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inifilr.F @ 576

Last change on this file since 576 was 2, checked in by lmdz, 25 years ago
Initial revision
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1	SUBROUTINE inifilr
2	c
3	c ... H. Upadhyaya, O.Sharma ...
4	c
5	IMPLICIT NONE
6	c
7	c version 3 .....
8
9	c Correction le 28/10/97 P. Le Van .
10	c -------------------------------------------------------------------
11	#include "dimensions.h"
12	#include "paramet.h"
13	#include "parafilt.h"
14	c -------------------------------------------------------------------
15	#include "comgeom.h"
16	#include "coefils.h"
17	#include "logic.h"
18	#include "serre.h"
19
20	REAL dlonu(iim),dlatu(jjm)
21	REAL rlamda( iim ), eignvl( iim )
22	c
23
24	REAL lamdamax,pi,cof
25	INTEGER i,j,modemax,imx,k,kf,ii
26	REAL dymin,dxmin,colat0
27	REAL eignft(iim,iim), coff
28	REAL matriceun,matriceus,matricevn,matricevs,matrinvn,matrinvs
29	COMMON/matrfil/matriceun(iim,iim,nfilun),matriceus(iim,iim,nfilus)
30	, , matricevn(iim,iim,nfilvn),matricevs(iim,iim,nfilvs)
31	, , matrinvn(iim,iim,nfilun),matrinvs (iim,iim,nfilus)
32	#ifdef CRAY
33	INTEGER ISMIN
34	EXTERNAL ISMIN
35	INTEGER iymin
36	INTEGER ixmineq
37	#endif
38	EXTERNAL inifgn
39	c
40	c ------------------------------------------------------------
41	c This routine computes the eigenfunctions of the laplacien
42	c on the stretched grid, and the filtering coefficients
43	c
44	c We designate:
45	c eignfn eigenfunctions of the discrete laplacien
46	c eigenvl eigenvalues
47	c jfiltn indexof the last scalar line filtered in NH
48	c jfilts index of the first line filtered in SH
49	c modfrst index of the mode from where modes are filtered
50	c modemax maximum number of modes ( im )
51	c coefil filtering coefficients ( lamda_max*cos(rlat)/lamda )
52	c sdd SQRT( dx )
53	c
54	c the modes are filtered from modfrst to modemax
55	c
56	c-----------------------------------------------------------
57	c
58
59	pi = 2. * ASIN( 1. )
60
61	DO i = 1,iim
62	dlonu(i) = xprimu( i )
63	ENDDO
64	c
65	CALL inifgn(eignvl)
66	c
67	print *,' EIGNVL '
68	PRINT 250,eignvl
69	250 FORMAT( 1x,5e13.6)
70	c
71	c compute eigenvalues and eigenfunctions
72	c
73	c
74	c.................................................................
75	c
76	c compute the filtering coefficients for scalar lines and
77	c meridional wind v-lines
78	c
79	c we filter all those latitude lines where coefil < 1
80	c NO FILTERING AT POLES
81	c
82	c colat0 is to be used when alpha (stretching coefficient)
83	c is set equal to zero for the regular grid case
84	c
85	c ....... Calcul de colat0 .........
86	c ..... colat0 = minimum de ( 0.5, min dy/ min dx ) ...
87	c
88	c
89	DO 45 j = 1,jjm
90	dlatu( j ) = rlatu( j ) - rlatu( j+1 )
91	45 CONTINUE
92	c
93	#ifdef CRAY
94	iymin = ISMIN( jjm, dlatu, 1 )
95	ixmineq = ISMIN( iim, dlonu, 1 )
96	dymin = dlatu( iymin )
97	dxmin = dlonu( ixmineq )
98	#else
99	dxmin = dlonu(1)
100	DO i = 2, iim
101	dxmin = MIN( dxmin,dlonu(i) )
102	ENDDO
103	dymin = dlatu(1)
104	DO j = 2, jjm
105	dymin = MIN( dymin,dlatu(j) )
106	ENDDO
107	#endif
108	c
109	c
110	colat0 = MIN( 0.5, dymin/dxmin )
111	c
112	IF( .NOT.fxyhypb.AND.ysinus ) THEN
113	colat0 = 0.6
114	c ...... a revoir pour ysinus ! .......
