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Masters Degrees (Medical Electronic)

We have 145 Masters Degrees (Medical Electronic)

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The MSc in Electronics with Medical Instrumentation aims to produce postgraduates with an ability to design and implement medical instrumentation based systems used for monitoring, detecting and analysing biomedical data. Read more
The MSc in Electronics with Medical Instrumentation aims to produce postgraduates with an ability to design and implement medical instrumentation based systems used for monitoring, detecting and analysing biomedical data. The course will provide ample opportunity to develop practical skill sets. The student will also develop an in-depth understanding of the scientific principles and use of the underlying components such as medical transducers, biosensors and state-of-the-art tools and algorithms used to implement and test diagnostic devices, therapeutic devices, medical imaging equipment and medical instrumentation devices.

The course broadens the discussion of medical equipment and its design by investigating a range of issues including medical equipment regulation, user requirements, impacts of risk, regulatory practice, legislation, quality insurance mechanisms, certification, ethics and ‘health and safety’ assessment. The course will enable a student with an interest in medical electronics to re-focus existing knowledge gained in software engineering, embedded systems engineering and/or electronic systems engineering and will deliver a set specialist practical skills and a deeper understanding of the underlying principles of medical physics. A graduate from this course will be able to immediately participate in this multi-disciplined engineering sector of biomedical and medical instrumentation systems design.

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.

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The MSc Design for Medical Technologies is aimed at providing the key knowledge and experience to allow you to pursue a career in bioengineering, healthcare or biotechnology. Read more
The MSc Design for Medical Technologies is aimed at providing the key knowledge and experience to allow you to pursue a career in bioengineering, healthcare or biotechnology. The course will expose you to the leading edge of modern medical and surgical technologies, as well as exploring the role of entrepreneurship, business development and intellectual property exploitation.

Why study Design for Medical Technologies at Dundee?

The unique environments of medicine and biotechnology offer exacting challenges in the design of high technology products for use in these fields. Engineers and product designers involved in the development of new biomedical instrumentation, surgical tools or biotechnology products must understand the constrictions placed on them by this environment. As a result, bioengineering has been established as the fusion of engineering and ergonomics with a deep understanding of medical science.

Benefits of the programme include:
Knowledge and understanding of medical and surgical engineering and technology
Skills in research methods, communications, teamwork and management
Appreciation of entrepreneurship and the global 'Medtech' industry
Participation in research activities of world renowned research groups
Preparation for careers in industry, academia and commerce

What's great about Design for Medical Technologies at Dundee?

The University of Dundee is one of the top UK universities, with a powerful research reputation, particularly in the medical and biomedical sciences. It has previously been named Scottish University of the Year and short-listed for the Sunday Times UK University of the year.

The Mechanical Engineering group has a high international research standing with expertise in medical instrumentation, signal processing, biomaterials, tissue engineering, advanced design in minimally invasive surgery and rehabilitation engineering.

Links and research partnerships:

We have extensive links and research partnerships with clinicians at Ninewells Hospital (largest teaching hospital in Europe) and with world renowned scientists from the University's College of Life Sciences.

The new Institute of Medical Science and Technology (IMSaT) at the University has been established as a multidisciplinary research 'hothouse' which seeks to commercialise and exploit advanced medical technologies leading to business opportunities.

The start date is September each year, and lasts for 12 months.

How you will be taught

The structure of the MSc course is divided into two parts. The taught modules expose students to the leading edge of modern medical and surgical technologies. The course gives concepts and understanding of the role of entrepreneurship, business development and intellectual property exploitation in the biomedical industry, with case examples.

The research project allows students to work in a research area of their own particular interest, learning skills in presentation, critical thinking and problem-solving. Project topics are offered to students during the first semester of the course.

What you will study

The three taught modules are:
Imaging and Instrumentation for Medicine and Surgery (30 Credits)
Biomechanics and Biomedical (30 Credits)
Advanced Medical and Surgical Instrumentation (30 Credits)

These modules are followed by the biomedical research project (90 credits).

How you will be assessed

The course is assessed by coursework and examination, plus research project.

Careers

The MSc Design for Medical Technologies is aimed at providing the key knowledge and experience to allow you to pursue a career in bioengineering, healthcare or biotechnology. This opens up a vast range of opportunities for employment in these industries as a design, development or product engineer, research scientist, sales and marketing manager or Director of a start-up company. The programme also provides the ideal academic grounding to undertake a PhD degree leading to a career in academic research.

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Medical imaging is a rapidly-growing discipline within the healthcare sector, involving clinicians, physicists, computer scientists and those in IT industries. Read more

Medical imaging is a rapidly-growing discipline within the healthcare sector, involving clinicians, physicists, computer scientists and those in IT industries.

This programme delivers the expertise you'll need to forge a career in medical imaging, including radiation physics, image processing, biology, computer vision, pattern recognition, artificial intelligence and machine learning.

Programme structure

This programme is studied full-time over 12 months and part-time over 48 months. It consists of eight taught modules and an extended project.

Example module listing

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Facilities, equipment and support

To support your learning, we hold regular MSc group meetings where any aspect of the programme, technical or non-technical, can be discussed in an informal atmosphere. This allows you to raise any problems that you would like to have addressed and encourages peer-based learning and general group discussion.

We provide computing support with any specialised software required during the programme, for example, Matlab.

The Department’s student common room is also covered by the university’s open-access wireless network, which makes it a very popular location for individual and group work using laptops and mobile devices. There is also a Faculty quiet room for individual study.

We pride ourselves on the many opportunities that we provide to visit collaborating hospitals. These enable you to see first-hand demonstrations of medical imaging facilities and to benefit from lectures by professional practitioners.

To support material presented during the programme, you will also undertake a selection of ultrasound and radiation detection experiments, hosted by our sister MSc programme in Medical Physics.

