If you fix you polynomial degree you can simply use the **leastsq** function from **scipy.optimize**

let say that you generate a simple circle. I will divide it into its x and y component

```
data = [ [cos(t)+0.1*randn(),sin(t)+0.1*randn()] for t in rand(100)*2*np.pi ]
contour = array(data)
x,y = contour.T
```

the write a simple function that evaluate the difference of each point from the 0 given the coefficients of the polynomial. We are fitting the curve as an circle centered on the origin.

```
def f(coef):
a = coef
return a*x**2+a*y**2-1
```

We can simply use the leastsq function to find the best coefficients.

```
from scipy.optimize import leastsq
initial_guess = [0.1,0.1]
coef = leastsq(f,initial_guess)[0]
# coef = array([ 0.92811554])
```

I take only the first element of the returned tuple because the leastsq return a lot of other information that we don't need.

if you need to fit a more complicated polynomial, for example an ellipse with a generic center, you can simply use a more complicated function:

```
def f(coef):
a,b,cx,cy = coef
return a*(x-cx)**2+b*(y-cy)**2-1
initial_guess = [0.1,0.1,0.0,0.0]
coef = leastsq(f,initial_guess)[0]
# coef = array([ 0.92624664, 0.93672577, 0.00531 , 0.01269507])
```

### EDIT:

If for some reason you need an estimation of the uncertainty of the fitted parameters, you can obtain this information from the covariance matrix of the results:

```
res = leastsq(f,initial_guess,full_output=True)
coef = res[0]
cov = res[1]
#cov = array([[ 0.02537329, -0.00970796, -0.00065069, 0.00045027],
# [-0.00970796, 0.03157025, 0.0006394 , 0.00207787],
# [-0.00065069, 0.0006394 , 0.00535228, -0.00053483],
# [ 0.00045027, 0.00207787, -0.00053483, 0.00618327]])
uncert = sqrt(diag(cov))
# uncert = array([ 0.15928997, 0.17768018, 0.07315927, 0.07863377])
```

The diagonal of the covariance matrix are the variance of each parameters, so the uncertainty is it's square root

take a look to http://www.scipy.org/Cookbook/FittingData for more information on the fitting procedure.

The reason I used the leastsq and not the curve_fit function,that is easier to use, is that the curve_fit requires an explicit function in the form `y = f(x)`

, and not every implicit polynomial can be transormed into that form (or better, almost no interesting implicit polynomial at all)