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Electrical and Electronic Engineering is characterised by the need for continuing education and training. Today, most Electrical and Electronic Engineers require more than is delivered in a conventional four-year undergraduate programme. Read more
Electrical and Electronic Engineering is characterised by the need for continuing education and training. Today, most Electrical and Electronic Engineers require more than is delivered in a conventional four-year undergraduate programme. The aim of the MEngSc (Electrical and Electronic Engineering) programme is to provide advanced coursework with options for a research element or industrial element, and additional professional development coursework. Students choose from a range of courses in Analogue, Mixed Signal, and RF Integrated Circuit Design, VLSI Architectures, Intelligent Sensors and Wireless Sensor Networks, Wireless Communications, Robotics and Mechatronics, Advanced Power Electronics and Electric Drives, Optoelectronics, Adaptive Signal Processing and Advanced Control. A range of electives for the coursework-only stream includes modules in Computer Architecture, Biomedical Design, Microsystems, Nanoelectronics, Innovation, Commercialisation, and Entrepreneurship

Visit the website: http://www.ucc.ie/en/ckr47/

Course Details

The MEngSc (EEE) has three Streams which include coursework only, coursework with a research project, or coursework with an industrial placement. Students following Stream 1 take course modules to the value of 60 credits and carry out a Minor Research Project to the value of 30 credits. Students following Stream 2 take course modules to the value of 60 credits and carry out an Industrial Placement to the value of 30 credits. Students following Stream 3 take course modules to the value of 90 credits, up to 20 credits of which can be in topics such as business, law, and innovation.

Format

In all Streams, students take five core modules from the following range of courses: Advanced Analogue and Mixed Signal Integrated Circuit Design, Advanced RF Integrated Circuit Design, Advanced VLSI Architectures, Intelligent Sensors and Wireless Sensor Networks, Wireless Communications, Robotics and Mechatronics, Advanced Power Electronics and Electric Drives, Optoelectronics, and Adaptive Signal Processing and Advanced Control. In addition, students following Stream 1 (Research Project) and Stream 2 (Industry Placement) carry out a Research Report. Following successful completion of the coursework and Research Report, students in Streams 1 and 2 carry out a research project or industry placement over the summer months.

Students who choose the coursework-only option, Stream 3, take additional courses in lieu of the project or placement. These can be chosen from a range of electives that includes modules in Computer Architecture, Biomedical Design, Microsystems, Nanoelectronics, Innovation, Commercialisation, and Entrepreneurship.

Assessment

Part I consists of coursework modules and mini-project to the value of 60 credits. These are assessed using a combination of written examinations and continuous assessment. Successful completion of the initial tranche of coursework modules qualifies the student to progress to Part II, the research project, industrial placement, or additional coursework to the value of 30 credits in the cases of Streams 1, 2, and 3, respectively.

Placement and Study Abroad Information

For students following Streams 1 and 2, research projects and industrial placements are normally in Ireland. Where the opportunity arises, a research project or work placement may be carried out outside Ireland.

Careers

MEngSc (Electrical and Electronic Engineering) graduates will have a competitive advantage in the jobs market by virtue of having completed advanced coursework in Electrical and Electronic Engineering and, in the case of Streams 1 and 2, having completed a significant research project or work placement.

How to apply: http://www.ucc.ie/en/study/postgrad/how/

Funding and Scholarships

Information regarding funding and available scholarships can be found here: https://www.ucc.ie/en/cblgradschool/current/fundingandfinance/fundingscholarships/

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Most people aren't familiar with Embedded Systems, but we use them every day of our lives. Smartphones, digital TV, MP3s and iPods, washing machines, even toys or a talking greetings card they all contain a microprocessor or a microcontroller. Read more
Most people aren't familiar with Embedded Systems, but we use them every day of our lives. Smartphones, digital TV, MP3s and iPods, washing machines, even toys or a talking greetings card they all contain a microprocessor or a microcontroller. Embedded systems are the backbone of the digital revolution.

As the complexity of embedded systems increases, the industry needs skilled graduates to fill the talent shortage.

