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Masters Degrees (Industrial Technology)

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The first course of its kind to be accredited by the Royal Society of Chemistry, this taught Masters course is designed to equip you with the necessary skills in green chemistry and green chemical technology to prepare you for a range of different careers in research, process development, environmental services, manufacturing, law, consultancy and government. Read more
The first course of its kind to be accredited by the Royal Society of Chemistry, this taught Masters course is designed to equip you with the necessary skills in green chemistry and green chemical technology to prepare you for a range of different careers in research, process development, environmental services, manufacturing, law, consultancy and government.

Course Content

The MSc is a one year full time course consisting of taught material and a substantial research project. Teaching is delivered by academic experts within the Department of Chemistry as well as external experts from other academic institutions and industry. The Teaching component of the course is delivered via a mix of lectures, workshops, seminars and practical work. You will learn about the key principles of green chemistry and the importance of sustainable technology in a variety of areas. In addition to this, you will also have the opportunity to enhance your transferable skills.

Assessment methods include a closed examination, written assignments, presentations, posters and practical work.

Our Students

The MSc course has been running for over ten years over which time there has been a large increase in the range of nationalities represented. The content of the course is globally relevant and so attracts applications from around the world from people keen to develop their own knowledge to pass on when they return to their home country. Students have an opportunity not only to benefit from the degree that will aid them in their future career in industry or elsewhere but also to experience the cultural and social attractions that the university and the city can offer.

Students who have previously studied the MSc programme have come from France, Spain, Ireland, Tanzania, Nigeria, Oman, Thailand, Malta, Lithuania, Brunei, China and Malaysia to name but few – the full range can be seen on the map below. The diversity of our students enriches the cultural experience for all members of the group.

Career Destinations

The course will be of benefit to students who wish to follow a range of career paths including those in chemistry-based industries:
-Speciality chemical and associated manufacturing industries
-Fine chemical and associated manufacturing industries
-Catalyst development
-Pharmaceutical industry in either a research or process-development role
-Chemical formulation
-Chemical user companies along the entire supply chain including retail
-Government departments and science laboratories
-University academic career
-University research career, in particular as a route to PhD research
-Environmental monitoring and evaluation
-Legal services and other organisations

Research Project

A key part of the MSc in Green Chemistry is the research project. The whole course is 180 credits and the research project accounts for 100 of these so is a very significant part of the programme.

Students are able to choose from a range of project areas in order to carry out research in their area of interest. Projects will be supervised by an academic member of staff, and may also involve collaboration with industry. Projects are chosen in the early stages of the course and you will be allocated to a PAG - Project Area Group - that corresponds with larger research projects that are currently taking place within the Green Chemistry Centre.

Projects can vary each year, but examples of recent MSc students' research includes:
-Production of natural flavours and fragrances using biocatalysis in scCO2
-Clean synthetic strategies for production of pharmaceuticals
-Extraction and utilisation of high value chemicals from food waste
-Starbon technology for catalysis
-Microwave assisted pyrolysis of wood pellets
-Bio-derived platform molecules

The research project module is assessed by a substantial written report by each student, a PAG report and an oral presentation on your individual research.

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WHAT YOU WILL GAIN. - Skills and know-how in the latest and developing technologies in instrumentation, process control and industrial automation. Read more
WHAT YOU WILL GAIN:

- Skills and know-how in the latest and developing technologies in instrumentation, process control and industrial automation
- Practical guidance and feedback from industrial automation experts from around the world
- Live knowledge from the extensive experience of expert instructors
- Credibility and respect as the local industrial automation expert in your firm
- Global networking contacts in the industry
- Improved career choices and income
- A valuable and accredited Master of Engineering (Industrial Automation)** qualification

Next intake is scheduled for June 27, 2016. Applications now open; places are limited.

Now also available on Campus.

INTRODUCTION

The respected International Society of Automation (ISA) estimated that at least 15,000 new automation engineers are needed annually in the US alone. Many industrial automation businesses throughout the world comment on the difficulty in finding experienced automation engineers despite paying outstanding salaries.

The Master of Engineering (Industrial Automation) perfectly addresses this gap in the Industrial Automation industry. The program's twelve core units, and project thesis, provide you with the practical knowledge and skills required. Students with a background in electrical, mechanical, instrumentation and control, or industrial computer systems engineering can benefit from this program.

The content has been carefully designed to provide you with relevant concepts and the tools required in today’s fast-moving work environment. For example, Power Engineering covers major equipment and technologies used in power systems, including power generation, transmission and distribution networks. Programmable Logic Controllers covers in-depth principles of operation of programmable controllers, networking, distributed controllers, and program control strategies. Industrial Process Control Systems combines the process identification and feedback control design with a broad understanding of the hardware, system architectures and software techniques widely used to evaluate and implement complex control solutions. Industrial Instrumentation identifies key features of widely used measurement techniques and transducers combined with microprocessor devices to create robust and reliable industrial instruments. Process Engineering will enable students to evaluate and apply complex process calculations through application of control principles. Industrial Data Communications provides the requisite knowledge to manage modern field buses and industrial wireless systems. Safety Systems provides an introduction to the common safety philosophy of hazard identification, risk management and risk-based design of protection methods and functional safety systems. SCADA and DCS cover hardware and software systems, evaluation of typical DCS and SCADA systems and configuration of DCS controllers. Special Topics enable students to incorporate current technologies and the knowledge acquired from the entire course and thus solve complex Industrial Automation problems.

The Masters project, as the capstone of the course, requires a high level of personal autonomy and accountability, and reinforces the knowledge and skill base developed in the preceding subjects. As a significant research component of the course, this project will facilitate research, critical evaluation and the application of knowledge and skills with creativity and initiative, enabling students to critique current professional practice in the Industrial Automation industry.

ENTRANCE REQUIREMENTS

To gain entry into the Master of Engineering (Industrial Automation), applicants need one of the following:
a) a recognized 3-year bachelor degree in an engineering qualification in a congruent* field of practice with relevant work experience**.
b) a 4-year Bachelor of Engineering qualification (or equivalent), that is recognized under the Washington Accord or Engineers Australia, in a congruent*, or a different field of practice at the discretion of the Admissions Committee.
c) a 4-year Bachelor of Engineering qualification (or equivalent) that is not recognized under the Washington Accord, in a congruent* field of practice to this program.

AND

An appropriate level of English Language Proficiency equivalent to an English pass level in an Australian Senior Certificate of Education, or an IELTS score of 6.5 (with no individual band less than 6), or equivalent as outlined in the EIT Admissions Policy.

*Congruent field of practice means one of the following with adequate Industrial Automation content (fields not listed below to be considered by the Dean and the Admissions Committee on a case-by-case basis):
• Industrial Automation
• Industrial Engineering
• Instrumentation, Control and Automation
• Mechanical Engineering
• Mechanical and Material Systems
• Mechatronic Systems
• Manufacturing and Management Systems
• Electrical Engineering
• Electronic and Communication Systems
• Chemical and Process Engineering
• Robotics
• Production Engineering

**Substantial industrial experience in a related field is preferred, with a minimum of two years’ relevant experience.

PROGRAM STRUCTURE

Students must complete 48 credit points comprised of 12 core subjects and one capstone thesis. The thesis is the equivalent of one full semester of work. There are no electives in this course. The course duration is two years full time, or equivalent. Subjects will be delivered over 4 semesters per year. Students will take 2 subjects per semester and be able to complete 8 subjects per year. There will be a short break between semesters. Each semester is 12 weeks long.

