1 | MODULE icbutl |
---|
2 | !!====================================================================== |
---|
3 | !! *** MODULE icbutl *** |
---|
4 | !! Icebergs: various iceberg utility routines |
---|
5 | !!====================================================================== |
---|
6 | !! History : 3.3.1 ! 2010-01 (Martin&Adcroft) Original code |
---|
7 | !! - ! 2011-03 (Madec) Part conversion to NEMO form |
---|
8 | !! - ! Removal of mapping from another grid |
---|
9 | !! - ! 2011-04 (Alderson) Split into separate modules |
---|
10 | !!---------------------------------------------------------------------- |
---|
11 | |
---|
12 | !!---------------------------------------------------------------------- |
---|
13 | !! icb_utl_interp : |
---|
14 | !! icb_utl_bilin : |
---|
15 | !! icb_utl_bilin_e : |
---|
16 | !!---------------------------------------------------------------------- |
---|
17 | USE par_oce ! ocean parameters |
---|
18 | USE dom_oce ! ocean domain |
---|
19 | USE in_out_manager ! IO parameters |
---|
20 | USE lbclnk ! lateral boundary condition |
---|
21 | USE lib_mpp ! MPI code and lk_mpp in particular |
---|
22 | USE icb_oce ! define iceberg arrays |
---|
23 | USE sbc_oce ! ocean surface boundary conditions |
---|
24 | #if defined key_si3 |
---|
25 | USE ice, ONLY: u_ice, v_ice, hm_i ! SI3 variables |
---|
26 | #endif |
---|
27 | |
---|
28 | IMPLICIT NONE |
---|
29 | PRIVATE |
---|
30 | |
---|
31 | PUBLIC icb_utl_copy ! routine called in icbstp module |
---|
32 | PUBLIC icb_utl_interp ! routine called in icbdyn, icbthm modules |
---|
33 | PUBLIC icb_utl_bilin ! routine called in icbini, icbdyn modules |
---|
34 | PUBLIC icb_utl_bilin_x ! routine called in icbdyn module |
---|
35 | PUBLIC icb_utl_add ! routine called in icbini.F90, icbclv, icblbc and icbrst modules |
---|
36 | PUBLIC icb_utl_delete ! routine called in icblbc, icbthm modules |
---|
37 | PUBLIC icb_utl_destroy ! routine called in icbstp module |
---|
38 | PUBLIC icb_utl_track ! routine not currently used, retain just in case |
---|
39 | PUBLIC icb_utl_print_berg ! routine called in icbthm module |
---|
40 | PUBLIC icb_utl_print ! routine called in icbini, icbstp module |
---|
41 | PUBLIC icb_utl_count ! routine called in icbdia, icbini, icblbc, icbrst modules |
---|
42 | PUBLIC icb_utl_incr ! routine called in icbini, icbclv modules |
---|
43 | PUBLIC icb_utl_yearday ! routine called in icbclv, icbstp module |
---|
44 | PUBLIC icb_utl_mass ! routine called in icbdia module |
---|
45 | PUBLIC icb_utl_heat ! routine called in icbdia module |
---|
46 | |
---|
47 | !!---------------------------------------------------------------------- |
---|
48 | !! NEMO/OCE 4.0 , NEMO Consortium (2018) |
---|
49 | !! $Id$ |
---|
50 | !! Software governed by the CeCILL licence (./LICENSE) |
---|
51 | !!---------------------------------------------------------------------- |
---|
52 | CONTAINS |
---|
53 | |
---|
54 | SUBROUTINE icb_utl_copy() |
---|
55 | !!---------------------------------------------------------------------- |
---|
56 | !! *** ROUTINE icb_utl_copy *** |
---|
57 | !! |
---|
58 | !! ** Purpose : iceberg initialization. |
---|
59 | !! |
---|
60 | !! ** Method : - blah blah |
---|
61 | !!---------------------------------------------------------------------- |
---|
62 | |
---|
63 | ! copy nemo forcing arrays into iceberg versions with extra halo |
---|
64 | ! only necessary for variables not on T points |
---|
65 | ! and ssh which is used to calculate gradients |
---|
66 | |
---|
67 | uo_e(:,:) = 0._wp ; uo_e(1:jpi,1:jpj) = ssu_m(:,:) * umask(:,:,1) |
---|
68 | vo_e(:,:) = 0._wp ; vo_e(1:jpi,1:jpj) = ssv_m(:,:) * vmask(:,:,1) |
---|
69 | ff_e(:,:) = 0._wp ; ff_e(1:jpi,1:jpj) = ff_f (:,:) |
---|
70 | tt_e(:,:) = 0._wp ; tt_e(1:jpi,1:jpj) = sst_m(:,:) |
---|
71 | fr_e(:,:) = 0._wp ; fr_e(1:jpi,1:jpj) = fr_i (:,:) |
---|
72 | ua_e(:,:) = 0._wp ; ua_e(1:jpi,1:jpj) = utau (:,:) * umask(:,:,1) ! maybe mask useless because mask applied in sbcblk |
---|
73 | va_e(:,:) = 0._wp ; va_e(1:jpi,1:jpj) = vtau (:,:) * vmask(:,:,1) ! maybe mask useless because mask applied in sbcblk |
---|
74 | ! |
---|
75 | CALL lbc_lnk_icb( uo_e, 'U', -1._wp, 1, 1 ) |
---|
76 | CALL lbc_lnk_icb( vo_e, 'V', -1._wp, 1, 1 ) |
---|
77 | CALL lbc_lnk_icb( ff_e, 'F', +1._wp, 1, 1 ) |
---|
78 | CALL lbc_lnk_icb( ua_e, 'U', -1._wp, 1, 1 ) |
---|
79 | CALL lbc_lnk_icb( va_e, 'V', -1._wp, 1, 1 ) |
---|
80 | CALL lbc_lnk_icb( fr_e, 'T', +1._wp, 1, 1 ) |
---|
81 | CALL lbc_lnk_icb( tt_e, 'T', +1._wp, 1, 1 ) |
---|
82 | #if defined key_si3 |
---|
