About this course
Biomedical engineers design, develop and deliver the health and wellbeing devices of the future. On this 5-year programme you’ll study key aspects of biomedicine, electronics and computer science with a year in industry. This will give you additional experience and the opportunity to relate your skills and knowledge to current industry practice.
With all economies facing an increase in health spending, engineers and computer scientists have an ever-increasing role to play in inventing solutions for healthcare and treatment. Biomedical engineers work across disciplines to bridge this gap.
You’ll explore topics like:
- the creation of diagnostic systems and devices for observing and controlling body functions
- the design and creation of electronic circuits, systems, and computer software
- the use of simulation, design, and verification tools to aid in the creation of systems, and how to report and comment on results
- the specific clinical, safety and ethical implications of biomedical engineering work and routes to commercialization of devices.
This programme includes a year of industrial studies, sometimes known as a placement year, or a year in industry. This is a great way to gain a competitive edge among graduate recruiters by ensuring that you graduate with both experience of contemporary industry operations and connections with potential employers.
You can also tailor your degree to your liking by picking a pathway. These include:
Electronic Systems
You’ll learn to develop engineering solutions to health and healthcare problems, ranging from rehabilitation technologies and implantable sensors to smart signal analysis for wearable healthcare, and rapid testing and diagnostic devices.
You will gain key insight into how to design and develop a wide range of systems, from underlying sensor technology to signal analysis and data interpretation.
Mechatronics for Health
You’ll learn the fundamental science, methods, analysis, and engineering applications to start a career in mechatronic engineering with a focus on medical technology and robotics.
You’ll have the opportunity to design and build intelligent machines and robots as part of your study, which integrate electrical, mechanical and control systems to perform complex tasks.
Digital Health
You'll learn to develop m-health and e-health solutions based on healthcare needs and available technology. You will gain key data science skills that allow you to analyse data, build solutions and communicate results.
As one of the few universities in the UK (United Kingdom) to have a Digital Health research group, you will be taught by academics actively involved in technologies in this area.
Artificial Intelligence
You’ll additionally learn to design and build AI (Artificial Intelligence) programs and systems to solve global healthcare challenges and integrate with Biomedical engineering solutions.
As a highly respected hub for AI research, you'll benefit from a range of specialist modules that few UK universities can match. You’ll also be taught by academics actively involved in the latest advances in AI.
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).
Biomedical Engineering 5 in Five
Learn more about this subject area
“For me, the speciality of the course was a massive winning point. In my second year, I had a design project looking at remote monitoring of physical therapy exercises for stroke rehabilitation. It was a really fun project, with incorporation from different sides of my course, including physical sensors, software design and machine learning.”
Course location
This course is based at Highfield.
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 202425
A-levels
A*AA including mathematics (minimum grade A) and either biology, chemistry or physics (minimum grade A)
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 the required subjects 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 either biology, chemistry or physics, plus grade A in the EPQ
A-levels contextual offer
We are committed to ensuring that all students 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 student’s potential to succeed in the context of their background and experience. Students who are highlighted in this way will be made an offer which is lower than the typical offer for that programme, as follows: AAA including mathematics and either biology, chemistry or physics.
International Baccalaureate Diploma
Pass, with 38 points overall with 19 points required at Higher Level including 6 at Higher Level in Mathematics (Analysis and Approaches) or 7 at Higher Level in Mathematics (Applications and Interpretation), and 6 at Higher Level in either Physics, Chemistry or Biology
International Baccalaureate Diploma additional information
Applicants who have not studied the required subjects at Higher Level 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 from two A-levels including mathematics and either physics, chemistry or biology.
or
D* in the BTEC National Extended Certificate plus grades AA from two A-levels including mathematics and either physics, chemistry or biology.
We will consider the BTEC National Extended Diploma in Engineering if studied alongside A-level mathematics.
We will consider the BTEC National Diploma if studied alongside A-levels in mathematics and either physics, chemistry or biology.
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
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 the required subjects can apply for the Engineering/Physics/Mathematics Foundation Year
QCF BTEC
D in the BTEC Subsidiary Diploma plus grades A*A from two A-levels including mathematics and physics, chemistry or biology.
or
D* in the BTEC Subsidiary Diploma plus grades AA from two A-levels including mathematics and either physics, chemistry or biology.
