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dynatfQCO.F90 in NEMO/branches/2020/dev_r12377_KERNEL-06_techene_e3/src/OCE/DYN – NEMO

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source: NEMO/branches/2020/dev_r12377_KERNEL-06_techene_e3/src/OCE/DYN/dynatfQCO.F90 @ 12624

Last change on this file since 12624 was 12624, checked in by techene, 4 years ago
all: add e3 substitute and limit precompiled files lines to about 130 character, change key_LF into key_QCO, change module name (dynatfQCO, traatfQCO, stepLF)
Property svn:keywords set to `Id`
File size: 15.0 KB

Line
1	MODULE dynatfqco
2	!!=========================================================================
3	!! * MODULE dynatfqco *
4	!! Ocean dynamics: time filtering
5	!!=========================================================================
6	!! History : OPA ! 1987-02 (P. Andrich, D. L Hostis) Original code
7	!! ! 1990-10 (C. Levy, G. Madec)
8	!! 7.0 ! 1993-03 (M. Guyon) symetrical conditions
9	!! 8.0 ! 1997-02 (G. Madec & M. Imbard) opa, release 8.0
10	!! 8.2 ! 1997-04 (A. Weaver) Euler forward step
11	!! - ! 1997-06 (G. Madec) lateral boudary cond., lbc routine
12	!! NEMO 1.0 ! 2002-08 (G. Madec) F90: Free form and module
13	!! - ! 2002-10 (C. Talandier, A-M. Treguier) Open boundary cond.
14	!! 2.0 ! 2005-11 (V. Garnier) Surface pressure gradient organization
15	!! 2.3 ! 2007-07 (D. Storkey) Calls to BDY routines.
16	!! 3.2 ! 2009-06 (G. Madec, R.Benshila) re-introduce the vvl option
17	!! 3.3 ! 2010-09 (D. Storkey, E.O'Dea) Bug fix for BDY module
18	!! 3.3 ! 2011-03 (P. Oddo) Bug fix for time-splitting+(BDY-OBC) and not VVL
19	!! 3.5 ! 2013-07 (J. Chanut) Compliant with time splitting changes
20	!! 3.6 ! 2014-04 (G. Madec) add the diagnostic of the time filter trends
21	!! 3.7 ! 2015-11 (J. Chanut) Free surface simplification
22	!! 4.1 ! 2019-08 (A. Coward, D. Storkey) Rename dynnxt.F90 -> dynatfLF.F90. Now just does time filtering.
23	!!-------------------------------------------------------------------------
24
25	!!----------------------------------------------------------------------------------------------
26	!! dyn_atf_qco : apply Asselin time filtering to "now" velocities and vertical scale factors
27	!!----------------------------------------------------------------------------------------------
28	USE oce ! ocean dynamics and tracers
29	USE dom_oce ! ocean space and time domain
30	USE sbc_oce ! Surface boundary condition: ocean fields
31	USE sbcrnf ! river runoffs
32	USE phycst ! physical constants
33	USE dynadv ! dynamics: vector invariant versus flux form
34	USE dynspg_ts ! surface pressure gradient: split-explicit scheme
35	USE domvvl ! variable volume
36	USE bdy_oce , ONLY: ln_bdy
37	USE bdydta ! ocean open boundary conditions
38	USE bdydyn ! ocean open boundary conditions
39	USE bdyvol ! ocean open boundary condition (bdy_vol routines)
40	USE trd_oce ! trends: ocean variables
41	USE trddyn ! trend manager: dynamics
42	USE trdken ! trend manager: kinetic energy
43	USE isf_oce , ONLY: ln_isf ! ice shelf
44	USE isfdynatf , ONLY: isf_dynatf ! ice shelf volume filter correction subroutine
45	!
