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for al_dddd:
you just forgot the 50 ohm load in your answer. I rewrite it here with the correction:
First you have voltage division 8.56 and 141.8||(8.56+50) and then you have voltage division between 8.56 and 50 Ohm.
Elaborating a little bit more:
let's call "x" the node where the two 8.56 ohm and the 141.8 ohm resistors are connected.
The voltage Vx will be given by the voltage divider formed by the "input" 8.56 ohm series resistor and the 141.8 resistor in parallel with the sum of the "output" 8.56 ohm resistor with the 50 ohm load.
The sum of the "output" 8.56 ohm resistor with the 50 ohm load will be obviously 58.56 ohm. This value in parallel with 141.8 ohm leads to 41.44 ohm.
Then:
Vx=V1*41.44/(41.44+8.56)
Now to go from Vx to V2 we will have the voltage divider formed by the "output" 8.56 ohm resistor and the 50 ohm load, thus
A load of 50 Ω is connected in shunt in a 2-wire transmission line of Zo = 50 Ω as shown in the figure. The 2-port scattering parameter matrix (s-matrix) of the shunt element is?
Not sure if I'm looking a the correct figure, but in the one I'm looking at, V1 (the left hand side) = V2 (the right hand side).
The input power is divided equally between the resistor and the output TL. Since (1/9) of the power reflects, the remaining power (8/9) is divided between the two loads, such that each receives (4/9) of the power. The insertion loss is related to the power which is received by the output TL, which is the square root of (4/9) - 2/3.
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