• Swansea University Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • Goldsmiths, University of London Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • Jacobs University Bremen gGmbH Featured Masters Courses
  • University of Southampton Featured Masters Courses
  • Anglia Ruskin University Featured Masters Courses
  • Ross University School of Veterinary Medicine Featured Masters Courses
University of Manchester Featured Masters Courses
Leeds Beckett University Featured Masters Courses
Queen Mary University of London Featured Masters Courses
Cass Business School Featured Masters Courses
FindA University Ltd Featured Masters Courses
"system" AND "on" AND "ch…×
0 miles

Masters Degrees (System On Chip)

We have 40 Masters Degrees (System On Chip)

  • "system" AND "on" AND "chip" ×
  • clear all
Showing 1 to 15 of 40
Order by 
Course Summary. Systems in mobile telephones, computers, cars and aircraft are shrinking, with many parts implemented as a single integrated circuit. Read more

Course Summary

Systems in mobile telephones, computers, cars and aircraft are shrinking, with many parts implemented as a single integrated circuit. This programme prepares you for the rapidly changing skills required to support this. The focus is on system-on-chip design techniques and extensive practical use of cutting-edge and industry-standard methods. You will be taken through the system-on-chip design process, from concept to implementation.

Modules

Semester one: Secure Hardware Design; Nanoelectronic Devices; Digital System Design; Digital IC and Systems Design; Real-Time Computing and Embedded Systems.

Semester two: SOC Design Project; Analogue and Mixed Signal CMOS Design; Advanced Wireless Communication Networks and Systems; Medical Electrical and Electronic Technologies; Cryptography; Digital Systems Synthesis; Embedded Processors.

Plus three-month independent research project culminating in a dissertation.

Visit our website for further information.



Read less
The MSc Electronics with System-On-Chip Technologies aims to produce postgraduates with an advanced understanding of the various routes to implementing systems-on-chip (SoC) and with hands-on experience of the design of such systems using several approaches to their implementation. Read more
The MSc Electronics with System-On-Chip Technologies aims to produce postgraduates with an advanced understanding of the various routes to implementing systems-on-chip (SoC) and with hands-on experience of the design of such systems using several approaches to their implementation. The core aim of the course is to produce students who are “silicon qualified” by providing them with a complete SoC design experience by setting a framework of activities that allow the student to use industry-standard Computer-Aided-Engineering (CAE) software tools for the fast and accurate design, simulation and verification of integrated circuits.

Course structure

Each MSc course consists of three learning modules (40 credits each) plus an individual project (60 credits). Each learning module consists of a short course of lectures and initial hands-on experience. This is followed by a period of independent study supported by a series of tutorials. During this time you complete an Independent Learning Package (ILP). The ILP is matched to the learning outcomes of the module. It can be either a large project or a series of small tasks depending on the needs of each module. Credits for each module are awarded following the submission of a completed ILP and its successful defence in a viva voce examination. This form of assessment develops your communication and personal skills and is highly relevant to the workplace. Overall, each learning module comprises approximately 400 hours of study.

The project counts for one third of the course and involves undertaking a substantial research or product development project. For part-time students, this can be linked to their employment. It is undertaken in two phases. In the first part, the project subject area is researched and a workplan developed. The second part involves the main research and development activity. In all, the project requires approximately 600 hours of work.
Further flexibility is provided within the structure of the courses in that you can study related topic areas by taking modules from other courses as options (pre-requisite knowledge and skills permitting).

Prior to starting your course, you are sent a Course Information and Preparation Pack which provides information to give you a flying start.

MSc Electronics Suite of Courses

The MSc in Electronics has four distinct pathways:
-Robotic and Control Systems
-Embedded Systems
-System-on-Chip Technologies
-Medical Instrumentation

The subject areas covered within the four pathways of the electronic suite of MSc courses offer students an excellent launch pad which will enable the successful graduate to enter into these ever expanding, fast growing and dominant areas. With ever increasing demands from consumers such as portability, increased battery life and greater functionality combined with reductions in cost and shrinking scales of technologies, modern electronic systems are finding ever more application areas.

