Module 2. DC Circuit. Version 2 EE IIT, Kharagpur

Similar documents
Module 2. DC Circuit. Version 2 EE IIT, Kharagpur

mywbut.com Lesson 6 Wye (Y) - Delta ( ) OR Delta ( )-Wye (Y) Transformations

EE-201 Review Exam I. 1. The voltage Vx in the circuit below is: (1) 3V (2) 2V (3) -2V (4) 1V (5) -1V (6) None of above

Module 2. DC Circuit. Version 2 EE IIT, Kharagpur

mywbut.com Mesh Analysis

D C Circuit Analysis and Network Theorems:

UNIT 4 DC EQUIVALENT CIRCUIT AND NETWORK THEOREMS

Module 2. DC Circuit. Version 2 EE IIT, Kharagpur

CHAPTER FOUR CIRCUIT THEOREMS

1.7 Delta-Star Transformation

Lecture Notes on DC Network Theory

Engineering Fundamentals and Problem Solving, 6e

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

CHAPTER 4. Circuit Theorems

POLYTECHNIC UNIVERSITY Electrical Engineering Department. EE SOPHOMORE LABORATORY Experiment 2 DC circuits and network theorems

Chapter 33 - Electric Fields and Potential. Chapter 34 - Electric Current

Module 2. DC Circuit. Version 2 EE IIT, Kharagpur

Chapter 18. Direct Current Circuits

CURRENT SOURCES EXAMPLE 1 Find the source voltage Vs and the current I1 for the circuit shown below SOURCE CONVERSIONS

EECE251 Circuit Analysis I Lecture Integrated Program Set 3: Circuit Theorems

Sinusoidal Steady State Analysis (AC Analysis) Part II

11. AC Circuit Power Analysis

Chapter 5 Objectives

Thevenin Norton Equivalencies - GATE Study Material in PDF

Series & Parallel Resistors 3/17/2015 1

ENGR 2405 Class No Electric Circuits I

Sinusoidal Response of RLC Circuits

ECE2262 Electric Circuits. Chapter 5: Circuit Theorems

3.1 Superposition theorem

Basic Electrical Circuits Analysis ECE 221

DC STEADY STATE CIRCUIT ANALYSIS

Fundamentals of Electric Circuits, Second Edition - Alexander/Sadiku

Circuit Theorems Overview Linearity Superposition Source Transformation Thévenin and Norton Equivalents Maximum Power Transfer

ECE2262 Electric Circuits

Chapter 2. Engr228 Circuit Analysis. Dr Curtis Nelson

2. Basic Components and Electrical Circuits

Chapter 4 Circuit Theorems: Linearity & Superposition

Switch or amplifies f. Capacitor i. Capacitance is measured in micro/pico farads ii. Filters frequencies iii. Stores electrical energy

Chapter 5. Department of Mechanical Engineering

Chapter 7 Direct-Current Circuits

ESE319 Introduction to Microelectronics Common Emitter BJT Amplifier

Chapter 10 AC Analysis Using Phasors

ELECTRICITY. Electric Circuit. What do you already know about it? Do Smarty Demo 5/30/2010. Electric Current. Voltage? Resistance? Current?

E40M Review - Part 1

Basics of Network Theory (Part-I)

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

Capacitance. A different kind of capacitor: Work must be done to charge a capacitor. Capacitors in circuits. Capacitor connected to a battery

As light level increases, resistance decreases. As temperature increases, resistance decreases. Voltage across capacitor increases with time LDR

Experiment #6. Thevenin Equivalent Circuits and Power Transfer

Physics 1214 Chapter 19: Current, Resistance, and Direct-Current Circuits

EXPERIMENT 12 OHM S LAW

Outline. Week 5: Circuits. Course Notes: 3.5. Goals: Use linear algebra to determine voltage drops and branch currents.

EE313 Fall 2013 Exam #1 (100 pts) Thursday, September 26, 2013 Name. 1) [6 pts] Convert the following time-domain circuit to the RMS Phasor Domain.

Chapter 10: Sinusoidal Steady-State Analysis

.. Use of non-programmable scientific calculator is permitted.

Physics for Scientists & Engineers 2

EE 3120 Electric Energy Systems Study Guide for Prerequisite Test Wednesday, Jan 18, pm, Room TBA

Homework 3 Solution. Due Friday (5pm), Feb. 14, 2013

Electric Circuit Theory

CHAPTER ONE. 1.1 International System of Units and scientific notation : Basic Units: Quantity Basic unit Symbol as shown in table 1

Study Notes on Network Theorems for GATE 2017

Sinusoidal Steady State Analysis (AC Analysis) Part I

Series, Parallel, and other Resistance

BASIC NETWORK ANALYSIS

Analysis of a single-loop circuit using the KVL method

Chapter 25 Electric Currents and. Copyright 2009 Pearson Education, Inc.

