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Masters Degrees (Aerospace Medicine)

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The Aerospace Medicine course aims to provide medical graduates with advanced theoretical and practical training in the physiology, psychology and clinical medicine of humans exposed to or working in the aviation environment. Read more

The Aerospace Medicine course aims to provide medical graduates with advanced theoretical and practical training in the physiology, psychology and clinical medicine of humans exposed to or working in the aviation environment.

The programme will also prepare students for the examination in the Diploma in Aviation Medicine, DAVMed which is run through the Faculty of Occupational Medicine (FOM). More details can be found here 

Key Benefits

  • World-class learning programme delivered at a location recognised by the Joint Royal Colleges of Physicians Training Board for higher professional training in aviation and space medicine.
  • Teaching by internationally renowned scientists and clinicians.
  • An advanced study course providing unique opportunities to undertake an aeromedical research project that are carried out in the laboratory or in approved aeromedical centres in the UK and elsewhere.
  • Additional preparation for the Diploma in Aviation Medicine, Faculty of Occupational Medicine (RCP) is available.

Description

The Aerospace Medicine course is a unique study pathway that provides physicians with comprehensive theoretical and practical instruction in advanced aviation physiology, psychology, pathology, clinical and operational aviation medicine.

This course includes time based at the RAF Centre of Aviation Medicine (CAM), as the Centre provides an appropriate location for valuable elements of the teaching and visits to some of the service and civilian establishments used. The Centre also offers unique practical facilities which are available to students on the course.

You will complete the MSc course in one year, studying September to September. If you are following the MSc pathway, you must take modules totalling 180 credits to meet the requirements of the qualification, of which 60 will come from a research project and written dissertation.

The Postgraduate Diploma pathway requires modules with a total of 120 credits to complete the programme and can be conducted in just over six months.

Teaching

If carrying out the MSc you will receive approximately 510 contact hours at King’s and various external study locations, primarily the RAF Centre for Aviation Medicine at Henlow – this includes lectures, seminars, practical sessions.

If you are studying for the full MSc qualification, you will be expected to spend approximately 600 hours on the research project module and thesis.

The study time and assessment methods detailed above are typical and give you a good indication of what to expect. However, they may change if the course modules change.

Assessment

The primary method of assessment for this course is a combination of oral presentations, written assignments and written examinations.

The MSc research project and dissertation will be assessed on an extended piece of writing. 

The study time and assessment methods detailed above are typical and give you a good indication of what to expect. However, they may change if the course modules change.

Course accreditation

The course at King’s is delivered at an approved centre of the Royal College of Physicians (RCP) to specifically deliver education and training for individuals wishing to take the RCP, Faculty of Occupational Medicine examination leading to the award of the Diploma in Aviation Medicine.

Location

This course is primarily taught at the King’s College London Guy’s campus, with some teaching at the RAF Centre of Aviation Medicine at Henlow as well as other locations, mainly in the UK but commonly with one overseas visit. Please note that locations are determined by where each module is taught and may vary.

Career prospects

Career opportunities in aerospace medicine are varied. Many undertaking specialist training have already been employed specifically for the role and are sponsored to undertake these courses. However others use such training so as to better equip themselves for potential employment.

Areas of possible careers include with airlines, aviation regulators, air traffic services, military aviation and space agencies as well as in academic or commercial research organisations. Some aviation medical examiners (AMEs) undertake the DAvMed. Appointment as an AME in the UK is now restricted to doctors on the GMC specialist register. 

Previous graduates of the M.Sc programme and DAvMed courses have been employed in all these areas and enjoyed a varied and challenging career.



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Biomedical engineers work at the interface of engineering, biology, and medicine, combining their engineering expertise with an understanding of human biology and medical needs to make the world a healthier place. Read more

Biomedical engineers work at the interface of engineering, biology, and medicine, combining their engineering expertise with an understanding of human biology and medical needs to make the world a healthier place.

This masters course will equip you with the specialist knowledge, expertise and skills to integrate biology and medicine with engineering to solve problems related to living systems.

Introducing your degree

The MSc Biomedical Engineering is designed for engineering, and physical science graduates who want to specialise in this vibrant area of engineering. There is high demand for biomedical engineers, and this masters has been developed with our graduates’ employability in mind.

Overview

During this course, you will learn the fundamental scientific and technical aspects of biomedical engineering, alongside developing your knowledge of the relevant aspects of human biology in health and disease. This interdisciplinary course draws on expertise from leading departments within the University of Southampton, brought together through the Institute for Life SciencesEngineering and the EnvironmentMedicineHealth SciencesNatural and Environmental Sciences, and Electronics and Computer Science.

If you choose to, you will be able to specialise in your chosen area of biomedical engineering through themed areas of application: musculoskeletal, cardiovascular, imaging, diagnostic systems and audiology.

The course will enable you to thrive in an environment where teams from range of disciplines have work together efficiently. To help you succeed as biomedical engineer, the course features ‘problem-driven’ seminars, site and hospital visits, workshops and training sessions by experts from industry and national laboratories. This combination of advanced engineering, industrial experience and research enables our graduates to make a significant contribution to the development and translation of biomedical technology in both industry and academia.

You will develop the skills to apply advanced engineering in an interdisciplinary environment working in teams of physicians, scientists, engineers, business people and other professionals to monitor, restore and enhance normal body function, abilities and outcomes. You will also enhance your understanding of the ethical, safety and societal implications of developing medical technologies. 

Through your research project you have a further opportunity to integrate your engineering skills with an understanding of the complexity of biological systems, enabling you to work successfully at the intersection of science, medicine and mathematics to solve biological and medical problems. Example research projects may include the design and performance evaluation of new devices to replace joints, or the development of new imaging methods to study bone or lung diseases.

View the specification document for this course

Career Opportunities

Many biomedical engineers work in research, either in academia or industry, along with medical scientists, to develop and evaluate systems and products such as artificial organs, prostheses, instrumentation, and diagnostic, health management and care delivery systems.

Biomedical engineers may design devices used in various medical procedures and develop imaging systems and devices for observing and controlling body functions.

Biomedical engineers therefore make careers in academia, industry, healthcare and clinical medicine, as well as government.



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Our Human & Applied Physiology MSc will give you an advanced theoretical and practical understanding of the functioning of the muscular, respiratory and cardiovascular systems, including the effects of extreme environmental conditions on whole-body physiology. Read more

Our Human & Applied Physiology MSc will give you an advanced theoretical and practical understanding of the functioning of the muscular, respiratory and cardiovascular systems, including the effects of extreme environmental conditions on whole-body physiology. This innovative course will put you at the cutting edge of the field alongside internationally renowned experts.

Key benefits

  • The original and foremost programme in human and applied physiology in the UK.
  • Unique exposure to human physiology applied to aerospace and military medicine offered only by King’s.
  • Training in a wide variety of relevant practical laboratory skills.
  • Gain a knowledge base of human physiology particularly relevant for careers in biomedical research and medicine.
  • Lectures from world-leading experts in a variety of different fields.

Description

This course will give you a theoretical and practical basis for explaining the functioning of the muscular, respiratory and cardiovascular systems at rest and during exercise. You will explore the effects of extreme environmental conditions on whole body physiology, including in relation to aerospace and military medicine.

You will study topics from both systemic and cellular/molecular perspectives in order to gain an understanding of the breadth of investigative approaches employed in human physiology research. You will also focus on practical work, learning how to plan and run experiments using human subjects.

Ultimately we aim to equip you with the knowledge and skills to enhance your understanding and expertise in human physiology in its broadest sense and build a career in a related field.

Course format and assessment

Teaching

For every 30-credit module we will provide you with 36 hours of teaching through lectures and tutorials, along with 24 hours of practical classes. For every 15-credit module you will have six hours of teaching. The 60-credit research project is a 12-week full-time laboratory-based research project, and how long it takes will depend on your project. We will expect you to complement all of this with self-study.

Assessment

We will assess you through unseen written exams, lab reports, poster and oral presentations and coursework essays.

The study time and assessment methods detailed above are typical and give you a good indication of what to expect. However, they may change if the course modules change.

Location

The course is primarily taught at the King’s College London Guy’s campus. Please note that locations are determined by where each module is taught and may vary depending on the optional modules you select.

Regulating body

King’s College London is regulated by the Higher Education Funding Council for England.

Career prospects

Our graduates go on to careers in academic teaching and research, medicine, clinical physiology, health services, sports science support, and research posts in industry or in Ministry of Defence research establishments.



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The MSC in Computational Fluid Dynamics (CFD) is an inherently interdisciplinary branch of science which has an extremely broad spectrum of applications. Read more
The MSC in Computational Fluid Dynamics (CFD) is an inherently interdisciplinary branch of science which has an extremely broad spectrum of applications. Fluid dynamics uses numerical methods and algorithms to solve and analyse problems that involve fluid flows. Sectors such as aviation, space, automotive, medicine and environment are just some industries which have fluid flows in common. This course has been designed to reflect the wide applications of CFD. It covers a broad range of fields from aerospace, turbo machinery, multiphase environmental flows and fluid-structure interaction problems.

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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Computer Modelling and Finite Elements in Engineering Mechanics at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Computer Modelling and Finite Elements in Engineering Mechanics at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

Swansea University has been at the forefront of international research in the area of computational engineering. Internationally renowned engineers at Swansea pioneered the development of numerical techniques, such as the finite element method, and associated computational procedures that have enabled the solution of many complex engineering problems. As a student on the Master's course in Computer Modelling and Finite Elements in Engineering Mechanics, you will find the course utilises the expertise of academic staff to provide high-quality postgraduate training.

Key Features: Computer Modelling and Finite Elements in Engineering Mechanics

Computer simulation is now an established discipline that has an important role to play in engineering, science and in newly emerging areas of interdisciplinary research.

Using mathematical modelling as the basis, computational methods provide procedures which, with the aid of the computer, allow complex problems to be solved. The techniques play an ever-increasing role in industry and there is further emphasis to apply the methodology to other important areas such as medicine and the life sciences.

This Computer Modelling and Finite Elements in Engineering Mechanics course provides a solid foundation in computer modelling and the finite element method in particular.

The Zienkiewicz Centre for Computational Engineering, within which this course is run, has excellent computing facilities, including a state-of-the-art multi-processor super computer with virtual reality facilities and high-speed networking.

Modules

Modules on the Computer Modelling and Finite Elements in Engineering Mechanics course can vary each year but you could expect to study:

Reservoir Modelling and Simulation

Solid Mechanics

Finite Element Computational Analysis

Advanced Fluid Mechanics

Computational Plasticity

Fluid-Structure Interaction

Nonlinear Continuum Mechanics

Computational Fluid Dynamics

Dynamics and Transient Analysis

Computational Case Study

Communication Skills for Research Engineers

Numerical Methods for Partial Differential Equations

Accreditation

The MSc Computer Modelling and Finite Elements in Engineering Mechanics course is accredited by the Joint Board of Moderators (JBM).

The Joint Board of Moderators (JBM) is composed of the Institution of Civil Engineers (ICE), the Institution of Structural Engineers (IStructE), the Chartered Institution of Highways and Transportation (CIHT), and the Institute of Highway Engineers (IHE).

The MSc Computer Modelling and Finite Elements in Engineering Mechanics degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

The MSc Computer Modelling and Finite Elements in Engineering Mechanics degree has been accredited by the JBM under licence from the UK regulator, the Engineering Council.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Facilities

Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Hardware includes a 450 cpu Cluster, high-end graphics workstations and high-speed network links. Extensive software packages include both in-house developed and 'off-the-shelf' commercial.

Links with Industry

The Zienkiewicz Centre for Computational Engineering has an extensive track record of industrial collaboration and contributes to many exciting projects, including the aerodynamics for the current World Land Speed Record car, Thrust SSC, and the future BLOODHOUND SSC, and the design of the double-decker super-jet Airbus A380.

Careers

Employment in a wide range of industries, which require the skills developed during the Computer Modelling and Finite Elements in Engineering Mechanics course, from aerospace to the medical sector. Computational modelling techniques have developed in importance to provide solutions to complex problems and as a graduate of this course in Computer Modelling and Finite Elements in Engineering Mechanics, you will be able to utilise your highly sought-after skills in industry or research.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.



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This is a specialised Management Masters giving students an opportunity to study a wide range of international business topics. There are three programmes;. Read more
This is a specialised Management Masters giving students an opportunity to study a wide range of international business topics. There are three programmes;

MSc International Business and Strategic Management

MSc International Strategic Management

MSc International Business

and all are designed to provide students with knowledge and skills that would be well suited for careers as business consultants and/or strategy analysts in the broad arena of business and management, but especially in the areas of international business and strategic management. It will also be relevant to those wishing to work in business and economic development roles in public sector organisations.

The programme is suitable for students from any background and will rapidly develop an understanding of management and business studies to an advanced level, with particular reference to the current research agenda and innovative thinking in international business practice.

MSc International Business and Strategic Management

Studying on our MSc in International Business and Strategic Management provides you with the chance look in-depth at the factors that shape international business and how strategy is articulated and enacted in a global context. During this programme of study, you will also have the chance to develop your skills in critical analysis, information processing and data presentation. Subject material is studied in an international context to prepare graduates for the global economy in which organisations operate. The programme is suitable for applicants from a wide range of backgrounds, including those with no previous business studies. Upon completing this programme, you will not only be prepared for a range of careers in international business and management, you will also have the skills and outlook necessary to thrive in an increasingly interconnected global workplace.

Term 1
-International Business in the Global Context [20]
-International Political Economy and Business [20]
-Introduction to Strategic Management [10]
-Managing People [10]

Term Break
Term 2
- Research Methods for International Business and Management Studies [20]
-Strategy in Global Organisations [20]

and One option from:
-Continuity and Change in Organisations [20]
-International Marketing Communications and Ethics [20]
-Social and Environmental Accounting [20]
-International Sales Management [20]
-Global Perspectives on HRM and Employment Relations [20]

Term 3 and Summer
- Dissertation (60)

Note: the University reserves the right to change the modules on offer.

MSc International Strategic Management

Studying on our MSc in International Strategic Management provides you with the chance look in-depth at how strategy is formulated, articulated and enacted in a global context. During this programme of study, you will also have the chance to develop your skills in critical analysis, information processing and data presentation. Subject material is studied in an international context to prepare graduates for the global economy in which organisations operate. The programme is suitable for applicants from a wide range of backgrounds, including those with no previous business studies. Upon completing this programme, you will not only be prepared for a range of careers in international business and management, you will also have the skills and outlook necessary to thrive in an increasingly interconnected global workplace.

Term 1
-International Business in the Global Context [20]
-International Political Economy and Business [20]
-Introduction to Strategic Management [10]
-Managing People [10]

Term Break
Term 2
-Research Methods for International Business and Management Studies [20]
-Case Studies in Strategic Management [20]
and One option from:
-International Business Management and Emerging Markets [20]
-Strategy in Global Organisations [20]
-International Sales Management [20]
-International Public Management (20)

Term Break
Term 3 and Summer
- Dissertation (60)

Note: the University reserves the right to change the modules on offer.

MSc International Business

Studying on our MSc in International Business provides you with the chance look in-depth at the factors that shape the international business environment and how corporations respond to these challenges. During this programme of study, you will also have the chance to develop your skills in critical analysis, information processing and data presentation. Subject material is studied in an international context to prepare graduates for the global economy in which organisations operate. The programme is suitable for applicants from a wide range of backgrounds, including those with no previous business studies. Upon completing this programme, you will not only be prepared for a range of careers in international business and management, you will also have the skills and outlook necessary to thrive in an increasingly interconnected global workplace.

Term 1
-International Business in the Global Context [20]
-International Political Economy and Business [20]
-Introduction to Strategic Management [10]
-Managerial Economics [10]

Term Break
Term 2
Qualitative Research Methods [10]
International Business Management and Emerging Markets [20]
and One option from:
-Strategy in Global Organisations [20]
-Innovation and Technology Management [20]
-Financial Strategy and Governance [20]
-International Marketing Communications and Ethics [20]
-Global Perspectives on HRM and Employment Relations [20]
-International Sales Management [20]


Term Break
Term 3 and Summer
-Quantitative Methods and Data Analysis (10)
Dissertation [60]

Note: the University reserves the right to change the modules on offer.

Where you’ll go from here

York Masters students have been successful in developing careers in a range of organisations in many parts of the world. Common destinations on leaving are:
-Accountancy and Audit
-Computing
-Defence and Aerospace
-Finance and Banking
-Healthcare and Medicine
-Insurance
-Management Consultancy
-Market Research
-Pharmaceuticals and Chemicals
-Tourism and Travel
-Transport, Logistics and Distribution

A small number of students each year are keen to continue their studies, enrolling on specialists masters programmes elsewhere in the UK or moving on to The York Management School’s Doctoral programme.

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This programme provides a practical understanding in a number of key areas of Electronic Engineering. You will work with current and familiar technology, such as Wi-Fi, and will discover what the future holds for silicon technology by studying sensory equipment, energy generation and interaction with surroundings. Read more

This programme provides a practical understanding in a number of key areas of Electronic Engineering. You will work with current and familiar technology, such as Wi-Fi, and will discover what the future holds for silicon technology by studying sensory equipment, energy generation and interaction with surroundings. The technical element of the degree includes system-on-chip, microengineering, RF engineering, control, communications and embedded systems, whilst the practical element features digital design and the design of microstructures for switching and biomedical applications, in addition to the programming of embedded microcontrollers, RF circuits and methods of building control loops and associated software.

To meet the demands of emerging markets such as Health, Security, Energy and the Environment, the programme will explore advanced sensors for chips and assemblies, and will cover actuators, display technologies and microwave and millimetre wave electronic systems. You will enhance your skills in MEMS design, microfluidics, high-frequency technologies and control solutions, in addition to advanced nanoelectronics.

The electronics industry is expanding rapidly with the UK alone aiming to increase the sector’s economic contribution from £80bn to £120bn by 2020 and creating 150,000 highly-skilled jobs in the process. Smart Grid, Health Care and Medicine, and Energy and Environment are set to join established industrial sectors including Security, Transport and Aerospace as key employment sectors for electronic engineers. We therefore equip our students with the skills and knowledge needed to further their career in these industries; a major part of which is linked into the opportunity to participate in existing projects that are both challenging and linked into real industrial need. In the past, these projects have helped to establish student-industry connections that can often lead to employment. Previous project topics have included:

  • Detection of living cells in a microfluidic system using electrochemical and RF technologies
  • Self-repairable electronics through unification of self-test and calibration technology
  • Solution-processed electronics over a large area: Design and realisation of a fully computerised XY(Z) spray coater employing multiple pneumatic and/or ultrasonic airbrushes
  • Higher-order mode couplers in semiconducting RF cavities
  • Monolithic microwave integrated circuit (MMIC) design for wireless networks
  • Vision and robotic control interface system.


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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Computer Modelling in Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Computer Modelling in Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

This MRes in Computer Modelling in Engineering programme consists of two streams: students may choose to specialise in either structures or fluids. The taught modules provide a good grounding in computer modelling and in the finite element method, in particular.

Key Features of MRes in Computer Modelling in Engineering

Computer simulation is now an established discipline that has an important role to play in engineering, science and in newly emerging areas of interdisciplinary research.

Using mathematical modelling as the basis, computational methods provide procedures which, with the aid of the computer, allow complex problems to be solved. The techniques play an ever-increasing role in industry and there is further emphasis to apply the methodology to other important areas such as medicine and the life sciences.

The Zienkiewicz Centre for Computational Engineering, within which this course is run, has excellent computing facilities, including a state-of-the-art multi-processor super computer with virtual reality facilities and high-speed networking.

This Computer Modelling in Engineering course is suitable for those who are interested in gaining a solid understanding of computer modelling, specialising in either structures or fluids, and taking the skills gained through this course to develop their career in industry or research.

If you would like to qualify as a Chartered Engineer, this course is accredited with providing the additional educational components for the further learning needed to qualify as a Chartered Engineer, as set out by UK and European engineering professional institutions.

Modules

Modules on the Computer Modelling in Engineering programme typically include:

• Finite Element and Computational Analysis

• Numerical Methods for Partial Differential Equations

• Solid Mechanics

• Advanced Fluid Mechanics

• Dynamics and Transient Analysis

• Communication Skills for Research Engineers

• MRes Research Project

Accreditation

The MRes Computer Modelling in Engineering course is accredited by the Joint Board of Moderators (JBM).

The Joint Board of Moderators (JBM) is composed of the Institution of Civil Engineers (ICE), the Institution of Structural Engineers (IStructE), the Chartered Institution of Highways and Transportation (CIHT), and the Institute of Highway Engineers (IHE).

The MRes Computer Modelling in Engineering degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

The MRes Computer Modelling in Engineering degree has been accredited by the JBM under licence from the UK regulator, the Engineering Council.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Links with Industry

The Civil and Computational Engineering Centre has an extensive track record of industrial collaboration and contributes to many exciting projects, including the aerodynamics for the current World Land Speed Record car, Thrust SSC, and the future BLOODHOUND SSC, and the design of the double-decker super-jet Airbus A380.

Examples of recent collaborators and sponsoring agencies include: ABB, Audi, BAE Systems, British Gas, Cinpress, DERA, Dti, EADS, EPSRC, European Union, HEFCW, HSE, Hyder, Mobil, NASA, Quinshield, Rolls-Royce, South West Water, Sumitomo Shell, Unilever, US Army, WDA.

Student Quotes

“I was attracted to the MRes course at Swansea as the subject matter was just what I was looking for.

I previously worked as a Cardiovascular Research Assistant at the Murdoch Children’s Research Institute in Melbourne. My employer, the Head of the Cardiology Department, encouraged me to develop skills in modelling as this has a lot of potential to help answer some current questions and controversies in the field. I was looking for a Master’s level course that could provide me with computational modelling skills that I could apply to blood flow problems, particularly those arising from congenital heart disease.

The College of Engineering at Swansea is certainly a good choice. In the computational modelling area, it is one of the leading centres in the world (they wrote the textbook, literally). A lot of people I knew in Swansea initially came to study for a couple of years, but then ended up never leaving. I can see how that could happen.”

Jonathan Mynard, MRes Computer Modelling in Engineering, then PhD at the University of Melbourne, currently post-doctoral fellow at the Biomedical Simulation Laboratory, University of Toronto, Canada

Careers

Employment in a wide range of industries, which require the skills developed during the Computer Modelling in Engineering course, from aerospace to the medical sector. Computational modelling techniques have developed in importance to provide solutions to complex problems and as a graduate of this course, you will be able to utilise your highly sought-after skills in industry or research.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

World-leading research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

Highlights of the Engineering results according to the General Engineering Unit of Assessment:

Research Environment at Swansea ranked 2nd in the UK

Research Impact ranked 10th in the UK

Research Power (3*/4* Equivalent staff) ranked 10th in the UK



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Research degrees may be undertaken in the three main areas of research interest in the Laboratory. The growing number of academic staff are supported in their research by the technical staff and post-doctoral research fellows. Read more
Research degrees may be undertaken in the three main areas of research interest in the Laboratory. The growing number of academic staff are supported in their research by the technical staff and post-doctoral research fellows.

We make every attempt to allocate you to a supervisor directly in your field of interest, consistent with available funding and staff loading. When you apply, please give specific indications of your research interest – including, where appropriate, the member(s) of staff you wish to work with – and whether you are applying for a studentship or propose to be self-funded.

Visit the website https://www.kent.ac.uk/courses/postgraduate/18/chemistry

About The School of Physical Sciences

The School offers postgraduate students the opportunity to participate in groundbreaking science in the realms of physics, chemistry, forensics and astronomy. With strong international reputations, our staff provide plausible ideas, well-designed projects, research training and enthusiasm within a stimulating environment. Recent investment in modern laboratory equipment and computational facilities accelerates the research.

The School maintains a focus on progress to ensure each student is able to compete with their peers in their chosen field. We carefully nurture the skills, abilities and motivation of our students which are vital elements in our research activity. We offer higher degree programmes in chemistry and physics (including specialisations in forensics, astronomy and space science) by research. We also offer taught programmes in Forensic Science, studied over one year full-time, and a two-year European-style Master’s in Physics.

Our principal research covers a wide variety of topics within physics, astronomy and chemistry, ranging from specifically theoretical work on surfaces and interfaces, through mainstream experimental condensed matter physics, astrobiology, space science and astrophysics, to applied areas such as biomedical imaging, forensic imaging and space vehicle protection. We scored highly in the most recent Research Assessment Exercise, with 25% of our research ranked as “world-leading” and our Functional Materials Research Group ranked 2nd nationally in the Metallurgy and Materials discipline.

Research areas

- Applied Optics Group (AOG):

Optical sensors
This activity largely covers research into the fundamental properties of guided wave interferometers, and their application in fields ranging from monitoring bridge structures to diagnostic procedures in medicine.

Biomedical imaging/Optical coherence tomography (OCT)
OCT is a relatively new technique which can provide very high-resolution images of tissue, and which has a major application in imaging the human eye. We are investigating different time domain and spectral domain OCT configurations.

The Group is developing systems in collaboration with a variety of different national and international institutions to extend the OCT capabilities from systems dedicated to eye imaging to systems for endoscopy, imaging skin and tooth caries. Distinctively, the OCT systems developed at Kent can provide both transverse and longitudinal images from the tissue, along with a confocal image, useful in associating the easy to interpret en-face view with the more traditional OCT cross section views.

The Group also conducts research on coherence gated wavefront sensors and multiple path interferometry, that extend the hardware technology of OCT to imaging with reduced aberrations and to sensing applications of optical time domain reflectometry.

- Forensic Imaging Group (FIG):

The research of the forensic imaging team is primarily applied, focusing on mathematical and computational techniques and employing a wide variety of image processing and analysis methods for applications in modern forensic science. The Group has attracted approximately £850,000 of research funding in the last five years, from several academic, industrial and commercial organisations in the UK and the US. The Group also collaborates closely with the Forensic Psychology Group of the Open University.

Current active research projects include:

- the development of high-quality, fast facial composite systems based on evolutionary algorithms and statistical models of human facial appearance

- interactive, evolutionary search methods and evolutionary design

- statistically rigorous ageing of photo-quality images of the human face (for tracing and identifying missing persons)

- real and pseudo 3D models for modelling and analysis of the human face

- generating ‘mathematically fair’ virtual line-ups for suspect identification.

- Functional Materials Group (FMG):
The research in FMG is concerned with synthesis and characterisation of functional materials, as exemplified by materials with useful optical, catalytic, or electronic properties, and with an
emerging theme in biomaterials. The Group also uses computer modelling studies to augment
experimental work. The research covers the following main areas:

- Amorphous and nanostructured solids
- Soft functional material
- Theory and modelling of materials

- Centre for Astrophysics and Planetary Science (CAPS):
The group’s research focuses on observational and modelling programmes in star formation, planetary science and early solar system bodies, galactic astronomy and astrobiology. We gain data from the largest telescopes in the world and in space, such as ESO’s Very Large Telescope, the New Technology Telescope, the Spitzer Space Telescope and the Herschel Space Observatory. We also use our in-house facilities which include a two-stage light gas gun for impact studies.

Staff are involved in a wide range of international collaborative research projects. Areas of particular interest include: star formation, extragalactic astronomy, solar system science and instrumentation development.

Careers

All programmes in the School of Physical Sciences equip you with the tools you need to conduct research, solve problems, communicate effectively and transfer skills to the workplace, which means our graduates are always in high demand. Our links with industry not only provide you with the opportunity to gain work experience during your degree, but also equip you with the general and specialist skills and knowledge needed to succeed in the workplace.

Typical employment destinations for graduates from the physics programmes include power companies, aerospace, defence, optoelectronics and medical industries. Typical employment destinations for graduates from our forensic science and chemistry programmes include government agencies, consultancies, emergency services, laboratories, research or academia.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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Biofluid Mechanics applies engineering, mathematical and physical principles of fluids to solve complex and multifaceted problems, primarily in biology and medicine, but also in aerospace and robotics. Read more

Why this course?

Biofluid Mechanics applies engineering, mathematical and physical principles of fluids to solve complex and multifaceted problems, primarily in biology and medicine, but also in aerospace and robotics.

This newly-launched MSc course is the first one-year taught course in the world dedicated to Biofluid Mechanics. It covers a wide range of multidisciplinary training on the kinematics and dynamics of fluids related to biological systems, medical science, cardiovascular devices, numerical modelling and computational fluid dynamics.

The one-year full-time programme offers you a unique opportunity to lead the next generation of highly-skilled postgraduates that will form a new model worldwide for academia – with world-class research knowledge, industry – with highly-competitive skills in both biomedical engineering and fluid dynamics, and for society – with better training to work with clinicians.

This course is taught by the Department of Biomedical Engineering, with input from other departments across the Faculty of Engineering and the wider University. You'll be supported throughout the course by a strong team of academics with global connections. You'll benefit from a unique training and an innovative teaching and learning environment.

You'll study

In Semesters 1 and 2, you'll take compulsory classes and a choice of optional classes. 
The remaining months are dedicated to project work, submitted as dissertation (Diploma students) or as a research thesis (MSc students).

Compulsory Classes

Biofluid Mechanics
Industrial Software
Medical Science for Engineering
Research Methodology
Professional Studies in Biomedical Engineering

Optional Classes

Haemodynamics for Engineers
Numerical Modelling in Biomedical Engineeirng
Cardiovascular Devices
The Medical Device Regulatory Process
Entrepreneurship and Commercialisation in Biomedical Engineering
Introduction to Biomechanics
Finite Element Methods for Boundary Value Problems and Approximation
Mathematical Biology and Marine Population Modelling
Design Management
Risk Management

Masters Research Project

The project provides MSc students with the opportunity to experience the challenges and rewards of independent study in a topic of their own choice; the project may involve an extended literature review, experimental and/or computational work.

Postgraduate Diploma Dissertation

The dissertation is likely to take the form of an extended literature review. Your project work will have been supported by a compulsory research methods module and specialist knowledge classes throughout the year designed to assist with technical aspects of methodology and analysis.

Industrial Partnerships

We have established strong partnerships with industrial companies that have offered their support through the provision of software licenses and/or teaching material.

Fees & funding

How much will my course cost?

All fees quoted are for full-time courses and per academic year unless stated otherwise.

Scotland/EU

2017/18 - £5,500
Rest of UK

2017/18 - £9,000
International

2017/18 - £19,100
How can I fund my course?

Scholarship search

Scottish and non-UK EU postgraduate students

Scottish and non-UK EU postgraduate students starting in 2017 can apply for support from the Student Awards Agency Scotland (SAAS). The support is in the form of a tuition fee loan and for eligible students a living cost loan. Find out more about the support and how to apply.

Don’t forget to check our scholarship search for more help with fees and funding.

Students coming from England

Students ordinarily resident in England can apply for Postgraduate support from Student Finance England. The support is a loan of up to £10,280 which can be used for both tuition fees and living costs. Find out more about the support and how to apply.

Don’t forget to check our scholarship search for more help with fees and funding.

Students coming from Wales

Postgraduate students starting in 2017 who are ordinarily resident in Wales can apply for support from Student Finance Wales. The support is a loan of up to £10,280 which can be used for both tuition fees and living costs. We are waiting on further information being released about this support and how to apply.

Don’t forget to check our scholarship search for more help with fees and funding.

Students coming from Northern Ireland

Postgraduate students starting in 2017 who are ordinarily resident in Northern Ireland can apply for support from Student Finance NI. The support is a tuition fee loan of up to £5,500. We are waiting on further information being released about this support and how to apply.

Don’t forget to check our scholarship search for more help with fees and funding.

International students

We have a large range of scholarships available to help you fund your studies. Check our scholarship search for more help with fees and funding.

Please note

The fees shown are annual and may be subject to an increase each year. Find out more about fees.

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Biofluid mechanics applies engineering, mathematical and physical principles of fluids to solve complex and multifaceted problems primarily in biology and medicine, but also in aerospace and robotics. Read more

Research opportunities

Biofluid mechanics applies engineering, mathematical and physical principles of fluids to solve complex and multifaceted problems primarily in biology and medicine, but also in aerospace and robotics.

Our new MRes course covers a wide range of multidisciplinary training on the kinematics and dynamics of fluids related to biological systems, medical science, cardiovascular devices, numerical modelling and computational fluid dynamics (CFD), focusing on research. The MRes differs from an MSc in that you'll have the opportunity to perform multidisciplinary research for a longer time, preparing you for a research career and equipping you with world-class research knowledge.

The course is taught by the Department of Biomedical Engineering, with input from other departments across the faculty and the University.

During the course, you'll be supported by a strong team of academics with worldwide connections and you'll be offered a unique training and innovative teaching and learning environment.

Course director: Dr Asimina Kazakidi

Lecturer in Biofluid Mechanics

Course co-director: Professor Dimitris Drikakis

Executive Dean of Engineering and Professor of Engineering Science

What you'll study

This one-year programme consists of compulsory and optional classes in the first two semesters. Each class has timetabled contact hours, delivered predominantly in lectures, laboratories and tutorials.

The MRes research project will be chosen and started in semester one with guidance from a supervisor. Throughout the year you'll be working on your project.

Compulsory classes

Professional Studies in Biomedical Engineering
Research Methodology
MRes project

Elective classes

Biofluid Mechanics
Industrial Software
Medical Science for Engineering
Haemodynamics for Engineers
Numerical Modelling in Biomedical Engineering
Cardiovascular Devices
The Medical Device Regulatory Process
Entrepreneurship & Commercialisation in Biomedical Engineering
Introduction to Biomechanics
Finite Element Methods for Boundary Value Problems and Approximation
Mathematical Biology & Marine Population Modelling
Design Management
Risk Management

Guest lectures

During the course, academics and industrial speakers will be invited as part of the training. You'll also benefit from departmental seminars and knowledge exchange events.

Fees & funding

Fees

All fees quoted are per academic year unless otherwise stated.

Here are our fees for 2017/18:

Scotland/ EU

£4,195
Rest of UK

£4,195
International students

£19,100
Funding

If you can't find what you're looking for, try our scholarship search instead.

The fees shown are annual and may be subject to an increase each year.

Support & development

Careers

The new MRes course aims to train students in the Biofluid Mechanics field, targeting primarily the academic research market, but also the Medical Devices and Simulation/Analysis software industries and other related and new emerging markets.

Our postgraduates will benefit from acquiring world-class training and competitive skills in both biomedical and fluid dynamics disciplines that will make them highly employable at the following markets and related sectors/companies:

academic research
medical device market
simulation & analysis software market
biosimulation market
NHS & the healthcare/medical simulation market
life science research tools & reagents market
We've identified the current key vendors in each of the above markets and aim to create links with the relevant industry and monitor the changing market and employability trends, in order to adjust teaching modules and approaches and to enhance employability of our graduates.

Industrial partnerships

We've already established strong partnerships with industrial companies that have offered their support through the provision of software licenses and/or teaching material.

Student support

From financial advice to our IT facilities, we have loads of different support for all students here at our University. Get all the information you need at Strathlife.

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