For example 3 with the bandpass filter design, when actually implementing this filter, do we use N*2 actual physical elements? I don’t see a way to make one transmission line section behave both as an inductor and a capacitor so that would mean you would need 2 transmission line sections to realize one N element which includes the pair of inductor and capacitor. Does anyone have any references I may use that shows a physical realization for this filter using the insertion loss method and prototype method as shown in this video?
Where is the frequency scaling ? Why did not we apply to the transmisson lines? These examples were extracted from Pozar's book. However Professor, you should explain the all the part of the question, we can totally check the book and you are writing the same solution rather than your solution :/ . Your own comments should be very prominent than the written ones.
For example 3 with the bandpass filter design, when actually implementing this filter, do we use N*2 actual physical elements? I don’t see a way to make one transmission line section behave both as an inductor and a capacitor so that would mean you would need 2 transmission line sections to realize one N element which includes the pair of inductor and capacitor. Does anyone have any references I may use that shows a physical realization for this filter using the insertion loss method and prototype method as shown in this video?
Tutorial on Insertion Loss Method of Filter Design
Where is the frequency scaling ? Why did not we apply to the transmisson lines? These examples were extracted from Pozar's book. However Professor, you should explain the all the part of the question, we can totally check the book and you are writing the same solution rather than your solution :/ . Your own comments should be very prominent than the written ones.
where does the n^2 = 1+ Z2/Z1 (at 27:55min) come from? is that a r²ow of the impedances?