EE292: Fundamentals of ECE

Chapter 2 Analysis Methods

DC CIRCUIT ANALYSIS. Loop Equations

Chapter 4. Techniques of Circuit Analysis

EECE208 Intro to Electrical Engineering Lab. 5. Circuit Theorems - Thevenin Theorem, Maximum Power Transfer, and Superposition

DC motors. 1. Parallel (shunt) excited DC motor

Chapter 21 Electric Current and Circuits

SOME USEFUL NETWORK THEOREMS

R 2, R 3, and R 4 are in parallel, R T = R 1 + (R 2 //R 3 //R 4 ) + R 5. C-C Tsai

Charge The most basic quantity in an electric circuit is the electric charge. Charge is an electrical property of the atomic particles of which matter

DEPARTMENT OF COMPUTER ENGINEERING UNIVERSITY OF LAHORE

Discussion Question 6A

Series/Parallel Circuit Simplification: Kirchoff, Thevenin & Norton

DC NETWORK THEOREMS. Learning Objectives

PHYSICS 171. Experiment 3. Kirchhoff's Laws. Three resistors (Nominally: 1 Kilohm, 2 Kilohm, 3 Kilohm).

1. Review of Circuit Theory Concepts

EE105 Fall 2014 Microelectronic Devices and Circuits

Preamble. Circuit Analysis II. Mesh Analysis. When circuits get really complex methods learned so far will still work,

Test Review Electricity

ECE2262 Electric Circuits. Chapter 1: Basic Concepts. Overview of the material discussed in ENG 1450

CHAPTER: 3 CURRENT ELECTRICITY

Chapter 28. Direct Current Circuits

Closed loop of moving charges (electrons move - flow of negative charges; positive ions move - flow of positive charges. Nucleus not moving)

Homework 1 solutions

Notes on Electricity (Circuits)

Science Olympiad Circuit Lab

Coulomb s constant k = 9x10 9 N m 2 /C 2

ELEC 250: LINEAR CIRCUITS I COURSE OVERHEADS. These overheads are adapted from the Elec 250 Course Pack developed by Dr. Fayez Guibaly.

Electric Circuits I. Midterm #1 Examination

Chapter 3: Electric Current and Direct-Current Circuit

Chapter 7. Chapter 7

ID # NAME. EE-255 EXAM 3 April 7, Instructor (circle one) Ogborn Lundstrom

Transistor Characteristics and A simple BJT Current Mirror

ECE 2100 Circuit Analysis

Transcription:

Module 2 DC Circuit

Lesson 7 Superposition Theorem in the context of dc voltage and current sources acting in a resistive network

Objectives Statement of superposition theorem and its application to a resistive d.c network containing more than one source in order to find a current through a branch or to find a voltage across the branch. L.7.1 Introduction If the circuit has more than one independent (voltage and/or current) sources, one way to determine the value of variable (voltage across the resistance or current through a resistance) is to use nodal or mesh current methods as discussed in detailed in lessons 4 and 5. Alternative method for any linear network, to determine the effect of each independent source (whether voltage or current) to the value of variable (voltage across the resistance or current through a resistance) and then the total effects simple added. This approach is known as the superposition. In lesson-3, it has been discussed the properties of a linear circuit that satisfy (i) homogeneity property [response of output due to input= α ut () equals to α times the response of output due to input= ut (), S( α u( t )) = α Sut ( ( )) for all α ; and ut () = input to the system] (ii) additive property [that is the response of u1() t + u2() t equals the sum of the response of u () t 1 and the response of u () t 2, Su ( 1( t) + u2( t)) = Su ( 1( t)) + Su ( 2( t)) ]. Both additive and multiplicative properties of a linear circuit help us to analysis a complicated network. The principle of superposition can be stated based on these two properties of linear circuits. L.7.1.1 Statement of superposition theorem In any linear bilateral network containing two or more independent sources (voltage or current sources or combination of voltage and current sources ), the resultant current / voltage in any branch is the algebraic sum of currents / voltages caused by each independent sources acting along, with all other independent sources being replaced meanwhile by their respective internal resistances. Superposition theorem can be explained through a simple resistive network as shown in fig.7.1 and it has two independent practical voltage sources and one practical current source.

