Basics Of Circuit Theory

Fundamentals of circuit theory. Ohm's law, Kirchhoff's law, Thevenin's theorem, Norton's theorem, Maximum Power Theorem

What you'll learn
 To understand the concepts of Basic Units of electrical engineering.
 To understand the concepts of Basic definitions of different terms used in circuit theory
 To understand the concepts of basic elements used in circuit theory also commonly used in electrical engineering
 To learn the analysis of electrical circuits by basic law’s, DC theorems and Kirchhoff’s law
To understand the concepts to solve the electrical circuits
To provide a systematic approach for analysis of circuits and solution of electric circuits
Student shall be able to understand and analyze the series, parallel and series-parallel combination of the elements.
Requirements
Basic mathematics of class 12
Description
This course is designed for the students of 12th class and first year engineering students for all branches where the course Basic Electrical Engineering is in their curriculum. In this course student shall be able to understand the basic units, derived units, basic electrical elements, combination of elements, analysis of the given circuit in terms of voltage, current and power. Also student shall be able to analyze the circuit by using Ohm's Law, Kirchhoff's law, Thevenin's theorem, Norton's Theorem, Maximum Power Transfer Theorem. After completion of this course student can solve the circuit. Student can learn different types of input signals used in circuit theory.This is basic course by which fundamentals are clear and can be helpful to analyze the circuit. In this course student shall be under stand the series, parallel and series-parallel combination of the circuit elements. Student shall be able to formulate the equilibrium equations using  Kirchhoff's law, mesh analysis and nodal analysis for DC circuits. This Circuit theory course provides you the knowledge of basic principles that you need to understand the behavior of electric circuits. A step by step procedure emphasizes principles and concepts. Solved examples step by steps are provided in each section also unsolved problems with answers will be provided. This course clears the student's doubts about the analysis of given circuit.   

Overview

Section 1: Introduction

Lecture 1 Introduction

Section 2: Course Objectives and Course Outcomes

Lecture 2 Course Objectives and Course Outcomes

Section 3: UNITS

Lecture 3 UNITS

Section 4: BASIC DEFINITIONS

Lecture 4 BASIC DEFINTION USED IN CIRCUIT THEORY

Lecture 5 BASIC TERMS AND DEFINITION

Lecture 6 NETWORK ELEMENTS

Lecture 7 RESISTANCE OF METALLIC CONDUCTOR

Lecture 8 SOLVED EXAMPLES BASED ON RESISTIVITY

Lecture 9 OHM'S LAW & KRICHHOFF'S LAW

Lecture 10 COMBINATION OF RESISTORS

Lecture 11 SOURCE TRANSFORMATION

Lecture 12 CURRENT SOURCES IN PARALLEL AND SERIES

Section 5: CAPACITORS

Lecture 13 CAPACITORS

Lecture 14 CAPACITANCE

Lecture 15 COMBINATION OF CAPACITORS

Lecture 16 EXAMPLE

Lecture 17 MORE EXAMPLES

Section 6: INDUCTORS

Lecture 18 Combination of Inductors

Lecture 19 Examples based on combination of Inductors

Section 7: MESH ANALYSIS

Lecture 20 How to write the mesh equation by apply KVL

Section 8: NODAL ANALYSIS

Lecture 21 Procedure for writing the equation by nodal analysis

Lecture 22 Example 1

Lecture 23 Example 2

Lecture 24 Example 3

Section 9: D.C.THEOREM

Lecture 25 Superposition Theorem

Lecture 26 Example 2

Lecture 27 Example 3

Lecture 28 Thevenin's Theorem

Lecture 29 Example 2

Lecture 30 Example 3

Lecture 31 Example 4

Lecture 32 Norton's Theorem

Lecture 33 Example 2

Lecture 34 Example 3

Lecture 35 Maximum Power Transfer Theorem

Lecture 36 Example 1

Lecture 37 Example 2

Students of class 12, B. Tech of first year students for all branches of engineering.