# SciPy LeastSq Goodness of Fit Estimator

I have a data surface that I'm fitting using SciPy's `leastsq` function.

I would like to have some estimate of the quality of the fit after `leastsq` returns. I'd expected that this would be included as a return from the function, but, if so, it doesn't seem to be clearly documented.

Is there such a return or, barring that, some function I can pass my data and the returned parameter values and fit function to that will give me an estimate of fit quality (R^2 or some such)?

Thanks!

-

If you call `leastsq` like this:

``````import scipy.optimize
p,cov,infodict,mesg,ier = optimize.leastsq(
residuals,a_guess,args=(x,y),full_output=True,warning=True)
``````

where

``````def residuals(a,x,y):
return y-f(x,a)
``````

then, using the definition of `R^2` given here,

``````ss_err=(infodict['fvec']**2).sum()
ss_tot=((y-y.mean())**2).sum()
rsquared=1-(ss_err/ss_tot)
``````

What is `infodict['fvec']` you ask? It's the array of residuals:

``````In [48]: optimize.leastsq?
...
infodict -- a dictionary of optional outputs with the keys:
'fvec' : the function evaluated at the output
``````

For example:

``````import scipy.optimize as optimize
import numpy as np
import collections
import matplotlib.pyplot as plt

x = np.array([821,576,473,377,326])
y = np.array([255,235,208,166,157])

def sigmoid(p,x):
x0,y0,c,k=p
y = c / (1 + np.exp(-k*(x-x0))) + y0
return y

def residuals(p,x,y):
return y - sigmoid(p,x)

Param=collections.namedtuple('Param','x0 y0 c k')
p_guess=Param(x0=600,y0=200,c=100,k=0.01)
p,cov,infodict,mesg,ier = optimize.leastsq(
residuals,p_guess,args=(x,y),full_output=True,warning=True)
p=Param(*p)
xp = np.linspace(100, 1600, 1500)
print('''\
x0 = {p.x0}
y0 = {p.y0}
c = {p.c}
k = {p.k}
'''.format(p=p))
pxp=sigmoid(p,xp)

# You could compute the residuals this way:
resid=residuals(p,x,y)
print(resid)
# [ 0.76205302 -2.010142    2.60265297 -3.02849144  1.6739274 ]

# But you don't have to compute `resid` -- `infodict['fvec']` already
# contains the info.
print(infodict['fvec'])
# [ 0.76205302 -2.010142    2.60265297 -3.02849144  1.6739274 ]

ss_err=(infodict['fvec']**2).sum()
ss_tot=((y-y.mean())**2).sum()
rsquared=1-(ss_err/ss_tot)
print(rsquared)
# 0.996768131959

plt.plot(x, y, '.', xp, pxp, '-')
plt.xlim(100,1000)
plt.ylim(130,270)
plt.xlabel('x')
plt.ylabel('y',rotation='horizontal')
plt.grid(True)
plt.show()
``````

-
Is the above definition of rsquared correct? For each bin, the value of residual^2 should be divided to variance^2 and then at the end, sum up all the results. –  user1016260 Oct 27 '11 at 10:09
@ user1016260 There aren't any errors in the above example, but yes, it should be taken into account in that way. My question is about doing this for different models with different numbers of parameters. Basically with this R^2 method there is no way that the number of parameters are being taken into account. With something like a reduced chi-square, it does. Wouldn't that be best to use for models? This may not be appropriate to discuss here. –  astromax Jun 24 '13 at 17:55
@astromax You might want to consider something like the . Akaike Information Criterion (AIC) –  DrSAR Nov 6 '13 at 6:44
@iamgin: `leastsq` uses the Levenberg–Marquardt algorithm. Per the link, "In cases with only one minimum, an uninformed standard guess ... will work fine; in cases with multiple minima, the algorithm converges only if the initial guess is already somewhat close to the final solution." –  unutbu Oct 22 '14 at 17:24
@iamgin: The sigmoid function used above has the form `y = c / (1 + np.exp(-k*(x-x0))) + y0`. When `x` is huge the `exp(...)` is essentially zero so `y` tends toward `c + y0`. When `x` is huge and negative, `exp(...)` is huge, `c / (huge)` tends to 0, so `y` tends toward `y0`. So `y0` is the lower limit -- in the picture around 140, and `c + y0` is the upper limit -- around 250. So `c` is the span or difference 250 - 140 ~ 110. –  unutbu Oct 23 '14 at 12:30