I can compute the autocorrelation using numpy's built in functionality:
`numpy.correlate(x,x,mode='same')`

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 `numpy`

or `scipy`

that does this, possibly faster than I would get if I were to compute partition and loop through the data myself?

# UPDATE

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()
```

`same`

option. – Dipole Dec 5 '17 at 20:18