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.

limrhg_2.F90 in trunk/NEMOGCM/NEMO/LIM_SRC_2 – NEMO

Context Navigation

source: trunk/NEMOGCM/NEMO/LIM_SRC_2/limrhg_2.F90 @ 3294

Last change on this file since 3294 was 3294, checked in by rblod, 12 years ago
Merge of 3.4beta into the trunk
Property svn:keywords set to `Id`
File size: 34.3 KB

Line
1	MODULE limrhg_2
2	!!======================================================================
3	!! * MODULE limrhg_2 *
4	!! Ice rheology : performs sea ice rheology
5	!!======================================================================
6	!! History : 0.0 ! 1993-12 (M.A. Morales Maqueda.) Original code
7	!! 1.0 ! 1994-12 (H. Goosse)
8	!! 2.0 ! 2003-12 (C. Ethe, G. Madec) F90, mpp
9	!! - ! 2006-08 (G. Madec) surface module, ice-stress at I-point
10	!! - ! 2009-09 (G. Madec) Huge verctor optimisation
11	!! 3.3 ! 2009-05 (G.Garric, C. Bricaud) addition of the lim2_evp case
12	!!----------------------------------------------------------------------
13	#if defined key_lim2 && defined key_lim2_vp
14	!!----------------------------------------------------------------------
15	!! 'key_lim2' AND LIM-2 sea-ice model
16	!! 'key_lim2_vp' VP ice rheology
17	!!----------------------------------------------------------------------
18	!! lim_rhg_2 : computes ice velocities
19	!!----------------------------------------------------------------------
20	USE par_oce ! ocean parameter
21	USE dom_oce ! ocean space and time domain
22	USE sbc_oce ! surface boundary condition: ocean variables
23	USE sbc_ice ! surface boundary condition: ice variables
24	USE dom_ice_2 ! LIM2: ice domain
25	USE phycst ! physical constant
26	USE ice_2 ! LIM2: ice variables
27	USE lbclnk ! lateral boundary condition - MPP exchanges
28	USE lib_mpp ! MPP library
29	USE wrk_nemo ! work arrays
30	USE in_out_manager ! I/O manager
31	USE prtctl ! Print control
32
33	IMPLICIT NONE
34	PRIVATE
35
36	PUBLIC lim_rhg_2 ! routine called by lim_dyn
37
38	REAL(wp) :: rzero = 0._wp ! constant value: zero
39	REAL(wp) :: rone = 1._wp ! and one
40
41	!! * Substitutions
42	# include "vectopt_loop_substitute.h90"
43	!!----------------------------------------------------------------------
44	!! NEMO/LIM2 3.3 , UCL - NEMO Consortium (2010)
45	!! $Id$
46	!! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt)
47	!!----------------------------------------------------------------------
48	CONTAINS
49
50	SUBROUTINE lim_rhg_2( k_j1, k_jpj )
51	!!-------------------------------------------------------------------
52	!! * SUBROUTINR lim_rhg_2 *
53	!!
54	!! ** purpose : determines the velocity field of sea ice by using
55	!! atmospheric (wind stress) and oceanic (water stress and surface
56	!! tilt) forcings. Ice-ice interaction is described by a non-linear
57	!! viscous-plastic law including shear strength and a bulk rheology.
58	!!
59	!! ** Action : - compute u_ice, v_ice the sea-ice velocity defined
60	!! at I-point
61	!!-------------------------------------------------------------------
62	INTEGER, INTENT(in) :: k_j1 ! southern j-index for ice computation
63	INTEGER, INTENT(in) :: k_jpj ! northern j-index for ice computation
64	!!
65	INTEGER :: ji, jj ! dummy loop indices
66	INTEGER :: iter, jter ! temporary integers
67	CHARACTER (len=50) :: charout
68	REAL(wp) :: ze11 , ze12 , ze22 , ze21 ! local scalars
69	REAL(wp) :: zt11 , zt12 , zt21 , zt22 ! - -
70	REAL(wp) :: zvis11, zvis21, zvis12, zvis22 ! - -
71	REAL(wp) :: zgphsx, ztagnx, zgsshx, zunw, zur, zusw ! - -
72	REAL(wp) :: zgphsy, ztagny, zgsshy, zvnw, zvr ! - -
73	REAL(wp) :: zresm, za, zac, zmod
74	REAL(wp) :: zmpzas, zstms, zindu, zusdtp, zmassdt, zcorlal
75	REAL(wp) :: ztrace2, zdeter, zdelta, zmask, zdgp, zdgi, zdiag
76	REAL(wp) :: za1, zb1, zc1, zd1
77	REAL(wp) :: za2, zb2, zc2, zd2, zden
78	REAL(wp) :: zs11_11, zs11_12, zs11_21, zs11_22
79	REAL(wp) :: zs12_11, zs12_12, zs12_21, zs12_22
80	REAL(wp) :: zs21_11, zs21_12, zs21_21, zs21_22
81	REAL(wp) :: zs22_11, zs22_12, zs22_21, zs22_22
82	REAL(wp), POINTER, DIMENSION(:,:) :: zfrld, zmass, zcorl
