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orografi.F @ 759

Last change on this file since 759 was 644, checked in by Laurent Fairhead, 19 years ago
Synchronisation avec tous les diagnostiques de Ionela IM Inclusion du slab ocean IM LF
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1	!
2	! $Header$
3	!
4	SUBROUTINE drag_noro (nlon,nlev,dtime,paprs,pplay,
5	e pmea,pstd, psig, pgam, pthe,ppic,pval,
6	e kgwd,kdx,ktest,
7	e t, u, v,
8	s pulow, pvlow, pustr, pvstr,
9	s d_t, d_u, d_v)
10	c
11	IMPLICIT none
12	c======================================================================
13	c Auteur(s): F.Lott (LMD/CNRS) date: 19950201
14	c Objet: Frottement de la montagne Interface
15	c======================================================================
16	c Arguments:
17	c dtime---input-R- pas d'integration (s)
18	c paprs---input-R-pression pour chaque inter-couche (en Pa)
19	c pplay---input-R-pression pour le mileu de chaque couche (en Pa)
20	c t-------input-R-temperature (K)
21	c u-------input-R-vitesse horizontale (m/s)
22	c v-------input-R-vitesse horizontale (m/s)
23	c
24	c d_t-----output-R-increment de la temperature
25	c d_u-----output-R-increment de la vitesse u
26	c d_v-----output-R-increment de la vitesse v
27	c======================================================================
28	#include "dimensions.h"
29	#include "dimphy.h"
30	#include "YOMCST.h"
31	c
32	c ARGUMENTS
33	c
34	INTEGER nlon,nlev
35	REAL dtime
36	REAL paprs(klon,klev+1)
37	REAL pplay(klon,klev)
38	REAL pmea(nlon),pstd(nlon),psig(nlon),pgam(nlon),pthe(nlon)
39	REAL ppic(nlon),pval(nlon)
40	REAL pulow(nlon),pvlow(nlon),pustr(nlon),pvstr(nlon)
41	REAL t(nlon,nlev), u(nlon,nlev), v(nlon,nlev)
42	REAL d_t(nlon,nlev), d_u(nlon,nlev), d_v(nlon,nlev)
43	c
44	INTEGER i, k, kgwd, kdx(nlon), ktest(nlon)
45	c
46	c Variables locales:
47	c
48	REAL zgeom(klon,klev)
49	REAL pdtdt(klon,klev), pdudt(klon,klev), pdvdt(klon,klev)
50	REAL pt(klon,klev), pu(klon,klev), pv(klon,klev)
51	REAL papmf(klon,klev),papmh(klon,klev+1)
52	c
53	c initialiser les variables de sortie (pour securite)
54	c
55	DO i = 1,klon
56	pulow(i) = 0.0
57	pvlow(i) = 0.0
58	pustr(i) = 0.0
59	pvstr(i) = 0.0
60	ENDDO
61	DO k = 1, klev
62	DO i = 1, klon
63	d_t(i,k) = 0.0
64	d_u(i,k) = 0.0
65	d_v(i,k) = 0.0
66	pdudt(i,k)=0.0
67	pdvdt(i,k)=0.0
68	pdtdt(i,k)=0.0
69	ENDDO
70	ENDDO
71	c
72	c preparer les variables d'entree (attention: l'ordre des niveaux
73	c verticaux augmente du haut vers le bas)
74	c
75	DO k = 1, klev
76	DO i = 1, klon
77	pt(i,k) = t(i,klev-k+1)
78	pu(i,k) = u(i,klev-k+1)
79	pv(i,k) = v(i,klev-k+1)
80	papmf(i,k) = pplay(i,klev-k+1)
81	ENDDO
82	ENDDO
83	DO k = 1, klev+1
84	DO i = 1, klon
85	papmh(i,k) = paprs(i,klev-k+2)
86	ENDDO
87	ENDDO
88	DO i = 1, klon
89	zgeom(i,klev) = RD * pt(i,klev)
90	. * LOG(papmh(i,klev+1)/papmf(i,klev))
91	ENDDO
92	DO k = klev-1, 1, -1
93	DO i = 1, klon
94	zgeom(i,k) = zgeom(i,k+1) + RD * (pt(i,k)+pt(i,k+1))/2.0
95	. * LOG(papmf(i,k+1)/papmf(i,k))
96	ENDDO
97	ENDDO
98	c
99	c appeler la routine principale
100	c
101	CALL orodrag(klon,klev,kgwd,kdx,ktest,
102	. dtime,
103	. papmh, papmf, zgeom,
104	. pt, pu, pv,
105	. pmea, pstd, psig, pgam, pthe, ppic,pval,
106	. pulow,pvlow,
107	. pdudt,pdvdt,pdtdt)
108	C
109	DO k = 1, klev
110	DO i = 1, klon
111	d_u(i,klev+1-k) = dtime*pdudt(i,k)
112	d_v(i,klev+1-k) = dtime*pdvdt(i,k)
113	d_t(i,klev+1-k) = dtime*pdtdt(i,k)
114	pustr(i) = pustr(i)
115	cIM BUG . +rgpdudt(i,k)(papmh(i,k+1)-papmh(i,k))
116	. +pdudt(i,k)*(papmh(i,k+1)-papmh(i,k))/RG
117	pvstr(i) = pvstr(i)
118	cIM BUG . +rgpdvdt(i,k)(papmh(i,k+1)-papmh(i,k))
119	. +pdvdt(i,k)*(papmh(i,k+1)-papmh(i,k))/RG
120	ENDDO
121	ENDDO
122	c
123	RETURN
124	END
125	SUBROUTINE orodrag( nlon,nlev
126	i , kgwd, kdx, ktest
127	r , ptsphy
128	r , paphm1,papm1,pgeom1,ptm1,pum1,pvm1
129	r , pmea, pstd, psig, pgamma, ptheta, ppic, pval
130	c outputs
131	r , pulow,pvlow
132	r , pvom,pvol,pte )
133
134	implicit none
135
136	c
137	c
138	c**** gwdrag - does the gravity wave parametrization.
139	c
140	c purpose.
141	c --------
142	c
143	c this routine computes the physical tendencies of the
144	c prognostic variables u,v and t due to vertical transports by
145	c subgridscale orographically excited gravity waves
146	c
147	c** interface.
148	c ----------
149	c called from callpar.
150	c
151	c the routine takes its input from the long-term storage:
152	c u,v,t and p at t-1.
153	c
154	c explicit arguments :
155	c --------------------
156	c ==== inputs ===
157	c ==== outputs ===
158	c
159	c implicit arguments : none
160	c --------------------
161	c
162	c implicit logical (l)
163	c
164	c method.
165	c -------
166	c
167	c externals.
168	c ----------
169	integer ismin, ismax
170	external ismin, ismax
171	c
172	c reference.
173	c ----------
174	c
175	c author.
176	c -------
177	c m.miller + b.ritter e.c.m.w.f. 15/06/86.
178	c
179	c f.lott + m. miller e.c.m.w.f. 22/11/94
180	c-----------------------------------------------------------------------
181	c
182	c
183	#include "dimensions.h"
184	#include "dimphy.h"
185	#include "YOMCST.h"
186	#include "YOEGWD.h"
187	c-----------------------------------------------------------------------
188	c
189	c* 0.1 arguments
190	c ---------
191	c
192	c
193	integer nlon, nlev, klevm1
194	integer kgwd, jl, ilevp1, jk, ji
195	real zdelp, ztemp, zforc, ztend
196	real rover, zb, zc, zconb, zabsv
197	real zzd1, ratio, zbet, zust,zvst, zdis
198	real pte(nlon,nlev),
199	* pvol(nlon,nlev),
200	* pvom(nlon,nlev),
201	* pulow(klon),
202	* pvlow(klon)
203	real pum1(nlon,nlev),
204	* pvm1(nlon,nlev),
205	* ptm1(nlon,nlev),
206	* pmea(nlon),pstd(nlon),psig(nlon),
207	* pgamma(nlon),ptheta(nlon),ppic(nlon),pval(nlon),
208	* pgeom1(nlon,nlev),
209	* papm1(nlon,nlev),
210	* paphm1(nlon,nlev+1)
211	c
212	integer kdx(nlon),ktest(nlon)
213	c-----------------------------------------------------------------------
214	c
215	c* 0.2 local arrays
216	c ------------
217	integer isect(klon),
218	* icrit(klon),
219	* ikcrith(klon),
220	* ikenvh(klon),
221	* iknu(klon),
222	* iknu2(klon),
223	* ikcrit(klon),
224	* ikhlim(klon)
225	c
226	real ztau(klon,klev+1),
227	$ ztauf(klon,klev+1),
228	* zstab(klon,klev+1),
229	* zvph(klon,klev+1),
230	* zrho(klon,klev+1),
231	* zri(klon,klev+1),
232	* zpsi(klon,klev+1),
233	* zzdep(klon,klev)
234	real zdudt(klon),
235	* zdvdt(klon),
236	* zdtdt(klon),
237	* zdedt(klon),
238	* zvidis(klon),
239	* znu(klon),
240	* zd1(klon),
241	* zd2(klon),
242	* zdmod(klon)
243	real ztmst, ptsphy, zrtmst
244	c
245	c------------------------------------------------------------------
246	c
247	c* 1. initialization
248	c --------------
249	c
250	100 continue
251	c
252	c ------------------------------------------------------------------
253	c
254	c* 1.1 computational constants
255	c -----------------------
256	c
257	110 continue
258	c
259	c ztmst=twodt
260	c if(nstep.eq.nstart) ztmst=0.5*twodt
261	klevm1=klev-1
262	ztmst=ptsphy
263	zrtmst=1./ztmst
264	c ------------------------------------------------------------------
265	c
266	120 continue
267	c
268	c ------------------------------------------------------------------
269	c
270	c* 1.3 check whether row contains point for printing
271	c ---------------------------------------------
272	c
273	130 continue
274	c
275	c ------------------------------------------------------------------
276	c
277	c* 2. precompute basic state variables.