115	alphax = 0.
116	ENDIF
117	c
118	PRINT 50, colat0,alphax
119	50 FORMAT(/15x,' Inifilr colat0 alphax ',2e16.7)
120	c
121	IF(alphax.EQ.1. ) THEN
122	PRINT *,' Inifilr alphax doit etre < a 1. Corriger '
123	STOP
124	ENDIF
125	c
126	lamdamax = iim / ( pi * colat0 * ( 1. - alphax ) )
127
128	cc ... Correction le 28/10/97 ( P.Le Van ) ..
129	c
130	DO 71 i = 2,iim
131	rlamda( i ) = lamdamax/ SQRT( ABS( eignvl(i) ) )
132	71 CONTINUE
133	c
134
135	DO 72 j = 1,jjm
136	DO 73 i = 1,iim
137	coefilu( i,j ) = 0.0
138	coefilv( i,j ) = 0.0
139	coefilu2( i,j ) = 0.0
140	coefilv2( i,j ) = 0.0
141	73 CONTINUE
142	72 CONTINUE
143
144	c
145	c ... Determination de jfiltnu,jfiltnv,jfiltsu,jfiltsv ....
146	c .........................................................
147	c
148	modemax = iim
149
150	cccc imx = modemax - 4 * (modemax/iim)
151
152	imx = iim
153	c
154	PRINT *,' TRUNCATION AT ',imx
155	c
156	DO 75 j = 2, jjm/2+1
157	cof = COS( rlatu(j) )/ colat0
158	IF ( cof .LT. 1. ) THEN
159	IF( rlamda(imx) * COS(rlatu(j) ).LT.1. ) jfiltnu= j
160	ENDIF
161
162	cof = COS( rlatu(jjp1-j+1) )/ colat0
163	IF ( cof .LT. 1. ) THEN
164	IF( rlamda(imx) * COS(rlatu(jjp1-j+1) ).LT.1. )
165	$ jfiltsu= jjp1-j+1
166	ENDIF
167	75 CONTINUE
168	c
169	DO 76 j = 1, jjm/2
170	cof = COS( rlatv(j) )/ colat0
171	IF ( cof .LT. 1. ) THEN
172	IF( rlamda(imx) * COS(rlatv(j) ).LT.1. ) jfiltnv= j
173	ENDIF
174
175	cof = COS( rlatv(jjm-j+1) )/ colat0
176	IF ( cof .LT. 1. ) THEN
177	IF( rlamda(imx) * COS(rlatv(jjm-j+1) ).LT.1. )
178	$ jfiltsv= jjm-j+1
179	ENDIF
180	76 CONTINUE
181	c
182
183	IF( jfiltnu.LE.0 .OR. jfiltnu.GT. jjm/2 +1 ) THEN
184	PRINT *,' jfiltnu en dehors des valeurs acceptables ' ,jfiltnu
185	STOP
186	ENDIF
187
188	IF( jfiltsu.LE.0 .OR. jfiltsu.GT. jjm +1 ) THEN
189	PRINT *,' jfiltsu en dehors des valeurs acceptables ' ,jfiltsu
190	STOP
191	ENDIF
192
193	IF( jfiltnv.LE.0 .OR. jfiltnv.GT. jjm/2 ) THEN
194	PRINT *,' jfiltnv en dehors des valeurs acceptables ' ,jfiltnv
195	STOP
196	ENDIF
197
198	IF( jfiltsv.LE.0 .OR. jfiltsv.GT. jjm ) THEN
199	PRINT *,' jfiltsv en dehors des valeurs acceptables ' ,jfiltsv
200	STOP
201	ENDIF
202
203	PRINT *,' jfiltnv jfiltsv jfiltnu jfiltsu ' ,
204	* jfiltnv,jfiltsv,jfiltnu,jfiltsu
205
206	c
207	c ... Determination de coefilu,coefilv,n=modfrstu,modfrstv ....