46	USE in_out_manager ! I/O manager
47	USE iom ! I/O manager library
48	USE lbclnk ! lateral boundary condition (or mpp link)
49	USE lib_mpp ! MPP library
50	USE prtctl ! Print control
51	USE timing ! Timing
52	#if defined key_agrif
53	USE agrif_oce_interp
54	#endif
55
56	IMPLICIT NONE
57	PRIVATE
58
59	PUBLIC dyn_atf_qco ! routine called by step.F90
60
61	!! * Substitutions
62	# include "do_loop_substitute.h90"
63	# include "domzgr_substitute.h90"
64	!!----------------------------------------------------------------------
65	!! NEMO/OCE 4.0 , NEMO Consortium (2018)
66	!! $Id$
67	!! Software governed by the CeCILL license (see ./LICENSE)
68	!!----------------------------------------------------------------------
69	CONTAINS
70
71	SUBROUTINE dyn_atf_qco ( kt, Kbb, Kmm, Kaa, puu, pvv, pe3t, pe3u, pe3v )
72	!!----------------------------------------------------------------------
73	!! * ROUTINE dyn_atf_qco *
74	!!
75	!! ** Purpose : Finalize after horizontal velocity. Apply the boundary
76	!! condition on the after velocity and apply the Asselin time
77	!! filter to the now fields.
78	!!
79	!! ** Method : * Ensure after velocities transport matches time splitting
80	!! estimate (ln_dynspg_ts=T)
81	!!
82	!! * Apply lateral boundary conditions on after velocity
83	!! at the local domain boundaries through lbc_lnk call,
84	!! at the one-way open boundaries (ln_bdy=T),
85	!! at the AGRIF zoom boundaries (lk_agrif=T)
86	!!
87	!! * Apply the Asselin time filter to the now fields
88	!! arrays to start the next time step:
89	!! (puu(Kmm),pvv(Kmm)) = (puu(Kmm),pvv(Kmm))
90	!! + atfp [ (puu(Kbb),pvv(Kbb)) + (puu(Kaa),pvv(Kaa)) - 2 (puu(Kmm),pvv(Kmm)) ]
91	!! Note that with flux form advection and non linear free surface,
92	!! the time filter is applied on thickness weighted velocity.
93	!! As a result, dyn_atf_lf MUST be called after tra_atf.
94	!!
95	!! ** Action : puu(Kmm),pvv(Kmm) filtered now horizontal velocity
96	!!----------------------------------------------------------------------
97	INTEGER , INTENT(in ) :: kt ! ocean time-step index
98	INTEGER , INTENT(in ) :: Kbb, Kmm, Kaa ! before and after time level indices
99	REAL(wp), DIMENSION(jpi,jpj,jpk,jpt), INTENT(inout) :: puu, pvv ! velocities to be time filtered
100	REAL(wp), DIMENSION(jpi,jpj,jpk,jpt), INTENT(inout) :: pe3t, pe3u, pe3v ! scale factors to be time filtered
101	!
102	INTEGER :: ji, jj, jk ! dummy loop indices
103	REAL(wp) :: zue3a, zue3n, zue3b, zcoef ! local scalars
104	REAL(wp) :: zve3a, zve3n, zve3b, z1_2dt ! - -
105	REAL(wp), ALLOCATABLE, DIMENSION(:,:) :: zue, zve
106	REAL(wp), ALLOCATABLE, DIMENSION(:,:,:) :: zua, zva
107	!!----------------------------------------------------------------------
108	!
109	IF( ln_timing ) CALL timing_start('dyn_atf_qco')
110	IF( ln_dynspg_ts ) ALLOCATE( zue(jpi,jpj) , zve(jpi,jpj) )
111	IF( l_trddyn ) ALLOCATE( zua(jpi,jpj,jpk) , zva(jpi,jpj,jpk) )
112	!
113	IF( kt == nit000 ) THEN
114	IF(lwp) WRITE(numout,*)
115	IF(lwp) WRITE(numout,*) 'dyn_atf_qco : Asselin time filtering'
116	IF(lwp) WRITE(numout,*) '~~~~~~~'
117	ENDIF
118	!
119	IF( l_trddyn ) THEN ! prepare the atf trend computation + some diagnostics
120	z1_2dt = 1._wp / (2. * rdt) ! Euler or leap-frog time step
121	IF( neuler == 0 .AND. kt == nit000 ) z1_2dt = 1._wp / rdt
122	!
123	! ! Kinetic energy and Conversion
124	IF( ln_KE_trd ) CALL trd_dyn( puu(:,:,:,Kaa), pvv(:,:,:,Kaa), jpdyn_ken, kt, Kmm )
125	!
