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
sort
-> 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