A vastly expanding application base for electronic systems has led to an explosion in the use of embedded system technologies. Part of this expansion has been led by the introduction of new medical devices and robotic devices entering the main stream consumer market. Industry has also fed the increase in demand particularly within the medical electronics area with the need of more sophisticated user interfaces, demands to reduce equipment costs, demands for greater accessibility of equipment and a demand for ever greater portability of equipment.

The technical tasks undertaken in ILPs, along with the required major project, thoroughly exercise the concepts covered in the course modules and give scope for originality and industry-relevant study. Team-working activities encouraged within modules, along with the all-oral individual examination regimen employed in this Electronics MSc Suite, have proven solidly beneficial in refining the communication and employability-enhancing skills that are strongly valued by industry.

Read less
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.



Read less
The Master’s programme in Electronics Engineering focuses on the design of integrated circuits and System-on-Chip in advanced semiconductor technologies. Read more
The Master’s programme in Electronics Engineering focuses on the design of integrated circuits and System-on-Chip in advanced semiconductor technologies. This requires a broad spectrum of knowledge and skills across many fields within engineering and science, far beyond the curriculum of traditional electronics education. The programme provides a competitive education in digital, analogue and Radio Frequency (RF) integrated circuits (IC) and System-on-Chip (SoC) design, combined with in-depth knowledge in signal processing, application specific processors, embedded systems design, modern communications systems and radio transceivers design.

The modern society depends to a large extent on reliable and efficient electronics. Mobile phones, internet, PCs and TVs are just a few examples that constantly improve in terms of functionality, performance and cost. In addition, there is a growing number of concepts and technologies which will significantly improve areas such as: mobile and broadband communications, healthcare, automotive, robotics, energy systems management, entertainment, consumer electronics, public safety and security, industrial applications and much more. This indicates that there will be vast industrial opportunities in the future, and also a high demand for competent engineers with the required knowledge and skills to lead the design of such complex integrated circuits and systems.

The programme is arranged by several strong divisions at the department of Electrical Engineering and the department of Computer and Information Science. These groups, which include more than 60 researchers and 10 internationally recognized professors, have excellent teaching experience, world-class research activities which cover nearly the entire field of integrated electronic design, state-of-the-art laboratories and design environments, as well as close research collaboration with many companies worldwide.

The programme starts with courses in wireless communication systems, digital integrated circuits, digital system design, analogue integrated circuits and an introduction to radio electronics, providing a solid base for the continuation of the studies. Later on, a large selection of courses provides two major tracks of studies, including common and specific courses. The tracks are:
System-on-Chip with focus on digital System-on-Chip design and embedded systems.
Analogue/Digital and RF IC design with emphasis on the design of mixed analogue/digital and radio frequency integrated circuits.

The programme offers several large design project courses, giving excellent opportunities for students to improve their design skills by using the same state-of-the-art circuit and system design environments and CAD tools that are used in industry today. For instance, in the project course VLSI Design students will design real chips using standard CMOS technology that will be sent for fabrication, measured and evaluated in a follow-up course. Only few universities in the world have the know-how and capability to provide such courses.

Read less
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.



Read less
ISMM is very different to any other academic course. it combines traditional teaching material with a series of industrial visits, some of which will take place overseas. Read more
ISMM is very different to any other academic course: it combines traditional teaching material with a series of industrial visits, some of which will take place overseas. The course members work a full industrial week and conform to business dress codes. This intensive, practical programme gives direct experience of many different industries, cultures and working environments, and the projects present real challenges in genuine industrial and business environments. The aim of the course is to equip numerate graduates with the skills, personal development and industrial experience to be immediately effective in their early careers in industry.

ISMM will broaden your perspective and experience and open the door to a wide range of industrial careers. Many blue chip companies recognise the value of the course and target our graduates. Equally, for those who want to work in a smaller company, ISMM gives the confidence to start directly in a manufacturing engineering or management role. Those with entrepreneurial flair go on to set up their own companies.

The programme is structured around taught modules, company visits and in-company projects solving live business or technical problems. An overseas study tour offers a broader international context and the individual research thesis allows greater depth of study in a specific area of manufacturing.

