Parallel Circuits Lecture No.5 By – Engr Sajid Hussain Qazi Mehran U.E.T Campus Khairpur.

Slides:



Advertisements
Similar presentations
Circuits.
Advertisements

Chapter 6 – Parallel Circuits
Quiz 1 a) Find the currents i1 and i2 in the circuit in the figure. b) Find the voltage vo. c) Verify that the total power developed equals the total power.
ELECTRICITY & MAGNETISM (Fall 2011) LECTURE # 14 BY MOEEN GHIYAS.
Series and Parallel Circuits Kirchoff’s Voltage and Current Laws Circuits 1 Fall 2005 Harding University Jonathan White.
1 Parallel Circuits Benchmark Companies Inc PO Box Aurora CO
Chapter 6 – Parallel dc Circuits Introductory Circuit Analysis Robert L. Boylestad.
QUIZ 3 T. Elsarnagawy, mde 207, semester 311, rcc.
ECE 201 Circuit Theory I1 Resistors in Parallel Resistors connected at a single node pair Voltage across each resistor is the same.
Parallel Circuits ENTC 210: Circuit Analysis I Rohit Singhal Lecturer Texas A&M University.
EE2003 Circuit Theory Chapter 2 Basic Laws
Network Theorems SUPERPOSITION THEOREM THÉVENIN’S THEOREM
Chapter 26 DC Circuits Chapter 26 Opener. These MP3 players contain circuits that are dc, at least in part. (The audio signal is ac.) The circuit diagram.
Lecture No. 11 By. Sajid Hussain Qazi
Resistors in Series Introduction Two types of current are readily available, direct current (dc) and sinusoidal alternating current (ac) We will first.
Lecture 5 Review: Circuit reduction Related educational modules:
1) Connect the Battery Which is the correct way to light the lightbulb with the battery? 4) all are correct 5) none are correct 1) 2) 3)
Lecture 2 Basic Circuit Laws
Chapter 17 – Methods of Analysis & Sel Topics Lecture 24 by Moeen Ghiyas 13/08/
ELECTRIC CIRCUIT ANALYSIS - I
Chapter 6 Parallel Circuits.
Objective of Lecture Explain mathematically how resistors in series are combined and their equivalent resistance. Chapter 2.5 Explain mathematically how.
ELECTRICITY & MAGNETISM (Fall 2011) LECTURE # 13 BY MOEEN GHIYAS.
electronics fundamentals
Series and Parallel Circuits
EEE107J1.
Series Circuits Lecture No.4 Mehran U.E.T Khairpur.
Basic Electrical Engineering Lecture # 04 Simple Resistive Circuits Course Instructor: Engr. Sana Ziafat.
Lecture 13 Direct Current Circuits
Series and Parallel Circuits Khemraj Nandanwar T.G.T.(Work Experience) Kendriya Vidyalaya,Golaghat.
Parallel dc Circuits.
Ohm’s law and Kirchhoff's laws
Electronics Fundamentals 8 th edition Floyd/Buchla © 2010 Pearson Education, Upper Saddle River, NJ All Rights Reserved. chapter 5 electronics fundamentals.
DC/AC Fundamentals: A Systems Approach
09/16/2010© 2010 NTUST Chapter 5 Course overview and information.
FUNDAMENTALS OF ELECTRIC CIRCUITS EE 318 Dr. ARVIND TIWARI B1-S DEPARTMENT OF ELECTRICAL ENGINEERING, COLLEGE OF.
Chapter 8 DC Circuits. 2 Objectives –After completing this chapter, the student should be able to: Solve for all unknown values, (current, voltage, resistance,
Electromagnetism Lecture#7 Instructor: Engr. Muhammad Mateen Yaqoob.
Parallel Circuits – Chapter 5
Series Circuits EE 2010: Fundamentals of Electric Circuits Mujahed AlDhaifallah.
Chapter 19 DC Circuits. Objective of the Lecture Explain Kirchhoff’s Current and Voltage Laws. Demonstrate how these laws can be used to find currents.
Series Current Series Voltage Drops In a series circuit the sum of the voltage drops across each resistor or device is equal to the potential difference.
SERIES RESISTORS AND VOLTAGE DIVISION In Fig the two resistors are in series, since the same current i flows in both of them. Applying Ohm’s law.
Circuits and Electronics Midway in Chapter 2 Resistor Combinations.
Norton’s Theorem and Maximum Power Transfer Theorem Lecture No.7 By – Engr Sajid Hussain Qazi Lecturer Mehran University C.E.T Khairpur.
Previous Lecture 7 (Problems Solving)
Series and Parallel.  a single resistance that can replace all the resistances in an electrical circuit while maintaining the same current when connected.
Chapter 5 Parallel Circuits MECH1100 Topics Resistors in Parallel Total Parallel Resistance Voltage in a Parallel Circuit Ohm’s Law Kirchhoff’s Current.
Ohm’s Law Resistance in Series Circuits
Series Circuits.
Lesson 5: Series-Parallel Circuits
Electric Circuits. Electric circuit: a complete path from the positive terminal to the negative terminal.
FIGURE 6.1 Parallel elements. Robert L. Boylestad Introductory Circuit Analysis, 10ed. Copyright ©2003 by Pearson Education, Inc. Upper Saddle River, New.
Series and Parallel Circuits
EE301 Parallel Circuits and Kirchhoff’s Current Law.
Lesson 6: Series-Parallel DC Circuits
Topics Resistors in Parallel Total Parallel Resistance
Chapter 6.
1) Connect the Battery Which is the correct way to light the lightbulb with the battery? 4) all are correct 5) none are correct 1) 2) 3)
1) Connect the Battery Which is the correct way to light the lightbulb with the battery? 4) all are correct 5) none are correct 1) 2) 3)
Chapter 2. Resistive circuits
ConcepTest 4.1a Series Resistors I
Electric Circuits Fundamentals
electronics fundamentals
Resistance in Series and Parallel
Resistors in Parallel Resistors connected at a single node pair
Electric Circuits Chapter 35.
Series and Parallel Circuit
Chapter 6.
Aim: How do we explain Parallel Circuits?
Presentation transcript:

Parallel Circuits Lecture No.5 By – Engr Sajid Hussain Qazi Mehran U.E.T Campus Khairpur

Parallel Circuits Engr. S.H.Qazi “Two elements, branches, or networks are in parallel if they have two points in common.” In Fig. 1, elements 1 and 2 have terminals a and b in common; they are therefore in parallel. FIGURE-1 In Fig. 2, all the elements are in parallel because they satisfy the above criterion. Three configurations are provided to demonstrate how the parallel networks can be drawn.

Engr. S.H.Qazi FIGURE-2 In Fig.3, elements 1 and 2 are in parallel because they have terminals a and b in common. The parallel combination of 1 and 2 is then in series with element 3 due to one common terminal point b. FIGURE-3

Total Conductance and Resistance Recall that for series resistors, the total resistance is the sum of the resistor values. For parallel elements, “The total conductance is the sum of the individual conductance.” That is, for the parallel network of Fig. 4, we write G-Conductance FIGURE-4 Engr. S.H.Qazi

Since increasing levels of conductance will establish higher current levels, the more terms appearing in above equation, the higher the input current level. In other words, as the number of resistors in parallel increases, the input current level will increase for the same applied voltage, the opposite effect of increasing the number of resistors in series. Substituting resistor values for the network of Fig.4, will result in the network of Fig. 5. Since G=1/R, the total resistance for the network can be determined by direct substitution into Equation. FIGURE-5 Engr. S.H.Qazi

EXAMPLE.1 Determine the total conductance and resistance for the parallel network of Figure shown. Solution. EXAMPLE.2 Determine the effect on the total conductance and resistance of the network of Figure, if another resistor of 10 ohms were added in parallel with the other elements. Solution. Note, as mentioned above, that adding additional terms increases the conductance level and decreases the resistance level.

Engr. S.H.Qazi EXAMPLE.3 Determine the total resistance for the network shown below. For same value of resistors, the equation for finding Rt, becomes more easier to apply. For N equals resistors in parallel, equation becomes..

Engr. S.H.Qazi EXAMPLE.4 Determine the total resistance for the networks shown below. Answer-4 ohms Answer-0.5 ohms When number of resistors in circuit are two, then total resistance can be found by using below formula.

Engr. S.H.Qazi Example.5. (a)Determine total resistance of circuit shown in fig.1. (b) What is the effect on total resistance of fig.1 if an additional resistor of same value is added in parallel as shown in fig.2. (c) What is the effect on total resistance of fig.1 if a large resistance is added in parallel as shown in fig.3. (d) What is the effect on total resistance of fig.1 if a small resistance is added in parallel as shown in fig.4. Fig.1 Fig.4 Fig.3 Fig.2 Exercise Problem (15 ohm) (0.099 ohm)(10 ohm) (14.77 ohm)

Engr. S.H.Qazi Current Divider Rule As the name suggests, the current divider rule (CDR) will determine how the current entering a set of parallel branches will split between the elements. “For two parallel elements of equal value, the current will divide equally.” “For parallel elements with different values, the smaller the resistance, the greater the share of input current.” “For parallel elements of different values, the current will split with a ratio equal to the inverse of their resistor values.” For example, if one of two parallel resistors is twice the other, then the current through the larger resistor will be half the other.

Engr. S.H.Qazi In Fig. 6, since I1 is 1 mA and R1 is six times R3, the current through R3 must be 6 mA. For R2 the current must be 2 mA since R1 is twice R2. The total current must then be the sum of I1, I2, and I3. FIGURE-6 For networks in which only the resistor values are given along with the input current, the current divider rule should be applied to determine the various branch currents. It can be derived using the network of Fig. 7.

Engr. S.H.Qazi Input Current I equals Substituting V=IxRx in above equation This is the general form for the current divider rule. In words, the current through any parallel branch is equal to “The product of the total resistance of the parallel branches and the input current divided by the resistance of the branch through which the current is to be determined.” For the current I1,For the current I2, And so on….

Engr. S.H.Qazi For the particular case of two parallel resistors, as shown in Fig.7. FIGURE-7 For I2,

Engr. S.H.Qazi Example 6. Determine current I2 for network shown. Example 7. Determine current I1 for circuit shown.

Engr. S.H.Qazi Example 8. Determine current I1, I2 and I3 for circuit shown. Also verify KCL. Using CDR Applying KCL For verification, using CDR Total current entering the branch must equal to leaving..

Engr. S.H.Qazi Example 9. Determine resistance R1 for circuit shown. Practice Example (R2=2 ohm)

Engr. S.H.Qazi PRACTICE TEST Q.1. Two branches will be in parallel if they have ______ terminals in common. Q.2. Opposite of resistance is_______ and its unit is __________. Q.3. If number of parallel resistors increases the value of _______________ increases for the same applied __________. Q.4. In parallel circuits relation of current and resistance is ___________.