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pentes_ini.F @ 5081

Last change on this file since 5081 was 2600, checked in by Ehouarn Millour, 8 years ago
Cleanup in the dynamics: turn comvert.h into module comvert_mod.F90 EM
Property copyright set to Name of program: LMDZ Creation date: 1984 Version: LMDZ5 License: CeCILL version 2 Holder: Laboratoire de m\'et\'eorologie dynamique, CNRS, UMR 8539 See the license file in the root directory Property svn:eol-style set to `native` Property svn:keywords set to `Author Date Id Revision`
File size: 13.5 KB

Rev	Line
[524]	1	!
	2	! $Header$
	3	!
	4	SUBROUTINE pentes_ini (q,w,masse,pbaru,pbarv,mode)
[2597]	5
	6	USE comconst_mod, ONLY: pi, dtvr
	7
[524]	8	IMPLICIT NONE
	9
	10	c=======================================================================
	11	c Adaptation LMDZ: A.Armengaud (LGGE)
	12	c ----------------
	13	c
	14	c ********************************************************************
	15	c Transport des traceurs par la methode des pentes
	16	c ********************************************************************
	17	c Reference possible : Russel. G.L., Lerner J.A.:
	18	c A new Finite-Differencing Scheme for Traceur Transport
	19	c Equation , Journal of Applied Meteorology, pp 1483-1498,dec. 81
	20	c ********************************************************************
	21	c q,w,masse,pbaru et pbarv
	22	c sont des arguments d'entree pour le s-pg ....
	23	c
	24	c=======================================================================
	25
	26
[2597]	27	include "dimensions.h"
	28	include "paramet.h"
	29	include "comgeom2.h"
[524]	30
	31	c Arguments:
	32	c ----------
	33	integer mode
	34	REAL pbaru( ip1jmp1,llm ),pbarv( ip1jm,llm )
	35	REAL q( iip1,jjp1,llm,0:3)
	36	REAL w( ip1jmp1,llm )
	37	REAL masse( iip1,jjp1,llm)
	38	c Local:
	39	c ------
	40	LOGICAL limit
	41	REAL sm ( iip1,jjp1, llm )
	42	REAL s0( iip1,jjp1,llm ), sx( iip1,jjp1,llm )
	43	REAL sy( iip1,jjp1,llm ), sz( iip1,jjp1,llm )
	44	real masn,mass,zz
	45	INTEGER i,j,l,iq
	46
	47	c modif Fred 24 03 96
	48
	49	real sinlon(iip1),sinlondlon(iip1)
	50	real coslon(iip1),coslondlon(iip1)
	51	save sinlon,coslon,sinlondlon,coslondlon
	52	real dyn1,dyn2,dys1,dys2
	53	real qpn,qps,dqzpn,dqzps
	54	real smn,sms,s0n,s0s,sxn(iip1),sxs(iip1)
	55	real qmin,zq,pente_max
	56	c
	57	REAL SSUM
	58	integer ismax,ismin,lati,latf
[1952]	59	EXTERNAL SSUM, ismin,ismax
[524]	60	logical first
	61	save first
	62	c fin modif
	63
	64	c EXTERNAL masskg
	65	EXTERNAL advx
	66	EXTERNAL advy
	67	EXTERNAL advz
	68
	69	c modif Fred 24 03 96
	70	data first/.true./
	71
	72	limit = .TRUE.
	73	pente_max=2
	74	c if (mode.eq.1.or.mode.eq.3) then
	75	c if (mode.eq.1) then
	76	if (mode.ge.1) then
	77	lati=2
	78	latf=jjm
	79	else
	80	lati=1
	81	latf=jjp1
	82	endif
	83
	84	qmin=0.4995
	85	qmin=0.
	86	if(first) then
	87	print*,'SCHEMA AMONT NOUVEAU'
	88	first=.false.
