Changeset 3108
- Timestamp:
- 2011-11-15T12:55:23+01:00 (13 years ago)
- Location:
- branches/2011/dev_NOC_UKMO_MERGE
- Files:
-
- 11 edited
- 2 moved
Legend:
- Unmodified
- Added
- Removed
-
branches/2011/dev_NOC_UKMO_MERGE/DOC/TexFiles/Chapters/Chap_DYN.tex
r3101 r3108 608 608 documented or tested. 609 609 610 $\bullet$ Traditional coding (see for example \citet{Madec_al_JPO96}: (\np{ln\_dynhpg\_sco}=true, 611 \np{ln\_dynhpg\_hel}=true) 610 $\bullet$ Traditional coding (see for example \citet{Madec_al_JPO96}: (\np{ln\_dynhpg\_sco}=true) 612 611 \begin{equation} \label{Eq_dynhpg_sco} 613 612 \left\{ \begin{aligned} … … 622 621 \eqref{Eq_dynhpg_zco_surf} - \eqref{Eq_dynhpg_zco}, and $z_T$ is the depth of 623 622 the $T$-point evaluated from the sum of the vertical scale factors at the $w$-point 624 ($e_{3w}$). The version \np{ln\_dynhpg\_hel}=true has been added by Aike 625 Beckmann and involves a redefinition of the relative position of $T$-points relative 626 to $w$-points. 627 628 $\bullet$ Weighted density Jacobian (WDJ) \citep{Song1998} (\np{ln\_dynhpg\_wdj}=true) 623 ($e_{3w}$). 629 624 630 625 $\bullet$ Density Jacobian with cubic polynomial scheme (DJC) \citep{Shchepetkin_McWilliams_OM05} 631 626 (\np{ln\_dynhpg\_djc}=true) 632 633 $\bullet$ Rotated axes scheme (rot) \citep{Thiem_Berntsen_OM06} (\np{ln\_dynhpg\_rot}=true)634 627 635 628 $\bullet$ Pressure Jacobian scheme (prj) \citep{Thiem_Berntsen_OM06} (\np{ln\_dynhpg\_prj}=true) -
branches/2011/dev_NOC_UKMO_MERGE/DOC/TexFiles/Namelist/namdyn_hpg
r3101 r3108 5 5 ln_hpg_zps = .true. ! z-coordinate - partial steps (interpolation) 6 6 ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation) 7 ln_hpg_hel = .false. ! s-coordinate (helsinki modification)8 ln_hpg_wdj = .false. ! s-coordinate (weighted density jacobian)9 7 ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial) 10 ln_hpg_rot = .false. ! s-coordinate (ROTated axes scheme)11 8 ln_hpg_prj = .false. ! s-coordinate (Pressure Jacobian scheme) 12 rn_gamma = 0.e0 ! weighting coefficient (wdj scheme)13 9 ln_dynhpg_imp = .false. ! time stepping: semi-implicit time scheme (T) 14 10 ! centered time scheme (F) -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/CONFIG/AMM12/EXP00/namelist
r3076 r3108 1 1 !!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> 2 2 !! NEMO/OPA : 1 - run manager (namrun) 3 !! namelists 2 - Domain (namzgr, namzgr_sco, namdom )3 !! namelists 2 - Domain (namzgr, namzgr_sco, namdom, namdta_tem, namdta_sal) 4 4 !! 3 - Surface boundary (namsbc, namsbc_ana, namsbc_flx, namsbc_clio, namsbc_core 5 !! namsbc_cpl, namqsr, namsbc_rnf, namsbc_ssr, namsbc_alb) 5 !! namsbc_cpl, namtra_qsr, namsbc_rnf, 6 !! namsbc_apr, namsbc_ssr, namsbc_alb) 6 7 !! 4 - lateral boundary (namlbc, namcla, namobc, namagrif, nambdy, nambdy_tide) 7 8 !! 5 - bottom boundary (nambfr, nambbc, nambbl) … … 9 10 !! 7 - dynamics (namdyn_adv, namdyn_vor, namdyn_hpg, namdyn_spg, namdyn_ldf) 10 11 !! 8 - Verical physics (namzdf, namzdf_ric, namzdf_tke, namzdf_kpp, namzdf_ddm, namzdf_tmx) 11 !! 9 - diagnostics (namtrd, namgap, namspr, namflo, namptr) 12 !! 9 - miscellaneous (namsol, nammpp, nammpp_dyndist, namctl) 12 !! 9 - diagnostics (namnc4, namtrd, namspr, namflo, namptr, namhsb) 13 !! 10 - miscellaneous (namsol, nammpp, nammpp_dyndist, namctl) 14 !! 11 - Obs & Assim (namobs, nam_asminc) 13 15 !!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> 14 ! CAUTION: some scripts does not support CAPITALs for logical use .true./.false., not .TRUE./.FALSE.15 16 16 17 !!====================================================================== 17 18 !! *** Run management namelists *** 18 19 !!====================================================================== 19 !! namrun 20 !!====================================================================== 21 20 !! namrun parameters of the run 21 !!====================================================================== 22 ! 22 23 !----------------------------------------------------------------------- 23 24 &namrun ! parameters of the run 24 25 !----------------------------------------------------------------------- 25 nn_no = 0 ! job number 26 cn_exp = "amm12" ! experience name 27 cn_ocerst_in = "restart" ! suffix of ocean restart name (input) 28 cn_ocerst_out = "restart" ! suffix of ocean restart name (output) 29 ln_rstart = .true. ! start from rest (F) or from a restart file (T) 30 nn_rstctl = 0 ! restart control = 0 nit000 is not compared to the restart file value 31 ! = 1 use ndate0 in namelist (not the value in the restart file) 32 ! = 2 calendar parameters read in the restart file 33 nn_it000 = 1 ! first time step 34 nn_itend = 5184 ! last time step (std 5475) 35 nn_date0 = 20070101 ! initial calendar date yymmdd (used if nrstdt=1) 36 nn_leapy = 1 ! Leap year calendar (1) or not (0) 37 nn_istate = 0 ! output the initial state (1) or not (0) 38 nn_stock = 5184 ! frequency of creation of a restart file (modulo referenced to 1) 39 nn_write = 12 ! frequency of write in the output file (modulo referenced to nit000) 40 ln_dimgnnn = .false. ! DIMG file format: 1 file for all processors (F) or by processor (T) 41 ln_mskland = .false. ! mask land points in NetCDF outputs (costly: + ~15%) 42 ln_clobber = .false. ! clobber (overwrite) an existing file 43 nn_chunksz = 0 ! chunksize (bytes) for NetCDF file (working only with iom_nf90 routines) 44 / 26 nn_no = 0 ! job number 27 cn_exp = "AMM12" ! experience name 28 nn_it000 = 1 ! first time step 29 nn_itend = 576 ! last time step (std 1 day = 576) 30 nn_date0 = 20070101 ! initial calendar date yymmdd (used if nn_rstctl=1) 31 nn_leapy = 1 ! Leap year calendar (1) or not (0) 32 ln_rstart = .true. ! start from rest (F) or from a restart file (T) 33 nn_rstctl = 0 ! restart control = 0 nn_it000 is not compared to the restart file value 34 ! = 1 use nn_date0 in namelist (not the value in the restart file) 35 ! = 2 calendar parameters read in the restart file 36 cn_ocerst_in = "restart" ! suffix of ocean restart name (input) 37 cn_ocerst_out = "restart" ! suffix of ocean restart name (output) 38 nn_istate = 0 ! output the initial state (1) or not (0) 39 nn_stock = 576 ! frequency of creation of a restart file (modulo referenced to 1) 40 nn_write = 12 ! frequency of write in the output file (modulo referenced to nit000) 41 ln_dimgnnn = .false. ! DIMG file format: 1 file for all processors (F) or by processor (T) 42 ln_mskland = .false. ! mask land points in NetCDF outputs (costly: + ~15%) 43 ln_clobber = .false. ! clobber (overwrite) an existing file 44 nn_chunksz = 0 ! chunksize (bytes) for NetCDF file (works only with iom_nf90 routines) 45 / 46 45 47 !!====================================================================== 46 48 !! *** Domain namelists *** … … 49 51 !! namzgr_sco s-coordinate or hybrid z-s-coordinate 50 52 !! namdom space and time domain (bathymetry, mesh, timestep) 51 !!====================================================================== 52 53 !! namdta_tem data: temperature ("key_dtatem") 54 !! namdta_sal data: salinity ("key_dtasal") 55 !!====================================================================== 56 ! 53 57 !----------------------------------------------------------------------- 54 58 &namzgr ! vertical coordinate … … 73 77 &namdom ! space and time domain (bathymetry, mesh, timestep) 74 78 !----------------------------------------------------------------------- 75 nn_bathy = 1 ! compute (=0) or read (=1) the bathymetry file76 nn_closea = 0 ! closed seas and lakes are removed (=0) or kept (=1) from the ORCA domain77 nn_msh = 3 ! create (=1) a mesh file (coordinates, scale factors, masks)or not (=0)78 rn_hmin = -279 rn_e3zps_min= 5. ! the thickness of the partial step is set larger than the minimum80 rn_e3zps_rat= 0. 3 ! of e3zps_min and e3zps_rat * e3t (N.B. 0<e3zps_rat<1)79 nn_bathy = 1 ! compute (=0) or read (=1) the bathymetry file 80 nn_closea = 0 ! remove (=0) or keep (=1) closed seas and lakes (ORCA) 81 nn_msh = 0 ! create (=1) a mesh file or not (=0) 82 rn_hmin = -3. ! min depth of the ocean (>0) or min number of ocean level (<0) 83 rn_e3zps_min= 20. ! partial step thickness is set larger than the minimum of 84 rn_e3zps_rat= 0.1 ! rn_e3zps_min and rn_e3zps_rat*e3t, with 0<rn_e3zps_rat<1 81 85 ! 82 rn_rdt = 150. ! time step for the dynamics (and tracer if n acc=0) ==> 576083 nn_baro = 30 ! number of barotropic time step (for the split explicit algorithm)("key_dynspg_ts")84 rn_atfp = 0.1! asselin time filter parameter86 rn_rdt = 150. ! time step for the dynamics (and tracer if nn_acc=0) 87 nn_baro = 30 ! number of barotropic time step ("key_dynspg_ts") 88 rn_atfp = 0.1 ! asselin time filter parameter 85 89 nn_acc = 0 ! acceleration of convergence : =1 used, rdt < rdttra(k) 86 90 ! =0, not used, rdt = rdttra 87 rn_rdtmin = 300. ! minimum time step on tracers (used if nacc=1) 88 rn_rdtmax = 300. ! maximum time step on tracers (used if nacc=1) 89 rn_rdth = 300. ! depth variation of tracer time step (used if nacc=1) 90 / 91 rn_rdtmin = 300. ! minimum time step on tracers (used if nn_acc=1) 92 rn_rdtmax = 300. ! maximum time step on tracers (used if nn_acc=1) 93 rn_rdth = 300. ! depth variation of tracer time step (used if nn_acc=1) 94 / 95 !----------------------------------------------------------------------- 96 &namdta_tem ! data : temperature ("key_dtatem") 97 !----------------------------------------------------------------------- 98 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim !'yearly' or ! weights ! rotation ! 99 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 100 sn_tem = 'data_1m_potential_temperature_nomask', -1,'votemper', .true. , .true., 'yearly' , ' ' , ' ' 101 ! 102 cn_dir = './' ! root directory for the location of the runoff files 103 / 104 !----------------------------------------------------------------------- 105 &namdta_sal ! data : salinity ("key_dtasal") 106 !----------------------------------------------------------------------- 107 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim !'yearly' or ! weights ! rotation ! 108 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 109 sn_sal = 'data_1m_salinity_nomask', -1 ,'vosaline', .true. , .true., 'yearly' , '' , ' ' 110 ! 111 cn_dir = './' ! root directory for the location of the runoff files 112 / 113 91 114 !!====================================================================== 92 115 !! *** Surface Boundary Condition namelists *** 93 116 !!====================================================================== 94 !! namsbc surface boundary condition 95 !! namsbc_ana analytical formulation 96 !! namsbc_flx flux formulation 97 !! namsbc_clio CLIO bulk formulea formulation 98 !! namsbc_core CORE bulk formulea formulation 99 !! namsbc_cpl CouPLed formulation ("key_coupled") 100 !! namtra_qsr penetrative solar radiation 101 !! namsbc_rnf river runoffs 102 !! namsbc_ssr sea surface restoring term (for T and/or S) 103 !! namsbc_alb albedo parameters 104 !!====================================================================== 105 117 !! namsbc surface boundary condition 118 !! namsbc_ana analytical formulation 119 !! namsbc_flx flux formulation 120 !! namsbc_clio CLIO bulk formulea formulation 121 !! namsbc_core CORE bulk formulea formulation 122 !! namsbc_cpl CouPLed formulation ("key_coupled") 123 !! namtra_qsr penetrative solar radiation 124 !! namsbc_rnf river runoffs 125 !! namsbc_apr Atmospheric Pressure 126 !! namsbc_ssr sea surface restoring term (for T and/or S) 127 !! namsbc_alb albedo parameters 128 !!====================================================================== 129 ! 106 130 !----------------------------------------------------------------------- 107 131 &namsbc ! Surface Boundary Condition (surface module) 108 132 !----------------------------------------------------------------------- 109 133 nn_fsbc = 1 ! frequency of surface boundary condition computation 110 ! (= the frequency of sea-ice model call)134 ! (also = the frequency of sea-ice model call) 111 135 ln_ana = .false ! analytical formulation (T => fill namsbc_ana ) 112 136 ln_flx = .true. ! flux formulation (T => fill namsbc_flx ) 113 ln_blk_clio = .false. ! CLIO bulk formulation (T => fill namsbc_clio) 114 ln_blk_core = .false. ! CORE bulk formulation (T => fill namsbc_core) 115 ln_cpl = .false. ! Coupled formulation (T => fill namsbc_cpl ) 137 ln_blk_clio = .false. ! CLIO bulk formulation (T => fill namsbc_clio) 138 ln_blk_core = .false. ! CORE bulk formulation (T => fill namsbc_core) 139 ln_cpl = .false. ! Coupled formulation (T => fill namsbc_cpl ) 140 ln_apr_dyn = .false. ! Patm gradient added in ocean & ice Eqs. (T => fill namsbc_apr ) 116 141 nn_ice = 0 ! =0 no ice boundary condition , 117 142 ! =1 use observed ice-cover , 118 ! =2 ice-model used 119 ln_dm2dc = .false. ! daily mean to diurnal cycle short wave (qsr)120 ln_rnf = .true. ! runoffs (T => fill namsbc_rnf)121 ln_ssr = .false. ! Sea Surface Restoring on T and/or S (T => fill namsbc_ssr)122 nn_fwb = 0 ! FreshWater Budget: =0 unchecked 123 ! =1 global mean of e-p-r set to zero at each time step124 ! 125 ! 143 ! =2 ice-model used ("key_lim3" or "key_lim2) 144 ln_dm2dc = .false. ! daily mean to diurnal cycle on short wave 145 ln_rnf = .true. ! runoffs (T => fill namsbc_rnf) 146 ln_ssr = .false. ! Sea Surface Restoring on T and/or S (T => fill namsbc_ssr) 147 nn_fwb = 0 ! FreshWater Budget: =0 unchecked 148 ! =1 global mean of e-p-r set to zero at each time step 149 ! =2 annual global mean of e-p-r set to zero 150 ! =3 global emp set to zero and spread out over erp area 126 151 / 127 152 !----------------------------------------------------------------------- … … 129 154 !----------------------------------------------------------------------- 130 155 nn_tau000 = 0 ! gently increase the stress over the first ntau_rst time-steps 131 rn_utau0 = 1.e0! uniform value for the i-stress132 rn_vtau0 = 1.e0 ! uniform value for the j-stress156 rn_utau0 = 0.5 ! uniform value for the i-stress 157 rn_vtau0 = 0.e0 ! uniform value for the j-stress 133 158 rn_qns0 = 0.e0 ! uniform value for the total heat flux 134 159 rn_qsr0 = 0.e0 ! uniform value for the solar radiation … … 138 163 &namsbc_flx ! surface boundary condition : flux formulation 139 164 !----------------------------------------------------------------------- 140 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation ! 141 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 142 sn_utau = '12km_utau' , 1 , 'utau' , .false. , .false. , 'daily' , '' , '' 143 sn_vtau = '12km_vtau' , 1 , 'vtau' , .false. , .false. , 'daily' , '' , '' 144 sn_qtot = '12km_trunkflx' , 3 , 'sonsfldo' , .true. , .false. , 'daily' , '' , '' 145 sn_qsr = '12km_trunkflx' , 3 , 'soshfldo' , .true. , .false. , 'daily' , '' , '' 146 sn_emp = '12km_trunkflx' , 3 , 'sowafldo' , .true. , .false. , 'daily' , '' , '' 147 ! sn_press = '12km_pressure' , 1 , 'p_msl' , .true. , .false. , 'daily' , '' , '' 165 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 166 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 167 sn_utau = 'amm12_utau' , 1 , 'utau' , .false. , .false. , 'daily' , '' , '' 168 sn_vtau = 'amm12_vtau' , 1 , 'vtau' , .false. , .false. , 'daily' , '' , '' 169 sn_qtot = 'amm12_flx' , 3 , 'sonsfldo' , .true. , .false. , 'daily' , '' , '' 170 sn_qsr = 'amm12_flx' , 3 , 'soshfldo' , .true. , .false. , 'daily' , '' , '' 171 sn_emp = 'amm12_flx' , 3 , 'sowafldo' , .true. , .false. , 'daily' , '' , '' 148 172 cn_dir = './fluxes/' ! root directory for the location of the flux files 149 ! ln_foam_flx = .FALSE. 150 ! ln_shelf_flx = .TRUE. 151 / 173 / 152 174 !----------------------------------------------------------------------- 153 175 &namsbc_clio ! namsbc_clio CLIO bulk formulea 154 176 !----------------------------------------------------------------------- 155 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim! 'yearly'/ ! weights ! rotation !156 ! ! ! (if <0 months) ! name ! (logical) ! (T/F)! 'monthly' ! filename ! pairing !157 sn_utau = 'taux_1m' , -1 , 'sozotaux' , .true. , .true., 'yearly' , '' , ''158 sn_vtau = 'tauy_1m' , -1 , 'sometauy' , .true. , .true., 'yearly' , '' , ''159 sn_wndm = 'flx' , -1 , 'socliowi' , .true. , .true., 'yearly' , '' , ''160 sn_tair = 'flx' , -1 , 'socliot2' , .true. , .true., 'yearly' , '' , ''161 sn_humi = 'flx' , -1 , 'socliohu' , .true. , .true., 'yearly' , '' , ''162 sn_ccov = 'flx' , -1 , 'socliocl' , .false. , .true., 'yearly' , '' , ''163 sn_prec = 'flx' , -1 , 'socliopl' , .false. , .true., 'yearly' , '' , ''164 ! 177 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 178 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 179 sn_utau = 'taux_1m' , -1 , 'sozotaux', .true. , .true. , 'yearly' , '' , '' 180 sn_vtau = 'tauy_1m' , -1 , 'sometauy', .true. , .true. , 'yearly' , '' , '' 181 sn_wndm = 'flx' , -1 , 'socliowi', .true. , .true. , 'yearly' , '' , '' 182 sn_tair = 'flx' , -1 , 'socliot2', .true. , .true. , 'yearly' , '' , '' 183 sn_humi = 'flx' , -1 , 'socliohu', .true. , .true. , 'yearly' , '' , '' 184 sn_ccov = 'flx' , -1 , 'socliocl', .false. , .true. , 'yearly' , '' , '' 185 sn_prec = 'flx' , -1 , 'socliopl', .false. , .true. , 'yearly' , '' , '' 186 165 187 cn_dir = './' ! root directory for the location of the bulk files are 166 188 / … … 168 190 &namsbc_core ! namsbc_core CORE bulk formulea 169 191 !----------------------------------------------------------------------- 170 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation ! 171 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 172 sn_wndi = 'u10_core' , -1 , 'u10' , .true. , .true. , 'yearly' ,'bicubic_weights_orca2.nc' , 'U1' 173 sn_wndj = 'v10_core' , -1 , 'v10' , .true. , .true. , 'yearly' ,'bicubic_weights_orca2.nc' , 'V1' 174 sn_qsr = 'qsw_core' , -1 , 'swdn' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 175 sn_qlw = 'qlw_core' , -1 , 'lwdn' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 176 sn_tair = 't2_core' , -1 , 't2' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 177 sn_humi = 'q2_core' , -1 , 'q2' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 178 sn_prec = 'precip_core', -1 , 'precip' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 179 sn_snow = 'snow_core' , -1 , 'snow' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 180 ! 192 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 193 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 194 sn_wndi = 'u_10.15JUNE2009_orca2' , 6 , 'U_10_MOD', .false. , .true. , 'yearly' , '' , 'Uwnd' 195 sn_wndj = 'v_10.15JUNE2009_orca2' , 6 , 'V_10_MOD', .false. , .true. , 'yearly' , '' , 'Vwnd' 196 sn_qsr = 'ncar_rad.15JUNE2009_orca2' , 24 , 'SWDN_MOD', .false. , .true. , 'yearly' , '' , '' 197 sn_qlw = 'ncar_rad.15JUNE2009_orca2' , 24 , 'LWDN_MOD', .false. , .true. , 'yearly' , '' , '' 198 sn_tair = 't_10.15JUNE2009_orca2' , 6 , 'T_10_MOD', .false. , .true. , 'yearly' , '' , '' 199 sn_humi = 'q_10.15JUNE2009_orca2' , 6 , 'Q_10_MOD', .false. , .true. , 'yearly' , '' , '' 200 sn_prec = 'ncar_precip.15JUNE2009_orca2', -1 , 'PRC_MOD1', .false. , .true. , 'yearly' , '' , '' 201 sn_snow = 'ncar_precip.15JUNE2009_orca2', -1 , 'SNOW' , .false. , .true. , 'yearly' , '' , '' 202 sn_tdif = 'taudif_core' , 24 , 'taudif' , .false. , .true. , 'yearly' , '' , '' 203 181 204 cn_dir = './' ! root directory for the location of the bulk files 182 ln_2m = .true. ! air temperature and humidity referenced at 2m (T) instead 10m (F) 205 ln_2m = .false. ! air temperature and humidity referenced at 2m (T) instead 10m (F) 206 ln_taudif = .false. ! HF tau contribution: use "mean of stress module - module of the mean stress" data 183 207 rn_pfac = 1. ! multiplicative factor for precipitation (total & snow) 184 208 / 185 209 !----------------------------------------------------------------------- 186 &namsbc_cpl ! coupled ocean/atmosphere model ("key_coupled") 187 !----------------------------------------------------------------------- 188 ! send 189 cn_snd_temperature= 'weighted oce and ice' ! 'oce only' 'weighted oce and ice' 'mixed oce-ice' 190 cn_snd_albedo = 'weighted ice' ! 'none' 'weighted ice' 'mixed oce-ice' 191 cn_snd_thickness = 'none' ! 'none' 'weighted ice and snow' 192 cn_snd_crt_nature = 'none' ! 'none' 'oce only' 'weighted oce and ice' 'mixed oce-ice' 193 cn_snd_crt_refere = 'spherical' ! 'spherical' 'cartesian' 194 cn_snd_crt_orient = 'eastward-northward' ! 'eastward-northward' or 'local grid' 195 cn_snd_crt_grid = 'T' ! 'T' 196 ! receive 197 cn_rcv_w10m = 'coupled' ! 'none' 'coupled' 198 cn_rcv_tau_nature = 'oce only' ! 'oce only' 'oce and ice' 'mixed oce-ice' 199 cn_rcv_tau_refere = 'cartesian' ! 'spherical' 'cartesian' 200 cn_rcv_tau_orient = 'eastward-northward' ! 'eastward-northward' or 'local grid' 201 cn_rcv_tau_grid = 'U,V' ! 'T' 'U,V' 'U,V,F' 'U,V,I' 'T,F' 'T,I' 'T,U,V' 202 cn_rcv_dqnsdt = 'coupled' ! 'none' 'coupled' 203 cn_rcv_qsr = 'oce and ice' ! 'conservative' 'oce and ice' 'mixed oce-ice' 204 cn_rcv_qns = 'oce and ice' ! 'conservative' 'oce and ice' 'mixed oce-ice' 205 cn_rcv_emp = 'conservative' ! 'conservative' 'oce and ice' 'mixed oce-ice' 206 cn_rcv_rnf = 'coupled' ! 'coupled' 'climato' 'mixed' 207 cn_rcv_cal = 'coupled' ! 'none' 'coupled' 208 / 209 !----------------------------------------------------------------------- 210 &namsbc_cpl_co2 ! coupled ocean/biogeo/atmosphere model ("key_cpl_carbon_cycle") 211 !