See the website http://www.graduate.study.cam.ac.uk/courses/directory/egegmpimm

Course detail

During the year you will acquire a working understanding of the fundamentals of a business enterprise, with a particular emphasis on manufacturing disciplines. You will visit up to forty companies, large and small, chosen to cover all industrial sectors; you will absorb the different cultures and learn to identify strengths and weaknesses. By the end of the course you will be in a perfect position to choose your career direction.

Skills acquired during the course include:

- critical analysis;
- creativity – the generation of innovative solutions;
- evaluation of designs, processes and products;
- balancing theory and practice;
- problem identification, definition and solution;
- data gathering, evaluation and analysis;
- effective communication written, verbal and graphic;
- preparation of business and finance cases;
- presentation preparation and delivery;
- project management;
- report writing;
- a 'can do' attitude;
- teamworking;
- appreciating the responsibilities of leadership

Format

Teaching is delivered through a variety of media. During Cambridge termtimes, there will be traditional academic lectures and interactive seminars; the dissertation is based in one of the Institute for Manufacturing's research groups and will involve normal graduate-level supervision. However, much of the learning during the course takes place during the industrial visits (of which there are approximately forty annually), and on the projects themselves. During the projects, students can expect to receive substantial 'supervisory' feedback from their line managers and colleagues. Academic assessment of the course is split into three components: examinations on module material; assessment of project reports; examination of the dissertation.

Placements

In addition to the series of industrial visits, students will undertake four two-week industrial placements over the course of the programme. During this time they will be working on live business/technical issues relevant to the company, and will be treated as an employee. These placements will terminate in a presentation to the Senior Management of the company, and in the writing of a handover report that will be examined as part of the course assessment.

Assessment

All students will be required to write a dissertation of no greater than 15,000 words. Achieving a passing mark on this dissertation is a precondition for obtaining the degree.

All students are required to write four project reports, each of which will be based on two weeks of project work on an issue relevant to a host company.

Four taught modules will be assessed through written assessments under timed conditions.
At the discretion of the Examiners, candidates may be required to take an additional oral examination on the work submitted during the course, and on the general field of knowledge within which it falls.

Students can expect to receive reports at least termly on the Cambridge Graduate Supervision Reporting System. They will have access to a University supervisor for their dissertation, and can expect to receive input from their line managers during project placements.

Continuing

The MPhil is a professional practice programme and is not specifically designed to lead on to doctoral research. Nevertheless, students wishing to apply for continuation to a PhD in Engineering at Cambridge would normally be expected to attain an overall mark of at least 70%.

How to apply: http://www.graduate.study.cam.ac.uk/applying

Funding Opportunities

Bursaries are available to two categories of applicant.

Category A: Bursaries of between £1,200 and £1,800 are available to successful applicants who either (i) have UK citizenship; or (ii) have settled status in the UK, and have been ordinarily resident in the UK and Islands (for a purpose other than full-time education) for the three years prior to the 1 September immediately preceding the course.

Category B: Successful applicants who have secured sufficient funding from studentship providers to cover the standard University Composition Fee rate, but not the additional cost, may receive a bursary to cover the discrepancy.

All eligible applicants will be considered for bursaries. Students in Category B may wish to contact the course email to ensure that their situation is noticed.

General Funding Opportunities http://www.graduate.study.cam.ac.uk/finance/funding

Read less
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



Read less
Microsystems Engineering is one of the most dynamic and interdisciplinary engineering fields. The Master of Science program in Microsystems Engineering (MSE) provides the educational basis for your success in this field. Read more
Microsystems Engineering is one of the most dynamic and interdisciplinary engineering fields. The Master of Science program in Microsystems Engineering (MSE) provides the educational basis for your success in this field. The MSE program is designed for highly qualified graduate students holding a Bachelor degree in engineering or science.

