The problem of characterizing signal from noise is not easy. From your question, a first try would be to characterize second order statistics: natural images are known to have pixel to pixel correlations that are -by definition- not present in white noise.

In Fourier space the correlation corresponds to the energy spectrum. It is known that for natural images, it decreases as 1/f^2 . To quantify noise, I would therefore recommend to compute the correlation coefficient of the spectrum of your image with both hypothesis (flat and 1/f^2), so that you extract the coefficient.

Some functions to start you up:

```
import numpy
def get_grids(N_X, N_Y):
from numpy import mgrid
return mgrid[-1:1:1j*N_X, -1:1:1j*N_Y]
def frequency_radius(fx, fy):
R2 = fx**2 + fy**2
(N_X, N_Y) = fx.shape
R2[N_X/2, N_Y/2]= numpy.inf
return numpy.sqrt(R2)
def enveloppe_color(fx, fy, alpha=1.0):
# 0.0, 0.5, 1.0, 2.0 are resp. white, pink, red, brown noise
# (see http://en.wikipedia.org/wiki/1/f_noise )
# enveloppe
return 1. / frequency_radius(fx, fy)**alpha #
import scipy
image = scipy.lena()
N_X, N_Y = image.shape
fx, fy = get_grids(N_X, N_Y)
pink_spectrum = enveloppe_color(fx, fy)
from scipy.fftpack import fft2
power_spectrum = numpy.abs(fft2(image))**2
```

I recommend this wonderful paper for more details.