I've just encountered a problem on converting *.mat file to *.nc file.
The *.mat(say,seagrid.mat) file was created by seagrid.
So I used the command:
seagrid2roms('seagrid.mat',grdfile);
However,the converting process went wrong.Here are the error message:
## SeaGrid Source File : ~/tools/test-data/seagrid.mat
## ROMS Destination File: ../test-data/test-grid.nc
Error in ==> mexnc at 1
function [varargout] = mexnc ( varargin )
??? Error using ==> feval
Output argument "varargout" (and maybe others) not assigned during call to
"/home/jerry/tools/Roms_tools_3/mexnc/mexnc.m>mexnc".
Error in ==> mexcdf53 at 9
[varargout{:}] = feval('mexnc', varargin{:});
Error in ==> ncmex at 139
[varargout{:}] = feval(fcn, varargin{:});
Error in ==> netcdf.create at 13
[theNCid, status] = ncmex('create', name(self), thePermission);
Error in ==> netcdf.netcdf at 413
result = create(result, thePermission);
Error in ==> seagrid2roms at 152
nc = netcdf(theRomsFile, 'clobber');
Someone help me!
Thank you!
Problems on converting *.mat file to *.nc file
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Re: Problems on converting *.mat file to *.nc file
Have you installed the tools for netcdf successfully? For my MATLAB (R2011a), the tools needed are mexcdf (mexnc and snctools) and netcdf_toolbox.
Hope this can help you.
Qian
Hope this can help you.
Qian
Qianqian@URI
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- Posts: 9
- Joined: Tue Jul 05, 2011 2:47 pm
- Location: Prooceano
Re: Problems on converting *.mat file to *.nc file
Hi,
try to use the script "seagrid2roms_new.m", instead of the "seagrid2roms.m" that you are using.
When I downloaded the seagrid, this script came together and is more compatible with my netcdf matlab packages.
good luck,
Gabriel Carvalho
Oceanographer - Rio de Janeiro
P.S: In case you don't have it:
function seagrid2roms_ML(theSeagridFile, theRomsFile,...
theGridTitle,theInterpMethod,FLIPPING)
% seagrid2roms -- Output ROMS format from SeaGrid file.
% Usage: seagrid2roms(theSeagridFile, theRomsFile,...
% theGridTitle, theInterpMethod);
% Inputs:
% theSeagridFile = name of seagrid output file (string)
% theRomsFile = name of Roms Grid file to be created (string)
% theGridTitle = title of grid (string)
% theInterpMethod = interp2d method used to double grid (string)
% Can be "linear" or "spline" (default is spline)
% Use "linear" for seagrid.mat files originating
% from Delft grids, which have info only on
% the wet cells.
% FLIPPING = should be 1 (default) for files produced by seagrid
% or 0 for files converted from Delft3D grids
%
% If '*' is input for theSeagridFile or theRomsFile, dialog boxes are
% invoked.
%
% NOTE: this routine does not employ _FillValue attributes
% in the output NetCDF variables.
%
% Disclosure without explicit written consent from the
% copyright owner does not constitute publication.
% Version of 18-Jun-1999 17:11:59. by Chuck Denham
% Updated 28-Oct-2002 10:12:55.
% Updated 14-Apr-2004 10:12:55. by Rich Signell
% - grid doubling now only in projected coordinate
% - distances between grid points now calculated from lon/lat values on spherical earth
% The default earth radius is
% assumed to be 6371*1000 meters, the radius for
% a sphere of equal-volume, the same default as "earthdist.m".
RADIAN_CONVERSION_FACTOR = 180/pi;
EARTH_RADIUS_METERS = 6371*1000; % Equatorial radius.
if nargin < 1, theSeagridFile = '*.mat'; end
if nargin < 2, theRomsFile = 'roms_grd.nc'; end
if nargin < 3, theGridTitle = char(zeros(1, 128)+abs(' ')); end
if isempty(theSeagridFile) | any(theSeagridFile == '*')
[f, p] = uigetfile(theSeagridFile, 'Select SeaGrid File:');
if ~any(f), return, end
if p(end) ~= filesep, p(end+1) = filesep; end
theSeagridFile = [p f]
end
if nargin < 2 | isempty(theSeagridFile) | any(theRomsFile == '*')
[f, p] = uiputfile(theRomsFile, 'Save to Roms File:');
if ~any(f), return, end
if p(end) ~= filesep, p(end+1) = filesep; end
theRomsFile = [p f]
end
disp([' ## SeaGrid Source File : ' theSeagridFile])
disp([' ## ROMS Destination File: ' theRomsFile])
% Load the SeaGrid file and get parameters.
try
theSeagridData = load(theSeagridFile, 's');
catch
disp([' ## Unable to load: "' theSeagridFile '"'])
return
end
% With grid_x of size [m, n], the grid itself has
% [m-1, n-1] cells. The latter size corresponds
% to the size of the mask and bathymetry. These
% cell-centers are called the "rho" points.
s = theSeagridData.s;
grid_x = s.grids{1} * EARTH_RADIUS_METERS;
grid_y = s.grids{2} * EARTH_RADIUS_METERS;
[m, n] = size(grid_x);
geogrid_lon = s.geographic_grids{1};
geogrid_lat = s.geographic_grids{2};
geometry = s.geometry;
mask = s.mask; % land = 1; water = 0.
if ~isequal(size(mask), size(grid_x)-1)
if ~isempty(mask)
disp(' ## Wrong size mask.')
end
mask = zeros(m-1, n-1);
end
mask = ~~mask;
land = mask;
water = ~land;
bathymetry = s.gridded_bathymetry;
projection = s.projection;
ang = s.orientation * pi / 180; % ROMS needs radians.
min_depth = s.clipping_depths(1);
max_depth = s.clipping_depths(2);
% Clip Bathymetry
bathymetry(find(isnan(bathymetry))) = min_depth;
bathymetry(bathymetry<min_depth) = min_depth;
bathymetry(bathymetry>max_depth) = max_depth;
% Double the grid-size before proceeding.
% The grid-cell-centers are termed the "rho" points.
theInterpFcn = 'interp2';
if nargin<4,
theInterpMethod = 'spline';
%theInterpMethod = 'linear';
end
grid_x = feval(theInterpFcn, grid_x, 1, theInterpMethod);
grid_y = feval(theInterpFcn, grid_y, 1, theInterpMethod);
geogrid_lon = feval(theInterpFcn, geogrid_lon, 1, theInterpMethod);
geogrid_lat = feval(theInterpFcn, geogrid_lat, 1, theInterpMethod);
% The present size of the grid nodes.
[n, m] = size(grid_x);
% Flip arrays top for bottom.
if (nargin<5)
FLIPPING = 1; % for files from Seagrid
%FLIPPING = 0; % for files from Delft3D conversion
end
if FLIPPING
grid_x = flipud(grid_x);
grid_y = flipud(grid_y);
geogrid_lon = flipud(geogrid_lon);
geogrid_lat = flipud(geogrid_lat);
geometry{1} = flipud(geometry{1});
geometry{2} = flipud(geometry{2});
mask = flipud(mask);
bathymetry = flipud(bathymetry);
ang = flipud(ang);
end
xl = max(grid_x(:)) - min(grid_x(:));
el = max(grid_y(:)) - min(grid_y(:));
% Create the Roms NetCDF file.
% nc = netcdf(theRomsFile, 'clobber');
ncid = netcdf.create(theRomsFile,'NC_CLOBBER');
if isempty(ncid), return, end
%% Global attributes:
disp(' ## Defining Global Attributes...')
% nc.type = ncchar('Gridpak file');
% nc.gridid = theGridTitle;
% nc.history = ncchar(['Created by "' mfilename '" on ' datestr(now)]);
%
% nc.CPP_options = ncchar('DCOMPLEX, DBLEPREC, NCARG_32, PLOTS,');
% name(nc.CPP_options, 'CPP-options')
% The SeaGrid is now a full array, whose height
% and width are odd-valued. We extract staggered
% sub-grids for the Roms scheme, ignoring the
% outermost rows and columns. Thus, the so-called
% "rho" points correspond to the even-numbered points
% in an (i, j) Matlab array. The "psi" points begin
% at i = 3 and j = 3. The whole set is indexed as
% follows:
% rho (2:2:end-1, 2:2:end-1), i.e. (2:2:m, 2:2:n), etc.