----------------------------------------------------------------------- 212 cn_snd_co2 = 'coupled' ! send : 'none' 'coupled' 213 cn_rcv_co2 = 'coupled' ! receive : 'none' 'coupled' 210 &namsbc_cpl ! coupled ocean/atmosphere model ("key_coupled") 211 !----------------------------------------------------------------------- 212 ! ! description ! multiple ! vector ! vector ! vector ! 213 ! ! ! categories ! reference ! orientation ! grids ! 214 ! send 215 sn_snd_temp = 'weighted oce and ice' , 'no' , '' , '' , '' 216 sn_snd_alb = 'weighted ice' , 'no' , '' , '' , '' 217 sn_snd_thick = 'none' , 'no' , '' , '' , '' 218 sn_snd_crt = 'none' , 'no' , 'spherical' , 'eastward-northward' , 'T' 219 sn_snd_co2 = 'coupled' , 'no' , '' , '' , '' 220 ! receive 221 sn_rcv_w10m = 'none' , 'no' , '' , '' , '' 222 sn_rcv_taumod = 'coupled' , 'no' , '' , '' , '' 223 sn_rcv_tau = 'oce only' , 'no' , 'cartesian' , 'eastward-northward', 'U,V' 224 sn_rcv_dqnsdt = 'coupled' , 'no' , '' , '' , '' 225 sn_rcv_qsr = 'oce and ice' , 'no' , '' , '' , '' 226 sn_rcv_qns = 'oce and ice' , 'no' , '' , '' , '' 227 sn_rcv_emp = 'conservative' , 'no' , '' , '' , '' 228 sn_rcv_rnf = 'coupled' , 'no' , '' , '' , '' 229 sn_rcv_cal = 'coupled' , 'no' , '' , '' , '' 230 sn_rcv_co2 = 'coupled' , 'no' , '' , '' , '' 214 231 / 215 232 !----------------------------------------------------------------------- 216 233 &namtra_qsr ! penetrative solar radiation 217 234 !----------------------------------------------------------------------- 218 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ !weights ! rotation !219 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' !filename ! pairing !220 sn_chl = 'chlorophyll', -1 , 'CHLA' , .true. , .true. , 'yearly' ,'' , ''221 235 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 236 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 237 sn_chl ='chlorophyll', -1 , 'CHLA' , .true. , .true. , 'yearly' , '' , '' 238 222 239 cn_dir = './' ! root directory for the location of the runoff files 223 240 ln_traqsr = .false. ! Light penetration (T) or not (F) … … 229 246 rn_si0 = 0.35 ! RGB & 2 bands: shortess depth of extinction 230 247 rn_si1 = 23.0 ! 2 bands: longest depth of extinction 231 ! rn_si2 = 62.0 ! 3 bands: longest depth of extinction (for blue waveband & 0.01 mg/m2 Chl)232 /233 !----------------------------------------------------------------------------------234 &namtra_dwl ! POLCOMS Style Downwell radiation for Short wave radiation235 !----------------------------------------------------------------------------------236 ln_tradwl = .true. ! Light penetration (T) or not (F)237 ln_vary_lambda = .true. ! Vary Lambda or not (T) or not (F)238 248 / 239 249 !----------------------------------------------------------------------- 240 250 &namsbc_rnf ! runoffs namelist surface boundary condition 241 251 !----------------------------------------------------------------------- 242 cn_dir = './' ! root directory for the location of the runoff files 243 ln_rnf_emp = .false. ! runoffs included into precipitation field (T) or into a file (F) 244 ln_rnf_depth = .true. 245 ln_rnf_tem = .true. 246 ln_rnf_sal = .true. 247 ! ! file name ! frequency(hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! check ! weights ! rotation ! 248 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! (T/F) ! filename ! pairing ! 249 sn_rnf = 'AMM_rivers' , 24 , 'rorunoff' , .false. , .true. , 'yearly' 250 sn_cnf = 'runoff_1m_nomask' , 0 , 'socoefr' , .false. , .true. , 'yearly' 251 sn_s_rnf = 'AMM_rivers' , 24 , 'rosaline' , .false. , .true. , 'yearly' 252 sn_t_rnf = 'AMM_rivers' , 24 , 'rotemper' , .false. , .true. , 'yearly' 253 sn_dep_rnf = 'AMM_rivers' , 24 , 'rodepth' , .false. , .true. , 'yearly' 254 ln_rnf_mouth = .false. ! specific treatment at rivers mouths 255 rn_hrnf = 1000.e0 ! depth over which enhanced vertical mixing is used 256 rn_avt_rnf = 10.e0 ! value of the additional vertical mixing coef. [m2/s] 257 rn_rfact = 1.e0 ! multiplicative factor for runoff 252 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 253 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 254 sn_rnf = 'amm12_rivers' , 24 , 'rorunoff', .false. , .true. , 'yearly' , '' , '' 255 sn_cnf = 'runoff_1m_nomask' , 0 , 'socoefr0', .false. , .true. , 'yearly' , '' , '' 256 sn_s_rnf = 'amm12_rivers' , 24 , 'rosaline', .false. , .true. , 'yearly' , '' , '' 257 sn_t_rnf = 'amm12_rivers' , 24 , 'rotemper', .false. , .true. , 'yearly' , '' , '' 258 sn_dep_rnf = 'amm12_rivers' , 24 , 'rodepth' , .false. , .true. , 'yearly' , '' , '' 259 260 cn_dir = './' ! root directory for the location of the runoff files 261 ln_rnf_emp = .false. ! runoffs included into precipitation field (T) or into a file (F) 262 ln_rnf_mouth = .false. ! specific treatment at rivers mouths 263 rn_hrnf = 15.e0 ! depth over which enhanced vertical mixing is used 264 rn_avt_rnf = 1.e-3 ! value of the additional vertical mixing coef. [m2/s] 265 rn_rfact = 1.e0 ! multiplicative factor for runoff 266 ln_rnf_depth = .true. ! read in depth information for runoff 267 ln_rnf_tem = .true. ! read in temperature information for runoff 268 ln_rnf_sal = .true. ! read in salinity information for runoff 269 / 270 !----------------------------------------------------------------------- 271 &namsbc_apr ! Atmospheric pressure used as ocean forcing or in bulk 272 !----------------------------------------------------------------------- 273 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation ! 274 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 275 sn_apr = 'patm' , -1 ,'somslpre', .true. , .true. , 'yearly' , '' , '' 276 277 cn_dir = './' ! root directory for the location of the bulk files 278 ln_ref_apr = .false. ! ref. pressure: global mean Patm (T) or a constant (F) 258 279 / 259 280 !----------------------------------------------------------------------- 260 281 &namsbc_ssr ! surface boundary condition : sea surface restoring 261 282 !----------------------------------------------------------------------- 262 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! check! weights ! rotation !263 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! (T/F)! filename ! pairing !264 sn_sst = ' references_amm', 24 , 'sst' , .true. , .false. , 'daily' , .false. , '' , ''283 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 284 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 285 sn_sst = 'amm12_sstref' , 24 , 'sst' , .true. , .false. , 'daily' , .false. , '' , '' 265 286 sn_sss = 'sss_data' , -1 , 'sss' , .true. , .true. , 'yearly' , .false. , '' , '' 266 287 267 288 cn_dir = 'fluxes/' ! root directory for the location of the runoff files 268 289 nn_sstr = 1 ! add a retroaction term in the surface heat flux (=1) or not (=0) … … 270 291 ! or to SSS only (=1) or no damping term (=0) 271 292 rn_dqdt = -40. ! magnitude of the retroaction on temperature [W/m2/K] 272 rn_deds = -27.7 ! magnitude of the damping on salinity [mm/day /psu]293 rn_deds = -27.7 ! magnitude of the damping on salinity [mm/day] 273 294 ln_sssr_bnd = .false. ! flag to bound erp term (associated with nn_sssr=2) 274 295 rn_sssr_bnd = 4.e0 ! ABS(Max/Min) value of the damping erp term [mm/day] 275 ln_UKMO_haney = .true. ! correct non-solar heat flux using Haney Correction.276 296 / 277 297 !----------------------------------------------------------------------- … … 295 315 !! namtide Tidal forcing at open boundaries ("key_bdy_tides") 296 316 !!====================================================================== 297 317 ! 298 318 !----------------------------------------------------------------------- 299 319 &namlbc ! lateral momentum boundary condition … … 310 330 &namobc ! open boundaries parameters ("key_obc") 311 331 !----------------------------------------------------------------------- 312 ln_obc_clim= .true.! climatological obc data files (T) or not (F)313 ln_vol_cst = .false.! impose the total volume conservation (T) or not (F)314 ln_obc_fla= .false. ! Flather open boundary condition315 nn_obcdta = 0! = 0 the obc data are equal to the initial state332 ln_obc_clim = .false. ! climatological obc data files (T) or not (F) 333 ln_vol_cst = .true. ! impose the total volume conservation (T) or not (F) 334 ln_obc_fla = .false. ! Flather open boundary condition 335 nn_obcdta = 1 ! = 0 the obc data are equal to the initial state 316 336 ! = 1 the obc data are read in 'obc.dta' files 317 cn_obcdta= 'annual' ! set to annual if obc datafile hold 1 year of data337 cn_obcdta = 'annual' ! set to annual if obc datafile hold 1 year of data 318 338 ! set to monthly if obc datafile hold 1 month of data 319 rn_dpein= 1. ! damping time scale for inflow at east open boundary320 rn_dpwin= 1. ! - - - west - -321 rn_dpnin = 30. ! - - - north - -322 rn_dpsin= 1. ! - - - south - -323 rn_dpeob = 1500. ! time relaxation (days) for the east open boundary324 rn_dpwob= 15. ! - - - west - -325 rn_dpnob = 150. ! - - - north - -326 rn_dpsob= 15. ! - - - south - -327 rn_volemp = 0. ! = 0 the total volume change with the surface flux (E-P-R)339 rn_dpein = 1. ! damping time scale for inflow at east open boundary 340 rn_dpwin = 1. ! - - - west - - 341 rn_dpnin = 1. ! - - - north - - 342 rn_dpsin = 1. ! - - - south - - 343 rn_dpeob = 3000. ! time relaxation (days) for the east open boundary 344 rn_dpwob = 15. ! - - - west - - 345 rn_dpnob = 3000. ! - - - north - - 346 rn_dpsob = 15. ! - - - south - - 347 rn_volemp = 1. ! = 0 the total volume change with the surface flux (E-P-R) 328 348 ! = 1 the total volume remains constant 329 349 / … … 331 351 &namagrif ! AGRIF zoom ("key_agrif") 332 352 !----------------------------------------------------------------------- 333 nn_cln_update = 3! baroclinic update frequency334 ln_spc_dyn = .true.! use 0 as special value for dynamics335 rn_sponge_tra = 2880. ! coefficient for tracer sponge layer [s]336 rn_sponge_dyn = 2880. ! coefficient for dynamics sponge layer [s]337 / 338 !----------------------------------------------------------------------- 339 &nambdy ! open boundaries ("key_bdy")353 nn_cln_update = 3 ! baroclinic update frequency 354 ln_spc_dyn = .true. ! use 0 as special value for dynamics 355 rn_sponge_tra = 2880. ! coefficient for tracer sponge layer [m2/s] 356 rn_sponge_dyn = 2880. ! coefficient for dynamics sponge layer [m2/s] 357 / 358 !----------------------------------------------------------------------- 359 &nambdy ! unstructured open boundaries ("key_bdy") 340 360 !----------------------------------------------------------------------- 341 361 nb_bdy = 1 ! number of open boundary sets 342 362 ln_coords_file = .true. ! =T : read bdy coordinates from file 343 cn_coords_file = 'coordinates. obc.nc' ! bdy coordinates files363 cn_coords_file = 'coordinates.bdy.nc' ! bdy coordinates files 344 364 ln_mask_file = .false. ! =T : read mask from file 345 365 cn_mask_file = '' ! name of mask file (if ln_mask_file=.TRUE.) … … 351 371 nn_dyn3d = 0 ! boundary conditions for baroclinic velocities 352 372 nn_dyn3d_dta = 0 ! = 0, bdy data are equal to the initial state 353 373 ! = 1, bdy data are read in 'bdydata .nc' files 354 374 nn_tra = 1 ! boundary conditions for T and S 355 375 nn_tra_dta = 1 ! = 0, bdy data are equal to the initial state 356 376 ! = 1, bdy data are read in 'bdydata .nc' files 357 377 nn_rimwidth = 10 ! width of the relaxation zone 358 378 nn_dmp2d_in = 0 ! … … 368 388 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation ! 369 389 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 370 bn_ssh = ' obcT_u2d_1d_amm7' , 24 , 'sossheig' , .true. , .false. , 'daily' , '' , ''371 bn_u2d = ' obcU_u2d_1d_amm7' , 24 , 'vobtcrtx' , .true. , .false. , 'daily' , '' , ''372 bn_v2d = ' obcV_u2d_1d_amm7' , 24 , 'vobtcrty' , .true. , .false. , 'daily' , '' , ''373 bn_u3d = ' obcU_u3d_1d_amm7' , 24 , 'vozocrtx' , .true. , .false. , 'daily' , '' , ''374 bn_v3d = ' obcV_u3d_1d_amm7' , 24 , 'vomecrty' , .true. , .false. , 'daily' , '' , ''375 bn_tem = ' obcT_tra_1d_amm7' , 24 , 'votemper' , .true. , .false. , 'daily' , '' , ''376 bn_sal = ' obcT_tra_1d_amm7' , 24 , 'vosaline' , .true. , .false. , 'daily' , '' , ''377 cn_dir = ' obcdta/'390 bn_ssh = 'amm12_bdyT_u2d_1d' , 24 , 'sossheig' , .true. , .false. , 'daily' , '' , '' 391 bn_u2d = 'amm12_bdyU_u2d_1d' , 24 , 'vobtcrtx' , .true. , .false. , 'daily' , '' , '' 392 bn_v2d = 'amm12_bdyV_u2d_1d' , 24 , 'vobtcrty' , .true. , .false. , 'daily' , '' , '' 393 bn_u3d = 'amm12_bdyU_u3d_1d' , 24 , 'vozocrtx' , .true. , .false. , 'daily' , '' , '' 394 bn_v3d = 'amm12_bdyV_u3d_1d' , 24 , 'vomecrty' , .true. , .false. , 'daily' , '' , '' 395 bn_tem = 'amm12_bdyT_tra_1d' , 24 , 'votemper' , .true. , .false. , 'daily' , '' , '' 396 bn_sal = 'amm12_bdyT_tra_1d' , 24 , 'vosaline' , .true. , .false. , 'daily' , '' , '' 397 cn_dir = 'bdydta/' 378 398 ln_full_vel = .false. 379 399 / … … 381 401 &nambdy_tide ! tidal forcing at open boundaries 382 402 !----------------------------------------------------------------------- 383 filtide = 'amm 7_bdytide_' ! file name root of tidal forcing files403 filtide = 'amm12_bdytide_' ! file name root of tidal forcing files 384 404 tide_cpt(1) ='Q1' ! names of tidal components used 385 405 tide_cpt(2) ='O1' ! names of tidal components used … … 414 434 ln_tide_date = .true. ! adjust tidal harmonics for start date of run 415 435 / 436 416 437 !!====================================================================== 417 438 !! *** Bottom boundary condition *** 418 439 !!====================================================================== 419 440 !! nambfr bottom friction 420 !! nambbc bottom temperature boundary condition ("key_trabbc")421 !! nambbl bottom boundary layer scheme ("key_trabbl _dif","key_trabbl_adv")422 !!====================================================================== 423 441 !! nambbc bottom temperature boundary condition 442 !! nambbl bottom boundary layer scheme ("key_trabbl") 443 !!====================================================================== 444 ! 424 445 !----------------------------------------------------------------------- 425 446 &nambfr ! bottom friction 426 447 !----------------------------------------------------------------------- 427 nn_bfr = 2 ! type of bottom friction : = 0 : no slip, = 2 : nonlinear friction428 ! = 3 : free slip, = 1 :linear friction448 nn_bfr = 2 ! type of bottom friction : = 0 : free slip, = 1 : linear friction 449 ! = 2 : nonlinear friction 429 450 rn_bfri1 = 4.e-4 ! bottom drag coefficient (linear case) 430 451 rn_bfri2 = 2.5e-3 ! bottom drag coefficient (non linear case) 431 rn_bfeb2 = 0.0 ! bottom turbulent kinetic energy background (m^2/s^2) 452 rn_bfeb2 = 0.0e0 ! bottom turbulent kinetic energy background (m2/s2) 453 ln_bfr2d = .false. ! horizontal variation of the bottom friction coef (read a 2D mask file ) 454 rn_bfrien = 50. ! local multiplying factor of bfr (ln_bfr2d=T) 455 ln_bfrimp = .true. ! implicit bottom friction (requires ln_zdfexp = .false. if true) 432 456 / 433 457 !----------------------------------------------------------------------- 434 458 &nambbc ! bottom temperature boundary condition 435 459 !----------------------------------------------------------------------- 436 nn_geoflx = 0 ! geothermal heat flux: = 0 no flux 460 ln_trabbc = .true. ! Apply a geothermal heating at the ocean bottom 461 nn_geoflx = 2 ! geothermal heat flux: = 0 no flux 437 462 ! = 1 constant flux 438 463 ! = 2 variable flux (read in geothermal_heating.nc in mW/m2) … … 442 467 &nambbl ! bottom boundary layer scheme 443 468 !----------------------------------------------------------------------- 444 ! ! diffusive bbl ("key_trabbl") 445 ! ! advective bbl ("key_trabbl_adv") 446 rn_ahtbbl = 0. ! lateral mixing coefficient in the bbl [m2/s] 447 / 469 nn_bbl_ldf = 0 ! diffusive bbl (=1) or not (=0) 470 nn_bbl_adv = 0 ! advective bbl (=1/2) or not (=0) 471 rn_ahtbbl = 1000. ! lateral mixing coefficient in the bbl [m2/s] 472 rn_gambbl = 10. ! advective bbl coefficient [s] 473 / 474 448 475 !!====================================================================== 449 476 !! Tracer (T & S ) namelists … … 454 481 !! namtra_dmp T & S newtonian damping ("key_tradmp") 455 482 !!====================================================================== 456 483 ! 457 484 !----------------------------------------------------------------------- 458 485 &nameos ! ocean physical parameters 459 486 !----------------------------------------------------------------------- 460 nn_eos = 0! type of equation of state and Brunt-Vaisala frequency487 nn_eos = 0 ! type of equation of state and Brunt-Vaisala frequency 461 488 ! = 0, UNESCO (formulation of Jackett and McDougall (1994) and of McDougall (1987) ) 462 489 ! = 1, linear: rho(T) = rau0 * ( 1.028 - ralpha * T ) 463 490 ! = 2, linear: rho(T,S) = rau0 * ( rbeta * S - ralpha * T ) 464 rn_alpha = 2.e-4 ! thermal expension coefficient (neos= 1 or 2)465 rn_beta = 0.001 ! saline expension coefficient (neos= 2)491 rn_alpha = 2.0e-4 ! thermal expension coefficient (nn_eos= 1 or 2) 492 rn_beta = 7.7e-4 ! saline expension coefficient (nn_eos= 2) 466 493 / 467 494 !----------------------------------------------------------------------- … … 469 496 !----------------------------------------------------------------------- 470 497 ln_traadv_cen2 = .false. ! 2nd order centered scheme 471 ln_traadv_tvd = .true. ! TVD scheme498 ln_traadv_tvd = .true. ! TVD scheme 472 499 ln_traadv_muscl = .false. ! MUSCL scheme 473 500 ln_traadv_muscl2 = .false. ! MUSCL2 scheme + cen2 at boundaries 474 ln_traadv_ubs = .false. 475 ! ln_traadv_ppm = .false. ! PPMscheme501 ln_traadv_ubs = .false. ! UBS scheme 502 ln_traadv_qck = .false. ! QUICKEST scheme 476 503 / 477 504 !----------------------------------------------------------------------- 478 505 &namtra_ldf ! lateral diffusion scheme for tracer 479 506 !----------------------------------------------------------------------- 480 481 ln_traldf_lap = .true. ! 482 ln_traldf_bilap = .false. ! 483 484 ln_traldf_level = .false. ! 507 ! ! Type of the operator : 508 ln_traldf_lap = .true. ! laplacian operator 509 ln_traldf_bilap = .false. ! bilaplacian operator 510 ! ! Direction of action : 511 ln_traldf_level = .false. ! iso-level 485 512 ln_traldf_hor = .true. ! horizontal (geopotential) (require "key_ldfslp" when ln_sco=T) 486 513 ln_traldf_iso = .false. ! iso-neutral (require "key_ldfslp") 487 ! Coefficient 514 ln_traldf_grif = .false. ! griffies skew flux formulation (require "key_ldfslp") 515 ln_traldf_gdia = .false. ! griffies operator strfn diagnostics (require "key_ldfslp") 516 ln_triad_iso = .false. ! griffies operator calculates triads twice => pure lateral mixing in ML (require "key_ldfslp") 517 ln_botmix_grif = .false. ! griffies operator with lateral mixing on bottom (require "key_ldfslp") 518 ! Coefficient 488 519 rn_aht_0 = 50. ! horizontal eddy diffusivity for tracers [m2/s] 489 rn_ahtb_0 = 0. !background eddy diffusivity for ldf_iso [m2/s]520 rn_ahtb_0 = 0. ! background eddy diffusivity for ldf_iso [m2/s] 490 521 rn_aeiv_0 = 0. ! eddy induced velocity coefficient [m2/s] (require "key_traldf_eiv") 491 522 / … … 496 527 ! =XX, damping poleward of XX degrees (XX>0) 497 528 ! + F(distance-to-coast) + Red and Med Seas 498 nn_zdmp = 1! vertical shape =0 damping throughout the water column529 nn_zdmp = 0 ! vertical shape =0 damping throughout the water column 499 530 ! =1 no damping in the mixing layer (kz criteria) 500 531 ! =2 no damping in the mixed layer (rho crieria) … … 502 533 rn_bot = 360. ! bottom time scale of damping [days] 503 534 rn_dep = 800. ! depth of transition between rn_surf and rn_bot [meters] 504 nn_file = 1 ! create a damping.coeff NetCDF file (=1) or not (=0) 505 / 535 nn_file = 0 ! create a damping.coeff NetCDF file (=1) or not (=0) 536 / 537 506 538 !!====================================================================== 507 539 !! *** Dynamics namelists *** … … 513 545 !! namdyn_ldf lateral diffusion scheme 514 546 !!====================================================================== 515 547 ! 516 548 !----------------------------------------------------------------------- 517 549 &namdyn_adv ! formulation of the momentum advection … … 527 559 ln_dynvor_ens = .false. ! energy conserving scheme 528 560 ln_dynvor_mix = .false. ! mixed scheme 529 ln_dynvor_een = .true. ! energy & enstrophy scheme561 ln_dynvor_een = .true. ! energy & enstrophy scheme 530 562 / 531 563 !----------------------------------------------------------------------- … … 534 566 ln_hpg_zco = .false. ! z-coordinate - full steps 535 567 ln_hpg_zps = .false. ! z-coordinate - partial steps (interpolation) 536 ln_hpg_sco = .true. ! s-coordinate (standard jacobian formulation) 537 ln_hpg_hel = .false. ! s-coordinate (helsinki modification) 538 ln_hpg_wdj = .false. ! s-coordinate (weighted density jacobian) 568 ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation) 539 569 ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial) 540 ln_hpg_rot = .false. ! s-coordinate (ROTated axes scheme) 541 rn_gamma = 0.125 ! weighting coefficient (wdj scheme) 570 ln_hpg_prj = .true. ! s-coordinate (Pressure Jacobian scheme) 542 571 ln_dynhpg_imp = .false. ! time stepping: semi-implicit time scheme (T) 543 572 ! centered time scheme (F) 544 ! nn_dynhpg_rst = 0 ! =1 dynhpg restartable restart or not (=0)545 573 / 546 574 !