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Masters Degrees (Operating Systems)

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

The MSc in High Performance and Scientific Computing is for you if you are a graduate in a scientific or engineering discipline and want to specialise in applications of High Performance computing in your chosen scientific area. During your studies in High Performance and Scientific Computing you will develop your computational and scientific knowledge and skills in tandem helping emphasise their inter-dependence.

On the course in High Performance and Scientific Computing you will develop a solid knowledge base of high performance computing tools and concepts with a flexibility in terms of techniques and applications. As s student of the MSc High Performance and Scientific Computing you will take core computational modules in addition to specialising in high performance computing applications in a scientific discipline that defines the route you have chosen (Biosciences, Computer Science, Geography or Physics). You will also be encouraged to take at least one module in a related discipline.

Modules of High Performance and Scientific Computing MSc

The modules you study on the High Performance and Scientific Computing MSc depend on the route you choose and routes are as follows:

Biosciences route (High Performance and Scientific Computing MSc):

Graphics Processor Programming

High Performance Computing in C/C++

Operating Systems and Architectures

Software Testing

Programming in C/C++

Conservation of Aquatic Resources or Environmental Impact Assessment

Ecosystems

Research Project in Environmental Biology

+ 10 credits from optional modules

Computer Science route (High Performance and Scientific Computing MSc):

Graphics Processor Programming

High Performance Computing in C/C++

Operating Systems and Architectures

Software Testing

Programming in C/C++

Partial Differential Equations

Numerics of ODEs and PDEs

Software Engineering

Data Visualization

MSc Project

+ 30 credits from optional modules

Geography route (High Performance and Scientific Computing MSc):

Graphics Processor Programming

High Performance Computing in C/C++

Operating Systems and Architectures

Software Testing

Programming in C/C++

Partial Differential Equations

Numerics of ODEs and PDEs

Modelling Earth Systems or Satellite Remote Sensing or Climate Change – Past, Present and Future or Geographical Information Systems

Research Project

+ 10 credits from optional modules

Physics route (High Performance and Scientific Computing MSc):

Graphics Processor Programming

High Performance Computing in C/C++

Operating Systems and Architectures

Software Testing

Programming in C/C++

Partial Differential Equations

Numerics of ODEs and PDEs

Monte Carlo Methods

Quantum Information Processing

Phase Transitions and Critical Phenomena

Physics Project

+ 20 credits from optional modules

Optional Modules (High Performance and Scientific Computing MSc):

Software Engineering

Data Visualization

Monte Carlo Methods

Quantum Information Processing

Phase Transitions and Critical Phenomena

Modelling Earth Systems

Satellite Remote Sensing

Climate Change – Past, Present and Future

Geographical Information Systems

Conservation of Aquatic Resources

Environmental Impact Assessment

Ecosystems

Facilities

Students of the High Performance and Scientific Computing programme will benefit from the Department that is well-resourced to support research. Swansea physics graduates are more fortunate than most, gaining unique insights into exciting cutting-edge areas of physics due to the specialized research interests of all the teaching staff. This combined with a great staff-student ratio enables individual supervision in advanced final year research projects. Projects range from superconductivity and nano-technology to superstring theory and anti-matter. The success of this programme is apparent in the large proportion of our M.Phys. students who seek to continue with postgraduate programmes in research.

Specialist equipment includes:

a low-energy positron beam with a highfield superconducting magnet for the study of positronium

a number of CW and pulsed laser systems

scanning tunnelling electron and nearfield optical microscopes

a Raman microscope

a 72 CPU parallel cluster

access to the IBM-built ‘Blue C’ Supercomputer at Swansea University and is part of the shared use of the teraflop QCDOC facility based in Edinburgh

The Physics laboratories and teaching rooms were refurbished during 2012 and were officially opened by Professor Lyn Evans, Project Leader of the Large Hadron Collider at CERN. This major refurbishment was made possible through the University’s capital programme, the College of Science, and a generous bequest made to the Physics Department by Dr Gething Morgan Lewis FRSE, an eminent physicist who grew up in Ystalyfera in the Swansea Valley and was educated at Brecon College.



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The Systems Engineering Management MSc has been specifically designed for the needs of engineering professionals working in the field of complex systems development. Read more
The Systems Engineering Management MSc has been specifically designed for the needs of engineering professionals working in the field of complex systems development. The programme encompasses not only the technical tools and approaches needed to build success in this area, but also the management dimension of the relevant processes.

Degree information

Students gain an integrated, interdisciplinary view of complex systems and an advanced understanding of the systems engineering process. They gain the ability to apply this process to a variety of real world situations and the management skills necessary to facilitate the development of complex systems on time and within budget.

Students undertake modules to the value of 180 credits.

The programme consists of four core taught modules (60 credits) two optional taught modules (30 credits) and three research modules (90 credits). Modules are generally taught as intensive five-day 'block weeks' to minimise time away from the office.

A Postgraduate Diploma (120 credits, full-time nine months, or flexible study up to five years) is offered. A Postgraduate Certificate (60 credits, full-time 12 weeks, or flexible study up to two years) is offered.

Core modules
-Systems Engineering Management
-Lifecycle Management
-Risk, Reliability, Resilience
-The Business Environment

Optional modules
-Defence Systems
-Environmental Systems*
-Project Management
-Rail Systems
-Spacecraft Systems
-Systems Design
-Systems, Society, Sustainability*

*These modules are delivered by UCL's Department of Civil, Environmental and Geomatic Engineering in ten half-day sessions over the course of a term instead of the usual intensive 'block week' format

Research modules - all MSc students undertake a structured research programme comprising the following mandatory modules:
-Systems Engineering in Practice (15 credits)
-Systems Engineering Project Concept (15 credits)
-Systems Engineering Research Project (60 credits)

Teaching and learning
The programme is delivered through a combination of lectures, discussion sessions, workshop activity, and project work. Each taught course will be separately assessed through a combination of course work and a written examination. The project will be assessed through written dissertation and subsequent oral examination.

Careers

Complex systems are commonplace in many branches of UK industry including rail, aerospace, defence, and manufacturing. The ability to create such systems effectively is crucial to the competitiveness of these industries and has a direct bearing on the wealth of the nation.

Recent graduates of the programme have the following careers:
-London Underground: Head of Railway Systems
-Accenture: Analyst
-Thales Aerospace: Design Authority Manager
-BAE Systems: Systems Design Authority
-Selex Sensors and Airborne Management: Engineering Lead
-Xerox: Engineering Manager
-QinetiQ: Marine Engineer
-BAE Systems: Senior Hardware Engineer
-British Aerospace: Software Engineer
-Orange: Principal Engineer
-Halcrow Group Limited: Design Manager

Top career destinations for this degree:
-Software Engineer, Bank of America Merrill Lynch
-Analyst, Accenture
-Proposals engineer, Invensys PLC
-Engineering Manager, BAE Systems
-Systems Engineer, BIG

Why study this degree at UCL?

This MSc combines academic rigour with the practical expertise exemplified by our collaborators in UK industry and government. The flexible programme enables participants to structure their studies to suit their own career goals, and is accredited by the IET as a programme of further learning for registration as a Chartered Engineer.

Lectures are presented by experts in the field, many of whom have engaged in the practice of systems engineering in industry.

Industry is operating in an environment where technology changes rapidly, and where global competition grows ever more intensive. The challenge to remain competitive means we must make the right thing at the right price. Our MSc equips graduates with the skills to meet this challenge.

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The 1-year Electrical Power Systems Masters/MSc is good, the 2-year Electrical Power Systems with Advanced Research Masters/MSc is even better!. Read more
The 1-year Electrical Power Systems Masters/MSc is good, the 2-year Electrical Power Systems with Advanced Research Masters/MSc is even better!

The 3rd energy industry revolution is taking place where the key is the development of electrical power systems in the contexts of smart grids. Electrical power systems are playing a pivotal role in the development of a sustainable energy supply, enabling renewable energy generation. Globally there is a big shortage of skilled engineers for designing, operating, controlling and the economic analysis of future electricity networks – smart grids

The new 2-year MSc Electrical Power Systems with Advanced Research will give you the timely advanced skills and specialist experience required to significantly enhance your career in the electrical power industry. The programme builds on a very close involvement with the power industry, the education of power engineers and extensive research work and expertise as well as the successful experience on the 1-year MSc Electrical Power Systems at the University of Birmingham. The 2-year MSc Electrical Power Systems with Advanced Research will be able to fill in the gap of skills between the 1-year MSc and PhD research.

Some modules will be taught by leading industry experts, which will give you the exciting opportunity to understand the real challenges that power industry is facing, hence propose innovative solutions. In addition, students working on relevant MSc projects may have the opportunity to work with leading industry experts directly.

The new 2-Year MSc Electrical Power Systems with Advanced Research will run in parallel with the existing 1-Year MSc Electrical Power Systems. The taught credits in the 1st year of the 2 Year MSc are identical to that of the 1-Year MSc while the 2nd Year is mainly focused on a research project.

This programme also aims to provide graduates with the ability to critically evaluate methodologies, analytical procedures and advanced research methods. Year 1 of the programme is focussed on the taught modules covering:

Control concepts and methods
Advanced energy conversion systems and power electronic applications
Advanced power electronic technologies for electrical power networks – HVDC and FACTS
Electrical power system engineering - using state-of-the-art computational tools and methods, and design of sustainable electrical power systems and networks
Economic analysis of electrical power systems and electricity markets.
While Year 2 of the programme will give you the opportunity to work on an advanced research project. For some suitable projects, in conjunction with joint industry supervisions, industry placement may be available.

It is envisaged there will be the opportunity for students to transfer between the two programmes using the University’s procedures for transfers between programmes, subject to programme requirements. This opportunity would take place at the end of the taught part of the programme.

About the School of Electronic, Electrical & Systems Engineering

Electronic, Electrical and Systems Engineering, is an exceptionally broad subject. It sits between Mathematics, Physics, Computer Science, Psychology, Materials Science, Education, Biological and Medical Sciences, with interfaces to many other areas of engineering such as transportation systems, renewable energy systems and the built environment.
Our students study in modern, purpose built and up to date facilities in the Gisbert Kapp building, which houses dedicated state-of-theart teaching and research facilities. The Department has a strong commitment to interdisciplinary research and boasts an annual research fund of more than £4 million a year. This means that wherever your interest lies, you can be sure you’ll be taught by experts in the field.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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Renewable energy and cutting carbon emissions now top the global environmental agenda. This programme addresses the fundamentals of renewable energy and shows how solar, wind and other such energy sources can be efficiently integrated into practical power systems. Read more

Renewable energy and cutting carbon emissions now top the global environmental agenda. This programme addresses the fundamentals of renewable energy and shows how solar, wind and other such energy sources can be efficiently integrated into practical power systems.

You’ll study core power engineering topics such as power electronic converters, machines and control alongside modules specific to renewable energy sources, on topics like power system modelling, analysis and power converters.

At the same time, you’ll study a unique set of modules on the efficient generation of electricity from solar and wind power, as well as integrating renewable generators into micro-grids, with stability analysis and active power management. Power electronics design is covered in depth, including conventional and emerging converter topologies and advances in semiconductor power devices.

You’ll be prepared to meet the renewable energy challenges of the 21st century in a wide range of careers.

School of Electronic and Electrical Engineering

Our School is an exciting and stimulating environment where you’ll learn from leading researchers in specialist facilities. These include our Keysight Technologies wireless communications lab, as well as labs for embedded systems, power electronics and drives.

Depending on your choice of research project, you may also have access to our labs in ultrasound and bioelectronics or our Terahertz photonics lab, class 100 semiconductor cleanroom, traffic generators and analysers, FPGA development tools, sensor network test beds. We have facilities for electron-beam lithography and ceramic circuit fabrication – and a III-V semiconductor molecular beam epitaxy facility.

Accreditation

This course is accredited by the Institution of Engineering and Technology (IET) under licence from the UK regulator, the Engineering Council.

Course content

Core modules that run throughout the year will allow you to take part in different lab-based projects and explore different forms of renewable energy as well as how they can be integrated into electricity systems. You’ll also consider how renewable source-powered generations can be integrated into the grid and analysis and design of control systems.

To build your understanding of the global electronics industry, you’ll also complete a dissertation. This could take the form of a business, manufacturing or outsourcing plan, a proposal for research funding or an essay on a specific aspect of the industry.

You’ll complete your studies with three optional modules, selecting one from each of three pairs that cover different topics. If you have no experience of c-programming you’ll take a module that develops those skills, or another focusing on software development. You’ll choose between Power Electronics and Drives and Electric Drives and take another module from Energy Management and Conservation and Energy in Buildings.

Over the summer months you’ll also work on your research project. This gives you the chance to work as an integral part of one of our active research groups, focusing on a specialist topic in power electronics, power engineering and control and selecting the appropriate research methods.

Want to find out more about your modules?

Take a look at the Electrical Engineering and Renewable Energy Systems module descriptions for more detail on what you will study.

Course structure

Compulsory modules

  • Industry Dissertation 15 credits
  • Mini Projects and Laboratory 15 credits
  • Grid-Connected Microgeneration Systems 15 credits
  • Micro-grid Laboratory 15 credits
  • Electric Power Generation by Renewable Sources 15 credits
  • Control Systems Design 15 credits
  • Main Project 45 credits

Optional modules

  • Energy Management and Conservation 15 credits
  • Micro- and Nano-Electromechanical Systems 15 credits
  • Power Electronics and Drives 15 credits
  • Electric Drives 15 credits
  • Programming 15 credits
  • Software Development 15 credits

For more information on typical modules, read Electrical Engineering and Renewable Energy Systems MSc(Eng) in the course catalogue

Learning and teaching

Our groundbreaking research feeds directly into teaching, and you’ll have regular contact with staff who are at the forefront of their disciplines. You’ll have regular contact with them through lectures, seminars, tutorials, small group work and project meetings. Independent study is also important to the programme, as you develop your problem-solving and research skills as well as your subject knowledge.

Assessment

You’ll be assessed using a range of techniques including case studies, technical reports, presentations, in-class tests, assignments and exams. Optional modules may also use alternative assessment methods.

Projects

The research project is one of the most satisfying elements of this course. It allows you to apply what you’ve learned to a piece of research focusing on a real-world problem, and it can be used to explore and develop your specific interests.

Recent projects by students on this programme have included:

  • Power Flow Control of a Distribution Network using FACTS Devices
  • Module Integrated Converters for Photovoltaic Energy Systems
  • Modelling and Control of Parallel Connected Inverters
  • Power Regulation in the Power System using an Energy Storage Device
  • Application of Current Source Converters to Power Flow Control in a Power System
  • Control of a Renewable Energy System based Microgrid having an Energy Storage System as Backup
  • Control of a Grid Connected Wind Energy System under Abnormal Operating Conditions
  • DC-AC Inverter for grid-side connection of an induction generator
  • Modelling and control of a DC motor simulating a wind turbine

Career opportunities

Renewable energy and efficient power conversion systems are of immense importance worldwide and graduates of this course can expect to find jobs in a wide variety of industries including the electronics, automotive, transport, construction, industrial automation, power utility, energy, oil and environmental sectors.

You’ll be well-placed to develop practical solutions to the problem of integrating renewable energy systems into established electricity distribution networks. You should be able to contribute to strategic planning, systems implementation and operation of sustainable power generation systems.

This programme is also excellent preparation for PhD study. 



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Learn how to identify new and existing cyber threats and determine methods and processes to minimise attacks. Gain skills in a real-life business context, by cracking passwords and wireless networks and testing web applications for vulnerabilities and security breaches. Read more
Learn how to identify new and existing cyber threats and determine methods and processes to minimise attacks. Gain skills in a real-life business context, by cracking passwords and wireless networks and testing web applications for vulnerabilities and security breaches.

Cyber security is a priority for governments and organisations throughout the world. We’ll work together to explore how organisations and individuals can take action to protect themselves online from cyber-attacks.

We’ll begin by understanding networks and operating systems, how they work and the strengths and weaknesses of them. You’ll then think like a hacker, working from the inside out, as you recognise the threats to an organisation and its resources, and learn to implement and test secure systems.

Focusing on the strategic deployment and implementation of cyber security within an organisation, you’ll cover all aspects of cyber security including network security, computer security and information security.

You’ll apply your knowledge and skills hands-on in a real-life context, in our specialised lab, which is already equipped with tools such as Kali LInux, Wireshark, Nmap and Burp Suite. You’ll write your own Metasploit modules, automate social-engineering attacks, bypass antivirus software and turn access to one machine as you take total control of the enterprise.

You’ll gain skills in communicating information to higher levels of the corporation’s managers, giving you confidence to present your invaluable problem solving solutions and strategic security planning in any organisation.

We know there’s a worldwide shortage of skills graduates in cyber security, so you’ll be ahead of the game as you further your career and make a real impact on a society that is increasingly dependent on the internet and IT technology.

See the website http://www.anglia.ac.uk/study/postgraduate/cyber-security

Careers

The 2015 Global Information Security Workforce Study predicts that the global cyber security workforce shortage will reach 1.5 million by 2020, as demand outstrips supply. This means that there hasn't been a better time to join the cyber security sector.

Computer security is a fast developing area and your skills in computer, network and information security could see you working closely with lawyers, government, commercial organisations, the education sector and investigation agencies, as well as the finance and e-commerce sectors and national security organisations.

You’re also in the perfect position to continue your academic career and move up to our research degree Computer Science PhD.

Modules & assessment

Computer Networks
Operating Systems and Virtualisation
Secure Systems
Research Methods
Advanced Network Security Principles
Penetration Testing
Major Project

Assessment

We’ll asses your knowledge and understanding through a case study in which you’ll design, implement and test the security strategy of an organisation. You’ll also complete in-class tests, written assignments, software projects and presentations as part of the course.

Your faculty

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

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

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

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Computer Science Departmental degree requirements for the master’s degree, which are in addition to those established by the College of Engineering and the Graduate School (http://graduate.ua.edu/), are as follows for Plan I and Plan II students. Read more
Computer Science Departmental degree requirements for the master’s degree, which are in addition to those established by the College of Engineering and the Graduate School (http://graduate.ua.edu/), are as follows for Plan I and Plan II students.

- Master of Science–Thesis Option (http://cs.ua.edu/graduate/ms-program/#thesis)
- Master of Science–Non-Thesis Option (http://cs.ua.edu/graduate/ms-program/#nonthesis)
- Timetable for the Submission of Graduate School Forms for an MS Degree (http://cs.ua.edu/graduate/ms-program/#timetable)

Visit the website http://cs.ua.edu/graduate/ms-program/

MASTER OF SCIENCE–THESIS OPTION (PLAN I):

30 CREDIT HOURS
Each candidate must earn a minimum of 24 semester hours of credit for coursework, plus a 6-hour thesis under the direction of a faculty member. Unlike the general College of Engineering requirements, graduate credit may not be obtained for courses at the 400-level.

Degree Requirements Effective Fall 2011

Credit Hours
The student must successfully complete 30 total credit hours, as follows:

- 24 hours of CS graduate-level course work

- 6 hours of CS 599 Master’s Thesis Research: Thesis Research.

- Completion of at least one 500-level or 600-level course in each of the four core areas (applications, software, systems and theory). These courses must be taken within the department and selected from the following:
Applications: CS 528, CS 535, CS 557, CS 560, CS 609, CS 615
Software: CS 503, CS 507, CS 515, CS 516, CS 534, CS 600, CS 603, CS 607, CS 614, CS 630
Systems: CS 526, CS 538, CS 567, CS 606, CS 613, CS 618
Theory: CS 500, CS 570, CS 575, CS 601, CS 602, CS 612

- No more than 12 hours from CS 511, CS 512, CS 591, CS 592, CS 691, CS 692 and non-CS courses may be counted towards the coursework requirements for the master’s degree. Courses taken outside of CS are subject to the approval of the student’s advisor.

- Additional Requirements -

- The student will select a thesis advisor and a thesis committee. The committee must contain at least four members, including the thesis advisor. At least two members are faculty of the Computer Science department, and at least one member must be from outside the Department of Computer Science.

- The student will develop a written research proposal. This should contain an introduction to the research area, a review of relevant literature in the area, a description of problems to be investigated, an identification of basic goals and objectives of the research, a methodology and timetable for approaching the research, and an extensive bibliography.

- The student will deliver an oral presentation of the research proposal, which is followed by a question-and-answer session that is open to all faculty members and which covers topics related directly or indirectly to the research area. The student’s committee will determine whether the proposal is acceptable based upon both the written and oral presentations.

- The student will develop a written thesis that demonstrates that the student has performed original research that makes a definite contribution to current knowledge. Its format and content must be acceptable to both the student’s committee and the Graduate School.

- The student will defend the written thesis. The defense includes an oral presentation of the thesis research, followed by a question-and-answer session. The student’s committee will determine whether the defense is acceptable.

- The student will complete an oral comprehensive exam. This exam is scheduled with the Department Head prior to the semester in which the student intends to graduate.

- Other requirements may be specified by the Graduate School (http://graduate.ua.edu/) and by the College of Engineering.

Degree Requirements Prior to Fall 2011

Credit hours

The student must successfully complete 30 total credit hours, as follows:

- 6 hours of CS 599 Master’s Thesis Research

- 24 hours of CS graduate-level course work with a grade of A or B, including the following courses completed at The University of Alabama:
At least 3 hours of theory courses (CS 500 Discrete math, CS 601 Algorithms, CS 602 Formal languages, CS 612 Data structures)

At least 3 hours of software courses (CS 600 Software engineering, CS 603 Programming languages, CS 607 Human-computer interaction, CS 614 Compilers, CS630 Empirical Software Engineering)

At least 3 hours of systems courses (CS 567 Computer architecture, CS 606 Operating systems, CS 613 Networks, CS 618 Wireless networks)

At least 3 hours of applications courses (CS 535 Graphics, CS 560 or 591 Robotics, CS 591 Security, CS 609 Databases)

- Additional Requirements -

- The student will select a thesis advisor and a thesis committee. The committee must contain at least four members, including the thesis advisor. At least two members are faculty of the Computer Science department, and at least one member must be from outside the Department of Computer Science.

- The student will develop a written research proposal. This should contain an introduction to the research area, a review of relevant literature in the area, a description of problems to be investigated, an identification of basic goals and objectives of the research, a methodology and timetable for approaching the research, and an extensive bibliography.

- The student will deliver an oral presentation of the research proposal, which is followed by a question-and-answer session that is open to all faculty members and which covers topics related directly or indirectly to the research area. The student’s committee will determine whether the proposal is acceptable based upon both the written and oral presentations.

- The student will develop a written thesis that demonstrates that the student has performed original research that makes a definite contribution to current knowledge. Its format and content must be acceptable to both the student’s committee and the Graduate School.

- The student will defend the written thesis. The defense includes an oral presentation of the thesis research, followed by a question-and-answer session. The student’s committee will determine whether the defense is acceptable.

- The student will complete an oral comprehensive exam. This exam is scheduled with the Department Head prior to the semester in which the student intends to graduate.

- Other requirements may be specified by the Graduate School (http://graduate.ua.edu/) and by the College of Engineering.

MASTER OF SCIENCE–NON-THESIS OPTION (PLAN II):

30 CREDIT HOURS
Each candidate must earn a minimum of 30 semester hours of credit for coursework, which may include a 3-hour non-thesis project under the direction of a faculty member. Unlike the general College of Engineering requirements, graduate credit may not be obtained for courses at the 400-level.

Degree Requirements Effective Fall 2011

The student must successfully complete 30 total credit hours, as follows:

- Completion of at least one 500-level or 600-level course in each of the four core areas (applications, software, systems and theory).
Applications: CS 528, CS 535, CS 557, CS 560, CS 609, CS 615
Software: CS 503, CS 507, CS 515, CS 516, CS 534, CS 600, CS 603, CS 607, CS 614, CS 630
Systems: CS 526, CS 538, CS 567, CS 606, CS 613, CS 618
Theory: CS 500, CS 570, CS 575, CS 601, CS 602, CS 612

- No more than 12 hours from CS 511, CS 512, CS 591, CS 592, CS 691, CS 692 and non-CS courses may be counted towards the coursework requirements for the master’s degree. Courses taken outside of CS are subject to the approval of the student’s advisor.

- The student may elect to replace 3 hours of course work with 3 hours of CS 598 Research Not Related to Thesis: Non-thesis Project. This course should be proposed in writing in advance, approved by the instructor, and a copy placed in the student’s file. The proposal should specify both the course content and the specific deliverables that will be evaluated to determine the course grade.

- Additional Requirements -

- The student will complete an oral comprehensive exam. This exam is scheduled with the Department Head prior to the semester in which the student intends to graduate.

- Other requirements may be specified by the Graduate School and by the College of Engineering.

Degree Requirements Prior to Fall 2011

Credit hours

The student must successfully complete 30 total credit hours of CS graduate-level course work with a grade of A or B, as follows:

- The following courses will be completed at The University of Alabama:
At least 3 hours of theory courses (CS 500 Discrete math, CS 601 Algorithms, CS 602 Formal languages, CS 612 Data structures)

At least 3 hours of software courses (CS 600 Software engineering, CS 603 Programming languages, CS 607 Human-computer interaction, CS 614 Compilers, CS630 Empirical Software Engineering)

At least 3 hours of systems courses (CS 567 Computer architecture, CS 606 Operating systems, CS 613 Networks, CS 618 Wireless networks)

At least 3 hours of applications courses (CS 535 Graphics, CS 560 or 591 Robotics, CS 591 Security, CS 609 Databases)

- The student may elect to replace 3 hours of course work with 3 hours of CS 598 Research Not Related to Thesis: Non-thesis Project. This course should be proposed in writing in advance, approved by the instructor, and a copy placed in the student’s file. The proposal should specify both the course content and the specific deliverables that will be evaluated to determine the course grade.

- Additional Requirements -

- The student will complete an oral comprehensive exam. This exam is scheduled with the Department Head prior to the semester in which the student intends to graduate.

- Other requirements may be specified by the Graduate School and by the College of Engineering.

TIMETABLE FOR THE SUBMISSION OF GRADUATE SCHOOL FORMS FOR AN MS DEGREE
This document identifies a timetable for the submission of all Graduate School paperwork associated with the completion of an M.S. degree

- For students in Plan I students only (thesis option) after a successful thesis proposal defense, you should submit the Appointment/Change of a Masters Thesis Committee form

- The semester before, or no later than the first week in the semester in which you plan to graduate, you should “Apply for Graduation” online in myBama.

- In the semester in which you apply for graduation, the Graduate Program Director will contact you about the Comprehensive Exam.

Find out how to apply here - http://graduate.ua.edu/prospects/application/

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Are you excited by the impact of technology on our everyday lives and are keen to forge a successful career in the field? From day one, you will be immersed in an exciting, innovative environment where you will develop broad knowledge and skills in the main areas of computing and information technology which will be directly relatable to your future career. Read more
Are you excited by the impact of technology on our everyday lives and are keen to forge a successful career in the field? From day one, you will be immersed in an exciting, innovative environment where you will develop broad knowledge and skills in the main areas of computing and information technology which will be directly relatable to your future career.

You will take core modules covering areas of computing in programming, databases, systems analysis and design, and computer networks and web development. Designed in consultation with partners from industry, you will develop the most up-to-date computing knowledge, desired by employers across the industry.

This course fully meets the educational requirements for BCS Chartered IT Professional registration.

This course has several available starts and study options - for more information, please view the relevant web-page:
16 months full time - https://www.northumbria.ac.uk/study-at-northumbria/courses/computing-and-information-technology-dtfcin6/

Part time study - https://www.northumbria.ac.uk/study-at-northumbria/courses/computing-and-information-technology-dtpcin6/

3 years distance learning - https://www.northumbria.ac.uk/study-at-northumbria/courses/computing-and-information-technology-dtdciy6/

Learn From The Best

You will be taught by a range of academic staff who bring a wealth of professional experience. They are experts in specialist areas such as Strategic Management, Computer Science and Web Based Information Retrieval.

In a dynamic learning environment with an expert team of staff, you will be taught theoretical and practical research skills such as information literacy, as well as problem solving skills, self-directed learning and communication skills.

Teaching And Assessment

On this course, you will have the opportunity to independently research topics to deepen your learning and understanding, while learning the skills to communicate your research and investigations.

Assessment methods will include reports, presentations, individual, group and project work, alongside regular feedback on your summative assessment.

Module Overview
KC7013 - Database Modelling (Core, 20 Credits)
KF7010 - Programme Design & Implementation (Core, 20 Credits)
KF7011 - Systems Analysis & Design with UML (Core, 20 Credits)
KF7013 - Website Development and Deployment (Core, 20 Credits)
KF7023 - Computer Networks & Operating Systems (Core, 20 Credits)
KF7028 - Research Methods and Project Management (Core, 20 Credits)
KF7029 - MSc Computer Science & Digital Technologies Project (Core, 60 Credits)

Learning Environment

Throughout the duration of your course you will have access to our state-of-the-art facilities including our dedicated computing suite, Pandon Basement.

Pandon Basement houses specialist facilities and studios with industry-standard software.

You will also have access to dedicated computing areas, which can be used during free periods and into the evenings and weekends.

When you want to get hands-on with technology our range of specialist facilities will support you.

You will also have access to the University’s award winning library (online and on campus). The library achieved the second highest score in the UK in the Times Higher Student Satisfaction Survey 2015.

Research-Rich Learning

You will be immersed in a research-rich environment supported by our rapidly expanding Computer Science and Information Science Research Groups.

Northumbria’s BCS-accredited MSc has been designed to ensure you learn the most up-to-date computing knowledge required by employers across the industry. We offer research-informed teaching, industry-standard software and a strong community of like-minded students.”

You will be taught by staff with a strong academic background in areas such as Web Programming who promote innovative and excellent learning and teaching practice.

You will develop an understanding of important research methods and approaches which could be directly applicable to the demands of your future career.

Give Your Career An Edge

Industry practice has strongly influenced the design of the programme to give you the computing knowledge to work within a variety of roles in the sector.

Learning independently, working collaboratively on projects, evaluating and reflecting upon practitioner experience, are all essential skills of the computing profession. Your modules will enable you to do all of this and more as you develop the qualities needed for a career in computing.

This programme will prepare you to meet the educational requirements for BCS, the Chartered Institute for IT, Chartered IT Professional (CITP) registration.

Your Future

Upon graduating from this course, you will have an in-depth knowledge and critical understanding of the main areas of Computing and Information Technology, including the key areas of systems analysis, systems development, operating systems, networking, databases and the internet .

We place a real emphasis on developing the transferable skills that will open doors to a range of careers. These include communication, analytical and problem solving skills, technical skills and the ability to work independently and as part of a team.

Graduates are expected to work in a number of career opportunities across a wide range of computer areas including software engineering, systems analysis and design, computer networks, database development and management, software testing and project management.

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Forensic information technology (FIT) is the scientific use or application of information technology (IT) in the generation and presentation of digital evidence to be used in courts, legal or other formal proceedings. Read more

Why take this course?

Forensic information technology (FIT) is the scientific use or application of information technology (IT) in the generation and presentation of digital evidence to be used in courts, legal or other formal proceedings.

This course will enable you to develop your understanding and application of security issues and cybercrime for the purpose of forensic computing and investigation.

What will I experience?

On this course you can:

Learn how to investigate hacking, fraud and deception using a range of digital forensic tools
Practise identifying intruders' trails and suspected inappropriate use of internet applications in order to compile scientific evidence to prosecute
Manage a real-life computer engineering project using appropriate techniques for writing and reasoning about security policies

What opportunities might it lead to?

Many police investigations or civil disputes involve investigation of computer systems, mobile phones or other information devices, and there are an increasing number of UK companies that undertake investigations as consultants. You can expect to find career opportunities in such companies as well as in law enforcement and other services.

Accredited by BCS, The Chartered Institute for IT for the purposes of fully meeting the further learning academic requirement for registration as a Chartered IT Professional (CITP). This course also partially meets the academic requirement for registration, either as a Chartered Scientist (CSci) or (on behalf of the Engineering Council) as a Chartered Engineer (CEng)*.

*On condition that the Master's Engineering Project is successfully completed.

Module Details

You will study four key topics which will collaboratively develop your knowledge and ability to carry out forensic IT investigations as well as an introduction on how to build protected specification software for data and other web applications. You will also get to build your own test system as part of your final project.

Here are the units you will study:

Computer Forensic Investigation and Cryptography: This unit covers the practical aspects of conducting a forensic investigation of digital evidence. In order for the students to develop a critical understanding of computer forensics, a holistic approach of the forensics investigation process is adopted, with a full investigation ‘life cycle’ from seizure of evidence through to giving evidence in court as an expert witness. We look at a range of tools, operating systems and devices.

Computer Security: The unit provides an introduction to computer security concepts and their practical application, in both closed and interconnected networks. Students are expected to both understand and be able to critically evaluate different approaches to securing complex computer systems.

Cybercrime Security and Risk Management: This unit provides opportunities for participants to develop skills and knowledge in the understanding of corporate cyber threats. Drawing upon a range of practical examples, students will examine how rapid technological development and expansion in access to the internet has impacted upon crime (e.g. how anonymity and unfounded trust encourage deception), mapping out the terrain of information technology, and identifying the emerging areas of cyber crime. Areas explored will include the crossing of established boundaries into spaces over which control has already been established such as cyber-intrusion and cyber-theft, but also 'new cyber crimes' in the form of virtual trespass, Denial of Service attacks, and the development of opportunities for offending in the context of social networking websites.

Master's Project: You will undertake either an engineering unit or a study project, during the summer period. The project offers students the opportunity to apply the taught material in the solution of a real-world problem directly related to their course. The engineering project usually involves building a piece of software to solve a problem. An example of the sort of thing you might do would be building a tool to address a specific forensics requirement. The study project usually involves undertaking a study of an IT domain relevant to forensics. To prepare for this the project includes a number of preparatory sessions, which contribute to part of your final mark.

Specialist optional units include:

Systems, Security and Data Analysis: The first part of the unit provides an overview of computer organisation, operating systems and network design, with a strong focus on security considerations and aspects relevant to computer and digital forensics. The early part of the unit will provide an introduction to relevant issues in system architecture and file system organisation. Threats to computer systems will be considered. The first half of the unit is concluded with studying in some depth current technologies for securing real computer networks. The second part of the unit deals with the important topic of data analytics.

Advanced Programming Skills for the Web: This unit draws together a number of system development skills, focusing on how they can be applied to the development specifically of web applications. Topics covered include web programming, connecting databases to web applications, software tools, testing and security.

Programme Assessment

You will be taught through a combination of practical exercises, simulations, lectures, guest lectures and formative assessments, and will be expected to use a wide range of on and offline learning tools.

You will encounter a range of assessment styles depending on the content and nature of the unit topic. This can include written assignments, presentations as well as group and individual lab-based assessments. However, the most significant assessment element is the final dissertation, which reports and reflects on your final project.

Student Destinations

On completing this course, you will be equipped to seek employment in the following areas: IT auditing, information security, independent investigation, Computer Emergency Response Teams (CERT) and law enforcement agencies. Some of our previous graduates have been successful in finding employment within high-tech crime units, commercial investigation and national security bodies, while others go on to further research study at PhD level.

This course will also appeal to already practising professionals in related areas such as law enforcement, system administration, corporate security, IS auditing or security analysis and management for the commercial sector.

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​This broad programme enables students to develop their skills in a range of computing areas. Read more

Course Overview

​This broad programme enables students to develop their skills in a range of computing areas. Graduates of this programme will have detailed knowledge of the state of the art in computing ranging from requirements engineering and programming through to developments in computer architecture and operating systems.​

See the website https://www.cardiffmet.ac.uk/management/courses/Pages/Computing---MSc.aspx

​Course Content​

The programme has nine taught modules:

Four foundational 10 credit modules:​​
- Technology Adoption
- Technology Project Management
- Legal Applications in Technology
- Team Software Development Project

Four specialist 20 credit modules:
- Requirements Engineering
- Object-Oriented Programming
- Architectures and Operating Systems
- Plus one option from the MSc Mobile Technologies programme​​

​In addition, one 20 credit module, 'Research Methods for Technology Dissertations' is undertaken in preparation for the self-managed element.

120 credits from these may result in the award of PgD; 60 credits from these may result in the award of PgC. The MSc requires all nine modules and completion of a 40 credit project.

Modules are delivered through lectures, tutorials, practical workshops and invited speakers.

Employability & Careers​

This programme is broad in scope, enabling a student to enhance their existing skills in anticipation of meeting the increasing commercial demand for advanced computing graduates.​​​

Find information on Scholarships here https://www.cardiffmet.ac.uk/scholarships

Find out how to apply here https://www.cardiffmet.ac.uk/howtoapply

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The Department of Computer Science at Binghamton University aims to provide all graduates with a strong foundation in computer science while also offering the opportunity to pursue specific interests within computer science and/or interests in other disciplines. Read more
The Department of Computer Science at Binghamton University aims to provide all graduates with a strong foundation in computer science while also offering the opportunity to pursue specific interests within computer science and/or interests in other disciplines. The program provides students with an understanding of the theory and practice of automating the representation, storage and processing of information, while emphasizing experimental research to design and engineer a wide variety of computer and information systems.

The Master of Science in Computer Science (MSCS) is intended for students with a strong background in computer science and a desire to prepare for research studies or professional practice. If you have bachelor's degree in computer science or a related field, you're invited to apply for admission to our MSCS program.

The doctoral program leads to a PhD in Computer Science. Students admitted into the program typically have a master's degree in computer science or a closely related discipline. Students with a bachelor's degree and a strong academic record may also be directly admitted.

Recent doctoral graduates have gone on to careers in as software engineering at Intel, eBay, Cisco Systems, positions at Hewlett Packard, Microsoft, Twitter, Bloomberg, the Air Force Research Lab, and the U.S. Census. Academic placements include assistant professorships at California State University at Fullerton, Valdosta State University, and Harran University, Turkey.

The Master's program leads to a Master of Science in Computer Science. It is intended for students with a strong background in computer science and a desire to prepare for research studies or professional practice. Holders of the baccalaureate degree in computer science or a related field are invited to apply for admission to the MSCS program. Students whose undergraduate degree is not in computer science may be required to complete some preparatory work in addition to fulfilling the requirements listed below.
Program requirements include four core courses taken over the first two semesters of study. These courses are Computer Organization and Architecture, Operating Systems, Programming Languages and Design & Analysis of Computer Algorithms. Three graduating options are offered: a thesis option, a project option and a comprehensive exam. Beyond the 4 core courses, these options require students to complete 4, 5 and 6 elective courses, respectively, chosen from a broad set of courses offered by the Department.

Applicant Qualifications

- Undergraduate major in computer science or related field desirable for admission
- Applicants are additionally expected to have completed coursework in the following areas:
*Algorithms and data structures
*Computer organization and architecture
*Operating systems
*Programming languages
*Discrete mathematics

All applicants must submit the following:

- Online graduate degree application and application fee
- Transcripts from each college/university you have attended
- Two letters of recommendation (three letters of recommendation for PhD applicants)
- Personal statement (2-3 pages) describing your reasons for pursuing graduate study, your career aspirations, your special interests within your field, and any unusual features of your background that might need explanation or be of interest to your program's admissions committee.
- Resume or Curriculum Vitae (max. 2 pages)
- Official GRE scores

And, for international applicants:
- International Student Financial Statement form
- Official bank statement/proof of support
- Official TOEFL, IELTS, or PTE Academic scores

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The Computer Science program will introduce you to core areas of advanced computing architecture, advanced operating systems and theories and algorithms used in computing. Read more
The Computer Science program will introduce you to core areas of advanced computing architecture, advanced operating systems and theories and algorithms used in computing. You will conduct advanced research in software engineering, systems or artificial intelligence as you learn high-demand skills sought by industry.

Program Highlights

State-of-the-art computing facilities including the Integrated Engineering Science and Laboratory Facility (ISELF) Visualization Lab, Sunfire 280R running Solaris, several workstations running Windows and Linux and supercomputing facilities in the Twin Cities.
Five to seven graduate assistantship positions each year.
Research and project labs are equipped with Sun, Silicon Graphics and DEC Alpha workstations.
Program is offered on a part-time or full-time track.

Program Distinctions

Graduates have gone on to work for Amazon, Google, Guidant, Medtronics, IBM, Beckman Coulter and Thomson Reuters among others. They have also continued on to Ph.D. programs where they have been awarded assistantships.
Taught by 13 internationally-recognized faculty members.

Requirements and Details

The GRE is required.

A strong showing (more than 75th percentile) in the quantitative GRE score is essential.
A strong score in the verbal section is also important.
Admission is competitive.

Positive letters of recommendation are important, as is a solid undergraduate academic record.

Lack of a computer science background is usually not a major concern, since prerequisite courses are prescribed. However, a background in the sciences and mathematics is essential.

Admission decisions are made at specific times associated with the application deadlines, usually in the week following the deadlines.

A final admission decision may take up to three weeks to receive from the application deadline and up to ten weeks for I-20s to be issued to international students.

Fully-qualified applicants will have taken courses that cover the following topics:

Non-linear data structures: sorting and searching algorithms.
Computer architecture: hardware organization, I/O interface, interrupt mechanisms and pipeline processor design.
File systems; hashed indexed, ISAM files; B-trees; external sorting.
Programming languages: design and implementation.
Operating systems: process, memory and file system management, device handlers.
Finite mathematics and modern algebra.

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The course aims to provide students with the skills to design, implement and manage computer-based systems security, using software and networking technologies. Read more
The course aims to provide students with the skills to design, implement and manage computer-based systems security, using software and networking technologies. This title also includes the basic, key elements of forensic computing: forensics and the legal and ethical issues involved in any digital investigation.

Students will gain a broad understanding of the different levels of computer and network security together with the basic phases of a forensic investigation and of computing in general. They will examine wireless communication systems; networks; operating systems and interfacing socket programming; servers and their security implications; and the planning and implementation of network security management, including security, risk analysis and disaster recovery planning.

Non means-tested loans of up to a maximum of £10,000 will be available to postgraduate master’s students.

Features and benefits of the course

-The School has an extensive range of equipment in our own specialist laboratories which is supported by a dedicated team of technical staff.
-Research in the School was rated 'internationally excellent' with some rated 'world-leading' in the 2014 Research Excellence Framework (REF).
-Our online virtual learning platform Moodle, provides access to lectures, course materials and assessment information.
-Classes are concentrated on certain days of the week to facilitate part-time students’ attendance and allow full-time students to undertake part-time employment if necessary.
-The School of Computing, Mathematics and Digital Technology is a member of the Oracle Academy.
-We are an academic partner of the Institute of Information Security Professionals (IISP). This partner status recognises our expertise in the field of information and cyber security.
-We are also an Academy of the Computer Technology Industry Association (CompTIA) and deliver their partner programme which provides a pathway for students towards a rewarding, high-growth IT career.

About the Course

You will study advanced topics in computer networks and operating systems, focusing on principles, architectures and protocols used in modern large scale networked systems.

Cryptography and encryption studies cover classical cryptography, key encryption algorithms, how to code algorithms and their variants in a modern programming language and implement cryptosystems over a computer network.

You will develop skills to design and implement advanced security mechanisms in a network environment, considering in depth wired and wireless network security and the best practice in the field.

All course units combine with a flexible approach, which allows students to undertake practical project work while attending work placements. With one-third of the course project-based, it may be possible to undertake yours in collaboration with an external organisation or within the School.

The Masters project will involve practical system creation or experimentation work. Where appropriate, the implementation or experimentation may be work-based.

Assessment details

Assessment will be through coursework, examination and dissertation.

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The MSc in Electronics with Embedded Systems aims to produce postgraduates with an advanced level of understanding in the design of real-time embedded systems for time-critical, power sensitive applications. Read more
The MSc in Electronics with Embedded Systems aims to produce postgraduates with an advanced level of understanding in the design of real-time embedded systems for time-critical, power sensitive applications. Practical skillset development is emphasized throughout the course. Students will be taught the theory, protocol and the efficient use of both analogue and digital interfaces and sensor devices together with the principles of and use of Real-Time-Operating-Systems (RTOS). A key focus of the course will be in the implementation of power aware sustainable solutions, the course will provide an in-depth discussion of the underlying power management hardware sub-systems within modern MCUs and will show and use software techniques that will exploit these to reduce power consumption.

Broader consideration of embedded system design will be examined. In particular, the design process, risk assessment, product life-cycle, software life-cycle, safety and regulation will be investigated and used. It is intended that the course will re-focus existing knowledge held by the student in software engineering and hardware engineering and deliver a set of enhanced practical skills that will enable the student to fully participate in this multi-disciplined, fast expanding and dominating engineering sector of embedded systems.

Course Structure

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

The project counts for one third of the course and involves undertaking a substantial research or product development project. For part-time students, this can be linked to their employment. It is undertaken in two phases. In the first part, the project subject area is researched and a workplan developed. The second part involves the main research and development activity. In all, the project requires approximately 600 hours of work.

Further flexibility is provided within the structure of the courses in that you can study related topic areas by taking modules from other courses as options (pre-requisite knowledge and skills permitting).

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

MSc Electronics Suite of Courses

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

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

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

There are plenty of opportunities for employment in the electronic systems subject area, in particular, there is a demand for engineers that can solve problems requiring a multi-disciplined approach covering skills from software engineering, control engineering, digital electronic systems engineering, analogue electronic engineering, medical physics, and mechanics amongst others. The MSc in Electronics and its specialist pathways will provide the foundations required to re-focus existing knowledge and enter this exciting world of multi-disciplined jobs.

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

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The 3rd energy industry revolution is taking place where the key is the development of electrical power systems in the contexts of smart grids. Read more
The 3rd energy industry revolution is taking place where the key is the development of electrical power systems in the contexts of smart grids. Electrical power systems are playing a pivotal role in the development of a sustainable energy supply, enabling renewable energy generation. Globally there is a big shortage of skilled engineers for designing, operating, controlling and the economic analysis of future electricity networks – smart grids

The MSc Electrical Power Systems will give you the timely skills and specialist knowledge required to significantly enhance your career prospects in the electrical power industry. This programme will develop your power engineering skills through expert teaching and extensive research work undertaken in collaboration with power industry partners.

Some modules will be taught by leading industry experts, offering exciting opportunities to understand the real challenges that the power industry is facing and will work with you to develop and provide innovative solutions. In addition, students working on relevant MSc projects may have the opportunity to work with leading industry experts directly

This programme also aims to provide graduates with the ability to critically evaluate methodologies, analytical procedures and research methods in:

Control concepts and methods
Advanced energy conversion systems and power electronic applications
Advanced power electronic technologies for electrical power networks – HVDC and FACTS
Electrical power system engineering - using state-of-the-art computational tools and methods, and design of sustainable electrical power systems and networks;
Economic analysis of electrical power systems and electricity markets.

About the School of Electronic, Electrical & Systems Engineering

Electronic, Electrical and Systems Engineering, is an exceptionally broad subject. It sits between Mathematics, Physics, Computer Science, Psychology, Materials Science, Education, Biological and Medical Sciences, with interfaces to many other areas of engineering such as transportation systems, renewable energy systems and the built environment.
Our students study in modern, purpose built and up to date facilities in the Gisbert Kapp building, which houses dedicated state-of-theart teaching and research facilities. The Department has a strong commitment to interdisciplinary research and boasts an annual research fund of more than £4 million a year. This means that wherever your interest lies, you can be sure you’ll be taught by experts in the field.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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This is the distance learning version of the full time MSc in Renewable Energy Systems Technology. By using the same course materials distance learning students are able to achieve the same outcomes as the full-time MSc in Renewable Energy Systems Technology. Read more
This is the distance learning version of the full time MSc in Renewable Energy Systems Technology.

By using the same course materials distance learning students are able to achieve the same outcomes as the full-time MSc in Renewable Energy Systems Technology. We have developed new ways of learning, which offer students flexibility in place, pace and mode to meet the demand for this highly sought after qualification but who cannot attend traditional university classes.

By the end of the course, our renewable energy MSc graduates, will have gained a comprehensive understanding of renewable energy technologies and developed a range of important transferable
skills.

Core study areas include solar power, wind power, water power, biomass, sustainability and energy systems, integration of renewables and a research project.

Optional study areas include advanced solar thermal, advanced photovoltaics, energy storage, energy system investment and risk management.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/renewable-energy-system-tech-dl/

Programme modules

Compulsory Modules:
- Sustainability and Energy Systems
- Integration of Renewables
- Solar 1
- Wind 1
- Water Power
- Biomass
- Research Project

Optional Modules (choose three):
- Energy Storage
- Advanced Solar Thermal
- Advanced Photovoltaics
- Wind 2
- Energy System Investment and Risk Management

Normally students are required to obtain 180 Master's level credits in these modules to become a Master of Science in Renewable Energy Systems Technology graduate. However optional leave awards of Postgraduate Diploma (120 credits) or Postgraduate Certificate (60 credits) are possible.

How you will learn

All of our renewable energy MSc Modules consist of a series of Study Units, each covering a specific subject area (see programme modules). Instead of face-to-face lectures and tutorials, the main learning routes for distance learning students are via the University’s virtual learning environment (LEARN). The learning resources for each Study Unit include:
- On line study materials
- Live streamed and recorded lectures
- Virtual and remote laboratories
- Tutorials, assignments and computer aided assessments
- Access to past exam papers

In addition there are several important communication features built into LEARN which include:
- Discussion forums (for communicating with tutors and fellow learners)
- Specialist tutor groups
- Assignment and tutorial upload facility (to allow tutors to check your progress and provide you with feedback)
- Online tutorial sessions with module lectures

Distance learning students also have the option to attend on campus modules.

- Assessment
By examination, coursework, group work and research project. Examinations are held in January and May/June with coursework and group work throughout the programme. The individual MSc research project is assessed by written report and viva voce. Students receive regular feedback on their progress from on-line support officers, tutors and academic staff.

It is also possible for distance learning students to take exams at a suitable local venue either a local British council or a recognised university. For further information about this process please contact the course administrator.

- Technical Requirements
To make full use of distance learning resources, the following are minimum requirements:
- Good specification PC or laptop running the latest operating system
- A printer if you wish to print out materials
- Good computer skills (see below)
- Fast and reliable access to the Internet via Broadband

You will require the skills that allow one to:
- Open, copy, and move files and directories on your hard drive
- Move around the desktop with several applications (programmes) opened at the same time
- Create documents using a software package such as MS Word or similar.
- Be able to zip files and make pdf files
- Manipulate and analyse data using spread sheet software such as MS Excel

Careers and further study

The flexibility offered by this MSc allows graduates already working in or seeking to enter the sector, the opportunity to gain strong technical knowledge whilst continuing to work.This combination of knowledge and practical experience makes them highly attractive to existing and future employers worldwide.

Fees: Structure and scholarships

Unlike the full time course distance learning students pay as they study and will pay for modules prior to registration at the beginning of each semester. There are no additional registration fees.
However please note that distance learning fees are reviewed annually and may increase during your period of study.

Why choose electronic, electrical and systems engineering at Loughborough?

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

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

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

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

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

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

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/renewable-energy-system-tech-dl/

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