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CC32 - Bachelor of Engineering (Honours) and Diploma of Professional Practice (Co-op Engineering)

Overview

Compulsory Residential School

Some units in this course require you to attend a compulsory Residential School or Work Integrated Learning. Please see Course Features in the Getting Started tab for further information.

Course Overview

The Bachelor of Engineering (Honours) and Diploma of Professional Practice (Co-op Engineering) allows you to gain hands-on experience in a professional industry environment, being paid while you learn. The course has a strong focus on contextual learning and promoting sustainable development, so you will apply theory to authentic scenarios throughout your course.

In your first year, you will develop skills in problem-solving, teamwork and professional practice together with learning foundation technical content. In the second term, you will undertake an authentic industry project with work-integrated learning. By the end of the first year, you will have experienced many engineering projects which will assist you in deciding which engineering discipline and course major you wish to pursue: Civil, Civil with Humanitarian, Electrical, Electrical with Data Analytics, Electrical with Information Processing, Mechanical, Mechatronics and Resource Systems.

Second-year is all about expanding knowledge and skills in your discipline. Your exposure to projects will continue, which will give you opportunities to apply the theoretical knowledge you have gained to deliver tangible engineering outcomes. As early as the end of your second year of study, you will go on an industry placement where you will develop your skills and experience in a professional engineering practice. Later in your course, you will complete a second placement, making a total of at least 48 weeks of paid industrial experience by the end of your course. The work placements allow you to earn while you learn, find out what engineering is about, put the theory you have learnt into practice and develop an industry network.

In the upper levels of your course, you will develop a deeper understanding of the foundation knowledge that you gained in the first and second years. In some units, you will explore specific aspects of your discipline. You will also complete up to three dual credit-point (12cp) units where you will work on authentic projects, sometimes with an industry mentor. In Civil, Electrical and Mechanical Majors, you will have the opportunity to choose an elective that will enhance your career prospects in your chosen field. Finally, you will complete a significant individual project for your undergraduate thesis to confirm your ability to work as a Professional Engineer.

This CQUniversity work-integrated-learning engineering course incorporates Project-Based Learning (PBL), Co-operative Education and Professional Practice, providing learning in context and industry employment integrated into your course. Teamwork and problem-solving skills are learned alongside technical content in exciting authentic contexts.

You will graduate with a Bachelor of Engineering (Honours) leading to qualification as a professional engineer and a Diploma of Professional Practice (Co-op Engineering) attesting to your advanced knowledge, skills and experience in professional engineering practice.

Career Information

As a professional engineer, you will create change by developing new technologies and solutions to improve working and living standards for the community while protecting the environment. Professional engineers engage with people from all sections of society. They must listen to societal needs and apply their knowledge of science, technology, mathematics, and engineering standards to design, prototype, implement, operate and maintain solutions to complex problems.

Civil engineers are typically involved in planning, designing and maintaining physical infrastructure systems, including the construction of buildings and bridges, transport and water resource systems, sewage and industrial waste systems, harbours and railways.

Electrical engineers are typically involved in designing, developing and maintaining electrical power and energy systems, including electricity generation and distribution, telecommunications, instrumentation and control, microprocessors and electronics.

Mechanical engineers are typically involved in planning, designing, installing, maintaining and operating machines, thermodynamic and combustion systems, fluid systems, materials handling systems, manufacturing equipment and process plant.

Resource Systems engineers are typically involved with designing, planning and operating mines and mineral and coal processing plants. They specialise in applying contemporary technologies to increase productivity, sustainability and safety of resource industry (mining and mineral processing) operations. In addition, they will work closely with Civil, Electrical and Mechanical engineers to maintain complex facilities.

Course Details
Duration 4.5 years full-time or 9 years part-time
Credit Points that Must be Earned 234
Number of Units Required CQUniversity uses the concept of credits to express the amount of study required for a particular course and individual units. The number of units varies between courses. Units in undergraduate courses normally consist of 6 points of credit or multiples thereof (e.g. 12, 18, 24).
Expected Hours of Study One point of credit is equivalent to an expectation of approximately two hours of student work per week in a term.
Course Type Undergraduate Double Degree
Qualification (post nominal) BEng (Hons)
AQF Level Level 8: Bachelor Honours Degree
Course Fees
Indicative Year - 2025
  • International Indicative First Term Fee - $20,160
  • International Indicative First Year Fee - $40,290
Indicative Year - 2024
  • Commonwealth Supported Place – Indicative First Year Fee - $7,819
  • Domestic Full Fee Paying – Indicative First Year Fee - $25,269
  • International Indicative First Term Fee - $18,510
  • International Indicative First Year Fee - $37,230
Indicative Year - 2023
  • Commonwealth Supported Place – Indicative First Year Fee - $7,253
  • International Indicative First Term Fee - $18,300
  • International Indicative First Year Fee - $36,600
Indicative Year - 2022
  • Commonwealth Supported Place – Indicative First Year Fee - $7,013
  • International Indicative First Term Fee - $18,030
  • International Indicative First Year Fee - $36,120

Admission Codes

Where and when can I start?
Units offered internally at the below campuses may be delivered using a combination of face-to-face and video conferencing style teaching.
Units offered via MIX mode are delivered online and require compulsory attendance of site-specific learning activities such as on-campus residential schools, placements and/or work integrated learning. See Course Features tab for further information. Online units are delivered using online resources only.
Please Click Here for more information.
The following tables list the courses availabilities by location and term. Directing your pointer over your preferred location will provide further information if this course is not available for the full duration. Please be sure to also check individual unit availability by location and term prior to enrolling.

