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#81
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How to measure speaker cable inductance and capacitance?
Per Stromgren wrote in message
And what does it tell you? It tells me that the Smith Chart may be a clever way to solve a computational *RF* problem, at least when we had no better alternatives than slide rules and log books. Perhaps there are better ways nowadays, who knows? The Smith Chart is based on standard transmission line theory. Like a sliderule it has limited accuracy. A sliderule may tell you that 2 times 3 is: 5.99, but we know it is based on sound priciples. The Smith Chart is slightly inaccurate also. But, just like as the sliderule, its fundamentals are valid. Radio frequency techniques can not automatically be applied to the snail pace of audio frequencies. Yes. Right. So why do you suggest we do use this method, then? Because you say so? I'm saying a transmission line model of a two-wire line, will give slightly more accurate results than a discrete component model. OK. What do you want me to do in order to convince you? Well, runing a physical test would be nice. Or you could prove from basic theory, that small wavelength lines don't "work". Citing sources won't do, abvoiusly. Is there any experiment result that would show you that you are wrong? As you know, our dialog is classical. You say A. I say: A is not what a lot of their people say. You say: prove that the others are right. Why should I? Isn't you the one who ought to prove "the others" wrong? I don't think they are wrong, I think you may be misunderstanding what they said. You may be confusing textbook statements about transmission lines at *low frequencies*, with transmission lines that have *small wavelenghts*. They are not the same thing at all! Your turn. (I think I know the next step.) I have presented a theory based on well known facts and formulas. What more do I need to do? Of course being a totally objective person, and being a totally honest person, and being ever *so* humble as well, I don't insist that everyone agree that I am right. (Even if I am.) Have an nice day. Bob Stanton |
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#82
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How to measure speaker cable inductance and capacitance?
Ron Capik wrote in message
Somehow you guys seem to keep poking sticks in each other's cages. I don't see that any of this hand waving will get you out of this poking match. I think we enjoy to poking at each others cage. :-) First I'd like to pose the question: with the thousands of components and feet of wire that audio goes through between the recorded source and the playback system (including room acoustic effects) why are people so passionate about the few feet of speaker cable? They are just plain ignorant. Ummm, why? What's the magic about the reactance to resistance ratio that makes "any two wire line" a transmission line? Seems to me you only made a statement rather than an explanation. There are two definitions of transmission lines. 1) A conductor or group of conductors, that carry electrical energy from one point to another. 2) A correctly dimentioned conductor or pair of conductors, for carrying RF energy from one point to another. In my messages, I referred to: 1) as a "line" and to 2) as a "transmission line". RF transmission lines have completely different characteristics than low frequency lines. For example, an RF transmission line can be (all by itself) a narrow band transformer, step up, or a step down and of any desired tranformation ratio ("turns" ratio). A 2.5 ft long RF cable on the ouptut of an amplifier, will look like a dead short circuit at 100 MHz. But, if you short circuit the end of the RF cable, it will look like a completly open circuit, at 100 MHz. Transmission lines, connected properly, can become RF bandpass filters or a notch filters. Two transmission lines coupled together slightly, can become a directional coupler, that looks at the RF signal coming down the cable but doesnt' see the RF signals coming up the cable. And that is only the tip of the strange iceberg called RF transmission lines. As the frequency gets lower, and the ratio of XL/R decreases, RF transmission lines lose their strange propertys. So, the question of the day is: at what low frequency do two-wire pairs stop acting like "transmission lines". Looking at the XL/R numbers for 12 gage speaker cable, I see the possibiliy that we *might* get more accurate results, by considering them as "transmission lines" rather than a just as "lines". At any rate, we are talking about *only a few tenths of a dB*, at 20 KHz. 2. Very long speaker wires MUCH longer than a wavelength, DO NOT behave like transmission lines. That right, if the resistance/ft is too high, it will be only a "line". [ see "Ummm" above... ] [ see "There are two..." above...] And we're still only talking about fractions of a dB difference ...at high frequencies. Heck, opening the curtains or another person in the room likely has more impact on the sound... Yes. [ see "At any rate..." above...] [ returning to lurking mode ] Excellent questions. Have fun lurking. Bob Stanton |
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#83
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How to measure speaker cable inductance and capacitance?
