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Hello Assume I have the set of numbers I want a quick to calculate some measure of uniformity. I know the variance is the most obvious answer but i am afraid the complexity of naive algorithm is too high Anyone have any suggestions?

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Do you have any programming language constraint ? – digEmAll Nov 23 '10 at 18:33
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Why do you think the standard (sum squares) algorithm is too complex? – winwaed Nov 23 '10 at 18:35
    
I program in c++ but I really like to see the general algorithm – Yakov Nov 23 '10 at 18:35
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For some pseudo-codes look here --> en.wikipedia.org/wiki/Algorithms_for_calculating_variance – digEmAll Nov 23 '10 at 18:46
up vote 6 down vote accepted

"Intuitive" algorithms for calculating variance usually suffer one or both of the following:

  1. Use two loops (one for calculating the mean, the other for the variance)
  2. Are not numerically stable

A good algorithm, with only one loop and numerically stable is due to D. Knuth (as always).

From Wikipedia:

n = 0
mean = 0
M2 = 0
 def calculate_online_variance(x):
    n = n + 1
    delta = x - mean
    mean = mean + delta/n
    M2 = M2 + delta*(x - mean)  # This expression uses the new value of mean

    variance_n = M2/n
    variance = M2/(n - 1) #note on the first pass with n=1 this will fail (should return Inf)
    return variance

You should invoke calculate_online_variance(x) for each point, and it returns the variance calculated so far.

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you mentioned lack of numerical stability, examples? I'm just not seeing it where it would creep in using mean(x)^2 - mean(x^2). I'm probably missing something obvious. – rcollyer Nov 23 '10 at 19:36
    
@rcollyer I was refering to this: en.wikipedia.org/wiki/… – Dr. belisarius Nov 23 '10 at 19:40
    
well it seems I need to actually read the links posted in the answers ... either way, gracias and +1. – rcollyer Nov 23 '10 at 19:52
    
@rcollyer Better this way ... I can't stand an argument about numerical stability with you :) – Dr. belisarius Nov 23 '10 at 20:05
    
Numerical stability is a problem in this common case: if mean^2 >> variance, you are subtracting two large numbers to get a small one, which kills your floating point precision. – comingstorm Nov 24 '10 at 20:15

I don't see why calculating the variance should be a problem at all. As the variance is just the sum of the squares of the distances from the mean divided by the number of elements, basic pseudocode to do this would be

  1. Calculate mu, the mean of the set
  2. Let s = 0
  3. For each element x in the list, let s = s + (x - mu)*(x-mu)
  4. Calculate s / n

Note that sometimes it's better to divide s by n-1 (specifically, when you're worried about biased estimators). See the Wikipedia article on Bessel's correction for why.

Of course, a lower variance indicates high uniformity.

Note that it might not be a bad idea to further divide your variance by mu^2 to get an absolute measure of uniformity (that is, so that ".5 1 .5 1 .5 1" is considered less tight than "100 101 100 101 100 101", as the relative differences are much bigger in the former than in the latter).

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Math Newb here - can someone comment or explain "further divide your variance by mu^2 to get an absolute measure" In my case I'm very interested in the part about "...considered less tight..." – Steve K Oct 21 '11 at 19:23

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