Scipy optimize: Set maximum error

I'm trying to optimize a 4 dimensional function with scipy. Everything works so far, except that I'm not satisfied with the quality of the solution. Right now I have ground truth data, which I use to verify my code. What I get so far is:

``````End error:  1.52606896507e-05
End Gradient:  [ -1.17291295e-05   2.60362493e-05   5.15347856e-06  -2.72388430e-05]

Ground Truth:   [0.07999999..., 0.0178329..., 0.9372903878..., 1.7756283966...]
Reconstructed:  [ 0.08375729  0.01226504  1.13730592  0.21389899]
``````

The error itself sounds good, but as the values are totally wrong I want to force the optimization algorithm (BFGS) to do more steps.

In the documentation I found the options 'gtol' and 'norm' and I tried to set both to pretty small values (like 0.0000001) but it did not seem to change anything.

Background: The problem is, that I try to demodulate waves, so I have sin and cos terms and potentially many local (or global) minima. I use bruteforce search to find a good starting point, witch helps a lot, but it currently seems that the most work is done by that brute force search, as the optimization uses often only one iteration step. So I'm trying to improve that part of the calculation somehow.

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I don't know much about waves, but it seems to me there should be a relationship between your tolerances and the distances separating local extrema. If your tolerance is much smaller than such a distance, then you'll fall into the closest local extremum. Another question that comes to mind: does your objective function have saddle points? Is there something you can do in the brute force step wrt the Hessian to avoid these? –  wkschwartz Sep 17 '13 at 17:05
My guess is that a analytical gradient would help for the optimization. If you use your "Ground Truth" as starting values, does the optimization actually stay there and give a better value for the objective function? –  user333700 Sep 17 '13 at 21:23

Many local minima + hardly any improvement after brute search, that sounds bad. It's hard to say something very specific with the level of detail you provide in the question, so here are vague ideas to try (basically, what I'd do if I suspect my minimizer gets stuck):

• try manually starting the minimizer from a bunch of different initial guesses.
• try using a stochastic minimizer. You're tagging a question `scipy`, so try `basinhopping`
• if worst comes to worst, just throw random points in a loop, leave it to work over the lunch break (or overnight)

Also, waves, sines and cosines --- it might be useful to think if you can reformulate your problem in the Fourier space.

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I found out that the gradient at the starting point is already very flat (values in 10^-5), so I tried to scale the gradient function witch I already provided. This seemed to be pretty effective, I could force the Algorithm to do much more steps and my results are far better now. They are not perfect though, but a complete discussion of this is outside of the bounds of this question, so I might start a new one, where I describe the whole problem from bottom up.

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