# How to efficiently calculate a running standard deviation?

I have an array of lists of numbers, e.g.:

``````[0] (0.01, 0.01, 0.02, 0.04, 0.03)
[1] (0.00, 0.02, 0.02, 0.03, 0.02)
[2] (0.01, 0.02, 0.02, 0.03, 0.02)
...
[n] (0.01, 0.00, 0.01, 0.05, 0.03)
``````

What I would like to do is efficiently calculate the mean and standard deviation at each index of a list, across all array elements.

To do the mean, I have been looping through the array and summing the value at a given index of a list. At the end, I divide each value in my "averages list" by `n`.

To do the standard deviation, I loop through again, now that I have the mean calculated.

I would like to avoid going through the array twice, once for the mean and then once for the SD (after I have a mean).

Is there an efficient method for calculating both values, only going through the array once? Any code in an interpreted language (e.g. Perl or Python) or pseudocode is fine.

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Different language, but same algorithm: stackoverflow.com/questions/895929/… –  dmckee Jul 23 '09 at 23:18
Thanks, I'll check that algorithm out. Sounds like what I need. –  Alex Reynolds Jul 23 '09 at 23:27
Thanks for pointing me to the right answer, dmckee. I'd like to give you the "best answer" checkmark, if you'd like to take a moment to add your answer below (if you'd like the points). –  Alex Reynolds Jul 24 '09 at 4:36
Also, there are several examples at rosettacode.org/wiki/Standard_Deviation –  glenn jackman Jul 24 '09 at 13:21
Wikipedia has a Python implementation en.wikipedia.org/wiki/… –  Hamish Grubijan Jul 27 '11 at 21:34

Perhaps not what you were asking, but ... If you use a numpy array, it will do the work for you, efficiently:

``````from numpy import array

nums = array(((0.01, 0.01, 0.02, 0.04, 0.03),
(0.00, 0.02, 0.02, 0.03, 0.02),
(0.01, 0.02, 0.02, 0.03, 0.02),
(0.01, 0.00, 0.01, 0.05, 0.03)))

print nums.std(axis=1)
# [ 0.0116619   0.00979796  0.00632456  0.01788854]

print nums.mean(axis=1)
# [ 0.022  0.018  0.02   0.02 ]
``````

By the way, there's some interesting discussion in this blog post and comments on one-pass methods for computing means and variances:

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The basic answer is to accumulate the sum of both x (call it 'sum_x1') and x2 (call it 'sum_x2') as you go. The value of the standard deviation is then:

``````stdev = sqrt((sum_x2 / n) - (mean * mean))
``````

where

``````mean = sum_x / n
``````

This is the sample standard deviation; you get the population standard deviation using 'n' instead of 'n - 1' as the divisor.

You may need to worry about the numerical stability of taking the difference between two large numbers if you are dealing with large samples. Go to the external references in other answers (Wikipedia, etc) for more information.

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This is what I was going to suggest. It's the best and fastest way, assuming precision errors are not a problem. –  Ray Hidayat Jul 24 '09 at 0:08
I decided to go with Welford's Algorithm as it performs more reliably with the same computational overhead. –  Alex Reynolds Jul 29 '09 at 23:34
This is a simplified version of the answer and may give non-real results depending on the input (i.e., when sum_x2 < sum_x1 * sum_x1). To ensure a valid real result, go with `sd = sqrt(((n * sum_x2) - (sum_x1 * sum_x1)) / (n * (n - 1))) –  Dan Tao Oct 8 '09 at 15:17
@Dan: am I missing something? Your expression appears to be different from mine - as in, guaranteed to produce a different result - because you've multiplied sum_x2 by n but not made a compensating multiplication of sum_x1 * sum_x1? –  Jonathan Leffler Oct 8 '09 at 16:42
@Dan points out a valid issue - the formula above breaks down for x>1 because you end up taking the sqrt of a negative number. The Knuth approach is: sqrt((sum_x2 / n) - (mean * mean)) where mean = (sum_x / n). –  Greg Jul 27 '10 at 4:12

The answer is to use Welford's algorithm, which is very clearly defined after the "naive methods" in:

It's more numerically stable than either the two-pass or online simple sum of squares collectors suggested in other responses. The stability only really matters when you have lots of values that are close to each other as they lead to what is known as "catastrophic cancellation" in the floating point literature.

