• Length 5 years full-time
  • Minimum 240 Units
Admission requirements
Prerequisites Adjustment factors availability
  • Academic plan AACRD / BBIOT
  • CRICOS code 079094C
  • UAC code 135010
Bachelor of Advanced Computing (Research and Development) (Honours) / Bachelor of Biotechnology

Join us on an exciting journey tailored for students who are passionate about pushing the boundaries of computing technology. The Bachelor of Advanced Computing (Research and Development) (Honours) program is designed to immerse you in a dynamic learning environment where you'll not only master advanced computing concepts but also engage deeply in hands-on research and development projects. From day one, you'll dive into a blend of challenging advanced coursework that covers everything from foundational principles to cutting-edge algorithms and software engineering techniques. Classes are interactive and designed to cultivate your critical thinking and problem-solving abilities, essential skills for tackling complex real-world challenges.


What sets the Bachelor of Advanced Computing (Research and Development) (Honours) program apart is its emphasis on research. You'll have the opportunity to work closely with renowned faculty members on groundbreaking research projects. This hands-on experience isn't just about learning theory—it's about applying what you've learned to solve real problems and contribute to advancements in computing. Within your degree program, you have the flexibility to learn and explore the range of computing offerings, and you can choose to complete a Computing Major or Specialisation if you want to study an area in more depth. Beyond the classroom, the program encourages interdisciplinary exploration. You'll have the flexibility to explore connections between computing and other fields like mathematics, biology, creative arts and social sciences. This interdisciplinary approach enriches your understanding and equips you with a broader perspective and adaptable skills that are highly sought after in today's tech-driven world.


As a Bachelor of Advanced Computing (Research and Development) (Honours) student, you'll graduate with a robust skill set and a portfolio of real-world projects that showcase your expertise. Whether your goal is to develop innovative software solutions, pursue advanced research opportunities, or lead technology initiatives, the ANU Bachelor of Advanced Computing (Research and Development) (Honours) program prepares you to excel in diverse career paths within the vibrant and evolving field of computing.

Place yourself at the forefront of innovation with the ANU Bachelor of Biotechnology.

Biotechnology is about applying new technologies to agriculture, food and medicine production, and environmental problems in the context of research, industry and the applied health sciences.

In this cutting-edge degree, you’ll learn the foundations of biology such as molecular and cellular biology, biotechnology and microbiology, as well as contemporary topics such as societal and ethical issues of biotechnology and intellectual property.

Find out more about biotechnology, the degree structure, the university experience, career opportunities and student stories on our website.

Get the inside story on what it’s like to be an ANU student by visiting our student blog.

This program is not available for Semester 2 commencement.

Career Options

ANU ranks among the world's very finest universities. Our nearly 100,000 alumni include political, business, government, and academic leaders around the world.

We have graduated remarkable people from every part of our continent, our region and all walks of life.

Employment Opportunities

Innovative solutions to many of the problems in society today will come from those working in R&D and are at the forefront of new product design and development as well as being a wealth and change generator. After graduation, students choose to become innovators and leaders in R&D roles in IT or other industries, government, academia, or by creating their own start-ups.


BACR&D students can work across a range of industries in a variety of roles. Examples include:

  • Data Mining Specialist
  • Big Data Analyst
  • Human-Computer Interaction Specialist,
  • Software Developer
  • Embedded systems developer
  • Network Architect
  • Systems Analyst
  • Advanced Software Solutions Engineer
  • Software Architect


Our graduates work in many organisations including IBM, Google, Microsoft, Intel, Atlassian, Price Waterhouse Coopers, Accenture, National Australia Bank, Deloitte, Reserve Bank of Australia and the Australian Signals Directorate.


Students graduating with AACRD have been accepted directly into PhD programs around the world including ANU.

Innovative solutions to many of the problems in society today will come from those working in R&D and are at the forefront of new product design and development as well as being a wealth and change generator. After graduation, students choose to become innovators and leaders in R&D roles in IT or other industries, government, academia, or by creating their own start-ups.


BACR&D students can work across a range of industries in a variety of roles. Examples include:

  • Data Mining Specialist
  • Big Data Analyst
  • Human-Computer Interaction Specialist,
  • Software Developer
  • Embedded systems developer
  • Network Architect
  • Systems Analyst
  • Advanced Software Solutions Engineer
  • Software Architect


Our graduates work in many organisations including IBM, Google, Microsoft, Intel, Atlassian, Price Waterhouse Coopers, Accenture, National Australia Bank, Deloitte, Reserve Bank of Australia and the Australian Signals Directorate.


