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Masters Degrees (Signals And Systems)

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Learn how to create artificial information systems that mimic biological systems as well as how to use theoretical insights from AI to better understand cognitive processing in humans. Read more

Learn how to create artificial information systems that mimic biological systems as well as how to use theoretical insights from AI to better understand cognitive processing in humans.

The human brain is a hugely complex machine that is able to perform tasks that are vastly beyond current capabilities of artificial systems. Understanding the brain has always been a source of inspiration for developing artificially intelligent agents and has led to some of the defining moments in the history of AI. At the same time, theoretical insights from artificial intelligence provide new ways to understand and probe neural information processing in biological systems.

On the one hand, the Master’s in Computation in Neural and Artificial Systems addresses how models based on neural information processing can be used to develop artificial systems, probing of human information processing in closed-loop online settings, as well as the development of new machine learning techniques to better understand human brain function.

On the other hand it addresses various ways of modelling and understanding cognitive processing in humans. These range from abstract mathematical models of learning that are derived from Bayesian statistics, complexity theory and optimal control theory to neural information processing systems such as neural networks that simulate particular cognitive functions in a biologically inspired manner. We also look at new groundbreaking areas in the field of AI, like brain computer interfacing and deep learning.

See the website http://www.ru.nl/masters/ai/computation

Why study Computation in Neural and Artificial Systems at Radboud University?

- Our cognitive focus leads to a highly interdisciplinary AI programme where students gain skills and knowledge from a number of different areas such as mathematics, computer science, psychology and neuroscience combined with a core foundation of artificial intelligence.

- Together with the world-renowned Donders Institute, the Behavioural Science Institute and various other leading research centres in Nijmegen, we train our students to become excellent researchers in AI.

- Master’s students are free to use the state-of-the-art facilities available on campus, like equipment for brain imaging as EEG, fMRI and MEG.

- Exceptional students who choose this specialisation have the opportunity to study for a double degree in Artificial Intelligence together with the specialisation in Brain Network and Neuronal Communication. This will take three instead of two years.

- This specialisation offers plenty of room to create a programme that meets your own academic and professional interests.

- To help you decide on a research topic there is a semi-annual Thesis Fair where academics and companies present possible project ideas. Often there are more project proposals than students to accept them, giving you ample choice. We are also open to any of you own ideas for research.

- Our AI students are a close-knit group; they have their own room in which they often get together to interact, debate and develop their ideas. Every student also receives personal guidance and supervision from a member of our expert staff.

Our research in this field

The programme is closely related to the research carried out in the internationally renowned Donders Institute for Brain, Cognition and Behaviour. This institute has several unique facilities for brain imaging using EEG, fMRI and MEG. You will be able to use these facilities for developing new experimental research techniques, as well as for developing new machine learning algorithms to analyse the brain data and integrate them with brain-computer interfacing systems.

Some examples of possible thesis subjects:

- Deep learning

Recent breakthroughs in AI have led to the development of artificial neural networks that achieve human level performance in object recognition. This has led companies like Google and Facebook to invest a lot of research in this technology. Within the AI department you can do research on this topic. This can range from developing deep neural networks to map and decode thoughts from human brain activity to the development of speech recognition systems or neural networks that can play arcade games.

- Brain Computer Interfacing

Brain computer interfaces are systems which decode a users mental state online in real-time for the purpose of communication or control. An effective BCI requires both neuro-scientific insight (which mental states should we decode?) and technical expertise (which measurement systems and decoding algorithms should be used?). A project could be to develop new mental tasks that induce stronger/easier to decode signals, such as using broadband stimuli. Another project could be to develop new decoding methods better able to tease a weak signal from the background noise, such as adaptive-beam forming. Results for both would assessed by performing empirical studies with target users in one of the EEG/MEG/fMRI labs available in the institute.

Career prospects

Our Artificial Intelligence graduates have excellent job prospects and are often offered a job before they have actually graduated. Many of our graduates go on to do a PhD either at a major research institute or university with an AI department. Other graduates work for companies interested in cognitive design and research. Examples of companies looking for AI experts with this specialisation: Google, Facebook, IBM, Philips and the Brain Foundation. Some students have even gone on to start their own companies.

Job positions

Examples of jobs that a graduate of the specialisation in Computation in Neural and Artificial Systems could get:

- PhD researcher on bio-inspired computing

- PhD researcher on neural decoding

- PhD researcher on neural information processing

- Machine learning expert in a software company

- Company founder for brain-based computer games

- Hospital-based designer of assistive technology for patients

- Policy advisor on new developments in neurotechnology

- Software developer for analysis and online visual displays of brain activity

Internship

Half of your second year consists of an internship, giving you plenty of hands-on experience. We encourage students to do this internship abroad, although this is not mandatory. We do have connections with companies abroad, for example in China, Sweden and the United States.

See the website http://www.ru.nl/masters/ai/computation

Radboud University Master's Open Day 10 March 2018



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The future of information and communication technology (ICT) is driven by mobile and networked embedded systems. Read more

About Mobile and Embedded Systems

The future of information and communication technology (ICT) is driven by mobile and networked embedded systems: tomorrow’s digital cities, Industry 4.0, cyber-physical systems (CPS) and the Internet of Things (IoT) will all depend on embedded sensing of real-world phenomena, in-situ computation as well as automated information exchange and data distribution using machine-to-machine (M2M) com­munications between local and distributed control systems and machinery.

The ‘smart grid’ is one example of an application for future embedded systems, as it uses real-time sensing of the available renewable energy to determine where energy is to be routed across the power grid and controls intelligent machinery to increase production during peak times; this requires that internet-connected smart meters are installed in industrial plants and private homes alike to facilitate real-time sensing and control of technical systems.

Another exciting area of application for embedded systems is mobile and wearable technology, which allows users to access and manipulate information ‘on the go’ as the system provides relevant and timely information — indeed, this is one of the main purposes of mobile information technology such as smartphones and tablet computers. Additional meaning for this Human-Computer Interaction (HCI) is generated by the context of the device, the user, the location and many more factors, all of which are sensed and computed by a plenitude of embedded sensors and collocated or connected systems.

