Changeset 3953
- Timestamp:
- 2013-07-03T13:41:32+02:00 (11 years ago)
- Location:
- branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC
- Files:
-
- 10 edited
Legend:
- Unmodified
- Added
- Removed
-
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/DIA/diaharm.F90
r3294 r3953 1 1 MODULE diaharm 2 3 #if defined key_diaharm && defined key_tide 4 !!================================================================================= 2 !!====================================================================== 5 3 !! *** MODULE diaharm *** 6 4 !! Harmonic analysis of tidal constituents 7 !!================================================================================= 8 !! * Modules used 5 !!====================================================================== 6 !! History : 3.1 ! 2007 (O. Le Galloudec, J. Chanut) Original code 7 !!---------------------------------------------------------------------- 8 #if defined key_diaharm && defined key_tide 9 !!---------------------------------------------------------------------- 10 !! 'key_diaharm' 11 !! 'key_tide' 12 !!---------------------------------------------------------------------- 9 13 USE oce ! ocean dynamics and tracers variables 10 14 USE dom_oce ! ocean space and time domain 11 USE in_out_manager ! I/O units12 USE lbclnk ! ocean lateral boundary conditions (or mpp link)13 USE ioipsl ! NetCDF IPSL library14 USE diadimg ! To write dimg15 15 USE phycst 16 16 USE dynspg_oce … … 18 18 USE daymod 19 19 USE tide_mod 20 USE iom 20 USE in_out_manager ! I/O units 21 USE iom ! I/0 library 22 USE ioipsl ! NetCDF IPSL library 23 USE lbclnk ! ocean lateral boundary conditions (or mpp link) 24 USE diadimg ! To write dimg 21 25 USE timing ! preformance summary 22 26 USE wrk_nemo ! working arrays … … 30 34 INTEGER, PARAMETER :: jpdimsparse = jpincomax*300*24 31 35 32 INTEGER :: & !! namelist variables 33 nit000_han = 1, & ! First time step used for harmonic analysis 34 nitend_han = 1, & ! Last time step used for harmonic analysis 35 nstep_han = 1, & ! Time step frequency for harmonic analysis 36 nb_ana ! Number of harmonics to analyse 37 38 INTEGER , ALLOCATABLE, DIMENSION(:) :: name 39 REAL(wp), ALLOCATABLE, DIMENSION(:,:,:,:) :: ana_temp 40 REAL(wp), ALLOCATABLE, DIMENSION(:) :: ana_freq, vt, ut, ft 41 REAL(wp), ALLOCATABLE, DIMENSION(:,:,:) :: out_eta, & 42 out_u , & 43 out_v 44 45 INTEGER :: ninco, nsparse 46 INTEGER , DIMENSION(jpdimsparse) :: njsparse, nisparse 47 INTEGER , SAVE, DIMENSION(jpincomax) :: ipos1 48 REAL(wp), DIMENSION(jpdimsparse) :: valuesparse 49 REAL(wp), DIMENSION(jpincomax) :: ztmp4 , ztmp7 50 REAL(wp), SAVE, DIMENSION(jpincomax,jpincomax) :: ztmp3 , zpilier 51 REAL(wp), SAVE, DIMENSION(jpincomax) :: zpivot 52 53 CHARACTER (LEN=4), DIMENSION(jpmax_harmo) :: & 54 tname ! Names of tidal constituents ('M2', 'K1',...) 55 56 57 !! * Routine accessibility 58 PUBLIC dia_harm ! routine called by step.F90 59 60 !!--------------------------------------------------------------------------------- 61 !! 62 !!--------------------------------------------------------------------------------- 63 36 ! !!!namelist variables 37 INTEGER :: nit000_han = 1 ! First time step used for harmonic analysis 38 INTEGER :: nitend_han = 1 ! Last time step used for harmonic analysis 39 INTEGER :: nstep_han = 1 ! Time step frequency for harmonic analysis 40 INTEGER :: nb_ana ! Number of harmonics to analyse 41 42 INTEGER , ALLOCATABLE, DIMENSION(:) :: name 43 REAL(wp), ALLOCATABLE, DIMENSION(:,:,:,:) :: ana_temp 44 REAL(wp), ALLOCATABLE, DIMENSION(:) :: ana_freq, ut , vt , ft 45 REAL(wp), ALLOCATABLE, DIMENSION(:,:,:) :: out_eta , out_u, out_v 46 47 INTEGER :: ninco, nsparse 48 INTEGER , DIMENSION(jpdimsparse) :: njsparse, nisparse 49 INTEGER , SAVE, DIMENSION(jpincomax) :: ipos1 50 REAL(wp), DIMENSION(jpdimsparse) :: valuesparse 51 REAL(wp), DIMENSION(jpincomax) :: ztmp4 , ztmp7 52 REAL(wp), SAVE, DIMENSION(jpincomax,jpincomax) :: ztmp3 , zpilier 53 REAL(wp), SAVE, DIMENSION(jpincomax) :: zpivot 54 55 CHARACTER (LEN=4), DIMENSION(jpmax_harmo) :: tname ! Names of tidal constituents ('M2', 'K1',...) 56 57 PUBLIC dia_harm ! routine called by step.F90 58 59 !!---------------------------------------------------------------------- 60 !! NEMO/OPA 3.5 , NEMO Consortium (2013) 61 !! $Id:$ 62 !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) 63 !!---------------------------------------------------------------------- 64 64 CONTAINS 65 65 … … 67 67 !!---------------------------------------------------------------------- 68 68 !! *** ROUTINE dia_harm_init *** 69 !!----------------------------------------------------------------------70 69 !! 71 70 !! ** Purpose : Initialization of tidal harmonic analysis … … 73 72 !! ** Method : Initialize frequency array and nodal factor for nit000_han 74 73 !! 75 !! History : 76 !! 9.0 O. Le Galloudec and J. Chanut (Original) 77 !!-------------------------------------------------------------------- 78 !! * Local declarations 74 !!-------------------------------------------------------------------- 79 75 INTEGER :: jh, nhan, jk, ji 80 76 ! 81 77 NAMELIST/nam_diaharm/ nit000_han, nitend_han, nstep_han, tname 82 78 !!---------------------------------------------------------------------- … … 92 88 tname(:)='' 93 89 ! 94 ! Read Namelist nam_diaharm 95 REWIND ( numnam ) 96 READ ( numnam, nam_diaharm ) 90 REWIND( numnam ) ! Read Namelist nam_diaharm 91 READ ( numnam, nam_diaharm ) 97 92 ! 98 93 IF(lwp) THEN … … 104 99 ! Basic checks on harmonic analysis time window: 105 100 ! ---------------------------------------------- 106 IF (nit000 > nit000_han) THEN 107 IF(lwp) WRITE(numout,*) ' E R R O R dia_harm_init : nit000_han must be greater than nit000, stop' 108 IF(lwp) WRITE(numout,*) ' restart capability not implemented' 109 nstop = nstop + 1 110 ENDIF 111 IF (nitend < nitend_han) THEN 112 IF(lwp) WRITE(numout,*) ' E R R O R dia_harm_init : nitend_han must be lower than nitend, stop' 113 IF(lwp) WRITE(numout,*) ' restart capability not implemented' 114 nstop = nstop + 1 115 ENDIF 116 117 IF (MOD(nitend_han-nit000_han+1,nstep_han).NE.0) THEN 118 IF(lwp) WRITE(numout,*) ' E R R O R dia_harm_init : analysis time span must be a multiple of nstep_han, stop' 119 nstop = nstop + 1 120 END IF 121 122 nb_ana=0 101 IF( nit000 > nit000_han ) CALL ctl_stop( 'dia_harm_init : nit000_han must be greater than nit000', & 102 & ' restart capability not implemented' ) 103 IF( nitend < nitend_han ) CALL ctl_stop( 'dia_harm_init : nitend_han must be lower than nitend', & 104 & 'restart capability not implemented' ) 105 106 IF( MOD( nitend_han-nit000_han+1 , nstep_han ) /= 0 ) & 107 & CALL ctl_stop( 'dia_harm_init : analysis time span must be a multiple of nstep_han' ) 108 109 nb_ana = 0 123 110 DO jk=1,jpmax_harmo 124 111 DO ji=1,jpmax_harmo … … 153 140 ! Initialize frequency array: 154 141 ! --------------------------- 155 ALLOCATE(ana_freq(nb_ana)) 156 ALLOCATE(vt (nb_ana)) 157 ALLOCATE(ut (nb_ana)) 158 ALLOCATE(ft (nb_ana)) 159 160 CALL tide_harmo(ana_freq, vt, ut , ft, name ,nb_ana) 142 ALLOCATE( ana_freq(nb_ana), ut(nb_ana), vt(nb_ana), ft(nb_ana) ) 143 144 CALL tide_harmo( ana_freq, vt, ut, ft, name, nb_ana ) 161 145 162 146 IF(lwp) WRITE(numout,*) 'Analysed frequency : ',nb_ana ,'Frequency ' … … 168 152 ! Initialize temporary arrays: 169 153 ! ---------------------------- 170 ALLOCATE( ana_temp(jpi,jpj, nb_ana*2,3))154 ALLOCATE( ana_temp(jpi,jpj,2*nb_ana,3) ) 171 155 ana_temp(:,:,:,:) = 0.e0 172 156 173 157 END SUBROUTINE dia_harm_init 174 158 159 175 160 SUBROUTINE dia_harm ( kt ) 176 161 !!---------------------------------------------------------------------- 177 162 !! *** ROUTINE dia_harm *** 178 !!----------------------------------------------------------------------179 163 !! 180 164 !! ** Purpose : Tidal harmonic analysis main routine … … 182 166 !! ** Action : Sums ssh/u/v over time analysis [nit000_han,nitend_han] 183 167 !! 184 !! History : 185 !! 9.0 O. Le Galloudec and J. Chanut (Original) 186 !!-------------------------------------------------------------------- 187 !! * Argument: 168 !!-------------------------------------------------------------------- 188 169 INTEGER, INTENT( IN ) :: kt 189 190 !! * Local declarations 170 ! 191 171 INTEGER :: ji, jj, jh, jc, nhc 192 172 REAL(wp) :: ztime, ztemp … … 194 174 IF( nn_timing == 1 ) CALL timing_start('dia_harm') 195 175 196 IF ( kt .EQ.nit000 ) CALL dia_harm_init176 IF ( kt == nit000 ) CALL dia_harm_init 197 177 198 178 IF ( ((kt.GE.nit000_han).AND.(kt.LE.nitend_han)).AND. & … … 211 191 DO ji = 1,jpi 212 192 ! Elevation 213 ana_temp(ji,jj,nhc,1) = ana_temp(ji,jj,nhc,1) & 214 + ztemp*sshn(ji,jj)*tmask(ji,jj,1) 193 ana_temp(ji,jj,nhc,1) = ana_temp(ji,jj,nhc,1) + ztemp*sshn(ji,jj) *tmask(ji,jj,1) 215 194 #if defined key_dynspg_ts 216 ! ubar 217 ana_temp(ji,jj,nhc,2) = ana_temp(ji,jj,nhc,2) & 218 + ztemp*un_b(ji,jj)*hur(ji,jj)*umask(ji,jj,1) 219 ! vbar 220 ana_temp(ji,jj,nhc,3) = ana_temp(ji,jj,nhc,3) & 221 + ztemp*vn_b(ji,jj)*hvr(ji,jj)*vmask(ji,jj,1) 195 ana_temp(ji,jj,nhc,2) = ana_temp(ji,jj,nhc,2) + ztemp*un_b(ji,jj)*hur(ji,jj)*umask(ji,jj,1) 196 ana_temp(ji,jj,nhc,3) = ana_temp(ji,jj,nhc,3) + ztemp*vn_b(ji,jj)*hvr(ji,jj)*vmask(ji,jj,1) 222 197 #endif 223 198 END DO … … 229 204 END IF 230 205 231 IF ( kt .EQ. nitend_han )CALL dia_harm_end206 IF ( kt == nitend_han ) CALL dia_harm_end 232 207 233 208 IF( nn_timing == 1 ) CALL timing_stop('dia_harm') … … 235 210 END SUBROUTINE dia_harm 236 211 212 237 213 SUBROUTINE dia_harm_end 238 214 !!