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Take advantage of one of our 100 Master’s Scholarships to study Computer Modelling and Finite Elements in Engineering Mechanics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Computer Modelling and Finite Elements in Engineering Mechanics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

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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Take advantage of one of our 100 Master’s Scholarships to study Computational Mechanics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Computational Mechanics at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

Swansea University has gained a significant international profile as one of the key international centres for research and training in computational mechanics and engineering. As a student on the Master's course in Erasmus Mundus Computational Mechanics, you will be provided with in-depth, multidisciplinary training in the application of the finite element method and related state-of-the-art numerical and computational techniques to the solution and simulation of highly challenging problems in engineering analysis and design.

Key Features of Erasmus Mundus Computational Mechanics MSc

The Zienkiewicz Centre for Computational Engineering is acknowledged internationally as the leading UK centre for computational engineering research. It represents an interdisciplinary group of researchers who are active in computational or applied mechanics. It is unrivalled concentration of knowledge and expertise in this field. Many numerical techniques currently in use in commercial simulation software have originated from Swansea University.

The Erasmus Mundus MSc Computational Mechanics course is a two-year postgraduate programme run by an international consortium of four leading European Universities, namely Swansea University, Universitat Politècnica de Catalunya (Spain), École Centrale de Nantes (France) and University of Stuttgart (Germany) in cooperation with the International Centre for Numerical Methods in Engineering (CIMNE, Spain).

As a student on the Erasmus Mundus MSc Computational Mechanics course, you will gain a general knowledge of the theory of computational mechanics, including the strengths and weaknesses of the approach, appreciate the worth of undertaking a computational simulation in an industrial context, and be provided with training in the development of new software for the improved simulation of current engineering problems.

In the first year of the Erasmus Mundus MSc Computational Mechanics course, you will follow an agreed common set of core modules leading to common examinations in Swansea or Barcelona. In addition, an industrial placement will take place during this year, where you will have the opportunity to be exposed to the use of computational mechanics within an industrial context. For the second year of the Erasmus Mundus MSc Computational Mechanics, you will move to one of the other Universities, depending upon your preferred specialisation, to complete a series of taught modules and the research thesis. There will be a wide choice of specialisation areas (i.e. fluids, structures, aerospace, biomedical) by incorporating modules from the four Universities. This allows you to experience postgraduate education in more than one European institution.

Modules

Modules on the Erasmus Mundus MSc Computational Mechanics course can vary each year but you could expect to study the following core modules (together with elective modules):

Numerical Methods for Partial Differential Equations
Continuum Mechanics
Advanced Fluid Mechanics
Industrial Project
Finite Element Computational Analysis
Entrepreneurship for Engineers
Finite Element in Fluids
Computational Plasticity
Fluid-Structure Interaction
Nonlinear Continuum Mechanics
Computational Fluid Dynamics
Dynamics and Transient Analysis
Reservoir Modelling and Simulation

Accreditation

The Erasmus Mundus Computational 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).

This 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.

See http://www.jbm.org.uk for further information.

This 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

On the Erasmus Mundus MSc Computational Mechanics course, you will have the opportunity to apply your skills and knowledge in computational mechanics in an industrial context.

As a student on the Erasmus Mundus MSc Computational Mechanics course you will be placed in engineering industries, consultancies or research institutions that have an interest and expertise in computational mechanics. Typically, you will be trained by the relevant industry in the use of their in-house or commercial computational mechanics software.

You will also gain knowledge and expertise on the use of the particular range of commercial software used in the industry where you are placed.

Careers

The next decade will experience an explosive growth in the demand for accurate and reliable numerical simulation and optimisation of engineering systems.

Computational mechanics will become even more multidisciplinary than in the past and many technological tools will be, for instance, integrated to explore biological systems and submicron devices. This will have a major impact in our everyday lives.

Employment can be found in a broad range of engineering industries as this course provides the skills for the modelling, formulation, analysis and implementation of simulation tools for advanced engineering problems.



Student Quotes

“I gained immensely from the high quality coursework, extensive research support, confluence of cultures and unforgettable friendship.”

Prabhu Muthuganeisan, MSc Computational Mechanics

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Innovative design allows more interesting and functional architecture but challenges traditional concepts of fire safety. To respond to these demands takes specialist knowledge and advanced skills in engineering analysis. Read more

Programme description

Innovative design allows more interesting and functional architecture but challenges traditional concepts of fire safety. To respond to these demands takes specialist knowledge and advanced skills in engineering analysis.

This programme covers the fundamentals of fire science, including laboratory classes, fire safety engineering and relevant structural engineering topics, such as finite element methods.

You will gain knowledge of the critical issues in structural fire safety engineering, and an understanding of relevant fire and structural behaviours.

You will become familiar with performance-based approaches to design and have an awareness of the capabilities – and limitations – of relevant advanced modelling methods for structures and fire.

This programme is fully accredited by the Joint Board of Moderators (JBM)

Facilities

Our Building Research Establishment (BRE) Centre for Fire Safety Engineering hosts bespoke equipment to support groundbreaking research and teaching, with combined thermal and mechanical loading and use of the latest image analysis techniques.

Programme structure

This programme is run over 12 months, with two semesters of taught courses followed by a research project leading to a masters thesis.

Semester 1 courses
Fire Science and Fire Dynamics
Structural Design for Fire
Finite Element Analysis for Solids
Fire Investigation and Failure Analysis
Thin-Walled Members and Stability
Semester 2 courses
Fire Science Laboratory
Fire Safety Engineering Analysis and Design
The Finite Element Method
Structural Dynamics and Earthquake Engineering

Career opportunities

Internationally, there is great demand for graduates in this field, with expertise in structural fire safety engineering particularly sought after as performance-based design expands. All of our previous graduates are in relevant employment, with the majority working in fire teams at engineering consultancies.

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This MSc programme offers very relevant modules in highly sought-after engineering and scientific subjects. Read more
This MSc programme offers very relevant modules in highly sought-after engineering and scientific subjects. Computational modelling has become an essential part of industrial product development; the manufacturing sector in particular has been experiencing a significant uptake of computational engineering technologies to increase its competitiveness in the global market. This programme is designed for engineering and science graduates, providing a wide exploration of these new and advanced technologies. Problem based learning facilities the application of the modelling techniques.

Subject guide and modules

The range of modules reflects the nature of engineering modelling and the uses it is put to in engineering and commercial practice.
Core modules:
-Computational Fluid Dynamics and Applications (ME4501)
-Practical Numerical Methods (ME4510)
-CAD Principles and Materials Selection (ME4505)
-Advanced Computer Aided Design (ADVCAD) (ME4518)
-Major Project (PD4000)
-Research Project (PD4001)
-Renewable Energy (ME4504)
-Sustainable Design (PD4005)

Elective Modules:
-Solid Mechanics and Finite Element Analysis (ME3070)
-Strategic Finance (EM4001)
-Project Management (EM4003)
-New Product Development (EM4006)
-Innovation Business Development (PD4008)
-Finite Element Analysis: Theory and Application (ME4502)

Learning, teaching & assessment

The modules in this programme are delivered with lectures and lab-based tutorials giving a good balance between scientific methodologies and hands-on practice.

There is a heavy emphasis on the use of computational engineering methods and this is reflected in the way the programme is delivered and assessed.

Modules are assessed through either course work or exams. The major project is assessed by dissertation; examples of past major projects include development of CFD code, aero and structural dynamics of vehicles and aircraft, and analysis of development of industrial machines.

Personal development

Along with the range of technical skills, the Programme aims to develop self reliance, project management, IT communications and research skills.

You will develop and deliver a major dissertation and the necessary project management processes. You will also make several individual presentations and get chance to hone your interview techniques.

Career prospects

Career prospects for graduates are excellent. The programme puts practical engineering modelling, research and project management skills in to the hands of graduate. This helps career progression in industries where computer-based technology is required including manufacturing, R&D, science, IT, design and academia.

Recent graduates have been employed in a range of jobs including:
-Product development with a manufacturer of domestic heating products
-Computer aided design with a manufacturer of military/surveillance equipment

Professional accreditation

The MSc Mechanical Engineering (Modelling) is accredited by the Institution of Mechanical Engineers (IMechE) for the purpose of meeting the educational requirements of Chartered Engineer (CEng).

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Take advantage of one of our 100 Master’s Scholarships to study Computer Modelling in Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study Computer Modelling in Engineering at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

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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To gain this qualification, you need 180 credits as follows. Stage 1. 60 credits from List A. List A. optional modules. Advanced routing - CCNP 1 (T824). Read more

Modules

To gain this qualification, you need 180 credits as follows:

Stage 1

60 credits from List A:

List A: optional modules

• Advanced routing - CCNP 1 (T824)
• Capacities for managing development (T878)
• Conflict and development (T879)
• Development: context and practice (T877)
• Environmental monitoring and protection (T868)
• Finite element analysis: basic principles and applications (T804)
• Institutional development (TU872)
• Making environmental decisions (T891)
• Managing for sustainability (T867)
• Managing systemic change: inquiry, action and interaction (TU812)
• Managing technological innovation (T848)
• Manufacture materials design (T805)
• Multilayer switching - CCNP 3 (T826)
• Network security (T828)
• Optimising networks - CCNP 4 (T827)
• Problem solving and improvement: quality and other approaches (T889)
• Strategic capabilities for technological innovation (T849)
• Thinking strategically: systems tools for managing change (TU811)

Plus 30 credits from List B:

List B: optional modules

• Advanced mathematical methods (M833)
• Advanced routing - CCNP 1 (T824)
• Analytic number theory I (M823)
• Analytic number theory II (M829)
• Applied complex variables (M828)
• Approximation theory (M832)
• Calculus of variations and advanced calculus (M820)
• Capacities for managing development (T878)
• Coding theory (M836)
• Conflict and development (T879)
• Data management (M816)
• Developing research skills in science (S825)
• Development: context and practice (T877)
• Digital forensics (M812)
• Environmental monitoring and protection (T868)
• Finite element analysis: basic principles and applications (T804)
• Fractal geometry (M835)
• Information security (M811)
• Institutional development (TU872)
• Making environmental decisions (T891)
• Managing for sustainability (T867)
• Managing systemic change: inquiry, action and interaction (TU812)
• Managing technological innovation (T848)
• Manufacture materials design (T805)
• Multilayer switching - CCNP 3 (T826)
• Network security (T828)
• Nonlinear ordinary differential equations (M821)
• Optimising networks - CCNP 4 (T827)
• Problem solving and improvement: quality and other approaches (T889)
• Project management (M815)
• Researching mathematics learning (ME825)*
• Software development (M813)
• Software engineering (M814)
• Space science (S818) NEW1
• Strategic capabilities for technological innovation (T849)
• Thinking strategically: systems tools for managing change (TU811)

* 60-credit module of which only 30 credits count towards this qualification

Plus 30 credits from:

Compulsory module

Team engineering (T885)

Stage 2

60 credits from:

Compulsory module

Research project (T802)

The modules quoted in this description are currently available for study. However, as we review the curriculum on a regular basis, the exact selection may change over time.

Credit transfer

Credit transfer is not permitted for the MSc except for any awarded as part of the Postgraduate Diploma in Engineering.
For further advice and guidance, please email us.

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This MSc programme offers you an advanced level of study in specific aspects of mechanical engineering which are in demand from industry. Read more
This MSc programme offers you an advanced level of study in specific aspects of mechanical engineering which are in demand from industry. It is an ideal bridging programme for those graduates seeking to register as a Chartered Engineer with the Institution of Mechanical Engineers.

Course details

You study the core modules in CAD/CAM and Product Development, Finite Element Methods and Machine Design and you select three additional modules from Automotive Engineering and Vehicle Design, Manufacturing Systems, Project Management and Enterprise, Supply Chain Management and Applied Continuum Mechanics.

Professional accreditation

Our MSc Mechanical Engineering is accredited to CEng level by the Institution of Mechanical Engineers 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).

The accredited Masters-level award will provide you with the underpinning knowledge, understanding and skills in preparation for your registration as a 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.

What you study

For the Postgraduate Diploma (PgDip) award you must successfully complete 120 credits of taught modules. For an MSc award you must successfully complete 120 credits of taught modules and a 60-credit master's research project.

Core modules
-CAD/CAM and Product Developments
-Finite Element Methods
-Machine Design
-Practical Health and Safety Skills
-Project Management and Enterprise
-Research and Study Skills

And three optional modules
-Applied Continuum Mechanics
-Automotive Engineering and Vehicle Design
-Manufacturing Systems
-Supply Chain Management

MSc candidates
-Project

Modules offered may vary.

Teaching

You learn through lectures, tutorials and practical sessions. Lectures provide the theoretical underpinning while practical sessions give you the opportunity to put theory into practice, applying your knowledge to specific problems.

Tutorials and seminars provide a context for interactive learning and allow you to explore relevant topics in depth. In addition to the taught sessions, you undertake a substantive MSc research project.

Assessment varies from module to module. The assessment methodology could include in-course assignments, design exercises, technical reports, presentations or formal examinations. For your MSc project you prepare a dissertation.

Employability

Mechanical engineers typically secure employment in structural engineering, research and development, automotive engineering and design, the aerospace industry, manufacturing, processing and chemical industries as well as management positions.

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Develop your knowledge, design and analysis skills, engage with modern challenges in structural engineering and transform your professional profile with this accredited technical MSc in Civil Engineering Structures. Read more
Develop your knowledge, design and analysis skills, engage with modern challenges in structural engineering and transform your professional profile with this accredited technical MSc in Civil Engineering Structures.

Who is it for?

This course is for professional engineers who want to specialise in structural engineering or move into this area of expertise to advance their career. Normally students have an undergraduate degree in engineering or a related discipline. Students who don’t have qualifications in civil engineering usually have relevant work experience in civil engineering structures so they are familiar with working within the specific technical domain.

Objectives

From analysing how carbon nanofibers can reduce the effect of corrosion in concrete to gaining insight from experts developing the new Forth Bridge, this MSc in Civil Engineering Structures has been designed to be broad in scope so you can develop your own area of structural engineering expertise.

As a department, we have broad interests from defining new structural forms to practical application of new materials. We believe civil engineering is a creative and collaborative profession, as much as a technical one. This course gives you the tools to immerse yourself in both the analytical and experimental side of the subject, so you can investigate diverse problems to generate your own structural solutions.

The Civil Engineering Structures MSc mirrors industry practice, so you will work in groups with your peers from the first term onwards and learn from a group of world-leading engineers with diverse research strengths. From earthquake engineering to sustainable construction, you have the opportunity to learn in breadth and depth using high-end industry software to develop safe solutions for real-world projects.

Academic facilities

There is a large dedicated lab on site equipped with facilities to investigate different structures and construction materials from concrete to timber. You also have access to other workshops where you can liaise with mechanical or electrical engineers to develop innovative scale models. There is access to specialist soil labs and large-scale equipment including wind tunnels.

We have an extensive library housing all the references, journals and codes of practice that you will need during your studies.

As part of the University of London you can also become a member of Senate House Library for free with your student ID card.

Teaching and learning

You will be taught by the staff team within the School of Mathematics, Computer Science and Engineering and also from visiting industry experts from around the world.

Teaching mainly takes the form of lectures, but IT sessions and seminars also form part of the Masters degree. Modules are shared between two ten-week teaching terms running from October to December and January to March. Although work for the MSc dissertation starts during the second term, you will conduct most of the research work during the summer months.

The length of the full-time degree is 12 months. A part-time route is also available where you can spend either two or three years completing the programme. If you follow the two-year part-time study route, you will need to attend lectures for up to two days each week. Alternatively, you can complete the degree over three years by attending a single day each week. The timetable has been designed to offer flexibility for part-time students.

In the first term you will consider core technical topics and be introduced to new concepts such as structural reliability. In the second term you will begin to focus your studies by selecting your dissertation topic and by selecting options getting involved in a specific areas of your own interest. Spread over the year you will have design presentations, class tests and reports.

If you select an experimental dissertation you will have the opportunity to use a range of materials. Skilled technical support is available in the workshop and you have access to recently refurbished facilities, including specialist geotechnical labs which accommodate a large flexible laboratory space used for centrifuge model preparation and testing. Adjacent to this you have concrete mixing and casting facilities, a temperature-controlled soil element testing laboratory and a concrete durability laboratory.

Assessment

For the theoretical modules, you will be assessed through a combination of examinations and coursework. Examinations are shared between the January and April/May examination periods. For the design-oriented modules you are normally assessed by coursework only, where you will work both in groups and individually on challenging projects.

Modules

There are six core modules which give you a strong technical foundation and three elective modules from which you can choose two. These reflect the specialist expertise on offer within the academic team. These modules will give you unique insight into computer analysis of structures for blast and fire, bridge engineering, and earthquake analysis where you may look at techniques for analysing structures and safe design. In the final part of the programme you undertake a dissertation in which you can explore an area of interest from a proposed list of themes, some of which are industry-related.

Core modules and dissertation
-Advanced structural analysis and stability (20 credits)
-Finite element methods (15 credits)
-Dynamics of structures (15 credits)
-Structural reliability and risk (10 credits)
-Design of concrete structures (15 credits)
-Design of steel and composite structures (15 credits)
-Dissertation for MSc degree (Research Skills and Individual Project) (60 credits)

Elective modules - you will be able to study two of the following elective modules:
-Earthquake analysis of structures (15 credits)
-Analysis of steel and concrete structures for blast and fire exposure (15 credits)
-Bridge engineering (15 credits)

Career prospects

Graduates have secured employment with leading civil engineering consultants, research institutes and government agencies and pursued doctoral studies both in the UK and internationally. The cohort of 2014 have moved on to jobs and further study working within the following organisations:
-WSP Consultant Engineers
-Tully De'Ath Consultant Civil and Structural Engineers
-SSA Consulting Engineers
-Bradbrook Consulting
-Clarke Nicholls Marcel

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Our MSc Automotive Engineering course will teach you the skills you need to become a skilled engineer, capable of undertaking related tasks within and across different organisations. Read more
Our MSc Automotive Engineering course will teach you the skills you need to become a skilled engineer, capable of undertaking related tasks within and across different organisations.

What's covered in the course?

Our MSc Automotive Engineering course will teach you the skills you need to become a skilled engineer, capable of undertaking related tasks within and across different organisations.

The course will encourage creative thinking and the development of engineering leadership skills, as well as teaching you how to solve problems through research. You’ll engage in independent study, advancing your understanding and developing new skills.

In addition to further academic research opportunities, career prospects are expected to keep pace with the rapid advances in computer aided methods and intelligent technologies, hence, there is expected to be continuing demand for competent, versatile postgraduates who can design and implement innovative solutions for industry.

Why choose us?

-You’ll be introduced to industry-standard, sophisticated computer-based tools, such as mechanism analysis, computational fluid dynamics, finite element analysis and solid modelling, and have the opportunity to apply them to real engineering problems.
-Our accreditation from the Institution of Mechanical Engineers (IMechE) keeps our course fresh and relevant, as well as providing us with key industry contacts and insight.

Course in depth

Knowledge and understanding are acquired though formal lectures, tutor-led seminars and practical activities, and a range of independent learning activities. Emphasis is placed on guided, self-directed and student-centred learning with a progressively increasing independence of approach, thought and process. This independent learning includes an element of peer review in order to evaluate the effectiveness of the learning.

Lectures are used to introduce themes, theories and concepts, which are further explored in seminars. Technology enhanced learning is used, where appropriate, through the provision of online resources, discussion forums and other activities. Analytical and problem-solving skills are further developed using a range of appropriate 'real' and 'theoretical' case studies and problem-based learning scenarios.

You will be supported by a personal tutor based at the University, who will see you for regular one-to-one meetings. These meetings will generally take place at the beginning of each semester and at the end of the academic year.

The course has an emphasis on active and participative education, including practical learning, problem-based learning and group work, which will develop their skills of analysis, synthesis, decision making and the ability to cope with new and unfamiliar problems.

A range of assessment methods are employed with associated assessment criteria. Knowledge and skills are assessed, formatively and summatively, by a number of methods such as coursework, examinations (seen and unseen, open and closed-book), presentations, practical assignments, vivas, online forums, podcasts, and project work.

Modules
-Research Methods 20 credits
-Advanced Dynamics 20 credits
-Advanced Systems Engineering 20 credits
-Control Engineering 20 credits
-Vehicle Control Systems 20 credits
-Advanced Powertrains and Controls 20 credits
-Master’s Project 60 credits

Institution of Mechanical Engineers (IMechE)

The course is accredited by IMechE, ensuring our content remains fresh, relevant and replete with key industry information.

Enhancing your employability skills

This course aims to provide you with an advanced understanding of modern automotive systems and processes, and their application within industry. It will relate to the requirements of new global, environmental infrastructure and economic drivers.

There is high demand throughout the automotive industry for engineers who can demonstrate that they have both a detailed academic knowledge and advanced practical skills. Employers are also keen to employ people who can design and analyse complex systems and components within the automotive engineering environment.

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Running continuously for over 50 years, our Masters in Biomedical Engineering is one of the longest-established in the world, giving a breadth of expertise with a focus on solving real-world, biomedical problems. Read more
Running continuously for over 50 years, our Masters in Biomedical Engineering is one of the longest-established in the world, giving a breadth of expertise with a focus on solving real-world, biomedical problems.

You’ll benefit from access to world-leading experts and teaching in state-of-the-art facilities, such as the new £12m “Engineering for Health” facility.

PROGRAMME OVERVIEW

In the first semester of the programme, graduates from a range of backgrounds are brought up-to-speed on core knowledge in engineering, biology and research practice.

This is followed by specialist modules in the second semester on human movement analysis, prostheses, implants, physiological measurements and rehabilitation, as well as numerous computer methods applied across the discipline.

The course makes use of different approaches to teaching, including traditional lectures and tutorials, off-site visits to museums and hospitals, and lab work (particularly in the Human Movement and Instrumentation modules).

The core lecturing team is supplemented by leading figures from hospitals and industry.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time over two academic years. It consists of eight taught modules and a research project.

All modules are taught on the University main campus, with the exception of visits to the health care industry (e.g. commercial companies and NHS hospitals). The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.
-Human Biology Compulsory
-Instrumentation Compulsory
-Biomechanics Compulsory
-Professional and Research Skills
-Computer Methods in Biomedical Research
-Medical Implants and Biomaterial Applications
-Human Movement and Rehabilitation
-Biomedical Sensors and Signals
-Research Project

EDUCATIONAL AIMS OF THE PROGRAMME

The course aims:
-To educate engineering, physical science, life science, medical and paramedical graduates in the broad base of knowledge required for a Biomedical Engineering career in industry, healthcare or research in the United Kingdom, Europe and the rest of the world
-To underpin the knowledge base with a wide range of practical sessions including laboratory/experimental work and applied visits to expert health care facilities and biomedical engineering industry
-To develop skills in critical review and evaluation of the current approaches in biomedical engineering
-To build on these through an MSc research project in which further experimental, analytical, computational, and/or design skills will be acquired

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

Knowledge and understanding
-Demonstrate breadth and depth of awareness and understanding of issues at the forefront of Biomedical Engineering
-Demonstrate broad knowledge in Human Biology, Instrumentation, Biomechanics, and Professional and Research skills
-Demonstrate specialist knowledge in Implants, Motion analysis and rehabilitation, and Medical signals
-Understand how to apply engineering principles to conceptually challenging (bio)medical problems
-Appreciate the limitations in the current understanding of clinical problems and inherent in adopted solutions
-Understand routes/requirements for personal development in biomedical engineering including state registration
-Understand key elements of the concept of ethics and patient-professional relationships, recognise, analyse and respond to the complex ethical issues

Intellectual / cognitive skills
-Evaluate a wide range of applied engineering and clinical measurement and assessment tools
-Design and implement a personal research project; this includes an ability to accurately assess/report on own/others work with justification and relate them to existing knowledge structures and methodologies, showing insight and understanding of alternative points of view
-Carry out such research in a flexible, effective and productive manner, optimising use of available support, supervisory and equipment resources, demonstrating understanding of the complex underlying issues
-Apply appropriate theory and quantitative methods to analyse problems

Professional practical skills
-Make effective and accurate use of referencing across a range of different types of sources in line with standard conventions
-Use/ apply basic and applied instrumentation hardware and software
-Correctly use anthropometric measurement equipment and interpret results in the clinical context
-Use/apply fundamental statistical analysis tools
-Use advanced movement analysis hardware and software and interpret results in the clinical context
-Use advanced finite element packages and other engineering software for computer simulation
-Program in a high-level programming language and use built-in functions to tackle a range of problems
-Use further specialist skills (laboratory-experimental, analytical, and computational) developed through the personal research project

Key / transferable skills
-Identify, select, plan for, use and evaluate ICT applications and strategies to enhance the achievement of aims and desired outcomes
-Undertake independent review, and research and development projects
-Communicate effectively between engineering, scientific and clinical disciplines
-Prepare relevant, clear project reports and presentations, selecting and adapting the appropriate format and style to convey information, attitudes and ideas to an appropriate standard and in such a way as to enhance understanding and engagement by academic/ professional audiences

GLOBAL OPPORTUNITIES

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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Applied Mathematical Sciences offers a clear and relevant gateway into a successful career in business, education or scientific research. Read more
Applied Mathematical Sciences offers a clear and relevant gateway into a successful career in business, education or scientific research. The programme arms students with the essential knowledge required by all professional mathematicians working across many disciplines. You will learn to communicate their ideas effectively to peers and others, as well as the importance of research, planning and self-motivation.

Students will take a total of 8 courses, 4 in each of the 1st and 2nd Semesters followed by a 3-month Project in the summer. A typical distribution for this programme is as follows:

Core courses

:

Modelling and Tools;
Optimization;
Dynamical Systems;
Applied Mathematics (recommended);
Applied Linear Algebra (recommended).

Optional Courses

:

Mathematical Ecology;
Functional Analysis;
Numerical Analysis of ODEs;
Pure Mathematics;
Statistical Methods;
Stochastic Simulation;
Software Engineering Foundations;
Mathematical Biology and Medicine;
Partial Differential Equations;
Numerical Analysis;
Geometry.

Typical project subjects

:

Pattern Formation of Whole Ecosystems;
Climate Change Impact;
Modelling Invasive Tumour Growth;
Simulation of Granular Flow and Growing Sandpiles;
Finite Element Discretisation of ODEs and PDEs;
Domain Decomposition;
Mathematical Modelling of Crime;
The Geometry of Point Particles;
Can we Trust Eigenvalues on a Computer?

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The University of South Wales Civil & Structural Engineering MSc is a taught postgraduate course offering full-time and part-time pathways. Read more

The University of South Wales Civil & Structural Engineering MSc is a taught postgraduate course offering full-time and part-time pathways.

Students complete a sequence of optional and compulsory modules, plus a final dissertation, before graduating with the 180 credit Master of Science degree.

This degree is your opportunity to establish or consolidate your career as a civil or structural design engineer. The course is accredited for the Further Learning Programme (formerly ‘Matching Sections’) at Chartered Engineer (CEng) level by 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).

There is also an opportunity for working professionals to progress towards CEng status through a tailor-made route. This will help you accelerate to the remaining steps of CEng status by working with your employer in the process. This is a unique feature of a Masters course and significantly reduces the period required to achieve Chartered status.

To provide the latest specialist knowledge and technical competence, all design-related modules are taught in accordance with the new structural Eurocodes. As well as developing your analytical and problem-solving skills, tuition covers project planning and contract management. The course is also underpinned by research into areas such as the use of novel and sustainable environmentally-friendly materials, geotechnics and structural modelling.

See the website http://courses.southwales.ac.uk/courses/577-msc-civil-and-structural-engineering

What you will study

You will study the following modules:

- Advanced Civil Engineering Materials

- Integrative Project Planning and Management

- Geo-environmental Engineering

- Advanced Structural Analysis and Structural Concrete Design

- Further Advanced Structural Analysis and Steel/Composite Design

- Dissertation

Optional modules include:

- Seismic Analysis and Design to Eurocodes*

- Structural Timber and Masonry Design to Eurocodes*

- Further Finite Element Analysis*

- Non-Destructive Testing*

*10 credit module

Learning and teaching methods

The course is delivered in three major blocks that offer an intensive but flexible learning pattern, with two entry opportunities for applicants each year – February and September. You will learn through lectures, tutorials and seminars, as well as guest lectures and seminars with prominent industry experts. You will complete a research project using our excellent laboratory facilities and a dissertation on a chosen topic of interest.

Work Experience and Employment Prospects

On completion of this course, you will be able to develop a career as a structural engineer, technical manager, or research and development manager. These roles can be with leading international consultancies, contractors, national and local consulting companies, as well as international research and government organisations.

Assessment methods

Some modules are assessed through coursework, others by a combination of design projects and a formal examination. If you want to continue working in industry, you can apply to study individual modules as short courses on a day-release or block-delivery basis.

Facilities

The University of South Wales has excellent facilities, and is committed to investment and refurbishment. We’ve just completed a £130m investment programme in new buildings and facilities, including significant investment in the Faculty of Computing, Engineering and Science. The University has also announced a further investment of £28m ensure that you’re using equipment and software that is state-of-the-art and industry-standard, we continually evaluate our labs and teaching spaces and regularly re-fit and re-equip them. A recent refurbishment of a number of our Civil and Mechanical Engineering labs is part of this programme of continuous enhancement of our facilities.

Accreditations

The MSc Civil and Structural Engineering 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) undergraduate first degree*. See http://www.jbm.org.uk for further information.

* It should be noted that candidates completing the MSc who hold an underpinning accredited IEng degree or a non-accredited bachelor degree will need to apply for an academic assessment to determine whether they will meet the educational base for CEng registration.

Applications

Apply directly to the University if you are applying for a part-time, professional or postgraduate course, an Erasmus/Exchange programme, the Legal Practice (part-time) course, to top up your Foundation Degree or HND, or to transfer to USW from another institution.  

Funding

The following postgraduate funding may be available to study the Civil & Structural Engineering MSc at The University of South Wales.

UK postgraduate loans:

Erasmus funding:

Funding from FindAMasters:

Fees

Full Time (UK / EU): £6,000

Full Time (international): £12,600

Part Time (UK /EU): £670 per 20 credit 



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This course provides education and training in selected weapons systems. The course is intended for officers of the armed forces and for scientists and technical officers in government defence establishments and the defence industry. Read more

Course Description

This course provides education and training in selected weapons systems. The course is intended for officers of the armed forces and for scientists and technical officers in government defence establishments and the defence industry. It is particularly suitable for those who, in their subsequent careers, will be involved with the specification, analysis, development, technical management or operation of weapons systems.

The course is accredited by the Institution of Mechanical Engineers and will contribute towards an application for chartered status.

Overview

The Gun System Design MSc is part of the Vehicle and Weapons Engineering Programme. The course is designed to provide an understanding of the technologies used in the design, development, test and evaluation of gun systems.

This course offers the underpinning knowledge and education to enhance the student’s suitability for senior positions within their organisation.

Each individual module is designed and offered as a standalone course which allows an individual to understand the fundamental technology required to efficiently perform the relevant, specific job responsibilities. The course provides students with the depth of knowledge to undertake engineering analysis or the evaluation of relevant sub systems.

Duration: Full-time MSc - one year, Part-time MSc - up to three years, Full-time PgCert - one year, Part-time PgCert - two years, Full-time PgDip - one year, Part-time PgDip - two years

English Language Requirements

If you are an international student you will need to provide evidence that you have achieved a satisfactory test result in an English qualification. The minimum standard expected from a number of accepted courses are as follows:

IELTS - 6.5
TOEFL - 92
Pearson PTE Academic - 65
Cambridge English Scale - 180
Cambridge English: Advanced - C
Cambridge English: Proficiency - C

In addition to these minimum scores you are also expected to achieve a balanced score across all elements of the test. We reserve the right to reject any test score if any one element of the test score is too low.

We can only accept tests taken within two years of your registration date (with the exception of Cambridge English tests which have no expiry date).

Course overview

This MSc course is made up of two essential components, the equivalent of 12 taught modules (including some double modules, typically of a two-week duration), and an individual project.

Modules

MSc and PGDip students take 11 compulsory modules and 1 optional module.
PGCert students take 4 compulsory modules and 2 optional modules.

Core:
- Element Design
- Fundamentals of Ballistics
- Finite Element Methods in Engineering
- Gun System Design
- Light Weapon Design
- Military Vehicle Propulsion and Dynamics
- Modelling, Simulation and Control
- Solid Modelling CAD
- Survivability
- Vehicle Systems Integration

Optional:
- Guided Weapons
- Military Vehicle Dynamics
- Reliability and System Effectiveness
- Uninhabited Military Vehicle Systems

Individual Project

In addition to the taught part of the course, students can opt either to undertake an individual project or participate in a group design project. The aim of the project phase is to enable students to develop expertise in engineering research, design or development. The project phase requires a thesis to be submitted and is worth 80 credit points.

Examples of recent titles are given below.
- Use of Vibration Absorber to help in Vibration
- Validated Model of Unmanned Ground Vehicle Power Usage
- Effect of Ceramic Tile Spacing in Lightweight Armour systems
- Investigation of Suspension System for Main Battle Tank
- An Experimental and Theoretical Investigation into a Pivot Adjustable Suspension System as a Low Cost Method of Adjusting for Payload
- Analysis of Amphibious Operation and Waterjet Propulsions for Infantry Combat Vehicle.
- Design of the Light Weapon System
- Analysis of the Off-road Performance of a Wheeled or Tracked Vehicle

Group Project

- Armoured Fighting Vehicle and Weapon Systems Study
To develop the technical requirements and characteristics of armoured fighting vehicles and weapon systems, and to examine the interactions between the various sub-systems and consequential compromises and trade-offs.

Syllabus/curriculum:
- Application of systems engineering practice to an armoured fighting vehicle and weapon system.
- Practical aspects of system integration.
- Ammunition stowage, handling, replenishment and their effects on crew performance and safety.
- Applications of power, data and video bus technology to next generation armoured fighting vehicles.
- Effects of nuclear, biological and chemical attack on personnel and vehicles, and their survivability.

- Intended learning outcomes
On successful completion of the group project the students should be able to –
- Demonstrate an understanding of the engineering principles involved in matching elements of the vehicle and weapon system together.
- Propose concepts for vehicle and weapon systems, taking into account incomplete and possibly conflicting user requirements.
- Effectively apply Solid Modelling in outlining proposed solutions.
- Interpret relevant legislation and standards and understand their relevance to vehicle and weapon systems.
- Work effectively in a team, communicate and make decisions.
- Report the outcome of a design study orally to a critical audience.

Assessment

Continuous assessment, examinations and thesis (MSc only). Approximately 30% of the assessment is by examination.

Career opportunities

Many previous students have returned to their sponsor organisations to take up senior programme appointments and equivalent research and development roles in this technical area.

For further information

On this course, please visit our course webpage - https://www.cranfield.ac.uk/Courses/Masters/Gun-Systems-Design

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This course provides education and training in military vehicle systems. The course is intended for officers of the armed forces and for scientists and technical officers in government defence establishments and the defence industry. Read more

Course Description

This course provides education and training in military vehicle systems. The course is intended for officers of the armed forces and for scientists and technical officers in government defence establishments and the defence industry. It is particularly suitable for those who, in their subsequent careers, will be involved with the specification, analysis, development, technical management or operation of military vehicles.

