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Masters Degrees (Semiconductors)

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The MSc in Compound Semiconductor Electronics has been designed to provide you with advanced level knowledge and skills in compound semiconductor engineering, fabrication and applications, and to develop related skills, enhancing your engineering competency and employability. Read more
The MSc in Compound Semiconductor Electronics has been designed to provide you with advanced level knowledge and skills in compound semiconductor engineering, fabrication and applications, and to develop related skills, enhancing your engineering competency and employability.

This programme is jointly delivered with the School of Physics and Astronomy and the Institute for Compound Semiconductors (ICS). The ICS is an exciting new development at the cutting edge of compound semiconductor technology. The Institute has been established in partnership with IQE plc, to capitalise on the existing expertise at Cardiff University and to move academic research to a point where it can be introduced reliably and quickly into the production environment. It is unique facility in the UK, and aims to create a global hub for compound semiconductor technology research, development and innovation.

As a student on this programme, you will have the opportunity to undertake a 3-month summer project which will be based either within the Institute for Compound Semiconductors, or in placement with one of our industrial partners. We have strong, long-established industrial links with companies such as National Instruments and Mesuro and are therefore able to offer a portfolio of theoretical, practical, fabrication and applications-centred projects in both academic and industrial placement environments.

Our flexible curriculum contains a robust set of required modules and a number of elective modules which include the latest results, innovations and techniques and are designed to incorporate the most effective teaching and learning techniques.

Upon graduation, you will have the training, skillsets and hands-on experience you need to succeed in the dynamic and highly competitive fields of compound semiconductors and advanced communications systems. Given the University’s unique position at the forefront of compound semiconductor technology, you will have a distinct advantage when applying for PhD studentships or employment in industry.

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The Nanoscale Engineering master is a two-year program corresponding to 120 ECTS credits. Students receive a universal and profound training in physics, materials science and electronics at the nanoscale, but also in nanobiotechnology. Read more
The Nanoscale Engineering master is a two-year program corresponding to 120 ECTS credits. Students receive a universal and profound training in physics, materials science and electronics at the nanoscale, but also in nanobiotechnology.

Elective courses can be followed by the students in their desired area of specialization and/or to broaden their horizons. The entire curriculum is taught in English.

A key educational concept of the program is that each student is immersed in a high-quality research environment for at least half of the time in the curriculum. Throughout the academic year, lab practicals and projects are carried out in research institutions that participate in the program, and thesis projects are undertaken in research laboratories or in nanotechnology companies.

In addition to the scientific and technological aspects, ethical issues and the societal impact of nanotechnology, as well as business considerations, are addressed in specialized seminars and courses.

Structure of the Curriculum

First Year (60 ECTS)

The major part of semester 1 is dedicated to lectures: The students follow 7 courses from the core modules and 2 elective modules. Laboratory practicals and mini-projects ensure a smooth transition into semester 2 with its four-month internship in a research group. This internship is prepared in semester 1 already with a dedicated literature survey. Seminars of speakers from both academia and industry complement the educational program throughout the entire first year.

Second Year (60 ECTS)

Semester 3 is again dedicated to lectures, featuring 5 slots for core modules and 3 for electives, as well as some ancillary courses. The entirety of semester 4 is taken up by the six-month Master thesis project, which can be conducted in a research laboratory or in a company, in France or abroad. As in the first year, seminars of speakers from both academia and industry complement the educational program.

Modules and Courses

Core Modules

These courses impart the fundamental knowledge in the nanotechnology field applied to physics, electronics, optics, materials science and biotechnology. Students are required to follow at least twelve core module courses during the two-year program.

Core modules in the first year There are four obligatory core modules in the first year:

Introduction to Nanoscale Engineering
Micro- and Nanofabrication, part 1
Characterization Tools for Nanostructures
Quantum Engineering

Furthermore, there is a remedial physics course to which students are assigned based on the results of a physics test at the beginning of semester 1:

Basics of Physics

Finally, students have to select a minimum of three courses from the following list for their first year:

Solid State Physics at the Nanoscale
Continuum Mechanics
Physics of Semiconductors, part 1
Physical Chemistry and Molecular Interactions
Biomolecules, Cells, and Biomimetic Systems

Core modules in the second year Students have to choose at least four courses from the following selection for their second year:

Nano-Optics and Biophotonics
Surface-Analysis Techniques
Physics of Semiconductors, part 2
Micro- and Nanofluidics
Micro- and Nanofabrication, part 2
Biosensors and Biochips
Computer Modeling of Nanoscale Systems

Elective Modules

These courses cover a wide range of nanotechnology-related disciplines and thus allow the students to specialize according to their preferences as well as to broaden their expertise. Elective modules in the first year Three courses from the following list have to be chosen for the first year:

Nanomechanics
MEMS and NEMS
Introduction to System Design
Drug-Delivery Systems

Elective modules in the second year Students follow a minimum of three courses from the following selection in the second year:

Multi-Domain System Integration
Solar Cells and Photovoltaics
Nanomagnetism and Spintronics
Nanoelectronics
Tissue and Cell Engineering

Experimental Modules

Students conduct lab practicals that are integrated into the various courses, during which they familiarize themselves hands-on with all standard techniques for fabrication and characterization of nanostructures. They furthermore have the opportunity to work more independently on individual or group projects.

Ancillary Courses and Seminars

This module deals with complementary know-how, relevant both for academia and in an industrial environment. Students follow a course on intellectual-property issues. Ethical aspects and the societal impact of nanotechnology are covered in specialized seminars, which also allow for networking with national and international nanotechnology companies and research laboratories. Communication skills are likewise developed through written and oral presentations of all experimental work that is carried out during the Master program.

Internship

In the second semester, students conduct two-month internships in two of the research laboratories participating in the program. The students choose their projects and come into contact with their host laboratories earlier in the academic year already, by spending some time in these laboratories to carry out an extensive literature survey and to prepare their research projects under the guidance of their supervisors.

Master Thesis Project

The final six-month period of the program is devoted to the master project, which can be carried out either in an academic research laboratory or in an industrial environment. Students have the option to conduct their thesis project anywhere in France or abroad.

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The MSc Compound Semiconductor Physics has been designed to deliver thorough training and practical experience in compound semiconductor theory, fabrication and applications, and integration with silicon technology. Read more
The MSc Compound Semiconductor Physics has been designed to deliver thorough training and practical experience in compound semiconductor theory, fabrication and applications, and integration with silicon technology.