% psi (3:2:end-2, 3:2:end-2)
% u (2:2:end-1, 3:2:end-2)
% v (3:2:end-2, 2:2:end-1)
if ~rem(m, 2), m = m-1; end % m, n must be odd.
if ~rem(n, 2), n = n-1; end
i_rho = 2:2:m-1; j_rho = 2:2:n-1;
i_psi = 3:2:m-2; j_psi = 3:2:n-2;
i_u = 3:2:m-2; j_u = 2:2:n-1;
i_v = 2:2:m-1; j_v = 3:2:n-2;
% The xi direction (left-right):
Lp = (m-1)/2; % The rho dimension.
L = Lp-1; % The psi dimension.
% The eta direction (up-down):
Mp = (n-1)/2; % The rho dimension.
M = Mp-1; % The psi dimension.
disp(' ## Defining Dimensions...')
xi_rho_ID = netcdf.defDim(ncid,'xi_rho',Lp);
xi_u_ID = netcdf.defDim(ncid,'xi_u',L);
xi_psi_ID = netcdf.defDim(ncid,'xi_psi',L);
xi_v_ID = netcdf.defDim(ncid,'xi_v',Lp);
eta_rho_ID = netcdf.defDim(ncid,'eta_rho',Mp);
eta_u_ID = netcdf.defDim(ncid,'eta_u',Mp);
eta_v_ID = netcdf.defDim(ncid,'eta_v',M);
eta_psi_ID = netcdf.defDim(ncid,'eta_psi',M);
one_ID = netcdf.defDim(ncid,'one',1);
two_ID = netcdf.defDim(ncid,'two',2);
bath_ID = netcdf.defDim(ncid,'bath',netcdf.getConstant('NC_UNLIMITED'));
% bath_ID = netcdf.defDim(ncid,'bath',0);
%% Variables and attributes:
disp(' ## Defining Variables and Attributes...')
xl_var_ID = netcdf.defVar(ncid,'xl','double',one_ID);
netcdf.putAtt(ncid,xl_var_ID,'long_name','domain length in the XI-direction')
netcdf.putAtt(ncid,xl_var_ID,'units','meter')
el_var_ID = netcdf.defVar(ncid,'el','double',one_ID);
netcdf.putAtt(ncid,el_var_ID,'long_name','domain length in the ETA-direction')
netcdf.putAtt(ncid,el_var_ID,'units','meter')
JPRJ_var_ID = netcdf.defVar(ncid,'JPRJ','char',two_ID);
netcdf.putAtt(ncid,JPRJ_var_ID,'long_name','Map projection type')
netcdf.putAtt(ncid,JPRJ_var_ID,'option_ME_','Mercator')
netcdf.putAtt(ncid,JPRJ_var_ID,'option_ST_','Stereographic')
netcdf.putAtt(ncid,JPRJ_var_ID,'option_LC_','Lambert conformal conic')
netcdf.renameAtt(ncid,JPRJ_var_ID,'option_ME_','option(ME)')
netcdf.renameAtt(ncid,JPRJ_var_ID,'option_ST_','option(ST)')
netcdf.renameAtt(ncid,JPRJ_var_ID,'option_LC_','option(LC)')
PLAT_var_ID = netcdf.defVar(ncid,'PLAT','float',two_ID);
netcdf.putAtt(ncid,PLAT_var_ID,'long_name','Reference latitude(s) for map projection')
netcdf.putAtt(ncid,PLAT_var_ID,'units','degree_north')
PLONG_var_ID = netcdf.defVar(ncid,'PLONG','float',one_ID);
netcdf.putAtt(ncid,PLONG_var_ID,'long_name','Reference longitude for map projection')
netcdf.putAtt(ncid,PLONG_var_ID,'units','degree_east')
ROTA_var_ID = netcdf.defVar(ncid,'ROTA','float',one_ID);
netcdf.putAtt(ncid,ROTA_var_ID,'long_name','Rotation angle for map projection')
netcdf.putAtt(ncid,ROTA_var_ID,'units','degree')
JLTS_var_ID = netcdf.defVar(ncid,'JLTS','char',two_ID);
netcdf.putAtt(ncid,JLTS_var_ID,'long_name','How limits of map are chosen')
netcdf.putAtt(ncid,JLTS_var_ID,'option_CO_','P1, .. P4 define two opposite corners')
netcdf.putAtt(ncid,JLTS_var_ID,'option_MA_','Maximum (whole world)')
netcdf.putAtt(ncid,JLTS_var_ID,'option_AN_','Angles - P1..P4 define angles to edge of domain')
netcdf.putAtt(ncid,JLTS_var_ID,'option_LI_','Limits - P1..P4 define limits in u,v space')
netcdf.renameAtt(ncid,JLTS_var_ID,'option_CO_','option(CO)')
netcdf.renameAtt(ncid,JLTS_var_ID,'option_MA_','option(MA)')
netcdf.renameAtt(ncid,JLTS_var_ID,'option_AN_','option(AN)')
netcdf.renameAtt(ncid,JLTS_var_ID,'option_LI_','option(LI)')
P1_var_ID = netcdf.defVar(ncid,'P1','float',one_ID);
netcdf.putAtt(ncid,P1_var_ID,'long_name','Map limit parameter number 1')
P2_var_ID = netcdf.defVar(ncid,'P2','float',one_ID);
netcdf.putAtt(ncid,P2_var_ID,'long_name','Map limit parameter number 2')
P3_var_ID = netcdf.defVar(ncid,'P3','float',one_ID);
netcdf.putAtt(ncid,P3_var_ID,'long_name','Map limit parameter number 3')
P4_var_ID = netcdf.defVar(ncid,'P4','float',one_ID);
netcdf.putAtt(ncid,P4_var_ID,'long_name','Map limit parameter number 4')
XOFF_var_ID = netcdf.defVar(ncid,'XOFF','float',one_ID);
netcdf.putAtt(ncid,XOFF_var_ID,'long_name','Offset in x direction')
netcdf.putAtt(ncid,XOFF_var_ID,'units','meter')
YOFF_var_ID = netcdf.defVar(ncid,'YOFF','float',one_ID);
netcdf.putAtt(ncid,YOFF_var_ID,'long_name','Offset in y direction')
netcdf.putAtt(ncid,YOFF_var_ID,'units','meter')
depthmin_var_ID = netcdf.defVar(ncid,'depthmin','short',one_ID);
netcdf.putAtt(ncid,depthmin_var_ID,'long_name','Shallow bathymetry clipping depth')
netcdf.putAtt(ncid,depthmin_var_ID,'units','meter')
depthmax_var_ID = netcdf.defVar(ncid,'depthmax','short',one_ID);
netcdf.putAtt(ncid,depthmax_var_ID,'long_name','Deep bathymetry clipping depth')
netcdf.putAtt(ncid,depthmax_var_ID,'units','meter')
spherical_var_ID = netcdf.defVar(ncid,'spherical','char',one_ID);
netcdf.putAtt(ncid,spherical_var_ID,'long_name','Grid type logical switch')
netcdf.putAtt(ncid,spherical_var_ID,'option_T_','spherical')
netcdf.putAtt(ncid,spherical_var_ID,'option_F_','cartesian')
netcdf.renameAtt(ncid,spherical_var_ID,'option_T_','option(T)')
netcdf.renameAtt(ncid,spherical_var_ID,'option_F_','option(F)')
hraw_var_ID = netcdf.defVar(ncid,'hraw','double',[xi_rho_ID eta_rho_ID bath_ID]);
netcdf.putAtt(ncid,hraw_var_ID,'long_name','Working bathymetry at RHO-points')
netcdf.putAtt(ncid,hraw_var_ID,'units','meter')
netcdf.putAtt(ncid,hraw_var_ID,'field','bath, scalar')
h_var_ID = netcdf.defVar(ncid,'h','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,h_var_ID,'long_name','Final bathymetry at RHO-points')
netcdf.putAtt(ncid,h_var_ID,'units','meter')
netcdf.putAtt(ncid,h_var_ID,'coordinates','lon_rho lat_rho')
netcdf.putAtt(ncid,h_var_ID,'field','bath,scalar')
f_var_ID = netcdf.defVar(ncid,'f','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,f_var_ID,'long_name','Coriolis parameter at RHO-points')
netcdf.putAtt(ncid,f_var_ID,'units','second-1')
netcdf.putAtt(ncid,f_var_ID,'coordinates','lon_rho lat_rho')
netcdf.putAtt(ncid,f_var_ID,'field','Coriolis,scalar')
pm_var_ID = netcdf.defVar(ncid,'pm','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,pm_var_ID,'long_name','curvilinear coordinate metric in XI')
netcdf.putAtt(ncid,pm_var_ID,'units','meter-1')