Students graduating with AACRD have been accepted directly into PhD programs around the world including ANU.

Learning Outcomes

  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. Illustrate an understanding of deep knowledge in at least one area of computer science
  4. Demonstrate a deep understanding of the fundamentals of research methodologies, including defining research problems, evaluating background readings, developing literature reviews, designing experiments, and effectively communicating results to a transdisciplinary audience.
  5. Proficiently apply research methods to the solution of contemporary research problems in computer science.
  1. understand and evaluate the significance of biotechnological discoveries in educational and professional contexts;
  2. apply a range of technological skills and laboratory techniques to addressing specific problems in the field of biological research;
  3. use a range of analytical techniques for the interpretation of biological data to address specific hypotheses;
  4. convey and relate professional and disciplinary information and ideas to diverse audiences in effective and appropriate ways;
  5. demonstrate the application of biotechnology to real life contexts;
  6. exercise personal, professional and social responsibility as a global citizen.

Further Information

The Bachelor of Advanced Computing (Research & Development) is a four-year program that has been specifically designed to provide exceptional students with early experience in undertaking research and or development. The program combines a strong foundation in computer science and mathematics, a specialty advanced computing curricula unique to the ANU, and a project-based, research-intensive course of study, also unique to the ANU. It provides ample scope for the student to pursue research in individual areas of interest, working with researchers of international distinction in the areas of computer science, engineering and mathematics.


Students are required to maintain high grades to remain and complete this program. Students who are unable to maintain these grades may transfer into the Bachelor of Advanced Computing (Honours) degree program.


The BAC(R&D) is not a professionally accredited degree, while the BAC is accredited by the Australian Computer Society (ACS).


Program Transfers

Current students wishing to transfer into the Bachelor of Advanced Computing (Research & Development) are required to achieve at least an 80% average in the university courses they have completed and be deemed suitable by an interview with the program convenor. Generally, students would need to transfer into the program before the end of their second year.


Learn more about the degrees offered at the ANU College of Engineering and Computer Science, read current student profiles to see what campus life is really like, and discover what our graduates have achieved since leaving the College by visiting the College of Engineering, Computing and Cybernetics website.

The Bachelor of Advanced Computing (Research & Development) is a four-year program that has been specifically designed to provide exceptional students with early experience in undertaking research and or development. The program combines a strong foundation in computer science and mathematics, a specialty advanced computing curricula unique to the ANU, and a project-based, research-intensive course of study, also unique to the ANU. It provides ample scope for the student to pursue research in individual areas of interest, working with researchers of international distinction in the areas of computer science, engineering and mathematics.


Students are required to maintain high grades to remain and complete this program. Students who are unable to maintain these grades may transfer into the Bachelor of Advanced Computing (Honours) degree program.


The BAC(R&D) is not a professionally accredited degree, while the BAC is accredited by the Australian Computer Society (ACS).


Program Transfers

Current students wishing to transfer into the Bachelor of Advanced Computing (Research & Development) are required to achieve at least an 80% average in the university courses they have completed and be deemed suitable by an interview with the program convenor. Generally, students would need to transfer into the program before the end of their second year.


Learn more about the degrees offered at the ANU College of Engineering and Computer Science, read current student profiles to see what campus life is really like, and discover what our graduates have achieved since leaving the College by visiting the College of Engineering, Computing and Cybernetics website.

Admission Requirements

ATAR:
98
International Baccalaureate:
42

Pathways

Bachelor of Advanced Computing (Honours) is the pathway for students who meet the Maths pre-requisites but do not have the required score for direct entry into this program.

Eligible students should enrol in the Bachelor of Advanced Computing (Honours) complete the Advanced first-year courses and if they can maintain a High Distinction average in their first year, they may be approved to transfer into the R&D program in their second year.

Prerequisites

ACT: Mathematical Methods (Major)/Further Mathematics (Major)/Specialist Mathematics/Specialist Methods (Major)

NSW: HSC Mathematics Advanced or equivalent.

