# Specify lag in numpy.correlate

Matlab's cross-correlation function `xcorr(x,y,maxlags)` has an option `maxlag`, which returns the cross-correlation sequence over the lag range `[-maxlags:maxlags]`. Numpy's `numpy.correlate(N,M,mode)` has three modes, but none of them allow me to set a specific lag, which is different from full `(N+M-1)`, same `(max(M, N))` or valid `(max(M, N) - min(M, N) + 1 )`. For `len(N) = 60000`, `len (M) = 200`, I want to set the lag as 100.

• So you're asking for a function like correlate that takes a variable lag parameter? – macduff Feb 21 '12 at 17:34

I would recommend looking at this file to determine how you would want to implement the correlation described here.

`matplotlib.xcorr` has the maxlags param. It is actually a wrapper of the `numpy.correlate`, so there is no performance saving. Nevertheless it gives exactly the same result given by Matlab's cross-correlation function. Below I edited the code from maxplotlib so that it will return only the correlation. The reason is that if we use `matplotlib.corr` as it is, it will return the plot as well. The problem is, if we put complex data type as the arguments into it, we will get "casting complex to real datatype" warning when matplotlib tries to draw the plot.

``````<!-- language: python -->

import numpy as np
import matplotlib.pyplot as plt

def xcorr(x, y, maxlags=10):
Nx = len(x)
if Nx != len(y):
raise ValueError('x and y must be equal length')

c = np.correlate(x, y, mode=2)

if maxlags is None:
maxlags = Nx - 1

if maxlags >= Nx or maxlags < 1:
raise ValueError('maxlags must be None or strictly positive < %d' % Nx)

c = c[Nx - 1 - maxlags:Nx + maxlags]

return c
``````

This is my implementation of the lead-lag correlation, but it is limited to be 1-D and not guaranteed to be the best in terms of efficient. It uses the scipy.stats.pearsonr to the do the core computation, so also returned is the p value for the coefficient. Please modify to optimize based on this straw man.

``````def lagcorr(x,y,lag=None,verbose=True):
'''Compute lead-lag correlations between 2 time series.

<x>,<y>: 1-D time series.
<lag>: lag option, could take different forms of <lag>:
if 0 or None, compute ordinary correlation and p-value;
if positive integer, compute lagged correlation with lag
upto <lag>;
upto <-lag>;
if pass in an list or tuple or array of integers, compute

Therefore positive lag means <x> lags <y> by <lag>, computation is
done by shifting <x> to the left hand side by <lag> with respect to
<y>.
Similarly negative lag means <x> leads <y> by <lag>, computation is
done by shifting <x> to the right hand side by <lag> with respect to
<y>.

Return <result>: a (n*2) array, with 1st column the correlation
coefficients, 2nd column correpsonding p values.

Currently only works for 1-D arrays.
'''

import numpy
from scipy.stats import pearsonr

if len(x)!=len(y):
raise('Input variables of different lengths.')

#--------Unify types of <lag>-------------
if numpy.isscalar(lag):
if abs(lag)>=len(x):
raise('Maximum lag equal or larger than array.')
if lag<0:
lag=-numpy.arange(abs(lag)+1)
elif lag==0:
lag=[0,]
else:
lag=numpy.arange(lag+1)
elif lag is None:
lag=[0,]
else:
lag=numpy.asarray(lag)

#-------Loop over lags---------------------
result=[]
if verbose:
print '\n#<lagcorr>: Computing lagged-correlations at lags:',lag

for ii in lag:
if ii<0:
result.append(pearsonr(x[:ii],y[-ii:]))
elif ii==0:
result.append(pearsonr(x,y))
elif ii>0:
result.append(pearsonr(x[ii:],y[:-ii]))

result=numpy.asarray(result)

return result
``````