0.0
97	zen_u(i,k) = 0.0
98	zde_u(i,k) = 0.0
99	zen_d(i,k) = 0.0
100	zde_d(i,k) = 0.0
101	ENDDO
102	ENDDO
103	DO k = 1, klev+1
104	DO i = 1, klon
105	zmflxr(i,k) = 0.0
106	zmflxs(i,k) = 0.0
107	ENDDO
108	ENDDO
109	c
110	c calculer la nature du sol (pour l'instant, ocean partout)
111	DO i = 1, klon
112	land(i) = .FALSE.
113	ENDDO
114	c
115	c preparer les variables d'entree (attention: l'ordre des niveaux
116	c verticaux augmente du haut vers le bas)
117	DO k = 1, klev
118	DO i = 1, klon
119	pt(i,k) = t(i,klev-k+1)
120	pq(i,k) = q(i,klev-k+1)
121	paprsf(i,k) = pres_f(i,klev-k+1)
122	paprs(i,k) = pres_h(i,klev+1-k+1)
123	pvervel(i,k) = w(i,klev+1-k)
124	zcvgt(i,k) = con_t(i,klev-k+1)
125	zcvgq(i,k) = con_q(i,klev-k+1)
126	c
127	zdelta=MAX(0.,SIGN(1.,RTT-pt(i,k)))
128	zqsat=R2ES*FOEEW ( pt(i,k), zdelta ) / paprsf(i,k)
129	zqsat=MIN(0.5,zqsat)
130	zqsat=zqsat/(1.-RETV *zqsat)
131	pqs(i,k) = zqsat
132	ENDDO
133	ENDDO
134	DO i = 1, klon
135	paprs(i,klev+1) = pres_h(i,1)
136	zgeom(i,klev) = RD * pt(i,klev)
137	. / (0.5*(paprs(i,klev+1)+paprsf(i,klev)))
138	. * (paprs(i,klev+1)-paprsf(i,klev))
139	ENDDO
140	DO k = klev-1, 1, -1
141	DO i = 1, klon
142	zgeom(i,k) = zgeom(i,k+1)
143	. + RD * 0.5*(pt(i,k+1)+pt(i,k)) / paprs(i,k+1)
144	. * (paprsf(i,k+1)-paprsf(i,k))
145	ENDDO
146	ENDDO
147	c
148	c appeler la routine principale
149	c
150	CALL flxmain(dtime, pt, pq, pqs, pqhfl,
151	. paprsf, paprs, zgeom, land, zcvgt, zcvgq, pvervel,
152	. rain, snow, kcbot, kctop, kdtop,
153	. zmfu, zmfd, zen_u, zde_u, zen_d, zde_d,
154	. d_t_bis, d_q_bis, zmflxr, zmflxs)
155	C
156	cAA--------------------------------------------------------
157	cAA rem : De la meme facon que l'on effectue le reindicage
158	cAA pour la temperature t et le champ q
159	cAA on reindice les flux necessaires a la convection
160	cAA des traceurs
161	cAA--------------------------------------------------------
162	DO k = 1, klev
163	DO i = 1, klon
164	d_q(i,klev+1-k) = dtime*d_q_bis(i,k)
165	d_t(i,klev+1-k) = dtime*d_t_bis(i,k)
166	ENDDO
167	ENDDO
168	c
169	DO i = 1, klon
170	pmfu(i,1)= 0.
171	pmfd(i,1)= 0.
172	pen_d(i,1)= 0.
173	pde_d(i,1)= 0.
174	ENDDO
175
176	DO k = 2, klev
177	DO i = 1, klon
178	pmfu(i,klev+2-k)= zmfu(i,k)
179	pmfd(i,klev+2-k)= zmfd(i,k)
180	ENDDO
181	ENDDO
182	c
183	DO k = 1, klev
184	DO i = 1, klon
185	pen_u(i,klev+1-k)= zen_u(i,k)
186	pde_u(i,klev+1-k)= zde_u(i,k)
187	ENDDO
188	ENDDO
189	c
190	DO k = 1, klev-1
191	DO i = 1, klon
192	pen_d(i,klev+1-k)= -zen_d(i,k+1)
193	pde_d(i,klev+1-k)= -zde_d(i,k+1)
194	ENDDO
195	ENDDO
196
197	DO k = 1, klev+1
198	DO i = 1, klon
199	pmflxr(i,klev+2-k)= zmflxr(i,k)
200	pmflxs(i,klev+2-k)= zmflxs(i,k)
201	ENDDO
202	ENDDO
203
204	RETURN
205	END
206	c--------------------------------------------------------------------
207	SUBROUTINE flxmain(pdtime, pten, pqen, pqsen, pqhfl, pap, paph,
208	. pgeo, ldland, ptte, pqte, pvervel,
209	. prsfc, pssfc, kcbot, kctop, kdtop,
210	c * ldcum, ktype,
211	. pmfu, pmfd, pen_u, pde_u, pen_d, pde_d,
212	. dt_con, dq_con, pmflxr, pmflxs)
213	IMPLICIT none
214	C ------------------------------------------------------------------
215	#include "dimensions.h"
216	#include "dimphy.h"
217	#include "YOMCST.h"
218	#include "YOETHF.h"
219	#include "YOECUMF.h"
220	C ----------------------------------------------------------------
221	REAL pten(klon,klev), pqen(klon,klev), pqsen(klon,klev)
222	REAL ptte(klon,klev)
223	REAL pqte(klon,klev)
224	REAL pvervel(klon,klev)
225	REAL pgeo(klon,klev), pap(klon,klev), paph(klon,klev+1)
226	REAL pqhfl(klon)
227	c
228	REAL ptu(klon,klev), pqu(klon,klev), plu(klon,klev)
229	REAL plude(klon,klev)
230	REAL pmfu(klon,klev)
231	REAL prsfc(klon), pssfc(klon)
232	INTEGER kcbot(klon), kctop(klon), ktype(klon)
233	LOGICAL ldland(klon), ldcum(klon)
234	c
235	REAL ztenh(klon,klev), zqenh(klon,klev), zqsenh(klon,klev)
236	REAL zgeoh(klon,klev)
237	REAL zmfub(klon), zmfub1(klon)
238	REAL zmfus(klon,klev), zmfuq(klon,klev), zmful(klon,klev)
239	REAL zdmfup(klon,klev), zdpmel(klon,klev)
240	REAL zentr(klon), zhcbase(klon)
241	REAL zdqpbl(klon), zdqcv(klon), zdhpbl(klon)
242	REAL zrfl(klon)
243	REAL pmflxr(klon,klev+1)
244	REAL pmflxs(klon,klev+1)
245	INTEGER ilab(klon,klev), ictop0(klon)
246	LOGICAL llo1
247	REAL dt_con(klon,klev), dq_con(klon,klev)
248	REAL zmfmax, zdh
249	REAL pdtime, zqumqe, zdqmin, zalvdcp, zhsat, zzz
250	REAL zhhat, zpbmpt, zgam, zeps, zfac
251	INTEGER i, k, ikb, itopm2, kcum
252	c
253	REAL pen_u(klon,klev), pde_u(klon,klev)
254	REAL pen_d(klon,klev), pde_d(klon,klev)
255	c
256	REAL ptd(klon,klev), pqd(klon,klev), pmfd(klon,klev)
257	REAL zmfds(klon,klev), zmfdq(klon,klev), zdmfdp(klon,klev)
258	INTEGER kdtop(klon)
259	LOGICAL lddraf(klon)
260	C---------------------------------------------------------------------
261	LOGICAL firstcal
262	SAVE firstcal
263	DATA firstcal / .TRUE. /
264	C---------------------------------------------------------------------
265	IF (firstcal) THEN
266	CALL flxsetup
267	firstcal = .FALSE.
268	ENDIF
269	C---------------------------------------------------------------------
270	DO i = 1, klon
271	ldcum(i) = .FALSE.
272	ENDDO
273	DO k = 1, klev
274	DO i = 1, klon
275	dt_con(i,k) = 0.0
276	dq_con(i,k) = 0.0
277	ENDDO
278	ENDDO
279	c----------------------------------------------------------------------
280	c initialiser les variables et faire l'interpolation verticale
281	c----------------------------------------------------------------------
282	CALL flxini(pten, pqen, pqsen, pgeo,
283	. paph, zgeoh, ztenh, zqenh, zqsenh,
284	. ptu, pqu, ptd, pqd, pmfd, zmfds, zmfdq, zdmfdp,
285	. pmfu, zmfus, zmfuq, zdmfup,
286	. zdpmel, plu, plude, ilab, pen_u, pde_u, pen_d, pde_d)
287	c---------------------------------------------------------------------
288	c determiner les valeurs au niveau de base de la tour convective
289	c---------------------------------------------------------------------
290	CALL flxbase(ztenh, zqenh, zgeoh, paph,
291	* ptu, pqu, plu, ldcum, kcbot, ilab)
292	c---------------------------------------------------------------------
293	c calculer la convergence totale de l'humidite et celle en provenance
294	c de la couche limite, plus precisement, la convergence integree entre
295	c le sol et la base de la convection. Cette derniere convergence est
296	c comparee avec l'evaporation obtenue dans la couche limite pour
297	c determiner le type de la convection
298	c---------------------------------------------------------------------
299	k=1
300	DO i = 1, klon
301	zdqcv(i) = pqte(i,k)*(paph(i,k+1)-paph(i,k))
302	zdhpbl(i) = 0.0
303	zdqpbl(i) = 0.0
304	ENDDO
305	c
306	DO k=2,klev
307	DO i = 1, klon
308	zdqcv(i)=zdqcv(i)+pqte(i,k)*(paph(i,k+1)-paph(i,k))
309	IF (k.GE.kcbot(i)) THEN
310	zdqpbl(i)=zdqpbl(i)+pqte(i,k)*(paph(i,k+1)-paph(i,k))
311	zdhpbl(i)=zdhpbl(i)+(RCPDptte(i,k)+RLVTTpqte(i,k))
312	. *(paph(i,k+1)-paph(i,k))
313	ENDIF
314	ENDDO
315	ENDDO
316	c
317	DO i = 1, klon
318	ktype(i) = 2
319	if (zdqcv(i).GT.MAX(0.,-1.5pqhfl(i)RG)) ktype(i) = 1
320	ccc if (zdqcv(i).GT.MAX(0.,-1.1pqhfl(i)RG)) ktype(i) = 1
321	ENDDO
322	c
323	c---------------------------------------------------------------------
324	c determiner le flux de masse entrant a travers la base.
