This course is for students who want to become professionals in computer networks and modern telecommunications fields.
You will gain a comprehensive understanding of techniques used to transmit digital information, modern computer network design and operation, communication protocols and the importance of standards and regulatory issues
These subjects are supplemented by modules in technical and administration management techniques and by an industry-sponsored seminar course.
MSc students also undertake an individual project.
This course covers a comprehensive range of topics split in to four large modules worth 30 credits each plus the MSc Project.
External speakers from blue-chip and local companies will give seminars to complement your learning, that will be real-world case studies related to the subjects you are studying in your modules. These are designed to improve the breadth of your learning and often lead to ideas that you can develop for your MSc Project.
MSc (one year full-time or two years part-time)
PgDip (nine months full-time or one year and six months part-time)
MSc (one year and four months full-time)
PgDip (one year full-time)
Teaching will be in the form of lectures, individual and group class work, plus topical and relevant participative class discussions and critical evaluation using case studies
Laboratories will be used to provide you with hand-on experience of using and setting up network systems. Tutorials will be used to give you practice in solving theoretical and design problems associated with network technologies and network systems.
Over the programme, the assessment of the taught modules is as follows:
Graduates with experience of computer network systems and digital communications are in demand in all industrial and commercial sectors.
The employment record for the MSc is good, with students obtaining jobs in traditional telecommunication companies, software development companies and companies in the service and commercial sectors.
Typical jobs range from network design engineers, network maintenance, software development, systems design and integration, marketing, after-sales support and technical support.
We have links with companies such as large companies such as BT, Talk Talk, Motorolla, BBC, CICSO and local companies like i-wimax.
These companies engage with the University by giving guest seminars and often our students will work with them on their MSc Project.
Many of our graduates will go on to further study in our Computer Networks and Telecommunications Research Centre (CNTR)
The CNTR undertakes both pure and applied research in the general field of telecommunications and computer networking including computer networking technologies, wireless systems, networked multimedia applications, quality of service, mobile networking, intelligent buildings, context driven information systems, smart environments and communication protocols. Much of this work is funded through research grants and supported by industry. In addition, members of the group are actively involved in a range of public engagement programmes which aim to raise the awareness of these subjects for the general public and in schools.
Research themes in this Centre include:
You will have access to a dedicated computer networks lab which is equipped with industry standard equipment. In addition to PC equipment, the lab contains a set of switches, routers, servers, wireless equipment, testing tools and analysers which help you in building various data networks.
Various software tools and simulation packages are also available in the school's labs for you to use in your assignment and final projects. Such tools enable you to design and test data networks in simulated environments allowing you to experiment with your design before implementing the real network. The course is also supported by other facilities including PC suites, library, programming and office packages and a virtual learning environment.
SCAV is designed for engineering or STEM subject graduates. It is particularly suitable for those with a background in electronics, electrical engineering, control systems, or communications who want to play a role in the development of connected and autonomous vehicles, and the Intelligent Transportation Systems Network.
With the advent of smart, connected and autonomous vehicles on the horizon of technical advancements, the automotive industry is facing a developmental challenge. How do we develop a robust technical infrastructure to support the anticipated explosive growth in smart vehicular functions, communications systems and driverless cars? This demands a comprehensive understanding of the technology and a bottom-up approach ensuring robustness and dependability of Electronics, Communications (e.g. V-2-V, V-2-I) and Control Systems.
The strategic success of any industrial player in this area would depend on a ready availability of a skilled work-force within high level technical competencies, specifically catered for the automotive environment.
Through this MSc we aim to address the knowledge-gap in the areas of machine learning, automated control strategies, connectivity, and communication infrastructure, cyber-security protocols, emerging automotive networks and robust automotive embedded systems within the context of smart, connected and autonomous vehicles.
WMG at the University of Warwick has an established legacy of leading automotive research in collaboration with industry. Our unique experimental facilities enable academics and industry practitioners to work together and include:
This MSc programme has extensive industrial support with the Industry Advisory Board consisting of Jaguar Land Rover (JLR), RDM and other industrial stakeholders.
You will need to choose four elective modules from the module list*, which should be chosen to supplement your core modules above (subject to availability). *Important, please note: the list relates to modules available in 2017/18 academic year, and should be regarded as an illustrative guide to modules available in future years.
You are required to pass nine modules in total as part of this Master's course.
Leveraging the close partnerships that WMG has with key organisations within the automotive sector, it is envisaged that your project will have an industrial sponsor, enabling you to work in close collaboration with an industry partner. This valuable experience will further your transferrable skills development, and expand your networking opportunities and understanding in a professional research and development environment.
The project is worth 50% of the final grade, and supports you in developing research and analytical skills.
Work on your project runs concurrently with your module study.
The taught component of the course consists of lectures, workshops, practicals, demonstrations, syndicate exercises, extended surgery time and reviews. Module leaders are experts in their fields and are supported by external speakers working in organisations at the forefront of their fields.
Assessment is through post module assignment (PMA) rather than exam and is based on the learning objectives of each module. Your PMA should take around 60 hours of work and consolidate the knowledge you have gained from the module.
Each module usually lasts one week. There is more information here about the course structure.
Graduates of this MSc will understand a myriad of factors contributing towards the performance and dependability of connected and autonomous vehicles and will be well placed to continue professional work within R&D.
