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

Upon successful completion of the ICTQual Level 6 Diploma in Electrical Engineering 360 Credits – Three Years, learners will be able to:

Year 1: Foundational Knowledge

Engineering Mathematics I

• Apply fundamental mathematical principles to solve basic engineering problems.
• Demonstrate proficiency in algebra, calculus, and trigonometry for electrical applications.
• Use mathematical tools to analyze electrical circuits and engineering models.
• Develop problem-solving strategies for real-world engineering contexts.
• Enhance critical thinking for technical and logical decision-making.

Fundamentals of Electrical Circuits

• Explain the laws governing electrical circuits, including Ohm’s and Kirchhoff’s Laws.
• Analyze AC and DC circuits using appropriate mathematical methods.
• Apply circuit theorems for simplified problem-solving.
• Use simulation tools for circuit analysis and verification.
• Identify and resolve common circuit-related issues in engineering practice.

Principles of Electronics

• Understand the working principles of diodes, transistors, and operational amplifiers.
• Design and analyze basic electronic circuits for practical applications.
• Demonstrate knowledge of analog and digital electronic systems.
• Apply semiconductor principles to solve electronic engineering challenges.
• Evaluate performance of electronic devices through experimentation.

Digital Logic Design

• Explain the fundamentals of digital systems and binary logic.
• Design and implement combinational and sequential logic circuits.
• Apply Boolean algebra for simplification of logic expressions.
• Utilize digital logic to develop simple computing applications.
• Test and troubleshoot digital systems for accuracy and reliability.

Electrical Machines and Transformers

• Understand the construction and working principles of electrical machines.
• Explain the operation of DC machines, induction motors, and synchronous machines.
• Analyze the performance characteristics of transformers.
• Apply practical knowledge to machine testing and maintenance.
• Demonstrate safe handling of electrical machines in laboratory settings.

Introduction to Control Systems

• Explain the principles of open-loop and closed-loop control systems.
• Apply mathematical models for system behavior analysis.
• Use block diagrams and transfer functions to represent systems.
• Evaluate stability and response of control systems.
• Apply control theory to practical engineering applications.

Engineering Drawing and CAD

• Interpret and produce professional engineering drawings.
• Use CAD software to design electrical and mechanical components.
• Apply drawing standards and conventions to technical diagrams.
• Develop skills in 2D and basic 3D modeling.
• Communicate engineering ideas effectively through technical drawings.

Introduction to Microprocessors and Microcontrollers

• Understand the architecture and functions of microprocessors and microcontrollers.
• Write basic assembly and C programs for microcontroller applications.
• Interface input/output devices with microcontrollers.
• Apply embedded system principles to solve engineering problems.
• Test and debug simple microcontroller-based systems.

Electrical Measurement and Instrumentation

• Demonstrate knowledge of measurement principles in electrical engineering.
• Use instruments such as voltmeters, ammeters, and oscilloscopes effectively.
• Apply calibration techniques for measurement accuracy.
• Interpret experimental data and prepare technical reports.
• Ensure safety and precision in electrical measurements.

Physics for Engineers

• Apply mechanics, electromagnetism, and thermodynamics to engineering.
• Explain wave theory, optics, and material properties relevant to electrical systems.
• Relate physics principles to practical engineering design.
• Conduct laboratory experiments to validate theoretical concepts.
• Demonstrate scientific reasoning in solving technical challenges.

Health and Safety in Engineering

• Identify workplace hazards and implement safety measures.
• Apply health and safety regulations in engineering environments.
• Develop risk assessment strategies for engineering projects.
• Promote a culture of safety and responsibility in engineering practice.
• Ensure compliance with international occupational safety standards.

Sustainability in Electrical Engineering

• Understand principles of sustainability in engineering design.
• Evaluate the environmental impact of electrical systems.
• Apply energy-efficient solutions in electrical engineering projects.
• Incorporate renewable technologies in sustainable design.
• Promote sustainable practices in professional engineering roles.

Year 2: Intermediate Proficiency

Engineering Mathematics II

• Apply advanced calculus, differential equations, and linear algebra to electrical systems.
• Model and analyze dynamic engineering systems mathematically.
• Use numerical methods to solve complex engineering problems.
• Apply probability and statistics in engineering design and testing.
• Demonstrate advanced problem-solving and analytical skills.

Power Systems Analysis

• Explain the structure and operation of modern power systems.
• Analyze transmission and distribution networks.
• Apply load flow analysis for system optimization.
• Evaluate fault analysis and system stability.
• Propose improvements for efficient and reliable power delivery.

Analog Electronics

• Analyze and design analog circuits with amplifiers and oscillators.
• Apply frequency response and filter concepts.
• Demonstrate knowledge of feedback and stability in analog systems.
• Use simulation tools for analog circuit analysis.
• Troubleshoot analog circuits for performance optimization.

Embedded Systems and Applications

• Design embedded systems for real-world engineering applications.
• Apply programming skills in C/C++ for embedded devices.
• Interface sensors, actuators, and communication modules.
• Test and optimize embedded system performance.
• Apply embedded solutions in automation and robotics.

