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bdytides.F90 in NEMO/branches/2019/dev_r10742_ENHANCE-12_SimonM-Tides/src/OCE/BDY – NEMO

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source: NEMO/branches/2019/dev_r10742_ENHANCE-12_SimonM-Tides/src/OCE/BDY/bdytides.F90 @ 12059

Last change on this file since 12059 was 12059, checked in by smueller, 4 years ago
Reversal of changeset [10865] to avoid a conflict in the upcoming sync merge with the trunk; a new version of the modification implemented by changeset [10865] will be applied following the upcoming sync merge with the trunk (ticket #2194)
Property svn:keywords set to `Id`
File size: 27.1 KB

Line
1	MODULE bdytides
2	!!======================================================================
3	!! * MODULE bdytides *
4	!! Ocean dynamics: Tidal forcing at open boundaries
5	!!======================================================================
6	!! History : 2.0 ! 2007-01 (D.Storkey) Original code
7	!! 2.3 ! 2008-01 (J.Holt) Add date correction. Origins POLCOMS v6.3 2007
8	!! 3.0 ! 2008-04 (NEMO team) add in the reference version
9	!! 3.3 ! 2010-09 (D.Storkey and E.O'Dea) bug fixes
10	!! 3.4 ! 2012-09 (G. Reffray and J. Chanut) New inputs + mods
11	!! 3.5 ! 2013-07 (J. Chanut) Compliant with time splitting changes
12	!!----------------------------------------------------------------------
13	!! bdytide_init : read of namelist and initialisation of tidal harmonics data
14	!! tide_update : calculation of tidal forcing at each timestep
15	!!----------------------------------------------------------------------
16	USE oce ! ocean dynamics and tracers
17	USE dom_oce ! ocean space and time domain
18	USE phycst ! physical constants
19	USE bdy_oce ! ocean open boundary conditions
20	USE tide_mod !
21	USE daymod ! calendar
22	!
23	USE in_out_manager ! I/O units
24	USE iom ! xIO server
25	USE fldread !
26	USE lbclnk ! ocean lateral boundary conditions (or mpp link)
27
28	IMPLICIT NONE
29	PRIVATE
30
31	PUBLIC bdytide_init ! routine called in bdy_init
32	PUBLIC bdytide_update ! routine called in bdy_dta
33	PUBLIC bdy_dta_tides ! routine called in dyn_spg_ts
34
35	TYPE, PUBLIC :: TIDES_DATA !: Storage for external tidal harmonics data
36	REAL(wp), POINTER, DIMENSION(:,:,:) :: ssh0 !: Tidal constituents : SSH0 (read in file)
37	REAL(wp), POINTER, DIMENSION(:,:,:) :: u0, v0 !: Tidal constituents : U0, V0 (read in file)
38	REAL(wp), POINTER, DIMENSION(:,:,:) :: ssh !: Tidal constituents : SSH (after nodal cor.)
39	REAL(wp), POINTER, DIMENSION(:,:,:) :: u , v !: Tidal constituents : U , V (after nodal cor.)
40	END TYPE TIDES_DATA
41
42	!$AGRIF_DO_NOT_TREAT
43	TYPE(TIDES_DATA), PUBLIC, DIMENSION(jp_bdy), TARGET :: tides !: External tidal harmonics data
44	!$AGRIF_END_DO_NOT_TREAT
45	TYPE(OBC_DATA) , PUBLIC, DIMENSION(jp_bdy) :: dta_bdy_s !: bdy external data (slow component)
46
47	INTEGER :: kt_tide
48
49	!!----------------------------------------------------------------------
50	!! NEMO/OCE 4.0 , NEMO Consortium (2018)
51	!! $Id$
52	!! Software governed by the CeCILL license (see ./LICENSE)
53	!!----------------------------------------------------------------------
54	CONTAINS
55
56	SUBROUTINE bdytide_init
57	!!----------------------------------------------------------------------
58	!! * SUBROUTINE bdytide_init *
59	!!
60	!! ** Purpose : - Read in namelist for tides and initialise external
61	!! tidal harmonics data
62	!!
