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Masters Degrees (Radio Frequency And Microwave Engineering)

We have 8 Masters Degrees (Radio Frequency And Microwave Engineering)

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This programme addresses the great shortage of skilled radio frequency (RF) and microwave engineers, and the growing demand for conceptually new wireless systems. Read more

This programme addresses the great shortage of skilled radio frequency (RF) and microwave engineers, and the growing demand for conceptually new wireless systems.

You will learn about a range of modern theories and techniques, accompanied by topics on wireless frequencies and sizes of RF and microwave devices.

This ranges from the lowest frequencies used in radio frequency identification (RFID) systems through to systems used at mm wave frequencies that can have applications in satellite communication systems and fifth generation wireless communication systems.

Theoretical concepts established in lectures are complemented by practical implementation in laboratory sessions, with direct experience of industry-standard computer-aided design (CAD) software.

Read about the experience of a previous student on this course, Uche Chukwumerije.

Programme structure

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a project.

Example module listing

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.

Academic support

We provide solid academic support through the taught modules and into the project period. You will be assigned a personal tutor with whom you can discuss both academic and general issues related to the programme.

When you move into the project phase of the programme, you will be assigned a project supervisor who you will meet, usually on a weekly basis, to discuss the progress of your project.

The individual taught modules also feature strong academic support, usually through a tutorial programme. All of the RF and microwave modules have tutorial sheets to support the lectures.

Although completing the tutorials is not part of the formal assessment, you have the option of using the tutorials to receive individual feedback on your progress in the modules.

Facilities and equipment

The combined facilities of the RF teaching laboratories and the Advanced Technology Institute provide MSc students with an exceptionally wide range of modern fabrication and measurement equipment.

Furthermore a wide variety of RF test and measurement facilities are available through Surrey Space Centre and the 5G Innovation Centre, which also involve work in the RF and microwave engineering domain.

Equipment includes access to CAD design tools, anechoic chamber, spectrum analysers, network analysers, wideband channel sounder, circuit etching and circuit testing.

Industrial and overseas links

The 5G Innovation Centre and Advanced Technology Institute within the Department have a range of active links with industry, both in the UK and overseas. During the past few years we have had students taking the MSc through the part-time route and completing their projects in industry.

Examples of industrial projects range from looking at new microwave measurement techniques at the National Physical Laboratory (NPL), to antenna design and construction at the Defence Science and Technology Laboratory (Dstl).

We have also sent students overseas to complete their projects, funded through the Erasmus scheme, which is a European programme that provides full financial support for students completing their project work at one of our partner universities in mainland Europe.

Students taking advantage of this opportunity not only enhance their CVs with a European perspective, but also produce excellent project dissertations.

Technical characteristics of the pathway

This programme in Microwave Engineering and Wireless Subsystem Designrf and microwavengineering provides detailed in-depth knowledge of theory and techniques applicable to radio frequency (RF) and microwave engineering.

The programme includes core modules in both RF and microwave covering all ranges of wireless frequencies and a number of application devices including radio frequency identification (RFID), broadcasting, satellite links, microwave ovens, printed and integrated microwave circuits.

Additional optional modules enable the student to apply the use of RF and microwave in subsystem design for either mobile communications, satellite communications, nanotechnology or for integration with optical communications.

The teaching material and projects are closely related to the research being carried out in the Department’s Advanced Technology Institute and the Institute for Communication Systems.

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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This programme is suitable for recent graduates and engineers with experience of microelectronics who have good mathematical ability. Read more
This programme is suitable for recent graduates and engineers with experience of microelectronics who have good mathematical ability. It provides a thorough knowledge of the principles and techniques of this exciting field and has been developed in consultation with industry advisors to ensure it is relevant to today’s workplace.

Modules are block taught so can also be studied separately by working engineers as continuous professional development either to enhance their knowledge in particular subject fields or to widen their portfolio.

Core study areas include ASIC engineering, sensors and actuators, technology and verification of VLSI systems, embedded software development and an individual project.

