Why enroll

This course builds a strong foundation in electromagnetics, which is essential for all EEE students. It explains complex topics in an easy and clear way. It also prepares learners for advanced engineering subjects and real-world applications.

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Course content

The course is readily available, allowing learners to start and complete it at their own pace.

Electromagnetic Fields

25 Lectures

1439 min

Introduction to Vector
Preview
55 min
Introduction to vector(contd..........)
57 min
Coulomb's Law
57 min
Electric Field
56 min
Electro Static Potential
57 min
The Gradient
61 min
Gauss's Law
57 min
Poisson's Equation
58 min
Energy in the Field
58 min
Example Problems in Eletro Statics
63 min
Fields in Materials
57 min
Fields in Material Bodies
57 min
Displacement Vector
55 min
Capacitors
57 min
Method Of Image
57 min
Poisson's Equation 2Dimensions
58 min
Field near Sharp Edges and Points
57 min
Magnetic Field--1
57 min
Magnetic Field-2
60 min
Stokes Theorems
58 min
The Curl
58 min
Field Due to Current Loop
55 min
Ampere's Law
58 min
Examples of Ampere,s Law
58 min
Inductance
58 min

Course details

This course introduces the fundamental concepts of electromagnetics for Electrical and Electronics Engineering (EEE) students. It begins with a clear review of vector algebra and vector calculus, which are essential tools for understanding electromagnetic fields. Students learn how electric and magnetic fields are represented and analyzed in space. The course then covers electrostatics, focusing on electric charges, electric fields, and electric potential. Important laws such as Coulomb’s Law and Gauss’s Law are explained in a simple and step-by-step manner. Magnetostatics is introduced to help students understand magnetic fields produced by steady currents. The relationship between electricity and magnetism is discussed using practical examples. Time-varying fields are also covered to explain how changing electric and magnetic fields interact. Mathematical concepts are always linked to physical meaning for better understanding. By the end of the course, students gain a strong foundation needed for advanced subjects in power systems, electronics, and communication engineering.

Source: nptelhrd [Youtube Channel]

Course suitable for

Automotive
Electrical
Engineering & Design
Project Management
Research & Developmnet

Key topics covered

Introduction to Vectors
Introduction to Vectors (Continued)
Coulomb’s Law
Electric Field
Electrostatic Potential
The Gradient
Gauss’s Law
Poisson’s Equation
Energy Stored in the Electric Field
Example Problems in Electrostatics
Fields in Materials
Fields in Material Bodies
Electric Displacement Vector
Capacitors
Method of Images
Poisson’s Equation in Two Dimensions
Electric Field Near Sharp Edges and Points
Magnetic Field – Part 1
Magnetic Field – Part 2
Stokes’ Theorem
The Curl of a Vector Field
Magnetic Field Due to a Current Loop
Ampere’s Law
Examples of Ampere’s Law
Inductance

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