---------------------------------------------------------------------- 239 215 !! *** ROUTINE diaharm_end *** 240 !!----------------------------------------------------------------------241 216 !! 242 217 !! ** Purpose : Compute the Real and Imaginary part of tidal constituents … … 244 219 !! ** Action : Decompose the signal on the harmonic constituents 245 220 !! 246 !! History : 247 !! 9.0 O. Le Galloudec and J. Chanut (Original) 248 !!-------------------------------------------------------------------- 249 250 !! * Local declarations 221 !!-------------------------------------------------------------------- 251 222 INTEGER :: ji, jj, jh, jc, jn, nhan, jl 252 223 INTEGER :: ksp, kun, keq … … 279 250 nisparse(ksp) = keq 280 251 njsparse(ksp) = kun 281 valuesparse(ksp)= & 282 +( MOD(jc,2) * ft(jh) * COS(ana_freq(jh)*ztime + vt(jh) + ut(jh)) & 283 +(1.-MOD(jc,2))* ft(jh) * SIN(ana_freq(jh)*ztime + vt(jh) + ut(jh))) 252 valuesparse(ksp) = ( MOD(jc,2) * ft(jh) * COS(ana_freq(jh)*ztime + vt(jh) + ut(jh)) & 253 & + (1.-MOD(jc,2))* ft(jh) * SIN(ana_freq(jh)*ztime + vt(jh) + ut(jh)) ) 284 254 END DO 285 255 END DO 286 256 END DO 287 257 288 nsparse =ksp258 nsparse = ksp 289 259 290 260 ! Elevation: … … 292 262 DO ji = 1, jpi 293 263 ! Fill input array 294 kun =0295 DO jh = 1, nb_ana296 DO jc = 1, 2264 kun = 0 265 DO jh = 1, nb_ana 266 DO jc = 1, 2 297 267 kun = kun + 1 298 268 ztmp4(kun)=ana_temp(ji,jj,kun,1) 299 END DO300 END DO269 END DO 270 END DO 301 271 302 272 CALL SUR_DETERMINE(jj) … … 310 280 END DO 311 281 312 ALLOCATE( out_eta(jpi,jpj,2*nb_ana))313 ALLOCATE(out_u (jpi,jpj,2*nb_ana))314 ALLOCATE(out_v (jpi,jpj,2*nb_ana))282 ALLOCATE( out_eta(jpi,jpj,2*nb_ana), & 283 & out_u (jpi,jpj,2*nb_ana), & 284 & out_v (jpi,jpj,2*nb_ana) ) 315 285 316 286 DO jj = 1, jpj 317 287 DO ji = 1, jpi 318 288 DO jh = 1, nb_ana 319 X1 =ana_amp(ji,jj,jh,1)320 X2 =-ana_amp(ji,jj,jh,2)321 out_eta(ji,jj,jh )=X1 * tmask(ji,jj,1)322 out_eta(ji,jj, nb_ana+jh)=X2 * tmask(ji,jj,1)289 X1 = ana_amp(ji,jj,jh,1) 290 X2 =-ana_amp(ji,jj,jh,2) 291 out_eta(ji,jj,jh ) = X1 * tmask(ji,jj,1) 292 out_eta(ji,jj,jh+nb_ana) = X2 * tmask(ji,jj,1) 323 293 ENDDO 324 294 ENDDO … … 398 368 END SUBROUTINE dia_harm_end 399 369 370 400 371 SUBROUTINE dia_wri_harm 401 372 !!-------------------------------------------------------------------- 402 373 !! *** ROUTINE dia_wri_harm *** 403 !!--------------------------------------------------------------------404 374 !! 405 375 !! ** Purpose : Write tidal harmonic analysis results in a netcdf file 406 !! 407 !! 408 !! History : 409 !! 9.0 O. Le Galloudec and J. Chanut (Original) 410 !!-------------------------------------------------------------------- 411 412 !! * Local declarations 376 !!-------------------------------------------------------------------- 413 377 CHARACTER(LEN=lc) :: cltext 414 378 CHARACTER(LEN=lc) :: & … … 468 432 #else 469 433 DO jh = 1, nb_ana 470 CALL iom_put( TRIM(tname(jh))//'x_v', out_u(:,:,jh) )471 CALL iom_put( TRIM(tname(jh))//'y_v', out_u(:,:,nb_ana+jh) )434 CALL iom_put( TRIM(tname(jh))//'x_v', out_u(:,:,jh ) ) 435 CALL iom_put( TRIM(tname(jh))//'y_v', out_u(:,:,jh+nb_ana) ) 472 436 END DO 473 437 #endif 474 438 475 439 END SUBROUTINE dia_wri_harm 440 476 441 477 442 SUBROUTINE SUR_DETERMINE(init) … … 482 447 !! 483 448 !!--------------------------------------------------------------------------------- 484 INTEGER, INTENT(in) :: init485 449 INTEGER, INTENT(in) :: init 450 ! 486 451 INTEGER :: ji_sd, jj_sd, ji1_sd, ji2_sd, jk1_sd, jk2_sd 487 452 REAL(wp) :: zval1, zval2, zx1 … … 492 457 CALL wrk_alloc( jpincomax , ipos2 , ipivot ) 493 458 494 IF( init==1 )THEN 495 496 IF( nsparse .GT. jpdimsparse ) & 497 CALL ctl_stop( 'STOP', 'SUR_DETERMINE : nsparse .GT. jpdimsparse') 498 499 IF( ninco .GT. jpincomax ) & 500 CALL ctl_stop( 'STOP', 'SUR_DETERMINE : ninco .GT. jpincomax') 501 502 ztmp3(:,:)=0.e0 503 459 IF( init == 1 ) THEN 460 IF( nsparse > jpdimsparse ) CALL ctl_stop( 'STOP', 'SUR_DETERMINE : nsparse .GT. jpdimsparse') 461 IF( ninco > jpincomax ) CALL ctl_stop( 'STOP', 'SUR_DETERMINE : ninco .GT. jpincomax') 462 ! 463 ztmp3(:,:) = 0._wp 464 ! 504 465 DO jk1_sd = 1, nsparse 505 466 DO jk2_sd = 1, nsparse 506 507 nisparse(jk2_sd)=nisparse(jk2_sd) 508 njsparse(jk2_sd)=njsparse(jk2_sd) 509 467 nisparse(jk2_sd) = nisparse(jk2_sd) 468 njsparse(jk2_sd) = njsparse(jk2_sd) 510 469 IF( nisparse(jk2_sd) == nisparse(jk1_sd) ) THEN 511 470 ztmp3(njsparse(jk1_sd),njsparse(jk2_sd)) = ztmp3(njsparse(jk1_sd),njsparse(jk2_sd)) & 512 471 + valuesparse(jk1_sd)*valuesparse(jk2_sd) 513 472 ENDIF 514 515 ENDDO 516 ENDDO 473 END DO 474 END DO 517 475 518 476 DO jj_sd = 1 ,ninco … … 584 542 ENDDO 585 543 586 587 544 CALL wrk_dealloc( jpincomax , ztmpx , zcol1 , zcol2 ) 588 545 CALL wrk_dealloc( jpincomax , ipos2 , ipivot ) … … 590 547 END SUBROUTINE SUR_DETERMINE 591 548 592 593 549 #else 594 550 !!---------------------------------------------------------------------- … … 597 553 LOGICAL, PUBLIC, PARAMETER :: lk_diaharm = .FALSE. 598 554 CONTAINS 599 600 555 SUBROUTINE dia_harm ( kt ) ! Empty routine 601 556 INTEGER, INTENT( IN ) :: kt 602 557 WRITE(*,*) 'dia_harm: you should not have seen this print' 603 558 END SUBROUTINE dia_harm 604 605 606 #endif 559 #endif 560 607 561 !!====================================================================== 608 562 END MODULE diaharm -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/DYN/dynspg.F90
r3625 r3953 22 22 USE dynspg_flt ! surface pressure gradient (dyn_spg_flt routine) 23 23 USE dynadv ! dynamics: vector invariant versus flux form 24 USE sbctide 25 USE updtide 24 26 USE trdmod ! ocean dynamics trends 25 27 USE trdmod_oce ! ocean variables trends … … 100 102 ENDIF 101 103 102 IF( ln_apr_dyn ) THEN !== Atmospheric pressure gradient ==! 103 zg_2 = grav * 0.5 104 DO jj = 2, jpjm1 ! gradient of Patm using inverse barometer ssh 104 IF( ln_apr_dyn & ! atmos. pressure 105 .OR. ( .NOT.lk_dynspg_ts .AND. (ln_tide_pot .AND. lk_tide) ) & ! tide potential (no time slitting) 106 .OR. nn_ice_embd == 2 ) THEN ! embedded sea-ice 107 ! 108 DO jj = 2, jpjm1 105 109 DO ji = fs_2, fs_jpim1 ! vector opt. 106 spgu(ji,jj) = zg_2 * ( ssh_ib (ji+1,jj) - ssh_ib (ji,jj) & 107 & + ssh_ibb(ji+1,jj) - ssh_ibb(ji,jj) ) /e1u(ji,jj) 108 spgv(ji,jj) = zg_2 * ( ssh_ib (ji,jj+1) - ssh_ib (ji,jj) & 109 & + ssh_ibb(ji,jj+1) - ssh_ibb(ji,jj) ) /e2v(ji,jj) 110 END DO 111 END DO 112 DO jk = 1, jpkm1 ! Add the apg to the general trend 110 spgu(ji,jj) = 0._wp 111 spgv(ji,jj) = 0._wp 112 END DO 113 END DO 114 ! 115 IF( ln_apr_dyn ) THEN !== Atmospheric pressure gradient ==! 116 zg_2 = grav * 0.5 117 DO jj = 2, jpjm1 ! gradient of Patm using inverse barometer ssh 118 DO ji = fs_2, fs_jpim1 ! vector opt. 119 spgu(ji,jj) = spgu(ji,jj) + zg_2 * ( ssh_ib (ji+1,jj) - ssh_ib (ji,jj) & 120 & + ssh_ibb(ji+1,jj) - ssh_ibb(ji,jj) ) /e1u(ji,jj) 121 spgv(ji,jj) = spgv(ji,jj) + zg_2 * ( ssh_ib (ji,jj+1) - ssh_ib (ji,jj) & 122 & + ssh_ibb(ji,jj+1) - ssh_ibb(ji,jj) ) /e2v(ji,jj) 123 END DO 124 END DO 125 ENDIF 126 ! 127 ! !== tide potential forcing term ==! 128 IF( .NOT.lk_dynspg_ts .AND. ( ln_tide_pot .AND. lk_tide ) ) THEN ! N.B. added directly at sub-time-step in ts-case 129 ! 130 CALL upd_tide( kt ) ! update tide potential 131 ! 132 DO jj = 2, jpjm1 ! add tide potential forcing 133 DO ji = fs_2, fs_jpim1 ! vector opt. 134 spgv(ji,jj) = spgu(ji,jj) + grav * ( pot_astro(ji+1,jj) - pot_astro(ji,jj) ) / e1u(ji,jj) 135 spgv(ji,jj) = spgv(ji,jj) + grav * ( pot_astro(ji,jj+1) - pot_astro(ji,jj) ) / e2v(ji,jj) 136 END DO 137 END DO 138 ENDIF 139 ! 140 IF( nn_ice_embd == 2 ) THEN !== embedded sea ice: Pressure gradient due to snow-ice mass ==! 141 CALL wrk_alloc( jpi, jpj, zpice ) 142 ! 143 zintp = REAL( MOD( kt-1, nn_fsbc ) ) / REAL( nn_fsbc ) 144 zgrau0r = - grav * r1_rau0 145 zpice(:,:) = ( zintp * snwice_mass(:,:) + ( 1.- zintp ) * snwice_mass_b(:,:) ) * zgrau0r 146 DO jj = 2, jpjm1 147 DO ji = fs_2, fs_jpim1 ! vector opt. 148 spgu(ji,jj) = spgu(ji,jj) + ( zpice(ji+1,jj) - zpice(ji,jj) ) / e1u(ji,jj) 149 spgv(ji,jj) = spgu(ji,jj) + ( zpice(ji,jj+1) - zpice(ji,jj) ) / e2v(ji,jj) 150 END DO 151 END DO 152 ! 153 CALL wrk_dealloc( jpi, jpj, zpice ) 154 ENDIF 155 ! 156 DO jk = 1, jpkm1 !== Add all terms to the general trend 113 157 DO jj = 2, jpjm1 114 158 DO ji = fs_2, fs_jpim1 ! vector opt. … … 117 161 END DO 118 162 END DO 119 END DO 120 ENDIF 121 122 IF( nn_ice_embd == 2 ) THEN !== embedded sea ice: Pressure gradient due to snow-ice mass ==! 123 CALL wrk_alloc( jpi, jpj, zpice ) 124 ! 125 zintp = REAL( MOD( kt-1, nn_fsbc ) ) / REAL( nn_fsbc ) 126 zgrau0r = - grav * r1_rau0 127 zpice(:,:) = ( zintp * snwice_mass(:,:) + ( 1.- zintp ) * snwice_mass_b(:,:) ) * zgrau0r 128 DO jj = 2, jpjm1 129 DO ji = fs_2, fs_jpim1 ! vector opt. 130 spgu(ji,jj) = ( zpice(ji+1,jj) - zpice(ji,jj) ) / e1u(ji,jj) 131 spgv(ji,jj) = ( zpice(ji,jj+1) - zpice(ji,jj) ) / e2v(ji,jj) 132 END DO 133 END DO 134 DO jk = 1, jpkm1 ! Add the surface pressure trend to the general trend 135 DO jj = 2, jpjm1 136 DO ji = fs_2, fs_jpim1 ! vector opt. 137 ua(ji,jj,jk) = ua(ji,jj,jk) + spgu(ji,jj) 138 va(ji,jj,jk) = va(ji,jj,jk) + spgv(ji,jj) 139 END DO 140 END DO 141 END DO 142 ! 143 CALL wrk_dealloc( jpi, jpj, zpice ) 144 ENDIF 145 163 END DO 164 ENDIF 146 165 147 166 SELECT CASE ( nspg ) ! compute surf. pressure gradient trend and add it to the general trend -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/DYN/dynspg_exp.F90