We will consider the BTEC Extended Diploma in Engineering if studied alongside A-level mathematics.
We will consider the BTEC Diploma if studied alongside A-levels in mathematics and either physics, electronics or further 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 either physics, physics and chemistry, chemistry or biology
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 and either biology, chemistry or physics.
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 the required Principal subjects can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate
A*AA including mathematics (minimum grade A) and either physics, chemistry or biology (minimum grade A) or A*A from two A-levels including mathematics and either physics, chemistry or biology, 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 the required subjects 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
A Distinction* overall, with A* in Core and Distinction in the Occupational Specialism, and grade A in A-level Mathematics.
The following T levels are accepted:
- Healthcare Science
- Science
- Design and Development for Engineering and Manufacturing
- Maintenance, Installation and Repair for Engineering and Manufacturing
The following Occupational Specialisms are required:
- For the T level in Design and Development for Engineering and Manufacturing: either "Electrical and electronic engineering” or "Control and instrumentation engineering".
- For the T level in Maintenance, Installation and Repair for Engineering and Manufacturing: either "Maintenance engineering technologies: Electrical and Electronic" or "Maintenance engineering technologies: Mechatronic" or "Maintenance engineering technologies: Control and Instrumentation" or "Light and Electric Vehicles".
Additional information
".
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.
You might meet our criteria in other ways if you do not have the qualifications we need. Find out more about:
- our Access to Southampton 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 202526
A-levels
A*AA including mathematics (minimum grade A) and either biology, chemistry or physics (minimum grade A)
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 the required subjects 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 either biology, chemistry or physics, 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 Mathematics (Analysis and Approaches) or 7 at Higher Level in Mathematics (Applications and Interpretation), and 6 at Higher Level in either Physics, Chemistry or Biology
International Baccalaureate Diploma additional information
Applicants who have not studied the required subjects at Higher Level 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 from two A-levels including mathematics and either physics, chemistry or biology.
or
D* in the BTEC National Extended Certificate plus grades AA from two A-levels including mathematics and either physics, chemistry or biology.
We will consider the BTEC National Extended Diploma in Engineering if studied alongside A-level mathematics.
We will consider the BTEC National Diploma if studied alongside A-levels in mathematics and either physics, chemistry or biology.
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
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 the required subjects can apply for the Engineering/Physics/Mathematics Foundation Year
QCF BTEC
D in the BTEC Subsidiary Diploma plus grades A*A from two A-levels including mathematics and physics, chemistry or biology.
or
D* in the BTEC Subsidiary Diploma plus grades AA from two A-levels including mathematics and either physics, chemistry or biology.
We will consider the BTEC Extended Diploma in Engineering if studied alongside A-level mathematics.
We will consider the BTEC Diploma if studied alongside A-levels in mathematics and either physics, electronics or further 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 either physics, physics and chemistry, chemistry or biology
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 and either biology, chemistry or physics.
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 the required Principal subjects can apply for the Engineering/Physics/Mathematics Foundation Year
Welsh Baccalaureate
A*AA including mathematics (minimum grade A) and either physics, chemistry or biology (minimum grade A) or A*A from two A-levels including mathematics and either physics, chemistry or biology, 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 the required subjects 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
A Distinction* overall, with A* in Core and Distinction in the Occupational Specialism, and grade A in A-level Mathematics.
The following T levels are accepted:
- Healthcare Science
- Science
- Design and Development for Engineering and Manufacturing
- Maintenance, Installation and Repair for Engineering and Manufacturing
The following Occupational Specialisms are required:
- For the T level in Design and Development for Engineering and Manufacturing: either "Electrical and electronic engineering” or "Control and instrumentation engineering".
- For the T level in Maintenance, Installation and Repair for Engineering and Manufacturing: either "Maintenance engineering technologies: Electrical and Electronic" or "Maintenance engineering technologies: Mechatronic" or "Maintenance engineering technologies: Control and Instrumentation" or "Light and Electric Vehicles".
Additional information
".
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.
