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convect2.F @ 5304

Last change on this file since 5304 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: 45.0 KB

Line
1	!
2	! $Id: convect2.F 1403 2010-07-01 09:02:53Z abarral $
3	!
4	subroutine convect2(ncum,idcum,len,nd,ndp1,nl,minorig,
5	& nk1,icb1,
6	& t1,q1,qs1,u1,v1,gz1,tv1,tp1,tvp1,clw1,h1,
7	& lv1,cpn1,p1,ph1,ft1,fq1,fu1,fv1,
8	& tnk1,qnk1,gznk1,plcl1,
9	& precip1,cbmf1,iflag1,
10	& delt,cpd,cpv,cl,rv,rd,lv0,g,
11	& sigs,sigd,elcrit,tlcrit,omtsnow,dtmax,damp,
12	& alpha,entp,coeffs,coeffr,omtrain,cu,Ma)
13	C.............................START PROLOGUE............................
14	C
15	C SCCS IDENTIFICATION: @(#)convect2.f 1.2 05/18/00
16	C 22:06:22 /h/cm/library/nogaps4/src/sub/fcst/convect2.f_v
17	C
18	C CONFIGURATION IDENTIFICATION: None
19	C
20	C MODULE NAME: convect2
21	C
22	C DESCRIPTION:
23	C
24	C convect1 The Emanuel Cumulus Convection Scheme - compute tendencies
25	C
26	C CONTRACT NUMBER AND TITLE: None
27	C
28	C REFERENCES: Programmers K. Emanuel (MIT), Timothy F. Hogan, M. Peng (NRL)
29	C
30	C CLASSIFICATION: Unclassified
31	C
32	C RESTRICTIONS: None
33	C
34	C COMPILER DEPENDENCIES: FORTRAN 77, FORTRAN 90
35	C
36	C COMPILE OPTIONS: Fortran 77: -Zu -Wf"-ei -o aggress"
37	C Fortran 90: -O vector3,scalar3,task1,aggress,overindex -ei -r 2
38	C
39	C LIBRARIES OF RESIDENCE: /a/ops/lib/libfcst159.a
40	C
41	C USAGE: call convect2(ncum,idcum,len,nd,nl,minorig,
42	C & nk1,icb1,
43	C & t1,q1,qs1,u1,v1,gz1,tv1,tp1,tvp1,clw1,h1,
44	C & lv1,cpn1,p1,ph1,ft1,fq1,fu1,fv1,
45	C & tnk1,qnk1,gznk1,plcl1,
46	C & precip1,cbmf1,iflag1,
47	C & delt,cpd,cpv,cl,rv,rd,lv0,g,
48	C & sigs,sigd,elcrit,tlcrit,omtsnow,dtmax,damp,
49	C & alpha,entp,coeffs,coeffr,omtrain,cu)
50	C
51	C PARAMETERS:
52	C Name Type Usage Description
53	C ---------- ---------- ------- ----------------------------
54	C
55	C ncum Integer Input number of cumulus points
56	C idcum Integer Input index of cumulus point
57	C len Integer Input first dimension
58	C nd Integer Input total vertical dimension
59	C ndp1 Integer Input nd + 1
60	C nl Integer Input vertical dimension for convection
61	C minorig Integer Input First level where convection is allow to begin
62	C nk1 Integer Input First level of convection
63	C ncb1 Integer Input Level of free convection
64	C t1 Real Input temperature
65	C q1 Real Input specific hum
66	C qs1 Real Input sat specific hum
67	C u1 Real Input u-wind
68	C v1 Real Input v-wind
69	C gz1 Real Inout geop
70	C tv1 Real Input virtual temp
71	C tp1 Real Input
72	C clw1 Real Inout cloud liquid water
73	C h1 Real Inout
74	C lv1 Real Inout
75	C cpn1 Real Inout
76	C p1 Real Input full level pressure
77	C ph1 Real Input half level pressure
78	C ft1 Real Output temp tend
79	C fq1 Real Output spec hum tend
80	C fu1 Real Output u-wind tend
81	C fv1 Real Output v-wind tend
82	C precip1 Real Output prec
83	C cbmf1 Real In/Out cumulus mass flux
84	C iflag1 Integer Output iflag on latitude strip
85	C delt Real Input time step
86	C cpd Integer Input See description below
87	C cpv Integer Input See description below
88	C cl Integer Input See description below
89	C rv Integer Input See description below
90	C rd Integer Input See description below
91	C lv0 Integer Input See description below
92	C g Integer Input See description below
93	C sigs Integer Input See description below
94	C sigd Integer Input See description below
95	C elcrit Integer Input See description below
96	C tlcrit Integer Input See description below
97	C omtsnow Integer Input See description below
98	C dtmax Integer Input See description below
99	C damp Integer Input See description below
100	C alpha Integer Input See description below
101	C ent Integer Input See description below
102	C coeffs Integer Input See description below
103	C coeffr Integer Input See description below
104	C omtrain Integer Input See description below
105	C cu Integer Input See description below
106	C
107	C COMMON BLOCKS:
108	C Block Name Type Usage Notes
109	C -------- -------- ---- ------ ------------------------
110	C
111	C FILES: None
112	C
113	C DATA BASES: None
114	C
115	C NON-FILE INPUT/OUTPUT: None
116	C
117	C ERROR CONDITIONS: None
118	C
119	C ADDITIONAL COMMENTS: None
120	C
121	C.................MAINTENANCE SECTION................................
122	C
123	C MODULES CALLED:
124	C Name Description
125	C zilch Zero out an array
126	C ------- ----------------------
127	C LOCAL VARIABLES AND
128	C STRUCTURES:
129	C Name Type Description
130	C ------- ------ -----------
131	C See Comments Below
132	C
133	C i Integer loop index
134	C k Integer loop index
135	c
136	C METHOD:
137	C
138	C See Emanuel, K. and M. Zivkovic-Rothman, 2000: Development and evaluation of a
139	C convective scheme for use in climate models.
140	C
141	C FILES: None
142	C
143	C INCLUDE FILES: None
144	C
145	C MAKEFILE: /a/ops/met/nogaps/src/sub/fcst/fcst159lib.mak
146	C
147	C..............................END PROLOGUE.............................
148	c
149	c
150	USE dimphy
151	implicit none
152	c
153	cym#include "dimensions.h"
154	cym#include "dimphy.h"
155	c
156	integer kmax2,imax2,kmin2,imin2
157	real ftmax2,ftmin2
158	integer kmax,imax,kmin,imin
159	real ftmax,ftmin
160	c
161	integer ncum
162	integer idcum(len)
163	integer len
164	integer nd
165	integer ndp1
166	integer nl
167	integer minorig
168	integer nk1(len)
169	integer icb1(len)
170	real t1(len,nd)
171	real q1(len,nd)
172	real qs1(len,nd)
173	real u1(len,nd)
174	real v1(len,nd)
175	real gz1(len,nd)
176	real tv1(len,nd)
177	real tp1(len,nd)
178	real tvp1(len,nd)
179	real clw1(len,nd)
180	real h1(len,nd)
181	real lv1(len,nd)
182	real cpn1(len,nd)
183	real p1(len,nd)
184	real ph1(len,ndp1)
185	real ft1(len,nd)
186	real fq1(len,nd)
187	real fu1(len,nd)
188	real fv1(len,nd)
189	real tnk1(len)
190	real qnk1(len)
191	real gznk1(len)
192	real precip1(len)
193	real cbmf1(len)
194	real plcl1(len)
195	integer iflag1(len)
196	real delt
197	real cpd
198	real cpv
199	real cl
200	real rv
201	real rd
202	real lv0
203	real g
204	real sigs ! SIGS IS THE FRACTION OF PRECIPITATION FALLING OUTSIDE
205	real sigd ! SIGD IS THE FRACTIONAL AREA COVERED BY UNSATURATED DNDRAFT
206	real elcrit ! ELCRIT IS THE AUTOCONVERSION THERSHOLD WATER CONTENT (gm/gm)
207	real tlcrit ! TLCRIT IS CRITICAL TEMPERATURE BELOW WHICH THE AUTO-
208	c CONVERSION THRESHOLD IS ASSUMED TO BE ZERO
209	real omtsnow ! OMTSNOW IS THE ASSUMED FALL SPEED (P/s) OF SNOW
210	real dtmax ! DTMAX IS THE MAXIMUM NEGATIVE TEMPERATURE PERTURBATION
211	c A LIFTED PARCEL IS ALLOWED TO HAVE BELOW ITS LFC.
