The series RLC circuit of Figure Q3 contains a resistorof R=202, an inductor of L=10MH and a capacitor ofC=600µF. The supply is 24V, 50HZ.R LCFigure Q3Using your calculated current that flows through thecircuit of Figure Q3, calculate the following:The voltage across the inductor (magnitude and angle)The voltage across the capacitor (magnitude and angle).Determine the resonant frequency.At resonance, what is the total impedance of the circuit?A three-phase balanced load of phase impedance withmagnitude 200 Q and power factor 0.5 is connected indelta. This load is connected to a 420 V (line voltage),50 Hz, 3-phase supply. Calculate:The magnitude of the phase voltage,The load phase angleThe magnitudes and phase angles of each load current.(The angle of phase voltage 1 = 25°)

As there are multiple questions, we shall answer only the first question. i.e the numerical on…

The series RLC circuit of Figure Q3 contains a resistor of R=200, an inductor of L=10mH and a capacitor of C=600µF. The supply is 24V, 50Hz. R C Figure Q3 Using your calculated current that flows through the circuit of Figure Q3, calculate the following: The voltage across the inductor (magnitude and angle) The voltage across the capacitor (magnitude and angle).

The series RLC circuit of Figure Q3 contains a resistor of R=200, an inductor of L=10mH and a capacitor of C=600µF. The supply is 24V, 50Hz. R C Figure Q3 Using your calculated current that flows through the circuit of Figure Q3, calculate the following: The voltage across the inductor (magnitude and angle) The voltage across the capacitor (magnitude and angle).

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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