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Richard Clark wrote:
The method of computation you employ violates Chipman and any other of a host of authoritative sources on the topic. If you actually attempted to verify this at the bench you would "perhaps" find it at only one point, or at harmonic distances (wavelength specific) along the line. -sigh- One cannot verify anything about lossless lines on the bench. The only verifications about lossless lines that are possible have to be done in one's head because that's the only place lossless lines exist. One can come close with open-wire line and extrapolate the results to lossless lines. You see the effects more on coax than on open-wire line simply because coax is lossier than open-wire line. I will leave you to discover Chipman's means to find SWR any where along any line for yourself. You told me to reference page 139 which I did. All that page talks about is lossy feedline with a complex Z0. The purely resistive feedline, given by you in your example, cannot have a complex Z0. So what Chipman has to say is irrelevant to the problem you posed, i.e. purely resistive Z0, purely resistive source impedance, and purely resistive load. You apparently should have posed a complex Z0. Chipman explains perfectly why the measured SWR may vary with a lossy line, i.e. with a complex Z0. There are points of conjugate matching up and down the line where an oscillation takes place. The oscillation causes extra reflections and re-reflections at the conjugate match point, an exchange of a third energy between the capacitive reactance and the inductive reactance at that point, that affects the SWR readings. But such is not possible with the purely resistive Z0 that you posed. -- 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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