212	real damp
213	real alpha
214	real entp ! ENTP IS THE COEFFICIENT OF MIXING IN THE ENTRAINMENT FORMULATION
215	real coeffs ! COEFFS IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION OF SNOW
216	real coeffr ! COEFFR IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION OF RAIN
217	real omtrain ! OMTRAIN IS THE ASSUMED FALL SPEED (P/s) OF RAIN
218	real cu ! CU IS THE COEFFICIENT GOVERNING CONVECTIVE MOMENTUM TRANSPORT
219	c
220	real Ma(len,nd)
221	c
222	C
223	C * ELCRIT IS THE AUTOCONVERSION THERSHOLD WATER CONTENT (gm/gm) *
224	C * TLCRIT IS CRITICAL TEMPERATURE BELOW WHICH THE AUTO- *
225	C * CONVERSION THRESHOLD IS ASSUMED TO BE ZERO *
226	C * (THE AUTOCONVERSION THRESHOLD VARIES LINEARLY *
227	C * BETWEEN 0 C AND TLCRIT) *
228	C * ENTP IS THE COEFFICIENT OF MIXING IN THE ENTRAINMENT *
229	C * FORMULATION *
230	C * SIGD IS THE FRACTIONAL AREA COVERED BY UNSATURATED DNDRAFT *
231	C * SIGS IS THE FRACTION OF PRECIPITATION FALLING OUTSIDE *
232	C * OF CLOUD *
233	C * OMTRAIN IS THE ASSUMED FALL SPEED (P/s) OF RAIN *
234	C * OMTSNOW IS THE ASSUMED FALL SPEED (P/s) OF SNOW *
235	C * COEFFR IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION *
236	C * OF RAIN *
237	C * COEFFS IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION *
238	C * OF SNOW *
239	C * CU IS THE COEFFICIENT GOVERNING CONVECTIVE MOMENTUM *
240	C * TRANSPORT *
241	C * DTMAX IS THE MAXIMUM NEGATIVE TEMPERATURE PERTURBATION *
242	C * A LIFTED PARCEL IS ALLOWED TO HAVE BELOW ITS LFC *
243	C * ALPHA AND DAMP ARE PARAMETERS THAT CONTROL THE RATE OF *
244	C * APPROACH TO QUASI-EQUILIBRIUM *
245	C * (THEIR STANDARD VALUES ARE 0.20 AND 0.1, RESPECTIVELY) *
246	C * (DAMP MUST BE LESS THAN 1) *
247	c
248	c Local arrays.
249	c
250	real work(ncum)
251	real t(ncum,klev)
252	real q(ncum,klev)
253	real qs(ncum,klev)
254	real u(ncum,klev)
255	real v(ncum,klev)
256	real gz(ncum,klev)
257	real h(ncum,klev)
258	real lv(ncum,klev)
259	real cpn(ncum,klev)
260	real p(ncum,klev)
261	real ph(ncum,klev)
262	real ft(ncum,klev)
263	real fq(ncum,klev)
264	real fu(ncum,klev)
265	real fv(ncum,klev)
266	real precip(ncum)
267	real cbmf(ncum)
268	real plcl(ncum)
269	real tnk(ncum)
270	real qnk(ncum)
271	real gznk(ncum)
272	real tv(ncum,klev)
273	real tp(ncum,klev)
274	real tvp(ncum,klev)
275	real clw(ncum,klev)
276	c real det(ncum,klev)
277	real dph(ncum,klev)
278	c real wd(ncum)
279	c real tprime(ncum)
280	c real qprime(ncum)
281	real ah0(ncum)
282	real ep(ncum,klev)
283	real sigp(ncum,klev)
284	integer nent(ncum,klev)
285	real water(ncum,klev)
286	real evap(ncum,klev)
287	real mp(ncum,klev)
288	real m(ncum,klev)
289	real qti
290	real wt(ncum,klev)
291	real hp(ncum,klev)
292	real lvcp(ncum,klev)
293	real elij(ncum,klev,klev)
294	real ment(ncum,klev,klev)
295	real sij(ncum,klev,klev)
296	real qent(ncum,klev,klev)
297	real uent(ncum,klev,klev)
298	real vent(ncum,klev,klev)
299	real qp(ncum,klev)
300	real up(ncum,klev)
301	real vp(ncum,klev)
302	real cape(ncum)
303	real capem(ncum)
304	real frac(ncum)
305	real dtpbl(ncum)
306	real tvpplcl(ncum)
307	real tvaplcl(ncum)
308	real dtmin(ncum)
309	real w3d(ncum,klev)
310	real am(ncum)
311	real ents(ncum)
312	real uav(ncum)
313	real vav(ncum)
314	c
315	integer iflag(ncum)
316	integer nk(ncum)
317	integer icb(ncum)
318	integer inb(ncum)
319	integer inb1(ncum)
320	integer jtt(ncum)
321	c
322	integer nn,i,k,n,icbmax,nlp,j
323	integer ij
324	integer nn2,nn3
325	real clmcpv
326	real clmcpd
327	real cpdmcp
328	real cpvmcpd
329	real eps
330	real epsi
331	real epsim1
332	real tg,qg,s,alv,tc,ahg,denom,es,rg,ginv,rowl
333	real delti
334	real tca,elacrit
335	real by,defrac
336	c real byp
337	real byp(ncum)
338	logical lcape(ncum)
339	real dbo
340	real bf2,anum,dei,altem,cwat,stemp
341	real alt,qp1,smid,sjmax,sjmin
342	real delp,delm
343	real awat,coeff,afac,revap,dhdp,fac,qstm,rat
344	real qsm,sigt,b6,c6
345	real dpinv,cpinv
346	real fqold,ftold,fuold,fvold
347	real wdtrain(ncum),xxx
348	real bsum(ncum,klev)
349	real asij(ncum)
350	real smin(ncum)
351	real scrit(ncum)
352	c real amp1,ad
353	real amp1(ncum),ad(ncum)
354	logical lwork(ncum)
355	integer num1,num2
356	c
357	c print*,'cpd en entree de convect2 ',cpd
358	nlp=nl+1
359	c
360	rowl=1000.0
361	ginv=1.0/g
362	delti=1.0/delt
363	c
364	c Define some thermodynamic variables.
365	c
366	clmcpv=cl-cpv
367	clmcpd=cl-cpd
368	cpdmcp=cpd-cpv
369	cpvmcpd=cpv-cpd
370	eps=rd/rv
371	epsi=1.0/eps
372	epsim1=epsi-1.0
373	c
374	c Compress the fields.