83	REAL(wp), POINTER, DIMENSION(:,:) :: za1ct, za2ct, zresr
84	REAL(wp), POINTER, DIMENSION(:,:) :: zc1u, zc1v, zc2u, zc2v
85	REAL(wp), POINTER, DIMENSION(:,:) :: zsang
86	REAL(wp), POINTER, DIMENSION(:,:) :: zu0, zv0
87	REAL(wp), POINTER, DIMENSION(:,:) :: zu_n, zv_n
88	REAL(wp), POINTER, DIMENSION(:,:) :: zu_a, zv_a
89	REAL(wp), POINTER, DIMENSION(:,:) :: zviszeta, zviseta
90	REAL(wp), POINTER, DIMENSION(:,:) :: zzfrld, zztms
91	REAL(wp), POINTER, DIMENSION(:,:) :: zi1, zi2, zmasst, zpresh
92	!!-------------------------------------------------------------------
93
94	CALL wrk_alloc( jpi,jpj, zfrld, zmass, zcorl, za1ct, za2ct, zresr )
95	CALL wrk_alloc( jpi,jpj, zc1u , zc1v , zc2u , zc2v , zsang )
96	CALL wrk_alloc( jpi,jpj+2, zu0, zv0, zu_n, zv_n, zu_a, zv_a, zviszeta, zviseta, kjstart = 0 )
97	CALL wrk_alloc( jpi,jpj+2, zzfrld, zztms, zi1, zi2, zmasst, zpresh, kjstart = 0 )
98
99	! Store initial velocities
100	! ----------------
101	zztms(:,0 ) = 0._wp ; zzfrld(:,0 ) = 0._wp
102	zztms(:,jpj+1) = 0._wp ; zzfrld(:,jpj+1) = 0._wp
103	zu0 (:,0 ) = 0._wp ; zv0 (:,0 ) = 0._wp
104	zu0 (:,jpj+1) = 0._wp ; zv0 (:,jpj+1) = 0._wp
105	zztms(:,1:jpj) = tms (:,:) ; zzfrld(:,1:jpj) = frld (:,:)
106	zu0 (:,1:jpj) = u_ice(:,:) ; zv0 (:,1:jpj) = v_ice(:,:)
107	zu_a (:, : ) = zu0 (:,:) ; zv_a (:, : ) = zv0 (:,:)
108	zu_n (:, : ) = zu0 (:,:) ; zv_n (:, : ) = zv0 (:,:)
109
110	!i
111	zi1 (:,:) = 0._wp
112	zi2 (:,:) = 0._wp
113	zpresh(:,:) = 0._wp
114	zmasst(:,:) = 0._wp
115	!i
116	!!gm violant
117	zfrld(:,:) =0._wp
118	zcorl(:,:) =0._wp
119	zmass(:,:) =0._wp
120	za1ct(:,:) =0._wp
121	za2ct(:,:) =0._wp
122	!!gm end
123
124	zviszeta(:,:) = 0._wp
125	zviseta (:,:) = 0._wp
126
127	!i zviszeta(:,0 ) = 0._wp ; zviseta(:,0 ) = 0._wp
128	!i zviszeta(:,jpj ) = 0._wp ; zviseta(:,jpj ) = 0._wp
129	!i zviszeta(:,jpj+1) = 0._wp ; zviseta(:,jpj+1) = 0._wp
130
131
132	! Ice mass, ice strength, and wind stress at the center \|
133	! of the grid squares. \|
134	!-------------------------------------------------------------------
135
136	!CDIR NOVERRCHK
137	DO jj = k_j1 , k_jpj-1
138	!CDIR NOVERRCHK
139	DO ji = 1 , jpi
140	! only the sinus changes its sign with the hemisphere
141	zsang(ji,jj) = SIGN( 1._wp, fcor(ji,jj) ) * sangvg ! only the sinus changes its sign with the hemisphere
142	!
143	zmasst(ji,jj) = tms(ji,jj) * ( rhosn * hsnm(ji,jj) + rhoic * hicm(ji,jj) )
144	zpresh(ji,jj) = tms(ji,jj) * pstarh * hicm(ji,jj) * EXP( -c_rhg * frld(ji,jj) )
145	!!gm :: stress given at I-point (F-point for the ocean) only compute the ponderation with the ice fraction (1-frld)
146	zi1(ji,jj) = tms(ji,jj) * ( 1._wp - frld(ji,jj) )
147	zi2(ji,jj) = tms(ji,jj) * ( 1._wp - frld(ji,jj) )
148	END DO
149	END DO
150
151
152	!---------------------------------------------------------------------------
153	! Wind stress, coriolis and mass terms at the corners of the grid squares \|
154	! Gradient of ice strenght. \|
155	!---------------------------------------------------------------------------
156
157	DO jj = k_j1+1, k_jpj-1
158	DO ji = 2, jpi ! NO vector opt.
159	zstms = zztms(ji,jj ) * wght(ji,jj,2,2) + zztms(ji-1,jj ) * wght(ji,jj,1,2) &
160	& + zztms(ji,jj-1) * wght(ji,jj,2,1) + zztms(ji-1,jj-1) * wght(ji,jj,1,1)
161	zusw = 1._wp / MAX( zstms, epsd )
162
163	zt11 = zztms(ji ,jj ) * zzfrld(ji ,jj )
164	zt12 = zztms(ji-1,jj ) * zzfrld(ji-1,jj )
165	zt21 = zztms(ji ,jj-1) * zzfrld(ji ,jj-1)
166	zt22 = zztms(ji-1,jj-1) * zzfrld(ji-1,jj-1)
167
168	! Leads area.
169	zfrld(ji,jj) = ( zt11 * wght(ji,jj,2,2) + zt12 * wght(ji,jj,1,2) &
170	& + zt21 * wght(ji,jj,2,1) + zt22 * wght(ji,jj,1,1) ) * zusw
171
172	! Mass and coriolis coeff. at I-point
173	zmass(ji,jj) = ( zmasst(ji,jj ) * wght(ji,jj,2,2) + zmasst(ji-1,jj ) * wght(ji,jj,1,2) &
174	& + zmasst(ji,jj-1) * wght(ji,jj,2,1) + zmasst(ji-1,jj-1) * wght(ji,jj,1,1) ) * zusw
175	zcorl(ji,jj) = zmass(ji,jj) &
176	& ( fcor(ji,jj ) wght(ji,jj,2,2) + fcor(ji-1,jj )*wght(ji,jj,1,2) &
177	& + fcor(ji,jj-1) * wght(ji,jj,2,1) + fcor(ji-1,jj-1)wght(ji,jj,1,1) ) zusw
178
179	! Wind stress.
