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cv_routines.F @ 497

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1	SUBROUTINE cv_param(nd)
2	implicit none
3
4	c------------------------------------------------------------
5	c Set parameters for convectL
6	c (includes microphysical parameters and parameters that
7	c control the rate of approach to quasi-equilibrium)
8	c------------------------------------------------------------
9
10	C * ELCRIT IS THE AUTOCONVERSION THERSHOLD WATER CONTENT (gm/gm) *
11	C * TLCRIT IS CRITICAL TEMPERATURE BELOW WHICH THE AUTO- *
12	C * CONVERSION THRESHOLD IS ASSUMED TO BE ZERO *
13	C * (THE AUTOCONVERSION THRESHOLD VARIES LINEARLY *
14	C * BETWEEN 0 C AND TLCRIT) *
15	C * ENTP IS THE COEFFICIENT OF MIXING IN THE ENTRAINMENT *
16	C * FORMULATION *
17	C * SIGD IS THE FRACTIONAL AREA COVERED BY UNSATURATED DNDRAFT *
18	C * SIGS IS THE FRACTION OF PRECIPITATION FALLING OUTSIDE *
19	C * OF CLOUD *
20	C * OMTRAIN IS THE ASSUMED FALL SPEED (P/s) OF RAIN *
21	C * OMTSNOW IS THE ASSUMED FALL SPEED (P/s) OF SNOW *
22	C * COEFFR IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION *
23	C * OF RAIN *
24	C * COEFFS IS A COEFFICIENT GOVERNING THE RATE OF EVAPORATION *
25	C * OF SNOW *
26	C * CU IS THE COEFFICIENT GOVERNING CONVECTIVE MOMENTUM *
27	C * TRANSPORT *
28	C * DTMAX IS THE MAXIMUM NEGATIVE TEMPERATURE PERTURBATION *
29	C * A LIFTED PARCEL IS ALLOWED TO HAVE BELOW ITS LFC *
30	C * ALPHA AND DAMP ARE PARAMETERS THAT CONTROL THE RATE OF *
31	C * APPROACH TO QUASI-EQUILIBRIUM *
32	C * (THEIR STANDARD VALUES ARE 0.20 AND 0.1, RESPECTIVELY) *
33	C * (DAMP MUST BE LESS THAN 1) *
34
35	#include "cvparam.h"
36	integer nd
37
38	c noff: integer limit for convection (nd-noff)
39	c minorig: First level of convection
40
41	noff = 2
42	minorig = 2
43
44	nl=nd-noff
45	nlp=nl+1
46	nlm=nl-1
47
48	elcrit=0.0011
49	tlcrit=-55.0
50	entp=1.5
51	sigs=0.12
52	sigd=0.05
53	omtrain=50.0
54	omtsnow=5.5
55	coeffr=1.0
56	coeffs=0.8
57	dtmax=0.9
58	c
59	cu=0.70
60	c
61	betad=10.0
62	c
63	damp=0.1
64	alpha=0.2
65	c
66	delta=0.01 ! cld
67	c
68	return
69	end
70
71	SUBROUTINE cv_prelim(len,nd,ndp1,t,q,p,ph
72	: ,lv,cpn,tv,gz,h,hm)
73	implicit none
74
75	!=====================================================================
76	! --- CALCULATE ARRAYS OF GEOPOTENTIAL, HEAT CAPACITY & STATIC ENERGY
77	!=====================================================================
78
79	c inputs:
80	integer len, nd, ndp1
81	real t(len,nd), q(len,nd), p(len,nd), ph(len,ndp1)
82
83	c outputs:
84	real lv(len,nd), cpn(len,nd), tv(len,nd)
85	real gz(len,nd), h(len,nd), hm(len,nd)
86
87	c local variables:
88	integer k, i
89	real cpx(len,nd)
90
91	#include "cvthermo.h"
92	#include "cvparam.h"
93
94
95	do 110 k=1,nlp
96	do 100 i=1,len
97	lv(i,k)= lv0-clmcpv*(t(i,k)-t0)
98	cpn(i,k)=cpd(1.0-q(i,k))+cpvq(i,k)
99	cpx(i,k)=cpd(1.0-q(i,k))+clq(i,k)
100	tv(i,k)=t(i,k)(1.0+q(i,k)epsim1)
101	100 continue
102	110 continue
103	c
104	c gz = phi at the full levels (same as p).
105	c
106	do 120 i=1,len
107	gz(i,1)=0.0
108	120 continue
109	do 140 k=2,nlp
110	do 130 i=1,len
111	gz(i,k)=gz(i,k-1)+hrd*(tv(i,k-1)+tv(i,k))
112	& *(p(i,k-1)-p(i,k))/ph(i,k)
113	130 continue
114	140 continue
115	c
116	c h = phi + cpT (dry static energy).
117	c hm = phi + cp(T-Tbase)+Lq
118	c
119	do 170 k=1,nlp
120	do 160 i=1,len
121	h(i,k)=gz(i,k)+cpn(i,k)*t(i,k)
122	hm(i,k)=gz(i,k)+cpx(i,k)(t(i,k)-t(i,1))+lv(i,k)q(i,k)
123	160 continue
124	170 continue
125
126	return
127	end
128
129	SUBROUTINE cv_feed(len,nd,t,q,qs,p,hm,gz
130	: ,nk,icb,icbmax,iflag,tnk,qnk,gznk,plcl)
131	implicit none
132
133	C================================================================
134	C Purpose: CONVECTIVE FEED
135	C================================================================
136
137	#include "cvparam.h"
138
139	c inputs:
140	integer len, nd
141	real t(len,nd), q(len,nd), qs(len,nd), p(len,nd)
142	real hm(len,nd), gz(len,nd)
143
144	c outputs:
145	integer iflag(len), nk(len), icb(len), icbmax
146	real tnk(len), qnk(len), gznk(len), plcl(len)
147
148	c local variables:
149	integer i, k
150	integer ihmin(len)
151	real work(len)
152	real pnk(len), qsnk(len), rh(len), chi(len)
153
154	!-------------------------------------------------------------------
155	! --- Find level of minimum moist static energy
156	! --- If level of minimum moist static energy coincides with
157	! --- or is lower than minimum allowable parcel origin level,
158	! --- set iflag to 6.
159	!-------------------------------------------------------------------
160
161	do 180 i=1,len
162	work(i)=1.0e12
163	ihmin(i)=nl
164	180 continue
165	do 200 k=2,nlp
166	do 190 i=1,len
167	if((hm(i,k).lt.work(i)).and.
168	& (hm(i,k).lt.hm(i,k-1)))then
169	work(i)=hm(i,k)
170	ihmin(i)=k
171	endif
172	190 continue
173	200 continue
174	do 210 i=1,len
175	ihmin(i)=min(ihmin(i),nlm)
176	if(ihmin(i).le.minorig)then
177	iflag(i)=6
178	endif
179	210 continue
180	c
181	!-------------------------------------------------------------------
182	! --- Find that model level below the level of minimum moist static
183	! --- energy that has the maximum value of moist static energy
184	!-------------------------------------------------------------------
185
186	do 220 i=1,len
187	work(i)=hm(i,minorig)
188	nk(i)=minorig
189	220 continue
190	do 240 k=minorig+1,nl
191	do 230 i=1,len
192	if((hm(i,k).gt.work(i)).and.(k.le.ihmin(i)))then
193	work(i)=hm(i,k)
194	nk(i)=k
195	endif
196	230 continue
197	240 continue
198	!-------------------------------------------------------------------
199	! --- Check whether parcel level temperature and specific humidity
200	! --- are reasonable
201	!-------------------------------------------------------------------
202	do 250 i=1,len
203	if(((t(i,nk(i)).lt.250.0).or.
204	& (q(i,nk(i)).le.0.0).or.
205	& (p(i,ihmin(i)).lt.400.0)).and.
206	& (iflag(i).eq.0))iflag(i)=7
207	250 continue
208	!-------------------------------------------------------------------
209	! --- Calculate lifted condensation level of air at parcel origin level
210	! --- (Within 0.2% of formula of Bolton, MON. WEA. REV.,1980)
211	!-------------------------------------------------------------------
212	do 260 i=1,len
213	tnk(i)=t(i,nk(i))
214	qnk(i)=q(i,nk(i))
215	gznk(i)=gz(i,nk(i))
216	pnk(i)=p(i,nk(i))
217	qsnk(i)=qs(i,nk(i))
218	c
219	rh(i)=qnk(i)/qsnk(i)
220	rh(i)=min(1.0,rh(i))
221	chi(i)=tnk(i)/(1669.0-122.0*rh(i)-tnk(i))
222	plcl(i)=pnk(i)(rh(i)*chi(i))
223	if(((plcl(i).lt.200.0).or.(plcl(i).ge.2000.0))
224	& .and.(iflag(i).eq.0))iflag(i)=8
225	260 continue
226	!-------------------------------------------------------------------
227	! --- Calculate first level above lcl (=icb)
228	!-------------------------------------------------------------------
229	do 270 i=1,len
230	icb(i)=nlm
231	270 continue
232	c
233	do 290 k=minorig,nl
234	do 280 i=1,len
235	if((k.ge.(nk(i)+1)).and.(p(i,k).lt.plcl(i)))
236	& icb(i)=min(icb(i),k)
237	280 continue
238	290 continue
239	c
240	do 300 i=1,len
241	if((icb(i).ge.nlm).and.(iflag(i).eq.0))iflag(i)=9
242	300 continue
243	c
244	c Compute icbmax.