Course detail

With the MSc Embedded Systems and Wireless Networks you'll develop a sound technical knowledge of the fundamentals of electronics, embedded systems, software and hardware, and become an embedded system designer with a multidisciplinary background. You'll develop software programming and hardware design skills, and a broad knowledge of electronics fundamentals.

Graduates of electronic engineering, systems engineering or other appropriate sciences can develop, deepen or update their skills and knowledge in advanced electronic engineering technology and cutting-edge research fields.

This course is ideal for graduate engineers interested in electronics, embedded systems, signal processing, mobile communications and wireless technology.

Modules

• Embedded Real-time Control Systems
• Safety Critical Embedded Systems
• Wireless and Mobile Communications
• Advanced Control and Dynamics
• System Design using HDLs
• Wireless Sensor Networks
• Group Project Challenge
• Dissertation

Format

You'll be taught by experienced specialist academic staff who are experts in basic and advanced electronics, control systems, basic and advanced robotics, mobile communications, wireless sensor networks, embedded systems, power systems, power electronics, signal processing and sensor technology. Many of them are involved in cutting-edge research.

You'll attend lectures, then apply what you've learned to real life through tutorial sessions, case studies, classroom discussions, project work, laboratory exercises and visits to or guest lectures from professionals working in engineering organisations.

Assessment

You are assessed through examinations, coursework, lab-based assessment and oral presentations. An independent examiner assesses your dissertation.

How to apply

Information on applications can be found at the following link: http://www1.uwe.ac.uk/study/applyingtouwebristol/postgraduateapplications.aspx

Funding

- New Postgraduate Master's loans for 2016/17 academic year –

The government are introducing a master’s loan scheme, whereby master’s students under 60 can access a loan of up to £10,000 as a contribution towards the cost of their study. This is part of the government’s long-term commitment to enhance support for postgraduate study.

Scholarships and other sources of funding are also available.

More information can be found here: http://www1.uwe.ac.uk/students/feesandfunding/fundingandscholarships/postgraduatefunding.aspx

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The Industrial Masters by Research is is supported by the University of Salford and by Dyer Environmental Controls Ltd. Supervisors. Read more
The Industrial Masters by Research is is supported by the University of Salford and by Dyer Environmental Controls Ltd

Supervisors: Professor Will Swan and Richard Fitton

It will run for 1 year and includes:
• A fee waiver
• A stipend of £15,363 p.a.

Candidates must have settled status in the UK and meet the Residency Requirements of EPSRC – see below.

Description:

An exciting Industrial Masters by Research opportunity has arisen out of the ongoing relationship between the University of Salford and Dyer Environmental Controls Ltd.

Highlighted by the recent flooding issues in the UK, Dyer Environmental Controls Ltd believes that there is a need for improved weather detection and is looking to design a low-cost , wireless weather sensor and transmitter to enable early warning sensing and quantitative data for analysis. Dyer believes this data can be used for many applications e.g. flood warning/defenses; agricultural irrigation control; building automation; and the data collection for future modelling.

The aim of this Industrial Masters project is to produce a trialed and tested working prototype unit which Dyer Environmental can then look to submit for commercial development.

The collaboration

The School of Built Environment at the University of Salford has a strong track record of working with industry. The placement will be with the Applied Buildings and Energy Research Group, which is home to the Salford Energy House. Over the last 5 years we have developed detailed knowledge of sensors to understand both internal and external environments that are used in both laboratory and field environments.

Dyer Environmental Controls Ltd has worked closely with the University of Salford for the past 8 years, completing a 2.5 year KTP project and also sponsoring a PhD student. Dyer has also worked on various projects with the University of Salford’s Energy House. Now celebrating its 25th year, Dyer has worked within the ventilation and building automation sectors and is constantly striving for innovation. Dyer’s success is through customer relationships and flexibility – providing the most efficient and most effective solution for their customer’s needs. The KTP project succeeded in bringing a new product to market and is now sold globally.

Candidates:

The preferred candidates must have a good understanding of:
• A suitable undergraduate level award in electronics/electronics engineering
• The design/implementation and construction of analogue and digital electronic circuits.
• A good working knowledge of C & C++ for embedded microcontrollers, wireless/ mobile communications and PCB layout and design.
• Should have a working knowledge of meteorological or environmental sensors

Candidates are asked to provide a personal statement describing their background, skills, academic interests and their motivation for doing a Masters in no more than 2 sides of A4. This should include evidence of being able to work independently to a high standard, collaborate with others, and excellent writing skills.