In the first year 12 mandatory courses provide the fundamental theoretical framework for a future career in Microsystems. These courses are designed to provide students with a broad knowledge base in the most important aspects of the field:

• MSE technologies and processes
• Microelectronics
• Micro-mechanics
• MSE design laboratory I
• Optical Microsystems
• Sensors
• Probability and statistics
• Assembly and packaging technology
• Dynamics of MEMS
• Micro-actuators
• Biomedical Microsystems
• Micro-fluidics
• MSE design laboratory II
• Signal processing

As part of the mandatory courses, the Microsystems design laboratory is a two-semester course in which small teams of students undertake a comprehensive, hands-on design project in Microsystems engineering. Requiring students to address all aspects of the generation of a microsystem, from conceptualization, through project planning to fabrication and testing, this course provides an essential glimpse into the workings of engineering projects.

In the second year, MSE students can specialise in two of the following seven concentration areas (elective courses), allowing each student to realize individual interests and to obtain an in-depth look at two sub-disciplines of this very broad, interdisciplinary field:

• Circuits and systems
• Design and simulation
• Life sciences: Biomedical engineering
• Life sciences: Lab-on-a-chip
• Materials
• Process engineering
• Sensors and actuators

Below are some examples of subjects offered in the concentration areas. These subjects do not only include theoretical lectures, but also hands-on courses such as labs, projects and seminars.

Circuits and Systems
• Analog CMOS Circuit Design
• Mixed-Signal CMOS Circuit Design
• VLSI – System Design
• RF- und Microwave Devices and Circuits
• Micro-acoustics
• Radio sensor systems
• Optoelectronic devices
• Reliability Engineering
• Lasers
• Micro-optics
• Advanced topics in Macro-, Micro- and Nano-optics


Design and Simulation
• Topology optimization
• Compact Modelling of large Scale Systems
• Lattice Gas Methods
• Particle Simulation Methods
• VLSI – System Design
• Hardware Development using the finite element method
• Computer-Aided Design

Life Sciences: Biomedical Engineering
• Signal processing and analysis of brain signals
• Neurophysiology I: Measurement and Analysis of Neuronal Activity
• Neurophysiology II: Electrophysiology in Living Brain
• DNA Analytics
• Basics of Electrostimulation
• Implant Manufacturing Techologies
• Biomedical Instrumentation I
• Biomedical Instrumentation II

Life Sciences: Lab-on-a-chip
• DNA Analytics
• Biochip Technologies
• Bio fuel cell
• Micro-fluidics 2: Platforms for Lab-on-a-Chip Applications

Materials
• Microstructured polymer components
• Test structures and methods for integrated circuits and microsystems
• Quantum mechanics for Micro- and Macrosystems Engineering
• Microsystems Analytics
• From Microsystems to the nano world
• Techniques for surface modification
• Nanomaterials
• Nanotechnology
• Semiconductor Technology and Devices

MEMS Processing
• Advanced silicon technologies
• Piezoelectric and dielectric transducers
• Nanotechnology

Sensors and Actuators
• Nonlinear optic materials
• CMOS Microsystems
• Quantum mechanics for Micro- and Macrosystems Engineering
• BioMEMS
• Bionic Sensors
• Micro-actuators
• Energy harvesting
• Electronic signal processing for sensors and actuators


Essential for the successful completion of the Master’s degree is submission of a Master’s thesis, which is based on a project performed during the third and fourth semesters of the program. Each student works as a member of one of the 18 research groups of the department, with full access to laboratory and cleanroom infrastructure.

Read less
The communications sector has changed dramatically in the past 5 years, as mobile internet, smartphones and associated apps such as social media, commerce and digital media have spurred an information revolution. Read more

The communications sector has changed dramatically in the past 5 years, as mobile internet, smartphones and associated apps such as social media, commerce and digital media have spurred an information revolution.

This programme responds to the growth of networks and mobile internet applications, allowing you to study traditional communications theory alongside modules dealing with network security and the protocols for high-speed switches and routers.

You’ll build your knowledge of new developments in data-centric networking and the growing trend in cloud computing and online services, such as web-search, video content hosting and distribution, social networking and large-scale computations. Optional modules will allow you to specialise in topics appropriate to your interests and career plans.

It’s a chance to gain specialist knowledge and skills that will be in demand over a wide range of disciplines, from the traditional communications industries to banking, finance and commerce.

