3
$\begingroup$

I constructed the flow graph in GNUradio 3.7 as below:
GNUradio flow with a sine input and frequency sink

I know a sine wave has only one frequency, so what causes the frequency sink to show two peaks?

Frequency domain graph with two peaks

$\endgroup$
4
  • $\begingroup$ Because it seems that your sinusoid has a DC component. Where did it acquire an offset? $\endgroup$ Sep 2 at 9:25
  • 1
    $\begingroup$ @RodrigodeAzevedo - by the x-axis labels, the displayed resultant frequency is 4kHz, not the nominal 2kHz indicated on the left of the block diagram. But, I know nothing about GnuRadio... $\endgroup$
    – Jon Custer
    Sep 2 at 13:24
  • 1
    $\begingroup$ dsp.stackexchange.com/questions/tagged/gnuradio $\endgroup$ Sep 2 at 13:29
  • 2
    $\begingroup$ @RodrigodeAzevedo It's not a DC offset, it's the -2kHz component but mislabeled because the center frequency parameter is wrong. $\endgroup$ Sep 2 at 13:50
6
$\begingroup$

Because mathematically, a function like $\sin(\omega t)$ has an angular frequency of $\omega$ and $-\omega$. Consider:

$$ e^{i\omega t} + e^{-i\omega t} $$

By Euler's formula this can be expanded to:

$$ \cos(\omega t)+i\sin(\omega t) + \cos(-\omega t)+i\sin(-\omega t) $$

By the trig identity $\sin(x) + \sin(-x) = 0$ this simplifies to:

$$ \cos(\omega t)+ \cos(-\omega t) $$

And because $\cos(-x) = \cos(x)$ it further simplifies to:

$$ e^{i\omega t} + e^{-i\omega t} = 2 \cos (\omega t) $$

Now, what does the GUI frequency sink do? It calculates the discrete Fourier transform, which essentially asks, "how much does this signal look like $e^{i\omega t}$?" for every frequency ($\omega$) from -0.5 cycles per sample to 0.5 cycles per sample.

Finally, it draws a scale on the bottom of the chart based only on what you've entered in the "bandwidth" and "center frequency" parameters which have nothing to do with the frequency unless you enter the correct parameters here. In your case you've entered 2k for the center frequency, which is incorrect. You haven't done anything in the flow graph to shift the frequency up or down, so the center frequency should remain at 0.

With the correct center frequency configured in the GUI sink, it would be telling you there's a peak at -2kHz and 2kHz, which is correct.

Why? Because your input signal is a real function: there are no imaginary numbers. The only way to cancel the $i$ in Euler's formula is for every positive frequency to have a negative frequency of equal amplitude and phase. Therefore, the discrete Fourier transform (what's shown on the GUI sink) will be a mirror image for any real function.

Because of this, for a real function the negative half of the discrete Fourier transform doesn't really tell you anything. It's a common enough case that within the setting for the GUI sink there's an option to hide it.

$\endgroup$
2
  • $\begingroup$ Pls allow me ask further.What 's the difference between real sine function and complex sine function?In real radio world,do we have real sine signal? $\endgroup$
    – kittygirl
    Sep 2 at 19:50
  • $\begingroup$ @kittygirl the difference is $\sin(\omega t)$ vs $e^{i\omega t}$. In the analog world, if a signal is just 1 voltage then it must be a real function. But it's also possible to represent a complex function as an analog system with two voltages, as in an IQ mixer. $\endgroup$ Sep 2 at 21:32
0
$\begingroup$

The output of the FFT you used is complex. When you input a strictly real signal to a FFT that produces a complex result, half of the complex result is the complex conjugate of the other half (this gets rid of all the unwanted imaginary components, when everything is summed up), mirrored.

When you display only the magnitudes in an FFT plot, a complex conjugate mirrored pair looks like two copies of your signal (each side with half the amplitude).

You also specified a shift of 2k in your FFT sink, by specifying a center frequency of other than zero. Why? I don't know. But it makes all the X axis labels off by 2k.

$\endgroup$
1
  • $\begingroup$ I treat center frequency as peak frequency,then specifying a center frequency of other than zero.I will keep in mind keep center frequency zero. Is there any counter example need to specifying a center frequency of other than zero? $\endgroup$
    – kittygirl
    Sep 2 at 19:34

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.