Motorsport Engineering

BEng (Hons) or MEng

UCAS code: H334 BEng/ H337 MEng

Start dates: September 2025 / September 2026

Full time: BEng: 3 years, or 4 years sandwich; MEng: 4 years or 5 years sandwich

Part time: BEng: up to 8 years; MEng: up to 10 years

Location: Headington

Department(s): School of Engineering, Computing and Mathematics

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Overview

Our motorsport engineering degree will help you become a design engineer for the motorsport industry. And we work with the local and global motorsport industry to shape course content. 

The course combines theory with practical, hands-on experience, to give you a well-rounded introduction to motorsport. Our research facilities are also your learning spaces. You’ll have full access to these, whenever you need them. And with a focus on electric vehicles, you’ll be prepared for the future of work in this profession. 

The course has 2 pathways: BEng and MEng. Whichever you pick, you’ll be on your way to receiving industry accreditation, improving your future job prospects and unlocking opportunities for postgraduate study. At the end of the BEng course, you can choose to study for an extra year to gain the MEng qualification.

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Why Oxford Brookes University?

  • Join a community

    Join Oxford Brookes Racing, Formula Student Team - who’ve been the top UK team and won the design award more times than any other UK university, and develop skills in designing, building and racing vehicles. Watch more about how the OBR car is designed.

  • Paid work placement

    Boost your career prospects by going on a paid industry work placement with top motorsport organisations including F1 teams

  • Hear from experts

    Formula One professionals teach on the course, and pass their knowledge on to you.

  • Brand new facilities

    All Engineering and Motorsport courses are moving from the Wheatley Campus to brand new, custom designed buildings at our main Headington site. These buildings will open in the 2024/25 academic year. You'll benefit from state-of-the-art facilities and equipment including a VR cave and material science labs, composite lab, autodynamics workshop and wind tunnel, as well as social learning spaces, teaching rooms and cafe space.

  • Meet recruiters

    As part of our Industrial Lecture series, you can meet prospective employers and Oxford Brookes alumni to make vital industry connections.

  • Free language courses

    Free language courses are available to full-time undergraduate and postgraduate students on many of our courses, and can be taken as a credit on some courses.

  • Accreditation(s)

    The BEng is accredited by the Institution of Engineering and Technology (IET) for the purposes of partly meeting the academic requirement for registration as a Chartered Engineer. The MEng is accredited by IET for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer. Both pathways are also accredited by The Institution of Mechanical Engineers (IMechE).

    • Engineering Council
    • Institution of Engineering and Technology
    • Institution of Mechanical Engineers

Course details

Course structure

You’ll work with other engineering students in Year 1 to design a Stirling Engine. It’s your responsibility to draw the parts, understand the physics and test the thermodynamics, dynamics, and stress analysis. Then you’ll market and sell your product in a global digital marketplace. You’ll also have the flexibility to switch to another engineering course in time for Year 2. 

In your second year, modules such as Engineering Thermo-Fluids and Mathematics and Modelling will help you sharpen your analytical skills. You’ll work on more group design tasks and use engineering analysis software. 

Before starting Year 3, you can go on a paid work placement. After you come back, you’ll see how you can apply everything you learn here to your third year projects and you’ll have picked up experience that looks impressive on your CV. Students have gone on placements with Formula One teams including Alpine, Mercedes and Williams. 

Students in the engineering workshop

Learning and teaching

Teaching and learning methods include:

  • seminars
  • lectures
  • practical work in the laboratory, at a computer or in a workshop. 

In many of the modules, teaching is based around the use of engineering software.

You'll have access to a broad range of up-to-date facilities, including:

  • computer equipment
  • audio and video media facilities
  • software for Computer Aided Design and analysis.

We also have the following well-equipped engineering laboratories and workshops:

  • Mechanical Engineering Workshop and Projects Lab 
  • Joining Technology Research Centre (JTRC)
  • Stress and Materials Laboratory 
  • Dynamics Laboratory 
  • Fluid Mechanics Laboratory
  • Automotive Laboratory 
  • Thermodynamics Laboratory.

Assessment

All modules taken in your first year have an element of continuous assessment.

Modules taken in your second and final years are assessed largely on the basis of written examinations, although some modules rely solely on coursework.

As part of this course you will be given an opportunity to gain a Monitored Professional Development Scheme (MPDS) accreditation by IMechE through a work placement with one of the University's industry partners. 