netcdf.putAtt(ncid,pm_var_ID,'field','pm, scalar')
pn_var_ID = netcdf.defVar(ncid,'pn','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,pn_var_ID,'long_name','curvilinear coordinate metric in ETA')
netcdf.putAtt(ncid,pn_var_ID,'units','meter-1')
netcdf.putAtt(ncid,pn_var_ID,'field','pn, scalar')
dndx_var_ID = netcdf.defVar(ncid,'dndx','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,dndx_var_ID,'long_name','xi derivative of inverse metric factor pn')
netcdf.putAtt(ncid,dndx_var_ID,'units','meter')
netcdf.putAtt(ncid,dndx_var_ID,'field','dndx, scalar')
dmde_var_ID = netcdf.defVar(ncid,'dmde','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,dmde_var_ID,'long_name','eta derivative of inverse metric factor pm')
netcdf.putAtt(ncid,dmde_var_ID,'units','meter')
netcdf.putAtt(ncid,dmde_var_ID,'field','dmde, scalar')
x_rho_var_ID = netcdf.defVar(ncid,'x_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,x_rho_var_ID,'long_name','x location of RHO-points')
netcdf.putAtt(ncid,x_rho_var_ID,'units','meter')
y_rho_var_ID = netcdf.defVar(ncid,'y_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,y_rho_var_ID,'long_name','y location of RHO-points')
netcdf.putAtt(ncid,y_rho_var_ID,'units','meter')
x_psi_var_ID = netcdf.defVar(ncid,'x_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,x_psi_var_ID,'long_name','x location of PSI-points')
netcdf.putAtt(ncid,x_psi_var_ID,'units','meter')
y_psi_var_ID = netcdf.defVar(ncid,'y_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,y_psi_var_ID,'long_name','y location of PSI-points')
netcdf.putAtt(ncid,y_psi_var_ID,'units','meter')
x_u_var_ID = netcdf.defVar(ncid,'x_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,x_u_var_ID,'long_name','x location of U-points')
netcdf.putAtt(ncid,x_u_var_ID,'units','meter')
y_u_var_ID = netcdf.defVar(ncid,'y_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,y_u_var_ID,'long_name','y location of U-points')
netcdf.putAtt(ncid,y_u_var_ID,'units','meter')
x_v_var_ID = netcdf.defVar(ncid,'x_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,x_v_var_ID,'long_name','x location of V-points')
netcdf.putAtt(ncid,x_v_var_ID,'units','meter')
y_v_var_ID = netcdf.defVar(ncid,'y_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,y_v_var_ID,'long_name','y location of V-points')
netcdf.putAtt(ncid,y_v_var_ID,'units','meter')
lat_rho_var_ID = netcdf.defVar(ncid,'lat_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,lat_rho_var_ID,'long_name','latitude of RHO-points')
netcdf.putAtt(ncid,lat_rho_var_ID,'units','degree_north')
lon_rho_var_ID = netcdf.defVar(ncid,'lon_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,lon_rho_var_ID,'long_name','longitude of RHO-points')
netcdf.putAtt(ncid,lon_rho_var_ID,'units','degree_east')
lat_psi_var_ID = netcdf.defVar(ncid,'lat_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,lat_psi_var_ID,'long_name','latitude of PSI-points')
netcdf.putAtt(ncid,lat_psi_var_ID,'units','degree_north')
lon_psi_var_ID = netcdf.defVar(ncid,'lon_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,lon_psi_var_ID,'long_name','longitude of PSI-points')
netcdf.putAtt(ncid,lon_psi_var_ID,'units','degree_north')
lat_u_var_ID = netcdf.defVar(ncid,'lat_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,lat_u_var_ID,'long_name','latitude of U-points')
netcdf.putAtt(ncid,lat_u_var_ID,'units','degree_north')
lon_u_var_ID = netcdf.defVar(ncid,'lon_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,lon_u_var_ID,'long_name','longitude of U-points')
netcdf.putAtt(ncid,lon_u_var_ID,'units','degree_north')
lat_v_var_ID = netcdf.defVar(ncid,'lat_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,lat_v_var_ID,'long_name','latitude of V-points')
netcdf.putAtt(ncid,lat_v_var_ID,'units','degree_north')
lon_v_var_ID = netcdf.defVar(ncid,'lon_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,lon_v_var_ID,'long_name','longitude of V-points')
netcdf.putAtt(ncid,lon_v_var_ID,'units','degree_east')
mask_rho_var_ID = netcdf.defVar(ncid,'mask_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,mask_rho_var_ID,'long_name','mask on RHO-points')
netcdf.putAtt(ncid,mask_rho_var_ID,'option_0_','land')
netcdf.putAtt(ncid,mask_rho_var_ID,'option_1_','water')
netcdf.renameAtt(ncid,mask_rho_var_ID,'option_0_','option(0)')
netcdf.renameAtt(ncid,mask_rho_var_ID,'option_1_','option(1)')
mask_u_var_ID = netcdf.defVar(ncid,'mask_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,mask_u_var_ID,'long_name','mask on U-points')
netcdf.putAtt(ncid,mask_u_var_ID,'option_0_','land')
netcdf.putAtt(ncid,mask_u_var_ID,'option_1_','water')
netcdf.renameAtt(ncid,mask_u_var_ID,'option_0_','option(0)')
netcdf.renameAtt(ncid,mask_u_var_ID,'option_1_','option(1)')
mask_v_var_ID = netcdf.defVar(ncid,'mask_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,mask_v_var_ID,'long_name','mask on V-points')
netcdf.putAtt(ncid,mask_v_var_ID,'option_0_','land')
netcdf.putAtt(ncid,mask_v_var_ID,'option_1_','water')
netcdf.renameAtt(ncid,mask_v_var_ID,'option_0_','option(0)')
netcdf.renameAtt(ncid,mask_v_var_ID,'option_1_','option(1)')
mask_psi_var_ID = netcdf.defVar(ncid,'mask_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,mask_psi_var_ID,'long_name','mask on PSI-points')
netcdf.putAtt(ncid,mask_psi_var_ID,'option_0_','land')
netcdf.putAtt(ncid,mask_psi_var_ID,'option_1_','water')
netcdf.renameAtt(ncid,mask_psi_var_ID,'option_0_','option(0)')
netcdf.renameAtt(ncid,mask_psi_var_ID,'option_1_','option(1)')
angle_var_ID = netcdf.defVar(ncid,'angle','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,angle_var_ID,'long_name','angle between xi axis and east')
netcdf.putAtt(ncid,angle_var_ID,'units','radian')
%end define mode
netcdf.endDef(ncid)
% Fill the variables with data.
disp(' ## Filling Variables...')
switch lower(projection)
case 'mercator'
theProjection = 'ME';
case 'stereographic'
theProjection = 'ST';
case 'lambert conformal conic'
theProjection = 'LC';
otherwise
theProjection = 'NA'; % not applicable
end
% Fill the variables.