245	c
246	icbmax=2
247	do 310 i=1,len
248	icbmax=max(icbmax,icb(i))
249	310 continue
250
251	return
252	end
253
254	SUBROUTINE cv_undilute1(len,nd,t,q,qs,gz,p,nk,icb,icbmax
255	: ,tp,tvp,clw)
256	implicit none
257
258	#include "cvthermo.h"
259	#include "cvparam.h"
260
261	c inputs:
262	integer len, nd
263	integer nk(len), icb(len), icbmax
264	real t(len,nd), q(len,nd), qs(len,nd), gz(len,nd)
265	real p(len,nd)
266
267	c outputs:
268	real tp(len,nd), tvp(len,nd), clw(len,nd)
269
270	c local variables:
271	integer i, k
272	real tg, qg, alv, s, ahg, tc, denom, es, rg
273	real ah0(len), cpp(len)
274	real tnk(len), qnk(len), gznk(len), ticb(len), gzicb(len)
275
276	!-------------------------------------------------------------------
277	! --- Calculates the lifted parcel virtual temperature at nk,
278	! --- the actual temperature, and the adiabatic
279	! --- liquid water content. The procedure is to solve the equation.
280	! cptp+Lqp+phi=cptnk+Lqnk+gznk.
281	!-------------------------------------------------------------------
282
283	do 320 i=1,len
284	tnk(i)=t(i,nk(i))
285	qnk(i)=q(i,nk(i))
286	gznk(i)=gz(i,nk(i))
287	ticb(i)=t(i,icb(i))
288	gzicb(i)=gz(i,icb(i))
289	320 continue
290	c
291	c * Calculate certain parcel quantities, including static energy *
292	c
293	do 330 i=1,len
294	ah0(i)=(cpd(1.-qnk(i))+clqnk(i))*tnk(i)
295	& +qnk(i)(lv0-clmcpv(tnk(i)-273.15))+gznk(i)
296	cpp(i)=cpd(1.-qnk(i))+qnk(i)cpv
297	330 continue
298	c
299	c * Calculate lifted parcel quantities below cloud base *
300	c
301	do 350 k=minorig,icbmax-1
302	do 340 i=1,len
303	tp(i,k)=tnk(i)-(gz(i,k)-gznk(i))/cpp(i)
304	tvp(i,k)=tp(i,k)(1.+qnk(i)epsi)
305	340 continue
306	350 continue
307	c
308	c * Find lifted parcel quantities above cloud base *
309	c
310	do 360 i=1,len
311	tg=ticb(i)
312	qg=qs(i,icb(i))
313	alv=lv0-clmcpv*(ticb(i)-t0)
314	c
315	c First iteration.
316	c
317	s=cpd+alvalvqg/(rrvticb(i)ticb(i))
318	s=1./s
319	ahg=cpdtg+(cl-cpd)qnk(i)ticb(i)+alvqg+gzicb(i)
320	tg=tg+s*(ah0(i)-ahg)
321	tg=max(tg,35.0)
322	tc=tg-t0
323	denom=243.5+tc
324	if(tc.ge.0.0)then
325	es=6.112exp(17.67tc/denom)
326	else
327	es=exp(23.33086-6111.72784/tg+0.15215*log(tg))
328	endif
329	qg=epses/(p(i,icb(i))-es(1.-eps))
330	c
331	c Second iteration.
332	c
333	s=cpd+alvalvqg/(rrvticb(i)ticb(i))
334	s=1./s
335	ahg=cpdtg+(cl-cpd)qnk(i)ticb(i)+alvqg+gzicb(i)
336	tg=tg+s*(ah0(i)-ahg)
337	tg=max(tg,35.0)
338	tc=tg-t0
339	denom=243.5+tc
340	if(tc.ge.0.0)then
341	es=6.112exp(17.67tc/denom)
342	else
343	es=exp(23.33086-6111.72784/tg+0.15215*log(tg))
344	end if
345	qg=epses/(p(i,icb(i))-es(1.-eps))
346	c
347	alv=lv0-clmcpv*(ticb(i)-273.15)
348	tp(i,icb(i))=(ah0(i)-(cl-cpd)qnk(i)ticb(i)
349	& -gz(i,icb(i))-alv*qg)/cpd
350	clw(i,icb(i))=qnk(i)-qg
351	clw(i,icb(i))=max(0.0,clw(i,icb(i)))
352	rg=qg/(1.-qnk(i))
353	tvp(i,icb(i))=tp(i,icb(i))(1.+rgepsi)
354	360 continue
355	c
356	do 380 k=minorig,icbmax
357	do 370 i=1,len
358	tvp(i,k)=tvp(i,k)-tp(i,k)*qnk(i)
359	370 continue
360	380 continue
361	c
362	return
363	end
364
365	SUBROUTINE cv_trigger(len,nd,icb,cbmf,tv,tvp,iflag)
366	implicit none
367
368	!-------------------------------------------------------------------
369	! --- Test for instability.
370	! --- If there was no convection at last time step and parcel
371	! --- is stable at icb, then set iflag to 4.
372	!-------------------------------------------------------------------
373
374	#include "cvparam.h"
375
376	c inputs:
377	integer len, nd, icb(len)
378	real cbmf(len), tv(len,nd), tvp(len,nd)
379
380	c outputs:
381	integer iflag(len) ! also an input
382
383	c local variables:
384	integer i
385
386
387	do 390 i=1,len
388	if((cbmf(i).eq.0.0) .and.(iflag(i).eq.0).and.
389	& (tvp(i,icb(i)).le.(tv(i,icb(i))-dtmax)))iflag(i)=4
390	390 continue
391
392	return
393	end
394
395	SUBROUTINE cv_compress( len,nloc,ncum,nd
396	: ,iflag1,nk1,icb1
397	: ,cbmf1,plcl1,tnk1,qnk1,gznk1
398	: ,t1,q1,qs1,u1,v1,gz1
399	: ,h1,lv1,cpn1,p1,ph1,tv1,tp1,tvp1,clw1
400	o ,iflag,nk,icb
401	o ,cbmf,plcl,tnk,qnk,gznk
402	o ,t,q,qs,u,v,gz,h,lv,cpn,p,ph,tv,tp,tvp,clw
403	o ,dph )
404	implicit none
405
406	#include "cvparam.h"
407
408	c inputs:
409	integer len,ncum,nd,nloc
410	integer iflag1(len),nk1(len),icb1(len)
411	real cbmf1(len),plcl1(len),tnk1(len),qnk1(len),gznk1(len)
412	real t1(len,nd),q1(len,nd),qs1(len,nd),u1(len,nd),v1(len,nd)
413	real gz1(len,nd),h1(len,nd),lv1(len,nd),cpn1(len,nd)
414	real p1(len,nd),ph1(len,nd+1),tv1(len,nd),tp1(len,nd)
415	real tvp1(len,nd),clw1(len,nd)
416
417	c outputs:
418	integer iflag(nloc),nk(nloc),icb(nloc)
419	real cbmf(nloc),plcl(nloc),tnk(nloc),qnk(nloc),gznk(nloc)
420	real t(nloc,nd),q(nloc,nd),qs(nloc,nd),u(nloc,nd),v(nloc,nd)
421	real gz(nloc,nd),h(nloc,nd),lv(nloc,nd),cpn(nloc,nd)
422	real p(nloc,nd),ph(nloc,nd+1),tv(nloc,nd),tp(nloc,nd)
423	real tvp(nloc,nd),clw(nloc,nd)
424	real dph(nloc,nd)
425
426	c local variables:
427	integer i,k,nn
428
429
430	do 110 k=1,nl+1
431	nn=0
432	do 100 i=1,len
433	if(iflag1(i).eq.0)then
434	nn=nn+1
435	t(nn,k)=t1(i,k)
436	q(nn,k)=q1(i,k)
437	qs(nn,k)=qs1(i,k)
438	u(nn,k)=u1(i,k)
439	v(nn,k)=v1(i,k)
440	gz(nn,k)=gz1(i,k)
441	h(nn,k)=h1(i,k)
442	lv(nn,k)=lv1(i,k)
443	cpn(nn,k)=cpn1(i,k)
444	p(nn,k)=p1(i,k)
445	ph(nn,k)=ph1(i,k)
446	tv(nn,k)=tv1(i,k)
447	tp(nn,k)=tp1(i,k)
448	tvp(nn,k)=tvp1(i,k)
449	clw(nn,k)=clw1(i,k)
450	endif
451	100 continue
452	110 continue
453
454	if (nn.ne.ncum) then
455	print*,'strange! nn not equal to ncum: ',nn,ncum
456	stop
457	endif
458
459	nn=0
460	do 150 i=1,len
461	if(iflag1(i).eq.0)then
462	nn=nn+1
463	cbmf(nn)=cbmf1(i)
464	plcl(nn)=plcl1(i)
465	tnk(nn)=tnk1(i)
466	qnk(nn)=qnk1(i)
467	gznk(nn)=gznk1(i)
468	nk(nn)=nk1(i)
469	icb(nn)=icb1(i)
470	iflag(nn)=iflag1(i)
471	endif
472	150 continue
473
474	do 170 k=1,nl
475	do 160 i=1,ncum
476	dph(i,k)=ph(i,k)-ph(i,k+1)
477	160 continue
478	170 continue
479
480	return
481	end
482
483	SUBROUTINE cv_undilute2(nloc,ncum,nd,icb,nk
484	: ,tnk,qnk,gznk,t,q,qs,gz
485	: ,p,dph,h,tv,lv
486	o ,inb,inb1,tp,tvp,clw,hp,ep,sigp,frac)
487	implicit none
488
489	C---------------------------------------------------------------------
490	C Purpose:
491	C FIND THE REST OF THE LIFTED PARCEL TEMPERATURES
492	C &
493	C COMPUTE THE PRECIPITATION EFFICIENCIES AND THE
494	C FRACTION OF PRECIPITATION FALLING OUTSIDE OF CLOUD
495	C &
496	C FIND THE LEVEL OF NEUTRAL BUOYANCY
497	C---------------------------------------------------------------------
498
499	#include "cvthermo.h"
500	#include "cvparam.h"
501
502	c inputs:
503	integer ncum, nd, nloc
504	integer icb(nloc), nk(nloc)
505	real t(nloc,nd), q(nloc,nd), qs(nloc,nd), gz(nloc,nd)
506	real p(nloc,nd), dph(nloc,nd)
507	real tnk(nloc), qnk(nloc), gznk(nloc)
508	real lv(nloc,nd), tv(nloc,nd), h(nloc,nd)
509
510	c outputs:
511	integer inb(nloc), inb1(nloc)
512	real tp(nloc,nd), tvp(nloc,nd), clw(nloc,nd)
513	real ep(nloc,nd), sigp(nloc,nd), hp(nloc,nd)
514	real frac(nloc)
515
516	c local variables:
517	integer i, k
518	real tg,qg,ahg,alv,s,tc,es,denom,rg,tca,elacrit
519	real by, defrac
520	real ah0(nloc), cape(nloc), capem(nloc), byp(nloc)
521	logical lcape(nloc)
522
523	!=====================================================================
524	! --- SOME INITIALIZATIONS
525	!=====================================================================
526
527	do 170 k=1,nl
528	do 160 i=1,ncum
529	ep(i,k)=0.0
530	sigp(i,k)=sigs
531	160 continue
532	170 continue
533
534	!=====================================================================
535	! --- FIND THE REST OF THE LIFTED PARCEL TEMPERATURES
536	!=====================================================================
537	c
538	c --- The procedure is to solve the equation.
