Lecture 15: Extra More on Sinusoidal Steady- State Analysis & MT Review Nilsson & Riedel 9.7-9.9, 9.12 ENG17 (Sec. 2): Circuits I Spring 2014 1 May 20,

Slides:

Advertisements

Similar presentations

CE ELECTRICAL PRINCIPLES STEADY STATE ANALYSIS OF SINGLE PHASE CIRCUITS UNDER SINUSOIDAL EXCITATION 1 Steady State response of Pure R,L and C &

Advertisements

Lecture 10: RL & RC Circuits Nilsson & Riedel ENG17 (Sec. 2): Circuits I Spring May 1, 2014.

Lecture 7: Op Amps Intro & Midterm I Review Nilsson & Riedel ENG17 (Sec. 2): Circuits I Spring April 22, 2014.

Impedance and Admittance. Objective of Lecture Demonstrate how to apply Thévenin and Norton transformations to simplify circuits that contain one or more.

Copyright ©2011, ©2008, ©2005 by Pearson Education, Inc. Upper Saddle River, New Jersey All rights reserved. Electric Circuits, Ninth Edition James.

Lecture 4: Nodal Analysis Nilsson & Riedel ENG17 (Sec. 2): Circuits I Spring April 10, 2014.

Lecture 5 Source Transformation Thevenin Equivalent Circuit Norton Equivalent Circuit.

Electronic Circuits, Tenth Edition James W. Nilsson | Susan A. Riedel Copyright ©2015 by Pearson Higher Education. All rights reserved. CHAPTER 9 Sinusoidal.

Lect7EEE 2021 Thévenin's and Norton’s Theorems Dr. Holbert February 6, 2008.

ECE 201 Circuit Theory I1 Assessment Problem #4.1 Page 99 of the text by Nilsson and Riedel.

ECE 201 Circuit Theory I1 Assessment Problem #4.7 Page 102 of the text by Nilsson and Riedel.

1 Circuit Theory Chapter 10 Sinusoidal Steady-State Analysis Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Lecture 10: RL & RC Circuits Nilsson 7.1 – 7.4

ECE 201 Circuit Theory I1 Passive elements in the frequency domain Consider a resistor, R, in the time domain + v - i.

EGR 240 Introduction to Electrical and Computer Engineering Prof. Richard E. Haskell 115 Dodge Hall Prof. Michael P. Polis 102J Science & Engineering Building.

Lecture 26 Review Steady state sinusoidal response Phasor representation of sinusoids Phasor diagrams Phasor representation of circuit elements Related.

Lecture 4: Mesh Current Analysis & Source Transformation Nilsson ENG17 : Circuits I Spring April 9, 2015.

Lecture 3: Resistive Circuits Nilsson & Riedel , 3.7 ENG17 (Sec. 2): Circuits I Spring April 8, 2014.

Lecture 2: Resistive Circuits Nilsson 2.5, , 3.7 ENG17 : Circuits I Spring April 2, 2015.

Phasor Method Aug 24, 2011USC. Outline Review of analysis of DC (Direct Current) circuits Analysis of AC (Alternating Current) circuits – Introduction.

A sinusoidal current source (independent or dependent) produces a current That varies sinusoidally with time.

ECE 3336 Introduction to Circuits & Electronics Supplementary Lecture Phasor Analysis Dr. Han Le ECE Dept.

ECE 201 Circuit Theory 11 Source Transformation to Solve a Circuit Find the power associated with the 6 V source. State whether the 6 V source is absorbing.

Circuits 2 Overview January 11, 2005 Harding University Jonathan White.

CIRCUITS by Ulaby & Maharbiz

The V  I Relationship for a Resistor Let the current through the resistor be a sinusoidal given as Is also sinusoidal with amplitude amplitudeAnd.

Lecture 16: Sinusoidal Sources and Phasors Nilsson , App. B ENG17 : Circuits I Spring May 21, 2015.

Lecture 13: Complex Numbers and Sinusoidal Analysis Nilsson & Riedel Appendix B, ENG17 (Sec. 2): Circuits I Spring May 13, 2014.

CIRCUIT ANALYSIS USING LAPLACE TRANSFORM

1 ECE 3336 Introduction to Circuits & Electronics Note Set #10 Phasors Analysis Fall 2012, TUE&TH 4:00-5:30 pm Dr. Wanda Wosik.

Lecture 12: RLC Circuits – Part Deux Nilsson & Riedel ENG17 (Sec. 2): Circuits I Spring May 6, 2014.

Lecture 14: More on Sinusoidal Steady-State Analysis Nilsson & Riedel ENG17 (Sec. 2): Circuits I Spring May 15, 2014.

ENG17 (Sec. 1): Circuits I Summer

Lecture 6: Thevenin and Norton Equivalents, Maximum Power Transfer, & Superposition Nilsson & Riedel ENG17 (Sec. 2): Circuits I Spring

Lecture 17: Analysis with Sinusoidal Sources, Transformers Nilsson ENG17 : Circuits I Spring May 26, 2015.

E E 2415 Lecture 9 Phasor Circuit Analysis, Effective Value and Complex Power: Watts, VAR’s and Volt-Amperes.