375	c
376	do 110 k=1,nl+1
377	nn=0
378	do 100 i=1,len
379	if(iflag1(i).eq.0)then
380	nn=nn+1
381	t(nn,k)=t1(i,k)
382	q(nn,k)=q1(i,k)
383	qs(nn,k)=qs1(i,k)
384	u(nn,k)=u1(i,k)
385	v(nn,k)=v1(i,k)
386	gz(nn,k)=gz1(i,k)
387	h(nn,k)=h1(i,k)
388	lv(nn,k)=lv1(i,k)
389	cpn(nn,k)=cpn1(i,k)
390	p(nn,k)=p1(i,k)
391	ph(nn,k)=ph1(i,k)
392	tv(nn,k)=tv1(i,k)
393	tp(nn,k)=tp1(i,k)
394	tvp(nn,k)=tvp1(i,k)
395	clw(nn,k)=clw1(i,k)
396	endif
397	100 continue
398	c print*,'100 ncum,nn',ncum,nn
399	110 continue
400	nn=0
401	do 150 i=1,len
402	if(iflag1(i).eq.0)then
403	nn=nn+1
404	cbmf(nn)=cbmf1(i)
405	plcl(nn)=plcl1(i)
406	tnk(nn)=tnk1(i)
407	qnk(nn)=qnk1(i)
408	gznk(nn)=gznk1(i)
409	nk(nn)=nk1(i)
410	icb(nn)=icb1(i)
411	iflag(nn)=iflag1(i)
412	endif
413	150 continue
414	c print*,'150 ncum,nn',ncum,nn
415	c
416	c Initialize the tendencies, det, wd, tprime, qprime.
417	c
418	do 170 k=1,nl
419	do 160 i=1,ncum
420	c det(i,k)=0.0
421	ft(i,k)=0.0
422	fu(i,k)=0.0
423	fv(i,k)=0.0
424	fq(i,k)=0.0
425	dph(i,k)=ph(i,k)-ph(i,k+1)
426	ep(i,k)=0.0
427	sigp(i,k)=sigs
428	160 continue
429	170 continue
430	do 180 i=1,ncum
431	c wd(i)=0.0
432	c tprime(i)=0.0
433	c qprime(i)=0.0
434	precip(i)=0.0
435	ft(i,nl+1)=0.0
436	fu(i,nl+1)=0.0
437	fv(i,nl+1)=0.0
438	fq(i,nl+1)=0.0
439	180 continue
440	c
441	c Compute icbmax.
442	c
443	icbmax=2
444	do 230 i=1,ncum
445	icbmax=max(icbmax,icb(i))
446	230 continue
447	c
448	c
449	!=====================================================================
450	! --- FIND THE REST OF THE LIFTED PARCEL TEMPERATURES
451	!=====================================================================
452	c
453	c --- The procedure is to solve the equation.
454	c cptp+Lqp+phi=cptnk+Lqnk+gznk.
455	c
456	c * Calculate certain parcel quantities, including static energy *
457	c
458	c
459	do 240 i=1,ncum
460	ah0(i)=(cpd(1.-qnk(i))+clqnk(i))*tnk(i)
461	& +qnk(i)(lv0-clmcpv(tnk(i)-273.15))+gznk(i)
462	240 continue
463	c
464	c
465	c * Find lifted parcel quantities above cloud base *
466	c
467	c
468	do 300 k=minorig+1,nl
469	do 290 i=1,ncum
470	if(k.ge.(icb(i)+1))then
471	tg=t(i,k)
472	qg=qs(i,k)
473	alv=lv0-clmcpv*(t(i,k)-273.15)
474	c
475	c First iteration.
476	c
477	s=cpd+alvalvqg/(rvt(i,k)t(i,k))
478	s=1./s
479	ahg=cpdtg+(cl-cpd)qnk(i)t(i,k)+alvqg+gz(i,k)
480	tg=tg+s*(ah0(i)-ahg)
481	tg=max(tg,35.0)
482	tc=tg-273.15
483	denom=243.5+tc
484	if(tc.ge.0.0)then
485	es=6.112exp(17.67tc/denom)
486	else
487	es=exp(23.33086-6111.72784/tg+0.15215*log(tg))
488	endif
489	qg=epses/(p(i,k)-es(1.-eps))
490	c
491	c Second iteration.
492	c
493	s=cpd+alvalvqg/(rvt(i,k)t(i,k))
494	s=1./s
495	ahg=cpdtg+(cl-cpd)qnk(i)t(i,k)+alvqg+gz(i,k)
496	tg=tg+s*(ah0(i)-ahg)
497	tg=max(tg,35.0)
498	tc=tg-273.15
499	denom=243.5+tc
500	if(tc.ge.0.0)then
501	es=6.112exp(17.67tc/denom)
502	else
503	es=exp(23.33086-6111.72784/tg+0.15215*log(tg))
504	endif
505	qg=epses/(p(i,k)-es(1.-eps))
506	c
507	alv=lv0-clmcpv*(t(i,k)-273.15)
508	c print*,'cpd dans convect2 ',cpd
509	c print*,'tp(i,k),ah0(i),cl,cpd,qnk(i),t(i,k),gz(i,k),alv,qg,cpd'
510	c print*,tp(i,k),ah0(i),cl,cpd,qnk(i),t(i,k),gz(i,k),alv,qg,cpd
511	tp(i,k)=(ah0(i)-(cl-cpd)qnk(i)t(i,k)-gz(i,k)-alv*qg)
512	& /cpd
513	c if (.not.cpd.gt.1000.) then
514	c print*,'CPD=',cpd
515	c stop
516	c endif
517	clw(i,k)=qnk(i)-qg
518	clw(i,k)=max(0.0,clw(i,k))
519	rg=qg/(1.-qnk(i))
520	tvp(i,k)=tp(i,k)(1.+rgepsi)
521	endif
522	290 continue
523	300 continue
524	c
525	!=====================================================================
526	! --- SET THE PRECIPITATION EFFICIENCIES AND THE FRACTION OF
527	! --- PRECIPITATION FALLING OUTSIDE OF CLOUD
528	! --- THESE MAY BE FUNCTIONS OF TP(I), P(I) AND CLW(I)
529	!=====================================================================
530	c
531	do 320 k=minorig+1,nl
532	do 310 i=1,ncum
533	if(k.ge.(nk(i)+1))then
534	tca=tp(i,k)-273.15
535	if(tca.ge.0.0)then
536	elacrit=elcrit
537	else
538	elacrit=elcrit*(1.0-tca/tlcrit)
539	endif
540	elacrit=max(elacrit,0.0)
541	ep(i,k)=1.0-elacrit/max(clw(i,k),1.0e-8)
542	ep(i,k)=max(ep(i,k),0.0 )
543	ep(i,k)=min(ep(i,k),1.0 )
544	sigp(i,k)=sigs
545	endif
546	310 continue
547	320 continue
548	c
549	!=====================================================================
550	! --- CALCULATE VIRTUAL TEMPERATURE AND LIFTED PARCEL
551	! --- VIRTUAL TEMPERATURE
552	!=====================================================================
553	c
554	do 340 k=minorig+1,nl
555	do 330 i=1,ncum
556	if(k.ge.(icb(i)+1))then
557	tvp(i,k)=tvp(i,k)(1.0-qnk(i)+ep(i,k)clw(i,k))
558	c print*,'i,k,tvp(i,k),qnk(i),ep(i,k),clw(i,k)'
559	c print*, i,k,tvp(i,k),qnk(i),ep(i,k),clw(i,k)
560	endif
561	330 continue
562	340 continue
563	do 350 i=1,ncum
564	tvp(i,nlp)=tvp(i,nl)-(gz(i,nlp)-gz(i,nl))/cpd
565	350 continue
566	c
567	c
568	c=====================================================================
569	c --- NOW INITIALIZE VARIOUS ARRAYS USED IN THE COMPUTATIONS
570	c=====================================================================
