# Moving average or running mean

Is there a scipy function or numpy function or module for python that calculates the running mean of a 1D array given a specific window?

/M

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if there is no specific function, it is easy to do it yourself.

If you do not plan to move your window one step furtherm, it is super simple, just add up all values in side the window, and divide by the window size.

If you plan to move your averagring window one step further, you should consider using the recursive definition of the mean value. (search wiki for recursive Mean value)

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Ok, thanks - I'll do some more searching. –  Shejo284 Dec 5 '12 at 17:30

You can calculate a running mean with:

import numpy as np

def runningMean(x, N):
y = np.zeros((len(x),))
for ctr in range(len(x)):
y[ctr] = np.sum(x[ctr:(ctr+N)])
return y/N

But it's slow.

Fortunately, numpy includes a convolve function which we can use to speed things up. The running mean is equivalent to convolving x with a vector that is N long, with all members equal to 1/N. The numpy implementation of convolve includes the starting transient, so you have to remove the first N-1 points:

def runningMeanFast(x, N):
return np.convolve(x, np.ones((N,))/N)[(N-1):]

On my machine, the fast version is 20-30 times faster, depending on the length of the input vector and size of the averaging window.

Note that convolve does include a 'same' mode which seems like it should address the starting transient issue, but it splits it between the beginning and end.

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Note that removing the first N-1 points still leaves a boundary effect in the last points. An easier way to solve the issue is to use mode='valid' in convolve which doesn't require any post-processing. –  lapis Mar 24 at 10:08
@Psycho - mode='valid' removes the transient from both ends, right? If len(x)=10 and N=4, for a running mean I would want 10 results but valid returns 7. –  mtrw Mar 24 at 13:09
It removes the transient from the end, and the beginning doesn't have one. Well, I guess it's a matter of priorities, I don't need the same number of results on the expense of getting a slope towards zero that isn't there in the data. BTW, here is a command to show the difference between the modes: modes = ('full', 'same', 'valid'); [plot(convolve(ones((200,)), ones((50,))/50, mode=m)) for m in modes]; axis([-10, 251, -.1, 1.1]); legend(modes, loc='lower center') (with pyplot and numpy imported). –  lapis Mar 24 at 13:56
@Psycho - very nice. You should make this an answer, I would certainly give it a vote. –  mtrw Mar 24 at 14:54
Done! Thank you :) –  lapis Mar 24 at 22:01

For a ready-to-use solution, see http://www.scipy.org/Cookbook/SignalSmooth. It provides running average with the flat window type. Note that this is a bit more sophisticated than the simple do-it-yourself convolve-method, since it tries to handle the problems at the beginning and the end of the data by reflecting it (which may or may not work in your case...).

a = np.random.random(100)
plt.plot(a)
b = smooth(a, window='flat')
plt.plot(b)
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You can use np.convolve for that:

np.convolve(x, np.ones((N,))/N, mode='valid')

The mode argument specifies how to handle the edges. I chose the valid mode here because I think that's how most people expect running mean to work, but you may have other priorities. Here is a plot that illustrates the difference between the modes:

modes = ('full', 'same', 'valid'); [plot(convolve(ones((200,)), ones((50,))/50, mode=m)) for m in modes]; axis([-10, 251, -.1, 1.1]); legend(modes, loc='lower center')

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If you do choose to roll your own, rather than use an existing library, please be conscious of floating point error and try to minimize its effects:

class SumAccumulator:
def __init__(self):
self.values = [0]
self.count = 0

self.values.append( val )
self.count = self.count + 1
i = self.count
while i & 0x01:
i = i >> 1
v0 = self.values.pop()
v1 = self.values.pop()
self.values.append( v0 + v1 )

def get_total(self):
return sum( self.values )

def get_size( self ):
return self.count

If all your values are roughly the same order of magnitude, then this will help to preserve precision by always adding values of roughly similar magnitudes.

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