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This MSc provides students with the skills, knowledge and research ability for a career in astrophysics. The programme is designed to satisfy the need, both nationally and internationally, for well-qualified postgraduates who will be able to respond to the challenges that arise from future developments in this field. Read more
This MSc provides students with the skills, knowledge and research ability for a career in astrophysics. The programme is designed to satisfy the need, both nationally and internationally, for well-qualified postgraduates who will be able to respond to the challenges that arise from future developments in this field.

Degree information

Students develop insights into the techniques used in current astrophysics projects, and gain in-depth experience of a particular specialised research area, through project work, as a member of a research team. The programme provides the professional skills necessary to play a meaningful role in industrial or academic life.

Students undertake modules to the value of 180 credits.

The programme consists of a choice of six optional modules (90 credits), a research essay (30 credits) and a research dissertation (60 credits).

A Postgraduate Diploma (120 credits, full-time nine months, part-time two years) is offered.

Optional modules 1 (15 credits each)
Students choose four of the following:
-Planetary Atmospheres
-Solar Physics
-High-energy Astrophysics
-Stellar Atmospheres and Stellar Winds
-Galaxy and Cluster Dynamics
-Cosmology
-Mathematics for General Relativity
-Space Plasma and Magnetospheric Physics

Optional modules 2 (15 credits each)
Students choose two of the following:
-Physics MSc core modules
-Space and Climate Science MSc core modules
-Medical Physics MSc core modules
-Intercollegiate fourth year modules
-Physics and Astrophysics MSc fourth-year modules
-Plastic and Molecular (Opto)electronics

Dissertation/report
Students submit a critical research essay of approximately 8,000 words and undertake an in-depth research project which culminates in a formal report and oral presentation.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials and practical, laboratory and computer-based classes. Student performance is assessed through coursework and written examination. The research project is assessed by literature survey, oral presentation and the dissertation.

Careers

Astrophysics-based careers embrace a broad range of areas, for example information technology, engineering, finance, research and development, medicine, nanotechnology and photonics. Employers regard a physics degree as flexible and highly desirable university training.

Top career destinations for this degree:
-PhD in Astrophysics, Kiel University, Germany
-Research Assistant, University College London
-Research Assistant, Max-Planck-Institut für Kernphysik (Nuclear Physics)
-PhD in Astrophysics, University of Crete

Employability
Astrophysics opens up many avenues to employment through the skills acquired: problem-solving; the training of a logical and numerate mind; computation skills; modelling and material analysis; and the ability to think laterally. In addition, work vision and enthusiasm make physics graduates highly desirable members of all dynamic companies.

Why study this degree at UCL?

UCL Physics & Astronomy is among the top departments in the UK for graduate study.

The department's participation in many international collaborations means we provide exceptional opportunities to work as part of an international team. Examples include the Dark Energy Survey - investigating the origin of the accelerating universe and the nature of dark matter, the Hubble Telescope and the Cassini project.

In some cases, opportunities exist for students to broaden their experience by spending part of their time overseas.

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This MSc provides students with the skills, knowledge and research ability for a career in physics. The programme is designed to satisfy the need, both nationally and internationally, for well-qualified postgraduates who will be able to respond to the challenges that arise from future developments in this field. Read more
This MSc provides students with the skills, knowledge and research ability for a career in physics. The programme is designed to satisfy the need, both nationally and internationally, for well-qualified postgraduates who will be able to respond to the challenges that arise from future developments in this field.

Degree information

Students develop insights into the techniques used in current projects, and gain in-depth experience of a particular specialised research area, through project work as a member of a research team. The programme provides the professional skills necessary to play a meaningful role in industrial or academic life.

Students undertake modules to the value of 180 credits. The programme consists of a choice of three core modules (45 credits), three optional modules (45 credits), a research essay (30 credits) and a dissertation (60 credits). A Postgraduate Diploma (120 credits, full-time nine months, part-time two years) is offered.

Core modules
-Advanced Quantum Theory
-Particle Physics
-Atom and Photon Physics
-Order and Excitations in Condensed Matter
-Mathematics for General Relativity
-Climate and Energy
-Molecular Physics

Please note: students choose three of the above.

