New URL for NEMO forge! http://forge.nemo-ocean.eu

Since March 2022 along with NEMO 4.2 release, the code development moved to a self-hosted GitLab.
This present forge is now archived and remained online for history.

diaharm.F90 in NEMO/branches/2019/dev_r10721_KERNEL-02_Storkey_Coward_IMMERSE_first_steps/src/OCE/DIA – NEMO

Context Navigation

source: NEMO/branches/2019/dev_r10721_KERNEL-02_Storkey_Coward_IMMERSE_first_steps/src/OCE/DIA/diaharm.F90 @ 10965

Last change on this file since 10965 was 10965, checked in by davestorkey, 5 years ago
2019/dev_r10721_KERNEL-02_Storkey_Coward_IMMERSE_first_steps : DIA and stpctl.F90. Just testing in ORCA1 so far.
Property svn:keywords set to `Id`
File size: 19.0 KB

Line
1	MODULE diaharm
2	!!======================================================================
3	!! * MODULE diaharm *
4	!! Harmonic analysis of tidal constituents
5	!!======================================================================
6	!! History : 3.1 ! 2007 (O. Le Galloudec, J. Chanut) Original code
7	!!----------------------------------------------------------------------
8	#if defined key_diaharm
9	!!----------------------------------------------------------------------
10	!! 'key_diaharm'
11	!!----------------------------------------------------------------------
12	USE oce ! ocean dynamics and tracers variables
13	USE dom_oce ! ocean space and time domain
14	USE phycst
15	USE daymod
16	USE tide_mod
17	USE sbctide ! Tidal forcing or not
18	!
19	USE in_out_manager ! I/O units
20	USE iom ! I/0 library
21	USE ioipsl ! NetCDF IPSL library
22	USE lbclnk ! ocean lateral boundary conditions (or mpp link)
23	USE timing ! preformance summary
24	USE lib_mpp ! MPP library
25
26	IMPLICIT NONE
27	PRIVATE
28
29	LOGICAL, PUBLIC, PARAMETER :: lk_diaharm = .TRUE.
30
31	INTEGER, PARAMETER :: jpincomax = 2.*jpmax_harmo
32	INTEGER, PARAMETER :: jpdimsparse = jpincomax30024
33
34	! !! namelist variables
35	INTEGER :: nit000_han ! First time step used for harmonic analysis
36	INTEGER :: nitend_han ! Last time step used for harmonic analysis
37	INTEGER :: nstep_han ! Time step frequency for harmonic analysis
38	INTEGER :: nb_ana ! Number of harmonics to analyse
39
40	INTEGER , ALLOCATABLE, DIMENSION(:) :: name
41	REAL(wp), ALLOCATABLE, DIMENSION(:,:,:,:) :: ana_temp
42	REAL(wp), ALLOCATABLE, DIMENSION(:) :: ana_freq, ut , vt , ft
43	REAL(wp), ALLOCATABLE, DIMENSION(:,:,:) :: out_eta , out_u, out_v
44
45	INTEGER :: ninco, nsparse
46	INTEGER , DIMENSION(jpdimsparse) :: njsparse, nisparse
47	INTEGER , SAVE, DIMENSION(jpincomax) :: ipos1
48	REAL(wp), DIMENSION(jpdimsparse) :: valuesparse
49	REAL(wp), DIMENSION(jpincomax) :: ztmp4 , ztmp7
50	REAL(wp), SAVE, DIMENSION(jpincomax,jpincomax) :: ztmp3 , zpilier
51	REAL(wp), SAVE, DIMENSION(jpincomax) :: zpivot
52
53	CHARACTER (LEN=4), DIMENSION(jpmax_harmo) :: tname ! Names of tidal constituents ('M2', 'K1',...)
54
55	PUBLIC dia_harm ! routine called by step.F90
56
57	!!----------------------------------------------------------------------
58	!! NEMO/OCE 4.0 , NEMO Consortium (2018)
59	!! $Id$
60	!! Software governed by the CeCILL license (see ./LICENSE)
61	!!----------------------------------------------------------------------
62	CONTAINS
63
64	SUBROUTINE dia_harm_init
65	!!----------------------------------------------------------------------
66	!! * ROUTINE dia_harm_init *
67	!!
