# Irregular Shape Comparison

I'm trying to come up with a scoring system for some behavioural psychology research.

I ask people to draw a letter, then trace over it, both on a graphics tablet. I want to assess the accuracy of this trace. So, you draw any letter ('a'), then you do it again, then I score it based on how similar it was to the first time you drew it. The drawings are stored as pixel locations.

Accuracy is assessed as closeness to the original letter. The method does not need to allow for scale, rotation or position changing. Conceptually it's like the area between the two lines, only the lines are highly irregular, so integrals (to my knowledge) wont work.

I'm writing in MATLAB, but any conceptual help would be appreciated. I've tried summing the minimum distance between all pixels drawn on, but this gives good (low) scores to well placed single points.

This must have been done before, but I'm not having any luck with my searches. Any help much appreciated!

--- Partial Solution using method suggested by @Bill below. Doesn't work, as the bwdist gradient is too steep. Rather than the nice second image Bill shows, it looks more like the original.

``````%% Letter to image
im = zeros(1080,1920,3); % The screen (possible pixel locations)
% A small square a bit like the letter 'a', a couple of pixels wide.
pixthick = 5;
im(450:450+pixthick,[900:1100],:) = 1;
im(550:550+pixthick,[900:1100],:) = 1;
im([450:550],900:900+pixthick,:) = 1;
im([450:570],1100:1100+pixthick,:) = 1;
subplot(2,1,1); imagesc(im); %% atransbw = bwdist(im(:,:,1)<0.5); subplot(2,1,2);
imagesc(atransbw);
``````
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what is the problem with the method you already described? (the sum of the shortest distances) –  Ali Feb 6 '12 at 15:32
A single point can score very highly, as there is only one value to find the shortest distance for. E.g. imagine a dot in the center of a circle - the sum of the shortest distances would be small, meaning a good score, when it's actually quite a bad trace. –  dgmp88 Feb 6 '12 at 15:39

What could help you is a distance transform, implemented in MATLAB as `bwdist`. This rewards lines being close, even if they don't match.

``````a_img_1 = imread('a.jpg');
imagesc(a_img_1);
``````

``````a_img_1_dist_transform = bwdist( a(:, :, 1) < 250 );
imagesc(a_img_1_dist_transform);
``````

You can do the same with the second image, and sum up the difference in pixel values in the distance transformed images, something like:

``````score = sum( abs( a_img_1_dist_transform(:) - a_img_2_dist_transform(:) ) )
``````

(Note that this will give higher scores to less similar images and v.v.)

To help prevent issues that you mention of "good (low) scores to well placed single points", you could experiment with other distance measures, such as squared distance between pixel values.

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OK, I'll try and implement that - thanks! My only problem with this solution is that it's quite expensive given that the 'images' are only stored as vectors. Sorry, I think I wasn't so clear - image-comparison may not be the best tag. Still, this might work, I'll try in a moment after a meeting. Cheers! (tried to vote up but my rep isn't high yet) –  dgmp88 Feb 6 '12 at 15:41
Do you mean they are stored as vector images, rather than raster files? In that case, yes there will I'm sure be better ways than this answer. –  Bill Cheatham Feb 6 '12 at 15:43
Not even images - it's just a two dimensional vector of pixel locations where the pen touched the graphics tablet. –  dgmp88 Feb 6 '12 at 15:48
@dgmp88 - There is no problem to convert this to an image given the size of the tablet. –  Andrey Feb 6 '12 at 17:31
@dgmp88 - update(edit) your question instead. –  Andrey Feb 6 '12 at 18:28
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You may want to find an affine transform that will match with some error criterion, say mean squared error. This way you will be invariant to translation and scaling. Or if you wanted to penalize translation, you could add the cost of translation as well. (It would help us help you if you give more information on what kind of features do consider similar or otherwise)

Now, an efficient implementation is another matter. Perhaps you should look into image registration. I'm sure this has been done numerous times.

