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Masters Degrees (Aerospace Engineer)

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Take advantage of one of our 100 Master’s Scholarships to study Aerospace 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 Aerospace 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.

Aerospace Engineering at Swansea University has a distinguished history of working with aerospace companies around the world. As a student on the MSc Aerospace Engineering, you will be provided with a systematic understanding of the advanced knowledge, critical awareness and new insights required by effective practising aerospace engineers.

The MSc Aerospace Engineering degree is based on the world-class expertise available in the Materials Engineering Centre and the Zienkiewicz Centre for Computational Engineering.

At Swansea, world-class aerospace research drives excellent teaching within a cutting-edge learning environment with state-of-the-art facilities. The MSc Aerospace Engineering course prepares you for the design, analysis, testing and flight of the full range of aeronautical vehicles, including propeller-driven and jet-powered planes, helicopters and gliders.

Students on the Aerospace Engineering course will gain hands-on experience through access to one of the world’s most advanced engineering flight simulators housed within the College of Engineering. The MSc Aerospace Engineering course at Swansea University is accredited by the Institution of Mechanical Engineers (IMechE), the Royal Aeronautical Society (RAeS), and the Institution of Engineering Designers (IED).

Modules on the Aerospace Engineering course typically include:

Finite Element Computational Analysis
Composite Materials
Flight Dynamics and Control
Advanced Airframe Structure
Advanced Aerodynamics
Numerical Methods for Partial Differential Equations
Aerospace Materials Engineering
Group Project
Research Dissertation
MSc Dissertation - Aerospace Engineering

Student Quotes

“After passing all the modules on the MSc Aerospace Engineering course, I had the possibility to develop my final thesis in an industrial environment. I learnt about avionics and electronic equipment and developed team work and communication skills.

My favourite memory of the MSc Aerospace Engineering course is our team winning the International Aircraft Design and Handling competition. Our effort really paid off when we won the first prize!

Before starting my final thesis, I found a job as an Applications Engineer in one of the most important aerospace engineering companies, MTorres. Personally, I think obtaining a Master’s degree in a university with a great reputation such as Swansea University makes it much easier to find a job.

Swansea University provides a fantastic opportunity to study any field of engineering due to the professional and friendly staff.”

Roberto Morujo, MSc Aerospace Engineering

Links with Industry

Aerospace Engineering at Swansea University has a distinguished history of working with aerospace companies around the world, including:

BAE Systems
Rolls Royce
EADS
Airbus

We have also contributed to many exciting projects, from the super-jet Airbus A380 to the 1,000mph land-speed record breaking BLOODHOUND SSC.

Careers

The MSc Aerospace Engineering course is suitable for those who would like to gain comprehensive knowledge, understanding and skills that will enable them to contribute to the creation and maintenance of aerospace and aeronautical equipment.

The MSc Aerospace Engineering course covers the necessary aspects for a successful career in the growing aerospace industry.

Facilities

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

Aerospace Engineering at Swansea University has a wide range of in-house facilities ranging from computer labs housing state-of-the-art PCs through to specialist equipment used almost exclusively by aerospace students.

Practical flying experience on the MSc Aerospace Engineering course is gained from the state-of-the-art Merlin MP521X engineering flight simulator mounted on a six axis hydraulic motion system and flying experience at a local airport.

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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Aerospace systems are the future of the aerospace industry and constitute the major component of all modern aircraft. They are the essential onboard systems that ensure the safe and accurate operation of all aerospace vehicles, from civil passenger planes to sophisticated unmanned aerial vehicles. Read more
Aerospace systems are the future of the aerospace industry and constitute the major component of all modern aircraft. They are the essential onboard systems that ensure the safe and accurate operation of all aerospace vehicles, from civil passenger planes to sophisticated unmanned aerial vehicles.

Why this programme

◾The University of Glasgow has been the home of Aerospace Research for over 60 years. This long-standing activity has culminated in the Division of Aerospace Sciences having internationally recognised expertise in all areas of Aeronautics and Aerospace Systems.
◾The University of Glasgow is one of the few institutions in the UK, and the only University in Scotland, to offer an Aerospace Systems MSc.
◾Aeronautical engineering at the University of Glasgow is consistently highly ranked recently achieving 10th in the UK and 1st in Scotland (Complete University Guide 2017).
◾If you are an aeronautical engineering or avionics graduate wanting to improve your skills and knowledge; a graduate of another engineering discipline, mathematics or physics and you want to change field; looking for a well-rounded postgraduate qualification in electronics & electrical engineering to enhance your career prospects; this programme is designed for you.
◾Students in this programme can benefit from access to our outstanding facilities: including several wind tunnels, a flight simulation lab, an autonomous unmanned vehicle (UAV) laboratory, helicopter test rig laboratories and computer labs for modelling and simulation.

Programme structure

Modes of delivery of the MSc in Aerospace Systems include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

The summer period is dedicated to project work, with either academic or industrial placements providing the context for your project.

Semester 1 core courses
◾Aircraft flight dynamics
◾Control M
◾Navigation systems
◾Simulation of aerospace systems
◾Space flight dynamics 1.

Semester 2 core courses
◾Autonomous vehicle guidance systems
◾Fault detection, isolation and reconfiguration
◾Radar and electro-optic systems
◾Robust control 5.
◾Aerospace systems team design project.

Projects

◾To complete the MSc degree you must undertake a project worth 60 credits.
◾The project will integrate subject knowledge and skills that you acquire during the MSc programme
◾The project is an important part of your MSc where you can apply your newly learned skills and show to future employers that you have been working on cutting edge projects relevant to the industry.
◾You can choose a topic from a list of MSc projects in Aerospace Systems. Alternatively, should you have your own idea for a project, department members are always open to discussion of topics

Example projects

Examples of projects can be found online

*Posters shown are for illustrative purposes

Accreditation

MSc Aerospace Systems is accredited by the Royal Aeronautical Society (RAeS)

Industry links and employability

◾You will be introduced to this exciting multi-disciplinary area of technology, gaining expertise in autonomous guidance and navigation, advanced aerospace control, simulation and simulators, fault detection and isolation, electro-optic and radar systems, and space systems.
◾The School of Engineering has extensive contacts with industrial partners who contribute to several of their taught courses, through active teaching, advising on projects, curriculum development, and panel discussion.
◾During the programme students have an opportunity to develop and practice relevant professional and transferrable skills, and to meet and learn from employers about working in the aerospace industry.

