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I need to do auto-correlation of a set of numbers, which as I understand it is just the correlation of the set with itself.

I've tried it using numpy's correlate function, but I don't believe the result, as it almost always gives a vector where the first number is not the largest, as it ought to be.

So, this question is really two questions:

  1. What exactly is numpy.correlate doing?
  2. How can I use it (or something else) to do auto-correlation?
share|improve this question
See also:… for information about normalized autocorrelation. – amcnabb Oct 10 '13 at 18:39
up vote 51 down vote accepted

To answer your first question, numpy.correlate(a, v, mode) is performing the convolution of a with the reverse of v and giving the results clipped by the specified mode. The definition of convolution, C(t)=∑ -∞ < i < ∞ aivt+i where -∞ < t < ∞, allows for results from -∞ to ∞, but you obviously can't store an infinitely long array. So it has to be clipped, and that is where the mode comes in. There are 3 different modes: full, same, & valid:

  • "full" mode returns results for every t where both a and v have some overlap.
  • "same" mode returns a result with the same length as the shortest vector (a or v).
  • "valid" mode returns results only when a and v completely overlap each other. The documentation for numpy.convolve gives more detail on the modes.

For your second question, I think numpy.correlate is giving you the autocorrelation, it is just giving you a little more as well. The autocorrelation is used to find how similar a signal, or function, is to itself at a certain time difference. At a time difference of 0, the auto-correlation should be the highest because the signal is identical to itself, so you expected that the first element in the autocorrelation result array would be the greatest. However, the correlation is not starting at a time difference of 0. It starts at a negative time difference, closes to 0, and then goes positive. That is, you were expecting:

autocorrelation(a) = ∑ -∞ < i < ∞ aivt+i where 0 <= t < ∞

But what you got was:

autocorrelation(a) = ∑ -∞ < i < ∞ aivt+i where -∞ < t < ∞

What you need to do is take the last half of your correlation result, and that should be the autocorrelation you are looking for. A simple python function to do that would be:

def autocorr(x):
    result = numpy.correlate(x, x, mode='full')
    return result[result.size/2:]

You will, of course, need error checking to make sure that x is actually a 1-d array. Also, this explanation probably isn't the most mathematically rigorous. I've been throwing around infinities because the definition of convolution uses them, but that doesn't necessarily apply for autocorrelation. So, the theoretical portion of this explanation may be slightly wonky, but hopefully the practical results are helpful. These pages on autocorrelation are pretty helpful, and can give you a much better theoretical background if you don't mind wading through the notation and heavy concepts.

share|improve this answer
In current builds of numpy, the mode 'same' can be specified to achieve exactly what the A. Levy proposed. The body of the function could then read return numpy.correlate(x, x, mode='same') – David Zwicker Dec 2 '11 at 16:32
@DavidZwicker but the resultings are different! np.correlate(x,x,mode='full')[len(x)//2:] != np.correlate(x,x,mode='same'). For example, x = [1,2,3,1,2]; np.correlate(x,x,mode='full'); {>>> array([ 2, 5, 11, 13, 19, 13, 11, 5, 2])} np.correlate(x,x,mode='same'); {>>> array([11, 13, 19, 13, 11])}. The correct one is: np.correlate(x,x,mode='full')[len(x)-1:]; {>>> array([19, 13, 11, 5, 2])} see the first item is the largest one. – Developer Jan 1 '12 at 8:52
Note that this answer gives the unnormalized autocorrelation. – amcnabb Oct 10 '13 at 18:25

Auto-correlation comes in two versions: statistical and convolution. They both do the same, except for a little detail: The former is normalized to be on the interval [-1,1]. Here is an example of how you do the statistical one:

def acf(x, length=20):
    return numpy.array([1]+[numpy.corrcoef(x[:-i], x[i:]) \
        for i in range(1, length)])
share|improve this answer
You want numpy.corrcoef[x:-i], x[i:])[0,1] in the second line as the return value of corrcoef is a 2x2 matrix – luispedro Apr 3 '13 at 11:48

Using the numpy.corrcoef function instead of numpy.correlate to calculate the statistical correlation for a lag of t:

def autocorr(x, t=1):
    numpy.corrcoef(numpy.array([x[0:len(x)-t], x[t:len(x)]]))
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As I just ran into the same problem, I would like to share a few lines of code with you. In fact there are several rather similar posts about autocorrelation in stackoverflow by now. If you define the autocorrelation as a(x, L) = sum(k=0,N-L-1)((xk-xbar)*(x(k+L)-xbar))/sum(k=0,N-1)((xk-xbar)**2) [this is the definition given in IDL's a_correlate function and it agrees with what I see in answer 2 of question #12269834], then the following seems to give the correct results:

import numpy as np
import matplotlib.pyplot as plt

# generate some data
x = np.arange(0.,6.12,0.01)
y = np.sin(x)
# y = np.random.uniform(size=300)
yunbiased = y-np.mean(y)
ynorm = np.sum(yunbiased**2)
acor = np.correlate(yunbiased, yunbiased, "same")/ynorm
# use only second half
acor = acor[len(acor)/2:]


As you see I have tested this with a sin curve and a uniform random distribution, and both results look like I would expect them. Note that I used mode="same" instead of mode="full" as the others did.

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I think the real answer to the OP's question is succinctly contained in this excerpt from the Numpy.correlate documentation:

mode : {'valid', 'same', 'full'}, optional
    Refer to the `convolve` docstring.  Note that the default
    is `valid`, unlike `convolve`, which uses `full`.

This implies that, when used with no 'mode' definition, the Numpy.correlate function will return a scalar, when given the same vector for its two input arguments (i.e. - when used to perform autocorrelation).

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I use talib.CORREL for autocorrelation like this, I suspect you could do the same with other packages:

def autocorrelate(x, period):

    # x is a deep indicator array 
    # period of sample and slices of comparison

    # oldest data (period of input array) may be nan; remove it
    x = x[-np.count_nonzero(~np.isnan(x)):]
    # subtract mean to normalize indicator
    x -= np.mean(x)
    # isolate the recent sample to be autocorrelated
    sample = x[-period:]
    # create slices of indicator data
    correls = []
    for n in range((len(x)-1), period, -1):
        alpha = period + n
        slices = (x[-alpha:])[:period]
        # compare each slice to the recent sample
        correls.append(ta.CORREL(slices, sample, period)[-1])
    # fill in zeros for sample overlap period of recent correlations    
    for n in range(period,0,-1):
    # oldest data (autocorrelation period) will be nan; remove it
    correls = np.array(correls[-np.count_nonzero(~np.isnan(correls)):])      

    return correls

# the highest value correlation    
max_value = np.max(correls)
# index of the best correlation
max_index = np.argmax(correls)
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1) Here is the documentation for numpy.correlate. The code inside the file looks like this:

mode = _mode_from_name(mode)
return multiarray.correlate(a,v,mode)

multiarray.correlate points to a .pyd file (i.e. a DLL file), so to get the inner workings you should probably ask the numpy developers.

2) If you don't believe the numpy results, you might try SciPy's correlate function.

share|improve this answer
The scipy and numpy correlate functions are both in C. numpy multiarray source code is somewhere in here: and scipy correlate source code is here: – endolith Nov 28 '09 at 1:00

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