126	IF( ln_dyn_trd ) THEN ! 3D output: total momentum trends
127	zua(:,:,:) = ( puu(:,:,:,Kaa) - puu(:,:,:,Kbb) ) * z1_2dt
128	zva(:,:,:) = ( pvv(:,:,:,Kaa) - pvv(:,:,:,Kbb) ) * z1_2dt
129	CALL iom_put( "utrd_tot", zua ) ! total momentum trends, except the asselin time filter
130	CALL iom_put( "vtrd_tot", zva )
131	ENDIF
132	!
133	zua(:,:,:) = puu(:,:,:,Kmm) ! save the now velocity before the asselin filter
134	zva(:,:,:) = pvv(:,:,:,Kmm) ! (caution: there will be a shift by 1 timestep in the
135	! ! computation of the asselin filter trends)
136	ENDIF
137
138	! Time filter and swap of dynamics arrays
139	! ------------------------------------------
140
141	IF( .NOT.( neuler == 0 .AND. kt == nit000 ) ) THEN !* Leap-Frog : Asselin time filter
142	! ! =============!
143	IF( ln_linssh ) THEN ! Fixed volume !
144	! ! =============!
145	DO_3D_11_11( 1, jpkm1 )
146	puu(ji,jj,jk,Kmm) = puu(ji,jj,jk,Kmm) + atfp * ( puu(ji,jj,jk,Kbb) - 2._wp * puu(ji,jj,jk,Kmm) + puu(ji,jj,jk,Kaa) )
147	pvv(ji,jj,jk,Kmm) = pvv(ji,jj,jk,Kmm) + atfp * ( pvv(ji,jj,jk,Kbb) - 2._wp * pvv(ji,jj,jk,Kmm) + pvv(ji,jj,jk,Kaa) )
148	END_3D
149	! ! ================!
150	ELSE ! Variable volume !
151	! ! ================!
152	! Time-filtered scale factor at t-points
153	! ----------------------------------------------------
154	! DO jk = 1, jpk ! filtered scale factor at T-points
155	! pe3t(:,:,jk,Kmm) = e3t_0(:,:,jk) * ( 1._wp + r3t_f(:,:) * tmask(:,:,jk) )
156	! END DO
157	!
158	!
159	IF( ln_dynadv_vec ) THEN ! Asselin filter applied on velocity
160	! Before filtered scale factor at (u/v)-points
161	! DO jk = 1, jpk
162	! pe3u(:,:,jk,Kmm) = e3u_0(:,:,jk) * ( 1._wp + r3u_f(:,:) * umask(:,:,jk) )
163	! pe3v(:,:,jk,Kmm) = e3v_0(:,:,jk) * ( 1._wp + r3v_f(:,:) * vmask(:,:,jk) )
164	! END DO
165	!
166	DO_3D_11_11( 1, jpkm1 )
167	puu(ji,jj,jk,Kmm) = puu(ji,jj,jk,Kmm) + atfp * ( puu(ji,jj,jk,Kbb) - 2._wp * puu(ji,jj,jk,Kmm) + puu(ji,jj,jk,Kaa) )
168	pvv(ji,jj,jk,Kmm) = pvv(ji,jj,jk,Kmm) + atfp * ( pvv(ji,jj,jk,Kbb) - 2._wp * pvv(ji,jj,jk,Kmm) + pvv(ji,jj,jk,Kaa) )
169	END_3D
170	!
171	ELSE ! Asselin filter applied on thickness weighted velocity
172	!
173	DO_3D_11_11( 1, jpkm1 )
174	! zue3a = pe3u(ji,jj,jk,Kaa) * puu(ji,jj,jk,Kaa)
175	! zve3a = pe3v(ji,jj,jk,Kaa) * pvv(ji,jj,jk,Kaa)
176	! zue3n = pe3u(ji,jj,jk,Kmm) * puu(ji,jj,jk,Kmm)
177	! zve3n = pe3v(ji,jj,jk,Kmm) * pvv(ji,jj,jk,Kmm)
178	! zue3b = pe3u(ji,jj,jk,Kbb) * puu(ji,jj,jk,Kbb)
179	! zve3b = pe3v(ji,jj,jk,Kbb) * pvv(ji,jj,jk,Kbb)
180	!
