D C Circuit Analysis and Network Theorems:

Similar documents
Lecture Notes on DC Network Theory

Chapter 5. Department of Mechanical Engineering

Thevenin Norton Equivalencies - GATE Study Material in PDF

Study Notes on Network Theorems for GATE 2017

UNIT 4 DC EQUIVALENT CIRCUIT AND NETWORK THEOREMS

UNIVERSITY F P RTLAND Sch l f Engineering

Chapter 10 AC Analysis Using Phasors

Chapter 5 Objectives

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

Sinusoidal Steady State Analysis (AC Analysis) Part I

Thevenin equivalent circuits

CHAPTER FOUR CIRCUIT THEOREMS

Sinusoidal Steady State Analysis (AC Analysis) Part II

Chapter 10: Sinusoidal Steady-State Analysis

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

ECE2262 Electric Circuits

Midterm Exam (closed book/notes) Tuesday, February 23, 2010

Electricity & Magnetism

ECE2262 Electric Circuits. Chapter 5: Circuit Theorems

Chapter 10 Sinusoidal Steady State Analysis Chapter Objectives:

OUTCOME 3 - TUTORIAL 2

SOME USEFUL NETWORK THEOREMS

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

Electrical Engineering Technology

QUESTION BANK SUBJECT: NETWORK ANALYSIS (10ES34)

CHAPTER 4. Circuit Theorems

Chapter 4. Techniques of Circuit Analysis

Electrical Circuits I Lecture 8

1.7 Delta-Star Transformation

3.1 Superposition theorem

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

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

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

BFF1303: ELECTRICAL / ELECTRONICS ENGINEERING. Alternating Current Circuits : Basic Law

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

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

Chapter 2 Direct Current Circuits

Basics of Network Theory (Part-I)

Series & Parallel Resistors 3/17/2015 1

DEPARTMENT OF COMPUTER ENGINEERING UNIVERSITY OF LAHORE

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

DC STEADY STATE CIRCUIT ANALYSIS

QUIZ 1 SOLUTION. One way of labeling voltages and currents is shown below.

Electric Circuits I. Midterm #1

MAE140 - Linear Circuits - Fall 14 Midterm, November 6

Delta & Y Configurations, Principles of Superposition, Resistor Voltage Divider Designs

Chapter 2. Engr228 Circuit Analysis. Dr Curtis Nelson

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

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

ECE 1311: Electric Circuits. Chapter 2: Basic laws

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

E1.1 Analysis of Circuits ( ) Revision Lecture 1 1 / 13

Direct Current Circuits

Direct Current Circuits. February 18, 2014 Physics for Scientists & Engineers 2, Chapter 26 1

Errors in Electrical Measurements

Introductory Circuit Analysis

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

Experiment #6. Thevenin Equivalent Circuits and Power Transfer

Lecture #3. Review: Power

Introduction to AC Circuits (Capacitors and Inductors)

DC CIRCUIT ANALYSIS. Loop Equations

Fundamental of Electrical circuits

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

Voltage Dividers, Nodal, and Mesh Analysis

Electric Circuit Theory

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

2/25/2014. Circuits. Properties of a Current. Conservation of Current. Definition of a Current A. I A > I B > I C B. I B > I A C. I C D. I A E.

Fundamentals of Electric Circuits, Second Edition - Alexander/Sadiku

Basic Electrical Circuits Analysis ECE 221

NUMBER OF TIMES COURSE MAY BE TAKEN FOR CREDIT: One

15.9 TWO-PORTS* . (15.114) R Thout = v 2a

NETWORK ANALYSIS WITH APPLICATIONS

Prepare for this experiment!

Chapter 5: Circuit Theorems

Physics 102 Lab 4: Circuit Algebra and Effective Resistance Dr. Timothy C. Black Spring, 2005

Sirindhorn International Institute of Technology Thammasat University at Rangsit

Homework 1 solutions

Chapter 5 Steady-State Sinusoidal Analysis

Circuits. PHY2054: Chapter 18 1

mywbut.com Mesh Analysis

Engineering Fundamentals and Problem Solving, 6e

Designing Information Devices and Systems I Fall 2018 Lecture Notes Note Resistive Touchscreen - expanding the model

resistance in the circuit. When voltage and current values are known, apply Ohm s law to determine circuit resistance. R = E/I ( )

Review of Ohm's Law: The potential drop across a resistor is given by Ohm's Law: V= IR where I is the current and R is the resistance.

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

US ARMY INTELLIGENCE CENTER CIRCUITS

EIE/ENE 104 Electric Circuit Theory

EE40. Lec 3. Basic Circuit Analysis. Prof. Nathan Cheung. Reading: Hambley Chapter 2

Chapter 10: Sinusoidal Steady-State Analysis

LABORATORY MODULE ELECTRIC CIRCUIT

EXPERIMENT 12 OHM S LAW

Notes for course EE1.1 Circuit Analysis TOPIC 10 2-PORT CIRCUITS

Chapter 6 DIRECT CURRENT CIRCUITS. Recommended Problems: 6,9,11,13,14,15,16,19,20,21,24,25,26,28,29,30,31,33,37,68,71.