278	c* ---------- ----- ----- ----------
279	c* define low level wind, project winds in plane of
280	c* low level wind, determine sector in which to take
281	c* the variance and set indicator for critical levels.
282	c
283	200 continue
284	c
285	c
286	c
287	call orosetup
288	* ( nlon, ktest
289	* , ikcrit, ikcrith, icrit, ikenvh,iknu,iknu2
290	* , paphm1, papm1 , pum1 , pvm1 , ptm1 , pgeom1, pstd
291	* , zrho , zri , zstab , ztau , zvph , zpsi, zzdep
292	* , pulow, pvlow
293	* , ptheta,pgamma,pmea,ppic,pval,znu ,zd1, zd2, zdmod )
294	c
295	c
296	c
297	c***********************************************************
298	c
299	c
300	c* 3. compute low level stresses using subcritical and
301	c* supercritical forms.computes anisotropy coefficient
302	c* as measure of orographic twodimensionality.
303	c
304	300 continue
305	c
306	call gwstress
307	* ( nlon , nlev
308	* , ktest , icrit, ikenvh, iknu
309	* , zrho , zstab, zvph , pstd, psig, pmea, ppic
310	* , ztau
311	* , pgeom1,zdmod)
312	c
313	c
314	c* 4. compute stress profile.
315	c* ------- ------ --------
316	c
317	400 continue
318	c
319	c
320	call gwprofil
321	* ( nlon , nlev
322	* , kgwd , kdx , ktest
323	* , ikcrith, icrit
324	* , paphm1, zrho , zstab , zvph
325	* , zri , ztau
326	* , zdmod , psig , pstd)
327	c
328	c
329	c* 5. compute tendencies.
330	c* -------------------
331	c
332	500 continue
333	c
334	c explicit solution at all levels for the gravity wave
335	c implicit solution for the blocked levels
336
337	do 510 jl=kidia,kfdia
338	zvidis(jl)=0.0
339	zdudt(jl)=0.0
340	zdvdt(jl)=0.0
341	zdtdt(jl)=0.0
342	510 continue
343	c
344	ilevp1=klev+1
345	c
346	c
347	do 524 jk=1,klev
348	c
349	c
350	c do 523 jl=1,kgwd
351	c ji=kdx(jl)
352	c Modif vectorisation 02/04/2004
353	do 523 ji=kidia,kfdia
354	if(ktest(ji).eq.1) then
355
356	zdelp=paphm1(ji,jk+1)-paphm1(ji,jk)
357	ztemp=-rg(ztau(ji,jk+1)-ztau(ji,jk))/(zvph(ji,ilevp1)zdelp)
358	zdudt(ji)=(pulow(ji)zd1(ji)-pvlow(ji)zd2(ji))*ztemp/zdmod(ji)
359	zdvdt(ji)=(pvlow(ji)zd1(ji)+pulow(ji)zd2(ji))*ztemp/zdmod(ji)
360	c
361	c controle des overshoots:
362	c
363	zforc=sqrt(zdudt(ji)2+zdvdt(ji)2)+1.E-12
364	ztend=sqrt(pum1(ji,jk)2+pvm1(ji,jk)2)/ztmst+1.E-12
365	rover=0.25
366	if(zforc.ge.rover*ztend)then
367	zdudt(ji)=roverztend/zforczdudt(ji)
368	zdvdt(ji)=roverztend/zforczdvdt(ji)
369	endif
370	c
371	c fin du controle des overshoots
372	c
373	if(jk.ge.ikenvh(ji)) then
374	zb=1.0-0.18pgamma(ji)-0.04pgamma(ji)**2
375	zc=0.48pgamma(ji)+0.3pgamma(ji)**2
376	zconb=2.ztmstgkwakepsig(ji)/(4.pstd(ji))
377	zabsv=sqrt(pum1(ji,jk)2+pvm1(ji,jk)2)/2.
378	zzd1=zbcos(zpsi(ji,jk))2+zcsin(zpsi(ji,jk))**2
379	ratio=(cos(zpsi(ji,jk))*2+pgamma(ji)sin(zpsi(ji,jk))**2)/
380	* (pgamma(ji)cos(zpsi(ji,jk))2+sin(zpsi(ji,jk))*2)
381	zbet=max(0.,2.-1./ratio)zconbzzdep(ji,jk)zzd1zabsv
382	c
383	c simplement oppose au vent
384	c
385	zdudt(ji)=-pum1(ji,jk)/ztmst
386	zdvdt(ji)=-pvm1(ji,jk)/ztmst
387	c
388	c projection dans la direction de l'axe principal de l'orographie
389	cmod zdudt(ji)=-(pum1(ji,jk)cos(ptheta(ji)rpi/180.)
390	cmod * +pvm1(ji,jk)sin(ptheta(ji)rpi/180.))
391	cmod * cos(ptheta(ji)rpi/180.)/ztmst
392	cmod zdvdt(ji)=-(pum1(ji,jk)cos(ptheta(ji)rpi/180.)
393	cmod * +pvm1(ji,jk)sin(ptheta(ji)rpi/180.))
394	cmod * sin(ptheta(ji)rpi/180.)/ztmst
395	zdudt(ji)=zdudt(ji)*(zbet/(1.+zbet))
396	zdvdt(ji)=zdvdt(ji)*(zbet/(1.+zbet))
397	end if
398	pvom(ji,jk)=zdudt(ji)
399	pvol(ji,jk)=zdvdt(ji)
400	zust=pum1(ji,jk)+ztmst*zdudt(ji)
401	zvst=pvm1(ji,jk)+ztmst*zdvdt(ji)
402	zdis=0.5(pum1(ji,jk)2+pvm1(ji,jk)2-zust2-zvst*2)
403	zdedt(ji)=zdis/ztmst
404	zvidis(ji)=zvidis(ji)+zdis*zdelp
405	zdtdt(ji)=zdedt(ji)/rcpd
406	c pte(ji,jk)=zdtdt(ji)
407	c
408	c ENCORE UN TRUC POUR EVITER LES EXPLOSIONS
409	c
410	pte(ji,jk)=0.0
411
412	endif
413	523 continue
414
415	524 continue
416	c
417	c
418	return
419	end
420	SUBROUTINE orosetup
421	* ( nlon , ktest
422	* , kkcrit, kkcrith, kcrit
423	* , kkenvh, kknu , kknu2
424	* , paphm1, papm1 , pum1 , pvm1 , ptm1 , pgeom1, pstd
425	* , prho , pri , pstab , ptau , pvph ,ppsi, pzdep
426	* , pulow , pvlow
427	* , ptheta, pgamma, pmea, ppic, pval
428	* , pnu , pd1 , pd2 ,pdmod )
429	c
430	c**** gwsetup
431	c
432	c purpose.
433	c --------
434	c
435	c** interface.
436	c ----------
437	c from orodrag
438	c
439	c explicit arguments :
440	c --------------------
441	c ==== inputs ===
442	c ==== outputs ===
443	c
444	c implicit arguments : none
445	c --------------------
446	c
447	c method.
448	c -------
449	c
450	c
451	c externals.
452	c ----------
453	c
454	c
455	c reference.
456	c ----------
457	c
458	c see ecmwf research department documentation of the "i.f.s."
459	c
460	c author.
461	c -------
462	c
463	c modifications.