Domestic Availability

Term 1 - 2026

Bundaberg
Cairns
Gladstone
Mackay
Online
Rockhampton

Term 1 - 2025

Bundaberg
Cairns
Gladstone
Mackay
Online
Rockhampton

Term 1 - 2024

Bundaberg
Cairns
Gladstone
Mackay
Online
Rockhampton

Term 1 - 2023

Bundaberg
Cairns
Gladstone
Mackay
Online
Rockhampton

Term 1 - 2022

The Mechatronics major is only available at the Mackay campus and by Mixed Mode (Online). The Resource Systems major is only available at Mackay (domestic only) and Rockhampton, and by Mixed Mode. Please see 'More Details' page for further information.
Bundaberg
Cairns
Gladstone
Mackay
Online
Rockhampton

Term 1 - 2021

Bundaberg
Cairns
Gladstone
Mackay
Rockhampton

Term 1 - 2020

The Mechatronics major is only available at the Mackay Campus and in Mixed Mode (Online). Please see the More Details section of the handbook for further information.
Bundaberg
Cairns
Gladstone
Mackay
Rockhampton

Term 1 - 2019

Bundaberg
Cairns
Gladstone
Mackay
Rockhampton

Term 1 - 2018

Bundaberg
Cairns
Gladstone
Mackay
Rockhampton

Term 1 - 2017

Bundaberg
Cairns
Gladstone
Mackay
Rockhampton

Term 1 - 2016

Bundaberg
Cairns
Gladstone
Mackay
Rockhampton

Term 1 - 2015

Bundaberg
Gladstone
Mackay
Rockhampton
Show All

International Availability

Term 1 - 2026

Cairns
Rockhampton

Term 1 - 2025

Sorry, no international availabilities found.

Term 1 - 2024

Cairns
Online
Rockhampton

Term 1 - 2023

Cairns
Rockhampton

Term 1 - 2022

The Mechatronics major is only available at the Mackay campus and by Mixed Mode (Online). The Resource Systems major is only available at Mackay (domestic only) and Rockhampton, and by Mixed Mode. Please see 'More Details' page for further information.
Cairns
Mackay
Rockhampton

Term 1 - 2021

Cairns
Mackay
Rockhampton

Term 1 - 2020

The Mechatronics major is only available at the Mackay Campus and in Mixed Mode (Online). Please see the More Details section of the handbook for further information.
Cairns
Rockhampton

Term 1 - 2019

Bundaberg
Cairns
Gladstone
Mackay
Rockhampton

Term 1 - 2018

Bundaberg
Cairns
Gladstone
Mackay
Rockhampton

Term 1 - 2017

Bundaberg
Gladstone
Mackay
Rockhampton

Term 1 - 2016

Bundaberg
Gladstone
Mackay
Rockhampton

Term 1 - 2015

Bundaberg
Gladstone
Mackay
Rockhampton
Show All
For any problems regarding admissions availability for the selected course please contact 13 CQUni (13 27 86) or send us an email at http://contactus.cqu.edu.au/
Entry Requirements - What do I need to start?
Entry Scores
Rank Threshold SR 72 | ATAR 72
Academic Requirements

English (Units 3 & 4, C) or equivalent; General Mathematics (Units 3 & 4, C) or equivalent

English Language Proficiency Requirements:

If you were not born in Australia, Canada, New Zealand, United Kingdom, Ireland, South Africa or the United States of America you are required to meet the English Language Proficiency requirements set by the University. Applicants are required to provide evidence of completion within the last 10 years of:

  • A secondary qualification (Year 11 and 12, or equivalent), or
  • Bachelor level qualification study for a period of at least 2 years full-time with a minimum overall GPA 4.0

completed in Australia, Canada, New Zealand, United Kingdom, Ireland, South Africa or the United States of America, which will meet the English proficiency.

If you do not satisfy any of the above you will need to undertake an English language proficiency test and achieve the following scores:

  • An International English Language Testing System (IELTS Academic) overall band score of at least 6.5, with a minimum 6.0 in each subset; or
  • An Occupational English Test with Grades A or B only in each of the four components.

English test results remain valid for no more than two years between final examination date and the date of commencement of study and must appear on a single result certificate.

International Students should visit http://www.cqu.edu.au/international for further information.

Each student will be assessed individually.

Assumed Knowledge

Recommended study: Mathematical Methods, Physics, and Design

Security Requirements

N/A

Health Requirements

N/A

Course Features

Awards and Accreditation

Interim Awards CC31 - Bachelor of Engineering (Honours)
Exit Awards CL42 - Diploma of Engineering Studies CC31 - Bachelor of Engineering (Honours)
Accreditation
  • Professional Practice: Electrical and Information Processing Major
    Engineers Australia

    The CC32 Bachelor of Engineering (Honours) Co-op course is fully accredited* by Engineers Australia

    Graduates are recognised as professional engineers and are eligible for Graduate membership with EA.

    *The following recently introduced majors have provisional accreditation until there are sufficient graduates for them to be reviewed by EA:

    • Electrical with Data Analytics
    • Electrical with Information Processing
    • Resource Systems
    • Civil with Humanitarian
  • Professional Practice: Electrical and Data Analytics Major
    Engineers Australia

    The CC32 Bachelor of Engineering (Honours) Co-op course is fully accredited* by Engineers Australia

    Graduates are recognised as professional engineers and are eligible for Graduate membership with EA.

    *The following recently introduced majors have provisional accreditation until there are sufficient graduates for them to be reviewed by EA:

    • Electrical with Data Analytics
    • Electrical with Information Processing
    • Resource Systems
    • Civil with Humanitarian
  • Professional Practice: Resource Systems Major
    Engineers Australia

    The CC32 Bachelor of Engineering (Honours) Co-op course is fully accredited* by Engineers Australia.

    Graduates are recognised as professional engineers and are eligible for Graduate membership with EA.

    *The following recently introduced majors have provisional accreditation until there are sufficient graduates for them to be reviewed by EA:

    • Electrical with Data Analytics
    • Electrical with Information Processing
    • Resource Systems
    • Civil with Humanitarian
  • Professional Practice: Civil and Humanitarian Major
    Engineers Australia

    The CC32 Bachelor of Engineering (Honours) Co-op course is fully accredited* by Engineers Australia

    Graduates are recognised as professional engineers and are eligible for Graduate membership with EA.