Study modules

Teaching for this course takes place face to face and you can expect around 12 hours of contact time per week. In addition to this, you should also anticipate a workload of 1,200 hours per year. Teaching usually takes place Monday to Friday, between 9.00am and 6.00pm.

Contact hours involve activities such as lectures, seminars, practicals, assessments, and academic advising sessions. These hours differ by year of study and typically increase significantly during placements or other types of work-based learning.

Year 1

Compulsory modules

  • Engineering Mathematics and Modelling I (double) (30 credits)

    A solid foundation in mathematics is essential for budding engineers. This module sets the stage by providing the necessary mathematical tools to support the analytical aspects of year one engineering courses. You will delve into fundamental algebraic and trigonometric principles, explore the applications of differential and integral calculus, and develop skills in using related functions. Additionally, you will gain hands-on experience with mathematical models, applying them to real engineering problems using specialized software.

    By the end of this module, you'll gain the ability to tackle defined engineering problems systematically, choose appropriate problem-solving approaches, and apply differential and integral calculus to diverse engineering scenarios. Additionally, you'll become proficient in matrix algebra, essential for solving complex systems of equations, and learn the practical use of trigonometry in solving triangles. 
     

  • Engineering Design and Practice I (double) (30 credits)

    Through a subject-specific engineering product as a case study, you will delve into technical drawing, CAD/CAE, modelling, management, and machining, gaining a holistic understanding of the engineering design process. Additionally, this module introduces you to electrical and electronic circuits, laboratory testing, and experimentation, providing invaluable hands-on experience. You will develop mathematical proficiency to solve complex engineering problems, master the design and analysis of electrical circuits, and critically evaluate system architectures. By honing your technical drawing skills and adhering to international standards, you will effectively communicate engineering designs.
     
    By the end of this module, you will develop a deep understanding of electrical circuits, master the art of technical drawing, and gain proficiency in CAE tools for comprehensive design analysis.

  • Basic Electrical Engineering (15 credits)

    This foundational module is designed to provide you with a comprehensive introduction to the fundamental concepts of electrical engineering. You will cover essential electrical quantities, parameters, and the operation of electronic components and circuits that are crucial for your journey as an engineering student. 

    By completing this module, you will develop crucial skills in problem-solving, circuit design, research, project execution, and effective communication. Moreover, you’ll gain a solid understanding of the general operation and behaviour of electrical circuits, enabling you to predict their outcomes. You'll gain hands-on experience in designing basic electrical and electronic circuits, with a focus on sustainability, legislation, and safety considerations. 
     

  • Introduction to Statics and Dynamics (15 credits)

    This module is designed to provide you with a foundational understanding of the principles crucial for analysing mechanical engineering design in terms of equilibrium and motion. You'll learn essential techniques for analysing a variety of basic mechanical and automotive components, devices, and systems.

    Through this module, you'll develop a comprehensive skill set for analysing engineering components and devices under both static and dynamic loads. You'll become adept at identifying the various forces acting on typical engineering elements, leading to the creation and use of free-body diagrams for solving static and dynamic problems. Additionally, you'll gain the ability to investigate and analyse the kinetics of simple engineering components, devices, and mechanisms, providing a solid foundation for more complex analyses in the field.  

  • Introduction to Materials and Stress Analysis (15 credits)

    This module is designed to provide you with a foundational understanding of the principles crucial for analysing mechanical engineering design in terms of equilibrium and motion. You'll learn essential techniques for analysing a variety of basic mechanical and automotive components, devices, and systems.

    Through this module, you'll develop a comprehensive skill set for analysing engineering components and devices under both static and dynamic loads. You'll become adept at identifying the various forces acting on typical engineering elements, leading to the creation and use of free-body diagrams for solving static and dynamic problems. Additionally, you'll gain the ability to investigate and analyse the kinetics of simple engineering components, devices, and mechanisms, providing a solid foundation for more complex analyses in the field.  

  • Introduction to Thermo Fluids (15 credits)

    This module serves as a comprehensive introduction to the fundamental principles of thermodynamics and fluid mechanics. The insights you gain from this module will be directly applicable to the mechanical engineering sector, providing you with a strong foundation for future studies and practical applications.

