ICTQual Level 6 Diploma in Electrical Engineering 360 Credits – Three Years

The ICTQual Level 6 Diploma in Electrical Engineering (360 Credits) is a robust and industry-focused program designed to equip aspiring electrical engineers with the skills, knowledge, and qualifications necessary to excel in today’s technology-driven world. Spanning three years, this comprehensive course is ideal for students aiming to master the fundamentals of electrical engineering while also gaining advanced insights into modern technologies and practices.

This diploma is tailored to meet the evolving needs of the engineering industry, providing students with a well-rounded education that blends theoretical knowledge with practical application. The program is structured to build expertise across core electrical engineering disciplines, including power systems, electronics, automation, and renewable energy technologies.

The ICTQual Level 6 Diploma in Electrical Engineering is more than just a qualification—it’s a stepping stone to a successful engineering career. By combining rigorous academics with hands-on training, this course ensures graduates are not only knowledgeable but also capable of tackling real-world challenges with confidence.

If you’re ready to embark on a transformative educational journey, the ICTQual Level 6 Diploma in Electrical Engineering is your ideal choice. With its structured curriculum, global recognition, and industry alignment, this three-year program is the key to unlocking your potential in the dynamic field of electrical engineering.

Study Units:

Year 1: Foundational Knowledge

1. Engineering Mathematics I
2. Fundamentals of Electrical Circuits
3. Principles of Electronics
4. Digital Logic Design
5. Electrical Machines and Transformers
6. Introduction to Control Systems
7. Engineering Drawing and CAD
8. Introduction to Microprocessors and Microcontrollers
9. Electrical Measurement and Instrumentation
10. Physics for Engineers
11. Health and Safety in Engineering
12. Sustainability in Electrical Engineering

Year 2: Intermediate Proficiency

1. Engineering Mathematics II
2. Power Systems Analysis
3. Analog Electronics
4. Embedded Systems and Applications
5. Electrical Energy Systems
6. Signals and Systems
7. Principles of Automation and Robotics
8. Industrial Electronics
9. Communication Systems Engineering
10. Renewable Energy Technologies
11. Electrical Project Management
12. Technical Report Writing and Research Methods

Year 3: Advanced Specialization and Application

1. Advanced Power Electronics
2. Smart Grid Technology
3. Electrical Machine Design
4. Advanced Control Systems
5. High Voltage Engineering
6. Instrumentation and Process Control
7. Advanced Embedded Systems
8. Energy Storage and Conversion Systems
9. Wireless and Optical Communication
10. Electromagnetic Compatibility
11. Capstone Project
12. Professional Development and Ethical Practices

Learning Outcomes:

Learning Outcomes for the Level 6 Diploma in Electrical Engineering 360 Credits – Three Years:

Year 1: Foundational Knowledge

1. Engineering Mathematics I
   • Demonstrate an understanding of fundamental mathematical principles and techniques used in electrical engineering, including algebra, calculus, and differential equations.
2. Fundamentals of Electrical Circuits
   • Analyze and design basic electrical circuits, applying Ohm’s Law, Kirchhoff’s Laws, and techniques for calculating voltage, current, and resistance.
3. Principles of Electronics
   • Understand the fundamental principles of electronics, including semiconductor physics, diodes, transistors, and their applications in various electrical devices.
4. Digital Logic Design
   • Apply digital logic principles to design, implement, and test combinational and sequential circuits using logic gates and flip-flops.
5. Electrical Machines and Transformers
   • Explain the working principles of electrical machines, including motors, generators, and transformers, and analyze their performance in various engineering applications.
6. Introduction to Control Systems
   • Understand basic control systems, including feedback loops and controllers, and evaluate their applications in regulating electrical systems.
7. Engineering Drawing and CAD
   • Create and interpret engineering drawings using traditional methods and Computer-Aided Design (CAD) tools, demonstrating proficiency in design communication.
8. Introduction to Microprocessors and Microcontrollers
   • Understand the basics of microprocessor and microcontroller systems, including their architecture, programming, and interfacing with external components.
9. Electrical Measurement and Instrumentation
   • Utilize electrical measurement tools and instruments to measure and analyze electrical quantities such as voltage, current, power, and frequency.
10. Physics for Engineers
    • Apply fundamental physics principles, including mechanics, thermodynamics, and electromagnetism, to solve engineering problems in electrical engineering.
11. Health and Safety in Engineering
    • Demonstrate awareness of health, safety, and environmental regulations in engineering, and apply them in practical electrical engineering settings.
12. Sustainability in Electrical Engineering
    • Identify and assess sustainable practices and technologies within electrical engineering, particularly in energy generation, consumption, and waste management.

