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Roy Lewallen wrote:
I'm trying to stay out of this, but can't avoid mentioning that although Cecil insists on only one Pref and one Pfwd, he has different criteria for voltage waves, and requires multiple Vfwd and Vref. So there are four directions for voltage, but only two for power? There are four voltage components flowing in two directions. Add up the two voltages flowing in the forward direction and you have total forward voltage. Add up the two voltages flowing in the reverse direction and you have total reverse voltage. From the total forward voltage, you can calculate the total forward power. From the total reverse voltage, you can calculate the total reverse power. There are no magic third terms after superposition. Vfwd2 = Vfwd1(tau1) + Vref2(rho2) Vref1 = Vfwd1(rho1) + Vref2(tau2) Four voltage components, two total voltages, two directions. -- 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! =----- |
wrote:
Just to make sure I understand correctly, are you saying that Vrev^2/Z0 can never be greater than Vfwd^2/Z0 (these being the common definitions of Prev and Pfwd) or did you have another set of defintions in mind for Prev and Pfwd when you state that Prev can never be greater than Pfwd? Assuming a single source, single feedline, a passive load, RMS voltage, and a real Z0, yes, average Prev can never be greater than average Pfwd, i.e. the total Poynting vector can never point away from the load. Such would be a violation of the conservation of energy principle. The fact that the Poynting vector still points toward the load in Roy's example means that reverse power cannot be greater than forward power. -- 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! =----- |
Cecil Moore wrote:
wrote: But without some equations defining Pfwd and Prev, the concept is not particularly useful since there are no predictions which you can make from it. The equations are to be found in Dr. Best's Nov/Dec 2001 QEX article, "Wave Mechanics of Transmission Lines: Part 3" and in _Optics_, by Hecht. When the characteristic impedances are real: Do recall that this discussion started with a line whose characteristic was complex not real, so all that follows here is moot. V1 = Vfwd1(tau1) V2 = Vref2(rho2) V3 = Vfwd1(rho1) V4 = Vref2(tau2) Vfwd2 = V1 + V2 Vref1 = V3 + V4 P1 = Pfwd1(1-|rho|^2) P2 = Pref2(|rho|^2) forward components P3 = Pfwd1(|rho|^2) P4 = Pref2(1-|rho|^2) reverse components Pfwd2 = P1 + P2 + 2*Sqrt(P1*P2)cos(delta-1) Pref1 = P3 + P4 + 2*Sqrt(P3*P4)cos(delta-2) where (delta-1) is the angle between V1 and V2, (delta-2) is the angle between V3 and V4, and that last term is called the interference term. In _Optics_, average power is called irradiance (I) and the equation is: I1 + I2 + 2*Sqrt(I1*I2)cos(delta) For further information, check out my Part 1 energy analysis article on my web page. Part 2 will appear shortly. But, going back to the original question, is Pfwd and Prev on a line with complex Z0? ....Keith |
wrote:
Cecil Moore wrote: Assuming a single source, single feedline, a passive load, RMS voltage, and a real Z0, yes, average Prev can never be greater than average Pfwd, i.e. the total Poynting vector can never point away from the load. Such would be a violation of the conservation of energy principle. Yes indeed. But in the original example Z0 was complex. So once again, with the clarification that the following question was phrased in general terms and not constrained to lines where Z0 is real... I believe my statement holds true for any possible Z0. Here's the logical proof. Replace the following: source---Z01 lossy line---x--passive load Pfwd1-- --Pref1 with an extra 1WL of lossless line that doesn't change anything. The lossy line still sees the same impedance looking into point 'x'. source---Z01 lossy line---x---1WL lossless Z02---+--passive load Pfwd1-- Pfwd2-- --Pref1 --Pref2 Pfwd1 and Pref1 exist just to the left of point 'x'. We know that (Pfwd1-Pref1) has to equal (Pfwd2-Pref2) which equals the power delivered to the load. Everything to the right of point 'x' is easy to analyze. We know that Pfwd2 Pref2 if there is any resistance in the load. If resistance in the load is zero, Pfwd2 = Pref2. In any possible case of a passive load, Pref2 cannot be greater than Pfwd2. Therefore, just to the left of point 'x', Pref1 cannot be greater than Pfwd1. Backtracking from the load, the lossy line really doesn't enter into the discussion at all. Note that Pfwd1 will not equal Pfwd2 and Pref1 will not equal Pref2 but the difference between forward power and reflected power must be equal to the power delivered to the load in order to satisfy the conservation of energy principle. -- 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! =----- |