    As you progress through this module, you'll develop a deep understanding of the scientific principles that underpin thermo-fluids. Through the application of appropriate mathematical analysis techniques, you'll be able to effectively analyse basic engineering systems involving heat and fluid flow. You'll become familiar with the fundamental features of both external and internal incompressible fluid flow, and you'll be able to recognize various types of thermodynamic processes. This knowledge will empower you to select the appropriate governing equations to evaluate the performance of simple engineering systems. 
     

Year 2

Compulsory modules

  • Design and Practice II (double) (30 credits)

    This module places a strong emphasis on utilising modern computer technology, including computer-aided engineering (CAE) packages, to create solid models, conduct simulation analyses, and ensure designs are fit for purpose. By actively engaging with the integrated design environment and collaborating with peers, you will acquire invaluable skills in engineering design, problem-solving, and effective communication.

    As you progress through this module, you will gain a comprehensive understanding of the engineering design process and its practical application in real-world contexts. You will learn to select and utilise appropriate industrial components, making informed decisions that contribute to the overall success of your designs. Through interdisciplinary collaboration, you will gain valuable experience working with others to produce design prototypes, simulating real-world scenarios encountered in professional engineering practice. 


     

  • Engineering Mathematics and Modelling II (15 credits)

    This module places significant emphasis on the solution of differential equations using both analytical and numerical methods. You will develop the skills to formulate and solve ordinary differential equations, employ advanced techniques of matrix algebra, and utilise numerical techniques to solve various engineering problems. Furthermore, you will learn to effectively describe and analyse engineering systems using the language of mathematics and employ mathematical software to perform numerical computations.
     
    By the end of this module, you will gain a deeper understanding of the role of calculus in engineering applications. Through the study of differential equations and matrix algebra, you will acquire advanced problem-solving techniques that are essential for addressing real-world engineering challenges. 
     

  • Electronics and Control Engineering 1 (15 credits)

    In this module, you'll develop a comprehensive understanding of electronic and electrical systems, their control mechanisms, and their integration with existing processes. The focus is on preparing you to analyse, apply, and predict the performance of these systems, especially in the context of high-level autonomous operations. 

    Upon completing this module, you'll be able to explain the operation and limitations of major control, electrical, and electronic systems. You'll have the skills to analyse complex electronics and control problems, design appropriate tests, and accurately assess outcomes. Leveraging industry-standard modelling and simulation software, you'll be capable of explaining and analysing the behaviour of electronics and control systems. 
     

  • Stress Analysis (15 credits)

    In this module, you'll delve into the intricacies of static stress analysis using closed-form solutions derived from fundamental principles. You'll also explore how this understanding relates to failure criteria and the material properties of the component. Practical application of theories will be facilitated through a hands-on laboratory session, offering a real-world context to the learned concepts.

    Through this module, you'll gain a profound ability to calculate stresses, strains, and deflections in beams undergoing bending and torsion. You'll be adept at determining various stress components like principal, octahedral, hydrostatic, and deviatoric stresses in three-dimensional components. This skill set will enable you to evaluate the strength and deformation suitability of a diverse range of components under static loading conditions. 
     

  • Thermo-Fluids (15 credits)

    In this module, you will gain an introduction to the fundamental principles of environmental engineering. You will explore the interactions between human activities and the environment, focusing on topics such as water and wastewater treatment, air pollution control, solid waste management, and environmental impact assessment. Through theoretical studies and practical exercises, you will learn about the design and operation of environmental engineering systems and the importance of sustainable practices to protect and preserve the environment.

    By engaging with this module, you will develop a comprehensive understanding of environmental engineering principles and their applications. You will gain the necessary knowledge to assess environmental issues and propose sustainable solutions for water, air, and solid waste management.
     

  • Engineering Dynamics (15 credits)

    This module is designed to give you a comprehensive understanding of dynamic mechanical systems. The focus includes mechanical vibration, control systems, and the performance evaluation of single-degree-of-freedom systems, as well as first and second-order systems. Additionally, you'll explore the kinematics of mechanisms, gears, and epicyclic gears. The coursework is enriched with practical laboratory exercises, providing hands-on experience to complement theoretical learning. 

    By the end of this module, you'll be equipped with the knowledge and skills to effectively analyse the dynamic performance of mechanical systems. 

