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Given a "shape" drawn by the user, I would like to "normalize" it so they all have similar size and orientation. What we have is a set of points. I can approximate the size using bounding box or circle, but the orientation is a bit more tricky.

The right way to do it, I think, is to calculate the majoraxis of its bounding ellipse. To do that you need to calculate the eigenvector of the covariance matrix. Doing so likely will be way too complicated for my need, since I am looking for some good-enough estimate. Picking min, max, and 20 random points could be some starter. Is there an easy way to approximate this?

Edit: I found Power method to iteratively approximate eigenvector. Wikipedia article. So far I am liking David's answer.

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You'd be calculating the eigenvectors of a 2x2 matrix, which can be done with a few simple formulas, so it's not that complicated. In pseudocode:

// sums are over all points
b = -(sum(x * x) - sum(y * y)) / (2 * sum(x * y))
evec1_x = b + sqrt(b ** 2 + 1)
evec1_y = 1
evec2_x = b - sqrt(b ** 2 + 1)
evec2_y = 1

You could even do this by summing over only some of the points to get an estimate, if you expect that your chosen subset of points would be representative of the full set.

Edit: I think x and y must be translated to zero-mean, i.e. subtract mean from all x, y first (eed3si9n).

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If this calculates the eigenvector of the covariance matrix, it's great. Is there a link that points to this method? – Eugene Yokota Feb 19 '09 at 5:18
Check out number-none.com/product/My%20Friend,%20the%20Covariance%20Body/… and the sample code at gdmag.com/code.htm (sep02.zip) – Dave Feb 19 '09 at 5:59
I found a quick cheat for 2x2 matrix's eigenvector: tinyurl.com/cd998p. For C = |E(x*x) E(x*y)||E(x*y) E(y*y)|, L1-d/c comes out to be (sum(x*x) - sum(y*y))/(2 * sum(x*y))+sqrt(((sum(x*x) - sum(y*y))/(2 * sum(x*y)))^2 + 1), which is exactly b + sqrt(b^2 + 1). – Eugene Yokota Feb 20 '09 at 8:18
As I added to the answer, I think x and y need to be adjusted to zero-mean. – Eugene Yokota Feb 20 '09 at 8:23
You're right, they do... I guess I was implicitly assuming that when I wrote out the formulas. – David Zaslavsky Feb 20 '09 at 16:43
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up vote 3 down vote

Here's a thought... What if you performed a linear regression on the points and used the slope of the resulting line? If not all of the points, at least a sample of them.

The r^2 value would also give you information about the general shape. The closer to 0, the more circular/uniform the shape is (circle/square). The closer to 1, the more stretched out the shape is (oval/rectangle).

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up vote 2 down vote

The ultimate solution to this problem is running PCA
I wish I could find a nice little implementation for you to refer to...

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I was going to say PCA. This is the ultimate correct answer. – Alex Feb 18 '09 at 8:21
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