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% ------------------------------------------------------------------------
% Preparations
% ------------------------------------------------------------------------
% Add some matlab paths
addpath('/usr/local/matlabtools/mexnc/');
addpath('/usr/local/matlabtools/snctools/');
addpath('/usr/local/matlabtools/cdf_io/');
addpath('/home/sprenger/lagranto/matlab/');
% Set the datadirectories
cdfdir = '/lhome/sprenger/lagranto/test/cdf/';
tradir = '/home/sprenger/lagranto/matlab/';
% Read a trajectory file
tra = read_trajectory( [ tradir '/trajectory2.lsl' ]);
% Set the tabel for input files
filelist.n = 4;
filelist.date(1) = cellstr('19891020_00'); filelist.time(1) = 0;
filelist.date(2) = cellstr('19891020_06'); filelist.time(2) = 6;
filelist.date(3) = cellstr('19891020_12'); filelist.time(3) = 12;
filelist.date(4) = cellstr('19891020_18'); filelist.time(4) = 18;
% Get the grid parameters from first data file
inp = ncget([ cdfdir 'P' char(filelist.date(1)) ],'U','PS');
grid.nx = size(inp.U.data,3);
grid.ny = size(inp.U.data,2);
grid.nz = size(inp.U.data,1);
grid.xmin = inp.cstfile.lonmin;
grid.ymin = inp.cstfile.latmin;
grid.dx = inp.cstfile.dellon;
grid.dy = inp.cstfile.dellat;
grid.xmax = grid.xmin + double(grid.nx-1) * grid.dx;
grid.ymax = grid.ymin + double(grid.ny-1) * grid.dy;
grid.mdv = -999.
grid.lon1 = grid.xmin + double(0:grid.nx-1) * grid.dx;
grid.lat1 = grid.ymin + double(0:grid.ny-1) * grid.dy;
[ grid.lon2 grid.lat2 ] = meshgrid(grid.lon1,grid.lat1);
grid.aklay = inp.cstfile.aklay;
grid.aklev = inp.cstfile.aklev;
grid.bklay = inp.cstfile.bklay;
grid.bklev = inp.cstfile.bklev;
% ------------------------------------------------------------------------
% Loop over al trajectory times
% ------------------------------------------------------------------------
% Set flags for load manager
load0 = -1;
load1 = -1;
% No trajectories are selected
select = zeros(tra.ntra,1);
% Init the textlines
for j=1:tra.nfield
textline(j) = cellstr(' ');
end
first = 1;
% Loop over all trajectory times
i = 1;
stat = 1;
while ( stat ~= 0 )
% Get the time
time = tra.time(i);
% Decide which data files are needed
need0 = find( time <= filelist.time , 1 );
need1 = need0 + 1;
if ( need1 > filelist.n )
need1 = need0;
end
% Load files if not yet done
if ( need0 == load1 )
inp0 = inp1;
load0 = need0;
end
if ( need1 == load0 )
inp1 = inp0;
load1 = need1;
end
if ( need0 ~= load0 )
inps = ncget([ cdfdir 'S' char(filelist.date(need0)) ],'TH','PV','RH');
inpp = ncget([ cdfdir 'P' char(filelist.date(need0)) ],'Q','U','V','T','PS');
inp0 = inpp;
inp0.TH = inps.TH;
inp0.PV = inps.PV;
inp0.RH = inps.RH;
inp0.P = inp.PS;
inp0.P.data = kron(inp0.PS.data,grid.bklay) + kron(ones(grid.ny,grid.nx),grid.aklay);
inp0.P.data = reshape(inp0.P.data,grid.nz,grid.ny,grid.nx);
load0 = need0;
end
if ( need1 ~= load1 )
inps = ncget([ cdfdir 'S' char(filelist.date(need1)) ],'TH','PV','RH');
inpp = ncget([ cdfdir 'P' char(filelist.date(need1)) ],'Q','U','V','T','PS');
inp1 = inpp;
inp1.TH = inps.TH;
inp1.PV = inps.PV;
inp1.RH = inps.RH;
inp1.P = inp.PS;
inp1.P.data = kron(inp1.PS.data,grid.bklay) + kron(ones(grid.ny,grid.nx),grid.aklay);
inp1.P.data = reshape(inp1.P.data,grid.nz,grid.ny,grid.nx);
load1 = need1;
end
% Get the mean pressure of the trajectory sample
if ( any(select) )
mask = ( find(select) - 1) * tra.ntime + i;
else
mask = ( (1:tra.ntra) -1 ) * tra.ntime + i;
end
hori.level = mean ( tra.p ( mask ) );
% Interpolate fields to a pressure surface
[ xpos ypos zpos ] = meshgrid( grid.lon1, grid.lat1, hori.level );
ind = get_index(inp0.P.data,[ zpos(:) ypos(:) xpos(:) ],grid);
