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I create a logarithmic chirp exactly as found on the matlab help page.

t = 0:0.001:10;      % 10 seconds @ 1kHz sample rate
fo = 10; f1 = 400;   % Start at 10Hz, go up to 400Hz
X = chirp(t,fo,10,f1,'logarithmic');


Then I bring it to the frequency domain with the following code which works on other applications for me.

fft_prep = fftshift(fft(X));
fft_mag = abs(fft_prep);
pos_fft = fft_mag(1:ceil(length(fft_mag)/2));
db_fft = 20*log10(pos_fft);

And I was surprised to see the following graph appear to be exciting 1kHz-5kHz:


I am not as familiar with the chirp function in matlab and was wondering if anyone saw something obvious that I am missing. Any other pointers are welcome.

share|improve this question
Taking the FFT of a chirp signal doesn't seem like a useful thing to do? I wouldn't think that just becauce the range of your spectrogram is 10Hz-400Hz that those would be the same frequencies to show on a bode plot. I think your question is more to do with the frequency properties of a finite time chirp signal than it has to do with matlab. I suggest you ask it here: – Dan Mar 14 '13 at 6:59
Good point, maybe that spectrogram isn't showing me the whole picture. It is the chirp function I am trying to understand better. I would expect that I can sweep through a limited number of frequencies and see them through the FFT. What do you think I would expect to see? I geared this question to be more code-centric focusing on maybe finding a bug in my chirp function or something. I have posted on the DSP forum as well with a more DSP-based question. Feel free to edit my question if you believe it can be more SO friendly. – Kyle Weller Mar 14 '13 at 7:07
No I don't think it belongs here, your question has nothing to do with the code. The chirp signal shows different frequencies at different times but FFT looks the whole signal (all times) and to achieve that I imagine it generates higher harmonics. There is a reason the matlab example plots a spectrogram and doesn't take an FFT and that is because the FFT of the chirp isn't really a generally useful thing to do. The chirp signal itself tests a system over a range of frequencies without having to leave the time domain, the point (in my mind) is to eliminate the need for taking an FFT – Dan Mar 14 '13 at 7:14
BTW if you're looking for a constant magnitude over a limited range of frequencies (i.e. a rect function in the frequency domain) then the transformed time domain function is a sinc function i.e. sin(t)/t. – Dan Mar 14 '13 at 7:20
I definitely agree with you that taking the FFT of a chirp is not a very useful thing. I am trying to learn more about the chirp function specifically and want to verify what exactly I am creating with it. I was trying to keep the theory out of this thread, but our comments definitely have led us astray here and maybe we should move our comments to the DSP thread or take them to email correspondence. As the answer below verifies, I had a bug or misunderstanding in my code which I was trying to focus on and I feel this thread was extremely valuable for me and hopefully for others in the future. – Kyle Weller Mar 14 '13 at 7:29
up vote 5 down vote accepted

Nothing wrong with the chirp function...

You just need to plot your db_fft against frequency values, and not vector indexes =).

plot(linspace(fo,f1,length(db_fft)), db_fft);

enter image description here

I also tested calculating the FFT of your signal using my other FFT methods and they too indicate a range between 0 and 400 Hz.


IMO, I find it visually easier not to plot in dB or power (periodogram). Here's an excellent example and my goto method of calculating the FFT of a time-domain signal:


After some thinking, I agree I'm incorrect with my answer above, but not for the reason you say. The x-axis in the frequency domain should NOT go to the actual length of the chirp (or half, or dubbel or anything like that). The x-axis in the frequency domain should go to half of the sampling rate of the signal (Fs/2) and its your obligation to ensure you are sampling your signal with a sampling frequency twice that of the maxium frequency you wish/hope to resolve.

In other words, its incorrect to assume your FFT is of same/twice/half the length of your time domain signal because we can choose ANY number of frequency bins to represent the FFT in, and best practice is a length = N^2 (power of 2) for quick computation. Think about, why do you even need to know the time values when you calculate the FFT? You dont! You only need the sampling frequency (which should be set to Fs = 1000 btw, not Fs = 0.001).

My answer above then is incorrect, it should be:

plot(linspace(0, Fs/2, length(db_fft)), db_fft)

Instead of Fs/2, you have written length(t)/(2*Tfinal). it's (almost) the same value as Fs/2 but its not the correct way going about it =).