netcdf.putVar(ncid,JPRJ_var_ID,theProjection);
netcdf.putVar(ncid,spherical_var_ID,'T');
netcdf.putVar(ncid,xl_var_ID,xl);
netcdf.putVar(ncid,el_var_ID,el);
f = 2.*7.29e-5.*sin(geogrid_lat(j_rho, i_rho).*pi./180);
f(isnan(f))=0; % doesn't like f to be NaN
netcdf.putVar(ncid,f_var_ID,f');
netcdf.putVar(ncid,x_rho_var_ID,grid_x(j_rho, i_rho)');
netcdf.putVar(ncid,y_rho_var_ID,grid_y(j_rho, i_rho)');
netcdf.putVar(ncid,x_psi_var_ID,grid_x(j_psi, i_psi)');
netcdf.putVar(ncid,y_psi_var_ID,grid_y(j_psi, i_psi)');
netcdf.putVar(ncid,x_u_var_ID,grid_x(j_u, i_u)');
netcdf.putVar(ncid,y_u_var_ID,grid_y(j_u, i_u)');
netcdf.putVar(ncid,x_v_var_ID,grid_x(j_v, i_v)');
netcdf.putVar(ncid,y_v_var_ID,grid_y(j_v, i_v)');
netcdf.putVar(ncid,lon_rho_var_ID,geogrid_lon(j_rho, i_rho)');
netcdf.putVar(ncid,lat_rho_var_ID,geogrid_lat(j_rho, i_rho)');
netcdf.putVar(ncid,lon_psi_var_ID,geogrid_lon(j_psi, i_psi)');
netcdf.putVar(ncid,lat_psi_var_ID,geogrid_lat(j_psi, i_psi)');
netcdf.putVar(ncid,lon_u_var_ID,geogrid_lon(j_u, i_u)');
netcdf.putVar(ncid,lat_u_var_ID,geogrid_lat(j_u, i_u)');
netcdf.putVar(ncid,lon_v_var_ID,geogrid_lon(j_v, i_v)');
netcdf.putVar(ncid,lat_v_var_ID,geogrid_lat(j_v, i_v)');
if ~isempty(bathymetry)
% netcdf.putVar(ncid,h_var_ID,bathymetry);
netcdf.putVar(ncid,h_var_ID,bathymetry');
end
% Masking.
mask = ~~mask;
land = mask;
water = ~land;
rmask = water;
% Calculate other masking arrays.
umask = zeros(size(rmask));
vmask = zeros(size(rmask));
pmask = zeros(size(rmask));
for i = 2:Lp
for j = 1:Mp
umask(j, i-1) = rmask(j, i) * rmask(j, i-1);
end
end
for i = 1:Lp
for j = 2:Mp
vmask(j-1, i) = rmask(j, i) * rmask(j-1, i);
end
end
for i = 2:Lp
for j = 2:Mp
pmask(j-1, i-1) = rmask(j, i) * rmask(j, i-1) * rmask(j-1, i) * rmask(j-1, i-1);
end
end
netcdf.putVar(ncid,mask_rho_var_ID,uint8(rmask'));
netcdf.putVar(ncid,mask_psi_var_ID,pmask(1:end-1, 1:end-1)');
netcdf.putVar(ncid,mask_u_var_ID,umask(1:end, 1:end-1)');
netcdf.putVar(ncid,mask_v_var_ID,vmask(1:end-1, 1:end)');
% Average angle -- We should do this via (x, y) components.
temp = 0.5*(ang(1:end-1, + ang(2:end, );
ang = zeros(n, m);
ang(2:2:end, 2:2:end) = temp;
ang(isnan(ang))=0; % doesn't like NaN
% nc{'angle'}(:) = ang(j_rho, i_rho);
netcdf.putVar(ncid,angle_var_ID,ang(j_rho, i_rho)');
% Use "geometry" from seagrid file for computation of "pm", "hraw".
% "geometry" contains distances computed from lon and lat in the
% Seagrid routine "dosave.m" using the "earthdist.m" routine, which
% assumes a spherical globe with a radius of 6371 km.
gx = geometry{1}; % Spherical distances in meters.
gy = geometry{2};
sx = 0.5*(gx(1:end-1, + gx(2:end, );
sy = 0.5*(gy(:, 1:end-1) + gy(:, 2:end));
pm = 1 ./ sx;
pn = 1 ./ sy;
hraw = 1 ./ sy;
% pm and hraw cannot be Inf, even if on land, so if values
% are Inf, set to an arbitrary non-zero value
pm(isinf(pm))=0.999e-3;
pn(isinf(pn))=0.999e-3;
hraw(isinf(hraw))=0.999e-3;
pm(isnan(pm))=0.999e-3;
pn(isnan(pn))=0.999e-3;
hraw(isnan(hraw))=0.999e-3;
netcdf.putVar(ncid,pm_var_ID,pm');
netcdf.putVar(ncid,pn_var_ID,pn');
count = [1 Lp Mp];
start = [0 0 0];
hraw_data(:,:,1) = hraw;
netcdf.putVar(ncid,hraw_var_ID,start,count,hraw_data');
dmde = zeros(size(pm));
dndx = zeros(size(hraw));
dmde(2:end-1, = 0.5*(1./pm(3:end, - 1./pm(1:end-2, );
dndx(:, 2:end-1) = 0.5*(1./hraw(:, 3:end) - 1./hraw(:, 1:end-2));
dmde(isinf(dmde))=0;
dndx(isinf(dndx))=0;
dmde(isnan(dmde))=0;
dndx(isnan(dndx))=0;
netcdf.putVar(ncid,dmde_var_ID,dmde');
netcdf.putVar(ncid,dndx_var_ID,dndx');
% Final size of file:
%
% s = size(nc);
% disp([' ## Dimensions: ' int2str(s(1))])
% disp([' ## Variables: ' int2str(s(2))])
% disp([' ## Global Attributes: ' int2str(s(3))])
% disp([' ## Record Dimension: ' name(recdim(nc))])
% disp([char(13),char(13),char(13)])
disp(['SCREEN DISPLAY:',char(13)])
disp('COPY-PASTE the following parameters into your ocean.in file')
disp('----------------------------------------------------------------------------------------------')
disp(char(13))
disp([' Lm == ' num2str(Lp-2) ' ! Number of I-direction INTERIOR RHO-points'])
disp([' Mm == ' num2str(Mp-2) ' ! Number of J-direction INTERIOR RHO-points'])
% disp([' N == ' num2str(N) ' ! Number of vertical levels'])
disp(char(13))
% disp(['Make sure the Baroclinic time-step (DT) in your ocean.in file is less than: ' num2str(sqrt(((min(min(dx))^2)+(min(min(dy))^2)) / (9.8 * (min(min(h))^2)))) ' seconds'])
disp('----------------------------------------------------------------------------------------------')
fprintf('\n Done. Grid written to %s!\n', theRomsFile)
netcdf.close(ncid);
try to use the script "seagrid2roms_new.m", instead of the "seagrid2roms.m" that you are using.
When I downloaded the seagrid, this script came together and is more compatible with my netcdf matlab packages.
good luck,
Gabriel Carvalho
Oceanographer - Rio de Janeiro
P.S: In case you don't have it:
function seagrid2roms_ML(theSeagridFile, theRomsFile,...
theGridTitle,theInterpMethod,FLIPPING)
% seagrid2roms -- Output ROMS format from SeaGrid file.
% Usage: seagrid2roms(theSeagridFile, theRomsFile,...
% theGridTitle, theInterpMethod);
% Inputs:
% theSeagridFile = name of seagrid output file (string)
% theRomsFile = name of Roms Grid file to be created (string)
% theGridTitle = title of grid (string)
% theInterpMethod = interp2d method used to double grid (string)
% Can be "linear" or "spline" (default is spline)
% Use "linear" for seagrid.mat files originating
% from Delft grids, which have info only on
% the wet cells.
% FLIPPING = should be 1 (default) for files produced by seagrid
% or 0 for files converted from Delft3D grids
%
% If '*' is input for theSeagridFile or theRomsFile, dialog boxes are
% invoked.
%
% NOTE: this routine does not employ _FillValue attributes
% in the output NetCDF variables.
%
% Disclosure without explicit written consent from the
% copyright owner does not constitute publication.
% Version of 18-Jun-1999 17:11:59. by Chuck Denham
% Updated 28-Oct-2002 10:12:55.
% Updated 14-Apr-2004 10:12:55. by Rich Signell
% - grid doubling now only in projected coordinate
% - distances between grid points now calculated from lon/lat values on spherical earth
% The default earth radius is
% assumed to be 6371*1000 meters, the radius for
% a sphere of equal-volume, the same default as "earthdist.m".
