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Our MSc in Electronic Engineering offers content that is different to many other similarly-titled courses. It equips you with a skill set that is in demand by industry worldwide, allowing you to maximise your employability by taking a course that is broad in scope but challenging in detail. Read more

About the course

Our MSc in Electronic Engineering offers content that is different to many other similarly-titled courses. It equips you with a skill set that is in demand by industry worldwide, allowing you to maximise your employability by taking a course that is broad in scope but challenging in detail.

Electronic Engineering provides a broad master’s-level study of some of the most important aspects of electronic engineering today. It builds on your undergraduate knowledge of core aspects of electronics, supported by a module in Engineering Business Environment and Energy Policies, which provides you with an understanding of the context of engineering in the early 21st Century.

The course embraces a number of themes in areas identified as being generally under-represented in many other courses, such as power electronics and electromagnetic compatibility, providing you with as wide a range of employment opportunities as possible – whether this is in industry or continuing in research at university.

The course has achieved accreditation by the Institution of Engineering and Technology (IET) to CEng level for the full five year period.

Reasons to study

• Accredited by the Institution of Engineering and Technology (IET) to CEng level
offering a streamlined route to professional registration

• Industry placement opportunity
you can chose to undertake a year-long work placement, gaining valuable experience to enhance your practical and professional skills further

• Graduate employability
Our graduates have gone on to work in a variety of specialist roles in diverse industries, including; embedded systems, electronic design and biomedical monitoring

• Access to superb professional facilities
such as general electronics and assembly, digital electronics and microprocessor engineering, power electronics, control systems and communications engineering

• Study a wide range of specialist modules
course content is regularly reviewed and modules have been specifically developed to address skills gaps in the industry

• Academic and research expertise
benefit from teaching by experienced academic and research-based staff, including those from DMU’s dedicated Centre for Electronic and Communications Engineering, who are actively involved in international leadership roles in the sector.Programme

Course Structure

First semester (September to January)

• Digital Signal Processing
• Physics of Semiconductor Devices
• Engineering Business Environment and Energy Policies
• Control and Instrumentation

Second semester (February to May)

• Embedded Systems
• Research Methods
• Electromagnetic Compatibility and Signal Integrity
• Power Electronics

Third semester (June to September)

This is a major research-based individual project

Optional placement
We offer a great opportunity to boost your career prospects through an optional one year placement as part of your postgraduate studies. We have a dedicated Placement Unit which will help you obtain this. Once on your placement you will be supported by your Visiting Tutor to ensure that you gain maximum benefit from the experience. Placements begin after the taught component of the course has been completed - usually around June - and last for one year. When you return from your work placement you will begin your dissertation.

Teaching and Assessment

Modules are delivered through a mixture of lectures, tutorials and laboratories. The methodology ensures a good balance between theory and practice so that real engineering problems are better understood, using strong theoretical and analytical knowledge translated into practical skills.

Contact and learning hours

You will normally attend 4 hours of timetabled taught sessions each week for each module undertaken during term time, for full time study this would be 16 hours per week during term time. You are expected to undertake around 212 further hours of independent study per 30 credit modules. Alternate study modes and entry points may change the timetabled session available, please contact us for details.

Industry Accreditation

he course is fully accredited by the Institution of Engineering and Technology (IET) which is one of the world’s leading professional societies for the engineering and technology community, with more than 150,000 members in 127 countries.

IET accreditation recognises the high standard of the course and confirms the relevance of its content. In order to achieve IET accreditation the course has had to reach a certain standard in areas such as the course structure, staffing, resourcing, quality assurance, student support and technical depth.

The benefits of an IET accredited course include increased opportunities, being looked on favourably by employers and completing the first step in your journey to achieving professional Chartered Engineer (CEng) status which can be applied for following a period of suitable industrial experience after graduation.

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

Facilities

You will have flexible access to our laboratories and workshops which include: electrical and electronic experimental facilities in general electronics and assembly, digital electronics and microprocessor engineering, power electronics, control systems and communications engineering. Each area is equipped with the latest experimental equipment appropriate to the corresponding areas of study and research. An additional CAD design suite provides access to computing facilities with specialist electronics CAD tools including OrCAD and PSpice. A specialised area incorporating a spacious radio frequency reverberation chamber and Faraday cage allows for experimentation in radio frequency engineering and electromagnetics, while our digital design suite is equipped with the latest 8 and 32-bit embedded microprocessor platforms together with high-speed programmable logic development environments. Power generation and conversion, industrial process control and embedded drives are provided while our communications laboratory is additionally equipped for RF engineering.

To find out more

To learn more about this course and DMU, visit our website:
Postgraduate open days: http://www.dmu.ac.uk/study/postgraduate-study/open-evenings/postgraduate-open-days.aspx

Applying for a postgraduate course:
http://www.dmu.ac.uk/study/postgraduate-study/entry-criteria-and-how-to-apply/entry-criteria-and-how-to-apply.aspx

Funding for postgraduate students:
http://www.dmu.ac.uk/study/postgraduate-study/postgraduate-funding-2017-18/postgraduate-funding-2017-18.aspx

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The huge growth of processing power, now available in small power-efficient packages, has fuelled the digital revolution, which has touched all sectors of the economy. Read more

The huge growth of processing power, now available in small power-efficient packages, has fuelled the digital revolution, which has touched all sectors of the economy. This practically orientated, advanced course in the area of electronics design and applications provides a strong digital technology core backed with applications-led modules.

You’ll study applications as diverse as medical and electronics, e-health, intelligent building design, automotive electronics, retail and commerce to prepare you for a range of careers in industry, where the skills you gain will be in high demand. A substantial element of practical work will give you confidence with software and digital hardware implementations using microcontrollers, FPGA, DSP devices and general system-on-chip methodology.

You’ll be taught by experts informed by their own world-leading research, and you’ll have access to world-class facilities to prepare for a career in a fast-changing industry.

