Mercurial > octave
view scripts/plot/scatter.m @ 14237:11949c9795a0
Revamp %!demos in m-files to use Octave coding conventions on spacing, etc.
Add clf() to all demos using plot features to get reproducibility.
Use 64 as input to all colormaps (jet (64)) to get reproducibility.
* bicubic.m, cell2mat.m, celldisp.m, cplxpair.m, interp1.m, interp2.m,
interpft.m, interpn.m, profile.m, profshow.m, convhull.m, delaunay.m,
griddata.m, inpolygon.m, voronoi.m, autumn.m, bone.m, contrast.m, cool.m,
copper.m, flag.m, gmap40.m, gray.m, hot.m, hsv.m, image.m, imshow.m, jet.m,
ocean.m, pink.m, prism.m, rainbow.m, spring.m, summer.m, white.m, winter.m,
condest.m, onenormest.m, axis.m, clabel.m, colorbar.m, comet.m, comet3.m,
compass.m, contour.m, contour3.m, contourf.m, cylinder.m, daspect.m,
ellipsoid.m, errorbar.m, ezcontour.m, ezcontourf.m, ezmesh.m, ezmeshc.m,
ezplot.m, ezplot3.m, ezpolar.m, ezsurf.m, ezsurfc.m, feather.m, fill.m,
fplot.m, grid.m, hold.m, isosurface.m, legend.m, loglog.m, loglogerr.m,
pareto.m, patch.m, pbaspect.m, pcolor.m, pie.m, pie3.m, plot3.m, plotmatrix.m,
plotyy.m, polar.m, quiver.m, quiver3.m, rectangle.m, refreshdata.m, ribbon.m,
rose.m, scatter.m, scatter3.m, semilogx.m, semilogxerr.m, semilogy.m,
semilogyerr.m, shading.m, slice.m, sombrero.m, stairs.m, stem.m, stem3.m,
subplot.m, surf.m, surfc.m, surfl.m, surfnorm.m, text.m, title.m, trimesh.m,
triplot.m, trisurf.m, uigetdir.m, uigetfile.m, uimenu.m, uiputfile.m,
waitbar.m, xlim.m, ylim.m, zlim.m, mkpp.m, pchip.m, polyaffine.m, spline.m,
bicgstab.m, cgs.m, gplot.m, pcg.m, pcr.m, treeplot.m, strtok.m, demo.m,
example.m, rundemos.m, speed.m, test.m, calendar.m, datestr.m, datetick.m,
weekday.m: Revamp %!demos to use Octave coding conventions on spacing, etc.
| author | Rik <octave@nomad.inbox5.com> |
|---|---|
| date | Fri, 20 Jan 2012 12:59:53 -0800 |
| parents | 72c96de7a403 |
| children | 4506eade9f04 |
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## Copyright (C) 2007-2012 David Bateman ## ## 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} {} scatter (@var{x}, @var{y}) ## @deftypefnx {Function File} {} scatter (@var{x}, @var{y}, @var{s}) ## @deftypefnx {Function File} {} scatter (@var{x}, @var{y}, @var{c}) ## @deftypefnx {Function File} {} scatter (@var{x}, @var{y}, @var{s}, @var{c}) ## @deftypefnx {Function File} {} scatter (@var{x}, @var{y}, @var{s}, @var{c}, @var{style}) ## @deftypefnx {Function File} {} scatter (@var{x}, @var{y}, @var{s}, @var{c}, @var{prop}, @var{val}) ## @deftypefnx {Function File} {} scatter (@dots{}, "filled") ## @deftypefnx {Function File} {} scatter (@var{h}, @dots{}) ## @deftypefnx {Function File} {@var{h} =} scatter (@dots{}) ## ## Plot a scatter plot of the data. A marker is plotted at each point ## defined by the points in the vectors @var{x} and @var{y}. The size of ## the markers used is determined by the @var{s}, which can be a scalar, ## a vector of the same length of @var{x} and @var{y}. If @var{s} is not ## given or is an empty matrix, then the default value of 8 points is used. ## ## The color of the markers is determined by @var{c}, which can be a string ## defining a fixed color; a 3-element vector giving the red, green,and blue ## components of the color; a vector of the same length as @var{x} that gives ## a scaled index into the current colormap; or a @var{n}-by-3 matrix defining ## the colors of each of the markers individually. ## ## The marker to use can be changed with the @var{style} argument, that is a ## string defining a marker in the same manner as the @code{plot} command. ## If the argument @code{"filled"} is given then the markers as filled. All ## additional arguments are passed to the underlying patch command. ## ## The optional return value @var{h} provides a handle to the patch object ## ## @example ## @group ## x = randn (100, 1); ## y = randn (100, 1); ## scatter (x, y, [], sqrt(x.