Study Program: Mechatronics – Master (MSc)

The learning outcomes are defined in accordance with the mission and strategic objectives of the Faculty of Mechanical Engineering and are harmonized with the National Qualifications Framework (NQF) and the best European practices in higher education. Therefore, upon successful completion of Master studies in the Mechatronics program, the student will be able to:

1. Apply advanced mathematical and analytical methods to solve complex engineering problems in the field of mechatronics.
2. Design, model, and control dynamic systems using advanced and nonlinear control techniques, with the integration of sensors and signal processing.
3. Perform high-level measurements and signal analysis, applying advanced instrumentation and intelligent sensor technologies.
4. Apply business, quality management, and cost analysis principles to effectively manage mechatronic projects and industrial systems.
5. Develop complex software solutions and implement software engineering methodologies for mechatronic systems, including real-time and embedded applications.
6. Design and simulate mechanical and electrical systems using CAE tools and Finite Element Methods (FEM) within digital factory environments.
7. Analyze and develop robotic systems, including advanced robotics and autonomous mechatronic applications for industrial and specialized sectors such as food processing.
8. Interpret and analyze the dynamics of mechanical systems, including nonlinear behaviors and diagnostic methods for fault detection in complex systems.
9. Develop and integrate MEMS, micro-electromechanical systems, and apply them in innovative mechatronic products.
10. Perform system-level modeling and simulation, enabling effective prediction and optimization of mechatronic system performance.
11. Apply artificial intelligence and image processing techniques to improve automation, decision-making, and perception in intelligent mechatronic systems.
12. Design real-time hardware and software systems, ensuring reliable operation under strict performance and timing requirements.
13. Conduct applied research and complex engineering projects, demonstrating the ability to manage and implement innovative solutions in industry-relevant environments.
14. Demonstrate professional and ethical responsibility, effective communication, and leadership in multidisciplinary teams and professional practice.
15. Complete a Master-level thesis, showing competence in research methodology, technical writing, and advanced problem-solving in mechatronics.