208	c................................................................
209	c
210	c
211	DO 77 j = 1,jjm
212	modfrstu( j ) = iim
213	modfrstv( j ) = iim
214	77 CONTINUE
215	c
216	DO 84 j = 2,jfiltnu
217	DO 81 k = 2,modemax
218	cof = rlamda(k) * COS( rlatu(j) )
219	IF ( cof .LT. 1. ) GOTO 82
220	81 CONTINUE
221	GOTO 84
222	82 modfrstu( j ) = k
223	c
224	kf = modfrstu( j )
225	DO 83 k = kf , modemax
226	cof = rlamda(k) * COS( rlatu(j) )
227	coefilu(k,j) = cof - 1.
228	coefilu2(k,j) = cof*cof - 1.
229	83 CONTINUE
230	84 CONTINUE
231	c
232	c
233	DO 89 j = 1,jfiltnv
234	c
235	DO 86 k = 2,modemax
236	cof = rlamda(k) * COS( rlatv(j) )
237	IF ( cof .LT. 1. ) GOTO 87
238	86 CONTINUE
239	GOTO 89
240	87 modfrstv( j ) = k
241	c
242	kf = modfrstv( j )
243	DO 88 k = kf , modemax
244	cof = rlamda(k) * COS( rlatv(j) )
245	coefilv(k,j) = cof - 1.
246	coefilv2(k,j) = cof*cof - 1.
247	88 CONTINUE
248	c
249	89 CONTINUE
250	c
251	DO 94 j = jfiltsu,jjm
252	DO 91 k = 2,modemax
253	cof = rlamda(k) * COS( rlatu(j) )
254	IF ( cof .LT. 1. ) GOTO 92
255	91 CONTINUE
256	GOTO 94
257	92 modfrstu( j ) = k
258	c
259	kf = modfrstu( j )
260	DO 93 k = kf , modemax
261	cof = rlamda(k) * COS( rlatu(j) )
262	coefilu(k,j) = cof - 1.
263	coefilu2(k,j) = cof*cof - 1.
264	93 CONTINUE
265	94 CONTINUE
266	c
267	DO 99 j = jfiltsv,jjm
268	DO 96 k = 2,modemax
269	cof = rlamda(k) * COS( rlatv(j) )
270	IF ( cof .LT. 1. ) GOTO 97
271	96 CONTINUE
272	GOTO 99
273	97 modfrstv( j ) = k
274	c
275	kf = modfrstv( j )
276	DO 98 k = kf , modemax
277	cof = rlamda(k) * COS( rlatv(j) )
278	coefilv(k,j) = cof - 1.
279	coefilv2(k,j) = cof*cof - 1.