464	c --------------
465	c f.lott for the new-gwdrag scheme november 1993
466	c
467	c-----------------------------------------------------------------------
468	implicit none
469	c
470
471	#include "dimensions.h"
472	#include "dimphy.h"
473	#include "YOMCST.h"
474	#include "YOEGWD.h"
475
476	c-----------------------------------------------------------------------
477	c
478	c* 0.1 arguments
479	c ---------
480	c
481	integer nlon
482	integer jl, jk
483	real zdelp
484
485	integer kkcrit(nlon),kkcrith(nlon),kcrit(nlon),
486	* ktest(nlon),kkenvh(nlon)
487
488	c
489	real paphm1(nlon,klev+1),papm1(nlon,klev),pum1(nlon,klev),
490	* pvm1(nlon,klev),ptm1(nlon,klev),pgeom1(nlon,klev),
491	* prho(nlon,klev+1),pri(nlon,klev+1),pstab(nlon,klev+1),
492	* ptau(nlon,klev+1),pvph(nlon,klev+1),ppsi(nlon,klev+1),
493	* pzdep(nlon,klev)
494	real pulow(nlon),pvlow(nlon),ptheta(nlon),pgamma(nlon),pnu(nlon),
495	* pd1(nlon),pd2(nlon),pdmod(nlon)
496	real pstd(nlon),pmea(nlon),ppic(nlon),pval(nlon)
497	c
498	c-----------------------------------------------------------------------
499	c
500	c* 0.2 local arrays
501	c ------------
502	c
503	c
504	integer ilevm1, ilevm2, ilevh
505	real zcons1, zcons2,zcons3, zhgeo
506	real zu, zphi, zvt1,zvt2, zst, zvar, zdwind, zwind
507	real zstabm, zstabp, zrhom, zrhop, alpha
508	real zggeenv, zggeom1,zgvar
509	logical lo
510	logical ll1(klon,klev+1)
511	integer kknu(klon),kknu2(klon),kknub(klon),kknul(klon),
512	* kentp(klon),ncount(klon)
513	c
514	real zhcrit(klon,klev),zvpf(klon,klev),
515	* zdp(klon,klev)
516	real znorm(klon),zb(klon),zc(klon),
517	* zulow(klon),zvlow(klon),znup(klon),znum(klon)
518	c
519	c ------------------------------------------------------------------
520	c
521	c* 1. initialization
522	c --------------
523	c
524	c print *,' entree gwsetup'
525	100 continue
526	c
527	c ------------------------------------------------------------------
528	c
529	c* 1.1 computational constants
530	c -----------------------
531	c
532	110 continue
533	c
534	ilevm1=klev-1
535	ilevm2=klev-2
536	ilevh =klev/3
537	c
538	zcons1=1./rd
539	cold zcons2=g**2/cpd
540	zcons2=rg**2/rcpd
541	cold zcons3=1.5*api
542	zcons3=1.5*rpi
543	c
544	c
545	c ------------------------------------------------------------------
546	c
547	c* 2.
548	c --------------
549	c
550	200 continue
551	c
552	c ------------------------------------------------------------------
553	c
554	c* 2.1 define low level wind, project winds in plane of
555	c* low level wind, determine sector in which to take
556	c* the variance and set indicator for critical levels.
557	c
558	c
559	c
560	do 2001 jl=kidia,kfdia
561	kknu(jl) =klev
562	kknu2(jl) =klev
563	kknub(jl) =klev
564	kknul(jl) =klev
565	pgamma(jl) =max(pgamma(jl),gtsec)
566	ll1(jl,klev+1)=.false.
567	2001 continue
568	c
569	c Ajouter une initialisation (L. Li, le 23fev99):
570	c
571	do jk=klev,ilevh,-1
572	do jl=kidia,kfdia
573	ll1(jl,jk)= .FALSE.
574	ENDDO
575	ENDDO
576	c
577	c* define top of low level flow
578	c ----------------------------
579	do 2002 jk=klev,ilevh,-1
580	do 2003 jl=kidia,kfdia
581	lo=(paphm1(jl,jk)/paphm1(jl,klev+1)).ge.gsigcr
582	if(lo) then
583	kkcrit(jl)=jk
584	endif
585	zhcrit(jl,jk)=ppic(jl)
586	zhgeo=pgeom1(jl,jk)/rg
587	ll1(jl,jk)=(zhgeo.gt.zhcrit(jl,jk))
588	if(ll1(jl,jk).xor.ll1(jl,jk+1)) then
589	kknu(jl)=jk
590	endif
591	if(.not.ll1(jl,ilevh))kknu(jl)=ilevh
592	2003 continue
593	2002 continue
594	do 2004 jk=klev,ilevh,-1
595	do 2005 jl=kidia,kfdia
596	zhcrit(jl,jk)=ppic(jl)-pval(jl)
597	zhgeo=pgeom1(jl,jk)/rg
598	ll1(jl,jk)=(zhgeo.gt.zhcrit(jl,jk))
599	if(ll1(jl,jk).xor.ll1(jl,jk+1)) then
600	kknu2(jl)=jk
601	endif
602	if(.not.ll1(jl,ilevh))kknu2(jl)=ilevh
603	2005 continue
604	2004 continue
605	do 2006 jk=klev,ilevh,-1
606	do 2007 jl=kidia,kfdia
607	zhcrit(jl,jk)=amax1(ppic(jl)-pmea(jl),pmea(jl)-pval(jl))
608	zhgeo=pgeom1(jl,jk)/rg
609	ll1(jl,jk)=(zhgeo.gt.zhcrit(jl,jk))
610	if(ll1(jl,jk).xor.ll1(jl,jk+1)) then
611	kknub(jl)=jk
612	endif
613	if(.not.ll1(jl,ilevh))kknub(jl)=ilevh
614	2007 continue
615	2006 continue
616	c
617	do 2010 jl=kidia,kfdia
618	kknu(jl)=min(kknu(jl),nktopg)
619	kknu2(jl)=min(kknu2(jl),nktopg)
620	kknub(jl)=min(kknub(jl),nktopg)
621	kknul(jl)=klev
622	2010 continue
623	c
624
625	210 continue
626	c
627	c
628	cc* initialize various arrays
629	c
630	do 2107 jl=kidia,kfdia
631	prho(jl,klev+1) =0.0
632	pstab(jl,klev+1) =0.0
633	pstab(jl,1) =0.0
634	pri(jl,klev+1) =9999.0
635	ppsi(jl,klev+1) =0.0
636	pri(jl,1) =0.0
637	pvph(jl,1) =0.0
638	pulow(jl) =0.0
639	pvlow(jl) =0.0
640	zulow(jl) =0.0
641	zvlow(jl) =0.0
642	kkcrith(jl) =klev
643	kkenvh(jl) =klev
644	kentp(jl) =klev
645	kcrit(jl) =1
646	ncount(jl) =0
647	ll1(jl,klev+1) =.false.
648	2107 continue
649	c
650	c* define low-level flow
651	c ---------------------
652	c
653	do 223 jk=klev,2,-1
654	do 222 jl=kidia,kfdia
655	if(ktest(jl).eq.1) then
656	zdp(jl,jk)=papm1(jl,jk)-papm1(jl,jk-1)
657	prho(jl,jk)=2.paphm1(jl,jk)zcons1/(ptm1(jl,jk)+ptm1(jl,jk-1))
658	pstab(jl,jk)=2.zcons2/(ptm1(jl,jk)+ptm1(jl,jk-1))
659	* (1.-rcpdprho(jl,jk)(ptm1(jl,jk)-ptm1(jl,jk-1))/zdp(jl,jk))
660	pstab(jl,jk)=max(pstab(jl,jk),gssec)
661	endif
662	222 continue
663	223 continue
664	c
665	c********************************************************************
666	c
667	c* define blocked flow
668	c -------------------
669	do 2115 jk=klev,ilevh,-1
670	do 2116 jl=kidia,kfdia
671	if(jk.ge.kknub(jl).and.jk.le.kknul(jl)) then
672	pulow(jl)=pulow(jl)+pum1(jl,jk)*(paphm1(jl,jk+1)-paphm1(jl,jk))
673	pvlow(jl)=pvlow(jl)+pvm1(jl,jk)*(paphm1(jl,jk+1)-paphm1(jl,jk))
674	end if
675	2116 continue
676	2115 continue
677	do 2110 jl=kidia,kfdia
678	pulow(jl)=pulow(jl)/(paphm1(jl,kknul(jl)+1)-paphm1(jl,kknub(jl)))
679	pvlow(jl)=pvlow(jl)/(paphm1(jl,kknul(jl)+1)-paphm1(jl,kknub(jl)))
680	znorm(jl)=max(sqrt(pulow(jl)2+pvlow(jl)2),gvsec)
681	pvph(jl,klev+1)=znorm(jl)
682	2110 continue
683	c
684	c***** setup orography axes and define plane of profiles *****
685	c
686	do 2112 jl=kidia,kfdia
687	lo=(pulow(jl).lt.gvsec).and.(pulow(jl).ge.-gvsec)
688	if(lo) then
689	zu=pulow(jl)+2.*gvsec
690	else
691	zu=pulow(jl)
692	endif
693	zphi=atan(pvlow(jl)/zu)
694	ppsi(jl,klev+1)=ptheta(jl)*rpi/180.-zphi
695	zb(jl)=1.-0.18pgamma(jl)-0.04pgamma(jl)**2
696	zc(jl)=0.48pgamma(jl)+0.3pgamma(jl)**2
697	pd1(jl)=zb(jl)-(zb(jl)-zc(jl))(sin(ppsi(jl,klev+1))*2)
698	pd2(jl)=(zb(jl)-zc(jl))sin(ppsi(jl,klev+1))cos(ppsi(jl,klev+1))
699	pdmod(jl)=sqrt(pd1(jl)2+pd2(jl)2)
700	2112 continue
701	c
702	c ********** define flow in plane of lowlevel stress ***********
703	c
704	do 213 jk=1,klev
705	do 212 jl=kidia,kfdia
706	if(ktest(jl).eq.1) then
707	zvt1 =pulow(jl)pum1(jl,jk)+pvlow(jl)pvm1(jl,jk)
708	zvt2 =-pvlow(jl)pum1(jl,jk)+pulow(jl)pvm1(jl,jk)
709	zvpf(jl,jk)=(zvt1pd1(jl)+zvt2pd2(jl))/(znorm(jl)*pdmod(jl))
710	endif
711	ptau(jl,jk) =0.0
712	pzdep(jl,jk) =0.0
713	ppsi(jl,jk) =0.0
714	ll1(jl,jk) =.false.