Optional modules
-Astrophysics MSc Core Modules
-Space and Climate Science MSc Core Modules
-Medical Physics MSc Core Modules
-Intercollegiate fourth-year courses
-Physics and Astrophysics MSci fourth-year courses
-Physics and Astrophysics MSci third-year courses
-Plastic and Molecular (Opto)electronics

Dissertation/report
All students submit a critical research essay and MSc students undertake an independent research project which culminates in a substantial dissertation and oral presentation.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials and practical, laboratory and computer-based classes. Student performance is assessed through coursework and written examination. The research project is assessed by literature survey, oral presentation and the dissertation.

Careers

Physics-based careers embrace a broad range of areas e.g. information technology, engineering, finance, research and development, medicine, nanotechnology and photonics.

Employability
A Master's degree in Physics is highly regarded by employers. Students gain a deep understanding of both basic phenomena underpinning a range of technologies with huge potential for future development, e.g. quantum information, as well as direct knowledge of cutting-edge technologies likely to play a major role in short to medium term industrial development while addressing key societal challenges such as energy supply or water sanitisation.

Why study this degree at UCL?

UCL Physics & Astronomy is among the top departments in the UK for graduate study.

The department's participation in many international collaborations means we provide exceptional opportunities to work as part of an international team. Examples include work at the Large Hadron Collider in Geneva, and at the EISCAT radar instruments in Scandinavia for studying the Earth's upper atmosphere.

For students whose interests tend towards the theoretical, the department is involved in many international projects, some aimed at the development of future quantum technologies, others at fundamental atomic and molecular physics. In some cases, opportunities exist for students to broaden their experience by spending part of their time overseas.

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This MSc concentrates on the commercially important and rapidly expanding area of embedded digital systems. It is the ideal choice if you plan a career in embedded systems engineering, or for professional development if you already work in the engineering industry. Read more
This MSc concentrates on the commercially important and rapidly expanding area of embedded digital systems. It is the ideal choice if you plan a career in embedded systems engineering, or for professional development if you already work in the engineering industry.

Embedded systems are at the heart of many engineering devices and you will investigate how they are designed and implemented in hardware and software. You will learn how to critically understand and apply circuit and system simulation techniques, with an emphasis on products that incorporate embedded technology. You will also understand the design of embedded systems, including microcontroller architectures and real-time embedded hardware operating systems.

The course has significant input from industry and as part of the course you will be given the chance to undertake a 6-month unpaid internship*. Whilst not compulsory, internships provide the opportunity to put the theory you’ve learned in the classroom into practice in the real world.

Routes of study:
The course is available to study via two routes:
- MSc Embedded Systems Design (with internship)
- MSc Embedded Systems Design (without internship)

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

See the website http://courses.southwales.ac.uk/courses/1492-msc-embedded-systems-design-with-internship

What you will study

Modules include:
- Embedded Systems Design
- Designing with RTOS
- Digital Design with HDLs
- Research Methodology and Product Management
- Opto-Electronics Devices for Life Science and Measurement
- Applied Digital Signal Processing
- * Six month Internship*
- Msc Major Project (60 credits)

Learning and teaching methods

MSc Embedded Systems Design is delivered in three major blocks that offer an intensive but flexible learning pattern, with two entry opportunities for applicants each year in February and September. You will learn to use the latest computer-aided engineering tools and techniques for the design, manufacture and testing of electronic products. There are six taught modules and an 18-week major project. If you study part-time, you will study three modules per year.

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


MSc Embedded Systems Design (with internship):

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


MSc Embedded Systems Design (without internship):

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

Work Experience and Employment Prospects

Many industries need specialists in embedded systems design, and by the time you graduate, your skills and knowledge will be highly desired by employers. Careers are available in industrial and technology sectors such as embedded systems hardware or software development, telecommunication implementations, instrumentation, general real-time device applications, and signal processing development.

Internship

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

There are 10 internship places available. Students who wish to undertake an internship must apply for the MSc Embedded Systems Design (with internship). It is anticipated that there will be significant demand for this programme and applicants are advised to apply as soon as possible to avoid disappointment. Applications will be considered on a first come first served basis and the numbers of students offered a place on the programme with internship will be capped.