VIC: Mathematics Methods or equivalent

QLD: Mathematics Methods or equivalent

TAS: Mathematical methods/Mathematics Specialised/Mathematics 1 and II through U Tas/Both Mathematics 1 and II through UTAS/Both Advanced Calculus and Applications 1A and 1B through UTAS

SA / NT: Mathematical Methods or equivalent

WA: Mathematical Methods or equivalent

IB: Mathematics: Applications and Interpretations HL/Mathematics: Analysis and Approaches SL or HL

ACT: Chemistry (Major)

NSW: Chemistry or equivalent

VIC: Chemistry

QLD: Chemistry

TAS: Chemistry

SA / NT: Chemistry

WA: Chemistry

IB: Chemistry SL or HL


  • More information about interstate subject equivalencies can be found here .
  • Students who do not meet the chemistry requirement are advised to seek academic advice by contacting students.cos@anu.edu.au. A Chemistry bridging course is available in February through the ANU Research School of Chemistry - contact rsc.teaching@anu.edu.au for more information.

Adjustment Factors

Adjustment factors are combined with an applicant's secondary education results to determine their Selection Rank. ANU offers adjustment factors based on equity, diversity, and/or performance principles, such as for recognition of difficult circumstances that students face in their studies.

To be eligible for adjustment factors, you must have:

  • achieved a Selection Rank of 70 or more before adjustment factors are applied
  • if you have undertaken higher education, completed less than one year full-time equivalent (1.0 FTE) of a higher education program
  • applied for an eligible ANU bachelor degree program

Please visit the ANU Adjustment Factors website for further information.

Indicative fees

Domestic International

Bachelor of Advanced Computing (Research and Development) (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
$53,700.00

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 (Research and Development) (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

A minimum of 12 units of courses tagged as Transdisciplinary Problem-Solving

The 144 units must include:

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

COMP1130 Programming as Problem Solving (Advanced) (6 units)

COMP1140 Structured Programming (Advanced) (6 units)

COMP1600 Foundations of Computing (6 units)

COMP2100 Software Construction (6 units)

COMP2300 Computer Architecture (6 units)

COMP2550 Computing R&D Methods (6 units)

COMP3600 Algorithms (6 units)

COMP3770 Individual Research Project which must be completed twice, in consecutive semesters (6+6 units)

COMP4550 Computing Research Project which must be completed twice, in consecutive semesters (12+12 units).


18 units from completion of courses from the following list:

MATH1005 Discrete Mathematical Models (6 units)

MATH1013 Mathematics and Applications 1 (6 units)

MATH1014 Mathematics and Applications 2 (6 units)

MATH1115 Advanced Mathematics and Applications 1 (6 units)

MATH1116 Advanced Mathematics and Applications 2 (6 units)

MATH2222 Introduction to Mathematical Thinking: Problem-Solving and Proofs (6 units)

STAT1003 Statistical Techniques (6 units)

STAT1008 Quantitative Research Methods (6 units)

 

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


12 units of Transdisciplinary Problem-Solving tagged courses


12 units from completion of elective courses offered by ANU, which may include courses in the subject area COMP Computer Science


After the first four periods of enrolment students must achieve a minimum 75% Weighted Average Mark in Computing courses. Students who do not achieve a minimum 75% Weighted Average Mark will be transferred to the Bachelor of Advanced Computing (Honours).


To continue into the final year of the program students must have completed 144 units and achieved a minimum 80% Weighted Average Mark calculated from the courses that contribute to the final Honours grade calculation. Students who do not achieve this 80% Weighted Average Mark will be automatically transferred to the Bachelor of Advanced Computing (Honours) degree. 


To graduate with the Bachelor of Advanced Computing (Research and Development) (Honours) students must achieve a minimum 80% final Honours mark. Students who do not achieve a minimum 80% final Honours mark will be transferred to the Bachelor of Advanced Computing (Honours) degree program prior to graduating.


Honours Calculation

COMP4801 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 calculated based on all courses completed (including fails), that are listed in the program requirements, excluding non-COMP-coded electives, giving NCN and WN a nominal mark of zero. 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 APM will then be used to determine the final grade according to the ANU Honours grading scale, found at http://www.anu.edu.au/students/program-administration/assessments-exams/grading-scale.