	89	do i=2,iip1
	90	coslon(i)=cos(rlonv(i))
	91	sinlon(i)=sin(rlonv(i))
	92	coslondlon(i)=coslon(i)*(rlonu(i)-rlonu(i-1))/pi
	93	sinlondlon(i)=sinlon(i)*(rlonu(i)-rlonu(i-1))/pi
	94	print*,coslondlon(i),sinlondlon(i)
	95	enddo
	96	coslon(1)=coslon(iip1)
	97	coslondlon(1)=coslondlon(iip1)
	98	sinlon(1)=sinlon(iip1)
	99	sinlondlon(1)=sinlondlon(iip1)
	100	print*,'sum sinlondlon ',ssum(iim,sinlondlon,1)/sinlondlon(1)
	101	print*,'sum coslondlon ',ssum(iim,coslondlon,1)/coslondlon(1)
	102	DO l = 1,llm
	103	DO j = 1,jjp1
	104	DO i = 1,iip1
	105	q ( i,j,l,1 )=0.
	106	q ( i,j,l,2 )=0.
	107	q ( i,j,l,3 )=0.
	108	ENDDO
	109	ENDDO
	110	ENDDO
	111
	112	endif
	113	c Fin modif Fred
	114
	115	c *** q contient les qqtes de traceur avant l'advection
	116
	117	c *** Affectation des tableaux S a partir de Q
	118	c *** Rem : utilisation de SCOPY ulterieurement
	119
	120	DO l = 1,llm
	121	DO j = 1,jjp1
	122	DO i = 1,iip1
	123	s0( i,j,llm+1-l ) = q ( i,j,l,0 )
	124	sx( i,j,llm+1-l ) = q ( i,j,l,1 )
	125	sy( i,j,llm+1-l ) = q ( i,j,l,2 )
	126	sz( i,j,llm+1-l ) = q ( i,j,l,3 )
	127	ENDDO
	128	ENDDO
	129	ENDDO
	130
	131	c PRINT*,'----- S0 just before conversion -------'
	132	c PRINT*,'S0(16,12,1)=',s0(16,12,1)
	133	c PRINT*,'Q(16,12,1,4)=',q(16,12,1,4)
	134
	135	c *** On calcule la masse d'air en kg
	136
	137	DO l = 1,llm
	138	DO j = 1,jjp1
	139	DO i = 1,iip1
	140	sm ( i,j,llm+1-l)=masse( i,j,l )
	141	ENDDO
	142	ENDDO
	143	ENDDO
	144
	145	c *** On converti les champs S en atome (resp. kg)
	146	c *** Les routines d'advection traitent les champs
	147	c *** a advecter si ces derniers sont en atome (resp. kg)
	148	c *** A optimiser !!!
	149
	150	DO l = 1,llm
	151	DO j = 1,jjp1
	152	DO i = 1,iip1
	153	s0(i,j,l) = s0(i,j,l) * sm ( i,j,l )
	154	sx(i,j,l) = sx(i,j,l) * sm ( i,j,l )
	155	sy(i,j,l) = sy(i,j,l) * sm ( i,j,l )
	156	sz(i,j,l) = sz(i,j,l) * sm ( i,j,l )
	157	ENDDO
	158	ENDDO
	159	ENDDO
	160
	161	c ss0 = 0.
	162	c DO l = 1,llm
	163	c DO j = 1,jjp1
	164	c DO i = 1,iim
	165	c ss0 = ss0 + s0 ( i,j,l )
	166	c ENDDO
	167	c ENDDO
	168	c ENDDO
	169	c PRINT*, 'valeur tot s0 avant advection=',ss0
	170
	171	c *** Appel des subroutines d'advection en X, en Y et en Z
	172	c *** Advection avec "time-splitting"
	173
	174	c-----------------------------------------------------------
	175	c PRINT*,'----- S0 just before ADVX -------'
	176	c PRINT*,'S0(16,12,1)=',s0(16,12,1)
	177
	178	c-----------------------------------------------------------
	179	c do l=1,llm
	180	c do j=1,jjp1
	181	c do i=1,iip1
	182	c zq=s0(i,j,l)/sm(i,j,l)
	183	c if(zq.lt.qmin)
	184	c , print*,'avant advx1, s0(',i,',',j,',',l,')=',zq
	185	c enddo
	186	c enddo
	187	c enddo
	188	CCC
	189	if(mode.eq.2) then
	190	do l=1,llm
	191	s0s=0.
	192	s0n=0.
	193	dyn1=0.
	194	dys1=0.
	195	dyn2=0.
	196	dys2=0.
	197	smn=0.
	198	sms=0.