Our School is an exciting and stimulating environment where you’ll learn from leading researchers in specialist facilities . These include our Keysight Technologies wireless communications lab, as well as labs for embedded systems, power electronics and drives, ultrasound and bioelectronics.

There’s also a Terahertz photonics lab, class 100 semiconductor cleanroom, traffic generators and analysers, FPGA development tools, sensor network test beds. We have facilities for electron-beam lithography and ceramic circuit fabrication – and a III-V semiconductor molecular beam epitaxy facility.

Accreditation

This course is accredited by the Institution of Engineering and Technology (IET) under licence from the UK regulator, the Engineering Council.

Course content

The programme is built around a set of core modules that will develop your knowledge and skills areas such as digital signal processing, embedded microprocessor systems and how electronics and communications technology could be used in healthcare. You’ll also take a core lab-based module to give you experience of different circuits, systems, equipment and tools.

Optional modules will give you the chance to develop specialist knowledge. If you don’t have any experience of C programming, you’ll take Programming – otherwise, you can choose to take either this module of Software Development. Then you’ll choose one additional module specialising either in data communications and network security or the principles of digital wireless communications.

To build your understanding of the global electronics industry, you’ll also complete a dissertation. This could take the form of a business, manufacturing or outsourcing plan, a proposal for research funding or an essay on a specific aspect of the industry.

Over the summer months you’ll also work on your research project. This gives you the chance to work as an integral part of one of our active research groups, focusing on a specialist topic in computer science and selecting the appropriate research methods.

Want to find out more about your modules?

Take a look at the Embedded Systems Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Industry Dissertation 15 credits
  • Digital Signal Processing for Communications 15 credits
  • Mini Projects and Laboratory 15 credits
  • FPGA Design for System-on-Chip 15 credits
  • Digital Media Engineering 15 credits
  • Embedded Microprocessor System Design 15 credits
  • Medical Electronics and E-Health 15 credits
  • Main Project 45 credits

Optional modules

  • Digital Wireless Communications Principles 15 credits
  • Data Communications and Network Security 15 credits
  • Programming 15 credits
  • Software Development 15 credits

For more information on typical modules, read Embedded Systems Engineering MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The research project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

A proportion of projects are formally linked to industry, and may include spending time at the collaborator’s site over the summer.

Career opportunities

Embedded systems are ubiquitous in engineering and graduates are likely to find employment in a wide and diverse range of industries including: communications, automotive, transport, construction, industrial, automation, energy and environmental monitoring

Careers support

You’ll have access to the wide range of engineering and computing careers resources held by our Employability team in our dedicated Employability Suite. You’ll have the chance to attend industry presentations book appointments with qualified careers consultants and take part in employability workshops. Our annual Engineering and Computing Careers Fairs provide further opportunities to explore your career options with some of the UK’s leading employers.

The University's Careers Centre also provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website



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This is an MSc course in Embedded Systems with contributions from the fields of mechatronics and robotics. Embedded systems are microprocessor-based systems within a larger mechanical or electrical system that performs a dedicated function or task. Read more
This is an MSc course in Embedded Systems with contributions from the fields of mechatronics and robotics.

Embedded systems are microprocessor-based systems within a larger mechanical or electrical system that performs a dedicated function or task. They encompass a wide variety of products ranging from small mobile phones to large process automation installations. A practicing engineer in the field of embedded systems needs to have a specialised expertise in more than one of the engineering subjects of this multi-discipline subject.

Our MSc is tailored to provide you with advanced learning in microprocessor systems that are at the heart of embedded systems, with additional contributions from the fields of mechatronics and robotics. This approach reflects the needs of the industry and is well supported by the range in expertise we have in our Department.

The Department of Engineering and Design covers the full gamete of teaching in electronic, telecommunication and computer networks engineering as well as mechanical engineering and product design.

Our academics are a cohesive group of highly skilled lecturers, practitioners and researchers. You'll benefit from your choice of supervisors to support a wide range of modern and multi-discipline Masters-level projects. Our teaching is supported by well-equipped laboratory workshops, using mostly the latest hardware and software available in universities.

Modules

In each of the semesters 1 and 2 you will be required to take two core and one optional module from the lists below:

Semester 1:

•Robotics (20 credits)
• Microprocessors and Control (20 credits)

Optional modules (Semester 1):

• Pattern recognition and machine learning (20 credits)
• Technical, research and professional skills (20 credits)
• Advanced Instrumentation and Design (20 credits)
• Electrical Energy Converters and Drives (20 credits)

Semester 2:

• Digital Signal Processing and Real Time Systems (20 credits)
• Mechatronics and Embedded System Design (20 credits)

Optional modules (Semester 2):

• Electromechanical systems and manufacturing technology (20 credits)
• Technology evaluation and commercialisation (20 credits)
• Cloud Computing (20 credits)
• E-Business Applications (20 credits)

Semester 3

•MSc project (60 credits)

Professional links

The School of Engineering at LSBU has a strong culture of research, extensive research links with industry through consultancy works and Knowledge Transfer Partnerships (KTPs), and teaching content is closely related to the latest research findings in the field.

History and expertise

A strong research tradition and our industrial links has helped shaped the course design, content selection, course delivery and project supervision.

The Department of Engineering and Design has a strong Mechatronics, Robotics and Non-destructive testing research group with a wide national and international profile. This is in addition to excellent research in many areas of mechanical engineering, electrical engineering, product design, computer network and telecommunications engineering.

Employability

The course has been designed to help to meet the needs of industry. How much your employability will increase, will depend on your background and the personal contribution you make to your development whilst studying on the course.

Benefits for new graduates

If you are a new graduate in electronic or computer engineering then you benefit from the further advanced topics presented. You'll get an opportunity to cut your teeth on a challenging MSc Project, which will demonstrate your abilities to the potential employers. Alternatively, you could also pursue PhD studies after completing the course.