The programme is jointly delivered by the School of Physics and Astronomy and the Institute for Compound Semiconductors (ICS). The ICS is an exciting new development at the cutting edge of compound semiconductor technology. The Institute has been established in partnership with IQE plc, to capitalise on the existing expertise at Cardiff University and to move academic research to a point where it can be introduced reliably and quickly into the production environment. It is unique facility in the UK, and aims to create a global hub for compound semiconductor technology research, development and innovation.

Our flexible curriculum contains a robust set of required modules and a number of cutting-edge elective modules, which include the latest results, innovations and techniques) and are designed to incorporate the most effective teaching and learning techniques.

As part of the programme you will undertake a 3-month summer project which will be based either in the School of Physics and Astronomy, within the ICS, or in placement with one of our industrial partners. We have strong, long-established industrial links with companies such as IQE and are therefore in a unique position to be able to offer a portfolio of theoretical, practical, fabrication and applications-centred projects in both academic and industrial placement environments. No other Russell Group university can boast such opportunities in this field.

Upon graduation, you will have the training, skillsets and hands-on experience you need to succeed in the dynamic and highly competitive field of compound semiconductors.

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Our MSc Computational Finance equips you with the core concepts and mathematical principles of modern quantitative finance, plus the operational skills to use computational packages (mainly Matlab) for financial modelling. Read more
Our MSc Computational Finance equips you with the core concepts and mathematical principles of modern quantitative finance, plus the operational skills to use computational packages (mainly Matlab) for financial modelling.

We provide practical, hands-on learning about how modern, highly computerised financial markets work, how assets should be priced, and how investors should construct a portfolio of assets. In addition to traditional topics in derivatives and asset pricing, we place a special emphasis on risk management in non-Gaussian environment with extreme events.

You master these areas through studying topics including:
-Non-linear and evolutionary computational methods for derivatives pricing and portfolio management
-Applications of calculus and statistical methods
-Computational intelligence in finance and economics
-Financial markets

You also graduate with an understanding of the use of artificial financial market environments for stress testing, and the design of auctions and other financial contracts.

Our Centre for Computational Finance and Economic Agents is an innovative and laboratory-based teaching and research centre, with an international reputation for leading-edge, interdisciplinary work combining economic and financial modelling with computational implementation.

Our research is geared towards real-world, practical applications, and many of our academic staff have experience of applying their findings in industry and in advising the UK government.

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

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

This course is taught by experts with both academic and industrial expertise in the financial and IT sectors. We bring together leading academics in the field from our departments of economics, computer science and business.

Our staff are currently researching the development of real-time trading platforms, new financial econometric models for real-time data, the use of artificially intelligent agents in the study of risk and market-based institutions, operational aspects of financial markets, financial engineering, portfolio and risk management.

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

We have an extensive network of industrial contacts through our City Associates Board and our alumni, while our expert seminar series gives you the opportunity to work with leading figures from industry.

Our recent graduates have gone on to become quantitative analysts, portfolio managers and software engineers at various institutions, including:
-HSBC
-Mitsubishi UFJ Securities
-Old Mutual
-Bank of England

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

-CCFEA MSc Dissertation
-Financial Engineering and Risk Management
-Introduction to Financial Market Analysis
-Learning and Computational Intelligence in Economics and Finance
-Professional Practice and Research Methodology
-Quantitative Methods in Finance and Trading
-Big-Data for Computational Finance (optional)
-Industry Expert Lectures in Finance (optional)
-Mathematical Research Techniques Using Matlab (optional)
-Programming in Python (optional)
-Artificial Neural Networks (optional)
-High Frequency Finance and Empirical Market Microstructure (optional)
-Machine Learning and Data Mining (optional)
-Trading Global Financial Markets (optional)
-Creating and Growing a New Business Venture (optional)
-Evolutionary Computation and Genetic Programming (optional)
-Constraint Satisfaction for Decision Making (optional)

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This course is designed for students from a variety of engineering backgrounds, to enhance and develop electronic engineering knowledge and skills essential for the modern engineer. Read more
This course is designed for students from a variety of engineering backgrounds, to enhance and develop electronic engineering knowledge and skills essential for the modern engineer.

You will gain expertise and experience in the areas of analogue and digital systems and circuit design using state-of-the-art software and processors. You will gain the in-depth knowledge and skills you need for analysing, modelling and optimising the performance of advanced microelectronic and communication systems. The course covers a broad range of topics including advanced embedded system technologies, digital design automation and silicon electronic design, as well as optical fibre communication systems and wireless communications.

This course can also be taken in January - for more information, please view this web-page: https://www.northumbria.ac.uk/study-at-northumbria/courses/microelectronic-and-communication-engineering-msc-ft-dtfmiz6/

Learn From The Best

Our passion for research informs the curriculum and impacts our teaching, ensuring that course content stays current and our academic staff are amongst the best in the country. The team include published authors and industry experts with research interests including analogue electronics, networking, professionalism in practice, teaching and learning in technology and project management.

The department of Physics and Electrical Engineering is a top-35 research department with 79% of our outputs ranked world-leading or internationally excellent according to the 2014 UK wide Research Excellence Framework. This places us in the top quartile for world-leading publications among UK universities in General Engineering.

Teaching And Assessment

Your progress will be monitored by lecturing staff and advice and appropriate links supplied to improve your learning. Web links are provided for further reading whilst online videos, where appropriate, are available for you to review taught material in your own time. Lecture material is enhanced with laboratory sessions which allow demonstration of theories and exploration of practical problems and limitations.

As a postgraduate student you will be expected to have a responsible and professional approach to learning, accessing the material and support provided and raising any problems with academic staff or your programme leader. You will have an opportunity to take an active role in the operation and content of the course via the departmental programme committee.

Module Overview
KD7019 - Advanced Embedded System Design Technology (Core, 20 Credits)
KD7020 - Digital Design Automation (Core, 20 Credits)
KD7063 - Wireless Communication Systems (Core, 20 Credits)
KD7064 - Optical Communications System (Core, 20 Credits)
KD7065 - MSc Engineering Project (Core, 60 Credits)
KD7066 - Analogue Electronic Design (Core, 20 Credits)
KD7067 - Engineering Research and Project Management (Core, 20 Credits)

Learning Environment

Whether your subject matter is renewable energy, astrophysics or communications, our range of specialist and general use facilities will support you. Throughout your work you will be able to measure, explore, experiment and model developments that are changing the way we all live our lives.

Technology to enhance learning in engineering is embedded throughout the programme. This takes the form of self-guided exercises, online tests with feedback, assessment feedback and videos and tutorials to support lectures. Self-development and employability are enhanced throughout the programme, especially with respect to communicating ideas in written and oral forms, the use of appropriate IT tools, personal time management, problem solving and independent learning skills.

Research-Rich Learning

Our course is at the forefront of current knowledge and practice, shaped by world-leading and internationally excellent research. All the modules are industry or research informed, based upon academic staff industrial experience, consultancy or personal research interests. This allows the knowledge and skills that you will acquire to meet the need and practical application for real world scenarios.

The course is supported by a team of academics who are highly respected by research groups around the world and who make a significant contribution to the faculty and University vision for the future of research within the higher education sector.

Give Your Career An Edge

A strong industrial and research based curriculum enhances your employability by considering real world scenarios in which known solutions are absent. You will be encouraged to research information from professional publications, company literature, etc. to determine innovative and appropriate solutions to these scenarios, enabling you to demonstrate relevant industry practice.

You will also be attached to one of the departmental or faculty research groups for your final dissertation, exposed to and incorporated into a working team and environment. This provides the opportunity for both work-related learning experience and professional career development.

Your Future

The rapid growth of the communications and microelectronics industries has created a strong demand for skilled engineers, who are able to design and manufacture semiconductors and freespace and optical communication systems. The UK Government’s commitment to high-speed broadband means that demand for communications engineers is expected to outstrip supply. UK and international demand for microelectronic engineers remains strong, with salaries reflecting employers’ need to attract the best candidates.

Upon graduation, you will be well-equipped to apply for roles such as communications engineer, electronic/electrical engineer, operational researcher, software engineer and systems developer. You may also consider the wider engineering and information technology sectors, including energy, transport, electronics and telecommunications, defence and manufacturing and engineering management.

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The Masters in Astrophysics gives you an understanding of the principles and methods of modern astrophysics at a level appropriate for a professional physicist. Read more
The Masters in Astrophysics gives you an understanding of the principles and methods of modern astrophysics at a level appropriate for a professional physicist.

Why this programme

-The School has a major role in the award winning NASA RHESSI X-ray mission studying solar flares and in several other forthcoming international space missions such as ESA’s Solar Orbiter.
-The School plays a world-leading role in the design and operation of the worldwide network of laser interferometers leading the search for gravitational waves.
-The University of Glasgow’s School of Physics and Astronomy is ranked 2nd in Scotland (Complete University Guide 2016).
With a 93% overall student satisfaction in the National Student Survey 2014, the School of Physics and Astronomy combines both teaching excellence and a supportive learning environment.
-You will gain the theoretical, observational and computational skills necessary to analyse and solve advanced astrophysics problems, providing you with an excellent foundation for a career of scientific leadership in academia or industry.
-You will develop transferable skills that will improve your career prospects, such as project management, team-working, advanced data analysis, problem-solving, critical evaluation of scientific literature, advanced laboratory and computing skills, and how to effectively communicate with different audiences.
-You will benefit from direct contact with our group of international experts who will teach you cutting-edge physics and supervise your projects.

Programme structure

Modes of delivery of the MSc in Astrophysics include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

The programme draws upon a wide range of advanced Masters-level courses. You will have the flexibility to tailor your choice of optional courses and project work to a variety of specific research topics and their applications in the area of astrophysics.

Core courses include
-Advanced data analysis
-General relativity and gravitation (alternate years, starting 2016–17)
-Plasma theory and diagnostics (alternate years, starting 2015–16)
-Pulsars and supernovae (alternate years, starting 2016–17)
-Research skills
-Statistical astronomy (alternate years, starting 2015–16)
-Extended project.

Optional courses include
-Advanced electromagnetic theory
-Applied optics
-Circumstellar matter (alternate years, starting 2015-16)
-Cosmology (alternate years, starting 2016–17)
-Dynamics, electrodynamics and relativity
-Exploring planetary systems (alternate years, starting 2016-17)
-Galaxies (alternate years, starting 2015-16)
-Gravitational wave detection
-Instruments for optical and radio astronomy (alternate years, starting 2016-17)
-Statistical mechanics
-Stellar astrophysics (alternate years, starting 2015–16)

Industry links and employability

-The School of Physics and Astronomy is highly active in research and knowledge transfer projects with industry. Our Masters students have regular opportunities to engage with our industrial collaborators through informal visits, guest lectures and workshops.
-You will also benefit from our membership of the Scottish Universities Physics Alliance. The alliance brings together internationally leading physics research across Scotland to form the largest physics grouping in the UK.
-Our staff and students come from all around the world providing a truly global experience. The School of Physics and Astronomy is committed to providing an equitable environment for study and work, in line with the principles of Project Juno of the Institute of Physics. This was recognised in 2011 by the award of Juno Champion status. We also have a strong programme of talks and seminars given by experts from the UK and abroad, which will give you the chance of broadening your knowledge in many other areas of physics and astronomy.
-This programme is accredited by the Institute of Physics. Accredited MSc programmes automatically meet the master's level education requirement for Chartered Physicist (CPhys) status. To fully meet the educational requirements for CPhys, graduates must also possess an IOP accredited undergraduate degree or equivalent.

Career prospects

Career opportunities include academic research, based in universities, research institutes, observatories and laboratory facilities; industrial research in a wide range of fields including energy and the environmental sector, IT and semiconductors, optics and lasers, materials science, telecommunications, engineering; banking and commerce; higher education.

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The Masters in Physics. Advanced Materials provides an understanding of the principles and methods of modern physics, with particular emphasis on their application to global interdisciplinary challenges in the area of advanced materials and at a level appropriate for a professional physicist. Read more
The Masters in Physics: Advanced Materials provides an understanding of the principles and methods of modern physics, with particular emphasis on their application to global interdisciplinary challenges in the area of advanced materials and at a level appropriate for a professional physicist.

Why this programme

-The School of Physics & Astronomy hosts the Kelvin Nanocharacterisation Centre, which houses state-of-the-art instrumentation for studying materials at the nanoscale or below.
-With a 93% overall student satisfaction in the National Student Survey 2014, the School of Physics and Astronomy combines both teaching excellence and a supportive learning environment.
-The University of Glasgow’s School of Physics and Astronomy is ranked 2nd in Scotland (Complete University Guide 2016).
-You will gain the theoretical, experimental and computational skills necessary to analyse and solve a range of advanced physics problems relevant to the theme of this global challenge, providing an excellent foundation for a career of scientific leadership in academia or industry.
-You will develop transferable skills that will improve your career prospects, such as project management, team-working, advanced data analysis, problem-solving, critical evaluation of scientific literature, advanced laboratory and computing skills, and how to effectively communicate with different audiences.
-You will benefit from direct contact with our group of international experts who will teach you cutting-edge physics and supervise your projects.

Programme structure

Modes of delivery of the MSc in Physics: Advanced Materials include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

The programme draws upon a wide range of advanced Masters-level courses. You will have the flexibility to tailor your choice of optional lecture courses and project work to a wide variety of specific research topics and their applications in the area of advanced materials.

Core courses include
-Advanced data analysis
-Nano and atomic scale imaging
-Research skills
-Solid state physics
-Extended project

Optional courses include
-Detection and analysis of ionising radiation
-Detectors and imaging
-Environmental radioactivity
-Nuclear power reactors
-Semiconductor physics
-Statistical mechanics

Industry links and employability

-The School of Physics and Astronomy is highly active in research and knowledge transfer projects with industry. Our Masters students have regular opportunities to engage with our industrial collaborators through informal visits, guest lectures and workshops.
-You will also benefit from our membership of the Scottish Universities Physics Alliance. The alliance brings together internationally leading physics research across Scotland to form the largest physics grouping in the UK.
-Our staff and students come from all around the world providing a truly global experience. The School of Physics and Astronomy is committed to providing an equitable environment for study and work, in line with the principles of Project Juno of the Institute of Physics. This was recognised in 2011 by the award of Juno Champion status. We also have a strong programme of talks and seminars given by experts from the UK and abroad, which will give you the chance of broadening your knowledge in many other areas of physics and astronomy.
-The School of Physics and Astronomy plays a world-leading role in the design and operation of the worldwide network of laser interferometers leading the search for gravitational waves. These interferometers are among the most sensitive scientific instruments ever built.
-This programme is accredited by the Institute of Physics. Accredited MSc programmes automatically meet the master's level education requirement for Chartered Physicist (CPhys) status. To fully meet the educational requirements for CPhys, graduates must also possess an IOP accredited undergraduate degree or equivalent.

Career prospects

Career opportunities in academic research, based in universities, research institutes, observatories and laboratory facilities; industrial research in a wide range of fields including energy and the environmental sector, IT and semiconductors, optics and lasers, materials science, telecommunications, engineering; banking and commerce; higher education.

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The Masters in Physics. Energy & the Environment provides an understanding of the principles and methods of modern physics, with emphasis on their application to global challenges in sustainable energy, climate change and the environment, and at a level appropriate for a professional physicist. Read more
The Masters in Physics: Energy & the Environment provides an understanding of the principles and methods of modern physics, with emphasis on their application to global challenges in sustainable energy, climate change and the environment, and at a level appropriate for a professional physicist.

Why this programme

-The University of Glasgow’s School of Physics and Astronomy is ranked 2nd in Scotland (Complete University Guide 2016).
-The School plays a leading role in the exploitation of data from the Large Hadron Collider, the world’s largest particle accelerator at CERN.
-With a 93% overall student satisfaction in the National Student Survey 2014 the School of Physics and Astronomy combines both teaching excellence and a supportive learning environment.
-The School of Physics & Astronomy hosts the Kelvin Nanocharacterisation Centre, which houses state-of-the-art instrumentation for studying materials at the nanoscale or below.
-You will gain the theoretical, experimental and computational skills necessary to analyse and solve a range of advanced physics problems relevant to the theme of this global challenge, providing an excellent foundation for a career of scientific leadership in academia or industry.
-You will develop transferable skills that will improve your career prospects, such as project management, team-working, advanced data analysis, problem-solving, critical evaluation of scientific literature, advanced laboratory and computing skills, and how to effectively communicate with different audiences.
-You will benefit from direct contact with our group of international experts who will teach you cutting-edge physics and supervise your projects.

Programme structure

Modes of delivery of the MSc Physics: Energy and the Environment include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

The programme draws upon a wide range of advanced Masters-level courses. You will have the flexibility to tailor your choice of optional lecture courses and project work to a wide variety of specific research topics and their applications in the areas of energy and the environment.

Core courses include
-Advanced data analysis
-Energy and environment
-Nuclear power reactors
-Research skills
-Extended project

Optional courses include
-Advanced electromagnetic theory
-Detection and analysis of ionising radiation
-Detectors and imaging
-Environmental radioactivity
-Plasma theory and diagnostics (alternate years, starting 2015–16)
-Statistical mechanics

Industry links and employability

-The School of Physics and Astronomy is highly active in research and knowledge transfer projects with industry. Our Masters students have regular opportunities to engage with our industrial collaborators through informal visits, guest lectures and workshops.
-You will also benefit from our membership of the Scottish Universities Physics Alliance. The alliance brings together internationally leading physics research across Scotland to form the largest physics grouping in the UK.
-Our staff and students come from all around the world providing a truly global experience. The School of Physics and Astronomy is committed to providing an equitable environment for study and work, in line with the principles of Project Juno of the Institute of Physics. This was recognised in 2011 by the award of Juno Champion status. We also have a strong programme of talks and seminars given by experts from the UK and abroad, which will give you the chance of broadening your knowledge in many other areas of physics and astronomy.
-The School plays a world-leading role in the exploitation of data from the Large Hadron Collider, the world’s largest particle accelerator at CERN.
-This programme is accredited by the Institute of Physics. Accredited MSc programmes automatically meet the master's level education requirement for Chartered Physicist (CPhys) status. To fully meet the educational requirements for CPhys, graduates must also possess an IOP accredited undergraduate degree or equivalent.

Career prospects

Career opportunities in academic research, based in universities, research institutes, observatories and laboratory facilities; industrial research in a wide range of fields including energy and the environmental sector, IT and semiconductors, optics and lasers, materials science, telecommunications, engineering; banking and commerce; higher education.

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The Masters in Physics. Global Security provides an understanding of the principles and methods of modern physics, with particular emphasis on their application to interdisciplinary challenges in the area of global security, and at a level appropriate for a professional physicist. Read more
The Masters in Physics: Global Security provides an understanding of the principles and methods of modern physics, with particular emphasis on their application to interdisciplinary challenges in the area of global security, and at a level appropriate for a professional physicist.

Why this programme

-The University of Glasgow’s School of Physics and Astronomy is ranked 2nd in Scotland (Complete University Guide 2016).
-The School plays a leading role in the exploitation of data from the Large Hadron Collider, the world’s largest particle accelerator at CERN.
-With a 93% overall student satisfaction in the National Student Survey 2014, the School of Physics and Astronomy combines both teaching excellence and a supportive learning environment.
-The School of Physics & Astronomy hosts the Kelvin Nanocharacterisation Centre, which houses state-of-the-art instrumentation for studying materials at the nanoscale or below.
-You will gain the theoretical, experimental and computational skills necessary to analyse and solve a range of advanced physics problems relevant to the theme of this global challenge, providing an excellent foundation for a career of scientific leadership in academia or industry.
-You will develop transferable skills that will improve your career prospects, such as project management, team-working, advanced data analysis, problem-solving, critical evaluation of scientific literature, advanced laboratory and computing skills, and how to effectively communicate with different audiences.
-You will benefit from direct contact with our group of international experts who will teach you cutting-edge physics and supervise your projects.

Programme structure

Modes of delivery of the MSc Physics: Global Security include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

The programme draws upon a wide range of advanced Masters-level courses. You will have the flexibility to tailor your choice of optional lecture courses and project work to a wide variety of specific research topics and their applications in the area of global security.

Core courses include
-Advanced data analysis
-Detection and analysis of ionising radiation
-Research skills
-Extended project

Optional courses include
-Advanced electromagnetic theory
-Applied optics
-Detectors and imaging
-Environmental radioactivity
-Nuclear power reactors
-Quantum information
-Statistical mechanics

Industry links and employability

-The School of Physics and Astronomy is highly active in research and knowledge transfer projects with industry. Our Masters students have regular opportunities to engage with our industrial collaborators through informal visits, guest lectures and workshops.
-You will also benefit from our membership of the Scottish Universities Physics Alliance. The alliance brings together internationally leading physics research across Scotland to form the largest physics grouping in the UK.
-Our staff and students come from all around the world providing a truly global experience. The School of Physics and Astronomy is committed to providing an equitable environment for study and work, in line with the principles of Project Juno of the Institute of Physics. This was recognised in 2011 by the award of Juno Champion status. We also have a strong programme of talks and seminars given by experts from the UK and abroad, which will give you the chance of broadening your knowledge in many other areas of physics and astronomy.
-The School plays a world-leading role in the exploitation of data from the Large Hadron Collider, the world’s largest particle accelerator at CERN.
-This programme is accredited by the Institute of Physics. Accredited MSc programmes automatically meet the master's level education requirement for Chartered Physicist (CPhys) status. To fully meet the educational requirements for CPhys, graduates must also possess an IOP accredited undergraduate degree or equivalent.

Career prospects

Career opportunities include academic research, based in universities, research institutes, observatories and laboratory facilities; industrial research in a wide range of fields including energy and the environmental sector, IT and semiconductors, optics and lasers, materials science, telecommunications, engineering; banking and commerce; higher education.

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The Masters in Theoretical Physics provides an understanding of the principles and methods of modern physics, with particular emphasis on the theoretical aspects of the subject, and at a level appropriate for a professional physicist. Read more
The Masters in Theoretical Physics provides an understanding of the principles and methods of modern physics, with particular emphasis on the theoretical aspects of the subject, and at a level appropriate for a professional physicist.

Why this programme

-The University of Glasgow’s School of Physics and Astronomy is ranked 2nd in Scotland (Complete University Guide 2016).
-The School plays a leading role in the exploitation of data from the Large Hadron Collider, the world’s largest particle accelerator at CERN.
-With a 93% overall student satisfaction in the National Student Survey 2014, the School of Physics and Astronomy combines both teaching excellence and a supportive learning environment.
-You will gain the theoretical and computational skills necessary to analyse and solve a range of advanced physics problems, providing an excellent foundation for a career of scientific leadership in academia or industry.
-You will develop transferable skills that will improve your career prospects, such as project management, team-working, advanced data analysis, problem-solving, critical evaluation of scientific literature, advanced laboratory and computing skills, and how to effectively communicate with different audiences.
-You will benefit from direct contact with our group of international experts who will teach you cutting-edge physics and supervise your projects.

Programme structure

Modes of delivery of the MSc in Theoretical Physics include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

The programme draws upon a wide range of advanced Masters-level courses. You will have the flexibility to tailor your choice of optional lecture courses and project work to a wide variety of specific research topics and their applications in the area of theoretical physics.

Core courses include
-Advanced data analysis
-Quantum information
-Quantum theory
-Research skills
-Extended project

Optional courses include
-Advanced electromagnetic theory
-Advanced mathematical methods
-Applied optics
-Dynamics, electrodynamics and relativity
-General relativity and gravitation (alternate years, offered 2016-17)
-Plasma theory and diagnostics (alternate years, offered 2015-16)
-Relativistic quantum fields
-Statistical mechanics

Industry links and employability

-The School of Physics and Astronomy is highly active in research and knowledge transfer projects with industry. Our Masters students have regular opportunities to engage with our industrial collaborators through informal visits, guest lectures and workshops.
-You will also benefit from our membership of the Scottish Universities Physics Alliance. The alliance brings together internationally leading physics research across Scotland to form the largest physics grouping in the UK.
-Our staff and students come from all around the world providing a truly global experience. The School of Physics and Astronomy is committed to providing an equitable environment for study and work, in line with the principles of Project Juno of the Institute of Physics. This was recognised in 2011 by the award of Juno Champion status. We also have a strong programme of talks and seminars given by experts from the UK and abroad, which will give you the chance of broadening your knowledge in many other areas of physics and astronomy.
-This programme is accredited by the Institute of Physics. Accredited MSc programmes automatically meet the master's level education requirement for Chartered Physicist (CPhys) status. To fully meet the educational requirements for CPhys, graduates must also possess an IOP accredited undergraduate degree or equivalent.

Career prospects

Career opportunities include academic research, based in universities, research institutes, observatories and laboratory facilities; industrial research in a wide range of fields including energy and the environmental sector, IT and semiconductors, optics and lasers, materials science, telecommunications, engineering; banking and commerce; higher education.

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This course has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation. Read more
This course has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation.

Who is it for?

This course is suitable for both practicing engineers and those considering a career in engineering.

The course has been designed to provide an in-depth insight into the technical workings, management and economics of the electrical power industry.

Objectives

This programme has been designed to meet the industrial demand for the training and education of both existing and future engineers in the advanced concepts of sustainable electrical power and energy generation. The aims are to produce graduates of a high calibre with the right skills and knowledge who will be capable of leading teams involved in the operation, control, design, regulation and management of power systems and networks of the future.

The programme aims to:
-Provide you with the ability to critically evaluate methodologies, analytical procedures and research methods.
-Provide an advanced education in electrical power engineering.
-Give you the education, knowledge and the skills you need to make sound decisions in a rapidly changing electricity supply industry.
-Provide a sound understanding of the principles and techniques of electrical power engineering.
-Give a broad knowledge of the issues and problems faced by electrical power engineers.
-Give a solid working knowledge of the techniques used to solve these problems.
-Provide a foundation in power systems principles for graduates with an engineering background.
-Demonstrate the practical relevance of these principles to the operation of successful enterprises in the broad field of electrical power engineering.
-Familiarise professional engineers and graduates with the theory and application of new technologies applied to power systems.

Academic facilities

Students in City's Department of Electronic and Electrical Engineering benefit from a recent lab equipment upgrade worth £130,000. This includes photovoltaic trainers, three phase synchronous machines, AC motor speed control machines, single and three phase transformers, thryistor controllers, a power systems mainframe and power systems virtual instrumentation.

The equipment is essential in training students to be highly skilled professionals in the energy industry.

The photovoltaic trainer, for instance, is a desk-top instrument which teaches the fundamental principles of photovoltaic energy. The 'photovoltaic effect' is a method of energy generation which converts solar radiation into an electrical current using semiconductors arranged into solar cells.

Teaching and learning

Modules are delivered by academics actively involved in energy related research, as well as visiting lecturers from the power industry who provide a valuable insight into the operation of energy companies.

Industry professionals give several seminars throughout the year. At least two industrial trips are organised per academic year.

Modules

The modules for this course are delivered over two semesters, with weekly lessons scheduled over two days a week. The third semester is spent completing a project that involves writing a dissertation and presenting findings. This course is organised into eight modules provided on a weekly basis.

Course content
-Introduction to Power Systems & Energy Management EPM874 (15 credits)
-Systems Modelling EPM744 (15 credits)
-Renewable Energy Fundamentals and Sustainable Energy Technologies EPM879 (15 credits)
-Transmission and Distribution Systems Management EPM875 (15 credits)
-Power Systems Design and Simulation EPM423 (15 credits)
-Power Electronics EPM501 (15 credits)
-Power Systems Protection and Grid Stability EPM990 (15 credits)
-Economics of the Power Industry EPM101 (15 credits)
-Dissertation EPM949 (60 credits)

Career prospects

Graduates are prepared for careers that encompass a variety of roles in the power industry, from technical aspects to management roles. Previously graduates have found jobs as engineers, managers and analysts in the power sector, with companies such as:
-OFGEM
-National Grid
-UK Power Networks
-EON
-EDF
-Vattenfall
-Caterpillar
-Railroad
-Graduates may also wish to further their research in the energy field by considering a PhD

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The Masters in Physics. Nuclear Technology provides an understanding of the application of nuclear processes and technology to energy generation, medical physics and environmental monitoring, and at a level appropriate for a professional physicist. Read more
The Masters in Physics: Nuclear Technology provides an understanding of the application of nuclear processes and technology to energy generation, medical physics and environmental monitoring, and at a level appropriate for a professional physicist.

Why this programme

-The University of Glasgow’s School of Physics and Astronomy is ranked 2nd in Scotland (Complete University Guide 2016).
-You will gain theoretical, experimental and computational skills necessary to analyse and solve advanced physics problems relevant to the theme of Nuclear Technology, providing an excellent foundation for a career of scientific leadership.
-With a 93% overall student satisfaction in the National Student Survey 2014, the School of Physics and Astronomy combines both teaching excellence and a supportive learning environment.
-You will benefit from direct contact with our group of international experts who will teach you cutting-edge physics and supervise your projects.

Programme structure

Modes of delivery of the MSc Physics: Nuclear Technology include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

Core courses include
-Advanced data analysis
-Detection and analysis of ionising radiation
-Environmental radioactivity
-Imaging and detectors
-Nuclear power reactors
-Research skills
-Extended project

Optional courses include
-Advanced electromagnetic theory
-Advanced nuclear physics
-Computational physics laboratory
-Dynamics, electrodynamics and relativity
-Energy and environment
-Medical imaging
-Nuclear and particle physics
-Numerical methods
-Plasma theory and diagnostics (alternate years starting 2015-16)
-Relativistic quantum fields
-Statistical mechanics

The programme in Physics: Nuclear technology lasts 1 year and contains a minimum of 180 credits. You will undertake a minimum of 120 credits in Semesters 1 and 2 and be assessed on these courses either via continuous assessment, or unseen examination in the May/June examination diet, or a combination thereof. The remaining 60 credits will take the form of an extended MSc project, carried out on a specific aspect of theoretical, computational or experimental physics which has current or potential application in the areas of nuclear technology, nuclear energy, radiation detection or environmental monitoring. You will conduct this project while embedded within a particular research group – under the direct supervision of a member of academic staff.

Your curriculum will be flexible and tailored to your prior experience and expertise, particular research interests and specific nature of the extended research project topic provisionally identified at the beginning of the MSc programme. Generally, however, courses taken in Semester 1 will focus on building core theoretical and experimental/computational skills relevant to the global challenge theme, while courses taken in Semester 2 will build key research skills (in preparation for the extended project).

Industry links and employability

-The School of Physics and Astronomy is highly active in research and knowledge transfer projects with industry. Our Masters students have regular opportunities to engage with our industrial collaborators through informal visits, guest lectures and workshops.
-You will also benefit from our membership of the Scottish Universities Physics Alliance. The alliance brings together internationally leading physics research across Scotland to form the largest physics grouping in the UK.
-Our staff and students come from all around the world providing a truly global experience. The School of Physics and Astronomy is committed to providing an equitable environment for study and work, in line with the principles of Project Juno of the Institute of Physics. This was recognised in 2011 by the award of Juno Champion status. We also have a strong programme of talks and seminars given by experts from the UK and abroad, which will give you the chance of broadening your knowledge in many other areas of physics and astronomy.
-This programme is accredited by the Institute of Physics. Accredited MSc programmes automatically meet the master's level education requirement for Chartered Physicist (CPhys) status. To fully meet the educational requirements for CPhys, graduates must also possess an IOP accredited undergraduate degree or equivalent.

Career prospects

Career opportunities in academic research, based in universities, research institutes, observatories and laboratory facilities; industrial research in a wide range of fields including energy and the environmental sector, IT and semiconductors, optics and lasers, materials science, telecommunications, engineering; banking and commerce; higher education.

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On our MSc Algorithmic Trading, we equip you with the core concepts and quantitative methods in high frequency finance, along with the operational skills to use state-of-the-art computational methods for financial modelling. Read more
On our MSc Algorithmic Trading, we equip you with the core concepts and quantitative methods in high frequency finance, along with the operational skills to use state-of-the-art computational methods for financial modelling.

We enable you to attain an understanding of financial markets at the level of individual trades occurring over sub-millisecond timescales, and apply this to the development of real-time approaches to trading and risk-management.

The course includes hands-on projects on topics such as order book analysis, VWAP & TWAP, pairs trading, statistical arbitrage, and market impact functions. You have the opportunity to study the use of financial market simulators for stress testing trading strategies, and designing electronic trading platforms.

In addition to traditional topics in financial econometrics and market microstructure theory, we put special emphasis on areas:
-Statistical and computational methods
-Modelling trading strategies and predictive services that are deployed by hedge funds
-Algorithmic trading groups
-Derivatives desks
-Risk management departments

Our Centre for Computational Finance and Economic Agents is an innovative and laboratory-based teaching and research centre, with an international reputation for leading-edge, interdisciplinary work combining economic and financial modelling with computational implementation. We are supported by Essex’s highly rated Department of Economics, School of Computer Science and Electronic Engineering, and Essex Business School.

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

This course is taught by experts with both academic and industrial expertise in the financial and IT sectors. We bring together leading academics in the field from our departments of economics, computer science and business.

Our staff are currently researching the development of real-time trading platforms, new financial econometric models for real-time data, the use of artificially intelligent agents in the study of risk and market-based institutions, operational aspects of financial markets, financial engineering, portfolio and risk management.

More broadly, our research covers a range of topics, from materials science and semiconductor device physics, to the theory of computation and the philosophy of computer science, with most of our research groups based around laboratories offering world-class facilities.

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

We have an extensive network of industrial contacts through our City Associates Board and our alumni, while our expert seminar series gives you the opportunity to work with leading figures from industry.

Our recent graduates have gone on to become quantitative analysts, portfolio managers and software engineers at various institutions, including:
-HSBC
-Mitsubishi UFJ Securities
-Old Mutual
-Bank of England

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

-CCFEA MSc Dissertation
-Big-Data for Computational Finance
-High Frequency Finance and Empirical Market Microstructure
-Introduction to Financial Market Analysis
-Professional Practice and Research Methodology
-Quantitative Methods in Finance and Trading
-Trading Global Financial Markets
-Cloud Technologies and Systems (optional)
-Constraint Satisfaction for Decision Making (optional)
-Creating and Growing a New Business Venture (optional)
-Digital Signal Processing (optional)
-Evolutionary Computation and Genetic Programming (optional)
-Financial Engineering and Risk Management (optional)
-High Performance Computing (optional)
-Industry Expert Lectures in Finance (optional)
-Learning and Computational Intelligence in Economics and Finance (optional)
-Mathematical Research Techniques Using Matlab (optional)
-Programming in Python (optional)
-Text Analytics (optional)

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The optoelectronics market is expected to grow significantly in coming years. This specialist optoelectronics Masters course will give you access to optoelectronics expertise, so you can take advantage of new opportunities in this field. Read more
The optoelectronics market is expected to grow significantly in coming years. This specialist optoelectronics Masters course will give you access to optoelectronics expertise, so you can take advantage of new opportunities in this field.

Optoelectronics includes electronic devices that source, detect and control light. On this course you will benefit from high-level vocational training in lasers, LED lighting and semiconductors, tailored to the needs of the optoelectronics and optical communications industries.

As part of your studies, you will also benefit from the latest research within the field. You will be able to attend relevant research seminars and departmental seminars that are held regularly throughout the year. These events reflect the most up-to-date thinking from academics and specialists from industry.

The teaching team, many of whom have published research in optoelectronics, lead the University’s Wireless and Optoelectronics Research and Innovation Centre This informs our teaching, so you will benefit from cutting-edge Course Content that embodies the latest research.

Routes of study:
The course is available to study via two routes:
- MSc Optoelectronics (with internship)
- MSc Optoelectronics (without internship)

Please note: *Internships are optional and available to full-time students only. Internship places are limited. Students have the opportunity to work in a participating UK company or within a Research Centre at the University. You can also opt to study the course without an internship which will reduce your course length.

What you will study

You will study the following modules:
- Physics in Modern Optics
- Optoelectronics Devices for Telecommunications
- Optoelectronics Devices for Life Science & Measurement
- Applied Digital Signal Processing
- Embedded System Design
- Product Innovation and Entrepreneurship
- Six month Internship
- Masters Major Individual Project

Learning and teaching methods

The optoelectronics course offers an intensive but flexible learning pattern, with two start points each year – February and September. There are three major blocks during the 18 months’ study (full-time), which includes 12 months of teaching and a possible six months of internship*. Throughout your studies you will complete a 15-week final research project.

You will be taught through lectures, tutorials and workshops involving hands-on systems modeling and simulations using state-of-the-art hardware and software facilities (Zemax, Lightools etc). Students will also engage in supervised research supported by full access to world-class online and library facilities.

You are also expected to regularly attend relevant research seminars and departmental colloquia, which reflect the up-to-date research interests of the Wireless and Optoelectronics Research and Innovation Centre (WORIC).

The optoelectronics course is available to study via two main routes, you can opt to add further value to your studies by undertaking an internship or simply focus on building your academic knowledge through a on-campus study as detailed below:

- MSc Optoelectronics (with internship):
Delivery: Full-time only | Start dates: September and February

If you choose to undertake an internship, your course will be delivered in four major blocks that offer an intensive but flexible learning pattern. Six taught modules are completed during two teaching blocks featuring 12 contact hours per week. This is followed by 6 month period of internship, after which the student returns to undertake a 16-week major research project. Please note: Course length may vary dependent on your chosen start date.

- MSc Optoelectronics (without internship):
Delivery: Full-time and Part-time | Start dates: September and February

The study pathway available without internship is available full-time and part-time. The full-time route is delivered in three major blocks. Six taught modules are completed during two teaching blocks featuring 12 contact hours per week followed by a 16-week major research project. The full-time course duration is about 12 months, if you study part-time then you will complete the course in three years. Part-time study involves completing three modules in each of the first two years and a major research project in the final year. The use of block-mode delivery in this way allows flexible entry and exit, and also enables practising engineers to attend a single module as a short course.

Work Experience and Employment Prospects

Many industries need specialists in optoelectronics systems design. Careers are available in industrial and technology sectors such as automotives, computers, consumer electronics, communications, industrial optical sensing equipment and medical laser equipment.

The major project gives you a great opportunity to deepen your knowledge and hone your skills in a specialist topic informed by your planned career, and the period of internship gives you an industrial experience that can set you apart from others immediately upon graduation.

Internship

Internships are only available to students studying full-time: Following successful completion of six taught modules, you will be competitively selected to join participating UK companies or University Research Centres on a six-month period of unpaid work placement before returning to undertake your major research project. All students who have an offer for the MSc Optoelectronics (with internship) are guaranteed an internship either in industry or in a University Research Centre.

There are 25 internship places available. Students who wish to undertake an internship must apply for the MSc Optoelectronics (with internship). It is anticipated that there will be significant demand for this programme and applicants are advised to apply as soon as possible to avoid disappointment. Applications will be considered on a first come first served basis and the numbers of students offered a place on the programme with internship will be capped.

If the course is already full and we are unable to offer you a place on the Masters course with internship, we may be able to consider you for the standard MSc Optoelectronics (without internship) which is a shorter programme.

Assessment methods

Each of the six taught modules is typically assessed through 50% coursework and 50% closed-book class test. The major project is assessed through presentation to a panel of examiners, viva and written report. Work for lecture modules is assessed largely through examinations whereas the laboratory work is assessed in a continuous manner. Lecture courses are examined at the end of each teaching block.

Facilities

There are two optoelectronics and two RF laboratories equipped with £1million worth of experimental equipments and modeling facilities. These state-of-the-art facilities are home to:

The Innova® Sabre® MotoFreD™ ion laser
Newfocus TLM-8700 fast sweep tunable laser source
Agilent 8164B Lightwave Measurement System
RENISHAW ML-10 Measurement Systems
Beam profilers: Thorlabs BC106-VIS – CCD Camera Beam Profiler, Thorlabs BP109-IR – Beam Profiler
Scanning Fabry-Perot Spectrum Analyzer. e.g. Thorlabs SA200-5B, Coherence 0464H08
Anritsu MS9710B Optical Spectrum Analyzer
Ocean Optics spectrometers. e.g. HR4000 and USB4000
Edwards E306A Coating System Thermal Vacuum Evaporator
SCS G3-8 Spin Coater
ZEPTO laboratory plasma cleaner ZEPTO
FUJIKURA FSM-40S ARC FUSION SPLICER
National Instruments FPGA and Digitizer
Signal generator: TG210 2MhZ function Generator
Oscilloscopes: HP infinium Oscilloscope, HM507 Combiscope
Anechoic Chamber suitable for frequencies above 1 GHz.
Various measurement systems for 2, 10, 20, 40, & 60 GHz links
VubiQ 60 GHz development kits
Three 60 GHz Backhaul links (Sub10 Systems)
Antenna radiation patterns measurement system
Two equipped vans for outdoor measurements
Programmable or Reconfigurable Platform (DSPs, FPGAs, GPPs)
The modeling facilities include high performance computing facilities (e.g. a 24-core cluster) equipped with various optoelectronic and EM modeling packages such as FDTD solutions, Zemax, FEKO, and VPI Photonics suites. We also in-house novel RF Ray-tracing and Physical Optics EM planning tools developed by members of WORIC.

Teaching

The academic staff teaching on the MSc Optoelectronics are the same people who lead and work in the WORIC. This international centre has a significant track record of innovation in lasers, sensors, nanophotonics, wireless communications, telecommunications, and optical communications and aims to provide industry with access to cutting edge innovative ideas and knowledge. WORIC has won many grants from EPSRC, TSB, EADS, as well as A4B is keen to solve real industrial problems with innovation that provides enormous market.

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The program aims to form Master graduates with a comprehensive and solid scientific and technological background in Electronics Engineering, able to design and to use electronic devices, electronic circuits and electronic systems of any complexity as well as to promote the diffusion of electronic technologies in the fields of human activity where benefits can be envisaged. Read more

Mission and goals

The program aims to form Master graduates with a comprehensive and solid scientific and technological background in Electronics Engineering, able to design and to use electronic devices, electronic circuits and electronic systems of any complexity as well as to promote the diffusion of electronic technologies in the fields of human activity where benefits can be envisaged.
To meet these training needs, the Master of Science in Electronics Engineering bases its roots on a full spectrum of basic courses (mathematics, classical and modern physics, computer science, signal theory, control and communications, basic electronic circuits) that are prerequisites required from the Bachelor, and focuses on the most advanced disciplines in electronic design (analog and digital electronics, solid state physics and devices, microelectronics, optoelectronics, sensors and electronic instrumentation, communications and control systems) to provide a complete and updated preparation. Upon graduating, students will have developed a “design oriented” mindset and acquired a skill to use engineering tools to design solutions to advanced electronic challenges in scientific and technological fields.

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

Career opportunities

Thanks to the deep and solid scientific and technological knowledge provided, Master of Science graduates in Electronics Engineering will be able to hold positions of great responsibility, both at technical and management level, in a wide variety of productive contexts:
- Scientific and technological research centers, national and international, public or private;
- Industries of semiconductors, integrated circuits and in general of electronic components;
- Industries of electronic systems and instrumentation, such as consumer electronics (audio, video, telephone, computers, etc.), optoelectronics, biomedical, etc.;
- Electromechanical industries with high technological content such as aeronautics, transportation, aerospace, energy, robotics and plant automation, etc.;
- Work as a freelance in the design and fabrication of custom electronic systems.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Electronics_Engineering_01.pdf
The Master of Science in Electronics Engineering aims to form graduates with a comprehensive and solid scientific and technological knowledge in the field of Electronics, able to design and to use electronic devices, electronic circuits and electronic systems of any complexity as well as to promote the diffusion of electronic technologies in the fields of human activity where benefits can be envisaged. The course focuses on the most advanced aspects of Electronics (analog and digital integrated circuits design, solid state devices, microelectronics, optoelectronic devices and sensors, electronic instrumentation, communications and control systems) to provide a complete and updated professional preparation. Upon graduating, students will have developed a “design oriented” mindset enabling them to successfully deal with the complex needs of today’s industrial system. They will have also acquired a skill to use engineering tools to design solutions to advanced electronic challenges in scientific and technological fields as well as a maturity to hold positions of great responsibility both at technical and management level. The programme is taught in English.

Required background from Bachelor studies

The Master of Science in Electronics Engineering bases its roots on a full spectrum of knowledge that students are expected to have successfully acquired in their Bachelor degree, like advanced mathematics, classical and modern physics, computer science, signal and communication theory, electric circuits and feedback control, basic electronic devices and analog & digital circuit analysis.

Subjects

- Analog & Digital Integrated Circuit Design
- MEMS and Microsensors
- Electronic Systems
- Electron Devices and Microelectronic Technologies
- Signal recovery and Feedback Control
- Optoelectronic Systems and Photonics Devices
- RF Circuit Design
- Power Electronics
- Semiconductor Radiation Detectors
- FPGA & Microcontroller System Design
- Biochip and Electronics Design for Biomedical Instrumentation

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

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

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

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