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Masters Degrees (Electrical Power)

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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.

Course details

Electrical Power Systems with Advanced Research Masters/MSc (Two Year): 

This 2-year MSc programme meets the industrial demand for the training and education of both existing and future engineers in the advanced concepts of electrical power systems and renewable energy as well as advanced research skills. It aims to produce graduates of the highest calibre with the right advanced skills and knowledge who will be capable of leading in teams involved in the operation, control, design, and economic analysis of the electrical power systems and networks of the future – smart grids as well as developing and managing R&D programmes.

It will meet the demand for the research and development of sustainable electrical power systems and the demand for training and education of existing and future power engineers in the advanced concepts and designing of sustainable electrical power systems and renewable energy with significant research training.

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Learning and teaching

Patterns of study 

The majority of students study our Masters programmes full time. Our programmes are also suitable for practising engineers who wish to study part-time or take a single module to earn Continuing Professional Development (CPD) points. Many modules are completed in three-day sessions allowing you to focus on one topic at a time. Following each session of lectures there is an opportunity for you to deepen your understanding through private study and in most cases there is also an assessed assignment. 

Core modules 

These modules cover the advanced specialist topics required for your specific degree programme, such as Power System Operation and Control, HVDC and FACTS and Power System Economics. These technologies are at the heart of many current developments in electrical power systems. 

Cross-programme option modules 

These options specialize in topics relevant to each degree programme and give you the opportunity to adapt the programme that you have chosen to study. The prior knowledge needed for each module is specified in the student handbook to help you make the most appropriate choice. This allows you the greatest possible freedom to customise your study package appropriately. 

Individual project 

In Year 2, you will have 12-months to work on a dedicated research project to develop your comprehensive research skills, which would be helpful to fill in the gap between the 1-year MSc and PhD. This is an opportunity for you to develop advanced specialist knowledge. Some projects are undertaken in collaboration with companies and, in some cases, you may work on company premises investigating issues of direct concern to future product development. 

Assessment and awards 

Assessment is by a combination of written examination and course work. There is a strong emphasis on course work to deepen understanding. The pass mark is 50%. A merit is awarded to students with an average of 60% or more and a distinction is awarded to students with an average of 70% or more, in both taught and project modules. There are prizes for students who perform especially well overall and for those who complete exceptionally good individual projects.



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Postgraduate degree programme. Electrical Power Systems Masters/MSc. 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

Postgraduate degree programme: Electrical Power Systems Masters/MSc:

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.

Course details

This MSc programme meets the industrial demand for the training and education of both existing and future engineers in the advanced concepts of electrical power systems and renewable energy. It aims to produce graduates of the highest calibre with the right skills and knowledge who will be capable of leading in teams involved in the operation, control, design, and economic analysis of the electrical power systems and networks of the future – smart grids.

It will meet the demand for the research and development of sustainable electrical power systems and the demand for training and education of existing and future power engineers in the advanced concepts and understanding of sustainable electrical power systems and renewable energy.

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.

Related links

Learning and teaching

Patterns of study

The majority of students study our taught Masters programmes full time. Our programmes are also suitable for practising engineers who wish to study part-time or take a single module to earn Continuing Professional Development (CPD) points. Many modules are completed in three-day sessions allowing you to focus one topic at a time. Following each session of lectures there is an opportunity for you to deepen your understanding through private study and in most cases there is also an assessed assignment.

Overview module

There is a shared introduction to topics from communications engineering, requirements analysis and object-oriented design, and an introduction to and recap of C programming. For the communications engineering programmes there is an introduction to key issues in the design of antennas, radio frequency circuits and link budgets. For the computing programmes there is an introduction to object-oriented programming.

Core modules

These modules cover the advanced specialist topics required for your specific degree programme, such as statistical signal processing and coding and advanced digital design. These technologies are at the heart of many current developments in modern electronic systems. 

Cross-programme option modules

These options specialize in topics relevant to each degree programme and give you the opportunity to adapt the programme that you have chosen to study. The prior knowledge needed for each module is specified in the student handbook to help you make the most appropriate choice. This allows you the greatest possible freedom to customise your study package appropriately.

Individual project

This is an opportunity for you to develop specialist knowledge. Some projects are undertaken in collaboration with companies and, in some cases, you may work on company premises investigating issues of direct concern to future product development. Typical projects include the development of hardware for automotive radar signal processing and the detection of leaks in landfill sites, wireless access systems, 3G mobile radio for light aircraft, the creation of 3D worlds for surgery simulation and wearable computing.

Assessment and awards

Assessment is by a combination of written examination and course work. There is a strong emphasis on course work to deepen understanding. The pass mark is 50%. A merit is awarded to students with an average of 60% or more and a distinction is awarded to students with an average of 70% or more, in both taught and project modules. There are prizes for students who perform especially well overall and for those who complete exceptionally good individual projects.

Employability

This course meets the industrial demand for the training and education of both existing and future engineers in the advanced concepts of electrical power systems and renewable energy. It aims to produce graduates of the highest calibre who will be much in demand due to their skills, knowledge and ability to lead in teams involved in the operation, control, design, and economic analysis of the electrical power systems and networks of the future – smart grids.



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This one-year programme is designed to equip graduates and professionals with a broad and robust training on modern power engineering technologies, with a strong focus on renewable energy conversion and smart grids. Read more

This one-year programme is designed to equip graduates and professionals with a broad and robust training on modern power engineering technologies, with a strong focus on renewable energy conversion and smart grids. It is suitable for recent graduates who wish to develop the specialist knowledge and skills relevant to this industry and is also suitable as advanced study in preparation for research work in an academic or industrial environment.

In semesters 1 and 2, the programmes comprises a mixture of taught courses, workshops and a group design project, led by leading experts in the field, covering the key topics in power systems, electrical machines and power electronics. The final part of the programme is an individual dissertation, which provides a good opportunity for students to apply their acquired skills to real problems in electrical power engineering.

This one year programme at the University of Edinburgh will immerse the students in the most current developments in the area of Electrical Power Engineering, through a combination of taught modules, workshops, a research dissertation, and a range of supporting activities delivered by internationally leading experts in the field. The programme develops through the year from advanced fundamental topics and research tools and techniques in electrical power engineering, to specialist courses on emerging technologies and advanced numerical methods for power engineering problems, and culminates in the summer dissertation project where the acquired skills in various areas are put into practice in application to an actual power engineering problem.

Topics covered within the individual courses of the programme, include (but are not limited to):

  • Fundamental and emerging power engineering technologies
  • Advanced numerical methods in application to electrical power engineering problems
  • Modern power conversion components & systems
  • Integration of renewable energy in the power system
  • Distributed energy resources
  • Electrical engineering aspects of energy storage
  • Power, telecommunications & control aspects of smart grids
  • Research and innovation management techniques.

In addition, our MSc students actively engage in research as part of their dissertation projects either within the Institute for Energy Systems or with industry, with some joining our PhD community afterwards.

Programme structure

This programme is delivered over 12 months, with two semesters of taught courses, followed by a research project leading to the submission of a Master’s Thesis.

Semester 1

  • Power Electronics, Machines & Systems
  • Power Engineering Research Techniques
  • Energy & Environmental Economics
  • Technologies for Sustainable Energy

Semester 2

  • Power Conversion and Control
  • Power Systems Engineering & Economics
  • Distributed Energy Resources and Smart Grids

Research Project

  • Electrical Power Engineering Dissertation

The above courses correspond to 120 credits of taught material, plus 60 credits of a research project.

Learning outcomes

The main objective of the programme is to train the next generation of electrical power engineers who:

  • are aware of the most recent, cutting edge developments in power engineering;
  • have skills and training needed in both industrial and academic settings;
  • are able to tackle the global energy trilemma of supplying secure, equitable and environmentally sustainable energy, while appreciating the technical, social and economic challenges faced in both developed and developing countries.

Career opportunities

Governments worldwide are putting in place plans to decarbonise and modernise their electricity sector. A transition to a green economy will require a highly skilled workforce led by electrical power engineers with a solid academic background, an appreciation of the trajectory of the industry and an understanding of the challenges and implications brought about by the introduction of new power technologies.

According to the Institution for Engineering & Technology (IET): “The business of managing and distributing power in the UK is beginning to undergo revolutionary changes and [power] engineers are the people who will play a pivotal role in keeping the lights on”. This also holds true in many other developed and developing countries in the world.

Power engineers are employed in public/governmental organisations as well as in the private sector and cover areas spanning from generation, to conversion and transmission of electrical power, design and manufacturing of power components and systems, and energy policy and commerce. In the UK, experienced, chartered power engineers can earn around £45,000 a year on average*.

The programme will run in a close association with other activities within the broader Electrical Engineering programme within the School, including networking events, industrial presentations and seminars. It will benefit from the current strong connections with industry (coordinated by the Student Industry Liaison Manager, and existing research associations and consortia (such as the EPSRC Centre for Energy Systems Integration).



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This programme is for graduate engineers wishing to work in the electrical power industry. It develops your knowledge of electrical power and energy systems, giving you a good understanding of the latest developments and techniques within the electrical power industry. Read more

This programme is for graduate engineers wishing to work in the electrical power industry. It develops your knowledge of electrical power and energy systems, giving you a good understanding of the latest developments and techniques within the electrical power industry.

Course details

The programme is centred around three major themes:

  • electrical power networks with emphasis on conventional networks, smart grids, high voltage direct current transmission and asset management of network infrastructure
  • renewable energies with emphasis on wind and solar power
  • power electronics with emphasis on power electronic convertors in converting and controlling power flows in electrical networks and renewable energy systems.

There are three routes you can select from to gain a postgraduate Master’s award:

  • MSc Electrical Power and Energy Systems – one year full time
  • MSc Electrical Power and Energy Systems – two years part time
  • MSc Electrical Power and Energy Systems (with Advanced Practice) – two years full time

The one-year programme is a great option if you want to gain a traditional MSc qualification – you can find out more here. This two-year master’s degree with advanced practice enhances your qualification by adding to the one-year master’s programme an internship, research or study abroad experience.The MSc Electrical Power and Energy Systems (with Advanced Practice) offers you the chance to enhance your qualification by completing an internship, research or study abroad experience in addition to the content of the one-year MSc.

What you study

For the MSc with advanced practice, you complete 120 credits of taught modules, a 60-credit master’s research project and 60 credits of advanced practice.

Course structure

Core modules

  • Asset Management
  • Data Acquisition and Signal Processing Techniques
  • Emerging Transmission Systems
  • Power Electronics
  • Practical Health and Safety Skills
  • Project Management and Enterprise
  • Renewable Energy Conversion Systems
  • Research and Study Skills
  • Research Project (Advanced Practice)
  • Smart Power Distribution

Advanced Practice options

  • Research Internship
  • Study Abroad
  • Vocational Internship

Modules offered may vary.

Teaching

How you learn

You learn through lectures, tutorials and practical sessions. Lectures provide the theoretical underpinning while practical sessions give you the opportunity to put theory into practice, applying your knowledge to specific problems. 

Tutorials and seminars provide a context for interactive learning and allow you to explore relevant topics in depth. In addition to the taught sessions, you undertake a substantive MSc research project.

In addition to the taught sessions, you undertake a substantive MSc research project and the Advanced Practice module. This module enables you to experience and develop employability or research attributes and experiential learning opportunities in either an external workplace, internal research environment or by studying abroad. You also critically engage with either external stakeholders or internal academic staff, and reflect on your own personal development through your Advanced Practice experience.

How you are assessed

Assessment varies from module to module. It may include in-course assignments, design exercises, technical reports, presentations or formal examinations. For your MSc project you prepare a dissertation.

Your Advanced Practice module is assessed by an individual written reflective report (3,000 words) together with a study or workplace log, where appropriate, and through a poster presentation.

Employability

As an electrical power and energy systems engineer you can be involved in designing, constructing, commissioning and lifecycle maintenance of complex energy production, conversion and distribution systems. 

Your work can include energy storage systems, management and efficient use of energy in building, manufacturing and processing systems. You can also be involved in work relating to the environmental and economic impact of energy usage.

Examples of the types of jobs you could be doing include:

  • designing new electrical transmission and distribution systems
  • managing maintenance and repair
  • managing operations of existing systems
  • managing operations of a wind turbine farm
  • analysing the efficiency of hydroelectric power systems
  • evaluating the economic viability of new solar power installations
  • assessing the environmental impact of energy systems.


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This MSc programme in Sustainable Electrical Power aims to produce graduates capable of leading teams which will operate, control, design, regulate and manage the power systems and networks of the future. Read more

About the course

This MSc programme in Sustainable Electrical Power aims to produce graduates capable of leading teams which will operate, control, design, regulate and manage the power systems and networks of the future.

The course equips graduates with the ability to critically evaluate methodologies, analytical procedures and research methods in:

-Power system engineering – using state-of-the-art computational tools and methods.
-Design of sustainable electrical power systems and networks.
-Regulatory frameworks for, and operation of, power systems and electricity markets.

The programme features practical workshops and the option of an industry-based dissertation. Students benefit from our high performance lab and computing facilities, including a grid-enabled cluster of processors. We’re also home to a world leading research group, the Brunel Institute of Power Systems.

Aims

Sustainable energy is a vital, growing sector and this newly designed MSc programme meets industry’s demand for engineers with advanced knowledge of sustainable electrical power and energy generation systems.

The course is suitable for:
- Graduates in power or electrical engineering, physical sciences, or related disciplines who aspire to work in the electrical power industry, especially within the renewable energy sector.
- Industrially experienced graduate engineers and managers who recognise the importance of developing new analytical and critical skills, and state-of-the-art methodologies associated with the development sustainable electrical power systems.

Course Content

Compulsory Modules:

Energy Economics and Power Markets
Power System Operation and Management
Power Electronics and FACTS
Power System Analysis and Security
Sustainable Power Generation
Power System Stability and Control
Project Management
Sustainable Electrical Power Workshop
Project & Dissertation

Special Features

All students enrolled in the course have the opportunity to develop real-world skills with the best globally available, cutting-edge power analysis software and tools. The course is also supported by a wide range of application oriented power engineering experiments carried out in a modern well-equipped practical power systems laboratory.

The Brunel Institute of Power Systems is an internationally leading research group specialising in the optimal design, operation and modelling of power systems, as well as in the economics of electricity markets.

Our high performance computing capability is considerable including a recently installed grid-enabled cluster of processors consisting of 20 dual processor nodes with dual Gigabit Ethernet interfaces.

Major power system software are available including MATLAB/SIMULINK, Orcad, PSCAD, DigSILENT, IPSA, ETAP, and PowerWorld.

Electronic and Computer Engineering is one of the largest disciplines at Brunel University, with a portfolio of research contracts totalling £7.5 million and strong links with industry.

Our laboratories are well equipped with an excellent range of facilities to support the research work and courses. We have comprehensive computing resources in addition to those offered centrally by the University. The discipline is particularly fortunate in having extensive gifts of software and hardware to enable it to undertake far-reaching design projects.

We have a wide range of research groups, each with a complement of academics and research staff and students. The groups are:

-Media Communications
-Wireless Networks and Communications
-Power Systems
-Electronic Systems
-Sensors and Instrumentation.

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This course delivers a broad coverage of all major disciplines in Electrical Power, including power electronics, electric drives, electrical machine design and power systems. Read more
This course delivers a broad coverage of all major disciplines in Electrical Power, including power electronics, electric drives, electrical machine design and power systems. It also covers important electrical power themes such as renewable energy systems and electric vehicles.

The Electrical Power MSc covers the following key subject areas:
-Electrical Machines
-Power Electronics
-Electric Drives
-Power System Operation
-Control of Electrical Power

A feature of the course is design of electrical systems for transportation and renewable energy applications. This is a particular specialisation of researchers in the School of Electrical and Electronic Engineering.

You will develop a knowledge of industry standard computer aided design and analysis techniques appropriate to electrical power such as the use of software packages such as MagNet, MATLAB, Simulink, PSpice and ERACS.

Throughout the course you use industry standard test and measurement equipment, experimental hardware, and software packages relevant to the field of electrical and power engineering.

The course comprises a mixture of lectures, tutorials, coursework and practical laboratory classes. You will research a specialist topic of your choice through an in-depth project. Innovative educational techniques are designed to equip you with practical design skills and research methodologies.

As a graduate of this course you are equipped with the knowledge and practical experience to embark on a career as an engineer in the field of Electrical Power. You will also have skills in research and knowledge acquisition and a solid foundation for further postgraduate studies in the field of electrical engineering and power engineering.

Delivery

You take modules to a total value of 180 credits over three semesters. Taught modules, worth 120 credits, take place during the first and second semesters with exams held in January and May/June. An individual project, worth 60 credits, is undertaken over semesters two and three.

Background reading and design work take place during the second semester. The majority of experimental work and preparation of your dissertation takes place during the semester three.

Teaching takes place in lecture theatres equipped with audio visual equipment. Blackboard, a web based Virtual Learning Environment (VLE) supports your taught modules. Practical sessions are in small groups with experts in the field of Power Electronics, Electric Drives, Machines, and Power Systems and in modern laboratory and computing facilities.

Employability

We collect information from our graduates six months after they leave University. This is part of the Destination of Leavers from Higher Education (DLHE) survey that every UK higher education institution takes part in.

Accreditation

The course is accredited by the Institution of Engineering and Technology (IET) and Engineering Council, and therefore provides a good foundation for professional registration.

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Power system engineering is about keeping things in balance. Not just the balance between generation and load or between production and consumption of reactive power. Read more

Power system engineering is about keeping things in balance. Not just the balance between generation and load or between production and consumption of reactive power. It is also about the balance between the cost of energy and its environmental impact or the balance between the reliability of the supply and the investments needed to develop the system. This course will teach you how to quantify both sides of these equations and then how to improve the balances through technological advances and the implementation of sophisticated computing techniques.

In the first semester you learn how power systems are designed and operated. This involves studying not only the characteristics of the various components (generators, lines, cables, transformers and power electronics devices) but also how these components interact. Through lectures and computer based exercises you become familiar with power flow and fault calculations and you learn how the techniques used to study the behaviour of large systems. Experiments in our high voltage laboratory give you an appreciation for the challenges of insulation co-ordination.

During the second semester the course units explore in more depth the 'operation' and the 'plant' aspects of power systems. For example, you will study how renewable generation is integrated in a power system or how to assess and remedy power quality problems.

Prior to your summer break a preliminary study and the outline of your MSc dissertation project is completed, this is fully developed throughout the second year of the course. The yearlong enhanced individual research provides you great opportunities to develop advanced research skills and to explore in depth some of the topics discussed during the course. This includes training in research methods, and advanced simulation and experimental techniques in power systems and high voltage engineering as well as academic paper writing and poster and paper presentation.

Aims

  • Provide an advanced education in electrical power engineering.
  • Give graduates the education, the knowledge and the skills they need to make sound decisions in a rapidly changing electricity supply industry.
  • Give 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.
  • Educate students with advanced research skills necessary to address current and future technological advancements.

Coursework and assessment

You are required to take seven examinations. In addition, course work (eg lab reports) accounts for typically 20% of the mark for each course unit. One course units is assessed on the basis of coursework only.

The enhanced research project is assessed on the basis of a research poster, an extended abstract, a research papers and a dissertation of about 70 pages.

Course unit details

Course units typically include:

  • Electrical Power Fundamentals
  • Analysis of Electrical Power and Energy Conversion Systems
  • Power System Plant, Asset Management and Condition Monitoring
  • Power System Operation and Economics
  • Power System Dynamics and Quality of Supply
  • Power System Protection
  • Smart Grids and Sustainable Electricity Systems
  • Techniques for Research and Industry

Disability support

Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: 

Career opportunities

Over the last thirty years, hundreds of students from around the world have come to the University to obtain an MSc in Electrical Power Engineering or similar. After graduation, they went on to work for electric utilities, equipment manufacturers, specialised software houses, universities and consultancy companies.

This course also provides the students with additional research skills necessary for starting a PhD degree or entering an industrial research and development career. 



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Are you interested in working in the electrical power engineering and renewable energy sectors? This course will give you a thorough understanding of power electronics, electric drive systems, smart grids, wind power, photovoltaic and other distributed generation systems. Read more
Are you interested in working in the electrical power engineering and renewable energy sectors? This course will give you a thorough understanding of power electronics, electric drive systems, smart grids, wind power, photovoltaic and other distributed generation systems.

The course, which enjoys very high student satisfaction rates, has been carefully designed to meet the needs of industry. It also meets the academic requirements of the Institution of Engineering and Technology (IET), by whom it is fully accredited.

Electrical power engineers need to be able to work in multidisciplinary teams and to show organisational and commercial skills alongside technical knowledge. The course therefore has a strong focus on project management, self-development and employability.

You’ll benefit from the University’s excellent facilities that include specialist electrical and electronics laboratory resources. Northumbria has a well-established reputation for producing graduates who can apply their knowledge to generate creative solutions for sustainable electrical power systems.

In the second year, for one semester, you’ll undertake an internship, study in another country or join a research group. This valuable experience will enhance your employability and further develop your theoretical and practical skills.

This course can also be started in January - for more information, please view this web-page: https://www.northumbria.ac.uk/study-at-northumbria/courses/electrical-power-engineering-msc-ft-dtfepz6/

Learn From The Best

Our teaching team includes experts from the Northumbria Photovoltaics Application Centre (NPAC) and Power and Wind Energy Research (PaWER) group. Their experience, combined with their on-going active research, will provide an excellent foundation for your learning.

The quality of their research has put Northumbria University among the UK’s top 25% of universities for the percentage of research outputs in engineering that are ranked as world-leading or internationally excellent (Research Excellence Framework 2014).

Our reputation for quality is reflected by the range and depth of our collaborations with industry partners. Our industrial links help inform our curriculums and ensure a variety of site visits and input from practitioners via guest lectures.

Teaching And Assessment

Our teaching methods include lectures, seminars, laboratory sessions, computer workshops, individual tutorials, and group projects. As this is a master’s course there is a significant element of independent learning and self-motivated reflection.

You’ll undertake a practical or theoretical master’s dissertation that will hone your skills in evaluating and applying research techniques and methodologies.

Assessments are designed to give feedback as well as to monitor your level of achievement. The assessed projects will enable you to test your skills in ways that relate to current industrial practice. Specific assessment methods include assignments, exams, technical reports and presentations.

The Advanced Practice semester will be assessed via a report and presentation about your internship, study abroad or research group activities.

Learning Environment

Northumbria University provides outstanding facilities for electrical power engineering. Our laboratories have equipment that includes oscilloscopes, signal generators and Labview software as well as National Instruments Educational Laboratory Virtual Instrumentation Suite (NI ELVIS) to measure and control signal voltages.

Our New and Renewable Energy Laboratory is an excellent resource for research into power networks, wind energy, photovoltaics and battery testing for electric vehicles. All our facilities are backed up by a team of technicians who will give support and advice when you need it.

Technology Enhanced Learning (TEL) is embedded throughout the course with tools such as the ‘Blackboard’ eLearning Portal and electronic reading lists that will guide your preparation for seminars and independent research. Our use of lecture capture software will help you revise challenging material.

To facilitate group projects there is a working space called The Hub that’s well equipped for meetings and working with IT. The Zone is another area that’s popular with students undertaking group work or individual study.

Research-Rich Learning

Northumbria’s strong research ethos is an essential aspect of how you will develop as a critical, reflective and independent thinker. With our problem-solving approach you’ll acquire a wide range of research and analytical skills as you progress through the course. These skills will come together in the practical/theoretical dissertation that you’ll undertake, which will require independent research and appropriate techniques of inquiry, critical evaluation and synthesis.

Throughout the course your learning will be directly impacted by the teaching team’s active research. Our specialist interests include electrical and electronic engineering, mobile communication, microelectronic, renewable and sustainable energy technologies, and advanced materials.

Give Your Career An Edge

The course will equip you with the knowledge and skills you’ll need to work in the electrical power engineering and renewable energy sectors. At the same time you’ll develop transferable key skills and personal attributes that promote employability and lifelong learning.

The group projects will provide experience of working with others while also raising your awareness of commercial considerations and how industry operates. One project involves the development of an innovative product that must satisfy pre-determined criteria including a realistic business model.

Your dissertation can be linked to the University’s on-going research, giving you experience of being incorporated into a pre-existing working team and environment. Alternatively you can undertake a practice-based dissertation that’s linked to a project that you’ve chosen for its relevance to your interests, self-development and career prospects.

The Advanced Practice semester will help you develop a track record of achievement that will help you stand out from other job applicants.

A two-year master’s course, like this one, will carry particular weight with employers. They’ll understand that you’ll have a deeper understanding of topics as well as more hands-on practical experience.

When it comes to applying for jobs our Careers and Employment Service offers resources and support that will help you find roles matching your interests and skills. You will be able to access a range of workshops, one-to-one advice, and networking opportunities.

Your Future

By the end of this course you’ll be in an excellent position to start or continue a career in electrical power engineering and/or the renewable energy industry. Roles could include designing, developing and maintaining electrical control systems and components.

You could also undertake a postgraduate research degree such as an MPhil, PhD and Professional Doctorate. If you decide to start up your own business, it’s good to know that the combined turnover of our graduates’ start-up companies is higher than that of any other UK university.

Whatever you decide to do, you will have the transferable skills that employers expect from a master’s graduate from Northumbria University. These include the ability to tackle complex issues through conceptualisation and undertaking research, the ability to contribute to new processes and knowledge, and the ability to formulate balanced judgements when considering incomplete or ambiguous data.

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Power system engineering is about keeping things in balance. Not just the balance between generation and load or between production and consumption of reactive power. Read more

Power system engineering is about keeping things in balance. Not just the balance between generation and load or between production and consumption of reactive power. It is also about the balance between the cost of energy and its environmental impact or the balance between the reliability of the supply and the investments needed to develop the system. These programmes will teach you how to quantify both sides of these equations and then how to improve the balances through technological advances and the implementation of sophisticated computing techniques.

During the second semester the course units explore in more depth the 'operation' and the 'plant' aspects of power systems. For example, you will study how renewable generation is integrated in a power system or how to assess and remedy power quality problems.

During the summer, your MSc dissertation project gives you a chance to develop your research skills and to explore in depth one of the topics discussed during the course.

Aims

Provide an advanced education in electrical power engineering.

Give graduates the education, the knowledge and the skills they need to make sound decisions in a rapidly changing electricity supply industry.

Give 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.

Coursework and assessment

You are required to take seven examinations. In addition, course work (eg lab reports) accounts for typically 20% of the mark for each course unit. One course units is assessed on the basis of course work only. The summer research project is assessed on the basis of a dissertation of about 50 pages.

Course unit details

Course units typically include:

  • Electrical Power Fundamentals
  • Analysis of Electrical Power and Energy Conversion Systems
  • Power System Plant, Asset Management and Condition Monitoring
  • Power System Operation and Economics
  • Power System Dynamics and Quality of Supply
  • Power System Protection
  • Smart Grids and Sustainable Electricity Systems
  • Techniques for Research and Industry

Disability support

Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: 

Career opportunities

Over the last thirty years, hundreds of students from around the world have come to the University to obtain an MSc in Electrical Power Engineering or similar. After graduation, they went on to work for electric utilities, equipment manufacturers, specialised software houses, universities and consultancy companies.



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Are you interested in working in the electrical power engineering and renewable energy sectors? This course will give you a thorough understanding of power electronics, electric drive systems, smart grids, wind power, photovoltaic and other distributed generation systems. Read more
Are you interested in working in the electrical power engineering and renewable energy sectors? This course will give you a thorough understanding of power electronics, electric drive systems, smart grids, wind power, photovoltaic and other distributed generation systems.

The course, which enjoys very high student satisfaction rates, has been carefully designed to meet the needs of industry. It also meets the academic requirements of the Institution of Engineering and Technology (IET), by whom it is fully accredited.

Electrical power engineers need to be able to work in multidisciplinary teams and to show organisational and commercial skills alongside technical knowledge. The course therefore has a strong focus on project management, self-development and employability.

You’ll benefit from the University’s excellent facilities that include specialist electrical and electronics laboratory resources. Northumbria has a well-established reputation for producing graduates who can apply their knowledge to generate creative solutions for sustainable electrical power systems.

In the second year, for one semester, you’ll undertake an internship, study in another country or join a research group. This valuable experience will enhance your employability and further develop your theoretical and practical skills.

Learn From The Best

Our teaching team includes experts from the Northumbria Photovoltaics Application Centre (NPAC) and Power and Wind Energy Research (PaWER) group. Their experience, combined with their on-going active research, will provide an excellent foundation for your learning

The quality of their research has put Northumbria University among the UK’s top 25% of universities for the percentage of research outputs in engineering that are ranked as world-leading or internationally excellent (Research Excellence Framework 2014).

Our reputation for quality is reflected by the range and depth of our collaborations with industry partners. Our industrial links help inform our curriculums and ensure a variety of site visits and input from practitioners via guest lectures.

Teaching And Assessment

Our teaching methods include lectures, seminars, laboratory sessions, computer workshops, individual tutorials, and group projects. As this is a master’s course there is a significant element of independent learning and self-motivated reflection.

You’ll undertake a practical or theoretical master’s dissertation that will hone your skills in evaluating and applying research techniques and methodologies.

Assessments are designed to give feedback as well as to monitor your level of achievement. The assessed projects will enable you to test your skills in ways that relate to current industrial practice. Specific assessment methods include assignments, exams, technical reports and presentations.

The Advanced Practice semester will be assessed via a report and presentation about your internship, study abroad or research group activities.

Learning Environment

Northumbria University provides outstanding facilities for electrical power engineering. Our laboratories have equipment that includes oscilloscopes, signal generators and Labview software as well as National Instruments Educational Laboratory Virtual Instrumentation Suite (NI ELVIS) to measure and control signal voltages.

Our New and Renewable Energy Laboratory is an excellent resource for research into power networks, wind energy, photovoltaics and battery testing for electric vehicles. All our facilities are backed up by a team of technicians who will give support and advice when you need it.

Technology Enhanced Learning (TEL) is embedded throughout the course with tools such as the ‘Blackboard’ eLearning Portal and electronic reading lists that will guide your preparation for seminars and independent research. Our use of lecture capture software will help you revise challenging material.

To facilitate group projects there is a working space called The Hub that’s well equipped for meetings and working with IT. The Zone is another area that’s popular with students undertaking group work or individual study.

Research-Rich Learning

Northumbria’s strong research ethos is an essential aspect of how you will develop as a critical, reflective and independent thinker. With our problem-solving approach you’ll acquire a wide range of research and analytical skills as you progress through the course. These skills will come together in the practical/theoretical dissertation that you’ll undertake, which will require independent research and appropriate techniques of inquiry, critical evaluation and synthesis.

Throughout the course your learning will be directly impacted by the teaching team’s active research. Our specialist interests include electrical and electronic engineering, mobile communication, microelectronic, renewable and sustainable energy technologies, and advanced materials.

Give Your Career An Edge

The course will equip you with the knowledge and skills you’ll need to work in the electrical power engineering and renewable energy sectors. At the same time you’ll develop transferable key skills and personal attributes that promote employability and lifelong learning.

The group projects will provide experience of working with others while also raising your awareness of commercial considerations and how industry operates. One project involves the development of an innovative product that must satisfy pre-determined criteria including a realistic business model.

Your dissertation can be linked to the University’s on-going research, giving you experience of being incorporated into a pre-existing working team and environment. Alternatively you can undertake a practice-based dissertation that’s linked to a project that you’ve chosen for its relevance to your interests, self-development and career prospects.

The Advanced Practice semester will help you develop a track record of achievement that will help you stand out from other job applicants.

A two-year master’s course, like this one, will carry particular weight with employers. They’ll understand that you’ll have a deeper understanding of topics as well as more hands-on practical experience.

When it comes to applying for jobs our Careers and Employment Service offers resources and support that will help you find roles matching your interests and skills. You will be able to access a range of workshops, one-to-one advice, and networking opportunities.

Your Future

By the end of this course you’ll be in an excellent position to start or continue a career in electrical power engineering and/or the renewable energy industry. Roles could include designing, developing and maintaining electrical control systems and components.

You could also undertake a postgraduate research degree such as an MPhil, PhD and Professional Doctorate. If you decide to start up your own business, it’s good to know that the combined turnover of our graduates’ start-up companies is higher than that of any other UK university.

Whatever you decide to do, you will have the transferable skills that employers expect from a master’s graduate from Northumbria University. These include the ability to tackle complex issues through conceptualisation and undertaking research, the ability to contribute to new processes and knowledge, and the ability to formulate balanced judgements when considering incomplete or ambiguous data.

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Electricity is playing an increasing role as we look to develop low carbon sources of energy. The design of electrical power systems is becoming increasingly complex, to manage intermittent sources of generation, and increased levels of demand from new types of load such as electric vehicles. Read more

Electricity is playing an increasing role as we look to develop low carbon sources of energy. The design of electrical power systems is becoming increasingly complex, to manage intermittent sources of generation, and increased levels of demand from new types of load such as electric vehicles.

The Distance Learning MSc in Electrical Power Systems Engineering allows engineers working in the sector to enhance their skills. It provides them with the tools and techniques to keep pace with the rapidly evolving electricity industry. The course covers the latest developments in the electricity industry and delivers up-to-date training in all aspects of electrical power systems.

Aim

The course will develop your understanding of how these future electrical networks will be designed and operated. It will provide you with a solid understanding of the characteristics of components such as generators, lines, cables, transformers and power electronics devices. It will provide you with the skills you need to carry out power flow and fault calculations, learning how these techniques are used to study the behaviour of large systems. The course also covers a range of other topics such as HVDC, how renewable generation is integrated into a power system, the increasing importance of smart grids, and how to assess and remedy power quality problems.The course is based on the long-running MSc in Electrical Power Systems Engineering delivered by The University of Manchester. On graduation you will be a member of a network of global alumni, many in senior positions in the electricity supply industry.

The course has been designed to support those working in industry. Multiple entry points exist and the course can be completed in a timescale that suits your needs. Your dissertation project will ideally be based on a problem you and your company need to resolve, ensuring the programme delivers value for both you and your employer.

Teaching and learning

Once you register for the course, you will be assigned a Course Advisor, who will stay with you throughout your studies and can be contacted by phone or email whenever you have a question or a concern.

Your Course Advisor will be able to guide you through your choice of units and help you to schedule and register for them. They will be familiar with all aspects of your course and your own progress and timetable and will be able to provide support on a wide range of issues or refer you to University specialist support services if necessary - such as the Careers Service, Counselling Service or Disability Support.

For each technical unit, you will be assigned an Academic Tutor with expertise in the particular subject area you will be studying. Your tutor will introduce themselves at the start of each unit to outline the material and plans for assessment. They will host regular online group discussions to review the content being presented that week and to give you the opportunity to engage with other students. They will also maintain and monitor a range of other tools including forums, blogs and live chat sessions, in case you have any questions about the course content.

You will typically need to commit around 15 hours per week during each unit taken when studying for your distance learning MSc. It is important to make sure your employer supports you by allowing suitable time to be spent on your studies.

Coursework and assessment

Each unit will require you to submit one or more pieces of coursework and a final assessment. Your Tutor will provide the exact details of how each activity contributes to your final marks for a given unit. The coursework will often involve using specialist software packages which we will make available to you.

You will also be provided with regular opportunities to assess your progress through self-tests that do not count towards your final mark. Your Tutor will seek to support you if you are having difficulty with a particular subject area and your Course Advisor will be there to help if there are any other issues affecting your studies.

Career opportunities

This distance learning course is an extension of the longstanding full time Electrical Power Systems Engineering MSc at the University of Manchester. Over the last thirty years, hundreds of students from around the world have come to the University to obtain an MSc in Electrical Power Engineering or similar. After graduation, they went on to work for electric utilities, equipment manufacturers, specialised software houses, universities and consultancy companies.

Many of our applications are from people already working in industry (but this is by no means a requirement) who are aiming to use this course to further propel their career. The majority of our applicants have come from system/network operators, manufacturers of power system components, consultancies, the oil & gas industry, and large construction companies.



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This programme is for graduate engineers wishing to work in the electrical power industry. It develops your knowledge of electrical power and energy ystems, giving you a good understanding of the latest developments and techniques within the electrical power industry. Read more

This programme is for graduate engineers wishing to work in the electrical power industry. It develops your knowledge of electrical power and energy ystems, giving you a good understanding of the latest developments and techniques within the electrical power industry.

Course details

The programme is centred around three major themes:

  • electrical power networks with emphasis on conventional networks, smart grids, high voltage direct current transmission and asset management of network infrastructure
  • renewable energies with emphasis on wind and solar power
  • power electronics with emphasis on power electronic convertors in converting and controlling power flows in electrical networks and renewable energy systems.

What you study

For the postgraduate diploma (PgDip) award you must successfully complete 120 credits of taught modules. 

For MSc students

For an MSc award you must successfully complete 120 credits of taught modules and a 60-credit master's research project.

Course structure

Core modules

  • Asset Management
  • Emerging Transmission Systems
  • Power Electronics
  • Practical Health and Safety Skills
  • Project Management and Enterprise
  • Renewable Energy Conversion Systems
  • Research and Study Skills
  • Smart Power Distribution

MSc only

  • Major Project

Modules offered may vary.

Teaching

How you learn

You learn through lectures, tutorials and practical sessions. Lectures provide the theoretical underpinning while practical sessions give you the opportunity to put theory into practice, applying your knowledge to specific problems. 

Tutorials and seminars provide a context for interactive learning and allow you to explore relevant topics in depth. In addition to the taught sessions, you undertake a substantive MSc research project.

How you are assessed

Assessment varies from module to module. The assessment methodology could include in-course assignments, design exercises, technical reports, presentations or formal examinations. For your MSc project you prepare a dissertation.

Employability

As an electrical power and energy systems engineer you can be involved in designing, constructing, commissioning and lifecycle maintenance of complex energy production, conversion and distribution systems. 

Your work could include energy storage systems, management and efficient use of energy in building, manufacturing and processing systems.

You could also be involved in work relating to the environmental and economic impact of energy usage.

Examples of the types of jobs you could be doing include:

  • designing new electrical transmission and distribution systems
  • managing maintenance and repair
  • managing operations of existing systems
  • managing operations of a wind turbine farm
  • analysing the efficiency of hydroelectric power systems
  • evaluating the economic viability of new solar power installations
  • assessing the environmental impact of energy systems.


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Gaining essential knowledge and skills in designing, managing, controlling and analysing the 21st century electric grid, you will bridge the gap that the Electrical Power industry is facing. Read more

Gaining essential knowledge and skills in designing, managing, controlling and analysing the 21st century electric grid, you will bridge the gap that the Electrical Power industry is facing. As an Electrical Power Engineer you will play a vital role in the development of a sustainable energy market. Your role will enable the merger of new technologies and the integration of renewable sources in the industry.

The MSc Electrical Power Engineering offers very exciting opportunities to understand the real challenges in future power networks and to develop innovative solutions.

GCU’s School of Engineering and Built Environment has almost 3 decades worth of graduates in the Electrical and Electronic Engineering field and this new Masters has been developed with UK-SPEC/IET (Institution of Engineering and Technology) to develop motivated and critical thinkers for the industry.

Students on the MSc Electrical Power Engineering programme are encouraged to join the IET and the Energy Institute (EI) and to participate in the activities which are frequently hosted by GCU. Involvement in the activities of the engineering institutions is an important aspect of career development for you as a student engineer, especially from the point of view of the eventual attainment of Chartered Engineer Status.

What you will study

Through the world class research led activities you will undertake you will develop proficiency in:

  • Exploring operational principles and management of future power networks and the importance of network asset management
  • Analyse and design power systems problems
  • Managerial, communication and information technology skills
  • Innovative thinking to accommodate future technological changes
  • Sufficiently wide perspective of the subject area to evaluate problem solving approaches.

Module information

Project Planning & Management

This module aims to develop in the student, the ability to select, develop and plan an MSc research project; to research and critically analyse the literature associated with the project; to present research findings effectively; and to be able to apply a competent process of thinking to all aspects of the project. In addition, the module aims to give the student an appreciation of the relationship between these skills and those associated with industrial project management.

Power Electronics and Drive Systems

This module examines Electro-magnetism and rare earth permanent magnets. It illustrates the applications of power electronic devices in addition to control and design of converter circuits and determination of filter technologies based on harmonic calculations. Characteristics of modern power electronic devices, driver circuits and protection. Also, it shows analysis and design of practical applications of electrical machines and power electronic systems.

Power System Operation & Protection

Critically analyse and assess technical requirements for power system operation, management and planning. It also develops a comprehensive view of power flow analysis, stability and protections. Appropriate modelling, analysis and design skills of AC power systems in steady state and in post-fault operation will be introduced.

Control Systems

This module aims to consolidate advanced classical and modern control design techniques encompassing the practical considerations in applying control design in an industrial environment. The appropriateness and difficulties encountered in applying various design techniques in practice is explored.

Energy Audit and Energy Asset Management

This module provides an understanding of the basic concepts and exposure to the relevant international standards in the areas of interests before it focuses the strategies and procedures of carrying out energy audit and asset management. The module will focus on life cycle management, including commissioning/decommissioning of equipment, techniques available for condition monitoring and statistical tools for remaining life and risk analysis.

Smart Grid & Sustainable Energy Systems

The module aims to introduce smart grids and renewable energy systems. It equips students with a detailed knowledge and problem solving skills of the engineering aspects of smart grids and the renewable generation of electricity.

Advanced AC and DC Transmission Systems

The module aims to equip the students with the knowledge and skills required for the design and analysis of hybrid modern AC/DC power systems. This module develops the students' understanding of FACTS (Flexible AC Transmission Systems), HVDC and other emerging power electronics applications for power systems and puts emphasis on the skills required to analyse and design such systems.

Condition Monitoring

This module aims to provide an understanding of both Mechanical and Electrical Condition monitoring and associated instrumentation requirements for successful condition monitoring. The application of standard and non-standard electrical condition monitoring systems to a range of electrical plant will be explained. The students learn to use condition monitoring tools and then to evaluate the data provided by them.

MSc Dissertation

The project acts as a vehicle for extending the knowledge and understanding of the student and the technical community in some specialist area. It serves to develop and extend a range of high-level 'thinking' skills, including analysing and synthesising skills and affords the opportunity for the student to demonstrate initiative and creativity in a major piece of technological work.



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The course of study Master of Science Management and Engineering in Electrical Power Systems (MME-EPS) is an interdisciplinary program run by two European universities, both well-reputed in their specific fields. . Read more

The course of study Master of Science Management and Engineering in Electrical Power Systems (MME-EPS) is an interdisciplinary program run by two European universities, both well-reputed in their specific fields. RWTH Aachen University's Faculty of Electrical Engineering and Information Technology runs the engineering part of the program, whilst the Dutch Maastricht School of Management covers the business and management part.

The program's main objective is to offer methodological and problem-oriented education, related to research as well as practice. The program will cover advanced topics in the areas of engineering, science, and economics. The course modules particularly focus on high voltage engineering, electrical machines and battery storage systems used to automatize and manage complex power systems. You will be exposed to topics such as the physical problems of energy storage and power electronics. You will also learn to solve faults and stability problems in power systems, as well as use computational engineering tools to automatize and manage complex power systems.

Our engineering graduates...

  • work at companies such as Anvis, BASF, Continental, Fiat, Ford, Kautex, Liebherr, Rolls Royce, Toyota and Volkswagen
  • are very successful on the job market: half of our graduates find employment within a month of graduating and two thirds within three months
  • increase their salary by more than 50% (about 40 %)

Our specialized graduates in Electrical Power Systems Engineering...

  • design, organize and manage virtual power plants, applying demand side management or dynamic demand management
  • design and operate peaking power plants, load following power plants, or virtual power stations to keep the electrical power systems in balance
  • improve the reliability of the supply by implementing sophisticated predictive simulation and computing techniques
  • optimize the cost balance between energy production and its environmental impact
  • develop investment strategies needed to improve electrical power systems
  • design and develop innovative smart grids

...to make a difference. Is this you?



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Gain IET accreditation on this Electrical Power and Control Engineering Masters at Liverpool John Moores University. This course meets Chartered Engineer requirements and the demand for postgraduates in this growing global industry. Read more
Gain IET accreditation on this Electrical Power and Control Engineering Masters at Liverpool John Moores University. This course meets Chartered Engineer requirements and the demand for postgraduates in this growing global industry

•Complete this masters degree in one year full time
•Study at one the UK’s leading Engineering Schools
•Programme informed by internationally-acclaimed research from LJMU’s Electrical and Electronic Engineering Research Centre
•Postgraduates of this course highly sought after by major UK and international employers

This MSc degree programme provides an excellent progression point from undergraduate courses in the area of electrical engineering. You can also complete the course as development and to specialise in the Electrical Power and Control Engineering field.

Did you know that there is growing demand for electrical power engineers in the energy, automotive, and process industries? You could be involved in the design and development of electrical systems, such as those found in hybrid vehicles, cooling systems and aircraft actuators or the generation, distribution, regulation and conversion of electrical power.
You’ll develop advanced analytical and experimental skills to design new power and control systems and learn how to critically analyse designs, their functionality and expected reliability.
It will also be important for you to gain a strong understanding of the capabilities and limitations of modelling and simulation tools.

The expertise and laboratories available are aligned to the new sources of energy, green energy and the energy saving industry. LJMU specialist facilities support investigation into wind power electricity generation, where wider penetration of remote off-shore wind farm installations is expected in near future and multi-phase systems have many advantages.
The programme design provides opportunities to practice communication skills at Chartered Engineer level. You’ll gain the professional behavioural traits to prepare you for technical and management roles in power and control engineering.

Please see guidance below on core and option modules for further information on what you will study.
Level 7
Modelling and Control of Electric Machines and Drives
Control Systems
Dynamic Systems Simulation
Digital Control Power Systems Modelling
Analysis Alternative Energy Systems Modelling with Matlab and Simulink
MSc Project
Operations Research
Safety Reliability
Project Management
Programming for Engineering
LabVIEW
Professional and Leadership Skills

Further guidance on modules

The information listed in the section entitled ‘What you will study’ is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal Academic Framework review, so may be subject to change. Students will be required to undertake modules that the University designates as core and will have a choice of designated option modules. Additionally, option modules may be offered subject to meeting minimum student numbers.

Academic Framework reviews are conducted by LJMU from time to time to ensure that academic standards continue to be maintained. A review is currently in progress and will be operational for the academic year 2016/2017. Final details of this programme’s designated core and option modules will be made available on LJMU’s website as soon as possible and prior to formal enrolment for the academic year 2016/2017.

Please email if you require further guidance or clarification.

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