Benefits of returning to University

If you are returning to University after a period of working in industry, then you'll be able to update yourself with the recent technological progress in the field. You'll gain confidence in your ability to perform at your best and stand a better chance to seek challenging work opportunities. If you are already working in the field, the MSc qualification will enhance your status which will may help with your promotion.

Employment links

We are continually developing links with employers who are interested to provide internship to our students . Examples of this can include small VHDL and DSP designs, ARM based designs, industrial design or correlation research. These projects can be performed as part of the curriculum or as part of a research project.

LSBU Employability Services

LSBU is committed to supporting you develop your employability and succeed in getting a job after you have graduated. Your qualification will certainly help, but in a competitive market you also need to work on your employability, and on your career search. Our Employability Service will support you in developing your skills, finding a job, interview techniques, work experience or an internship, and will help you assess what you need to do to get the job you want at the end of your course. LSBU offers a comprehensive Employability Service, with a range of initiatives to complement your studies, including:

• Direct engagement from employers who come in to interview and talk to students
• Job Shop and on-campus recruitment agencies to help your job search
• Mentoring and work shadowing schemes.

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Digital signal processing (DSP) is at the core of the communications revolution. Research is constantly being carried out to develop new DSP algorithms, allowing mobile broadband services, ‘Internet of Things’ applications and other technologies to be delivered to a growing number of users. Read more

Digital signal processing (DSP) is at the core of the communications revolution. Research is constantly being carried out to develop new DSP algorithms, allowing mobile broadband services, ‘Internet of Things’ applications and other technologies to be delivered to a growing number of users.

This programme will give you a thorough understanding of different aspects of DSP and as it relates to the communications landscape, as well as specialist knowledge from your choice of optional modules.

Our DSP lab will give you hands-on experience using the DSP technology that can be found in computers, cellular phones, GPS and other technologies, and you’ll learn from expert researchers at the forefront of their fields.

You’ll also benefit from specialist industrial lectures, allowing you to relate the theoretical and design aspects of communications and signal processing to practical problems and real-world constraints.

School Facilities

Our School is an exciting and stimulating environment where you’ll learn from leading researchers in specialist facilities. These include our Keysight Technologies wireless communications lab, as well as labs for embedded systems, power electronics and drives, ultrasound and bioelectronics.

There’s also a Terahertz photonics lab, class 100 semiconductor cleanroom, traffic generators and analysers, FPGA development tools, sensor network test beds. We have facilities for electron-beam lithography and ceramic circuit fabrication – and a III-V semiconductor molecular beam epitaxy facility. The Faculty is also home to the £4.3 million EPSRC National Facility for Innovative Robotic Systems, set to make us a world leader in robot design and construction.

Course content

Throughout the year you’ll study a set of core modules that give you an in-depth understanding of DSP, wireless communications, different optical communications networks and the complex issues around network security. If you don’t have any experience of c-programming you’ll also take a module that develops these skills; alternatively, you can choose between this module and another on software development.

You’ll also select optional modules that are tailored to your own interests or career plans – you could focus on embedded microprocessor systems, high-speed internet architecture or other topics. To build your understanding of the global electronics industry, you’ll also complete a dissertation. This could take the form of a business, manufacturing or outsourcing plan, a proposal for research funding or an essay on a specific aspect of the industry.

Over the summer months you’ll also work on your research project. This gives you the chance to work as an integral part of one of our active research groups, focusing on a specialist topic in computer science and selecting the appropriate research methods.

Want to find out more about your modules?

Take a look at the Communications and Signal Processing module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Industry Dissertation 15 credits
  • Wireless Communications Systems Design 15 credits
  • Digital Signal Processing for Communications 15 credits
  • Digital Wireless Communications Principles 15 credits
  • Optical Communications Networks 15 credits
  • Data Communications and Network Security 15 credits
  • Main Project 45 credits

Optional modules

  • Cellular Mobile Communication Systems 15 credits
  • High Speed Internet Architecture 15 credits
  • FPGA Design for System-on-Chip 15 credits
  • Embedded Microprocessor System Design 15 credits
  • Programming 15 credits
  • Software Development 15 credits

For more information on typical modules, read Communications and Signal Processing MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings. Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The research project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects on the MSc in Communications and Signal Processing include:

  • Powerline communications for smart grid
  • Quantum key distribution over passive optical networks
  • Physical layer security using artificial noise
  • An energy-saving robot mobility diversity algorithm for wireless communications
  • Analysis and processing of physiological data from a smart watch to monitor health
  • Evaluation of wireless sensor networks for civil engineering applications
  • Cooperative wireless communications over fading channels
  • Carrier frequency offset compensation in OFDM for IEEE 802.11
  • Underlay spectrum access strategy in cognitive radio
  • Spectrum sensing for cognitive radio

Career opportunities

On completing this course, you will have obtained the skills that will lead to employment in any area of the communications/signal processing industry including optical networking, DSP design and implementation, cellular mobile, RF planning, broadband systems and general communications research and development.

Graduates from our School have gone on to work for organisations such as the National Grid, Ericsson Telecommunications, Cisco Systems, AECOM, Deep Sea Electronics, Huawei, Intel Corp., the Technology and Strategy Board and many more.

This course is also an excellent base from which to pursue a PhD and possibly an academic career.



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The control and conversion of electric power using solid-state techniques are now commonplace in both the domestic and industrial environments. Read more
The control and conversion of electric power using solid-state techniques are now commonplace in both the domestic and industrial environments. A knowledge and understanding of the diverse disciplines encompassed by Power Electronics: devices, converters, control theory and motor drive systems, is now essential to all power engineers. Power electronics, driven by the need for greater energy efficiency and more accurate control of a wide range of systems, is developing rapidly.

This course aims to provide specialist education in power electronics and drive techniques, covering key fundamental principles along with modern applications and current practices. It provides a specialist education in power electronics and drives techniques, covering key fundamental principles along with modern applications and current practices.