Educational aims of the programme

The taught postgraduate Degree Programmes of the Department are intended both to assist with professional career development within the relevant industry and, for a small number of students, to serve as a precursor to academic research.

Our philosophy is to integrate the acquisition of core engineering and scientific knowledge with the development of key practical skills (where relevant).

To fulfil these objectives, the programme aims to:

  • Attract well-qualified entrants, with a background in Electronic Engineering, Physical Sciences, Mathematics, Computing & Communications, from the UK, Europe and overseas
  • Provide participants with advanced knowledge, practical skills and understanding applicable to the MSc degree
  • Develop participants' understanding of the underlying science, engineering, and technology, and enhance their ability to relate this to industrial practice
  • Develop participants' critical and analytical powers so that they can effectively plan and execute individual research/design/development projects
  • Provide a high level of flexibility in programme pattern and exit point
  • Provide students with an extensive choice of taught modules, in subjects for which the Department has an international and UK research reputation

Technical characteristics of the pathway

Medical Imaging is a rapidly growing discipline within the healthcare sector, incorporating engineers, physicists, computer scientists and clinicians. It is driven by the recent rapid development of 3-D Medical Imaging Systems, fuelled by an exponential rise in computing power.

New methods have been developed for the acquisition, reconstruction, processing and display of digital medical-image data with unprecedented speed, resolution and contrast.

This programme in Medical Imaging is aimed at training graduates for careers in this exciting multi-disciplinary area, and our graduates can expect to find employment in the medical imaging industry or the public health care sector.

It represents a blend of fundamental medical physics topics concerned with image acquisition and reconstruction coupled with imaging science and image engineering topics such that graduates understand how images are formed and how advanced machine-based methods can be bought to bare to provide new diagnostic information.

Global opportunities

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.



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With an ever growing demand for skilled electronic engineers, our course will equip you with the skills and expertise you’ll need to meet the challenges of a constantly changing industrial world. Read more
With an ever growing demand for skilled electronic engineers, our course will equip you with the skills and expertise you’ll need to meet the challenges of a constantly changing industrial world.

Your course will have a new home in Compass House, which will extend our campus along East Road. You’ll have the latest technology at your fingertips and be able to collaborate with other students on innovative projects to hone your skills.

See the website http://www.anglia.ac.uk/study/postgraduate/electronic-and-electrical-engineering

Our course covers a number of contemporary topics, including power electronics, signal processing, renewable systems, holistic modeling of electronic systems and image processing. Building on your previous experience, and with developed practical skills, you’ll leave with the expert knowledge and understanding to practice safely and effectively in a wide range of environments.

Cambridge is home to the Silicon Fen, Europe’s largest high-technology commercial research and development centre. We have excellent, established links with many employers in the sector including:

- ARM Ltd
- British Computer Society
- Cambridge Network
- Cambridge Silicon Radio
- E2V
- Ford Motor Company
- Selex Sensors and Airborne Systems
- South East Essex PCT

Our specially equipped laboratories provide you with the essential tools you need in the field of industrial electronics and microelectronics. Among other features they are equipped with wind and solar energy systems, development boards with FPGA circuits and power electronics modules. You’ll also have access to our CAD laboratories with the very latest software.

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

See the website http://www.anglia.ac.uk/study/postgraduate/electronic-and-electrical-engineering

Our course is designed to address the challenges of the modern industrial world. It focuses on power electronics, renewable systems, signal processing, holistic modelling of electronic systems and image processing. The main aims of the course are to:
• Meet a local, national and international demand for skilled electronic and electrical engineers.
• Provide an opportunity for students to gain in-depth relevant specialist knowledge in electronics systems design.
• Synthesise formal solutions through the application of specialist knowledge to design and create innovative electronic and electrical circuits.
• Perform and develop objective and critical analysis skills necessary to synthesis effective solutions when presented with a set of specifications.
• Equip you with the appropriate depth in understanding of electronic engineering development tools and techniques.

Upon completion of the course you will be able to:
• Exercise an in-depth understanding of the design mechanisms which can be used to create electronic and electrical designs and critically evaluate their effectiveness.
• Demonstrate an ability to deal with complex and interdependent design issues both systematically and creatively in a sustainability context.
• Analyse and devise strategies to design, evaluate and optimise microelectronics based systems.
• Critically evaluate the tools and techniques required to create microelectronics circuits which satisfy specifications.
• Analyse current research and technical problems within the discipline for further reflection for evaluation and critique.
• Recognise your obligations to function in a professional, moral and ethical way.
• Synthesise original circuit design from a knowledge of current tools, methodologies and strategies.
• Critically survey current and recent practice in the field of electronic and electrical engineering, in a sustainability context, in order to identify examples of best practice and to propose new hypotheses.
• Develop the ability to act autonomously to plan and manage a project through its life cycle, and to reflect on the outcomes.
• Define the goals, parameters and methodology of a research and development activity.

Careers

The possibilities that are open to you range from design or systems engineering, to medical electronics, environmental monitoring, sound technology biophysics or microelectronics. Across industry, whether it’s in process control, construction and building or services, teaching and beyond, there’ll be opportunities to find your own specialist niche.

Core modules

Sustainable Technologies
DSP Applications and ARM® Technology
Digital Systems Design with VHDL and FPGAs
Power Conversion Systems
Remote Sensing and the Internet of Things
Research Methods
Major Project

Assessment

You’ll be assessed through exams and written assignments based on case studies and scenarios.

Facilities

Our Department has specialist laboratories for electronics and microelectronics, equipped with wind and solar energy systems, power electronics modules, development boards with FPGA circuits and more. Our laboratories are designed, maintained, and operated by an in-house team of technical experts. Students also benefit from access to a wide range of central computing and media facilities.