Ron Capik wrote in message
Somehow you guys seem to keep poking sticks in each other's cages. I don't see that any of this hand waving will get you out of this poking match. I think we enjoy to poking at each others cage. :-) First I'd like to pose the question: with the thousands of components and feet of wire that audio goes through between the recorded source and the playback system (including room acoustic effects) why are people so passionate about the few feet of speaker cable? They are just plain ignorant. Ummm, why? What's the magic about the reactance to resistance ratio that makes "any two wire line" a transmission line? Seems to me you only made a statement rather than an explanation. There are two definitions of transmission lines. 1) A conductor or group of conductors, that carry electrical energy from one point to another. 2) A correctly dimentioned conductor or pair of conductors, for carrying RF energy from one point to another. In my messages, I referred to: 1) as a "line" and to 2) as a "transmission line". RF transmission lines have completely different characteristics than low frequency lines. For example, an RF transmission line can be (all by itself) a narrow band transformer, step up, or a step down and of any desired tranformation ratio ("turns" ratio). A 2.5 ft long RF cable on the ouptut of an amplifier, will look like a dead short circuit at 100 MHz. But, if you short circuit the end of the RF cable, it will look like a completly open circuit, at 100 MHz. Transmission lines, connected properly, can become RF bandpass filters or a notch filters. Two transmission lines coupled together slightly, can become a directional coupler, that looks at the RF signal coming down the cable but doesnt' see the RF signals coming up the cable. And that is only the tip of the strange iceberg called RF transmission lines. As the frequency gets lower, and the ratio of XL/R decreases, RF transmission lines lose their strange propertys. So, the question of the day is: at what low frequency do two-wire pairs stop acting like "transmission lines". Looking at the XL/R numbers for 12 gage speaker cable, I see the possibiliy that we *might* get more accurate results, by considering them as "transmission lines" rather than a just as "lines". At any rate, we are talking about *only a few tenths of a dB*, at 20 KHz. 2. Very long speaker wires MUCH longer than a wavelength, DO NOT behave like transmission lines. That right, if the resistance/ft is too high, it will be only a "line". [ see "Ummm" above... ] [ see "There are two..." above...] And we're still only talking about fractions of a dB difference ...at high frequencies. Heck, opening the curtains or another person in the room likely has more impact on the sound... Yes. [ see "At any rate..." above...] [ returning to lurking mode ] Excellent questions. Have fun lurking. Bob Stanton |
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#84
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How to measure speaker cable inductance and capacitance?
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#87
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How to measure speaker cable inductance and capacitance?
(Bob-Stanton) wrote in message . com...
(Dick Pierce) wrote in message Mr. STanton, it's not my job or anyone else's to do YOUR work for you. YOU are the one making the claim, YOU are the one who has utterly failed to to provide ANY evidence for your claim. I thought, if you were interested in the subject, you might make the effort. So, let's see if we have this straight: you're either too lazy, too frightened or just too arrogant to provide support for your hypothesis. I think they *do* apply, but I won't be dogmatic about it without supporting physical evidence. No, sir, "dogma" is assertion with NO evidence. You're the one spouting dogam. Since the Roman Catholic Church had 100% confidence in their model of the universe with the earth at the center and all else moving around it in harmonic spheres, why should THEY test them? I agree with them. And you're the one claiming other peopl spout dogma? |
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#88
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How to measure speaker cable inductance and capacitance?
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#89
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How to measure speaker cable inductance and capacitance?
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#90
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How to measure speaker cable inductance and capacitance?
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#91
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How to measure speaker cable inductance and capacitance?
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#92
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How to measure speaker cable inductance and capacitance?
