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I'm trying to use the scipy Nelder-Mead simplex search function to find a minimum to a non-linear function. It appears my simplex gets stuck because it starts off with an initial simplex that is too small. Unfortunately, I don't see anywhere in scipy where you can change some of the simplex parameters (e.g. initial simplex size). Is there a way? Am I missing something? Or are there other implementations of the NM simplex?


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by "stuck" you mean, you have found a local minimum? –  Bort Mar 20 '12 at 14:48
try other initial conditions for x0, e.g. random numbers in the appropriate range, to find other minima –  Bort Mar 20 '12 at 14:55
i mean stuck as in it always returns to the initial values i give it. likely because the local space it search does not have any value change –  tomas Mar 20 '12 at 14:58
without seeing the code it's hard to parse what is going on here, but my gut feeling is that the function you wanna minimize actually spit out constant values in the vicinity of your initial arguments, maybe some discontinuities or illegal input parameters. –  nye17 Mar 20 '12 at 16:33
yea i think that's what's happening. I'm not sure exactly what my function looks like but there is likely to some discontinuities at certain points. –  tomas Mar 20 '12 at 17:05

2 Answers 2

Two suggestions for Nelder-Mead:

1) snap all x to a grid, say .01, inside the function:

x = np.round( x / grid ) * grid
f = ...

This acts as a simple noise filter in high dimensions (in 2d or 3d, don't bother).

2) start off with the best d+1 of 2d+1 nearby points, instead of the usual d+1:

def neard1( func, x, h, verbose=1 ):
    """ eval func at 2d+1 points x, x +- h
        -> f[ d+1 best values ],  X[ d+1 ] 
        to start or restart Nelder-Mead
    dim = len(x)
    I = np.eye(dim)
    np.fill_diagonal( I, h )  # scalar or vec
    X = x + np.vstack(( np.zeros(dim), I, - I ))
    fnear = np.array([ func( x ) for x in X ])  # 2d+1
    f0 = fnear[0]
    up = np.argsort( fnear )  # vec func: |fnear|
    if verbose:
        print "neard1: f %g +- %s  around x %s" % ( 
            f0, fnear[up] - f0, x )
    bestd1 = up[:dim+1]
    return fnear[bestd1], X[bestd1]

It's also not a bad idea to look at the neard1() values after Nelder-Mead, to get an idea of what func() looks like there.
If any neighbors are better then the N-M "best", restart N-M from that new simplex. (One can alternate neard1, N-M, neard1, N-M: easy but very problem-dependent.)

How many variables do you have, and how noisy is your function ?

Hope this helps

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From the reference at http://docs.scipy.org/doc/:

Method Nelder-Mead uses the Simplex algorithm [R54], [R55]. This algorithm has been     successful in many
applications but other algorithms using the first and/or second derivatives information might be preferred for
their better performances and robustness in general.

It may be recommended to use a completely different algorithm, then. Note that:

Method BFGS uses the quasi-Newton method of Broyden, Fletcher, Goldfarb, and Shanno (BFGS) [R58] pp.
136. It uses the first derivatives only. BFGS has proven good performance even for non-smooth optimizations

BFGS sounds more robust and faster overall.


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Um... thanks. I'm trying the BFGS method as well. Unfortunately, it uses first derivatives, which have to be estimated for my function using first differences. So not sure if it will be better. It might for sure. –  tomas Mar 20 '12 at 14:46

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