715	212 continue
716	213 continue
717	do 215 jk=2,klev
718	do 214 jl=kidia,kfdia
719	if(ktest(jl).eq.1) then
720	zdp(jl,jk)=papm1(jl,jk)-papm1(jl,jk-1)
721	pvph(jl,jk)=((paphm1(jl,jk)-papm1(jl,jk-1))*zvpf(jl,jk)+
722	* (papm1(jl,jk)-paphm1(jl,jk))*zvpf(jl,jk-1))
723	* /zdp(jl,jk)
724	if(pvph(jl,jk).lt.gvsec) then
725	pvph(jl,jk)=gvsec
726	kcrit(jl)=jk
727	endif
728	endif
729	214 continue
730	215 continue
731	c
732	c
733	c* 2.2 brunt-vaisala frequency and density at half levels.
734	c
735	220 continue
736	c
737	do 2211 jk=ilevh,klev
738	do 221 jl=kidia,kfdia
739	if(ktest(jl).eq.1) then
740	if(jk.ge.(kknub(jl)+1).and.jk.le.kknul(jl)) then
741	zst=zcons2/ptm1(jl,jk)(1.-rcpdprho(jl,jk)*
742	* (ptm1(jl,jk)-ptm1(jl,jk-1))/zdp(jl,jk))
743	pstab(jl,klev+1)=pstab(jl,klev+1)+zst*zdp(jl,jk)
744	pstab(jl,klev+1)=max(pstab(jl,klev+1),gssec)
745	prho(jl,klev+1)=prho(jl,klev+1)+paphm1(jl,jk)2.zdp(jl,jk)
746	* *zcons1/(ptm1(jl,jk)+ptm1(jl,jk-1))
747	endif
748	endif
749	221 continue
750	2211 continue
751	c
752	do 2212 jl=kidia,kfdia
753	pstab(jl,klev+1)=pstab(jl,klev+1)/(papm1(jl,kknul(jl))
754	* -papm1(jl,kknub(jl)))
755	prho(jl,klev+1)=prho(jl,klev+1)/(papm1(jl,kknul(jl))
756	* -papm1(jl,kknub(jl)))
757	zvar=pstd(jl)
758	2212 continue
759	c
760	c* 2.3 mean flow richardson number.
761	c* and critical height for froude layer
762	c
763	230 continue
764	c
765	do 232 jk=2,klev
766	do 231 jl=kidia,kfdia
767	if(ktest(jl).eq.1) then
768	zdwind=max(abs(zvpf(jl,jk)-zvpf(jl,jk-1)),gvsec)
769	pri(jl,jk)=pstab(jl,jk)*(zdp(jl,jk)
770	* /(rgprho(jl,jk)zdwind))**2
771	pri(jl,jk)=max(pri(jl,jk),grcrit)
772	endif
773	231 continue
774	232 continue
775
776	c
777	c
778	c* define top of 'envelope' layer
779	c ----------------------------
780
781	do 233 jl=kidia,kfdia
782	pnu (jl)=0.0
783	znum(jl)=0.0
784	233 continue
785
786	do 234 jk=2,klev-1
787	do 234 jl=kidia,kfdia
788
789	if(ktest(jl).eq.1) then
790
791	if (jk.ge.kknub(jl)) then
792
793	znum(jl)=pnu(jl)
794	zwind=(pulow(jl)pum1(jl,jk)+pvlow(jl)pvm1(jl,jk))/
795	* max(sqrt(pulow(jl)2+pvlow(jl)2),gvsec)
796	zwind=max(sqrt(zwind**2),gvsec)
797	zdelp=paphm1(jl,jk+1)-paphm1(jl,jk)
798	zstabm=sqrt(max(pstab(jl,jk ),gssec))
799	zstabp=sqrt(max(pstab(jl,jk+1),gssec))
800	zrhom=prho(jl,jk )
801	zrhop=prho(jl,jk+1)
802	pnu(jl) = pnu(jl) + (zdelp/rg)*
803	* ((zstabp/zrhop+zstabm/zrhom)/2.)/zwind
804	if((znum(jl).le.gfrcrit).and.(pnu(jl).gt.gfrcrit)
805	* .and.(kkenvh(jl).eq.klev))
806	* kkenvh(jl)=jk
807
808	endif
809
810	endif
811
812	234 continue
813
814	c calculation of a dynamical mixing height for the breaking
815	c of gravity waves:
816
817
818	do 235 jl=kidia,kfdia
819	znup(jl)=0.0
820	znum(jl)=0.0
821	235 continue
822
823	do 236 jk=klev-1,2,-1
824	do 236 jl=kidia,kfdia
825
826	if(ktest(jl).eq.1) then
827
828	znum(jl)=znup(jl)
829	zwind=(pulow(jl)pum1(jl,jk)+pvlow(jl)pvm1(jl,jk))/
830	* max(sqrt(pulow(jl)2+pvlow(jl)2),gvsec)
831	zwind=max(sqrt(zwind**2),gvsec)
832	zdelp=paphm1(jl,jk+1)-paphm1(jl,jk)
833	zstabm=sqrt(max(pstab(jl,jk ),gssec))
834	zstabp=sqrt(max(pstab(jl,jk+1),gssec))
835	zrhom=prho(jl,jk )
836	zrhop=prho(jl,jk+1)
837	znup(jl) = znup(jl) + (zdelp/rg)*
838	* ((zstabp/zrhop+zstabm/zrhom)/2.)/zwind
839	if((znum(jl).le.rpi/2.).and.(znup(jl).gt.rpi/2.)
840	* .and.(kkcrith(jl).eq.klev))
841	* kkcrith(jl)=jk
842
843	endif
844
845	236 continue
846
847	do 237 jl=kidia,kfdia
848	kkcrith(jl)=min0(kkcrith(jl),kknu2(jl))
849	kkcrith(jl)=max0(kkcrith(jl),ilevh*2)
850	237 continue
851	c
852	c directional info for flow blocking *************************
853	c
854	do 251 jk=ilevh,klev
855	do 252 jl=kidia,kfdia
856	if(jk.ge.kkenvh(jl)) then
857	lo=(pum1(jl,jk).lt.gvsec).and.(pum1(jl,jk).ge.-gvsec)
858	if(lo) then
859	zu=pum1(jl,jk)+2.*gvsec
860	else
861	zu=pum1(jl,jk)
862	endif
863	zphi=atan(pvm1(jl,jk)/zu)
864	ppsi(jl,jk)=ptheta(jl)*rpi/180.-zphi
865	end if
866	252 continue
867	251 continue
868	c forms the vertical 'leakiness' **************************
869
870	alpha=3.
871
872	do 254 jk=ilevh,klev
873	do 253 jl=kidia,kfdia
874	if(jk.ge.kkenvh(jl)) then
875	zggeenv=amax1(1.,
876	* (pgeom1(jl,kkenvh(jl))+pgeom1(jl,kkenvh(jl)-1))/2.)
877	zggeom1=amax1(pgeom1(jl,jk),1.)
878	zgvar=amax1(pstd(jl)*rg,1.)
879	cmod pzdep(jl,jk)=sqrt((zggeenv-zggeom1)/(zggeom1+zgvar))
880	pzdep(jl,jk)=(pgeom1(jl,kkenvh(jl)-1)-pgeom1(jl, jk))/
881	* (pgeom1(jl,kkenvh(jl)-1)-pgeom1(jl,klev))
882	end if
883	253 continue
884	254 continue
885
886	260 continue
887
888	return
889	end
890	SUBROUTINE gwstress
891	* ( nlon , nlev
892	* , ktest, kcrit, kkenvh
893	* , kknu
894	* , prho , pstab , pvph , pstd, psig
895	* , pmea , ppic , ptau
896	* , pgeom1 , pdmod )
897	c
898	c**** gwstress
899	c
900	c purpose.
901	c --------
902	c
903	c** interface.
904	c ----------
905	c call gwstress from gwdrag
906	c
907	c explicit arguments :
908	c --------------------
909	c ==== inputs ===
910	c ==== outputs ===
911	c
912	c implicit arguments : none
913	c --------------------
914	c
915	c method.
916	c -------
917	c
918	c
919	c externals.
920	c ----------
921	c
922	c
923	c reference.
924	c ----------
925	c
926	c see ecmwf research department documentation of the "i.f.s."
927	c
928	c author.
929	c -------
930	c
931	c modifications.
