About this course
Discover how automobiles are designed, built and tested. Learn the specialist science and engineering behind the industry, then design and create your own. You'll have the chance to specialise in areas of motor vehicle engineering that interest you, from race cars to vehicle electronics. This degree will prepare you for a career in automotive mechanical engineering.
This course provides a solid foundation in mechanical engineering and you'll learn the core principles of:
- vehicle dynamics
- structural design
- propulsion
- automotive electronics
Then you can specialise in subjects, including composite engineering.
As part of this course you can:
- use our range of engineering facilities and gain practical experience with our design workshops and studios.
- get a solid introduction to relevant subjects such as mathematics and mechanics
- take a work placement to boost your academic performance and career prospects
- showcase your work in our annual Engineering Design Show
- study management modules to explore a variety of career paths
- go on site visits to experience engineering in practice
You can also join our Formula Student team. You'll help design, build and race a car in competitions.
We're a designated university for the Defence Technical Undergraduate Scheme (DTUS).
Year in industry
Enhance your employability by taking this course with a paid industrial placement year.
Apply using:
- Course name: Mechanical Engineering / Automotive Engineering with Industrial Placement Year
- UCAS code: H3H3
You'll spend this extra year at an engineering firm, applying the skills and knowledge you've learned so far.
The fee is 20% of the standard annual tuition fee.
We regularly review our courses to ensure and improve quality. This course may be revised as a result of this. Any revision will be balanced against the requirement that the student should receive the educational service expected. Find out why, when, and how we might make changes.
Our courses are regulated in England by the Office for Students (OfS).
Accreditations
This course is accredited by the Institution of Mechanical Engineers (IMechE) as meeting the academic requirement, in full, for Chartered Engineer registration.
This course is accredited by:
Course locations
This course is based at Highfield and Boldrewood.
Awarding body
This qualification is awarded by the University of Southampton.
Download the Course Description Document
The Course Description Document details your course overview, your course structure and how your course is taught and assessed.
Entry requirements
For Academic year 202526
A-levels
A*AA including mathematics (minimum grade A) and physics (minimum grade A), with a pass in the physics Practical (where it is separately endorsed).
A-levels additional information
A pass in the science Practical is required where it is separately endorsed. Offers typically exclude General Studies and Critical Thinking. Applicants who have not studied mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
A-levels with Extended Project Qualification
If you are taking an EPQ in addition to 3 A levels, you will receive the following offer in addition to the standard A level offer: AAA including mathematics and physics, with a pass in the physics Practical (where it is separately endorsed) plus grade A in the EPQ
A-levels contextual offer
We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
International Baccalaureate Diploma
Pass, with 38 points overall with 19 points required at Higher Level, including 6 at Higher Level in Physics and 6 at Higher Level in Mathematics (Analysis and Approaches) or 7 at Higher Level in Mathematics (Applications and Interpretation)
International Baccalaureate Diploma additional information
Applicants who have not studied the required subjects can apply for the Engineering/Physics/Mathematics Foundation Year
International Baccalaureate contextual offer
We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
International Baccalaureate Career Programme (IBCP) statement
Offers will be made on the individual Diploma Course subject(s) and the career-related study qualification. The CP core will not form part of the offer. Where there is a subject pre-requisite(s), applicants will be required to study the subject(s) at Higher Level in the Diploma course subject and/or take a specified unit in the career-related study qualification. Applicants may also be asked to achieve a specific grade in those elements. Please see the University of Southampton International Baccalaureate Career-Related Programme (IBCP) Statement for further information. Applicants are advised to contact their Faculty Admissions Office for more information.
BTEC
D in the BTEC National Extended Certificate plus grades A*A in A-level mathematics and physics (the A* can be in either subject), with a pass in the physics Practical (where it is separately endorsed).
or
D* in the BTEC National Extended Certificate plus grades AA in A-level mathematics and physics, with a pass in the physics Practical (where it is separately endorsed).
We will consider the BTEC National Diploma if studied alongside A-levels in mathematics and physics.
We will consider the BTEC National Extended Diploma in Engineering if studied alongside A-level mathematics.
RQF BTEC
We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
Additional information
Applicants who have not studied mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
QCF BTEC
D in the BTEC Subsidiary Diploma plus A*A in A-level mathematics and physics (the A* can be in either subject), with a pass in the physics Practical (where it is separately endorsed).
or
D* in the BTEC Subsidiary Diploma plus AA in A-level mathematics and physics, with a pass in the physics Practical (where it is separately endorsed).
We will consider the BTEC Diploma if studied alongside A-levels in mathematics and physics.
We will consider the BTEC Extended Diploma in Engineering if studied alongside A-level mathematics.