571	c
572	do 360 i=1,ncum*nlp
573	nent(i,1)=0
574	water(i,1)=0.0
575	evap(i,1)=0.0
576	mp(i,1)=0.0
577	m(i,1)=0.0
578	wt(i,1)=omtsnow
579	hp(i,1)=h(i,1)
580	c if(.not.cpn(i,1).gt.900.) then
581	c print*,'i,lv(i,1),cpn(i,1)'
582	c print*, i,lv(i,1),cpn(i,1)
583	c k=(i-1)/ncum+1
584	c print*,'i,k',mod(i,ncum),k,' cpn',cpn(mod(i,ncum),k)
585	c stop
586	c endif
587	lvcp(i,1)=lv(i,1)/cpn(i,1)
588	360 continue
589	c
590	do 380 i=1,ncumnlpnlp
591	elij(i,1,1)=0.0
592	ment(i,1,1)=0.0
593	sij(i,1,1)=0.0
594	380 continue
595	c
596	do 400 k=1,nlp
597	do 390 j=1,nlp
598	do 385 i=1,ncum
599	qent(i,k,j)=q(i,j)
600	uent(i,k,j)=u(i,j)
601	vent(i,k,j)=v(i,j)
602	385 continue
603	390 continue
604	400 continue
605	c
606	do 420 i=1,ncum
607	qp(i,1)=q(i,1)
608	up(i,1)=u(i,1)
609	vp(i,1)=v(i,1)
610	420 continue
611	do 440 k=2,nlp
612	do 430 i=1,ncum
613	qp(i,k)=q(i,k-1)
614	up(i,k)=u(i,k-1)
615	vp(i,k)=v(i,k-1)
616	430 continue
617	440 continue
618	c
619	c=====================================================================
620	c --- FIND THE FIRST MODEL LEVEL (INB1) ABOVE THE PARCEL'S
621	c --- HIGHEST LEVEL OF NEUTRAL BUOYANCY
622	c --- AND THE HIGHEST LEVEL OF POSITIVE CAPE (INB)
623	c=====================================================================
624	c
625	do 510 i=1,ncum
626	cape(i)=0.0
627	capem(i)=0.0
628	inb(i)=icb(i)+1
629	inb1(i)=inb(i)
630	510 continue
631	c
632	c Originial Code
633	c
634	c do 530 k=minorig+1,nl-1
635	c do 520 i=1,ncum
636	c if(k.ge.(icb(i)+1))then
637	c by=(tvp(i,k)-tv(i,k))*dph(i,k)/p(i,k)
638	c byp=(tvp(i,k+1)-tv(i,k+1))*dph(i,k+1)/p(i,k+1)
639	c cape(i)=cape(i)+by
640	c if(by.ge.0.0)inb1(i)=k+1
641	c if(cape(i).gt.0.0)then
642	c inb(i)=k+1
643	c capem(i)=cape(i)
644	c endif
645	c endif
646	c520 continue
647	c530 continue
648	c do 540 i=1,ncum
649	c byp=(tvp(i,nl)-tv(i,nl))*dph(i,nl)/p(i,nl)
650	c cape(i)=capem(i)+byp
651	c defrac=capem(i)-cape(i)
652	c defrac=max(defrac,0.001)
653	c frac(i)=-cape(i)/defrac
654	c frac(i)=min(frac(i),1.0)
655	c frac(i)=max(frac(i),0.0)
656	c540 continue
657	c
658	c K Emanuel fix
659	c
660	c call zilch(byp,ncum)
661	c do 530 k=minorig+1,nl-1
662	c do 520 i=1,ncum
663	c if(k.ge.(icb(i)+1))then
664	c by=(tvp(i,k)-tv(i,k))*dph(i,k)/p(i,k)
665	c cape(i)=cape(i)+by
666	c if(by.ge.0.0)inb1(i)=k+1
667	c if(cape(i).gt.0.0)then
668	c inb(i)=k+1
669	c capem(i)=cape(i)
670	c byp(i)=(tvp(i,k+1)-tv(i,k+1))*dph(i,k+1)/p(i,k+1)
671	c endif
672	c endif
673	c520 continue
674	c530 continue
675	c do 540 i=1,ncum
676	c inb(i)=max(inb(i),inb1(i))
677	c cape(i)=capem(i)+byp(i)
678	c defrac=capem(i)-cape(i)
679	c defrac=max(defrac,0.001)
680	c frac(i)=-cape(i)/defrac
681	c frac(i)=min(frac(i),1.0)
682	c frac(i)=max(frac(i),0.0)
683	c540 continue
684	c
685	c J Teixeira fix
686	c
687	call zilch(byp,ncum)
688	do 515 i=1,ncum
689	lcape(i)=.true.
690	515 continue
691	do 530 k=minorig+1,nl-1
692	do 520 i=1,ncum
693	if(cape(i).lt.0.0)lcape(i)=.false.
694	if((k.ge.(icb(i)+1)).and.lcape(i))then
695	by=(tvp(i,k)-tv(i,k))*dph(i,k)/p(i,k)
696	byp(i)=(tvp(i,k+1)-tv(i,k+1))*dph(i,k+1)/p(i,k+1)
697	cape(i)=cape(i)+by
698	if(by.ge.0.0)inb1(i)=k+1
699	if(cape(i).gt.0.0)then
700	inb(i)=k+1
701	capem(i)=cape(i)
702	endif
703	endif
704	520 continue
705	530 continue
706	do 540 i=1,ncum
707	cape(i)=capem(i)+byp(i)
708	defrac=capem(i)-cape(i)
709	defrac=max(defrac,0.001)
710	frac(i)=-cape(i)/defrac
711	frac(i)=min(frac(i),1.0)
712	frac(i)=max(frac(i),0.0)
713	540 continue
714	c
715	c=====================================================================
716	c --- CALCULATE LIQUID WATER STATIC ENERGY OF LIFTED PARCEL
717	c=====================================================================
718	c
719	do 600 k=minorig+1,nl
720	do 590 i=1,ncum
721	if((k.ge.icb(i)).and.(k.le.inb(i)))then
722	hp(i,k)=h(i,nk(i))+(lv(i,k)+(cpd-cpv)t(i,k))ep(i,k)*clw(i,k)
723	endif
724	590 continue
725	600 continue
726	c
727	c=====================================================================
728	c --- CALCULATE CLOUD BASE MASS FLUX AND RATES OF MIXING, M(I),
729	c --- AT EACH MODEL LEVEL
730	c=====================================================================
731	c
732	c tvpplcl = parcel temperature lifted adiabatically from level
733	c icb-1 to the LCL.
734	c tvaplcl = virtual temperature at the LCL.
735	c
736	do 610 i=1,ncum
737	dtpbl(i)=0.0
738	tvpplcl(i)=tvp(i,icb(i)-1)
739	& -rdtvp(i,icb(i)-1)(p(i,icb(i)-1)-plcl(i))
740	& /(cpn(i,icb(i)-1)*p(i,icb(i)-1))
741	tvaplcl(i)=tv(i,icb(i))
742	& +(tvp(i,icb(i))-tvp(i,icb(i)+1))*(plcl(i)-p(i,icb(i)))
743	& /(p(i,icb(i))-p(i,icb(i)+1))
744	610 continue
745	c
746	c-------------------------------------------------------------------
747	c --- Interpolate difference between lifted parcel and
748	c --- environmental temperatures to lifted condensation level
749	c-------------------------------------------------------------------
750	c
751	c dtpbl = average of tvp-tv in the PBL (k=nk to icb-1).