Wearable devices such as fitness trackers and smart watches collect bio-physiological and health-related data to facilitate novel applications, including smart contact lenses and feedback systems for the learning of physical activities. At the same time, increasing cross-device interoperability means that users of head-mounted augmented reality and virtual reality displays can, for instance, use their entire smartphone screen as a keyboard and have the typed text displayed on augmented reality glasses.

Programme content

The programme is divided into three module groups with core and elective modules. These are:

1. Human-Computer Interaction
2. Systems Engineering
3. Data Processing, Signals and Systems

Features

- Excellent rankings for computer science, e.g. in U-Multirank and the CHE rankings
- A strongly research-oriented two-year programme with a modern, broad range of subjects
- Allows flexible interest-based selection of modules from the groups ‘Human-Computer Interaction’, ‘Systems Engineering’ and ‘Data Processing, Signals and Systems’
- A fully English-taught programme
- An outstanding staff-student ratio
- Participation in cutting-edge research projects
- Excellent research and teaching infrastructure
- An extensive network of partnerships with academic institutions and businesses worldwide
- A great student experience in Passau, the ‘City of Three Rivers’

Language requirements

Unless English is your native language or the language of your secondary or undergraduate education, you should provide an English language certificate at level B2 CEFR, e.g. TOEFL with a minimum score of 567 PBT, 87 iBT or ITP 543 (silver); IELTS starting from 5.5; or an equivalent language certificate.

To facilitate daily life in Germany, it would be beneficial for you to have German language skills at level A1 CEFR (beginner’s level). If you do not have any German skills when starting out on the programme, you will complete a compulsory beginner’s German course during your first year of study.

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The international master on “Control for Green Mechatronics” (GREEM), within the “Robotics and Control” mention of the French Ministry of Education, promotes a high-quality educational offer in the area of design and control of mechatronic systems with a particular focus on two points. Read more

The international master on “Control for Green Mechatronics” (GREEM), within the “Robotics and Control” mention of the French Ministry of Education, promotes a high-quality educational offer in the area of design and control of mechatronic systems with a particular focus on two points: their functional performances and their energetic efficiency. The consideration of the energy efficiency makes the GREEM international master very singular and very innovative and makes it answer a real actual societal matter which is the effect of technological devices to the ecology. After graduation, the students will have mastered the area of green mechatronics where they will be able to design new or re-design existing mechatronic systems, to model and simulate them, to calculate controllers for their automation and their performances improvement, and to setup networks of mechatronic systems, all together with consideration of the energy efficiency. Furthermore, international experience possibility is offered to the students: exchanges with partner universities at the international level are possible with eventual dual-degree, internships at the international level are encouraged, a great part of the courses are given in English, and French language and culture courses are given for non-francophone students. 

Program structure

The master program lasts two years and includes a total of 120 ECTS. The two years are split into four semesters (S7, S8, S9 and S10) which include several features such as: two industrial certifications (Schneider and Siemens), in excess of 50% of the courses given in English, French course offered to non-francophone students, 3-days labs in another city (in Poligny which is a small and original city of the Jura department where winery is also well known), seminars by researchers, research labs visiting, students project in robotics for national competition, possibility of international exchange ...

The global content is given below.

Master-1:

S7 semester (30 ECTS):

  • Digital signals, systems and control
  • Micromechatronics
  • Technologies in control
  • Systems engineering
  • Modeling of mechatronic systems
  • Siemens certification

S8 semester (30 ECTS):

  • Robotics
  • Industrial computing
  • Linear multivariable control
  • Methodologies tools
  • Optimization
  • French or foreigner languages
  • Energy microtransduction
  • Schneider certification

Master-2:

S9 semester (30 ECTS):

  • Numerical computation and simulation
  • Multiphysic microsystems and applications (biomed and accoustic)
  • Nonlinear and robust control
  • Energy based modeling and control
  • 3D design and manufacturing of mechatronic systems
  • Mechatronic systems network energy management

S10 semester (30 ECTS):

  • Microrobotics
  • Energy harvesting in mechatronic systems
  • INTERNSHIP (21 ECTS)

The master is also supported by the internationally renown research center FEMTO-ST (http://femto-st.fr/).

International partners and dual-degrees

Exchanges with international universities (Canada, Mexico, Peru, Qatar...) are possible during the curriculum. Dual-degree of Master is possible with some of the partner universities. 

After the GREEM master program

The career prospects of the students are very high because mechatronic systems are found and increasingly developed in a very wide range of applications. The fact that today’s problematic, like energy consumption in technological devices, is particularly tackled in this master will make the graduated students very attractive to industry at the international level. Furthermore, high skills and specialized students will have been educated making them the best candidates for research and PhD programs in the fields of mechatronics at large, of control, of robotics...

Site of training

The site of training is Besançon, a French old city that combines old stones buildings, French culture, various activities from sports to cultural, and students life. Approximately 10% of the population are students or interns in Besançon city and in its agglomeration. The center of applied languages (CLA, http://cla.univ-fcomte.fr/) which is a part of the university (UFC/UBFC) is one of the most important center for learning languages in France and hosts approximately 4000 interns per year coming from various countries for some days or for several months. Public transportation is very practical and the old-city is doable by walks.

Entry requirements (Students profiles)

The applicant should have a level of English and a background on “control systems” following the UFC/UBFC criterias. Additionally to these, the motivations and the professional project of the applicant are also examined carefully.

Several applications are possible.

- Entering directly in Master-1 at the UBFC: application is made through eCandidat (https://scolarite.univ-fcomte.fr/ecandidat/).

- Entering in Master-2: this is possible for those who have at least the level of Master-1 and who have very good tracks in the required background.

- Entering through a partner university: students from one of the partner universities who would like to enroll the GREEM master within a dual-degree track can be informed by the contact person at these universities.

For particular cases or for more information about the application, feel free to contact us, (Micky Rakotondrabe). 

Scholarships

Every year, a very limited number of UBFC scholarships could be offered on the basis of tracks and academic records. Application to such scholarships must be done no latter than the beginning of Master-1.



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Our graduates work in major telecommunications companies around the world. We have run this course for over 25 years and, in that time, educated over a thousand communications specialists. Read more
Our graduates work in major telecommunications companies around the world. We have run this course for over 25 years and, in that time, educated over a thousand communications specialists.