Specialist facilities

Our School is an exciting and stimulating environment where you’ll learn from leading researchers in specialist facilities. Depending on your research project, these may 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

The programme is built around a set of core modules that develop your knowledge across both semesters. You’ll build your understanding of topics like communication network design, high-speed internet architecture, optical communications networks, data communications and the issues surrounding network security.

If you have no experience of C programming, you’ll also take a module that will equip you with these skills. However, if you do, you could choose to take a specialist module on software development instead. In addition, you’ll choose from optional modules on topics such as digital media engineering, cellular mobile communication systems and even applications of this technology in the medical sector.

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 Digital Communications Networks module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Industry Dissertation 15 credits
  • Communication Network Design 15 credits
  • Optical Communications Networks 15 credits
  • High Speed Internet Architecture 15 credits
  • Data Communications and Network Security 15 credits
  • Main Project 45 credits

Optional modules

  • Wireless Communications Systems Design 15 credits
  • Cellular Mobile Communication Systems 15 credits
  • Digital Wireless Communications Principles 15 credits
  • FPGA Design for System-on-Chip 15 credits
  • Digital Media Engineering 15 credits
  • Medical Electronics and E-Health 15 credits
  • Programming 15 credits
  • Software Development 15 credits

For more information on typical modules, read Digital Communications Networks 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.

Career opportunities

Career prospects are excellent. There is a wide range of career opportunities in all aspects of the communications industry, and the skills learned here will also be generic to allow employment in other sectors such as finance, banking, general manufacturing, etc.

Graduates from our School have pursued careers with organisations like Cisco Systems, General Electric, Huawei, Ericsson Telecommunications, Intel Corp., Technology and Strategy Board, Wabtec Rail UK, AECOM and Orascom Telecom.

Some graduates also choose the path of academic research and therefore subsequently undertake a PhD.

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



Read less
Mechatronics, robotics and autonomous systems represent a range of important technologies which underpin many applications – from manufacturing and automation through to self-driving cars and robotic surgical tools. Read more

Mechatronics, robotics and autonomous systems represent a range of important technologies which underpin many applications – from manufacturing and automation through to self-driving cars and robotic surgical tools.

Delivered by the Schools of Electronic and Electrical Engineering, Mechanical Engineering and Computing, this programme will equip you with the specialist knowledge and wide range of skills to pursue a career in this dynamic field.

Core modules will give you a foundation in the many applications of mechatronics and robotics and develop your understanding of the wide range of industry sectors that use robotics. You’ll also build research skills with a major project in fields as diverse as robot swarms, sensing systems, bio-inspired robots and surgical robotics.

Diverse optional modules will allow you to focus on topics that suit your interests and career plans, guided by academics whose teaching is informed by their own world-class research.

Specialist facilities

The Faculty of Engineering is an exciting and stimulating environment where you’ll learn in specialist facilities. These include an ABB robotic manufacturing cell, the Embedded Systems Lab, the Keysight Technologies Communications Lab, the National Instruments LabVIEW Academy, and computer clusters with a very wide range of industry-standard CAD/CAE/CAM software packages.

The three Schools that deliver this programme collaborate in research projects within the themes of surgical robotics, rehabilitation robotics, exploration robotics and future cities. 

Course content

Three core modules act as the foundations of the course, developing your understanding of key aspects of mechatronics and robotics and how they fit into the context of the full range of industrial sectors and rapidly-developing everyday applications.

Mechatronics and Robotics Applications will look at the challenges, problems and solutions involved in integrating components such as actuators and computer control into modern engineering systems in domains such as healthcare and the automotive industry.

To build your understanding of the global industry and career opportunities, you’ll also complete a dissertation in a topic of your choice. This is supported by a series of lectures that cover the principles of globalisation, industry sectors, manufacturing, business models, teamwork skills and entrepreneurship. 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 on a project allied to one of our research groups, spanning an exceptionally wide range of areas ranging from computer vision and artificial intelligence through robotic communications, sensing and embedded systems to mechanical design, industrial inspection, biomedical engineering and surgical robotics.

You’ll complete your studies by selecting from a range of optional modules that allow you to focus on topics that suit your personal interests or career intentions. You could build your understanding of computational methods, medical robotics, control systems design and more.

Want to find out more about your modules?

