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I’m trying to obtain the FFT spectrum of these data: using Excel. @Paul R helped me a lot in another question to figure out the meaning of bins but there are still questions which I’d like to understand.

First, Excel, even when the moduli are represented in log scale, does not show them in dB. What do you do to have these magnitudes converted to dB?

Further, there’s a concern about the window function, aliasing etc. Since I’m crunching data from exactly one period, it seems that applying a window function is not necessary. Also, because I need only the fundamental, second and third harmonic and no other peaks in the higher bins, taking care of aliasing also does not seem necessary. Of great concern, however, is the non-n^2 number of points – 1253. I tried padding them with zeros up to 2048 or doing the FFT on just the first 1024, ignoring the 229 remaining points and, finally, deleting every 6th point and then deleting every 52nd point and doubling the last point to get the necessary 1024. Ultimately, padding with zeros turned out to be the worst approach – couples of high and low bars repeat throughout the whole spectrum. Truncating the data (processing only the first 1024 points) appears to work the best. I would really like to know what someone with experience in signal processing would recommend as the best approach in producing the most realistic spectrum.

Here are examples of two different ways I applied the FFT on these data:

share|improve this question
Sorry - I hadn't picked up from your previous question that you have exactly one period of data, so my previous suggestions re windowing etc were off base. One thing I notice form your data is that you have a very large (negative) DC component, and the non-DC peaks are relatively small compared to the noise floor - is that what you expect ? – Paul R Jan 9 '12 at 17:05
Here's what I'm getting -- This figure shows the result from the FFT when data are padded w/ zeros to 2048: . Here is the figure with 1024 data points under FFT (the remaining 229 points ignored): . And this link shows the result when every 6th and then every 52nd point is deleted and the last data point is doubled: fig_every_6th_and_52nd_point_deleted.jpg . – ganzewoort Jan 9 '12 at 20:29
Sorry - I get Forbidden. You don't have permission to access /fig_truncated.jpg on this server. – Paul R Jan 9 '12 at 22:20
I get the same message sometimes. Please try the address without the http:// and see if you can open the pic. – ganzewoort Jan 9 '12 at 22:39
@Paul R, I need the DC component in combination with the non-DC one. The non-DC component is part of the useful signal and should be clearly above the noise. – ganzewoort Jan 10 '12 at 8:34

If you have exactly one period of data, you should use a FFT (or DFT if no fft is available) of exactly that length. In theory, FFTs are not limited to powers of 2 in length.

share|improve this answer
Excel will not accept data other than powers of 2 in length. If I can do FFT otherwise (using some king of macro in Excel) whereby all the 1253 points can be processed that would be much preferable that using the FFT Excel add-in. – ganzewoort Jan 10 '12 at 8:37
correction: ... kind of macro ... much preferable than using ... – ganzewoort Jan 10 '12 at 8:48

Here is a PSD plot as generated by Octave (MATLAB clone) using all 1253 of your data points:

> t = load('sample.txt');
> m = mean(t)
m = -13.679
> periodogram(t,[],'onesided',1253,1e9)


As you can see, there is a large DC component and the non-DC components just look like a typical noise floor with no obvious peaks. My guess is that you'll need to collect more data if you suspect that there really are peaks buried in the noise - you may then be able to extract these using time averaging or ensemble averaging.

Here are just the first ten points of the PSD:

> Pxx = periodogram(t,[],'onesided',1253,1e9);
> plot(10*log10(Pxx(1:10)))

plot (10*log10(Pxx(1:10)))

share|improve this answer
Could you plot only the first ten bins? – ganzewoort Jan 10 '12 at 13:41
No problem - added to answer above (note that for this second plot the X axis is bin number (1-based) rather than frequency) – Paul R Jan 10 '12 at 13:52
It appears that at least the offset peak (at 0Hz) and the fundamental (~800kHz) are seen clearly. One may consider even the second harmonic (third bin) to be above the noise floor. This is all there is to it. No other peaks are expected to be seen at higher frequencies, if I understand the graph correctly. – ganzewoort Jan 10 '12 at 14:00
Seems like this one: is the closest to what you have presented. How are the dB values calculated from the moduli? – ganzewoort Jan 10 '12 at 14:07
The dB values are just the usual 10*log10 (see Octave code above). If you are expecting your peaks to lie within these first few bins then you probably need to either collect more data (at least 10x more points) or low pass filter and downsample (decimate) and get more resolution that way. – Paul R Jan 10 '12 at 14:17

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