752	c
753	do 630 k=minorig,icbmax
754	do 620 i=1,ncum
755	if((k.ge.nk(i)).and.(k.le.(icb(i)-1)))then
756	dtpbl(i)=dtpbl(i)+(tvp(i,k)-tv(i,k))*dph(i,k)
757	endif
758	620 continue
759	630 continue
760	do 640 i=1,ncum
761	dtpbl(i)=dtpbl(i)/(ph(i,nk(i))-ph(i,icb(i)))
762	dtmin(i)=tvpplcl(i)-tvaplcl(i)+dtmax+dtpbl(i)
763	640 continue
764	c
765	c-------------------------------------------------------------------
766	c --- Adjust cloud base mass flux
767	c-------------------------------------------------------------------
768	c
769	do 650 i=1,ncum
770	work(i)=cbmf(i)
771	cbmf(i)=max(0.0,(1.0-damp)cbmf(i)+0.1alpha*dtmin(i))
772	if((work(i).eq.0.0).and.(cbmf(i).eq.0.0))then
773	iflag(i)=3
774	endif
775	650 continue
776	c
777	c-------------------------------------------------------------------
778	c --- Calculate rates of mixing, m(i)
779	c-------------------------------------------------------------------
780	c
781	call zilch(work,ncum)
782	c
783	do 670 j=minorig+1,nl
784	do 660 i=1,ncum
785	if((j.ge.(icb(i)+1)).and.(j.le.inb(i)))then
786	k=min(j,inb1(i))
787	dbo=abs(tv(i,k+1)-tvp(i,k+1)-tv(i,k-1)+tvp(i,k-1))
788	& +entp0.04(ph(i,k)-ph(i,k+1))
789	work(i)=work(i)+dbo
790	m(i,j)=cbmf(i)*dbo
791	endif
792	660 continue
793	670 continue
794	do 690 k=minorig+1,nl
795	do 680 i=1,ncum
796	if((k.ge.(icb(i)+1)).and.(k.le.inb(i)))then
797	m(i,k)=m(i,k)/work(i)
798	endif
799	680 continue
800	690 continue
801	c
802	c
803	c=====================================================================
804	c --- CALCULATE ENTRAINED AIR MASS FLUX (ment), TOTAL WATER MIXING
805	c --- RATIO (QENT), TOTAL CONDENSED WATER (elij), AND MIXING
806	c --- FRACTION (sij)
807	c=====================================================================
808	c
809	c
810	do 750 i=minorig+1,nl
811	do 710 j=minorig+1,nl
812	do 700 ij=1,ncum
813	if((i.ge.(icb(ij)+1)).and.(j.ge.icb(ij))
814	& .and.(i.le.inb(ij)).and.(j.le.inb(ij)))then
815	qti=qnk(ij)-ep(ij,i)*clw(ij,i)
816	bf2=1.+lv(ij,j)lv(ij,j)qs(ij,j)
817	& /(rvt(ij,j)t(ij,j)*cpd)
818	anum=h(ij,j)-hp(ij,i)+(cpv-cpd)t(ij,j)(qti-q(ij,j))
819	denom=h(ij,i)-hp(ij,i)+(cpd-cpv)(q(ij,i)-qti)t(ij,j)
820	dei=denom
821	if(abs(dei).lt.0.01)dei=0.01
822	sij(ij,i,j)=anum/dei
823	sij(ij,i,i)=1.0
824	altem=sij(ij,i,j)q(ij,i)+(1.-sij(ij,i,j))qti-qs(ij,j)
825	altem=altem/bf2
826	cwat=clw(ij,j)*(1.-ep(ij,j))
827	stemp=sij(ij,i,j)
828	if((stemp.lt.0.0.or.stemp.gt.1.0.or.
829	1 altem.gt.cwat).and.j.gt.i)then
830	anum=anum-lv(ij,j)(qti-qs(ij,j)-cwatbf2)
831	denom=denom+lv(ij,j)*(q(ij,i)-qti)
832	if(abs(denom).lt.0.01)denom=0.01
833	sij(ij,i,j)=anum/denom
834	altem=sij(ij,i,j)q(ij,i)+(1.-sij(ij,i,j))qti-qs(ij,j)
835	altem=altem-(bf2-1.)*cwat
836	endif
837	if(sij(ij,i,j).gt.0.0.and.sij(ij,i,j).lt.0.9)then
838	qent(ij,i,j)=sij(ij,i,j)*q(ij,i)
839	& +(1.-sij(ij,i,j))*qti
840	uent(ij,i,j)=sij(ij,i,j)*u(ij,i)
841	& +(1.-sij(ij,i,j))*u(ij,nk(ij))
842	vent(ij,i,j)=sij(ij,i,j)*v(ij,i)
843	& +(1.-sij(ij,i,j))*v(ij,nk(ij))
844	elij(ij,i,j)=altem
845	elij(ij,i,j)=max(0.0,elij(ij,i,j))
846	ment(ij,i,j)=m(ij,i)/(1.-sij(ij,i,j))
847	nent(ij,i)=nent(ij,i)+1
848	endif
849	sij(ij,i,j)=max(0.0,sij(ij,i,j))
850	sij(ij,i,j)=min(1.0,sij(ij,i,j))
851	endif
852	700 continue
853	710 continue
854	c
855	c * If no air can entrain at level i assume that updraft detrains *
856	c * at that level and calculate detrained air flux and properties *
857	c
858	do 740 ij=1,ncum
859	if((i.ge.(icb(ij)+1)).and.(i.le.inb(ij))
860	& .and.(nent(ij,i).eq.0))then
861	ment(ij,i,i)=m(ij,i)
862	qent(ij,i,i)=q(ij,nk(ij))-ep(ij,i)*clw(ij,i)
863	uent(ij,i,i)=u(ij,nk(ij))
864	vent(ij,i,i)=v(ij,nk(ij))
865	elij(ij,i,i)=clw(ij,i)
866	sij(ij,i,i)=1.0
867	endif
868	740 continue
869	750 continue
870	c
871	do 770 i=1,ncum
872	sij(i,inb(i),inb(i))=1.0
873	770 continue
874	c
875	c=====================================================================
876	c --- NORMALIZE ENTRAINED AIR MASS FLUXES
877	c --- TO REPRESENT EQUAL PROBABILITIES OF MIXING
878	c=====================================================================
879	c
880	c
881	call zilch(bsum,ncum*nlp)
882	do 780 ij=1,ncum
883	lwork(ij)=.false.