RADIAN_CONVERSION_FACTOR = 180/pi;
EARTH_RADIUS_METERS = 6371*1000; % Equatorial radius.
if nargin < 1, theSeagridFile = '*.mat'; end
if nargin < 2, theRomsFile = 'roms_grd.nc'; end
if nargin < 3, theGridTitle = char(zeros(1, 128)+abs(' ')); end
if isempty(theSeagridFile) | any(theSeagridFile == '*')
[f, p] = uigetfile(theSeagridFile, 'Select SeaGrid File:');
if ~any(f), return, end
if p(end) ~= filesep, p(end+1) = filesep; end
theSeagridFile = [p f]
end
if nargin < 2 | isempty(theSeagridFile) | any(theRomsFile == '*')
[f, p] = uiputfile(theRomsFile, 'Save to Roms File:');
if ~any(f), return, end
if p(end) ~= filesep, p(end+1) = filesep; end
theRomsFile = [p f]
end
disp([' ## SeaGrid Source File : ' theSeagridFile])
disp([' ## ROMS Destination File: ' theRomsFile])
% Load the SeaGrid file and get parameters.
try
theSeagridData = load(theSeagridFile, 's');
catch
disp([' ## Unable to load: "' theSeagridFile '"'])
return
end
% With grid_x of size [m, n], the grid itself has
% [m-1, n-1] cells. The latter size corresponds
% to the size of the mask and bathymetry. These
% cell-centers are called the "rho" points.
s = theSeagridData.s;
grid_x = s.grids{1} * EARTH_RADIUS_METERS;
grid_y = s.grids{2} * EARTH_RADIUS_METERS;
[m, n] = size(grid_x);
geogrid_lon = s.geographic_grids{1};
geogrid_lat = s.geographic_grids{2};
geometry = s.geometry;
mask = s.mask; % land = 1; water = 0.
if ~isequal(size(mask), size(grid_x)-1)
if ~isempty(mask)
disp(' ## Wrong size mask.')
end
mask = zeros(m-1, n-1);
end
mask = ~~mask;
land = mask;
water = ~land;
bathymetry = s.gridded_bathymetry;
projection = s.projection;
ang = s.orientation * pi / 180; % ROMS needs radians.
min_depth = s.clipping_depths(1);
max_depth = s.clipping_depths(2);
% Clip Bathymetry
bathymetry(find(isnan(bathymetry))) = min_depth;
bathymetry(bathymetry<min_depth) = min_depth;
bathymetry(bathymetry>max_depth) = max_depth;
% Double the grid-size before proceeding.
% The grid-cell-centers are termed the "rho" points.
theInterpFcn = 'interp2';
if nargin<4,
theInterpMethod = 'spline';
%theInterpMethod = 'linear';
end
grid_x = feval(theInterpFcn, grid_x, 1, theInterpMethod);
grid_y = feval(theInterpFcn, grid_y, 1, theInterpMethod);
geogrid_lon = feval(theInterpFcn, geogrid_lon, 1, theInterpMethod);
geogrid_lat = feval(theInterpFcn, geogrid_lat, 1, theInterpMethod);
% The present size of the grid nodes.
[n, m] = size(grid_x);
% Flip arrays top for bottom.
if (nargin<5)
FLIPPING = 1; % for files from Seagrid
%FLIPPING = 0; % for files from Delft3D conversion
end
if FLIPPING
grid_x = flipud(grid_x);
grid_y = flipud(grid_y);
geogrid_lon = flipud(geogrid_lon);
geogrid_lat = flipud(geogrid_lat);
geometry{1} = flipud(geometry{1});
geometry{2} = flipud(geometry{2});
mask = flipud(mask);
bathymetry = flipud(bathymetry);
ang = flipud(ang);
end
xl = max(grid_x(:)) - min(grid_x(:));
el = max(grid_y(:)) - min(grid_y(:));
% Create the Roms NetCDF file.
% nc = netcdf(theRomsFile, 'clobber');
ncid = netcdf.create(theRomsFile,'NC_CLOBBER');
if isempty(ncid), return, end
%% Global attributes:
disp(' ## Defining Global Attributes...')
% nc.type = ncchar('Gridpak file');
% nc.gridid = theGridTitle;
% nc.history = ncchar(['Created by "' mfilename '" on ' datestr(now)]);
%
% nc.CPP_options = ncchar('DCOMPLEX, DBLEPREC, NCARG_32, PLOTS,');
% name(nc.CPP_options, 'CPP-options')
% The SeaGrid is now a full array, whose height
% and width are odd-valued. We extract staggered
% sub-grids for the Roms scheme, ignoring the
% outermost rows and columns. Thus, the so-called
% "rho" points correspond to the even-numbered points
% in an (i, j) Matlab array. The "psi" points begin
% at i = 3 and j = 3. The whole set is indexed as
% follows:
% rho (2:2:end-1, 2:2:end-1), i.e. (2:2:m, 2:2:n), etc.
% psi (3:2:end-2, 3:2:end-2)
% u (2:2:end-1, 3:2:end-2)
% v (3:2:end-2, 2:2:end-1)
if ~rem(m, 2), m = m-1; end % m, n must be odd.
if ~rem(n, 2), n = n-1; end
i_rho = 2:2:m-1; j_rho = 2:2:n-1;
i_psi = 3:2:m-2; j_psi = 3:2:n-2;
i_u = 3:2:m-2; j_u = 2:2:n-1;
i_v = 2:2:m-1; j_v = 3:2:n-2;
% The xi direction (left-right):
Lp = (m-1)/2; % The rho dimension.
L = Lp-1; % The psi dimension.
% The eta direction (up-down):
Mp = (n-1)/2; % The rho dimension.
M = Mp-1; % The psi dimension.
disp(' ## Defining Dimensions...')
xi_rho_ID = netcdf.defDim(ncid,'xi_rho',Lp);
xi_u_ID = netcdf.defDim(ncid,'xi_u',L);
xi_psi_ID = netcdf.defDim(ncid,'xi_psi',L);
xi_v_ID = netcdf.defDim(ncid,'xi_v',Lp);
eta_rho_ID = netcdf.defDim(ncid,'eta_rho',Mp);
eta_u_ID = netcdf.defDim(ncid,'eta_u',Mp);
eta_v_ID = netcdf.defDim(ncid,'eta_v',M);
eta_psi_ID = netcdf.defDim(ncid,'eta_psi',M);
one_ID = netcdf.defDim(ncid,'one',1);
two_ID = netcdf.defDim(ncid,'two',2);
bath_ID = netcdf.defDim(ncid,'bath',netcdf.getConstant('NC_UNLIMITED'));
% bath_ID = netcdf.defDim(ncid,'bath',0);
%% Variables and attributes:
disp(' ## Defining Variables and Attributes...')
