function create_bryfile(bryname,grdname,title,obc,... theta_s,theta_b,hc,N,... time,cycle,clobber,vtransform); %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % function create_bryfile(bryname,grdname,title,obc... % theta_s,theta_b,hc,N,... % time,cycle,clobber); % % This function create the header of a Netcdf climatology % file. % % Input: % % bryname Netcdf climatology file name (character string). % grdname Netcdf grid file name (character string). % obc open boundaries flag (1=open , [S E N W]). % theta_s S-coordinate surface control parameter.(Real) % theta_b S-coordinate bottom control parameter.(Real) % hc Width (m) of surface or bottom boundary layer % where higher vertical resolution is required % during stretching.(Real) % N Number of vertical levels.(Integer) % time time.(vector) % cycle Length (days) for cycling the climatology.(Real) % clobber Switch to allow or not writing over an existing % file.(character string) % % Further Information: % http://www.croco-ocean.org % % This file is part of CROCOTOOLS % % CROCOTOOLS is free software; you can redistribute it and/or modify % it under the terms of the GNU General Public License as published % by the Free Software Foundation; either version 2 of the License, % or (at your option) any later version. % % CROCOTOOLS is distributed in the hope that it will be useful, but % WITHOUT ANY WARRANTY; without even the implied warranty of % MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the % GNU General Public License for more details. % % You should have received a copy of the GNU General Public License % along with this program; if not, write to the Free Software % Foundation, Inc., 59 Temple Place, Suite 330, Boston, % MA 02111-1307 USA % % Copyright (c) 2001-2006 by Pierrick Penven % e-mail:Pierrick.Penven@ird.fr % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% disp(' ') disp([' Creating the file : ',bryname]) disp(' ') if nargin < 12 disp([' NO VTRANSFORM parameter found']) disp([' USE TRANSFORM default value vtransform = 1']) vtransform = 1; end disp([' VTRANSFORM = ',num2str(vtransform)]) % % Read the grid file and check the topography % nc = netcdf(grdname, 'nowrite'); h=nc{'h'}(:); maskr=nc{'mask_rho'}(:); Lp=length(nc('xi_rho')); Mp=length(nc('eta_rho')); close(nc); hmin=min(min(h(maskr==1))); if vtransform ==1; if hc > hmin error([' hc (',num2str(hc),' m) > hmin (',num2str(hmin),' m)']) end end L=Lp-1; M=Mp-1; Np=N+1; % % Create the boundary file % type = 'BOUNDARY file' ; history = 'CROCO' ; nc = netcdf(bryname,clobber); %%result = redef(nc); % % Create dimensions % nc('xi_u') = L; nc('xi_v') = Lp; nc('xi_rho') = Lp; nc('eta_u') = Mp; nc('eta_v') = M; nc('eta_rho') = Mp; nc('s_rho') = N; nc('s_w') = Np; nc('tracer') = 2; nc('bry_time') = length(time); nc('tclm_time') = length(time); nc('temp_time') = length(time); nc('sclm_time') = length(time); nc('salt_time') = length(time); nc('uclm_time') = length(time); nc('vclm_time') = length(time); nc('v2d_time') = length(time); nc('v3d_time') = length(time); nc('ssh_time') = length(time); nc('zeta_time') = length(time); nc('one') = 1; % % Create variables and attributes % nc{'spherical'} = ncchar('one') ; nc{'spherical'}.long_name = ncchar('grid type logical switch'); nc{'spherical'}.long_name = 'grid type logical switch'; nc{'spherical'}.flag_values = ncchar('T, F'); nc{'spherical'}.flag_values = 'T, F'; nc{'spherical'}.flag_meanings = ncchar('spherical Cartesian'); nc{'spherical'}.flag_meanings = 'spherical Cartesian'; % nc{'Vtransform'} = ncint('one') ; nc{'Vtransform'}.long_name = ncchar('vertical terrain-following transformation equation'); nc{'Vtransform'}.long_name = 'vertical terrain-following transformation equation'; % nc{'Vstretching'} = ncint('one') ; nc{'Vstretching'}.long_name = ncchar('vertical terrain-following stretching function'); nc{'Vstretching'}.long_name = 'vertical terrain-following stretching function'; % nc{'tstart'} = ncdouble('one') ; nc{'tstart'}.long_name = ncchar('start processing day'); nc{'tstart'}.long_name = 'start processing day'; nc{'tstart'}.units = ncchar('day'); nc{'tstart'}.units = 'day'; % nc{'tend'} = ncdouble('one') ; nc{'tend'}.long_name = ncchar('end processing day'); nc{'tend'}.long_name = 'end processing day'; nc{'tend'}.units = ncchar('day'); nc{'tend'}.units = 'day'; % nc{'theta_s'} = ncdouble('one') ; nc{'theta_s'}.long_name = ncchar('S-coordinate surface control parameter'); nc{'theta_s'}.long_name = 'S-coordinate surface control parameter'; nc{'theta_s'}.units = ncchar('nondimensional'); nc{'theta_s'}.units = 'nondimensional'; % nc{'theta_b'} = ncdouble('one') ; nc{'theta_b'}.long_name = ncchar('S-coordinate bottom control parameter'); nc{'theta_b'}.long_name = 'S-coordinate bottom control parameter'; nc{'theta_b'}.units = ncchar('nondimensional'); nc{'theta_b'}.units = 'nondimensional'; % nc{'Tcline'} = ncdouble('one') ; nc{'Tcline'}.long_name = ncchar('S-coordinate surface/bottom layer width'); nc{'Tcline'}.long_name = 'S-coordinate surface/bottom layer width'; nc{'Tcline'}.units = ncchar('meter'); nc{'Tcline'}.units = 'meter'; % nc{'hc'} = ncdouble('one') ; nc{'hc'}.long_name = ncchar('S-coordinate parameter, critical depth'); nc{'hc'}.long_name = 'S-coordinate parameter, critical depth'; nc{'hc'}.units = ncchar('meter'); nc{'hc'}.units = 'meter'; % nc{'sc_r'} = ncdouble('s_rho') ; nc{'sc_r'}.long_name = ncchar('S-coordinate at RHO-points'); nc{'sc_r'}.long_name = 'S-coordinate at RHO-points'; nc{'sc_r'}.valid_min = -1.; nc{'sc_r'}.valid_max = 0.; nc{'sc_r'}.positive = ncchar('up'); nc{'sc_r'}.positive = 'up'; if (vtransform == 1) nc{'sc_r'}.standard_name = ncchar('ocena_s_coordinate_g1'); nc{'sc_r'}.standard_name = 'ocena_s_coordinate_g1'; elseif (vtransform == 2) nc{'sc_r'}.standard_name = ncchar('ocena_s_coordinate_g2'); nc{'sc_r'}.standard_name = 'ocena_s_coordinate_g2' end nc{'sc_r'}.formula_terms = ncchar('s: s_rho C: Cs_r eta: zeta depth: h depth_c: hc'); nc{'sc_r'}.formula_terms = 's: s_rho C: Cs_r eta: zeta depth: h depth_c: hc'; % nc{'sc_w'} = ncdouble('s_w') ; nc{'sc_w'}.long_name = ncchar('S-coordinate at W-points'); nc{'sc_w'}.long_name = 'S-coordinate at W-points'; nc{'sc_w'}.valid_min = -1. ; nc{'sc_w'}.valid_max = 0. ; nc{'sc_w'}.positive = ncchar('up'); nc{'sc_w'}.positive = 'up'; if (vtransform == 