Master of Engineering (Mechatronic)

Make smarter machines

Mechatronic engineering combines mechanics, electronics and computing. Mechatronic engineers work comfortably across all three areas, often creating complex and intelligent technologies.

This intensive degree is suited to high-achieving engineering graduates, as well as engineers with relevant work experience. It is fully accredited by

Our Master of Engineering (Mechatronic) comprises a foundation year and an advanced studies year. You will:

• take advanced courses in mechanical engineering and programming
• gain hands-on mechatronic experience through small-group projects
• pursue specialist topics according to your interests and career goals
• build communication and project management skills
• undertake a significant research project.

You might design and optimise micro-machines, craft the next generation of cameras or help build underwater exploration vehicles. You could maintain a fully automated robotic assembly line. Perhaps you'll develop cutting-edge defence or medical technologies.

• Ranked #50 in the world for computer science and engineering^
• Undertake a major research project supervised by world-class academic staff
• Graduates qualify for professional membership with Engineers Australia

^ARWU, 2022

• 12 units of core courses;
• 12 units of foundation courses;
• 12 units of advanced technical coursework and;
• a project to the value of 12 units, which introduces candidates to research.

Program Learning Outcomes

1. Employ highly developed oral and written communication skills to communicate complex information and present persuasive arguments.
2. Exercise professional judgement, founded on a strong commitment to principles of continuing professional development, ethics, sustainability and social responsibility.
3. Contribute pro-actively to the work of teams, both as a team member and a team leader, and maintain respectful, constructive and diverse team environments.
4. Plan and manage resources using systematic methodologies to create solutions to complex engineering problems.
5. Think critically and independently, apply logic and exercise judgement to create safe and sustainable outcomes.
6. Apply in-depth knowledge of the principles and methods of research, and of the research directions in the nominated field of specialisation to devise innovative engineering solutions.
7. Demonstrate comprehensive knowledge of the natural and physical sciences, and mathematical and computer sciences, which underpin the nominated field of specialisation.
8. Apply an in-depth specialist body of knowledge and skills in the nominated field of specialisation.
9. Create innovative solutions to complex socio-technical problems using the established engineering methods, tools and processes in the nominated field of specialisation.