280	98 CONTINUE
281	99 CONTINUE
282	c
283
284	IF(jfiltnv.GE.jjm/2 .OR. jfiltnu.GE.jjm/2)THEN
285
286	IF(jfiltnv.EQ.jfiltsv)jfiltsv=1+jfiltnv
287	IF(jfiltnu.EQ.jfiltsu)jfiltsu=1+jfiltnu
288
289	PRINT *,'jfiltnv jfiltsv jfiltnu jfiltsu' ,
290	* jfiltnv,jfiltsv,jfiltnu,jfiltsu
291	ENDIF
292
293	PRINT *,' Modes premiers v '
294	PRINT 334,modfrstv
295	PRINT *,' Modes premiers u '
296	PRINT 334,modfrstu
297
298
299	IF( nfilun.LT. jfiltnu ) THEN
300	PRINT *,' le parametre nfilun utilise pour la matrice ',
301	* ' matriceun est trop petit ! '
302	PRINT *,'Le changer dans parafilt.h et le mettre a ',jfiltnu
303	PRINT *,' Pour information, nfilun,nfilus,nfilvn,nfilvs '
304	* ,'doivent etre egaux successivement a ',jfiltnu,jjm-jfiltsu+1
305	* ,jfiltnv,jjm-jfiltsv+1
306	STOP
307	ENDIF
308	IF( nfilun.GT. jfiltnu+ 2 ) THEN
309	PRINT *,' le parametre nfilun utilise pour la matrice ',
310	*' matriceun est trop grand ! Gachis de memoire ! '
311	PRINT *,'Le changer dans parafilt.h et le mettre a ',jfiltnu
312	PRINT *,' Pour information, nfilun,nfilus,nfilvn,nfilvs '
313	* ,'doivent etre egaux successivement a ',jfiltnu,jjm-jfiltsu+1
314	* ,jfiltnv,jjm-jfiltsv+1
315	c STOP
316	ENDIF
317	IF( nfilus.LT. jjm - jfiltsu +1 ) THEN
318	PRINT *,' le parametre nfilus utilise pour la matrice ',
319	* ' matriceus est trop petit ! '
320	PRINT *,' Le changer dans parafilt.h et le mettre a ',
321	* jjm - jfiltsu + 1
322	PRINT *,' Pour information , nfilun,nfilus,nfilvn,nfilvs '
323	* ,'doivent etre egaux successivement a ',jfiltnu,jjm-jfiltsu+1
324	* ,jfiltnv,jjm-jfiltsv+1
325	STOP
326	ENDIF
327	IF( nfilus.GT. jjm - jfiltsu + 3 ) THEN
328	PRINT *,' le parametre nfilus utilise pour la matrice ',
329	* ' matriceus est trop grand ! '
330	PRINT *,' Le changer dans parafilt.h et le mettre a ' ,
331	* jjm - jfiltsu + 1
332	PRINT *,' Pour information , nfilun,nfilus,nfilvn,nfilvs '
333	* ,'doivent etre egaux successivement a ',jfiltnu,jjm-jfiltsu+1
334	* ,jfiltnv,jjm-jfiltsv+1
335	c STOP
336	ENDIF
337	IF( nfilvn.LT. jfiltnv ) THEN
338	PRINT *,' le parametre nfilvn utilise pour la matrice ',
339	* ' matricevn est trop petit ! '
340	PRINT *,'Le changer dans parafilt.h et le mettre a ',jfiltnv
341	PRINT *,' Pour information , nfilun,nfilus,nfilvn,nfilvs '
342	* ,'doivent etre egaux successivement a ',jfiltnu,jjm-jfiltsu+1
343	* ,jfiltnv,jjm-jfiltsv+1
344	STOP
345	ENDIF
346	IF( nfilvn.GT. jfiltnv+ 2 ) THEN
347	PRINT *,' le parametre nfilvn utilise pour la matrice ',
348	*' matricevn est trop grand ! Gachis de memoire ! '
349	PRINT *,'Le changer dans parafilt.h et le mettre a ',jfiltnv
350	PRINT *,' Pour information , nfilun,nfilus,nfilvn,nfilvs '
351	* ,'doivent etre egaux successivement a ',jfiltnu,jjm-jfiltsu+1
352	* ,jfiltnv,jjm-jfiltsv+1
353	c STOP
354	ENDIF
355	IF( nfilvs.LT. jjm - jfiltsv +1 ) THEN
356	PRINT *,' le parametre nfilvs utilise pour la matrice ',
357	* ' matricevs est trop petit ! Le changer dans parafilt.h '
358	PRINT *,' Le changer dans parafilt.h et le mettre a '
359	* , jjm - jfiltsv + 1
360	PRINT *,' Pour information , nfilun,nfilus,nfilvn,nfilvs '
361	* ,'doivent etre egaux successivement a ',jfiltnu,jjm-jfiltsu+1
362	* ,jfiltnv,jjm-jfiltsv+1
363	STOP
364	ENDIF
365	IF( nfilvs.GT. jjm - jfiltsv + 3 ) THEN
366	PRINT *,' le parametre nfilvs utilise pour la matrice ',
367	* ' matricevs est trop grand ! Gachis de memoire ! '
368	PRINT *,' Le changer dans parafilt.h et le mettre a '
369	* , jjm - jfiltsv + 1
370	PRINT *,' Pour information , nfilun,nfilus,nfilvn,nfilvs '
371	* ,'doivent etre egaux successivement a ',jfiltnu,jjm-jfiltsu+1
372	* ,jfiltnv,jjm-jfiltsv+1
373	c STOP
374	ENDIF
375
376	c
377	c ...................................................................
