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[[Image:p1010006.JPG|thumb|Aric Goe]]
[[Image:p1010006.JPG|thumb|Aric Goe]]
== Signals & Systems ==
== Signals & Systems ==
*[[Signals and systems|Signals and Systems]]

=== Introduction ===
=== Introduction ===

[http://www.myspace.com/goemaster Aric's Homepage (Updated 10.01.07)],

==== Becoming familiar with Wiki ====
==== Becoming familiar with Wiki ====
Well, it all seems a little too convenitent to me.
Well, it all seems a little too convenient to me.


====Practicing TEX====
====Practicing TEX====
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:<math>\frac{Ep}{Tp} = \frac{Es}{Ts}</math>
:<math>\frac{Ep}{Tp} = \frac{Es}{Ts}</math>


=== How a CD Player Works ===
== How a CD Player Works ==




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First, a digital signal <math>x(kt)</math> is read from the CD adn then convolved with a pulse function <math>p(t)</math>. The result in the time domain looks like this:
First, a digital signal <math>\ x(kt) </math> is read from the CD and then convolved with a pulse function <math>\ p(t) </math> in the D/A converter. The result in the time domain looks like this:




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Let's look at this is frequency space. Note that convolution in time means multiplication in frequency.
Let's look at this result in frequency space. Note that convolution in time means multiplication in frequency.




<center>
<center>
[[Image:DAfreqout.jpg|Description]]
<math>\hat X(f) = 1/T \sum_{n=-\infty}^\infty X(f - n/T) \cdot P(f)</math>


<math>\hat X(f) = \frac{1}{T} \sum_{n=-\infty}^\infty X(f - \frac{n}{T}) \cdot P(f)</math>
</center>
</center>
where
where
<center>
<center>
<math>P(f) = \int_{-T/2}^{T/2} e^{j2\pi ft} \, dt = T sinc(fT)
<math>P(f) = \int_{-\frac{T}{2}}^{\frac{T}{2}} e^{j2\pi ft} \, dt = T sinc(fT)
</math>
</math>
</center>
</center>


The low pass filter then knocks the high frequencies out of the signal to be sent to the speaker.
The low pass filter then knocks the high frequencies out of the signal coming from the D/A converter, which smoothes out the edges of the reproduced sine wave <math>\hat x(t)</math> in time. This output waveform then drives the speaker, thereby recreating the original sound stored on the CD.

Contributing Authors:

[[User:caswto|Todd Caswell]]

[[User:goeari|Aric Goe]]

Latest revision as of 22:26, 1 October 2007

Aric Goe

Signals & Systems

Introduction

Aric's Homepage (Updated 10.01.07),

Becoming familiar with Wiki

Well, it all seems a little too convenient to me.

Practicing TEX

Simple Transformer Equation

How a CD Player Works

Description


First, a digital signal is read from the CD and then convolved with a pulse function in the D/A converter. The result in the time domain looks like this:


Description


Let's look at this result in frequency space. Note that convolution in time means multiplication in frequency.


Description


where

The low pass filter then knocks the high frequencies out of the signal coming from the D/A converter, which smoothes out the edges of the reproduced sine wave in time. This output waveform then drives the speaker, thereby recreating the original sound stored on the CD.

Contributing Authors:

Todd Caswell

Aric Goe