180	! always provide stress at I-point
181	ztagnx = ( zi1(ji,jj ) * wght(ji,jj,2,2) + zi1(ji-1,jj ) * wght(ji,jj,1,2) &
182	& + zi1(ji,jj-1) * wght(ji,jj,2,1) + zi1(ji-1,jj-1) * wght(ji,jj,1,1) ) * zusw * utau_ice(ji,jj)
183	ztagny = ( zi2(ji,jj ) * wght(ji,jj,2,2) + zi2(ji-1,jj ) * wght(ji,jj,1,2) &
184	& + zi2(ji,jj-1) * wght(ji,jj,2,1) + zi2(ji-1,jj-1) * wght(ji,jj,1,1) ) * zusw * vtau_ice(ji,jj)
185
186	! Gradient of ice strength
187	zgphsx = ( alambd(ji,jj,2,2,2,1) - alambd(ji,jj,2,1,2,1) ) * zpresh(ji ,jj-1) &
188	& + ( alambd(ji,jj,2,2,2,2) - alambd(ji,jj,2,1,2,2) ) * zpresh(ji ,jj ) &
189	& - ( alambd(ji,jj,2,2,1,1) + alambd(ji,jj,2,1,1,1) ) * zpresh(ji-1,jj-1) &
190	& - ( alambd(ji,jj,2,2,1,2) + alambd(ji,jj,2,1,1,2) ) * zpresh(ji-1,jj )
191
192	zgphsy = - ( alambd(ji,jj,1,1,2,1) + alambd(ji,jj,1,2,2,1) ) * zpresh(ji ,jj-1) &
193	& - ( alambd(ji,jj,1,1,1,1) + alambd(ji,jj,1,2,1,1) ) * zpresh(ji-1,jj-1) &
194	& + ( alambd(ji,jj,1,1,2,2) - alambd(ji,jj,1,2,2,2) ) * zpresh(ji ,jj ) &
195	& + ( alambd(ji,jj,1,1,1,2) - alambd(ji,jj,1,2,1,2) ) * zpresh(ji-1,jj )
196
197	! Gradient of the sea surface height
198	zgsshx = ( (ssh_m(ji ,jj ) - ssh_m(ji-1,jj ))/e1u(ji-1,jj ) &
199	& + (ssh_m(ji ,jj-1) - ssh_m(ji-1,jj-1))/e1u(ji-1,jj-1) ) * 0.5_wp
200	zgsshy = ( (ssh_m(ji ,jj ) - ssh_m(ji ,jj-1))/e2v(ji ,jj-1) &
201	& + (ssh_m(ji-1,jj ) - ssh_m(ji-1,jj-1))/e2v(ji-1,jj-1) ) * 0.5_wp
202
203	! Computation of the velocity field taking into account the ice-ice interaction.
204	! Terms that are independent of the ice velocity field.
205	za1ct(ji,jj) = ztagnx - zmass(ji,jj) * grav * zgsshx - zgphsx
206	za2ct(ji,jj) = ztagny - zmass(ji,jj) * grav * zgsshy - zgphsy
207	END DO
208	END DO
209
210
211	! SOLUTION OF THE MOMENTUM EQUATION.
212	!------------------------------------------
213	! ! ==================== !
214	DO iter = 1 , 2 * nbiter ! loop over iter !
215	! ! ==================== !
216	zindu = MOD( iter , 2 )
217	zusdtp = ( zindu * 2._wp + ( 1._wp - zindu ) * 1._wp ) * REAL( nbiter ) / rdt_ice
218
219	! Computation of free drift field for free slip boundary conditions.
220
221	!CDIR NOVERRCHK
222	DO jj = k_j1, k_jpj-1
223	!CDIR NOVERRCHK
224	DO ji = 1, fs_jpim1
225	!- Rate of strain tensor.
226	zt11 = akappa(ji,jj,1,1) * ( zu_a(ji+1,jj) + zu_a(ji+1,jj+1) - zu_a(ji,jj ) - zu_a(ji ,jj+1) ) &
227	& + akappa(ji,jj,1,2) * ( zv_a(ji+1,jj) + zv_a(ji+1,jj+1) + zv_a(ji,jj ) + zv_a(ji ,jj+1) )
228	zt12 = - akappa(ji,jj,2,2) * ( zu_a(ji ,jj) + zu_a(ji+1,jj ) - zu_a(ji,jj+1) - zu_a(ji+1,jj+1) ) &
229	& - akappa(ji,jj,2,1) * ( zv_a(ji ,jj) + zv_a(ji+1,jj ) + zv_a(ji,jj+1) + zv_a(ji+1,jj+1) )
230	zt22 = - akappa(ji,jj,2,2) * ( zv_a(ji ,jj) + zv_a(ji+1,jj ) - zv_a(ji,jj+1) - zv_a(ji+1,jj+1) ) &
231	& + akappa(ji,jj,2,1) * ( zu_a(ji ,jj) + zu_a(ji+1,jj ) + zu_a(ji,jj+1) + zu_a(ji+1,jj+1) )
232	zt21 = akappa(ji,jj,1,1) * ( zv_a(ji+1,jj) + zv_a(ji+1,jj+1) - zv_a(ji,jj ) - zv_a(ji ,jj+1) ) &
233	& - akappa(ji,jj,1,2) * ( zu_a(ji+1,jj) + zu_a(ji+1,jj+1) + zu_a(ji,jj ) + zu_a(ji ,jj+1) )
234
235	!- Rate of strain tensor.
236	zdgp = zt11 + zt22
237	zdgi = zt12 + zt21
238	ztrace2 = zdgp * zdgp
239	zdeter = zt11 * zt22 - 0.25_wp * zdgi * zdgi
240
241	! Creep limit depends on the size of the grid.
242	zdelta = MAX( SQRT( ztrace2 + ( ztrace2 - 4._wp * zdeter ) * usecc2 ), creepl)
243
244	!- Computation of viscosities.
245	zviszeta(ji,jj) = MAX( zpresh(ji,jj) / zdelta, etamn )
246	zviseta (ji,jj) = zviszeta(ji,jj) * usecc2
247	END DO
248	END DO
249
250	!- Determination of zc1u, zc2u, zc1v and zc2v.
