/[MITgcm]/MITgcm_contrib/eh3/llc/ecco-godae/climatology/gen_bathy.m
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Contents of /MITgcm_contrib/eh3/llc/ecco-godae/climatology/gen_bathy.m

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Revision 1.5 - (show annotations) (download)
Wed Nov 15 01:27:17 2006 UTC (18 years, 11 months ago) by heimbach
Branch: MAIN
CVS Tags: HEAD
Changes since 1.4: +5 -2 lines 
Adding and modifying matlab scripts which hopefully are now
self-consistent in dealing with original grid shift and transposing bugs.
1 %
2 % Ed Hill
3 %
4 % Generate approximate bathymetry for the llc grid
5 %
6
7 % clear all ; close all
8
9 do_print = 0;
10 dbug = 0;
11
12 % Get the ETOPO2 data
13 disp('Reading the ETOPO2 data...');
14 nlat = 5400;
15 nlon = 10800;
16 lons = linspace(-180, (180 - 2/60), nlon);
17 lats = linspace(90, -(90 - 2/60), nlat);
18 fid = fopen('ETOPO2.raw.bin', 'r', 'ieee-be');
19 et2 = reshape( fread(fid, nlat*nlon, 'int16'), [ nlon nlat ]);
20 fid = fclose(fid);
21
22 if dbug > 10
23 surf( et2(1:500,1:500) ), view(2), shading flat
24 ilon = [ 1:10:5000 ];
25 ilat = [ 1:10:5400 ];
26 surf(lons(ilon), lats(ilat), et2(ilon,ilat)'), view(2), ...
27 shading flat, axis equal
28 end
29
30 % Get the llc grid information
31 disp('Reading the grid information...');
32 fnc_in = 'llc_p90_%d.nc';
33 vnms = { 'XC' 'YC' 'XG' 'YG' };
34 d2r = pi/180.0;
35 ginfo = {};
36 for k = 1:5
37 nc = netcdf(sprintf(fnc_in,k),'nowrite');
38 for j = 1:length(vnms)
39 eval(sprintf('ginfo(k).%s = nc{''%s''}(:);',vnms{j},vnms{j}));
40 end
41 nc = close(nc);
42
43 % compute 3D coords of the C and G points
44 cor = zeros( [ size(ginfo(k).XG) 3 ]);
45 [cor(:,:,1),cor(:,:,2),cor(:,:,3)] = sph2cart( ginfo(k).XG*d2r, ...
46 ginfo(k).YG*d2r,1 );
47 cen = zeros( [ size(ginfo(k).XC) 3 ]);
48 [cen(:,:,1),cen(:,:,2),cen(:,:,3)] = sph2cart( ginfo(k).XC*d2r, ...
49 ginfo(k).YC*d2r,1 );
50 ginfo(k).cor = cor;
51 ginfo(k).cen = cen;
52
53 % empty bathy
54 ginfo(k).bathy = zeros(size( size(ginfo(k).XC) ));
55 end
56
57 % Do a quick-and-dirty regrid
58 disp('Performing the regrid...');
59 %ph(
60 %%%s_lon = 0.0;
61 s_lon = -37.0;
62 %ph)
63 s_lat = 0.0;
64 for k = 1:5
65 disp(sprintf(' k = %d',k));
66 %
67 % / i,j+1 i+1,j+1 \
68 % \ i,j i+i,j /
69 for j = 1:size(ginfo(k).XC,2)
70 jr = [ j j+1 ];
71 for i = 1:size(ginfo(k).XC,1)
72 ir = [ i i+1 ];
73 lon_min = min(min( ginfo(k).XG(ir,jr) + s_lon ));
74 lon_max = max(max( ginfo(k).XG(ir,jr) + s_lon ));
75 lat_min = min(min( ginfo(k).YG(ir,jr) + s_lat ));
76 lat_max = max(max( ginfo(k).YG(ir,jr) + s_lat ));
77 % [ lon_min lon_max lat_min lat_max ]
78 lon_mm = [ mod(lon_min + 180,360)-180 ...
79 mod(lon_max + 180,360)-180 ];
80 lon_min = min(lon_mm);
81 lon_max = max(lon_mm);
82
83 d_lon = lon_max - lon_min;
84 if (abs(d_lon) > 45 && lat_min < 88)
85 i_lon = find( lons >= lon_max ...
