Homework Eight: Difference between revisions

Revision as of 18:51, 8 November 2009

How does a CD player work with no oversampling, but digital filtering (1x oversampling)?

Recall that when the audio for a music CD is produced it has an infinite amount of data points which can be expressed as $x(t)$ in the time domain (Figure 1) and $X(f)$ in the frequency domain (Figure 2).

Figure 1: Audio data as a function of time, x(t)

Figure 2: Audio data as a function of frequency, X(f)

When one wants to store the data of $x(t)$ (i.e. reading the data onto a CD in this case) an infinite number of data points is not ideal -- in fact, it is impossible. Therefore, we must sample the data at the (typical) rate of $f_{s}={\frac {1}{T}}$ . This will give us a periodic function which we will call $x(nT){\mbox{, where }}n\in \mathbb {Z} {\mbox{ and }}T$ is the sampling period. It is common to allow a sampling rate of twice the frequency at which a human can hear (i.e. 2 x 22 kHz) -- that means, $f_{s}=44$ kHz.

Recall from class that in order to sample the original function, $x(nT)$ , we need to use a delta function. In other words, the continuous function of $x(nT)$ can be written as $\sum _{-\infty }^{\infty }x(nT)\delta (t-nT_{0})$ (Figure 3)

Figure 3: x(nT) written as impulses for sampling purposes

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-Recall that when the audio for a music CD is produced it has an infinite amount of data points which can be expressed as <math>x(t)</math> in the time domain and <math>X(f)</math> in the frequency domain, as follows
+Recall that when the audio for a music CD is produced it has an infinite amount of data points which can be expressed as <math>x(t)</math> in the time domain ('''Figure 1''') and <math>X(f)</math> in the frequency domain ('''Figure 2''').
-[[Image:x_continuous3.jpg |thumb|left|upright=2|Audio data as a function of time, x(t)]]
+[[Image:x_continuous3.jpg |thumb|center|upright=2|Figure 1: Audio data as a function of time, x(t)]]
-[[Image:x_frequency1b.jpg |thumb|left|upright=2|Audio data as a function of frequency, X(f)]]<br>\
+[[Image:x_frequency1b.jpg |thumb|center|upright=2|Figure 2: Audio data as a function of frequency, X(f)]]
+When one wants to store the data of <math>x(t)</math> (i.e. reading the data onto a CD in this case) an infinite number of data points is not ideal -- in fact, it is impossible. Therefore, we must sample the data at the (typical) rate of <math>f_{s} = \frac{1}{T}</math>. This will give us a periodic function which we will call <math>x(nT) \mbox{, where } n \in \mathbb{Z} \mbox{ and } T</math> is the sampling period. It is common to allow a sampling rate of twice the frequency at which a human can hear (i.e. 2 x 22 kHz) -- that means, <math>f_{s} = 44</math> kHz.<br/>
+Recall from class that in order to sample the original function, <math>x(nT)</math>, we need to use a delta function. In other words, the continuous function of <math>x(nT)</math> can be written as <math>\sum_{-\infty}^{\infty}x(nT) \delta (t-nT_{0})</math> ('''Figure 3''')
+[[Image:x_discrete_a.jpg |thumb|center|upright=2|Figure 3: x(nT) written as impulses for sampling purposes]]

Homework Eight: Difference between revisions

Revision as of 18:51, 8 November 2009

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