251	DO jj = k_j1+1, k_jpj-1
252	DO ji = 2, fs_jpim1 ! NO vector opt.
253	!* zc1u , zc2v
254	zvis11 = 2._wp * zviseta (ji-1,jj-1) + dm
255	zvis12 = zviseta (ji-1,jj-1) + dm
256	zvis21 = zviseta (ji-1,jj-1)
257	zvis22 = zviszeta(ji-1,jj-1) - zviseta(ji-1,jj-1)
258	zdiag = zvis22 * ( akappa(ji-1,jj-1,1,1) + akappa(ji-1,jj-1,2,1) )
259	zs11_11 = zvis11 * akappa(ji-1,jj-1,1,1) + zdiag
260	zs12_11 = zvis12 * akappa(ji-1,jj-1,2,2) - zvis21 * akappa(ji-1,jj-1,1,2)
261	zs21_11 = -zvis12 * akappa(ji-1,jj-1,1,2) + zvis21 * akappa(ji-1,jj-1,2,2)
262	zs22_11 = zvis11 * akappa(ji-1,jj-1,2,1) + zdiag
263
264	zvis11 = 2._wp * zviseta (ji,jj-1) + dm
265	zvis22 = zviszeta(ji,jj-1) - zviseta(ji,jj-1)
266	zvis12 = zviseta (ji,jj-1) + dm
267	zvis21 = zviseta (ji,jj-1)
268	zdiag = zvis22 * ( -akappa(ji,jj-1,1,1) + akappa(ji,jj-1,2,1) )
269	zs11_21 = -zvis11 * akappa(ji,jj-1,1,1) + zdiag
270	zs12_21 = zvis12 * akappa(ji,jj-1,2,2) - zvis21 * akappa(ji,jj-1,1,2)
271	zs22_21 = zvis11 * akappa(ji,jj-1,2,1) + zdiag
272	zs21_21 = -zvis12 * akappa(ji,jj-1,1,2) + zvis21 * akappa(ji,jj-1,2,2)
273
274	zvis11 = 2._wp * zviseta (ji-1,jj) + dm
275	zvis22 = zviszeta(ji-1,jj) - zviseta(ji-1,jj)
276	zvis12 = zviseta (ji-1,jj) + dm
277	zvis21 = zviseta (ji-1,jj)
278	zdiag = zvis22 * ( akappa(ji-1,jj,1,1) + akappa(ji-1,jj,2,1) )
279	zs11_12 = zvis11 * akappa(ji-1,jj,1,1) + zdiag
280	zs12_12 = -zvis12 * akappa(ji-1,jj,2,2) - zvis21 * akappa(ji-1,jj,1,2)
281	zs22_12 = zvis11 * akappa(ji-1,jj,2,1) + zdiag
282	zs21_12 = -zvis12 * akappa(ji-1,jj,1,2) - zvis21 * akappa(ji-1,jj,2,2)
283
284	zvis11 = 2._wp * zviseta (ji,jj) + dm
285	zvis22 = zviszeta(ji,jj) - zviseta(ji,jj)
286	zvis12 = zviseta (ji,jj) + dm
287	zvis21 = zviseta (ji,jj)
288	zdiag = zvis22 * ( -akappa(ji,jj,1,1) + akappa(ji,jj,2,1) )
289	zs11_22 = -zvis11 * akappa(ji,jj,1,1) + zdiag
290	zs12_22 = -zvis12 * akappa(ji,jj,2,2) - zvis21 * akappa(ji,jj,1,2)
291	zs22_22 = zvis11 * akappa(ji,jj,2,1) + zdiag
292	zs21_22 = -zvis12 * akappa(ji,jj,1,2) - zvis21 * akappa(ji,jj,2,2)
293
294	zc1u(ji,jj) = + alambd(ji,jj,2,2,2,1) * zs11_21 + alambd(ji,jj,2,2,2,2) * zs11_22 &
295	& - alambd(ji,jj,2,2,1,1) * zs11_11 - alambd(ji,jj,2,2,1,2) * zs11_12 &
296	& - alambd(ji,jj,1,1,2,1) * zs12_21 - alambd(ji,jj,1,1,1,1) * zs12_11 &
297	& + alambd(ji,jj,1,1,2,2) * zs12_22 + alambd(ji,jj,1,1,1,2) * zs12_12 &
298	& + alambd(ji,jj,1,2,1,1) * zs21_11 + alambd(ji,jj,1,2,2,1) * zs21_21 &
299	& + alambd(ji,jj,1,2,1,2) * zs21_12 + alambd(ji,jj,1,2,2,2) * zs21_22 &
300	& - alambd(ji,jj,2,1,1,1) * zs22_11 - alambd(ji,jj,2,1,2,1) * zs22_21 &
301	& - alambd(ji,jj,2,1,1,2) * zs22_12 - alambd(ji,jj,2,1,2,2) * zs22_22
302
303	zc2u(ji,jj) = + alambd(ji,jj,2,2,2,1) * zs21_21 + alambd(ji,jj,2,2,2,2) * zs21_22 &
304	& - alambd(ji,jj,2,2,1,1) * zs21_11 - alambd(ji,jj,2,2,1,2) * zs21_12 &
305	& - alambd(ji,jj,1,1,2,1) * zs22_21 - alambd(ji,jj,1,1,1,1) * zs22_11 &
306	& + alambd(ji,jj,1,1,2,2) * zs22_22 + alambd(ji,jj,1,1,1,2) * zs22_12 &
307	& - alambd(ji,jj,1,2,1,1) * zs11_11 - alambd(ji,jj,1,2,2,1) * zs11_21 &
308	& - alambd(ji,jj,1,2,1,2) * zs11_12 - alambd(ji,jj,1,2,2,2) * zs11_22 &
309	& + alambd(ji,jj,2,1,1,1) * zs12_11 + alambd(ji,jj,2,1,2,1) * zs12_21 &
310	& + alambd(ji,jj,2,1,1,2) * zs12_12 + alambd(ji,jj,2,1,2,2) * zs12_22
311
312	!* zc1v , zc2v.