Career prospects

Career opportunities include aerospace, defence, laser targeting systems, radar development, electro-optics, autonomous systems and systems modelling.

Graduates of this programme have gone on to positions such as:
Software Engineer at Hewlett-Packard
Avionic and Mission System Engineer at Qinetiq
Engineering Corporal & Driver at Hellenic Army.

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The School of Mechanical, Aerospace and Civil Engineering has a strong and unique tradition in the UK in Aerospace Design, Helicopters, Heat Transfer, Aerodynamics, Computational Fluid Dynamics and Flow Diagnostics. Read more
The School of Mechanical, Aerospace and Civil Engineering has a strong and unique tradition in the UK in Aerospace Design, Helicopters, Heat Transfer, Aerodynamics, Computational Fluid Dynamics and Flow Diagnostics. This course builds on those strengths and exploits our links with BAe Systems, Airbus, Rolls-Royce, DSTL, USAF, North West Aerospace Alliance, North West Development Agency and SBAC.

This MSc aims to produce high quality graduates with specialist training in aerospace engineering who will be suitable for employment in the engineering industries and consultancies linked to that industry. Aerospace engineering graduates are highly valued and are currently in great demand and the Manchester programme specifically seeks to serve this growing industry requirement. The programme is suitable for engineering and science graduates, as well as engineering professionals working in technical and commercial management. The programme is also well designed to be used for conversion to Aerospace Engineering from some close enough specialities such as Mechanics, Mathematics and Physics.

Teaching and learning

The Aerospace Engineering MSc is a full time course which is studied over 12 months and there is one start date each year in September. You will develop advanced technical skills in Aerospace Engineering that will enable you to pursue a career in both general and specialised engineering industries or develop an in depth knowledge for a career in research in industry or academia.

Career opportunities

The Aerospace Engineering MSc has a strong focus on employability to support you to take control of your future and give yourself the best chance of securing your ideal job after graduation.

Each year Manchester careers fairs, workshops and presentations attract more than 600 exhibitors and 20,000 visitors to target Manchester graduates.

After graduating with an Aerospace Engineering MSc you will be in a strong position to seek employment with companies such as: Airbus, Rolls Royce, GE Aviation, Airbus, Bombardier Transportation, BAe Systems, MBDA, SAFRAN, GKN Aerospace, Spirit, Finmeccanica, EDF, BP, Schlumberger, etc.

The UK Aerospace Engineering is 2nd largest in the world and around 30% of companies in the Aerospace sector currently have vacancies.

Destination of Leavers Survey
Past graduates have found employment in:
-Airframe manufacturers
-Gas turbine and aircraft systems industries
-Defence laboratories
-Consultancy and management
-Postgraduate research

Accrediting organisations

Two highly established organisations, the Royal Aeronautical Society and Institution of Mechanical Engineers , have accredited the Aerospace Engineering MSc course under license from the UK regulator, the Engineering Council . This allows satisfactory completion of the Aerospace Engineering MSc to contribute towards the academic requirements for registration with these Institutions as a Chartered Engineer.

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The MSc Aerospace is accredited by the Royal Aeronautical Society (RAeS) and the Institution of Mechanical Engineers (IMechE). It's aimed at Engineers looking to increase their professional skills and capabilities in the industry through a strategic understanding of major technical, business and environmental factors. Read more
The MSc Aerospace is accredited by the Royal Aeronautical Society (RAeS) and the Institution of Mechanical Engineers (IMechE). It's aimed at Engineers looking to increase their professional skills and capabilities in the industry through a strategic understanding of major technical, business and environmental factors. It's designed to help develop and broaden technical and business skills in the industry. It is also aimed at enhancing the industry's competitiveness and creating, developing and implementing flexible and innovative research and development opportunities.

Key benefits

The range of optional modules, and flexibility of formats and learning, make this course unique. You can also apply for the Government funded Aerospace MSc Bursary Scheme, created in partnership with employers, to study it.

This course is affiliated to, and accredited by, the Royal Aeronautical Society (RAeS), and has been developed further in conjunction with other awards in the ECCDF.

Course detail

Students on the course come are either full time students completing the award in one year, or industrially based students that from a wide range of different companies within the sector, including primes and throughout the supply chain. This mix of people from different backgrounds, companies and with different roles adds a unique perspective of peer learning, as you network and learn from each other.

However you approach the course, we're here to help support your long-term career professional development, including helping you develop a 'portfolio of evidence' to support your application to become a Chartered Engineer.

Modules

Full-time students will study the following modules:

• Advanced Manufacturing
• Airworthiness
• Aerospace Design Process
• Aerospace Business Context and Environment
• Lean Engineering
• Professional Development Appraisal and Review
• Aircraft Structural Design and Stress Analysis
• Foundations of Systems Engineering
• Dissertation

For students studying on a flexible basis, whilst there is flexibility to your studies, the course has four core modules:

• Professional Development Appraisal and Continuous Review
• Advanced Manufacture
• Aerospace Design Process
• Airworthiness

Structure

The full Master's course comprises 180 credits divided into three 60 credits stages: Postgraduate Certificate, Postgraduate Diploma, and Masters. Students work incrementally through the three stages and must pass all modules at each stage in order to progress to the next.

Format

We usually hold taught modules over three to five consecutive days. In some cases we use other teaching methods, including distance and work-based learning. You'll organise your work-based learning with your module leader, this ensures it's tailored to your needs and the learning outcomes are achievable.

Assessment

Assessment is normally by assignment. At this level, we do not need to test your understanding, but rather your ability to implement your newfound skills and knowledge. Assignments will normally be about a real industrial case study, or a live project in your workplace.

Careers / Further study

The MSc Aerospace is excellent for developing technical and business knowledge and skills for the Aerospace sector. The breadth of optional learning allows you to steer your own academic progress, develop personal career objectives and show competencies required for professional recognition.

This makes the course ideal for engineers who want to mix technical and business learning with one customisable course. Successful graduates are suited to work across a range of roles.

How to apply

Information on applications can be found at the following link: http://www1.uwe.ac.uk/study/applyingtouwebristol/postgraduateapplications.aspx

Funding

- New Postgraduate Master's loans for 2016/17 academic year –

The government are introducing a master’s loan scheme, whereby master’s students under 60 can access a loan of up to £10,000 as a contribution towards the cost of their study. This is part of the government’s long-term commitment to enhance support for postgraduate study.