83 | hicth(:,:) = 0._wp ; hicth(1:jpi,1:jpj) = hm_i (:,:) |
---|
84 | ui_e(:,:) = 0._wp ; ui_e(1:jpi, 1:jpj) = u_ice(:,:) |
---|
85 | vi_e(:,:) = 0._wp ; vi_e(1:jpi, 1:jpj) = v_ice(:,:) |
---|
86 | ! |
---|
87 | CALL lbc_lnk_icb( hicth, 'T', +1._wp, 1, 1 ) |
---|
88 | CALL lbc_lnk_icb( ui_e , 'U', -1._wp, 1, 1 ) |
---|
89 | CALL lbc_lnk_icb( vi_e , 'V', -1._wp, 1, 1 ) |
---|
90 | #endif |
---|
91 | |
---|
92 | !! special for ssh which is used to calculate slope |
---|
93 | !! so fudge some numbers all the way around the boundary |
---|
94 | |
---|
95 | ssh_e(:,:) = 0._wp ; ssh_e(1:jpi, 1:jpj) = ssh_m(:,:) * tmask(:,:,1) |
---|
96 | ssh_e(0 , :) = ssh_e(1 , :) |
---|
97 | ssh_e(jpi+1, :) = ssh_e(jpi, :) |
---|
98 | ssh_e(: , 0) = ssh_e(: , 1) |
---|
99 | ssh_e(: ,jpj+1) = ssh_e(: ,jpj) |
---|
100 | ssh_e(0,0) = ssh_e(1,1) |
---|
101 | ssh_e(jpi+1,0) = ssh_e(jpi,1) |
---|
102 | ssh_e(0,jpj+1) = ssh_e(1,jpj) |
---|
103 | ssh_e(jpi+1,jpj+1) = ssh_e(jpi,jpj) |
---|
104 | CALL lbc_lnk_icb( ssh_e, 'T', +1._wp, 1, 1 ) |
---|
105 | ! |
---|
106 | END SUBROUTINE icb_utl_copy |
---|
107 | |
---|
108 | |
---|
109 | SUBROUTINE icb_utl_interp( pi, pe1, puo, pui, pua, pssh_i, & |
---|
110 | & pj, pe2, pvo, pvi, pva, pssh_j, & |
---|
111 | & psst, pcn, phi, pff ) |
---|
112 | !!---------------------------------------------------------------------- |
---|
113 | !! *** ROUTINE icb_utl_interp *** |
---|
114 | !! |
---|
115 | !! ** Purpose : interpolation |
---|
116 | !! |
---|
117 | !! ** Method : - interpolate from various ocean arrays onto iceberg position |
---|
118 | !! |
---|
119 | !! !!gm CAUTION here I do not care of the slip/no-slip conditions |
---|
120 | !! this can be done later (not that easy to do...) |
---|
121 | !! right now, U is 0 in land so that the coastal value of velocity parallel to the coast |
---|
122 | !! is half the off shore value, wile the normal-to-the-coast value is zero. |
---|
123 | !! This is OK as a starting point. |
---|
124 | !! |
---|
125 | !!---------------------------------------------------------------------- |
---|
126 | REAL(wp), INTENT(in ) :: pi , pj ! position in (i,j) referential |
---|
127 | REAL(wp), INTENT( out) :: pe1, pe2 ! i- and j scale factors |
---|
128 | REAL(wp), INTENT( out) :: puo, pvo, pui, pvi, pua, pva ! ocean, ice and wind speeds |
---|
129 | REAL(wp), INTENT( out) :: pssh_i, pssh_j ! ssh i- & j-gradients |
---|
130 | REAL(wp), INTENT( out) :: psst, pcn, phi, pff ! SST, ice concentration, ice thickness, Coriolis |
---|
131 | ! |
---|
132 | REAL(wp) :: zcd, zmod ! local scalars |
---|
133 | !!---------------------------------------------------------------------- |
---|
134 | |
---|
135 | pe1 = icb_utl_bilin_e( e1t, e1u, e1v, e1f, pi, pj ) ! scale factors |
---|
136 | pe2 = icb_utl_bilin_e( e2t, e2u, e2v, e2f, pi, pj ) |
---|
137 | ! |
---|
138 | puo = icb_utl_bilin_h( uo_e, pi, pj, 'U' ) ! ocean velocities |
---|
139 | pvo = icb_utl_bilin_h( vo_e, pi, pj, 'V' ) |
---|
140 | psst = icb_utl_bilin_h( tt_e, pi, pj, 'T' ) ! SST |
---|
141 | pcn = icb_utl_bilin_h( fr_e , pi, pj, 'T' ) ! ice concentration |
---|
142 | pff = icb_utl_bilin_h( ff_e , pi, pj, 'F' ) ! Coriolis parameter |
---|
143 | ! |
---|
144 | pua = icb_utl_bilin_h( ua_e , pi, pj, 'U' ) ! 10m wind |
---|
145 | pva = icb_utl_bilin_h( va_e , pi, pj, 'V' ) ! here (ua,va) are stress => rough conversion from stress to speed |
---|
146 | zcd = 1.22_wp * 1.5e-3_wp ! air density * drag coefficient |
---|
147 | zmod = 1._wp / MAX( 1.e-20, SQRT( zcd * SQRT( pua*pua + pva*pva) ) ) |
---|
148 | pua = pua * zmod ! note: stress module=0 necessarly implies ua=va=0 |
---|
149 | pva = pva * zmod |
---|
150 | |
---|
151 | #if defined key_si3 |
---|
152 | pui = icb_utl_bilin_h( ui_e , pi, pj, 'U' ) ! sea-ice velocities |
---|
153 | pvi = icb_utl_bilin_h( vi_e , pi, pj, 'V' ) |
---|
154 | phi = icb_utl_bilin_h( hicth, pi, pj, 'T' ) ! ice thickness |
---|
155 | #else |
---|
156 | pui = 0._wp |
---|
157 | pvi = 0._wp |
---|
158 | phi = 0._wp |
---|
159 | #endif |
---|
160 | |
---|
161 | ! Estimate SSH gradient in i- and j-direction (centred evaluation) |
---|
162 | pssh_i = ( icb_utl_bilin_h( ssh_e, pi+0.1_wp, pj, 'T' ) - & |
---|
163 | & icb_utl_bilin_h( ssh_e, pi-0.1_wp, pj, 'T' ) ) / ( 0.2_wp * pe1 ) |
---|
164 | pssh_j = ( icb_utl_bilin_h( ssh_e, pi, pj+0.1_wp, 'T' ) - & |
---|
165 | & icb_utl_bilin_h( ssh_e, pi, pj-0.1_wp, 'T' ) ) / ( 0.2_wp * pe2 ) |
---|
166 | ! |
---|
167 | END SUBROUTINE icb_utl_interp |
---|
168 | |
---|
169 | |
---|
170 | REAL(wp) FUNCTION icb_utl_bilin_h( pfld, pi, pj, cd_type ) |