313	zvis11 = 2._wp * zviseta (ji-1,jj-1) + dm
314	zvis22 = zviszeta(ji-1,jj-1) - zviseta(ji-1,jj-1)
315	zvis12 = zviseta (ji-1,jj-1) + dm
316	zvis21 = zviseta (ji-1,jj-1)
317	zdiag = zvis22 * ( akappa(ji-1,jj-1,1,2) + akappa(ji-1,jj-1,2,2) )
318	zs11_11 = zvis11 * akappa(ji-1,jj-1,1,2) + zdiag
319	zs12_11 = -zvis12 * akappa(ji-1,jj-1,2,1) + zvis21 * akappa(ji-1,jj-1,1,1)
320	zs22_11 = zvis11 * akappa(ji-1,jj-1,2,2) + zdiag
321	zs21_11 = zvis12 * akappa(ji-1,jj-1,1,1) - zvis21 * akappa(ji-1,jj-1,2,1)
322
323	zvis11 = 2._wp * zviseta (ji,jj-1) + dm
324	zvis22 = zviszeta(ji,jj-1) - zviseta(ji,jj-1)
325	zvis12 = zviseta (ji,jj-1) + dm
326	zvis21 = zviseta (ji,jj-1)
327	zdiag = zvis22 * ( akappa(ji,jj-1,1,2) + akappa(ji,jj-1,2,2) )
328	zs11_21 = zvis11 * akappa(ji,jj-1,1,2) + zdiag
329	zs12_21 = -zvis12 * akappa(ji,jj-1,2,1) - zvis21 * akappa(ji,jj-1,1,1)
330	zs22_21 = zvis11 * akappa(ji,jj-1,2,2) + zdiag
331	zs21_21 = -zvis12 * akappa(ji,jj-1,1,1) - zvis21 * akappa(ji,jj-1,2,1)
332
333	zvis11 = 2._wp * zviseta (ji-1,jj) + dm
334	zvis22 = zviszeta(ji-1,jj) - zviseta(ji-1,jj)
335	zvis12 = zviseta (ji-1,jj) + dm
336	zvis21 = zviseta (ji-1,jj)
337	zdiag = zvis22 * ( akappa(ji-1,jj,1,2) - akappa(ji-1,jj,2,2) )
338	zs11_12 = zvis11 * akappa(ji-1,jj,1,2) + zdiag
339	zs12_12 = -zvis12 * akappa(ji-1,jj,2,1) + zvis21 * akappa(ji-1,jj,1,1)
340	zs22_12 = -zvis11 * akappa(ji-1,jj,2,2) + zdiag
341	zs21_12 = zvis12 * akappa(ji-1,jj,1,1) - zvis21 * akappa(ji-1,jj,2,1)
342
343	zvis11 = 2._wp * zviseta (ji,jj) + dm
344	zvis22 = zviszeta(ji,jj) - zviseta(ji,jj)
345	zvis12 = zviseta (ji,jj) + dm
346	zvis21 = zviseta (ji,jj)
347	zdiag = zvis22 * ( akappa(ji,jj,1,2) - akappa(ji,jj,2,2) )
348	zs11_22 = zvis11 * akappa(ji,jj,1,2) + zdiag
349	zs12_22 = -zvis12 * akappa(ji,jj,2,1) - zvis21 * akappa(ji,jj,1,1)
350	zs22_22 = -zvis11 * akappa(ji,jj,2,2) + zdiag
351	zs21_22 = -zvis12 * akappa(ji,jj,1,1) - zvis21 * akappa(ji,jj,2,1)
352
353	zc1v(ji,jj) = + alambd(ji,jj,2,2,2,1) * zs11_21 + alambd(ji,jj,2,2,2,2) * zs11_22 &
354	& - alambd(ji,jj,2,2,1,1) * zs11_11 - alambd(ji,jj,2,2,1,2) * zs11_12 &
355	& - alambd(ji,jj,1,1,2,1) * zs12_21 - alambd(ji,jj,1,1,1,1) * zs12_11 &
356	& + alambd(ji,jj,1,1,2,2) * zs12_22 + alambd(ji,jj,1,1,1,2) * zs12_12 &
357	& + alambd(ji,jj,1,2,1,1) * zs21_11 + alambd(ji,jj,1,2,2,1) * zs21_21 &
358	& + alambd(ji,jj,1,2,1,2) * zs21_12 + alambd(ji,jj,1,2,2,2) * zs21_22 &
359	& - alambd(ji,jj,2,1,1,1) * zs22_11 - alambd(ji,jj,2,1,2,1) * zs22_21 &
360	& - alambd(ji,jj,2,1,1,2) * zs22_12 - alambd(ji,jj,2,1,2,2) * zs22_22
361
362	zc2v(ji,jj) = + alambd(ji,jj,2,2,2,1) * zs21_21 + alambd(ji,jj,2,2,2,2) * zs21_22 &
363	& - alambd(ji,jj,2,2,1,1) * zs21_11 - alambd(ji,jj,2,2,1,2) * zs21_12 &
364	& - alambd(ji,jj,1,1,2,1) * zs22_21 - alambd(ji,jj,1,1,1,1) * zs22_11 &
365	& + alambd(ji,jj,1,1,2,2) * zs22_22 + alambd(ji,jj,1,1,1,2) * zs22_12 &
366	& - alambd(ji,jj,1,2,1,1) * zs11_11 - alambd(ji,jj,1,2,2,1) * zs11_21 &
367	& - alambd(ji,jj,1,2,1,2) * zs11_12 - alambd(ji,jj,1,2,2,2) * zs11_22 &
368	& + alambd(ji,jj,2,1,1,1) * zs12_11 + alambd(ji,jj,2,1,2,1) * zs12_21 &
369	& + alambd(ji,jj,2,1,1,2) * zs12_12 + alambd(ji,jj,2,1,2,2) * zs12_22
370	END DO
371	END DO
372
373	! GAUSS-SEIDEL method
374	! ! ================ !
375	iflag: DO jter = 1 , nbitdr ! Relaxation !
376	! ! ================ !
377	!CDIR NOVERRCHK
378	DO jj = k_j1+1, k_jpj-1
379	!CDIR NOVERRCHK
380	DO ji = 2, fs_jpim1 ! NO vector opt.
381	!