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Invariance to translation and scaling isn't important. Conceptually, some way to calculate the area between the original and the trace would be perfect. Something like what you see if you use the bucket fill tool in paint, for each place where the original and the trace deviate from each other, would be perfect. I'll look into affine transforms and image registration, cheers! –  dgmp88 Feb 6 '12 at 17:17

I would actually suggest a much more high-level solution. Find an OCR machine learning algorithm that returns some kind of confidence. Or, if you don't have confidence, test the distance between the output text and the actual.
This is like a human that watches the handwriting and attempts to understand it. The higher the confidence, the better the result.

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The OCR solution seems really high level. I'm sure it would work, but I'm hoping for a simpler solution, as I'm just using collections of pixel locations to define the letters. But yes, I may have to do this in the end :). –  dgmp88 Feb 6 '12 at 17:18

Shape contexts are a powerful feature descriptor based on "polar histograms" of the shapes. The Wikipedia page is in-depth, but here is another page with additional information (and a good visual explanation of the technique), as well as MATLAB demo code. Matching letters was one of the original applications of the method, and the demo code I link to doesn't require you to convert your trace vectors to images.

A more simplistic method might be an "image difference" defined as the exclusive-or of two letters. This would require converting your trace vectors to binary images. Something like:

``````x = xor(im1,im2);
d = sum(x(:)) / sum(im1(:)); %# normalize to the first image
``````

Finally, if your trace vectors have the same number of points, or can be made to by sampling, Procrustes Analysis could be useful. The idea of Procrustes analysis is to find a least-squares optimum linear transformation (rotation, translation and scaling) between two sets of points. Goodness of fit between the two point sets is given by the "Procrustes statistic" or other measures like root-mean-square deviation of the points.

``````%# Whatever makes sense;
%# procrustes needs N x 2 matrices with (x,y) coords for N points.
coords1 = [x1 y1];
coords2 = [x2 y2];

%# This sampling may be too naive.
n = max( size(coords1,1), size(coords2,1) );
coords1 = coords1(1:n,:);
coords2 = coords2(1:n,:);

%# d is sum-of-squares error
%# z is transformed coords2
%# tr is the linear transformation
[ d, z, tr ] = procrustes( coords1, coords2 );

%# RMS deviation of points may be better than SSE.
n = size(coords1,1);
rmsd = sqrt((sum((coords1(:) - z(:)).^2) / n));
``````
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Nice ideas, thanks! One problem though is that I don't want the invariance to various transformations which procrustes and shape contexts allow - too small/big/rotated count as errors. –  dgmp88 Feb 7 '12 at 9:09
You can use `procrustes(X,Y,'scaling',false)` to turn off the scaling component. You might also use RMSD or SSE of the points directly... –  reve_etrange Feb 7 '12 at 9:20
thanks, I'll test that and compare it with a different version of the solution proposed by Bill Cheatham I'm working on now. –  dgmp88 Feb 7 '12 at 13:22

This is my final, overcomplicated solution, which basically uses Bill Cheatham's method. Thanks for all the help!

``````% pixLet is the 2D vector contain locations where drawing occurred. First convert it to an image.

im = zeros(1000,1000); % This is the image
for pix = 2:size(pixLet,1)
y1 = pixLet(pix-1,2); x1 = pixLet(pix-1,1);
y2 = pixLet(pix,2); x2 = pixLet(pix,1);
xyd = round(pdist([x1 y1; x2 y2])*2);
xs = round(linspace(x1,x2,xyd));
ys = round(linspace(y1,y2,xyd));
for linepix = 1:length(xs)
im(ys(linepix),xs(linepix)) = 1;
end
end

% Blur the image
blur = fspecial('gaussian',[sz sz],reach);
gausIm = conv2(im,blur,'same');

% I made a function of the above to do this for both the template and the trace.
score = sum(sum(abs(gausIm1-gausIm2)));
``````
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