Why do you get sideband frequencies for amplitude modulation (AM)?

In summary, the AM carrier frequency is constant but the modulation signal can change. When modulating the carrier frequency with a pure sine wave, the resulting AM waveform can be viewed as a product of two sine waves or as a sum of three sine waves: the carrier and two side bands. This is due to the non-linear nature of AM mixing, which can be simplified using trigonometry. The side bands exist during transmission and are necessary for the signal to be properly transmitted and received. They can be observed using spectrum analysis and are a result of the modulation process, where the average energy over a period of time can make it seem like there are distinct frequencies with related phases.
  • #1
CraigH
222
1
I thought that the frequency was constant for AM modulation, and just the amplitude was modulated. So why are there a range of frequency's (side bands around the baseband) when the signal is plotted on a frequency domain graph?
 
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  • #2


The AM carrier frequency is constant but the modulation signal can change.

If you look at the case of modulating the AM carrier frequency (a sine wave) with a pure sine wave, the resulting AM waveform is close to what you would get if you multiplied the two sine waves. AM mixing is like multiplication. In the realm of trigonometry, the product of two sine waves can be simplified to the sum of three pure sine waves: The carrier and two side bands. So if you multiply two sine waves (carrier and modulation), you get the same result as adding three sine waves (carrier and two side band sine waves). That result, the AM waveform, can be viewed in two different ways:through mixing (multiplication) or as a sum of three sine wave (which is the frequency domain way of looking at things).
 
  • #3


kevlat said:
The AM carrier frequency is constant but the modulation signal can change.

If you look at the case of modulating the AM carrier frequency (a sine wave) with a pure sine wave, the resulting AM waveform is close to what you would get if you multiplied the two sine waves. AM mixing is like multiplication. In the realm of trigonometry, the product of two sine waves can be simplified to the sum of three pure sine waves: The carrier and two side bands. So if you multiply two sine waves (carrier and modulation), you get the same result as adding three sine waves (carrier and two side band sine waves). That result, the AM waveform, can be viewed in two different ways:through mixing (multiplication) or as a sum of three sine wave (which is the frequency domain way of looking at things).

I'd like to amend that. Trig can be used to simplify the product of two sine waves to a sum of the carrier and two sidebands. The sidebands are really cosines, which are phase-shifted sines.
 
  • #4


Craig,
As kevlat indicates, the sidebands fall out of the trig. However, you are right in that it seems counterintuitive at first. In order to get a sense of where the other frequencies come from consider that the amplitude modulation is in the form of periodic instantaneous shifts in amplitude. Say we have a 1MHz RF carrier 1Vpeak. It periodically shifts in amplitude to 100Vpeak, and the shift occurs at the crest of the sine wave. So we have a 1MHz sinusoidal signal that at some point reaches 1V and shifts instantaneously to 100V then continues on as a sinusoid. That vertical 1V to 100V step in voltage is where the non-1MHz frequency components are introduced. We will create the same frequencies that you would get from a square wave with instantaneous edges.
 
  • #5


A good rule to remember is that you cannot do ANYTHING to a sine wave without creating new frequencies.
 
  • #6


See

The product of a small amplitude modulation on a carrier can be represented by [itex] \left(1+A\cos\omega_1t \right)\cos\omega_2t [/itex]. This can be rewritten as
[tex] \left(1+A\cos\omega_2t \right)\cos\omega_1t=\cos\omega_1t +A\cos\omega_2t\cos\omega_1t =\cos\omega_1t + \frac{A}{2} \cos\left(\omega_1-\omega_2 \right)t+\frac{A}{2} \cos\left(\omega_1+\omega_2 \right)t [/tex]
So the AM modulation produces sum and difference sidebands at any amplitude modulation frequency.
 
  • #7
Hi, I'm new to the forum and also to the topic and so pardon me for maybe not doing the proper protocol. I have a follow-up related question. Do the sidebands frequencies exist during transmission? I mean does the transmitter actually transmits three signals at a time, the lower, upper and the carrier?
 
