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

As a degree accredited by the Australian Computer Society you will not only learn advanced computing techniques and have the opportunity to complete a unique specialisation, but also develop exceptional professional skills including communication and teamwork.

While some of our students are developing code which controls unmanned aerial vehicles, others are busy writing algorithms to mine through Peta-bytes of data.  If mastering challenging projects is your thing, the ANU Bachelor of Advanced Computing (Honours) can launch you into a spectacular career.

Are you a maths whiz who wants stimulating work, limitless potential and an ever growing salary? This is the esteemed degree that will make you a thought leader in financial fields. With an ANU Bachelor of Actuarial Studies you will excel your career literally anywhere in the world.

Risk is all around us - in investment markets, on the roads, from our health and the climate. This degree will teach you how to apply your mathematical talent in understanding, measuring and managing the risks.

Graduates will apply mathematical, statistical, financial, economic and other skills to untangle the most complex and difficult problems facing the commercial world.

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.

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, students will be able to:

1.     Define and analyse complex problems, and design, implement and evaluate solutions that demonstrate an understanding of the systems context in which software is developed and operated including economic, social, historical, sustainability and ethical aspects.

2.     Demonstrate an operational and theoretical understanding of the foundations of computer science including programming, algorithms, logic, architectures and data structures

3.     Recognise connections and recurring themes, including abstraction and complexity, across the discipline

4.     Adapt to new environments and technologies, and to innovate

5.     Demonstrate an understanding of deep knowledge in at least one area of computer science

6.     Communicate complex concepts effectively with diverse audiences using a range of modalities

7.     Work effectively within teams in order to achieve a common goal

8.     Demonstrate commitment to professional conduct and development that recognises the social, legal and ethical implications of their work, to work independently, and self- and peer-assess performance.

9.     Demonstrate an understanding of the fundamentals of research methodologies, including defining research problems, background reading and literature review, designing experiments, and effectively communicating results.

10.  Apply research methods to the solution of contemporary research problems in computer science.

• To develop a grounding in financial mathematics and applications, including the time value of money, annuities, bond and loan calculations
• To develop the ability to interpret the accounts and financial statements of companies and financial institutions.
• To develop a grounding in mathematical statistics and regression modeling
• To develop a grounding in stochastic processes, survival models and their application in actuarial contexts
• To develop a grounding in the mathematical techniques used to model and value cashflows dependent on death, survival, illness, retirement, and other contingencies.
• To develop a grounding in the advanced mathematics which has particular relevance to financial work, including risk theory, bayesian statistics, generalized linear modeling, and time series techniques.
• To develop a grounding in the fundamental concepts of micro and macroeconomics.

Professional Accreditation

To meet Part I of the professional requirements of the Actuaries Institute  you must complete eight Core Technical (CT) subjects that correspond with 14 to 15 ANU courses which are accredited by the Institute. An average grade of 60 per cent must be achieved across the ANU courses corresponding with each CT subject in order to be recommended for the Part I exemptions. Further information on the ANU Part I exemption policy can be found here. Part II requirements of the Institute can be met by an additional fourth year of study in the College, usually in the form of an honours year. Interested students should contact the ANU College of Business and Economics. For further information about the Actuaries Institute visit: www.actuaries.asn.au.

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.

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

Admission to all programs is on a competitive basis. Admission to undergraduate degrees is based on meeting the ATAR requirement or an equivalent rank derived from the following qualifications:

• An Australian year 12 qualification or international equivalent; OR
• A completed Associate Diploma, Associate Degree, AQF Diploma, Diploma, AQF Advanced Diploma, Graduate Certificate or international equivalent; OR
• At least one standard full-time year (1.0 FTE) in a single program of degree level study at an Australian higher education institution or international equivalent; OR
• An approved tertiary preparation course unless subsequent study is undertaken.

Click HERE for further information about domestic admission.

More information about ATAR requirements for individual programs can be found HERE.

The National Register of higher education providers is an authoritative source of information that will help you confirm your institution of choice is registered to deliver higher education in Australia.

The Quality Indicators for Learning and Teaching (QILT) website is HERE. Based on surveys done by thousands of students across Australia you can find out about universities that interest you, doing side-by-side comparisons.

The table below is a guide to the entry level required for domestic applicants. Exact entry level will be set at time of offer.

Domestic applicant entry requirements

Queensland Band equivalents are a guide only - selection is made on an ATAR equivalent that is not available to students.

International applicant entry requirements

International applicants may view further information on admissions requirements at Entry Requirements for International Undergraduate Applicants

The University reserves the right to alter or discontinue its programs as required.

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)/Further Mathematics (Major)/Specialist Mathematics/Specialist Methods (Major), NSW: Mathematics or equivalent. More information about interstate subject equivalencies can be found here.

ACT:  Specialist Mathematics (Major/Minor) (160+)/Specialist Methods(Major/Minor) (160+), NSW: Mathematics Extension 1 (Band E3) or equivelant. More information about interstate subject equivalencies can be found here.

Adjustment Factors

ANU offers rank adjustments for a number of adjustment factors, including for high achievement in nationally strategic senior secondary subjects and for recognition of difficult circumstances that students face in their studies. Rank adjustments are applied to Bachelor degree applicants with an ATAR at or above 70. Points are awarded in accordance with the approved schedules, and no more than 15 points (maximum 5 subject/performance-based adjustments, maximum 10 equity-based adjustments and maximum 5 Elite Athlete adjustments) will be awarded. Subject and performance-based adjustments do not apply to programs with a minimum selection rank of 98 or higher. Visit the ANU Adjustment Factors website for further information.

