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filtreg_mod.F90 @ 2930

Last change on this file since 2930 was 1279, checked in by Laurent Fairhead, 15 years ago
Merged LMDZ4-dev branch changes r1241:1278 into the trunk Running trunk and LMDZ4-dev in LMDZOR configuration on local machine (sequential) and SX8 (4-proc) yields identical results (restart and restartphy are identical binarily) Log history from r1241 to r1278 is available by switching to source:LMDZ4/branches/LMDZ4-dev-20091210
File size: 13.8 KB

Rev	Line
[1108]	1	MODULE filtreg_mod
[1086]	2
	3	REAL, DIMENSION(:,:,:), ALLOCATABLE :: matriceun,matriceus,matricevn
	4	REAL, DIMENSION(:,:,:), ALLOCATABLE :: matricevs,matrinvn,matrinvs
	5
	6	CONTAINS
	7
	8	SUBROUTINE inifilr
[1279]	9	USE mod_filtre_fft
[1086]	10	!
	11	! ... H. Upadhyaya, O.Sharma ...
	12	!
	13	IMPLICIT NONE
	14	!
	15	! version 3 .....
	16
	17	! Correction le 28/10/97 P. Le Van .
	18	! -------------------------------------------------------------------
	19	#include "dimensions.h"
	20	#include "paramet.h"
	21	! -------------------------------------------------------------------
	22	#include "comgeom.h"
	23	#include "coefils.h"
	24	#include "logic.h"
	25	#include "serre.h"
	26
	27	REAL dlonu(iim),dlatu(jjm)
	28	REAL rlamda( iim ), eignvl( iim )
	29	!
	30
	31	REAL lamdamax,pi,cof
	32	INTEGER i,j,modemax,imx,k,kf,ii
	33	REAL dymin,dxmin,colat0
	34	REAL eignft(iim,iim), coff
	35
	36	LOGICAL, SAVE :: first_call_inifilr = .TRUE.
	37
	38	#ifdef CRAY
	39	INTEGER ISMIN
	40	EXTERNAL ISMIN
	41	INTEGER iymin
	42	INTEGER ixmineq
	43	#endif
	44	EXTERNAL inifgn
	45	!
	46	! ------------------------------------------------------------
	47	! This routine computes the eigenfunctions of the laplacien
	48	! on the stretched grid, and the filtering coefficients
	49	!
	50	! We designate:
	51	! eignfn eigenfunctions of the discrete laplacien
	52	! eigenvl eigenvalues
	53	! jfiltn indexof the last scalar line filtered in NH
	54	! jfilts index of the first line filtered in SH
	55	! modfrst index of the mode from WHERE modes are filtered
	56	! modemax maximum number of modes ( im )
	57	! coefil filtering coefficients ( lamda_max*COS(rlat)/lamda )
	58	! sdd SQRT( dx )
	59	!
	60	! the modes are filtered from modfrst to modemax
	61	!
	62	!-----------------------------------------------------------
	63	!
	64
	65	pi = 2. * ASIN( 1. )
	66
	67	DO i = 1,iim
	68	dlonu(i) = xprimu( i )
	69	ENDDO
	70	!
	71	CALL inifgn(eignvl)
	72	!
	73	PRINT *,' EIGNVL '
	74	PRINT 250,eignvl
	75	250 FORMAT( 1x,5e13.6)
	76	!
	77	! compute eigenvalues and eigenfunctions
	78	!
	79	!
	80	!.................................................................
	81	!
	82	! compute the filtering coefficients for scalar lines and
	83	! meridional wind v-lines
	84	!
	85	! we filter all those latitude lines WHERE coefil < 1
	86	! NO FILTERING AT POLES
	87	!
	88	! colat0 is to be used when alpha (stretching coefficient)
	89	! is set equal to zero for the regular grid CASE
	90	!
	91	! ....... Calcul de colat0 .........
	92	! ..... colat0 = minimum de ( 0.5, min dy/ min dx ) ...
	93	!
	94	!
	95	DO j = 1,jjm
	96	dlatu( j ) = rlatu( j ) - rlatu( j+1 )
	97	ENDDO
	98	!