    *The following recently introduced majors have provisional accreditation until there are sufficient graduates for them to be reviewed by EA:

    • Electrical with Data Analytics
    • Electrical with Information Processing
    • Resource Systems
    • Civil with Humanitarian
  • Professional Practice: Mechatronics Major
    Engineers Australia

    The CC32 Bachelor of Engineering (Honours) Co-op course is fully accredited* by Engineers Australia

    Graduates are recognised as professional engineers and are eligible for Graduate membership with EA.

    *The following recently introduced majors have provisional accreditation until there are sufficient graduates for them to be reviewed by EA:

    • Electrical with Data Analytics
    • Electrical with Information Processing
    • Resource Systems
    • Civil with Humanitarian
  • Professional Practice: Mechanical Major
    Engineers Australia

    The CC32 Bachelor of Engineering (Honours) Co-op course is fully accredited* by Engineers Australia

    Graduates are recognised as professional engineers and are eligible for Graduate membership with EA.

    *The following recently introduced majors have provisional accreditation until there are sufficient graduates for them to be reviewed by EA:

    • Electrical with Data Analytics
    • Electrical with Information Processing
    • Resource Systems
    • Civil with Humanitarian
  • Professional Practice: Electrical Major
    Engineers Australia

    The CC32 Bachelor of Engineering (Honours) Co-op course is fully accredited* by Engineers Australia.

    Graduates are recognised as professional engineers and are eligible for Graduate membership with EA.

    *The following recently introduced majors have provisional accreditation until there are sufficient graduates for them to be reviewed by EA:

    • Electrical with Data Analytics
    • Electrical with Information Processing
    • Resource Systems
    • Civil with Humanitarian
  • Professional Practice: Civil Major
    Engineers Australia

    The CC32 Bachelor of Engineering (Honours) Co-op course is fully accredited* by Engineers Australia

    Graduates are recognised as professional engineers and are eligible for Graduate membership with EA.

    *The following recently introduced majors have provisional accreditation until there are sufficient graduates for them to be reviewed by EA:

    • Electrical with Data Analytics
    • Electrical with Information Processing
    • Resource Systems
    • Civil with Humanitarian

Residential School Requirements

Compulsory Residential School All units in this course are offered in online mode. Some units will have a compulsory Residential School for distance students. These Residential Schools give students an opportunity to develop and demonstrate practical skills.
Click here to view all Residential Schools

Practicum/Work Placement

ENEP12010 - 24 weeks industry placement
ENEP11006 - 24 weeks industry placement

Previous and Current Enrolments

Year Number of Students
2024 146
2023 137
2022 153
2021 167
2020 190
Inherent Requirements
There are Inherent Requirements (IRs) that you need to be aware of, and fulfil, to achieve the core learning outcomes of the units and course. IRs are the essential capabilities, knowledge, behaviours and skills that are needed to complete a unit or course.

Please note that in some instances there may be similarities between course, entry and inherent requirements.

If you experience difficulties meeting these requirements, reasonable adjustments may be made upon contacting accessibility@cqu.edu.au. Adjustment must not compromise the academic integrity of the degree or course chosen at CQUniversity or the legal requirements of field education.

Ethical Behaviour

Examples are:

  • Complying with academic and non-academic misconduct policies and procedures such as CQUniversity’s Student Charter, Student Misconduct Policy and Student Behavioural Misconduct Procedures and Assessment Policy and Procedure (Higher Education Coursework).
  • Using your knowledge and skills for the benefit of the community to create engineering solutions for a sustainable future, in accordance with the Engineers Australia Code of Ethics. In doing so, you will strive to serve the community ahead of other personal or sectarian interests.
  • Demonstrating integrity, scientific and technical competence, exude leadership qualities and promote sustainability, in the course of your engineering practice.
Behavioural Stability

Examples are:

  • Being reflective with personal behaviours in relation to professional performance and being positive and receptive to processing constructive supervisor/lecturer feedback or criticism.
  • Interacting with people from a wide range of backgrounds and cultures in a calm and composed manner in difficult to deal with situations.
  • Approaching difficult situations with diplomacy and refraining from using inappropriate words/actions either verbally or in written communication.
  • Accepting that engineering practice is a human-centric activity and that you must therefore, develop your ability to work well with others.
  • Having the desire to solve problems in order to improve the standard of living of the people in the community.
Legal Compliance

Examples are:

  • Understanding and complying with all relevant policies and procedures applicable in engineering practice.
  • Complying with rules and regulations that apply in your practice location.
  • Recognising and positively responding to any legal compliance issues that arise and bringing them to the attention of the appropriate stakeholders.
Communication Skills (Verbal, Non-verbal, Written and Technology)

Examples are:

  • Verbally communicating in the English language with accuracy, appropriateness and effectiveness.
  • Listening to other's point of view and actively participating in discussion activities related to the course.
  • Using language that is appropriate to the context of the individual, group or workplace.
  • Presenting in front of a range of audiences including academics, students and industry personnel.
  • Establishing rapport with clients from differing socio-cultural environments in the delivery of engineering projects and responding appropriately to clients, supervisors and other professionals.
  • Using appropriate facial expressions: eye contact, being mindful of space, time boundaries, a range of body movements and gestures.
  • Recognising and interpreting non-verbal cues of others and responding appropriately during activities related to the course, as well as in the engineering practice environment.
  • Competently and appropriately constructing written assessment work in a logical, coherent manner, and with correct grammar and punctuation to the required academic standards.
  • Expressing complex and detailed information and knowledge into a logical and legible report, in a timely manner that meets professional standards and clearly communicates the intended message.
  • Accurately conveying and documenting information in a written form that meets legal and engineering requirements.
  • Accessing a computer for your studies, and possessing basic computer knowledge and skills to engage in the on-line learning environment that may include completing relevant on-line assessments and participating in on-line forums or responding to emails.
  • Regularly accessing the Internet for research, and email for communication with peers and lecturers.
  • Being adept and proficient in the use of discipline specific computer systems and be able to analyse, manipulate and display scientific information.
Cognitive Abilities (Knowledge and Cognitive Skills, Literacy and Numeracy)

Examples are:

  • Conceptualising and using appropriate knowledge in response to academic assessment items.
  • Applying theoretical knowledge, research evidence, policies and procedures in engineering practice.
  • Discerning the wide variety of socio-economic environments that engineering practice takes place in, and provide effective professional solutions to stakeholders.
  • Competently reading, writing and accurately interpreting information to convey language effectively in engineering projects and services.
  • Producing accurate, concise and clear engineering documentation which meets legal requirements.
  • Retrieving correct information from appropriates sources, processing it and converting it into simpler terms if required.
  • Demonstrating competency in applying appropriate mathematical knowledge and skills to make calculations that represent an engineering system.
  • Demonstrating effective use of numeracy skills to make accurate interpretations of engineering system response data.
  • Applying numeracy skills to interpret and solve problems in a range of engineering projects and services.
Sensory Abilities (Visual, Auditory, Tactile)

Examples are:

  • Accurately using instruments for measurements.
  • Observing and detecting subtle changes in responses to engineering systems using instrumentation.
  • Having sufficient auditory ability to be capable of hearing warnings when on site.
  • Interacting effectively with stakeholders including clients, members of the community, tradespeople and other members of the engineering team.
  • Climbing a ladder or steep stairs, walking along scaffolding and traversing a construction site.
Relational Skills

Examples are:

  • Patience - is valuable when it comes to dealing with picky or difficult clients, complex long-term projects or colleagues who are slow and hard to keep on task.
  • Trustworthiness - an invaluable asset to employers, who not only feel comfortable with the individual’s honesty and ethical values, but believe they will do what they say when they say they will do it.
  • Reliability - is an important relational skill in every profession, whether it relates to showing up for work on time, performing duties as assigned, or meeting crucial deadlines.
  • Empathy - being able to consistently look at and understand the perspective of others is a relational skill that’s highly valued in the customer service arena.
  • Influence - Having the ability to effectively persuade and influence others is a valuable relational workplace skill. An influential employee is typically intuitive and able to read people, which is an asset in many professional venues.
Reflective Skills

Examples are:

  • Read - around the topics you are learning about or want to learn about and develop
  • Ask - others about the way they do things and why
  • Watch - what is going on around you
  • Feel - pay attention to your emotions, what prompts them, and how you deal with negative ones
  • Talk - share your views and experiences with others
  • Think - learn to value time spent thinking about your work
Sustainable Performance

Examples are:

  • Actively participating in activities related to the course and professional experience.
  • Performing with the required physical and mental energy and endurance in performing engineering skills and services during set time frames.
  • Showing persistence when learning a new concept - seeing it as a challenge to be solved rather than an insurmountable obstacle.
Strength and Mobility (Gross Motor Skills and Fine Motor Skills)

Examples are:

  • Conducting repairs to engineering systems.
  • Transporting field equipment during the data collection phase of engineering projects.
  • Traversing uneven ground on construction sites.
  • Manipulating instruments in tests and measurements.
  • Using knobs and dials in equipment used for field data collection.
Interpersonal Engagement

Examples are:

