ICTQual Level 5 Diploma in Electrical Engineering 240 Credits – Two Years

Learning Outcomes for ICTQual Level 5 Diploma in Electrical Engineering

Upon successful completion of the ICTQual Level 5 Diploma in Electrical Engineering, students will have gained the knowledge, skills, and expertise necessary to excel in the electrical engineering field. The learning outcomes are structured around foundational principles, intermediate proficiency, and advanced specialization, ensuring comprehensive expertise in electrical engineering.

---

Year 1 (120 Credits) – Learning Outcomes

1. Introduction to Electrical Engineering:
   • Understand fundamental electrical engineering concepts, principles, and their applications.
   • Identify the role of electrical engineering in modern technologies and industries.
2. Engineering Mathematics:
   • Apply mathematical techniques such as calculus, algebra, and differential equations to solve electrical engineering problems.
   • Use mathematical tools to model and analyze electrical circuits and systems.
3. Basic Circuit Analysis:
   • Analyze and design basic electrical circuits, applying Ohm’s Law, Kirchhoff’s Laws, and other fundamental principles.
   • Understand the behavior of resistive, capacitive, and inductive components in DC and AC circuits.
4. Electrical Machines and Transformers:
   • Identify and explain the operation of electrical machines, including motors, generators, and transformers.
   • Analyze the working principles, efficiency, and applications of different electrical machines.
5. Digital Electronics:
   • Understand the basic principles of digital electronics, including logic gates, flip-flops, and combinational circuits.
   • Design and implement simple digital circuits using fundamental electronic components.
6. Electrical Power Systems Fundamentals:
   • Understand the basic structure and components of electrical power systems, including generation, transmission, and distribution.
   • Analyze and evaluate power flow and stability in simple electrical power networks.
7. Electromagnetic Principles:
   • Understand the fundamental principles of electromagnetism, including electric fields, magnetic fields, and electromagnetic waves.
   • Apply electromagnetic concepts to the design and analysis of electrical systems and devices.
8. Health and Safety in Engineering:
   • Identify and apply health and safety regulations and best practices when working with electrical systems and equipment.
   • Understand the risks and hazards associated with electrical engineering and implement safety measures.
9. Physics for Electrical Engineers:
   • Apply basic physics principles to electrical engineering problems, including force, energy, and power calculations.
   • Use physics concepts to understand the behavior of electrical systems and components.
10. Technical Drawing and CAD for Electrical Systems:

• Develop technical drawings for electrical systems using CAD software.
• Interpret and create schematics for electrical circuits, systems, and installations.

11. Introduction to Renewable Energy Systems:

• Understand the basic concepts and technologies related to renewable energy sources, such as solar, wind, and hydroelectric power.
• Evaluate the feasibility and integration of renewable energy systems into existing power networks.

12. Communication and Professional Skills:

• Develop effective communication skills, both written and verbal, for professional engineering contexts.
• Enhance teamwork, problem-solving, and presentation skills within technical environments.

---

Year 2 (120 Credits) – Learning Outcomes

1. Advanced Circuit Design:
   • Design and analyze complex electrical circuits using advanced techniques such as feedback and operational amplifiers.
   • Use simulation tools to model and optimize circuit performance.
2. Power Electronics:
   • Understand and design power electronic circuits, including rectifiers, inverters, and voltage regulators.
   • Analyze the performance and efficiency of power electronic systems in energy conversion and control applications.
3. Control Systems Engineering:
   • Design and analyze control systems, including feedback loops, controllers, and stability analysis.
   • Apply control systems theory to design automated systems and improve system performance.
4. Electrical Machines and Drives:
   • Understand the operation and control of electrical drives, including motors and actuators.
   • Design and implement drive systems for various industrial applications, optimizing for efficiency and control.
5. High Voltage Engineering:
   • Analyze and design high-voltage electrical systems, including transformers, circuit breakers, and insulation.
   • Understand the safety, testing, and maintenance procedures for high-voltage electrical equipment.
6. Energy Management and Power Distribution:
   • Evaluate and implement energy management systems for optimizing power generation, distribution, and consumption.
   • Design and analyze power distribution systems to ensure efficient and reliable energy supply.
7. Microcontroller and Microprocessor Systems:
   • Understand the architecture and programming of microcontrollers and microprocessors for embedded systems.
   • Design and develop control systems using microprocessors in electrical applications.
8. Automation and Industrial Control Systems:
   • Design and implement automated control systems, including PLCs and SCADA systems.
   • Apply industrial control techniques to optimize production and manufacturing processes.
9. Instrumentation and Measurement:
   • Design and apply instrumentation systems for measuring electrical parameters such as voltage, current, and resistance.
   • Use measurement systems and sensors for monitoring and control in electrical engineering applications.
10. Electrical System Protection and Relaying:
    • Understand the principles of electrical protection, including circuit breakers, fuses, and protective relays.
    • Design and implement protection systems to ensure the safe operation of electrical networks and equipment.
11. Project Management for Engineers:
    • Develop skills in managing engineering projects, including budgeting, scheduling, and risk management.
    • Learn to lead and collaborate with teams to successfully complete engineering projects.
12. Capstone Project in Electrical Engineering:
    • Apply the knowledge and skills gained throughout the course to a practical engineering project.
    • Conduct independent research, design, and analysis in an area of electrical engineering, demonstrating professional engineering capabilities.