----------------------------------------------------------------------- … … 554 582 &namdyn_ldf ! lateral diffusion on momentum 555 583 !----------------------------------------------------------------------- 556 ! Type of the operator : 557 ln_dynldf_lap = .true. ! laplacian operator 558 ln_dynldf_bilap = .true. ! bilaplacian operator 559 ln_dynldf_level = .false. 584 ! ! Type of the operator : 585 ln_dynldf_lap = .true. ! laplacian operator 586 ln_dynldf_bilap = .true. ! bilaplacian operator 560 587 ! Direction of action : 561 ! ln_dynldf_lap_level = .false. ! iso-level 562 ! ln_dynldf_lap_hor = .true. ! horizontal (geopotential) (require "key_ldfslp" in s-coord.) 563 ! ln_dynldf_lap_iso = .false. ! iso-neutral (require "key_ldfslp") 564 ! ln_dynldf_bilap_level = .true. ! iso-level 565 ! ln_dynldf_bilap_hor = .false. ! horizontal (geopotential) (require "key_ldfslp" in s-coord.) 566 ! ln_dynldf_bilap_iso = .false. ! iso-neutral (require "key_ldfslp") 567 ! Coefficient : 568 rn_ahm_0_lap = 60.0 ! horizontal eddy viscosity [m2/s] 569 rn_ahmb_0 = 0.0 ! background eddy viscosity for ldf_iso [m2/s] 570 rn_ahm_0_blp = -1.0e+10 ! background eddy viscosity for ldf_iso [m2/s] 571 / 588 ln_dynldf_level = .false. ! iso-level 589 ln_dynldf_hor = .true. ! horizontal (geopotential) (require "key_ldfslp" in s-coord.) 590 ln_dynldf_iso = .false. ! iso-neutral (require "key_ldfslp") 591 ! Coefficient 592 rn_ahm_0_lap = 60.0 ! horizontal laplacian eddy viscosity [m2/s] 593 rn_ahmb_0 = 0.0 ! background eddy viscosity for ldf_iso [m2/s] 594 rn_ahm_0_blp = -1.0e+10 ! horizontal bilaplacian eddy viscosity [m4/s] 595 / 596 572 597 !!====================================================================== 573 598 !! Tracers & Dynamics vertical physics namelists 574 599 !!====================================================================== 575 !! 576 !! namzdf_ric richardson number dependent vertical mixing ("key_zdfric")577 !! namzdf_tke TKE dependent vertical mixing ("key_zdftke")578 !! namzdf_kpp KPP dependent vertical mixing ("key_zdfkpp")579 !! namzdf_ddm double diffusive mixing parameterization ("key_zdfddm")580 !! namzdf_tmx tidal mixing parameterization ("key_zdftmx")581 !!====================================================================== 582 600 !! namzdf vertical physics 601 !! namzdf_ric richardson number dependent vertical mixing ("key_zdfric") 602 !! namzdf_tke TKE dependent vertical mixing ("key_zdftke") 603 !! namzdf_kpp KPP dependent vertical mixing ("key_zdfkpp") 604 !! namzdf_ddm double diffusive mixing parameterization ("key_zdfddm") 605 !! namzdf_tmx tidal mixing parameterization ("key_zdftmx") 606 !!====================================================================== 607 ! 583 608 !----------------------------------------------------------------------- 584 609 &namzdf ! vertical physics … … 590 615 ln_zdfevd = .false. ! enhanced vertical diffusion (evd) (T) or not (F) 591 616 nn_evdm = 1 ! evd apply on tracer (=0) or on tracer and momentum (=1) 592 rn_avevd = 100.! evd mixing coefficient [m2/s]593 ln_zdfnpc = .false. ! Non-Penetrative algorithm (T) or not (F)617 rn_avevd = 100. ! evd mixing coefficient [m2/s] 618 ln_zdfnpc = .false. ! Non-Penetrative Convective algorithm (T) or not (F) 594 619 nn_npc = 1 ! frequency of application of npc 595 620 nn_npcp = 365 ! npc control print frequency … … 605 630 / 606 631 !----------------------------------------------------------------------- 607 608 &namzdf_gls ! Generic length scale model vertical diffusion ("key_zdfgls")609 610 !-----------------------------------------------------------------------611 rn_emin = 1.e-6 ! minimum value of e [m2/s2]612 rn_epsmin = 1.e-12 ! minimum value of eps [m2/s3]613 ln_length_lim = .true. ! limit on the dissipation rate under stable stratification (Galperin et al., 1988)614 ! rn_clim_galp = 0.267 ! galperin limit615 ln_crban = .TRUE. ! Use Craig & Banner (1994) surface wave mixing parametrisation616 ln_sigpsi = .TRUE. ! Activate or not Burchard 2001 mods on psi schmidt number in the wb case617 rn_crban = 100. ! Craig and Banner 1994 constant for wb tke flux618 rn_charn = 100000. ! Charnock constant for wb induced roughness length619 nn_tkebc_surf = 1 ! surface tke condition (0/1=Dir/Neum)620 nn_tkebc_bot = 1 ! bottom tke condition (0/1=Dir/Neum)621 nn_psibc_surf = 1 ! surface psi condition (0/1=Dir/Neum)622 nn_psibc_bot = 1 ! bottom psi condition (0/1=Dir/Neum)623 nn_stab_func = 2 ! stability function (0=Galp, 1= KC94, 2=CanutoA, 3=CanutoB)624 nn_clos = 1 ! predefined closure type (0=MY82, 1=k-eps, 2=k-w, 3=Gen)625 /626 !-----------------------------------------------------------------------627 632 &namzdf_tke ! turbulent eddy kinetic dependent vertical diffusion ("key_zdftke") 628 633 !----------------------------------------------------------------------- 629 rn_ediff = 0. 2! coef. for vertical eddy coef. (avt=rn_ediff*mxl*sqrt(e) )634 rn_ediff = 0.1 ! coef. for vertical eddy coef. (avt=rn_ediff*mxl*sqrt(e) ) 630 635 rn_ediss = 0.7 ! coef. of the Kolmogoroff dissipation 631 rn_ebb = 6 0. ! coef. of the surface input of tke636 rn_ebb = 67.83 ! coef. of the surface input of tke (=67.83 suggested when ln_mxl0=T) 632 637 rn_emin = 1.e-6 ! minimum value of tke [m2/s2] 633 638 rn_emin0 = 1.e-4 ! surface minimum value of tke [m2/s2] 634 rn_bshear = 1.e-20 ! background shear (>0) 635 nn_mxl = 3 ! mixing length: = 0 bounded by the distance to surface and bottom 639 nn_mxl = 2 ! mixing length: = 0 bounded by the distance to surface and bottom 636 640 ! = 1 bounded by the local vertical scale factor 637 641 ! = 2 first vertical derivative of mixing length bounded by 1 638 ! = 3 same criteria as case 2 but applied in a different way 639 ln_mxl0 = .true. ! mixing length scale surface value as function of wind stress (T) or not (F) 642 ! = 3 as =2 with distinct disspipative an mixing length scale 640 643 nn_pdl = 1 ! Prandtl number function of richarson number (=1, avt=pdl(Ri)*avm) or not (=0, avt=avm) 641 ln_lc = .false. ! Langmuir cell parameterisation 644 ln_mxl0 = .true. ! surface mixing length scale = F(wind stress) (T) or not (F) 645 rn_mxl0 = 0.04 ! surface buoyancy lenght scale minimum value 646 ln_lc = .true. ! Langmuir cell parameterisation (Axell 2002) 642 647 rn_lc = 0.15 ! coef. associated to Langmuir cells 643 nn_etau = 1 ! exponentially deceasing penetration of tke due to internal & intertial waves 644 ! = 0 no penetration ( O(2 km) resolution) 645 ! = 1 additional tke source 646 ! = 2 additional tke source applied only at the base of the mixed layer 647 nn_htau = 1 ! type of exponential decrease of tke penetration 648 nn_etau = 1 ! penetration of tke below the mixed layer (ML) due to internal & intertial waves 649 ! = 0 no penetration 650 ! = 1 add a tke source below the ML 651 ! = 2 add a tke source just at the base of the ML 652 ! = 3 as = 1 applied on HF part of the stress ("key_coupled") 653 rn_efr = 0.05 ! fraction of surface tke value which penetrates below the ML (nn_etau=1 or 2) 654 nn_htau = 1 ! type of exponential decrease of tke penetration below the ML 648 655 ! = 0 constant 10 m length scale 649 ! = 1 0.5m at the equator to 30m at high latitudes 650 rn_efr = 0.05 ! fraction of surface tke value which penetrates inside the ocean 656 ! = 1 0.5m at the equator to 30m poleward of 40 degrees 651 657 / 652 658 !------------------------------------------------------------------------ 653 &namzdf_kpp ! K-Profile Parameterization dependent vertical mixing ("key_zdfkpp", and option nally:659 &namzdf_kpp ! K-Profile Parameterization dependent vertical mixing ("key_zdfkpp", and optionally: 654 660 !------------------------------------------------------------------------ "key_kppcustom" or "key_kpplktb") 655 661 ln_kpprimix = .true. ! shear instability mixing … … 664 670 / 665 671 !----------------------------------------------------------------------- 672 &namzdf_gls ! GLS vertical diffusion ("key_zdfgls") 673 !----------------------------------------------------------------------- 674 rn_emin = 1.e-6 ! minimum value of e [m2/s2] 675 rn_epsmin = 1.e-12 ! minimum value of eps [m2/s3] 676 ln_length_lim = .true. ! limit on the dissipation rate under stable stratification (Galperin et al., 1988) 677 rn_clim_galp = 0.53 ! galperin limit 678 ln_crban = .true. ! Use Craig & Banner (1994) surface wave mixing parametrisation 679 ln_sigpsi = .true. ! Activate or not Burchard 2001 mods on psi schmidt number in the wb case 680 rn_crban = 100. ! Craig and Banner 1994 constant for wb tke flux 681 rn_charn = 100000. ! Charnock constant for wb induced roughness length 682 nn_tkebc_surf = 1 ! surface tke condition (0/1/2=Dir/Neum/Dir Mellor-Blumberg) 683 nn_tkebc_bot = 1 ! bottom tke condition (0/1=Dir/Neum) 684 nn_psibc_surf = 1 ! surface psi condition (0/1/2=Dir/Neum/Dir Mellor-Blumberg) 685 nn_psibc_bot = 1 ! bottom psi condition (0/1=Dir/Neum) 686 nn_stab_func = 2 ! stability function (0=Galp, 1= KC94, 2=CanutoA, 3=CanutoB) 687 nn_clos = 1 ! predefined closure type (0=MY82, 1=k-eps, 2=k-w, 3=Gen) 688 / 689 !----------------------------------------------------------------------- 666 690 &namzdf_ddm ! double diffusive mixing parameterization ("key_zdfddm") 667 691 !----------------------------------------------------------------------- … … 679 703 rn_tfe_itf = 1. ! ITF tidal dissipation efficiency 680 704 / 681 !!====================================================================== 682 !! *** Miscelaneous namelists *** 705 706 !!====================================================================== 707 !! *** Miscellaneous namelists *** 683 708 !!====================================================================== 684 709 !! nammpp Massively Parallel Processing ("key_mpp_mpi) 685 !! nammpp_dyndist Massively Parallel domain decomposition ("key_agrif" && "key_mpp_dyndist")686 710 !! namctl Control prints & Benchmark 687 711 !! namsol elliptic solver / island / free surface 688 712 !!====================================================================== 689 713 ! 690 714 !----------------------------------------------------------------------- 691 715 &namsol ! elliptic solver / island / free surface … … 696 720 rn_eps = 1.e-6 ! absolute precision of the solver 697 721 nn_nmin = 300 ! minimum of iterations for the SOR solver 698 nn_nmax = 2800 ! maximum of iterations for the SOR solver722 nn_nmax = 800 ! maximum of iterations for the SOR solver 699 723 nn_nmod = 10 ! frequency of test for the SOR solver 700 724 rn_resmax = 1.e-10 ! absolute precision for the SOR solver … … 704 728 &nammpp ! Massively Parallel Processing ("key_mpp_mpi) 705 729 !----------------------------------------------------------------------- 706 cn_mpi_send = ' S' ! mpi send/recieve type ='S', 'B', or 'I' for standard send,730 cn_mpi_send = 'I' ! mpi send/recieve type ='S', 'B', or 'I' for standard send, 707 731 ! buffer blocking send or immediate non-blocking sends, resp. 708 732 nn_buffer = 0 ! size in bytes of exported buffer ('B' case), 0 no exportation 709 / 710 !----------------------------------------------------------------------- 711 &nammpp_dyndist ! Massively Parallel Distribution for AGRIF zoom ("key_agrif" && "key_mpp_dyndist") 712 !----------------------------------------------------------------------- 713 jpni = 4 ! jpni number of processors following i 714 jpnj = 8 ! jpnj number of processors following j 715 jpnij = 32 ! jpnij number of local domains 733 ln_nnogather= .false. ! activate code to avoid mpi_allgather use at the northfold 734 jpni = 0 ! jpni number of processors following i (set automatically if < 1) 735 jpnj = 0 ! jpnj number of processors following j (set automatically if < 1) 736 jpnij = 0 ! jpnij number of local domains (set automatically if < 1) 716 737 / 717 738 !----------------------------------------------------------------------- 718 739 &namctl ! Control prints & Benchmark 719 740 !----------------------------------------------------------------------- 720 ln_ctl = . true.! trends control print (expensive!)741 ln_ctl = .false. ! trends control print (expensive!) 721 742 nn_print = 0 ! level of print (0 no extra print) 722 743 nn_ictls = 0 ! start i indice of control sum (use to compare mono versus … … 731 752 732 753 !!====================================================================== 733 !! *** Diagnostics namelists *** 734 !!====================================================================== 754 !! *** Diagnostics namelists *** 755 !!====================================================================== 756 !! namnc4 netcdf4 chunking and compression settings ("key_netcdf4") 735 757 !! namtrd dynamics and/or tracer trends ("key_trddyn","key_trdtra","key_trdmld") 736 !! namgap level mean model-data gap ("key_diagap")737 758 !! namflo float parameters ("key_float") 738 759 !! namptr Poleward Transport Diagnostics 739 !!====================================================================== 740 760 !! namhsb Heat and salt budgets 761 !!====================================================================== 762 ! 763 !----------------------------------------------------------------------- 764 &namnc4 ! netcdf4 chunking and compression settings ("key_netcdf4") 765 !----------------------------------------------------------------------- 766 nn_nchunks_i= 4 ! number of chunks in i-dimension 767 nn_nchunks_j= 4 ! number of chunks in j-dimension 768 nn_nchunks_k= 31 ! number of chunks in k-dimension 769 ! setting nn_nchunks_k = jpk will give a chunk size of 1 in the vertical which 770 ! is optimal for postprocessing which works exclusively with horizontal slabs 771 ln_nc4zip = .true. ! (T) use netcdf4 chunking and compression 772 ! (F) ignore chunking information and produce netcdf3-compatible files 773 / 741 774 !----------------------------------------------------------------------- 742 775 &namtrd ! diagnostics on dynamics and/or tracer trends ("key_trddyn" and/or "key_trdtra") 743 ! ! or mixed-layer trends or barotropic vorticity ( 'key_trdmld' or"key_trdvor")776 ! ! or mixed-layer trends or barotropic vorticity ("key_trdmld" or "key_trdvor") 744 777 !----------------------------------------------------------------------- 745 778 nn_trd = 365 ! time step frequency dynamics and tracers trends … … 760 793 &namflo ! float parameters ("key_float") 761 794 !----------------------------------------------------------------------- 762 ln_rstflo= .false. ! float restart (T) or not (F)763 nn_writefl= 75 ! frequency of writing in float output file764 nn_stockfl= 5475 ! frequency of creation of the float restart file765 ln_argo= .false. ! Argo type floats (stay at the surface each 10 days)766 ln_flork4= .false. ! trajectories computed with a 4th order Runge-Kutta (T)795 ln_rstflo = .false. ! float restart (T) or not (F) 796 nn_writefl = 75 ! frequency of writing in float output file 797 nn_stockfl = 5475 ! frequency of creation of the float restart file 798 ln_argo = .false. ! Argo type floats (stay at the surface each 10 days) 799 ln_flork4 = .false. ! trajectories computed with a 4th order Runge-Kutta (T) 767 800 ! or computed with Blanke' scheme (F) 768 801 / … … 774 807 ln_subbas = .false. ! Atlantic/Pacific/Indian basins computation (T) or not 775 808 ! (orca configuration only, need input basins mask file named "subbasins.nc" 776 ! nn_fptr = 15 ! Frequency of ptr computation [time step] 777 ! nn_fwri = 15 ! Frequency of ptr outputs 778 / 779 !----------------------------------------------------------------------- 780 ! nam_asminc assim increment parameters (#ifdef key_asminc) 781 !----------------------------------------------------------------------- 782 ! aincstr Assimilation period start time (s) relative to run start 783 ! aincper Assimilation period length (s) 784 ! mld_choice chooses the mixed layer definition to use in the assimilation 785 ! 1) turbocline depth 2) 0.001 density criteria 3) Kara mixed layer 786 ! ln_trainc Apply tracer incerements when assimilating 787 ! ln_dyninc Apply velocity incerements when assimilating 788 ! ln_sshinc Apply sea surface height incerements when assimilating 789 &nam_asminc 790 aincstr = 0.0 791 aincper = 86400.0 792 mld_choice = 1 793 ln_trainc = .false. 794 ln_dyninc = .false. 795 ln_sshinc = .false. 796 ln_seaiceinc = .false. 797 ln_seaicebal = .true. 798 / 799 !----------------------------------------------------------------------- 800 ! namobs observation operator switch (#ifdef key_diaobs) 801 !----------------------------------------------------------------------- 802 ! ln_ena Logical switch for ENACT insitu data set 803 ! ln_cor Logical switch for Coriolis insitu data set 804 ! ln_t3d Logical switch for T profile observations 805 ! ln_s3d Logical switch for S profile observations 806 ! ln_pto Logical switch for gen profile T obs sfc 807 ! ln_pro Logical switch for gen profile Rho obs sfc 808 ! ln_pts Logical switch for gen profile T spec sfc 809 ! ln_prs Logical switch for gen profile Rho spec sfc 810 ! ln_pzm Logical switch for gen profile Z model lev 811 ! ln_sla Logical switch for SLA observations 812 ! ln_ssh Logical switch for SSH observations 813 ! ln_sst Logical switch for SST observations 814 ! ln_sss Logical switch for SSS observations 815 ! ln_reysst Logical switch for Reynolds SST 816 ! ln_ghrsst Logical switch for GHRSST format SST observations 817 ! enactfiles List of filenames containing profile data in ENACT format 818 ! slafiles List of filenames containing SLA data in CLS format 819 ! sstfiles List of filenames containing SST data in GHRSST format 820 ! dobsini Initial date in window YYYYMMDD.HHMMSS 821 ! dobsend Final date in window YYYYMMDD.HHMMSS 822 ! n1dint Type of vertical interpolation method 823 ! 0 = Linear intepolation. 824 ! 1 = Cubic spline interpolation. 825 ! n2dint Type of horizontal interpolation method 826 ! 0 = Distance-weighted interpolation 827 ! 1 = Distance-weighted interpolation (small angle) 828 ! 2 = Bilinear interpolation (geographical grid) 829 ! 3 = Bilinear remapping interpolation (general grid) 830 ! 4 = Polynomial interpolation 831 ! ln_nea Logical switch to reject observations near land 832 ! nmsshc MSSH correction scheme 833 ! 0 = no correction 834 ! 1 = compute online 835 ! 2 = set to mdtcorr 836 ! mdtcutoff MDT cutoff for computed correction 837 ! mdtcorr MDT correction factor (used if nmsshc = 2) 838 &namobs 839 ln_ena = .false. 840 ln_cor = .false. 841 842 ln_t3d = .false. 843 ln_s3d = .false. 844 ln_sla = .false. 845 ln_ssh = .false. 846 ln_sst = .false. 847 ln_sss = .false. 848 849 enactfiles = 'enact.1.nc' 850 851 slafilesact= 'sla.1.nc' 852 853 seaicefiles = 'seaice.1.nc' 'seaice.2.nc' 854 855 ln_pto = .false. 856 ln_pro = .false. 857 ln_pts = .false. 858 ln_prs = .false. 859 ln_pzm = .false. 860 ln_reysst = .false. 861 ln_ghrsst = .true. 862 ln_seaice = .false. 863 ln_logchl = .false. 864 sstfiles = 'Surface.1.nc' 865 logchlfiles = 'logchl.1.nc' 866 ln_grid_search_lookup = .true. 867 ln_obs_bound_check = .true. 868 ln_altbias = .false. 869 bias_file = 'bias.nc' 870 n1dint = 1 871 n2dint = 3 872 ln_nea = .false. 873 nmsshc = 0 874 mdtcutoff = 65.0 875 mdtcorr = 1.61 876 / 877 !----------------------------------------------------------------------- 878 ! nambias bias parameters (#ifdef key_bias) 879 !----------------------------------------------------------------------- 880 &nam_bias 881 bias_file = 'bias.nc' 882 bias_time_unit = 86400.0 883 ln_obias = .false. 884 ln_bias_ts_app = .false. 885 ln_bias_pc_app = .true. 886 / 887 !----------------------------------------------------------------------- 888 &nammoor 889 path_moor = "./" 890 nmoor = 1 891 nwmoor = 24 892 ln_moor_out = .false. 893 ln_moor_pos = .false. 894 ln_ijproc_moor_read = .false. 895 ln_ijproc_moor_write = .false. 896 / 897 !----------------------------------------------------------------------- 898 ! namdct Namelist for creating transports through sections 899 !----------------------------------------------------------------------- 900 &namdct 901 ndct = 1 ! frequency of summing 902 ndctwri = 24 ! frequency of writing 903 nsecdebug = 0 ! =0; no debugging output i.e. no fort.2?? files written 904 ! =1; transect positions outputted to fort.2?? files 905 ln_verif = .false. ! =false; only first transect output in fort.2?? files 906 ! =true; all transects output in fort 2?? files 907 / 908 !----------------------------------------------------------------------- 909 ! nammht namelist for meridional heat transport diagnostic 910 !----------------------------------------------------------------------- 911 &nammht 912 nmht=1 913 nmhtwri=80 914 / 915 !----------------------------------------------------------------------- 916 ! nammsb 917 !----------------------------------------------------------------------- 918 &namhsb 919 ln_diahsb=false 920 / 809 ln_ptrcomp = .false. ! Add decomposition : overturning 810 nn_fptr = 1 ! Frequency of ptr computation [time step] 811 nn_fwri = 15 ! Frequency of ptr outputs [time step] 812 / 813 !----------------------------------------------------------------------- 814 &namhsb ! Heat and salt budgets 815 !----------------------------------------------------------------------- 816 ln_diahsb = .false. ! check the heat and salt budgets (T) or not (F) 817 / 818 819 !!