You might meet our criteria in other ways if you do not have the qualifications we need. Find out more about:
- our Access to Southampton 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: enquiries@southampton.ac.uk
Tel: +44(0)23 8059 5000
Course structure
This is a five-year, full-time course (including the industrial placement). The topics you explore will vary depending on which pathway you choose.
In the early stages you'll take core and compulsory modules in electronics and programming together with a thorough grounding in mathematics. You will also take modules covering the fundamentals of life science.
As the programme progresses, you’ll undertake an individual project, a year of industrial studies and finally a group design project.
Year 1 overview
The first year will introduce you to the fundamentals of biomedical engineering and your chosen pathway. You’ll cover topics like programming, digital systems and microprocessors, maths, electronic systems and sensors, biomedical engineering design and key elements of life science.
Year 2 overview
You'll continue to build upon your knowledge of key topics, with further modules in electronics, programming and fundamentals of cell biology and physiology.
You’ll also apply your knowledge to design a health and wellness monitoring platform within a healthcare technology design project.
Year 3 overview
You’ll undertake an individual project. You’ll also choose from a range of optional modules.
Year 4 overview
You’ll undertake your industrial studies with one of our partner companies.
This will allow you to apply the knowledge and skills that you’ve developed during the early years of your degree. You’ll gain vital experience towards becoming a professional biomedical engineer after graduation.
The year in industry is assessed by academics and industry experts. During the year you will continue to have the support of the University, with regular contact and reduced fees while you are on placement. You will also receive a salary from the company for that year.
Year 5 overview
You'll work on a group design project. This is compulsory, taken over the full academic year and may include students from other engineering disciplines.
You’ll also have the freedom to tailor the degree to your liking by choosing from a wide variety of optional modules.
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.
Year 1 modules
You must study the following modules in year 1:
Biomedical Engineering Design
This module teaches the applications of biomedical signal analysis and control systems for biomedicine. The module emphasises developing an understanding through lab-based system design exercises by applying theoretical knowledge taught in the module. The...
Biomedical Engineering Mathematics
This course is designed to develop fundamental mathematical skills which Biomedical engineers need in order to tackle a wide variety of engineering and design problems. There is a particular focus on developing an understanding of mathematics as a toolbox...
Digital Systems
To introduce digital system design, the principles of programmable logic devices, the implementation of combinational and sequential circuits, and the principles of hardware design using industry standard hardware design tools.
ELEC Part One Laboratory Programme
This module is the lab programme for all first-year students enrolled on an ELEC degree programme. It aims to give students the opportunity to apply the theory that they learn in their other modules, and to provide them with transferrable, subject-based a...
Introduction to Biomedical Engineering
This module will introduce students to the disciplines of biomedical engineering (BME). This module is organized into 4 blocks. The first block provides an overview of the key challenges in health and wellness. Students will also study 3 furthe...
Programming
To introduce the student to the concepts of programming using the C programming language, with an emphasis on programming for embedded systems.
Sensor Interfaces
This module will introduce you to the mathematical techniques needed to describe and analyse linear and simple non-linear electronic circuits. The module explains the properties of ideal circuit elements and the tools & techniques required to analyse a wi...
You must also choose from the following modules in year 1:
Applied Biomechanical Mathematics
This course explores the use of mathematics as a toolbox for engineers to calculate, model, visualise and design physical systems. The focus is on solving physical problems via equations, both analytically and numerically using computation, along with dev...
From Biological Molecules to Biomedical Data
This module is designed for Biomedical Engineering students on the Artificial Intelligence and Digital Health pathways. In this module, you will learn about the different types of macromolecules found in cells, with a particular emphasis on DNA and pro...
From Biological Molecules to Electromagnetism
This module is designed for Biomedical Engineering students on the Electronics and Mechatronics for Health pathways. In this module, you will learn about the different types of macromolecules found in cells, with a particular emphasis on DNA and protei...
Programming II
Year 2 modules
You must study the following modules in year 2:
Control and Systems Engineering
This module guides students through the development of knowledge and understanding of linear continuous-time systems. It then introduces the basic analysis and design tools for electronic system control and provides opportunities to develop practical desi...
Signal Processing
To develop knowledge of the fundamentals of Signals and Systems. To introduce the concepts of signal transforms, system convolution and linear operations. To introduce the concepts of randomness in signals and systems. To provide a comprehensive found...