  • Communicating respectfully with a multitude of community, government and industry stakeholders.
  • Creating and sustaining professional relationships.
  • Considering the views of different stakeholders in decision making.
Information and Communication Technology (ICT) Abilities
Examples are:
  • Competently using a desktop operating system such as Microsoft Windows or Mac OS X.
  • Competently using productivity software such as Microsoft Office.
  • Competently using the internet for a range of study and work integrated learning activities.
  • Using associated electronic devices such as (but not limited to) digital scanners, copiers, cameras and video cameras, a tablet computer or a mobile phone for study activities.
  • Completely using video communication software such as Zoom and Skype.
Core Learning Outcomes
Please refer to the Core Structure Learning Outcomes
Civil Learning Outcomes
  • 1. Design and analyse complex structures that comply with Australian Standards
  • 2. Analyse and design geotechnical engineering elements using fundamental concepts including soil classification and properties
  • 3. Analyse and design water resource infrastructure by applying hydraulics and hydrology concepts considering Australian Rainfall and Runoff standards
  • 4. Evaluate traffic data and road safety issues and apply relevant standards to design transportation infrastructure
  • 5. Apply mathematical, science and engineering skills to engineering disciplines
  • 6. Scope, research, plan, manage and successfully complete engineering projects autonomously or in teams
  • 7. Demonstrate professional skills for civil engineering graduates including effective management of risks, ethical practice, and disseminating outcomes through reports, presentations and technical drawings
  • 8. Develop a strategic approach to personal and professional growth
  • 9. Apply civil engineering principles to create innovative solutions aligned with the United Nations Sustainable Development Goals.
  Course Learning Outcomes
Australian Qualifications Framework Descriptors 1 2 3 4 5 6 7 8 9
1. KNOWLEDGE Have coherent and advanced knowledge of the underlying principles and concepts in one or more disciplines and knowledge of research principles and methods
2. SKILLS Have cognitive skills to review, analyse, consolidate and synthesise knowledge to identify and provide solutions to complex problems with intellectual independence
3. SKILLS Have cognitive and technical skills to demonstrate a broad understanding of a body of knowledge and theoretical concepts with advanced understanding in some areas
4. SKILLS Have cognitive skills to exercise critical thinking and judgement in developing new understanding
5. SKILLS Have technical skills to design and use research in a project
6. SKILLS Have communication skills to present a clear and coherent exposition of knowledge and ideas to a variety of audiences
7. APPLICATION OF KNOWLEDGE & SKILLS Demonstrate initiative and judgement in professional practice and/or scholarship
8. APPLICATION OF KNOWLEDGE & SKILLS Be able to adapt knowledge and skills in diverse contexts
9. APPLICATION OF KNOWLEDGE & SKILL Be responsible and accountable for own learning and practice and in collaboration with others within broad parameters
10. APPLICATION OF KNOWLEDGE & SKILL Plan and execute project work and/or a piece of research and scholarship with some independence
APPLICATION OF KNOWLEDGE & SKILLS Display leadership by creating inclusive work environments and work with Aboriginal and Torres Strait Islander people in a culturally respectful manner
Civil with Humanitarian Learning Outcomes
  • 1. Design and analyse complex structures that comply with relevant Australian Standards
  • 2. Analyse and design geotechnical engineering elements using fundamental concepts including soil classification and properties
  • 3. Analyse and design water resource infrastructure by applying hydraulics and hydrology concepts considering Australian Rainfall and Runoff standards
  • 4. Design municipal infrastructure for increased disaster resilience
  • 5. Design transportation infrastructure using traffic data evaluations and relevant Australian standards
  • 6. Conduct all phases of engineering projects both autonomously and in teams
  • 7. Demonstrate the skills of risk management, ethical practice and professional communication at the level expected of a civil engineering graduate
  • 8. Develop a strategic approach to personal and professional growth
  • 9. Apply civil and humanitarian engineering principles to create innovative solutions aligned with the United Nations Sustainable Development Goals.
  Course Learning Outcomes
Australian Qualifications Framework Descriptors 1 2 3 4 5 6 7 8 9
1. KNOWLEDGE Have coherent and advanced knowledge of the underlying principles and concepts in one or more disciplines and knowledge of research principles and methods
2. SKILLS Have cognitive skills to review, analyse, consolidate and synthesise knowledge to identify and provide solutions to complex problems with intellectual independence
3. SKILLS Have cognitive and technical skills to demonstrate a broad understanding of a body of knowledge and theoretical concepts with advanced understanding in some areas
4. SKILLS Have cognitive skills to exercise critical thinking and judgement in developing new understanding
5. SKILLS Have technical skills to design and use research in a project
6. SKILLS Have communication skills to present a clear and coherent exposition of knowledge and ideas to a variety of audiences
7. APPLICATION OF KNOWLEDGE & SKILLS Demonstrate initiative and judgement in professional practice and/or scholarship
8. APPLICATION OF KNOWLEDGE & SKILLS Be able to adapt knowledge and skills in diverse contexts
9. APPLICATION OF KNOWLEDGE & SKILL Be responsible and accountable for own learning and practice and in collaboration with others within broad parameters
10. APPLICATION OF KNOWLEDGE & SKILL Plan and execute project work and/or a piece of research and scholarship with some independence
APPLICATION OF KNOWLEDGE & SKILLS Display leadership by creating inclusive work environments and work with Aboriginal and Torres Strait Islander people in a culturally respectful manner
Electrical Learning Outcomes
  • 1. Analyse and solve complex problems in electrical power systems associated with energy generation, transmission, distribution, system protection, and integration of renewable energy
  • 2. Design and analyse complex industrial electrical machines and drive applications
  • 3. Analyse, design, implement and test instrumentation and control systems using industry-standard software and hardware tools
  • 4. Design, analyse and implement complex circuits, embedded systems and industrial communication networks to provide solutions to industrial applications
  • 5. Apply mathematics, science and engineering skills to engineering disciplines
  • 6. Scope, research, plan, manage and successfully complete engineering projects autonomously or in teams
  • 7. Demonstrate professional skills for electrical engineering graduates including effective management of risks, ethical practice, and disseminating outcomes through reports, presentations and technical drawings
  • 8. Develop a strategic approach to personal and professional growth
  • 9. Apply electrical engineering principles to create innovative solutions aligned with the United Nations Sustainable Development Goals.
  Course Learning Outcomes
Australian Qualifications Framework Descriptors 1 2 3 4 5 6 7 8 9
1. KNOWLEDGE Have coherent and advanced knowledge of the underlying principles and concepts in one or more disciplines and knowledge of research principles and methods
2. SKILLS Have cognitive skills to review, analyse, consolidate and synthesise knowledge to identify and provide solutions to complex problems with intellectual independence
3. SKILLS Have cognitive and technical skills to demonstrate a broad understanding of a body of knowledge and theoretical concepts with advanced understanding in some areas
4. SKILLS Have cognitive skills to exercise critical thinking and judgement in developing new understanding
5. SKILLS Have technical skills to design and use research in a project
6. SKILLS Have communication skills to present a clear and coherent exposition of knowledge and ideas to a variety of audiences
7. APPLICATION OF KNOWLEDGE & SKILLS Demonstrate initiative and judgement in professional practice and/or scholarship
8. APPLICATION OF KNOWLEDGE & SKILLS Be able to adapt knowledge and skills in diverse contexts
9. APPLICATION OF KNOWLEDGE & SKILL Be responsible and accountable for own learning and practice and in collaboration with others within broad parameters
10. APPLICATION OF KNOWLEDGE & SKILL Plan and execute project work and/or a piece of research and scholarship with some independence
APPLICATION OF KNOWLEDGE & SKILLS Display leadership by creating inclusive work environments and work with Aboriginal and Torres Strait Islander people in a culturally respectful manner
Electrical with Data Analytics Learning Outcomes
  • 1. Analyse and solve complex problems in electrical power systems associated with energy generation, transmission, distribution, system protection, and integration of renewable energy
  • 2. Design and analyse complex industrial electrical machines and drive applications
  • 3. Analyse, design, implement and test instrumentation and control systems using industry-standard software and hardware tools
  • 4. Design, analyse and implement complex circuits, embedded systems and industrial communication networks to provide solutions to industrial applications
  • 5. Design and program databases and dashboards for monitoring and analysing electrical systems
  • 6. Scope, research, plan, manage and successfully complete engineering projects autonomously or in teams
  • 7. Demonstrate professional skills for electrical engineering graduates including effective management of risks, ethical practice, and disseminating outcomes through reports, presentations and technical drawings
  • 8. Develop a strategic approach to personal and professional growth
  • 9. Apply electrical engineering principles to create innovative solutions aligned with the United Nations Sustainable Development Goals.
  Course Learning Outcomes
Australian Qualifications Framework Descriptors 1 2 3 4 5 6 7 8 9
1. KNOWLEDGE Have coherent and advanced knowledge of the underlying principles and concepts in one or more disciplines and knowledge of research principles and methods
2. SKILLS Have cognitive skills to review, analyse, consolidate and synthesise knowledge to identify and provide solutions to complex problems with intellectual independence
3. SKILLS Have cognitive and technical skills to demonstrate a broad understanding of a body of knowledge and theoretical concepts with advanced understanding in some areas
4. SKILLS Have cognitive skills to exercise critical thinking and judgement in developing new understanding
5. SKILLS Have technical skills to design and use research in a project
6. SKILLS Have communication skills to present a clear and coherent exposition of knowledge and ideas to a variety of audiences
7. APPLICATION OF KNOWLEDGE & SKILLS Demonstrate initiative and judgement in professional practice and/or scholarship
8. APPLICATION OF KNOWLEDGE & SKILLS Be able to adapt knowledge and skills in diverse contexts