Students will develop:

the analytical and critical powers for the development of hardware and software required for power electronics and drives
the ability to plan and undertake an individual project
interpersonal, communication and professional skills
the ability to communicate ideas effectively in written reports
the technical skills to equip them for a leading career in power electronics or electrical machine drive systems
an understanding of how power electronics are applied within key industries such as aerospace and power supply

Following the successful completion of the taught modules, an individual research project is undertaken during the summer term.

Previous research projects on this course have included:

Development of a microprocessor controlled variable speed permanent magnet motor for an aerospace application
Experimental determination of induction motor torque-speed curves under variable speed
Evaluation of stray reactance in a current source rectifier for marine propulsion motor drives and wind power generators
Design, build and testing of a DSP-controlled switched reluctance motor for an automotive power assisted steering application

Scholarship information can be found at http://www.nottingham.ac.uk/graduateschool/funding/index.aspx

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On this well-established MSc programme you willdevelop advanced knowledge and skills in key aspects of telecommunications and wireless systems. Read more
On this well-established MSc programme you willdevelop advanced knowledge and skills in key aspects of telecommunications and wireless systems.

The course content is updated annually to maintain industry relevance and to reflect the latest developments in the industry.

We cover the following core (compulsory) topics during the MSc:

- Embedded computer systems
- Digital system design
- IC design
- Microprocess systems
- Research skills and project management.

Part-time study is in co-operation with the students’ employers. Please contact the Programme Director before applying.

Projects

Your project work will earn you 60 credits towards your MSc degree. The project's examined by oral presentation and dissertation.

In your work you'll need to demonstrate an in-depth understanding of your topic, mastery of research techniques, and the ability to analyse assembled data and assess outcomes.

Why Electrical Engineering and Electronics?

World-class facilities, including top industry standard laboratories

We have specialist facilities for processing semiconductor devices, optical imaging spectroscopy and sensing, technological plasmas, equipment for testing switch gear, specialist robot laboratories, clean room laboratories, e-automation, RF Engineering, bio-nano engineering labs and excellent mechanical and electrical workshops.

A leading centre for electrical and electronic engineering expertise

We are closely involved with over 50 prominent companies and research organisations worldwide, many of which not only fund and collaborate with us but also make a vital contribution to developing our students.

Career prospects

Our postgraduate students get to be a part of the cutting edge research projects being undertaken by our academic staff.

Here are some of the areas these projects cover:-

Molecular and semiconductor integrated circuit electronics
Technological plasmas
Communications
Digital signal processing
Optoelectronics
Nanotechnology
Robotics
Free electron lasers
Power electronics
Energy efficient systems
E-Automation
Intelligence engineering.

You'll get plenty of industry exposure too. Our industrial partners include ARM Holdings Plc, a top 200 UK company that specialises in microprocessor design and development.

As a result our postgraduates have an impressive record of securing employment after graduation in a wide range of careers not limited to engineering.

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This advanced course focuses on enabling you to become proficient in communicating across a range of different disciplines and delivering optimised engineering solutions using an integrated multidisciplinary mechatronics approach. Read more

About the course

This advanced course focuses on enabling you to become proficient in communicating across a range of different disciplines and delivering optimised engineering solutions using an integrated multidisciplinary mechatronics approach. You will be exposed to a broad range of engineering disciplines, be able to solve multidisciplinary mechatronics problems and develop the skills to apply a mechatronic approach to the solution of technical problems.

Reasons to Study

• Accredited by the Institution of Engineering and Technology (IET)
ensuring you will benefit from the highest quality teaching, and graduate with a recognised qualification

• Graduate employability
Mechatronic engineers are in high demand as more industries seek to apply advances across a range of engineering disciplines

• Enjoy access to state-of-the-art facilities
including dedicated mechanical, electrical and electronic laboratories especially suited for mechatronics, as well as an for the manufacture of student designs

• Industry placement opportunity
you can chose to undertake a year-long work placement, gaining valuable experience to enhance your practical and professional skills further

• Work with leading research groups
you will be offered opportunities to work on projects with research groups within the faculty, including the Centre for Advanced Manufacturing Processes and Mechatronics, that are engaged in high-class, research and industrial collaboration and consultancy

• Course content relevant to modern day practice
our research informs our teaching, ensuring the course content covers current industry topics and issues

• Excellent graduate prospects
graduates enjoy exciting career opportunities in a range of fields such as robotics and automation, manufacturing, aerospace, material processing, energy and power.

Modules

First semester (September to January)

• Electromechanics
• Mechatronic Systems - Engineering and Design
• Engineering Business Environment and Energy Studies
• Programming and Software Engineering

Second semester (February to May)

• Machine Vision, Robotics and Flexible Automation
• Engineering Systems: Dynamics and Control
• Microprocessor Applications and Digital Signal Processing
• Research Methods

Individual Project (Stage three)

This research can be industrially-based or linked to an industrial partner, attached to one of the mechatronic-related research teams within the faculty or in other collaborating institutions. The research project should be in an area relevant to Mechatronics, where clear evidence of the ability to solve a real multidisciplinary problem is demonstrated. The project assessment involves a formal presentation, production of a technical paper and a thesis.

Optional placement
We offer a great opportunity to boost your career prospects through an optional one year placement as part of your postgraduate studies. We have a dedicated Placement Unit which will help you obtain this. Once on your placement you will be supported by your Visiting Tutor to ensure that you gain maximum benefit from the experience. Placements begin after the taught component of the course has been completed - usually around June - and last for one year. When you return from your work placement you will begin your dissertation.

Teaching and assessment

Teaching is delivered through a variety of methods including lectures, tutorials and laboratories. You will be expected to undertake self-directed study.

