This question is related to the "numerical recipes in C++" book, so it will be reserved to people knowing a little about it as well as about multidimensional optimization.

I am writing a program that needs to search for a multidimensional root, and in order to solve it, I am using the multidimensional newton root finding method, namely the *"newt"* procedure.

For those interested in the details, I am trying to fit a deformable 3D model to a steresocopic view of an object, based on a few feature points (feature points which are seen by two cameras).

For this, I am using the newt procedure with the following :

*11 Input parameters :*my deformable model can be modeled with 11 parameters (composed of 5 geometric parameters and 6 deegres of freedom for the 3D object location) :*14 Output parameters*for which I need to find the root : based on feature points which are identified by the camera, and given a set on "input parameters", I can calculate a set of distances between the feature points seen by the camera and their theoretical location. I have 7 of those points, so that gives me 14 parameters (7 distances times 2, since I calculate the distances on both cameras)

My problem is that I have more output parameters (14) than input parameters (11) : whenever I call "newt", the algorithm always converges, however it will find a solution that minimizes almost perfectly the 11 first output parameters, but that has lots of errors on the 3 remaining parameters.

However I would like the errors to be uniformly divided among the output parameters.

I already tried the approaches described below :

- Try to combine the 14 output parameters into 11 parameter (for example, you take the average of some distances, instead of using both distances). However I am not 100% satisfied with this approach
- Mix several solutions with the following principle :
- Call mnewt and memorize the found root
- Change the order of the 14 output parameter
- Calling mnewt again and memorize the found root
- Compute a solution is the average of the two found roots

Does anyone know of a more generic approach, in which the root finding algorithm would favor an error that is uniformly divided among the output parameters, instead of favoring the first parameters?

lotsof local minima andlotsof flat zones in one direction (ie the derived on one component is null : a nightmare for newton-like methods) – Pascal T. Oct 28 '11 at 10:50