Electrical Energy Systems

• Explain the principles of energy generation, conversion, and distribution.
• Analyze renewable and non-renewable energy systems.
• Apply efficiency optimization techniques for energy systems.
• Evaluate energy storage and smart grid integration.
• Promote sustainable energy practices in engineering solutions.

Signals and Systems

• Analyze continuous and discrete-time signals.
• Apply Fourier and Laplace transforms in system analysis.
• Evaluate the response of linear time-invariant systems.
• Use MATLAB or similar tools for signal processing.
• Apply concepts in communication and control engineering.

Principles of Automation and Robotics

• Explain the fundamentals of automation and robotics systems.
• Design robotic control systems for industrial applications.
• Apply sensors, actuators, and controllers in robotics.
• Program robotic systems for automated tasks.
• Promote innovation in automation technologies.

Industrial Electronics

• Understand the principles of industrial electronic devices.
• Apply power electronics in industrial applications.
• Design control circuits for industrial machinery.
• Evaluate industrial automation systems.
• Ensure safety and reliability in industrial electronic systems.

Communication Systems Engineering

• Explain the fundamentals of analog and digital communication.
• Apply modulation and demodulation techniques.
• Evaluate noise and bandwidth in communication systems.
• Analyze wireless and optical communication technologies.
• Design and troubleshoot communication circuits.

Renewable Energy Technologies

• Understand the principles of solar, wind, hydro, and bioenergy systems.
• Evaluate performance of renewable energy installations.
• Design renewable systems for sustainable energy supply.
• Analyze integration of renewable energy into power grids.
• Promote innovation in renewable energy engineering.

Electrical Project Management

• Apply project management principles in electrical engineering.
• Develop project schedules, budgets, and resource plans.
• Manage risks and ensure quality in project execution.
• Communicate effectively with stakeholders in technical projects.
• Deliver successful projects within scope, time, and cost.

Technical Report Writing and Research Methods

• Write professional and structured technical reports.
• Apply research methods in engineering studies.
• Collect, analyze, and interpret engineering data.
• Reference academic sources using international standards.
• Communicate research findings clearly and effectively.

Year 3: Advanced Specialization and Application

Advanced Power Electronics

• Design and analyze advanced power electronic circuits.
• Apply converters, inverters, and power control devices.
• Evaluate efficiency and performance of power systems.
• Integrate renewable energy into power electronics applications.
• Apply advanced simulation tools for power electronics.

Smart Grid Technology

• Explain the architecture and components of smart grids.
• Analyze smart metering and demand-side management.
• Apply digital communication in smart grid systems.
• Evaluate cybersecurity challenges in smart grids.
• Promote smart energy solutions for sustainable power.

Electrical Machine Design

• Apply design principles for electrical machines.
• Use CAD and simulation tools for machine design.
• Evaluate performance of custom-designed machines.
• Apply standards and safety in machine design.
• Innovate in electrical machine technologies.

Advanced Control Systems

• Design advanced control strategies for engineering systems.
• Apply digital control and adaptive control techniques.
• Evaluate system stability and optimization.
• Use simulation software for control system design.
• Apply control theory in robotics, power, and automation.

High Voltage Engineering

• Understand principles of high voltage generation and testing.
• Analyze insulation systems for high voltage applications.
• Evaluate breakdown mechanisms and safety measures.
• Apply high voltage techniques in power transmission.
• Demonstrate safe practices in high voltage laboratories.

Instrumentation and Process Control

• Design and apply instrumentation systems for industrial processes.
• Evaluate sensors and transducers for accurate measurement.
• Apply process control strategies for automation.
• Ensure reliability and accuracy in instrumentation.
• Integrate instrumentation with advanced control systems.

Advanced Embedded Systems

• Design high-performance embedded systems for specialized applications.
• Apply real-time operating systems (RTOS) in embedded design.
• Interface advanced hardware modules with embedded processors.
• Optimize power consumption and system efficiency.
• Apply embedded systems in IoT and industrial automation.

Energy Storage and Conversion Systems

• Explain principles of energy storage technologies.
• Evaluate performance of batteries, supercapacitors, and fuel cells.
• Design systems for efficient energy storage and conversion.
• Apply hybrid storage solutions for smart grids.
• Promote innovation in energy storage technologies.

Wireless and Optical Communication

• Analyze wireless and optical communication systems.
• Apply modulation and multiplexing in modern communication.
• Evaluate system performance in different environments.
• Integrate wireless and optical systems for advanced networks.
• Promote innovation in high-speed communication technologies.

Electromagnetic Compatibility

• Explain principles of electromagnetic interference (EMI).
• Apply standards and regulations for EMC compliance.
• Design systems with improved electromagnetic compatibility.
• Evaluate shielding, grounding, and filtering techniques.
• Promote safe and reliable operation of electrical systems.

Capstone Project

• Apply theoretical and practical knowledge to real-world problems.
• Design, implement, and test an engineering solution.
• Demonstrate project management and teamwork skills.
• Communicate findings effectively through reports and presentations.
• Showcase innovation, creativity, and technical expertise.

Professional Development and Ethical Practices

• Demonstrate ethical practices in professional engineering.
• Apply leadership and teamwork skills in engineering contexts.
• Promote lifelong learning and continuous professional development.
• Ensure compliance with international engineering standards.
• Contribute positively to society through engineering practice.