68	!! ** Purpose : Initialization of tidal harmonic analysis
69	!!
70	!! ** Method : Initialize frequency array and nodal factor for nit000_han
71	!!
72	!!--------------------------------------------------------------------
73	INTEGER :: jh, nhan, jk, ji
74	INTEGER :: ios ! Local integer output status for namelist read
75
76	NAMELIST/nam_diaharm/ nit000_han, nitend_han, nstep_han, tname
77	!!----------------------------------------------------------------------
78
79	IF(lwp) THEN
80	WRITE(numout,*)
81	WRITE(numout,*) 'dia_harm_init: Tidal harmonic analysis initialization'
82	WRITE(numout,*) '~~~~~~~ '
83	ENDIF
84	!
85	IF( .NOT. ln_tide ) CALL ctl_stop( 'dia_harm_init : ln_tide must be true for harmonic analysis')
86	!
87	CALL tide_init_Wave
88	!
89	REWIND( numnam_ref ) ! Namelist nam_diaharm in reference namelist : Tidal harmonic analysis
90	READ ( numnam_ref, nam_diaharm, IOSTAT = ios, ERR = 901)
91	901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'nam_diaharm in reference namelist', lwp )
92	REWIND( numnam_cfg ) ! Namelist nam_diaharm in configuration namelist : Tidal harmonic analysis
93	READ ( numnam_cfg, nam_diaharm, IOSTAT = ios, ERR = 902 )
94	902 IF( ios > 0 ) CALL ctl_nam ( ios , 'nam_diaharm in configuration namelist', lwp )
95	IF(lwm) WRITE ( numond, nam_diaharm )
96	!
97	IF(lwp) THEN
98	WRITE(numout,*) 'First time step used for analysis: nit000_han= ', nit000_han
99	WRITE(numout,*) 'Last time step used for analysis: nitend_han= ', nitend_han
100	WRITE(numout,*) 'Time step frequency for harmonic analysis: nstep_han= ', nstep_han
101	ENDIF
102
103	! Basic checks on harmonic analysis time window:
104	! ----------------------------------------------
105	IF( nit000 > nit000_han ) CALL ctl_stop( 'dia_harm_init : nit000_han must be greater than nit000', &
106	& ' restart capability not implemented' )
107	IF( nitend < nitend_han ) CALL ctl_stop( 'dia_harm_init : nitend_han must be lower than nitend', &
108	& 'restart capability not implemented' )
109
110	IF( MOD( nitend_han-nit000_han+1 , nstep_han ) /= 0 ) &
111	& CALL ctl_stop( 'dia_harm_init : analysis time span must be a multiple of nstep_han' )
112
113	nb_ana = 0
114	DO jk=1,jpmax_harmo
115	DO ji=1,jpmax_harmo
116	IF(TRIM(tname(jk)) == Wave(ji)%cname_tide) THEN
117	nb_ana=nb_ana+1
118	ENDIF
119	END DO
120	END DO
121	!
122	IF(lwp) THEN
123	WRITE(numout,*) ' Namelist nam_diaharm'
124	WRITE(numout,*) ' nb_ana = ', nb_ana
125	CALL flush(numout)
126	ENDIF
127	!
128	IF (nb_ana > jpmax_harmo) THEN
129	WRITE(ctmp1,*) 'Can not use XIOS in iom_g0d, file: '//TRIM(clname)//', var:'//TRIM(cdvar)
130	WRITE(ctmp2,*) ' jpmax_harmo= ', jpmax_harmo
131	CALL ctl_stop( 'dia_harm_init', ctmp1, ctmp2 )
132	ENDIF
133
134	ALLOCATE(name (nb_ana))
135	DO jk=1,nb_ana
136	DO ji=1,jpmax_harmo
137	IF (TRIM(tname(jk)) == Wave(ji)%cname_tide) THEN
138	name(jk) = ji
139	EXIT
140	END IF
141	END DO
142	END DO
143
144	! Initialize frequency array:
145	! ---------------------------
146	ALLOCATE( ana_freq(nb_ana), ut(nb_ana), vt(nb_ana), ft(nb_ana) )
147
148	CALL tide_harmo( ana_freq, vt, ut, ft, name, nb_ana )
149
150	IF(lwp) WRITE(numout,*) 'Analysed frequency : ',nb_ana ,'Frequency '
151
152	DO jh = 1, nb_ana
153	IF(lwp) WRITE(numout,*) ' : ',tname(jh),' ',ana_freq(jh)
154	END DO
155
156	! Initialize temporary arrays:
157	! ----------------------------
158	ALLOCATE( ana_temp(jpi,jpj,2*nb_ana,3) )
159	ana_temp(:,:,:,:) = 0._wp
160
161	END SUBROUTINE dia_harm_init
162
163
164	SUBROUTINE dia_harm ( kt, Kmm )
165	!!----------------------------------------------------------------------
166	!! * ROUTINE dia_harm *
167	!!