884	780 continue
885	do 789 i=minorig+1,nl
886	c
887	num1=0
888	do 779 ij=1,ncum
889	if((i.ge.icb(ij)+1).and.(i.le.inb(ij)))num1=num1+1
890	779 continue
891	if(num1.le.0)go to 789
892	c
893	do 781 ij=1,ncum
894	if((i.ge.icb(ij)+1).and.(i.le.inb(ij)))then
895	lwork(ij)=(nent(ij,i).ne.0)
896	qp1=q(ij,nk(ij))-ep(ij,i)*clw(ij,i)
897	anum=h(ij,i)-hp(ij,i)-lv(ij,i)*(qp1-qs(ij,i))
898	denom=h(ij,i)-hp(ij,i)+lv(ij,i)*(q(ij,i)-qp1)
899	if(abs(denom).lt.0.01)denom=0.01
900	scrit(ij)=anum/denom
901	alt=qp1-qs(ij,i)+scrit(ij)*(q(ij,i)-qp1)
902	if(scrit(ij).lt.0.0.or.alt.lt.0.0)scrit(ij)=1.0
903	asij(ij)=0.0
904	smin(ij)=1.0
905	endif
906	781 continue
907	do 783 j=minorig,nl
908	c
909	num2=0
910	do 778 ij=1,ncum
911	if((i.ge.icb(ij)+1).and.(i.le.inb(ij))
912	& .and.(j.ge.icb(ij)).and.(j.le.inb(ij))
913	& .and.lwork(ij))num2=num2+1
914	778 continue
915	if(num2.le.0)go to 783
916	c
917	do 782 ij=1,ncum
918	if((i.ge.icb(ij)+1).and.(i.le.inb(ij))
919	& .and.(j.ge.icb(ij)).and.(j.le.inb(ij)).and.lwork(ij))then
920	if(sij(ij,i,j).gt.0.0.and.sij(ij,i,j).lt.0.9)then
921	if(j.gt.i)then
922	smid=min(sij(ij,i,j),scrit(ij))
923	sjmax=smid
924	sjmin=smid
925	if(smid.lt.smin(ij)
926	& .and.sij(ij,i,j+1).lt.smid)then
927	smin(ij)=smid
928	sjmax=min(sij(ij,i,j+1),sij(ij,i,j),scrit(ij))
929	sjmin=max(sij(ij,i,j-1),sij(ij,i,j))
930	sjmin=min(sjmin,scrit(ij))
931	endif
932	else
933	sjmax=max(sij(ij,i,j+1),scrit(ij))
934	smid=max(sij(ij,i,j),scrit(ij))
935	sjmin=0.0
936	if(j.gt.1)sjmin=sij(ij,i,j-1)
937	sjmin=max(sjmin,scrit(ij))
938	endif
939	delp=abs(sjmax-smid)
940	delm=abs(sjmin-smid)
941	asij(ij)=asij(ij)+(delp+delm)
942	& *(ph(ij,j)-ph(ij,j+1))
943	ment(ij,i,j)=ment(ij,i,j)*(delp+delm)
944	& *(ph(ij,j)-ph(ij,j+1))
945	endif
946	endif
947	782 continue
948	783 continue
949	do 784 ij=1,ncum
950	if((i.ge.icb(ij)+1).and.(i.le.inb(ij)).and.lwork(ij))then
951	asij(ij)=max(1.0e-21,asij(ij))
952	asij(ij)=1.0/asij(ij)
953	bsum(ij,i)=0.0
954	endif
955	784 continue
956	do 786 j=minorig,nl+1
957	do 785 ij=1,ncum
958	if((i.ge.icb(ij)+1).and.(i.le.inb(ij))
959	& .and.(j.ge.icb(ij)).and.(j.le.inb(ij))
960	& .and.lwork(ij))then
961	ment(ij,i,j)=ment(ij,i,j)*asij(ij)
962	bsum(ij,i)=bsum(ij,i)+ment(ij,i,j)
963	endif
964	785 continue
965	786 continue
966	do 787 ij=1,ncum
967	if((i.ge.icb(ij)+1).and.(i.le.inb(ij))
968	& .and.(bsum(ij,i).lt.1.0e-18).and.lwork(ij))then
969	nent(ij,i)=0
970	ment(ij,i,i)=m(ij,i)
971	qent(ij,i,i)=q(ij,nk(ij))-ep(ij,i)*clw(ij,i)
972	uent(ij,i,i)=u(ij,nk(ij))
973	vent(ij,i,i)=v(ij,nk(ij))
974	elij(ij,i,i)=clw(ij,i)
975	sij(ij,i,i)=1.0
976	endif
977	787 continue
978	789 continue
979	c
980	c=====================================================================
981	c --- PRECIPITATING DOWNDRAFT CALCULATION
982	c=====================================================================
983	c
984	c * Check whether ep(inb)=0, if so, skip precipitating *
985	c * downdraft calculation *
986	c
987	c
988	c * Integrate liquid water equation to find condensed water *
989	c * and condensed water flux *
990	c
991	c
992	do 890 i=1,ncum
993	jtt(i)=2
994	if(ep(i,inb(i)).le.0.0001)iflag(i)=2
995	if(iflag(i).eq.0)then
996	lwork(i)=.true.
997	else
998	lwork(i)=.false.
999	endif
1000	890 continue
1001	c
1002	c * Begin downdraft loop *
1003	c
1004	c
1005	call zilch(wdtrain,ncum)
1006	do 899 i=nl+1,1,-1
1007	c
1008	num1=0
1009	do 879 ij=1,ncum
1010	if((i.le.inb(ij)).and.lwork(ij))num1=num1+1
1011	879 continue
1012	if(num1.le.0)go to 899
1013	c
1014	c
1015	c * Calculate detrained precipitation *
1016	c
1017	do 891 ij=1,ncum
1018	if((i.le.inb(ij)).and.(lwork(ij)))then
1019	wdtrain(ij)=gep(ij,i)m(ij,i)*clw(ij,i)
1020	endif
1021	891 continue
1022	c
1023	if(i.gt.1)then
1024	do 893 j=1,i-1
1025	do 892 ij=1,ncum
1026	if((i.le.inb(ij)).and.(lwork(ij)))then
1027	awat=elij(ij,j,i)-(1.-ep(ij,i))*clw(ij,i)
1028	awat=max(0.0,awat)
1029	wdtrain(ij)=wdtrain(ij)+gawatment(ij,j,i)
1030	endif
1031	892 continue
1032	893 continue
1033	endif
1034	c
1035	c * Find rain water and evaporation using provisional *
1036	c * estimates of qp(i)and qp(i-1) *
1037	c
1038	c
1039	c * Value of terminal velocity and coeffecient of evaporation for snow *
1040	c
1041	do 894 ij=1,ncum
1042	if((i.le.inb(ij)).and.(lwork(ij)))then
1043	coeff=coeffs
1044	wt(ij,i)=omtsnow
1045	c
1046	c * Value of terminal velocity and coeffecient of evaporation for rain *
1047	c
1048	if(t(ij,i).gt.273.0)then
1049	coeff=coeffr
1050	wt(ij,i)=omtrain
1051	endif
1052	qsm=0.5*(q(ij,i)+qp(ij,i+1))
1053	afac=coeffph(ij,i)(qs(ij,i)-qsm)
1054	& /(1.0e4+2.0e3ph(ij,i)qs(ij,i))
1055	afac=max(afac,0.0)
1056	sigt=sigp(ij,i)
1057	sigt=max(0.0,sigt)
1058	sigt=min(1.0,sigt)
1059	b6=100.(ph(ij,i)-ph(ij,i+1))sigt*afac/wt(ij,i)
1060	c6=(water(ij,i+1)*wt(ij,i+1)+wdtrain(ij)/sigd)/wt(ij,i)
1061	revap=0.5(-b6+sqrt(b6b6+4.*c6))
1062	evap(ij,i)=sigtafacrevap
1063	water(ij,i)=revap*revap
1064	c
1065	c * Calculate precipitating downdraft mass flux under *
1066	c * hydrostatic approximation *
1067	c
1068	if(i.gt.1)then
1069	dhdp=(h(ij,i)-h(ij,i-1))/(p(ij,i-1)-p(ij,i))
1070	dhdp=max(dhdp,10.0)
1071	mp(ij,i)=100.ginvlv(ij,i)sigdevap(ij,i)/dhdp
1072	mp(ij,i)=max(mp(ij,i),0.0)
1073	c
1074	c * Add small amount of inertia to downdraft *
1075	c
1076	fac=20.0/(ph(ij,i-1)-ph(ij,i))
1077	mp(ij,i)=(fac*mp(ij,i+1)+mp(ij,i))/(1.+fac)
1078	c
1079	c * Force mp to decrease linearly to zero *
1080	c * between about 950 mb and the surface *
1081	c
1082	if(p(ij,i).gt.(0.949*p(ij,1)))then
1083	jtt(ij)=max(jtt(ij),i)
1084	mp(ij,i)=mp(ij,jtt(ij))*(p(ij,1)-p(ij,i))
1085	& /(p(ij,1)-p(ij,jtt(ij)))
1086	endif
1087	endif
1088	c
1089	c * Find mixing ratio of precipitating downdraft *
1090	c
1091	if(i.ne.inb(ij))then
1092	if(i.eq.1)then
1093	qstm=qs(ij,1)
1094	else
1095	qstm=qs(ij,i-1)
1096	endif
1097	if(mp(ij,i).gt.mp(ij,i+1))then
1098	rat=mp(ij,i+1)/mp(ij,i)
1099	qp(ij,i)=qp(ij,i+1)rat+q(ij,i)(1.0-rat)+100.ginv
1100	& sigd(ph(ij,i)-ph(ij,i+1))(evap(ij,i)/mp(ij,i))
1101	up(ij,i)=up(ij,i+1)rat+u(ij,i)(1.-rat)
1102	vp(ij,i)=vp(ij,i+1)rat+v(ij,i)(1.-rat)
1103	else
1104	if(mp(ij,i+1).gt.0.0)then
1105	qp(ij,i)=(gz(ij,i+1)-gz(ij,i)
1106	& +qp(ij,i+1)*(lv(ij,i+1)+t(ij,i+1)
1107	& (cl-cpd))+cpd(t(ij,i+1)-t(ij,i)))
1108	& /(lv(ij,i)+t(ij,i)*(cl-cpd))
1109	up(ij,i)=up(ij,i+1)
1110	vp(ij,i)=vp(ij,i+1)
1111	endif
1112	endif
1113	qp(ij,i)=min(qp(ij,i),qstm)
1114	qp(ij,i)=max(qp(ij,i),0.0)
1115	endif
1116	endif
1117	894 continue
1118	899 continue
1119	c
1120	c * Calculate surface precipitation in mm/day *
1121	c
1122	do 1190 i=1,ncum
1123	if(iflag(i).le.1)then
1124	cc precip(i)=precip(i)+wt(i,1)sigdwater(i,1)3600.24000.