xl_var_ID = netcdf.defVar(ncid,'xl','double',one_ID);
netcdf.putAtt(ncid,xl_var_ID,'long_name','domain length in the XI-direction')
netcdf.putAtt(ncid,xl_var_ID,'units','meter')
el_var_ID = netcdf.defVar(ncid,'el','double',one_ID);
netcdf.putAtt(ncid,el_var_ID,'long_name','domain length in the ETA-direction')
netcdf.putAtt(ncid,el_var_ID,'units','meter')
JPRJ_var_ID = netcdf.defVar(ncid,'JPRJ','char',two_ID);
netcdf.putAtt(ncid,JPRJ_var_ID,'long_name','Map projection type')
netcdf.putAtt(ncid,JPRJ_var_ID,'option_ME_','Mercator')
netcdf.putAtt(ncid,JPRJ_var_ID,'option_ST_','Stereographic')
netcdf.putAtt(ncid,JPRJ_var_ID,'option_LC_','Lambert conformal conic')
netcdf.renameAtt(ncid,JPRJ_var_ID,'option_ME_','option(ME)')
netcdf.renameAtt(ncid,JPRJ_var_ID,'option_ST_','option(ST)')
netcdf.renameAtt(ncid,JPRJ_var_ID,'option_LC_','option(LC)')
PLAT_var_ID = netcdf.defVar(ncid,'PLAT','float',two_ID);
netcdf.putAtt(ncid,PLAT_var_ID,'long_name','Reference latitude(s) for map projection')
netcdf.putAtt(ncid,PLAT_var_ID,'units','degree_north')
PLONG_var_ID = netcdf.defVar(ncid,'PLONG','float',one_ID);
netcdf.putAtt(ncid,PLONG_var_ID,'long_name','Reference longitude for map projection')
netcdf.putAtt(ncid,PLONG_var_ID,'units','degree_east')
ROTA_var_ID = netcdf.defVar(ncid,'ROTA','float',one_ID);
netcdf.putAtt(ncid,ROTA_var_ID,'long_name','Rotation angle for map projection')
netcdf.putAtt(ncid,ROTA_var_ID,'units','degree')
JLTS_var_ID = netcdf.defVar(ncid,'JLTS','char',two_ID);
netcdf.putAtt(ncid,JLTS_var_ID,'long_name','How limits of map are chosen')
netcdf.putAtt(ncid,JLTS_var_ID,'option_CO_','P1, .. P4 define two opposite corners')
netcdf.putAtt(ncid,JLTS_var_ID,'option_MA_','Maximum (whole world)')
netcdf.putAtt(ncid,JLTS_var_ID,'option_AN_','Angles - P1..P4 define angles to edge of domain')
netcdf.putAtt(ncid,JLTS_var_ID,'option_LI_','Limits - P1..P4 define limits in u,v space')
netcdf.renameAtt(ncid,JLTS_var_ID,'option_CO_','option(CO)')
netcdf.renameAtt(ncid,JLTS_var_ID,'option_MA_','option(MA)')
netcdf.renameAtt(ncid,JLTS_var_ID,'option_AN_','option(AN)')
netcdf.renameAtt(ncid,JLTS_var_ID,'option_LI_','option(LI)')
P1_var_ID = netcdf.defVar(ncid,'P1','float',one_ID);
netcdf.putAtt(ncid,P1_var_ID,'long_name','Map limit parameter number 1')
P2_var_ID = netcdf.defVar(ncid,'P2','float',one_ID);
netcdf.putAtt(ncid,P2_var_ID,'long_name','Map limit parameter number 2')
P3_var_ID = netcdf.defVar(ncid,'P3','float',one_ID);
netcdf.putAtt(ncid,P3_var_ID,'long_name','Map limit parameter number 3')
P4_var_ID = netcdf.defVar(ncid,'P4','float',one_ID);
netcdf.putAtt(ncid,P4_var_ID,'long_name','Map limit parameter number 4')
XOFF_var_ID = netcdf.defVar(ncid,'XOFF','float',one_ID);
netcdf.putAtt(ncid,XOFF_var_ID,'long_name','Offset in x direction')
netcdf.putAtt(ncid,XOFF_var_ID,'units','meter')
YOFF_var_ID = netcdf.defVar(ncid,'YOFF','float',one_ID);
netcdf.putAtt(ncid,YOFF_var_ID,'long_name','Offset in y direction')
netcdf.putAtt(ncid,YOFF_var_ID,'units','meter')
depthmin_var_ID = netcdf.defVar(ncid,'depthmin','short',one_ID);
netcdf.putAtt(ncid,depthmin_var_ID,'long_name','Shallow bathymetry clipping depth')
netcdf.putAtt(ncid,depthmin_var_ID,'units','meter')
depthmax_var_ID = netcdf.defVar(ncid,'depthmax','short',one_ID);
netcdf.putAtt(ncid,depthmax_var_ID,'long_name','Deep bathymetry clipping depth')
netcdf.putAtt(ncid,depthmax_var_ID,'units','meter')
spherical_var_ID = netcdf.defVar(ncid,'spherical','char',one_ID);
netcdf.putAtt(ncid,spherical_var_ID,'long_name','Grid type logical switch')
netcdf.putAtt(ncid,spherical_var_ID,'option_T_','spherical')
netcdf.putAtt(ncid,spherical_var_ID,'option_F_','cartesian')
netcdf.renameAtt(ncid,spherical_var_ID,'option_T_','option(T)')
netcdf.renameAtt(ncid,spherical_var_ID,'option_F_','option(F)')
hraw_var_ID = netcdf.defVar(ncid,'hraw','double',[xi_rho_ID eta_rho_ID bath_ID]);
netcdf.putAtt(ncid,hraw_var_ID,'long_name','Working bathymetry at RHO-points')
netcdf.putAtt(ncid,hraw_var_ID,'units','meter')
netcdf.putAtt(ncid,hraw_var_ID,'field','bath, scalar')
h_var_ID = netcdf.defVar(ncid,'h','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,h_var_ID,'long_name','Final bathymetry at RHO-points')
netcdf.putAtt(ncid,h_var_ID,'units','meter')
netcdf.putAtt(ncid,h_var_ID,'coordinates','lon_rho lat_rho')
netcdf.putAtt(ncid,h_var_ID,'field','bath,scalar')
f_var_ID = netcdf.defVar(ncid,'f','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,f_var_ID,'long_name','Coriolis parameter at RHO-points')
netcdf.putAtt(ncid,f_var_ID,'units','second-1')
netcdf.putAtt(ncid,f_var_ID,'coordinates','lon_rho lat_rho')
netcdf.putAtt(ncid,f_var_ID,'field','Coriolis,scalar')
pm_var_ID = netcdf.defVar(ncid,'pm','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,pm_var_ID,'long_name','curvilinear coordinate metric in XI')
netcdf.putAtt(ncid,pm_var_ID,'units','meter-1')
netcdf.putAtt(ncid,pm_var_ID,'field','pm, scalar')
pn_var_ID = netcdf.defVar(ncid,'pn','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,pn_var_ID,'long_name','curvilinear coordinate metric in ETA')
netcdf.putAtt(ncid,pn_var_ID,'units','meter-1')
netcdf.putAtt(ncid,pn_var_ID,'field','pn, scalar')
dndx_var_ID = netcdf.defVar(ncid,'dndx','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,dndx_var_ID,'long_name','xi derivative of inverse metric factor pn')
netcdf.putAtt(ncid,dndx_var_ID,'units','meter')
netcdf.putAtt(ncid,dndx_var_ID,'field','dndx, scalar')
dmde_var_ID = netcdf.defVar(ncid,'dmde','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,dmde_var_ID,'long_name','eta derivative of inverse metric factor pm')
netcdf.putAtt(ncid,dmde_var_ID,'units','meter')
netcdf.putAtt(ncid,dmde_var_ID,'field','dmde, scalar')
x_rho_var_ID = netcdf.defVar(ncid,'x_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,x_rho_var_ID,'long_name','x location of RHO-points')
netcdf.putAtt(ncid,x_rho_var_ID,'units','meter')
y_rho_var_ID = netcdf.defVar(ncid,'y_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,y_rho_var_ID,'long_name','y location of RHO-points')
netcdf.putAtt(ncid,y_rho_var_ID,'units','meter')
x_psi_var_ID = netcdf.defVar(ncid,'x_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,x_psi_var_ID,'long_name','x location of PSI-points')
netcdf.putAtt(ncid,x_psi_var_ID,'units','meter')
y_psi_var_ID = netcdf.defVar(ncid,'y_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,y_psi_var_ID,'long_name','y location of PSI-points')
netcdf.putAtt(ncid,y_psi_var_ID,'units','meter')
x_u_var_ID = netcdf.defVar(ncid,'x_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,x_u_var_ID,'long_name','x location of U-points')