r3680 r3953 91 91 spgv(ji,jj) = - grav * ( sshn(ji,jj+1) - sshn(ji,jj) ) / e2v(ji,jj) 92 92 END DO 93 END DO 93 END DO 94 ! 94 95 DO jk = 1, jpkm1 ! Add it to the general trend 95 96 DO jj = 2, jpjm1 -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/DYN/dynspg_ts.F90
r3951 r3953 396 396 ! !* Update the forcing (BDY and tides) 397 397 ! ! ------------------ 398 IF( lk_obc ) CALL obc_dta_bt( kt, jn )399 IF( lk_bdy ) CALL bdy_dta ( kt, jit=jn, time_offset=+1 )400 IF ( ln_tide_pot .AND. lk_tide) CALL upd_tide( kt, jn)398 IF( lk_obc ) CALL obc_dta_bt( kt, jn ) 399 IF( lk_bdy ) CALL bdy_dta ( kt, jit=jn, time_offset=1 ) 400 IF( ln_tide_pot .AND. lk_tide ) CALL upd_tide ( kt, kit=jn, kbaro=nn_baro ) 401 401 402 402 ! !* after ssh_e -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/SBC/sbctide.F90
r3651 r3953 1 1 MODULE sbctide 2 !!================================================================================= 3 !! *** MODULE sbctide *** 4 !! Initialization of tidal forcing 5 !! History : 9.0 ! 07 (O. Le Galloudec) Original code 6 !!================================================================================= 7 !! * Modules used 8 USE oce ! ocean dynamics and tracers variables 9 USE dom_oce ! ocean space and time domain 10 USE in_out_manager ! I/O units 11 USE ioipsl ! NetCDF IPSL library 12 USE lbclnk ! ocean lateral boundary conditions (or mpp link) 13 USE phycst 14 USE daymod 15 USE dynspg_oce 16 USE tideini 17 USE iom 2 !!====================================================================== 3 !! *** MODULE sbctide *** 4 !! Initialization of tidal forcing 5 !!====================================================================== 6 !! History : 9.0 ! 2007 (O. Le Galloudec) Original code 7 !!---------------------------------------------------------------------- 8 USE oce ! ocean dynamics and tracers variables 9 USE dom_oce ! ocean space and time domain 10 USE phycst 11 USE daymod 12 USE dynspg_oce 13 USE tideini 14 ! 15 USE iom 16 USE in_out_manager ! I/O units 17 USE ioipsl ! NetCDF IPSL library 18 USE lbclnk ! ocean lateral boundary conditions (or mpp link) 18 19 19 IMPLICIT NONE20 PUBLIC20 IMPLICIT NONE 21 PUBLIC 21 22 22 REAL(wp), PUBLIC, ALLOCATABLE, DIMENSION(:,:) :: pot_astro23 REAL(wp), PUBLIC, ALLOCATABLE, DIMENSION(:,:) :: pot_astro ! 23 24 24 25 #if defined key_tide 26 !!---------------------------------------------------------------------- 27 !! 'key_tide' : tidal potential 28 !!---------------------------------------------------------------------- 29 !! sbc_tide : 30 !! tide_init_potential : 31 !!---------------------------------------------------------------------- 25 32 26 LOGICAL, PUBLIC, PARAMETER :: lk_tide = .TRUE. 27 REAL(wp), ALLOCATABLE, DIMENSION(:,:,:) :: amp_pot,phi_pot 28 !!--------------------------------------------------------------------------------- 29 !! OPA 9.0 , LODYC-IPSL (2003) 30 !!--------------------------------------------------------------------------------- 33 LOGICAL, PUBLIC, PARAMETER :: lk_tide = .TRUE. 34 REAL(wp), ALLOCATABLE, DIMENSION(:,:,:) :: amp_pot, phi_pot 31 35 36 !!---------------------------------------------------------------------- 37 !! NEMO/OPA 3.5 , NEMO Consortium (2013) 38 !! $Id: $ 39 !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) 40 !!---------------------------------------------------------------------- 32 41 CONTAINS 33 42 34 SUBROUTINE sbc_tide ( kt ) 35 !!---------------------------------------------------------------------- 36 !! *** ROUTINE sbc_tide *** 37 !!---------------------------------------------------------------------- 38 !! * Arguments 39 INTEGER, INTENT( in ) :: kt ! ocean time-step 40 !!---------------------------------------------------------------------- 43 SUBROUTINE sbc_tide( kt ) 44 !!---------------------------------------------------------------------- 45 !! *** ROUTINE sbc_tide *** 46 !!---------------------------------------------------------------------- 47 INTEGER, INTENT( in ) :: kt ! ocean time-step 48 !!---------------------------------------------------------------------- 41 49 42 IF ( kt == nit000 .AND. .NOT. lk_dynspg_ts ) CALL ctl_stop( 'STOP', 'sbc_tide : tidal potential use only with time splitting')50 IF( kt /= nit000 ) CALL tide_init( kt ) 43 51 44 IF ( nsec_day == NINT(0.5 * rdttra(1)) ) THEN 52 IF( nsec_day == NINT(0.5 * rdttra(1)) ) THEN ! start a new day 53 ! 54 IF( kt == nit000 ) THEN 55 ALLOCATE( amp_pot(jpi,jpj,nb_harmo), & 56 & phi_pot(jpi,jpj,nb_harmo), pot_astro(jpi,jpj) ) 57 ! 58 amp_pot(:,:,:) = 0._wp 59 phi_pot(:,:,:) = 0._wp 60 pot_astro(:,:) = 0._wp 61 ENDIF 62 ! 63 CALL tide_harmo( omega_tide, v0tide, utide, ftide, ntide, nb_harmo ) 64 ! 65 kt_tide = kt 66 ! 67 IF(lwp) THEN 68 WRITE(numout,*) 69 WRITE(numout,*) 'sbc_tide : Update of the components and (re)Init. the potential at kt=', kt 70 WRITE(numout,*) '~~~~~~~~ ' 71 DO jk = 1, nb_harmo 72 WRITE(numout,*) Wave(ntide(jk))%cname_tide, utide(jk), ftide(jk), v0tide(jk), omega_tide(jk) 73 END DO 74 ENDIF 75 ! 76 IF( ln_tide_pot ) CALL tide_init_potential 77 ! 78 ENDIF 45 79 ! 46 kt_tide = kt 47 48 IF(lwp) THEN 49 WRITE(numout,*) 50 WRITE(numout,*) 'sbc_tide : (re)Initialization of the tidal potential at kt=',kt 51 WRITE(numout,*) '~~~~~~~ ' 52 ENDIF 53 54 IF(lwp) THEN 55 IF ( kt == nit000 ) WRITE(numout,*) 'Apply astronomical potential : ln_tide_pot =', ln_tide_pot 56 CALL flush(numout) 57 ENDIF 58 59 IF ( kt == nit000 ) ALLOCATE(amp_pot(jpi,jpj,nb_harmo)) 60 IF ( kt == nit000 ) ALLOCATE(phi_pot(jpi,jpj,nb_harmo)) 61 IF ( kt == nit000 ) ALLOCATE(pot_astro(jpi,jpj)) 62 63 amp_pot(:,:,:) = 0.e0 64 phi_pot(:,:,:) = 0.e0 65 pot_astro(:,:) = 0.e0 66 67 IF ( ln_tide_pot ) CALL tide_init_potential 68 ! 69 ENDIF 70 71 END SUBROUTINE sbc_tide 72 73 SUBROUTINE tide_init_potential 74 !!---------------------------------------------------------------------- 75 !! *** ROUTINE tide_init_potential *** 76 !!---------------------------------------------------------------------- 77 !! * Local declarations 78 INTEGER :: ji,jj,jk 79 REAL(wp) :: zcons,ztmp1,ztmp2,zlat,zlon 80 END SUBROUTINE sbc_tide 80 81 81 82 82 DO jk=1,nb_harmo 83 zcons=0.7*Wave(ntide(jk))%equitide*ftide(jk) 84 do ji=1,jpi 85 do jj=1,jpj 86 ztmp1 = amp_pot(ji,jj,jk)*COS(phi_pot(ji,jj,jk)) 87 ztmp2 = -amp_pot(ji,jj,jk)*SIN(phi_pot(ji,jj,jk)) 88 zlat = gphit(ji,jj)*rad !! latitude en radian 89 zlon = glamt(ji,jj)*rad !! longitude en radian 90 ! le potentiel est composé des effets des astres: 91 IF (Wave(ntide(jk))%nutide .EQ.1) THEN 92 ztmp1= ztmp1 + zcons*(SIN(2.*zlat))*COS(v0tide(jk)+utide(jk)+Wave(ntide(jk))%nutide*zlon) 93 ztmp2= ztmp2 - zcons*(SIN(2.*zlat))*SIN(v0tide(jk)+utide(jk)+Wave(ntide(jk))%nutide*zlon) 94 ENDIF 95 IF (Wave(ntide(jk))%nutide.EQ.2) THEN 96 ztmp1= ztmp1 + zcons*(COS(zlat)**2)*COS(v0tide(jk)+utide(jk)+Wave(ntide(jk))%nutide*zlon) 97 ztmp2= ztmp2 - zcons*(COS(zlat)**2)*SIN(v0tide(jk)+utide(jk)+Wave(ntide(jk))%nutide*zlon) 98 ENDIF 99 amp_pot(ji,jj,jk)=SQRT(ztmp1**2+ztmp2**2) 100 phi_pot(ji,jj,jk)=ATAN2(-ztmp2/MAX(1.E-10,SQRT(ztmp1**2+ztmp2**2)),ztmp1/MAX(1.E-10,SQRT(ztmp1**2+ztmp2**2))) 101 enddo 102 enddo 103 END DO 83 SUBROUTINE tide_init_potential 84 !!---------------------------------------------------------------------- 85 !! *** ROUTINE tide_init_potential *** 86 !!---------------------------------------------------------------------- 87 INTEGER :: ji, jj, jk ! dummy loop indices 88 REAL(wp) :: zcons, ztmp1, ztmp2, zlat, zlon, ztmp, zamp, zsc ! local scalar 89 !!---------------------------------------------------------------------- 104 90 105 END SUBROUTINE tide_init_potential 91 DO jk = 1, nb_harmo 92 zcons = 0.7 * Wave(ntide(jk))%equitide * ftide(jk) 93 DO ji = 1, jpi 94 DO jj = 1, jpj 95 ztmp1 = amp_pot(ji,jj,jk) * COS( phi_pot(ji,jj,jk) ) 96 ztmp2 = -amp_pot(ji,jj,jk) * SIN( phi_pot(ji,jj,jk) ) 97 zlat = gphit(ji,jj)*rad !! latitude en radian 98 zlon = glamt(ji,jj)*rad !! longitude en radian 99 ztmp = v0tide(jk) + utide(jk) + Wave(ntide(jk))%nutide * zlon 100 ! le potentiel est composé des effets des astres: 101 IF( Wave(ntide(jk))%nutide == 1 ) zcs = zcons * SIN( 2.*zlat ) 102 IF( Wave(ntide(jk))%nutide == 2 ) zcs = zcons * COS( zlat )**2 103 ztmp1 = ztmp1 + zcs * COS( ztmp ) 104 ztmp2 = ztmp2 - zcs * SIN( ztmp ) 105 zamp = SQRT( ztmp1*ztmp1 + ztmp2*ztmp2 ) 106 amp_pot(ji,jj,jk) = zamp 107 phi_pot(ji,jj,jk) = ATAN2( -ztmp2 / MAX( 1.e-10 , zamp ) , & 108 & ztmp1 / MAX( 1.e-10, zamp ) ) 109 END DO 110 END DO 111 END DO 112 ! 113 END SUBROUTINE tide_init_potential 106 114 107 115 #else … … 116 124 END SUBROUTINE sbc_tide 117 125 #endif 126 118 127 !!====================================================================== 119 120 128 END MODULE sbctide -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/SBC/tide.h90