932	c --------------
933	c f. lott put the new gwd on ifs 22/11/93
934	c
935	c-----------------------------------------------------------------------
936	implicit none
937	#include "dimensions.h"
938	#include "dimphy.h"
939	#include "YOMCST.h"
940	#include "YOEGWD.h"
941
942	c-----------------------------------------------------------------------
943	c
944	c* 0.1 arguments
945	c ---------
946	c
947	integer nlon, nlev
948	integer kcrit(nlon),
949	* ktest(nlon),kkenvh(nlon),kknu(nlon)
950	c
951	real prho(nlon,nlev+1),pstab(nlon,nlev+1),ptau(nlon,nlev+1),
952	* pvph(nlon,nlev+1),
953	* pgeom1(nlon,nlev),pstd(nlon)
954	c
955	real psig(nlon)
956	real pmea(nlon),ppic(nlon)
957	real pdmod(nlon)
958	c
959	c-----------------------------------------------------------------------
960	c
961	c* 0.2 local arrays
962	c ------------
963	integer jl
964	real zblock, zvar, zeff
965	logical lo
966	c
967	c-----------------------------------------------------------------------
968	c
969	c* 0.3 functions
970	c ---------
971	c ------------------------------------------------------------------
972	c
973	c* 1. initialization
974	c --------------
975	c
976	100 continue
977	c
978	c* 3.1 gravity wave stress.
979	c
980	300 continue
981	c
982	c
983	do 301 jl=kidia,kfdia
984	if(ktest(jl).eq.1) then
985
986	c effective mountain height above the blocked flow
987
988	if(kkenvh(jl).eq.klev)then
989	zblock=0.0
990	else
991	zblock=(pgeom1(jl,kkenvh(jl))+pgeom1(jl,kkenvh(jl)+1))/2./rg
992	endif
993
994	zvar=ppic(jl)-pmea(jl)
995	zeff=amax1(0.,zvar-zblock)
996
997	ptau(jl,klev+1)=prho(jl,klev+1)gkdragpsig(jl)zeff*2
998	* /4./pstd(jl)pvph(jl,klev+1)pdmod(jl)*sqrt(pstab(jl,klev+1))
999
1000	c too small value of stress or low level flow include critical level
1001	c or low level flow: gravity wave stress nul.
1002
1003	lo=(ptau(jl,klev+1).lt.gtsec).or.(kcrit(jl).ge.kknu(jl))
1004	* .or.(pvph(jl,klev+1).lt.gvcrit)
1005	c if(lo) ptau(jl,klev+1)=0.0
1006
1007	else
1008
1009	ptau(jl,klev+1)=0.0
1010
1011	endif
1012
1013	301 continue
1014	c
1015	return
1016	end
1017	SUBROUTINE GWPROFIL
1018	* ( NLON, NLEV
1019	* , kgwd, kdx , ktest
1020	* , KKCRITH, KCRIT
1021	* , PAPHM1, PRHO , PSTAB , PVPH , PRI , PTAU
1022	* , pdmod , psig , pvar)
1023
1024	C**** GWPROFIL
1025	C
1026	C PURPOSE.
1027	C --------
1028	C
1029	C** INTERFACE.
1030	C ----------
1031	C FROM GWDRAG
1032	C
1033	C EXPLICIT ARGUMENTS :
1034	C --------------------
1035	C ==== INPUTS ===
1036	C ==== OUTPUTS ===
1037	C
1038	C IMPLICIT ARGUMENTS : NONE
1039	C --------------------
1040	C
1041	C METHOD:
1042	C -------
1043	C THE STRESS PROFILE FOR GRAVITY WAVES IS COMPUTED AS FOLLOWS:
1044	C IT IS CONSTANT (NO GWD) AT THE LEVELS BETWEEN THE GROUND
1045	C AND THE TOP OF THE BLOCKED LAYER (KKENVH).
1046	C IT DECREASES LINEARLY WITH HEIGHTS FROM THE TOP OF THE
1047	C BLOCKED LAYER TO 3*VAROR (kKNU), TO SIMULATES LEE WAVES OR
1048	C NONLINEAR GRAVITY WAVE BREAKING.
1049	C ABOVE IT IS CONSTANT, EXCEPT WHEN THE WAVE ENCOUNTERS A CRITICAL
1050	C LEVEL (KCRIT) OR WHEN IT BREAKS.
1051	C
1052	C
1053	C
1054	C EXTERNALS.
1055	C ----------
1056	C
1057	C
1058	C REFERENCE.
1059	C ----------
1060	C
1061	C SEE ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE "I.F.S."
1062	C
1063	C AUTHOR.
1064	C -------
1065	C
1066	C MODIFICATIONS.
1067	C --------------
1068	C PASSAGE OF THE NEW GWDRAG TO I.F.S. (F. LOTT, 22/11/93)
1069	C-----------------------------------------------------------------------
1070	implicit none
1071	C
1072
1073	C
1074
1075	#include "dimensions.h"
1076	#include "dimphy.h"
1077	#include "YOMCST.h"
1078	#include "YOEGWD.h"
1079
1080	C-----------------------------------------------------------------------
1081	C
1082	C* 0.1 ARGUMENTS
1083	C ---------
1084	C
1085	integer nlon,nlev
1086	INTEGER KKCRITH(NLON),KCRIT(NLON)
1087	* ,kdx(nlon) , ktest(nlon)
1088
1089	C
1090	REAL PAPHM1(NLON,NLEV+1), PSTAB(NLON,NLEV+1),
1091	* PRHO (NLON,NLEV+1), PVPH (NLON,NLEV+1),
1092	* PRI (NLON,NLEV+1), PTAU(NLON,NLEV+1)
1093
1094	REAL pdmod (NLON) , psig(NLON),
1095	* pvar(NLON)
1096
1097	C-----------------------------------------------------------------------
1098	C
1099	C* 0.2 LOCAL ARRAYS
1100	C ------------
1101	C
1102	integer ilevh, ji, kgwd, jl, jk
1103	real zsqr, zalfa, zriw, zdel, zb, zalpha,zdz2n
1104	real zdelp, zdelpt
1105	REAL ZDZ2 (KLON,KLEV) , ZNORM(KLON) , zoro(KLON)
1106	REAL ZTAU (KLON,KLEV+1)
1107	C
1108	C-----------------------------------------------------------------------
1109	C
1110	C* 1. INITIALIZATION
1111	C --------------
1112	C
1113	c print *,' entree gwprofil'
1114	100 CONTINUE
1115	C
1116	C
1117	C* COMPUTATIONAL CONSTANTS.
1118	C ------------- ----------
1119	C
1120	ilevh=KLEV/3
1121	C
1122	c DO 400 ji=1,kgwd
1123	c jl=kdx(ji)
1124	c Modif vectorisation 02/04/2004
1125	DO 400 jl=kidia,kfdia
1126	if (ktest(jl).eq.1) then
1127	Zoro(JL)=Psig(JL)*Pdmod(JL)/4./max(pvar(jl),1.0)
1128	ZTAU(JL,KLEV+1)=PTAU(JL,KLEV+1)
1129	endif
1130	400 CONTINUE
1131
1132	C
1133	DO 430 JK=KLEV,2,-1
1134	C
1135	C
1136	C* 4.1 CONSTANT WAVE STRESS UNTIL TOP OF THE
1137	C BLOCKING LAYER.
1138	410 CONTINUE
1139	C
1140	c DO 411 ji=1,kgwd
1141	c jl=kdx(ji)
