Amplitude modulation - why is ωc ωm necessary?

In summary, amplitude modulation requires that the carrier frequency be higher than the modulating frequency so that sidebands are not created that would be difficult for a simple demodulator to understand.
  • #1
karakov
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amplitude modulation -- why is ωc >> ωm necessary?

i just want to ask why is ωc >> ωm is necessary for a good amplitude modulation
 
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  • #2
karakov said:
i just want to ask why is ωc >> ωm is necessary for a good amplitude modulation

Welcome to the PF.

Where have you seen that condition referred to (textbook/web page/lecture notes/etc.)? Is it discussed there?
 
  • #3
we admit that condition . but why??
 
  • #4
karakov said:
we admit that condition . but why??

What do you mean? You use that condition in some calculations? Can you show us the calculations?
 
  • #5
i have in a lesson about amplitude modulation :
technically to have a good modulation .two conditions should be considered : M< 1 and ωc >> ωm (at least ten times )
 
  • #6
karakov said:
i have in a lesson about amplitude modulation :
technically to have a good modulation .two conditions should be considered : M< 1 and ωc >> ωm (at least ten times )

Correct. Can you see why M < 1 is necessary to avoid distortion of the modulating waveform that rides on the carrier waveform? There are good pictures that you can find with a Google Images search on Amplitude Modulation.

The requirement that ωc >> ωm is a little more subtle. Think about what the modulated carrier looks like when ωm gets close to ωc. What happens if they are equal?
 
  • #7
it is going to lead to distortion of the modulating waveform ?!
 
  • #8
karakov said:
it is going to lead to distortion of the modulating waveform ?!

Yes, when you try to demodulate it with a simple rectifier, the recovered signal will be distorted compared to the original modulating signal. With a little Google searching, you may be able to find a graphical waveform calculator to show the distortion as the two frequencies get too close...
 
  • #9
I really can't find wavesform calculator .so tell me what happens ?
 
  • #10
karakov said:
I really can't find wavesform calculator .so tell me what happens ?

You didn't look for very long...
 
  • #11
ok whatever just tell me what happens ?? please.
 
  • #12
karakov said:
ok whatever just tell me what happens ?? please.

No, this is your schoolwork, and you should be able to figure this out. Especially if it is part of an assignment, we can give you hints, but we are not allowed to do your work for you.
 
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  • #13
karakov said:
i just want to ask why is ωc >> ωm is necessary for a good amplitude modulation

It depends on what you mean by "good".

You can AM 'anything onto anything', in fact; the formula still applies. This question is both theoretical and practical, I think. If the modulating frequency is higher than that of the carrier, where would the sidebands turn up? What sort of sense would a simple demodulator make of that? (You might be familiar with the subject of Sampling and aliasing, which is along the same lines)
A practical consideration, (and practical ones are sometimes difficult to find in textbooks) is that it is difficult to ensure that the usable pass band of a channel will be better than, say 10% of the carrier frequency. If the frequency response of the channel is asymmetrical then what will happen to the sidebands? (Amplitude response is the easy one to consider but Phase response will also be relevant)
These comments should be enough to help you come up with a reasonable answer to your question. I suggest you should do some thinking about the problem before putting values into a calculator. A calculator doesn't tell you anything about why things happen but some sketches of the spectrum could give you some serious insight here..
 

1. What is amplitude modulation and why is it necessary?

Amplitude modulation is a method of transmitting information by varying the amplitude of a carrier wave. It is necessary because it allows for the transmission of analog signals, such as sound or video, over long distances.

2. What is ωc and ωm in amplitude modulation?

ωc represents the carrier frequency, which is the frequency of the electromagnetic wave that carries the information. ωm represents the modulating frequency, which is the frequency of the signal being transmitted.

3. Why is it important for ωc to be greater than ωm in amplitude modulation?

Having ωc greater than ωm ensures that the modulated signal can be easily separated from the carrier wave at the receiving end. This allows for the accurate reproduction of the original signal.

4. How does amplitude modulation work?

In amplitude modulation, the amplitude of the carrier wave is varied in proportion to the amplitude of the modulating signal. This results in an altered carrier wave with the information embedded in it, which is then transmitted to the receiver.

5. What are some advantages of using amplitude modulation?

Amplitude modulation allows for the transmission of analog signals, which can accurately reproduce the original signal. It also has a wider bandwidth compared to other modulation techniques, allowing for the transmission of more information. Additionally, amplitude modulation is relatively easy and inexpensive to implement.

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