# Using fourier analysis for time series prediction

For data that is known to have seasonal, or daily patterns I'd like to use fourier analysis be used to make predictions. After running fft on time series data, I obtain coefficients. How can I use these coefficients for prediction?

I believe FFT assumes all data it receives constitute one period, then, if I simply regenerate data using ifft, I am also regenerating the continuation of my function, so can I use these values for future values?

Simply put: I run fft for t=0,1,2,..10 then using ifft on coef, can I use regenerated time series for t=11,12,..20 ?

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It sounds like you want a combination of extrapolation and denoising.

You say you want to repeat the observed data over multiple periods. Well, then just repeat the observed data. No need for Fourier analysis.

But you also want to find "patterns". I assume that means finding the dominant frequency components in the observed data. Then yes, take the Fourier transform, preserve the largest coefficients, and eliminate the rest.

``````X = scipy.fft(x)
Y = scipy.zeros(len(X))
Y[important frequencies] = X[important frequencies]
``````

As for periodic repetition: Let `z = [x, x]`, i.e., two periods of the signal `x`. Then `Z[2k] = X[k]` for all `k` in {0, 1, ..., N-1}, and zeros otherwise.

``````Z = scipy.zeros(2*len(X))
Z[::2] = X
``````
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So you are repeating most important coefficients in Z (twice in the above example), and if use ifft to regenerate my time series, this new series will be longer than the original and by definition will have predictions in it. –  user423805 Dec 18 '10 at 20:28
I guess by denoising you mean picking the most important coefficients. –  user423805 Dec 18 '10 at 20:30
`Z = [X[0], 0, X[1], 0, X[2], 0, ..., X[N-1], 0]`. If that's what you mean, then yes. And yes, preserving the most important coefficients will have a "smoothing" or "blurring" or "denoising" effect on the signal. –  Steve Tjoa Dec 18 '10 at 20:46
I just realized I can keep calling Y[ctr] * (np.cos(x*ctr*2*pi/N) + 1j*np.sin(x*ctr*2*pi/N)) where x is new values and Y is coefficients, and ctr is coef indexes, and add this up; this will essentially forecast. What do you think? –  user423805 Dec 18 '10 at 20:58
Yes, that is basically isolating a single complex sinusoid in the time domain. But the answer will be complex. You also need the component `Y[N-ctr]` in order to get a real signal. (`x` is a real signal iff `X` has conjugate symmetry, i.e., `X[k] = X*[-k]`.) –  Steve Tjoa Dec 18 '10 at 21:34

When you run an FFT on time series data, you transform it into the frequency domain. The coefficients multiply the terms in the series (sines and cosines or complex exponentials), each with a different frequency.

Extrapolation is always a dangerous thing, but you're welcome to try it. You're using past information to predict the future when you do this: "Predict tomorrow's weather by looking at today." Just be aware of the risks.