1) nc{'sc_w'}.standard_name = ncchar('ocena_s_coordinate_g1'); nc{'sc_w'}.standard_name = 'ocena_s_coordinate_g1'; elseif (vtransform == 2) nc{'sc_w'}.standard_name = ncchar('ocena_s_coordinate_g2'); nc{'sc_w'}.standard_name = 'ocena_s_coordinate_g2'; end nc{'sc_w'}.formula_terms = ncchar('s: s_w C: Cs_w eta: zeta depth: h depth_c: hc'); nc{'sc_w'}.formula_terms = 's: s_w C: Cs_w eta: zeta depth: h depth_c: hc'; % nc{'Cs_r'} = ncdouble('s_rho') ; nc{'Cs_r'}.long_name = ncchar('S-coordinate stretching curves at RHO-points'); nc{'Cs_r'}.long_name = 'S-coordinate stretching curves at RHO-points'; nc{'Cs_r'}.units = ncchar('nondimensional'); nc{'Cs_r'}.units = 'nondimensional'; nc{'Cs_r'}.valid_min = -1; nc{'Cs_r'}.valid_max = 0; % nc{'Cs_w'} = ncdouble('s_w') ; nc{'Cs_w'}.long_name = ncchar('S-coordinate stretching curves at W-points'); nc{'Cs_w'}.long_name = 'S-coordinate stretching curves at W-points'; nc{'Cs_w'}.units = ncchar('nondimensional'); nc{'Cs_w'}.units = 'nondimensional'; nc{'Cs_w'}.valid_min = -1; nc{'Cs_w'}.valid_max = 0; % nc{'bry_time'} = ncdouble('bry_time') ; nc{'bry_time'}.long_name = ncchar('time for boundary climatology'); nc{'bry_time'}.long_name = 'time for boundary climatology'; nc{'bry_time'}.units = ncchar('day'); nc{'bry_time'}.units = 'day'; nc{'bry_time'}.calendar = ncchar('360.0 days in every year'); nc{'bry_time'}.calendar = '360.0 days in every year'; nc{'bry_time'}.cycle_length = cycle; % nc{'tclm_time'} = ncdouble('tclm_time') ; nc{'tclm_time'}.long_name = ncchar('time for temperature climatology'); nc{'tclm_time'}.long_name = 'time for temperature climatology'; nc{'tclm_time'}.units = ncchar('day'); nc{'tclm_time'}.units = 'day'; nc{'tclm_time'}.calendar = ncchar('360.0 days in every year'); nc{'tclm_time'}.calendar = '360.0 days in every year'; nc{'tclm_time'}.cycle_length = cycle; % nc{'temp_time'} = ncdouble('temp_time') ; nc{'temp_time'}.long_name = ncchar('time for temperature climatology'); nc{'temp_time'}.long_name = 'time for temperature climatology'; nc{'temp_time'}.units = ncchar('day'); nc{'temp_time'}.units = 'day'; nc{'temp_time'}.calendar = ncchar('360.0 days in every year'); nc{'temp_time'}.calendar = '360.0 days in every year'; nc{'temp_time'}.cycle_length = cycle; % nc{'sclm_time'} = ncdouble('sclm_time') ; nc{'sclm_time'}.long_name = ncchar('time for salinity climatology'); nc{'sclm_time'}.long_name = 'time for salinity climatology'; nc{'sclm_time'}.units = ncchar('day'); nc{'sclm_time'}.units = 'day'; nc{'sclm_time'}.calendar = ncchar('360.0 days in every year'); nc{'sclm_time'}.calendar = '360.0 days in every year'; nc{'sclm_time'}.cycle_length = cycle; % nc{'salt_time'} = ncdouble('salt_time') ; nc{'salt_time'}.long_name = ncchar('time for salinity climatology'); nc{'salt_time'}.long_name = 'time for salinity climatology'; nc{'salt_time'}.units = ncchar('day'); nc{'salt_time'}.units = 'day'; nc{'salt_time'}.calendar = ncchar('360.0 days in every year'); nc{'salt_time'}.calendar = '360.0 days in every year'; nc{'salt_time'}.cycle_length = cycle; % nc{'uclm_time'} = ncdouble('uclm_time') ; nc{'uclm_time'}.long_name = ncchar('time climatological