# Recreating time series data using FFT results without using ifft

I analyzed the sunspots.dat data (below) using fft which is a classic example in this area. I obtained results from fft in real and imaginery parts. Then I tried to use these coefficients (first 20) to recreate the data following the formula for Fourier transform. Thinking real parts correspond to a_n and imaginery to b_n, I have

``````import numpy as np
from scipy import *
from matplotlib import pyplot as gplt
from scipy import fftpack

def f(Y,x):
total = 0
for i in range(20):
total += Y.real[i]*np.cos(i*x) + Y.imag[i]*np.sin(i*x)

year=tempdata[:,0]
wolfer=tempdata[:,1]

Y=fft(wolfer)
n=len(Y)
print n

xs = linspace(0, 2*pi,1000)
gplt.plot(xs, [f(Y, x) for x in xs], '.')
gplt.show()
``````

For some reason however, my plot does not mirror the one generated by ifft (I use the same number of coefficients on both sides). What could be wrong ?

Data:

http://linuxgazette.net/115/misc/andreasen/sunspots.dat

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Just out of curiosity, what are you doing with the spectrum? If you're trying to determine relative spectral amplitudes of various components, you might want to use a data window (en.wikipedia.org/wiki/Window_function). For instance, if you plot `np.abs(fft(wolfer*hanning(len(wolfer))))` the peak around n=30 shows a little more structure than without the window. – mtrw Dec 15 '10 at 17:01

When you called `fft(wolfer)`, you told the transform to assume a fundamental period equal to the length of the data. To reconstruct the data, you have to use basis functions of the same fundamental period = `2*pi/N`. By the same token, your time index `xs` has to range over the time samples of the original signal.

Another mistake was in forgetting to do to the full complex multiplication. It's easier to think of this as `Y[omega]*exp(1j*n*omega/N)`.

Here's the fixed code. Note I renamed `i` to `ctr` to avoid confusion with `sqrt(-1)`, and `n` to `N` to follow the usual signal processing convention of using the lower case for a sample, and the upper case for total sample length. I also imported `__future__ division` to avoid confusion about integer division.

forgot to add earlier: Note that SciPy's `fft` doesn't divide by `N` after accumulating. I didn't divide this out before using `Y[n]`; you should if you want to get back the same numbers, rather than just seeing the same shape.

And finally, note that I am summing over the full range of frequency coefficients. When I plotted `np.abs(Y)`, it looked like there were significant values in the upper frequencies, at least until sample 70 or so. I figured it would be easier to understand the result by summing over the full range, seeing the correct result, then paring back coefficients and seeing what happens.

``````from __future__ import division
import numpy as np
from scipy import *
from matplotlib import pyplot as gplt
from scipy import fftpack

def f(Y,x, N):
total = 0
for ctr in range(len(Y)):
total += Y[ctr] * (np.cos(x*ctr*2*pi/N) + 1j*np.sin(x*ctr*2*pi/N))
return real(total)

year=tempdata[:,0]
wolfer=tempdata[:,1]

Y=fft(wolfer)
N=len(Y)
print N

xs = range(N)
gplt.plot(xs, [f(Y, x, N) for x in xs])
gplt.show()
``````
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For the first 20, I just changed the line to "for ctr in range(20)", and that fits perfectly with ifft with the same number of coefficients. Your len(Y) obviously uses the entire thing and that fits perfectly with the data. Very cool. Thanks. – user423805 Dec 15 '10 at 17:14
You might want to use both the first 20 and last 20. If you plot `abs(Y)`, you'll see the coefficients are symmetric. But if you `print` the values, you'll see that they're actually complex conjugates of each other. This is due to the FFT's Hermitian symmetry for real data. The upshot is you won't get back a real answer without using both the low and high frequency coefficient. – mtrw Dec 15 '10 at 17:23
It's going to take weeks to digest this :) Thanks again. – user423805 Dec 15 '10 at 17:45
It took me SEMESTERS! Have fun, it's good stuff. – mtrw Dec 15 '10 at 17:50