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

Assessment methods

Typically, each module will be assessed through coursework.

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The application of engineering in the field of biomedicine is gaining significant momentum with many emerging themes within the medical and healthcare communities. Read more
The application of engineering in the field of biomedicine is gaining significant momentum with many emerging themes within the medical and healthcare communities. Consequently there is an increasing demand to train science and engineering graduates to augment and extend their knowledge under the general umbrella of biomedical engineering.

The design and implementation of biomedical instrumentation in the form of monitoring, diagnostic or therapeutic devices is a growing specialist field and the demand for a suitably qualified workforce is set to expand rapidly as healthcare is increasingly devolved to smaller clinics and household devices.

London South Bank University is well placed to deliver first-rate professional education in this field because of the Division of Mechanical Engineering and Design's established work in telemedicine and signal processing, allied to our strong industry connections and reputation for developing innovative practical hardware solutions through knowledge transfer partnerships or other similar industrial collaborations. Together, with specialist input from the School of Health and Social Care, this programme enables graduate scientists and engineers to focus themselves towards a career in biomedical engineering.

The programme will cover a broad range of techniques for developing fundamental skills for medical applications of electronics and communications. Further, it will provide students with a thorough understanding of the field, specifically with practical knowledge and expertise sufficient to evaluate, design and build medical engineering systems using a wide range of tools and techniques.

See the website http://www.lsbu.ac.uk/courses/course-finder/biomedical-engineering-instrumentation-msc

Modules

- Technical, research and professional skills
This module introduces and develops the skills you'll need to make use of your technical knowledge as a professional engineer.

- Technology evaluation and commercialisation
This module will increase your awareness of the commercial aspects of your design embedded in your MSc project.

- Advanced instrumentation and control
You'll develop advanced techniques in data acquisition and manipulation that is required for instrumentation and control applications.

- Digital signal processing and real-time systems
You'll be introduced to the theory behind digital signal processing to including how it can be implemented in real-time and embedded systems.

- Applied biomedical sciences for engineers
This module introduces you to biological systems; from the organisational level of the molecular, to the organ and physiological functions of the whole body.

All modules have a number of assessment components. These can consist of assignments, mini tests, essays, laboratory reports and log books and examinations of various kinds.

Employability

This programme provides students with a thorough understanding of the field and with practical knowledge and expertise sufficient to evaluate, design and build medical engineering systems using a wide range of tools and techniques. This postgraduate programme aims to address the upsurge in interest in this field and the future need for highly skilled graduates in this area.

Graduate career opportunities

Jobs are widespread throughout the UK, particularly in NHS trusts. Manufacturing industries employ around 35 percent of all biomedical engineers, primarily in the pharmaceutical and medicine manufacturing and medical instruments and supplies industries. Many others work for hospitals. Some also worked for government agencies or as independent consultants. The workplace may be an office, laboratory, workshop, hospital, clinic or more likely a combination of the above.

After graduating from this course you'll acquire a broad range of techniques for developing basic skills for healthcare applications of electronic and instrumentation systems. You'll be able to design and build medical engineering systems using a large range of tools and techniques.

LSBU Employability Services

LSBU is committed to supporting you develop your employability and succeed in getting a job after you have graduated. Your qualification will certainly help, but in a competitive market you also need to work on your employability, and on your career search. Our Employability Service will support you in developing your skills, finding a job, interview techniques, work experience or an internship, and will help you assess what you need to do to get the job you want at the end of your course. LSBU offers a comprehensive Employability Service, with a range of initiatives to complement your studies, including:

- direct engagement from employers who come in to interview and talk to students
- Job Shop and on-campus recruitment agencies to help your job search
- mentoring and work shadowing schemes.

Professional links

The Department maintains active industry links through KTP schemes, spin-out companies, and industrial consultancy works. The industry requirements and needs are then fed back into the teaching to enhance the teaching quality and student learning experiences. This also improves personal development planning.

Established research expertise

This programme builds on the expertise of the research team established by the Biomedical Communications and Engineering (BiMEC) Research Group within the Department of Engineering and Design. This research group has diverse research interests broadly in the fields of telecommunications, computer networks, ultra wideband systems, opto-electronics, signal processing, embedded systems and software engineering.

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