u'); nc{'uclm_time'}.long_name = 'time climatological u'; nc{'uclm_time'}.units = ncchar('day'); nc{'uclm_time'}.units = 'day'; nc{'uclm_time'}.calendar = ncchar('360.0 days in every year'); nc{'uclm_time'}.calendar = '360.0 days in every year'; nc{'uclm_time'}.cycle_length = cycle; % nc{'vclm_time'} = ncdouble('vclm_time') ; nc{'vclm_time'}.long_name = ncchar('time climatological v'); nc{'vclm_time'}.long_name = 'time climatological v'; nc{'vclm_time'}.units = ncchar('day'); nc{'vclm_time'}.units = 'day'; nc{'vclm_time'}.calendar = ncchar('360.0 days in every year'); nc{'vclm_time'}.calendar = '360.0 days in every year'; nc{'vclm_time'}.cycle_length = cycle; % nc{'v2d_time'} = ncdouble('v2d_time') ; nc{'v2d_time'}.long_name = ncchar('time for 2D velocity climatology'); nc{'v2d_time'}.long_name = 'time for 2D velocity climatology'; nc{'v2d_time'}.units = ncchar('day'); nc{'v2d_time'}.units = 'day'; nc{'v2d_time'}.calendar = ncchar('360.0 days in every year'); nc{'v2d_time'}.calendar = '360.0 days in every year'; nc{'v2d_time'}.cycle_length = cycle; % nc{'v3d_time'} = ncdouble('v3d_time') ; nc{'v3d_time'}.long_name = ncchar('time for 3D velocity climatology'); nc{'v3d_time'}.long_name = 'time for 3D velocity climatology'; nc{'v3d_time'}.units = ncchar('day'); nc{'v3d_time'}.units = 'day'; nc{'v3d_time'}.calendar = ncchar('360.0 days in every year'); nc{'v3d_time'}.calendar = '360.0 days in every year'; nc{'v3d_time'}.cycle_length = cycle; % nc{'ssh_time'} = ncdouble('ssh_time') ; nc{'ssh_time'}.long_name = ncchar('time for sea surface height'); nc{'ssh_time'}.long_name = 'time for sea surface height'; nc{'ssh_time'}.units = ncchar('day'); nc{'ssh_time'}.units = 'day'; nc{'ssh_time'}.calendar = ncchar('360.0 days in every year'); nc{'ssh_time'}.calendar = '360.0 days in every year'; nc{'ssh_time'}.cycle_length = cycle; % nc{'zeta_time'} = ncdouble('zeta_time') ; nc{'zeta_time'}.long_name = ncchar('time for sea surface height'); nc{'zeta_time'}.long_name = 'time for sea surface height'; nc{'zeta_time'}.units = ncchar('day'); nc{'zeta_time'}.units = 'day'; nc{'zeta_time'}.calendar = ncchar('360.0 days in every year'); nc{'zeta_time'}.calendar = '360.0 days in every year'; nc{'zeta_time'}.cycle_length = cycle; % if obc(1)==1 % % Southern boundary % nc{'temp_south'} = ncdouble('temp_time','s_rho','xi_rho') ; nc{'temp_south'}.long_name = ncchar('southern boundary potential temperature'); nc{'temp_south'}.long_name = 'southern boundary potential temperature'; nc{'temp_south'}.units = ncchar('Celsius'); nc{'temp_south'}.units = 'Celsius'; nc{'temp_south'}.coordinates = ncchar('lon_rho s_rho temp_time'); nc{'temp_south'}.coordinates = 'lon_rho s_rho temp_time'; % nc{'salt_south'} = ncdouble('salt_time','s_rho','xi_rho') ; nc{'salt_south'}.long_name = ncchar('southern boundary salinity'); nc{'salt_south'}.long_name = 'southern boundary salinity'; nc{'salt_south'}.units = ncchar('PSU'); nc{'salt_south'}.units = 'PSU'; nc{'salt_south'}.coordinates = ncchar('lon_rho s_rho salt_time'); nc{'salt_south'}.coordinates = 'lon_rho s_rho salt_time'; % nc{'u_south'} = ncdouble('v3d_time','s_rho','xi_u') ; nc{'u_south'}.long_name = ncchar('southern boundary u-momentum component'); nc{'u_south'}.long_name = 'southern boundary u-momentum component'; nc{'u_south'}.units = ncchar('meter second-1'); nc{'u_south'}.units = 'meter second-1'; nc{'u_south'}.coordinates = ncchar('lon_u s_rho uclm_time'); nc{'u_south'}.coordinates = 'lon_u s_rho u_time'; % nc{'v_south'} = ncdouble('v3d_time','s_rho','xi_rho') ; nc{'v_south'}.long_name = ncchar('southern boundary v-momentum component'); nc{'v_south'}.long_name = 'southern boundary v-momentum component'; nc{'v_south'}.units = ncchar('meter second-1'); nc{'v_south'}.units = 'meter second-1'; nc{'v_south'}.coordinates = ncchar('lon_v s_rho vclm_time'); nc{'v_south'}.coordinates = 'lon_v s_rho vclm_time'; % nc{'ubar_south'} = ncdouble('v2d_time','xi_u') ; nc{'ubar_south'}.long_name = ncchar('southern boundary vertically integrated u-momentum component'); nc{'ubar_south'}.long_name = 'southern boundary vertically integrated u-momentum component'; nc{'ubar_south'}.units = ncchar('meter second-1'); nc{'ubar_south'}.units = 'meter second-1'; nc{'ubar_south'}.coordinates = ncchar('lon_u uclm_time'); nc{'ubar_south'}.coordinates = 'lon_u uclm_time'; % nc{'vbar_south'} = ncdouble('v2d_time','xi_rho') ; nc{'vbar_south'}.long_name = ncchar('southern boundary vertically integrated v-momentum component'); nc{'vbar_south'}.long_name = 'southern boundary vertically integrated v-momentum component'; nc{'vbar_south'}.units = ncchar('meter second-1'); nc{'vbar_south'}.units = 'meter second-1'; nc{'vbar_south'}.coordinates = ncchar('lon_v vclm_time'); nc{'vbar_south'}.coordinates = 'lon_v vclm_time'; % nc{'zeta_south'} = ncdouble('zeta_time','xi_rho') ; nc{'zeta_south'}.long_name = ncchar('southern boundary sea surface height'); nc{'zeta_south'}.long_name = 'southern boundary sea surface height'; nc{'zeta_south'}.units = ncchar('meter'); nc{'zeta_south'}.units = 'meter'; nc{'zeta_south'}.coordinates = ncchar('lon_rho zeta_time'); nc{'zeta_south'}.coordinates = 'lon_rho zeta_time'; % end % if obc(2)==1 % % Eastern boundary % nc{'temp_east'} = ncdouble('temp_time','s_rho','eta_rho') ; nc{'temp_east'}.long_name = ncchar('eastern boundary potential temperature'); nc{'temp_east'}.long_name = 'eastern boundary potential temperature'; nc{'temp_east'}.units = ncchar('Celsius'); nc{'temp_east'}.units = 'Celsius'; nc{'temp_east'}.coordinates = ncchar('lat_rho s_rho temp_time'); nc{'temp_east'}.coordinates = 'lat_rho s_rho temp_time'; % nc{'salt_east'} = ncdouble('salt_time','s_rho','eta_rho') ; nc{'salt_east'}.long_name = ncchar('eastern boundary salinity'); nc{'salt_east'}.long_name = 'eastern boundary salinity'; nc{'salt_east'}.units = ncchar('PSU'); nc{'salt_east'}.units = 'PSU'; nc{'salt_east'}.coordinates = ncchar('lat_rho s_rho salt_time'); nc{'salt_east'}.coordinates = 'lat_rho s_rho salt_time'; % nc{'u_east'} = ncdouble('v3d_time','s_rho','eta_rho') ; nc{'u_east'}.long_name = ncchar('eastern boundary u-momentum component'); nc{'u_east'}.long_name = 'eastern boundary u-momentum component'; nc{'u_east'}.units = ncchar('meter second-1'); nc{'u_east'}.units = 'meter second-1'; nc{'u_east'}.coordinates = ncchar('lat_u