325	c on ignore, pour l'instant, l'effet du panache descendant
326	c---------------------------------------------------------------------
327	DO i = 1, klon
328	ikb=kcbot(i)
329	zqumqe=pqu(i,ikb)+plu(i,ikb)-zqenh(i,ikb)
330	zdqmin=MAX(0.01*zqenh(i,ikb),1.E-10)
331	IF (zdqpbl(i).GT.0..AND.zqumqe.GT.zdqmin.AND.ldcum(i)) THEN
332	zmfub(i) = zdqpbl(i)/(RG*MAX(zqumqe,zdqmin))
333	ELSE
334	zmfub(i) = 0.01
335	ldcum(i)=.FALSE.
336	ENDIF
337	IF (ktype(i).EQ.2) THEN
338	zdh = RCPD(ptu(i,ikb)-ztenh(i,ikb)) + RLVTTzqumqe
339	zdh = RG * MAX(zdh,1.0E5*zdqmin)
340	IF (zdhpbl(i).GT.0..AND.ldcum(i))zmfub(i)=zdhpbl(i)/zdh
341	ENDIF
342	zmfmax = (paph(i,ikb)-paph(i,ikb-1)) / (RG*pdtime)
343	zmfub(i) = MIN(zmfub(i),zmfmax)
344	zentr(i) = ENTRSCV
345	IF (ktype(i).EQ.1) zentr(i) = ENTRPEN
346	ENDDO
347	C-----------------------------------------------------------------------
348	C DETERMINE CLOUD ASCENT FOR ENTRAINING PLUME
349	C-----------------------------------------------------------------------
350	c (A) calculer d'abord la hauteur "theorique" de la tour convective sans
351	c considerer l'entrainement ni le detrainement du panache, sachant
352	c ces derniers peuvent abaisser la hauteur theorique.
353	c
354	DO i = 1, klon
355	ikb=kcbot(i)
356	zhcbase(i)=RCPDptu(i,ikb)+zgeoh(i,ikb)+RLVTTpqu(i,ikb)
357	ictop0(i)=kcbot(i)-1
358	ENDDO
359	c
360	zalvdcp=RLVTT/RCPD
361	DO k=klev-1,3,-1
362	DO i = 1, klon
363	zhsat=RCPDztenh(i,k)+zgeoh(i,k)+RLVTTzqsenh(i,k)
364	zgam=R5LESzalvdcpzqsenh(i,k)/
365	. ((1.-RETV zqsenh(i,k))(ztenh(i,k)-R4LES)**2)
366	zzz=RCPDztenh(i,k)0.608
367	zhhat=zhsat-(zzz+zgamzzz)/(1.+zgamzzz/RLVTT)*
368	. MAX(zqsenh(i,k)-zqenh(i,k),0.)
369	IF(k.LT.ictop0(i).AND.zhcbase(i).GT.zhhat) ictop0(i)=k
370	ENDDO
371	ENDDO
372	c
373	c (B) calculer le panache ascendant
374	c
375	CALL flxasc(pdtime,ztenh, zqenh, pten, pqen, pqsen,
376	. pgeo, zgeoh, pap, paph, pqte, pvervel,
377	. ldland, ldcum, ktype, ilab,
378	. ptu, pqu, plu, pmfu, zmfub, zentr,
379	. zmfus, zmfuq, zmful, plude, zdmfup,
380	. kcbot, kctop, ictop0, kcum, pen_u, pde_u)
381	IF (kcum.EQ.0) GO TO 1000
382	C
383	C verifier l'epaisseur de la convection et changer eventuellement
384	c le taux d'entrainement/detrainement
385	C
386	DO i = 1, klon
387	zpbmpt=paph(i,kcbot(i))-paph(i,kctop(i))
388	IF(ldcum(i).AND.ktype(i).EQ.1.AND.zpbmpt.LT.2.E4)ktype(i)=2
389	IF(ldcum(i)) ictop0(i)=kctop(i)
390	IF(ktype(i).EQ.2) zentr(i)=ENTRSCV
391	ENDDO
392	c
393	IF (lmfdd) THEN ! si l'on considere le panache descendant
394	c
395	c calculer la precipitation issue du panache ascendant pour
396	c determiner l'existence du panache descendant dans la convection
397	DO i = 1, klon
398	zrfl(i)=zdmfup(i,1)
399	ENDDO
400	DO k=2,klev
401	DO i = 1, klon
402	zrfl(i)=zrfl(i)+zdmfup(i,k)
403	ENDDO
404	ENDDO
405	c
406	c determiner le LFS (level of free sinking: niveau de plonge libre)
407	CALL flxdlfs(ztenh, zqenh, zgeoh, paph, ptu, pqu,
408	* ldcum, kcbot, kctop, zmfub, zrfl,
409	* ptd, pqd,
410	* pmfd, zmfds, zmfdq, zdmfdp,
411	* kdtop, lddraf)
412	c
413	c calculer le panache descendant
414	CALL flxddraf(ztenh, zqenh,
415	* zgeoh, paph, zrfl,
416	* ptd, pqd,
417	* pmfd, zmfds, zmfdq, zdmfdp,
418	* lddraf, pen_d, pde_d)
419	c
420	c calculer de nouveau le flux de masse entrant a travers la base
421	c de la convection, sachant qu'il a ete modifie par le panache
422	c descendant
423	DO i = 1, klon
424	IF (lddraf(i)) THEN
425	ikb = kcbot(i)
426	llo1 = PMFD(i,ikb).LT.0.
427	zeps = 0.
428	IF ( llo1 ) zeps = CMFDEPS
429	zqumqe = pqu(i,ikb)+plu(i,ikb)-
430	. zepspqd(i,ikb)-(1.-zeps)zqenh(i,ikb)
431	zdqmin = MAX(0.01*zqenh(i,ikb),1.E-10)
432	zmfmax = (paph(i,ikb)-paph(i,ikb-1)) / (RG*pdtime)
433	IF (zdqpbl(i).GT.0..AND.zqumqe.GT.zdqmin.AND.ldcum(i)
434	. .AND.zmfub(i).LT.zmfmax) THEN
435	zmfub1(i) = zdqpbl(i) / (RG*MAX(zqumqe,zdqmin))
436	ELSE
437	zmfub1(i) = zmfub(i)
438	ENDIF
439	IF (ktype(i).EQ.2) THEN
440	zdh = RCPD(ptu(i,ikb)-zepsptd(i,ikb)-
441	. (1.-zeps)ztenh(i,ikb))+RLVTTzqumqe
442	zdh = RG * MAX(zdh,1.0E5*zdqmin)
443	IF (zdhpbl(i).GT.0..AND.ldcum(i))zmfub1(i)=zdhpbl(i)/zdh
444	ENDIF
445	IF ( .NOT.((ktype(i).EQ.1.OR.ktype(i).EQ.2).AND.
446	. ABS(zmfub1(i)-zmfub(i)).LT.0.2*zmfub(i)) )
447	. zmfub1(i) = zmfub(i)
448	ENDIF
449	ENDDO
450	DO k = 1, klev
451	DO i = 1, klon
452	IF (lddraf(i)) THEN
453	zfac = zmfub1(i)/MAX(zmfub(i),1.E-10)
454	pmfd(i,k) = pmfd(i,k)*zfac
455	zmfds(i,k) = zmfds(i,k)*zfac
456	zmfdq(i,k) = zmfdq(i,k)*zfac
457	zdmfdp(i,k) = zdmfdp(i,k)*zfac
458	pen_d(i,k) = pen_d(i,k)*zfac
459	pde_d(i,k) = pde_d(i,k)*zfac
460	ENDIF
461	ENDDO
462	ENDDO
463	DO i = 1, klon
464	IF (lddraf(i)) zmfub(i)=zmfub1(i)
465	ENDDO
466	c
467	ENDIF ! fin de test sur lmfdd
468	c
469	c-----------------------------------------------------------------------
470	c calculer de nouveau le panache ascendant
471	c-----------------------------------------------------------------------
472	CALL flxasc(pdtime,ztenh, zqenh, pten, pqen, pqsen,
473	. pgeo, zgeoh, pap, paph, pqte, pvervel,
474	. ldland, ldcum, ktype, ilab,
475	. ptu, pqu, plu, pmfu, zmfub, zentr,
476	. zmfus, zmfuq, zmful, plude, zdmfup,
477	. kcbot, kctop, ictop0, kcum, pen_u, pde_u)
478	c
479	c-----------------------------------------------------------------------
480	c determiner les flux convectifs en forme finale, ainsi que
481	c la quantite des precipitations
482	c-----------------------------------------------------------------------
483	CALL flxflux(pdtime, pqen, pqsen, ztenh, zqenh, pap, paph,
484	. ldland, zgeoh, kcbot, kctop, lddraf, kdtop, ktype, ldcum,
485	. pmfu, pmfd, zmfus, zmfds, zmfuq, zmfdq, zmful, plude,
486	. zdmfup, zdmfdp, pten, prsfc, pssfc, zdpmel, itopm2,
487	. pmflxr, pmflxs)
488	c
489	c----------------------------------------------------------------------
490	c calculer les tendances pour T et Q
491	c----------------------------------------------------------------------
492	CALL flxdtdq(pdtime, itopm2, paph, ldcum, pten,
493	e zmfus, zmfds, zmfuq, zmfdq, zmful, zdmfup, zdmfdp, zdpmel,
494	s dt_con,dq_con)
495	c
496	1000 CONTINUE
497	RETURN
498	END
499	SUBROUTINE flxini(pten, pqen, pqsen, pgeo, paph, pgeoh, ptenh,
500	. pqenh, pqsenh, ptu, pqu, ptd, pqd, pmfd, pmfds, pmfdq,
501	. pdmfdp, pmfu, pmfus, pmfuq, pdmfup, pdpmel, plu, plude,
502	. klab,pen_u, pde_u, pen_d, pde_d)