We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
Access to HE Diploma
Not accepted for this course. Applicants with an Access to HE Diploma in a relevant subject should apply for the Engineering/Physics/Mathematics Foundation Year
Irish Leaving Certificate
Irish Leaving Certificate (first awarded 2017)
H1 H1 H1 H2 H2 H2 including mathematics, applied mathematics and physics
Irish Leaving Certificate (first awarded 2016)
A1 A1 A1 A2 A2 A2 including mathematics, applied mathematics and physics
Irish certificate additional information
Applicants who have not studied the required subjects can apply for the Engineering/Physics/Mathematics Foundation Year
Scottish Qualification
Offers will be based on exams being taken at the end of S6. Subjects taken and qualifications achieved in S5 will be reviewed. Careful consideration will be given to an individual’s academic achievement, taking in to account the context and circumstances of their pre-university education.
Please see the University of Southampton’s Curriculum for Excellence Scotland Statement (PDF) for further information. Applicants are advised to contact their Faculty Admissions Office for more information.
Cambridge Pre-U
D2, D3, D3 in three Principal subjects including mathematics (minimum grade D3) and physics (minimum grade D3)
Cambridge Pre-U additional information
Cambridge Pre-U's can be used in combination with other qualifications such as A levels to achieve the equivalent of the typical offer, where D2 can be used in lieu of A-level grade A* or grade D3 can be used in lieu of A-level grade A. Applicants who have not studied mathematics and/or physics can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate
A*AA including mathematics (minimum grade A) and physics (minimum grade A), with a pass in the physics Practical (where it is separately endorsed) or A*A from two A levels including mathematics and physics (the A* can be in either subject), with a pass in the physics Practical (where it is separately endorsed) and A from the Advanced Welsh Baccalaureate Skills Challenge Certificate
Welsh Baccalaureate additional information
A pass in the science Practical is required where it is separately endorsed. Offers typically exclude General Studies and Critical Thinking. Applicants who have not studied mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate contextual offer
We are committed to ensuring that all applicants with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise an applicant's potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
T-Level
Not accepted for this course. Applicants with a T level Technical Qualification in a relevant subject can apply for the Engineering/Physics/Mathematics Foundation Year
Other requirements
GCSE requirements
Applicants must hold GCSE English language (or GCSE English) (minimum grade 4/C) and mathematics (minimum grade 4/C)
Find the equivalent international qualifications for our entry requirements.
English language requirements
If English isn't your first language, you'll need to complete an International English Language Testing System (IELTS) to demonstrate your competence in English. You'll need all of the following scores as a minimum:
IELTS score requirements
- overall score
- 6.5
- reading
- 6.0
- writing
- 6.0
- speaking
- 6.0
- listening
- 6.0
We accept other English language tests. Find out which English language tests we accept.
If you don’t meet the English language requirements, you can achieve the level you need by completing a pre-sessional English programme before you start your course.
You might meet our criteria in other ways if you do not have the qualifications we need. Find out more about:
- our Ignite your Journey scheme for students living permanently in the UK (including residential summer school, application support and scholarship)
- skills you might have gained through work or other life experiences (otherwise known as recognition of prior learning)
Find out more about our Admissions Policy.
For Academic year 202425
A-levels
A*AA including mathematics (minimum grade A) and physics (minimum grade A), with a pass in the physics Practical (where it is separately endorsed).
A-levels additional information
A pass in the science Practical is required where it is separately endorsed. Offers typically exclude General Studies and Critical Thinking. Applicants who have not studied mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
A-levels with Extended Project Qualification
If you are taking an EPQ in addition to 3 A levels, you will receive the following offer in addition to the standard A level offer: AAA including mathematics and physics, with a pass in the physics Practical (where it is separately endorsed) plus grade A in the EPQ
A-levels contextual offer
We are committed to ensuring that all applicants with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise an applicant's potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme, as follows: AAA or A*AB including mathematics (minimum grade A) and physics (minimum grade A), with a pass in the physics Practical (where it is separately endorsed).
International Baccalaureate Diploma
Pass, with 38 points overall with 19 points required at Higher Level, including 6 at Higher Level in Physics and 6 at Higher Level in Mathematics (Analysis and Approaches) or 7 at Higher Level in Mathematics (Applications and Interpretation)
International Baccalaureate Diploma additional information
Applicants who have not studied the required subjects can apply for the Engineering/Physics/Mathematics Foundation Year
International Baccalaureate contextual offer
We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
International Baccalaureate Career Programme (IBCP) statement
Offers will be made on the individual Diploma Course subject(s) and the career-related study qualification. The CP core will not form part of the offer. Where there is a subject pre-requisite(s), applicants will be required to study the subject(s) at Higher Level in the Diploma course subject and/or take a specified unit in the career-related study qualification. Applicants may also be asked to achieve a specific grade in those elements. Please see the University of Southampton International Baccalaureate Career-Related Programme (IBCP) Statement for further information. Applicants are advised to contact their Faculty Admissions Office for more information.
