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#281
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AM electromagnetic waves: 20 KHz modulation frequencyonanastronomically-low carrier frequency
In article .com,
Keith Dysart wrote: On Jul 16, 11:31 am, John Fields wrote: On Sun, 15 Jul 2007 14:57:17 -0700, Keith Dysart wrote: I thought the experiment being discussed was one where the modulation was 1e5, the carrier 1e6 and the resulting spectrum .9e6, 1e6 and 1.1e6. --- That was my understanding, and is why I was surprised when you made the claim, above: "It does not matter how the .9e6, 1.0e6 and 1.1e6 are put into the resulting signal. One can multiply 1e6 by 1e5 with a DC offset, or one can add .9e6, 1.0e6 and 1.1e6. The resulting signal is identical." which I interpret to mean that three unrelated signals occupying those spectral positions were identical to three signals occupying the same spectral locations, but which were created by heterodyning. Are you now saying that wasn't your claim? --- No, that was indeed the claim. As a demonstration, I've attached a variant of your original LTspice simulation. Plot Vprod and Vsum. They are on top of each other. Plot the FFT for each. They are indistinguishable. -- lots o' snipping goin' on -- OK. I haven't been (had the patience to keep on) following this discussion, so I apologize if this is totally inappropriate, but If the statements above refer to creating that set of signals by using a bunch of signal generators, or alternately by using some sort of actual "modulation", the answer is, there is a very significant difference. In the case where the set is created by modulating the "carrier" with the low frequency, there is a very specific phase relationship between the signals which would be essentially impossible to achieve if the signals were to be generated independently. In fact, the only difference between AM and FM/PM is that the phase relationship between the carrier and the sideband set differs by 90 degrees between the two. Isaac |
#282
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AM electromagnetic waves: 20 KHz modulation frequency on an astronomically-low carrier frequency
Ron Baker, Pluralitas! wrote:
"isw" wrote: After you get done talking about modulation and sidebands, somebody might want to take a stab at explaining why, if you tune a receiver to the second harmonic (or any other harmonic) of a modulated carrier (AM or FM; makes no difference), the audio comes out sounding exactly as it does if you tune to the fundamental? That is, while the second harmonic of the carrier is twice the frequency of the fundamental, the sidebands of the second harmonic are *not* located at twice the frequencies of the sidebands of the fundamental, but rather precisely as far from the second harmonic of the carrier as they are from the fundamental. Isaac Whoa. I thought you were smoking something but my curiosity is piqued. I tried shortwave stations and heard no harmonics. But that could be blamed on propagation. There is an AM station here at 1.21 MHz that is s9+20dB. Tuned to 2.42 MHz. Nothing. Generally the lowest harmonics should be strongest. Then I remembered that many types of non-linearity favor odd harmonics. Tuned to 3.63 MHz. Holy harmonics, batman. There it was and the modulation was not multiplied! Voices sounded normal pitch. When music was played the pitch was the same on the original and the harmonic. One clue is that the effect comes and goes rather abruptly. It seems to switch in and out rather than fade in an out. Maybe the coming and going is from switching the audio material source? This is strange. If a signal is multiplied then the sidebands should be multiplied too. Maybe the carrier generator is generating a harmonic and the harmonic is also being modulated with the normal audio in the modulator. But then that signal would have to make it through the power amp and the antenna. Possible, but why would it come and go? Strange. I've once listened to the first five harmonics of a powerful medium wave transmitter (400 kW) at a distance of some 300 m. All harmonics gave normal audio; no strange switching effects (Sony ICF-7600D). What I'd like to know is if in such an 'experiment' it can be excluded that (some of) these signals are generated by the receiver itself. gr, Hein |
#283
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AM electromagnetic waves: 20 KHz modulation frequency on an astronomically-low carrier frequency
isw wrote:
"Ron Baker, Pluralitas!" wrote: Then you understand Fourier transforms and convolution. I suppose so; I've spent over fifteen years poking around in the entrails of MPEG... Ever learned, unfortunately seldom used. What can radio hobbyists do with Fourier transforms nowadays? (Nowadays, for aids and appliances like software and spectrum analysers take over some work.) If somebody could provide some examples I'd be grateful. Thanks. gr, Hein |
#284
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AM electromagnetic waves: 20 KHz modulation frequency on an astronomically-low carrier frequency
John Fields wrote:
Hein ten Horn wrote: John Fields wrote: And what does it look like, then? Roughly like the ones in your Excel(lent) plots. I've posted nothing like that, so if you have graphics which support your position I'm sure we'd all be happy to see them. Oops, I'm sorry Keith! http://keith.dysart.googlepages.com/radio5 Mathematical terms like linear, logarithmic, etc. are familiar to me, but the guys here use linear and nonlinear in another sense. Retrospectively viewed: not the term "linear". gr, Hein |
#285
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AM electromagnetic waves: 20 KHz modulation frequency on an astronomically-low carrier frequency
"Ron Baker, Pluralitas!" wrote in message ... "Hein ten Horn" wrote in message ... Ron Baker, Pluralitas! wrote: "Hein ten Horn" wrote: Ron Baker, Pluralitas! wrote: Hein ten Horn wrote: Ron Baker, Pluralitas! wrote: Hein ten Horn wrote: As a matter of fact the resulting force (the resultant) is fully determining the change of the velocity (vector) of the element. The resulting force on our element is changing at the frequency of 222 Hz, so the matter is vibrating at the one and only 222 Hz. Your idea of frequency is informal and leaves out essential aspects of how physical systems work. Nonsense. Mechanical oscillations are fully determined by forces acting on the vibrating mass. Both mass and resulting force determine the frequency. It's just a matter of applying the laws of physics. You don't know the laws of physics or how to apply them. I'm not understood. So, back to basics. Take a simple harmonic oscillation of a mass m, then x(t) = A*sin(2*pi*f*t) v(t) = d(x(t))/dt = 2*pi*f*A*cos(2*pi*f*t) a(t) = d(v(t))/dt = -(2*pi*f)^2*A*sin(2*pi*f*t) hence a(t) = -(2*pi*f)^2*x(t) Only for a single sinusoid. and, applying Newton's second law, Fres(t) = -m*(2*pi*f)^2*x(t) or f = ( -Fres(t) / m / x(t) )^0.5 / (2pi). Only for a single sinusoid. What if x(t) = sin(2pi f1 t) + sin(2pi f2 t) In the following passage I wrote "a relatively slow varying amplitude", which relates to the 4 Hz beat in the case under discussion (f1 = 220 Hz and f2 = 224 Hz) where your expression evaluates to x(t) = 2 * cos(2pi 2 t) * sin(2pi 222 t), indicating the matter is vibrating at 222 Hz. So where did you apply the laws of physics? You said, "It's just a matter of applying the laws of physics." Then you did that for the single sine case. Where is your physics calculation for the two sine case? Where is the expression for 'f' as in your first example? Put x(t) = 2 * cos(2pi 2 t) * sin(2pi 222 t) in your calculations and tell me what you get for 'f'. And how do you get 222 Hz out of cos(2pi 2 t) * sin(2pi 222 t) Why don't you say it is 2 Hz? What is your law of physics here? Always pick the bigger number? Always pick the frequency of the second term? Always pick the frequency of the sine? What is "the frequency" of cos(2pi 410 t) * cos(2pi 400 t) What is "the frequency" of cos(2pi 200 t) + cos(2pi 210 t) + cos(2pi 1200 t) + cos(2pi 1207 t) So my statements above, in which we have a relatively slow varying amplitude (4 Hz), How do you determine amplitude? What's the math (or physics) to derive amplitude? are fundamentally spoken valid. Calling someone an idiot is a weak scientific argument. Yes. And so is "Nonsense." And so is your idea of "the frequency". Note the piquant difference: nonsense points to content and we're not discussing idiots (despite a passing by of some very strange postings. ). Hard words break no bones, yet deflate creditability. gr, Hein Well, I think I've had it. A 'never' ending story. Too much to straighten out. Too much comment needed. Questions moving away from the subject. No more indistinguishable close frequencies. No audible beat, no slow changing envelopes. Take a plot, use a high speed camera or whatever else and see for yourself the particle is vibrating at a period in accordance with 222 Hz. In my view I've sufficiently underpinned the 222 Hz frequency. If you disagree, then do the job. Show your frequencies and elucidate them. (No hint needed, I guess.) gr, Hein |
#286
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AM electromagnetic waves: 20 KHz modulation frequency on an astronomically-low carrier frequency
