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Masters Degrees (Sensor And Imaging Systems)

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This Masters in Sensor and Imaging Systems (SIS) focuses on the technologies and techniques that underpin a vast range of societal, research and industrial needs. Read more
This Masters in Sensor and Imaging Systems (SIS) focuses on the technologies and techniques that underpin a vast range of societal, research and industrial needs. It is delivered and awarded jointly by the Universities of Glasgow and Edinburgh. Sensing and sensor systems are essential for advances in research across all fields of physics, engineering and chemistry and are enhanced when multiple sensing functions are combined into arrays to enable imaging. Industrial applications of sensor systems are ubiquitous: from mass-produced sensors found in modern smart phones and every modern car to the state-of-the-art, specialist high-value sensors routinely used in oil and gas recovery, scientific equipment, machine tools, medical equipment and environmental monitoring. This is an industry-focused programme, designed for people looking to develop skills that will open up opportunities in a host of end applications.

Why this programme

-This is a jointly taught and awarded degree from the University of Glasgow and the University of Edinburgh, developed in with conjunction with CENSIS.
-CENSIS is a centre of excellence for Sensor and Imaging Systems (SIS) technologies, CENSIS enables industry innovators and university researchers to collaborate at the forefront of market-focused SIS innovation, developing products and services for global markets.
-CENSIS, the Innovation Centre for Sensor and Imaging Systems, is one of eight Innovation Centres that are transforming the way universities and business work together to enhance innovation and entrepreneurship across Scotland’s key economic sectors, create jobs and grow the economy. CENSIS is funded by the Scottish Funding Council (£10m) and supported by Scottish Enterprise, Highlands and Islands Enterprise and the Scottish Government.
-CENSIS has now launched its collaborative MSc in Sensor and Imaging Systems, designed to train the next generation of sensor system experts.
-This programme will allow you to benefit from the commercial focus of CENSIS along with the combined resources and complementary expertise of staff from two top ranking Russell Group universities, working together to offer you a curriculum relevant to the needs of industry.
-The Colleges of Science and Engineering at the University of Glasgow and the University of Edinburgh delivered power and impact in the 2014 Research Excellent Framework. Overall, 94% of Edinburgh’s and 90% of Glasgow’s research activity is world leading or internationally excellent, rising in Glasgow’s case to 95% for its impact.

Programme structure

The programme comprises a mix of core and optional courses. The curriculum you undertake is flexible and tailored to your prior experience and expertise, your particular research interests, and the specific nature of the extended research project topic provisionally identified at the beginning of the MSc programme.

Graduates receive a joint degree from the universities of Edinburgh and Glasgow.

Programme timetable
-Semester 1: University of Glasgow
-Semester 2: University of Edinburgh
-Semester 3: MSc project, including the possibility of an industry placement

Core courses
-Circuits and systems
-Detection and analysis of ionising radiation
-Fundamentals of sensing and imaging
-Imaging and detectors
-Technology and innovation management
-Research project preparation

Optional courses
-Biomedical imaging techniques
-Biophysical chemistry
-Biosensors and instrumentation
-Chemical biology
-Digital signal processing
-Electronic product design and manufacture
-Electronic system design
-Entrepreneurship
-Lab-on-chip technologies
-Lasers and electro-optic systems
-Microelectronics in consumer products
-Microfabrication techniques
-Nanofabrication
-Physical techniques in action
-Waves and diffraction