	199	do i=1,iim
	200	smn=smn+sm(i,1,l)
	201	sms=sms+sm(i,jjp1,l)
	202	s0n=s0n+s0(i,1,l)
	203	s0s=s0s+s0(i,jjp1,l)
	204	zz=sy(i,1,l)/sm(i,1,l)
	205	dyn1=dyn1+sinlondlon(i)*zz
	206	dyn2=dyn2+coslondlon(i)*zz
	207	zz=sy(i,jjp1,l)/sm(i,jjp1,l)
	208	dys1=dys1+sinlondlon(i)*zz
	209	dys2=dys2+coslondlon(i)*zz
	210	enddo
	211	do i=1,iim
	212	sy(i,1,l)=dyn1sinlon(i)+dyn2coslon(i)
	213	sy(i,jjp1,l)=dys1sinlon(i)+dys2coslon(i)
	214	enddo
	215	do i=1,iim
	216	s0(i,1,l)=s0n/smn+sy(i,1,l)
	217	s0(i,jjp1,l)=s0s/sms-sy(i,jjp1,l)
	218	enddo
	219
	220	s0(iip1,1,l)=s0(1,1,l)
	221	s0(iip1,jjp1,l)=s0(1,jjp1,l)
	222
	223	do i=1,iim
	224	sxn(i)=s0(i+1,1,l)-s0(i,1,l)
	225	sxs(i)=s0(i+1,jjp1,l)-s0(i,jjp1,l)
	226	c on rerentre les masses
	227	enddo
	228	do i=1,iim
	229	sy(i,1,l)=sy(i,1,l)*sm(i,1,l)
	230	sy(i,jjp1,l)=sy(i,jjp1,l)*sm(i,jjp1,l)
	231	s0(i,1,l)=s0(i,1,l)*sm(i,1,l)
	232	s0(i,jjp1,l)=s0(i,jjp1,l)*sm(i,jjp1,l)
	233	enddo
	234	sxn(iip1)=sxn(1)
	235	sxs(iip1)=sxs(1)
	236	do i=1,iim
	237	sx(i+1,1,l)=0.25(sxn(i)+sxn(i+1))sm(i+1,1,l)
	238	sx(i+1,jjp1,l)=0.25(sxs(i)+sxs(i+1))sm(i+1,jjp1,l)
	239	enddo
	240	s0(iip1,1,l)=s0(1,1,l)
	241	s0(iip1,jjp1,l)=s0(1,jjp1,l)
	242	sy(iip1,1,l)=sy(1,1,l)
	243	sy(iip1,jjp1,l)=sy(1,jjp1,l)
	244	sx(1,1,l)=sx(iip1,1,l)
	245	sx(1,jjp1,l)=sx(iip1,jjp1,l)
	246	enddo
	247	endif
	248
	249	if (mode.eq.4) then
	250	do l=1,llm
	251	do i=1,iip1
	252	sx(i,1,l)=0.
	253	sx(i,jjp1,l)=0.
	254	sy(i,1,l)=0.
	255	sy(i,jjp1,l)=0.
	256	enddo
	257	enddo
	258	endif
	259	call limx(s0,sx,sm,pente_max)
	260	c call minmaxq(zq,1.e33,-1.e33,'avant advx ')
	261	call advx( limit,.5*dtvr,pbaru,sm,s0,sx,sy,sz,lati,latf)
	262	c call minmaxq(zq,1.e33,-1.e33,'avant advy ')
	263	if (mode.eq.4) then
	264	do l=1,llm
	265	do i=1,iip1
	266	sx(i,1,l)=0.
	267	sx(i,jjp1,l)=0.
	268	sy(i,1,l)=0.
	269	sy(i,jjp1,l)=0.
	270	enddo
	271	enddo
	272	endif
	273	call limy(s0,sy,sm,pente_max)
	274	call advy( limit,.5*dtvr,pbarv,sm,s0,sx,sy,sz )
	275	c call minmaxq(zq,1.e33,-1.e33,'avant advz ')
	276	do j=1,jjp1
	277	do i=1,iip1
	278	sz(i,j,1)=0.
	279	sz(i,j,llm)=0.
	280	enddo
	281	enddo
	282	call limz(s0,sz,sm,pente_max)
	283	call advz( limit,dtvr,w,sm,s0,sx,sy,sz )
	284	if (mode.eq.4) then
	285	do l=1,llm
	286	do i=1,iip1
	287	sx(i,1,l)=0.
	288	sx(i,jjp1,l)=0.
	289	sy(i,1,l)=0.