We also operate modern electronic Computer Aided Design labs loaded with the latest software that includes Integrated Synthesis Environment Design Suite, Matlab, Simulink and other relevant software.

Your faculty

The Faculty of Science & Technology is one of the largest of five faculties at Anglia Ruskin University. Whether you choose to study with us full- or part-time, on campus or at a distance, there’s an option whatever your level – from a foundation degree, to a BSc, MSc, PhD or professional doctorate.

Whichever course you pick, you’ll gain the theory and practical skills needed to progress with confidence. Join us and you could find yourself learning in the very latest laboratories or on field trips or work placements with well-known and respected companies. You may even have the opportunity to study abroad.

Everything we do in the faculty has a singular purpose: to provide a world-class environment to create, share and advance knowledge in science and technology fields. This is key to all of our futures.

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Why Surrey?. This degree mirrors the two-year Masters programme structure that is common in the USA, and is an ideal stepping stone to a PhD or a career in industry. Read more

Why Surrey?

This degree mirrors the two-year Masters programme structure that is common in the USA, and is an ideal stepping stone to a PhD or a career in industry.

The optional professional placement component gives you the opportunity to gain experience from working in industry, which cannot normally be offered by the standard technically-focused one-year Masters programme.

Programme overview

The Electronic Engineering Euromasters programme is designed for electronic engineering graduates and professionals with an interest in gaining further qualifications in advanced, cutting-edge techniques and technologies. Current pathways offered include:

  • Communications Networks and Software
  • RF and Microwave Engineering
  • Mobile Communications Systems
  • Mobile and Satellite Communications
  • Mobile Media Communications
  • Computer Vision, Robotics and Machine Learning
  • Satellite Communications Engineering
  • Electronic Engineering
  • Space Engineering
  • Nanotechnology and Renewable Energy
  • Medical Imaging

Please note that at applicant stage, it is necessary to apply for the Electronic Engineering (Euromasters). If you wish to specialise in one of the other pathways mentioned above, you can adjust your Euromaster programme accordingly on starting the course.

Programme structure

This programme is studied full-time over 24 months. It consists of eight taught modules, two modules based on experimental reflective learning and an extended project.

Please view the website for an example module listing.

Partners

The MSc Euromasters complies with the structure defined by the Bologna Agreement, and thus it is in harmony with the Masters programme formats adhered to in European universities. Consequently, it facilitates student exchanges with our partner universities in the Erasmus Exchange programme.

A number of bilateral partnerships exist with partner institutions at which students can undertake their project. Current partnerships held by the Department include the following:

  • Brno University of Technology, Czech Republic
  • University of Prague, Czech Republic
  • Universität di Bologna, Italy
  • Universität Politècnica de Catalunya, Barcelona, Spain
  • Universita' degli Studi di Napoli Federico II, Italy

Educational aims of the programme

The taught postgraduate degree programmes of the Department are intended both to assist with professional career development within the relevant industry and, for a small number of students, to serve as a precursor to academic research.

Our philosophy is to integrate the acquisition of core engineering and scientific knowledge with the development of key practical skills (where relevant). To fulfil these objectives, the programme aims to:

  • Attract well-qualified entrants, with a background in electronic engineering, physical sciences, mathematics, computing and communications, from the UK, Europe and overseas
  • Provide participants with advanced knowledge, practical skills and understanding applicable to the MSc degree
  • Develop participants' understanding of the underlying science, engineering, and technology, and enhance their ability to relate this to industrial practice
  • Develop participants' critical and analytical powers so that they can effectively plan and execute individual research/design/development projects
  • Provide a high level of flexibility in programme pattern and exit point
  • Provide students with an extensive choice of taught modules, in subjects for which the Department has an international and UK research reputation

A graduate from this MSc programme should:

  • Know, understand and be able to apply the fundamental mathematical, scientific and engineering facts and principles that underpin electronic engineering
  • Be able to analyse problems within the field of electronic engineering and find solutions
  • Be able to use relevant workshop and laboratory tools and equipment, and have experience of using relevant task-specific software packages to perform engineering tasks
  • Know, understand and be able to use the basic mathematical, scientific and engineering facts and principles associated with the topics within electronic engineering
  • Be aware of the societal and environmental context of his/her engineering activities
  • Be aware of commercial, industrial and employment-related practices and issues likely to affect his/her engineering activities
  • Be able to carry out research-and-development investigations
  • Be able to design electronic circuits and electronic/software products and systems

Enhanced capabilities of MSc (Euromasters) graduates:

  • Demonstrate transferable skills such as problem solving, analysis and critical interpretation of data, through the undertaking of the extended 90-credit project
  • Know how to take into account constraints such as environmental and sustainability limitations, health and safety and risk assessment
  • Have gained comprehensive understanding of design processes
  • Understand customer and user needs, including aesthetics, ergonomics and usability
  • Have acquired experience in producing an innovative design
  • Appreciate the need to identify and manage cost drivers
  • Have become familiar with the design process and the methodology of evaluating outcomes
  • Have acquired knowledge and understanding of management and business practices
  • Have gained the ability to evaluate risks, including commercial risks
  • Understand current engineering practice and some appreciation of likely developments
  • Have gained extensive understanding of a wide range of engineering materials/components
  • Understand appropriate codes of practice and industry standards
  • Have become aware of quality issues in the discipline

Global opportunities

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.



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This programme pathway is designed for students with an interest in the engineering aspects of technology that are applied in modern medicine. Read more

This programme pathway is designed for students with an interest in the engineering aspects of technology that are applied in modern medicine. Students gain an understanding of bioengineering principles and practices that are used in hospitals, industries and research laboratories through lectures, problem-solving sessions, a research project and collaborative work.