Bob-Stanton wrote:
Ron Capik wrote in message ..snips... Ummm, why? What's the magic about the reactance to resistance ratio that makes "any two wire line" a transmission line? Seems to me you only made a statement rather than an explanation. That right, if the resistance/ft is too high, it will be only a "line". [ see "Ummm" above... ] [ see "There are two..." above...] Bob, there was only one "Ummm" above and it asked what makes the ratios special. As far as I know that two wire case is but one example of TEM mode transmission lines. If you were dealing with flat conductor ribbon cable (maybe like some of those "under the carpet" audio cables) you might be dealing with significant transmission line effects at audio frequencies, depending on geometry etc. [Like say: fold the cable in half or run the right and left speaker ribbons on top of each other ...not that I think you might ever do such a thing. G ] Anyway... back to lurking. Ron Capik -- |
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#93
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How to measure speaker cable inductance and capacitance?
Bob-Stanton wrote:
Ron Capik wrote in message ..snips... Ummm, why? What's the magic about the reactance to resistance ratio that makes "any two wire line" a transmission line? Seems to me you only made a statement rather than an explanation. That right, if the resistance/ft is too high, it will be only a "line". [ see "Ummm" above... ] [ see "There are two..." above...] Bob, there was only one "Ummm" above and it asked what makes the ratios special. As far as I know that two wire case is but one example of TEM mode transmission lines. If you were dealing with flat conductor ribbon cable (maybe like some of those "under the carpet" audio cables) you might be dealing with significant transmission line effects at audio frequencies, depending on geometry etc. [Like say: fold the cable in half or run the right and left speaker ribbons on top of each other ...not that I think you might ever do such a thing. G ] Anyway... back to lurking. Ron Capik -- |
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#94
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How to measure speaker cable inductance and capacitance?
Ron Capik wrote in message
As far as I know that two wire case is but one example of TEM mode transmission lines. That's right. T.E.M. means: "transverse electric mode". A mode where the electric field is perpendicular to the direction of propagation. Even hollow pipes (waveguides) can have a TEM. Bob Stanton |
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#95
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How to measure speaker cable inductance and capacitance?
Ron Capik wrote in message
As far as I know that two wire case is but one example of TEM mode transmission lines. That's right. T.E.M. means: "transverse electric mode". A mode where the electric field is perpendicular to the direction of propagation. Even hollow pipes (waveguides) can have a TEM. Bob Stanton |
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#96
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How to measure speaker cable inductance and capacitance?
Bob-Stanton wrote:
...snip.. Even hollow pipes (waveguides) can have a TEM. Don't even need a pipe. TEM modes can be supported in free space. Somewhat in support of your conjecture I contend that there are transmission line effects in any electromagnetic interaction. Under some conditions the bulk effects overwhelm the spatial effects but they're still there. Any time you move a charge there's a spatial effect than can be coupled to other charges. Reactance is a spatial effect. It's been years since I played with transmission lines but I think your argument is on the right track. Dick has been looking for substantiation, I threw the ratio question in as a possible direction for investigation. I think pulling up a Smith Chart was innovative. Were we in class and I your professor you'd get extra credit for that. ;-) I was having fun watching the thread 'till it hit the rocks. ....thought a few questions might nudge it along. ....not quite lurking. Later... Ron Capik -- ....the more you know the more you know you don't know. |
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#97
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How to measure speaker cable inductance and capacitance?
Bob-Stanton wrote:
...snip.. Even hollow pipes (waveguides) can have a TEM. Don't even need a pipe. TEM modes can be supported in free space. Somewhat in support of your conjecture I contend that there are transmission line effects in any electromagnetic interaction. Under some conditions the bulk effects overwhelm the spatial effects but they're still there. Any time you move a charge there's a spatial effect than can be coupled to other charges. Reactance is a spatial effect. It's been years since I played with transmission lines but I think your argument is on the right track. Dick has been looking for substantiation, I threw the ratio question in as a possible direction for investigation. I think pulling up a Smith Chart was innovative. Were we in class and I your professor you'd get extra credit for that. ;-) I was having fun watching the thread 'till it hit the rocks. ....thought a few questions might nudge it along. ....not quite lurking. Later... Ron Capik -- ....the more you know the more you know you don't know. |
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#98
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How to measure speaker cable inductance and capacitance?