63	!!----------------------------------------------------------------------
64	!! namelist variables
65	!!-------------------
66	CHARACTER(len=80) :: filtide !: Filename root for tidal input files
67	LOGICAL :: ln_bdytide_2ddta !: If true, read 2d harmonic data
68	!!
69	INTEGER :: ib_bdy, itide, ib !: dummy loop indices
70	INTEGER :: ii, ij !: dummy loop indices
71	INTEGER :: inum, igrd
72	INTEGER, DIMENSION(3) :: ilen0 !: length of boundary data (from OBC arrays)
73	INTEGER, POINTER, DIMENSION(:) :: nblen, nblenrim ! short cuts
74	INTEGER :: ios ! Local integer output status for namelist read
75	CHARACTER(len=80) :: clfile !: full file name for tidal input file
76	REAL(wp),ALLOCATABLE, DIMENSION(:,:,:) :: dta_read !: work space to read in tidal harmonics data
77	REAL(wp),ALLOCATABLE, DIMENSION(:,:) :: ztr, zti !: " " " " " " " "
78	!!
79	TYPE(TIDES_DATA), POINTER :: td !: local short cut
80	TYPE(MAP_POINTER), DIMENSION(jpbgrd) :: ibmap_ptr !: array of pointers to nbmap
81	!!
82	NAMELIST/nambdy_tide/filtide, ln_bdytide_2ddta
83	!!----------------------------------------------------------------------
84	!
85	IF (nb_bdy>0) THEN
86	IF(lwp) WRITE(numout,*)
87	IF(lwp) WRITE(numout,*) 'bdytide_init : initialization of tidal harmonic forcing at open boundaries'
88	IF(lwp) WRITE(numout,*) '~~~~~~~~~~~~'
89	ENDIF
90
91	REWIND(numnam_cfg)
92
93	DO ib_bdy = 1, nb_bdy
94	IF( nn_dyn2d_dta(ib_bdy) >= 2 ) THEN
95	!
96	td => tides(ib_bdy)
97	nblen => idx_bdy(ib_bdy)%nblen
98	nblenrim => idx_bdy(ib_bdy)%nblenrim
99
100	! Namelist nambdy_tide : tidal harmonic forcing at open boundaries
101	filtide(:) = ''
102
103	! Don't REWIND here - may need to read more than one of these namelists.
104	READ ( numnam_ref, nambdy_tide, IOSTAT = ios, ERR = 901)
105	901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'nambdy_tide in reference namelist', lwp )
106	READ ( numnam_cfg, nambdy_tide, IOSTAT = ios, ERR = 902 )
107	902 IF( ios > 0 ) CALL ctl_nam ( ios , 'nambdy_tide in configuration namelist', lwp )
108	IF(lwm) WRITE ( numond, nambdy_tide )
109	! ! Parameter control and print
110	IF(lwp) WRITE(numout,*) ' '
111	IF(lwp) WRITE(numout,*) ' Namelist nambdy_tide : tidal harmonic forcing at open boundaries'
112	IF(lwp) WRITE(numout,*) ' read tidal data in 2d files: ', ln_bdytide_2ddta
113	IF(lwp) WRITE(numout,*) ' Number of tidal components to read: ', nb_harmo
114	IF(lwp) THEN
115	WRITE(numout,*) ' Tidal components: '
116	DO itide = 1, nb_harmo
117	WRITE(numout,*) ' ', tide_harmonics(itide)%cname_tide
118	END DO
119	ENDIF
120	IF(lwp) WRITE(numout,*) ' '
121
122	! Allocate space for tidal harmonics data - get size from OBC data arrays
123	! -----------------------------------------------------------------------
124
125	! JC: If FRS scheme is used, we assume that tidal is needed over the whole
126	! relaxation area
127	IF( cn_dyn2d(ib_bdy) == 'frs' ) THEN ; ilen0(:) = nblen (:)
128	ELSE ; ilen0(:) = nblenrim(:)
129	ENDIF
130
131	ALLOCATE( td%ssh0( ilen0(1), nb_harmo, 2 ) )
132	ALLOCATE( td%ssh ( ilen0(1), nb_harmo, 2 ) )
133
134	ALLOCATE( td%u0( ilen0(2), nb_harmo, 2 ) )
135	ALLOCATE( td%u ( ilen0(2), nb_harmo, 2 ) )
136
137	ALLOCATE( td%v0( ilen0(3), nb_harmo, 2 ) )
138	ALLOCATE( td%v ( ilen0(3), nb_harmo, 2 ) )
139
140	td%ssh0(:,:,:) = 0._wp
141	td%ssh (:,:,:) = 0._wp
142	td%u0 (:,:,:) = 0._wp
143	td%u (:,:,:) = 0._wp
144	td%v0 (:,:,:) = 0._wp
145	td%v (:,:,:) = 0._wp
146
147	IF( ln_bdytide_2ddta ) THEN
148	! It is assumed that each data file contains all complex harmonic amplitudes
149	! given on the global domain (ie global, jpiglo x jpjglo)
150	!