netcdf.putAtt(ncid,x_u_var_ID,'units','meter')
y_u_var_ID = netcdf.defVar(ncid,'y_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,y_u_var_ID,'long_name','y location of U-points')
netcdf.putAtt(ncid,y_u_var_ID,'units','meter')
x_v_var_ID = netcdf.defVar(ncid,'x_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,x_v_var_ID,'long_name','x location of V-points')
netcdf.putAtt(ncid,x_v_var_ID,'units','meter')
y_v_var_ID = netcdf.defVar(ncid,'y_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,y_v_var_ID,'long_name','y location of V-points')
netcdf.putAtt(ncid,y_v_var_ID,'units','meter')
lat_rho_var_ID = netcdf.defVar(ncid,'lat_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,lat_rho_var_ID,'long_name','latitude of RHO-points')
netcdf.putAtt(ncid,lat_rho_var_ID,'units','degree_north')
lon_rho_var_ID = netcdf.defVar(ncid,'lon_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,lon_rho_var_ID,'long_name','longitude of RHO-points')
netcdf.putAtt(ncid,lon_rho_var_ID,'units','degree_east')
lat_psi_var_ID = netcdf.defVar(ncid,'lat_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,lat_psi_var_ID,'long_name','latitude of PSI-points')
netcdf.putAtt(ncid,lat_psi_var_ID,'units','degree_north')
lon_psi_var_ID = netcdf.defVar(ncid,'lon_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,lon_psi_var_ID,'long_name','longitude of PSI-points')
netcdf.putAtt(ncid,lon_psi_var_ID,'units','degree_north')
lat_u_var_ID = netcdf.defVar(ncid,'lat_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,lat_u_var_ID,'long_name','latitude of U-points')
netcdf.putAtt(ncid,lat_u_var_ID,'units','degree_north')
lon_u_var_ID = netcdf.defVar(ncid,'lon_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,lon_u_var_ID,'long_name','longitude of U-points')
netcdf.putAtt(ncid,lon_u_var_ID,'units','degree_north')
lat_v_var_ID = netcdf.defVar(ncid,'lat_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,lat_v_var_ID,'long_name','latitude of V-points')
netcdf.putAtt(ncid,lat_v_var_ID,'units','degree_north')
lon_v_var_ID = netcdf.defVar(ncid,'lon_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,lon_v_var_ID,'long_name','longitude of V-points')
netcdf.putAtt(ncid,lon_v_var_ID,'units','degree_east')
mask_rho_var_ID = netcdf.defVar(ncid,'mask_rho','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,mask_rho_var_ID,'long_name','mask on RHO-points')
netcdf.putAtt(ncid,mask_rho_var_ID,'option_0_','land')
netcdf.putAtt(ncid,mask_rho_var_ID,'option_1_','water')
netcdf.renameAtt(ncid,mask_rho_var_ID,'option_0_','option(0)')
netcdf.renameAtt(ncid,mask_rho_var_ID,'option_1_','option(1)')
mask_u_var_ID = netcdf.defVar(ncid,'mask_u','double',[xi_u_ID eta_u_ID]);
netcdf.putAtt(ncid,mask_u_var_ID,'long_name','mask on U-points')
netcdf.putAtt(ncid,mask_u_var_ID,'option_0_','land')
netcdf.putAtt(ncid,mask_u_var_ID,'option_1_','water')
netcdf.renameAtt(ncid,mask_u_var_ID,'option_0_','option(0)')
netcdf.renameAtt(ncid,mask_u_var_ID,'option_1_','option(1)')
mask_v_var_ID = netcdf.defVar(ncid,'mask_v','double',[xi_v_ID eta_v_ID]);
netcdf.putAtt(ncid,mask_v_var_ID,'long_name','mask on V-points')
netcdf.putAtt(ncid,mask_v_var_ID,'option_0_','land')
netcdf.putAtt(ncid,mask_v_var_ID,'option_1_','water')
netcdf.renameAtt(ncid,mask_v_var_ID,'option_0_','option(0)')
netcdf.renameAtt(ncid,mask_v_var_ID,'option_1_','option(1)')
mask_psi_var_ID = netcdf.defVar(ncid,'mask_psi','double',[xi_psi_ID eta_psi_ID]);
netcdf.putAtt(ncid,mask_psi_var_ID,'long_name','mask on PSI-points')
netcdf.putAtt(ncid,mask_psi_var_ID,'option_0_','land')
netcdf.putAtt(ncid,mask_psi_var_ID,'option_1_','water')
netcdf.renameAtt(ncid,mask_psi_var_ID,'option_0_','option(0)')
netcdf.renameAtt(ncid,mask_psi_var_ID,'option_1_','option(1)')
angle_var_ID = netcdf.defVar(ncid,'angle','double',[xi_rho_ID eta_rho_ID]);
netcdf.putAtt(ncid,angle_var_ID,'long_name','angle between xi axis and east')
netcdf.putAtt(ncid,angle_var_ID,'units','radian')
%end define mode
netcdf.endDef(ncid)
% Fill the variables with data.
disp(' ## Filling Variables...')
switch lower(projection)
case 'mercator'
theProjection = 'ME';
case 'stereographic'
theProjection = 'ST';
case 'lambert conformal conic'
theProjection = 'LC';
otherwise
theProjection = 'NA'; % not applicable
end
% Fill the variables.
netcdf.putVar(ncid,JPRJ_var_ID,theProjection);
netcdf.putVar(ncid,spherical_var_ID,'T');
netcdf.putVar(ncid,xl_var_ID,xl);
netcdf.putVar(ncid,el_var_ID,el);
f = 2.*7.29e-5.*sin(geogrid_lat(j_rho, i_rho).*pi./180);
f(isnan(f))=0; % doesn't like f to be NaN
netcdf.putVar(ncid,f_var_ID,f');
netcdf.putVar(ncid,x_rho_var_ID,grid_x(j_rho, i_rho)');
netcdf.putVar(ncid,y_rho_var_ID,grid_y(j_rho, i_rho)');
netcdf.putVar(ncid,x_psi_var_ID,grid_x(j_psi, i_psi)');
netcdf.putVar(ncid,y_psi_var_ID,grid_y(j_psi, i_psi)');
netcdf.putVar(ncid,x_u_var_ID,grid_x(j_u, i_u)');
netcdf.putVar(ncid,y_u_var_ID,grid_y(j_u, i_u)');
netcdf.putVar(ncid,x_v_var_ID,grid_x(j_v, i_v)');
netcdf.putVar(ncid,y_v_var_ID,grid_y(j_v, i_v)');
netcdf.putVar(ncid,lon_rho_var_ID,geogrid_lon(j_rho, i_rho)');
netcdf.putVar(ncid,lat_rho_var_ID,geogrid_lat(j_rho, i_rho)');
netcdf.putVar(ncid,lon_psi_var_ID,geogrid_lon(j_psi, i_psi)');
netcdf.putVar(ncid,lat_psi_var_ID,geogrid_lat(j_psi, i_psi)');
netcdf.putVar(ncid,lon_u_var_ID,geogrid_lon(j_u, i_u)');
netcdf.putVar(ncid,lat_u_var_ID,geogrid_lat(j_u, i_u)');
netcdf.putVar(ncid,lon_v_var_ID,geogrid_lon(j_v, i_v)');
netcdf.putVar(ncid,lat_v_var_ID,geogrid_lat(j_v, i_v)');
if ~isempty(bathymetry)
% netcdf.putVar(ncid,h_var_ID,bathymetry);
netcdf.putVar(ncid,h_var_ID,bathymetry');
end
% Masking.
mask = ~~mask;
land = mask;
water = ~land;
rmask = water;
% Calculate other masking arrays.
umask = zeros(size(rmask));
vmask = zeros(size(rmask));
pmask = zeros(size(rmask));
for i = 2:Lp
for j = 1:Mp
umask(j, i-1) = rmask(j, i) * rmask(j, i-1);
end
end
for i = 1:Lp
for j = 2:Mp
vmask(j-1, i) = rmask(j, i) * rmask(j-1, i);
end
end
for i = 2:Lp
for j = 2:Mp
pmask(j-1, i-1) = rmask(j, i) * rmask(j, i-1) * rmask(j-1, i) * rmask(j-1, i-1);
end
end
netcdf.putVar(ncid,mask_rho_var_ID,uint8(rmask'));
netcdf.putVar(ncid,mask_psi_var_ID,pmask(1:end-1, 1:end-1)');
netcdf.putVar(ncid,mask_u_var_ID,umask(1:end, 1:end-1)');
netcdf.putVar(ncid,mask_v_var_ID,vmask(1:end-1, 1:end)');
% Average angle -- We should do this via (x, y) components.
temp = 0.5*(ang(1:end-1, + ang(2:end, );
ang = zeros(n, m);
ang(2:2:end, 2:2:end) = temp;
ang(isnan(ang))=0; % doesn't like NaN
% nc{'angle'}(:) = ang(j_rho, i_rho);
netcdf.putVar(ncid,angle_var_ID,ang(j_rho, i_rho)');
% Use "geometry" from seagrid file for computation of "pm", "hraw".