Starting from the concept of a signal, we cover the fundamentals of how signals are acquired, processed and transmitted over a wide range of media — electronic, optical and radio. Our laboratory work shows how these principles are put into practice and your software development skills are improved through a series of lectures, exercises and assignments.

Building on this, we explore a number of state-of-the-art topics in detail, including:

- Modern digital transmission systems
- Wireless communication systems
- Computer security and cryptography
- Complex electronic circuits
- Networked systems

Our School is a community of scholars leading the way in technological research and development. Today’s telecommunications engineers are creative people who are focused and committed, yet restless and experimental. We are home to many of the world’s top engineers, and our work is driven by creativity and imagination as well as technical excellence.

We are ranked Top 10 in the UK in the 2015 Academic Ranking of World Universities, with more than two-thirds of our research rated ‘world-leading’ or ‘internationally excellent (REF 2014).

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Our MA in Music Production gives you time, facilities and authoritative guidance from academics and industry professionals to develop both practical studio craft along with a firm theoretical and critical understanding of modern technique and practice. Read more
Our MA in Music Production gives you time, facilities and authoritative guidance from academics and industry professionals to develop both practical studio craft along with a firm theoretical and critical understanding of modern technique and practice.

Course summary

This new programme (which replaces the Production pathway of the Music MA) provides practical, theoretical and analytical study of the creation, perception and reception of audio productions. An interdisciplinary approach is adopted which examines how creative studio practice is informed by perspectives provided by science and engineering (acoustics, psychoacoustics, electroacoustics, signal processing) as well as composition, performance and musicology. Professional competences in various aspects of sound recording practice are developed and assessed, along with the underlying transferable knowledge. This is in addition to a cultural and historical perspective which encourages the understanding of production, with its own notions of style and genre, as an evolving and integral part of music making.

Aims

The MA in Music Production degree is aimed at students wishing to explore the practice and theory of Music Production. This combines a very broad view of the techniques and applications of production for audio media with the subsequent development of more tightly focussed individual skills and scholarship. Music Production might involve anything ranging from the creation of entirely synthetic material using computer-based techniques to the successful capture of acoustic performances, as well as the restoration and reconstruction of existing audio heritage. There are also important philosophies and technologies underlying this discipline that are constantly evolving.

Whether you are an electronic/computer-based composer or an early music specialist who wants to make the very best recordings, this course will provide you with the intellectual and practical skills to realise your goals. This is not a training course in specific pieces of software or hardware. It is a year-long exposure to thinking about and working in Music Production in its many forms. It is an opportunity to develop your own ideas, styles and career in this exciting discipline.

Structure and Ethos

The use of technology for the creation and capture of music is a core part of the Department of Music’s activities. The Department is home to the Music Research Centre: one of the finest facilities for listening to and recording sound in the UK. There is a large-scale neutral listening and performing space built to extremely low noise specifications (PNC15), a linked studio suite containing a dedicated performance space with configurable acoustics and two mix down/control rooms. The department’s main concert hall has a dedicated studio control room along with a suite of editing and programming rooms. This remarkable set of facilities is populated with a wide range of microphones and recording hardware/software. There are extensive computing facilities for practical work and research. Surround sound work is very well supported by multiple sets of 5.1 and full periphonic (i.e. with height) ambisonic reproduction systems.

Throughout the course MA Music Production students are expected to use these facilities to make recordings and other audio artefacts. Running alongside this practical activity are taught modules which provide an understanding and fluency in audio signals and systems and the production chain, listening and analytical skills. In the final six months students produce a self-directed portfolio as well as undertaking a large research project.

Industry and Employment Relevance

The role of producer is widely recognised within the music industry, across all styles and in many different areas of activity. This course will provide you with a versatile skill-set which will be of value for entrepreneurs or for candidates seeking professional appointments, be it with a small independent production house or a broadcaster with global reach. The department is home to professional sound recordists, producers, performers, composers and technology developers and so offers a unique combination of expertise in this field. Rather than a narrow set of competencies which will quickly date, you will graduate with a set of robust skills which will transfer to many different scenarios along with a breadth and depth of understanding of Music Production which will allow you to create meaningful and significant audio content, as well as critically analyse the work of other producers. A significant proportion of our graduates go on to do further research at PhD level.

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Our MSc Electronic Engineering enables you to acquire the essential knowledge, skills, competency, and critical awareness necessary for a rewarding career in the electronics industry. Read more
Our MSc Electronic Engineering enables you to acquire the essential knowledge, skills, competency, and critical awareness necessary for a rewarding career in the electronics industry. We prepare you for a career in analogue and digital circuit design, an area with a major skills shortage worldwide and particularly in the UK.

The content of our course is far-reaching and includes theory, practice, simulation and realisation underpinned by our 40 years of expertise in electronics and telecommunications.

Our course brings together our teaching, research and industrial contacts to form a vocational offering with enhanced postgraduate employability. You will be equipped with skills in the areas of:
-Analogue and digital design
-CAD and IC design
-Time and frequency domain analysis
-Fault analysis
-Embedded processing
-DSPs and fast prototyping

All of your acquired knowledge culminates in a project which sees the design, simulation, construction, testing and manufacture of a complex electronic system aimed at the industrial or consumer markets.

Our School is a community of scholars leading the way in technological research and development. Today’s electronic engineers are creative people who are focused and committed, yet restless and experimental. We are home to many of the world’s top engineers, and our work is driven by creativity and imagination as well as technical excellence.

We are ranked Top 10 in the UK in the 2015 Academic Ranking of World Universities, with more than two-thirds of our research rated ‘world-leading’ or ‘internationally excellent (REF 2014).

Professional accreditation

This degree is accredited by the Institution of Engineering and Technology (IET).This accreditation is increasingly sought by employers, and provides the first stage towards eventual professional registration as a Chartered Engineer (CEng).

Our expert staff

We have been one of the leading electronics departments in the country throughout our history, and in recent years, our prolific research staff have contributed to some major breakthroughs.

We invented the world's first telephone-based system for deaf people to communicate with each other in 1981, with cameras and display devices that were able to work within the limited telephone bandwidth. Our academics have also invented a streamlined protocol system for worldwide high speed optical communications.