You might also want to brush up on the difference between dividing by the number of samples (N) and N-1 in the variance calculation (squared deviation). Dividing by N-1 leads to an unbiased estimate of variance from the sample, whereas dividing by N on average underestimates variance (because it doesn't take into account the variance between the sample mean and the true mean).

I wrote two blog entries on the topic which go into more details, including how to delete previous values online:

You can also take a look at my Java implement; the javadoc, source, and unit tests are all online:

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+1, for taking care about deleting values from Welford's algorithm –  Svisstack Oct 6 '13 at 20:57
Nice answer, +1 for reminding the reader of the difference between a population stddev and a sample stddev. –  Assad Ebrahim Nov 11 '13 at 15:53

Have a look at PDL (pronounced "piddle!").

This is the Perl Data Language which is designed for high precision mathematics and scientific computing.

Here is an example using your figures....

``````use strict;
use warnings;
use PDL;

my \$figs = pdl [
[0.01, 0.01, 0.02, 0.04, 0.03],
[0.00, 0.02, 0.02, 0.03, 0.02],
[0.01, 0.02, 0.02, 0.03, 0.02],
[0.01, 0.00, 0.01, 0.05, 0.03],
];

my ( \$mean, \$prms, \$median, \$min, \$max, \$adev, \$rms ) = statsover( \$figs );

say "Mean scores:     ", \$mean;
say "Std dev? (prms): ", \$prms;
say "Std dev? (rms):  ", \$rms;
``````

Which produces:

``````Mean scores:     [0.022 0.018 0.02 0.02]
Std dev? (adev): [0.0104 0.0072 0.004 0.016]
Std dev? (prms): [0.013038405 0.010954451 0.0070710678 0.02]
Std dev? (rms):  [0.011661904 0.009797959 0.0063245553 0.017888544]
``````

Have a look at PDL::Primitive for more information on the statsover function. This seems to suggest that ADEV is the "standard deviation".

However it maybe PRMS (which Sinan's Statistics::Descriptive example show) or RMS (which ars's NumPy example shows). I guess one of these three must be right ;-)

For more PDL information have a look at:

/I3az/

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Statistics::Descriptive is a very decent Perl module for these types of calculations:

``````#!/usr/bin/perl

use strict; use warnings;

use Statistics::Descriptive qw( :all );

my \$data = [
[ 0.01, 0.01, 0.02, 0.04, 0.03 ],
[ 0.00, 0.02, 0.02, 0.03, 0.02 ],
[ 0.01, 0.02, 0.02, 0.03, 0.02 ],
[ 0.01, 0.00, 0.01, 0.05, 0.03 ],
];

my \$stat = Statistics::Descriptive::Full->new;
# You also have the option of using sparse data structures

for my \$ref ( @\$data ) {
printf "Running mean: %f\n", \$stat->mean;
printf "Running stdev: %f\n", \$stat->standard_deviation;
}
__END__
``````

Output:

``````C:\Temp> g
Running mean: 0.022000
Running stdev: 0.013038
Running mean: 0.020000
Running stdev: 0.011547
Running mean: 0.020000
Running stdev: 0.010000
Running mean: 0.020000
Running stdev: 0.012566
``````
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How big is your array? Unless it is zillions of elements long, don't worry about looping through it twice. The code is simple and easily tested.

My preference would be to use the numpy array maths extension to convert your array of arrays into a numpy 2D array and get the standard deviation directly:

``````>>> x = [ [ 1, 2, 4, 3, 4, 5 ], [ 3, 4, 5, 6, 7, 8 ] ] * 10
>>> import numpy
>>> a = numpy.array(x)
>>> a.std(axis=0)
array([ 1. ,  1. ,  0.5,  1.5,  1.5,  1.5])
>>> a.mean(axis=0)
array([ 2. ,  3. ,  4.5,  4.5,  5.5,  6.5])
``````