Contact and learning hours

For taught sessions you will attend eight modules with a total of 48 hours (four hours per week for 12 weeks each), with eight hours per module per week of average additional self-directed study. For the individual project you normally will spend 13 weeks working five days (eight hours per day) a week to complete it, and have one hour per week contact time with your supervisor.

Academic expertise

Research is carried out by the Mechatronics Research Centre, which holds a considerable number of UK and EU research project grants and has collaborative research links with more than 100 national and international organisations. The group is internationally regarded and specialises in machine design, control and simulation, fluid power systems and motion control.

As part of your studies, you will be offered opportunities to work on projects with research groups within the faculty that are engaged in high-class, leading-edge research and industrial collaboration and consultancy.

During the project element of the course, the Intelligent Machines and Automation Systems (IMAS) Research Laboratory provides access to dedicated research facilities

To find out more

To learn more about this course and DMU, visit our website:
Postgraduate open days: http://www.dmu.ac.uk/study/postgraduate-study/open-evenings/postgraduate-open-days.aspx

Applying for a postgraduate course:
http://www.dmu.ac.uk/study/postgraduate-study/entry-criteria-and-how-to-apply/entry-criteria-and-how-to-apply.aspx

Funding for postgraduate students
http://www.dmu.ac.uk/study/postgraduate-study/postgraduate-funding-2017-18/postgraduate-funding-2017-18.aspx

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Ideal for you if you are a professional with a background in computer engineering, communication systems or electronic/electrical engineering, and provides you with the skills and knowledge needed to move into computer networking. Read more

Ideal for you if you are a professional with a background in computer engineering, communication systems or electronic/electrical engineering, and provides you with the skills and knowledge needed to move into computer networking. It is particularly useful for people working in companies that rely on constant innovation in electronics, computer engineering and communications.

Computer networks currently provide the infrastructure for most, businesses, educational institutions, retailers, manufacturers and public services. Many companies rely increasingly on computer and network engineering, which is now a global discipline.

This course is hardware and software based, and examines the design, specification, and integration of current and next generation computer and communications network technologies.

This course provides an opportunity for you to

  • increase the depth of your technical knowledge
  • develop your computer hardware and software skills
  • gain a thorough working knowledge of computer engineering
  • study the latest technologies used in modern day computer networking systems and their applications
  • gain the skills needed to design, develop and maintain computer network systems

You may wish to expand your current knowledge and expertise if you already have computer networking skills or possibly move into a new area of engineering and have the necessary entry requirements for this course.

Professional recognition

This programme is CEng accredited by the Institution of Engineering and Technology (IET) and fulfils the educational requirements for registration as a Chartered Engineer when presented with an CEng accredited Bachelors programme.

Course structure

Full time – September start – typically 12 or 18 months

Full time – January start – typically 12 or 18 months

Part time – September start – typically 36 months

Part time – January start – typically 36 months

The course is based around two main themes, communication and networks, and computer engineering. You study eight modules plus a major project.

Communications and network modules

At least three from

  • communication engineering
  • communication media
  • communication networks
  • network applications

Computer engineering modules

At least three from

  • microprocessor engineering
  • object-oriented methods
  • operating systems
  • software engineering

Option modules

Up to two from

  • applicable artificial intelligence
  • digital signal processing
  • embedded systems
  • mixed signal design
  • electrical energy systems
  • efficient machines and electromagnetic applications

Project (equivalent to four modules)

You undertake a major project under the supervision of a tutor.

Assessment

By final examination, coursework and project reports

Employability

Information technology, communications, computer networks and electronics are among some of the fastest growing areas of the economy. By completing this course, you gain a thorough understanding of computer networking systems with the knowledge and expertise to enable you to apply your skills within many areas of industry, or take up a position in higher education or research.



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Engineering is constantly changing, and graduates often need to deepen their technical skills and understanding. This course is especially relevant for mechanical and manufacturing engineers and technicians wishing to broaden their industrial and managerial skills. Read more

Engineering is constantly changing, and graduates often need to deepen their technical skills and understanding.

This course is especially relevant for mechanical and manufacturing engineers and technicians wishing to broaden their industrial and managerial skills. It is ideal for continuing professional development and updating technical skills.

You study eight taught modules drawn from a wide choice of technical and management modules. This gives you advanced tuition in areas of engineering tailored to your career needs such as design, manufacturing, materials, networking or electronics and telecommunications.

We emphasise applying knowledge to relevant workplace skills in areas such as

  • design, manufacture, electronics, telecommunications and information technology, networking and materials
  • core management disciplines of quality, finance and marketing and others

The international product development module involves working in multidisciplinary teams to design and develop a product in the global market.

This flexible course helps you to develop your career based your needs, and helps you on your path towards Chartered Engineer status.

Professional recognition

This course is accredited by the Institute of Materials, Minerals and Mining (IOM3), on behalf of the Engineering Council, for the purposes of partly meeting the academic requirement for registration as a Chartered Engineer; graduates who have a BEng (Hons) accredited for CEng will be able to show that they have satisfied the further learning requirement for CEng accreditation.

This course is also accredited by the Institution of Mechanical Engineers (IMechE) on behalf of the Engineering Council and will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer. Accredited MSc graduates who also have a BEng (Hons) accredited for CEng, will be able to show that they have satisfied the educational base for CEng registration. It should be noted that graduates from an accredited MSc programme, who do not also have an appropriately accredited Honours degree, will not be regarded as having the exemplifying qualifications for professional registration as a Chartered Engineer with the Engineering Council; and will need to have their first qualification individually assessed through the Individual Case Procedure if they wish to progress to CEng.

This programme is CEng accredited by the Institution of Engineering and Technology (IET) and fulfils the educational requirements for registration as a Chartered Engineer when presented with an CEng accredited Bachelors programme.

Course structure

You choose a combination of management, technical and optional modules from a choice of 36. Your choice must total eight 15-credit modules and be agreed with your course leader. At least four must be technical modules.