181	zue3a = ( 1._wp + r3u(ji,jj,Kaa) * umask(ji,jj,jk) ) * puu(ji,jj,jk,Kaa)
182	zve3a = ( 1._wp + r3v(ji,jj,Kaa) * vmask(ji,jj,jk) ) * pvv(ji,jj,jk,Kaa)
183	zue3n = ( 1._wp + r3u(ji,jj,Kmm) * umask(ji,jj,jk) ) * puu(ji,jj,jk,Kmm)
184	zve3n = ( 1._wp + r3v(ji,jj,Kmm) * vmask(ji,jj,jk) ) * pvv(ji,jj,jk,Kmm)
185	zue3b = ( 1._wp + r3u(ji,jj,Kbb) * umask(ji,jj,jk) ) * puu(ji,jj,jk,Kbb)
186	zve3b = ( 1._wp + r3v(ji,jj,Kbb) * vmask(ji,jj,jk) ) * pvv(ji,jj,jk,Kbb)
187	! ! filtered scale factor at U-,V-points
188	! pe3u(ji,jj,jk,Kmm) = e3u_0(ji,jj,jk) * ( 1._wp + r3u_f(ji,jj) * umask(ji,jj,jk) )
189	! pe3v(ji,jj,jk,Kmm) = e3v_0(ji,jj,jk) * ( 1._wp + r3v_f(ji,jj) * vmask(ji,jj,jk) )
190	!
191	puu(ji,jj,jk,Kmm) = ( zue3n + atfp * ( zue3b - 2._wp * zue3n + zue3a ) ) / ( 1._wp + r3u_f(ji,jj)*umask(ji,jj,jk) ) !!st ze3u_f(ji,jj,jk)
192	pvv(ji,jj,jk,Kmm) = ( zve3n + atfp * ( zve3b - 2._wp * zve3n + zve3a ) ) / ( 1._wp + r3v_f(ji,jj)*vmask(ji,jj,jk) ) !!st ze3v_f(ji,jj,jk)
193	END_3D
194	!
195	ENDIF
196	!
197	ENDIF
198	!
199	IF( ln_dynspg_ts .AND. ln_bt_fw ) THEN
200	! Revert filtered "now" velocities to time split estimate
201	! Doing it here also means that asselin filter contribution is removed
202	! zue(:,:) = pe3u(:,:,1,Kmm) * puu(:,:,1,Kmm) * umask(:,:,1)
203	! zve(:,:) = pe3v(:,:,1,Kmm) * pvv(:,:,1,Kmm) * vmask(:,:,1)
204	! DO jk = 2, jpkm1
205	! zue(:,:) = zue(:,:) + pe3u(:,:,jk,Kmm) * puu(:,:,jk,Kmm) * umask(:,:,jk)
206	! zve(:,:) = zve(:,:) + pe3v(:,:,jk,Kmm) * pvv(:,:,jk,Kmm) * vmask(:,:,jk)
207	! END DO
208	zue(:,:) = e3u(:,:,1,Kmm) * puu(:,:,1,Kmm) * umask(:,:,1)
209	zve(:,:) = e3v(:,:,1,Kmm) * pvv(:,:,1,Kmm) * vmask(:,:,1)
210	DO jk = 2, jpkm1
211	zue(:,:) = zue(:,:) + e3u(:,:,jk,Kmm) * puu(:,:,jk,Kmm) * umask(:,:,jk)
212	zve(:,:) = zve(:,:) + e3v(:,:,jk,Kmm) * pvv(:,:,jk,Kmm) * vmask(:,:,jk)
213	END DO
214	DO jk = 1, jpkm1
215	puu(:,:,jk,Kmm) = puu(:,:,jk,Kmm) - (zue(:,:) * r1_hu(:,:,Kmm) - uu_b(:,:,Kmm)) * umask(:,:,jk)
216	pvv(:,:,jk,Kmm) = pvv(:,:,jk,Kmm) - (zve(:,:) * r1_hv(:,:,Kmm) - vv_b(:,:,Kmm)) * vmask(:,:,jk)
217	END DO
218	ENDIF
219	!
220	ENDIF ! neuler /= 0
221	!
222	! Set "now" and "before" barotropic velocities for next time step:
223	! JC: Would be more clever to swap variables than to make a full vertical
224	! integration
225	!