Specialist facilities

We are one of the largest and best resourced computer science and electronic engineering schools in the UK. Our work is supported by extensive networked computer facilities and software aids, together with a wide range of test and instrumentation equipment.
-We have six laboratories that are exclusively for computer science and electronic engineering students. Three are open 24/7, and you have free access to the labs except when there is a scheduled practical class in progress
-All computers run either Windows 7 or are dual boot with Linux
-Software includes Java, Prolog, C++, Perl, Mysql, Matlab, DB2, Microsoft Office, Visual Studio, and Project
-Students have access to CAD tools and simulators for chip design (Xilinx) and computer networks (OPNET)
-We also have specialist facilities for research into areas including non-invasive brain-computer interfaces, intelligent environments, robotics, optoelectronics, video, RF and MW, printed circuit milling, and semiconductors

Your future

There are career opportunities for well-qualified electronics design engineers in the avionics, automotive, entertainment and consumer product markets, and within companies such as Siemens, Fujitsu, Sony, Toshiba, Nokia, Samsung, LG, Apple, Microsoft, Intel, Dell, Sharp, Canon, Acer, Levono, Hitachi, Epson, Philips, Nikon, Pioneer, TCL, and JVC, all of whom are searching for competent designers.

A number of careers are also available through local SMEs, geographically close to Essex, who account for a significant proportion of the workforce, both in the UK and on the continent.

Our recent graduates have gone on to work for a wide range of high-profile companies including:
-Electronic Data Systems
-Pfizer Pharmaceuticals
-Bank of Mexico
-Visa International
-Hyperknowledge (Cambridge)
-Hellenic Air Force
-ICSS (Beijing)
-United Microelectronic Corporation (Taiwan)

We also work with the university’s Employability and Careers Centre to help you find out about further work experience, internships, placements, and voluntary opportunities.

Example structure

-MSc Project and Dissertation
-Electronic System Design & Integration
-Professional Practice and Research Methodology
-Programming Embedded Systems
-Programming in Python
-Theory of Signals and Systems
-Advanced Embedded Systems Design (optional)
-Creating and Growing a New Business Venture (optional)
-Digital Signal Processing (optional)
-High Level Logic Design (optional)
-Intelligent Systems and Robotics (optional)
-IP Networking and Applications (optional)
-Mathematical Research Techniques Using Matlab (optional)
-Mobile Communications (optional)
-Networking Principles (optional)

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Our graduates work in major telecommunications companies around the world. We have run this course for over 25 years and, in that time, educated over a thousand communications specialists. Read more
Our graduates work in major telecommunications companies around the world. We have run this course for over 25 years and, in that time, educated over a thousand communications specialists.

Starting from the concept of a signal, we cover the fundamentals of how signals are acquired, processed and transmitted over a wide range of media — electronic, optical and radio. Our laboratory work shows how these principles are put into practice and your software development skills are improved through a series of lectures, exercises and assignments.

Building on this, we explore a number of state-of-the-art topics in detail, including:
-Modern digital transmission systems
-Wireless communication systems
-Computer security and cryptography
-Complex electronic circuits
-Networked systems

Our School is a community of scholars leading the way in technological research and development. Today’s telecommunications engineers are creative people who are focused and committed, yet restless and experimental. We are home to many of the world’s top engineers, and our work is driven by creativity and imagination as well as technical excellence.

We are ranked Top 10 in the UK in the 2015 Academic Ranking of World Universities, with more than two-thirds of our research rated ‘world-leading’ or ‘internationally excellent (REF 2014).

This course is also available on a part-time basis.

This degree is accredited by the Institution of Engineering and Technology (IET).This accreditation is increasingly sought by employers, and provides the first stage towards eventual professional registration as a Chartered Engineer (CEng).

Our expert staff

We have been one of the leading electronics departments in the country throughout our history, and in recent years, our prolific research staff have contributed to some major breakthroughs.

We invented the world's first telephone-based system for deaf people to communicate with each other in 1981, with cameras and display devices that were able to work within the limited telephone bandwidth. Our academics have also invented a streamlined protocol system for worldwide high speed optical communications.

Specialist facilities

We are one of the largest and best resourced computer science and electronic engineering schools in the UK. Our work is supported by extensive networked computer facilities and software aids, together with a wide range of test and instrumentation equipment.
-We have six laboratories that are exclusively for computer science and electronic engineering students. Three are open 24/7, and you have free access to the labs except when there is a scheduled practical class in progress
-All computers run either Windows 7 or are dual boot with Linux
-Software includes Java, Prolog, C++, Perl, Mysql, Matlab, DB2, Microsoft Office, Visual Studio, and Project
-Students have access to CAD tools and simulators for chip design (Xilinx) and computer networks (OPNET)
-We also have specialist facilities for research into areas including non-invasive brain-computer interfaces, intelligent environments, robotics, optoelectronics, video, RF and MW, printed circuit milling, and semiconductors

Your future

Our recent graduates have progressed to a variety of senior positions in industry and academia. Some of the companies and organisations where our former graduates are now employed include:
-Elitecore Technologies Ltd
-Juniper Networks
-Cisco Systems
-Incendio Technologies

We also work with the university’s Employability and Careers Centre to help you find out about further work experience, internships, placements, and voluntary opportunities.

Example structure

Postgraduate study is the chance to take your education to the next level. The combination of compulsory and optional modules means our courses help you develop extensive knowledge in your chosen discipline, whilst providing plenty of freedom to pursue your own interests. Our research-led teaching is continually evolving to address the latest challenges and breakthroughs in the field, therefore to ensure your course is as relevant and up-to-date as possible your core module structure may be subject to change.

MSc Advanced Communications Systems
-Theory of Signals and Systems
-Digital Communications
-Networking Principles
-Mobile Communications
-Communications Laboratory
-Mathematical Research Techniques Using Matlab
-MSc Project and Dissertation
-Professional Practice and Research Methodology
-Converged Networks and Services (optional)
-Creating and Growing a New Business Venture (optional)
-Data Science and Decision Making (optional)
-Electronic System Design & Integration
-Network Security and Cryptographic Principles
-Computer Security

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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Electronic and Electrical Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Electronic and Electrical Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

As a student on the Master's course in Electronic and Electrical Engineering, you will develop specialist skills aligned with the College of Engineering’s research interests and reflecting the needs of the electronics industry.