The Bachelor of Biotechnology double degree component requires completion of 96 units, of which:

A maximum of 36 units may come from completion of 1000-level courses

A minimum of 30 units must come from completion of 3000-level courses from the subject area BIOL- Biology

A minimum of 12 units of courses tagged as Transdisciplinary Problem-Solving
 

The 96 units must consist of:

 

54 units from the completion of the following compulsory courses:

BIOL1003 Evolution, Ecology and Genetics (6 units)

BIOL1004 Molecular and Cell Biology (6 units)

BIOL2161 Genes: Replication and Expression (6 units)

BIOL2162 Molecular Genetic Techniques (6 units)

BIOL3161 Genomics and its Applications (6 units)

CHEM1101 Chemistry 1 (6 units)

CHEM1201 Chemistry 2 (6 units)

CHEM2211 Chemical Biology I (6 units)

CHEM2208 Chemical Biology II (6 units)

 

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

BIOL2001 Introduction to Quantitative Biology (6 units)

BIOL2202 Experimental Design and Analysis in Biology (6 units)

 

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

BIOL3191 Bioethics and Society (6 units)

BIOL3194 Biological Science in the Work Place (6 units)


A minimum of 18 units from completion of courses from the following lists:

BIOL3106 Biosecurity (6 units)

BIOL3125 Plants and Global Climate Change (6 units)

BIOL3177 Advances in Molecular Plant Science (6 units)

BIOL3188 ANUSynBio Challenge Team Project (6 units)

BIOL3203 Advanced Microscopy in Biosciences (6 units)

A maximum of 12 units from completion of research project/topics courses from the following list, in which the project/topic must be in the field of Biotechnology:

BIOL3023 Special Topics in Biology (6 units)

BIOL3208 Biology Research Project (6 units)

BIOL3209 Biology Research Project (12 units)


A maximum of 12 units from completion of courses not previously taken from the following subject areas:

BIOL – Biology

CHEM – Chemistry

MEDN – Medical Science

NEUR – Neuroscience

Specialisations

Bachelor of Advanced Computing (Research and Development) (Honours) Specialisations

Study Options

Year 1 COMP1130 Programming as Problem Solving (Advanced) 6 units MATH1005 Discrete Mathematical Models 6 units MATH1115 Advanced Mathematics and Applications 1 6 units OR MATH1013;
COMP1140 Structured Programming (Advanced) 6 units COMP1600 Foundations of Computing 6 units MATH1116 Advanced Mathematics and Applications 2 6 units OR MATH1014;
Year 2 COMP2100 Software Construction 6 units COMP2550 Computing R&D Methods 6 units COMP2300 Computer Architecture 6 units
COMP2120 Software Engineering 6 units COMP2310 Systems, Networks, and Concurrency 6 units COMP2560
Year 3 COMP2420 Computing Research Specialisation 6 units
COMP3600 Algorithms 6 units Computing Research Specialisation 6 units
Year 4 COMP3770 Computing Research Project (R&D) 6 units Computing Research Specialisation 6 units
COMP3770 Computing Research Project (R&D) 6 units Computing Research Specialisation 6 units
Year 5 COMP4550 Computing Research Project 12 units COMP4550
COMP4550 Computing Research Project 12 units COMP4550

Back to the Bachelor of Advanced Computing (Research and Development) (Honours) page

The Bachelor of Advanced Computing (Research & Development) AACRD can be taken as a part of many double degrees. In a double degree you may not be able to complete a major in a computing discipline depending on your other degree. For help on planning your double degree follow the advice on the College Student Services Website.

Single degree

  • The single degree offers 60 units (ten courses) of electives that can be taken from additional computing courses enabling you to complete a Computing major, minor, or additional specialisation), or a major or minor from another College.

  • There are 12 units of elective courses in the degree that can be used to meet your Transdisciplinary Problem-Solving (TD) requirements with any ANU TD tagged courses (including COMP). By following your degree rules you will meet your TD program requirements.

Double degree

  •  The Double degree allows 12 units of electives to allow you to explore subjects across ANU.
  • There are 12 units of elective courses in the degree that can be used to meet your 12 units 
  • Transdisciplinary Problem-Solving requirements across the Double degree. By following your degree rules you will meet your TD program requirements. · 
  • You can find your double degree with BAC(R&D) from Program and Courses


About this degree

  • Typically you will study 4 courses per semester (total of 24 units) as a full time student giving you a total of 24 courses across your whole degree.
  • The degree comprises compulsory requirements, Computing electives, research and development projects, and University electives.
  • You can choose to complete one, or more, of the AACOM Specialisations, BCOMP majors or HCCC Minor using your computing and University electives. Talk to the College Student Services about how to plan your degree to include any of these options after your first semester.

