ICTQual AB Level 6 International Diploma in Mechatronics

Upon successful completion of the ICTQual AB Level 6 International Diploma in Mechatronics, learners will be able to:

Year 1 – Foundation in Mechatronics

Principles of Mechanical Engineering

• Understand core mechanical engineering concepts and principles.
• Analyse forces, stress, and mechanical properties in engineering applications.
• Apply mechanical principles to design simple engineering components.
• Develop problem-solving skills for mechanical systems and machinery.
• Enhance foundational knowledge for advanced mechatronic system design.

Fundamentals of Electrical and Electronic Engineering

• Understand basic electrical and electronic circuit principles.
• Analyse AC and DC circuits and their applications.
• Develop skills in designing and testing simple electronic systems.
• Apply electrical concepts to integrate mechanical and electronic systems.
• Build knowledge for advanced mechatronic and automation applications.

Engineering Mathematics

• Apply advanced mathematical techniques to engineering problems.
• Use calculus, algebra, and differential equations in system modelling.
• Develop analytical skills for problem-solving in mechatronics.
• Understand mathematical tools for simulation and control systems.
• Enhance quantitative reasoning for design and engineering analysis.

Introduction to Computer Programming

• Develop proficiency in programming languages relevant to mechatronics.
• Apply coding to automate processes and control systems.
• Understand algorithms and data structures for engineering applications.
• Implement simple programs for system modelling and simulation.
• Build computational thinking skills to solve engineering challenges.

Materials Science and Engineering

• Understand properties and applications of engineering materials.
• Analyse material selection for mechanical, electrical, and electronic systems.
• Develop skills in testing and evaluating material performance.
• Apply material science principles in design and manufacturing processes.
• Enhance knowledge for sustainable and durable engineering solutions.

Engineering Drawing and CAD

• Create and interpret technical drawings and schematics.
• Use computer-aided design (CAD) software for engineering modelling.
• Apply drafting standards to produce accurate and professional designs.
• Develop visualization skills for mechanical and mechatronic systems.
• Enhance practical design capabilities for complex engineering projects.

Basics of Control Systems

• Understand control theory and feedback system principles.
• Analyse simple control systems and stability criteria.
• Apply control concepts to mechanical and electrical systems.
• Develop foundational skills for automation and robotics applications.
• Build knowledge to design and implement basic control solutions.

Digital Logic and Microprocessors

• Understand principles of digital circuits and logic design.
• Analyse and design microprocessor-based systems.
• Apply digital logic to control and automation applications.
• Develop skills in integrating microprocessors with sensors and actuators.
• Build foundational knowledge for embedded system programming.

Sensors and Instrumentation

• Understand the working principles of sensors and measurement devices.
• Analyse sensor data for control and automation applications.
• Apply instrumentation techniques in monitoring engineering systems.
• Develop skills in selecting and integrating sensors into mechatronic systems.
• Enhance practical knowledge in precision measurement and data acquisition.

Fundamentals of Robotics

• Understand core concepts in robotics and automation.
• Analyse robotic mechanisms and motion control.
• Apply programming and control techniques to simple robotic systems.
• Develop skills in integrating mechanical, electrical, and electronic systems in robotics.
• Build foundational knowledge for advanced robotics and autonomous systems.

Health, Safety and Environmental Practices in Engineering

• Understand key principles of workplace health and safety.
• Analyse potential risks and implement preventive measures.
• Apply environmental sustainability practices in engineering projects.
• Develop skills to maintain safe and compliant engineering operations.
• Enhance awareness of professional responsibilities in engineering practice.

Communication and Technical Report Writing

• Develop professional technical writing skills for engineering documentation.
• Apply clear and structured communication for reports and presentations.
• Analyse technical data and present findings effectively.
• Enhance interpersonal and team communication skills.
• Build the ability to convey complex engineering concepts to diverse audiences.