Ron Capik wrote in message
If you were dealing with flat conductor ribbon cable (maybe like some of those "under the carpet" audio cables) you might be dealing with significant transmission line effects at audio frequencies, depending on geometry etc. [Like say: fold the cable in half or run the right and left speaker ribbons on top of each other ...not that I think you might ever do such a thing. G ] Anyway... back to lurking. Dunlavy Z6, flat speaker cable has a lower inductance/ft than Home Depot 12 gage, but the same resistance /ft. I would not expect Z6 to act as a transmission line at audio frequencies. However, modeling it as discrete components, it has excellent performance. Any open two-wire cable (flat or round) will be affected by the external environment. Back to lurking, me to. Bob Stanton |
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#99
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How to measure speaker cable inductance and capacitance?
Ron Capik wrote in message
If you were dealing with flat conductor ribbon cable (maybe like some of those "under the carpet" audio cables) you might be dealing with significant transmission line effects at audio frequencies, depending on geometry etc. [Like say: fold the cable in half or run the right and left speaker ribbons on top of each other ...not that I think you might ever do such a thing. G ] Anyway... back to lurking. Dunlavy Z6, flat speaker cable has a lower inductance/ft than Home Depot 12 gage, but the same resistance /ft. I would not expect Z6 to act as a transmission line at audio frequencies. However, modeling it as discrete components, it has excellent performance. Any open two-wire cable (flat or round) will be affected by the external environment. Back to lurking, me to. Bob Stanton |
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#100
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How to measure speaker cable inductance and capacitance?
On 15 Nov 2003 08:41:22 -0800, (Bob-Stanton)
wrote: Ron Capik wrote in message If you were dealing with flat conductor ribbon cable (maybe like some of those "under the carpet" audio cables) you might be dealing with significant transmission line effects at audio frequencies, depending on geometry etc. [Like say: fold the cable in half or run the right and left speaker ribbons on top of each other ...not that I think you might ever do such a thing. G ] Anyway... back to lurking. Dunlavy Z6, flat speaker cable has a lower inductance/ft than Home Depot 12 gage, but the same resistance /ft. I would not expect Z6 to act as a transmission line at audio frequencies. However, modeling it as discrete components, it has excellent performance. Any open two-wire cable (flat or round) will be affected by the external environment. Back to lurking, me to. Bob Stanton Why would you not expect the Z6 to act as a transmission line? It really has no choice in the matter since it is one, and it has no preconceptions about audio frequencies. And of course its performance lies in what it actually is - not how you model it. As for open two-wire systems interacting with their environment, well, certainly there is some interaction, but it is vastly lower than the interaction between the two conductors. More specifically, how the wire is laid out - folded, bunched or straight - has no effect whatever, since the effect is only present in the common mode, not the differential (signal-carrying) mode. d _____________________________ http://www.pearce.uk.com |
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#101
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How to measure speaker cable inductance and capacitance?
On 15 Nov 2003 08:41:22 -0800, (Bob-Stanton)
wrote: Ron Capik wrote in message If you were dealing with flat conductor ribbon cable (maybe like some of those "under the carpet" audio cables) you might be dealing with significant transmission line effects at audio frequencies, depending on geometry etc. [Like say: fold the cable in half or run the right and left speaker ribbons on top of each other ...not that I think you might ever do such a thing. G ] Anyway... back to lurking. Dunlavy Z6, flat speaker cable has a lower inductance/ft than Home Depot 12 gage, but the same resistance /ft. I would not expect Z6 to act as a transmission line at audio frequencies. However, modeling it as discrete components, it has excellent performance. Any open two-wire cable (flat or round) will be affected by the external environment. Back to lurking, me to. Bob Stanton Why would you not expect the Z6 to act as a transmission line? It really has no choice in the matter since it is one, and it has no preconceptions about audio frequencies. And of course its performance lies in what it actually is - not how you model it. As for open two-wire systems interacting with their environment, well, certainly there is some interaction, but it is vastly lower than the interaction between the two conductors. More specifically, how the wire is laid out - folded, bunched or straight - has no effect whatever, since the effect is only present in the common mode, not the differential (signal-carrying) mode. d _____________________________ http://www.pearce.uk.com |
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#102
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How to measure speaker cable inductance and capacitance?