r3294 r3953 1 !! History : 9.0 ! 07 (O. Le Galloudec) Original code 1 !!---------------------------------------------------------------------- 2 !! History : 3.2 ! 2007 (O. Le Galloudec) Original code 3 !!---------------------------------------------------------------------- 2 4 3 ! Wave(1)= tide(name_tide,equitide,nutide,nt,ns,nh,np,np1,shift,nksi,nnu0,nnu1,nnu2,R,formula) 4 5 6 Wave(1)= tide('M2' ,0.242297,2 ,2 ,-2,2 ,0 ,0 ,0 ,2 ,-2 ,0 ,0 ,0,78) 7 Wave(2)= tide('N2' ,0.046313,2 ,2 ,-3,2 ,1 ,0 ,0 ,2 ,-2 ,0 ,0 ,0,78) 8 Wave(3)= tide('2N2' ,0.006184,2 ,2 ,-4,2 ,2 ,0 ,0 ,2 ,-2 ,0 ,0 ,0,78) 9 Wave(4)= tide('S2' ,0.113572,2 ,2 , 0,0 ,0 ,0 ,0 ,0 , 0 ,0 ,0 ,0,0) 10 Wave(5)= tide('K2' ,0.030875,2 ,2 , 0,2 ,0 ,0 ,0 ,0 , 0 ,0 ,-2 ,0,235) 11 12 Wave(6)= tide('K1' ,0.142408,1 ,1 , 0,1 ,0 ,0 ,-90 ,0 , 0 ,-1 ,0 ,0,227) 13 Wave(7)= tide('O1' ,0.101266,1 ,1 ,-2,1 ,0 ,0 ,+90 ,2 ,-1 , 0 ,0 ,0,75) 14 Wave(8)= tide('Q1' ,0.019387,1 ,1 ,-3,1 ,1 ,0 ,+90 ,2 ,-1 , 0 ,0 ,0,75) 15 Wave(9)= tide('P1' ,0.047129,1 ,1 , 0,-1,0 ,0 ,+90 ,0 , 0 , 0 ,0 ,0,0) 16 17 Wave(10)= tide('M4' ,0.000000,4 ,4 ,-4, 4,0 ,0 ,0 ,4 , -4 , 0 ,0 ,0,1) 18 19 Wave(11) = tide('Mf' ,0.042017,0 ,0 , 2, 0,0 ,0 ,0 ,-2 , 0 , 0 ,0 ,0,74) 20 Wave(12) = tide('Mm' ,0.022191,0 ,0 , 1,0 ,-1,0 ,0 ,0 , 0 , 0 ,0 ,0,73) 21 Wave(13) = tide('Msqm' ,0.000667,0 ,0 , 4,-2, 0,0 ,0 ,-2 , 0 , 0 ,0 ,0,74) 22 Wave(14) = tide('Mtm' ,0.008049,0 ,0 , 3, 0,-1,0 ,0 ,-2 , 0 , 0 ,0 ,0,74) 23 24 Wave(15) = tide('S1' ,0.000000,1 ,1, 0, 0, 0,0 ,0 , 0 , 0 , 0 ,0 ,0,0) 25 Wave(16) = tide('MU2' ,0.005841,2 ,2, -4, 4, 0,0 ,0 ,2 ,-2 , 0, 0 ,0,78) 26 Wave(17) = tide('NU2' ,0.009094,2 ,2, -3, 4,-1,0 ,0 ,2 ,-2 , 0, 0 ,0,78) 27 Wave(18) = tide('L2' ,0.006694,2 ,2, -1, 2,-1,0 ,+180 ,2 ,-2 , 0, 0 ,0,215) 28 Wave(19) = tide('T2' ,0.006614,2 ,2, 0,-1, 0,1 ,0 ,0 , 0 , 0, 0 ,0,0) 5 ! !! name_tide , equitide , nutide , nt , ns , nh , np , np1 , shift , nksi , nnu0 , nnu1 , nnu2 , R , formula !! 6 ! !! ! ! ! ! ! ! ! ! ! ! ! ! ! ! !! 7 Wave( 1) = tide( 'M2' , 0.242297 , 2 , 2 , -2 , 2 , 0 , 0 , 0 , 2 , -2 , 0 , 0 , 0 , 78 ) 8 Wave( 2) = tide( 'N2' , 0.046313 , 2 , 2 , -3 , 2 , 1 , 0 , 0 , 2 , -2 , 0 , 0 , 0 , 78 ) 9 Wave( 3) = tide( '2N2' , 0.006184 , 2 , 2 , -4 , 2 , 2 , 0 , 0 , 2 , -2 , 0 , 0 , 0 , 78 ) 10 Wave( 4) = tide( 'S2' , 0.113572 , 2 , 2 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 ) 11 Wave( 5) = tide( 'K2' , 0.030875 , 2 , 2 , 0 , 2 , 0 , 0 , 0 , 0 , 0 , 0 , -2 , 0 , 235 ) 12 ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! 13 Wave( 6) = tide( 'K1' , 0.142408 , 1 , 1 , 0 , 1 , 0 , 0 , -90 , 0 , 0 , -1 , 0 , 0 , 227 ) 14 Wave( 7) = tide( 'O1' , 0.101266 , 1 , 1 , -2 , 1 , 0 , 0 , +90 , 2 , -1 , 0 , 0 , 0 , 75 ) 15 Wave( 8) = tide( 'Q1' , 0.019387 , 1 , 1 , -3 , 1 , 1 , 0 , +90 , 2 , -1 , 0 , 0 , 0 , 75 ) 16 Wave( 9) = tide( 'P1' , 0.047129 , 1 , 1 , 0 , -1 , 0 , 0 , +90 , 0 , 0 , 0 , 0 , 0 , 0 ) 17 ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! 18 Wave(10) = tide( 'M4' , 0.000000 , 4 , 4 , -4 , 4 , 0 , 0 , 0 , 4 , -4 , 0 , 0 , 0 , 1 ) 19 ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! 20 Wave(11) = tide( 'Mf' , 0.042017 , 0 , 0 , 2 , 0 , 0 , 0 , 0 , -2 , 0 , 0 , 0 , 0 , 74 ) 21 Wave(12) = tide( 'Mm' , 0.022191 , 0 , 0 , 1 , 0 , -1 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 73 ) 22 Wave(13) = tide( 'Msqm' , 0.000667 , 0 , 0 , 4 , -2 , 0 , 0 , 0 , -2 , 0 , 0 , 0 , 0 , 74 ) 23 Wave(14) = tide( 'Mtm' , 0.008049 , 0 , 0 , 3 , 0 , -1 , 0 , 0 , -2 , 0 , 0 , 0 , 0 , 74 ) 24 ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! ! 25 Wave(15) = tide( 'S1' , 0.000000 , 1 , 1 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 , 0 ) 26 Wave(16) = tide( 'MU2' , 0.005841 , 2 , 2 , -4 , 4 , 0 , 0 , 0 , 2 , -2 , 0 , 0 , 0 , 78 ) 27 Wave(17) = tide( 'NU2' , 0.009094 , 2 , 2 , -3 , 4 , -1 , 0 , 0 , 2 , -2 , 0 , 0 , 0 , 78 ) 28 Wave(18) = tide( 'L2' , 0.006694 , 2 , 2 , -1 , 2 , -1 , 0 , +180 , 2 , -2 , 0 , 0 , 0 , 215 ) 29 Wave(19) = tide( 'T2' , 0.006614 , 2 , 2 , 0 , -1 , 0 , 1 , 0 , 0 , 0 , 0 , 0 , 0 , 0 ) -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/SBC/tide_mod.F90
r3670 r3953 1 1 MODULE tide_mod 2 !!================================================================================= 3 !! *** MODULE tide_mod *** 4 !! Compute nodal modulations corrections and pulsations 5 !!================================================================================= 6 !!--------------------------------------------------------------------------------- 7 !! OPA 9.0 , LODYC-IPSL (2003) 8 !!--------------------------------------------------------------------------------- 9 USE dom_oce ! ocean space and time domain 10 USE phycst 11 USE daymod 12 13 IMPLICIT NONE 14 PRIVATE 15 16 REAL(wp) :: sh_T, sh_s, sh_h, sh_p, sh_p1, & 17 sh_xi, sh_nu, sh_nuprim, sh_nusec, sh_R, & 18 sh_I, sh_x1ra, sh_N 19 20 INTEGER,PUBLIC, PARAMETER :: & 21 jpmax_harmo = 19 ! maximum number of harmonic 22 23 TYPE, PUBLIC :: tide 24 CHARACTER(LEN=4) :: cname_tide 25 REAL(wp) :: equitide 26 INTEGER :: nutide 27 INTEGER :: nt,ns,nh,np,np1,shift 28 INTEGER :: nksi,nnu0,nnu1,nnu2,R 29 INTEGER :: nformula 30 END TYPE tide 31 32 TYPE(tide), PUBLIC, DIMENSION(jpmax_harmo) :: Wave 33 34 !! * Accessibility 35 PUBLIC tide_harmo 36 PUBLIC nodal_factort 37 PUBLIC tide_init_Wave 38 2 !!====================================================================== 3 !! *** MODULE tide_mod *** 4 !! Compute nodal modulations corrections and pulsations 5 !!====================================================================== 6 !! History : 1.0 ! 2007 (O. Le Galloudec) Original code 7 !!---------------------------------------------------------------------- 8 USE dom_oce ! ocean space and time domain 9 USE phycst ! physical constant 10 USE daymod ! calendar 11 12 IMPLICIT NONE 13 PRIVATE 14 15 PUBLIC tide_harmo ! called by tideini and diaharm modules 16 PUBLIC tide_init_Wave ! called by tideini and diaharm modules 17 18 INTEGER, PUBLIC, PARAMETER :: jpmax_harmo = 19 !: maximum number of harmonic 19 20 TYPE, PUBLIC :: tide 21 CHARACTER(LEN=4) :: cname_tide 22 REAL(wp) :: equitide 23 INTEGER :: nutide 24 INTEGER :: nt, ns, nh, np, np1, shift 25 INTEGER :: nksi, nnu0, nnu1, nnu2, R 26 INTEGER :: nformula 27 END TYPE tide 28 29 TYPE(tide), PUBLIC, DIMENSION(jpmax_harmo) :: Wave !: 30 31 REAL(wp) :: sh_T, sh_s, sh_h, sh_p, sh_p1 ! astronomic angles 32 REAL(wp) :: sh_xi, sh_nu, sh_nuprim, sh_nusec, sh_R ! 33 REAL(wp) :: sh_I, sh_x1ra, sh_N ! 34 35 !!---------------------------------------------------------------------- 36 !! NEMO/OPA 3.3 , LOCEAN-IPSL (2010) 37 !! $Id:$ 38 !! Software governed by the CeCILL licence (modipsl/doc/NEMO_CeCILL.txt) 39 !!---------------------------------------------------------------------- 39 40 CONTAINS 40 41 41 SUBROUTINE tide_init_Wave 42 43 # include "tide.h90" 44 45 END SUBROUTINE tide_init_Wave 46 47 SUBROUTINE tide_harmo( pomega, pvt, put , pcor, ktide ,kc) 48 49 INTEGER, DIMENSION(kc), INTENT( in ) :: & 50 ktide ! Indice of tidal constituents 51 52 INTEGER, INTENT( in ) :: & 53 kc ! Total number of tidal constituents 54 55 REAL (wp), DIMENSION(kc), INTENT( out ) :: & 56 pomega ! pulsation in radians/s 57 58 REAL (wp), DIMENSION(kc), INTENT( out ) :: & 59 pvt, & ! 60 put, & ! 61 pcor ! 62 63 CALL astronomic_angle 64 CALL tide_pulse(pomega, ktide ,kc) 65 CALL tide_vuf( pvt, put, pcor, ktide ,kc) 66 67 END SUBROUTINE tide_harmo 68 69 SUBROUTINE astronomic_angle 70 71 !!---------------------------------------------------------------------- 72 !! 73 !! tj is time elapsed since 1st January 1900, 0 hour, counted in julian 74 !! century (e.g. time in days divide by 36525) 75 !!---------------------------------------------------------------------- 76 77 REAL(wp) :: cosI,p,q,t2,t4,sin2I,s2,tgI2,P1,sh_tgn2,at1,at2 78 REAL(wp) :: zqy,zsy,zday,zdj,zhfrac 79 80 zqy=AINT((nyear-1901.)/4.) 81 zsy=nyear-1900. 82 83 zdj=dayjul(nyear,nmonth,nday) 84 zday=zdj+zqy-1. 85 86 zhfrac=nsec_day/3600. 87 88 !---------------------------------------------------------------------- 89 ! Sh_n Longitude of ascending lunar node 90 !---------------------------------------------------------------------- 91 92 sh_N=(259.1560564-19.328185764*zsy-.0529539336*zday-.0022064139*zhfrac)*rad 93 !---------------------------------------------------------------------- 94 ! T mean solar angle (Greenwhich time) 95 !---------------------------------------------------------------------- 96 sh_T=(180.+zhfrac*(360./24.))*rad 97 !