  • Materials Engineering (15 credits)

    This module aims to provide you with a comprehensive understanding of materials used in mechanical engineering, with a focus on selection, design, manufacturing optimization, and environmental impact assessment. You'll delve into the specifics of metals and polymer composite materials, gaining valuable insights into their structure, properties, and manufacturing processes.

    By the end of this module, you'll have the underpinning knowledge and comprehension necessary to make informed decisions about materials selection for engineering applications. You'll explore how the structure and properties of materials are influenced by their manufacturing processes, leading to optimized performance in real-world scenarios. Additionally, you'll gain an understanding of the factors and processes involved in material degradation, enabling you to evaluate and account for these factors in your design work.
     

Year 3 (optional placement year - compulsory for sandwich year students)

Optional modules

Optional placement year

Our work placement programme has been commended by professional bodies as a model of excellence. We have placement opportunities with local, national and international Engineering companies. We provide support and guidance in applying for placements. Placements are highly valued by prospective employers, helps with consolidating your understanding of mechanical engineering and gives you the opportunity to apply your knowledge in an industrial environment. Students usually have to arrange their own accommodation during their placement year and will have to cover their own transport and living costs. Previous students have gained placements with companies such as: Red Bull Racing Mercedes AMG HPP Nitron Racing Systems AP Racing Ltd Sahara Force India F1 X-Trac Ltd Lotus F1 Mercedes AMG Petronas Williams Grand Prix Engineering We have an excellent record of graduates gaining full-time employment with their industrial placement-year company.

Year 4 (or year 3 if no placement)

Compulsory modules

  • Engineering Project (double) (30 credits)

    This module aims to provide you with a platform to delve deeply into a practical engineering issue, fostering a comprehensive understanding of real-world problem-solving. You will undertake a substantial project that goes beyond the scope of your previous coursework, allowing you to solidify your knowledge and hone the skills you've acquired during your studies. 

    Throughout the module, you will be required to meticulously document your project's journey, from its inception to its completion, in a comprehensive report. You'll learn to prepare effective project plans and Gantt charts, crucial tools for organising and executing the project in a systematic manner. Your ability to critically evaluate engineering practices through in-depth analysis of published literature will be nurtured. You'll also learn to apply a diverse range of both innovative and established techniques to address complex engineering problems, showcasing your problem-solving prowess.
     

  • Management Ethics, Energy and Sustainability (double) (30 credits)

    This module is designed to equip you with a comprehensive understanding of the multifaceted challenges that intersect business, society, and sustainability. With a specific focus on the automotive, transport, and general engineering sectors, this module delves into critical topics such as project management, leadership, energy, environmental concerns, sustainable engineering, ethics, and social aspects of employment.

    By the end of this module, you'll possess a holistic perspective on business practices and their impact on the triple bottom line: economic, social, and environmental aspects. You'll learn to craft effective business plans, making compelling arguments that incorporate sustainability principles, echoing the shift towards a circular economy.
     

  • Vehicle Dynamics (15 credits)

    This module is designed to provide you with a comprehensive grasp of both theoretical and practical aspects related to the critical components of vehicle dynamics: tyres, ride, and handling. Through a combination of theory and practical exercises, you will delve into various analyses and design considerations to understand the dynamic behaviour of vehicles.

    By the end of this module, you will develop a critical understanding of the techniques required to analyse and assess the handling and ride qualities of an entire vehicle. Throughout the module, you will gain proficiency in using computer-based tools for vehicle dynamic analysis and design, enabling you to confidently prepare specifications for optimal vehicle performance. Additionally, you will be encouraged to explore and solve new vehicle dynamics problems independently, nurturing your ability to strategize solutions autonomously.
     

  • Powertrain Engineering (15 credits)

    This module will cover the principles of mechanical engineering with the analysis, design, and selection of automotive powertrain systems and components. Through this module, you will delve into the intricate workings of powertrain systems, exploring their design, configuration, and influences, all while considering the thermodynamic and mechanical theories that underpin their suitability for various vehicle applications. Additionally, you will develop a comprehensive understanding of the various processes—chemical, dynamic, thermal, material, and economic—that impact powertrain performance and environmental sustainability.

    On successful completion of this module, you will gain the ability to comprehensively evaluate engine performance using advanced dynamometer techniques. By evaluating these cutting-edge solutions, you will stay at the forefront of the field and be equipped to contribute to the development of innovative, efficient, and environmentally conscious powertrain systems.