503	IMPLICIT none
504	C----------------------------------------------------------------------
505	C THIS ROUTINE INTERPOLATES LARGE-SCALE FIELDS OF T,Q ETC.
506	C TO HALF LEVELS (I.E. GRID FOR MASSFLUX SCHEME),
507	C AND INITIALIZES VALUES FOR UPDRAFTS
508	C----------------------------------------------------------------------
509	#include "dimensions.h"
510	#include "dimphy.h"
511	#include "YOMCST.h"
512	#include "YOETHF.h"
513	C
514	REAL pten(klon,klev) ! temperature (environnement)
515	REAL pqen(klon,klev) ! humidite (environnement)
516	REAL pqsen(klon,klev) ! humidite saturante (environnement)
517	REAL pgeo(klon,klev) ! geopotentiel (g * metre)
518	REAL pgeoh(klon,klev) ! geopotentiel aux demi-niveaux
519	REAL paph(klon,klev+1) ! pression aux demi-niveaux
520	REAL ptenh(klon,klev) ! temperature aux demi-niveaux
521	REAL pqenh(klon,klev) ! humidite aux demi-niveaux
522	REAL pqsenh(klon,klev) ! humidite saturante aux demi-niveaux
523	C
524	REAL ptu(klon,klev) ! temperature du panache ascendant (p-a)
525	REAL pqu(klon,klev) ! humidite du p-a
526	REAL plu(klon,klev) ! eau liquide du p-a
527	REAL pmfu(klon,klev) ! flux de masse du p-a
528	REAL pmfus(klon,klev) ! flux de l'energie seche dans le p-a
529	REAL pmfuq(klon,klev) ! flux de l'humidite dans le p-a
530	REAL pdmfup(klon,klev) ! quantite de l'eau precipitee dans p-a
531	REAL plude(klon,klev) ! quantite de l'eau liquide jetee du
532	c p-a a l'environnement
533	REAL pdpmel(klon,klev) ! quantite de neige fondue
534	c
535	REAL ptd(klon,klev) ! temperature du panache descendant (p-d)
536	REAL pqd(klon,klev) ! humidite du p-d
537	REAL pmfd(klon,klev) ! flux de masse du p-d
538	REAL pmfds(klon,klev) ! flux de l'energie seche dans le p-d
539	REAL pmfdq(klon,klev) ! flux de l'humidite dans le p-d
540	REAL pdmfdp(klon,klev) ! quantite de precipitation dans p-d
541	c
542	REAL pen_u(klon,klev) ! quantite de masse entrainee pour p-a
543	REAL pde_u(klon,klev) ! quantite de masse detrainee pour p-a
544	REAL pen_d(klon,klev) ! quantite de masse entrainee pour p-d
545	REAL pde_d(klon,klev) ! quantite de masse detrainee pour p-d
546	C
547	INTEGER klab(klon,klev)
548	LOGICAL llflag(klon)
549	INTEGER k, i, icall
550	REAL zzs
551	C----------------------------------------------------------------------
552	C SPECIFY LARGE SCALE PARAMETERS AT HALF LEVELS
553	C ADJUST TEMPERATURE FIELDS IF STATICLY UNSTABLE
554	C----------------------------------------------------------------------
555	DO 130 k = 2, klev
556	c
557	DO i = 1, klon
558	pgeoh(i,k)=pgeo(i,k)+(pgeo(i,k-1)-pgeo(i,k))*0.5
559	ptenh(i,k)=(MAX(RCPD*pten(i,k-1)+pgeo(i,k-1),
560	. RCPD*pten(i,k)+pgeo(i,k))-pgeoh(i,k))/RCPD
561	pqsenh(i,k)=pqsen(i,k-1)
562	llflag(i)=.TRUE.
563	ENDDO
564	c
565	icall=0
566	CALL flxadjtq(paph(1,k),ptenh(1,k),pqsenh(1,k),llflag,icall)
567	c
568	DO i = 1, klon
569	pqenh(i,k)=MIN(pqen(i,k-1),pqsen(i,k-1))
570	. +(pqsenh(i,k)-pqsen(i,k-1))
571	pqenh(i,k)=MAX(pqenh(i,k),0.)
572	ENDDO
573	c
574	130 CONTINUE
575	C
576	DO 140 i = 1, klon
577	ptenh(i,klev)=(RCPD*pten(i,klev)+pgeo(i,klev)-
578	1 pgeoh(i,klev))/RCPD
579	pqenh(i,klev)=pqen(i,klev)
580	ptenh(i,1)=pten(i,1)
581	pqenh(i,1)=pqen(i,1)
582	pgeoh(i,1)=pgeo(i,1)
583	140 CONTINUE
584	c
585	DO 160 k = klev-1, 2, -1
586	DO 150 i = 1, klon
587	zzs = MAX(RCPD*ptenh(i,k)+pgeoh(i,k),
588	. RCPD*ptenh(i,k+1)+pgeoh(i,k+1))
589	ptenh(i,k) = (zzs-pgeoh(i,k))/RCPD
590	150 CONTINUE
591	160 CONTINUE
592	C
593	C-----------------------------------------------------------------------
594	C INITIALIZE VALUES FOR UPDRAFTS AND DOWNDRAFTS
595	C-----------------------------------------------------------------------
596	DO k = 1, klev
597	DO i = 1, klon
598	ptu(i,k) = ptenh(i,k)
599	pqu(i,k) = pqenh(i,k)
600	plu(i,k) = 0.
601	pmfu(i,k) = 0.
602	pmfus(i,k) = 0.
603	pmfuq(i,k) = 0.
604	pdmfup(i,k) = 0.
605	pdpmel(i,k) = 0.
606	plude(i,k) = 0.
607	c
608	klab(i,k) = 0
609	c
610	ptd(i,k) = ptenh(i,k)
611	pqd(i,k) = pqenh(i,k)
612	pmfd(i,k) = 0.0
613	pmfds(i,k) = 0.0
614	pmfdq(i,k) = 0.0
615	pdmfdp(i,k) = 0.0
616	c
617	pen_u(i,k) = 0.0
618	pde_u(i,k) = 0.0
619	pen_d(i,k) = 0.0
620	pde_d(i,k) = 0.0
621	ENDDO
622	ENDDO
623	C
624	RETURN
625	END
626	SUBROUTINE flxbase(ptenh, pqenh, pgeoh, paph,
627	* ptu, pqu, plu, ldcum, kcbot, klab)
628	IMPLICIT none
629	C----------------------------------------------------------------------
630	C THIS ROUTINE CALCULATES CLOUD BASE VALUES (T AND Q)
631	C
632	C INPUT ARE ENVIRONM. VALUES OF T,Q,P,PHI AT HALF LEVELS.
633	C IT RETURNS CLOUD BASE VALUES AND FLAGS AS FOLLOWS;
634	C klab=1 FOR SUBCLOUD LEVELS
635	C klab=2 FOR CONDENSATION LEVEL
636	C
637	C LIFT SURFACE AIR DRY-ADIABATICALLY TO CLOUD BASE
638	C (NON ENTRAINING PLUME,I.E.CONSTANT MASSFLUX)
639	C----------------------------------------------------------------------
640	#include "dimensions.h"
641	#include "dimphy.h"
642	#include "YOMCST.h"
643	#include "YOETHF.h"
644	C ----------------------------------------------------------------
645	REAL ptenh(klon,klev), pqenh(klon,klev)
646	REAL pgeoh(klon,klev), paph(klon,klev+1)
647	C
648	REAL ptu(klon,klev), pqu(klon,klev), plu(klon,klev)
649	INTEGER klab(klon,klev), kcbot(klon)
650	C
651	LOGICAL llflag(klon), ldcum(klon)
652	INTEGER i, k, icall, is
653	REAL zbuo, zqold(klon)
654	C----------------------------------------------------------------------
655	C INITIALIZE VALUES AT LIFTING LEVEL
656	C----------------------------------------------------------------------
657	DO i = 1, klon
658	klab(i,klev)=1
659	kcbot(i)=klev-1
660	ldcum(i)=.FALSE.
661	ENDDO
662	C----------------------------------------------------------------------
663	C DO ASCENT IN SUBCLOUD LAYER,
664	C CHECK FOR EXISTENCE OF CONDENSATION LEVEL,
665	C ADJUST T,Q AND L ACCORDINGLY
666	C CHECK FOR BUOYANCY AND SET FLAGS
667	C----------------------------------------------------------------------
668	DO 290 k = klev-1, 2, -1
669	c
670	is = 0
671	DO i = 1, klon
672	IF (klab(i,k+1).EQ.1) is = is + 1
673	llflag(i) = .FALSE.