  • #8
jettenazas said:
Hi, I'm new to the forum and also to the topic and so pardon me for maybe not doing the proper protocol. I have a follow-up related question. Do the sidebands frequencies exist during transmission? I mean does the transmitter actually transmits three signals at a time, the lower, upper and the carrier?
Absolutely. The sidebands are part of the signal. If you pass the AM signal through a very narrow band-pass filter, you will just see the carrier and there will be no modulation on it. A.M. transmitters need to be designed with enough bandwidth to accommodate the carrier and all the sidebands (+and- the highest audio frequency about the carrier). The spectrum when a real audio programme signal is transmitted looks like a single carrier frequency with sidebands, each of which look like the audio signal spectrum. (Mirror images, aamof).

The process of Modulation is Non Linear - it's a sort of Multiplication - and it produces those extra frequency components (if you choose to think of it in the frequency domain). In the time domain, it looks like a carrier with a varying amplitude (the 'envelope'). That's the 'scope picture, where the frequency domain is the Spectrum Analyser picture of the same signal. Mentally hopping between time and frequency domains can be very handy.
 
  • #9
This is my weird intuitive view, and can't stand up to any rigorous scrutiny. (be gentle, folks)

When you measure the spectrum of a modulated sinewave you are measuring the average energy over a period of time. That makes it look like there are three distinct frequencies with related phases. Well, there are 3 distinct frequencies by any measurement methods, but if you could track instantaneous frequency (a debatable concept) you would sort of see a continuum of frequencies. But the energy between sidebands sort of cancels out when you average over an interval.

Think of a sinewave. If you lower the amplitude, there is a frequency/phase discontinuity that occurs. That is, there has to be a transition that isn't exactly a sinewave. That is, or results in, "spurious" energy at different frequencies.

This get more complicated when you think of FM modulation, where a continuous sweeping frequency somehow unintuitively becomes bessel sidebands.

Again, it is "sort of" an "artifact" of the measurement method caused by the fact that it is an average over an interval. Don't get me wrong. This average is very real and very useful.

Instantaneous frequency is tricky because a single point can't have frequency without knowledge of past and future. But, in contrast, most people don't really think about the "averaging" occurring in a spectrum analysis filter (be it FFT, DFT, Fourier based or whatever).
 
  • #12
meBigGuy said:
This is my weird intuitive view, and can't stand up to any rigorous scrutiny. (be gentle, folks)

When you measure the spectrum of a modulated sinewave you are measuring the average energy over a period of time. That makes it look like there are three distinct frequencies with related phases. Well, there are 3 distinct frequencies by any measurement methods, but if you could track instantaneous frequency (a debatable concept) you would sort of see a continuum of frequencies. But the energy between sidebands sort of cancels out when you average over an interval.

Think of a sinewave. If you lower the amplitude, there is a frequency/phase discontinuity that occurs. That is, there has to be a transition that isn't exactly a sinewave. That is, or results in, "spurious" energy at different frequencies.

This get more complicated when you think of FM modulation, where a continuous sweeping frequency somehow unintuitively becomes bessel sidebands.

Again, it is "sort of" an "artifact" of the measurement method caused by the fact that it is an average over an interval. Don't get me wrong. This average is very real and very useful.

Instantaneous frequency is tricky because a single point can't have frequency without knowledge of past and future. But, in contrast, most people don't really think about the "averaging" occurring in a spectrum analysis filter (be it FFT, DFT, Fourier based or whatever).

I think that is rather too much of a 'personal' view of things to help anyone else. You have mixed up so many concepts in your soup of buzzwords that the uninitiated will just get further confused, I'm afraid.
(I love the way that the "Bessel sidebands" just pop out of 'intuition'. They emerge from a pretty difficult bit of Fourier Transform and I don't think that's very intuitive at all)
 
  • #13
Well, your reading skills could use some honing. I absolutely did say unintuitive. And, what I am saying is actually not so far off as you seem to think. It is not a "soup of buzzwords" as you insultingly state (you do that sort of thing a lot, it seems). There is actually some real stuff there regarding instantaneous frequency that you obviously do not understand.