Optional study areas include communication networks, information theory and coding, solar power, wind power, systems architecture, advanced FPGAs, DSP for software radio, advanced photovoltaics, mobile network technologies and advanced applications.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/electronic-electrical-engineering/

Programme modules

Compulsory Modules:
• ASIC Engineering
• Sensors and Actuators for Control
• Embedded Software Development
• Individual Project

Optional Modules (Choose five):
• Communication Networks
• Fundamentals of Digital Signal Processing
• Solar Power 1
• Wind Power 1
• Communications Channels
• DSP for Software Radio
• Imagineering
• Mobile Networks
• Advanced FPGAs
• Engineering Applications
• Systems Modelling for Control Engineering – new for 2015
• Radio Frequency and Microwave Integrated Circuit Design – new for 2015

Block-taught, individual modules are also highly suitable as CPD for professional engineers needing to fill a skills gap.

How you will learn

Compulsory modules provide a comprehensive understanding of modern microelectronics, embedded electronic systems, emerging technologies and their uses while the individual research project offers the chance to pursue a specialism in-depth. You’ll have access to advanced research knowledge and state of the art laboratories using industry standard software (Altera, Cadence, Mentor, Xilinx) so that you are prepared to enter a wide range of industry sectors on graduation.

- Assessment
Examinations are held in January and May, with coursework and group work assessments throughout the programme. The high practical content of this course is reflected in the inclusion of laboratory assessments and practical examinations. The individual research project is assessed by written report and viva voce in September.

Facilities

You’ll have access to laboratories, industry standard software (Altera, Cadence, Mentor Graphics, Xilinx) and hardware including equipment provided by Texas Instruments.

Careers and further study

Consultation with industry to craft the syllabus ensures that you’ll have an advantage in the job market. The in-depth knowledge acquired can be applied wherever embedded electronic systems are found including mobile phones (4/5G), acoustics, defence, medical instrumentation, radio and satellite communication and networked systems, control engineering, instrumentation, signal processing and telecommunications engineering.

Scholarships and bursaries

Scholarships and bursaries are available each year for UK/EU and international students who meet the criteria for award.

Why choose electronic, electrical and systems engineering at Loughborough?

We develop and nurture the world’s top engineering talent to meet the challenges of an increasingly complex world. All of our Masters programmes are accredited by one or more of the following professional bodies: the IET, IMechE, InstMC, Royal Aeronautical Society and the Energy Institute.

We carefully integrate our research and education programmes in order to support the technical and commercial needs of society and to extend the boundaries of current knowledge.

Consequently, our graduates are highly sought after by industry and commerce worldwide, and our programmes are consistently ranked as excellent in student surveys, including the National Student Survey, and independent assessments.

- Facilities
Our facilities are flexible and serve to enable our research and teaching as well as modest preproduction testing for industry.
Our extensive laboratories allow you the opportunity to gain crucial practical skills and experience in some of the latest electrical and electronic experimental facilities and using industry standard software.

- Research
We are passionate about our research and continually strive to strengthen and stimulate our portfolio. We have traditionally built our expertise around the themes of communications, energy and systems, critical areas where technology and engineering impact on modern life.

- Career prospects
90% of our graduates were in employment and/or further study six months after graduating. They go on to work with companies such as Accenture, BAE Systems, E.ON, ESB International, Hewlett Packard, Mitsubishi, Renewable Energy Systems Ltd, Rolls Royce and Siemens AG.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/electronic-electrical-engineering/

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Our Masters programme in Satellite Communications Engineering is designed to give you the specialist multidisciplinary skills required for careers in the satellite and space industries. Read more

Our Masters programme in Satellite Communications Engineering is designed to give you the specialist multidisciplinary skills required for careers in the satellite and space industries.

We have an exceptional concentration of academic staff experienced in the satellite area, in addition to well-established contacts with all the major satellite manufacturers, operators and service providers.

Industry participates in the MSc programme in both lecturing and projects, and facilitates excellent engagement for our students. Graduation from this programme will therefore make you very attractive to the relevant space-related industries that employ over 6,500 people in the UK alone.

Read about the experience of a previous student on this course, Thanat Varathon.

Programme structure

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a project.

Example module listing

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.

Facilities, equipment and support

Through consistent investment, we have built up an impressive infrastructure to support our students and researchers. The University of Surrey hosts Surrey Space Centre – a unique facility comprising academics and engineers from our own spin-out company, Surrey Satellite Technology Ltd.

Our mission control centre was designed and developed by students to support international CubeSat operations as part of the GENSO network, and it also supports the development of the University’s own educational satellites.