539	c cptp+Lqp+phi=cptnk+Lqnk+gznk.
540	c
541	c * Calculate certain parcel quantities, including static energy *
542	c
543	c
544	do 240 i=1,ncum
545	ah0(i)=(cpd(1.-qnk(i))+clqnk(i))*tnk(i)
546	& +qnk(i)(lv0-clmcpv(tnk(i)-t0))+gznk(i)
547	240 continue
548	c
549	c
550	c * Find lifted parcel quantities above cloud base *
551	c
552	c
553	do 300 k=minorig+1,nl
554	do 290 i=1,ncum
555	if(k.ge.(icb(i)+1))then
556	tg=t(i,k)
557	qg=qs(i,k)
558	alv=lv0-clmcpv*(t(i,k)-t0)
559	c
560	c First iteration.
561	c
562	s=cpd+alvalvqg/(rrvt(i,k)t(i,k))
563	s=1./s
564	ahg=cpdtg+(cl-cpd)qnk(i)t(i,k)+alvqg+gz(i,k)
565	tg=tg+s*(ah0(i)-ahg)
566	tg=max(tg,35.0)
567	tc=tg-t0
568	denom=243.5+tc
569	if(tc.ge.0.0)then
570	es=6.112exp(17.67tc/denom)
571	else
572	es=exp(23.33086-6111.72784/tg+0.15215*log(tg))
573	endif
574	qg=epses/(p(i,k)-es(1.-eps))
575	c
576	c Second iteration.
577	c
578	s=cpd+alvalvqg/(rrvt(i,k)t(i,k))
579	s=1./s
580	ahg=cpdtg+(cl-cpd)qnk(i)t(i,k)+alvqg+gz(i,k)
581	tg=tg+s*(ah0(i)-ahg)
582	tg=max(tg,35.0)
583	tc=tg-t0
584	denom=243.5+tc
585	if(tc.ge.0.0)then
586	es=6.112exp(17.67tc/denom)
587	else
588	es=exp(23.33086-6111.72784/tg+0.15215*log(tg))
589	endif
590	qg=epses/(p(i,k)-es(1.-eps))
591	c
592	alv=lv0-clmcpv*(t(i,k)-t0)
593	c print*,'cpd dans convect2 ',cpd
594	c print*,'tp(i,k),ah0(i),cl,cpd,qnk(i),t(i,k),gz(i,k),alv,qg,cpd'
595	c print*,tp(i,k),ah0(i),cl,cpd,qnk(i),t(i,k),gz(i,k),alv,qg,cpd
596	tp(i,k)=(ah0(i)-(cl-cpd)qnk(i)t(i,k)-gz(i,k)-alv*qg)/cpd
597	c if (.not.cpd.gt.1000.) then
598	c print*,'CPD=',cpd
599	c stop
600	c endif
601	clw(i,k)=qnk(i)-qg
602	clw(i,k)=max(0.0,clw(i,k))
603	rg=qg/(1.-qnk(i))
604	tvp(i,k)=tp(i,k)(1.+rgepsi)
605	endif
606	290 continue
607	300 continue
608	c
609	!=====================================================================
610	! --- SET THE PRECIPITATION EFFICIENCIES AND THE FRACTION OF
611	! --- PRECIPITATION FALLING OUTSIDE OF CLOUD
612	! --- THESE MAY BE FUNCTIONS OF TP(I), P(I) AND CLW(I)
613	!=====================================================================
614	c
615	do 320 k=minorig+1,nl
616	do 310 i=1,ncum
617	if(k.ge.(nk(i)+1))then
618	tca=tp(i,k)-t0
619	if(tca.ge.0.0)then
620	elacrit=elcrit
621	else
622	elacrit=elcrit*(1.0-tca/tlcrit)
623	endif
624	elacrit=max(elacrit,0.0)
625	ep(i,k)=1.0-elacrit/max(clw(i,k),1.0e-8)
626	ep(i,k)=max(ep(i,k),0.0 )
627	ep(i,k)=min(ep(i,k),1.0 )
628	sigp(i,k)=sigs
629	endif
630	310 continue
631	320 continue
632	c
633	!=====================================================================
634	! --- CALCULATE VIRTUAL TEMPERATURE AND LIFTED PARCEL
635	! --- VIRTUAL TEMPERATURE
636	!=====================================================================
637	c
638	do 340 k=minorig+1,nl
639	do 330 i=1,ncum
640	if(k.ge.(icb(i)+1))then
641	tvp(i,k)=tvp(i,k)(1.0-qnk(i)+ep(i,k)clw(i,k))
642	c print*,'i,k,tvp(i,k),qnk(i),ep(i,k),clw(i,k)'
643	c print*, i,k,tvp(i,k),qnk(i),ep(i,k),clw(i,k)
644	endif
645	330 continue
646	340 continue
647	do 350 i=1,ncum
648	tvp(i,nlp)=tvp(i,nl)-(gz(i,nlp)-gz(i,nl))/cpd
649	350 continue
650	c
651	c=====================================================================
652	c --- FIND THE FIRST MODEL LEVEL (INB1) ABOVE THE PARCEL'S
653	c --- HIGHEST LEVEL OF NEUTRAL BUOYANCY
654	c --- AND THE HIGHEST LEVEL OF POSITIVE CAPE (INB)
655	c=====================================================================
656	c
657	do 510 i=1,ncum
658	cape(i)=0.0
659	capem(i)=0.0
660	inb(i)=icb(i)+1
661	inb1(i)=inb(i)
662	510 continue
663	c
664	c Originial Code
665	c
666	c do 530 k=minorig+1,nl-1
667	c do 520 i=1,ncum
668	c if(k.ge.(icb(i)+1))then
669	c by=(tvp(i,k)-tv(i,k))*dph(i,k)/p(i,k)
670	c byp=(tvp(i,k+1)-tv(i,k+1))*dph(i,k+1)/p(i,k+1)
671	c cape(i)=cape(i)+by
672	c if(by.ge.0.0)inb1(i)=k+1
673	c if(cape(i).gt.0.0)then
674	c inb(i)=k+1
675	c capem(i)=cape(i)
676	c endif
677	c endif
678	c520 continue
679	c530 continue
680	c do 540 i=1,ncum
681	c byp=(tvp(i,nl)-tv(i,nl))*dph(i,nl)/p(i,nl)
682	c cape(i)=capem(i)+byp
683	c defrac=capem(i)-cape(i)
684	c defrac=max(defrac,0.001)
685	c frac(i)=-cape(i)/defrac
686	c frac(i)=min(frac(i),1.0)
687	c frac(i)=max(frac(i),0.0)
688	c540 continue
689	c
690	c K Emanuel fix
691	c
692	c call zilch(byp,ncum)
693	c do 530 k=minorig+1,nl-1
694	c do 520 i=1,ncum
695	c if(k.ge.(icb(i)+1))then
696	c by=(tvp(i,k)-tv(i,k))*dph(i,k)/p(i,k)
697	c cape(i)=cape(i)+by
698	c if(by.ge.0.0)inb1(i)=k+1
699	c if(cape(i).gt.0.0)then
700	c inb(i)=k+1
701	c capem(i)=cape(i)
702	c byp(i)=(tvp(i,k+1)-tv(i,k+1))*dph(i,k+1)/p(i,k+1)
703	c endif
704	c endif
705	c520 continue
706	c530 continue
707	c do 540 i=1,ncum
708	c inb(i)=max(inb(i),inb1(i))
709	c cape(i)=capem(i)+byp(i)
710	c defrac=capem(i)-cape(i)
711	c defrac=max(defrac,0.001)
712	c frac(i)=-cape(i)/defrac
713	c frac(i)=min(frac(i),1.0)
714	c frac(i)=max(frac(i),0.0)
715	c540 continue
716	c
717	c J Teixeira fix
718	c
719	call zilch(byp,ncum)
720	do 515 i=1,ncum
721	lcape(i)=.true.
722	515 continue
723	do 530 k=minorig+1,nl-1
724	do 520 i=1,ncum
725	if(cape(i).lt.0.0)lcape(i)=.false.