9. APPLICATION OF KNOWLEDGE & SKILL Be responsible and accountable for own learning and practice and in collaboration with others within broad parameters
10. APPLICATION OF KNOWLEDGE & SKILL Plan and execute project work and/or a piece of research and scholarship with some independence
APPLICATION OF KNOWLEDGE & SKILLS Display leadership by creating inclusive work environments and work with Aboriginal and Torres Strait Islander people in a culturally respectful manner
Electrical with Information Processing Learning Outcomes
  • 1. Analyse and solve complex problems in electrical power systems associated with energy generation, transmission, distribution, system protection, and integration of renewable energy
  • 2. Design and analyse complex industrial electrical machines and drive applications
  • 3. Analyse, design, implement and test instrumentation and control systems using industry-standard software and hardware tools
  • 4. Design, analyse and implement complex circuits, embedded systems and industrial communication networks to provide solutions to industrial applications
  • 5. Design and program databases and applications for monitoring and controlling electrical systems
  • 6. Scope, research, plan, manage and successfully complete engineering projects autonomously or in teams
  • 7. Demonstrate professional skills for electrical engineering graduates including effective management of risks, ethical practice, and disseminating outcomes through reports, presentations and technical drawings
  • 8. Develop a strategic approach to personal and professional growth
  • 9. Apply electrical engineering principles to create innovative solutions aligned with the United Nations Sustainable Development Goals.
  Course Learning Outcomes
Australian Qualifications Framework Descriptors 1 2 3 4 5 6 7 8 9
1. KNOWLEDGE Have coherent and advanced knowledge of the underlying principles and concepts in one or more disciplines and knowledge of research principles and methods
2. SKILLS Have cognitive skills to review, analyse, consolidate and synthesise knowledge to identify and provide solutions to complex problems with intellectual independence
3. SKILLS Have cognitive and technical skills to demonstrate a broad understanding of a body of knowledge and theoretical concepts with advanced understanding in some areas
4. SKILLS Have cognitive skills to exercise critical thinking and judgement in developing new understanding
5. SKILLS Have technical skills to design and use research in a project
6. SKILLS Have communication skills to present a clear and coherent exposition of knowledge and ideas to a variety of audiences
7. APPLICATION OF KNOWLEDGE & SKILLS Demonstrate initiative and judgement in professional practice and/or scholarship
8. APPLICATION OF KNOWLEDGE & SKILLS Be able to adapt knowledge and skills in diverse contexts
9. APPLICATION OF KNOWLEDGE & SKILL Be responsible and accountable for own learning and practice and in collaboration with others within broad parameters
10. APPLICATION OF KNOWLEDGE & SKILL Plan and execute project work and/or a piece of research and scholarship with some independence
APPLICATION OF KNOWLEDGE & SKILLS Display leadership by creating inclusive work environments and work with Aboriginal and Torres Strait Islander people in a culturally respectful manner
Mechanical Learning Outcomes
  • 1. Apply mathematics, science and engineering skills to engineering disciplines
  • 2. Design and analyse machine components and systems by applying principles of materials, statics, stress analysis and machine design using relevant design standards and codes
  • 3. Apply dynamic modelling, control and simulation methods to design machine components and systems
  • 4. Design and analyse energy generation and energy conversion systems through the application of thermodynamics and heat transfer principles
  • 5. Design and model fluid machinery by applying fluid mechanics and hydraulics principles
  • 6. Scope, research, plan, manage and successfully complete engineering projects autonomously and as part of teams
  • 7. Demonstrate professional skills for mechanical engineering graduates including effective management of risks, ethical practice, and disseminating outcomes through reports, presentations and technical drawings
  • 8. Develop a strategic approach to personal and professional growth
  • 9. Apply mechanical engineering principles to create innovative solutions aligned with the United Nations Sustainable Development Goals.
  Course Learning Outcomes
Australian Qualifications Framework Descriptors 1 2 3 4 5 6 7 8 9
1. KNOWLEDGE Have coherent and advanced knowledge of the underlying principles and concepts in one or more disciplines and knowledge of research principles and methods
2. SKILLS Have cognitive skills to review, analyse, consolidate and synthesise knowledge to identify and provide solutions to complex problems with intellectual independence
3. SKILLS Have cognitive and technical skills to demonstrate a broad understanding of a body of knowledge and theoretical concepts with advanced understanding in some areas
4. SKILLS Have cognitive skills to exercise critical thinking and judgement in developing new understanding
5. SKILLS Have technical skills to design and use research in a project
6. SKILLS Have communication skills to present a clear and coherent exposition of knowledge and ideas to a variety of audiences
7. APPLICATION OF KNOWLEDGE & SKILLS Demonstrate initiative and judgement in professional practice and/or scholarship
8. APPLICATION OF KNOWLEDGE & SKILLS Be able to adapt knowledge and skills in diverse contexts
9. APPLICATION OF KNOWLEDGE & SKILL Be responsible and accountable for own learning and practice and in collaboration with others within broad parameters
10. APPLICATION OF KNOWLEDGE & SKILL Plan and execute project work and/or a piece of research and scholarship with some independence
APPLICATION OF KNOWLEDGE & SKILLS Display leadership by creating inclusive work environments and work with Aboriginal and Torres Strait Islander people in a culturally respectful manner
Mechatronics Learning Outcomes
  • 1. Solve authentic problems through analyses, design and programming of robotic systems
  • 2. Analyse, Design and build instrumentation and automated control systems to meet desired industrial needs within realistic constraints
  • 3. Analyse complex scenarios and design mechatronics solutions using appropriate industry standard software, hardware and embedded-systems development tools
  • 4. Analyse mechatronics systems including parasitics and uncertainties by applying the principles of mechanical engineering design
  • 5. Apply mathematics, science and engineering skills to engineering disciplines
  • 6. Scope, research, plan, manage and successfully complete engineering projects autonomously or in teams
  • 7. Demonstrate professional skills for mechatronics engineering graduates including effective management of risks, ethical practice, and disseminating outcomes through reports, presentations and technical drawings
  • 8. Develop a strategic approach to personal and professional growth
  • 9. Apply mechatronics engineering principles to create innovative solutions aligned with the United Nations Sustainable Development Goals.
  Course Learning Outcomes
Australian Qualifications Framework Descriptors 1 2 3 4 5 6 7 8 9
1. KNOWLEDGE Have coherent and advanced knowledge of the underlying principles and concepts in one or more disciplines and knowledge of research principles and methods
2. SKILLS Have cognitive skills to review, analyse, consolidate and synthesise knowledge to identify and provide solutions to complex problems with intellectual independence
3. SKILLS Have cognitive and technical skills to demonstrate a broad understanding of a body of knowledge and theoretical concepts with advanced understanding in some areas
4. SKILLS Have cognitive skills to exercise critical thinking and judgement in developing new understanding
5. SKILLS Have technical skills to design and use research in a project
6. SKILLS Have communication skills to present a clear and coherent exposition of knowledge and ideas to a variety of audiences
7. APPLICATION OF KNOWLEDGE & SKILLS Demonstrate initiative and judgement in professional practice and/or scholarship
8. APPLICATION OF KNOWLEDGE & SKILLS Be able to adapt knowledge and skills in diverse contexts
9. APPLICATION OF KNOWLEDGE & SKILL Be responsible and accountable for own learning and practice and in collaboration with others within broad parameters
10. APPLICATION OF KNOWLEDGE & SKILL Plan and execute project work and/or a piece of research and scholarship with some independence
APPLICATION OF KNOWLEDGE & SKILLS Display leadership by creating inclusive work environments and work with Aboriginal and Torres Strait Islander people in a culturally respectful manner
Resource Systems Learning Outcomes
  • 1. Convert a traditional mine site design to an automated mine site design
  • 2. Assess the feasibility of a resource project within the constraints of relevant legislation
  • 3. Analyse and interpret data to make decisions using an evidence-based approach
  • 4. Design effective solutions for complex resource systems problems using industry standards, relevant legislation and appropriate software
  • 5. Design resource systems to improve safety and productivity while engaging stakeholders in a socially sustainable manner
  • 6. Conduct all phases of engineering projects both autonomously and in teams
  • 7. Demonstrate the skills of risk management, ethical practice and professional communication at the level expected of a resource systems engineering graduate
  • 8. Develop a strategic approach to personal and professional growth.
  Course Learning Outcomes
Australian Qualifications Framework Descriptors 1 2 3 4 5 6 7 8
1. KNOWLEDGE Have coherent and advanced knowledge of the underlying principles and concepts in one or more disciplines and knowledge of research principles and methods
2. SKILLS Have cognitive skills to review, analyse, consolidate and synthesise knowledge to identify and provide solutions to complex problems with intellectual independence
3. SKILLS Have cognitive and technical skills to demonstrate a broad understanding of a body of knowledge and theoretical concepts with advanced understanding in some areas
4. SKILLS Have cognitive skills to exercise critical thinking and judgement in developing new understanding
5. SKILLS Have technical skills to design and use research in a project
6. SKILLS Have communication skills to present a clear and coherent exposition of knowledge and ideas to a variety of audiences
7. APPLICATION OF KNOWLEDGE & SKILLS Demonstrate initiative and judgement in professional practice and/or scholarship
8. APPLICATION OF KNOWLEDGE & SKILLS Be able to adapt knowledge and skills in diverse contexts
9. APPLICATION OF KNOWLEDGE & SKILL Be responsible and accountable for own learning and practice and in collaboration with others within broad parameters
10. APPLICATION OF KNOWLEDGE & SKILL Plan and execute project work and/or a piece of research and scholarship with some independence
APPLICATION OF KNOWLEDGE & SKILLS Display leadership by creating inclusive work environments and work with Aboriginal and Torres Strait Islander people in a culturally respectful manner
Course Structure