674	IF (klab(i,k+1).EQ.1) llflag(i) = .TRUE.
675	ENDDO
676	IF (is.EQ.0) GOTO 290
677	c
678	DO i = 1, klon
679	IF(llflag(i)) THEN
680	pqu(i,k) = pqu(i,k+1)
681	ptu(i,k) = ptu(i,k+1)+(pgeoh(i,k+1)-pgeoh(i,k))/RCPD
682	zbuo = ptu(i,k)(1.+RETVpqu(i,k))-
683	. ptenh(i,k)(1.+RETVpqenh(i,k))+0.5
684	IF (zbuo.GT.0.) klab(i,k) = 1
685	zqold(i) = pqu(i,k)
686	ENDIF
687	ENDDO
688	c
689	icall=1
690	CALL flxadjtq(paph(1,k), ptu(1,k), pqu(1,k), llflag, icall)
691	c
692	DO i = 1, klon
693	IF (llflag(i).AND.pqu(i,k).NE.zqold(i)) THEN
694	klab(i,k) = 2
695	plu(i,k) = plu(i,k) + zqold(i)-pqu(i,k)
696	zbuo = ptu(i,k)(1.+RETVpqu(i,k))-
697	. ptenh(i,k)(1.+RETVpqenh(i,k))+0.5
698	IF (zbuo.GT.0.) kcbot(i) = k
699	IF (zbuo.GT.0.) ldcum(i) = .TRUE.
700	ENDIF
701	ENDDO
702	c
703	290 CONTINUE
704	c
705	RETURN
706	END
707	SUBROUTINE flxasc(pdtime, ptenh, pqenh, pten, pqen, pqsen,
708	. pgeo, pgeoh, pap, paph, pqte, pvervel,
709	. ldland, ldcum, ktype, klab, ptu, pqu, plu,
710	. pmfu, pmfub, pentr, pmfus, pmfuq,
711	. pmful, plude, pdmfup, kcbot, kctop, kctop0, kcum,
712	. pen_u, pde_u)
713	IMPLICIT none
714	C----------------------------------------------------------------------
715	C THIS ROUTINE DOES THE CALCULATIONS FOR CLOUD ASCENTS
716	C FOR CUMULUS PARAMETERIZATION
717	C----------------------------------------------------------------------
718	#include "dimensions.h"
719	#include "dimphy.h"
720	#include "YOMCST.h"
721	#include "YOETHF.h"
722	#include "YOECUMF.h"
723	C
724	REAL pdtime
725	REAL pten(klon,klev), ptenh(klon,klev)
726	REAL pqen(klon,klev), pqenh(klon,klev), pqsen(klon,klev)
727	REAL pgeo(klon,klev), pgeoh(klon,klev)
728	REAL pap(klon,klev), paph(klon,klev+1)
729	REAL pqte(klon,klev)
730	REAL pvervel(klon,klev) ! vitesse verticale en Pa/s
731	C
732	REAL pmfub(klon), pentr(klon)
733	REAL ptu(klon,klev), pqu(klon,klev), plu(klon,klev)
734	REAL plude(klon,klev)
735	REAL pmfu(klon,klev), pmfus(klon,klev)
736	REAL pmfuq(klon,klev), pmful(klon,klev)
737	REAL pdmfup(klon,klev)
738	INTEGER ktype(klon), klab(klon,klev), kcbot(klon), kctop(klon)
739	INTEGER kctop0(klon)
740	LOGICAL ldland(klon), ldcum(klon)
741	C
742	REAL pen_u(klon,klev), pde_u(klon,klev)
743	REAL zqold(klon)
744	REAL zdland(klon)
745	LOGICAL llflag(klon)
746	INTEGER k, i, is, icall, kcum
747	REAL ztglace, zdphi, zqeen, zseen, zscde, zqude
748	REAL zmfusk, zmfuqk, zmfulk, zbuo, zdnoprc, zprcon, zlnew
749	c
750	REAL zpbot(klon), zptop(klon), zrho(klon)
751	REAL zdprho, zentr, zpmid, zmftest, zmfmax
752	LOGICAL llo1, llo2
753	c
754	REAL zwmax(klon), zzzmb
755	INTEGER klwmin(klon) ! level of maximum vertical velocity
756	C----------------------------------------------------------------------
757	ztglace = RTT - 13.
758	c
759	c Chercher le niveau ou la vitesse verticale est maximale:
760	DO i = 1, klon
761	klwmin(i) = klev
762	zwmax(i) = 0.0
763	ENDDO
764	DO k = klev, 3, -1
765	DO i = 1, klon
766	IF (pvervel(i,k).LT.zwmax(i)) THEN
767	zwmax(i) = pvervel(i,k)
768	klwmin(i) = k
769	ENDIF
770	ENDDO
771	ENDDO
772	C----------------------------------------------------------------------
773	C SET DEFAULT VALUES
774	C----------------------------------------------------------------------
775	DO i = 1, klon
776	IF (.NOT.ldcum(i)) ktype(i)=0
777	ENDDO
778	c
779	DO k=1,klev
780	DO i = 1, klon
781	plu(i,k)=0.
782	pmfu(i,k)=0.
783	pmfus(i,k)=0.
784	pmfuq(i,k)=0.
785	pmful(i,k)=0.
786	plude(i,k)=0.
787	pdmfup(i,k)=0.
788	IF(.NOT.ldcum(i).OR.ktype(i).EQ.3) klab(i,k)=0
789	IF(.NOT.ldcum(i).AND.paph(i,k).LT.4.E4) kctop0(i)=k
790	ENDDO
791	ENDDO
792	c
793	DO i = 1, klon
794	IF (ldland(i)) THEN
795	zdland(i)=3.0E4
796	zdphi=pgeoh(i,kctop0(i))-pgeoh(i,kcbot(i))
797	IF (ptu(i,kctop0(i)).GE.ztglace) zdland(i)=zdphi
798	zdland(i)=MAX(3.0E4,zdland(i))
799	zdland(i)=MIN(5.0E4,zdland(i))
800	ENDIF
801	ENDDO
802	C
803	C Initialiser les valeurs au niveau d'ascendance
804	C
805	DO i = 1, klon
806	kctop(i) = klev-1
807	IF (.NOT.ldcum(i)) THEN
808	kcbot(i) = klev-1
809	pmfub(i) = 0.
810	pqu(i,klev) = 0.
811	ENDIF
812	pmfu(i,klev) = pmfub(i)
813	pmfus(i,klev) = pmfub(i)(RCPDptu(i,klev)+pgeoh(i,klev))
814	pmfuq(i,klev) = pmfub(i)*pqu(i,klev)
815	ENDDO
816	c
817	DO i = 1, klon
818	ldcum(i) = .FALSE.
819	ENDDO
820	C----------------------------------------------------------------------
821	C DO ASCENT: SUBCLOUD LAYER (klab=1) ,CLOUDS (klab=2)
822	C BY DOING FIRST DRY-ADIABATIC ASCENT AND THEN
823	C BY ADJUSTING T,Q AND L ACCORDINGLY IN flxadjtq,
824	C THEN CHECK FOR BUOYANCY AND SET FLAGS ACCORDINGLY
825	C----------------------------------------------------------------------
826	DO 480 k = klev-1,3,-1
827	c
828	IF (LMFMID .AND. k.LT.klev-1 .AND. k.GT.klev/2) THEN
829	DO i = 1, klon
830	IF (.NOT.ldcum(i) .AND. klab(i,k+1).EQ.0 .AND.
831	. pqen(i,k).GT.0.9*pqsen(i,k)) THEN
832	ptu(i,k+1) = pten(i,k) +(pgeo(i,k)-pgeoh(i,k+1))/RCPD
833	pqu(i,k+1) = pqen(i,k)
834	plu(i,k+1) = 0.0
835	zzzmb = MAX(CMFCMIN, -pvervel(i,k))
836	zmfmax = (paph(i,k)-paph(i,k-1))/(RG*pdtime)
837	pmfub(i) = MIN(zzzmb,zmfmax)
838	pmfu(i,k+1) = pmfub(i)
839	pmfus(i,k+1) = pmfub(i)(RCPDptu(i,k+1)+pgeoh(i,k+1))
840	pmfuq(i,k+1) = pmfub(i)*pqu(i,k+1)
841	pmful(i,k+1) = 0.0
842	pdmfup(i,k+1) = 0.0
843	kcbot(i) = k
844	klab(i,k+1) = 1
845	ktype(i) = 3
846	pentr(i) = ENTRMID
847	ENDIF
848	ENDDO
849	ENDIF
850	c
851	is = 0
852	DO i = 1, klon
853	is = is + klab(i,k+1)
854	IF (klab(i,k+1) .EQ. 0) klab(i,k) = 0
855	llflag(i) = .FALSE.
856	IF (klab(i,k+1) .GT. 0) llflag(i) = .TRUE.
857	ENDDO
858	IF (is .EQ. 0) GOTO 480
859	c
860	c calculer le taux d'entrainement et de detrainement
861	c
862	DO i = 1, klon
863	pen_u(i,k) = 0.0
864	pde_u(i,k) = 0.0
865	zrho(i)=paph(i,k+1)/(RD*ptenh(i,k+1))
866	zpbot(i)=paph(i,kcbot(i))
867	zptop(i)=paph(i,kctop0(i))
868	ENDDO
869	c
870	DO 125 i = 1, klon
871	IF(ldcum(i)) THEN
872	zdprho=(paph(i,k+1)-paph(i,k))/(RG*zrho(i))
873	zentr=pentr(i)pmfu(i,k+1)zdprho
874	llo1=k.LT.kcbot(i)
875	IF(llo1) pde_u(i,k)=zentr
876	zpmid=0.5*(zpbot(i)+zptop(i))
877	llo2=llo1.AND.ktype(i).EQ.2.AND.
878	. (zpbot(i)-paph(i,k).LT.0.2E5.OR.
879	. paph(i,k).GT.zpmid)
880	IF(llo2) pen_u(i,k)=zentr
881	llo2=llo1.AND.(ktype(i).EQ.1.OR.ktype(i).EQ.3).AND.