Think about narrowband FM and why it appears to have 2 sidebands, yet is made by a continuously sweeping VCO.
 
  • #14
meBigGuy said:
Well, your reading skills could use some honing. I absolutely did say unintuitive. And, what I am saying is actually not so far off as you seem to think. It is not a "soup of buzzwords" as you insultingly state (you do that sort of thing a lot, it seems). There is actually some real stuff there regarding instantaneous frequency that you obviously do not understand.

Think about narrowband FM and why it appears to have 2 sidebands, yet is made by a continuously sweeping VCO.

"unintuitive" -sorry about that but I was already into buzz-word fatigue before I got to it.
My problem with your post is that it contains a lot of correct words and phrases 'but not in the right order' - to quote Eric Morcambe, in his sketch with Andre Previn.

You could look at the 'Rules and Guidelines', to be found in the 'site info' at the top of this page. Greg Bernhardt makes it quite clear what the purpose of the site is and it is not to promote personal and non-standard views. Your initial post starts with an excuse for 'weird and intuitive' views and that is just what they are. I merely confirmed that. Many of the ideas in your post are, at best confusing and certainly cannot be found in mainstream textbooks (in that order).
Mr Fourier went to a lot of trouble to provide a way of relating time and frequency domains (defining them properly). You don't need to "think about" FM. You just write out the time domain formula and do the transform and you get the spectrum. We are lucky that Mr Bessel sorted out the integration for us. It may be difficult to accept that some things are not explicable by waving arms.
I do understand that "instantaneous frequency" is, in fact, an oxymoron and the term, whilst in common enough use, needs a lot of qualification before it can be used in a valid way.
 
  • #15
Good response.

I'll look around and see if I can find somthing more rigourous that addresses this. I've seen stuff in the past, but it didn't pop out when I did my search.

You are obviously quite happy not trying to understand how a sweeping frequency becomes 2 sidebands. It just is.
 
  • #16
Just two?
 
  • #17
meBigGuy said:
Good response.

I'll look around and see if I can find somthing more rigourous that addresses this. I've seen stuff in the past, but it didn't pop out when I did my search.

You are obviously quite happy not trying to understand how a sweeping frequency becomes 2 sidebands. It just is.
When I first studied forms of modulation, I read a few textbooks and they treated it formally, obtaining expressions for the spectra in each case and describing methods of achieving the various types. It all made perfect sense, except for how the Bessel Function was actually derived and I left it to Mr Bessel. I really don't see how there would be any rigorous way of describing time and frequency domain models and the mechanics of moving from one to the other in a valid way (windowing etc.), if you don't use the Maths. Without the maths it's just a 'black box'. That's fine as long as you don't try to discuss the workings inside as if you understand it and then try to tell someone else the personal theory. That was the reason I was a tad grumpy about your first post.

Anything you need to 'explain' all this to me is available in a dozen well know books on communications theory and signal analysis. Google tends to throw up a lot of less rigorous stuff - which is why PF can be a bit huffy about what's available on the Web.
 
  • #18
sophiecentaur said:
Mr Fourier went to a lot of trouble to provide a way of relating time and frequency domains (defining them properly). You don't need to "think about" FM. You just write out the time domain formula and do the transform and you get the spectrum. We are lucky that Mr Bessel sorted out the integration for us. It may be difficult to accept that some things are not explicable by waving arms.

So what you saying is "just write down this formula and accept it and shut-up!" That would be like telling a child to accept "2+2=4" without ever actually showing them with blocks. A math formula can ALWAYS be explained by other means as it is a language describing something observed.

meBigGuy actually provided a very good visual of what is actually going on. I've always had trouble understanding why AM produced sidebands, and accepting the math just wasn't cutting it. I'm a visual person. This quote right here:
meBigGuy said:
Think of a sinewave. If you lower the amplitude, there is a frequency/phase discontinuity that occurs. That is, there has to be a transition that isn't exactly a sinewave. That is, or results in, "spurious" energy at different frequencies.