---|
171 | !!---------------------------------------------------------------------- |
---|
172 | !! *** FUNCTION icb_utl_bilin *** |
---|
173 | !! |
---|
174 | !! ** Purpose : bilinear interpolation at berg location depending on the grid-point type |
---|
175 | !! this version deals with extra halo points |
---|
176 | !! |
---|
177 | !! !!gm CAUTION an optional argument should be added to handle |
---|
178 | !! the slip/no-slip conditions ==>>> to be done later |
---|
179 | !! |
---|
180 | !!---------------------------------------------------------------------- |
---|
181 | REAL(wp), DIMENSION(0:jpi+1,0:jpj+1), INTENT(in) :: pfld ! field to be interpolated |
---|
182 | REAL(wp) , INTENT(in) :: pi, pj ! targeted coordinates in (i,j) referential |
---|
183 | CHARACTER(len=1) , INTENT(in) :: cd_type ! type of pfld array grid-points: = T , U , V or F points |
---|
184 | ! |
---|
185 | INTEGER :: ii, ij ! local integer |
---|
186 | REAL(wp) :: zi, zj ! local real |
---|
187 | !!---------------------------------------------------------------------- |
---|
188 | ! |
---|
189 | SELECT CASE ( cd_type ) |
---|
190 | CASE ( 'T' ) |
---|
191 | ! note that here there is no +0.5 added |
---|
192 | ! since we're looking for four T points containing quadrant we're in of |
---|
193 | ! current T cell |
---|
194 | ii = MAX(1, INT( pi )) |
---|
195 | ij = MAX(1, INT( pj )) ! T-point |
---|
196 | zi = pi - REAL(ii,wp) |
---|
197 | zj = pj - REAL(ij,wp) |
---|
198 | CASE ( 'U' ) |
---|
199 | ii = MAX(1, INT( pi-0.5 )) |
---|
200 | ij = MAX(1, INT( pj )) ! U-point |
---|
201 | zi = pi - 0.5 - REAL(ii,wp) |
---|
202 | zj = pj - REAL(ij,wp) |
---|
203 | CASE ( 'V' ) |
---|
204 | ii = MAX(1, INT( pi )) |
---|
205 | ij = MAX(1, INT( pj-0.5 )) ! V-point |
---|
206 | zi = pi - REAL(ii,wp) |
---|
207 | zj = pj - 0.5 - REAL(ij,wp) |
---|
208 | CASE ( 'F' ) |
---|
209 | ii = MAX(1, INT( pi-0.5 )) |
---|
210 | ij = MAX(1, INT( pj-0.5 )) ! F-point |
---|
211 | zi = pi - 0.5 - REAL(ii,wp) |
---|
212 | zj = pj - 0.5 - REAL(ij,wp) |
---|
213 | END SELECT |
---|
214 | ! |
---|
215 | ! find position in this processor. Prevent near edge problems (see #1389) |
---|
216 | ! |
---|
217 | IF ( ii < mig( 1 ) ) THEN ; ii = 1 |
---|
218 | ELSEIF( ii > mig(jpi) ) THEN ; ii = jpi |
---|
219 | ELSE ; ii = mi1(ii) |
---|
220 | ENDIF |
---|
221 | IF ( ij < mjg( 1 ) ) THEN ; ij = 1 |
---|
222 | ELSEIF( ij > mjg(jpj) ) THEN ; ij = jpj |
---|
223 | ELSE ; ij = mj1(ij) |
---|
224 | ENDIF |
---|
225 | ! |
---|
226 | IF( ii == jpi ) ii = ii-1 |
---|
227 | IF( ij == jpj ) ij = ij-1 |
---|
228 | ! |
---|
229 | icb_utl_bilin_h = ( pfld(ii,ij ) * (1.-zi) + pfld(ii+1,ij ) * zi ) * (1.-zj) & |
---|
230 | & + ( pfld(ii,ij+1) * (1.-zi) + pfld(ii+1,ij+1) * zi ) * zj |
---|
231 | ! |
---|
232 | END FUNCTION icb_utl_bilin_h |
---|
233 | |
---|
234 | |
---|
235 | REAL(wp) FUNCTION icb_utl_bilin( pfld, pi, pj, cd_type ) |
---|
236 | !!---------------------------------------------------------------------- |
---|
237 | !! *** FUNCTION icb_utl_bilin *** |
---|
238 | !! |
---|
239 | !! ** Purpose : bilinear interpolation at berg location depending on the grid-point type |
---|
240 | !! |
---|
241 | !! !!gm CAUTION an optional argument should be added to handle |
---|
242 | !! the slip/no-slip conditions ==>>> to be done later |
---|
243 | !! |
---|
244 | !!---------------------------------------------------------------------- |
---|
245 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pfld ! field to be interpolated |
---|
246 | REAL(wp) , INTENT(in) :: pi, pj ! targeted coordinates in (i,j) referential |
---|
247 | CHARACTER(len=1) , INTENT(in) :: cd_type ! type of pfld array grid-points: = T , U , V or F points |
---|
248 | ! |
---|
249 | INTEGER :: ii, ij ! local integer |
---|
250 | REAL(wp) :: zi, zj ! local real |
---|
251 | !!---------------------------------------------------------------------- |
---|
252 | ! |
---|
253 | SELECT CASE ( cd_type ) |
---|
254 | CASE ( 'T' ) |
---|
255 | ! note that here there is no +0.5 added |
---|
256 | ! since we're looking for four T points containing quadrant we're in of |
---|
257 | ! current T cell |
---|
258 | ii = MAX(1, INT( pi )) |
---|
259 | ij = MAX(1, INT( pj )) ! T-point |
---|
260 | zi = pi - REAL(ii,wp) |
---|
261 | zj = pj - REAL(ij,wp) |
---|
262 | CASE ( 'U' ) |
---|
263 | ii = MAX(1, INT( pi-0.5 )) |
---|
264 | ij = MAX(1, INT( pj )) ! U-point |
---|
265 | zi = pi - 0.5 - REAL(ii,wp) |
---|
266 | zj = pj - REAL(ij,wp) |
---|
267 | CASE ( 'V' ) |
---|
268 | ii = MAX(1, INT( pi )) |