Don Pearce wrote:
...snip.. As for open two-wire systems interacting with their environment, well, certainly there is some interaction, but it is vastly lower than the interaction between the two conductors. More specifically, how the wire is laid out - folded, bunched or straight - has no effect whatever, since the effect is only present in the common mode, not the differential (signal-carrying) mode. Think capacitive rather than inductive coupling; as in slab waveguide. The systems have a common ground. The interaction would be in the form of cross talk if the right and left cables were overlaid, like if the amp were in the back of the room. Depends a lot on geometry, we're still talking fractions of a dB ...and any good tech would never run the wires on top of each other. Darn, now you have me poking about with quasi-academic sticks... ;-) Carry on... Ron Capik cynic in training -- |
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#103
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How to measure speaker cable inductance and capacitance?
Don Pearce wrote:
...snip.. As for open two-wire systems interacting with their environment, well, certainly there is some interaction, but it is vastly lower than the interaction between the two conductors. More specifically, how the wire is laid out - folded, bunched or straight - has no effect whatever, since the effect is only present in the common mode, not the differential (signal-carrying) mode. Think capacitive rather than inductive coupling; as in slab waveguide. The systems have a common ground. The interaction would be in the form of cross talk if the right and left cables were overlaid, like if the amp were in the back of the room. Depends a lot on geometry, we're still talking fractions of a dB ...and any good tech would never run the wires on top of each other. Darn, now you have me poking about with quasi-academic sticks... ;-) Carry on... Ron Capik cynic in training -- |
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#104
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How to measure speaker cable inductance and capacitance?
Don Pearce wrote in message
Why would you not expect the Z6 to act as a transmission line? It really has no choice in the matter since it is one, and it has no preconceptions about audio frequencies. There are two definitions of "transmission lines". (Transmission lines, and RF transmission lines) Z6 is always a transmission line, at any frequency. But, it won't act as a RF transmission line below a certain frequency. For example, if you tried to make it into a 1/4 wave transformer (at 1000 Hz), it wouldn't transform. And of course its performance lies in what it actually is - not how you model it. What we want to be able to do is to model the way it actually is, from simple R, L, and C measurements. Bob Stanton |
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#105
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How to measure speaker cable inductance and capacitance?
Don Pearce wrote in message
Why would you not expect the Z6 to act as a transmission line? It really has no choice in the matter since it is one, and it has no preconceptions about audio frequencies. There are two definitions of "transmission lines". (Transmission lines, and RF transmission lines) Z6 is always a transmission line, at any frequency. But, it won't act as a RF transmission line below a certain frequency. For example, if you tried to make it into a 1/4 wave transformer (at 1000 Hz), it wouldn't transform. And of course its performance lies in what it actually is - not how you model it. What we want to be able to do is to model the way it actually is, from simple R, L, and C measurements. Bob Stanton |
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#106
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How to measure speaker cable inductance and capacitance?