Optional management modules

  • finance and marketing
  • project and quality management
  • management of strategy, change and innovation
  • lean operations and six sigma
  • manufacturing systems

Optional technical modules

• group project - international product development • competitive materials technology • advanced CAD/CAM • competitive design for manufacture • advanced manufacturing technology • advanced metallic materials • sustainability, energy and environmental management • computer networks • communication media • network applications • communication engineering • digital signal processing • applicable artificial intelligence • microprocessor engineering • software engineering • operating systems • object oriented methods • digital electronic system design • VLSI design • industrial applications of finite element methods • industrial automation • robotics • machine vision • equipment engineering and design • control of linear systems • advanced investigatory techniques for materials engineers • advanced control methods • advanced vibration and acoustics

MSc

  • project and dissertation (60 credits)

Assessment

By final examination, coursework and project reports    

Employability

Graduates in technical subjects can broaden their experience in mechanical manufacturing, electronics and information technology, networking, materials and management areas.

The flexible choice of modules allows you to tailor the course to your particular needs and this can enhance career prospects in the engineering industry, research, teaching and public service.

   



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This course is for engineers or graduates who want to become technical specialists or managers in industrial and manufacturing companies. Read more

This course is for engineers or graduates who want to become technical specialists or managers in industrial and manufacturing companies.

It increases your career potential by improving your

  • knowledge and experience of engineering
  • technical and problem solving skills
  • management skills
  • ability to take on greater responsibility

This course helps you understand concepts and theories behind developing, manufacturing and managing engineering products and systems. You learn to explore and apply developments in engineering and management academic thinking and industrial practice.

You study

  • two management modules
  • two technical modules
  • four optional modules

There is a wide range of optional modules including • lean operations and six sigma • advanced manufacturing technology • applicable artificial intelligence • computer-aided design/computer-aided manufacture • advanced computer system architecture • network applications.

The international product development module involves working in multidisciplinary teams to develop a new product in a global market. This allows you to develop much sought after advanced technical and business skills and improves your career prospects in engineering industry, and public service. This project also develops your particular interest in a supported environment.

Professional recognition

This course is accredited by the Institute of Materials, Minerals and Mining (IOM3), on behalf of the Engineering Council, for the purposes of partly meeting the academic requirement for registration as a Chartered Engineer; graduates who have a BEng (Hons) accredited for CEng will be able to show that they have satisfied the further learning requirement for CEng accreditation.

This course is also accredited by the Institution of Mechanical Engineers (IMechE) on behalf of the Engineering Council and will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer. Accredited MSc graduates who also have a BEng (Hons) accredited for CEng, will be able to show that they have satisfied the educational base for CEng registration. It should be noted that graduates from an accredited MSc programme, who do not also have an appropriately accredited Honours degree, will not be regarded as having the exemplifying qualifications for professional registration as a Chartered Engineer with the Engineering Council; and will need to have their first qualification individually assessed through the Individual Case Procedure if they wish to progress to CEng.

This programme is CEng accredited by the Institution of Engineering and Technology (IET) and fulfils the educational requirements for registration as a Chartered Engineer when presented with an CEng accredited Bachelors programme.

Course structure

Core management modules

  • Finance and marketing
  • Project and quality management

Core technical modules

  • Group project – international product development
  • Sustainability, energy and environmental management

Optional modules

Two from

• lean operations and six sigma • management of strategy, change and innovation • manufacturing systems

plus two from

• advanced control methods • advanced investigatory techniques for materials engineers • advanced manufacturing technology • advanced metallic materials • advanced vibration and acoustics • applicable artificial intelligence • computer-aided design/computer-aided manufacturing • communication engineering • communication media • computer networks • competitive design for manufacture • competitive materials technology • control of linear systems • digital electronics system design • digital signal processing • embedded systems • equipment engineering and design • industrial applications of finite element methods • industrial automation • machine vision • microprocessor engineering • advanced computer system architecture • network applications • object-oriented methods • operating systems • robotics • software engineering • VSLI

MSc

  • Project and dissertation

Assessment

  • examination
  • coursework
  • project reports

Employability

If you are a new graduate, this course gives you the knowledge and skills to begin a career as a technical specialist or manager. If you are already employed in engineering, it improves you career potential and can lead to roles with greater responsibility.

It can also help towards a career teaching engineering.



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Most people aren't familiar with Embedded Systems, but we use them every day of our lives. Smartphones, digital TV, MP3s and iPods, washing machines, even toys or a talking greetings card they all contain a microprocessor or a microcontroller. Read more
Most people aren't familiar with Embedded Systems, but we use them every day of our lives. Smartphones, digital TV, MP3s and iPods, washing machines, even toys or a talking greetings card they all contain a microprocessor or a microcontroller. Embedded systems are the backbone of the digital revolution.

As the complexity of embedded systems increases, the industry needs skilled graduates to fill the talent shortage.

Course detail

With the MSc Embedded Systems and Wireless Networks you'll develop a sound technical knowledge of the fundamentals of electronics, embedded systems, software and hardware, and become an embedded system designer with a multidisciplinary background. You'll develop software programming and hardware design skills, and a broad knowledge of electronics fundamentals.

Graduates of electronic engineering, systems engineering or other appropriate sciences can develop, deepen or update their skills and knowledge in advanced electronic engineering technology and cutting-edge research fields.

This course is ideal for graduate engineers interested in electronics, embedded systems, signal processing, mobile communications and wireless technology.

Modules

• Embedded Real-time Control Systems
• Safety Critical Embedded Systems
• Wireless and Mobile Communications
• Advanced Control and Dynamics
• System Design using HDLs
• Wireless Sensor Networks
• Group Project Challenge
• Dissertation

Format

You'll be taught by experienced specialist academic staff who are experts in basic and advanced electronics, control systems, basic and advanced robotics, mobile communications, wireless sensor networks, embedded systems, power systems, power electronics, signal processing and sensor technology. Many of them are involved in cutting-edge research.