Take a look at the Mechatronics and Robotics module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Industry Dissertation 15 credits
  • Mechatronics and Robotics Applications 15 credits
  • Professional Project 75 credits

Optional modules

  • Bio-Inspired Computing 15 credits
  • Power Electronics and Drives 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
  • Automotive Driveline Engineering 15 credits
  • Engineering Computational Methods 15 credits
  • Biomechatronics and Medical Robotics 15 credits

For more information on typical modules, read Mechatronics and Robotics 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.

Career opportunities

Mechatronics and robotics is a multidisciplinary field with a strong future, exciting career opportunities and a huge range of applications in robotics, manufacturing, automation, automotive engineering, aerospace, healthcare and medicine, leisure & entertainment and many more.

After graduating from this course, you will be in a good position to seek employment as a development, project or graduate engineer with leading organisations such as GCHQ, JN Bentley, Oilger Towler Ltd, Airbus UK, Avesta, Crosslee Plc, ABB Ltd, AWE, Ricardo, APV Baker, Jaguar Land Rover and Jacobs Engineering.

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.



Read less
Taking electronic engineering to the next level by adding high frequency devices, micro sensors, micro actuators, biology and novel materials is one of the primary goals of engineers and scientists within the electronic community. Read more
Taking electronic engineering to the next level by adding high frequency devices, micro sensors, micro actuators, biology and novel materials is one of the primary goals of engineers and scientists within the electronic community.

This course focuses on miniaturised systems which are able to describe and diagnose a situation, detect critical conditions, and identify and address each other. They may also be energy autonomous and networked. Students will also learn how to design advanced circuits for high frequency applications.

The course will also include methods of building control loops and associated software; the design of analogue and digital electronic interfaces; and the manufacture of novel packaging technologies.

The dissertation will be on a major industrial project.

Modules
• Smart Systems
• Intelligent Control
• Advanced Embedded Systems
• High Frequency Electronics
• Linking Group Project
• System on Chip Engineering

Read less
A University of Hertfordshire research degree is an internationally recognised degree signifying high levels of achievement in research. Read more
A University of Hertfordshire research degree is an internationally recognised degree signifying high levels of achievement in research. It develops extensive subject expertise and independent research skills which are honed over an extended period, depending on the level of the award. You would undertake a substantial, original research project for the duration of the degree, under the supervision and guidance of two or more academic members of staff. Your supervisory team provides guidance both in the selection of a research topic and in the conduct of the research. You are also supported by attendance at postgraduate seminar series to develop subject specific knowledge and research skills relevant to your field of research. The degree is assessed solely on the basis of the final research output, in the form of a substantial written thesis which must be "defended" in a viva. During the course of the degree, you would be given opportunities to present your work at major conferences and in refereed research publications.

Why choose this course?

-An internationally recognised research qualification
-Developing advanced subject expertise at postgraduate level
-Develop research skills through practice and extensive research experience
-Employers are looking for high calibre graduates with advanced skills who can demonstrate independence through research

Careers

Graduates with this degree will be able to demonstrate to employers a highly-valued ability to work independently on a substantial and challenging original project and to maintain that focus over an extended period, and will have developed much sought after, highly refined research skills.

Teaching methods

Research degrees are not taught programmes, however, programmes of supporting studies are a key element.

The School of Engineering and Technology has extensive expertise in the areas of Digital Broadcast Technology, System on Chip and specialist Processor Architecture, Robotics and Virtual environments, Digital Signal Processing and Biometrics and Broadband Communication Networks which are underpinned by a series of specialised laboratories and supported by Industry forming membership of the School's own Industrial Advisory Group.

With more than a fifth of the school's student population steered towards postgraduate taught and research programmes, blue sky and applied research has been successfully conducted, with funding originating from responsive, knowledge transfer and industrial CASE funding schemes and dynamically supported by research seminars, showcases and exposition to research conferences.

Read less
Research profile. Read more

Research profile

The Institute for Integrated Micro and Nano Systems (IMNS) brings together researchers from integrated-circuit design, system-on-chip design, image-sensor design, bioelectronics, micro/nano-fabrication, microelectromechanical systems (MEMS), micromachining, neural computation and reconfigurable and adaptive computing.