BTEC
D in the BTEC National Extended Certificate plus grades A*A in A-level mathematics and physics (the A* can be in either subject), with a pass in the physics Practical (where it is separately endorsed).
or
D* in the BTEC National Extended Certificate plus grades AA in A-level mathematics and physics, with a pass in the physics Practical (where it is separately endorsed).
We will consider the BTEC National Diploma if studied alongside A-levels in mathematics and physics.
We will consider the BTEC National Extended Diploma in Engineering if studied alongside A-level mathematics.
RQF BTEC
We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
Additional information
Applicants who have not studied mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
QCF BTEC
D in the BTEC Subsidiary Diploma plus A*A in A-level mathematics and physics (the A* can be in either subject), with a pass in the physics Practical (where it is separately endorsed).
or
D* in the BTEC Subsidiary Diploma plus AA in A-level mathematics and physics, with a pass in the physics Practical (where it is separately endorsed).
We will consider the BTEC Diploma if studied alongside A-levels in mathematics and physics.
We will consider the BTEC Extended Diploma in Engineering if studied alongside A-level mathematics.
We are committed to ensuring that all learners with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise a learner’s potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
Access to HE Diploma
Not accepted for this course. Applicants with an Access to HE Diploma in a relevant subject should apply for the Engineering/Physics/Mathematics Foundation Year
Irish Leaving Certificate
Irish Leaving Certificate (first awarded 2017)
H1 H1 H1 H2 H2 H2 including mathematics, applied mathematics and physics
Irish Leaving Certificate (first awarded 2016)
A1 A1 A1 A2 A2 A2 including mathematics, applied mathematics and physics
Irish certificate additional information
Applicants who have not studied the required subjects can apply for the Engineering/Physics/Mathematics Foundation Year
Scottish Qualification
Offers will be based on exams being taken at the end of S6. Subjects taken and qualifications achieved in S5 will be reviewed. Careful consideration will be given to an individual’s academic achievement, taking in to account the context and circumstances of their pre-university education.
Please see the University of Southampton’s Curriculum for Excellence Scotland Statement (PDF) for further information. Applicants are advised to contact their Faculty Admissions Office for more information.
Cambridge Pre-U
D2, D3, D3 in three Principal subjects including mathematics (minimum grade D3) and physics (minimum grade D3)
Cambridge Pre-U additional information
Cambridge Pre-U's can be used in combination with other qualifications such as A levels to achieve the equivalent of the typical offer, where D2 can be used in lieu of A-level grade A* or grade D3 can be used in lieu of A-level grade A. Applicants who have not studied mathematics and/or physics can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate
A*AA including mathematics (minimum grade A) and physics (minimum grade A), with a pass in the physics Practical (where it is separately endorsed) or A*A from two A levels including mathematics and physics (the A* can be in either subject), with a pass in the physics Practical (where it is separately endorsed) and A from the Advanced Welsh Baccalaureate Skills Challenge Certificate
Welsh Baccalaureate additional information
A pass in the science Practical is required where it is separately endorsed. Offers typically exclude General Studies and Critical Thinking. Applicants who have not studied mathematics and/or physics at A-level can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate contextual offer
We are committed to ensuring that all applicants with the potential to succeed, regardless of their background, are encouraged to apply to study with us. The additional information gained through contextual data allows us to recognise an applicant's potential to succeed in the context of their background and experience. Applicants who are highlighted in this way will be made an offer which is lower than the typical offer for that programme.
T-Level
Not accepted for this course. Applicants with a T level Technical Qualification in a relevant subject can apply for the Engineering/Physics/Mathematics Foundation Year
Other requirements
GCSE requirements
Applicants must hold GCSE English language (or GCSE English) (minimum grade 4/C) and mathematics (minimum grade 4/C)
Find the equivalent international qualifications for our entry requirements.
English language requirements
If English isn't your first language, you'll need to complete an International English Language Testing System (IELTS) to demonstrate your competence in English. You'll need all of the following scores as a minimum:
IELTS score requirements
- overall score
- 6.5
- reading
- 6.0
- writing
- 6.0
- speaking
- 6.0
- listening
- 6.0
We accept other English language tests. Find out which English language tests we accept.
If you don’t meet the English language requirements, you can achieve the level you need by completing a pre-sessional English programme before you start your course.