882	. (k.GE.MAX(klwmin(i),kctop0(i)+2).OR.pap(i,k).GT.zpmid)
883	IF(llo2) pen_u(i,k)=zentr
884	llo1=pen_u(i,k).GT.0..AND.(ktype(i).EQ.1.OR.ktype(i).EQ.2)
885	IF(llo1) THEN
886	zentr=zentr(1.+3.(1.-MIN(1.,(zpbot(i)-pap(i,k))/1.5E4)))
887	pen_u(i,k)=pen_u(i,k)(1.+3.(1.-MIN(1.,
888	. (zpbot(i)-pap(i,k))/1.5E4)))
889	pde_u(i,k)=pde_u(i,k)(1.+3.(1.-MIN(1.,
890	. (zpbot(i)-pap(i,k))/1.5E4)))
891	ENDIF
892	IF(llo2.AND.pqenh(i,k+1).GT.1.E-5)
893	. pen_u(i,k)=zentr+MAX(pqte(i,k),0.)/pqenh(i,k+1)*
894	. zrho(i)*zdprho
895	ENDIF
896	125 CONTINUE
897	c
898	C----------------------------------------------------------------------
899	c DO ADIABATIC ASCENT FOR ENTRAINING/DETRAINING PLUME
900	C----------------------------------------------------------------------
901	c
902	DO 420 i = 1, klon
903	IF (llflag(i)) THEN
904	IF (k.LT.kcbot(i)) THEN
905	zmftest = pmfu(i,k+1)+pen_u(i,k)-pde_u(i,k)
906	zmfmax = MIN(zmftest,(paph(i,k)-paph(i,k-1))/(RG*pdtime))
907	pen_u(i,k)=MAX(pen_u(i,k)-MAX(0.0,zmftest-zmfmax),0.0)
908	ENDIF
909	pde_u(i,k)=MIN(pde_u(i,k),0.75*pmfu(i,k+1))
910	c calculer le flux de masse du niveau k a partir de celui du k+1
911	pmfu(i,k)=pmfu(i,k+1)+pen_u(i,k)-pde_u(i,k)
912	c calculer les valeurs Su, Qu et l du niveau k dans le panache montant
913	zqeen=pqenh(i,k+1)*pen_u(i,k)
914	zseen=(RCPDptenh(i,k+1)+pgeoh(i,k+1))pen_u(i,k)
915	zscde=(RCPDptu(i,k+1)+pgeoh(i,k+1))pde_u(i,k)
916	zqude=pqu(i,k+1)*pde_u(i,k)
917	plude(i,k)=plu(i,k+1)*pde_u(i,k)
918	zmfusk=pmfus(i,k+1)+zseen-zscde
919	zmfuqk=pmfuq(i,k+1)+zqeen-zqude
920	zmfulk=pmful(i,k+1) -plude(i,k)
921	plu(i,k)=zmfulk*(1./MAX(CMFCMIN,pmfu(i,k)))
922	pqu(i,k)=zmfuqk*(1./MAX(CMFCMIN,pmfu(i,k)))
923	ptu(i,k)=(zmfusk*(1./MAX(CMFCMIN,pmfu(i,k)))-
924	1 pgeoh(i,k))/RCPD
925	ptu(i,k)=MAX(100.,ptu(i,k))
926	ptu(i,k)=MIN(400.,ptu(i,k))
927	zqold(i)=pqu(i,k)
928	ELSE
929	zqold(i)=0.0
930	ENDIF
931	420 CONTINUE
932	c
933	C----------------------------------------------------------------------
934	c DO CORRECTIONS FOR MOIST ASCENT BY ADJUSTING T,Q AND L
935	C----------------------------------------------------------------------
936	c
937	icall = 1
938	CALL flxadjtq(paph(1,k), ptu(1,k), pqu(1,k), llflag, icall)
939	C
940	DO 440 i = 1, klon
941	IF(llflag(i).AND.pqu(i,k).NE.zqold(i)) THEN
942	klab(i,k) = 2
943	plu(i,k) = plu(i,k)+zqold(i)-pqu(i,k)
944	zbuo = ptu(i,k)(1.+RETVpqu(i,k))-
945	. ptenh(i,k)(1.+RETVpqenh(i,k))
946	IF (klab(i,k+1).EQ.1) zbuo=zbuo+0.5
947	IF (zbuo.GT.0..AND.pmfu(i,k).GE.0.1*pmfub(i)) THEN
948	kctop(i) = k
949	ldcum(i) = .TRUE.
950	zdnoprc = 1.5E4
951	IF (ldland(i)) zdnoprc = zdland(i)
952	zprcon = CPRCON
953	IF ((zpbot(i)-paph(i,k)).LT.zdnoprc) zprcon = 0.0
954	zlnew=plu(i,k)/(1.+zprcon*(pgeoh(i,k)-pgeoh(i,k+1)))
955	pdmfup(i,k)=MAX(0.,(plu(i,k)-zlnew)*pmfu(i,k))
956	plu(i,k)=zlnew
957	ELSE
958	klab(i,k)=0
959	pmfu(i,k)=0.
960	ENDIF
961	ENDIF
962	440 CONTINUE
963	DO 455 i = 1, klon
964	IF (llflag(i)) THEN
965	pmful(i,k)=plu(i,k)*pmfu(i,k)
966	pmfus(i,k)=(RCPDptu(i,k)+pgeoh(i,k))pmfu(i,k)
967	pmfuq(i,k)=pqu(i,k)*pmfu(i,k)
968	ENDIF
969	455 CONTINUE
970	C
971	480 CONTINUE
972	C----------------------------------------------------------------------
973	C DETERMINE CONVECTIVE FLUXES ABOVE NON-BUOYANCY LEVEL
974	C (NOTE: CLOUD VARIABLES LIKE T,Q AND L ARE NOT
975	C AFFECTED BY DETRAINMENT AND ARE ALREADY KNOWN
976	C FROM PREVIOUS CALCULATIONS ABOVE)
977	C----------------------------------------------------------------------
978	DO i = 1, klon
979	IF (kctop(i).EQ.klev-1) ldcum(i) = .FALSE.
980	kcbot(i) = MAX(kcbot(i),kctop(i))
981	ENDDO
982	c
983	ldcum(1)=ldcum(1)
984	c
985	is = 0
986	DO i = 1, klon
987	if (ldcum(i)) is = is + 1
988	ENDDO
989	kcum = is
990	IF (is.EQ.0) GOTO 800
991	c
992	DO 530 i = 1, klon
993	IF (ldcum(i)) THEN
994	k=kctop(i)-1
995	pde_u(i,k)=(1.-CMFCTOP)*pmfu(i,k+1)
996	plude(i,k)=pde_u(i,k)*plu(i,k+1)
997	pmfu(i,k)=pmfu(i,k+1)-pde_u(i,k)
998	zlnew=plu(i,k)
999	pdmfup(i,k)=MAX(0.,(plu(i,k)-zlnew)*pmfu(i,k))
1000	plu(i,k)=zlnew
1001	pmfus(i,k)=(RCPDptu(i,k)+pgeoh(i,k))pmfu(i,k)
1002	pmfuq(i,k)=pqu(i,k)*pmfu(i,k)
1003	pmful(i,k)=plu(i,k)*pmfu(i,k)
1004	plude(i,k-1)=pmful(i,k)
1005	ENDIF
1006	530 CONTINUE
1007	C
1008	800 CONTINUE
1009	RETURN
1010	END
1011	SUBROUTINE flxflux(pdtime, pqen, pqsen, ptenh, pqenh, pap
1012	. , paph, ldland, pgeoh, kcbot, kctop, lddraf, kdtop
1013	. , ktype, ldcum, pmfu, pmfd, pmfus, pmfds
1014	. , pmfuq, pmfdq, pmful, plude, pdmfup, pdmfdp
1015	. , pten, prfl, psfl, pdpmel, ktopm2
1016	. , pmflxr, pmflxs)
1017	IMPLICIT none
1018	C----------------------------------------------------------------------
1019	C THIS ROUTINE DOES THE FINAL CALCULATION OF CONVECTIVE
1020	C FLUXES IN THE CLOUD LAYER AND IN THE SUBCLOUD LAYER
1021	C----------------------------------------------------------------------
1022	#include "dimensions.h"
1023	#include "dimphy.h"
1024	#include "YOMCST.h"
1025	#include "YOETHF.h"
1026	#include "YOECUMF.h"
1027	C
1028	REAL cevapcu(klev)
1029	C -----------------------------------------------------------------
1030	REAL pqen(klon,klev), pqenh(klon,klev), pqsen(klon,klev)
1031	REAL pten(klon,klev), ptenh(klon,klev)
1032	REAL paph(klon,klev+1), pgeoh(klon,klev)
1033	c
1034	REAL pap(klon,klev)
1035	REAL ztmsmlt, zdelta, zqsat
1036	C
1037	REAL pmfu(klon,klev), pmfus(klon,klev)
1038	REAL pmfd(klon,klev), pmfds(klon,klev)
1039	REAL pmfuq(klon,klev), pmful(klon,klev)
1040	REAL pmfdq(klon,klev)
1041	REAL plude(klon,klev)
1042	REAL pdmfup(klon,klev), pdpmel(klon,klev)
1043	cjq The variable maxpdmfdp(klon) has been introduced by Olivier Boucher
1044	cjq 14/11/00 to fix the problem with the negative precipitation.
1045	REAL pdmfdp(klon,klev), maxpdmfdp(klon,klev)
1046	REAL prfl(klon), psfl(klon)
1047	REAL pmflxr(klon,klev+1), pmflxs(klon,klev+1)
1048	INTEGER kcbot(klon), kctop(klon), ktype(klon)
1049	LOGICAL ldland(klon), ldcum(klon)
1050	INTEGER k, kp, i
1051	REAL zcons1, zcons2, zcucov, ztmelp2
1052	REAL pdtime, zdp, zzp, zfac, zsnmlt, zrfl, zrnew
1053	REAL zrmin, zrfln, zdrfl
1054	REAL zpds, zpdr, zdenom
1055	INTEGER ktopm2, itop, ikb
1056	c
1057	LOGICAL lddraf(klon)
1058	INTEGER kdtop(klon)
1059	c
1060	#include "FCTTRE.h"
1061	c
1062	DO 101 k=1,klev
1063	CEVAPCU(k)=1.93E-6261.SQRT(1.E3/(38.3*0.293)
1064	1 SQRT(0.5(paph(1,k)+paph(1,k+1))/paph(1,klev+1)) ) * 0.5/RG
1065	101 CONTINUE
1066	c
1067	c SPECIFY CONSTANTS
1068	c
1069	zcons1 = RCPD/(RLMLTRGpdtime)
1070	zcons2 = 1./(RG*pdtime)
1071	zcucov = 0.05
1072	ztmelp2 = RTT + 2.
