Bachelor of Electrical and Electronics Engineering (Honours)
Deakin University
About
Gain practical, market-ready skills when you study Deakin’s Bachelor of Electrical and Electronics Engineering (Honours).
Explore renewables, alternative energy generation and the role of energy production in climate change, and get the hands-on experience and theoretical knowledge to tackle energy production challenges in a changing world.You’ll have access to the very latest electrical and electronics engineering tools in world-class, multi-million dollar facilities.From high-voltage labs capable of reaching up to 500kV, to Deakin’s new 8MW Microgrid facility and Visualisation and Control Centre, you’ll have everything you need to design, create and test your big ideas.
You’ll practise with the same tools professionals use and work alongside experienced engineers through industry placement opportunities that enable you to develop your professional networks before you graduate.Want to change the future of renewable energy and have a tangible impact on climate change?In addition to traditional theory-based classes, 50 per cent of each trimester is dedicated to learning via team-based projects.
You’ll tackle real-world industry problems and research, design, test and evaluate solutions, with the support of an academic.
Structure
To complete the Bachelor of Electrical and Electronics Engineering (Honours), students must attain 32 credit points. Units (think of units as ‘subjects’) are equal to 1 or 2 credit points, sometimes abbreviated as cps. Most students choose to study units amounting to 4 credit points (or cps) per trimester, and usually undertake two trimesters each year.
The course comprises a total of 32 credit points, which must include the following:
- 31 credit points of core units (including SEP499 Professional Engineering Practice (12 weeks) and 1 elective unit (1 credit point)
- completion of SEJ010 Introduction to Safety and Project Oriented Learning (0-credit point compulsory unit)
- Completion of STP050 Academic Integrity (0-credit point compulsory unit)
- completion of STP010 Career Tools for Employability (0 credit point compulsory unit)
- Cloud Campus enrolled students are required to attend campus mode conducted activities during the corresponding Intensive Week in a trimester. Attendance at campus mode activities is linked to assessment requirements within the Engineering programmes, failure to attend will result in not meeting the hurdle requirement of the respective assessment. Thus, a fail grade shall be awarded for the respective affected unit(s) for that particular trimester.
Entry requirements
If you are currently studying Year 12 in 2020 or completed Year 12 in 2018 or 2019 and have not attempted higher education or VET study since, your selection is based on the following.
Prerequisite subjects
Units 3 and 4: a study score of at least 25 in English EAL (English as an additional language) or at least 20 in English other than EAL; Units 3 and 4: a study score of at least 20 in one of Maths: Mathematical Methods or Maths: Specialist Mathematics.
ATAR
This course uses the ATAR as part of its selection consideration
Personal statement
If you wish for your professional, work, life or community experience to be considered you are required to complete and submit a personal statement. Learn more about the personal statement.
Selection is competitive and meeting the minimum entry requirements does not guarantee selection. Our Admission Criteria and Selection Policy outlines the principles of selection.
Learning outcomes
Deakin's graduate learning outcomes describe the knowledge and capabilities graduates can demonstrate at the completion of their course. These outcomes mean that regardless of the Deakin course you undertake, you can rest assured your degree will teach you the skills and professional attributes that employers value. They'll set you up to learn and work effectively in the future.
| outcome type | outcome description |
|---|---|
| Discipline-specific knowledge and capabilities | Integrate well-developed knowledge of physical sciences and engineering fundamentals, which underpins the engineering discipline to analyse complex engineering problems and to evaluate possible solutions. Apply professional engineering knowledge, and knowledge of contextual factors in order to design, develop and maintain sustainable engineering infrastructure, systems or products. Plan and execute research projects to show capacity for advanced knowledge and skills in an engineering discipline and thereby demonstrate the ability to continue professional development and/or scholarship. |
| Communication | Apply effective communication skills in a professional context to interpret, evaluate and present technical engineering information using oral, written, visual modes. Demonstrate proficiency in comprehending viewpoints of others and present arguments and justifications for representing engineering position to technical and non-technical audience. |
| Digital literacy | Identify, select and use digital technologies and tools relevant to the engineering discipline to generate, manage and share information. Demonstrate the ability to independently and systematically locate information, evaluate its reliability, and use the information for engineering design, problem solving and research purposes. |
| Critical thinking | Demonstrate autonomy and judgement through balanced application of logic, intellectual and research criteria to review, analyse, and synthesise information for engineering problem solving. |
| Problem solving | Apply engineering knowledge, skills and techniques to identify and define complex problems in a variety of contexts. Evaluate and use established engineering methods to identify potential solutions to independently and collaboratively resolve complex engineering problems and realise solutions. Demonstrate innovative and creative approaches and/or solutions in planning, designing or executing engineering projects. |
| Self-management | Evaluate own knowledge and skills using frameworks of reflection and take responsibility for learning and performance. Work responsibly and safely in engineering environments to demonstrate professionalism. |
| Teamwork | Undertake various team roles, work effectively within a team, and utilise effective teamwork skills in order to achieve learning goals. Apply interpersonal skills to interact and collaborate to enhance outcomes through shared individual and collective knowledge and creative capacity to optimise complex problem resolution. |
| Global citizenship | Formulate sustainable engineering practices by integrating aspects of design, development or research through concern for economic, environmental, social and cultural perspectives and values. Engage with global traditions and current trends in engineering practice in order to appreciate diversity, seek equity in outcomes and adopt ethical and professional standards. |
Institution