====================================================================== 820 !! *** Observation & Assimilation namelists *** 821 !!====================================================================== 822 !! namobs observation and model comparison ('key_diaobs') 823 !! nam_asminc assimilation increments ('key_asminc') 824 !!====================================================================== 825 ! 826 !----------------------------------------------------------------------- 827 &namobs ! observation usage switch ('key_diaobs') 828 !----------------------------------------------------------------------- 829 ln_t3d = .false. ! Logical switch for T profile observations 830 ln_s3d = .false. ! Logical switch for S profile observations 831 ln_ena = .false. ! Logical switch for ENACT insitu data set 832 ! ! ln_cor Logical switch for Coriolis insitu data set 833 ln_profb = .false. ! Logical switch for feedback insitu data set 834 ln_sla = .false. ! Logical switch for SLA observations 835 836 ln_sladt = .false. ! Logical switch for AVISO SLA data 837 838 ln_slafb = .false. ! Logical switch for feedback SLA data 839 ! ln_ssh Logical switch for SSH observations 840 841 ln_sst = .false. ! Logical switch for SST observations 842 ! ln_reysst Logical switch for Reynolds observations 843 ! ln_ghrsst Logical switch for GHRSST observations 844 845 ln_sstfb = .false. ! Logical switch for feedback SST data 846 ! ln_sss Logical switch for SSS observations 847 ! ln_seaice Logical switch for Sea Ice observations 848 ! ln_vel3d Logical switch for velocity observations 849 ! ln_velavcur Logical switch for velocity daily av. cur. 850 ! ln_velhrcur Logical switch for velocity high freq. cur. 851 ! ln_velavadcp Logical switch for velocity daily av. ADCP 852 ! ln_velhradcp Logical switch for velocity high freq. ADCP 853 ! ln_velfb Logical switch for feedback velocity data 854 ! ln_grid_global Global distribtion of observations 855 ! ln_grid_search_lookup Logical switch for obs grid search w/lookup table 856 ! grid_search_file Grid search lookup file header 857 ! enactfiles ENACT input observation file names 858 ! coriofiles Coriolis input observation file name 859 ! ! profbfiles: Profile feedback input observation file name 860 profbfiles = 'profiles_01.nc' 861 ! ln_profb_enatim Enact feedback input time setting switch 862 ! slafilesact Active SLA input observation file name 863 ! slafilespas Passive SLA input observation file name 864 ! ! slafbfiles: Feedback SLA input observation file name 865 slafbfiles = 'sla_01.nc' 866 ! sstfiles GHRSST input observation file name 867 ! ! sstfbfiles: Feedback SST input observation file name 868 sstfbfiles = 'sst_01.nc' 'sst_02.nc' 'sst_03.nc' 'sst_04.nc' 'sst_05.nc' 869 ! seaicefiles Sea Ice input observation file name 870 ! velavcurfiles Vel. cur. daily av. input file name 871 ! velhvcurfiles Vel. cur. high freq. input file name 872 ! velavadcpfiles Vel. ADCP daily av. input file name 873 ! velhvadcpfiles Vel. ADCP high freq. input file name 874 ! velfbfiles Vel. feedback input observation file name 875 ! dobsini Initial date in window YYYYMMDD.HHMMSS 876 ! dobsend Final date in window YYYYMMDD.HHMMSS 877 ! n1dint Type of vertical interpolation method 878 ! n2dint Type of horizontal interpolation method 879 ! ln_nea Rejection of observations near land switch 880 nmsshc = 0 ! MSSH correction scheme 881 ! mdtcorr MDT correction 882 ! mdtcutoff MDT cutoff for computed correction 883 ln_altbias = .false. ! Logical switch for alt bias 884 ln_ignmis = .true. ! Logical switch for ignoring missing files 885 ! endailyavtypes ENACT daily average types 886 ln_grid_global = .true. 887 ln_grid_search_lookup = .false. 888 / 889 !----------------------------------------------------------------------- 890 &nam_asminc ! assimilation increments ('key_asminc') 891 !----------------------------------------------------------------------- 892 ln_bkgwri = .false. ! Logical switch for writing out background state 893 ln_trjwri = .false. ! Logical switch for writing out state trajectory 894 ln_trainc = .false. ! Logical switch for applying tracer increments 895 ln_dyninc = .false. ! Logical switch for applying velocity increments 896 ln_sshinc = .false. ! Logical switch for applying SSH increments 897 ln_asmdin = .false. ! Logical switch for Direct Initialization (DI) 898 ln_asmiau = .false. ! Logical switch for Incremental Analysis Updating (IAU) 899 nitbkg = 0 ! Timestep of background in [0,nitend-nit000-1] 900 nitdin = 0 ! Timestep of background for DI in [0,nitend-nit000-1] 901 nitiaustr = 1 ! Timestep of start of IAU interval in [0,nitend-nit000-1] 902 nitiaufin = 15 ! Timestep of end of IAU interval in [0,nitend-nit000-1] 903 niaufn = 0 ! Type of IAU weighting function 904 nittrjfrq = 0 ! Frequency of trajectory output for 4D-VAR 905 ln_salfix = .false. ! Logical switch for ensuring that the sa > salfixmin 906 salfixmin = -9999 ! Minimum salinity after applying the increments 907 / 908 !----------------------------------------------------------------------- 909 &namdyn_nept ! Neptune effect (simplified: lateral and vertical diffusions removed) 910 !----------------------------------------------------------------------- 911 ! Suggested lengthscale values are those of Eby & Holloway (1994) for a coarse model 912 ln_neptsimp = .false. ! yes/no use simplified neptune 913 914 ln_smooth_neptvel = .false. ! yes/no smooth zunep, zvnep 915 rn_tslse = 1.2e4 ! value of lengthscale L at the equator 916 rn_tslsp = 3.0e3 ! value of lengthscale L at the pole 917 ! Specify whether to ramp down the Neptune velocity in shallow 918 ! water, and if so the depth range controlling such ramping down 919 ln_neptramp = .true. ! ramp down Neptune velocity in shallow water 920 rn_htrmin = 100.0 ! min. depth of transition range 921 rn_htrmax = 200.0 ! max. depth of transition range 922 / -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/CONFIG/AMM12_PISCES/EXP00/namelist
r3034 r3108 1 1 !!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> 2 2 !! NEMO/OPA : 1 - run manager (namrun) 3 !! namelists 2 - Domain (namzgr, namzgr_sco, namdom )3 !! namelists 2 - Domain (namzgr, namzgr_sco, namdom, namdta_tem, namdta_sal) 4 4 !! 3 - Surface boundary (namsbc, namsbc_ana, namsbc_flx, namsbc_clio, namsbc_core 5 !! namsbc_cpl, namqsr, namsbc_rnf, namsbc_ssr, namsbc_alb) 5 !! namsbc_cpl, namtra_qsr, namsbc_rnf, 6 !! namsbc_apr, namsbc_ssr, namsbc_alb) 6 7 !! 4 - lateral boundary (namlbc, namcla, namobc, namagrif, nambdy, nambdy_tide) 7 8 !! 5 - bottom boundary (nambfr, nambbc, nambbl) … … 9 10 !! 7 - dynamics (namdyn_adv, namdyn_vor, namdyn_hpg, namdyn_spg, namdyn_ldf) 10 11 !! 8 - Verical physics (namzdf, namzdf_ric, namzdf_tke, namzdf_kpp, namzdf_ddm, namzdf_tmx) 11 !! 9 - diagnostics (namtrd, namgap, namspr, namflo, namptr) 12 !! 9 - miscellaneous (namsol, nammpp, nammpp_dyndist, namctl) 12 !! 9 - diagnostics (namnc4, namtrd, namspr, namflo, namptr, namhsb) 13 !! 10 - miscellaneous (namsol, nammpp, nammpp_dyndist, namctl) 14 !! 11 - Obs & Assim (namobs, nam_asminc) 13 15 !!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> 14 ! CAUTION: some scripts does not support CAPITALs for logical use .true./.false., not .TRUE./.FALSE.15 16 16 17 !!====================================================================== 17 18 !! *** Run management namelists *** 18 19 !!====================================================================== 19 !! namrun 20 !!====================================================================== 21 20 !! namrun parameters of the run 21 !!====================================================================== 22 ! 22 23 !----------------------------------------------------------------------- 23 24 &namrun ! parameters of the run 24 25 !----------------------------------------------------------------------- 25 nn_no = 0 ! job number 26 cn_exp = "amm12" ! experience name 27 cn_ocerst_in = "restart" ! suffix of ocean restart name (input) 28 cn_ocerst_out = "restart" ! suffix of ocean restart name (output) 29 ln_rstart = .true. ! start from rest (F) or from a restart file (T) 30 nn_rstctl = 0 ! restart control = 0 nit000 is not compared to the restart file value 31 ! = 1 use ndate0 in namelist (not the value in the restart file) 32 ! = 2 calendar parameters read in the restart file 33 nn_it000 = 1 ! first time step 34 nn_itend = 5184 ! last time step (std 5475) 35 nn_date0 = 20070101 ! initial calendar date yymmdd (used if nrstdt=1) 36 nn_leapy = 1 ! Leap year calendar (1) or not (0) 37 nn_istate = 0 ! output the initial state (1) or not (0) 38 nn_stock = 5184 ! frequency of creation of a restart file (modulo referenced to 1) 39 nn_write = 12 ! frequency of write in the output file (modulo referenced to nit000) 40 ln_dimgnnn = .false. ! DIMG file format: 1 file for all processors (F) or by processor (T) 41 ln_mskland = .false. ! mask land points in NetCDF outputs (costly: + ~15%) 42 ln_clobber = .false. ! clobber (overwrite) an existing file 43 nn_chunksz = 0 ! chunksize (bytes) for NetCDF file (working only with iom_nf90 routines) 44 / 26 nn_no = 0 ! job number 27 cn_exp = "AMM12" ! experience name 28 nn_it000 = 1 ! first time step 29 nn_itend = 576 ! last time step (std 1 day = 576) 30 nn_date0 = 20070101 ! initial calendar date yymmdd (used if nn_rstctl=1) 31 nn_leapy = 1 ! Leap year calendar (1) or not (0) 32 ln_rstart = .true. ! start from rest (F) or from a restart file (T) 33 nn_rstctl = 0 ! restart control = 0 nn_it000 is not compared to the restart file value 34 ! = 1 use nn_date0 in namelist (not the value in the restart file) 35 ! = 2 calendar parameters read in the restart file 36 cn_ocerst_in = "restart" ! suffix of ocean restart name (input) 37 cn_ocerst_out = "restart" ! suffix of ocean restart name (output) 38 nn_istate = 0 ! output the initial state (1) or not (0) 39 nn_stock = 576 ! frequency of creation of a restart file (modulo referenced to 1) 40 nn_write = 12 ! frequency of write in the output file (modulo referenced to nit000) 41 ln_dimgnnn = .false. ! DIMG file format: 1 file for all processors (F) or by processor (T) 42 ln_mskland = .false. ! mask land points in NetCDF outputs (costly: + ~15%) 43 ln_clobber = .false. ! clobber (overwrite) an existing file 44 nn_chunksz = 0 ! chunksize (bytes) for NetCDF file (works only with iom_nf90 routines) 45 / 46 45 47 !!====================================================================== 46 48 !! *** Domain namelists *** … … 49 51 !! namzgr_sco s-coordinate or hybrid z-s-coordinate 50 52 !! namdom space and time domain (bathymetry, mesh, timestep) 51 !!====================================================================== 52 53 !! namdta_tem data: temperature ("key_dtatem") 54 !! namdta_sal data: salinity ("key_dtasal") 55 !!====================================================================== 56 ! 53 57 !----------------------------------------------------------------------- 54 58 &namzgr ! vertical coordinate … … 73 77 &namdom ! space and time domain (bathymetry, mesh, timestep) 74 78 !----------------------------------------------------------------------- 75 nn_bathy = 1 ! compute (=0) or read (=1) the bathymetry file76 nn_closea = 0 ! closed seas and lakes are removed (=0) or kept (=1) from the ORCA domain77 nn_msh = 3 ! create (=1) a mesh file (coordinates, scale factors, masks)or not (=0)78 rn_hmin = -279 rn_e3zps_min= 5. ! the thickness of the partial step is set larger than the minimum80 rn_e3zps_rat= 0. 3 ! of e3zps_min and e3zps_rat * e3t (N.B. 0<e3zps_rat<1)79 nn_bathy = 1 ! compute (=0) or read (=1) the bathymetry file 80 nn_closea = 0 ! remove (=0) or keep (=1) closed seas and lakes (ORCA) 81 nn_msh = 0 ! create (=1) a mesh file or not (=0) 82 rn_hmin = -3. ! min depth of the ocean (>0) or min number of ocean level (<0) 83 rn_e3zps_min= 20. ! partial step thickness is set larger than the minimum of 84 rn_e3zps_rat= 0.1 ! rn_e3zps_min and rn_e3zps_rat*e3t, with 0<rn_e3zps_rat<1 81 85 ! 82 rn_rdt = 150. ! time step for the dynamics (and tracer if n acc=0) ==> 576083 nn_baro = 30 ! number of barotropic time step (for the split explicit algorithm)("key_dynspg_ts")84 rn_atfp = 0.1! asselin time filter parameter86 rn_rdt = 150. ! time step for the dynamics (and tracer if nn_acc=0) 87 nn_baro = 30 ! number of barotropic time step ("key_dynspg_ts") 88 rn_atfp = 0.1 ! asselin time filter parameter 85 89 nn_acc = 0 ! acceleration of convergence : =1 used, rdt < rdttra(k) 86 90 ! =0, not used, rdt = rdttra 87 rn_rdtmin = 300. ! minimum time step on tracers (used if nacc=1) 88 rn_rdtmax = 300. ! maximum time step on tracers (used if nacc=1) 89 rn_rdth = 300. ! depth variation of tracer time step (used if nacc=1) 90 / 91 rn_rdtmin = 300. ! minimum time step on tracers (used if nn_acc=1) 92 rn_rdtmax = 300. ! maximum time step on tracers (used if nn_acc=1) 93 rn_rdth = 300. ! depth variation of tracer time step (used if nn_acc=1) 94 / 95 !----------------------------------------------------------------------- 96 &namdta_tem ! data : temperature ("key_dtatem") 97 !----------------------------------------------------------------------- 98 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim !'yearly' or ! weights ! rotation ! 99 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 100 sn_tem = 'data_1m_potential_temperature_nomask', -1,'votemper', .true. , .true., 'yearly' , ' ' , ' ' 101 ! 102 cn_dir = './' ! root directory for the location of the runoff files 103 / 104 !----------------------------------------------------------------------- 105 &namdta_sal ! data : salinity ("key_dtasal") 106 !----------------------------------------------------------------------- 107 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim !'yearly' or ! weights ! rotation ! 108 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 109 sn_sal = 'data_1m_salinity_nomask', -1 ,'vosaline', .true. , .true., 'yearly' , '' , ' ' 110 ! 111 cn_dir = './' ! root directory for the location of the runoff files 112 / 113 91 114 !!====================================================================== 92 115 !! *** Surface Boundary Condition namelists *** 93 116 !!====================================================================== 94 !! namsbc surface boundary condition 95 !! namsbc_ana analytical formulation 96 !! namsbc_flx flux formulation 97 !! namsbc_clio CLIO bulk formulea formulation 98 !! namsbc_core CORE bulk formulea formulation 99 !! namsbc_cpl CouPLed formulation ("key_coupled") 100 !! namtra_qsr penetrative solar radiation 101 !! namsbc_rnf river runoffs 102 !! namsbc_ssr sea surface restoring term (for T and/or S) 103 !! namsbc_alb albedo parameters 104 !!====================================================================== 105 117 !! namsbc surface boundary condition 118 !! namsbc_ana analytical formulation 119 !! namsbc_flx flux formulation 120 !! namsbc_clio CLIO bulk formulea formulation 121 !! namsbc_core CORE bulk formulea formulation 122 !! namsbc_cpl CouPLed formulation ("key_coupled") 123 !! namtra_qsr penetrative solar radiation 124 !! namsbc_rnf river runoffs 125 !! namsbc_apr Atmospheric Pressure 126 !! namsbc_ssr sea surface restoring term (for T and/or S) 127 !! namsbc_alb albedo parameters 128 !!====================================================================== 129 ! 106 130 !----------------------------------------------------------------------- 107 131 &namsbc ! Surface Boundary Condition (surface module) 108 132 !----------------------------------------------------------------------- 109 133 nn_fsbc = 1 ! frequency of surface boundary condition computation 110 ! (= the frequency of sea-ice model call)134 ! (also = the frequency of sea-ice model call) 111 135 ln_ana = .false ! analytical formulation (T => fill namsbc_ana ) 112 136 ln_flx = .true. ! flux formulation (T => fill namsbc_flx ) 113 ln_blk_clio = .false. ! CLIO bulk formulation (T => fill namsbc_clio) 114 ln_blk_core = .false. ! CORE bulk formulation (T => fill namsbc_core) 115 ln_cpl = .false. ! Coupled formulation (T => fill namsbc_cpl ) 137 ln_blk_clio = .false. ! CLIO bulk formulation (T => fill namsbc_clio) 138 ln_blk_core = .false. ! CORE bulk formulation (T => fill namsbc_core) 139 ln_cpl = .false. ! Coupled formulation (T => fill namsbc_cpl ) 140 ln_apr_dyn = .false. ! Patm gradient added in ocean & ice Eqs. (T => fill namsbc_apr ) 116 141 nn_ice = 0 ! =0 no ice boundary condition , 117 142 ! =1 use observed ice-cover , 118 ! =2 ice-model used 119 ln_dm2dc = .false. ! daily mean to diurnal cycle short wave (qsr)120 ln_rnf = .true. ! runoffs (T => fill namsbc_rnf)121 ln_ssr = .false. ! Sea Surface Restoring on T and/or S (T => fill namsbc_ssr)122 nn_fwb = 0 ! FreshWater Budget: =0 unchecked 123 ! =1 global mean of e-p-r set to zero at each time step124 ! 125 ! 143 ! =2 ice-model used ("key_lim3" or "key_lim2) 144 ln_dm2dc = .false. ! daily mean to diurnal cycle on short wave 145 ln_rnf = .true. ! runoffs (T => fill namsbc_rnf) 146 ln_ssr = .false. ! Sea Surface Restoring on T and/or S (T => fill namsbc_ssr) 147 nn_fwb = 0 ! FreshWater Budget: =0 unchecked 148 ! =1 global mean of e-p-r set to zero at each time step 149 ! =2 annual global mean of e-p-r set to zero 150 ! =3 global emp set to zero and spread out over erp area 126 151 / 127 152 !----------------------------------------------------------------------- … … 129 154 !----------------------------------------------------------------------- 130 155 nn_tau000 = 0 ! gently increase the stress over the first ntau_rst time-steps 131 rn_utau0 = 1.e0! uniform value for the i-stress132 rn_vtau0 = 1.e0 ! uniform value for the j-stress156 rn_utau0 = 0.5 ! uniform value for the i-stress 157 rn_vtau0 = 0.e0 ! uniform value for the j-stress 133 158 rn_qns0 = 0.e0 ! uniform value for the total heat flux 134 159 rn_qsr0 = 0.e0 ! uniform value for the solar radiation … … 138 163 &namsbc_flx ! surface boundary condition : flux formulation 139 164 !----------------------------------------------------------------------- 140 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation ! 141 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 142 sn_utau = '12km_utau' , 1 , 'utau' , .false. , .false. , 'daily' , '' , '' 143 sn_vtau = '12km_vtau' , 1 , 'vtau' , .false. , .false. , 'daily' , '' , '' 144 sn_qtot = '12km_trunkflx' , 3 , 'sonsfldo' , .true. , .false. , 'daily' , '' , '' 145 sn_qsr = '12km_trunkflx' , 3 , 'soshfldo' , .true. , .false. , 'daily' , '' , '' 146 sn_emp = '12km_trunkflx' , 3 , 'sowafldo' , .true. , .false. , 'daily' , '' , '' 147 ! sn_press = '12km_pressure' , 1 , 'p_msl' , .true. , .false. , 'daily' , '' , '' 165 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 166 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 167 sn_utau = 'amm12_utau' , 1 , 'utau' , .false. , .false. , 'daily' , '' , '' 168 sn_vtau = 'amm12_vtau' , 1 , 'vtau' , .false. , .false. , 'daily' , '' , '' 169 sn_qtot = 'amm12_flx' , 3 , 'sonsfldo' , .true. , .false. , 'daily' , '' , '' 170 sn_qsr = 'amm12_flx' , 3 , 'soshfldo' , .true. , .false. , 'daily' , '' , '' 171 sn_emp = 'amm12_flx' , 3 , 'sowafldo' , .true. , .false. , 'daily' , '' , '' 148 172 cn_dir = './fluxes/' ! root directory for the location of the flux files 149 ! ln_foam_flx = .FALSE. 150 ! ln_shelf_flx = .TRUE. 151 / 173 / 152 174 !----------------------------------------------------------------------- 153 175 &namsbc_clio ! namsbc_clio CLIO bulk formulea 154 176 !----------------------------------------------------------------------- 155 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim! 'yearly'/ ! weights ! rotation !156 ! ! ! (if <0 months) ! name ! (logical) ! (T/F)! 'monthly' ! filename ! pairing !157 sn_utau = 'taux_1m' , -1 , 'sozotaux' , .true. , .true., 'yearly' , '' , ''158 sn_vtau = 'tauy_1m' , -1 , 'sometauy' , .true. , .true., 'yearly' , '' , ''159 sn_wndm = 'flx' , -1 , 'socliowi' , .true. , .true., 'yearly' , '' , ''160 sn_tair = 'flx' , -1 , 'socliot2' , .true. , .true., 'yearly' , '' , ''161 sn_humi = 'flx' , -1 , 'socliohu' , .true. , .true., 'yearly' , '' , ''162 sn_ccov = 'flx' , -1 , 'socliocl' , .false. , .true., 'yearly' , '' , ''163 sn_prec = 'flx' , -1 , 'socliopl' , .false. , .true., 'yearly' , '' , ''164 ! 177 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 178 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 179 sn_utau = 'taux_1m' , -1 , 'sozotaux', .true. , .true. , 'yearly' , '' , '' 180 sn_vtau = 'tauy_1m' , -1 , 'sometauy', .true. , .true. , 'yearly' , '' , '' 181 sn_wndm = 'flx' , -1 , 'socliowi', .true. , .true. , 'yearly' , '' , '' 182 sn_tair = 'flx' , -1 , 'socliot2', .true. , .true. , 'yearly' , '' , '' 183 sn_humi = 'flx' , -1 , 'socliohu', .true. , .true. , 'yearly' , '' , '' 184 sn_ccov = 'flx' , -1 , 'socliocl', .false. , .true. , 'yearly' , '' , '' 185 sn_prec = 'flx' , -1 , 'socliopl', .false. , .true. , 'yearly' , '' , '' 186 165 187 cn_dir = './' ! root directory for the location of the bulk files are 166 188 / … … 168 190 &namsbc_core ! namsbc_core CORE bulk formulea 169 191 !----------------------------------------------------------------------- 170 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation ! 