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

The ICTQual Level 5 Diploma in Electrical Engineering is an industry-leading qualification designed to equip students with the knowledge and skills required to excel in electrical engineering. This 240-credit program spans two years, offering a comprehensive curriculum that blends theory with practical application. By the end of this course, learners will be well-prepared for a variety of roles within the electrical engineering field, including design, maintenance, and development of electrical systems.

The ICTQual Level 5 Diploma in Electrical Engineering is a higher-level qualification aimed at individuals looking to advance their careers in electrical engineering. The course is structured to be completed over two years, with a total of 240 credits required for certification. This qualification is suitable for those seeking to deepen their understanding of electrical principles, enhance their technical skills, and prepare for leadership roles within the engineering sector.

This two-year course is carefully designed to cover both theoretical concepts and hands-on experience in electrical engineering. Students will study a wide range of topics, including electrical circuit theory, electronic systems, power systems, and control systems. The curriculum also includes project management, health and safety in engineering environments, and sustainable energy solutions, ensuring a well-rounded understanding of modern electrical engineering practices.

Upon completion of the ICTQual Level 5 Diploma in Electrical Engineering, students will be equipped with the skills and knowledge to pursue a wide variety of career paths in electrical engineering. Graduates can expect to find job opportunities in sectors such as power generation, renewable energy, construction, and automation.

The ICTQual Level 5 Diploma in Electrical Engineering offers a comprehensive and flexible pathway for students seeking to advance their careers in electrical engineering. With a duration of two years and a total of 240 credits, this qualification ensures that graduates are well-prepared to tackle the challenges of the modern engineering landscape. If you’re looking to develop your expertise in electrical engineering and open doors to exciting career opportunities, this diploma could be the perfect step forward.

Study Units:

Year 1 (120 Credits)

• Introduction to Electrical Engineering
• Engineering Mathematics
• Basic Circuit Analysis
• Electrical Machines and Transformers
• Digital Electronics
• Electrical Power Systems Fundamentals
• Electromagnetic Principles
• Health and Safety in Engineering
• Physics for Electrical Engineers
• Technical Drawing and CAD for Electrical Systems
• Introduction to Renewable Energy Systems
• Communication and Professional Skills

Year 2 (120 Credits)

• Advanced Circuit Design
• Power Electronics
• Control Systems Engineering
• Electrical Machines and Drives
• High Voltage Engineering
• Energy Management and Power Distribution
• Microcontroller and Microprocessor Systems
• Automation and Industrial Control Systems
• Instrumentation and Measurement
• Electrical System Protection and Relaying
• Project Management for Engineers
• Capstone Project in Electrical Engineering

Learning Outcomes:

Below are the learning outcomes for each of the study units in the ICTQual Level 5 Diploma in Electrical Engineering program:

Year 1 (120 Credits)

Electrical Engineering Fundamentals

• Understand basic electrical concepts, including voltage, current, resistance, and power.
• Apply Ohm’s law and Kirchhoff’s laws in the analysis of electrical circuits.
• Demonstrate knowledge of the fundamental principles of electrical engineering.

Electrical Circuit Theory

• Analyze DC and AC circuits, including series and parallel circuits.
• Calculate current, voltage, power, and impedance in various electrical circuits.
• Apply Kirchhoff’s current and voltage laws to solve complex circuits.

Electronics and Semiconductor Devices

• Understand the principles of semiconductor materials and components.
• Analyze the operation of diodes, transistors, and other semiconductor devices.
• Apply knowledge of electronics in practical applications like amplifiers and oscillators.

Mathematics for Engineers

• Solve engineering problems using calculus, linear algebra, and differential equations.
• Apply mathematical techniques to electrical engineering contexts, such as circuit analysis and signal processing.
• Demonstrate proficiency in mathematical problem-solving for engineering scenarios.

Electrical Power Systems

• Understand the generation, transmission, and distribution of electrical power.
• Analyze the operation of electrical grids, including power flow, fault analysis, and protection systems.
• Explore the principles behind power system stability and efficiency.

Control Systems and Instrumentation

• Understand the principles of feedback control systems and their components.
• Design and analyze basic control systems used in electrical engineering.
• Evaluate and apply instrumentation systems for measuring and controlling electrical variables.