1073	c
1074	c DETERMINE FINAL CONVECTIVE FLUXES
1075	c
1076	itop=klev
1077	DO 110 i = 1, klon
1078	itop=MIN(itop,kctop(i))
1079	IF (.NOT.ldcum(i) .OR. kdtop(i).LT.kctop(i)) lddraf(i)=.FALSE.
1080	IF(.NOT.ldcum(i)) ktype(i)=0
1081	110 CONTINUE
1082	c
1083	ktopm2=itop-2
1084	DO 120 k=ktopm2,klev
1085	DO 115 i = 1, klon
1086	IF(ldcum(i).AND.k.GE.kctop(i)-1) THEN
1087	pmfus(i,k)=pmfus(i,k)-pmfu(i,k)*
1088	. (RCPD*ptenh(i,k)+pgeoh(i,k))
1089	pmfuq(i,k)=pmfuq(i,k)-pmfu(i,k)*pqenh(i,k)
1090	zdp = 1.5E4
1091	IF ( ldland(i) ) zdp = 3.E4
1092	c
1093	c l'eau liquide detrainee est precipitee quand certaines
1094	c conditions sont reunies (sinon, elle est consideree
1095	c evaporee dans l'environnement)
1096	c
1097	IF(paph(i,kcbot(i))-paph(i,kctop(i)).GE.zdp.AND.
1098	. pqen(i,k-1).GT.0.8*pqsen(i,k-1))
1099	. pdmfup(i,k-1)=pdmfup(i,k-1)+plude(i,k-1)
1100	c
1101	IF(lddraf(i).AND.k.GE.kdtop(i)) THEN
1102	pmfds(i,k)=pmfds(i,k)-pmfd(i,k)*
1103	. (RCPD*ptenh(i,k)+pgeoh(i,k))
1104	pmfdq(i,k)=pmfdq(i,k)-pmfd(i,k)*pqenh(i,k)
1105	ELSE
1106	pmfd(i,k)=0.
1107	pmfds(i,k)=0.
1108	pmfdq(i,k)=0.
1109	pdmfdp(i,k-1)=0.
1110	END IF
1111	ELSE
1112	pmfu(i,k)=0.
1113	pmfus(i,k)=0.
1114	pmfuq(i,k)=0.
1115	pmful(i,k)=0.
1116	pdmfup(i,k-1)=0.
1117	plude(i,k-1)=0.
1118	pmfd(i,k)=0.
1119	pmfds(i,k)=0.
1120	pmfdq(i,k)=0.
1121	pdmfdp(i,k-1)=0.
1122	ENDIF
1123	115 CONTINUE
1124	120 CONTINUE
1125	c
1126	DO 130 k=ktopm2,klev
1127	DO 125 i = 1, klon
1128	IF(ldcum(i).AND.k.GT.kcbot(i)) THEN
1129	ikb=kcbot(i)
1130	zzp=((paph(i,klev+1)-paph(i,k))/
1131	. (paph(i,klev+1)-paph(i,ikb)))
1132	IF (ktype(i).EQ.3) zzp = zzp**2
1133	pmfu(i,k)=pmfu(i,ikb)*zzp
1134	pmfus(i,k)=pmfus(i,ikb)*zzp
1135	pmfuq(i,k)=pmfuq(i,ikb)*zzp
1136	pmful(i,k)=pmful(i,ikb)*zzp
1137	ENDIF
1138	125 CONTINUE
1139	130 CONTINUE
1140	c
1141	c CALCULATE RAIN/SNOW FALL RATES
1142	c CALCULATE MELTING OF SNOW
1143	c CALCULATE EVAPORATION OF PRECIP
1144	c
1145	DO k = 1, klev+1
1146	DO i = 1, klon
1147	pmflxr(i,k) = 0.0
1148	pmflxs(i,k) = 0.0
1149	ENDDO
1150	ENDDO
1151	DO k = ktopm2, klev
1152	DO i = 1, klon
1153	IF (ldcum(i)) THEN
1154	IF (pmflxs(i,k).GT.0.0 .AND. pten(i,k).GT.ztmelp2) THEN
1155	zfac=zcons1*(paph(i,k+1)-paph(i,k))
1156	zsnmlt=MIN(pmflxs(i,k),zfac*(pten(i,k)-ztmelp2))
1157	pdpmel(i,k)=zsnmlt
1158	ztmsmlt=pten(i,k)-zsnmlt/zfac
1159	zdelta=MAX(0.,SIGN(1.,RTT-ztmsmlt))
1160	zqsat=R2ES*FOEEW(ztmsmlt, zdelta) / pap(i,k)
1161	zqsat=MIN(0.5,zqsat)
1162	zqsat=zqsat/(1.-RETV *zqsat)
1163	pqsen(i,k) = zqsat
1164	ENDIF
1165	IF (pten(i,k).GT.RTT) THEN
1166	pmflxr(i,k+1)=pmflxr(i,k)+pdmfup(i,k)+pdmfdp(i,k)+pdpmel(i,k)
1167	pmflxs(i,k+1)=pmflxs(i,k)-pdpmel(i,k)
1168	ELSE
1169	pmflxs(i,k+1)=pmflxs(i,k)+pdmfup(i,k)+pdmfdp(i,k)
1170	pmflxr(i,k+1)=pmflxr(i,k)
1171	ENDIF
1172	c si la precipitation est negative, on ajuste le plux du
1173	c panache descendant pour eliminer la negativite
1174	IF ((pmflxr(i,k+1)+pmflxs(i,k+1)).LT.0.0) THEN
1175	pdmfdp(i,k) = -pmflxr(i,k)-pmflxs(i,k)-pdmfup(i,k)
1176	pmflxr(i,k+1) = 0.0
1177	pmflxs(i,k+1) = 0.0
1178	pdpmel(i,k) = 0.0
1179	ENDIF
1180	ENDIF
1181	ENDDO
1182	ENDDO
1183	c
1184	cjq The new variable is initialized here.
1185	cjq It contains the humidity which is fed to the downdraft
1186	cjq by evaporation of precipitation in the column below the base
1187	cjq of convection.
1188	cjq
1189	cjq In the former version, this term has been subtracted from precip
1190	cjq as well as the evaporation.
1191	cjq
1192	DO k = 1, klev
1193	DO i = 1, klon
1194	maxpdmfdp(i,k)=0.0
1195	ENDDO
1196	ENDDO
1197	DO k = 1, klev
1198	DO kp = k, klev
1199	DO i = 1, klon
1200	maxpdmfdp(i,k)=maxpdmfdp(i,k)+pdmfdp(i,kp)
1201	ENDDO
1202	ENDDO
1203	ENDDO
1204	cjq End of initialization
1205	c
1206	DO k = ktopm2, klev
1207	DO i = 1, klon
1208	IF (ldcum(i) .AND. k.GE.kcbot(i)) THEN
1209	zrfl = pmflxr(i,k) + pmflxs(i,k)
1210	IF (zrfl.GT.1.0E-20) THEN
1211	zrnew=(MAX(0.,SQRT(zrfl/zcucov)-
1212	. CEVAPCU(k)(paph(i,k+1)-paph(i,k))
1213	. MAX(0.,pqsen(i,k)-pqen(i,k))))*2zcucov
1214	zrmin=zrfl-zcucovMAX(0.,0.8pqsen(i,k)-pqen(i,k))
1215	. zcons2(paph(i,k+1)-paph(i,k))
1216	zrnew=MAX(zrnew,zrmin)
1217	zrfln=MAX(zrnew,0.)
1218	zdrfl=MIN(0.,zrfln-zrfl)
1219	cjq At least the amount of precipiation needed to feed the downdraft
1220	cjq with humidity below the base of convection has to be left and can't
1221	cjq be evaporated (surely the evaporation can't be positive):
1222	zdrfl=MAX(zdrfl,
1223	. MIN(-pmflxr(i,k)-pmflxs(i,k)-maxpdmfdp(i,k),0.0))
1224	cjq End of insertion
1225	c
1226	zdenom=1.0/MAX(1.0E-20,pmflxr(i,k)+pmflxs(i,k))
1227	IF (pten(i,k).GT.RTT) THEN
1228	zpdr = pdmfdp(i,k)
1229	zpds = 0.0
1230	ELSE
1231	zpdr = 0.0
1232	zpds = pdmfdp(i,k)
1233	ENDIF
1234	pmflxr(i,k+1) = pmflxr(i,k) + zpdr + pdpmel(i,k)
1235	. + zdrflpmflxr(i,k)zdenom
1236	pmflxs(i,k+1) = pmflxs(i,k) + zpds - pdpmel(i,k)
1237	. + zdrflpmflxs(i,k)zdenom
1238	pdmfup(i,k) = pdmfup(i,k) + zdrfl
1239	ELSE
1240	pmflxr(i,k+1) = 0.0
1241	pmflxs(i,k+1) = 0.0
1242	pdmfdp(i,k) = 0.0
1243	pdpmel(i,k) = 0.0
1244	ENDIF
1245	if (pmflxr(i,k) + pmflxs(i,k).lt.-1.e-26)
1246	. write(,) 'precip. < 1e-16 ',pmflxr(i,k) + pmflxs(i,k)
1247	ENDIF
1248	ENDDO
1249	ENDDO
1250	c
1251	DO 210 i = 1, klon
1252	prfl(i) = pmflxr(i,klev+1)
1253	psfl(i) = pmflxs(i,klev+1)
1254	210 CONTINUE
1255	c
1256	RETURN
1257	END
1258	SUBROUTINE flxdtdq(pdtime, ktopm2, paph, ldcum, pten
1259	. , pmfus, pmfds, pmfuq, pmfdq, pmful, pdmfup, pdmfdp
1260	. , pdpmel, dt_con, dq_con)
1261	IMPLICIT none
1262	c----------------------------------------------------------------------
1263	c calculer les tendances T et Q
1264	c----------------------------------------------------------------------
1265	#include "dimensions.h"
1266	#include "dimphy.h"
1267	#include "YOMCST.h"
1268	#include "YOETHF.h"
1269	#include "YOECUMF.h"
1270	C -----------------------------------------------------------------
1271	LOGICAL llo1
1272	C
1273	REAL pten(klon,klev), paph(klon,klev+1)
1274	REAL pmfus(klon,klev), pmfuq(klon,klev), pmful(klon,klev)
1275	REAL pmfds(klon,klev), pmfdq(klon,klev)
1276	REAL pdmfup(klon,klev)
1277	REAL pdmfdp(klon,klev)
1278	REAL pdpmel(klon,klev)
1279	LOGICAL ldcum(klon)
1280	REAL dt_con(klon,klev), dq_con(klon,klev)
1281	c
1282	INTEGER ktopm2
1283	REAL pdtime
1284	c
1285	INTEGER i, k
1286	REAL zalv, zdtdt, zdqdt
1287	c
1288	DO 210 k=ktopm2,klev-1
1289	DO 220 i = 1, klon
1290	IF (ldcum(i)) THEN
1291	llo1 = (pten(i,k)-RTT).GT.0.