168	!! ** Purpose : Tidal harmonic analysis main routine
169	!!
170	!! ** Action : Sums ssh/u/v over time analysis [nit000_han,nitend_han]
171	!!
172	!!--------------------------------------------------------------------
173	INTEGER, INTENT( IN ) :: kt
174	INTEGER, INTENT( IN ) :: Kmm ! time level index
175	!
176	INTEGER :: ji, jj, jh, jc, nhc
177	REAL(wp) :: ztime, ztemp
178	!!--------------------------------------------------------------------
179	IF( ln_timing ) CALL timing_start('dia_harm')
180	!
181	IF( kt == nit000 ) CALL dia_harm_init
182	!
183	IF( kt >= nit000_han .AND. kt <= nitend_han .AND. MOD(kt,nstep_han) == 0 ) THEN
184	!
185	ztime = (kt-nit000+1) * rdt
186	!
187	nhc = 0
188	DO jh = 1, nb_ana
189	DO jc = 1, 2
190	nhc = nhc+1
191	ztemp =( MOD(jc,2) * ft(jh) COS(ana_freq(jh)ztime + vt(jh) + ut(jh)) &
192	& +(1.-MOD(jc,2))* ft(jh) SIN(ana_freq(jh)ztime + vt(jh) + ut(jh)))
193	!
194	DO jj = 1,jpj
195	DO ji = 1,jpi
196	! Elevation
197	ana_temp(ji,jj,nhc,1) = ana_temp(ji,jj,nhc,1) + ztempssh(ji,jj,Kmm)ssmask (ji,jj)
198	ana_temp(ji,jj,nhc,2) = ana_temp(ji,jj,nhc,2) + ztempuu_b(ji,jj,Kmm)ssumask(ji,jj)
199	ana_temp(ji,jj,nhc,3) = ana_temp(ji,jj,nhc,3) + ztempvv_b(ji,jj,Kmm)ssvmask(ji,jj)
200	END DO
201	END DO
202	!
203	END DO
204	END DO
205	!
206	END IF
207	!
208	IF( kt == nitend_han ) CALL dia_harm_end
209	!
210	IF( ln_timing ) CALL timing_stop('dia_harm')
211	!
212	END SUBROUTINE dia_harm
213
214
215	SUBROUTINE dia_harm_end
216	!!----------------------------------------------------------------------
217	!! * ROUTINE diaharm_end *
218	!!
219	!! ** Purpose : Compute the Real and Imaginary part of tidal constituents
220	!!
221	!! ** Action : Decompose the signal on the harmonic constituents
222	!!
223	!!--------------------------------------------------------------------
224	INTEGER :: ji, jj, jh, jc, jn, nhan, jl
225	INTEGER :: ksp, kun, keq
226	REAL(wp) :: ztime, ztime_ini, ztime_end
227	REAL(wp) :: X1, X2
228	REAL(wp), DIMENSION(jpi,jpj,jpmax_harmo,2) :: ana_amp ! workspace
229	!!--------------------------------------------------------------------
230	!