About this degree

Students study in detail the engineering and physics principles that underpin modern medicine, and learn to apply their knowledge to established and emerging technologies in medical imaging and patient monitoring. The programme covers the engineering applications across the diagnosis and measurement of the human body and its physiology, as well as the electronic and computational skills needed to apply this theory in practice.

Students undertake modules to the value of 180 credits.

The programme consists of seven core modules (105 credits), one optional module (15 credits), and a research project (60 credits).

A Postgraduate Diploma (120 credits) is offered.

A Postgraduate Certificate (60 credits) is offered.

Core modules

  • Ionising Radiation Physics: Interactions and Dosimetry
  • Imaging with Ionising Radiation
  • MRI and Biomedical Optics
  • Ultrasound in Medicine
  • Medical Electronics and Control
  • Clinical Practice
  • Medical Device Enterprise Scenario

Optional modules

Students choose one of the following:

  • Applications of Biomedical Engineering
  • Materials and Engineering for Orthopaedic Devices
  • Computing in Medicine
  • Programming Foundations for Medical Image Analysis

Dissertation/report

All MSc students undertake an independent research project within the broad area of physics and engineering in medicine which culminates in a written report of 10,000 words, a poster and an oral examination.

Teaching and learning

The programme is delivered through a combination of lectures, demonstrations, practicals, assignments and a research project. Lecturers are drawn from UCL and from London teaching hospitals including UCLH, St. Bartholomew's, and the Royal Free Hospital. Assessment is through supervised examination, coursework, the dissertation and an oral examination.

Further information on modules and degree structure is available on the department website: Physics and Engineering in Medicine: Biomedical Engineering and Medical Imaging MSc

Funding

For a comprehensive list of the funding opportunities available at UCL, including funding relevant to your nationality, please visit the Scholarships and Funding website.

Careers

Graduates from the Biomedical Engineering and Medical Imaging stream of the MSc programme have obtained employment with a wide range of employers in health care, industry and academia sectors.

Employability

Postgraduate study within the department offers the chance to develop important skills and acquire new knowledge through involvement with a team of scientists or engineers working in a world-leading research group. Graduates complete their study having gained new scientific or engineering skills applied to solving problems at the forefront of human endeavour. Skills associated with project management, effective communication and teamwork are also refined in this high-quality working environment.

Why study this degree at UCL?

The spectrum of medical physics activities undertaken in UCL Medical Physics & Biomedical Engineering is probably the broadest of any in the United Kingdom. The department is widely acknowledged as an internationally leading centre of excellence and students receive comprehensive training in the latest methodologies and technologies from leaders in the field.

The department operates alongside the NHS department which provides the medical physics and clinical engineering services for the UCL Hospitals Trust, as well as undertaking industrial contract research and technology transfer.

Students have access to a wide range of workshop, laboratory, teaching and clinical facilities in the department and associated hospitals. A large range of scientific equipment is available for research involving nuclear magnetic resonance, optics, acoustics, X-rays, radiation dosimetry, and implant development, as well as new biomedical engineering facilities at the Royal Free Hospital and Royal National Orthopaedic Hospital in Stanmore.



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This course offers the academic training required for a career in scientific support of medical procedures and technology. The course is coordinated through the Medical Physics Departments in St. Read more
This course offers the academic training required for a career in scientific support of medical procedures and technology. The course is coordinated through the Medical Physics Departments in St. James's Hospital and St. Luke's Hospital, Dublin.

Students enter via the M.Sc. register. This course covers areas frequently known as Medical Physics and Clinical Engineering. It is designed for students who have a good honours degree in one of the Physical Sciences (physics, electronic or mechanical engineering, computer science, mathematics) and builds on this knowledge to present the academic foundation for the application of the Physical Sciences in Medicine.

The course will be delivered as lectures, demonstrations, seminars, practicals and workshops. All students must take a Core Module. Upon completion of this, the student will then take one of three specialisation tracks in Diagnostic Radiology, Radiation Therapy or Clinical Engineering. The running of each of these tracks is subject to a minimum number of students taking each track and therefore all three tracks may not run each year.

Core Modules

Introduction to Radiation Protection andamp; Radiation Physics (5 ECTS)
Imaging Physics andamp; Technology (5 ECTS)
Introduction to Radiotherapy and Non-Ionising Imaging (5 ECTS)
Basic Medical Sciences (5 ECTS)
Introduction to Research Methodology and Safety (5 ECTS)
Medical Technology and Information Systems (5 ECTS)
Seminars (5 ECTS)
Specialisation Track Modules (Diagnostic Radiology)

Radiation Physics and Dosimetry (5 ECTS)
Medical Informatics and Image Processing (5 ECTS)
Ionising and Non-Ionising Radiation Protection (5 ECTS)
Imaging Physics and Technology 2 (10 ECTS)
Specialisation Track Modules (Radiation Therapy)

Radiation Physics and Dosimetry (5 ECTS)
Principles and Applications of Clinical Radiobiology (5 ECTS)
External Beam Radiotherapy (10 ECTS)
Brachytherapy and Unsealed Source Radiotherapy (5 ECTS)
Specialisation Track Modules (Clinical Engineering)

The Human Medical Device Interface (5 ECTS)
Principle and Practice of Medical Technology Design, Prototyping andamp; Testing (5 ECTS)
Medical Technology 1: Critical Care (5 ECTS)
Medical Technology 2: Interventions, Therapeutics andamp; Diagnostics (5 ECTS)
Medical Informatics and Equipment Management (5 ECTS)
Project Work and Dissertation (30 ECTS)

In parallel with the taught components, the students will engage in original research and report their findings in a dissertation. A pass mark in the assessment components of all three required sections (Core Module, Specialisation Track and Dissertation) will result in the awarding of MSc in Physical Sciences in Medicine. If the student does not pass the dissertation component, but successfully passes the taught components, an exit Postgraduate Diploma in Physical Sciences in Medicine will be awarded. Subject areas include

Radiation Protection and Radiation Physics
Imaging Physics and Technology
Basic Medical Sciences
Medical Technology Design, Prototyping and Testing
Medical Informatics
Image Processing
External Bean Radiotherapy
Brachytherapy and Unsealed Source Radiotherapy
The Human-Medical Device Interface
The course presents the core of knowledge for the application of the Physical Sciences in Medicine; it demonstrates practical implementations of physics and engineering in clinical practice, and develops practical skills in selected areas. It also engages students in original research in the field of Medical Physics / Engineering. The course is designed to be a 1 year full-time course but is timetabled to facilitate students who want to engage over a 2 year part-time process.