---|
269 | ij = MAX(1, INT( pj-0.5 )) ! V-point |
---|
270 | zi = pi - REAL(ii,wp) |
---|
271 | zj = pj - 0.5 - REAL(ij,wp) |
---|
272 | CASE ( 'F' ) |
---|
273 | ii = MAX(1, INT( pi-0.5 )) |
---|
274 | ij = MAX(1, INT( pj-0.5 )) ! F-point |
---|
275 | zi = pi - 0.5 - REAL(ii,wp) |
---|
276 | zj = pj - 0.5 - REAL(ij,wp) |
---|
277 | END SELECT |
---|
278 | ! |
---|
279 | ! find position in this processor. Prevent near edge problems (see #1389) |
---|
280 | IF ( ii < mig( 1 ) ) THEN ; ii = 1 |
---|
281 | ELSEIF( ii > mig(jpi) ) THEN ; ii = jpi |
---|
282 | ELSE ; ii = mi1(ii) |
---|
283 | ENDIF |
---|
284 | IF ( ij < mjg( 1 ) ) THEN ; ij = 1 |
---|
285 | ELSEIF( ij > mjg(jpj) ) THEN ; ij = jpj |
---|
286 | ELSE ; ij = mj1(ij) |
---|
287 | ENDIF |
---|
288 | ! |
---|
289 | IF( ii == jpi ) ii = ii-1 |
---|
290 | IF( ij == jpj ) ij = ij-1 |
---|
291 | ! |
---|
292 | icb_utl_bilin = ( pfld(ii,ij ) * (1.-zi) + pfld(ii+1,ij ) * zi ) * (1.-zj) & |
---|
293 | & + ( pfld(ii,ij+1) * (1.-zi) + pfld(ii+1,ij+1) * zi ) * zj |
---|
294 | ! |
---|
295 | END FUNCTION icb_utl_bilin |
---|
296 | |
---|
297 | |
---|
298 | REAL(wp) FUNCTION icb_utl_bilin_x( pfld, pi, pj ) |
---|
299 | !!---------------------------------------------------------------------- |
---|
300 | !! *** FUNCTION icb_utl_bilin_x *** |
---|
301 | !! |
---|
302 | !! ** Purpose : bilinear interpolation at berg location depending on the grid-point type |
---|
303 | !! Special case for interpolating longitude |
---|
304 | !! |
---|
305 | !! !!gm CAUTION an optional argument should be added to handle |
---|
306 | !! the slip/no-slip conditions ==>>> to be done later |
---|
307 | !! |
---|
308 | !!---------------------------------------------------------------------- |
---|
309 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pfld ! field to be interpolated |
---|
310 | REAL(wp) , INTENT(in) :: pi, pj ! targeted coordinates in (i,j) referential |
---|
311 | ! |
---|
312 | INTEGER :: ii, ij ! local integer |
---|
313 | REAL(wp) :: zi, zj ! local real |
---|
314 | REAL(wp) :: zret ! local real |
---|
315 | REAL(wp), DIMENSION(4) :: z4 |
---|
316 | !!---------------------------------------------------------------------- |
---|
317 | ! |
---|
318 | ! note that here there is no +0.5 added |
---|
319 | ! since we're looking for four T points containing quadrant we're in of |
---|
320 | ! current T cell |
---|
321 | ii = MAX(1, INT( pi )) |
---|
322 | ij = MAX(1, INT( pj )) ! T-point |
---|
323 | zi = pi - REAL(ii,wp) |
---|
324 | zj = pj - REAL(ij,wp) |
---|
325 | ! |
---|
326 | ! find position in this processor. Prevent near edge problems (see #1389) |
---|
327 | IF ( ii < mig( 1 ) ) THEN ; ii = 1 |
---|
328 | ELSEIF( ii > mig(jpi) ) THEN ; ii = jpi |
---|
329 | ELSE ; ii = mi1(ii) |
---|
330 | ENDIF |
---|
331 | IF ( ij < mjg( 1 ) ) THEN ; ij = 1 |
---|
332 | ELSEIF( ij > mjg(jpj) ) THEN ; ij = jpj |
---|
333 | ELSE ; ij = mj1(ij) |
---|
334 | ENDIF |
---|
335 | ! |
---|
336 | IF( ii == jpi ) ii = ii-1 |
---|
337 | IF( ij == jpj ) ij = ij-1 |
---|
338 | ! |
---|
339 | z4(1) = pfld(ii ,ij ) |
---|
340 | z4(2) = pfld(ii+1,ij ) |
---|
341 | z4(3) = pfld(ii ,ij+1) |
---|
342 | z4(4) = pfld(ii+1,ij+1) |
---|
343 | IF( MAXVAL(z4) - MINVAL(z4) > 90._wp ) THEN |
---|
344 | WHERE( z4 < 0._wp ) z4 = z4 + 360._wp |
---|
345 | ENDIF |
---|
346 | ! |
---|
347 | zret = (z4(1) * (1.-zi) + z4(2) * zi) * (1.-zj) + (z4(3) * (1.-zi) + z4(4) * zi) * zj |
---|
348 | IF( zret > 180._wp ) zret = zret - 360._wp |
---|
349 | icb_utl_bilin_x = zret |
---|
350 | ! |
---|
351 | END FUNCTION icb_utl_bilin_x |
---|
352 | |
---|
353 | |
---|
354 | REAL(wp) FUNCTION icb_utl_bilin_e( pet, peu, pev, pef, pi, pj ) |
---|
355 | !!---------------------------------------------------------------------- |
---|
356 | !! *** FUNCTION dom_init *** |
---|
357 | !! |
---|
358 | !! ** Purpose : bilinear interpolation at berg location of horizontal scale factor |
---|
359 | !! ** Method : interpolation done using the 4 nearest grid points among |
---|
360 | !! t-, u-, v-, and f-points. |
---|
361 | !!---------------------------------------------------------------------- |
---|
362 | REAL(wp), DIMENSION(:,:), INTENT(in) :: pet, peu, pev, pef ! horizontal scale factor to be interpolated at t-,u-,v- & f-pts |
---|
363 | REAL(wp) , INTENT(in) :: pi, pj ! targeted coordinates in (i,j) referential |
---|
364 | ! |
---|
365 | INTEGER :: ii, ij, icase ! local integer |
---|
366 | ! |
---|
367 | ! weights corresponding to corner points of a T cell quadrant |
---|