Here is my goto FFT method (values not in dB).

function [X,f] = myfft(x,Fs,norm)
    % usage: [X, f] = myfft(x,Fs,norm);
    %        figure(); plot(f,X)
    % norm: 'true' normalizes max(amplitude(fft))=1, default=false.
    if nargin==2
    L = length(x); NFFT = 2^nextpow2(L);
    f = Fs/2*linspace(0,1,NFFT/2+1);
    %f =0:(Fs/NFFT):Fs/2;
    X = fft(x,NFFT)/L; X = 2*abs(X(1:NFFT/2+1));
    if norm==true; X = X/max(abs(X)); end

And here's the resulting graph from [Xfft, f] = myfft(X,Fs); plot(f,Xfft); Notice that the return frequency bin vector has max(f) = Fs/2 in accordance to NyQuist theorem (any higher frequencies than Fs/2 cannot be resolved).

enter image description here

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I might be mistaken, but isn't the fft signal still plotted left-right mirrored? After using fftshift, the spectrum is zero centered and when you plot only the left half you end up with zero at the right hand side of your plot, right? – H.Muster Mar 14 '13 at 7:33
indeed, i noticed that too. – FredrikRedin Mar 14 '13 at 7:37
I assume you are talking about this line: pos_fft = fft_mag(1:ceil(length(fft_mag)/2)); to be switched to pos_fft = fft_mag(ceil(length(fft_mag)/2)+1:length(fft_mag));? – Kyle Weller Mar 14 '13 at 7:44
yes, or you can simply fft(fftshift(X)), instead of fftshift(fft(X)) – FredrikRedin Mar 14 '13 at 7:48
Thanks for helping me find these coding issues! I have updated this DSP thread to ask more about the theory and learn how to create a constant magnitude chirp. – Kyle Weller Mar 14 '13 at 13:21

I had a couple of errors, but not all of them were fixed. After trying the code out a little more, here is the solution I have come up with.

I added a few more variables to make the setup more modular.

Tfinal = 10;
Fs = 1/1000;
t = 0:Fs:Tfinal;      % 10 seconds @ 1kHz sample rate
fo = 10; f1 = 400;   % Start at 10Hz, go up to 400Hz
X = chirp(t,fo,Tfinal,f1,'linear');

When I plot the magnitude versus the linspace, the linspace needs to match up to the length of the actual chirp signal and not just from the low frequency to the high frequency. Because the vector t is of length 1000 and after the FFT we use the positive half, the chirp signal is 500 long and not 400, which the linspace up to f1 would suggest.

fft_prep = fftshift(fft(X));
fft_mag = abs(fft_prep);
pos_fft = fft_mag(ceil(length(fft_mag)/2)+1:length(fft_mag));
plot(linspace(0,length(t)/(2*Tfinal),length(db_fft)), db_fft);

I also made the fix previously mentioned to get the positive side of the FFT instead of the negative. This plots:

enter image description here

This accurately graphs the chirp exciting 10Hz-400Hz. You can see it clearer by going to extreme cases and making it linear. Try a sampling frequency of 100, and a range from 10-25, without the linspace correction:

enter image description here

After the correction:

enter image description here

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Incidentally, it may be useful to extract the original chirp amplitude from the FFT. For example if you are doing an audio sweep in frequency of some device, and you would like to know the amplitude and phase of the response at each frequency (like Pspice givs you). In short, the amplitude is a^2 = abs(FFT)^2 *4 *bandwidth of chirp /(Fs * N) where Fs is sample frequency and N is the number of points in the FFT. e.g. the bandwidth of a chirp from 200 to 400Hz is 200Hz.

If you want to know the dervition, start with Parseval's theorum: mean sqr of time signal = area under PSD. Thus, a^2/2 = sum(abs(FFT)^2) / N^2 where a is the peak amplitude of the swept frequency signal (e.g. chirp). If the chirp is linear rather than logarithmic in frequency distribution, then the FFT is flat, as in the above plots. THus we may replace the sum with Nb * abs(FFT)^2 / N^2 where Nb is the number of frequency bins that the chirp occupies, and abs(FFT) is the magnitude of the FFT, which is the same for all the frequency bins that the chirp occupies. Using the fact that the bandwidth of one frequency bin is Fs/N, we get that the bandwidth of the chirp is Nb * Fs /N. The result above is now easily derivable from here.

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