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W5DXP wrote:
wrote: W5DXP wrote: Actually, not. You continue to resist pointing out which step is wrong. You obviously have not read all of my replies. On the contrary. But finally this one actually addresses one of the steps rather than just attempting to show that that conclusion is wrong. Is it step 2)? "2) At quarter wave points along this line, voltages and currents which are always 0 can be observed -- the standing wave" This seems to be generally accepted. This is where your confusion starts. There are points where the NET voltage and NET current are zero. Those are merely the points where the forward Poynting vector and reflected Poynting vector are out of phase. This emphasis on NET seems to be the place where the difficulties begin. An (ideal) voltmeter placed at a voltage minima on the line indicates a voltage of 0 volts. You appear to be saying that despite this indication of 0, there is actually voltage present. This contention leads to a number of questions related to voltmeters: - when I use a voltmeter to measure the voltage in a circuit, how do I know when an indication of 0 means 0? - how do I know when an indication of 0 means there are really a number of voltages which sum to 0? - how do I determine what these voltages are which sum to 0? - if it indicates other than 0, is it really indicating a number of voltages which sum to the result? - how do I determine what these voltages actually are? - can voltmeters be trusted at all? - when? In my world, voltmeters indicate volts. There is no need for second guessing. Until this very fundamental difference is settled, there is no value in examining the remaining steps. ....Keith |
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wrote:
This emphasis on NET seems to be the place where the difficulties begin. An (ideal) voltmeter placed at a voltage minima on the line indicates a voltage of 0 volts. You appear to be saying that despite this indication of 0, there is actually voltage present. There are actually two voltages present of equal amplitude and opposite phase. Their phasor sum is zero volts. - how do I determine what these voltages actually are? |Vfwd| = Sqrt(Pfwd*Z0) |Vref| = Sqrt(Pref*Z0) If the voltmeter reads zero, these two voltages are equal in magnitude and opposite in phase. Do you know how to sum two phasor voltages? -- 73, Cecil http://www.qsl.net/w5dxp -----= Posted via Newsfeeds.Com, Uncensored Usenet News =----- http://www.newsfeeds.com - The #1 Newsgroup Service in the World! -----== Over 100,000 Newsgroups - 19 Different Servers! =----- |
Hm, this has me puzzled. Assuming a purely real Z0, you're taking the
square roots of two purely real quantities, each of which can have two values, and speaking of a phase angle between them. Where in the process did they pick up phase information? Or do you just mean when one is the negative of the other? If so, how do you tell -- each has two roots, that is, Sqrt(Pfwd*Z0) can be either positive or negative, and so can Sqrt(Pfref*Z0). How do you know when one is the negative of the other? Roy Lewallen, W7EL W5DXP wrote: Richard Clark wrote: We covered this before. The NET 0 "could be" the result of a bajillion volts and -bajillion volts. It could be but it's not. The NET 0 is the result of Pfwd=Pref Thus, Sqrt(Pfwd*Z0) = Sqrt(Pref*Z0) and when they are 180 deg out of phase, the net voltage is zero. |
Keith wrote:
"-how do I determine what these voltages actually are?" You measure the power in either direction using a wattmeter containing a directional coupler. The volts, amps, and power flowing each direction are the same. That`s why you have zeros. Then, P = Esquared / Zo, so E = sq rt (P)(Zo) Best regards, Richard Harrison, KB5WZI |
I wrote:
"E = sq rt (P)(Zo)" Some may not realize that E is an rms value. Keith early in the thread was inserting instantaneous volts which can be an infinite range of values as they may be taken at any point in a cycle for evaluation. I agree with Cecil`s "tits on a boar hog" characterization of value in transmission line problem utility. Best regards, Richard Harrison, KB5WZI |
Roy Lewallen wrote:
Hm, this has me puzzled. :-) Good one, Roy. :-) Assuming a purely real Z0, you're taking the square roots of two purely real quantities, each of which can have two values, and speaking of a phase angle between them. Where in the process did they pick up phase information? Or do you just mean when one is the negative of the other? If so, how do you tell -- each has two roots, that is, Sqrt(Pfwd*Z0) can be either positive or negative, and so can Sqrt(Pfref*Z0). How do you know when one is the negative of the other? V^2/Z0=P is a well known equation (so is I^2*Z0=P). These are *RMS* values. So the RMS voltage is V = Sqrt(Pfwd*Z0). Root Mean Square AC voltages are equivalent to DC voltages in power dissipation and are generally considered to be positive values because they are the sum of squared terms. We can turn those RMS voltages into phasors by adding the phase angles. When Vfwd+Vref = Vmax, Vfwd and Vref are in phase (at the SWR voltage maximum point). When Vfwd+Vref = Vmin, Vfwd and Vref are 180 degrees out of phase (at the SWR voltage minimum point). Vmax/Vmin = VSWR. Please feel free to pull my leg again anytime. :-) -- 73, Cecil http://www.qsl.net/w5dxp -----= Posted via Newsfeeds.Com, Uncensored Usenet News =----- http://www.newsfeeds.com - The #1 Newsgroup Service in the World! -----== Over 100,000 Newsgroups - 19 Different Servers! =----- |
Richard Clark wrote:
Certainly we cannot ignore the bajillion volts *RMS*, now, can we? ;-) We can unless Sqrt(P*Z0) equals a bajillion volts which it usually doesn't. These values are all inter-related. A 200W transmitter will pour Sqrt(200*50) = 100 volts RMS into a 50 ohm load. That's a no-brainer. Why do you act like it is a far out big deal? -- 73, Cecil http://www.qsl.net/w5dxp -----= Posted via Newsfeeds.Com, Uncensored Usenet News =----- http://www.newsfeeds.com - The #1 Newsgroup Service in the World! -----== Over 100,000 Newsgroups - 19 Different Servers! =----- |
On Wed, 27 Aug 2003 15:51:20 -0500, W5DXP
wrote: Why do you act like it is a far out big deal? Hi Cecil, Are you now trying to convince us that a bajillion volts *RMS* meeting -bajillion volts *RMS* is NOT NET 0? Those are merely the points where the forward Poynting vector and reflected Poynting vector are out of phase. We are dealing with component energies. The NET energy is zero. The component energies are not zero. This would seem to conflict with much of your wave mechanics for the last 6 months. Shirley you cannot deny the impact of a bajillion volts *RMS* simply because your current argument doesn't need that solution, can you? (I guess you can.) However, that is not to say that we didn't notice that rhetorical slide from "could be" to the firmer "is." We can specify these bajillion volts *RMS* with a phase of a mega-bajillion degrees (with deliberate care to avoid problematic 179 or 181 degrees) to suit any opportunistic need. ;-) 73's Richard Clark, KB7QHC |
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