---------------------------------------------------------------------- 98 ! h mean solar Longitude 99 !---------------------------------------------------------------------- 100 101 sh_h=(280.1895014-.238724988*zsy+.9856473288*zday+.0410686387*zhfrac)*rad 102 !---------------------------------------------------------------------- 103 ! s mean lunar Longitude 104 !---------------------------------------------------------------------- 105 106 sh_s=(277.0256206+129.38482032*zsy+13.176396768*zday+.549016532*zhfrac)*rad 107 !---------------------------------------------------------------------- 108 ! p1 Longitude of solar perigee 109 !---------------------------------------------------------------------- 110 111 sh_p1=(281.2208569+.01717836*zsy+.000047064*zday+.000001961*zhfrac)*rad 112 !---------------------------------------------------------------------- 113 ! p Longitude of lunar perigee 114 !---------------------------------------------------------------------- 115 116 sh_p=(334.3837214+40.66246584*zsy+.111404016*zday+.004641834*zhfrac)*rad 117 118 sh_N =mod(sh_N ,2*rpi) 119 sh_s =mod(sh_s ,2*rpi) 120 sh_h =mod(sh_h, 2*rpi) 121 sh_p =mod(sh_p, 2*rpi) 122 sh_p1=mod(sh_p1,2*rpi) 123 124 cosI=0.913694997 -0.035692561 *cos(sh_N) 125 126 sh_I=acos(cosI) 127 128 sin2I=sin(sh_I) 129 sh_tgn2=tan(sh_N/2.0) 130 131 at1=atan(1.01883*sh_tgn2) 132 at2=atan(0.64412*sh_tgn2) 133 134 sh_xi=-at1-at2+sh_N 135 136 if (sh_N > rpi) sh_xi=sh_xi-2.0*rpi 137 138 sh_nu=at1-at2 139 140 !---------------------------------------------------------------------- 141 ! For constituents l2 k1 k2 142 !---------------------------------------------------------------------- 143 144 tgI2=tan(sh_I/2.0) 145 P1=sh_p-sh_xi 146 147 t2=tgI2*tgI2 148 t4=t2*t2 149 sh_x1ra=sqrt(1.0-12.0*t2*cos(2.0*P1)+36.0*t4) 150 151 p=sin(2.0*P1) 152 q=1.0/(6.0*t2)-cos(2.0*P1) 153 sh_R=atan(p/q) 154 155 p=sin(2.0*sh_I)*sin(sh_nu) 156 q=sin(2.0*sh_I)*cos(sh_nu)+0.3347 157 sh_nuprim=atan(p/q) 158 159 s2=sin(sh_I)*sin(sh_I) 160 p=s2*sin(2.0*sh_nu) 161 q=s2*cos(2.0*sh_nu)+0.0727 162 sh_nusec=0.5*atan(p/q) 163 164 END SUBROUTINE astronomic_angle 165 166 SUBROUTINE tide_pulse( pomega, ktide ,kc) 167 !!---------------------------------------------------------------------- 168 !! *** ROUTINE tide_pulse *** 169 !! 170 !! ** Purpose : Compute tidal frequencies 171 !! 172 !!---------------------------------------------------------------------- 173 !! * Arguments 174 INTEGER, DIMENSION(kc), INTENT( in ) :: & 175 ktide ! Indice of tidal constituents 176 177 INTEGER, INTENT( in ) :: & 178 kc ! Total number of tidal constituents 179 180 REAL (wp), DIMENSION(kc), INTENT( out ) :: & 181 pomega ! pulsation in radians/s 182 183 !! * Local declarations 184 INTEGER :: jh 185 REAL(wp) :: zscale = 36525*24.0 186 REAL(wp) :: zomega_T= 13149000.0 187 REAL(wp) :: zomega_s= 481267.892 188 REAL(wp) :: zomega_h= 36000.76892 189 REAL(wp) :: zomega_p= 4069.0322056 190 REAL(wp) :: zomega_n= 1934.1423972 191 REAL(wp) :: zomega_p1= 1.719175 192 !!---------------------------------------------------------------------- 193 194 DO jh=1,kc 195 pomega(jh) = zomega_T * Wave(ktide(jh))%nT & 196 + zomega_s * Wave(ktide(jh))%ns & 197 + zomega_h * Wave(ktide(jh))%nh & 198 + zomega_p * Wave(ktide(jh))%np & 199 + zomega_p1* Wave(ktide(jh))%np1 200 pomega(jh) = (pomega(jh)/zscale)*rad/3600. 201 END DO 202 203 END SUBROUTINE tide_pulse 204 205 SUBROUTINE tide_vuf( pvt, put, pcor, ktide ,kc) 206 !!---------------------------------------------------------------------- 207 !! *** ROUTINE tide_vuf *** 208 !! 209 !! ** Purpose : Compute nodal modulation corrections 210 !! 211 !! ** Outputs : 212 !! vt: Pase of tidal potential relative to Greenwich (radians) 213 !! ut: Phase correction u due to nodal motion (radians) 214 !! ft: Nodal correction factor 215 !! 216 !! ** Inputs : 217 !! tname: array of constituents names (dimension<=nc) 218 !! nc: number of constituents 219 !! 220 !!---------------------------------------------------------------------- 221 !! * Arguments 222 INTEGER, DIMENSION(kc), INTENT( in ) :: & 223 ktide ! Indice of tidal constituents 224 INTEGER, INTENT( in ) :: & 225 kc ! Total number of tidal constituents 226 REAL (wp), DIMENSION(kc), INTENT( out ) :: & 227 pvt, & ! 228 put, & ! 229 pcor ! 230 !! * Local declarations 231 INTEGER :: jh 232 !!---------------------------------------------------------------------- 233 234 DO jh =1,kc 235 ! Phase of the tidal potential relative to the Greenwhich 236 ! meridian (e.g. the position of the fictuous celestial body). Units are 237 ! radian: 238 pvt(jh) = sh_T *Wave(ktide(jh))%nT & 239 +sh_s *Wave(ktide(jh))%ns & 240 +sh_h *Wave(ktide(jh))%nh & 241 +sh_p *Wave(ktide(jh))%np & 242 +sh_p1*Wave(ktide(jh))%np1 & 243 +Wave(ktide(jh))%shift*rad 42 SUBROUTINE tide_init_Wave 43 # include "tide.h90" 44 END SUBROUTINE tide_init_Wave 45 46 47 SUBROUTINE tide_harmo( pomega, pvt, put , pcor, ktide ,kc) 48 !!---------------------------------------------------------------------- 49 !!---------------------------------------------------------------------- 50 INTEGER , DIMENSION(kc), INTENT(in ) :: ktide ! Indice of tidal constituents 51 INTEGER , INTENT(in ) :: kc ! Total number of tidal constituents 52 REAL(wp), DIMENSION(kc), INTENT(out) :: pomega ! pulsation in radians/s 53 REAL(wp), DIMENSION(kc), INTENT(out) :: pvt, put, pcor ! 54 !!---------------------------------------------------------------------- 55 ! 56 CALL astronomic_angle 57 CALL tide_pulse( pomega, ktide ,kc ) 58 CALL tide_vuf ( pvt, put, pcor, ktide ,kc ) 59 ! 60 END SUBROUTINE tide_harmo 61 62 63 SUBROUTINE astronomic_angle 64 !!---------------------------------------------------------------------- 65 !! tj is time elapsed since 1st January 1900, 0 hour, counted in julian 66 !! century (e.g. time in days divide by 36525) 67 !!---------------------------------------------------------------------- 68 REAL(wp) :: cosI, p, q, t2, t4, sin2I, s2, tgI2, P1, sh_tgn2, at1, at2 69 REAL(wp) :: zqy , zsy, zday, zdj, zhfrac 70 !!---------------------------------------------------------------------- 71 ! 72 zqy = AINT( (nyear-1901.)/4. ) 73 zsy = nyear - 1900. 74 ! 75 zdj = dayjul( nyear, nmonth, nday ) 76 zday = zdj + zqy - 1. 77 ! 78 zhfrac = nsec_day / 3600. 79 ! 80 !---------------------------------------------------------------------- 81 ! Sh_n Longitude of ascending lunar node 82 !---------------------------------------------------------------------- 83 sh_N=(259.1560564-19.328185764*zsy-.0529539336*zday-.0022064139*zhfrac)*rad 84 !---------------------------------------------------------------------- 85 ! T mean solar angle (Greenwhich time) 86 !---------------------------------------------------------------------- 87 sh_T=(180.+zhfrac*(360./24.))*rad 88 !---------------------------------------------------------------------- 89 ! h mean solar Longitude 90 !---------------------------------------------------------------------- 91 sh_h=(280.1895014-.238724988*zsy+.9856473288*zday+.0410686387*zhfrac)*rad 92 !---------------------------------------------------------------------- 93 ! s mean lunar Longitude 94 !---------------------------------------------------------------------- 95 sh_s=(277.0256206+129.38482032*zsy+13.176396768*zday+.549016532*zhfrac)*rad 96 !---------------------------------------------------------------------- 97 ! p1 Longitude of solar perigee 98 !---------------------------------------------------------------------- 99 sh_p1=(281.2208569+.01717836*zsy+.000047064*zday+.000001961*zhfrac)*rad 100 !---------------------------------------------------------------------- 101 ! p Longitude of lunar perigee 102 !---------------------------------------------------------------------- 103 sh_p=(334.3837214+40.66246584*zsy+.111404016*zday+.004641834*zhfrac)*rad 104 105 sh_N = MOD( sh_N ,2*rpi ) 106 sh_s = MOD( sh_s ,2*rpi ) 107 sh_h = MOD( sh_h, 2*rpi ) 108 sh_p = MOD( sh_p, 2*rpi ) 109 sh_p1= MOD( sh_p1,2*rpi ) 110 111 cosI = 0.913694997 -0.035692561 *cos(sh_N) 112 113 sh_I = ACOS( cosI ) 114 115 sin2I = sin(sh_I) 116 sh_tgn2 = tan(sh_N/2.0) 117 118 at1=atan(1.01883*sh_tgn2) 119 at2=atan(0.64412*sh_tgn2) 120 121 sh_xi=-at1-at2+sh_N 122 123 IF( sh_N > rpi ) sh_xi=sh_xi-2.0*rpi 124 125 sh_nu = at1 - at2 126 127 !---------------------------------------------------------------------- 128 ! For constituents l2 k1 k2 129 !---------------------------------------------------------------------- 130 131 tgI2 = tan(sh_I/2.0) 132 P1 = sh_p-sh_xi 133 134 t2 = tgI2*tgI2 135 t4 = t2*t2 136 sh_x1ra = sqrt( 1.0-12.0*t2*cos(2.0*P1)+36.0*t4 ) 137 138 p = sin(2.0*P1) 139 q = 1.0/(6.0*t2)-cos(2.0*P1) 140 sh_R = atan(p/q) 141 142 p = sin(2.0*sh_I)*sin(sh_nu) 143 q = sin(2.0*sh_I)*cos(sh_nu)+0.3347 144 sh_nuprim = atan(p/q) 145 146 s2 = sin(sh_I)*sin(sh_I) 147 p = s2*sin(2.0*sh_nu) 148 q = s2*cos(2.0*sh_nu)+0.0727 149 sh_nusec = 0.5*atan(p/q) 150 ! 151 END SUBROUTINE astronomic_angle 152 153 154 SUBROUTINE tide_pulse( pomega, ktide ,kc ) 155 !!---------------------------------------------------------------------- 156 !! *** ROUTINE tide_pulse *** 157 !! 