226	IF(.NOT.ln_linssh ) THEN
227	hu(:,:,Kmm) = e3u(:,:,1,Kmm ) * umask(:,:,1)
228	hv(:,:,Kmm) = e3v(:,:,1,Kmm ) * vmask(:,:,1)
229	DO jk = 2, jpkm1
230	hu(:,:,Kmm) = hu(:,:,Kmm) + e3u(:,:,jk,Kmm ) * umask(:,:,jk)
231	hv(:,:,Kmm) = hv(:,:,Kmm) + e3v(:,:,jk,Kmm ) * vmask(:,:,jk)
232	END DO
233	r1_hu(:,:,Kmm) = ssumask(:,:) / ( hu(:,:,Kmm) + 1._wp - ssumask(:,:) )
234	r1_hv(:,:,Kmm) = ssvmask(:,:) / ( hv(:,:,Kmm) + 1._wp - ssvmask(:,:) )
235	ENDIF
236	!
237	uu_b(:,:,Kaa) = e3u(:,:,1,Kaa) * puu(:,:,1,Kaa) * umask(:,:,1)
238	uu_b(:,:,Kmm) = e3u(:,:,1,Kmm) * puu(:,:,1,Kmm) * umask(:,:,1)
239	vv_b(:,:,Kaa) = e3v(:,:,1,Kaa) * pvv(:,:,1,Kaa) * vmask(:,:,1)
240	vv_b(:,:,Kmm) = e3v(:,:,1,Kmm) * pvv(:,:,1,Kmm) * vmask(:,:,1)
241	DO jk = 2, jpkm1
242	uu_b(:,:,Kaa) = uu_b(:,:,Kaa) + e3u(:,:,jk,Kaa) * puu(:,:,jk,Kaa) * umask(:,:,jk)
243	uu_b(:,:,Kmm) = uu_b(:,:,Kmm) + e3u(:,:,jk,Kmm) * puu(:,:,jk,Kmm) * umask(:,:,jk)
244	vv_b(:,:,Kaa) = vv_b(:,:,Kaa) + e3v(:,:,jk,Kaa) * pvv(:,:,jk,Kaa) * vmask(:,:,jk)
245	vv_b(:,:,Kmm) = vv_b(:,:,Kmm) + e3v(:,:,jk,Kmm) * pvv(:,:,jk,Kmm) * vmask(:,:,jk)
246	END DO
247	uu_b(:,:,Kaa) = uu_b(:,:,Kaa) * r1_hu(:,:,Kaa)
248	vv_b(:,:,Kaa) = vv_b(:,:,Kaa) * r1_hv(:,:,Kaa)
249	uu_b(:,:,Kmm) = uu_b(:,:,Kmm) * r1_hu(:,:,Kmm)
250	vv_b(:,:,Kmm) = vv_b(:,:,Kmm) * r1_hv(:,:,Kmm)
251	!
252	IF( .NOT.ln_dynspg_ts ) THEN ! output the barotropic currents
253	CALL iom_put( "ubar", uu_b(:,:,Kmm) )
254	CALL iom_put( "vbar", vv_b(:,:,Kmm) )
255	ENDIF
256	IF( l_trddyn ) THEN ! 3D output: asselin filter trends on momentum
257	zua(:,:,:) = ( puu(:,:,:,Kmm) - zua(:,:,:) ) * z1_2dt
258	zva(:,:,:) = ( pvv(:,:,:,Kmm) - zva(:,:,:) ) * z1_2dt
259	CALL trd_dyn( zua, zva, jpdyn_atf, kt, Kmm )
260	ENDIF
261	!
262	IF(sn_cfctl%l_prtctl) CALL prt_ctl( tab3d_1=puu(:,:,:,Kaa), clinfo1=' nxt - puu(:,:,:,Kaa): ', mask1=umask, &
263	& tab3d_2=pvv(:,:,:,Kaa), clinfo2=' pvv(:,:,:,Kaa): ' , mask2=vmask )
264	!
265	IF( ln_dynspg_ts ) DEALLOCATE( zue, zve )
266	IF( l_trddyn ) DEALLOCATE( zua, zva )
267	IF( ln_timing ) CALL timing_stop('dyn_atf_qco')
268	!
269	END SUBROUTINE dyn_atf_qco
270
271	!!=========================================================================
272	END MODULE dynatfqco

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