231	IF(lwp) WRITE(numout,*)
232	IF(lwp) WRITE(numout,*) 'anharmo_end: kt=nitend_han: Perform harmonic analysis'
233	IF(lwp) WRITE(numout,*) '~~~~~~~~~~~~'
234
235	ztime_ini = nit000_han*rdt ! Initial time in seconds at the beginning of analysis
236	ztime_end = nitend_han*rdt ! Final time in seconds at the end of analysis
237	nhan = (nitend_han-nit000_han+1)/nstep_han ! Number of dumps used for analysis
238
239	ninco = 2*nb_ana
240
241	ksp = 0
242	keq = 0
243	DO jn = 1, nhan
244	ztime=( (nhan-jn)ztime_ini + (jn-1)ztime_end )/FLOAT(nhan-1)
245	keq = keq + 1
246	kun = 0
247	DO jh = 1, nb_ana
248	DO jc = 1, 2
249	kun = kun + 1
250	ksp = ksp + 1
251	nisparse(ksp) = keq
252	njsparse(ksp) = kun
253	valuesparse(ksp) = ( MOD(jc,2) * ft(jh) * COS(ana_freq(jh)*ztime + vt(jh) + ut(jh)) &
254	& + (1.-MOD(jc,2))* ft(jh) * SIN(ana_freq(jh)*ztime + vt(jh) + ut(jh)) )
255	END DO
256	END DO
257	END DO
258
259	nsparse = ksp
260
261	! Elevation:
262	DO jj = 1, jpj
263	DO ji = 1, jpi
264	! Fill input array
265	kun = 0
266	DO jh = 1, nb_ana
267	DO jc = 1, 2
268	kun = kun + 1
269	ztmp4(kun)=ana_temp(ji,jj,kun,1)
270	END DO
271	END DO
272
273	CALL SUR_DETERMINE(jj)
274
275	! Fill output array
276	DO jh = 1, nb_ana
277	ana_amp(ji,jj,jh,1)=ztmp7((jh-1)*2+1)
278	ana_amp(ji,jj,jh,2)=ztmp7((jh-1)*2+2)
279	END DO
280	END DO
281	END DO
282
283	ALLOCATE( out_eta(jpi,jpj,2*nb_ana), &
284	& out_u (jpi,jpj,2*nb_ana), &
285	& out_v (jpi,jpj,2*nb_ana) )
286
287	DO jj = 1, jpj
288	DO ji = 1, jpi
289	DO jh = 1, nb_ana
290	X1 = ana_amp(ji,jj,jh,1)
291	X2 =-ana_amp(ji,jj,jh,2)
292	out_eta(ji,jj,jh ) = X1 * tmask_i(ji,jj)
293	out_eta(ji,jj,jh+nb_ana) = X2 * tmask_i(ji,jj)
294	END DO
295	END DO
296	END DO
297
298	! ubar:
299	DO jj = 1, jpj
300	DO ji = 1, jpi
301	! Fill input array
302	kun=0
303	DO jh = 1,nb_ana
304	DO jc = 1,2
305	kun = kun + 1
306	ztmp4(kun)=ana_temp(ji,jj,kun,2)
307	END DO
308	END DO
309
310	CALL SUR_DETERMINE(jj+1)
311
312	! Fill output array
313	DO jh = 1, nb_ana
314	ana_amp(ji,jj,jh,1) = ztmp7((jh-1)*2+1)
315	ana_amp(ji,jj,jh,2) = ztmp7((jh-1)*2+2)
316	END DO
317
318	END DO
319	END DO
320
321	DO jj = 1, jpj
322	DO ji = 1, jpi
323	DO jh = 1, nb_ana
324	X1= ana_amp(ji,jj,jh,1)
325	X2=-ana_amp(ji,jj,jh,2)
326	out_u(ji,jj, jh) = X1 * ssumask(ji,jj)
327	out_u(ji,jj,nb_ana+jh) = X2 * ssumask(ji,jj)
328	ENDDO
329	ENDDO
330	ENDDO
331
332	! vbar:
333	DO jj = 1, jpj
334	DO ji = 1, jpi
335	! Fill input array
336	kun=0
337	DO jh = 1,nb_ana
338	DO jc = 1,2
339	kun = kun + 1
340	ztmp4(kun)=ana_temp(ji,jj,kun,3)
341	END DO
342	END DO
343
344	CALL SUR_DETERMINE(jj+1)
345
346	! Fill output array
347	DO jh = 1, nb_ana
348	ana_amp(ji,jj,jh,1)=ztmp7((jh-1)*2+1)
349	ana_amp(ji,jj,jh,2)=ztmp7((jh-1)*2+2)
350	END DO
351
352	END DO
353	END DO
354
355	DO jj = 1, jpj
356	DO ji = 1, jpi
357	DO jh = 1, nb_ana
358	X1=ana_amp(ji,jj,jh,1)
359	X2=-ana_amp(ji,jj,jh,2)
360	out_v(ji,jj, jh)=X1 * ssvmask(ji,jj)
361	out_v(ji,jj,nb_ana+jh)=X2 * ssvmask(ji,jj)
362	END DO
363	END DO
364	END DO
365	!
