Presentation is loading. Please wait.

Presentation is loading. Please wait.

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

Published byMyra Harrington Modified over 8 years ago

Similar presentations

Presentation on theme: "7. AC ANALYSIS CIRCUITS by Ulaby & Maharbiz All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press All rights reserved."— Presentation transcript:

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

2 Overview All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

3 Linear Circuits at ac Objective: To determine the steady state response of a linear circuit to ac signals  Sinusoidal input is common in electronic circuits  Any time-varying periodic signal can be represented by a series of sinusoids (Fourier Series)  Time-domain solution method can be cumbersome All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

4 Sinusoidal Signals Useful relations All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

5 Phase Lead/Lag All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

6 Phasor Domain 1. The phasor-analysis technique transforms equations from the time domain to the phasor domain. 2. Integro-differential equations get converted into linear equations with no sinusoidal functions. 3. After solving for the desired variable--such as a particular voltage or current-- in the phasor domain, conversion back to the time domain provides the same solution that would have been obtained had the original integro-differential equations been solved entirely in the time domain. All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

7 Phasor Domain Phasor counterpart of All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

8 Time and Phasor Domain It is much easier to deal with exponentials in the phasor domain than sinusoidal relations in the time domain. You just need to track magnitude/phase, knowing that everything is at frequency  All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

9 Phasor Relation for Resistors Time DomainFrequency Domain Current through a resistor Time domain Phasor Domain All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

10 Phasor Relation for Inductors Time Domain Current through inductor in time domain Time domain Phasor Domain All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

11 Phasor Relation for Capacitors Time Domain Voltage across capacitor in time domain is Time domain Phasor Domain All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

12 Summary of R, L, C All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

13 ac Phasor Analysis General Procedure Using this procedure, we can apply our techniques from dc analysis All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

14 Example 7-4: RL Circuit Cont. All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

15 Example 7-4: RL Circuit cont. All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

16 Impedance and Admittance R = resistance = Re(Z) Impedance is voltage/current X = reactance = Im(Z) Resistor Inductor Capacitor G = conductance = Re(Y) Admittance is current/voltage B = susceptance = Im(Y) All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

17 Impedance Transformation All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

18 Voltage & Current Division All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

19 Cont. All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

20 Example 7-5: Input Impedance (cont.) All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

21 Example 7-8: Thévenin Circuit All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

22 Linear Circuit Properties Thévenin/Norton and Source Transformation Also Valid All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

23 Phasor Diagrams All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

24 Phase-Shift Circuits All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

25 Example 7-10: Cascaded Phase Shifter Choose R such that output is 120 0 ahead of input Solution leads to: All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

26 Node 1Cont. All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

27 (cont.) Cont. All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

28 (cont.) All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

29 Example 7-13: Mesh Analysis by Inspection All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

30 Power Supply Circuit All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

31 Ideal Transformer All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

32 Half-Wave Rectifier All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

33 Full-Wave Rectifier Current flow during first half of cycle Current flow during second half of cycle All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

34 Smoothing RC Filter All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

35 Complete Power Supply All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

36 All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

37 Example 7-19: Multisim Measurement of Phase Shift All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

38 Example 7-19 (cont.) Using Transient Analysis All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

39 All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

40 Summary All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press

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

Similar presentations

CE00436-1 ELECTRICAL PRINCIPLES STEADY STATE ANALYSIS OF SINGLE PHASE CIRCUITS UNDER SINUSOIDAL EXCITATION 1 Steady State response of Pure R,L and C &

CE ELECTRICAL PRINCIPLES STEADY STATE ANALYSIS OF SINGLE PHASE CIRCUITS UNDER SINUSOIDAL EXCITATION 1 Steady State response of Pure R,L and C &
Impedance and Admittance. Objective of Lecture Demonstrate how to apply Thévenin and Norton transformations to simplify circuits that contain one or more.

Impedance and Admittance. Objective of Lecture Demonstrate how to apply Thévenin and Norton transformations to simplify circuits that contain one or more.
Chapter 12 RL Circuits.

Chapter 12 RL Circuits.
Ch4 Sinusoidal Steady State Analysis 4.1 Characteristics of Sinusoidal 4.2 Phasors 4.3 Phasor Relationships for R, L and C 4.4 Impedance 4.5 Parallel and.

Ch4 Sinusoidal Steady State Analysis 4.1 Characteristics of Sinusoidal 4.2 Phasors 4.3 Phasor Relationships for R, L and C 4.4 Impedance 4.5 Parallel and.
Fundamentals of Electric Circuits Chapter 10 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Fundamentals of Electric Circuits Chapter 10 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Phasors Complex numbers LCR Oscillator circuit: An example Transient and Steady States Lecture 18. System Response II 1.

Phasors Complex numbers LCR Oscillator circuit: An example Transient and Steady States Lecture 18. System Response II 1.
Lect17EEE 2021 Phasor Relationships; Impedance Dr. Holbert April 2, 2008.

Lect17EEE 2021 Phasor Relationships; Impedance Dr. Holbert April 2, 2008.
3. ANALYSIS TECHNIQUES CIRCUITS by Ulaby & Maharbiz All rights reserved. Do not reproduce or distribute. © 2013 National Technology and Science Press.

3. ANALYSIS TECHNIQUES CIRCUITS by Ulaby & Maharbiz All rights reserved. Do not reproduce or distribute. © 2013 National Technology and Science Press.
Lesson 19 Impedance. Learning Objectives For purely resistive, inductive and capacitive elements define the voltage and current phase differences. Define.

Lesson 19 Impedance. Learning Objectives For purely resistive, inductive and capacitive elements define the voltage and current phase differences. Define.
Lecture 16 AC Circuit Analysis (1) Hung-yi Lee. Textbook Chapter 6.1.

Lecture 16 AC Circuit Analysis (1) Hung-yi Lee. Textbook Chapter 6.1.
6. Circuit Analysis by Laplace

6. Circuit Analysis by Laplace
Chapter 6(a) Sinusoidal Steady-State Analysis

Chapter 6(a) Sinusoidal Steady-State Analysis
Feb 23, 2007 EEE393 Basic Electrical Engineering K.A.Peker Signals and Systems Introduction EEE393 Basic Electrical Engineering.

Feb 23, 2007 EEE393 Basic Electrical Engineering K.A.Peker Signals and Systems Introduction EEE393 Basic Electrical Engineering.
Lecture 26 Review Steady state sinusoidal response Phasor representation of sinusoids Phasor diagrams Phasor representation of circuit elements Related.

Lecture 26 Review Steady state sinusoidal response Phasor representation of sinusoids Phasor diagrams Phasor representation of circuit elements Related.
8. AC POWER CIRCUITS by Ulaby & Maharbiz. Overview.

8. AC POWER CIRCUITS by Ulaby & Maharbiz. Overview.
ELECTRIC CIRCUIT ANALYSIS - I

ELECTRIC CIRCUIT ANALYSIS - I
Lecture 27 Review Phasor voltage-current relations for circuit elements Impedance and admittance Steady-state sinusoidal analysis Examples Related educational.

Lecture 27 Review Phasor voltage-current relations for circuit elements Impedance and admittance Steady-state sinusoidal analysis Examples Related educational.
Chapter 10 Sinusoidal Steady-State Analysis

Chapter 10 Sinusoidal Steady-State Analysis
ES250: Electrical Science

ES250: Electrical Science
A sinusoidal current source (independent or dependent) produces a current That varies sinusoidally with time.

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

Similar presentations

Ads by Google