368 | REAL(wp) :: zi, zj ! local real |
---|
369 | ! |
---|
370 | ! values at corner points of a T cell quadrant |
---|
371 | ! 00 = bottom left, 10 = bottom right, 01 = top left, 11 = top right |
---|
372 | REAL(wp) :: ze00, ze10, ze01, ze11 |
---|
373 | !!---------------------------------------------------------------------- |
---|
374 | ! |
---|
375 | ii = MAX(1, INT( pi )) ; ij = MAX(1, INT( pj )) ! left bottom T-point (i,j) indices |
---|
376 | |
---|
377 | ! fractional box spacing |
---|
378 | ! 0 <= zi < 0.5, 0 <= zj < 0.5 --> NW quadrant of current T cell |
---|
379 | ! 0.5 <= zi < 1 , 0 <= zj < 0.5 --> NE quadrant |
---|
380 | ! 0 <= zi < 0.5, 0.5 <= zj < 1 --> SE quadrant |
---|
381 | ! 0.5 <= zi < 1 , 0.5 <= zj < 1 --> SW quadrant |
---|
382 | |
---|
383 | zi = pi - REAL(ii,wp) !!gm use here mig, mjg arrays |
---|
384 | zj = pj - REAL(ij,wp) |
---|
385 | |
---|
386 | ! find position in this processor. Prevent near edge problems (see #1389) |
---|
387 | IF ( ii < mig( 1 ) ) THEN ; ii = 1 |
---|
388 | ELSEIF( ii > mig(jpi) ) THEN ; ii = jpi |
---|
389 | ELSE ; ii = mi1(ii) |
---|
390 | ENDIF |
---|
391 | IF ( ij < mjg( 1 ) ) THEN ; ij = 1 |
---|
392 | ELSEIF( ij > mjg(jpj) ) THEN ; ij = jpj |
---|
393 | ELSE ; ij = mj1(ij) |
---|
394 | ENDIF |
---|
395 | ! |
---|
396 | IF( ii == jpi ) ii = ii-1 |
---|
397 | IF( ij == jpj ) ij = ij-1 |
---|
398 | ! |
---|
399 | IF( 0.0_wp <= zi .AND. zi < 0.5_wp ) THEN |
---|
400 | IF( 0.0_wp <= zj .AND. zj < 0.5_wp ) THEN ! NE quadrant |
---|
401 | ! ! i=I i=I+1/2 |
---|
402 | ze01 = pev(ii ,ij ) ; ze11 = pef(ii ,ij ) ! j=J+1/2 V ------- F |
---|
403 | ze00 = pet(ii ,ij ) ; ze10 = peu(ii ,ij ) ! j=J T ------- U |
---|
404 | zi = 2._wp * zi |
---|
405 | zj = 2._wp * zj |
---|
406 | ELSE ! SE quadrant |
---|
407 | ! ! i=I i=I+1/2 |
---|
408 | ze01 = pet(ii ,ij+1) ; ze11 = peu(ii ,ij+1) ! j=J+1 T ------- U |
---|
409 | ze00 = pev(ii ,ij ) ; ze10 = pef(ii ,ij ) ! j=J+1/2 V ------- F |
---|
410 | zi = 2._wp * zi |
---|
411 | zj = 2._wp * (zj-0.5_wp) |
---|
412 | ENDIF |
---|
413 | ELSE |
---|
414 | IF( 0.0_wp <= zj .AND. zj < 0.5_wp ) THEN ! NW quadrant |
---|
415 | ! ! i=I i=I+1/2 |
---|
416 | ze01 = pef(ii ,ij ) ; ze11 = pev(ii+1,ij) ! j=J+1/2 F ------- V |
---|
417 | ze00 = peu(ii ,ij ) ; ze10 = pet(ii+1,ij) ! j=J U ------- T |
---|
418 | zi = 2._wp * (zi-0.5_wp) |
---|
419 | zj = 2._wp * zj |
---|
420 | ELSE ! SW quadrant |
---|
421 | ! ! i=I+1/2 i=I+1 |
---|
422 | ze01 = peu(ii ,ij+1) ; ze11 = pet(ii+1,ij+1) ! j=J+1 U ------- T |
---|
423 | ze00 = pef(ii ,ij ) ; ze10 = pev(ii+1,ij ) ! j=J+1/2 F ------- V |
---|
424 | zi = 2._wp * (zi-0.5_wp) |
---|
425 | zj = 2._wp * (zj-0.5_wp) |
---|
426 | ENDIF |
---|
427 | ENDIF |
---|
428 | ! |
---|
429 | icb_utl_bilin_e = ( ze01 * (1.-zi) + ze11 * zi ) * zj & |
---|
430 | & + ( ze00 * (1.-zi) + ze10 * zi ) * (1.-zj) |
---|
431 | ! |
---|
432 | END FUNCTION icb_utl_bilin_e |
---|
433 | |
---|
434 | |
---|
435 | SUBROUTINE icb_utl_add( bergvals, ptvals ) |
---|
436 | !!---------------------------------------------------------------------- |
---|
437 | !! *** ROUTINE icb_utl_add *** |
---|
438 | !! |
---|
439 | !! ** Purpose : add a new berg to the iceberg list |
---|
440 | !! |
---|
441 | !!---------------------------------------------------------------------- |
---|
442 | TYPE(iceberg), INTENT(in) :: bergvals |
---|
443 | TYPE(point) , INTENT(in) :: ptvals |
---|
444 | ! |
---|
445 | TYPE(iceberg), POINTER :: new => NULL() |
---|
446 | !!---------------------------------------------------------------------- |
---|
447 | ! |
---|
448 | new => NULL() |
---|
449 | CALL icb_utl_create( new, bergvals, ptvals ) |
---|
450 | CALL icb_utl_insert( new ) |
---|
451 | new => NULL() ! Clear new |
---|
452 | ! |
---|
453 | END SUBROUTINE icb_utl_add |
---|
454 | |
---|
455 | |
---|
456 | SUBROUTINE icb_utl_create( berg, bergvals, ptvals ) |
---|
457 | !!---------------------------------------------------------------------- |
---|
458 | !! *** ROUTINE icb_utl_create *** |
---|
459 | !! |
---|
460 | !! ** Purpose : add a new berg to the iceberg list |
---|
461 | !! |
---|
462 | !!---------------------------------------------------------------------- |
---|
463 | TYPE(iceberg), INTENT(in) :: bergvals |
---|
464 | TYPE(point) , INTENT(in) :: ptvals |
---|
465 | TYPE(iceberg), POINTER :: berg |
---|
466 | ! |
---|
467 | TYPE(point) , POINTER :: pt |
---|
468 | INTEGER :: istat |
---|
469 | !!---------------------------------------------------------------------- |
---|
470 | ! |
---|
