Electrical Engineering Certification Course

Why Select this Training Course?

With new housing and commercial projects going up and an ageing engineering workforce, the demand for electricians with education and skills is increasing at unprecedented levels. It is anticipated that in the year 2030, 80% of electricity will be regulated by power electronics. To assist both freshmen and experts in the field, this Rcademy Electrical Engineering Certification Course explores both fundamental and advanced concepts. It contains concepts of electricity, theoretical methods, and engineering science. Throughout this course, participants will be offered a complete picture of the industry, including design, installation, estimating, and sales. This program presents fundamental electronics concepts such as op-amps, diodes, and transistors.

A professional certificate is not just a piece of paper; it’s a testament to your expertise and dedication in a particular area or subject. The Rcademy Electrical Engineering Certification Course offers participants a basic idea of how electric circuits can control and convert high-efficiency electrical power. The course lays out the principles of converter circuit analysis and further discusses the development of steady state voltages, current and efficiency of power converters. This certification will enhance your skills and boost your career prospects, making you a valuable asset in the industry.

What exactly does an electrical engineer do?

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Electrical engineers develop, design, test, and monitor the manufacture of electrical equipment, such as radar and navigation systems, electric motors, power generation equipment, and communications systems. They are also in charge of designing the electrical systems of aircraft and automobiles.

What is the difference between Electrical Engineering (EE) and Electrical and Electronics Engineering (EEE)?

The two branches differ: Electrical Engineering (EE) focuses on using electricity to transmit energy, while Electrical and Electronics Engineering (EEE) combines both electrical and electronics principles, concentrating on using electricity to transmit information.

Who Should Attend?

The Rcademy Electrical Engineering Certification Course is designed to cater to a wide range of professionals within the power industry, including:

• New professionals in the power industry who have recently become involved with working with electrical engineering systems.
• Technicians or technical engineers engaged in electronics, meaning designing, manufacturing, electrical maintenance, testing or fault-finding.
• Electricians who just got hired and are only learning on the job.
• Journeyman electricians who have now completed their apprenticeship program and want to obtain higher level skill and knowledge.
• Leaders in electric engineering teams.
• Area managers in charge of supervising electrical engineering projects in specific regions or departments.
• Experts in charge of identifying the expenses and resources linked to electrical engineering jobs.

What are the Course Objectives?

After completing the Rcademy Electrical Engineering Certification Course, participants will be able to:

• Analyse and interpret the steady-state voltages and currents of various power converters, including step-down, step-up, and inverting converters.
• Understand the concept of a switched-mode converter and grasp its fundamental operating principles.
• Evaluate the integration of new technologies in future electric grid designs.
• Assess the advantages and disadvantages of employing untested technologies in power systems.
• Gain a comprehensive understanding of electric circuits and their basic operational principles.
• Learn techniques to derive averaged equivalent electric models and determine converter efficiencies.
• Implement power semiconductor devices effectively in switching converters.

How will this Course be Presented?

This participant-centred course is carefully designed to meet the expectations of attendees while enhancing their knowledge and skills. Various practical methodologies ensure active and continuous learning throughout the program. Led by esteemed professionals with significant experience in the field, the course content is informed by extensive research, ensuring its relevance and depth.

The Rcademy Electrical Engineering Certification Course offers a comprehensive blend of practical and theoretical learning. Participants gain access to a range of resources, including slides, lecture notes, case studies, video presentations, and real-life scenarios. Interactive quizzes, seminars, and mock sessions reinforce learning and engagement. Moreover, a feedback platform ensures participants’ optimal satisfaction with the course content and delivery.

What are the Topics Covered in this Course? 