Year 2 – Intermediate Studies in Mechatronics

Advanced Electrical and Electronic Systems

• Analyse complex electrical circuits and systems for engineering applications.
• Develop advanced troubleshooting skills for electrical and electronic systems.
• Apply electrical design principles in integrated mechatronic systems.
• Evaluate performance of electrical components in automation and robotics.
• Enhance knowledge for advanced control and embedded systems.

Applied Thermodynamics and Fluid Mechanics

• Understand principles of thermodynamics and fluid flow in engineering systems.
• Analyse energy transfer, heat engines, and fluid dynamics in mechatronics.
• Apply thermodynamic calculations to design efficient systems.
• Develop skills in thermal and fluid system problem-solving.
• Enhance understanding of energy efficiency and sustainable engineering.

Microcontrollers and Embedded Systems

• Understand microcontroller architectures and applications.
• Develop embedded system programming skills for control and automation.
• Apply microcontroller-based solutions in mechatronic systems.
• Analyse and integrate hardware and software components effectively.
• Build advanced skills in IoT and automation integration.

Automation and PLC Programming

• Understand principles of industrial automation and control.
• Develop programming skills for PLCs and automated systems.
• Apply automation techniques in manufacturing and robotics processes.
• Analyse system performance and implement improvements.
• Enhance capability to manage industrial automation projects.

Mechanical Design and Manufacturing Processes

• Analyse mechanical components and design for manufacturability.
• Apply CAD/CAM techniques in mechanical design.
• Understand material selection and manufacturing methods.
• Develop skills in integrating design with practical engineering applications.
• Enhance ability to produce efficient, reliable mechatronic components.

Dynamics and Vibration Analysis

• Understand mechanical dynamics and vibration principles.
• Analyse the impact of forces and motion on mechanical systems.
• Apply vibration analysis techniques to improve system stability.
• Develop predictive maintenance strategies using dynamic analysis.
• Enhance design skills for resilient and reliable engineering systems.

Power Electronics and Drives

• Understand principles of power electronics and motor drives.
• Analyse electrical drive systems for automation applications.
• Apply power electronics in mechatronic and robotic systems.
• Develop troubleshooting skills for drive and control systems.
• Build knowledge for energy-efficient and high-performance systems.

Robotics Systems and Applications

• Apply robotics concepts to design and implement automated solutions.
• Analyse robotic kinematics, dynamics, and control systems.
• Develop skills in programming and integrating robotic applications.
• Evaluate robotics systems for industrial and commercial use.
• Enhance understanding of human-robot interaction and automation trends.

Mechatronic System Design

• Integrate mechanical, electrical, and electronic systems into cohesive designs.
• Apply systems engineering principles to complex projects.
• Develop design optimization and problem-solving skills.
• Analyse system performance and implement improvements.
• Build expertise in designing functional and efficient mechatronic systems.

Data Acquisition and Signal Processing

• Understand principles of data acquisition and signal processing.
• Analyse sensor data for control and monitoring purposes.
• Apply signal filtering, sampling, and data interpretation techniques.
• Develop practical skills for instrumentation and automation systems.
• Enhance ability to make informed engineering decisions based on data.

Industrial Maintenance and Reliability Engineering

• Understand principles of maintenance planning and reliability analysis.
• Analyse failure modes and implement preventive strategies.
• Apply maintenance techniques to ensure system efficiency and uptime.
• Develop skills in predictive and corrective maintenance.
• Enhance knowledge for long-term system performance and sustainability.

Project Planning and Management in Engineering

• Develop project management skills specific to engineering contexts.
• Apply planning, scheduling, and resource management techniques.
• Analyse project risks and implement mitigation strategies.
• Develop leadership skills for managing technical teams.
• Enhance ability to deliver engineering projects successfully and efficiently.

