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How do one find the mean, std dev, and gradient from image integral? Given an image such as follows:

summed area table and normal table of numbers

As shown in the figure above, to find the sum of the highlighted parts, sum = C+A-B-D.
So we have sum = 22.

How can I proceed next in order to find:

  • Mean
  • Std dev
  • Gradient
  • 2
    I don't get your question at all. Can you improve it? – ArtemStorozhuk Oct 28 '12 at 17:03
  • You want to find mean, std dev and gradient of some image part (ROI)? – ArtemStorozhuk Oct 28 '12 at 17:16
  • I want to find the mean, std dev and gradient of all the image. – Mzk Oct 28 '12 at 17:20
  • Well, surely you would be able to calculate the mean/std dev/gradient from an integral image, but it would be a lot easier in the original image.. The alogrithm mean/std dev/gradient for integral image is the same like for the original image.. you just need to "back calculate" each value (to get values from original image) -> there is really no reason to use the integral image for this.. just makes it harder and slower If you want a "short form like sum=C+A-B-D" for dev/std dev/gardient ..., I don't think there is one. – KoKuToru Oct 28 '12 at 17:25
  • At first, that's what I thought too @KoKuToru. But, I saw some say it is pretty fast by using integral. So, I might wanna try and see. – Mzk Oct 28 '12 at 17:27
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C+A-B-D gives you the sum of the gray levels in the zone delimited by A,B,C,D, so, to get the mean you just need to dived it by the area of the zone:

mean = (C+A-B-D)/4

To get the dev, you must compute the sum of square area table (using cv::integral you can pass a additional parameters to get the sum of squares). Quoting wikipedia, the standard deviation is equal to the square root of (the average of the squares less the square of the average). So assuming A',B',C',D' the values in your square area table:

dev = sqrt((C'+A'-B'-D')/4 - (mean*mean))

So computing mean and dev using integral image is very fast using integral images, especially if you want to compute those quantities at random locations and on random size of image patches.

Concerning the gradient, it's more complex. Are you sure you do not want to use sobel operator?

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  • You said computing mean and dev using integral image is fast especially at random location or size. Then do you mean it is slower to apply on the entire image? Is Sobel operator fast? – Mzk Oct 29 '12 at 4:28
  • to compute the gradient, sobel is fast with a careful implementation (convolution in the frequency domain). If you have to get mean values at each pixel for a fixed-size neighnbourhood, using a boxFilter can be a good idea, maybe quicker but I'm not sure. it will be a matter of milliseconds in my opinion. But you dont get the dev in this way. Integral image is a good option when speed is required – remi Oct 29 '12 at 8:42
  • @remi Are you sure the formula is right? for at least the mean value? isn't it (C+A-B-D)/4? – maximus Feb 6 '16 at 10:36
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If C+A-B-C is the sum of all gray levels in the zone, then the mean is not

mean = C+A-B-D/4

but

mean = C+A-B-D/K

where K is the number of graylevels in the zone.

Also,

dev = sqrt( C'+A'-B'-D'/4 - (mean*mean) )

is not the stdev, because

dev = sqrt( (1/N)*sum_N ( x_i - u )^2 )

the equation here is equivalent to

dev = sqrt( (1/N)*sum_N ( (x_i)^2 ) - u^2 )

those equations are not equivalent.

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  • Nice one. Thank you @jmch. – Mzk Feb 25 '13 at 6:38
  • Actually, as I show in my answer, remi was on the right track to derive the standard deviation formula, he just stumbled on the averaging factor. – xperroni Jan 21 '14 at 4:53
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What jmch didn't say is, if sqrt( C'+A'-B'-D'/K - (mean*mean) ) is not how you compute the standard deviation from the integral image, then how you do it?

First, let me switch to Python / numpy code, so we get a modicum of notation consistency and expressions are easier to check. Given a sample array X, say:

X = array([random() * 10.0 for i in range(0, 9)])

The uncorrected sample standard deviation of X can be defined as:

std = (sum((X - mean(X)) ** 2) / len(X)) ** 0.5 # 1

Applying the binomial theorem to (X - mean(X)) ** 2 we get:

std = (sum(X ** 2 - X * 2 * mean(X) + mean(X) ** 2) / len(X)) ** 0.5 # 2

Given the identities of the summation operation, we can make:

std = ((sum(X ** 2) - 2 * mean(X) * sum(X) + len(X) * mean(X) ** 2) / len(X)) ** 0.5 # 3

If we make S = sum(X), S2 = sum(X ** 2), M = mean(X) and N = len(X) we get:

std = ((S2 - 2 * M * S + N * M ** 2) / N) ** 0.5 # 4

Now for an image I and two integral images P and P2 calculated from I (where P2 is the integral image for squared pixel values), we know that, given the four edge coordinates A = (i0, j0), B = (i0, j1), C = (i1, j0) and D = (i1, j1), the values of S, S2, M and N can be calculated for the range I[A:D] as:

S = P[A] + P[D] - P[B] - P[C]

S2 = P2[A] + P2[D] - P2[B] - P2[C]

N = (i1 - i0) * (j1 - j0)

M = S / N

Which can then be applied to equation (4) above yielding the standard deviation of the range I[A:D].

Edit: It's not entirely necessary, but given that M = S / N we can apply the following substitutions and simplifications to equation (4):

std = ((S2 - 2 * M * S + N * M ** 2) / N) ** 0.5

std = ((S2 - 2 * (S / N) * S + N * (S / N) ** 2) / N) ** 0.5

std = ((S2 - 2 * ((S ** 2) / N) + (S ** 2 / N)) / N) ** 0.5

std = ((S2 - ((S ** 2) / N)) / N) ** 0.5

std = (S2 / N - (S / N) ** 2) ** 0.5 # 5

Which is quite close to the equation remi gave, actually.

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