hori0.U = reshape( int_index(inp0.U.data,ind,grid.mdv), 1,grid.ny,grid.nx);
hori0.V = reshape( int_index(inp0.V.data,ind,grid.mdv), 1,grid.ny,grid.nx);
hori0.VEL = sqrt(hori0.U .^ 2 + hori0.V .^ 2);
[ xpos ypos zpos ] = meshgrid( grid.lon1, grid.lat1, hori.level );
ind = get_index(inp1.P.data,[ zpos(:) ypos(:) xpos(:) ],grid);
hori1.U = reshape( int_index(inp1.U.data,ind,grid.mdv), 1,grid.ny,grid.nx);
hori1.V = reshape( int_index(inp1.V.data,ind,grid.mdv), 1,grid.ny,grid.nx);
hori1.VEL = sqrt(hori1.U .^ 2 + hori1.V .^ 2);
% Do a time interpolation (and get rid of 1-dimensions)
if ( need1 ~= need0 )
frac = ( time - filelist.time(need0) ) / ( filelist.time(need1) - filelist.time(need0) );
hori.U = squeeze( (1-frac) * hori0.U + frac * hori1.U );
hori.V = squeeze( (1-frac) * hori0.V + frac * hori1.V );
hori.VEL = squeeze( (1-frac) * hori0.VEL + frac * hori1.VEL );
else
hori.U = squeeze( hori0.U );
hori.V = squeeze( hori0.V );
hori.VEL = squeeze( hori0.VEL );
end
% Open a new figure ans set the geographical projection
figure(1);
clf;
load coast
%h=axesm('MapProjection','stereo','origin',[ 90 0 ]);
h=axesm( 'eqdcylin','MapLatLimit',[ 20 80 ], 'MapLonLimit', [ -100 40 ] );
gridm;
h=plotm(lat,long,'Color','k','LineWidth',1.5);
%axis([-0.6 0.67 -1.2 -0.1]);
axis([ -1.0 1.0 0.4000 1.4000 ]);
daspect([ 1 0.75 1] );
title ( [ 'P = ' num2str(round(hori.level)) ' hPa / T = ' num2str(time) ' h'],...
'FontSize',22)
% Plot velocity and overlay wind vectors
c_map = col_scale([0:2.5:50 ],hori.VEL);
[C,h] = contourfm(grid.lat1,grid.lon1,c_map.data,c_map.xtick);
colormap('default');
col_load( [ pwd '/col_table.txt' ],c_map.xtick,44);
caxis(c_map.caxis)
q=colorbar('vert');
set(q,'ytick',c_map.xtick,'YTickLabel',c_map.label,'FontSize',15);
[ c_map.x c_map.y ] = meshgrid(grid.lon1,grid.lat1);
c_map.u = squeeze(hori.U);
c_map.v = squeeze(hori.V);
maskx = 1:2:size(grid.lon2,2);
masky = 1:2:size(grid.lon2,1);
hold on
q=quiverm(grid.lat2(masky,maskx),grid.lon2(masky,maskx),...
hori.V (masky,maskx),hori.U (masky,maskx),'k');
set(q,'Linewidth',1,'Color','k')
hold off
% Handle user commands
stat = 2;
while ( stat == 2 )
% Show the positions of the trajectory points
hold on
for j=1:tra.ntra
if select(j)
mask = ( tra.time == time ) & ( tra.label == j );
plotm(tra.lat(mask),tra.lon(mask),'o','markersize',10,'color','r',...
'MarkerEdgeColor','k','MarkerFaceColor','r');
else
mask = ( tra.time == time ) & ( tra.label == j );
plotm(tra.lat(mask),tra.lon(mask),'o','markersize',10,'color','k',...
'MarkerEdgeColor','k','MarkerFaceColor','k');
end
end
hold off
% Get the cursor position
[ x y ] = ginput(1)
plotdom = axis;
% Step backward
if ( x < plotdom(1) )
i = i - 1;
if ( i < 1)
i = tra.ntime;
end
stat = 1;
% Step forward
elseif ( x > plotdom(2) )
i = i + 1;
if ( i > tra.ntime )
i = 1;
end
stat = 1;
% Exit
elseif ( y > plotdom(4) )
stat = 0;
% Write trajectory info
elseif ( (y < plotdom(3)) & any(select) )
for j=1:tra.nfield
mask = ( find(select) - 1) * tra.ntime + i;
val = tra.(char(tra.field(j)));
val = mean( val(mask) );
if ( first == 0 )
text(plotdom(1),plotdom(3)-0.04*j,char(textline(j)),...
'FontSize',15,'Color','g' );
end
textline(j) = cellstr([ char(tra.field(j)) ' = ' num2str(val)]);
text(plotdom(1),plotdom(3)-0.04*j,char(textline(j)),...
'FontSize',15,'Color','b' );
first = 0;
end
% Select trajectory points
else
[ lat0, lon0 ] = minvtran(x,y);
mask = (tra.time == time );
lon1 = tra.lon(mask);
lat1 = tra.lat(mask);
dist = distance(lat0,lon0,lat1,lon1);
label = find( min(dist) == dist );
if ( dist(label) < 5 )
if ( select(label) == 0 )
select(label) = 1;
elseif ( select(label) == 1 )
select(label) = 0;
end
else
stat = 1;
end
end
end
% End loop
end