382	ze11 = akappa(ji,jj-1,1,1) * zu_a(ji+1,jj) + akappa(ji,jj-1,1,2) * zv_a(ji+1,jj)
383	ze12 = + akappa(ji,jj-1,2,2) * zu_a(ji+1,jj) - akappa(ji,jj-1,2,1) * zv_a(ji+1,jj)
384	ze22 = + akappa(ji,jj-1,2,2) * zv_a(ji+1,jj) + akappa(ji,jj-1,2,1) * zu_a(ji+1,jj)
385	ze21 = akappa(ji,jj-1,1,1) * zv_a(ji+1,jj) - akappa(ji,jj-1,1,2) * zu_a(ji+1,jj)
386	zvis11 = 2._wp * zviseta (ji,jj-1) + dm
387	zvis22 = zviszeta(ji,jj-1) - zviseta(ji,jj-1)
388	zvis12 = zviseta (ji,jj-1) + dm
389	zvis21 = zviseta (ji,jj-1)
390	zdiag = zvis22 * ( ze11 + ze22 )
391	zs11_21 = zvis11 * ze11 + zdiag
392	zs12_21 = zvis12 * ze12 + zvis21 * ze21
393	zs22_21 = zvis11 * ze22 + zdiag
394	zs21_21 = zvis12 * ze21 + zvis21 * ze12
395
396	ze11 = akappa(ji-1,jj,1,1) * ( zu_a(ji ,jj+1) - zu_a(ji-1,jj+1) ) &
397	& + akappa(ji-1,jj,1,2) * ( zv_a(ji ,jj+1) + zv_a(ji-1,jj+1) )
398	ze12 = + akappa(ji-1,jj,2,2) * ( zu_a(ji-1,jj+1) + zu_a(ji ,jj+1) ) &
399	& - akappa(ji-1,jj,2,1) * ( zv_a(ji-1,jj+1) + zv_a(ji ,jj+1) )
400	ze22 = + akappa(ji-1,jj,2,2) * ( zv_a(ji-1,jj+1) + zv_a(ji ,jj+1) ) &
401	& + akappa(ji-1,jj,2,1) * ( zu_a(ji-1,jj+1) + zu_a(ji ,jj+1) )
402	ze21 = akappa(ji-1,jj,1,1) * ( zv_a(ji ,jj+1) - zv_a(ji-1,jj+1) ) &
403	& - akappa(ji-1,jj,1,2) * ( zu_a(ji ,jj+1) + zu_a(ji-1,jj+1) )
404	zvis11 = 2._wp * zviseta (ji-1,jj) + dm
405	zvis22 = zviszeta(ji-1,jj) - zviseta(ji-1,jj)
406	zvis12 = zviseta (ji-1,jj) + dm
407	zvis21 = zviseta (ji-1,jj)
408	zdiag = zvis22 * ( ze11 + ze22 )
409	zs11_12 = zvis11 * ze11 + zdiag
410	zs12_12 = zvis12 * ze12 + zvis21 * ze21
411	zs22_12 = zvis11 * ze22 + zdiag
412	zs21_12 = zvis12 * ze21 + zvis21 * ze12
413
414	ze11 = akappa(ji,jj,1,1) * ( zu_a(ji+1,jj) + zu_a(ji+1,jj+1) - zu_a(ji ,jj+1) ) &
415	& + akappa(ji,jj,1,2) * ( zv_a(ji+1,jj) + zv_a(ji+1,jj+1) + zv_a(ji ,jj+1) )
416	ze12 = - akappa(ji,jj,2,2) * ( zu_a(ji+1,jj) - zu_a(ji ,jj+1) - zu_a(ji+1,jj+1) ) &
417	& - akappa(ji,jj,2,1) * ( zv_a(ji+1,jj) + zv_a(ji ,jj+1) + zv_a(ji+1,jj+1) )
418	ze22 = - akappa(ji,jj,2,2) * ( zv_a(ji+1,jj) - zv_a(ji ,jj+1) - zv_a(ji+1,jj+1) ) &
419	& + akappa(ji,jj,2,1) * ( zu_a(ji+1,jj) + zu_a(ji ,jj+1) + zu_a(ji+1,jj+1) )
420	ze21 = akappa(ji,jj,1,1) * ( zv_a(ji+1,jj) + zv_a(ji+1,jj+1) - zv_a(ji ,jj+1) ) &
421	& - akappa(ji,jj,1,2) * ( zu_a(ji+1,jj) + zu_a(ji+1,jj+1) + zu_a(ji ,jj+1) )
422	zvis11 = 2._wp * zviseta (ji,jj) + dm
423	zvis22 = zviszeta(ji,jj) - zviseta(ji,jj)
424	zvis12 = zviseta (ji,jj) + dm
425	zvis21 = zviseta (ji,jj)
426	zdiag = zvis22 * ( ze11 + ze22 )
427	zs11_22 = zvis11 * ze11 + zdiag
428	zs12_22 = zvis12 * ze12 + zvis21 * ze21
429	zs22_22 = zvis11 * ze22 + zdiag
430	zs21_22 = zvis12 * ze21 + zvis21 * ze12
431
432	! 2nd part
433	ze11 = akappa(ji-1,jj-1,1,1) * ( zu_a(ji ,jj-1) - zu_a(ji-1,jj-1) - zu_a(ji-1,jj) ) &
434	& + akappa(ji-1,jj-1,1,2) * ( zv_a(ji ,jj-1) + zv_a(ji-1,jj-1) + zv_a(ji-1,jj) )
435	ze12 = - akappa(ji-1,jj-1,2,2) * ( zu_a(ji-1,jj-1) + zu_a(ji ,jj-1) - zu_a(ji-1,jj) ) &
436	& - akappa(ji-1,jj-1,2,1) * ( zv_a(ji-1,jj-1) + zv_a(ji ,jj-1) + zv_a(ji-1,jj) )
437	ze22 = - akappa(ji-1,jj-1,2,2) * ( zv_a(ji-1,jj-1) + zv_a(ji ,jj-1) - zv_a(ji-1,jj) ) &
438	& + akappa(ji-1,jj-1,2,1) * ( zu_a(ji-1,jj-1) + zu_a(ji ,jj-1) + zu_a(ji-1,jj) )
439	ze21 = akappa(ji-1,jj-1,1,1) * ( zv_a(ji ,jj-1) - zv_a(ji-1,jj-1) - zv_a(ji-1,jj) ) &
440	& - akappa(ji-1,jj-1,1,2) * ( zu_a(ji ,jj-1) + zu_a(ji-1,jj-1) + zu_a(ji-1,jj) )
