ENGR 2405 Chapter 8. Second Order Circuits

Similar documents
To find the step response of an RC circuit

Electric Circuit Theory

Source-Free RC Circuit

Response of Second-Order Systems

MODULE I. Transient Response:

EE292: Fundamentals of ECE

Electric Circuits. Overview. Hani Mehrpouyan,

Physics 116A Notes Fall 2004

Chapter 4 Transients. Chapter 4 Transients

8 sin 3 V. For the circuit given, determine the voltage v for all time t. Assume that no energy is stored in the circuit before t = 0.

Basic RL and RC Circuits R-L TRANSIENTS: STORAGE CYCLE. Engineering Collage Electrical Engineering Dep. Dr. Ibrahim Aljubouri

Inductance, Inductors, RL Circuits & RC Circuits, LC, and RLC Circuits

The RLC circuits have a wide range of applications, including oscillators and frequency filters

Linear Circuits. Concept Map 9/10/ Resistive Background Circuits. 5 Power. 3 4 Reactive Circuits. Frequency Analysis

LAPLACE TRANSFORMATION AND APPLICATIONS. Laplace transformation It s a transformation method used for solving differential equation.

8. Introduction and Chapter Objectives

QUESTION BANK SUBJECT: NETWORK ANALYSIS (10ES34)

ECE 212H1F Circuit Analysis October 30, :10-19: Reza Iravani 02 Reza Iravani 03 Piero Triverio. (Non-programmable Calculators Allowed)

ECE2262 Electric Circuit

ECE Circuit Theory. Final Examination. December 5, 2008


Chapter 10 Sinusoidal Steady State Analysis Chapter Objectives:

Circuits with Capacitor and Inductor

Handout 10: Inductance. Self-Inductance and inductors

Fall 2011 ME 2305 Network Analysis. Sinusoidal Steady State Analysis of RLC Circuits

E40M Review - Part 1

Chapter 10: Sinusoids and Phasors

Electric Circuits Fall 2015 Solution #5

EIT Review. Electrical Circuits DC Circuits. Lecturer: Russ Tatro. Presented by Tau Beta Pi The Engineering Honor Society 10/3/2006 1

Electric Circuits I. Nodal Analysis. Dr. Firas Obeidat

Slide 1 / 26. Inductance by Bryan Pflueger

Revision: June 11, E Main Suite D Pullman, WA (509) Voice and Fax

LECTURE 8 RC AND RL FIRST-ORDER CIRCUITS (PART 1)

Basics of Network Theory (Part-I)

P441 Analytical Mechanics - I. RLC Circuits. c Alex R. Dzierba. In this note we discuss electrical oscillating circuits: undamped, damped and driven.

Chapter 32. Inductance

EE 242 EXPERIMENT 8: CHARACTERISTIC OF PARALLEL RLC CIRCUIT BY USING PULSE EXCITATION 1

Electrical Circuits (2)

EEE105 Teori Litar I Chapter 7 Lecture #3. Dr. Shahrel Azmin Suandi Emel:

General Response of Second Order System

Self-inductance A time-varying current in a circuit produces an induced emf opposing the emf that initially set up the time-varying current.

EE292: Fundamentals of ECE

EE 40: Introduction to Microelectronic Circuits Spring 2008: Midterm 2

Transient Analysis of Electrical Circuits Using Runge- Kutta Method and its Application

RC, RL, and LCR Circuits

Prof. Shayla Sawyer CP08 solution

Problem Set 5 Solutions

Lecture 39. PHYC 161 Fall 2016

vtusolution.in Initial conditions Necessity and advantages: Initial conditions assist

Figure Circuit for Question 1. Figure Circuit for Question 2

Chapter 10 AC Analysis Using Phasors

ELECTRONICS E # 1 FUNDAMENTALS 2/2/2011

Sinusoidal Steady-State Analysis

C R. Consider from point of view of energy! Consider the RC and LC series circuits shown:

First Order RC and RL Transient Circuits

EIT Quick-Review Electrical Prof. Frank Merat

AC analysis. EE 201 AC analysis 1

Inductance, RL Circuits, LC Circuits, RLC Circuits

Introduction to AC Circuits (Capacitors and Inductors)

Initial conditions. Necessity and advantages: Initial conditions assist

Electric Circuits II Sinusoidal Steady State Analysis. Dr. Firas Obeidat

Inductance, RL and RLC Circuits

Phasors: Impedance and Circuit Anlysis. Phasors

Basic. Theory. ircuit. Charles A. Desoer. Ernest S. Kuh. and. McGraw-Hill Book Company

Circuits Advanced Topics by Dr. Colton (Fall 2016)

Mixing Problems. Solution of concentration c 1 grams/liter flows in at a rate of r 1 liters/minute. Figure 1.7.1: A mixing problem.

