# How to calculate moving average using NumPy?

There seems to be no function that simply calculates the moving average on numpy/scipy, leading to convoluted solutions.

My question is two-fold:

• What's the easiest way to (correctly) implement a moving average with numpy?
• Since this seems non-trivial and error prone, is there a good reason not to have the batteries included in this case?
• The convolution solution doesn't seem that convoluted to me! – wim Jan 14 '13 at 5:29
• Isn't a moving average just a low-pass filter (i.e. 'blur')? Pretty sure that's exactly the sort of thing convolution is meant for... – user541686 Jan 14 '13 at 7:20
• @mmgp I guess I was hoping to be wrong, or that there was a good, obvious reason. – goncalopp Jan 14 '13 at 19:55
• @wim It was half-meant as a pun. But the mere fact that the question exists means that it's not straightforward to create a moving average from numpy.convolute. – goncalopp Jan 14 '13 at 19:56
• Possible duplicate of Moving average or running mean – Andreas K. Nov 1 '18 at 7:38

If you just want a straightforward non-weighted moving average, you can easily implement it with `np.cumsum`, which may be is faster than FFT based methods:

EDIT Corrected an off-by-one wrong indexing spotted by Bean in the code. EDIT

``````def moving_average(a, n=3) :
ret = np.cumsum(a, dtype=float)
ret[n:] = ret[n:] - ret[:-n]
return ret[n - 1:] / n

>>> a = np.arange(20)
>>> moving_average(a)
array([  1.,   2.,   3.,   4.,   5.,   6.,   7.,   8.,   9.,  10.,  11.,
12.,  13.,  14.,  15.,  16.,  17.,  18.])
>>> moving_average(a, n=4)
array([  1.5,   2.5,   3.5,   4.5,   5.5,   6.5,   7.5,   8.5,   9.5,
10.5,  11.5,  12.5,  13.5,  14.5,  15.5,  16.5,  17.5])
``````

So I guess the answer is: it is really easy to implement, and maybe numpy is already a little bloated with specialized functionality.

• This code is incorrect. e.g. moving_average([1,2,5,10], n=2) gives [ 1. , 3.5, 8.5]. Even the answerer's test case for a moving average of values from 0 to 19 is incorrect, claiming that the average of 0, 1, and 2 is 0.5. How did it get 6 upvotes? – JeremyKun Aug 22 '13 at 18:18
• I have found the problem. `ret[n:] -= ret[:-n]` is NOT THE SAME as `ret[n:] = ret[n:] - ret[:-n]`. I have fixed the code in this answer. Edit: Nope somebody else just beat me to it. – Timmmm Dec 4 '13 at 14:29
• @Timmmm I did, that was indeed the issue. The general principle behind this answer is widely used in image processing (summed area tables they call it), so the issue had to be in the implementation. A good example of being bit by premature optimization, since I kind of recall doing the operation in-place "because it will be more efficient." On the bright side, it probably did produce the wrong answer faster... – Jaime Dec 4 '13 at 14:39
• @askewchan In Timmmm's example, when doing `ret[2:] -= ret[:-2]`, `ret` is `[1, 2, 3, 4, 5, 6]`. When it processes the last data point it is basically doing `ret[5] -= ret[3]`. We would like to get `ret[5] = 6 - 4`, but we get `ret[5] = 6 - 2` instead, because `ret[3]` has already been modified by the in-place operation to be `ret[3] -= ret[1]`, i.e. `2`. If you don't do the operation in-place it creates a temporary array and then copies it into `ret`, avoiding this problem. – Jaime Dec 4 '13 at 16:31
• Hmmm, it seems this "easy to implement" function is actually pretty easy to get wrong and has fostered a good discussion on memory efficiency. I'm happy to have bloat if it means knowing that something's been done right. – Richard Sep 20 '14 at 19:23

NumPy's lack of a particular domain-specific function is perhaps due to the Core Team's discipline and fidelity to NumPy's prime directive: provide an N-dimensional array type, as well as functions for creating, and indexing those arrays. Like many foundational objectives, this one is not small, and NumPy does it brilliantly.

The (much) larger SciPy contains a much larger collection of domain-specific libraries (called subpackages by SciPy devs)--for instance, numerical optimization (optimize), signal processsing (signal), and integral calculus (integrate).

My guess is that the function you are after is in at least one of the SciPy subpackages (scipy.signal perhaps); however, i would look first in the collection of SciPy scikits, identify the relevant scikit(s) and look for the function of interest there.