726	if((k.ge.(icb(i)+1)).and.lcape(i))then
727	by=(tvp(i,k)-tv(i,k))*dph(i,k)/p(i,k)
728	byp(i)=(tvp(i,k+1)-tv(i,k+1))*dph(i,k+1)/p(i,k+1)
729	cape(i)=cape(i)+by
730	if(by.ge.0.0)inb1(i)=k+1
731	if(cape(i).gt.0.0)then
732	inb(i)=k+1
733	capem(i)=cape(i)
734	endif
735	endif
736	520 continue
737	530 continue
738	do 540 i=1,ncum
739	cape(i)=capem(i)+byp(i)
740	defrac=capem(i)-cape(i)
741	defrac=max(defrac,0.001)
742	frac(i)=-cape(i)/defrac
743	frac(i)=min(frac(i),1.0)
744	frac(i)=max(frac(i),0.0)
745	540 continue
746	c
747	c=====================================================================
748	c --- CALCULATE LIQUID WATER STATIC ENERGY OF LIFTED PARCEL
749	c=====================================================================
750	c
751	c initialization:
752	do i=1,ncum*nlp
753	hp(i,1)=h(i,1)
754	enddo
755
756	do 600 k=minorig+1,nl
757	do 590 i=1,ncum
758	if((k.ge.icb(i)).and.(k.le.inb(i)))then
759	hp(i,k)=h(i,nk(i))+(lv(i,k)+(cpd-cpv)t(i,k))ep(i,k)*clw(i,k)
760	endif
761	590 continue
762	600 continue
763	c
764	return
765	end
766	c
767	SUBROUTINE cv_closure(nloc,ncum,nd,nk,icb
768	: ,tv,tvp,p,ph,dph,plcl,cpn
769	: ,iflag,cbmf)
770	implicit none
771
772	c inputs:
773	integer ncum, nd, nloc
774	integer nk(nloc), icb(nloc)
775	real tv(nloc,nd), tvp(nloc,nd), p(nloc,nd), dph(nloc,nd)
776	real ph(nloc,nd+1) ! caution nd instead ndp1 to be consistent...
777	real plcl(nloc), cpn(nloc,nd)
778
779	c outputs:
780	integer iflag(nloc)
781	real cbmf(nloc) ! also an input
782
783	c local variables:
784	integer i, k, icbmax
785	real dtpbl(nloc), dtmin(nloc), tvpplcl(nloc), tvaplcl(nloc)
786	real work(nloc)
787
788	#include "cvthermo.h"
789	#include "cvparam.h"
790
791	c-------------------------------------------------------------------
792	c Compute icbmax.
793	c-------------------------------------------------------------------
794
795	icbmax=2
796	do 230 i=1,ncum
797	icbmax=max(icbmax,icb(i))
798	230 continue
799
800	c=====================================================================
801	c --- CALCULATE CLOUD BASE MASS FLUX
802	c=====================================================================
803	c
804	c tvpplcl = parcel temperature lifted adiabatically from level
805	c icb-1 to the LCL.
806	c tvaplcl = virtual temperature at the LCL.
807	c
808	do 610 i=1,ncum
809	dtpbl(i)=0.0
810	tvpplcl(i)=tvp(i,icb(i)-1)
811	& -rrdtvp(i,icb(i)-1)(p(i,icb(i)-1)-plcl(i))
812	& /(cpn(i,icb(i)-1)*p(i,icb(i)-1))
813	tvaplcl(i)=tv(i,icb(i))
814	& +(tvp(i,icb(i))-tvp(i,icb(i)+1))*(plcl(i)-p(i,icb(i)))
815	& /(p(i,icb(i))-p(i,icb(i)+1))
816	610 continue
817
818	c-------------------------------------------------------------------
819	c --- Interpolate difference between lifted parcel and
820	c --- environmental temperatures to lifted condensation level
821	c-------------------------------------------------------------------
822	c
823	c dtpbl = average of tvp-tv in the PBL (k=nk to icb-1).
824	c
825	do 630 k=minorig,icbmax
826	do 620 i=1,ncum
827	if((k.ge.nk(i)).and.(k.le.(icb(i)-1)))then
828	dtpbl(i)=dtpbl(i)+(tvp(i,k)-tv(i,k))*dph(i,k)
829	endif
830	620 continue
831	630 continue
832	do 640 i=1,ncum
833	dtpbl(i)=dtpbl(i)/(ph(i,nk(i))-ph(i,icb(i)))
834	dtmin(i)=tvpplcl(i)-tvaplcl(i)+dtmax+dtpbl(i)
835	640 continue
836	c
837	c-------------------------------------------------------------------
838	c --- Adjust cloud base mass flux
839	c-------------------------------------------------------------------
840	c
841	do 650 i=1,ncum
842	work(i)=cbmf(i)
843	cbmf(i)=max(0.0,(1.0-damp)cbmf(i)+0.1alpha*dtmin(i))
844	if((work(i).eq.0.0).and.(cbmf(i).eq.0.0))then
845	iflag(i)=3
846	endif
847	650 continue
848
849	return
850	end
851
852	SUBROUTINE cv_mixing(nloc,ncum,nd,icb,nk,inb,inb1
853	: ,ph,t,q,qs,u,v,h,lv,qnk
854	: ,hp,tv,tvp,ep,clw,cbmf
855	: ,m,ment,qent,uent,vent,nent,sij,elij)
856	implicit none
857
858	#include "cvthermo.h"
859	#include "cvparam.h"
860
861	c inputs:
862	integer ncum, nd, nloc
863	integer icb(nloc), inb(nloc), inb1(nloc), nk(nloc)
864	real cbmf(nloc), qnk(nloc)
865	real ph(nloc,nd+1)
866	real t(nloc,nd), q(nloc,nd), qs(nloc,nd), lv(nloc,nd)
867	real u(nloc,nd), v(nloc,nd), h(nloc,nd), hp(nloc,nd)
868	real tv(nloc,nd), tvp(nloc,nd), ep(nloc,nd), clw(nloc,nd)
869
870	c outputs:
871	integer nent(nloc,nd)
872	real m(nloc,nd), ment(nloc,nd,nd), qent(nloc,nd,nd)
873	real uent(nloc,nd,nd), vent(nloc,nd,nd)
874	real sij(nloc,nd,nd), elij(nloc,nd,nd)
875
876	c local variables:
877	integer i, j, k, ij
878	integer num1, num2
879	real dbo, qti, bf2, anum, denom, dei, altem, cwat, stemp
880	real alt, qp1, smid, sjmin, sjmax, delp, delm
881	real work(nloc), asij(nloc), smin(nloc), scrit(nloc)
882	real bsum(nloc,nd)
883	logical lwork(nloc)
884
885	c=====================================================================
886	c --- INITIALIZE VARIOUS ARRAYS USED IN THE COMPUTATIONS
887	c=====================================================================
888	c
889	do 360 i=1,ncum*nlp
890	nent(i,1)=0
891	m(i,1)=0.0
892	360 continue
893	c
894	do 400 k=1,nlp
895	do 390 j=1,nlp
896	do 385 i=1,ncum
897	qent(i,k,j)=q(i,j)
898	uent(i,k,j)=u(i,j)
899	vent(i,k,j)=v(i,j)
900	elij(i,k,j)=0.0
901	ment(i,k,j)=0.0
902	sij(i,k,j)=0.0
903	385 continue
904	390 continue
905	400 continue
906	c
907	c-------------------------------------------------------------------
908	c --- Calculate rates of mixing, m(i)
909	c-------------------------------------------------------------------
910	c
911	call zilch(work,ncum)
912	c
913	do 670 j=minorig+1,nl
914	do 660 i=1,ncum
915	if((j.ge.(icb(i)+1)).and.(j.le.inb(i)))then
916	k=min(j,inb1(i))
917	dbo=abs(tv(i,k+1)-tvp(i,k+1)-tv(i,k-1)+tvp(i,k-1))
918	& +entp0.04(ph(i,k)-ph(i,k+1))
919	work(i)=work(i)+dbo
920	m(i,j)=cbmf(i)*dbo
921	endif
922	660 continue
923	670 continue
924	do 690 k=minorig+1,nl
925	do 680 i=1,ncum
926	if((k.ge.(icb(i)+1)).and.(k.le.inb(i)))then
927	m(i,k)=m(i,k)/work(i)
928	endif
929	680 continue
930	690 continue
931	c
932	c
933	c=====================================================================
934	c --- CALCULATE ENTRAINED AIR MASS FLUX (ment), TOTAL WATER MIXING
935	c --- RATIO (QENT), TOTAL CONDENSED WATER (elij), AND MIXING
936	c --- FRACTION (sij)
937	c=====================================================================
938	c
939	c
940	do 750 i=minorig+1,nl
941	do 710 j=minorig+1,nl
942	do 700 ij=1,ncum
943	if((i.ge.(icb(ij)+1)).and.(j.ge.icb(ij))
944	& .and.(i.le.inb(ij)).and.(j.le.inb(ij)))then
945	qti=qnk(ij)-ep(ij,i)*clw(ij,i)
946	bf2=1.+lv(ij,j)lv(ij,j)qs(ij,j)
947	& /(rrvt(ij,j)t(ij,j)*cpd)
948	anum=h(ij,j)-hp(ij,i)+(cpv-cpd)t(ij,j)(qti-q(ij,j))
949	denom=h(ij,i)-hp(ij,i)+(cpd-cpv)(q(ij,i)-qti)t(ij,j)
950	dei=denom
951	if(abs(dei).lt.0.01)dei=0.01
952	sij(ij,i,j)=anum/dei
953	sij(ij,i,i)=1.0
954	altem=sij(ij,i,j)q(ij,i)+(1.-sij(ij,i,j))qti-qs(ij,j)
955	altem=altem/bf2
956	cwat=clw(ij,j)*(1.-ep(ij,j))
957	stemp=sij(ij,i,j)
958	if((stemp.lt.0.0.or.stemp.gt.1.0.or.