Year 3 – Advanced Studies in Mechatronics

Intelligent Systems and Artificial Intelligence in Engineering

• Understand AI concepts and their applications in mechatronics.
• Apply machine learning algorithms to control and automation systems.
• Analyse intelligent systems for optimisation and predictive performance.
• Develop skills in AI-driven robotics and automation solutions.
• Enhance knowledge of emerging technologies in engineering innovation.

Advanced Control Engineering

• Understand advanced control strategies including PID, adaptive, and predictive control.
• Analyse and design control systems for complex engineering applications.
• Apply control techniques to robotics and automated systems.
• Develop skills in simulation and performance tuning of control systems.
• Enhance ability to optimise system performance and reliability.

Robotics and Autonomous Systems

• Design, implement, and program autonomous robotic systems.
• Analyse sensor integration, navigation, and control strategies.
• Develop problem-solving skills for autonomous operations.
• Apply robotics solutions in industrial, commercial, and research contexts.
• Enhance knowledge in autonomous decision-making and AI applications.

Smart Manufacturing and Industry 4.0

• Understand principles of Industry 4.0 and smart manufacturing systems.
• Apply IoT, automation, and cyber-physical integration in manufacturing.
• Analyse processes for efficiency, quality, and scalability improvements.
• Develop skills to implement intelligent manufacturing solutions.
• Enhance knowledge in digital transformation and industrial innovation.

Renewable Energy Systems and Applications

• Understand renewable energy technologies and their engineering principles.
• Analyse energy conversion systems for efficiency and sustainability.
• Apply mechatronic solutions in renewable energy projects.
• Develop skills in integrating energy systems with automation and control.
• Enhance knowledge of sustainable engineering practices.

Advanced Computer-Aided Design and Simulation

• Use advanced CAD and simulation tools for engineering design.
• Analyse mechanical and electrical systems using virtual modelling.
• Apply simulations to optimise design and system performance.
• Develop skills in virtual prototyping and design validation.
• Enhance ability to implement complex engineering solutions effectively.

Cyber-Physical Systems and IoT in Engineering

• Understand integration of cyber-physical systems and IoT technologies.
• Apply IoT solutions for monitoring, control, and automation.
• Analyse system performance and data-driven optimisation.
• Develop skills in networked and interconnected engineering systems.
• Enhance knowledge of smart systems and Industry 4.0 applications.

Advanced Mechatronic System Integration

• Integrate mechanical, electrical, electronic, and software components into advanced systems.
• Analyse system performance, reliability, and efficiency.
• Apply design principles to complex mechatronic and robotic solutions.
• Develop skills in troubleshooting and optimisation of integrated systems.
• Enhance ability to deliver high-performance engineering solutions.

Engineering Research Methods

• Understand research methodology and experimental design in engineering.
• Analyse data and evaluate engineering solutions critically.
• Apply research techniques to problem-solving and innovation.
• Develop skills in technical reporting, literature review, and evidence-based decision-making.
• Enhance ability to conduct professional and applied research in engineering.

Professional Ethics and Sustainability in Engineering

• Understand ethical responsibilities in engineering practice.
• Apply sustainability principles in design, manufacturing, and system integration.
• Analyse the social and environmental impact of engineering solutions.
• Develop skills in responsible decision-making and professional conduct.
• Enhance knowledge of corporate responsibility and sustainable engineering practices.

Innovation and Entrepreneurship in Technology

• Understand principles of technological innovation and business development.
• Analyse market opportunities for engineering products and solutions.
• Apply entrepreneurial thinking to engineering projects.
• Develop skills to commercialise and implement innovative technologies.
• Enhance knowledge of business strategy, start-ups, and technology management.

Final Year Major Project (Capstone Project)

• Apply all theoretical and practical knowledge from the program to a real-world project.
• Develop problem-solving, project management, and research skills.
• Analyse, design, implement, and evaluate a complex mechatronic system.
• Demonstrate creativity, technical competence, and professional skills.
• Produce a comprehensive report and presentation showcasing mastery in mechatronics.