Module 1: Introduction to Electrical Engineering

• Overview of electrical engineering
• Historical development and milestones
• Basic electrical quantities and units
• Circuit elements and analysis techniques
• Introduction to circuit simulation software

Module 2: Circuit Analysis

• Ohm’s Law and Kirchhoff’s Laws
• Series and parallel circuits
• Mesh and Nodal analysis
• Network theorems (Thevenin, Norton, Superposition)
• Transient analysis of circuits
• AC circuit analysis (impedance, phasors, power)

Module 3: Electronic Devices and Circuits

• Semiconductor physics
• Diodes and applications
• Bipolar Junction Transistors (BJTs)
• Field Effect Transistors (FETs)
• Amplifiers and operational amplifiers
• Digital logic circuits

Module 4: Electromagnetic Fields and Waves

• Electrostatics and Coulomb’s Law
• Gauss’s Law and Electric Flux
• Magnetic fields and forces
• Faraday’s Law of Electromagnetic Induction
• Maxwell’s equations
• Electromagnetic waves and propagation

Module 5: Electrical and Electronic Principles

• Engineering design
• Engineering maths
• Engineering science
• Managing a professional engineering project

Module 6: Electronics Review

• Review of circuit elements
• Review of Kirchhoff’s Laws
• Review of impedance
• Review of transfer functions
• Review of frequency response plots

Module 7: Steady-State Converter Analysis

• Volt-Sec Balance and Small Ripple Approximation
• Boost converter example

Module 8: Job Roles

• Responsibilities of electrical engineers
• Circuitry and power generation
• Planning, designing, and implementing projects
• Integration of 21st-century computing technology and electrical devices
• Introduction to Biomedical Engineering

Module 9: Steady-State Equivalent Circuit Modelling, Efficiency, and Losses

• DC transformer model
• Supplement: Ideal transformers in circuits
• Inductor copper loss
• Constructing equivalent circuit models
• Instructions for acquiring model input ports
• Example: Conduction losses in boost converter semiconductor

Module 10: Op Amp Introduction

• Basic concepts and ideal behaviour
• Buffer Circuitry
• Common Op Amp Configurations
• Applications: Differentiators, integrators, active filters

Module 11: Advanced Op Amp Insights

• First-order Low Pass Filters
• First-order Pass Filters
• Cascaded First-order Filters
• Second-order Transfer Functions and Circuits
• Design Example: Low Pass Filter
• Active filtering techniques
• Additional: Cascaded Filter transfer function
• Additional: Derivation of Sallen-key Low Pass Filter Transfer Function

Module 12: Diode Fundamentals

• Introduction to PN junctions
• Modelling Diode Behaviour
• Ideal Diodes
• Assumed states method
• Ideal Diode with Voltage Source Model

Module 13: Advanced Diode Analysis

• Half-Wave Rectification
• Full-Wave Rectification
• Voltage transfer characteristics
• AC to DC conversion techniques
• Limiter circuits
• Voltage regulation methods
• Envelope detection circuitry

Module 14: Power Systems

• Introduction to power generation, transmission, and distribution
• Single-Phase and Three-Phase systems
• Transformers and power distribution
• Transmission line parameters and performance
• Power system stability and control
• Renewable energy sources and integration

Module 15: Control Systems

• Introduction to control systems
• Modelling of dynamic systems
• Control system components (controllers, sensors, actuators)
• Time and Frequency Domain Analysis
• Stability Analysis and Root Locus Method
• PID control and advanced control techniques

Module 16: Communication Systems

• Introduction to communication engineering
• Analog and digital modulation techniques
• Demodulation and detection methods
• Noise in communication systems
• Introduction to wireless communication

Module 17: MOSFET Fundamentals

• Introduction to MOSFETs and their physics
• MOSFET as switches
• CMOS Logic Gates
• MOSFET characteristics
• DC analysis of Common Source Amplifiers
• AC analysis of Common Source Amplifiers

Module 18: Bipolar Junction Transistors (BJTs)

• Introduction to Bipolar Junction Transistors
• BJT Terminal Characteristics
• BJT Parameters
• BJT Curve Tracing
• BJT Switching Applications
• Common Emitter Amplifier Configuration for BJTs
• AC Behaviour Analysis of Common Emitter Amplifiers

Module 19: Additional Topics

• Electrical machines overview
• Microprocessor systems
• Programmable logic controllers

Module 19: Emerging Technologies

• Renewable energy technologies
• Electric Vehicles (EVs) and charging infrastructure
• Smart grid and grid modernisation
• 5G and wireless communication technologies
• Energy efficiency and power electronics

Module 20: Trends

• Internet of Things & AI
• Application of Nanotechnology
• 3D printing
• Robot Phlebotomists
• Circuit design