Lecture 18: Sinusoidal Steady-State Power Nilsson & Riedel ENG17 (Sec. 2): Circuits I Spring May 29, 2014.

1 Node-Voltage Analysis Use KCL to write a  i in =  i out equation at each node (except the reference node)

Chapter 4 AC Network Analysis Tai-Cheng Lee Electrical Engineering/GIEE 1.

1 ECE 3144 Lecture 32 Dr. Rose Q. Hu Electrical and Computer Engineering Department Mississippi State University.

ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Fourth Edition, by Allan R. Hambley, ©2008 Pearson Education, Inc. Lecture 3 Circuit Laws, Voltage.

Complex Impedances Sinusoidal Steady State Analysis ELEC 308 Elements of Electrical Engineering Dr. Ron Hayne Images Courtesy of Allan Hambley and Prentice-Hall.

4.9 Source Transformations The Node-Voltage Method and the Mesh-Current Method are powerful techniques for solving circuits. We are still interested in.

1 Lecture #6 EGR 272 – Circuit Theory II Read: Chapter 9 and Appendix B in Electric Circuits, 6 th Edition by Nilsson Using Phasors to Add Sinusoids Sinusoidal.

A sinusoidal current source (independent or dependent) produces a current That varies sinusoidally with time.

Lecture 8: Op Amps and Circuits Nilsson

7. AC ANALYSIS CIRCUITS by Ulaby & Maharbiz All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press All rights reserved.

Electrical Power System SMJE The Importance of Electrical Power Importance in daily live Importance in industrial Importance in security Importance.

EE101 Introduction to Electronic Circuits Fall Quarter 2012 Lecture 15 on W, November 14, 2012 Professor Sung Mo (Steve) Kang Office: BE-235; Phone (831)

1. Using superposition, find the current I through the 10 resistor for the network CLASS ASSIGNMENT SUPERPOSITION THEOREM.

ELECTRIC CIRCUITS EIGHTH EDITION JAMES W. NILSSON & SUSAN A. RIEDEL.

Lecture 17: Mutual Inductance and Transformers Nilsson & Riedel 6.4, 6.5, 9.10, 9.11 ENG17 (Sec. 2): Circuits I Spring May 27, 2014.

Lecture 20: Review – ENG17 ENG17 (Sec. 2): Circuits I Spring June 5, 2014.

Alternating Current Circuits Based on Serway and Jewett e6.

ELECTRIC CIRCUITS EIGHTH EDITION

Dynamic Presentation of Key Concepts Module 8 – Part 3 AC Circuits – Solution Techniques Filename: DPKC_Mod08_Part03.ppt.

Impedance V = I Z, Z is impedance, measured in ohms (  ) Resistor: –The impedance is R Inductor: –The impedance is j  L Capacitor: –The impedance is.

ELECTRIC CIRCUITS EIGHTH EDITION JAMES W. NILSSON & SUSAN A. RIEDEL.

ECE 1270: Introduction to Electric Circuits

Lecture 13 - Step Response of Series and Parallel RLC Circuits

Passive elements in the frequency domain

Time Domain to Phasor Domain (Linear Transformation)

Lecture 05 - Thévenin and Norton Equivalent Circuits

Chapter 10 – AC Circuits Recall: Element Impedances and Admittances

Chapter 10 – AC Circuits Recall: Element Impedances and Admittances

CIRCUITS by Ulaby & Maharbiz

Superposition Theorem

E E 2415 Lecture 9 Phasor Circuit Analysis, Effective Value and Complex Power: Watts, VAR’s and Volt-Amperes.

ECE 2202 Circuit Analysis II

INC 111 Basic Circuit Analysis

Presentation transcript:

Lecture 15: Extra More on Sinusoidal Steady- State Analysis & MT Review Nilsson & Riedel , 9.12 ENG17 (Sec. 2): Circuits I Spring May 20, 2014

Overview Source Transformations Node-Voltage Mesh-Current Phasor Diagrams MT Review 2

Source Transformations 3 Same as before, but now with impedances

Thevenin-Norton Equivalents 4

Example 5 Find using source transformation

Example 6 Find Thevenin Equivalent

Overview Source Transformations Node-Voltage Mesh-Current Phasor Diagrams MT Review 7

Node-Voltage Example 8 Find I a, I b, I c

Overview Source Transformations Node-Voltage Mesh-Current Phasor Diagrams MT Review 9

Mesh-Current Example 10 Find V a, V b, V c

Overview Source Transformations Node-Voltage Mesh-Current Phasor Diagrams MT Review 11

Phasor Diagrams 12

Example 13 Use phasor diagram to find R that will cause resistor current (i R ) to lag the source current (i S ) by 45° when ω = 5 krad / s.

Overview Source Transformations Node-Voltage Mesh-Current Phasor Diagrams MT Review 14

Difficulties 15

Op Amp Circuits 16

Sequential Switching 17

Unbounded Response 18

RLC Circuits 19

Phasors 20

Extra Office Hours Tomorrow, Wednesday 3-5pm Kemper