Bachelor of Engineering (Robotics)

The Bachelor of Engineering (Robotics) requires four years of full-time study (or the equivalent part-time).

These courses are offered by the School of Computer Science, Engineering and Mathematics, within the Faculty of Science and Engineering.

• Admission requirements
• Course aims
• Learning outcomes
• Program of study
• Combined degrees
  
  

Admission requirements

The minimum requirements for consideration for entry to all undergraduate courses are specified in detail in the University Entry Requirements.

Successful completion of either SACE Stage 2 (Year 12) Mathematical Studies or Mathematical Methods is normally required for entry to the Bachelor of Engineering (Robotics). Knowledge of SACE Stage 2 (Year 12) Physics is assumed.

Course aims

The course has been designed to provide graduates with:

• a strong foundation in both the theoretical and the practical aspects of engineering, particularly those relevant to the systematic development of robotic systems
• an awareness of social, economic, cultural and environmental  aspects of (robotic) engineering
• an ability to critically analyse and evaluate information and solve problems
• an understanding of professional and ethical responsibilities and a commitment to them
• well developed written and oral communication skills
• structured engineering work experience
• the ability to work and interact professionally as an individual and as a member of multi-disciplinary teams
• an understanding of the need to undertake lifelong learning and the capacity to do so
• preparation for future management roles as professional engineers.

The course provides the foundations that will underpin ongoing professional development, preparing graduates for further study or for a career in an engineering related field or in other areas where the range of skills and knowledge acquired is needed or desirable.

Learning outcomes

On completion of the award, students will be able to:

• competently use professional skills and knowledge in the systematic development of complex robotic systems
• apply their skills and knowledge in a professionally responsible manner
• communicate effectively with other engineers and the wider global community using a wide range of communication technologies;
• work professionally as an individual and in a team
• understand describe the processes through which current knowledge was developed
• develop engineering solutions appropriate to the social, political, international, economic and environmental contexts in which they are applied
• engage in the process of continuing learning needed to retain the necessary level of professional skills and knowledge in the area of robotic engineering
• contribute successfully to project management.

On completion of the Bachelor of Engineering (Robotics), students will be eligible for professional membership of Engineers Australia.

Program of study

To qualify for the Bachelor of Engineering (Robotics) a student must complete 144 units with a grade of P or NGP or better in each topic, according to the program of study below.

Students achieving a credit level average or better at the end of third year will be allowed to enrol in the honours degree program in Engineering in their final year. Other students will be able to complete the ordinary degree program. Students admitted to the honours degree program and maintaining a credit average or better will be awarded the degree of Bachelor of Engineering with Honours. Students who complete the honours degree program but who fail to maintain a credit average and students who complete the ordinary degree program will be awarded the ordinary degree of Bachelor of Engineering.

Students who have successfully completed the first three years of the program (108 units) (plus Engineering Work Experience (0 units) if the practicum has not been completed) may exit with a Bachelor of Engineering Science.

This award has two recommended sequences:

• Sequence 1 - Intelligent Robotics
• Sequence 2 - Mechatronics

These recommended sequences indicate sensible progressions that will satisfy prerequisites. However, students are free to select topics from either sequence subject to meeting topic pre-requisites.

Not all topics are necessarily available in a given year.

Core - Year 1 topics

36 units comprising:

 COMP1102  Computer Programming 1  (4.5 units)
 ENGR1201  Digital Electronics 1  (4.5 units)
 ENGR1202  Analog Electronics 1  (4.5 units)
 ENGR1401  Professional Skills for Engineers  (4.5 units)
 ENGR1711  Engineering Design  (4.5 units)
 MATH1121  Mathematics 1A  (4.5 units)
 MATH1122  Mathematics 1B  (4.5 units)
 PHYS1332  Engineering Physics 1  (4.5 units)

Core - Year 2 topics

27 units comprising:

 ENGR2701  Engineering Programming  (4.5 units)
 ENGR2702  Electrical Circuits and Machines  (4.5 units)
 ENGR2711  Engineering Mathematics  (4.5 units)
 ENGR2721  Microprocessors  (4.5 units)
 ENGR2722  Signals and Systems  (4.5 units)
 ENGR2772  Sensors and Actuators  (4.5 units)