1125	cc & /(rowl*g)
1126	cc precip(i)=precip(i)*delt/86400.
1127	precip(i) = wt(i,1)sigdwater(i,1)*86400/g
1128	endif
1129	1190 continue
1130	c
1131	c
1132	c * Calculate downdraft velocity scale and surface temperature and *
1133	c * water vapor fluctuations *
1134	c
1135	c wd=betaabs(mp(icb))0.01rdt(icb)/(sigd*p(icb))
1136	c qprime=0.5*(qp(1)-q(1))
1137	c tprime=lv0*qprime/cpd
1138	c
1139	c * Calculate tendencies of lowest level potential temperature *
1140	c * and mixing ratio *
1141	c
1142	do 1200 i=1,ncum
1143	work(i)=0.01/(ph(i,1)-ph(i,2))
1144	am(i)=0.0
1145	1200 continue
1146	do 1220 k=2,nl
1147	do 1210 i=1,ncum
1148	if((nk(i).eq.1).and.(k.le.inb(i)).and.(nk(i).eq.1))then
1149	am(i)=am(i)+m(i,k)
1150	endif
1151	1210 continue
1152	1220 continue
1153	do 1240 i=1,ncum
1154	if((gwork(i)am(i)).ge.delti)iflag(i)=1
1155	ft(i,1)=ft(i,1)+gwork(i)am(i)*(t(i,2)-t(i,1)
1156	& +(gz(i,2)-gz(i,1))/cpn(i,1))
1157	ft(i,1)=ft(i,1)-lvcp(i,1)sigdevap(i,1)
1158	ft(i,1)=ft(i,1)+sigdwt(i,2)(cl-cpd)water(i,2)(t(i,2)
1159	& -t(i,1))*work(i)/cpn(i,1)
1160	fq(i,1)=fq(i,1)+gmp(i,2)(qp(i,2)-q(i,1))*
1161	& work(i)+sigd*evap(i,1)
1162	fq(i,1)=fq(i,1)+gam(i)(q(i,2)-q(i,1))*work(i)
1163	fu(i,1)=fu(i,1)+gwork(i)(mp(i,2)*(up(i,2)-u(i,1))
1164	& +am(i)*(u(i,2)-u(i,1)))
1165	fv(i,1)=fv(i,1)+gwork(i)(mp(i,2)*(vp(i,2)-v(i,1))
1166	& +am(i)*(v(i,2)-v(i,1)))
1167	1240 continue
1168	do 1260 j=2,nl
1169	do 1250 i=1,ncum
1170	if(j.le.inb(i))then
1171	fq(i,1)=fq(i,1)
1172	& +gwork(i)ment(i,j,1)*(qent(i,j,1)-q(i,1))
1173	fu(i,1)=fu(i,1)
1174	& +gwork(i)ment(i,j,1)*(uent(i,j,1)-u(i,1))
1175	fv(i,1)=fv(i,1)
1176	& +gwork(i)ment(i,j,1)*(vent(i,j,1)-v(i,1))
1177	endif
1178	1250 continue
1179	1260 continue
1180	c
1181	c * Calculate tendencies of potential temperature and mixing ratio *
1182	c * at levels above the lowest level *
1183	c
1184	c * First find the net saturated updraft and downdraft mass fluxes *
1185	c * through each level *
1186	c
1187	do 1500 i=2,nl+1
1188	c
1189	num1=0
1190	do 1265 ij=1,ncum
1191	if(i.le.inb(ij))num1=num1+1
1192	1265 continue
1193	if(num1.le.0)go to 1500
1194	c
1195	call zilch(amp1,ncum)
1196	call zilch(ad,ncum)
1197	c
1198	do 1280 k=i+1,nl+1
1199	do 1270 ij=1,ncum
1200	if((i.ge.nk(ij)).and.(i.le.inb(ij))
1201	& .and.(k.le.(inb(ij)+1)))then
1202	amp1(ij)=amp1(ij)+m(ij,k)
1203	endif
1204	1270 continue
1205	1280 continue
1206	c
1207	do 1310 k=1,i
1208	do 1300 j=i+1,nl+1
1209	do 1290 ij=1,ncum
1210	if((j.le.(inb(ij)+1)).and.(i.le.inb(ij)))then
1211	amp1(ij)=amp1(ij)+ment(ij,k,j)
1212	endif
1213	1290 continue
1214	1300 continue
1215	1310 continue
1216	do 1340 k=1,i-1
1217	do 1330 j=i,nl+1
1218	do 1320 ij=1,ncum
1219	if((i.le.inb(ij)).and.(j.le.inb(ij)))then
1220	ad(ij)=ad(ij)+ment(ij,j,k)
1221	endif
1222	1320 continue
1223	1330 continue
1224	1340 continue
1225	c
1226	do 1350 ij=1,ncum
1227	if(i.le.inb(ij))then
1228	dpinv=0.01/(ph(ij,i)-ph(ij,i+1))
1229	cpinv=1.0/cpn(ij,i)
1230	c
1231	ft(ij,i)=ft(ij,i)
1232	& +gdpinv(amp1(ij)*(t(ij,i+1)-t(ij,i)
1233	& +(gz(ij,i+1)-gz(ij,i))*cpinv)
1234	& -ad(ij)(t(ij,i)-t(ij,i-1)+(gz(ij,i)-gz(ij,i-1))cpinv))
1235	& -sigdlvcp(ij,i)evap(ij,i)
1236	ft(ij,i)=ft(ij,i)+gdpinvment(ij,i,i)*(hp(ij,i)-h(ij,i)+
1237	& t(ij,i)(cpv-cpd)(q(ij,i)-qent(ij,i,i)))*cpinv
1238	ft(ij,i)=ft(ij,i)+sigdwt(ij,i+1)(cl-cpd)water(ij,i+1)
1239	& (t(ij,i+1)-t(ij,i))dpinvcpinv
1240	fq(ij,i)=fq(ij,i)+gdpinv(amp1(ij)*(q(ij,i+1)-q(ij,i))-
1241	& ad(ij)*(q(ij,i)-q(ij,i-1)))
1242	fu(ij,i)=fu(ij,i)+gdpinv(amp1(ij)*(u(ij,i+1)-u(ij,i))-
1243	& ad(ij)*(u(ij,i)-u(ij,i-1)))
1244	fv(ij,i)=fv(ij,i)+gdpinv(amp1(ij)*(v(ij,i+1)-v(ij,i))-
1245	& ad(ij)*(v(ij,i)-v(ij,i-1)))
1246	endif
1247	1350 continue
1248	do 1370 k=1,i-1
1249	do 1360 ij=1,ncum
1250	if(i.le.inb(ij))then
1251	awat=elij(ij,k,i)-(1.-ep(ij,i))*clw(ij,i)
1252	awat=max(awat,0.0)
1253	fq(ij,i)=fq(ij,i)
1254	& +gdpinvment(ij,k,i)*(qent(ij,k,i)-awat-q(ij,i))
1255	fu(ij,i)=fu(ij,i)
1256	& +gdpinvment(ij,k,i)*(uent(ij,k,i)-u(ij,i))
1257	fv(ij,i)=fv(ij,i)