  • Vehicle Aerodynamics (15 credits)

    In this module, you’ll dive into the intricate realm of ground vehicle aerodynamics, exploring how design impacts flow characteristics and performance. You’ll gain an understanding of the synergy between physical principles, experimental data, and software tools like Computational Fluid Dynamics (CFD). 

    By the end of this module, you will be able to adeptly assess and communicate the aerodynamic attributes and performance of ground vehicles. Additionally, you’ll skillfully employ experimental and simulation techniques to scrutinise aerodynamic characteristics. Moreover, you’ll interpret and communicate numerical simulation results.
     

  • Motorsport Vehicle Performance (15 credits)

    This module delves into the intricacies of high-performance racing vehicles with an emphasis on advanced concepts. Explore lap-time simulation, data acquisition, and cutting-edge instrumentation, all crucial for achieving peak performance. 

    By the end of this module, you’ll develop your ability to analyse and design racing cars, leveraging software tools like EXCEL and MATLAB. You’ll also craft detailed lap-time simulations utilising specialised modelling techniques. Additionally, you’ll expertly evaluate the significance of diverse design parameters, quantifying their impact on various racing formulas.
     

Year 5 (MEng)

Compulsory modules

  • Group Design Project (double) (40 credits)

    In this module, you’ll collaborate closely with research, industrial, or commercial partners for real-world project experience.

    This module equips you to apply theory to real-world scenarios, solving intricate Mechanical and Automotive Engineering problems. You’ll develop advanced problem-solving skills, employ research methods, and embrace project management techniques. As a team, you’ll tackle complex challenges, critically analyse methods, and present innovative solutions that reflect industry standards and collaboration.

  • Engineering Business Management (20 credits)

    This module is designed to equip you with the essential management skills and knowledge necessary for success in the engineering industry. The focus lies on key areas such as project management, leadership, team building, motivation, and legal considerations. While the automotive and motorsports sectors are emphasised, the knowledge and skills gained are widely applicable across the broader engineering landscape.

    Upon completion of this module, you will possess a comprehensive understanding of management practices vital in engineering contexts. You will develop a systematic comprehension of the prerequisites for crafting a successful business plan within engineering domains. Additionally, you will master the skill of presenting compelling business plans to potential stakeholders. This involves proposing well-reasoned strategies for organizations seeking industry funding.
     

  • Electric Powertrain Systems (20 credits)

    This module focuses on electric drives within automotive powertrains. It provides a comprehensive understanding of both theoretical and practical aspects related to the design and operation of Electric Drives. You’ll delve into control strategies, hardware design, and control implementation in the context of electric powertrains.

    By the end of this module, you will be adept at evaluating design methods and component selection for various Electric Drive systems. You’ll conduct comprehensive thermal analyses of both electrical and mechanical systems, effectively addressing design conflicts and constraints. Also, you’ll critically assess design methodologies and their practical application in automotive Electric Drives.
     

  • Composite Design and Impact Modelling (20 credits)

    This module explores material, component, and structural responses to medium to high impact events in this module. Dive into crashworthiness design, testing, and modelling for motorsport and automotive vehicles, with a focus on using the Finite Element Method (FEM) to predict crash effects. The module establishes the theory behind explicit numerical modelling to assess the validity of numerical results.

    By the end of this module, you'll exhibit a profound and methodical grasp of material behaviour, explicit FEM, and the design, manufacture, and testing of impact-resistant vehicles and structures. Your ability to select, evaluate, and justify manufacturing processes aligned with your design criteria will be evident. Additionally, you'll be able to critically appraise design concepts, handling incomplete or contradictory data with expertise.
     

  • Laptime Simulation and Race Engineering (20 credits)

    This module is designed for postgraduate study and professional application. You’ll delve into the intricacies of race car performance, applying advanced computational and analytical methods to optimise racing outcomes.

    By the end of this module, you will possess a profound understanding of race car performance synthesis. You’ll expertly select and apply suitable computational and analytical techniques for assessing race car performance. Additionally, you’ll create intricate computer simulations of race car lap times, utilising both technical information and wider literature to support your analysis of design parameters' impact on various racing formulas.

Please note: As our courses are reviewed regularly as part of our quality assurance framework, the modules you can choose from may vary from those shown here. The structure of the course may also mean some modules are not available to you.

Careers

This course is your chance to join IMechE Monitored Professional Development Scheme before you finish the course. 