Key Features of MSc in Electronic and Electrical Engineering

The MSc Electronic and Electrical Engineering course covers the ability to apply the knowledge gained in the course creatively and effectively for the benefit of the profession, to plan and execute a programme of work efficiently, and to be able, on your own initiative, to enhance your skills and knowledge as required throughout your career in Electronic and Electrical Engineering.

Students on the Electronic and Electrical Engineering course benefit from the use of industry-standard equipment, such as a scanning tunnelling microscope for atomic scale probing or an hp4124 parameter analyzer for power devices, for simulation, implementation and communication.

During the Electronic and Electrical Engineering course there will be the opportunity to choose and apply suitable prototyping and production methods and components, gain knowledge in constructing and evaluating advanced models of various manufacturing techniques, and be able to differentiate, analyse and discuss various product lifetime management solutions and how they affect different sectors of Electronic and Electrical Engineering industry.

The MSc in Electronic and Electrical Engineering programme is modular in structure. Students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits in the taught element (Part One) and a project (Part Two) that is worth 60 credits and culminates in a written dissertation in Electronic and Electrical Engineering. Students on the Electronic and Electrical Engineering course must successfully complete Part One before being allowed to progress to Part Two.

Part-time Delivery mode of MSc in Electronic and Electrical Engineering

The part-time scheme of the MSc in Electronic and Electrical Engineering is a version of the full-time equivalent MSc in Electronic and Electrical Engineering scheme, and as such it means lectures are spread right across each week and you may have lectures across every day. Due to this timetabling format, the College advises that the scheme is likely to suit individuals who are looking to combine this with other commitments (typically family/caring) and who are looking for a less than full-time study option in Electronic and Electrical Engineering.

Those candidates seeking to combine the part-time option with full-time work are unlikely to find the timetable suitable, unless their job is extremely flexible and local to the Bay Campus.

Modules on Electronic and Electrical Engineering

Modules on the MSc Electronic and Electrical Engineering course can vary each year but you could expect to study:

Communication Skills for Research Engineers

Energy and Power Electronics Laboratory

Power Semiconductor Devices

Advanced Power Electronics and Drives

Wide Band-Gap Electronics

Power Generation Systems

Modern Control Systems

Advanced Power Systems

Signals and Systems

Digital Communications

Optical Communications

Probing at the Nanoscale

RF and Microwaves

Wireless Communications

Facilities for Electronic and Electrical Engineering

The new home of the Electronic and Electrical Engineering programme is at the innovative Bay Campus which provides some of the best university facilities in the UK, in an outstanding location.

Engineering at Swansea University has extensive IT facilities and provides extensive software licenses and packages to support teaching. In addition the University provides open access IT resources.

Find out more about the facilities used by Electronic and Electrical students at Swansea University, including the electronics lab on our website.

Links with Industry

At Swansea University, Electronic and Electrical Engineering has an active interface with industry and many of our activities are sponsored by companies such as Agilent, Auto Glass, BT and Siemens.

Electronic and Electrical Engineering has a good track record of working with industry both at research level and in linking industry-related work to our postgraduate courses. We also have an industrial advisory board that ensures our taught courses including the MSc in Electronic and Electrical Engineering maintain relevance.

Our research groups work with many major UK, Japanese, European and American multinational companies and numerous small and medium sized enterprises (SMEs) to pioneer research. This activity filters down and influences the project work that is undertaken by all our postgraduate students including those on the MSc in Electronic and Electrical Engineering.

Careers

Electronic and Electrical Engineering graduates find employment in industry, research centres, government or as entrepreneurs in a wide range of careers, from a design and development role for electronic and electrical equipment or as a technological specialist contributing to a multi-disciplinary team in a range of fields, including medicine, travel, business and education.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

With recent academic appointments strengthening electronics research at the College, the Electronic Systems Design Centre (ESDC) has been re-launched to support these activities.

The Centre aims to represent all major electronics research within the College and to promote the Electrical and Electronics Engineering degree.

Best known for its research in ground-breaking Power IC technology, the key technology for more energy efficient electronics, the Centre is also a world leader in semiconductor device modelling, FEM and compact modelling.



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Automation, control and robotics are pervasive enabling technologies found in almost every modern technical system, particularly in manufacturing and production. Read more

Automation, control and robotics are pervasive enabling technologies found in almost every modern technical system, particularly in manufacturing and production. They combine the diverse and rapidly expanding disciplines of automation, control, mechanics, software and signal processing.

This course is ideal if you wish to develop comprehensive knowledge and understanding of • classical and modern control theory • industrial automation • systems analysis • design and simulation • robotics.

You gain the ability to apply principles of modelling, classical and modern control concepts and controller design packages in various areas of industry. You also learn how to design and exploit automation and robotic systems in a range of manufacturing and industrial applications.

The course has six core modules which cover the major aspects of industrial automation and control systems engineering and robotics, ranging from classical linear control system design to non-linear, optimal and intelligent control systems, including distributed control systems, robotics, computer networks and artificial intelligence.

You also choose two optional modules relevant to automation and control to suit your interests. For example, if you wish to work in the manufacturing industry you can choose manufacturing systems or machine vision. There is the opportunity to study one or two management modules if you wish to apply yourself to a more managerial role.

To gain the masters you complete a major research-based project, which can be focused on an area of your particular interest or career need.

You work alongside staff from the Electrical, Electronic and Control Engineering Group and the Centre for Automation and Robotics Research (CARR) at Sheffield Hallam. This provides the opportunity to work with active researchers.

Professional recognition

This course is seeking accreditation by the Institution of Engineering and Technology (IET) on behalf of the Engineering Council for the purposes of fully meeting the academic requirements for registration as a Chartered Engineer. The MSc will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer; graduates who have a BEng (Hons) accredited for CEng will be able to show that they have satisfied the further learning requirement for CEng accreditation.

Course structure

Core modules

  • industrial automation
  • control of linear systems
  • advanced control methods
  • robotics
  • applicable artificial intelligence

Options

Choose two from

  • software engineering
  • computer networks
  • project and quality management
  • sustainability, energy and environmental management
  • machine vision
  • digital signals processing
  • manufacturing systems
  • mixed signal design
  • electrical energy systems
  • efficient machines and electromagnetic applications.

MSc

  • project and dissertation

Assessment

  • coursework
  • examination
  • presentation
  • MSc project report

Employability

This course provides you with the knowledge and skills for further advanced study in this area.

You can also apply your skills in an industrial setting for automated manufacturing, control system design, or in the wide range of industries that exploit intelligent robotics. Graduates from this course find career opportunities in areas including • automation and control • process and petrochemical • biomedical • manufacturing • energy • automotive • aerospace.

You can also pursue careers in engineering design and development, engineering research, engineering consultancy and engineering management.

Completing this course combined with further work-based experience enables you to gain Chartered Engineer status.



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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Communications Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Communications Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

As a student on the MSc in Communications Engineering, you will be provided with an in-depth understanding of the technology and architecture of computer communications, photonics and telecommunication networks, wireless telecommunications and related wireless information technologies.

Key Features of MSc in Communications Engineering

The practical knowledge and skills you will gain as a student on the MSc Communications Engineering course include being presented with the essential element of modern optical communication systems based on single mode optical fibres from the core to the access, evaluating bandwidth-rich contemporary approaches.

The MSc Communications Engineering course also covers advanced networking topics including network performance and network security. This is supported with some practical knowledge and skills for project and business management principles.

As a student on the MSc Communications Engineering course, you will also be introduced to technologies underlying the compressions and transmission of digital video over networking platforms, gain knowledge on the channel models and associated impairments that typically limit the performance of wireless systems, and learn to design optimum digital communication receivers for some basic communications channel models.

The MSc in Communications Engineering is modular in structure. Communications Engineering students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits in the taught element (Part One) and a project (Part Two) that is worth 60 credits and culminates in a written dissertation. Students on the Communications Engineering course must successfully complete Part One before being allowed to progress to Part Two.

Part-time MSc in Communications Engineering Delivery mode:

The part-time scheme is a version of the full-time equivalent MSc in Communications Engineering scheme, and as such it means lectures are spread right across each week and you may have lectures across every day. Due to this timetabling format, the College advises that the scheme is likely to suit individuals who are looking to combine this with other commitments (typically family/caring) and who are looking for a less than full-time study option.

Those candidates seeking to combine the part-time option with full-time work are unlikely to find the timetable suitable, unless their job is extremely flexible and local to the Bay Campus.

Timetables for the Communications Engineering programme are typically available one week prior to each semester.

Modules

Modules on the MSc Communications Engineering course can vary each year but you could expect to study:

RF and Microwave

Signals and Systems

Entrepreneurship for Engineers

Nanophotonics

Micro and Nano Electro-Mechnical Systems

Lasers and applications

Wireless Communications

Digital Communications

Optical Communications

Optical Networks

Communication Skills for Research Engineers

Research Dissertation

MSc Dissertation - Communications Engineering

Facilities

Our new home at the innovative Bay Campus provides some of the best university facilities in the UK, in an outstanding location.

Engineering at Swansea University has extensive IT facilities and provides extensive software licenses and packages to support teaching which benefit students on the MSc in Communications Engineering course. In addition the University provides open access IT resources.

Links with Industry

At Swansea University, Electronic and Electrical Engineering has an active interface with industry and many of our activities are sponsored by companies such as Agilent, Auto Glass, BT and Siemens.

This discipline has a good track record of working with industry both at research level and in linking industry-related work to our postgraduate courses. We also have an industrial advisory board that ensures our taught courses maintain relevance.

Our research groups work with many major UK, Japanese, European and American multinational companies and numerous small and medium sized enterprises (SMEs) to pioneer research. This activity filters down and influences the project work that is undertaken by all our postgraduate students.

Careers

The MSc Communications Engineering is suitable for those who have a career interest in the field of communication systems, which has been fundamentally changing the whole world in virtually every aspect, and would like to gain lasting career skills and in-depth knowledge to carry out development projects and advanced research in the area of communication systems.

Communications Engineering graduates can seek employment in wireless communication systems and network administration, and mobile applications development.

Student Quotes

“I was fascinated by the natural beauty of Swansea before I came here. Swansea University is near the beach so you can walk around the beach at any time. This Master’s is very useful to enhance your ability and enrich your principle of the academic knowledge.”

Zhang Daping, MSc Communication Systems (now Communications Engineering)

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

With recent academic appointments strengthening electronics research at the College, the Electronic Systems Design Centre (ESDC) has been re-launched to support these activities.

The Centre aims to represent all major electronics research within the College and to promote the Electrical and Electronics Engineering degree.

Best known for its research in ground-breaking Power IC technology, the key technology for more energy efficient electronics, the Centre is also a world leader in semiconductor device modelling, FEM and compact modelling.



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The Master of Science program in Telecommunications Engineering features an advanced and innovative curriculum with multidisciplinary courses in the areas of Internet services and applications, communication systems, multimedia signal processing, optical and radio technologies, and remote sensing. Read more

Mission and goals

The Master of Science program in Telecommunications Engineering features an advanced and innovative curriculum with multidisciplinary courses in the areas of Internet services and applications, communication systems, multimedia signal processing, optical and radio technologies, and remote sensing.

Students can select four possible tracks (all taught in English):
- Photonics and Radio
- Communication Networks
- Signals
- Internet Engineering (in cooperation with MSc in Computer Science and Engineering)

or define their personalized study program through a large set of available courses.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/telecommunication-engineering/

Professional opportunities

Our graduates are engineers that are expert in the design of communication systems, in organizing and managing communication networks that are part of the big Internet, and in the defining and customizing communication services. Career opportunities are available not only in the traditional sector of Telecommunications (operators and manufacturers) but in many others for which the communication services are crucial (like finance, energy, production, public services, commerce, etc.)

For more information visit the web site: http://commtech.dei.polimi.it/en/

Presentation

See http://www.polinternational.polimi.it/uploads/media/Telecommunication_Engineering_01.pdf
Communication Technologies provide the infrastructures, the services, and the applications to the users of the Information Society around the globe: electronic commerce, real-time multimedia applications, secure banking transactions, remote medical diagnosis, exchange of music and video clips on both fixed and mobile devices, technologies for observing the earth’s surface and interior for land monitoring and oil prospecting. The Master of Science in Telecommunications Engineering aims at producing engineers that are experts in the design of communication systems, in organizing and managing communication networks that are part of the big Internet, and in the defining and customizing communication services. It offers a wide range of specialization opportunities that stimulate the creativity of the students in the areas of networking, signal processing, transmission systems, and radio communications.
The programme is taught in English.

Subjects

Five specializations available:
- Networks
- Communications
- Signals
- Technologies
- Internet Engineering (joint with MS in Computer Systems Eng.)

The mandatory courses include:
- Traffic theory
- Network design
- Digital communications,
- Digital signal processing,
- Operations Research

The optional specializing courses include:
- Wireless Networks,
- Multimedia Internet,
- Internet of Things,
- Audio and video signals
- Wireless systems,
- Antennas and propagation,
- Network security and cryptography
- Radar and localization systems,

For more information please visit: http://commtech.dei.polimi.it

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/telecommunication-engineering/

For contact information see here http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/telecommunication-engineering/

Find out how to apply here http://www.polinternational.polimi.it/how-to-apply/

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The International Master Program in Image Processing and Computer Vision provides specialized training in a field of increasing importance in our daily lives. Read more

The International Master Program in Image Processing and Computer Vision provides specialized training in a field of increasing importance in our daily lives. It is essential in domains such as medicine, surveillance, industrial control, remote sensing, e-commerce and automation. The program covers a wide range of methods in computer vision thus guaranteeing highly-qualified graduates in this field. Three partner universities, with internationally recognized experience in these domains, have pooled their complementary expertise and developed this international postgraduate cooperation initiative.

The result is a high-quality, strongly recognized, triple Master degree that respects the 120 ECTS syllabus, and is well adapted to job market criteria. In order to benefit from the knowledge of these three partner universities and their professors, students spend an entire semester in each university.

Program structure

All students follow the same curriculum with some optional courses. The program is organized as follows:

Semester 1: PPCU, Budapest, Hungary

  • Functional Analysis (5 ECTS) – Compulsory
  • Parallel Computing Architectures (3 ECTS) – Compulsory
  • Numerical Analysis 1 (4 ECTS) – Compulsory
  • Basic Image Processing Algorithms (5 ECTS) – Compulsory
  • Data mining (5 ECTS) - Compulsory
  • Stochastic Signals and Systems (4 ECTS) – Optional
  • FPGA-based Algorithm Design (5 ECTS) – Optional
  • Biomedical Signal Processing (4 ECTS) – Optional
  • Programming Methodology (5 ECTS) – Optional
  • Intelligent Sensors (3 ECTS) – Optional

Semester 2: UAM, Madrid, Spain

  • Applied Bayesian Methods (6 ECTS) – Compulsory
  • Biomedical Image Processing and Applications (6 ECTS) – Compulsory
  • Biometrics (6 ECTS) – Compulsory
  • Video Sequences Analysis for Video Surveillance (6 ECTS) – Compulsory
  • Tutored Research Project 1 (6 ECTS) - Compulsory

Semester 3: UBx, Bordeaux, France

  • Image and Inversion (6 ECTS) – Compulsory
  • Variational Methods and PDEs for Image Processing (6 ECTS) - Compulsory
  • Advanced Image Processing (3 ECTS) - Compulsory
  • Video and Indexing (3 ECTS) – Compulsory
  • Image Acquisition and Reconstruction (3 ECTS) – Compulsory
  • IT Project Management (3 ECTS) – Compulsory
  • Tutored Research Project 2 (6 ECTS) – Compulsory

Semester 4: Internship in academic or industry laboratory

Strengths of this Master program

  • International program taught by experts from three different universities in Europe.
  • Triple Master degree.
  • International mobility period in three countries.

After this Master program?

After graduation, students have access to career opportunities such as engineers or further research as PhD students.

Their educational background makes them attractive candidates for companies in the following areas: E-commerce, Medical imaging, Personal assistance, Automation, Industrial control, Security, Post-production, Remote sensing, Software publishing.



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Our PGCert in Music Production gives you time, facilities and authoritative guidance from academics and industry professionals to develop both practical studio craft along with a firm theoretical and critical understanding of modern technique and practice. Read more
Our PGCert in Music Production gives you time, facilities and authoritative guidance from academics and industry professionals to develop both practical studio craft along with a firm theoretical and critical understanding of modern technique and practice.

Course summary

This new programme (which replaces the Production pathway of the Music MA) provides practical, theoretical and analytical study of the creation, perception and reception of audio productions. An interdisciplinary approach is adopted which examines how creative studio practice is informed by perspectives provided by science and engineering (acoustics, psychoacoustics, electroacoustics, signal processing) as well as composition, performance and musicology. Professional competences in various aspects of sound recording practice are developed and assessed, along with the underlying transferable knowledge. This is in addition to a cultural and historical perspective which encourages the understanding of production, with its own notions of style and genre, as an evolving and integral part of music making.

Aims

The PGCert in Music Production degree is aimed at students wishing to explore the practice and theory of Music Production. This combines a very broad view of the techniques and applications of production for audio media with the subsequent development of more tightly focussed individual skills and scholarship. Music Production might involve anything ranging from the creation of entirely synthetic material using computer-based techniques to the successful capture of acoustic performances, as well as the restoration and reconstruction of existing audio heritage. There are also important philosophies and technologies underlying this discipline that are constantly evolving.

Whether you are an electronic/computer-based composer or an early music specialist who wants to make the very best recordings, this course will provide you with the intellectual and practical skills to realise your goals. This is not a training course in specific pieces of software or hardware. It is a year-long exposure to thinking about and working in Music Production in its many forms. It is an opportunity to develop your own ideas, styles and career in this exciting discipline.

Structure and Ethos

The use of technology for the creation and capture of music is a core part of the Department of Music’s activities. The Department is home to the Music Research Centre: one of the finest facilities for listening to and recording sound in the UK. There is a large-scale neutral listening and performing space built to extremely low noise specifications (PNC15), a linked studio suite containing a dedicated performance space with configurable acoustics and two mix down/control rooms. The department’s main concert hall has a dedicated studio control room along with a suite of editing and programming rooms. This remarkable set of facilities is populated with a wide range of microphones and recording hardware/software. There are extensive computing facilities for practical work and research. Surround sound work is very well supported by multiple sets of 5.1 and full periphonic (i.e. with height) ambisonic reproduction systems.