s_rho uclm_time'); nc{'u_east'}.coordinates = 'lat_u s_rho u_time'; % nc{'v_east'} = ncdouble('v3d_time','s_rho','eta_v') ; nc{'v_east'}.long_name = ncchar('eastern boundary v-momentum component'); nc{'v_east'}.long_name = 'eastern boundary v-momentum component'; nc{'v_east'}.units = ncchar('meter second-1'); nc{'v_east'}.units = 'meter second-1'; nc{'v_east'}.coordinates = ncchar('lat_v s_rho vclm_time'); nc{'v_east'}.coordinates = 'lat_v s_rho vclm_time'; % nc{'ubar_east'} = ncdouble('v2d_time','eta_rho') ; nc{'ubar_east'}.long_name = ncchar('eastern boundary vertically integrated u-momentum component'); nc{'ubar_east'}.long_name = 'eastern boundary vertically integrated u-momentum component'; nc{'ubar_east'}.units = ncchar('meter second-1'); nc{'ubar_east'}.units = 'meter second-1'; nc{'ubar_east'}.coordinates = ncchar('lat_u uclm_time'); nc{'ubar_east'}.coordinates = 'lat_u uclm_time'; % nc{'vbar_east'} = ncdouble('v2d_time','eta_v') ; nc{'vbar_east'}.long_name = ncchar('eastern boundary vertically integrated v-momentum component'); nc{'vbar_east'}.long_name = 'eastern boundary vertically integrated v-momentum component'; nc{'vbar_east'}.units = ncchar('meter second-1'); nc{'vbar_east'}.units = 'meter second-1'; nc{'vbar_east'}.coordinates = ncchar('lat_v vclm_time'); nc{'vbar_east'}.coordinates = 'lat_v vclm_time'; % nc{'zeta_east'} = ncdouble('zeta_time','eta_rho') ; nc{'zeta_east'}.long_name = ncchar('eastern boundary sea surface height'); nc{'zeta_east'}.long_name = 'eastern boundary sea surface height'; nc{'zeta_east'}.units = ncchar('meter'); nc{'zeta_east'}.units = 'meter'; nc{'zeta_east'}.coordinates = ncchar('lat_rho zeta_time'); nc{'zeta_east'}.coordinates = 'lat_rho zeta_time'; % end % if obc(3)==1 % % Northern boundary % nc{'temp_north'} = ncdouble('temp_time','s_rho','xi_rho') ; nc{'temp_north'}.long_name = ncchar('northern boundary potential temperature'); nc{'temp_north'}.long_name = 'northern boundary potential temperature'; nc{'temp_north'}.units = ncchar('Celsius'); nc{'temp_north'}.units = 'Celsius'; nc{'temp_north'}.coordinates = ncchar('lon_rho s_rho temp_time'); nc{'temp_north'}.coordinates = 'lon_rho s_rho temp_time'; % nc{'salt_north'} = ncdouble('salt_time','s_rho','xi_rho') ; nc{'salt_north'}.long_name = ncchar('northern boundary salinity'); nc{'salt_north'}.long_name = 'northern boundary salinity'; nc{'salt_north'}.units = ncchar('PSU'); nc{'salt_north'}.units = 'PSU'; nc{'salt_north'}.coordinates = ncchar('lon_rho s_rho salt_time'); nc{'salt_north'}.coordinates = 'lon_rho s_rho salt_time'; % nc{'u_north'} = ncdouble('v3d_time','s_rho','xi_u') ; nc{'u_north'}.long_name = ncchar('northern boundary u-momentum component'); nc{'u_north'}.long_name = 'northern boundary u-momentum component'; nc{'u_north'}.units = ncchar('meter second-1'); nc{'u_north'}.units = 'meter second-1'; nc{'u_north'}.coordinates = ncchar('lon_u s_rho uclm_time'); nc{'u_north'}.coordinates = 'lon_u s_rho u_time'; % nc{'v_north'} = ncdouble('v3d_time','s_rho','xi_rho') ; nc{'v_north'}.long_name = ncchar('northern boundary v-momentum component'); nc{'v_north'}.long_name = 'northern boundary v-momentum