# Run a function in between each iteration of fsolve in MATLAB

I am using `fsolve` to minimise an energy function in MATLAB. The algorithm I am using fits a grid to noisy lattice data, with costs for the distances of the grid from each data point.

The objective function is formulated with squared error terms, to allow for the Gauss–Newton algorithm to be used. However, the program reverts to Levenberg-Marquardt:

``````Warning: Trust-region-dogleg algorithm of FSOLVE cannot handle non-square systems;
``````

I realised this is probably due to the fact that while the costs have squared errors, there is a stage in the objective (cost) function that chooses the nearest grid centre to each data point, thus making the algorithm non-square.

What I would like to do is to perform this assignment update of nearest grid centres separately to the evaluation of the Jacobian of the cost function. I believe this would then allow Gauss-Newton to be used, and significantly improve the speed of the algorithm.

Currently, I believe there is something like this going on:

``````while i < options.MaxIter && threshold has not been met
Compute Jacobian of cost function (which includes assignment routine)
Move down the slope in the direction of highest gradient
end
``````

What i would like to happen instead:

``````while i < options.MaxIter && threshold has not been met
Perform assignment routine
Compute Jacobian of cost function (which is now square, as no assignment occurs)
Move down the slope
end
``````

Is there a way to insert a function like this into the iterations without picking apart the whole of the `fsolve` algorithm? Even if I manually edited fsolve, would the nature of the Gauss-Newton algorithm allow me to add in this extra step?

Thanks

-

Since you're working with squared errors, anyway, you could use LSQNONLIN instead of `fsovle`. This allows you to compute the Jacobian (as well as all necessary preparations) in your objective function. The Jacobian is then returned as second output argument.
@Bill Cheatham: You may also be interested in looking at @woodchips' optimization tips and tricks, which includes `pleas.m`, and algorithm for partitioned least squares. If you have both linear and nonlinear unknowns, this algorithm can make a massive difference in terms of speed and stability. –  Jonas Apr 5 '11 at 15:33