441	zvis11 = 2._wp * zviseta (ji-1,jj-1) + dm
442	zvis22 = zviszeta(ji-1,jj-1) - zviseta(ji-1,jj-1)
443	zvis12 = zviseta (ji-1,jj-1) + dm
444	zvis21 = zviseta (ji-1,jj-1)
445	zdiag = zvis22 * ( ze11 + ze22 )
446	zs11_11 = zvis11 * ze11 + zdiag
447	zs12_11 = zvis12 * ze12 + zvis21 * ze21
448	zs22_11 = zvis11 * ze22 + zdiag
449	zs21_11 = zvis12 * ze21 + zvis21 * ze12
450
451	ze11 = akappa(ji,jj-1,1,1) * ( zu_a(ji+1,jj-1) - zu_a(ji ,jj-1) ) &
452	& + akappa(ji,jj-1,1,2) * ( zv_a(ji+1,jj-1) + zv_a(ji ,jj-1) )
453	ze12 = - akappa(ji,jj-1,2,2) * ( zu_a(ji ,jj-1) + zu_a(ji+1,jj-1) ) &
454	& - akappa(ji,jj-1,2,1) * ( zv_a(ji ,jj-1) + zv_a(ji+1,jj-1) )
455	ze22 = - akappa(ji,jj-1,2,2) * ( zv_a(ji ,jj-1) + zv_a(ji+1,jj-1) ) &
456	& + akappa(ji,jj-1,2,1) * ( zu_a(ji ,jj-1) + zu_a(ji+1,jj-1) )
457	ze21 = akappa(ji,jj-1,1,1) * ( zv_a(ji+1,jj-1) - zv_a(ji ,jj-1) ) &
458	& - akappa(ji,jj-1,1,2) * ( zu_a(ji+1,jj-1) + zu_a(ji ,jj-1) )
459	zvis11 = 2._wp * zviseta (ji,jj-1) + dm
460	zvis22 = zviszeta(ji,jj-1) - zviseta(ji,jj-1)
461	zvis12 = zviseta (ji,jj-1) + dm
462	zvis21 = zviseta (ji,jj-1)
463	zdiag = zvis22 * ( ze11 + ze22 )
464	zs11_21 = zs11_21 + zvis11 * ze11 + zdiag
465	zs12_21 = zs12_21 + zvis12 * ze12 + zvis21 * ze21
466	zs22_21 = zs22_21 + zvis11 * ze22 + zdiag
467	zs21_21 = zs21_21 + zvis12 * ze21 + zvis21 * ze12
468
469	ze11 = - akappa(ji-1,jj,1,1) * zu_a(ji-1,jj) + akappa(ji-1,jj,1,2) * zv_a(ji-1,jj)
470	ze12 = - akappa(ji-1,jj,2,2) * zu_a(ji-1,jj) - akappa(ji-1,jj,2,1) * zv_a(ji-1,jj)
471	ze22 = - akappa(ji-1,jj,2,2) * zv_a(ji-1,jj) + akappa(ji-1,jj,2,1) * zu_a(ji-1,jj)
472	ze21 = - akappa(ji-1,jj,1,1) * zv_a(ji-1,jj) - akappa(ji-1,jj,1,2) * zu_a(ji-1,jj)
473	zvis11 = 2._wp * zviseta (ji-1,jj) + dm
474	zvis22 = zviszeta(ji-1,jj) - zviseta(ji-1,jj)
475	zvis12 = zviseta (ji-1,jj) + dm
476	zvis21 = zviseta (ji-1,jj)
477	zdiag = zvis22 * ( ze11 + ze22 )
478	zs11_12 = zs11_12 + zvis11 * ze11 + zdiag
479	zs12_12 = zs12_12 + zvis12 * ze12 + zvis21 * ze21
480	zs22_12 = zs22_12 + zvis11 * ze22 + zdiag
481	zs21_12 = zs21_12 + zvis12 * ze21 + zvis21 * ze12
482
483	zd1 = + alambd(ji,jj,2,2,2,1) * zs11_21 + alambd(ji,jj,2,2,2,2) * zs11_22 &
484	& - alambd(ji,jj,2,2,1,1) * zs11_11 - alambd(ji,jj,2,2,1,2) * zs11_12 &
485	& - alambd(ji,jj,1,1,2,1) * zs12_21 - alambd(ji,jj,1,1,1,1) * zs12_11 &
486	& + alambd(ji,jj,1,1,2,2) * zs12_22 + alambd(ji,jj,1,1,1,2) * zs12_12 &
487	& + alambd(ji,jj,1,2,1,1) * zs21_11 + alambd(ji,jj,1,2,2,1) * zs21_21 &
488	& + alambd(ji,jj,1,2,1,2) * zs21_12 + alambd(ji,jj,1,2,2,2) * zs21_22 &
489	& - alambd(ji,jj,2,1,1,1) * zs22_11 - alambd(ji,jj,2,1,2,1) * zs22_21 &
490	& - alambd(ji,jj,2,1,1,2) * zs22_12 - alambd(ji,jj,2,1,2,2) * zs22_22
491
492	zd2 = + alambd(ji,jj,2,2,2,1) * zs21_21 + alambd(ji,jj,2,2,2,2) * zs21_22 &
493	& - alambd(ji,jj,2,2,1,1) * zs21_11 - alambd(ji,jj,2,2,1,2) * zs21_12 &
494	& - alambd(ji,jj,1,1,2,1) * zs22_21 - alambd(ji,jj,1,1,1,1) * zs22_11 &
495	& + alambd(ji,jj,1,1,2,2) * zs22_22 + alambd(ji,jj,1,1,1,2) * zs22_12 &
496	& - alambd(ji,jj,1,2,1,1) * zs11_11 - alambd(ji,jj,1,2,2,1) * zs11_21 &
497	& - alambd(ji,jj,1,2,1,2) * zs11_12 - alambd(ji,jj,1,2,2,2) * zs11_22 &
498	& + alambd(ji,jj,2,1,1,1) * zs12_11 + alambd(ji,jj,2,1,2,1) * zs12_21 &
499	& + alambd(ji,jj,2,1,1,2) * zs12_12 + alambd(ji,jj,2,1,2,2) * zs12_22
500
501	zur = zu_a(ji,jj) - u_oce(ji,jj)
502	zvr = zv_a(ji,jj) - v_oce(ji,jj)
503	!!!!