You'll attend lectures, then apply what you've learned to real life through tutorial sessions, case studies, classroom discussions, project work, laboratory exercises and visits to or guest lectures from professionals working in engineering organisations.

Assessment

You are assessed through examinations, coursework, lab-based assessment and oral presentations. An independent examiner assesses your dissertation.

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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Commercial products today combine many technologies, and industry is increasingly interdisciplinary. This course is designed to meet this demand, giving you an interdisciplinary knowledge base in modern electronics including power, communications, control and embedded processors. Read more

Commercial products today combine many technologies, and industry is increasingly interdisciplinary. This course is designed to meet this demand, giving you an interdisciplinary knowledge base in modern electronics including power, communications, control and embedded processors.

You’ll develop a broad grasp of a range of interlocking disciplines, combining core modules developing your practical lab skills and industry awareness with a range of optional modules that allow you to focus on topics that suit your interests or career plans. Next-generation silicon technologies, electric drives and generating electric power from renewable sources are among the topics you could study.

This course will appeal to people with a broad interest in electronics and communications, as well as those who are interested in modern communications techniques, radio propagation, cellular mobile systems, control systems, power and drives, and modern system on-chip technology.

Specialist facilities

Our School is an exciting and stimulating environment where you’ll learn from leading researchers in specialist facilities. These include our Keysight Technologies wireless communications lab, as well as labs for embedded systems, power electronics and drives.

Depending on your choice of project, you may have use of our Terahertz photonics lab, ultrasound and bioelectronics labs, class 100 semiconductor cleanroom, traffic generators and analysers, FPGA development tools, sensor network test beds.

The School also contains facilities for electron-beam lithography and ceramic circuit fabrication – and a III-V semiconductor molecular beam epitaxy facility. The Faculty is also home to the £4.3 million EPSRC National Facility for Innovative Robotic Systems, set to make us a world leader in robot design and construction.

Accreditation

This course is accredited by the Institution of Engineering and Technology (IET) under licence from the UK regulator, the Engineering Council.

Course content

Throughout the course you’ll choose from a range of optional modules that allow you to pursue topics across electronic and electrical engineering as they relate to your interests or career plans. You could focus on FPGA design for system-on-chip, wireless communications systems nano-electromechanical systems among many others to gain a broad and deep understanding a range of subjects.

A set of core modules will support your learning. You’ll take part in a range of experiments linked to your subject on our lab module, and you’ll develop your skills in programming. If you have no experience of C programming you’ll take the Programming module, or you can take Software Development if you already have those skills.

To build your understanding of the global electronics industry, you’ll also complete a dissertation. This could take the form of a business, manufacturing or outsourcing plan, a proposal for research funding or an essay on a specific aspect of the industry.

Over the summer months you’ll also work on your research project. This may give you the chance to work as an integral part of one of our active research groups, focusing on a specialist topic in computer science and selecting the appropriate research methods.

Want to find out more about your modules?

Take a look at the Electronic and Electrical Engineering module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Industry Dissertation 15 credits
  • Mini Projects and Laboratory 15 credits
  • Main Project 45 credits

Optional modules

  • Wireless Communications Systems Design 15 credits
  • Micro- and Nano-Electromechanical Systems 15 credits
  • Power Electronics and Drives 15 credits
  • Electric Power Generation by Renewable Sources 15 credits
  • Electric Drives 15 credits
  • FPGA Design for System-on-Chip 15 credits
  • Control Systems Design 15 credits
  • Embedded Microprocessor System Design 15 credits
  • Medical Electronics and E-Health 15 credits
  • Programming 15 credits
  • Software Development 15 credits

For more information on typical modules, read Electronic and Electrical Engineering MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings.

Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The professional project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects by students in the School of Electronic and Electrical Engineering have included:

  • Wireless sensor networks, the internet of things and bicycle traffic in the city.
  • Device to Monitor Activity of Ageing People
  • Wind turbine strain gauge system
  • Wind turbine teaching demonstrator
  • Virtual Machines Placement in Core Networks with Renewable Energy
  • Design and Analysis of High-Performance Internet Routers
  • Spatial Modulation for Massive MIMO System
  • Fuel cell for energy storage
  • Low cost design and fabrication of 3D MEMS components
  • Ultrasonic Wind Speed Detection
  • Core Quantum Networks
  • Microwave Low Noise Amplifier

A proportion of projects are formally linked to industry, and can include spending time at the collaborator’s site over the summer.

Career opportunities

Graduates of this course can expect to find jobs where industry needs a breadth of knowledge matched by a depth in certain areas.

You’ll be well equipped to integrate and co-ordinate the strands of a cross-disciplinary project and manage the interfaces between specialities. With these skills, you’ll be in a good position to progress to project management roles in companies working at the cutting edge of modern multi-faceted systems.

General Electric, AECOM, Deep Sea Electronics, Hyperdrive Innovation, Descon Engineering, Broadcom, Pakistan Oilfields Ltd., Wabtec Rail UK and many others are among the organisations where graduates from our School have found employment.



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MSc. This MSc is designed to provide instruction and training in the most recent developments in equipment and systems used to interface and control renewable and sustainable energy systems. Read more
MSc:

This MSc is designed to provide instruction and training in the most recent developments in equipment and systems used to interface and control renewable and sustainable energy systems. The course provides essential knowledge both for electrical
engineers wanting to work within the renewable energy systems industry, and for engineers planning a research career in the field.

Students will develop:
advanced and comprehensive knowledge of the specialist
engineering skills required by an engineer working in this field
the ability to plan and undertake an individual project
interpersonal, communication and professional skills
the ability to communicate ideas effectively in written reports
the technical knowledge and skills to equip them for a leading career in engineering for renewable and sustainable energy technologies, electrical engineering and power engineering
the ability to design, analyse and evaluate hardware and software aspects of renewable and energy efficient power systems
decision making powers in relation to the specification and solution of power electronics, power systems and electrical
engineering problems for appropriate renewable and sustainable energy technologies

Following the successful completion of the taught modules, an individual research project is undertaken during the summer term.