LIVE WEBINARS

During the program you will participate in weekly interactive sessions with the lecturers and other participants from around the world. Each unit's weekly live tutorial will last 60 to 90 minutes. We take student availability into consideration wherever possible before scheduling webinar times. All you need to participate is an adequate Internet connection, speakers and a microphone. The software package and setup details will be sent to you at the start of the program.

COURSE FEES

EIT provides distance education to students located almost anywhere in the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. A full list of fees in a currency appropriate for every country would be complex to navigate and, with today’s exchange rate fluctuations, difficult to maintain. Instead we aim to give you a rapid response regarding fees that is customized to your individual circumstances.

We understand that cost is a major consideration before a student commences study. For a rapid reply to your query regarding courses fees and payment options, please query via the below button and we will respond within 2 business days.

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WHAT YOU WILL GAIN. - Skills and know-how in the latest and developing technologies in instrumentation, process control and industrial automation. Read more
WHAT YOU WILL GAIN:

- Skills and know-how in the latest and developing technologies in instrumentation, process control and industrial automation
- Practical guidance and feedback from industrial automation experts from around the world
- Live knowledge from the extensive experience of expert instructors
- Credibility and respect as the local industrial automation expert in your firm
- Global networking contacts in the industry
- Improved career choices and income
- A valuable and accredited Master of Engineering (Industrial Automation)** qualification

Perth Campus next intake is scheduled for June 27, 2016. Applications now open; places are limited.

INTRODUCTION

The respected International Society of Automation (ISA) estimated that at least 15,000 new automation engineers are needed annually in the US alone. Many industrial automation businesses throughout the world comment on the difficulty in finding experienced automation engineers despite paying outstanding salaries.

The Master of Engineering (Industrial Automation) perfectly addresses this gap in the Industrial Automation industry. The program's twelve core units, and project thesis, provide you with the practical knowledge and skills required. Students with a background in electrical, mechanical, instrumentation and control, or industrial computer systems engineering can benefit from this program.

The content has been carefully designed to provide you with relevant concepts and the tools required in today’s fast-moving work environment. For example, Power Engineering covers major equipment and technologies used in power systems, including power generation, transmission and distribution networks. Programmable Logic Controllers covers in-depth principles of operation of programmable controllers, networking, distributed controllers, and program control strategies. Industrial Process Control Systems combines the process identification and feedback control design with a broad understanding of the hardware, system architectures and software techniques widely used to evaluate and implement complex control solutions. Industrial Instrumentation identifies key features of widely used measurement techniques and transducers combined with microprocessor devices to create robust and reliable industrial instruments. Process Engineering will enable students to evaluate and apply complex process calculations through application of control principles. Industrial Data Communications provides the requisite knowledge to manage modern field buses and industrial wireless systems. Safety Systems provides an introduction to the common safety philosophy of hazard identification, risk management and risk-based design of protection methods and functional safety systems. SCADA and DCS cover hardware and software systems, evaluation of typical DCS and SCADA systems and configuration of DCS controllers. Special Topics enable students to incorporate current technologies and the knowledge acquired from the entire course and thus solve complex Industrial Automation problems.

The Masters project, as the capstone of the course, requires a high level of personal autonomy and accountability, and reinforces the knowledge and skill base developed in the preceding subjects. As a significant research component of the course, this project will facilitate research, critical evaluation and the application of knowledge and skills with creativity and initiative, enabling students to critique current professional practice in the Industrial Automation industry.

ENTRANCE REQUIREMENTS

To gain entry into the Master of Engineering (Industrial Automation), applicants need one of the following:
a) a recognized 3-year bachelor degree in an engineering qualification in a congruent* field of practice with relevant work experience**.
b) a 4-year Bachelor of Engineering qualification (or equivalent), that is recognized under the Washington Accord or Engineers Australia, in a congruent*, or a different field of practice at the discretion of the Admissions Committee.
c) a 4-year Bachelor of Engineering qualification (or equivalent) that is not recognized under the Washington Accord, in a congruent* field of practice to this program.

AND

An appropriate level of English Language Proficiency equivalent to an English pass level in an Australian Senior Certificate of Education, or an IELTS score of 6.5 (with no individual band less than 6), or equivalent as outlined in the EIT Admissions Policy.

*Congruent field of practice means one of the following with adequate Industrial Automation content (fields not listed below to be considered by the Dean and the Admissions Committee on a case-by-case basis):
• Industrial Automation
• Industrial Engineering
• Instrumentation, Control and Automation
• Mechanical Engineering
• Mechanical and Material Systems
• Mechatronic Systems
• Manufacturing and Management Systems
• Electrical Engineering
• Electronic and Communication Systems
• Chemical and Process Engineering
• Robotics
• Production Engineering

**Substantial industrial experience in a related field is preferred, with a minimum of two years’ relevant experience.

PROGRAM STRUCTURE

Students must complete 48 credit points comprised of 12 core subjects and one capstone thesis. The thesis is the equivalent of one full semester of work. There are no electives in this course. The course duration is two years full time, or equivalent. Subjects will be delivered over 4 semesters per year. Students will take 2 subjects per semester and be able to complete 8 subjects per year. There will be a short break between semesters. Each semester is 12 weeks long.

LIVE WEBINARS

During the program you will participate in weekly interactive sessions with the lecturers and other participants from around the world. Each unit's weekly live tutorial will last 60 to 90 minutes. We take student availability into consideration wherever possible before scheduling webinar times. All you need to participate is an adequate Internet connection, speakers and a microphone. The software package and setup details will be sent to you at the start of the program.

COURSE FEES

EIT provides distance education to students located almost anywhere in the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. A full list of fees in a currency appropriate for every country would be complex to navigate and, with today’s exchange rate fluctuations, difficult to maintain. Instead we aim to give you a rapid response regarding fees that is customized to your individual circumstances.

We understand that cost is a major consideration before a student commences study. For a rapid reply to your query regarding courses fees and payment options, please query via the below button and we will respond within 2 business days.

Read less
Solving global water problems requires a multidisciplinary approach of knowledge and skills. That is why the Wetsus Insitute and three Dutch universities offer a joint degree in Water Technology. Read more
Solving global water problems requires a multidisciplinary approach of knowledge and skills. That is why the Wetsus Insitute and three Dutch universities offer a joint degree in Water Technology.

The master Water Technology is a two year programme offered jointly by Wageningen University, University Twente and University of Groningen with all education being provided at the Technological Top Institute for Water technology (TTIW Wetsus), in Leeuwarden.

In the field of water technology, breakthrough technological developments are required. Not only to enable the export ambitions of the water sector but also to solve global threats and challenges in society.

The main added value of the course lies in the multidisciplinary study of biotechnology and separation technology. Such a combined technological approach may offer a solution to global developments, within business and society, and have a worldwide impact on the demand for and use of water.

This program will qualify you as the expert who is able to participate in resolving world-wide water issues. It enables students to complement their Bachelor of Sciences diploma with scientific knowledge and capabilities that they need for a successful career in the dynamic international setting of business and research.

Why in Groningen?

- a multidisciplinary research program: cooperation with three Dutch universities and a Technological Top Insitute
- Water Technology is an area of expertise in which the Netherlands has gained an international reputation
- Commercial parties are involved in Wetsus and help to define and guide the research program

Job perspectives

The study domain is becoming more and more relevant due to the urgent need for new technologies to meet the global water problems. Water technology for public drinking water production and sewer water treatment is a very large market. Further, the largest use of fresh water is for irrigation purposes.