The Successful candidate will work mainly on the premises of the University but will spend a significant amount of time at the Company Partner premises.

Funding:

This Industrial Masters by Research studentship is only available to students with settled status in the UK, as classified by EPSRC eligibility. http://www.epsrc.ac.uk/funding/students/Pages/eligibility.aspx

Eligibility: Residence requirements

To be eligible for a full award (stipend and fees) a student must have:

• Settled status in the UK
• Been ‘ordinarily resident’ in the UK for 3 years prior to the start of the grant.
• Not been residing in the UK wholly or mainly for the purpose of full-time education. (This does not apply to UK or EU nationals)

Enquiries: Informal enquiries may be made to Professor Will Swan by e-mail
Applicants should send a curriculum vitae and a covering letter explaining their interest to Vicky Beckett

Application deadline: Friday 22nd July 2016.

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Telecommunication engineering encompasses the design and optimisation of communication networks for voice, data and multimedia applications. Read more
Telecommunication engineering encompasses the design and optimisation of communication networks for voice, data and multimedia applications. This award will provide students with an indepth knowledge and skills of computer communication, telecommunication networks, project management and research methods.This award aims to produce postgraduates with the knowledge and skills to enable them to enhance their career opportunities, which is relevant to the fast paced changing needs of the telecommunications and related industries.

Course content

On the Engineering Extended MSc you will spend your first semester studying modules that have been written to provide you with the academic, professional and technical skills that you will need to succeed on your chosen award.

All engineering students on the Extended MSc study the same modules for one semester and then study specialist modules depending on their chosen discipline.

This means that whether you have chosen the Aeronautical, Automotive, Electrical, Electronic, Mechanical, Mechatronic or Telecommunication route, you will study the following modules in your first semester:
-Academic English: This module will help you to develop your English Language speaking, listening, reading and writing skills and will introduce you to the conventions of academic writing.
-Study skills & Employability: This module will help you to develop the skills and knowledge required to support study at Masters level. It will also help you to develop skills that will aid you in the job market and will look at things such as writing a C.V. and creating a personal development plan.
-Engineering Principles: Basic electrical measurement techniques Introduction to Xilinx Digital Design software to enter and simulate the operation of a number of logic designs. Undertake a simple electrical systems test in a simulation environment such as MATLAB and analyse the results to provide performance measures. Design a cellular network and/or a computer data network using simulation packages such as Mentum Planet or OPNet software.
-Mathematical Applications: As an engineering graduate you should already have a strong mathematical knowledge. This module will revise your existing knowledge and introduce you to some of the more advanced mathematical concepts deployed in the field of professional engineering. Where appropriate you will utilise software to support and enhance the problem solving and analysis techniques met in this module, allowing you to hone an essential skill for the modern industry based working environment.

After successfully completing the first semester, you will concentrate on your chosen engineering discipline as below:
-Digital Signal Processing
-Cellular Network Planning Principles
-Voice and Data over Broadband Network
-Wireless Sensor Networks & IOT: Principles and Practices
-Digital Electronic Systems

Teaching Block 2
-Telecommunications
-Wireless Navigation Systems
-Optical Fibre Communication Systems
-Research Methods and Project Management

Teaching Block 3
-MSc Project

There is the opportunity to undertake a placement. Applicants who require a Tier 4 visa for study in the UK are not able to apply for the Sandwich degree in the first instance due to Immigration regulations. We encourage International students, once enrolled, to apply for a placement and we have a dedicated team of experts who will lead you through the process. Students who are successful with finding a placement will be provided with help and advice with their visa extension application (subject to the University deadlines and Immigration requirements).

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

Read less
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

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Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Read more
Energy has been considered a core research area within the broadly-based disciplines of environmental science and technology. It is one of the most salient emerging disciplines amongst many in the fields of engineering, science and social science. Energy Technology research covers many areas, including sustainable technology, conventional technology, and energy efficiency and conservation. The interdisciplinary postgraduate research program in Energy Technology in the School of Engineering at the Hong Kong University of Science and Technology provides long-term support to our ongoing educational training and fast-developing research in technology in general.

