Extrapolation is never easy. It's almost always poor, except if you have some strong assumptions about the data.

In your case, you could try it, but I don't think there's something available immediately.

I'd try:

- determine the first maximum of the autocorrelation
- extend your signal by shifting it with a multiple of this value

If needed, do interpolation afterwards.

Example:

```
import numpy as np
import matplotlib.pyplot as plt
def autocorr(x):
result = np.correlate(x, x, mode='full')
return result[result.size/2:]
data = np.sin(np.linspace(0,30,300)) + np.random.random((300)) * 0.1
plt.subplot(3,1,1)
#plt.plot(data,"b-")
plt.plot(data,"bx")
acorr = autocorr(data)
acorr_diff = np.diff(acorr)
maxima = [i+1 for i in range(acorr_diff.shape[0]-1)
if acorr_diff[i]>=0 and acorr_diff[i+1]<0]
plt.subplot(3,1,2)
plt.plot(acorr)
for m in maxima:
plt.axvline(m, color="b", alpha=0.5)
first_max = maxima[0]
new_data = np.hstack([data[:4*first_max],data])
plt.subplot(3,1,3)
plt.plot(data)
#plt.plot(data,"b-", alpha=0.1)
plt.plot(data,"bx")
plt.plot(new_data,"r-")
#plt.plot(new_data,"rx")
plt.show()
```

This is only a very basic implementation. It has limitations, for sure, but the principle should be clear.