	99	#ifdef CRAY
	100	iymin = ISMIN( jjm, dlatu, 1 )
	101	ixmineq = ISMIN( iim, dlonu, 1 )
	102	dymin = dlatu( iymin )
	103	dxmin = dlonu( ixmineq )
	104	#else
	105	dxmin = dlonu(1)
	106	DO i = 2, iim
	107	dxmin = MIN( dxmin,dlonu(i) )
	108	ENDDO
	109	dymin = dlatu(1)
	110	DO j = 2, jjm
	111	dymin = MIN( dymin,dlatu(j) )
	112	ENDDO
	113	#endif
	114	!
	115	!
	116	colat0 = MIN( 0.5, dymin/dxmin )
	117	!
	118	IF( .NOT.fxyhypb.AND.ysinus ) THEN
	119	colat0 = 0.6
	120	! ...... a revoir pour ysinus ! .......
	121	alphax = 0.
	122	ENDIF
	123	!
	124	PRINT 50, colat0,alphax
	125	50 FORMAT(/15x,' Inifilr colat0 alphax ',2e16.7)
	126	!
	127	IF(alphax.EQ.1. ) THEN
	128	PRINT *,' Inifilr alphax doit etre < a 1. Corriger '
	129	STOP
	130	ENDIF
	131	!
	132	lamdamax = iim / ( pi * colat0 * ( 1. - alphax ) )
	133
	134	! ... Correction le 28/10/97 ( P.Le Van ) ..
	135	!
	136	DO i = 2,iim
	137	rlamda( i ) = lamdamax/ SQRT( ABS( eignvl(i) ) )
	138	ENDDO
	139	!
	140
	141	DO j = 1,jjm
	142	DO i = 1,iim
	143	coefilu( i,j ) = 0.0
	144	coefilv( i,j ) = 0.0
	145	coefilu2( i,j ) = 0.0
	146	coefilv2( i,j ) = 0.0
	147	ENDDO
	148	ENDDO
	149
	150	!
	151	! ... Determination de jfiltnu,jfiltnv,jfiltsu,jfiltsv ....
	152	! .........................................................
	153	!
	154	modemax = iim
	155
	156	!!!! imx = modemax - 4 * (modemax/iim)
	157
	158	imx = iim
	159	!
	160	PRINT *,' TRUNCATION AT ',imx
	161	!
	162	DO j = 2, jjm/2+1
	163	cof = COS( rlatu(j) )/ colat0
	164	IF ( cof .LT. 1. ) THEN
	165	IF( rlamda(imx) * COS(rlatu(j) ).LT.1. ) jfiltnu= j
	166	ENDIF
	167
	168	cof = COS( rlatu(jjp1-j+1) )/ colat0
	169	IF ( cof .LT. 1. ) THEN
	170	IF( rlamda(imx) * COS(rlatu(jjp1-j+1) ).LT.1. ) &
	171	jfiltsu= jjp1-j+1
	172	ENDIF
	173	ENDDO
	174	!
	175	DO j = 1, jjm/2
	176	cof = COS( rlatv(j) )/ colat0
	177	IF ( cof .LT. 1. ) THEN
	178	IF( rlamda(imx) * COS(rlatv(j) ).LT.1. ) jfiltnv= j
	179	ENDIF
	180
	181	cof = COS( rlatv(jjm-j+1) )/ colat0
	182	IF ( cof .LT. 1. ) THEN
	183	IF( rlamda(imx) * COS(rlatv(jjm-j+1) ).LT.1. ) &
	184	jfiltsv= jjm-j+1
	185	ENDIF
	186	ENDDO
	187	!