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Our Masters in Electrical and Electronic Engineering is an advanced course designed for engineering graduates to enhance their skills in this area of high technology. Read more
Our Masters in Electrical and Electronic Engineering is an advanced course designed for engineering graduates to enhance their skills in this area of high technology. The ever increasing pace of developments in all areas of electrical and electronic engineering, (and in particular in the systems that are related to energy and the environment), requires engineers with a thorough understanding of operation principles and design methods for various modern electrical and electronic systems. As a graduate you'll be able to not only respond to the latest changes but also to look ahead and help in shaping future developments.

The unique features of this course are that the traditional electrical and electronic engineering subjects are supported by the more modern topics of computer control and machine learning techniques, which are at the forefront of modern electrical and electronic systems in the industry today. This course offers an integrated systems approach to engineering, incorporating modules in advanced power electronics and renewable energy systems, advanced instrumentation and control with signal processing, real-time systems and machine learning techniques.

There is an increasing demand for skilled engineers who are able to design and maintain electrical and electronic systems that are at the forefront of current technologies. These positions cover many industries, hence graduates from this course can expect significantly enhanced job prospects in electrical, electronic as well as systems engineering.

Modules

Digital signal processing
Pattern recognition and machine learning
Advanced Instrumentation and Design
Advanced power electronics and renewable energy systems
Technology evaluation and commercialization
Technical, research and professional skills
MSc engineering project

Professional links

The School has a strong culture of research and extensive research links with industry through consultancy works and Knowledge Transfer Partnerships (KTPs). Teaching content on our courses is closely related to the latest research work.

This course is accredited by the IET as meeting the further learning requirements for CEng registration. The IET is one of the world’s largest engineering institutions with over 167,000 members in 127 countries.

Employability

The acquired skills in computer control and AI techniques offer additional scope for jobs in the design of decision support systems that cross traditional boundaries between engineering and other disciplines. (i.e. medical, finance). Successful graduates will enjoy exciting career opportunities from a wide range of industries, such as electrical energy supply and control, electronics and instrumentation products and services, intelligent systems and automation to include: automotive, aerospace, electrical and electronic consumer products, telecommunications. The students can also pursue PhD studies after completing the course.

Engineering management skills

Engineering employers have expressed their need for engineers with a solid grasp of the business requirements that underpin real engineering projects. Our course incorporates a management-related module focused on entrepreneurship and project management. This management module develops our graduates' commercial awareness and ensures that they have the skill-set valued by industry employers.

LSBU Employability Services

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

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

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This taught Masters is designed to provide you with an advanced programme of study in Medical Physics. It provides an understanding of the application of physics and technology to a range of disciplines within medical physics at a level appropriate for a professional physicist. Read more
This taught Masters is designed to provide you with an advanced programme of study in Medical Physics. It provides an understanding of the application of physics and technology to a range of disciplines within medical physics at a level appropriate for a professional physicist. We have expertise in traditional areas like ionising radiation, but also specialist sections in PET Scanning, Ophthalmology, Urology, Informatics and leading researchers in MRI.

Why this programme

◾A key strength of this programme is that you will be taught mostly by physicists working in the NHS. It will quip you for employment in a clinical environment.
◾Due to the large size of the NHS medical physics department in Glasgow, all mainstream areas of medical physics are covered along with some specialised fields.
◾The programme is accredited with the Institute of Physics & Engineering in Medicine (IPEM), the UK professional body for medical physicists.
◾The department has access to 1.5, 3 and 7 Tesla MRI, Pet Scanning, a cyclotron, dedicated SPECT and has its own radiosotope dispensary.
◾Your lecturers are operating at the forefront of the profession with a balance of research and clinical practice, perfect for studying Medical Science.
◾The research component of this programme allows you to develop valuable skills for practising and interpreting research.
◾We draw on expert resources within the wider university for anatomy, statistics and the two optional courses.

Programme structure

You will attend lectures, seminars and tutorials, take part in e-learning and undertake a research project.

Core courses
◾Radiation physics
◾Anatomy and physiology
◾Statistics and experimental techniques
◾Medical imaging physics
◾Programming
◾Scientific management
◾Clinical medical imaging
◾Radiotherapy
◾Clinical measurement
◾Research dissertation.

Optional courses
◾Advanced data analysis
◾Problem solving.

Career prospects

Career opportunities include positions in the NHS, private healthcare and equipment manufacturers. This is the course followed by the NHS trainees in Scotland so it is highly attuned to preparing the successful student for employment.

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This is a course designed to meet the needs of medical educators. It will enable you to meet the new General Medical Council (GMC) standards for trainers and be accredited by Health Education North West as clinical or educational supervisors. Read more
This is a course designed to meet the needs of medical educators. It will enable you to meet the new General Medical Council (GMC) standards for trainers and be accredited by Health Education North West as clinical or educational supervisors.