^2 + y.^2)); ## @end group ## @end example ## ## @seealso{plot, patch, scatter3} ## @end deftypefn function retval = scatter (varargin) [h, varargin, nargin] = __plt_get_axis_arg__ ("scatter", varargin{:}); if (nargin < 2) print_usage (); else oldh = gca (); unwind_protect axes (h); newplot (); tmp = __scatter__ (h, 2, "scatter", varargin{:}); unwind_protect_cleanup axes (oldh); end_unwind_protect endif if (nargout > 0) retval = tmp; endif endfunction %!demo %! clf; %! x = randn (100, 1); %! y = randn (100, 1); %! scatter (x, y, "r"); %! title ("Scatter plot with red bubbles"); %!demo %! clf; %! x = randn (100, 1); %! y = randn (100, 1); %! scatter (x, y, [], sqrt (x.^2 + y.^2)); %! title ("Scatter plot with bubble color determined by distance from origin"); %!demo %! clf; %! rand_10x1_data1 = [0.171577, 0.404796, 0.025469, 0.335309, 0.047814, 0.898480, 0.639599, 0.700247, 0.497798, 0.737940]; %! rand_10x1_data2 = [0.75495, 0.83991, 0.80850, 0.73603, 0.19360, 0.72573, 0.69371, 0.74388, 0.13837, 0.54143]; %! x = rand_10x1_data1; %! y = rand_10x1_data2; %! s = 10 - 10*log (x.^2 + y.^2); %! h = scatter (x, y, s, s, "s", "filled"); %! title ({"Scatter plot with filled square markers", ... %! "size and color of markers determined by algorithm"}); %!demo %! clf; %! rand_10x1_data3 = [0.42262, 0.51623, 0.65992, 0.14999, 0.68385, 0.55929, 0.52251, 0.92204, 0.19762, 0.93726]; %! rand_10x1_data4 = [0.020207, 0.527193, 0.443472, 0.061683, 0.370277, 0.947349, 0.249591, 0.666304, 0.134247, 0.920356]; %! x = rand_10x1_data3; %! y = rand_10x1_data4; %! s = 10 - 10*log (x.^2 + y.^2); %! h = scatter (x, y, [], "r", "s", "filled"); %!demo %! clf; %! rand_10x1_data5 = [0.777753, 0.093848, 0.183162, 0.399499, 0.337997, 0.686724, 0.073906, 0.651808, 0.869273, 0.137949]; %! rand_10x1_data6 = [0.37460, 0.25027, 0.19510, 0.51182, 0.54704, 0.56087, 0.24853, 0.75443, 0.42712, 0.44273]; %! x = rand_10x1_data5; %! y = rand_10x1_data6; %! s = 10 - 10*log (x.^2 + y.^2); %! h = scatter (x, y, [], "r", "s"); %!demo %! clf; %! k = 1; %! for m = [1, 3] %! for n = [101, 50, 1] %! x = rand (n, 1); %! y = rand (n, 1); %! if (m > 1) %! str = "Three Colors"; %! idx = ceil (rand (n, 1) * 3); %! colors = eye (3); %! colors = colors(idx, :); %! else %! str = "Random Colors"; %! colors = rand (n, m); %! endif %! if (n == 1) %! str = sprintf ("%s: 1 point", str); %! elseif (n < 100) %! str = sprintf ("%s: < 100 points", str); %! else %! str = sprintf ("%s: > 100 points", str); %! endif %! subplot (2,3,k); %! k = k + 1; %! scatter (x, y, 15, colors, "filled"); %! axis ([0 1 0 1]); %! title (str); %! endfor %! endfor %!demo %! clf; %! k = 1; %! for m = [1, 3] %! for n = [101, 50, 1] %! x = rand (n, 1); %! y = rand (n, 1); %! if (m > 1) %! str = "Three Colors"; %! idx = ceil (rand (n, 1) * 3); %! colors = eye (3); %! colors = colors(idx, :); %! else %! str = "Random Colors"; %! colors = rand (n, m); %! endif %! if (n == 1) %! str = sprintf ("%s: 1 point", str); %! elseif (n < 100) %! str = sprintf ("%s: < 100 points", str); %! else %! str = sprintf ("%s: > 100 points", str); %! endif %! subplot (2,3,k); %! k = k + 1; %! scatter (x, y, 15, colors); %! axis ([0 1 0 1]); %! title (str); %! endfor %! endfor