# Power law with a constant factor using curve_fitting

I want to fit my x and y data using power law with a constant factor. My power law model is y(r) = F0 + F*(r)**alpha where F0 is a constant. My code is,

``````x = [0.015000000000000001, 0.024999999999999998, 0.034999999999999996, 0.044999999999999998, 0.055, 0.065000000000000002, 0.075000000000000011, 0.085000000000000006, 0.094999999999999987, 0.125, 0.17500000000000002, 0.22500000000000003, 0.27500000000000002]

y= [5.6283727993522774, 4.6240796612752799, 3.7366642904247769, 3.0668203445969828, 2.5751865553847577, 2.0815063796430979, 1.7152655187581032, 1.4686235817532258, 1.2501921057958358, 0.80178306738561222, 0.43372429238424598, 0.26012305284446235, 0.19396186239328625]

def func(x,m,c,c0):
return c0 + x**m * c

coeff,var=curve_fit(func,x,y)

print coeff

Traceback (most recent call last):
File "<stdin>", line 1, in <module>
File "/usr/local/lib/python2.6/dist-packages/scipy/optimize/minpack.py", line 511, in curve_fit
raise RuntimeError(msg)
RuntimeError: Optimal parameters not found: Number of calls to function has reached maxfev = 800.
``````

Then I changed maxfev=2000 then it gives me wrong coeff values. If I change, my slope m to (-m) in func then it gives me right answer but my slope will be negative. Is there any way to overcome this problem?

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The issue is that `curve_fit` is starting with default guesses for the parameters that are too poor (namely, it starts them all at 1).

Instead, use what you know about the data to make a very rough guess: at the very least, you know `m` must be negative (since it's a power law). Therefore, try starting `m` at `-1`. (You can start the intercept term at `0` and the slope term at `1` since those are reasonable defaults).

``````def func(x,m,c,c0):
return c0 + x**m * c

coeff,var=curve_fit(func,x,y, p0=[-1, 1, 0])
``````

This gives you the correct output:

``````[-0.34815029  2.16546037 -3.4650323 ]
``````

(Note that you can start `m` with any number between `0` and `-9` and it still converges to this result).

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Looking at your data, an idea would be to rescale your problem, given the order of magnitude of difference between X and Y.

An example is given in details in first post.

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