Feedback Control part 2

Network Analysis V. Mesh Equations Three Loops

Sinusoidal Steady State Analysis (AC Analysis) Part I

EE40 Midterm Review Prof. Nathan Cheung

Chapter 32. Inductance

Chapter 30 INDUCTANCE. Copyright 2012 Pearson Education Inc.

First-order transient

Module 24: Outline. Expt. 8: Part 2:Undriven RLC Circuits

EE102 Homework 2, 3, and 4 Solutions

Time Response Analysis (Part II)

Coupled Electrical Oscillators Physics Advanced Physics Lab - Summer 2018 Don Heiman, Northeastern University, 5/24/2018

Applications of Second-Order Differential Equations

Unit 2: Modeling in the Frequency Domain. Unit 2, Part 4: Modeling Electrical Systems. First Example: Via DE. Resistors, Inductors, and Capacitors

Inductance. Slide 2 / 26. Slide 1 / 26. Slide 4 / 26. Slide 3 / 26. Slide 6 / 26. Slide 5 / 26. Mutual Inductance. Mutual Inductance.

ECE 212H1F Circuit Analysis October 20, :15-19: Reza Iravani 02 Reza Iravani 03 Ali Nabavi-Niaki. (Non-programmable Calculators Allowed)

Chapter 3. Steady-State Equivalent Circuit Modeling, Losses, and Efficiency

Read each question and its parts carefully before starting. Show all your work. Give units with your answers (where appropriate).

Designing Information Devices and Systems II Spring 2016 Anant Sahai and Michel Maharbiz Midterm 2

CS 436 HCI Technology Basic Electricity/Electronics Review

arxiv: v1 [physics.class-ph] 15 Oct 2012

Active Figure 32.3 (SLIDESHOW MODE ONLY)

4/27 Friday. I have all the old homework if you need to collect them.

Dynamic circuits: Frequency domain analysis

Chapter 2. Engr228 Circuit Analysis. Dr Curtis Nelson

Transient Response of a Second-Order System

Electromagnetic Oscillations and Alternating Current. 1. Electromagnetic oscillations and LC circuit 2. Alternating Current 3.

Real Analog Chapter 7: First Order Circuits. 7 Introduction and Chapter Objectives

SINUSOIDAL STEADY STATE CIRCUIT ANALYSIS

ET3-7: Modelling II(V) Electrical, Mechanical and Thermal Systems

DEPARTMENT OF ELECTRICAL AND COMPUTER ENGINEERING RUTGERS UNIVERSITY

Electronic Circuits. Prof. Dr. Qiuting Huang Integrated Systems Laboratory

Unit-2.0 Circuit Element Theory

Chapter 30 Inductance

First and Second Order Circuits. Claudio Talarico, Gonzaga University Spring 2015

Transcription:

ENGR 2405 Chapter 8 Second Order Circuits

Overview The previous chapter introduced the concept of first order circuits. This chapter will expand on that with second order circuits: those that need a second order differential equation. RLC series and parallel circuits will be discussed in this context. The step response of these circuits will be covered as well. Finally the concept of duality will be discussed. 2

Second Order Circuits The previous chapter considered circuits which only required first order differential equations to solve. However, when more than one storage element, i.e. capacitor or inductor is present, the equations require second order differential equations The analysis is similar to what was done with first order circuits This time, though we will only consider DC independent sources 3

Finding Initial and Final Values Working on second order system is harder than first order in terms of finding initial and final conditions. You need to know the derivatives, dv/dt and di/dt as well. Getting the polarity across a capacitor and the direction of current through an inductor is critical. Capacitor voltage and inductor current are always continuous. 4

Source Free Series RLC Consider the circuit shown. The energy at t=0 is stored in the capacitor, represented by V 0 and in the inductor, represented by I 0. 1 0 v 0 idt V C i I 0 0 0 5

Source Free Series RLC Applying KVL around the loop: di 1 t Ri L i d 0 dt C The integral can be eliminated by differentiation: d 2 i R di i 0 2 dt L dt LC Here you can see the second order equation that results 6

Source Free Series RLC Two initial conditions are needed for solving this problem. The initial current is given. The first derivative of the current can also be had: Or 0 Ri 0 L di V0 0 dt di 0 1 dt L RI V 0 0 7

Source Free Series RLC Based on the first order solutions, we can expect that the solution will be in exponential form. The equation will then be: 2 R 1 st Ae s s 0 L LC For which the solutions are: s s 2 2 2 2 1 o 2 o R 2L 0 1 LC 8

Overdamped (α>ω 0 ) When α>ω 0, the system is overdamped In this case, both s 1 and s 2 are real and negative. The response of the system is: s1t 2 i t Ae A e 1 2 From this, we should not expect to see an oscillation s t 9

Critically Damped (α=ω 0 ) When α=ω 0, the system is critically damped. The differential equation becomes: d e i A dt t 1 For which the solution is: i t A At e t 2 1 There are two components to the response, an exponential decay and an exponential decay multiplied by a linear term 10