I absolutely loved. Very intuitive. This goes well with other explanations I've read where even spending days to increase the amplitude of a signal would still produce finite sidebands.


As for the "soup of buzzwords" jab, I fail to see what you're talking about. Thanks meBigGuy, very simple and to the point.
 
  • #19
Logicwax said:
So what you saying is "just write down this formula and accept it and shut-up!" That would be like telling a child to accept "2+2=4" without ever actually showing them with blocks. A math formula can ALWAYS be explained by other means as it is a language describing something observed.

meBigGuy actually provided a very good visual of what is actually going on. I've always had trouble understanding why AM produced sidebands, and accepting the math just wasn't cutting it. I'm a visual person. This quote right here:


I absolutely loved. Very intuitive. This goes well with other explanations I've read where even spending days to increase the amplitude of a signal would still produce finite sidebands.


As for the "soup of buzzwords" jab, I fail to see what you're talking about. Thanks meBigGuy, very simple and to the point.

What I am saying is that you can either go through the Maths and have some certainty that your explanation is valid or wave your arms about and not be sure if you're wrong or right. You really are selling Mathematics very short if you think that the formula are just made up for the sake of it. If you can be bothered, you can go right back (further back than 2+ 2 = 4) and start Mathematical Analysis from scratch, showing that 2 blocks plus 2 blocks has the same qualities about it as 2 elephants plus 2 elephants and that involves the 'twoness' of the number 2. Your small child would not be too surprised if 2+2 = 4 only worked for certain items and not for others. I could even say that you, logicwax, could not be sure that somewhere there is a something for which 2+2=4 doesn't actually apply - until you have gone through (or at least acknowledge the validity of) the serious Maths behind it.
"Stands to reason", I hear you cry. But does it? That's what the Mathematicians are there to help us with.

If you are prepare to accept a convincing sounding 'visual' argument about Amplitude Modulation then you should be very careful about listening to politicians and salesmen. They will give you the same cosy feeling of understanding about what they are selling, too.

That explanation you were so happy with contained a load of concepts that were just not strictly defined and were used inconsistently. What was mean by frequency, phase and discontinuity, for a start? Those words appeared in the same sentence bu what did it actually mean?

There are many ways of describing complicated processes and one's personal view (we all have them) about what is 'really happening' is strictly personal. The danger is when someone gives a personal view and assumes that it is an valid explanation, good enough for someone else. If one starts with undefined terms then arranging them in any sort of order gives a message with no defined meaning. Demanding a 'physical explanation' for something as abstract as Communications theory is to ask to be misled. Just because it 'feels' right doesn't mean it 'is' right. The Maths, scrupulously derived from the very basics, is the only way to give any certainty about it.

No one is in a position to 'demand' a version of Science that doesn't involve Maths, if they want to approach a reasonable understanding. Fair enough, one can enjoy lots of things about Science without 'having the Maths', but that implies a strict limit on the depth of understanding and the need just to accept a lot of things as read. The interrelationships between the quantities are just too complicated to describe in ordinary language. Why not accept that?
 
  • #20
Thanks Logicwax.

I have never said or implied that the math isn't the final word in all modeling. As long as you understand what you are modeling and what assumptions you are making.

sophie represents his point of view well.
 
  • #21
meBigGuy said:
Thanks Logicwax.

I have never said or implied that the math isn't the final word in all modeling. As long as you understand what you are modeling and what assumptions you are making.

sophie represents his point of view well.

Ah well - that is my point. What do you understand about the arm waving model? It is all based on a Mathematical premise, in the first place. All the terms that (arm waving) people use, to describe waves, are Maths based so how can you rely on any non- maths based conclusion the arm waving model will deliver?

After the result has been delivered by the Maths, then I see no problem with rationalising it in tangible terms and getting a feel for it. We all must do that. But it's definitely a step too far to 'demand' a valid explanation that's based solely on a mechanical interpretation.