	188
	189	IF ( jfiltnu.LE.0 ) jfiltnu=1
	190	IF( jfiltnu.GT. jjm/2 +1 ) THEN
	191	PRINT *,' jfiltnu en dehors des valeurs acceptables ' ,jfiltnu
	192	STOP
	193	ENDIF
	194
	195	IF( jfiltsu.LE.0) jfiltsu=1
	196	IF( jfiltsu.GT. jjm +1 ) THEN
	197	PRINT *,' jfiltsu en dehors des valeurs acceptables ' ,jfiltsu
	198	STOP
	199	ENDIF
	200
	201	IF( jfiltnv.LE.0) jfiltnv=1
	202	IF( jfiltnv.GT. jjm/2 ) THEN
	203	PRINT *,' jfiltnv en dehors des valeurs acceptables ' ,jfiltnv
	204	STOP
	205	ENDIF
	206
	207	IF( jfiltsv.LE.0) jfiltsv=1
	208	IF( jfiltsv.GT. jjm ) THEN
	209	PRINT *,' jfiltsv en dehors des valeurs acceptables ' ,jfiltsv
	210	STOP
	211	ENDIF
	212
	213	PRINT *,' jfiltnv jfiltsv jfiltnu jfiltsu ' , &
	214	jfiltnv,jfiltsv,jfiltnu,jfiltsu
	215
	216	IF(first_call_inifilr) THEN
	217	ALLOCATE(matriceun(iim,iim,jfiltnu))
	218	ALLOCATE(matriceus(iim,iim,jfiltsu))
	219	ALLOCATE(matricevn(iim,iim,jfiltnv))
	220	ALLOCATE(matricevs(iim,iim,jfiltsv))
	221	ALLOCATE( matrinvn(iim,iim,jfiltnu))
	222	ALLOCATE( matrinvs(iim,iim,jfiltsu))
	223	first_call_inifilr = .FALSE.
	224	ENDIF
	225
	226	!
	227	! ... Determination de coefilu,coefilv,n=modfrstu,modfrstv ....
	228	!................................................................
	229	!
	230	!
	231	DO j = 1,jjm
	232	modfrstu( j ) = iim
	233	modfrstv( j ) = iim
	234	ENDDO
	235	!
	236	DO j = 2,jfiltnu
	237	DO k = 2,modemax
	238	cof = rlamda(k) * COS( rlatu(j) )
	239	IF ( cof .LT. 1. ) GOTO 82
	240	ENDDO
	241	GOTO 84
	242	82 modfrstu( j ) = k
	243	!
	244	kf = modfrstu( j )
	245	DO k = kf , modemax
	246	cof = rlamda(k) * COS( rlatu(j) )
	247	coefilu(k,j) = cof - 1.
	248	coefilu2(k,j) = cof*cof - 1.
	249	ENDDO
	250	84 CONTINUE
	251	ENDDO
	252	!
	253	!
	254	DO j = 1,jfiltnv
	255	!
	256	DO k = 2,modemax
	257	cof = rlamda(k) * COS( rlatv(j) )
	258	IF ( cof .LT. 1. ) GOTO 87
	259	ENDDO
	260	GOTO 89
	261	87 modfrstv( j ) = k
	262	!
	263	kf = modfrstv( j )
	264	DO k = kf , modemax
	265	cof = rlamda(k) * COS( rlatv(j) )
	266	coefilv(k,j) = cof - 1.
	267	coefilv2(k,j) = cof*cof - 1.
	268	ENDDO
	269	89 CONTINUE
	270	ENDDO
	271	!
	272	DO j = jfiltsu,jjm
	273	DO k = 2,modemax
	274	cof = rlamda(k) * COS( rlatu(j) )
	275	IF ( cof .LT. 1. ) GOTO 92
	276	ENDDO
	277	GOTO 94
	278	92 modfrstu( j ) = k
	279	!
	280	kf = modfrstu( j )
	281	DO k = kf , modemax
	282	cof = rlamda(k) * COS( rlatu(j) )
	283	coefilu(k,j) = cof - 1.
	284	coefilu2(k,j) = cof*cof - 1.
	285	ENDDO
	286	94 CONTINUE
	287	ENDDO
	288	!
	289	DO j = jfiltsv,jjm
	290	DO k = 2,modemax
	291	cof = rlamda(k) * COS( rlatv(j) )
	292	IF ( cof .LT. 1. ) GOTO 97
	293	ENDDO
	294	GOTO 99
	295	97 modfrstv( j ) = k
	296	!
	297	kf = modfrstv( j )
	298	DO k = kf , modemax
	299	cof = rlamda(k) * COS( rlatv(j) )
	300	coefilv(k,j) = cof - 1.
	301	coefilv2(k,j) = cof*cof - 1.
	302	ENDDO
	303	99 CONTINUE
	304	ENDDO
	305	!