1292	zalv = RLSTT
1293	IF (llo1) zalv = RLVTT
1294	zdtdt=RG/(paph(i,k+1)-paph(i,k))/RCPD
1295	. *(pmfus(i,k+1)-pmfus(i,k)
1296	. +pmfds(i,k+1)-pmfds(i,k)
1297	. -RLMLT*pdpmel(i,k)
1298	. -zalv*(pmful(i,k+1)-pmful(i,k)-pdmfup(i,k)-pdmfdp(i,k))
1299	. )
1300	dt_con(i,k)=zdtdt
1301	zdqdt=RG/(paph(i,k+1)-paph(i,k))
1302	. *(pmfuq(i,k+1)-pmfuq(i,k)
1303	. +pmfdq(i,k+1)-pmfdq(i,k)
1304	. +pmful(i,k+1)-pmful(i,k)-pdmfup(i,k)-pdmfdp(i,k))
1305	dq_con(i,k)=zdqdt
1306	ENDIF
1307	220 CONTINUE
1308	210 CONTINUE
1309	C
1310	k = klev
1311	DO 230 i = 1, klon
1312	IF (ldcum(i)) THEN
1313	llo1 = (pten(i,k)-RTT).GT.0.
1314	zalv = RLSTT
1315	IF (llo1) zalv = RLVTT
1316	zdtdt=-RG/(paph(i,k+1)-paph(i,k))/RCPD
1317	. (pmfus(i,k)+pmfds(i,k)+RLMLTpdpmel(i,k)
1318	. -zalv*(pmful(i,k)+pdmfup(i,k)+pdmfdp(i,k)))
1319	dt_con(i,k)=zdtdt
1320	zdqdt=-RG/(paph(i,k+1)-paph(i,k))
1321	. *(pmfuq(i,k)+pmfdq(i,k)+pmful(i,k)
1322	. +pdmfup(i,k)+pdmfdp(i,k))
1323	dq_con(i,k)=zdqdt
1324	ENDIF
1325	230 CONTINUE
1326	C
1327	RETURN
1328	END
1329	SUBROUTINE flxdlfs(ptenh, pqenh, pgeoh, paph, ptu, pqu,
1330	. ldcum, kcbot, kctop, pmfub, prfl, ptd, pqd,
1331	. pmfd, pmfds, pmfdq, pdmfdp, kdtop, lddraf)
1332	IMPLICIT none
1333	C
1334	C----------------------------------------------------------------------
1335	C THIS ROUTINE CALCULATES LEVEL OF FREE SINKING FOR
1336	C CUMULUS DOWNDRAFTS AND SPECIFIES T,Q,U AND V VALUES
1337	C
1338	C TO PRODUCE LFS-VALUES FOR CUMULUS DOWNDRAFTS
1339	C FOR MASSFLUX CUMULUS PARAMETERIZATION
1340	C
1341	C INPUT ARE ENVIRONMENTAL VALUES OF T,Q,U,V,P,PHI
1342	C AND UPDRAFT VALUES T,Q,U AND V AND ALSO
1343	C CLOUD BASE MASSFLUX AND CU-PRECIPITATION RATE.
1344	C IT RETURNS T,Q,U AND V VALUES AND MASSFLUX AT LFS.
1345	C
1346	C CHECK FOR NEGATIVE BUOYANCY OF AIR OF EQUAL PARTS OF
1347	C MOIST ENVIRONMENTAL AIR AND CLOUD AIR.
1348	C----------------------------------------------------------------------
1349	#include "dimensions.h"
1350	#include "dimphy.h"
1351	#include "YOMCST.h"
1352	#include "YOETHF.h"
1353	#include "YOECUMF.h"
1354	C
1355	REAL ptenh(klon,klev)
1356	REAL pqenh(klon,klev)
1357	REAL pgeoh(klon,klev), paph(klon,klev+1)
1358	REAL ptu(klon,klev), pqu(klon,klev)
1359	REAL pmfub(klon)
1360	REAL prfl(klon)
1361	C
1362	REAL ptd(klon,klev), pqd(klon,klev)
1363	REAL pmfd(klon,klev), pmfds(klon,klev), pmfdq(klon,klev)
1364	REAL pdmfdp(klon,klev)
1365	INTEGER kcbot(klon), kctop(klon), kdtop(klon)
1366	LOGICAL ldcum(klon), lddraf(klon)
1367	C
1368	REAL ztenwb(klon,klev), zqenwb(klon,klev), zcond(klon)
1369	REAL zttest, zqtest, zbuo, zmftop
1370	LOGICAL llo2(klon)
1371	INTEGER i, k, is, icall
1372	C----------------------------------------------------------------------
1373	DO i= 1, klon
1374	lddraf(i)=.FALSE.
1375	kdtop(i)=klev+1
1376	ENDDO
1377	C
1378	C----------------------------------------------------------------------
1379	C DETERMINE LEVEL OF FREE SINKING BY
1380	C DOING A SCAN FROM TOP TO BASE OF CUMULUS CLOUDS
1381	C
1382	C FOR EVERY POINT AND PROCEED AS FOLLOWS:
1383	C (1) DETEMINE WET BULB ENVIRONMENTAL T AND Q
1384	C (2) DO MIXING WITH CUMULUS CLOUD AIR
1385	C (3) CHECK FOR NEGATIVE BUOYANCY
1386	C
1387	C THE ASSUMPTION IS THAT AIR OF DOWNDRAFTS IS MIXTURE
1388	C OF 50% CLOUD AIR + 50% ENVIRONMENTAL AIR AT WET BULB
1389	C TEMPERATURE (I.E. WHICH BECAME SATURATED DUE TO
1390	C EVAPORATION OF RAIN AND CLOUD WATER)
1391	C----------------------------------------------------------------------
1392	C
1393	DO 290 k = 3, klev-3
1394	C
1395	is=0
1396	DO 212 i= 1, klon
1397	ztenwb(i,k)=ptenh(i,k)
1398	zqenwb(i,k)=pqenh(i,k)
1399	llo2(i) = ldcum(i).AND.prfl(i).GT.0.
1400	. .AND..NOT.lddraf(i)
1401	. .AND.(k.LT.kcbot(i).AND.k.GT.kctop(i))
1402	IF ( llo2(i) ) is = is + 1
1403	212 CONTINUE
1404	IF(is.EQ.0) GO TO 290
1405	C
1406	icall=2
1407	CALL flxadjtq(paph(1,k), ztenwb(1,k), zqenwb(1,k), llo2, icall)
1408	C
1409	C----------------------------------------------------------------------
1410	C DO MIXING OF CUMULUS AND ENVIRONMENTAL AIR
1411	C AND CHECK FOR NEGATIVE BUOYANCY.
1412	C THEN SET VALUES FOR DOWNDRAFT AT LFS.
1413	C----------------------------------------------------------------------
1414	DO 222 i= 1, klon
1415	IF (llo2(i)) THEN
1416	zttest=0.5*(ptu(i,k)+ztenwb(i,k))
1417	zqtest=0.5*(pqu(i,k)+zqenwb(i,k))
1418	zbuo=zttest(1.+RETVzqtest)-
1419	. ptenh(i,k)(1.+RETV pqenh(i,k))
1420	zcond(i)=pqenh(i,k)-zqenwb(i,k)
1421	zmftop=-CMFDEPS*pmfub(i)
1422	IF (zbuo.LT.0..AND.prfl(i).GT.10.zmftopzcond(i)) THEN
1423	kdtop(i)=k
1424	lddraf(i)=.TRUE.
1425	ptd(i,k)=zttest
1426	pqd(i,k)=zqtest
1427	pmfd(i,k)=zmftop
1428	pmfds(i,k)=pmfd(i,k)(RCPDptd(i,k)+pgeoh(i,k))
1429	pmfdq(i,k)=pmfd(i,k)*pqd(i,k)
1430	pdmfdp(i,k-1)=-0.5pmfd(i,k)zcond(i)
1431	prfl(i)=prfl(i)+pdmfdp(i,k-1)
1432	ENDIF
1433	ENDIF
1434	222 CONTINUE
1435	c
1436	290 CONTINUE
1437	C
1438	RETURN
1439	END
1440	SUBROUTINE flxddraf(ptenh, pqenh, pgeoh, paph, prfl,
1441	. ptd, pqd, pmfd, pmfds, pmfdq, pdmfdp,
1442	. lddraf, pen_d, pde_d)
1443	IMPLICIT none
1444	C
1445	C----------------------------------------------------------------------
1446	C THIS ROUTINE CALCULATES CUMULUS DOWNDRAFT DESCENT
1447	C
1448	C TO PRODUCE THE VERTICAL PROFILES FOR CUMULUS DOWNDRAFTS
1449	C (I.E. T,Q,U AND V AND FLUXES)
1450	C
1451	C INPUT IS T,Q,P,PHI,U,V AT HALF LEVELS.
1452	C IT RETURNS FLUXES OF S,Q AND EVAPORATION RATE
1453	C AND U,V AT LEVELS WHERE DOWNDRAFT OCCURS
1454	C
1455	C CALCULATE MOIST DESCENT FOR ENTRAINING/DETRAINING PLUME BY
1456	C A) MOVING AIR DRY-ADIABATICALLY TO NEXT LEVEL BELOW AND
1457	C B) CORRECTING FOR EVAPORATION TO OBTAIN SATURATED STATE.
1458	C
1459	C----------------------------------------------------------------------
1460	#include "dimensions.h"
1461	#include "dimphy.h"
1462	#include "YOMCST.h"
1463	#include "YOETHF.h"
1464	#include "YOECUMF.h"
1465	C
1466	REAL ptenh(klon,klev), pqenh(klon,klev)
1467	REAL pgeoh(klon,klev), paph(klon,klev+1)
1468	C
1469	REAL ptd(klon,klev), pqd(klon,klev)
1470	REAL pmfd(klon,klev), pmfds(klon,klev), pmfdq(klon,klev)
1471	REAL pdmfdp(klon,klev)
1472	REAL prfl(klon)
1473	LOGICAL lddraf(klon)
1474	C
1475	REAL pen_d(klon,klev), pde_d(klon,klev), zcond(klon)
1476	LOGICAL llo2(klon), llo1
1477	INTEGER i, k, is, icall, itopde
1478	REAL zentr, zseen, zqeen, zsdde, zqdde, zmfdsk, zmfdqk, zdmfdp
1479	REAL zbuo
1480	C----------------------------------------------------------------------
1481	C CALCULATE MOIST DESCENT FOR CUMULUS DOWNDRAFT BY
1482	C (A) CALCULATING ENTRAINMENT RATES, ASSUMING
1483	C LINEAR DECREASE OF MASSFLUX IN PBL
1484	C (B) DOING MOIST DESCENT - EVAPORATIVE COOLING
1485	C AND MOISTENING IS CALCULATED IN flxadjtq
1486	C (C) CHECKING FOR NEGATIVE BUOYANCY AND
1487	C SPECIFYING FINAL T,Q,U,V AND DOWNWARD FLUXES
1488	C
1489	DO 180 k = 3, klev
1490	c
1491	is = 0
1492	DO i = 1, klon
1493	llo2(i)=lddraf(i).AND.pmfd(i,k-1).LT.0.