In order to complete this course, you must:

  1. Complete the core structure
  2. Complete 1 major
Number of units: 11 Total credit points: 84

To complete this course, you must pass all units in the Core Structure and one Major. The More Details tab has a link to the Course Planners Site which list all units for this course. Note that full-time students generally enrol in 24cp per term and part-time students generally enrol in a half-load of 12cp per term.

Course planners for the Civil, Electrical and Mechanical Majors include the MATH11247 Foundation Mathematics unit. You may opt-out of this unit and complete an additional elective instead if you completed the Mathematics Self-Diagnostics Test and achieved satisfactory results. See the More Details tab for how to access the Mathematics Self-Diagnostic Test and for more information on alternate pathways for completing the first-year mathematics units.

Available units
Students must complete the following compulsory units:
ENEG11005 Introduction to Contemporary Engineering
ENEG11007 Engineering Industry Project Investigation
ENEG11008 Materials for Engineers
MATH11218 Applied Mathematics
MATH11219 Applied Calculus

Professional Engineering Practice

You must complete the following Diploma of Professional Practice (Co-op Engineering) units during your course. This Diploma consists of three compulsory units, two compulsory 24-week work placements and one Leadership Elective.

If you are intending to go on placement at the end of your second year of study, you should enrol in ENEP11007 Engineering Employment Preparation in Year 2 Term 2. As ENEP11007 is a prerequisite to ENEP11006 Industry Practice 1, you will not be able to go on placement if you have not completed ENEP11007. The More Details tab includes a link to the Course Planners Site for this course.