Scikits are independently developed packages based on NumPy/SciPy and directed to a particular technical discipline (e.g., scikits-image, scikits-learn, etc.) Several of these were (in particular, the awesome OpenOpt for numerical optimization) were highly regarded, mature projects long before choosing to reside under the relatively new scikits rubric. The Scikits homepage liked to above lists about 30 such scikits, though at least several of those are no longer under active development.

Following this advice would lead you to scikits-timeseries; however, that package is no longer under active development; In effect, Pandas has become, AFAIK, the de facto NumPy-based time series library.

Pandas has several functions that can be used to calculate a moving average; the simplest of these is probably rolling_mean, which you use like so:

``````>>> # the recommended syntax to import pandas
>>> import pandas as PD
>>> import numpy as NP

>>> # prepare some fake data:
>>> # the date-time indices:
>>> t = PD.date_range('1/1/2010', '12/31/2012', freq='D')

>>> # the data:
>>> x = NP.arange(0, t.shape[0])

>>> # combine the data & index into a Pandas 'Series' object
>>> D = PD.Series(x, t)
``````

Now, just call the function rolling_mean passing in the Series object and a window size, which in my example below is 10 days.

``````>>> d_mva = PD.rolling_mean(D, 10)

>>> # d_mva is the same size as the original Series
>>> d_mva.shape
(1096,)

>>> # though obviously the first w values are NaN where w is the window size
>>> d_mva[:3]
2010-01-01         NaN
2010-01-02         NaN
2010-01-03         NaN
``````

verify that it worked--e.g., compared values 10 - 15 in the original series versus the new Series smoothed with rolling mean

``````>>> D[10:15]
2010-01-11    2.041076
2010-01-12    2.041076
2010-01-13    2.720585
2010-01-14    2.720585
2010-01-15    3.656987
Freq: D

>>> d_mva[10:20]
2010-01-11    3.131125
2010-01-12    3.035232
2010-01-13    2.923144
2010-01-14    2.811055
2010-01-15    2.785824
Freq: D
``````

The function rolling_mean, along with about a dozen or so other function are informally grouped in the Pandas documentation under the rubric moving window functions; a second, related group of functions in Pandas is referred to as exponentially-weighted functions (e.g., ewma, which calculates exponentially moving weighted average). The fact that this second group is not included in the first (moving window functions) is perhaps because the exponentially-weighted transforms don't rely on a fixed-length window

• Pandas does have a strong line up of moving window functions. But it seems to me like a little too much overhead for a simple moving average. – Jaime Jan 14 '13 at 7:31
• well i doubt that calculating a moving average is an isolated requirement for the OP or for just about anyone else. If you need to calculate a moving average then you almost certainly have a time series, which means you need a data structure that allows you to conform a date-time index to your data and that's the 'overhead' you refer to. – doug Jan 14 '13 at 7:45
• Firstly, thank you for taking the time to write this extremely informative answer. Indeed, I can't see a use for a moving average that doesn't involve a time series. But that doesn't mean that one needs to conform it to a datetime, or even to a particular sampling interval (it may be unknown) – goncalopp Jan 14 '13 at 20:02
• Just wanted to add that the moving average function has been extracted into the Bottleneck library if pandas seems too heavyweight as a dependency. – robochat Jul 16 '14 at 12:38

A simple way to achieve this is by using `np.convolve`. The idea behind this is to leverage the way the discrete convolution is computed and use it to return a rolling mean. This can be done by convolving with a sequence of `np.ones` of a length equal to the sliding window length we want.

In order to do so we could define the following function:

``````def moving_average(x, w):
return np.convolve(x, np.ones(w), 'valid') / w
``````

This function will be taking the convolution of the sequence `x` and a sequence of ones of length `w`. Note that the chosen `mode` is `valid` so that the convolution product is only given for points where the sequences overlap completely.

Use case

Some examples:

``````x = np.array([5,3,8,10,2,1,5,1,0,2])
``````

For a moving average with a window of length `2` we would have:

``````moving_average(x, 2)
# array([4. , 5.5, 9. , 6. , 1.5, 3. , 3. , 0.5, 1. ])
``````

And for a window of length `4`:

``````moving_average(x, 4)
# array([6.5 , 5.75, 5.25, 4.5 , 2.25, 1.75, 2.  ])
``````

Details

Lets have a more in depth look at the way the discrete convolution is being computed. The following function aims to replicate the way `np.convolve` is computing the output values:

``````def mov_avg(x, w):
for m in range(len(x)-(w-1)):
yield sum(np.ones(w) * x[m:m+w]) / w
``````

Which, for the same example above would also yield:

``````list(mov_avg(x, 2))
# [4.0, 5.5, 9.0, 6.0, 1.5, 3.0, 3.0, 0.5, 1.0]
``````

So what is being done at each step is to take the inner product between the array of ones and the current window. In this case the multiplication by `np.ones(w)` is superfluous given that we are directly taking the `sum` of the sequence.

