Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 ECE 3144 Lecture 30 Dr. Rose Q. Hu Electrical and Computer Engineering Department Mississippi State University.

Published byDaniel Whitehead Modified over 8 years ago

Similar presentations

Presentation on theme: "1 ECE 3144 Lecture 30 Dr. Rose Q. Hu Electrical and Computer Engineering Department Mississippi State University."— Presentation transcript:

1 1 ECE 3144 Lecture 30 Dr. Rose Q. Hu Electrical and Computer Engineering Department Mississippi State University

2 2 Reminder from Lecture 29 Representation of sinusoidal functions Acos(  t+  ) Steady state response of Sinusoid functions i(t) v(t)=V M cos  t

3 3 Complex Number A complex number a+jb: –a = Re(a+jb) is the real part of the complex number a+jb –b=Im(a+jb) is the imaginary part of the complex number a+bj Complex number relationships a+bj = re j  a=rcos , b=rsin  Now we want to establish a relationship between time-varying sinusoidal functions and complex numbers through Euler’s equation cos  t = Re(e j  t ) sin  t = Im(e j  t )

4 4 Complex forcing function Think about applying a complex forcing function v(t) = V M cos(  t+  ) + jV M sin(  t+  ) to a linear circuit network. –We expect a complex forcing function to produce a complex response; –The real part of the forcing function, V M cos(  t+  ), will produce the real part of the response I M cos(  t+  ) –The imaginary part of the forcing function, jV M sin(  t+  ), will result in the imaginary portion of the response jI M sin(  t+  ) –Based on the superposition, the response to the complex forcing function v(t) = V M cos(  t+  ) + jV M sin(  t+  ) is i(t) = I M cos(  t+  ) + jI M sin(  t+  ) Applying Euler’s identity –v(t) = V M cos(  t+  ) + jV M sin(  t+  )= V M e j(  t+  ) –i(t) =I M cos(  t+  ) + jI M sin(  t+  ) = I M e j(  t+  ) –The complex source and response are illustrated as v(t) = V M e j(  t+  ) i(t) =I M e j(  t+  )

5 5 i(t) v(t)=V M cos  t Apply complex forcing function to the problem as shown in Lecture 29 Once gain, let us determine the current in the RL circuit. However, rather than applying V M cos  t, we will apply V M e j  t as the input signal The forced response of input V M e j  t will be of form i(t) = I m e j(  t+  ), where I M and  need to be decided. The KVL equation for the circuit is Substituting i(t) = I m e j(  t+  ) into the above differential equation =>, converting the right side to exponential form => => and Since the actual forcing function was V M cos  t, the actual response is the real part of the complex response

6 6 Phasor By introducing in complex forcing function, the differential equations becomes simple algebraic equations with coefficients as complex numbers. The actual response is the real part of the complex response from the complex forcing function. For the given example, the forcing function is v(t) = V M e j  t and steady sate response is i(t) = I m e j(  t+  ). The steady state response in the network has the same form and the same frequency with the forcing function. So from now on, we will simply drop the frequency e j  t since each term in the equation will contain it. Thus every voltage and current can be fully described by a magnitude and phase. This abbreviated complex representation is called a phasor. For a voltage v(t)=V M cos(  t+  ), a current i(t)=I M cos(  t+  ), –Their exponential notations are v(t) = Re[V M e i(  t+  ) ], i(t) = Re[I M e i(  t+  ) ] –Their phasor notations are Phasor operation: v(t) represents a voltage in time domain while phasor V represents the voltage in the frequency domain. Time DomainFrequency Domain Acos(  t  ) Asin(  t  )

7 7 Phasor relationship for a resistor R The voltage-current relationship is known as v(t) = Ri(t) Applying the complex voltage source results in the complex current, the above equation becomes: => The above equation can be written in phasor form as V=RI Where (2) (1) (3) From equation (2) we see that  v =  I. Thus the current through and voltage across a resistor are in phase.

8 8 Phasor relationship for an inductor L The voltage-current relationship for an inductor is Applying the complex voltage source results in the complex current, the above equation becomes: => (1) Equation (1) in phasor notation is V = j  LI (2) Note that Thus the voltage and current for an inductor are 90 o out of phase. Actually I lags V by 90 o for an inductor.