	306
	307	IF(jfiltnv.GE.jjm/2 .OR. jfiltnu.GE.jjm/2)THEN
	308
	309	IF(jfiltnv.EQ.jfiltsv)jfiltsv=1+jfiltnv
	310	IF(jfiltnu.EQ.jfiltsu)jfiltsu=1+jfiltnu
	311
	312	PRINT *,'jfiltnv jfiltsv jfiltnu jfiltsu' , &
	313	jfiltnv,jfiltsv,jfiltnu,jfiltsu
	314	ENDIF
	315
	316	PRINT *,' Modes premiers v '
	317	PRINT 334,modfrstv
	318	PRINT *,' Modes premiers u '
	319	PRINT 334,modfrstu
	320
	321	!
	322	! ...................................................................
	323	!
	324	! ... Calcul de la matrice filtre 'matriceu' pour les champs situes
	325	! sur la grille scalaire ........
	326	! ...................................................................
	327	!
	328	DO j = 2, jfiltnu
	329
	330	DO i=1,iim
	331	coff = coefilu(i,j)
	332	IF( i.LT.modfrstu(j) ) coff = 0.
	333	DO k=1,iim
	334	eignft(i,k) = eignfnv(k,i) * coff
	335	ENDDO
	336	ENDDO
	337	#ifdef CRAY
	338	CALL MXM( eignfnv,iim,eignft,iim,matriceun(1,1,j),iim )
	339	#else
	340	#ifdef BLAS
	341	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
	342	eignfnv, iim, eignft, iim, 0.0, matriceun(1,1,j), iim)
	343	#else
	344	DO k = 1, iim
	345	DO i = 1, iim
	346	matriceun(i,k,j) = 0.0
	347	DO ii = 1, iim
	348	matriceun(i,k,j) = matriceun(i,k,j) &
	349	+ eignfnv(i,ii)*eignft(ii,k)
	350	ENDDO
	351	ENDDO
	352	ENDDO
	353	#endif
	354	#endif
	355
	356	ENDDO
	357
	358	DO j = jfiltsu, jjm
	359
	360	DO i=1,iim
	361	coff = coefilu(i,j)
	362	IF( i.LT.modfrstu(j) ) coff = 0.
	363	DO k=1,iim
	364	eignft(i,k) = eignfnv(k,i) * coff
	365	ENDDO
	366	ENDDO
	367	#ifdef CRAY
	368	CALL MXM(eignfnv,iim,eignft,iim,matriceus(1,1,j-jfiltsu+1),iim)
	369	#else
	370	#ifdef BLAS
	371	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
	372	eignfnv, iim, eignft, iim, 0.0, &
	373	matriceus(1,1,j-jfiltsu+1), iim)
	374	#else
	375	DO k = 1, iim
	376	DO i = 1, iim
	377	matriceus(i,k,j-jfiltsu+1) = 0.0
	378	DO ii = 1, iim
	379	matriceus(i,k,j-jfiltsu+1) = matriceus(i,k,j-jfiltsu+1) &
	380	+ eignfnv(i,ii)*eignft(ii,k)
	381	ENDDO
	382	ENDDO
	383	ENDDO
	384	#endif
	385	#endif
	386
	387	ENDDO
	388
	389	! ...................................................................
	390	!
	391	! ... Calcul de la matrice filtre 'matricev' pour les champs situes
	392	! sur la grille de V ou de Z ........
	393	! ...................................................................
	394	!
	395	DO j = 1, jfiltnv
	396
	397	DO i = 1, iim
	398	coff = coefilv(i,j)
	399	IF( i.LT.modfrstv(j) ) coff = 0.
	400	DO k = 1, iim
	401	eignft(i,k) = eignfnu(k,i) * coff
	402	ENDDO
	403	ENDDO
	404	#ifdef CRAY
	405	CALL MXM( eignfnu,iim,eignft,iim,matricevn(1,1,j),iim )
	406	#else
	407	#ifdef BLAS
	408	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
	409	eignfnu, iim, eignft, iim, 0.0, matricevn(1,1,j), iim)
	410	#else
	411	DO k = 1, iim
	412	DO i = 1, iim
	413	matricevn(i,k,j) = 0.0
	414	DO ii = 1, iim
	415	matricevn(i,k,j) = matricevn(i,k,j) &
	416	+ eignfnu(i,ii)*eignft(ii,k)
	417	ENDDO
	418	ENDDO
	419	ENDDO
	420	#endif
	421	#endif
	422
	423	ENDDO
	424
	425	DO j = jfiltsv, jjm
	426
	427	DO i = 1, iim
	428	coff = coefilv(i,j)
