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Masters Degrees (Fibre Optics)

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Materials are substances or things from which something is or can be made. Technological development is often based on the development of new materials. Read more
Materials are substances or things from which something is or can be made. Technological development is often based on the development of new materials. Materials research plays an important part in solving challenging problems relating to energy, food, water, health and well-being, the environment, sustainable use of resources, and urbanisation.

An expert in materials research studies the chemical and physical bases of existing and new materials; their synthesis and processing, composition and structure, properties and performance. As an expert in materials research, your skills will be needed in research institutions, the technology industry (electronics and electrotechnical industry, information technology, mechanical engineering, metal industry, consulting), chemical industry, forest industry, energy industry, medical technology and pharmaceuticals.

This programme combines expertise from the areas of chemistry, physics and materials research at the University of Helsinki, which are ranked high in international evaluations. In the programme, you will focus on the fundamental physical and chemical problems in synthesising and characterising materials, developing new materials and improving existing ones. Your studies will concentrate on materials science rather than materials engineering.

Upon graduating from the programme you will have a solid understanding of the essential concepts, theories, and experimental methods of materials research. You will learn the different types of materials and will be able to apply and adapt theories and experimental methods to new problems in the field and assess critically other scientists’ work. You will also be able to communicate information in your field to both colleagues and laymen.

Depending on the study line you choose you will gain in-depth understanding of:
-The synthesis, processing, structure and properties of inorganic materials.
-Modelling methods in materials research.
-The structure and dynamics of biomolecular systems.
-The synthesis, structure and properties of polymers.
-Applications of materials research in industrial applications.
-The use of methods of physics in medicine.

The University of Helsinki will introduce annual tuition fees to foreign-language Master’s programmes starting on August 1, 2017 or later. The fee ranges from 13 000-18 000 euros. Citizens of non-EU/EEA countries, who do not have a permanent residence status in the area, are liable to these fees. You can check this FAQ at the Studyinfo website whether or not you are required to pay tuition fees: https://studyinfo.fi/wp2/en/higher-education/higher-education-institutions-will-introduce-tuition-fees-in-autumn-2017/am-i-required-to-pay-tuition-fees/

Programme Contents

In the programme, all teaching is based on the teachers’ solid expertise in the fundamental chemistry and physics of materials. All teachers also use their own current research in the field in their teaching.

Your studies will include a variety of teaching methods such as lectures, exercises, laboratory work, projects and summer schools.

In addition to your major subject, you can include studies in minor subjects from other programmes in chemistry, physics and computer science.

Selection of the Major

At the beginning of your studies you will make a personal study plan, with the help of teaching staff, where you choose your study line. This programme has the following six study lines representing different branches of materials research.

Experimental Materials Physics
Here you will study the properties and processing of a wide variety of materials using experimental methods of physics to characterise and process them. In this programme the materials range from the thin films used in electronics components, future fusion reactor materials, and energy materials to biological and medical materials. The methods are based on different radiation species, mostly X-rays and ion beams.

Computational Materials Physics
In this study line you will use computer simulations to model the structures, properties and processes of materials, both inorganic materials such as metals and semiconductors, and biological materials such as cell membranes and proteins. You will also study various nanostructures. The methods are mostly atomistic ones where information is obtained with atomic level precision. Supercomputers are often needed for the calculations. Modelling research is closely connected with the experimental work related to the other study lines.

Medical Physics
Medical physics is a branch of applied physics encompassing the concepts, principles and methodology of the physical sciences to medicine in clinics. Primarily, medical physics seeks to develop safe and efficient diagnosis and treatment methods for human diseases with the highest quality assurance protocols. In Finland most medical physicists are licensed hospital physicists (PhD or Phil.Lic).

Polymer Materials Chemistry
In this line you will study polymer synthesis and characterisation methods. One of the central questions in polymer chemistry is how the properties of large molecules depend on the chemical structure and on the size and shape of the polymer. The number of applications of synthetic polymers is constantly increasing, due to the development of polymerisation processes as well as to better comprehension of the physical properties of polymers.