The MSc in New and Renewable Energy is designed to equip our graduates with the skills required to meet the growing challenge to achieve energy and environmental sustainability through the application of new and renewable energy technologies. The programme aims to enable students to develop the capacity to solve problems across the traditional Engineering boundaries and to have an appreciation of complete energy systems from source to end user, to have knowledge of the relevant technologies and to understand the interactions between them. The programme also provides students with the opportunity to develop skills in research, development, design and project management through individual and team-based project work.
The programme consists of four core modules to provide an advanced engineering education in New and Renewable Energy technologies alongside an optional module that allows students to increase their understanding in a core area suited to their interests and needs. The modules include lecture courses, laboratory experiments, a group design project and a major, individual research and development project.
Students select one optional module. In previous years optional modules have included:
This is a 12-month full time programme beginning at the start of the academic year and finishing with students submitting a report and completing an oral examination on their chosen research and development project. The programme consists of four core modules to provide a solid education in a broad range of New and Renewable Energy technologies. A choice of one from two optional modules allows students to choose a study programme most suited to their interests and needs. The modules include lecture courses, a group design project and an individual research and development project.
Students select one of two optional modules. These modules typically include 38 hours of lectures in addition to coursework and laboratory experiments, allowing students to develop research skills in parallel with lectures. The modules are designed to increase a student’s understanding in either thermodynamics and fluid mechanics or electrical engineering. Students are advised to select the module which they feel would best support their learning needs.
The core lecture modules typically involve 38 hours of lectures and cover topics such as electricity generation from renewable and conventional sources, transmission and distribution (including smart networks), electricity markets and optimisation, and low carbon technologies (including electrical vehicles).
The third core module is a group design project focused on a realistic application of renewable energy technology. Students gain experience of teamwork, presentation skills and project management, as well as the technical aspects of engineering design. Students also benefit from this opportunity to develop their research skills in preparation for their individual research and development project.
A major individual research and development project completes the core modules. This provides an open-ended challenge to each individual student, in collaboration with a staff supervisor. Regular meetings are held with the supervisor to discuss project progress and planning issues. A mid-term assessment is carried out to ensure project is on track. At the end of the project students are required to submit a final report on their work, in the style of a research paper. They are also required to prepare and present a poster to encourage further development of their ability to present their work to staff and their peers. An oral examination is held to allow detailed questions to be put to the student regarding the technical aspects of their project. Students should expect to have up to 15 hours of contact time with their supervisors plus over 500 hours of research work and preparation, supported by the School’s technicians and other research workers, over the course of their research projects.
This masters is multidisciplinary with a strong emphasis on Electrical and Mechanical Engineering. Electrical energy networks and the methods by which electrical energy is generated are changing. Generating resources are being connected to the distribution network rather than the transmission network. These distributed resources include renewables and conventional thermal plant. You will look in depth at the design, modelling, evaluation and operating requirements of smart girds. The masters is designed to give you an understanding of how the components in an energy or electricity network interact. With the increased contribution of renewable power, there’s a demand for highly-trained specialists with technical skills and knowledge in this area.
This programme is concerned with the concepts, applications, design, development and deployment of renewable generation and distributed electrical systems. It aims to enable students to acquire detailed knowledge and critical understanding of the core skills in renewable and distributed generation of electrical energy. Building on these, students will then develop and use a significant range of principal and specialist skills, techniques and practices in both renewable generation and distributed electrical energy systems, and apply this knowledge directly to complex applications.
Application period/deadline: November 1, 2017 - January 24, 2018
• Cutting-edge knowledge in wireless communications both at physical and network layers
• Capability to design and implement wireless solutions, e.g., for future 5G networks, Internet-of-Things (IoT) devices and smart energy-efficient wireless sensor applications
• Relevant skills of the latest radio engineering methods, tools, and technologies, and ability to design RF electronics for smart phones and base stations of mobile systems
The International Master’s Degree Programme in Wireless Communications Engineering (WCE) is a two-year programme concentrating on wireless communications network technology. The programme will give you relevant skills and core knowledge of the latest methods, tools and technologies combined with time-tested issues such as:
• Advanced wireless communication systems
• Communication networks
• Computer engineering
• Information theory
• Stochastical and digital signal processing
• Radio channels
• Radio engineering
The two-year programme has two specialisation options:
• Radio Access and Networks
• RF Engineering
Radio Access and Networks concentrates on designing and applying radio access technologies both at physical layer and at network layer for 5G, IoT, and future mobile system generations.
RF Engineering focuses on essential radio system parts and gives the knowledge to design integrated RF and DSP circuits for mobile handsets, base stations, future 5G devices, IoT applications, and smart & energy efficient sensors.
Optional module makes it possible to widen your expertise into:
• Machine vision
• Mobile and social computing
• Signal processors, and
• Video and biomedical signal processing.
The education is organized by the Centre for Wireless Communications which consists of 150 academics from over 20 countries. CWC performs world-class research for the future of 5G and IoT applications, which will give you the possibility to move forward already during your studies. CWC provides a number of jobs as a trainee or a master’s thesis student, with the possibility to continue as a doctoral student, and even as a post-doctoral researcher.
The skills gained in the programme offer you a solid academic training and essential knowledge on the design of wireless communications networks at the system level. After graduation you are capable of designing, implementing and employing 5G and IoT applications and developing future wireless communications technologies.
Possible titles include:
• Chief engineer
• Design engineer
• Development engineer
• Maintenance engineer
• Patent engineer
• Program manager
• Project manager
• Radio network designer
• Research engineer
• RF engineer
• Sales engineer
• System engineer
• Test engineer, and
• University teacher
Students applying for the programme must possess an applicable B.Sc. degree in one of the following fields of study: communications engineering, electronics & electrical engineering, or computer engineering.