But here's the clincher - ask around. How many people who actually 'have the Maths' would not rely on (and believe) the mathematical version as against the arm waving one? Or would the answer be that they've all been indoctrinated? haha
 
  • #22
How can amplitude modulation create sideband frequencies? It may be easier to develop an intuitive feel for this by considering the inverse: How does summing sideband frequencies to a pure carrier create amplitude modulation?

I have attached a spreadsheet that contains a carrier, two sidebands, and their sum (which is amplitude modulated).

The relative amplitudes and offsets of the sidebands can be modified, and the sum shows their effect on the modulation frequency and index.

If you zoom in on the graph, looking at just a couple cycles, you can see how the sidebands conspire to pull the amplitude of the carrier.

Enjoy
 

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Likes Joe the crow and cheah10
  • #23
That's a very savvy reply, to use synthesis instead of analysis makes perfect sense.
 
  • #24
cool spreadsheet. Like it a lot
 
  • #25
OK, why the heck can I not view that spreadsheet ??

I click or right click on it and it comes up as " attachment.php" instead of am.xlsx

and asks me to find a prog on the www to open it

Dave
 
  • #26
Notice that the link is to attachment.php.

I would guess it has to do with the xlsx association in your browser or OS. Can you open the non-xlsx attachments here? (I assume you can)
https://www.physicsforums.com/showthread.php?t=660622#post4208575

Can you view other excel xlsx documents (do you have office, or some other xlsx viewer)
 
  • #27
sophiecentaur said:
What I am saying is that you can either go through the Maths and have some certainty that your explanation is valid or wave your arms about and not be sure if you're wrong or right.
An explanation can be mathematically correct, yet concentrate on conveying an intuition rather than regurgitating some math that may be opaque to the audience. There's nothing wrong with that.
 
  • #28
meBigGuy said:
Notice that the link is to attachment.php.

I would guess it has to do with the xlsx association in your browser or OS. Can you open the non-xlsx attachments here? (I assume you can)
https://www.physicsforums.com/showthread.php?t=660622#post4208575

Can you view other excel xlsx documents (do you have office, or some other xlsx viewer)

Hi
thanks for responding

Notice that the link is to attachment.php ---- yup, so where is the xlsx file ?

no problems with opening other forum attachments, pdf's, txt, png, or other image files

yup definitely have office with XL on the puter, it gets used every day here at work

cheers
Dave
 
  • #30
olivermsun said:
An explanation can be mathematically correct, yet concentrate on conveying an intuition rather than regurgitating some math that may be opaque to the audience. There's nothing wrong with that.

There is no doubt that I committed some arm waving. But, there is also no doubt that there is validity to the concept of the derivitive of phase (instantaneous frequency), and that Fourier transforms average energy over a time interval. Most people don't think about the averaging (or summing, if you will). The very mathematical operation of a Fourier transform consists of aliasing each sample to "dc" and summing it for every frequency bin. Multiply each time domain sample by a complex exponential and sum all the results as the value for the frequency bin represented by that exponential. Do that and watch how the bins progressively sum to zero except at the carrier and the sidebands.

But the xlsx spreadsheet is awsome. Hard to reconcile both both worlds.
 
  • #31
@davenn

I reposted spreadsheet as .zip.
 

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  • #32
olivermsun said:
An explanation can be mathematically correct, yet concentrate on conveying an intuition rather than regurgitating some math that may be opaque to the audience. There's nothing wrong with that.

Nothing wrong, in principle, but just how far do you expect to take it? Even the 'explanation' that involves minimal maths will still be opaque to some of the audience (do you assume they know what a sine wave is?). My problem with this approach is that it implies that the Subject has to be subservient to the Learner. Whether you're beginning to walk, read or to understand communication theory, there are certain new things that you have to take on board and just learn. It's a giving process, just as much as a taking process. The tail does not wag the dog here.
TV Science presenters would give us all the impression that Science is nothing but Fun and Animations. It isn't; anyone who wants to get there needs do have done some graft.
 