Bellow is an example of how the first outputs are computed so that it is a little clearer. Lets suppose we want a window of `w=4`:

``````[1,1,1,1]
[5,3,8,10,2,1,5,1,0,2]
= (1*5 + 1*3 + 1*8 + 1*10) / w = 6.5
``````

And the following output would be computed as:

``````  [1,1,1,1]
[5,3,8,10,2,1,5,1,0,2]
= (1*3 + 1*8 + 1*10 + 1*2) / w = 5.75
``````

And so on, returning a moving average of the sequence once all overlaps have been performed.

• This is a nice idea! It is faster than @Jaime's answer for small n, but becomes slower for larger n. – Felipe Gerard May 7 '19 at 14:06
• Thanks @FelipeGerard! Yes as pointed out in the comments, while this approach may perhaps not be as efficient as some other numpy solutions, imo it is nice to have as an alternative for future visitors given its simplicity and conciseness – yatu May 7 '19 at 14:31

This answer using Pandas is adapted from above, as `rolling_mean` is not part of Pandas anymore

``````# the recommended syntax to import pandas
import pandas as pd
import numpy as np

# prepare some fake data:
# the date-time indices:
t = pd.date_range('1/1/2010', '12/31/2012', freq='D')

# the data:
x = np.arange(0, t.shape[0])

# combine the data & index into a Pandas 'Series' object
D = pd.Series(x, t)
``````

Now, just call the function `rolling` on the dataframe with a window size, which in my example below is 10 days.

``````d_mva10 = D.rolling(10).mean()

# d_mva is the same size as the original Series
# though obviously the first w values are NaN where w is the window size
d_mva10[:11]

2010-01-01    NaN
2010-01-02    NaN
2010-01-03    NaN
2010-01-04    NaN
2010-01-05    NaN
2010-01-06    NaN
2010-01-07    NaN
2010-01-08    NaN
2010-01-09    NaN
2010-01-10    4.5
2010-01-11    5.5
Freq: D, dtype: float64
``````

Here are a variety of ways to do this, along with some benchmarks. The best methods are versions using optimized code from other libraries. The `bottleneck.move_mean` method is probably best all around. The `scipy.convolve` approach is also very fast, extensible, and syntactically and conceptually simple, but doesn't scale well for very large window values. The `numpy.cumsum` method is good if you need a pure `numpy` approach.