One may consider the resistances R 1 and R 3 are the internal resistances of the voltage sources whereas the resistance R 4 is considered as internal resistance of the current source. The problem is to determine the response I in the in the resistor R 2. The current I can be obtained from I= I + I + I 1 2 s due to E ( alone) due to E ( alone) due to I ( alone) according to the application of the superposition theorem. It may be noted that each independent source is considered at a time while all other sources are turned off or killed. To kill a voltage source means the voltage source is replaced by its internal resistance (i.e. R1 or R 3 ; in other words E1 or E 2 should be replaced temporarily by a short circuit) whereas to kill a current source means to replace the current source by its internal resistance (i.e. R ; in other words I should be replaced temporarily by an open circuit). 4 s Remarks: Superposition theorem is most often used when it is necessary to determine the individual contribution of each source to a particular response. L.7.1.2 Procedure for using the superposition theorem Step-1: Retain one source at a time in the circuit and replace all other sources with their internal resistances. Step-2: Determine the output (current or voltage) due to the single source acting alone using the techniques discussed in lessons 3 and 4. Step-3: Repeat steps 1 and 2 for each of the other independent sources. Step-4: Find the total contribution by adding algebraically all the contributions due to the independent sources.

L.7.2 Application of superposition theorem Example- L.7.1 Consider the network shown in fig. 7.2(a). Calculate I ab superposition theorem. and V using cg Solution: Voltage Source Only (retain one source at a time): First consider the voltage source V a that acts only in the circuit and the current source is replaced by its internal resistance ( in this case internal resistance is infinite ( )). The corresponding circuit diagram is shown in fig.7.2(b) and calculate the current flowing through the a-b branch.

7 23 Req = [( Rac + Rcb) Rab] + Rbg = + 2 = Ω 8 8 3 I = A = 1.043A; Now current through a to b, is given by 23 8 7 24 Iab = = 0.913A ( a to b) 8 23 I acb = 1.043 0.913 = 0. 13A Voltage across c-g terminal : V = V + V = 2 1.043+ 4 0.13 = 2.61volts (Note: we are moving opposite to the cg bg cb direction of current flow and this indicates there is rise in potential). Note c is higher potential than g. Current source only (retain one source at a time): Now consider the current source Is = 2 A only and the voltage source V a is replaced by its internal resistance which is zero in the present case. The corresponding the simplified circuit diagram is shown below (see fig.7.2(c)& fig.7.2(d)).

Current in the following branches: (14 / 3) 2 3Ω resistor = = 1.217A ; 4Ω resistor = 2 1.217 = 0.783A (14 / 3) + 3 2 1Ω resistor = 0.783 = 0.522 A ( b to a) 3 Voltage across 3Ω resistor (c & g terminals) V = 1.217 3 = 3.651volts The total current flowing through 1Ω resistor (due to the both sources) from a to b = 0.913 (due to voltage source only; current flowing from a to b ) 0.522 ( due to current source only; current flowing from b to a ) = 0.391 A. Total voltage across the current source V = 2.61volt (due to voltage source ; c is cg higher potential than g ) + 3.651 volt (due to current source only; c is higher potential than g ) = 6.26volt. Example L.7.2 For the circuit shown in fig.7.3(a), the value of Vs 1 and I s are fixed. When V s2 = 0, the current I = 4 A. Find the value of I when Vs 2 = 32V. cg

Solution: Let us assume that the current flowing 6 Ω resistors due to the voltage and current sources are given by (assume circuit linearity) = α + β + η = + + (7.1) I Vs 1 Vs 2 Is I( due to V ) I( due to V I ( due to I ) s1 s2) where the parameters α, β, and η represent the positive constant numbers. The parameters α and β are the total conductance of the circuit when each voltage source acting alone in the circuit and the remaining sources are replaced by their internal resistances. On the other hand, the parameter η represents the total resistance of the circuit when the current source acting alone in the circuit and the remaining voltage sources are replaced by their internal resistances. The expression (7.1) for current I is basically written from the concept of superposition theorem. From the first condition of the problem statement one can write an expression as (when the voltage source V s1 and the current source I s acting jointly in the circuit and the other voltage source V s2 is not present in the circuit.) = = α + η = + (Note both the sources are fixed) (7.2) 4 I Vs1 Is I( due to Vs1 ) I( due to Is ) Let us assume the current following through the 6 Ω resistor when all the sources acting in the circuit with V s2 = 32V is given by the expression (7.1). Now, one can determine the current following through 6 Ω resistor when the voltage source V s2 = 32V acting alone in the circuit and the other sources are replaced by their internal resistances. For the circuit shown in fig.7.3 (b), the current delivered by the voltage source to the 6 Ω resistor is given by s I V 32 S 2 1 = = = Req ( 8 8) + 4 4 A (7.3) The current following through the 6 Ω due to the voltage source V S 2 = 32V only is 2 A (flowing from left to right; i,e. in the direction as indicated in the figure 7.3(b)). Using equation (7.1), the total current I flowing the 6 Ω resistor can be obtained as

