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I learned about fourier transformation in mathematics classes and thought I had understood them. Now, I am trying to play around with R (statistical language) and interpret the results of a discrete FFT in practice. This is what I have done:

x = seq(0,1,by=0.1)
y = sin(2*pi*(x))

calcenergy <- function(x) Im(x) * Im(x) + Re(x) * Re(x)

fy <- fft(y)
plot(x, calcenergy(fy))

and get this plot:

energy density spectrum of sin(2*pi*(x)) from 0 to 1 with a 0.1 step

If I understand this right, this represents the 'half' of the energy density spectrum. As the transformation is symmetric, I could just mirror all values to the negative values of x to get the full spectrum.

However, what I dont understand is, why I am getting two spikes? There is only a single sinus frequency in here. Is this an aliasing effect?

Also, I have no clue how to get the frequencies out of this plot. Lets assume the units of the sinus function were seconds, is the peak at 1.0 in the density spectrum 1Hz then?

Again: I understand the theory behind FFT; the practical application is the problem :).

Thanks for any help!

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Tangentially, calcenergy can be written as function(x) abs(x)^2. (This will be more efficient). –  dbaupp May 11 '12 at 10:33
    
@dbaupp oh thanks. I knew there was some built in way to do it, but I was lazy searching for it :) –  Peter Müller May 11 '12 at 10:34
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2 Answers

up vote 8 down vote accepted

For a purely real input signal of N points you get a complex output of N points with complex conjugate symmetry about N/2. You can ignore the output points above N/2, since they provide no useful additional information for a real input signal, but if you do plot them you will see the aforementioned symmetry, and for a single sine wave you will see peaks at bins n and N - n. (Note: you can think of the upper N/2 bins as representing negative frequencies.) In summary, for a real input signal of N points, you get N/2 useful complex output bins from the FFT, which represent frequencies from DC (0 Hz) to Nyquist (Fs / 2).

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Thanks for your answer. I just tried it use an odd number of values with seq(0,1.1,by=0.1) and indeed the symmetry was exactly around the 6th bucket as you said. This answeres my first question already. How about the second one, how can I infer the frequency of those bins? Would upvote if i could (needs 15 rep) :/ –  Peter Müller May 11 '12 at 10:11
    
Oh, just saw you ansered that already in the meantime :) Thank you! –  Peter Müller May 11 '12 at 10:13
1  
+1 Finally got the rep to upvote yay :) –  Peter Müller May 11 '12 at 16:28
    
I upvoted and favourited your question to get you a little more rep. ;-) –  Paul R May 11 '12 at 16:32
    
thanks, very kind :) –  Peter Müller May 11 '12 at 16:33
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To get frequencies from the result of an FFT you need to know the sample rate of the data that was input to the FFT and the length of the FFT. The center frequency of each bin is the bin index times the sample rate divided by the length of the FFT. Thus you will get frequencies from DC (0 Hz) to Fs/2 at the halfway bin.

The second half of the FFT results are just complex conjugates of the first for real data inputs. The reason is that the imaginary portions of complex conjugates cancel, which is required to represent a summed result with zero imaginary content, e.g. strictly real.

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