366	CALL dia_wri_harm ! Write results in files
367	!
368	END SUBROUTINE dia_harm_end
369
370
371	SUBROUTINE dia_wri_harm
372	!!--------------------------------------------------------------------
373	!! * ROUTINE dia_wri_harm *
374	!!
375	!! ** Purpose : Write tidal harmonic analysis results in a netcdf file
376	!!--------------------------------------------------------------------
377	CHARACTER(LEN=lc) :: cltext
378	CHARACTER(LEN=lc) :: &
379	cdfile_name_T , & ! name of the file created (T-points)
380	cdfile_name_U , & ! name of the file created (U-points)
381	cdfile_name_V ! name of the file created (V-points)
382	INTEGER :: jh
383	!!----------------------------------------------------------------------
384
385	IF(lwp) WRITE(numout,*) ' '
386	IF(lwp) WRITE(numout,*) 'dia_wri_harm : Write harmonic analysis results'
387	IF(lwp) WRITE(numout,*) ' '
388
389	! A) Elevation
390	!/////////////
391	!
392	DO jh = 1, nb_ana
393	CALL iom_put( TRIM(tname(jh))//'x', out_eta(:,:,jh) )
394	CALL iom_put( TRIM(tname(jh))//'y', out_eta(:,:,nb_ana+jh) )
395	END DO
396
397	! B) ubar
398	!/////////
399	!
400	DO jh = 1, nb_ana
401	CALL iom_put( TRIM(tname(jh))//'x_u', out_u(:,:,jh) )
402	CALL iom_put( TRIM(tname(jh))//'y_u', out_u(:,:,nb_ana+jh) )
403	END DO
404
405	! C) vbar
406	!/////////
407	!
408	DO jh = 1, nb_ana
409	CALL iom_put( TRIM(tname(jh))//'x_v', out_v(:,:,jh ) )
410	CALL iom_put( TRIM(tname(jh))//'y_v', out_v(:,:,jh+nb_ana) )
411	END DO
412	!
413	END SUBROUTINE dia_wri_harm
414
415
416	SUBROUTINE SUR_DETERMINE(init)
417	!!---------------------------------------------------------------------------------
418	!! * ROUTINE SUR_DETERMINE *
419	!!
420	!!
421	!!
422	!!---------------------------------------------------------------------------------
423	INTEGER, INTENT(in) :: init
424	!
425	INTEGER :: ji_sd, jj_sd, ji1_sd, ji2_sd, jk1_sd, jk2_sd
426	REAL(wp) :: zval1, zval2, zx1
427	REAL(wp), DIMENSION(jpincomax) :: ztmpx, zcol1, zcol2
428	INTEGER , DIMENSION(jpincomax) :: ipos2, ipivot
429	!---------------------------------------------------------------------------------
430	!
431	IF( init == 1 ) THEN
432	IF( nsparse > jpdimsparse ) CALL ctl_stop( 'STOP', 'SUR_DETERMINE : nsparse .GT. jpdimsparse')
433	IF( ninco > jpincomax ) CALL ctl_stop( 'STOP', 'SUR_DETERMINE : ninco .GT. jpincomax')
434	!
435	ztmp3(:,:) = 0._wp
436	!
437	DO jk1_sd = 1, nsparse
438	DO jk2_sd = 1, nsparse
439	nisparse(jk2_sd) = nisparse(jk2_sd)
440	njsparse(jk2_sd) = njsparse(jk2_sd)
441	IF( nisparse(jk2_sd) == nisparse(jk1_sd) ) THEN
442	ztmp3(njsparse(jk1_sd),njsparse(jk2_sd)) = ztmp3(njsparse(jk1_sd),njsparse(jk2_sd)) &
443	& + valuesparse(jk1_sd)*valuesparse(jk2_sd)
444	ENDIF
445	END DO
446	END DO
447	!
