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michaesp |
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function out = get_index (vert,position,grid);
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% General index calculation for data grid
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% Usage: out = int_index(vert,coords,grid)
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% Example: grid.xmin = -180;
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% grid.dx = 1;
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% grid.nx = 361;
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% grid.ymin = 0;
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% grid.dy = 1;
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% grid.ny = 91;
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% out get_index(inp.P.data,[ 500 45 78; 250 56.7 78.4],grid)
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% Get the position arrays
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xpos = position(:,3)';
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ypos = position(:,2)';
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zpos = position(:,1)';
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% Get the grid dimension
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nx = size(vert,3);
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ny = size(vert,2);
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nz = size(vert,1);
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% Get the horiozontal grid indices
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rindx = (xpos-grid.xmin)/grid.dx+1;
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rindy = (ypos-grid.ymin)/grid.dy+1;
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% Special treatment if the the <vert> field is two-dimensional
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if ( nz == 1 )
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out = [ ones(size(rindy))', rindy', rindx' ];
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return;
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end
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% Direction of the vertical axis (Pressure: descencding, Height: ascending)
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dir = vert(2:nz,:,:) - vert(1:nz-1,:,:);
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if ( mean(dir(:)) > 0 )
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zpos = -zpos;
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vert = -vert;
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end
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% Get the weights for the individual grid points
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fracx = 1-rindx+floor(rindx);
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fracy = 1-rindy+floor(rindy);
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% Combine the indices i and j to a common index ij
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vert1 = reshape(vert,nz,nx*ny);
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% The position array and the vertical index is needed in the same format
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zpos1 = kron(ones(nz,1),zpos);
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zind1 = kron([1:nz]',ones(size(zpos)));
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shif1 = (0:length(zpos)-1) * nz;
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% Get the vertical indices at position 00
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indx = floor(rindx);
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indy = floor(rindy);
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indxy = indy+(indx-1)*ny;
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isnok1 = (indx<1) | (indx>nx) | (indy<1) | (indy>ny);
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indxy(isnok1) = 1;
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vert = vert1(:,indxy);
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indz = max((vert>=zpos1).*zind1);
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isnok2 = (indz<1) | (indz>=nz);
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indz(isnok2) = 1;
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indu = indz + shif1;
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indo = indz + 1 + shif1;
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diff = vert(indo)-vert(indu);
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isnok3 = (diff==0);
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diff(isnok3) = 1;
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rind00 = indz + (zpos-vert(indu)) ./ diff;
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isnok4 = isnok1 | isnok2 | isnok3;
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rind00(isnok4) = NaN;
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% Get the vertical indices at positions 01, 10, 11 (if necessary)
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if ( any(fracx ~= 1) | any(fracy ~=1) )
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indx = floor(rindx+1);
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indy = floor(rindy);
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indxy = indy+(indx-1)*ny;
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isnok1 = (indx<1) | (indx>nx) | (indy<1) | (indy>ny);
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indxy(isnok1) = 1;
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vert = vert1(:,indxy);
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indz = max((vert>zpos1).*zind1);
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isnok2 = (indz<1) | (indz>=nz);
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indz(isnok2) = 1;
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indu = indz + shif1;
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indo = indz + 1 + shif1;
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diff = vert(indo)-vert(indu);
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isnok3 = (diff==0);
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diff(isnok3) = 1;
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rind01 = indz + (zpos-vert(indu)) ./ diff;
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isnok4 = isnok1 | isnok2 | isnok3;
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rind01(isnok4) = NaN;
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indx = floor(rindx);
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indy = floor(rindy+1);
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indxy = indy+(indx-1)*ny;
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isnok1 = (indx<1) | (indx>nx) | (indy<1) | (indy>ny);
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indxy(isnok1) = 1;
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vert = vert1(:,indxy);
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indz = max((vert>zpos1).*zind1);
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isnok2 = (indz<1) | (indz>=nz);
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indz(isnok2) = 1;
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indu = indz + shif1;
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indo = indz + 1 + shif1;
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diff = vert(indo)-vert(indu);
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isnok3 = (diff==0);
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diff(isnok3) = 1;
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rind10 = indz + (zpos-vert(indu)) ./ diff;
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isnok4 = isnok1 | isnok2 | isnok3;
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rind10(isnok4) = NaN;
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indx = floor(rindx+1);
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indy = floor(rindy+1);
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indxy = indy+(indx-1)*ny;
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isnok1 = (indx<1) | (indx>nx) | (indy<1) | (indy>ny);
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indxy(isnok1) = 1;
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vert = vert1(:,indxy);
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indz = max((vert>zpos1).*zind1);
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isnok2 = (indz<1) | (indz>=nz);
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indz(isnok2) = 1;
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indu = indz + shif1;
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indo = indz + 1 + shif1;
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diff = vert(indo)-vert(indu);
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isnok3 = (diff==0);
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diff(isnok3) = 1;
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rind11 = indz + (zpos-vert(indu)) ./ diff;
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isnok4 = isnok1 | isnok2 | isnok3;
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rind11(isnok4) = NaN;
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else
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rind01 = rind00;
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rind10 = rind00;
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rind11 = rind00;
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end
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% Vectorised interpolation
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rindz = fracx .* fracy .* rind00 + ...
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(1-fracx) .* fracy .* rind01 + ...
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fracx .* (1-fracy) .* rind10 + ...
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(1-fracx) .* (1-fracy) .* rind11;
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% Set the output of the function
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nok = isnan(rindz') | isnan(rindy') | isnan(rindx');
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out = [ rindz', rindy', rindx' ];
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