9 9 Phasor relationship for a capacitor C The voltage-current relationship for an inductor is Applying the complex voltage source results in the complex current, the above equation becomes: => (1) Equation (1) in phasor notation is I = j  CV (2) Note that Thus the voltage and current for a capacitor are 90 o out of phase. Actually V lags I by 90 o for a capacitor.

10 10 Homework for lecture 30 Problems 7.5, 7.6, 7.7 Due April 8

Download ppt "1 ECE 3144 Lecture 30 Dr. Rose Q. Hu Electrical and Computer Engineering Department Mississippi State University."

Similar presentations

Math Review with Matlab:

Math Review with Matlab:
Chapter 5. Objective of Lecture Describe the mathematical relationships between ac voltage and ac current for a resistor, capacitor, and inductor. Discuss.

Chapter 5. Objective of Lecture Describe the mathematical relationships between ac voltage and ac current for a resistor, capacitor, and inductor. Discuss.
Lecture 28 Review: Frequency domain circuit analysis Superposition Frequency domain system characterization Frequency Response Related educational modules:

Lecture 28 Review: Frequency domain circuit analysis Superposition Frequency domain system characterization Frequency Response Related educational modules:
Chapter 10 Sinusoidal Steady-State Analysis Engineering Circuit Analysis Sixth Edition W.H. Hayt, Jr., J.E. Kemmerly, S.M. Durbin Copyright © 2002 McGraw-Hill,

Chapter 10 Sinusoidal Steady-State Analysis Engineering Circuit Analysis Sixth Edition W.H. Hayt, Jr., J.E. Kemmerly, S.M. Durbin Copyright © 2002 McGraw-Hill,
ECE 3336 Introduction to Circuits & Electronics

ECE 3336 Introduction to Circuits & Electronics
Department of Electronic Engineering BASIC ELECTRONIC ENGINEERING Steady-State Sinusoidal Analysis.

Department of Electronic Engineering BASIC ELECTRONIC ENGINEERING Steady-State Sinusoidal Analysis.
EE40 Summer 2006: Lecture 5 Instructor: Octavian Florescu 1 Announcements Lecture 3 updated on web. Slide 29 reversed dependent and independent sources.

EE40 Summer 2006: Lecture 5 Instructor: Octavian Florescu 1 Announcements Lecture 3 updated on web. Slide 29 reversed dependent and independent sources.
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.
STEADY STATE AC CIRCUIT ANALYSIS

STEADY STATE AC CIRCUIT ANALYSIS
Slide 1EE100 Summer 2008Bharathwaj Muthuswamy EE100Su08 Lecture #11 (July 21 st 2008) Bureaucratic Stuff –Lecture videos should be up by tonight –HW #2:

Slide 1EE100 Summer 2008Bharathwaj Muthuswamy EE100Su08 Lecture #11 (July 21 st 2008) Bureaucratic Stuff –Lecture videos should be up by tonight –HW #2:
Lecture 191 Sinusoids (7.1); Phasors (7.3); Complex Numbers (Appendix) Prof. Phillips April 16, 2003.

Lecture 191 Sinusoids (7.1); Phasors (7.3); Complex Numbers (Appendix) Prof. Phillips April 16, 2003.
Lect17EEE 2021 Phasor Relationships; Impedance Dr. Holbert April 2, 2008.

Lect17EEE 2021 Phasor Relationships; Impedance Dr. Holbert April 2, 2008.
1 Sinusoidal Functions, Complex Numbers, and Phasors Discussion D14.2 Sections 4-2, 4-3 Appendix A.

1 Sinusoidal Functions, Complex Numbers, and Phasors Discussion D14.2 Sections 4-2, 4-3 Appendix A.
R,L, and C Elements and the Impedance Concept

R,L, and C Elements and the Impedance Concept
Chapter 6(a) Sinusoidal Steady-State Analysis

Chapter 6(a) Sinusoidal Steady-State Analysis
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.
Source-Free RLC Circuit

Source-Free RLC Circuit
Parallel RLC Network. Objective of Lecture Derive the equations that relate the voltages across a resistor, an inductor, and a capacitor in parallel as:

Parallel RLC Network. Objective of Lecture Derive the equations that relate the voltages across a resistor, an inductor, and a capacitor in parallel as:
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

Similar presentations

Ads by Google