959	1 altem.gt.cwat).and.j.gt.i)then
960	anum=anum-lv(ij,j)(qti-qs(ij,j)-cwatbf2)
961	denom=denom+lv(ij,j)*(q(ij,i)-qti)
962	if(abs(denom).lt.0.01)denom=0.01
963	sij(ij,i,j)=anum/denom
964	altem=sij(ij,i,j)q(ij,i)+(1.-sij(ij,i,j))qti-qs(ij,j)
965	altem=altem-(bf2-1.)*cwat
966	endif
967	if(sij(ij,i,j).gt.0.0.and.sij(ij,i,j).lt.0.9)then
968	qent(ij,i,j)=sij(ij,i,j)*q(ij,i)
969	& +(1.-sij(ij,i,j))*qti
970	uent(ij,i,j)=sij(ij,i,j)*u(ij,i)
971	& +(1.-sij(ij,i,j))*u(ij,nk(ij))
972	vent(ij,i,j)=sij(ij,i,j)*v(ij,i)
973	& +(1.-sij(ij,i,j))*v(ij,nk(ij))
974	elij(ij,i,j)=altem
975	elij(ij,i,j)=max(0.0,elij(ij,i,j))
976	ment(ij,i,j)=m(ij,i)/(1.-sij(ij,i,j))
977	nent(ij,i)=nent(ij,i)+1
978	endif
979	sij(ij,i,j)=max(0.0,sij(ij,i,j))
980	sij(ij,i,j)=min(1.0,sij(ij,i,j))
981	endif
982	700 continue
983	710 continue
984	c
985	c * If no air can entrain at level i assume that updraft detrains *
986	c * at that level and calculate detrained air flux and properties *
987	c
988	do 740 ij=1,ncum
989	if((i.ge.(icb(ij)+1)).and.(i.le.inb(ij))
990	& .and.(nent(ij,i).eq.0))then
991	ment(ij,i,i)=m(ij,i)
992	qent(ij,i,i)=q(ij,nk(ij))-ep(ij,i)*clw(ij,i)
993	uent(ij,i,i)=u(ij,nk(ij))
994	vent(ij,i,i)=v(ij,nk(ij))
995	elij(ij,i,i)=clw(ij,i)
996	sij(ij,i,i)=1.0
997	endif
998	740 continue
999	750 continue
1000	c
1001	do 770 i=1,ncum
1002	sij(i,inb(i),inb(i))=1.0
1003	770 continue
1004	c
1005	c=====================================================================
1006	c --- NORMALIZE ENTRAINED AIR MASS FLUXES
1007	c --- TO REPRESENT EQUAL PROBABILITIES OF MIXING
1008	c=====================================================================
1009	c
1010	call zilch(bsum,ncum*nlp)
1011	do 780 ij=1,ncum
1012	lwork(ij)=.false.
1013	780 continue
1014	do 789 i=minorig+1,nl
1015	c
1016	num1=0
1017	do 779 ij=1,ncum
1018	if((i.ge.icb(ij)+1).and.(i.le.inb(ij)))num1=num1+1
1019	779 continue
1020	if(num1.le.0)go to 789
1021	c
1022	do 781 ij=1,ncum
1023	if((i.ge.icb(ij)+1).and.(i.le.inb(ij)))then
1024	lwork(ij)=(nent(ij,i).ne.0)
1025	qp1=q(ij,nk(ij))-ep(ij,i)*clw(ij,i)
1026	anum=h(ij,i)-hp(ij,i)-lv(ij,i)*(qp1-qs(ij,i))
1027	denom=h(ij,i)-hp(ij,i)+lv(ij,i)*(q(ij,i)-qp1)
1028	if(abs(denom).lt.0.01)denom=0.01
1029	scrit(ij)=anum/denom
1030	alt=qp1-qs(ij,i)+scrit(ij)*(q(ij,i)-qp1)
1031	if(scrit(ij).lt.0.0.or.alt.lt.0.0)scrit(ij)=1.0
1032	asij(ij)=0.0
1033	smin(ij)=1.0
1034	endif
1035	781 continue
1036	do 783 j=minorig,nl
1037	c
1038	num2=0
1039	do 778 ij=1,ncum
1040	if((i.ge.icb(ij)+1).and.(i.le.inb(ij))
1041	& .and.(j.ge.icb(ij)).and.(j.le.inb(ij))
1042	& .and.lwork(ij))num2=num2+1
1043	778 continue
1044	if(num2.le.0)go to 783
1045	c
1046	do 782 ij=1,ncum
1047	if((i.ge.icb(ij)+1).and.(i.le.inb(ij))
1048	& .and.(j.ge.icb(ij)).and.(j.le.inb(ij)).and.lwork(ij))then
1049	if(sij(ij,i,j).gt.0.0.and.sij(ij,i,j).lt.0.9)then
1050	if(j.gt.i)then
1051	smid=min(sij(ij,i,j),scrit(ij))
1052	sjmax=smid
1053	sjmin=smid
1054	if(smid.lt.smin(ij)
1055	& .and.sij(ij,i,j+1).lt.smid)then
1056	smin(ij)=smid
1057	sjmax=min(sij(ij,i,j+1),sij(ij,i,j),scrit(ij))
1058	sjmin=max(sij(ij,i,j-1),sij(ij,i,j))
1059	sjmin=min(sjmin,scrit(ij))
1060	endif
1061	else
1062	sjmax=max(sij(ij,i,j+1),scrit(ij))
1063	smid=max(sij(ij,i,j),scrit(ij))
1064	sjmin=0.0
1065	if(j.gt.1)sjmin=sij(ij,i,j-1)
1066	sjmin=max(sjmin,scrit(ij))
1067	endif
1068	delp=abs(sjmax-smid)
1069	delm=abs(sjmin-smid)
1070	asij(ij)=asij(ij)+(delp+delm)
1071	& *(ph(ij,j)-ph(ij,j+1))
1072	ment(ij,i,j)=ment(ij,i,j)*(delp+delm)
1073	& *(ph(ij,j)-ph(ij,j+1))
1074	endif
1075	endif
1076	782 continue
1077	783 continue
1078	do 784 ij=1,ncum
1079	if((i.ge.icb(ij)+1).and.(i.le.inb(ij)).and.lwork(ij))then
1080	asij(ij)=max(1.0e-21,asij(ij))
1081	asij(ij)=1.0/asij(ij)
1082	bsum(ij,i)=0.0
1083	endif
1084	784 continue
1085	do 786 j=minorig,nl+1
1086	do 785 ij=1,ncum
1087	if((i.ge.icb(ij)+1).and.(i.le.inb(ij))
1088	& .and.(j.ge.icb(ij)).and.(j.le.inb(ij))
1089	& .and.lwork(ij))then
1090	ment(ij,i,j)=ment(ij,i,j)*asij(ij)
1091	bsum(ij,i)=bsum(ij,i)+ment(ij,i,j)
1092	endif
1093	785 continue
1094	786 continue
1095	do 787 ij=1,ncum
1096	if((i.ge.icb(ij)+1).and.(i.le.inb(ij))
1097	& .and.(bsum(ij,i).lt.1.0e-18).and.lwork(ij))then
1098	nent(ij,i)=0
1099	ment(ij,i,i)=m(ij,i)
1100	qent(ij,i,i)=q(ij,nk(ij))-ep(ij,i)*clw(ij,i)
1101	uent(ij,i,i)=u(ij,nk(ij))
1102	vent(ij,i,i)=v(ij,nk(ij))
1103	elij(ij,i,i)=clw(ij,i)
1104	sij(ij,i,i)=1.0
1105	endif
1106	787 continue
1107	789 continue
1108	c
1109	return
1110	end
1111
1112	SUBROUTINE cv_unsat(nloc,ncum,nd,inb,t,q,qs,gz,u,v,p,ph
1113	: ,h,lv,ep,sigp,clw,m,ment,elij
1114	: ,iflag,mp,qp,up,vp,wt,water,evap)
1115	implicit none
1116
1117
1118	#include "cvthermo.h"
1119	#include "cvparam.h"
1120
1121	c inputs:
1122	integer ncum, nd, nloc
1123	integer inb(nloc)
1124	real t(nloc,nd), q(nloc,nd), qs(nloc,nd)
1125	real gz(nloc,nd), u(nloc,nd), v(nloc,nd)
1126	real p(nloc,nd), ph(nloc,nd+1), h(nloc,nd)
1127	real lv(nloc,nd), ep(nloc,nd), sigp(nloc,nd), clw(nloc,nd)
1128	real m(nloc,nd), ment(nloc,nd,nd), elij(nloc,nd,nd)
1129
1130	c outputs:
1131	integer iflag(nloc) ! also an input
1132	real mp(nloc,nd), qp(nloc,nd), up(nloc,nd), vp(nloc,nd)
1133	real water(nloc,nd), evap(nloc,nd), wt(nloc,nd)
1134
1135	c local variables:
1136	integer i,j,k,ij,num1
1137	integer jtt(nloc)
1138	real awat, coeff, qsm, afac, sigt, b6, c6, revap
1139	real dhdp, fac, qstm, rat
1140	real wdtrain(nloc)
1141	logical lwork(nloc)
1142
1143	c=====================================================================
1144	c --- PRECIPITATING DOWNDRAFT CALCULATION
1145	c=====================================================================
1146	c
1147	c Initializations:
1148	c
1149	do i = 1, ncum
1150	do k = 1, nl+1
1151	wt(i,k) = omtsnow
1152	mp(i,k) = 0.0
1153	evap(i,k) = 0.0
1154	water(i,k) = 0.0
1155	enddo
1156	enddo
1157
1158	do 420 i=1,ncum
1159	qp(i,1)=q(i,1)
1160	up(i,1)=u(i,1)
1161	vp(i,1)=v(i,1)
1162	420 continue
1163
1164	do 440 k=2,nl+1
1165	do 430 i=1,ncum
1166	qp(i,k)=q(i,k-1)
1167	up(i,k)=u(i,k-1)
1168	vp(i,k)=v(i,k-1)
1169	430 continue
1170	440 continue
1171
1172
1173	c * Check whether ep(inb)=0, if so, skip precipitating *
1174	c * downdraft calculation *
1175	c
1176	c
1177	c * Integrate liquid water equation to find condensed water *
1178	c * and condensed water flux *
1179	c
1180	c
1181	do 890 i=1,ncum
1182	jtt(i)=2
1183	if(ep(i,inb(i)).le.0.0001)iflag(i)=2
1184	if(iflag(i).eq.0)then
1185	lwork(i)=.true.