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

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:

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

COMP1600 Foundations of Computing

COMP2100 Software Design Methodologies

COMP2120 Software Engineering

COMP2300 Computer Organisation and Program Execution

COMP2310 Systems, Networks and Concurrency

COMP2420 Introduction to Data Management, Analysis and Security

COMP3600 Algorithms

COMP4450 Advanced Computing Research Methods

MATH1005 Discrete Mathematical Models

6 units from completion of course from the following list:

COMP1100 Programming as Problem Solving

COMP1130 Programming as Problem Solving (Advanced)

6 units from completion of course from the following list:

COMP1110 Structured Programming

COMP1140 Structured Programming (Advanced)

24 units from completion of one of the following specialisations:

Intelligent Systems

Systems and Architecture

Theoretical Computer Science

6 units from completion of further courses from the subject area COMP Computer Science

6 units from completion of further 3000- and 4000-level courses from the subject area COMP Computer Science

Either:

12 units from completion of 3000- or 4000-level courses from the subject area COMP Computer Science

Or:

12 units from completion of courses from the following list:

ENGN3230 Engineering Innovation

VCUG3001 Unravelling Complexity

VCUG3002 Mobilising Research

Either:

6 units from completion of further courses from the subject area COMP Computer Science

Or:

6 units from completion of courses from the following list:

MATH1013 Mathematics and Applications 1

MATH1014 Mathematics and Applications 2

MATH1115 Advanced Mathematics and Applications 1

MATH1116 Advanced Mathematics and Applications 2

MATH2301 Games, Graphs and Machines

ENGN1211 Discovering Engineering

STAT1008 Quantitative Research Methods

STAT1003 Statistical Techniques

Either:

24 units from completion of COMP4550 Advanced Computing Research Project

Or:

12 units from completion of COMP4560 Advanced Computing Project

12 units from completion of further 4000-level courses from the subject area COMP Computer Science

HONS4700 Final Honours Grade will be used to record the Class of Honours and the Mark. The Honours Mark will be a weighted average percentage mark (APM) calculated by first calculating the average mark for 1000,2000, 3000 and 4000 level courses. We denote these averages: A1, A2, A3, and A4 respectively. The averages are computed based on all units counted towards satisfaction of degree requirements, excluding non-COMP electives. Finally these averages are combined using the formula APM = (0.1 X A1) + (0.2 X A2) + (0.3 X A3) + (0.4 X A4).

The Bachelor of Actuarial Studies flexible double degree component requires completion of 96 units, of which:

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

The 96 units must include:

72 units from completion of the following compulsory courses:

BUSN1001 Business Reporting and Analysis

ECON1101 Microeconomics 1

STAT1008 Quantitative Research Methods

STAT2001 Introductory Mathematical Statistics

STAT2005 Introduction to Stochastic Processes

STAT2008 Regression Modelling

STAT2032 Financial Mathematics

STAT3032 Survival Models

STAT3035 Risk Theory

STAT3036 Credibility Theory

STAT3037 Life Contingencies

STAT3038 Actuarial Techniques

6 units from completion of a course from the following list:

ECON1100 Economics 1 (H)

ECON1102 Macroeconomics 1

6 units from completion of a course from the following list:

ECON2102 Macroeconomics 2 (P)

ECON2016 Economics II (H)

ECON2112 Macroeconomics 2 (H)

12 units from the completion of courses on List 1 of the ANU College of Business and Economics.

Students may choose to take two MATH courses instead of MATH1113. The options are MATH1013 / MATH1014 or MATH1115 / MATH1116. MATH1013 / MATH1014 is recommended for students with the bare minimum of mathematical background for the Bachelor of Actuarial Studies or for those not confident in their mathematical ability. MATH1115 / MATH1116 is a higher level of MATH1013 / MATH1014 and is recommended for those who are considering further mathematical study. Should two MATH courses be chosen, the elective course position would need to be used for the additional MATH course.

In the requirements of the Bachelor of Actuarial Studies above it is not possible to gain full exemptions from Actuaries Institute Part I requirements as the required FINM courses are not included. However, by including these FINM courses in the other flexible double degree (if the FINM courses meet the requirements of the other degree), or overloading (i.e., taking more than the standard four courses in some semesters on non-award basis which means you will need to pay full fees for the courses you are overloading) or by using the College of Business and Economics Summer School Program (if available), students may be able to complete their exemptions from Part I. To facilitate either of these options, it is recommended that students undertake FINM1001 Foundations of Finance as their elective course.

If your flexible double degree is within the College of Business and Economics (for example Commerce and Economics), the suggested study plan may show the same course twice. If this is the case, you must only do the course once and replace the other course with a University Wide Elective or CBE List 1 course. Please note that you cannot exceed 8 out of college electives.

The minor in Business and Economics Essentials will not be listed on transcripts for students completing the Bachelor of Actuarial Studies.

For majors and minors offered by the ANU College of Business and Economics, students may count a course towards multiple majors and minors. If a minor is a subset of all stated courses and/or prerequisites for a major, then completion of the major overrides completion of the minor, and only the major is regarded as having been completed. If all courses in a major and/or minor are compulsory courses in the degree, the major and/or minor will not be listed on the transcript.

Majors

Bachelor of Advanced Computing (Honours) Majors

Minors

Bachelor of Advanced Computing (Honours) Minors

Specialisations

Bachelor of Advanced Computing (Honours) Specialisations

Study Options

Honours

Students may proceed to an additional honours year in Actuarial Studies. Entry to the honours year program is subject to an appropriately high average grade (generally distinction level or above) in the 3000-level compulsory subjects described in the course listings and requires the approval of College. Other conditions may also apply. Students who are interested in the honours program should seek further advice from the Convenor of the Actuarial Program in the Research School of Finance, Actuarial Studies and Applied Statistics

Students undertaking honours will be able to meet the Actuaries Institute Part II requirements