Due to the multi-disciplinary nature of Energy Technology, research and training in the field is integrated with different disciplines so that students can be equipped with the necessary knowledge and experience. The School of Engineering has introduced an Energy Technology Concentration in different disciplines including Chemical and Biomolecular Engineering, Civil and Environmental Engineering, Computer Science and Engineering, Electronic and Computer Engineering, Industrial Engineering and Logistics Management and Mechanical Engineering. Students can enroll in a particular discipline for research with a special focus on topic(s) in Energy Technology.

The Energy Technology Concentration is open exclusively to research postgraduates in the School of Engineering. Students interested in energy technology can enroll in one of the following research degree programs:
-MPhil/PhD in Chemical Engineering and Biomolecular Engineering
-MPhil/PhD in Civil Engineering
-MPhil/PhD in Computer Science and Engineering
-MPhil/PhD in Electronic and Computer Engineering
-MPhil/PhD in Industrial Engineering and Logistics Management
-MPhil/PhD in Mechanical Engineering

Research Foci

The School of Engineering has unrivaled strength in Energy Technology with a strong team of more than 40 faculty members working in one or multiple topics related to energy. The following core research areas represent the current expertise and research activities across the six departments in the School:

Sustainable Technology
Sustainable energy sources including all renewable sources, such as plant matter, solar power, wind power, wave power, geothermal power and tidal power, improving energy efficiency, fuel cells for transportation and power generation, nanostructured materials for energy storage devices including fuel cells, advanced batteries and supercapacitors, nanostructured electrodes, graphene-based anode and cathode materials, battery system and package management, organic and inorganic photovoltaic materials, gasification of biomass for energy production, biorefinery and bioprocessing for energy generation, and innovative technologies for converting and recovering solid wastes into energy.

Production of Ethanol from Cellulosic Materials
Enhanced use of biogas produced from microbial conversion in landfills of municipal solid wastes, wastewater, industrial effluents, and manure wastes, use of planted forests for production of electricity either by direct combustion or by gasification, use of highly efficient gas turbines, energy scavenging for mobile and wireless electronics which enable systems to scavenge power from human activity or derive limited energy from ambient heat, light, radio, or vibrations.

Conventional Technology
Three main types of fossil fuels, namely coal, petroleum, and natural gas, liquefied petroleum gas (LPG) derived from the production of natural gas, nuclear energy, solid waste treatment and management, radioactive waste treatment, reactor materials, durability and fracture mechanics of reactor materials and structure, nuclear reprocessing, environmental effect of nuclear power, hydropower dam structures, turbine materials and design, hydrology and sediment, water quantity and quality, sources of water, environmental consideration in the design of waterway systems, advanced technologies for conventional energy production, such as gas hydrates, microwave refining, and synthetic fuel involving the conversion process from coal, natural gas and biomass into liquid fuel.

Energy Efficiency and Conservation
In electronics: energy integration for chemical and energy industries, energy-efficient computation, high-efficiency power electronics, power management integrated circuits, low power ICs, green radio, customized building for energy-saving, LED for solid state lighting, smart grids, wireless sensor networks, battery-powered electronics, and mobile electronics. In energy-efficient building: lightweight heat-insulating building material, customized building for energy-saving, energy-saving from solid state lighting.

Economy and Society
Clean production process for reducing material consumption and pollution, software for waste minimization and pollution prevention, green materials for industrial application and building environment, hazards impacting environmental health, analysis of environmental risk, socio-economic and life-cycle analysis for policy-making and planning, novel compounds from marine organisms, and policy on efficient energy use.

Facilities

A total of six research centers are actively involved in energy-related topics: the Center for Sustainable Energy Technology, Center for Display Research, Center for Advanced Microsystems Packaging, Finetex-HKUST R&D Center, Photonics Technology Center, and Building Energy Research Center at Nansha.

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This course is accredited by the Institution of Engineering and Technology. This course, for graduates with a background in electronics, was designed with industry experts and is ideal for those aiming to enter a range of specialist careers in digital electronics or communications. Read more
This course is accredited by the Institution of Engineering and Technology.

This course, for graduates with a background in electronics, was designed with industry experts and is ideal for those aiming to enter a range of specialist careers in digital electronics or communications.

Gain advanced theoretical and practical knowledge and skills in digital communications, signal processing, electronic circuits and microprocessors, as well as an understanding of engineering best practice and how to apply it in real-life scenarios.

The course will provide you with academic and technical skills to analyse, synthesise, interpret and make sense of modern electronic systems. It will enable you to meet the demands of tomorrow’s engineering society.

Intermediate qualifications available:
• Postgraduate certificate – 60 credits at Masters level
• Postgraduate diploma – 120 credits at Masters level

This course is offered via block delivery. There are two entry points (October and November). This allows you to start when it is most suitable.

Visit the website: https://www.beds.ac.uk/howtoapply/courses/postgraduate/next-year/electronic-engineering-ucmk-15-months

Course detail

• Study in an electronic laboratory environment, gaining valuable hands-on experience as well as opportunities for industry connections including National Instruments, Rhode & Schwarz and Axis Electronics
• Explore topics including applied microwave and optical communications, systems engineering, embedded sensors, controllers and energy, advanced digital signal processing, microprocessor architecture and embedded hardware, advanced digital communications, wireless sensor networks, optical communications and other exciting emerging technologies such as energy harvesting
• Develop practical skills in laboratory sessions in which you will build and work with your own electronic devices
• Gain skills and insight into a fast-changing area on a course accredited by the Institute of Engineering & Technology (IET), making you well-prepared to enter a demanding and exciting industry
• Benefit from developing expertise and understanding of professional standards to allow you to access careers like electronic systems design, as a development engineer, in software design, as an embedded systems engineer, a communications engineer, product support engineer, technical consultant or further study on an MSc by Research, MPhil or PhD.

Modules

• Network Systems and Administration
• Accounting and Finance
• The Telecoms Business Environment
• Research Methodologies and Project Management
• MSc Project – Telecommunications Management

Assessment

The majority of units are assessed through coursework, group and individual projects, portfolios, essays, presentations or exams. Presentations are usually given and assessed in a group seminar. You will also produce software artefacts in the area of your specialism.

Constant feedback and advice from a supervisory or unit team will be provided to support you in your work.

You will progress from well-defined briefs to more open-ended and challenging assessments, which culminate in your major project – the MSc Project – where you will be given freedom to choose your area of work.

Careers

You will gain valuable skills for a career within Electronic Engineering as well as those relevant for the wider areas such as computer science or system engineering.

The unit ‘Professional Project Management’ requires you to work in a team to apply current project management methodology that embraces all of these knowledge areas in an integrated way while going through the stages of planning, execution and project control. You will work as part of a team, take responsibility and make autonomous decisions that impact on the project team performance.

Funding

For information on available funding, please follow the link: https://www.beds.ac.uk/howtoapply/money/scholarships/pg

How to apply

For information on how to apply, please follow the link: https://www.beds.ac.uk/howtoapply/course/applicationform

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This programme is designed as a specialised extension to the study of electronics at undergraduate level. The programme provides students with specialist expertise across a wide range of electronic subjects including microelectronics, hardware design, communications, computer design and digital hardware. Read more

Aim

This programme is designed as a specialised extension to the study of electronics at undergraduate level. The programme provides students with specialist expertise across a wide range of electronic subjects including microelectronics, hardware design, communications, computer design and digital hardware. The programme is normally full-time, starts at the end of September and lasts for 12 months. Electronics with Professional Internship students have the opportunity to complete an industrial placement of up to six months as part of their studies.

Programme Content

The MSc programme consists of a practical project of a research nature (60 CATS points) plus six modules (120 CATS points)
The Postgraduate Diploma programme consists of six modules (120 CATS points).

Modules for both programmes are selected from the list below:

Digital Signal Processing
Intelligent Systems and Control
High Frequency Technology and Design
Microelectronic Devices & Technology
MEMS Devices & Technology
Wireless Communications Systems
Wireless Sensor Systems

In any given year further specialist topics may be available for selection or listed topics may not be offered.

Assessment

Assessment for MSc in Electronics: Coursework and written examination in six modules, dissertation on project.
Postgraduate Diploma: Coursework and written examination in six modules.

Career Opportunities

Our graduates have found that holding a prestigious MSc qualification from one of the UK's top engineering schools has significantly enhanced their job opportunities and employment prospects.

Graduates typically find employment in a wide range of fields including with semiconductor companies, electronic equipment manufacturers, design and service providers, software houses and in other electronic engineering-based industries.

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NOTE Are you a student from outside the EU? If you are an international student we have designed a version of this award especially for you! It is called the Extended International Master in Telecommunication Engineering. Read more
NOTE Are you a student from outside the EU? If you are an international student we have designed a version of this award especially for you! It is called the Extended International Master in Telecommunication Engineering. It includes an extra semester of preliminary study to prepare you for postgraduate learning in the UK. We strongly recommend that all international students take this option as it is proven to improve your chances of success.

About this Course Telecommunication engineering encompasses the design and optimisation of communication networks for voice, data and multimedia applications. This award will provide students with an indepth knowledge and skills of computer communication, telecommunication networks, project management and research methods. This award aims to produce postgraduates with the knowledge and skills to enable them to enhance their career opportunities, which is relevant to the fast paced changing needs of the telecommunications and related industries.

Course content

The MSc in Telecommunication Engineering will give you a deep understanding of the principles of Telecommunication Systems

Modules Offered: Teaching Block 1
-Digital Signal Processing
-Cellular Network Planning Principles
-Voice and Data over Broadband Network
-Wireless Sensor Networks & IOT: Principles and Practices
-Digital Electronic Systems

Teaching Block 2
-Telecommunications
-Wireless Navigation Systems
-Optical Fibre Communication Systems
-Research Methods and Project Management

Teaching Block 3
-MSc Project

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The MSc by research ­ Engineering provides a flexible framework if you're an engineering graduate intending to specialise in a specific area of interest, such as aircraft design, robotics system development, vehicle performance or intelligent systems. Read more
The MSc by research ­ Engineering provides a flexible framework if you're an engineering graduate intending to specialise in a specific area of interest, such as aircraft design, robotics system development, vehicle performance or intelligent systems. You will study an engineering research topic in depth during your project dissertation, while working closely with academic experts in the related field and taking advantage of our world-class facilities.

Course detail

UWE Bristol Engineering's strong industry and international academic links give you the opportunity to gain additional industrial experience through an industry-linked project. The course also provides a solid platform for those who wish to pursue higher postgraduate degrees, such as an MPhil or PhD, or gain the necessary skills to become a professional engineering practitioner with additional specialisation in your own field of interest.

Structure

You qualify for the awards MSc Research (Engineering), and Postgraduate Certificate by accumulating credits completion modules as follows:

• The MSc Research (Engineering) requires 180 credits, including 120 credits from the dissertation and 60 credits from the taught component.

• The Postgraduate Certificate in Engineering requires 60 credits, all from the taught part of the course (no dissertation is completed).

Modules

• Project Dissertation
• Research Investigation, Planning and Methods for Change
• Research Portfolio
• Research Methods
• Computer Vision and Modern Control
• Innovations in Operations Management
• Design of Fluid Systems
• Structural Integrity in Design
• Industrial Applications of Vision and Automation
• Robotics Mechanics, Intelligence and Programming
• Lean Engineering and Decision Support Tools for Continuous Improvement
• Electromechanical Systems Integration
• Concurrent Engineering
• Flight Test and Airworthiness
• Aerospace Manufacturing Technology
• Aerodynamics C
• Aircraft Structural Design
• Aero-elasticity
• Aero-acoustics
• Embedded Real Time Control Systems
• Wireless and Mobile Communications
• Safety Critical Embedded Systems
• System Design Using HDLs
• Advanced Control and Dynamics
• Wireless Sensor Networks

Format

In common with other MScs in the faculty, MSc Research (Engineering) is delivered through a combination of taught modules and an in-depth dissertation.

Assessment

You are usually assessed through a combination of examinations, coursework and the dissertation.

Careers / Further study

This course produces graduates capable of ground-breaking research with an in-depth specialisation in a particular area of engineering interest.

On completing this course you will be equally ready to continue onto MPhil and PhD programmes or take a role in a senior technical position in a wide range of industry sectors.

How to apply

Information on applications can be found at the following link: http://www1.uwe.ac.uk/study/applyingtouwebristol/postgraduateapplications.aspx

Funding

- New Postgraduate Master's loans for 2016/17 academic year –

The government are introducing a master’s loan scheme, whereby master’s students under 60 can access a loan of up to £10,000 as a contribution towards the cost of their study. This is part of the government’s long-term commitment to enhance support for postgraduate study.

Scholarships and other sources of funding are also available.

More information can be found here: http://www1.uwe.ac.uk/students/feesandfunding/fundingandscholarships/postgraduatefunding.aspx

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This course is accredited by the Internationally recognised Institution of Engineering and Technology. This course, for graduates with a background in electronics, was designed with industry experts and is ideal for those aiming to enter a range of specialist careers in digital electronics or communications. Read more
This course is accredited by the Internationally recognised Institution of Engineering and Technology.

This course, for graduates with a background in electronics, was designed with industry experts and is ideal for those aiming to enter a range of specialist careers in digital electronics or communications.

Gain advanced theoretical and practical knowledge and skills in digital communications, signal processing, electronic circuits and microprocessors, as well as an understanding of engineering best practice and how to apply it in real-life scenarios.

Intermediate qualifications available:

• Postgraduate certificate – 60 credits at Masters level
• Postgraduate diploma – 120 credits at Masters level

There are six entry points through the year. This allows you to start when it is most suitable. The entry points are:

• September
• November
• January
• March
• June
• July

Visit the website:
Luton - https://www.beds.ac.uk/howtoapply/courses/postgraduate/next-year/electronic-engineering2#about
Milton Keynes - https://www.beds.ac.uk/howtoapply/courses/postgraduate/next-year/electronic-engineering

Course detail

• Study in an electronic laboratory environment, gaining valuable hands-on experience as well as opportunities for industry connections including National Instruments, Rhode & Schwarz and Axis Electronics
• Explore topics including applied microwave and optical communications, systems engineering, embedded sensors, controllers and energy, advanced digital signal processing, microprocessor architecture and embedded hardware, advanced digital communications, wireless sensor networks, optical communications and other exciting emerging technologies such as energy harvesting
• Develop practical skills in laboratory sessions in which you will build and work with your own electronic devices
• Gain skills and insight into a fast-changing area on a course accredited by the Institute of Engineering & Technology (IET), making you well-prepared to enter a demanding and exciting industry
• Benefit from developing expertise and understanding of professional standards to allow you to access careers like electronic systems design, as a development engineer, in software design, as an embedded systems engineer, a communications engineer, product support engineer, technical consultant or further study on an MSc by Research, MPhil or PhD.

Modules

• Digital, Microwave and Optical Communications
• Wireless Embedded Systems
• Signals and Electronic Systems
• Research Methodologies and Project Management
• MSc Project – Electronic Engineering

Assessment

The majority of units are assessed through coursework, group and individual projects, portfolios, essays, presentations or exams. Presentations are usually given and assessed in a group seminar. You will also produce software artefacts in the area of your specialism.

Constant feedback and advice from a supervisory or unit team will be provided to support you in your work.

You will progress from well-defined briefs to more open-ended and challenging assessments, which culminate in your major project – the MSc Project – where you will be given freedom to choose your area of work.

Careers

You will gain valuable skills for a career within Electronic Engineering as well as those relevant for the wider areas such as computer science or system engineering.

The unit ‘Professional Project Management’ requires you to work in a team to apply current project management methodology that embraces all of these knowledge areas in an integrated way while going through the stages of planning, execution and project control. You will work as part of a team, take responsibility and make autonomous decisions that impact on the project team performance.

Funding

For information on available funding, please follow the link: https://www.beds.ac.uk/howtoapply/money/scholarships/pg

How to apply

For information on how to apply, please follow the link: https://www.beds.ac.uk/howtoapply/course/applicationform

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