  • #33
sophiecentaur said:
Nothing wrong, in principle, but just how far do you expect to take it? Even the 'explanation' that involves minimal maths will still be opaque to some of the audience (do you assume they know what a sine wave is?).
I'm willing to make that assumption given that the OP was asking about "sidebands" and "frequencies" and "amplitude." If it turns out the audience is confused, then we can always back up.

My problem with this approach is that it implies that the Subject has to be subservient to the Learner.
Trying to connect a Subject to concepts a Learner might grasp isn't some kind of some kind of subordination. It's an attempt to communicate.
 
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  • #34
olivermsun said:
I'm willing to make that assumption given that the OP was asking about "sidebands" and "frequencies" and "amplitude." If it turns out the audience is confused, then we can always back up.


The Subject doesn't care what we think about it, but sometimes teaching the Subject does require some concessions to the Learner.


Gets where?

So they have already started down the Maths road. But they have drawn a line and said "no further" but they still want an answer? Isn't that asking a bit much? Shouldn't they realize that?

And some concessions from the learner in the form of preparedness to use a common language of description. I am sure you are not rejecting the Maths but are you saying its only an 'option'?

Gets to an improved (valid) understanding.
 
  • #35
talk about arm waving ---- LOL ---- ironic
 
<h2>1. Why do you get sideband frequencies for amplitude modulation (AM)?</h2><p>Sideband frequencies are a result of the process of amplitude modulation, where the amplitude of a carrier wave is varied in proportion to the amplitude of the modulating signal. This variation creates new frequencies, known as sidebands, that are located above and below the carrier frequency.</p><h2>2. How are sideband frequencies calculated in AM?</h2><p>The sideband frequencies in AM are calculated using the formula fc ± fm, where fc is the carrier frequency and fm is the modulating frequency. The plus sign represents the upper sideband (USB) and the minus sign represents the lower sideband (LSB).</p><h2>3. What is the purpose of sideband frequencies in AM?</h2><p>The sideband frequencies in AM contain the information that is being transmitted. They allow for the modulation of the carrier wave, which carries the signal, without altering the original frequency. This makes it possible to transmit multiple signals at different frequencies simultaneously.</p><h2>4. Can sideband frequencies be eliminated in AM?</h2><p>No, it is not possible to completely eliminate sideband frequencies in AM. However, techniques such as single sideband (SSB) modulation can be used to suppress one of the sidebands, resulting in a more efficient use of the transmission bandwidth.</p><h2>5. Are sideband frequencies present in other types of modulation?</h2><p>Yes, sideband frequencies can also be found in other types of modulation, such as frequency modulation (FM) and phase modulation (PM). However, the sideband frequencies in these types of modulation are not as prominent as in AM, as the carrier wave is not directly affected by the modulating signal.</p>

1. Why do you get sideband frequencies for amplitude modulation (AM)?

Sideband frequencies are a result of the process of amplitude modulation, where the amplitude of a carrier wave is varied in proportion to the amplitude of the modulating signal. This variation creates new frequencies, known as sidebands, that are located above and below the carrier frequency.

2. How are sideband frequencies calculated in AM?

The sideband frequencies in AM are calculated using the formula fc ± fm, where fc is the carrier frequency and fm is the modulating frequency. The plus sign represents the upper sideband (USB) and the minus sign represents the lower sideband (LSB).

3. What is the purpose of sideband frequencies in AM?

The sideband frequencies in AM contain the information that is being transmitted. They allow for the modulation of the carrier wave, which carries the signal, without altering the original frequency. This makes it possible to transmit multiple signals at different frequencies simultaneously.

4. Can sideband frequencies be eliminated in AM?

No, it is not possible to completely eliminate sideband frequencies in AM. However, techniques such as single sideband (SSB) modulation can be used to suppress one of the sidebands, resulting in a more efficient use of the transmission bandwidth.

5. Are sideband frequencies present in other types of modulation?

Yes, sideband frequencies can also be found in other types of modulation, such as frequency modulation (FM) and phase modulation (PM). However, the sideband frequencies in these types of modulation are not as prominent as in AM, as the carrier wave is not directly affected by the modulating signal.

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