Inorganic Materials Chemistry
Thin films form the most important research topic in inorganic materials chemistry. Atomic Layer Deposition (ALD) is the most widely studied deposition method. The ALD research covers virtually all areas related to ALD: precursor synthesis and characterisation, film growth and characterisation, reaction mechanism studies, and the first steps of taking the processes toward applications. The emphasis has been on thin film materials needed in future generation integrated circuits, but applications of ALD in energy technologies, optics, surface engineering and biomaterials are also being studied. Other thin film deposition techniques studied include electrodeposition, SILAR (successive ionic layer adsorption and reaction) and sol-gel. Nanostructured materials are prepared either directly (fibres by electrospinning and porous materials by anodisation) or by combining these or other templates with thin film deposition techniques.

Electronics and Industrial Applications
Sound and light are used both to sense and to actuate across a broad spectrum of disciplines employing samples ranging from red hot steel to smooth muscle fibres. Particular interest is in exploiting the link between the structure and mechanics of the samples. The main emphasis is on developing quantitative methods suitable for the needs of industry. To support these goals, research concentrates on several applied physics disciplines, the main areas being ultrasonics, photoacoustics, fibre optics and confocal microscopy.

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Humber’s Wireless Telecommunications graduate certificate program prepares you with electronics, computer engineering, physics and telecommunications skills for work on the cutting-edge technologies in the wireless telecommunications industry. Read more
Humber’s Wireless Telecommunications graduate certificate program prepares you with electronics, computer engineering, physics and telecommunications skills for work on the cutting-edge technologies in the wireless telecommunications industry.

Students will become familiar with the infrastructure of communications systems and how to be successful in the communications industry. This wireless program focuses on three main outcomes: RF/optical test and measurement, networking, and troubleshooting a number of wireless telecommunications systems.You will learn to use engineering tools and equipment for testing of systems including LTE/UMTS/GSM drive test tools, spectrum analyzers, network analyzers, optical time domain reflectometers. You will also learn how to troubleshoot and configure local- and wide-area networks (LAN/WANs) at the device and at the protocol levels. Our courses cover additional networking topics relevant to telecom carriers such as MPLS, VPNs, QoS and VoIP. You will be prepared to understand the technology roadmap leading into Internet of Things (IoT), 5G and data center virtualization technologies.

This program is an established program with industry with over two decades of expertise. Students will have access to learn on some of the best equipment available. Curriculum is kept current with the collaboration of our industry partners in the wireless field. Students utilize the latest technologies in small classes taught by experienced faculty and industry leaders.

Course detail

Upon successful completion of the program, a graduate will:

• Analyze, test, measure and troubleshoot RF (radio frequency) signals, attenuation and antenna systems, and test and troubleshoot linear and non-linear circuit modules.
• Manage network performance issues and problems against user needs through the design, implementation, testing, and troubleshooting of a variety of current and relevant protocols.
• Build wired and/or wireless networks using design documentation, and measure the performance of both the wired and wireless networks’ components and the networks’ applications using basic and advanced network management tools and applications.
• Design, install and configure networks - implementing various network configurations using different standard protocols, and upgrade network hardware (e.g. workstations, servers, wireless access points, routers, switches, firewalls etc.) and related components and software according to the best practices in the industry.
• Monitor and evaluate network security issues and perform basic security audits on both wired and wireless networks.
• Utilize change control, issue documentation and problem escalation procedures and processes, generate and maintain “as-built” network documentation following industry best practices.
• Apply RF analog and digital circuit analysis and design concepts to analyze voice and data communication using different modulation techniques.
• Use simulation tools to mathematically model and solve RF (radio frequency) electrical and electronics networks which are essential components of telecommunications and wireless technologies.
• Install, or use existing, operating systems & its components and manage users, processes, memory management, peripheral devices, telecommunication, networking and security, and troubleshoot hardware and software components of computer and operating systems using system level commands and scripts.
• Assist in the design and development of a wide area of networks using a variety of network layer-one, layer-two and layer-three protocols, microwave communication links, and fiber optics links.
• Describe the infrastructures, components, and protocols of a wide range of wireless technologies.
• Develop the infrastructure required for VoIP transport through IP networks, and be able to configure VoIP clients such as IP telephones and soft phones.

Modules

Semester 1
• WLS 5000: Applied Electromagnetics
• WLS 5002: RF Technology
• WLS 5003: Telecommunication Systems
• WLS 5004: Data Networks
• WLS 5500: Microwave and Fibre Optics

Semester 2
• WLS 5501: Broadband Communications and Security
• WLS 5503: Mobile Technologies
• WLS 5505: Wireless Data Networks
• WLS 5506: LTE Core
• WLS 5507: Wireless Project and ITIL

Your Career

The Canadian wireless industry supports over 280,000 jobs with sector salary average more than Canada’s average salary. In addition, the international wireless telecommunications market is growing. There are numerous employment opportunities in the planning, developing, manufacturing, co-ordinating, implementing, maintaining and managing of telecommunications systems for businesses and government.

As the rate of technology adoption increases in Canadian industry, the Wireless Telecommunications program is preparing graduates for these new markets. A 2015-2019 labour market report by the Information and Communications Technology Council (ICTC) indicates that by 2019, over 182,000 critical ICT positions will be left unfilled.

Graduates of the program work at cell phone service providers, equipment manufacturers, in house information technology (IT) departments, sales departments, and specialized telecommunication and networking companies.

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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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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This programme provides students with a challenging range of advanced topics drawn from optical communications systems and devices, and optics-related signal processing, including associated enabling technologies. Read more
This programme provides students with a challenging range of advanced topics drawn from optical communications systems and devices, and optics-related signal processing, including associated enabling technologies. It provides an excellent opportunity to acquire the skills needed for a career in the most dynamic fields in optical communications.

This programme builds on the internationally-recognised research strengths of the Photonics and High Performance Networks research groups within the Smart Internet Lab. Optical fibre communications form the backbone of all land-based communications and is the only viable means to support today's global information systems. Research at Bristol is contributing to the ever-increasing requirement for bandwidth and flexibility through research into optical switching technology, wavelength conversion, high-speed modulation, data regeneration and novel semiconductor lasers.

There are two taught units related to optical communications: Optical Networks and Data Centre Networks. Optical Networks focuses on Wavelength Division Multiplexed (WDM) networks, Time Division Multiplexed (TDM) networks including SDH/SONET and OTN, optical frequency division multiplexed networks, and optical sub-wavelength switched networks. Data Centre Networks focuses on networks for cloud computing, cloud-based networking, grid computing and e-science.

The group at Bristol is a world leader in the new field of quantum photonics, with key successes in developing photonic crystal fibre light sources, quantum secured optical communications and novel quantum gate technologies.

The programme is accredited by Institute of Engineering and Technology until 2018, one of only a handful of accredited programmes in the UK.

Programme structure

Your programme will cover the following core subjects:

Semester one (50 credits)
-Communication systems
-Digital filters and spectral analysis
-Mobile communications
-Networking protocol principles
-Optoelectronic devices and systems

Semester two (70 credits)
-Advanced optoelectronic devices
-Data centre networking
-Advanced networks
-Engineering research skills
-Optical communications systems and data networks
-Optical networks

Research project (60 credits)
A substantial research project is initiated during the second teaching block and completed during the summer. This may be based at the University or with industrial partners.

Careers

This one-year MSc programme gives you a world-class education in all aspects of current and future optical communication systems, along with associated signal processing technologies. It will prepare you for a diverse range of exciting careers - not only in the communications field, but also in other areas such as management consultancy, project management, finance and government agencies.

Our graduates have gone on to have rewarding careers in some of the leading multinational communications companies, such as Huawei, China Telecom, Toshiba, China Mobile and Intel. Some graduates follow a more research-oriented career path with a number of students going on to study for PhDs at leading universities.

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Photonics is an exciting area of physics, which enables developments in fields as diverse as biomedical imaging and high power fibre lasers. Read more
Photonics is an exciting area of physics, which enables developments in fields as diverse as biomedical imaging and high power fibre lasers.

The Department of Physics has a long and successful research record in imaging and photonic.

This 12-month MRes, built on our renowned MSc in Optics and Photonics, usually forms the first year of the four-year (MRes+PhD) research training programme in the Photonics Group.

Some funded studentships for the combined MRes and PhD programme are available to Home students.

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