The industrial water supply and industrial waste water treatment also represent a significant market. There is no question that business involved in water technology will grow tremendously. Besides this human capital is a basic condition to guarantee the success and continuity of the development of sustainable technologies and a European know-how economy in water technology. In many EU countries the lack of talented technological professionals is becoming an increasingly limiting factor. The program prepares students for a professional position in the broad area of water technology. Graduates have good national and international career prospects in business and research.

Job examples

- Consultant or manager at a development project
- Designer of purification processes
- R&D department of companies, e.g. Arcadis or Philips
- PhD, starting a scientific career

Collaboration, Integration, and Top Level Research

As a student Water Technology you will be in the center of the multidisciplinary laboratory of Wetsus, in which 80% of the research will be carried out. Wetsus is situated in Leeuwarden, the Netherlands. By inviting all the researchers to one location, maximal cooperation and creativity is generated. The researchers are seconded by the participating EU-universities at Wetsus, but the universities carry scientific responsibility of the projects.

In this way, an enormous intellectual and creative power will be focused on water technology and at the same time knowledge capacity will be build up by all the participating universities.

The Netherlands is Europe's leading country in water process technology. The Dutch government focuses in her innovation policy on water and has appointed Leeuwarden as the focal point for water technology development. This results in a supportive government policy in the form of enabling subsidies for water research and innovation. Around the Wetsus research and education facilities, a high-tech water campus is realised to concentrate know how, entrepreneurship, talent and venture capital. This attracts starting companies as well as research centers of large companies.

Wetsus is part of the Dutch Innovation Program on Water Technology. The innovation program aims for the development of sustainable water treatment technology with a strong focus on export. Wetsus, operating as as Technological Top Institute, takes care of the pre-competitive technology development within this program. Wetsus focuses on the research and development of entirely new concepts and on breakthrough improvements of existing technology.

In both cases, an entirely new approach has been chosen whereby the basic principle is always the integration of various knowledge disciplines. In addition to collaboration between industry and universities, there is also unique scientific collaboration within Wetsus. Many scientific chairs cooperate in the program. Leading researchers from various universities and other research institutes can physically work side-by-side in the Wetsus laboratory. This unique collaboration brings synergy and new creativity to the search for new sustainable water treatment technology.

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The Technology Management Group of UCL's Mullard Space Science Laboratory (MSSL) and UCL Centre for Systems Engineering (UCLse) have pooled expertise to develop this exciting programme, which equips students with the knowledge and skills necessary to develop a career in technology management or engineering management. Read more

The Technology Management Group of UCL's Mullard Space Science Laboratory (MSSL) and UCL Centre for Systems Engineering (UCLse) have pooled expertise to develop this exciting programme, which equips students with the knowledge and skills necessary to develop a career in technology management or engineering management.

About this degree

Students learn about the challenges and opportunities of working with new and legacy technology, and are introduced to key concepts such as technology maturity, lifecycles, risk, reliability and resilience. Systems and strategic thinking is promoted throughout, and the importance of the enterprise context. The research elements aim to instil a deep knowledge of at least one area of technology management with industrial relevance.

Students undertake modules to the value of 180 credits.

The programme consists of four core taught modules (60 credits), two optional taught modules (30 credits) and three research modules (90 credits).

Core modules

  • Technology Strategy
  • Systems Thinking and Engineering Management
  • The Business Environment
  • Risk, Reliability, Resilience

Optional modules

Students choose two of the following:

  • Project Management
  • Delivering Complex Projects
  • Lifecycle Management
  • New Product Development
  • Systems Design
  • Defence and Security Systems
  • Rail Systems
  • Space Systems

Research modules

Students undertake a structured research programme comprising:

  • Emerging Technology Review (group project, 15 credits)
  • Technology Management Project Concept (15 credits)
  • Technology Management Research Project (60 credits, including a 12,000-word dissertation)

Teaching and learning

Teaching methods incorporate a mix of lectures and case study-based teaching, and groupwork, in which students will be challenged to come up with novel ideas, lead groups to innovative solutions and manage complex tasks under tight time pressure. Assessment is through coursework, examinations, written reports and presentations, and the dissertation.

Further information on modules and degree structure is available on the department website: Technology Management MSc

Careers

UCLse has strong links with companies in the aerospace, communications, construction, energy, transport and defence sectors and our Industrial Advisory Board ensures relevance to industry.

Typical career destinations might include:

  • Graduate Systems Engineer (Airbus, BAE Systems, Boeing, GE, GDUK, SELEX, THALES, Ultra Electronics)
  • Technology/Business Consultant (Accenture, Capgemini, Deloitte, Ernst & Young, KPMG, PwC).

Employability

Drawing on our experience of providing short training courses for industry (such as the Project Manager training courses we run for the European Space Agency) we will integrate a large amount of skills development into our teaching, including skills in communication, negotiation, leadership and motivation, decision-making, and managing complex, time-constrained tasks, all of which will be beneficial for future careers.

Why study this degree at UCL?

The programme blends general principles of management with technology-focused teaching and integrates aspects of systems engineering and project management; the UCL Mullard Space Science Laboratory has nearly fifty years’ experience of developing cutting-edge spacecraft technology, and the programme content builds on research conducted by the Technology Management Group at MSSL in these areas.

The programme contains two compulsory modules relevant to leadership and entrepreneurship (Technology Strategy, and Business Environment). These modules will give students the knowledge and skills necessary to lead new technology-driven enterprises.

The curriculum has an international focus, with case studies from major technology companies around the world including Apple, Samsung and Lenovo. A number of industrial visits are anticipated and this ‘real world’ exposure to organisations will help contextualise the theory and techniques learnt.



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The Master’s programme in Technology Governance and Digital Transformation leads to a technology-focused graduate degree in the fields of Public Administration, Innovation/Industrial Policy, Development Economics, and E-Governance. Read more

The Master’s programme in Technology Governance and Digital Transformation leads to a technology-focused graduate degree in the fields of Public Administration, Innovation/Industrial Policy, Development Economics, and E-Governance. The overall purpose of the program is to educate (policy) analysts with interdisciplinary skills to govern, analyse and develop a knowledge-based state and society. Innovation policy and its use in different economic situations has become a very important topic in the world, as the need for people who are knowledgeable in dealing with economic cycles in a new way is increasing. The program should be attractive for those international students who want to get an understanding of the dynamics of capitalist economies and economic development processes from a rather non-orthodox perspective, i.e. from evolutionary, post-Keynesian and other heterodox economics perspectives.

Key features

  • Faculty includes internationally distinguished, award-winning professors (Carlota Perez, Erik S. Reinert, Jan A. Kregel, Wolfgang Drechsler, Rainer Kattel, Robert Krimmer)
  • Opposed to standard text-book, mainstream economics that is taught in most universities
  • Case-study based teaching and student-friendly study arrangements
  • Site visits and guest lecturers from leading Estonian and international companies
  • Minimum stay in Estonia is one year – second year is dedicated for internship and MA thesis writing that can be accomplished anywhere

Course outline

The MA in Technology Governance and Digital Transformation programme is aimed at understanding economic development processes and is taught through the development and evolutionary economics perspectives, which oppose to standard text-book economics, taught at most universities around the world. The programme covers various interlinked areas of study, including public administration and the role of the state in economic development, innovation, industries, and finance.

Technology Governance is an approach and set of policies undertaken by the public and private sector and social actors to develop a knowledge base, social cohesion and competitiveness at the same time. So far, both in academic research and in policy advice, these aspects have tended to be separated. The Technology Governance and Digital Trasformation programme is designed to bridge these gaps. The current crisis has made the Technology Governance approach more necessary than ever. Not only are several of the core faculty members among the earliest who predicted the coming of the collapse, but they are all actively engaged in dealing with crisis now, both nationally and internationally.

Our Master’s programme in Technology Governance and Digital Transformation is a technology-focused special graduate degree as a realistic alternative to mainstream economics that could be placed in such areas as innovation policy, industrial policy or development economics. This is the international innovation policy and high-tech programme with a solid foundation in history and theory, embedded in an exciting environment that so many students and scholars were always looking for, yet could not find! Our Master’s programme in Technology Governance and Digital Transformation is a technology-focused special graduate degree as a realistic alternative to mainstream economics that could be placed in such areas as innovation policy, industrial policy or development economics. This is the international innovation policy and high-tech programme with a solid foundation in history and theory, embedded in an exciting environment that so many students and scholars were always looking for, yet could not find! 

The programme is interesting as an early- or mid-career professional degree for those working in development authorities, private companies and NGOs. Programme graduates are working in the following organizations: Morgan Stanley (London), GIZ Private Sector Development Project (Georgia), Office of Prime Minister (Greece), Ministry of Economic Affairs and Communications (Estonia) and various IT companies (Edicy, RM Solutions etc.). Other potential employers include international organizations, governmental institutions, science and technology parks, development agencies, think-tanks, and technology-intensive private companies.

Faculty

Faculty of Social Sciences

Studying humanities and social sciences has become increasingly popular at the University. The studies in Technology Governance are organized by the Ragnar Nurkse School of Innovation and Governancee. There are about 450 students studying for a diploma, bachelor’s, master’s or doctoral degree. The School offers also courses in philosophy, cultural history, logic, and the history of technology. The lecturers of the programme are internationally recognized professionals.

Curriculum

Structure of curriculum

Future career options

Although the program is designed to educate prospective policy analysts and public servants, it is also ideal for those who see themselves working in the private sector (entrepreneurs, consultants, analysts) or non-governmental organisations. Potential employers could include international organisations, science and technology parks, development agencies, think-tanks, and technology-intensive companies. Furthermore, the program provides the grounds for a continuing academic career by engagement as a researcher in academic institutions or pursuing PhD studies. Career examples of our alumni: JP Morgan Stanley, Innovalue Management Partner GmbH, Office of the State Minister of Georgia, Estonian Ministry of Economic Affairs and Communications, Czechinvest, etc.



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The MSc in Environmental Technology has been running for over 40 years and provides the highest standard of knowledge and skills development for environmental and sustainability specialists. Read more

The MSc in Environmental Technology has been running for over 40 years and provides the highest standard of knowledge and skills development for environmental and sustainability specialists. Through the course students acquire a diverse range of discipline-specific problem-solving skills for tackling contemporary sustainability issues. A major emphasis of the course is on the way that environments function and on the compatible tools, alternative technologies and policies for sustainable environmental management.

Our course combines the natural and social sciences, engineering and business in a truly interdisciplinary manner, providing a foundation for graduates to demonstrate their ability to identify and resolve environmental and sustainability issues in a holistic way. This broad training is followed by an in-depth education in many specialised areas, maintaining the course's interdisciplinary nature. The specialist options in the second term are designed to cater for a variety of individual interests and career requirements. 

The course provides students with different options to build on their undergraduate degree, by allowing them to specialise in an area of particular interest, convert undergraduate knowledge to a different setting, differentiate for the job market and learn specific techniques and tools for research and management.

MSc candidates learn to appreciate that successful projects depend, at least in part, on belonging to a network of experts aiming to advance personal and collective environmental goals. We emphasise a friendly and supportive learning environment.

Building on Imperial’s environmental world-class research portfolio, dedicated teaching staff coordinate the interdisciplinary nature of our course and very strong links with industry, business and regulators. We pride ourselves on the quality of the service we provide to students, science and the society, and our excellence in delivering the valuable interaction between scientific/technological training and industrial experience.

Course Structure

First term – Core Course

The Core Course emphasises contemporary policy debates through a number of cross-cutting themes: climate change and energy, international development, sustainability and health, and biodiversity. This is delivered through the following modules:

Second term – specialist Options

Student elect to specialise in one of nine Options in the second term. A strong case study approach is employed with emphasis on working in teams, decision-making, strong analytical skills and report writing and delivery. The nine specialist options currently offered on the course include:

Third Term – Individual Research Project

The research project term, running from April to September, aims to provide graduates with valuable research and practical experience and give them the ability to address individual sustainability and environmental problems with confidence. It provides the opportunity to undertake rigorous independent research; to apply knowledge and understanding of sustainability and environmental disciplines to practical problems; and to develop and demonstrate interdisciplinary, transferable skills with specific emphasis on project management and oral and written presentation skills. 

The research project normally follows from the specialist Option and may involve any combination of desk-, laboratory- or fieldwork. It may be set up and carried out in conjunction with an outside organisation thereby providing practical experience which greatly enhances employment prospects, and may be carried out in the UK or abroad.

Learning Approach

The programme aims to: 

• Provide the highest standard of training for environmental scientists and managers, who will become leaders in their fields, whether in academia, consultancy, research, government bodies, non-governmental organisations or industry and commerce, both nationally and internationally

• Deliver an holistic understanding of the interdisciplinary complexities underlying environmental issues integrating science, technology, law, economics, policy and management, with in-depth education in the more specific areas addressed by the eight specialist options

• Attract highly motivated students, both from within the UK and from overseas

 The expected learning outcomes are:

  • to understand the fundamental mechanisms operating in the environment and the principles underlying the tools for sustainable environmental management
  • to specialise in particular chosen areas
  • to develop the ability to conduct independent rigorous research into environmental problems with confidence
  • to be able to employ a knowledge from range of subjects necessary to understand and resolve practical sustainability and environmental problems
  • to develop interpersonal and transferable skills, quantitative and qualitative skills

Links with Industry

The MSc in Environmental Technology has developed very strong links with employers and research organisations, and maintains strong links with our large alumni body. All Options benefit from industry and alumni teaching into the course, actively complementing the academic teaching delivered by staff members. Collaborative frameworks are in place aim to deliver outputs beneficial to both organisations and the students in our course.



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The Master of Science in Industrial Ecology (IE) offers talented students from around the world the opportunity to enhance their expertise and work on the grand challenge to achieve global prosperity within the planetary boundaries. Read more

The Master of Science in Industrial Ecology (IE) offers talented students from around the world the opportunity to enhance their expertise and work on the grand challenge to achieve global prosperity within the planetary boundaries.

What does this master’s programme entail?

The master's programme Industrial Ecology is an emerging scientific discipline that takes a systemic approach to environmental problems. An interdisciplinary approach, integrating technical, environmental and social frames of reference, is essential for sustainable development. The Master in Industrial Ecology is a co-operation between Leiden University and Delft University of Technology. Both universities are at the forefront of the field of Industrial Ecology.

Read more about our Industrial Ecology programme.

Why study Industrial Ecology at Leiden University?

  • You will learn concepts such as industrial metabolism, industrial symbiosis, industrial evolution and life cycle thinking, in order to generate innovative solutions as a catalyst for change.
  • We offer an international multidisciplinary environment, where each student brings their own specific bachelor knowledge and cultural background. We believe that this multidisciplinary approach is the best way to move forward.
  • Collaboration with third parties, such as national or international partner universities, NGOs, industrial partners, or government institutes is encouraged and facilitated.
  • You will be inspired by professors from two world-class universities, who are at the forefront of the field of Industrial Ecology.

Find more reasons to study Industrial Ecology at Leiden University.

Industrial Ecology: the right master’s programme for you?

The programme is open to students from a wide range of studies in engineering, natural and social sciences. If you are an idealistic, ambitious and critical thinking student who is looking for the opportunity to enhance expertise and work on the grand challenges facing our world today, this master’s programme is the right choice.

Read more about the entry requirements for Industrial Ecology.



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Manufacturing is at the heart of engineering, as everything in our daily lives needs to be made. Manufacturing engineers therefore play a vital role in the creation of wealth and in sustaining and improving the living standards of society. Read more

Manufacturing is at the heart of engineering, as everything in our daily lives needs to be made. Manufacturing engineers therefore play a vital role in the creation of wealth and in sustaining and improving the living standards of society. The Advanced Manufacturing Technology & Systems Management course is one of the most well-established of its kind in the UK, and it aims to provide our students with the tools, knowledge and understanding of this broad based discipline that demands expertise in many diverse topics.  

This course is one of the most well-established of its kind in the UK, having evolved from the very successful MSc course in Machine Tool Technology, and is regularly updated in line with subject developments and changing industrial practices. Advanced Manufacturing Technology and Systems Management has developed into a broad based multi-disciplinary field, demanding expertise in many diverse topics. The structure of the course reflects this by requiring in-depth study of a number of topics ranging from the fundamentals of manufacturing processes to the management of manufacturing systems. More specialised study takes place during the dissertation project where students undertake individual research projects of industrial relevance. The MSc course has a strong practical orientation and it aims to produce engineers with the theoretical and practical experience which will enable them to analyse and investigate problems and to engage in design, development and research involving manufacturing technology. The course also prepares graduates for the management of manufacturing systems. Whilst the course is intended primarily for those wishing to pursue an industrial career, it is equally relevant as preparation for research in advanced manufacturing technology and systems management.

Teaching and learning

The Advanced Manufacturing Technology and Systems Management MSc is a full time course which is studied over 12 months and there is one start date each year in September. 

Throughout the course you will develop advanced technical skills in both manufacturing technology and systems management, as well as soft skill such as team working, presenting and report writing, all of which will enable you to pursue a career in both general and specialised engineering industries or develop an in-depth knowledge for a career in research in industry or academia.

During the course you will visit a number of companies, such as Airbus and Jaguar Land Rover, and have the opportunity to attend industrial guest lectures, which will not only further enhance your understanding of manufacturing but also to give you an insight into the practical application of many of the subject areas you will be studying. Moreover, many of the dissertation projects, one of which you will be working on as part of this course, originate from and are run in collaboration with industry.

For further information about the course content, please see the example programme structure .

Disability support

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

Career opportunities

The Advanced Manufacturing Technology and Systems Management MSc has a strong focus on employability, which will give you the best chance of securing your ideal job after graduation. Most academics who teach on this course have strong links with industry, which you will benefit from, not only by having the opportunity to visit a number of companies and attend industrial talks but also to work on a dissertation project that is closely related to an industrial problem.

Each year Manchester careers fairs, workshops and presentations attract more than 600 exhibitors and 20,000 visitors illustrating how employers target Manchester graduates.

After graduating with an MSc in Advanced Manufacturing Technology and Systems Management you will be in a strong position to seek employment with companies such as: Rolls Royce, Airbus, BAE Systems, Siemens, Jaguar Land Rover, Bentley Motors, Nissan Motor Company, Bombardier Transportation, to name just a few.

Destination of Leavers Survey

Every year our The University of Manchester conducts a destination of leavers survey with students six months after they have graduated. A small selection of these destinations since 2010 is listed below:

  • Rolls Royce (Design Engineer)
  • The University of Manchester (PhD Researcher)
  • University of Sheffield (PhD Researcher)
  • BAE Systems (Design Engineer)
  • Airbus UK (Research and Technology Engineer)
  • Siemens
  • Tata Steel

Accrediting organisations

The  Institution of Mechanical Engineers has accredited the Advanced Manufacturing Technology and Systems Management MSc course under license from the UK regulator, the Engineering Council. This allows satisfactory completion of the Advanced Manufacturing Technology and Systems Management MSc to contribute towards the academic requirements for registration with the Institution as a Chartered Engineer.



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IN THIS 18-MONTH INTENSIVE PART-TIME PROGRAM YOU WILL GAIN. - Skills and know-how in the latest technologies in instrumentation, process control and industrial automation. Read more
IN THIS 18-MONTH INTENSIVE PART-TIME PROGRAM YOU WILL GAIN:

- Skills and know-how in the latest technologies in instrumentation, process control and industrial automation
- Guidance from industrial automation experts in the field
- Knowledge from the extensive experience of instructors, rather than from the clinical information gained from books and college
- Credibility as the local industrial automation expert in your firm
- Networking contacts in the industry
- Improved career prospects and income
- An Advanced Diploma of Industrial Automation

Next intake starts October 09, 2017. Applications now open; places are limited.

Contact us now to secure your place!

Payment is not required until around 2 to 4 weeks before the start of the program.

The EIT Advanced Diploma of of Industrial Automation is recognized worldwide and has been endorsed by the International Society of Automation (ISA). Please ask us about specific information on accreditation for your location.

OVERVIEW

Gain strong underpinning knowledge and expertise in Industrial Automation covering a wide range of skills ranging from instrumentation, automation and process control, industrial data communications, process plant layout, project and financial management and chemical engineering with a strong practical focus. Industrial Automation is an extremely fast moving area especially compared to the more traditional areas such as electrical and mechanical engineering. The field is diverse and dynamic and offers the opportunity for a well paid and enjoyable career. The aim of the course is to empower you with practical knowledge that will improve your productivity in the area and make you stand out as a leader in industrial automation amongst your peers.

*JOB OUTCOMES, INTERNATIONAL RECOGNITION AND PROFESSIONAL MEMBERSHIP:

A range of global opportunities awaits graduates of the Advanced Diploma of Industrial Automation. Pending full accreditation you may become a full member of Engineers Australia and your qualification will be recognized by Engineers Australia and (through the Dublin Accord) by leading professional associations and societies in Australia, Canada, Ireland, Korea, New Zealand, South Africa, United Kingdom and the United States. The Dublin Accord is an agreement for the international recognition of Engineering Technician qualifications.

For example, current enrolled students can apply for free student membership of Engineers Australia. After graduation, you can apply for membership to become an Engineering Associate, while graduates interested in UK recognition can apply for membership of the Institution of Engineering and Technology (IET) as a Technician Member of the Institution of Engineering and Technology.

This professional recognition greatly improves the global mobility of graduates, and offers you the opportunity of a truly international career.

You will be qualified to find employment as an Engineering Associate in public and private industry including transportation, manufacturing, process, construction, resource, energy and utilities industries. Engineering Associates often work in support of professional engineers or engineering technologists in a team environment. If you prefer to work in the field you may choose to find employment as a site supervisor, senior technician, engineering assistant, or similar.

PROGRAM STRUCTURE

The program is composed of 72 topics within 21 modules. These cover the following seven engineering threads to provide you with maximum practical coverage in the field of industrial automation:

- Instrumentation, Automation and Process Control
- Electrical Engineering
- Electronics
- Industrial Data Communications and Networking
- Mechanical Engineering
- Project Management
- Chemical Engineering

The modules will be completed in the following order:
1. Practical Instrumentation for Automation and Process Control
2. Practical Fundamentals of Chemical Engineering (for Non- Chemical Engineers)
3. Control Valve Sizing, Selection and Maintenance
4. Fundamentals of Process Plant Layout and Piping Design
5. Practical Process Control for Engineers and Technicians
6. Practical Tuning of Industrial Control Loops for Engineers and Technicians
7. Practical Distributed Control Systems (DCS)
8. Practical Programmable Logic Controllers (PLCs) for Automation and Process Control
9. Best Practice in Industrial Data Communications
10. Practical Advanced Process Control for Engineers and Technicians
11. Practical Boiler Control and Instrumentation for Engineers and Technicians
12. Practical Hazardous Areas for Engineers and Technicians
13. Practical Safety Instrumentation and Emergency Shutdown Systems for Process Industries Using IEC 6155 and IEC 61508
14. Practical HAZOPS (Hazard and Operability Studies) for Engineers and Technicians
15. Practical Shielding, EMC/EMI, Noise Reduction, Earthing and Circuit Board Layout of Electronic Systems
16. Practical Wireless Ethernet and TCP/ IP Networking
17. Practical Radio Telemetry Systems for Industry
18. Practical SCADA Systems for Industry
19. Motor Protection, Control and Maintenance Technologies
20. Practical Power Distribution for Engineers and Technicians
21. Practical Project Management for Electrical, Instrumentation and Mechanical Engineers and Technicians

COURSE FEES

EIT provides distance education to students located all around the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. We aim to give you a rapid response regarding course fees that are relevant to your individual circumstances.

We understand that cost is a major consideration before a student begins to study. For a rapid reply to your query regarding course fees and payment options, please contact a Course Advisor in your region via the below button and we will respond within two (2) business days.

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This course will train physicists and engineers in the area of photonics, which is a key enabling technology, underpinning many areas of industry. Read more

Why this course?

This course will train physicists and engineers in the area of photonics, which is a key enabling technology, underpinning many areas of industry.

You'll have the opportunity to undertake a three-month research or development project based with one of our industrial partners such as M Squared Lasers.

We have a long tradition of cutting-edge photonics research, which supports our courses. Much of this work has resulted in significant industrial impact through our spin-out companies and academic-industrial collaborations.

You'll also have the opportunity to develop your entrepreneurial skills by taking courses delivered by the Hunter Centre for Entrepreneurship.

You’ll study

The course is made up of two semesters of taught classes, followed by a three-month research project based with one of our industrial partners. The majority of your classes are delivered by the Department of Physics and cover the following:
-research and grant writing skills, which are valuable in both academic and commercial settings
-project training, including entrepreneurial and innovation skills training and a literature survey preparing for the project in the company
-topics in photonics, covering laser physics, laser optics and non-linear optics
-optical design, where you will learn about advanced geometrical optics and apply this knowledge to the design of optical systems, through the use of modern optical design software
-photonic materials and devices, focusing on semiconductor materials physics and micro/nano-structures
-advanced photonic devices and applications, covering quantum well structures, waveguides and photonic crystals

These classes are complemented by two classes delivered by the Department of Electronic & Electrical Engineering, which look at:
-system engineering and electronic control which forms a key part of modern optical systems
-photonic systems, where fibre optic communications systems and principles of photonic networks are discussed

Work placement

You'll be based with one of our industrial partners for a three-month project placement. This is your opportunity to experience how research and development operate within a commercial environment. It'll also give you a chance to form strong links with industry contacts.

The project is put forward by the company and supervised by both industrial and academic staff. Training on relevant skills and background will be received before and during the project.

Facilities:
Scotland has a world-leading position in optics and photonics industry.Your project will be carried out mainly in the excellent facilities of our Scottish industry partners. Projects elsewhere in the UK and with international companies may also be possible.

Advanced research facilities are also available in:
-the Department of Physics here at Strathclyde
-the Institute of Photonics
-the Fraunhofer Centre for Applied Photonics

Our research is strongly supported in equipment and infrastructure. This includes a newly opened 3-storey wing in the John Anderson Building as part of a £13M investment programme in Physics. Furthermore, the IoP and FCAP have recently relocated into the University's Technology & Innovation Centre (TIC) which at £90 million TIC is Strathclyde’s single-biggest investment in research and technology collaboration capacity. This new centre will accelerate the way in which researchers in academia and industry collaborate and innovate together in a new specifically designed state-of-the-art building in the heart of Glasgow.

Guest lectures

You'll attend the seminar series of the Institute of Photonics and Fraunhofer Centre of Applied Photonics with distinguished guest speakers giving a first-hand overview of the rapid development in applied photonics research.

Learning & teaching

In semesters one and two, the course involves:
-lectures
-tutorials
-various assignments including a literature review
-workshops where you'll gain presentation experience

The courses include compulsory and elective classes from the Department of Electronic & Electrical Engineering.
Over the summer, you'll undertake a three-month project based on practical laboratory work in a partner company. You'll be supervised by the industrial partner and supported by an academic supervisor.

Assessment

Assessment methods are different for each class and include:
-written examinations
-marked homework consisting of problems and/or essay assignments
-presentations

Your practical project is assessed on a combination of a written report, an oral presentation, and a viva in which you're questioned on the project.

How can I fund my course?

Financial support for Scottish and EU students may be available on a case-by-case basis which will be supported by the industrial partners. Selection will be based on an excellent academic record and/or industrial experience and the promise of a successful career in Industrial Photonics.

Please indicate that you apply for such a scholarship in the "Funding" section of the application form. You'll also need to provide a CV and a statement explaining your interests and motivation with your application. This will inform the decision on a possible scholarship.

For more information, just get in touch with the Department of Physics.

Available scholarships:
We currently have a scholarship available for this course.

You must be able to demonstrate academic excellence based on your previous study along with the promise of a successful career in Industrial Photonics. Relevant previous industrial experience will be considered.

Deadline:
The first round of applications closes on 20th May 2016, and a second one will close on the 30th June 2016.

How to apply:
Apply for this scholarship via our scholarship search: https://www.strath.ac.uk/studywithus/scholarships/sciencescholarships/physicsscholarships/physicsindustrialphotonicsscholarships/

Careers

A degree in industrial photonics can set you up to work in a range of jobs in physics and positions in other industries.

Typically, it can lead you to photonic technologies in industrial corporate research and development units, production engineering and applied academic laboratories.

Work experience is key:
Employers want to know you can do the job so work experience is key.

This course has a strong focus on the relationship between academia and industry. It's a great opportunity to enhance your skills and provides a direct transition from university to the work place.

We have an excellent record of graduate employment in the Scottish, national and international optics and photonics industries.

Doctorate study:
If you're interested in practical work with impact but are also interested in a further academic qualification, you can move on to study an EngD or a CASE PhD studentship. These can lead to a doctorate within industry or in close collaboration with industry.

Job roles:
Our Physics graduates from photonics related courses have found employment in a number of different roles including:

-Medical Physicist
-Optical engineer
-Laser engineer
-Optical and laser production engineer
-Research and production engineer
-Senior Engineer
-Systems Engineer
-Software Engineer
-Spacecraft Project Manager
-Defence Scientist
-Oscar winner

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Make future breakthroughs within healthcare with the MSc Biomedical Engineering with Healthcare Technology Management course. This course is for inquisitive students who want to design, develop, apply or even manage the use of cutting-edge methods and devices that will revolutionise healthcare. Read more
Make future breakthroughs within healthcare with the MSc Biomedical Engineering with Healthcare Technology Management course.

