One way that you can do this, would be to use a surface object with a texture-map as the
In MATLAB, you can create a simple rectangular surface. You can set the
FaceColor to be
texturemap which will cause the value assigned to
CData to be mapped across the surface.
Then to get transparency, you can also set the
FaceAlpha value to be
texturemap and set the
AlphaData and those transparency values will be mapped across the extent of the surface as well.
For this to be applied to your case, you want to set the
CData to the image that you want to use to replace your arrows. And you will want the
AlphaData to be the same size as your image data with values of 1 where you want it to be opaque and 0 where you want it to be transparent. This will allow it to not look like the image that you have posted where you can clearly see the bounding box. Then you will need to draw one of these surfaces where each of the arrows would go and scale/position it appropriately.
Update: A more polished version of this code (
ImageQuiver) is now available on Github as well as the MATLAB File Exchange.
As a demonstration of what I'm talking about, I have created the following function which essentially does just this. It accepts the same inputs as
quiver (with the image data being supplied first and an optional
AlphaData parameter at the end) and creates a surface at all of the requested coordinates pointing in the requested direction, and scaled by the specified amount.
function h = quiverpic(im, X, Y, dX, dY, scale, alpha)
% im - RGB or indexed image
% X - X positions
% Y - Y positions
% dX - X direction vector
% dY - Y direction vector
% scale - Any scaling (Default = 1)
% alpha - Transparency (same size as im), if not specified = ~isnan(im)
h = hggroup();
if ~exist('scale', 'var')
% By default there is no scaling
scale = 1;
if ~exist('alpha', 'var')
% By default, any NaN will be transparent
alpha = ~isnan(im);
% Determine aspect ratio of the source image
width_to_height = size(im, 2) / size(im, 1);
for k = 1:numel(X)
% Determine angle from displacement vectors
theta = atan2(dY(k), dX(k));
% Subtract pi/2 to +y is considered "up"
theta = theta + pi/2;
% Setup surface plot boundary
[xx,yy] = meshgrid([-0.5, 0.5] * width_to_height, [0 1]);
% Scale depending on magnitude of dX and dY
this_scale = scale * sqrt(dX(k).^2 + dY(k).^2);
% Scale X and Y components prior to rotating
xx = xx .* this_scale;
yy = yy .* this_scale;
% Rotate to align with the desired direction
xdata = xx .* cos(theta) - yy .* sin(theta);
ydata = xx .* sin(theta) + yy .* cos(theta);
% Determine what is considered the "anchor" of the graphic.
% For now this is assumed to be the "bottom-middle"
xoffset = X(k) - mean(xdata(2,:));
yoffset = Y(k) - mean(ydata(2,:));
% Actually plot the surface.
surf(xdata + xoffset, ...
ydata + yoffset, zeros(2), ...
'Parent', h, ...
'FaceColor', 'texture', ...
'EdgeColor', 'none', ...
'CData', im, ...
'FaceAlpha', 'texture', ...
I wrote a little test script to show how this can be used and to show the results.
t = linspace(0, 2*pi, 13);
dX = cos(t(1:end-1));
dY = sin(t(1:end-1));
X = (3 * dX) + 5;
Y = (3 * dY) + 5;
scale = 1;
% Load the MATLAB logo as an example image
png = fullfile(matlabroot,'/toolbox/matlab/icons/matlabicon.gif');
[im, map] = imread(png);
im = ind2rgb(im, map);
% Determine alpha channel based on upper left hand corner pixel
flatim = reshape(im, , 3);
alpha = ~ismember(flatim, squeeze(im(1,1,:)).', 'rows');
alpha = reshape(alpha, size(im(:,:,1)));
% Plot some things prior to creating the quiverpic object
fig = figure();
hax = axes('Parent', fig);
% Plot a full circle
t = linspace(0, 2*pi, 100);
plot((cos(t) * 3) + 5, (sin(t) * 3) + 5, '-')
% Plot markers at all the quiver centers
plot(X, Y, 'o', 'MarkerFaceColor', 'w')
% Plot a random image behind everything to demonstrate transparency
him = imagesc(rand(9));
set(hax, 'clim', [-4 4]);
% Now plot the quiverpic
h = quiverpic(im, X, Y, dX, dY, 1, alpha);
Same image with varying vectors and scaling
Any image of any aspect ratio will work just fine