You might meet our criteria in other ways if you do not have the qualifications we need. Find out more about:
- our Ignite your Journey scheme for students living permanently in the UK (including residential summer school, application support and scholarship)
- skills you might have gained through work or other life experiences (otherwise known as recognition of prior learning)
Find out more about our Admissions Policy.
Got a question?
Please contact our enquiries team if you're not sure that you have the right experience or qualifications to get onto this course.
Email: [email protected]
Tel: +44(0)23 8059 5000
Course structure
Modules in the first 2 years explore the fundamentals of mechanical engineering. You’ll gain the skills to apply your theoretical understanding to a wide range of real design problems.
In years 3 and 4, you'll extend your knowledge and skills by taking part in both individual and group projects. You'll take specialist modules in automotive systems and engineering.
Year 1 overview
You'll take part in our award-winning induction programme and gain practical experience. Teams of new students work together to design and create. For example, you could take apart and put back together a 4 stroke engine.
The first year provides a background in engineering science, emphasising the mechanical engineering aspects. This includes a workshop training course.
Core modules cover topics such as:
- thermofluids
- materials
- solid mechanics
- electrical and electronics systems
You'll develop your design and programming skills, preparing you to design, build and test engineering systems, components and mechanisms.
Year 2 overview
You'll explore the main mechanical engineering subjects with tailored modules. This includes topics such as:
- materials and structures
- drives and machines
- vibration
You'll also take part in a challenging design project, such as designing an autonomous robot or quadcopter.
You can apply to spend a semester abroad at the end of the year. We have several partner institutions that teach modules in English.
Year 3 overview
You'll undertake an individual project that usually takes the form of a design or research exercise.
You'll specialise in automotive engineering and study topics including:
- manufacturing and materials
- automotive power train and chassis systems
- heat transfer and applications
- automotive mechatronics
You'll also choose from a range of optional modules to focus or broaden your knowledge.
Year 4 overview
You'll take part in a group design project, these are often linked to current research activities or topics that have practical relevance to industry. You'll apply your conceptual engineering and scientific knowledge to an engineering design problem.
As a team, you'll develop your ideas through detailed design, experimentation, computer modelling and manufacture.
You’ll have the option to study advanced topics, including:
- tribological engineering
- vibration engineering
- photovoltaics, fuel cells and batteries
Want more detail? See all the modules in the course.
Modules
The modules outlined provide examples of what you can expect to learn on this degree course based on recent academic teaching. As a research-led University, we undertake a continuous review of our course to ensure quality enhancement and to manage our resources. The precise modules available to you in future years may vary depending on staff availability and research interests, new topics of study, timetabling and student demand. Find out why, when and how we might make changes.
For entry in academic year 2024 to 2025
Year 1 modules
You must study the following modules in year 1:
An Introduction to Engineering Design
Engineers design physical products, systems and processes. They think big with vision, research, analyse, create, refine and deliver solutions. Engineering is a design discipline that is broad, creative, logical and holistic, while also focused and ex...
Electrical and Electronics Systems
It is difficult to imagine what the world would be like without electricity: homes without electric light, without television or radio, without motors to drive the washing machine, the refrigerator and the vacuum cleaner; offices without computers, word p...
Mathematics for Engineering and the Environment
This course lays the mathematical foundation for all engineering degrees. Its structure allows students with different levels of previous knowledge to work at their own pace. Pre-requisite for MATH2048 One of the pre-requisites for MATH3081 and MATH...
Mechanical Systems Analysis
This module builds upon the technical content of the other first year modules and develops skills needed for the professional application of Mechanical Engineering. The ability to solve new challenges through innovation and through application of scientif...
Mechanics, Structures and Materials
This module covers the fundamentals of mechanics, statics, dynamics and materials. Providing a firm basis for all subsequent modules in these areas in later Parts and a further career in engineering. This module consists of four parts, Statics-1, Statics...
ThermoFluids
Core Thermodynamics and Fluid Mechanics for all Engineering Themes. Students should be aware that this module requires pre requisites of Mathematics
Year 2 modules
You must study the following modules in year 2:
Electronics and Control
Modern mechanical and acoustic systems contain numerous electronic and control components. For example, an electric vehicle may have speed, traction and active noise control systems. Practicing Mechanical and Acoustical Engineers therefore require a worki...
Fluid Mechanics
This module covers a wide range of topics of fluid mechanics in order to offer basic knowledge and foundations applicable to various mechanical and acoustical engineering problems. This module introduces fundamental principles of conservation (mass, momen...