I = αvs 1+ βvs 2 + ηis = I ( due to Vs1) + I ( due to V + I s2) ( due to Is) = I ( due to Vs1) + I ( due to Is) + I ( due to Vs 2) = 4A + 2A = 6A (note: I ( due to V 1 ) + I ( ) 4 s due to I = A (see eq. 7.2) s Example L.7.3: Calculate the current I ab flowing through the resistor3 Ω as shown in fig.7.4(a), using the superposition theorem. Solution: Assume that the current source 3 A ( left to the 1volt source) is acting alone in the circuit and the internal resistances replace the other sources. The current flowing through 3 Ω resistor can be obtained from fig.7.4(b) and it is given by I 2 6 = = (7.4) 7 7 1( due to 3 A current source ) 3 A( a to b)

Current flowing through 3 Ω resistor due to 2V source (only) can be obtained from fig.7.4(c) and it is seen from no current is flowing. I2( due to 2 V voltage source) = 0 A( a to b) (7.5) Current through 3Ω resistor due to 1 V voltage source only (see fig.7.3(d)) is given by 1 I3( due to 1 V voltage source ) = A( b to a) (7.6) 7 Current through 3Ω resistor due to 3 A current source only (see fig.7.3(e)) is obtained by

I 2 6 = 3 = A( a to b (7.7) 7 7 4( due to 3 A current source ) ) Current through 3Ω resistor due to 2V voltage source only (see fig.7.3(f)) is given by 2 I5( due to 2 V voltage source ) = A ( b to a) (7.8) 7 Resultant current I ab flowing through 3Ω resistor due to the combination of all sources is obtained by the following expression (the algebraic sum of all currents obtained in eqs. (7.4)-(7.8) with proper direction of currents) I = I + I + I + I ab 1( due to 3 A current source) 2( due to 2 V voltage source) 3( due to 1 V voltage source) 4( due to 3 A current source) + I 5( due to 2 V voltage source) 6 1 6 2 9 = + 0 + = = 1.285( atob) 7 7 7 7 7

L.7.3 Limitations of superposition Theorem Superposition theorem doesn t work for power calculation. Because power calculations involve either the product of voltage and current, the square of current or the square of the voltage, they are not linear operations. This statement can be explained with a simple example as given below. Example: Consider the circuit diagram as shown in fig.7.5. Using superposition theorem one can find the resultant current flowing through 12Ω resistor is zero and consequently power consumed by the resistor is also zero. For power consumed in an any resistive element of a network can not be computed using superposition theorem. Note that the power consumed by each individual source is given by P = 12 watts; P = 12 watts W1( due to 12 V source( left)) W 2( due to 12 V source( right )) The total power consumed by 12 Ω = 24 watts (applying superposition theorem). This result is wrong conceptually. In fact, we may use the superposition theorem to find a current in any branch or a voltage across any branch, from which power is then can be calculated. Superposition theorem can not be applied for non linear circuit ( Diodes or Transistors ). This method has weaknesses:- In order to calculate load current I L or the load voltage VL for the several choices of load resistance RL of the resistive network, one needs to solve for every source voltage and current, perhaps several times. With the simple circuit, this is fairly easy but in a large circuit this method becomes an painful experience. L.7.4 Test Your Understanding [Marks: 40] T.7.1 When using the superposition theorem, to find the current produced independently by one voltage source, the other voltage source(s) must be ----------- and the current source(s) must be --------------. [2]

T.7.2 For a linear circuit with independent sources p1, p2, p 3 p n and if y i is the response of the circuit to source p i, with all other independent sources set to zero), then resultant response y =. [1] T.7.3 Use superposition theorem to find the value of the voltage v a in fig.7.6. [8] (Ans. 14 volts ) T.7.4 For the circuit shown in fig.7.7, calculate the value of source current I x that yields I = 0 if VA and V C are kept fixed at 7Vand28V. [7] (Ans. I = 5.833 A ) x T.7.5 For the circuit shown below (see fig.7.8), it follows from linearly that we can write Vab = α I x + βva + ηvb, where α, β, and η are constants. Find the values of (i) () i α ( ii) β and ( iii) η. [7]

(Ans. α = 1; β = 0.063; and η= 0.063) T.7.6 Using superposition theorem, find the current i through 5Ω resistor as shown in fig.7.9. [8] (Ans. 0.538 A ) T.7.7 Consider the circuit of fig.7.10

(a) Find the linear relationship between Vout and input sources Vs and I s (b) If Vs = 10V and Is = 1, find Vout (c) What is the effect of doubling all resistance values on the coefficients of the linear relationship found in part (a)? [7] (Ans. (a) V = 0.3333V + 6.666 I ; (b) V = 9.999V (c) V = 0.3333V + 13.332I ) out s s out out s s

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