171 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 172 sn_wndi = 'u10_core' , -1 , 'u10' , .true. , .true. , 'yearly' ,'bicubic_weights_orca2.nc' , 'U1' 173 sn_wndj = 'v10_core' , -1 , 'v10' , .true. , .true. , 'yearly' ,'bicubic_weights_orca2.nc' , 'V1' 174 sn_qsr = 'qsw_core' , -1 , 'swdn' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 175 sn_qlw = 'qlw_core' , -1 , 'lwdn' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 176 sn_tair = 't2_core' , -1 , 't2' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 177 sn_humi = 'q2_core' , -1 , 'q2' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 178 sn_prec = 'precip_core', -1 , 'precip' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 179 sn_snow = 'snow_core' , -1 , 'snow' , .true. , .true. , 'yearly' ,'bilinear_weights_orca2.nc', '' 180 ! 192 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 193 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 194 sn_wndi = 'u_10.15JUNE2009_orca2' , 6 , 'U_10_MOD', .false. , .true. , 'yearly' , '' , 'Uwnd' 195 sn_wndj = 'v_10.15JUNE2009_orca2' , 6 , 'V_10_MOD', .false. , .true. , 'yearly' , '' , 'Vwnd' 196 sn_qsr = 'ncar_rad.15JUNE2009_orca2' , 24 , 'SWDN_MOD', .false. , .true. , 'yearly' , '' , '' 197 sn_qlw = 'ncar_rad.15JUNE2009_orca2' , 24 , 'LWDN_MOD', .false. , .true. , 'yearly' , '' , '' 198 sn_tair = 't_10.15JUNE2009_orca2' , 6 , 'T_10_MOD', .false. , .true. , 'yearly' , '' , '' 199 sn_humi = 'q_10.15JUNE2009_orca2' , 6 , 'Q_10_MOD', .false. , .true. , 'yearly' , '' , '' 200 sn_prec = 'ncar_precip.15JUNE2009_orca2', -1 , 'PRC_MOD1', .false. , .true. , 'yearly' , '' , '' 201 sn_snow = 'ncar_precip.15JUNE2009_orca2', -1 , 'SNOW' , .false. , .true. , 'yearly' , '' , '' 202 sn_tdif = 'taudif_core' , 24 , 'taudif' , .false. , .true. , 'yearly' , '' , '' 203 181 204 cn_dir = './' ! root directory for the location of the bulk files 182 ln_2m = .true. ! air temperature and humidity referenced at 2m (T) instead 10m (F) 205 ln_2m = .false. ! air temperature and humidity referenced at 2m (T) instead 10m (F) 206 ln_taudif = .false. ! HF tau contribution: use "mean of stress module - module of the mean stress" data 183 207 rn_pfac = 1. ! multiplicative factor for precipitation (total & snow) 184 208 / 185 209 !----------------------------------------------------------------------- 186 &namsbc_cpl ! coupled ocean/atmosphere model ("key_coupled") 187 !----------------------------------------------------------------------- 188 ! send 189 cn_snd_temperature= 'weighted oce and ice' ! 'oce only' 'weighted oce and ice' 'mixed oce-ice' 190 cn_snd_albedo = 'weighted ice' ! 'none' 'weighted ice' 'mixed oce-ice' 191 cn_snd_thickness = 'none' ! 'none' 'weighted ice and snow' 192 cn_snd_crt_nature = 'none' ! 'none' 'oce only' 'weighted oce and ice' 'mixed oce-ice' 193 cn_snd_crt_refere = 'spherical' ! 'spherical' 'cartesian' 194 cn_snd_crt_orient = 'eastward-northward' ! 'eastward-northward' or 'local grid' 195 cn_snd_crt_grid = 'T' ! 'T' 196 ! receive 197 cn_rcv_w10m = 'coupled' ! 'none' 'coupled' 198 cn_rcv_tau_nature = 'oce only' ! 'oce only' 'oce and ice' 'mixed oce-ice' 199 cn_rcv_tau_refere = 'cartesian' ! 'spherical' 'cartesian' 200 cn_rcv_tau_orient = 'eastward-northward' ! 'eastward-northward' or 'local grid' 201 cn_rcv_tau_grid = 'U,V' ! 'T' 'U,V' 'U,V,F' 'U,V,I' 'T,F' 'T,I' 'T,U,V' 202 cn_rcv_dqnsdt = 'coupled' ! 'none' 'coupled' 203 cn_rcv_qsr = 'oce and ice' ! 'conservative' 'oce and ice' 'mixed oce-ice' 204 cn_rcv_qns = 'oce and ice' ! 'conservative' 'oce and ice' 'mixed oce-ice' 205 cn_rcv_emp = 'conservative' ! 'conservative' 'oce and ice' 'mixed oce-ice' 206 cn_rcv_rnf = 'coupled' ! 'coupled' 'climato' 'mixed' 207 cn_rcv_cal = 'coupled' ! 'none' 'coupled' 208 / 209 !----------------------------------------------------------------------- 210 &namsbc_cpl_co2 ! coupled ocean/biogeo/atmosphere model ("key_cpl_carbon_cycle") 211 !----------------------------------------------------------------------- 212 cn_snd_co2 = 'coupled' ! send : 'none' 'coupled' 213 cn_rcv_co2 = 'coupled' ! receive : 'none' 'coupled' 210 &namsbc_cpl ! coupled ocean/atmosphere model ("key_coupled") 211 !----------------------------------------------------------------------- 212 ! ! description ! multiple ! vector ! vector ! vector ! 213 ! ! ! categories ! reference ! orientation ! grids ! 214 ! send 215 sn_snd_temp = 'weighted oce and ice' , 'no' , '' , '' , '' 216 sn_snd_alb = 'weighted ice' , 'no' , '' , '' , '' 217 sn_snd_thick = 'none' , 'no' , '' , '' , '' 218 sn_snd_crt = 'none' , 'no' , 'spherical' , 'eastward-northward' , 'T' 219 sn_snd_co2 = 'coupled' , 'no' , '' , '' , '' 220 ! receive 221 sn_rcv_w10m = 'none' , 'no' , '' , '' , '' 222 sn_rcv_taumod = 'coupled' , 'no' , '' , '' , '' 223 sn_rcv_tau = 'oce only' , 'no' , 'cartesian' , 'eastward-northward', 'U,V' 224 sn_rcv_dqnsdt = 'coupled' , 'no' , '' , '' , '' 225 sn_rcv_qsr = 'oce and ice' , 'no' , '' , '' , '' 226 sn_rcv_qns = 'oce and ice' , 'no' , '' , '' , '' 227 sn_rcv_emp = 'conservative' , 'no' , '' , '' , '' 228 sn_rcv_rnf = 'coupled' , 'no' , '' , '' , '' 229 sn_rcv_cal = 'coupled' , 'no' , '' , '' , '' 230 sn_rcv_co2 = 'coupled' , 'no' , '' , '' , '' 214 231 / 215 232 !----------------------------------------------------------------------- 216 233 &namtra_qsr ! penetrative solar radiation 217 234 !----------------------------------------------------------------------- 218 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ !weights ! rotation !219 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' !filename ! pairing !220 sn_chl = 'chlorophyll', -1 , 'CHLA' , .true. , .true. , 'yearly' ,'' , ''221 235 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 236 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 237 sn_chl ='chlorophyll', -1 , 'CHLA' , .true. , .true. , 'yearly' , '' , '' 238 222 239 cn_dir = './' ! root directory for the location of the runoff files 223 240 ln_traqsr = .false. ! Light penetration (T) or not (F) … … 229 246 rn_si0 = 0.35 ! RGB & 2 bands: shortess depth of extinction 230 247 rn_si1 = 23.0 ! 2 bands: longest depth of extinction 231 ! rn_si2 = 62.0 ! 3 bands: longest depth of extinction (for blue waveband & 0.01 mg/m2 Chl)232 /233 !----------------------------------------------------------------------------------234 &namtra_dwl ! POLCOMS Style Downwell radiation for Short wave radiation235 !----------------------------------------------------------------------------------236 ln_tradwl = .true. ! Light penetration (T) or not (F)237 ln_vary_lambda = .true. ! Vary Lambda or not (T) or not (F)238 248 / 239 249 !----------------------------------------------------------------------- 240 250 &namsbc_rnf ! runoffs namelist surface boundary condition 241 251 !----------------------------------------------------------------------- 242 cn_dir = './' ! root directory for the location of the runoff files 243 ln_rnf_emp = .false. ! runoffs included into precipitation field (T) or into a file (F) 244 ln_rnf_depth = .true. 245 ln_rnf_tem = .true. 246 ln_rnf_sal = .true. 247 ! ! file name ! frequency(hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! check ! weights ! rotation ! 248 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! (T/F) ! filename ! pairing ! 249 sn_rnf = 'AMM_rivers' , 24 , 'rorunoff' , .false. , .true. , 'yearly' 250 sn_cnf = 'runoff_1m_nomask' , 0 , 'socoefr' , .false. , .true. , 'yearly' 251 sn_s_rnf = 'AMM_rivers' , 24 , 'rosaline' , .false. , .true. , 'yearly' 252 sn_t_rnf = 'AMM_rivers' , 24 , 'rotemper' , .false. , .true. , 'yearly' 253 sn_dep_rnf = 'AMM_rivers' , 24 , 'rodepth' , .false. , .true. , 'yearly' 254 ln_rnf_mouth = .false. ! specific treatment at rivers mouths 255 rn_hrnf = 1000.e0 ! depth over which enhanced vertical mixing is used 256 rn_avt_rnf = 10.e0 ! value of the additional vertical mixing coef. [m2/s] 257 rn_rfact = 1.e0 ! multiplicative factor for runoff 252 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 253 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 254 sn_rnf = 'amm12_rivers' , 24 , 'rorunoff', .false. , .true. , 'yearly' , '' , '' 255 sn_cnf = 'runoff_1m_nomask' , 0 , 'socoefr0', .false. , .true. , 'yearly' , '' , '' 256 sn_s_rnf = 'amm12_rivers' , 24 , 'rosaline', .false. , .true. , 'yearly' , '' , '' 257 sn_t_rnf = 'amm12_rivers' , 24 , 'rotemper', .false. , .true. , 'yearly' , '' , '' 258 sn_dep_rnf = 'amm12_rivers' , 24 , 'rodepth' , .false. , .true. , 'yearly' , '' , '' 259 260 cn_dir = './' ! root directory for the location of the runoff files 261 ln_rnf_emp = .false. ! runoffs included into precipitation field (T) or into a file (F) 262 ln_rnf_mouth = .false. ! specific treatment at rivers mouths 263 rn_hrnf = 15.e0 ! depth over which enhanced vertical mixing is used 264 rn_avt_rnf = 1.e-3 ! value of the additional vertical mixing coef. [m2/s] 265 rn_rfact = 1.e0 ! multiplicative factor for runoff 266 ln_rnf_depth = .true. ! read in depth information for runoff 267 ln_rnf_tem = .true. ! read in temperature information for runoff 268 ln_rnf_sal = .true. ! read in salinity information for runoff 269 / 270 !----------------------------------------------------------------------- 271 &namsbc_apr ! Atmospheric pressure used as ocean forcing or in bulk 272 !----------------------------------------------------------------------- 273 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation ! 274 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 275 sn_apr = 'patm' , -1 ,'somslpre', .true. , .true. , 'yearly' , '' , '' 276 277 cn_dir = './' ! root directory for the location of the bulk files 278 ln_ref_apr = .false. ! ref. pressure: global mean Patm (T) or a constant (F) 258 279 / 259 280 !----------------------------------------------------------------------- 260 281 &namsbc_ssr ! surface boundary condition : sea surface restoring 261 282 !----------------------------------------------------------------------- 262 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! check! weights ! rotation !263 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! (T/F)! filename ! pairing !264 sn_sst = ' references_amm', 24 , 'sst' , .true. , .false. , 'daily' , .false. , '' , ''283 ! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! 284 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 285 sn_sst = 'amm12_sstref' , 24 , 'sst' , .true. , .false. , 'daily' , .false. , '' , '' 265 286 sn_sss = 'sss_data' , -1 , 'sss' , .true. , .true. , 'yearly' , .false. , '' , '' 266 287 267 288 cn_dir = 'fluxes/' ! root directory for the location of the runoff files 268 289 nn_sstr = 1 ! add a retroaction term in the surface heat flux (=1) or not (=0) … … 270 291 ! or to SSS only (=1) or no damping term (=0) 271 292 rn_dqdt = -40. ! magnitude of the retroaction on temperature [W/m2/K] 272 rn_deds = -27.7 ! magnitude of the damping on salinity [mm/day /psu]293 rn_deds = -27.7 ! magnitude of the damping on salinity [mm/day] 273 294 ln_sssr_bnd = .false. ! flag to bound erp term (associated with nn_sssr=2) 274 295 rn_sssr_bnd = 4.e0 ! ABS(Max/Min) value of the damping erp term [mm/day] 275 ln_UKMO_haney = .true. ! correct non-solar heat flux using Haney Correction.276 296 / 277 297 !----------------------------------------------------------------------- … … 295 315 !! namtide Tidal forcing at open boundaries ("key_bdy_tides") 296 316 !!====================================================================== 297 317 ! 298 318 !----------------------------------------------------------------------- 299 319 &namlbc ! lateral momentum boundary condition … … 310 330 &namobc ! open boundaries parameters ("key_obc") 311 331 !----------------------------------------------------------------------- 312 ln_obc_clim= .true.! climatological obc data files (T) or not (F)313 ln_vol_cst = .false.! impose the total volume conservation (T) or not (F)314 ln_obc_fla= .false. ! Flather open boundary condition315 nn_obcdta = 0! = 0 the obc data are equal to the initial state332 ln_obc_clim = .false. ! climatological obc data files (T) or not (F) 333 ln_vol_cst = .true. ! impose the total volume conservation (T) or not (F) 334 ln_obc_fla = .false. ! Flather open boundary condition 335 nn_obcdta = 1 ! = 0 the obc data are equal to the initial state 316 336 ! = 1 the obc data are read in 'obc.dta' files 317 cn_obcdta= 'annual' ! set to annual if obc datafile hold 1 year of data337 cn_obcdta = 'annual' ! set to annual if obc datafile hold 1 year of data 318 338 ! set to monthly if obc datafile hold 1 month of data 319 rn_dpein= 1. ! damping time scale for inflow at east open boundary320 rn_dpwin= 1. ! - - - west - -321 rn_dpnin = 30. ! - - - north - -322 rn_dpsin= 1. ! - - - south - -323 rn_dpeob = 1500. ! time relaxation (days) for the east open boundary324 rn_dpwob= 15. ! - - - west - -325 rn_dpnob = 150. ! - - - north - -326 rn_dpsob= 15. ! - - - south - -327 rn_volemp = 0. ! = 0 the total volume change with the surface flux (E-P-R)339 rn_dpein = 1. ! damping time scale for inflow at east open boundary 340 rn_dpwin = 1. ! - - - west - - 341 rn_dpnin = 1. ! - - - north - - 342 rn_dpsin = 1. ! - - - south - - 343 rn_dpeob = 3000. ! time relaxation (days) for the east open boundary 344 rn_dpwob = 15. ! - - - west - - 345 rn_dpnob = 3000. ! - - - north - - 346 rn_dpsob = 15. ! - - - south - - 347 rn_volemp = 1. ! = 0 the total volume change with the surface flux (E-P-R) 328 348 ! = 1 the total volume remains constant 329 349 / … … 331 351 &namagrif ! AGRIF zoom ("key_agrif") 332 352 !----------------------------------------------------------------------- 333 nn_cln_update = 3! baroclinic update frequency334 ln_spc_dyn = .true.! use 0 as special value for dynamics335 rn_sponge_tra = 2880. ! coefficient for tracer sponge layer [s]336 rn_sponge_dyn = 2880. ! coefficient for dynamics sponge layer [s]353 nn_cln_update = 3 ! baroclinic update frequency 354 ln_spc_dyn = .true. ! use 0 as special value for dynamics 355 rn_sponge_tra = 2880. ! coefficient for tracer sponge layer [m2/s] 356 rn_sponge_dyn = 2880. ! coefficient for dynamics sponge layer [m2/s] 337 357 / 338 358 !----------------------------------------------------------------------- 339 359 &nambdy ! unstructured open boundaries ("key_bdy") 340 360 !----------------------------------------------------------------------- 341 cn_mask = 'mask_amm_bdyT.nc' ! name of mask file (if ln_bdy_mask=.TRUE.) 342 cn_dta_frs_T = 'bdydata_grid_T.nc' ! name of data file (T-points) 343 cn_dta_frs_U = 'bdydata_grid_U.nc' ! name of data file (U-points) 344 cn_dta_frs_V = 'bdydata_grid_V.nc' ! name of data file (V-points) 345 cn_dta_fla_T = 'bdydata_bt_grid_T.nc' ! name of data file (T-points) 346 cn_dta_fla_U = 'bdydata_bt_grid_U.nc' ! name of data file (U-points) 347 cn_dta_fla_V = 'bdydata_bt_grid_V.nc' ! name of data file (V-points) 348 ln_tides = .true. ! Apply tidal harmonic forcing with Flather condition 349 ln_clim = .false. ! contain 1 (T) or 12 (F) time dumps and be cyclic 350 ln_vol = .true. ! total volume correction (see volbdy parameter) 351 ln_mask = .false. ! boundary mask from filbdy_mask (T) or boundaries are on edges of domain (F) 352 ln_dyn_fla = .true. ! Apply Flather condition to velocities 353 ln_dyn_frs = .false. ! Apply FRS condition to velocities 354 ln_tra_frs = .true. ! Apply FRS condition to temperature and salinity 355 nn_dtactl = 1 ! = 0, bdy data are equal to the initial state 361 nb_bdy = 1 ! number of open boundary sets 362 ln_coords_file = .true. ! =T : read bdy coordinates from file 363 cn_coords_file = 'coordinates.bdy.nc' ! bdy coordinates files 364 ln_mask_file = .false. ! =T : read mask from file 365 cn_mask_file = '' ! name of mask file (if ln_mask_file=.TRUE.) 366 nn_dyn2d = 2 ! boundary conditions for barotropic fields 367 nn_dyn2d_dta = 3 ! = 0, bdy data are equal to the initial state 356 368 ! = 1, bdy data are read in 'bdydata .nc' files 357 nn_rimwidth = 10 ! width of the relaxation zone 358 nn_volctl = 1 ! = 0, the total water flux across open boundaries is zero 359 ! = 1, the total volume of the system is conserved 360 / 361 !----------------------------------------------------------------------- 362 &nambdy_tide ! tidal forcing at unstructured boundaries 363 !----------------------------------------------------------------------- 364 filtide = 'AMM_bdytide_' ! file name root of tidal forcing files 365 tide_cpt(1) ='Q1' ! names of tidal components used 366 tide_cpt(2) ='O1' ! names of tidal components used 367 tide_cpt(3) ='P1' ! names of tidal components used 368 tide_cpt(4) ='S1' ! names of tidal components used 369 tide_cpt(5) ='K1' ! names of tidal components used 370 tide_cpt(6) ='2N2' ! names of tidal components used 371 tide_cpt(7) ='MU2' ! names of tidal components used 372 tide_cpt(8) ='N2' ! names of tidal components used 373 tide_cpt(9) ='NU2' ! names of tidal components used 374 tide_cpt(10) ='M2' ! names of tidal components used 375 tide_cpt(11) ='L2' ! names of tidal components used 376 tide_cpt(12) ='T2' ! names of tidal components used 377 tide_cpt(13) ='S2' ! names of tidal components used 378 tide_cpt(14) ='K2' ! names of tidal components used 379 tide_cpt(15) ='M4' ! names of tidal components used 380 tide_speed(1) = 13.398661 ! phase speeds of tidal components (deg/hour) 381 tide_speed(2) = 13.943036 ! phase speeds of tidal components (deg/hour) 382 tide_speed(3) = 14.958932 ! phase speeds of tidal components (deg/hour) 383 tide_speed(4) = 15.000001 ! phase speeds of tidal components (deg/hour) 384 tide_speed(5) = 15.041069 ! phase speeds of tidal components (deg/hour) 385 tide_speed(6) = 27.895355 ! phase speeds of tidal components (deg/hour) 386 tide_speed(7) = 27.968210 ! phase speeds of tidal components (deg/hour) 387 tide_speed(8) = 28.439730 ! phase speeds of tidal components (deg/hour) 388 tide_speed(9) = 28.512585 ! phase speeds of tidal components (deg/hour) 389 tide_speed(10) = 28.984106 ! phase speeds of tidal components (deg/hour) 390 tide_speed(11) = 29.528479 ! phase speeds of tidal components (deg/hour) 391 tide_speed(12) = 29.958935 ! phase speeds of tidal components (deg/hour) 392 tide_speed(13) = 30.000002 ! phase speeds of tidal components (deg/hour) 393 tide_speed(14) = 30.082138 ! phase speeds of tidal components (deg/hour) 394 tide_speed(15) = 57.968212 ! phase speeds of tidal components (deg/hour) 395 ln_tide_date = .true. ! adjust tidal harmonics for start date of run 396 ! ln_tide_czbar = .true. ! Apply Equil. Tide 397 ! ln_harm_ana = .true. ! Use Harmonic Analyzer 398 / 369 ! = 2, use tidal harmonic forcing data from files 370 ! = 3, use external data AND tidal harmonic forcing 371 nn_dyn3d = 0 ! boundary conditions for baroclinic velocities 372 nn_dyn3d_dta = 0 ! = 0, bdy data are equal to the initial state 373 ! = 1, bdy data are read in 'bdydata .nc' files 374 nn_tra = 1 ! boundary conditions for T and S 375 nn_tra_dta = 1 ! = 0, bdy data are equal to the initial state 376 ! = 1, bdy data are read in 'bdydata .nc' files 377 nn_rimwidth = 10 ! width of the relaxation zone 378 nn_dmp2d_in = 0 ! 379 nn_dmp2d_out = 0 ! 380 nn_dmp2d_in = 0 ! 381 nn_dmp2d_out = 0 ! 382 ln_vol = .false. ! total volume correction (see nn_volctl parameter) 383 nn_volctl = 1 ! = 0, the total water flux across open boundaries is zero 384 / 385 !----------------------------------------------------------------------- 386 &nambdy_dta ! open boundaries - external data ("key_bdy") 387 !----------------------------------------------------------------------- 388 ! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation ! 389 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! 390 bn_ssh = 'amm12_bdyT_u2d_1d' , 24 , 'sossheig' , .true. , .false. , 'daily' , '' , '' 391 bn_u2d = 'amm12_bdyU_u2d_1d' , 24 , 'vobtcrtx' , .true. , .false. , 'daily' , '' , '' 392 bn_v2d = 'amm12_bdyV_u2d_1d' , 24 , 'vobtcrty' , .true. , .false. , 'daily' , '' , '' 393 bn_u3d = 'amm12_bdyU_u3d_1d' , 24 , 'vozocrtx' , .true. , .false. , 'daily' , '' , '' 394 bn_v3d = 'amm12_bdyV_u3d_1d' , 24 , 'vomecrty' , .true. , .false. , 'daily' , '' , '' 395 bn_tem = 'amm12_bdyT_tra_1d' , 24 , 'votemper' , .true. , .false. , 'daily' , '' , '' 396 bn_sal = 'amm12_bdyT_tra_1d' , 24 , 'vosaline' , .true. , .false. , 'daily' , '' , '' 397 cn_dir = 'bdydta/' 398 ln_full_vel = .false. 399 / 400 !----------------------------------------------------------------------- 401 &nambdy_tide ! tidal forcing at open boundaries 402 !