University certificate
The world's largest faculty of engineering”
Why study at TECH?
In only 6 months, you will obtain the most advanced knowledge in Electromagnetism and its great potential in digital electronics”
Possessing a solid knowledge of Electromagnetism together with the technical and creative capacity of the Engineering professional will lead to the development of devices or systems, which will have a great impact on people's daily life. In fact, its discovery led to the creation of wireless communications, geolocation, radar and laser. Thus, new technologies, which have now been perfected, are based on this concept of physics.
The difficulty and complexity of Electromagnetic Engineering make it essential for companies to have highly qualified professional profiles with the capacity to provide innovation in a booming technological field. Given this scenario of growth and favorable for graduates, TECH has decided to create this program in Electromagnetism taught in a 100% online format, which will allow students to delve into the fundamentals of Electromagnetism, electrostatics in material media or electromagnetic waves in material media over the course of 6 months.
All this will be possible, thanks to the multimedia resources developed by the specialized team that teaches this program. These will lead you to delve, in a much more dynamic way, into the operation of different devices using analog and digital electronics, as well as the laws of conservation in Electromagnetism and their application in problem solving. Additionally, with the Relearning system, a methodology used by this academic institution, the students will reduce the long hours of study, so common in other teaching methods.
Therefore, engineering professionals have an excellent opportunity to advance their careers through a university program, which they can study whenever and wherever they wish. All you need is an electronic device (computer, tablet or cell phone) with an Internet connection to access, at any time, the syllabus available in the Virtual Campus. In addition, the students are free to distribute the teaching load according to their needs, which makes even easier for them to combine quality education with the most demanding responsibilities.
You are looking at a program that will give you the necessary learning to contribute your skills to the development of wireless networks”
This Postgraduate diploma 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 self-assessment can be used 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 electronic device with an Internet connection
You can comfortably delve into the operation of electrostatics both in vacuum and in material media thanks to this university education”
includes in its teaching staff a team of professionals from the field who bring to this program the experience of their work, in addition to recognized specialists from prestigious reference societies and universities.
Its 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 an immersive education programmed to learn in real situations.
The design of this program focuses on Problem-Based Learning, by means of which the professionals must try to solve the different professional practice situations that are presented throughout the program. For this purpose, the student will be assisted by an innovative interactive video system created by renowned experts.
A 100% online academic option, which will immerse you with a theoretical-practical approach in Electromagnetism and its different applications”
A Postgraduate diploma that will give you the boost you need to advance in your professional career as an electromagnetic engineer. Click and enroll now”
Syllabus
The syllabus of this Postgraduate diploma has been designed with a theoretical as well as practical approach, in order to offer students the most comprehensive and advanced information on Electromagnetism. In this way, it provides the graduates with a solid learning, to be subsequently applied in the field of Engineering. For this, it will have video summaries, diagrams, videos in detail or case studies, which will lead you both to deepen comfortably and to acquire a more grounded knowledge.
The Relearning system, based on the reiteration of contents, will allow you to advance in a much more natural and progressive way through this Postgraduate diploma. Enroll now”
Module 1. Electromagnetism I
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
1.1.2.2. Gradient
1.1.2.3. Divergence
1.1.2.4. Rotational
1.1.2.5. 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. Waves electromagnetic: 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 Material Media
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 II
2.10.1. Resonant Cavities
2.10.2. Transmission Lines
2.10.3. Transitional Regime
2.10.4. Permanent Regime
Module 3. Analog and Digital Electronics
3.1. Circuit Analysis
3.1.1. Element Constraints
3.1.2. Connection Constraints
3.1.3. Combined Constraints
3.1.4. Equivalent Circuits
3.1.5. Voltage and Current Division
3.1.6. Circuit Reduction
3.2. Analog Systems
3.2.1. Kirchoff’s Laws
3.2.2. Thévenin’s Theorem
3.2.3. Norton’s Theorem
3.2.4. Introduction to Semiconductor Physics
3.3. Devices and Characteristic Equations
3.3.1. Diode
3.3.2. Bipolar Transistors (BJTs) and MOSFETs
3.3.3. Pspice Model
3.3.4. Characteristic Curves
3.3.5. Regions of Operation
3.4. Amplifiers
3.4.1. Amplifier Operation
3.4.2. Equivalent Circuits of Amplifiers
3.4.3. Feedback
3.4.4. Frequency Domain Analysis
3.5. Amplification Stages
3.5.1. BJT and MOSFET Amplifier Function
3.5.2. Polarization
3.5.3. Equivalent Small-Signal Model
3.5.4. Single-Stage Amplifiers
3.5.5. Frequency Response
3.5.6. Connection of Amplifier Stages in Cascade
3.5.7. Differential Torque
3.5.8. Current Mirrors and Application as Active Loads
3.6. Operational Amplifier and Applications
3.6.1. Ideal Operational Amplifier
3.6.2. Deviations from Ideality
3.6.3. Sinusoidal Oscillators
3.6.4. Comparators and Relaxation Oscillators
3.7. Logic Functions and Combinational Circuits
3.7.1. Information Representation in Digital Electronics
3.7.2. Boolean Algebra
3.7.3. Simplification of Logic Functions
3.7.4. Two-Level Combinational Structures
3.7.5. Combinational Functional Modules
3.8. Sequential Systems
3.8.1. Concept of Sequential System
3.8.2. Latches, Flip-Flops and Registers
3.8.3. State Tables and State Diagrams: Moore and Mealy Models
3.8.4. Synchronous Sequential Systems Implementation
3.8.5. General Structure of a Computer
3.9. MOS Digital Circuits
3.9.1. Inverters
3.9.2. Static and Dynamic Parameters
3.9.3. Combinational MOS Circuits
3.9.3.1. Step Transistor Logic
3.9.3.2. Implementing Latches and Flip-Flops l
3.10. Bipolar and Advanced Technology Digital Circuits
3.10.1. BJT Switch. BTJ Digital Circuits
3.10.2. TTL Transistor-Transistor Logic Circuits
3.10.3. Characteristic Curves of a Standard TTL
3.10.4. Emitter-Coupled Logic Circuits ECL
3.10.5. Digital Circuits with BiCMOS
A 100% online program that will allow you to acquire advanced and solid knowledge about bipolar digital circuits and advanced technology”
Postgraduate Diploma in Electromagnetism
Electromagnetic Engineering is a fundamental branch for the development of current technology. From GPS to communication systems, the electronic devices we use every day are based on the principles of this discipline. That is why TECH has created this Postgraduate Diploma in Electromagnetism, a 100% online program that will allow you to specialize in this area and expand your job opportunities. Through this program, you will acquire the theoretical and practical knowledge necessary to understand the fundamentals of electromagnetism, conservation laws and their application in problem-solving.
Expand your professional field with this 100% online program
Through this Postgraduate Diploma in Electromagnetism, you will learn the basics of electrostatics and electromagnetic waves in material media, as well as the operation of different devices that use analog and digital electronics. The 100% online mode of this program will allow you to access the syllabus at any time and place, from a device with an Internet connection. In addition, the Relearning system, used by TECH, facilitates the understanding of the content through innovative multimedia resources, developed by experts in the field. In this way, you will be prepared to tackle highly complex and high-impact projects in the technological field.