On Mon, 16 Jul 2007 12:28:07 -0700, Jim Kelley
wrote: John Fields wrote: On Fri, 06 Jul 2007 19:04:00 -0000, Jim Kelley wrote: In your example, with 300Hz and 400Hz as the carriers, the sidebands would be located at: f3 = f1 + f2 = 300Hz + 400Hz = 700Hz and f4 = f2 - f1 = 400Hz - 300Hz = 100Hz both of which are clearly within the range of frequencies to which the human ear responds. Indeed. We would hear f3 and f4 if they were in fact there. Your use of the term "beat frequency" is confusing since it's usually used to describe the products of heterodyning, not the audible warble caused by the vector addition of signals close to unison. The term is commonly used in describing the results of interference in time, as well as for mixing. Since the response of the ear is non-linear in amplitude it has no choice _but_ to be a mixer and create sidebands. Perhaps you're confusing log(sin(a)+sin(b)) with log(sin(a))+log(sin(b)). --- Perhaps, but I don't think either of those is correct, since for mixing to occur (AIUI, for sidebands to be generated) the sine waves themselves must be multiplied at the lowest level of the equation instead of added. That is, the solution of log(sin(a)+sin(b)) will describe the numerical value of the logarithm of the vector sum of two sine waves, and since the addition created no sidebands, the output of the circuitry providing the logarithmic transfer function will only be the instantaneous value of the logarithm of the vector sum of the amplitudes of both signals. Similarly, log(sin(a))+log(sin(b)) describes the addition of the logarithm of the amplitude of sin(a) to the logarithm of the amplitude of sin(b), which still produces only a sum. That is, no sidebands. --- If you don't mind me asking, where did you get this notion about the ears creating sidebands? --- Well, whether I mind or not it seems you've asked anyway, so your concern for my sensitivity is feigned. That, coupled with your relegating it to being a "notion", seems to be designed to discredit the hypothesis, offhandedly, and make me work against a headwind in order to prove it valid, with you being the negative authoritarian blowhard detractor. If you're really interested in the subject I'll be happy to discuss it with you if you can keep your end of the discussion objective and free from pejorative comments. Otherwise, **** off. ;^) -- Note tongue-in-cheek smiley, :-) -- JF |
#287
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AM electromagnetic waves: 20 KHz modulation frequency on an astronomically-low carrier frequency
In article ,
"Michael A. Terrell" wrote: Hein ten Horn wrote: I've once listened to the first five harmonics of a powerful medium wave transmitter (400 kW) at a distance of some 300 m. All harmonics gave normal audio; no strange switching effects (Sony ICF-7600D). What I'd like to know is if in such an 'experiment' it can be excluded that (some of) these signals are generated by the receiver itself. That much power that close to the receiver? Its a wonder you didn't destroy the receiver's frontend. That particular receiver doesn't have much of a "front end"; diodes (with protection) and straight into the first mixer. No RF stage, tuned or otherwise. Isaac |
#288
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AM electromagnetic waves: 20 KHz modulation frequency on anast...
But, can you ride electromagnetic waves? Will they astronomically
modulate you? cuhulin |
#289
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AM electromagnetic waves: 20 KHz modulation frequency on an astronomically-lowcarrier frequency
John Fields wrote:
log(sin(a))+log(sin(b)) describes the addition of the logarithm of the amplitude of sin(a) to the logarithm of the amplitude of sin(b), which still produces only a sum. That is, no sidebands. log(x)+log(y)=log(x*y) jk |
#290
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AM electromagnetic waves: 20 KHz modulation frequency on an astronomically-low carrier frequency
Michael A. Terrell wrote:
isw wrote: That particular receiver doesn't have much of a "front end"; diodes (with protection) and straight into the first mixer. No RF stage, tuned or otherwise. It can exceed the PIV of the protection diodes and cause them to short, or explode. That crappy Sony design is where the harmonics came from. The diodes, (or any other semiconductor) with enough RF can generate a lot of spurious signals. It can even come from a rusty joint in the area. Is the ICF-SW7600GR significantly better performing than the ICF-7600D on this? gr, Hein |
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