1186	else
1187	lwork(i)=.false.
1188	endif
1189	890 continue
1190	c
1191	c * Begin downdraft loop *
1192	c
1193	c
1194	call zilch(wdtrain,ncum)
1195	do 899 i=nl+1,1,-1
1196	c
1197	num1=0
1198	do 879 ij=1,ncum
1199	if((i.le.inb(ij)).and.lwork(ij))num1=num1+1
1200	879 continue
1201	if(num1.le.0)go to 899
1202	c
1203	c
1204	c * Calculate detrained precipitation *
1205	c
1206	do 891 ij=1,ncum
1207	if((i.le.inb(ij)).and.(lwork(ij)))then
1208	wdtrain(ij)=gep(ij,i)m(ij,i)*clw(ij,i)
1209	endif
1210	891 continue
1211	c
1212	if(i.gt.1)then
1213	do 893 j=1,i-1
1214	do 892 ij=1,ncum
1215	if((i.le.inb(ij)).and.(lwork(ij)))then
1216	awat=elij(ij,j,i)-(1.-ep(ij,i))*clw(ij,i)
1217	awat=max(0.0,awat)
1218	wdtrain(ij)=wdtrain(ij)+gawatment(ij,j,i)
1219	endif
1220	892 continue
1221	893 continue
1222	endif
1223	c
1224	c * Find rain water and evaporation using provisional *
1225	c * estimates of qp(i)and qp(i-1) *
1226	c
1227	c
1228	c * Value of terminal velocity and coeffecient of evaporation for snow *
1229	c
1230	do 894 ij=1,ncum
1231	if((i.le.inb(ij)).and.(lwork(ij)))then
1232	coeff=coeffs
1233	wt(ij,i)=omtsnow
1234	c
1235	c * Value of terminal velocity and coeffecient of evaporation for rain *
1236	c
1237	if(t(ij,i).gt.273.0)then
1238	coeff=coeffr
1239	wt(ij,i)=omtrain
1240	endif
1241	qsm=0.5*(q(ij,i)+qp(ij,i+1))
1242	afac=coeffph(ij,i)(qs(ij,i)-qsm)
1243	& /(1.0e4+2.0e3ph(ij,i)qs(ij,i))
1244	afac=max(afac,0.0)
1245	sigt=sigp(ij,i)
1246	sigt=max(0.0,sigt)
1247	sigt=min(1.0,sigt)
1248	b6=100.(ph(ij,i)-ph(ij,i+1))sigt*afac/wt(ij,i)
1249	c6=(water(ij,i+1)*wt(ij,i+1)+wdtrain(ij)/sigd)/wt(ij,i)
1250	revap=0.5(-b6+sqrt(b6b6+4.*c6))
1251	evap(ij,i)=sigtafacrevap
1252	water(ij,i)=revap*revap
1253	c
1254	c * Calculate precipitating downdraft mass flux under *
1255	c * hydrostatic approximation *
1256	c
1257	if(i.gt.1)then
1258	dhdp=(h(ij,i)-h(ij,i-1))/(p(ij,i-1)-p(ij,i))
1259	dhdp=max(dhdp,10.0)
1260	mp(ij,i)=100.ginvlv(ij,i)sigdevap(ij,i)/dhdp
1261	mp(ij,i)=max(mp(ij,i),0.0)
1262	c
1263	c * Add small amount of inertia to downdraft *
1264	c
1265	fac=20.0/(ph(ij,i-1)-ph(ij,i))
1266	mp(ij,i)=(fac*mp(ij,i+1)+mp(ij,i))/(1.+fac)
1267	c
1268	c * Force mp to decrease linearly to zero *
1269	c * between about 950 mb and the surface *
1270	c
1271	if(p(ij,i).gt.(0.949*p(ij,1)))then
1272	jtt(ij)=max(jtt(ij),i)
1273	mp(ij,i)=mp(ij,jtt(ij))*(p(ij,1)-p(ij,i))
1274	& /(p(ij,1)-p(ij,jtt(ij)))
1275	endif
1276	endif
1277	c
1278	c * Find mixing ratio of precipitating downdraft *
1279	c
1280	if(i.ne.inb(ij))then
1281	if(i.eq.1)then
1282	qstm=qs(ij,1)
1283	else
1284	qstm=qs(ij,i-1)
1285	endif
1286	if(mp(ij,i).gt.mp(ij,i+1))then
1287	rat=mp(ij,i+1)/mp(ij,i)
1288	qp(ij,i)=qp(ij,i+1)rat+q(ij,i)(1.0-rat)+100.ginv
1289	& sigd(ph(ij,i)-ph(ij,i+1))(evap(ij,i)/mp(ij,i))
1290	up(ij,i)=up(ij,i+1)rat+u(ij,i)(1.-rat)
1291	vp(ij,i)=vp(ij,i+1)rat+v(ij,i)(1.-rat)
1292	else
1293	if(mp(ij,i+1).gt.0.0)then
1294	qp(ij,i)=(gz(ij,i+1)-gz(ij,i)
1295	& +qp(ij,i+1)*(lv(ij,i+1)+t(ij,i+1)
1296	& (cl-cpd))+cpd(t(ij,i+1)-t(ij,i)))
1297	& /(lv(ij,i)+t(ij,i)*(cl-cpd))
1298	up(ij,i)=up(ij,i+1)
1299	vp(ij,i)=vp(ij,i+1)
1300	endif
1301	endif
1302	qp(ij,i)=min(qp(ij,i),qstm)
1303	qp(ij,i)=max(qp(ij,i),0.0)
1304	endif
1305	endif
1306	894 continue
1307	899 continue
1308	c
1309	return
1310	end
1311
1312	SUBROUTINE cv_yield(nloc,ncum,nd,nk,icb,inb,delt
1313	: ,t,q,u,v,gz,p,ph,h,hp,lv,cpn
1314	: ,ep,clw,frac,m,mp,qp,up,vp
1315	: ,wt,water,evap
1316	: ,ment,qent,uent,vent,nent,elij
1317	: ,tv,tvp
1318	o ,iflag,wd,qprime,tprime
1319	o ,precip,cbmf,ft,fq,fu,fv,Ma,qcondc)
1320	implicit none
1321
1322	#include "cvthermo.h"
1323	#include "cvparam.h"
1324
1325	c inputs
1326	integer ncum, nd, nloc
1327	integer nk(nloc), icb(nloc), inb(nloc)
1328	integer nent(nloc,nd)
1329	real delt
1330	real t(nloc,nd), q(nloc,nd), u(nloc,nd), v(nloc,nd)
1331	real gz(nloc,nd)
1332	real p(nloc,nd), ph(nloc,nd+1), h(nloc,nd)
1333	real hp(nloc,nd), lv(nloc,nd)
1334	real cpn(nloc,nd), ep(nloc,nd), clw(nloc,nd), frac(nloc)
1335	real m(nloc,nd), mp(nloc,nd), qp(nloc,nd)
1336	real up(nloc,nd), vp(nloc,nd)
1337	real wt(nloc,nd), water(nloc,nd), evap(nloc,nd)
1338	real ment(nloc,nd,nd), qent(nloc,nd,nd), elij(nloc,nd,nd)
1339	real uent(nloc,nd,nd), vent(nloc,nd,nd)
1340	real tv(nloc,nd), tvp(nloc,nd)
1341
1342	c outputs
1343	integer iflag(nloc) ! also an input
1344	real cbmf(nloc) ! also an input
1345	real wd(nloc), tprime(nloc), qprime(nloc)
1346	real precip(nloc)
1347	real ft(nloc,nd), fq(nloc,nd), fu(nloc,nd), fv(nloc,nd)
1348	real Ma(nloc,nd)
1349	real qcondc(nloc,nd)
1350
1351	c local variables
1352	integer i,j,ij,k,num1
1353	real dpinv,cpinv,awat,fqold,ftold,fuold,fvold,delti
1354	real work(nloc), am(nloc),amp1(nloc),ad(nloc)
1355	real ents(nloc), uav(nloc),vav(nloc),lvcp(nloc,nd)
1356	real qcond(nloc,nd), nqcond(nloc,nd), wa(nloc,nd) ! cld
1357	real siga(nloc,nd), ax(nloc,nd), mac(nloc,nd) ! cld
1358
1359
1360	c -- initializations:
1361
1362	delti = 1.0/delt
1363
1364	do 160 i=1,ncum
1365	precip(i)=0.0
1366	wd(i)=0.0
1367	tprime(i)=0.0
1368	qprime(i)=0.0
1369	do 170 k=1,nl+1
1370	ft(i,k)=0.0
1371	fu(i,k)=0.0
1372	fv(i,k)=0.0
1373	fq(i,k)=0.0
1374	lvcp(i,k)=lv(i,k)/cpn(i,k)
1375	qcondc(i,k)=0.0 ! cld
1376	qcond(i,k)=0.0 ! cld
1377	nqcond(i,k)=0.0 ! cld
1378	170 continue
1379	160 continue
1380
1381	c
1382	c * Calculate surface precipitation in mm/day *
1383	c
1384	do 1190 i=1,ncum
1385	if(iflag(i).le.1)then
1386	cc precip(i)=precip(i)+wt(i,1)sigdwater(i,1)3600.24000.