Industry links and employability

-This is an industry-focused programme, developed in conjunction with CENSIS, an Innovation Centre established to maximise the growth potential of Scottish companies operating in the sensor systems market. It will appeal to graduates seeking to develop sensor and imaging systems (SIS) skills that can be used in a range of end markets and applications.
-SIS is key enabling technology to achieve quality, efficiency and performance across all key markets – from transport, security and oil and gas, through to agriculture, the built environment and life sciences. The underlying requirement across of these sectors is the same: to sense, measure, process, communicate and visualise in a way that provides valuable and actionable information based on data.
-Sensing is essential for advances in research across all fields of physics, engineering and chemistry, and is enhanced when multiple sensing functions are combined into arrays to enable imaging. Industrial applications of SIS are ubiquitous: from mass-produced sensors found in smart phones and cars, to the state-of-the-art, specialist high-value sensors routinely used in oil and gas recovery, scientific equipment, machine tools, medical equipment and environmental monitoring.
-Increasingly, sensor systems – along with their underpinning device, signal processing, networking, information dissemination and diagnostics technologies - are being tightly integrated within the products and services of a wide range of Scottish businesses. There are endless opportunities within this emerging global market (worth £500Bn) to develop fundamental changes to benefit society and commercialise sensor lead products over wide market areas.
-Markets that need graduates with SIS skills include include defence and security, renewables, aerospace, subsea, intelligent transport, environmental science, built environment, energy and the smart grid, healthcare and drug discovery, medical diagnostics, and food and drink.

Career prospects

You will gain an understanding of sensor-based systems applicable to a whole host of markets supported by CENSIS.

Career opportunities are extensive. Sensor systems are spearheading the next wave of connectivity and intelligence for internet connected devices, underpinning all of the new ‘smart markets’, e.g., grid, cities, transport and mobility, digital healthcare and big data.

You will graduate with domain-appropriate skills suitable for a range of careers in areas including renewable energy, subsea and marine technologies, defence, automotive engineering, intelligent transport, healthcare, aerospace, manufacturing and process control, consumer electronics, and environmental monitoring.

Globally, the market for sensor systems is valued at £500Bn with an annual growth rate of 10%. The Scottish sensor systems market is worth £2.6Bn pa. There are over 170 sensor systems companies based in Scotland (SMEs and large companies), employing 16,000 people in high-value jobs including product R&D, design, engineering, manufacturing and field services.

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As well as giving a solid scientific understanding, the course also addresses commercial, ethical, legal and regulatory requirements, aided by extensive industrial contacts. Read more
As well as giving a solid scientific understanding, the course also addresses commercial, ethical, legal and regulatory requirements, aided by extensive industrial contacts.

Programme Structure

The MSc programmes in Biomedical Engineering are full-time, one academic year (12 consecutive months). The programmes consist of 4 core taught modules and two optional streams. Biomedical, Genetics and Tissue Engineering stream has 3 modules, all compulsory (individual course pages). The second option, Biomedical, Biomechanics and Bioelectronics Engineering stream consists of 5 modules. Students choosing this option will be required to choose 60 credit worth of modules.

The taught modules are delivered to students over two terms of each academic year. The taught modules are examined at the end of each term, and the students begin working on their dissertations on a part-time basis in term 2, then full-time during the months of May to September.

Core Modules
Biomechanics and Biomaterials (15 credit)
Design and Manufacture (15 credit)
Biomedical Engineering Principles (15 credit)
Innovation, Management and Research Methods (15 credit)
Plus: Dissertation (60 credit)

Optional Modules

60 credit to be selected from the following optional modules:
Design of Mechatronic Systems (15 credit)
Biomedical Imaging (15 credit)
Biofluid Mechanics (15 credit)
Artificial Organs and Biomedical Applications (15 credit)
Applied Sensors Instrumentation and Control (30 credit)

Module Descriptions

Applied Sensors Instrumentation and Control

Main topics:

Sensors and instrumentation – Sensor characteristics and the principles of sensing; electronic interfacing with sensors; sensor technologies – physical, chemical and biosensors; sensor examples – position, displacement, velocity, acceleration, force, strain, pressure, temperature; distributed sensor networks; instrumentation for imaging, spectroscopy and ionising radiation detection; 'lab-on-a-chip'.

Control – Control theory and matrix/vector operations; state-space systems, multi-input, multi-output (MIMO) systems, nonlinear systems and linearization. Recurrence relations, discrete time state-space representation, controllability and observability, pole-placement for both continuous and discrete time systems, Luenberger observer. Optimal control systems, Stochastic systems: random variable theory; recursive estimation; introduction to Kalman filtering (KF); brief look at KF for non-linear systems and new results in KF theory.

