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I want to use numpy.polyfit for physical calculations, therefore I need the magnitude of the error.

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2 Answers

If you specify full=True in your call to polyfit, it will include extra information:

>>> x = np.arange(100)
>>> y = x**2 + 3*x + 5 + np.random.rand(100)
>>> np.polyfit(x, y, 2)
array([ 0.99995888,  3.00221219,  5.56776641])
>>> np.polyfit(x, y, 2, full=True)
(array([ 0.99995888,  3.00221219,  5.56776641]), # coefficients
 array([ 7.19260721]), # residuals
 3, # rank
 array([ 11.87708199,   3.5299267 ,   0.52876389]), # singular values
 2.2204460492503131e-14) # conditioning threshold

The residual value returned is the sum of the squares of the fit errors, not sure if this is what you are after:

>>> np.sum((np.polyval(np.polyfit(x, y, 2), x) - y)**2)

In version 1.7 there is also a cov keyword that will return the covariance matrix for your coefficients, which you could use to calculate the uncertainty of the fit coefficients themselves.

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As you can see in the documentation:

p : ndarray, shape (M,) or (M, K)
    Polynomial coefficients, highest power first.
    If `y` was 2-D, the coefficients for `k`-th data set are in ``p[:,k]``.

residuals, rank, singular_values, rcond : present only if `full` = True
    Residuals of the least-squares fit, the effective rank of the scaled
    Vandermonde coefficient matrix, its singular values, and the specified
    value of `rcond`. For more details, see `linalg.lstsq`.

Which means that if you can do a fit and get the residuals as:

 import numpy as np
 x = np.arange(10)
 y = x**2 -3*x + np.random.random(10)

 p, res, _, _, _ = numpy.polyfit(x, y, deg, full=True)

Then, the p are your fit parameters, and the res will be the residuals, as described above. The _'s are because you don't need to save the last three parameters, so you can just save them in the variable _ which you won't use. This is a convention and is not required.

@Jaime's answer explains what the residual means. Another thing you can do is look at those squared deviations as a function (the sum of which is res). This is particularly helpful to see a trend that didn't fit sufficiently. res can be large because of statistical noise, or possibly systematic poor fitting, for example:

x = np.arange(100)
y = 1000*np.sqrt(x) + x**2 - 10*x + 500*np.random.random(100) - 250

p = np.polyfit(x,y,2) # insufficient degree to include sqrt

yfit = np.polyval(p,x)

plot(x,y, label='data')
plot(x,yfit, label='fit')
plot(x,yfit-y, label='var')

So in the figure, note the bad fit near x = 0:

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