Who is it for?

This course is for inquisitive students who want to design, develop, apply or even manage the use of cutting-edge methods and devices that will revolutionise healthcare. It is open to science and engineering graduates and those working within hospitals or related industry who want to work in healthcare organisations, in the medical devices industry, or in biomedical engineering research.

The course will suit recent graduates and/or clinical engineers with a technical background or those working in healthcare who want to move into a management position.

Objectives

With several medical conditions requiring extensive and continuous monitoring and early and accurate diagnosis becoming increasingly desirable, technology for biomedical applications is rapidly becoming one of the key ingredients of today and tomorrow’s medical care.

From miniaturised home diagnostic instruments to therapeutic devices and to large scale hospital imaging and monitoring systems, healthcare is becoming increasingly dependent on technology. This course meets the growing need for biomedical and clinical engineers across the world by focusing on the design of medical devices from conception to application.

One of the few accredited courses of its kind in London, the programme concentrates on the use of biomedical-driven engineering design and technology in healthcare settings so you can approach this multidisciplinary topic from the biological and medical perspective; the technological design and development perspective; and from the perspective of managing the organisation and maintenance of large scale equipment and IT systems in a hospital.

This MSc in Biomedical Engineering with Healthcare Technology Management course has been created in consultation and close collaboration with clinicians, biomedical engineering researchers and medical technology industrial partners. The programme fosters close links with the NHS and internationally-renowned hospitals including St. Bartholomew's (Barts) and the Royal London Hospital and Great Ormond street so that you can gain a comprehensive insight into the applied use and the management of medical technology and apply your knowledge in real-world clinical settings.

Placements

In the last few years there have been some limited opportunities for our top students to carry out their projects through placements within hospital-based healthcare technology groups or specialist London-based biomedical technology companies. Placement-based projects are also offered to selected students in City’s leading Research Centre for Biomedical Engineering (RCBE). As we continue our cutting-edge research and industrial and clinical collaborations, you will also have this opportunity.

Academic facilities

As a student on this course you will have the opportunity to work with cutting-edge test and measurement instrumentation – oscilloscopes, function generators, analysers – as well as specialist signal generators and analysers. The equipment is predominantly provided by the world-leading test and measurement equipment manufacturer Keysight, who have partnered with City to provide branding to our electronics laboratories. You also have access to brand new teaching labs and a dedicated postgraduate teaching lab. And as part of the University of London you can also become a member of Senate House Library for free with your student ID card.

Teaching and learning

You will be taught through face-to-face lectures in small groups, where there is a lot of interaction and feedback. Laboratory sessions run alongside the lectures, giving you the opportunity to develop your problem-solving and design skills. You also learn software skills in certain modules, which are taught inside computer labs. We also arrange hospital visits so you gain hands-on experience of different clinical environments.

We arrange tutorials for setting coursework, highlight important subject areas, conduct practical demonstrations, and offer support with revision. You are assessed by written examinations at the end of each term, and coursework assignments, which are set at various times throughout the term.

You also work towards an individual project, which is assessed in the form of a written thesis and an oral examination at the end of the summer. The project can be based on any area of biomedical engineering, telemedicine or technology management and will be supervised by an academic or clinical scientist with expertise in the subject area. Many projects are based in hospital clinical engineering departments, or if you are a part-time student, you can base the project on your own workplace. You will have regular contact with the supervisor to make sure the project progresses satisfactorily. Some of the programme’s current students are working on a project focusing on devices that use brain signals to move external objects such as a remote control car and a prosthetic arm.

Some of the previous projects students have worked on include:
-A cursor controller based on electrooculography (EOG)
-Modelling a closed-loop automated anaesthesia system
-Design of a movement artefact-resistant wearable heart rate/activity monitor
-Review of progress towards a fully autonomous artificial mechanical heart
-Design of smartphone-based healthcare diagnostic devices and sensors.

If you successfully complete eight modules and the dissertation 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. Completing four modules (60 credits) will lead to a postgraduate certificate.

Modules

Along with the 60 credit dissertation eight core modules cover diverse subject areas including biomedical electronics and instrumentation, technology infrastructure management, as well as the latest advances in medical imaging and patient monitoring.

The course includes a special module which gives you an introduction to anatomy, physiology and pathology designed for non-clinical science graduates.

The most innovative areas of biomedical and clinical engineering are covered and the content draws from our research expertise in biomedical sensors, bio-optics, medical imaging, signal processing and modelling. You will learn from academic lecturers as well as clinical scientists drawn from our collaborating institutions and departments, which include:
-Charing Cross Hospital, London
-The Royal London Hospital
-St Bartholomew's Hospital, London
-Basildon Hospital
-Department of Radiography, School of Community and Health Sciences, City, University of London

Modules
-Anatomy, Physiology and Pathology (15 credits)
-Physiological Measurement (15 credits)
-Biomedical Instrumentation (15 credits)
-Medical Electronics (15 credits)
-Cardiovascular Diagnostics and Therapy (15 credits)
-Medical Imaging Modalities (15 credits)
-Clinical Engineering Practice (15 credits)
-Healthcare Technology Management (15 credits)

Career prospects

This exciting MSc programme offers a well-rounded background and specialised knowledge for those seeking a professional career as biomedical engineers in medical technology companies or research groups but is also uniquely placed for offering skills to clinical engineers in the NHS and international healthcare organisations.

Alumnus Alex Serdaris is now working as field clinical engineer for E&E Medical and alumna Despoina Sklia is working as a technical support specialist at Royal Brompton & Harefield NHS Foundation Trust. Other Alumni are carrying out research in City’s Research Centre for Biomedical Engineering (RCBE).

Applicants may wish to apply for vacancies in the NHS, private sector or international healthcare organisations. Students are encouraged to become members of the Institute of Physics and Engineering in Medicine (IPEM) where they will be put in touch with the Clinical Engineering community and any opportunities that arise around the UK during their studies. Application to the Clinical Scientist training programme is encouraged and fully supported.

The Careers, Student Development & Outreach team provides a professional, high quality careers and information service for students and recent graduates of City, University of London, in collaboration with employers and other institutional academic and service departments. The course also prepares graduates who plan to work in biomedical engineering research and work within an academic setting.

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ENGINEERING THE FUNCTIONAL RESTORATION OF TISSUES AND ORGANS. Regenerative Medicine and Technology. (RMT) combines fundamental disciplines such as stem cell biology, materials science and biomechanics with more applied disciplines such as cell therapy, implantology and imaging. Read more

ENGINEERING THE FUNCTIONAL RESTORATION OF TISSUES AND ORGANS

Regenerative Medicine and Technology (RMT) combines fundamental disciplines such as stem cell biology, materials science and biomechanics with more applied disciplines such as cell therapy, implantology and imaging. New collaborations amongst these disciplines can assist in innovation in fundamental life sciences but also in new patient therapies and clinical applications with the ultimate goal to restore lost tissue or organ function.

This Master’s programme aims to train multidisciplinary scientists and to stimulate innovative research at the interface between biomedical sciences, engineering and clinical application. The rapidly emerging multidisciplinary field of regenerative medicine has significant effects on current and future health care applications. Our strong focus on technology will equip you with an understanding of processes ranging from specific cell culturing techniques and the use of biomaterials to computer models and imaging modalities.