158 !! ** Purpose : Compute tidal frequencies 159 !!---------------------------------------------------------------------- 160 INTEGER , INTENT(in ) :: kc ! Total number of tidal constituents 161 INTEGER , DIMENSION(kc), INTENT(in ) :: ktide ! Indice of tidal constituents 162 REAL(wp), DIMENSION(kc), INTENT(out) :: pomega ! pulsation in radians/s 163 ! 164 INTEGER :: jh 165 REAL(wp) :: zscale 166 REAL(wp) :: zomega_T = 13149000.0_wp 167 REAL(wp) :: zomega_s = 481267.892_wp 168 REAL(wp) :: zomega_h = 36000.76892_wp 169 REAL(wp) :: zomega_p = 4069.0322056_wp 170 REAL(wp) :: zomega_n = 1934.1423972_wp 171 REAL(wp) :: zomega_p1= 1.719175_wp 172 !!---------------------------------------------------------------------- 173 ! 174 zscale = rad / ( 36525._wp * 86400._wp ) 175 ! 176 DO jh = 1, kc 177 pomega(jh) = ( zomega_T * Wave( ktide(jh) )%nT & 178 & + zomega_s * Wave( ktide(jh) )%ns & 179 & + zomega_h * Wave( ktide(jh) )%nh & 180 & + zomega_p * Wave( ktide(jh) )%np & 181 & + zomega_p1* Wave( ktide(jh) )%np1 ) * zscale 182 END DO 183 ! 184 END SUBROUTINE tide_pulse 185 186 187 SUBROUTINE tide_vuf( pvt, put, pcor, ktide ,kc ) 188 !!---------------------------------------------------------------------- 189 !! *** ROUTINE tide_vuf *** 190 !! 191 !! ** Purpose : Compute nodal modulation corrections 192 !! 193 !! ** Outputs : vt: Phase of tidal potential relative to Greenwich (radians) 194 !! ut: Phase correction u due to nodal motion (radians) 195 !! ft: Nodal correction factor 196 !!---------------------------------------------------------------------- 197 INTEGER , INTENT(in ) :: kc ! Total number of tidal constituents 198 INTEGER , DIMENSION(kc), INTENT(in ) :: ktide ! Indice of tidal constituents 199 REAL(wp), DIMENSION(kc), INTENT(out) :: pvt, put, pcor ! 200 ! 201 INTEGER :: jh ! dummy loop index 202 !!---------------------------------------------------------------------- 203 ! 204 DO jh = 1, kc 205 ! Phase of the tidal potential relative to the Greenwhich 206 ! meridian (e.g. the position of the fictuous celestial body). Units are radian: 207 pvt(jh) = sh_T * Wave( ktide(jh) )%nT & 208 & + sh_s * Wave( ktide(jh) )%ns & 209 & + sh_h * Wave( ktide(jh) )%nh & 210 & + sh_p * Wave( ktide(jh) )%np & 211 & + sh_p1* Wave( ktide(jh) )%np1 & 212 & + Wave( ktide(jh) )%shift * rad 213 ! 214 ! Phase correction u due to nodal motion. Units are radian: 215 put(jh) = sh_xi * Wave( ktide(jh) )%nksi & 216 & + sh_nu * Wave( ktide(jh) )%nnu0 & 217 & + sh_nuprim * Wave( ktide(jh) )%nnu1 & 218 & + sh_nusec * Wave( ktide(jh) )%nnu2 & 219 & + sh_R * Wave( ktide(jh) )%R 220 221 ! Nodal correction factor: 222 pcor(jh) = nodal_factort( Wave( ktide(jh) )%nformula ) 223 END DO 224 ! 225 END SUBROUTINE tide_vuf 226 227 228 RECURSIVE FUNCTION nodal_factort( kformula ) RESULT( zf ) 229 !!---------------------------------------------------------------------- 230 !!---------------------------------------------------------------------- 231 INTEGER, INTENT(in) :: kformula 232 ! 233 REAL(wp) :: zf 234 REAL(wp) :: zs, zf1, zf2 235 !!---------------------------------------------------------------------- 236 ! 237 SELECT CASE( kformula ) 238 ! 239 CASE( 0 ) !== formule 0, solar waves 240 zf = 1.0 241 ! 242 CASE( 1 ) !== formule 1, compound waves (78 x 78) 243 zf=nodal_factort(78) 244 zf = zf * zf 245 ! 246 CASE ( 2 ) !== formule 2, compound waves (78 x 0) === (78) 247 zf1= nodal_factort(78) 248 zf = nodal_factort( 0) 249 zf = zf1 * zf 244 250 ! 245 ! Phase correction u due to nodal motion. Units are radian: 246 put(jh) = sh_xi *Wave(ktide(jh))%nksi & 247 +sh_nu *Wave(ktide(jh))%nnu0 & 248 +sh_nuprim*Wave(ktide(jh))%nnu1 & 249 +sh_nusec *Wave(ktide(jh))%nnu2 & 250 +sh_R *Wave(ktide(jh))%R 251 252 ! Nodal correction factor: 253 pcor(jh) = nodal_factort(Wave(ktide(jh))%nformula) 254 END DO 255 256 END SUBROUTINE tide_vuf 257 258 recursive function nodal_factort(kformula) result (zf) 259 !!---------------------------------------------------------------------- 260 INTEGER, INTENT(IN) :: kformula 261 REAL(wp) :: zf 262 REAL(wp) :: zs,zf1,zf2 263 264 SELECT CASE (kformula) 265 266 !! formule 0, solar waves 267 268 case ( 0 ) 269 zf=1.0 270 271 !! formule 1, compound waves (78 x 78) 272 273 case ( 1 ) 274 zf=nodal_factort(78) 275 zf=zf*zf 276 277 !! formule 2, compound waves (78 x 0) === (78) 278 279 case ( 2 ) 280 zf1=nodal_factort(78) 281 zf=nodal_factort(0) 282 zf=zf1*zf 283 284 !! formule 4, compound waves (78 x 235) 285 286 case ( 4 ) 287 zf1=nodal_factort(78) 288 zf=nodal_factort(235) 289 zf=zf1*zf 290 291 !! formule 5, compound waves (78 *78 x 235) 292 293 case ( 5 ) 294 zf1=nodal_factort(78) 295 zf=nodal_factort(235) 296 zf=zf*zf1*zf1 297 298 !! formule 6, compound waves (78 *78 x 0) 299 300 case ( 6 ) 301 zf1=nodal_factort(78) 302 zf=nodal_factort(0) 303 zf=zf*zf1*zf1 304 305 !! formule 7, compound waves (75 x 75) 306 307 case ( 7 ) 308 zf=nodal_factort(75) 309 zf=zf*zf 310 311 !! formule 8, compound waves (78 x 0 x 235) 312 313 case ( 8 ) 314 zf=nodal_factort(78) 315 zf1=nodal_factort(0) 316 zf2=nodal_factort(235) 317 zf=zf*zf1*zf2 318 319 !! formule 9, compound waves (78 x 0 x 227) 320 321 case ( 9 ) 322 zf=nodal_factort(78) 323 zf1=nodal_factort(0) 324 zf2=nodal_factort(227) 325 zf=zf*zf1*zf2 326 327 !! formule 10, compound waves (78 x 227) 328 329 case ( 10 ) 330 zf=nodal_factort(78) 331 zf1=nodal_factort(227) 332 zf=zf*zf1 333 334 !! formule 11, compound waves (75 x 0) 335 336 case ( 11 ) 337 zf=nodal_factort(75) 338 zf=nodal_factort(0) 339 zf=zf*zf1 340 341 !! formule 12, compound waves (78 x 78 x 78 x 0) 342 343 case ( 12 ) 344 zf1=nodal_factort(78) 345 zf=nodal_factort(0) 346 zf=zf*zf1*zf1*zf1 347 348 !! formule 13, compound waves (78 x 75) 349 350 case ( 13 ) 351 zf1=nodal_factort(78) 352 zf=nodal_factort(75) 353 zf=zf*zf1 354 355 !! formule 14, compound waves (235 x 0) === (235) 356 357 case ( 14 ) 358 zf=nodal_factort(235) 359 zf1=nodal_factort(0) 360 zf=zf*zf1 361 362 !! formule 15, compound waves (235 x 75) 363 364 case ( 15 ) 365 zf=nodal_factort(235) 366 zf1=nodal_factort(75) 367 zf=zf*zf1 368 369 !! formule 16, compound waves (78 x 0 x 0) === (78) 370 371 case ( 16 ) 372 zf=nodal_factort(78) 373 zf1=nodal_factort(0) 374 zf=zf*zf1*zf1 375 376 !! formule 17, compound waves (227 x 0) 377 378 case ( 17 ) 379 zf1=nodal_factort(227) 380 zf=nodal_factort(0) 381 zf=zf*zf1 382 383 !! formule 18, compound waves (78 x 78 x 78 ) 384 385 case ( 18 ) 386 zf1=nodal_factort(78) 387 zf=zf1*zf1*zf1 388 389 !! formule 19, compound waves (78 x 0 x 0 x 0) === (78) 390 391 case ( 19 ) 392 zf=nodal_factort(78) 393 zf1=nodal_factort(0) 394 zf=zf*zf1*zf1 395 396 !! formule 73 397 398 case ( 73 ) 399 zs=sin(sh_I) 400 zf=(2./3.-zs*zs)/0.5021 401 402 !! formule 74 403 404 case ( 74 ) 405 zs=sin(sh_I) 406 zf=zs*zs/0.1578 407 408 !! formule 75 409 410 case ( 75 ) 411 zs=cos (sh_I/2) 412 zf=sin (sh_I)*zs*zs/0.3800 413 414 !! formule 76 415 416 case ( 76 ) 417 zf=sin (2*sh_I)/0.7214 418 419 !! formule 77 420 421 case ( 77 ) 422 zs=sin (sh_I/2) 423 zf=sin (sh_I)*zs*zs/0.0164 424 425 !! formule 78 426 427 case ( 78 ) 428 zs=cos (sh_I/2) 429 zf=zs*zs*zs*zs/0.9154 430 431 !! formule 79 432 433 case ( 79 ) 434 zs=sin(sh_I) 435 zf=zs*zs/0.1565 436 437 !! formule 144 438 439 case ( 144 ) 440 zs=sin (sh_I/2) 441 zf=(1-10*zs*zs+15*zs*zs*zs*zs)*cos(sh_I/2)/0.5873 442 443 !! formule 149 444 445 case ( 149 ) 446 zs=cos (sh_I/2) 447 zf=zs*zs*zs*zs*zs*zs/0.8758 448 449 !! formule 215 450 451 case ( 215 ) 452 zs=cos (sh_I/2) 453 zf=zs*zs*zs*zs/0.9154*sh_x1ra 454 455 !! formule 227 456 457 case ( 227 ) 458 zs=sin (2*sh_I) 459 zf=sqrt (0.8965*zs*zs+0.6001*zs*cos (sh_nu)+0.1006) 460 461 !! formule 235 462 463 case ( 235 ) 464 zs=sin (sh_I) 465 zf=sqrt (19.0444*zs*zs*zs*zs+2.7702*zs*zs*cos (2*sh_nu)+.0981) 466 467 END SELECT 468 469 end function nodal_factort 470 471 function dayjul(kyr,kmonth,kday) 472 ! 473 !*** THIS ROUTINE COMPUTES THE JULIAN DAY (AS A REAL VARIABLE) 474 ! 475 INTEGER,INTENT(IN) :: kyr,kmonth,kday 476 INTEGER,DIMENSION(12) :: idayt,idays 477 INTEGER :: inc,ji 478 REAL(wp) :: dayjul,zyq 479 480 DATA idayt/0.,31.,59.,90.,120.,151.,181.,212.,243.,273.,304.,334./ 481 idays(1)=0. 482 idays(2)=31. 483 inc=0. 484 zyq=MOD((kyr-1900.),4.) 485 IF(zyq .eq. 0.) inc=1. 486 DO ji=3,12 487 idays(ji)=idayt(ji)+inc 488 END DO 489 dayjul=idays(kmonth)+kday 490 491 END FUNCTION dayjul 492 251 CASE ( 4 ) !== formule 4, compound waves (78 x 235) 252 zf1 = nodal_factort( 78) 253 zf = nodal_factort(235) 254 zf = zf1 * zf 255 ! 256 CASE ( 5 ) !== formule 5, compound waves (78 *78 x 235) 257 zf1 = nodal_factort( 78) 258 zf = nodal_factort(235) 259 zf = zf * zf1 * zf1 260 ! 261 CASE ( 6 ) !== formule 6, compound waves (78 *78 x 0) 262 zf1 = nodal_factort(78) 263 zf = nodal_factort( 0) 264 zf = zf * zf1 * zf1 265 ! 266 CASE( 7 ) !== formule 7, compound waves (75 x 75) 267 zf = nodal_factort(75) 268 zf = zf * zf 269 ! 270 CASE( 8 ) !== formule 8, compound waves (78 x 0 x 235) 271 zf = nodal_factort( 78) 272 zf1 = nodal_factort( 0) 273 zf2 = nodal_factort(235) 274 zf = zf * zf1 * zf2 275 ! 