Given the parallel-connected RLC circuit below: a. Calculate the resonance frequency. b. Calculate the supply current, and the individual current flowing through the coil and capacitor, when the circuit is resonating. c. Draw the supply current transient along the frequency-axis when the input frequency sweeps from 0Hz to the resonant frequency and beyond (>1.5fo). d. Calculate the Q-factor. e. Draw the bandwidth profiles for y-axis being current (A), voltage (V), and maximum k-value (impedance), and it's respective cut-off frequencies. V = 540°Vrr rms 0.2 Ω www. 100MH3 coil Figure 2. Parallel-connected RLC circuit. 2 μF

Given the parallel-connected RLC circuit below: a. Calculate the resonance frequency. b. Calculate the supply current, and the individual current flowing through the coil and capacitor, when the circuit is resonating. c. Draw the supply current transient along the frequency-axis when the input frequency sweeps from 0Hz to the resonant frequency and beyond (>1.5fo). d. Calculate the Q-factor. e. Draw the bandwidth profiles for y-axis being current (A), voltage (V), and maximum k-value (impedance), and it's respective cut-off frequencies. V = 540°Vrr rms 0.2 Ω www. 100MH3 coil Figure 2. Parallel-connected RLC circuit. 2 μF

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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