The programme is suitable for consultants, higher speciality trainees and non-consultant career-grade doctors working within the Health Education North West region.

What will I study?

You will study three modules, the first two of which will provide you with an introduction to medical education in the clinical workplace and offer an in-depth exploration of educational supervision in the medical workplace.

For the third module, you will choose a specific theme from options including educational leadership, simulation, technology enhanced learning, management, teaching and learning, and mentoring and coaching.

How will I study?

The programme primarily comprises substantial studying online via the University’s Virtual Learning Environment where you will find an array of specially-created learning materials to support each module and also a discussion board for active debate within each Learning Set. You will also have access to a vast range of electronic resources, including e-books and electronic journals, which can be accessed online.

The course also requires attendance at one full induction day in addition to a small number of half-day workshops for each module.

How will I be assessed?

There are no exams on this programme. Instead, a variety of coursework assignments will be used, including reflective case studies on actual practice, peer observation of teaching, and short seminar presentations.

Who will be teaching me?

The course team consists of a mixture of academic staff and experienced medical educators from clinical practice. You can expect to have contact with both academic tutors and experienced clinicians throughout the course. The course team is highly experienced in designing and delivering postgraduate online learning for medical educators.

What are my career prospects?

Successful completion of this programme will enable you to critically analyse and explore the role of teaching and learning in the clinical context and make critical judgments within the medical workplace.

You will enhance your skills in teaching, assessment, appraisal, supervision and reflective practice, with the opportunity to review your own professional needs and to plan and undertake relevant and appropriate activities to meet those identified needs.

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This Master's degree, run by Birkbeck in association with the Royal College of Physicians (RCP), is designed specifically for doctors to help them to deal with the modern-day pressures and situations that they face as leaders in the medical world. Read more
This Master's degree, run by Birkbeck in association with the Royal College of Physicians (RCP), is designed specifically for doctors to help them to deal with the modern-day pressures and situations that they face as leaders in the medical world. Modules are delivered in purpose-built teaching facilities at the Royal College of Physicians (RCP) in London.

The academic content is put into clinical context through medical case studies. Presentations about these case studies are given by expert speakers, including postgraduate deans, medical directors and hospital chief executives.

Why study this course at Birkbeck?

Gain the qualification, skills and knowledge to become an effective leader in the modern-day medical workplace, increasing your future promotion prospects.
Unique opportunities to meet and learn from leading medical figures.
The programme is approved for external, non-clinical CPD credits (1 credit an hour) and can be added as self-certified entries to the CPD diary.
Access to an extensive range of electronic resources, including specially prepared texts for each module and access to Birkbeck's online learning environment. Full access to the Medical Education Resource Centre (MERC) at the RCP which offers a leading collection of books and reports on all aspects of medical leadership to support you.

Our research

Birkbeck is one of the world’s leading research-intensive institutions. Our cutting-edge scholarship informs public policy, achieves scientific advances, supports the economy, promotes culture and the arts, and makes a positive difference to society.

Birkbeck’s research excellence was confirmed in the 2014 Research Excellence Framework, which placed Birkbeck 30th in the UK for research, with 73% of our research rated world-leading or internationally excellent.

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The M.Sc. in Medical Physics is a full time course which aims to equip you for a career as a scientist in medicine. You will be given the basic knowledge of the subject area and some limited training. Read more
The M.Sc. in Medical Physics is a full time course which aims to equip you for a career as a scientist in medicine. You will be given the basic knowledge of the subject area and some limited training. The course consists of an intense program of lectures and workshops, followed by a short project and dissertation. Extensive use is made of the electronic learning environment "Blackboard" as used by NUI Galway. The course has been accredited by the Institute of Physics and Engineering in Medicine (UK).

Syllabus Outline. (with ECTS weighting)
Human Gross Anatomy (5 ECTS)
The cell, basic tissues, nervous system, nerves and muscle, bone and cartilage, blood, cardiovascular system, respiratory system, gastrointestinal tract, nutrition, genital system, urinary system, eye and vision, ear, hearing and balance, upper limb – hand, lower limb – foot, back and vertebral column, embryology, teratology, anthropometrics; static and dynamic anthropometrics data, anthropometric dimensions, clearance and reach and range of movement, method of limits, mathematics modelling.

Human Body Function (5 ECTS)
Biological Molecules and their functions. Body composition. Cell physiology. Cell membranes and membrane transport. Cell electrical potentials. Nerve function – nerve conduction, nerve synapses. Skeletal muscle function – neuromuscular junction, muscle excitation, muscle contraction, energy considerations. Blood and blood cells – blood groups, blood clotting. Immune system. Autonomous nervous system. Cardiovascular system – electrical and mechanical activity of the heart. – the peripheral circulation. Respiratory system- how the lungs work. Renal system – how the kidneys work. Digestive system. Endocrine system – how hormones work. Central nervous system and brain function.

Occupational Hygiene (5 ECTS)
Historical development of Occupational Hygiene, Safety and Health at Work Act. Hazards to Health, Surveys, Noise and Vibrations, Ionizing radiations, Non-Ionizing Radiations, Thermal Environments, Chemical hazards, Airborne Monitoring, Control of Contaminants, Ventilation, Management of Occupational Hygiene.

Medical Informatics (5 ECTS)
Bio statistics, Distributions, Hypothesis testing. Chi-square, Mann-Whitney, T-tests, ANOVA, regression. Critical Appraisal of Literature, screening and audit. Patient and Medical records, Coding, Hospital Information Systems, Decision support systems. Ethical consideration in Research.
Practicals: SPSS. Appraisal exercises.