Our teaching laboratories provide ‘hands-on’ experience of satellite design and construction through the use of EyasSAT nano-satellite kits. They also house meteorological satellite receiving stations for the live reception of satellite weather images.

Elsewhere, our fully equipped RF lab has network analyser, signal and satellite link simulators. The Rohde and Schwartz Satellite Networking Laboratory includes DVBS2-RCS generation and measurement equipment, and roof-mounted antennas to communicating live with satellites.

A security test-bed also exists for satellite security evaluation. We have a full range of software support for assignments and project work, including Matlab, and you will be able to access system simulators already built in-house.

Satellite Communications Engineering students can also make use of SatNEX, a European Network of Excellence in satellite communications supported by ESA; a satellite platform exists to link the 22 partners around Europe. This is used for virtual meetings and to participate in lectures and seminars delivered by partners.

Our own spin-out company, Surrey Satellite Technology Ltd, is situated close by on the Surrey Research Park and provides ready access to satellite production and industrial facilities. In addition, we have a strategic relationship with EADS Airbus Europe-wide and several other major communications companies.

Technical characteristics of the pathway

This programme in satellite communications engineering. provides detailed in-depth knowledge of theory and techniques applicable to radio frequency (RF) and microwave engineering.

The programme includes core modules in both RF and microwave covering all ranges of wireless frequencies and a number of application devices including radio frequency identification (RFID), broadcasting, satellite links, microwave ovens, printed and integrated microwave circuits.

Additional optional modules enable the student to apply the use of RF and microwave in subsystem design for either mobile communications, satellite communications, nanotechnology or for integration with optical communications.

The teaching material and projects are closely related to the research being carried out in the Department’s Advanced Technology Institute and the Institute for Communication Systems.

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.



Read less
This course aims to provide you with key, advanced level knowledge and skills that will allow you to succeed in the rapidly growing wireless and microwave communication industry. Read more
This course aims to provide you with key, advanced level knowledge and skills that will allow you to succeed in the rapidly growing wireless and microwave communication industry. You will also develop research skills and other related abilities, enhancing your general engineering competency, employability, and providing you with an excellent platform for career development, whether that be within industry or academic research.

The distinctive features of this course include:

• The opportunity to learn in a research-led teaching institution, taught by staff in one of the highest ranked university units in the 2014 Research Excellence Framework (REF), ranked 7th in the UK for research and 1st in the UK for the research impact.

• The opportunity to work in modern facilities and commensurate with a top-class research university.

• The participation of research-active staff in programme design and delivery.

• MSc teaching complemented by guest lectures given by industrial professionals.

• Formal accreditation by the Institution of Engineering and Technology (IET).

Structure

The course is presented as a one-year full time Masters level programme, and is also available as a part-time scheme run over two years. The programme is presented in two stages: In Part 1 students follow two semesters of taught modules to the value of 120 credits. Part 2 consists of a Dissertation or research project module worth 60 credits.

Core modules:

RF Circuits Design & CAD
RESEARCH STUDY
Advanced Communication Systems
Fundamentals of Micro- and Nanotechnology
Management in Industry
Software Tools and Simulation
High Frequency Electronic Materials
HF and RF Engineering
Optoelectronics
Non-Linear RF Design and Concepts
Advanced CAD, Fabrication and Test
Dissertation (Electronic)

Teaching

A wide range of teaching styles are used to deliver the diverse material forming the curriculum of the programme. You will attend lectures and take part in lab and tutorial based study during the Autumn and Spring semesters. During the summer you will undertake an individual research project.

At the beginning of Stage 2, you will be allocated a project supervisor. Dissertation topics are normally chosen from a range of project titles proposed by academic staff in consultation with industrial partners, usually in areas of current research or industrial interest. You will also be encouraged to put forward your own project ideas.

Assessment

The course is assessed through examinations, written coursework, and a final individual project report.

Achievement of learning outcomes in the majority of modules is assessed by a combination of coursework assignments, plus University examinations set in January and May. Examinations count for 60%–70% of assessment in Stage 1 of the programme, depending on the options chosen, the remainder being largely project work and elements of coursework.

Career prospects

Career prospects are generally excellent with graduating students following paths either into research or related industry.

