ZR3 ZL A ZR1 10 Is 2/0° A + -j10 Zc Vab B Now VTH is the voltage between point A and B. What is the value of VAB? Note that, NO currents between A and B, since these two points are disconnected. This is also point A j10 1 Ω m ww ZR3 ZL Is A 11 -j10 ZR1 1Ω Is 2/0° A + VAB Zc B O 2V 3V 4V O5V In this quiz, we will solve a circuit using Thevenin's Theorem step by step. First, take a look at the circuit: j10 ZL 10 ww ZR3 ZR1 1 Ω Is 12/0° A ZR2 10 Ω -j10 Zc 10 The goal is to find Io. To use Thevenin's Theorem, we first identify the load. Since we are looking for the current in R2, R2 is the load. Then, to determine VTH, we replace R2 with an open circuit, so the circuit becomes: j10 ZL 1 Ω ww ZR3 -j10 ZR1 10 1Ω Is 2/0° A + VAB Zc

ZR3 ZL A ZR1 10 Is 2/0° A + -j10 Zc Vab B Now VTH is the voltage between point A and B. What is the value of VAB? Note that, NO currents between A and B, since these two points are disconnected. This is also point A j10 1 Ω m ww ZR3 ZL Is A 11 -j10 ZR1 1Ω Is 2/0° A + VAB Zc B O 2V 3V 4V O5V In this quiz, we will solve a circuit using Thevenin's Theorem step by step. First, take a look at the circuit: j10 ZL 10 ww ZR3 ZR1 1 Ω Is 12/0° A ZR2 10 Ω -j10 Zc 10 The goal is to find Io. To use Thevenin's Theorem, we first identify the load. Since we are looking for the current in R2, R2 is the load. Then, to determine VTH, we replace R2 with an open circuit, so the circuit becomes: j10 ZL 1 Ω ww ZR3 -j10 ZR1 10 1Ω Is 2/0° A + VAB Zc

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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