Artificial Organs and Biomedical Applications

Main topics include: audiology and cochlear implants; prostheses; artificial limbs and rehabilitation engineering; life support systems; robotic surgical assistance; telemedicine; nanotechnology.

Biofluid Mechanics

Main topics include: review of the cardiovascular system; the cardiac cycle and cardiac performance, models of the cardiac system, respiratory system and respiratory performance, lung models, physiological effects of exercise, trauma and disease; blood structure and composition, blood gases. oxygenation, effect of implants and prostheses, blood damage and repair, viscometry of blood, measurement of blood pressure and flow; urinary system: anatomy and physiology, fluid and waste transfer mechanisms, urinary performance and control, effects of trauma, ageing and disease; modelling of biofluid systems, review of mass, momentum and energy transfers related to biological flow systems, fluid mechanics in selected topics relating to the cardiovascular and respiratory systems; measurements in biomedical flows.

Biomechanics and Biomaterials

Main topics include: review of biomechanical principles; introduction to biomedical materials; stability of biomedical materials; biocompatibility; materials for adhesion and joining; applications of biomedical materials; implant design.

Biomedical Engineering Principles

Main topics include: bone structure and composition; the mechanical properties of bone, cartilage and tendon; the cardiovascular function and the cardiac cycle; body fluids and organs; organisation of the nervous system; sensory systems; biomechanical principles; biomedical materials; biofluid mechanics principles, the cardiovascular system, blood structure and composition, modelling of biofluid systems.

Biomedical Imaging

Principle and applications of medical image processing – Basic image processing operations, Advanced edge-detection techniques and image segmentation, Flexible shape extraction, Image restoration, 3D image reconstruction, image guided surgery

Introduction of modern medical imaging techniques – Computerized tomography imaging (principle, image reconstruction with nondiffracting sources, artifacts, clinical applications)

Magnetic resonance imaging (principle, image contrast and measurement of MR related phenomena, examples of contrast changes with changes of instrumental parameters and medical applications)

Ultrasound imaging (description of ultrasound radiation, transducers, basic imaging techniques: A-scan, B-scan and Doppler technique; clinical application)

Positron emission tomography (PET imaging) (principle, radioactive substance, major clinical applications)

Design and Manufacture

Main topics include: design and materials optimisation; management and manufacturing strategies; improving clinical medical and industrial interaction; meeting product liability, ethical, legal and commercial needs.

Design of Mechatronic Systems

Microcontroller technologies. Data acquisition. Interfacing to power devices. Sensors (Infrared, Ultrasonic, etc.). Optoelectronic devices and signal conditioning circuits. Pulse and timing-control circuits. Drive circuits. Electrical motor types: Stepper, Servo. Electronic Circuits. Power devices. Power conversion and power electronics. Line filters and protective devices. Industrial applications of digital devices.

Innovation and Management and Research Methods

Main topics include: company structure and organisation will be considered (with particular reference to the United Kingdom), together with the interfacing between hospital, clinical and healthcare sectors; review of existing practice: examination of existing equipment and devices; consideration of current procedures for integrating engineering expertise into the biomedical environment. Discussion of management techniques; design of biomedical equipment: statistical Procedures and Data Handling; matching of equipment to biomedical systems; quality assurance requirements in clinical technology; patient safety requirements and protection; sterilisation procedures and infection control; failure criteria and fail-safe design; maintainability and whole life provision; public and environmental considerations: environmental and hygenic topics in the provision of hospital services; legal and ethical requirements; product development: innovation in the company environment, innovation in the clinical environment; cash flow and capital provision; testing and validation; product development criteria and strategies.

Dissertation

The choice of Dissertation topic will be made by the student in consultation with academic staff and (where applicable) with the sponsoring company. The topic agreed is also subject to approval by the Module Co-ordinator. The primary requirement for the topic is that it must have sufficient scope to allow the student to demonstrate his or her ability to conduct a well-founded programme of investigation and research. It is not only the outcome that is important since the topic chosen must be such that the whole process of investigation can be clearly demonstrated throughout the project. In industrially sponsored projects the potential differences between industrial and academic expectations must be clearly understood.