1142	c Modif vectorisation 02/04/2004
1143	do 411 jl=kidia,kfdia
1144	if (ktest(jl).eq.1) then
1145	IF(JK.GT.KKCRITH(JL)) THEN
1146	PTAU(JL,JK)=ZTAU(JL,KLEV+1)
1147	C ENDIF
1148	C IF(JK.EQ.KKCRITH(JL)) THEN
1149	ELSE
1150	PTAU(JL,JK)=GRAHILO*ZTAU(JL,KLEV+1)
1151	ENDIF
1152	endif
1153	411 CONTINUE
1154	C
1155	C* 4.15 CONSTANT SHEAR STRESS UNTIL THE TOP OF THE
1156	C LOW LEVEL FLOW LAYER.
1157	415 CONTINUE
1158	C
1159	C
1160	C* 4.2 WAVE DISPLACEMENT AT NEXT LEVEL.
1161	C
1162	420 CONTINUE
1163	C
1164	c DO 421 ji=1,kgwd
1165	c jl=kdx(ji)
1166	c Modif vectorisation 02/04/2004
1167	do 421 jl=kidia,kfdia
1168	if(ktest(jl).eq.1) then
1169	IF(JK.LT.KKCRITH(JL)) THEN
1170	ZNORM(JL)=gkdragPRHO(JL,JK)SQRT(PSTAB(JL,JK))*PVPH(JL,JK)
1171	* *zoro(jl)
1172	ZDZ2(JL,JK)=PTAU(JL,JK+1)/max(ZNORM(JL),gssec)
1173	ENDIF
1174	endif
1175	421 CONTINUE
1176	C
1177	C* 4.3 WAVE RICHARDSON NUMBER, NEW WAVE DISPLACEMENT
1178	C* AND STRESS: BREAKING EVALUATION AND CRITICAL
1179	C LEVEL
1180	C
1181
1182	c DO 431 ji=1,kgwd
1183	c jl=Kdx(ji)
1184	c Modif vectorisation 02/04/2004
1185	do 431 jl=kidia,kfdia
1186	if(ktest(jl).eq.1) then
1187
1188	IF(JK.LT.KKCRITH(JL)) THEN
1189	IF((PTAU(JL,JK+1).LT.GTSEC).OR.(JK.LE.KCRIT(JL))) THEN
1190	PTAU(JL,JK)=0.0
1191	ELSE
1192	ZSQR=SQRT(PRI(JL,JK))
1193	ZALFA=SQRT(PSTAB(JL,JK)*ZDZ2(JL,JK))/PVPH(JL,JK)
1194	ZRIW=PRI(JL,JK)(1.-ZALFA)/(1+ZALFAZSQR)**2
1195	IF(ZRIW.LT.GRCRIT) THEN
1196	ZDEL=4./ZSQR/GRCRIT+1./GRCRIT**2+4./GRCRIT
1197	ZB=1./GRCRIT+2./ZSQR
1198	ZALPHA=0.5*(-ZB+SQRT(ZDEL))
1199	ZDZ2N=(PVPH(JL,JK)ZALPHA)*2/PSTAB(JL,JK)
1200	PTAU(JL,JK)=ZNORM(JL)*ZDZ2N
1201	ELSE
1202	PTAU(JL,JK)=ZNORM(JL)*ZDZ2(JL,JK)
1203	ENDIF
1204	PTAU(JL,JK)=MIN(PTAU(JL,JK),PTAU(JL,JK+1))
1205	ENDIF
1206	ENDIF
1207	endif
1208	431 CONTINUE
1209
1210	430 CONTINUE
1211	440 CONTINUE
1212
1213	C REORGANISATION OF THE STRESS PROFILE AT LOW LEVEL
1214
1215	c DO 530 ji=1,kgwd
1216	c jl=kdx(ji)
1217	c Modif vectorisation 02/04/2004
1218	do 530 jl=kidia,kfdia
1219	if(ktest(jl).eq.1) then
1220	ZTAU(JL,KKCRITH(JL))=PTAU(JL,KKCRITH(JL))
1221	ZTAU(JL,NSTRA)=PTAU(JL,NSTRA)
1222	endif
1223	530 CONTINUE
1224
1225	DO 531 JK=1,KLEV
1226
1227	c DO 532 ji=1,kgwd
1228	c jl=kdx(ji)
1229	c Modif vectorisation 02/04/2004
1230	do 532 jl=kidia,kfdia
1231	if(ktest(jl).eq.1) then
1232
1233
1234	IF(JK.GT.KKCRITH(JL))THEN
1235
1236	ZDELP=PAPHM1(JL,JK)-PAPHM1(JL,KLEV+1 )
1237	ZDELPT=PAPHM1(JL,KKCRITH(JL))-PAPHM1(JL,KLEV+1 )
1238	PTAU(JL,JK)=ZTAU(JL,KLEV+1 ) +
1239	. (ZTAU(JL,KKCRITH(JL))-ZTAU(JL,KLEV+1 ) )*
1240	. ZDELP/ZDELPT
1241
1242	ENDIF
1243
1244	endif
1245	532 CONTINUE
1246
1247	C REORGANISATION IN THE STRATOSPHERE
1248
1249	c DO 533 ji=1,kgwd
1250	c jl=kdx(ji)
1251	c Modif vectorisation 02/04/2004
1252	do 533 jl=kidia,kfdia
1253	if(ktest(jl).eq.1) then
1254
1255
1256	IF(JK.LT.NSTRA)THEN
1257
1258	ZDELP =PAPHM1(JL,NSTRA)
1259	ZDELPT=PAPHM1(JL,JK)
1260	PTAU(JL,JK)=ZTAU(JL,NSTRA)*ZDELPT/ZDELP
1261
1262	ENDIF
1263
1264	endif
1265	533 CONTINUE
1266
1267	C REORGANISATION IN THE TROPOSPHERE
1268
1269	c DO 534 ji=1,kgwd
1270	c jl=kdx(ji)
1271	c Modif vectorisation 02/04/2004
1272	do 534 jl=kidia,kfdia
1273	if(ktest(jl).eq.1) then
1274
1275
1276	IF(JK.LT.KKCRITH(JL).AND.JK.GT.NSTRA)THEN
1277
1278	ZDELP=PAPHM1(JL,JK)-PAPHM1(JL,KKCRITH(JL))
1279	ZDELPT=PAPHM1(JL,NSTRA)-PAPHM1(JL,KKCRITH(JL))
1280	PTAU(JL,JK)=ZTAU(JL,KKCRITH(JL)) +
1281	* (ZTAU(JL,NSTRA)-ZTAU(JL,KKCRITH(JL)))*ZDELP
1282	. /ZDELPT
1283
1284	ENDIF
1285	endif
1286	534 CONTINUE
1287
1288
1289	531 CONTINUE
1290
1291
1292	RETURN
1293	END
1294	SUBROUTINE lift_noro (nlon,nlev,dtime,paprs,pplay,
1295	e plat,pmea,pstd, ppic,
1296	e ktest,
1297	e t, u, v,
1298	s pulow, pvlow, pustr, pvstr,
1299	s d_t, d_u, d_v)
1300	c
1301	IMPLICIT none
1302	c======================================================================
1303	c Auteur(s): F.Lott (LMD/CNRS) date: 19950201
1304	c Objet: Frottement de la montagne Interface
1305	c======================================================================
1306	c Arguments:
1307	c dtime---input-R- pas d'integration (s)
1308	c paprs---input-R-pression pour chaque inter-couche (en Pa)
1309	c pplay---input-R-pression pour le mileu de chaque couche (en Pa)
1310	c t-------input-R-temperature (K)
1311	c u-------input-R-vitesse horizontale (m/s)
1312	c v-------input-R-vitesse horizontale (m/s)
1313	c
1314	c d_t-----output-R-increment de la temperature
1315	c d_u-----output-R-increment de la vitesse u
1316	c d_v-----output-R-increment de la vitesse v
1317	c======================================================================
1318	#include "dimensions.h"
1319	#include "dimphy.h"
1320	#include "YOMCST.h"
1321	c
1322	c ARGUMENTS
1323	c
1324	INTEGER nlon,nlev
1325	REAL dtime
1326	REAL paprs(klon,klev+1)
1327	REAL pplay(klon,klev)
1328	REAL plat(nlon),pmea(nlon)
1329	REAL pstd(nlon)
1330	REAL ppic(nlon)
1331	REAL pulow(nlon),pvlow(nlon),pustr(nlon),pvstr(nlon)
1332	REAL t(nlon,nlev), u(nlon,nlev), v(nlon,nlev)
1333	REAL d_t(nlon,nlev), d_u(nlon,nlev), d_v(nlon,nlev)
1334	c
1335	INTEGER i, k, ktest(nlon)
1336	c
1337	c Variables locales:
1338	c
1339	REAL zgeom(klon,klev)
1340	REAL pdtdt(klon,klev), pdudt(klon,klev), pdvdt(klon,klev)
1341	REAL pt(klon,klev), pu(klon,klev), pv(klon,klev)
1342	REAL papmf(klon,klev),papmh(klon,klev+1)
1343	c
1344	c initialiser les variables de sortie (pour securite)
1345	c
1346	DO i = 1,klon
1347	pulow(i) = 0.0
1348	pvlow(i) = 0.0
1349	pustr(i) = 0.0
1350	pvstr(i) = 0.0
1351	ENDDO
1352	DO k = 1, klev
1353	DO i = 1, klon
1354	d_t(i,k) = 0.0
1355	d_u(i,k) = 0.0
1356	d_v(i,k) = 0.0
1357	pdudt(i,k)=0.0
1358	pdvdt(i,k)=0.0
1359	pdtdt(i,k)=0.0
1360	ENDDO
1361	ENDDO
1362	c
1363	c preparer les variables d'entree (attention: l'ordre des niveaux
1364	c verticaux augmente du haut vers le bas)
1365	c
1366	DO k = 1, klev
1367	DO i = 1, klon
1368	pt(i,k) = t(i,klev-k+1)
1369	pu(i,k) = u(i,klev-k+1)
1370	pv(i,k) = v(i,klev-k+1)
1371	papmf(i,k) = pplay(i,klev-k+1)
1372	ENDDO
1373	ENDDO
1374	DO k = 1, klev+1
1375	DO i = 1, klon
1376	papmh(i,k) = paprs(i,klev-k+2)
1377	ENDDO
1378	ENDDO
1379	DO i = 1, klon
1380	zgeom(i,klev) = RD * pt(i,klev)
1381	. * LOG(papmh(i,klev+1)/papmf(i,klev))
1382	ENDDO
1383	DO k = klev-1, 1, -1
1384	DO i = 1, klon
1385	zgeom(i,k) = zgeom(i,k+1) + RD * (pt(i,k)+pt(i,k+1))/2.0
1386	. * LOG(papmf(i,k+1)/papmf(i,k))
1387	ENDDO
1388	ENDDO
1389	c
1390	c appeler la routine principale
1391	c
1392	CALL OROLIFT(klon,klev,ktest,
1393	. dtime,
1394	. papmh, zgeom,
1395	. pt, pu, pv,
1396	. plat,pmea, pstd, ppic,
1397	. pulow,pvlow,
1398	. pdudt,pdvdt,pdtdt)
1399	C
1400	DO k = 1, klev
1401	DO i = 1, klon
1402	d_u(i,klev+1-k) = dtime*pdudt(i,k)
1403	d_v(i,klev+1-k) = dtime*pdvdt(i,k)
1404	d_t(i,klev+1-k) = dtime*pdtdt(i,k)
1405	pustr(i) = pustr(i)
1406	cIM BUG . +RGpdudt(i,k)(papmh(i,k+1)-papmh(i,k))
1407	. +pdudt(i,k)*(papmh(i,k+1)-papmh(i,k))/RG
1408	pvstr(i) = pvstr(i)
1409	cIM BUG . +RGpdvdt(i,k)(papmh(i,k+1)-papmh(i,k))