If that's not an option and you need a pure Python solution, keep reading...

``````x = [
[ 1, 2, 4, 3, 4, 5 ],
[ 3, 4, 5, 6, 7, 8 ],
....
]
``````

Then the standard deviation is:

``````d = len(x[0])
n = len(x)
sum_x = [ sum(v[i] for v in x) for i in range(d) ]
sum_x2 = [ sum(v[i]**2 for v in x) for i in range(d) ]
std_dev = [ sqrt((sx2 - sx**2)/N)  for sx, sx2 in zip(sum_x, sum_x2) ]
``````

If you are determined to loop through your array only once, the running sums can be combined.

``````sum_x  = [ 0 ] * d
sum_x2 = [ 0 ] * d
for v in x:
for i, t in enumerate(v):
sum_x[i] += t
sum_x2[i] += t**2
``````

This isn't nearly as elegant as the list comprehension solution above.

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I do actually have to deal with zillions of numbers, which is what motivates my need for an efficient solution. Thanks! –  Alex Reynolds Jul 24 '09 at 4:33

You could look at the Wikipedia article on Standard Deviation, in particular the section about Rapid calculation methods.

There's also an article I found that uses Python, you should be able to use the code in it without much change: Subliminal Messages - Running Standard Deviations.

-

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+1 @Lasse V. Karlsen's link to Wikipedia's good, but this is the right algorithm I've used... –  kenny Jul 24 '09 at 17:44

Here is a literal pure Python translation of the Welford's algorithm implementation from http://www.johndcook.com/standard_deviation.html:

https://github.com/liyanage/python-modules/blob/master/running_stats.py

``````class RunningStats:

def __init__(self):
self.n = 0
self.old_m = 0
self.new_m = 0
self.old_s = 0
self.new_s = 0

def clear(self):
self.n = 0

def push(self, x):
self.n += 1

if self.n == 1:
self.old_m = self.new_m = x
self.old_s = 0
else:
self.new_m = self.old_m + (x - self.old_m) / self.n
self.new_s = self.old_s + (x - self.old_m) * (x - self.new_m)

self.old_m = self.new_m
self.old_s = self.new_s

def mean(self):
return self.new_m if self.n else 0.0

def variance(self):
return self.new_s / (self.n - 1) if self.n > 1 else 0.0

def standard_deviation(self):
return math.sqrt(self.variance())
``````

Usage:

``````rs = RunningStats()
rs.push(17.0);
rs.push(19.0);
rs.push(24.0);

mean = rs.mean();
variance = rs.variance();
stdev = rs.standard_deviation();
``````
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The Python runstats Module is for just this sort of thing. Install runstats from PyPI:

``````pip install runstats
``````

Runstats summaries can produce the mean, variance, standard deviation, skewness, and kurtosis in a single pass of data. We can use this to create your "running" version.

``````from runstats import Statistics

stats = [Statistics() for num in range(len(data[0]))]

for row in data:

for index, val in enumerate(row):
stats[index].push(val)

for index, stat in enumerate(stats):
print 'Index', index, 'mean:', stat.mean()
print 'Index', index, 'standard deviation:', stat.stddev()
``````

Statistics summaries are based on the Knuth and Welford method for computing standard deviation in one pass as described in the Art of Computer Programming, Vol 2, p. 232, 3rd edition. The benefit of this is numerically stable and accurate results.

Disclaimer: I am the author the Python runstats module.

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``````n=int(raw_input("Enter no. of terms:"))

L=[]

for i in range (1,n+1):

x=float(raw_input("Enter term:"))

L.append(x)

sum=0

for i in range(n):

sum=sum+L[i]

avg=sum/n

sumdev=0

for j in range(n):

sumdev=sumdev+(L[j]-avg)**2

dev=(sumdev/n)**0.5

print "Standard deviation is", dev
``````
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Here's a "one-liner", spread over multiple lines, in functional programming style:

``````def variance(data, opt=0):
return (lambda (m2, i, _): m2 / (opt + i - 1))(
reduce(
lambda (m2, i, avg), x:
(
m2 + (x - avg) ** 2 * i / (i + 1),
i + 1,
avg + (x - avg) / (i + 1)
),
data,
(0, 0, 0)))
``````
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