Scholarships and other sources of funding are also available.

More information can be found here: http://www1.uwe.ac.uk/students/feesandfunding/fundingandscholarships/postgraduatefunding.aspx

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Modern aircraft are a complex combination of aerodynamic performance, lightweight durable structures and advanced systems engineering. Read more
Modern aircraft are a complex combination of aerodynamic performance, lightweight durable structures and advanced systems engineering. Air passengers demand more comfort and more environmentally friendly aircraft. Hence many technical challenges need to be balanced for an aircraft to economically achieve its design specification. This course trains engineers to meet these challenges, and prepares them for careers in civil and military aviation.

Aircraft Design is an option for the MSc Aerospace Vehicle Design. Aircraft Design aims to provide a comprehensive overview of aircraft performance, structures and systems. A holistic teaching approach is taken to explore how the individual elements of an aircraft can be designed and integrated using up-to-date methods and techniques. You will learn to understand how to select specific systems such as fuel systems, and their effect on the aircraft as a whole.

This course is suitable for students with a background in aeronautical or mechanical engineering or those with relevant industrial experience, and prepares graduates for careers as project design engineers, systems design, structural design or avionic engineers in aerospace or related industries, with the aim of progressing to technical management/chief engineer.

Course overview

The Aircraft Design option consists of a taught component, a group design project and an individual research project.

In addition to management, communication, team work and research skills, each student will attain at least the following outcomes from this degree course:

To build upon knowledge to enable students to enter a wide range of aerospace and related activities concerned with the design of flying vehicles such as aircraft, missiles, airships and spacecraft.
To ensure that the student is of immediate use to their employer and has sufficient breadth of understanding of multi-discipline design to position them for accelerated career progression.
To provide teaching that integrates the range of disciplines required by modern aircraft design.
To provide the opportunity for students to be immersed in a 'Virtual Industrial Environment' giving them hands-on experience of interacting with and working on an aircraft design project.

Group project

The extensive group design project is a distinctive and unique feature of this course. This teamwork project takes place from October to March, and recreates a virtual industrial environment bringing together students with various experience levels and different nationalities into one integrated design team.

Each team member is given responsibility for the detailed design of a significant part of the aircraft, for example, forward fuselage, fuel system, or navigation system. The project will progress from the conceptual phase through to the preliminary and detail design phases. You will be required to run project meetings, produce engineering drawings and detailed analyses of your design. Problem solving and project coordination must be undertaken on a team and individual basis. At the end of the project, groups are required to report and present findings to a panel of 200 senior engineers from industry.

This element of the course is both realistic and engaging, and places the student group in a professional role as aerospace design engineers. Students testify that working as an integrated team on real problems is invaluable and prepares them well for careers in a highly competitive industry.

Watch past presentation videos to give you a taster of our innovative and exciting group projects (YouTube)

Blended Wing Body Aircraft
A9 Dragonfly Box Wing Aircraft
MRT7 Tanker Aircraft
A-13 Voyager
SL-12 Vimana

Individual Project

The individual research project aims to provide the training necessary for you to apply knowledge from the taught element to research, and takes place from March to September. The project may be theoretical and/or experimental and drawn from a range of topics related to the course and suggested by teaching staff, your employer or focused on your own area of interest.

Recent Individual Research Projects include:

Ultra Long Range Science UAV Structure / Systems Development
Conceptual Design of a Hypersonic Space Launcher and Global Transportation System
Effect of Aerodynamics on the Conceptual Design of Blended Wing Body Aircraft
Review, Evaluation and Development of a Microlight Aircraft
Feasibility of the Application of Low Cost Scaled Aircraft Demonstrators.

Assessment

The taught modules (10%) are assessed by an examination and/or assignment. The Group Project (50%) is assessed by a written technical report and oral presentations. The Individual Research Project (40%) forms the remainder of the course.

Career opportunities

The MSc in Aircraft Design is valued and respected by employers worldwide. The applied nature of this course ensures that our graduates are ready to be of immediate use to their future employer and has provided sufficient breadth of understanding of multi-discipline design to position them for accelerated career progression.

This course prepares graduates for careers as project design engineers, systems design, structural design or avionic engineers in aerospace or related industries, with the aim of progressing to technical management/chief engineer. Graduates from the MSc in Aircraft Design can therefore look forward to a varied choice of challenging career opportunities in the above disciplines.

Many of our graduates occupy very senior positions in their organisations, making valuable contributions to the international aerospace industry. Typical student destinations include BAE Systems, Airbus, Dassault and Rolls-Royce.

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A fantastic time to be a specialist in aerospace materials, Sheffield is in the heartland of the UK aerospace industry, meaning many international aerospace companies look to the Department to discover ways to improve both materials and processes for use in their products. Read more

About the course

A fantastic time to be a specialist in aerospace materials, Sheffield is in the heartland of the UK aerospace industry, meaning many international aerospace companies look to the Department to discover ways to improve both materials and processes for use in their products.

You’ll develop knowledge of the manufacturing, processing and properties of the metals and composite materials used in airframes and aeroengines. You’ll also be trained in the fundamentals of thermodynamics, structure and mechanical behaviour.

A welcoming department

A friendly, forward-thinking community, our students and staff are on hand to welcome you to the department and ensure you settle into student life.

Your project supervisor will support you throughout your course. Plus you’ll have access to our extensive network of alumni, offering industry insight and valuable career advice to support your own career pathway.

Your career

Prospective employers recognise the value of our courses, and know that our students can apply their knowledge to industry. Our graduates work for organisations including Airbus, Rolls-Royce, the National Nuclear Laboratory and Saint-Gobain. Roles include materials development engineer, reactor engineer and research manager. They also work in academia in the UK and abroad.

90 per cent of our graduates are employed or in further study 6 months after graduating, with an average starting salary of £27,000, the highest being £50,000.

Equipment and facilities

We have invested in extensive, world-class equipment and facilities to provide a stimulating learning environment. Our laboratories are equipped to a high standard, with specialist facilities for each area of research.

Materials processing

Tools and production facilities for materials processing, fabrication and testing, including wet chemical processing for ceramics and polymers, rapid solidification and water atomisation for nanoscale metallic materials, and extensive facilities for deposition of functional and structural coatings.

Radioactive nuclear waste and disposal

Our £3million advanced nuclear materials research facility provides a high-quality environment for research on radioactive waste and disposal. Our unique thermomechanical compression and arbitrary strain path equipment is used for simulation of hot deformation.

Characterisation

You’ll have access to newly refurbished array of microscopy and analysis equipment, x-ray facilities, and surface analysis techniques covering state-of-the-art XPS and SIMS. There are also laboratories for cell and tissue culture, and facilities for measuring electrical, magnetic and mechanical properties.

The Kroto Research Institute and the Nanoscience and Technology Centre enhance our capabilities in materials fabrication and characterisation, and we have a computer cluster for modelling from the atomistic through nano and mesoscopic to the macroscopic.

Stimulating learning environment

An interdisciplinary research-led department; our network of world leading academics at the cutting edge of their research inform our courses providing a stimulating, dynamic environment in which to study.

Teaching and assessment

Working alongside students and staff from across the globe, you’ll tackle real-world projects, and attend lectures, seminars and laboratory classes delivered by academic and industry experts.

You’ll be assessed by formal examinations, coursework assignments and a dissertation.

Core modules

Aerospace Metals; Design and Manufacture of Composites; Science of Materials; Materials Processing and Characterisation; Materials Selection, Properties and Applications; Technical Skills Development; Heat and Materials with Application; Advanced Materials Manufacturing; Deformation, Fracture and Fatigue; Research project in an area of your choice.

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Today’s military aviation platforms are complex systems and it is essential, therefore, that they are deployed and maintained in such a way as to ensure their continued airworthiness and the safety of the crew operating them. Read more

Course Description

Today’s military aviation platforms are complex systems and it is essential, therefore, that they are deployed and maintained in such a way as to ensure their continued airworthiness and the safety of the crew operating them. To achieve this requires engineers to be cognisant of a broad range of aerospace engineering, airworthiness and safety disciplines.

The MSc in Military Aerospace and Airworthiness has been designed to address these needs by providing a course aimed specifically at employees in the MoD, the Armed Forces and the international defence industry. It provides practicing engineers with the knowledge and skills to enable them to work more effectively in aerospace engineering, airworthiness, and safety. The course structure allows students to continue in full-time employment whilst they are studying.

Cranfield University has been at the forefront of postgraduate education in aeronautics and engineering for over 60 years, so you can be sure that your qualification will be valued and respected by employers.

Overview

The MSc distinguishes itself from similar courses offered by leading UK Universities by offering one focussed specifically on the Military context and offers unique subject areas unavailable elsewhere. You will be taught by staff, primarily from Cranfield Defence and Security at Shrivenham, and the School of Engineering at Cranfield, Bedfordshire, many of them world leaders in their field. Visiting lecturers include experts from industry, research establishments, and the MoD. The course draws students from the UK and Western Europe giving an eclectic mix to the classroom environment. Maximum number of places: 25 per year.

Course overview

The course is delivered on a part-time basis. It contains five compulsory modules:
- Airworthiness of Military Aircraft
- Aviation Safety Management
- Fixed-Wing Aeromechanics
- Propulsion Systems
- Safety Assessment of Aircraft Systems

which together provide an overarching introduction to the subject of military aerospace and airworthiness and impart the essential knowledge required by all students on the course.

Students choose one further module to complete the PgCert or a further seven modules to complete the PgDip (MSc taught phase). This provides students with the flexibility to tailor their studies to account for prior educational and work experience and the current and future needs of their employment role.

The modules taken in the taught phase of the MSc (the PgDip) provide students with the knowledge and skills necessary to complete a research-based project, which forms the final part of the Masters award.

Modules

Core:
- Study Skills (non-assessed)
- Airworthiness of Military Aircraft
- Aviation Safety Management
- Fixed-Wing Aeromechanics
- Fundamentals of Aeronautical Engineering Top-up (FAE qualified students only)
- Propulsion Systems
- Safety Assessment of Aircraft Systems
- Research Project (MSc only)

Elective:
- Aircraft Accident Investigation and Response
- Aircraft Fatigue and Damage Tolerance
- Aircraft Survivability
- Air Transport Engineering - Maintenance Operations
- Design Durability and Integrity of Composite Aircraft Structures
- Fundamentals of Aircraft Engine Control
- Guided Weapons
- Human Factors in Aircraft Maintenance
- Introduction to Aircraft Structural Crashworthiness
- Introduction to Human Factors
- Mechanical Integrity of Gas Turbines
- Military Aircraft Systems
- Military Avionics -STA Communications and Navigation
- Practical Reliability
- Rotary-Wing Aeromechanics

Individual Project

The individual research project would focus on a topical subject area covered by the taught phase of the course. The subject of the project can be chosen to match the research needs of the sponsor and/or the interests of the individual student and students are encouraged to utilise their employment resources to place the project in context. Lecturing staff on both campuses will undertake supervision of research projects.

Assessment

Specific assessment details will be dependent upon the modules chosen but will include closed-book written examinations, individual and group design exercises, technical essays, engineering calculations, computer-based assessment.
In addition, for MSc students, the assessment includes lectures and tutorials relating to research, methodologies, project planning, research ethics, plagiarism and technical writing skills, one-to-one discussion with a nominated
academic supervisor, examination of a written dissertation and viva voce examination.

Career opportunities

The course creates opportunities to develop your career at a more senior level and in achieving Incorporated or Chartered Engineer status.

For further information

On this course, please visit our course webpage http://www.cranfield.ac.uk/courses/masters/military-aerospace-and-airworthiness.html

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This is an integrated degree programme that brings together the key generic skills of management and research methods with specific modules focusing on aerodynamics and flight mechanics. Read more
This is an integrated degree programme that brings together the key generic skills of management and research methods with specific modules focusing on aerodynamics and flight mechanics. This approach will help you to develop your critical thinking skills as a future engineering manager, or technical specialist enabling you effectively to analyse technical and or management issues. The programme aims to:
-Equip you with the theory and the practice of relevant subjects, technologies and analytical tools to provide solutions for aerospace and related manufacturing problems
-Provide a blend of knowledge and application experience through case studies and project work
-Focus on the links between analysis and design and the supporting skills of management
-Provide education and experience which enhances prospects of professional employment within the industry

Why choose this course?

-The School has over 50 years' experience of teaching aerospace, and has established an excellent international reputation in this field
-We offer extensive lab facilities for aerospace engineering students, including a flight simulator, the latest software packages and windtunnels
-This MSc combines analysis and design with management skills to produce highly-employable postgraduates.

Professional Accreditations

Accredited for Chartered Engineer (CEng) status by the Institution of Engineering and Technology (IET) and by the Royal Aeronautical Society (RAeS).

Careers

This programme will help you to develop your critical thinking skills as a future engineering manager or technical specialist as it will enable you to effectively analyse technical and management issues. This blend of technical and managerial content is invaluable in job applications as well as helping to fast-track your career in the industry.

Teaching methods

The School has a reputation for innovation in teaching and learning, where nearly all MSc modules are delivered through a combination of traditional face-to-face teaching and backup tutorial's using the University's StudyNet web based facility. StudyNet allows students to access electronic teaching and learning resources, and conduct electronic discussion's with staff and other students. A heavy emphasis is placed on theory and practice, and the School has a policy of using industrial standard software wherever possible. The School also operate an open access laboratory, and computer policy, that will help students complete coursework and assignments, at a scheduled pace and on time.

Structure

Core Modules
-Aeroelasticity
-CFD Analysis for Aerospace Applications
-CFD Techniques
-Control of Engineering Systems
-FEA & Applications
-Flight Mechanics
-MSc Project
-Operations Management
-Operations Research

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With increasing traffic density of civil aircraft, and the need for increased military precision in conflicts around the world, safer aircraft operations require more sophisticated avionic systems. Read more
With increasing traffic density of civil aircraft, and the need for increased military precision in conflicts around the world, safer aircraft operations require more sophisticated avionic systems.

This specialist option of the MSc Aerospace Vehicle Design (http://www.cranfield.ac.uk/courses/taught/aerospace-vehicle-design) provides you with an understanding of avionic systems design, analysis, development, test and airframe integration.

Who is it for?

This course is suitable for students with a background in aeronautical or mechanical engineering or those with relevant industrial experience. It provides a taught engineering programme with a focus on the technical, business and management aspects of aircraft design in the civil and military aerospace sectors.

Why this course?

The Avionic Systems Design option aims to provide an understanding of avionic systems design, analysis, development, test and airframe integration. This includes a detailed look at robust and fault-tolerant flight control, advanced 4D flight management and RNP navigation, self-separation and collision avoidance and advanced digital data communications systems, as well as pilot-friendly and intelligent cockpit displays and situation awareness.

We have been at the forefront of postgraduate education in aerospace engineering since 1946. Aerospace Vehicle Design at Cranfield University was one of the original foundation courses of the College of Aeronautics. Graduates of this course are eligible to join the Cranfield College of Aeronautics Alumni Association (CCAAA), an active community which hold a number of networking and social events throughout the year.

Cranfield University is well located for students from all over the world, and offers a range of library and support facilities to support your studies. This enables students from all over the world to complete this qualification whilst balancing work/life commitments.

Informed by Industry

The course has an Industrial Advisory Committee with senior members from major UK aerospace companies, government bodies, and the military services. The committee meets twice a year to review and advise on course content, acquisition skills and other attributes are desirable from graduates of the course. Panel members include:

- BAE Systems
- Airbus
- Royal Air Force
- Department for Business, Enterprise and Regulatory Reform
- Royal Australian Air Force
- Messier-Dowty
- Department of National Defence and the Canadian Armed Forces.

We also arrange visits to sites such as BAE Systems, Thales, GKN and RAF bases which specialise in the maintenance of military aircraft. This allows you to get up close to the aircraft and components to help with ideas for the group project

Accreditation

Royal Aeronautical Society (RAeS) - http://aerosociety.com/
Institution of Mechanical Engineers (IMechE) - http://www.imeche.org/

Course details

This option is comprised of 14 compulsory modules and a minimum of 60 hours of optional modules, selected from a list of 10 options. You are also required to complete a group design project and an individual research project. Delivered via a combination of structured lectures, industry guest lectures, computer based workshops and private study.

A unique feature of the course is that we have four external examiners; two from industry who assess the group design project and two from academia who assess the individual research project.

Group project

The extensive group design project is a distinctive and unique feature of this course. This teamwork project takes place over six months, usually between October and March; and recreates a virtual industrial environment bringing together students with various experience levels and different nationalities into one integrated design team.

You will be given responsibility for the detailed design of a significant part of the aircraft, for example, forward fuselage, fuel system, or navigation system. The project will progress from the conceptual phase through to the preliminary and detail design phases. You are required to run project meetings, produce engineering drawings and detailed analyses of their design. Problem solving and project coordination must be undertaken on a team and individual basis. At the end of the project, groups are required to report and present findings to a panel of 200 senior engineers from industry.

This element of the course is both real and engaging, and places the student group in a professional role as aerospace design engineers. Students testify that working as an integrated team on real problems is invaluable and prepares them well for careers in a highly competitive industry.

Watch past presentation YouTube videos to give you a taster of our innovative and exciting group projects:

- Blended Wing Body Aircraft - https://www.youtube.com/watch?v=UfD0CIAscOI
- A9 Dragonfly Box Wing Aircraft - https://www.youtube.com/watch?v=C4LQzXBJInw
- MRT7 Tanker Aircraft - https://www.youtube.com/watch?v=bNfQM2ELXvg
- A-13 Voyager - https://www.youtube.com/watch?v=LS6Wq7lpmDw
- SL-12 Vimana - https://www.youtube.com/watch?v=HjEEazsVtSc

Individual project

The individual research project aims to provide the training necessary for you to apply knowledge from the taught element to research, and takes place over six months. The project may be theoretical and/or experimental and drawn from a range of topics related to the course and suggested by teaching staff, your employer or focused on your own area of interest.

Recent Individual Research Projects include:

• Analysis and Design of Stability and Flight Control System of Unconventional Aircraft/ Rotorcraft
• Advanced Control System Design of VTOL Aircraft in Hybrid Flight Mode During Take-off and Landing
• Analysis of Airframe Noise of Hybrid-Wing-Body-Type Aircraft in the Terminal Area
• Simulation of Optimised TMA Manoeuvring, Stand Instrument Departure (SID) and Standard Arrival (STAR) under CNS/ATM Constraints
• Design of Autopilot Flight Control Systems of Unconventional Aircraft/ Rotorcraft.

Assessment

Taught modules 10%, Group project 50%, Individual research project 40%

Your career

The Avionic Systems Design option is valued and respected by employers worldwide. The applied nature of this course ensures that our graduates are ready to be of immediate use to their future employer and has provided sufficient breadth of understanding of multi-discipline design to position them for accelerated career progression.

This course prepares graduates for careers as project design engineers, systems design, structural design or avionic engineers in aerospace or related industries, with the aim of progressing to technical management/chief engineer. Graduates from the MSc in Avionic Systems Design can therefore look forward to a varied choice of challenging career opportunities in the above disciplines.

Many of our graduates occupy very senior positions in their organisations, making valuable contributions to the international aerospace industry. Typical student destinations include BAE Systems, Airbus, Dassault and Rolls-Royce plc

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The Systems Engineering Management MSc has been specifically designed for the needs of engineering professionals working in the field of complex systems development. Read more
The Systems Engineering Management MSc has been specifically designed for the needs of engineering professionals working in the field of complex systems development. The programme encompasses not only the technical tools and approaches needed to build success in this area, but also the management dimension of the relevant processes.

Degree information

Students gain an integrated, interdisciplinary view of complex systems and an advanced understanding of the systems engineering process. They gain the ability to apply this process to a variety of real world situations and the management skills necessary to facilitate the development of complex systems on time and within budget.

Students undertake modules to the value of 180 credits.

The programme consists of four core taught modules (60 credits) two optional taught modules (30 credits) and three research modules (90 credits). Modules are generally taught as intensive five-day 'block weeks' to minimise time away from the office.

A Postgraduate Diploma (120 credits, full-time nine months, or flexible study up to five years) is offered. A Postgraduate Certificate (60 credits, full-time 12 weeks, or flexible study up to two years) is offered.

Core modules
-Systems Engineering Management
-Lifecycle Management
-Risk, Reliability, Resilience
-The Business Environment

Optional modules
-Defence Systems
-Environmental Systems*
-Project Management
-Rail Systems
-Spacecraft Systems
-Systems Design
-Systems, Society, Sustainability*

*These modules are delivered by UCL's Department of Civil, Environmental and Geomatic Engineering in ten half-day sessions over the course of a term instead of the usual intensive 'block week' format

Research modules - all MSc students undertake a structured research programme comprising the following mandatory modules:
-Systems Engineering in Practice (15 credits)
-Systems Engineering Project Concept (15 credits)
-Systems Engineering Research Project (60 credits)

Teaching and learning
The programme is delivered through a combination of lectures, discussion sessions, workshop activity, and project work. Each taught course will be separately assessed through a combination of course work and a written examination. The project will be assessed through written dissertation and subsequent oral examination.

Careers

Complex systems are commonplace in many branches of UK industry including rail, aerospace, defence, and manufacturing. The ability to create such systems effectively is crucial to the competitiveness of these industries and has a direct bearing on the wealth of the nation.

Recent graduates of the programme have the following careers:
-London Underground: Head of Railway Systems
-Accenture: Analyst
-Thales Aerospace: Design Authority Manager
-BAE Systems: Systems Design Authority
-Selex Sensors and Airborne Management: Engineering Lead
-Xerox: Engineering Manager
-QinetiQ: Marine Engineer
-BAE Systems: Senior Hardware Engineer
-British Aerospace: Software Engineer
-Orange: Principal Engineer
-Halcrow Group Limited: Design Manager

Top career destinations for this degree:
-Software Engineer, Bank of America Merrill Lynch
-Analyst, Accenture
-Proposals engineer, Invensys PLC
-Engineering Manager, BAE Systems
-Systems Engineer, BIG

Why study this degree at UCL?

This MSc combines academic rigour with the practical expertise exemplified by our collaborators in UK industry and government. The flexible programme enables participants to structure their studies to suit their own career goals, and is accredited by the IET as a programme of further learning for registration as a Chartered Engineer.

Lectures are presented by experts in the field, many of whom have engaged in the practice of systems engineering in industry.

Industry is operating in an environment where technology changes rapidly, and where global competition grows ever more intensive. The challenge to remain competitive means we must make the right thing at the right price. Our MSc equips graduates with the skills to meet this challenge.

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Through this MSc programme, you will develop an understanding of the core subjects in Advanced Aerospace Engineering, along with knowledge and skills in mathematics, computing, design and business studies. Read more
Through this MSc programme, you will develop an understanding of the core subjects in Advanced Aerospace Engineering, along with knowledge and skills in mathematics, computing, design and business studies. Additionally, you will develop the wider transferable skills of analysis, problem-solving, communication and team-working.

A postgraduate degree in Advanced Aerospace Engineering is the basis for a career in a profession that offers an extremely wide choice of employment opportunities. Graduates will also understand the Engineer’s role within industry in the UK, Europe and the rest of the world.

The programme is suitable for people with an Engineering background wishing to gain a masters level qualification for a professional career route or those with a physical science background seeking to change disciplines to broaden their employment opportunities.

This programme aligns with the current accredited Undergraduate integrated Masters MEng 4th year in Aerospace Engineering with co-taught M level modules from the existing programme organised in two 12-week semesters with examinations at the end of each semester worth 120 credits from a total of 180. This is then combined with an MSc advanced research project over the summer term worth the remaining 60 credits.

Projects

Project work which contributes 60 credits, will be based on a topic of industrial or scientific relevance, and will be carried out in laboratories in the University or at an approved placement in industry. The project is examined by dissertation, and award of the MSc(Eng) degree will require evidence of in-depth understanding, mastery of research techniques, ability to analyse assembled data, and assessment of outcomes.

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This course is accredited by the Institution of Mechanical Engineers (IMechE) and provides a route for you to achieve Chartered Engineer (CEng) status. Read more

Why this course?

This course is accredited by the Institution of Mechanical Engineers (IMechE) and provides a route for you to achieve Chartered Engineer (CEng) status.

It has been developed to provide high-calibre mechanical engineering graduates with an in-depth technical understanding of advanced mechanical engineering topics together with generic skills that will allow them to contribute effectively post graduation.

The course helps you to become a specialist in the area of aerospace. You'll also have the opportunity to take modules in general skills such as project management and risk analysis. These are necessary skills for any professional aerospace engineer.

You’ll study

You'll study three compulsory modules:
- Aerodynamics Performance
- Aerodynamic Propulsion Systems
- Spaceflight Mechanics

You'll select a number of specialist instructional classes in your chosen area. You'll also choose three generic skill modules from the following topics:
- Design Management
- Project Management
- Sustainability
- Information Management
- Finance
- Risk Management
- Environmental Impact Assessment
- Knowledge Engineering & Management for Engineers

MSc students take on an individual project which allows study of a selected topic in-depth. This may be an industry-themed project or one aligned to engineering research at Strathclyde.

Facilities

Our facilities include many laboratories and research centres including:
- Advanced Space Concepts Laboratory
- Energy Systems Research Unit
- Future Air-Space Transportation Technology
- James Weir Fluids Laboratory
- Mechanics & Materials Research Centre

We have local access to a 3500-node region supercomputer.

Accreditation

This course is accredited by the Institution of Mechanical Engineers and meets requirements for Chartered Engineer (CEng) status.

English language requirements for international students

IELTS - minimum overall band score of 6.5 (no individual test score below 5.5).

Pre-Masters preparation course

The Pre-Masters Programme is a preparation course for international students (non EU/UK) who do not meet the entry requirements for a Masters degree at University of Strathclyde. The Pre-Masters programme provides progression to a number of degree options.

To find out more about the courses and opportunities on offer visit isc.strath.ac.uk or call today on +44 (0) 1273 339333 and discuss your education future. You can also complete the online application form. To ask a question please fill in the enquiry form and talk to one of our multi-lingual Student Enrolment Advisers today.

Learning & teaching

Students take three compulsory modules and a selection of specialist and generic modules.
To qualify for the MSc, students undertake an individual project which allows study of a selected topic in depth, normally industry-themed or aligned to engineering research at Strathclyde.

Assessment

Assessment is by written assignments, exams and the individual project.

Careers

This course is particularly suitable for graduate engineers in these sectors:
- chemical, petrochemical & process engineering
- design engineering
- power generation
- manufacturing
- oil & gas
- renewable energy

Find information on Scholarships here http://www.strath.ac.uk/search/scholarships/

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This course is designed to respond to a growing shortage of workforce in manufacturing sector. Read more

Why take this course?

This course is designed to respond to a growing shortage of workforce in manufacturing sector. It intends to equip our students with relevant and up-to-date knowledge and skills of advanced design tools, materials, manufacturing processes and systems in conjunction with developing efficient operation and effective management skills. Integrating these will ensure our students to develop the technological and practical ability to meet manufacturing demand for product, company and market needs.

What will I experience?

On this course you can:

Use simulation and modelling application software for virtual design and manufacturing
Utilise our strong links with companies and investigate real industrial problems to enhance your understanding of the profession
Tie in the topic of your individual project with one of our research groups and benefit from the expertise of our actively researching academics

What opportunities might it lead to?

This course has been accredited by the Institution of Mechanical Engineers (IMechE) meeting the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). It will provide you with some of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng).

Here are some routes our graduates have pursued:

Design
Research and development
Product manufacture
Project management

Module Details

This course aims to provide you with the inter-disciplinary knowledge, attributes and skills necessary to apply the principles of advanced manufacturing systems within the manufacturing industry. You will study several key topics and also complete a four-month individual project tailored to your individual interests that can take place in our own laboratories or, by agreement, in industry.

Here are the units you will study:

Integrated Manufacturing Systems: Systems concepts and techniques are developed in logistics and manufacturing areas with a strong emphasis on simulation techniques and practical case study analysis.

Operations and Quality Management: A strategic approach is used with modern inventory and supply chain management and logistics tools and techniques. Management strategies are developed for quality, including quality systems and quality control.

Advanced Materials: This unit is designed to deal with a wide range of advanced materials for engineering applications. Teaching will address analytical and numerical methods to assess the strength, stiffness, toughness, non-linearity behaviours, vibration and failures of engineering materials for component and structure design.

Supply Chain Management: Supply chain management involves the coordination of production, inventory, location and transportation, among participants in a supply chain. This unit considers the principles and tools of supply chain management, with an emphasis on lean six sigma methods.

Virtual Systems Design and Simulation for Production: This unit is particularly designed to enhance students’ analytical knowledge and practical skills focusing on a sustainable development of systematic approaches and lean production methods to support manufacturing systems analysis, design and performance evaluation with an aid of using advanced computer design and modelling simulation tools.

CAD/CAM Systems: An integrated approach is used towards CAD and CAM. Significant practical hands-on experience is given with commercial level software. Emphasis is placed on case study analysis and system selection and evaluation.

Individual Project: A strong feature that comprises a third of the course. You will be encouraged to undertake projects where possible in industrial companies. However, we also use our extensive resources and staff skills to undertake them within the University.

Programme Assessment

You will be taught through a mixture of lectures, seminars, tutorials (personal and academic), laboratory sessions and project work. The course has a strong practical emphasis with a significant amount of your time spent our laboratories. We pride ourselves on working at the leading-edge of technology and learning practices.

A range of assessment methods encourages a deeper understanding of engineering and allows you to develop your skills. Here’s how we assess your work:

Written examinations
Coursework
Laboratory-based project work
A major individual project/dissertation

Student Destinations

The demand for more highly skilled manufacturing engineers is always present and it is generally accepted that there is a current shortage of engineers.

This course has a record of almost 100 per cent of our graduates gaining employment in relevant areas such as manufacturing and logistics management, systems engineering, production engineering, design engineering and project management. You could work for a large company, in the Armed Forces or in one of the many small companies within this sector. You could even start your own specialist company.

Roles our graduates have taken on include:

Manufacturing engineer
Product design engineer
Aerospace engineer
Application engineer

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Electronic engineering is a discipline at the forefront of advances for modern-day living and continues to push forward technological frontiers. Read more

Why take this course?

Electronic engineering is a discipline at the forefront of advances for modern-day living and continues to push forward technological frontiers.

This course provides relevant, up-to-date skills that will enhance your engineering competencies. You will broaden your knowledge of electronic engineering and strengthen your ability to apply new technologies in the design and implementation of modern systems.

What will I experience?

On this course you can:

Focus on the practical application and design aspects of electronic systems rather than intensive analytical detail
Experiment with our range of control applications including helicopter development kits and walking robots
Access a wide range of powerful and modern multimedia computational facilities, with the latest industry software installed

What opportunities might it lead to?

This course has been accredited by the Institution of Engineering and Technology (IET) and meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). It will provide you with some of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng).

Here are some routes our graduates have pursued:

Professional electronics
Design
Research and development
Product manufacture
Project management

Module Details

You will study several key topics and complete a four-month individual project in which you apply your knowledge to a significant, in-depth piece of analysis or design. Projects are tailored to your individual interests and may take place in our own laboratories or, by agreement, in industry.

Here are the units you will study:

VHDL and Digital Systems Design: This unit covers the use of a hardware description language (VHDL) to capture and model the design requirement - whilst programmable logic devices enable an implementation to be explored and tested prior to moving into manufacture. The learning will have a practical bias such that experience as well as theory is gained in completing this unit.

Advanced DSP Techniques: This unit aims to introduce you to the fundamentals of statistical signal processing, with particular emphasis upon classical and modern estimation theory, parametric and nonparametric modelling, time series analysis, least squares methods, and basics of adaptive signal processing.

Mixed Signal Processors: This unit focuses on both control and signal processing hardware, how it works, how to interface to it, and software - how to design it and debug it.

Sensors and Measurement Systems: This unit proposes to introduce you to the technologies underpinning measurements including sensors both in terms of hardware and software. It also aims to provide you with an opportunity to apply classroom knowledge in a practical setting and gain an appreciation of modern day requirements in terms of measurement.

Microwave and Wireless Technology: The unit combines team working via a project based learning activity relating to a significant circuit simulation and design problem with lectures aimed at analysing and applying the characteristics of a range of devices used in the microwave and wireless industries.

Communication System Analysis: This unit focuses on basic principles in the analysis and design of modern communication systems, the workhorses behind the information age. It puts emphasis on the treatment of analogue communications as the necessary background for understanding digital communications.

Programme Assessment

You will be taught through a mixture of lectures, seminars, tutorials (personal and academic), laboratory sessions and project work. The course has a strong practical emphasis and you will spend a significant amount of time in our electronic, communications and computer laboratories.

A range of assessment methods encourages a deeper understanding of engineering and allows you to develop your skills. Here’s how we assess your work:

Written examinations
Coursework
Laboratory-based project work
A major individual project/dissertation

Student Destinations

This course is designed to respond to a growing skills shortage of people with core knowledge in advanced electronic engineering. It is an excellent preparation for a successful career in this ever expanding and dynamic field of modern electronics.

On successful completion of the course, you will have gained the skills and knowledge that will make you attractive to a wide variety of employers with interests ranging from overall system design to the more detailed development of subsystems.

Roles our graduates have taken on include:

Electronics engineer
Product design engineer
Aerospace engineer
Application engineer

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This course is designed to respond to a growing shortage of workforce in mechanical engineering sectors. It intends to equip our students with relevant and up-to-date knowledge and skills for their engineering competencies and careers. Read more

Why take this course?

This course is designed to respond to a growing shortage of workforce in mechanical engineering sectors. It intends to equip our students with relevant and up-to-date knowledge and skills for their engineering competencies and careers. Students have a chance to broaden and deepen their knowledge in wide range of mechanical engineering subjects. This enables our students to undertake an advanced treatment of core mechanical engineering disciplines such as design and critical evaluation of structural integrity, computation fluid dynamics, advanced materials, energy and control systems.

What will I experience?

On this course you can:

Use simulation and modelling application software for virtual design and manufacturing
Utilise our strong links with companies and investigate real industrial problems to enhance your understanding of the profession
Tie in the topic of your individual project with one of our research groups and benefit from the expertise of our actively researching academics

What opportunities might it lead to?

This course has been accredited by the Institution of Mechanical Engineers (IMechE) and Institution of Engineering and Technology (IET), meeting the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). It will provide you with some of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng).

Here are some routes our graduates have pursued:

Design
Research and development
Product manufacture
Project management

Module Details

You will study several key topics that will help equip you to work as a mechanical engineer in a broad spectrum of mechanical engineering business activity management, research, design and development roles. You will also complete a four-month individual project tailored to your individual interests that can take place in our own laboratories or, by agreement, in industry.

Here are the units you will study:

Structural Integrity: Contemporary approaches are applied to the evaluation of mixed mode fracture and fatigue failure. Dynamic plastic responses of structures and the performance of composite structures are evaluated.

Industrial Control Systems: This unit covers mathematical representation of control system models is developed principally using Laplace transforms. System behaviour and simulation is analysed with practical case studies, leading to control system specifications.

Advanced Materials: This unit is designed to deal with a wide range of advanced materials for engineering applications. Teaching will address analytical and numerical methods to assess the strength, stiffness, toughness, non-linearity behaviours, vibration and failures of engineering materials for component and structure design.

Energy Systems: This unit is designed to study the principles and techniques of operation of thermodynamics and combustion systems, as well as the provision and management of energy. The current and future requirements and trends in energy production and consumption are addressed.

Structural Application of Finite Elements: The use of finite element analysis techniques and software applied to structural problems is developed. Modelling with both isotropic and orthotropic materials is investigated, as well as such topics as cracking in dissimilar materials and composite laminates.

Computational Fluid Dynamics: A practical case study analysis approach is used for model formulation and CFD simulation. Fundamental principles are used to appraise the results of CFD analysis of problems with industrial applications.

Individual Project: A strong feature of the course is the individual project, which comprises a third of the course. We encourage students to undertake projects in industrial companies, but we can also use our extensive resources and staff skills to undertake projects within the University.

Programme Assessment

You will be taught through a mixture of lectures, seminars, tutorials (personal and academic), laboratory sessions and project work. The course has a strong practical emphasis with a significant amount of your time spent our laboratories. We pride ourselves on working at the leading-edge of technology and learning practices.

A range of assessment methods encourages a deeper understanding of engineering and allows you to develop your skills. Here’s how we assess your work:

Written examinations
Coursework
Laboratory-based project work
A major individual project/dissertation

Student Destinations

The demand for more highly skilled mechanical engineers is always present and it is generally accepted that there is a current shortage of engineers.

When you graduate from this course you could find employment in a wide range of mechanical engineering-based careers, such as design, research and development and manufacturing. You could work for a large company, in the Armed Forces or in one of the many small companies within this sector. You could even start your own specialist company.

Roles our graduates have taken on include:

Mechanical engineer
Product design engineer
Aerospace engineer
Application engineer

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