151	ALLOCATE( zti(jpi,jpj), ztr(jpi,jpj) )
152	!
153	! SSH fields
154	clfile = TRIM(filtide)//'_grid_T.nc'
155	CALL iom_open( clfile , inum )
156	igrd = 1 ! Everything is at T-points here
157	DO itide = 1, nb_harmo
158	CALL iom_get( inum, jpdom_autoglo, TRIM(tide_harmonics(itide)%cname_tide)//'_z1', ztr(:,:) )
159	CALL iom_get( inum, jpdom_autoglo, TRIM(tide_harmonics(itide)%cname_tide)//'_z2', zti(:,:) )
160	DO ib = 1, ilen0(igrd)
161	ii = idx_bdy(ib_bdy)%nbi(ib,igrd)
162	ij = idx_bdy(ib_bdy)%nbj(ib,igrd)
163	td%ssh0(ib,itide,1) = ztr(ii,ij)
164	td%ssh0(ib,itide,2) = zti(ii,ij)
165	END DO
166	END DO
167	CALL iom_close( inum )
168	!
169	! U fields
170	clfile = TRIM(filtide)//'_grid_U.nc'
171	CALL iom_open( clfile , inum )
172	igrd = 2 ! Everything is at U-points here
173	DO itide = 1, nb_harmo
174	CALL iom_get ( inum, jpdom_autoglo, TRIM(tide_harmonics(itide)%cname_tide)//'_u1', ztr(:,:) )
175	CALL iom_get ( inum, jpdom_autoglo, TRIM(tide_harmonics(itide)%cname_tide)//'_u2', zti(:,:) )
176	DO ib = 1, ilen0(igrd)
177	ii = idx_bdy(ib_bdy)%nbi(ib,igrd)
178	ij = idx_bdy(ib_bdy)%nbj(ib,igrd)
179	td%u0(ib,itide,1) = ztr(ii,ij)
180	td%u0(ib,itide,2) = zti(ii,ij)
181	END DO
182	END DO
183	CALL iom_close( inum )
184	!
185	! V fields
186	clfile = TRIM(filtide)//'_grid_V.nc'
187	CALL iom_open( clfile , inum )
188	igrd = 3 ! Everything is at V-points here
189	DO itide = 1, nb_harmo
190	CALL iom_get ( inum, jpdom_autoglo, TRIM(tide_harmonics(itide)%cname_tide)//'_v1', ztr(:,:) )
191	CALL iom_get ( inum, jpdom_autoglo, TRIM(tide_harmonics(itide)%cname_tide)//'_v2', zti(:,:) )
192	DO ib = 1, ilen0(igrd)
193	ii = idx_bdy(ib_bdy)%nbi(ib,igrd)
194	ij = idx_bdy(ib_bdy)%nbj(ib,igrd)
195	td%v0(ib,itide,1) = ztr(ii,ij)
196	td%v0(ib,itide,2) = zti(ii,ij)
197	END DO
198	END DO
199	CALL iom_close( inum )
200	!
201	DEALLOCATE( ztr, zti )
202	!
203	ELSE
204	!
205	! Read tidal data only on bdy segments
206	!
207	ALLOCATE( dta_read( MAXVAL(ilen0(1:3)), 1, 1 ) )
208	!