24-unit Specialisations:

 § Artificial Intelligence 

§ Human-Centred and Creative Computing 

§ Machine Learning § Systems and Architecture 

§ Theoretical Computer Science


48-unit Majors

§ COMS-MAJ Computer systems

§ CSEC-MAJ Cyber Security

§ HCCC-MAJ Human-Centred and Creative Computing

§ INFS-MAJ Information Systems

§ INSY-MAJ Intelligent Systems

Follow the steps here: Declaring majors, minors & specialisations to declare your Specialisation and any majors you wish to take, noting the dates this can be done. You do not need to declare any majors or Specialisations until your second or third year but note that you need to plan to complete the required courses to meet their requirements.

Enrolment Status

While it is possible to enrol in fewer courses per semester, which is called studying part-time, it will take you longer to finish your program and get your degree. If you are an international student, you must always be full-time.

· You cannot study more than four courses (24 units) per semester, eight for the year without permission

Important things to keep in mind when choosing your 1000-level courses

  •  
  • Students doing double degrees with business degrees do STAT1008 in place of STAT1003 and take an additional Computing elective.
  • You may take 1000-level courses later in your program. But remember you can’t count more than ten 1000-level courses (60 units) towards your single degree or six 1000-level courses (36 units) towards your BAC(R&D) half of the double degree.



Study Options

Bachelor of Advanced Computing (Research & Development) (Honours)

Study Options

Year 1 48 units COMP1130 Programming as Problem Solving (Advanced) 6 units MATH1005 Discrete Mathematical Models 6 units MATH1115 Advanced Mathematics and Applications 1 6 units OR MATH1013; University Elective
COMP1140 Structured Programming (Advanced) 6 units COMP1600 Foundations of Computing 6 units MATH1116 Advanced Mathematics and Applications 2 6 units OR MATH1014; University Elective

Bachelor of Advanced Computing (Research & Development) (Honours)

Study Options

Year 1 48 units COMP1130 Programming as Problem Solving (Advanced) 6 units MATH1005 Discrete Mathematical Models 6 units MATH1115 Advanced Mathematics and Applications 1 6 units OR MATH1013; Other Degree course
COMP1140 Structured Programming (Advanced) 6 units COMP1600 Foundations of Computing 6 units MATH1116 Advanced Mathematics and Applications 2 6 units OR MATH1014; Other Degree course

Academic Advice

The Study Options below are a guide, depending on your personal circumstances and interests you may need to move Electives and courses into different semesters.

If you want to talk to someone before enrolling or have your study plan reviewed review the information on Getting Started in your Study Program and then contact the College Student Enquiries team student.css@anu.edu.au

Back to the Bachelor of Biotechnology page

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, from genes through to ecology, while examining important questions about ethics and intellectual property.

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.

Note: Advice on this page is indicative only. Where a number of courses has been identified, it assumes that all of your courses are 6-units. If you take a course worth 12-units please refer to the unit-load in the study requirements in the program orders.

This degree can be taken as a single degree or combined with another degree in a Flexible Double Degree (FDD). When the Bachelor of Biotechnology is combined with another undergraduate degree through a Flexible Double Degree, 48 units of ANU electives units are replaced with the core requirements of the other degree and the total program duration is expanded to 192 units (4 years Full-Time) or 240 units (5 years Full-Time) depending on the duration of the other program.

Single degree

The Bachelor of Biotechnology requires 144 units (24 courses), including:

  • A maximum of 10 x 1000-level courses
  • A minimum of 5 x 3000-level courses from courses listed in the core requirements of the BBIOT
  • 9 x compulsory courses
  • A minimum of 2 transdisciplinary problem-solving (TD) courses
  • 1 x quantitative skills course
  • A maximum of 10 courses from the lists in the BBIOT not previously taken or other ANU electives

    Double degree

    The total number of overall units in a Flexible Double Degree (FDD) depends on the FDD combination eg.

    • 4050: 192 units
    • 4350, 4569, 4750: 240 units

    Of which a minimum of 2 courses must be tagged as transdisciplinary problem-solving. These courses may be taken in either component of the FDD.

     The Bachelor of Biotechnology component of an FDD requires 96 units, including:

    • A maximum of 6 x 1000-level courses
    • A minimum of 5 x 3000-level courses from courses listed in the core requirements of the BBIOT
    • 9 x compulsory courses
    • A minimum of 2 transdisciplinary problem-solving (TD) courses
    • 1 x quantitative skills course
    • A maximum of 2 courses from the lists in the BBIOT not previously taken or other ANU electives

    About this degree

    Transdisciplinary Problem-Solving courses

    In this degree, you will have to complete 12 units of courses flagged as Transdisciplinary Problem-Solving (TD). TD courses can be identified using the Programs and Courses search engine.