471 | IF( ASSOCIATED(berg) ) CALL ctl_stop( 'icebergs, icb_utl_create: berg already associated' ) |
---|
472 | ALLOCATE(berg, STAT=istat) |
---|
473 | IF( istat /= 0 ) CALL ctl_stop( 'failed to allocate iceberg' ) |
---|
474 | berg%number(:) = bergvals%number(:) |
---|
475 | berg%mass_scaling = bergvals%mass_scaling |
---|
476 | berg%prev => NULL() |
---|
477 | berg%next => NULL() |
---|
478 | ! |
---|
479 | ALLOCATE(pt, STAT=istat) |
---|
480 | IF( istat /= 0 ) CALL ctl_stop( 'failed to allocate first iceberg point' ) |
---|
481 | pt = ptvals |
---|
482 | berg%current_point => pt |
---|
483 | ! |
---|
484 | END SUBROUTINE icb_utl_create |
---|
485 | |
---|
486 | |
---|
487 | SUBROUTINE icb_utl_insert( newberg ) |
---|
488 | !!---------------------------------------------------------------------- |
---|
489 | !! *** ROUTINE icb_utl_insert *** |
---|
490 | !! |
---|
491 | !! ** Purpose : add a new berg to the iceberg list |
---|
492 | !! |
---|
493 | !!---------------------------------------------------------------------- |
---|
494 | TYPE(iceberg), POINTER :: newberg |
---|
495 | ! |
---|
496 | TYPE(iceberg), POINTER :: this, prev, last |
---|
497 | !!---------------------------------------------------------------------- |
---|
498 | ! |
---|
499 | IF( ASSOCIATED( first_berg ) ) THEN |
---|
500 | last => first_berg |
---|
501 | DO WHILE (ASSOCIATED(last%next)) |
---|
502 | last => last%next |
---|
503 | ENDDO |
---|
504 | newberg%prev => last |
---|
505 | last%next => newberg |
---|
506 | last => newberg |
---|
507 | ELSE ! list is empty so create it |
---|
508 | first_berg => newberg |
---|
509 | ENDIF |
---|
510 | ! |
---|
511 | END SUBROUTINE icb_utl_insert |
---|
512 | |
---|
513 | |
---|
514 | REAL(wp) FUNCTION icb_utl_yearday(kmon, kday, khr, kmin, ksec) |
---|
515 | !!---------------------------------------------------------------------- |
---|
516 | !! *** FUNCTION icb_utl_yearday *** |
---|
517 | !! |
---|
518 | !! ** Purpose : |
---|
519 | !! |
---|
520 | ! sga - improved but still only applies to 365 day year, need to do this properly |
---|
521 | ! |
---|
522 | !!gm all these info are already known in daymod, no??? |
---|
523 | !! |
---|
524 | !!---------------------------------------------------------------------- |
---|
525 | INTEGER, INTENT(in) :: kmon, kday, khr, kmin, ksec |
---|
526 | ! |
---|
527 | INTEGER, DIMENSION(12) :: imonths = (/ 0,31,28,31,30,31,30,31,31,30,31,30 /) |
---|
528 | !!---------------------------------------------------------------------- |
---|
529 | ! |
---|
530 | icb_utl_yearday = REAL( SUM( imonths(1:kmon) ), wp ) |
---|
531 | icb_utl_yearday = icb_utl_yearday + REAL(kday-1,wp) + (REAL(khr,wp) + (REAL(kmin,wp) + REAL(ksec,wp)/60.)/60.)/24. |
---|
532 | ! |
---|
533 | END FUNCTION icb_utl_yearday |
---|
534 | |
---|
535 | !!------------------------------------------------------------------------- |
---|
536 | |
---|
537 | SUBROUTINE icb_utl_delete( first, berg ) |
---|
538 | !!---------------------------------------------------------------------- |
---|
539 | !! *** ROUTINE icb_utl_delete *** |
---|
540 | !! |
---|
541 | !! ** Purpose : |
---|
542 | !! |
---|
543 | !!---------------------------------------------------------------------- |
---|
544 | TYPE(iceberg), POINTER :: first, berg |
---|
545 | !!---------------------------------------------------------------------- |
---|
546 | ! Connect neighbors to each other |
---|
547 | IF ( ASSOCIATED(berg%prev) ) THEN |
---|
548 | berg%prev%next => berg%next |
---|
549 | ELSE |
---|
550 | first => berg%next |
---|
551 | ENDIF |
---|
552 | IF (ASSOCIATED(berg%next)) berg%next%prev => berg%prev |
---|
553 | ! |
---|
554 | CALL icb_utl_destroy(berg) |
---|
555 | ! |
---|
556 | END SUBROUTINE icb_utl_delete |
---|
557 | |
---|
558 | |
---|
559 | SUBROUTINE icb_utl_destroy( berg ) |
---|
560 | !!---------------------------------------------------------------------- |
---|
561 | !! *** ROUTINE icb_utl_destroy *** |
---|
562 | !! |
---|
563 | !! ** Purpose : remove a single iceberg instance |
---|
564 | !! |
---|
565 | !!---------------------------------------------------------------------- |
---|
566 | TYPE(iceberg), POINTER :: berg |
---|
567 | !!---------------------------------------------------------------------- |
---|
568 | ! |
---|
569 | ! Remove any points |
---|
570 | IF( ASSOCIATED( berg%current_point ) ) DEALLOCATE( berg%current_point ) |
---|
571 | ! |
---|
572 | DEALLOCATE(berg) |
---|
573 | ! |
---|
574 | END SUBROUTINE icb_utl_destroy |
---|
575 | |
---|
576 | |
---|
577 | SUBROUTINE icb_utl_track( knum, cd_label, kt ) |
---|