1410	. +pdvdt(i,k)*(papmh(i,k+1)-papmh(i,k))/RG
1411	ENDDO
1412	ENDDO
1413	c
1414	RETURN
1415	END
1416	SUBROUTINE OROLIFT( NLON,NLEV
1417	I , KTEST
1418	R , PTSPHY
1419	R , PAPHM1,PGEOM1,PTM1,PUM1,PVM1
1420	R , PLAT
1421	R , PMEA, PVAROR, ppic
1422	C OUTPUTS
1423	R , PULOW,PVLOW
1424	R , PVOM,PVOL,PTE )
1425
1426	C
1427	C**** *OROLIFT: SIMULATE THE GEOSTROPHIC LIFT.
1428	C
1429	C PURPOSE.
1430	C --------
1431	C
1432	C** INTERFACE.
1433	C ----------
1434	C CALLED FROM *lift_noro
1435	C ----------
1436	C
1437	C AUTHOR.
1438	C -------
1439	C F.LOTT LMD 22/11/95
1440	C
1441	implicit none
1442	C
1443	C
1444	#include "dimensions.h"
1445	#include "dimphy.h"
1446	#include "YOMCST.h"
1447	#include "YOEGWD.h"
1448	C-----------------------------------------------------------------------
1449	C
1450	C* 0.1 ARGUMENTS
1451	C ---------
1452	C
1453	C
1454	integer nlon, nlev
1455	REAL PTE(NLON,NLEV),
1456	* PVOL(NLON,NLEV),
1457	* PVOM(NLON,NLEV),
1458	* PULOW(NLON),
1459	* PVLOW(NLON)
1460	REAL PUM1(NLON,NLEV),
1461	* PVM1(NLON,NLEV),
1462	* PTM1(NLON,NLEV),
1463	* PLAT(NLON),PMEA(NLON),
1464	* PVAROR(NLON),
1465	* ppic(NLON),
1466	* PGEOM1(NLON,NLEV),
1467	* PAPHM1(NLON,NLEV+1)
1468	C
1469	INTEGER KTEST(NLON)
1470	real ptsphy
1471	C-----------------------------------------------------------------------
1472	C
1473	C* 0.2 LOCAL ARRAYS
1474	C ------------
1475	logical lifthigh, ll1
1476	integer klevm1, jl, ilevh, jk
1477	real zcons1, ztmst, zrtmst,zpi, zhgeo
1478	real zdelp, zslow, zsqua, zscav, zbet
1479	INTEGER
1480	* IKNUB(klon),
1481	* IKNUL(klon)
1482	LOGICAL LL1(KLON,KLEV+1)
1483	C
1484	REAL ZTAU(KLON,KLEV+1),
1485	* ZTAV(KLON,KLEV+1),
1486	* ZRHO(KLON,KLEV+1)
1487	REAL ZDUDT(KLON),
1488	* ZDVDT(KLON)
1489	REAL ZHCRIT(KLON,KLEV)
1490	C-----------------------------------------------------------------------
1491	C
1492	C* 1.1 INITIALIZATIONS
1493	C ---------------
1494
1495	LIFTHIGH=.FALSE.
1496
1497	IF(NLON.NE.KLON.OR.NLEV.NE.KLEV)STOP
1498	ZCONS1=1./RD
1499	KLEVM1=KLEV-1
1500	ZTMST=PTSPHY
1501	ZRTMST=1./ZTMST
1502	ZPI=ACOS(-1.)
1503	C
1504	DO 1001 JL=kidia,kfdia
1505	ZRHO(JL,KLEV+1) =0.0
1506	PULOW(JL) =0.0
1507	PVLOW(JL) =0.0
1508	iknub(JL) =klev
1509	iknul(JL) =klev
1510	ilevh=klev/3
1511	ll1(jl,klev+1)=.false.
1512	DO 1000 JK=1,KLEV
1513	PVOM(JL,JK)=0.0
1514	PVOL(JL,JK)=0.0
1515	PTE (JL,JK)=0.0
1516	1000 CONTINUE
1517	1001 CONTINUE
1518
1519	C
1520	C* 2.1 DEFINE LOW LEVEL WIND, PROJECT WINDS IN PLANE OF
1521	C* LOW LEVEL WIND, DETERMINE SECTOR IN WHICH TO TAKE
1522	C* THE VARIANCE AND SET INDICATOR FOR CRITICAL LEVELS.
1523	C
1524	C
1525	C
1526	DO 2006 JK=KLEV,1,-1
1527	DO 2007 JL=kidia,kfdia
1528	IF(KTEST(JL).EQ.1) THEN
1529	ZHCRIT(JL,JK)=amax1(Ppic(JL)-pmea(JL),100.)
1530	ZHGEO=PGEOM1(JL,JK)/RG
1531	ll1(JL,JK)=(ZHGEO.GT.ZHCRIT(JL,JK))
1532	IF(ll1(JL,JK).XOR.ll1(JL,JK+1)) THEN
1533	iknub(JL)=JK
1534	ENDIF
1535	ENDIF
1536	2007 CONTINUE
1537	2006 CONTINUE
1538	C
1539	do 2010 jl=kidia,kfdia
1540	IF(KTEST(JL).EQ.1) THEN
1541	iknub(jl)=max(iknub(jl),klev/2)
1542	iknul(jl)=max(iknul(jl),2*klev/3)
1543	if(iknub(jl).gt.nktopg) iknub(jl)=nktopg
1544	if(iknub(jl).eq.nktopg) iknul(jl)=klev
1545	if(iknub(jl).eq.iknul(jl)) iknub(jl)=iknul(jl)-1
1546	ENDIF
1547	2010 continue
1548
1549	C do 2011 jl=kidia,kfdia
1550	C IF(KTEST(JL).EQ.1) THEN
1551	C print *,' iknul= ',iknul(jl),' iknub=',iknub(jl)
1552	C ENDIF
1553	C2011 continue
1554
1555	C PRINT *,' DANS OROLIFT: 2010'
1556
1557	DO 223 JK=KLEV,2,-1
1558	DO 222 JL=kidia,kfdia
1559	ZRHO(JL,JK)=2.PAPHM1(JL,JK)ZCONS1/(PTM1(JL,JK)+PTM1(JL,JK-1))
1560	222 CONTINUE
1561	223 CONTINUE
1562	C PRINT *,' DANS OROLIFT: 223'
1563
1564	C********************************************************************
1565	C
1566	C* DEFINE LOW LEVEL FLOW
1567	C -------------------
1568	DO 2115 JK=klev,1,-1
1569	DO 2116 JL=kidia,kfdia
1570	IF(KTEST(JL).EQ.1) THEN
1571	if(jk.ge.iknub(jl).and.jk.le.iknul(jl)) then
1572	pulow(JL)=pulow(JL)+PUM1(JL,JK)*(PAPHM1(JL,JK+1)-PAPHM1(JL,JK))
1573	pvlow(JL)=pvlow(JL)+PVM1(JL,JK)*(PAPHM1(JL,JK+1)-PAPHM1(JL,JK))
1574	zrho(JL,klev+1)=zrho(JL,klev+1)
1575	* +zrho(JL,JK)*(PAPHM1(JL,JK+1)-PAPHM1(JL,JK))
1576	end if
1577	ENDIF
1578	2116 CONTINUE
1579	2115 CONTINUE
1580	DO 2110 JL=kidia,kfdia
1581	IF(KTEST(JL).EQ.1) THEN
1582	pulow(JL)=pulow(JL)/(PAPHM1(JL,iknul(jl)+1)-PAPHM1(JL,iknub(jl)))
1583	pvlow(JL)=pvlow(JL)/(PAPHM1(JL,iknul(jl)+1)-PAPHM1(JL,iknub(jl)))
1584	zrho(JL,klev+1)=zrho(JL,klev+1)
1585	* /(PAPHM1(JL,iknul(jl)+1)-PAPHM1(JL,iknub(jl)))
1586	ENDIF
1587	2110 CONTINUE
1588
1589
1590	200 CONTINUE
1591
1592	C***********************************************************
1593	C
1594	C* 3. COMPUTE MOUNTAIN LIFT
1595	C
1596	300 CONTINUE
1597	C
1598	DO 301 JL=kidia,kfdia
1599	IF(KTEST(JL).EQ.1) THEN
1600	ZTAU(JL,KLEV+1)= - GKLIFTZRHO(JL,KLEV+1)2.ROMEGA
1601	C * (2PVAROR(JL)+PMEA(JL))
1602	* 2PVAROR(JL)
1603	* SIN(ZPI/180.PLAT(JL))PVLOW(JL)
1604	ZTAV(JL,KLEV+1)= GKLIFTZRHO(JL,KLEV+1)2.ROMEGA
1605	C * (2PVAROR(JL)+PMEA(JL))
1606	* 2PVAROR(JL)
1607	* SIN(ZPI/180.PLAT(JL))PULOW(JL)