Underdamped (α<ω 0 ) When α<ω 0, the system is considered to be underdamped In this case, the solution will be: Where t cos sin i t e B t B t j 1 d 2 1 and 2 2 0 ω 0 is often called the undamped natural frequency d ω d is called the damped natural frequency d 11

Damping and RLC networks RLC networks can be charaterized by the following: 1. The behavior of these networks is captured by the idea of damping 2. Oscillatory response is possible due to the presence of two types of energy storage elements. 3. It is typically difficult to tell the difference between damped and critically damped responses. 12

Source Free Parallel RLC Network Now let us look at parallel forms of RLC networks Consider the circuit shown Assume the initial current and voltage to be: 1 0 i 0 I0 v t dt L v V 0 0 13

Source Free Parallel RLC Network Applying KCL to the top node we get: v 1 t dv v d C R L dt 0 Taking the derivative with respect to t gives: 2 d v 1 dv 1 2 dt RC dt LC v 0 The characteristic equation for this is: 2 1 1 s s 0 RC LC 14

Source Free Parallel RLC Network From this, we can find the roots of the characteristic equation to be: s 2 2 1,2 0 1 1 0 2RC LC As in last time, there are three scenarios to consider. 15

Damping For the overdamped case, the roots are real and negetive, so the response is: v t Ae A e s1t 2 1 2 s t For critically damped, the roots are real and equal, so the response is: v t A At e t 2 1 16

Underdamped In the underdamped case, the roots are complex and so the response will be: t cos sin v t e A t A t 1 d 2 To get the values for the constants, we need to know v(0) and dv(0)/dt. To find the second term, we use: 0 V dv 0 I0 C 0 R dt d 17

Underdamped The voltage waveforms will be similar to those shown for the series network. Note that in the series network, we first found the inductor current and then solved for the rest from that. Here we start with the capacitor voltage and similarly, solve for the other variables from that. 18

Step Response of a Series RLC Circuit Now let us consider what happens when a DC voltage is suddenly applied to a second order circuit. Consider the circuit shown. The switch closes at t=0. Applying KVL around the loop for t>0: di L Ri v V dt but dv i C dt s 19

Step Response of a Series RLC Circuit Substituting for i gives: 2 d v R dv v V s 2 dt L dt LC LC This is similar to the response for the source free version of the series circuit, except the variable is different. The solution to this equation is a combination of transient response and steady state v t v t v t t ss 20

Step Response of a Series RLC Circuit The transient response is in the same form as the solutions for the source free version. The steady state response is the final value of v(t). In this case, the capacitor voltage will equal the source voltage. 21

Step Response of a Series RLC Circuit The complete solutions for the three conditions of damping are: s1t s2t v t Vs Ae 1 A2e t v t Vs A1 A2 e s 1 d 2 d (Overdamped) (Critically Damped) v t V A cos t A sin t (Underdamped) The variables A 1 and A 2 are obtained from the initial conditions, v(0) and dv(0)/dt. 22

Step Response of a Parallel RLC Circuit The same treatment given to the parallel RLC circuit yields the same result. The response is a combination of transient and steady state responses: 1t 2t i t Is Ae 1 A2e t i t Is A1 A2t e s 1 d 2 d (Overdamped) (Critally Damped) t i t I A cos t A sin t e (Underdamped) Here the variables A 1 and A 2 are obtained from the initial conditions, i(0) and di(0)/dt. 23

General Second Order Circuits The principles of the approach to solving the series and parallel forms of RLC circuits can be applied to second order circuits in general: The following four steps need to be taken: 1. First determine the initial conditions, x(0) and dx(0)/dt. 24

Second Order Op-amp Circuits 2. Turn off the independent sources and find the form of the transient response by applying KVL and KCL. Depending on the damping found, the unknown constants will be found. 3. We obtain the stead state response as: x t x ss Where x( ) is the final value of x obtained in step 1 25

Second Order Op-amp Circuits II 4. The total response is now found as the sum of the transient response and steady-state response. x t x t x t t ss 26

Duality The concept of duality is a time saving measure for solving circuit problems. It is based on the idea that circuits that appear to be different may be related to each other. They may use the same equations, but the roles of certain complimentary elements are interchanged. The following is a table of dual pairs 27

Duality 28

Duality Once you know the solution to one circuit, you have the solution to the dual circuit. Finding the dual of a circuit can be done with a graphical method: 1. Place a node at the center of each mesh of a given circuit. Place the reference node outside the given circuit. 2. Draw lines between the nodes such that each line crosses an element. Replace the element with its dual 29

Duality 3. To determine the polarity of voltage sources and of current sources, follow this rule: A voltage source that produces a positive (clockwise) mesh current has as its dual a current source whose reference direction is from the ground to the nonreference node. When in doubt, one can refer to the mesh or nodal equations of the dual circuit. 30

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback