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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.

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.

Read less
Information technology (IT) is all around us, forming the very destiny of our lives…our world. IT advances a wide array of disciplines, such as engineering, business and medicine, and even art and archaeology. Read more
Information technology (IT) is all around us, forming the very destiny of our lives…our world. IT advances a wide array of disciplines, such as engineering, business and medicine, and even art and archaeology.

The Master of Information Technology (MIT) provides the knowledge, understanding and skills to solve real-world problems with cutting-edge technology. You learn to create innovative IT solutions in your chosen area, in order to work in the industry at the highest levels.

As an MIT graduate, you could become a software engineer, an enterprise data architect, a mobile systems analyst, or even a chief technology officer.

The MIT caters to students from a variety of backgrounds. If you do not have previous training in IT, the course includes preparatory units that will give you the IT knowledge needed for the remainder of the course. However, if you already have a degree in IT, you can accelerate your study with an exemption from these preparatory units, or perhaps study further elective units in areas of your choice.

The course offers you the opportunity to explore a wide range of areas, such as software engineering, mobile and distributed systems, project management and machine learning.

In your final semester, you may take part in an Industry Experience program, working in a small team with industry mentors to develop entrepreneurial IT solutions. Or you may undertake a minor-thesis research project, investigating cutting-edge problems in IT under the supervision of internationally recognised researchers.

High-achieving students who complete the research component may progress to further research study.

The MIT is accredited with the Australian Computer Society (ACS).

Visit the website http://www.study.monash/courses/find-a-course/2016/information-technology-c6001?domestic=true

Overview

This course prepares students for work in the information technology industry at the highest levels. It provides students with a previous tertiary qualification in another discipline area with the knowledge, understanding and skills to enable them to deal effectively with advanced issues involving the application of information technology.

Students with previous studies in a technical IT area can complete in three semesters (full-time) by applying for credit for foundation units.

Career opportunities

Graduates of the MIT will have the knowledge and skills to solve complex social, economic and technical problems within the context of information technology. Students will develop deep theoretical and practical knowledge in specific areas so that they will have the intellectual and conceptual foundation to play leading roles in the development of the information technology industry.

Course Structure

PART A. Foundations for advanced information technology studies
These studies will provide an orientation to the field of information technology at graduate level. They are intended for students whose previous qualification is not in a cognate field.

PART B. Core Master's study
These studies draw on best practices within the broad realm of IT application, theory and practice. You will gain an understanding of information technology real world IT problems and gain problem solving skills. Your study will focus on IT project management, software, network and systems areas.

PART C. Advanced practice
The focus of these studies is professional or scholarly work that can contribute to a portfolio of professional development. You have two options.

The first option is a research pathway including a thesis. Students wishing to use this Masters course as a pathway to a higher degree by research should take this first option. For students to be able to progress to HDR, this course must have a minimum 12 points of research.

The second option is a program of coursework involving advanced study and an Industry experience studio project.

Students admitted to the course, who have a recognised honours degree in a discipline cognate to information technology, will receive credit for PART C, however, should they wish to complete a 24 point research project as part of the course they should consult with the course coordinator.

For more information visit the faculty website - http://www.study.monash/media/links/faculty-websites/information-technology

Find out how to apply here - http://www.study.monash/courses/find-a-course/2016/information-technology-c6001?domestic=true#making-the-application

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This programme is designed to meet the demands of the increasing use of mobile devices, which are being coupled with cloud computing to provide applications and services to users and enterprises. Read more
This programme is designed to meet the demands of the increasing use of mobile devices, which are being coupled with cloud computing to provide applications and services to users and enterprises.

About the programme

A number of prominent technology experts, including Apple CEO Tim Cook, have been proclaiming the focus of software innovation has nearly completely shifted from an emphasis on developing tools for use on full-size personal computers to developing for mobile devices.

The MSc Mobile Web Development programme intends to develop these skills and produce graduates who are in a position to target employment opportunities in software development for the mobile web.

Your learning

Many of the learning outcomes are practical and a large proportion of class time is spent in computing laboratories engaging with the appropriate tools and acquiring practical knowledge. Theoretical knowledge is provided through lectures, tutorials, seminars and individual study. Active learning is promoted through practical assignments. Certain classes and assignments involve problem-solving through analysis, evaluation and the synthesis of a solution reflecting the practical emphasis of the programme.

To achieve a Postgraduate Diploma you must successfully complete the core modules including:
• Web Development
• Mobile and Web Design
• Computing for the Mobile Web
• Ethics for the IT Professional
• Dynamic Web Applications
• Mobile Development
• Security for the Mobile Web
• Research Design and Methods

Msc

The Masters research project and dissertation is necessary for those students seeking an MSc in Mobile Web Development. Part-time students may exit the course with a Postgraduate Certificate in Web Development (as opposed to Mobile Web Development) after completing one of the following module combinations successfully: Web Development and Computing for the Mobile Web with; Dynamic Web Applications or Mobile and Web Design; and Ethics for the IT Professional or Security for the Mobile Web.

Our Careers Adviser says

Graduates are poised for employment opportunities in software development for the mobile web and are well-equipped to undertake employment as mobile and web application developers.

Professional recognition

Accreditation is being sought from the British Computer Society.