----------------------------------------------------------------------- 403 filtide = 'amm12_bdytide_' ! file name root of tidal forcing files 404 tide_cpt(1) ='Q1' ! names of tidal components used 405 tide_cpt(2) ='O1' ! names of tidal components used 406 tide_cpt(3) ='P1' ! names of tidal components used 407 tide_cpt(4) ='S1' ! names of tidal components used 408 tide_cpt(5) ='K1' ! names of tidal components used 409 tide_cpt(6) ='2N2' ! names of tidal components used 410 tide_cpt(7) ='MU2' ! names of tidal components used 411 tide_cpt(8) ='N2' ! names of tidal components used 412 tide_cpt(9) ='NU2' ! names of tidal components used 413 tide_cpt(10) ='M2' ! names of tidal components used 414 tide_cpt(11) ='L2' ! names of tidal components used 415 tide_cpt(12) ='T2' ! names of tidal components used 416 tide_cpt(13) ='S2' ! names of tidal components used 417 tide_cpt(14) ='K2' ! names of tidal components used 418 tide_cpt(15) ='M4' ! names of tidal components used 419 tide_speed(1) = 13.398661 ! phase speeds of tidal components (deg/hour) 420 tide_speed(2) = 13.943036 ! phase speeds of tidal components (deg/hour) 421 tide_speed(3) = 14.958932 ! phase speeds of tidal components (deg/hour) 422 tide_speed(4) = 15.000001 ! phase speeds of tidal components (deg/hour) 423 tide_speed(5) = 15.041069 ! phase speeds of tidal components (deg/hour) 424 tide_speed(6) = 27.895355 ! phase speeds of tidal components (deg/hour) 425 tide_speed(7) = 27.968210 ! phase speeds of tidal components (deg/hour) 426 tide_speed(8) = 28.439730 ! phase speeds of tidal components (deg/hour) 427 tide_speed(9) = 28.512585 ! phase speeds of tidal components (deg/hour) 428 tide_speed(10) = 28.984106 ! phase speeds of tidal components (deg/hour) 429 tide_speed(11) = 29.528479 ! phase speeds of tidal components (deg/hour) 430 tide_speed(12) = 29.958935 ! phase speeds of tidal components (deg/hour) 431 tide_speed(13) = 30.000002 ! phase speeds of tidal components (deg/hour) 432 tide_speed(14) = 30.082138 ! phase speeds of tidal components (deg/hour) 433 tide_speed(15) = 57.968212 ! phase speeds of tidal components (deg/hour) 434 ln_tide_date = .true. ! adjust tidal harmonics for start date of run 435 / 436 399 437 !!====================================================================== 400 438 !! *** Bottom boundary condition *** 401 439 !!====================================================================== 402 440 !! nambfr bottom friction 403 !! nambbc bottom temperature boundary condition ("key_trabbc")404 !! nambbl bottom boundary layer scheme ("key_trabbl _dif","key_trabbl_adv")405 !!====================================================================== 406 441 !! nambbc bottom temperature boundary condition 442 !! nambbl bottom boundary layer scheme ("key_trabbl") 443 !!====================================================================== 444 ! 407 445 !----------------------------------------------------------------------- 408 446 &nambfr ! bottom friction 409 447 !----------------------------------------------------------------------- 410 nn_bfr = 2 ! type of bottom friction : = 0 : no slip, = 2 : nonlinear friction411 ! = 3 : free slip, = 1 :linear friction448 nn_bfr = 2 ! type of bottom friction : = 0 : free slip, = 1 : linear friction 449 ! = 2 : nonlinear friction 412 450 rn_bfri1 = 4.e-4 ! bottom drag coefficient (linear case) 413 451 rn_bfri2 = 2.5e-3 ! bottom drag coefficient (non linear case) 414 rn_bfeb2 = 0.0 ! bottom turbulent kinetic energy background (m^2/s^2) 452 rn_bfeb2 = 0.0e0 ! bottom turbulent kinetic energy background (m2/s2) 453 ln_bfr2d = .false. ! horizontal variation of the bottom friction coef (read a 2D mask file ) 454 rn_bfrien = 50. ! local multiplying factor of bfr (ln_bfr2d=T) 455 ln_bfrimp = .true. ! implicit bottom friction (requires ln_zdfexp = .false. if true) 415 456 / 416 457 !----------------------------------------------------------------------- 417 458 &nambbc ! bottom temperature boundary condition 418 459 !----------------------------------------------------------------------- 419 nn_geoflx = 0 ! geothermal heat flux: = 0 no flux 460 ln_trabbc = .true. ! Apply a geothermal heating at the ocean bottom 461 nn_geoflx = 2 ! geothermal heat flux: = 0 no flux 420 462 ! = 1 constant flux 421 463 ! = 2 variable flux (read in geothermal_heating.nc in mW/m2) … … 425 467 &nambbl ! bottom boundary layer scheme 426 468 !----------------------------------------------------------------------- 427 ! ! diffusive bbl ("key_trabbl") 428 ! ! advective bbl ("key_trabbl_adv") 429 rn_ahtbbl = 0. ! lateral mixing coefficient in the bbl [m2/s] 430 / 469 nn_bbl_ldf = 0 ! diffusive bbl (=1) or not (=0) 470 nn_bbl_adv = 0 ! advective bbl (=1/2) or not (=0) 471 rn_ahtbbl = 1000. ! lateral mixing coefficient in the bbl [m2/s] 472 rn_gambbl = 10. ! advective bbl coefficient [s] 473 / 474 431 475 !!====================================================================== 432 476 !! Tracer (T & S ) namelists … … 437 481 !! namtra_dmp T & S newtonian damping ("key_tradmp") 438 482 !!====================================================================== 439 483 ! 440 484 !----------------------------------------------------------------------- 441 485 &nameos ! ocean physical parameters 442 486 !----------------------------------------------------------------------- 443 nn_eos = 0! type of equation of state and Brunt-Vaisala frequency487 nn_eos = 0 ! type of equation of state and Brunt-Vaisala frequency 444 488 ! = 0, UNESCO (formulation of Jackett and McDougall (1994) and of McDougall (1987) ) 445 489 ! = 1, linear: rho(T) = rau0 * ( 1.028 - ralpha * T ) 446 490 ! = 2, linear: rho(T,S) = rau0 * ( rbeta * S - ralpha * T ) 447 rn_alpha = 2.e-4 ! thermal expension coefficient (neos= 1 or 2)448 rn_beta = 0.001 ! saline expension coefficient (neos= 2)491 rn_alpha = 2.0e-4 ! thermal expension coefficient (nn_eos= 1 or 2) 492 rn_beta = 7.7e-4 ! saline expension coefficient (nn_eos= 2) 449 493 / 450 494 !----------------------------------------------------------------------- … … 452 496 !----------------------------------------------------------------------- 453 497 ln_traadv_cen2 = .false. ! 2nd order centered scheme 454 ln_traadv_tvd = .true. ! TVD scheme498 ln_traadv_tvd = .true. ! TVD scheme 455 499 ln_traadv_muscl = .false. ! MUSCL scheme 456 500 ln_traadv_muscl2 = .false. ! MUSCL2 scheme + cen2 at boundaries 457 ln_traadv_ubs = .false. 458 ! ln_traadv_ppm = .false. ! PPMscheme501 ln_traadv_ubs = .false. ! UBS scheme 502 ln_traadv_qck = .false. ! QUICKEST scheme 459 503 / 460 504 !----------------------------------------------------------------------- 461 505 &namtra_ldf ! lateral diffusion scheme for tracer 462 506 !----------------------------------------------------------------------- 463 464 ln_traldf_lap = .true. ! 465 ln_traldf_bilap = .false. ! 466 467 ln_traldf_level = .false. ! 507 ! ! Type of the operator : 508 ln_traldf_lap = .true. ! laplacian operator 509 ln_traldf_bilap = .false. ! bilaplacian operator 510 ! ! Direction of action : 511 ln_traldf_level = .false. ! iso-level 468 512 ln_traldf_hor = .true. ! horizontal (geopotential) (require "key_ldfslp" when ln_sco=T) 469 513 ln_traldf_iso = .false. ! iso-neutral (require "key_ldfslp") 470 ! Coefficient 514 ln_traldf_grif = .false. ! griffies skew flux formulation (require "key_ldfslp") 515 ln_traldf_gdia = .false. ! griffies operator strfn diagnostics (require "key_ldfslp") 516 ln_triad_iso = .false. ! griffies operator calculates triads twice => pure lateral mixing in ML (require "key_ldfslp") 517 ln_botmix_grif = .false. ! griffies operator with lateral mixing on bottom (require "key_ldfslp") 518 ! Coefficient 471 519 rn_aht_0 = 50. ! horizontal eddy diffusivity for tracers [m2/s] 472 rn_ahtb_0 = 0. !background eddy diffusivity for ldf_iso [m2/s]520 rn_ahtb_0 = 0. ! background eddy diffusivity for ldf_iso [m2/s] 473 521 rn_aeiv_0 = 0. ! eddy induced velocity coefficient [m2/s] (require "key_traldf_eiv") 474 522 / … … 479 527 ! =XX, damping poleward of XX degrees (XX>0) 480 528 ! + F(distance-to-coast) + Red and Med Seas 481 nn_zdmp = 1! vertical shape =0 damping throughout the water column529 nn_zdmp = 0 ! vertical shape =0 damping throughout the water column 482 530 ! =1 no damping in the mixing layer (kz criteria) 483 531 ! =2 no damping in the mixed layer (rho crieria) … … 485 533 rn_bot = 360. ! bottom time scale of damping [days] 486 534 rn_dep = 800. ! depth of transition between rn_surf and rn_bot [meters] 487 nn_file = 1 ! create a damping.coeff NetCDF file (=1) or not (=0) 488 / 535 nn_file = 0 ! create a damping.coeff NetCDF file (=1) or not (=0) 536 / 537 489 538 !!====================================================================== 490 539 !! *** Dynamics namelists *** … … 496 545 !! namdyn_ldf lateral diffusion scheme 497 546 !!====================================================================== 498 547 ! 499 548 !----------------------------------------------------------------------- 500 549 &namdyn_adv ! formulation of the momentum advection … … 510 559 ln_dynvor_ens = .false. ! energy conserving scheme 511 560 ln_dynvor_mix = .false. ! mixed scheme 512 ln_dynvor_een = .true. ! energy & enstrophy scheme561 ln_dynvor_een = .true. ! energy & enstrophy scheme 513 562 / 514 563 !----------------------------------------------------------------------- … … 517 566 ln_hpg_zco = .false. ! z-coordinate - full steps 518 567 ln_hpg_zps = .false. ! z-coordinate - partial steps (interpolation) 519 ln_hpg_sco = .true. ! s-coordinate (standard jacobian formulation) 520 ln_hpg_hel = .false. ! s-coordinate (helsinki modification) 521 ln_hpg_wdj = .false. ! s-coordinate (weighted density jacobian) 568 ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation) 522 569 ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial) 523 ln_hpg_rot = .false. ! s-coordinate (ROTated axes scheme) 524 rn_gamma = 0.125 ! weighting coefficient (wdj scheme) 570 ln_hpg_prj = .true. ! s-coordinate (Pressure Jacobian scheme) 525 571 ln_dynhpg_imp = .false. ! time stepping: semi-implicit time scheme (T) 526 572 ! centered time scheme (F) 527 ! nn_dynhpg_rst = 0 ! =1 dynhpg restartable restart or not (=0)528 573 / 529 574 !----------------------------------------------------------------------- … … 537 582 &namdyn_ldf ! lateral diffusion on momentum 538 583 !----------------------------------------------------------------------- 539 ! Type of the operator : 540 ln_dynldf_lap = .true. ! laplacian operator 541 ln_dynldf_bilap = .true. ! bilaplacian operator 542 ln_dynldf_level = .false. 584 ! ! Type of the operator : 585 ln_dynldf_lap = .true. ! laplacian operator 586 ln_dynldf_bilap = .true. ! bilaplacian operator 543 587 ! Direction of action : 544 ! ln_dynldf_lap_level = .false. ! iso-level 545 ! ln_dynldf_lap_hor = .true. ! horizontal (geopotential) (require "key_ldfslp" in s-coord.) 546 ! ln_dynldf_lap_iso = .false. ! iso-neutral (require "key_ldfslp") 547 ! ln_dynldf_bilap_level = .true. ! iso-level 548 ! ln_dynldf_bilap_hor = .false. ! horizontal (geopotential) (require "key_ldfslp" in s-coord.) 549 ! ln_dynldf_bilap_iso = .false. ! iso-neutral (require "key_ldfslp") 550 ! Coefficient : 551 rn_ahm_0_lap = 60.0 ! horizontal eddy viscosity [m2/s] 552 rn_ahmb_0 = 0.0 ! background eddy viscosity for ldf_iso [m2/s] 553 rn_ahm_0_blp = -1.0e+10 ! background eddy viscosity for ldf_iso [m2/s] 554 / 588 ln_dynldf_level = .false. ! iso-level 589 ln_dynldf_hor = .true. ! horizontal (geopotential) (require "key_ldfslp" in s-coord.) 590 ln_dynldf_iso = .false. ! iso-neutral (require "key_ldfslp") 591 ! Coefficient 592 rn_ahm_0_lap = 60.0 ! horizontal laplacian eddy viscosity [m2/s] 593 rn_ahmb_0 = 0.0 ! background eddy viscosity for ldf_iso [m2/s] 594 rn_ahm_0_blp = -1.0e+10 ! horizontal bilaplacian eddy viscosity [m4/s] 595 / 596 555 597 !!====================================================================== 556 598 !! Tracers & Dynamics vertical physics namelists 557 599 !!====================================================================== 558 !! 559 !! namzdf_ric richardson number dependent vertical mixing ("key_zdfric")560 !! namzdf_tke TKE dependent vertical mixing ("key_zdftke")561 !! namzdf_kpp KPP dependent vertical mixing ("key_zdfkpp")562 !! namzdf_ddm double diffusive mixing parameterization ("key_zdfddm")563 !! namzdf_tmx tidal mixing parameterization ("key_zdftmx")564 !!====================================================================== 565 600 !! namzdf vertical physics 601 !! namzdf_ric richardson number dependent vertical mixing ("key_zdfric") 602 !! namzdf_tke TKE dependent vertical mixing ("key_zdftke") 603 !! namzdf_kpp KPP dependent vertical mixing ("key_zdfkpp") 604 !! namzdf_ddm double diffusive mixing parameterization ("key_zdfddm") 605 !! namzdf_tmx tidal mixing parameterization ("key_zdftmx") 606 !!====================================================================== 607 ! 566 608 !----------------------------------------------------------------------- 567 609 &namzdf ! vertical physics … … 573 615 ln_zdfevd = .false. ! enhanced vertical diffusion (evd) (T) or not (F) 574 616 nn_evdm = 1 ! evd apply on tracer (=0) or on tracer and momentum (=1) 575 rn_avevd = 100.! evd mixing coefficient [m2/s]576 ln_zdfnpc = .false. ! Non-Penetrative algorithm (T) or not (F)617 rn_avevd = 100. ! evd mixing coefficient [m2/s] 618 ln_zdfnpc = .false. ! Non-Penetrative Convective algorithm (T) or not (F) 577 619 nn_npc = 1 ! frequency of application of npc 578 620 nn_npcp = 365 ! npc control print frequency … … 588 630 / 589 631 !----------------------------------------------------------------------- 590 591 &namzdf_gls ! Generic length scale model vertical diffusion ("key_zdfgls")592 593 !-----------------------------------------------------------------------594 rn_emin = 1.e-6 ! minimum value of e [m2/s2]595 rn_epsmin = 1.e-12 ! minimum value of eps [m2/s3]596 ln_length_lim = .true. ! limit on the dissipation rate under stable stratification (Galperin et al., 1988)597 ! rn_clim_galp = 0.267 ! galperin limit598 ln_crban = .TRUE. ! Use Craig & Banner (1994) surface wave mixing parametrisation599 ln_sigpsi = .TRUE. ! Activate or not Burchard 2001 mods on psi schmidt number in the wb case600 rn_crban = 100. ! Craig and Banner 1994 constant for wb tke flux601 rn_charn = 100000. ! Charnock constant for wb induced roughness length602 nn_tkebc_surf = 1 ! surface tke condition (0/1=Dir/Neum)603 nn_tkebc_bot = 1 ! bottom tke condition (0/1=Dir/Neum)604 nn_psibc_surf = 1 ! surface psi condition (0/1=Dir/Neum)605 nn_psibc_bot = 1 ! bottom psi condition (0/1=Dir/Neum)606 nn_stab_func = 2 ! stability function (0=Galp, 1= KC94, 2=CanutoA, 3=CanutoB)607 nn_clos = 1 ! predefined closure type (0=MY82, 1=k-eps, 2=k-w, 3=Gen)608 /609 !-----------------------------------------------------------------------610 632 &namzdf_tke ! turbulent eddy kinetic dependent vertical diffusion ("key_zdftke") 611 633 !----------------------------------------------------------------------- 612 rn_ediff = 0. 2! coef. for vertical eddy coef. (avt=rn_ediff*mxl*sqrt(e) )634 rn_ediff = 0.1 ! coef. for vertical eddy coef. (avt=rn_ediff*mxl*sqrt(e) ) 613 635 rn_ediss = 0.7 ! coef. of the Kolmogoroff dissipation 614 rn_ebb = 6 0. ! coef. of the surface input of tke636 rn_ebb = 67.83 ! coef. of the surface input of tke (=67.83 suggested when ln_mxl0=T) 615 637 rn_emin = 1.e-6 ! minimum value of tke [m2/s2] 616 638 rn_emin0 = 1.e-4 ! surface minimum value of tke [m2/s2] 617 rn_bshear = 1.e-20 ! background shear (>0) 618 nn_mxl = 3 ! mixing length: = 0 bounded by the distance to surface and bottom 639 nn_mxl = 2 ! mixing length: = 0 bounded by the distance to surface and bottom 619 640 ! = 1 bounded by the local vertical scale factor 620 641 ! = 2 first vertical derivative of mixing length bounded by 1 621 ! = 3 same criteria as case 2 but applied in a different way 622 ln_mxl0 = .true. ! mixing length scale surface value as function of wind stress (T) or not (F) 642 ! = 3 as =2 with distinct disspipative an mixing length scale 623 643 nn_pdl = 1 ! Prandtl number function of richarson number (=1, avt=pdl(Ri)*avm) or not (=0, avt=avm) 624 ln_lc = .false. ! Langmuir cell parameterisation 644 ln_mxl0 = .true. ! surface mixing length scale = F(wind stress) (T) or not (F) 645 rn_mxl0 = 0.04 ! surface buoyancy lenght scale minimum value 646 ln_lc = .true. ! Langmuir cell parameterisation (Axell 2002) 625 647 rn_lc = 0.15 ! coef. associated to Langmuir cells 626 nn_etau = 1 ! exponentially deceasing penetration of tke due to internal & intertial waves 627 ! = 0 no penetration ( O(2 km) resolution) 628 ! = 1 additional tke source 629 ! = 2 additional tke source applied only at the base of the mixed layer 630 nn_htau = 1 ! type of exponential decrease of tke penetration 648 nn_etau = 1 ! penetration of tke below the mixed layer (ML) due to internal & intertial waves 649 ! = 0 no penetration 650 ! = 1 add a tke source below the ML 651 ! = 2 add a tke source just at the base of the ML 652 ! = 3 as = 1 applied on HF part of the stress ("key_coupled") 653 rn_efr = 0.05 ! fraction of surface tke value which penetrates below the ML (nn_etau=1 or 2) 654 nn_htau = 1 ! type of exponential decrease of tke penetration below the ML 631 655 ! = 0 constant 10 m length scale 632 ! = 1 0.5m at the equator to 30m at high latitudes 633 rn_efr = 0.05 ! fraction of surface tke value which penetrates inside the ocean 656 ! = 1 0.5m at the equator to 30m poleward of 40 degrees 634 657 / 635 658 !------------------------------------------------------------------------ 636 &namzdf_kpp ! K-Profile Parameterization dependent vertical mixing ("key_zdfkpp", and option nally:659 &namzdf_kpp ! K-Profile Parameterization dependent vertical mixing ("key_zdfkpp", and optionally: 637 660 !------------------------------------------------------------------------ "key_kppcustom" or "key_kpplktb") 638 661 ln_kpprimix = .true. ! shear instability mixing … … 647 670 / 648 671 !----------------------------------------------------------------------- 672 &namzdf_gls ! GLS vertical diffusion ("key_zdfgls") 673 !----------------------------------------------------------------------- 674 rn_emin = 1.e-6 ! minimum value of e [m2/s2] 675 rn_epsmin = 1.e-12 ! minimum value of eps [m2/s3] 676 ln_length_lim = .true. ! limit on the dissipation rate under stable stratification (Galperin et al., 1988) 677 rn_clim_galp = 0.53 ! galperin limit 678 ln_crban = .true. ! Use Craig & Banner (1994) surface wave mixing parametrisation 679 ln_sigpsi = .true. ! Activate or not Burchard 2001 mods on psi schmidt number in the wb case 680 rn_crban = 100. ! Craig and Banner 1994 constant for wb tke flux 681 rn_charn = 100000. ! Charnock constant for wb induced roughness length 682 nn_tkebc_surf = 1 ! surface tke condition (0/1/2=Dir/Neum/Dir Mellor-Blumberg) 683 nn_tkebc_bot = 1 ! bottom tke condition (0/1=Dir/Neum) 684 nn_psibc_surf = 1 ! surface psi condition (0/1/2=Dir/Neum/Dir Mellor-Blumberg) 685 nn_psibc_bot = 1 ! bottom psi condition (0/1=Dir/Neum) 686 nn_stab_func = 2 ! stability function (0=Galp, 1= KC94, 2=CanutoA, 3=CanutoB) 687 nn_clos = 1 ! predefined closure type (0=MY82, 1=k-eps, 2=k-w, 3=Gen) 688 / 689 !----------------------------------------------------------------------- 649 690 &namzdf_ddm ! double diffusive mixing parameterization ("key_zdfddm") 650 691 !----------------------------------------------------------------------- … … 662 703 rn_tfe_itf = 1. ! ITF tidal dissipation efficiency 663 704 / 664 !!====================================================================== 665 !! *** Miscelaneous namelists *** 705 706 !!====================================================================== 707 !! *** Miscellaneous namelists *** 666 708 !!====================================================================== 667 709 !! nammpp Massively Parallel Processing ("key_mpp_mpi) 668 !! nammpp_dyndist Massively Parallel domain decomposition ("key_agrif" && "key_mpp_dyndist")669 710 !! namctl Control prints & Benchmark 670 711 !! namsol elliptic solver / island / free surface 671 712 !!====================================================================== 672 713 ! 673 714 !----------------------------------------------------------------------- 674 715 &namsol ! elliptic solver / island / free surface … … 679 720 rn_eps = 1.e-6 ! absolute precision of the solver 680 721 nn_nmin = 300 ! minimum of iterations for the SOR solver 681 nn_nmax = 2800 ! maximum of iterations for the SOR solver722 nn_nmax = 800 ! maximum of iterations for the SOR solver 682 723 nn_nmod = 10 ! frequency of test for the SOR solver 683 724 rn_resmax = 1.e-10 ! absolute precision for the SOR solver … … 687 728 &nammpp ! Massively Parallel Processing ("key_mpp_mpi) 688 729 !----------------------------------------------------------------------- 689 cn_mpi_send = ' S' ! mpi send/recieve type ='S', 'B', or 'I' for standard send,730 cn_mpi_send = 'I' ! mpi send/recieve type ='S', 'B', or 'I' for standard send, 690 731 ! buffer blocking send or immediate non-blocking sends, resp. 691 732 nn_buffer = 0 ! size in bytes of exported buffer ('B' case), 0 no exportation 692 / 693 !----------------------------------------------------------------------- 694 &nammpp_dyndist ! Massively Parallel Distribution for AGRIF zoom ("key_agrif" && "key_mpp_dyndist") 695 !----------------------------------------------------------------------- 696 jpni = 4 ! jpni number of processors following i 697 jpnj = 8 ! jpnj number of processors following j 698 jpnij = 32 ! jpnij number of local domains 733 ln_nnogather= .false. ! activate code to avoid mpi_allgather use at the northfold 734 jpni = 0 ! jpni number of processors following i (set automatically if < 1) 735 jpnj = 0 ! jpnj number of processors following j (set automatically if < 1) 736 jpnij = 0 ! jpnij number of local domains (set automatically if < 1) 699 737 / 700 738 !----------------------------------------------------------------------- 701 739 &namctl ! Control prints & Benchmark 702 740 !----------------------------------------------------------------------- 703 ln_ctl = . true.! trends control print (expensive!)741 ln_ctl = .false. ! trends control print (expensive!) 