209	! Set map structure
210	ibmap_ptr(1)%ptr => idx_bdy(ib_bdy)%nbmap(:,1) ; ibmap_ptr(1)%ll_unstruc = ln_coords_file(ib_bdy)
211	ibmap_ptr(2)%ptr => idx_bdy(ib_bdy)%nbmap(:,2) ; ibmap_ptr(2)%ll_unstruc = ln_coords_file(ib_bdy)
212	ibmap_ptr(3)%ptr => idx_bdy(ib_bdy)%nbmap(:,3) ; ibmap_ptr(3)%ll_unstruc = ln_coords_file(ib_bdy)
213
214	! Open files and read in tidal forcing data
215	! -----------------------------------------
216
217	DO itide = 1, nb_harmo
218	! ! SSH fields
219	clfile = TRIM(filtide)//TRIM(tide_harmonics(itide)%cname_tide)//'_grid_T.nc'
220	CALL iom_open( clfile, inum )
221	CALL fld_map( inum, 'z1' , dta_read(1:ilen0(1),1:1,1:1) , 1, ibmap_ptr(1) )
222	td%ssh0(:,itide,1) = dta_read(1:ilen0(1),1,1)
223	CALL fld_map( inum, 'z2' , dta_read(1:ilen0(1),1:1,1:1) , 1, ibmap_ptr(1) )
224	td%ssh0(:,itide,2) = dta_read(1:ilen0(1),1,1)
225	CALL iom_close( inum )
226	! ! U fields
227	clfile = TRIM(filtide)//TRIM(tide_harmonics(itide)%cname_tide)//'_grid_U.nc'
228	CALL iom_open( clfile, inum )
229	CALL fld_map( inum, 'u1' , dta_read(1:ilen0(2),1:1,1:1) , 1, ibmap_ptr(2) )
230	td%u0(:,itide,1) = dta_read(1:ilen0(2),1,1)
231	CALL fld_map( inum, 'u2' , dta_read(1:ilen0(2),1:1,1:1) , 1, ibmap_ptr(2) )
232	td%u0(:,itide,2) = dta_read(1:ilen0(2),1,1)
233	CALL iom_close( inum )
234	! ! V fields
235	clfile = TRIM(filtide)//TRIM(tide_harmonics(itide)%cname_tide)//'_grid_V.nc'
236	CALL iom_open( clfile, inum )
237	CALL fld_map( inum, 'v1' , dta_read(1:ilen0(3),1:1,1:1) , 1, ibmap_ptr(3) )
238	td%v0(:,itide,1) = dta_read(1:ilen0(3),1,1)
239	CALL fld_map( inum, 'v2' , dta_read(1:ilen0(3),1:1,1:1) , 1, ibmap_ptr(3) )
240	td%v0(:,itide,2) = dta_read(1:ilen0(3),1,1)
241	CALL iom_close( inum )
242	!
243	END DO ! end loop on tidal components
244	!
245	DEALLOCATE( dta_read )
246	!
247	ENDIF ! ln_bdytide_2ddta=.true.
248	!
249	! Allocate slow varying data in the case of time splitting:
250	! Do it anyway because at this stage knowledge of free surface scheme is unknown
251	ALLOCATE( dta_bdy_s(ib_bdy)%ssh ( ilen0(1) ) )
252	ALLOCATE( dta_bdy_s(ib_bdy)%u2d ( ilen0(2) ) )
253	ALLOCATE( dta_bdy_s(ib_bdy)%v2d ( ilen0(3) ) )
254	dta_bdy_s(ib_bdy)%ssh(:) = 0._wp
255	dta_bdy_s(ib_bdy)%u2d(:) = 0._wp
256	dta_bdy_s(ib_bdy)%v2d(:) = 0._wp
257	!
258	ENDIF ! nn_dyn2d_dta(ib_bdy) >= 2
259	!
260	END DO ! loop on ib_bdy
261	!
262	END SUBROUTINE bdytide_init
263
264
265	SUBROUTINE bdytide_update( kt, idx, dta, td, jit, time_offset )
266	!!----------------------------------------------------------------------
267	!! * SUBROUTINE bdytide_update *
268	!!
269	!! ** Purpose : - Add tidal forcing to ssh, u2d and v2d OBC data arrays.