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This industry-focused programme - run jointly by the universities of Edinburgh and Glasgow - focuses on the principles, methods, techniques and technologies that underpin a vast range of needs in applications spanning from research to industry to medicine. Read more

Programme description

This industry-focused programme - run jointly by the universities of Edinburgh and Glasgow - focuses on the principles, methods, techniques and technologies that underpin a vast range of needs in applications spanning from research to industry to medicine.

The programme is designed for students looking to develop the skills and knowledge that will open up opportunities in the many companies developing sensor and image based solutions.

Sensing and sensor systems are essential for advances in research across all fields of physics, engineering and chemistry and can be enhanced when multiple sensing functions are combined into arrays to enable imaging.

Industrial applications of sensor systems are ubiquitous: from mass-produced sensors found in modern smartphones and cars to the state-of-the-art, specialist high-value sensors routinely used in oil and gas recovery, scientific equipment, machine tools, medical equipment and environmental monitoring.

Programme structure

This programme is run over 12 months. The first semester of taught courses is run at the University of Glasgow and the second at the University of Edinburgh. The taught courses are followed by a research project, carried out at either university, leading to the production of your masters thesis.

Semester 1
Semester 1 is delivered at the University of Glasgow.

Sensing and Imaging
Imaging and Detectors
Detection and Analysis of Ionising Radiation
Circuits and Systems
Optional course in physics or engineering

Semester 2
Semester 2 is delivered at the University of Edinburgh.

Two compulsory courses:

Applications of Sensor and Imaging Systems
Research Project Preparation
Two optional courses in engineering and/or chemistry:

Biophysical Chemistry
Biosensors and Instrumentation
Lab-on-Chip Technologies
Biomedical Imaging Techniques
Microfabrication Techniques

Career opportunities

Sensor and imaging systems (SIS) underpin a vast range of societal, research and industrial needs. Sensing is essential for advances in capability across all fields of physics, engineering and chemistry and is enhanced when individual sensing units are configured in arrays to enable imaging and when multiple sensing functions are integrated into a single smart system.

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

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

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

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

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

Project opportunities

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

Research areas

- Communications

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

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

- Intelligent Interactions:

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

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

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

- Instrumentation, Control and Embedded Systems:

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

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

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

Careers

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

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

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

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

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An MSc-level conversion programme for those with first degrees in numerate disciplines (e.g. Maths, Physics, others with some mathematics to pre-university level should enquire). Read more
An MSc-level conversion programme for those with first degrees in numerate disciplines (e.g. Maths, Physics, others with some mathematics to pre-university level should enquire). The programme targets producing engineers with the knowledge and skills required for working in the communications industry on programmable hardware, in particular. There is a high demand for people to fill such roles in communications and test & measure equipment vendors, and in many smaller companies developing devices for the internet of things.

The huge growth of interconnected devices expected in the Internet of Things and the goals of flexible, high-speed wireless connections for 5G mobile networks and beyond, require programmable, embedded electronics to play a vital role. From the development of small, intelligence sensors to the design of large-scale network hardware that can be functionally adaptive in software-defined networking, there is a huge demand for advanced embedded electronics knowledge and skills in the communications sector.

Visit the website https://www.kent.ac.uk/courses/postgraduate/1223/embedded-communications-engineering

About the School of Engineering and Digital Arts

The School of Engineering and Digital Arts successfully combines modern engineering and technology with the exciting field of digital media.

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

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

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

EL829 - Embedded Real-Time Operating Systems (15 credits)
EL849 - Research Methods & Project Design (30 credits)
EL893 - Reconfigurable Architectures (15 credits)
EL896 - Computer and Microcontroller Architectures (15 credits)
EL822 - Communication Networks (15 credits)
EL827 - Signal & Communication Theory II (15 credits)
EL871 - Digital Signal Processing (DSP) (15 credits)
EL872 - Wireless/Mobile Communications (15 credits)
EL873 - Broadband Networks (15 credits)
EL890 - MSc Project (60 credits)

Research areas

- Communications

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

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

- Intelligent Interactions:

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

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

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

- Instrumentation, Control and Embedded Systems:

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

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

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

Careers

The programme targets producing engineers with the knowledge and skills required for working in the communications industry on programmable hardware, in particular. There is a high demand for people to fill such roles in communications and test & measure equipment vendors, and in many smaller companies developing devices for the internet of things.

