Flexible Double Degree – Engineering or Advanced Computing

Length 5 years full-time
Minimum 240 Units

Admission requirements

Prerequisites Adjustment factors availability

Academic plan AACOM / BBIOT
CRICOS code 079094C
UAC code 135010

Academic contact

If you want to find out what drives (and how to work for) companies like Google, Microsoft, Apple or Facebook, you are looking at the right degree.

This is a unique, interdisciplinary program that will prepare you to be a future leader of the information and communications technology revolution.

You will not only learn advanced computing techniques and have the opportunity to complete a unique major, but also develop exceptional professional skills in areas of entrepreneurship and management.

While some of our students are flying unmanned aerial vehicles 15,000 kilometres away, others are busy writing algorithms to mine through Petabytes of data. If mastering challenging projects is your thing, the ANU Bachelor of Advanced Computing can launch you into a spectacular career.

Algal biofuels, drought resistant crops and bionic eyes may sound like things of the distant future, but these are just some of the projects our biotechnologists are working on today.

Biotechnology is a fast moving field where scientists use living organisms and their products, to solve real world problems facing modern society. This exciting field has broad applications in medicine, biology, agriculture, manufacturing, renewable energy and engineering.

You will learn the foundations of biology, including the basic principles of molecular and cellular biology, biotechnology, microbiology, societal and ethical issues in biotechnology and intellectual property. Elective courses available within science allow you to tailor the program to your specific interests such as medical, plant/agricultural or chemical biotechnology.

An ANU Bachelor of Biotechnology gives you the knowledge to develop the fuel sources, foods and medical treatments of the future, while teaching you to think ethically about how they will change our society.

This program is not available for Semester 2 commencement.

Career Options

ANU provides you with more choice for your entrance score by offering the new Flexible Double Degree program.

The ANU Flexible Double Degree lets you build skills for your chosen career without forfeiting your passion. It's your choice to build a double degree partnership that suits your head and your heart.http://students.anu.edu.au/applications/

Employment Opportunities

The best computing professionals often have knowledge or a wider field than computing alone. BAC graduates will be ideally positioned to shape their chosen sector of the computing industry now and into the future. They will acquire the skills and knowledge to become leaders in the ICT industry.

Opportunities exist in high tech industries, software start-ups computing research and developement as well as specialist computing organisations. Examples include, software developers, data mining specialists for insurance, banking and health sectors, human-computer interction specialists for software services industries, embedded systems developers for defence, and automotive industries.

Learning Outcomes

Upon successful completion of this program Science graduates will be able to:

understand and evaluate the significance of biotechnological discoveries in educational and professional contexts;
apply a range of technological skills and laboratory techniques to addressing specific problems in the field of biological research;
use a range of analytical techniques for the interpretation of biological data to address specific hypotheses;
convey and relate professional and disciplinary information and ideas to diverse audiences in effective and appropriate ways;
function in public and professional situations as an interpreter of biotechnological information in the public domain;
exercise personal, professional and social responsibility as a global citizen.

Further Information

The computing industry has grown very rapidly in the last 40 years, with various specialized areas requiring advanced computational techniques emerging. The pervasiveness of computers and computer-enabled devices is rapidly becoming established in modern society. Humans are interacting with computers in ever more profound and sophisticated ways. Allied with this, computers are having to act more intelligently in many different contexts. As the scale and complexity of these computer systems increases, so too do challenges in their engineering. As the amount of data increases exponentially, new challenges in the mining and warehousing of information emerge. In all areas of computing, increasingly sophisticated algorithms underpin all of the resulting technologies. The resulting hardware and software systems in these areas are complex; hence a systems engineering perspective on their design and construction is valuable.

In these areas of computing, another emerging trend is linkages with other disciplines. Valuable perspectives on artificial intelligence are emerging from the study of natural intelligence and biological systems. Psychology is a central element in human-computer interaction. The explosion in the volume and utility of information from bioinformatics is a key driver of large-scale data systems. An engineering approach, with emphasis on both hardware and software, is needed for the design of embedded computing technology. In all cases, reliable and systematic software development remains as a key element.