	290	sy(i,jjp1,l)=0.
	291	enddo
	292	enddo
	293	endif
	294	call limy(s0,sy,sm,pente_max)
	295	call advy( limit,.5*dtvr,pbarv,sm,s0,sx,sy,sz )
	296	do l=1,llm
	297	do j=1,jjp1
	298	sm(iip1,j,l)=sm(1,j,l)
	299	s0(iip1,j,l)=s0(1,j,l)
	300	sx(iip1,j,l)=sx(1,j,l)
	301	sy(iip1,j,l)=sy(1,j,l)
	302	sz(iip1,j,l)=sz(1,j,l)
	303	enddo
	304	enddo
	305
	306
	307	c call minmaxq(zq,1.e33,-1.e33,'avant advx ')
	308	if (mode.eq.4) then
	309	do l=1,llm
	310	do i=1,iip1
	311	sx(i,1,l)=0.
	312	sx(i,jjp1,l)=0.
	313	sy(i,1,l)=0.
	314	sy(i,jjp1,l)=0.
	315	enddo
	316	enddo
	317	endif
	318	call limx(s0,sx,sm,pente_max)
	319	call advx( limit,.5*dtvr,pbaru,sm,s0,sx,sy,sz,lati,latf)
	320	c call minmaxq(zq,1.e33,-1.e33,'apres advx ')
	321	c do l=1,llm
	322	c do j=1,jjp1
	323	c do i=1,iip1
	324	c zq=s0(i,j,l)/sm(i,j,l)
	325	c if(zq.lt.qmin)
	326	c , print*,'apres advx2, s0(',i,',',j,',',l,')=',zq
	327	c enddo
	328	c enddo
	329	c enddo
	330	c *** On repasse les S dans la variable q directement 14/10/94
	331	c On revient a des rapports de melange en divisant par la masse
	332
	333	c En dehors des poles:
	334
	335	DO l = 1,llm
	336	DO j = 1,jjp1
	337	DO i = 1,iim
	338	q(i,j,llm+1-l,0)=s0(i,j,l)/sm(i,j,l)
	339	q(i,j,llm+1-l,1)=sx(i,j,l)/sm(i,j,l)
	340	q(i,j,llm+1-l,2)=sy(i,j,l)/sm(i,j,l)
	341	q(i,j,llm+1-l,3)=sz(i,j,l)/sm(i,j,l)
	342	ENDDO
	343	ENDDO
	344	ENDDO
	345
	346	c Traitements specifiques au pole
	347
	348	if(mode.ge.1) then
	349	DO l=1,llm
	350	c filtrages aux poles
	351	masn=ssum(iim,sm(1,1,l),1)
	352	mass=ssum(iim,sm(1,jjp1,l),1)
	353	qpn=ssum(iim,s0(1,1,l),1)/masn
	354	qps=ssum(iim,s0(1,jjp1,l),1)/mass
	355	dqzpn=ssum(iim,sz(1,1,l),1)/masn
	356	dqzps=ssum(iim,sz(1,jjp1,l),1)/mass
	357	do i=1,iip1
	358	q( i,1,llm+1-l,3)=dqzpn
	359	q( i,jjp1,llm+1-l,3)=dqzps
	360	q( i,1,llm+1-l,0)=qpn
	361	q( i,jjp1,llm+1-l,0)=qps
	362	enddo
	363	if(mode.eq.3) then
	364	dyn1=0.
	365	dys1=0.
	366	dyn2=0.
	367	dys2=0.
	368	do i=1,iim
	369	dyn1=dyn1+sinlondlon(i)*sy(i,1,l)/sm(i,1,l)
	370	dyn2=dyn2+coslondlon(i)*sy(i,1,l)/sm(i,1,l)
	371	dys1=dys1+sinlondlon(i)*sy(i,jjp1,l)/sm(i,jjp1,l)
	372	dys2=dys2+coslondlon(i)*sy(i,jjp1,l)/sm(i,jjp1,l)
	373	enddo
	374	do i=1,iim
	375	q(i,1,llm+1-l,2)=
	376	s (sinlon(i)dyn1+coslon(i)dyn2)
	377	q(i,1,llm+1-l,0)=q(i,1,llm+1-l,0)+q(i,1,llm+1-l,2)
	378	q(i,jjp1,llm+1-l,2)=
	379	s (sinlon(i)dys1+coslon(i)dys2)
	380	q(i,jjp1,llm+1-l,0)=q(i,jjp1,llm+1-l,0)
	381	s -q(i,jjp1,llm+1-l,2)
	382	enddo
	383	endif
	384	if(mode.eq.1) then
	385	c on filtre les valeurs au bord de la "grande maille pole"
	386	dyn1=0.