504	zmod = SQRT( zurzur + zvrzvr ) * ( 1._wp - zfrld(ji,jj) )
505	za = rhoco * zmod
506	!!!!
507	!!gm chg resul za = rhoco * SQRT( zurzur + zvrzvr ) * ( 1._wp - zfrld(ji,jj) )
508	zac = za * cangvg
509	zmpzas = alpha * zcorl(ji,jj) + za * zsang(ji,jj)
510	zmassdt = zusdtp * zmass(ji,jj)
511	zcorlal = ( 1._wp - alpha ) * zcorl(ji,jj)
512
513	za1 = zmassdt * zu0(ji,jj) + zcorlal * zv0(ji,jj) + za1ct(ji,jj) &
514	& + za * ( cangvg * u_oce(ji,jj) - zsang(ji,jj) * v_oce(ji,jj) )
515	za2 = zmassdt * zv0(ji,jj) - zcorlal * zu0(ji,jj) + za2ct(ji,jj) &
516	& + za * ( cangvg * v_oce(ji,jj) + zsang(ji,jj) * u_oce(ji,jj) )
517	zb1 = zmassdt + zac - zc1u(ji,jj)
518	zb2 = zmpzas - zc2u(ji,jj)
519	zc1 = zmpzas + zc1v(ji,jj)
520	zc2 = zmassdt + zac - zc2v(ji,jj)
521	zdeter = zc1 * zb2 + zc2 * zb1
522	zden = SIGN( rone, zdeter) / MAX( epsd , ABS( zdeter ) )
523	zunw = ( ( za1 + zd1 ) * zc2 + ( za2 + zd2 ) * zc1 ) * zden
524	zvnw = ( ( za2 + zd2 ) * zb1 - ( za1 + zd1 ) * zb2 ) * zden
525	zmask = ( 1._wp - MAX( rzero, SIGN( rone , 1._wp - zmass(ji,jj) ) ) ) * tmu(ji,jj)
526
527	zu_n(ji,jj) = ( zu_a(ji,jj) + om * ( zunw - zu_a(ji,jj) ) * tmu(ji,jj) ) * zmask
528	zv_n(ji,jj) = ( zv_a(ji,jj) + om * ( zvnw - zv_a(ji,jj) ) * tmu(ji,jj) ) * zmask
529	END DO
530	END DO
531
532	CALL lbc_lnk( zu_n(:,1:jpj), 'I', -1. )
533	CALL lbc_lnk( zv_n(:,1:jpj), 'I', -1. )
534
535	! Test of Convergence
536	DO jj = k_j1+1 , k_jpj-1
537	zresr(:,jj) = MAX( ABS( zu_a(:,jj) - zu_n(:,jj) ) , ABS( zv_a(:,jj) - zv_n(:,jj) ) )
538	END DO
539	zresm = MAXVAL( zresr(1:jpi,k_j1+1:k_jpj-1) )
540	!!!! this should be faster on scalar processor
541	! zresm = MAXVAL( MAX( ABS( zu_a(1:jpi,k_j1+1:k_jpj-1) - zu_n(1:jpi,k_j1+1:k_jpj-1) ), &
542	! & ABS( zv_a(1:jpi,k_j1+1:k_jpj-1) - zv_n(1:jpi,k_j1+1:k_jpj-1) ) ) )
543	!!!!
544	IF( lk_mpp ) CALL mpp_max( zresm ) ! max over the global domain
545
546	DO jj = k_j1, k_jpj
547	zu_a(:,jj) = zu_n(:,jj)
548	zv_a(:,jj) = zv_n(:,jj)
549	END DO
550
551	IF( zresm <= resl ) EXIT iflag
552
553	! ! ================ !
554	END DO iflag ! end Relaxation !
555	! ! ================ !
556
557	IF( zindu == 0 ) THEN ! even iteration
558	DO jj = k_j1 , k_jpj-1
559	zu0(:,jj) = zu_a(:,jj)
560	zv0(:,jj) = zv_a(:,jj)
561	END DO
562	ENDIF
563	! ! ==================== !
564	END DO ! end loop over iter !
565	! ! ==================== !
566
567	u_ice(:,:) = zu_a(:,1:jpj)
568	v_ice(:,:) = zv_a(:,1:jpj)
569
570	IF(ln_ctl) THEN
571	WRITE(charout,FMT="('lim_rhg : res =',D23.16, ' iter =',I4)") zresm, jter
572	CALL prt_ctl_info(charout)
573	CALL prt_ctl(tab2d_1=u_ice, clinfo1=' lim_rhg : u_ice :', tab2d_2=v_ice, clinfo2=' v_ice :')
574	ENDIF
575
576	CALL wrk_dealloc( jpi,jpj, zfrld, zmass, zcorl, za1ct, za2ct, zresr )
577	CALL wrk_dealloc( jpi,jpj, zc1u , zc1v , zc2u , zc2v , zsang )
578	CALL wrk_dealloc( jpi,jpj+2, zu0, zv0, zu_n, zv_n, zu_a, zv_a, zviszeta, zviseta, kjstart = 0 )
579	CALL wrk_dealloc( jpi,jpj+2, zzfrld, zztms, zi1, zi2, zmasst, zpresh, kjstart = 0 )
580
581	END SUBROUTINE lim_rhg_2
582
583	#else
584	!!----------------------------------------------------------------------
585	!! Default option Dummy module NO VP & LIM-2 sea-ice model
586	!!----------------------------------------------------------------------
587	CONTAINS
588	SUBROUTINE lim_rhg_2( k1 , k2 ) ! Dummy routine
589	WRITE(,) 'lim_rhg_2: You should not have seen this print! error?', k1, k2
590	END SUBROUTINE lim_rhg_2
591	#endif
592
593	!!==============================================================================
594	END MODULE limrhg_2

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

Download in other formats: