In the circuit shown in Fig. P8.49, a generator is8.49connected to a load via a transmission line. Given that10 2, Zline= (4 + j2) S2, and Zload(40 j30) 2:Rs(a) Determine the power factor of the load, the power factor ofthe transmission line, and the power factor of the voltageSource.(b) Specify the capacitance of a shunt capacitor C thatwould raise the power factor of the source to unity whenconnected between terminals (a, b). The source frequencyis 60 Hz.Transmission lineRsLoadbFigure P8.49: Circuit for Problem 8.49.weeer

Redrawing the circuit diagram using the given points:

Answered: In the circuit shown in Fig. P8.49, a…

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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Problem 4-A 80 kHz sinusoidal voltage has zero phase angle and a maximum amplitude of 25 mV. When this voltage is applied across the terminals of a capacitor, the resulting steady-state current has a maximum amplitude of 628.32 μA. a) What is the frequency of the current in radians per second? b) What is the phase angle of the current? c) What is the impedance of the capacitor? d) What is the capacitance of the capacitor in microfarads?
Consider the sinusoidal voltage v(t) = 80 cos (1000nt -30°) V. A. What is the maximum amplitude of the voltage? B. What is the frequency in hertz? C. What is the frequency in radians per second? D. What is the phase angle in radians? E. What is the phase angle in degrees
Write an expression for the complex impedance of a parallel combination of an inductor, L, and a capacitor, C, as a function of frequency. Find the frequency at which the magnitude of the impedance becomes infinite. What happens to the phase of the impedance at this frequency? What current will the parallel combination draw from an ideal sinusoidal voltage source at this frequency?
Consider the sinusoidal voltage A. What is the maximum amplitude of the voltage? B. What is the frequency in hertz? C. What is the frequency in radians per second? v(t) = 80 cos (1000nt - 30°) V.
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Problem 3-An AC circuit is shown. The frequency is 1000 Hz. The source voltage is v(t) = 10 cos(2x1000) of clouent a) Find the impedance seen by the voltage souree b) Find the phasoj current delivered by the source. c) Find the phasor voltage across the resistor, Vr. d) Find the sor voltage across the capacitor, Ve e) Find the voltage across the capacitor, v.(1). 4 kQ 10/ 0 sine 1 kHz C C1 53 nF
A current nource, I, - 18.4 cem(100N) A. a resntor R- 22M1, and an inductor. I. .26 H are al in paratel Assume steady-state conditions exist Att 2.9 ms. find the power being absorbed by the (a) resistor (b) inductor (c) sinusoidal source (a) Pa(2.9ma) -21.83 (b) P2 (2.0ms) - 0 (c) P, (2.0m) - 21 83
36 - By applying a sinusoidal signal of frequency w0 to a linear system, the steady-state output of the system will be: O A) a sinusoidal signal with the same phase, but difference in amplitude and frequency O B) a sinusoidal signal with the same frequency, but difference in amplitude and phase O C) a sinusoidal signal with the same amplitude, but difference in frequency and phase O D) any signal with the difference frequency and amplitude O E) any signal with the same frequency and amplitude
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