Previous research projects on this course have included:
the design of a DC-DC voltage convertor with maximum power tracking for a photovoltaic module
electrical modelling of a PEM fuel Cell
microprocessor based control of a wind turbine generator
optimisation of the operation of a renewable energy micro grid

Scholarship information can be found at http://www.nottingham.ac.uk/graduateschool/funding/index.aspx

PGDip:

The Postgraduate Diploma Electrical Engineering for Sustainable and Renewable Energy is designed to provide instruction and training in the most recent developments in the equipment and systems used to interface and control renewable and sustainable energy systems.

This knowledge is essential both for an engineer wanting to work in research and development in electrical engineering for renewable energy systems in industry. The course will give you an advanced and comprehensive coverage of the specialist engineering skills required by an engineer working in electrical technology for renewable and sustainable energy systems.

Key facts

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Microprocessor manufacturers have recently presented the software industry with its most serious challenge ever, by switching from serial execution architectures clocked at ever-increasing clock rates to ever-more parallel multi-core architectures clocked at a constant (or even decreasing) clock rate. Read more
Microprocessor manufacturers have recently presented the software industry with its most serious challenge ever, by switching from serial execution architectures clocked at ever-increasing clock rates to ever-more parallel multi-core architectures clocked at a constant (or even decreasing) clock rate. The consequences will be profound because parallel computational activities will need to be handled as the norm, rather than the exception; programmers of the future will need skills that are currently possessed by very few, due to the inherent complexities of parallel systems.

This pathway is centred round a core theme, Parallel Computing in the Multi-core Era , that introduces students to the aforementioned complexities, and provides techniques and tools that can alleviate the ensuing problems of correctness, reliability, performance and system management. Subsidiary themes allow students to investigate broader areas in which they might apply their newly learned skills.

Teaching and learning

Computational thinking is becoming increasingly pervasive and is informing our understanding of phenomena across a range of areas; from engineering and physical sciences, to business and society. This is reflected in the way the Manchester course is taught, with students able to choose from an extremely broad range of units that not only cover core computer science topics, but that draw on our interdisciplinary research strengths in areas such as Medical and Health Sciences, Life Sciences and Humanities.

Coursework and assessment

Lectures and seminars are supported by practical exercises that impart skills as well as knowledge. These skills are augmented through an MSc project that enables students to put into practice the techniques they have been taught throughout the course.

Facilities

-Newly refurbished computing labs furnished with modern desktop computers
-Access to world leading academic staff
-Collaborative working labs complete with specialist computing and audio visual equipment to support group working
-Over 300 Computers in the School dedicated exclusively for the use of our students
-An Advanced Interfaces Laboratory to explore real time collaborative working
-A Nanotechnology Centre for the fabrication of new generation electronic devices
-An e-Science Centre and Access Grid facility for world wide collaboration over the internet
-Access to a range of Integrated Development Environments (IDEs)
-Specialist electronic system design and computer engineering tools

Career opportunities

Students following the Multi-Core Computing pathway have all the career options as described for general Advanced Computer Science.

In addition, students following this pathway are well placed for careers in the software industry since they will acquire the necessary skills to design and develop software that makes the most out of state-of-the-art multi-core architectures. This includes the games industry, the financial sector, and all other areas in which high performance computing is key.

We maintain close relationships with potential employers and run various activities throughout the year, including career fairs, guest lectures, and projects run jointly with partners from industry.

Accrediting organisations

This programme is CEng accredited and fulfils the educational requirements for registration as a Chartered Engineer when presented with a CEng accredited Bachelors programme.

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The increased need for communications in modern day society has led to the development of a complex global communication infrastructure that uses the latest wireless and wired technologies for the communication of information. Read more

The increased need for communications in modern day society has led to the development of a complex global communication infrastructure that uses the latest wireless and wired technologies for the communication of information.

To keep up with the increasing demands placed on this infrastructure requires engineers with the latest knowledge of and skills in current and emerging technologies.

Studying this course enables you to gain an advanced understanding of current telecommunications and electronic systems and acquire the skills necessary for their design, development and maintenance.

You study key technical areas such as digital electronics and communications with the option of selecting management modules to develop your project and managerial ability.

A number of option modules ranging from artificial intelligence to software engineering allow you to focus your studies towards your career aspirations and tailor the course to your requirements.

As well as improving your technical skills and knowledge, we also focus on building wider professional skills, such as planning, research techniques and promoting innovation.

We emphasise learning through practical investigations and problem solving, where you explore the complex issues that are typical of modern telecommunication systems typically through real world case studies. You complete a major project, supported by a project tutor, in an area of your choice allowing you to focus on a topic that can contribute to your career aims.

Professional recognition

This programme is CEng accredited by the Institution of Engineering and Technology (IET) and fulfils the educational requirements for registration as a Chartered Engineer when presented with an CEng accredited Bachelors programme.

Course structure

Core modules

  • Communication media
  • Digital electronic system design
  • Project

Management modules

Choose up to two from

  • Finance and marketing
  • Management of strategy, change and innovation
  • Project and quality management

Options

Choose up to six from

• advanced control methods • applicable artificial intelligence • communication engineering • computer networks • control of linear systems • microprocessor engineering • digital signal processing • group project – international product development • network applications • object-oriented methods • operating systems • software engineering • machine vision • embedded systems • mixed signal design • electrical energy systems • efficient machines and electromagnetic applications.

Assessment

  • coursework
  • examinations
  • project reports

Employability

One of the primary motivations in developing this course is to enhance your employability or to allow you to progress to higher levels of study such as academic research.

You can consider employment in a number of areas of telecommunications and electronics at senior and management level or alternatively undertake further study by working towards a research degree and pursue a career possibly in academia.



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