1387	cc & /(rowl*g)
1388	cc precip(i)=precip(i)*delt/86400.
1389	precip(i) = wt(i,1)sigdwater(i,1)*86400/g
1390	endif
1391	1190 continue
1392	c
1393	c
1394	c * Calculate downdraft velocity scale and surface temperature and *
1395	c * water vapor fluctuations *
1396	c
1397	do i=1,ncum
1398	wd(i)=betadabs(mp(i,icb(i)))0.01rrdt(i,icb(i))
1399	: /(sigd*p(i,icb(i)))
1400	qprime(i)=0.5*(qp(i,1)-q(i,1))
1401	tprime(i)=lv0*qprime(i)/cpd
1402	enddo
1403	c
1404	c * Calculate tendencies of lowest level potential temperature *
1405	c * and mixing ratio *
1406	c
1407	do 1200 i=1,ncum
1408	work(i)=0.01/(ph(i,1)-ph(i,2))
1409	am(i)=0.0
1410	1200 continue
1411	do 1220 k=2,nl
1412	do 1210 i=1,ncum
1413	if((nk(i).eq.1).and.(k.le.inb(i)).and.(nk(i).eq.1))then
1414	am(i)=am(i)+m(i,k)
1415	endif
1416	1210 continue
1417	1220 continue
1418	do 1240 i=1,ncum
1419	if((gwork(i)am(i)).ge.delti)iflag(i)=1
1420	ft(i,1)=ft(i,1)+gwork(i)am(i)*(t(i,2)-t(i,1)
1421	& +(gz(i,2)-gz(i,1))/cpn(i,1))
1422	ft(i,1)=ft(i,1)-lvcp(i,1)sigdevap(i,1)
1423	ft(i,1)=ft(i,1)+sigdwt(i,2)(cl-cpd)water(i,2)(t(i,2)
1424	& -t(i,1))*work(i)/cpn(i,1)
1425	fq(i,1)=fq(i,1)+gmp(i,2)(qp(i,2)-q(i,1))*
1426	& work(i)+sigd*evap(i,1)
1427	fq(i,1)=fq(i,1)+gam(i)(q(i,2)-q(i,1))*work(i)
1428	fu(i,1)=fu(i,1)+gwork(i)(mp(i,2)*(up(i,2)-u(i,1))
1429	& +am(i)*(u(i,2)-u(i,1)))
1430	fv(i,1)=fv(i,1)+gwork(i)(mp(i,2)*(vp(i,2)-v(i,1))
1431	& +am(i)*(v(i,2)-v(i,1)))
1432	1240 continue
1433	do 1260 j=2,nl
1434	do 1250 i=1,ncum
1435	if(j.le.inb(i))then
1436	fq(i,1)=fq(i,1)
1437	& +gwork(i)ment(i,j,1)*(qent(i,j,1)-q(i,1))
1438	fu(i,1)=fu(i,1)
1439	& +gwork(i)ment(i,j,1)*(uent(i,j,1)-u(i,1))
1440	fv(i,1)=fv(i,1)
1441	& +gwork(i)ment(i,j,1)*(vent(i,j,1)-v(i,1))
1442	endif
1443	1250 continue
1444	1260 continue
1445	c
1446	c * Calculate tendencies of potential temperature and mixing ratio *
1447	c * at levels above the lowest level *
1448	c
1449	c * First find the net saturated updraft and downdraft mass fluxes *
1450	c * through each level *
1451	c
1452	do 1500 i=2,nl+1
1453	c
1454	num1=0
1455	do 1265 ij=1,ncum
1456	if(i.le.inb(ij))num1=num1+1
1457	1265 continue
1458	if(num1.le.0)go to 1500
1459	c
1460	call zilch(amp1,ncum)
1461	call zilch(ad,ncum)
1462	c
1463	do 1280 k=i+1,nl+1
1464	do 1270 ij=1,ncum
1465	if((i.ge.nk(ij)).and.(i.le.inb(ij))
1466	& .and.(k.le.(inb(ij)+1)))then
1467	amp1(ij)=amp1(ij)+m(ij,k)
1468	endif
1469	1270 continue
1470	1280 continue
1471	c
1472	do 1310 k=1,i
1473	do 1300 j=i+1,nl+1
1474	do 1290 ij=1,ncum
1475	if((j.le.(inb(ij)+1)).and.(i.le.inb(ij)))then
1476	amp1(ij)=amp1(ij)+ment(ij,k,j)
1477	endif
1478	1290 continue
1479	1300 continue
1480	1310 continue
1481	do 1340 k=1,i-1
1482	do 1330 j=i,nl+1
1483	do 1320 ij=1,ncum
1484	if((i.le.inb(ij)).and.(j.le.inb(ij)))then
1485	ad(ij)=ad(ij)+ment(ij,j,k)
1486	endif
1487	1320 continue
1488	1330 continue
1489	1340 continue
1490	c
1491	do 1350 ij=1,ncum
1492	if(i.le.inb(ij))then
1493	dpinv=0.01/(ph(ij,i)-ph(ij,i+1))
1494	cpinv=1.0/cpn(ij,i)
1495	c
1496	ft(ij,i)=ft(ij,i)
1497	& +gdpinv(amp1(ij)*(t(ij,i+1)-t(ij,i)
1498	& +(gz(ij,i+1)-gz(ij,i))*cpinv)
1499	& -ad(ij)(t(ij,i)-t(ij,i-1)+(gz(ij,i)-gz(ij,i-1))cpinv))
1500	& -sigdlvcp(ij,i)evap(ij,i)
1501	ft(ij,i)=ft(ij,i)+gdpinvment(ij,i,i)*(hp(ij,i)-h(ij,i)+
1502	& t(ij,i)(cpv-cpd)(q(ij,i)-qent(ij,i,i)))*cpinv
1503	ft(ij,i)=ft(ij,i)+sigdwt(ij,i+1)(cl-cpd)water(ij,i+1)
1504	& (t(ij,i+1)-t(ij,i))dpinvcpinv
1505	fq(ij,i)=fq(ij,i)+gdpinv(amp1(ij)*(q(ij,i+1)-q(ij,i))-
1506	& ad(ij)*(q(ij,i)-q(ij,i-1)))
1507	fu(ij,i)=fu(ij,i)+gdpinv(amp1(ij)*(u(ij,i+1)-u(ij,i))-
1508	& ad(ij)*(u(ij,i)-u(ij,i-1)))
1509	fv(ij,i)=fv(ij,i)+gdpinv(amp1(ij)*(v(ij,i+1)-v(ij,i))-
1510	& ad(ij)*(v(ij,i)-v(ij,i-1)))
1511	endif
1512	1350 continue
1513	do 1370 k=1,i-1
1514	do 1360 ij=1,ncum
1515	if(i.le.inb(ij))then
1516	awat=elij(ij,k,i)-(1.-ep(ij,i))*clw(ij,i)
1517	awat=max(awat,0.0)
1518	fq(ij,i)=fq(ij,i)
1519	& +gdpinvment(ij,k,i)*(qent(ij,k,i)-awat-q(ij,i))
1520	fu(ij,i)=fu(ij,i)
1521	& +gdpinvment(ij,k,i)*(uent(ij,k,i)-u(ij,i))
1522	fv(ij,i)=fv(ij,i)
1523	& +gdpinvment(ij,k,i)*(vent(ij,k,i)-v(ij,i))
1524	c (saturated updrafts resulting from mixing) ! cld
1525	qcond(ij,i)=qcond(ij,i)+(elij(ij,k,i)-awat) ! cld
1526	nqcond(ij,i)=nqcond(ij,i)+1. ! cld
1527	endif
1528	1360 continue
1529	1370 continue
1530	do 1390 k=i,nl+1
1531	do 1380 ij=1,ncum
1532	if((i.le.inb(ij)).and.(k.le.inb(ij)))then
1533	fq(ij,i)=fq(ij,i)
1534	& +gdpinvment(ij,k,i)*(qent(ij,k,i)-q(ij,i))
1535	fu(ij,i)=fu(ij,i)
1536	& +gdpinvment(ij,k,i)*(uent(ij,k,i)-u(ij,i))
1537	fv(ij,i)=fv(ij,i)
1538	& +gdpinvment(ij,k,i)*(vent(ij,k,i)-v(ij,i))
1539	endif
1540	1380 continue
1541	1390 continue
1542	do 1400 ij=1,ncum
1543	if(i.le.inb(ij))then
1544	fq(ij,i)=fq(ij,i)
1545	& +sigdevap(ij,i)+g(mp(ij,i+1)*
1546	& (qp(ij,i+1)-q(ij,i))
1547	& -mp(ij,i)(qp(ij,i)-q(ij,i-1)))dpinv
1548	fu(ij,i)=fu(ij,i)
1549	& +g(mp(ij,i+1)(up(ij,i+1)-u(ij,i))-mp(ij,i)*
1550	& (up(ij,i)-u(ij,i-1)))*dpinv
1551	fv(ij,i)=fv(ij,i)
1552	& +g(mp(ij,i+1)(vp(ij,i+1)-v(ij,i))-mp(ij,i)*
1553	& (vp(ij,i)-v(ij,i-1)))*dpinv
1554	C (saturated downdrafts resulting from mixing) ! cld
1555	do k=i+1,inb(ij) ! cld
1556	qcond(ij,i)=qcond(ij,i)+elij(ij,k,i) ! cld
1557	nqcond(ij,i)=nqcond(ij,i)+1. ! cld
1558	enddo ! cld
1559	C (particular case: no detraining level is found) ! cld