Research interests include low-level analogue, low-power, adaptive and bio-inspired approaches, system-on-chip computing and applications from telecommunications to finance and astronomy. There is also a research focus on integrating CMOS microelectronic technology with sensors and microsystems/MEMS to create smart sensor systems. We also have a strong and growing interest in applications relating to life sciences and medicine, with particular focus on bioelectronics, biophotonics and bio-MEMS.

IMNS has laboratory facilities that are unique within the UK, including an advanced silicon and MEMS micro-fabrication capability coupled with substantial design and test resources. The Institute has an excellent reputation for commercialising technology.

Training and support

The development of transferable skills is a vital part of postgraduate training and a vibrant, interdisciplinary training programme is offered to all research students by the University’s Institute for Academic Development (IAD). The programme concentrates on the professional development of postgraduates, providing courses directly linked to postgraduate study.

Courses run by the IAD are free and have been designed to be as flexible as possible so that you can tailor the content and timing to your own requirements.

Our researchers are strongly encouraged to present their research at conferences and in journal during the course of their PhD.

Every year, the Graduate School organises a Postgraduate Research Conference to showcase the research carried out by students across the Research Institutes

Our researchers are also encouraged and supported to attend transferable skills courses provided by organisations such as the Engineering and Physical Sciences Research Council (EPSRC).

Facilities

The Institute has laboratory facilities that are unique within the UK, including a comprehensive silicon and MEMS micro-fabrication capability coupled with substantial design and test resources.

The Institute has an excellent reputation for commercialising technology.



Read less
Programme description. This programme offers distinct specialisation areas in electronics. analogue VLSI design, bioelectronics and analogue and digital systems. Read more

Programme description

This programme offers distinct specialisation areas in electronics: analogue VLSI design, bioelectronics and analogue and digital systems.

In analogue VLSI design, our facilities include a unique custom designed analogue integrated circuit specifically designed to support laboratory based teaching. Our advanced design and prototyping laboratories, advanced micro and nano fabrication facilities and state-of-the-art digital system laboratories use the latest industry standard software tools.

Alternatively, students may specialise in the emergent discipline of bioelectronics where our research and teaching interests include access to the fabrication facilities at the Scottish Microelectronics Centre. For students who wish to study a more general electronics course including digital systems, a prescribed course selection is available.

Programme structure

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

Semester 1 courses

  • Analogue IC Design
  • Analogue VLSI A
  • Discrete-Time Signal Analysis
  • Power Electronics
  • Principles of Microelectronic Devices
  • Digital Systems Laboratory A
  • Introduction to Bioelectronics
  • Biosensors

Semester 2 courses

  • Digital System Design
  • Digital Systems Laboratory
  • Research Project Preparation
  • Electronic/Electrical Engineering System Design
  • Analogue VLSI B
  • Sigma Delta Converters
  • Analogue Circuit Design
  • Microfabrication Techniques
  • Biosensors and Instrumentation
  • Lab-on-Chip Technologies
  • Biomedical Imaging Techniques
  • Embedded Mobile and Wireless Systems
  • Modern Economic Issues in Industry
  • Technology and Innovation Management

Career opportunities

You will gain significant practical experience in analogue and digital laboratories and become familiar with the latest industry standard design software and environments. Having been exposed to concepts such as design re-use and systems on chip technology, you will be able to cooperate with others in electronic system design. Recent graduates are now working as applications, design, field, test and validation engineering for employers such as BMW, Guangzhou Hangxin Avionics and Kongsberg Maritime.



Read less
The Masters in Electronics & Electrical Engineering & Management introduces you to contemporary business and management issues while increasing your depth of knowledge in your chosen speciality of electronics and electrical engineering. Read more
The Masters in Electronics & Electrical Engineering & Management introduces you to contemporary business and management issues while increasing your depth of knowledge in your chosen speciality of electronics and electrical engineering.