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

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

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

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This course has been developed in consultation with the nuclear engineering industry to provide advanced theoretical and practical knowledge to work with modern control and instrumentation technologies. Read more

Description

This course has been developed in consultation with the nuclear engineering industry to provide advanced theoretical and practical knowledge to work with modern control and instrumentation technologies. This course offers an opportunity not only to specialise in nuclear engineering control, instrumentation and standards for operation and maintenance but also provides sufficient scope for students wishing to develop advanced skills in modern automation and in working with large industrial networks.

You may build valuable skills through a selection of option units and a project to gain advanced knowledge in sustainable energy systems and smart technologies for power system applications or in specialising in embedded systems as well as in applied digital signal processing for industrial applications. The course will also offer opportunities for those interested in combining engineering skills with management practice.

You will learn advanced concepts in the principles and operation of instrumentation for control, including control system architectures, communications, open systems security, hazard analysis, system reliability, safety and protection.

The course enables the appreciation of the practical aspects of control design and maintenance and offers hands-on experience in designing and developing solutions for control problem-solving using the IEC61131-3 standard. The course covers specialist and intelligent sensor systems, PLC-based control, Profibus and Profinet.

Core units

- Advanced Control and Instrumentation
- MSc Engineering Project

Option units

- Management Practice
- Embedded Systems and Systems on Chip
- Digital Signal Processing
- Sustainable Energy Systems
- Industrial Communication Systems
- Smart Technologies for Power Management
- Sensing and Imaging
- Manufacturing Systems Management

Optional units listed in the following curriculum structures are all approved for delivery, but may not all run/be available in any one academic session.

Assessment is though a combination of written reports, oral presentations, practical assignments and written examinations.

Career Prospects

You may enter the nuclear industry and target specific roles that fit with your own expertise. Learning in current regulations and industry-standard practice in control and instrumentation could be transferred across a range of industries.

You will also be well placed to pursue an employment position with partners or further study through a PhD or an Engineering Doctorate.

Careers support is available from the moment you join us, throughout your time here, and for up to three years after the completion of your course. We have a range of services available through the School of Engineering and the University Careers Service including dedicated careers and employability advisors.

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The Computer Animation Master’s programme at Kent is oriented towards current industrial needs, technology and practice. It is designed to be a direct route into this high-profile, modern and creative industry, and has been developed jointly by the School and our industrial partner Framestore CFC. Read more
The Computer Animation Master’s programme at Kent is oriented towards current industrial needs, technology and practice. It is designed to be a direct route into this high-profile, modern and creative industry, and has been developed jointly by the School and our industrial partner Framestore CFC.

Develop your knowledge and understanding of the animation process, software tools, techniques and packages, and the technical aspects of working in a professional animation environment. The MSc programme offers invaluable experience of working to professional briefs and under expert supervision of professional animators to prepare you for a career in industry.

Competition is fierce in animation and visual effects and success depends on your concentration levels, constant practise and ability to grasp the essence and modern techniques of animation. Successful former students are now working in animation and animation layout roles for companies such as Sony Games and Framestore CFC on major titles in games, television and film.

Visit the website https://www.kent.ac.uk/courses/postgraduate/248/computer-animation

About the School of Engineering and Digital Arts

The School of Engineering and Digital Arts successfully combines modern engineering and technology with the exciting field of digital media. The School, which was established over 40 years ago, has developed a top-quality teaching and research base, receiving excellent ratings in both research and teaching assessments.

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

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

Course structure

This intensively taught postgraduate course lasts a full year. It takes place in a dedicated computer laboratory where you have your own seat and computer for the duration of the course. The course lectures and workshops, whether led by visiting professionals or staff, are all held in this room. Demonstrations and showing of films are by means of an HD projector. By the end of the year, the lab will be where you live as much as your accommodation.