1560	if (nent(ij,i).eq.0) then ! cld
1561	qcond(ij,i)=qcond(ij,i)+(1.-ep(ij,i))*clw(ij,i) ! cld
1562	nqcond(ij,i)=nqcond(ij,i)+1. ! cld
1563	endif ! cld
1564	if (nqcond(ij,i).ne.0.) then ! cld
1565	qcond(ij,i)=qcond(ij,i)/nqcond(ij,i) ! cld
1566	endif ! cld
1567	endif
1568	1400 continue
1569	1500 continue
1570	c
1571	c * Adjust tendencies at top of convection layer to reflect *
1572	c * actual position of the level zero cape *
1573	c
1574	do 503 ij=1,ncum
1575	fqold=fq(ij,inb(ij))
1576	fq(ij,inb(ij))=fq(ij,inb(ij))*(1.-frac(ij))
1577	fq(ij,inb(ij)-1)=fq(ij,inb(ij)-1)
1578	& +frac(ij)fqold((ph(ij,inb(ij))-ph(ij,inb(ij)+1))/
1579	1 (ph(ij,inb(ij)-1)-ph(ij,inb(ij))))*lv(ij,inb(ij))
1580	& /lv(ij,inb(ij)-1)
1581	ftold=ft(ij,inb(ij))
1582	ft(ij,inb(ij))=ft(ij,inb(ij))*(1.-frac(ij))
1583	ft(ij,inb(ij)-1)=ft(ij,inb(ij)-1)
1584	& +frac(ij)ftold((ph(ij,inb(ij))-ph(ij,inb(ij)+1))/
1585	1 (ph(ij,inb(ij)-1)-ph(ij,inb(ij))))*cpn(ij,inb(ij))
1586	& /cpn(ij,inb(ij)-1)
1587	fuold=fu(ij,inb(ij))
1588	fu(ij,inb(ij))=fu(ij,inb(ij))*(1.-frac(ij))
1589	fu(ij,inb(ij)-1)=fu(ij,inb(ij)-1)
1590	& +frac(ij)fuold((ph(ij,inb(ij))-ph(ij,inb(ij)+1))/
1591	1 (ph(ij,inb(ij)-1)-ph(ij,inb(ij))))
1592	fvold=fv(ij,inb(ij))
1593	fv(ij,inb(ij))=fv(ij,inb(ij))*(1.-frac(ij))
1594	fv(ij,inb(ij)-1)=fv(ij,inb(ij)-1)
1595	& +frac(ij)fvold((ph(ij,inb(ij))-ph(ij,inb(ij)+1))/
1596	1 (ph(ij,inb(ij)-1)-ph(ij,inb(ij))))
1597	503 continue
1598	c
1599	c * Very slightly adjust tendencies to force exact *
1600	c * enthalpy, momentum and tracer conservation *
1601	c
1602	do 682 ij=1,ncum
1603	ents(ij)=0.0
1604	uav(ij)=0.0
1605	vav(ij)=0.0
1606	do 681 i=1,inb(ij)
1607	ents(ij)=ents(ij)
1608	& +(cpn(ij,i)ft(ij,i)+lv(ij,i)fq(ij,i))*(ph(ij,i)-ph(ij,i+1))
1609	uav(ij)=uav(ij)+fu(ij,i)*(ph(ij,i)-ph(ij,i+1))
1610	vav(ij)=vav(ij)+fv(ij,i)*(ph(ij,i)-ph(ij,i+1))
1611	681 continue
1612	682 continue
1613	do 683 ij=1,ncum
1614	ents(ij)=ents(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
1615	uav(ij)=uav(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
1616	vav(ij)=vav(ij)/(ph(ij,1)-ph(ij,inb(ij)+1))
1617	683 continue
1618	do 642 ij=1,ncum
1619	do 641 i=1,inb(ij)
1620	ft(ij,i)=ft(ij,i)-ents(ij)/cpn(ij,i)
1621	fu(ij,i)=(1.-cu)*(fu(ij,i)-uav(ij))
1622	fv(ij,i)=(1.-cu)*(fv(ij,i)-vav(ij))
1623	641 continue
1624	642 continue
1625	c
1626	do 1810 k=1,nl+1
1627	do 1800 i=1,ncum
1628	if((q(i,k)+delt*fq(i,k)).lt.0.0)iflag(i)=10
1629	1800 continue
1630	1810 continue
1631	c
1632	c
1633	do 1900 i=1,ncum
1634	if(iflag(i).gt.2)then
1635	precip(i)=0.0
1636	cbmf(i)=0.0
1637	endif
1638	1900 continue
1639	do 1920 k=1,nl
1640	do 1910 i=1,ncum
1641	if(iflag(i).gt.2)then
1642	ft(i,k)=0.0
1643	fq(i,k)=0.0
1644	fu(i,k)=0.0
1645	fv(i,k)=0.0
1646	qcondc(i,k)=0.0 ! cld
1647	endif
1648	1910 continue
1649	1920 continue
1650
1651	do k=1,nl+1
1652	do i=1,ncum
1653	Ma(i,k) = 0.
1654	enddo
1655	enddo
1656	do k=nl,1,-1
1657	do i=1,ncum
1658	Ma(i,k) = Ma(i,k+1)+m(i,k)
1659	enddo
1660	enddo
1661
1662	c
1663	c * diagnose the in-cloud mixing ratio * ! cld
1664	c * of condensed water * ! cld
1665	c ! cld
1666	DO ij=1,ncum ! cld
1667	do i=1,nd ! cld
1668	mac(ij,i)=0.0 ! cld
1669	wa(ij,i)=0.0 ! cld
1670	siga(ij,i)=0.0 ! cld
1671	enddo ! cld
1672	do i=nk(ij),inb(ij) ! cld
1673	do k=i+1,inb(ij)+1 ! cld
1674	mac(ij,i)=mac(ij,i)+m(ij,k) ! cld
1675	enddo ! cld
1676	enddo ! cld
1677	do i=icb(ij),inb(ij)-1 ! cld
1678	ax(ij,i)=0. ! cld
1679	do j=icb(ij),i ! cld
1680	ax(ij,i)=ax(ij,i)+rrd*(tvp(ij,j)-tv(ij,j)) ! cld
1681	: *(ph(ij,j)-ph(ij,j+1))/p(ij,j) ! cld
1682	enddo ! cld
1683	if (ax(ij,i).gt.0.0) then ! cld
1684	wa(ij,i)=sqrt(2.*ax(ij,i)) ! cld
1685	endif ! cld
1686	enddo ! cld
1687	do i=1,nl ! cld
1688	if (wa(ij,i).gt.0.0) ! cld
1689	: siga(ij,i)=mac(ij,i)/wa(ij,i) ! cld
1690	: rrdtvp(ij,i)/p(ij,i)/100./delta ! cld
1691	siga(ij,i) = min(siga(ij,i),1.0) ! cld
1692	qcondc(ij,i)=siga(ij,i)clw(ij,i)(1.-ep(ij,i)) ! cld
1693	: + (1.-siga(ij,i))*qcond(ij,i) ! cld
1694	enddo ! cld
1695	ENDDO ! cld
1696
1697	return
1698	end
1699
1700	SUBROUTINE cv_uncompress(nloc,len,ncum,nd,idcum
1701	: ,iflag
1702	: ,precip,cbmf
1703	: ,ft,fq,fu,fv
1704	: ,Ma,qcondc
1705	: ,iflag1
1706	: ,precip1,cbmf1
1707	: ,ft1,fq1,fu1,fv1
1708	: ,Ma1,qcondc1
1709	: )
1710	implicit none
1711
1712	#include "cvparam.h"
1713
1714	c inputs:
1715	integer len, ncum, nd, nloc
1716	integer idcum(nloc)
1717	integer iflag(nloc)
1718	real precip(nloc), cbmf(nloc)
1719	real ft(nloc,nd), fq(nloc,nd), fu(nloc,nd), fv(nloc,nd)
1720	real Ma(nloc,nd)
1721	real qcondc(nloc,nd) !cld
1722
1723	c outputs:
1724	integer iflag1(len)
1725	real precip1(len), cbmf1(len)
1726	real ft1(len,nd), fq1(len,nd), fu1(len,nd), fv1(len,nd)
1727	real Ma1(len,nd)
1728	real qcondc1(len,nd) !cld
1729
1730	c local variables:
1731	integer i,k
1732
1733	do 2000 i=1,ncum
1734	precip1(idcum(i))=precip(i)
1735	cbmf1(idcum(i))=cbmf(i)
1736	iflag1(idcum(i))=iflag(i)
1737	2000 continue
1738
1739	do 2020 k=1,nl
1740	do 2010 i=1,ncum
1741	ft1(idcum(i),k)=ft(i,k)
1742	fq1(idcum(i),k)=fq(i,k)
1743	fu1(idcum(i),k)=fu(i,k)
1744	fv1(idcum(i),k)=fv(i,k)
1745	Ma1(idcum(i),k)=Ma(i,k)
1746	qcondc1(idcum(i),k)=qcondc(i,k)
1747	2010 continue
1748	2020 continue
1749
1750	return
1751	end
1752

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