270	!!
271	!!----------------------------------------------------------------------
272	INTEGER , INTENT(in ) :: kt ! Main timestep counter
273	TYPE(OBC_INDEX) , INTENT(in ) :: idx ! OBC indices
274	TYPE(OBC_DATA) , INTENT(inout) :: dta ! OBC external data
275	TYPE(TIDES_DATA) , INTENT(inout) :: td ! tidal harmonics data
276	INTEGER, OPTIONAL, INTENT(in ) :: jit ! Barotropic timestep counter (for timesplitting option)
277	INTEGER, OPTIONAL, INTENT(in ) :: time_offset ! time offset in units of timesteps. NB. if jit
278	! ! is present then units = subcycle timesteps.
279	! ! time_offset = 0 => get data at "now" time level
280	! ! time_offset = -1 => get data at "before" time level
281	! ! time_offset = +1 => get data at "after" time level
282	! ! etc.
283	!
284	INTEGER :: itide, igrd, ib ! dummy loop indices
285	INTEGER :: time_add ! time offset in units of timesteps
286	INTEGER, DIMENSION(3) :: ilen0 ! length of boundary data (from OBC arrays)
287	REAL(wp) :: z_arg, z_sarg, zflag, zramp ! local scalars
288	REAL(wp), DIMENSION(jpmax_harmo) :: z_sist, z_cost
289	!!----------------------------------------------------------------------
290	!
291	ilen0(1) = SIZE(td%ssh(:,1,1))
292	ilen0(2) = SIZE(td%u(:,1,1))
293	ilen0(3) = SIZE(td%v(:,1,1))
294
295	zflag=1
296	IF ( PRESENT(jit) ) THEN
297	IF ( jit /= 1 ) zflag=0
298	ENDIF
299
300	IF ( (nsec_day == NINT(0.5_wp * rdt) .OR. kt==nit000) .AND. zflag==1 ) THEN
301	!
302	kt_tide = kt - (nsec_day - 0.5_wp * rdt)/rdt
303	!
304	IF(lwp) THEN
305	WRITE(numout,*)
306	WRITE(numout,*) 'bdytide_update : (re)Initialization of the tidal bdy forcing at kt=',kt
307	WRITE(numout,*) '~~~~~~~~~~~~~~ '
308	ENDIF
309	!
310	CALL tide_init_elevation ( idx, td )
311	CALL tide_init_velocities( idx, td )
312	!
313	ENDIF
314
315	time_add = 0
316	IF( PRESENT(time_offset) ) THEN
317	time_add = time_offset
318	ENDIF
319
320	IF( PRESENT(jit) ) THEN
321	z_arg = ((kt-kt_tide) * rdt + (jit+0.5_wp(time_add-1)) rdt / REAL(nn_baro,wp) )
322	ELSE
323	z_arg = ((kt-kt_tide)+time_add) * rdt
324	ENDIF
325
326	! Linear ramp on tidal component at open boundaries
327	zramp = 1._wp
328	IF (ln_tide_ramp) zramp = MIN(MAX( (z_arg + (kt_tide-nit000)rdt)/(rn_tide_ramp_dtrday),0._wp),1._wp)
329
330	DO itide = 1, nb_harmo
331	z_sarg = z_arg * tide_harmonics(itide)%omega
332	z_cost(itide) = COS( z_sarg )
333	z_sist(itide) = SIN( z_sarg )
334	END DO
335
336	DO itide = 1, nb_harmo
337	igrd=1 ! SSH on tracer grid
338	DO ib = 1, ilen0(igrd)
339	dta%ssh(ib) = dta%ssh(ib) + zramp(td%ssh(ib,itide,1)z_cost(itide) + td%ssh(ib,itide,2)*z_sist(itide))
340	END DO
341	igrd=2 ! U grid
342	DO ib = 1, ilen0(igrd)
343	dta%u2d(ib) = dta%u2d(ib) + zramp(td%u (ib,itide,1)z_cost(itide) + td%u (ib,itide,2)*z_sist(itide))
344	END DO
345	igrd=3 ! V grid
346	DO ib = 1, ilen0(igrd)
347	dta%v2d(ib) = dta%v2d(ib) + zramp(td%v (ib,itide,1)z_cost(itide) + td%v (ib,itide,2)*z_sist(itide))
348	END DO
349	END DO
350	!
