This Postgraduate certificate in Electromagnetism provides you with the knowledge you need to put your next digital creations into action" 

Thanks to the Scottish mathematician and scientist James Clerk Maxwell and his formulation of the classical theory of electromagnetic radiation, nowadays human beings have achieved great technological and industrial progress, such as energy storage, the creation of computer chips, Bluetooth connections or cell phones.

Undoubtedly, a thorough and accurate knowledge of Electromagnetism is essential in the field of engineering. Its application by professionals has allowed the development of machines, household appliances and devices that have boosted different productive sectors such as industrial. Given this reality, it is essential that the professional has a solid foundation, which can be achieved through this Postgraduate certificate in Electromagnetism , designed by TECH to offer the most advanced learning in this area.

An exclusively online program, which over 12 weeks, will allow students to delve into the operation of the electric field and field lines, understand the magnetostatics in natural means or apply Maxwell's equations. For this purpose, it has innovative teaching tools, in which this academic institution has used the latest technology applied to university teaching.

In addition, the Relearning system will allow students to progress through the content of this program in a much more natural way, reducing the long hours of study that are more frequent in other teaching methods.

The professionals have an excellent opportunity to study a program according to the current academic times and to which they can access comfortably whenever and wherever they wish. Students will only need an electronic device with Internet connection to access the program’s syllabus. All you need is an electronic device with Internet connection to view the content of this program.

An academic option without in-person attendance or classes with fixed schedules, which adapts to your needs. Enroll now”

This Postgraduate certificate in Electromagnetism  contains the most complete and up-to-date program on the market. The most important features include:

• Practical case studies are presented by experts in Physics
• The graphic, schematic, and practical contents with which they are created, provide scientific and practical information on the disciplines that are essential for professional practice
• Practical exercises where the self-assessment process can be carried out to improve learning
• Its special emphasis on innovative methodologies
• Theoretical lessons, questions to the expert, debate forums on controversial topics, and individual reflection assignments
• Content that is accessible from any fixed or portable device with an Internet connection

Case studies developed by specialists provide a practical approach to university teaching that is highly applicable to engineering" 

The program’s teaching staff includes professionals from the sector who contribute their work experience to this educational program, as well as renowned specialists from leading societies and prestigious universities.

The multimedia content, developed with the latest educational technology, will provide the professional with situated and contextual learning, i.e., a simulated environment that will provide immersive education programmed to learn in real situations.

This program is designed around Problem-Based Learning, whereby the professional must try to solve the different professional practice situations that arise throughout the program. For this purpose, the student will be assisted by an innovative interactive video system created by renowned and experienced experts.

With this program, you will obtain a comprehensive learning about the laws of conservation and electromagnetic energy"

TECH has designed multimedia pills using the latest technology applied to academic teaching. Enroll now"

Students who take this Program have at their disposal, 24 hours a day, a library of didactic material composed of video summaries, videos in detail, diagrams or complementary readings. Thanks to these resources, students will be able to study electromagnetic waves in vacuum and confined means, electric potential or Ohm's and Faraday's laws in a much more agile way. In addition, students will be able to solve any doubts arising from the content of this syllabus with the expert teaching team that is part of this 100% online program. 

All of this, in a syllabus with a theoretical-practical approach that can be accessed 24 hours a day from your computer with Internet connection” 

Module 1. Electromagnetism

1.1. Vector Calculus: Review

1.1.1. Vector Operations

1.1.1.1. Scalar Products
1.1.1.2. Vectorial Products
1.1.1.3. Mixed Products
1.1.1.4. Triple Product Properties

1.1.2. Vector Transformation

1.1.2.1. Differential Calculus
1.1.2.1. Gradient
1.1.2.2. Divergence
1.1.2.3. Rotational
1.1.2.4. Multiplication Rules

1.1.3. Integral Calculus

1.1.3.1. Line, Surface and Volume Integrals
1.1.3.2. Fundamental Calculus Theorem
1.1.3.3. Fundamental Gradient Theorem
1.1.3.4. Fundamental Divergence Theorem
1.1.3.5. Fundamental Rotational Theorem

1.1.4. Dirac Delta Function
1.1.5. Helmholtz Theorem

1.2. Coordinate Systems and Transformations

1.2.1. Line, Surface and Volume Element
1.2.2. Cartesian Coordinates
1.2.3. Polar Coordinates
1.2.4. Spherical Coordinates
1.2.5. Cylindrical Coordinates
1.2.6. Coordinate Change

1.3. Electric Field

1.3.1. Point Charges
1.3.2. Coulomb's Law
1.3.3. Electric Field and Field Lines
1.3.4. Discrete Charge Distributions
1.3.5. Continuous Load Distributions
1.3.6. Divergence and Rotational Electric Field
1.3.7. Electric Field Flow. Gauss Theorem