Note: Some of these (e.g. `bottleneck.move_mean`) are not centered, and will shift your data.

``````import numpy as np
import scipy as sci
import scipy.signal as sig
import pandas as pd
import bottleneck as bn
import time as time

def rollavg_direct(a,n):
'Direct "for" loop'
assert n%2==1
b = a*0.0
for i in range(len(a)) :
b[i]=a[max(i-n//2,0):min(i+n//2+1,len(a))].mean()
return b

def rollavg_comprehension(a,n):
'List comprehension'
assert n%2==1
r,N = int(n/2),len(a)
return np.array([a[max(i-r,0):min(i+r+1,N)].mean() for i in range(N)])

def rollavg_convolve(a,n):
'scipy.convolve'
assert n%2==1
return sci.convolve(a,np.ones(n,dtype='float')/n, 'same')[n//2:-n//2+1]

def rollavg_convolve_edges(a,n):
'scipy.convolve, edge handling'
assert n%2==1
return sci.convolve(a,np.ones(n,dtype='float'), 'same')/sci.convolve(np.ones(len(a)),np.ones(n), 'same')

def rollavg_cumsum(a,n):
'numpy.cumsum'
assert n%2==1
cumsum_vec = np.cumsum(np.insert(a, 0, 0))
return (cumsum_vec[n:] - cumsum_vec[:-n]) / n

def rollavg_cumsum_edges(a,n):
'numpy.cumsum, edge handling'
assert n%2==1
N = len(a)
d = np.hstack((np.arange(n//2+1,n),np.ones(N-n)*n,np.arange(n,n//2,-1)))
return (cumsum_vec[n+n//2:-n//2+1] - cumsum_vec[n//2:-n-n//2]) / d

def rollavg_roll(a,n):
'Numpy array rolling'
assert n%2==1
N = len(a)
rolling_idx = np.mod((N-1)*np.arange(n)[:,None] + np.arange(N), N)
return a[rolling_idx].mean(axis=0)[n-1:]

def rollavg_roll_edges(a,n):
# see https://stackoverflow.com/questions/42101082/fast-numpy-roll
'Numpy array rolling, edge handling'
assert n%2==1
m = a.shape[1]
idx = np.mod((m-1)*np.arange(n)[:,None] + np.arange(m), m) # Rolling index
out = a[np.arange(-n//2,n//2)[:,None], idx]
d = np.hstack((np.arange(1,n),np.ones(m-2*n+1+n//2)*n,np.arange(n,n//2,-1)))
return (out.sum(axis=0)/d)[n//2:]

def rollavg_pandas(a,n):
'Pandas rolling average'
return pd.DataFrame(a).rolling(5, center=True, min_periods=1).mean().to_numpy()

def rollavg_bottlneck(a,n):
'bottleneck.move_mean'
return bn.move_mean(a, window=n, min_count=1)

N = 10**6
a = np.random.rand(N)
functions = [rollavg_direct, rollavg_comprehension, rollavg_convolve,
rollavg_convolve_edges, rollavg_cumsum, rollavg_cumsum_edges,
rollavg_pandas, rollavg_bottlneck, rollavg_roll, rollavg_roll_edges]

print('Small window (n=3)')
for f in functions :
print('\n'+f.__doc__+ ' : ')
%timeit b=f(a,3)

print('\nLarge window (n=1001)')
for f in functions[0:-2] :
print('\n'+f.__doc__+ ' : ')
%timeit b=f(a,1001)

print('\nMemory\n')
print('Small window (n=3)')
N = 10**7
a = np.random.rand(N)
for f in functions[2:] :
print('\n'+f.__doc__+ ' : ')
%memit b=f(a,3)

print('\nLarge window (n=1001)')
for f in functions[2:-2] :
print('\n'+f.__doc__+ ' : ')
%memit b=f(a,1001)
``````

Timing, Small window (n=3)

``````Direct "for" loop :

4.14 s ± 23.7 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

List comprehension :
3.96 s ± 27.9 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

scipy.convolve :
1.07 ms ± 26.7 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)

scipy.convolve, edge handling :
4.68 ms ± 9.69 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

numpy.cumsum :
5.31 ms ± 5.11 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

numpy.cumsum, edge handling :
8.52 ms ± 11.1 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

Pandas rolling average :
9.85 ms ± 9.63 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

bottleneck.move_mean :
1.3 ms ± 12.2 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

Numpy array rolling :
31.3 ms ± 91.9 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)

Numpy array rolling, edge handling :
61.1 ms ± 55.9 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)
``````

Timing, Large window (n=1001)

``````Direct "for" loop :
4.67 s ± 34 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

List comprehension :
4.46 s ± 14.6 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

scipy.convolve :
103 ms ± 165 µs per loop (mean ± std. dev. of 7 runs, 10 loops each)

scipy.convolve, edge handling :
272 ms ± 1.23 ms per loop (mean ± std. dev. of 7 runs, 1 loop each)

numpy.cumsum :
5.19 ms ± 12.4 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

numpy.cumsum, edge handling :
8.7 ms ± 11.5 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

Pandas rolling average :
9.67 ms ± 199 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

bottleneck.move_mean :
1.31 ms ± 15.7 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)
``````

Memory, Small window (n=3)

``````The memory_profiler extension is already loaded. To reload it, use:

scipy.convolve :
peak memory: 362.66 MiB, increment: 73.61 MiB

scipy.convolve, edge handling :
peak memory: 510.24 MiB, increment: 221.19 MiB

numpy.cumsum :
peak memory: 441.81 MiB, increment: 152.76 MiB

numpy.cumsum, edge handling :
peak memory: 518.14 MiB, increment: 228.84 MiB

Pandas rolling average :
peak memory: 449.34 MiB, increment: 160.02 MiB

bottleneck.move_mean :
peak memory: 374.17 MiB, increment: 75.54 MiB

Numpy array rolling :
peak memory: 661.29 MiB, increment: 362.65 MiB

Numpy array rolling, edge handling :
peak memory: 1111.25 MiB, increment: 812.61 MiB
``````