15EE103L ELECTRIC CIRCUITS LAB RECORD

Agenda for Today. Elements of Physics II. Resistance Resistors Series Parallel Ohm s law Electric Circuits. Current Kirchoff s laws

Analysis of a single-loop circuit using the KVL method

... after Norton conversion...

Lab #3 Linearity, Proportionality, and Superposition

Notes for course EE1.1 Circuit Analysis TOPIC 3 CIRCUIT ANALYSIS USING SUB-CIRCUITS

Topic 5.2 Heating Effect of Electric Currents

Transcription:

UNIT-1 D C Circuit Analysis and Network Theorems: Circuit Concepts: Concepts of network, Active and passive elements, voltage and current sources, source transformation, unilateral and bilateral elements, Kirchhoff s laws; loop and nodal methods of analysis; star-delta transformation; Network Theorems: Superposition Theorem, Thevenin s Theorem, Maximum Power Transfer Theorem. Electrical Engineering (NEE-101) by Dinesh,DGI

Introduction This chapter introduces important fundamental theorems of network analysis. They are the Superposition theorem Thévenin s theorem Norton s theorem Maximum power transfer theorem

Superposition Theorem Used to find the solution to networks with two or more sources that are not in series or parallel. The current through, or voltage across, an element in a network is equal to the algebraic sum of the currents or voltages produced independently by each source. Since the effect of each source will be determined independently, the number of networks to be analyzed will equal the number of sources.

Superposition Theorem The total power delivered to a resistive element must be determined using the total current through or the total voltage across the element and cannot be determined by a simple sum of the power levels established by each source.

Thévenin s Theorem Any two-terminal dc network can be replaced by an equivalent circuit consisting of a voltage source and a series resistor.

Thévenin s Theorem Thévenin s theorem can be used to: Analyze networks with sources that are not in series or parallel. Reduce the number of components required to establish the same characteristics at the output terminals. Investigate the effect of changing a particular component on the behavior of a network without having to analyze the entire network after each change.

Thévenin s Theorem Procedure to determine the proper values of R Th and E Th Preliminary 1. Remove that portion of the network across which the Thévenin equation circuit is to be found. In the figure below, this requires that the load resistor R L be temporarily removed from the network.

Thévenin s Theorem 2. Mark the terminals of the remaining two-terminal network. (The importance of this step will become obvious as we progress through some complex networks.) R Th : 3. Calculate R Th by first setting all sources to zero (voltage sources are replaced by short circuits, and current sources by open circuits) and then finding the resultant resistance between the two marked terminals. (If the internal resistance of the voltage and/or current sources is included in the original network, it must remain when the sources are set to zero.)

Thévenin s Theorem E Th : 4. Calculate E Th by first returning all sources to their original position and finding the open-circuit voltage between the marked terminals. (This step is invariably the one that will lead to the most confusion and errors. In all cases, keep in mind that it is the open-circuit potential between the two terminals marked in step 2.)

Thévenin s Theorem Conclusion: 5. Draw the Thévenin equivalent circuit with the portion of the circuit previously removed replaced between the terminals of the equivalent circuit. This step is indicated by the placement of the resistor R L between the terminals of the Thévenin equivalent circuit. Insert Figure 9.26(b)

Thévenin s Theorem Experimental Procedures Two popular experimental procedures for determining the parameters of the Thévenin equivalent network: Direct Measurement of E Th and R Th For any physical network, the value of E Th can be determined experimentally by measuring the open-circuit voltage across the load terminals. The value of R Th can then be determined by completing the network with a variable resistance R L.

Thévenin s Theorem Measuring V OC and I SC The Thévenin voltage is again determined by measuring the open-circuit voltage across the terminals of interest; that is, E Th = V OC. To determine R Th, a short-circuit condition is established across the terminals of interest and the current through the short circuit (I sc ) is measured with an ammeter. Using Ohm s law: R Th = V oc / I sc

Norton s Theorem Norton s theorem states the following: Any two-terminal linear bilateral dc network can be replaced by an equivalent circuit consisting of a current and a parallel resistor. The steps leading to the proper values of I N and R N. Preliminary steps: 1. Remove that portion of the network across which the Norton equivalent circuit is found. 2. Mark the terminals of the remaining two-terminal network.

Finding R N : Norton s Theorem 3. Calculate R N by first setting all sources to zero (voltage sources are replaced with short circuits, and current sources with open circuits) and then finding the resultant resistance between the two marked terminals. (If the internal resistance of the voltage and/or current sources is included in the original network, it must remain when the sources are set to zero.) Since R N = R Th the procedure and value obtained using the approach described for Thévenin s theorem will determine the proper value of R N.

Finding I N : Norton s Theorem 4. Calculate I N by first returning all the sources to their original position and then finding the short-circuit current between the marked terminals. It is the same current that would be measured by an ammeter placed between the marked terminals. Conclusion: 5. Draw the Norton equivalent circuit with the portion of the circuit previously removed replaced between the terminals of the equivalent circuit.

Maximum Power Transfer Theorem The maximum power transfer theorem states the following: A load will receive maximum power from a network when its total resistive value is exactly equal to the Thévenin resistance of the network applied to the load. That is, R L = R Th

Maximum Power Transfer Theorem For loads connected directly to a dc voltage supply, maximum power will be delivered to the load when the load resistance is equal to the internal resistance of the source; that is, when: R L = R int

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