Electrical Machines and Transformers

• Analyze the operation of electrical machines such as motors and generators.
• Understand transformer principles, including efficiency, voltage regulation, and power transfer.
• Apply electrical machine principles to real-world applications like energy conversion and motor control.

Engineering Materials and Electrical Components

• Understand the properties and applications of materials used in electrical engineering.
• Identify and apply the characteristics of electrical components such as resistors, capacitors, and inductors.
• Evaluate the suitability of materials for various electrical engineering projects.

Electrical Safety and Risk Management

• Recognize electrical hazards and implement safety practices in electrical engineering environments.
• Understand relevant electrical safety regulations and standards.
• Assess and manage risks associated with electrical systems and equipment.

Renewable Energy Systems

• Understand the principles and technologies behind renewable energy sources like solar, wind, and hydroelectric power.
• Evaluate the integration of renewable energy systems into existing electrical power systems.
• Analyze the challenges and benefits of sustainable energy solutions.

Year 2 (120 Credits)

Advanced Electrical Circuit Analysis

• Apply advanced techniques to analyze complex AC and DC circuits, including resonance and impedance.
• Design and analyze filters and complex network systems.
• Utilize simulation tools for circuit analysis and optimization.

Microprocessors and Microcontrollers

• Understand the architecture and functioning of microprocessors and microcontrollers.
• Program microcontrollers to interface with electrical systems.
• Design embedded systems and understand their applications in electrical engineering.

Electromagnetic Fields and Waves

• Understand the principles of electromagnetism, including Maxwell’s equations and wave propagation.
• Analyze the behavior of electromagnetic fields in different materials and environments.
• Apply electromagnetic theory to the design of electrical systems, such as transmission lines and antennas.

Power Electronics and Electrical Drives

• Understand the operation of power electronics devices, such as thyristors, IGBTs, and MOSFETs.
• Design and analyze electrical drives and converters used in industrial applications.
• Evaluate the efficiency and performance of power electronic circuits.

Electrical System Design and Simulation

• Apply design principles to develop electrical systems for specific applications.
• Use simulation tools to model and test electrical systems.
• Analyze and optimize electrical system designs for performance and cost.

Energy Management and Optimization

• Understand techniques for managing energy consumption and reducing waste.
• Analyze energy use in electrical systems and propose optimization strategies.
• Apply principles of energy efficiency to industrial and commercial applications.

Advanced Control Systems

• Design and analyze advanced control systems, including PID and state-space controllers.
• Apply control theories to complex electrical systems such as robotics and automation.
• Evaluate system stability, performance, and response to disturbances.

Industrial Automation and Robotics

• Understand the principles of industrial automation and robotic systems.
• Design and implement automated control systems using PLCs and other industrial controllers.
• Apply robotics technology in manufacturing and automation systems.

Power Generation and Distribution Networks

• Analyze the design and operation of power generation facilities, including thermal, hydro, and nuclear plants.
• Evaluate the operation of electrical distribution networks, including substations and transformers.
• Understand the impact of emerging technologies like smart grids on power generation and distribution.

Electrical Engineering Project Management

• Apply project management techniques to plan, execute, and close electrical engineering projects.
• Understand project budgeting, resource allocation, and risk management strategies.
• Demonstrate leadership and teamwork skills in managing engineering projects.

Advanced Renewable Energy Systems

• Study advanced renewable energy technologies, including photovoltaic systems, wind turbines, and biomass.
• Evaluate the integration of renewable energy sources into national grids.
• Design and optimize renewable energy systems for efficiency and sustainability.

Electrical Maintenance and Fault Diagnosis

• Understand maintenance strategies for electrical systems and equipment.
• Develop fault diagnosis techniques for electrical systems, including testing and troubleshooting.
• Apply diagnostic tools to identify and resolve electrical faults.

Sustainable Electrical Engineering Solutions

• Explore sustainable engineering practices, including energy-efficient design and low-carbon technologies.
• Apply green engineering principles to electrical system design and operation.
• Evaluate the environmental impact of electrical engineering projects and propose sustainable solutions.

Engineering Ethics and Professionalism

• Understand the ethical responsibilities of electrical engineers in society.
• Explore professional standards and codes of conduct for electrical engineers.
• Apply ethical decision-making frameworks to real-world engineering scenarios.