Memory, Large window (n=1001)

``````scipy.convolve :
peak memory: 370.62 MiB, increment: 71.83 MiB

scipy.convolve, edge handling :
peak memory: 521.98 MiB, increment: 223.18 MiB

numpy.cumsum :
peak memory: 451.32 MiB, increment: 152.52 MiB

numpy.cumsum, edge handling :
peak memory: 527.51 MiB, increment: 228.71 MiB

Pandas rolling average :
peak memory: 451.25 MiB, increment: 152.50 MiB

bottleneck.move_mean :
peak memory: 374.64 MiB, increment: 75.85 MiB
``````

I feel this can be easily solved using bottleneck

See basic sample below:

``````import numpy as np
import bottleneck as bn

a = np.random.randint(4, 1000, size=(5, 7))
mm = bn.move_mean(a, window=2, min_count=1)
``````

This gives move mean along each axis.

• "mm" is the moving mean for "a".

• "window" is the max number of entries to consider for moving mean.

• "min_count" is min number of entries to consider for moving mean (e.g. for first element or if the array has nan values).

The good part is Bottleneck helps to deal with nan values and it's also very efficient.

In case you want to take care the edge conditions carefully (compute mean only from available elements at edges), the following function will do the trick.

``````import numpy as np

def running_mean(x, N):
out = np.zeros_like(x, dtype=np.float64)
dim_len = x.shape[0]
for i in range(dim_len):
if N%2 == 0:
a, b = i - (N-1)//2, i + (N-1)//2 + 2
else:
a, b = i - (N-1)//2, i + (N-1)//2 + 1

#cap indices to min and max indices
a = max(0, a)
b = min(dim_len, b)
out[i] = np.mean(x[a:b])
return out

>>> running_mean(np.array([1,2,3,4]), 2)
array([1.5, 2.5, 3.5, 4. ])

>>> running_mean(np.array([1,2,3,4]), 3)
array([1.5, 2. , 3. , 3.5])
``````
``````for i in range(len(Data)):
Data[i, 1] = Data[i-lookback:i, 0].sum() / lookback
``````

Try this piece of code. I think it's simpler and does the job. lookback is the window of the moving average.

In the `Data[i-lookback:i, 0].sum()` I have put `0` to refer to the first column of the dataset but you can put any column you like in case you have more than one column.

I actually wanted a slightly different behavior than the accepted answer. I was building a moving average feature extractor for an `sklearn` pipeline, so I required that the output of the moving average have the same dimension as the input. What I want is for the moving average to assume the series stays constant, ie a moving average of `[1,2,3,4,5]` with window 2 would give `[1.5,2.5,3.5,4.5,5.0]`.

For column vectors (my use case) we get

``````def moving_average_col(X, n):
z2 = np.cumsum(np.pad(X, ((n,0),(0,0)), 'constant', constant_values=0), axis=0)
z1 = np.cumsum(np.pad(X, ((0,n),(0,0)), 'constant', constant_values=X[-1]), axis=0)
return (z1-z2)[(n-1):-1]/n
``````

And for arrays

``````def moving_average_array(X, n):
z2 = np.cumsum(np.pad(X, (n,0), 'constant', constant_values=0))
z1 = np.cumsum(np.pad(X, (0,n), 'constant', constant_values=X[-1]))
return (z1-z2)[(n-1):-1]/n
``````

Of course, one doesn't have to assume constant values for the padding, but doing so should be adequate in most cases.

talib contains a simple moving average tool, as well as other similar averaging tools (i.e. exponential moving average). Below compares the method to some of the other solutions.

``````%timeit pd.Series(np.arange(100000)).rolling(3).mean()
2.53 ms ± 40.5 µs per loop (mean ± std. dev. of 7 runs, 100 loops each)

%timeit talib.SMA(real = np.arange(100000.), timeperiod = 3)
348 µs ± 3.5 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)

%timeit moving_average(np.arange(100000))
638 µs ± 45.1 µs per loop (mean ± std. dev. of 7 runs, 1000 loops each)
``````

One caveat is that the real must have elements of `dtype = float`. Otherwise the following error is raised

Exception: real is not double

Here is a fast implementation using numba (mind the types). Note it does contain nans where shifted.

``````import numpy as np
import numba as nb

@nb.jit(nb.float64[:](nb.float64[:],nb.int64),
fastmath=True,nopython=True)
def moving_average( array, window ):
ret = np.cumsum(array)
ret[window:] = ret[window:] - ret[:-window]
ma = ret[window - 1:] / window
n = np.empty(window-1); n.fill(np.nan)
return np.concatenate((n.ravel(), ma.ravel()))
``````
• This returns nans at the beginning. – Adam Erickson Jan 15 at 19:19