Materials and Structures
This second year module continues to develop the links between structures and materials, building on the fundamentals established in the first year course on mechanics, structures and materials. The relationship between composition, microstructure and pro...
Mathematics for Engineering and the Environment Part II
The module aims to teach mathematical methods relevant for engineering. The first part is about differential equations and how solve them, from ordinary differential equations to partial differential equations. The second part is about either vector calcu...
Mechanics, Machines and Vibration
This module will help the students to understand the fundamental concepts in Kinematics and Dynamics of multi-body systems. It provides an understanding of the application of simple mathematical models to vibration problems in engineering using different...
Systems Design and Computing
This module follows on from FEEG1201 Introduction to Engineering Design where students are introduced to design processes supported by computing methods. In FEEG2001 students address the design of a system consisting of a number of interacting sub-systems...
Thermodynamics
Enables students to analyse and design advanced power, propulsion, heating and cooling systems using thermodynamic principles.
Year 3 modules
You must study the following modules in year 3:
Automotive Chassis and Powertrain
This module will first be offered in 2021/22. This module introduces students to the design of safe and eco-friendly vehicles for road transportation in the twenty-first century. Different aspects of design and operation of modern automobile systems wi...
Automotive Mechatronics
This module will first be offered in the 2021/22 academic year. This module provides knowledge and understanding of electronics systems of modern road vehicles. Students will become familiar with electro-mechanical and electronic components and systems...
Engineering Design with Management
This module will introduce you to the practice of mechanical engineering design as applied to one of a number of contrasting applications. It will also enable you to understand key management topics that are relevant to engineering practice, specifically ...
Finite Element Analysis in Solid Mechanics
Many real-world engineering structures are too complex for their behaviour to be understood using an ‘exact’ analytical or theoretical method alone. Therefore, in practice we often use approximate numerical or simulation-based tools for structural analysi...
Heat Transfer and Applications
This module gives a comprehensive coverage of the classical heat transfer syllables, including steady and transient heat conduction, convection and radiation. While the underlying mathematics are properly elaborated, their conceptual significance and phys...
Individual Project
The Individual Project is a learning experience that enables you to carry out research and bring together many of the concepts that you have learnt over the first two years of the course as well as the knowledge and skills learnt during part III. You w...
Manufacturing and Materials
This module manufacturing and materials is intended to develop a deeper understanding of the relationship between design, manufacturing processing and materials properties. This module discusses various manufacturing methods including casting, forming, we...
Year 4 modules
You must study the following modules in year 4:
Advanced Electrical Systems
To provide an introduction to power system analysis and power electronics, and an in-depth coverage of electrical machine operation and design in the context of applications from the fields of renewable energy, marine propulsion and electric vehicles.
Automotive Propulsion
Motorised transport has transformed many aspects of human life over the past 120 years. Today’s automotive engineers, however, face the unresolved challenge of continuing that transformation in a sustainable manner. Therefore this module develops the stud...
Group Design Project
This group project enables you to apply your conceptual engineering and science knowledge to an engineering design problem. The ideas are developed through detailed design, experimentation, computer modelling and/or manufacture. You will also consider and...
Materials, Manufacturing and Supply Chain Management
This module will first be offered in the 2022/23 academic year. This module provides a case study-led approach to topics relevant to contemporary manufacturing and supply chain management processes. The course will apply knowledge of engineering materi...
You must also choose from the following modules in year 4:
Applications of CFD
The basic concept of Computational Fluid Dynamics and numerical procedures (FVM/FDM) are introduced. The major focus is practical applications, including geometry and grid generation, using solvers and turbulence models in CFD packages, and interpretation...
Applications of Renewable Energy, Storage and Nuclear Energy
This module covers applications of renewable energy, storage and nuclear power. The module is split equally across the three aspects of renewable energy, storage and nuclear power.
Control and Instrumentation
This module covers topics in classical and modern control analysis and design with a focus on linear time invariant systems. Fundamental design and analysis in the time and frequency domain are reviewed and developed. The properties of discrete-time syste...
Intelligent Mobile Robotics
This module teaches the theory and practice of robotic perception and reasoning needed for mobile autonomous vehicles to operate in dynamic, unstructured environments across land, sea and air. You will learn probabilistic methods so that robots can self-l...
Materials for Transport Applications
This module considers metallic alloys with special reference to applications in transport applications. The main materials considered are aluminium, titanium and nickel based alloys, and steel. Also metal based composites, and high temperature materials s...
Principles of Photovoltaics, Fuel Cells and Batteries
This module covers the aspects of design and operation of modern fuels cells and photovoltaic systems. It discusses the fundamentals, structure, materials and operation of these systems. Students attending this module are expected to have understood th...