276 CASE( 9 ) !== formule 9, compound waves (78 x 0 x 227) 277 zf = nodal_factort( 78) 278 zf1 = nodal_factort( 0) 279 zf2 = nodal_factort(227) 280 zf = zf * zf1 * zf2 281 ! 282 CASE( 10 ) !== formule 10, compound waves (78 x 227) 283 zf = nodal_factort( 78) 284 zf1 = nodal_factort(227) 285 zf = zf * zf1 286 ! 287 CASE( 11 ) !== formule 11, compound waves (75 x 0) 288 !!gm bug???? zf 2 fois ! 289 zf = nodal_factort(75) 290 zf = nodal_factort( 0) 291 zf = zf * zf1 292 ! 293 CASE( 12 ) !== formule 12, compound waves (78 x 78 x 78 x 0) 294 zf1 = nodal_factort(78) 295 zf = nodal_factort( 0) 296 zf = zf * zf1 * zf1 * zf1 297 ! 298 CASE( 13 ) !== formule 13, compound waves (78 x 75) 299 zf1 = nodal_factort(78) 300 zf = nodal_factort(75) 301 zf = zf * zf1 302 ! 303 CASE( 14 ) !== formule 14, compound waves (235 x 0) === (235) 304 zf = nodal_factort(235) 305 zf1 = nodal_factort( 0) 306 zf = zf * zf1 307 ! 308 CASE( 15 ) !== formule 15, compound waves (235 x 75) 309 zf = nodal_factort(235) 310 zf1 = nodal_factort( 75) 311 zf = zf * zf1 312 ! 313 CASE( 16 ) !== formule 16, compound waves (78 x 0 x 0) === (78) 314 zf = nodal_factort(78) 315 zf1 = nodal_factort( 0) 316 zf = zf * zf1 * zf1 317 ! 318 CASE( 17 ) !== formule 17, compound waves (227 x 0) 319 zf1 = nodal_factort(227) 320 zf = nodal_factort( 0) 321 zf = zf * zf1 322 ! 323 CASE( 18 ) !== formule 18, compound waves (78 x 78 x 78 ) 324 zf1 = nodal_factort(78) 325 zf = zf1 * zf1 * zf1 326 ! 327 CASE( 19 ) !== formule 19, compound waves (78 x 0 x 0 x 0) === (78) 328 !!gm bug2 ==>>> here identical to formule 16, a third multiplication by zf1 is missing 329 zf = nodal_factort(78) 330 zf1 = nodal_factort( 0) 331 zf = zf * zf1 * zf1 332 ! 333 CASE( 73 ) !== formule 73 334 zs = sin(sh_I) 335 zf = (2./3.-zs*zs)/0.5021 336 ! 337 CASE( 74 ) !== formule 74 338 zs = sin(sh_I) 339 zf = zs * zs / 0.1578 340 ! 341 CASE( 75 ) !== formule 75 342 zs = cos(sh_I/2) 343 zf = sin(sh_I) * zs * zs / 0.3800 344 ! 345 CASE( 76 ) !== formule 76 346 zf = sin(2*sh_I) / 0.7214 347 ! 348 CASE( 77 ) !== formule 77 349 zs = sin(sh_I/2) 350 zf = sin(sh_I) * zs * zs / 0.0164 351 ! 352 CASE( 78 ) !== formule 78 353 zs = cos(sh_I/2) 354 zf = zs * zs * zs * zs / 0.9154 355 ! 356 CASE( 79 ) !== formule 79 357 zs = sin(sh_I) 358 zf = zs * zs / 0.1565 359 ! 360 CASE( 144 ) !== formule 144 361 zs = sin(sh_I/2) 362 zf = ( 1-10*zs*zs+15*zs*zs*zs*zs ) * cos(sh_I/2) / 0.5873 363 ! 364 CASE( 149 ) !== formule 149 365 zs = cos(sh_I/2) 366 zf = zs*zs*zs*zs*zs*zs / 0.8758 367 ! 368 CASE( 215 ) !== formule 215 369 zs = cos(sh_I/2) 370 zf = zs*zs*zs*zs / 0.9154 * sh_x1ra 371 ! 372 CASE( 227 ) !== formule 227 373 zs = sin(2*sh_I) 374 zf = sqrt( 0.8965*zs*zs+0.6001*zs*cos (sh_nu)+0.1006 ) 375 ! 376 CASE ( 235 ) !== formule 235 377 zs = sin(sh_I) 378 zf = sqrt( 19.0444*zs*zs*zs*zs + 2.7702*zs*zs*cos(2*sh_nu) + .0981 ) 379 ! 380 END SELECT 381 ! 382 END FUNCTION nodal_factort 383 384 385 FUNCTION dayjul( kyr, kmonth, kday ) 386 !!---------------------------------------------------------------------- 387 !! *** THIS ROUTINE COMPUTES THE JULIAN DAY (AS A REAL VARIABLE) 388 !!---------------------------------------------------------------------- 389 INTEGER,INTENT(in) :: kyr, kmonth, kday 390 ! 391 INTEGER,DIMENSION(12) :: idayt, idays 392 INTEGER :: inc, ji 393 REAL(wp) :: dayjul, zyq 394 ! 395 DATA idayt/0.,31.,59.,90.,120.,151.,181.,212.,243.,273.,304.,334./ 396 !!---------------------------------------------------------------------- 397 ! 398 idays(1) = 0. 399 idays(2) = 31. 400 inc = 0. 401 zyq = MOD( kyr-1900. , 4. ) 402 IF( zyq == 0.) inc = 1. 403 DO ji = 3, 12 404 idays(ji)=idayt(ji)+inc 405 END DO 406 dayjul = idays(kmonth) + kday 407 ! 408 END FUNCTION dayjul 409 410 !!====================================================================== 493 411 END MODULE tide_mod -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/SBC/tideini.F90
r3651 r3953 1 1 MODULE tideini 2 !!================================================================================= 3 !! *** MODULE tideini *** 4 !! Initialization of tidal forcing 5 !! History : 9.0 ! 07 (O. Le Galloudec) Original code 6 !!================================================================================= 7 !! * Modules used 8 USE oce ! ocean dynamics and tracers variables 9 USE dom_oce ! ocean space and time domain 10 USE in_out_manager ! I/O units 11 USE ioipsl ! NetCDF IPSL library 12 USE lbclnk ! ocean lateral boundary conditions (or mpp link) 13 USE phycst 14 USE daymod 15 USE dynspg_oce 16 USE tide_mod 17 USE iom 2 !!====================================================================== 3 !! *** MODULE tideini *** 4 !! Initialization of tidal forcing 5 !!====================================================================== 6 !! History : 1.0 ! 2007 (O. Le Galloudec) Original code 7 !!---------------------------------------------------------------------- 8 USE oce ! ocean dynamics and tracers variables 9 USE dom_oce ! ocean space and time domain 10 USE phycst 11 USE daymod 12 USE dynspg_oce 13 USE tide_mod 14 ! 15 USE iom 16 USE in_out_manager ! I/O units 17 USE ioipsl ! NetCDF IPSL library 18 USE lbclnk ! ocean lateral boundary conditions (or mpp link) 18 19 19 IMPLICIT NONE20 PUBLIC20 IMPLICIT NONE 21 PUBLIC 21 22 22 REAL(wp), PUBLIC, ALLOCATABLE, DIMENSION(:) :: & 23 omega_tide, & 24 v0tide, & 25 utide, & 26 ftide 23 REAL(wp), PUBLIC, ALLOCATABLE, DIMENSION(:) :: omega_tide !: 24 REAL(wp), PUBLIC, ALLOCATABLE, DIMENSION(:) :: v0tide !: 25 REAL(wp), PUBLIC, ALLOCATABLE, DIMENSION(:) :: utide !: 26 REAL(wp), PUBLIC, ALLOCATABLE, DIMENSION(:) :: ftide !: 27 27 28 LOGICAL, PUBLIC :: ln_tide_pot = .false., ln_tide_ramp = .false. 29 REAL(wp), PUBLIC :: rdttideramp 30 INTEGER, PUBLIC :: nb_harmo 31 INTEGER, PUBLIC, ALLOCATABLE, DIMENSION(:) :: ntide 32 INTEGER, PUBLIC :: kt_tide 28 LOGICAL , PUBLIC :: ln_tide_pot = .FALSE. !: 29 LOGICAL , PUBLIC :: ln_tide_ramp = .FALSE. !: 30 INTEGER , PUBLIC :: nb_harmo !: 31 INTEGER , PUBLIC :: kt_tide !: 32 REAL(wp), PUBLIC :: rdttideramp !: 33 34 INTEGER , PUBLIC, ALLOCATABLE, DIMENSION(:) :: ntide !: 33 35 34 !!--------------------------------------------------------------------------------- 35 !! OPA 9.0 , LODYC-IPSL (2003) 36 !!--------------------------------------------------------------------------------- 37 36 !!---------------------------------------------------------------------- 37 !! NEMO/OPA 3.5 , NEMO Consortium (2013) 38 !! $Id: $ 39 !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) 40 !!---------------------------------------------------------------------- 38 41 CONTAINS 39 42 40 SUBROUTINE tide_init ( kt ) 41 !!---------------------------------------------------------------------- 42 !! *** ROUTINE tide_init *** 43 !!---------------------------------------------------------------------- 44 !! * Local declarations 45 INTEGER :: ji, jk 46 INTEGER, INTENT( in ) :: kt ! ocean time-step 47 CHARACTER(LEN=4), DIMENSION(jpmax_harmo) :: clname 48 ! 49 NAMELIST/nam_tide/ln_tide_pot, ln_tide_ramp, rdttideramp, clname 50 !!---------------------------------------------------------------------- 43 SUBROUTINE tide_init ( kt ) 44 !!---------------------------------------------------------------------- 45 !! *** ROUTINE tide_init *** 46 !!---------------------------------------------------------------------- 47 INTEGER :: ji, jk 48 INTEGER, INTENT( in ) :: kt ! ocean time-step 49 CHARACTER(LEN=4), DIMENSION(jpmax_harmo) :: clname 50 ! 51 NAMELIST/nam_tide/ln_tide_pot, ln_tide_ramp, rdttideramp, clname 52 !!---------------------------------------------------------------------- 51 53 52 IF ( kt == nit000 ) THEN 53 ! 54 IF(lwp) THEN 55 WRITE(numout,*) 56 WRITE(numout,*) 'tide_init : Initialization of the tidal components' 57 WRITE(numout,*) '~~~~~~~~~ ' 58 ENDIF 59 ! 60 CALL tide_init_Wave 61 ! 62 clname(:)='' 63 ! 64 ! Read Namelist nam_tide 65 REWIND ( numnam ) 66 READ ( numnam, nam_tide ) 67 ! 68 nb_harmo=0 69 DO jk=1,jpmax_harmo 70 DO ji=1,jpmax_harmo 71 IF(TRIM(clname(jk)) .eq. Wave(ji)%cname_tide) THEN 72 nb_harmo=nb_harmo+1 73 ENDIF 74 END DO 75 ENDDO 76 ! 77 IF(lwp) THEN 78 WRITE(numout,*) ' Namelist nam_tide' 79 WRITE(numout,*) ' nb_harmo = ', nb_harmo 80 WRITE(numout,*) ' ln_tide_ramp = ', ln_tide_ramp 81 WRITE(numout,*) ' rdttideramp = ', rdttideramp 82 IF (ln_tide_ramp.AND.((nitend-nit000+1)*rdt/rday < rdttideramp)) & 83 & CALL ctl_stop('rdttideramp must be lower than run duration') 84 IF (ln_tide_ramp.AND.(rdttideramp<0.)) & 85 & CALL ctl_stop('rdttideramp must be positive') 86 CALL flush(numout) 87 ENDIF 88 ! 89 ALLOCATE(ntide(nb_harmo)) 90 DO jk=1,nb_harmo 91 DO ji=1,jpmax_harmo 92 IF (TRIM(clname(jk)) .eq. Wave(ji)%cname_tide) THEN 93 ntide(jk) = ji 94 EXIT 95 END IF 96 END DO 97 END DO 98 ! 99 ALLOCATE(omega_tide(nb_harmo)) 100 ALLOCATE(v0tide (nb_harmo)) 101 ALLOCATE(utide (nb_harmo)) 102 ALLOCATE(ftide (nb_harmo)) 103 kt_tide = kt 104 ! 105 ENDIF 106 107 IF ( nsec_day == NINT(0.5 * rdttra(1)) ) THEN 108 ! 