You must also choose from the following modules in year 2:
Algorithms and data
Artificial Intelligence
Biomechatronics
The module aims to provide an integrated understanding of the representation and analysis of dynamical systems (electrical and mechanical), their solution and practical implementation in diagnosis and health monitoring for biomedical engineering problems ...
Design
Conventional laboratory experiments are useful mainly to assist understanding or analysis. Because they are of necessity stereotyped, they are of limited usefulness when a circuit or system must be designed to meet a given specification. The majority of e...
Digital Health Principles
Fundamentals of Cell Biology and Biomaterials
This module develops an understanding of the foundational principles of cell biology, delving into the cell structure, functions, and molecular processes, and diversity. Additionally, the course will introduce biomaterials, focusing on their types, proper...
Fundamentals of Physiology and Anatomy
The module will provide students with an understanding of the basic human anatomy (study of the structure) and physiology (study of the function). The students will learn the coupling of structure with function through a series of lectures and labs. The ...
Programming and Modelling Mechatronic Systems
This module introduces some advanced programming, simulation and design modelling frameworks and tools. Teaching activities are a combination of taught sessions, expanded self-study supported by the Professional Skills Hub and practical hands-on sessions ...
Semiconductor Devices and Sensors
This module will introduce the concepts of semiconductor materials, devices, and sensors. You will develop a detailed understanding of the design, operating mechanisms and fabrication technology of semiconductor electronic/power electronic devices, optoel...
Software Design and Development Project
Statistical Modelling I
Simple linear regression is developed for one explanatory variable using the principle of least squares. The extension to two explanatory variables raises the issue of whether both variables are needed for a well-fitting model, or whether one is sufficien...
Year 3 modules
You must study the following modules in year 3:
Advanced Databases
This module builds on the first year Data Management module to give students a deeper and broader view of the issues involved in database management systems, some of the most complex software in common use.
Biosensors and Diagnostics
A biosensor is a device that translates a biomolecular binding event into an electrical or optical signal that can be quantified and recorded. Biosensors come in many different formats, from complicated nanofabricated mechanical transducers to simple but...
Machine Learning Technologies
Machine Learning is about extracting useful information from large and complex datasets. The module will cover the practical basis of how learning algorithms are can be applied. You will gain hands-on experience in laboratory-bases sessions. Exclusions...
Machine Learning for Resource Constrained Systems
This module will study the devices, technologies and software that enables “Machine Learning on Embedded Systems” ranging from tiny resource-constrained platforms such as microcontrollers to edge devices
Part III Individual Project Phase 1
The Part Three Individual Project gives students the opportunity to gain both detailed knowledge and practical experience in a more focussed area than generally possible elsewhere in their degree programme. Most projects are in the nature of a challenging...
Part III Individual Project Phase 2
The Part III Individual Project gives students the opportunity to gain both detailed knowledge and practical experience in a more focussed area than generally possible elsewhere in their degree programme. Most projects are in the nature of a challenging e...
Robotic Systems
Robots are becoming more widely used in society, with applications ranging from agriculture through to manufacturing, with increasing interest in autonomous systems. This module will introduce students to the fundamentals of robotic systems including k...
You must also choose from the following modules in year 3:
Advanced Databases
This module builds on the first year Data Management module to give students a deeper and broader view of the issues involved in database management systems, some of the most complex software in common use.
Advanced Partial Differential Equations
Partial Differential Equations (PDEs) occur frequently in many areas of mathematics. This module extends earlier work on PDEs by presenting a variety of more advanced solution techniques together with some of the underlying theory.
Bioinformatics and Systems Biology
Large-scale approaches at the molecular, cellular, organismal and ecological level are revolutionizing biology by enabling systems-level questions to be addressed. In many cases, these approaches are driven by technologies that allow the components of bio...
Biomaterials
A biomaterial can be described as a material used in a biomedical device intended to interact with biological systems. The selection of an appropriate biomaterial is critical to the performance of an implant. For a hip replacement, properties such as good...
Biosensors and Diagnostics
A biosensor is a device that translates a biomolecular binding event into an electrical or optical signal that can be quantified and recorded. Biosensors come in many different formats, from complicated nanofabricated mechanical transducers to simple but...
Cloud Application Development
During the first two years of the degree students gain experience in a variety of 'traditional' programming languages in procedural, functional and object-oriented flavours. This module addresses the design and use of scripting languages for a contemporar...
Control System Design
Engineering Replacement Body Parts
Do you want to find out how stem cells are being used to help treat disease and allow us to live better, for longer? And are you interested in the controversy surrounding them? Do you want to find out what tissue engineering is, and how scientists are ...
Fluids and Mechanical Materials
Global Health
The global health module is an exciting opportunity to examine the factors associated with emerging and re-emerging infectious diseases such as the recent outbreak of Ebola and Swine Flu that quickly spread around the world, and non-communicable diseases ...
Machine Learning Technologies
Machine Learning is about extracting useful information from large and complex datasets. The module will cover the practical basis of how learning algorithms are can be applied. You will gain hands-on experience in laboratory-bases sessions. Exclusions...
Machine Learning for Resource Constrained Systems
This module will study the devices, technologies and software that enables “Machine Learning on Embedded Systems” ranging from tiny resource-constrained platforms such as microcontrollers to edge devices
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...
Mechanical Power Transmission and Vibration
The module provides an overview of relevant topics in mechanical power transmission and methodology of vibration analysis for such mechanical assemblies. The main objective of the module is to learn methods of analysis and design of machines and their ...
Natural Language Processing
This module gives students an introduction to natural language processing (NLP) algorithms and an understanding of how to implement NLP applications.
Operational Research
The module introduces the operational research approach for modelling and solving engineering and management problems.
Orthopaedic Biomechanics
This module will provide an insight into the engineering based problems faced in orthopaedic biomechanics, through a detailed study of intact lower limb and the lower limb pre- and post- total joint replacement. You will gain an understanding of the struc...
Principles of Neuroscience
This module conveys the concept of neuroscience as an integrative discipline by providing a description of mammalian nervous system function from molecular aspects of synaptic signalling to information integration and system level processing. Lectures ...
Robotic Systems
Robots are becoming more widely used in society, with applications ranging from agriculture through to manufacturing, with increasing interest in autonomous systems. This module will introduce students to the fundamentals of robotic systems including k...
Security of Cyber Physical Systems
The course requires to understand C code, assembly language, x86 architectures and memory allocation (a refresher will be provided).
Signal and Image Processing
Signal processing is an essential part of human life and of modern industrial systems. As humans we see and hear and process signals. This is the same in electronic systems: we sense and then process signals. We need to be able to understand these signals...
Year 4 modules
You must study the following modules in year 4:
Data Mining
The challenge of data mining is to transform raw data into useful information and actionable knowledge. Data mining is the computational process of discovering patterns in data sets involving methods at the intersection of artificial intelligence, machine...
Deep Learning Technologies
Deep learning has revolutionised numerous fields in recent years. We've witnessed improvements in everything from computer vision through speech analysis to natural language processing as a result of the advent of massively parallel compute coupled with l...
Group Design Project
This module provides an introduction to intensive group project work in collaboration with an industrial or academic customer. Students work in groups of at least four people on a project typically based on an idea from an industrial partner, or from an a...
Industrial Studies
This Industrial Studies module is part of our MEng programmes with “Industrial Studies” in the title, and allows students to go on to a one-year placement in industry in Part III of their programme. Students are normally expected start their placement...
Interdisciplinary Thinking
This module is offered in the context of a multi-disciplinary programme that requires students to both demonstrate appropriate appreciation of disciplines which are foreign to them (including an understanding of current research and research methods, an a...
You must also choose from the following modules in year 4:
Advanced Micro and Nanosystems
The aim of this module is to provide an overview of a range of microscale and nanoscale systems and devices, including sensors, actuators, and transducers. The module consists of practical works on micro and nanosystems, involving construction and charact...
Applied Control Systems
This module will introduce the student to key topics within control and signal processing, developing understanding through a combination of theoretical content and practical application. The theoretical content is focussed in a number of key themes wi...