578 | !!---------------------------------------------------------------------- |
---|
579 | !! *** ROUTINE icb_utl_track *** |
---|
580 | !! |
---|
581 | !! ** Purpose : |
---|
582 | !! |
---|
583 | !!---------------------------------------------------------------------- |
---|
584 | INTEGER, DIMENSION(nkounts) :: knum ! iceberg number |
---|
585 | CHARACTER(len=*) :: cd_label ! |
---|
586 | INTEGER :: kt ! timestep number |
---|
587 | ! |
---|
588 | TYPE(iceberg), POINTER :: this |
---|
589 | LOGICAL :: match |
---|
590 | INTEGER :: k |
---|
591 | !!---------------------------------------------------------------------- |
---|
592 | ! |
---|
593 | this => first_berg |
---|
594 | DO WHILE( ASSOCIATED(this) ) |
---|
595 | match = .TRUE. |
---|
596 | DO k = 1, nkounts |
---|
597 | IF( this%number(k) /= knum(k) ) match = .FALSE. |
---|
598 | END DO |
---|
599 | IF( match ) CALL icb_utl_print_berg(this, kt) |
---|
600 | this => this%next |
---|
601 | END DO |
---|
602 | ! |
---|
603 | END SUBROUTINE icb_utl_track |
---|
604 | |
---|
605 | |
---|
606 | SUBROUTINE icb_utl_print_berg( berg, kt ) |
---|
607 | !!---------------------------------------------------------------------- |
---|
608 | !! *** ROUTINE icb_utl_print_berg *** |
---|
609 | !! |
---|
610 | !! ** Purpose : print one |
---|
611 | !! |
---|
612 | !!---------------------------------------------------------------------- |
---|
613 | TYPE(iceberg), POINTER :: berg |
---|
614 | TYPE(point) , POINTER :: pt |
---|
615 | INTEGER :: kt ! timestep number |
---|
616 | !!---------------------------------------------------------------------- |
---|
617 | ! |
---|
618 | pt => berg%current_point |
---|
619 | WRITE(numicb, 9200) kt, berg%number(1), & |
---|
620 | pt%xi, pt%yj, pt%lon, pt%lat, pt%uvel, pt%vvel, & |
---|
621 | pt%uo, pt%vo, pt%ua, pt%va, pt%ui, pt%vi |
---|
622 | CALL flush( numicb ) |
---|
623 | 9200 FORMAT(5x,i5,2x,i10,6(2x,2f10.4)) |
---|
624 | ! |
---|
625 | END SUBROUTINE icb_utl_print_berg |
---|
626 | |
---|
627 | |
---|
628 | SUBROUTINE icb_utl_print( cd_label, kt ) |
---|
629 | !!---------------------------------------------------------------------- |
---|
630 | !! *** ROUTINE icb_utl_print *** |
---|
631 | !! |
---|
632 | !! ** Purpose : print many |
---|
633 | !! |
---|
634 | !!---------------------------------------------------------------------- |
---|
635 | CHARACTER(len=*) :: cd_label |
---|
636 | INTEGER :: kt ! timestep number |
---|
637 | ! |
---|
638 | INTEGER :: ibergs, inbergs |
---|
639 | TYPE(iceberg), POINTER :: this |
---|
640 | !!---------------------------------------------------------------------- |
---|
641 | ! |
---|
642 | this => first_berg |
---|
643 | IF( ASSOCIATED(this) ) THEN |
---|
644 | WRITE(numicb,'(a," pe=(",i3,")")' ) cd_label, narea |
---|
645 | WRITE(numicb,'(a8,4x,a6,12x,a5,15x,a7,19x,a3,17x,a5,17x,a5,17x,a5)' ) & |
---|
646 | & 'timestep', 'number', 'xi,yj','lon,lat','u,v','uo,vo','ua,va','ui,vi' |
---|
647 | ENDIF |
---|
648 | DO WHILE( ASSOCIATED(this) ) |
---|
649 | CALL icb_utl_print_berg(this, kt) |
---|
650 | this => this%next |
---|
651 | END DO |
---|
652 | ibergs = icb_utl_count() |
---|
653 | inbergs = ibergs |
---|
654 | IF( lk_mpp ) CALL mpp_sum(inbergs) |
---|
655 | IF( ibergs > 0 ) WRITE(numicb,'(a," there are",i5," bergs out of",i6," on PE ",i4)') & |
---|
656 | & cd_label, ibergs, inbergs, narea |
---|
657 | ! |
---|
658 | END SUBROUTINE icb_utl_print |
---|
659 | |
---|
660 | |
---|
661 | SUBROUTINE icb_utl_incr() |
---|
662 | !!---------------------------------------------------------------------- |
---|
663 | !! *** ROUTINE icb_utl_incr *** |
---|
664 | !! |
---|
665 | !! ** Purpose : |
---|
666 | !! |
---|
667 | ! Small routine for coping with very large integer values labelling icebergs |
---|
668 | ! num_bergs is a array of integers |
---|
669 | ! the first member is incremented in steps of jpnij starting from narea |
---|
670 | ! this means each iceberg is labelled with a unique number |
---|
671 | ! when this gets to the maximum allowed integer the second and subsequent members are |
---|
672 | ! used to count how many times the member before cycles |
---|
673 | !!---------------------------------------------------------------------- |
---|
674 | INTEGER :: ii, ibig |
---|
675 | !!---------------------------------------------------------------------- |
---|
676 | |
---|
677 | ibig = HUGE(num_bergs(1)) |
---|
678 | IF( ibig-jpnij < num_bergs(1) ) THEN |
---|
679 | num_bergs(1) = narea |
---|
680 | DO ii = 2,nkounts |
---|
681 | IF( num_bergs(ii) == ibig ) THEN |