	429	IF( i.LT.modfrstv(j) ) coff = 0.
	430	DO k = 1, iim
	431	eignft(i,k) = eignfnu(k,i) * coff
	432	ENDDO
	433	ENDDO
	434	#ifdef CRAY
	435	CALL MXM(eignfnu,iim,eignft,iim,matricevs(1,1,j-jfiltsv+1),iim)
	436	#else
	437	#ifdef BLAS
	438	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
	439	eignfnu, iim, eignft, iim, 0.0, &
	440	matricevs(1,1,j-jfiltsv+1), iim)
	441	#else
	442	DO k = 1, iim
	443	DO i = 1, iim
	444	matricevs(i,k,j-jfiltsv+1) = 0.0
	445	DO ii = 1, iim
	446	matricevs(i,k,j-jfiltsv+1) = matricevs(i,k,j-jfiltsv+1) &
	447	+ eignfnu(i,ii)*eignft(ii,k)
	448	ENDDO
	449	ENDDO
	450	ENDDO
	451	#endif
	452	#endif
	453
	454	ENDDO
	455
	456	! ...................................................................
	457	!
	458	! ... Calcul de la matrice filtre 'matrinv' pour les champs situes
	459	! sur la grille scalaire , pour le filtre inverse ........
	460	! ...................................................................
	461	!
	462	DO j = 2, jfiltnu
	463
	464	DO i = 1,iim
	465	coff = coefilu(i,j)/ ( 1. + coefilu(i,j) )
	466	IF( i.LT.modfrstu(j) ) coff = 0.
	467	DO k=1,iim
	468	eignft(i,k) = eignfnv(k,i) * coff
	469	ENDDO
	470	ENDDO
	471	#ifdef CRAY
	472	CALL MXM( eignfnv,iim,eignft,iim,matrinvn(1,1,j),iim )
	473	#else
	474	#ifdef BLAS
	475	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
	476	eignfnv, iim, eignft, iim, 0.0, matrinvn(1,1,j), iim)
	477	#else
	478	DO k = 1, iim
	479	DO i = 1, iim
	480	matrinvn(i,k,j) = 0.0
	481	DO ii = 1, iim
	482	matrinvn(i,k,j) = matrinvn(i,k,j) &
	483	+ eignfnv(i,ii)*eignft(ii,k)
	484	ENDDO
	485	ENDDO
	486	ENDDO
	487	#endif
	488	#endif
	489
	490	ENDDO
	491
	492	DO j = jfiltsu, jjm
	493
	494	DO i = 1,iim
	495	coff = coefilu(i,j) / ( 1. + coefilu(i,j) )
	496	IF( i.LT.modfrstu(j) ) coff = 0.
	497	DO k=1,iim
	498	eignft(i,k) = eignfnv(k,i) * coff
	499	ENDDO
	500	ENDDO
	501	#ifdef CRAY
	502	CALL MXM(eignfnv,iim,eignft,iim,matrinvs(1,1,j-jfiltsu+1),iim)
	503	#else
	504	#ifdef BLAS
	505	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0, &
	506	eignfnv, iim, eignft, iim, 0.0, matrinvs(1,1,j-jfiltsu+1), iim)
	507	#else
	508	DO k = 1, iim
	509	DO i = 1, iim
	510	matrinvs(i,k,j-jfiltsu+1) = 0.0
	511	DO ii = 1, iim
	512	matrinvs(i,k,j-jfiltsu+1) = matrinvs(i,k,j-jfiltsu+1) &
	513	+ eignfnv(i,ii)*eignft(ii,k)
	514	ENDDO
	515	ENDDO
	516	ENDDO
	517	#endif
	518	#endif
	519
	520	ENDDO
	521
[1279]	522	IF (use_filtre_fft) THEN
	523	CALL Init_filtre_fft(coefilu,modfrstu,jfiltnu,jfiltsu, &
	524	coefilv,modfrstv,jfiltnv,jfiltsv)
	525	ENDIF
	526
[1086]	527	! ...................................................................
	528
	529	!
	530	334 FORMAT(1x,24i3)
	531	755 FORMAT(1x,6f10.3,i3)
	532
	533	RETURN
	534	END SUBROUTINE inifilr
	535
[1108]	536	END MODULE filtreg_mod

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