Tribology for Future Mobility
Tribological interactions are ubiquitous and have profound impact across all areas of engineering and everyday life. This module places emphasis on the future application of tribological engineering to address the contact mechanics, friction, wear, lubri...
Vibration Engineering Practice
Vibration and shock of engineered structures occur due to dynamic loads arising during operation, e.g. in transportation vehicles, motors/generators and buildings. Analytical and numerical prediction tools are required during virtual prototyping to desig...
Learning and assessment
The learning activities for this course include the following:
- lectures
- classes and tutorials
- coursework
- individual and group projects
- independent learning (studying on your own)
Course time
How you'll spend your course time:
Year 1
Study time
Your scheduled learning, teaching and independent study for year 1:
How we'll assess you
- coursework, laboratory reports and essays
- design and problem-solving exercises
- individual and group projects
- oral presentations
- written exams
Your assessment breakdown
Year 1:
Year 2
Study time
Your scheduled learning, teaching and independent study for year 2:
How we'll assess you
- coursework, laboratory reports and essays
- design and problem-solving exercises
- individual and group projects
- oral presentations
- written exams
Your assessment breakdown
Year 2:
Academic support
You’ll be supported by a personal academic tutor and have access to a senior tutor.
Course leader
John Walker is the course leader.
Careers
Our mechanical engineering courses are fully accredited by the Institution of Mechanical Engineers, and offer a route to chartered status.
We're also a designated university for the Defence Technical Undergraduate Scheme (DTUS).
Our collaboration with Lloyd's Register at our Boldrewood Innovation Campus allows our students to gain industry experience through projects and placements.
As a mechanical engineer with an automotive specialism, your skills and knowledge will be in demand in many industries. You could be involved in testing vehicle components or incorporating the latest emissions guidelines into new designs.
Recent mechanical engineering graduates have gone on to work at organisations including:
- Aston Martin Lagonda
- Babcock
- Dyson
- ExxonMobil
- Rolls-Royce
- Siemens
- Formula 1 teams
Roles you'll be suited for include:
- automotive engineer
- mechanical engineer
- CAD technician
- control and instrumentation engineer
- maintenance engineer
- nuclear engineer
You'll develop transferable skills that are highly sought after in careers outside engineering. These include:
- problem-solving
- teamwork
- communication
- IT
Careers services at Southampton
We are a top 20 UK university for employability (QS Graduate Employability Rankings 2022). Our Careers, Employability and Student Enterprise team will support you. This support includes:
- work experience schemes
- CV and interview skills and workshops
- networking events
- careers fairs attended by top employers
- a wealth of volunteering opportunities
- study abroad and summer school opportunities
We have a vibrant entrepreneurship culture and our dedicated start-up supporter, Futureworlds, is open to every student.
Work in industry
You can take an Industrial Placement Year as part of this course.
This is an opportunity to apply what you have learned so far on your course, try out a potential career, and develop new skills and experience that will help you stand out to future employers.
Fees, costs and funding
Tuition fees
Fees for a year's study:
- UK students pay £9,250.
- EU and international students pay £29,400.
The Government has recently announced changes to UK tuition fees from September 2025 onwards. We will update our website to reflect this shortly.
What your fees pay for
Your tuition fees pay for the full cost of tuition and standard exams.
Find out how to:
Accommodation and living costs, such as travel and food, are not included in your tuition fees. There may also be extra costs for retake and professional exams.
Explore:
Bursaries, scholarships and other funding
If you're a UK or EU student and your household income is under £25,000 a year, you may be able to get a University of Southampton bursary to help with your living costs. Find out about bursaries and other funding we offer at Southampton.
If you're a care leaver or estranged from your parents, you may be able to get a specific bursary.
Get in touch for advice about student money matters.
Scholarships and grants
You may be able to get a scholarship or grant to help fund your studies.
We award scholarships and grants for travel, academic excellence, or to students from under-represented backgrounds.
Support during your course
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We will assess your application on the strength of your:
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We'll aim to process your application within 2 to 6 weeks, but this will depend on when it is submitted. Applications submitted in January, particularly near to the UCAS equal consideration deadline, might take substantially longer to be processed due to the high volume received at that time.
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Email: [email protected]
Tel: +44(0)23 8059 5000
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Mechanical Engineering / Automotive Engineering (MEng) is a course in the Mechanical engineering subject area. Here are some other courses within this subject area:
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- A missing link between continental shelves and the deep sea: Have we underestimated the importance of land-detached canyons?
