I can compute the autocorrelation using numpy's built in functionality:
However the resulting correlation is naturally noisy. I can partition my data, and compute the correlation on each resulting window, then average them all together to compute cleaner autocorrelation, similar to what
signal.welch does. Is there a handy function in either
scipy that does this, possibly faster than I would get if I were to compute partition and loop through the data myself?
This is motivated by @kazemakase answer. I have tried to show what I mean with some code used to generate the figure below.
One can see that @kazemakase is correct with the fact that the AC function naturally averages out the noise. However the averaging of the AC has the advantage that it is much faster!
np.correlate seems to scale as the slow
O(n^2) rather than
O(nlogn) that I would expect if the correlation was calculated using circular convolution via the FFT...
from statsmodels.tsa.arima_model import ARIMA import statsmodels as sm import matplotlib.pyplot as plt import numpy as np np.random.seed(12345) arparams = np.array([.75, -.25, 0.2, -0.15]) maparams = np.array([.65, .35]) ar = np.r_[1, -arparams] # add zero-lag and negate ma = np.r_[1, maparams] # add zero-lag x = sm.tsa.arima_process.arma_generate_sample(ar, ma, 10000) def calc_rxx(x): x = x-x.mean() N = len(x) Rxx = np.correlate(x,x,mode="same")[N/2::]/N #Rxx = np.correlate(x,x,mode="same")[N/2::]/np.arange(N,N/2,-1) return Rxx/x.var() def avg_rxx(x,nperseg=1024): rxx_windows =  Nw = int(np.floor(len(x)/nperseg)) print Nw first = True for i in range(Nw-1): xw = x[i*nperseg:nperseg*(i+1)] y = calc_rxx(xw) if i%1 == 0: if first: plt.semilogx(y,"k",alpha=0.2,label="Short AC") first = False else: plt.semilogx(y,"k",alpha=0.2) rxx_windows.append(y) print np.shape(rxx_windows) return np.mean(rxx_windows,axis=0) plt.figure() r_avg = avg_rxx(x,nperseg=300) r = calc_rxx(x) plt.semilogx(r_avg,label="Average AC") plt.semilogx(r,label="Long AC") plt.xlabel("Lag") plt.ylabel("Auto-correlation") plt.legend() plt.xlim([0,150]) plt.show()