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Hi Tom,<br />
the simplest way to build an radio antenna, a lot of people do not<br />
really know is use a light bulb and a colored sheet of plastic.<br />
<br />
Basically, take your source of audio waves you want want to send, for<br />
example from a microphone, even better one, would be the sound card<br />
output of your computer. Connect the source to the light bulb and put<br />
a colored sheet of plastic over it. Sometimes, it is better to use a<br />
red LED, for this sort of stuff.<br />
<br />
The color of the plastic is the carrier frequency and your signal will<br />
be the modulated signal. And roughly speaking you have a built a<br />
narrow band FM modulator. So, roughly, you have also built a<br />
heterodyning device.<br />
<br />
In fact, this simple device can also help students picture how radio<br />
waves really work.<br />
<br />
Make a sine audio wave using ur computer that is about 40 hz(small<br />
enough so the you can see as it happen, and large enough, not to be<br />
cut off). Now, take the audio output of your computer and connect it<br />
to a light blub covered with a colored sheet of plastic or even<br />
better, an LED. Now, Plot the wave on the screen. And now, play it to<br />
the sound card output, which is connected to the light blub. The<br />
frequency of fickering of the light blub is match the one the students<br />
see on the screen. Sometimes, it is use Audio tools(from<br />
[[SoundForge]].net) that show how these events happen synchroneously.<br />
<br />
Sometimes, it better to replace the source of the light blub with a<br />
switch connected to the voltage source. If you periodically turn the<br />
switch off and on, the light blub will behave as the switch tell it to<br />
behave. Even though the switching happens at one frequency, the light<br />
blub internally also contains a color component that has a frequency<br />
of its own.<br />
<br />
You can also show students the purpose of modulation. You have take<br />
another computer, take a light blub and wrap it in another color, blue<br />
for example. Now, you can show them how, you can simulateously<br />
modulated another signal, by band shifting it to the blue specturm<br />
without it interfering with the infrared one.<br />
<br />
To be more effective, you can play the 2 audio signals simulateously<br />
using the speaker. And show your students that without band shifting<br />
the singals, the signals will interfere and contribute to noise.<br />
-------------------------<br />
<br />
To be more fun, you could build an evenlope detector using a<br />
photoelectric diode. Fiber optic cables are useful, in this case<br />
because they can transfer signals, from one end to another,without<br />
degrading the intensity of the signal. Now, take that demodulated<br />
signal from the evenlope detector, connect it to the microphone input<br />
of another computer and play it there. I should warn you that you<br />
cannot use an envelope detector to successfully disentangle modulated<br />
signals with different carriers, unless you use a filter. One way to<br />
build a simpe filter would be once again, a sheet of plastic of a<br />
certain color. Once can you could use the math sinAsinB = 0.5(cos(A -<br />
B) + cos(A+B)) to explain why the filter works.<br />
<br />
And if you want to even more fun, you can make ur students build a<br />
low baud wireless network between 2 computers. MATLAB will be of great<br />
use to you for these sort of things. MATLAB comes with sndrec(sound<br />
recorder function) and play( sound play function). It can also read<br />
and save files locally. May be, you can motivate your students to send<br />
messages between 2 computers, using these techique. :-)<br />
<br />
Ofcourse, i randomly ended up (re-) discovering these things when i<br />
was trying to build a no cost random number generator which can<br />
reproduce results of PEAR PSI experiments. Although i never succeeded<br />
with reproducing PEAR PSI results, i did have a lot of fun, in between<br />
;-)<br />
<br />
-suresh<br />
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