	387	dys1=0.
	388	dyn2=0.
	389	dys2=0.
	390	do i=1,iim
	391	zz=s0(i,2,l)/sm(i,2,l)-q(i,1,llm+1-l,0)
	392	dyn1=dyn1+sinlondlon(i)*zz
	393	dyn2=dyn2+coslondlon(i)*zz
	394	zz=q(i,jjp1,llm+1-l,0)-s0(i,jjm,l)/sm(i,jjm,l)
	395	dys1=dys1+sinlondlon(i)*zz
	396	dys2=dys2+coslondlon(i)*zz
	397	enddo
	398	do i=1,iim
	399	q(i,1,llm+1-l,2)=
	400	s (sinlon(i)dyn1+coslon(i)dyn2)/2.
	401	q(i,1,llm+1-l,0)=q(i,1,llm+1-l,0)+q(i,1,llm+1-l,2)
	402	q(i,jjp1,llm+1-l,2)=
	403	s (sinlon(i)dys1+coslon(i)dys2)/2.
	404	q(i,jjp1,llm+1-l,0)=q(i,jjp1,llm+1-l,0)
	405	s -q(i,jjp1,llm+1-l,2)
	406	enddo
	407	q(iip1,1,llm+1-l,0)=q(1,1,llm+1-l,0)
	408	q(iip1,jjp1,llm+1-l,0)=q(1,jjp1,llm+1-l,0)
	409
	410	do i=1,iim
	411	sxn(i)=q(i+1,1,llm+1-l,0)-q(i,1,llm+1-l,0)
	412	sxs(i)=q(i+1,jjp1,llm+1-l,0)-q(i,jjp1,llm+1-l,0)
	413	enddo
	414	sxn(iip1)=sxn(1)
	415	sxs(iip1)=sxs(1)
	416	do i=1,iim
	417	q(i+1,1,llm+1-l,1)=0.25*(sxn(i)+sxn(i+1))
	418	q(i+1,jjp1,llm+1-l,1)=0.25*(sxs(i)+sxs(i+1))
	419	enddo
	420	q(1,1,llm+1-l,1)=q(iip1,1,llm+1-l,1)
	421	q(1,jjp1,llm+1-l,1)=q(iip1,jjp1,llm+1-l,1)
	422
	423	endif
	424
	425	ENDDO
	426	endif
	427
	428	c bouclage en longitude
	429	do iq=0,3
	430	do l=1,llm
	431	do j=1,jjp1
	432	q(iip1,j,l,iq)=q(1,j,l,iq)
	433	enddo
	434	enddo
	435	enddo
	436
	437	c PRINT*, ' SORTIE DE PENTES --- ca peut glisser ....'
	438
	439	DO l = 1,llm
[2600]	440	DO j = 1,jjp1
	441	DO i = 1,iip1
[524]	442	IF (q(i,j,l,0).lt.0.) THEN
	443	c PRINT*,'------------ BIP-----------'
	444	c PRINT*,'Q0(',i,j,l,')=',q(i,j,l,0)
	445	c PRINT*,'QX(',i,j,l,')=',q(i,j,l,1)
	446	c PRINT*,'QY(',i,j,l,')=',q(i,j,l,2)
	447	c PRINT*,'QZ(',i,j,l,')=',q(i,j,l,3)
[2600]	448	c PRINT*,' PBL EN SORTIE DE PENTES'
[524]	449	q(i,j,l,0)=0.
	450	c STOP
	451	ENDIF
	452	ENDDO
	453	ENDDO
	454	ENDDO
	455
	456	c PRINT*, '-------------------------------------------'
	457
	458	do l=1,llm
	459	do j=1,jjp1
	460	do i=1,iip1
	461	if(q(i,j,l,0).lt.qmin)
	462	, print*,'apres pentes, s0(',i,',',j,',',l,')=',q(i,j,l,0)
	463	enddo
	464	enddo
	465	enddo
	466	RETURN
	467	END
	468
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