704 742 nn_print = 0 ! level of print (0 no extra print) 705 743 nn_ictls = 0 ! start i indice of control sum (use to compare mono versus … … 714 752 715 753 !!====================================================================== 716 !! *** Diagnostics namelists *** 717 !!====================================================================== 754 !! *** Diagnostics namelists *** 755 !!====================================================================== 756 !! namnc4 netcdf4 chunking and compression settings ("key_netcdf4") 718 757 !! namtrd dynamics and/or tracer trends ("key_trddyn","key_trdtra","key_trdmld") 719 !! namgap level mean model-data gap ("key_diagap")720 758 !! namflo float parameters ("key_float") 721 759 !! namptr Poleward Transport Diagnostics 722 !!====================================================================== 723 760 !! namhsb Heat and salt budgets 761 !!====================================================================== 762 ! 763 !----------------------------------------------------------------------- 764 &namnc4 ! netcdf4 chunking and compression settings ("key_netcdf4") 765 !----------------------------------------------------------------------- 766 nn_nchunks_i= 4 ! number of chunks in i-dimension 767 nn_nchunks_j= 4 ! number of chunks in j-dimension 768 nn_nchunks_k= 31 ! number of chunks in k-dimension 769 ! setting nn_nchunks_k = jpk will give a chunk size of 1 in the vertical which 770 ! is optimal for postprocessing which works exclusively with horizontal slabs 771 ln_nc4zip = .true. ! (T) use netcdf4 chunking and compression 772 ! (F) ignore chunking information and produce netcdf3-compatible files 773 / 724 774 !----------------------------------------------------------------------- 725 775 &namtrd ! diagnostics on dynamics and/or tracer trends ("key_trddyn" and/or "key_trdtra") 726 ! ! or mixed-layer trends or barotropic vorticity ( 'key_trdmld' or"key_trdvor")776 ! ! or mixed-layer trends or barotropic vorticity ("key_trdmld" or "key_trdvor") 727 777 !----------------------------------------------------------------------- 728 778 nn_trd = 365 ! time step frequency dynamics and tracers trends … … 743 793 &namflo ! float parameters ("key_float") 744 794 !----------------------------------------------------------------------- 745 ln_rstflo= .false. ! float restart (T) or not (F)746 nn_writefl= 75 ! frequency of writing in float output file747 nn_stockfl= 5475 ! frequency of creation of the float restart file748 ln_argo= .false. ! Argo type floats (stay at the surface each 10 days)749 ln_flork4= .false. ! trajectories computed with a 4th order Runge-Kutta (T)795 ln_rstflo = .false. ! float restart (T) or not (F) 796 nn_writefl = 75 ! frequency of writing in float output file 797 nn_stockfl = 5475 ! frequency of creation of the float restart file 798 ln_argo = .false. ! Argo type floats (stay at the surface each 10 days) 799 ln_flork4 = .false. ! trajectories computed with a 4th order Runge-Kutta (T) 750 800 ! or computed with Blanke' scheme (F) 751 801 / … … 757 807 ln_subbas = .false. ! Atlantic/Pacific/Indian basins computation (T) or not 758 808 ! (orca configuration only, need input basins mask file named "subbasins.nc" 759 ! nn_fptr = 15 ! Frequency of ptr computation [time step] 760 ! nn_fwri = 15 ! Frequency of ptr outputs 761 / 762 !----------------------------------------------------------------------- 763 ! nam_asminc assim increment parameters (#ifdef key_asminc) 764 !----------------------------------------------------------------------- 765 ! aincstr Assimilation period start time (s) relative to run start 766 ! aincper Assimilation period length (s) 767 ! mld_choice chooses the mixed layer definition to use in the assimilation 768 ! 1) turbocline depth 2) 0.001 density criteria 3) Kara mixed layer 769 ! ln_trainc Apply tracer incerements when assimilating 770 ! ln_dyninc Apply velocity incerements when assimilating 771 ! ln_sshinc Apply sea surface height incerements when assimilating 772 &nam_asminc 773 aincstr = 0.0 774 aincper = 86400.0 775 mld_choice = 1 776 ln_trainc = .false. 777 ln_dyninc = .false. 778 ln_sshinc = .false. 779 ln_seaiceinc = .false. 780 ln_seaicebal = .true. 781 / 782 !----------------------------------------------------------------------- 783 ! namobs observation operator switch (#ifdef key_diaobs) 784 !----------------------------------------------------------------------- 785 ! ln_ena Logical switch for ENACT insitu data set 786 ! ln_cor Logical switch for Coriolis insitu data set 787 ! ln_t3d Logical switch for T profile observations 788 ! ln_s3d Logical switch for S profile observations 789 ! ln_pto Logical switch for gen profile T obs sfc 790 ! ln_pro Logical switch for gen profile Rho obs sfc 791 ! ln_pts Logical switch for gen profile T spec sfc 792 ! ln_prs Logical switch for gen profile Rho spec sfc 793 ! ln_pzm Logical switch for gen profile Z model lev 794 ! ln_sla Logical switch for SLA observations 795 ! ln_ssh Logical switch for SSH observations 796 ! ln_sst Logical switch for SST observations 797 ! ln_sss Logical switch for SSS observations 798 ! ln_reysst Logical switch for Reynolds SST 799 ! ln_ghrsst Logical switch for GHRSST format SST observations 800 ! enactfiles List of filenames containing profile data in ENACT format 801 ! slafiles List of filenames containing SLA data in CLS format 802 ! sstfiles List of filenames containing SST data in GHRSST format 803 ! dobsini Initial date in window YYYYMMDD.HHMMSS 804 ! dobsend Final date in window YYYYMMDD.HHMMSS 805 ! n1dint Type of vertical interpolation method 806 ! 0 = Linear intepolation. 807 ! 1 = Cubic spline interpolation. 808 ! n2dint Type of horizontal interpolation method 809 ! 0 = Distance-weighted interpolation 810 ! 1 = Distance-weighted interpolation (small angle) 811 ! 2 = Bilinear interpolation (geographical grid) 812 ! 3 = Bilinear remapping interpolation (general grid) 813 ! 4 = Polynomial interpolation 814 ! ln_nea Logical switch to reject observations near land 815 ! nmsshc MSSH correction scheme 816 ! 0 = no correction 817 ! 1 = compute online 818 ! 2 = set to mdtcorr 819 ! mdtcutoff MDT cutoff for computed correction 820 ! mdtcorr MDT correction factor (used if nmsshc = 2) 821 &namobs 822 ln_ena = .false. 823 ln_cor = .false. 824 825 ln_t3d = .false. 826 ln_s3d = .false. 827 ln_sla = .false. 828 ln_ssh = .false. 829 ln_sst = .false. 830 ln_sss = .false. 831 832 enactfiles = 'enact.1.nc' 833 834 slafilesact= 'sla.1.nc' 835 836 seaicefiles = 'seaice.1.nc' 'seaice.2.nc' 837 838 ln_pto = .false. 839 ln_pro = .false. 840 ln_pts = .false. 841 ln_prs = .false. 842 ln_pzm = .false. 843 ln_reysst = .false. 844 ln_ghrsst = .true. 845 ln_seaice = .false. 846 ln_logchl = .false. 847 sstfiles = 'Surface.1.nc' 848 logchlfiles = 'logchl.1.nc' 849 ln_grid_search_lookup = .true. 850 ln_obs_bound_check = .true. 851 ln_altbias = .false. 852 bias_file = 'bias.nc' 853 n1dint = 1 854 n2dint = 3 855 ln_nea = .false. 856 nmsshc = 0 857 mdtcutoff = 65.0 858 mdtcorr = 1.61 859 / 860 !----------------------------------------------------------------------- 861 ! nambias bias parameters (#ifdef key_bias) 862 !----------------------------------------------------------------------- 863 &nam_bias 864 bias_file = 'bias.nc' 865 bias_time_unit = 86400.0 866 ln_obias = .false. 867 ln_bias_ts_app = .false. 868 ln_bias_pc_app = .true. 869 / 870 !----------------------------------------------------------------------- 871 &nammoor 872 path_moor = "./" 873 nmoor = 1 874 nwmoor = 24 875 ln_moor_out = .false. 876 ln_moor_pos = .false. 877 ln_ijproc_moor_read = .false. 878 ln_ijproc_moor_write = .false. 879 / 880 !----------------------------------------------------------------------- 881 ! namdct Namelist for creating transports through sections 882 !----------------------------------------------------------------------- 883 &namdct 884 ndct = 1 ! frequency of summing 885 ndctwri = 24 ! frequency of writing 886 nsecdebug = 0 ! =0; no debugging output i.e. no fort.2?? files written 887 ! =1; transect positions outputted to fort.2?? files 888 ln_verif = .false. ! =false; only first transect output in fort.2?? files 889 ! =true; all transects output in fort 2?? files 890 / 891 !----------------------------------------------------------------------- 892 ! nammht namelist for meridional heat transport diagnostic 893 !----------------------------------------------------------------------- 894 &nammht 895 nmht=1 896 nmhtwri=80 897 / 898 !----------------------------------------------------------------------- 899 ! nammsb 900 !----------------------------------------------------------------------- 901 &namhsb 902 ln_diahsb=false 903 / 809 ln_ptrcomp = .false. ! Add decomposition : overturning 810 nn_fptr = 1 ! Frequency of ptr computation [time step] 811 nn_fwri = 15 ! Frequency of ptr outputs [time step] 812 / 813 !----------------------------------------------------------------------- 814 &namhsb ! Heat and salt budgets 815 !----------------------------------------------------------------------- 816 ln_diahsb = .false. ! check the heat and salt budgets (T) or not (F) 817 / 818 819 !!====================================================================== 820 !! *** Observation & Assimilation namelists *** 821 !!====================================================================== 822 !! namobs observation and model comparison ('key_diaobs') 823 !! nam_asminc assimilation increments ('key_asminc') 824 !!====================================================================== 825 ! 826 !----------------------------------------------------------------------- 827 &namobs ! observation usage switch ('key_diaobs') 828 !----------------------------------------------------------------------- 829 ln_t3d = .false. ! Logical switch for T profile observations 830 ln_s3d = .false. ! Logical switch for S profile observations 831 ln_ena = .false. ! Logical switch for ENACT insitu data set 832 ! ! ln_cor Logical switch for Coriolis insitu data set 833 ln_profb = .false. ! Logical switch for feedback insitu data set 834 ln_sla = .false. ! Logical switch for SLA observations 835 836 ln_sladt = .false. ! Logical switch for AVISO SLA data 837 838 ln_slafb = .false. ! Logical switch for feedback SLA data 839 ! ln_ssh Logical switch for SSH observations 840 841 ln_sst = .false. ! Logical switch for SST observations 842 ! ln_reysst Logical switch for Reynolds observations 843 ! ln_ghrsst Logical switch for GHRSST observations 844 845 ln_sstfb = .false. ! Logical switch for feedback SST data 846 ! ln_sss Logical switch for SSS observations 847 ! ln_seaice Logical switch for Sea Ice observations 848 ! ln_vel3d Logical switch for velocity observations 849 ! ln_velavcur Logical switch for velocity daily av. cur. 850 ! ln_velhrcur Logical switch for velocity high freq. cur. 851 ! ln_velavadcp Logical switch for velocity daily av. ADCP 852 ! ln_velhradcp Logical switch for velocity high freq. ADCP 853 ! ln_velfb Logical switch for feedback velocity data 854 ! ln_grid_global Global distribtion of observations 855 ! ln_grid_search_lookup Logical switch for obs grid search w/lookup table 856 ! grid_search_file Grid search lookup file header 857 ! enactfiles ENACT input observation file names 858 ! coriofiles Coriolis input observation file name 859 ! ! profbfiles: Profile feedback input observation file name 860 profbfiles = 'profiles_01.nc' 861 ! ln_profb_enatim Enact feedback input time setting switch 862 ! slafilesact Active SLA input observation file name 863 ! slafilespas Passive SLA input observation file name 864 ! ! slafbfiles: Feedback SLA input observation file name 865 slafbfiles = 'sla_01.nc' 866 ! sstfiles GHRSST input observation file name 867 ! ! sstfbfiles: Feedback SST input observation file name 868 sstfbfiles = 'sst_01.nc' 'sst_02.nc' 'sst_03.nc' 'sst_04.nc' 'sst_05.nc' 869 ! seaicefiles Sea Ice input observation file name 870 ! velavcurfiles Vel. cur. daily av. input file name 871 ! velhvcurfiles Vel. cur. high freq. input file name 872 ! velavadcpfiles Vel. ADCP daily av. input file name 873 ! velhvadcpfiles Vel. ADCP high freq. input file name 874 ! velfbfiles Vel. feedback input observation file name 875 ! dobsini Initial date in window YYYYMMDD.HHMMSS 876 ! dobsend Final date in window YYYYMMDD.HHMMSS 877 ! n1dint Type of vertical interpolation method 878 ! n2dint Type of horizontal interpolation method 879 ! ln_nea Rejection of observations near land switch 880 nmsshc = 0 ! MSSH correction scheme 881 ! mdtcorr MDT correction 882 ! mdtcutoff MDT cutoff for computed correction 883 ln_altbias = .false. ! Logical switch for alt bias 884 ln_ignmis = .true. ! Logical switch for ignoring missing files 885 ! endailyavtypes ENACT daily average types 886 ln_grid_global = .true. 887 ln_grid_search_lookup = .false. 888 / 889 !----------------------------------------------------------------------- 890 &nam_asminc ! assimilation increments ('key_asminc') 891 !----------------------------------------------------------------------- 892 ln_bkgwri = .false. ! Logical switch for writing out background state 893 ln_trjwri = .false. ! Logical switch for writing out state trajectory 894 ln_trainc = .false. ! Logical switch for applying tracer increments 895 ln_dyninc = .false. ! Logical switch for applying velocity increments 896 ln_sshinc = .false. ! Logical switch for applying SSH increments 897 ln_asmdin = .false. ! Logical switch for Direct Initialization (DI) 898 ln_asmiau = .false. ! Logical switch for Incremental Analysis Updating (IAU) 899 nitbkg = 0 ! Timestep of background in [0,nitend-nit000-1] 900 nitdin = 0 ! Timestep of background for DI in [0,nitend-nit000-1] 901 nitiaustr = 1 ! Timestep of start of IAU interval in [0,nitend-nit000-1] 902 nitiaufin = 15 ! Timestep of end of IAU interval in [0,nitend-nit000-1] 903 niaufn = 0 ! Type of IAU weighting function 904 nittrjfrq = 0 ! Frequency of trajectory output for 4D-VAR 905 ln_salfix = .false. ! Logical switch for ensuring that the sa > salfixmin 906 salfixmin = -9999 ! Minimum salinity after applying the increments 907 / 908 !----------------------------------------------------------------------- 909 &namdyn_nept ! Neptune effect (simplified: lateral and vertical diffusions removed) 910 !----------------------------------------------------------------------- 911 ! Suggested lengthscale values are those of Eby & Holloway (1994) for a coarse model 912 ln_neptsimp = .false. ! yes/no use simplified neptune 913 914 ln_smooth_neptvel = .false. ! yes/no smooth zunep, zvnep 915 rn_tslse = 1.2e4 ! value of lengthscale L at the equator 916 rn_tslsp = 3.0e3 ! value of lengthscale L at the pole 917 ! Specify whether to ramp down the Neptune velocity in shallow 918 ! water, and if so the depth range controlling such ramping down 919 ln_neptramp = .true. ! ramp down Neptune velocity in shallow water 920 rn_htrmin = 100.0 ! min. depth of transition range 921 rn_htrmax = 200.0 ! max. depth of transition range 922 / -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/CONFIG/GYRE/EXP00/namelist
r3101 r3108 408 408 ln_bfr2d = .false. ! horizontal variation of the bottom friction coef (read a 2D mask file ) 409 409 rn_bfrien = 50. ! local multiplying factor of bfr (ln_bfr2d = .true.) 410 ln_bfrimp = . false.! implicit bottom friction (requires ln_zdfexp = .false. if true)410 ln_bfrimp = .true. ! implicit bottom friction (requires ln_zdfexp = .false. if true) 411 411 / 412 412 !----------------------------------------------------------------------- … … 522 522 ln_hpg_zps = .false. ! z-coordinate - partial steps (interpolation) 523 523 ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation) 524 ln_hpg_hel = .false. ! s-coordinate (helsinki modification)525 ln_hpg_wdj = .false. ! s-coordinate (weighted density jacobian)526 524 ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial) 527 ln_hpg_rot = .false. ! s-coordinate (ROTated axes scheme)528 525 ln_hpg_prj = .false. ! s-coordinate (Pressure Jacobian scheme) 529 rn_gamma = 0.e0 ! weighting coefficient (wdj scheme)530 526 ln_dynhpg_imp = .false. ! time stepping: semi-implicit time scheme (T) 531 527 ! centered time scheme (F) -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/CONFIG/ORCA2_LIM/EXP00/1_namelist
r3101 r3108 408 408 ln_bfr2d = .false. ! horizontal variation of the bottom friction coef (read a 2D mask file ) 409 409 rn_bfrien = 50. ! local multiplying factor of bfr (ln_bfr2d=T) 410 ln_bfrimp = . false.! implicit bottom friction (requires ln_zdfexp = .false. if true)410 ln_bfrimp = .true. ! implicit bottom friction (requires ln_zdfexp = .false. if true) 411 411 / 412 412 !----------------------------------------------------------------------- … … 520 520 ln_hpg_zps = .true. ! z-coordinate - partial steps (interpolation) 521 521 ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation) 522 ln_hpg_hel = .false. ! s-coordinate (helsinki modification)523 ln_hpg_wdj = .false. ! s-coordinate (weighted density jacobian)524 522 ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial) 525 ln_hpg_rot = .false. ! s-coordinate (ROTated axes scheme)526 523 ln_hpg_prj = .false. ! s-coordinate (Pressure Jacobian scheme) 527 rn_gamma = 0.e0 ! weighting coefficient (wdj scheme)528 524 ln_dynhpg_imp = .false. ! time stepping: semi-implicit time scheme (T) 529 525 ! centered time scheme (F) -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/CONFIG/ORCA2_LIM/EXP00/namelist
r3101 r3108 408 408 ln_bfr2d = .false. ! horizontal variation of the bottom friction coef (read a 2D mask file ) 409 409 rn_bfrien = 50. ! local multiplying factor of bfr (ln_bfr2d=T) 410 ln_bfrimp = . false.! implicit bottom friction (requires ln_zdfexp = .false. if true)410 ln_bfrimp = .true. ! implicit bottom friction (requires ln_zdfexp = .false. if true) 411 411 / 412 412 !----------------------------------------------------------------------- … … 522 522 ln_hpg_zps = .true. ! z-coordinate - partial steps (interpolation) 523 523 ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation) 524 ln_hpg_hel = .false. ! s-coordinate (helsinki modification)525 ln_hpg_wdj = .false. ! s-coordinate (weighted density jacobian)526 524 ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial) 527 ln_hpg_rot = .false. ! s-coordinate (ROTated axes scheme)528 525 ln_hpg_prj = .false. ! s-coordinate (Pressure Jacobian scheme) 529 rn_gamma = 0.e0 ! weighting coefficient (wdj scheme)530 526 ln_dynhpg_imp = .false. ! time stepping: semi-implicit time scheme (T) 531 527 ! centered time scheme (F) -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/CONFIG/ORCA2_OFF_PISCES/EXP00/namelist
r3101 r3108 408 408 ln_bfr2d = .false. ! horizontal variation of the bottom friction coef (read a 2D mask file ) 409 409 rn_bfrien = 50. ! local multiplying factor of bfr (ln_bfr2d = .true.) 410 ln_bfrimp = . false.! implicit bottom friction (requires ln_zdfexp = .false. if true)410 ln_bfrimp = .true. ! implicit bottom friction (requires ln_zdfexp = .false. if true) 411 411 / 412 412 !----------------------------------------------------------------------- … … 523 523 ln_hpg_zps = .true. ! z-coordinate - partial steps (interpolation) 524 524 ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation) 525 ln_hpg_hel = .false. ! s-coordinate (helsinki modification)526 ln_hpg_wdj = .false. ! s-coordinate (weighted density jacobian)527 525 ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial) 528 ln_hpg_rot = .false. ! s-coordinate (ROTated axes scheme)529 526 ln_hpg_prj = .false. ! s-coordinate (Pressure Jacobian scheme) 530 rn_gamma = 0.e0 ! weighting coefficient (wdj scheme)531 527 ln_dynhpg_imp = .false. ! time stepping: semi-implicit time scheme (T) 532 528 ! centered time scheme (F) -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/CONFIG/POMME/EXP00/namelist
r3101 r3108 408 408 ln_bfr2d = .false. ! horizontal variation of the bottom friction coef (read a 2D mask file ) 409 409 rn_bfrien = 50. ! local multiplying factor of bfr (ln_bfr2d=T) 410 ln_bfrimp = . false.! implicit bottom friction (requires ln_zdfexp = .false. if true)410 ln_bfrimp = .true. ! implicit bottom friction (requires ln_zdfexp = .false. if true) 411 411 / 412 412 !----------------------------------------------------------------------- … … 522 522 ln_hpg_zps = .true. ! z-coordinate - partial steps (interpolation) 523 523 ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation) 524 ln_hpg_hel = .false. ! s-coordinate (helsinki modification)525 ln_hpg_wdj = .false. ! s-coordinate (weighted density jacobian)526 524 ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial) 527 ln_hpg_rot = .false. ! s-coordinate (ROTated axes scheme)528 525 ln_hpg_prj = .false. ! s-coordinate (Pressure Jacobian scheme) 529 rn_gamma = 0.e0 ! weighting coefficient (wdj scheme)530 526 ln_dynhpg_imp = .true. ! time stepping: semi-implicit time scheme (T) 531 527 ! centered time scheme (F) -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/NEMO/OPA_SRC/DYN/dynhpg.F90