1.4. Electric Potential

1.4.1. Electric Potential Definition
1.4.2. Poisson's Equation
1.4.3. Laplace's Equation
1.4.4. Potential Charge Distribution Calculation

1.5. Electrostatic Energy

1.5.1. Electrostatic Work
1.5.2. Discrete Charge Distribution Energy
1.5.3. Continuous Charge Distribution Energy
1.5.4. Electrostatic Equilibrium Conductors
1.5.5. Induced Charges

1.6. Vacuum Electrostatics

1.6.1. Laplace's Equation in One, Two and Three Dimensions
1.6.2. Laplace’s Equation - Boundary Conditions and Uniqueness Theorems
1.6.3. Image Method
1.6.4. Variable Separation

1.7. Multi-Polar Expansion

1.7.1. Approximate Potentials Away from the Source
1.7.2. Multi-Polar Development
1.7.3. Mono-Polar Term
1.7.4. Di-Polar Term
1.7.5. Coordinate Origins in Multipole Expansions
1.7.6. Electric Field of an Electric Dipole

1.8. Electrostatics in Material Media I

1.8.1. Dielectric Field
1.8.2. Dielectric Types
1.8.3. Vector Displacement
1.8.4. Gauss's Law in Dielectric Presence
1.8.5. Boundary Conditions
1.8.6. Electric Field within Dielectrics

1.9. Electrostatics in Material Media II: Linear Dielectrics

1.9.1. Electrical Susceptibility
1.9.2. Electrical Permittivity
1.9.3. Dielectric Constant
1.9.4. Dielectric Systems Energy
1.9.5. Dielectric Forces

1.10. Magnetostatics

1.10.1. Magnetic Induction Field
1.10.2. Electric Currents
1.10.3. Magnetic Field Calculation: Biot and Savart's Law
1.10.4. Lorentz Force
1.10.5. Divergence and Rotational Magnetic Field
1.10.6. Ampere's Law
1.10.7. Magnetic Vector Potential

Module 2. Electromagnetism II

2.1. Magnetism in Material Mediums

2.1.1. Multi-Polar Development
2.1.2. Magnetic Dipole
2.1.3. Field Created by a Magnetic Material
2.1.4. Magnetic Intensity
2.1.5. Types of Magnetic Materials: Diamagnetic, Paramagnetic and Ferromagnetic
2.1.6. Border Conditions

2.2. Magnetism in Material Media II

2.2.1. Auxiliary Field H
2.2.2. Ampere's Law in Magnetized Media
2.2.3. Magnetic Susceptibility
2.2.4. Magnetic Permeability
2.2.5. Magnetic Circuits

2.3. Electrodynamics

2.3.1. Ohm's Law
2.3.2. Electromotive Force
2.3.3. Faraday's Law and its Limitations
2.3.4. Mutual Inductance and Self-Inductance
2.3.5. Induced Electric Field
2.3.6. Inductance
2.3.7. Magnetic Field Energy

2.4. Maxwell's Equations

2.4.1. Displacement Current
2.4.2. Maxwell's Equations in Vacuum and in Material Media
2.4.3. Boundary Conditions
2.4.4. Solution Uniqueness
2.4.5. Electromagnetic Energy
2.4.6. Electromagnetic Field Drive
2.4.7. Angular Momentum of Electromagnetic Fields

2.5. Conservation Laws

2.5.1. Electromagnetic Energy
2.5.2. Continuity Equation
2.5.3. Poynting's Theorem
2.5.4. Newton's Third Law in Electrodynamics

2.6. Electromagnetic Waves: Introduction

2.6.1. Wave Motion
2.6.2. Wave Equation
2.6.3. Electromagnetic Spectrum
2.6.4. Plane Waves
2.6.5. Sine Waves
2.6.6. Boundary Conditions:
2.6.7. Polarization

2.7. Electromagnetic Waves in Vacuums

2.7.1. Wave Equation for Electric Fields and Magnetic Induction
2.7.2. Monochromatic Waves
2.7.3. Electromagnetic Wave Energy
2.7.4. Electromagnetic Wave Momentum

2.8. Electromagnetic Waves in Materials

2.8.1. Flat Dielectric Waves
2.8.2. Flat Conductor Waves
2.8.3. Wave Propagation in Linear Media
2.8.4. Medium Dispersive
2.8.5. Reflection and Refraction

2.9. Waves in Confined Mediums I

2.9.1. Maxwell's Guide Equations
2.9.2. Dielectric Guides
2.9.3. Modes in a Guide
2.9.4. Propagation speed
2.9.5. Rectangular Guide

2.10. Waves in Confined Mediums

2.10.1. Resonant Cavities
2.10.2. Transmission Lines
2.10.3. Transitional Regime
2.10.4. Permanent Regime

A unique, key and decisive training experience to boost your professional development"