1608	ELSE
1609	ZTAU(JL,KLEV+1)=0.0
1610	ZTAV(JL,KLEV+1)=0.0
1611	ENDIF
1612	301 CONTINUE
1613
1614	C
1615	C* 4. COMPUTE LIFT PROFILE
1616	C* --------------------
1617	C
1618
1619	400 CONTINUE
1620
1621	DO 401 JK=1,KLEV
1622	DO 401 JL=kidia,kfdia
1623	IF(KTEST(JL).EQ.1) THEN
1624	ZTAU(JL,JK)=ZTAU(JL,KLEV+1)*PAPHM1(JL,JK)/PAPHM1(JL,KLEV+1)
1625	ZTAV(JL,JK)=ZTAV(JL,KLEV+1)*PAPHM1(JL,JK)/PAPHM1(JL,KLEV+1)
1626	ELSE
1627	ZTAU(JL,JK)=0.0
1628	ZTAV(JL,JK)=0.0
1629	ENDIF
1630	401 CONTINUE
1631	C
1632	C
1633	C* 5. COMPUTE TENDENCIES.
1634	C* -------------------
1635	IF(LIFTHIGH)THEN
1636	C
1637	500 CONTINUE
1638	C PRINT *,' DANS OROLIFT: 500'
1639	C
1640	C EXPLICIT SOLUTION AT ALL LEVELS
1641	C
1642	DO 524 JK=1,klev
1643	DO 523 JL=KIDIA,KFDIA
1644	IF(KTEST(JL).EQ.1) THEN
1645	ZDELP=PAPHM1(JL,JK+1)-PAPHM1(JL,JK)
1646	ZDUDT(JL)=-RG*(ZTAU(JL,JK+1)-ZTAU(JL,JK))/ZDELP
1647	ZDVDT(JL)=-RG*(ZTAV(JL,JK+1)-ZTAV(JL,JK))/ZDELP
1648	ENDIF
1649	523 CONTINUE
1650	524 CONTINUE
1651	C
1652	C PROJECT PERPENDICULARLY TO U NOT TO DESTROY ENERGY
1653	C
1654	DO 530 JK=1,klev
1655	DO 530 JL=KIDIA,KFDIA
1656	IF(KTEST(JL).EQ.1) THEN
1657
1658	ZSLOW=SQRT(PULOW(JL)2+PVLOW(JL)2)
1659	ZSQUA=AMAX1(SQRT(PUM1(JL,JK)2+PVM1(JL,JK)2),GVSEC)
1660	ZSCAV=-ZDUDT(JL)PVM1(JL,JK)+ZDVDT(JL)PUM1(JL,JK)
1661	IF(ZSQUA.GT.GVSEC)THEN
1662	PVOM(JL,JK)=-ZSCAVPVM1(JL,JK)/ZSQUA*2
1663	PVOL(JL,JK)= ZSCAVPUM1(JL,JK)/ZSQUA*2
1664	ELSE
1665	PVOM(JL,JK)=0.0
1666	PVOL(JL,JK)=0.0
1667	ENDIF
1668	ZSQUA=SQRT(PUM1(JL,JK)2+PUM1(JL,JK)2)
1669	IF(ZSQUA.LT.ZSLOW)THEN
1670	PVOM(JL,JK)=ZSQUA/ZSLOW*PVOM(JL,JK)
1671	PVOL(JL,JK)=ZSQUA/ZSLOW*PVOL(JL,JK)
1672	ENDIF
1673
1674	ENDIF
1675	530 CONTINUE
1676	C
1677	C 6. LOW LEVEL LIFT, SEMI IMPLICIT:
1678	C ----------------------------------
1679
1680	ELSE
1681
1682	DO 601 JL=KIDIA,KFDIA
1683	IF(KTEST(JL).EQ.1) THEN
1684	DO JK=KLEV,IKNUB(JL),-1
1685	ZBET=GKLIFT2.ROMEGASIN(ZPI/180.PLAT(JL))ztmst
1686	* (PGEOM1(JL,IKNUB(JL)-1)-PGEOM1(JL, JK))/
1687	* (PGEOM1(JL,IKNUB(JL)-1)-PGEOM1(JL,KLEV))
1688	ZDUDT(JL)=-PUM1(JL,JK)/ztmst/(1+ZBET**2)
1689	ZDVDT(JL)=-PVM1(JL,JK)/ztmst/(1+ZBET**2)
1690	PVOM(JL,JK)= ZBET*2ZDUDT(JL) - ZBET *ZDVDT(JL)
1691	PVOL(JL,JK)= ZBET ZDUDT(JL) + ZBET2ZDVDT(JL)
1692	ENDDO
1693	ENDIF
1694	601 CONTINUE
1695
1696	ENDIF
1697
1698	RETURN
1699	END
1700	SUBROUTINE SUGWD(NLON,NLEV,paprs,pplay)
1701	C
1702	C**** SUGWD INITIALIZE COMMON YOEGWD CONTROLLING GRAVITY WAVE DRAG
1703	C
1704	C PURPOSE.
1705	C --------
1706	C INITIALIZE YOEGWD, THE COMMON THAT CONTROLS THE
1707	C GRAVITY WAVE DRAG PARAMETRIZATION.
1708	C
1709	C** INTERFACE.
1710	C ----------
1711	C CALL SUGWD FROM SUPHEC
1712	C ----- ------
1713	C
1714	C EXPLICIT ARGUMENTS :
1715	C --------------------
1716	C PSIG : VERTICAL COORDINATE TABLE
1717	C NLEV : NUMBER OF MODEL LEVELS
1718	C
1719	C IMPLICIT ARGUMENTS :
1720	C --------------------
1721	C COMMON YOEGWD
1722	C
1723	C METHOD.
1724	C -------
1725	C SEE DOCUMENTATION
1726	C
1727	C EXTERNALS.
1728	C ----------
1729	C NONE
1730	C
1731	C REFERENCE.
1732	C ----------
1733	C ECMWF Research Department documentation of the IFS
1734	C
1735	C AUTHOR.
1736	C -------
1737	C MARTIN MILLER ECMWF
1738	C
1739	C MODIFICATIONS.
1740	C --------------
1741	C ORIGINAL : 90-01-01
1742	C ------------------------------------------------------------------
1743	implicit none
1744	C
1745	C -----------------------------------------------------------------
1746	#include "YOEGWD.h"
1747	C ----------------------------------------------------------------
1748	C
1749	integer nlon,nlev, jk
1750	REAL paprs(nlon,nlev+1)
1751	REAL pplay(nlon,nlev)
1752	real zpr,zstra,zsigt,zpm1r
1753	C
1754	C* 1. SET THE VALUES OF THE PARAMETERS
1755	C --------------------------------
1756	C
1757	100 CONTINUE
1758	C
1759	PRINT *,' DANS SUGWD NLEV=',NLEV
1760	GHMAX=10000.
1761	C
1762	ZPR=100000.
1763	ZSTRA=0.1
1764	ZSIGT=0.94
1765	cold ZPR=80000.
1766	cold ZSIGT=0.85
1767	C
1768	DO 110 JK=1,NLEV
1769	ZPM1R=pplay(nlon/2,jk)/paprs(nlon/2,1)
1770	IF(ZPM1R.GE.ZSIGT)THEN
1771	nktopg=JK
1772	ENDIF
1773	ZPM1R=pplay(nlon/2,jk)/paprs(nlon/2,1)
1774	IF(ZPM1R.GE.ZSTRA)THEN
1775	NSTRA=JK
1776	ENDIF
1777	110 CONTINUE
1778	c
1779	c inversion car dans orodrag on compte les niveaux a l'envers
1780	nktopg=nlev-nktopg+1
1781	nstra=nlev-nstra
1782	print *,' DANS SUGWD nktopg=', nktopg
1783	print *,' DANS SUGWD nstra=', nstra
1784	C
1785	GSIGCR=0.80
1786	C
1787	GKDRAG=0.2
1788	GRAHILO=1.
1789	GRCRIT=0.01
1790	GFRCRIT=1.0
1791	GKWAKE=0.50
1792	C
1793	GKLIFT=0.50
1794	GVCRIT =0.0
1795	C
1796	C
1797	C ----------------------------------------------------------------
1798	C
1799	C* 2. SET VALUES OF SECURITY PARAMETERS
1800	C ---------------------------------
1801	C
1802	200 CONTINUE
1803	C
1804	GVSEC=0.10
1805	GSSEC=1.E-12
1806	C
1807	GTSEC=1.E-07
1808	C
1809	C ----------------------------------------------------------------
1810	C
1811	RETURN
1812	END

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