I have a question regarding Active Shape Models. I am using the paper of T. Coots (which can be found here.)

I have done all of the initial steps (Procrustes Analysis to calculate mean shape, PCA to reduce dimensions) but am stuck on fitting.

This is the situation I am in now: I have calculated the mean shape with points **X** and have also calculated a new set of points **Y** that **X** should move to, to better fit my image.

I am using the following algorithm, which can be found on page 23 of the paper previously linked:

To clarify: is the mean shape calculated with Procrustes Analysis, and the is the matrix containing the eigenvectors calculated with PCA.

Everything goes well up to step 4. I can calculate the pose parameters and invert the transformation onto the points **Y**.

However, in stap 5, something strange happens. Whatever the pose parameters are calculated in stap 3 and applied in stap 4, stap 5 always results in almost exactly the same vector **y'** with very low values (one of them being 1.17747114e-05 for example). (So whether i calculated a scale of 1/10 or 1000, **y'** barely changes).

This results in the algorithm always converging to the same value of **b**, and thus in the same output shape **x**, no matter what the input set of target points **Y** are that I want the model points **X** to match with.

This sure is not the goal of the algorithm... Could anyone explain this strange behaviour? Somehow, projecting my calculated vector **y** in *step 5* into the "tangent plane" does not take into account any of the changes made in *step 4*.

Edit: I have some more reasoning, though no explanation or solution. If, in *step 5*, i manually set **y'** to consist only of zeros, then in *step 6*, **b** is equal to the matrix of **eigenvectors multiplicated with the meanshape**. And this results in the same b I always get (since **y'** is always a vector with very low values).

But these eigenvectors are calculated from the meanshape using PCA... So what's expected, is that no change should take place, right?