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

EL831 - Digital Visual Art set-up (15 credits)
EL832 - Animation Principles (15 credits)
EL833 - Visual Training (15 credits)
EL837 - Professional Group Work (15 credits)
EL863 - Advanced 3D Modelling (15 credits)
EL864 - Pre-Visualisation (15 credits)
EL865 - Action in Animation (15 credits)
EL866 - Acting in Animation (15 credits)
EL830 - Computer Animation Project (60 credits)

Assessment

Each module is assessed by practical assignments. The project work is assessed on the outcome of the project itself.

Programme aims

This programme aims to:

- enable you to develop your knowledge and understanding within the field of 3D computer animation, which will equip you to become a professional in the animation and visual effects industry

- produce professionally-trained animators who are highly skilled in using state-of-the-art 3D animation software for producing animated films

- provide you with proper academic guidance and welfare support

- create an atmosphere of co-operation and partnership between staff and students, and offer you an environment where you can develop your potential

- strengthen and expand opportunities for industrial collaboration with the School of Engineering and Digital Arts.

Research areas

- Intelligent Interactions

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

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

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

Careers

We have developed the programme with a number of industrial organisations, which means that successful students will be in a strong position to build a long-term career in this important discipline.

The School of Engineering and Digital Arts (http://www.eda.kent.ac.uk/) has an excellent record of student employability (http://www.eda.kent.ac.uk/school/employability.aspx). We are committed to enhancing the employability of all our students, to equip you with the skills and knowledge to succeed in a competitive, fast-moving, knowledge-based economy.

Graduates who can show that they have developed transferable skills and valuable experience are better prepared to start their careers and are more attractive to potential employers.

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

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Signal processing is recognised as a core technology in rapidly growing areas such as sensor networks, medical devices and renewable energy, audio, image and video systems. Read more

Why this course?

Signal processing is recognised as a core technology in rapidly growing areas such as sensor networks, medical devices and renewable energy, audio, image and video systems. It’s the underpinning technology of all communication including the internet, wireless and satellite.

We’ve been carrying out research and development in signal processing for more than 30 years. Many of today’s industry leaders are alumni of the University and this industry awareness and experience underpins this specialised degree.

This MSc aims to address the growing skills shortage in industry of engineers who have an understanding of the complete signal processing design cycle. It’s also essential preparation if you’re considering advanced research in applied signal processing.

See the website https://www.strath.ac.uk/courses/postgraduatetaught/signalprocessing/

What you’ll study

There are two semesters of compulsory and optional classes, followed by a three-month practical research project in a specialist area. There’s the opportunity to carry this out through the department's competitive MSc industrial internships.

The internships are offered in collaboration with selected department industry partners eg ScottishPower, SmarterGridSolutions, SSE. You'll address real-world engineering challenges facing the partner, with site visits, access and provision of relevant technical data and/or facilities provided, along with an industry mentor and academic supervisor.

Facilities

You'll have exclusive access to our extensive computing network and purpose built teaching spaces such as our Hyperspectral Imaging Centre and the DG Smith Radio Frequency laboratory, equipped with the latest technologies.

Accreditation

The course is fully accredited by the professional body, the Institution of Engineering and Technology (IET). This means that you'll meet the educational requirements to become a Chartered Engineer – a must for your future engineering career.

Pre-Masters preparation course

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

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

Learning & teaching

We use a blend of teaching and learning methods including interactive lectures, problem-solving tutorials and practical project-based laboratories. Our technical and experimental officers are available to support and guide you on individual subject material.

Each module comprises approximately five hours of direct teaching per week. To enhance your understanding of the technical and theoretical topics covered in these, you're expected to undertake a further five to six hours of self-study, using our web-based virtual learning environment (MyPlace), research journals and library facilities.

The teaching and learning methods used ensure you'll develop not only technical engineering expertise but also communications, project management and leadership skills.

- Industry engagement
Interaction with industry is provided through our internships, teaching seminars and networking events. The department delivers monthly seminars to support students’ learning and career development. Xilinx, Texas Instruments, MathWorks, and Agilent are just a few examples of the industry partners you can engage with during your course.