wrote:
But, going back to the original question, is Pfwd and Prev on a line with complex Z0? See my logical proof in another posting. -- 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! =----- |
wrote in message ... Vrev^2/Z0 can NEVER be greater than Vfwd^2/Z0 (these being the common definitions of Prev and Pfwd) or did you have another set of defintions in mind for Prev and Pfwd this is another of the basic misconceptions that is being applied over and over on there. note from my big message about powers a couple days ago that from phasor notation there are really only two types of power that can be discussed: average power: Pav= .5 |I|^2 Re[Z] = .5 |V|^2 Re[Y] and complex power. P=.5 V I* now, note that given Pav you can NOT recover enough information about V to know its proper phase and magnitude in order to be able to compare it with anything properly. Complex power on the other had requires the conjugate of the current, which when expanded gives an equation like: P=.5 |V| |I| cos(/_V-/_I) + j.5 |V| |I| sin(/_V-/_I) where again, it is not possible to back up from the power to the full phasor description of the voltage to be able to use it in calculations or comparisons. now, you CAN do this if you restrict Z0 to be purely real, you can NOT do it if you use a complex Z0 because you can't extract the imaginary term back out of a power calculation that has specifically removed it. so all these places where you guys start doing sqrt(Pref/Pfwd)=Vfwd/Vref or Vrev^2/Z0/Vfwd^2/Z0 are worthless in the general case. |
Cecil Moore wrote:
wrote: Cecil Moore wrote: Assuming a single source, single feedline, a passive load, RMS voltage, and a real Z0, yes, average Prev can never be greater than average Pfwd, i.e. the total Poynting vector can never point away from the load. Such would be a violation of the conservation of energy principle. Yes indeed. But in the original example Z0 was complex. So once again, with the clarification that the following question was phrased in general terms and not constrained to lines where Z0 is real... I believe my statement holds true for any possible Z0. Here's the logical proof. Replace the following: source---Z01 lossy line---x--passive load Pfwd1-- --Pref1 with an extra 1WL of lossless line that doesn't change anything. The lossy line still sees the same impedance looking into point 'x'. source---Z01 lossy line---x---1WL lossless Z02---+--passive load Pfwd1-- Pfwd2-- --Pref1 --Pref2 Pfwd1 and Pref1 exist just to the left of point 'x'. We know that (Pfwd1-Pref1) has to equal (Pfwd2-Pref2) which equals the power delivered to the load. While Pnet = Pfwd - Prev using the classic definitions Pfwd = Vi^2/R0 and Prev = Vr^2/R0 works for lossless line, we do not yet have an equivalent set of definitions for Pfwd and Prev on a lossy line. When we do find appropriate definitions for Prev and Pfwd on a lossy line such that Pnet = Pfwd - Prev, then Prev/Pfwd will not be greater than one and it definitely will not be equal to rho^2 (which can be greater than one). So we are still looking for appropriate definitions of Pfwd and Prev on a lossy line. Or we could just throw this whole power analysis thing away and stick with voltage analysis which works just fine and lets us compute everything of interest. ....Keith |
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wrote:
So we have the following requirements Pload = Pfwd - Prev Prho = Prev/Pfwd There is still a very large selection of pairs which will satisfy these constraints. Nope, there are not. Assuming Pload is known and Prho is known, you have two equations and two unknowns which can be solved for with unique solutions. For instance, in my previous example: Pload = 100 watts, Prho = 0.25. Prho can be calculated. Prev = Pfwd*Prho and substituting, we have: 100W = Pfwd - 0.25*Pfwd 100W = 0.75*Pfwd, therefore Pfwd = 133.33W, a unique solution. Incidentally, if you want a reference for losses in low-loss lines, _Fields_and_Waves_... by Ramo, Whinnery, and Van Duzer has a section 1.22 on page 41 titled, "Physical Approximations for Low-Loss Lines". They assume an average loss per unit length. I won't even try to reproduce the equations in ASCII. -- 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! =----- |
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