    You can satisfy this requirement through a course/s listed in the program or through the ANU electives it all depends on how you structure your degree and your other enrolment choices.

    Enrolment Status

    Duration

    The Bachelor of Biotechnology typically takes three years to complete on a full-time basis. Students will usually take 24-units (four six-unit courses) each semester and there are two semesters each year. One course is typically worth six-units.

    In total, students need to complete 144 units of study towards the Bachelor of Biotechnology. This will be 24 courses if all courses are worth six-units, but may be fewer if one or more courses of 12-units or more are taken.

    • If you combine the Bachelor of Biotechnology with another degree in a Flexible Double Degree, you will need to complete a total of 192 units (32 six-unit courses) or 240 units (40 six-unit courses)  depending on the combination. This will typically take four years for a 192-unit degree or five years for a 240-unit degree .

     

    Domestic students may choose to enrol in fewer than 24-units in any semester or half-year study period. Students studying 18 or more units in a half year (January – June or July – December) are considered full-time. Students studying less than this are considered part-time.

    If you take fewer than 24-units in any half year period, then your degree is likely to take longer than three years to complete.

    International students on a student visa are required to enrol in a full-time study load of 24-units in each half year study period (Summer, Semester 1, Autumn or Winter, Semester 2, Spring) unless they have been approved for Reduced Study Load or program leave.

    Maximum time for completion

    • The maximum period for completion of the single Bachelor of Biotechology degree is ten years from the date of first enrolment in the program. This ten years includes any periods of leave.
    • The maximum period for completion of a flexible double degree is ten years for a 192-unit degree or 11 years for a 240-unit degree from the date of first enrolment in the program. The maximum period includes periods of leave.


    A transfer of credit (status) from previous studies will reduce the total amount of time remaining to complete the balance of your degree. When you are assessed for credit, you will be notified of the new maximum end date for your degree in your credit offer.

    Important things to keep in mind when choosing your 1000-level courses

    There are 4 compulsory 1000 level courses you must take in your first year:

     You may take 1000-level courses later in your program.  But remember you can’t count more than ten 1000-level courses (60 units) towards your single degree or six 1000-level courses (36 units) towards your Biotechnology half of the double degree.

    Electives

    Remember you can choose up to 10 courses from another ANU College at the University if you are undertaking the single Bachelor of Biotechnology program. You can try a range of courses or take a major or minor in a non-biotechnology subject, such as philosophy, history or computing. The choice is yours.

    How do I use my electives?

    Electives are courses that provide freedom for you to select subjects that align to your personal interests and career aspirations in a more individualised way than is possible through general major or degree requirements. An ANU elective is a course that you can select without restriction, beyond the global requirements of your program (e.g. limits on 1000-level courses, etc).

    We also recommend holding some ANU electives in reserve to keep other opportunities open, such as international exchange, internships, and meeting the transdisciplinary requirements of your degree.

    Study Options

    Bachelor of Biotechnology - single degree

    This is a typical study pattern for the first year of a student undertaking a Bachelor of Biotechnology.

    Study Options

    Year 1 48 units CHEM1101 Chemistry 1 6 units BIOL1003 Biology 1: Evolution, Ecology and Genetics 6 units BBIOT or ANU elective course 6 units BBIOT or ANU elective course 6 units
    CHEM1201 Chemistry 2 6 units BIOL1004 Biology 2: Molecular and Cell Biology 6 units BBIOT or ANU elective course 6 units BBIOT or ANU elective course 6 units

    Bachelor of Biotechnology - double degree

    This is a typical study pattern for the first year of a student undertaking a Bachelor of Biotechnology with another three year degree, such as the Bachelor of Arts. Please note that for some double degrees (e.g. with Bachelor of Engineering) you may only be able to take one course in semester 1 for your science degree. In these circumstances it is recommended that in your first year you take CHEM1101, CHEM1201 and BIOL1004. You can then take BIOL1003 in your second year of study.

    Study Options

    Year 1 48 units CHEM1101 Chemistry 1 6 units BIOL1003 Biology 1: Evolution, Ecology and Genetics 6 units Degree B Course 6 units Degree B Course 6 units
    CHEM1201 Chemistry 2 6 units BIOL1004 Biology 2: Molecular and Cell Biology 6 units Degree B Course 6 units Degree B Course 6 units

    Academic Advice

    For further information, you can:

    If you need help on any aspect of university life, our "Need Help" webpage is a good place to start and can link you to services across the University.

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