On 15 Nov 2003 17:42:45 -0800, (Bob-Stanton)
wrote: Don Pearce wrote in message Why would you not expect the Z6 to act as a transmission line? It really has no choice in the matter since it is one, and it has no preconceptions about audio frequencies. There are two definitions of "transmission lines". (Transmission lines, and RF transmission lines) Z6 is always a transmission line, at any frequency. But, it won't act as a RF transmission line below a certain frequency. For example, if you tried to make it into a 1/4 wave transformer (at 1000 Hz), it wouldn't transform. It acts as a transmission line at every frequency. The question of how you choose to model it is quite different. And of course its performance lies in what it actually is - not how you model it. What we want to be able to do is to model the way it actually is, from simple R, L, and C measurements. Bob Stanton No, you aren't modelling it the way it is, but as an approximate abstraction - more than good enough to give you the results you want. That is of course the nature of all models, but some are further abstracted than others. d _____________________________ http://www.pearce.uk.com |
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#107
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How to measure speaker cable inductance and capacitance?
On 15 Nov 2003 17:42:45 -0800, (Bob-Stanton)
wrote: Don Pearce wrote in message Why would you not expect the Z6 to act as a transmission line? It really has no choice in the matter since it is one, and it has no preconceptions about audio frequencies. There are two definitions of "transmission lines". (Transmission lines, and RF transmission lines) Z6 is always a transmission line, at any frequency. But, it won't act as a RF transmission line below a certain frequency. For example, if you tried to make it into a 1/4 wave transformer (at 1000 Hz), it wouldn't transform. It acts as a transmission line at every frequency. The question of how you choose to model it is quite different. And of course its performance lies in what it actually is - not how you model it. What we want to be able to do is to model the way it actually is, from simple R, L, and C measurements. Bob Stanton No, you aren't modelling it the way it is, but as an approximate abstraction - more than good enough to give you the results you want. That is of course the nature of all models, but some are further abstracted than others. d _____________________________ http://www.pearce.uk.com |
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#108
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How to measure speaker cable inductance and capacitance?
Don Pearce wrote in message
It acts as a transmission line at every frequency. The question of how you choose to model it is quite different. No, you aren't modelling it the way it is, but as an approximate abstraction - more than good enough to give you the results you want. That is of course the nature of all models, but some are further abstracted than others. I agree, if we are making a standard model from R, L, C, and/or even RF transmission lines. There is one model type, however, that is as accurate as the best test equipment. That would be a two-port, S-parameter, data file. A speaker cable's S-parameters can be measured by an HP Network Analyzer, (down to the lowest RF frequencies). Then below RF, Y-parameters can be used down to the lowest audio frequencies. (The Y-parameters can then be converted to S-parameters.) Now, you have an S-parameter, two-port data file, that goes from audio to RF. A circuit analysis program can use this file to simulate the speaker cable. The two-port data file is treated, as a *component*. The output of the program will be exactly the same as the data the network analyzer measured. The nice thing about this two-port data component model is: it will also work in low frequency AC circuit analysis programs, with *any source and any load impedance*. Using a voltage source and a typical *loudspeaker load*, it will give the response of that cable into that load, even though the speaker cable was originally measured using equal source and load impedance. Bob Stanton |
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#109
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How to measure speaker cable inductance and capacitance?
Don Pearce wrote in message
It acts as a transmission line at every frequency. The question of how you choose to model it is quite different. No, you aren't modelling it the way it is, but as an approximate abstraction - more than good enough to give you the results you want. That is of course the nature of all models, but some are further abstracted than others. I agree, if we are making a standard model from R, L, C, and/or even RF transmission lines. There is one model type, however, that is as accurate as the best test equipment. That would be a two-port, S-parameter, data file. A speaker cable's S-parameters can be measured by an HP Network Analyzer, (down to the lowest RF frequencies). Then below RF, Y-parameters can be used down to the lowest audio frequencies. (The Y-parameters can then be converted to S-parameters.) Now, you have an S-parameter, two-port data file, that goes from audio to RF. A circuit analysis program can use this file to simulate the speaker cable. The two-port data file is treated, as a *component*. The output of the program will be exactly the same as the data the network analyzer measured. The nice thing about this two-port data component model is: it will also work in low frequency AC circuit analysis programs, with *any source and any load impedance*. Using a voltage source and a typical *loudspeaker load*, it will give the response of that cable into that load, even though the speaker cable was originally measured using equal source and load impedance. Bob Stanton |
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