Clinical Instrumentation (6 ECTS)
Biofluid Mechanics: Theory: Pressures in the Body, Fluid Dynamics, Viscous Flow, Elastic Walls, Instrumentation Examples: Respiratory Function Testing, Pressure Measurements, Blood Flow measurements. Physics of the Senses: Theory: Cutaneous and Chemical sensors, Audition, Vision, Psychophysics; Instrumentation Examples: Evoked responses, Audiology, Ophthalmology instrumentation, Physiological Signals: Theory Electrodes, Bioelectric Amplifiers, Transducers, Electrophysiology Instrumentation.

Medical Imaging (10 ECTS)
Theory of Image Formation including Fourier Transforms and Reconstruction from Projections (radon transform). Modulation transfer Function, Detective Quantum Efficiency.
X-ray imaging: Interaction of x-rays with matter, X-ray generation, Projection images, Scatter, Digital Radiography, CT – Imaging. Fundamentals of Image Processing.
Ultrasound: Physics of Ultrasound, Image formation, Doppler scanning, hazards of Ultrasound.
Nuclear Medicine : Overview of isotopes, generation of Isotopes, Anger Cameras, SPECT Imaging, Positron Emitters and generation, PET Imaging, Clinical aspects of Planar, SPECT and PET Imaging with isotopes.
Magnetic Resonance Imaging : Magnetization, Resonance, Relaxation, Contrast in MR Imaging, Image formation, Image sequences, their appearances and clinical uses, Safety in MR.

Radiation Fundamentals (5 ECTS)
Review of Atomic and Nuclear Physics. Radiation from charged particles. X-ray production and quality. Attenuation of Photon Beams in Matter. Interaction of Photons with Matter. Interaction of Charged Particles with matter. Introduction to Monte Carlo techniques. Concept to Dosimetry. Cavity Theory. Radiation Detectors. Practical aspects of Ionization chambers

The Physics of Radiation Therapy (10 ECTS)
The interaction of single beams of X and gamma rays with a scattering medium. Treatment planning with single photon beams. Treatment planning for combinations of photon beams. Radiotherapy with particle beams: electrons, pions, neutrons, heavy charged particles. Special Techniques in Radiotherapy. Equipment for external Radiotherapy. Relative dosimetry techniques. Dosimetry using sealed sources. Brachytherapy. Dosimetry of radio-isotopes.

Workshops / Practicals
Hospital & Radiation Safety [11 ECTS]
Workshop in Risk and Safety.
Concepts of Risk and Safety. Legal Aspects. Fundamental concepts in Risk Assessment and Human Factor Engineering. Risk and Safety management of complex systems with examples from ICU and Radiotherapy. Accidents in Radiotherapy and how to avoid them. Principles of Electrical Safety, Electrical Safety Testing, Non-ionizing Radiation Safety, including UV and laser safety.
- NUIG Radiation Safety Course.
Course for Radiation Safety Officer.
- Advanced Radiation Safety
Concepts of Radiation Protection in Medical Practice, Regulations. Patient Dosimetry. Shielding design in Diagnostic Radiology, Nuclear Medicine and Radiotherapy.
- Medical Imaging Workshop
Operation of imaging systems. Calibration and Quality Assurance of General
radiography, fluoroscopy systems, ultrasound scanners, CT-scanners and MR scanners. Radiopharmacy and Gamma Cameras Quality Control.

Research Project [28 ECTS]
A limited research project will be undertaken in a medical physics area. Duration of this will be 4 months full time

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This MSc course in Advanced Electronic and Electrical Engineering is specifically designed for students who wish to pursue a broad programme of advanced studies, whilst also offering a wide range of specialist modules which open a variety of career pathways on graduation. Read more

About the course

This MSc course in Advanced Electronic and Electrical Engineering is specifically designed for students who wish to pursue a broad programme of advanced studies, whilst also offering a wide range of specialist modules which open a variety of career pathways on graduation. The distinctive feature of the MSc is its flexible structure – you are able to customise the content of your programme to meet your academic interests and career aspirations. Core modules are used to ensure there is depth and breadth in key areas of electronic and electrical engineering – notably sensors and instrumentation, control, photonics, sustainable power systems, telecommunications, intelligent systems, medical systems, integrated circuits and embedded systems.

Aims

Having an advanced, broad level of engineering knowledge and skills is a prerequisite for improving your career options in a demanding and dynamic sector. The course allows graduates with an electronic and electrical engineering background to further develop their skills as well as allowing able students from other numerate degree backgrounds to build up strong expertise in this area to complement their original undergraduate studies.
On the MSC programme you will:
Gain the in-depth knowledge you need to resolve new, complex and unusual challenges across a range of electrical and electronics issues.
Develop imagination, initiative and creativity to allow you to problem solve effectively.
Become work ready for a career with leading engineering organisations.

Women in Engineering Scholarships

Both the Government and Brunel University are keen to promote women taking up degrees in Engineering, and we are offering exciting scholarships linked to a bespoke mentoring programme to eligible Home / EU applicants. Please read more about these Women in Engineering Scholarships. http://www.brunel.ac.uk/study/postgraduate-fees-and-funding/funding

Course Content

Core Modules

Project Management
Advanced Analogue Electronics & Photonics
Applied Sensors, Instrumentation and Control
AEEE Group Project
Power Electronics and FACTS

Optional Modules

Choose three modules with at least one from:
Analogue Integrated Circuit Design
Embedded Systems Engineering
DSP for Communications
Intelligent Systems
Project/Dissertation

Special Features

The Electronic and Computer Engineering discipline is one of the largest in the University, with a portfolio of research contracts totalling £7.5 million, and has strong links with industry.
We have a wide range of research groups, each with a complement of academics and research staff and students. The groups are:
Media Communications
Wireless Networks and Communications
Brunel Institute for Power Systems
Electronic Systems
Sensors and Instrumentation
Our laboratories are well equipped with an excellent range of facilities to support the research work and courses. We have comprehensive computing resources in addition to those offered centrally by the University. The discipline is particularly fortunate in having extensive gifts of software and hardware to enable it to undertake far-reaching design projects.
This course is accredited by the Institution of Engineering and Technology (IET).