---|
682 | num_bergs(ii) = 0 |
---|
683 | IF( ii == nkounts ) CALL ctl_stop('Sorry, run out of iceberg number space') |
---|
684 | ELSE |
---|
685 | num_bergs(ii) = num_bergs(ii) + 1 |
---|
686 | EXIT |
---|
687 | ENDIF |
---|
688 | END DO |
---|
689 | ELSE |
---|
690 | num_bergs(1) = num_bergs(1) + jpnij |
---|
691 | ENDIF |
---|
692 | ! |
---|
693 | END SUBROUTINE icb_utl_incr |
---|
694 | |
---|
695 | |
---|
696 | INTEGER FUNCTION icb_utl_count() |
---|
697 | !!---------------------------------------------------------------------- |
---|
698 | !! *** FUNCTION icb_utl_count *** |
---|
699 | !! |
---|
700 | !! ** Purpose : |
---|
701 | !!---------------------------------------------------------------------- |
---|
702 | TYPE(iceberg), POINTER :: this |
---|
703 | !!---------------------------------------------------------------------- |
---|
704 | ! |
---|
705 | icb_utl_count = 0 |
---|
706 | this => first_berg |
---|
707 | DO WHILE( ASSOCIATED(this) ) |
---|
708 | icb_utl_count = icb_utl_count+1 |
---|
709 | this => this%next |
---|
710 | END DO |
---|
711 | ! |
---|
712 | END FUNCTION icb_utl_count |
---|
713 | |
---|
714 | |
---|
715 | REAL(wp) FUNCTION icb_utl_mass( first, justbits, justbergs ) |
---|
716 | !!---------------------------------------------------------------------- |
---|
717 | !! *** FUNCTION icb_utl_mass *** |
---|
718 | !! |
---|
719 | !! ** Purpose : compute the mass all iceberg, all berg bits or all bergs. |
---|
720 | !!---------------------------------------------------------------------- |
---|
721 | TYPE(iceberg) , POINTER :: first |
---|
722 | TYPE(point) , POINTER :: pt |
---|
723 | LOGICAL, INTENT(in), OPTIONAL :: justbits, justbergs |
---|
724 | ! |
---|
725 | TYPE(iceberg), POINTER :: this |
---|
726 | !!---------------------------------------------------------------------- |
---|
727 | icb_utl_mass = 0._wp |
---|
728 | this => first |
---|
729 | ! |
---|
730 | IF( PRESENT( justbergs ) ) THEN |
---|
731 | DO WHILE( ASSOCIATED( this ) ) |
---|
732 | pt => this%current_point |
---|
733 | icb_utl_mass = icb_utl_mass + pt%mass * this%mass_scaling |
---|
734 | this => this%next |
---|
735 | END DO |
---|
736 | ELSEIF( PRESENT(justbits) ) THEN |
---|
737 | DO WHILE( ASSOCIATED( this ) ) |
---|
738 | pt => this%current_point |
---|
739 | icb_utl_mass = icb_utl_mass + pt%mass_of_bits * this%mass_scaling |
---|
740 | this => this%next |
---|
741 | END DO |
---|
742 | ELSE |
---|
743 | DO WHILE( ASSOCIATED( this ) ) |
---|
744 | pt => this%current_point |
---|
745 | icb_utl_mass = icb_utl_mass + ( pt%mass + pt%mass_of_bits ) * this%mass_scaling |
---|
746 | this => this%next |
---|
747 | END DO |
---|
748 | ENDIF |
---|
749 | ! |
---|
750 | END FUNCTION icb_utl_mass |
---|
751 | |
---|
752 | |
---|
753 | REAL(wp) FUNCTION icb_utl_heat( first, justbits, justbergs ) |
---|
754 | !!---------------------------------------------------------------------- |
---|
755 | !! *** FUNCTION icb_utl_heat *** |
---|
756 | !! |
---|
757 | !! ** Purpose : compute the heat in all iceberg, all bergies or all bergs. |
---|
758 | !!---------------------------------------------------------------------- |
---|
759 | TYPE(iceberg) , POINTER :: first |
---|
760 | LOGICAL, INTENT(in), OPTIONAL :: justbits, justbergs |
---|
761 | ! |
---|
762 | TYPE(iceberg) , POINTER :: this |
---|
763 | TYPE(point) , POINTER :: pt |
---|
764 | !!---------------------------------------------------------------------- |
---|
765 | icb_utl_heat = 0._wp |
---|
766 | this => first |
---|
767 | ! |
---|
768 | IF( PRESENT( justbergs ) ) THEN |
---|
769 | DO WHILE( ASSOCIATED( this ) ) |
---|
770 | pt => this%current_point |
---|
771 | icb_utl_heat = icb_utl_heat + pt%mass * this%mass_scaling * pt%heat_density |
---|
772 | this => this%next |
---|
773 | END DO |
---|
774 | ELSEIF( PRESENT(justbits) ) THEN |
---|
775 | DO WHILE( ASSOCIATED( this ) ) |
---|
776 | pt => this%current_point |
---|
777 | icb_utl_heat = icb_utl_heat + pt%mass_of_bits * this%mass_scaling * pt%heat_density |
---|
778 | this => this%next |
---|
779 | END DO |
---|
780 | ELSE |
---|
781 | DO WHILE( ASSOCIATED( this ) ) |
---|
782 | pt => this%current_point |
---|
783 | icb_utl_heat = icb_utl_heat + ( pt%mass + pt%mass_of_bits ) * this%mass_scaling * pt%heat_density |
---|
784 | this => this%next |
---|
785 | END DO |
---|
786 | ENDIF |
---|
787 | ! |
---|
788 | END FUNCTION icb_utl_heat |
---|
789 | |
---|
790 | !!====================================================================== |
---|
791 | END MODULE icbutl |
---|