Year 2: Intermediate Proficiency

1. Engineering Mathematics II
   • Apply advanced mathematical concepts and techniques, including vector calculus and complex analysis, to solve engineering problems in electrical systems.
2. Power Systems Analysis
   • Analyze and design power systems, including generation, transmission, and distribution, to ensure efficient and stable operation of electrical grids.
3. Analog Electronics
   • Design and analyze analog circuits, including amplifiers, filters, oscillators, and power supplies, for various applications in electrical engineering.
4. Embedded Systems and Applications
   • Develop and implement embedded systems using microcontrollers and software programming to create solutions for real-time applications.
5. Electrical Energy Systems
   • Evaluate and optimize electrical energy systems, including generation, storage, and distribution methods, with a focus on efficiency and sustainability.
6. Signals and Systems
   • Understand the theory and practical applications of signals and systems, including signal processing, Fourier analysis, and system response.
7. Principles of Automation and Robotics
   • Apply principles of automation and robotics to design systems for control, monitoring, and data collection in industrial and electrical applications.
8. Industrial Electronics
   • Design and implement industrial electronic systems, including sensors, actuators, and control circuits, for automation and manufacturing processes.
9. Communication Systems Engineering
   • Understand the principles and components of communication systems, including modulation, transmission, and signal processing techniques.
10. Renewable Energy Technologies
    • Analyze and evaluate renewable energy technologies such as solar, wind, and hydroelectric power, and assess their integration into electrical systems.
11. Electrical Project Management
    • Develop project management skills, including planning, scheduling, budgeting, and risk management, for the successful execution of electrical engineering projects.
12. Technical Report Writing and Research Methods
    • Demonstrate proficiency in writing technical reports, conducting research, and applying appropriate methodologies to solve engineering problems.

Year 3: Advanced Specialization and Application

1. Advanced Power Electronics
   • Design and analyze advanced power electronic systems, including converters, inverters, and power regulation techniques for high-performance applications.
2. Smart Grid Technology
   • Evaluate and implement smart grid technologies, including real-time data management, grid optimization, and integration of renewable energy sources.
3. Electrical Machine Design
   • Apply engineering principles to design, model, and optimize electrical machines, including motors and transformers, for specific industrial applications.
4. Advanced Control Systems
   • Analyze and design advanced control systems using modern techniques such as state-space analysis, optimal control, and adaptive control.
5. High Voltage Engineering
   • Understand and apply high voltage engineering principles, including insulation design, dielectric materials, and testing techniques for high-voltage equipment.
6. Instrumentation and Process Control
   • Design and implement instrumentation systems for monitoring and controlling industrial processes, ensuring safety, efficiency, and precision.
7. Advanced Embedded Systems
   • Develop advanced embedded systems for complex applications, including multi-threaded processing, real-time operating systems, and hardware/software integration.
8. Energy Storage and Conversion Systems
   • Analyze and design energy storage and conversion systems, such as batteries, capacitors, and fuel cells, for efficient energy use and distribution.
9. Wireless and Optical Communication
   • Understand and apply the principles of wireless and optical communication technologies, including antennas, modulation schemes, and fiber optics.
10. Electromagnetic Compatibility
    • Analyze and mitigate electromagnetic interference (EMI) in electrical systems, ensuring compliance with industry standards for electromagnetic compatibility.
11. Capstone Project
    • Apply the skills and knowledge gained throughout the program to complete an individual project, demonstrating problem-solving ability and engineering expertise.
12. Professional Development and Ethical Practices
    • Develop professional and ethical conduct in engineering, including communication, teamwork, leadership, and adherence to engineering codes of practice.