Financial support

A limited number of scholarships were available in 2015 – check our website for updates on 2016 information.

Cutting-edge facilities

As you would expect, we offer access to high-quality computing and state-of-the-art software systems as well as tried and tested in demand technologies such as Oracle, CIW, Adobe, CISCO, SAP and Microsoft.

Research and collaboration

We have a proven track record in knowledge and technology transfer in the form of applied research, training and consultancy. More than 65% of our research outputs were rated as world-leading and internationally excellent in the Research Excellence Framework 2014. We are proud that our research expertise informs teaching and our students are taught by academic staff who are at the forefront of their profession.

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Build cutting edge applications for phones, tablets and other mobile devices by studying a course developed by professionals for professionals. Read more
Build cutting edge applications for phones, tablets and other mobile devices by studying a course developed by professionals for professionals.

There is an overwhelming demand in the software and games industry for highly skilled application developers and we have launched this short course so you can create mobile application software and content for platforms such as iOS (iPhone) and Android.

The course is split into two key areas - Mobile Application Development and Mobile Games Prototyping - providing you with an opportunity practice your skills and develop professional standard mobile applications through project work.

If you are already working in the software development industry, this is excellent opportunity for professional development. You will look at the development of applications using two approaches - a WYSIWYG editor system and through the use of coding.

We'll enhance your understanding of the design and development of mobile device applications and, in addition to this, show you how applications can be used to benefit a range of business environments.

Visit the website http://courses.leedsbeckett.ac.uk/mobileappdevelopment_apd

Mature Applicants

Our University welcomes applications from mature applicants who demonstrate academic potential. We usually require some evidence of recent academic study, for example completion of an access course, however recent relevant work experience may also be considered. Please note that for some of our professional courses all applicants will need to meet the specified entry criteria and in these cases work experience cannot be considered in lieu.

If you wish to apply through this route you should refer to our University Recognition of Prior Learning policy that is available on our website (http://www.leedsbeckett.ac.uk/studenthub/recognition-of-prior-learning.htm).

Please note that all applicants to our University are required to meet our standard English language requirement of GCSE grade C or equivalent, variations to this will be listed on the individual course entry requirements.

Careers

As the mobile device application industry continues to expand, the demand for highly-skilled professionals also increases. You will be able to offer employers expertise in creative content design alongside technical software development skills that can be applied to industries around the world.

A more entrepreneurial route is also available to you, setting up your own business and bringing apps to market. Our teaching team can provide support and advice if this is something you wish to pursue.

- Application Developer
- Software Developer
- Web Developer
- Applications Designer

Careers advice: The dedicated Jobs and Careers team offers expert advice and a host of resources to help you choose and gain employment. Whether you're in your first or final year, you can speak to members of staff from our Careers Office who can offer you advice from writing a CV to searching for jobs.

Visit the careers site - https://www.leedsbeckett.ac.uk/employability/jobs-careers-support.htm

Course Benefits

You will be taught by experts in the field - software developers, creative designers, games designers and technologists - staff who will give you help and advice with your career or with setting up your own entrepreneurial activities.

You will also benefit from our strong links with industry, with access to our guest speakers programme and industry led seminars, developing your knowledge through the experience of respected professionals in the sector.

We have excellent equipment and resources including state-of-the-art laboratories supporting software development, 2D and 3D content design, audio content production and high level content creation tools.

Modules

Mobile Games Prototyping
Develop advanced skills and a systematic understanding of the key aspects in mobile games prototyping.

Mobile Application Development
Investigate the architectures, platforms and techniques available to build applications for mobile devices.

Meg Soosay

Senior Lecturer

"Recent years have seen a massive growth in the development of apps for mobile devices. We’ll provide you with the opportunity to design and develop quality mobile applications for the growing market, teaching you the problems at the forefront of app development and how to overcome them."

Meg has extensive background in designing and evaluating positive user experiences using computing devices. She applies e-learning methods in her teaching, having worked on a number of JISC and EU-funded projects such as PC3 and EuroPlot. Your teaching team also includes Patrick Ingham, who has been working with android development since the first handsets arrived in the UK. Patrick is a great believer in mobile offering new ways of doing things and crafting better user experiences.

Facilities

- Library
Our libraries are two of the only university libraries in the UK open 24/7 every day of the year. However you like to study, the libraries have got you covered with group study, silent study, extensive e-learning resources and PC suites.

- Broadcasting Place
Broadcasting Place provides students with creative and contemporary learning environments, is packed with the latest technology and is a focal point for new and innovative thinking in the city.

Find out how to apply here - http://www.leedsbeckett.ac.uk/postgraduate/how-to-apply/

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This advanced Master's programme in Mobile Application Development prepares students to develop applications for these devices, equipping you to become highly skilled professionals for the Mobile Industry with the latest skill set. Read more
This advanced Master's programme in Mobile Application Development prepares students to develop applications for these devices, equipping you to become highly skilled professionals for the Mobile Industry with the latest skill set.

The programme combines technology, interface design and application development for mobile platforms, with a particular emphasis on developing iPhone and iPad apps and creating apps with high usability and reliability.

On completion of the course, you will have gained skills in the latest technologies in this rapidly expanding and developing field.

