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Masters Degrees (Software Technology)

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Take advantage of one of our 100 Master’s Scholarships or College of Science Postgraduate Scholarships to study Advanced Software Technology at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships or College of Science Postgraduate Scholarships to study Advanced Software Technology at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students. For more information on fees and funding please visit our website.

Computing is about data, algorithms, programs and computers. It is a young academic discipline and is rich in applications, since computing systems are everywhere: in science and engineering, medicine, design and manufacture, commerce and public service, defence, transportation, arts and the media, and the home.

The MSc Advanced Software Technology is suitable you if you are a Computer Science graduate or have gained some experience of computing and basic programming in your first degree. This programme in Advanced Software Technology will also be of interest to you If you have substantial relevant experience gained from working in a computer related environment for some time and are looking to update or broaden your knowledge.

Key Features of Advanced Software Technology MSc

• We are top in the UK for career prospects*
• We are 3rd in the UK for teaching quality**
• 5th in the UK overall*
• 7th in the UK for student satisfaction with 98% [National Student Survey 2016]
• 7th in the UK overall and Top in Wales*
• High employability prospects - we are 8th in the UK for graduate prospects*
• 92% in graduate employment or further study six months after leaving University [HESA data 2014/15]
• UK TOP 20 for Research Excellence [Research Excellence Framework 2014]
• Our Project Fair allows students to present their work to local industry
• Strong links with industry
• £31m Computational Foundry for computer and mathematical sciences will provide the most up-to-date and high quality teaching facilities featuring world-leading experimental set-ups, devices and prototypes to accelerate innovation and ensure students will be ready for exciting and successful careers. (From September 2018)

*Guardian University Guide 2017
**Times & Sunday Times University Guide 2016

Modules of Advanced Software Technology MSc

Modules for the MSc in Advanced Software Technology include Computer Science Project Research Methods but please visit our course page for more information.

Facilities

The Department of Computer Science is well equipped for teaching, and is continually upgrading its laboratories to ensure equipment is up-to-date – equipment is never more than three years old, and rarely more than two. Currently, our Computer Science students use three fully networked laboratories: one, running Windows; another running Linux; and a project laboratory, containing specialised equipment. These laboratories support a wide range of software, including the programming languages Java, C# and the .net framework, C, C++, Haskell and Prolog among many; integrated programme development environments such as Visual Studio and Netbeans; the widely-used Microsoft Office package; web access tools; and many special purpose software tools including graphical rendering and image manipulation tools; expert system production tools; concurrent system modelling tools; World Wide Web authoring tools; and databases.

As part of the expansion of the Department of Computer Science, we are building the Computational Foundry on our Bay Campus for computer science and mathematical science.

Careers

All Computer Science courses will provide you the transferable skills and knowledge to help you take advantage of the excellent employment and career development prospects in an ever growing and changing computing and ICT industry.

94% of our Postgraduate Taught Graduates of Computer Science were in professional level work or study [DLHE 14/15]

Student profiles

“One of the main reasons I chose Swansea was because of the excellent reputation of the Computer Science Department which is ranked among the top 25 in the UK. The Lecturers in the Department are excellent, and are equally very accessible to students. Many are actively involved in world class research. Their knowledge is shared with us in lectures. I love Swansea. I have recently completed the MSc and intend to gain further experience in the software industry before pursuing a PhD at Swansea University. “

Manikanta Gudur - MSc in Advanced Computer Science Graduate

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You will study in an innovative department with an international reputation for research, training and education in software engineering, with access to facilities and expertise from the Software Technology Research Laboratory (STRL). Read more

About the course

You will study in an innovative department with an international reputation for research, training and education in software engineering, with access to facilities and expertise from the Software Technology Research Laboratory (STRL). Taught by acknowledged experts from the STRL, Software Engineering will equip you with skills you need for industry.

Accredited by the European-wide accreditation system for Informatics curricula, the course is committed to excellence in European-wide software education and training of engineers to deliver high-quality and trustworthy software systems that meet industrial needs. The taught element of the course lasts for the first two semesters, while the third semester is devoted to the project. The total length of study depends on the mode of delivery. .

Reasons to Study

• Gain an industry-recognised accreditation
the course is accredited by the British Computer Society (BCS) to Chartered Engineering (CEng) level

• Taught by expert academic staff
taught by experienced experts within the Software Technology Research Laboratory (STRL) with international reputation for research, training and education in software engineering, with access to specialist facilities

• Specialise your learning to your area of interest
combine modules from across Cyber Security, Cyber Technology, Digital Forensics and Software Engineering, allowing you to tailor the course to your areas of interest

• Flexible study options
full-time, part time or distance learning study options available; making the course suitable for recent graduates and professionals in work

• Benefit from our Research Expertise
our internationally recognised Software Technology Research Laboratory (STRL) will have input into the course and will explore and allow you to understand the current research issues

• Excellent career prospects
graduates have gone on to work in both public and private sector organisations, and have been employed in positions in consultancies and worked for companies including IBM, Deloitte, Airbus and BT

Course Structure

First semester:

• Research Methods
• Advanced Requirements Engineering
• Software Project Management and Testing
• Pervasive Systems

Second Semester:

• Software Evolution
• Formal Methods Engineering
• Software Engineering for Dependable Systems
• Advanced Topics in Software Engineering

Project:
Your project will be chosen to explore an issue from a wide range of applications such as:

• Electronic Purse
• Electronic Patient Records
• Personal Insulin Pump Systems
• London Ambulance System
• System of Human Resources
• E-voting System
• Arion 5 Launcher
• Flight Control System

Optional Placement

We offer a great opportunity to boost your career prospects through an optional one year placement as part of your postgraduate studies. We have a dedicated Placement Unit which will help you obtain this. Once on your placement you will be supported by your Visiting Tutor to ensure that you gain maximum benefit from the experience. Placements begin after the taught component of the course has been completed - usually around June - and last for one year. When you return from your work placement you will begin your dissertation.

Teaching and assessment

There are provisions for a traditional classroom-based delivery, either part-time or full-time, as well as distance learning. Teaching will include formal lectures, tutorials and labs. You will also be expected to undertake independent study and research to support your assignments and dissertation. Assessment will be 100 per cent coursework. It will involve various group and individual methods, including oral exams, projects, presentations, written essays and reports.

Contact and learning hours

The time allocated to study is around 30 hours per week, carried out in block teaching. The taught element of the course lasts for the first two semesters, while the third semester is devoted to the project.

Academic expertise

he Software Technology Research Laboratory is one of the largest software engineering research groups in the UK and its research activities are acknowledged as being at the highest level of international excellence. In the last UK HEFCE Research Assessment Exercise (RAE 2008), 85 per cent of the research produced by the group was considered to be world-leading, internationally excellent or international.

The major themes within the lab include computer security and trust, software evolution, theory and computational paradigms and semantic web and service oriented computing. The staff working in these areas bring to the course their academic excellence and their experience of applying their work to various industrial sectors.

To find out more

To learn more about this course and DMU, visit our website:
Postgraduate open days: http://www.dmu.ac.uk/study/postgraduate-study/open-evenings/postgraduate-open-days.aspx

Applying for a postgraduate course:
http://www.dmu.ac.uk/study/postgraduate-study/entry-criteria-and-how-to-apply/entry-criteria-and-how-to-apply.aspx

Funding for postgraduate students
http://www.dmu.ac.uk/study/postgraduate-study/postgraduate-funding-2017-18/postgraduate-funding-2017-18.aspx

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This industry-focused course is for Computer Science graduates and experienced professional programmers interested in developing high-quality, complex software systems. Read more
This industry-focused course is for Computer Science graduates and experienced professional programmers interested in developing high-quality, complex software systems.

Who is it for?

This industry-focused course is for Computer Science graduates and experienced professional programmers interested in developing high-quality, complex software systems and aiming at a high-quality career in the industry, e.g. software houses, consultancies, and major software users across different sectors.

Students will have a keen interest in designing complex software systems, coding them in a programming language using the latest technologies (SOA, cloud, etc.), and ensuring that they are of high quality and that they actually meet the needs of their stakeholders.

Objectives

You will develop skills in analysing requirements and designing appropriate software solutions; designing and creating complex software systems to solve real-world problems, evaluating and using advanced software engineering environments, design methods and programming languages, and evaluating and responding to recent trends in interoperability and software development.

The course focuses on advanced engineering concepts and methods, as well as design issues for the systematic development of high-quality complex software systems. These are explored using industrial strength technologies, like the C++ and Java programming languages and the UML modelling language.

The course covers significant trends in systems development, including service-oriented architecture, cloud computing, and big data. The course is delivered by acknowledged experts and draws on City's world-class research in Systems and Software Engineering, which has one of the largest groups of academics working in this area in London, covering almost all aspects - from requirements, to designing reliable systems for the nuclear industry.

Placements

Postgraduate students on a Computing and Information Systems course are offered the opportunity to complete up to six months of professional experience as part of their degree.

Our longstanding internship scheme gives students the chance to apply the knowledge and skills gained from their taught modules within a real business environment. An internship also provides students with professional development opportunities that enhance their technical skills and business knowledge.

Internships delivered by City, University of London offer an exceptional opportunity to help students stand out in the competitive IT industry job market. The structure of the course extends the period for dissertation submission to January, allowing students to work full-time for up to six months. Students will be supported by our outstanding Professional Liaison Unit (PLU) should they wish to consider undertaking this route.

Teaching and learning

Software Engineering MSc is available full-time (12 months) as well as part-time (up to 28 months).

Students successfully completing eight taught modules and the dissertation for their individual project will be awarded 180 credits and a Master's level qualification. Alternatively, students who do not complete the dissertation but have successfully completed eight taught modules will be awarded 120 credits and a postgraduate diploma. Successful completion of four taught modules (60 credits) will lead to the award of a postgraduate certificate.

Assessment

Each module is assessed through a combination of coursework and examination.

Modules

You will develop skills in analysing requirements and designing appropriate software solutions; designing and creating complex software systems to solve real-world problems, evaluating and using advanced software engineering environments, design methods and programming languages and evaluating and responding to recent trends in interoperability and software development.

The focus of the course is on advanced engineering concepts and methods, as well as design issues for the systematic development of high-quality complex software systems. These are explored using industrial strength technologies, such as the C++ and Java object-oriented programming languages and the UML modelling language.

The course covers significant trends in systems development, including service-oriented architecture, mobile and pervasive computing, cloud computing, big data, and XML-enabled interoperable services. The course is delivered by acknowledged experts and draws on City's world-class research in Systems and Software Engineering. City has one of the largest groups of academics working in the area in London, working on almost all aspects of the area - from requirements, to designing reliable systems for the nuclear industry.

Core modules - there are five core modules:
-Advanced Database Technologies (15 credits)
-Research Methods and Professional Issues (15 credits)
-Service Oriented Architectures (15 credits)
-Software Systems Design (15 credits)
-Advanced Programming: Concurrency (15 credits)

Elective modules - you will be required to take three elective modules, choosing from the following:
-Advanced Algorithms and Data Structures (15 credits)
-Big Data (15 credits)
-Programming in C++ (15 credits)
-Business Engineering with ERP Solutions (15 credits)
-Mobile and Pervasive Computing (15 credits)
-Data Visualization (15 credits)
-Cloud Computing (15 credits)

Career prospects

The MSc in Software Engineering aims to meet the significant demand for graduates with a good knowledge of computing. This demand arises from consultancies, software houses, major software users such as banks, large manufacturers, retailers, and the public services, defence, aerospace and telecommunications companies.

Typical entrants to the course have a degree in an engineering or scientific discipline, and wish to either move into the software engineering field or to the development of software for their current field. Entrants must have previous exposure to computing, especially to programming (particularly in Java or C#) and relational databases (from either academic or professional experience).

From this base, the course provides solid technical coverage of advanced software development, including such widely used languages as C++, Java, UML and XML for which demand is particularly high. The course is therefore quite demanding; its success in providing advanced academic education along these lines is evident from the fact that recent graduates of the course are currently employed in a wide spectrum of organisations.

Of course, the employment value of a master's degree is not just short term. Although on-the-job training and experience as well as technology specific skills are valuable, they can be rather narrow and difficult to validate, and to transfer. The structure of this course ensures that there is a strong balance between the development of particular skills and a solid education in the enduring principles and concepts that underlie complex software system development.

SAP Certification - in parallel to your degree you will be able to register for a SAP TERP10 Certification course at a substantial discount, thus obtaining an additional, much sought-after qualification

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You will take eight Assessed Modules plus an Individual Project carried out in the department. Six of the modules cover core Software Engineering methods, practices and tools, and are compulsory. Read more
You will take eight Assessed Modules plus an Individual Project carried out in the department. Six of the modules cover core Software Engineering methods, practices and tools, and are compulsory. For the remaining two modules, you will be able to choose from Natural Language Processing, Topics in Privacy & Security, Evolutionary Computation, Concurrent & Real-Time Programming, and Functional Programming Technology.

Software Engineering has become a crucial discipline in the functioning of the modern world. Information systems, communications, transport, manufacturing and services all require well-engineered and reliable software. The focus of our MSc in Software Engineering is automated and large-scale software engineering, so the course will equip you to deal with the types of systems widely found in industry.

The MSc is a full-time, one-year course for those with some experience or background in Software Engineering. You will learn up-to-date theory and practice in the core areas of Software Engineering, and the main methods and tools used in industry. The course also covers model-driven engineering, service-oriented architectures, software architectures and user-centred design. You will gain a thorough understanding of techniques and practices of software management, including measurement and testing. This in-depth understanding of the role of software in commercial organisations will enable you to develop and maintain large-scale software systems.

You will gain a thorough understanding of techniques and practices of software management, including measurement and testing. These techniques will allow you to understand the role of software in commercial organisations and you will be able to develop and maintain these large scale systems.

Course Aims
When you graduate, you will be able to apply advanced Software Engineering techniques to analyse systems and design solutions, particularly in a commercial context. You will have experience of using state-of-the-art Software Engineering tool suites (e.g., Eclipse and Epsilon). You will also understand the human factors in Software Engineering, and will be able to design systems taking into account the needs of users.

Your individual project gives you the chance to specialise in a specific area of Software Engineering, as you will undertake independent research and apply your results to develop a real solution – an application, tool or technique.

On graduation, you will be equipped to design and maintain large systems in a wide range of industries, or to pursue an academic research career in Software Engineering.

Learning Outcomes
A thorough grounding and practical experience in the use of state-of-the-art techniques for developing software-based systems.
An in-depth understanding of the principles underpinning these techniques, so as to make sound judgements throughout the systems and software engineering life cycle.

Project

Team Project
You are taught a broad range of project management skills, which you will directly apply to a medium-sized software project that is conducted in small student teams.

Individual Project
The course concludes with your individual project. You may choose a topic among the many offered by the academic staff, or you may propose your own topic. Some recent topics were:
-Air Traffic Control application using PostgreSQL
-Automated Development of Graphical Editors built atop Graphiti
-Multi-Agent Reinforcement Learning: Conquest of Mars
-Natural Disaster Planning - A System of Systems Analysis
-Reinforcement Learning for Mobile Cognitive Radio Agents
-Simulation-based Hazard Analysis for Autonomous Robots
-Study of Business Processes in a Complex Enterprise System
-Using heuristics for Monte Carlo Tree Search

Careers

Here at York, we're really proud of the fact that more than 97% of our postgraduate students go on to employment or further study within six months of graduating from York. We think the reason for this is that our courses prepare our students for life in the workplace through our collaboration with industry to ensure that what we are teaching is useful for employers.

Our postgraduate taught courses are specifically designed to meet the needs of industry, and the thorough grounding we provide, alongside the skills you learn from undertaking a Masters degree, will stand you in good stead in the workplace.

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Software development is one of the most rapidly evolving industries in the world, presenting an ever-greater number of creative opportunities and exciting challenges. Read more

Overview

Software development is one of the most rapidly evolving industries in the world, presenting an ever-greater number of creative opportunities and exciting challenges. Software developers therefore need a special set of skills to keep pace with technology and innovation. Our course gives you the knowledge and confidence to do just that. We focus on large-scale development of advanced software, teaching you how to make use of the latest frameworks, methodologies and technology to produce professional-quality applications. Crucially, you will also learn how to be an effective member of a development team. With close links to software giants like Microsoft, Sony, and IBM, we work hard to ensure that our course is always up to date and that our graduates leave with the cutting-edge skills highly sought-after by industry. Therefore, this MSc is appropriate not just for fresh Computer Science graduates, but also for those with existing commercial experience who wish to update their skills and knowledge.

The course begins in September each year and lasts twelve months. There are two trimesters of taught modules, followed by an individual dissertation project during the third trimester. An optional extra trimester – either immediately before or after the dissertation – gives you significant industrial experience through a module based in our software development unit, working with commercial clients and software. This is unique to Hull.

The Department of Computer Science creates an excellent experience for students, with a supportive student community. We have an international reputation for our research activities, with a strong record of industrial and public grant funding. We are also affiliated with Microsoft’s DreamSpark programme, which allows you to access the latest Microsoft operating systems and development software for home use. Once registered with the department, you can download the software free of charge.

Industrial Experience

There is the option to take an Industrial Experience variant, with the opportunity to extend the period of study by a trimester, to gain experience of working alongside commercial software developers within a commercial software development facility on site (SEED), promoting real-world applications of the advanced concepts met in the course.

Study

The MSc Computer Science (Software Engineering) programme is designed to support students with various levels of computing and programming practice experience. There is suitable content on professional skills and the importance of ethics for practising computer scientists. Material on software engineering, referencing and unfair means supports the transition into the postgraduate environment.
As a route into research, the programme supports the development of postgraduate technical skills, alongside critical research, analysis and planning activities.
In lectures you’ll benefit from a range of techniques, from interpreting complex ideas through interactive discussions, to live programming or other problem-solving demonstrations.

Core modules

• Oriented Design and Development Using C++
• Component-based Architecture
• Maintaining Large Software Systems
• Development Project
• Distributed Applications
• Trustworthy Computing
Optional modules
• Computer Science Software Development Practice – pass/fail module
• Dissertation (There is the option of taking this module either in trimester 3 or trimester 4, depending on whether you take the Industrial Experience module.)

Teaching and learning

We place a strong emphasis on practical laboratory sessions. This will significantly develop your core computer science skills, and enhance your employability through exposure to commercial projects.
As teamwork plays a key role in commercial software development and has great value as an employable skill, group work is used in a number of modules.

Assessment

Practical coursework is the main form of assessment, and you will design, build and test software solutions to a variety of problems. This is complemented by written coursework.
The largest assessment is the dissertation, which is based on the work done in the third trimester and documented in a report of up to 20,000 words.

Careers

The MSc Computer Science (Software Engineering) is designed to open up pathways to postgraduate research, as well as careers in a wide range of areas within your discipline. The industrial placement option will enable you to practise your skills and knowledge of computer science ‘in situ’, giving you a useful insight and advantage when it comes to starting your career.
We have a range of inspirational extra-curricular activities including the Three Thing Game, Imagine Cup Worldwide Software Development Challenge, Really Useful Seminars and Global Game Jam. They are designed to boost your CV and employability, and taking part costs very little.

Our graduates gain a wide range of roles including: Applications Developer, Business Systems Analyst, Computer Analyst, Computer Programmer, Computer Operations Manager, Data Management Analyst, Database Assistant, Developer Support Engineer, Games Programmer, Games Programmer (Engine design), Information Manager, IT Design, IT Systems Manager, IT Technician, IT user Support, Mobile Developer, Operations Director, Software Designer, Software Developer, Software Engineer, Solutions Developer, Systems Engineer, Technical Sales, Technical Specialist, Web Developer.

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Society is increasingly focusing on embedded and combined hardware and software solutions that are dynamic rather than static, which can grow and develop during their life cycle. Read more
Society is increasingly focusing on embedded and combined hardware and software solutions that are dynamic rather than static, which can grow and develop during their life cycle. Software is therefore rapidly becoming the main driving force for innovation and the future development in many different industries such as the automotive industry, the telecom industry, the defence industry and the software industry itself.

Programme description

The current evolution is creating a growing importance of software in several areas of society. At the same time, the size and complexity of software is constantly increasing alongside the pressure of speedy supply in turbulent environments with rapidly changing demands. To meet these challenges and the demands of delivering reliable and high quality software, this programme offers a unique combination of advanced technical knowledge and required management skills.

Your studies will benefit greatly from the use of real industrial projects and collaboration with industry representatives from for example Ericsson, Volvo AB, Volvo IT, Volvo Cars, Saab and Astra Zeneca. In your future career you will be the team player with the important holistic software engineering perspective the industry demands for, able to handle technical and organizational challenges.

Our programme combines a number of perspectives on software engineering, all of which promote the common goal of educating engineers who are skilled in designing quality software at low development and maintenance costs. Software Engineering and Technology is also a platform for future researchers who get qualified to perform advanced technological and methodological experiments in software engineering.

The programme focuses on three main competences in software engineering:

Avanced technical knowledge and skills
Advanced knowledge of methods and processes
Advanced knowledge of industrial activities and practices

The combination of this knowledge is highly valued and in great demand in the software industry in order to support, innovates, and improve practices with new methods and tools.

Educational methods

Our programme offers a mixture of conventional lectures, seminars, and project work in close collaboration with real industrial projects and industry representatives. Projects, group work, and student presentations are important parts of the programme.

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Our Software Systems Engineering (SSE) MSc provides an ideal foundation for PhD study. The UCL SSE group is regularly ranked in the top three groups in the world (Microsoft Academic Search), you will be taught by those who are setting the international agenda, and our research has been repeatedly rated as world-class. Read more
Our Software Systems Engineering (SSE) MSc provides an ideal foundation for PhD study. The UCL SSE group is regularly ranked in the top three groups in the world (Microsoft Academic Search), you will be taught by those who are setting the international agenda, and our research has been repeatedly rated as world-class. Fully-funded PhD scholarships are available for high-performing students.

Degree information

Students are trained in the principles and techniques of engineering large, complex software systems and gain the opportunity to apply these techniques in a realistic group project setting. The programme analyses current practice in software systems engineering, looking at the most significant trends, problems and results in complex software systems.

Students undertake modules to the value of 180 credits.

The programme consists of five core modules (75 credits), three optional modules (45 credits) and a group project (60 credits).

Core modules
-Requirements Engineering and Software Architecture
-Software Abstractions and Systems Integration
-Validation and Verification
-Tools and Environments
-Professional Practice

Optional modules
-People and Security
-Networked Systems
-Language Based Security
-Distributed Systems and Security
-Supervised Learning
-Research Seminar in Software Engineering

Dissertation/report
Most students participate in a group industrial project, generally in close collaboration with one of our industsrial partners.

Other students undertake either an individual or small-group research project, under the supervision of academics in UCL Software Systems Engineering group.

Teaching and learning
The programme is delivered through a combination of lectures, written and laboratory exercises, and group project supervision. Student performance is assessed through written exercises with modelling notations, laboratory exercises with tools and environments, unseen examination papers, and a significant, comprehensive group project.

Careers

This professionally oriented programme provides an ideal foundation for graduates who wish to pursue a career as a software architect or leader of software development organisations. It also provides an excellent introduction for those who want to pursue research in software systems engineering.

Graduates from UCL are keenly sought by the world's leading organisations, and many progress in their careers to secure senior and influential positions. UCL Computer Science (UCL-CS) graduates are particularly valued as a result of the department's strong international reputation, strong links with industry, and ideal location close to the City of London.

Graduates have found positions at global companies such as Barclays and RBS.

Top career destinations for this degree:
-IT Consultant, OnTrack
-Software Analyst and Designer, Nok Technology
-Software Engineer, Accenture
-Software Engineer, Orange
-Security Science, UCL

Employability
There is, throughout the world, a strong demand for software engineers with solid foundations covering not only the programming aspects of software development, but also aspects related to requirements engineering, software architectures, system integration, and testing. Many surveys rank software engineering positions as among the best jobs in the world.

Following graduation, our students are generally hired as software engineers or software architects, sometimes by companies they have engaged with in the context of their MSc project.

Why study this degree at UCL?

UCL Computer Science is recognised as a world-leader in teaching and research, and was one of the top-rated departments in the country according to the UK government's recent research assessment exercise.

Our Master's programmes have some of the highest employment rates and starting salaries, with graduates entering a wide variety of industries from entertainment to finance.

We take an experimental approach to our subject and place a high value on our extensive range of industrial collaborations. In the recent past, students have worked on projects and coursework in collaboration with Microsoft, IBM, JP Morgan, Citigroup and BNP Paribas.

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Music Technology is a rapidly evolving field of study with a diverse and expanding range of possibilities. Read more

Aims

Music Technology is a rapidly evolving field of study with a diverse and expanding range of possibilities.

The MSc in Audio Technology is designed to go beyond the simple provision of training, and to instead enable you to engage with current debates and actively participate in some of the most vibrant areas of contemporary research.

Throughout the course you will be encouraged to demonstrate self-direction and autonomy as you critically explore and define your position within the wider field. One overarching aim is that you should leave the course as not only an adept user of various hardware and software technologies, but as someone able to actively shape and develop their own, responding as necessary to future developments.

Thus, in addition to developing your theoretical and methodological understanding, the MSc in Audio Technology features a strong emphasis on practical work in a number of different (but related) areas. For example, you will study modules in Advanced Studio Practice, Sound on Screen, Music Computing and Musical Human-Computer Interaction. These are supported by a technology-orientated Research and Development module that provides robust foundation for the final Audio Technology Project.

Acting as summary of all that you have learned and a portfolio going forward, the Audio Technology Project provides an opportunity to plan and execute a substantial project in an area of personal specialism or interest. Innovative projects are encouraged, and there exists the potential for interdisciplinary and/or collaboration with practitioners in other fields.

Fees and finance

2015/6 Home/EU International
Full time £5,750 £11,960
Part time £2,875

These fees are applicable for new entrants in 2015/6. Fees are for the academic year only, any subsequent years may be subject to an annual increase, usually in line with inflation.

The University also offers a postgraduate loyalty discount: If you have completed an undergraduate degree at the University of Wolverhampton, you may be eligible for a 20% discount on the first year of a taught postgraduate programme.

Employability

The course will actively equip both graduates and those already in industry with a diverse range of skills to enhance their career prospects. It will also develop a range of opportunities for experience and employment in areas such as studio recording, media production and content creation, video game and software development, education (FE/HE), research assistantships/studentships, and employment in HE institutions.

In addition to subject-specific practical skills, you will also acquire a range of transferable skills relevant for pursuing a research degree. These include critical, analytical, project management and research skills from the study of a broad spectrum of literature, research, and external projects.

Outcomes

- Demonstrate knowledge and critical understanding of a variety of issues in the expanded field of contemporary music technology, taking an independent and rounded perspective.
- Apply theoretical discourse relating to aspects such as technologised production and performance, reactive/interactive/non-linear media, and computational creativity (etc.) to practice through a systematic understanding of historical, contextual, philosophical, technical and scientific theory.
- Select, interpret, develop and apply a variety of research methodologies appropriate for their work.
- Critically evaluate and use a wide variety of hardware and software technologies, and, where appropriate, develop their own.
- Exercise personal autonomy in learning through effective self-organisation and management of workload in both individual and group scenarios.
- Understand the possibilities afforded by the contemporary, expanded field of music technology (including its gaps and trends), and be able to position their own work, interests and aspirations within this wider context.

Why Wolverhampton?

The course offers an explicit and concerted move away from the notion of “training” in how to use specific software and/or other music technologies in favour of a more balanced synthesis of theory and practice.

The proposal for the Audio Technology Project is developed in the Research and Development module, providing time and opportunity to consider the project’s direction thoroughly, and to explore possibilities for collaborative/interdisciplinary working.

Course staff specialise in both traditional/well-established areas of music technology (studio production, film sound, audio synthesis and processing) and flourishing areas of contemporary research (musical interaction, generative music).

A wide range of career routes are open to graduates of the course. These are largely dependent upon the nature of the work the student chooses to produce, but may include: studio production, sound for games and film/video/animation, interactive media, interaction design, creative software development, design for music technology, post-compulsory and higher education.

The University of Wolverhampton continues to develop state of the art facilities to greatly enhance your learning experience. The Performance Hub, opened in 2011, has a diverse range of fully equipped music teaching, performance and practice rooms (accommodating single person to large band / ensemble), two high-end professional recording studios, and two bespoke technology suites boasting sixty Apple iMacs running industry standard software including Pro Tools, Logic Pro, Max, Pure Data and SuperCollider.

Our two recording studios offer the perfect blend of digital and analogue technologies giving students the opportunity to combine classic analogue recording technique with the flexibility and reliability digital technology provides. As well as a dedicated live room each for recording, for increased flexibility and choice of room acoustic, any of the music rehearsal rooms surrounding each studio can also be patched into the studio's control room.

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Humber’s Enterprise Software Development graduate certificate program provides the advanced concepts, skills and knowledge for those currently employed in information technology (IT) and related fields, or those who are graduates of an information technology or computer studies program. Read more
Humber’s Enterprise Software Development graduate certificate program provides the advanced concepts, skills and knowledge for those currently employed in information technology (IT) and related fields, or those who are graduates of an information technology or computer studies program.

This program allows you to increase employment opportunities in your specialized field. You can select your focus of study on databases, software development, mobile application development, web application development and are able to mix them as well throughout the choice of professional electives.

Course detail

Upon successful completion of the program, a graduate will:

• Describe the current and future use of e-commerce technology to improve intra and inter-organizational processes.
• Analyze and define the specifications and design of an e-commerce system based on user requirements.
• Identify connectivity and interoperability issues in the development of Internet applications for networking.
• Plan, track and present the progress of a project applying principles of project management.
• Develop programs for distributed applications involving web page technology.
• Develop interfaces on the web.
• Modify, document and maintain existing software components.
• Outline legal, ethical and intellectual property issues and practices.
• Develop applications consistent with security practices.
• Develop code to deliver multimedia data streams.
• Develop programs for distributed applications using client-side technology.
• Develop a web site that implements business transactions.
• Integrate corporate database capabilities with a web site.
• Develop applications consistent with performance applications.
• Write project proposals.
• Prepare and present a web project.
• Research new technology.
• Compare and contrast current e-commerce strategies.
• Demonstrate professional and ethical behaviour.
• Perform user training.
• Using available technology, implement e-commerce objectives.

Modules

Semester 1
• ITC 5301: Career Connections
• ITC 5302: Project Management
• Select 5 from the following courses
• ESE: Enterprise Software Electives

Semester 2
• ITC 5401: Employee Engagement
• ITC 5402: Capstone Project
• Select 5 from the following courses
• ESE: Enterprise Software Electives

Work Placement

This program does not have a work placement component. However, in conjunction with our Career Connections course, we provide graduates with job search assistance at the end of the program. Students are encouraged to market themselves to prospective employers.

Your Career

According to the Indo-Canadian Business Chamber website, Canada has the highest levels of broadband penetration and the lowest overall communication costs of almost any country in the world. Therefore, Canada has an edge over its competitors when it comes to software development. Canada’s software advantage starts with its world-renowned workforce and mature, technologically advanced telecommunications infrastructure, which provides the backbone for all technology businesses.

Work as a database administrator, database designer, Oracle programmer, enterprise software developer, junior software developer, intermediate software developer, programmer/analyst, website designer, web programmer or programmer of mobile devices.

How to apply

Click here to apply: http://humber.ca/admissions/how-apply.html

Funding

For information on funding, please use the following link: http://humber.ca/admissions/financial-aid.html

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

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

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

Research Foci

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

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

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

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

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

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

Facilities

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

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

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

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

Research Foci

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

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

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

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

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

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

Facilities

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

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

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

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

Research Foci

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

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

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

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

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

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

Facilities

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

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

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

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

Research Foci

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

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

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

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

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

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

Facilities

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

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

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

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

Research Foci

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

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

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

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

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

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

Facilities

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

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