It will provide students with the technical knowledge and understanding of weapon systems and military vehicles to make them effective in their specification, design, development and assessment.

The course is accredited by the Institute of Mechanical Engineers and will contribute towards an application for chartered status.

Course overview

This course is made up of two essential components, the equivalent of 12 taught modules (including some double modules, typically of a two week duration).

In addition to the taught part of the course, students undertake an individual project . The aim of the project phase is to enable students to develop expertise in engineering research, design or development. The project phase requires a thesis to be submitted and is worth 80 credit points.

Earning the appropriate credits can lead to the following academic awards:

- Postgraduate Certificate (PgCert) – any combination of modules (building a total of 60 credits).
- Postgraduate Diploma (PgDip) – all modules (120 credits).
- Master of Science (MSc) – all modules (120 credits) plus project (80 credits).

The Military Vehicle Technology MSc is part of the Vehicle and Weapons Engineering Programme. The course is designed to provide an understanding of the technologies used in the design, development, test and evaluation of military vehicle systems. Both armoured and support vehicles are covered within the course.

This course offers the underpinning knowledge and education to enhance the student’s suitability for senior positions within their organisation.

Each individual module is designed and offered as a standalone course which allows an individual to understand the fundamental technology required to efficiently perform the relevant, specific job responsibilities. The course also offers a critical depth to undertake engineering analysis or the evaluation of relevant sub systems.

Individual Project

In addition to the taught part of the course, students undertake an individual project. The aim of the project phase is to enable students to develop expertise in engineering research, design or development. The project phase requires a thesis to be submitted and is worth 80 credit points.

Examples of current titles are given below:

- Use of Vibration Absorber to help in Vibration
- Validated Model of UGV Power Usage
- Effect of Ceramic Tile Spacing in Lightweight Armour systems
- Investigation of Suspension System for Main Battle Tank
- An Experimental and Theoretical Investigation into a Pivot Adjustable Suspension System as a Low Cost Method of Adjusting for Payload
- Analysis of Amphibious Operation and Waterjet Propulsions for Infantry Combat Vehicle.
- Optimisation of the suspension system for a vehicle.
- Analysis of the off-road performance of a wheeled or tracked vehicle.

Modules

Core -

Introductory Studies
Solid Modelling CAD
Finite Element Methods in Engineering
Modelling, Simulation and Control
Weapon System Technology
Survivability
Vehicle Systems Integration
Armoured Fighting Vehicle and Weapon Systems Study
Military Vehicle Dynamics
Military Vehicle Propulsion

Optional -

Fundamentals of Ballistics
Military Vehicle Propulsion and Dynamics
Gun System Design
Element Design
Guided Weapons
Uninhabited Military Vehicle Systems
Reliability and System Effectiveness
Light Weapon Design
Rocket Motors and Propellants

Assessment

Continuous assessment, examinations and thesis (MSc only). Approximately 30% of the assessment is by examination.

Funding

For more information on funding please contact

Career opportunities

Many previous students have returned to their sponsor organisations to take-up senior programme appointments and equivalent research and development roles in this technical area.

Further Information

For further information on this course, please visit our course webpage - http://www.cranfield.ac.uk/courses/masters/military-vehicle-technology.html

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This course is aimed at graduates with an honours degree or relevant professional experience who want to develop their understanding and skills as structural engineers. Read more
This course is aimed at graduates with an honours degree or relevant professional experience who want to develop their understanding and skills as structural engineers.

Key benefits:

• The emphasis is on current methodology and practice
• You will be well equipped to meet the challenges of the modern structural engineering industry
• Meets the requirements for Further Learning for a Chartered Engineer (CEng)

Visit the website: http://www.salford.ac.uk/pgt-courses/structural-engineering

Suitable for

Suitable for engineering graduates who want to specialise in structural engineering.

You may be working in industry and want to formalise your training or you may be a recent graduate and wish to gain extra qualifications to help you stand out in the jobs market or enter your engineering career at a higher level.

Programme details

The course meets 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 Eng (Full) BEng/BSc (Hons) undergraduate first degree. See http://www.jbm.org.uk for further information.

Format

The course is delivered via a combination of lectures, tutorials, design projects, computing sessions and laboratory demonstrations. You will be encouraged to attend meetings of the professional institutions, where relevant topics are being discussed. Where possible, pertinent site visits and guest lectures will be organised.

Semester 1

• Introduction to Design with Computer Applications (30 credits)
• Seismic Engineering and Practical Applications of Finite Element Analysis (30 credits)

Semester 2

• Further Design with Applications to Building Structures (30 credits)
• Bridge Engineering (30 credits)
• MSc Dissertation (60 credits)

Assessment

Coursework 42%, Examination 47% and Dissertation 11%.

Career Prospects

Graduates of this course will be well equipped to meet the challenges of the modern structural engineering industry. They may occupy pivotal appointments in prestigious building schemes and the prospect of a challenging career to provide and protect the infrastructure that underpins society.

Graduates might typically work as a structural engineer in a design office or for an engineering consultancy.

How to apply: http://www.salford.ac.uk/study/postgraduate/applying

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