448	DO jj_sd = 1 ,ninco
449	ipos1(jj_sd) = jj_sd
450	ipos2(jj_sd) = jj_sd
451	END DO
452	!
453	DO ji_sd = 1 , ninco
454	!
455	!find greatest non-zero pivot:
456	zval1 = ABS(ztmp3(ji_sd,ji_sd))
457	!
458	ipivot(ji_sd) = ji_sd
459	DO jj_sd = ji_sd, ninco
460	zval2 = ABS(ztmp3(ji_sd,jj_sd))
461	IF( zval2 >= zval1 )THEN
462	ipivot(ji_sd) = jj_sd
463	zval1 = zval2
464	ENDIF
465	END DO
466	!
467	DO ji1_sd = 1, ninco
468	zcol1(ji1_sd) = ztmp3(ji1_sd,ji_sd)
469	zcol2(ji1_sd) = ztmp3(ji1_sd,ipivot(ji_sd))
470	ztmp3(ji1_sd,ji_sd) = zcol2(ji1_sd)
471	ztmp3(ji1_sd,ipivot(ji_sd)) = zcol1(ji1_sd)
472	END DO
473	!
474	ipos2(ji_sd) = ipos1(ipivot(ji_sd))
475	ipos2(ipivot(ji_sd)) = ipos1(ji_sd)
476	ipos1(ji_sd) = ipos2(ji_sd)
477	ipos1(ipivot(ji_sd)) = ipos2(ipivot(ji_sd))
478	zpivot(ji_sd) = ztmp3(ji_sd,ji_sd)
479	DO jj_sd = 1, ninco
480	ztmp3(ji_sd,jj_sd) = ztmp3(ji_sd,jj_sd) / zpivot(ji_sd)
481	END DO
482	!
483	DO ji2_sd = ji_sd+1, ninco
484	zpilier(ji2_sd,ji_sd)=ztmp3(ji2_sd,ji_sd)
485	DO jj_sd=1,ninco
486	ztmp3(ji2_sd,jj_sd)= ztmp3(ji2_sd,jj_sd) - ztmp3(ji_sd,jj_sd) * zpilier(ji2_sd,ji_sd)
487	END DO
488	END DO
489	!
490	END DO
491	!
492	ENDIF ! End init==1
493
494	DO ji_sd = 1, ninco
495	ztmp4(ji_sd) = ztmp4(ji_sd) / zpivot(ji_sd)
496	DO ji2_sd = ji_sd+1, ninco
497	ztmp4(ji2_sd) = ztmp4(ji2_sd) - ztmp4(ji_sd) * zpilier(ji2_sd,ji_sd)
498	END DO
499	END DO
500
501	!system solving:
502	ztmpx(ninco) = ztmp4(ninco) / ztmp3(ninco,ninco)
503	ji_sd = ninco
504	DO ji_sd = ninco-1, 1, -1
505	zx1 = 0._wp
506	DO jj_sd = ji_sd+1, ninco
507	zx1 = zx1 + ztmpx(jj_sd) * ztmp3(ji_sd,jj_sd)
508	END DO
509	ztmpx(ji_sd) = ztmp4(ji_sd)-zx1
510	END DO
511
512	DO jj_sd =1, ninco
513	ztmp7(ipos1(jj_sd))=ztmpx(jj_sd)
514	END DO
515	!
516	END SUBROUTINE SUR_DETERMINE
517
518	#else
519	!!----------------------------------------------------------------------
520	!! Default case : Empty module
521	!!----------------------------------------------------------------------
522	LOGICAL, PUBLIC, PARAMETER :: lk_diaharm = .FALSE.
523	CONTAINS
524	SUBROUTINE dia_harm ( kt, Kmm ) ! Empty routine
525	INTEGER, INTENT( IN ) :: kt
526	INTEGER, INTENT( IN ) :: Kmm
527	WRITE(,) 'dia_harm: you should not have seen this print'
528	END SUBROUTINE dia_harm
529	#endif
530
531	!!======================================================================
532	END MODULE diaharm

Note: See TracBrowser for help on using the repository browser.

Download in other formats: