I would probably do it like this:

```
from __future__ import division
from __future__ import print_function
from scipy.optimize import curve_fit
import numpy as np
def parabola(t, *p):
a, b, c, d = p
y = np.zeros(t.shape)
indices = np.abs(t) < b
y[indices] = (a*(1-(((t[indices]-c)/b)**2)) + d)
return y
p0 = [1, 2, 3, 4]
x = np.linspace(-10, 10, 20)
y = parabola(x, *p0)
coeff, cov = curve_fit(parabola, x, y, p0)
print(coeff)
```

**Update**

With the provided data (see link in the comment), things start to become somewhat clearer:

this is tricky data with respect to its behaviour. A lot of the "zero" data will not help fitting the function, since the weight of the actual function becomes less and less with more zero data. Often, the best is to cut down somewhat and concentrate on the relevant data (once you have that, you can try and fit all the data with your best-found parameters).

The criterion is incorrect: it is centred around zero, not around the peak of the data (`c`

).

Having the parameters `b`

and `c`

in both the function and the criterion for the indices makes things harder: the function behaves less and less linearly. I found the initial best parameters by using a fixed criterion, which is the commented-out line below.

Provide good starting parameters. `[1, 2, 3, 4]`

are just very generic, which in case of non-linear least squares can make it hard to fit.

So, taking all of the above into account, I came up with this:

```
from __future__ import division
from __future__ import print_function
from scipy.optimize import curve_fit
import numpy as np
from matplotlib import pyplot as plt
def parabola(t, *p):
a, b, c, d = p
y = np.zeros(t.shape)
# The indices criterion was first fixed to values that appeared reasonably;
# otherwise the fit would completely fail.
# Once decent parameters were found, I replaced 28 and 0.3 with the center `c`
# and the width `b`.
#indices = np.abs(t-28) < 0.3
indices = np.abs(t-c) < b
y[indices] = (a*(1-(((t[indices]-c)/b)**2)) + d)
return y
out = np.loadtxt('data.dat')
# Limit the data to only the interesting part of the data
# Once we have the fit correct, we can always attempt a fit to all data with
# good starting parameters
xdata = out[...,0][450:550]
ydata = out[...,1][450:550]
# These starting parameters are either from trial fitting, or from theory
p0 = [2, 0.2, 28, 6.6]
coeff, cov = curve_fit(parabola, xdata, ydata, p0)
plt.plot(xdata, ydata, '.')
xfit = np.linspace(min(xdata), max(xdata))
yfit = parabola(xfit, *coeff)
plt.plot(xfit, yfit, '-')
plt.show()
```

Note that the resulting `b`

parameter still indicates a bad fit. I'm guessing that the combination of these data and this function are just tricky. One option would be to iterate over various reasonable values of `b`

(e.g., between 0.2 and 0.3) and find the best reduced chi-squared.

But, I also note that the data do not appear as a parabola. Initially, when I saw the full data picture, I thought "Gaussian", but that's not it either. It looks almost like a boxcar function.
If you have a good theoretical model that says it's a parabola, then either the data is off or the model may be incorrect. If you're just looking for a descriptive function, try a few other functions as well.

`import numpy as np`

and replace`abs`

with`np.abs`

. – Jaime Apr 25 '13 at 7:01