Women in Engineering and Computing Programme

Brunel’s Women in Engineering and Computing mentoring scheme provides our female students with invaluable help and support from their industry mentors.

Teaching and Assessment

Teaching

This course in Advanced Electronic and Electrical Engineering blends lectures, tutorials, laboratories, individual and group projects with presentations and a major research based dissertation project.
External lectures and research seminars will be used to enhance the student experience and highlight the application of the technologies in industry.

Assessment

You will be assessed on your written assignments, presentations, examinations and a major dissertation project.
The course comprises a blend of lectures, tutorials, laboratories, individual and group projects, presentations and a major research-based dissertation project, with external lectures and research seminars used to enhance your experience and highlight the application of the technologies in industry.

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The Integrated Photonic and Electronic Systems MRes, taught at the University of Cambridge and at the UCL Centre for Doctoral Training in Integrated Photonic and Electronic Systems, aims to train students to PhD level in the skills needed to produce new integrated photonic systems for applications ranging from information display to ultra-fast communications and industrial materials processing. Read more

The Integrated Photonic and Electronic Systems MRes, taught at the University of Cambridge and at the UCL Centre for Doctoral Training in Integrated Photonic and Electronic Systems, aims to train students to PhD level in the skills needed to produce new integrated photonic systems for applications ranging from information display to ultra-fast communications and industrial materials processing.

About this degree

The programme offers a wide range of specialised modules, including electronics and biotechnology. Students gain a foundation training in the scientific basis of photonics and systems, and develop a good understanding of the industry. They are able to design an individual bespoke programme to reflect their prior experience and future interests.

Students undertake modules to the value of 180 credits.

Students take two compulsory research projects (90 credits), one transferable skills module (15 credits), three optional modules (45 credits) and two elective modules (30 credits).

  • Project Report 1 at either UCL or Cambridge
  • Project Report 2 at either UCL, Cambridge or in industry
  • Transferable Business Skills

Optional modules

Students choose three optional modules from the following:

  • Biosensors
  • Advanced Photonic Devices
  • Photonic Systems
  • Broadband Technologies and Components
  • Management of Technology
  • Strategic Management
  • Telecommunication Business Environment

Elective modules

Students choose a further two elective modules from the list below:

  • Electronic Sensors and Instrumentation
  • Display Technology
  • Analogue Integrated Circuits
  • Robust and Nonlinear Systems and Control
  • Digital Filters and Spectrum Estimation
  • Image Processing and Image Coding
  • Computer Vision and Robotics
  • Materials and Processes for Microsystems
  • Building an Internet Router
  • Network Architecture
  • Sensors for Network Services and Design
  • Optical Transmission and Networks
  • Nanotechnology and Healthcare
  • RF Circuits and Sub-systems
  • Physics and Optics of Nano-Structure
  • Broadband Communications Lab
  • Analogue CMOS IC Design Applications
  • Embedded systems for the Internet of Things
  • Flexible Electronics

Dissertation/report

All students undertake two research projects. An independent research project (45 credits) and an industry-focused project (45 credits).

Teaching and learning

The programme is delivered through a combination of lectures, tutorials, projects, seminars, and laboratory work. Student performance is assessed through unseen written examination and coursework (written assignments and design work).

Further information on modules and degree structure is available on the department website: Integrated Photonic and Electronic Systems MRes

Careers

Dramatic progress has been made in the past few years in the field of photonic technologies. These advances have set the scene for a major change in commercialisation activity where photonics and electronics will converge in a wide range of information, sensing, display, and personal healthcare systems. Importantly, photonics will become a fundamental underpinning technology for a much greater range of companies outside the conventional photonics arena, who will in turn require those skilled in photonic systems to have a much greater degree of interdisciplinary training, and indeed be expert in certain fields outside photonics.

Employability

Our students are highly employable and have the opportunity to gain industry experience during their MRes year in large aerospace companies like Qioptiq, medical equipment companies such as Hitachi; and technology and communications companies such as Toshiba through industry placements. Several smaller spin-out companies from both UCL and Cambridge also offer projects. The CDT organises industry day events which provide an excellent opportunity to network with senior technologists and managers interested in recruiting photonics engineers. One recent graduate is now working as a fiber laser development engineer; another is a patent attorney.

Why study this degree at UCL?

The University of Cambridge and UCL have recently established an exciting Centre for Doctoral Training (CDT) in Integrated Photonic and Electronic Systems, leveraging their current strong collaborations in research and innovation.

The CDT provides doctoral training using expertise drawn from a range of disciplines, and collaborates closely with a wide range of UK industries, using innovative teaching and learning techniques.

The centre aims to create graduates with the skills and confidence able to drive future technology research, development and exploitation, as photonics becomes fully embedded in electronics-based systems applications ranging from communications to sensing, industrial manufacture and biomedicine.

Research Excellence Framework (REF)

The Research Excellence Framework, or REF, is the system for assessing the quality of research in UK higher education institutions. The 2014 REF was carried out by the UK's higher education funding bodies, and the results used to allocate research funding from 2015/16.

The following REF score was awarded to the department: Electronic & Electrical Engineering

97% rated 4* (‘world-leading’) or 3* (‘internationally excellent’)

Learn more about the scope of UCL's research, and browse case studies, on our Research Impact website.



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

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

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

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

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

Programme modules

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

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

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

How you will learn

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

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

Facilities

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

Careers and further study

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

Scholarships and bursaries

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

Why choose electronic, electrical and systems engineering at Loughborough?

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

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

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

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

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

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

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

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