Mercurial > hg > octave-lyh
view scripts/geometry/griddata.m @ 14868:5d3a684236b0
maint: Use Octave coding conventions for cuddling parentheses in scripts directory
* lin2mu.m, loadaudio.m, wavread.m, accumarray.m, bicubic.m, celldisp.m,
colon.m, cplxpair.m, dblquad.m, divergence.m, genvarname.m, gradient.m,
int2str.m, interp1.m, interp1q.m, interp2.m, interpn.m, loadobj.m, nthargout.m,
__isequal__.m, __splinen__.m, quadgk.m, quadl.m, quadv.m, rat.m, rot90.m,
rotdim.m, saveobj.m, subsindex.m, triplequad.m, delaunay3.m, griddata.m,
inpolygon.m, tsearchn.m, voronoi.m, get_first_help_sentence.m, which.m,
gray2ind.m, pink.m, dlmwrite.m, strread.m, textread.m, textscan.m, housh.m,
ishermitian.m, issymmetric.m, krylov.m, logm.m, null.m, rref.m,
compare_versions.m, copyfile.m, dump_prefs.m, edit.m, fileparts.m,
getappdata.m, isappdata.m, movefile.m, orderfields.m, parseparams.m,
__xzip__.m, rmappdata.m, setappdata.m, swapbytes.m, unpack.m, ver.m, fminbnd.m,
fminunc.m, fsolve.m, glpk.m, lsqnonneg.m, qp.m, sqp.m, configure_make.m,
copy_files.m, describe.m, get_description.m, get_forge_pkg.m, install.m,
installed_packages.m, is_architecture_dependent.m, load_package_dirs.m,
print_package_description.m, rebuild.m, repackage.m, save_order.m, shell.m,
allchild.m, ancestor.m, area.m, axes.m, axis.m, clabel.m, close.m, colorbar.m,
comet.m, comet3.m, contour.m, cylinder.m, ezmesh.m, ezsurf.m, findobj.m,
fplot.m, hist.m, isocolors.m, isonormals.m, isosurface.m, isprop.m, legend.m,
mesh.m, meshz.m, pareto.m, pcolor.m, peaks.m, plot3.m, plotmatrix.m, plotyy.m,
polar.m, print.m, __add_datasource__.m, __add_default_menu__.m,
__axes_limits__.m, __bar__.m, __clabel__.m, __contour__.m, __errcomm__.m,
__errplot__.m, __ezplot__.m, __file_filter__.m, __fltk_print__.m,
__ghostscript__.m, __gnuplot_print__.m, __go_draw_axes__.m,
__go_draw_figure__.m, __interp_cube__.m, __marching_cube__.m, __patch__.m,
__pie__.m, __plt__.m, __print_parse_opts__.m, __quiver__.m, __scatter__.m,
__stem__.m, __tight_eps_bbox__.m, __uigetdir_fltk__.m, __uigetfile_fltk__.m,
__uiputfile_fltk__.m, quiver.m, quiver3.m, rectangle.m, refreshdata.m,
ribbon.m, scatter.m, semilogy.m, shading.m, slice.m, subplot.m, surface.m,
surfl.m, surfnorm.m, text.m, uigetfile.m, uiputfile.m, whitebg.m, deconv.m,
mkpp.m, pchip.m, polyaffine.m, polyder.m, polygcd.m, polyout.m, polyval.m,
ppint.m, ppjumps.m, ppval.m, residue.m, roots.m, spline.m, splinefit.m,
addpref.m, getpref.m, setpref.m, ismember.m, setxor.m, arch_fit.m, arch_rnd.m,
arch_test.m, autoreg_matrix.m, diffpara.m, fftconv.m, filter2.m, hanning.m,
hurst.m, periodogram.m, triangle_sw.m, sinc.m, spectral_xdf.m, spencer.m,
stft.m, synthesis.m, unwrap.m, yulewalker.m, bicgstab.m, gmres.m, pcg.m, pcr.m,
__sprand_impl__.m, speye.m, spfun.m, sprandn.m, spstats.m, svds.m,
treelayout.m, treeplot.m, bessel.m, factor.m, legendre.m, perms.m, primes.m,
magic.m, toeplitz.m, corr.m, cov.m, mean.m, median.m, mode.m, qqplot.m,
quantile.m, ranks.m, zscore.m, logistic_regression_likelihood.m,
bartlett_test.m, chisquare_test_homogeneity.m, chisquare_test_independence.m,
kolmogorov_smirnov_test.m, run_test.m, u_test.m, wilcoxon_test.m, z_test.m,
z_test_2.m, bin2dec.m, dec2base.m, mat2str.m, strcat.m, strchr.m, strjust.m,
strtok.m, substr.m, untabify.m, assert.m, demo.m, example.m, fail.m, speed.m,
test.m, now.m: Use Octave coding conventions for cuddling parentheses in
scripts directory.