1258	& +gdpinvment(ij,k,i)*(vent(ij,k,i)-v(ij,i))
1259	endif
1260	1360 continue
1261	1370 continue
1262	do 1390 k=i,nl+1
1263	do 1380 ij=1,ncum
1264	if((i.le.inb(ij)).and.(k.le.inb(ij)))then
1265	fq(ij,i)=fq(ij,i)
1266	& +gdpinvment(ij,k,i)*(qent(ij,k,i)-q(ij,i))
1267	fu(ij,i)=fu(ij,i)
1268	& +gdpinvment(ij,k,i)*(uent(ij,k,i)-u(ij,i))
1269	fv(ij,i)=fv(ij,i)
1270	& +gdpinvment(ij,k,i)*(vent(ij,k,i)-v(ij,i))
1271	endif
1272	1380 continue
1273	1390 continue
1274	do 1400 ij=1,ncum
1275	if(i.le.inb(ij))then
1276	fq(ij,i)=fq(ij,i)
1277	& +sigdevap(ij,i)+g(mp(ij,i+1)*
1278	& (qp(ij,i+1)-q(ij,i))
1279	& -mp(ij,i)(qp(ij,i)-q(ij,i-1)))dpinv
1280	fu(ij,i)=fu(ij,i)
1281	& +g(mp(ij,i+1)(up(ij,i+1)-u(ij,i))-mp(ij,i)*
1282	& (up(ij,i)-u(ij,i-1)))*dpinv
1283	fv(ij,i)=fv(ij,i)
1284	& +g(mp(ij,i+1)(vp(ij,i+1)-v(ij,i))-mp(ij,i)*
1285	& (vp(ij,i)-v(ij,i-1)))*dpinv
1286	endif
1287	1400 continue
1288	1500 continue
1289	c
1290	c * Adjust tendencies at top of convection layer to reflect *
1291	c * actual position of the level zero cape *
1292	c
1293	do 503 ij=1,ncum
1294	fqold=fq(ij,inb(ij))
1295	fq(ij,inb(ij))=fq(ij,inb(ij))*(1.-frac(ij))
1296	fq(ij,inb(ij)-1)=fq(ij,inb(ij)-1)
1297	& +frac(ij)fqold((ph(ij,inb(ij))-ph(ij,inb(ij)+1))/
1298	1 (ph(ij,inb(ij)-1)-ph(ij,inb(ij))))*lv(ij,inb(ij))
1299	& /lv(ij,inb(ij)-1)
1300	ftold=ft(ij,inb(ij))
1301	ft(ij,inb(ij))=ft(ij,inb(ij))*(1.-frac(ij))
1302	ft(ij,inb(ij)-1)=ft(ij,inb(ij)-1)
1303	& +frac(ij)ftold((ph(ij,inb(ij))-ph(ij,inb(ij)+1))/
1304	1 (ph(ij,inb(ij)-1)-ph(ij,inb(ij))))*cpn(ij,inb(ij))
1305	& /cpn(ij,inb(ij)-1)
1306	fuold=fu(ij,inb(ij))
1307	fu(ij,inb(ij))=fu(ij,inb(ij))*(1.-frac(ij))
1308	fu(ij,inb(ij)-1)=fu(ij,inb(ij)-1)
1309	& +frac(ij)fuold((ph(ij,inb(ij))-ph(ij,inb(ij)+1))/
1310	1 (ph(ij,inb(ij)-1)-ph(ij,inb(ij))))
1311	fvold=fv(ij,inb(ij))
1312	fv(ij,inb(ij))=fv(ij,inb(ij))*(1.-frac(ij))
1313	fv(ij,inb(ij)-1)=fv(ij,inb(ij)-1)
1314	& +frac(ij)fvold((ph(ij,inb(ij))-ph(ij,inb(ij)+1))/
1315	1 (ph(ij,inb(ij)-1)-ph(ij,inb(ij))))
1316	503 continue
1317	c
1318	c * Very slightly adjust tendencies to force exact *
1319	c * enthalpy, momentum and tracer conservation *
1320	c
1321	do 682 ij=1,ncum
1322	ents(ij)=0.0
1323	uav(ij)=0.0
1324	vav(ij)=0.0
1325	do 681 i=1,inb(ij)
1326	ents(ij)=ents(ij)
1327	& +(cpn(ij,i)ft(ij,i)+lv(ij,i)fq(ij,i))*(ph(ij,i)-ph(ij,i+1))
1328	uav(ij)=uav(ij)+fu(ij,i)*(ph(ij,i)-ph(ij,i+1))
1329	vav(ij)=vav(ij)+fv(ij,i)*(ph(ij,i)-ph(ij,i+1))
1330	681 continue
1331	682 continue
1332	do 683 ij=1,ncum
1333	ents(ij)=ents(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
1334	uav(ij)=uav(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
1335	vav(ij)=vav(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
1336	683 continue
1337	do 642 ij=1,ncum
1338	do 641 i=1,inb(ij)
1339	ft(ij,i)=ft(ij,i)-ents(ij)/cpn(ij,i)
1340	fu(ij,i)=(1.-cu)*(fu(ij,i)-uav(ij))
1341	fv(ij,i)=(1.-cu)*(fv(ij,i)-vav(ij))
1342	641 continue
1343	642 continue
1344	c
1345	do 1810 k=1,nl+1
1346	do 1800 i=1,ncum
1347	if((q(i,k)+delt*fq(i,k)).lt.0.0)iflag(i)=10
1348	1800 continue
1349	1810 continue
1350	c
1351	c
1352	do 1900 i=1,ncum
1353	if(iflag(i).gt.2)then
1354	precip(i)=0.0
1355	cbmf(i)=0.0
1356	endif
1357	1900 continue
1358	do 1920 k=1,nl
1359	do 1910 i=1,ncum
1360	if(iflag(i).gt.2)then
1361	ft(i,k)=0.0
1362	fq(i,k)=0.0
1363	fu(i,k)=0.0
1364	fv(i,k)=0.0
1365	endif
1366	1910 continue
1367	1920 continue
1368	do 2000 i=1,ncum
1369	precip1(idcum(i))=precip(i)
1370	cbmf1(idcum(i))=cbmf(i)
1371	iflag1(idcum(i))=iflag(i)
1372	2000 continue
1373	do 2020 k=1,nl
1374	do 2010 i=1,ncum
1375	ft1(idcum(i),k)=ft(i,k)
1376	fq1(idcum(i),k)=fq(i,k)
1377	fu1(idcum(i),k)=fu(i,k)
1378	fv1(idcum(i),k)=fv(i,k)
1379	2010 continue
1380	2020 continue
1381	c
1382	DO k=1,nd
1383	DO i=1,len
1384	Ma(i,k) = 0.
1385	ENDDO
1386	ENDDO
1387	DO k=nl,1,-1
1388	DO i=1,ncum
1389	Ma(i,k) = Ma(i,k+1)+m(i,k)
1390	ENDDO
1391	ENDDO
1392	c
1393	return
1394	end
1395

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