Unlocking The Power Of Electromagnetic Fields

Exploring Theory, Applications, and Breakthroughs

What you'll learn

This course is designed to review the fundamentals and application of Electromagnetic Field Theory.

This course also enables the Learners to understand to solve real life problem related to Electromagnetics.

To introduce the basic mathematical concepts related to Electromagnetic vector fields.

To impart knowledge on the concepts of Electrostatics, Electric Potential, Energy density and their applications.

To impart knowledge on the concepts of Magnetostatics, Magnetic flux density, Scalar and Vector potential and its applications.

To impart knowledge on the concepts of Faraday ‘s law, induced emf and Maxwell ‘s equations.

To impart knowledge on the concepts of Concepts of electromagnetic waves and Transmission lines.

Requirements

No prerequistes.

Description

Discover the captivating realm of Electromagnetic Theory and unlock the secrets behind its phenomenal power. Join us on an exhilarating journey as we explore the core principles of Electromagnetism, from experimental foundations to Electrostatics, Magnetic fields, and Electromagnetic Induction. Dive into Maxwell's equations, the mesmerizing Propagation and Radiation of electromagnetic waves, and the intriguing Electric and Magnetic properties of matter.This course is your gateway to understanding the inner workings of essential devices like Generators, Motors, and Transformers. Gain a comprehensive knowledge of Electric and Magnetic fields to analyze Transmission Lines, Substations, Insulator flashover mechanisms, and fascinating Transient phenomena.Experience the cutting edge of remote power transmission as we delve into the design of innovative Antennas. Your understanding of electromagnetic fields becomes paramount as we revolutionize electricity distribution to remote areas.Beyond communication systems like Satellite, TV, Wireless, Mobile, and Microwave Communication, explore antenna design, transmission lines, and waveguide analysis. Witness the far-reaching applications of Electromagnetic Field Theory in Bio-medical systems, Weather forecast radars, Remote sensing radars, Radio astronomy radars, Plasmas, Radiation therapy, Surface hardening, Annealing, Soldering, Dielectric heating, Joining and Sealing, and even enhancing vegetable flavors. The possibilities are endless, including the fascinating realms of Lasers and Masers.Unleash your mastery of Electromagnetic Power! Enroll now to join a vibrant community of learners, unravel the mysteries of Electromagnetic Theory, and ignite innovation for our electrified future.

Overview

Section 1: Module 1

Lecture 1 Vector Analysis (Part 1)

Lecture 2 Vector Analysis (Part 2)

Lecture 3 Cylindrical Co-ordinate System in Vector Analysis

Lecture 4 Application of Dot Product & Cross Product

Lecture 5 Concept of Differential length, Surface and Volume

Lecture 6 Coulomb's Law of Forces

Section 2: Module 2

Lecture 7 Different types of Charge Distribution

Lecture 8 Electric field intensity due to point charges

Lecture 9 Electric Field Intensity due to Infinite Sheet of Charge

Lecture 10 Electric Field Intensity due to Infinite Line Charge

Lecture 11 Concept of Electric Flux & Electric Flux Density

Lecture 12 Gauss's Law

Lecture 13 Divergence of Electric Flux Density

Lecture 14 Maxwell's First Equation in Electrostatics

Lecture 15 Divergence Theorem

Section 3: Module 3

Lecture 16 Concept of Potential Difference and Potential due to point Charge

Lecture 17 Concept of Potential Gradient

Lecture 18 Concept of Electric Dipole

Lecture 19 Energy Density in Electrostatics Field(part-1)

Lecture 20 Electric Density in Electrostatic Field (Part-2)

Lecture 21 Continuity Equation of Current

Section 4: Module 3

Lecture 22 Boundary Conditions at a Conductor - Free Space Boundary

Lecture 23 Boundary Conditions between Two Perfect Dielectrics

Lecture 24 Conductor-Dielectric Boundary Conditions

Lecture 25 Capacitance of Parallel Plate Capacitor

Lecture 26 Poisson's & Laplace's Equation

Lecture 27 Cylindrical Capacitor or Capacitor for Coaxial Cable

Lecture 28 Spherical Capacitor

Section 5: Module 4

Lecture 29 Different Types of Current Distributions

Lecture 30 Numerical 1 on Electrostatic Field

Lecture 31 Numerical 2 on Electrostatic Field

Section 6: Module 5

Lecture 32 Biot-Savart Law

Lecture 33 Magnetic Field due to Infinite Long Filament Conductor

Lecture 34 Ampere's Circuital Law

Lecture 35 Numerical 3 on Electrostatic Field

Lecture 36 Composite Capacitor Part I

Lecture 37 Composite Capacitor Part II

Lecture 38 Application of Ampere's Circuital Law - Coaxial Cable Part I

Lecture 39 Application of Ampere's Circuital Law - Coaxial Cable Part II

Lecture 40 Numerical 4 on Electrostatic Fields

Lecture 41 Numerical 5 on Electrostatic Field

Lecture 42 Numerical 6 on Electrostatic Field

Lecture 43 Curl of Magnetic Field Intensity Part I

Lecture 44 Curl of Magnetic Field Intensity Part II

Lecture 45 Lorentz Force Equation

Lecture 46 Application of Lorentz Force Equation Part I

Lecture 47 Stoke's Theorem

Lecture 48 Magnetic Boundary Conditions

Lecture 49 Maxwell's Equations for Time Varying Fields Part I

Lecture 50 Maxwell's Equations for Time Varying Fields Part II

Lecture 51 Maxwell's Equations for Time Varying Fields Part III

Lecture 52 Numerical 7 on Electrostatic Field

Lecture 53 Numerical 8 on Electrostatic Field

Lecture 54 Numerical 9 on Electrostatic Field

Lecture 55 Numerical 10 on Electrostatic Field

Lecture 56 Numerical 11 on Electrostatic Field

Lecture 57 Energy stored in Magnetic Field

Section 7: Test

Anyone who has an interest in electromagnetic field theory and wants to start from the basics