Biologically Inspired Robotics
This module lies at the intersection of robotics and biology. Through the abstraction of design principles from biological systems, it is possible to develop a range of core competences, including mechatronic systems, sensor and actuator technologies. By ...
Deep Learning Technologies
Deep learning has revolutionised numerous fields in recent years. We've witnessed improvements in everything from computer vision through speech analysis to natural language processing as a result of the advent of massively parallel compute coupled with l...
Knowledge Graphs for AI Systems
The last decade and a half have seen the Web move away from a purely document-centric information system to one in which hypertext techniques are applied to the sort of data found in databases; the term “Semantic Web” is used to refer to this Web of linke...
Microfluidics and Lab-on-a-Chip
This module teaches the basics of the behaviour of fluids in microsystems, specifically focussing on the interaction of fundamental physical mechanisms and the design of microfluidic devices. It also reviews and analyses the state of the art in applied mi...
Microsensor Technologies
This module presents a broad overview of microsensor technologies, including the basic principles of measurement systems and the scaling effects arising from system miniaturisation. The practical component, assessed by a Lab Report, involves the design an...
Mobile Applications Development
More and more people are using increasingly powerful mobile devices as their primary means of obtaining information and requesting services over the Internet. The shift from traditional personal computers (desktops and laptops) to mobile devices (Smart ph...
Numerical Methods
Often in mathematics, it is possible to prove the existence of a solution to a given problem, but it is not possible to "find it". For example, there are general theorems to prove the existence and uniqueness of an initial value problem for an ordinary di...
Simulation Modelling for Computer Science
Simulation modelling plays an increasingly significant role across modern science and engineering, with the development of computational models becoming established practice in industry, consulting, and policy formulation. Computer scientists are often em...
Web and Cloud Applications Development
The aims of the module are: - To provide students with the opportunity to improve their understanding of web application development, and cloud computing systems. - To cover important techniques and issues in designing and building a modern web applicat...
Wireless Networks
This course is intended to give students an outline of how wireless communication and computer networks work "above the physical layer". This includes the interoperability of wireless networks such as WiMax/GPRS and WiFi to provide WiFi on trains etc. How...
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)
Academic support
You’ll be supported by a personal academic tutor and have access to a senior tutor.
Course leader
Russel Torah is the course leader.
Careers
You'll graduate with the skills required to work across the health technology sector, from small and large medtech companies, to NHS Digital analyst roles.
The industrial studies year will help you to connect with future employers, add value to your CV or launch your career in a new direction. It will also enable you to develop business and team-working skills in your chosen industry.
You’ll have access to our specialist careers support from our Careers Hub, which coordinates opportunities to connect with employers. This includes things like career fairs, support with job applications, summer internships and more.
Careers services at Southampton
Fees, costs and funding
Tuition fees
Fees for a year's study:
- UK students pay £9,250.
- EU and international students pay £27,400.
Your fees will remain the same each year from when you start studying this course. This includes if you suspend and return.
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
The Student Services Centre offers support and advice on money to students. You may be able to access our Student Support fund and other sources of financial support during your course.
Funding for EU and international students
Find out about funding you could get as an international student.
How to apply
When you apply use:
- UCAS course code: BB98
- UCAS institution code: S27
What happens after you apply?
We will assess your application on the strength of your:
- predicted grades
- academic achievements
- personal statement
- academic reference
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.
Equality and diversity
We treat and select everyone in line with our Equality and Diversity Statement.
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: enquiries@southampton.ac.uk
Tel: +44(0)23 8059 5000
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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?
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- Defining the Marine Fisheries-Energy-Environment Nexus: Learning from shocks to enhance natural resource resilience
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- Environmental and genetic determinants of Brassica crop damage by the agricultural pest Diamondback moth
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- Examining evolutionary loss of calcification in coccolithophores
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- 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
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- 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
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- Impact of neuromodulating drugs on gut microbiome homeostasis
- Impact of pharmaceuticals in the marine environment in a changing world
- Impacts of environmental change on coastal habitat restoration
- 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
- Long-term change in the benthos – creating robust data from varying camera systems
- 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
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- 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
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- Will it stick? Exploring the role of turbulence and biological glues on ocean carbon storage
- X-ray imaging and property characterisation of porous materials
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