Help engineer the future
Forget about robots coming to take your job – instead, make it your job to design the robots and automated systems of the future. Mechatronics is an exciting field that combines the best of mechanical, electrical and computer engineering to create new technologies and constantly improve the systems around us. With automation set to play an increasing role in almost every product and industry, this degree will give you skills that are in demand and future-proof your engineering career.
Forget about robots coming to take your job – instead, make it your job to design the robots and automated systems of the future. Mechatronics is an exciting field that combines the best of mechanical, electrical and computer engineering to create new technologies and constantly improve the systems around us. With automation set to play an increasing role in almost every product and industry, this degree will give you skills that are in demand and future-proof your engineering career.
In this degree you will:
- Study the fundamentals of engineering, including applied maths, physics, statistics and system design
- Learn about robotics and autonomous systems, communication engineering, digital logic and computer programming, machine vision and more
- Choose the area you want to specialise in, including electrical or mechanical engineering, management or entrepreneurship
- Get hands-on project management experience by designing your own major engineering research project
Career opportunities
Mechatronics engineers work across a range of fields, including robotics engineering, industrial engineering and product design, manufacturing, data communications, automotive and more.
Membership
Graduates are eligible for registration with Engineers Australia as professional engineers, following five years of suitable professional engineering experience.
Accreditation
This program is currently undergoing provisional accreditation by Engineers Australia.
Program structure
Introductory courses (8) 96 units
COR109 Communication and Thought
ENG101 Foundations of Engineering
ENG102 Engineering Statics
ENG103 Introduction to the Internet of Things
ENG104 Introduction to Engineering Design
MTH103 Introduction to Applied Mathematics
MTH104 Introductory Calculus
SCI107 Physics
Developing courses (8) 96 units
ELC200 Digital Logic and Computer Programming
ELC201 Electronic Circuits: Fundamental Theory and Applications
ELC205 Introduction to Control Systems
MEC200 Introduction to Thermofluids
MEC205 Dynamics 1*
MEC221 Mechanics of Materials
MEC225 Engineering Materials*
MCH200 Mechatronic Design 1
Graduate courses (12) 144 units
MTH201 Calculus II and Linear Algebra
MTH203 Numerical Analysis
ELC301 Communications Engineering (Hardware and protocols)
ELC304 Embedded System Design
ENG302 Engineering Project Management
ENG304 Engineering Research Methodology
MCH301 Mechatronic Design 2
MEC336 Engineering System Design*
ELC400 Robotics and Autonomous Systems
ENG401 Engineering Project 1
ENG402 Engineering Project 2
MCH400 Image Processing and Machine Vision
Minor courses (4) 48 units
Students must select one of the following minor study areas:
- Electrical Engineering (for Mechatronic Engineers)
- Mechanical Engineering (for Mechatronic Engineers)
- Civil Engineering (for Mechanical and Mechatronic Engineers)
- Environmental Studies for Engineers
- Management for Engineers
- Entrepreneurship
- Wider Engineering Studies
Honours
The Bachelor of Engineering (Mechatronic) (Honours) may be awarded with a class of Honours to a
student:
- with the percentage results achieved in twelve courses as specified in the table below; and
- achieving at least 65% in ENG402 Engineering Research Project 2.
Courses |
MTH203 Numerical Analysis |
MCH200 Mechatronic Design 1 |
ELC301 Communications Engineering (Hardware and protocols) |
MEC336 Engineering System Design* |
ENG302 Engineering Project Management |
MCH301 Mechatronic Design 2 |
ELC304 Embedded System Design |
ENG304 Engineering Research Methodology |
ENG401 Engineering Project 1 |
ENG402 Engineering Project 2 |
ELC400 Robotics and Autonomous Systems |
MCH400 Image Processing and Machine Vision |
- The minimum levels of achievement normally required for each class of honours are shown in the following table:
Honours results classification | Overall Percentage attained in Specified Courses* |
Honours Class I | 80% - 100% |
Honours Class IIA | 70% - 79% |
Honours Class IIB | 60% - 69% |
*The percentage result shall be rounded up if ≥ 0.5 or rounded down if < 0.5.
Note: Program structures are subject to change. Not all USC courses are available on every USC campus.
Total units: 384
Program requirements and notes
Program requirements
In order to graduate you must:
- Successfully complete 384 units as outlined in the Program Structure
- Select a minor from one of the minors as listed below. Students must choose the minor to be studied before the completion of Semester 1, Year 3
- Complete a minimum of 60 days of suitable work experience. Students must meet all costs associated with the acquisition of practical experience to satisfy this requirement
Program notes
- Completing this program within the specified (full-time) duration is based on studying 48 unit points per semester (normally 4 courses) and following the recommended study sequence
- The unit value of all courses is 12 units unless otherwise specified
- It is each students responsibility to enrol correctly according to your course requisites, program rules and requirements and be aware of the academic calendar dates
- Courses within this program are assessed using a variety of assessment methods including essays, seminar presentations, reports, in-class tests and examinations. Not all courses will necessarily include all methods
- As part of your USC program, you may apply to Study Overseas to undertake courses with an overseas higher education provider
- Refer to the Managing your progression page for help in understanding your program structure, reviewing your progress and planning remaining courses.