If you are interested in working in industry, many of our graduating MSc students achieve excellent employment opportunities in organisations including Infineon, Huawei, Cambridge Silicon Radio, Vodafone and International Rectifier.

In terms of research, Cardiff University has many electrical, electronic and microwave related research areas that require PhD students, and this MSc will provide you with an excellent platform if this is your chosen career path.

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The School of Engineering and Digital Arts offers research-led degrees in a wide range of research disciplines, related to Electronic, Control and Information Engineering, in a highly stimulating academic environment. Read more
The School of Engineering and Digital Arts offers research-led degrees in a wide range of research disciplines, related to Electronic, Control and Information Engineering, in a highly stimulating academic environment. The School enjoys an international reputation for its work and prides itself in allowing students the freedom to realise their maximum potential.

Established over 40 years ago, the School has developed a top-quality teaching and research base, receiving excellent ratings in both research and teaching assessments.

We undertake high-quality research that has had significant national and international impact, and our spread of expertise allows us to respond rapidly to new developments. Our 30 academic staff and over 130 postgraduate students and research staff provide an ideal focus to effectively support a high level of research activity. There is a thriving student population studying for postgraduate degrees in a friendly and supportive teaching and research environment.

We have research funding from the Research Councils UK, European research programmes, a number of industrial and commercial companies and government agencies including the Ministry of Defence. Our Electronic Systems Design Centre and Digital Media Hub provide training and consultancy for a wide range of companies. Many of our research projects are collaborative, and we have well-developed links with institutions worldwide.

Visit the website https://www.kent.ac.uk/courses/postgraduate/262/electronic-engineering

Project opportunities

Some projects available for postgraduate research degrees (http://www.eda.kent.ac.uk/postgraduate/projects_funding/pgr_projects.aspx).

Research areas

- Communications

The Group’s activities cover system and component technologies from microwave to terahertz frequencies. These include photonics, antennae and wireless components for a broad range of communication systems. The Group has extensive software research tools together with antenna anechoic chambers, network and spectrum analysers to millimetre wave frequencies and optical signal generation, processing and measurement facilities. Current research themes include:

- photonic components
- networks/wireless systems
- microwave and millimetre-wave systems
- antenna systems
- radio-over-fibre systems
- electromagnetic bandgaps and metamaterials
- frequency selective surfaces.

- Intelligent Interactions:

The Intelligent Interactions group has interests in all aspects of information engineering and human-machine interactions. It was formed in 2014 by the merger of the Image and Information Research Group and the Digital Media Research Group.

The group has an international reputation for its work in a number of key application areas. These include: image processing and vision, pattern recognition, interaction design, social, ubiquitous and mobile computing with a range of applications in security and biometrics, healthcare, e-learning, computer games, digital film and animation.

- Social and Affective Computing
- Assistive Robotics and Human-Robot Interaction
- Brain-Computer Interfaces
- Mobile, Ubiquitous and Pervasive Computing
- Sensor Networks and Data Analytics
- Biometric and Forensic Technologies
- Behaviour Models for Security
- Distributed Systems Security (Cloud Computing, Internet of Things)
- Advanced Pattern Recognition (medical imaging, document and handwriting recognition, animal biometrics)
- Computer Animation, Game Design and Game Technologies
- Virtual and Augmented Reality
- Digital Arts, Virtual Narratives.

- Instrumentation, Control and Embedded Systems:

The Instrumentation, Control and Embedded Systems Research Group comprises a mixture of highly experienced, young and vibrant academics working in three complementary research themes – embedded systems, instrumentation and control. The Group has established a major reputation in recent years for solving challenging scientific and technical problems across a range of industrial sectors, and has strong links with many European countries through EU-funded research programmes. The Group also has a history of industrial collaboration in the UK through Knowledge Transfer Partnerships.

The Group’s main expertise lies primarily in image processing, signal processing, embedded systems, optical sensors, neural networks, and systems on chip and advanced control. It is currently working in the following areas:

- monitoring and characterisation of combustion flames
- flow measurement of particulate solids
- medical instrumentation
- control of autonomous vehicles
- control of time-delay systems
- high-speed architectures for real-time image processing
- novel signal processing architectures based on logarithmic arithmetic.

