I need to implement a "geometric median"-type algorithm that would apply to rigid bodies, meaning it would not only find a point minimizing the distance from a set of points, but would also take into account the orientation of the body. I haven't found a solution for this type of problem anywhere, while for the geometric median (or Weber or Fermat-Torricelli problem, or facilities location problem), there is a lot of information available, including the Weiszfeld algorithm (and modern improvements). I'm hoping someone will have references to possible solutions. I would have thought this to be a relatively common problem in registration, but maybe I just haven't found the right words to search for...
My problem could be formulated as follows: Say I have a "reference" rigid body with 3 non-colinear points (a triangle), and I measure the coordinates of the 3 points a bunch of times (with some error, or the object was moving a bit). I want to find a good "central location", that would minimize the sum of distances (not square distances) between each measured point and its corresponding centrally-located-object point. This is equivalent to the "multi-facility location problem" but with extra contstraints of fixed distances between the "facilities" and with each point pre-assigned to a facility (not necessarily the closest one).
Actually, I'm thinking instead of minimizing the sum for all the points, I'd only keep the max distance out of the 3 points for each measurement. (is that what's called "minimax"?) But I don't think that would make a big difference in the type of algorithm I'd have to use.
A possible difficulty compared to the geometric median could be that with the added freedom of rotations, the quantity to minimize is no longer convex (not 100% sure, but I think). I'm hoping I can still use a similar algorithm as Weiszfeld's (which is a subgradient method), and hopefully this has been investigated previously. Thanks for any help!
P.S. I'll be doing this in Matlab.