- A study of rolling contact fatigue in electric vehicles (EVs)
- Acoustic monitoring of forest exploitation to establish community perspectives of sustainable hunting
- Acoustic sensing and characterisation of soil organic matter
- Advancing intersectional geographies of diaspora-led development in times of multiple crises
- Aero engine fan wake turbulence – Simulation and wind tunnel experiments
- Against Climate Change (DACC): improving the estimates of forest fire smoke emissions
- All-in-one Mars in-situ resource utilisation (ISRU) system and life-supporting using non-thermal plasma
- An electromagnetic study of the continent-ocean transition southwest of the UK
- An investigation of the relationship between health, home and law in the context of poor and precarious housing, and complex and advanced illness
- Antibiotic resistance genes in chalk streams
- Being autistic in care: Understanding differences in care experiences including breakdowns in placements for autistic and non-autistic children
- Biogeochemical cycling in the critical coastal zone: Developing novel methods to make reliable measurements of geochemical fluxes in permeable sediments
- Bloom and bust: seasonal cycles of phytoplankton and carbon flux
- British Black Lives Matter: The emergence of a modern civil rights movement
- Building physics for low carbon comfort using artificial intelligence
- Building-resolved large-eddy simulations of wind and dispersion over a city scale urban area
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- Carbon storage in reactive rock systems: determining the coupling of geo-chemo-mechanical processes in reactive transport
- Cascading hazards from the largest volcanic eruption in over a century: What happened when Hunga Tonga-Hunga Ha’apai erupted in January 2022?
- Characterisation of cast austenitic stainless steels using ultrasonic backscatter and artificial intelligence
- Climate Change effects on the developmental physiology of the small-spotted catshark
- Climate at the time of the Human settlement of the Eastern Pacific
- Collaborative privacy in data marketplaces
- Compatibility of climate and biodiversity targets under future land use change
- Cost of living in modern and fossil animals
- Creative clusters in rural, coastal and post-industrial towns
- Deep oceanic convection: the outsized role of small-scale processes
- Defect categories and their realisation in supersymmetric gauge theory
- Defining the Marine Fisheries-Energy-Environment Nexus: Learning from shocks to enhance natural resource resilience
- Design and fabrication of next generation optical fibres
- Developing a practical application of unmanned aerial vehicle technologies for conservation research and monitoring of endangered wildlife
- Development and evolution of animal biomineral skeletons
- Development of all-in-one in-situ resource utilisation system for crewed Mars exploration missions
- Ecological role of offshore artificial structures
- Effect of embankment and subgrade weathering on railway track performance
- Efficient ‘whole-life’ anchoring systems for offshore floating renewables
- Electrochemical sensing of the sea surface microlayer
- Engagement with nature among children from minority ethnic backgrounds
- Enhancing UAV manoeuvres and control using distributed sensor arrays
- Ensuring the Safety and Security of Autonomous Cyber-Physical Systems
- Environmental and genetic determinants of Brassica crop damage by the agricultural pest Diamondback moth
- Estimating marine mammal abundance and distribution from passive acoustic and biotelemetry data
- Evolution of symbiosis in a warmer world
- Examining evolutionary loss of calcification in coccolithophores
- Explainable AI (XAI) for health
- Explaining process, pattern and dynamics of marine predator hotspots in the Southern Ocean
- Exploring dynamics of natural capital in coastal barrier systems
- Exploring the mechanisms of microplastics incorporation and their influence on the functioning of coral holobionts
- Exploring the potential electrical activity of gut for healthcare and wellbeing
- Exploring the trans-local nature of cultural scene
- Facilitating forest restoration sustainability of tropical swidden agriculture
- Faulting, fluids and geohazards within subduction zone forearcs
- Faulting, magmatism and fluid flow during volcanic rifting in East Africa
- Fingerprinting environmental releases from nuclear facilities
- Flexible hybrid thermoelectric materials for wearable energy harvesting
- Floating hydrokinetic power converter
- Glacial sedimentology associated subglacial hydrology
- Green and sustainable Internet of Things
- How do antimicrobial peptides alter T cell cytokine production?
- How do calcifying marine organisms grow? Determining the role of non-classical precipitation processes in biogenic marine calcite formation
- How do neutrophils alter T cell metabolism?
- How well can we predict future changes in biodiversity using machine learning?