Plus 9 units from recommended sequence 1 or 2:

Option - Intelligent Robotics - Year 2 topics

 ENGR2712  Electronic Design and Automation  (4.5 units)
 ENGR2731  Electronic Circuits  (4.5 units)

Option - Mechatronics - Year 2 topics

 COMP3742  Intelligent Systems  (4.5 units)
 ENGR2771  Dynamics and Mechanical Design  (4.5 units)

Core - Year 3 topics

31.5 units comprising:

 ENGR3701  Computer Organisation and Design  (4.5 units)
 ENGR3704  Project Management for Engineering and Science  (4.5 units)
 ENGR3711  Control Systems  (4.5 units)
 ENGR3771  Robotic Systems  (4.5 units)

One of:

 ENGR3700  Engineering Practicum*  (13.5 units)
 ENGR3710  International Engineering Practicum*##  (13.5 units)

Plus 4.5 units from recommended sequence 1 or 2:

Option - Intelligent Robotics - Year 3 topics

 ENGR3721  Signal Processing  (4.5 units)

Option - Mechatronics - Year 3 topics

 ENGR2741  Mechanics and Structures  (4.5 units)

*With the permission of the Director of Studies (Engineering), students may undertake ENGR3403 Engineering Work Experience (0 units) in place of ENGR3700 Engineering Practicum or ENGR3710 International Engineering Practicum. ENGR3403 may be taken any time after the student has completed 72 units, plus 13.5 units of CSEM upper-level topics. CSEM upper-level topics must be selected from COMP, ENGR, MATH and STAT topics at 2000-level and above.

##ENGR3710 International Engineering Practicum should be selected by those students intending to undertake their Practicum outside of Australia. Enrolment is subject to approval by the School and will consider the quality and appropriateness of the placement. 

Core - Year 4 Honours program topics 

27 units comprising:

 ENGR4700  Honours Thesis  (18 units) OR
 ENGR4700A  Honours Thesis  (4.5/18 units) AND
 ENGR4700B  Honours Thesis  (4.5/18 units) AND 
 ENGR4700C  Honours Thesis  (4.5/18 units) AND 
 ENGR4700D  Honours Thesis  (4.5/18 units)  
 ENGR4711  Advanced Control Systems  (4.5 units)
 ENGR4712  Autonomous Systems  (4.5 units)

Option - CSEM option topics#&hash

Plus 4.5 units of CSEM option topics

Elective - Year 4 topics

Plus a 4.5 unit elective topic from across the University where entry requirements are met.

#&hashCSEM option topics must be selected from Table A, at least half of which will be chosen from those labelled as Computer Electronics (Group E). With permission of the Director of Studies, one CSEM option topic may be chosen from CSEM upper-level topics. CSEM upper-level topics must be selected from COMP, ENGR, MATH and STAT topics at 2000-level and above.

Core - Year 4 ordinary program topics

18 units comprising:

 ENGR4710  Engineering Project  (9 units) OR
 ENGR4710A  Engineering Project  (4.5/9 Units) AND 
 ENGR4710B  Engineering Project  (4.5/9 Units)  
 ENGR4711  Advanced Control Systems  (4.5 units)
 ENGR4712  Autonomous Systems  (4.5 units)

Option - CSEM option topics#&hash

Plus 13.5 units of CSEM option topics

Elective - Year 4 topics

Plus a 4.5 unit elective topic from across the University where entry requirements are met.

#&hashCSEM option topics must be selected from Table A, at least half of which will be chosen from those labelled as Computer Electronics (Group E). With permission of the Director of Studies, one CSEM option topic may be chosen from CSEM upper-level topics. CSEM upper-level topics must be selected from COMP, ENGR, MATH and STAT topics at 2000-level and above.

Combined degrees

The Bachelor of Engineering (Robotics) may also be studied in a combined degrees program with a:

• Bachelor of Computer Science
• Bachelor of Science
• Master of Business and Technology