351	END SUBROUTINE bdytide_update
352
353
354	SUBROUTINE bdy_dta_tides( kt, kit, time_offset )
355	!!----------------------------------------------------------------------
356	!! * SUBROUTINE bdy_dta_tides *
357	!!
358	!! ** Purpose : - Add tidal forcing to ssh, u2d and v2d OBC data arrays.
359	!!
360	!!----------------------------------------------------------------------
361	INTEGER, INTENT(in) :: kt ! Main timestep counter
362	INTEGER, OPTIONAL, INTENT(in) :: kit ! Barotropic timestep counter (for timesplitting option)
363	INTEGER, OPTIONAL, INTENT(in) :: time_offset ! time offset in units of timesteps. NB. if kit
364	! ! is present then units = subcycle timesteps.
365	! ! time_offset = 0 => get data at "now" time level
366	! ! time_offset = -1 => get data at "before" time level
367	! ! time_offset = +1 => get data at "after" time level
368	! ! etc.
369	!
370	LOGICAL :: lk_first_btstp ! =.TRUE. if time splitting and first barotropic step
371	INTEGER :: itide, ib_bdy, ib, igrd ! loop indices
372	INTEGER :: time_add ! time offset in units of timesteps
373	INTEGER, DIMENSION(jpbgrd) :: ilen0
374	INTEGER, DIMENSION(1:jpbgrd) :: nblen, nblenrim ! short cuts
375	REAL(wp) :: z_arg, z_sarg, zramp, zoff, z_cost, z_sist
376	!!----------------------------------------------------------------------
377	!
378	lk_first_btstp=.TRUE.
379	IF ( PRESENT(kit).AND.( kit /= 1 ) ) THEN ; lk_first_btstp=.FALSE. ; ENDIF
380
381	time_add = 0
382	IF( PRESENT(time_offset) ) THEN
383	time_add = time_offset
384	ENDIF
385
386	! Absolute time from model initialization:
387	IF( PRESENT(kit) ) THEN
388	z_arg = ( kt + (kit+time_add-1) / REAL(nn_baro,wp) ) * rdt
389	ELSE
390	z_arg = ( kt + time_add ) * rdt
391	ENDIF
392
393	! Linear ramp on tidal component at open boundaries
394	zramp = 1.
395	IF (ln_tide_ramp) zramp = MIN(MAX( (z_arg - nit000rdt)/(rn_tide_ramp_dtrday),0.),1.)
396
397	DO ib_bdy = 1,nb_bdy
398	!
399	IF( nn_dyn2d_dta(ib_bdy) >= 2 ) THEN
400	!
401	nblen(1:jpbgrd) = idx_bdy(ib_bdy)%nblen(1:jpbgrd)
402	nblenrim(1:jpbgrd) = idx_bdy(ib_bdy)%nblenrim(1:jpbgrd)
403	!
404	IF( cn_dyn2d(ib_bdy) == 'frs' ) THEN ; ilen0(:) = nblen (:)
405	ELSE ; ilen0(:) = nblenrim(:)
406	ENDIF
407	!
408	! We refresh nodal factors every day below
409	! This should be done somewhere else
410	IF ( ( nsec_day == NINT(0.5_wp * rdt) .OR. kt==nit000 ) .AND. lk_first_btstp ) THEN
411	!
412	kt_tide = kt - (nsec_day - 0.5_wp * rdt)/rdt
413	!
414	IF(lwp) THEN
415	WRITE(numout,*)
416	WRITE(numout,*) 'bdy_tide_dta : Refresh nodal factors for tidal open bdy data at kt=',kt
417	WRITE(numout,*) '~~~~~~~~~~~~~~ '
418	ENDIF
419	!
420	CALL tide_init_elevation ( idx=idx_bdy(ib_bdy), td=tides(ib_bdy) )
421	CALL tide_init_velocities( idx=idx_bdy(ib_bdy), td=tides(ib_bdy) )
422	!