The Bachelor of Advanced Computing graduate will posses technical knowledge of programming, With these as a foundation, their technical knowledge will have been honed by the study of a selection of advanced computing topics. Professional and practical skills in software development will be gained through a series of courses in software analysis, design and construction, capped off with a group software project, With professional skills developed in the areas of entrepreneurship and management, the graduate will be in a position to apply their in-depth technical knowledge to become innovators in industry.

The best computing professionals are informed by knowledge of a wider field than computing alone. Graduates fulfilling a Major in an area of advanced computing and a cognate interdisciplinary area will be ideally positioned to shape the respective sector of the computing industry as it evolves over the near future. This will also imbue a capacity for lifelong learning by exposure to a broader range of perspectives and of ways of studying.

The degree also offers a research pathway for graduates wishing to pursue careers with a high emphasis on research.

Admission Requirements

ATAR:: 90
QLD Band:: 6
International Baccalaureate:: 34

Pathways

There are a range of pathways available to students for entry into Bachelor of Advanced Computing (Honours):

-Academy of Interactive Entertainment (AIE): A Diploma from AIE might be a pathway into Bachelor of Advanced Computing (Honours) for eligible students and may also provide advance standing into the program.

-International agreements/pathways: College of Engineering and Computer Science has a range of articulation agreements with institutions around the world. Students completing the appropriate qualification in these institutions may be approved for entry and credit exemptions towards Bachelor of Advanced Computing (Honours).

- Maths Bridging course: ANU College offers a Maths Bridging course for students who do not meet pre-requisite for Maths for entry into Bachelor of Advanced Computing (Honours). Successful completion of the Maths Bridging course meets the Maths pre-requisite for entry into this program (other entry requirements still apply).

Prerequisites

ACT: Mathematical Methods major.

NSW: Mathematics.

ACT major in Chemistry or NSW HSC Chemistry or equivalent. A bridging course is available in February through the Department of Chemistry.

Adjustment Factors

The National Access Scheme 2014

ANU offers bonus points for nationally strategic senior secondary subjects, and in recognition of difficult circumstances that students face in their studies.

Bonus points are applied to all applicants with an ATAR at or above 70. Points are awarded in accordance with the approved schedule, and no more than 10 points (maximum 5 academic points and maximum 5 equity points) will be awarded.

Bonus points do not apply to programs with an ATAR cutoff of 98 or higher.

Bonus Points are only awarded to domestic applicants applying for admission through UAC who have not previously attempted tertiary study.

How to apply

Academic Bonus Points: senior secondary students do not need to apply for ANU academic bonus points. They are automatically added in accordance with the schedule.

Educational Access Scheme: senior secondary students do not need to apply if their school is part of the Priority School Funding Program or Country Areas Program. All other applicants should refer to www.uac.edu.au/undergraduate/eas for more information.

Bachelor of Advanced Computing (Honours) - Commonwealth Supported Place (CSP)

Bachelor of Biotechnology - Commonwealth Supported Place (CSP)

For more information see: http://www.anu.edu.au/students/program-administration/costs-fees

Annual indicative fee for international students: $33,168.00

Scholarships

ANU offers a wide range of scholarships to students to assist with the cost of their studies.

Eligibility to apply for ANU scholarships varies depending on the specifics of the scholarship and can be categorised by the type of student you are. Specific scholarship application process information is included in the relevant scholarship listing.

For further information see the Scholarships website.

Program Requirements

This double degree requires the completion of 240 units.

The Bachelor of Advanced Computing (Honours) flexible double degree component requires completion of 144 units, of which:

A maximum of 48 units may come from completion of 1000-level courses

The 144 units must include:

78 units from completion of compulsory courses from the following list:

COMP2100 Software Construction

COMP2130 Software Design and Analysis

COMP2300 Introduction to Computer Systems

COMP2310 Concurrent and Distributed Systems

COMP2600 Formal Methods in Software Engineering

COMP3100 Software Project (12 units)

COMP3120 Managing Software Development

COMP3530 Systems Engineering for Software Engineers

COMP3600 Algorithms

COMP3630 Theory of Computation

ENGN1211 Discovering Engineering

MGMT3027 Entrepreneurship and Innovation