| author | Rik <octave@nomad.inbox5.com> |
|---|---|
| date | Tue, 17 Jul 2012 07:08:39 -0700 |
| parents | 3f6489feca1e |
| children | bc924baa2c4e |
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## Copyright (C) 1999-2012 Kai Habel ## ## This file is part of Octave. ## ## Octave 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 3 of the License, or (at ## your option) any later version. ## ## Octave 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 Octave; see the file COPYING. If not, see ## <http://www.gnu.org/licenses/>. ## -*- texinfo -*- ## @deftypefn {Function File} {@var{zi} =} griddata (@var{x}, @var{y}, @var{z}, @var{xi}, @var{yi}) ## @deftypefnx {Function File} {@var{zi} =} griddata (@var{x}, @var{y}, @var{z}, @var{xi}, @var{yi}, @var{method}) ## @deftypefnx {Function File} {[@var{xi}, @var{yi}, @var{zi}] =} griddata (@dots{}) ## ## Generate a regular mesh from irregular data using interpolation. ## The function is defined by @code{@var{z} = f (@var{x}, @var{y})}. ## Inputs @code{@var{x}, @var{y}, @var{z}} are vectors of the same length ## or @code{@var{x}, @var{y}} are vectors and @code{@var{z}} is matrix. ## ## The interpolation points are all @code{(@var{xi}, @var{yi})}. If ## @var{xi}, @var{yi} are vectors then they are made into a 2-D mesh. ## ## The interpolation method can be @code{"nearest"}, @code{"cubic"} or ## @code{"linear"}. If method is omitted it defaults to @code{"linear"}. ## @seealso{griddata3, griddatan, delaunay} ## @end deftypefn ## Author: Kai Habel <kai.habel@gmx.de> ## Adapted-by: Alexander Barth <barth.alexander@gmail.com> ## xi and yi are not "meshgridded" if both are vectors ## of the same size (for compatibility) function [rx, ry, rz] = griddata (x, y, z, xi, yi, method = "linear") if (nargin < 5 || nargin > 7) print_usage (); endif if (ischar (method)) method = tolower (method); endif ## Meshgrid if x and y are vectors but z is matrix if (isvector (x) && isvector (y) && all ([numel(y), numel(x)] == size (z))) [x, y] = meshgrid (x, y); endif if (isvector (x) && isvector (y) && isvector (z)) if (! isequal (length (x), length (y), length (z))) error ("griddata: X, Y, and Z must be vectors of the same length"); endif elseif (! size_equal (x, y, z)) error ("griddata: lengths of X, Y must match the columns and rows of Z"); endif ## Meshgrid xi and yi if they are a row and column vector. if (rows (xi) == 1 && columns (yi) == 1) [xi, yi] = meshgrid (xi, yi); elseif (isvector (xi) && isvector (yi)) ## Otherwise, convert to column vectors xi = xi(:); yi = yi(:); endif if (! size_equal (xi, yi)) error ("griddata: XI and YI must be vectors or matrices of same size"); endif x = x(:); y = y(:); z = z(:); ## Triangulate data. tri = delaunay (x, y); zi = NaN (size (xi)); if (strcmp (method, "cubic")) error ("griddata: cubic interpolation not yet implemented"); elseif (strcmp (method, "nearest")) ## Search index of nearest point. idx = dsearch (x, y, tri, xi, yi); valid = !isnan (idx); zi(valid) = z(idx(valid)); elseif (strcmp (method, "linear")) ## Search for every point the enclosing triangle. tri_list = tsearch (x, y, tri, xi(:), yi(:)); ## Only keep the points within triangles. valid = !isnan (tri_list); tri_list = tri_list(valid); nr_t = rows (tri_list); tri = tri(tri_list,:); ## Assign x,y,z for each point of triangle. x1 = x(tri(:,1)); x2 = x(tri(:,2)); x3 = x(tri(:,3)); y1 = y(tri(:,1)); y2 = y(tri(:,2)); y3 = y(tri(:,3)); z1 = z(tri(:,1)); z2 = z(tri(:,2)); z3 = z(tri(:,3)); ## Calculate norm vector. N = cross ([x2-x1, y2-y1, z2-z1], [x3-x1, y3-y1, z3-z1]); ## Normalize. N = diag (norm (N, "rows")) \ N; ## Calculate D of plane equation ## Ax+By+Cz+D = 0; D = -(N(:,1) .* x1 + N(:,2) .* y1 + N(:,3) .* z1); ## Calculate zi by solving plane equation for xi, yi. zi(valid) = -(N(:,1).*xi(:)(valid) + N(:,2).*yi(:)(valid) + D) ./ N(:,3); else error ("griddata: unknown interpolation METHOD"); endif if (nargout == 3) rx = xi; ry = yi; rz = zi; elseif (nargout == 1) rx = zi; elseif (nargout == 0) mesh (xi, yi, zi); endif endfunction %!demo %! clf; %! colormap ("default"); %! x = 2*rand (100,1) - 1; %! y = 2*rand (size (x)) - 1; %! z = sin (2*(x.^2 + y.^2)); %! [xx,yy] = meshgrid (linspace (-1,1,32)); %! griddata (x,y,z,xx,yy); %! title ("nonuniform grid sampled at 100 points"); %!demo %! clf; %! colormap ("default"); %! x = 2*rand (1000,1) - 1; %! y = 2*rand (size (x)) - 1; %! z = sin (2*(x.^2 + y.^2)); %! [xx,yy] = meshgrid (linspace (-1,1,32)); %! griddata (x,y,z,xx,yy); %! title ("nonuniform grid sampled at 1000 points"); %!demo %! clf; %! colormap ("default"); %! x = 2*rand (1000,1) - 1; %! y = 2*rand (size (x)) - 1; %! z = sin (2*(x.^2 + y.^2)); %! [xx,yy] = meshgrid (linspace (-1,1,32)); %! griddata (x,y,z,xx,yy,"nearest"); %! title ("nonuniform grid sampled at 1000 points with nearest neighbor"); %!testif HAVE_QHULL %! [xx,yy] = meshgrid (linspace (-1,1,32)); %! x = xx(:); %! x = x + 10*(2*round (rand (size (x))) - 1) * eps; %! y = yy(:); %! y = y + 10*(2*round (rand (size (y))) - 1) * eps; %! z = sin (2*(x.^2 + y.^2)); %! zz = griddata (x,y,z,xx,yy,"linear"); %! zz2 = sin (2*(xx.^2 + yy.^2)); %! zz2(isnan (zz)) = NaN; %! assert (zz, zz2, 100*eps); %% Test input validation %!error griddata () %!error griddata (1) %!error griddata (1,2) %!error griddata (1,2,3) %!error griddata (1,2,3,4) %!error griddata (1,2,3,4,5,6,7) %!error <vectors of the same length> griddata (1:3, 1:3, 1:4, 1:3, 1:3) %!error <vectors of the same length> griddata (1:3, 1:4, 1:3, 1:3, 1:3) %!error <vectors of the same length> griddata (1:4, 1:3, 1:3, 1:3, 1:3) %!error <the columns and rows of Z> griddata (1:4, 1:3, ones (4,4), 1:3, 1:3) %!error <the columns and rows of Z> griddata (1:4, 1:3, ones (3,5), 1:3, 1:3) %!error <matrices of same size> griddata (1:3, 1:3, 1:3, 1:4, 1:3) %!error <matrices of same size> griddata (1:3, 1:3, 1:3, 1:3, 1:4)