FFT of a Zero-Padded Sinusoid
FFT of a Simple Sinusoid
Spectrum Analysis of a Sinusoid
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Now let's increase the frequency in the above example by one-half of a bin:
% Example 2 = Example 1 with frequency between bins f = 0.25 + 0.5/N; % Move frequency up 1/2 bin x = cos(2*pi*n*f*T); % Signal to analyze X = fft(x); % Spectrum ... % See Example 1 for plots and such
The resulting magnitude spectrum is shown in Fig. 8.2b and c. At this frequency, we get extensive ``spectral leakage'' into all the bins. To get an idea of where this is coming from, let's look at the periodic extension of the time waveform:
. a) Time waveform. b) Magnitude spectrum. c) ![\includegraphics[width=\textwidth]{eps/example2.eps}](img1223.png)
% Plot the periodic extension of the time-domain signal
plot([x,x],'--ok');
title('Time Waveform Repeated Once');
xlabel('Time (samples)'); ylabel('Amplitude');
The result is shown in Fig. 8.3. Note the ``glitch'' in the
middle where the signal begins its forced repetition.
![\includegraphics[width=\textwidth,height=2in]{eps/waveform2.eps}](img1224.png) |
FFT of a Zero-Padded Sinusoid
FFT of a Simple Sinusoid
Spectrum Analysis of a Sinusoid
Index
Search
