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Using Python, assume I'm running through a known quantity of items I, and have the ability to time how long it takes to process each one t, as well as a running total of time spent processing T and the number of items processed so far c. I'm currently calculating the average on the fly A = T / c but this can be skewed by say a single item taking an extraordinarily long time to process (a few seconds compared to a few milliseconds).

I would like to show a running Standard Deviation. How can I do this without keeping a record of each t?

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9  
See here: johndcook.com/standard_deviation.html –  Lasse V. Karlsen Apr 4 '11 at 20:05
    
You may also want to have a look at numpy –  Daenyth Apr 4 '11 at 20:15

3 Answers 3

up vote 11 down vote accepted

I use Welford's Method, which gives more accurate results. This link points to John D. Cook's overview.

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As outlined in the Wikipedia article on the standard deviation, it is enough to keep track of the following three sums:

s0 = sum(1 for x in samples)
s1 = sum(x for x in samples)
s2 = sum(x*x for x in samples)

These sums are easily updated as new values arrive. The standard deviation can be calculated as

std_dev = math.sqrt((s0 * s2 - s1 * s1)/(s0 * (s0 - 1)))
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1  
Can't s0 be calculated more simply as length(samples), and s1 as sum(samples)? –  Benjamin Apr 4 '11 at 20:20
2  
@Benjamin: Of course. But the OP does not want to keep track of samples. I chose this syntax to make clear what will be added in each iteration (and for the nice symmetric look of it). –  Sven Marnach Apr 4 '11 at 20:27
3  
@Benjamin: Sven is showing programmatically that the standard deviation is defined as a function of the zeroth, first, and second moments of your data. –  Seth Johnson Apr 4 '11 at 20:59
    
For one sample, (s0 * (s0 - 1)) == 0, so there's division by zero. –  XTL May 11 '12 at 6:28
    
Of course this algorithm, while simple, is much more susceptible to numeric overflow than Welford's. –  Tom Morris Dec 4 '13 at 1:28

Based on Welford's algorithm:

import numpy as np

def online_variance(datum,n=0.0,mean=0.0,M2=0.0):
    n += 1
    delta = datum - mean
    mean = mean + delta/n
    M2 = M2 + delta*(datum - mean)  
    variance = M2/n    # use this for population variance
    # variance = M2/(n - 1)  # use this for sample variance
    return variance,n,mean,M2

Here we update the variance with each new piece of data:

N=100
data=np.random.random(N)    
n,mean,M2=0,0,0
for d in data:
    variance,n,mean,M2 = online_variance(d,n,mean,M2)
online_std=np.sqrt(variance)
print(online_std)

Here we check our result against the standard deviation computed by numpy:

assert np.allclose(online_std,data.std())
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