# Empirical methods

Here's a fun take on the problem. The more general form of your question is this:

Given a repeating sequence of unknown length, determine the period of
the signal.

The process to determine the repeating frequencies is known as the Fourier Transform. In your example case the signal is clean and discrete, but the following solution will work even with continuous noisy data! The FFT will try to duplicate the frequencies of the input signal by approximating them in the so-called "wave-space" or "Fourier-space". Basically a peak in this space corresponds to a repeating signal. The period of your signal is related to the longest wavelength that is peaked.

```
import itertools
# of course this is a fake one just to offer an example
def source():
return itertools.cycle((1, 0, 1, 4, 8, 2, 1, 3, 3, 2))
import pylab as plt
import numpy as np
import scipy as sp
# Generate some test data, i.e. our "observations" of the signal
N = 300
vals = source()
X = np.array([vals.next() for _ in xrange(N)])
# Compute the FFT
W = np.fft.fft(X)
freq = np.fft.fftfreq(N,1)
# Look for the longest signal that is "loud"
threshold = 10**2
idx = np.where(abs(W)>threshold)[0][-1]
max_f = abs(freq[idx])
print "Period estimate: ", 1/max_f
```

This gives the correct answer for this case, `10`

though if `N`

didn't divide the cycles cleanly, you would get a close estimate. We can visualize this via:

```
plt.subplot(211)
plt.scatter([max_f,], [np.abs(W[idx]),], s=100,color='r')
plt.plot(freq[:N/2], abs(W[:N/2]))
plt.xlabel(r"$f$")
plt.subplot(212)
plt.plot(1.0/freq[:N/2], abs(W[:N/2]))
plt.scatter([1/max_f,], [np.abs(W[idx]),], s=100,color='r')
plt.xlabel(r"$1/f$")
plt.xlim(0,20)
plt.show()
```

`x_{n+1} := f(x_n)`

or else there won't be a good definition of a repetition! – katrielalex Jun 26 '12 at 10:13`(0, 1, 4, 8, 2, 1, 3, 3, 1, 1)`

be a correct answer? – Lev Levitsky Jun 26 '12 at 12:06