423	ENDIF
424	zoff = -kt_tide * rdt ! time offset relative to nodal factor computation time
425	!
426	! If time splitting, initialize arrays from slow varying open boundary data:
427	IF ( PRESENT(kit) ) THEN
428	IF ( dta_bdy(ib_bdy)%ll_ssh ) dta_bdy(ib_bdy)%ssh(1:ilen0(1)) = dta_bdy_s(ib_bdy)%ssh(1:ilen0(1))
429	IF ( dta_bdy(ib_bdy)%ll_u2d ) dta_bdy(ib_bdy)%u2d(1:ilen0(2)) = dta_bdy_s(ib_bdy)%u2d(1:ilen0(2))
430	IF ( dta_bdy(ib_bdy)%ll_v2d ) dta_bdy(ib_bdy)%v2d(1:ilen0(3)) = dta_bdy_s(ib_bdy)%v2d(1:ilen0(3))
431	ENDIF
432	!
433	! Update open boundary data arrays:
434	DO itide = 1, nb_harmo
435	!
436	z_sarg = (z_arg + zoff) * tide_harmonics(itide)%omega
437	z_cost = zramp * COS( z_sarg )
438	z_sist = zramp * SIN( z_sarg )
439	!
440	IF ( dta_bdy(ib_bdy)%ll_ssh ) THEN
441	igrd=1 ! SSH on tracer grid
442	DO ib = 1, ilen0(igrd)
443	dta_bdy(ib_bdy)%ssh(ib) = dta_bdy(ib_bdy)%ssh(ib) + &
444	& ( tides(ib_bdy)%ssh(ib,itide,1)*z_cost + &
445	& tides(ib_bdy)%ssh(ib,itide,2)*z_sist )
446	END DO
447	ENDIF
448	!
449	IF ( dta_bdy(ib_bdy)%ll_u2d ) THEN
450	igrd=2 ! U grid
451	DO ib = 1, ilen0(igrd)
452	dta_bdy(ib_bdy)%u2d(ib) = dta_bdy(ib_bdy)%u2d(ib) + &
453	& ( tides(ib_bdy)%u(ib,itide,1)*z_cost + &
454	& tides(ib_bdy)%u(ib,itide,2)*z_sist )
455	END DO
456	ENDIF
457	!
458	IF ( dta_bdy(ib_bdy)%ll_v2d ) THEN
459	igrd=3 ! V grid
460	DO ib = 1, ilen0(igrd)
461	dta_bdy(ib_bdy)%v2d(ib) = dta_bdy(ib_bdy)%v2d(ib) + &
462	& ( tides(ib_bdy)%v(ib,itide,1)*z_cost + &
463	& tides(ib_bdy)%v(ib,itide,2)*z_sist )
464	END DO
465	ENDIF
466	END DO
467	END IF
468	END DO
469	!
470	END SUBROUTINE bdy_dta_tides
471
472
473	SUBROUTINE tide_init_elevation( idx, td )
474	!!----------------------------------------------------------------------
475	!! * ROUTINE tide_init_elevation *
476	!!----------------------------------------------------------------------
477	TYPE(OBC_INDEX) , INTENT(in ) :: idx ! OBC indices
478	TYPE(TIDES_DATA), INTENT(inout) :: td ! tidal harmonics data
479	!
480	INTEGER :: itide, igrd, ib ! dummy loop indices
481	INTEGER, DIMENSION(1) :: ilen0 ! length of boundary data (from OBC arrays)
482	REAL(wp),ALLOCATABLE, DIMENSION(:) :: mod_tide, phi_tide
483	!!----------------------------------------------------------------------
484	!
485	igrd=1
486	! SSH on tracer grid.
487	ilen0(1) = SIZE(td%ssh0(:,1,1))
488	!
489	ALLOCATE( mod_tide(ilen0(igrd)), phi_tide(ilen0(igrd)) )
490	!
491	DO itide = 1, nb_harmo
492	DO ib = 1, ilen0(igrd)
493	mod_tide(ib)=SQRT(td%ssh0(ib,itide,1)2.+td%ssh0(ib,itide,2)2.)