378	c
379	c ... Calcul de la matrice filtre 'matriceu' pour les champs situes
380	c sur la grille scalaire ........
381	c ...................................................................
382	c
383	DO j = 2, jfiltnu
384
385	DO i=1,iim
386	coff = coefilu(i,j)
387	IF( i.LT.modfrstu(j) ) coff = 0.
388	DO k=1,iim
389	eignft(i,k) = eignfnv(k,i) * coff
390	ENDDO
391	ENDDO
392	#ifdef CRAY
393	CALL MXM( eignfnv,iim,eignft,iim,matriceun(1,1,j),iim )
394	#else
395	#ifdef BLAS
396	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0,
397	$ eignfnv, iim, eignft, iim, 0.0, matriceun(1,1,j), iim)
398	#else
399	DO k = 1, iim
400	DO i = 1, iim
401	matriceun(i,k,j) = 0.0
402	DO ii = 1, iim
403	matriceun(i,k,j) = matriceun(i,k,j)
404	. + eignfnv(i,ii)*eignft(ii,k)
405	ENDDO
406	ENDDO
407	ENDDO
408	#endif
409	#endif
410
411	ENDDO
412
413	DO j = jfiltsu, jjm
414
415	DO i=1,iim
416	coff = coefilu(i,j)
417	IF( i.LT.modfrstu(j) ) coff = 0.
418	DO k=1,iim
419	eignft(i,k) = eignfnv(k,i) * coff
420	ENDDO
421	ENDDO
422	#ifdef CRAY
423	CALL MXM(eignfnv,iim,eignft,iim,matriceus(1,1,j-jfiltsu+1),iim)
424	#else
425	#ifdef BLAS
426	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0,
427	$ eignfnv, iim, eignft, iim, 0.0,
428	$ matriceus(1,1,j-jfiltsu+1), iim)
429	#else
430	DO k = 1, iim
431	DO i = 1, iim
432	matriceus(i,k,j-jfiltsu+1) = 0.0
433	DO ii = 1, iim
434	matriceus(i,k,j-jfiltsu+1) = matriceus(i,k,j-jfiltsu+1)
435	. + eignfnv(i,ii)*eignft(ii,k)
436	ENDDO
437	ENDDO
438	ENDDO
439	#endif
440	#endif
441
442	ENDDO
443
444	c ...................................................................
445	c
446	c ... Calcul de la matrice filtre 'matricev' pour les champs situes
447	c sur la grille de V ou de Z ........
448	c ...................................................................
449	c
450	DO j = 1, jfiltnv
451
452	DO i = 1, iim
453	coff = coefilv(i,j)
454	IF( i.LT.modfrstv(j) ) coff = 0.
455	DO k = 1, iim
456	eignft(i,k) = eignfnu(k,i) * coff
457	ENDDO
458	ENDDO
459	#ifdef CRAY
460	CALL MXM( eignfnu,iim,eignft,iim,matricevn(1,1,j),iim )
461	#else
462	#ifdef BLAS
463	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0,
464	$ eignfnu, iim, eignft, iim, 0.0, matricevn(1,1,j), iim)
465	#else
466	DO k = 1, iim
467	DO i = 1, iim
468	matricevn(i,k,j) = 0.0
469	DO ii = 1, iim
470	matricevn(i,k,j) = matricevn(i,k,j)
471	. + eignfnu(i,ii)*eignft(ii,k)
472	ENDDO
473	ENDDO
474	ENDDO
475	#endif
476	#endif
477
478	ENDDO
479
480	DO j = jfiltsv, jjm
481
482	DO i = 1, iim
483	coff = coefilv(i,j)