r3102 r3108 14 14 !! - ! 2005-11 (G. Madec) style & small optimisation 15 15 !! 3.3 ! 2010-10 (C. Ethe, G. Madec) reorganisation of initialisation phase 16 !! 3.4 ! 2011-11 (A. Coward, H. Liu) introduction of prj scheme; 17 !! ! suppression of hel, wdj and rot options 16 18 !!---------------------------------------------------------------------- 17 19 … … 23 25 !! hpg_zps : z-coordinate plus partial steps (interpolation) 24 26 !! hpg_sco : s-coordinate (standard jacobian formulation) 25 !! hpg_hel : s-coordinate (helsinki modification)26 !! hpg_wdj : s-coordinate (weighted density jacobian)27 27 !! hpg_djc : s-coordinate (Density Jacobian with Cubic polynomial) 28 !! hpg_rot : s-coordinate (ROTated axes scheme)29 28 !! hpg_prj : s-coordinate (Pressure Jacobian with Cubic polynomial) 30 29 !!---------------------------------------------------------------------- … … 49 48 LOGICAL , PUBLIC :: ln_hpg_zps = .FALSE. !: z-coordinate - partial steps (interpolation) 50 49 LOGICAL , PUBLIC :: ln_hpg_sco = .FALSE. !: s-coordinate (standard jacobian formulation) 51 LOGICAL , PUBLIC :: ln_hpg_hel = .FALSE. !: s-coordinate (helsinki modification)52 LOGICAL , PUBLIC :: ln_hpg_wdj = .FALSE. !: s-coordinate (weighted density jacobian)53 50 LOGICAL , PUBLIC :: ln_hpg_djc = .FALSE. !: s-coordinate (Density Jacobian with Cubic polynomial) 54 LOGICAL , PUBLIC :: ln_hpg_rot = .FALSE. !: s-coordinate (ROTated axes scheme)55 51 LOGICAL , PUBLIC :: ln_hpg_prj = .FALSE. !: s-coordinate (Pressure Jacobian scheme) 56 REAL(wp), PUBLIC :: rn_gamma = 0._wp !: weighting coefficient57 52 LOGICAL , PUBLIC :: ln_dynhpg_imp = .FALSE. !: semi-implicite hpg flag 58 53 … … 98 93 CASE ( 1 ) ; CALL hpg_zps ( kt ) ! z-coordinate plus partial steps (interpolation) 99 94 CASE ( 2 ) ; CALL hpg_sco ( kt ) ! s-coordinate (standard jacobian formulation) 100 CASE ( 3 ) ; CALL hpg_hel ( kt ) ! s-coordinate (helsinki modification) 101 CASE ( 4 ) ; CALL hpg_wdj ( kt ) ! s-coordinate (weighted density jacobian) 102 CASE ( 5 ) ; CALL hpg_djc ( kt ) ! s-coordinate (Density Jacobian with Cubic polynomial) 103 CASE ( 6 ) ; CALL hpg_rot ( kt ) ! s-coordinate (ROTated axes scheme) 104 CASE ( 7 ) ; CALL hpg_prj ( kt ) ! s-coordinate (Pressure Jacobian scheme) 95 CASE ( 3 ) ; CALL hpg_djc ( kt ) ! s-coordinate (Density Jacobian with Cubic polynomial) 96 CASE ( 4 ) ; CALL hpg_prj ( kt ) ! s-coordinate (Pressure Jacobian scheme) 105 97 END SELECT 106 98 ! … … 131 123 INTEGER :: ioptio = 0 ! temporary integer 132 124 !! 133 NAMELIST/namdyn_hpg/ ln_hpg_zco, ln_hpg_zps, ln_hpg_sco, ln_hpg_hel, & 134 & ln_hpg_wdj, ln_hpg_djc, ln_hpg_rot, ln_hpg_prj, & 135 & rn_gamma , ln_dynhpg_imp 125 NAMELIST/namdyn_hpg/ ln_hpg_zco, ln_hpg_zps, ln_hpg_sco, & 126 & ln_hpg_djc, ln_hpg_prj, ln_dynhpg_imp 136 127 !!---------------------------------------------------------------------- 137 128 ! … … 147 138 WRITE(numout,*) ' z-coord. - partial steps (interpolation) ln_hpg_zps = ', ln_hpg_zps 148 139 WRITE(numout,*) ' s-coord. (standard jacobian formulation) ln_hpg_sco = ', ln_hpg_sco 149 WRITE(numout,*) ' s-coord. (helsinki modification) ln_hpg_hel = ', ln_hpg_hel150 WRITE(numout,*) ' s-coord. (weighted density jacobian) ln_hpg_wdj = ', ln_hpg_wdj151 140 WRITE(numout,*) ' s-coord. (Density Jacobian: Cubic polynomial) ln_hpg_djc = ', ln_hpg_djc 152 WRITE(numout,*) ' s-coord. (ROTated axes scheme) ln_hpg_rot = ', ln_hpg_rot153 141 WRITE(numout,*) ' s-coord. (Pressure Jacobian: Cubic polynomial) ln_hpg_prj = ', ln_hpg_prj 154 WRITE(numout,*) ' weighting coeff. (wdj scheme) rn_gamma = ', rn_gamma155 142 WRITE(numout,*) ' time stepping: centered (F) or semi-implicit (T) ln_dynhpg_imp = ', ln_dynhpg_imp 156 143 ENDIF … … 165 152 IF( ln_hpg_zps ) nhpg = 1 166 153 IF( ln_hpg_sco ) nhpg = 2 167 IF( ln_hpg_hel ) nhpg = 3 168 IF( ln_hpg_wdj ) nhpg = 4 169 IF( ln_hpg_djc ) nhpg = 5 170 IF( ln_hpg_rot ) nhpg = 6 171 IF( ln_hpg_prj ) nhpg = 7 154 IF( ln_hpg_djc ) nhpg = 3 155 IF( ln_hpg_prj ) nhpg = 4 172 156 ! 173 157 ! ! Consistency check … … 176 160 IF( ln_hpg_zps ) ioptio = ioptio + 1 177 161 IF( ln_hpg_sco ) ioptio = ioptio + 1 178 IF( ln_hpg_hel ) ioptio = ioptio + 1179 IF( ln_hpg_wdj ) ioptio = ioptio + 1180 162 IF( ln_hpg_djc ) ioptio = ioptio + 1 181 IF( ln_hpg_rot ) ioptio = ioptio + 1182 163 IF( ln_hpg_prj ) ioptio = ioptio + 1 183 164 IF( ioptio /= 1 ) CALL ctl_stop( 'NO or several hydrostatic pressure gradient options used' ) … … 428 409 END SUBROUTINE hpg_sco 429 410 430 431 SUBROUTINE hpg_hel( kt )432 !!---------------------------------------------------------------------433 !! *** ROUTINE hpg_hel ***434 !!435 !! ** Method : s-coordinate case.436 !! The now hydrostatic pressure gradient at a given level437 !! jk is computed by taking the vertical integral of the in-situ438 !! density gradient along the model level from the suface to that439 !! level. s-coordinates (ln_sco): a corrective term is added440 !! to the horizontal pressure gradient :441 !! zhpi = grav ..... + 1/e1u mi(rhd) di[ grav dep3w ]442 !! zhpj = grav ..... + 1/e2v mj(rhd) dj[ grav dep3w ]443 !! add it to the general momentum trend (ua,va).444 !! ua = ua - 1/e1u * zhpi445 !! va = va - 1/e2v * zhpj446 !!447 !! ** Action : - Update (ua,va) with the now hydrastatic pressure trend448 !! - Save the trend (l_trddyn=T)449 !!----------------------------------------------------------------------450 USE oce, ONLY: zhpi => ta , zhpj => sa ! (ta,sa) used as 3D workspace451 !!452 INTEGER, INTENT(in) :: kt ! ocean time-step index453 !!454 INTEGER :: ji, jj, jk ! dummy loop indices455 REAL(wp) :: zcoef0, zuap, zvap ! temporary scalars456 !!----------------------------------------------------------------------457 458 IF( kt == nit000 ) THEN459 IF(lwp) WRITE(numout,*)460 IF(lwp) WRITE(numout,*) 'dyn:hpg_hel : hydrostatic pressure gradient trend'461 IF(lwp) WRITE(numout,*) '~~~~~~~~~~~ s-coordinate case, helsinki modified scheme'462 ENDIF463 464 ! Local constant initialization465 zcoef0 = - grav * 0.5_wp466 467 ! Surface value468 DO jj = 2, jpjm1469 DO ji = fs_2, fs_jpim1 ! vector opt.470 ! hydrostatic pressure gradient along s-surfaces471 zhpi(ji,jj,1) = zcoef0 / e1u(ji,jj) * ( fse3t(ji+1,jj ,1) * rhd(ji+1,jj ,1) &472 & - fse3t(ji ,jj ,1) * rhd(ji ,jj ,1) )473 zhpj(ji,jj,1) = zcoef0 / e2v(ji,jj) * ( fse3t(ji ,jj+1,1) * rhd(ji ,jj+1,1) &474 & - fse3t(ji ,jj ,1) * rhd(ji ,jj ,1) )475 ! s-coordinate pressure gradient correction476 zuap = -zcoef0 * ( rhd (ji+1,jj,1) + rhd (ji,jj,1) ) &477 & * ( fsdept(ji+1,jj,1) - fsdept(ji,jj,1) ) / e1u(ji,jj)478 zvap = -zcoef0 * ( rhd (ji,jj+1,1) + rhd (ji,jj,1) ) &479 & * ( fsdept(ji,jj+1,1) - fsdept(ji,jj,1) ) / e2v(ji,jj)480 ! add to the general momentum trend481 ua(ji,jj,1) = ua(ji,jj,1) + zhpi(ji,jj,1) + zuap482 va(ji,jj,1) = va(ji,jj,1) + zhpj(ji,jj,1) + zvap483 END DO484 END DO485 !486 ! interior value (2=<jk=<jpkm1)487 DO jk = 2, jpkm1488 DO jj = 2, jpjm1489 DO ji = fs_2, fs_jpim1 ! vector opt.490 ! hydrostatic pressure gradient along s-surfaces491 zhpi(ji,jj,jk) = zhpi(ji,jj,jk-1) &492 & + zcoef0 / e1u(ji,jj) * ( fse3t(ji+1,jj,jk ) * rhd(ji+1,jj,jk) &493 & -fse3t(ji ,jj,jk ) * rhd(ji ,jj,jk) ) &494 & + zcoef0 / e1u(ji,jj) * ( fse3t(ji+1,jj,jk-1) * rhd(ji+1,jj,jk-1) &495 & -fse3t(ji ,jj,jk-1) * rhd(ji ,jj,jk-1) )496 zhpj(ji,jj,jk) = zhpj(ji,jj,jk-1) &497 & + zcoef0 / e2v(ji,jj) * ( fse3t(ji,jj+1,jk ) * rhd(ji,jj+1,jk) &498 & -fse3t(ji,jj ,jk ) * rhd(ji,jj, jk) ) &499 & + zcoef0 / e2v(ji,jj) * ( fse3t(ji,jj+1,jk-1) * rhd(ji,jj+1,jk-1) &500 & -fse3t(ji,jj ,jk-1) * rhd(ji,jj, jk-1) )501 ! s-coordinate pressure gradient correction502 zuap = - zcoef0 * ( rhd (ji+1,jj,jk) + rhd (ji,jj,jk) ) &503 & * ( fsdept(ji+1,jj,jk) - fsdept(ji,jj,jk) ) / e1u(ji,jj)504 zvap = - zcoef0 * ( rhd (ji,jj+1,jk) + rhd (ji,jj,jk) ) &505 & * ( fsdept(ji,jj+1,jk) - fsdept(ji,jj,jk) ) / e2v(ji,jj)506 ! add to the general momentum trend507 ua(ji,jj,jk) = ua(ji,jj,jk) + zhpi(ji,jj,jk) + zuap508 va(ji,jj,jk) = va(ji,jj,jk) + zhpj(ji,jj,jk) + zvap509 END DO510 END DO511 END DO512 !513 END SUBROUTINE hpg_hel514 515 516 SUBROUTINE hpg_wdj( kt )517 !!---------------------------------------------------------------------518 !! *** ROUTINE hpg_wdj ***519 !!520 !! ** Method : Weighted Density Jacobian (wdj) scheme (song 1998)521 !! The weighting coefficients from the namelist parameter rn_gamma522 !! (alpha=0.5-rn_gamma ; beta=1-alpha=0.5+rn_gamma523 !!524 !! Reference : Song, Mon. Wea. Rev., 126, 3213-3230, 1998.525 !!----------------------------------------------------------------------526 USE oce, ONLY: zhpi => ta , zhpj => sa ! (ta,sa) used as 3D workspace527 !!528 INTEGER, INTENT(in) :: kt ! ocean time-step index529 !!530 INTEGER :: ji, jj, jk ! dummy loop indices531 REAL(wp) :: zcoef0, zuap, zvap ! temporary scalars532 REAL(wp) :: zalph , zbeta ! " "533 !!----------------------------------------------------------------------534 535 IF( kt == nit000 ) THEN536 IF(lwp) WRITE(numout,*)537 IF(lwp) WRITE(numout,*) 'dyn:hpg_wdj : hydrostatic pressure gradient trend'538 IF(lwp) WRITE(numout,*) '~~~~~~~~~~~ Weighted Density Jacobian'539 ENDIF540 541 ! Local constant initialization542 zcoef0 = - grav * 0.5_wp543 zalph = 0.5_wp - rn_gamma ! weighting coefficients (alpha=0.5-rn_gamma544 zbeta = 0.5_wp + rn_gamma ! (beta =1-alpha=0.5+rn_gamma545 546 ! Surface value (no ponderation)547 DO jj = 2, jpjm1548 DO ji = fs_2, fs_jpim1 ! vector opt.549 ! hydrostatic pressure gradient along s-surfaces550 zhpi(ji,jj,1) = zcoef0 / e1u(ji,jj) * ( fse3w(ji+1,jj ,1) * rhd(ji+1,jj ,1) &551 & - fse3w(ji ,jj ,1) * rhd(ji ,jj ,1) )552 zhpj(ji,jj,1) = zcoef0 / e2v(ji,jj) * ( fse3w(ji ,jj+1,1) * rhd(ji ,jj+1,1) &553 & - fse3w(ji ,jj ,1) * rhd(ji, jj ,1) )554 ! s-coordinate pressure gradient correction555 zuap = -zcoef0 * ( rhd (ji+1,jj,1) + rhd (ji,jj,1) ) &556 & * ( fsde3w(ji+1,jj,1) - fsde3w(ji,jj,1) ) / e1u(ji,jj)557 zvap = -zcoef0 * ( rhd (ji,jj+1,1) + rhd (ji,jj,1) ) &558 & * ( fsde3w(ji,jj+1,1) - fsde3w(ji,jj,1) ) / e2v(ji,jj)559 ! add to the general momentum trend560 ua(ji,jj,1) = ua(ji,jj,1) + zhpi(ji,jj,1) + zuap561 va(ji,jj,1) = va(ji,jj,1) + zhpj(ji,jj,1) + zvap562 END DO563 END DO564 565 ! Interior value (2=<jk=<jpkm1) (weighted with zalph & zbeta)566 DO jk = 2, jpkm1567 DO jj = 2, jpjm1568 DO ji = fs_2, fs_jpim1 ! vector opt.569 zhpi(ji,jj,jk) = zhpi(ji,jj,jk-1) + zcoef0 / e1u(ji,jj) &570 & * ( ( fsde3w(ji+1,jj,jk ) + fsde3w(ji,jj,jk ) &571 & - fsde3w(ji+1,jj,jk-1) - fsde3w(ji,jj,jk-1) ) &572 & * ( zalph * ( rhd (ji+1,jj,jk-1) - rhd (ji,jj,jk-1) ) &573 & + zbeta * ( rhd (ji+1,jj,jk ) - rhd (ji,jj,jk ) ) ) &574 & - ( rhd (ji+1,jj,jk ) + rhd (ji,jj,jk ) &575 & - rhd (ji+1,jj,jk-1) - rhd (ji,jj,jk-1) ) &576 & * ( zalph * ( fsde3w(ji+1,jj,jk-1) - fsde3w(ji,jj,jk-1) ) &577 & + zbeta * ( fsde3w(ji+1,jj,jk ) - fsde3w(ji,jj,jk ) ) ) )578 zhpj(ji,jj,jk) = zhpj(ji,jj,jk-1) + zcoef0 / e2v(ji,jj) &579 & * ( ( fsde3w(ji,jj+1,jk ) + fsde3w(ji,jj,jk ) &580 & - fsde3w(ji,jj+1,jk-1) - fsde3w(ji,jj,jk-1) ) &581 & * ( zalph * ( rhd (ji,jj+1,jk-1) - rhd (ji,jj,jk-1) ) &582 & + zbeta * ( rhd (ji,jj+1,jk ) - rhd (ji,jj,jk ) ) ) &583 & - ( rhd (ji,jj+1,jk ) + rhd (ji,jj,jk ) &584 & - rhd (ji,jj+1,jk-1) - rhd (ji,jj,jk-1) ) &585 & * ( zalph * ( fsde3w(ji,jj+1,jk-1) - fsde3w(ji,jj,jk-1) ) &586 & + zbeta * ( fsde3w(ji,jj+1,jk ) - fsde3w(ji,jj,jk ) ) ) )587 ! add to the general momentum trend588 ua(ji,jj,jk) = ua(ji,jj,jk) + zhpi(ji,jj,jk)589 va(ji,jj,jk) = va(ji,jj,jk) + zhpj(ji,jj,jk)590 END DO591 END DO592 END DO593 !594 END SUBROUTINE hpg_wdj595 596 597 411 SUBROUTINE hpg_djc( kt ) 598 412 !!--------------------------------------------------------------------- … … 826 640 827 641 828 SUBROUTINE hpg_rot( kt )829 !!---------------------------------------------------------------------830 !! *** ROUTINE hpg_rot ***831 !!832 !! ** Method : rotated axes scheme (Thiem and Berntsen 2005)833 !!834 !! Reference: Thiem & Berntsen, Ocean Modelling, In press, 2005.835 !!----------------------------------------------------------------------836 USE wrk_nemo, ONLY: wrk_in_use, wrk_not_released837 USE oce , ONLY: zhpi => ta , zhpj => sa ! (ta,sa) used as 3D workspace838 USE wrk_nemo, ONLY: zdistr => wrk_2d_1 , zsina => wrk_2d_2 , zcosa => wrk_2d_3839 USE wrk_nemo, ONLY: zhpiorg => wrk_3d_1 , zhpirot => wrk_3d_2840 USE wrk_nemo, ONLY: zhpitra => wrk_3d_3 , zhpine => wrk_3d_4841 USE wrk_nemo, ONLY: zhpjorg => wrk_3d_5 , zhpjrot => wrk_3d_6842 USE wrk_nemo, ONLY: zhpjtra => wrk_3d_7 , zhpjne => wrk_3d_8843 !!844 INTEGER, INTENT(in) :: kt ! ocean time-step index845 !!846 INTEGER :: ji, jj, jk ! dummy loop indices847 REAL(wp) :: zforg, zcoef0, zuap, zmskd1, zmskd1m ! temporary scalar848 REAL(wp) :: zfrot , zvap, zmskd2, zmskd2m ! " "849 !!----------------------------------------------------------------------850 851 IF( wrk_in_use(2, 1,2,3) .OR. &852 wrk_in_use(3, 1,2,3,4,5,6,7,8) ) THEN853 CALL ctl_stop('dyn:hpg_rot: requested workspace arrays unavailable') ; RETURN854 ENDIF855 856 IF( kt == nit000 ) THEN857 IF(lwp) WRITE(numout,*)858 IF(lwp) WRITE(numout,*) 'dyn:hpg_rot : hydrostatic pressure gradient trend'859 IF(lwp) WRITE(numout,*) '~~~~~~~~~~~ s-coordinate case, rotated axes scheme used'860 ENDIF861 862 ! -------------------------------863 ! Local constant initialization864 ! -------------------------------865 zcoef0 = - grav * 0.5_wp866 zforg = 0.95_wp867 zfrot = 1._wp - zforg868 869 ! inverse of the distance between 2 diagonal T-points (defined at F-point) (here zcoef0/distance)870 zdistr(:,:) = zcoef0 / SQRT( e1f(:,:)*e1f(:,:) + e2f(:,:)*e1f(:,:) )871 872 ! sinus and cosinus of diagonal angle at F-point873 zsina(:,:) = ATAN2( e2f(:,:), e1f(:,:) )874 zcosa(:,:) = COS( zsina(:,:) )875 zsina(:,:) = SIN( zsina(:,:) )876 877 ! ---------------878 ! Surface value879 ! ---------------880 ! compute and add to the general trend the pressure gradients along the axes881 DO jj = 2, jpjm1882 DO ji = fs_2, fs_jpim1 ! vector opt.883 ! hydrostatic pressure gradient along s-surfaces884 zhpiorg(ji,jj,1) = zcoef0 / e1u(ji,jj) * ( fse3t(ji+1,jj,1) * rhd(ji+1,jj,1) &885 & - fse3t(ji ,jj,1) * rhd(ji ,jj,1) )886 zhpjorg(ji,jj,1) = zcoef0 / e2v(ji,jj) * ( fse3t(ji,jj+1,1) * rhd(ji,jj+1,1) &887 & - fse3t(ji,jj ,1) * rhd(ji,jj ,1) )888 ! s-coordinate pressure gradient correction889 zuap = -zcoef0 * ( rhd (ji+1,jj ,1) + rhd (ji,jj,1) ) &890 & * ( fsdept(ji+1,jj ,1) - fsdept(ji,jj,1) ) / e1u(ji,jj)891 zvap = -zcoef0 * ( rhd (ji ,jj+1,1) + rhd (ji,jj,1) ) &892 & * ( fsdept(ji ,jj+1,1) - fsdept(ji,jj,1) ) / e2v(ji,jj)893 ! add to the general momentum trend894 ua(ji,jj,1) = ua(ji,jj,1) + zforg * ( zhpiorg(ji,jj,1) + zuap )895 va(ji,jj,1) = va(ji,jj,1) + zforg * ( zhpjorg(ji,jj,1) + zvap )896 END DO897 END DO898 899 ! compute the pressure gradients in the diagonal directions900 DO jj = 1, jpjm1901 DO ji = 1, fs_jpim1 ! vector opt.902 zmskd1 = tmask(ji+1,jj+1,1) * tmask(ji ,jj,1) ! mask in the 1st diagnonal903 zmskd2 = tmask(ji ,jj+1,1) * tmask(ji+1,jj,1) ! mask in the 2nd diagnonal904 ! hydrostatic pressure gradient along s-surfaces905 zhpitra(ji,jj,1) = zdistr(ji,jj) * zmskd1 * ( fse3t(ji+1,jj+1,1) * rhd(ji+1,jj+1,1) &906 & - fse3t(ji ,jj ,1) * rhd(ji ,jj ,1) )907 zhpjtra(ji,jj,1) = zdistr(ji,jj) * zmskd2 * ( fse3t(ji ,jj+1,1) * rhd(ji ,jj+1,1) &908 & - fse3t(ji+1,jj ,1) * rhd(ji+1,jj ,1) )909 ! s-coordinate pressure gradient correction910 zuap = -zdistr(ji,jj) * zmskd1 * ( rhd (ji+1,jj+1,1) + rhd (ji ,jj,1) ) &911 & * ( fsdept(ji+1,jj+1,1) - fsdept(ji ,jj,1) )912 zvap = -zdistr(ji,jj) * zmskd2 * ( rhd (ji ,jj+1,1) + rhd (ji+1,jj,1) ) &913 & * ( fsdept(ji ,jj+1,1) - fsdept(ji+1,jj,1) )914 ! back rotation915 zhpine(ji,jj,1) = zcosa(ji,jj) * ( zhpitra(ji,jj,1) + zuap ) &916 & - zsina(ji,jj) * ( zhpjtra(ji,jj,1) + zvap )917 zhpjne(ji,jj,1) = zsina(ji,jj) * ( zhpitra(ji,jj,1) + zuap ) &918 & + zcosa(ji,jj) * ( zhpjtra(ji,jj,1) + zvap )919 END DO920 END DO921 922 ! interpolate and add to the general trend the diagonal gradient923 DO jj = 2, jpjm1924 DO ji = fs_2, fs_jpim1 ! vector opt.925 ! averaging926 zhpirot(ji,jj,1) = 0.5 * ( zhpine(ji,jj,1) + zhpine(ji ,jj-1,1) )927 zhpjrot(ji,jj,1) = 0.5 * ( zhpjne(ji,jj,1) + zhpjne(ji-1,jj ,1) )928 ! add to the general momentum trend929 ua(ji,jj,1) = ua(ji,jj,1) + zfrot * zhpirot(ji,jj,1)930 va(ji,jj,1) = va(ji,jj,1) + zfrot * zhpjrot(ji,jj,1)931 END DO932 END DO933 934 ! -----------------935 ! 2. interior value (2=<jk=<jpkm1)936 ! -----------------937 ! compute and add to the general trend the pressure gradients along the axes938 DO jk = 2, jpkm1939 DO jj = 2, jpjm1940 DO ji = fs_2, fs_jpim1 ! vector opt.941 ! hydrostatic pressure gradient along s-surfaces942 zhpiorg(ji,jj,jk) = zhpiorg(ji,jj,jk-1) &943 & + zcoef0 / e1u(ji,jj) * ( fse3t(ji+1,jj,jk ) * rhd(ji+1,jj,jk ) &944 & - fse3t(ji ,jj,jk ) * rhd(ji ,jj,jk ) &945 & + fse3t(ji+1,jj,jk-1) * rhd(ji+1,jj,jk-1) &946 & - fse3t(ji ,jj,jk-1) * rhd(ji ,jj,jk-1) )947 zhpjorg(ji,jj,jk) = zhpjorg(ji,jj,jk-1) &948 & + zcoef0 / e2v(ji,jj) * ( fse3t(ji,jj+1,jk ) * rhd(ji,jj+1,jk ) &949 & - fse3t(ji,jj ,jk ) * rhd(ji,jj, jk ) &950 & + fse3t(ji,jj+1,jk-1) * rhd(ji,jj+1,jk-1) &951 & - fse3t(ji,jj ,jk-1) * rhd(ji,jj, jk-1) )952 ! s-coordinate pressure gradient correction953 zuap = - zcoef0 * ( rhd (ji+1,jj ,jk) + rhd (ji,jj,jk) ) &954 & * ( fsdept(ji+1,jj ,jk) - fsdept(ji,jj,jk) ) / e1u(ji,jj)955 zvap = - zcoef0 * ( rhd (ji ,jj+1,jk) + rhd (ji,jj,jk) ) &956 & * ( fsdept(ji ,jj+1,jk) - fsdept(ji,jj,jk) ) / e2v(ji,jj)957 ! add to the general momentum trend958 ua(ji,jj,jk) = ua(ji,jj,jk) + zforg*( zhpiorg(ji,jj,jk) + zuap )959 va(ji,jj,jk) = va(ji,jj,jk) + zforg*( zhpjorg(ji,jj,jk) + zvap )960 END DO961 END DO962 END DO963 964 ! compute the pressure gradients in the diagonal directions965 DO jk = 2, jpkm1966 DO jj = 1, jpjm1967 DO ji = 1, fs_jpim1 ! vector opt.968 zmskd1 = tmask(ji+1,jj+1,jk ) * tmask(ji ,jj,jk ) ! level jk mask in the 1st diagnonal969 zmskd1m = tmask(ji+1,jj+1,jk-1) * tmask(ji ,jj,jk-1) ! level jk-1 " "970 zmskd2 = tmask(ji ,jj+1,jk ) * tmask(ji+1,jj,jk ) ! level jk mask in the 2nd diagnonal971 zmskd2m = tmask(ji ,jj+1,jk-1) * tmask(ji+1,jj,jk-1) ! level jk-1 " "972 ! hydrostatic pressure gradient along s-surfaces973 zhpitra(ji,jj,jk) = zhpitra(ji,jj,jk-1) &974 & + zdistr(ji,jj) * zmskd1 * ( fse3t(ji+1,jj+1,jk ) * rhd(ji+1,jj+1,jk) &975 & -fse3t(ji ,jj ,jk ) * rhd(ji ,jj ,jk) ) &976 & + zdistr(ji,jj) * zmskd1m * ( fse3t(ji+1,jj+1,jk-1) * rhd(ji+1,jj+1,jk-1) &977 & -fse3t(ji ,jj ,jk-1) * rhd(ji ,jj ,jk-1) )978 zhpjtra(ji,jj,jk) = zhpjtra(ji,jj,jk-1) &979 & + zdistr(ji,jj) * zmskd2 * ( fse3t(ji ,jj+1,jk ) * rhd(ji ,jj+1,jk) &980 & -fse3t(ji+1,jj ,jk ) * rhd(ji+1,jj, jk) ) &981 & + zdistr(ji,jj) * zmskd2m * ( fse3t(ji ,jj+1,jk-1) * rhd(ji ,jj+1,jk-1) &982 & -fse3t(ji+1,jj ,jk-1) * rhd(ji+1,jj, jk-1) )983 ! s-coordinate pressure gradient correction984 zuap = - zdistr(ji,jj) * zmskd1 * ( rhd (ji+1,jj+1,jk) + rhd (ji ,jj,jk) ) &985 & * ( fsdept(ji+1,jj+1,jk) - fsdept(ji ,jj,jk) )986 zvap = - zdistr(ji,jj) * zmskd2 * ( rhd (ji ,jj+1,jk) + rhd (ji+1,jj,jk) ) &987 & * ( fsdept(ji ,jj+1,jk) - fsdept(ji+1,jj,jk) )988 ! back rotation989 zhpine(ji,jj,jk) = zcosa(ji,jj) * ( zhpitra(ji,jj,jk) + zuap ) &990 & - zsina(ji,jj) * ( zhpjtra(ji,jj,jk) + zvap )991 zhpjne(ji,jj,jk) = zsina(ji,jj) * ( zhpitra(ji,jj,jk) + zuap ) &992 & + zcosa(ji,jj) * ( zhpjtra(ji,jj,jk) + zvap )993 END DO994 END DO995 END DO996 997 ! interpolate and add to the general trend998 DO jk = 2, jpkm1999 DO jj = 2, jpjm11000 DO ji = fs_2, fs_jpim1 ! vector opt.1001 ! averaging1002 zhpirot(ji,jj,jk) = 0.5 * ( zhpine(ji,jj,jk) + zhpine(ji ,jj-1,jk) )1003 zhpjrot(ji,jj,jk) = 0.5 * ( zhpjne(ji,jj,jk) + zhpjne(ji-1,jj ,jk) )1004 ! add to the general momentum trend1005 ua(ji,jj,jk) = ua(ji,jj,jk) + zfrot * zhpirot(ji,jj,jk)1006 va(ji,jj,jk) = va(ji,jj,jk) + zfrot * zhpjrot(ji,jj,jk)1007 END DO1008 END DO1009 END DO1010 !1011 IF( wrk_not_released(2, 1,2,3) .OR. &1012 wrk_not_released(3, 1,2,3,4,5,6,7,8) ) CALL ctl_stop('dyn:hpg_rot: failed to release workspace arrays')1013 !1014 END SUBROUTINE hpg_rot1015 1016 1017 642 SUBROUTINE hpg_prj( kt ) 1018 643 !!--------------------------------------------------------------------- -
branches/2011/dev_NOC_UKMO_MERGE/NEMOGCM/SETTE/sette.sh
r2756 r3108 126 126 ## for (( config=2; config<=${NBTEST}; config++ )) 127 127 128 for config in 1 2 3 4 5 6 7 8 128 for config in 1 2 3 4 5 6 7 8 9 129 129 do 130 130 … … 414 414 fi 415 415 416 if [ ${config} -eq 9 ] ; then 417 # Restartability tests for AMM12 418 export TEST_NAME="LONG" 419 cd ${SETTE_DIR} 420 . ../CONFIG/makenemo -m ${CMP_NAM} -n AMM12 -r AMM12 421 cd ${SETTE_DIR} 422 . param.cfg 423 . all_functions.sh 424 . prepare_exe_dir.sh 425 cd ${EXE_DIR} 426 set_namelist namelist cn_exp \"AMM12_LONG\" 427 set_namelist namelist nn_it000 1 428 set_namelist namelist nn_itend 120 429 set_namelist namelist nn_stock 60 430 set_namelist namelist ln_clobber .true. 431 cd ${SETTE_DIR} 432 . ./fcm_job.sh input_AMM12.cfg 1 ${TEST_NAME} 433 434 cd ${SETTE_DIR} 435 export TEST_NAME="SHORT" 436 . prepare_exe_dir.sh 437 cd ${EXE_DIR} 438 set_namelist namelist cn_exp \"AMM12_SHORT\" 439 set_namelist namelist nn_it000 61 440 set_namelist namelist nn_itend 120 441 set_namelist namelist nn_stock 60 442 set_namelist namelist ln_rstart .true. 443 set_namelist namelist nn_rstctl 2 444 set_namelist namelist ln_clobber .true. 445 cp ..\/LONG\/AMM12_LONG_00000060_restart.nc . 446 set_namelist namelist cn_ocerst_in \"AMM12_LONG_00000060_restart.nc\" 447 cd ${SETTE_DIR} 448 . ./fcm_job.sh input_AMM12.cfg 1 ${TEST_NAME} 449 fi 416 450 done
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