Both BEng and MEng courses lead to professional accreditation. Completing the BEng meets the academic requirements for becoming an Incorporated Engineer, and partly meets the academic requirements for becoming a Chartered Engineer. Completing the MEng fully meets the academic requirements for Chartered Engineer status.

Our graduates go on to have successful careers in the motorsport industry. They work for big names including Ferrari, Williams Advanced Engineering, Tuthill Porsche, plus many Formula One and Formula E teams. 

You’ll also have the option of studying motorsport engineering, or a similar discipline, at a higher level. The BEng can lead to MSc opportunities, and both the MEng and MSc open up PhD routes. 

Entry requirements

Wherever possible we make our conditional offers using the UCAS Tariff. The combination of A-level grades listed here would be just one way of achieving the UCAS Tariff points for this course.

Standard offer

UCAS Tariff Points: 112

A Level: BBC

IB Points: 30

BTEC: DMM

Contextual offer

UCAS Tariff Points: 88

A Level: CCD

IB Points: 27

BTEC: MMM

Further offer details

A levels: tariff points must include A level Grade B in Maths, and Grade B in Physics, Chemistry, Electronics, Engineering or another suitable science.  

BEng contextual offer points must include C in Maths and C in Physics, Chemistry, Electronics, Engineering or another science.  MEng contextual offer points must include B in Maths and C in Physics, Chemistry, Electronics, Engineering or suitable science

IB Diploma: 31 points (BEng) or 32 points (MEng) to include minimum grade 5 in Higher Level Maths and Physics

BEng contextual offer points must include 4 in HL Maths and Physics.  MEng contextual offer points must include 5 in HL Maths and 4 in HL Physics

BTEC: tariff points must include BTEC Extended Diploma in an engineering subject, plus a distinction in the Further Mathematics module.

We welcome applications from candidates with equivalent alternative qualifications, and from mature students

International qualifications and equivalences

Tuition fees

Please see the fees note
Home (UK) full time
£9,250

Home (UK) part time
£1,155 per single module

Home (UK) sandwich (placement)
£1,600

International full time
£16,900

International sandwich (placement)
£1,600

Home (UK) full time
£9,250*

Home (UK) part time
£1,155 per single module*

Home (UK) sandwich (placement)
£1,700

International full time
£17,750

International sandwich (placement)
£1,700

Questions about fees?

Contact Student Finance on:

Tuition fees

2024 / 25
Home (UK) full time
£9,250

Home (UK) part time
£1,155 per single module

Home (UK) sandwich (placement)
£1,600

International full time
£16,900

International sandwich (placement)
£1,600

2025 / 26
Home (UK) full time
£9,250*

Home (UK) part time
£1,155 per single module*

Home (UK) sandwich (placement)
£1,700

International full time
£17,750

International sandwich (placement)
£1,700

Questions about fees?

Contact Student Finance on:

+44 (0)1865 534400

financefees@brookes.ac.uk

* Following the government’s announcement of 4 November 2024, we expect to increase our undergraduate tuition fees for UK students to £9,535 from the start of the 2025/26 academic year. Please visit The Education Hub for more information about the changes. We will confirm our fees for 2025/26 as soon as possible.

Please note, tuition fees for Home students may increase in subsequent years both for new and continuing students in line with an inflationary amount determined by government. Oxford Brookes University intends to maintain its fees for new and returning Home students at the maximum permitted level.

Tuition fees for International students may increase in subsequent years both for new and continuing students. 

The following factors will be taken into account by the University when it is setting the annual fees: inflationary measures such as the retail price indices, projected increases in University costs, changes in the level of funding received from Government sources, admissions statistics and access considerations including the availability of student support. 

How and when to pay

Tuition fee instalments for the semester are due by the Monday of week 1 of each semester. Students are not liable for full fees for that semester if they leave before week 4. If the leaving date is after week 4, full fees for the semester are payable.

  • For information on payment methods please see our Make a Payment page.
  • For information about refunds please visit our Refund policy page

Additional costs

Please be aware that some courses will involve some additional costs that are not covered by your fees. Specific additional costs for this course are detailed below.

Information from Discover Uni

Full-time study

Part-time study

Full-time study

Part-time study

Programme changes:
On rare occasions we may need to make changes to our course programmes after they have been published on the website. For more information, please visit our changes to programmes page.