The input of a transmission line with Z. = 300 ohms is connected in parallel with the input of anothertransmission with 200-ohm characteristic impedance. Each line is terminated with a load that is equal to itscharacteristic impedance. The inputs of the two lines are connected to a third transmission line which suppliespower to the first two lines. Find the Z of the third line such that there will be no reflected signal on the thirdline.

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Answered: The input of a transmission line with…

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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Transmission line parametres
Q1) Derive an expression for the input impedance Zin in terms of the load impedance ZL and the characteristic impedance of the line Zo. What is the importance of this case? State briefly.
i need the answer quickly
2. Estimate the distance over which a load of 12000 kW at a p.f. 0-65 lagging can be delivered by a 3-phase transmission line having conductors each of resistance 2 2 per kilometer. The voltage at the receiving end is to be 132 kV and the loss in the transmission is to be 4%.
I turned the voltage value of the AC source into Vrms and got magnitude 16.97 & angle 10.Then calculated the impedance of Load A to be [ -9.28 - j23.4 ]. From that, I calculated the complex power of load B to be [ -2.42 + j6.33 ] my power factor calculation I am using inverse tan ( Q/P) , where Q i got -1.91 & P to be 5.559, which I got from my total complex power. If that helps. But I am calculating a negative power factor, so i am curious where I went wrong, Thank you!
The impedance of a transmission line with a length of 50 km is given as z = 0.08 + j0.48 22/km. At the end of the line, a power of 250 MW is drawn with a lagging power factor of cosy = 0.95 under 220 kV voltage. Under these conditions, find the voltage, current, and power factor at the beginning of the line.
Q) A source of 10 V and frequency 1000 KHz with internal resistance of 10 2 is connected to the sending end of a transmission line which can be represented by a resistance of 70 Q in series with capacitance of 0.001 µF connected across the line at the receiving end. An inductive load of inductance 0.002 H and resistance 100 Q is connected across the receiving end of the line. Determine the load current.
A 60-2 transmission line is connected to a 75-2 resistive load. If the incident voltage is 5 V rms, then the reflected voltage is: a) -1.026 Vrms. b) -0.832 Vrms. c) 0.556 Vrms. d) 1.569 Vrms. e) 2.320 Vrms.
Q) A transmission line of negligible loss has a characteristic impedance of 600 Q. Calculate the VSWR along the line when it is terminated by an impedance of (400+j300) . What is the VSWR if the load is changed to a purely resistive one of 500 0?
Transmission Lines (i). (ii). What is transmission line and why we can study it using periodic configuration of LC circuits? What is characteristic impedance and why it is important? Do you know any practical example of its use? (ii). Explain the difference between open and short circuit at the end?
Q6: An AM signal of 50 watt power is transmitted in a frequency range 200 – 210 kHz in a transmission channel with power spectral density shown in figure. below. Calculate signal-to-noise ratio in the transmission channel. S,(f) watt/Hz 106 f(kHz) -400 400

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