1494	IF (llo2(i)) is = is + 1
1495	ENDDO
1496	IF (is.EQ.0) GOTO 180
1497	c
1498	DO i = 1, klon
1499	IF (llo2(i)) THEN
1500	zentr = ENTRDDpmfd(i,k-1)RD*ptenh(i,k-1)/
1501	. (RGpaph(i,k-1))(paph(i,k)-paph(i,k-1))
1502	pen_d(i,k) = zentr
1503	pde_d(i,k) = zentr
1504	ENDIF
1505	ENDDO
1506	c
1507	itopde = klev-2
1508	IF (k.GT.itopde) THEN
1509	DO i = 1, klon
1510	IF (llo2(i)) THEN
1511	pen_d(i,k)=0.
1512	pde_d(i,k)=pmfd(i,itopde)*
1513	. (paph(i,k)-paph(i,k-1))/(paph(i,klev+1)-paph(i,itopde))
1514	ENDIF
1515	ENDDO
1516	ENDIF
1517	C
1518	DO i = 1, klon
1519	IF (llo2(i)) THEN
1520	pmfd(i,k) = pmfd(i,k-1)+pen_d(i,k)-pde_d(i,k)
1521	zseen = (RCPDptenh(i,k-1)+pgeoh(i,k-1))pen_d(i,k)
1522	zqeen = pqenh(i,k-1)*pen_d(i,k)
1523	zsdde = (RCPDptd(i,k-1)+pgeoh(i,k-1))pde_d(i,k)
1524	zqdde = pqd(i,k-1)*pde_d(i,k)
1525	zmfdsk = pmfds(i,k-1)+zseen-zsdde
1526	zmfdqk = pmfdq(i,k-1)+zqeen-zqdde
1527	pqd(i,k) = zmfdqk*(1./MIN(-CMFCMIN,pmfd(i,k)))
1528	ptd(i,k) = (zmfdsk*(1./MIN(-CMFCMIN,pmfd(i,k)))-
1529	. pgeoh(i,k))/RCPD
1530	ptd(i,k) = MIN(400.,ptd(i,k))
1531	ptd(i,k) = MAX(100.,ptd(i,k))
1532	zcond(i) = pqd(i,k)
1533	ENDIF
1534	ENDDO
1535	C
1536	icall = 2
1537	CALL flxadjtq(paph(1,k), ptd(1,k), pqd(1,k), llo2, icall)
1538	C
1539	DO i = 1, klon
1540	IF (llo2(i)) THEN
1541	zcond(i) = zcond(i)-pqd(i,k)
1542	zbuo = ptd(i,k)(1.+RETV pqd(i,k))-
1543	. ptenh(i,k)(1.+RETV pqenh(i,k))
1544	llo1 = zbuo.LT.0..AND.(prfl(i)-pmfd(i,k)*zcond(i).GT.0.)
1545	IF (.not.llo1) pmfd(i,k) = 0.0
1546	pmfds(i,k) = (RCPDptd(i,k)+pgeoh(i,k))pmfd(i,k)
1547	pmfdq(i,k) = pqd(i,k)*pmfd(i,k)
1548	zdmfdp = -pmfd(i,k)*zcond(i)
1549	pdmfdp(i,k-1) = zdmfdp
1550	prfl(i) = prfl(i)+zdmfdp
1551	ENDIF
1552	ENDDO
1553	c
1554	180 CONTINUE
1555	RETURN
1556	END
1557	SUBROUTINE flxadjtq(pp, pt, pq, ldflag, kcall)
1558	IMPLICIT none
1559	c======================================================================
1560	c Objet: ajustement entre T et Q
1561	c======================================================================
1562	C NOTE: INPUT PARAMETER kcall DEFINES CALCULATION AS
1563	C kcall=0 ENV. T AND QS INCUINI
1564	C kcall=1 CONDENSATION IN UPDRAFTS (E.G. CUBASE, CUASC)
1565	C kcall=2 EVAPORATION IN DOWNDRAFTS (E.G. CUDLFS,CUDDRAF)
1566	C
1567	#include "dimensions.h"
1568	#include "dimphy.h"
1569	#include "YOMCST.h"
1570	C
1571	REAL pt(klon), pq(klon), pp(klon)
1572	LOGICAL ldflag(klon)
1573	INTEGER kcall
1574	c
1575	REAL zcond(klon), zcond1
1576	REAL Z5alvcp, z5alscp, zalvdcp, zalsdcp
1577	REAL zdelta, zcvm5, zldcp, zqsat, zcor
1578	INTEGER is, i
1579	#include "YOETHF.h"
1580	#include "FCTTRE.h"
1581	C
1582	z5alvcp = r5les*RLVTT/RCPD
1583	z5alscp = r5ies*RLSTT/RCPD
1584	zalvdcp = rlvtt/RCPD
1585	zalsdcp = rlstt/RCPD
1586	C
1587
1588	DO i = 1, klon
1589	zcond(i) = 0.0
1590	ENDDO
1591
1592	DO 210 i =1, klon
1593	IF (ldflag(i)) THEN
1594	zdelta = MAX(0.,SIGN(1.,RTT-pt(i)))
1595	zcvm5 = z5alvcp(1.-zdelta) + zdeltaz5alscp
1596	zldcp = zalvdcp(1.-zdelta) + zdeltazalsdcp
1597	zqsat = R2ES*FOEEW(pt(i),zdelta) / pp(i)
1598	zqsat = MIN(0.5,zqsat)
1599	zcor = 1./(1.-RETV*zqsat)
1600	zqsat = zqsat*zcor
1601	zcond(i) = (pq(i)-zqsat)
1602	. / (1. + FOEDE(pt(i), zdelta, zcvm5, zqsat, zcor))
1603	IF (kcall.EQ.1) zcond(i) = MAX(zcond(i),0.)
1604	IF (kcall.EQ.2) zcond(i) = MIN(zcond(i),0.)
1605	pt(i) = pt(i) + zldcp*zcond(i)
1606	pq(i) = pq(i) - zcond(i)
1607	ENDIF
1608	210 CONTINUE
1609	C
1610	is = 0
1611	DO i =1, klon
1612	IF (zcond(i).NE.0.) is = is + 1
1613	ENDDO
1614	IF (is.EQ.0) GOTO 230
1615	C
1616	DO 220 i = 1, klon
1617	IF(ldflag(i).AND.zcond(i).NE.0.) THEN
1618	zdelta = MAX(0.,SIGN(1.,RTT-pt(i)))
1619	zcvm5 = z5alvcp(1.-zdelta) + zdeltaz5alscp
1620	zldcp = zalvdcp(1.-zdelta) + zdeltazalsdcp
1621	zqsat = R2ES* FOEEW(pt(i),zdelta) / pp(i)
1622	zqsat = MIN(0.5,zqsat)
1623	zcor = 1./(1.-RETV*zqsat)
1624	zqsat = zqsat*zcor
1625	zcond1 = (pq(i)-zqsat)
1626	. / (1. + FOEDE(pt(i),zdelta,zcvm5,zqsat,zcor))
1627	pt(i) = pt(i) + zldcp*zcond1
1628	pq(i) = pq(i) - zcond1
1629	ENDIF
1630	220 CONTINUE
1631	C
1632	230 CONTINUE
1633	RETURN
1634	END
1635	SUBROUTINE flxsetup
1636	IMPLICIT none
1637	C
1638	C THIS ROUTINE DEFINES DISPOSABLE PARAMETERS FOR MASSFLUX SCHEME
1639	C
1640	#include "YOECUMF.h"
1641	C
1642	ENTRPEN=1.0E-4 ! ENTRAINMENT RATE FOR PENETRATIVE CONVECTION
1643	ENTRSCV=3.0E-4 ! ENTRAINMENT RATE FOR SHALLOW CONVECTION
1644	ENTRMID=1.0E-4 ! ENTRAINMENT RATE FOR MIDLEVEL CONVECTION
1645	ENTRDD =2.0E-4 ! ENTRAINMENT RATE FOR DOWNDRAFTS
1646	CMFCTOP=0.33 ! RELATIVE CLOUD MASSFLUX AT LEVEL ABOVE NONBUO LEVEL
1647	CMFCMAX=1.0 ! MAXIMUM MASSFLUX VALUE ALLOWED FOR UPDRAFTS ETC
1648	CMFCMIN=1.E-10 ! MINIMUM MASSFLUX VALUE (FOR SAFETY)
1649	CMFDEPS=0.3 ! FRACTIONAL MASSFLUX FOR DOWNDRAFTS AT LFS
1650	CPRCON =2.0E-4 ! CONVERSION FROM CLOUD WATER TO RAIN
1651	RHCDD=1. ! RELATIVE SATURATION IN DOWNDRAFRS (NO LONGER USED)
1652	c (FORMULATION IMPLIES SATURATION)
1653	LMFPEN = .TRUE.
1654	LMFSCV = .TRUE.
1655	LMFMID = .TRUE.
1656	LMFDD = .TRUE.
1657	LMFDUDV = .TRUE.
1658	c
1659	RETURN
1660	END

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