% "geometry" contains distances computed from lon and lat in the
% Seagrid routine "dosave.m" using the "earthdist.m" routine, which
% assumes a spherical globe with a radius of 6371 km.
gx = geometry{1}; % Spherical distances in meters.
gy = geometry{2};
sx = 0.5*(gx(1:end-1, + gx(2:end, );
sy = 0.5*(gy(:, 1:end-1) + gy(:, 2:end));
pm = 1 ./ sx;
pn = 1 ./ sy;
hraw = 1 ./ sy;
% pm and hraw cannot be Inf, even if on land, so if values
% are Inf, set to an arbitrary non-zero value
pm(isinf(pm))=0.999e-3;
pn(isinf(pn))=0.999e-3;
hraw(isinf(hraw))=0.999e-3;
pm(isnan(pm))=0.999e-3;
pn(isnan(pn))=0.999e-3;
hraw(isnan(hraw))=0.999e-3;
netcdf.putVar(ncid,pm_var_ID,pm');
netcdf.putVar(ncid,pn_var_ID,pn');
count = [1 Lp Mp];
start = [0 0 0];
hraw_data(:,:,1) = hraw;
netcdf.putVar(ncid,hraw_var_ID,start,count,hraw_data');
dmde = zeros(size(pm));
dndx = zeros(size(hraw));
dmde(2:end-1, = 0.5*(1./pm(3:end, - 1./pm(1:end-2, );
dndx(:, 2:end-1) = 0.5*(1./hraw(:, 3:end) - 1./hraw(:, 1:end-2));
dmde(isinf(dmde))=0;
dndx(isinf(dndx))=0;
dmde(isnan(dmde))=0;
dndx(isnan(dndx))=0;
netcdf.putVar(ncid,dmde_var_ID,dmde');
netcdf.putVar(ncid,dndx_var_ID,dndx');
% Final size of file:
%
% s = size(nc);
% disp([' ## Dimensions: ' int2str(s(1))])
% disp([' ## Variables: ' int2str(s(2))])
% disp([' ## Global Attributes: ' int2str(s(3))])
% disp([' ## Record Dimension: ' name(recdim(nc))])
% disp([char(13),char(13),char(13)])
disp(['SCREEN DISPLAY:',char(13)])
disp('COPY-PASTE the following parameters into your ocean.in file')
disp('----------------------------------------------------------------------------------------------')
disp(char(13))
disp([' Lm == ' num2str(Lp-2) ' ! Number of I-direction INTERIOR RHO-points'])
disp([' Mm == ' num2str(Mp-2) ' ! Number of J-direction INTERIOR RHO-points'])
% disp([' N == ' num2str(N) ' ! Number of vertical levels'])
disp(char(13))
% disp(['Make sure the Baroclinic time-step (DT) in your ocean.in file is less than: ' num2str(sqrt(((min(min(dx))^2)+(min(min(dy))^2)) / (9.8 * (min(min(h))^2)))) ' seconds'])
disp('----------------------------------------------------------------------------------------------')
fprintf('\n Done. Grid written to %s!\n', theRomsFile)
netcdf.close(ncid);
Re: Problems on converting *.mat file to *.nc file
I have the same problem.when i use "seagrid2roms",it happens the errors as follows.
??? Undefined function or method 'name' for input arguments of type 'double'.
## SeaGrid Source File : D:\lwb\model\seagrid\seagrid.mat
## ROMS Destination File: D:\lwb\model\seagrid\roms_grd.nc
## Defining Global Attributes...
## Defining Dimensions...
## Defining Variables and Attributes...
??? Undefined function or method 'name' for input arguments of type 'double'.
Error in ==> seagrid2roms at 231
name(nc{'JPRJ'}.option_ME_, 'option(ME)')
Error in ==> seagrid2roms at 231
name(nc{'JPRJ'}.option_ME_, 'option(ME)')
??? Undefined function or method 'name' for input arguments of type 'double'.
## SeaGrid Source File : D:\lwb\model\seagrid\seagrid.mat
## ROMS Destination File: D:\lwb\model\seagrid\roms_grd.nc
## Defining Global Attributes...
## Defining Dimensions...
## Defining Variables and Attributes...
??? Undefined function or method 'name' for input arguments of type 'double'.
Error in ==> seagrid2roms at 231
name(nc{'JPRJ'}.option_ME_, 'option(ME)')
Error in ==> seagrid2roms at 231
name(nc{'JPRJ'}.option_ME_, 'option(ME)')
Re: Problems on converting *.mat file to *.nc file
Hi,
I am using the seagrid2roms_new file provided here and I am getting the following errors.
theSeagridFile =
/Users/gracemaze/ROMS/Projects/Upwelling/MyDir/wfs_seagrid.mat
theRomsFile =
/Users/gracemaze/ROMS/Projects/Upwelling/MyDir/roms_grd.nc
## SeaGrid Source File : /Users/gracemaze/ROMS/Projects/Upwelling/MyDir/wfs_seagrid.mat
## ROMS Destination File: /Users/gracemaze/ROMS/Projects/Upwelling/MyDir/roms_grd.nc
## Defining Global Attributes...
## Defining Dimensions...
## Defining Variables and Attributes...
## Filling Variables...
??? Error using ==> netcdflib
Library failure "NetCDF: Start+count exceeds dimension bound".
Error in ==> putVar at 102
netcdflib(funcstr,ncid,varid,varargin{:});
Error in ==> seagrid2roms_new at 574
netcdf.putVar(ncid,hraw_var_ID,start,count,hraw_data');
Can anyone help?
I am using the seagrid2roms_new file provided here and I am getting the following errors.
theSeagridFile =
/Users/gracemaze/ROMS/Projects/Upwelling/MyDir/wfs_seagrid.mat
theRomsFile =
/Users/gracemaze/ROMS/Projects/Upwelling/MyDir/roms_grd.nc
## SeaGrid Source File : /Users/gracemaze/ROMS/Projects/Upwelling/MyDir/wfs_seagrid.mat
## ROMS Destination File: /Users/gracemaze/ROMS/Projects/Upwelling/MyDir/roms_grd.nc
## Defining Global Attributes...
## Defining Dimensions...
## Defining Variables and Attributes...
## Filling Variables...
??? Error using ==> netcdflib
Library failure "NetCDF: Start+count exceeds dimension bound".
Error in ==> putVar at 102
netcdflib(funcstr,ncid,varid,varargin{:});
Error in ==> seagrid2roms_new at 574
netcdf.putVar(ncid,hraw_var_ID,start,count,hraw_data');
Can anyone help?
- arango
- Site Admin
- Posts: 1367
- Joined: Wed Feb 26, 2003 4:41 pm
- Location: DMCS, Rutgers University
- Contact:
Re: Problems on converting *.mat file to *.nc file
The only seagrid2roms.m that we support is distributed in the ROMS matlab repository. This file was updated couple of months ago to be consistent with ROMS new developments about nesting. I also made changes to SeaGrid. This works well for me...
We are not responsible for the scripts developed by third parties. I have checked these scripts from time to time and I usually find several mistakes due to the lack of familiarity with ROMS numerical kernel options, Matlab, NetCDF, and NetCDF interface to Matlab. I do not have the time to correct the scripts that are distributed by others.
In WikiROMS, we provide instructions how to download of the various ROMS repository codes. All the Matlab scripts are self-consistent and tested.
We are not responsible for the scripts developed by third parties. I have checked these scripts from time to time and I usually find several mistakes due to the lack of familiarity with ROMS numerical kernel options, Matlab, NetCDF, and NetCDF interface to Matlab. I do not have the time to correct the scripts that are distributed by others.
In WikiROMS, we provide instructions how to download of the various ROMS repository codes. All the Matlab scripts are self-consistent and tested.
Re: Problems on converting *.mat file to *.nc file
Hi, I got the error as you did on the Matlab2011a platform. I changed the 'count' array into the following format in the seagrid2roms_new.m file :
count = [ Lp Mp 1];
and the error did not come out again
count = [ Lp Mp 1];
and the error did not come out again
gmaze wrote:Hi,
I am using the seagrid2roms_new file provided here and I am getting the following errors.
theSeagridFile =
/Users/gracemaze/ROMS/Projects/Upwelling/MyDir/wfs_seagrid.mat
theRomsFile =
/Users/gracemaze/ROMS/Projects/Upwelling/MyDir/roms_grd.nc
## SeaGrid Source File : /Users/gracemaze/ROMS/Projects/Upwelling/MyDir/wfs_seagrid.mat
## ROMS Destination File: /Users/gracemaze/ROMS/Projects/Upwelling/MyDir/roms_grd.nc
## Defining Global Attributes...
## Defining Dimensions...
## Defining Variables and Attributes...
## Filling Variables...
??? Error using ==> netcdflib
Library failure "NetCDF: Start+count exceeds dimension bound".
Error in ==> putVar at 102
netcdflib(funcstr,ncid,varid,varargin{:});
Error in ==> seagrid2roms_new at 574
netcdf.putVar(ncid,hraw_var_ID,start,count,hraw_data');
Can anyone help?