component'; nc{'v_north'}.units = ncchar('meter second-1'); nc{'v_north'}.units = 'meter second-1'; nc{'v_north'}.coordinates = ncchar('lon_v s_rho vclm_time'); nc{'v_north'}.coordinates = 'lon_v s_rho vclm_time'; % nc{'ubar_north'} = ncdouble('v2d_time','xi_u') ; nc{'ubar_north'}.long_name = ncchar('northern boundary vertically integrated u-momentum component'); nc{'ubar_north'}.long_name = 'northern boundary vertically integrated u-momentum component'; nc{'ubar_north'}.units = ncchar('meter second-1'); nc{'ubar_north'}.units = 'meter second-1'; nc{'ubar_north'}.coordinates = ncchar('lon_u uclm_time'); nc{'ubar_north'}.coordinates = 'lon_u uclm_time'; % nc{'vbar_north'} = ncdouble('v2d_time','xi_rho') ; nc{'vbar_north'}.long_name = ncchar('northern boundary vertically integrated v-momentum component'); nc{'vbar_north'}.long_name = 'northern boundary vertically integrated v-momentum component'; nc{'vbar_north'}.units = ncchar('meter second-1'); nc{'vbar_north'}.units = 'meter second-1'; nc{'vbar_north'}.coordinates = ncchar('lon_v vclm_time'); nc{'vbar_north'}.coordinates = 'lon_v vclm_time'; nc{'zeta_north'} = ncdouble('zeta_time','xi_rho') ; nc{'zeta_north'}.long_name = ncchar('northern boundary sea surface height'); nc{'zeta_north'}.long_name = 'northern boundary sea surface height'; nc{'zeta_north'}.units = ncchar('meter'); nc{'zeta_north'}.units = 'meter'; nc{'zeta_north'}.coordinates = ncchar('lon_rho zeta_time'); nc{'zeta_north'}.coordinates = 'lon_rho zeta_time'; % end % if obc(4)==1 % % Western boundary % nc{'temp_west'} = ncdouble('temp_time','s_rho','eta_rho') ; nc{'temp_west'}.long_name = ncchar('western boundary potential temperature'); nc{'temp_west'}.long_name = 'western boundary potential temperature'; nc{'temp_west'}.units = ncchar('Celsius'); nc{'temp_west'}.units = 'Celsius'; nc{'temp_west'}.coordinates = ncchar('lat_rho s_rho temp_time'); nc{'temp_west'}.coordinates = 'lat_rho s_rho temp_time'; % nc{'salt_west'} = ncdouble('salt_time','s_rho','eta_rho') ; nc{'salt_west'}.long_name = ncchar('western boundary salinity'); nc{'salt_west'}.long_name = 'western boundary salinity'; nc{'salt_west'}.units = ncchar('PSU'); nc{'salt_west'}.units = 'PSU'; nc{'salt_west'}.coordinates = ncchar('lat_rho s_rho salt_time'); nc{'salt_west'}.coordinates = 'lat_rho s_rho salt_time'; % nc{'u_west'} = ncdouble('v3d_time','s_rho','eta_rho') ; nc{'u_west'}.long_name = ncchar('western boundary u-momentum component'); nc{'u_west'}.long_name = 'western boundary u-momentum component'; nc{'u_west'}.units = ncchar('meter second-1'); nc{'u_west'}.units = 'meter second-1'; nc{'u_west'}.coordinates = ncchar('lat_u s_rho uclm_time'); nc{'u_west'}.coordinates = 'lat_u s_rho u_time'; % nc{'v_west'} = ncdouble('v3d_time','s_rho','eta_v') ; nc{'v_west'}.long_name = ncchar('western boundary v-momentum component'); nc{'v_west'}.long_name = 'western boundary v-momentum component'; nc{'v_west'}.units = ncchar('meter second-1'); nc{'v_west'}.units = 'meter second-1'; nc{'v_west'}.coordinates = ncchar('lat_v s_rho vclm_time'); nc{'v_west'}.coordinates = 'lat_v s_rho vclm_time'; % nc{'ubar_west'} = ncdouble('v2d_time','eta_rho') ; nc{'ubar_west'}.long_name = ncchar('western boundary vertically integrated u-momentum component'); nc{'ubar_west'}.long_name = 'western boundary vertically integrated u-momentum component'; nc{'ubar_west'}.units = ncchar('meter second-1'); nc{'ubar_west'}.units = 'meter second-1'; nc{'ubar_west'}.coordinates = ncchar('lat_u uclm_time'); nc{'ubar_west'}.coordinates = 'lat_u uclm_time'; % nc{'vbar_west'} = ncdouble('v2d_time','eta_v') ; nc{'vbar_west'}.long_name = ncchar('western boundary vertically integrated v-momentum component'); nc{'vbar_west'}.long_name = 'western boundary vertically integrated v-momentum component'; nc{'vbar_west'}.units = ncchar('meter second-1'); nc{'vbar_west'}.units = 'meter second-1'; nc{'vbar_west'}.coordinates = ncchar('lat_v vclm_time'); nc{'vbar_west'}.coordinates = 'lat_v vclm_time'; % nc{'zeta_west'} = ncdouble('zeta_time','eta_rho') ; nc{'zeta_west'}.long_name = ncchar('western boundary sea surface height'); nc{'zeta_west'}.long_name = 'western boundary sea surface height'; nc{'zeta_west'}.units = ncchar('meter'); nc{'zeta_west'}.units = 'meter'; nc{'zeta_west'}.coordinates = ncchar('lat_rho zeta_time'); nc{'zeta_west'}.coordinates = 'lat_rho zeta_time'; % end % % % Create global attributes % nc.title = ncchar(title); nc.title = title; nc.date = ncchar(date); nc.date = date; nc.clim_file = ncchar(bryname); nc.clim_file = bryname; nc.grd_file = ncchar(grdname); nc.grd_file = grdname; nc.type = ncchar(type); nc.type = type; nc.history = ncchar(history); nc.history = history; % % Leave define mode % %%result = endef(nc); % % Compute S coordinates % [sc_r,Cs_r,sc_w,Cs_w] = scoordinate(theta_s,theta_b,N,hc,vtransform); %disp(['vtransform=',num2str(vtransform)]) % % Write variables % nc{'spherical'}(:)='T'; nc{'Vtransform'}(:)=vtransform; nc{'Vstretching'}(:)=1; nc{'tstart'}(:) = min([min(time) min(time) min(time)]); nc{'tend'}(:) = max([max(time) max(time) max(time)]); nc{'theta_s'}(:) = theta_s; nc{'theta_b'}(:) = theta_b; nc{'Tcline'}(:) = hc; nc{'hc'}(:) = hc; nc{'sc_r'}(:) = sc_r; nc{'sc_w'}(:) = sc_w; nc{'Cs_r'}(:) = Cs_r ; nc{'Cs_w'}(:) = Cs_w; nc{'tclm_time'}(:) = time; nc{'temp_time'}(:) = time; nc{'sclm_time'}(:) = time; nc{'salt_time'}(:) = time; nc{'uclm_time'}(:) = time; nc{'vclm_time'}(:) = time; nc{'v2d_time'}(:) = time; nc{'v3d_time'}(:) = time; nc{'ssh_time'}(:) = time; nc{'zeta_time'}(:) = time; nc{'bry_time'}(:) = time; if obc(1)==1 nc{'u_south'}(:) = 0; nc{'v_south'}(:) = 0; nc{'ubar_south'}(:) = 0; nc{'vbar_south'}(:) = 0; nc{'zeta_south'}(:) = 0; nc{'temp_south'}(:) = 0; nc{'salt_south'}(:) = 0; end if obc(2)==1 nc{'u_east'}(:) = 0; nc{'v_east'}(:) = 0; nc{'ubar_east'}(:) = 0; nc{'vbar_east'}(:) = 0; nc{'zeta_east'}(:) = 0; nc{'temp_east'}(:) = 0; nc{'salt_east'}(:) = 0; end if obc(3)==1 nc{'u_north'}(:) = 0; nc{'v_north'}(:) = 0; nc{'ubar_north'}(:) = 0; nc{'vbar_north'}(:) = 0; nc{'zeta_north'}(:) = 0; nc{'temp_north'}(:) = 0; nc{'salt_north'}(:) = 0; end if obc(4)==1 nc{'u_west'}(:) = 0; nc{'v_west'}(:) = 0; nc{'ubar_west'}(:) = 0; nc{'vbar_west'}(:) = 0; nc{'zeta_west'}(:) = 0; nc{'temp_west'}(:) = 0; nc{'salt_west'}(:) = 0; end close(nc) return