Throughout the course Music Production students are expected to use these facilities to make recordings and other audio artefacts. Running alongside this practical activity are taught modules which provide an understanding and fluency in audio signals and systems and the production chain, listening and analytical skills. In the final six months students produce a self-directed portfolio as well as undertaking a large research project.

Industry and Employment Relevance

The role of producer is widely recognised within the music industry, across all styles and in many different areas of activity. This course will provide you with a versatile skill-set which will be of value for entrepreneurs or for candidates seeking professional appointments, be it with a small independent production house or a broadcaster with global reach. The department is home to professional sound recordists, producers, performers, composers and technology developers and so offers a unique combination of expertise in this field. Rather than a narrow set of competencies which will quickly date, you will graduate with a set of robust skills which will transfer to many different scenarios along with a breadth and depth of understanding of Music Production which will allow you to create meaningful and significant audio content, as well as critically analyse the work of other producers. A significant proportion of our graduates go on to do further research at PhD level.

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Our Postgraduate Diploma (PGDip) in Music Production gives you time, facilities and authoritative guidance from academics and industry professionals to develop both practical studio craft along with a firm theoretical and critical understanding of modern technique and practice. Read more
Our Postgraduate Diploma (PGDip) in Music Production gives you time, facilities and authoritative guidance from academics and industry professionals to develop both practical studio craft along with a firm theoretical and critical understanding of modern technique and practice.

Course summary

This new programme provides practical, theoretical and analytical study of the creation, perception and reception of audio productions. An interdisciplinary approach is adopted which examines how creative studio practice is informed by perspectives provided by science and engineering (acoustics, psychoacoustics, electroacoustics, signal processing) as well as composition, performance and musicology. Professional competences in various aspects of sound recording practice are developed and assessed, along with the underlying transferable knowledge. This is in addition to a cultural and historical perspective which encourages the understanding of production, with its own notions of style and genre, as an evolving and integral part of music making.

Aims

The PGDip in Music Production degree is aimed at students wishing to explore the practice and theory of Music Production. This combines a very broad view of the techniques and applications of production for audio media with the subsequent development of more tightly focussed individual skills and scholarship. Music Production might involve anything ranging from the creation of entirely synthetic material using computer-based techniques to the successful capture of acoustic performances, as well as the restoration and reconstruction of existing audio heritage. There are also important philosophies and technologies underlying this discipline that are constantly evolving.

Whether you are an electronic/computer-based composer or an early music specialist who wants to make the very best recordings, this course will provide you with the intellectual and practical skills to realise your goals. This is not a training course in specific pieces of software or hardware. It is a year-long exposure to thinking about and working in Music Production in its many forms. It is an opportunity to develop your own ideas, styles and career in this exciting discipline.

Structure and Ethos

The use of technology for the creation and capture of music is a core part of the Department of Music’s activities. The Department is home to the Music Research Centre: one of the finest facilities for listening to and recording sound in the UK. There is a large-scale neutral listening and performing space built to extremely low noise specifications (PNC15), a linked studio suite containing a dedicated performance space with configurable acoustics and two mix down/control rooms. The department’s main concert hall has a dedicated studio control room along with a suite of editing and programming rooms. This remarkable set of facilities is populated with a wide range of microphones and recording hardware/software. There are extensive computing facilities for practical work and research. Surround sound work is very well supported by multiple sets of 5.1 and full periphonic (i.e. with height) ambisonic reproduction systems.

Throughout the course Music Production students are expected to use these facilities to make recordings and other audio artefacts. Running alongside this practical activity are taught modules which provide an understanding and fluency in audio signals and systems and the production chain, listening and analytical skills. In the final six months students produce a self-directed portfolio as well as undertaking a large research project.

Industry and Employment Relevance

The role of producer is widely recognised within the music industry, across all styles and in many different areas of activity. This course will provide you with a versatile skill-set which will be of value for entrepreneurs or for candidates seeking professional appointments, be it with a small independent production house or a broadcaster with global reach. The department is home to professional sound recordists, producers, performers, composers and technology developers and so offers a unique combination of expertise in this field. Rather than a narrow set of competencies which will quickly date, you will graduate with a set of robust skills which will transfer to many different scenarios along with a breadth and depth of understanding of Music Production which will allow you to create meaningful and significant audio content, as well as critically analyse the work of other producers. A significant proportion of our graduates go on to do further research at PhD level.

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This exciting, two year MSc programme is concerned with a wide range of biomedical imaging and sensing science and technology. Biomedical Imaging and Sensing is, in a broad sense, a set of competencies from engineering and sciences to support future quantitative biology and personalised medicine. Read more
This exciting, two year MSc programme is concerned with a wide range of biomedical imaging and sensing science and technology. Biomedical Imaging and Sensing is, in a broad sense, a set of competencies from engineering and sciences to support future quantitative biology and personalised medicine.

It will provide you with theoretical and practical knowledge to develop methods and systems for disease understanding, diagnosis, prognosis and therapeutics where imaging and sensing play a key role.

Core modules

Interdisciplinary Seminars in Biomedical Imaging and Sensing
Mathematics of Imaging Sciences
Scientific Software Development for Biomedical Imaging

Departmental optional modules

Advanced Signal Processing
Computer Vision, Biomedical Signals and Systems
Physiological Signals and Sensing; Physics of Light Microscopy of Cells and Tissues
Physics of Medical Imaging with Ionising Radiation
Physical Principles of Imaging: Radiation-Matter Interaction
Medical Image Computing
Biomaging with Light and Sound
Microscopy Image Analysis
Magnetic Resonance Imaging and Spectroscopy

Interdisciplinary optional modules

The programme allows you to explore some elective modules from interdisciplinary domains that relate to anatomy, physiology, cell biology, physics of the senses, and vision and neurosciences, among others.

Teaching and assessment

Research-led teaching from our department, and various interdisciplinary modules from other departments from the Faculty of Engineering and the Faculty of Medicine, Health and Dentistry.

Individual support for your research project and dissertation.

Assessment is by examination, a project, and coursework in the first year with future examinations and dissertation in your second year.

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