484	IF( i.LT.modfrstv(j) ) coff = 0.
485	DO k = 1, iim
486	eignft(i,k) = eignfnu(k,i) * coff
487	ENDDO
488	ENDDO
489	#ifdef CRAY
490	CALL MXM(eignfnu,iim,eignft,iim,matricevs(1,1,j-jfiltsv+1),iim)
491	#else
492	#ifdef BLAS
493	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0,
494	$ eignfnu, iim, eignft, iim, 0.0,
495	$ matricevs(1,1,j-jfiltsv+1), iim)
496	#else
497	DO k = 1, iim
498	DO i = 1, iim
499	matricevs(i,k,j-jfiltsv+1) = 0.0
500	DO ii = 1, iim
501	matricevs(i,k,j-jfiltsv+1) = matricevs(i,k,j-jfiltsv+1)
502	. + eignfnu(i,ii)*eignft(ii,k)
503	ENDDO
504	ENDDO
505	ENDDO
506	#endif
507	#endif
508
509	ENDDO
510
511	c ...................................................................
512	c
513	c ... Calcul de la matrice filtre 'matrinv' pour les champs situes
514	c sur la grille scalaire , pour le filtre inverse ........
515	c ...................................................................
516	c
517	DO j = 2, jfiltnu
518
519	DO i = 1,iim
520	coff = coefilu(i,j)/ ( 1. + coefilu(i,j) )
521	IF( i.LT.modfrstu(j) ) coff = 0.
522	DO k=1,iim
523	eignft(i,k) = eignfnv(k,i) * coff
524	ENDDO
525	ENDDO
526	#ifdef CRAY
527	CALL MXM( eignfnv,iim,eignft,iim,matrinvn(1,1,j),iim )
528	#else
529	#ifdef BLAS
530	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0,
531	$ eignfnv, iim, eignft, iim, 0.0, matrinvn(1,1,j), iim)
532	#else
533	DO k = 1, iim
534	DO i = 1, iim
535	matrinvn(i,k,j) = 0.0
536	DO ii = 1, iim
537	matrinvn(i,k,j) = matrinvn(i,k,j)
538	. + eignfnv(i,ii)*eignft(ii,k)
539	ENDDO
540	ENDDO
541	ENDDO
542	#endif
543	#endif
544
545	ENDDO
546
547	DO j = jfiltsu, jjm
548
549	DO i = 1,iim
550	coff = coefilu(i,j) / ( 1. + coefilu(i,j) )
551	IF( i.LT.modfrstu(j) ) coff = 0.
552	DO k=1,iim
553	eignft(i,k) = eignfnv(k,i) * coff
554	ENDDO
555	ENDDO
556	#ifdef CRAY
557	CALL MXM(eignfnv,iim,eignft,iim,matrinvs(1,1,j-jfiltsu+1),iim)
558	#else
559	#ifdef BLAS
560	CALL SGEMM ('N', 'N', iim, iim, iim, 1.0,
561	$ eignfnv, iim, eignft, iim, 0.0, matrinvs(1,1,j-jfiltsu+1), iim)
562	#else
563	DO k = 1, iim
564	DO i = 1, iim
565	matrinvs(i,k,j-jfiltsu+1) = 0.0
566	DO ii = 1, iim
567	matrinvs(i,k,j-jfiltsu+1) = matrinvs(i,k,j-jfiltsu+1)
568	. + eignfnv(i,ii)*eignft(ii,k)
569	ENDDO
570	ENDDO
571	ENDDO
572	#endif
573	#endif
574
575	ENDDO
576
577	c ...................................................................
578
579	c
580	334 FORMAT(1x,24i3)
581	755 FORMAT(1x,6f10.3,i3)
582
583	RETURN
584	END

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