Utrecht University offers the Master’s programme in cooperation with the University Medical Center Utrecht and the Faculty of Biomedical Engineering at Eindhoven University of Technology (TU/e). The programme combines the expertise of both universities and provides access to their state-of-the-art laboratories and research groups.

WHY STUDY REGENERATIVE MEDICINE AND TECHNOLOGY AT UTRECHT UNIVERSITY?

  • A unique combination of the TU/e technological with the UMC Utrecht clinical and UU biomedical approach
  • Excellent international reputation in the RM field and partners in innovative research projects with partners worldwide allowing students to do their internship at prestigious partner institutions all around the world .
  • New Utrecht Regenerative Medicine Center realized in 2015 at the Uithof campus gives students the opportunity to familiarize themselves with innovative science and to collaborate with the scientists associated with it
  • As a student you will have the opportunity to carry out two hands-on research projects at renowned research groups.

STUDY PROGRAMME

As a Master’s student of Regenerative Medicine and Technology you will take theoretical courses and seminars as well as master classes led by renowned specialists in the field in both Eindhoven and Utrecht. The courses are interactive, and challenge students to further improve their communication, writing and presenting skills. During your six to nine month internships you work in a lively research environment in academia or in consultancy companies and industry.

CAREER IN REGENERATIVE MEDICINE AND TECHNOLOGY

Regenerative Medicine and Technology will address the shortage of donor organs/tissue by providing the opportunity to produce tissue substitutes. As a graduates you can pursue a career in academic (PhD) or in industrial and commercial directions, including R&D, sales and consultancy.



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The master's programme Water Technology is a two-year MSc programme with a joint degree. Global water threats and water challenges in society require new directions that lead to breakthrough solutions. Read more

The master's programme Water Technology is a two-year MSc programme with a joint degree. Global water threats and water challenges in society require new directions that lead to breakthrough solutions. You will develop new water processes and find technological answers. Science and technology from various disciplines adds value to your career in water research and business.

Study programme

New water process technology needs to be developed in order to produce clean water from alternative sources like salt (sea) water, waste water or humid air minimizing the use of precious groundwater and to treat waste water and to recover valuable compounds. These challenges require academically-trained experts that can think out of the box and help to find process oriented technological solutions in the near future.

To train and educate these experts a dedicated joint master’s programme in Water Technology has been set up. The programme is offered jointly by Wageningen University & Research, University of Twente and University of Groningen. You will study in Leeuwarden at Wetsus, the European centre of excellence for sustainable water technology.

On the programme of Water Technology page you can find the general outline of the programme and more detailed information about courses, thesis and internship. 

Wetsus as innovation environment

Wetsus brings researchers from various disciplines together in one research laboratory. In this way, it creates a unique multidisciplinary environment to develop new innovations.

A huge network of universities and companies enable the exchange of ideas, knowledge and opportunities. Wetsus aims at breakthrough process oriented technological solutions. Learn more about the innovation environment.

Your future career

This study domain is becoming more and more relevant due to the urgent need for new technologies to meet global water problems. Water technology for public drinking water production and sewage water treatment is a very large market. Furthermore, the largest use of fresh water is for irrigation purposes. The industrial water supply and industrial waste water treatment also represent a significant market. There is no question that businesses involved in water technology will grow tremendously. Besides this, human capital is a basic condition to guarantee the success and continuity of the development of sustainable technologies. In many EU countries, the lack of talented technological professionals is becoming an increasingly limiting factor. The programme prepares students for a professional position in the broad area of water technology. Graduates have good national and international career prospects in business and research.

Student Stefanie Stubbé.

"Wetsus gave me the opportunity to get personalized education: teachers that take the time for you and fellow students that challenge and collaborate with you at the same time. Water technology is going to be huge in the future; I already experienced that at several companies when I searched for an internship. Although it is sometimes hard work and far away from the "city-life" in the Netherlands; I've never regretted my choice to start this Master!"

Related programmes:

MSc Biotechnology 

MSc Environmental Sciences



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The Advanced Technology programme has been designed to allow you to study a range of engineering and technology subjects at postgraduate level. Read more
The Advanced Technology programme has been designed to allow you to study a range of engineering and technology subjects at postgraduate level. It offers a choice of flexible options – you can choose to study full time at the University, to combine work and study (where the majority of your study will be based in your place of work) or to study by distance learning, if that suits you best. This course provides an opportunity for you to earn a Masters degree by studying in different formats, in work, distance learning of full time. There are a number of prescribed subtitles of MSc Advanced Technology:
-Mechanical Engineering
-Electronic Engineering
-Electrical Engineering
-Technology Management
-Energy Technology
-Design Technology
-Sports Technology
-Digital Media Technology

You can also negotiate to study in a different area that the faculty can support using the MSc Advanced Technology title.

Course content

Work Based Study
Your work may already be of Masters level, using the MSc Advanced Technology award you can get full recognition for it by submitting it towards a Masters degree from Staffordshire University. This is also a way in which your employer may provide an opportunity for you to further your education in areas of study directly related to your employment thus making you a more efficient employee. Virtually all parts of the course can be studied at your place of work. You need to attend the University only to maintain contact with tutors and to present your work at seminars.

Part Time Study
This is for students who are employed in industry in a capacity which provides an appropriate setting for MSc study. You will be assigned a supervisor who will guide your studies throughout the course. Your supervisor will set assignments for you and will recommend material for you to study as required to complete your assignments by self study. Your supervisor will be available for consultation via email, phone etc.

Full Time Study
This course is primarily offered on a part time basis, but you can also study full time if you wish. You will need to be available at Staffordshire University full time during teaching semesters. You may be given taught classes to attend as part of your studies for Modules 1, 2 and 3. These classes will be selected to provide appropriate contributions to your course of study, but will not provide all the content required for all of the modules.

You will also be assigned a supervisor who will give you additional assignments for self study to complete the requirements for Modules 1, 2 and 3. Your supervisor will recommend study material as required for you to complete these assignments. Your supervisor will be available for consultation on a weekly or bi-weekly basis.

All students study the same four modules below, however, the contents of each module vary depending on the subject areas you have chosen for your project. Supervising staff assist students in identifying and defining the detail of the module content, much of which is based on research and project work. Whilst most study and assessment is assignment based, you also have the opportunity to attend appropriate formal lectures at the University.

Module 1 Project Management and Research Methods (30 credits) provides basic knowledge of project management techniques and research methods required for industrial research and development work and to undertake MSc project work. It also teaches you how to communicate the findings in a concise and professional manner.

Module 2 Advanced Technology (30 credits) refreshes and enhances your knowledge in a broad range of interrelated subject areas within the chosen discipline. If you plan to proceed to an MSc, the material studied in this module provides a broad foundation for the research topic chosen for Module 4.

Module 3 Specialist Technology (60 credits) provides a high level of technical expertise in a specialist area for students who wish to graduate with a postgraduate diploma. It also provides the required specialists technical knowledge required to proceed to the MSc project in Module 4.

Module 4 MSc Project and Thesis (60 credits) lets you apply the material studied in the previous modules to an advanced research project. It prepares you for planning and undertaking leading edge industry based research and development work with a high degree of competence and minimal supervision.

Employment opportunities

Many students take this course as a way of securing promotion or use it to cover the further learning requirements to gain Chartered Engineering status. Other options on graduation are progression to further study of MPhil or PhD qualifications.

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