109 IF(lwp) THEN 110 WRITE(numout,*) 111 WRITE(numout,*) 'tide_ini : Update of the tidal components at kt=',kt 112 WRITE(numout,*) '~~~~~~~~ ' 113 ENDIF 114 CALL tide_harmo(omega_tide, v0tide, utide, ftide, ntide, nb_harmo) 115 DO jk =1,nb_harmo 116 IF(lwp) WRITE(numout,*) Wave(ntide(jk))%cname_tide,utide(jk),ftide(jk),v0tide(jk),omega_tide(jk) 117 call flush(numout) 118 END DO 119 ! 120 kt_tide = kt 121 ! 122 ENDIF 123 124 END SUBROUTINE tide_init 125 54 IF( kt == nit000 ) THEN 55 ! 56 IF(lwp) THEN 57 WRITE(numout,*) 58 WRITE(numout,*) 'tide_init : Initialization of the tidal components' 59 WRITE(numout,*) '~~~~~~~~~ ' 60 ENDIF 61 ! 62 CALL tide_init_Wave 63 ! 64 clname(:)='' 65 ! 66 REWIND( numnam ) ! Read Namelist nam_tide 67 READ ( numnam, nam_tide ) 68 ! 69 nb_harmo=0 70 DO jk = 1, jpmax_harmo 71 DO ji = 1,jpmax_harmo 72 IF( TRIM(clname(jk)) == Wave(ji)%cname_tide ) nb_harmo = nb_harmo + 1 73 END DO 74 END DO 75 ! 76 IF(lwp) THEN 77 WRITE(numout,*) ' Namelist nam_tide' 78 WRITE(numout,*) ' Apply astronomical potential : ln_tide_pot =', ln_tide_pot 79 WRITE(numout,*) ' nb_harmo = ', nb_harmo 80 WRITE(numout,*) ' ln_tide_ramp = ', ln_tide_ramp 81 WRITE(numout,*) ' rdttideramp = ', rdttideramp 82 ENDIF 83 IF( ln_tide_ramp.AND.((nitend-nit000+1)*rdt/rday < rdttideramp) ) & 84 & CALL ctl_stop('rdttideramp must be lower than run duration') 85 IF( ln_tide_ramp.AND.(rdttideramp<0.) ) & 86 & CALL ctl_stop('rdttideramp must be positive') 87 ! 88 IF( .NOT. lk_dynspg_ts ) CALL ctl_warn( 'sbc_tide : use of time splitting is recommended' ) 89 ! 90 ALLOCATE( ntide(nb_harmo) ) 91 DO jk = 1, nb_harmo 92 DO ji = 1, jpmax_harmo 93 IF( TRIM(clname(jk)) .eq. Wave(ji)%cname_tide ) THEN 94 ntide(jk) = ji 95 EXIT 96 END IF 97 END DO 98 END DO 99 ! 100 ALLOCATE( omega_tide(nb_harmo), v0tide (nb_harmo), & 101 & utide (nb_harmo), ftide (nb_harmo) ) 102 kt_tide = kt 103 ! 104 ENDIF 105 ! 106 IF( nsec_day == NINT(0.5 * rdttra(1)) ) THEN 107 ! 108 CALL tide_harmo( omega_tide, v0tide, utide, ftide, ntide, nb_harmo ) 109 ! 110 kt_tide = kt 111 ! 112 IF(lwp) THEN 113 WRITE(numout,*) 114 WRITE(numout,*) 'tide_ini : Update of the tidal components at kt=', kt 115 WRITE(numout,*) '~~~~~~~~ ' 116 DO jk = 1, nb_harmo 117 WRITE(numout,*) Wave(ntide(jk))%cname_tide, utide(jk), ftide(jk), v0tide(jk), omega_tide(jk) 118 END DO 119 ENDIF 120 ! 121 ENDIF 122 ! 123 END SUBROUTINE tide_init 124 125 !!====================================================================== 126 126 END MODULE tideini -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/SBC/updtide.F90
r3651 r3953 1 1 MODULE updtide 2 !!================================================================================= 3 !! *** MODULE updtide *** 4 !! Initialization of tidal forcing 5 !! History : 9.0 ! 07 (O. Le Galloudec) Original code 6 !!================================================================================= 2 !!====================================================================== 3 !! *** MODULE updtide *** 4 !! Initialization of tidal forcing 5 !!====================================================================== 6 !! History : 9.0 ! 07 (O. Le Galloudec) Original code 7 !!---------------------------------------------------------------------- 7 8 #if defined key_tide 8 !! * Modules used 9 USE oce ! ocean dynamics and tracers variables 10 USE dom_oce ! ocean space and time domain 11 USE in_out_manager ! I/O units 12 USE phycst 13 USE sbctide 14 USE dynspg_oce 15 USE tideini, ONLY: ln_tide_ramp, rdttideramp 9 !!---------------------------------------------------------------------- 10 !! 'key_tide' : tidal potential 11 !!---------------------------------------------------------------------- 12 !! upd_tide : update tidal potential 13 !!---------------------------------------------------------------------- 14 USE oce ! ocean dynamics and tracers variables 15 USE dom_oce ! ocean space and time domain 16 USE in_out_manager ! I/O units 17 USE phycst ! physical constant 18 USE sbctide ! tide potential variable 19 USE tideini, ONLY: ln_tide_ramp, rdttideramp 16 20 17 IMPLICIT NONE18 PUBLIC21 IMPLICIT NONE 22 PUBLIC 19 23 20 !! * Routine accessibility 21 PUBLIC upd_tide 22 !!--------------------------------------------------------------------------------- 23 !! OPA 9.0 , LODYC-IPSL (2003) 24 !!--------------------------------------------------------------------------------- 25 24 PUBLIC upd_tide ! called in dynspg_... modules 25 26 !!---------------------------------------------------------------------- 27 !! NEMO/OPA 3.3 , NEMO Consortium (2010) 28 !! $Id: sbcfwb.F90 3625 2012-11-21 13:19:18Z acc $ 29 !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) 30 !!---------------------------------------------------------------------- 26 31 CONTAINS 27 32 28 SUBROUTINE upd_tide (kt,kit) 29 !!---------------------------------------------------------------------- 30 !! *** ROUTINE upd_tide *** 31 !!---------------------------------------------------------------------- 32 !! * Local declarations 33 SUBROUTINE upd_tide( kt, kit, kbaro ) 34 !!---------------------------------------------------------------------- 35 !! *** ROUTINE upd_tide *** 36 !! 37 !! ** Purpose : provide at each time step the astronomical potential 38 !! 39 !! ** Method : computed from pulsation and amplitude of all tide components 40 !! 41 !! ** Action : pot_astro actronomical potential 42 !!---------------------------------------------------------------------- 43 INTEGER, INTENT(in) :: kt ! ocean time-step index 44 INTEGER, INTENT(in), OPTIONAL :: kit ! external mode sub-time-step index (lk_dynspg_ts=T only) 45 INTEGER, INTENT(in), OPTIONAL :: kbaro ! number of sub-time-step (lk_dynspg_ts=T only) 46 ! 47 INTEGER :: ji, jj, jk ! dummy loop indices 48 REAL(wp) :: zt, zramp ! local scalar 49 REAL(wp), DIMENSION(nb_harmo) :: zwt 50 !!---------------------------------------------------------------------- 51 ! 52 ! ! tide pulsation at model time step (or sub-time-step) 53 zt = ( kt - kt_tide ) * rdt 54 IF( PRESENT( kit ) .AND. PRESENT( kbaro ) ) zt = zt + kit * rdt / REAL( kbaro, wp ) 55 zwt(:) = omega_tide(:) * zt 33 56 34 INTEGER, INTENT( in ) :: kt,kit ! ocean time-step index 35 INTEGER :: ji,jj,jk 36 REAL (wp) :: zramp 37 REAL (wp), DIMENSION(nb_harmo) :: zwt 38 !............................................................................... 39 40 pot_astro(:,:)=0.e0 41 zramp = 1.e0 42 43 IF (lk_dynspg_ts) THEN 44 zwt(:) = omega_tide(:)* ((kt-kt_tide)*rdt + kit*(rdt/REAL(nn_baro,wp))) 45 IF (ln_tide_ramp) THEN 46 zramp = MIN(MAX( ((kt-nit000)*rdt + kit*(rdt/REAL(nn_baro,wp)))/(rdttideramp*rday),0.),1.) 47 ENDIF 48 ELSE 49 zwt(:) = omega_tide(:)*(kt-kt_tide)*rdt 50 IF (ln_tide_ramp) THEN 51 zramp = MIN(MAX( ((kt-nit000)*rdt)/(rdttideramp*rday),0.),1.) 52 ENDIF 53 ENDIF 54 55 do jk=1,nb_harmo 56 do ji=1,jpi 57 do jj=1,jpj 58 pot_astro(ji,jj)=pot_astro(ji,jj) + zramp*(amp_pot(ji,jj,jk)*COS(zwt(jk)+phi_pot(ji,jj,jk))) 59 enddo 60 enddo 61 enddo 62 63 END SUBROUTINE upd_tide 57 pot_astro(:,:) = 0._wp ! update tidal potential (sum of all harmonics) 58 DO jk = 1, nb_harmo 59 pot_astro(:,:) = pot_astro(:,:) + amp_pot(:,:,jk) * COS( zwt(jk) + phi_pot(:,:,jk) ) 60 END DO 61 ! 62 IF( ln_tide_ramp ) THEN ! linear increase if asked 63 zt = ( kt - nit000 ) * rdt 64 IF( PRESENT( kit ) .AND. PRESENT( kbaro ) ) zt = zt + kit * rdt / REAL( kbaro, wp ) 65 zramp = MIN( MAX( zt / (rdttideramp*rday) , 0._wp ) , 1._wp ) 66 pot_astro(:,:) = zramp * pot_astro(:,:) 67 ENDIF 68 ! 69 END SUBROUTINE upd_tide 64 70 65 71 #else -
branches/2013/dev_r3858_NOC_ZTC/NEMOGCM/NEMO/OPA_SRC/step.F90
r3865 r3953 89 89 ! Update data, open boundaries, surface boundary condition (including sea-ice) 90 90 !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< 91 CALL sbc ( kstp ) ! Sea Boundary Condition (including sea-ice) 92 IF( lk_tide.AND.(kstp /= nit000 )) CALL tide_init ( kstp ) 91 CALL sbc ( kstp ) ! Sea Boundary Condition (including sea-ice) 93 92 IF( lk_tide ) CALL sbc_tide( kstp ) 94 IF( lk_obc ) CALL obc_dta ( kstp )! update dynamic and tracer data at open boundaries95 IF( lk_obc ) CALL obc_rad ( kstp )! compute phase velocities at open boundaries96 IF( lk_bdy ) CALL bdy_dta ( kstp, time_offset=+1 ) ! update dynamic andtracer data at open boundaries93 IF( lk_obc ) CALL obc_dta ( kstp ) ! update dynamic and tracer data at open boundaries 94 IF( lk_obc ) CALL obc_rad ( kstp ) ! compute phase velocities at open boundaries 95 IF( lk_bdy ) CALL bdy_dta ( kstp, time_offset=+1 ) ! update dynamic & tracer data at open boundaries 97 96 98 97 !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> … … 117 116 IF( lk_zdfgls ) CALL zdf_gls( kstp ) ! GLS closure scheme for Kz 118 117 IF( lk_zdfkpp ) CALL zdf_kpp( kstp ) ! KPP closure scheme for Kz 119 IF( lk_zdfcst ) THEN! Constant Kz (reset avt, avm[uv] to the background value)118 IF( lk_zdfcst ) THEN ! Constant Kz (reset avt, avm[uv] to the background value) 120 119 avt (:,:,:) = rn_avt0 * tmask(:,:,:) 121 120 avmu(:,:,:) = rn_avm0 * umask(:,:,:)
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