Here is an example that uses scipy.optimize to fit a non-linear functions like a Gaussian, even when the data is in a histogram that isn't well ranged, so that a simple mean estimate would fail. An offset constant also would cause simple normal statistics to fail ( just remove p[3] and c[3] for plain gaussian data).

```
from pylab import *
from numpy import loadtxt
from scipy.optimize import leastsq
fitfunc = lambda p, x: p[0]*exp(-0.5*((x-p[1])/p[2])**2)+p[3]
errfunc = lambda p, x, y: (y - fitfunc(p, x))
filename = "gaussdata.csv"
data = loadtxt(filename,skiprows=1,delimiter=',')
xdata = data[:,0]
ydata = data[:,1]
init = [1.0, 0.5, 0.5, 0.5]
out = leastsq( errfunc, init, args=(xdata, ydata))
c = out[0]
print "A exp[-0.5((x-mu)/sigma)^2] + k "
print "Parent Coefficients:"
print "1.000, 0.200, 0.300, 0.625"
print "Fit Coefficients:"
print c[0],c[1],abs(c[2]),c[3]
plot(xdata, fitfunc(c, xdata))
plot(xdata, ydata)
title(r'$A = %.3f\ \mu = %.3f\ \sigma = %.3f\ k = %.3f $' %(c[0],c[1],abs(c[2]),c[3]));
show()
```

Output:

```
A exp[-0.5((x-mu)/sigma)^2] + k
Parent Coefficients:
1.000, 0.200, 0.300, 0.625
Fit Coefficients:
0.961231625289 0.197254597618 0.293989275502 0.65370344131
```

`sum( value*frequency for value,frequency in h )/sum( frequency for _,frequency in h )`

. The standard deviation is equally simple -- but a bit long for a comment. Can you pleaseupdatethe question to explain in more detail what you're trying to do? – S.Lott Oct 18 '11 at 12:08