494	phi_tide(ib)=ATAN2(-td%ssh0(ib,itide,2),td%ssh0(ib,itide,1))
495	END DO
496	DO ib = 1 , ilen0(igrd)
497	mod_tide(ib)=mod_tide(ib)*tide_harmonics(itide)%f
498	phi_tide(ib)=phi_tide(ib)+tide_harmonics(itide)%v0+tide_harmonics(itide)%u
499	ENDDO
500	DO ib = 1 , ilen0(igrd)
501	td%ssh(ib,itide,1)= mod_tide(ib)*COS(phi_tide(ib))
502	td%ssh(ib,itide,2)=-mod_tide(ib)*SIN(phi_tide(ib))
503	ENDDO
504	END DO
505	!
506	DEALLOCATE( mod_tide, phi_tide )
507	!
508	END SUBROUTINE tide_init_elevation
509
510
511	SUBROUTINE tide_init_velocities( idx, td )
512	!!----------------------------------------------------------------------
513	!! * ROUTINE tide_init_elevation *
514	!!----------------------------------------------------------------------
515	TYPE(OBC_INDEX) , INTENT(in ) :: idx ! OBC indices
516	TYPE(TIDES_DATA), INTENT(inout) :: td ! tidal harmonics data
517	!
518	INTEGER :: itide, igrd, ib ! dummy loop indices
519	INTEGER, DIMENSION(3) :: ilen0 ! length of boundary data (from OBC arrays)
520	REAL(wp),ALLOCATABLE, DIMENSION(:) :: mod_tide, phi_tide
521	!!----------------------------------------------------------------------
522	!
523	ilen0(2) = SIZE(td%u0(:,1,1))
524	ilen0(3) = SIZE(td%v0(:,1,1))
525	!
526	igrd=2 ! U grid.
527	!
528	ALLOCATE( mod_tide(ilen0(igrd)) , phi_tide(ilen0(igrd)) )
529	!
530	DO itide = 1, nb_harmo
531	DO ib = 1, ilen0(igrd)
532	mod_tide(ib)=SQRT(td%u0(ib,itide,1)2.+td%u0(ib,itide,2)2.)
533	phi_tide(ib)=ATAN2(-td%u0(ib,itide,2),td%u0(ib,itide,1))
534	END DO
535	DO ib = 1, ilen0(igrd)
536	mod_tide(ib)=mod_tide(ib)*tide_harmonics(itide)%f
537	phi_tide(ib)=phi_tide(ib)+tide_harmonics(itide)%v0 + tide_harmonics(itide)%u
538	ENDDO
539	DO ib = 1, ilen0(igrd)
540	td%u(ib,itide,1)= mod_tide(ib)*COS(phi_tide(ib))
541	td%u(ib,itide,2)=-mod_tide(ib)*SIN(phi_tide(ib))
542	ENDDO
543	END DO
544	!
545	DEALLOCATE( mod_tide , phi_tide )
546	!
547	igrd=3 ! V grid.
548	!
549	ALLOCATE( mod_tide(ilen0(igrd)) , phi_tide(ilen0(igrd)) )
550
551	DO itide = 1, nb_harmo
552	DO ib = 1, ilen0(igrd)
553	mod_tide(ib)=SQRT(td%v0(ib,itide,1)2.+td%v0(ib,itide,2)2.)
554	phi_tide(ib)=ATAN2(-td%v0(ib,itide,2),td%v0(ib,itide,1))
555	END DO
556	DO ib = 1, ilen0(igrd)
557	mod_tide(ib)=mod_tide(ib)*tide_harmonics(itide)%f
558	phi_tide(ib)=phi_tide(ib)+tide_harmonics(itide)%v0 + tide_harmonics(itide)%u
559	ENDDO
560	DO ib = 1, ilen0(igrd)
561	td%v(ib,itide,1)= mod_tide(ib)*COS(phi_tide(ib))
562	td%v(ib,itide,2)=-mod_tide(ib)*SIN(phi_tide(ib))
563	ENDDO
564	END DO
565	!
566	DEALLOCATE( mod_tide, phi_tide )
567	!
568	END SUBROUTINE tide_init_velocities
569
570	!!======================================================================
571	END MODULE bdytides
572

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