- Hydrant dynamics for acoustic leak detection in water pipes
- If ‘Black Lives Matter’, do ‘Asian Lives Matter’ too? Impact trajectories of organisation activism on wellbeing of ethnic minority communities
- Illuminating luciferin bioluminescence in dinoflagellates
- Imaging quantum materials with an XFEL
- Impact of neuromodulating drugs on gut microbiome homeostasis
- Impact of pharmaceuticals in the marine environment in a changing world
- Improving subsea navigation using environment observations for long term autonomy
- Information theoretic methods for sensor management
- Installation effect on the noise of small high speed fans
- Integrated earth observation mapping change land sea
- Interconnections of past greenhouse climates
- Investigating IgG cell depletion mechanisms
- Is ocean mixing upside down? How mixing processes drive upwelling in a deep-ocean basin
- Landing gear aerodynamics and aeroacoustics
- Lightweight gas storage: real-world strategies for the hydrogen economy
- Machine learning for multi-robot perception
- Machine learning for multi-robot perception
- Marine ecosystem responses to past climate change and its oceanographic impacts
- Mechanical effects in the surf zone - in situ electrochemical sensing
- Microfluidic cell isolation systems for sepsis
- Migrant entrepreneurship, gender and generation: context and family dynamics in small town Britain
- Miniaturisation in fishes: evolutionary and ecological perspectives
- Modelling high-power fibre laser and amplifier stability
- Modelling soil dewatering and recharge for cost-effective and climate resilient infrastructure
- Modelling the evolution of adaptive responses to climate change across spatial landscapes
- Nanomaterials sensors for biomedicine and/or the environment
- New high-resolution observations of ocean surface current and winds from innovative airborne and satellite measurements
- New perspectives on ocean photosynthesis
- Novel methods of detecting carbon cycling pathways in lakes and their impact on ecosystem change
- Novel technologies for cyber-physical security
- Novel transparent conducting films with unusual optoelectronic properties
- Novel wavelength fibre lasers for industrial applications
- Ocean circulation and the Southern Ocean carbon sink
- Ocean influence on recent climate extremes
- Ocean methane sensing using novel surface plasmon resonance technology
- Ocean physics and ecology: can robots disentangle the mix?
- Ocean-based Carbon Dioxide Removal: Assessing the utility of coastal enhanced weathering
- Offshore renewable energy (ORE) foundations on rock seabeds: advancing design through analogue testing and modelling
- Optical fibre sensing for acoustic leak detection in buried pipelines
- Optimal energy transfer in nonlinear systems
- Optimal energy transfer in nonlinear systems
- Optimizing machine learning for embedded systems
- Oxidation of fossil organic matter as a source of atmospheric CO2
- Partnership dissolution and re-formation in later life among individuals from minority ethnic communities in the UK
- Personalized multimodal human-robot interactions
- Preventing disease by enhancing the cleaning power of domestic water taps using sound
- Quantifying riparian vegetation dynamics and flow interactions for Nature Based Solutions using novel environmental sensing techniques
- Quantifying the response and sensitivity of tropical forest carbon sinks to various drivers
- Quantifying variability in phytoplankton electron requirements for carbon fixation
- Resilient and sustainable steel-framed building structures
- Resolving Antarctic meltwater events in Southern Ocean marine sediments and exploring their significance using climate models
- Robust acoustic leak detection in water pipes using contact sound guides
- Silicon synapses for artificial intelligence hardware
- Smart photon delivery via reconfigurable optical fibres
- The Gulf Stream control of the North Atlantic carbon sink
- The Mayflower Studentship: a prestigious fully funded PhD studentship in bioscience
- The calming effect of group living in social fishes
- The duration of ridge flank hydrothermal exchange and its role in global biogeochemical cycles
- The evolution of symmetry in echinoderms
- The impact of early life stress on neuronal enhancer function
- The oceanic fingerprints on changing monsoons over South and Southeast Asia
- The role of iron in nitrogen fixation and photosynthesis in changing polar oceans
- The role of singlet oxygen signaling in plant responses to heat and drought stress
- Time variability on turbulent mixing of heat around melting ice in the West Antarctic
- Triggers and Feedbacks of Climate Tipping Points
- Uncovering the drivers of non-alcoholic fatty liver disease progression using patient derived organoids
- Understanding recent land-use change in Snowdonia to plan a sustainable future for uplands: integrating palaeoecology and conservation practice
- Understanding the role of cell motility in resource acquisition by marine phytoplankton
- Understanding the structure and engagement of personal networks that support older people with complex care needs in marginalised communities and their ability to adapt to increasingly ‘digitalised’ health and social care
- Unpicking the Anthropocene in the Hawaiian Archipelago
- Unraveling oceanic multi-element cycles using single cell ionomics
- Unravelling southwest Indian Ocean biological productivity and physics: a machine learning approach
- Using acoustics to monitor how small cracks develop into bursts in pipelines
- Using machine learning to improve predictions of ocean carbon storage by marine life
- Vulnerability of low-lying coastal transportation networks to natural hazards
- Wideband fibre optical parametric amplifiers for Space Division Multiplexing technology
- X-ray imaging and property characterisation of porous materials
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