Visit the website https://www.kent.ac.uk/courses/postgraduate/257/mobile-application-design

About the School of Engineering and Digital Arts

The School of Engineering and Digital Arts successfully combines modern engineering and technology with the exciting new field of digital media.

Established over 40 years ago, the School has developed a top-quality teaching and research base, receiving excellent ratings in both research and teaching assessments.

The School undertakes high-quality research that has had significant national and international impact, and our spread of expertise allows us to respond rapidly to new developments. Our 30 academic staff and over 130 postgraduate students and research staff provide an ideal focus to effectively support a high level of research activity. There is a thriving student population studying for postgraduate degrees in a friendly and supportive teaching and research environment.

We have research funding from the Research Councils UK, European research programmes, a number of industrial and commercial companies and government agencies including the Ministry of Defence. Our Electronic Systems Design Centre and Digital Media Hub provide training and consultancy for a wide range of companies. Many of our research projects are collaborative, and we have well-developed links with institutions worldwide.

Course structure

The MSc begins in late September and finishes in September of the following year, and consists of approximately six months of coursework followed by a short period reserved for examinations and a four-month project.

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

EL880 - HCI For Mobiles (15 credits)

EL881 - Android Application Design (15 credits)
This module is concerned with the design, implementation and testing of applications for the Android operating system. Students will work at all stages of the development life-cycle from inception to testing, whilst considering usability and device capabilities for a mobile application capable of meeting a functional specification.

EL882 - iPhone Application Design (15 credits)
This module is concerned with the design, implementation and testing of applications for the iPhone. Students will work at all stages of the development life-cycle from inception to testing, whilst considering usability and device capabilities for a mobile application capable of meeting a functional specification.

EL883 - Mobile Web Development (15 credits)

EL884 - Mobile Application Design Project (30 credits)
A mobile application will be developed for a platform agreed between the student and the supervisor either in an industrial context or within the School.

EL885 - Research Methods and Project Design for Mobile Apps (15 credits)

CO871 - Advanced Java for Programmers (15 credits)
This module provides for well-qualified computer science students entering the MSc programme from a range of backgrounds. These students will have good programming skills but will not necessarily have used Java or another object-oriented language extensively. This module seeks to ensure that students have the Java and object-oriented design skills necessary for the rest of their programme.

CO881 - Object-Oriented Programming (15 credits)
This module provides an introduction to object-oriented programming using the popular Java language. It is designed for beginners who have not studied computer programming before. By the end students will be able to develop simple programmes using Java. (Note that students with substantial prior experience of programming take module CO871 Advanced Java for Programmers[1] instead.)

EL890 - MSc Project (60 credits)
A major practical system will be developed either in an industrial context or within the department. There are no formal lectures - students will undertake the work in their own time under the regular supervision of a member of the academic staff and, where appropriate, industrial collaborators.

Assessment

The project module is examined by a presentation and dissertation. The Research Methods and Project Design module is examined by several components of continuous assessment. The other modules are assessed by examinations and smaller components of continuous assessment. MSc students must gain credits from all the modules (180 credits in total). For the PDip, you must gain at least 120 credits in total, and pass certain modules to meet the learning outcomes of the PDip programme.

Programme aims

This programme aims to:

- educate graduate engineers and equip them with advanced knowledge of the technology required to deliver applications and web content to mobile devices

- produce high-calibre designers versed in modern interaction design methodology who are able to develop mobile applications with high usability

- provide you with proper academic guidance and welfare support

- create an atmosphere of co-operation and partnership between staff and students, and offer you an environment where you can develop your potential

- to strengthen and expand opportunities for industrial collaboration with the School of Engineering and Digital Arts.

Careers

We have developed the programme with a number of industrial organisations, which means that successful students will be in a strong position to build a long-term career in this important discipline.

The School of Engineering and Digital Arts (http://www.eda.kent.ac.uk/) has an excellent record of student employability (http://www.eda.kent.ac.uk/school/employability.aspx). We are committed to enhancing the employability of all our students, to equip you with the skills and knowledge to succeed in a competitive, fast-moving, knowledge-based economy.


Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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An astonishing global revolution has taken place in mobile and satellite communications, the full impact of which is difficult to exaggerate. Read more
An astonishing global revolution has taken place in mobile and satellite communications, the full impact of which is difficult to exaggerate. The resulting growth in mobile and satellite communications industries has created a high demand for graduates with expertise in the key areas of digital, mobile and satellite communications and networking.

With significant input from industry, this course produces highly competent graduates who can fill key positions and play leading roles in shaping this rapidly evolving field. By graduation, you will be well-equipped to develop new engineering applications for the next generation of communication systems. You will also be given the chance to undertake a six-month unpaid internship*.

Your studies will include advances in antennas and propagation, digital transmission, satellite communications, mobile communications, satellite networks, wireless applications, digital signal processing and product management. All this is enriched with seminars, field trips and a period of internship* in industry. You will also learn to use the latest engineering design tools, including the Systems ToolKit (STK) used by NASA for planning space missions.

Routes of study:
The course is available to study via two routes:
- MSc Mobile and Satellite Communications (with internship)
- MSc Mobile and Satellite Communications (without internship)

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

See the website http://courses.southwales.ac.uk/courses/1431-msc-mobile-and-satellite-communications-with-internship

What you will study

You will study the following modules:
- Mobile Communication Technologies
- Satellite Communications
- Digital Communications Systems
- Applied Digital Signal Processing
- Product Management and Integrating Case Studies
- Six month Internship
- MSc Major Project

Optional modules:
- Wireless and Personal Communications
- Satellite Networking

Learning and teaching methods

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

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

MSc Mobile and Satellite Communications (with internship):

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


MSc Mobile and Satellite Communications (without internship):

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

Work Experience and Employment Prospects

Advancements in technology such as the increased use of Wi-Fi, are creating exciting career opportunities for graduates with the right skills. Graduates of this Masters award can enter the telecommunications industry in many different roles, conduct research or work towards a PhD.

Internship

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

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

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

Assessment methods

Each of the six taught modules is typically assessed through 50% coursework and 50% closed-book class test. The major project is assessed through presentation to a panel of examiners, viva and written report.

Facilities

A state-of-the-art University library gives you access to most of the world’s leading publications. Other major facilities include a Cisco Academy networking laboratory, a Wireless Communications laboratory including a 1-65 GHz anechoic chamber and a satellite communication earth station, and a Communication Systems simulation laboratory equipped with PCs running the latest versions of MATLAB, SIMULINK, STK and other software.

In addition, we have recently opened a Calypto lab, which has software licences and support for the Catapult C toolset. This is used to develop advanced electronic products, such as the next generation of smart phones, more quickly and cost-effectively and to help engineers overcome design challenges in the increasingly complex world of board and chip design. The lab is sponsored by Calypto Design Systems Inc, a leader in electronic design automation. We are one of only four UK universities and 60 universities globally that have been granted permission to use the software worth £1.9m.

The new Renesas Embedded Systems lab comprises 25 new high-end terminals running cuttingedge tools. The facility was designed in collaboration with Renesas, the world’s leading supplier of microcontrollers, whose sponsorship helps ensure that students are always working with the latest technologies and development tools.

Teaching

The course is led by Professor Otung, a Chartered Engineer and internationally acclaimed author of Communication Engineering textbooks used in leading universities around the world, and supported by an impressive and highly-qualified teaching and supervision team. Generations of graduates from this course speak very highly of not only the cutting-edge expertise and technical skills that they developed on the course but also of the inspiration, professionalism and friendship of the entire teaching team.

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The longest established MSc in Health Informatics in Europe, focusing on cutting-edge skills for delivering informatics-led healthcare. Read more
The longest established MSc in Health Informatics in Europe, focusing on cutting-edge skills for delivering informatics-led healthcare.

Who is it for?

This course is for health professionals who wish to enhance their careers with an informatics qualification, and computer scientists, engineers and others with relevant technical or professional qualifications who wish to move into a successful career involving the application of informatics in the health service.

You will have a keen interest in developing high-quality and sustainable healthcare through the application of informatics solutions and a desire to be part of the newest and fastest growing specialty in health care.

Objectives

The Health Informatics MSc at City University London aims to develop future leaders in the field who will transform healthcare with informatics-led approaches.

High-quality teaching is a healthy balance of theory and practice, with a strong focus on real-world applications including EHR systems, clinical data analytics, mobile technology and telemedicine. University teaching is supported by guest lectures from medicine and industry and you will also benefit from City University's central location close to many hospitals. Further, you will be part of a highly multi-professional and strongly international cohort bringing together multiple points of view on national and international computerized healthcare initiatives.

Health Informatics at City University London is the only such MSc in the UK to be accredited by the British Computer Science Society.

Academic facilities

Lectures, tutorials and workshops are delivered in small classrooms equipped with state-of-the-art interactive technologies. The University’s computer science laboratories are equipped with modern and up-to-date hardware and software required for you to progress through your studies.

Teaching and learning

High-quality teaching is delivered by research-active academic experts in Health Informatics from City University London. Furthermore university teaching is supported by guest lectures from medicine and industry.

Teaching is a healthy balance of theory and practice, with a strong focus on real-world applications including EHR systems, clinical data analytics, mobile technology and telemedicine. You will also undertake an independent research project.

All taught modules are delivered through a combination of lectures, online activities and interactive workshops and tutorials and are supported by the University's online learning environment.

Taught modules are generally assessed through a combination of coursework and examination where coursework is worth 30% of the final mark and the examination contributes 70%. Some elective modules are 100% coursework based (e.g. Information Architecture and Project Management). See the full programme specification for details.

The taught component of the MSc is worth 66.67% (eight 15-credit modules) and the independent research project is worth 33.33% (60 credits).

Upon successful completion of eight modules and the independent research project, you will be awarded 180 credits and a masters level qualification. Alternatively, if you do not complete the dissertation but have successfully completed eight modules you will be awarded 120 credits and a postgraduate diploma. Successful completion of four modules (60 credits) will lead to the award of a postgraduate certificate.

Modules

You will study six core modules and two elective modules. You will also undertake an independent research project.

A full time student is expected to commit 35 hours a week which includes attendance at lectures, tutorials and workshops, and independent study on coursework, the individual research project and preparation for examinations.

Taught Core Modules
-Clinical Records
-Data Analysis with Healthcare
-Information for Decisions in Healthcare
-Knowledge Management in Healthcare
-Telemedicine
-Research, Methods and Professional Issues

Taught Elective Modules - choose two options from the following:
-Databases
-Information Architecture
-Project Management
-Programming with Java
-Practices and Theories in Interaction Design

Career prospects

Graduates pursue successful careers in the health service (both state and private sectors in the UK and overseas), and in related healthcare industries such as Electronic Health Record providers.

Specifically graduates have pursued roles such as application analysts, IT project managers, data and taxonomy managers, digital transformation leads, PACS & RIS managers and research informatics programme managers. Other graduates have successfully completed PhD degrees.

The course has a successful track record of producing more than 350 employable graduates over the past 20 years.

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The Mobile and High Speed Telecommunication Networks course is designed to provide you with in-depth knowledge of modern high-speed telecommunication systems and to enhance your professional development in the rapidly expanding field of personal communications. Read more
The Mobile and High Speed Telecommunication Networks course is designed to provide you with in-depth knowledge of modern high-speed telecommunication systems and to enhance your professional development in the rapidly expanding field of personal communications.

This course has two main components: 2G - 4G mobile communications, and fixed high-speed and multi-service networks. Emphasis is given to developing essential industrial and commercial skills. The project is a major element of the course and gives you the opportunity to enhance your career prospects by acquiring in-depth knowledge of a key aspect of telecommunications technology.

Why choose this course?

You will be taught industrially relevant techniques using some of the same tools and software used by the communications industry. Our telecommunications laboratories are equipped for the design, testing and analysis of mobile wireless and optical networks using industry standard tools such Asset, Ranopt, OptSim, OpNet and Matlab. You will have the opportunity to analyse real data from operational 2G and 3G networks and to design 3G and LTE networks.

Our networking laboratories are equipped with modern Cisco routers, switches and security devices to enable design construction and testing of complete high bandwidth secure, wired and wireless networks. You will have the opportunity to put the skills you have gained into practice if you choose to undertake our 1 year optional placement. The universal nature of the technical skills developed in our programmes means our courses are of equal relevance to both new graduates and those with many years of industrial experience.

This course in detail

MSc in Mobile and High Speed Telecommunication Networks has a modular course-unit design providing you with maximum flexibility and choice. To qualify for a master’s degree, you must pass modules amounting to 180 credits. This comprises six taught modules (20 credits each) plus your dissertation (60 credits).

The MSc in Mobile and High Speed Telecommunication Networks with placement enables you to work in industry for a year in the middle of your course to give valuable workplace experience. Placements are not guaranteed, but the departments dedicated placement team will help with the process of finding and applying for placements. To qualify for a master’s degree with placement, you must pass modules amounting to 180 credits plus the zero credit placement module. This comprises six taught modules (20 credits each) plus your dissertation (60 credits).

The Postgraduate Diploma in Mobile and High Speed Telecommunication Networks allows you to concentrate on the taught part of the degree and is ideal for people working in the communications industry who wish to brush up their skills. To qualify for a Postgraduate Diploma, you must pass modules amounting to 120 credits. This comprises six taught modules (20 credits each). In some cases, it may be possible for a student on a Postgraduate Diploma to do 3 taught modules (20 credits each) plus your dissertation (60 credits).

The Postgraduate Certificate in Mobile and High Speed Telecommunication Networks allows you to concentrate on the taught part of the degree and is ideal for people working in the communications industry who wish to learn a specific area in this rapidly changing discipline. To qualify for a Postgraduate Certificate, you must pass modules amounting to 60 credits. This comprises three taught modules (20 credits each).

We also offer a Postgraduate Certificate Mobile and High Speed Telecommunication Networks Research Project.

In Semester 1 you can choose from the following modules:
-Research and Scholarship Methods (compulsory for MSc)
-Digital Mobile Communications (alternative compulsory for MSc and PGDip)
-Digital Communications (alternative compulsory for MSc)
-Network Principles (alternative compulsory for MSc)

In Semester 2 you can choose from the following modules:
-Advanced Mobile Communications (compulsory for MSc and PGDip)
-High Speed Mobile Communications (compulsory for MSc and PGDip)
-Optical and Broadband Networks (alternative compulsory for MSc)
-Multiservice Networks (alternative compulsory for MSc)

As courses are reviewed regularly, the list of taught modules you choose from may vary from the list here.

Students undertaking an MSc with placement will do a 1 year placement in industry. The placement will be undertaken after the taught component and before doing the dissertation.

Students studying for an MSc will also take:
-MSc Dissertation (completed over summer)

Teaching and learning

The taught modules include lectures, seminars, library and internet research, and practical design and experimentation. Assessments include coursework exercises, presentations, essays and examinations (maximum 50% for taught modules).

Teaching staff include experienced academic staff and recent recruits from the telecommunications industry. Visiting speakers give you relevant and up-to-date developments from within the industry.

Laboratory facilities include the latest industry standard tools for mobile and wireless network analysis and software modelling facilities to enable network design.

Careers and professional development

Our MSc students come from all over the world and follow careers in many countries after their graduation. They are engaged in activities such as 3G network design, WiMax and LTE roll-out, handset compliance, DVB-H planning, communications software development and university lecturing. Many of them have commented on how the course content and training enabled their careers to flourish.

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Mobile telephony is reaching saturation in the most technologically advanced countries and is rapidly becoming the main telecommunications infrastructure in the rest of the world. Read more
Mobile telephony is reaching saturation in the most technologically advanced countries and is rapidly becoming the main telecommunications infrastructure in the rest of the world.

This programme gives you a thorough understanding of the engineering aspects of this rapidly developing field, as well as new emerging systems for the support of broadband mobile Internet.

PROGRAMME OVERVIEW

We have a wide range of testbeds available for projects, including wireless networking, wireless sensors, satellite networking, and security testbeds, future internet testbed and cloud infrastructure.

We also have a wide range of software tools for assignments and project work, including OPNET, NS2/3, Matlab, C, C++ and various system simulators. Some projects can offer the opportunity to work with industry.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year, until a total of eight is reached. It consists of eight taught modules and a standard project. The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.
-Digital Communications
-Fundamentals of Mobile Communications
-Principles of Telecommunications and Packet Networks
-RF Systems and Circuit Design
-Internet of Things
-Applied Mathematics for Communication Systems
-Data and Internet Networking
-Advanced Signal Processing
-Advanced Mobile Communication Systems C
-Network and Service Management and Control
-Operating Systems for Mobile Systems Programming
-Mobile Applications and Web Services
-Advanced 5G Wireless Technologies
-Standard Project

EDUCATIONAL AIMS OF THE PROGRAMME

The taught postgraduate Degree Programmes of the Department are intended both to assist with professional career development within the relevant industry and, for a small number of students, to serve as a precursor to academic research.

Our philosophy is to integrate the acquisition of core engineering and scientific knowledge with the development of key practical skills (where relevant).

To fulfil these objectives, the programme aims to:
-Attract well-qualified entrants, with a background in Electronic Engineering, Physical Sciences, Mathematics, Computing & -Communications, from the UK, Europe and overseas
-Provide participants with advanced knowledge, practical skills and understanding applicable to the MSc degree
-Develop participants' understanding of the underlying science, engineering, and technology, and enhance their ability to relate this to industrial practice
-Develop participants' critical and analytical powers so that they can effectively plan and execute individual research/design/development projects
-Provide a high level of flexibility in programme pattern and exit point
-Provide students with an extensive choice of taught modules, in subjects for which the Department has an international and UK research reputation

Intended capabilities for MSc graduates:
-Underpinning learning– know, understand and be able to apply the fundamental mathematical, scientific and engineering facts and principles that underpin mobile and satellite communications
-Engineering problem solving - be able to analyse problems within the field of mobile and satellite communications and more broadly in electronic engineering and find solutions
-Engineering tools - be able to use relevant workshop and laboratory tools and equipment, and have experience of using relevant task-specific software packages to perform engineering tasks
-Technical expertise - know, understand and be able to use the basic mathematical, scientific and engineering facts and principles associated with the topics within mobile and satellite communications
-Societal and environmental context - be aware of the societal and environmental context of his/her engineering activities
-Employment context - be aware of commercial, industrial and employment-related practices and issues likely to affect his/her engineering activities
-Research & development investigations - be able to carry out research-and- development investigations
-Design - where relevant, be able to design electronic circuits and electronic/software products and systems

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

General transferable skills
-Be able to use computers and basic IT tools effectively
-Be able to retrieve information from written and electronic sources
-Be able to apply critical but constructive thinking to received information
-Be able to study and learn effectively
-Be able to communicate effectively in writing and by oral presentations
-Be able to present quantitative data effectively, using appropriate methods
-Be able to manage own time and resources
-Be able to develop, monitor and update a plan, in the light of changing circumstances
-Be able to reflect on own learning and performance, and plan its development/improvement, as a foundation for life-long learning

Underpinning learning
-Know and understand scientific principles necessary to underpin their education in electronic and electrical engineering, to enable appreciation of its scientific and engineering content, and to support their understanding of historical, current and future developments
-Know and understand the mathematical principles necessary to underpin their education in electronic and electrical engineering and to enable them to apply mathematical methods, tools and notations proficiently in the analysis and solution of engineering problems
-Be able to apply and integrate knowledge and understanding of other engineering disciplines to support study of electronic and electrical engineering.

Engineering problem-solving
-Understand electronic and electrical engineering principles and be able to apply them to analyse key engineering processes
-Be able to identify, classify and describe the performance of systems and components through the use of analytical methods and modelling techniques
-Be able to apply mathematical and computer-based models to solve problems in electronic and electrical engineering, and be able to assess the limitations of particular cases
-Be able to apply quantitative methods relevant to electronic and electrical engineering, in order to solve engineering problems
-Understand and be able to apply a systems approach to electronic and electrical engineering problems

Engineering tools
-Have relevant workshop and laboratory skills
-Be able to write simple computer programs, be aware of the nature of microprocessor programming, and be aware of the nature of software design
-Be able to apply computer software packages relevant to electronic and electrical engineering, in order to solve engineering problems

Technical expertise
-Know and understand the facts, concepts, conventions, principles, mathematics and applications of the range of electronic and electrical engineering topics he/she has chosen to study
-Know the characteristics of particular materials, equipment, processes or products
-Have thorough understanding of current practice and limitations, and some appreciation of likely future developments
-Be aware of developing technologies related to electronic and electrical engineering
-Have comprehensive understanding of the scientific principles of electronic engineering and related disciplines
-Have comprehensive knowledge and understanding of mathematical and computer models relevant to electronic and electrical engineering, and an appreciation of their limitations
-Know and understand, at Master's level, the facts, concepts, conventions, principles, mathematics and applications of a range of engineering topics that he/she has chosen to study
-Have extensive knowledge of a wide range of engineering materials and components
-Understand concepts from a range of areas including some from outside engineering, and be able to apply them effectively in engineering projects

Societal and environmental context
-Understand the requirement for engineering activities to promote sustainable development
-Be aware of the framework of relevant legal requirements governing engineering activities, including personnel, health, safety and risk (including environmental risk issues
-Understand the need for a high level of professional and ethical conduct in engineering

Employment context
-Know and understand the commercial and economic context of electronic and electrical engineering processes
-Understand the contexts in which engineering knowledge can be applied (e.g. operations and management, technology development, etc.)
-Be aware of the nature of intellectual property
-Understand appropriate codes of practice and industry standards
-Be aware of quality issues
-Be able to apply engineering techniques taking account of a range of commercial and industrial constraints
-Understand the basics of financial accounting procedures relevant to engineering project work
-Be able to make general evaluations of commercial risks through some understanding of the basis of such risks
-Be aware of the framework of relevant legal requirements governing engineering activities, including personnel, health, safety and risk (including environmental risk) issues

Research and development
-Understand the use of technical literature and other information sources
-Be aware of the need, in appropriate cases, for experimentation during scientific investigations and during engineering development
-Be able to use fundamental knowledge to investigate new and emerging technologies
-Be able to extract data pertinent to an unfamiliar problem, and employ this data in solving the problem, using computer-based engineering tools when appropriate
-Be able to work with technical uncertainty

Design
-Understand the nature of the engineering design process
-Investigate and define a problem and identify constraints, including environmental and sustainability limitations, and health and safety and risk assessment issues
-Understand customer and user needs and the importance of considerations such as aesthetics
-Identify and manage cost drivers
-Use creativity to establish innovative solutions
-Ensure fitness for purpose and all aspects of the problem including production, operation, maintenance and disposal
-Manage the design process and evaluate outcomes
-Have wide knowledge and comprehensive understanding of design processes and methodologies and be able to apply and adapt them in unfamiliar situations
-Be able to generate an innovative design for products, systems, components or processes, to fulfil new needs

Project management
-Be able to work as a member of a team
-Be able to exercise leadership in a team
-Be able to work in a multidisciplinary environment
-Know about management techniques that may be used to achieve engineering objectives within the commercial and economic context of engineering processes
-Have extensive knowledge and understanding of management and business practices, and their limitations, and how these may be applied appropriately

GLOBAL OPPORTUNITIES

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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Surrey is a world leader in satellite communications, broadcasting, terrestrial mobile networks and the Internet. essential components of communication and information infrastructures. Read more
Surrey is a world leader in satellite communications, broadcasting, terrestrial mobile networks and the Internet: essential components of communication and information infrastructures.

This has allowed us to create a Masters programme in this burgeoning field that is delivered by academics and researchers with extensive theoretical expertise and practical experience.

PROGRAMME OVERVIEW

Mobile communications provide terrestrial coverage in densely populated areas, while satellite communications enable wireless communication in regions where mobile networking is not cost-effective. The programme gives you an in-depth understanding of the engineering aspects of these important current and future technologies.

Read about the experience of a previous student on this course, Gideon Ewa.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year, until a total of eight is reached. It consists of eight taught modules and a project. The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.
-Digital Communications
-Fundamentals of Mobile Communications
-Principles of Telecommunications and Packet Networks
-Satellite Communications Fundamentals
-RF Systems and Circuit Design
-Applied Mathematics for Communication Systems
-Data and Internet Networking
-Advanced Signal Processing
-Advanced Mobile Communication Systems
-Networking and Service Management & Control
-Operating Systems for Mobile Systems Programming
-Advanced Satellite Communication Techniques
-Advanced 5G Wireless Technologies
-60-Credit Standard Project

EDUCATIONAL AIMS OF THE PROGRAMME

The programme aims to:
-Attract well-qualified entrants, with a background in Electronic Engineering, Physical Sciences, Mathematics, Computing & Communications, from the UK, Europe and overseas
-Provide participants with advanced knowledge, practical skills and understanding applicable to the MSc degree
-Develop participants' understanding of the underlying science, engineering, and technology, and enhance their ability to relate this to industrial practice
-Develop participants' critical and analytical powers so that they can effectively plan and execute individual research/design/development projects
-Provide a high level of flexibility in programme pattern and exit point
-Provide students with an extensive choice of taught modules, in subjects for which the Department has an international and UK research reputation

Intended capabilities for MSc graduates:
-Underpinning learning– know, understand and be able to apply the fundamental mathematical, scientific and engineering facts and principles that underpin mobile and satellite communications
-Engineering problem solving - be able to analyse problems within the field of mobile and satellite communications and more broadly in electronic engineering and find solutions
-Engineering tools - be able to use relevant workshop and laboratory tools and equipment, and have experience of using relevant task-specific software packages to perform engineering tasks
-Technical expertise - know, understand and be able to use the basic mathematical, scientific and engineering facts and principles associated with the topics within mobile and satellite communications
-Societal and environmental context - be aware of the societal and environmental context of his/her engineering activities
-Employment context - be aware of commercial, industrial and employment-related practices and issues likely to affect his/her engineering activities
-Research & development investigations - be able to carry out research-and- development investigations
-Design - where relevant, be able to design electronic circuits and electronic/software products and systems

PROGRAMME LEARNING OUTCOMES

General transferable skills
-Be able to use computers and basic IT tools effectively
-Be able to retrieve information from written and electronic sources
-Be able to apply critical but constructive thinking to received information
-Be able to study and learn effectively
-Be able to communicate effectively in writing and by oral presentations
-Be able to present quantitative data effectively, using appropriate methods
-Be able to manage own time and resources
-Be able to develop, monitor and update a plan, in the light of changing circumstances
-Be able to reflect on own learning and performance, and plan its development/improvement, as a foundation for life-long learning

Underpinning learning
-Know and understand scientific principles necessary to underpin their education in electronic and electrical engineering, to enable appreciation of its scientific and engineering content, and to support their understanding of historical, current and future developments
-Know and understand the mathematical principles necessary to underpin their education in electronic and electrical engineering and to enable them to apply mathematical methods, tools and notations proficiently in the analysis and solution of engineering problems
-Be able to apply and integrate knowledge and understanding of other engineering disciplines to support study of electronic and electrical engineering

Engineering problem-solving
-Understand electronic and electrical engineering principles and be able to apply them to analyse key engineering processes
-Be able to identify, classify and describe the performance of systems and components through the use of analytical methods and modelling techniques
-Be able to apply mathematical and computer-based models to solve problems in electronic and electrical engineering, and be able to assess the limitations of particular cases
-Be able to apply quantitative methods relevant to electronic and electrical engineering, in order to solve engineering problems
-Understand and be able to apply a systems approach to electronic and electrical engineering problems

Engineering tools
-Have relevant workshop and laboratory skills
-Be able to write simple computer programs, be aware of the nature of microprocessor programming, and be aware of the nature of software design
-Be able to apply computer software packages relevant to electronic and electrical engineering, in order to solve engineering problems

Technical expertise
-Know and understand the facts, concepts, conventions, principles, mathematics and applications of the range of electronic and electrical engineering topics he/she has chosen to study
-Know the characteristics of particular materials, equipment, processes or products
-Have thorough understanding of current practice and limitations, and some appreciation of likely future developments
-Be aware of developing technologies related to electronic and electrical engineering
-Have comprehensive understanding of the scientific principles of electronic engineering and related disciplines
-Have comprehensive knowledge and understanding of mathematical and computer models relevant to electronic and electrical engineering, and an appreciation of their limitations
-Know and understand, at Master's level, the facts, concepts, conventions, principles, mathematics and applications of a range of engineering topics that he/she has chosen to study
-Have extensive knowledge of a wide range of engineering materials and components
-Understand concepts from a range of areas including some from outside engineering, and be able to apply them effectively in engineering projects

Societal and environmental context
-Understand the requirement for engineering activities to promote sustainable development
-Be aware of the framework of relevant legal requirements governing engineering activities, including personnel, health, safety and risk (including environmental risk issues
-Understand the need for a high level of professional and ethical conduct in engineering

Employment context
-Know and understand the commercial and economic context of electronic and electrical engineering processes
-Understand the contexts in which engineering knowledge can be applied (e.g. operations and management, technology development, etc.)
-Be aware of the nature of intellectual property
-Understand appropriate codes of practice and industry standards
-Be aware of quality issues
-Be able to apply engineering techniques taking account of a range of commercial and industrial constraints
-Understand the basics of financial accounting procedures relevant to engineering project work
-Be able to make general evaluations of commercial risks through some understanding of the basis of such risks
-Be aware of the framework of relevant legal requirements governing engineering activities, including personnel, health, safety and risk (including environmental risk) issues

Research and development
-Understand the use of technical literature and other information sources
-Be aware of the need, in appropriate cases, for experimentation during scientific investigations and during engineering development
-Be able to use fundamental knowledge to investigate new and emerging technologies
-Be able to extract data pertinent to an unfamiliar problem, and employ this data in solving the problem, using computer-based engineering tools when appropriate
-Be able to work with technical uncertainty

Design
-Understand the nature of the engineering design process
-Investigate and define a problem and identify constraints, including environmental and sustainability limitations, and health and safety and risk assessment issues
-Understand customer and user needs and the importance of considerations such as aesthetics
-Identify and manage cost drivers
-Use creativity to establish innovative solutions
-Ensure fitness for purpose and all aspects of the problem including production, operation, maintenance and disposal
-Manage the design process and evaluate outcomes
-Have wide knowledge and comprehensive understanding of design processes and methodologies and be able to apply and adapt them in unfamiliar situations
-Be able to generate an innovative design for products, systems, components or processes, to fulfil new needs

Project management
-Be able to work as a member of a team
-Be able to exercise leadership in a team
-Be able to work in a multidisciplinary environment
-Know about management techniques that may be used to achieve engineering objectives within the commercial and economic context of engineering processes
-Have extensive knowledge and understanding of management and business practices, and their limitations, and how these may be applied appropriately

GLOBAL OPPORTUNITIES

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

Read less

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