86 | lons <= lon_min );
87 else
88 i_lon = find(lon_min <= lons & lons <= lon_max);
89 end
90 i_lat = find(lat_min <= lats & lats <= lat_max);
91
92 % average the bathy
93 bv = et2(i_lon,i_lat);
94 if length(bv(:)) > 1
95 ginfo(k).bathy(i,j) = mean(bv(:));
96 else
97 % If not averaging, then interpolate
98 % ginfo(k).bathy(i,j) = NaN;
99 i_lon = interp1(lons,[1:length(lons)],lon_min,'nearest');
100 i_lat = interp1(lats,[1:length(lats)],lat_min,'nearest');
101 ginfo(k).bathy(i,j) = et2(i_lon,i_lat);
102 end
103 end
104 end
105 end
106
107 % Plot the resulting bathymetry
108 k = 3;
109 for k = 1:5
110 disp(sprintf(' k = %d',k));
111 ginfo(k).b_oce = ginfo(k).bathy;
112 % ginfo(k).b_oce(find(ginfo(k).b_oce >= 0.0)) = NaN;
113 ginfo(k).b_oce(find(ginfo(k).b_oce >= 0.0)) = 1000;
114 if k == 2
115 hold on
116 end
117 % figure(k)
118 surf( ginfo(k).cor(:,:,1), ...
119 ginfo(k).cor(:,:,2), ...
120 ginfo(k).cor(:,:,3), ginfo(k).b_oce )
121 if k == 5
122 hold off
123 end
124 end
125 axis equal, view(2)
126
127
128 % Plot the bathymetry at 1/2 resolution
129 k = 3;
130 for k = 1:5
131 disp(sprintf(' k = %d',k));
132 ginfo(k).c_half = ginfo(k).cor(1:2:end,1:2:end,:);
133 ginfo(k).b_half = ginfo(k).bathy(1:2:end,1:2:end);
134 ginfo(k).b_half(find(ginfo(k).b_half >= 0.0)) = 1000;
135 if k == 2
136 hold on
137 end
138 % figure(k)
139 surf( ginfo(k).c_half(:,:,1), ...
140 ginfo(k).c_half(:,:,2), ...
141 ginfo(k).c_half(:,:,3), ginfo(k).b_half )
142 if k == 5
143 hold off
144 end
145 end
146 axis equal, view(2)
147
148 %--- BREAK POINT HERE
149 %--- do e.g. view(80,45) to change view angle
150
151
152
153 if do_print > 0
154 print -depsc llc_bathy.eps
155 end
156
157
158 % Write the bathymetry to netCDF compatible with MNC
159 id = 'bathy';
160 units = 'm';
161 for k = 1:5
162 disp(sprintf(' k = %d',k));
163 ginfo(k).b_out = ginfo(k).bathy;
164 ginfo(k).b_out(find(ginfo(k).bathy >= 0.0)) = 0.0;
165 bfile = sprintf('llc_p90_bathy.f%03d.nc',k);
166
167 nc = netcdf(bfile, 'clobber');
168 nc.reference = 'bathymetry';
169 nc.author = 'Ed Hill <eh3@mit.edu>';
170 nc.date = eval('date');
171 nc('X') = size( ginfo(k).XC, 1 );
172 nc('Y') = size( ginfo(k).XC, 2 );
173 nc{ id } = { 'Y', 'X' };
174 nc{ id }.units = units;
175 nc{ id }(:) = ginfo(k).b_out';
176 nc = close(nc);
177 end
178
179 % Write the bathymetry to a set of 90-by-90 per-tile MDSIO-compatible
180 % files
181 % face is js
182 iti = [ 1 1 1 ; ...
183 1 91 1 ; ...
184 1 181 1 ; ...
185 1 271 1 ; ...
186 2 1 1 ; ...
187 2 91 1 ; ...
188 2 181 1 ; ...
189 2 271 1 ; ...
190 3 1 1 ; ...
191 4 1 1 ; ...
192 4 1 91 ; ...
193 4 1 181 ; ...
194 4 1 271 ; ...
195 5 1 1 ; ...
196 5 1 91 ; ...
197 5 1 181 ; ...
198 5 1 271 ];
199 for k = 1:size(iti,1)
200 disp(sprintf(' k = %d',k));
201 fname = sprintf('bathy.%03d.001.data',k);
202 disp( fname )
203 fid = fopen(fname, 'w', 'ieee-be');
204 is = iti(k,3); ie = is + 90 - 1;
205 js = iti(k,2); je = js + 90 - 1;
206 tmp = ginfo(iti(k,1)).b_out(is:ie,js:je);
207 fwrite(fid,tmp,'real*8',0,'ieee-be');
208 fclose(fid);
209 surf(tmp), view(2), axis equal, shading flat, pause(1)
210 end
211
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