Careers

We have developed our programmes with a number of industrial organisations, which means that successful students are in a strong position to build a long-term career in this important discipline. You develop the skills and capabilities that employers are looking for, including problem solving, independent thought, report-writing, time management, leadership skills, team-working and good communication.

Kent has an excellent record for postgraduate employment: over 94% of our postgraduate students who graduated in 2013 found a job or further study opportunity within six months.

Building on Kent’s success as the region’s leading institution for student employability, we offer many opportunities for you to gain worthwhile experience and develop the specific skills and aptitudes that employers value.

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

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In an increasingly overcrowded electromagnetic spectrum, the efficient and reliable operation of wireless, mobile and satellite communication systems, and of radar and remote sensing systems, relies upon advanced components and subsystems that exploit ongoing developments in technologies such as microfabrication, nanotechnology and high frequency semiconductor devices. Read more
In an increasingly overcrowded electromagnetic spectrum, the efficient and reliable operation of wireless, mobile and satellite communication systems, and of radar and remote sensing systems, relies upon advanced components and subsystems that exploit ongoing developments in technologies such as microfabrication, nanotechnology and high frequency semiconductor devices.

This programme provides training for engineers to become innovators in these rapidly expanding markets. A firm grasp of the fundamentals is established through modules in the foundations of communications engineering and in satellite, cellular and optical fibrte communications, electromagnetics and antennas, propagation, radio frequency and microwave engineering and computer and communications networksprovide advanced knowledge in an aspect of the relevant component technologies.

The programme will help you to develop an ability to interpret user requirements and component specifications, to engineer effective designs within the constraints imposed by the available resources and the fundamental physical limits. The programme provides a theoretical basis from which the design, construction and operation of satellite and cellular radio communications can be understood.

About the School of Electronic, Electrical & Systems Engineering

Electronic, Electrical and Systems Engineering, is an exceptionally broad subject. It sits between Mathematics, Physics, Computer Science, Psychology, Materials Science, Education, Biological and Medical Sciences, with interfaces to many other areas of engineering such as transportation systems, renewable energy systems and the built environment.
Our students study in modern, purpose built and up to date facilities in the Gisbert Kapp building, which houses dedicated state-of-theart teaching and research facilities. The Department has a strong commitment to interdisciplinary research and boasts an annual research fund of more than £4 million a year. This means that wherever your interest lies, you can be sure you’ll be taught by experts in the field.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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The Composite Materials research degrees are part of a forward-thinking area of research in the school. Read more
The Composite Materials research degrees are part of a forward-thinking area of research in the school. We have close links with the Northwest Regional Development Agency and other leading companies such as, Quickstep, a manufacturer of autoclave processing equipment, as well as a large number of suppliers in the aircraft industry.

Active research

Current research covers interfacial phenomena in composite materials, natural composites and rapid composites manufacture. The deformation mechanics of a range of high performance synthetic reinforcement fibres for composites are explored, as are those of natural and regenerated cellulose fibres. In the later case the main emphasis is on understanding the relationships between the microstructure and molecular structure of these materials and their mechanical properties. Molecular dynamics modelling together with experimental studies have been used to gain an improved insight into the behaviour of natural fibres.

Northwest Composites Centre

We are actively involved with the Northwest Composites Centre, a collaboration which incorporates researchers from several schools in the university, together with colleagues from the University of Liverpool, University of Bolton and Lancaster University covering a wide range of polymer and metallic composites. The hub of this activity is based here at the School of Materials, established through a £2.1m grant from NWDA, and has facilities for rapid processing of composites through a variety of new technologies, including microwave and radio frequency heating as well as Quickstep. There are also extensive facilities for the characterisation of composites.

There are a large number of researchers working in the centre, nearly all on the rapid processing of composites with a view to improving the cycle time and properties of composites. These involve not just the use of rapid curing techniques, but also textile structures for next generation 3 D composites. The evaluation of these materials is also an important part of the projects and therefore supported by state-of-the-art equipment.

Facilities

To underpin the research and teaching activities, we have established state-of-the-art laboratories, which allow comprehensive characterisation and development of materials. These facilities range from synthetic/textile fibre chemistry to materials processing and materials testing.

To complement our teaching resources, there is a comprehensive range of electrochemical, electronoptical imaging and surface and bulk analytical facilities and techniques.

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