If you are taking the Civil with Humanitarian Major, you are required to take ENEP12008 Engineering Leadership unit as your Leadership Elective.

Available units
Students must complete the following compulsory units:
ENEP11007 Engineering Employment Preparation
ENEP11006 Industry Practice 1
ENEP11010 Industry Practice Review
ENEP12007 Engineering Business Fundamentals
ENEP12010 Industry Practice 2
Available units
Students must complete 1 from the following units:
ENEP12008 Engineering Leadership
ENEG13001 Humanitarian Engineering Project
Number of units: 21 Total credit points: 150

Intermediate units

You are required to complete 30cp in Year 2 Term 2 and Year 3 Term 2 for this course. Please contact the Course Advisers for enrolment assistance for these two terms. 

Available units
Students must complete the following compulsory units:
MATH11247 Foundation Mathematics
ENEG11006 Engineering Statics
ENEG11009 Fundamentals of Sustainable Energy
ENEG12007 Creative Engineering
ENEC12008 Geotechnical Engineering
ENEC12009 Engineering Surveying and Spatial Sciences
ENEC12010 Hydraulics and Hydrology
ENEG13002 Engineering Futures
ENEC12011 Transport Systems
ENEC12012 Stress Analysis
MATH12225 Applied Computational Modelling

Advanced Units

ENEC14014, ENEC14016 and ENEC14017 are double credit-point (12cp) units intended to provide an authentic project experience. You may need to rearrange your Course Planner around your work placements. If you are not undertaking the work placements designated in the original Course Planner, please contact the Course Advisers to modify your work planners to suit the work placements.

Available units
Students must complete the following compulsory units:
ENEC13014 Water Supply and Wastewater Technology
ENEC13015 Steel and Timber Design
ENEC13017 Advanced Structural Analysis
ENEC13016 Concrete Technology and Design
ENEC14014 Structural and Geotechnical Design
ENEC14016 Traffic and Transportation Engineering
ENEC14017 Water Resources Engineering

Elective Units

There is one elective unit. If you opt-out of the MATH11247 Foundation Mathematics unit you must complete one additional elective from the 6cp units available. The More Details tab contains a link to the Course Planner Site where all pre-approved electives are listed. Contact the Head of Course if you want to discuss studying a unit not on the pre-approved list.

Undergraduate Thesis

At the end of your course, you will complete an undergraduate thesis over two terms. Your thesis confirms your ability to work as a Professional Engineer. It is strongly recommended to decide your topic based on your career interests. You should organise an Academic Adviser just prior to commencing the thesis planning unit.

Available units
Students must complete the following compulsory units:
ENEG14003 Engineering Honours Project Planning
ENEG14005 Engineering Honours Project Implementation

Civil with Humanitarian Major

Number of units: 21 Total credit points: 150

Intermediate Units

You are required to complete 30cp in Year 2 Term 2 and Year 3 Term 2 for this course. Please contact the Course Advisers for enrolment assistance for these two terms.

Available units
Students must complete the following compulsory units:
MATH11247 Foundation Mathematics
SOCL11059 Introducing Social Change
ENEG11006 Engineering Statics
ENEG12007 Creative Engineering
ENEC12008 Geotechnical Engineering
ENEC12009 Engineering Surveying and Spatial Sciences
ENEC12010 Hydraulics and Hydrology
ENEC12011 Transport Systems
ENEC12012 Stress Analysis
ENEG13002 Engineering Futures
ENEG12008 Appropriate Technology for Humanitarian Projects

Advanced Units

ENEC14014, ENEC14016 and ENEC14017 are double credit-point (12cp) units intended to provide an authentic project experience. You may need to rearrange your Course Planner around your work placements. If you are not undertaking the work placements designated in the original Course Planner, please contact the Course Advisers to modify your work planners to suit the work placements.

Available units
Students must complete the following compulsory units:
ENEC13014 Water Supply and Wastewater Technology
ENEC13015 Steel and Timber Design
ENEC13016 Concrete Technology and Design
ENEG13001 Humanitarian Engineering Project
ENEC14014 Structural and Geotechnical Design
ENEC14016 Traffic and Transportation Engineering
ENEC14017 Water Resources Engineering
ENEC14018 Disaster Resilient Infrastructure

Elective Units

If you opt-out of the MATH11247 Foundation Mathematics unit you must complete one elective from the 6cp units available. The More Details tab contains a link to the Course Planner Site where all pre-approved electives are listed. Contact the Head of Course if you want to discuss studying a unit not on the pre-approved list.

Undergraduate Thesis

At the end of your course, you will complete an undergraduate thesis over two terms. Your thesis confirms your ability to work as a Professional Engineer. It is strongly recommended to decide your topic based on your career interests. You should organise an Academic Adviser just prior to commencing the thesis planning unit.

Available units
Students must complete the following compulsory units:
ENEG14003 Engineering Honours Project Planning
ENEG14005 Engineering Honours Project Implementation
Number of units: 21 Total credit points: 150

Intermediate Units

You are required to complete 30cp in Year 2 Term 2 and Year 3 Term 2 for this course. Please contact the Course Advisers for enrolment assistance for these two terms.

Available units
Students must complete the following compulsory units:
MATH11247 Foundation Mathematics
ENEG11006 Engineering Statics
ENEG11009 Fundamentals of Sustainable Energy
ENEG12007 Creative Engineering
ENEE12014 Electrical Circuit Analysis
ENEE12015 Electrical Power Engineering
ENEE12016 Signals and Systems
ENEX12002 Introductory Electronics
ENEG13002 Engineering Futures
MATH12225 Applied Computational Modelling

Advanced Units

ENEE14005, ENEE14006 and ENEE14007 are double credit-point (12cp) units intended to provide an authentic project experience.

You may need to rearrange your Course Planner around your work placements. If you are not undertaking the work placements designated in the original Course Planner, please contact the Course Advisers to modify your work planners to suit the work placements.

Available units
Students must complete the following compulsory units:
ENEX13002 Power Electronics
ENEE13016 Power System Protection
ENEE13019 Control Systems Analysis and Design
ENEE13021 Power System Analysis and Design