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I want to estimate the noise in an image.

Let's assume the model of an Image + White Noise. Now I want to estimate the Noise Variance.

My method is to calculate the Local Variance (3*3 up to 21*21 Blocks) of the image and then find areas where the Local Variance is fairly constant (By calculating the Local Variance of the Local Variance Matrix). I assume those areas are "Flat" hence the Variance is almost "Pure" noise.

Yet I don't get constant results.

Is there a better way?

Thanks.

P.S. I can't assume anything about the Image but the independent noise (Which isn't true for real image yet let's assume it).

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2 Answers 2

The problem of caracterizing 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 hypotesis (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.

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To make things clearer, Let's say I have an Image Matrix - I. In Matlab syntax I would write: NoisyImage = I + 5 * randn(size(I)); Now, I want to estimate the variance of the noise - 25 (Assuming no noise at I). Now, the method should be reliable with much smaller factors (Variance) of the noise and later on to estimate at some degree the noise level of an practical image (With the Independent Noise Model) Thanks. P.S. Could you point me where should I look for it at the article? Do you know any others? –  Drazick Mar 15 '10 at 0:00

You can use the following method to estimate the noise variance (this implementation works for grayscale images only):

def estimate_noise(I):

  H, W = I.shape

  M = [[1, -2, 1],
       [-2, 4, -2],
       [1, -2, 1]]

  sigma = np.sum(np.sum(np.absolute(convolve2d(I, M))))
  sigma = sigma * math.sqrt(0.5 * math.pi) / (6 * (W-2) * (H-2))

  return sigma

Reference: J. Immerkær, “Fast Noise Variance Estimation”, Computer Vision and Image Understanding, Vol. 64, No. 2, pp. 300-302, Sep. 1996 [PDF]

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Thank You. I will give it a try. –  Drazick Aug 22 at 13:10

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