Assessment

A variety of assessment techniques are used throughout the course. You'll complete at least six modules. Each module has a combination of written assignments, individual and group reports, oral presentations, practical lab work and, where appropriate, an end-of-term exam.

Assessment of the summer research project/internship consists of four elements, with individual criteria:
1. Interim report (10%, 1,500 to 3,000 words) – the purpose of this report is to provide a mechanism for supervisors to provide valuable feedback on the project’s objectives and direction.

2. Poster Presentation (15%) – a vital skill of an engineer is the ability to describe their work to others and respond to requests for information. The poster presentation is designed to give you an opportunity to practise that.

3. Final report (55%) – this assesses the communication of project objectives and context, accuracy and relevant of background material, description of practical work and results, depth and soundness of discussion and conclusions, level of engineering achievement and the quality of the report’s presentation.

4. Conduct (20%) - independent study, project and time management are key features of university learning. The level of your initiative & independent thinking and technical understanding are assessed through project meetings with your supervisor and your written logbooks.

Careers

With Signal Processing being a core technology in high-growth areas such as sensor networks, medical devices, renewable energy and communications, this course enables you to capitalise on job opportunities across all of these sectors, as well as in electronics design, IT, banking, and oil and gas.

Almost all of our graduates secure jobs by the time they have completed their course. They've taken up well-paid professional and technical occupations with multinationals such as Google, Microsoft, Texas Instruments, Motorola Mobility, Intel, as well as Wolfson Microelectronics, Agilent, Freescale and Thales in the vibrant national UK arena.

Find information on Scholarships here http://www.strath.ac.uk/engineering/electronicelectricalengineering/ourscholarships/.

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The School conducts high-quality significant national and international research and offers excellent opportunities for graduate studies, successfully combining modern engineering and technology with the exciting field of digital media. Read more
The School conducts high-quality significant national and international research and offers excellent opportunities for graduate studies, successfully combining modern engineering and technology with the exciting field of digital media. The digital media group has interests in many areas of interactive multimedia and digital film and animation.

Visit the website https://www.kent.ac.uk/courses/postgraduate/264/digital-arts

About the School of Engineering and Digital Arts

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

The School undertakes high-quality research (http://www.eda.kent.ac.uk/research/default.aspx) that has had significant national and international impact, and our spread of expertise allows us to respond rapidly to new developments. Our 30 academic staff and over 130 postgraduate students and research staff provide an ideal focus to effectively support a high level of research activity. There is a thriving student population studying for postgraduate degrees in a friendly and supportive teaching and research environment.

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

Course structure

The digital media group has interests in many areas of interactive multimedia and digital film and animation.

There is particular strength in web design and development, including e-commerce, e-learning, e-health; and the group has substantial experience in interaction design (eg, Usability and accessibility), social computing (eg, Social networking, computer mediated communication), mobile technology (eg, iPhone), virtual worlds (eg, Second Life) and video games. In the area of time-based media, the group has substantial interest in digital film capture and editing, and manipulation on to fully animated 3D modelling techniques as used in games and feature films.

Research Themes:
- E-Learning Technology (http://www.eda.kent.ac.uk/research/theme_detail.aspx?gid=1&tid=1)

- Medical Multimedia Applications and Telemedicine (http://www.eda.kent.ac.uk/research/theme_detail.aspx?gid=1&tid=2)

- Human Computer Interaction and Social Computing (http://www.eda.kent.ac.uk/research/theme_detail.aspx?gid=1&tid=3)

- Computer Animation and Digital Visual Effects (http://www.eda.kent.ac.uk/research/theme_detail.aspx?gid=1&tid=4)

- Mobile Application Design and Development (http://www.eda.kent.ac.uk/research/theme_detail.aspx?gid=1&tid=25)

- Digital Arts (http://www.eda.kent.ac.uk/research/theme_detail.aspx?gid=1&tid=26)

Research areas

- Intelligent Interactions

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

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

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

Careers

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

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

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

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

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