Why this programme

◾Electronic and Electrical Engineering at the University of Glasgow is consistently highly ranked recently achieving 1st in Scotland and 4th in the UK (Complete University Guide 2017).
◾You will be taught jointly by staff from the School of Engineering and the Adam Smith Business School. You will benefit from their combined resources and expertise and from an industry-focused curriculum.
◾If you have an engineering background, but with little management experience and are wanting to develop your knowledge of management while also furthering your knowledge of electronics and electrical engineering, this programme is designed for you.
◾You will gain first-hand experience of managing an engineering project through the integrated system design module, allowing development of skills in project management, quality management and accountancy.
◾You will benefit from access to our outstanding laboratory facilities and interaction with staff at the forefront of research in electronics and electrical engineering.
◾With a 92% overall student satisfaction in the National Student Survey 2015, Electronic and Electrical Engineering at the School of Engineering combines both teaching excellence and a supportive learning environment.
◾This programme has a September and January intake.

Programme structure

There are two semesters of taught material and a summer session working on a project or dissertation. September entry students start with management courses and January entry students with engineering courses.

Semester 1

You will be based in the Business School, developing knowledge and skills of management principles and techniques. We offer an applied approach, with an emphasis on an informed critical evaluation of information, and the subsequent application of concepts and tools to the core areas of business and management.

Core courses

◾Contemporary issues in human resource management
◾Managing creativity and innovation
◾Managing innovative change
◾Marketing management
◾Operations management
◾Project management.

Semester 2

You will study engineering courses, which aim to enhance your group working and project management capability at the same time as improving your depth of knowledge in chosen electronics and electrical engineering subjects.

Core course

◾Integrated systems design project

Optional courses

(a choice of two)
◾Computer communications
◾Electrical energy systems
◾Micro- and nano-technology
◾Microwave and millimetre wave circuit design
◾Microwave electronic and optoelectronic devices
◾Optical communications
◾Real-time embedded programming.

Project or dissertation

You will undertake an individual project or dissertation work in the summer period (May - August). This will give you an opportunity to apply and consolidate your newly learned skills and show to future employers that you have been working on cutting edge projects relevant to the industry. Project and dissertation options are closely linked to staff research interests. September entry students have a choice of management dissertation topics in addition to electronics and electrical engineering projects, and January entry students have a choice of electronics and electrical engineering projects.

Projects

◾To complete the MSc degree you must undertake a project worth 60 credits. This is an integral part of the MSc programme and many have a technical or business focus.
◾The project will integrate subject knowledge and skills that you acquire during the MSc programme.
◾The project is an important part of your MSc where you can apply your newly learned skills and show to future employers that you have been working on cutting edge projects relevant to the industry.
◾You can choose a topic from a list of MSc projects in Electronic and Electrical Engineering or the Management portion of your degree.
◾Alternatively, should you have your own idea for a project, department members are always open to discussion of topics.
◾Students who start in January must choose an engineering focussed project.

Example projects

Examples of projects can be found online

*Posters shown are for illustrative purposes

Industry links and employability

◾The programme makes use of the combined resources and complementary expertise of the electronic and electrical engineering and business school staff to deliver a curriculum which is relevant to the needs of industry.
◾If you are looking to advance to a senior position in industry and to perform well at this level, knowledge and understanding of management principles will give you a competitive edge in the jobs market.
◾You, as a graduate of this programme, will be capable of applying the extremely important aspect of management to engineering projects allowing you to gain an advantage in today’s competitive job market and advance to the most senior positions within an engineering organisation.
◾The School of Engineering has extensive contacts with industrial partners who contribute to several of their taught courses, through active teaching, curriculum development, and panel discussion. Recent contributions in Electronic and Electrical Engineering include Freescale.
◾During the programme students have an opportunity to develop and practice relevant professional and transferrable skills, and to meet and learn from employers about working in the electronic and electrical engineering industry.

Career prospects

Career opportunities include software development, chip design, embedded system design, telecommunications, video systems, automation and control, aerospace, development of PC peripherals and FPGA programming, defence, services for the heavy industries, for example electricity generation equipment and renewables plant, etc.

Graduates of this programme have gone on to positions such as:
Project Engineer at TOTAL
Schedule Officer at OSCO SDN BHD
Control and Automation Engineer at an oil and gas company.

Read less

Show 10 15 30 per page



Cookie Policy    X