0.3 Dsp laboratory: aliasing  (Page 2/2)

• To really see the effects of aliasing, change the input signal to a square wave (square [2]on the function generator) and sweep from 100 Hz. to 50 kHz (keeping the sampling frequency at8000 Hz.). Carefully examine the frequency-domain graph as you sweep the signal through its frequency ranges.

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6711 dsk instructions:

We will now look at aliasing and the operation of the anti-aliasing filter on the DSP board. As youknow, aliasing exists whenever signal frequencies greater than Fs/2 are sampled using a sampling frequency of Fs. To eliminatealiasing, most sound cards and DSP boards have some sort of built-in analog anti-aliasing filter that removes all input signalsgreater than a certain frequency prior to sampling. It is important to remember that anti-aliasing filters must do the filtering priorto sampling–otherwise, the high-frequency signals would have already aliased to lower frequencies by the samplingprocess.

Some boards (and most Soundcards) have anti-aliasing filters with variable cutoff frequencies that removeall frequencies>Fs/2. As Fs changes, the cutoff frequency of the anti-aliasing filter changes as well. If a board has a variablefrequency anti-aliasing filter that is always set to Fs/2, there will never be aliasing (at least in theory). Although this type ofoperation is ideal from a performance point of view, it doesn’t allow the user to examine the effect of aliasing. Fortunately forus, our particular DSP board (or more precisely, the Audio Daughter Card attached to the DSP board) has a fixed-frequency anti-aliasingfilter with a cutoff frequency of 24 kHz. If Fs = 48 kHz, this filter will prevent aliasing completely. However, if Fs is chosento be some value<48 kHz, the anti-aliasing filter won’t remove all frequencies>Fs/2, so some aliasing will result. The fact that our anti-aliasing filter is fixed rather than variable allowsus to examine what happens when we have aliasing. We will examine this now.

• Set the sampling frequency to 48000 Hz (in both the Analog Input and Analog Output nodes).
• Set the function generator to a 0.2 V, 100 Hz, sinusoid. Move thearrows on the function generator so that the hundreds-digit on the frequency display is flashing.
• You can now easily increase the frequency in steps of 100 Hz. by pressing thebuttons.
• Run the program and observe the frequency display, time display, and sound as you sweep the signal frequencyfrom 100 Hz. to 50 kHz.
• Pay particular attention to the amplitude and sound of the reconstructed signal for input frequencies>24 kHz.

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• Repeat the experiment above, but set the sampling frequency to Fs = 8000 Hz. Here, pay special attention to what happens onceyou get above 4 kHz and again once you get above 24 kHz.

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• To really see the effects of aliasing, change the input signal to a square wave (square [2]on the function generator) and sweep from 100 Hz. to 50 kHz. (keeping the sampling frequency at8000 Hz.). Carefully examine the frequency-domain graph as you sweep the signal through its frequency ranges.

Answer these questions

Conclusion

When you are done with each lab, exit LabVIEW, log off the computer, turn off the function generator andthe headphone volume booster, and unplug the DSP board from the A/C adapter. Turn in Answered Questions to the TA.